mamamiya405/verilog · Datasets at Hugging Face

text stringlengths 992 1.04M
// (C) 2001-2016 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. // THIS FILE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL // THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING // FROM, OUT OF OR IN CONNECTION WITH THIS FILE OR THE USE OR OTHER DEALINGS // IN THIS FILE. /****************************************************************************** * * * This module is a FIFO with same clock for both reads and writes. * * * ****************************************************************************/ module altera_up_sync_fifo ( // Inputs clk, reset, write_en, write_data, read_en, // Bidirectionals // Outputs fifo_is_empty, fifo_is_full, words_used, read_data ); /*************************************************************************** * Parameter Declarations * ***************************************************************************/ parameter DW = 31; // Data width parameter DATA_DEPTH = 128; parameter AW = 6; // Address width /*************************************************************************** * Port Declarations * ***************************************************************************/ // Inputs input clk; input reset; input write_en; input [DW: 0] write_data; input read_en; // Bidirectionals // Outputs output fifo_is_empty; output fifo_is_full; output [AW: 0] words_used; output [DW: 0] read_data; /*************************************************************************** * Constant Declarations * ***************************************************************************/ /*************************************************************************** * Internal Wires and Registers Declarations * ***************************************************************************/ // Internal Wires // Internal Registers // State Machine Registers /*************************************************************************** * Finite State Machine(s) * ***************************************************************************/ /*************************************************************************** * Sequential Logic * ***************************************************************************/ /*************************************************************************** * Combinational Logic * ***************************************************************************/ /*************************************************************************** * Internal Modules * *****************************************************************************/ scfifo Sync_FIFO ( // Inputs .clock (clk), .sclr (reset), .data (write_data), .wrreq (write_en), .rdreq (read_en), // Bidirectionals // Outputs .empty (fifo_is_empty), .full (fifo_is_full), .usedw (words_used), .q (read_data), // Unused // synopsys translate_off .aclr (), .almost_empty (), .almost_full () // synopsys translate_on ); defparam Sync_FIFO.add_ram_output_register = "OFF", Sync_FIFO.intended_device_family = "Cyclone II", Sync_FIFO.lpm_numwords = DATA_DEPTH, Sync_FIFO.lpm_showahead = "ON", Sync_FIFO.lpm_type = "scfifo", Sync_FIFO.lpm_width = DW + 1, Sync_FIFO.lpm_widthu = AW + 1, Sync_FIFO.overflow_checking = "OFF", Sync_FIFO.underflow_checking = "OFF", Sync_FIFO.use_eab = "ON"; endmodule
// Copyright 1986-2014 Xilinx, Inc. All Rights Reserved. // -------------------------------------------------------------------------------- // Tool Version: Vivado v.2014.1 (lin64) Build 881834 Fri Apr 4 14:00:25 MDT 2014 // Date : Thu May 1 14:05:15 2014 // Host : macbook running 64-bit Arch Linux // Command : write_verilog -force -mode synth_stub /home/keith/Documents/VHDL-lib/top/lab_7/part_3/ip/bram/bram_stub.v // Design : bram // Purpose : Stub declaration of top-level module interface // Device : xc7z020clg484-1 // -------------------------------------------------------------------------------- // This empty module with port declaration file causes synthesis tools to infer a black box for IP. // The synthesis directives are for Synopsys Synplify support to prevent IO buffer insertion. // Please paste the declaration into a Verilog source file or add the file as an additional source. (* x_core_info = "blk_mem_gen_v8_2,Vivado 2014.1" ) module bram(clka, wea, addra, dina, clkb, addrb, doutb) / synthesis syn_black_box black_box_pad_pin="clka,wea[0:0],addra[10:0],dina[15:0],clkb,addrb[10:0],doutb[15:0]" */; input clka; input [0:0]wea; input [10:0]addra; input [15:0]dina; input clkb; input [10:0]addrb; output [15:0]doutb; endmodule
/** * $Id: bus_clk_bridge.v 961 2014-01-21 11:40:39Z matej.oblak $ * * @brief Red Pitaya system bus clock crossing bridge. * * @Author Matej Oblak * * (c) Red Pitaya http://www.redpitaya.com * * This part of code is written in Verilog hardware description language (HDL). * Please visit http://en.wikipedia.org/wiki/Verilog * for more details on the language used herein. / /* * GENERAL DESCRIPTION: * * Clock domain bridge for system bus. * * * /------\ * SYSTEM \| \| PROCESSING * BUS <-----> \| SYNC \| <-----> BUS * \| \| * \------/ * * * System bus runs on one clock domain while processing runs on separate. To * simplify transition of writing and reading data this bridge was created. * */ module bus_clk_bridge ( // system bus input sys_clk_i , //!< bus clock input sys_rstn_i , //!< bus reset - active low input [ 32-1: 0] sys_addr_i , //!< bus address input [ 32-1: 0] sys_wdata_i , //!< bus write data input [ 4-1: 0] sys_sel_i , //!< bus write byte select input sys_wen_i , //!< bus write enable input sys_ren_i , //!< bus read enable output [ 32-1: 0] sys_rdata_o , //!< bus read data output sys_err_o , //!< bus error indicator output sys_ack_o , //!< bus acknowledge signal // Destination bus input clk_i , //!< clock input rstn_i , //!< reset - active low output reg [ 32-1: 0] addr_o , //!< address output reg [ 32-1: 0] wdata_o , //!< write data output wen_o , //!< write enable output ren_o , //!< read enable input [ 32-1: 0] rdata_i , //!< read data input err_i , //!< error indicator input ack_i //!< acknowledge signal ); //--------------------------------------------------------------------------------- // Synchronize signals between clock domains reg sys_rd ; reg sys_wr ; reg sys_do ; reg [ 2-1: 0] sys_sync ; reg sys_done ; reg dst_do ; reg [ 2-1: 0] dst_sync ; reg dst_done ; always @(posedge sys_clk_i) begin if (sys_rstn_i == 1'b0) begin sys_rd <= 1'b0 ; sys_wr <= 1'b0 ; sys_do <= 1'b0 ; sys_sync <= 2'h0 ; sys_done <= 1'b0 ; end else begin if ((sys_do == sys_done) && (sys_wen_i \|\| sys_ren_i)) begin addr_o <= sys_addr_i ; wdata_o <= sys_wdata_i ; sys_rd <= sys_ren_i ; sys_wr <= sys_wen_i ; sys_do <= !sys_do ; end sys_sync <= {sys_sync[0], dst_done}; sys_done <= sys_sync[1]; end end always @(posedge clk_i) begin if (rstn_i == 1'b0) begin dst_do <= 1'b0 ; dst_sync <= 2'h0 ; dst_done <= 1'b0 ; end else begin dst_sync <= {dst_sync[0], sys_do}; dst_do <= dst_sync[1]; if (ack_i && (dst_do != dst_done)) dst_done <= dst_do; end end assign ren_o = sys_rd && (dst_sync[1]^dst_do); assign wen_o = sys_wr && (dst_sync[1]^dst_do); assign sys_rdata_o = rdata_i ; assign sys_err_o = err_i ; assign sys_ack_o = sys_done ^ sys_sync[1] ; endmodule
//*************************************************************************** // (c) Copyright 2009 - 2013 Xilinx, Inc. All rights reserved. // // This file contains confidential and proprietary information // of Xilinx, Inc. and is protected under U.S. and // international copyright and other intellectual property // laws. // // DISCLAIMER // This disclaimer is not a license and does not grant any // rights to the materials distributed herewith. Except as // otherwise provided in a valid license issued to you by // Xilinx, and to the maximum extent permitted by applicable // law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // (2) Xilinx shall not be liable (whether in contract or tort, // including negligence, or under any other theory of // liability) for any loss or damage of any kind or nature // related to, arising under or in connection with these // materials, including for any direct, or any indirect, // special, incidental, or consequential loss or damage // (including loss of data, profits, goodwill, or any type of // loss or damage suffered as a result of any action brought // by a third party) even if such damage or loss was // reasonably foreseeable or Xilinx had been advised of the // possibility of the same. // // CRITICAL APPLICATIONS // Xilinx products are not designed or intended to be fail- // safe, or for use in any application requiring fail-safe // performance, such as life-support or safety devices or // systems, Class III medical devices, nuclear facilities, // applications related to the deployment of airbags, or any // other applications that could lead to death, personal // injury, or severe property or environmental damage // (individually and collectively, "Critical // Applications"). Customer assumes the sole risk and // liability of any use of Xilinx products in Critical // Applications, subject only to applicable laws and // regulations governing limitations on product liability. // // THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // PART OF THIS FILE AT ALL TIMES. // //************************************************************************* // ____ ____ // / /\/ / // /___/ \ / Vendor: Xilinx // \ \ \/ Version: // \ \ Application: MIG // / / Filename: ddr_phy_dqs_found_cal.v // /___/ /\ Date Last Modified: $Date: 2011/06/02 08:35:08 $ // \ \ / \ Date Created: // \___\/\___\ // //Device: 7 Series //Design Name: DDR3 SDRAM //Purpose: // Read leveling calibration logic // NOTES: // 1. Phaser_In DQSFOUND calibration //Reference: //Revision History: //************************************************************************* /************************************************************************** $Id: ddr_phy_dqs_found_cal.v,v 1.1 2011/06/02 08:35:08 mishra Exp $ $Date: 2011/06/02 08:35:08 $ $Author: $Revision: $Source: *****************************************************************************/ `timescale 1ps/1ps module mig_7series_v2_3_ddr_phy_dqs_found_cal_hr # ( parameter TCQ = 100, // clk->out delay (sim only) parameter nCK_PER_CLK = 2, // # of memory clocks per CLK parameter nCL = 5, // Read CAS latency parameter AL = "0", parameter nCWL = 5, // Write CAS latency parameter DRAM_TYPE = "DDR3", // Memory I/F type: "DDR3", "DDR2" parameter RANKS = 1, // # of memory ranks in the system parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH)) parameter DQS_WIDTH = 8, // # of DQS (strobe) parameter DRAM_WIDTH = 8, // # of DQ per DQS parameter REG_CTRL = "ON", // "ON" for registered DIMM parameter SIM_CAL_OPTION = "NONE", // Performs all calibration steps parameter NUM_DQSFOUND_CAL = 3, // Number of times to iterate parameter N_CTL_LANES = 3, // Number of control byte lanes parameter HIGHEST_LANE = 12, // Sum of byte lanes (Data + Ctrl) parameter HIGHEST_BANK = 3, // Sum of I/O Banks parameter BYTE_LANES_B0 = 4'b1111, parameter BYTE_LANES_B1 = 4'b0000, parameter BYTE_LANES_B2 = 4'b0000, parameter BYTE_LANES_B3 = 4'b0000, parameter BYTE_LANES_B4 = 4'b0000, parameter DATA_CTL_B0 = 4'hc, parameter DATA_CTL_B1 = 4'hf, parameter DATA_CTL_B2 = 4'hf, parameter DATA_CTL_B3 = 4'hf, parameter DATA_CTL_B4 = 4'hf ) ( input clk, input rst, input dqsfound_retry, // From phy_init input pi_dqs_found_start, input detect_pi_found_dqs, input prech_done, // DQSFOUND per Phaser_IN input [HIGHEST_LANE-1:0] pi_dqs_found_lanes, output reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal, // To phy_init output [5:0] rd_data_offset_0, output [5:0] rd_data_offset_1, output [5:0] rd_data_offset_2, output pi_dqs_found_rank_done, output pi_dqs_found_done, output reg pi_dqs_found_err, output [6RANKS-1:0] rd_data_offset_ranks_0, output [6RANKS-1:0] rd_data_offset_ranks_1, output [6RANKS-1:0] rd_data_offset_ranks_2, output reg dqsfound_retry_done, output reg dqs_found_prech_req, //To MC output [6RANKS-1:0] rd_data_offset_ranks_mc_0, output [6RANKS-1:0] rd_data_offset_ranks_mc_1, output [6RANKS-1:0] rd_data_offset_ranks_mc_2, input [8:0] po_counter_read_val, output rd_data_offset_cal_done, output fine_adjust_done, output [N_CTL_LANES-1:0] fine_adjust_lane_cnt, output reg ck_po_stg2_f_indec, output reg ck_po_stg2_f_en, output [255:0] dbg_dqs_found_cal ); // For non-zero AL values localparam nAL = (AL == "CL-1") ? nCL - 1 : 0; // Adding the register dimm latency to write latency localparam CWL_M = (REG_CTRL == "ON") ? nCWL + nAL + 1 : nCWL + nAL; // Added to reduce simulation time localparam LATENCY_FACTOR = 13; localparam NUM_READS = (SIM_CAL_OPTION == "NONE") ? 7 : 1; localparam [19:0] DATA_PRESENT = {(DATA_CTL_B4[3] & BYTE_LANES_B4[3]), (DATA_CTL_B4[2] & BYTE_LANES_B4[2]), (DATA_CTL_B4[1] & BYTE_LANES_B4[1]), (DATA_CTL_B4[0] & BYTE_LANES_B4[0]), (DATA_CTL_B3[3] & BYTE_LANES_B3[3]), (DATA_CTL_B3[2] & BYTE_LANES_B3[2]), (DATA_CTL_B3[1] & BYTE_LANES_B3[1]), (DATA_CTL_B3[0] & BYTE_LANES_B3[0]), (DATA_CTL_B2[3] & BYTE_LANES_B2[3]), (DATA_CTL_B2[2] & BYTE_LANES_B2[2]), (DATA_CTL_B2[1] & BYTE_LANES_B2[1]), (DATA_CTL_B2[0] & BYTE_LANES_B2[0]), (DATA_CTL_B1[3] & BYTE_LANES_B1[3]), (DATA_CTL_B1[2] & BYTE_LANES_B1[2]), (DATA_CTL_B1[1] & BYTE_LANES_B1[1]), (DATA_CTL_B1[0] & BYTE_LANES_B1[0]), (DATA_CTL_B0[3] & BYTE_LANES_B0[3]), (DATA_CTL_B0[2] & BYTE_LANES_B0[2]), (DATA_CTL_B0[1] & BYTE_LANES_B0[1]), (DATA_CTL_B0[0] & BYTE_LANES_B0[0])}; localparam FINE_ADJ_IDLE = 4'h0; localparam RST_POSTWAIT = 4'h1; localparam RST_POSTWAIT1 = 4'h2; localparam RST_WAIT = 4'h3; localparam FINE_ADJ_INIT = 4'h4; localparam FINE_INC = 4'h5; localparam FINE_INC_WAIT = 4'h6; localparam FINE_INC_PREWAIT = 4'h7; localparam DETECT_PREWAIT = 4'h8; localparam DETECT_DQSFOUND = 4'h9; localparam PRECH_WAIT = 4'hA; localparam FINE_DEC = 4'hB; localparam FINE_DEC_WAIT = 4'hC; localparam FINE_DEC_PREWAIT = 4'hD; localparam FINAL_WAIT = 4'hE; localparam FINE_ADJ_DONE = 4'hF; integer k,l,m,n,p,q,r,s; reg dqs_found_start_r; reg [6HIGHEST_BANK-1:0] rd_byte_data_offset[0:RANKS-1]; reg rank_done_r; reg rank_done_r1; reg dqs_found_done_r; (* ASYNC_REG = "TRUE" ) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r1; ( ASYNC_REG = "TRUE" ) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r2; ( ASYNC_REG = "TRUE" ) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r3; reg init_dqsfound_done_r; reg init_dqsfound_done_r1; reg init_dqsfound_done_r2; reg init_dqsfound_done_r3; reg init_dqsfound_done_r4; reg init_dqsfound_done_r5; reg [1:0] rnk_cnt_r; reg [2:0 ] final_do_index[0:RANKS-1]; reg [5:0 ] final_do_max[0:RANKS-1]; reg [6HIGHEST_BANK-1:0] final_data_offset[0:RANKS-1]; reg [6HIGHEST_BANK-1:0] final_data_offset_mc[0:RANKS-1]; reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal_r; reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal_r1; reg [10HIGHEST_BANK-1:0] retry_cnt; reg dqsfound_retry_r1; wire [4HIGHEST_BANK-1:0] pi_dqs_found_lanes_int; reg [HIGHEST_BANK-1:0] pi_dqs_found_all_bank; reg [HIGHEST_BANK-1:0] pi_dqs_found_all_bank_r; reg [HIGHEST_BANK-1:0] pi_dqs_found_any_bank; reg [HIGHEST_BANK-1:0] pi_dqs_found_any_bank_r; reg [HIGHEST_BANK-1:0] pi_dqs_found_err_r; // CK/Control byte lanes fine adjust stage reg fine_adjust; reg [N_CTL_LANES-1:0] ctl_lane_cnt; reg [3:0] fine_adj_state_r; reg fine_adjust_done_r; reg rst_dqs_find; reg rst_dqs_find_r1; reg rst_dqs_find_r2; reg [5:0] init_dec_cnt; reg [5:0] dec_cnt; reg [5:0] inc_cnt; reg final_dec_done; reg init_dec_done; reg first_fail_detect; reg second_fail_detect; reg [5:0] first_fail_taps; reg [5:0] second_fail_taps; reg [5:0] stable_pass_cnt; reg [3:0] detect_rd_cnt; //************************************************************************ // Debug signals // //************************************************************************* assign dbg_dqs_found_cal[5:0] = first_fail_taps; assign dbg_dqs_found_cal[11:6] = second_fail_taps; assign dbg_dqs_found_cal[12] = first_fail_detect; assign dbg_dqs_found_cal[13] = second_fail_detect; assign dbg_dqs_found_cal[14] = fine_adjust_done_r; assign pi_dqs_found_rank_done = rank_done_r; assign pi_dqs_found_done = dqs_found_done_r; generate genvar rnk_cnt; if (HIGHEST_BANK == 3) begin // Three Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6rnk_cnt+:6] = final_data_offset[rnk_cnt][11:6]; assign rd_data_offset_ranks_2[6rnk_cnt+:6] = final_data_offset[rnk_cnt][17:12]; assign rd_data_offset_ranks_mc_0[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][11:6]; assign rd_data_offset_ranks_mc_2[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][17:12]; end end else if (HIGHEST_BANK == 2) begin // Two Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6rnk_cnt+:6] = final_data_offset[rnk_cnt][11:6]; assign rd_data_offset_ranks_2[6rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_0[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][11:6]; assign rd_data_offset_ranks_mc_2[6rnk_cnt+:6] = 'd0; end end else begin // Single Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_2[6rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_0[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_2[6rnk_cnt+:6] = 'd0; end end endgenerate // final_data_offset is used during write calibration and during // normal operation. One rd_data_offset value per rank for entire // interface generate if (HIGHEST_BANK == 3) begin // Three I/O Bank interface assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][6+:6] : final_data_offset[rnk_cnt_r][6+:6]; assign rd_data_offset_2 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][12+:6] : final_data_offset[rnk_cnt_r][12+:6]; end else if (HIGHEST_BANK == 2) begin // Two I/O Bank interface assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][6+:6] : final_data_offset[rnk_cnt_r][6+:6]; assign rd_data_offset_2 = 'd0; end else begin assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = 'd0; assign rd_data_offset_2 = 'd0; end endgenerate assign rd_data_offset_cal_done = init_dqsfound_done_r; assign fine_adjust_lane_cnt = ctl_lane_cnt; //************************************************************************ // DQSFOUND all and any generation // pi_dqs_found_all_bank[x] asserted when all Phaser_INs in Bankx are // asserted // pi_dqs_found_any_bank[x] asserted when at least one Phaser_IN in Bankx // is asserted //************************************************************************ generate if ((HIGHEST_LANE == 4) \|\| (HIGHEST_LANE == 8) \|\| (HIGHEST_LANE == 12)) assign pi_dqs_found_lanes_int = pi_dqs_found_lanes_r3; else if ((HIGHEST_LANE == 7) \|\| (HIGHEST_LANE == 11)) assign pi_dqs_found_lanes_int = {1'b0, pi_dqs_found_lanes_r3}; else if ((HIGHEST_LANE == 6) \|\| (HIGHEST_LANE == 10)) assign pi_dqs_found_lanes_int = {2'b00, pi_dqs_found_lanes_r3}; else if ((HIGHEST_LANE == 5) \|\| (HIGHEST_LANE == 9)) assign pi_dqs_found_lanes_int = {3'b000, pi_dqs_found_lanes_r3}; endgenerate always @(posedge clk) begin if (rst) begin for (k = 0; k < HIGHEST_BANK; k = k + 1) begin: rst_pi_dqs_found pi_dqs_found_all_bank[k] <= #TCQ 'b0; pi_dqs_found_any_bank[k] <= #TCQ 'b0; end end else if (pi_dqs_found_start) begin for (p = 0; p < HIGHEST_BANK; p = p +1) begin: assign_pi_dqs_found pi_dqs_found_all_bank[p] <= #TCQ (!DATA_PRESENT[4p+0] \| pi_dqs_found_lanes_int[4p+0]) & (!DATA_PRESENT[4p+1] \| pi_dqs_found_lanes_int[4p+1]) & (!DATA_PRESENT[4p+2] \| pi_dqs_found_lanes_int[4p+2]) & (!DATA_PRESENT[4p+3] \| pi_dqs_found_lanes_int[4p+3]); pi_dqs_found_any_bank[p] <= #TCQ (DATA_PRESENT[4p+0] & pi_dqs_found_lanes_int[4p+0]) \| (DATA_PRESENT[4p+1] & pi_dqs_found_lanes_int[4p+1]) \| (DATA_PRESENT[4p+2] & pi_dqs_found_lanes_int[4p+2]) \| (DATA_PRESENT[4p+3] & pi_dqs_found_lanes_int[4p+3]); end end end always @(posedge clk) begin pi_dqs_found_all_bank_r <= #TCQ pi_dqs_found_all_bank; pi_dqs_found_any_bank_r <= #TCQ pi_dqs_found_any_bank; end //*************************************************************************** // Counter to increase number of 4 back-to-back reads per rd_data_offset and // per CK/A/C tap value //************************************************************************* always @(posedge clk) begin if (rst \|\| (detect_rd_cnt == 'd0)) detect_rd_cnt <= #TCQ NUM_READS; else if (detect_pi_found_dqs && (detect_rd_cnt > 'd0)) detect_rd_cnt <= #TCQ detect_rd_cnt - 1; end //********************************************************************** // Adjust Phaser_Out stage 2 taps on CK/Address/Command/Controls // //********************************************************************** assign fine_adjust_done = fine_adjust_done_r; always @(posedge clk) begin rst_dqs_find_r1 <= #TCQ rst_dqs_find; rst_dqs_find_r2 <= #TCQ rst_dqs_find_r1; end always @(posedge clk) begin if(rst)begin fine_adjust <= #TCQ 1'b0; ctl_lane_cnt <= #TCQ 'd0; fine_adj_state_r <= #TCQ FINE_ADJ_IDLE; fine_adjust_done_r <= #TCQ 1'b0; ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; rst_dqs_find <= #TCQ 1'b0; init_dec_cnt <= #TCQ 'd31; dec_cnt <= #TCQ 'd0; inc_cnt <= #TCQ 'd0; init_dec_done <= #TCQ 1'b0; final_dec_done <= #TCQ 1'b0; first_fail_detect <= #TCQ 1'b0; second_fail_detect <= #TCQ 1'b0; first_fail_taps <= #TCQ 'd0; second_fail_taps <= #TCQ 'd0; stable_pass_cnt <= #TCQ 'd0; dqs_found_prech_req<= #TCQ 1'b0; end else begin case (fine_adj_state_r) FINE_ADJ_IDLE: begin if (init_dqsfound_done_r5) begin if (SIM_CAL_OPTION == "FAST_CAL") begin fine_adjust <= #TCQ 1'b1; fine_adj_state_r <= #TCQ FINE_ADJ_DONE; rst_dqs_find <= #TCQ 1'b0; end else begin fine_adjust <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; rst_dqs_find <= #TCQ 1'b1; end end end RST_WAIT: begin if (~(\|pi_dqs_found_any_bank) && rst_dqs_find_r2) begin rst_dqs_find <= #TCQ 1'b0; if (\|init_dec_cnt) fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; else if (final_dec_done) fine_adj_state_r <= #TCQ FINE_ADJ_DONE; else fine_adj_state_r <= #TCQ RST_POSTWAIT; end end RST_POSTWAIT: begin fine_adj_state_r <= #TCQ RST_POSTWAIT1; end RST_POSTWAIT1: begin fine_adj_state_r <= #TCQ FINE_ADJ_INIT; end FINE_ADJ_INIT: begin //if (detect_pi_found_dqs && (inc_cnt < 'd63)) fine_adj_state_r <= #TCQ FINE_INC; end FINE_INC: begin fine_adj_state_r <= #TCQ FINE_INC_WAIT; ck_po_stg2_f_indec <= #TCQ 1'b1; ck_po_stg2_f_en <= #TCQ 1'b1; if (ctl_lane_cnt == N_CTL_LANES-1) inc_cnt <= #TCQ inc_cnt + 1; end FINE_INC_WAIT: begin ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; if (ctl_lane_cnt != N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ ctl_lane_cnt + 1; fine_adj_state_r <= #TCQ FINE_INC_PREWAIT; end else if (ctl_lane_cnt == N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ 'd0; fine_adj_state_r <= #TCQ DETECT_PREWAIT; end end FINE_INC_PREWAIT: begin fine_adj_state_r <= #TCQ FINE_INC; end DETECT_PREWAIT: begin if (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) fine_adj_state_r <= #TCQ DETECT_DQSFOUND; else fine_adj_state_r <= #TCQ DETECT_PREWAIT; end DETECT_DQSFOUND: begin if (detect_pi_found_dqs && ~(&pi_dqs_found_all_bank)) begin stable_pass_cnt <= #TCQ 'd0; if (~first_fail_detect && (inc_cnt == 'd63)) begin // First failing tap detected at 63 taps // then decrement to 31 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ 'd32; end else if (~first_fail_detect && (inc_cnt > 'd30) && (stable_pass_cnt > 'd29)) begin // First failing tap detected at greater than 30 taps // then stop looking for second edge and decrement first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ (inc_cnt>>1) + 1; end else if (~first_fail_detect \|\| (first_fail_detect && (stable_pass_cnt < 'd30) && (inc_cnt <= 'd32))) begin // First failing tap detected, continue incrementing // until either second failing tap detected or 63 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; rst_dqs_find <= #TCQ 1'b1; if ((inc_cnt == 'd12) \|\| (inc_cnt == 'd24)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else fine_adj_state_r <= #TCQ RST_WAIT; end else if (first_fail_detect && (inc_cnt > 'd32) && (inc_cnt < 'd63) && (stable_pass_cnt < 'd30)) begin // Consecutive 30 taps of passing region was not found // continue incrementing first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; rst_dqs_find <= #TCQ 1'b1; if ((inc_cnt == 'd36) \|\| (inc_cnt == 'd48) \|\| (inc_cnt == 'd60)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else fine_adj_state_r <= #TCQ RST_WAIT; end else if (first_fail_detect && (inc_cnt == 'd63)) begin if (stable_pass_cnt < 'd30) begin // Consecutive 30 taps of passing region was not found // from tap 0 to 63 so decrement back to 31 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ 'd32; end else begin // Consecutive 30 taps of passing region was found // between first_fail_taps and 63 fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); end end else begin // Second failing tap detected, decrement to center of // failing taps second_fail_detect <= #TCQ 1'b1; second_fail_taps <= #TCQ inc_cnt; dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); fine_adj_state_r <= #TCQ FINE_DEC; end end else if (detect_pi_found_dqs && (&pi_dqs_found_all_bank)) begin stable_pass_cnt <= #TCQ stable_pass_cnt + 1; if ((inc_cnt == 'd12) \|\| (inc_cnt == 'd24) \|\| (inc_cnt == 'd36) \|\| (inc_cnt == 'd48) \|\| (inc_cnt == 'd60)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else if (inc_cnt < 'd63) begin rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end else begin fine_adj_state_r <= #TCQ FINE_DEC; if (~first_fail_detect \|\| (first_fail_taps > 'd33)) // No failing taps detected, decrement by 31 dec_cnt <= #TCQ 'd32; //else if (first_fail_detect && (stable_pass_cnt > 'd28)) // // First failing tap detected between 0 and 34 // // decrement midpoint between 63 and failing tap // dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); else // First failing tap detected // decrement to midpoint between 63 and failing tap dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); end end end PRECH_WAIT: begin if (prech_done) begin dqs_found_prech_req <= #TCQ 1'b0; rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end end FINE_DEC: begin fine_adj_state_r <= #TCQ FINE_DEC_WAIT; ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b1; if ((ctl_lane_cnt == N_CTL_LANES-1) && (init_dec_cnt > 'd0)) init_dec_cnt <= #TCQ init_dec_cnt - 1; else if ((ctl_lane_cnt == N_CTL_LANES-1) && (dec_cnt > 'd0)) dec_cnt <= #TCQ dec_cnt - 1; end FINE_DEC_WAIT: begin ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; if (ctl_lane_cnt != N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ ctl_lane_cnt + 1; fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; end else if (ctl_lane_cnt == N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ 'd0; if ((dec_cnt > 'd0) \|\| (init_dec_cnt > 'd0)) fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; else begin fine_adj_state_r <= #TCQ FINAL_WAIT; if ((init_dec_cnt == 'd0) && ~init_dec_done) init_dec_done <= #TCQ 1'b1; else final_dec_done <= #TCQ 1'b1; end end end FINE_DEC_PREWAIT: begin fine_adj_state_r <= #TCQ FINE_DEC; end FINAL_WAIT: begin rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end FINE_ADJ_DONE: begin if (&pi_dqs_found_all_bank) begin fine_adjust_done_r <= #TCQ 1'b1; rst_dqs_find <= #TCQ 1'b0; fine_adj_state_r <= #TCQ FINE_ADJ_DONE; end end endcase end end //************************************************************************* always@(posedge clk) dqs_found_start_r <= #TCQ pi_dqs_found_start; always @(posedge clk) begin if (rst) rnk_cnt_r <= #TCQ 2'b00; else if (init_dqsfound_done_r) rnk_cnt_r <= #TCQ rnk_cnt_r; else if (rank_done_r) rnk_cnt_r <= #TCQ rnk_cnt_r + 1; end //************************************************************* // Read data_offset calibration done signal //************************************************************* always @(posedge clk) begin if (rst \|\| (\|pi_rst_stg1_cal_r)) init_dqsfound_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank) begin if (rnk_cnt_r == RANKS-1) init_dqsfound_done_r <= #TCQ 1'b1; else init_dqsfound_done_r <= #TCQ 1'b0; end end always @(posedge clk) begin if (rst \|\| (init_dqsfound_done_r && (rnk_cnt_r == RANKS-1))) rank_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank && ~(&pi_dqs_found_all_bank_r)) rank_done_r <= #TCQ 1'b1; else rank_done_r <= #TCQ 1'b0; end always @(posedge clk) begin pi_dqs_found_lanes_r1 <= #TCQ pi_dqs_found_lanes; pi_dqs_found_lanes_r2 <= #TCQ pi_dqs_found_lanes_r1; pi_dqs_found_lanes_r3 <= #TCQ pi_dqs_found_lanes_r2; init_dqsfound_done_r1 <= #TCQ init_dqsfound_done_r; init_dqsfound_done_r2 <= #TCQ init_dqsfound_done_r1; init_dqsfound_done_r3 <= #TCQ init_dqsfound_done_r2; init_dqsfound_done_r4 <= #TCQ init_dqsfound_done_r3; init_dqsfound_done_r5 <= #TCQ init_dqsfound_done_r4; rank_done_r1 <= #TCQ rank_done_r; dqsfound_retry_r1 <= #TCQ dqsfound_retry; end always @(posedge clk) begin if (rst) dqs_found_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank && (rnk_cnt_r == RANKS-1) && init_dqsfound_done_r1 && (fine_adj_state_r == FINE_ADJ_DONE)) dqs_found_done_r <= #TCQ 1'b1; else dqs_found_done_r <= #TCQ 1'b0; end generate if (HIGHEST_BANK == 3) begin // Three I/O Bank interface // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[0] \|\| fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[0]) \|\| (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) \|\| (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[1] \|\| fine_adjust) pi_rst_stg1_cal_r[1] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[1]) \|\| (pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) \|\| (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[2] \|\| fine_adjust) pi_rst_stg1_cal_r[2] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[2]) \|\| (pi_dqs_found_any_bank_r[2] && ~pi_dqs_found_all_bank[2]) \|\| (rd_byte_data_offset[rnk_cnt_r][12+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[2] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[2]) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[2] && ~pi_dqs_found_all_bank[2]) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b0; end //************************************************************************* // Retry counter to track number of DQSFOUND retries //************************************************************************* always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[10+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[1]) retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10] + 1; else retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10]; end always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[20+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][12+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[2]) retry_cnt[20+:10] <= #TCQ retry_cnt[20+:10] + 1; else retry_cnt[20+:10] <= #TCQ retry_cnt[20+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[1] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[1] && (retry_cnt[10+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[2] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[2] && (retry_cnt[20+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][12+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[2] <= #TCQ 1'b1; end // Read data offset value for all DQS in a Bank always @(posedge clk) begin if (rst) begin for (q = 0; q < RANKS; q = q + 1) begin: three_bank0_rst_loop rd_byte_data_offset[q][0+:6] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][0+:6] + 1; end always @(posedge clk) begin if (rst) begin for (r = 0; r < RANKS; r = r + 1) begin: three_bank1_rst_loop rd_byte_data_offset[r][6+:6] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[1] && //(rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][6+:6] + 1; end always @(posedge clk) begin if (rst) begin for (s = 0; s < RANKS; s = s + 1) begin: three_bank2_rst_loop rd_byte_data_offset[s][12+:6] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r][12+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r][12+:6] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[2] && //(rd_byte_data_offset[rnk_cnt_r][12+:6] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][12+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][12+:6] + 1; end //************************************************************************* // Two I/O Bank Interface //************************************************************************* end else if (HIGHEST_BANK == 2) begin // Two I/O Bank interface // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[0] \|\| fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[0]) \|\| (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) \|\| (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[1] \|\| fine_adjust) pi_rst_stg1_cal_r[1] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[1]) \|\| (pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) \|\| (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; end //************************************************************************* // Retry counter to track number of DQSFOUND retries //************************************************************************* always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[10+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[1]) retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10] + 1; else retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[1] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[1] && (retry_cnt[10+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[1] <= #TCQ 1'b1; end // Read data offset value for all DQS in a Bank always @(posedge clk) begin if (rst) begin for (q = 0; q < RANKS; q = q + 1) begin: two_bank0_rst_loop rd_byte_data_offset[q][0+:6] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][0+:6] + 1; end always @(posedge clk) begin if (rst) begin for (r = 0; r < RANKS; r = r + 1) begin: two_bank1_rst_loop rd_byte_data_offset[r][6+:6] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[1] && //(rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][6+:6] + 1; end //************************************************************************* // One I/O Bank Interface //************************************************************************* end else begin // One I/O Bank Interface // Read data offset value for all DQS in Bank0 always @(posedge clk) begin if (rst) begin for (l = 0; l < RANKS; l = l + 1) begin: bank_rst_loop rd_byte_data_offset[l] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r] <= #TCQ rd_byte_data_offset[rnk_cnt_r] + 1; end // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[0] \|\| fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[0]) \|\| (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) \|\| (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end //************************************************************************* // Retry counter to track number of DQSFOUND retries //*************************************************************************** always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted even with 3 dqfound retries always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end end endgenerate always @(posedge clk) begin if (rst) pi_rst_stg1_cal <= #TCQ {HIGHEST_BANK{1'b0}}; else if (rst_dqs_find) pi_rst_stg1_cal <= #TCQ {HIGHEST_BANK{1'b1}}; else pi_rst_stg1_cal <= #TCQ pi_rst_stg1_cal_r; end // Final read data offset value to be used during write calibration and // normal operation generate genvar i; genvar j; for (i = 0; i < RANKS; i = i + 1) begin: rank_final_loop reg [5:0] final_do_cand [RANKS-1:0]; // combinatorially select the candidate offset for the bank // indexed by final_do_index if (HIGHEST_BANK == 3) begin always @() begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = final_data_offset[i][11:6]; 3'b010: final_do_cand[i] = final_data_offset[i][17:12]; default: final_do_cand[i] = 'd0; endcase end end else if (HIGHEST_BANK == 2) begin always @() begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = final_data_offset[i][11:6]; 3'b010: final_do_cand[i] = 'd0; default: final_do_cand[i] = 'd0; endcase end end else begin always @() begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = 'd0; 3'b010: final_do_cand[i] = 'd0; default: final_do_cand[i] = 'd0; endcase end end always @(posedge clk) begin if (rst) final_do_max[i] <= #TCQ 0; else begin final_do_max[i] <= #TCQ final_do_max[i]; // default case (final_do_index[i]) 3'b000: if ( \| DATA_PRESENT[3:0]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; 3'b001: if ( \| DATA_PRESENT[7:4]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; 3'b010: if ( \| DATA_PRESENT[11:8]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; default: final_do_max[i] <= #TCQ final_do_max[i]; endcase end end always @(posedge clk) if (rst) begin final_do_index[i] <= #TCQ 0; end else begin final_do_index[i] <= #TCQ final_do_index[i] + 1; end for (j = 0; j < HIGHEST_BANK; j = j + 1) begin: bank_final_loop always @(posedge clk) begin if (rst) begin final_data_offset[i][6j+:6] <= #TCQ 'b0; end else begin //if (dqsfound_retry[j]) // final_data_offset[i][6j+:6] <= #TCQ rd_byte_data_offset[i][6j+:6]; //else if (init_dqsfound_done_r && ~init_dqsfound_done_r1) begin if ( DATA_PRESENT [ j4+:4] != 0) begin // has a data lane final_data_offset[i][6j+:6] <= #TCQ rd_byte_data_offset[i][6j+:6]; if (CWL_M % 2) // odd latency CAS slot 1 final_data_offset_mc[i][6j+:6] <= #TCQ rd_byte_data_offset[i][6j+:6] - 1; else // even latency CAS slot 0 final_data_offset_mc[i][6j+:6] <= #TCQ rd_byte_data_offset[i][6j+:6]; end end else if (init_dqsfound_done_r5 ) begin if ( DATA_PRESENT [ j4+:4] == 0) begin // all control lanes final_data_offset[i][6j+:6] <= #TCQ final_do_max[i]; final_data_offset_mc[i][6j+:6] <= #TCQ final_do_max[i]; end end end end end end endgenerate // Error generation in case pi_found_dqs signal from Phaser_IN // is not asserted when a common rddata_offset value is used always @(posedge clk) begin pi_dqs_found_err <= #TCQ \|pi_dqs_found_err_r; end endmodule
`include "hi_simulate.v" /* pck0 - input main 24Mhz clock (PLL / 4) [7:0] adc_d - input data from A/D converter mod_type - modulation type pwr_lo - output to coil drivers (ssp_clk / 8) adc_clk - output A/D clock signal ssp_frame - output SSS frame indicator (goes high while the 8 bits are shifted) ssp_din - output SSP data to ARM (shifts 8 bit A/D value serially to ARM MSB first) ssp_clk - output SSP clock signal ck_1356meg - input unused ck_1356megb - input unused ssp_dout - input unused cross_hi - input unused cross_lo - input unused pwr_hi - output unused, tied low pwr_oe1 - output unused, undefined pwr_oe2 - output unused, undefined pwr_oe3 - output unused, undefined pwr_oe4 - output unused, undefined dbg - output alias for adc_clk */ module testbed_hi_simulate; reg pck0; reg [7:0] adc_d; reg mod_type; wire pwr_lo; wire adc_clk; reg ck_1356meg; reg ck_1356megb; wire ssp_frame; wire ssp_din; wire ssp_clk; reg ssp_dout; wire pwr_hi; wire pwr_oe1; wire pwr_oe2; wire pwr_oe3; wire pwr_oe4; wire cross_lo; wire cross_hi; wire dbg; hi_simulate #(5,200) dut( .pck0(pck0), .ck_1356meg(ck_1356meg), .ck_1356megb(ck_1356megb), .pwr_lo(pwr_lo), .pwr_hi(pwr_hi), .pwr_oe1(pwr_oe1), .pwr_oe2(pwr_oe2), .pwr_oe3(pwr_oe3), .pwr_oe4(pwr_oe4), .adc_d(adc_d), .adc_clk(adc_clk), .ssp_frame(ssp_frame), .ssp_din(ssp_din), .ssp_dout(ssp_dout), .ssp_clk(ssp_clk), .cross_hi(cross_hi), .cross_lo(cross_lo), .dbg(dbg), .mod_type(mod_type) ); integer idx, i; // main clock always #5 begin ck_1356megb = !ck_1356megb; ck_1356meg = ck_1356megb; end always begin @(negedge adc_clk) ; adc_d = $random; end //crank DUT task crank_dut; begin @(negedge ssp_clk) ; ssp_dout = $random; end endtask initial begin // init inputs ck_1356megb = 0; // random values adc_d = 0; ssp_dout=1; // shallow modulation off mod_type=0; for (i = 0 ; i < 16 ; i = i + 1) begin crank_dut; end // shallow modulation on mod_type=1; for (i = 0 ; i < 16 ; i = i + 1) begin crank_dut; end $finish; end endmodule // main
module shift_in ( data_in, wr_en, shift_en, data_out, clk, rst ); parameter WIDTH=1; input [(64WIDTH)-1:0] data_in; input wr_en; input shift_en; output [(16WIDTH)-1:0] data_out; input clk; input rst; wire [(64WIDTH)-1:0] reg_in; wire [(64WIDTH)-1:0] reg_out; reg line_wr_en; reg s_or_w_; always @ (shift_en or wr_en) begin casex({shift_en,wr_en}) 2'b00: begin line_wr_en <= 1'b0; s_or_w_ <= 1'bx; end 2'b01: begin line_wr_en <= 1'b1; s_or_w_ <= 1'b0; end 2'b10: begin line_wr_en <= 1'b1; s_or_w_ <= 1'b1; end default: begin line_wr_en <= 1'bx; s_or_w_ <= 1'bx; end endcase end register #(WIDTH16) reg_line[3:0](.out(reg_out), .in(reg_in), .wr_en(line_wr_en), .clk(clk), .rst(rst)); mux_2_to_1 #(WIDTH16) line3_mux(.out(reg_in[(WIDTH64)-1:(WIDTH48)]), .in({{WIDTH16{1'bx}},data_in[(WIDTH64)-1:(WIDTH48)]}), .select(s_or_w_)); mux_2_to_1 #(WIDTH16) line2_mux(.out(reg_in[(WIDTH48)-1:(WIDTH32)]), .in({reg_out[(WIDTH64)-1:WIDTH48],data_in[(WIDTH48)-1:(WIDTH32)]}), .select(s_or_w_)); mux_2_to_1 #(WIDTH16) line1_mux(.out(reg_in[(WIDTH32)-1:(WIDTH16)]), .in({reg_out[(WIDTH48)-1:WIDTH32],data_in[(WIDTH32)-1:(WIDTH16)]}), .select(s_or_w_)); mux_2_to_1 #(WIDTH16) line0_mux(.out(reg_in[(WIDTH16)-1:0]), .in({reg_out[(WIDTH32)-1:WIDTH16],data_in[(WIDTH16)-1:0]}), .select(s_or_w_)); assign data_out = reg_out[(WIDTH*16)-1:0]; endmodule
// DESCRIPTION: Verilator: Verilog Test module // // This file ONLY is placed under the Creative Commons Public Domain, for // any use, without warranty, 2011 by Wilson Snyder. // SPDX-License-Identifier: CC0-1.0 module t_embed1_wrap (/AUTOARG/ // Outputs bit_out, vec_out, wide_out, did_init_out, // Inputs clk, bit_in, vec_in, wide_in, is_ref ); /AUTOINOUTMODULE("t_embed1_child")/ // Beginning of automatic in/out/inouts (from specific module) output bit bit_out; output bit [30:0] vec_out; output bit [123:0] wide_out; output bit did_init_out; input clk; input bit_in; input [30:0] vec_in; input [123:0] wide_in; input is_ref; // End of automatics `ifdef verilator // Import $t_embed_child__initial etc as a DPI function `endif //TODO would like __'s as in {PREFIX}__initial but presently illegal for users to do this import "DPI-C" context function void t_embed_child_initial(); import "DPI-C" context function void t_embed_child_final(); import "DPI-C" context function void t_embed_child_eval(); import "DPI-C" context function void t_embed_child_io_eval ( //TODO we support bit, but not logic input bit clk, input bit bit_in, input bit [30:0] vec_in, input bit [123:0] wide_in, input bit is_ref, output bit bit_out, output bit [30:0] vec_out, output bit [123:0] wide_out, output bit did_init_out); initial begin // Load all values t_embed_child_initial(); end // Only if system verilog, and if a "final" block in the code final begin t_embed_child_final(); end bit _temp_bit_out; bit _temp_did_init_out; bit [30:0] _temp_vec_out; bit [123:0] _temp_wide_out; always @* begin t_embed_child_io_eval( clk, bit_in, vec_in, wide_in, is_ref, _temp_bit_out, _temp_vec_out, _temp_wide_out, _temp_did_init_out ); // TODO might eliminate these temporaries bit_out = _temp_bit_out; did_init_out = _temp_did_init_out; end // Send all variables every cycle, // or have a sensitivity routine for each? // How to make sure we call eval at end of variable changes? // #0 (though not verilator compatible!) // TODO for now, we know what changes when always @ (posedge clk) begin vec_out <= _temp_vec_out; wide_out <= _temp_wide_out; end endmodule
///////////////////////////////////////////////////////////////////// //// //// //// Non-restoring unsigned divider //// //// //// //// Author: Richard Herveille //// //// [email protected] //// //// www.asics.ws //// //// //// ///////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2002 Richard Herveille //// //// [email protected] //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer.//// //// //// //// THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY //// //// EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED //// //// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS //// //// FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL THE AUTHOR //// //// OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, //// //// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES //// //// (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE //// //// GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR //// //// BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF //// //// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT //// //// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT //// //// OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE //// //// POSSIBILITY OF SUCH DAMAGE. //// //// //// ///////////////////////////////////////////////////////////////////// // CVS Log // // $Id: div_uu.v,v 1.3 2003-09-17 13:08:53 rherveille Exp $ // // $Date: 2003-09-17 13:08:53 $ // $Revision: 1.3 $ // $Author: rherveille $ // $Locker: $ // $State: Exp $ // // Change History: // $Log: not supported by cvs2svn $ // Revision 1.2 2002/10/31 13:54:58 rherveille // Fixed a bug in the remainder output of div_su.v // // Revision 1.1.1.1 2002/10/29 20:29:10 rherveille // // // //synopsys translate_off `include "timescale.v" //synopsys translate_on module div_uu(clk, ena, z, d, q, s, div0, ovf); // // parameters // parameter z_width = 16; parameter d_width = z_width /2; // // inputs & outputs // input clk; // system clock input ena; // clock enable input [z_width -1:0] z; // divident input [d_width -1:0] d; // divisor output [d_width -1:0] q; // quotient output [d_width -1:0] s; // remainder output div0; output ovf; reg [d_width-1:0] q; reg [d_width-1:0] s; reg div0; reg ovf; // // functions // function [z_width:0] gen_s; input [z_width:0] si; input [z_width:0] di; begin if(si[z_width]) gen_s = {si[z_width-1:0], 1'b0} + di; else gen_s = {si[z_width-1:0], 1'b0} - di; end endfunction function [d_width-1:0] gen_q; input [d_width-1:0] qi; input [z_width:0] si; begin gen_q = {qi[d_width-2:0], ~si[z_width]}; end endfunction function [d_width-1:0] assign_s; input [z_width:0] si; input [z_width:0] di; reg [z_width:0] tmp; begin if(si[z_width]) tmp = si + di; else tmp = si; assign_s = tmp[z_width-1:z_width-d_width]; end endfunction // // variables // reg [d_width-1:0] q_pipe [d_width-1:0]; reg [z_width:0] s_pipe [d_width:0]; reg [z_width:0] d_pipe [d_width:0]; reg [d_width:0] div0_pipe, ovf_pipe; // // perform parameter checks // // synopsys translate_off initial begin if(d_width !== z_width / 2) $display("div.v parameter error (d_width != z_width/2)."); end // synopsys translate_on integer n0, n1, n2, n3; // generate divisor (d) pipe always @(d) d_pipe[0] <= {1'b0, d, {(z_width-d_width){1'b0}} }; always @(posedge clk) if(ena) for(n0=1; n0 <= d_width; n0=n0+1) d_pipe[n0] <= #1 d_pipe[n0-1]; // generate internal remainder pipe always @(z) s_pipe[0] <= z; always @(posedge clk) if(ena) for(n1=1; n1 <= d_width; n1=n1+1) s_pipe[n1] <= #1 gen_s(s_pipe[n1-1], d_pipe[n1-1]); // generate quotient pipe always @(posedge clk) q_pipe[0] <= #1 0; always @(posedge clk) if(ena) for(n2=1; n2 < d_width; n2=n2+1) q_pipe[n2] <= #1 gen_q(q_pipe[n2-1], s_pipe[n2]); // flags (divide_by_zero, overflow) always @(z or d) begin ovf_pipe[0] <= !(z[z_width-1:d_width] < d); div0_pipe[0] <= ~\|d; end always @(posedge clk) if(ena) for(n3=1; n3 <= d_width; n3=n3+1) begin ovf_pipe[n3] <= #1 ovf_pipe[n3-1]; div0_pipe[n3] <= #1 div0_pipe[n3-1]; end // assign outputs always @(posedge clk) if(ena) ovf <= #1 ovf_pipe[d_width]; always @(posedge clk) if(ena) div0 <= #1 div0_pipe[d_width]; always @(posedge clk) if(ena) q <= #1 gen_q(q_pipe[d_width-1], s_pipe[d_width]); always @(posedge clk) if(ena) s <= #1 assign_s(s_pipe[d_width], d_pipe[d_width]); endmodule
//----------------------------------------------------------------------------- //-- Baudrate generator //-- It generates a square signal, with a frequency for communicating at the //-- given baudrate //-- The output is set to 1 only during one clock cycle. The rest of the // time is 0 //-- Once enabled, the pulse is generated just in the middle of the period //-- This is necessary for the implementation of the receptor //------------------------------------------------------------------------------ //-- (c) Juan Gonzalez (obijuan) //----------------------------------------------------------------------------- //-- GPL license //----------------------------------------------------------------------------- `include "baudgen.vh" //------------------------------------------------------------------------------ //-- baudgen module //-- //-- INPUTS: //-- -clk: System clock (12 MHZ in the iceStick board) //-- -clk_ena: clock enable: //-- 1. Normal working: The squeare signal is generated //-- 0: stoped. Output always 0 //-- OUTPUTS: //-- - clk_out: Output signal. Pulse width: 1 clock cycle. //-- Output not registered //-- It tells the uart_rx when to sample the next bit //-- __ __ //-- _____\| \|________________________________________\| \|_____________________ //-- \| -> <- 1 clock cycle \| //-- <------- Period ------------------------> //-- //------------------------------------------------------------------------------ module baudgen_rx #( parameter BAUDRATE = `B115200 //-- Default baudrate )( input wire clk, //-- System clock input wire clk_ena, //-- Clock enable output wire clk_out //-- Bitrate Clock output ); //-- Number of bits needed for storing the baudrate divisor localparam N = $clog2(BAUDRATE); //-- Value for generating the pulse in the middle of the period localparam M2 = (BAUDRATE >> 1); //-- Counter for implementing the divisor (it is a BAUDRATE module counter) //-- (when BAUDRATE is reached, it start again from 0) reg [N-1:0] divcounter = 0; //-- Contador módulo M always @(posedge clk) if (clk_ena) //-- Normal working: counting. When the maximum count is reached, it starts from 0 divcounter <= (divcounter == BAUDRATE - 1) ? 0 : divcounter + 1; else //-- Counter fixed to its maximum value //-- When it is resumed it start from 0 divcounter <= BAUDRATE - 1; //-- The output is 1 when the counter is in the middle of the period, if clk_ena is active //-- It is 1 only for one system clock cycle assign clk_out = (divcounter == M2) ? clk_ena : 0; endmodule
// wasca_nios2_gen2_0.v // This file was auto-generated from altera_nios2_hw.tcl. If you edit it your changes // will probably be lost. // // Generated using ACDS version 15.1 193 `timescale 1 ps / 1 ps module wasca_nios2_gen2_0 ( input wire clk, // clk.clk input wire reset_n, // reset.reset_n output wire [27:0] d_address, // data_master.address output wire [3:0] d_byteenable, // .byteenable output wire d_read, // .read input wire [31:0] d_readdata, // .readdata input wire d_waitrequest, // .waitrequest output wire d_write, // .write output wire [31:0] d_writedata, // .writedata output wire debug_mem_slave_debugaccess_to_roms, // .debugaccess output wire [24:0] i_address, // instruction_master.address output wire i_read, // .read input wire [31:0] i_readdata, // .readdata input wire i_waitrequest, // .waitrequest input wire [31:0] irq, // irq.irq output wire debug_reset_request, // debug_reset_request.reset input wire [8:0] debug_mem_slave_address, // debug_mem_slave.address input wire [3:0] debug_mem_slave_byteenable, // .byteenable input wire debug_mem_slave_debugaccess, // .debugaccess input wire debug_mem_slave_read, // .read output wire [31:0] debug_mem_slave_readdata, // .readdata output wire debug_mem_slave_waitrequest, // .waitrequest input wire debug_mem_slave_write, // .write input wire [31:0] debug_mem_slave_writedata, // .writedata output wire dummy_ci_port // custom_instruction_master.readra ); wasca_nios2_gen2_0_cpu cpu ( .clk (clk), // clk.clk .reset_n (reset_n), // reset.reset_n .d_address (d_address), // data_master.address .d_byteenable (d_byteenable), // .byteenable .d_read (d_read), // .read .d_readdata (d_readdata), // .readdata .d_waitrequest (d_waitrequest), // .waitrequest .d_write (d_write), // .write .d_writedata (d_writedata), // .writedata .debug_mem_slave_debugaccess_to_roms (debug_mem_slave_debugaccess_to_roms), // .debugaccess .i_address (i_address), // instruction_master.address .i_read (i_read), // .read .i_readdata (i_readdata), // .readdata .i_waitrequest (i_waitrequest), // .waitrequest .irq (irq), // irq.irq .debug_reset_request (debug_reset_request), // debug_reset_request.reset .debug_mem_slave_address (debug_mem_slave_address), // debug_mem_slave.address .debug_mem_slave_byteenable (debug_mem_slave_byteenable), // .byteenable .debug_mem_slave_debugaccess (debug_mem_slave_debugaccess), // .debugaccess .debug_mem_slave_read (debug_mem_slave_read), // .read .debug_mem_slave_readdata (debug_mem_slave_readdata), // .readdata .debug_mem_slave_waitrequest (debug_mem_slave_waitrequest), // .waitrequest .debug_mem_slave_write (debug_mem_slave_write), // .write .debug_mem_slave_writedata (debug_mem_slave_writedata), // .writedata .dummy_ci_port (dummy_ci_port), // custom_instruction_master.readra .reset_req (1'b0) // (terminated) ); endmodule
/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 / `ifndef SKY130_FD_SC_MS__O311A_4_V `define SKY130_FD_SC_MS__O311A_4_V /* * o311a: 3-input OR into 3-input AND. * * X = ((A1 \| A2 \| A3) & B1 & C1) * * Verilog wrapper for o311a with size of 4 units. * * WARNING: This file is autogenerated, do not modify directly! / `timescale 1ns / 1ps `default_nettype none `include "sky130_fd_sc_ms__o311a.v" `ifdef USE_POWER_PINS /******************************************************/ `celldefine module sky130_fd_sc_ms__o311a_4 ( X , A1 , A2 , A3 , B1 , C1 , VPWR, VGND, VPB , VNB ); output X ; input A1 ; input A2 ; input A3 ; input B1 ; input C1 ; input VPWR; input VGND; input VPB ; input VNB ; sky130_fd_sc_ms__o311a base ( .X(X), .A1(A1), .A2(A2), .A3(A3), .B1(B1), .C1(C1), .VPWR(VPWR), .VGND(VGND), .VPB(VPB), .VNB(VNB) ); endmodule `endcelldefine /*****************************************************/ `else // If not USE_POWER_PINS /*****************************************************/ `celldefine module sky130_fd_sc_ms__o311a_4 ( X , A1, A2, A3, B1, C1 ); output X ; input A1; input A2; input A3; input B1; input C1; // Voltage supply signals supply1 VPWR; supply0 VGND; supply1 VPB ; supply0 VNB ; sky130_fd_sc_ms__o311a base ( .X(X), .A1(A1), .A2(A2), .A3(A3), .B1(B1), .C1(C1) ); endmodule `endcelldefine /*******************************************************/ `endif // USE_POWER_PINS `default_nettype wire `endif // SKY130_FD_SC_MS__O311A_4_V
//*************************************************************************** // (c) Copyright 2009 - 2013 Xilinx, Inc. All rights reserved. // // This file contains confidential and proprietary information // of Xilinx, Inc. and is protected under U.S. and // international copyright and other intellectual property // laws. // // DISCLAIMER // This disclaimer is not a license and does not grant any // rights to the materials distributed herewith. Except as // otherwise provided in a valid license issued to you by // Xilinx, and to the maximum extent permitted by applicable // law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // (2) Xilinx shall not be liable (whether in contract or tort, // including negligence, or under any other theory of // liability) for any loss or damage of any kind or nature // related to, arising under or in connection with these // materials, including for any direct, or any indirect, // special, incidental, or consequential loss or damage // (including loss of data, profits, goodwill, or any type of // loss or damage suffered as a result of any action brought // by a third party) even if such damage or loss was // reasonably foreseeable or Xilinx had been advised of the // possibility of the same. // // CRITICAL APPLICATIONS // Xilinx products are not designed or intended to be fail- // safe, or for use in any application requiring fail-safe // performance, such as life-support or safety devices or // systems, Class III medical devices, nuclear facilities, // applications related to the deployment of airbags, or any // other applications that could lead to death, personal // injury, or severe property or environmental damage // (individually and collectively, "Critical // Applications"). Customer assumes the sole risk and // liability of any use of Xilinx products in Critical // Applications, subject only to applicable laws and // regulations governing limitations on product liability. // // THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // PART OF THIS FILE AT ALL TIMES. // //************************************************************************* // ____ ____ // / /\/ / // /___/ \ / Vendor: Xilinx // \ \ \/ Version: // \ \ Application: MIG // / / Filename: ddr_phy_dqs_found_cal.v // /___/ /\ Date Last Modified: $Date: 2011/06/02 08:35:08 $ // \ \ / \ Date Created: // \___\/\___\ // //Device: 7 Series //Design Name: DDR3 SDRAM //Purpose: // Read leveling calibration logic // NOTES: // 1. Phaser_In DQSFOUND calibration //Reference: //Revision History: //************************************************************************* /************************************************************************** $Id: ddr_phy_dqs_found_cal.v,v 1.1 2011/06/02 08:35:08 mishra Exp $ $Date: 2011/06/02 08:35:08 $ $Author: $Revision: $Source: *****************************************************************************/ `timescale 1ps/1ps module mig_7series_v1_9_ddr_phy_dqs_found_cal # ( parameter TCQ = 100, // clk->out delay (sim only) parameter nCK_PER_CLK = 2, // # of memory clocks per CLK parameter nCL = 5, // Read CAS latency parameter AL = "0", parameter nCWL = 5, // Write CAS latency parameter DRAM_TYPE = "DDR3", // Memory I/F type: "DDR3", "DDR2" parameter RANKS = 1, // # of memory ranks in the system parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH)) parameter DQS_WIDTH = 8, // # of DQS (strobe) parameter DRAM_WIDTH = 8, // # of DQ per DQS parameter REG_CTRL = "ON", // "ON" for registered DIMM parameter SIM_CAL_OPTION = "NONE", // Performs all calibration steps parameter NUM_DQSFOUND_CAL = 3, // Number of times to iterate parameter N_CTL_LANES = 3, // Number of control byte lanes parameter HIGHEST_LANE = 12, // Sum of byte lanes (Data + Ctrl) parameter HIGHEST_BANK = 3, // Sum of I/O Banks parameter BYTE_LANES_B0 = 4'b1111, parameter BYTE_LANES_B1 = 4'b0000, parameter BYTE_LANES_B2 = 4'b0000, parameter BYTE_LANES_B3 = 4'b0000, parameter BYTE_LANES_B4 = 4'b0000, parameter DATA_CTL_B0 = 4'hc, parameter DATA_CTL_B1 = 4'hf, parameter DATA_CTL_B2 = 4'hf, parameter DATA_CTL_B3 = 4'hf, parameter DATA_CTL_B4 = 4'hf ) ( input clk, input rst, input dqsfound_retry, // From phy_init input pi_dqs_found_start, input detect_pi_found_dqs, input prech_done, // DQSFOUND per Phaser_IN input [HIGHEST_LANE-1:0] pi_dqs_found_lanes, output reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal, // To phy_init output [5:0] rd_data_offset_0, output [5:0] rd_data_offset_1, output [5:0] rd_data_offset_2, output pi_dqs_found_rank_done, output pi_dqs_found_done, output reg pi_dqs_found_err, output [6RANKS-1:0] rd_data_offset_ranks_0, output [6RANKS-1:0] rd_data_offset_ranks_1, output [6RANKS-1:0] rd_data_offset_ranks_2, output reg dqsfound_retry_done, output reg dqs_found_prech_req, //To MC output [6RANKS-1:0] rd_data_offset_ranks_mc_0, output [6RANKS-1:0] rd_data_offset_ranks_mc_1, output [6RANKS-1:0] rd_data_offset_ranks_mc_2, input [8:0] po_counter_read_val, output rd_data_offset_cal_done, output fine_adjust_done, output [N_CTL_LANES-1:0] fine_adjust_lane_cnt, output reg ck_po_stg2_f_indec, output reg ck_po_stg2_f_en, output [255:0] dbg_dqs_found_cal ); // For non-zero AL values localparam nAL = (AL == "CL-1") ? nCL - 1 : 0; // Adding the register dimm latency to write latency localparam CWL_M = (REG_CTRL == "ON") ? nCWL + nAL + 1 : nCWL + nAL; // Added to reduce simulation time localparam LATENCY_FACTOR = 13; localparam NUM_READS = (SIM_CAL_OPTION == "NONE") ? 7 : 1; localparam [19:0] DATA_PRESENT = {(DATA_CTL_B4[3] & BYTE_LANES_B4[3]), (DATA_CTL_B4[2] & BYTE_LANES_B4[2]), (DATA_CTL_B4[1] & BYTE_LANES_B4[1]), (DATA_CTL_B4[0] & BYTE_LANES_B4[0]), (DATA_CTL_B3[3] & BYTE_LANES_B3[3]), (DATA_CTL_B3[2] & BYTE_LANES_B3[2]), (DATA_CTL_B3[1] & BYTE_LANES_B3[1]), (DATA_CTL_B3[0] & BYTE_LANES_B3[0]), (DATA_CTL_B2[3] & BYTE_LANES_B2[3]), (DATA_CTL_B2[2] & BYTE_LANES_B2[2]), (DATA_CTL_B2[1] & BYTE_LANES_B2[1]), (DATA_CTL_B2[0] & BYTE_LANES_B2[0]), (DATA_CTL_B1[3] & BYTE_LANES_B1[3]), (DATA_CTL_B1[2] & BYTE_LANES_B1[2]), (DATA_CTL_B1[1] & BYTE_LANES_B1[1]), (DATA_CTL_B1[0] & BYTE_LANES_B1[0]), (DATA_CTL_B0[3] & BYTE_LANES_B0[3]), (DATA_CTL_B0[2] & BYTE_LANES_B0[2]), (DATA_CTL_B0[1] & BYTE_LANES_B0[1]), (DATA_CTL_B0[0] & BYTE_LANES_B0[0])}; localparam FINE_ADJ_IDLE = 4'h0; localparam RST_POSTWAIT = 4'h1; localparam RST_POSTWAIT1 = 4'h2; localparam RST_WAIT = 4'h3; localparam FINE_ADJ_INIT = 4'h4; localparam FINE_INC = 4'h5; localparam FINE_INC_WAIT = 4'h6; localparam FINE_INC_PREWAIT = 4'h7; localparam DETECT_PREWAIT = 4'h8; localparam DETECT_DQSFOUND = 4'h9; localparam PRECH_WAIT = 4'hA; localparam FINE_DEC = 4'hB; localparam FINE_DEC_WAIT = 4'hC; localparam FINE_DEC_PREWAIT = 4'hD; localparam FINAL_WAIT = 4'hE; localparam FINE_ADJ_DONE = 4'hF; integer k,l,m,n,p,q,r,s; reg dqs_found_start_r; reg [6HIGHEST_BANK-1:0] rd_byte_data_offset[0:RANKS-1]; reg rank_done_r; reg rank_done_r1; reg dqs_found_done_r; (* ASYNC_REG = "TRUE" ) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r1; ( ASYNC_REG = "TRUE" ) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r2; ( ASYNC_REG = "TRUE" ) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r3; reg init_dqsfound_done_r; reg init_dqsfound_done_r1; reg init_dqsfound_done_r2; reg init_dqsfound_done_r3; reg init_dqsfound_done_r4; reg init_dqsfound_done_r5; reg [1:0] rnk_cnt_r; reg [2:0 ] final_do_index[0:RANKS-1]; reg [5:0 ] final_do_max[0:RANKS-1]; reg [6HIGHEST_BANK-1:0] final_data_offset[0:RANKS-1]; reg [6HIGHEST_BANK-1:0] final_data_offset_mc[0:RANKS-1]; reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal_r; reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal_r1; reg [10HIGHEST_BANK-1:0] retry_cnt; reg dqsfound_retry_r1; wire [4HIGHEST_BANK-1:0] pi_dqs_found_lanes_int; reg [HIGHEST_BANK-1:0] pi_dqs_found_all_bank; reg [HIGHEST_BANK-1:0] pi_dqs_found_all_bank_r; reg [HIGHEST_BANK-1:0] pi_dqs_found_any_bank; reg [HIGHEST_BANK-1:0] pi_dqs_found_any_bank_r; reg [HIGHEST_BANK-1:0] pi_dqs_found_err_r; // CK/Control byte lanes fine adjust stage reg fine_adjust; reg [N_CTL_LANES-1:0] ctl_lane_cnt; reg [3:0] fine_adj_state_r; reg fine_adjust_done_r; reg rst_dqs_find; reg rst_dqs_find_r1; reg rst_dqs_find_r2; reg [5:0] init_dec_cnt; reg [5:0] dec_cnt; reg [5:0] inc_cnt; reg final_dec_done; reg init_dec_done; reg first_fail_detect; reg second_fail_detect; reg [5:0] first_fail_taps; reg [5:0] second_fail_taps; reg [5:0] stable_pass_cnt; reg [3:0] detect_rd_cnt; //************************************************************************ // Debug signals // //************************************************************************* assign dbg_dqs_found_cal[5:0] = first_fail_taps; assign dbg_dqs_found_cal[11:6] = second_fail_taps; assign dbg_dqs_found_cal[12] = first_fail_detect; assign dbg_dqs_found_cal[13] = second_fail_detect; assign dbg_dqs_found_cal[14] = fine_adjust_done_r; assign pi_dqs_found_rank_done = rank_done_r; assign pi_dqs_found_done = dqs_found_done_r; generate genvar rnk_cnt; if (HIGHEST_BANK == 3) begin // Three Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6rnk_cnt+:6] = final_data_offset[rnk_cnt][11:6]; assign rd_data_offset_ranks_2[6rnk_cnt+:6] = final_data_offset[rnk_cnt][17:12]; assign rd_data_offset_ranks_mc_0[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][11:6]; assign rd_data_offset_ranks_mc_2[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][17:12]; end end else if (HIGHEST_BANK == 2) begin // Two Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6rnk_cnt+:6] = final_data_offset[rnk_cnt][11:6]; assign rd_data_offset_ranks_2[6rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_0[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][11:6]; assign rd_data_offset_ranks_mc_2[6rnk_cnt+:6] = 'd0; end end else begin // Single Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_2[6rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_0[6rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_2[6rnk_cnt+:6] = 'd0; end end endgenerate // final_data_offset is used during write calibration and during // normal operation. One rd_data_offset value per rank for entire // interface generate if (HIGHEST_BANK == 3) begin // Three I/O Bank interface assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][6+:6] : final_data_offset[rnk_cnt_r][6+:6]; assign rd_data_offset_2 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][12+:6] : final_data_offset[rnk_cnt_r][12+:6]; end else if (HIGHEST_BANK == 2) begin // Two I/O Bank interface assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][6+:6] : final_data_offset[rnk_cnt_r][6+:6]; assign rd_data_offset_2 = 'd0; end else begin assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = 'd0; assign rd_data_offset_2 = 'd0; end endgenerate assign rd_data_offset_cal_done = init_dqsfound_done_r; assign fine_adjust_lane_cnt = ctl_lane_cnt; //************************************************************************ // DQSFOUND all and any generation // pi_dqs_found_all_bank[x] asserted when all Phaser_INs in Bankx are // asserted // pi_dqs_found_any_bank[x] asserted when at least one Phaser_IN in Bankx // is asserted //************************************************************************ generate if ((HIGHEST_LANE == 4) \|\| (HIGHEST_LANE == 8) \|\| (HIGHEST_LANE == 12)) assign pi_dqs_found_lanes_int = pi_dqs_found_lanes_r3; else if ((HIGHEST_LANE == 7) \|\| (HIGHEST_LANE == 11)) assign pi_dqs_found_lanes_int = {1'b0, pi_dqs_found_lanes_r3}; else if ((HIGHEST_LANE == 6) \|\| (HIGHEST_LANE == 10)) assign pi_dqs_found_lanes_int = {2'b00, pi_dqs_found_lanes_r3}; else if ((HIGHEST_LANE == 5) \|\| (HIGHEST_LANE == 9)) assign pi_dqs_found_lanes_int = {3'b000, pi_dqs_found_lanes_r3}; endgenerate always @(posedge clk) begin if (rst) begin for (k = 0; k < HIGHEST_BANK; k = k + 1) begin: rst_pi_dqs_found pi_dqs_found_all_bank[k] <= #TCQ 'b0; pi_dqs_found_any_bank[k] <= #TCQ 'b0; end end else if (pi_dqs_found_start) begin for (p = 0; p < HIGHEST_BANK; p = p +1) begin: assign_pi_dqs_found pi_dqs_found_all_bank[p] <= #TCQ (!DATA_PRESENT[4p+0] \| pi_dqs_found_lanes_int[4p+0]) & (!DATA_PRESENT[4p+1] \| pi_dqs_found_lanes_int[4p+1]) & (!DATA_PRESENT[4p+2] \| pi_dqs_found_lanes_int[4p+2]) & (!DATA_PRESENT[4p+3] \| pi_dqs_found_lanes_int[4p+3]); pi_dqs_found_any_bank[p] <= #TCQ (DATA_PRESENT[4p+0] & pi_dqs_found_lanes_int[4p+0]) \| (DATA_PRESENT[4p+1] & pi_dqs_found_lanes_int[4p+1]) \| (DATA_PRESENT[4p+2] & pi_dqs_found_lanes_int[4p+2]) \| (DATA_PRESENT[4p+3] & pi_dqs_found_lanes_int[4p+3]); end end end always @(posedge clk) begin pi_dqs_found_all_bank_r <= #TCQ pi_dqs_found_all_bank; pi_dqs_found_any_bank_r <= #TCQ pi_dqs_found_any_bank; end //*************************************************************************** // Counter to increase number of 4 back-to-back reads per rd_data_offset and // per CK/A/C tap value //************************************************************************* always @(posedge clk) begin if (rst \|\| (detect_rd_cnt == 'd0)) detect_rd_cnt <= #TCQ NUM_READS; else if (detect_pi_found_dqs && (detect_rd_cnt > 'd0)) detect_rd_cnt <= #TCQ detect_rd_cnt - 1; end //********************************************************************** // Adjust Phaser_Out stage 2 taps on CK/Address/Command/Controls // //********************************************************************** assign fine_adjust_done = fine_adjust_done_r; always @(posedge clk) begin rst_dqs_find_r1 <= #TCQ rst_dqs_find; rst_dqs_find_r2 <= #TCQ rst_dqs_find_r1; end always @(posedge clk) begin if(rst)begin fine_adjust <= #TCQ 1'b0; ctl_lane_cnt <= #TCQ 'd0; fine_adj_state_r <= #TCQ FINE_ADJ_IDLE; fine_adjust_done_r <= #TCQ 1'b0; ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; rst_dqs_find <= #TCQ 1'b0; init_dec_cnt <= #TCQ 'd31; dec_cnt <= #TCQ 'd0; inc_cnt <= #TCQ 'd0; init_dec_done <= #TCQ 1'b0; final_dec_done <= #TCQ 1'b0; first_fail_detect <= #TCQ 1'b0; second_fail_detect <= #TCQ 1'b0; first_fail_taps <= #TCQ 'd0; second_fail_taps <= #TCQ 'd0; stable_pass_cnt <= #TCQ 'd0; dqs_found_prech_req<= #TCQ 1'b0; end else begin case (fine_adj_state_r) FINE_ADJ_IDLE: begin if (init_dqsfound_done_r5) begin if (SIM_CAL_OPTION == "FAST_CAL") begin fine_adjust <= #TCQ 1'b1; fine_adj_state_r <= #TCQ FINE_ADJ_DONE; rst_dqs_find <= #TCQ 1'b0; end else begin fine_adjust <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; rst_dqs_find <= #TCQ 1'b1; end end end RST_WAIT: begin if (~(\|pi_dqs_found_any_bank) && rst_dqs_find_r2) begin rst_dqs_find <= #TCQ 1'b0; if (\|init_dec_cnt) fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; else if (final_dec_done) fine_adj_state_r <= #TCQ FINE_ADJ_DONE; else fine_adj_state_r <= #TCQ RST_POSTWAIT; end end RST_POSTWAIT: begin fine_adj_state_r <= #TCQ RST_POSTWAIT1; end RST_POSTWAIT1: begin fine_adj_state_r <= #TCQ FINE_ADJ_INIT; end FINE_ADJ_INIT: begin //if (detect_pi_found_dqs && (inc_cnt < 'd63)) fine_adj_state_r <= #TCQ FINE_INC; end FINE_INC: begin fine_adj_state_r <= #TCQ FINE_INC_WAIT; ck_po_stg2_f_indec <= #TCQ 1'b1; ck_po_stg2_f_en <= #TCQ 1'b1; if (ctl_lane_cnt == N_CTL_LANES-1) inc_cnt <= #TCQ inc_cnt + 1; end FINE_INC_WAIT: begin ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; if (ctl_lane_cnt != N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ ctl_lane_cnt + 1; fine_adj_state_r <= #TCQ FINE_INC_PREWAIT; end else if (ctl_lane_cnt == N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ 'd0; fine_adj_state_r <= #TCQ DETECT_PREWAIT; end end FINE_INC_PREWAIT: begin fine_adj_state_r <= #TCQ FINE_INC; end DETECT_PREWAIT: begin if (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) fine_adj_state_r <= #TCQ DETECT_DQSFOUND; else fine_adj_state_r <= #TCQ DETECT_PREWAIT; end DETECT_DQSFOUND: begin if (detect_pi_found_dqs && ~(&pi_dqs_found_all_bank)) begin stable_pass_cnt <= #TCQ 'd0; if (~first_fail_detect && (inc_cnt == 'd63)) begin // First failing tap detected at 63 taps // then decrement to 31 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ 'd32; end else if (~first_fail_detect && (inc_cnt > 'd30) && (stable_pass_cnt > 'd29)) begin // First failing tap detected at greater than 30 taps // then stop looking for second edge and decrement first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ (inc_cnt>>1) + 1; end else if (~first_fail_detect \|\| (first_fail_detect && (stable_pass_cnt < 'd30) && (inc_cnt <= 'd32))) begin // First failing tap detected, continue incrementing // until either second failing tap detected or 63 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; rst_dqs_find <= #TCQ 1'b1; if ((inc_cnt == 'd12) \|\| (inc_cnt == 'd24)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else fine_adj_state_r <= #TCQ RST_WAIT; end else if (first_fail_detect && (inc_cnt > 'd32) && (inc_cnt < 'd63) && (stable_pass_cnt < 'd30)) begin // Consecutive 30 taps of passing region was not found // continue incrementing first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; rst_dqs_find <= #TCQ 1'b1; if ((inc_cnt == 'd36) \|\| (inc_cnt == 'd48) \|\| (inc_cnt == 'd60)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else fine_adj_state_r <= #TCQ RST_WAIT; end else if (first_fail_detect && (inc_cnt == 'd63)) begin if (stable_pass_cnt < 'd30) begin // Consecutive 30 taps of passing region was not found // from tap 0 to 63 so decrement back to 31 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ 'd32; end else begin // Consecutive 30 taps of passing region was found // between first_fail_taps and 63 fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); end end else begin // Second failing tap detected, decrement to center of // failing taps second_fail_detect <= #TCQ 1'b1; second_fail_taps <= #TCQ inc_cnt; dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); fine_adj_state_r <= #TCQ FINE_DEC; end end else if (detect_pi_found_dqs && (&pi_dqs_found_all_bank)) begin stable_pass_cnt <= #TCQ stable_pass_cnt + 1; if ((inc_cnt == 'd12) \|\| (inc_cnt == 'd24) \|\| (inc_cnt == 'd36) \|\| (inc_cnt == 'd48) \|\| (inc_cnt == 'd60)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else if (inc_cnt < 'd63) begin rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end else begin fine_adj_state_r <= #TCQ FINE_DEC; if (~first_fail_detect \|\| (first_fail_taps > 'd33)) // No failing taps detected, decrement by 31 dec_cnt <= #TCQ 'd32; //else if (first_fail_detect && (stable_pass_cnt > 'd28)) // // First failing tap detected between 0 and 34 // // decrement midpoint between 63 and failing tap // dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); else // First failing tap detected // decrement to midpoint between 63 and failing tap dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); end end end PRECH_WAIT: begin if (prech_done) begin dqs_found_prech_req <= #TCQ 1'b0; rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end end FINE_DEC: begin fine_adj_state_r <= #TCQ FINE_DEC_WAIT; ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b1; if ((ctl_lane_cnt == N_CTL_LANES-1) && (init_dec_cnt > 'd0)) init_dec_cnt <= #TCQ init_dec_cnt - 1; else if ((ctl_lane_cnt == N_CTL_LANES-1) && (dec_cnt > 'd0)) dec_cnt <= #TCQ dec_cnt - 1; end FINE_DEC_WAIT: begin ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; if (ctl_lane_cnt != N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ ctl_lane_cnt + 1; fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; end else if (ctl_lane_cnt == N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ 'd0; if ((dec_cnt > 'd0) \|\| (init_dec_cnt > 'd0)) fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; else begin fine_adj_state_r <= #TCQ FINAL_WAIT; if ((init_dec_cnt == 'd0) && ~init_dec_done) init_dec_done <= #TCQ 1'b1; else final_dec_done <= #TCQ 1'b1; end end end FINE_DEC_PREWAIT: begin fine_adj_state_r <= #TCQ FINE_DEC; end FINAL_WAIT: begin rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end FINE_ADJ_DONE: begin if (&pi_dqs_found_all_bank) begin fine_adjust_done_r <= #TCQ 1'b1; rst_dqs_find <= #TCQ 1'b0; fine_adj_state_r <= #TCQ FINE_ADJ_DONE; end end endcase end end //************************************************************************* always@(posedge clk) dqs_found_start_r <= #TCQ pi_dqs_found_start; always @(posedge clk) begin if (rst) rnk_cnt_r <= #TCQ 2'b00; else if (init_dqsfound_done_r) rnk_cnt_r <= #TCQ rnk_cnt_r; else if (rank_done_r) rnk_cnt_r <= #TCQ rnk_cnt_r + 1; end //************************************************************* // Read data_offset calibration done signal //************************************************************* always @(posedge clk) begin if (rst \|\| (\|pi_rst_stg1_cal_r)) init_dqsfound_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank) begin if (rnk_cnt_r == RANKS-1) init_dqsfound_done_r <= #TCQ 1'b1; else init_dqsfound_done_r <= #TCQ 1'b0; end end always @(posedge clk) begin if (rst \|\| (init_dqsfound_done_r && (rnk_cnt_r == RANKS-1))) rank_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank && ~(&pi_dqs_found_all_bank_r)) rank_done_r <= #TCQ 1'b1; else rank_done_r <= #TCQ 1'b0; end always @(posedge clk) begin pi_dqs_found_lanes_r1 <= #TCQ pi_dqs_found_lanes; pi_dqs_found_lanes_r2 <= #TCQ pi_dqs_found_lanes_r1; pi_dqs_found_lanes_r3 <= #TCQ pi_dqs_found_lanes_r2; init_dqsfound_done_r1 <= #TCQ init_dqsfound_done_r; init_dqsfound_done_r2 <= #TCQ init_dqsfound_done_r1; init_dqsfound_done_r3 <= #TCQ init_dqsfound_done_r2; init_dqsfound_done_r4 <= #TCQ init_dqsfound_done_r3; init_dqsfound_done_r5 <= #TCQ init_dqsfound_done_r4; rank_done_r1 <= #TCQ rank_done_r; dqsfound_retry_r1 <= #TCQ dqsfound_retry; end always @(posedge clk) begin if (rst) dqs_found_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank && (rnk_cnt_r == RANKS-1) && init_dqsfound_done_r1 && (fine_adj_state_r == FINE_ADJ_DONE)) dqs_found_done_r <= #TCQ 1'b1; else dqs_found_done_r <= #TCQ 1'b0; end generate if (HIGHEST_BANK == 3) begin // Three I/O Bank interface // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[0] \|\| fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[0]) \|\| (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) \|\| (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[1] \|\| fine_adjust) pi_rst_stg1_cal_r[1] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[1]) \|\| (pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) \|\| (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[2] \|\| fine_adjust) pi_rst_stg1_cal_r[2] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[2]) \|\| (pi_dqs_found_any_bank_r[2] && ~pi_dqs_found_all_bank[2]) \|\| (rd_byte_data_offset[rnk_cnt_r][12+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[2] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[2]) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[2] && ~pi_dqs_found_all_bank[2]) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b0; end //************************************************************************* // Retry counter to track number of DQSFOUND retries //************************************************************************* always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[10+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[1]) retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10] + 1; else retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10]; end always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[20+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][12+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[2]) retry_cnt[20+:10] <= #TCQ retry_cnt[20+:10] + 1; else retry_cnt[20+:10] <= #TCQ retry_cnt[20+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[1] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[1] && (retry_cnt[10+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[2] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[2] && (retry_cnt[20+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][12+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[2] <= #TCQ 1'b1; end // Read data offset value for all DQS in a Bank always @(posedge clk) begin if (rst) begin for (q = 0; q < RANKS; q = q + 1) begin: three_bank0_rst_loop rd_byte_data_offset[q][0+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][0+:6] - 1; end always @(posedge clk) begin if (rst) begin for (r = 0; r < RANKS; r = r + 1) begin: three_bank1_rst_loop rd_byte_data_offset[r][6+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[1] && //(rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][6+:6] - 1; end always @(posedge clk) begin if (rst) begin for (s = 0; s < RANKS; s = s + 1) begin: three_bank2_rst_loop rd_byte_data_offset[s][12+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r][12+:6] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r][12+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[2] && //(rd_byte_data_offset[rnk_cnt_r][12+:6] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][12+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][12+:6] - 1; end //************************************************************************* // Two I/O Bank Interface //************************************************************************* end else if (HIGHEST_BANK == 2) begin // Two I/O Bank interface // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[0] \|\| fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[0]) \|\| (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) \|\| (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[1] \|\| fine_adjust) pi_rst_stg1_cal_r[1] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[1]) \|\| (pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) \|\| (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; end //************************************************************************* // Retry counter to track number of DQSFOUND retries //************************************************************************* always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[10+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[1]) retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10] + 1; else retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[1] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[1] && (retry_cnt[10+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[1] <= #TCQ 1'b1; end // Read data offset value for all DQS in a Bank always @(posedge clk) begin if (rst) begin for (q = 0; q < RANKS; q = q + 1) begin: two_bank0_rst_loop rd_byte_data_offset[q][0+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][0+:6] - 1; end always @(posedge clk) begin if (rst) begin for (r = 0; r < RANKS; r = r + 1) begin: two_bank1_rst_loop rd_byte_data_offset[r][6+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[1] && //(rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][6+:6] - 1; end //************************************************************************* // One I/O Bank Interface //************************************************************************* end else begin // One I/O Bank Interface // Read data offset value for all DQS in Bank0 always @(posedge clk) begin if (rst) begin for (l = 0; l < RANKS; l = l + 1) begin: bank_rst_loop rd_byte_data_offset[l] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) \|\| (rd_byte_data_offset[rnk_cnt_r] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r] <= #TCQ rd_byte_data_offset[rnk_cnt_r] - 1; end // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst \|\| pi_rst_stg1_cal_r1[0] \|\| fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) \|\| //(dqsfound_retry[0]) \|\| (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) \|\| (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst \|\| fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end //************************************************************************* // Retry counter to track number of DQSFOUND retries //*************************************************************************** always @(posedge clk) begin if (rst \|\| rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted even with 3 dqfound retries always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end end endgenerate always @(posedge clk) begin if (rst) pi_rst_stg1_cal <= #TCQ {HIGHEST_BANK{1'b0}}; else if (rst_dqs_find) pi_rst_stg1_cal <= #TCQ {HIGHEST_BANK{1'b1}}; else pi_rst_stg1_cal <= #TCQ pi_rst_stg1_cal_r; end // Final read data offset value to be used during write calibration and // normal operation generate genvar i; genvar j; for (i = 0; i < RANKS; i = i + 1) begin: rank_final_loop reg [5:0] final_do_cand [RANKS-1:0]; // combinatorially select the candidate offset for the bank // indexed by final_do_index if (HIGHEST_BANK == 3) begin always @() begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = final_data_offset[i][11:6]; 3'b010: final_do_cand[i] = final_data_offset[i][17:12]; default: final_do_cand[i] = 'd0; endcase end end else if (HIGHEST_BANK == 2) begin always @() begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = final_data_offset[i][11:6]; 3'b010: final_do_cand[i] = 'd0; default: final_do_cand[i] = 'd0; endcase end end else begin always @() begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = 'd0; 3'b010: final_do_cand[i] = 'd0; default: final_do_cand[i] = 'd0; endcase end end always @(posedge clk or posedge rst) begin if (rst) final_do_max[i] <= #TCQ 0; else begin final_do_max[i] <= #TCQ final_do_max[i]; // default case (final_do_index[i]) 3'b000: if ( \| DATA_PRESENT[3:0]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; 3'b001: if ( \| DATA_PRESENT[7:4]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; 3'b010: if ( \| DATA_PRESENT[11:8]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; default: final_do_max[i] <= #TCQ final_do_max[i]; endcase end end always @(posedge clk) if (rst) begin final_do_index[i] <= #TCQ 0; end else begin final_do_index[i] <= #TCQ final_do_index[i] + 1; end for (j = 0; j < HIGHEST_BANK; j = j + 1) begin: bank_final_loop always @(posedge clk) begin if (rst) begin final_data_offset[i][6j+:6] <= #TCQ 'b0; end else begin //if (dqsfound_retry[j]) // final_data_offset[i][6j+:6] <= #TCQ rd_byte_data_offset[i][6j+:6]; //else if (init_dqsfound_done_r && ~init_dqsfound_done_r1) begin if ( DATA_PRESENT [ j4+:4] != 0) begin // has a data lane final_data_offset[i][6j+:6] <= #TCQ rd_byte_data_offset[i][6j+:6]; if (CWL_M % 2) // odd latency CAS slot 1 final_data_offset_mc[i][6j+:6] <= #TCQ rd_byte_data_offset[i][6j+:6] - 1; else // even latency CAS slot 0 final_data_offset_mc[i][6j+:6] <= #TCQ rd_byte_data_offset[i][6j+:6]; end end else if (init_dqsfound_done_r5 ) begin if ( DATA_PRESENT [ j4+:4] == 0) begin // all control lanes final_data_offset[i][6j+:6] <= #TCQ final_do_max[i]; final_data_offset_mc[i][6j+:6] <= #TCQ final_do_max[i]; end end end end end end endgenerate // Error generation in case pi_found_dqs signal from Phaser_IN // is not asserted when a common rddata_offset value is used always @(posedge clk) begin pi_dqs_found_err <= #TCQ \|pi_dqs_found_err_r; end endmodule
// $Id: testbench.v 1853 2010-03-24 03:06:21Z dub $ /* Copyright (c) 2007-2009, Trustees of The Leland Stanford Junior University All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. Neither the name of the Stanford University nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. / `default_nettype none module testbench (); `include "c_functions.v" `include "c_constants.v" `include "vcr_constants.v" `include "parameters.v" parameter Tclk = 4; // total number of packet classes localparam num_packet_classes = num_message_classes num_resource_classes; // number of VCs localparam num_vcs = num_packet_classes * num_vcs_per_class; // width required to select individual VC localparam vc_idx_width = clogb(num_vcs); // total number of routers localparam num_routers = (num_nodes + num_nodes_per_router - 1) / num_nodes_per_router; // number of routers in each dimension localparam num_routers_per_dim = croot(num_routers, num_dimensions); // width required to select individual router in a dimension localparam dim_addr_width = clogb(num_routers_per_dim); // width required to select individual router in entire network localparam router_addr_width = num_dimensions * dim_addr_width; // width required to select individual node at current router localparam node_addr_width = clogb(num_nodes_per_router); // width of global addresses localparam addr_width = router_addr_width + node_addr_width; // connectivity within each dimension localparam connectivity = (topology == `TOPOLOGY_MESH) ? `CONNECTIVITY_LINE : (topology == `TOPOLOGY_TORUS) ? `CONNECTIVITY_RING : (topology == `TOPOLOGY_FBFLY) ? `CONNECTIVITY_FULL : -1; // number of adjacent routers in each dimension localparam num_neighbors_per_dim = ((connectivity == `CONNECTIVITY_LINE) \|\| (connectivity == `CONNECTIVITY_RING)) ? 2 : (connectivity == `CONNECTIVITY_FULL) ? (num_routers_per_dim - 1) : -1; // number of input and output ports on router localparam num_ports = num_dimensions * num_neighbors_per_dim + num_nodes_per_router; // width required to select individual port localparam port_idx_width = clogb(num_ports); // width required for lookahead routing information localparam la_route_info_width = port_idx_width + ((num_resource_classes > 1) ? 1 : 0); // total number of bits required for storing routing information localparam route_info_width = num_resource_classes * router_addr_width + node_addr_width; // number of bits required to represent all possible payload sizes localparam payload_length_width = clogb(max_payload_length-min_payload_length+1); // width of counter for remaining flits localparam flit_ctr_width = clogb(max_payload_length); // total number of bits required for storing header information localparam header_info_width = (packet_format == `PACKET_FORMAT_HEAD_TAIL) ? (la_route_info_width + route_info_width) : (packet_format == `PACKET_FORMAT_EXPLICIT_LENGTH) ? (la_route_info_width + route_info_width + payload_length_width) : -1; // width of flit control signals localparam flit_ctrl_width = (packet_format == `PACKET_FORMAT_HEAD_TAIL) ? (1 + vc_idx_width + 1 + 1) : (packet_format == `PACKET_FORMAT_EXPLICIT_LENGTH) ? (1 + vc_idx_width + 1) : -1; // width of flow control signals localparam flow_ctrl_width = 1 + vc_idx_width; // select set of feedback polynomials used for LFSRs parameter lfsr_index = 0; // number of bits in address that are considered base address parameter cfg_node_addr_width = 10; // width of register selector part of control register address parameter cfg_reg_addr_width = 6; // width of configuration bus addresses localparam cfg_addr_width = cfg_node_addr_width + cfg_reg_addr_width; // width of control register data parameter cfg_data_width = 32; // base address width for interface bus localparam io_node_addr_width = cfg_node_addr_width; // register index width for interface bus localparam io_reg_addr_width = cfg_reg_addr_width; // width of interface bus addresses localparam io_addr_width = cfg_addr_width; // width of interface bus datapath localparam io_data_width = cfg_data_width; // width of run cycle counter parameter num_packets_width = 16; // width of arrival rate LFSR parameter arrival_rv_width = 16; // width of message class selection LFSR parameter mc_idx_rv_width = 4; // width of resource class selection LFSR parameter rc_idx_rv_width = 4; // width of payload length selection LFSR parameter plength_idx_rv_width = 4; // number of selectable payload lengths parameter num_plength_vals = 2; // width of register that holds the number of outstanding packets parameter packet_count_width = 8; // number of bits in delay counter for acknowledgement (i.e., log2 of // interval before acknowledgement is sent) parameter done_delay_width = 4; // number of node control signals to generate parameter node_ctrl_width = 2; // number of node status signals to accept parameter node_status_width = 1; // RNG seed value parameter initial_seed = 0; reg reset; reg clk; reg [0:io_node_addr_width-1] io_node_addr_base; reg io_write; reg io_read; reg [0:cfg_addr_width-1] io_addr; reg [0:cfg_data_width-1] io_write_data; wire [0:cfg_data_width-1] io_read_data; wire io_done; wire error; tc_router_wrap #(.topology(topology), .num_flit_buffers(num_flit_buffers), .num_header_buffers(num_header_buffers), .num_message_classes(num_message_classes), .num_resource_classes(num_resource_classes), .num_vcs_per_class(num_vcs_per_class), .num_nodes(num_nodes), .num_dimensions(num_dimensions), .num_nodes_per_router(num_nodes_per_router), .packet_format(packet_format), .max_payload_length(max_payload_length), .min_payload_length(min_payload_length), .perf_ctr_enable(perf_ctr_enable), .perf_ctr_width(perf_ctr_width), .error_capture_mode(error_capture_mode), .track_vcs_at_output(track_vcs_at_output), .router_type(router_type), .flit_data_width(flit_data_width), .dim_order(dim_order), .int_flow_ctrl_type(int_flow_ctrl_type), .header_fifo_type(header_fifo_type), .fbf_regfile_type(fbf_regfile_type), .vc_alloc_type(vc_alloc_type), .vc_alloc_arbiter_type(vc_alloc_arbiter_type), .sw_alloc_type(sw_alloc_type), .sw_alloc_arbiter_type(sw_alloc_arbiter_type), .sw_alloc_spec_type(sw_alloc_spec_type), .ctrl_crossbar_type(ctrl_crossbar_type), .data_crossbar_type(data_crossbar_type), .reset_type(reset_type), .lfsr_index(lfsr_index), .cfg_node_addr_width(cfg_node_addr_width), .cfg_reg_addr_width(cfg_reg_addr_width), .cfg_data_width(cfg_data_width), .num_packets_width(num_packets_width), .arrival_rv_width(arrival_rv_width), .mc_idx_rv_width(mc_idx_rv_width), .rc_idx_rv_width(rc_idx_rv_width), .plength_idx_rv_width(plength_idx_rv_width), .num_plength_vals(num_plength_vals), .packet_count_width(packet_count_width)) dut (.clk(clk), .reset(reset), .io_node_addr_base(io_node_addr_base), .io_write(io_write), .io_read(io_read), .io_addr(io_addr), .io_write_data(io_write_data), .io_read_data(io_read_data), .io_done(io_done), .error(error)); reg clk_en; always begin clk <= clk_en; #(Tclk/2); clk <= 1'b0; #(Tclk/2); end always @(posedge clk) begin if(error) begin $display("error detected, cyc=%d", $time); $stop; end end reg done; integer i, j; integer seed = initial_seed; initial begin reset = 1'b0; clk_en = 1'b0; io_node_addr_base = 'd0; #(Tclk); #(Tclk/4); reset = 1'b1; io_write = 1'b0; io_read = 1'b0; io_addr = 'b0; io_write_data = 'b0; done = 1'b0; #(Tclk); reset = 1'b0; #(Tclk); clk_en = 1'b1; #(Tclk); // disable reset (i.e., enable reset_b) io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 'd0; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; io_write_data[0] = 1'b1; io_write_data[2] = 1'b1; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // enable clocks io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 'd0; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; io_write_data[0] = 1'b1; io_write_data[1] = 1'b1; io_write_data[2] = 1'b1; io_write_data[3] = 1'b1; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set LFSR seeds for(j = (num_ports - num_nodes_per_router); j < num_ports; j = j + 1) begin io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + j; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd3; for(i = 0; i < cfg_data_width; i = i + 1) io_write_data[i] = $dist_uniform(seed, 0, 1); while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); end // set number of packets io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd4; io_write_data = 'd0; io_write_data[0:num_packets_width-1] = 'd1024; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set arrival rate threshold io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd5; io_write_data = 'd0; io_write_data[0:arrival_rv_width-1] = 'd4096; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set packet length selection threshold io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd6; io_write_data = 'd0; io_write_data[0:plength_idx_rv_width-1] = 'd8; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set packet length values io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd7; io_write_data = 'd0; io_write_data[0:payload_length_width-1] = 'd0; io_write_data[payload_length_width:2payload_length_width-1] = 'd4; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set message class selection thresholds io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd8; io_write_data = 'd0; io_write_data[0:mc_idx_rv_width-1] = 'd10; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set resource class selection thresholds io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd9; io_write_data = 'd0; io_write_data[0:rc_idx_rv_width-1] = 'd12; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(10Tclk); // start experiment io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; io_write_data[0] = 'd1; io_write_data[1] = 'd0; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); // wait for experiment to finish while(!done) begin #(10Tclk); io_read = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd1; io_write_data = 'd0; while(!io_done) #(Tclk); done = ~io_read_data[0]; #(Tclk); io_read = 1'b0; while(io_done) #(Tclk); end done = 1'b0; #(Tclk); // disable nodes io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // disable router clocks io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 'd0; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; io_write_data[0] = 1'b1; io_write_data[1] = 1'b1; io_write_data[2] = 1'b1; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // reset number of packets io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd4; io_write_data = 'd0; io_write_data[0:num_packets_width-1] = 'd1024; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(10Tclk); // restart experiment in loopback mode io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; io_write_data[0] = 'd1; io_write_data[1] = 'd1; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); // wait for experiment to finish while(!done) begin #(10Tclk); io_read = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd1; io_write_data = 'd0; while(!io_done) #(Tclk); done = ~io_read_data[0]; #(Tclk); io_read = 1'b0; while(io_done) #(Tclk); end done = 1'b0; #(Tclk); // disable nodes io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(3Tclk/4); #(Tclk); $finish; end endmodule
// megafunction wizard: %FIFO%VBB% // GENERATION: STANDARD // VERSION: WM1.0 // MODULE: dcfifo // ============================================================ // File Name: fifo_4kx16_dc.v // Megafunction Name(s): // dcfifo // ============================================================ // ********************************************************** // THIS IS A WIZARD-GENERATED FILE. DO NOT EDIT THIS FILE! // // 5.1 Build 213 01/19/2006 SP 1 SJ Web Edition // ********************************************************** //Copyright (C) 1991-2006 Altera Corporation //Your use of Altera Corporation's design tools, logic functions //and other software and tools, and its AMPP partner logic //functions, and any output files any of the foregoing //(including device programming or simulation files), and any //associated documentation or information are expressly subject //to the terms and conditions of the Altera Program License //Subscription Agreement, Altera MegaCore Function License //Agreement, or other applicable license agreement, including, //without limitation, that your use is for the sole purpose of //programming logic devices manufactured by Altera and sold by //Altera or its authorized distributors. Please refer to the //applicable agreement for further details. module fifo_4kx16_dc ( aclr, data, rdclk, rdreq, wrclk, wrreq, q, rdempty, rdusedw, wrfull, wrusedw); input aclr; input [15:0] data; input rdclk; input rdreq; input wrclk; input wrreq; output [15:0] q; output rdempty; output [11:0] rdusedw; output wrfull; output [11:0] wrusedw; endmodule // ============================================================ // CNX file retrieval info // ============================================================ // Retrieval info: PRIVATE: AlmostEmpty NUMERIC "0" // Retrieval info: PRIVATE: AlmostEmptyThr NUMERIC "-1" // Retrieval info: PRIVATE: AlmostFull NUMERIC "0" // Retrieval info: PRIVATE: AlmostFullThr NUMERIC "-1" // Retrieval info: PRIVATE: CLOCKS_ARE_SYNCHRONIZED NUMERIC "0" // Retrieval info: PRIVATE: Clock NUMERIC "4" // Retrieval info: PRIVATE: Depth NUMERIC "4096" // Retrieval info: PRIVATE: Empty NUMERIC "1" // Retrieval info: PRIVATE: Full NUMERIC "1" // Retrieval info: PRIVATE: INTENDED_DEVICE_FAMILY STRING "Cyclone" // Retrieval info: PRIVATE: LE_BasedFIFO NUMERIC "0" // Retrieval info: PRIVATE: LegacyRREQ NUMERIC "0" // Retrieval info: PRIVATE: MAX_DEPTH_BY_9 NUMERIC "0" // Retrieval info: PRIVATE: OVERFLOW_CHECKING NUMERIC "1" // Retrieval info: PRIVATE: Optimize NUMERIC "2" // Retrieval info: PRIVATE: RAM_BLOCK_TYPE NUMERIC "0" // Retrieval info: PRIVATE: UNDERFLOW_CHECKING NUMERIC "1" // Retrieval info: PRIVATE: UsedW NUMERIC "1" // Retrieval info: PRIVATE: Width NUMERIC "16" // Retrieval info: PRIVATE: dc_aclr NUMERIC "1" // Retrieval info: PRIVATE: rsEmpty NUMERIC "1" // Retrieval info: PRIVATE: rsFull NUMERIC "0" // Retrieval info: PRIVATE: rsUsedW NUMERIC "1" // Retrieval info: PRIVATE: sc_aclr NUMERIC "0" // Retrieval info: PRIVATE: sc_sclr NUMERIC "0" // Retrieval info: PRIVATE: wsEmpty NUMERIC "0" // Retrieval info: PRIVATE: wsFull NUMERIC "1" // Retrieval info: PRIVATE: wsUsedW NUMERIC "1" // Retrieval info: CONSTANT: ADD_RAM_OUTPUT_REGISTER STRING "OFF" // Retrieval info: CONSTANT: CLOCKS_ARE_SYNCHRONIZED STRING "FALSE" // Retrieval info: CONSTANT: INTENDED_DEVICE_FAMILY STRING "Cyclone" // Retrieval info: CONSTANT: LPM_NUMWORDS NUMERIC "4096" // Retrieval info: CONSTANT: LPM_SHOWAHEAD STRING "ON" // Retrieval info: CONSTANT: LPM_TYPE STRING "dcfifo" // Retrieval info: CONSTANT: LPM_WIDTH NUMERIC "16" // Retrieval info: CONSTANT: LPM_WIDTHU NUMERIC "12" // Retrieval info: CONSTANT: OVERFLOW_CHECKING STRING "OFF" // Retrieval info: CONSTANT: UNDERFLOW_CHECKING STRING "OFF" // Retrieval info: CONSTANT: USE_EAB STRING "ON" // Retrieval info: USED_PORT: aclr 0 0 0 0 INPUT GND aclr // Retrieval info: USED_PORT: data 0 0 16 0 INPUT NODEFVAL data[15..0] // Retrieval info: USED_PORT: q 0 0 16 0 OUTPUT NODEFVAL q[15..0] // Retrieval info: USED_PORT: rdclk 0 0 0 0 INPUT NODEFVAL rdclk // Retrieval info: USED_PORT: rdempty 0 0 0 0 OUTPUT NODEFVAL rdempty // Retrieval info: USED_PORT: rdreq 0 0 0 0 INPUT NODEFVAL rdreq // Retrieval info: USED_PORT: rdusedw 0 0 12 0 OUTPUT NODEFVAL rdusedw[11..0] // Retrieval info: USED_PORT: wrclk 0 0 0 0 INPUT NODEFVAL wrclk // Retrieval info: USED_PORT: wrfull 0 0 0 0 OUTPUT NODEFVAL wrfull // Retrieval info: USED_PORT: wrreq 0 0 0 0 INPUT NODEFVAL wrreq // Retrieval info: USED_PORT: wrusedw 0 0 12 0 OUTPUT NODEFVAL wrusedw[11..0] // Retrieval info: CONNECT: @data 0 0 16 0 data 0 0 16 0 // Retrieval info: CONNECT: q 0 0 16 0 @q 0 0 16 0 // Retrieval info: CONNECT: @wrreq 0 0 0 0 wrreq 0 0 0 0 // Retrieval info: CONNECT: @rdreq 0 0 0 0 rdreq 0 0 0 0 // Retrieval info: CONNECT: @rdclk 0 0 0 0 rdclk 0 0 0 0 // Retrieval info: CONNECT: @wrclk 0 0 0 0 wrclk 0 0 0 0 // Retrieval info: CONNECT: rdempty 0 0 0 0 @rdempty 0 0 0 0 // Retrieval info: CONNECT: rdusedw 0 0 12 0 @rdusedw 0 0 12 0 // Retrieval info: CONNECT: wrfull 0 0 0 0 @wrfull 0 0 0 0 // Retrieval info: CONNECT: wrusedw 0 0 12 0 @wrusedw 0 0 12 0 // Retrieval info: CONNECT: @aclr 0 0 0 0 aclr 0 0 0 0 // Retrieval info: LIBRARY: altera_mf altera_mf.altera_mf_components.all // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc.v TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc.inc TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc.cmp TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc.bsf TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc_inst.v TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc_bb.v TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc_waveforms.html FALSE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc_wave*.jpg FALSE
/* * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 / `ifndef SKY130_FD_SC_MS__DLYGATE4SD1_FUNCTIONAL_V `define SKY130_FD_SC_MS__DLYGATE4SD1_FUNCTIONAL_V /* * dlygate4sd1: Delay Buffer 4-stage 0.15um length inner stage gates. * * Verilog simulation functional model. */ `timescale 1ns / 1ps `default_nettype none `celldefine module sky130_fd_sc_ms__dlygate4sd1 ( X, A ); // Module ports output X; input A; // Local signals wire buf0_out_X; // Name Output Other arguments buf buf0 (buf0_out_X, A ); buf buf1 (X , buf0_out_X ); endmodule `endcelldefine `default_nettype wire `endif // SKY130_FD_SC_MS__DLYGATE4SD1_FUNCTIONAL_V
////////////////////////////////////////////////////////////////////////////// // File name : mt48lc4m16.v ////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2008 Free Model Foundry; http://www.freemodelfoundry.com // // This program is free software; you can redistribute it and/or modify // it under the terms of the GNU General Public License version 2 as // published by the Free Software Foundation. // // MODIFICATION HISTORY: // // version: \| author: \| mod date: \| changes made: // V1.0 S.Janevski 08 Feb 27 Initial release // V1.1 S.Janevski 08 Mar 26 Assertions of wrong DQM settings during powerup removed ////////////////////////////////////////////////////////////////////////////// // PART DESCRIPTION: // // Library: RAM // Technology: LVTTL // Part: mt48lc4m16 // // Description: 1M x 16 x 4Banks SDRAM // ////////////////////////////////////////////////////////////////////////////// // Known Bugs: // ////////////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////////// // MODULE DECLARATION // ////////////////////////////////////////////////////////////////////////////// `timescale 1 ns/100 ps module mt48lc4m16 ( A11 , A10 , A9 , A8 , A7 , A6 , A5 , A4 , A3 , A2 , A1 , A0 , DQ15 , DQ14 , DQ13 , DQ12 , DQ11 , DQ10 , DQ9 , DQ8 , DQ7 , DQ6 , DQ5 , DQ4 , DQ3 , DQ2 , DQ1 , DQ0 , BA0 , BA1 , DQMH , DQML , CLK , CKE , WENeg , RASNeg , CSNeg , CASNeg ); //////////////////////////////////////////////////////////////////////// // Port / Part Pin Declarations //////////////////////////////////////////////////////////////////////// input A11 ; input A10 ; input A9 ; input A8 ; input A7 ; input A6 ; input A5 ; input A4 ; input A3 ; input A2 ; input A1 ; input A0 ; inout DQ15 ; inout DQ14 ; inout DQ13 ; inout DQ12 ; inout DQ11 ; inout DQ10 ; inout DQ9 ; inout DQ8 ; inout DQ7 ; inout DQ6 ; inout DQ5 ; inout DQ4 ; inout DQ3 ; inout DQ2 ; inout DQ1 ; inout DQ0 ; input BA0 ; input BA1 ; input DQMH ; input DQML ; input CLK ; input CKE ; input WENeg ; input RASNeg ; input CSNeg ; input CASNeg ; // interconnect path delay signals wire A11_ipd ; wire A10_ipd ; wire A9_ipd ; wire A8_ipd ; wire A7_ipd ; wire A6_ipd ; wire A5_ipd ; wire A4_ipd ; wire A3_ipd ; wire A2_ipd ; wire A1_ipd ; wire A0_ipd ; wire [11 : 0] A; assign A = {A11_ipd, A10_ipd, A9_ipd, A8_ipd, A7_ipd, A6_ipd, A5_ipd, A4_ipd, A3_ipd, A2_ipd, A1_ipd, A0_ipd }; wire DQ15_ipd ; wire DQ14_ipd ; wire DQ13_ipd ; wire DQ12_ipd ; wire DQ11_ipd ; wire DQ10_ipd ; wire DQ9_ipd ; wire DQ8_ipd ; wire DQ7_ipd ; wire DQ6_ipd ; wire DQ5_ipd ; wire DQ4_ipd ; wire DQ3_ipd ; wire DQ2_ipd ; wire DQ1_ipd ; wire DQ0_ipd ; wire [15 : 0 ] DQIn; assign DQIn = { DQ15_ipd, DQ14_ipd, DQ13_ipd, DQ12_ipd, DQ11_ipd, DQ10_ipd, DQ9_ipd, DQ8_ipd, DQ7_ipd, DQ6_ipd, DQ5_ipd, DQ4_ipd, DQ3_ipd, DQ2_ipd, DQ1_ipd, DQ0_ipd }; wire [15 : 0] DQOut; assign DQOut = { DQ15, DQ14, DQ13, DQ12, DQ11, DQ10, DQ9, DQ8, DQ7, DQ6, DQ5, DQ4, DQ3, DQ2, DQ1, DQ0 }; wire BA0_ipd ; wire BA1_ipd ; wire DQM1_ipd ; wire DQM0_ipd ; wire CLK_ipd ; wire CKE_ipd ; wire WENeg_ipd ; wire RASNeg_ipd ; wire CSNeg_ipd ; wire CASNeg_ipd ; integer bank; integer bank_tmp; // internal delays reg rct_in ; reg rct_out; reg [3:0] rcdt_in ; reg [3:0] rcdt_out; reg pre_in ; reg pre_out ; reg refreshed_in ; reg refreshed_out ; reg rcar_out ; reg rcar_in ; reg [3:0] ras_in = 1'b0; reg [3:0] ras_out = 1'b0; reg [15 : 0] DQ_zd = 16'bz; assign {DQ15_zd, DQ14_zd, DQ13_zd, DQ12_zd, DQ11_zd, DQ10_zd, DQ9_zd, DQ8_zd, DQ7_zd, DQ6_zd, DQ5_zd, DQ4_zd, DQ3_zd, DQ2_zd, DQ1_zd, DQ0_zd } = DQ_zd; parameter UserPreload = 1'b1; // parameter mem_file_name = "none"; //"mt48lc4m16.mem"; parameter mem_file_name = "mt48lc4m16.mem"; parameter TimingModel = "DefaultTimingModel"; parameter PartID = "mt48lc4m16"; parameter hi_bank = 3; parameter depth = 25'h100000; reg PoweredUp = 1'b0; reg CKEreg = 1'b0; reg CAS_Lat ; reg CAS_Lat2; reg [15:0] DataDrive = 16'bz ; // Memory array declaration integer Mem [0:(hi_bank+1)depth2-1]; // Type definition for state machine parameter pwron = 5'd0; parameter precharge = 5'd1; parameter idle = 5'd2; parameter mode_set = 5'd3; parameter self_refresh = 5'd4; parameter auto_refresh = 5'd5; parameter pwrdwn = 5'd6; parameter bank_act = 5'd7; parameter bank_act_pwrdwn = 5'd8; parameter write = 5'd9; parameter write_suspend = 5'd10; parameter read = 5'd11; parameter read_suspend = 5'd12; parameter write_auto_pre = 5'd13; parameter read_auto_pre = 5'd14; reg [4:0] statebank [hi_bank:0]; reg [4:0] debug_state; // Type definition for commands parameter desl = 4'd0; parameter nop = 4'd1; parameter bst = 4'd2; parameter rd = 4'd3; parameter writ = 4'd4; parameter act = 4'd5; parameter pre = 4'd6; parameter mrs = 4'd7; parameter ref = 4'd8; reg [3:0] command = desl; // burst type parameter sequential = 1'b0; parameter interleave = 1'b1; reg Burst ; // write burst mode parameter programmed = 1'b0; parameter single = 1'b1; reg WB ; //burst sequences integer intab [0:63]; reg [19:0] MemAddr [hi_bank:0]; integer BurstCnt [hi_bank:0]; integer StartAddr [hi_bank:0]; integer BurstInc [hi_bank:0]; integer BaseLoc [hi_bank:0]; integer Loc; integer BurstLen; integer Burst_Bits; reg written = 1'b0; reg chip_en = 1'b0; integer cur_bank; reg [11:0] ModeReg ; integer Ref_Cnt = 0; time Next_Ref = 0; reg [88:1] BankString ; reg Viol = 1'b0; reg [15:0] DataDriveOut = 16'bz; reg [15:0] DataDrive1 = 16'bz; reg [15:0] DataDrive2 = 16'bz; reg [15:0] DataDrive3 = 16'bz; reg DQM0_reg0 ; reg DQM0_reg1 ; reg DQM0_reg2 ; reg DQM1_reg0 ; reg DQM1_reg1 ; reg DQM1_reg2 ; // tdevice values: values for internal delays parameter TRAS_VAL = 37; parameter TRCD_VAL = 15; time tdevice_TRASmin = 37; time tdevice_TRASmax = 1200000; time tdevice_TRC = 66; time tdevice_TRCAR = 60; time tdevice_TRCD = TRCD_VAL; time tdevice_TRP = 15; /////////////////////////////////////////////////////////////////////////// //Interconnect Path Delay Section /////////////////////////////////////////////////////////////////////////// buf (A11_ipd, A11); buf (A10_ipd, A10); buf (A9_ipd , A9 ); buf (A8_ipd , A8 ); buf (A7_ipd , A7 ); buf (A6_ipd , A6 ); buf (A5_ipd , A5 ); buf (A4_ipd , A4 ); buf (A3_ipd , A3 ); buf (A2_ipd , A2 ); buf (A1_ipd , A1 ); buf (A0_ipd , A0 ); buf (DQ15_ipd , DQ15 ); buf (DQ14_ipd , DQ14 ); buf (DQ13_ipd , DQ13 ); buf (DQ12_ipd , DQ12 ); buf (DQ11_ipd , DQ11 ); buf (DQ10_ipd , DQ10 ); buf (DQ9_ipd , DQ9 ); buf (DQ8_ipd , DQ8 ); buf (DQ7_ipd , DQ7 ); buf (DQ6_ipd , DQ6 ); buf (DQ5_ipd , DQ5 ); buf (DQ4_ipd , DQ4 ); buf (DQ3_ipd , DQ3 ); buf (DQ2_ipd , DQ2 ); buf (DQ1_ipd , DQ1 ); buf (DQ0_ipd , DQ0 ); buf (CASNeg_ipd, CASNeg); buf (RASNeg_ipd, RASNeg); buf (BA0_ipd , BA0 ); buf (BA1_ipd , BA1 ); buf (DQM0_ipd , DQML ); buf (DQM1_ipd , DQMH ); buf (CLK_ipd , CLK ); buf (CKE_ipd , CKE ); buf (WENeg_ipd , WENeg ); buf (CSNeg_ipd , CSNeg ); /////////////////////////////////////////////////////////////////////////// // Propagation delay Section /////////////////////////////////////////////////////////////////////////// nmos (DQ15 , DQ15_zd , 1); nmos (DQ14 , DQ14_zd , 1); nmos (DQ13 , DQ13_zd , 1); nmos (DQ12 , DQ12_zd , 1); nmos (DQ11 , DQ11_zd , 1); nmos (DQ10 , DQ10_zd , 1); nmos (DQ9 , DQ9_zd , 1); nmos (DQ8 , DQ8_zd , 1); nmos (DQ7 , DQ7_zd , 1); nmos (DQ6 , DQ6_zd , 1); nmos (DQ5 , DQ5_zd , 1); nmos (DQ4 , DQ4_zd , 1); nmos (DQ3 , DQ3_zd , 1); nmos (DQ2 , DQ2_zd , 1); nmos (DQ1 , DQ1_zd , 1); nmos (DQ0 , DQ0_zd , 1); wire deg; wire chip_act; assign chip_act = chip_en; wire chip_act_deg; assign chip_act_deg = chip_act && deg; wire cas_latency2; wire cas_latency3; assign cas_latency2 = ~CAS_Lat && CAS_Lat2; assign cas_latency3 = CAS_Lat && CAS_Lat2; specify // tipd delays: interconnect path delays, mapped to input port delays. // In Verilog it is not necessary to declare any tipd delay variables, // they can be taken from SDF file // With all the other delays real delays would be taken from SDF file // tpd delays specparam tpd_CLK_DQ0 = 1; specparam tpd_CLK_DQ1 = 1; // tpw values: pulse widths specparam tpw_CLK_posedge = 1; specparam tpw_CLK_negedge = 1; // tsetup values: setup times specparam tsetup_DQ0_CLK = 1; // tDS // thold values: hold times specparam thold_DQ0_CLK = 1; // tDH // tperiod_min: minimum clock period = 1/max freq specparam tperiod_CLK_cl1_eq_1_posedge = 1; specparam tperiod_CLK_cl2_eq_1_posedge = 1; // tdevice values: values for internal delays specparam tdevice_REF = 15625 ; /////////////////////////////////////////////////////////////////////// // Input Port Delays don't require Verilog description /////////////////////////////////////////////////////////////////////// // Path delays // /////////////////////////////////////////////////////////////////////// if (~CAS_Lat && CAS_Lat2) (CLK > DQ0) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ1) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ2) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ3) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ4) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ5) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ6) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ7) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ8) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ9) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ10) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ11) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ12) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ13) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ14) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK > DQ15) = tpd_CLK_DQ0; if (CAS_Lat && CAS_Lat2) (CLK > DQ0) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ1) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ2) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ3) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ4) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ5) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ6) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ7) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ8) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ9) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ10) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ11) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ12) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ13) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ14) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK > DQ15) = tpd_CLK_DQ1; //////////////////////////////////////////////////////////////////////// // Timing Check Section //////////////////////////////////////////////////////////////////////// $setup (BA0 , posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (BA1 , posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (DQML, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (DQMH, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (CKE , posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (WENeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (CSNeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (CASNeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (RASNeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (DQ0 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ1 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ2 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ3 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ4 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ5 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ6 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ7 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ8 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ9 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ10 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ11 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ12 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ13 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ14 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ15 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (A0, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A1, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A2, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A3, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A4, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A5, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A6, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A7, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A8, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A9, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A10, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A11, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, BA0, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, BA1, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, DQML, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, DQMH, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, CKE , thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, CASNeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, RASNeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, WENeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, CSNeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A0, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A1, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A2, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A3, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A4, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A5, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A6, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A7, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A8, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A9, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A10, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A11, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ0, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ1, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ2, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ3, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ4, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ5, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ6, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ7, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ8, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ9, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ10, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ11, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ12, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ13, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ14, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ15, thold_DQ0_CLK, Viol); $width (posedge CLK &&& chip_act, tpw_CLK_posedge); $width (negedge CLK &&& chip_act, tpw_CLK_negedge); $period (posedge CLK &&& cas_latency2, tperiod_CLK_cl1_eq_1_posedge); $period (posedge CLK &&& cas_latency3, tperiod_CLK_cl2_eq_1_posedge); endspecify task generate_out ; output [15:0] DataDrive; input Bank; integer Bank; integer location; begin location = Bank depth * 2 + Loc; DataDrive[7:0] = 8'bx; if (Mem[location] > -1) DataDrive[7:0] = Mem[location]; DataDrive[15:8] = 8'bx; if (Mem[location+1] > -1) DataDrive[15:8] = Mem[location+1]; end endtask task MemWrite; input Bank; integer Bank; integer location; begin location = Bank * depth * 2 + Loc; if (~DQM0_ipd) begin Mem[location] = -1; if (~Viol) Mem[location] = DQIn[7:0]; end if (~DQM1_ipd) begin Mem[location+1] = -1; if (~Viol) Mem[location+1] = DQIn[15:8]; end end endtask task BurstIncProc; input Bank; integer Bank; begin BurstInc[Bank] = 0; if (Burst_Bits == 1) BurstInc[Bank] = A[0:0]; if (Burst_Bits == 2) BurstInc[Bank] = A[1:0]; if (Burst_Bits == 3) BurstInc[Bank] = A[2:0]; if (Burst_Bits == 7) BurstInc[Bank] = A[6:0]; end endtask task NextStateAuto; input Bank; input state; integer Bank; reg [4:0] state; begin if (~A[10]) statebank[Bank] = state; else if (A[10]) if (state == write) statebank[Bank] = write_auto_pre; else statebank[Bank] = read_auto_pre; end endtask ////////////////////////////////////////////////////////////////////////// // Main Behavior Block // ////////////////////////////////////////////////////////////////////////// // chech when data is generated from model to avoid setup/hold check in // those occasion reg deq; always @(DQIn, DQOut) begin if (DQIn==DQOut) deq=1'b1; else deq=1'b0; end assign deg=deq; // initialize burst sequences initial begin intab[0] = 0; intab[1] = 1; intab[2] = 2; intab[3] = 3; intab[4] = 4; intab[5] = 5; intab[6] = 6; intab[7] = 7; intab[8] = 1; intab[9] = 0; intab[10] = 3; intab[11] = 2; intab[12] = 5; intab[13] = 4; intab[14] = 7; intab[15] = 6; intab[16] = 2; intab[17] = 3; intab[18] = 0; intab[19] = 1; intab[20] = 6; intab[21] = 7; intab[22] = 4; intab[23] = 5; intab[24] = 3; intab[25] = 2; intab[26] = 1; intab[27] = 0; intab[28] = 7; intab[29] = 6; intab[30] = 5; intab[31] = 4; intab[32] = 4; intab[33] = 5; intab[34] = 6; intab[35] = 7; intab[36] = 0; intab[37] = 1; intab[38] = 2; intab[39] = 3; intab[40] = 5; intab[41] = 4; intab[42] = 7; intab[43] = 6; intab[44] = 1; intab[45] = 0; intab[46] = 3; intab[47] = 2; intab[48] = 6; intab[49] = 7; intab[50] = 4; intab[51] = 5; intab[52] = 2; intab[53] = 3; intab[54] = 0; intab[55] = 1; intab[56] = 7; intab[57] = 6; intab[58] = 5; intab[59] = 4; intab[60] = 3; intab[61] = 2; intab[62] = 1; intab[63] = 0; end // initialize memory and load preload files if any initial begin: InitMemory integer i; for (i=0; i<=((hi_bank+1)depth2 - 1); i=i+1) begin Mem[i] = -1; end // Memory preload file // mt48lc4m16.mem file // @bbbbbb - <bbbbbb> stands for address within memory, // dd - <dd> is word to be written at Mem(bbbbbb++) // (bbbbbb is incremented at every load) if (UserPreload && !(mem_file_name == "none")) $readmemh(mem_file_name,Mem); end //Power Up time 100 us; initial begin PoweredUp = 1'b0; statebank[0] = pwron; statebank[1] = pwron; statebank[2] = pwron; statebank[3] = pwron; $display ("Powering up! Time: %d", $time); #100 PoweredUp = 1'b1; $display ("Powerup Finished at %d", $time); end always @(posedge ras_in[0]) begin:TRASrise0 // $display ("ras in for bank 0 high, tdevice_TRASmin = %d", tdevice_TRASmin); ras_out[0] <= #tdevice_TRASmin ras_in[0]; end always @(negedge ras_in[0]) begin:TRASfall0 ras_out[0] <= #tdevice_TRASmax ras_in[0]; end always @(posedge ras_in[1]) begin:TRASrise1 ras_out[1] <= #tdevice_TRASmin ras_in[1]; end always @(negedge ras_in[1]) begin:TRASfall1 ras_out[1] <= #tdevice_TRASmax ras_in[1]; end always @(posedge ras_in[2]) begin:TRASrise2 ras_out[2] <= #tdevice_TRASmin ras_in[2]; end always @(negedge ras_in[2]) begin:TRASfall2 ras_out[2] <= #tdevice_TRASmax ras_in[2]; end always @(posedge ras_in[3]) begin:TRASrise3 ras_out[3] <= #tdevice_TRASmin ras_in[3]; end always @(negedge ras_in[3]) begin:TRASfall3 ras_out[3] <= #tdevice_TRASmax ras_in[3]; end always @(posedge rcdt_in[0]) begin:TRCDrise0 // $display ("TRD went high"); rcdt_out[0] <= #5 1'b1; end always @(negedge rcdt_in[0]) begin:TRCDfall0 // $display ("TRD went low"); rcdt_out[0] <= #tdevice_TRCD 1'b0; end always @(posedge rcdt_in[1]) begin:TRCDrise1 rcdt_out[1] <= #5 1'b1; end always @(negedge rcdt_in[1]) begin:TRCDfall1 rcdt_out[1] <= #tdevice_TRCD 1'b0; end always @(posedge rcdt_in[2]) begin:TRCDrise2 rcdt_out[2] <= #5 1'b1; end always @(negedge rcdt_in[2]) begin:TRCDfall2 rcdt_out[2] <= #tdevice_TRCD 1'b0; end always @(posedge rcdt_in[3]) begin:TRCDrise3 rcdt_out[3] <= #5 1'b1; end always @(negedge rcdt_in[3]) begin:TRCDfall3 rcdt_out[3] <= #tdevice_TRCD 1'b0; end ///////////////////////////////////////////////////////////////////////// // Functional Section ///////////////////////////////////////////////////////////////////////// always @(posedge CLK) begin if ($time > Next_Ref && PoweredUp && Ref_Cnt > 0) begin Ref_Cnt = Ref_Cnt - 1; // Next_Ref = $time + tdevice_REF; Next_Ref = $time + 15625; end if (CKEreg) begin if (~CSNeg_ipd) chip_en = 1; else chip_en = 0; end if (CKEreg && ~CSNeg_ipd) begin if (WENeg_ipd == 1'bx) $display(" Unusable value for WENeg "); if (RASNeg_ipd == 1'bx) $display(" Unusable value for RASNeg "); if (CASNeg_ipd == 1'bx) $display(" Unusable value for CASNeg "); // Command Decode if (RASNeg_ipd && CASNeg_ipd && WENeg_ipd) command = nop; else if (~RASNeg_ipd && CASNeg_ipd && WENeg_ipd) command = act; else if (RASNeg_ipd && ~CASNeg_ipd && WENeg_ipd) command = rd; else if (RASNeg_ipd && ~CASNeg_ipd && ~WENeg_ipd) command = writ; else if (RASNeg_ipd && CASNeg_ipd && ~WENeg_ipd) command = bst; else if (~RASNeg_ipd && CASNeg_ipd && ~WENeg_ipd) command = pre; else if (~RASNeg_ipd && ~CASNeg_ipd && WENeg_ipd) command = ref; else if (~RASNeg_ipd && ~CASNeg_ipd && ~WENeg_ipd) command = mrs; // PowerUp Check if (~(PoweredUp) && command != nop) begin $display (" Incorrect power up. Command %h issued before ", command); $display (" power up complete. "); end // Bank Decode if (~BA0_ipd && ~BA1_ipd) cur_bank = 0; else if (BA0_ipd && ~BA1_ipd) cur_bank = 1; else if (~BA0_ipd && BA1_ipd) cur_bank = 2; else if (BA0_ipd && BA1_ipd) cur_bank = 3; else begin $display ("Could not decode bank selection - results"); $display ("may be incorrect."); end end // The Big State Machine if (CKEreg) begin if (CSNeg_ipd == 1'bx) $display ("Unusable value for CSNeg"); if (CSNeg_ipd) command = nop; // DQM pipeline DQM0_reg2 = DQM0_reg1; DQM0_reg1 = DQM0_reg0; DQM0_reg0 = DQM0_ipd; DQM1_reg2 = DQM1_reg1; DQM1_reg1 = DQM1_reg0; DQM1_reg0 = DQM1_ipd; // by default data drive is Z, might get over written in one // of the passes below DataDrive = 16'bz; debug_state <= statebank[0]; for (bank = 0; bank <= hi_bank; bank = bank + 1) begin case (statebank[bank]) pwron : begin if (~PoweredUp) begin if (command != nop) $display ("Only NOPs allowed during power up."); DataDrive = 16'bz; end else if (command == pre && (cur_bank == bank \|\| A[10])) begin statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end end precharge : begin //$display ("\tRAM: Precharge"); if (cur_bank == bank) // It is only an error if this bank is selected if (command != nop && command != pre) begin $display ("Illegal command received "); $display ("during precharge.",$time); end end idle : begin if (command == nop \|\| command == bst \|\| command == pre \|\| cur_bank != bank) begin end else if (command == mrs) begin if (statebank[0] == idle && statebank[1] == idle && statebank[2] == idle && statebank[3] == idle) begin ModeReg = A; statebank[bank] = mode_set; end end else if (command == ref) begin if (statebank[0] == idle && statebank[1] == idle && statebank[2] == idle && statebank[3] == idle) if (CKE) begin statebank[bank] = auto_refresh; statebank[bank] <= #tdevice_TRCAR idle; end else begin statebank[0] = self_refresh; statebank[1] = self_refresh; statebank[2] = self_refresh; statebank[3] = self_refresh; end end else if (command == act) begin $display ("\tRAM: Activate Command Received"); statebank[bank] = bank_act; ras_in[bank] = 1'b1; ras_in [bank] <= #70 1'b0; rct_in = 1'b1; rct_in <= #1 1'b0; rcdt_in[bank] = 1'b1; rcdt_in[bank] <= #1 1'b0; MemAddr[bank][19:8] = A; // latch row addr end else $display ("Illegal command received in idle state.",$time); end mode_set : begin $display ("\tRAM: Setting mode to %h", ModeReg); if (ModeReg[7] != 0 \|\| ModeReg[8] != 0) $display ("Illegal operating mode set."); if (command != nop) begin $display ("Illegal command received during mode"); $display ("set.",$time); end // read burst length if (ModeReg[2:0] == 3'b000) begin BurstLen = 1; Burst_Bits = 0; end else if (ModeReg[2:0] == 3'b001) begin BurstLen = 2; Burst_Bits = 1; end else if (ModeReg[2:0] == 3'b010) begin BurstLen = 4; Burst_Bits = 2; end else if (ModeReg[2:0] == 3'b011) begin BurstLen = 8; Burst_Bits = 3; end else if (ModeReg[2:0] == 3'b111) begin BurstLen = 256; Burst_Bits = 7; end else $display ("Invalid burst length specified."); $display ("Burst Length set to %d", BurstLen); // read burst type if (~ModeReg[3]) begin Burst = sequential; $display ("Burst Type == Sequential"); end else if (ModeReg[3]) Burst = interleave; else $display ("Invalid burst type specified."); // read CAS latency if (ModeReg[6:4] == 3'b010) begin CAS_Lat = 1'b0; CAS_Lat2 = 1'b1; end else if (ModeReg[6:4] == 3'b011) begin CAS_Lat = 1'b1; CAS_Lat2 = 1'b1; end else $display ("CAS Latency set incorrecty"); // write burst mode if (~ModeReg[9]) WB = programmed; else if (ModeReg[9]) WB = single; else $display ("Invalid burst type specified."); statebank[bank] = idle; end auto_refresh : begin //$display ("\tRAM: Auto Refresh Entered"); if (Ref_Cnt < 8192) Ref_Cnt = Ref_Cnt + 1; if (command != nop) begin //$display ("Illegal command received during autorefresh: %h", command); //$display ("auto_refresh.",$time); end end bank_act : begin $display ("\tRAM: Bank Activate"); if (command == pre && (cur_bank == bank \|\| A[10])) begin if (~ras_out[bank]) begin $display ("precharge command does not meet tRAS"); $display ("time", $time); end statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else if (command == nop \|\| command == bst \|\| cur_bank != bank) begin end else if (command == rd) begin if (rcdt_out[bank]) begin $display ("read command received too soon"); $display ("after active",$time); $display ("rcdt_out[bank] == %d", rcdt_out[bank]); end if (A[10] == 1'bx) begin $display ("A(10) = X during read command."); $display ("Next state unknown."); end MemAddr[bank][7:0] = 8'b0;// clr old addr // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; BurstIncProc(bank); StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive,bank); BurstCnt[bank] = 1; NextStateAuto(bank, read); bank_tmp = bank; end else if (command == writ) begin if (rcdt_out[bank]) begin $display ("write command received too soon"); $display ("after active",$time); $display ("bank: %h", bank); $display ("rcdt_out[bank] = %d", rcdt_out[bank]); end if (A[10] == 1'bx) begin $display ("A(10) = X during write command."); $display ("Next state unknown."); end MemAddr[bank][7:0] = 8'b0; // clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = 1'b1; NextStateAuto(bank, write); written = 1'b1; end else if (cur_bank == bank \|\| command == mrs) begin $display ("Illegal command received in"); $display ("active state",$time); end end write : begin $display ("\tRAM: Write: %h", DQIn); if (command == bst) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; end else if (command == rd) if (cur_bank == bank) begin MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = 1'b1; NextStateAuto(bank, read); end else statebank[bank] = bank_act; else if (command == writ) if (cur_bank == bank) begin MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = 1'b1; if (A[10]) statebank[bank] = write_auto_pre; end else statebank[bank] = bank_act; else if (command == pre && (cur_bank == bank \|\| A[10])) begin if (~ras_out[bank]) begin $display ("precharge command does not meet tRAS time",$time); end if (~DQM0_ipd) begin $display ("DQM0 should be held high, data is"); $display ("lost.",$time); end if (~DQM1_ipd) begin $display ("DQM1 should be held high, data is"); $display ("lost.",$time); end statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else if (command == nop \|\| cur_bank != bank) if (BurstCnt[bank] == BurstLen \|\| WB == single) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]8 + BurstCnt[bank]]; Loc = 2(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = BurstCnt[bank] + 1; end else if (cur_bank == bank) $display ("Illegal command received in write state",$time); end read : begin $display ("\tRAM: Read"); if (command == bst) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; end else if (command == rd) if (cur_bank == bank) begin MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = 1'b1; NextStateAuto(bank, read); end else statebank[bank] = bank_act; else if (command == writ) if (cur_bank == bank) begin if (rcdt_out[bank]) begin $display ("write command received too soon after active",$time); $display ("Bank: %h", bank); $display ("rcdt_out[bank]: %h", rcdt_out[bank]); end if (A[10] == 1'bx) begin $display ("A(10) = X during write command."); $display ("Next state unknown."); end MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = 1'b1; NextStateAuto(bank,write); end else statebank[bank] = bank_act; else if (command == pre && (cur_bank == bank \|\| A[10])) begin if (~ras_out[bank]) begin $display ("Precharge command does not meet tRAS time",$time); end statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else if (command == nop \|\| cur_bank != bank) begin if (BurstCnt[bank] == BurstLen) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]8 + BurstCnt[bank]]; Loc = 2(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = BurstCnt[bank] + 1; end end else if (cur_bank == bank) $display ("Illegal command received in read state",$time); end write_auto_pre : begin $display ("\tRAM: Write with auto precharge"); if (command == nop \|\| cur_bank != bank) if (BurstCnt[bank] == BurstLen \|\| WB == single) begin statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]8 + BurstCnt[bank]]; Loc = 2(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = BurstCnt[bank] + 1; end else $display ("Illegal command received in write state.",$time); end read_auto_pre : begin $display ("\tRAM: Read with auto precharge"); if (command == nop \|\| (cur_bank != bank && command != rd && command != writ)) if (BurstCnt[bank] == BurstLen) begin $display ("\tRAM: Read W/ SP Continue Reading"); statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin $display ("\tRAM: Read W/ AP Start Reading"); if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]8 + BurstCnt[bank]]; Loc = 2(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = BurstCnt[bank] + 1; end else if ((command == rd \|\| command == writ) && cur_bank != bank) begin $display ("\tRAM: Case 3"); statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else $display ("Illegal command received in read state",$time); end endcase end // Check Refresh Status if (written && (Ref_Cnt == 0)) $display ("memory not refreshed (by ref_cnt)", $time); DataDrive3 = DataDrive2; DataDrive2 = DataDrive1; DataDrive1 = DataDrive; end // Latency adjustments and DQM read masking if (~DQM0_reg1) if (CAS_Lat && CAS_Lat2) DataDriveOut[7:0] = DataDrive3[7:0]; else DataDriveOut[7:0] = DataDrive2[7:0]; else DataDriveOut[7:0] = 8'bz; if (~DQM1_reg1) if (CAS_Lat && CAS_Lat2) DataDriveOut[15:8] = DataDrive3[15:8]; else DataDriveOut[15:8] = DataDrive2[15:8]; else DataDriveOut[15:8] = 8'bz; // The Powering-up State Machine if (~CKEreg && CKE_ipd) begin if (CSNeg_ipd == 1'bx) $display ("Unusable value for CSNeg"); if (CSNeg_ipd) command = nop; case (statebank[cur_bank]) write_suspend : begin statebank[cur_bank] = write; end read_suspend : begin statebank[cur_bank] = read; end self_refresh : begin statebank[0] <= #tdevice_TRP idle; statebank[1] <= #tdevice_TRP idle; statebank[2] <= #tdevice_TRP idle; statebank[3] <= #tdevice_TRP idle; Ref_Cnt = 8192; if (command != nop) begin $display ("Illegal command received during self"); $display ("refresh",$time); end end pwrdwn : begin statebank[0] = idle; statebank[1] = idle; statebank[2] = idle; statebank[3] = idle; end bank_act_pwrdwn : begin statebank[cur_bank] = bank_act; end endcase end // The Powering-down State Machine if (CKEreg && ~CKE_ipd) begin if (CSNeg_ipd == 1'bx) $display ("Unusable value for CSNeg"); if (CSNeg_ipd) command = nop; case (statebank[cur_bank]) idle : begin if (command == nop) begin statebank[0] = pwrdwn; statebank[1] = pwrdwn; statebank[2] = pwrdwn; statebank[3] = pwrdwn; end end write : begin statebank[cur_bank] = write_suspend; end read : begin statebank[cur_bank] = read_suspend; end bank_act : begin statebank[cur_bank] = bank_act_pwrdwn; end endcase end CKEreg = CKE_ipd; end always @(DataDriveOut) begin DQ_zd = DataDriveOut; end reg TRASMIN_In, TRASMAX_In, TRC_In , TRCAR_In; reg TRCD_In , TRP_In , TWR_In; wire TRASMIN_Out,TRASMAX_Out,TRC_Out,TRCAR_Out, TRCD_Out, TRP_Out, TWR_Out; BUFFER BUF_TRASMIN (TRASMIN_Out , TRASMIN_In); BUFFER BUF_TRASMAX (TRASMAX_Out , TRASMAX_In); BUFFER BUF_TRC (TRC_Out , TRC_In); BUFFER BUF_TRCAR (TRCAR_Out, TRCAR_In); BUFFER BUF_TRCD (TRCD_Out , TRCD_In); BUFFER BUF_TRP (TRP_Out , TRP_In); initial begin TRASMIN_In = 1; TRASMAX_In = 1; TRC_In = 1; TRCAR_In = 1; TRCD_In = 1'b1; TRP_In = 1; TWR_In = 1; end /* always @(posedge TRC_Out) begin tdevice_TRC = $time; end always @(posedge TRASMIN_Out) begin tdevice_TRASmin = $time; end always @(posedge TRASMAX_Out) begin tdevice_TRASmax = $time; end always @(posedge TRCAR_Out) begin tdevice_TRCAR = $time; end always @(posedge TRCD_Out) begin tdevice_TRCD = $time; end always @(posedge TRP_Out) begin tdevice_TRP = $time; end */ endmodule module BUFFER (OUT,IN); input IN; output OUT; buf (OUT, IN); endmodule
// ============================================================== // File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC // Version: 2014.4 // Copyright (C) 2014 Xilinx Inc. All rights reserved. // // ============================================================== `timescale 1 ns / 1 ps module image_filter_Loop_1_proc_line_buffer_0_0_val_ram (addr0, ce0, q0, addr1, ce1, d1, we1, clk); parameter DWIDTH = 8; parameter AWIDTH = 11; parameter MEM_SIZE = 1921; input[AWIDTH-1:0] addr0; input ce0; output reg[DWIDTH-1:0] q0; input[AWIDTH-1:0] addr1; input ce1; input[DWIDTH-1:0] d1; input we1; input clk; (* ram_style = "block" *)reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) begin ram[addr1] <= d1; end end end endmodule `timescale 1 ns / 1 ps module image_filter_Loop_1_proc_line_buffer_0_0_val( reset, clk, address0, ce0, q0, address1, ce1, we1, d1); parameter DataWidth = 32'd8; parameter AddressRange = 32'd1921; parameter AddressWidth = 32'd11; input reset; input clk; input[AddressWidth - 1:0] address0; input ce0; output[DataWidth - 1:0] q0; input[AddressWidth - 1:0] address1; input ce1; input we1; input[DataWidth - 1:0] d1; image_filter_Loop_1_proc_line_buffer_0_0_val_ram image_filter_Loop_1_proc_line_buffer_0_0_val_ram_U( .clk( clk ), .addr0( address0 ), .ce0( ce0 ), .q0( q0 ), .addr1( address1 ), .ce1( ce1 ), .d1( d1 ), .we1( we1 )); endmodule
`timescale 1ns / 1ps // KCP53002 Furcula to Wishbone bus bridge // // Note that Furcula is, in reality, a slight modification of Wishbone. // Since these two interconnects share so many signals in common, the // interface to the bridge is kept very small. module bridge( // FURCULA BUS input f_signed_i, input [1:0] f_siz_i, input [2:0] f_adr_i, input [63:0] f_dat_i, output [63:0] f_dat_o, // WISHBONE BUS output [7:0] wb_sel_o, output [63:0] wb_dat_o, input [63:0] wb_dat_i ); // Wishbone SEL_O signal generation. wire size_byte = (f_siz_i == 2'b00); wire size_hword = (f_siz_i == 2'b01); wire size_word = (f_siz_i == 2'b10); wire size_dword = (f_siz_i == 2'b11); wire ab7 = f_adr_i[2:0] == 3'b111; wire ab6 = f_adr_i[2:0] == 3'b110; wire ab5 = f_adr_i[2:0] == 3'b101; wire ab4 = f_adr_i[2:0] == 3'b100; wire ab3 = f_adr_i[2:0] == 3'b011; wire ab2 = f_adr_i[2:0] == 3'b010; wire ab1 = f_adr_i[2:0] == 3'b001; wire ab0 = f_adr_i[2:0] == 3'b000; wire ah3 = f_adr_i[2:1] == 2'b11; wire ah2 = f_adr_i[2:1] == 2'b10; wire ah1 = f_adr_i[2:1] == 2'b01; wire ah0 = f_adr_i[2:1] == 2'b00; wire aw1 = f_adr_i[2] == 1'b1; wire aw0 = f_adr_i[2] == 1'b0; wire den = size_dword; wire wen1 = size_word & aw1; wire wen0 = size_word & aw0; wire hen3 = size_hword & ah3; wire hen2 = size_hword & ah2; wire hen1 = size_hword & ah1; wire hen0 = size_hword & ah0; wire ben7 = size_byte & ab7; wire ben6 = size_byte & ab6; wire ben5 = size_byte & ab5; wire ben4 = size_byte & ab4; wire ben3 = size_byte & ab3; wire ben2 = size_byte & ab2; wire ben1 = size_byte & ab1; wire ben0 = size_byte & ab0; wire sel7 = den \| wen1 \| hen3 \| ben7; wire sel6 = den \| wen1 \| hen3 \| ben6; wire sel5 = den \| wen1 \| hen2 \| ben5; wire sel4 = den \| wen1 \| hen2 \| ben4; wire sel3 = den \| wen0 \| hen1 \| ben3; wire sel2 = den \| wen0 \| hen1 \| ben2; wire sel1 = den \| wen0 \| hen0 \| ben1; wire sel0 = den \| wen0 \| hen0 \| ben0; assign wb_sel_o = {sel7, sel6, sel5, sel4, sel3, sel2, sel1, sel0}; // Furcula-to-Wishbone Data Routing wire [7:0] od7 = (size_byte ? f_dat_i[7:0] : 0) \| (size_hword ? f_dat_i[15:8] : 0) \| (size_word ? f_dat_i[31:24] : 0) \| (size_dword ? f_dat_i[63:56] : 0); wire [7:0] od6 = (size_byte ? f_dat_i[7:0] : 0) \| (size_hword ? f_dat_i[7:0] : 0) \| (size_word ? f_dat_i[23:16] : 0) \| (size_dword ? f_dat_i[55:48] : 0); wire [7:0] od5 = (size_byte ? f_dat_i[7:0] : 0) \| (size_hword ? f_dat_i[15:8] : 0) \| (size_word ? f_dat_i[15:8] : 0) \| (size_dword ? f_dat_i[47:40] : 0); wire [7:0] od4 = (size_byte ? f_dat_i[7:0] : 0) \| (size_hword ? f_dat_i[7:0] : 0) \| (size_word ? f_dat_i[7:0] : 0) \| (size_dword ? f_dat_i[39:32] : 0); wire [7:0] od3 = (size_byte ? f_dat_i[7:0] : 0) \| (size_hword ? f_dat_i[15:8] : 0) \| (size_word ? f_dat_i[31:24] : 0) \| (size_dword ? f_dat_i[31:24] : 0); wire [7:0] od2 = (size_byte ? f_dat_i[7:0] : 0) \| (size_hword ? f_dat_i[7:0] : 0) \| (size_word ? f_dat_i[23:16] : 0) \| (size_dword ? f_dat_i[23:16] : 0); wire [7:0] od1 = (size_byte ? f_dat_i[7:0] : 0) \| (size_hword ? f_dat_i[15:8] : 0) \| (size_word ? f_dat_i[15:8] : 0) \| (size_dword ? f_dat_i[15:8] : 0); wire [7:0] od0 = f_dat_i[7:0]; assign wb_dat_o = {od7, od6, od5, od4, od3, od2, od1, od0}; // Wishbone to Furcula Data Routing wire [31:0] id2 = (wen1 ? wb_dat_i[63:32] : 0) \| (wen0 ? wb_dat_i[31:0] : 0); wire [15:0] id1 = (hen3 ? wb_dat_i[63:48] : 0) \| (hen2 ? wb_dat_i[47:32] : 0) \| (hen1 ? wb_dat_i[31:16] : 0) \| (hen0 ? wb_dat_i[15:0] : 0); wire [7:0] id0 = (ben7 ? wb_dat_i[63:56] : 0) \| (ben6 ? wb_dat_i[55:48] : 0) \| (ben5 ? wb_dat_i[47:40] : 0) \| (ben4 ? wb_dat_i[39:32] : 0) \| (ben3 ? wb_dat_i[31:24] : 0) \| (ben2 ? wb_dat_i[23:16] : 0) \| (ben1 ? wb_dat_i[15:8] : 0) \| (ben0 ? wb_dat_i[7:0] : 0); wire [63:32] id2s = (f_signed_i ? {32{id2[31]}} : 32'd0); wire [63:16] id1s = (f_signed_i ? {48{id1[15]}} : 48'd0); wire [63:8] id0s = (f_signed_i ? {56{id0[7]}} : 56'd0); assign f_dat_o = (size_dword ? wb_dat_i : 0) \| (size_word ? {id2s, id2} : 0) \| (size_hword ? {id1s, id1} : 0) \| (size_byte ? {id0s, id0} : 0); endmodule
/* File: eproto_tx.v This file is part of the Parallella Project. Copyright (C) 2014 Adapteva, Inc. Contributed by Fred Huettig <[email protected]> This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program (see the file COPYING). If not, see <http://www.gnu.org/licenses/>. / / ######################################################################## EPIPHANY eLink TX Protocol block ######################################################################## This block takes standard eMesh protocol (104-bit transactions) and encodes the bytes into 8-byte parallel outputs for the output serializers. / module eproto_tx (/AUTOARG*/ // Outputs emtx_rd_wait, emtx_wr_wait, emtx_ack, txframe_p, txdata_p, // Inputs reset, emtx_access, emtx_write, emtx_datamode, emtx_ctrlmode, emtx_dstaddr, emtx_srcaddr, emtx_data, txlclk_p, tx_rd_wait, tx_wr_wait ); // System reset input input reset; // Input from TX Arbiter input emtx_access; input emtx_write; input [1:0] emtx_datamode; input [3:0] emtx_ctrlmode; input [31:0] emtx_dstaddr; input [31:0] emtx_srcaddr; input [31:0] emtx_data; output emtx_rd_wait; output emtx_wr_wait; output emtx_ack; // Parallel interface, 8 eLink bytes at a time input txlclk_p; // Parallel-rate clock from eClock block output [7:0] txframe_p; output [63:0] txdata_p; input tx_rd_wait; // The wait signals are passed through input tx_wr_wait; // to the emesh interfaces //############# //# Configuration bits //############# //############ //# Local regs & wires //############ reg emtx_ack; // Acknowledge transaction reg [7:0] txframe_p; reg [63:0] txdata_p; //############ //# Logic //############ // TODO: Bursts always @( posedge txlclk_p or posedge reset ) begin if( reset ) begin emtx_ack <= 1'b0; txframe_p <= 'd0; txdata_p <= 'd0; end else begin if( emtx_access & ~emtx_ack ) begin emtx_ack <= 1'b1; txframe_p <= 8'h3F; txdata_p <= { 8'd0, // Not used 8'd0, ~emtx_write, 7'd0, // B0- TODO: For bursts, add the inc bit emtx_ctrlmode, emtx_dstaddr[31:28], // B1 emtx_dstaddr[27:4], // B2, B3, B4 emtx_dstaddr[3:0], emtx_datamode, emtx_write, emtx_access // B5 }; end else if( emtx_ack ) begin // if ( emtx_access & ~emtx_ack ) emtx_ack <= 1'b0; txframe_p <= 8'hFF; txdata_p <= { emtx_data, emtx_srcaddr }; end else begin emtx_ack <= 1'b0; txframe_p <= 8'h00; txdata_p <= 64'd0; end end // else: !if( reset ) end // always @ ( posedge txlclk_p or reset ) //############################# //# Wait signals //############################# reg rd_wait_sync; reg wr_wait_sync; reg emtx_rd_wait; reg emtx_wr_wait; always @( posedge txlclk_p ) begin rd_wait_sync <= tx_rd_wait; emtx_rd_wait <= rd_wait_sync; wr_wait_sync <= tx_wr_wait; emtx_wr_wait <= wr_wait_sync; end endmodule // eproto_tx
`timescale 1ns / 1ps //////////////////////////////////////////////////////////////////////////////// // Company: // Engineer: // // Create Date: 14:40:38 05/31/2011 // Design Name: main // Module Name: /home/ikari/prj/sd2snes/verilog/sd2snes/main_tf.v // Project Name: sd2snes // Target Device: // Tool versions: // Description: // // Verilog Test Fixture created by ISE for module: main // // Dependencies: // // Revision: // Revision 0.01 - File Created // Additional Comments: // //////////////////////////////////////////////////////////////////////////////// module main_tf; // Inputs reg CLKIN; reg [23:0] SNES_ADDR; reg SNES_READ; reg SNES_WRITE; reg SNES_CS; reg SNES_CPU_CLK; reg SNES_REFRESH; reg SNES_SYSCLK; reg SPI_MOSI; reg SPI_SS; reg MCU_OVR; reg [3:0] SD_DAT; // Outputs wire SNES_DATABUS_OE; wire SNES_DATABUS_DIR; wire IRQ_DIR; wire [22:0] ROM_ADDR; wire ROM_CE; wire ROM_OE; wire ROM_WE; wire ROM_BHE; wire ROM_BLE; wire [18:0] RAM_ADDR; wire RAM_CE; wire RAM_OE; wire RAM_WE; wire DAC_MCLK; wire DAC_LRCK; wire DAC_SDOUT; // Bidirs wire [7:0] SNES_DATA; wire SNES_IRQ; wire [15:0] ROM_DATA; wire [7:0] RAM_DATA; wire SPI_MISO; wire SPI_SCK; wire SD_CMD; wire SD_CLK; // Instantiate the Unit Under Test (UUT) main uut ( .CLKIN(CLKIN), .SNES_ADDR(SNES_ADDR), .SNES_READ(SNES_READ), .SNES_WRITE(SNES_WRITE), .SNES_CS(SNES_CS), .SNES_DATA(SNES_DATA), .SNES_CPU_CLK(SNES_CPU_CLK), .SNES_REFRESH(SNES_REFRESH), .SNES_IRQ(SNES_IRQ), .SNES_DATABUS_OE(SNES_DATABUS_OE), .SNES_DATABUS_DIR(SNES_DATABUS_DIR), .IRQ_DIR(IRQ_DIR), .SNES_SYSCLK(SNES_SYSCLK), .ROM_DATA(ROM_DATA), .ROM_ADDR(ROM_ADDR), .ROM_CE(ROM_CE), .ROM_OE(ROM_OE), .ROM_WE(ROM_WE), .ROM_BHE(ROM_BHE), .ROM_BLE(ROM_BLE), .RAM_DATA(RAM_DATA), .RAM_ADDR(RAM_ADDR), .RAM_CE(RAM_CE), .RAM_OE(RAM_OE), .RAM_WE(RAM_WE), .SPI_MOSI(SPI_MOSI), .SPI_MISO(SPI_MISO), .SPI_SS(SPI_SS), .SPI_SCK(SPI_SCK), .MCU_OVR(MCU_OVR), .DAC_MCLK(DAC_MCLK), .DAC_LRCK(DAC_LRCK), .DAC_SDOUT(DAC_SDOUT), .SD_DAT(SD_DAT), .SD_CMD(SD_CMD), .SD_CLK(SD_CLK) ); integer i; reg [7:0] SNES_DATA_OUT; reg [7:0] SNES_DATA_IN; assign SNES_DATA = (!SNES_READ) ? 8'bZ : SNES_DATA_IN; initial begin // Initialize Inputs CLKIN = 0; SNES_ADDR = 0; SNES_READ = 1; SNES_WRITE = 1; SNES_CS = 0; SNES_CPU_CLK = 0; SNES_REFRESH = 0; SNES_SYSCLK = 0; SPI_MOSI = 0; SPI_SS = 0; MCU_OVR = 1; SD_DAT = 0; // Wait 100 ns for global reset to finish #500; // Add stimulus here SNES_ADDR = 24'h208000; SNES_DATA_IN = 8'h1f; SNES_WRITE = 0; #100 SNES_WRITE = 1; #100; for (i = 0; i < 4096; i = i + 1) begin #140 SNES_READ = 0; SNES_CPU_CLK = 1; #140 SNES_READ = 1; SNES_CPU_CLK = 0; end end always #24 CLKIN = ~CLKIN; endmodule
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Description: Read Data Response AXI3 Slave Converter // Forwards and re-assembles split transactions. // // Verilog-standard: Verilog 2001 //-------------------------------------------------------------------------- // // Structure: // r_axi3_conv // //-------------------------------------------------------------------------- `timescale 1ps/1ps (* DowngradeIPIdentifiedWarnings="yes" *) module axi_protocol_converter_v2_1_r_axi3_conv # ( parameter C_FAMILY = "none", parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_ADDR_WIDTH = 32, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_SUPPORT_SPLITTING = 1, // Implement transaction splitting logic. // Disabled whan all connected masters are AXI3 and have same or narrower data width. parameter integer C_SUPPORT_BURSTS = 1 // Disabled when all connected masters are AxiLite, // allowing logic to be simplified. ) ( // System Signals input wire ACLK, input wire ARESET, // Command Interface input wire cmd_valid, input wire cmd_split, output wire cmd_ready, // Slave Interface Read Data Ports output wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID, output wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA, output wire [2-1:0] S_AXI_RRESP, output wire S_AXI_RLAST, output wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire S_AXI_RVALID, input wire S_AXI_RREADY, // Master Interface Read Data Ports input wire [C_AXI_ID_WIDTH-1:0] M_AXI_RID, input wire [C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA, input wire [2-1:0] M_AXI_RRESP, input wire M_AXI_RLAST, input wire [C_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER, input wire M_AXI_RVALID, output wire M_AXI_RREADY ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Constants for packing levels. localparam [2-1:0] C_RESP_OKAY = 2'b00; localparam [2-1:0] C_RESP_EXOKAY = 2'b01; localparam [2-1:0] C_RESP_SLVERROR = 2'b10; localparam [2-1:0] C_RESP_DECERR = 2'b11; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// // Throttling help signals. wire cmd_ready_i; wire pop_si_data; wire si_stalling; // Internal MI-side control signals. wire M_AXI_RREADY_I; // Internal signals for SI-side. wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID_I; wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA_I; wire [2-1:0] S_AXI_RRESP_I; wire S_AXI_RLAST_I; wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER_I; wire S_AXI_RVALID_I; wire S_AXI_RREADY_I; ///////////////////////////////////////////////////////////////////////////// // Handle interface handshaking: // // Forward data from MI-Side to SI-Side while a command is available. When // the transaction has completed the command is popped from the Command FIFO. // // ///////////////////////////////////////////////////////////////////////////// // Pop word from SI-side. assign M_AXI_RREADY_I = ~si_stalling & cmd_valid; assign M_AXI_RREADY = M_AXI_RREADY_I; // Indicate when there is data available @ SI-side. assign S_AXI_RVALID_I = M_AXI_RVALID & cmd_valid; // Get SI-side data. assign pop_si_data = S_AXI_RVALID_I & S_AXI_RREADY_I; // Signal that the command is done (so that it can be poped from command queue). assign cmd_ready_i = cmd_valid & pop_si_data & M_AXI_RLAST; assign cmd_ready = cmd_ready_i; // Detect when MI-side is stalling. assign si_stalling = S_AXI_RVALID_I & ~S_AXI_RREADY_I; ///////////////////////////////////////////////////////////////////////////// // Simple AXI signal forwarding: // // USER, ID, DATA and RRESP passes through untouched. // // LAST has to be filtered to remove any intermediate LAST (due to split // trasactions). LAST is only removed for the first parts of a split // transaction. When splitting is unsupported is the LAST filtering completely // completely removed. // ///////////////////////////////////////////////////////////////////////////// // Calculate last, i.e. mask from split transactions. assign S_AXI_RLAST_I = M_AXI_RLAST & ( ~cmd_split \| ( C_SUPPORT_SPLITTING == 0 ) ); // Data is passed through. assign S_AXI_RID_I = M_AXI_RID; assign S_AXI_RUSER_I = M_AXI_RUSER; assign S_AXI_RDATA_I = M_AXI_RDATA; assign S_AXI_RRESP_I = M_AXI_RRESP; ///////////////////////////////////////////////////////////////////////////// // SI-side output handling // ///////////////////////////////////////////////////////////////////////////// // TODO: registered? assign S_AXI_RREADY_I = S_AXI_RREADY; assign S_AXI_RVALID = S_AXI_RVALID_I; assign S_AXI_RID = S_AXI_RID_I; assign S_AXI_RDATA = S_AXI_RDATA_I; assign S_AXI_RRESP = S_AXI_RRESP_I; assign S_AXI_RLAST = S_AXI_RLAST_I; assign S_AXI_RUSER = S_AXI_RUSER_I; endmodule
/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 / `ifndef SKY130_FD_SC_LP__A32OI_BLACKBOX_V `define SKY130_FD_SC_LP__A32OI_BLACKBOX_V /* * a32oi: 3-input AND into first input, and 2-input AND into * 2nd input of 2-input NOR. * * Y = !((A1 & A2 & A3) \| (B1 & B2)) * * Verilog stub definition (black box without power pins). * * WARNING: This file is autogenerated, do not modify directly! / `timescale 1ns / 1ps `default_nettype none ( blackbox *) module sky130_fd_sc_lp__a32oi ( Y , A1, A2, A3, B1, B2 ); output Y ; input A1; input A2; input A3; input B1; input B2; // Voltage supply signals supply1 VPWR; supply0 VGND; supply1 VPB ; supply0 VNB ; endmodule `default_nettype wire `endif // SKY130_FD_SC_LP__A32OI_BLACKBOX_V
//----------------------------------------------------------------------------- //-- (c) Copyright 2010 Xilinx, Inc. All rights reserved. //-- //-- This file contains confidential and proprietary information //-- of Xilinx, Inc. and is protected under U.S. and //-- international copyright and other intellectual property //-- laws. //-- //-- DISCLAIMER //-- This disclaimer is not a license and does not grant any //-- rights to the materials distributed herewith. Except as //-- otherwise provided in a valid license issued to you by //-- Xilinx, and to the maximum extent permitted by applicable //-- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND //-- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES //-- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING //-- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- //-- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and //-- (2) Xilinx shall not be liable (whether in contract or tort, //-- including negligence, or under any other theory of //-- liability) for any loss or damage of any kind or nature //-- related to, arising under or in connection with these //-- materials, including for any direct, or any indirect, //-- special, incidental, or consequential loss or damage //-- (including loss of data, profits, goodwill, or any type of //-- loss or damage suffered as a result of any action brought //-- by a third party) even if such damage or loss was //-- reasonably foreseeable or Xilinx had been advised of the //-- possibility of the same. //-- //-- CRITICAL APPLICATIONS //-- Xilinx products are not designed or intended to be fail- //-- safe, or for use in any application requiring fail-safe //-- performance, such as life-support or safety devices or //-- systems, Class III medical devices, nuclear facilities, //-- applications related to the deployment of airbags, or any //-- other applications that could lead to death, personal //-- injury, or severe property or environmental damage //-- (individually and collectively, "Critical //-- Applications"). Customer assumes the sole risk and //-- liability of any use of Xilinx products in Critical //-- Applications, subject only to applicable laws and //-- regulations governing limitations on product liability. //-- //-- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS //-- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Description: Up-Sizer // Up-Sizer for generic SI- and MI-side data widths. This module instantiates // Address, Write Data and Read Data Up-Sizer modules, each one taking care // of the channel specific tasks. // The Address Up-Sizer can handle both AR and AW channels. // // Verilog-standard: Verilog 2001 //-------------------------------------------------------------------------- // // Structure: // axi_upsizer // a_upsizer // fifo // fifo_gen // fifo_coregen // w_upsizer // r_upsizer // //-------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none (* DowngradeIPIdentifiedWarnings="yes" ) module axi_dwidth_converter_v2_1_axi_upsizer # ( parameter C_FAMILY = "virtex7", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_AXI_PROTOCOL = 0, // Protocol of SI and MI (0=AXI4, 1=AXI3). parameter integer C_S_AXI_ID_WIDTH = 1, // Width of all ID signals on SI side of converter. // Range: 1 - 32. parameter integer C_SUPPORTS_ID = 0, // Indicates whether SI-side ID needs to be stored and compared. // 0 = No, SI is single-threaded, propagate all transactions. // 1 = Yes, stall any transaction with ID different than outstanding transactions. parameter integer C_AXI_ADDR_WIDTH = 32, // Width of all ADDR signals on SI and MI. // Range (AXI4, AXI3): 12 - 64. parameter integer C_S_AXI_DATA_WIDTH = 32, // Width of s_axi_wdata and s_axi_rdata. // Range: 32, 64, 128, 256, 512, 1024. parameter integer C_M_AXI_DATA_WIDTH = 64, // Width of m_axi_wdata and m_axi_rdata. // Assume always >= than C_S_AXI_DATA_WIDTH. // Range: 32, 64, 128, 256, 512, 1024. parameter integer C_AXI_SUPPORTS_WRITE = 1, parameter integer C_AXI_SUPPORTS_READ = 1, /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // parameter integer C_FIFO_MODE = 0, parameter integer C_FIFO_MODE = 1, // 0=None, 1=Packet_FIFO, 2=Clock_conversion_Packet_FIFO, 3=Simple_FIFO (FUTURE), 4=Clock_conversion_Simple_FIFO (FUTURE) parameter integer C_S_AXI_ACLK_RATIO = 1, // Clock frequency ratio of SI w.r.t. MI. // Range = [1..16]. parameter integer C_M_AXI_ACLK_RATIO = 2, // Clock frequency ratio of MI w.r.t. SI. // Range = [2..16] if C_S_AXI_ACLK_RATIO = 1; else must be 1. parameter integer C_AXI_IS_ACLK_ASYNC = 0, // Indicates whether S and M clocks are asynchronous. // FUTURE FEATURE // Range = [0, 1]. parameter integer C_PACKING_LEVEL = 1, // 0 = Never pack (expander only); packing logic is omitted. // 1 = Pack only when CACHE[1] (Modifiable) is high. // 2 = Always pack, regardless of sub-size transaction or Modifiable bit. // (Required when used as helper-core by mem-con. Same size AXI interfaces // should only be used when always packing) parameter integer C_SYNCHRONIZER_STAGE = 3 ) ( // Slave Interface input wire s_axi_aresetn, input wire s_axi_aclk, // Slave Interface Write Address Ports input wire [C_S_AXI_ID_WIDTH-1:0] s_axi_awid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr, input wire [8-1:0] s_axi_awlen, input wire [3-1:0] s_axi_awsize, input wire [2-1:0] s_axi_awburst, input wire [2-1:0] s_axi_awlock, input wire [4-1:0] s_axi_awcache, input wire [3-1:0] s_axi_awprot, input wire [4-1:0] s_axi_awregion, input wire [4-1:0] s_axi_awqos, input wire s_axi_awvalid, output wire s_axi_awready, // Slave Interface Write Data Ports input wire [C_S_AXI_DATA_WIDTH-1:0] s_axi_wdata, input wire [C_S_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb, input wire s_axi_wlast, input wire s_axi_wvalid, output wire s_axi_wready, // Slave Interface Write Response Ports output wire [C_S_AXI_ID_WIDTH-1:0] s_axi_bid, output wire [2-1:0] s_axi_bresp, output wire s_axi_bvalid, input wire s_axi_bready, // Slave Interface Read Address Ports input wire [C_S_AXI_ID_WIDTH-1:0] s_axi_arid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr, input wire [8-1:0] s_axi_arlen, input wire [3-1:0] s_axi_arsize, input wire [2-1:0] s_axi_arburst, input wire [2-1:0] s_axi_arlock, input wire [4-1:0] s_axi_arcache, input wire [3-1:0] s_axi_arprot, input wire [4-1:0] s_axi_arregion, input wire [4-1:0] s_axi_arqos, input wire s_axi_arvalid, output wire s_axi_arready, // Slave Interface Read Data Ports output wire [C_S_AXI_ID_WIDTH-1:0] s_axi_rid, output wire [C_S_AXI_DATA_WIDTH-1:0] s_axi_rdata, output wire [2-1:0] s_axi_rresp, output wire s_axi_rlast, output wire s_axi_rvalid, input wire s_axi_rready, // Master Interface input wire m_axi_aresetn, input wire m_axi_aclk, // Master Interface Write Address Port output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr, output wire [8-1:0] m_axi_awlen, output wire [3-1:0] m_axi_awsize, output wire [2-1:0] m_axi_awburst, output wire [2-1:0] m_axi_awlock, output wire [4-1:0] m_axi_awcache, output wire [3-1:0] m_axi_awprot, output wire [4-1:0] m_axi_awregion, output wire [4-1:0] m_axi_awqos, output wire m_axi_awvalid, input wire m_axi_awready, // Master Interface Write Data Ports output wire [C_M_AXI_DATA_WIDTH-1:0] m_axi_wdata, output wire [C_M_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb, output wire m_axi_wlast, output wire m_axi_wvalid, input wire m_axi_wready, // Master Interface Write Response Ports input wire [2-1:0] m_axi_bresp, input wire m_axi_bvalid, output wire m_axi_bready, // Master Interface Read Address Port output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr, output wire [8-1:0] m_axi_arlen, output wire [3-1:0] m_axi_arsize, output wire [2-1:0] m_axi_arburst, output wire [2-1:0] m_axi_arlock, output wire [4-1:0] m_axi_arcache, output wire [3-1:0] m_axi_arprot, output wire [4-1:0] m_axi_arregion, output wire [4-1:0] m_axi_arqos, output wire m_axi_arvalid, input wire m_axi_arready, // Master Interface Read Data Ports input wire [C_M_AXI_DATA_WIDTH-1:0] m_axi_rdata, input wire [2-1:0] m_axi_rresp, input wire m_axi_rlast, input wire m_axi_rvalid, output wire m_axi_rready ); // Log2 of number of 32bit word on SI-side. localparam integer C_S_AXI_BYTES_LOG = log2(C_S_AXI_DATA_WIDTH/8); // Log2 of number of 32bit word on MI-side. localparam integer C_M_AXI_BYTES_LOG = log2(C_M_AXI_DATA_WIDTH/8); // Log2 of Up-Sizing ratio for data. localparam integer C_RATIO = C_M_AXI_DATA_WIDTH / C_S_AXI_DATA_WIDTH; localparam integer C_RATIO_LOG = log2(C_RATIO); localparam P_BYPASS = 32'h0; localparam P_LIGHTWT = 32'h7; localparam P_FWD_REV = 32'h1; localparam integer P_CONV_LIGHT_WT = 0; localparam integer P_AXI4 = 0; localparam integer C_FIFO_DEPTH_LOG = 5; localparam P_SI_LT_MI = (C_S_AXI_ACLK_RATIO < C_M_AXI_ACLK_RATIO); localparam integer P_ACLK_RATIO = P_SI_LT_MI ? (C_M_AXI_ACLK_RATIO / C_S_AXI_ACLK_RATIO) : (C_S_AXI_ACLK_RATIO / C_M_AXI_ACLK_RATIO); localparam integer P_NO_FIFO = 0; localparam integer P_PKTFIFO = 1; localparam integer P_PKTFIFO_CLK = 2; localparam integer P_DATAFIFO = 3; localparam integer P_DATAFIFO_CLK = 4; localparam P_CLK_CONV = ((C_FIFO_MODE == P_PKTFIFO_CLK) \|\| (C_FIFO_MODE == P_DATAFIFO_CLK)); localparam integer C_M_AXI_AW_REGISTER = 0; // Simple register AW output. // Range: 0, 1 localparam integer C_M_AXI_W_REGISTER = 1; // Parameter not used; W reg always implemented. localparam integer C_M_AXI_AR_REGISTER = 0; // Simple register AR output. // Range: 0, 1 localparam integer C_S_AXI_R_REGISTER = 0; // Simple register R output (SI). // Range: 0, 1 localparam integer C_M_AXI_R_REGISTER = 1; // Register slice on R input (MI) side. // 0 = Bypass (not recommended due to combinatorial M_RVALID -> M_RREADY path) // 1 = Fully-registered (needed only when upsizer propagates bursts at 1:1 width ratio) // 7 = Light-weight (safe when upsizer always packs at 1:n width ratio, as in interconnect) localparam integer P_RID_QUEUE = ((C_SUPPORTS_ID != 0) && !((C_FIFO_MODE == P_PKTFIFO) \|\| (C_FIFO_MODE == P_PKTFIFO_CLK))) ? 1 : 0; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// // Log2. function integer log2 ( input integer x ); integer acc; begin acc=0; while ((2*acc) < x) acc = acc + 1; log2 = acc; end endfunction ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire aclk; wire m_aclk; wire sample_cycle; wire sample_cycle_early; wire sm_aresetn; wire s_aresetn_i; wire [C_S_AXI_ID_WIDTH-1:0] sr_awid ; wire [C_AXI_ADDR_WIDTH-1:0] sr_awaddr ; wire [8-1:0] sr_awlen ; wire [3-1:0] sr_awsize ; wire [2-1:0] sr_awburst ; wire [2-1:0] sr_awlock ; wire [4-1:0] sr_awcache ; wire [3-1:0] sr_awprot ; wire [4-1:0] sr_awregion ; wire [4-1:0] sr_awqos ; wire sr_awvalid ; wire sr_awready ; wire [C_S_AXI_ID_WIDTH-1:0] sr_arid ; wire [C_AXI_ADDR_WIDTH-1:0] sr_araddr ; wire [8-1:0] sr_arlen ; wire [3-1:0] sr_arsize ; wire [2-1:0] sr_arburst ; wire [2-1:0] sr_arlock ; wire [4-1:0] sr_arcache ; wire [3-1:0] sr_arprot ; wire [4-1:0] sr_arregion ; wire [4-1:0] sr_arqos ; wire sr_arvalid ; wire sr_arready ; wire [C_S_AXI_DATA_WIDTH-1:0] sr_wdata ; wire [(C_S_AXI_DATA_WIDTH/8)-1:0] sr_wstrb ; wire sr_wlast ; wire sr_wvalid ; wire sr_wready ; wire [C_M_AXI_DATA_WIDTH-1:0] mr_rdata ; wire [2-1:0] mr_rresp ; wire mr_rlast ; wire mr_rvalid ; wire mr_rready ; wire m_axi_rready_i; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_awlen_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_arlen_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_awlock_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_arlock_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_awlen_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_arlen_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_awlock_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_arlock_ii ; wire [3:0] s_axi_awregion_ii; wire [3:0] s_axi_arregion_ii; assign s_axi_awlen_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlen : s_axi_awlen[3:0]; assign s_axi_awlock_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlock[0] : s_axi_awlock; assign s_axi_arlen_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlen : s_axi_arlen[3:0]; assign s_axi_arlock_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlock[0] : s_axi_arlock; assign sr_awlen = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlen_ii: {4'b0, s_axi_awlen_ii}; assign sr_awlock = (C_AXI_PROTOCOL == P_AXI4) ? {1'b0, s_axi_awlock_ii} : s_axi_awlock_ii; assign sr_arlen = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlen_ii: {4'b0, s_axi_arlen_ii}; assign sr_arlock = (C_AXI_PROTOCOL == P_AXI4) ? {1'b0, s_axi_arlock_ii} : s_axi_arlock_ii; assign sr_awregion = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awregion_ii : 4'b0; assign sr_arregion = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arregion_ii : 4'b0; assign aclk = s_axi_aclk; assign sm_aresetn = s_axi_aresetn & m_axi_aresetn; generate if (P_CLK_CONV) begin : gen_clock_conv if (C_AXI_IS_ACLK_ASYNC) begin : gen_async_conv assign m_aclk = m_axi_aclk; assign s_aresetn_i = s_axi_aresetn; assign sample_cycle_early = 1'b1; assign sample_cycle = 1'b1; end else begin : gen_sync_conv wire fast_aclk; wire slow_aclk; reg s_aresetn_r; if (P_SI_LT_MI) begin : gen_fastclk_mi assign fast_aclk = m_axi_aclk; assign slow_aclk = s_axi_aclk; end else begin : gen_fastclk_si assign fast_aclk = s_axi_aclk; assign slow_aclk = m_axi_aclk; end assign m_aclk = m_axi_aclk; assign s_aresetn_i = s_aresetn_r; always @(negedge sm_aresetn, posedge fast_aclk) begin if (~sm_aresetn) begin s_aresetn_r <= 1'b0; end else if (s_axi_aresetn & m_axi_aresetn & sample_cycle_early) begin s_aresetn_r <= 1'b1; end end // Sample cycle used to determine when to assert a signal on a fast clock // to be flopped onto a slow clock. axi_clock_converter_v2_1_axic_sample_cycle_ratio #( .C_RATIO ( P_ACLK_RATIO ) ) axic_sample_cycle_inst ( .SLOW_ACLK ( slow_aclk ) , .FAST_ACLK ( fast_aclk ) , .SAMPLE_CYCLE_EARLY ( sample_cycle_early ) , .SAMPLE_CYCLE ( sample_cycle ) ); end end else begin : gen_no_clk_conv assign m_aclk = s_axi_aclk; assign s_aresetn_i = s_axi_aresetn; assign sample_cycle_early = 1'b1; assign sample_cycle = 1'b1; end // gen_clock_conv axi_register_slice_v2_1_axi_register_slice # ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (0), .C_REG_CONFIG_AW (C_AXI_SUPPORTS_WRITE ? P_LIGHTWT : P_BYPASS), .C_REG_CONFIG_AR (C_AXI_SUPPORTS_READ ? P_LIGHTWT : P_BYPASS) ) si_register_slice_inst ( .aresetn (s_aresetn_i), .aclk (aclk), .s_axi_awid (s_axi_awid ), .s_axi_awaddr (s_axi_awaddr ), .s_axi_awlen (s_axi_awlen_i ), .s_axi_awsize (s_axi_awsize ), .s_axi_awburst (s_axi_awburst ), .s_axi_awlock (s_axi_awlock_i ), .s_axi_awcache (s_axi_awcache ), .s_axi_awprot (s_axi_awprot ), .s_axi_awregion (s_axi_awregion ), .s_axi_awqos (s_axi_awqos ), .s_axi_awuser (1'b0 ), .s_axi_awvalid (s_axi_awvalid ), .s_axi_awready (s_axi_awready ), .s_axi_wid ( {C_S_AXI_ID_WIDTH{1'b0}}), .s_axi_wdata ( {C_S_AXI_DATA_WIDTH{1'b0}} ), .s_axi_wstrb ( {C_S_AXI_DATA_WIDTH/8{1'b0}} ), .s_axi_wlast ( 1'b0 ), .s_axi_wuser ( 1'b0 ), .s_axi_wvalid ( 1'b0 ), .s_axi_wready ( ), .s_axi_bid ( ), .s_axi_bresp ( ), .s_axi_buser ( ), .s_axi_bvalid ( ), .s_axi_bready ( 1'b0 ), .s_axi_arid (s_axi_arid ), .s_axi_araddr (s_axi_araddr ), .s_axi_arlen (s_axi_arlen_i ), .s_axi_arsize (s_axi_arsize ), .s_axi_arburst (s_axi_arburst ), .s_axi_arlock (s_axi_arlock_i ), .s_axi_arcache (s_axi_arcache ), .s_axi_arprot (s_axi_arprot ), .s_axi_arregion (s_axi_arregion ), .s_axi_arqos (s_axi_arqos ), .s_axi_aruser (1'b0 ), .s_axi_arvalid (s_axi_arvalid ), .s_axi_arready (s_axi_arready ), .s_axi_rid ( ) , .s_axi_rdata ( ) , .s_axi_rresp ( ) , .s_axi_rlast ( ) , .s_axi_ruser ( ) , .s_axi_rvalid ( ) , .s_axi_rready ( 1'b0 ) , .m_axi_awid (sr_awid ), .m_axi_awaddr (sr_awaddr ), .m_axi_awlen (s_axi_awlen_ii), .m_axi_awsize (sr_awsize ), .m_axi_awburst (sr_awburst ), .m_axi_awlock (s_axi_awlock_ii), .m_axi_awcache (sr_awcache ), .m_axi_awprot (sr_awprot ), .m_axi_awregion (s_axi_awregion_ii ), .m_axi_awqos (sr_awqos ), .m_axi_awuser (), .m_axi_awvalid (sr_awvalid ), .m_axi_awready (sr_awready ), .m_axi_wid () , .m_axi_wdata (), .m_axi_wstrb (), .m_axi_wlast (), .m_axi_wuser (), .m_axi_wvalid (), .m_axi_wready (1'b0), .m_axi_bid ( {C_S_AXI_ID_WIDTH{1'b0}} ) , .m_axi_bresp ( 2'b0 ) , .m_axi_buser ( 1'b0 ) , .m_axi_bvalid ( 1'b0 ) , .m_axi_bready ( ) , .m_axi_arid (sr_arid ), .m_axi_araddr (sr_araddr ), .m_axi_arlen (s_axi_arlen_ii), .m_axi_arsize (sr_arsize ), .m_axi_arburst (sr_arburst ), .m_axi_arlock (s_axi_arlock_ii), .m_axi_arcache (sr_arcache ), .m_axi_arprot (sr_arprot ), .m_axi_arregion (s_axi_arregion_ii ), .m_axi_arqos (sr_arqos ), .m_axi_aruser (), .m_axi_arvalid (sr_arvalid ), .m_axi_arready (sr_arready ), .m_axi_rid ( {C_S_AXI_ID_WIDTH{1'b0}}), .m_axi_rdata ( {C_S_AXI_DATA_WIDTH{1'b0}} ), .m_axi_rresp ( 2'b00 ), .m_axi_rlast ( 1'b0 ), .m_axi_ruser ( 1'b0 ), .m_axi_rvalid ( 1'b0 ), .m_axi_rready ( ) ); ///////////////////////////////////////////////////////////////////////////// // Handle Write Channels (AW/W/B) ///////////////////////////////////////////////////////////////////////////// if (C_AXI_SUPPORTS_WRITE == 1) begin : USE_WRITE wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr_i ; wire [8-1:0] m_axi_awlen_i ; wire [3-1:0] m_axi_awsize_i ; wire [2-1:0] m_axi_awburst_i ; wire [2-1:0] m_axi_awlock_i ; wire [4-1:0] m_axi_awcache_i ; wire [3-1:0] m_axi_awprot_i ; wire [4-1:0] m_axi_awregion_i ; wire [4-1:0] m_axi_awqos_i ; wire m_axi_awvalid_i ; wire m_axi_awready_i ; wire s_axi_bvalid_i ; wire [2-1:0] s_axi_bresp_i ; wire [C_AXI_ADDR_WIDTH-1:0] wr_cmd_si_addr; wire [8-1:0] wr_cmd_si_len; wire [3-1:0] wr_cmd_si_size; wire [2-1:0] wr_cmd_si_burst; // Write Channel Signals for Commands Queue Interface. wire wr_cmd_valid; wire wr_cmd_fix; wire wr_cmd_modified; wire wr_cmd_complete_wrap; wire wr_cmd_packed_wrap; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_first_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_next_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_last_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_offset; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_mask; wire [C_S_AXI_BYTES_LOG:0] wr_cmd_step; wire [8-1:0] wr_cmd_length; wire wr_cmd_ready; wire wr_cmd_id_ready; wire [C_S_AXI_ID_WIDTH-1:0] wr_cmd_id; wire wpush; wire wpop; reg [C_FIFO_DEPTH_LOG-1:0] wcnt; // Write Address Channel. axi_dwidth_converter_v2_1_a_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_SUPPORTS_ID (C_SUPPORTS_ID), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (C_M_AXI_AW_REGISTER), .C_AXI_CHANNEL (0), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_FIFO_MODE (C_FIFO_MODE), .C_ID_QUEUE (C_SUPPORTS_ID), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG) ) write_addr_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (wr_cmd_valid), .cmd_fix (wr_cmd_fix), .cmd_modified (wr_cmd_modified), .cmd_complete_wrap (wr_cmd_complete_wrap), .cmd_packed_wrap (wr_cmd_packed_wrap), .cmd_first_word (wr_cmd_first_word), .cmd_next_word (wr_cmd_next_word), .cmd_last_word (wr_cmd_last_word), .cmd_offset (wr_cmd_offset), .cmd_mask (wr_cmd_mask), .cmd_step (wr_cmd_step), .cmd_length (wr_cmd_length), .cmd_ready (wr_cmd_ready), .cmd_id (wr_cmd_id), .cmd_id_ready (wr_cmd_id_ready), .cmd_si_addr (wr_cmd_si_addr ), .cmd_si_id (), .cmd_si_len (wr_cmd_si_len ), .cmd_si_size (wr_cmd_si_size ), .cmd_si_burst (wr_cmd_si_burst), // Slave Interface Write Address Ports .S_AXI_AID (sr_awid), .S_AXI_AADDR (sr_awaddr), .S_AXI_ALEN (sr_awlen), .S_AXI_ASIZE (sr_awsize), .S_AXI_ABURST (sr_awburst), .S_AXI_ALOCK (sr_awlock), .S_AXI_ACACHE (sr_awcache), .S_AXI_APROT (sr_awprot), .S_AXI_AREGION (sr_awregion), .S_AXI_AQOS (sr_awqos), .S_AXI_AVALID (sr_awvalid), .S_AXI_AREADY (sr_awready), // Master Interface Write Address Port .M_AXI_AADDR (m_axi_awaddr_i ), .M_AXI_ALEN (m_axi_awlen_i ), .M_AXI_ASIZE (m_axi_awsize_i ), .M_AXI_ABURST (m_axi_awburst_i ), .M_AXI_ALOCK (m_axi_awlock_i ), .M_AXI_ACACHE (m_axi_awcache_i ), .M_AXI_APROT (m_axi_awprot_i ), .M_AXI_AREGION (m_axi_awregion_i ), .M_AXI_AQOS (m_axi_awqos_i ), .M_AXI_AVALID (m_axi_awvalid_i ), .M_AXI_AREADY (m_axi_awready_i ) ); if ((C_FIFO_MODE == P_PKTFIFO) \|\| (C_FIFO_MODE == P_PKTFIFO_CLK)) begin : gen_pktfifo_w_upsizer // Packet FIFO Write Data channel. axi_dwidth_converter_v2_1_w_upsizer_pktfifo # ( .C_FAMILY (C_FAMILY), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG), .C_CLK_CONV (P_CLK_CONV), .C_S_AXI_ACLK_RATIO (C_S_AXI_ACLK_RATIO), .C_M_AXI_ACLK_RATIO (C_M_AXI_ACLK_RATIO), .C_AXI_IS_ACLK_ASYNC (C_AXI_IS_ACLK_ASYNC), .C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE) ) pktfifo_write_data_inst ( .S_AXI_ARESETN ( s_axi_aresetn ) , .S_AXI_ACLK ( s_axi_aclk ) , .M_AXI_ARESETN ( m_axi_aresetn ) , .M_AXI_ACLK ( m_axi_aclk ) , // Command Interface .cmd_si_addr (wr_cmd_si_addr ), .cmd_si_len (wr_cmd_si_len ), .cmd_si_size (wr_cmd_si_size ), .cmd_si_burst (wr_cmd_si_burst), .cmd_ready (wr_cmd_ready), // Slave Interface Write Address Ports .S_AXI_AWADDR (m_axi_awaddr_i ), .S_AXI_AWLEN (m_axi_awlen_i ), .S_AXI_AWSIZE (m_axi_awsize_i ), .S_AXI_AWBURST (m_axi_awburst_i ), .S_AXI_AWLOCK (m_axi_awlock_i ), .S_AXI_AWCACHE (m_axi_awcache_i ), .S_AXI_AWPROT (m_axi_awprot_i ), .S_AXI_AWREGION (m_axi_awregion_i ), .S_AXI_AWQOS (m_axi_awqos_i ), .S_AXI_AWVALID (m_axi_awvalid_i ), .S_AXI_AWREADY (m_axi_awready_i ), // Master Interface Write Address Port .M_AXI_AWADDR (m_axi_awaddr), .M_AXI_AWLEN (m_axi_awlen), .M_AXI_AWSIZE (m_axi_awsize), .M_AXI_AWBURST (m_axi_awburst), .M_AXI_AWLOCK (m_axi_awlock), .M_AXI_AWCACHE (m_axi_awcache), .M_AXI_AWPROT (m_axi_awprot), .M_AXI_AWREGION (m_axi_awregion), .M_AXI_AWQOS (m_axi_awqos), .M_AXI_AWVALID (m_axi_awvalid), .M_AXI_AWREADY (m_axi_awready), // Slave Interface Write Data Ports .S_AXI_WDATA (s_axi_wdata), .S_AXI_WSTRB (s_axi_wstrb), .S_AXI_WLAST (s_axi_wlast), .S_AXI_WVALID (s_axi_wvalid), .S_AXI_WREADY (s_axi_wready), // Master Interface Write Data Ports .M_AXI_WDATA (m_axi_wdata), .M_AXI_WSTRB (m_axi_wstrb), .M_AXI_WLAST (m_axi_wlast), .M_AXI_WVALID (m_axi_wvalid), .M_AXI_WREADY (m_axi_wready), .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early) ); end else begin : gen_non_fifo_w_upsizer // Write Data channel. axi_dwidth_converter_v2_1_w_upsizer # ( .C_FAMILY ("rtl"), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (1), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG) ) write_data_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (wr_cmd_valid), .cmd_fix (wr_cmd_fix), .cmd_modified (wr_cmd_modified), .cmd_complete_wrap (wr_cmd_complete_wrap), .cmd_packed_wrap (wr_cmd_packed_wrap), .cmd_first_word (wr_cmd_first_word), .cmd_next_word (wr_cmd_next_word), .cmd_last_word (wr_cmd_last_word), .cmd_offset (wr_cmd_offset), .cmd_mask (wr_cmd_mask), .cmd_step (wr_cmd_step), .cmd_length (wr_cmd_length), .cmd_ready (wr_cmd_ready), // Slave Interface Write Data Ports .S_AXI_WDATA (s_axi_wdata), .S_AXI_WSTRB (s_axi_wstrb), .S_AXI_WLAST (s_axi_wlast), .S_AXI_WVALID (s_axi_wvalid), .S_AXI_WREADY (s_axi_wready), // Master Interface Write Data Ports .M_AXI_WDATA (m_axi_wdata), .M_AXI_WSTRB (m_axi_wstrb), .M_AXI_WLAST (m_axi_wlast), .M_AXI_WVALID (m_axi_wvalid), .M_AXI_WREADY (m_axi_wready) ); assign m_axi_awaddr = m_axi_awaddr_i ; assign m_axi_awlen = m_axi_awlen_i ; assign m_axi_awsize = m_axi_awsize_i ; assign m_axi_awburst = m_axi_awburst_i ; assign m_axi_awlock = m_axi_awlock_i ; assign m_axi_awcache = m_axi_awcache_i ; assign m_axi_awprot = m_axi_awprot_i ; assign m_axi_awregion = m_axi_awregion_i ; assign m_axi_awqos = m_axi_awqos_i ; assign m_axi_awvalid = m_axi_awvalid_i ; assign m_axi_awready_i = m_axi_awready ; end // gen_w_upsizer // Write Response channel. assign wr_cmd_id_ready = s_axi_bvalid_i & s_axi_bready; assign s_axi_bid = wr_cmd_id; assign s_axi_bresp = s_axi_bresp_i; assign s_axi_bvalid = s_axi_bvalid_i; if (P_CLK_CONV) begin : gen_b_clk_conv if (C_AXI_IS_ACLK_ASYNC == 0) begin : gen_b_sync_conv axi_clock_converter_v2_1_axic_sync_clock_converter #( .C_FAMILY ( C_FAMILY ) , .C_PAYLOAD_WIDTH ( 2 ) , .C_M_ACLK_RATIO ( P_SI_LT_MI ? 1 : P_ACLK_RATIO ) , .C_S_ACLK_RATIO ( P_SI_LT_MI ? P_ACLK_RATIO : 1 ) , .C_MODE(P_CONV_LIGHT_WT) ) b_sync_clock_converter ( .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early), .S_ACLK ( m_axi_aclk ) , .S_ARESETN ( m_axi_aresetn ) , .S_PAYLOAD ( m_axi_bresp ) , .S_VALID ( m_axi_bvalid ) , .S_READY ( m_axi_bready ) , .M_ACLK ( s_axi_aclk ) , .M_ARESETN ( s_axi_aresetn ) , .M_PAYLOAD ( s_axi_bresp_i ) , .M_VALID ( s_axi_bvalid_i ) , .M_READY ( s_axi_bready ) ); end else begin : gen_b_async_conv fifo_generator_v12_0 #( .C_COMMON_CLOCK(0), .C_SYNCHRONIZER_STAGE(C_SYNCHRONIZER_STAGE), .C_INTERFACE_TYPE(2), .C_AXI_TYPE(1), .C_HAS_AXI_ID(1), .C_AXI_LEN_WIDTH(8), .C_AXI_LOCK_WIDTH(2), .C_DIN_WIDTH_WACH(63), .C_DIN_WIDTH_WDCH(38), .C_DIN_WIDTH_WRCH(3), .C_DIN_WIDTH_RACH(63), .C_DIN_WIDTH_RDCH(36), .C_COUNT_TYPE(0), .C_DATA_COUNT_WIDTH(10), .C_DEFAULT_VALUE("BlankString"), .C_DIN_WIDTH(18), .C_DOUT_RST_VAL("0"), .C_DOUT_WIDTH(18), .C_ENABLE_RLOCS(0), .C_FAMILY(C_FAMILY), .C_FULL_FLAGS_RST_VAL(1), .C_HAS_ALMOST_EMPTY(0), .C_HAS_ALMOST_FULL(0), .C_HAS_BACKUP(0), .C_HAS_DATA_COUNT(0), .C_HAS_INT_CLK(0), .C_HAS_MEMINIT_FILE(0), .C_HAS_OVERFLOW(0), .C_HAS_RD_DATA_COUNT(0), .C_HAS_RD_RST(0), .C_HAS_RST(1), .C_HAS_SRST(0), .C_HAS_UNDERFLOW(0), .C_HAS_VALID(0), .C_HAS_WR_ACK(0), .C_HAS_WR_DATA_COUNT(0), .C_HAS_WR_RST(0), .C_IMPLEMENTATION_TYPE(0), .C_INIT_WR_PNTR_VAL(0), .C_MEMORY_TYPE(1), .C_MIF_FILE_NAME("BlankString"), .C_OPTIMIZATION_MODE(0), .C_OVERFLOW_LOW(0), .C_PRELOAD_LATENCY(1), .C_PRELOAD_REGS(0), .C_PRIM_FIFO_TYPE("4kx4"), .C_PROG_EMPTY_THRESH_ASSERT_VAL(2), .C_PROG_EMPTY_THRESH_NEGATE_VAL(3), .C_PROG_EMPTY_TYPE(0), .C_PROG_FULL_THRESH_ASSERT_VAL(1022), .C_PROG_FULL_THRESH_NEGATE_VAL(1021), .C_PROG_FULL_TYPE(0), .C_RD_DATA_COUNT_WIDTH(10), .C_RD_DEPTH(1024), .C_RD_FREQ(1), .C_RD_PNTR_WIDTH(10), .C_UNDERFLOW_LOW(0), .C_USE_DOUT_RST(1), .C_USE_ECC(0), .C_USE_EMBEDDED_REG(0), .C_USE_FIFO16_FLAGS(0), .C_USE_FWFT_DATA_COUNT(0), .C_VALID_LOW(0), .C_WR_ACK_LOW(0), .C_WR_DATA_COUNT_WIDTH(10), .C_WR_DEPTH(1024), .C_WR_FREQ(1), .C_WR_PNTR_WIDTH(10), .C_WR_RESPONSE_LATENCY(1), .C_MSGON_VAL(1), .C_ENABLE_RST_SYNC(1), .C_ERROR_INJECTION_TYPE(0), .C_HAS_AXI_WR_CHANNEL(1), .C_HAS_AXI_RD_CHANNEL(0), .C_HAS_SLAVE_CE(0), .C_HAS_MASTER_CE(0), .C_ADD_NGC_CONSTRAINT(0), .C_USE_COMMON_OVERFLOW(0), .C_USE_COMMON_UNDERFLOW(0), .C_USE_DEFAULT_SETTINGS(0), .C_AXI_ID_WIDTH(1), .C_AXI_ADDR_WIDTH(32), .C_AXI_DATA_WIDTH(32), .C_HAS_AXI_AWUSER(0), .C_HAS_AXI_WUSER(0), .C_HAS_AXI_BUSER(0), .C_HAS_AXI_ARUSER(0), .C_HAS_AXI_RUSER(0), .C_AXI_ARUSER_WIDTH(1), .C_AXI_AWUSER_WIDTH(1), .C_AXI_WUSER_WIDTH(1), .C_AXI_BUSER_WIDTH(1), .C_AXI_RUSER_WIDTH(1), .C_HAS_AXIS_TDATA(0), .C_HAS_AXIS_TID(0), .C_HAS_AXIS_TDEST(0), .C_HAS_AXIS_TUSER(0), .C_HAS_AXIS_TREADY(1), .C_HAS_AXIS_TLAST(0), .C_HAS_AXIS_TSTRB(0), .C_HAS_AXIS_TKEEP(0), .C_AXIS_TDATA_WIDTH(64), .C_AXIS_TID_WIDTH(8), .C_AXIS_TDEST_WIDTH(4), .C_AXIS_TUSER_WIDTH(4), .C_AXIS_TSTRB_WIDTH(4), .C_AXIS_TKEEP_WIDTH(4), .C_WACH_TYPE(2), .C_WDCH_TYPE(2), .C_WRCH_TYPE(0), .C_RACH_TYPE(0), .C_RDCH_TYPE(0), .C_AXIS_TYPE(0), .C_IMPLEMENTATION_TYPE_WACH(12), .C_IMPLEMENTATION_TYPE_WDCH(11), .C_IMPLEMENTATION_TYPE_WRCH(12), .C_IMPLEMENTATION_TYPE_RACH(12), .C_IMPLEMENTATION_TYPE_RDCH(11), .C_IMPLEMENTATION_TYPE_AXIS(11), .C_APPLICATION_TYPE_WACH(0), .C_APPLICATION_TYPE_WDCH(0), .C_APPLICATION_TYPE_WRCH(0), .C_APPLICATION_TYPE_RACH(0), .C_APPLICATION_TYPE_RDCH(0), .C_APPLICATION_TYPE_AXIS(0), .C_USE_ECC_WACH(0), .C_USE_ECC_WDCH(0), .C_USE_ECC_WRCH(0), .C_USE_ECC_RACH(0), .C_USE_ECC_RDCH(0), .C_USE_ECC_AXIS(0), .C_ERROR_INJECTION_TYPE_WACH(0), .C_ERROR_INJECTION_TYPE_WDCH(0), .C_ERROR_INJECTION_TYPE_WRCH(0), .C_ERROR_INJECTION_TYPE_RACH(0), .C_ERROR_INJECTION_TYPE_RDCH(0), .C_ERROR_INJECTION_TYPE_AXIS(0), .C_DIN_WIDTH_AXIS(1), .C_WR_DEPTH_WACH(16), .C_WR_DEPTH_WDCH(1024), .C_WR_DEPTH_WRCH(32), .C_WR_DEPTH_RACH(16), .C_WR_DEPTH_RDCH(1024), .C_WR_DEPTH_AXIS(1024), .C_WR_PNTR_WIDTH_WACH(4), .C_WR_PNTR_WIDTH_WDCH(10), .C_WR_PNTR_WIDTH_WRCH(5), .C_WR_PNTR_WIDTH_RACH(4), .C_WR_PNTR_WIDTH_RDCH(10), .C_WR_PNTR_WIDTH_AXIS(10), .C_HAS_DATA_COUNTS_WACH(0), .C_HAS_DATA_COUNTS_WDCH(0), .C_HAS_DATA_COUNTS_WRCH(0), .C_HAS_DATA_COUNTS_RACH(0), .C_HAS_DATA_COUNTS_RDCH(0), .C_HAS_DATA_COUNTS_AXIS(0), .C_HAS_PROG_FLAGS_WACH(0), .C_HAS_PROG_FLAGS_WDCH(0), .C_HAS_PROG_FLAGS_WRCH(0), .C_HAS_PROG_FLAGS_RACH(0), .C_HAS_PROG_FLAGS_RDCH(0), .C_HAS_PROG_FLAGS_AXIS(0), .C_PROG_FULL_TYPE_WACH(0), .C_PROG_FULL_TYPE_WDCH(0), .C_PROG_FULL_TYPE_WRCH(0), .C_PROG_FULL_TYPE_RACH(0), .C_PROG_FULL_TYPE_RDCH(0), .C_PROG_FULL_TYPE_AXIS(0), .C_PROG_FULL_THRESH_ASSERT_VAL_WACH(15), .C_PROG_FULL_THRESH_ASSERT_VAL_WDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_WRCH(31), .C_PROG_FULL_THRESH_ASSERT_VAL_RACH(15), .C_PROG_FULL_THRESH_ASSERT_VAL_RDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_AXIS(1023), .C_PROG_EMPTY_TYPE_WACH(0), .C_PROG_EMPTY_TYPE_WDCH(0), .C_PROG_EMPTY_TYPE_WRCH(0), .C_PROG_EMPTY_TYPE_RACH(0), .C_PROG_EMPTY_TYPE_RDCH(0), .C_PROG_EMPTY_TYPE_AXIS(0), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH(13), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH(1021), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH(29), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH(13), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH(1021), .C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS(1021), .C_REG_SLICE_MODE_WACH(0), .C_REG_SLICE_MODE_WDCH(0), .C_REG_SLICE_MODE_WRCH(0), .C_REG_SLICE_MODE_RACH(0), .C_REG_SLICE_MODE_RDCH(0), .C_REG_SLICE_MODE_AXIS(0) ) dw_fifogen_b_async ( .m_aclk(m_axi_aclk), .s_aclk(s_axi_aclk), .s_aresetn(sm_aresetn), .s_axi_awid(1'b0), .s_axi_awaddr(32'b0), .s_axi_awlen(8'b0), .s_axi_awsize(3'b0), .s_axi_awburst(2'b0), .s_axi_awlock(2'b0), .s_axi_awcache(4'b0), .s_axi_awprot(3'b0), .s_axi_awqos(4'b0), .s_axi_awregion(4'b0), .s_axi_awuser(1'b0), .s_axi_awvalid(1'b0), .s_axi_awready(), .s_axi_wid(1'b0), .s_axi_wdata(32'b0), .s_axi_wstrb(4'b0), .s_axi_wlast(1'b0), .s_axi_wuser(1'b0), .s_axi_wvalid(1'b0), .s_axi_wready(), .s_axi_bid(), .s_axi_bresp(s_axi_bresp_i), .s_axi_buser(), .s_axi_bvalid(s_axi_bvalid_i), .s_axi_bready(s_axi_bready), .m_axi_awid(), .m_axi_awaddr(), .m_axi_awlen(), .m_axi_awsize(), .m_axi_awburst(), .m_axi_awlock(), .m_axi_awcache(), .m_axi_awprot(), .m_axi_awqos(), .m_axi_awregion(), .m_axi_awuser(), .m_axi_awvalid(), .m_axi_awready(1'b0), .m_axi_wid(), .m_axi_wdata(), .m_axi_wstrb(), .m_axi_wlast(), .m_axi_wuser(), .m_axi_wvalid(), .m_axi_wready(1'b0), .m_axi_bid(1'b0), .m_axi_bresp(m_axi_bresp), .m_axi_buser(1'b0), .m_axi_bvalid(m_axi_bvalid), .m_axi_bready(m_axi_bready), .s_axi_arid(1'b0), .s_axi_araddr(32'b0), .s_axi_arlen(8'b0), .s_axi_arsize(3'b0), .s_axi_arburst(2'b0), .s_axi_arlock(2'b0), .s_axi_arcache(4'b0), .s_axi_arprot(3'b0), .s_axi_arqos(4'b0), .s_axi_arregion(4'b0), .s_axi_aruser(1'b0), .s_axi_arvalid(1'b0), .s_axi_arready(), .s_axi_rid(), .s_axi_rdata(), .s_axi_rresp(), .s_axi_rlast(), .s_axi_ruser(), .s_axi_rvalid(), .s_axi_rready(1'b0), .m_axi_arid(), .m_axi_araddr(), .m_axi_arlen(), .m_axi_arsize(), .m_axi_arburst(), .m_axi_arlock(), .m_axi_arcache(), .m_axi_arprot(), .m_axi_arqos(), .m_axi_arregion(), .m_axi_aruser(), .m_axi_arvalid(), .m_axi_arready(1'b0), .m_axi_rid(1'b0), .m_axi_rdata(32'b0), .m_axi_rresp(2'b0), .m_axi_rlast(1'b0), .m_axi_ruser(1'b0), .m_axi_rvalid(1'b0), .m_axi_rready(), .m_aclk_en(1'b0), .s_aclk_en(1'b0), .backup(1'b0), .backup_marker(1'b0), .clk(1'b0), .rst(1'b0), .srst(1'b0), .wr_clk(1'b0), .wr_rst(1'b0), .rd_clk(1'b0), .rd_rst(1'b0), .din(18'b0), .wr_en(1'b0), .rd_en(1'b0), .prog_empty_thresh(10'b0), .prog_empty_thresh_assert(10'b0), .prog_empty_thresh_negate(10'b0), .prog_full_thresh(10'b0), .prog_full_thresh_assert(10'b0), .prog_full_thresh_negate(10'b0), .int_clk(1'b0), .injectdbiterr(1'b0), .injectsbiterr(1'b0), .dout(), .full(), .almost_full(), .wr_ack(), .overflow(), .empty(), .almost_empty(), .valid(), .underflow(), .data_count(), .rd_data_count(), .wr_data_count(), .prog_full(), .prog_empty(), .sbiterr(), .dbiterr(), .s_axis_tvalid(1'b0), .s_axis_tready(), .s_axis_tdata(64'b0), .s_axis_tstrb(4'b0), .s_axis_tkeep(4'b0), .s_axis_tlast(1'b0), .s_axis_tid(8'b0), .s_axis_tdest(4'b0), .s_axis_tuser(4'b0), .m_axis_tvalid(), .m_axis_tready(1'b0), .m_axis_tdata(), .m_axis_tstrb(), .m_axis_tkeep(), .m_axis_tlast(), .m_axis_tid(), .m_axis_tdest(), .m_axis_tuser(), .axi_aw_injectsbiterr(1'b0), .axi_aw_injectdbiterr(1'b0), .axi_aw_prog_full_thresh(4'b0), .axi_aw_prog_empty_thresh(4'b0), .axi_aw_data_count(), .axi_aw_wr_data_count(), .axi_aw_rd_data_count(), .axi_aw_sbiterr(), .axi_aw_dbiterr(), .axi_aw_overflow(), .axi_aw_underflow(), .axi_aw_prog_full(), .axi_aw_prog_empty(), .axi_w_injectsbiterr(1'b0), .axi_w_injectdbiterr(1'b0), .axi_w_prog_full_thresh(10'b0), .axi_w_prog_empty_thresh(10'b0), .axi_w_data_count(), .axi_w_wr_data_count(), .axi_w_rd_data_count(), .axi_w_sbiterr(), .axi_w_dbiterr(), .axi_w_overflow(), .axi_w_underflow(), .axi_b_injectsbiterr(1'b0), .axi_w_prog_full(), .axi_w_prog_empty(), .axi_b_injectdbiterr(1'b0), .axi_b_prog_full_thresh(5'b0), .axi_b_prog_empty_thresh(5'b0), .axi_b_data_count(), .axi_b_wr_data_count(), .axi_b_rd_data_count(), .axi_b_sbiterr(), .axi_b_dbiterr(), .axi_b_overflow(), .axi_b_underflow(), .axi_ar_injectsbiterr(1'b0), .axi_b_prog_full(), .axi_b_prog_empty(), .axi_ar_injectdbiterr(1'b0), .axi_ar_prog_full_thresh(4'b0), .axi_ar_prog_empty_thresh(4'b0), .axi_ar_data_count(), .axi_ar_wr_data_count(), .axi_ar_rd_data_count(), .axi_ar_sbiterr(), .axi_ar_dbiterr(), .axi_ar_overflow(), .axi_ar_underflow(), .axi_ar_prog_full(), .axi_ar_prog_empty(), .axi_r_injectsbiterr(1'b0), .axi_r_injectdbiterr(1'b0), .axi_r_prog_full_thresh(10'b0), .axi_r_prog_empty_thresh(10'b0), .axi_r_data_count(), .axi_r_wr_data_count(), .axi_r_rd_data_count(), .axi_r_sbiterr(), .axi_r_dbiterr(), .axi_r_overflow(), .axi_r_underflow(), .axis_injectsbiterr(1'b0), .axi_r_prog_full(), .axi_r_prog_empty(), .axis_injectdbiterr(1'b0), .axis_prog_full_thresh(10'b0), .axis_prog_empty_thresh(10'b0), .axis_data_count(), .axis_wr_data_count(), .axis_rd_data_count(), .axis_sbiterr(), .axis_dbiterr(), .axis_overflow(), .axis_underflow(), .axis_prog_full(), .axis_prog_empty(), .wr_rst_busy(), .rd_rst_busy(), .sleep(1'b0) ); end end else begin : gen_b_passthru assign m_axi_bready = s_axi_bready; assign s_axi_bresp_i = m_axi_bresp; assign s_axi_bvalid_i = m_axi_bvalid; end // gen_b end else begin : NO_WRITE assign sr_awready = 1'b0; assign s_axi_wready = 1'b0; assign s_axi_bid = {C_S_AXI_ID_WIDTH{1'b0}}; assign s_axi_bresp = 2'b0; assign s_axi_bvalid = 1'b0; assign m_axi_awaddr = {C_AXI_ADDR_WIDTH{1'b0}}; assign m_axi_awlen = 8'b0; assign m_axi_awsize = 3'b0; assign m_axi_awburst = 2'b0; assign m_axi_awlock = 2'b0; assign m_axi_awcache = 4'b0; assign m_axi_awprot = 3'b0; assign m_axi_awregion = 4'b0; assign m_axi_awqos = 4'b0; assign m_axi_awvalid = 1'b0; assign m_axi_wdata = {C_M_AXI_DATA_WIDTH{1'b0}}; assign m_axi_wstrb = {C_M_AXI_DATA_WIDTH/8{1'b0}}; assign m_axi_wlast = 1'b0; assign m_axi_wvalid = 1'b0; assign m_axi_bready = 1'b0; end endgenerate ///////////////////////////////////////////////////////////////////////////// // Handle Read Channels (AR/R) ///////////////////////////////////////////////////////////////////////////// generate if (C_AXI_SUPPORTS_READ == 1) begin : USE_READ wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr_i ; wire [8-1:0] m_axi_arlen_i ; wire [3-1:0] m_axi_arsize_i ; wire [2-1:0] m_axi_arburst_i ; wire [2-1:0] m_axi_arlock_i ; wire [4-1:0] m_axi_arcache_i ; wire [3-1:0] m_axi_arprot_i ; wire [4-1:0] m_axi_arregion_i ; wire [4-1:0] m_axi_arqos_i ; wire m_axi_arvalid_i ; wire m_axi_arready_i ; // Read Channel Signals for Commands Queue Interface. wire rd_cmd_valid; wire rd_cmd_fix; wire rd_cmd_modified; wire rd_cmd_complete_wrap; wire rd_cmd_packed_wrap; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_first_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_next_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_last_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_offset; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_mask; wire [C_S_AXI_BYTES_LOG:0] rd_cmd_step; wire [8-1:0] rd_cmd_length; wire rd_cmd_ready; wire [C_S_AXI_ID_WIDTH-1:0] rd_cmd_id; wire [C_AXI_ADDR_WIDTH-1:0] rd_cmd_si_addr; wire [C_S_AXI_ID_WIDTH-1:0] rd_cmd_si_id; wire [8-1:0] rd_cmd_si_len; wire [3-1:0] rd_cmd_si_size; wire [2-1:0] rd_cmd_si_burst; // Read Address Channel. axi_dwidth_converter_v2_1_a_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_SUPPORTS_ID (C_SUPPORTS_ID), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (C_M_AXI_AR_REGISTER), .C_AXI_CHANNEL (1), .C_PACKING_LEVEL (C_PACKING_LEVEL), // .C_FIFO_MODE (0), .C_FIFO_MODE (C_FIFO_MODE), .C_ID_QUEUE (P_RID_QUEUE), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG) ) read_addr_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (rd_cmd_valid), .cmd_fix (rd_cmd_fix), .cmd_modified (rd_cmd_modified), .cmd_complete_wrap (rd_cmd_complete_wrap), .cmd_packed_wrap (rd_cmd_packed_wrap), .cmd_first_word (rd_cmd_first_word), .cmd_next_word (rd_cmd_next_word), .cmd_last_word (rd_cmd_last_word), .cmd_offset (rd_cmd_offset), .cmd_mask (rd_cmd_mask), .cmd_step (rd_cmd_step), .cmd_length (rd_cmd_length), .cmd_ready (rd_cmd_ready), .cmd_id_ready (rd_cmd_ready), .cmd_id (rd_cmd_id), .cmd_si_addr (rd_cmd_si_addr ), .cmd_si_id (rd_cmd_si_id ), .cmd_si_len (rd_cmd_si_len ), .cmd_si_size (rd_cmd_si_size ), .cmd_si_burst (rd_cmd_si_burst), // Slave Interface Write Address Ports .S_AXI_AID (sr_arid), .S_AXI_AADDR (sr_araddr), .S_AXI_ALEN (sr_arlen), .S_AXI_ASIZE (sr_arsize), .S_AXI_ABURST (sr_arburst), .S_AXI_ALOCK (sr_arlock), .S_AXI_ACACHE (sr_arcache), .S_AXI_APROT (sr_arprot), .S_AXI_AREGION (sr_arregion), .S_AXI_AQOS (sr_arqos), .S_AXI_AVALID (sr_arvalid), .S_AXI_AREADY (sr_arready), // Master Interface Write Address Port .M_AXI_AADDR (m_axi_araddr_i ), .M_AXI_ALEN (m_axi_arlen_i ), .M_AXI_ASIZE (m_axi_arsize_i ), .M_AXI_ABURST (m_axi_arburst_i ), .M_AXI_ALOCK (m_axi_arlock_i ), .M_AXI_ACACHE (m_axi_arcache_i ), .M_AXI_APROT (m_axi_arprot_i ), .M_AXI_AREGION (m_axi_arregion_i ), .M_AXI_AQOS (m_axi_arqos_i ), .M_AXI_AVALID (m_axi_arvalid_i ), .M_AXI_AREADY (m_axi_arready_i ) ); if ((C_FIFO_MODE == P_PKTFIFO) \|\| (C_FIFO_MODE == P_PKTFIFO_CLK)) begin : gen_pktfifo_r_upsizer // Packet FIFO Read Data channel. axi_dwidth_converter_v2_1_r_upsizer_pktfifo # ( .C_FAMILY (C_FAMILY), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG), .C_CLK_CONV (P_CLK_CONV), .C_S_AXI_ACLK_RATIO (C_S_AXI_ACLK_RATIO), .C_M_AXI_ACLK_RATIO (C_M_AXI_ACLK_RATIO), .C_AXI_IS_ACLK_ASYNC (C_AXI_IS_ACLK_ASYNC), .C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE) ) pktfifo_read_data_inst ( .S_AXI_ARESETN ( s_axi_aresetn ) , .S_AXI_ACLK ( s_axi_aclk ) , .M_AXI_ARESETN ( m_axi_aresetn ) , .M_AXI_ACLK ( m_axi_aclk ) , // Command Interface .cmd_si_addr (rd_cmd_si_addr ), .cmd_si_id (rd_cmd_si_id ), .cmd_si_len (rd_cmd_si_len ), .cmd_si_size (rd_cmd_si_size ), .cmd_si_burst (rd_cmd_si_burst), .cmd_ready (rd_cmd_ready), // Slave Interface Write Address Ports .S_AXI_ARADDR (m_axi_araddr_i ), .S_AXI_ARLEN (m_axi_arlen_i ), .S_AXI_ARSIZE (m_axi_arsize_i ), .S_AXI_ARBURST (m_axi_arburst_i ), .S_AXI_ARLOCK (m_axi_arlock_i ), .S_AXI_ARCACHE (m_axi_arcache_i ), .S_AXI_ARPROT (m_axi_arprot_i ), .S_AXI_ARREGION (m_axi_arregion_i ), .S_AXI_ARQOS (m_axi_arqos_i ), .S_AXI_ARVALID (m_axi_arvalid_i ), .S_AXI_ARREADY (m_axi_arready_i ), // Master Interface Write Address Port .M_AXI_ARADDR (m_axi_araddr), .M_AXI_ARLEN (m_axi_arlen), .M_AXI_ARSIZE (m_axi_arsize), .M_AXI_ARBURST (m_axi_arburst), .M_AXI_ARLOCK (m_axi_arlock), .M_AXI_ARCACHE (m_axi_arcache), .M_AXI_ARPROT (m_axi_arprot), .M_AXI_ARREGION (m_axi_arregion), .M_AXI_ARQOS (m_axi_arqos), .M_AXI_ARVALID (m_axi_arvalid), .M_AXI_ARREADY (m_axi_arready), // Slave Interface Write Data Ports .S_AXI_RID (s_axi_rid), .S_AXI_RDATA (s_axi_rdata), .S_AXI_RRESP (s_axi_rresp), .S_AXI_RLAST (s_axi_rlast), .S_AXI_RVALID (s_axi_rvalid), .S_AXI_RREADY (s_axi_rready), // Master Interface Write Data Ports .M_AXI_RDATA (m_axi_rdata), .M_AXI_RRESP (m_axi_rresp), .M_AXI_RLAST (m_axi_rlast), .M_AXI_RVALID (m_axi_rvalid), .M_AXI_RREADY (m_axi_rready), .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early) ); end else begin : gen_non_fifo_r_upsizer // Read Data channel. axi_dwidth_converter_v2_1_r_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_S_AXI_REGISTER (C_S_AXI_R_REGISTER), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG) ) read_data_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (rd_cmd_valid), .cmd_fix (rd_cmd_fix), .cmd_modified (rd_cmd_modified), .cmd_complete_wrap (rd_cmd_complete_wrap), .cmd_packed_wrap (rd_cmd_packed_wrap), .cmd_first_word (rd_cmd_first_word), .cmd_next_word (rd_cmd_next_word), .cmd_last_word (rd_cmd_last_word), .cmd_offset (rd_cmd_offset), .cmd_mask (rd_cmd_mask), .cmd_step (rd_cmd_step), .cmd_length (rd_cmd_length), .cmd_ready (rd_cmd_ready), .cmd_id (rd_cmd_id), // Slave Interface Read Data Ports .S_AXI_RID (s_axi_rid), .S_AXI_RDATA (s_axi_rdata), .S_AXI_RRESP (s_axi_rresp), .S_AXI_RLAST (s_axi_rlast), .S_AXI_RVALID (s_axi_rvalid), .S_AXI_RREADY (s_axi_rready), // Master Interface Read Data Ports .M_AXI_RDATA (mr_rdata), .M_AXI_RRESP (mr_rresp), .M_AXI_RLAST (mr_rlast), .M_AXI_RVALID (mr_rvalid), .M_AXI_RREADY (mr_rready) ); axi_register_slice_v2_1_axi_register_slice # ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL (0), .C_AXI_ID_WIDTH (1), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (0), .C_REG_CONFIG_R (C_M_AXI_R_REGISTER) ) mi_register_slice_inst ( .aresetn (s_aresetn_i), .aclk (m_aclk), .s_axi_awid ( 1'b0 ), .s_axi_awaddr ( {C_AXI_ADDR_WIDTH{1'b0}} ), .s_axi_awlen ( 8'b0 ), .s_axi_awsize ( 3'b0 ), .s_axi_awburst ( 2'b0 ), .s_axi_awlock ( 1'b0 ), .s_axi_awcache ( 4'b0 ), .s_axi_awprot ( 3'b0 ), .s_axi_awregion ( 4'b0 ), .s_axi_awqos ( 4'b0 ), .s_axi_awuser ( 1'b0 ), .s_axi_awvalid ( 1'b0 ), .s_axi_awready ( ), .s_axi_wid ( 1'b0 ), .s_axi_wdata ( {C_M_AXI_DATA_WIDTH{1'b0}} ), .s_axi_wstrb ( {C_M_AXI_DATA_WIDTH/8{1'b0}} ), .s_axi_wlast ( 1'b0 ), .s_axi_wuser ( 1'b0 ), .s_axi_wvalid ( 1'b0 ), .s_axi_wready ( ), .s_axi_bid ( ), .s_axi_bresp ( ), .s_axi_buser ( ), .s_axi_bvalid ( ), .s_axi_bready ( 1'b0 ), .s_axi_arid ( 1'b0 ), .s_axi_araddr ( {C_AXI_ADDR_WIDTH{1'b0}} ), .s_axi_arlen ( 8'b0 ), .s_axi_arsize ( 3'b0 ), .s_axi_arburst ( 2'b0 ), .s_axi_arlock ( 1'b0 ), .s_axi_arcache ( 4'b0 ), .s_axi_arprot ( 3'b0 ), .s_axi_arregion ( 4'b0 ), .s_axi_arqos ( 4'b0 ), .s_axi_aruser ( 1'b0 ), .s_axi_arvalid ( 1'b0 ), .s_axi_arready ( ), .s_axi_rid (), .s_axi_rdata (mr_rdata ), .s_axi_rresp (mr_rresp ), .s_axi_rlast (mr_rlast ), .s_axi_ruser (), .s_axi_rvalid (mr_rvalid ), .s_axi_rready (mr_rready ), .m_axi_awid (), .m_axi_awaddr (), .m_axi_awlen (), .m_axi_awsize (), .m_axi_awburst (), .m_axi_awlock (), .m_axi_awcache (), .m_axi_awprot (), .m_axi_awregion (), .m_axi_awqos (), .m_axi_awuser (), .m_axi_awvalid (), .m_axi_awready (1'b0), .m_axi_wid () , .m_axi_wdata (), .m_axi_wstrb (), .m_axi_wlast (), .m_axi_wuser (), .m_axi_wvalid (), .m_axi_wready (1'b0), .m_axi_bid ( 1'b0 ) , .m_axi_bresp ( 2'b0 ) , .m_axi_buser ( 1'b0 ) , .m_axi_bvalid ( 1'b0 ) , .m_axi_bready ( ) , .m_axi_arid (), .m_axi_araddr (), .m_axi_arlen (), .m_axi_arsize (), .m_axi_arburst (), .m_axi_arlock (), .m_axi_arcache (), .m_axi_arprot (), .m_axi_arregion (), .m_axi_arqos (), .m_axi_aruser (), .m_axi_arvalid (), .m_axi_arready (1'b0), .m_axi_rid (1'b0 ), .m_axi_rdata (m_axi_rdata ), .m_axi_rresp (m_axi_rresp ), .m_axi_rlast (m_axi_rlast ), .m_axi_ruser (1'b0 ), .m_axi_rvalid (m_axi_rvalid ), .m_axi_rready (m_axi_rready_i ) ); assign m_axi_araddr = m_axi_araddr_i ; assign m_axi_arlen = m_axi_arlen_i ; assign m_axi_arsize = m_axi_arsize_i ; assign m_axi_arburst = m_axi_arburst_i ; assign m_axi_arlock = m_axi_arlock_i ; assign m_axi_arcache = m_axi_arcache_i ; assign m_axi_arprot = m_axi_arprot_i ; assign m_axi_arregion = m_axi_arregion_i ; assign m_axi_arqos = m_axi_arqos_i ; assign m_axi_arvalid = m_axi_arvalid_i ; assign m_axi_arready_i = m_axi_arready ; assign m_axi_rready = m_axi_rready_i; end // gen_r_upsizer end else begin : NO_READ assign sr_arready = 1'b0; assign s_axi_rid = {C_S_AXI_ID_WIDTH{1'b0}}; assign s_axi_rdata = {C_S_AXI_DATA_WIDTH{1'b0}}; assign s_axi_rresp = 2'b0; assign s_axi_rlast = 1'b0; assign s_axi_rvalid = 1'b0; assign m_axi_araddr = {C_AXI_ADDR_WIDTH{1'b0}}; assign m_axi_arlen = 8'b0; assign m_axi_arsize = 3'b0; assign m_axi_arburst = 2'b0; assign m_axi_arlock = 2'b0; assign m_axi_arcache = 4'b0; assign m_axi_arprot = 3'b0; assign m_axi_arregion = 4'b0; assign m_axi_arqos = 4'b0; assign m_axi_arvalid = 1'b0; assign mr_rready = 1'b0; end endgenerate endmodule `default_nettype wire
//deps: sdram_controller3.v, IS42S16160.v `timescale 1ns/1ps module sdram_controller3_tb; /AUTOWIRE/ // Beginning of automatic wires (for undeclared instantiated-module outputs) wire [12:0] DRAM_ADDR; // From controller of sdram_controller3.v wire [1:0] DRAM_BA; // From controller of sdram_controller3.v wire DRAM_CAS_N; // From controller of sdram_controller3.v wire DRAM_CKE; // From controller of sdram_controller3.v wire DRAM_CLK; // From controller of sdram_controller3.v wire DRAM_CS_N; // From controller of sdram_controller3.v wire [15:0] DRAM_DQ; // To/From controller of sdram_controller3.v wire [1:0] DRAM_DQM; // From controller of sdram_controller3.v wire DRAM_RAS_N; // From controller of sdram_controller3.v wire DRAM_WE_N; // From controller of sdram_controller3.v wire [31:0] data_out; // From controller of sdram_controller3.v wire data_valid; // From controller of sdram_controller3.v wire write_complete; // From controller of sdram_controller3.v // End of automatics /AUTOREGINPUT/ // Beginning of automatic reg inputs (for undeclared instantiated-module inputs) reg CLOCK_100; // To controller of sdram_controller3.v reg CLOCK_100_del_3ns; // To controller of sdram_controller3.v reg CLOCK_50; // To controller of sdram_controller3.v reg [23:0] address; // To controller of sdram_controller3.v reg [31:0] data_in; // To controller of sdram_controller3.v reg req_read; // To controller of sdram_controller3.v reg req_write; // To controller of sdram_controller3.v reg rst; // To controller of sdram_controller3.v // End of automatics sdram_controller3 controller(/AUTOINST/ // Outputs .data_out (data_out[31:0]), .data_valid (data_valid), .write_complete (write_complete), .DRAM_ADDR (DRAM_ADDR[12:0]), .DRAM_BA (DRAM_BA[1:0]), .DRAM_CAS_N (DRAM_CAS_N), .DRAM_CKE (DRAM_CKE), .DRAM_CLK (DRAM_CLK), .DRAM_CS_N (DRAM_CS_N), .DRAM_DQM (DRAM_DQM[1:0]), .DRAM_RAS_N (DRAM_RAS_N), .DRAM_WE_N (DRAM_WE_N), // Inouts .DRAM_DQ (DRAM_DQ[15:0]), // Inputs .CLOCK_50 (CLOCK_50), .CLOCK_100 (CLOCK_100), .CLOCK_100_del_3ns(CLOCK_100_del_3ns), .rst (rst), .address (address[23:0]), .req_read (req_read), .req_write (req_write), .data_in (data_in[31:0])); IS42S16160 RAM ( // Inouts .Dq (DRAM_DQ[15:0]), // Inputs .Addr (DRAM_ADDR[12:0]), .Ba (DRAM_BA[1:0]), .Clk (DRAM_CLK), .Cke (DRAM_CKE), .Cs_n (DRAM_CS_N), .Ras_n (DRAM_RAS_N), .Cas_n (DRAM_CAS_N), .We_n (DRAM_WE_N), .Dqm (DRAM_DQM[1:0])); initial begin rst = 1; CLOCK_50 = 0; CLOCK_100 = 0; CLOCK_100_del_3ns = 0; address = 0; req_read = 0; req_write = 0; data_in = 0; $dumpfile("dump.vcd"); $dumpvars; #3000 $finish; end always #10 CLOCK_50 <= ~CLOCK_50; always #5 begin CLOCK_100 <= ~CLOCK_100; end always @(CLOCK_100) begin #3 CLOCK_100_del_3ns <= CLOCK_100; end initial begin #20 rst = 0; #1000 address = 16; data_in = 32'h12345678; req_write = 1; #20 req_write = 0; @(posedge write_complete) #60 address = 16; req_read = 1; #20 req_read = 0; end // initial begin endmodule
//------------------------------------------------------------------------------ // This confidential and proprietary software may be used only as authorized by // a licensing agreement from Altera Corporation. // // Legal Notice: (C)2010 Altera Corporation. All rights reserved. Your // use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any // output files any of the foregoing (including device programming or // simulation files), and any associated documentation or information are // expressly subject to the terms and conditions of the Altera Program // License Subscription Agreement or other applicable license agreement, // including, without limitation, that your use is for the sole purpose // of programming logic devices manufactured by Altera and sold by Altera // or its authorized distributors. Please refer to the applicable // agreement for further details. // // The entire notice above must be reproduced on all authorized copies and any // such reproduction must be pursuant to a licensing agreement from Altera. // // Title : Example top level testbench for ddr3_int DDR/2/3 SDRAM High Performance Controller // Project : DDR/2/3 SDRAM High Performance Controller // // File : ddr3_int_example_top_tb.v // // Revision : V10.0 // // Abstract: // Automatically generated testbench for the example top level design to allow // functional and timing simulation. // //------------------------------------------------------------------------------ // // ************* This is a MegaWizard generated file ************** // // If you need to edit this file make sure the edits are not inside any 'MEGAWIZARD' // text insertion areas. // (between "<< START MEGAWIZARD INSERT" and "<< END MEGAWIZARD INSERT" comments) // // Any edits inside these delimiters will be overwritten by the megawizard if you // re-run it. // // If you really need to make changes inside these delimiters then delete // both 'START' and 'END' delimiters. This will stop the megawizard updating this // section again. // //---------------------------------------------------------------------------------- // << START MEGAWIZARD INSERT PARAMETER_LIST // Parameters: // // Device Family : arria ii gx // local Interface Data Width : 128 // MEM_CHIPSELS : 1 // MEM_CS_PER_RANK : 1 // MEM_BANK_BITS : 3 // MEM_ROW_BITS : 13 // MEM_COL_BITS : 10 // LOCAL_DATA_BITS : 128 // NUM_CLOCK_PAIRS : 1 // CLOCK_TICK_IN_PS : 3333 // REGISTERED_DIMM : false // TINIT_CLOCKS : 75008 // Data_Width_Ratio : 4 // << END MEGAWIZARD INSERT PARAMETER_LIST //---------------------------------------------------------------------------------- // << MEGAWIZARD PARSE FILE DDR10.0 `timescale 1 ps/1 ps // << START MEGAWIZARD INSERT MODULE module ddr3_int_example_top_tb (); // << END MEGAWIZARD INSERT MODULE // << START MEGAWIZARD INSERT PARAMS parameter gMEM_CHIPSELS = 1; parameter gMEM_CS_PER_RANK = 1; parameter gMEM_NUM_RANKS = 1 / 1; parameter gMEM_BANK_BITS = 3; parameter gMEM_ROW_BITS = 13; parameter gMEM_COL_BITS = 10; parameter gMEM_ADDR_BITS = 13; parameter gMEM_DQ_PER_DQS = 8; parameter DM_DQS_WIDTH = 4; parameter gLOCAL_DATA_BITS = 128; parameter gLOCAL_IF_DWIDTH_AFTER_ECC = 128; parameter gNUM_CLOCK_PAIRS = 1; parameter RTL_ROUNDTRIP_CLOCKS = 0.0; parameter CLOCK_TICK_IN_PS = 3333; parameter REGISTERED_DIMM = 1'b0; parameter BOARD_DQS_DELAY = 0; parameter BOARD_CLK_DELAY = 0; parameter DWIDTH_RATIO = 4; parameter TINIT_CLOCKS = 75008; parameter REF_CLOCK_TICK_IN_PS = 40000; // Parameters below are for generic memory model parameter gMEM_TQHS_PS = 300; parameter gMEM_TAC_PS = 400; parameter gMEM_TDQSQ_PS = 125; parameter gMEM_IF_TRCD_NS = 13.5; parameter gMEM_IF_TWTR_CK = 4; parameter gMEM_TDSS_CK = 0.2; parameter gMEM_IF_TRFC_NS = 110.0; parameter gMEM_IF_TRP_NS = 13.5; parameter gMEM_IF_TRCD_PS = gMEM_IF_TRCD_NS * 1000.0; parameter gMEM_IF_TWTR_PS = gMEM_IF_TWTR_CK * CLOCK_TICK_IN_PS; parameter gMEM_IF_TRFC_PS = gMEM_IF_TRFC_NS * 1000.0; parameter gMEM_IF_TRP_PS = gMEM_IF_TRP_NS * 1000.0; parameter CLOCK_TICK_IN_NS = CLOCK_TICK_IN_PS / 1000.0; parameter gMEM_TDQSQ_NS = gMEM_TDQSQ_PS / 1000.0; parameter gMEM_TDSS_NS = gMEM_TDSS_CK * CLOCK_TICK_IN_NS; // << END MEGAWIZARD INSERT PARAMS // set to zero for Gatelevel parameter RTL_DELAYS = 1; parameter USE_GENERIC_MEMORY_MODEL = 1'b0; // The round trip delay is now modeled inside the datapath (<your core name>_auk_ddr_dqs_group.v/vhd) for RTL simulation. parameter D90_DEG_DELAY = 0; //RTL only parameter GATE_BOARD_DQS_DELAY = BOARD_DQS_DELAY * (RTL_DELAYS ? 0 : 1); // Gate level timing only parameter GATE_BOARD_CLK_DELAY = BOARD_CLK_DELAY * (RTL_DELAYS ? 0 : 1); // Gate level timing only // Below 5 lines for SPR272543: // Testbench workaround for tests with "dedicated memory clock phase shift" failing, // because dqs delay isnt' being modelled in simulations parameter gMEM_CLK_PHASE_EN = "false"; parameter real gMEM_CLK_PHASE = 0; parameter real MEM_CLK_RATIO = ((360.0-gMEM_CLK_PHASE)/360.0); parameter MEM_CLK_DELAY = MEM_CLK_RATIOCLOCK_TICK_IN_PS ((gMEM_CLK_PHASE_EN=="true") ? 1 : 0); wire clk_to_ram0, clk_to_ram1, clk_to_ram2; wire cmd_bus_watcher_enabled; reg clk; reg clk_n; reg reset_n; wire mem_reset_n; wire[gMEM_ADDR_BITS - 1:0] a; wire[gMEM_BANK_BITS - 1:0] ba; wire[gMEM_CHIPSELS - 1:0] cs_n; wire[gMEM_NUM_RANKS - 1:0] cke; wire[gMEM_NUM_RANKS - 1:0] odt; //DDR2 only wire ras_n; wire cas_n; wire we_n; wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dm; //wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dqs; //wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dqs_n; //wire stratix_dqs_ref_clk; // only used on stratix to provide external dll reference clock wire[gNUM_CLOCK_PAIRS - 1:0] clk_to_sdram; wire[gNUM_CLOCK_PAIRS - 1:0] clk_to_sdram_n; wire #(GATE_BOARD_CLK_DELAY * 1) clk_to_ram; wire clk_to_ram_n; wire[gMEM_ROW_BITS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) a_delayed; wire[gMEM_BANK_BITS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) ba_delayed; wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) cke_delayed; wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) odt_delayed; //DDR2 only wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) cs_n_delayed; wire #(GATE_BOARD_CLK_DELAY * 1 + 1) ras_n_delayed; wire #(GATE_BOARD_CLK_DELAY * 1 + 1) cas_n_delayed; wire #(GATE_BOARD_CLK_DELAY * 1 + 1) we_n_delayed; wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dm_delayed; // DDR3 parity only wire ac_parity; wire mem_err_out_n; assign mem_err_out_n = 1'b1; // pulldown (dm); assign (weak1, weak0) dm = 0; tri [gLOCAL_DATA_BITS / DWIDTH_RATIO - 1:0] mem_dq = 100'bz; tri [gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] mem_dqs = 100'bz; tri [gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] mem_dqs_n = 100'bz; assign (weak1, weak0) mem_dq = 0; assign (weak1, weak0) mem_dqs = 0; assign (weak1, weak0) mem_dqs_n = 1; wire [gMEM_BANK_BITS - 1:0] zero_one; //"01"; assign zero_one = 1; wire test_complete; wire [7:0] test_status; // counter to count the number of sucessful read and write loops integer test_complete_count; wire pnf; wire [gLOCAL_IF_DWIDTH_AFTER_ECC / 8 - 1:0] pnf_per_byte; assign cmd_bus_watcher_enabled = 1'b0; // Below 5 lines for SPR272543: // Testbench workaround for tests with "dedicated memory clock phase shift" failing, // because dqs delay isnt' being modelled in simulations assign #(MEM_CLK_DELAY/4.0) clk_to_ram2 = clk_to_sdram[0]; assign #(MEM_CLK_DELAY/4.0) clk_to_ram1 = clk_to_ram2; assign #(MEM_CLK_DELAY/4.0) clk_to_ram0 = clk_to_ram1; assign #((MEM_CLK_DELAY/4.0)) clk_to_ram = clk_to_ram0; assign clk_to_ram_n = ~clk_to_ram ; // mem model ignores clk_n ? // ddr sdram interface // << START MEGAWIZARD INSERT ENTITY ddr3_int_example_top dut ( // << END MEGAWIZARD INSERT ENTITY .clock_source(clk), .global_reset_n(reset_n), // << START MEGAWIZARD INSERT PORT_MAP .mem_clk(clk_to_sdram), .mem_clk_n(clk_to_sdram_n), .mem_odt(odt), .mem_dqsn(mem_dqs_n), .mem_reset_n(mem_reset_n), .mem_cke(cke), .mem_cs_n(cs_n), .mem_ras_n(ras_n), .mem_cas_n(cas_n), .mem_we_n(we_n), .mem_ba(ba), .mem_addr(a), .mem_dq(mem_dq), .mem_dqs(mem_dqs), .mem_dm(dm), // << END MEGAWIZARD INSERT PORT_MAP .test_complete(test_complete), .test_status(test_status), .pnf_per_byte(pnf_per_byte), .pnf(pnf) ); // << START MEGAWIZARD INSERT MEMORY_ARRAY // This will need updating to match the memory models you are using. // Instantiate a generated DDR memory model to match the datawidth & chipselect requirements ddr3_int_mem_model mem ( .mem_rst_n (mem_reset_n), .mem_dq (mem_dq), .mem_dqs (mem_dqs), .mem_dqs_n (mem_dqs_n), .mem_addr (a_delayed), .mem_ba (ba_delayed), .mem_clk (clk_to_ram), .mem_clk_n (clk_to_ram_n), .mem_cke (cke_delayed), .mem_cs_n (cs_n_delayed), .mem_ras_n (ras_n_delayed), .mem_cas_n (cas_n_delayed), .mem_we_n (we_n_delayed), .mem_dm (dm_delayed), .mem_odt (odt_delayed) ); // << END MEGAWIZARD INSERT MEMORY_ARRAY always begin clk <= 1'b0 ; clk_n <= 1'b1 ; while (1'b1) begin #((REF_CLOCK_TICK_IN_PS / 2) * 1); clk <= ~clk ; clk_n <= ~clk_n ; end end initial begin reset_n <= 1'b0 ; @(clk); @(clk); @(clk); @(clk); @(clk); @(clk); reset_n <= 1'b1 ; end // control and data lines = 3 inches assign a_delayed = a[gMEM_ROW_BITS - 1:0] ; assign ba_delayed = ba ; assign cke_delayed = cke ; assign odt_delayed = odt ; assign cs_n_delayed = cs_n ; assign ras_n_delayed = ras_n ; assign cas_n_delayed = cas_n ; assign we_n_delayed = we_n ; assign dm_delayed = dm ; // --------------------------------------------------------------- initial begin : endit integer count; reg ln; count = 0; // Stop simulation after test_complete or TINIT + 600000 clocks while ((count < (TINIT_CLOCKS + 600000)) & (test_complete !== 1)) begin count = count + 1; @(negedge clk_to_sdram[0]); end if (test_complete === 1) begin if (pnf) begin $write($time); $write(" --- SIMULATION PASSED --- "); $stop; end else begin $write($time); $write(" --- SIMULATION FAILED --- "); $stop; end end else begin $write($time); $write(" --- SIMULATION FAILED, DID NOT COMPLETE --- "); $stop; end end always @(clk_to_sdram[0] or reset_n) begin if (!reset_n) begin test_complete_count <= 0 ; end else if ((clk_to_sdram[0])) begin if (test_complete) begin test_complete_count <= test_complete_count + 1 ; end end end reg[2:0] cmd_bus; //*********************************************************** // Watch the SDRAM command bus always @(clk_to_ram) begin if (clk_to_ram) begin if (1'b1) begin cmd_bus = {ras_n_delayed, cas_n_delayed, we_n_delayed}; case (cmd_bus) 3'b000 : begin // LMR command $write($time); if (ba_delayed == zero_one) begin $write(" ELMR settings = "); if (!(a_delayed[0])) begin $write("DLL enable"); end end else begin $write(" LMR settings = "); case (a_delayed[1:0]) 3'b00 : $write("BL = 8,"); 3'b01 : $write("BL = On The Fly,"); 3'b10 : $write("BL = 4,"); default : $write("BL = ??,"); endcase case (a_delayed[6:4]) 3'b001 : $write(" CL = 5.0,"); 3'b010 : $write(" CL = 6.0,"); 3'b011 : $write(" CL = 7.0,"); 3'b100 : $write(" CL = 8.0,"); 3'b101 : $write(" CL = 9.0,"); 3'b110 : $write(" CL = 10.0,"); default : $write(" CL = ??,"); endcase if ((a_delayed[8])) $write(" DLL reset"); end $write("\n"); end 3'b001 : begin // ARF command $write($time); $write(" ARF\n"); end 3'b010 : begin // PCH command $write($time); $write(" PCH"); if ((a_delayed[10])) begin $write(" all banks \n"); end else begin $write(" bank "); $write("%H\n", ba_delayed); end end 3'b011 : begin // ACT command $write($time); $write(" ACT row address "); $write("%H", a_delayed); $write(" bank "); $write("%H\n", ba_delayed); end 3'b100 : begin // WR command $write($time); $write(" WR to col address "); $write("%H", a_delayed); $write(" bank "); $write("%H\n", ba_delayed); end 3'b101 : begin // RD command $write($time); $write(" RD from col address "); $write("%H", a_delayed); $write(" bank "); $write("%H\n", ba_delayed); end 3'b110 : begin // BT command $write($time); $write(" BT "); end 3'b111 : begin // NOP command end endcase end else begin end // if enabled end end endmodule
//wishbone master interconnect testbench /* Distributed under the MIT licesnse. Copyright (c) 2011 Dave McCoy ([email protected]) Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. / / Log 04/16/2013 -implement naming convention 08/30/2012 -Major overhall of the testbench -modfied the way reads and writes happen, now each write requires the number of 32-bit data packets even if the user sends only 1 -there is no more streaming as the data_count will implicity declare that a read/write is streaming -added the ih_reset which has not been formally defined within the system, but will more than likely reset the entire statemachine 11/12/2011 -overhauled the design to behave more similar to a real I/O handler -changed the timeout to 40 seconds to allow the wishbone master to catch nacks 11/08/2011 -added interrupt support / `timescale 1 ns/1 ps `define TIMEOUT_COUNT 40 `define INPUT_FILE "sim/master_input_test_data.txt" `define OUTPUT_FILE "sim/master_output_test_data.txt" `define CLK_HALF_PERIOD 10 `define CLK_PERIOD (2 `CLK_HALF_PERIOD) `define SLEEP_HALF_CLK #(`CLK_HALF_PERIOD) `define SLEEP_FULL_CLK #(`CLK_PERIOD) //Sleep a number of clock cycles `define SLEEP_CLK(x) #(x * `CLK_PERIOD) //`define VERBOSE module wishbone_master_tb ( ); //Virtual Host Interface Signals reg clk = 0; reg rst = 0; wire w_master_ready; reg r_in_ready = 0; reg [31:0] r_in_command = 32'h00000000; reg [31:0] r_in_address = 32'h00000000; reg [31:0] r_in_data = 32'h00000000; reg [27:0] r_in_data_count = 0; reg r_out_ready = 0; wire w_out_en; wire [31:0] w_out_status; wire [31:0] w_out_address; wire [31:0] w_out_data; wire [27:0] w_out_data_count; reg r_ih_reset = 0; //wishbone signals wire w_wbm_we; wire w_wbm_cyc; wire w_wbm_stb; wire [3:0] w_wbm_sel; wire [31:0] w_wbm_adr; wire [31:0] w_wbm_dat_o; wire [31:0] w_wbm_dat_i; wire w_wbm_ack; wire w_wbm_int; //Wishbone Slave 0 (SDB) signals wire w_wbs0_we; wire w_wbs0_cyc; wire [31:0] w_wbs0_dat_o; wire w_wbs0_stb; wire [3:0] w_wbs0_sel; wire w_wbs0_ack; wire [31:0] w_wbs0_dat_i; wire [31:0] w_wbs0_adr; wire w_wbs0_int; //wishbone slave 1 (Unit Under Test) signals wire w_wbs1_we; wire w_wbs1_cyc; wire w_wbs1_stb; wire [3:0] w_wbs1_sel; wire w_wbs1_ack; wire [31:0] w_wbs1_dat_i; wire [31:0] w_wbs1_dat_o; wire [31:0] w_wbs1_adr; wire w_wbs1_int; //Local Parameters localparam WAIT_FOR_SDRAM = 8'h00; localparam IDLE = 8'h01; localparam SEND_COMMAND = 8'h02; localparam MASTER_READ_COMMAND = 8'h03; localparam RESET = 8'h04; localparam PING_RESPONSE = 8'h05; localparam WRITE_DATA = 8'h06; localparam WRITE_RESPONSE = 8'h07; localparam GET_WRITE_DATA = 8'h08; localparam READ_RESPONSE = 8'h09; localparam READ_MORE_DATA = 8'h0A; localparam FINISHED = 8'h0B; //Registers/Wires/Simulation Integers integer fd_in; integer fd_out; integer read_count; integer timeout_count; integer ch; integer data_count; reg [3:0] state = IDLE; reg prev_int = 0; wire start; reg execute_command; reg command_finished; reg request_more_data; reg request_more_data_ack; reg [27:0] data_write_count; reg [27:0] data_read_count; //Submodules wishbone_master wm ( .clk (clk ), .rst (rst ), .i_ih_rst (r_ih_reset ), .i_ready (r_in_ready ), .i_command (r_in_command ), .i_address (r_in_address ), .i_data (r_in_data ), .i_data_count (r_in_data_count ), .i_out_ready (r_out_ready ), .o_en (w_out_en ), .o_status (w_out_status ), .o_address (w_out_address ), .o_data (w_out_data ), .o_data_count (w_out_data_count ), .o_master_ready (w_master_ready ), .o_per_we (w_wbm_we ), .o_per_adr (w_wbm_adr ), .o_per_dat (w_wbm_dat_i ), .i_per_dat (w_wbm_dat_o ), .o_per_stb (w_wbm_stb ), .o_per_cyc (w_wbm_cyc ), .o_per_msk (w_wbm_msk ), .o_per_sel (w_wbm_sel ), .i_per_ack (w_wbm_ack ), .i_per_int (w_wbm_int ) ); //slave 1 wb_hs_demo s1 ( .clk (clk ), .rst (rst ), .i_wbs_we (w_wbs1_we ), .i_wbs_cyc (w_wbs1_cyc ), .i_wbs_dat (w_wbs1_dat_i ), .i_wbs_stb (w_wbs1_stb ), .o_wbs_ack (w_wbs1_ack ), .o_wbs_dat (w_wbs1_dat_o ), .i_wbs_adr (w_wbs1_adr ), .o_wbs_int (w_wbs1_int ) ); wishbone_interconnect wi ( .clk (clk ), .rst (rst ), .i_m_we (w_wbm_we ), .i_m_cyc (w_wbm_cyc ), .i_m_stb (w_wbm_stb ), .o_m_ack (w_wbm_ack ), .i_m_dat (w_wbm_dat_i ), .o_m_dat (w_wbm_dat_o ), .i_m_adr (w_wbm_adr ), .o_m_int (w_wbm_int ), .o_s0_we (w_wbs0_we ), .o_s0_cyc (w_wbs0_cyc ), .o_s0_stb (w_wbs0_stb ), .i_s0_ack (w_wbs0_ack ), .o_s0_dat (w_wbs0_dat_i ), .i_s0_dat (w_wbs0_dat_o ), .o_s0_adr (w_wbs0_adr ), .i_s0_int (w_wbs0_int ), .o_s1_we (w_wbs1_we ), .o_s1_cyc (w_wbs1_cyc ), .o_s1_stb (w_wbs1_stb ), .i_s1_ack (w_wbs1_ack ), .o_s1_dat (w_wbs1_dat_i ), .i_s1_dat (w_wbs1_dat_o ), .o_s1_adr (w_wbs1_adr ), .i_s1_int (w_wbs1_int ) ); assign w_wbs0_ack = 0; assign w_wbs0_dat_o = 0; assign start = 1; always #`CLK_HALF_PERIOD clk = ~clk; initial begin fd_out = 0; read_count = 0; data_count = 0; timeout_count = 0; request_more_data_ack <= 0; execute_command <= 0; $dumpfile ("design.vcd"); $dumpvars (0, wishbone_master_tb); fd_in = $fopen(`INPUT_FILE, "r"); fd_out = $fopen(`OUTPUT_FILE, "w"); `SLEEP_HALF_CLK; rst <= 0; `SLEEP_CLK(100); rst <= 1; //clear the handler signals r_in_ready <= 0; r_in_command <= 0; r_in_address <= 32'h0; r_in_data <= 32'h0; r_in_data_count <= 0; r_out_ready <= 0; //clear wishbone signals `SLEEP_CLK(10); rst <= 0; r_out_ready <= 1; if (fd_in == 0) begin $display ("TB: input stimulus file was not found"); end else begin //while there is still data to be read from the file while (!$feof(fd_in)) begin //read in a command read_count = $fscanf (fd_in, "%h:%h:%h:%h\n", r_in_data_count, r_in_command, r_in_address, r_in_data); //Handle Frindge commands/comments if (read_count != 4) begin if (read_count == 0) begin ch = $fgetc(fd_in); if (ch == "\#") begin //$display ("Eat a comment"); //Eat the line while (ch != "\n") begin ch = $fgetc(fd_in); end `ifdef VERBOSE $display (""); `endif end else begin `ifdef VERBOSE $display ("Error unrecognized line: %h" % ch); `endif //Eat the line while (ch != "\n") begin ch = $fgetc(fd_in); end end end else if (read_count == 1) begin `ifdef VERBOSE $display ("Sleep for %h Clock cycles", r_in_data_count); `endif `SLEEP_CLK(r_in_data_count); `ifdef VERBOSE $display ("Sleep Finished"); `endif end else begin `ifdef VERBOSE $display ("Error: read_count = %h != 4", read_count); `endif `ifdef VERBOSE $display ("Character: %h", ch); `endif end end else begin `ifdef VERBOSE case (r_in_command) 0: $display ("TB: Executing PING commad"); 1: $display ("TB: Executing WRITE command"); 2: $display ("TB: Executing READ command"); 3: $display ("TB: Executing RESET command"); endcase `endif `ifdef VERBOSE $display ("Execute Command"); `endif execute_command <= 1; `SLEEP_CLK(1); while (~command_finished) begin request_more_data_ack <= 0; if ((r_in_command & 32'h0000FFFF) == 1) begin if (request_more_data && ~request_more_data_ack) begin read_count = $fscanf(fd_in, "%h\n", r_in_data); `ifdef VERBOSE $display ("TB: reading a new double word: %h", r_in_data); `endif request_more_data_ack <= 1; end end //so time porgresses wait a tick `SLEEP_CLK(1); //this doesn't need to be here, but there is a weird behavior in iverilog //that wont allow me to put a delay in right before an 'end' statement //execute_command <= 1; end //while command is not finished execute_command <= 0; while (command_finished) begin `ifdef VERBOSE $display ("Command Finished"); `endif `SLEEP_CLK(1); execute_command <= 0; end `SLEEP_CLK(50); `ifdef VERBOSE $display ("TB: finished command"); `endif end //end read_count == 4 end //end while ! eof end //end not reset `SLEEP_CLK(50); $fclose (fd_in); $fclose (fd_out); $finish(); end //initial begin // $monitor("%t, state: %h", $time, state); //end //initial begin // $monitor("%t, data: %h, state: %h, execute command: %h", $time, w_wbm_dat_o, state, execute_command); //end //initial begin //$monitor("%t, state: %h, execute: %h, cmd_fin: %h", $time, state, execute_command, command_finished); //$monitor("%t, state: %h, write_size: %d, write_count: %d, execute: %h", $time, state, r_in_data_count, data_write_count, execute_command); //end always @ (posedge clk) begin if (rst) begin state <= WAIT_FOR_SDRAM; request_more_data <= 0; timeout_count <= 0; prev_int <= 0; r_ih_reset <= 0; data_write_count <= 0; data_read_count <= 1; command_finished <= 0; end else begin r_ih_reset <= 0; r_in_ready <= 0; r_out_ready <= 1; command_finished <= 0; //Countdown the NACK timeout if (execute_command && timeout_count < `TIMEOUT_COUNT) begin timeout_count <= timeout_count + 1; end if (execute_command && timeout_count >= `TIMEOUT_COUNT) begin `ifdef VERBOSE case (r_in_command) 0: $display ("TB: Master timed out while executing PING commad"); 1: $display ("TB: Master timed out while executing WRITE command"); 2: $display ("TB: Master timed out while executing READ command"); 3: $display ("TB: Master timed out while executing RESET command"); endcase `endif command_finished <= 1; state <= IDLE; timeout_count <= 0; end //end reached the end of a timeout case (state) WAIT_FOR_SDRAM: begin timeout_count <= 0; r_in_ready <= 0; //Uncomment 'start' conditional to wait for SDRAM to finish starting //up if (start) begin `ifdef VERBOSE $display ("TB: sdram is ready"); `endif state <= IDLE; end end IDLE: begin timeout_count <= 0; command_finished <= 0; data_write_count <= 1; if (execute_command && !command_finished) begin state <= SEND_COMMAND; end data_read_count <= 1; end SEND_COMMAND: begin timeout_count <= 0; if (w_master_ready) begin r_in_ready <= 1; state <= MASTER_READ_COMMAND; end end MASTER_READ_COMMAND: begin r_in_ready <= 1; if (!w_master_ready) begin r_in_ready <= 0; case (r_in_command & 32'h0000FFFF) 0: begin state <= PING_RESPONSE; end 1: begin if (r_in_data_count > 1) begin `ifdef VERBOSE $display ("TB:\tWrote Double Word %d: %h", data_write_count, r_in_data); `endif if (data_write_count < r_in_data_count) begin state <= WRITE_DATA; timeout_count <= 0; data_write_count<= data_write_count + 1; end else begin `ifdef VERBOSE $display ("TB: Finished Writing: %d 32bit words of %d size", r_in_data_count, data_write_count); `endif state <= WRITE_RESPONSE; end end else begin `ifdef VERBOSE $display ("TB:\tWrote Double Word %d: %h", data_write_count, r_in_data); `endif `ifdef VERBOSE $display ("TB: Finished Writing: %d 32bit words of %d size", r_in_data_count, data_write_count); `endif state <= WRITE_RESPONSE; end end 2: begin state <= READ_RESPONSE; end 3: begin state <= RESET; end endcase end end RESET: begin r_ih_reset <= 1; state <= RESET; end PING_RESPONSE: begin if (w_out_en) begin if (w_out_status[7:0] == 8'hFF) begin `ifdef VERBOSE $display ("TB: Ping Response Good"); `endif end else begin `ifdef VERBOSE $display ("TB: Ping Response Bad (Malformed response: %h)", w_out_status); `endif end `ifdef VERBOSE $display ("TB: \tS:A:D = %h:%h:%h\n", w_out_status, w_out_address, w_out_data); `endif state <= FINISHED; end end WRITE_DATA: begin if (!r_in_ready && w_master_ready) begin state <= GET_WRITE_DATA; request_more_data <= 1; end end WRITE_RESPONSE: begin `ifdef VERBOSE $display ("In Write Response"); `endif if (w_out_en) begin if (w_out_status[7:0] == (~(8'h01))) begin `ifdef VERBOSE $display ("TB: Write Response Good"); `endif end else begin `ifdef VERBOSE $display ("TB: Write Response Bad (Malformed response: %h)", w_out_status); `endif end `ifdef VERBOSE $display ("TB: \tS:A:D = %h:%h:%h\n", w_out_status, w_out_address, w_out_data); `endif state <= FINISHED; end end GET_WRITE_DATA: begin if (request_more_data_ack) begin request_more_data <= 0; r_in_ready <= 1; state <= SEND_COMMAND; end end READ_RESPONSE: begin if (w_out_en) begin if (w_out_status[7:0] == (~(8'h02))) begin `ifdef VERBOSE $display ("TB: Read Response Good"); `endif if (w_out_data_count > 0) begin if (data_read_count < w_out_data_count) begin state <= READ_MORE_DATA; timeout_count <= 0; data_read_count <= data_read_count + 1; end else begin state <= FINISHED; end end end else begin `ifdef VERBOSE $display ("TB: Read Response Bad (Malformed response: %h)", w_out_status); `endif state <= FINISHED; end `ifdef VERBOSE $display ("TB: \tS:A:D = %h:%h:%h\n", w_out_status, w_out_address, w_out_data); `endif end end READ_MORE_DATA: begin if (w_out_en) begin timeout_count <= 0; r_out_ready <= 0; `ifdef VERBOSE $display ("TB: Read a 32bit data packet"); `endif `ifdef VERBOSE $display ("TB: \tRead Data: %h", w_out_data); `endif data_read_count <= data_read_count + 1; end if (data_read_count >= r_in_data_count) begin state <= FINISHED; end end FINISHED: begin command_finished <= 1; if (!execute_command) begin `ifdef VERBOSE $display ("Execute Command is low"); `endif command_finished <= 0; state <= IDLE; end end endcase if (w_out_en && w_out_status == `PERIPH_INTERRUPT) begin `ifdef VERBOSE $display("TB: Output Handler Recieved interrupt"); `endif `ifdef VERBOSE $display("TB:\tcommand: %h", w_out_status); `endif `ifdef VERBOSE $display("TB:\taddress: %h", w_out_address); `endif `ifdef VERBOSE $display("TB:\tdata: %h", w_out_data); `endif end end//not reset end endmodule
// Copyright 1986-2017 Xilinx, Inc. All Rights Reserved. // -------------------------------------------------------------------------------- // Tool Version: Vivado v.2017.2 (win64) Build 1909853 Thu Jun 15 18:39:09 MDT 2017 // Date : Tue Sep 19 09:38:30 2017 // Host : DarkCube running 64-bit major release (build 9200) // Command : write_verilog -force -mode synth_stub -rename_top decalper_eb_ot_sdeen_pot_pi_dehcac_xnilix -prefix // decalper_eb_ot_sdeen_pot_pi_dehcac_xnilix_ zynq_design_1_processing_system7_0_0_stub.v // Design : zynq_design_1_processing_system7_0_0 // Purpose : Stub declaration of top-level module interface // Device : xc7z020clg484-1 // -------------------------------------------------------------------------------- // This empty module with port declaration file causes synthesis tools to infer a black box for IP. // The synthesis directives are for Synopsys Synplify support to prevent IO buffer insertion. // Please paste the declaration into a Verilog source file or add the file as an additional source. (* X_CORE_INFO = "processing_system7_v5_5_processing_system7,Vivado 2017.2" ) module decalper_eb_ot_sdeen_pot_pi_dehcac_xnilix(TTC0_WAVE0_OUT, TTC0_WAVE1_OUT, TTC0_WAVE2_OUT, USB0_PORT_INDCTL, USB0_VBUS_PWRSELECT, USB0_VBUS_PWRFAULT, M_AXI_GP0_ARVALID, M_AXI_GP0_AWVALID, M_AXI_GP0_BREADY, M_AXI_GP0_RREADY, M_AXI_GP0_WLAST, M_AXI_GP0_WVALID, M_AXI_GP0_ARID, M_AXI_GP0_AWID, M_AXI_GP0_WID, M_AXI_GP0_ARBURST, M_AXI_GP0_ARLOCK, M_AXI_GP0_ARSIZE, M_AXI_GP0_AWBURST, M_AXI_GP0_AWLOCK, M_AXI_GP0_AWSIZE, M_AXI_GP0_ARPROT, M_AXI_GP0_AWPROT, M_AXI_GP0_ARADDR, M_AXI_GP0_AWADDR, M_AXI_GP0_WDATA, M_AXI_GP0_ARCACHE, M_AXI_GP0_ARLEN, M_AXI_GP0_ARQOS, M_AXI_GP0_AWCACHE, M_AXI_GP0_AWLEN, M_AXI_GP0_AWQOS, M_AXI_GP0_WSTRB, M_AXI_GP0_ACLK, M_AXI_GP0_ARREADY, M_AXI_GP0_AWREADY, M_AXI_GP0_BVALID, M_AXI_GP0_RLAST, M_AXI_GP0_RVALID, M_AXI_GP0_WREADY, M_AXI_GP0_BID, M_AXI_GP0_RID, M_AXI_GP0_BRESP, M_AXI_GP0_RRESP, M_AXI_GP0_RDATA, FCLK_CLK0, FCLK_RESET0_N, FTMT_F2P_TRIG_0, FTMT_F2P_TRIGACK_0, FTMT_P2F_TRIGACK_0, FTMT_P2F_TRIG_0, MIO, DDR_CAS_n, DDR_CKE, DDR_Clk_n, DDR_Clk, DDR_CS_n, DDR_DRSTB, DDR_ODT, DDR_RAS_n, DDR_WEB, DDR_BankAddr, DDR_Addr, DDR_VRN, DDR_VRP, DDR_DM, DDR_DQ, DDR_DQS_n, DDR_DQS, PS_SRSTB, PS_CLK, PS_PORB) / synthesis syn_black_box black_box_pad_pin="TTC0_WAVE0_OUT,TTC0_WAVE1_OUT,TTC0_WAVE2_OUT,USB0_PORT_INDCTL[1:0],USB0_VBUS_PWRSELECT,USB0_VBUS_PWRFAULT,M_AXI_GP0_ARVALID,M_AXI_GP0_AWVALID,M_AXI_GP0_BREADY,M_AXI_GP0_RREADY,M_AXI_GP0_WLAST,M_AXI_GP0_WVALID,M_AXI_GP0_ARID[11:0],M_AXI_GP0_AWID[11:0],M_AXI_GP0_WID[11:0],M_AXI_GP0_ARBURST[1:0],M_AXI_GP0_ARLOCK[1:0],M_AXI_GP0_ARSIZE[2:0],M_AXI_GP0_AWBURST[1:0],M_AXI_GP0_AWLOCK[1:0],M_AXI_GP0_AWSIZE[2:0],M_AXI_GP0_ARPROT[2:0],M_AXI_GP0_AWPROT[2:0],M_AXI_GP0_ARADDR[31:0],M_AXI_GP0_AWADDR[31:0],M_AXI_GP0_WDATA[31:0],M_AXI_GP0_ARCACHE[3:0],M_AXI_GP0_ARLEN[3:0],M_AXI_GP0_ARQOS[3:0],M_AXI_GP0_AWCACHE[3:0],M_AXI_GP0_AWLEN[3:0],M_AXI_GP0_AWQOS[3:0],M_AXI_GP0_WSTRB[3:0],M_AXI_GP0_ACLK,M_AXI_GP0_ARREADY,M_AXI_GP0_AWREADY,M_AXI_GP0_BVALID,M_AXI_GP0_RLAST,M_AXI_GP0_RVALID,M_AXI_GP0_WREADY,M_AXI_GP0_BID[11:0],M_AXI_GP0_RID[11:0],M_AXI_GP0_BRESP[1:0],M_AXI_GP0_RRESP[1:0],M_AXI_GP0_RDATA[31:0],FCLK_CLK0,FCLK_RESET0_N,FTMT_F2P_TRIG_0,FTMT_F2P_TRIGACK_0,FTMT_P2F_TRIGACK_0,FTMT_P2F_TRIG_0,MIO[53:0],DDR_CAS_n,DDR_CKE,DDR_Clk_n,DDR_Clk,DDR_CS_n,DDR_DRSTB,DDR_ODT,DDR_RAS_n,DDR_WEB,DDR_BankAddr[2:0],DDR_Addr[14:0],DDR_VRN,DDR_VRP,DDR_DM[3:0],DDR_DQ[31:0],DDR_DQS_n[3:0],DDR_DQS[3:0],PS_SRSTB,PS_CLK,PS_PORB" */; output TTC0_WAVE0_OUT; output TTC0_WAVE1_OUT; output TTC0_WAVE2_OUT; output [1:0]USB0_PORT_INDCTL; output USB0_VBUS_PWRSELECT; input USB0_VBUS_PWRFAULT; output M_AXI_GP0_ARVALID; output M_AXI_GP0_AWVALID; output M_AXI_GP0_BREADY; output M_AXI_GP0_RREADY; output M_AXI_GP0_WLAST; output M_AXI_GP0_WVALID; output [11:0]M_AXI_GP0_ARID; output [11:0]M_AXI_GP0_AWID; output [11:0]M_AXI_GP0_WID; output [1:0]M_AXI_GP0_ARBURST; output [1:0]M_AXI_GP0_ARLOCK; output [2:0]M_AXI_GP0_ARSIZE; output [1:0]M_AXI_GP0_AWBURST; output [1:0]M_AXI_GP0_AWLOCK; output [2:0]M_AXI_GP0_AWSIZE; output [2:0]M_AXI_GP0_ARPROT; output [2:0]M_AXI_GP0_AWPROT; output [31:0]M_AXI_GP0_ARADDR; output [31:0]M_AXI_GP0_AWADDR; output [31:0]M_AXI_GP0_WDATA; output [3:0]M_AXI_GP0_ARCACHE; output [3:0]M_AXI_GP0_ARLEN; output [3:0]M_AXI_GP0_ARQOS; output [3:0]M_AXI_GP0_AWCACHE; output [3:0]M_AXI_GP0_AWLEN; output [3:0]M_AXI_GP0_AWQOS; output [3:0]M_AXI_GP0_WSTRB; input M_AXI_GP0_ACLK; input M_AXI_GP0_ARREADY; input M_AXI_GP0_AWREADY; input M_AXI_GP0_BVALID; input M_AXI_GP0_RLAST; input M_AXI_GP0_RVALID; input M_AXI_GP0_WREADY; input [11:0]M_AXI_GP0_BID; input [11:0]M_AXI_GP0_RID; input [1:0]M_AXI_GP0_BRESP; input [1:0]M_AXI_GP0_RRESP; input [31:0]M_AXI_GP0_RDATA; output FCLK_CLK0; output FCLK_RESET0_N; input FTMT_F2P_TRIG_0; output FTMT_F2P_TRIGACK_0; input FTMT_P2F_TRIGACK_0; output FTMT_P2F_TRIG_0; inout [53:0]MIO; inout DDR_CAS_n; inout DDR_CKE; inout DDR_Clk_n; inout DDR_Clk; inout DDR_CS_n; inout DDR_DRSTB; inout DDR_ODT; inout DDR_RAS_n; inout DDR_WEB; inout [2:0]DDR_BankAddr; inout [14:0]DDR_Addr; inout DDR_VRN; inout DDR_VRP; inout [3:0]DDR_DM; inout [31:0]DDR_DQ; inout [3:0]DDR_DQS_n; inout [3:0]DDR_DQS; inout PS_SRSTB; inout PS_CLK; inout PS_PORB; endmodule
// ************************************************************************* // *********************************************************************** // Copyright 2011(c) Analog Devices, Inc. // // All rights reserved. // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // - Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // - Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in // the documentation and/or other materials provided with the // distribution. // - Neither the name of Analog Devices, Inc. nor the names of its // contributors may be used to endorse or promote products derived // from this software without specific prior written permission. // - The use of this software may or may not infringe the patent rights // of one or more patent holders. This license does not release you // from the requirement that you obtain separate licenses from these // patent holders to use this software. // - Use of the software either in source or binary form, must be run // on or directly connected to an Analog Devices Inc. component. // // THIS SOFTWARE IS PROVIDED BY ANALOG DEVICES "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, // INCLUDING, BUT NOT LIMITED TO, NON-INFRINGEMENT, MERCHANTABILITY AND FITNESS FOR A // PARTICULAR PURPOSE ARE DISCLAIMED. // // IN NO EVENT SHALL ANALOG DEVICES BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, // EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, INTELLECTUAL PROPERTY // RIGHTS, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR // BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, // STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF // THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // *********************************************************************** // *********************************************************************** // *********************************************************************** // ************************************************************************* // both inputs are considered unsigned 16 bits- // ddata is delay matched generic data `timescale 1ps/1ps module ad_mul_u16 ( // data_p = data_a * data_b; clk, data_a, data_b, data_p, // delay interface ddata_in, ddata_out); // delayed data bus width parameter DELAY_DATA_WIDTH = 16; localparam DW = DELAY_DATA_WIDTH - 1; // data_p = data_a * data_b; input clk; input [15:0] data_a; input [15:0] data_b; output [31:0] data_p; // delay interface input [DW:0] ddata_in; output [DW:0] ddata_out; // internal registers reg [DW:0] p1_ddata = 'd0; reg [DW:0] p2_ddata = 'd0; reg [DW:0] ddata_out = 'd0; // internal signals wire [33:0] data_p_s; // a/b reg, m-reg, p-reg delay match always @(posedge clk) begin p1_ddata <= ddata_in; p2_ddata <= p1_ddata; ddata_out <= p2_ddata; end assign data_p = data_p_s[31:0]; MULT_MACRO #( .LATENCY (3), .A_DATA_WIDTH (17), .B_DATA_WIDTH (17)) i_mult_macro ( .CE (1'b1), .RST (1'b0), .CLK (clk), .A ({1'b0, data_a}), .B ({1'b0, data_b}), .P (data_p_s)); endmodule // ************************************************************************* // *************************************************************************
module ADC_CTRL ( iRST, iCLK, iCLK_n, iGO, oDIN, oCS_n, oSCLK, iDOUT, oADC_12_bit_channel_0, oADC_12_bit_channel_1, oADC_12_bit_channel_2, oADC_12_bit_channel_3, oADC_12_bit_channel_4, oADC_12_bit_channel_5, oADC_12_bit_channel_6, oADC_12_bit_channel_7 ); input iRST; input iCLK; input iCLK_n; input iGO; output oDIN; output oCS_n; output oSCLK; input iDOUT; output reg [11:0] oADC_12_bit_channel_0; output reg [11:0] oADC_12_bit_channel_1; output reg [11:0] oADC_12_bit_channel_2; output reg [11:0] oADC_12_bit_channel_3; output reg [11:0] oADC_12_bit_channel_4; output reg [11:0] oADC_12_bit_channel_5; output reg [11:0] oADC_12_bit_channel_6; output reg [11:0] oADC_12_bit_channel_7; reg [2:0] channel; reg data; reg go_en; reg sclk; reg [3:0] cont; reg [3:0] m_cont; reg [11:0] adc_data; reg [31:0] adc_counter; assign oCS_n = ~go_en; assign oSCLK = (go_en)? iCLK:1; assign oDIN = data; always@( iCLK )//posedge iGO or posedge iRST) begin if(iRST) go_en <= 0; else begin if(iGO) go_en <= 1; end end always@(posedge iCLK or negedge go_en) begin if(!go_en) cont <= 0; else begin if(iCLK) cont <= cont + 1; end end always@(posedge iCLK_n) begin if(iCLK_n) m_cont <= cont; end always@(posedge iCLK_n or negedge go_en) begin if(!go_en) data <= 0; else begin if(iCLK_n) begin if (cont == 2) data <= channel[2]; else if (cont == 3) data <= channel[1]; else if (cont == 4) data <= channel[0]; else data <= 0; end end end always@(posedge iCLK or negedge go_en) begin if(!go_en) begin adc_data <= 0; end else if(iCLK) begin if (m_cont == 4) adc_data[11] <= iDOUT; else if (m_cont == 5) adc_data[10] <= iDOUT; else if (m_cont == 6) adc_data[9] <= iDOUT; else if (m_cont == 7) adc_data[8] <= iDOUT; else if (m_cont == 8) adc_data[7] <= iDOUT; else if (m_cont == 9) adc_data[6] <= iDOUT; else if (m_cont == 10) adc_data[5] <= iDOUT; else if (m_cont == 11) adc_data[4] <= iDOUT; else if (m_cont == 12) adc_data[3] <= iDOUT; else if (m_cont == 13) adc_data[2] <= iDOUT; else if (m_cont == 14) adc_data[1] <= iDOUT; else if (m_cont == 15) adc_data[0] <= iDOUT; else if (m_cont == 1) begin if ( adc_counter < 32'd20 ) begin adc_counter <= adc_counter + 1'b1; end else begin if (channel == 3'd0) oADC_12_bit_channel_0 <= adc_data; else if (channel == 3'd1) oADC_12_bit_channel_1 <= adc_data; else if (channel == 3'd2) oADC_12_bit_channel_2 <= adc_data; else if (channel == 3'd3) oADC_12_bit_channel_3 <= adc_data; else if (channel == 3'd4) oADC_12_bit_channel_4 <= adc_data; else if (channel == 3'd5) oADC_12_bit_channel_5 <= adc_data; else if (channel == 3'd6) oADC_12_bit_channel_6 <= adc_data; else if (channel == 3'd7) oADC_12_bit_channel_7 <= adc_data; adc_counter <= 32'd0; channel <= channel + 1'b1; end end end end endmodule
`timescale 1ns/1ns `define IDLE 2'b00 `define LOAD 2'b01 `define CNTING 2'b10 `define INT 2'b11 `define MODE_0 2'b00 `define MODE_1 2'b01 module coco_timer (clk_i,rst_i,add_i,we_i,dat_i,dat_o,irq); input [3:2] add_i; input clk_i,rst_i,we_i; input [31:0] dat_i; output [31:0] dat_o; output irq; reg [31:0] count; reg [31:0] preset; reg [31:0] ctrl; reg _irq; reg [1:0] curr_state,next_state; assign dat_o=(add_i==2'b00)?ctrl: (add_i==2'b01)?preset: (add_i==2'b10)?count: 32'h12345678; assign irq=_irq; always @(posedge clk_i or posedge rst_i) begin if (rst_i) begin count<=31'h0000_0000; preset<=31'h0000_0000; ctrl<=31'h0000_0000; _irq<=0; curr_state<=`IDLE; end // if(rst) else if (we_i) begin if (add_i==2'b00) begin ctrl<=dat_i; curr_state<=next_state; end // if(dat_i) else if (add_i==2'b01) begin preset<=dat_i; _irq<=0; next_state<=`LOAD; end // if(add_i=2'b01) else if (add_i==2'b10) begin count<=dat_i; curr_state<=next_state; end else begin curr_state<=next_state; end end // if(we) else begin curr_state<=next_state; end end // always @ (posedge clk_i or posedge rst_i) always @(curr_state or ctrl or count) begin next_state=`IDLE; if (!ctrl[0]) begin next_state=`IDLE; end // if(ctrl[0]) else begin case (curr_state) `IDLE: begin if (ctrl[2:1]==`MODE_1) begin next_state=`LOAD; end // if(ctrl[2:1]) //ctrl[2:1]==`MODE_0 else if (ctrl[0] && count>1) begin next_state=`CNTING; end else begin next_state=`IDLE; end end // case: IDLE `LOAD: begin next_state=`CNTING; end `CNTING: begin if (count==1) begin next_state=`INT; end // if(count==1) else begin next_state=`CNTING; end end default: begin next_state=`IDLE; end endcase // case(curr_state) end end // always @ (curr_state) always @(posedge clk_i or posedge rst_i) begin case (next_state) `CNTING: begin count<=count-1; end `INT: begin _irq<=(ctrl[3]&&ctrl[2:1]==`MODE_0); end `LOAD: begin count<=preset; _irq<=0; end default: begin //do nothing end endcase // case(next_state) end endmodule // cp0
`include "hi_read_tx.v" /* pck0 - input main 24Mhz clock (PLL / 4) [7:0] adc_d - input data from A/D converter shallow_modulation - modulation type pwr_lo - output to coil drivers (ssp_clk / 8) adc_clk - output A/D clock signal ssp_frame - output SSS frame indicator (goes high while the 8 bits are shifted) ssp_din - output SSP data to ARM (shifts 8 bit A/D value serially to ARM MSB first) ssp_clk - output SSP clock signal ck_1356meg - input unused ck_1356megb - input unused ssp_dout - input unused cross_hi - input unused cross_lo - input unused pwr_hi - output unused, tied low pwr_oe1 - output unused, undefined pwr_oe2 - output unused, undefined pwr_oe3 - output unused, undefined pwr_oe4 - output unused, undefined dbg - output alias for adc_clk */ module testbed_hi_read_tx; reg pck0; reg [7:0] adc_d; reg shallow_modulation; wire pwr_lo; wire adc_clk; reg ck_1356meg; reg ck_1356megb; wire ssp_frame; wire ssp_din; wire ssp_clk; reg ssp_dout; wire pwr_hi; wire pwr_oe1; wire pwr_oe2; wire pwr_oe3; wire pwr_oe4; wire cross_lo; wire cross_hi; wire dbg; hi_read_tx #(5,200) dut( .pck0(pck0), .ck_1356meg(ck_1356meg), .ck_1356megb(ck_1356megb), .pwr_lo(pwr_lo), .pwr_hi(pwr_hi), .pwr_oe1(pwr_oe1), .pwr_oe2(pwr_oe2), .pwr_oe3(pwr_oe3), .pwr_oe4(pwr_oe4), .adc_d(adc_d), .adc_clk(adc_clk), .ssp_frame(ssp_frame), .ssp_din(ssp_din), .ssp_dout(ssp_dout), .ssp_clk(ssp_clk), .cross_hi(cross_hi), .cross_lo(cross_lo), .dbg(dbg), .shallow_modulation(shallow_modulation) ); integer idx, i; // main clock always #5 begin ck_1356megb = !ck_1356megb; ck_1356meg = ck_1356megb; end //crank DUT task crank_dut; begin @(posedge ssp_clk) ; ssp_dout = $random; end endtask initial begin // init inputs ck_1356megb = 0; adc_d = 0; ssp_dout=0; // shallow modulation off shallow_modulation=0; for (i = 0 ; i < 16 ; i = i + 1) begin crank_dut; end // shallow modulation on shallow_modulation=1; for (i = 0 ; i < 16 ; i = i + 1) begin crank_dut; end $finish; end endmodule // main
// // Copyright (c) 1999 Steven Wilson ([email protected]) // // This source code is free software; you can redistribute it // and/or modify it in source code form under the terms of the GNU // General Public License as published by the Free Software // Foundation; either version 2 of the License, or (at your option) // any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA // // SDW - Validate unary nor ~\|(value) // SJW - ~\| in behavioral assignment to reg. module main; reg [3:0] vect; reg error; reg result; initial begin error = 0; for(vect=4'b0001;vect<4'b1111;vect = vect + 1) begin result = ~\| vect; if(result !== 1'b0) begin $display("FAILED - Unary nor ~\|(%b)=%b",vect,result); error = 1'b1; end end #1; vect = 4'b0000; result = ~\| vect; if(result !== 1'b1) begin $display("FAILED - Unary nor \|~(%b)=%b",vect,result); error = 1'b1; end if(error === 0 ) $display("PASSED"); end endmodule // main
`timescale 1ns / 1ps ////////////////////////////////////////////////////////////////////////////////// // Company: // Engineer: // // Create Date: 22:40:46 12/20/2010 // Design Name: // Module Name: clk_test // Project Name: // Target Devices: // Tool versions: // Description: // // Dependencies: // // Revision: // Revision 0.01 - File Created // Additional Comments: // ////////////////////////////////////////////////////////////////////////////////// module clk_test( input clk, input sysclk, output [31:0] snes_sysclk_freq ); reg [31:0] snes_sysclk_freq_r; assign snes_sysclk_freq = snes_sysclk_freq_r; reg [31:0] sysclk_counter; reg [31:0] sysclk_value; initial snes_sysclk_freq_r = 32'hFFFFFFFF; initial sysclk_counter = 0; initial sysclk_value = 0; reg [1:0] sysclk_sreg; always @(posedge clk) sysclk_sreg <= {sysclk_sreg[0], sysclk}; wire sysclk_rising = (sysclk_sreg == 2'b01); always @(posedge clk) begin if(sysclk_counter < 96000000) begin sysclk_counter <= sysclk_counter + 1; if(sysclk_rising) sysclk_value <= sysclk_value + 1; end else begin snes_sysclk_freq_r <= sysclk_value; sysclk_counter <= 0; sysclk_value <= 0; end end endmodule
// (C) 2001-2016 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. // synthesis translate_off `timescale 1ns / 1ps // synthesis translate_on // turn off superfluous verilog processor warnings // altera message_level Level1 // altera message_off 10034 10035 10036 10037 10230 10240 10030 module efifo_module #( parameter DATA_WIDTH = 16, parameter DEPTH = 2 )( // inputs: clk, rd, rst_n, wr, wr_data, // outputs: almost_empty, almost_full, empty, full, rd_data ) ; output almost_empty; output almost_full; output empty; output full; output [ DATA_WIDTH - 1 : 0 ] rd_data; input clk; input rd; input rst_n; input wr; input [ DATA_WIDTH - 1 : 0 ] wr_data; wire almost_empty; wire almost_full; wire empty; reg [ DEPTH - 1 : 0 ] entries; reg [ DATA_WIDTH - 1 : 0 ] entry_0; reg [ DATA_WIDTH - 1 : 0 ] entry_1; wire full; reg rd_address; reg [ DATA_WIDTH - 1 : 0 ] rd_data; wire [ 1: 0] rdwr; reg wr_address; assign rdwr = {rd, wr}; assign full = entries == DEPTH; assign almost_full = entries >= DEPTH - 1; assign empty = entries == 0; assign almost_empty = entries <= DEPTH - 1; always @(entry_0 or entry_1 or rd_address) begin case (rd_address) // synthesis parallel_case full_case 1'd0: begin rd_data = entry_0; end // 1'd0 1'd1: begin rd_data = entry_1; end // 1'd1 default: begin end // default endcase // rd_address end always @(posedge clk or negedge rst_n) begin if (rst_n == 0) begin wr_address <= 0; rd_address <= 0; entries <= 0; end else case (rdwr) // synthesis parallel_case full_case 2'd1: begin // Write data if (!full) begin entries <= entries + 1; wr_address <= (wr_address == 1) ? 0 : (wr_address + 1); end end // 2'd1 2'd2: begin // Read data if (!empty) begin entries <= entries - 1; rd_address <= (rd_address == 1) ? 0 : (rd_address + 1); end end // 2'd2 2'd3: begin wr_address <= (wr_address == 1) ? 0 : (wr_address + 1); rd_address <= (rd_address == 1) ? 0 : (rd_address + 1); end // 2'd3 default: begin end // default endcase // rdwr end always @(posedge clk) begin //Write data if (wr & !full) case (wr_address) // synthesis parallel_case full_case 1'd0: begin entry_0 <= wr_data; end // 1'd0 1'd1: begin entry_1 <= wr_data; end // 1'd1 default: begin end // default endcase // wr_address end endmodule
/** * This is written by Zhiyang Ong * and Andrew Mattheisen * for EE577b Troy WideWord Processor Project / // Behavioral model for the 32-bit program counter module program_counter2 (next_pc,rst,clk); // Output signals... // Incremented value of the program counter output [0:31] next_pc; // =============================================================== // Input signals // Clock signal for the program counter input clk; // Reset signal for the program counter input rst; /* * May also include: branch_offset[n:0], is_branch * Size of branch offset is specified in the Instruction Set * Architecture */ // =============================================================== // Declare "wire" signals: //wire FSM_OUTPUT; // =============================================================== // Declare "reg" signals: reg [0:31] next_pc; // Output signals // =============================================================== always @(posedge clk) begin // If the reset signal sis set to HIGH if(rst) begin // Set its value to ZERO next_pc<=32'd0; end else begin next_pc<=next_pc+32'd4; end end endmodule
(** * Poly: Polymorphism and Higher-Order Functions ) (* In this chapter we continue our development of basic concepts of functional programming. The critical new ideas are _polymorphism_ (abstracting functions over the types of the data they manipulate) and _higher-order functions_ (treating functions as data). ) Require Export Lists. ( ###################################################### ) (* * Polymorphism ) ( ###################################################### ) (* ** Polymorphic Lists ) (* For the last couple of chapters, we've been working just with lists of numbers. Obviously, interesting programs also need to be able to manipulate lists with elements from other types -- lists of strings, lists of booleans, lists of lists, etc. We _could_ just define a new inductive datatype for each of these, for example... ) Inductive boollist : Type := \| bool_nil : boollist \| bool_cons : bool -> boollist -> boollist. (* ... but this would quickly become tedious, partly because we have to make up different constructor names for each datatype, but mostly because we would also need to define new versions of all our list manipulating functions ([length], [rev], etc.) for each new datatype definition. ) (* *** ) (* To avoid all this repetition, Coq supports _polymorphic_ inductive type definitions. For example, here is a _polymorphic list_ datatype. ) Inductive list (X:Type) : Type := \| nil : list X \| cons : X -> list X -> list X. (* This is exactly like the definition of [natlist] from the previous chapter, except that the [nat] argument to the [cons] constructor has been replaced by an arbitrary type [X], a binding for [X] has been added to the header, and the occurrences of [natlist] in the types of the constructors have been replaced by [list X]. (We can re-use the constructor names [nil] and [cons] because the earlier definition of [natlist] was inside of a [Module] definition that is now out of scope.) ) (* What sort of thing is [list] itself? One good way to think about it is that [list] is a _function_ from [Type]s to [Inductive] definitions; or, to put it another way, [list] is a function from [Type]s to [Type]s. For any particular type [X], the type [list X] is an [Inductive]ly defined set of lists whose elements are things of type [X]. ) (* With this definition, when we use the constructors [nil] and [cons] to build lists, we need to tell Coq the type of the elements in the lists we are building -- that is, [nil] and [cons] are now _polymorphic constructors_. Observe the types of these constructors: ) Check nil. ( ===> nil : forall X : Type, list X ) Check cons. ( ===> cons : forall X : Type, X -> list X -> list X ) (* The "[forall X]" in these types can be read as an additional argument to the constructors that determines the expected types of the arguments that follow. When [nil] and [cons] are used, these arguments are supplied in the same way as the others. For example, the list containing [2] and [1] is written like this: ) Check (cons nat 2 (cons nat 1 (nil nat))). (* (We've gone back to writing [nil] and [cons] explicitly here because we haven't yet defined the [ [] ] and [::] notations for the new version of lists. We'll do that in a bit.) ) (* We can now go back and make polymorphic (or "generic") versions of all the list-processing functions that we wrote before. Here is [length], for example: ) (* *** ) Fixpoint length (X:Type) (l:list X) : nat := match l with \| nil => 0 \| cons h t => S (length X t) end. (* Note that the uses of [nil] and [cons] in [match] patterns do not require any type annotations: Coq already knows that the list [l] contains elements of type [X], so there's no reason to include [X] in the pattern. (More precisely, the type [X] is a parameter of the whole definition of [list], not of the individual constructors. We'll come back to this point later.) As with [nil] and [cons], we can use [length] by applying it first to a type and then to its list argument: ) Example test_length1 : length nat (cons nat 1 (cons nat 2 (nil nat))) = 2. Proof. reflexivity. Qed. (* To use our length with other kinds of lists, we simply instantiate it with an appropriate type parameter: ) Example test_length2 : length bool (cons bool true (nil bool)) = 1. Proof. reflexivity. Qed. (* *** ) (* Let's close this subsection by re-implementing a few other standard list functions on our new polymorphic lists: ) Fixpoint app (X : Type) (l1 l2 : list X) : (list X) := match l1 with \| nil => l2 \| cons h t => cons X h (app X t l2) end. Fixpoint snoc (X:Type) (l:list X) (v:X) : (list X) := match l with \| nil => cons X v (nil X) \| cons h t => cons X h (snoc X t v) end. Fixpoint rev (X:Type) (l:list X) : list X := match l with \| nil => nil X \| cons h t => snoc X (rev X t) h end. Example test_rev1 : rev nat (cons nat 1 (cons nat 2 (nil nat))) = (cons nat 2 (cons nat 1 (nil nat))). Proof. reflexivity. Qed. Example test_rev2: rev bool (nil bool) = nil bool. Proof. reflexivity. Qed. Module MumbleBaz. (* **** Exercise: 2 stars (mumble_grumble) ) (* Consider the following two inductively defined types. ) Inductive mumble : Type := \| a : mumble \| b : mumble -> nat -> mumble \| c : mumble. Inductive grumble (X:Type) : Type := \| d : mumble -> grumble X \| e : X -> grumble X. (* Which of the following are well-typed elements of [grumble X] for some type [X]? - [d (b a 5)] : No. - [d mumble (b a 5)] : Yes (grumble mumble). - [d bool (b a 5)] : Yes (grumble bool). - [e bool true] : Yes (grumble bool). - [e mumble (b c 0)] : Yes (grumble mumble). - [e bool (b c 0)] : No. - [c] : No (type mumble). [] ) (* **** Exercise: 2 stars (baz_num_elts) ) (* Consider the following inductive definition: ) Inductive baz : Type := \| x : baz -> baz \| y : baz -> bool -> baz. (* How _many_ elements does the type [baz] have? Confused by definition of "element" here. x: 0 elements (just the continuation of the data structure) y: 1 element (a bool, and the continuation of baz) [] ) End MumbleBaz. ( ###################################################### ) (* *** Type Annotation Inference ) (* Let's write the definition of [app] again, but this time we won't specify the types of any of the arguments. Will Coq still accept it? ) Fixpoint app' X l1 l2 : list X := match l1 with \| nil => l2 \| cons h t => cons X h (app' X t l2) end. (* Indeed it will. Let's see what type Coq has assigned to [app']: ) Check app'. ( ===> forall X : Type, list X -> list X -> list X ) Check app. ( ===> forall X : Type, list X -> list X -> list X ) (* It has exactly the same type type as [app]. Coq was able to use a process called _type inference_ to deduce what the types of [X], [l1], and [l2] must be, based on how they are used. For example, since [X] is used as an argument to [cons], it must be a [Type], since [cons] expects a [Type] as its first argument; matching [l1] with [nil] and [cons] means it must be a [list]; and so on. This powerful facility means we don't always have to write explicit type annotations everywhere, although explicit type annotations are still quite useful as documentation and sanity checks. You should try to find a balance in your own code between too many type annotations (so many that they clutter and distract) and too few (which forces readers to perform type inference in their heads in order to understand your code). ) ( ###################################################### ) (* *** Type Argument Synthesis ) (* Whenever we use a polymorphic function, we need to pass it one or more types in addition to its other arguments. For example, the recursive call in the body of the [length] function above must pass along the type [X]. But just like providing explicit type annotations everywhere, this is heavy and verbose. Since the second argument to [length] is a list of [X]s, it seems entirely obvious that the first argument can only be [X] -- why should we have to write it explicitly? Fortunately, Coq permits us to avoid this kind of redundancy. In place of any type argument we can write the "implicit argument" [_], which can be read as "Please figure out for yourself what type belongs here." More precisely, when Coq encounters a [_], it will attempt to _unify_ all locally available information -- the type of the function being applied, the types of the other arguments, and the type expected by the context in which the application appears -- to determine what concrete type should replace the [_]. This may sound similar to type annotation inference -- and, indeed, the two procedures rely on the same underlying mechanisms. Instead of simply omitting the types of some arguments to a function, like app' X l1 l2 : list X := we can also replace the types with [_], like app' (X : _) (l1 l2 : _) : list X := which tells Coq to attempt to infer the missing information, just as with argument synthesis. Using implicit arguments, the [length] function can be written like this: ) Fixpoint length' (X:Type) (l:list X) : nat := match l with \| nil => 0 \| cons h t => S (length' _ t) end. (* In this instance, we don't save much by writing [_] instead of [X]. But in many cases the difference can be significant. For example, suppose we want to write down a list containing the numbers [1], [2], and [3]. Instead of writing this... ) Definition list123 := cons nat 1 (cons nat 2 (cons nat 3 (nil nat))). (* ...we can use argument synthesis to write this: ) Definition list123' := cons _ 1 (cons _ 2 (cons _ 3 (nil _))). ( ###################################################### ) (* *** Implicit Arguments ) (* If fact, we can go further. To avoid having to sprinkle [_]'s throughout our programs, we can tell Coq _always_ to infer the type argument(s) of a given function. The [Arguments] directive specifies the name of the function or constructor, and then lists its argument names, with curly braces around any arguments to be treated as implicit. ) Arguments nil {X}. Arguments cons {X} _ _. ( use underscore for argument position that has no name ) Arguments length {X} l. Arguments app {X} l1 l2. Arguments rev {X} l. Arguments snoc {X} l v. ( note: no _ arguments required... ) Definition list123'' := cons 1 (cons 2 (cons 3 nil)). Check (length list123''). (* *** ) (* Alternatively, we can declare an argument to be implicit while defining the function itself, by surrounding the argument in curly braces. For example: ) Fixpoint length'' {X:Type} (l:list X) : nat := match l with \| nil => 0 \| cons h t => S (length'' t) end. (* (Note that we didn't even have to provide a type argument to the recursive call to [length'']; indeed, it is invalid to provide one.) We will use this style whenever possible, although we will continue to use use explicit [Argument] declarations for [Inductive] constructors. ) (* *** ) (* One small problem with declaring arguments [Implicit] is that, occasionally, Coq does not have enough local information to determine a type argument; in such cases, we need to tell Coq that we want to give the argument explicitly this time, even though we've globally declared it to be [Implicit]. For example, suppose we write this: ) ( Definition mynil := nil. ) (* If we uncomment this definition, Coq will give us an error, because it doesn't know what type argument to supply to [nil]. We can help it by providing an explicit type declaration (so that Coq has more information available when it gets to the "application" of [nil]): ) Definition mynil : list nat := nil. (* Alternatively, we can force the implicit arguments to be explicit by prefixing the function name with [@]. ) Check @nil. Definition mynil' := @nil nat. (* *** ) (* Using argument synthesis and implicit arguments, we can define convenient notation for lists, as before. Since we have made the constructor type arguments implicit, Coq will know to automatically infer these when we use the notations. ) Notation "x :: y" := (cons x y) (at level 60, right associativity). Notation "[ ]" := nil. Notation "[ x ; .. ; y ]" := (cons x .. (cons y []) ..). Notation "x ++ y" := (app x y) (at level 60, right associativity). (* Now lists can be written just the way we'd hope: ) Definition list123''' := [1; 2; 3]. Check ([3 + 4] ++ nil). ( ###################################################### ) (* *** Exercises: Polymorphic Lists ) (* **** Exercise: 2 stars, optional (poly_exercises) ) (* Here are a few simple exercises, just like ones in the [Lists] chapter, for practice with polymorphism. Fill in the definitions and complete the proofs below. ) Fixpoint repeat {X : Type} (n : X) (count : nat) : list X := match count with \| 0 => nil \| S count' => n :: repeat n count' end. Example test_repeat1: repeat true 2 = cons true (cons true nil). reflexivity. Qed. Theorem nil_app : forall X:Type, forall l:list X, app [] l = l. Proof. reflexivity. Qed. Theorem rev_snoc : forall X : Type, forall v : X, forall s : list X, rev (snoc s v) = v :: (rev s). Proof. intros X v s. induction s as [\|h t]. Case "s = []". simpl. reflexivity. Case "s = h::t". simpl. rewrite IHt. simpl. reflexivity. Qed. Theorem rev_involutive : forall X : Type, forall l : list X, rev (rev l) = l. Proof. intros X l. induction l as [\|v l']. Case "l = []". simpl. reflexivity. Case "l = v::l'". simpl. rewrite rev_snoc. rewrite IHl'. reflexivity. Qed. Theorem snoc_append : forall X (l:list X) x, snoc l x = l ++ [x]. Proof. intros X l x. induction l as [\|y l']. Case "l=[]". reflexivity. Case "l=y::l'". simpl. rewrite IHl'. reflexivity. Qed. Theorem snoc_with_append : forall X : Type, forall l1 l2 : list X, forall v : X, snoc (l1 ++ l2) v = l1 ++ (snoc l2 v). Proof. intros X l1 l2 v. induction l1 as [\|x l']. Case "l1 = []". simpl. reflexivity. Case "l1=x::l'". simpl. rewrite IHl'. reflexivity. Qed. Theorem rev_app : forall X (l:list X) x, x :: rev l = rev (l ++ [x]). Proof. intros X l. induction l as [\|y l']. Case "l=[]". simpl. reflexivity. Case "l=y::l'". intros. simpl. rewrite snoc_append. rewrite <- IHl'. simpl. rewrite snoc_append. reflexivity. Qed. (* [] ) Theorem cons_app_assoc : forall X (l1 l2:list X) x, (x :: l1) ++ l2 = x :: (l1 ++ l2). Proof. intros. reflexivity. Qed. ( ###################################################### ) (* ** Polymorphic Pairs ) (* Following the same pattern, the type definition we gave in the last chapter for pairs of numbers can be generalized to _polymorphic pairs_ (or _products_): ) Inductive prod (X Y : Type) : Type := pair : X -> Y -> prod X Y. Arguments pair {X} {Y} _ _. (* As with lists, we make the type arguments implicit and define the familiar concrete notation. ) Notation "( x , y )" := (pair x y). (* We can also use the [Notation] mechanism to define the standard notation for pair _types_: ) Notation "X Y" := (prod X Y) : type_scope. (** (The annotation [: type_scope] tells Coq that this abbreviation should be used when parsing types. This avoids a clash with the multiplication symbol.) ) (* *** ) (* A note of caution: it is easy at first to get [(x,y)] and [XY] confused. Remember that [(x,y)] is a _value_ built from two other values; [XY] is a _type_ built from two other types. If [x] has type [X] and [y] has type [Y], then [(x,y)] has type [XY]. ) (** The first and second projection functions now look pretty much as they would in any functional programming language. ) Definition fst {X Y : Type} (p : X Y) : X := match p with (x,y) => x end. Definition snd {X Y : Type} (p : X * Y) : Y := match p with (x,y) => y end. (** The following function takes two lists and combines them into a list of pairs. In many functional programming languages, it is called [zip]. We call it [combine] for consistency with Coq's standard library. ) (* Note that the pair notation can be used both in expressions and in patterns... ) Fixpoint combine {X Y : Type} (lx : list X) (ly : list Y) : list (XY) := match (lx,ly) with \| ([],_) => [] \| (_,[]) => [] \| (x::tx, y::ty) => (x,y) :: (combine tx ty) end. ( ** Exercise: 1 star, optional (combine_checks) ) (* Try answering the following questions on paper and checking your answers in coq: - What is the type of [combine] (i.e., what does [Check @combine] print?) forall X Y : Type, list X -> list Y -> list (XY) - What does Eval compute in (combine [1;2] [false;false;true;true]). print? [(1,false);(2,false)] : list (natbool) ) (* **** Exercise: 2 stars (split) ) (* The function [split] is the right inverse of combine: it takes a list of pairs and returns a pair of lists. In many functional programing languages, this function is called [unzip]. Uncomment the material below and fill in the definition of [split]. Make sure it passes the given unit tests. ) Fixpoint split {X Y : Type} (l : list (XY)) : (list X) * (list Y) := match l with \| [] => ([],[]) \| (x,y) :: ls => (x :: fst (split ls), y :: snd (split ls)) end. Example test_split: split [(1,false);(2,false)] = ([1;2],[false;false]). Proof. reflexivity. Qed. (** [] ) ( ###################################################### ) (* ** Polymorphic Options ) (* One last polymorphic type for now: _polymorphic options_. The type declaration generalizes the one for [natoption] in the previous chapter: ) Inductive option (X:Type) : Type := \| Some : X -> option X \| None : option X. Arguments Some {X} _. Arguments None {X}. (* *** ) (* We can now rewrite the [index] function so that it works with any type of lists. ) Fixpoint index {X : Type} (n : nat) (l : list X) : option X := match l with \| [] => None \| a :: l' => if beq_nat n O then Some a else index (pred n) l' end. Example test_index1 : index 0 [4;5;6;7] = Some 4. Proof. reflexivity. Qed. Example test_index2 : index 1 [[1];[2]] = Some [2]. Proof. reflexivity. Qed. Example test_index3 : index 2 [true] = None. Proof. reflexivity. Qed. (* **** Exercise: 1 star, optional (hd_opt_poly) ) (* Complete the definition of a polymorphic version of the [hd_opt] function from the last chapter. Be sure that it passes the unit tests below. ) Definition hd_opt {X : Type} (l : list X) : option X := match l with \| [] => None \| x :: _ => Some x end. (* Once again, to force the implicit arguments to be explicit, we can use [@] before the name of the function. ) Check @hd_opt. Example test_hd_opt1 : hd_opt [1;2] = Some 1. reflexivity. Qed. Example test_hd_opt2 : hd_opt [[1];[2]] = Some [1]. reflexivity. Qed. (* [] ) ( ###################################################### ) (* * Functions as Data ) ( ###################################################### ) (* ** Higher-Order Functions ) (* Like many other modern programming languages -- including all _functional languages_ (ML, Haskell, Scheme, etc.) -- Coq treats functions as first-class citizens, allowing functions to be passed as arguments to other functions, returned as results, stored in data structures, etc. Functions that manipulate other functions are often called _higher-order_ functions. Here's a simple one: ) Definition doit3times {X:Type} (f:X->X) (n:X) : X := f (f (f n)). (* The argument [f] here is itself a function (from [X] to [X]); the body of [doit3times] applies [f] three times to some value [n]. ) Check @doit3times. ( ===> doit3times : forall X : Type, (X -> X) -> X -> X ) Example test_doit3times: doit3times minustwo 9 = 3. Proof. reflexivity. Qed. Example test_doit3times': doit3times negb true = false. Proof. reflexivity. Qed. ( ###################################################### ) (* ** Partial Application ) (* In fact, the multiple-argument functions we have already seen are also examples of passing functions as data. To see why, recall the type of [plus]. ) Check plus. ( ==> nat -> nat -> nat ) (* Each [->] in this expression is actually a _binary_ operator on types. (This is the same as saying that Coq primitively supports only one-argument functions -- do you see why?) This operator is _right-associative_, so the type of [plus] is really a shorthand for [nat -> (nat -> nat)] -- i.e., it can be read as saying that "[plus] is a one-argument function that takes a [nat] and returns a one-argument function that takes another [nat] and returns a [nat]." In the examples above, we have always applied [plus] to both of its arguments at once, but if we like we can supply just the first. This is called _partial application_. ) Definition plus3 := plus 3. Check plus3. Example test_plus3 : plus3 4 = 7. Proof. reflexivity. Qed. Example test_plus3' : doit3times plus3 0 = 9. Proof. reflexivity. Qed. Example test_plus3'' : doit3times (plus 3) 0 = 9. Proof. reflexivity. Qed. ( ###################################################### ) (* ** Digression: Currying ) (* **** Exercise: 2 stars, advanced (currying) ) (* In Coq, a function [f : A -> B -> C] really has the type [A -> (B -> C)]. That is, if you give [f] a value of type [A], it will give you function [f' : B -> C]. If you then give [f'] a value of type [B], it will return a value of type [C]. This allows for partial application, as in [plus3]. Processing a list of arguments with functions that return functions is called _currying_, in honor of the logician Haskell Curry. Conversely, we can reinterpret the type [A -> B -> C] as [(A * B) -> C]. This is called _uncurrying_. With an uncurried binary function, both arguments must be given at once as a pair; there is no partial application. ) (* We can define currying as follows: ) Definition prod_curry {X Y Z : Type} (f : X Y -> Z) (x : X) (y : Y) : Z := f (x, y). (** As an exercise, define its inverse, [prod_uncurry]. Then prove the theorems below to show that the two are inverses. ) Definition prod_uncurry {X Y Z : Type} (f : X -> Y -> Z) (p : X Y) : Z := f (fst p) (snd p). (** (Thought exercise: before running these commands, can you calculate the types of [prod_curry] and [prod_uncurry]?) ) Check @prod_curry. Check @prod_uncurry. Theorem uncurry_curry : forall (X Y Z : Type) (f : X -> Y -> Z) x y, prod_curry (prod_uncurry f) x y = f x y. Proof. reflexivity. Qed. Theorem curry_uncurry : forall (X Y Z : Type) (f : (X Y) -> Z) (p : X * Y), prod_uncurry (prod_curry f) p = f p. Proof. intros X Y Z f p. destruct p. reflexivity. Qed. (** [] ) ( ###################################################### ) (* ** Filter ) (* Here is a useful higher-order function, which takes a list of [X]s and a _predicate_ on [X] (a function from [X] to [bool]) and "filters" the list, returning a new list containing just those elements for which the predicate returns [true]. ) Fixpoint filter {X:Type} (test: X->bool) (l:list X) : (list X) := match l with \| [] => [] \| h :: t => if test h then h :: (filter test t) else filter test t end. (* For example, if we apply [filter] to the predicate [evenb] and a list of numbers [l], it returns a list containing just the even members of [l]. ) Example test_filter1: filter evenb [1;2;3;4] = [2;4]. Proof. reflexivity. Qed. (* *** ) Definition length_is_1 {X : Type} (l : list X) : bool := beq_nat (length l) 1. Example test_filter2: filter length_is_1 [ [1; 2]; [3]; [4]; [5;6;7]; []; [8] ] = [ [3]; [4]; [8] ]. Proof. reflexivity. Qed. (* *** ) (* We can use [filter] to give a concise version of the [countoddmembers] function from the [Lists] chapter. ) Definition countoddmembers' (l:list nat) : nat := length (filter oddb l). Example test_countoddmembers'1: countoddmembers' [1;0;3;1;4;5] = 4. Proof. reflexivity. Qed. Example test_countoddmembers'2: countoddmembers' [0;2;4] = 0. Proof. reflexivity. Qed. Example test_countoddmembers'3: countoddmembers' nil = 0. Proof. reflexivity. Qed. ( ###################################################### ) (* ** Anonymous Functions ) (* It is a little annoying to be forced to define the function [length_is_1] and give it a name just to be able to pass it as an argument to [filter], since we will probably never use it again. Moreover, this is not an isolated example. When using higher-order functions, we often want to pass as arguments "one-off" functions that we will never use again; having to give each of these functions a name would be tedious. Fortunately, there is a better way. It is also possible to construct a function "on the fly" without declaring it at the top level or giving it a name; this is analogous to the notation we've been using for writing down constant lists, natural numbers, and so on. ) Example test_anon_fun': doit3times (fun n => n n) 2 = 256. Proof. reflexivity. Qed. (** Here is the motivating example from before, rewritten to use an anonymous function. ) Example test_filter2': filter (fun l => beq_nat (length l) 1) [ [1; 2]; [3]; [4]; [5;6;7]; []; [8] ] = [ [3]; [4]; [8] ]. Proof. reflexivity. Qed. (* **** Exercise: 2 stars (filter_even_gt7) ) (* Use [filter] (instead of [Fixpoint]) to write a Coq function [filter_even_gt7] that takes a list of natural numbers as input and returns a list of just those that are even and greater than 7. ) Definition filter_even_gt7 (l : list nat) : list nat := filter (fun n => andb (negb (ble_nat n 7)) (evenb n)) l. Example test_filter_even_gt7_1 : filter_even_gt7 [1;2;6;9;10;3;12;8] = [10;12;8]. reflexivity. Qed. Example test_filter_even_gt7_2 : filter_even_gt7 [5;2;6;19;129] = []. reflexivity. Qed. (* [] ) (* **** Exercise: 3 stars (partition) ) (* Use [filter] to write a Coq function [partition]: partition : forall X : Type, (X -> bool) -> list X -> list X * list X Given a set [X], a test function of type [X -> bool] and a [list X], [partition] should return a pair of lists. The first member of the pair is the sublist of the original list containing the elements that satisfy the test, and the second is the sublist containing those that fail the test. The order of elements in the two sublists should be the same as their order in the original list. ) Definition partition {X : Type} (test : X -> bool) (l : list X) : list X list X := (filter test l, filter (fun n => negb (test n)) l). Example test_partition1: partition oddb [1;2;3;4;5] = ([1;3;5], [2;4]). reflexivity. Qed. Example test_partition2: partition (fun x => false) [5;9;0] = ([], [5;9;0]). reflexivity. Qed. (** [] ) ( ###################################################### ) (* ** Map ) (* Another handy higher-order function is called [map]. ) Fixpoint map {X Y:Type} (f:X->Y) (l:list X) : (list Y) := match l with \| [] => [] \| h :: t => (f h) :: (map f t) end. (* *** ) (* It takes a function [f] and a list [ l = [n1, n2, n3, ...] ] and returns the list [ [f n1, f n2, f n3,...] ], where [f] has been applied to each element of [l] in turn. For example: ) Example test_map1: map (plus 3) [2;0;2] = [5;3;5]. Proof. reflexivity. Qed. (* The element types of the input and output lists need not be the same ([map] takes _two_ type arguments, [X] and [Y]). This version of [map] can thus be applied to a list of numbers and a function from numbers to booleans to yield a list of booleans: ) Example test_map2: map oddb [2;1;2;5] = [false;true;false;true]. Proof. reflexivity. Qed. (* It can even be applied to a list of numbers and a function from numbers to _lists_ of booleans to yield a list of lists of booleans: ) Example test_map3: map (fun n => [evenb n;oddb n]) [2;1;2;5] = [[true;false];[false;true];[true;false];[false;true]]. Proof. reflexivity. Qed. (* ** Map for options ) (* **** Exercise: 3 stars (map_rev) ) (* Show that [map] and [rev] commute. You may need to define an auxiliary lemma. ) Theorem map_snoc : forall (X Y : Type) (f : X -> Y) (l : list X) (x : X), map f (snoc l x) = snoc (map f l) (f x). Proof. intros X Y f l x. induction l as [\|h l']. Case "l = []". simpl. reflexivity. Case "l=h::l'". simpl. rewrite IHl'. reflexivity. Qed. Theorem map_rev : forall (X Y : Type) (f : X -> Y) (l : list X), map f (rev l) = rev (map f l). Proof. intros X Y f l. induction l as [\|x l']. Case "l = []". simpl. reflexivity. Case "l=x::l'". simpl. rewrite map_snoc. rewrite IHl'. reflexivity. Qed. (* [] ) (* **** Exercise: 2 stars (flat_map) ) (* The function [map] maps a [list X] to a [list Y] using a function of type [X -> Y]. We can define a similar function, [flat_map], which maps a [list X] to a [list Y] using a function [f] of type [X -> list Y]. Your definition should work by 'flattening' the results of [f], like so: flat_map (fun n => [n;n+1;n+2]) [1;5;10] = [1; 2; 3; 5; 6; 7; 10; 11; 12]. ) Fixpoint flat_map {X Y:Type} (f:X -> list Y) (l:list X) : (list Y) := match l with \| [] => [] \| x :: ls => (f x) ++ (flat_map f ls) end. Example test_flat_map1: flat_map (fun n => [n;n;n]) [1;5;4] = [1; 1; 1; 5; 5; 5; 4; 4; 4]. reflexivity. Qed. (* [] ) (* Lists are not the only inductive type that we can write a [map] function for. Here is the definition of [map] for the [option] type: ) Definition option_map {X Y : Type} (f : X -> Y) (xo : option X) : option Y := match xo with \| None => None \| Some x => Some (f x) end. (* **** Exercise: 2 stars, optional (implicit_args) ) (* The definitions and uses of [filter] and [map] use implicit arguments in many places. Replace the curly braces around the implicit arguments with parentheses, and then fill in explicit type parameters where necessary and use Coq to check that you've done so correctly. (This exercise is not to be turned in; it is probably easiest to do it on a _copy_ of this file that you can throw away afterwards.) [] ) ( ###################################################### ) (* ** Fold ) (* An even more powerful higher-order function is called [fold]. This function is the inspiration for the "[reduce]" operation that lies at the heart of Google's map/reduce distributed programming framework. ) Fixpoint fold {X Y:Type} (f: X->Y->Y) (l:list X) (b:Y) : Y := match l with \| nil => b \| h :: t => f h (fold f t b) end. (* *** ) (* Intuitively, the behavior of the [fold] operation is to insert a given binary operator [f] between every pair of elements in a given list. For example, [ fold plus [1;2;3;4] ] intuitively means [1+2+3+4]. To make this precise, we also need a "starting element" that serves as the initial second input to [f]. So, for example, fold plus [1;2;3;4] 0 yields 1 + (2 + (3 + (4 + 0))). Here are some more examples: ) Check (fold andb). ( ===> fold andb : list bool -> bool -> bool ) Example fold_example1 : fold mult [1;2;3;4] 1 = 24. Proof. reflexivity. Qed. Example fold_example2 : fold andb [true;true;false;true] true = false. Proof. reflexivity. Qed. Example fold_example3 : fold app [[1];[];[2;3];[4]] [] = [1;2;3;4]. Proof. reflexivity. Qed. (* **** Exercise: 1 star, advanced (fold_types_different) ) (* Observe that the type of [fold] is parameterized by _two_ type variables, [X] and [Y], and the parameter [f] is a binary operator that takes an [X] and a [Y] and returns a [Y]. Can you think of a situation where it would be useful for [X] and [Y] to be different? List flattening ) ( ###################################################### ) (* ** Functions For Constructing Functions ) (* Most of the higher-order functions we have talked about so far take functions as _arguments_. Now let's look at some examples involving _returning_ functions as the results of other functions. To begin, here is a function that takes a value [x] (drawn from some type [X]) and returns a function from [nat] to [X] that yields [x] whenever it is called, ignoring its [nat] argument. ) Definition constfun {X: Type} (x: X) : nat->X := fun (k:nat) => x. Definition ftrue := constfun true. Example constfun_example1 : ftrue 0 = true. Proof. reflexivity. Qed. Example constfun_example2 : (constfun 5) 99 = 5. Proof. reflexivity. Qed. (* *** ) (* Similarly, but a bit more interestingly, here is a function that takes a function [f] from numbers to some type [X], a number [k], and a value [x], and constructs a function that behaves exactly like [f] except that, when called with the argument [k], it returns [x]. ) Definition override {X: Type} (f: nat->X) (k:nat) (x:X) : nat->X:= fun (k':nat) => if beq_nat k k' then x else f k'. (* For example, we can apply [override] twice to obtain a function from numbers to booleans that returns [false] on [1] and [3] and returns [true] on all other arguments. ) Definition fmostlytrue := override (override ftrue 1 false) 3 false. (* *** ) Example override_example1 : fmostlytrue 0 = true. Proof. reflexivity. Qed. Example override_example2 : fmostlytrue 1 = false. Proof. reflexivity. Qed. Example override_example3 : fmostlytrue 2 = true. Proof. reflexivity. Qed. Example override_example4 : fmostlytrue 3 = false. Proof. reflexivity. Qed. (* *** ) (* **** Exercise: 1 star (override_example) ) (* Before starting to work on the following proof, make sure you understand exactly what the theorem is saying and can paraphrase it in your own words. The proof itself is straightforward. ) Theorem override_example : forall (b:bool), (override (constfun b) 3 true) 2 = b. Proof. reflexivity. Qed. (* [] ) (* We'll use function overriding heavily in parts of the rest of the course, and we will end up needing to know quite a bit about its properties. To prove these properties, though, we need to know about a few more of Coq's tactics; developing these is the main topic of the next chapter. For now, though, let's introduce just one very useful tactic that will also help us with proving properties of some of the other functions we have introduced in this chapter. ) ( ###################################################### ) ( ###################################################### ) (* * The [unfold] Tactic ) (* Sometimes, a proof will get stuck because Coq doesn't automatically expand a function call into its definition. (This is a feature, not a bug: if Coq automatically expanded everything possible, our proof goals would quickly become enormous -- hard to read and slow for Coq to manipulate!) ) Theorem unfold_example_bad : forall m n, 3 + n = m -> plus3 n + 1 = m + 1. Proof. intros m n H. ( At this point, we'd like to do [rewrite -> H], since [plus3 n] is definitionally equal to [3 + n]. However, Coq doesn't automatically expand [plus3 n] to its definition. ) Abort. (* The [unfold] tactic can be used to explicitly replace a defined name by the right-hand side of its definition. ) Theorem unfold_example : forall m n, 3 + n = m -> plus3 n + 1 = m + 1. Proof. intros m n H. unfold plus3. rewrite -> H. reflexivity. Qed. (* Now we can prove a first property of [override]: If we override a function at some argument [k] and then look up [k], we get back the overridden value. ) Theorem override_eq : forall {X:Type} x k (f:nat->X), (override f k x) k = x. Proof. intros X x k f. unfold override. rewrite <- beq_nat_refl. reflexivity. Qed. (* This proof was straightforward, but note that it requires [unfold] to expand the definition of [override]. ) (* **** Exercise: 2 stars (override_neq) ) Theorem override_neq : forall (X:Type) x1 x2 k1 k2 (f : nat->X), f k1 = x1 -> beq_nat k2 k1 = false -> (override f k2 x2) k1 = x1. Proof. intros X x1 x2 k1 k2 f H H0. unfold override. rewrite H0. rewrite H. reflexivity. Qed. (* [] ) (* As the inverse of [unfold], Coq also provides a tactic [fold], which can be used to "unexpand" a definition. It is used much less often. ) ( ##################################################### ) (* * Additional Exercises ) (* **** Exercise: 2 stars (fold_length) ) (* Many common functions on lists can be implemented in terms of [fold]. For example, here is an alternative definition of [length]: ) Definition fold_length {X : Type} (l : list X) : nat := fold (fun _ n => S n) l 0. Example test_fold_length1 : fold_length [4;7;0] = 3. Proof. reflexivity. Qed. (* Prove the correctness of [fold_length]. ) Theorem fold_length_correct : forall X (l : list X), fold_length l = length l. Proof. intros X l. induction l as [\|x l']. Case "l = []". reflexivity. Case "l=x::l'". simpl. unfold fold_length. simpl. rewrite <- IHl'. reflexivity. Qed. (* [] ) (* **** Exercise: 3 stars (fold_map) ) (* We can also define [map] in terms of [fold]. Finish [fold_map] below. ) Definition fold_map {X Y:Type} (f : X -> Y) (l : list X) : list Y := fold (fun x ly => (f x) :: ly) l []. (* Write down a theorem in Coq stating that [fold_map] is correct, and prove it. ) Theorem fold_map_correct : forall X Y (f : X -> Y) (l : list X), map f l = fold_map f l. Proof. intros X Y f l. induction l as [\|x l']. Case "l = []". reflexivity. Case "l = x::l'". simpl. rewrite IHl'. unfold fold_map. simpl. reflexivity. Qed. (* [] ) ( $Date: 2013-09-26 14:40:26 -0400 (Thu, 26 Sep 2013) $ *)
extern "C" int checkWgAvailable(); extern "C" void prepareNextWg(); extern "C" int hardDisGetWgId(); extern "C" int hardDisGetWfCnt(); extern "C" int hardDisGetWfNumThrds(); extern "C" int hardDisGetVregSize(); extern "C" int hardDisGetVregSizePerWf(); extern "C" int hardDisGetSregSize() ; extern "C" int hardDisGetSregSizePerWf(); extern "C" int hardDisGetLdsSize(); extern "C" int hardDisGetGdsSize(); extern "C" int hardDisGetPc(); module dispatcher_hard_host (/AUTOARG/ // Outputs host_wg_valid, host_wg_id, host_num_wf, host_wf_size, host_vgpr_size_total, host_sgpr_size_total, host_lds_size_total, host_gds_size_total, host_vgpr_size_per_wf, host_sgpr_size_per_wf, host_start_pc, // Inputs inflight_wg_buffer_host_rcvd_ack, inflight_wg_buffer_host_wf_done, inflight_wg_buffer_host_wf_done_wg_id, clk, rst ) ; // Resource accounting parameters parameter WG_ID_WIDTH = 6; parameter WG_SLOT_ID_WIDTH = 6; parameter WF_COUNT_WIDTH = 4; parameter WAVE_ITEM_WIDTH = 6; parameter VGPR_ID_WIDTH = 8; parameter SGPR_ID_WIDTH = 4; parameter LDS_ID_WIDTH = 8; parameter GDS_ID_WIDTH = 14; parameter MEM_ADDR_WIDTH = 32; // Output from cu output host_wg_valid; output [WG_ID_WIDTH-1:0] host_wg_id; output [WF_COUNT_WIDTH-1:0] host_num_wf; output [WAVE_ITEM_WIDTH-1:0] host_wf_size; // number of work itens in the last wf output [VGPR_ID_WIDTH :0] host_vgpr_size_total; output [SGPR_ID_WIDTH :0] host_sgpr_size_total; output [LDS_ID_WIDTH :0] host_lds_size_total; output [GDS_ID_WIDTH :0] host_gds_size_total; output [VGPR_ID_WIDTH :0] host_vgpr_size_per_wf; output [SGPR_ID_WIDTH :0] host_sgpr_size_per_wf; output [MEM_ADDR_WIDTH-1:0] host_start_pc; // Input from CU input inflight_wg_buffer_host_rcvd_ack; input inflight_wg_buffer_host_wf_done; input [WG_ID_WIDTH-1:0] inflight_wg_buffer_host_wf_done_wg_id; input clk,rst; reg host_wg_valid_i; reg [WG_ID_WIDTH-1:0] host_wg_id_i; reg [WF_COUNT_WIDTH-1:0] host_num_wf_i; reg [WAVE_ITEM_WIDTH-1:0] host_wf_size_i; // number of work itens in the last wf reg [VGPR_ID_WIDTH :0] host_vgpr_size_total_i; reg [SGPR_ID_WIDTH :0] host_sgpr_size_total_i; reg [LDS_ID_WIDTH :0] host_lds_size_total_i; reg [GDS_ID_WIDTH :0] host_gds_size_total_i; reg [VGPR_ID_WIDTH :0] host_vgpr_size_per_wf_i; reg [SGPR_ID_WIDTH :0] host_sgpr_size_per_wf_i; reg [MEM_ADDR_WIDTH-1:0] host_start_pc_i; reg initialized; always @ ( posedge clk or posedge rst ) begin if(rst) begin host_wg_valid_i = 0; host_wg_id_i = 0; host_num_wf_i = 0; host_wf_size_i = 0; host_vgpr_size_total_i = 0; host_sgpr_size_total_i = 0; host_lds_size_total_i = 0; host_gds_size_total_i = 0; host_vgpr_size_per_wf_i = 0; host_sgpr_size_per_wf_i = 0; host_start_pc_i = 0; initialized = 0; end else begin if(inflight_wg_buffer_host_rcvd_ack \|\| !initialized) begin if(checkWgAvailable()) begin host_wg_valid_i = 1'b1; host_wg_id_i = hardDisGetWgId(); host_num_wf_i = hardDisGetWfCnt(); host_wf_size_i = hardDisGetWfNumThrds(); host_vgpr_size_total_i = hardDisGetVregSize(); host_sgpr_size_total_i = hardDisGetSregSize(); host_lds_size_total_i = hardDisGetLdsSize(); host_gds_size_total_i = hardDisGetGdsSize(); host_vgpr_size_per_wf_i = hardDisGetVregSizePerWf(); host_sgpr_size_per_wf_i = hardDisGetSregSizePerWf(); host_start_pc_i = hardDisGetPc(); prepareNextWg(); initialized = 1'b1; end else begin host_wg_valid_i = 1'b0; end // else: !if(checkWgAvailable()) end // if (inflight_wg_buffer_host_rcvd_ack \|\|... end // else: !if(rst) end // always @ ( posedge clk or posedge rst ) assign host_wg_valid = host_wg_valid_i; assign host_wg_id = host_wg_id_i; assign host_num_wf = host_num_wf_i; assign host_wf_size = host_wf_size_i; assign host_vgpr_size_total = host_vgpr_size_total_i; assign host_sgpr_size_total = host_sgpr_size_total_i; assign host_lds_size_total = host_lds_size_total_i; assign host_gds_size_total = host_gds_size_total_i; assign host_vgpr_size_per_wf = host_vgpr_size_per_wf_i; assign host_sgpr_size_per_wf = host_sgpr_size_per_wf_i; assign host_start_pc = host_start_pc_i; endmodule // dispatcher_hard_host
// ============================================================== // File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC // Version: 2014.4 // Copyright (C) 2014 Xilinx Inc. All rights reserved. // // ============================================================== `timescale 1ns/1ps `define AUTOTB_DUT adder `define AUTOTB_DUT_INST AESL_inst_adder `define AUTOTB_TOP apatb_adder_top `define AUTOTB_LAT_RESULT_FILE "adder.result.lat.rb" `define AUTOTB_PER_RESULT_TRANS_FILE "adder.performance.result.transaction.xml" `define AUTOTB_TOP_INST AESL_inst_apatb_adder_top `define AUTOTB_MAX_ALLOW_LATENCY 15000000 `define AUTOTB_TRANSACTION_NUM 1 `define AUTOTB_CLOCK_PERIOD 10.000000 `define LENGTH_a 1 `define LENGTH_b 1 `define LENGTH_c 1 `define AESL_DEPTH_a 1 `define AESL_DEPTH_b 1 `define AESL_DEPTH_c 1 `define AUTOTB_TVIN_a "../tv/cdatafile/c.adder.autotvin_a.dat" `define AUTOTB_TVIN_b "../tv/cdatafile/c.adder.autotvin_b.dat" `define AUTOTB_TVIN_a_out_wrapc "../tv/rtldatafile/rtl.adder.autotvin_a.dat" `define AUTOTB_TVIN_b_out_wrapc "../tv/rtldatafile/rtl.adder.autotvin_b.dat" `define AUTOTB_TVOUT_c "../tv/cdatafile/c.adder.autotvout_c.dat" `define AUTOTB_TVOUT_c_out_wrapc "../tv/rtldatafile/rtl.adder.autotvout_c.dat" module `AUTOTB_TOP; task read_token; input integer fp; output reg [199 : 0] token; reg [7:0] c; reg intoken; reg done; begin token = ""; intoken = 0; done = 0; while (!done) begin c = $fgetc(fp); if (c == 8'hff) begin // EOF done = 1; end else if (c == " " \|\| c == "\011" \|\| c == "\012" \|\| c == "\015") begin // blank if (intoken) begin done = 1; end end else begin // valid character intoken = 1; token = (token << 8) \| c; end end end endtask reg AESL_clock; reg rst; reg start; reg ce; reg continue; wire AESL_start; wire AESL_reset; wire AESL_ce; wire AESL_ready; wire AESL_idle; wire AESL_continue; wire AESL_done; reg AESL_done_delay = 0; reg AESL_done_delay2 = 0; reg AESL_ready_delay = 0; wire ready; wire ready_wire; reg [31 : 0] AESL_mLatCnterIn [0 : `AUTOTB_TRANSACTION_NUM + 1]; reg [31 : 0] AESL_mLatCnterIn_addr; reg [31 : 0] AESL_mLatCnterOut [0 : `AUTOTB_TRANSACTION_NUM + 1]; reg [31 : 0] AESL_mLatCnterOut_addr ; reg [31 : 0] AESL_clk_counter ; wire s_axi_AXI_CTRL_AWVALID; wire s_axi_AXI_CTRL_AWREADY; wire [5 : 0] s_axi_AXI_CTRL_AWADDR; wire s_axi_AXI_CTRL_WVALID; wire s_axi_AXI_CTRL_WREADY; wire [31 : 0] s_axi_AXI_CTRL_WDATA; wire [3 : 0] s_axi_AXI_CTRL_WSTRB; wire s_axi_AXI_CTRL_ARVALID; wire s_axi_AXI_CTRL_ARREADY; wire [5 : 0] s_axi_AXI_CTRL_ARADDR; wire s_axi_AXI_CTRL_RVALID; wire s_axi_AXI_CTRL_RREADY; wire [31 : 0] s_axi_AXI_CTRL_RDATA; wire [1 : 0] s_axi_AXI_CTRL_RRESP; wire s_axi_AXI_CTRL_BVALID; wire s_axi_AXI_CTRL_BREADY; wire [1 : 0] s_axi_AXI_CTRL_BRESP; wire ap_clk; wire ap_rst_n; wire interrupt; integer done_cnt = 0; integer AESL_ready_cnt = 0; integer ready_cnt = 0; reg ready_initial; reg ready_initial_n; reg ready_last_n; reg ready_delay_last_n; reg done_delay_last_n; reg interface_done = 0; wire AXI_CTRL_read_data_finish; wire AXI_CTRL_write_data_finish; wire AESL_slave_start; wire AESL_slave_write_start_in; wire AESL_slave_write_start_finish; reg AESL_slave_ready; wire AESL_slave_output_done; reg ready_rise = 0; reg start_rise = 0; reg slave_start_status = 0; reg slave_done_status = 0; `AUTOTB_DUT `AUTOTB_DUT_INST( .s_axi_AXI_CTRL_AWVALID(s_axi_AXI_CTRL_AWVALID), .s_axi_AXI_CTRL_AWREADY(s_axi_AXI_CTRL_AWREADY), .s_axi_AXI_CTRL_AWADDR(s_axi_AXI_CTRL_AWADDR), .s_axi_AXI_CTRL_WVALID(s_axi_AXI_CTRL_WVALID), .s_axi_AXI_CTRL_WREADY(s_axi_AXI_CTRL_WREADY), .s_axi_AXI_CTRL_WDATA(s_axi_AXI_CTRL_WDATA), .s_axi_AXI_CTRL_WSTRB(s_axi_AXI_CTRL_WSTRB), .s_axi_AXI_CTRL_ARVALID(s_axi_AXI_CTRL_ARVALID), .s_axi_AXI_CTRL_ARREADY(s_axi_AXI_CTRL_ARREADY), .s_axi_AXI_CTRL_ARADDR(s_axi_AXI_CTRL_ARADDR), .s_axi_AXI_CTRL_RVALID(s_axi_AXI_CTRL_RVALID), .s_axi_AXI_CTRL_RREADY(s_axi_AXI_CTRL_RREADY), .s_axi_AXI_CTRL_RDATA(s_axi_AXI_CTRL_RDATA), .s_axi_AXI_CTRL_RRESP(s_axi_AXI_CTRL_RRESP), .s_axi_AXI_CTRL_BVALID(s_axi_AXI_CTRL_BVALID), .s_axi_AXI_CTRL_BREADY(s_axi_AXI_CTRL_BREADY), .s_axi_AXI_CTRL_BRESP(s_axi_AXI_CTRL_BRESP), .ap_clk(ap_clk), .ap_rst_n(ap_rst_n), .interrupt(interrupt) ); // Assignment for control signal assign ap_clk = AESL_clock; assign ap_rst_n = AESL_reset; assign ap_rst_n_n = ~AESL_reset; assign AESL_reset = rst; assign AESL_start = start; assign AESL_ce = ce; assign AESL_continue = continue; assign AESL_slave_write_start_in = slave_start_status & AXI_CTRL_write_data_finish; assign AESL_slave_start = AESL_slave_write_start_finish; assign AESL_done = slave_done_status & AXI_CTRL_read_data_finish; always @(posedge AESL_clock) begin if(AESL_reset === 0) begin slave_start_status <= 1; end else begin if (AESL_start == 1 ) begin start_rise = 1; end if (start_rise == 1 && AESL_done == 1 ) begin slave_start_status <= 1; end if (AESL_slave_write_start_in == 1) begin slave_start_status <= 0; start_rise = 0; end end end always @(posedge AESL_clock) begin if(AESL_reset === 0) begin AESL_slave_ready <= 0; ready_rise = 0; end else begin if (AESL_ready == 1 ) begin ready_rise = 1; end if (ready_rise == 1 && AESL_done_delay == 1 ) begin AESL_slave_ready <= 1; end if (AESL_slave_ready == 1) begin AESL_slave_ready <= 0; ready_rise = 0; end end end always @ (posedge AESL_clock) begin if (AESL_done == 1) begin slave_done_status <= 0; end else if (AESL_slave_output_done == 1 ) begin slave_done_status <= 1; end end AESL_axi_slave_AXI_CTRL AESL_AXI_SLAVE_AXI_CTRL( .clk (AESL_clock), .reset (AESL_reset), .TRAN_s_axi_AXI_CTRL_AWADDR (s_axi_AXI_CTRL_AWADDR), .TRAN_s_axi_AXI_CTRL_AWVALID (s_axi_AXI_CTRL_AWVALID), .TRAN_s_axi_AXI_CTRL_AWREADY (s_axi_AXI_CTRL_AWREADY), .TRAN_s_axi_AXI_CTRL_WVALID (s_axi_AXI_CTRL_WVALID), .TRAN_s_axi_AXI_CTRL_WREADY (s_axi_AXI_CTRL_WREADY), .TRAN_s_axi_AXI_CTRL_WDATA (s_axi_AXI_CTRL_WDATA), .TRAN_s_axi_AXI_CTRL_WSTRB (s_axi_AXI_CTRL_WSTRB), .TRAN_s_axi_AXI_CTRL_ARADDR (s_axi_AXI_CTRL_ARADDR), .TRAN_s_axi_AXI_CTRL_ARVALID (s_axi_AXI_CTRL_ARVALID), .TRAN_s_axi_AXI_CTRL_ARREADY (s_axi_AXI_CTRL_ARREADY), .TRAN_s_axi_AXI_CTRL_RVALID (s_axi_AXI_CTRL_RVALID), .TRAN_s_axi_AXI_CTRL_RREADY (s_axi_AXI_CTRL_RREADY), .TRAN_s_axi_AXI_CTRL_RDATA (s_axi_AXI_CTRL_RDATA), .TRAN_s_axi_AXI_CTRL_RRESP (s_axi_AXI_CTRL_RRESP), .TRAN_s_axi_AXI_CTRL_BVALID (s_axi_AXI_CTRL_BVALID), .TRAN_s_axi_AXI_CTRL_BREADY (s_axi_AXI_CTRL_BREADY), .TRAN_s_axi_AXI_CTRL_BRESP (s_axi_AXI_CTRL_BRESP), .TRAN_AXI_CTRL_read_data_finish(AXI_CTRL_read_data_finish), .TRAN_AXI_CTRL_write_data_finish(AXI_CTRL_write_data_finish), .TRAN_AXI_CTRL_ready_out (AESL_ready), .TRAN_AXI_CTRL_ready_in (AESL_slave_ready), .TRAN_AXI_CTRL_done_out (AESL_slave_output_done), .TRAN_AXI_CTRL_idle_out (AESL_idle), .TRAN_AXI_CTRL_write_start_in (AESL_slave_write_start_in), .TRAN_AXI_CTRL_write_start_finish (AESL_slave_write_start_finish), .TRAN_AXI_CTRL_transaction_done_in (AESL_done_delay), .TRAN_AXI_CTRL_interrupt (interrupt), .TRAN_AXI_CTRL_start_in (AESL_slave_start) ); initial begin : generate_AESL_ready_cnt_proc AESL_ready_cnt = 0; wait(AESL_reset === 1); while(AESL_ready_cnt != `AUTOTB_TRANSACTION_NUM) begin while(AESL_ready !== 1) begin @(posedge AESL_clock); # 0.4; end @(negedge AESL_clock); AESL_ready_cnt = AESL_ready_cnt + 1; @(posedge AESL_clock); # 0.4; end end initial begin : generate_ready_cnt_proc ready_cnt = 0; wait(AESL_reset === 1); while(ready_cnt != `AUTOTB_TRANSACTION_NUM) begin while(ready !== 1) begin @(posedge AESL_clock); # 0.4; end @(negedge AESL_clock); ready_cnt = ready_cnt + 1; @(posedge AESL_clock); # 0.4; end end initial begin : generate_done_cnt_proc done_cnt = 0; wait(AESL_reset === 1); while(done_cnt != `AUTOTB_TRANSACTION_NUM) begin while(AESL_done !== 1) begin @(posedge AESL_clock); # 0.4; end @(negedge AESL_clock); done_cnt = done_cnt + 1; @(posedge AESL_clock); # 0.4; end @(posedge AESL_clock); # 0.4; $finish; end initial fork AESL_clock = 0; forever #(`AUTOTB_CLOCK_PERIOD/2) AESL_clock = ~AESL_clock; join initial begin : initial_process integer rand; rst = 0; # 100; repeat(3) @(posedge AESL_clock); rst = 1; end initial begin : start_process integer rand; start = 0; ce = 1; wait(AESL_reset === 1); @(posedge AESL_clock); start <= 1; while(done_cnt != `AUTOTB_TRANSACTION_NUM) begin @(posedge AESL_clock); end start <= 0; end always @(AESL_done) begin if(done_cnt < `AUTOTB_TRANSACTION_NUM - 1) continue = AESL_done; else continue = 0; end initial begin : ready_initial_process ready_initial = 0; wait (AESL_start === 1); ready_initial = 1; @(posedge AESL_clock); ready_initial = 0; end initial begin : ready_last_n_process ready_last_n = 1; wait(ready_cnt == `AUTOTB_TRANSACTION_NUM) @(posedge AESL_clock); ready_last_n <= 0; end assign ready = (ready_initial \| AESL_done_delay); always @(posedge AESL_clock) begin if(AESL_reset === 0) ready_delay_last_n = 0; else ready_delay_last_n <= ready_last_n; end assign ready_wire = (ready_initial \| AESL_done_delay); initial begin : done_delay_last_n_process done_delay_last_n = 1; while(done_cnt != `AUTOTB_TRANSACTION_NUM) @(posedge AESL_clock); # 0.1; done_delay_last_n = 0; end always @(posedge AESL_clock) begin if(AESL_reset === 0) begin AESL_done_delay <= 0; AESL_done_delay2 <= 0; end else begin AESL_done_delay <= AESL_done & done_delay_last_n; AESL_done_delay2 <= AESL_done_delay; end end always @(posedge AESL_clock) begin if(AESL_reset === 0) interface_done = 0; else begin # 0.01; if(ready === 1 && ready_cnt > 0 && ready_cnt < `AUTOTB_TRANSACTION_NUM) interface_done = 1; else if(AESL_done_delay === 1 && done_cnt == `AUTOTB_TRANSACTION_NUM) interface_done = 1; else interface_done = 0; end end // Write "[[[runtime]]]" and "[[[/runtime]]]" for output-only transactor initial begin : write_output_transactor_c_runtime_process integer fp; fp = $fopen(`AUTOTB_TVOUT_c_out_wrapc, "w"); if(fp == 0) begin // Failed to open file $display("Failed to open file \"%s\"!", `AUTOTB_TVOUT_c_out_wrapc); $display("ERROR: Simulation using HLS TB failed."); $finish; end $fdisplay(fp,"[[[runtime]]]"); $fclose(fp); wait(done_cnt == `AUTOTB_TRANSACTION_NUM) repeat(2) @(posedge AESL_clock); # 0.2; fp = $fopen(`AUTOTB_TVOUT_c_out_wrapc, "a"); if(fp == 0) begin // Failed to open file $display("Failed to open file \"%s\"!", `AUTOTB_TVOUT_c_out_wrapc); $display("ERROR: Simulation using HLS TB failed."); $finish; end $fdisplay(fp,"[[[/runtime]]]"); $fclose(fp); end always @(posedge AESL_clock) begin if(AESL_reset === 0) begin AESL_clk_counter <= 0; end else begin AESL_clk_counter = AESL_clk_counter + 1; end end always @ (posedge AESL_clock or negedge AESL_reset) begin if(AESL_reset === 0) begin AESL_mLatCnterOut_addr = 0; AESL_mLatCnterOut[AESL_mLatCnterOut_addr] = AESL_clk_counter + 1; end else if (AESL_done && AESL_mLatCnterOut_addr < `AUTOTB_TRANSACTION_NUM + 1) begin AESL_mLatCnterOut[AESL_mLatCnterOut_addr] = AESL_clk_counter; AESL_mLatCnterOut_addr = AESL_mLatCnterOut_addr + 1; end end always @ (posedge AESL_clock or negedge AESL_reset) begin if(AESL_reset === 0) begin AESL_mLatCnterIn_addr = 0; end else if (AESL_slave_write_start_finish && AESL_mLatCnterIn_addr < `AUTOTB_TRANSACTION_NUM + 1) begin AESL_mLatCnterIn[AESL_mLatCnterIn_addr] = AESL_clk_counter; AESL_mLatCnterIn_addr = AESL_mLatCnterIn_addr + 1; end end initial begin : performance_check integer transaction_counter; integer i; integer fp; integer latthistime; integer lattotal; integer latmax; integer latmin; integer thrthistime; integer thrtotal; integer thrmax; integer thrmin; integer lataver; integer thraver; reg [31 : 0] lat_array [0 : `AUTOTB_TRANSACTION_NUM]; reg [31 : 0] thr_array [0 : `AUTOTB_TRANSACTION_NUM]; i = 0; lattotal = 0; latmax = 0; latmin = 32'h 7fffffff; lataver = 0; thrtotal = 0; thrmax = 0; thrmin = 32'h 7fffffff; thraver = 0; @(negedge AESL_clock); @(posedge AESL_reset); while (done_cnt != `AUTOTB_TRANSACTION_NUM) begin @(posedge AESL_clock); end #0.001 latmax = 0; latmin = 0; lataver = 0; thrmax = 0; thrmin = 0; thraver = 0; fp = $fopen(`AUTOTB_LAT_RESULT_FILE, "w"); $fdisplay(fp, "$MAX_LATENCY = \"%0d\"", latmax); $fdisplay(fp, "$MIN_LATENCY = \"%0d\"", latmin); $fdisplay(fp, "$AVER_LATENCY = \"%0d\"", lataver); $fdisplay(fp, "$MAX_THROUGHPUT = \"%0d\"", latmax); $fdisplay(fp, "$MIN_THROUGHPUT = \"%0d\"", latmin); $fdisplay(fp, "$AVER_THROUGHPUT = \"%0d\"", lataver); $fclose(fp); fp = $fopen(`AUTOTB_PER_RESULT_TRANS_FILE, "w"); $fdisplay (fp,"%20s%16s%16s","","latency","interval"); for (i = 0; i < AESL_mLatCnterOut_addr; i = i + 1) begin $fdisplay (fp,"transaction%8d: 0 0",i ); end $fclose(fp); end endmodule
(***********************************************************************) ( v * The Coq Proof Assistant / The Coq Development Team ) ( <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2017 ) ( \VV/ *************************************************************) ( // * This file is distributed under the terms of the ) ( * GNU Lesser General Public License Version 2.1 ) (**********************************************************************) Require Setoid. Require Import PeanoNat Le Gt Minus Bool Lt. Set Implicit Arguments. ( Set Universe Polymorphism. ) (***************************************************************) ( * Basics: definition of polymorphic lists and some operations ) (***************************************************************) ( The definition of [list] is now in [Init/Datatypes], as well as the definitions of [length] and [app] ) Open Scope list_scope. (* Standard notations for lists. In a special module to avoid conflicts. ) Module ListNotations. Notation "[ ]" := nil (format "[ ]") : list_scope. Notation "[ x ]" := (cons x nil) : list_scope. Notation "[ x ; y ; .. ; z ]" := (cons x (cons y .. (cons z nil) ..)) : list_scope. Notation "[ x ; .. ; y ]" := (cons x .. (cons y nil) ..) (compat "8.4") : list_scope. End ListNotations. Import ListNotations. Section Lists. Variable A : Type. (* Head and tail ) Definition hd (default:A) (l:list A) := match l with \| [] => default \| x :: _ => x end. Definition hd_error (l:list A) := match l with \| [] => None \| x :: _ => Some x end. Definition tl (l:list A) := match l with \| [] => nil \| a :: m => m end. (* The [In] predicate ) Fixpoint In (a:A) (l:list A) : Prop := match l with \| [] => False \| b :: m => b = a \/ In a m end. End Lists. Section Facts. Variable A : Type. (* *** Generic facts ) (* Discrimination ) Theorem nil_cons : forall (x:A) (l:list A), [] <> x :: l. Proof. intros; discriminate. Qed. (* Destruction ) Theorem destruct_list : forall l : list A, {x:A & {tl:list A \| l = x::tl}}+{l = []}. Proof. induction l as [\|a tail]. right; reflexivity. left; exists a, tail; reflexivity. Qed. Lemma hd_error_tl_repr : forall l (a:A) r, hd_error l = Some a /\ tl l = r <-> l = a :: r. Proof. destruct l as [\|x xs]. - unfold hd_error, tl; intros a r. split; firstorder discriminate. - intros. simpl. split. intros (H1, H2). inversion H1. rewrite H2. reflexivity. * inversion 1. subst. auto. Qed. Lemma hd_error_some_nil : forall l (a:A), hd_error l = Some a -> l <> nil. Proof. unfold hd_error. destruct l; now discriminate. Qed. Theorem length_zero_iff_nil (l : list A): length l = 0 <-> l=[]. Proof. split; [now destruct l \| now intros ->]. Qed. ( * Head and tail ) Theorem hd_error_nil : hd_error (@nil A) = None. Proof. simpl; reflexivity. Qed. Theorem hd_error_cons : forall (l : list A) (x : A), hd_error (x::l) = Some x. Proof. intros; simpl; reflexivity. Qed. (*********************) ( *** Facts about [In] ) (*********************) ( Characterization of [In] ) Theorem in_eq : forall (a:A) (l:list A), In a (a :: l). Proof. simpl; auto. Qed. Theorem in_cons : forall (a b:A) (l:list A), In b l -> In b (a :: l). Proof. simpl; auto. Qed. Theorem not_in_cons (x a : A) (l : list A): ~ In x (a::l) <-> x<>a /\ ~ In x l. Proof. simpl. intuition. Qed. Theorem in_nil : forall a:A, ~ In a []. Proof. unfold not; intros a H; inversion_clear H. Qed. Theorem in_split : forall x (l:list A), In x l -> exists l1 l2, l = l1++x::l2. Proof. induction l; simpl; destruct 1. subst a; auto. exists [], l; auto. destruct (IHl H) as (l1,(l2,H0)). exists (a::l1), l2; simpl. apply f_equal. auto. Qed. (* Inversion ) Lemma in_inv : forall (a b:A) (l:list A), In b (a :: l) -> a = b \/ In b l. Proof. intros a b l H; inversion_clear H; auto. Qed. (* Decidability of [In] ) Theorem in_dec : (forall x y:A, {x = y} + {x <> y}) -> forall (a:A) (l:list A), {In a l} + {~ In a l}. Proof. intro H; induction l as [\| a0 l IHl]. right; apply in_nil. destruct (H a0 a); simpl; auto. destruct IHl; simpl; auto. right; unfold not; intros [Hc1\| Hc2]; auto. Defined. (***********************) ( *** Facts about [app] ) (***********************) ( Discrimination ) Theorem app_cons_not_nil : forall (x y:list A) (a:A), [] <> x ++ a :: y. Proof. unfold not. destruct x as [\| a l]; simpl; intros. discriminate H. discriminate H. Qed. (* Concat with [nil] ) Theorem app_nil_l : forall l:list A, [] ++ l = l. Proof. reflexivity. Qed. Theorem app_nil_r : forall l:list A, l ++ [] = l. Proof. induction l; simpl; f_equal; auto. Qed. ( begin hide ) ( Deprecated ) Theorem app_nil_end : forall (l:list A), l = l ++ []. Proof. symmetry; apply app_nil_r. Qed. ( end hide ) (* [app] is associative ) Theorem app_assoc : forall l m n:list A, l ++ m ++ n = (l ++ m) ++ n. Proof. intros l m n; induction l; simpl; f_equal; auto. Qed. ( begin hide ) ( Deprecated ) Theorem app_assoc_reverse : forall l m n:list A, (l ++ m) ++ n = l ++ m ++ n. Proof. auto using app_assoc. Qed. Hint Resolve app_assoc_reverse. ( end hide ) (* [app] commutes with [cons] ) Theorem app_comm_cons : forall (x y:list A) (a:A), a :: (x ++ y) = (a :: x) ++ y. Proof. auto. Qed. (* Facts deduced from the result of a concatenation ) Theorem app_eq_nil : forall l l':list A, l ++ l' = [] -> l = [] /\ l' = []. Proof. destruct l as [\| x l]; destruct l' as [\| y l']; simpl; auto. intro; discriminate. intros H; discriminate H. Qed. Theorem app_eq_unit : forall (x y:list A) (a:A), x ++ y = [a] -> x = [] /\ y = [a] \/ x = [a] /\ y = []. Proof. destruct x as [\| a l]; [ destruct y as [\| a l] \| destruct y as [\| a0 l0] ]; simpl. intros a H; discriminate H. left; split; auto. right; split; auto. generalize H. generalize (app_nil_r l); intros E. rewrite -> E; auto. intros. injection H as H H0. assert ([] = l ++ a0 :: l0) by auto. apply app_cons_not_nil in H1 as []. Qed. Lemma app_inj_tail : forall (x y:list A) (a b:A), x ++ [a] = y ++ [b] -> x = y /\ a = b. Proof. induction x as [\| x l IHl]; [ destruct y as [\| a l] \| destruct y as [\| a l0] ]; simpl; auto. - intros a b H. injection H. auto. - intros a0 b H. injection H as H1 H0. apply app_cons_not_nil in H0 as []. - intros a b H. injection H as H1 H0. assert ([] = l ++ [a]) by auto. apply app_cons_not_nil in H as []. - intros a0 b H. injection H as <- H0. destruct (IHl l0 a0 b H0) as (<-,<-). split; auto. Qed. (* Compatibility with other operations ) Lemma app_length : forall l l' : list A, length (l++l') = length l + length l'. Proof. induction l; simpl; auto. Qed. Lemma in_app_or : forall (l m:list A) (a:A), In a (l ++ m) -> In a l \/ In a m. Proof. intros l m a. elim l; simpl; auto. intros a0 y H H0. now_show ((a0 = a \/ In a y) \/ In a m). elim H0; auto. intro H1. now_show ((a0 = a \/ In a y) \/ In a m). elim (H H1); auto. Qed. Lemma in_or_app : forall (l m:list A) (a:A), In a l \/ In a m -> In a (l ++ m). Proof. intros l m a. elim l; simpl; intro H. now_show (In a m). elim H; auto; intro H0. now_show (In a m). elim H0. ( subProof completed ) intros y H0 H1. now_show (H = a \/ In a (y ++ m)). elim H1; auto 4. intro H2. now_show (H = a \/ In a (y ++ m)). elim H2; auto. Qed. Lemma in_app_iff : forall l l' (a:A), In a (l++l') <-> In a l \/ In a l'. Proof. split; auto using in_app_or, in_or_app. Qed. Lemma app_inv_head: forall l l1 l2 : list A, l ++ l1 = l ++ l2 -> l1 = l2. Proof. induction l; simpl; auto; injection 1; auto. Qed. Lemma app_inv_tail: forall l l1 l2 : list A, l1 ++ l = l2 ++ l -> l1 = l2. Proof. intros l l1 l2; revert l1 l2 l. induction l1 as [ \| x1 l1]; destruct l2 as [ \| x2 l2]; simpl; auto; intros l H. absurd (length (x2 :: l2 ++ l) <= length l). simpl; rewrite app_length; auto with arith. rewrite <- H; auto with arith. absurd (length (x1 :: l1 ++ l) <= length l). simpl; rewrite app_length; auto with arith. rewrite H; auto with arith. injection H as H H0; f_equal; eauto. Qed. End Facts. Hint Resolve app_assoc app_assoc_reverse: datatypes. Hint Resolve app_comm_cons app_cons_not_nil: datatypes. Hint Immediate app_eq_nil: datatypes. Hint Resolve app_eq_unit app_inj_tail: datatypes. Hint Resolve in_eq in_cons in_inv in_nil in_app_or in_or_app: datatypes. (****************************************) ( * Operations on the elements of a list ) (****************************************) Section Elts. Variable A : Type. (*************************) ( ** Nth element of a list ) (***************************) Fixpoint nth (n:nat) (l:list A) (default:A) {struct l} : A := match n, l with \| O, x :: l' => x \| O, other => default \| S m, [] => default \| S m, x :: t => nth m t default end. Fixpoint nth_ok (n:nat) (l:list A) (default:A) {struct l} : bool := match n, l with \| O, x :: l' => true \| O, other => false \| S m, [] => false \| S m, x :: t => nth_ok m t default end. Lemma nth_in_or_default : forall (n:nat) (l:list A) (d:A), {In (nth n l d) l} + {nth n l d = d}. Proof. intros n l d; revert n; induction l. - right; destruct n; trivial. - intros [\|n]; simpl. left; auto. * destruct (IHl n); auto. Qed. Lemma nth_S_cons : forall (n:nat) (l:list A) (d a:A), In (nth n l d) l -> In (nth (S n) (a :: l) d) (a :: l). Proof. simpl; auto. Qed. Fixpoint nth_error (l:list A) (n:nat) {struct n} : option A := match n, l with \| O, x :: _ => Some x \| S n, _ :: l => nth_error l n \| _, _ => None end. Definition nth_default (default:A) (l:list A) (n:nat) : A := match nth_error l n with \| Some x => x \| None => default end. Lemma nth_default_eq : forall n l (d:A), nth_default d l n = nth n l d. Proof. unfold nth_default; induction n; intros [ \| ] ?; simpl; auto. Qed. (** Results about [nth] ) Lemma nth_In : forall (n:nat) (l:list A) (d:A), n < length l -> In (nth n l d) l. Proof. unfold lt; induction n as [\| n hn]; simpl. - destruct l; simpl; [ inversion 2 \| auto ]. - destruct l; simpl. inversion 2. * intros d ie; right; apply hn; auto with arith. Qed. Lemma In_nth l x d : In x l -> exists n, n < length l /\ nth n l d = x. Proof. induction l as [\|a l IH]. - easy. - intros [H\|H]. * subst; exists 0; simpl; auto with arith. * destruct (IH H) as (n & Hn & Hn'). exists (S n); simpl; auto with arith. Qed. Lemma nth_overflow : forall l n d, length l <= n -> nth n l d = d. Proof. induction l; destruct n; simpl; intros; auto. - inversion H. - apply IHl; auto with arith. Qed. Lemma nth_indep : forall l n d d', n < length l -> nth n l d = nth n l d'. Proof. induction l. - inversion 1. - intros [\|n] d d'; simpl; auto with arith. Qed. Lemma app_nth1 : forall l l' d n, n < length l -> nth n (l++l') d = nth n l d. Proof. induction l. - inversion 1. - intros l' d [\|n]; simpl; auto with arith. Qed. Lemma app_nth2 : forall l l' d n, n >= length l -> nth n (l++l') d = nth (n-length l) l' d. Proof. induction l; intros l' d [\|n]; auto. - inversion 1. - intros; simpl; rewrite IHl; auto with arith. Qed. Lemma nth_split n l d : n < length l -> exists l1, exists l2, l = l1 ++ nth n l d :: l2 /\ length l1 = n. Proof. revert l. induction n as [\|n IH]; intros [\|a l] H; try easy. - exists nil; exists l; now simpl. - destruct (IH l) as (l1 & l2 & Hl & Hl1); auto with arith. exists (a::l1); exists l2; simpl; split; now f_equal. Qed. (** Results about [nth_error] ) Lemma nth_error_In l n x : nth_error l n = Some x -> In x l. Proof. revert n. induction l as [\|a l IH]; intros [\|n]; simpl; try easy. - injection 1; auto. - eauto. Qed. Lemma In_nth_error l x : In x l -> exists n, nth_error l n = Some x. Proof. induction l as [\|a l IH]. - easy. - intros [H\|H]. subst; exists 0; simpl; auto with arith. * destruct (IH H) as (n,Hn). exists (S n); simpl; auto with arith. Qed. Lemma nth_error_None l n : nth_error l n = None <-> length l <= n. Proof. revert n. induction l; destruct n; simpl. - split; auto. - split; auto with arith. - split; now auto with arith. - rewrite IHl; split; auto with arith. Qed. Lemma nth_error_Some l n : nth_error l n <> None <-> n < length l. Proof. revert n. induction l; destruct n; simpl. - split; [now destruct 1 \| inversion 1]. - split; [now destruct 1 \| inversion 1]. - split; now auto with arith. - rewrite IHl; split; auto with arith. Qed. Lemma nth_error_split l n a : nth_error l n = Some a -> exists l1, exists l2, l = l1 ++ a :: l2 /\ length l1 = n. Proof. revert l. induction n as [\|n IH]; intros [\|x l] H; simpl in ; try easy. - exists nil; exists l. now injection H as ->. - destruct (IH _ H) as (l1 & l2 & H1 & H2). exists (x::l1); exists l2; simpl; split; now f_equal. Qed. Lemma nth_error_app1 l l' n : n < length l -> nth_error (l++l') n = nth_error l n. Proof. revert l. induction n; intros [\|a l] H; auto; try solve [inversion H]. simpl in . apply IHn. auto with arith. Qed. Lemma nth_error_app2 l l' n : length l <= n -> nth_error (l++l') n = nth_error l' (n-length l). Proof. revert l. induction n; intros [\|a l] H; auto; try solve [inversion H]. simpl in . apply IHn. auto with arith. Qed. (**************) ( ** Remove ) (**************) Hypothesis eq_dec : forall x y : A, {x = y}+{x <> y}. Fixpoint remove (x : A) (l : list A) : list A := match l with \| [] => [] \| y::tl => if (eq_dec x y) then remove x tl else y::(remove x tl) end. Theorem remove_In : forall (l : list A) (x : A), ~ In x (remove x l). Proof. induction l as [\|x l]; auto. intro y; simpl; destruct (eq_dec y x) as [yeqx \| yneqx]. apply IHl. unfold not; intro HF; simpl in HF; destruct HF; auto. apply (IHl y); assumption. Qed. (**************************) ( ** Last element of a list ) (***************************) ( [last l d] returns the last element of the list [l], or the default value [d] if [l] is empty. ) Fixpoint last (l:list A) (d:A) : A := match l with \| [] => d \| [a] => a \| a :: l => last l d end. (* [removelast l] remove the last element of [l] ) Fixpoint removelast (l:list A) : list A := match l with \| [] => [] \| [a] => [] \| a :: l => a :: removelast l end. Lemma app_removelast_last : forall l d, l <> [] -> l = removelast l ++ [last l d]. Proof. induction l. destruct 1; auto. intros d _. destruct l; auto. pattern (a0::l) at 1; rewrite IHl with d; auto; discriminate. Qed. Lemma exists_last : forall l, l <> [] -> { l' : (list A) & { a : A \| l = l' ++ [a]}}. Proof. induction l. destruct 1; auto. intros _. destruct l. exists [], a; auto. destruct IHl as [l' (a',H)]; try discriminate. rewrite H. exists (a::l'), a'; auto. Qed. Lemma removelast_app : forall l l', l' <> [] -> removelast (l++l') = l ++ removelast l'. Proof. induction l. simpl; auto. simpl; intros. assert (l++l' <> []). destruct l. simpl; auto. simpl; discriminate. specialize (IHl l' H). destruct (l++l'); [elim H0; auto\|f_equal; auto]. Qed. (***************************************) ( ** Counting occurrences of an element ) (***************************************) Fixpoint count_occ (l : list A) (x : A) : nat := match l with \| [] => 0 \| y :: tl => let n := count_occ tl x in if eq_dec y x then S n else n end. ( Compatibility of count_occ with operations on list ) Theorem count_occ_In l x : In x l <-> count_occ l x > 0. Proof. induction l as [\|y l]; simpl. - split; [destruct 1 \| apply gt_irrefl]. - destruct eq_dec as [->\|Hneq]; rewrite IHl; intuition. Qed. Theorem count_occ_not_In l x : ~ In x l <-> count_occ l x = 0. Proof. rewrite count_occ_In. unfold gt. now rewrite Nat.nlt_ge, Nat.le_0_r. Qed. Lemma count_occ_nil x : count_occ [] x = 0. Proof. reflexivity. Qed. Theorem count_occ_inv_nil l : (forall x:A, count_occ l x = 0) <-> l = []. Proof. split. - induction l as [\|x l]; trivial. intros H. specialize (H x). simpl in H. destruct eq_dec as [_\|NEQ]; [discriminate\|now elim NEQ]. - now intros ->. Qed. Lemma count_occ_cons_eq l x y : x = y -> count_occ (x::l) y = S (count_occ l y). Proof. intros H. simpl. now destruct (eq_dec x y). Qed. Lemma count_occ_cons_neq l x y : x <> y -> count_occ (x::l) y = count_occ l y. Proof. intros H. simpl. now destruct (eq_dec x y). Qed. End Elts. (****************************) ( * Manipulating whole lists ) (****************************) Section ListOps. Variable A : Type. (*********************) ( ** Reverse ) (**********************) Fixpoint rev (l:list A) : list A := match l with \| [] => [] \| x :: l' => rev l' ++ [x] end. Lemma rev_app_distr : forall x y:list A, rev (x ++ y) = rev y ++ rev x. Proof. induction x as [\| a l IHl]. destruct y as [\| a l]. simpl. auto. simpl. rewrite app_nil_r; auto. intro y. simpl. rewrite (IHl y). rewrite app_assoc; trivial. Qed. Remark rev_unit : forall (l:list A) (a:A), rev (l ++ [a]) = a :: rev l. Proof. intros. apply (rev_app_distr l [a]); simpl; auto. Qed. Lemma rev_involutive : forall l:list A, rev (rev l) = l. Proof. induction l as [\| a l IHl]. simpl; auto. simpl. rewrite (rev_unit (rev l) a). rewrite IHl; auto. Qed. ( Compatibility with other operations ) Lemma in_rev : forall l x, In x l <-> In x (rev l). Proof. induction l. simpl; intuition. intros. simpl. intuition. subst. apply in_or_app; right; simpl; auto. apply in_or_app; left; firstorder. destruct (in_app_or _ _ _ H); firstorder. Qed. Lemma rev_length : forall l, length (rev l) = length l. Proof. induction l;simpl; auto. rewrite app_length. rewrite IHl. simpl. elim (length l); simpl; auto. Qed. Lemma rev_nth : forall l d n, n < length l -> nth n (rev l) d = nth (length l - S n) l d. Proof. induction l. intros; inversion H. intros. simpl in H. simpl (rev (a :: l)). simpl (length (a :: l) - S n). inversion H. rewrite <- minus_n_n; simpl. rewrite <- rev_length. rewrite app_nth2; auto. rewrite <- minus_n_n; auto. rewrite app_nth1; auto. rewrite (minus_plus_simpl_l_reverse (length l) n 1). replace (1 + length l) with (S (length l)); auto with arith. rewrite <- minus_Sn_m; auto with arith. apply IHl ; auto with arith. rewrite rev_length; auto. Qed. (* An alternative tail-recursive definition for reverse ) Fixpoint rev_append (l l': list A) : list A := match l with \| [] => l' \| a::l => rev_append l (a::l') end. Definition rev' l : list A := rev_append l []. Lemma rev_append_rev : forall l l', rev_append l l' = rev l ++ l'. Proof. induction l; simpl; auto; intros. rewrite <- app_assoc; firstorder. Qed. Lemma rev_alt : forall l, rev l = rev_append l []. Proof. intros; rewrite rev_append_rev. rewrite app_nil_r; trivial. Qed. (******************************************) ( Reverse Induction Principle on Lists ) (******************************************) Section Reverse_Induction. Lemma rev_list_ind : forall P:list A-> Prop, P [] -> (forall (a:A) (l:list A), P (rev l) -> P (rev (a :: l))) -> forall l:list A, P (rev l). Proof. induction l; auto. Qed. Theorem rev_ind : forall P:list A -> Prop, P [] -> (forall (x:A) (l:list A), P l -> P (l ++ [x])) -> forall l:list A, P l. Proof. intros. generalize (rev_involutive l). intros E; rewrite <- E. apply (rev_list_ind P). auto. simpl. intros. apply (H0 a (rev l0)). auto. Qed. End Reverse_Induction. (*********************) ( ** Concatenation ) (**********************) Fixpoint concat (l : list (list A)) : list A := match l with \| nil => nil \| cons x l => x ++ concat l end. Lemma concat_nil : concat nil = nil. Proof. reflexivity. Qed. Lemma concat_cons : forall x l, concat (cons x l) = x ++ concat l. Proof. reflexivity. Qed. Lemma concat_app : forall l1 l2, concat (l1 ++ l2) = concat l1 ++ concat l2. Proof. intros l1; induction l1 as [\|x l1 IH]; intros l2; simpl. + reflexivity. + rewrite IH; apply app_assoc. Qed. (*******************************) ( ** Decidable equality on lists ) (********************************) Hypothesis eq_dec : forall (x y : A), {x = y}+{x <> y}. Lemma list_eq_dec : forall l l':list A, {l = l'} + {l <> l'}. Proof. decide equality. Defined. End ListOps. (***********************************************) ( * Applying functions to the elements of a list ) (************************************************) (********) ( ** Map ) (**********) Section Map. Variables (A : Type) (B : Type). Variable f : A -> B. Fixpoint map (l:list A) : list B := match l with \| [] => [] \| a :: t => (f a) :: (map t) end. Lemma map_cons (x:A)(l:list A) : map (x::l) = (f x) :: (map l). Proof. reflexivity. Qed. Lemma in_map : forall (l:list A) (x:A), In x l -> In (f x) (map l). Proof. induction l; firstorder (subst; auto). Qed. Lemma in_map_iff : forall l y, In y (map l) <-> exists x, f x = y /\ In x l. Proof. induction l; firstorder (subst; auto). Qed. Lemma map_length : forall l, length (map l) = length l. Proof. induction l; simpl; auto. Qed. Lemma map_nth : forall l d n, nth n (map l) (f d) = f (nth n l d). Proof. induction l; simpl map; destruct n; firstorder. Qed. Lemma map_nth_error : forall n l d, nth_error l n = Some d -> nth_error (map l) n = Some (f d). Proof. induction n; intros [ \| ] ? Heq; simpl in ; inversion Heq; auto. Qed. Lemma map_app : forall l l', map (l++l') = (map l)++(map l'). Proof. induction l; simpl; auto. intros; rewrite IHl; auto. Qed. Lemma map_rev : forall l, map (rev l) = rev (map l). Proof. induction l; simpl; auto. rewrite map_app. rewrite IHl; auto. Qed. Lemma map_eq_nil : forall l, map l = [] -> l = []. Proof. destruct l; simpl; reflexivity \|\| discriminate. Qed. (** [map] and count of occurrences ) Hypothesis decA: forall x1 x2 : A, {x1 = x2} + {x1 <> x2}. Hypothesis decB: forall y1 y2 : B, {y1 = y2} + {y1 <> y2}. Hypothesis Hfinjective: forall x1 x2: A, (f x1) = (f x2) -> x1 = x2. Theorem count_occ_map x l: count_occ decA l x = count_occ decB (map l) (f x). Proof. revert x. induction l as [\| a l' Hrec]; intro x; simpl. - reflexivity. - specialize (Hrec x). destruct (decA a x) as [H1\|H1], (decB (f a) (f x)) as [H2\|H2]. rewrite Hrec. reflexivity. * contradiction H2. rewrite H1. reflexivity. * specialize (Hfinjective H2). contradiction H1. * assumption. Qed. (** [flat_map] ) Definition flat_map (f:A -> list B) := fix flat_map (l:list A) : list B := match l with \| nil => nil \| cons x t => (f x)++(flat_map t) end. Lemma in_flat_map : forall (f:A->list B)(l:list A)(y:B), In y (flat_map f l) <-> exists x, In x l /\ In y (f x). Proof using A B. clear Hfinjective. induction l; simpl; split; intros. contradiction. destruct H as (x,(H,_)); contradiction. destruct (in_app_or _ _ _ H). exists a; auto. destruct (IHl y) as (H1,_); destruct (H1 H0) as (x,(H2,H3)). exists x; auto. apply in_or_app. destruct H as (x,(H0,H1)); destruct H0. subst; auto. right; destruct (IHl y) as (_,H2); apply H2. exists x; auto. Qed. End Map. Lemma flat_map_concat_map : forall A B (f : A -> list B) l, flat_map f l = concat (map f l). Proof. intros A B f l; induction l as [\|x l IH]; simpl. + reflexivity. + rewrite IH; reflexivity. Qed. Lemma concat_map : forall A B (f : A -> B) l, map f (concat l) = concat (map (map f) l). Proof. intros A B f l; induction l as [\|x l IH]; simpl. + reflexivity. + rewrite map_app, IH; reflexivity. Qed. Lemma map_id : forall (A :Type) (l : list A), map (fun x => x) l = l. Proof. induction l; simpl; auto; rewrite IHl; auto. Qed. Lemma map_map : forall (A B C:Type)(f:A->B)(g:B->C) l, map g (map f l) = map (fun x => g (f x)) l. Proof. induction l; simpl; auto. rewrite IHl; auto. Qed. Lemma map_ext_in : forall (A B : Type)(f g:A->B) l, (forall a, In a l -> f a = g a) -> map f l = map g l. Proof. induction l; simpl; auto. intros; rewrite H by intuition; rewrite IHl; auto. Qed. Lemma map_ext : forall (A B : Type)(f g:A->B), (forall a, f a = g a) -> forall l, map f l = map g l. Proof. intros; apply map_ext_in; auto. Qed. (*********************************) ( Left-to-right iterator on lists ) (*********************************) Section Fold_Left_Recursor. Variables (A : Type) (B : Type). Variable f : A -> B -> A. Fixpoint fold_left (l:list B) (a0:A) : A := match l with \| nil => a0 \| cons b t => fold_left t (f a0 b) end. Lemma fold_left_app : forall (l l':list B)(i:A), fold_left (l++l') i = fold_left l' (fold_left l i). Proof. induction l. simpl; auto. intros. simpl. auto. Qed. End Fold_Left_Recursor. Lemma fold_left_length : forall (A:Type)(l:list A), fold_left (fun x _ => S x) l 0 = length l. Proof. intros A l. enough (H : forall n, fold_left (fun x _ => S x) l n = n + length l) by exact (H 0). induction l; simpl; auto. intros; rewrite IHl. simpl; auto with arith. Qed. (********************************) ( Right-to-left iterator on lists ) (*********************************) Section Fold_Right_Recursor. Variables (A : Type) (B : Type). Variable f : B -> A -> A. Variable a0 : A. Fixpoint fold_right (l:list B) : A := match l with \| nil => a0 \| cons b t => f b (fold_right t) end. End Fold_Right_Recursor. Lemma fold_right_app : forall (A B:Type)(f:A->B->B) l l' i, fold_right f i (l++l') = fold_right f (fold_right f i l') l. Proof. induction l. simpl; auto. simpl; intros. f_equal; auto. Qed. Lemma fold_left_rev_right : forall (A B:Type)(f:A->B->B) l i, fold_right f i (rev l) = fold_left (fun x y => f y x) l i. Proof. induction l. simpl; auto. intros. simpl. rewrite fold_right_app; simpl; auto. Qed. Theorem fold_symmetric : forall (A : Type) (f : A -> A -> A), (forall x y z : A, f x (f y z) = f (f x y) z) -> forall (a0 : A), (forall y : A, f a0 y = f y a0) -> forall (l : list A), fold_left f l a0 = fold_right f a0 l. Proof. intros A f assoc a0 comma0 l. induction l as [ \| a1 l ]; [ simpl; reflexivity \| ]. simpl. rewrite <- IHl. clear IHl. revert a1. induction l; [ auto \| ]. simpl. intro. rewrite <- assoc. rewrite IHl. rewrite IHl. auto. Qed. ( [(list_power x y)] is [y^x], or the set of sequences of elts of [y] indexed by elts of [x], sorted in lexicographic order. ) Fixpoint list_power (A B:Type)(l:list A) (l':list B) : list (list (A B)) := match l with \| nil => cons nil nil \| cons x t => flat_map (fun f:list (A * B) => map (fun y:B => cons (x, y) f) l') (list_power t l') end. (***********************************) ( ** Boolean operations over lists ) (**********************************) Section Bool. Variable A : Type. Variable f : A -> bool. ( find whether a boolean function can be satisfied by an elements of the list. ) Fixpoint existsb (l:list A) : bool := match l with \| nil => false \| a::l => f a \|\| existsb l end. Lemma existsb_exists : forall l, existsb l = true <-> exists x, In x l /\ f x = true. Proof. induction l; simpl; intuition. inversion H. firstorder. destruct (orb_prop _ _ H1); firstorder. firstorder. subst. rewrite H2; auto. Qed. Lemma existsb_nth : forall l n d, n < length l -> existsb l = false -> f (nth n l d) = false. Proof. induction l. inversion 1. simpl; intros. destruct (orb_false_elim _ _ H0); clear H0; auto. destruct n ; auto. rewrite IHl; auto with arith. Qed. Lemma existsb_app : forall l1 l2, existsb (l1++l2) = existsb l1 \|\| existsb l2. Proof. induction l1; intros l2; simpl. solve[auto]. case (f a); simpl; solve[auto]. Qed. (* find whether a boolean function is satisfied by all the elements of a list. ) Fixpoint forallb (l:list A) : bool := match l with \| nil => true \| a::l => f a && forallb l end. Lemma forallb_forall : forall l, forallb l = true <-> (forall x, In x l -> f x = true). Proof. induction l; simpl; intuition. destruct (andb_prop _ _ H1). congruence. destruct (andb_prop _ _ H1); auto. assert (forallb l = true). apply H0; intuition. rewrite H1; auto. Qed. Lemma forallb_app : forall l1 l2, forallb (l1++l2) = forallb l1 && forallb l2. Proof. induction l1; simpl. solve[auto]. case (f a); simpl; solve[auto]. Qed. (* [filter] ) Fixpoint filter (l:list A) : list A := match l with \| nil => nil \| x :: l => if f x then x::(filter l) else filter l end. Lemma filter_In : forall x l, In x (filter l) <-> In x l /\ f x = true. Proof. induction l; simpl. intuition. intros. case_eq (f a); intros; simpl; intuition congruence. Qed. (* [find] ) Fixpoint find (l:list A) : option A := match l with \| nil => None \| x :: tl => if f x then Some x else find tl end. Lemma find_some l x : find l = Some x -> In x l /\ f x = true. Proof. induction l as [\|a l IH]; simpl; [easy\| ]. case_eq (f a); intros Ha Eq. injection Eq as ->; auto. * destruct (IH Eq); auto. Qed. Lemma find_none l : find l = None -> forall x, In x l -> f x = false. Proof. induction l as [\|a l IH]; simpl; [easy\|]. case_eq (f a); intros Ha Eq x IN; [easy\|]. destruct IN as [<-\|IN]; auto. Qed. (** [partition] ) Fixpoint partition (l:list A) : list A list A := match l with \| nil => (nil, nil) \| x :: tl => let (g,d) := partition tl in if f x then (x::g,d) else (g,x::d) end. Theorem partition_cons1 a l l1 l2: partition l = (l1, l2) -> f a = true -> partition (a::l) = (a::l1, l2). Proof. simpl. now intros -> ->. Qed. Theorem partition_cons2 a l l1 l2: partition l = (l1, l2) -> f a=false -> partition (a::l) = (l1, a::l2). Proof. simpl. now intros -> ->. Qed. Theorem partition_length l l1 l2: partition l = (l1, l2) -> length l = length l1 + length l2. Proof. revert l1 l2. induction l as [ \| a l' Hrec]; intros l1 l2. - now intros [= <- <- ]. - simpl. destruct (f a), (partition l') as (left, right); intros [= <- <- ]; simpl; rewrite (Hrec left right); auto. Qed. Theorem partition_inv_nil (l : list A): partition l = ([], []) <-> l = []. Proof. split. - destruct l as [\|a l']. * intuition. * simpl. destruct (f a), (partition l'); now intros [= -> ->]. - now intros ->. Qed. Theorem elements_in_partition l l1 l2: partition l = (l1, l2) -> forall x:A, In x l <-> In x l1 \/ In x l2. Proof. revert l1 l2. induction l as [\| a l' Hrec]; simpl; intros l1 l2 Eq x. - injection Eq as <- <-. tauto. - destruct (partition l') as (left, right). specialize (Hrec left right eq_refl x). destruct (f a); injection Eq as <- <-; simpl; tauto. Qed. End Bool. (****************************************************) ( ** Operations on lists of pairs or lists of lists ) (***************************************************) Section ListPairs. Variables (A : Type) (B : Type). ( [split] derives two lists from a list of pairs ) Fixpoint split (l:list (AB)) : list A * list B := match l with \| [] => ([], []) \| (x,y) :: tl => let (left,right) := split tl in (x::left, y::right) end. Lemma in_split_l : forall (l:list (AB))(p:AB), In p l -> In (fst p) (fst (split l)). Proof. induction l; simpl; intros; auto. destruct p; destruct a; destruct (split l); simpl in . destruct H. injection H; auto. right; apply (IHl (a0,b) H). Qed. Lemma in_split_r : forall (l:list (AB))(p:AB), In p l -> In (snd p) (snd (split l)). Proof. induction l; simpl; intros; auto. destruct p; destruct a; destruct (split l); simpl in . destruct H. injection H; auto. right; apply (IHl (a0,b) H). Qed. Lemma split_nth : forall (l:list (AB))(n:nat)(d:AB), nth n l d = (nth n (fst (split l)) (fst d), nth n (snd (split l)) (snd d)). Proof. induction l. destruct n; destruct d; simpl; auto. destruct n; destruct d; simpl; auto. destruct a; destruct (split l); simpl; auto. destruct a; destruct (split l); simpl in ; auto. apply IHl. Qed. Lemma split_length_l : forall (l:list (AB)), length (fst (split l)) = length l. Proof. induction l; simpl; auto. destruct a; destruct (split l); simpl; auto. Qed. Lemma split_length_r : forall (l:list (AB)), length (snd (split l)) = length l. Proof. induction l; simpl; auto. destruct a; destruct (split l); simpl; auto. Qed. (* [combine] is the opposite of [split]. Lists given to [combine] are meant to be of same length. If not, [combine] stops on the shorter list ) Fixpoint combine (l : list A) (l' : list B) : list (AB) := match l,l' with \| x::tl, y::tl' => (x,y)::(combine tl tl') \| _, _ => nil end. Lemma split_combine : forall (l: list (AB)), let (l1,l2) := split l in combine l1 l2 = l. Proof. induction l. simpl; auto. destruct a; simpl. destruct (split l); simpl in . f_equal; auto. Qed. Lemma combine_split : forall (l:list A)(l':list B), length l = length l' -> split (combine l l') = (l,l'). Proof. induction l, l'; simpl; trivial; try discriminate. now intros [= ->%IHl]. Qed. Lemma in_combine_l : forall (l:list A)(l':list B)(x:A)(y:B), In (x,y) (combine l l') -> In x l. Proof. induction l. simpl; auto. destruct l'; simpl; auto; intros. contradiction. destruct H. injection H; auto. right; apply IHl with l' y; auto. Qed. Lemma in_combine_r : forall (l:list A)(l':list B)(x:A)(y:B), In (x,y) (combine l l') -> In y l'. Proof. induction l. simpl; intros; contradiction. destruct l'; simpl; auto; intros. destruct H. injection H; auto. right; apply IHl with x; auto. Qed. Lemma combine_length : forall (l:list A)(l':list B), length (combine l l') = min (length l) (length l'). Proof. induction l. simpl; auto. destruct l'; simpl; auto. Qed. Lemma combine_nth : forall (l:list A)(l':list B)(n:nat)(x:A)(y:B), length l = length l' -> nth n (combine l l') (x,y) = (nth n l x, nth n l' y). Proof. induction l; destruct l'; intros; try discriminate. destruct n; simpl; auto. destruct n; simpl in ; auto. Qed. (* [list_prod] has the same signature as [combine], but unlike [combine], it adds every possible pairs, not only those at the same position. ) Fixpoint list_prod (l:list A) (l':list B) : list (A B) := match l with \| nil => nil \| cons x t => (map (fun y:B => (x, y)) l')++(list_prod t l') end. Lemma in_prod_aux : forall (x:A) (y:B) (l:list B), In y l -> In (x, y) (map (fun y0:B => (x, y0)) l). Proof. induction l; [ simpl; auto \| simpl; destruct 1 as [H1\| ]; [ left; rewrite H1; trivial \| right; auto ] ]. Qed. Lemma in_prod : forall (l:list A) (l':list B) (x:A) (y:B), In x l -> In y l' -> In (x, y) (list_prod l l'). Proof. induction l; [ simpl; tauto \| simpl; intros; apply in_or_app; destruct H; [ left; rewrite H; apply in_prod_aux; assumption \| right; auto ] ]. Qed. Lemma in_prod_iff : forall (l:list A)(l':list B)(x:A)(y:B), In (x,y) (list_prod l l') <-> In x l /\ In y l'. Proof. split; [ \| intros; apply in_prod; intuition ]. induction l; simpl; intros. intuition. destruct (in_app_or _ _ _ H); clear H. destruct (in_map_iff (fun y : B => (a, y)) l' (x,y)) as (H1,_). destruct (H1 H0) as (z,(H2,H3)); clear H0 H1. injection H2 as -> ->; intuition. intuition. Qed. Lemma prod_length : forall (l:list A)(l':list B), length (list_prod l l') = (length l) * (length l'). Proof. induction l; simpl; auto. intros. rewrite app_length. rewrite map_length. auto. Qed. End ListPairs. (***************************************) ( * Miscellaneous operations on lists ) (**************************************) (**************************) ( ** Length order of lists ) (***************************) Section length_order. Variable A : Type. Definition lel (l m:list A) := length l <= length m. Variables a b : A. Variables l m n : list A. Lemma lel_refl : lel l l. Proof. unfold lel; auto with arith. Qed. Lemma lel_trans : lel l m -> lel m n -> lel l n. Proof. unfold lel; intros. now_show (length l <= length n). apply le_trans with (length m); auto with arith. Qed. Lemma lel_cons_cons : lel l m -> lel (a :: l) (b :: m). Proof. unfold lel; simpl; auto with arith. Qed. Lemma lel_cons : lel l m -> lel l (b :: m). Proof. unfold lel; simpl; auto with arith. Qed. Lemma lel_tail : lel (a :: l) (b :: m) -> lel l m. Proof. unfold lel; simpl; auto with arith. Qed. Lemma lel_nil : forall l':list A, lel l' nil -> nil = l'. Proof. intro l'; elim l'; auto with arith. intros a' y H H0. now_show (nil = a' :: y). absurd (S (length y) <= 0); auto with arith. Qed. End length_order. Hint Resolve lel_refl lel_cons_cons lel_cons lel_nil lel_nil nil_cons: datatypes. (**************************) ( ** Set inclusion on list ) (****************************) Section SetIncl. Variable A : Type. Definition incl (l m:list A) := forall a:A, In a l -> In a m. Hint Unfold incl. Lemma incl_refl : forall l:list A, incl l l. Proof. auto. Qed. Hint Resolve incl_refl. Lemma incl_tl : forall (a:A) (l m:list A), incl l m -> incl l (a :: m). Proof. auto with datatypes. Qed. Hint Immediate incl_tl. Lemma incl_tran : forall l m n:list A, incl l m -> incl m n -> incl l n. Proof. auto. Qed. Lemma incl_appl : forall l m n:list A, incl l n -> incl l (n ++ m). Proof. auto with datatypes. Qed. Hint Immediate incl_appl. Lemma incl_appr : forall l m n:list A, incl l n -> incl l (m ++ n). Proof. auto with datatypes. Qed. Hint Immediate incl_appr. Lemma incl_cons : forall (a:A) (l m:list A), In a m -> incl l m -> incl (a :: l) m. Proof. unfold incl; simpl; intros a l m H H0 a0 H1. now_show (In a0 m). elim H1. now_show (a = a0 -> In a0 m). elim H1; auto; intro H2. now_show (a = a0 -> In a0 m). elim H2; auto. ( solves subgoal ) now_show (In a0 l -> In a0 m). auto. Qed. Hint Resolve incl_cons. Lemma incl_app : forall l m n:list A, incl l n -> incl m n -> incl (l ++ m) n. Proof. unfold incl; simpl; intros l m n H H0 a H1. now_show (In a n). elim (in_app_or _ _ _ H1); auto. Qed. Hint Resolve incl_app. End SetIncl. Hint Resolve incl_refl incl_tl incl_tran incl_appl incl_appr incl_cons incl_app: datatypes. (***********************************) ( * Cutting a list at some position ) (************************************) Section Cutting. Variable A : Type. Fixpoint firstn (n:nat)(l:list A) : list A := match n with \| 0 => nil \| S n => match l with \| nil => nil \| a::l => a::(firstn n l) end end. Lemma firstn_nil n: firstn n [] = []. Proof. induction n; now simpl. Qed. Lemma firstn_cons n a l: firstn (S n) (a::l) = a :: (firstn n l). Proof. now simpl. Qed. Lemma firstn_all l: firstn (length l) l = l. Proof. induction l as [\| ? ? H]; simpl; [reflexivity \| now rewrite H]. Qed. Lemma firstn_all2 n: forall (l:list A), (length l) <= n -> firstn n l = l. Proof. induction n as [\|k iHk]. - intro. inversion 1 as [H1\|?]. rewrite (length_zero_iff_nil l) in H1. subst. now simpl. - destruct l as [\|x xs]; simpl. now reflexivity. * simpl. intro H. apply Peano.le_S_n in H. f_equal. apply iHk, H. Qed. Lemma firstn_O l: firstn 0 l = []. Proof. now simpl. Qed. Lemma firstn_le_length n: forall l:list A, length (firstn n l) <= n. Proof. induction n as [\|k iHk]; simpl; [auto \| destruct l as [\|x xs]; simpl]. - auto with arith. - apply Peano.le_n_S, iHk. Qed. Lemma firstn_length_le: forall l:list A, forall n:nat, n <= length l -> length (firstn n l) = n. Proof. induction l as [\|x xs Hrec]. - simpl. intros n H. apply le_n_0_eq in H. rewrite <- H. now simpl. - destruct n. * now simpl. * simpl. intro H. apply le_S_n in H. now rewrite (Hrec n H). Qed. Lemma firstn_app n: forall l1 l2, firstn n (l1 ++ l2) = (firstn n l1) ++ (firstn (n - length l1) l2). Proof. induction n as [\|k iHk]; intros l1 l2. - now simpl. - destruct l1 as [\|x xs]. * unfold firstn at 2, length. now rewrite 2!app_nil_l, <- minus_n_O. * rewrite <- app_comm_cons. simpl. f_equal. apply iHk. Qed. Lemma firstn_app_2 n: forall l1 l2, firstn ((length l1) + n) (l1 ++ l2) = l1 ++ firstn n l2. Proof. induction n as [\| k iHk];intros l1 l2. - unfold firstn at 2. rewrite <- plus_n_O, app_nil_r. rewrite firstn_app. rewrite <- minus_diag_reverse. unfold firstn at 2. rewrite app_nil_r. apply firstn_all. - destruct l2 as [\|x xs]. * simpl. rewrite app_nil_r. apply firstn_all2. auto with arith. * rewrite firstn_app. assert (H0 : (length l1 + S k - length l1) = S k). auto with arith. rewrite H0, firstn_all2; [reflexivity \| auto with arith]. Qed. Lemma firstn_firstn: forall l:list A, forall i j : nat, firstn i (firstn j l) = firstn (min i j) l. Proof. induction l as [\|x xs Hl]. - intros. simpl. now rewrite ?firstn_nil. - destruct i. * intro. now simpl. * destruct j. + now simpl. + simpl. f_equal. apply Hl. Qed. Fixpoint skipn (n:nat)(l:list A) : list A := match n with \| 0 => l \| S n => match l with \| nil => nil \| a::l => skipn n l end end. Lemma firstn_skipn : forall n l, firstn n l ++ skipn n l = l. Proof. induction n. simpl; auto. destruct l; simpl; auto. f_equal; auto. Qed. Lemma firstn_length : forall n l, length (firstn n l) = min n (length l). Proof. induction n; destruct l; simpl; auto. Qed. Lemma removelast_firstn : forall n l, n < length l -> removelast (firstn (S n) l) = firstn n l. Proof. induction n; destruct l. simpl; auto. simpl; auto. simpl; auto. intros. simpl in H. change (firstn (S (S n)) (a::l)) with ((a::nil)++firstn (S n) l). change (firstn (S n) (a::l)) with (a::firstn n l). rewrite removelast_app. rewrite IHn; auto with arith. clear IHn; destruct l; simpl in ; try discriminate. inversion_clear H. inversion_clear H0. Qed. Lemma firstn_removelast : forall n l, n < length l -> firstn n (removelast l) = firstn n l. Proof. induction n; destruct l. simpl; auto. simpl; auto. simpl; auto. intros. simpl in H. change (removelast (a :: l)) with (removelast ((a::nil)++l)). rewrite removelast_app. simpl; f_equal; auto with arith. intro H0; rewrite H0 in H; inversion_clear H; inversion_clear H1. Qed. End Cutting. (*******************************************************************) ( ** Predicate for List addition/removal (no need for decidability) ) (********************************************************************) Section Add. Variable A : Type. ( [Add a l l'] means that [l'] is exactly [l], with [a] added once somewhere ) Inductive Add (a:A) : list A -> list A -> Prop := \| Add_head l : Add a l (a::l) \| Add_cons x l l' : Add a l l' -> Add a (x::l) (x::l'). Lemma Add_app a l1 l2 : Add a (l1++l2) (l1++a::l2). Proof. induction l1; simpl; now constructor. Qed. Lemma Add_split a l l' : Add a l l' -> exists l1 l2, l = l1++l2 /\ l' = l1++a::l2. Proof. induction 1. - exists nil; exists l; split; trivial. - destruct IHAdd as (l1 & l2 & Hl & Hl'). exists (x::l1); exists l2; split; simpl; f_equal; trivial. Qed. Lemma Add_in a l l' : Add a l l' -> forall x, In x l' <-> In x (a::l). Proof. induction 1; intros; simpl in ; rewrite ?IHAdd; tauto. Qed. Lemma Add_length a l l' : Add a l l' -> length l' = S (length l). Proof. induction 1; simpl; auto with arith. Qed. Lemma Add_inv a l : In a l -> exists l', Add a l' l. Proof. intro Ha. destruct (in_split _ _ Ha) as (l1 & l2 & ->). exists (l1 ++ l2). apply Add_app. Qed. Lemma incl_Add_inv a l u v : ~In a l -> incl (a::l) v -> Add a u v -> incl l u. Proof. intros Ha H AD y Hy. assert (Hy' : In y (a::u)). { rewrite <- (Add_in AD). apply H; simpl; auto. } destruct Hy'; [ subst; now elim Ha \| trivial ]. Qed. End Add. (******************************) ( ** Lists without redundancy ) (******************************) Section ReDun. Variable A : Type. Inductive NoDup : list A -> Prop := \| NoDup_nil : NoDup nil \| NoDup_cons : forall x l, ~ In x l -> NoDup l -> NoDup (x::l). Lemma NoDup_Add a l l' : Add a l l' -> (NoDup l' <-> NoDup l /\ ~In a l). Proof. induction 1 as [l\|x l l' AD IH]. - split; [ inversion_clear 1; now split \| now constructor ]. - split. + inversion_clear 1. rewrite IH in . rewrite (Add_in AD) in . simpl in ; split; try constructor; intuition. + intros (N,IN). inversion_clear N. constructor. * rewrite (Add_in AD); simpl in ; intuition. apply IH. split; trivial. simpl in ; intuition. Qed. Lemma NoDup_remove l l' a : NoDup (l++a::l') -> NoDup (l++l') /\ ~In a (l++l'). Proof. apply NoDup_Add. apply Add_app. Qed. Lemma NoDup_remove_1 l l' a : NoDup (l++a::l') -> NoDup (l++l'). Proof. intros. now apply NoDup_remove with a. Qed. Lemma NoDup_remove_2 l l' a : NoDup (l++a::l') -> ~In a (l++l'). Proof. intros. now apply NoDup_remove. Qed. Theorem NoDup_cons_iff a l: NoDup (a::l) <-> ~ In a l /\ NoDup l. Proof. split. + inversion_clear 1. now split. + now constructor. Qed. (* Effective computation of a list without duplicates ) Hypothesis decA: forall x y : A, {x = y} + {x <> y}. Fixpoint nodup (l : list A) : list A := match l with \| [] => [] \| x::xs => if in_dec decA x xs then nodup xs else x::(nodup xs) end. Lemma nodup_In l x : In x (nodup l) <-> In x l. Proof. induction l as [\|a l' Hrec]; simpl. - reflexivity. - destruct (in_dec decA a l'); simpl; rewrite Hrec. intuition; now subst. * reflexivity. Qed. Lemma NoDup_nodup l: NoDup (nodup l). Proof. induction l as [\|a l' Hrec]; simpl. - constructor. - destruct (in_dec decA a l'); simpl. * assumption. * constructor; [ now rewrite nodup_In \| assumption]. Qed. Lemma nodup_inv k l a : nodup k = a :: l -> ~ In a l. Proof. intros H. assert (H' : NoDup (a::l)). { rewrite <- H. apply NoDup_nodup. } now inversion_clear H'. Qed. Theorem NoDup_count_occ l: NoDup l <-> (forall x:A, count_occ decA l x <= 1). Proof. induction l as [\| a l' Hrec]. - simpl; split; auto. constructor. - rewrite NoDup_cons_iff, Hrec, (count_occ_not_In decA). clear Hrec. split. + intros (Ha, H) x. simpl. destruct (decA a x); auto. subst; now rewrite Ha. + split. * specialize (H a). rewrite count_occ_cons_eq in H; trivial. now inversion H. * intros x. specialize (H x). simpl in . destruct (decA a x); auto. now apply Nat.lt_le_incl. Qed. Theorem NoDup_count_occ' l: NoDup l <-> (forall x:A, In x l -> count_occ decA l x = 1). Proof. rewrite NoDup_count_occ. setoid_rewrite (count_occ_In decA). unfold gt, lt in . split; intros H x; specialize (H x); set (n := count_occ decA l x) in ; clearbody n. ( the rest would be solved by omega if we had it here... ) - now apply Nat.le_antisymm. - destruct (Nat.le_gt_cases 1 n); trivial. + rewrite H; trivial. + now apply Nat.lt_le_incl. Qed. (* Alternative characterisations of being without duplicates, thanks to [nth_error] and [nth] ) Lemma NoDup_nth_error l : NoDup l <-> (forall i j, i<length l -> nth_error l i = nth_error l j -> i = j). Proof. split. { intros H; induction H as [\|a l Hal Hl IH]; intros i j Hi E. - inversion Hi. - destruct i, j; simpl in ; auto. * elim Hal. eapply nth_error_In; eauto. * elim Hal. eapply nth_error_In; eauto. * f_equal. apply IH; auto with arith. } { induction l as [\|a l]; intros H; constructor. * intro Ha. apply In_nth_error in Ha. destruct Ha as (n,Hn). assert (n < length l) by (now rewrite <- nth_error_Some, Hn). specialize (H 0 (S n)). simpl in H. discriminate H; auto with arith. * apply IHl. intros i j Hi E. apply eq_add_S, H; simpl; auto with arith. } Qed. Lemma NoDup_nth l d : NoDup l <-> (forall i j, i<length l -> j<length l -> nth i l d = nth j l d -> i = j). Proof. split. { intros H; induction H as [\|a l Hal Hl IH]; intros i j Hi Hj E. - inversion Hi. - destruct i, j; simpl in ; auto. elim Hal. subst a. apply nth_In; auto with arith. * elim Hal. subst a. apply nth_In; auto with arith. * f_equal. apply IH; auto with arith. } { induction l as [\|a l]; intros H; constructor. * intro Ha. eapply In_nth in Ha. destruct Ha as (n & Hn & Hn'). specialize (H 0 (S n)). simpl in H. discriminate H; eauto with arith. * apply IHl. intros i j Hi Hj E. apply eq_add_S, H; simpl; auto with arith. } Qed. (** Having [NoDup] hypotheses bring more precise facts about [incl]. ) Lemma NoDup_incl_length l l' : NoDup l -> incl l l' -> length l <= length l'. Proof. intros N. revert l'. induction N as [\|a l Hal N IH]; simpl. - auto with arith. - intros l' H. destruct (Add_inv a l') as (l'', AD). { apply H; simpl; auto. } rewrite (Add_length AD). apply le_n_S. apply IH. now apply incl_Add_inv with a l'. Qed. Lemma NoDup_length_incl l l' : NoDup l -> length l' <= length l -> incl l l' -> incl l' l. Proof. intros N. revert l'. induction N as [\|a l Hal N IH]. - destruct l'; easy. - intros l' E H x Hx. destruct (Add_inv a l') as (l'', AD). { apply H; simpl; auto. } rewrite (Add_in AD) in Hx. simpl in Hx. destruct Hx as [Hx\|Hx]; [left; trivial\|right]. revert x Hx. apply (IH l''); trivial. apply le_S_n. now rewrite <- (Add_length AD). * now apply incl_Add_inv with a l'. Qed. End ReDun. (** NoDup and map ) (* NB: the reciprocal result holds only for injective functions, see FinFun.v ) Lemma NoDup_map_inv A B (f:A->B) l : NoDup (map f l) -> NoDup l. Proof. induction l; simpl; inversion_clear 1; subst; constructor; auto. intro H. now apply (in_map f) in H. Qed. (********************************) ( ** Sequence of natural numbers ) (********************************) Section NatSeq. ( [seq] computes the sequence of [len] contiguous integers that starts at [start]. For instance, [seq 2 3] is [2::3::4::nil]. ) Fixpoint seq (start len:nat) : list nat := match len with \| 0 => nil \| S len => start :: seq (S start) len end. Lemma seq_length : forall len start, length (seq start len) = len. Proof. induction len; simpl; auto. Qed. Lemma seq_nth : forall len start n d, n < len -> nth n (seq start len) d = start+n. Proof. induction len; intros. inversion H. simpl seq. destruct n; simpl. auto with arith. rewrite IHlen;simpl; auto with arith. Qed. Lemma seq_shift : forall len start, map S (seq start len) = seq (S start) len. Proof. induction len; simpl; auto. intros. rewrite IHlen. auto with arith. Qed. Lemma in_seq len start n : In n (seq start len) <-> start <= n < start+len. Proof. revert start. induction len; simpl; intros. - rewrite <- plus_n_O. split;[easy\|]. intros (H,H'). apply (Lt.lt_irrefl _ (Lt.le_lt_trans _ _ _ H H')). - rewrite IHlen, <- plus_n_Sm; simpl; split. intros [H\|H]; subst; intuition auto with arith. * intros (H,H'). destruct (Lt.le_lt_or_eq _ _ H); intuition. Qed. Lemma seq_NoDup len start : NoDup (seq start len). Proof. revert start; induction len; simpl; constructor; trivial. rewrite in_seq. intros (H,_). apply (Lt.lt_irrefl _ H). Qed. End NatSeq. Section Exists_Forall. (** * Existential and universal predicates over lists ) Variable A:Type. Section One_predicate. Variable P:A->Prop. Inductive Exists : list A -> Prop := \| Exists_cons_hd : forall x l, P x -> Exists (x::l) \| Exists_cons_tl : forall x l, Exists l -> Exists (x::l). Hint Constructors Exists. Lemma Exists_exists (l:list A) : Exists l <-> (exists x, In x l /\ P x). Proof. split. - induction 1; firstorder. - induction l; firstorder; subst; auto. Qed. Lemma Exists_nil : Exists nil <-> False. Proof. split; inversion 1. Qed. Lemma Exists_cons x l: Exists (x::l) <-> P x \/ Exists l. Proof. split; inversion 1; auto. Qed. Lemma Exists_dec l: (forall x:A, {P x} + { ~ P x }) -> {Exists l} + {~ Exists l}. Proof. intro Pdec. induction l as [\|a l' Hrec]. - right. now rewrite Exists_nil. - destruct Hrec as [Hl'\|Hl']. left. now apply Exists_cons_tl. * destruct (Pdec a) as [Ha\|Ha]. + left. now apply Exists_cons_hd. + right. now inversion_clear 1. Qed. Inductive Forall : list A -> Prop := \| Forall_nil : Forall nil \| Forall_cons : forall x l, P x -> Forall l -> Forall (x::l). Hint Constructors Forall. Lemma Forall_forall (l:list A): Forall l <-> (forall x, In x l -> P x). Proof. split. - induction 1; firstorder; subst; auto. - induction l; firstorder. Qed. Lemma Forall_inv : forall (a:A) l, Forall (a :: l) -> P a. Proof. intros; inversion H; trivial. Qed. Lemma Forall_rect : forall (Q : list A -> Type), Q [] -> (forall b l, P b -> Q (b :: l)) -> forall l, Forall l -> Q l. Proof. intros Q H H'; induction l; intro; [\|eapply H', Forall_inv]; eassumption. Qed. Lemma Forall_dec : (forall x:A, {P x} + { ~ P x }) -> forall l:list A, {Forall l} + {~ Forall l}. Proof. intro Pdec. induction l as [\|a l' Hrec]. - left. apply Forall_nil. - destruct Hrec as [Hl'\|Hl']. + destruct (Pdec a) as [Ha\|Ha]. * left. now apply Forall_cons. * right. now inversion_clear 1. + right. now inversion_clear 1. Qed. End One_predicate. Lemma Forall_Exists_neg (P:A->Prop)(l:list A) : Forall (fun x => ~ P x) l <-> ~(Exists P l). Proof. rewrite Forall_forall, Exists_exists. firstorder. Qed. Lemma Exists_Forall_neg (P:A->Prop)(l:list A) : (forall x, P x \/ ~P x) -> Exists (fun x => ~ P x) l <-> ~(Forall P l). Proof. intro Dec. split. - rewrite Forall_forall, Exists_exists; firstorder. - intros NF. induction l as [\|a l IH]. + destruct NF. constructor. + destruct (Dec a) as [Ha\|Ha]. * apply Exists_cons_tl, IH. contradict NF. now constructor. * now apply Exists_cons_hd. Qed. Lemma Forall_Exists_dec (P:A->Prop) : (forall x:A, {P x} + { ~ P x }) -> forall l:list A, {Forall P l} + {Exists (fun x => ~ P x) l}. Proof. intros Pdec l. destruct (Forall_dec P Pdec l); [left\|right]; trivial. apply Exists_Forall_neg; trivial. intro x. destruct (Pdec x); [now left\|now right]. Qed. Lemma Forall_impl : forall (P Q : A -> Prop), (forall a, P a -> Q a) -> forall l, Forall P l -> Forall Q l. Proof. intros P Q H l. rewrite !Forall_forall. firstorder. Qed. End Exists_Forall. Hint Constructors Exists. Hint Constructors Forall. Section Forall2. (** [Forall2]: stating that elements of two lists are pairwise related. ) Variables A B : Type. Variable R : A -> B -> Prop. Inductive Forall2 : list A -> list B -> Prop := \| Forall2_nil : Forall2 [] [] \| Forall2_cons : forall x y l l', R x y -> Forall2 l l' -> Forall2 (x::l) (y::l'). Hint Constructors Forall2. Theorem Forall2_refl : Forall2 [] []. Proof. intros; apply Forall2_nil. Qed. Theorem Forall2_app_inv_l : forall l1 l2 l', Forall2 (l1 ++ l2) l' -> exists l1' l2', Forall2 l1 l1' /\ Forall2 l2 l2' /\ l' = l1' ++ l2'. Proof. induction l1; intros. exists [], l'; auto. simpl in H; inversion H; subst; clear H. apply IHl1 in H4 as (l1' & l2' & Hl1 & Hl2 & ->). exists (y::l1'), l2'; simpl; auto. Qed. Theorem Forall2_app_inv_r : forall l1' l2' l, Forall2 l (l1' ++ l2') -> exists l1 l2, Forall2 l1 l1' /\ Forall2 l2 l2' /\ l = l1 ++ l2. Proof. induction l1'; intros. exists [], l; auto. simpl in H; inversion H; subst; clear H. apply IHl1' in H4 as (l1 & l2 & Hl1 & Hl2 & ->). exists (x::l1), l2; simpl; auto. Qed. Theorem Forall2_app : forall l1 l2 l1' l2', Forall2 l1 l1' -> Forall2 l2 l2' -> Forall2 (l1 ++ l2) (l1' ++ l2'). Proof. intros. induction l1 in l1', H, H0 \|- ; inversion H; subst; simpl; auto. Qed. End Forall2. Hint Constructors Forall2. Section ForallPairs. (** [ForallPairs] : specifies that a certain relation should always hold when inspecting all possible pairs of elements of a list. ) Variable A : Type. Variable R : A -> A -> Prop. Definition ForallPairs l := forall a b, In a l -> In b l -> R a b. (* [ForallOrdPairs] : we still check a relation over all pairs of elements of a list, but now the order of elements matters. ) Inductive ForallOrdPairs : list A -> Prop := \| FOP_nil : ForallOrdPairs nil \| FOP_cons : forall a l, Forall (R a) l -> ForallOrdPairs l -> ForallOrdPairs (a::l). Hint Constructors ForallOrdPairs. Lemma ForallOrdPairs_In : forall l, ForallOrdPairs l -> forall x y, In x l -> In y l -> x=y \/ R x y \/ R y x. Proof. induction 1. inversion 1. simpl; destruct 1; destruct 1; subst; auto. right; left. apply -> Forall_forall; eauto. right; right. apply -> Forall_forall; eauto. Qed. (* [ForallPairs] implies [ForallOrdPairs]. The reverse implication is true only when [R] is symmetric and reflexive. ) Lemma ForallPairs_ForallOrdPairs l: ForallPairs l -> ForallOrdPairs l. Proof. induction l; auto. intros H. constructor. apply <- Forall_forall. intros; apply H; simpl; auto. apply IHl. red; intros; apply H; simpl; auto. Qed. Lemma ForallOrdPairs_ForallPairs : (forall x, R x x) -> (forall x y, R x y -> R y x) -> forall l, ForallOrdPairs l -> ForallPairs l. Proof. intros Refl Sym l Hl x y Hx Hy. destruct (ForallOrdPairs_In Hl _ _ Hx Hy); subst; intuition. Qed. End ForallPairs. (* * Inversion of predicates over lists based on head symbol ) Ltac is_list_constr c := match c with \| nil => idtac \| (_::_) => idtac \| _ => fail end. Ltac invlist f := match goal with \| H:f ?l \|- _ => is_list_constr l; inversion_clear H; invlist f \| H:f _ ?l \|- _ => is_list_constr l; inversion_clear H; invlist f \| H:f _ _ ?l \|- _ => is_list_constr l; inversion_clear H; invlist f \| H:f _ _ _ ?l \|- _ => is_list_constr l; inversion_clear H; invlist f \| H:f _ _ _ _ ?l \|- _ => is_list_constr l; inversion_clear H; invlist f \| _ => idtac end. (* * Exporting hints and tactics ) Hint Rewrite rev_involutive ( rev (rev l) = l ) rev_unit ( rev (l ++ a :: nil) = a :: rev l ) map_nth ( nth n (map f l) (f d) = f (nth n l d) ) map_length ( length (map f l) = length l ) seq_length ( length (seq start len) = len ) app_length ( length (l ++ l') = length l + length l' ) rev_length ( length (rev l) = length l ) app_nil_r ( l ++ nil = l ) : list. Ltac simpl_list := autorewrite with list. Ltac ssimpl_list := autorewrite with list using simpl. ( begin hide ) ( Compatibility notations after the migration of [list] to [Datatypes] ) Notation list := list (only parsing). Notation list_rect := list_rect (only parsing). Notation list_rec := list_rec (only parsing). Notation list_ind := list_ind (only parsing). Notation nil := nil (only parsing). Notation cons := cons (only parsing). Notation length := length (only parsing). Notation app := app (only parsing). ( Compatibility Names ) Notation tail := tl (only parsing). Notation head := hd_error (only parsing). Notation head_nil := hd_error_nil (only parsing). Notation head_cons := hd_error_cons (only parsing). Notation ass_app := app_assoc (only parsing). Notation app_ass := app_assoc_reverse (only parsing). Notation In_split := in_split (only parsing). Notation In_rev := in_rev (only parsing). Notation In_dec := in_dec (only parsing). Notation distr_rev := rev_app_distr (only parsing). Notation rev_acc := rev_append (only parsing). Notation rev_acc_rev := rev_append_rev (only parsing). Notation AllS := Forall (only parsing). ( was formerly in TheoryList ) Hint Resolve app_nil_end : datatypes. ( end hide ) Section Repeat. Variable A : Type. Fixpoint repeat (x : A) (n: nat ) := match n with \| O => [] \| S k => x::(repeat x k) end. Theorem repeat_length x n: length (repeat x n) = n. Proof. induction n as [\| k Hrec]; simpl; rewrite ?Hrec; reflexivity. Qed. Theorem repeat_spec n x y: In y (repeat x n) -> y=x. Proof. induction n as [\|k Hrec]; simpl; destruct 1; auto. Qed. End Repeat. ( Unset Universe Polymorphism. *)
// -- (c) Copyright 2009 - 2011 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // Filename: trace_buffer.v // Description: Trace port buffer //----------------------------------------------------------------------------- // Structure: This section shows the hierarchical structure of // pss_wrapper. // // --processing_system7 // \| // --trace_buffer //----------------------------------------------------------------------------- module processing_system7_v5_5_trace_buffer # ( parameter integer FIFO_SIZE = 128, parameter integer USE_TRACE_DATA_EDGE_DETECTOR = 0, parameter integer C_DELAY_CLKS = 12 ) ( input wire TRACE_CLK, input wire RST, input wire TRACE_VALID_IN, input wire [3:0] TRACE_ATID_IN, input wire [31:0] TRACE_DATA_IN, output wire TRACE_VALID_OUT, output wire [3:0] TRACE_ATID_OUT, output wire [31:0] TRACE_DATA_OUT ); //------------------------------------------------------------ // Architecture section //------------------------------------------------------------ // function called clogb2 that returns an integer which has the // value of the ceiling of the log base 2. function integer clogb2 (input integer bit_depth); integer i; integer temp_log; begin temp_log = 0; for(i=bit_depth; i > 0; i = i>>1) clogb2 = temp_log; temp_log=temp_log+1; end endfunction localparam DEPTH = clogb2(FIFO_SIZE-1); wire [31:0] reset_zeros; reg [31:0] trace_pedge; // write enable for FIFO reg [31:0] ti; reg [31:0] tom; reg [3:0] atid; reg [31:0] trace_fifo [FIFO_SIZE-1:0];//Memory reg [4:0] dly_ctr; reg [DEPTH-1:0] fifo_wp; reg [DEPTH-1:0] fifo_rp; reg fifo_re; wire fifo_empty; wire fifo_full; reg fifo_full_reg; assign reset_zeros = 32'h0; // Pipeline Stage for Traceport ATID ports always @(posedge TRACE_CLK) begin // process pedge_ti // rising clock edge if((RST == 1'b1)) begin atid <= reset_zeros; end else begin atid <= TRACE_ATID_IN; end end assign TRACE_ATID_OUT = atid; ///////////////////////////////////////////// // Generate FIFO data based on TRACE_VALID_IN ///////////////////////////////////////////// generate if (USE_TRACE_DATA_EDGE_DETECTOR == 0) begin : gen_no_data_edge_detector ///////////////////////////////////////////// // memory update process // Update memory when positive edge detected and FIFO not full always @(posedge TRACE_CLK) begin if (TRACE_VALID_IN == 1'b1 && fifo_full_reg != 1'b1) begin trace_fifo[fifo_wp] <= TRACE_DATA_IN; end end // fifo write pointer always @(posedge TRACE_CLK) begin // process if(RST == 1'b1) begin fifo_wp <= {DEPTH{1'b0}}; end else if(TRACE_VALID_IN ) begin if(fifo_wp == (FIFO_SIZE - 1)) begin if (fifo_empty) begin fifo_wp <= {DEPTH{1'b0}}; end end else begin fifo_wp <= fifo_wp + 1; end end end ///////////////////////////////////////////// // Generate FIFO data based on data edge ///////////////////////////////////////////// end else begin : gen_data_edge_detector ///////////////////////////////////////////// // purpose: check for pos edge on any trace input always @(posedge TRACE_CLK) begin // process pedge_ti // rising clock edge if((RST == 1'b1)) begin ti <= reset_zeros; trace_pedge <= reset_zeros; end else begin ti <= TRACE_DATA_IN; trace_pedge <= (~ti & TRACE_DATA_IN); //trace_pedge <= ((~ti ^ TRACE_DATA_IN)) & ~ti; // posedge only end end // memory update process // Update memory when positive edge detected and FIFO not full always @(posedge TRACE_CLK) begin if(\|(trace_pedge) == 1'b1 && fifo_full_reg != 1'b1) begin trace_fifo[fifo_wp] <= trace_pedge; end end // fifo write pointer always @(posedge TRACE_CLK) begin // process if(RST == 1'b1) begin fifo_wp <= {DEPTH{1'b0}}; end else if(\|(trace_pedge) == 1'b1) begin if(fifo_wp == (FIFO_SIZE - 1)) begin if (fifo_empty) begin fifo_wp <= {DEPTH{1'b0}}; end end else begin fifo_wp <= fifo_wp + 1; end end end end endgenerate always @(posedge TRACE_CLK) begin tom <= trace_fifo[fifo_rp] ; end // // fifo write pointer // always @(posedge TRACE_CLK) begin // // process // if(RST == 1'b1) begin // fifo_wp <= {DEPTH{1'b0}}; // end // else if(\|(trace_pedge) == 1'b1) begin // if(fifo_wp == (FIFO_SIZE - 1)) begin // fifo_wp <= {DEPTH{1'b0}}; // end // else begin // fifo_wp <= fifo_wp + 1; // end // end // end // fifo read pointer update always @(posedge TRACE_CLK) begin if(RST == 1'b1) begin fifo_rp <= {DEPTH{1'b0}}; fifo_re <= 1'b0; end else if(fifo_empty != 1'b1 && dly_ctr == 5'b00000 && fifo_re == 1'b0) begin fifo_re <= 1'b1; if(fifo_rp == (FIFO_SIZE - 1)) begin fifo_rp <= {DEPTH{1'b0}}; end else begin fifo_rp <= fifo_rp + 1; end end else begin fifo_re <= 1'b0; end end // delay counter update always @(posedge TRACE_CLK) begin if(RST == 1'b1) begin dly_ctr <= 5'h0; end else if (fifo_re == 1'b1) begin dly_ctr <= C_DELAY_CLKS-1; end else if(dly_ctr != 5'h0) begin dly_ctr <= dly_ctr - 1; end end // fifo empty update assign fifo_empty = (fifo_wp == fifo_rp) ? 1'b1 : 1'b0; // fifo full update assign fifo_full = (fifo_wp == FIFO_SIZE-1)? 1'b1 : 1'b0; always @(posedge TRACE_CLK) begin if(RST == 1'b1) begin fifo_full_reg <= 1'b0; end else if (fifo_empty) begin fifo_full_reg <= 1'b0; end else begin fifo_full_reg <= fifo_full; end end // always @(posedge TRACE_CLK) begin // if(RST == 1'b1) begin // fifo_full_reg <= 1'b0; // end // else if ((fifo_wp == FIFO_SIZE-1) && (\|(trace_pedge) == 1'b1)) begin // fifo_full_reg <= 1'b1; // end // else begin // fifo_full_reg <= 1'b0; // end // end // assign TRACE_DATA_OUT = tom; assign TRACE_VALID_OUT = fifo_re; endmodule
// (c) Copyright 1995-2015 Xilinx, Inc. All rights reserved. // // This file contains confidential and proprietary information // of Xilinx, Inc. and is protected under U.S. and // international copyright and other intellectual property // laws. // // DISCLAIMER // This disclaimer is not a license and does not grant any // rights to the materials distributed herewith. Except as // otherwise provided in a valid license issued to you by // Xilinx, and to the maximum extent permitted by applicable // law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // (2) Xilinx shall not be liable (whether in contract or tort, // including negligence, or under any other theory of // liability) for any loss or damage of any kind or nature // related to, arising under or in connection with these // materials, including for any direct, or any indirect, // special, incidental, or consequential loss or damage // (including loss of data, profits, goodwill, or any type of // loss or damage suffered as a result of any action brought // by a third party) even if such damage or loss was // reasonably foreseeable or Xilinx had been advised of the // possibility of the same. // // CRITICAL APPLICATIONS // Xilinx products are not designed or intended to be fail- // safe, or for use in any application requiring fail-safe // performance, such as life-support or safety devices or // systems, Class III medical devices, nuclear facilities, // applications related to the deployment of airbags, or any // other applications that could lead to death, personal // injury, or severe property or environmental damage // (individually and collectively, "Critical // Applications"). Customer assumes the sole risk and // liability of any use of Xilinx products in Critical // Applications, subject only to applicable laws and // regulations governing limitations on product liability. // // THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // PART OF THIS FILE AT ALL TIMES. // // DO NOT MODIFY THIS FILE. // IP VLNV: xilinx.com:ip:axi_crossbar:2.1 // IP Revision: 5 `timescale 1ns/1ps (* DowngradeIPIdentifiedWarnings = "yes" ) module tutorial_xbar_1 ( aclk, aresetn, s_axi_awid, s_axi_awaddr, s_axi_awlen, s_axi_awsize, s_axi_awburst, s_axi_awlock, s_axi_awcache, s_axi_awprot, s_axi_awqos, s_axi_awvalid, s_axi_awready, s_axi_wdata, s_axi_wstrb, s_axi_wlast, s_axi_wvalid, s_axi_wready, s_axi_bid, s_axi_bresp, s_axi_bvalid, s_axi_bready, s_axi_arid, s_axi_araddr, s_axi_arlen, s_axi_arsize, s_axi_arburst, s_axi_arlock, s_axi_arcache, s_axi_arprot, s_axi_arqos, s_axi_arvalid, s_axi_arready, s_axi_rid, s_axi_rdata, s_axi_rresp, s_axi_rlast, s_axi_rvalid, s_axi_rready, m_axi_awid, m_axi_awaddr, m_axi_awlen, m_axi_awsize, m_axi_awburst, m_axi_awlock, m_axi_awcache, m_axi_awprot, m_axi_awregion, m_axi_awqos, m_axi_awvalid, m_axi_awready, m_axi_wdata, m_axi_wstrb, m_axi_wlast, m_axi_wvalid, m_axi_wready, m_axi_bid, m_axi_bresp, m_axi_bvalid, m_axi_bready, m_axi_arid, m_axi_araddr, m_axi_arlen, m_axi_arsize, m_axi_arburst, m_axi_arlock, m_axi_arcache, m_axi_arprot, m_axi_arregion, m_axi_arqos, m_axi_arvalid, m_axi_arready, m_axi_rid, m_axi_rdata, m_axi_rresp, m_axi_rlast, m_axi_rvalid, m_axi_rready ); ( X_INTERFACE_INFO = "xilinx.com:signal:clock:1.0 CLKIF CLK" ) input wire aclk; ( X_INTERFACE_INFO = "xilinx.com:signal:reset:1.0 RSTIF RST" ) input wire aresetn; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI AWID [0:0] [1:1]" ) input wire [1 : 0] s_axi_awid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWADDR [31:0] [31:0], xilinx.com:interface:aximm:1.0 S01_AXI AWADDR [31:0] [63:32]" ) input wire [63 : 0] s_axi_awaddr; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWLEN [7:0] [7:0], xilinx.com:interface:aximm:1.0 S01_AXI AWLEN [7:0] [15:8]" ) input wire [15 : 0] s_axi_awlen; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWSIZE [2:0] [2:0], xilinx.com:interface:aximm:1.0 S01_AXI AWSIZE [2:0] [5:3]" ) input wire [5 : 0] s_axi_awsize; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWBURST [1:0] [1:0], xilinx.com:interface:aximm:1.0 S01_AXI AWBURST [1:0] [3:2]" ) input wire [3 : 0] s_axi_awburst; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWLOCK [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI AWLOCK [0:0] [1:1]" ) input wire [1 : 0] s_axi_awlock; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWCACHE [3:0] [3:0], xilinx.com:interface:aximm:1.0 S01_AXI AWCACHE [3:0] [7:4]" ) input wire [7 : 0] s_axi_awcache; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWPROT [2:0] [2:0], xilinx.com:interface:aximm:1.0 S01_AXI AWPROT [2:0] [5:3]" ) input wire [5 : 0] s_axi_awprot; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWQOS [3:0] [3:0], xilinx.com:interface:aximm:1.0 S01_AXI AWQOS [3:0] [7:4]" ) input wire [7 : 0] s_axi_awqos; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWVALID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI AWVALID [0:0] [1:1]" ) input wire [1 : 0] s_axi_awvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWREADY [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI AWREADY [0:0] [1:1]" ) output wire [1 : 0] s_axi_awready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI WDATA [63:0] [63:0], xilinx.com:interface:aximm:1.0 S01_AXI WDATA [63:0] [127:64]" ) input wire [127 : 0] s_axi_wdata; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI WSTRB [7:0] [7:0], xilinx.com:interface:aximm:1.0 S01_AXI WSTRB [7:0] [15:8]" ) input wire [15 : 0] s_axi_wstrb; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI WLAST [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI WLAST [0:0] [1:1]" ) input wire [1 : 0] s_axi_wlast; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI WVALID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI WVALID [0:0] [1:1]" ) input wire [1 : 0] s_axi_wvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI WREADY [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI WREADY [0:0] [1:1]" ) output wire [1 : 0] s_axi_wready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI BID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI BID [0:0] [1:1]" ) output wire [1 : 0] s_axi_bid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI BRESP [1:0] [1:0], xilinx.com:interface:aximm:1.0 S01_AXI BRESP [1:0] [3:2]" ) output wire [3 : 0] s_axi_bresp; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI BVALID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI BVALID [0:0] [1:1]" ) output wire [1 : 0] s_axi_bvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI BREADY [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI BREADY [0:0] [1:1]" ) input wire [1 : 0] s_axi_bready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI ARID [0:0] [1:1]" ) input wire [1 : 0] s_axi_arid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARADDR [31:0] [31:0], xilinx.com:interface:aximm:1.0 S01_AXI ARADDR [31:0] [63:32]" ) input wire [63 : 0] s_axi_araddr; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARLEN [7:0] [7:0], xilinx.com:interface:aximm:1.0 S01_AXI ARLEN [7:0] [15:8]" ) input wire [15 : 0] s_axi_arlen; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARSIZE [2:0] [2:0], xilinx.com:interface:aximm:1.0 S01_AXI ARSIZE [2:0] [5:3]" ) input wire [5 : 0] s_axi_arsize; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARBURST [1:0] [1:0], xilinx.com:interface:aximm:1.0 S01_AXI ARBURST [1:0] [3:2]" ) input wire [3 : 0] s_axi_arburst; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARLOCK [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI ARLOCK [0:0] [1:1]" ) input wire [1 : 0] s_axi_arlock; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARCACHE [3:0] [3:0], xilinx.com:interface:aximm:1.0 S01_AXI ARCACHE [3:0] [7:4]" ) input wire [7 : 0] s_axi_arcache; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARPROT [2:0] [2:0], xilinx.com:interface:aximm:1.0 S01_AXI ARPROT [2:0] [5:3]" ) input wire [5 : 0] s_axi_arprot; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARQOS [3:0] [3:0], xilinx.com:interface:aximm:1.0 S01_AXI ARQOS [3:0] [7:4]" ) input wire [7 : 0] s_axi_arqos; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARVALID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI ARVALID [0:0] [1:1]" ) input wire [1 : 0] s_axi_arvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARREADY [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI ARREADY [0:0] [1:1]" ) output wire [1 : 0] s_axi_arready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI RID [0:0] [1:1]" ) output wire [1 : 0] s_axi_rid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RDATA [63:0] [63:0], xilinx.com:interface:aximm:1.0 S01_AXI RDATA [63:0] [127:64]" ) output wire [127 : 0] s_axi_rdata; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RRESP [1:0] [1:0], xilinx.com:interface:aximm:1.0 S01_AXI RRESP [1:0] [3:2]" ) output wire [3 : 0] s_axi_rresp; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RLAST [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI RLAST [0:0] [1:1]" ) output wire [1 : 0] s_axi_rlast; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RVALID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI RVALID [0:0] [1:1]" ) output wire [1 : 0] s_axi_rvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RREADY [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI RREADY [0:0] [1:1]" ) input wire [1 : 0] s_axi_rready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWID" ) output wire [0 : 0] m_axi_awid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWADDR" ) output wire [31 : 0] m_axi_awaddr; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWLEN" ) output wire [7 : 0] m_axi_awlen; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWSIZE" ) output wire [2 : 0] m_axi_awsize; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWBURST" ) output wire [1 : 0] m_axi_awburst; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWLOCK" ) output wire [0 : 0] m_axi_awlock; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWCACHE" ) output wire [3 : 0] m_axi_awcache; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWPROT" ) output wire [2 : 0] m_axi_awprot; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWREGION" ) output wire [3 : 0] m_axi_awregion; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWQOS" ) output wire [3 : 0] m_axi_awqos; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWVALID" ) output wire [0 : 0] m_axi_awvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWREADY" ) input wire [0 : 0] m_axi_awready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI WDATA" ) output wire [63 : 0] m_axi_wdata; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI WSTRB" ) output wire [7 : 0] m_axi_wstrb; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI WLAST" ) output wire [0 : 0] m_axi_wlast; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI WVALID" ) output wire [0 : 0] m_axi_wvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI WREADY" ) input wire [0 : 0] m_axi_wready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI BID" ) input wire [0 : 0] m_axi_bid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI BRESP" ) input wire [1 : 0] m_axi_bresp; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI BVALID" ) input wire [0 : 0] m_axi_bvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI BREADY" ) output wire [0 : 0] m_axi_bready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARID" ) output wire [0 : 0] m_axi_arid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARADDR" ) output wire [31 : 0] m_axi_araddr; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARLEN" ) output wire [7 : 0] m_axi_arlen; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARSIZE" ) output wire [2 : 0] m_axi_arsize; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARBURST" ) output wire [1 : 0] m_axi_arburst; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARLOCK" ) output wire [0 : 0] m_axi_arlock; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARCACHE" ) output wire [3 : 0] m_axi_arcache; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARPROT" ) output wire [2 : 0] m_axi_arprot; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARREGION" ) output wire [3 : 0] m_axi_arregion; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARQOS" ) output wire [3 : 0] m_axi_arqos; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARVALID" ) output wire [0 : 0] m_axi_arvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARREADY" ) input wire [0 : 0] m_axi_arready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RID" ) input wire [0 : 0] m_axi_rid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RDATA" ) input wire [63 : 0] m_axi_rdata; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RRESP" ) input wire [1 : 0] m_axi_rresp; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RLAST" ) input wire [0 : 0] m_axi_rlast; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RVALID" ) input wire [0 : 0] m_axi_rvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RREADY" *) output wire [0 : 0] m_axi_rready; axi_crossbar_v2_1_axi_crossbar #( .C_FAMILY("zynq"), .C_NUM_SLAVE_SLOTS(2), .C_NUM_MASTER_SLOTS(1), .C_AXI_ID_WIDTH(1), .C_AXI_ADDR_WIDTH(32), .C_AXI_DATA_WIDTH(64), .C_AXI_PROTOCOL(0), .C_NUM_ADDR_RANGES(1), .C_M_AXI_BASE_ADDR(64'H0000000000000000), .C_M_AXI_ADDR_WIDTH(32'H0000001d), .C_S_AXI_BASE_ID(64'H0000000100000000), .C_S_AXI_THREAD_ID_WIDTH(64'H0000000100000000), .C_AXI_SUPPORTS_USER_SIGNALS(0), .C_AXI_AWUSER_WIDTH(1), .C_AXI_ARUSER_WIDTH(1), .C_AXI_WUSER_WIDTH(1), .C_AXI_RUSER_WIDTH(1), .C_AXI_BUSER_WIDTH(1), .C_M_AXI_WRITE_CONNECTIVITY(32'H00000002), .C_M_AXI_READ_CONNECTIVITY(32'H00000003), .C_R_REGISTER(0), .C_S_AXI_SINGLE_THREAD(64'H0000000000000000), .C_S_AXI_WRITE_ACCEPTANCE(64'H0000000200000004), .C_S_AXI_READ_ACCEPTANCE(64'H0000000200000002), .C_M_AXI_WRITE_ISSUING(32'H00000008), .C_M_AXI_READ_ISSUING(32'H00000008), .C_S_AXI_ARB_PRIORITY(64'H0000000000000000), .C_M_AXI_SECURE(32'H00000000), .C_CONNECTIVITY_MODE(1) ) inst ( .aclk(aclk), .aresetn(aresetn), .s_axi_awid(s_axi_awid), .s_axi_awaddr(s_axi_awaddr), .s_axi_awlen(s_axi_awlen), .s_axi_awsize(s_axi_awsize), .s_axi_awburst(s_axi_awburst), .s_axi_awlock(s_axi_awlock), .s_axi_awcache(s_axi_awcache), .s_axi_awprot(s_axi_awprot), .s_axi_awqos(s_axi_awqos), .s_axi_awuser(2'H0), .s_axi_awvalid(s_axi_awvalid), .s_axi_awready(s_axi_awready), .s_axi_wid(2'H0), .s_axi_wdata(s_axi_wdata), .s_axi_wstrb(s_axi_wstrb), .s_axi_wlast(s_axi_wlast), .s_axi_wuser(2'H0), .s_axi_wvalid(s_axi_wvalid), .s_axi_wready(s_axi_wready), .s_axi_bid(s_axi_bid), .s_axi_bresp(s_axi_bresp), .s_axi_buser(), .s_axi_bvalid(s_axi_bvalid), .s_axi_bready(s_axi_bready), .s_axi_arid(s_axi_arid), .s_axi_araddr(s_axi_araddr), .s_axi_arlen(s_axi_arlen), .s_axi_arsize(s_axi_arsize), .s_axi_arburst(s_axi_arburst), .s_axi_arlock(s_axi_arlock), .s_axi_arcache(s_axi_arcache), .s_axi_arprot(s_axi_arprot), .s_axi_arqos(s_axi_arqos), .s_axi_aruser(2'H0), .s_axi_arvalid(s_axi_arvalid), .s_axi_arready(s_axi_arready), .s_axi_rid(s_axi_rid), .s_axi_rdata(s_axi_rdata), .s_axi_rresp(s_axi_rresp), .s_axi_rlast(s_axi_rlast), .s_axi_ruser(), .s_axi_rvalid(s_axi_rvalid), .s_axi_rready(s_axi_rready), .m_axi_awid(m_axi_awid), .m_axi_awaddr(m_axi_awaddr), .m_axi_awlen(m_axi_awlen), .m_axi_awsize(m_axi_awsize), .m_axi_awburst(m_axi_awburst), .m_axi_awlock(m_axi_awlock), .m_axi_awcache(m_axi_awcache), .m_axi_awprot(m_axi_awprot), .m_axi_awregion(m_axi_awregion), .m_axi_awqos(m_axi_awqos), .m_axi_awuser(), .m_axi_awvalid(m_axi_awvalid), .m_axi_awready(m_axi_awready), .m_axi_wid(), .m_axi_wdata(m_axi_wdata), .m_axi_wstrb(m_axi_wstrb), .m_axi_wlast(m_axi_wlast), .m_axi_wuser(), .m_axi_wvalid(m_axi_wvalid), .m_axi_wready(m_axi_wready), .m_axi_bid(m_axi_bid), .m_axi_bresp(m_axi_bresp), .m_axi_buser(1'H0), .m_axi_bvalid(m_axi_bvalid), .m_axi_bready(m_axi_bready), .m_axi_arid(m_axi_arid), .m_axi_araddr(m_axi_araddr), .m_axi_arlen(m_axi_arlen), .m_axi_arsize(m_axi_arsize), .m_axi_arburst(m_axi_arburst), .m_axi_arlock(m_axi_arlock), .m_axi_arcache(m_axi_arcache), .m_axi_arprot(m_axi_arprot), .m_axi_arregion(m_axi_arregion), .m_axi_arqos(m_axi_arqos), .m_axi_aruser(), .m_axi_arvalid(m_axi_arvalid), .m_axi_arready(m_axi_arready), .m_axi_rid(m_axi_rid), .m_axi_rdata(m_axi_rdata), .m_axi_rresp(m_axi_rresp), .m_axi_rlast(m_axi_rlast), .m_axi_ruser(1'H0), .m_axi_rvalid(m_axi_rvalid), .m_axi_rready(m_axi_rready) ); endmodule
//---------------------------------------------------------------------- // my6502mc: my6502 mpu microcode decoder //---------------------------------------------------------------------- module my6502mc ( input [7:0] opcode, // opcode input [2:0] cyc_cnt, // execution cycle count output reg [55:0] opc_inst, // opcode decode by instruction output reg [7:0] opc_flag, // modified flag indicator output opc_src_a_ar, // alu source a indicator (a reg) output opc_src_a_xr, // alu source a indicator (x reg) output opc_src_a_yr, // alu source a indicator (y reg) output opc_src_a_sp, // alu source a indicator (sp reg) output opc_src_a_ps, // alu source a indicator (ps reg) output opc_src_a_din, // alu source a indicator (din) output opc_src_b_din, // alu source b indicator (din) output opc_dst_ar, // alu destination indicator (a reg) output opc_dst_xr, // alu destination indicator (x reg) output opc_dst_yr, // alu destination indicator (y reg) output opc_dst_sp, // alu destination indicator (sp reg) output opc_dst_ps, // alu destination indicator (ps reg) output opc_dst_dout, // alu destination indicator (dout) output mc_fetch_en, // opcode fetch enable output mc_din_le, // data input latch enable output mc_pc_chg, // change program counter value output mc_addr_pc, // output program counter value output mc_addr_zp, // output zero page address output mc_addr_abs, // output absolute address output mc_addr_sp, // output stack address output mc_addr_vl, // output interrupt vector(low) address output mc_addr_vh, // output interrupt vector(high) address output mc_dout_pch, // output pc value(high) to data bus output mc_dout_pcl, // output pc value(low) to data bus output mc_oe_next, // set output enable in next cycle output mc_alu_inst_op, // use alu for instruction operation output mc_alu_add_xr, // add x to input data output mc_alu_add_yr, // add y to input data output mc_alu_add_z, // add 0 to input data output mc_alu_inc_din, // increment input data output mc_alu_inc_reg, // increment saved data output mc_alu_inc_sp, // increment stack pointer value output mc_alu_dec_sp, // decrement stack pointer value output mc_brk_if_set, // interrupt i flag setting timing output mc_br_chk // branch condition check timing ); //---------------------------------------------------------------------- // internal regs and nets //---------------------------------------------------------------------- // number of decoded instructions parameter NUM_OF_INST = 56; // internal nets reg [12:0] src_dst; reg [15:0] mc_exec; //---------------------------------------------------------------------- // instruction bit position //---------------------------------------------------------------------- parameter I_ADC = 0; parameter I_AND = 1; parameter I_ASL = 2; parameter I_BCC = 3; parameter I_BCS = 4; parameter I_BEQ = 5; parameter I_BIT = 6; parameter I_BMI = 7; parameter I_BNE = 8; parameter I_BPL = 9; parameter I_BRK = 10; parameter I_BVC = 11; parameter I_BVS = 12; parameter I_CLC = 13; parameter I_CLD = 14; parameter I_CLI = 15; parameter I_CLV = 16; parameter I_CMP = 17; parameter I_CPX = 18; parameter I_CPY = 19; parameter I_DEC = 20; parameter I_DEX = 21; parameter I_DEY = 22; parameter I_EOR = 23; parameter I_INC = 24; parameter I_INX = 25; parameter I_INY = 26; parameter I_JMP = 27; parameter I_JSR = 28; parameter I_LDA = 29; parameter I_LDX = 30; parameter I_LDY = 31; parameter I_LSR = 32; parameter I_NOP = 33; parameter I_ORA = 34; parameter I_PHA = 35; parameter I_PHP = 36; parameter I_PLA = 37; parameter I_PLP = 38; parameter I_ROL = 39; parameter I_ROR = 40; parameter I_RTI = 41; parameter I_RTS = 42; parameter I_SBC = 43; parameter I_SEC = 44; parameter I_SED = 45; parameter I_SEI = 46; parameter I_STA = 47; parameter I_STX = 48; parameter I_STY = 49; parameter I_TAX = 50; parameter I_TAY = 51; parameter I_TSX = 52; parameter I_TXA = 53; parameter I_TXS = 54; parameter I_TYA = 55; //---------------------------------------------------------------------- // opcodes //---------------------------------------------------------------------- parameter ADC_IMM = 8'h69; parameter ADC_ZP = 8'h65; parameter ADC_ZX = 8'h75; parameter ADC_ABS = 8'h6D; parameter ADC_AX = 8'h7D; parameter ADC_AY = 8'h79; parameter ADC_IX = 8'h61; parameter ADC_IY = 8'h71; parameter AND_IMM = 8'h29; parameter AND_ZP = 8'h25; parameter AND_ZX = 8'h35; parameter AND_ABS = 8'h2D; parameter AND_AX = 8'h3D; parameter AND_AY = 8'h39; parameter AND_IX = 8'h21; parameter AND_IY = 8'h31; parameter ASL_ACC = 8'h0A; parameter ASL_ZP = 8'h06; parameter ASL_ZX = 8'h16; parameter ASL_ABS = 8'h0E; parameter ASL_AX = 8'h1E; parameter BCC = 8'h90; parameter BCS = 8'hB0; parameter BEQ = 8'hF0; parameter BIT_ZP = 8'h24; parameter BIT_ABS = 8'h2C; parameter BMI = 8'h30; parameter BNE = 8'hD0; parameter BPL = 8'h10; parameter BRK = 8'h00; parameter BVC = 8'h50; parameter BVS = 8'h70; parameter CLC = 8'h18; parameter CLD = 8'hD8; parameter CLI = 8'h58; parameter CLV = 8'hB8; parameter CMP_IMM = 8'hC9; parameter CMP_ZP = 8'hC5; parameter CMP_ZX = 8'hD5; parameter CMP_ABS = 8'hCD; parameter CMP_AX = 8'hDD; parameter CMP_AY = 8'hD9; parameter CMP_IX = 8'hC1; parameter CMP_IY = 8'hD1; parameter CPX_IMM = 8'hE0; parameter CPX_ZP = 8'hE4; parameter CPX_ABS = 8'hEC; parameter CPY_IMM = 8'hC0; parameter CPY_ZP = 8'hC4; parameter CPY_ABS = 8'hCC; parameter DEC_ZP = 8'hC6; parameter DEC_ZX = 8'hD6; parameter DEC_ABS = 8'hCE; parameter DEC_AX = 8'hDE; parameter DEX = 8'hCA; parameter DEY = 8'h88; parameter EOR_IMM = 8'h49; parameter EOR_ZP = 8'h45; parameter EOR_ZX = 8'h55; parameter EOR_ABS = 8'h4D; parameter EOR_AX = 8'h5D; parameter EOR_AY = 8'h59; parameter EOR_IX = 8'h41; parameter EOR_IY = 8'h51; parameter INC_ZP = 8'hE6; parameter INC_ZX = 8'hF6; parameter INC_ABS = 8'hEE; parameter INC_AX = 8'hFE; parameter INX = 8'hE8; parameter INY = 8'hC8; parameter JMP_ABS = 8'h4C; parameter JMP_IND = 8'h6C; parameter JSR_ABS = 8'h20; parameter LDA_IMM = 8'hA9; parameter LDA_ZP = 8'hA5; parameter LDA_ZX = 8'hB5; parameter LDA_ABS = 8'hAD; parameter LDA_AX = 8'hBD; parameter LDA_AY = 8'hB9; parameter LDA_IX = 8'hA1; parameter LDA_IY = 8'hB1; parameter LDX_IMM = 8'hA2; parameter LDX_ZP = 8'hA6; parameter LDX_ZY = 8'hB6; parameter LDX_ABS = 8'hAE; parameter LDX_AY = 8'hBE; parameter LDY_IMM = 8'hA0; parameter LDY_ZP = 8'hA4; parameter LDY_ZX = 8'hB4; parameter LDY_ABS = 8'hAC; parameter LDY_AX = 8'hBC; parameter LSR_ACC = 8'h4A; parameter LSR_ZP = 8'h46; parameter LSR_ZX = 8'h56; parameter LSR_ABS = 8'h4E; parameter LSR_AX = 8'h5E; parameter NOP = 8'hEA; parameter ORA_IMM = 8'h09; parameter ORA_ZP = 8'h05; parameter ORA_ZX = 8'h15; parameter ORA_ABS = 8'h0D; parameter ORA_AX = 8'h1D; parameter ORA_AY = 8'h19; parameter ORA_IX = 8'h01; parameter ORA_IY = 8'h11; parameter PHA = 8'h48; parameter PHP = 8'h08; parameter PLA = 8'h68; parameter PLP = 8'h28; parameter ROL_ACC = 8'h2A; parameter ROL_ZP = 8'h26; parameter ROL_ZX = 8'h36; parameter ROL_ABS = 8'h2E; parameter ROL_AX = 8'h3E; parameter ROR_ACC = 8'h6A; parameter ROR_ZP = 8'h66; parameter ROR_ZX = 8'h76; parameter ROR_ABS = 8'h6E; parameter ROR_AX = 8'h7E; parameter RTI = 8'h40; parameter RTS = 8'h60; parameter SBC_IMM = 8'hE9; parameter SBC_ZP = 8'hE5; parameter SBC_ZX = 8'hF5; parameter SBC_ABS = 8'hED; parameter SBC_AX = 8'hFD; parameter SBC_AY = 8'hF9; parameter SBC_IX = 8'hE1; parameter SBC_IY = 8'hF1; parameter SEC = 8'h38; parameter SED = 8'hF8; parameter SEI = 8'h78; parameter STA_ZP = 8'h85; parameter STA_ZX = 8'h95; parameter STA_ABS = 8'h8D; parameter STA_AX = 8'h9D; parameter STA_AY = 8'h99; parameter STA_IX = 8'h81; parameter STA_IY = 8'h91; parameter STX_ZP = 8'h86; parameter STX_ZY = 8'h96; parameter STX_ABS = 8'h8E; parameter STY_ZP = 8'h84; parameter STY_ZX = 8'h94; parameter STY_ABS = 8'h8C; parameter TAX = 8'hAA; parameter TAY = 8'hA8; parameter TSX = 8'hBA; parameter TXA = 8'h8A; parameter TXS = 8'h9A; parameter TYA = 8'h98; //---------------------------------------------------------------------- // opcode decode by instruction //---------------------------------------------------------------------- always @* begin opc_inst = {NUM_OF_INST{1'b0}}; case (opcode) ADC_IMM : opc_inst[I_ADC] = 1'b1; ADC_ZP : opc_inst[I_ADC] = 1'b1; ADC_ZX : opc_inst[I_ADC] = 1'b1; ADC_ABS : opc_inst[I_ADC] = 1'b1; ADC_AX : opc_inst[I_ADC] = 1'b1; ADC_AY : opc_inst[I_ADC] = 1'b1; ADC_IX : opc_inst[I_ADC] = 1'b1; ADC_IY : opc_inst[I_ADC] = 1'b1; AND_IMM : opc_inst[I_AND] = 1'b1; AND_ZP : opc_inst[I_AND] = 1'b1; AND_ZX : opc_inst[I_AND] = 1'b1; AND_ABS : opc_inst[I_AND] = 1'b1; AND_AX : opc_inst[I_AND] = 1'b1; AND_AY : opc_inst[I_AND] = 1'b1; AND_IX : opc_inst[I_AND] = 1'b1; AND_IY : opc_inst[I_AND] = 1'b1; ASL_ACC : opc_inst[I_ASL] = 1'b1; ASL_ZP : opc_inst[I_ASL] = 1'b1; ASL_ZX : opc_inst[I_ASL] = 1'b1; ASL_ABS : opc_inst[I_ASL] = 1'b1; ASL_AX : opc_inst[I_ASL] = 1'b1; BCC : opc_inst[I_BCC] = 1'b1; BCS : opc_inst[I_BCS] = 1'b1; BEQ : opc_inst[I_BEQ] = 1'b1; BIT_ZP : opc_inst[I_BIT] = 1'b1; BIT_ABS : opc_inst[I_BIT] = 1'b1; BMI : opc_inst[I_BMI] = 1'b1; BNE : opc_inst[I_BNE] = 1'b1; BPL : opc_inst[I_BPL] = 1'b1; BRK : opc_inst[I_BRK] = 1'b1; BVC : opc_inst[I_BVC] = 1'b1; BVS : opc_inst[I_BVS] = 1'b1; CLC : opc_inst[I_CLC] = 1'b1; CLD : opc_inst[I_CLD] = 1'b1; CLI : opc_inst[I_CLI] = 1'b1; CLV : opc_inst[I_CLV] = 1'b1; CMP_IMM : opc_inst[I_CMP] = 1'b1; CMP_ZP : opc_inst[I_CMP] = 1'b1; CMP_ZX : opc_inst[I_CMP] = 1'b1; CMP_ABS : opc_inst[I_CMP] = 1'b1; CMP_AX : opc_inst[I_CMP] = 1'b1; CMP_AY : opc_inst[I_CMP] = 1'b1; CMP_IX : opc_inst[I_CMP] = 1'b1; CMP_IY : opc_inst[I_CMP] = 1'b1; CPX_IMM : opc_inst[I_CPX] = 1'b1; CPX_ZP : opc_inst[I_CPX] = 1'b1; CPX_ABS : opc_inst[I_CPX] = 1'b1; CPY_IMM : opc_inst[I_CPY] = 1'b1; CPY_ZP : opc_inst[I_CPY] = 1'b1; CPY_ABS : opc_inst[I_CPY] = 1'b1; DEC_ZP : opc_inst[I_DEC] = 1'b1; DEC_ZX : opc_inst[I_DEC] = 1'b1; DEC_ABS : opc_inst[I_DEC] = 1'b1; DEC_AX : opc_inst[I_DEC] = 1'b1; DEX : opc_inst[I_DEX] = 1'b1; DEY : opc_inst[I_DEY] = 1'b1; EOR_IMM : opc_inst[I_EOR] = 1'b1; EOR_ZP : opc_inst[I_EOR] = 1'b1; EOR_ZX : opc_inst[I_EOR] = 1'b1; EOR_ABS : opc_inst[I_EOR] = 1'b1; EOR_AX : opc_inst[I_EOR] = 1'b1; EOR_AY : opc_inst[I_EOR] = 1'b1; EOR_IX : opc_inst[I_EOR] = 1'b1; EOR_IY : opc_inst[I_EOR] = 1'b1; INC_ZP : opc_inst[I_INC] = 1'b1; INC_ZX : opc_inst[I_INC] = 1'b1; INC_ABS : opc_inst[I_INC] = 1'b1; INC_AX : opc_inst[I_INC] = 1'b1; INX : opc_inst[I_INX] = 1'b1; INY : opc_inst[I_INY] = 1'b1; JMP_ABS : opc_inst[I_JMP] = 1'b1; JMP_IND : opc_inst[I_JMP] = 1'b1; JSR_ABS : opc_inst[I_JSR] = 1'b1; LDA_IMM : opc_inst[I_LDA] = 1'b1; LDA_ZP : opc_inst[I_LDA] = 1'b1; LDA_ZX : opc_inst[I_LDA] = 1'b1; LDA_ABS : opc_inst[I_LDA] = 1'b1; LDA_AX : opc_inst[I_LDA] = 1'b1; LDA_AY : opc_inst[I_LDA] = 1'b1; LDA_IX : opc_inst[I_LDA] = 1'b1; LDA_IY : opc_inst[I_LDA] = 1'b1; LDX_IMM : opc_inst[I_LDX] = 1'b1; LDX_ZP : opc_inst[I_LDX] = 1'b1; LDX_ZY : opc_inst[I_LDX] = 1'b1; LDX_ABS : opc_inst[I_LDX] = 1'b1; LDX_AY : opc_inst[I_LDX] = 1'b1; LDY_IMM : opc_inst[I_LDY] = 1'b1; LDY_ZP : opc_inst[I_LDY] = 1'b1; LDY_ZX : opc_inst[I_LDY] = 1'b1; LDY_ABS : opc_inst[I_LDY] = 1'b1; LDY_AX : opc_inst[I_LDY] = 1'b1; LSR_ACC : opc_inst[I_LSR] = 1'b1; LSR_ZP : opc_inst[I_LSR] = 1'b1; LSR_ZX : opc_inst[I_LSR] = 1'b1; LSR_ABS : opc_inst[I_LSR] = 1'b1; LSR_AX : opc_inst[I_LSR] = 1'b1; NOP : opc_inst[I_NOP] = 1'b1; ORA_IMM : opc_inst[I_ORA] = 1'b1; ORA_ZP : opc_inst[I_ORA] = 1'b1; ORA_ZX : opc_inst[I_ORA] = 1'b1; ORA_ABS : opc_inst[I_ORA] = 1'b1; ORA_AX : opc_inst[I_ORA] = 1'b1; ORA_AY : opc_inst[I_ORA] = 1'b1; ORA_IX : opc_inst[I_ORA] = 1'b1; ORA_IY : opc_inst[I_ORA] = 1'b1; PHA : opc_inst[I_PHA] = 1'b1; PHP : opc_inst[I_PHP] = 1'b1; PLA : opc_inst[I_PLA] = 1'b1; PLP : opc_inst[I_PLP] = 1'b1; ROL_ACC : opc_inst[I_ROL] = 1'b1; ROL_ZP : opc_inst[I_ROL] = 1'b1; ROL_ZX : opc_inst[I_ROL] = 1'b1; ROL_ABS : opc_inst[I_ROL] = 1'b1; ROL_AX : opc_inst[I_ROL] = 1'b1; ROR_ACC : opc_inst[I_ROR] = 1'b1; ROR_ZP : opc_inst[I_ROR] = 1'b1; ROR_ZX : opc_inst[I_ROR] = 1'b1; ROR_ABS : opc_inst[I_ROR] = 1'b1; ROR_AX : opc_inst[I_ROR] = 1'b1; RTI : opc_inst[I_RTI] = 1'b1; RTS : opc_inst[I_RTS] = 1'b1; SBC_IMM : opc_inst[I_SBC] = 1'b1; SBC_ZP : opc_inst[I_SBC] = 1'b1; SBC_ZX : opc_inst[I_SBC] = 1'b1; SBC_ABS : opc_inst[I_SBC] = 1'b1; SBC_AX : opc_inst[I_SBC] = 1'b1; SBC_AY : opc_inst[I_SBC] = 1'b1; SBC_IX : opc_inst[I_SBC] = 1'b1; SBC_IY : opc_inst[I_SBC] = 1'b1; SEC : opc_inst[I_SEC] = 1'b1; SED : opc_inst[I_SED] = 1'b1; SEI : opc_inst[I_SEI] = 1'b1; STA_ZP : opc_inst[I_STA] = 1'b1; STA_ZX : opc_inst[I_STA] = 1'b1; STA_ABS : opc_inst[I_STA] = 1'b1; STA_AX : opc_inst[I_STA] = 1'b1; STA_AY : opc_inst[I_STA] = 1'b1; STA_IX : opc_inst[I_STA] = 1'b1; STA_IY : opc_inst[I_STA] = 1'b1; STX_ZP : opc_inst[I_STX] = 1'b1; STX_ZY : opc_inst[I_STX] = 1'b1; STX_ABS : opc_inst[I_STX] = 1'b1; STY_ZP : opc_inst[I_STY] = 1'b1; STY_ZX : opc_inst[I_STY] = 1'b1; STY_ABS : opc_inst[I_STY] = 1'b1; TAX : opc_inst[I_TAX] = 1'b1; TAY : opc_inst[I_TAY] = 1'b1; TSX : opc_inst[I_TSX] = 1'b1; TXA : opc_inst[I_TXA] = 1'b1; TXS : opc_inst[I_TXS] = 1'b1; TYA : opc_inst[I_TYA] = 1'b1; endcase end //---------------------------------------------------------------------- // alu source/dest and modified flag decoder //---------------------------------------------------------------------- // alu source/dest indicator assignments assign opc_src_a_ar = src_dst[12]; // alu source a indicator (a reg) assign opc_src_a_xr = src_dst[11]; // alu source a indicator (x reg) assign opc_src_a_yr = src_dst[10]; // alu source a indicator (y reg) assign opc_src_a_sp = src_dst[ 9]; // alu source a indicator (sp reg) assign opc_src_a_ps = src_dst[ 8]; // alu source a indicator (ps reg) assign opc_src_a_din = src_dst[ 7]; // alu source a indicator (din) assign opc_src_b_din = src_dst[ 6]; // alu source b indicator (din) assign opc_dst_ar = src_dst[ 5]; // alu destination indicator (a reg) assign opc_dst_xr = src_dst[ 4]; // alu destination indicator (x reg) assign opc_dst_yr = src_dst[ 3]; // alu destination indicator (y reg) assign opc_dst_sp = src_dst[ 2]; // alu destination indicator (sp reg) assign opc_dst_ps = src_dst[ 1]; // alu destination indicator (ps reg) assign opc_dst_dout = src_dst[ 0]; // alu destination indicator (dout) // alu source/dest and modified flag decoder always @* begin case (opcode) // AXYSPD D AXYSPD NV-B DIZC ADC_IMM : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_ZP : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_ZX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_ABS : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_AX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_AY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_IX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_IY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; // AXYSPD D AXYSPD NV-B DIZC AND_IMM : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_ZP : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_ZX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_ABS : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_AX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_AY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_IX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_IY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC ASL_ACC : {src_dst, opc_flag} = {13'b 100000_0_100000, 8'b 1000_0011}; ASL_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ASL_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ASL_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ASL_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC BCC : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BCS : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BEQ : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BMI : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BNE : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BPL : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BVC : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BVS : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC BIT_ZP : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1100_0010}; BIT_ABS : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1100_0010}; // AXYSPD D AXYSPD NV-B DIZC BRK : {src_dst, opc_flag} = {13'b 000010_0_000001, 8'b 0001_0100}; // AXYSPD D AXYSPD NV-B DIZC CLC : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0001}; CLD : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_1000}; CLI : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0100}; CLV : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0100_0000}; // AXYSPD D AXYSPD NV-B DIZC CMP_IMM : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_ZP : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_ZX : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_ABS : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_AX : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_AY : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_IX : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_IY : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC CPX_IMM : {src_dst, opc_flag} = {13'b 010000_1_000000, 8'b 1000_0011}; CPX_ZP : {src_dst, opc_flag} = {13'b 010000_1_000000, 8'b 1000_0011}; CPX_ABS : {src_dst, opc_flag} = {13'b 010000_1_000000, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC CPY_IMM : {src_dst, opc_flag} = {13'b 001000_1_000000, 8'b 1000_0011}; CPY_ZP : {src_dst, opc_flag} = {13'b 001000_1_000000, 8'b 1000_0011}; CPY_ABS : {src_dst, opc_flag} = {13'b 001000_1_000000, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC DEC_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; DEC_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; DEC_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; DEC_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC DEX : {src_dst, opc_flag} = {13'b 010000_0_010000, 8'b 1000_0010}; DEY : {src_dst, opc_flag} = {13'b 001000_0_001000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC EOR_IMM : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_ZP : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_ZX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_ABS : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_AX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_AY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_IX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_IY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC INC_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; INC_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; INC_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; INC_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC INX : {src_dst, opc_flag} = {13'b 010000_0_010000, 8'b 1000_0010}; INY : {src_dst, opc_flag} = {13'b 001000_0_001000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC JMP_ABS : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; JMP_IND : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC JSR_ABS : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC LDA_IMM : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_ZP : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_ZX : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_ABS : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_AX : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_AY : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_IX : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_IY : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC LDX_IMM : {src_dst, opc_flag} = {13'b 000000_1_010000, 8'b 1000_0010}; LDX_ZP : {src_dst, opc_flag} = {13'b 000000_1_010000, 8'b 1000_0010}; LDX_ZY : {src_dst, opc_flag} = {13'b 000000_1_010000, 8'b 1000_0010}; LDX_ABS : {src_dst, opc_flag} = {13'b 000000_1_010000, 8'b 1000_0010}; LDX_AY : {src_dst, opc_flag} = {13'b 000000_1_010000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC LDY_IMM : {src_dst, opc_flag} = {13'b 000000_1_001000, 8'b 1000_0010}; LDY_ZP : {src_dst, opc_flag} = {13'b 000000_1_001000, 8'b 1000_0010}; LDY_ZX : {src_dst, opc_flag} = {13'b 000000_1_001000, 8'b 1000_0010}; LDY_ABS : {src_dst, opc_flag} = {13'b 000000_1_001000, 8'b 1000_0010}; LDY_AX : {src_dst, opc_flag} = {13'b 000000_1_001000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC LSR_ACC : {src_dst, opc_flag} = {13'b 100000_0_100000, 8'b 1000_0011}; LSR_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; LSR_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; LSR_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; LSR_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC NOP : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC ORA_IMM : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_ZP : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_ZX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_ABS : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_AX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_AY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_IX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_IY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC PHA : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; PHP : {src_dst, opc_flag} = {13'b 000010_0_000001, 8'b 0000_0000}; PLA : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; PLP : {src_dst, opc_flag} = {13'b 000000_1_000010, 8'b 1111_1111}; // AXYSPD D AXYSPD NV-B DIZC ROL_ACC : {src_dst, opc_flag} = {13'b 100000_0_100000, 8'b 1000_0011}; ROL_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROL_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROL_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROL_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC ROR_ACC : {src_dst, opc_flag} = {13'b 100000_0_100000, 8'b 1000_0011}; ROR_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROR_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROR_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROR_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC RTI : {src_dst, opc_flag} = {13'b 000000_1_000010, 8'b 1111_1111}; // AXYSPD D AXYSPD NV-B DIZC RTS : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC SBC_IMM : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_ZP : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_ZX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_ABS : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_AX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_AY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_IX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_IY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; // AXYSPD D AXYSPD NV-B DIZC SEC : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0001}; SED : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_1000}; SEI : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0100}; // AXYSPD D AXYSPD NV-B DIZC STA_ZP : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_ZX : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_ABS : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_AX : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_AY : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_IX : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_IY : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC STX_ZP : {src_dst, opc_flag} = {13'b 010000_0_000001, 8'b 0000_0000}; STX_ZY : {src_dst, opc_flag} = {13'b 010000_0_000001, 8'b 0000_0000}; STX_ABS : {src_dst, opc_flag} = {13'b 010000_0_000001, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC STY_ZP : {src_dst, opc_flag} = {13'b 001000_0_000001, 8'b 0000_0000}; STY_ZX : {src_dst, opc_flag} = {13'b 001000_0_000001, 8'b 0000_0000}; STY_ABS : {src_dst, opc_flag} = {13'b 001000_0_000001, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC TAX : {src_dst, opc_flag} = {13'b 100000_0_010000, 8'b 1000_0010}; TAY : {src_dst, opc_flag} = {13'b 100000_0_001000, 8'b 1000_0010}; TSX : {src_dst, opc_flag} = {13'b 000100_0_010000, 8'b 1000_0010}; TXA : {src_dst, opc_flag} = {13'b 010000_0_100000, 8'b 1000_0010}; TXS : {src_dst, opc_flag} = {13'b 010000_0_000100, 8'b 0000_0000}; TYA : {src_dst, opc_flag} = {13'b 001000_0_100000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC default : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; endcase end //---------------------------------------------------------------------- // execution timing decoder //---------------------------------------------------------------------- // microcode assignments assign mc_fetch_en = mc_exec[15]; // opcode fetch enable assign mc_din_le = mc_exec[14]; // data input latch enable assign mc_pc_chg = mc_exec[13]; // change program counter value assign mc_addr_pc = mc_exec[12]; // output program counter value assign mc_addr_zp = mc_exec[11]; // output zero page address assign mc_addr_abs = mc_exec[10]; // output absolute address assign mc_addr_sp = mc_exec[ 9]; // output stack address assign mc_oe_next = mc_exec[ 8]; // set output enable in next cycle assign mc_alu_inst_op = mc_exec[ 7]; // use alu for instruction operation assign mc_alu_add_xr = mc_exec[ 6]; // add x to input data assign mc_alu_add_yr = mc_exec[ 5]; // add y to input data assign mc_alu_add_z = mc_exec[ 4]; // add 0 to input data assign mc_alu_inc_din = mc_exec[ 3]; // increment input data assign mc_alu_inc_reg = mc_exec[ 2]; // increment saved data assign mc_alu_inc_sp = mc_exec[ 1]; // increment stack pointer value assign mc_alu_dec_sp = mc_exec[ 0]; // decrement stack pointer value // execution timing decoder always @* begin mc_exec = {16{1'b0}}; case (opcode) //-------------------------------------------------- // accumulator //-------------------------------------------------- ASL_ACC, LSR_ACC, ROL_ACC, ROR_ACC: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0000; // PC+1 -- R - - 3'd1: mc_exec = 16'b 101_1000_0_1000_0000; // PC+1 OP R a 0 endcase //-------------------------------------------------- // immediate //-------------------------------------------------- AND_IMM, ORA_IMM, EOR_IMM, ADC_IMM, SBC_IMM, CMP_IMM, CPX_IMM, CPY_IMM, LDA_IMM, LDX_IMM, LDY_IMM: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 DATA R - - 3'd1: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R a d endcase //-------------------------------------------------- // zero page //-------------------------------------------------- AND_ZP, ORA_ZP, EOR_ZP, ADC_ZP, SBC_ZP, CMP_ZP, CPX_ZP, CPY_ZP, LDA_ZP, LDX_ZP, LDY_ZP, BIT_ZP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0100_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 011_1000_0_0000_0000; // ZA DATA R - - 3'd2: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R a d endcase STA_ZP, STX_ZP, STY_ZP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0100_1_1000_0000; // PC+1 ZA R a 0 3'd1: mc_exec = 16'b 001_1000_0_0000_0000; // ZA DATA W - - 3'd2: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase ASL_ZP, LSR_ZP, ROL_ZP, ROR_ZP, INC_ZP, DEC_ZP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0100_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 010_0000_0_0000_0000; // ZA DATA R - - 3'd2: mc_exec = 16'b 000_0000_1_1000_0000; // ZA -- R d 0 3'd3: mc_exec = 16'b 001_1000_0_0000_0000; // ZA DATA W - - 3'd4: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase //-------------------------------------------------- // zero page, x //-------------------------------------------------- AND_ZX, ORA_ZX, EOR_ZX, ADC_ZX, SBC_ZX, CMP_ZX, LDA_ZX, LDY_ZX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 000_0100_0_0100_0000; // PC+1 -- R x d 3'd2: mc_exec = 16'b 011_1000_0_0000_0000; // ZA+X DATA R - - 3'd3: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R a d endcase STA_ZX, STY_ZX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_1000_0000; // PC+1 ZA R a 0 3'd1: mc_exec = 16'b 000_0100_1_0100_0000; // PC+1 -- R x d 3'd2: mc_exec = 16'b 001_1000_0_0000_0000; // ZA+X DATA W - - 3'd3: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase ASL_ZX, LSR_ZX, ROL_ZX, ROR_ZX, INC_ZX, DEC_ZX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 000_0100_0_0100_0000; // PC+1 -- R x d 3'd2: mc_exec = 16'b 010_0000_0_0000_0000; // ZA+X DATA R - - 3'd3: mc_exec = 16'b 000_0000_1_1000_0000; // ZA+X -- R d 0 3'd4: mc_exec = 16'b 001_1000_0_0000_0000; // ZA+X DATA W - - 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase //-------------------------------------------------- // zero page, y //-------------------------------------------------- LDX_ZY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 000_0100_0_0010_0000; // PC+1 -- R y d 3'd2: mc_exec = 16'b 011_1000_0_0000_0000; // ZA+Y DATA R - - 3'd3: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R 0 d endcase STX_ZY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_1000_0000; // PC+1 ZA R x 0 3'd1: mc_exec = 16'b 000_0100_1_0010_0000; // PC+1 -- R y d 3'd2: mc_exec = 16'b 001_1000_0_0000_0000; // ZA+Y DATA W - - 3'd3: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase //-------------------------------------------------- // absolute //-------------------------------------------------- AND_ABS, ORA_ABS, EOR_ABS, ADC_ABS, SBC_ABS, CMP_ABS, CPX_ABS, CPY_ABS, LDA_ABS, LDX_ABS, LDY_ABS, BIT_ABS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0001_0000; // PC+2 AH R 0 d 3'd2: mc_exec = 16'b 011_1000_0_0000_0000; // A DATA R - - 3'd3: mc_exec = 16'b 101_1000_0_1000_0000; // PC+3 OP R a d endcase STA_ABS, STX_ABS, STY_ABS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_1000_0000; // PC+1 AL R a 0 3'd1: mc_exec = 16'b 010_0010_1_0001_0000; // PC+2 AH R 0 d 3'd2: mc_exec = 16'b 001_1000_0_0000_0000; // A DATA W - - 3'd3: mc_exec = 16'b 101_1000_0_0000_0000; // PC+3 OP R - - endcase ASL_ABS, LSR_ABS, ROL_ABS, ROR_ABS, INC_ABS, DEC_ABS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0001_0000; // PC+2 AH R 0 d 3'd2: mc_exec = 16'b 010_0000_0_0000_0000; // A DATA R - - 3'd3: mc_exec = 16'b 000_0000_1_1000_0000; // A -- R d 0 3'd4: mc_exec = 16'b 001_1000_0_0000_0000; // A DATA W - - 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // PC+3 OP R - - endcase JMP_ABS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 newPCL R - - 3'd1: mc_exec = 16'b 011_0010_0_0001_0000; // PC+2 newPCH R 0 d 3'd2: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - endcase JSR_ABS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 newPCL R - - 3'd1: mc_exec = 16'b 000_0001_1_0000_0001; // PC+1 -- R s 0 3'd2: mc_exec = 16'b 000_0001_1_0000_0001; // S PCH W s 0 3'd3: mc_exec = 16'b 001_1000_0_0000_0000; // S-1 PCL+2 W - - 3'd4: mc_exec = 16'b 011_0010_0_0001_0000; // PC+2 newPCH R 0 d 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - endcase //-------------------------------------------------- // absolute, x //-------------------------------------------------- AND_AX, ORA_AX, EOR_AX, ADC_AX, SBC_AX, CMP_AX, LDA_AX, LDY_AX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0100_0000; // PC+2 AH R x d 3'd2: mc_exec = 16'b 011_1000_0_0000_0000; // A+X DATA R - - 3'd3: mc_exec = 16'b 101_1000_0_1000_0000; // PC+3 OP R a d endcase STA_AX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_1000_0000; // PC+1 AL R a 0 3'd1: mc_exec = 16'b 010_0010_1_0100_0000; // PC+2 AH R x d 3'd2: mc_exec = 16'b 001_1000_0_0000_0000; // A+X DATA W - - 3'd3: mc_exec = 16'b 101_1000_0_0000_0000; // PC+3 OP R - - endcase ASL_AX, LSR_AX, ROL_AX, ROR_AX, INC_AX, DEC_AX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0100_0000; // PC+2 AH R x d 3'd2: mc_exec = 16'b 010_0000_0_0000_0000; // A+X DATA R - - 3'd3: mc_exec = 16'b 000_0000_1_1000_0000; // A+X -- R d 0 3'd4: mc_exec = 16'b 001_1000_0_0000_0000; // A+X DATA W - - 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // PC+3 OP R - - endcase //-------------------------------------------------- // absolute, y //-------------------------------------------------- AND_AY, ORA_AY, EOR_AY, ADC_AY, SBC_AY, CMP_AY, LDA_AY, LDX_AY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0010_0000; // PC+2 AH R y d 3'd2: mc_exec = 16'b 011_1000_0_0000_0000; // A+Y DATA R - - 3'd3: mc_exec = 16'b 101_1000_0_1000_0000; // PC+3 OP R a d endcase STA_AY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_1000_0000; // PC+1 AL R a 0 3'd1: mc_exec = 16'b 010_0010_1_0010_0000; // PC+2 AH R y d 3'd2: mc_exec = 16'b 001_1000_0_0000_0000; // A+Y DATA W - - 3'd3: mc_exec = 16'b 101_1000_0_0000_0000; // PC+3 OP R - - endcase //-------------------------------------------------- // indirect, x //-------------------------------------------------- AND_IX, ORA_IX, EOR_IX, ADC_IX, SBC_IX, CMP_IX, LDA_IX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 000_0100_0_0100_0000; // PC+1 -- R x d 3'd2: mc_exec = 16'b 010_0100_0_0000_0100; // ZA+X AL R r 0 3'd3: mc_exec = 16'b 010_0010_0_0001_0000; // ZA+X+1 AH R 0 d 3'd4: mc_exec = 16'b 011_1000_0_0000_0000; // A DATA R - - 3'd5: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R a d endcase STA_IX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_1000_0000; // PC+1 ZA R a 0 3'd1: mc_exec = 16'b 000_0100_0_0100_0000; // PC+1 -- R x d 3'd2: mc_exec = 16'b 010_0100_0_0000_0100; // ZA+X AL R r 0 3'd3: mc_exec = 16'b 010_0010_1_0001_0000; // ZA+X+1 AH R 0 d 3'd4: mc_exec = 16'b 001_1000_0_0000_0000; // A DATA W - - 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase //-------------------------------------------------- // indirect, y //-------------------------------------------------- AND_IY, ORA_IY, EOR_IY, ADC_IY, SBC_IY, CMP_IY, LDA_IY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0100_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 010_0100_0_0000_1000; // ZA AL R d 0 3'd2: mc_exec = 16'b 010_0010_0_0010_0000; // ZA+1 AH R y d 3'd3: mc_exec = 16'b 011_1000_0_0000_0000; // A+Y DATA R - - 3'd4: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R a d endcase STA_IY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0100_0_1000_0000; // PC+1 ZA R a 0 3'd1: mc_exec = 16'b 010_0100_0_0000_1000; // ZA AL R d 0 3'd2: mc_exec = 16'b 010_0010_1_0010_0000; // ZA+1 AH R y d 3'd3: mc_exec = 16'b 001_1000_0_0000_0000; // A+Y DATA W - - 3'd4: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase //-------------------------------------------------- // indirect //-------------------------------------------------- JMP_IND: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0001_0000; // PC+2 AH R 0 d 3'd2: mc_exec = 16'b 010_0010_0_0000_0100; // A newPCL R r 0 3'd3: mc_exec = 16'b 011_0010_0_0001_0000; // A+1 newPCH R 0 d 3'd4: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - endcase //-------------------------------------------------- // implied //-------------------------------------------------- TAX, TXA, TAY, TYA, TSX, TXS, INX, INY, DEX, DEY, CLC, CLD, CLI, CLV, SEC, SED, SEI, NOP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0000; // PC+1 -- R - - 3'd1: mc_exec = 16'b 101_1000_0_1000_0000; // PC+1 OP R a 0 endcase PHA, PHP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0001_1_1000_0000; // PC+1 -- R a 0 3'd1: mc_exec = 16'b 000_1000_0_0000_0001; // S REG W s 0 3'd2: mc_exec = 16'b 101_1000_0_0000_0000; // PC+1 OP R - - endcase PLA, PLP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0010; // PC+1 -- R s 0 3'd1: mc_exec = 16'b 000_0001_0_0000_0000; // PC+1 -- R - - 3'd2: mc_exec = 16'b 010_1000_0_0000_0000; // S+1 REG R - - 3'd3: mc_exec = 16'b 101_1000_0_1001_0000; // PC+1 OP R 0 d endcase RTI: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0010; // PC+1 -- R s 0 3'd1: mc_exec = 16'b 000_0001_0_0000_0010; // PC+1 -- R s 0 3'd2: mc_exec = 16'b 010_0001_0_0000_0010; // S+1 P R s 0 3'd3: mc_exec = 16'b 010_0001_0_1001_0000; // S+2 newPCL R 0 d 3'd4: mc_exec = 16'b 011_0010_0_0001_0000; // S+3 newPCH R 0 d 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - endcase RTS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0010; // PC+1 -- R s 0 3'd1: mc_exec = 16'b 000_0001_0_0000_0010; // PC+1 -- R s 0 3'd2: mc_exec = 16'b 010_0001_0_0000_0000; // S+1 newPCL R - - 3'd3: mc_exec = 16'b 011_0010_0_0001_0000; // S+2 newPCH R 0 d 3'd4: mc_exec = 16'b 001_1000_0_0000_0000; // newPC -- R - - 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // newPC+1 OP R - - endcase BRK: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0001_1_0000_0001; // PC+1 -- R s 0 3'd1: mc_exec = 16'b 000_0001_1_0000_0001; // S PCH W s 0 3'd2: mc_exec = 16'b 000_0001_1_1000_0000; // S-1 PCL+2 W p 0 3'd3: mc_exec = 16'b 000_0000_0_0000_0001; // S-2 P W s 0 3'd4: mc_exec = 16'b 010_0000_0_0000_0000; // VA newPCL R - - 3'd5: mc_exec = 16'b 011_0010_0_0001_0000; // VA+1 newPCH R 0 d 3'd6: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - endcase // // nmi/irq cycle // case (cyc_cnt) // // // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // // EIC CPBP E PDDD NNNE // a b // // TNC S XYZ DRSS // PC OP R // 3'd0: mc_exec = 16'b 000_0001_1_0000_0001; // PC -- R s 0 // 3'd1: mc_exec = 16'b 000_0001_1_0000_0001; // S PCH W s 0 // 3'd2: mc_exec = 16'b 000_0001_1_1000_0000; // S-1 PCL W p 0 // 3'd3: mc_exec = 16'b 000_0000_0_0000_0001; // S-2 P W s 0 // 3'd4: mc_exec = 16'b 010_0000_0_0000_0000; // VA newPCL R - - // 3'd5: mc_exec = 16'b 011_0010_0_0001_0000; // VA+1 newPCH R 0 d // 3'd6: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - // endcase // // reset cycle // case (cyc_cnt) // // // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // // EIC CPBP E PDDD NNNE // a b // // TNC S XYZ DRSS // PC OP R // 3'd0: mc_exec = 16'b 000_0001_0_0000_0001; // PC -- R s 0 // 3'd1: mc_exec = 16'b 000_0001_0_0000_0001; // S -- R s 0 // 3'd2: mc_exec = 16'b 000_0001_0_1000_0000; // S-1 -- R p 0 // 3'd3: mc_exec = 16'b 000_0000_0_0000_0001; // S-2 -- R s 0 // 3'd4: mc_exec = 16'b 010_0000_0_0000_0000; // VA newPCL R - - // 3'd5: mc_exec = 16'b 011_0010_0_0001_0000; // VA+1 newPCH R 0 d // 3'd6: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - // endcase //-------------------------------------------------- // relative //-------------------------------------------------- BEQ, BNE, BCS, BCC, BVS, BVC, BMI, BPL: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 OFS R - - 3'd1: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R pcl d endcase //-------------------------------------------------- // undefined opcode (same as nop) //-------------------------------------------------- default: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0000; // PC+1 -- R - - 3'd1: mc_exec = 16'b 101_1000_0_0000_0000; // PC+1 OP R - - endcase endcase end //---------------------------------------------------------------------- // other microcodes //---------------------------------------------------------------------- // BRK: // case (cyc_cnt) // // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // // EIC CPBP E PDDD NNNE // a b // // TNC S XYZ DRSS // PC OP R // 3'd0: mc_exec = 16'b 000_0001_1_0000_0001; // PC+1 -- R s 0 // 3'd1: mc_exec = 16'b 000_0001_1_0000_0001; // S PCH W s 0 // 3'd2: mc_exec = 16'b 000_0001_1_1000_0000; // S-1 PCL+2 W p 0 // 3'd3: mc_exec = 16'b 000_0000_0_0000_0001; // S-2 P W s 0 // 3'd4: mc_exec = 16'b 010_0000_0_0000_0000; // VA newPCL R - - // 3'd5: mc_exec = 16'b 011_0010_0_0001_0000; // VA+1 newPCH R 0 d // 3'd6: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - // endcase // JSR_ABS: // case (cyc_cnt) // // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // // EIC CPBP E PDDD NNNE // a b // // TNC S XYZ DRSS // PC OP R // 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 newPCL R - - // 3'd1: mc_exec = 16'b 000_0001_1_0000_0001; // PC+1 -- R s 0 // 3'd2: mc_exec = 16'b 000_0001_1_0000_0001; // S PCH W s 0 // 3'd3: mc_exec = 16'b 001_1000_0_0000_0000; // S-1 PCL+2 W - - // 3'd4: mc_exec = 16'b 011_0010_0_0001_0000; // PC+2 newPCH R 0 d // 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - // endcase // interrupt vector address timing assign mc_addr_vl = (opcode == BRK ) & (cyc_cnt == 3'd3); assign mc_addr_vh = (opcode == BRK ) & (cyc_cnt == 3'd4); // pc value(high/low) data output timing assign mc_dout_pch = (opcode == BRK ) & (cyc_cnt == 3'd0) \| (opcode == JSR_ABS) & (cyc_cnt == 3'd1); assign mc_dout_pcl = (opcode == BRK ) & (cyc_cnt == 3'd1) \| (opcode == JSR_ABS) & (cyc_cnt == 3'd2); // interrupt i flag setting timing assign mc_brk_if_set = (opcode == BRK ) & (cyc_cnt == 3'd2); // BEQ, // BNE, // BCS, // BCC, // BVS, // BVC, // BMI, // BPL: // case (cyc_cnt) // // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // // EIC CPBP E PDDD NNNE // a b // // TNC S XYZ DRSS // PC OP R // 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 OFS R - - // 3'd1: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - // endcase // branch condition check timing assign mc_br_chk = (opcode == BEQ) & (cyc_cnt == 3'd1) \| (opcode == BNE) & (cyc_cnt == 3'd1) \| (opcode == BCS) & (cyc_cnt == 3'd1) \| (opcode == BCC) & (cyc_cnt == 3'd1) \| (opcode == BVS) & (cyc_cnt == 3'd1) \| (opcode == BVC) & (cyc_cnt == 3'd1) \| (opcode == BMI) & (cyc_cnt == 3'd1) \| (opcode == BPL) & (cyc_cnt == 3'd1); endmodule
// DESCRIPTION: Verilator: Verilog Test module // // This file ONLY is placed into the Public Domain, for any use, // without warranty, 2003-2007 by Wilson Snyder. module t (/AUTOARG/ // Inputs clk ); input clk; integer cyc; initial cyc=1; // verilator lint_on GENCLK reg [31:0] long; reg [63:0] quad; wire [31:0] longout; wire [63:0] quadout; wire [7:0] narrow = long[7:0]; sub sub (/AUTOINST/ // Outputs .longout (longout[31:0]), .quadout (quadout[63:0]), // Inputs .narrow (narrow[7:0]), .quad (quad[63:0])); always @ (posedge clk) begin if (cyc!=0) begin cyc <= cyc + 1; if (cyc==1) begin long <= 32'h12345678; quad <= 64'h12345678_abcdef12; end if (cyc==2) begin if (longout !== 32'h79) $stop; if (quadout !== 64'h12345678_abcdef13) $stop; $write("- All Finished -\n"); $finish; end end end endmodule module sub (input [7:0] narrow, input [63:0] quad, output [31:0] longout, output [63:0] quadout); // verilator public_module `ifdef verilator wire [31:0] longout = $c32("(",narrow,"+1)"); wire [63:0] quadout = $c64("(",quad,"+1)"); `else wire [31:0] longout = narrow + 8'd1; wire [63:0] quadout = quad + 64'd1; `endif endmodule
//Legal Notice: (C)2016 Altera Corporation. All rights reserved. Your //use of Altera Corporation's design tools, logic functions and other //software and tools, and its AMPP partner logic functions, and any //output files any of the foregoing (including device programming or //simulation files), and any associated documentation or information are //expressly subject to the terms and conditions of the Altera Program //License Subscription Agreement or other applicable license agreement, //including, without limitation, that your use is for the sole purpose //of programming logic devices manufactured by Altera and sold by Altera //or its authorized distributors. Please refer to the applicable //agreement for further details. // synthesis translate_off `timescale 1ns / 1ps // synthesis translate_on // turn off superfluous verilog processor warnings // altera message_level Level1 // altera message_off 10034 10035 10036 10037 10230 10240 10030 module niosii_pio_0 ( // inputs: address, chipselect, clk, reset_n, write_n, writedata, // outputs: out_port, readdata ) ; output [ 7: 0] out_port; output [ 31: 0] readdata; input [ 1: 0] address; input chipselect; input clk; input reset_n; input write_n; input [ 31: 0] writedata; wire clk_en; reg [ 7: 0] data_out; wire [ 7: 0] out_port; wire [ 7: 0] read_mux_out; wire [ 31: 0] readdata; assign clk_en = 1; //s1, which is an e_avalon_slave assign read_mux_out = {8 {(address == 0)}} & data_out; always @(posedge clk or negedge reset_n) begin if (reset_n == 0) data_out <= 0; else if (chipselect && ~write_n && (address == 0)) data_out <= writedata[7 : 0]; end assign readdata = {32'b0 \| read_mux_out}; assign out_port = data_out; endmodule
//////////////////////////////////////////////////////////////////////////////// // Copyright (c) 1995-2011 Xilinx, Inc. All rights reserved. //////////////////////////////////////////////////////////////////////////////// // ____ ____ // / /\/ / // /___/ \ / Vendor: Xilinx // \ \ \/ Version : 13.1 // \ \ Application : xaw2verilog // / / Filename : main_pll.v // /___/ /\ Timestamp : 06/03/2011 01:58:13 // \ \ / \ // \___\/\___\ // //Command: xaw2verilog -st /home/teknohog/dcm2/ipcore_dir/./main_pll.xaw /home/teknohog/dcm2/ipcore_dir/./main_pll //Design Name: main_pll //Device: xc3s500e-4fg320 // // Module main_pll // Generated by Xilinx Architecture Wizard // Written for synthesis tool: XST `timescale 1ns / 1ps module dyn_pll # (parameter SPEED_MHZ = 25 ) (CLKIN_IN, CLKFX1_OUT, CLKFX2_OUT, CLKDV_OUT, DCM_SP_LOCKED_OUT, dcm_progclk, dcm_progdata, dcm_progen, dcm_reset, dcm_progdone, dcm_locked, dcm_status); input CLKIN_IN; wire CLKIN_IBUFG_OUT; wire CLK0_OUT; output CLKFX1_OUT; output CLKFX2_OUT; output CLKDV_OUT; output DCM_SP_LOCKED_OUT; input dcm_progclk; input dcm_progdata; input dcm_progen; input dcm_reset; output dcm_progdone; output dcm_locked; output [2:1] dcm_status; wire CLKFB_IN; wire CLKIN_IBUFG; wire CLK0_BUF; wire CLKFX1_BUF; wire CLKFX2_BUF; wire CLKDV_BUF; wire GND_BIT; wire dcm_progclk_buf; assign GND_BIT = 0; assign CLKIN_IBUFG_OUT = CLKIN_IBUFG; assign CLK0_OUT = CLKFB_IN; IBUFG CLKIN_IBUFG_INST (.I(CLKIN_IN), .O(CLKIN_IBUFG)); BUFG CLK0_BUFG_INST (.I(CLK0_BUF), .O(CLKFB_IN)); BUFG CLKFX1_BUFG_INST (.I(CLKFX1_BUF), .O(CLKFX1_OUT)); BUFG CLKFX2_BUFG_INST (.I(CLKFX2_BUF), .O(CLKFX2_OUT)); BUFG CLKDV_BUFG_INST (.I(CLKDV_BUF), .O(CLKDV_OUT)); BUFG DCMPROGCLK_BUFG_INST (.I(dcm_progclk), .O(dcm_progclk_buf)); // 100 MHZ osc gives fixed 50MHz CLKFX1, 12.5MHZ CLKDV DCM_SP #( .CLK_FEEDBACK("1X"), .CLKDV_DIVIDE(8.0), .CLKFX_DIVIDE(8), .CLKFX_MULTIPLY(4), .CLKIN_DIVIDE_BY_2("FALSE"), .CLKIN_PERIOD(10.000), .CLKOUT_PHASE_SHIFT("NONE"), .DESKEW_ADJUST("SYSTEM_SYNCHRONOUS"), .DFS_FREQUENCY_MODE("LOW"), .DLL_FREQUENCY_MODE("LOW"), .DUTY_CYCLE_CORRECTION("TRUE"), .FACTORY_JF(16'hC080), .PHASE_SHIFT(0), .STARTUP_WAIT("FALSE") ) DCM_SP_INST (.CLKFB(CLKFB_IN), .CLKIN(CLKIN_IBUFG), .DSSEN(GND_BIT), .PSCLK(GND_BIT), .PSEN(GND_BIT), .PSINCDEC(GND_BIT), .RST(GND_BIT), .CLKDV(CLKDV_BUF), .CLKFX(CLKFX1_BUF), .CLKFX180(), .CLK0(CLK0_BUF), .CLK2X(), .CLK2X180(), .CLK90(), .CLK180(), .CLK270(), .LOCKED(DCM_SP_LOCKED_OUT), .PSDONE(), .STATUS()); DCM_CLKGEN #( .CLKFX_DIVIDE(100), // 100Mhz osc so gives steps of 1MHz .CLKFX_MULTIPLY(SPEED_MHZ), .CLKFXDV_DIVIDE(2), // Unused .CLKIN_PERIOD(10.0), .CLKFX_MD_MAX(0.000), .SPREAD_SPECTRUM("NONE"), .STARTUP_WAIT("FALSE") ) DCM_CLKGEN_INST ( .CLKIN(CLKIN_IBUFG), .CLKFX(CLKFX2_BUF), .FREEZEDCM(1'b0), .PROGCLK(dcm_progclk_buf), .PROGDATA(dcm_progdata), .PROGEN(dcm_progen), .PROGDONE(dcm_progdone), .LOCKED(dcm_locked), .STATUS(dcm_status), .RST(dcm_reset) ); endmodule
module opc8cpu(input[23:0] din,input clk,input reset_b,input[1:0] int_b,input clken,output vpa,output vda,output[23:0] dout,output[23:0] address,output rnw); parameter HALT=5'h00,NOT=5'h01,OR=5'h02,XOR=5'h03,BPERM=5'h04,ROR=5'h05,LSR=5'h06,ASR=5'h07,ROL=5'h08,RTI=5'h09,PPSR=5'h0A,GPSR=5'h0B; parameter BROR=5'h0C, BROL=5'h0D,MOV=5'h10,JSR=5'h11,CMP=5'h12,SUB=5'h13,ADD=5'h14,AND=5'h15,STO=5'h16,LD=5'h17; parameter FET=3'h0,FET1=3'h1,EAD=3'h2,RDM=3'h3,EXEC=3'h4,WRM=3'h5,INT=3'h6,EI=3,S=2,C=1,Z=0,INT_VECTOR0=24'h2,INT_VECTOR1=24'h4; reg [7:0] PSR_q; (* RAM_STYLE="DISTRIBUTED" ) reg [23:0] PC_q,PCI_q, RF_q[14:0], RF_pipe_q, OR_q, result; reg [4:0] IR_q; reg [3:0] swiid,PSRI_q,dst_q,src_q, pred_q; reg [2:0] FSM_q, FSM_d; reg zero,carry,sign,enable_int,reset_s0_b,reset_s1_b,subnotadd_q, rnw_q, vpa_q, vda_q; wire pred = (pred_q[0] ^ (pred_q[1]?(pred_q[2]?PSR_q[S]:PSR_q[Z]):(pred_q[2]?PSR_q[C]:1))); wire [23:0] RF_sout = {24{(\|src_q)&&IR_q[4:2]!=3'b111}} & ((src_q==4'hF)? PC_q : RF_q[src_q]); wire [23:0] bytes = (IR_q==BROL)?{OR_q[15:0],OR_q[23:16]}:{OR_q[7:0],OR_q[23:8]}; assign {rnw,dout,address}= {rnw_q, RF_pipe_q, (vpa_q)? PC_q : OR_q}; assign {vpa,vda} = {vpa_q, vda_q}; always @( ) begin case (IR_q) AND,OR :{carry,result} = {PSR_q[C],(IR_q==AND)?(RF_pipe_q & OR_q):(RF_pipe_q \| OR_q)}; ROL,NOT :{carry,result} = (IR_q==NOT)? {PSR_q[C], ~OR_q} : {OR_q, PSR_q[C]}; ADD,SUB,CMP :{carry,result} = RF_pipe_q + OR_q + subnotadd_q; // OR_q negated in EAD if required for sub/cmp XOR,GPSR :{carry,result} = (IR_q==GPSR)?{PSR_q[C],8'b0,PSR_q}:{PSR_q[C],RF_pipe_q ^ OR_q}; ROR,ASR,LSR :{result,carry} = {(IR_q==ROR)?PSR_q[C]:(IR_q==ASR)?OR_q[23]:1'b0,OR_q}; BROL,BROR :{carry,result} = { (IR_q==BROL)? (\|OR_q[23:16]): (\|OR_q[7:0]), OR_q}; default :{carry,result} = {PSR_q[C],OR_q} ; endcase // case ( IR_q ) {swiid,enable_int,sign,carry,zero} = (IR_q==PPSR)?OR_q[7:0]:(dst_q!=4'hF)?{PSR_q[7:3],result[23],carry,!(\|result)}:PSR_q; case (FSM_q) FET : FSM_d = (din[20:19]==2'b11)? FET1 : EAD; FET1 : FSM_d = EAD; // Could check predicates here to speed up skipped double word instructions EAD : FSM_d = (!pred) ? FET : (IR_q==LD) ? RDM : (IR_q==STO) ? WRM : EXEC; EXEC : FSM_d = ((!(&int_b) & PSR_q[EI])\|\|(IR_q==PPSR&&(\|swiid)))?INT:(dst_q==4'hF\|\|IR_q==JSR)?FET:(din[20:19]==2'b11)?FET1:EAD; WRM : FSM_d = (!(&int_b) & PSR_q[EI])?INT:FET; default: FSM_d = (FSM_q==RDM)? EXEC : FET; endcase end // always @ ( * ) always @(posedge clk) if (clken) begin RF_pipe_q <= (dst_q==4'hF)? PC_q : RF_q[dst_q] & {24{(\|dst_q)}}; // Sign extension on short immediates only if source field==0 being done on reading memory - may move this to EAD state... OR_q <= (FSM_q==EAD)?(IR_q==BROL\|\|IR_q==BROR)? bytes: ((RF_sout+OR_q)^{24{(IR_q==SUB\|\|IR_q==CMP)}}):(FSM_q==FET\|\|FSM_q==EXEC)?{{16{(din[7]&(\|din[11:8]))}}, din[7:0]}:din; {reset_s0_b,reset_s1_b, subnotadd_q} <= {reset_b,reset_s0_b, IR_q!=ADD}; if (!reset_s1_b) begin {PC_q,PCI_q,PSRI_q,PSR_q,FSM_q,vda_q} <= 0; {rnw_q, vpa_q} <= 2'b11; end else begin {FSM_q, rnw_q} <= {FSM_d, !(FSM_d==WRM) } ; {vpa_q, vda_q} <= {FSM_d==FET\|\|FSM_d==FET1\|\|FSM_d==EXEC,FSM_d==RDM\|\|FSM_d==WRM}; if ((FSM_q==FET)\|\|(FSM_q==EXEC)) {pred_q, IR_q, dst_q, src_q} <= { din[23:21],(din[20:19]==2'b11)?2'b10: din[20:19], din[18:8]}; // Alias 'long' opcodes to short equivalent else if (FSM_q==EAD & IR_q==CMP ) dst_q <= 4'b0; // Zero dest address after reading it in EAD for CMP operations if ( FSM_q == INT ) {PC_q,PCI_q,PSRI_q,PSR_q[EI]} <= {(!int_b[1])?INT_VECTOR1:INT_VECTOR0,PC_q,PSR_q[3:0],1'b0}; else if (FSM_q==FET\|\|FSM_q==FET1) PC_q <= PC_q + 1; else if ( FSM_q == EXEC) begin PC_q <= (IR_q==RTI)?PCI_q: (dst_q==4'hF) ? result[23:0] : (IR_q==JSR)?OR_q:((!(&int_b)&&PSR_q[EI])\|\|(IR_q==PPSR&&(\|swiid)))?PC_q:PC_q + 1; PSR_q <= (IR_q==RTI)?{4'b0,PSRI_q}:{swiid,enable_int,sign,carry,zero}; RF_q[dst_q] <= (IR_q==JSR)? PC_q : result ; end end end endmodule // opc8cpu
//====================================================================== // // rosc_entropy_core.v // ------------------- // Digitial ring oscillator based entropy generation core. // This version implements 32 separate oscillators where each // oscillator can be enabled or disabled. // // // Author: Joachim Strombergson // Copyright (c) 2014, Secworks Sweden AB // All rights reserved. // // Redistribution and use in source and binary forms, with or // without modification, are permitted provided that the following // conditions are met: // // 1. Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // // 2. Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in // the documentation and/or other materials provided with the // distribution. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS // FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE // COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, // INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, // BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; // LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER // CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, // STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) // ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF // ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // //====================================================================== module rosc_entropy_core( input wire clk, input wire reset_n, input wire [31 : 0] opa, input wire [31 : 0] opb, input wire [31 : 0] rosc_en, input wire [7 : 0] rosc_cycles, output wire [31 : 0] raw_entropy, output wire [31 : 0] rosc_outputs, output wire [31 : 0] entropy_data, output wire entropy_valid, input wire entropy_ack, output wire [7 : 0] debug, input wire debug_update ); //---------------------------------------------------------------- // Parameters. //---------------------------------------------------------------- localparam ADDER_WIDTH = 2; localparam DEBUG_DELAY = 32'h002c4b40; localparam NUM_SHIFT_BITS = 8'h20; localparam SAMPLE_CLK_CYCLES = 8'hff; //---------------------------------------------------------------- // Registers including update variables and write enable. //---------------------------------------------------------------- reg [31 : 0] ent_shift_reg; reg [31 : 0] ent_shift_new; reg ent_shift_we; reg [31 : 0] entropy_reg; reg entropy_we; reg entropy_valid_reg; reg entropy_valid_new; reg entropy_valid_we; reg bit_we_reg; reg bit_we_new; reg [7 : 0] bit_ctr_reg; reg [7 : 0] bit_ctr_new; reg bit_ctr_inc; reg bit_ctr_we; reg [7 : 0] sample_ctr_reg; reg [7 : 0] sample_ctr_new; reg [31 : 0] debug_delay_ctr_reg; reg [31 : 0] debug_delay_ctr_new; reg debug_delay_ctr_we; reg [7 : 0] debug_reg; reg debug_we; reg debug_update_reg; //---------------------------------------------------------------- // Wires. //---------------------------------------------------------------- reg [31 : 0] rosc_we; // Ugly in-line Xilinx attribute to preserve the registers. (* equivalent_register_removal = "no" ) wire [31 : 0] rosc_dout; //---------------------------------------------------------------- // Concurrent connectivity for ports etc. //---------------------------------------------------------------- assign rosc_outputs = rosc_dout; assign raw_entropy = ent_shift_reg; assign entropy_data = entropy_reg; assign entropy_valid = entropy_valid_reg; assign debug = debug_reg; //---------------------------------------------------------------- // module instantiations. // // 32 oscillators each ADDER_WIDTH wide. We want them to run // as fast as possible to maximize differences over time. // We also only sample the oscillators SAMPLE_CLK_CYCLES number // of cycles. //---------------------------------------------------------------- genvar i; generate for(i = 0 ; i < 32 ; i = i + 1) begin: oscillators rosc #(.WIDTH(ADDER_WIDTH)) rosc_array(.clk(clk), .we(rosc_we[i]), .reset_n(reset_n), .opa(opa[(ADDER_WIDTH - 1) : 0]), .opb(opb[(ADDER_WIDTH - 1) : 0]), .dout(rosc_dout[i]) ); end endgenerate //---------------------------------------------------------------- // reg_update // // Update functionality for all registers in the core. // All registers are positive edge triggered with asynchronous // active low reset. //---------------------------------------------------------------- always @ (posedge clk or negedge reset_n) begin if (!reset_n) begin ent_shift_reg <= 32'h00000000; entropy_reg <= 32'h00000000; entropy_valid_reg <= 0; bit_ctr_reg <= 8'h00; sample_ctr_reg <= 8'h00; debug_delay_ctr_reg <= 32'h00000000; debug_reg <= 8'h00; debug_update_reg <= 0; end else begin sample_ctr_reg <= sample_ctr_new; debug_update_reg <= debug_update; if (ent_shift_we) begin ent_shift_reg <= ent_shift_new; end if (bit_ctr_we) begin bit_ctr_reg <= bit_ctr_new; end if (entropy_we) begin entropy_reg <= ent_shift_reg; end if (entropy_valid_we) begin entropy_valid_reg <= entropy_valid_new; end if (debug_delay_ctr_we) begin debug_delay_ctr_reg <= debug_delay_ctr_new; end if (debug_we) begin debug_reg <= ent_shift_reg[7 : 0]; end end end // reg_update //---------------------------------------------------------------- // debug_out // // Logic that updates the debug port. //---------------------------------------------------------------- always @ begin : debug_out debug_delay_ctr_new = 32'h00000000; debug_delay_ctr_we = 0; debug_we = 0; if (debug_update_reg) begin debug_delay_ctr_new = debug_delay_ctr_reg + 1'b1; debug_delay_ctr_we = 1; end if (debug_delay_ctr_reg == DEBUG_DELAY) begin debug_delay_ctr_new = 32'h00000000; debug_delay_ctr_we = 1; debug_we = 1; end end //---------------------------------------------------------------- // entropy_out // // Logic that implements the random output control. If we have // added more than NUM_SHIFT_BITS we raise the entropy_valid flag. // When we detect and ACK, the valid flag is dropped. //---------------------------------------------------------------- always @* begin : entropy_out bit_ctr_new = 8'h00; bit_ctr_we = 0; entropy_we = 0; entropy_valid_new = 0; entropy_valid_we = 0; if (bit_ctr_inc) begin if (bit_ctr_reg < NUM_SHIFT_BITS) begin bit_ctr_new = bit_ctr_reg + 1'b1; bit_ctr_we = 1; end else begin entropy_we = 1; entropy_valid_new = 1; entropy_valid_we = 1; end end if (entropy_ack) begin bit_ctr_new = 8'h00; bit_ctr_we = 1; entropy_valid_new = 0; entropy_valid_we = 1; end end //---------------------------------------------------------------- // entropy_gen // // Logic that implements the actual entropy bit value generator // by XOR mixing the oscillator outputs. These outputs are // sampled once every SAMPLE_CLK_CYCLES. //---------------------------------------------------------------- always @* begin : entropy_gen reg ent_bit; bit_ctr_inc = 0; rosc_we = 32'h00000000; ent_shift_we = 0; ent_bit = ^rosc_dout; ent_shift_new = {ent_shift_reg[30 : 0], ent_bit}; sample_ctr_new = sample_ctr_reg + 1'b1; if (sample_ctr_reg == SAMPLE_CLK_CYCLES) begin sample_ctr_new = 8'h00; bit_ctr_inc = 1; rosc_we = rosc_en; ent_shift_we = 1; end end endmodule // rosc_entropy_core //====================================================================== // EOF rosc_entropy_core.v //======================================================================
/* File: ewrapper_link_receiver.v This file is part of the Parallella FPGA Reference Design. Copyright (C) 2013 Adapteva, Inc. Contributed by Roman Trogan <[email protected]> This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program (see the file COPYING). If not, see <http://www.gnu.org/licenses/>. / module ewrapper_link_receiver (/AUTOARG/ // Outputs rxi_wr_wait, rxi_rd_wait, emesh_clk_inb, emesh_access_inb, emesh_write_inb, emesh_datamode_inb, emesh_ctrlmode_inb, emesh_dstaddr_inb, emesh_srcaddr_inb, emesh_data_inb, // Inputs reset, rxi_data, rxi_lclk, rxi_frame, emesh_wr_wait_outb, emesh_rd_wait_outb ); //######### //# INPUTS //######### input reset; //reset input //# From the lvds-serdes input [63:0] rxi_data; //Eight Parallel Byte words input rxi_lclk; //receive clock (synchronized to the data) input [7:0] rxi_frame; //Parallel frame signals representing // 4 transmission clock cycles //# From the emesh interface input emesh_wr_wait_outb; input emesh_rd_wait_outb; //########## //# OUTPUTS //########## //# To the transmitter output rxi_wr_wait; //wait indicator output rxi_rd_wait; //wait indicator //# To the emesh interface output emesh_clk_inb; output emesh_access_inb; output emesh_write_inb; output [1:0] emesh_datamode_inb; output [3:0] emesh_ctrlmode_inb; output [31:0] emesh_dstaddr_inb; output [31:0] emesh_srcaddr_inb; output [31:0] emesh_data_inb; /AUTOINPUT/ /AUTOWIRE/ //######### //# Wires //######### wire emesh_wr_access_inb; wire emesh_wr_write_inb; wire [1:0] emesh_wr_datamode_inb; wire [3:0] emesh_wr_ctrlmode_inb; wire [31:0] emesh_wr_dstaddr_inb; wire [31:0] emesh_wr_srcaddr_inb; wire [31:0] emesh_wr_data_inb; wire emesh_rd_access_inb; wire emesh_rd_write_inb; wire [1:0] emesh_rd_datamode_inb; wire [3:0] emesh_rd_ctrlmode_inb; wire [31:0] emesh_rd_dstaddr_inb; wire [31:0] emesh_rd_srcaddr_inb; wire [31:0] emesh_rd_data_inb; wire select_write_tran; wire wr_wait; wire rd_wait; wire emesh_access_tmp; //############### //# Emesh clock //############### assign emesh_clk_inb = rxi_lclk; //###################################### //# Write-Read Transactions Arbitration //# Write has a higher priority ALWAYS //###################################### assign select_write_tran = emesh_wr_access_inb & ~emesh_wr_wait_outb; assign emesh_access_inb = emesh_access_tmp & ~emesh_wr_wait_outb; assign wr_wait = emesh_wr_wait_outb; assign rd_wait = emesh_rd_access_inb & select_write_tran \| (emesh_wr_wait_outb \| emesh_rd_wait_outb); assign emesh_srcaddr_inb[31:0] = select_write_tran ? emesh_wr_srcaddr_inb[31:0] : emesh_rd_srcaddr_inb[31:0]; assign emesh_dstaddr_inb[31:0] = select_write_tran ? emesh_wr_dstaddr_inb[31:0] : emesh_rd_dstaddr_inb[31:0]; assign emesh_datamode_inb[1:0] = select_write_tran ? emesh_wr_datamode_inb[1:0] : emesh_rd_datamode_inb[1:0]; assign emesh_ctrlmode_inb[3:0] = select_write_tran ? emesh_wr_ctrlmode_inb[3:0] : emesh_rd_ctrlmode_inb[3:0]; assign emesh_data_inb[31:0] = select_write_tran ? emesh_wr_data_inb[31:0] : emesh_rd_data_inb[31:0]; assign emesh_access_tmp = select_write_tran ? emesh_wr_access_inb : emesh_rd_access_inb; assign emesh_write_inb = select_write_tran ? emesh_wr_write_inb : emesh_rd_write_inb; //############################################ //# Write Transactions Receiver Instantiation //############################################ /ewrapper_link_rxi AUTO_TEMPLATE( .rxi_rd (1'b0), .emesh_wait_outb (wr_wait), .rxi_wait (rxi_wr_wait), .emesh_\(.\) (emesh_wr_\1[]), ); / ewrapper_link_rxi wr_rxi(/AUTOINST/ // Outputs .rxi_wait (rxi_wr_wait), // Templated .emesh_access_inb (emesh_wr_access_inb), // Templated .emesh_write_inb (emesh_wr_write_inb), // Templated .emesh_datamode_inb (emesh_wr_datamode_inb[1:0]), // Templated .emesh_ctrlmode_inb (emesh_wr_ctrlmode_inb[3:0]), // Templated .emesh_dstaddr_inb (emesh_wr_dstaddr_inb[31:0]), // Templated .emesh_srcaddr_inb (emesh_wr_srcaddr_inb[31:0]), // Templated .emesh_data_inb (emesh_wr_data_inb[31:0]), // Templated // Inputs .reset (reset), .rxi_data (rxi_data[63:0]), .rxi_lclk (rxi_lclk), .rxi_frame (rxi_frame[7:0]), .emesh_wait_outb (wr_wait), // Templated .rxi_rd (1'b0)); // Templated //############################################ //# Read Transactions Receiver Instantiation //############################################ /ewrapper_link_rxi AUTO_TEMPLATE( .rxi_rd (1'b1), .emesh_wait_outb (rd_wait), .rxi_wait (rxi_rd_wait), .emesh_\(.\) (emesh_rd_\1[]), ); / ewrapper_link_rxi rd_rxi(/AUTOINST*/ // Outputs .rxi_wait (rxi_rd_wait), // Templated .emesh_access_inb (emesh_rd_access_inb), // Templated .emesh_write_inb (emesh_rd_write_inb), // Templated .emesh_datamode_inb (emesh_rd_datamode_inb[1:0]), // Templated .emesh_ctrlmode_inb (emesh_rd_ctrlmode_inb[3:0]), // Templated .emesh_dstaddr_inb (emesh_rd_dstaddr_inb[31:0]), // Templated .emesh_srcaddr_inb (emesh_rd_srcaddr_inb[31:0]), // Templated .emesh_data_inb (emesh_rd_data_inb[31:0]), // Templated // Inputs .reset (reset), .rxi_data (rxi_data[63:0]), .rxi_lclk (rxi_lclk), .rxi_frame (rxi_frame[7:0]), .emesh_wait_outb (rd_wait), // Templated .rxi_rd (1'b1)); // Templated endmodule // ewrapper_link_receiver
// (C) 1992-2014 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. module vfabric_icmp(clock, resetn, i_dataa, i_dataa_valid, o_dataa_stall, i_datab, i_datab_valid, o_datab_stall, o_dataout, o_dataout_valid, i_stall, i_settings); parameter DATA_WIDTH = 32; parameter MODE_WIDTH = 4; parameter FIFO_DEPTH = 64; input clock, resetn; input [DATA_WIDTH-1:0] i_dataa; input [DATA_WIDTH-1:0] i_datab; input i_dataa_valid, i_datab_valid; output o_dataa_stall, o_datab_stall; output reg o_dataout; output o_dataout_valid; input i_stall; input [MODE_WIDTH-1:0] i_settings; wire [DATA_WIDTH-1:0] dataa; wire [DATA_WIDTH-1:0] datab; wire signed [DATA_WIDTH-1:0] sdataa; wire signed [DATA_WIDTH-1:0] sdatab; wire is_fifo_a_valid; wire is_fifo_b_valid; wire is_stalled; vfabric_buffered_fifo fifo_a ( .clock(clock), .resetn(resetn), .data_in(i_dataa), .data_out(dataa), .valid_in(i_dataa_valid), .valid_out( is_fifo_a_valid ), .stall_in(is_stalled), .stall_out(o_dataa_stall) ); defparam fifo_a.DATA_WIDTH = DATA_WIDTH; defparam fifo_a.DEPTH = FIFO_DEPTH; vfabric_buffered_fifo fifo_b ( .clock(clock), .resetn(resetn), .data_in(i_datab), .data_out(datab), .valid_in(i_datab_valid), .valid_out( is_fifo_b_valid ), .stall_in(is_stalled), .stall_out(o_datab_stall) ); defparam fifo_b.DATA_WIDTH = DATA_WIDTH; defparam fifo_b.DEPTH = FIFO_DEPTH; assign is_stalled = ~(is_fifo_a_valid & is_fifo_b_valid & ~i_stall); assign sdataa = dataa; assign sdatab = datab; always @(*) begin case (i_settings) 5'h0: // EQ begin o_dataout <= (dataa == datab) ? 1'b1 : 1'b0; end 5'h1: // NE begin o_dataout <= (dataa != datab) ? 1'b1 : 1'b0; end 5'h2: // UGT begin o_dataout <= (dataa > datab) ? 1'b1 : 1'b0; end 5'h3: // UGE begin o_dataout <= (dataa >= datab) ? 1'b1 : 1'b0; end 5'h4: // ULT begin o_dataout <= (dataa < datab) ? 1'b1 : 1'b0; end 5'h5: // ULE begin o_dataout <= (dataa <= datab) ? 1'b1 : 1'b0; end 5'h6: // SGT begin o_dataout <= (sdataa > sdatab) ? 1'b1 : 1'b0; end 5'h7: // SGE begin o_dataout <= (sdataa >= sdatab) ? 1'b1 : 1'b0; end 5'h8: // SLT begin o_dataout <= (sdataa < sdatab) ? 1'b1 : 1'b0; end 5'h9: // SLE begin o_dataout <= (sdataa <= sdatab) ? 1'b1 : 1'b0; end default: begin o_dataout <= 1'b0; end endcase end assign o_dataout_valid = is_fifo_a_valid & is_fifo_b_valid; endmodule
//----------------------------------------------------------------------------- //-- Baudrate generator //-- It generates a square signal, with a frequency for communicating at the given //-- given baudrate //-- The output is set to 1 only during one clock cycle. The rest of the time is 0 //-------------------------------------------------------------------------------- //-- (c) BQ. December 2015. written by Juan Gonzalez (obijuan) //----------------------------------------------------------------------------- //-- GPL license //----------------------------------------------------------------------------- `default_nettype none `include "baudgen.vh" //---------------------------------------------------------------------------------------- //-- baudgen module //-- //-- INPUTS: //-- -clk: System clock (12 MHZ in the iceStick board) //-- -clk_ena: clock enable: //-- 1. Normal working: The squeare signal is generated //-- 0: stoped. Output always 0 //-- OUTPUTS: //-- - clk_out: Output signal. Pulse width: 1 clock cycle. Output not registered //-- It tells the uart_tx when to transmit the next bit //-- __ __ //-- __\| \|________________________________________________________\| \|________________ //-- -> <- 1 clock cycle //-- //--------------------------------------------------------------------------------------- module baudgen_tx #( parameter BAUDRATE = `B115200 //-- Default baudrate )( input wire rstn, //-- Reset (active low) input wire clk, //-- System clock input wire clk_ena, //-- Clock enable output wire clk_out //-- Bitrate Clock output ); //-- Number of bits needed for storing the baudrate divisor localparam N = $clog2(BAUDRATE); //-- Counter for implementing the divisor (it is a BAUDRATE module counter) //-- (when BAUDRATE is reached, it start again from 0) reg [N-1:0] divcounter = 0; always @(posedge clk) if (!rstn) divcounter <= 0; else if (clk_ena) //-- Normal working: counting. When the maximum count is reached, it starts from 0 divcounter <= (divcounter == BAUDRATE - 1) ? 0 : divcounter + 1; else //-- Counter fixed to its maximum value //-- When it is resumed it start from 0 divcounter <= BAUDRATE - 1; //-- The output is 1 when the counter is 0, if clk_ena is active //-- It is 1 only for one system clock cycle assign clk_out = (divcounter == 0) ? clk_ena : 0; endmodule
/////////////////////////////////////////////////////////////////////////////// // vim:set shiftwidth=3 softtabstop=3 expandtab: // $Id: unused_reg.v 1914 2007-07-11 23:58:33Z grg $ // // Module: unused_reg.v // Project: NetFPGA // Description: Unused register block // /////////////////////////////////////////////////////////////////////////////// module unused_reg #( parameter REG_ADDR_WIDTH = 5 ) ( // Register interface signals input reg_req, output reg_ack, input reg_rd_wr_L, input [REG_ADDR_WIDTH - 1:0] reg_addr, output [`CPCI_NF2_DATA_WIDTH - 1:0] reg_rd_data, input [`CPCI_NF2_DATA_WIDTH - 1:0] reg_wr_data, // input clk, input reset ); reg reg_req_d1; assign reg_rd_data = 'h dead_beef; // Only generate an ack on a new request assign reg_ack = reg_req && !reg_req_d1; always @(posedge clk) begin reg_req_d1 <= reg_req; end endmodule // unused_reg
module bts ( z , a , e); inout z ; wire z ; input a ; wire a ; input e ; wire e ; assign #4 z= ( (e==1'b1)? a : 1'bz ); endmodule module test(); reg [1:0] aa; wire [1:0] zz; reg [1:0] ee; bts sub1 (.z(zz[1]), .a(aa[1]), .e(ee[1])); bts sub0 (.z(zz[0]), .a(aa[0]), .e(ee[0])); initial begin // $dumpvars; ee=2'b00; aa=2'b00; #100; if (zz !== 2'bzz) begin $display("FAILED -- (1) All disabled, expected HiZ, got %b", zz); $finish; end aa=2'b11; #100; if (zz !== 2'bzz) begin $display("FAILED -- (2) All disabled, expected HiZ, got %b", zz); $finish; end aa=2'b00; #100; if (zz !== 2'bzz) begin $display("FAILED -- (3) All disabled, expected HiZ, got %b", zz); $finish; end aa=2'b11; #100; if (zz !== 2'bzz) begin $display("FAILED -- (4) All disabled, expected HiZ, got %b", zz); $finish; end ee=2'b11; aa=2'b00; #100; if (zz !== 2'b00) begin $display("FAILED -- (5) All enabled, expected 00, got %b", zz); $finish; end aa=2'b11; #100; if (zz !== 2'b11) begin $display("FAILED -- (6) All enabled, expected 11, got %b", zz); $finish; end aa=2'b00; #100; if (zz !== 2'b00) begin $display("FAILED -- (7) All enabled, expected 00, got %b", zz); $finish; end aa=2'b11; #100; if (zz !== 2'b11) begin $display("FAILED -- (8) All enabled, expected 11, got %b", zz); $finish; end $display("PASSED"); end endmodule
//----------------------------------------------------------------------------- //-- (c) Copyright 2010 Xilinx, Inc. All rights reserved. //-- //-- This file contains confidential and proprietary information //-- of Xilinx, Inc. and is protected under U.S. and //-- international copyright and other intellectual property //-- laws. //-- //-- DISCLAIMER //-- This disclaimer is not a license and does not grant any //-- rights to the materials distributed herewith. Except as //-- otherwise provided in a valid license issued to you by //-- Xilinx, and to the maximum extent permitted by applicable //-- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND //-- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES //-- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING //-- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- //-- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and //-- (2) Xilinx shall not be liable (whether in contract or tort, //-- including negligence, or under any other theory of //-- liability) for any loss or damage of any kind or nature //-- related to, arising under or in connection with these //-- materials, including for any direct, or any indirect, //-- special, incidental, or consequential loss or damage //-- (including loss of data, profits, goodwill, or any type of //-- loss or damage suffered as a result of any action brought //-- by a third party) even if such damage or loss was //-- reasonably foreseeable or Xilinx had been advised of the //-- possibility of the same. //-- //-- CRITICAL APPLICATIONS //-- Xilinx products are not designed or intended to be fail- //-- safe, or for use in any application requiring fail-safe //-- performance, such as life-support or safety devices or //-- systems, Class III medical devices, nuclear facilities, //-- applications related to the deployment of airbags, or any //-- other applications that could lead to death, personal //-- injury, or severe property or environmental damage //-- (individually and collectively, "Critical //-- Applications"). Customer assumes the sole risk and //-- liability of any use of Xilinx products in Critical //-- Applications, subject only to applicable laws and //-- regulations governing limitations on product liability. //-- //-- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS //-- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Description: Up-Sizer // Up-Sizer for generic SI- and MI-side data widths. This module instantiates // Address, Write Data and Read Data Up-Sizer modules, each one taking care // of the channel specific tasks. // The Address Up-Sizer can handle both AR and AW channels. // // Verilog-standard: Verilog 2001 //-------------------------------------------------------------------------- // // Structure: // axi_upsizer // a_upsizer // fifo // fifo_gen // fifo_coregen // w_upsizer // r_upsizer // //-------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none (* DowngradeIPIdentifiedWarnings="yes" ) module axi_dwidth_converter_v2_1_7_axi_upsizer # ( parameter C_FAMILY = "virtex7", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_AXI_PROTOCOL = 0, // Protocol of SI and MI (0=AXI4, 1=AXI3). parameter integer C_S_AXI_ID_WIDTH = 1, // Width of all ID signals on SI side of converter. // Range: 1 - 32. parameter integer C_SUPPORTS_ID = 0, // Indicates whether SI-side ID needs to be stored and compared. // 0 = No, SI is single-threaded, propagate all transactions. // 1 = Yes, stall any transaction with ID different than outstanding transactions. parameter integer C_AXI_ADDR_WIDTH = 32, // Width of all ADDR signals on SI and MI. // Range (AXI4, AXI3): 12 - 64. parameter integer C_S_AXI_DATA_WIDTH = 32, // Width of s_axi_wdata and s_axi_rdata. // Range: 32, 64, 128, 256, 512, 1024. parameter integer C_M_AXI_DATA_WIDTH = 64, // Width of m_axi_wdata and m_axi_rdata. // Assume always >= than C_S_AXI_DATA_WIDTH. // Range: 32, 64, 128, 256, 512, 1024. parameter integer C_AXI_SUPPORTS_WRITE = 1, parameter integer C_AXI_SUPPORTS_READ = 1, /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // parameter integer C_FIFO_MODE = 0, parameter integer C_FIFO_MODE = 1, // 0=None, 1=Packet_FIFO, 2=Clock_conversion_Packet_FIFO, 3=Simple_FIFO (FUTURE), 4=Clock_conversion_Simple_FIFO (FUTURE) parameter integer C_S_AXI_ACLK_RATIO = 1, // Clock frequency ratio of SI w.r.t. MI. // Range = [1..16]. parameter integer C_M_AXI_ACLK_RATIO = 2, // Clock frequency ratio of MI w.r.t. SI. // Range = [2..16] if C_S_AXI_ACLK_RATIO = 1; else must be 1. parameter integer C_AXI_IS_ACLK_ASYNC = 0, // Indicates whether S and M clocks are asynchronous. // FUTURE FEATURE // Range = [0, 1]. parameter integer C_PACKING_LEVEL = 1, // 0 = Never pack (expander only); packing logic is omitted. // 1 = Pack only when CACHE[1] (Modifiable) is high. // 2 = Always pack, regardless of sub-size transaction or Modifiable bit. // (Required when used as helper-core by mem-con. Same size AXI interfaces // should only be used when always packing) parameter integer C_SYNCHRONIZER_STAGE = 3 ) ( // Slave Interface input wire s_axi_aresetn, input wire s_axi_aclk, // Slave Interface Write Address Ports input wire [C_S_AXI_ID_WIDTH-1:0] s_axi_awid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr, input wire [8-1:0] s_axi_awlen, input wire [3-1:0] s_axi_awsize, input wire [2-1:0] s_axi_awburst, input wire [2-1:0] s_axi_awlock, input wire [4-1:0] s_axi_awcache, input wire [3-1:0] s_axi_awprot, input wire [4-1:0] s_axi_awregion, input wire [4-1:0] s_axi_awqos, input wire s_axi_awvalid, output wire s_axi_awready, // Slave Interface Write Data Ports input wire [C_S_AXI_DATA_WIDTH-1:0] s_axi_wdata, input wire [C_S_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb, input wire s_axi_wlast, input wire s_axi_wvalid, output wire s_axi_wready, // Slave Interface Write Response Ports output wire [C_S_AXI_ID_WIDTH-1:0] s_axi_bid, output wire [2-1:0] s_axi_bresp, output wire s_axi_bvalid, input wire s_axi_bready, // Slave Interface Read Address Ports input wire [C_S_AXI_ID_WIDTH-1:0] s_axi_arid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr, input wire [8-1:0] s_axi_arlen, input wire [3-1:0] s_axi_arsize, input wire [2-1:0] s_axi_arburst, input wire [2-1:0] s_axi_arlock, input wire [4-1:0] s_axi_arcache, input wire [3-1:0] s_axi_arprot, input wire [4-1:0] s_axi_arregion, input wire [4-1:0] s_axi_arqos, input wire s_axi_arvalid, output wire s_axi_arready, // Slave Interface Read Data Ports output wire [C_S_AXI_ID_WIDTH-1:0] s_axi_rid, output wire [C_S_AXI_DATA_WIDTH-1:0] s_axi_rdata, output wire [2-1:0] s_axi_rresp, output wire s_axi_rlast, output wire s_axi_rvalid, input wire s_axi_rready, // Master Interface input wire m_axi_aresetn, input wire m_axi_aclk, // Master Interface Write Address Port output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr, output wire [8-1:0] m_axi_awlen, output wire [3-1:0] m_axi_awsize, output wire [2-1:0] m_axi_awburst, output wire [2-1:0] m_axi_awlock, output wire [4-1:0] m_axi_awcache, output wire [3-1:0] m_axi_awprot, output wire [4-1:0] m_axi_awregion, output wire [4-1:0] m_axi_awqos, output wire m_axi_awvalid, input wire m_axi_awready, // Master Interface Write Data Ports output wire [C_M_AXI_DATA_WIDTH-1:0] m_axi_wdata, output wire [C_M_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb, output wire m_axi_wlast, output wire m_axi_wvalid, input wire m_axi_wready, // Master Interface Write Response Ports input wire [2-1:0] m_axi_bresp, input wire m_axi_bvalid, output wire m_axi_bready, // Master Interface Read Address Port output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr, output wire [8-1:0] m_axi_arlen, output wire [3-1:0] m_axi_arsize, output wire [2-1:0] m_axi_arburst, output wire [2-1:0] m_axi_arlock, output wire [4-1:0] m_axi_arcache, output wire [3-1:0] m_axi_arprot, output wire [4-1:0] m_axi_arregion, output wire [4-1:0] m_axi_arqos, output wire m_axi_arvalid, input wire m_axi_arready, // Master Interface Read Data Ports input wire [C_M_AXI_DATA_WIDTH-1:0] m_axi_rdata, input wire [2-1:0] m_axi_rresp, input wire m_axi_rlast, input wire m_axi_rvalid, output wire m_axi_rready ); // Log2 of number of 32bit word on SI-side. localparam integer C_S_AXI_BYTES_LOG = log2(C_S_AXI_DATA_WIDTH/8); // Log2 of number of 32bit word on MI-side. localparam integer C_M_AXI_BYTES_LOG = log2(C_M_AXI_DATA_WIDTH/8); // Log2 of Up-Sizing ratio for data. localparam integer C_RATIO = C_M_AXI_DATA_WIDTH / C_S_AXI_DATA_WIDTH; localparam integer C_RATIO_LOG = log2(C_RATIO); localparam P_BYPASS = 32'h0; localparam P_LIGHTWT = 32'h7; localparam P_FWD_REV = 32'h1; localparam integer P_CONV_LIGHT_WT = 0; localparam integer P_AXI4 = 0; localparam integer C_FIFO_DEPTH_LOG = 5; localparam P_SI_LT_MI = (C_S_AXI_ACLK_RATIO < C_M_AXI_ACLK_RATIO); localparam integer P_ACLK_RATIO = P_SI_LT_MI ? (C_M_AXI_ACLK_RATIO / C_S_AXI_ACLK_RATIO) : (C_S_AXI_ACLK_RATIO / C_M_AXI_ACLK_RATIO); localparam integer P_NO_FIFO = 0; localparam integer P_PKTFIFO = 1; localparam integer P_PKTFIFO_CLK = 2; localparam integer P_DATAFIFO = 3; localparam integer P_DATAFIFO_CLK = 4; localparam P_CLK_CONV = ((C_FIFO_MODE == P_PKTFIFO_CLK) \|\| (C_FIFO_MODE == P_DATAFIFO_CLK)); localparam integer C_M_AXI_AW_REGISTER = 0; // Simple register AW output. // Range: 0, 1 localparam integer C_M_AXI_W_REGISTER = 1; // Parameter not used; W reg always implemented. localparam integer C_M_AXI_AR_REGISTER = 0; // Simple register AR output. // Range: 0, 1 localparam integer C_S_AXI_R_REGISTER = 0; // Simple register R output (SI). // Range: 0, 1 localparam integer C_M_AXI_R_REGISTER = 1; // Register slice on R input (MI) side. // 0 = Bypass (not recommended due to combinatorial M_RVALID -> M_RREADY path) // 1 = Fully-registered (needed only when upsizer propagates bursts at 1:1 width ratio) // 7 = Light-weight (safe when upsizer always packs at 1:n width ratio, as in interconnect) localparam integer P_RID_QUEUE = ((C_SUPPORTS_ID != 0) && !((C_FIFO_MODE == P_PKTFIFO) \|\| (C_FIFO_MODE == P_PKTFIFO_CLK))) ? 1 : 0; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// // Log2. function integer log2 ( input integer x ); integer acc; begin acc=0; while ((2*acc) < x) acc = acc + 1; log2 = acc; end endfunction ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire aclk; wire m_aclk; wire sample_cycle; wire sample_cycle_early; wire sm_aresetn; wire s_aresetn_i; wire [C_S_AXI_ID_WIDTH-1:0] sr_awid ; wire [C_AXI_ADDR_WIDTH-1:0] sr_awaddr ; wire [8-1:0] sr_awlen ; wire [3-1:0] sr_awsize ; wire [2-1:0] sr_awburst ; wire [2-1:0] sr_awlock ; wire [4-1:0] sr_awcache ; wire [3-1:0] sr_awprot ; wire [4-1:0] sr_awregion ; wire [4-1:0] sr_awqos ; wire sr_awvalid ; wire sr_awready ; wire [C_S_AXI_ID_WIDTH-1:0] sr_arid ; wire [C_AXI_ADDR_WIDTH-1:0] sr_araddr ; wire [8-1:0] sr_arlen ; wire [3-1:0] sr_arsize ; wire [2-1:0] sr_arburst ; wire [2-1:0] sr_arlock ; wire [4-1:0] sr_arcache ; wire [3-1:0] sr_arprot ; wire [4-1:0] sr_arregion ; wire [4-1:0] sr_arqos ; wire sr_arvalid ; wire sr_arready ; wire [C_S_AXI_DATA_WIDTH-1:0] sr_wdata ; wire [(C_S_AXI_DATA_WIDTH/8)-1:0] sr_wstrb ; wire sr_wlast ; wire sr_wvalid ; wire sr_wready ; wire [C_M_AXI_DATA_WIDTH-1:0] mr_rdata ; wire [2-1:0] mr_rresp ; wire mr_rlast ; wire mr_rvalid ; wire mr_rready ; wire m_axi_rready_i; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_awlen_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_arlen_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_awlock_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_arlock_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_awlen_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_arlen_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_awlock_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_arlock_ii ; wire [3:0] s_axi_awregion_ii; wire [3:0] s_axi_arregion_ii; assign s_axi_awlen_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlen : s_axi_awlen[3:0]; assign s_axi_awlock_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlock[0] : s_axi_awlock; assign s_axi_arlen_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlen : s_axi_arlen[3:0]; assign s_axi_arlock_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlock[0] : s_axi_arlock; assign sr_awlen = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlen_ii: {4'b0, s_axi_awlen_ii}; assign sr_awlock = (C_AXI_PROTOCOL == P_AXI4) ? {1'b0, s_axi_awlock_ii} : s_axi_awlock_ii; assign sr_arlen = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlen_ii: {4'b0, s_axi_arlen_ii}; assign sr_arlock = (C_AXI_PROTOCOL == P_AXI4) ? {1'b0, s_axi_arlock_ii} : s_axi_arlock_ii; assign sr_awregion = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awregion_ii : 4'b0; assign sr_arregion = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arregion_ii : 4'b0; assign aclk = s_axi_aclk; assign sm_aresetn = s_axi_aresetn & m_axi_aresetn; generate if (P_CLK_CONV) begin : gen_clock_conv if (C_AXI_IS_ACLK_ASYNC) begin : gen_async_conv assign m_aclk = m_axi_aclk; assign s_aresetn_i = s_axi_aresetn; assign sample_cycle_early = 1'b1; assign sample_cycle = 1'b1; end else begin : gen_sync_conv wire fast_aclk; wire slow_aclk; reg s_aresetn_r; if (P_SI_LT_MI) begin : gen_fastclk_mi assign fast_aclk = m_axi_aclk; assign slow_aclk = s_axi_aclk; end else begin : gen_fastclk_si assign fast_aclk = s_axi_aclk; assign slow_aclk = m_axi_aclk; end assign m_aclk = m_axi_aclk; assign s_aresetn_i = s_aresetn_r; always @(negedge sm_aresetn, posedge fast_aclk) begin if (~sm_aresetn) begin s_aresetn_r <= 1'b0; end else if (s_axi_aresetn & m_axi_aresetn & sample_cycle_early) begin s_aresetn_r <= 1'b1; end end // Sample cycle used to determine when to assert a signal on a fast clock // to be flopped onto a slow clock. axi_clock_converter_v2_1_6_axic_sample_cycle_ratio #( .C_RATIO ( P_ACLK_RATIO ) ) axic_sample_cycle_inst ( .SLOW_ACLK ( slow_aclk ) , .FAST_ACLK ( fast_aclk ) , .SAMPLE_CYCLE_EARLY ( sample_cycle_early ) , .SAMPLE_CYCLE ( sample_cycle ) ); end end else begin : gen_no_clk_conv assign m_aclk = s_axi_aclk; assign s_aresetn_i = s_axi_aresetn; assign sample_cycle_early = 1'b1; assign sample_cycle = 1'b1; end // gen_clock_conv axi_register_slice_v2_1_7_axi_register_slice # ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (0), .C_REG_CONFIG_AW (C_AXI_SUPPORTS_WRITE ? P_LIGHTWT : P_BYPASS), .C_REG_CONFIG_AR (C_AXI_SUPPORTS_READ ? P_LIGHTWT : P_BYPASS) ) si_register_slice_inst ( .aresetn (s_aresetn_i), .aclk (aclk), .s_axi_awid (s_axi_awid ), .s_axi_awaddr (s_axi_awaddr ), .s_axi_awlen (s_axi_awlen_i ), .s_axi_awsize (s_axi_awsize ), .s_axi_awburst (s_axi_awburst ), .s_axi_awlock (s_axi_awlock_i ), .s_axi_awcache (s_axi_awcache ), .s_axi_awprot (s_axi_awprot ), .s_axi_awregion (s_axi_awregion ), .s_axi_awqos (s_axi_awqos ), .s_axi_awuser (1'b0 ), .s_axi_awvalid (s_axi_awvalid ), .s_axi_awready (s_axi_awready ), .s_axi_wid ( {C_S_AXI_ID_WIDTH{1'b0}}), .s_axi_wdata ( {C_S_AXI_DATA_WIDTH{1'b0}} ), .s_axi_wstrb ( {C_S_AXI_DATA_WIDTH/8{1'b0}} ), .s_axi_wlast ( 1'b0 ), .s_axi_wuser ( 1'b0 ), .s_axi_wvalid ( 1'b0 ), .s_axi_wready ( ), .s_axi_bid ( ), .s_axi_bresp ( ), .s_axi_buser ( ), .s_axi_bvalid ( ), .s_axi_bready ( 1'b0 ), .s_axi_arid (s_axi_arid ), .s_axi_araddr (s_axi_araddr ), .s_axi_arlen (s_axi_arlen_i ), .s_axi_arsize (s_axi_arsize ), .s_axi_arburst (s_axi_arburst ), .s_axi_arlock (s_axi_arlock_i ), .s_axi_arcache (s_axi_arcache ), .s_axi_arprot (s_axi_arprot ), .s_axi_arregion (s_axi_arregion ), .s_axi_arqos (s_axi_arqos ), .s_axi_aruser (1'b0 ), .s_axi_arvalid (s_axi_arvalid ), .s_axi_arready (s_axi_arready ), .s_axi_rid ( ) , .s_axi_rdata ( ) , .s_axi_rresp ( ) , .s_axi_rlast ( ) , .s_axi_ruser ( ) , .s_axi_rvalid ( ) , .s_axi_rready ( 1'b0 ) , .m_axi_awid (sr_awid ), .m_axi_awaddr (sr_awaddr ), .m_axi_awlen (s_axi_awlen_ii), .m_axi_awsize (sr_awsize ), .m_axi_awburst (sr_awburst ), .m_axi_awlock (s_axi_awlock_ii), .m_axi_awcache (sr_awcache ), .m_axi_awprot (sr_awprot ), .m_axi_awregion (s_axi_awregion_ii ), .m_axi_awqos (sr_awqos ), .m_axi_awuser (), .m_axi_awvalid (sr_awvalid ), .m_axi_awready (sr_awready ), .m_axi_wid () , .m_axi_wdata (), .m_axi_wstrb (), .m_axi_wlast (), .m_axi_wuser (), .m_axi_wvalid (), .m_axi_wready (1'b0), .m_axi_bid ( {C_S_AXI_ID_WIDTH{1'b0}} ) , .m_axi_bresp ( 2'b0 ) , .m_axi_buser ( 1'b0 ) , .m_axi_bvalid ( 1'b0 ) , .m_axi_bready ( ) , .m_axi_arid (sr_arid ), .m_axi_araddr (sr_araddr ), .m_axi_arlen (s_axi_arlen_ii), .m_axi_arsize (sr_arsize ), .m_axi_arburst (sr_arburst ), .m_axi_arlock (s_axi_arlock_ii), .m_axi_arcache (sr_arcache ), .m_axi_arprot (sr_arprot ), .m_axi_arregion (s_axi_arregion_ii ), .m_axi_arqos (sr_arqos ), .m_axi_aruser (), .m_axi_arvalid (sr_arvalid ), .m_axi_arready (sr_arready ), .m_axi_rid ( {C_S_AXI_ID_WIDTH{1'b0}}), .m_axi_rdata ( {C_S_AXI_DATA_WIDTH{1'b0}} ), .m_axi_rresp ( 2'b00 ), .m_axi_rlast ( 1'b0 ), .m_axi_ruser ( 1'b0 ), .m_axi_rvalid ( 1'b0 ), .m_axi_rready ( ) ); ///////////////////////////////////////////////////////////////////////////// // Handle Write Channels (AW/W/B) ///////////////////////////////////////////////////////////////////////////// if (C_AXI_SUPPORTS_WRITE == 1) begin : USE_WRITE wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr_i ; wire [8-1:0] m_axi_awlen_i ; wire [3-1:0] m_axi_awsize_i ; wire [2-1:0] m_axi_awburst_i ; wire [2-1:0] m_axi_awlock_i ; wire [4-1:0] m_axi_awcache_i ; wire [3-1:0] m_axi_awprot_i ; wire [4-1:0] m_axi_awregion_i ; wire [4-1:0] m_axi_awqos_i ; wire m_axi_awvalid_i ; wire m_axi_awready_i ; wire s_axi_bvalid_i ; wire [2-1:0] s_axi_bresp_i ; wire [C_AXI_ADDR_WIDTH-1:0] wr_cmd_si_addr; wire [8-1:0] wr_cmd_si_len; wire [3-1:0] wr_cmd_si_size; wire [2-1:0] wr_cmd_si_burst; // Write Channel Signals for Commands Queue Interface. wire wr_cmd_valid; wire wr_cmd_fix; wire wr_cmd_modified; wire wr_cmd_complete_wrap; wire wr_cmd_packed_wrap; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_first_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_next_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_last_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_offset; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_mask; wire [C_S_AXI_BYTES_LOG:0] wr_cmd_step; wire [8-1:0] wr_cmd_length; wire wr_cmd_ready; wire wr_cmd_id_ready; wire [C_S_AXI_ID_WIDTH-1:0] wr_cmd_id; wire wpush; wire wpop; reg [C_FIFO_DEPTH_LOG-1:0] wcnt; // Write Address Channel. axi_dwidth_converter_v2_1_7_a_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_SUPPORTS_ID (C_SUPPORTS_ID), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (C_M_AXI_AW_REGISTER), .C_AXI_CHANNEL (0), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_FIFO_MODE (C_FIFO_MODE), .C_ID_QUEUE (C_SUPPORTS_ID), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG) ) write_addr_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (wr_cmd_valid), .cmd_fix (wr_cmd_fix), .cmd_modified (wr_cmd_modified), .cmd_complete_wrap (wr_cmd_complete_wrap), .cmd_packed_wrap (wr_cmd_packed_wrap), .cmd_first_word (wr_cmd_first_word), .cmd_next_word (wr_cmd_next_word), .cmd_last_word (wr_cmd_last_word), .cmd_offset (wr_cmd_offset), .cmd_mask (wr_cmd_mask), .cmd_step (wr_cmd_step), .cmd_length (wr_cmd_length), .cmd_ready (wr_cmd_ready), .cmd_id (wr_cmd_id), .cmd_id_ready (wr_cmd_id_ready), .cmd_si_addr (wr_cmd_si_addr ), .cmd_si_id (), .cmd_si_len (wr_cmd_si_len ), .cmd_si_size (wr_cmd_si_size ), .cmd_si_burst (wr_cmd_si_burst), // Slave Interface Write Address Ports .S_AXI_AID (sr_awid), .S_AXI_AADDR (sr_awaddr), .S_AXI_ALEN (sr_awlen), .S_AXI_ASIZE (sr_awsize), .S_AXI_ABURST (sr_awburst), .S_AXI_ALOCK (sr_awlock), .S_AXI_ACACHE (sr_awcache), .S_AXI_APROT (sr_awprot), .S_AXI_AREGION (sr_awregion), .S_AXI_AQOS (sr_awqos), .S_AXI_AVALID (sr_awvalid), .S_AXI_AREADY (sr_awready), // Master Interface Write Address Port .M_AXI_AADDR (m_axi_awaddr_i ), .M_AXI_ALEN (m_axi_awlen_i ), .M_AXI_ASIZE (m_axi_awsize_i ), .M_AXI_ABURST (m_axi_awburst_i ), .M_AXI_ALOCK (m_axi_awlock_i ), .M_AXI_ACACHE (m_axi_awcache_i ), .M_AXI_APROT (m_axi_awprot_i ), .M_AXI_AREGION (m_axi_awregion_i ), .M_AXI_AQOS (m_axi_awqos_i ), .M_AXI_AVALID (m_axi_awvalid_i ), .M_AXI_AREADY (m_axi_awready_i ) ); if ((C_FIFO_MODE == P_PKTFIFO) \|\| (C_FIFO_MODE == P_PKTFIFO_CLK)) begin : gen_pktfifo_w_upsizer // Packet FIFO Write Data channel. axi_dwidth_converter_v2_1_7_w_upsizer_pktfifo # ( .C_FAMILY (C_FAMILY), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG), .C_CLK_CONV (P_CLK_CONV), .C_S_AXI_ACLK_RATIO (C_S_AXI_ACLK_RATIO), .C_M_AXI_ACLK_RATIO (C_M_AXI_ACLK_RATIO), .C_AXI_IS_ACLK_ASYNC (C_AXI_IS_ACLK_ASYNC), .C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE) ) pktfifo_write_data_inst ( .S_AXI_ARESETN ( s_axi_aresetn ) , .S_AXI_ACLK ( s_axi_aclk ) , .M_AXI_ARESETN ( m_axi_aresetn ) , .M_AXI_ACLK ( m_axi_aclk ) , // Command Interface .cmd_si_addr (wr_cmd_si_addr ), .cmd_si_len (wr_cmd_si_len ), .cmd_si_size (wr_cmd_si_size ), .cmd_si_burst (wr_cmd_si_burst), .cmd_ready (wr_cmd_ready), // Slave Interface Write Address Ports .S_AXI_AWADDR (m_axi_awaddr_i ), .S_AXI_AWLEN (m_axi_awlen_i ), .S_AXI_AWSIZE (m_axi_awsize_i ), .S_AXI_AWBURST (m_axi_awburst_i ), .S_AXI_AWLOCK (m_axi_awlock_i ), .S_AXI_AWCACHE (m_axi_awcache_i ), .S_AXI_AWPROT (m_axi_awprot_i ), .S_AXI_AWREGION (m_axi_awregion_i ), .S_AXI_AWQOS (m_axi_awqos_i ), .S_AXI_AWVALID (m_axi_awvalid_i ), .S_AXI_AWREADY (m_axi_awready_i ), // Master Interface Write Address Port .M_AXI_AWADDR (m_axi_awaddr), .M_AXI_AWLEN (m_axi_awlen), .M_AXI_AWSIZE (m_axi_awsize), .M_AXI_AWBURST (m_axi_awburst), .M_AXI_AWLOCK (m_axi_awlock), .M_AXI_AWCACHE (m_axi_awcache), .M_AXI_AWPROT (m_axi_awprot), .M_AXI_AWREGION (m_axi_awregion), .M_AXI_AWQOS (m_axi_awqos), .M_AXI_AWVALID (m_axi_awvalid), .M_AXI_AWREADY (m_axi_awready), // Slave Interface Write Data Ports .S_AXI_WDATA (s_axi_wdata), .S_AXI_WSTRB (s_axi_wstrb), .S_AXI_WLAST (s_axi_wlast), .S_AXI_WVALID (s_axi_wvalid), .S_AXI_WREADY (s_axi_wready), // Master Interface Write Data Ports .M_AXI_WDATA (m_axi_wdata), .M_AXI_WSTRB (m_axi_wstrb), .M_AXI_WLAST (m_axi_wlast), .M_AXI_WVALID (m_axi_wvalid), .M_AXI_WREADY (m_axi_wready), .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early) ); end else begin : gen_non_fifo_w_upsizer // Write Data channel. axi_dwidth_converter_v2_1_7_w_upsizer # ( .C_FAMILY ("rtl"), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (1), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG) ) write_data_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (wr_cmd_valid), .cmd_fix (wr_cmd_fix), .cmd_modified (wr_cmd_modified), .cmd_complete_wrap (wr_cmd_complete_wrap), .cmd_packed_wrap (wr_cmd_packed_wrap), .cmd_first_word (wr_cmd_first_word), .cmd_next_word (wr_cmd_next_word), .cmd_last_word (wr_cmd_last_word), .cmd_offset (wr_cmd_offset), .cmd_mask (wr_cmd_mask), .cmd_step (wr_cmd_step), .cmd_length (wr_cmd_length), .cmd_ready (wr_cmd_ready), // Slave Interface Write Data Ports .S_AXI_WDATA (s_axi_wdata), .S_AXI_WSTRB (s_axi_wstrb), .S_AXI_WLAST (s_axi_wlast), .S_AXI_WVALID (s_axi_wvalid), .S_AXI_WREADY (s_axi_wready), // Master Interface Write Data Ports .M_AXI_WDATA (m_axi_wdata), .M_AXI_WSTRB (m_axi_wstrb), .M_AXI_WLAST (m_axi_wlast), .M_AXI_WVALID (m_axi_wvalid), .M_AXI_WREADY (m_axi_wready) ); assign m_axi_awaddr = m_axi_awaddr_i ; assign m_axi_awlen = m_axi_awlen_i ; assign m_axi_awsize = m_axi_awsize_i ; assign m_axi_awburst = m_axi_awburst_i ; assign m_axi_awlock = m_axi_awlock_i ; assign m_axi_awcache = m_axi_awcache_i ; assign m_axi_awprot = m_axi_awprot_i ; assign m_axi_awregion = m_axi_awregion_i ; assign m_axi_awqos = m_axi_awqos_i ; assign m_axi_awvalid = m_axi_awvalid_i ; assign m_axi_awready_i = m_axi_awready ; end // gen_w_upsizer // Write Response channel. assign wr_cmd_id_ready = s_axi_bvalid_i & s_axi_bready; assign s_axi_bid = wr_cmd_id; assign s_axi_bresp = s_axi_bresp_i; assign s_axi_bvalid = s_axi_bvalid_i; if (P_CLK_CONV) begin : gen_b_clk_conv if (C_AXI_IS_ACLK_ASYNC == 0) begin : gen_b_sync_conv axi_clock_converter_v2_1_6_axic_sync_clock_converter #( .C_FAMILY ( C_FAMILY ) , .C_PAYLOAD_WIDTH ( 2 ) , .C_M_ACLK_RATIO ( P_SI_LT_MI ? 1 : P_ACLK_RATIO ) , .C_S_ACLK_RATIO ( P_SI_LT_MI ? P_ACLK_RATIO : 1 ) , .C_MODE(P_CONV_LIGHT_WT) ) b_sync_clock_converter ( .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early), .S_ACLK ( m_axi_aclk ) , .S_ARESETN ( m_axi_aresetn ) , .S_PAYLOAD ( m_axi_bresp ) , .S_VALID ( m_axi_bvalid ) , .S_READY ( m_axi_bready ) , .M_ACLK ( s_axi_aclk ) , .M_ARESETN ( s_axi_aresetn ) , .M_PAYLOAD ( s_axi_bresp_i ) , .M_VALID ( s_axi_bvalid_i ) , .M_READY ( s_axi_bready ) ); end else begin : gen_b_async_conv fifo_generator_v13_0_1 #( .C_COMMON_CLOCK(0), .C_SYNCHRONIZER_STAGE(C_SYNCHRONIZER_STAGE), .C_INTERFACE_TYPE(2), .C_AXI_TYPE(1), .C_HAS_AXI_ID(1), .C_AXI_LEN_WIDTH(8), .C_AXI_LOCK_WIDTH(2), .C_DIN_WIDTH_WACH(63), .C_DIN_WIDTH_WDCH(38), .C_DIN_WIDTH_WRCH(3), .C_DIN_WIDTH_RACH(63), .C_DIN_WIDTH_RDCH(36), .C_COUNT_TYPE(0), .C_DATA_COUNT_WIDTH(10), .C_DEFAULT_VALUE("BlankString"), .C_DIN_WIDTH(18), .C_DOUT_RST_VAL("0"), .C_DOUT_WIDTH(18), .C_ENABLE_RLOCS(0), .C_FAMILY(C_FAMILY), .C_FULL_FLAGS_RST_VAL(1), .C_HAS_ALMOST_EMPTY(0), .C_HAS_ALMOST_FULL(0), .C_HAS_BACKUP(0), .C_HAS_DATA_COUNT(0), .C_HAS_INT_CLK(0), .C_HAS_MEMINIT_FILE(0), .C_HAS_OVERFLOW(0), .C_HAS_RD_DATA_COUNT(0), .C_HAS_RD_RST(0), .C_HAS_RST(1), .C_HAS_SRST(0), .C_HAS_UNDERFLOW(0), .C_HAS_VALID(0), .C_HAS_WR_ACK(0), .C_HAS_WR_DATA_COUNT(0), .C_HAS_WR_RST(0), .C_IMPLEMENTATION_TYPE(0), .C_INIT_WR_PNTR_VAL(0), .C_MEMORY_TYPE(1), .C_MIF_FILE_NAME("BlankString"), .C_OPTIMIZATION_MODE(0), .C_OVERFLOW_LOW(0), .C_PRELOAD_LATENCY(1), .C_PRELOAD_REGS(0), .C_PRIM_FIFO_TYPE("4kx4"), .C_PROG_EMPTY_THRESH_ASSERT_VAL(2), .C_PROG_EMPTY_THRESH_NEGATE_VAL(3), .C_PROG_EMPTY_TYPE(0), .C_PROG_FULL_THRESH_ASSERT_VAL(1022), .C_PROG_FULL_THRESH_NEGATE_VAL(1021), .C_PROG_FULL_TYPE(0), .C_RD_DATA_COUNT_WIDTH(10), .C_RD_DEPTH(1024), .C_RD_FREQ(1), .C_RD_PNTR_WIDTH(10), .C_UNDERFLOW_LOW(0), .C_USE_DOUT_RST(1), .C_USE_ECC(0), .C_USE_EMBEDDED_REG(0), .C_USE_FIFO16_FLAGS(0), .C_USE_FWFT_DATA_COUNT(0), .C_VALID_LOW(0), .C_WR_ACK_LOW(0), .C_WR_DATA_COUNT_WIDTH(10), .C_WR_DEPTH(1024), .C_WR_FREQ(1), .C_WR_PNTR_WIDTH(10), .C_WR_RESPONSE_LATENCY(1), .C_MSGON_VAL(1), .C_ENABLE_RST_SYNC(1), .C_ERROR_INJECTION_TYPE(0), .C_HAS_AXI_WR_CHANNEL(1), .C_HAS_AXI_RD_CHANNEL(0), .C_HAS_SLAVE_CE(0), .C_HAS_MASTER_CE(0), .C_ADD_NGC_CONSTRAINT(0), .C_USE_COMMON_OVERFLOW(0), .C_USE_COMMON_UNDERFLOW(0), .C_USE_DEFAULT_SETTINGS(0), .C_AXI_ID_WIDTH(1), .C_AXI_ADDR_WIDTH(32), .C_AXI_DATA_WIDTH(32), .C_HAS_AXI_AWUSER(0), .C_HAS_AXI_WUSER(0), .C_HAS_AXI_BUSER(0), .C_HAS_AXI_ARUSER(0), .C_HAS_AXI_RUSER(0), .C_AXI_ARUSER_WIDTH(1), .C_AXI_AWUSER_WIDTH(1), .C_AXI_WUSER_WIDTH(1), .C_AXI_BUSER_WIDTH(1), .C_AXI_RUSER_WIDTH(1), .C_HAS_AXIS_TDATA(0), .C_HAS_AXIS_TID(0), .C_HAS_AXIS_TDEST(0), .C_HAS_AXIS_TUSER(0), .C_HAS_AXIS_TREADY(1), .C_HAS_AXIS_TLAST(0), .C_HAS_AXIS_TSTRB(0), .C_HAS_AXIS_TKEEP(0), .C_AXIS_TDATA_WIDTH(64), .C_AXIS_TID_WIDTH(8), .C_AXIS_TDEST_WIDTH(4), .C_AXIS_TUSER_WIDTH(4), .C_AXIS_TSTRB_WIDTH(4), .C_AXIS_TKEEP_WIDTH(4), .C_WACH_TYPE(2), .C_WDCH_TYPE(2), .C_WRCH_TYPE(0), .C_RACH_TYPE(0), .C_RDCH_TYPE(0), .C_AXIS_TYPE(0), .C_IMPLEMENTATION_TYPE_WACH(12), .C_IMPLEMENTATION_TYPE_WDCH(11), .C_IMPLEMENTATION_TYPE_WRCH(12), .C_IMPLEMENTATION_TYPE_RACH(12), .C_IMPLEMENTATION_TYPE_RDCH(11), .C_IMPLEMENTATION_TYPE_AXIS(11), .C_APPLICATION_TYPE_WACH(0), .C_APPLICATION_TYPE_WDCH(0), .C_APPLICATION_TYPE_WRCH(0), .C_APPLICATION_TYPE_RACH(0), .C_APPLICATION_TYPE_RDCH(0), .C_APPLICATION_TYPE_AXIS(0), .C_USE_ECC_WACH(0), .C_USE_ECC_WDCH(0), .C_USE_ECC_WRCH(0), .C_USE_ECC_RACH(0), .C_USE_ECC_RDCH(0), .C_USE_ECC_AXIS(0), .C_ERROR_INJECTION_TYPE_WACH(0), .C_ERROR_INJECTION_TYPE_WDCH(0), .C_ERROR_INJECTION_TYPE_WRCH(0), .C_ERROR_INJECTION_TYPE_RACH(0), .C_ERROR_INJECTION_TYPE_RDCH(0), .C_ERROR_INJECTION_TYPE_AXIS(0), .C_DIN_WIDTH_AXIS(1), .C_WR_DEPTH_WACH(16), .C_WR_DEPTH_WDCH(1024), .C_WR_DEPTH_WRCH(32), .C_WR_DEPTH_RACH(16), .C_WR_DEPTH_RDCH(1024), .C_WR_DEPTH_AXIS(1024), .C_WR_PNTR_WIDTH_WACH(4), .C_WR_PNTR_WIDTH_WDCH(10), .C_WR_PNTR_WIDTH_WRCH(5), .C_WR_PNTR_WIDTH_RACH(4), .C_WR_PNTR_WIDTH_RDCH(10), .C_WR_PNTR_WIDTH_AXIS(10), .C_HAS_DATA_COUNTS_WACH(0), .C_HAS_DATA_COUNTS_WDCH(0), .C_HAS_DATA_COUNTS_WRCH(0), .C_HAS_DATA_COUNTS_RACH(0), .C_HAS_DATA_COUNTS_RDCH(0), .C_HAS_DATA_COUNTS_AXIS(0), .C_HAS_PROG_FLAGS_WACH(0), .C_HAS_PROG_FLAGS_WDCH(0), .C_HAS_PROG_FLAGS_WRCH(0), .C_HAS_PROG_FLAGS_RACH(0), .C_HAS_PROG_FLAGS_RDCH(0), .C_HAS_PROG_FLAGS_AXIS(0), .C_PROG_FULL_TYPE_WACH(0), .C_PROG_FULL_TYPE_WDCH(0), .C_PROG_FULL_TYPE_WRCH(0), .C_PROG_FULL_TYPE_RACH(0), .C_PROG_FULL_TYPE_RDCH(0), .C_PROG_FULL_TYPE_AXIS(0), .C_PROG_FULL_THRESH_ASSERT_VAL_WACH(15), .C_PROG_FULL_THRESH_ASSERT_VAL_WDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_WRCH(31), .C_PROG_FULL_THRESH_ASSERT_VAL_RACH(15), .C_PROG_FULL_THRESH_ASSERT_VAL_RDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_AXIS(1023), .C_PROG_EMPTY_TYPE_WACH(0), .C_PROG_EMPTY_TYPE_WDCH(0), .C_PROG_EMPTY_TYPE_WRCH(0), .C_PROG_EMPTY_TYPE_RACH(0), .C_PROG_EMPTY_TYPE_RDCH(0), .C_PROG_EMPTY_TYPE_AXIS(0), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH(13), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH(1021), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH(29), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH(13), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH(1021), .C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS(1021), .C_REG_SLICE_MODE_WACH(0), .C_REG_SLICE_MODE_WDCH(0), .C_REG_SLICE_MODE_WRCH(0), .C_REG_SLICE_MODE_RACH(0), .C_REG_SLICE_MODE_RDCH(0), .C_REG_SLICE_MODE_AXIS(0) ) dw_fifogen_b_async ( .m_aclk(m_axi_aclk), .s_aclk(s_axi_aclk), .s_aresetn(sm_aresetn), .s_axi_awid(1'b0), .s_axi_awaddr(32'b0), .s_axi_awlen(8'b0), .s_axi_awsize(3'b0), .s_axi_awburst(2'b0), .s_axi_awlock(2'b0), .s_axi_awcache(4'b0), .s_axi_awprot(3'b0), .s_axi_awqos(4'b0), .s_axi_awregion(4'b0), .s_axi_awuser(1'b0), .s_axi_awvalid(1'b0), .s_axi_awready(), .s_axi_wid(1'b0), .s_axi_wdata(32'b0), .s_axi_wstrb(4'b0), .s_axi_wlast(1'b0), .s_axi_wuser(1'b0), .s_axi_wvalid(1'b0), .s_axi_wready(), .s_axi_bid(), .s_axi_bresp(s_axi_bresp_i), .s_axi_buser(), .s_axi_bvalid(s_axi_bvalid_i), .s_axi_bready(s_axi_bready), .m_axi_awid(), .m_axi_awaddr(), .m_axi_awlen(), .m_axi_awsize(), .m_axi_awburst(), .m_axi_awlock(), .m_axi_awcache(), .m_axi_awprot(), .m_axi_awqos(), .m_axi_awregion(), .m_axi_awuser(), .m_axi_awvalid(), .m_axi_awready(1'b0), .m_axi_wid(), .m_axi_wdata(), .m_axi_wstrb(), .m_axi_wlast(), .m_axi_wuser(), .m_axi_wvalid(), .m_axi_wready(1'b0), .m_axi_bid(1'b0), .m_axi_bresp(m_axi_bresp), .m_axi_buser(1'b0), .m_axi_bvalid(m_axi_bvalid), .m_axi_bready(m_axi_bready), .s_axi_arid(1'b0), .s_axi_araddr(32'b0), .s_axi_arlen(8'b0), .s_axi_arsize(3'b0), .s_axi_arburst(2'b0), .s_axi_arlock(2'b0), .s_axi_arcache(4'b0), .s_axi_arprot(3'b0), .s_axi_arqos(4'b0), .s_axi_arregion(4'b0), .s_axi_aruser(1'b0), .s_axi_arvalid(1'b0), .s_axi_arready(), .s_axi_rid(), .s_axi_rdata(), .s_axi_rresp(), .s_axi_rlast(), .s_axi_ruser(), .s_axi_rvalid(), .s_axi_rready(1'b0), .m_axi_arid(), .m_axi_araddr(), .m_axi_arlen(), .m_axi_arsize(), .m_axi_arburst(), .m_axi_arlock(), .m_axi_arcache(), .m_axi_arprot(), .m_axi_arqos(), .m_axi_arregion(), .m_axi_aruser(), .m_axi_arvalid(), .m_axi_arready(1'b0), .m_axi_rid(1'b0), .m_axi_rdata(32'b0), .m_axi_rresp(2'b0), .m_axi_rlast(1'b0), .m_axi_ruser(1'b0), .m_axi_rvalid(1'b0), .m_axi_rready(), .m_aclk_en(1'b0), .s_aclk_en(1'b0), .backup(1'b0), .backup_marker(1'b0), .clk(1'b0), .rst(1'b0), .srst(1'b0), .wr_clk(1'b0), .wr_rst(1'b0), .rd_clk(1'b0), .rd_rst(1'b0), .din(18'b0), .wr_en(1'b0), .rd_en(1'b0), .prog_empty_thresh(10'b0), .prog_empty_thresh_assert(10'b0), .prog_empty_thresh_negate(10'b0), .prog_full_thresh(10'b0), .prog_full_thresh_assert(10'b0), .prog_full_thresh_negate(10'b0), .int_clk(1'b0), .injectdbiterr(1'b0), .injectsbiterr(1'b0), .dout(), .full(), .almost_full(), .wr_ack(), .overflow(), .empty(), .almost_empty(), .valid(), .underflow(), .data_count(), .rd_data_count(), .wr_data_count(), .prog_full(), .prog_empty(), .sbiterr(), .dbiterr(), .s_axis_tvalid(1'b0), .s_axis_tready(), .s_axis_tdata(64'b0), .s_axis_tstrb(4'b0), .s_axis_tkeep(4'b0), .s_axis_tlast(1'b0), .s_axis_tid(8'b0), .s_axis_tdest(4'b0), .s_axis_tuser(4'b0), .m_axis_tvalid(), .m_axis_tready(1'b0), .m_axis_tdata(), .m_axis_tstrb(), .m_axis_tkeep(), .m_axis_tlast(), .m_axis_tid(), .m_axis_tdest(), .m_axis_tuser(), .axi_aw_injectsbiterr(1'b0), .axi_aw_injectdbiterr(1'b0), .axi_aw_prog_full_thresh(4'b0), .axi_aw_prog_empty_thresh(4'b0), .axi_aw_data_count(), .axi_aw_wr_data_count(), .axi_aw_rd_data_count(), .axi_aw_sbiterr(), .axi_aw_dbiterr(), .axi_aw_overflow(), .axi_aw_underflow(), .axi_aw_prog_full(), .axi_aw_prog_empty(), .axi_w_injectsbiterr(1'b0), .axi_w_injectdbiterr(1'b0), .axi_w_prog_full_thresh(10'b0), .axi_w_prog_empty_thresh(10'b0), .axi_w_data_count(), .axi_w_wr_data_count(), .axi_w_rd_data_count(), .axi_w_sbiterr(), .axi_w_dbiterr(), .axi_w_overflow(), .axi_w_underflow(), .axi_b_injectsbiterr(1'b0), .axi_w_prog_full(), .axi_w_prog_empty(), .axi_b_injectdbiterr(1'b0), .axi_b_prog_full_thresh(5'b0), .axi_b_prog_empty_thresh(5'b0), .axi_b_data_count(), .axi_b_wr_data_count(), .axi_b_rd_data_count(), .axi_b_sbiterr(), .axi_b_dbiterr(), .axi_b_overflow(), .axi_b_underflow(), .axi_ar_injectsbiterr(1'b0), .axi_b_prog_full(), .axi_b_prog_empty(), .axi_ar_injectdbiterr(1'b0), .axi_ar_prog_full_thresh(4'b0), .axi_ar_prog_empty_thresh(4'b0), .axi_ar_data_count(), .axi_ar_wr_data_count(), .axi_ar_rd_data_count(), .axi_ar_sbiterr(), .axi_ar_dbiterr(), .axi_ar_overflow(), .axi_ar_underflow(), .axi_ar_prog_full(), .axi_ar_prog_empty(), .axi_r_injectsbiterr(1'b0), .axi_r_injectdbiterr(1'b0), .axi_r_prog_full_thresh(10'b0), .axi_r_prog_empty_thresh(10'b0), .axi_r_data_count(), .axi_r_wr_data_count(), .axi_r_rd_data_count(), .axi_r_sbiterr(), .axi_r_dbiterr(), .axi_r_overflow(), .axi_r_underflow(), .axis_injectsbiterr(1'b0), .axi_r_prog_full(), .axi_r_prog_empty(), .axis_injectdbiterr(1'b0), .axis_prog_full_thresh(10'b0), .axis_prog_empty_thresh(10'b0), .axis_data_count(), .axis_wr_data_count(), .axis_rd_data_count(), .axis_sbiterr(), .axis_dbiterr(), .axis_overflow(), .axis_underflow(), .axis_prog_full(), .axis_prog_empty(), .wr_rst_busy(), .rd_rst_busy(), .sleep(1'b0) ); end end else begin : gen_b_passthru assign m_axi_bready = s_axi_bready; assign s_axi_bresp_i = m_axi_bresp; assign s_axi_bvalid_i = m_axi_bvalid; end // gen_b end else begin : NO_WRITE assign sr_awready = 1'b0; assign s_axi_wready = 1'b0; assign s_axi_bid = {C_S_AXI_ID_WIDTH{1'b0}}; assign s_axi_bresp = 2'b0; assign s_axi_bvalid = 1'b0; assign m_axi_awaddr = {C_AXI_ADDR_WIDTH{1'b0}}; assign m_axi_awlen = 8'b0; assign m_axi_awsize = 3'b0; assign m_axi_awburst = 2'b0; assign m_axi_awlock = 2'b0; assign m_axi_awcache = 4'b0; assign m_axi_awprot = 3'b0; assign m_axi_awregion = 4'b0; assign m_axi_awqos = 4'b0; assign m_axi_awvalid = 1'b0; assign m_axi_wdata = {C_M_AXI_DATA_WIDTH{1'b0}}; assign m_axi_wstrb = {C_M_AXI_DATA_WIDTH/8{1'b0}}; assign m_axi_wlast = 1'b0; assign m_axi_wvalid = 1'b0; assign m_axi_bready = 1'b0; end endgenerate ///////////////////////////////////////////////////////////////////////////// // Handle Read Channels (AR/R) ///////////////////////////////////////////////////////////////////////////// generate if (C_AXI_SUPPORTS_READ == 1) begin : USE_READ wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr_i ; wire [8-1:0] m_axi_arlen_i ; wire [3-1:0] m_axi_arsize_i ; wire [2-1:0] m_axi_arburst_i ; wire [2-1:0] m_axi_arlock_i ; wire [4-1:0] m_axi_arcache_i ; wire [3-1:0] m_axi_arprot_i ; wire [4-1:0] m_axi_arregion_i ; wire [4-1:0] m_axi_arqos_i ; wire m_axi_arvalid_i ; wire m_axi_arready_i ; // Read Channel Signals for Commands Queue Interface. wire rd_cmd_valid; wire rd_cmd_fix; wire rd_cmd_modified; wire rd_cmd_complete_wrap; wire rd_cmd_packed_wrap; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_first_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_next_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_last_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_offset; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_mask; wire [C_S_AXI_BYTES_LOG:0] rd_cmd_step; wire [8-1:0] rd_cmd_length; wire rd_cmd_ready; wire [C_S_AXI_ID_WIDTH-1:0] rd_cmd_id; wire [C_AXI_ADDR_WIDTH-1:0] rd_cmd_si_addr; wire [C_S_AXI_ID_WIDTH-1:0] rd_cmd_si_id; wire [8-1:0] rd_cmd_si_len; wire [3-1:0] rd_cmd_si_size; wire [2-1:0] rd_cmd_si_burst; // Read Address Channel. axi_dwidth_converter_v2_1_7_a_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_SUPPORTS_ID (C_SUPPORTS_ID), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (C_M_AXI_AR_REGISTER), .C_AXI_CHANNEL (1), .C_PACKING_LEVEL (C_PACKING_LEVEL), // .C_FIFO_MODE (0), .C_FIFO_MODE (C_FIFO_MODE), .C_ID_QUEUE (P_RID_QUEUE), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG) ) read_addr_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (rd_cmd_valid), .cmd_fix (rd_cmd_fix), .cmd_modified (rd_cmd_modified), .cmd_complete_wrap (rd_cmd_complete_wrap), .cmd_packed_wrap (rd_cmd_packed_wrap), .cmd_first_word (rd_cmd_first_word), .cmd_next_word (rd_cmd_next_word), .cmd_last_word (rd_cmd_last_word), .cmd_offset (rd_cmd_offset), .cmd_mask (rd_cmd_mask), .cmd_step (rd_cmd_step), .cmd_length (rd_cmd_length), .cmd_ready (rd_cmd_ready), .cmd_id_ready (rd_cmd_ready), .cmd_id (rd_cmd_id), .cmd_si_addr (rd_cmd_si_addr ), .cmd_si_id (rd_cmd_si_id ), .cmd_si_len (rd_cmd_si_len ), .cmd_si_size (rd_cmd_si_size ), .cmd_si_burst (rd_cmd_si_burst), // Slave Interface Write Address Ports .S_AXI_AID (sr_arid), .S_AXI_AADDR (sr_araddr), .S_AXI_ALEN (sr_arlen), .S_AXI_ASIZE (sr_arsize), .S_AXI_ABURST (sr_arburst), .S_AXI_ALOCK (sr_arlock), .S_AXI_ACACHE (sr_arcache), .S_AXI_APROT (sr_arprot), .S_AXI_AREGION (sr_arregion), .S_AXI_AQOS (sr_arqos), .S_AXI_AVALID (sr_arvalid), .S_AXI_AREADY (sr_arready), // Master Interface Write Address Port .M_AXI_AADDR (m_axi_araddr_i ), .M_AXI_ALEN (m_axi_arlen_i ), .M_AXI_ASIZE (m_axi_arsize_i ), .M_AXI_ABURST (m_axi_arburst_i ), .M_AXI_ALOCK (m_axi_arlock_i ), .M_AXI_ACACHE (m_axi_arcache_i ), .M_AXI_APROT (m_axi_arprot_i ), .M_AXI_AREGION (m_axi_arregion_i ), .M_AXI_AQOS (m_axi_arqos_i ), .M_AXI_AVALID (m_axi_arvalid_i ), .M_AXI_AREADY (m_axi_arready_i ) ); if ((C_FIFO_MODE == P_PKTFIFO) \|\| (C_FIFO_MODE == P_PKTFIFO_CLK)) begin : gen_pktfifo_r_upsizer // Packet FIFO Read Data channel. axi_dwidth_converter_v2_1_7_r_upsizer_pktfifo # ( .C_FAMILY (C_FAMILY), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG), .C_CLK_CONV (P_CLK_CONV), .C_S_AXI_ACLK_RATIO (C_S_AXI_ACLK_RATIO), .C_M_AXI_ACLK_RATIO (C_M_AXI_ACLK_RATIO), .C_AXI_IS_ACLK_ASYNC (C_AXI_IS_ACLK_ASYNC), .C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE) ) pktfifo_read_data_inst ( .S_AXI_ARESETN ( s_axi_aresetn ) , .S_AXI_ACLK ( s_axi_aclk ) , .M_AXI_ARESETN ( m_axi_aresetn ) , .M_AXI_ACLK ( m_axi_aclk ) , // Command Interface .cmd_si_addr (rd_cmd_si_addr ), .cmd_si_id (rd_cmd_si_id ), .cmd_si_len (rd_cmd_si_len ), .cmd_si_size (rd_cmd_si_size ), .cmd_si_burst (rd_cmd_si_burst), .cmd_ready (rd_cmd_ready), // Slave Interface Write Address Ports .S_AXI_ARADDR (m_axi_araddr_i ), .S_AXI_ARLEN (m_axi_arlen_i ), .S_AXI_ARSIZE (m_axi_arsize_i ), .S_AXI_ARBURST (m_axi_arburst_i ), .S_AXI_ARLOCK (m_axi_arlock_i ), .S_AXI_ARCACHE (m_axi_arcache_i ), .S_AXI_ARPROT (m_axi_arprot_i ), .S_AXI_ARREGION (m_axi_arregion_i ), .S_AXI_ARQOS (m_axi_arqos_i ), .S_AXI_ARVALID (m_axi_arvalid_i ), .S_AXI_ARREADY (m_axi_arready_i ), // Master Interface Write Address Port .M_AXI_ARADDR (m_axi_araddr), .M_AXI_ARLEN (m_axi_arlen), .M_AXI_ARSIZE (m_axi_arsize), .M_AXI_ARBURST (m_axi_arburst), .M_AXI_ARLOCK (m_axi_arlock), .M_AXI_ARCACHE (m_axi_arcache), .M_AXI_ARPROT (m_axi_arprot), .M_AXI_ARREGION (m_axi_arregion), .M_AXI_ARQOS (m_axi_arqos), .M_AXI_ARVALID (m_axi_arvalid), .M_AXI_ARREADY (m_axi_arready), // Slave Interface Write Data Ports .S_AXI_RID (s_axi_rid), .S_AXI_RDATA (s_axi_rdata), .S_AXI_RRESP (s_axi_rresp), .S_AXI_RLAST (s_axi_rlast), .S_AXI_RVALID (s_axi_rvalid), .S_AXI_RREADY (s_axi_rready), // Master Interface Write Data Ports .M_AXI_RDATA (m_axi_rdata), .M_AXI_RRESP (m_axi_rresp), .M_AXI_RLAST (m_axi_rlast), .M_AXI_RVALID (m_axi_rvalid), .M_AXI_RREADY (m_axi_rready), .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early) ); end else begin : gen_non_fifo_r_upsizer // Read Data channel. axi_dwidth_converter_v2_1_7_r_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_S_AXI_REGISTER (C_S_AXI_R_REGISTER), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG) ) read_data_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (rd_cmd_valid), .cmd_fix (rd_cmd_fix), .cmd_modified (rd_cmd_modified), .cmd_complete_wrap (rd_cmd_complete_wrap), .cmd_packed_wrap (rd_cmd_packed_wrap), .cmd_first_word (rd_cmd_first_word), .cmd_next_word (rd_cmd_next_word), .cmd_last_word (rd_cmd_last_word), .cmd_offset (rd_cmd_offset), .cmd_mask (rd_cmd_mask), .cmd_step (rd_cmd_step), .cmd_length (rd_cmd_length), .cmd_ready (rd_cmd_ready), .cmd_id (rd_cmd_id), // Slave Interface Read Data Ports .S_AXI_RID (s_axi_rid), .S_AXI_RDATA (s_axi_rdata), .S_AXI_RRESP (s_axi_rresp), .S_AXI_RLAST (s_axi_rlast), .S_AXI_RVALID (s_axi_rvalid), .S_AXI_RREADY (s_axi_rready), // Master Interface Read Data Ports .M_AXI_RDATA (mr_rdata), .M_AXI_RRESP (mr_rresp), .M_AXI_RLAST (mr_rlast), .M_AXI_RVALID (mr_rvalid), .M_AXI_RREADY (mr_rready) ); axi_register_slice_v2_1_7_axi_register_slice # ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL (0), .C_AXI_ID_WIDTH (1), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (0), .C_REG_CONFIG_R (C_M_AXI_R_REGISTER) ) mi_register_slice_inst ( .aresetn (s_aresetn_i), .aclk (m_aclk), .s_axi_awid ( 1'b0 ), .s_axi_awaddr ( {C_AXI_ADDR_WIDTH{1'b0}} ), .s_axi_awlen ( 8'b0 ), .s_axi_awsize ( 3'b0 ), .s_axi_awburst ( 2'b0 ), .s_axi_awlock ( 1'b0 ), .s_axi_awcache ( 4'b0 ), .s_axi_awprot ( 3'b0 ), .s_axi_awregion ( 4'b0 ), .s_axi_awqos ( 4'b0 ), .s_axi_awuser ( 1'b0 ), .s_axi_awvalid ( 1'b0 ), .s_axi_awready ( ), .s_axi_wid ( 1'b0 ), .s_axi_wdata ( {C_M_AXI_DATA_WIDTH{1'b0}} ), .s_axi_wstrb ( {C_M_AXI_DATA_WIDTH/8{1'b0}} ), .s_axi_wlast ( 1'b0 ), .s_axi_wuser ( 1'b0 ), .s_axi_wvalid ( 1'b0 ), .s_axi_wready ( ), .s_axi_bid ( ), .s_axi_bresp ( ), .s_axi_buser ( ), .s_axi_bvalid ( ), .s_axi_bready ( 1'b0 ), .s_axi_arid ( 1'b0 ), .s_axi_araddr ( {C_AXI_ADDR_WIDTH{1'b0}} ), .s_axi_arlen ( 8'b0 ), .s_axi_arsize ( 3'b0 ), .s_axi_arburst ( 2'b0 ), .s_axi_arlock ( 1'b0 ), .s_axi_arcache ( 4'b0 ), .s_axi_arprot ( 3'b0 ), .s_axi_arregion ( 4'b0 ), .s_axi_arqos ( 4'b0 ), .s_axi_aruser ( 1'b0 ), .s_axi_arvalid ( 1'b0 ), .s_axi_arready ( ), .s_axi_rid (), .s_axi_rdata (mr_rdata ), .s_axi_rresp (mr_rresp ), .s_axi_rlast (mr_rlast ), .s_axi_ruser (), .s_axi_rvalid (mr_rvalid ), .s_axi_rready (mr_rready ), .m_axi_awid (), .m_axi_awaddr (), .m_axi_awlen (), .m_axi_awsize (), .m_axi_awburst (), .m_axi_awlock (), .m_axi_awcache (), .m_axi_awprot (), .m_axi_awregion (), .m_axi_awqos (), .m_axi_awuser (), .m_axi_awvalid (), .m_axi_awready (1'b0), .m_axi_wid () , .m_axi_wdata (), .m_axi_wstrb (), .m_axi_wlast (), .m_axi_wuser (), .m_axi_wvalid (), .m_axi_wready (1'b0), .m_axi_bid ( 1'b0 ) , .m_axi_bresp ( 2'b0 ) , .m_axi_buser ( 1'b0 ) , .m_axi_bvalid ( 1'b0 ) , .m_axi_bready ( ) , .m_axi_arid (), .m_axi_araddr (), .m_axi_arlen (), .m_axi_arsize (), .m_axi_arburst (), .m_axi_arlock (), .m_axi_arcache (), .m_axi_arprot (), .m_axi_arregion (), .m_axi_arqos (), .m_axi_aruser (), .m_axi_arvalid (), .m_axi_arready (1'b0), .m_axi_rid (1'b0 ), .m_axi_rdata (m_axi_rdata ), .m_axi_rresp (m_axi_rresp ), .m_axi_rlast (m_axi_rlast ), .m_axi_ruser (1'b0 ), .m_axi_rvalid (m_axi_rvalid ), .m_axi_rready (m_axi_rready_i ) ); assign m_axi_araddr = m_axi_araddr_i ; assign m_axi_arlen = m_axi_arlen_i ; assign m_axi_arsize = m_axi_arsize_i ; assign m_axi_arburst = m_axi_arburst_i ; assign m_axi_arlock = m_axi_arlock_i ; assign m_axi_arcache = m_axi_arcache_i ; assign m_axi_arprot = m_axi_arprot_i ; assign m_axi_arregion = m_axi_arregion_i ; assign m_axi_arqos = m_axi_arqos_i ; assign m_axi_arvalid = m_axi_arvalid_i ; assign m_axi_arready_i = m_axi_arready ; assign m_axi_rready = m_axi_rready_i; end // gen_r_upsizer end else begin : NO_READ assign sr_arready = 1'b0; assign s_axi_rid = {C_S_AXI_ID_WIDTH{1'b0}}; assign s_axi_rdata = {C_S_AXI_DATA_WIDTH{1'b0}}; assign s_axi_rresp = 2'b0; assign s_axi_rlast = 1'b0; assign s_axi_rvalid = 1'b0; assign m_axi_araddr = {C_AXI_ADDR_WIDTH{1'b0}}; assign m_axi_arlen = 8'b0; assign m_axi_arsize = 3'b0; assign m_axi_arburst = 2'b0; assign m_axi_arlock = 2'b0; assign m_axi_arcache = 4'b0; assign m_axi_arprot = 3'b0; assign m_axi_arregion = 4'b0; assign m_axi_arqos = 4'b0; assign m_axi_arvalid = 1'b0; assign mr_rready = 1'b0; end endgenerate endmodule `default_nettype wire
// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Generic single-channel AXI FIFO // Synchronous FIFO is implemented using either LUTs (SRL) or BRAM. // Transfers received on the AXI slave port are pushed onto the FIFO. // FIFO output, when available, is presented on the AXI master port and // popped when the master port responds (M_READY). // // Verilog-standard: Verilog 2001 //-------------------------------------------------------------------------- // Structure: // axic_fifo // fifo_gen //-------------------------------------------------------------------------- `timescale 1ps/1ps (* DowngradeIPIdentifiedWarnings="yes" ) module axi_data_fifo_v2_1_12_axic_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2C_FIFO_DEPTH_LOG // Range = [5:9] when TYPE="lut", // Range = [5:12] when TYPE="bram", parameter integer C_FIFO_WIDTH = 64, // Width of payload [1:512] parameter C_FIFO_TYPE = "lut" // "lut" = LUT (SRL) based, // "bram" = BRAM based ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); axi_data_fifo_v2_1_12_fifo_gen #( .C_FAMILY(C_FAMILY), .C_COMMON_CLOCK(1), .C_FIFO_DEPTH_LOG(C_FIFO_DEPTH_LOG), .C_FIFO_WIDTH(C_FIFO_WIDTH), .C_FIFO_TYPE(C_FIFO_TYPE)) inst ( .clk(ACLK), .rst(ARESET), .wr_clk(1'b0), .wr_en(S_VALID), .wr_ready(S_READY), .wr_data(S_MESG), .rd_clk(1'b0), .rd_en(M_READY), .rd_valid(M_VALID), .rd_data(M_MESG)); endmodule // -- (c) Copyright 1995 - 2012 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------- // The synthesis directives "translate_off/translate_on" specified below are // supported by Xilinx, Mentor Graphics and Synplicity synthesis // tools. Ensure they are correct for your synthesis tool(s). // You must compile the fifo_generator wrapper file when simulating // the core. When compiling the wrapper file, be sure to // reference the XilinxCoreLib Verilog simulation library. For detailed // instructions, please refer to the "CORE Generator Help". `timescale 1ps/1ps ( DowngradeIPIdentifiedWarnings="yes" ) module axi_data_fifo_v2_1_12_fifo_gen #( parameter C_FAMILY = "virtex7", parameter integer C_COMMON_CLOCK = 1, parameter integer C_SYNCHRONIZER_STAGE = 3, parameter integer C_FIFO_DEPTH_LOG = 5, parameter integer C_FIFO_WIDTH = 64, parameter C_FIFO_TYPE = "lut" )( clk, rst, wr_clk, wr_en, wr_ready, wr_data, rd_clk, rd_en, rd_valid, rd_data); input clk; input wr_clk; input rd_clk; input rst; input [C_FIFO_WIDTH-1 : 0] wr_data; input wr_en; input rd_en; output [C_FIFO_WIDTH-1 : 0] rd_data; output wr_ready; output rd_valid; wire full; wire empty; wire rd_valid = ~empty; wire wr_ready = ~full; localparam C_MEMORY_TYPE = (C_FIFO_TYPE == "bram")? 1 : 2; localparam C_IMPLEMENTATION_TYPE = (C_COMMON_CLOCK == 1)? 0 : 2; fifo_generator_v13_1_4 #( .C_COMMON_CLOCK(C_COMMON_CLOCK), .C_DIN_WIDTH(C_FIFO_WIDTH), .C_DOUT_WIDTH(C_FIFO_WIDTH), .C_FAMILY(C_FAMILY), .C_IMPLEMENTATION_TYPE(C_IMPLEMENTATION_TYPE), .C_MEMORY_TYPE(C_MEMORY_TYPE), .C_RD_DEPTH(1<<C_FIFO_DEPTH_LOG), .C_RD_PNTR_WIDTH(C_FIFO_DEPTH_LOG), .C_WR_DEPTH(1<<C_FIFO_DEPTH_LOG), .C_WR_PNTR_WIDTH(C_FIFO_DEPTH_LOG), .C_ADD_NGC_CONSTRAINT(0), .C_APPLICATION_TYPE_AXIS(0), .C_APPLICATION_TYPE_RACH(0), .C_APPLICATION_TYPE_RDCH(0), .C_APPLICATION_TYPE_WACH(0), .C_APPLICATION_TYPE_WDCH(0), .C_APPLICATION_TYPE_WRCH(0), .C_AXIS_TDATA_WIDTH(64), .C_AXIS_TDEST_WIDTH(4), .C_AXIS_TID_WIDTH(8), .C_AXIS_TKEEP_WIDTH(4), .C_AXIS_TSTRB_WIDTH(4), .C_AXIS_TUSER_WIDTH(4), .C_AXIS_TYPE(0), .C_AXI_ADDR_WIDTH(32), .C_AXI_ARUSER_WIDTH(1), .C_AXI_AWUSER_WIDTH(1), .C_AXI_BUSER_WIDTH(1), .C_AXI_DATA_WIDTH(64), .C_AXI_ID_WIDTH(4), .C_AXI_LEN_WIDTH(8), .C_AXI_LOCK_WIDTH(2), .C_AXI_RUSER_WIDTH(1), .C_AXI_TYPE(0), .C_AXI_WUSER_WIDTH(1), .C_COUNT_TYPE(0), .C_DATA_COUNT_WIDTH(6), .C_DEFAULT_VALUE("BlankString"), .C_DIN_WIDTH_AXIS(1), .C_DIN_WIDTH_RACH(32), .C_DIN_WIDTH_RDCH(64), .C_DIN_WIDTH_WACH(32), .C_DIN_WIDTH_WDCH(64), .C_DIN_WIDTH_WRCH(2), .C_DOUT_RST_VAL("0"), .C_ENABLE_RLOCS(0), .C_ENABLE_RST_SYNC(1), .C_ERROR_INJECTION_TYPE(0), .C_ERROR_INJECTION_TYPE_AXIS(0), .C_ERROR_INJECTION_TYPE_RACH(0), .C_ERROR_INJECTION_TYPE_RDCH(0), .C_ERROR_INJECTION_TYPE_WACH(0), .C_ERROR_INJECTION_TYPE_WDCH(0), .C_ERROR_INJECTION_TYPE_WRCH(0), .C_FULL_FLAGS_RST_VAL(0), .C_HAS_ALMOST_EMPTY(0), .C_HAS_ALMOST_FULL(0), .C_HAS_AXIS_TDATA(0), .C_HAS_AXIS_TDEST(0), .C_HAS_AXIS_TID(0), .C_HAS_AXIS_TKEEP(0), .C_HAS_AXIS_TLAST(0), .C_HAS_AXIS_TREADY(1), .C_HAS_AXIS_TSTRB(0), .C_HAS_AXIS_TUSER(0), .C_HAS_AXI_ARUSER(0), .C_HAS_AXI_AWUSER(0), .C_HAS_AXI_BUSER(0), .C_HAS_AXI_RD_CHANNEL(0), .C_HAS_AXI_RUSER(0), .C_HAS_AXI_WR_CHANNEL(0), .C_HAS_AXI_WUSER(0), .C_HAS_BACKUP(0), .C_HAS_DATA_COUNT(0), .C_HAS_DATA_COUNTS_AXIS(0), .C_HAS_DATA_COUNTS_RACH(0), .C_HAS_DATA_COUNTS_RDCH(0), .C_HAS_DATA_COUNTS_WACH(0), .C_HAS_DATA_COUNTS_WDCH(0), .C_HAS_DATA_COUNTS_WRCH(0), .C_HAS_INT_CLK(0), .C_HAS_MASTER_CE(0), .C_HAS_MEMINIT_FILE(0), .C_HAS_OVERFLOW(0), .C_HAS_PROG_FLAGS_AXIS(0), .C_HAS_PROG_FLAGS_RACH(0), .C_HAS_PROG_FLAGS_RDCH(0), .C_HAS_PROG_FLAGS_WACH(0), .C_HAS_PROG_FLAGS_WDCH(0), .C_HAS_PROG_FLAGS_WRCH(0), .C_HAS_RD_DATA_COUNT(0), .C_HAS_RD_RST(0), .C_HAS_RST(1), .C_HAS_SLAVE_CE(0), .C_HAS_SRST(0), .C_HAS_UNDERFLOW(0), .C_HAS_VALID(0), .C_HAS_WR_ACK(0), .C_HAS_WR_DATA_COUNT(0), .C_HAS_WR_RST(0), .C_IMPLEMENTATION_TYPE_AXIS(1), .C_IMPLEMENTATION_TYPE_RACH(1), .C_IMPLEMENTATION_TYPE_RDCH(1), .C_IMPLEMENTATION_TYPE_WACH(1), .C_IMPLEMENTATION_TYPE_WDCH(1), .C_IMPLEMENTATION_TYPE_WRCH(1), .C_INIT_WR_PNTR_VAL(0), .C_INTERFACE_TYPE(0), .C_MIF_FILE_NAME("BlankString"), .C_MSGON_VAL(1), .C_OPTIMIZATION_MODE(0), .C_OVERFLOW_LOW(0), .C_PRELOAD_LATENCY(0), .C_PRELOAD_REGS(1), .C_PRIM_FIFO_TYPE("512x36"), .C_PROG_EMPTY_THRESH_ASSERT_VAL(4), .C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH(1022), .C_PROG_EMPTY_THRESH_NEGATE_VAL(5), .C_PROG_EMPTY_TYPE(0), .C_PROG_EMPTY_TYPE_AXIS(0), .C_PROG_EMPTY_TYPE_RACH(0), .C_PROG_EMPTY_TYPE_RDCH(0), .C_PROG_EMPTY_TYPE_WACH(0), .C_PROG_EMPTY_TYPE_WDCH(0), .C_PROG_EMPTY_TYPE_WRCH(0), .C_PROG_FULL_THRESH_ASSERT_VAL(31), .C_PROG_FULL_THRESH_ASSERT_VAL_AXIS(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_RACH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_RDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_WACH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_WDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_WRCH(1023), .C_PROG_FULL_THRESH_NEGATE_VAL(30), .C_PROG_FULL_TYPE(0), .C_PROG_FULL_TYPE_AXIS(0), .C_PROG_FULL_TYPE_RACH(0), .C_PROG_FULL_TYPE_RDCH(0), .C_PROG_FULL_TYPE_WACH(0), .C_PROG_FULL_TYPE_WDCH(0), .C_PROG_FULL_TYPE_WRCH(0), .C_RACH_TYPE(0), .C_RDCH_TYPE(0), .C_RD_DATA_COUNT_WIDTH(6), .C_RD_FREQ(1), .C_REG_SLICE_MODE_AXIS(0), .C_REG_SLICE_MODE_RACH(0), .C_REG_SLICE_MODE_RDCH(0), .C_REG_SLICE_MODE_WACH(0), .C_REG_SLICE_MODE_WDCH(0), .C_REG_SLICE_MODE_WRCH(0), .C_SYNCHRONIZER_STAGE(C_SYNCHRONIZER_STAGE), .C_UNDERFLOW_LOW(0), .C_USE_COMMON_OVERFLOW(0), .C_USE_COMMON_UNDERFLOW(0), .C_USE_DEFAULT_SETTINGS(0), .C_USE_DOUT_RST(0), .C_USE_ECC(0), .C_USE_ECC_AXIS(0), .C_USE_ECC_RACH(0), .C_USE_ECC_RDCH(0), .C_USE_ECC_WACH(0), .C_USE_ECC_WDCH(0), .C_USE_ECC_WRCH(0), .C_USE_EMBEDDED_REG(0), .C_USE_FIFO16_FLAGS(0), .C_USE_FWFT_DATA_COUNT(1), .C_VALID_LOW(0), .C_WACH_TYPE(0), .C_WDCH_TYPE(0), .C_WRCH_TYPE(0), .C_WR_ACK_LOW(0), .C_WR_DATA_COUNT_WIDTH(6), .C_WR_DEPTH_AXIS(1024), .C_WR_DEPTH_RACH(16), .C_WR_DEPTH_RDCH(1024), .C_WR_DEPTH_WACH(16), .C_WR_DEPTH_WDCH(1024), .C_WR_DEPTH_WRCH(16), .C_WR_FREQ(1), .C_WR_PNTR_WIDTH_AXIS(10), .C_WR_PNTR_WIDTH_RACH(4), .C_WR_PNTR_WIDTH_RDCH(10), .C_WR_PNTR_WIDTH_WACH(4), .C_WR_PNTR_WIDTH_WDCH(10), .C_WR_PNTR_WIDTH_WRCH(4), .C_WR_RESPONSE_LATENCY(1) ) fifo_gen_inst ( .clk(clk), .din(wr_data), .dout(rd_data), .empty(empty), .full(full), .rd_clk(rd_clk), .rd_en(rd_en), .rst(rst), .wr_clk(wr_clk), .wr_en(wr_en), .almost_empty(), .almost_full(), .axi_ar_data_count(), .axi_ar_dbiterr(), .axi_ar_injectdbiterr(1'b0), .axi_ar_injectsbiterr(1'b0), .axi_ar_overflow(), .axi_ar_prog_empty(), .axi_ar_prog_empty_thresh(4'b0), .axi_ar_prog_full(), .axi_ar_prog_full_thresh(4'b0), .axi_ar_rd_data_count(), .axi_ar_sbiterr(), .axi_ar_underflow(), .axi_ar_wr_data_count(), .axi_aw_data_count(), .axi_aw_dbiterr(), .axi_aw_injectdbiterr(1'b0), .axi_aw_injectsbiterr(1'b0), .axi_aw_overflow(), .axi_aw_prog_empty(), .axi_aw_prog_empty_thresh(4'b0), .axi_aw_prog_full(), .axi_aw_prog_full_thresh(4'b0), .axi_aw_rd_data_count(), .axi_aw_sbiterr(), .axi_aw_underflow(), .axi_aw_wr_data_count(), .axi_b_data_count(), .axi_b_dbiterr(), .axi_b_injectdbiterr(1'b0), .axi_b_injectsbiterr(1'b0), .axi_b_overflow(), .axi_b_prog_empty(), .axi_b_prog_empty_thresh(4'b0), .axi_b_prog_full(), .axi_b_prog_full_thresh(4'b0), .axi_b_rd_data_count(), .axi_b_sbiterr(), .axi_b_underflow(), .axi_b_wr_data_count(), .axi_r_data_count(), .axi_r_dbiterr(), .axi_r_injectdbiterr(1'b0), .axi_r_injectsbiterr(1'b0), .axi_r_overflow(), .axi_r_prog_empty(), .axi_r_prog_empty_thresh(10'b0), .axi_r_prog_full(), .axi_r_prog_full_thresh(10'b0), .axi_r_rd_data_count(), .axi_r_sbiterr(), .axi_r_underflow(), .axi_r_wr_data_count(), .axi_w_data_count(), .axi_w_dbiterr(), .axi_w_injectdbiterr(1'b0), .axi_w_injectsbiterr(1'b0), .axi_w_overflow(), .axi_w_prog_empty(), .axi_w_prog_empty_thresh(10'b0), .axi_w_prog_full(), .axi_w_prog_full_thresh(10'b0), .axi_w_rd_data_count(), .axi_w_sbiterr(), .axi_w_underflow(), .axi_w_wr_data_count(), .axis_data_count(), .axis_dbiterr(), .axis_injectdbiterr(1'b0), .axis_injectsbiterr(1'b0), .axis_overflow(), .axis_prog_empty(), .axis_prog_empty_thresh(10'b0), .axis_prog_full(), .axis_prog_full_thresh(10'b0), .axis_rd_data_count(), .axis_sbiterr(), .axis_underflow(), .axis_wr_data_count(), .backup(1'b0), .backup_marker(1'b0), .data_count(), .dbiterr(), .injectdbiterr(1'b0), .injectsbiterr(1'b0), .int_clk(1'b0), .m_aclk(1'b0), .m_aclk_en(1'b0), .m_axi_araddr(), .m_axi_arburst(), .m_axi_arcache(), .m_axi_arid(), .m_axi_arlen(), .m_axi_arlock(), .m_axi_arprot(), .m_axi_arqos(), .m_axi_arready(1'b0), .m_axi_arregion(), .m_axi_arsize(), .m_axi_aruser(), .m_axi_arvalid(), .m_axi_awaddr(), .m_axi_awburst(), .m_axi_awcache(), .m_axi_awid(), .m_axi_awlen(), .m_axi_awlock(), .m_axi_awprot(), .m_axi_awqos(), .m_axi_awready(1'b0), .m_axi_awregion(), .m_axi_awsize(), .m_axi_awuser(), .m_axi_awvalid(), .m_axi_bid(4'b0), .m_axi_bready(), .m_axi_bresp(2'b0), .m_axi_buser(1'b0), .m_axi_bvalid(1'b0), .m_axi_rdata(64'b0), .m_axi_rid(4'b0), .m_axi_rlast(1'b0), .m_axi_rready(), .m_axi_rresp(2'b0), .m_axi_ruser(1'b0), .m_axi_rvalid(1'b0), .m_axi_wdata(), .m_axi_wid(), .m_axi_wlast(), .m_axi_wready(1'b0), .m_axi_wstrb(), .m_axi_wuser(), .m_axi_wvalid(), .m_axis_tdata(), .m_axis_tdest(), .m_axis_tid(), .m_axis_tkeep(), .m_axis_tlast(), .m_axis_tready(1'b0), .m_axis_tstrb(), .m_axis_tuser(), .m_axis_tvalid(), .overflow(), .prog_empty(), .prog_empty_thresh(5'b0), .prog_empty_thresh_assert(5'b0), .prog_empty_thresh_negate(5'b0), .prog_full(), .prog_full_thresh(5'b0), .prog_full_thresh_assert(5'b0), .prog_full_thresh_negate(5'b0), .rd_data_count(), .rd_rst(1'b0), .s_aclk(1'b0), .s_aclk_en(1'b0), .s_aresetn(1'b0), .s_axi_araddr(32'b0), .s_axi_arburst(2'b0), .s_axi_arcache(4'b0), .s_axi_arid(4'b0), .s_axi_arlen(8'b0), .s_axi_arlock(2'b0), .s_axi_arprot(3'b0), .s_axi_arqos(4'b0), .s_axi_arready(), .s_axi_arregion(4'b0), .s_axi_arsize(3'b0), .s_axi_aruser(1'b0), .s_axi_arvalid(1'b0), .s_axi_awaddr(32'b0), .s_axi_awburst(2'b0), .s_axi_awcache(4'b0), .s_axi_awid(4'b0), .s_axi_awlen(8'b0), .s_axi_awlock(2'b0), .s_axi_awprot(3'b0), .s_axi_awqos(4'b0), .s_axi_awready(), .s_axi_awregion(4'b0), .s_axi_awsize(3'b0), .s_axi_awuser(1'b0), .s_axi_awvalid(1'b0), .s_axi_bid(), .s_axi_bready(1'b0), .s_axi_bresp(), .s_axi_buser(), .s_axi_bvalid(), .s_axi_rdata(), .s_axi_rid(), .s_axi_rlast(), .s_axi_rready(1'b0), .s_axi_rresp(), .s_axi_ruser(), .s_axi_rvalid(), .s_axi_wdata(64'b0), .s_axi_wid(4'b0), .s_axi_wlast(1'b0), .s_axi_wready(), .s_axi_wstrb(8'b0), .s_axi_wuser(1'b0), .s_axi_wvalid(1'b0), .s_axis_tdata(64'b0), .s_axis_tdest(4'b0), .s_axis_tid(8'b0), .s_axis_tkeep(4'b0), .s_axis_tlast(1'b0), .s_axis_tready(), .s_axis_tstrb(4'b0), .s_axis_tuser(4'b0), .s_axis_tvalid(1'b0), .sbiterr(), .srst(1'b0), .underflow(), .valid(), .wr_ack(), .wr_data_count(), .wr_rst(1'b0), .wr_rst_busy(), .rd_rst_busy(), .sleep(1'b0) ); endmodule // -- (c) Copyright 2008 - 2012 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Description: N-deep SRL pipeline element with generic single-channel AXI interfaces. // Verilog-standard: Verilog 2001 //-------------------------------------------------------------------------- // Structure: // axic_srl_fifo // ndeep_srl // nto1_mux //-------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none ( DowngradeIPIdentifiedWarnings="yes" ) module axi_data_fifo_v2_1_12_axic_srl_fifo # ( parameter C_FAMILY = "none", // FPGA Family parameter integer C_FIFO_WIDTH = 1, // Width of S_MESG/M_MESG. parameter integer C_MAX_CTRL_FANOUT = 33, // Maximum number of mesg bits // the control logic can be used // on before the control logic // needs to be replicated. parameter integer C_FIFO_DEPTH_LOG = 2, // Depth of FIFO is 2C_FIFO_DEPTH_LOG. // The minimum size fifo generated is 4-deep. parameter C_USE_FULL = 1 // Prevent overwrite by throttling S_READY. ) ( input wire ACLK, // Clock input wire ARESET, // Reset input wire [C_FIFO_WIDTH-1:0] S_MESG, // Input data input wire S_VALID, // Input data valid output wire S_READY, // Input data ready output wire [C_FIFO_WIDTH-1:0] M_MESG, // Output data output wire M_VALID, // Output data valid input wire M_READY // Output data ready ); localparam P_FIFO_DEPTH_LOG = (C_FIFO_DEPTH_LOG>1) ? C_FIFO_DEPTH_LOG : 2; localparam P_EMPTY = {P_FIFO_DEPTH_LOG{1'b1}}; localparam P_ALMOSTEMPTY = {P_FIFO_DEPTH_LOG{1'b0}}; localparam P_ALMOSTFULL_TEMP = {P_EMPTY, 1'b0}; localparam P_ALMOSTFULL = P_ALMOSTFULL_TEMP[0+:P_FIFO_DEPTH_LOG]; localparam P_NUM_REPS = (((C_FIFO_WIDTH+1)%C_MAX_CTRL_FANOUT) == 0) ? (C_FIFO_WIDTH+1)/C_MAX_CTRL_FANOUT : ((C_FIFO_WIDTH+1)/C_MAX_CTRL_FANOUT)+1; ( syn_keep = "1" ) reg [P_NUM_REPSP_FIFO_DEPTH_LOG-1:0] fifoaddr; (* syn_keep = "1" ) wire [P_NUM_REPSP_FIFO_DEPTH_LOG-1:0] fifoaddr_i; genvar i; genvar j; reg M_VALID_i; reg S_READY_i; wire push; // FIFO push wire pop; // FIFO pop reg areset_d1; // Reset delay register wire [C_FIFO_WIDTH-1:0] m_axi_mesg_i; // Intermediate SRL data assign M_VALID = M_VALID_i; assign S_READY = C_USE_FULL ? S_READY_i : 1'b1; assign M_MESG = m_axi_mesg_i; assign push = S_VALID & (C_USE_FULL ? S_READY_i : 1'b1); assign pop = M_VALID_i & M_READY; always @(posedge ACLK) begin areset_d1 <= ARESET; end generate //--------------------------------------------------------------------------- // Create count of number of elements in FIFOs //--------------------------------------------------------------------------- for (i=0;i<P_NUM_REPS;i=i+1) begin : gen_rep assign fifoaddr_i[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi] = push ? fifoaddr[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi] + 1 : fifoaddr[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi] - 1; always @(posedge ACLK) begin if (ARESET) fifoaddr[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi] <= {P_FIFO_DEPTH_LOG{1'b1}}; else if (push ^ pop) fifoaddr[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi] <= fifoaddr_i[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi]; end end //--------------------------------------------------------------------------- // When FIFO is empty, reset master valid bit. When not empty set valid bit. // When FIFO is full, reset slave ready bit. When not full set ready bit. //--------------------------------------------------------------------------- always @(posedge ACLK) begin if (ARESET) begin M_VALID_i <= 1'b0; end else if ((fifoaddr[P_FIFO_DEPTH_LOGP_NUM_REPS-1:P_FIFO_DEPTH_LOG(P_NUM_REPS-1)] == P_ALMOSTEMPTY) && pop && ~push) begin M_VALID_i <= 1'b0; end else if (push) begin M_VALID_i <= 1'b1; end end always @(posedge ACLK) begin if (ARESET) begin S_READY_i <= 1'b0; end else if (areset_d1) begin S_READY_i <= 1'b1; end else if (C_USE_FULL && ((fifoaddr[P_FIFO_DEPTH_LOGP_NUM_REPS-1:P_FIFO_DEPTH_LOG(P_NUM_REPS-1)] == P_ALMOSTFULL) && push && ~pop)) begin S_READY_i <= 1'b0; end else if (C_USE_FULL && pop) begin S_READY_i <= 1'b1; end end //--------------------------------------------------------------------------- // Instantiate SRLs //--------------------------------------------------------------------------- for (i=0;i<(C_FIFO_WIDTH/C_MAX_CTRL_FANOUT)+((C_FIFO_WIDTH%C_MAX_CTRL_FANOUT)>0);i=i+1) begin : gen_srls for (j=0;((j<C_MAX_CTRL_FANOUT)&&(iC_MAX_CTRL_FANOUT+j<C_FIFO_WIDTH));j=j+1) begin : gen_rep axi_data_fifo_v2_1_12_ndeep_srl # ( .C_FAMILY (C_FAMILY), .C_A_WIDTH (P_FIFO_DEPTH_LOG) ) srl_nx1 ( .CLK (ACLK), .A (fifoaddr[P_FIFO_DEPTH_LOG(i+1)-1: P_FIFO_DEPTH_LOG(i)]), .CE (push), .D (S_MESG[iC_MAX_CTRL_FANOUT+j]), .Q (m_axi_mesg_i[iC_MAX_CTRL_FANOUT+j]) ); end end endgenerate endmodule `default_nettype wire // -- (c) Copyright 2010 - 2012 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // Description: N-deep SRL pipeline element with generic single-channel AXI interfaces. // Interface outputs are synchronized using ordinary flops for improved timing. //-------------------------------------------------------------------------- // Structure: // axic_reg_srl_fifo // ndeep_srl // nto1_mux //-------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none ( DowngradeIPIdentifiedWarnings="yes" ) module axi_data_fifo_v2_1_12_axic_reg_srl_fifo # ( parameter C_FAMILY = "none", // FPGA Family parameter integer C_FIFO_WIDTH = 1, // Width of S_MESG/M_MESG. parameter integer C_MAX_CTRL_FANOUT = 33, // Maximum number of mesg bits // the control logic can be used // on before the control logic // needs to be replicated. parameter integer C_FIFO_DEPTH_LOG = 2, // Depth of FIFO is 2C_FIFO_DEPTH_LOG. // The minimum size fifo generated is 4-deep. parameter C_USE_FULL = 1 // Prevent overwrite by throttling S_READY. ) ( input wire ACLK, // Clock input wire ARESET, // Reset input wire [C_FIFO_WIDTH-1:0] S_MESG, // Input data input wire S_VALID, // Input data valid output wire S_READY, // Input data ready output wire [C_FIFO_WIDTH-1:0] M_MESG, // Output data output wire M_VALID, // Output data valid input wire M_READY // Output data ready ); localparam P_FIFO_DEPTH_LOG = (C_FIFO_DEPTH_LOG>1) ? C_FIFO_DEPTH_LOG : 2; localparam P_EMPTY = {P_FIFO_DEPTH_LOG{1'b1}}; localparam P_ALMOSTEMPTY = {P_FIFO_DEPTH_LOG{1'b0}}; localparam P_ALMOSTFULL_TEMP = {P_EMPTY, 1'b0}; localparam P_ALMOSTFULL = P_ALMOSTFULL_TEMP[0+:P_FIFO_DEPTH_LOG]; localparam P_NUM_REPS = (((C_FIFO_WIDTH+1)%C_MAX_CTRL_FANOUT) == 0) ? (C_FIFO_WIDTH+1)/C_MAX_CTRL_FANOUT : ((C_FIFO_WIDTH+1)/C_MAX_CTRL_FANOUT)+1; ( syn_keep = "1" ) reg [P_NUM_REPSP_FIFO_DEPTH_LOG-1:0] fifoaddr; (* syn_keep = "1" ) wire [P_NUM_REPSP_FIFO_DEPTH_LOG-1:0] fifoaddr_i; genvar i; genvar j; reg m_valid_i = 1'b0; reg s_ready_i; wire push; // FIFO push wire pop; // FIFO pop reg areset_d1; // Reset delay register reg [C_FIFO_WIDTH-1:0] storage_data1; wire [C_FIFO_WIDTH-1:0] storage_data2; // Intermediate SRL data reg load_s1; wire load_s1_from_s2; reg [1:0] state; localparam [1:0] ZERO = 2'b10, ONE = 2'b11, TWO = 2'b01; assign M_VALID = m_valid_i; assign S_READY = C_USE_FULL ? s_ready_i : 1'b1; assign push = (S_VALID & (C_USE_FULL ? s_ready_i : 1'b1) & (state == TWO)) \| (~M_READY & S_VALID & (state == ONE)); assign pop = M_READY & (state == TWO); assign M_MESG = storage_data1; always @(posedge ACLK) begin areset_d1 <= ARESET; end // Load storage1 with either slave side data or from storage2 always @(posedge ACLK) begin if (load_s1) if (load_s1_from_s2) storage_data1 <= storage_data2; else storage_data1 <= S_MESG; end // Loading s1 always @ * begin if ( ((state == ZERO) && (S_VALID == 1)) \|\| // Load when empty on slave transaction // Load when ONE if we both have read and write at the same time ((state == ONE) && (S_VALID == 1) && (M_READY == 1)) \|\| // Load when TWO and we have a transaction on Master side ((state == TWO) && (M_READY == 1))) load_s1 = 1'b1; else load_s1 = 1'b0; end // always @ * assign load_s1_from_s2 = (state == TWO); // State Machine for handling output signals always @(posedge ACLK) begin if (areset_d1) begin state <= ZERO; m_valid_i <= 1'b0; end else begin case (state) // No transaction stored locally ZERO: begin if (S_VALID) begin state <= ONE; // Got one so move to ONE m_valid_i <= 1'b1; end end // One transaction stored locally ONE: begin if (M_READY & ~S_VALID) begin state <= ZERO; // Read out one so move to ZERO m_valid_i <= 1'b0; end else if (~M_READY & S_VALID) begin state <= TWO; // Got another one so move to TWO m_valid_i <= 1'b1; end end // TWO transaction stored locally TWO: begin if ((fifoaddr[P_FIFO_DEPTH_LOGP_NUM_REPS-1:P_FIFO_DEPTH_LOG(P_NUM_REPS-1)] == P_ALMOSTEMPTY) && pop && ~push) begin state <= ONE; // Read out one so move to ONE m_valid_i <= 1'b1; end end endcase // case (state) end end // always @ (posedge ACLK) generate //--------------------------------------------------------------------------- // Create count of number of elements in FIFOs //--------------------------------------------------------------------------- for (i=0;i<P_NUM_REPS;i=i+1) begin : gen_rep assign fifoaddr_i[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi] = push ? fifoaddr[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi] + 1 : fifoaddr[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi] - 1; always @(posedge ACLK) begin if (ARESET) fifoaddr[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi] <= {P_FIFO_DEPTH_LOG{1'b1}}; else if (push ^ pop) fifoaddr[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi] <= fifoaddr_i[P_FIFO_DEPTH_LOG(i+1)-1:P_FIFO_DEPTH_LOGi]; end end always @(posedge ACLK) begin if (ARESET) begin s_ready_i <= 1'b0; end else if (areset_d1) begin s_ready_i <= 1'b1; end else if (C_USE_FULL && ((fifoaddr[P_FIFO_DEPTH_LOGP_NUM_REPS-1:P_FIFO_DEPTH_LOG(P_NUM_REPS-1)] == P_ALMOSTFULL) && push && ~pop)) begin s_ready_i <= 1'b0; end else if (C_USE_FULL && pop) begin s_ready_i <= 1'b1; end end //--------------------------------------------------------------------------- // Instantiate SRLs //--------------------------------------------------------------------------- for (i=0;i<(C_FIFO_WIDTH/C_MAX_CTRL_FANOUT)+((C_FIFO_WIDTH%C_MAX_CTRL_FANOUT)>0);i=i+1) begin : gen_srls for (j=0;((j<C_MAX_CTRL_FANOUT)&&(iC_MAX_CTRL_FANOUT+j<C_FIFO_WIDTH));j=j+1) begin : gen_rep axi_data_fifo_v2_1_12_ndeep_srl # ( .C_FAMILY (C_FAMILY), .C_A_WIDTH (P_FIFO_DEPTH_LOG) ) srl_nx1 ( .CLK (ACLK), .A (fifoaddr[P_FIFO_DEPTH_LOG(i+1)-1: P_FIFO_DEPTH_LOG(i)]), .CE (push), .D (S_MESG[iC_MAX_CTRL_FANOUT+j]), .Q (storage_data2[iC_MAX_CTRL_FANOUT+j]) ); end end endgenerate endmodule `default_nettype wire // -- (c) Copyright 2008 - 2014 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Description: This is a generic n-deep SRL instantiation // Verilog-standard: Verilog 2001 // $Revision: // $Date: // //----------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none ( DowngradeIPIdentifiedWarnings="yes" ) module axi_data_fifo_v2_1_12_ndeep_srl # ( parameter C_FAMILY = "rtl", // FPGA Family parameter C_A_WIDTH = 1 // Address Width (>= 1) ) ( input wire CLK, // Clock input wire [C_A_WIDTH-1:0] A, // Address input wire CE, // Clock Enable input wire D, // Input Data output wire Q // Output Data ); localparam integer P_SRLASIZE = 5; localparam integer P_SRLDEPTH = 32; localparam integer P_NUMSRLS = (C_A_WIDTH>P_SRLASIZE) ? (2(C_A_WIDTH-P_SRLASIZE)) : 1; localparam integer P_SHIFT_DEPTH = 2C_A_WIDTH; wire [P_NUMSRLS:0] d_i; wire [P_NUMSRLS-1:0] q_i; wire [(C_A_WIDTH>P_SRLASIZE) ? (C_A_WIDTH-1) : (P_SRLASIZE-1) : 0] a_i; genvar i; // Instantiate SRLs in carry chain format assign d_i[0] = D; assign a_i = A; generate if (C_FAMILY == "rtl") begin : gen_rtl_shifter if (C_A_WIDTH <= P_SRLASIZE) begin : gen_inferred_srl reg [P_SRLDEPTH-1:0] shift_reg = {P_SRLDEPTH{1'b0}}; always @(posedge CLK) if (CE) shift_reg <= {shift_reg[P_SRLDEPTH-2:0], D}; assign Q = shift_reg[a_i]; end else begin : gen_logic_shifter // Very wasteful reg [P_SHIFT_DEPTH-1:0] shift_reg = {P_SHIFT_DEPTH{1'b0}}; always @(posedge CLK) if (CE) shift_reg <= {shift_reg[P_SHIFT_DEPTH-2:0], D}; assign Q = shift_reg[a_i]; end end else begin : gen_primitive_shifter for (i=0;i<P_NUMSRLS;i=i+1) begin : gen_srls SRLC32E srl_inst ( .CLK (CLK), .A (a_i[P_SRLASIZE-1:0]), .CE (CE), .D (d_i[i]), .Q (q_i[i]), .Q31 (d_i[i+1]) ); end if (C_A_WIDTH>P_SRLASIZE) begin : gen_srl_mux generic_baseblocks_v2_1_0_nto1_mux # ( .C_RATIO (2(C_A_WIDTH-P_SRLASIZE)), .C_SEL_WIDTH (C_A_WIDTH-P_SRLASIZE), .C_DATAOUT_WIDTH (1), .C_ONEHOT (0) ) srl_q_mux_inst ( .SEL_ONEHOT ({2(C_A_WIDTH-P_SRLASIZE){1'b0}}), .SEL (a_i[C_A_WIDTH-1:P_SRLASIZE]), .IN (q_i), .OUT (Q) ); end else begin : gen_no_srl_mux assign Q = q_i[0]; end end endgenerate endmodule `default_nettype wire // -- (c) Copyright 2010 - 2012 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // AXI data fifo module: // 5-channel memory-mapped AXI4 interfaces. // SRL or BRAM based FIFO on AXI W and/or R channels. // FIFO to accommodate various data flow rates through the AXI interconnect // // Verilog-standard: Verilog 2001 //----------------------------------------------------------------------------- // // Structure: // axi_data_fifo // fifo_generator // //----------------------------------------------------------------------------- `timescale 1ps/1ps ( DowngradeIPIdentifiedWarnings="yes" ) module axi_data_fifo_v2_1_12_axi_data_fifo # ( parameter C_FAMILY = "virtex7", parameter integer C_AXI_PROTOCOL = 0, parameter integer C_AXI_ID_WIDTH = 4, parameter integer C_AXI_ADDR_WIDTH = 32, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0, parameter integer C_AXI_AWUSER_WIDTH = 1, parameter integer C_AXI_ARUSER_WIDTH = 1, parameter integer C_AXI_WUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_BUSER_WIDTH = 1, parameter integer C_AXI_WRITE_FIFO_DEPTH = 0, // Range: (0, 32, 512) parameter C_AXI_WRITE_FIFO_TYPE = "lut", // "lut" = LUT (SRL) based, // "bram" = BRAM based parameter integer C_AXI_WRITE_FIFO_DELAY = 0, // 0 = No, 1 = Yes // Indicates whether AWVALID and WVALID assertion is delayed until: // a. the corresponding WLAST is stored in the FIFO, or // b. no WLAST is stored and the FIFO is full. // 0 means AW channel is pass-through and // WVALID is asserted whenever FIFO is not empty. parameter integer C_AXI_READ_FIFO_DEPTH = 0, // Range: (0, 32, 512) parameter C_AXI_READ_FIFO_TYPE = "lut", // "lut" = LUT (SRL) based, // "bram" = BRAM based parameter integer C_AXI_READ_FIFO_DELAY = 0) // 0 = No, 1 = Yes // Indicates whether ARVALID assertion is delayed until the // the remaining vacancy of the FIFO is at least the burst length // as indicated by ARLEN. // 0 means AR channel is pass-through. // System Signals (input wire aclk, input wire aresetn, // Slave Interface Write Address Ports input wire [C_AXI_ID_WIDTH-1:0] s_axi_awid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr, input wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] s_axi_awlen, input wire [3-1:0] s_axi_awsize, input wire [2-1:0] s_axi_awburst, input wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] s_axi_awlock, input wire [4-1:0] s_axi_awcache, input wire [3-1:0] s_axi_awprot, input wire [4-1:0] s_axi_awregion, input wire [4-1:0] s_axi_awqos, input wire [C_AXI_AWUSER_WIDTH-1:0] s_axi_awuser, input wire s_axi_awvalid, output wire s_axi_awready, // Slave Interface Write Data Ports input wire [C_AXI_ID_WIDTH-1:0] s_axi_wid, input wire [C_AXI_DATA_WIDTH-1:0] s_axi_wdata, input wire [C_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb, input wire s_axi_wlast, input wire [C_AXI_WUSER_WIDTH-1:0] s_axi_wuser, input wire s_axi_wvalid, output wire s_axi_wready, // Slave Interface Write Response Ports output wire [C_AXI_ID_WIDTH-1:0] s_axi_bid, output wire [2-1:0] s_axi_bresp, output wire [C_AXI_BUSER_WIDTH-1:0] s_axi_buser, output wire s_axi_bvalid, input wire s_axi_bready, // Slave Interface Read Address Ports input wire [C_AXI_ID_WIDTH-1:0] s_axi_arid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr, input wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] s_axi_arlen, input wire [3-1:0] s_axi_arsize, input wire [2-1:0] s_axi_arburst, input wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] s_axi_arlock, input wire [4-1:0] s_axi_arcache, input wire [3-1:0] s_axi_arprot, input wire [4-1:0] s_axi_arregion, input wire [4-1:0] s_axi_arqos, input wire [C_AXI_ARUSER_WIDTH-1:0] s_axi_aruser, input wire s_axi_arvalid, output wire s_axi_arready, // Slave Interface Read Data Ports output wire [C_AXI_ID_WIDTH-1:0] s_axi_rid, output wire [C_AXI_DATA_WIDTH-1:0] s_axi_rdata, output wire [2-1:0] s_axi_rresp, output wire s_axi_rlast, output wire [C_AXI_RUSER_WIDTH-1:0] s_axi_ruser, output wire s_axi_rvalid, input wire s_axi_rready, // Master Interface Write Address Port output wire [C_AXI_ID_WIDTH-1:0] m_axi_awid, output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr, output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_awlen, output wire [3-1:0] m_axi_awsize, output wire [2-1:0] m_axi_awburst, output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_awlock, output wire [4-1:0] m_axi_awcache, output wire [3-1:0] m_axi_awprot, output wire [4-1:0] m_axi_awregion, output wire [4-1:0] m_axi_awqos, output wire [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser, output wire m_axi_awvalid, input wire m_axi_awready, // Master Interface Write Data Ports output wire [C_AXI_ID_WIDTH-1:0] m_axi_wid, output wire [C_AXI_DATA_WIDTH-1:0] m_axi_wdata, output wire [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb, output wire m_axi_wlast, output wire [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser, output wire m_axi_wvalid, input wire m_axi_wready, // Master Interface Write Response Ports input wire [C_AXI_ID_WIDTH-1:0] m_axi_bid, input wire [2-1:0] m_axi_bresp, input wire [C_AXI_BUSER_WIDTH-1:0] m_axi_buser, input wire m_axi_bvalid, output wire m_axi_bready, // Master Interface Read Address Port output wire [C_AXI_ID_WIDTH-1:0] m_axi_arid, output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr, output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_arlen, output wire [3-1:0] m_axi_arsize, output wire [2-1:0] m_axi_arburst, output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_arlock, output wire [4-1:0] m_axi_arcache, output wire [3-1:0] m_axi_arprot, output wire [4-1:0] m_axi_arregion, output wire [4-1:0] m_axi_arqos, output wire [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser, output wire m_axi_arvalid, input wire m_axi_arready, // Master Interface Read Data Ports input wire [C_AXI_ID_WIDTH-1:0] m_axi_rid, input wire [C_AXI_DATA_WIDTH-1:0] m_axi_rdata, input wire [2-1:0] m_axi_rresp, input wire m_axi_rlast, input wire [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser, input wire m_axi_rvalid, output wire m_axi_rready); localparam integer P_WIDTH_RACH = 4+4+3+4+2+3+((C_AXI_PROTOCOL==1)?6:9)+C_AXI_ADDR_WIDTH+C_AXI_ID_WIDTH+C_AXI_ARUSER_WIDTH; localparam integer P_WIDTH_WACH = 4+4+3+4+2+3+((C_AXI_PROTOCOL==1)?6:9)+C_AXI_ADDR_WIDTH+C_AXI_ID_WIDTH+C_AXI_AWUSER_WIDTH; localparam integer P_WIDTH_RDCH = 1 + 2 + C_AXI_DATA_WIDTH + C_AXI_ID_WIDTH + C_AXI_RUSER_WIDTH; localparam integer P_WIDTH_WDCH = 1+C_AXI_DATA_WIDTH+C_AXI_DATA_WIDTH/8+((C_AXI_PROTOCOL==1)?C_AXI_ID_WIDTH:0)+C_AXI_WUSER_WIDTH; localparam integer P_WIDTH_WRCH = 2 + C_AXI_ID_WIDTH + C_AXI_BUSER_WIDTH; localparam P_PRIM_FIFO_TYPE = "512x72" ; localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; localparam integer P_WRITE_FIFO_DEPTH_LOG = (C_AXI_WRITE_FIFO_DEPTH > 1) ? f_ceil_log2(C_AXI_WRITE_FIFO_DEPTH) : 1; localparam integer P_READ_FIFO_DEPTH_LOG = (C_AXI_READ_FIFO_DEPTH > 1) ? f_ceil_log2(C_AXI_READ_FIFO_DEPTH) : 1; // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2*acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction generate if (((C_AXI_WRITE_FIFO_DEPTH == 0) && (C_AXI_READ_FIFO_DEPTH == 0)) \|\| (C_AXI_PROTOCOL == P_AXILITE)) begin : gen_bypass assign m_axi_awid = s_axi_awid; assign m_axi_awaddr = s_axi_awaddr; assign m_axi_awlen = s_axi_awlen; assign m_axi_awsize = s_axi_awsize; assign m_axi_awburst = s_axi_awburst; assign m_axi_awlock = s_axi_awlock; assign m_axi_awcache = s_axi_awcache; assign m_axi_awprot = s_axi_awprot; assign m_axi_awregion = s_axi_awregion; assign m_axi_awqos = s_axi_awqos; assign m_axi_awuser = s_axi_awuser; assign m_axi_awvalid = s_axi_awvalid; assign s_axi_awready = m_axi_awready; assign m_axi_wid = s_axi_wid; assign m_axi_wdata = s_axi_wdata; assign m_axi_wstrb = s_axi_wstrb; assign m_axi_wlast = s_axi_wlast; assign m_axi_wuser = s_axi_wuser; assign m_axi_wvalid = s_axi_wvalid; assign s_axi_wready = m_axi_wready; assign s_axi_bid = m_axi_bid; assign s_axi_bresp = m_axi_bresp; assign s_axi_buser = m_axi_buser; assign s_axi_bvalid = m_axi_bvalid; assign m_axi_bready = s_axi_bready; assign m_axi_arid = s_axi_arid; assign m_axi_araddr = s_axi_araddr; assign m_axi_arlen = s_axi_arlen; assign m_axi_arsize = s_axi_arsize; assign m_axi_arburst = s_axi_arburst; assign m_axi_arlock = s_axi_arlock; assign m_axi_arcache = s_axi_arcache; assign m_axi_arprot = s_axi_arprot; assign m_axi_arregion = s_axi_arregion; assign m_axi_arqos = s_axi_arqos; assign m_axi_aruser = s_axi_aruser; assign m_axi_arvalid = s_axi_arvalid; assign s_axi_arready = m_axi_arready; assign s_axi_rid = m_axi_rid; assign s_axi_rdata = m_axi_rdata; assign s_axi_rresp = m_axi_rresp; assign s_axi_rlast = m_axi_rlast; assign s_axi_ruser = m_axi_ruser; assign s_axi_rvalid = m_axi_rvalid; assign m_axi_rready = s_axi_rready; end else begin : gen_fifo wire [4-1:0] s_axi_awregion_i; wire [4-1:0] s_axi_arregion_i; wire [4-1:0] m_axi_awregion_i; wire [4-1:0] m_axi_arregion_i; wire [C_AXI_ID_WIDTH-1:0] s_axi_wid_i; wire [C_AXI_ID_WIDTH-1:0] m_axi_wid_i; assign s_axi_awregion_i = (C_AXI_PROTOCOL == P_AXI3) ? 4'b0 : s_axi_awregion; assign s_axi_arregion_i = (C_AXI_PROTOCOL == P_AXI3) ? 4'b0 : s_axi_arregion; assign m_axi_awregion = (C_AXI_PROTOCOL == P_AXI3) ? 4'b0 : m_axi_awregion_i; assign m_axi_arregion = (C_AXI_PROTOCOL == P_AXI3) ? 4'b0 : m_axi_arregion_i; assign s_axi_wid_i = (C_AXI_PROTOCOL == P_AXI3) ? s_axi_wid : {C_AXI_ID_WIDTH{1'b0}}; assign m_axi_wid = (C_AXI_PROTOCOL == P_AXI3) ? m_axi_wid_i : {C_AXI_ID_WIDTH{1'b0}}; fifo_generator_v13_1_4 #( .C_INTERFACE_TYPE(2), .C_AXI_TYPE((C_AXI_PROTOCOL == P_AXI4) ? 1 : 3), .C_AXI_DATA_WIDTH(C_AXI_DATA_WIDTH), .C_AXI_ID_WIDTH(C_AXI_ID_WIDTH), .C_HAS_AXI_ID(1), .C_AXI_LEN_WIDTH((C_AXI_PROTOCOL == P_AXI4) ? 8 : 4), .C_AXI_LOCK_WIDTH((C_AXI_PROTOCOL == P_AXI4) ? 1 : 2), .C_HAS_AXI_ARUSER(1), .C_HAS_AXI_AWUSER(1), .C_HAS_AXI_BUSER(1), .C_HAS_AXI_RUSER(1), .C_HAS_AXI_WUSER(1), .C_AXI_ADDR_WIDTH(C_AXI_ADDR_WIDTH), .C_AXI_ARUSER_WIDTH(C_AXI_ARUSER_WIDTH), .C_AXI_AWUSER_WIDTH(C_AXI_AWUSER_WIDTH), .C_AXI_BUSER_WIDTH(C_AXI_BUSER_WIDTH), .C_AXI_RUSER_WIDTH(C_AXI_RUSER_WIDTH), .C_AXI_WUSER_WIDTH(C_AXI_WUSER_WIDTH), .C_DIN_WIDTH_RACH(P_WIDTH_RACH), .C_DIN_WIDTH_RDCH(P_WIDTH_RDCH), .C_DIN_WIDTH_WACH(P_WIDTH_WACH), .C_DIN_WIDTH_WDCH(P_WIDTH_WDCH), .C_DIN_WIDTH_WRCH(P_WIDTH_WDCH), .C_RACH_TYPE(((C_AXI_READ_FIFO_DEPTH != 0) && C_AXI_READ_FIFO_DELAY) ? 0 : 2), .C_WACH_TYPE(((C_AXI_WRITE_FIFO_DEPTH != 0) && C_AXI_WRITE_FIFO_DELAY) ? 0 : 2), .C_WDCH_TYPE((C_AXI_WRITE_FIFO_DEPTH != 0) ? 0 : 2), .C_RDCH_TYPE((C_AXI_READ_FIFO_DEPTH != 0) ? 0 : 2), .C_WRCH_TYPE(2), .C_COMMON_CLOCK(1), .C_ADD_NGC_CONSTRAINT(0), .C_APPLICATION_TYPE_AXIS(0), .C_APPLICATION_TYPE_RACH(C_AXI_READ_FIFO_DELAY ? 1 : 0), .C_APPLICATION_TYPE_RDCH(0), .C_APPLICATION_TYPE_WACH(C_AXI_WRITE_FIFO_DELAY ? 1 : 0), .C_APPLICATION_TYPE_WDCH(0), .C_APPLICATION_TYPE_WRCH(0), .C_AXIS_TDATA_WIDTH(64), .C_AXIS_TDEST_WIDTH(4), .C_AXIS_TID_WIDTH(8), .C_AXIS_TKEEP_WIDTH(4), .C_AXIS_TSTRB_WIDTH(4), .C_AXIS_TUSER_WIDTH(4), .C_AXIS_TYPE(0), .C_COUNT_TYPE(0), .C_DATA_COUNT_WIDTH(10), .C_DEFAULT_VALUE("BlankString"), .C_DIN_WIDTH(18), .C_DIN_WIDTH_AXIS(1), .C_DOUT_RST_VAL("0"), .C_DOUT_WIDTH(18), .C_ENABLE_RLOCS(0), .C_ENABLE_RST_SYNC(1), .C_ERROR_INJECTION_TYPE(0), .C_ERROR_INJECTION_TYPE_AXIS(0), .C_ERROR_INJECTION_TYPE_RACH(0), .C_ERROR_INJECTION_TYPE_RDCH(0), .C_ERROR_INJECTION_TYPE_WACH(0), .C_ERROR_INJECTION_TYPE_WDCH(0), .C_ERROR_INJECTION_TYPE_WRCH(0), .C_FAMILY(C_FAMILY), .C_FULL_FLAGS_RST_VAL(1), .C_HAS_ALMOST_EMPTY(0), .C_HAS_ALMOST_FULL(0), .C_HAS_AXI_RD_CHANNEL(1), .C_HAS_AXI_WR_CHANNEL(1), .C_HAS_AXIS_TDATA(0), .C_HAS_AXIS_TDEST(0), .C_HAS_AXIS_TID(0), .C_HAS_AXIS_TKEEP(0), .C_HAS_AXIS_TLAST(0), .C_HAS_AXIS_TREADY(1), .C_HAS_AXIS_TSTRB(0), .C_HAS_AXIS_TUSER(0), .C_HAS_BACKUP(0), .C_HAS_DATA_COUNT(0), .C_HAS_DATA_COUNTS_AXIS(0), .C_HAS_DATA_COUNTS_RACH(0), .C_HAS_DATA_COUNTS_RDCH(0), .C_HAS_DATA_COUNTS_WACH(0), .C_HAS_DATA_COUNTS_WDCH(0), .C_HAS_DATA_COUNTS_WRCH(0), .C_HAS_INT_CLK(0), .C_HAS_MASTER_CE(0), .C_HAS_MEMINIT_FILE(0), .C_HAS_OVERFLOW(0), .C_HAS_PROG_FLAGS_AXIS(0), .C_HAS_PROG_FLAGS_RACH(0), .C_HAS_PROG_FLAGS_RDCH(0), .C_HAS_PROG_FLAGS_WACH(0), .C_HAS_PROG_FLAGS_WDCH(0), .C_HAS_PROG_FLAGS_WRCH(0), .C_HAS_RD_DATA_COUNT(0), .C_HAS_RD_RST(0), .C_HAS_RST(1), .C_HAS_SLAVE_CE(0), .C_HAS_SRST(0), .C_HAS_UNDERFLOW(0), .C_HAS_VALID(0), .C_HAS_WR_ACK(0), .C_HAS_WR_DATA_COUNT(0), .C_HAS_WR_RST(0), .C_IMPLEMENTATION_TYPE(0), .C_IMPLEMENTATION_TYPE_AXIS(1), .C_IMPLEMENTATION_TYPE_RACH(2), .C_IMPLEMENTATION_TYPE_RDCH((C_AXI_READ_FIFO_TYPE == "bram") ? 1 : 2), .C_IMPLEMENTATION_TYPE_WACH(2), .C_IMPLEMENTATION_TYPE_WDCH((C_AXI_WRITE_FIFO_TYPE == "bram") ? 1 : 2), .C_IMPLEMENTATION_TYPE_WRCH(2), .C_INIT_WR_PNTR_VAL(0), .C_MEMORY_TYPE(1), .C_MIF_FILE_NAME("BlankString"), .C_MSGON_VAL(1), .C_OPTIMIZATION_MODE(0), .C_OVERFLOW_LOW(0), .C_PRELOAD_LATENCY(1), .C_PRELOAD_REGS(0), .C_PRIM_FIFO_TYPE(P_PRIM_FIFO_TYPE), .C_PROG_EMPTY_THRESH_ASSERT_VAL(2), .C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH(30), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH(510), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH(30), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH(510), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH(14), .C_PROG_EMPTY_THRESH_NEGATE_VAL(3), .C_PROG_EMPTY_TYPE(0), .C_PROG_EMPTY_TYPE_AXIS(5), .C_PROG_EMPTY_TYPE_RACH(5), .C_PROG_EMPTY_TYPE_RDCH(5), .C_PROG_EMPTY_TYPE_WACH(5), .C_PROG_EMPTY_TYPE_WDCH(5), .C_PROG_EMPTY_TYPE_WRCH(5), .C_PROG_FULL_THRESH_ASSERT_VAL(1022), .C_PROG_FULL_THRESH_ASSERT_VAL_AXIS(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_RACH(31), .C_PROG_FULL_THRESH_ASSERT_VAL_RDCH(511), .C_PROG_FULL_THRESH_ASSERT_VAL_WACH(31), .C_PROG_FULL_THRESH_ASSERT_VAL_WDCH(511), .C_PROG_FULL_THRESH_ASSERT_VAL_WRCH(15), .C_PROG_FULL_THRESH_NEGATE_VAL(1021), .C_PROG_FULL_TYPE(0), .C_PROG_FULL_TYPE_AXIS(5), .C_PROG_FULL_TYPE_RACH(5), .C_PROG_FULL_TYPE_RDCH(5), .C_PROG_FULL_TYPE_WACH(5), .C_PROG_FULL_TYPE_WDCH(5), .C_PROG_FULL_TYPE_WRCH(5), .C_RD_DATA_COUNT_WIDTH(10), .C_RD_DEPTH(1024), .C_RD_FREQ(1), .C_RD_PNTR_WIDTH(10), .C_REG_SLICE_MODE_AXIS(0), .C_REG_SLICE_MODE_RACH(0), .C_REG_SLICE_MODE_RDCH(0), .C_REG_SLICE_MODE_WACH(0), .C_REG_SLICE_MODE_WDCH(0), .C_REG_SLICE_MODE_WRCH(0), .C_UNDERFLOW_LOW(0), .C_USE_COMMON_OVERFLOW(0), .C_USE_COMMON_UNDERFLOW(0), .C_USE_DEFAULT_SETTINGS(0), .C_USE_DOUT_RST(1), .C_USE_ECC(0), .C_USE_ECC_AXIS(0), .C_USE_ECC_RACH(0), .C_USE_ECC_RDCH(0), .C_USE_ECC_WACH(0), .C_USE_ECC_WDCH(0), .C_USE_ECC_WRCH(0), .C_USE_EMBEDDED_REG(0), .C_USE_FIFO16_FLAGS(0), .C_USE_FWFT_DATA_COUNT(0), .C_VALID_LOW(0), .C_WR_ACK_LOW(0), .C_WR_DATA_COUNT_WIDTH(10), .C_WR_DEPTH(1024), .C_WR_DEPTH_AXIS(1024), .C_WR_DEPTH_RACH(32), .C_WR_DEPTH_RDCH(C_AXI_READ_FIFO_DEPTH), .C_WR_DEPTH_WACH(32), .C_WR_DEPTH_WDCH(C_AXI_WRITE_FIFO_DEPTH), .C_WR_DEPTH_WRCH(16), .C_WR_FREQ(1), .C_WR_PNTR_WIDTH(10), .C_WR_PNTR_WIDTH_AXIS(10), .C_WR_PNTR_WIDTH_RACH(5), .C_WR_PNTR_WIDTH_RDCH((C_AXI_READ_FIFO_DEPTH> 1) ? f_ceil_log2(C_AXI_READ_FIFO_DEPTH) : 1), .C_WR_PNTR_WIDTH_WACH(5), .C_WR_PNTR_WIDTH_WDCH((C_AXI_WRITE_FIFO_DEPTH > 1) ? f_ceil_log2(C_AXI_WRITE_FIFO_DEPTH) : 1), .C_WR_PNTR_WIDTH_WRCH(4), .C_WR_RESPONSE_LATENCY(1) ) fifo_gen_inst ( .s_aclk(aclk), .s_aresetn(aresetn), .s_axi_awid(s_axi_awid), .s_axi_awaddr(s_axi_awaddr), .s_axi_awlen(s_axi_awlen), .s_axi_awsize(s_axi_awsize), .s_axi_awburst(s_axi_awburst), .s_axi_awlock(s_axi_awlock), .s_axi_awcache(s_axi_awcache), .s_axi_awprot(s_axi_awprot), .s_axi_awqos(s_axi_awqos), .s_axi_awregion(s_axi_awregion_i), .s_axi_awuser(s_axi_awuser), .s_axi_awvalid(s_axi_awvalid), .s_axi_awready(s_axi_awready), .s_axi_wid(s_axi_wid_i), .s_axi_wdata(s_axi_wdata), .s_axi_wstrb(s_axi_wstrb), .s_axi_wlast(s_axi_wlast), .s_axi_wvalid(s_axi_wvalid), .s_axi_wready(s_axi_wready), .s_axi_bid(s_axi_bid), .s_axi_bresp(s_axi_bresp), .s_axi_bvalid(s_axi_bvalid), .s_axi_bready(s_axi_bready), .m_axi_awid(m_axi_awid), .m_axi_awaddr(m_axi_awaddr), .m_axi_awlen(m_axi_awlen), .m_axi_awsize(m_axi_awsize), .m_axi_awburst(m_axi_awburst), .m_axi_awlock(m_axi_awlock), .m_axi_awcache(m_axi_awcache), .m_axi_awprot(m_axi_awprot), .m_axi_awqos(m_axi_awqos), .m_axi_awregion(m_axi_awregion_i), .m_axi_awuser(m_axi_awuser), .m_axi_awvalid(m_axi_awvalid), .m_axi_awready(m_axi_awready), .m_axi_wid(m_axi_wid_i), .m_axi_wdata(m_axi_wdata), .m_axi_wstrb(m_axi_wstrb), .m_axi_wlast(m_axi_wlast), .m_axi_wvalid(m_axi_wvalid), .m_axi_wready(m_axi_wready), .m_axi_bid(m_axi_bid), .m_axi_bresp(m_axi_bresp), .m_axi_bvalid(m_axi_bvalid), .m_axi_bready(m_axi_bready), .s_axi_arid(s_axi_arid), .s_axi_araddr(s_axi_araddr), .s_axi_arlen(s_axi_arlen), .s_axi_arsize(s_axi_arsize), .s_axi_arburst(s_axi_arburst), .s_axi_arlock(s_axi_arlock), .s_axi_arcache(s_axi_arcache), .s_axi_arprot(s_axi_arprot), .s_axi_arqos(s_axi_arqos), .s_axi_arregion(s_axi_arregion_i), .s_axi_arvalid(s_axi_arvalid), .s_axi_arready(s_axi_arready), .s_axi_rid(s_axi_rid), .s_axi_rdata(s_axi_rdata), .s_axi_rresp(s_axi_rresp), .s_axi_rlast(s_axi_rlast), .s_axi_rvalid(s_axi_rvalid), .s_axi_rready(s_axi_rready), .m_axi_arid(m_axi_arid), .m_axi_araddr(m_axi_araddr), .m_axi_arlen(m_axi_arlen), .m_axi_arsize(m_axi_arsize), .m_axi_arburst(m_axi_arburst), .m_axi_arlock(m_axi_arlock), .m_axi_arcache(m_axi_arcache), .m_axi_arprot(m_axi_arprot), .m_axi_arqos(m_axi_arqos), .m_axi_arregion(m_axi_arregion_i), .m_axi_arvalid(m_axi_arvalid), .m_axi_arready(m_axi_arready), .m_axi_rid(m_axi_rid), .m_axi_rdata(m_axi_rdata), .m_axi_rresp(m_axi_rresp), .m_axi_rlast(m_axi_rlast), .m_axi_rvalid(m_axi_rvalid), .m_axi_rready(m_axi_rready), .m_aclk(aclk), .m_aclk_en(1'b1), .s_aclk_en(1'b1), .s_axi_wuser(s_axi_wuser), .s_axi_buser(s_axi_buser), .m_axi_wuser(m_axi_wuser), .m_axi_buser(m_axi_buser), .s_axi_aruser(s_axi_aruser), .s_axi_ruser(s_axi_ruser), .m_axi_aruser(m_axi_aruser), .m_axi_ruser(m_axi_ruser), .almost_empty(), .almost_full(), .axis_data_count(), .axis_dbiterr(), .axis_injectdbiterr(1'b0), .axis_injectsbiterr(1'b0), .axis_overflow(), .axis_prog_empty(), .axis_prog_empty_thresh(10'b0), .axis_prog_full(), .axis_prog_full_thresh(10'b0), .axis_rd_data_count(), .axis_sbiterr(), .axis_underflow(), .axis_wr_data_count(), .axi_ar_data_count(), .axi_ar_dbiterr(), .axi_ar_injectdbiterr(1'b0), .axi_ar_injectsbiterr(1'b0), .axi_ar_overflow(), .axi_ar_prog_empty(), .axi_ar_prog_empty_thresh(5'b0), .axi_ar_prog_full(), .axi_ar_prog_full_thresh(5'b0), .axi_ar_rd_data_count(), .axi_ar_sbiterr(), .axi_ar_underflow(), .axi_ar_wr_data_count(), .axi_aw_data_count(), .axi_aw_dbiterr(), .axi_aw_injectdbiterr(1'b0), .axi_aw_injectsbiterr(1'b0), .axi_aw_overflow(), .axi_aw_prog_empty(), .axi_aw_prog_empty_thresh(5'b0), .axi_aw_prog_full(), .axi_aw_prog_full_thresh(5'b0), .axi_aw_rd_data_count(), .axi_aw_sbiterr(), .axi_aw_underflow(), .axi_aw_wr_data_count(), .axi_b_data_count(), .axi_b_dbiterr(), .axi_b_injectdbiterr(1'b0), .axi_b_injectsbiterr(1'b0), .axi_b_overflow(), .axi_b_prog_empty(), .axi_b_prog_empty_thresh(4'b0), .axi_b_prog_full(), .axi_b_prog_full_thresh(4'b0), .axi_b_rd_data_count(), .axi_b_sbiterr(), .axi_b_underflow(), .axi_b_wr_data_count(), .axi_r_data_count(), .axi_r_dbiterr(), .axi_r_injectdbiterr(1'b0), .axi_r_injectsbiterr(1'b0), .axi_r_overflow(), .axi_r_prog_empty(), .axi_r_prog_empty_thresh({P_READ_FIFO_DEPTH_LOG{1'b0}}), .axi_r_prog_full(), .axi_r_prog_full_thresh({P_READ_FIFO_DEPTH_LOG{1'b0}}), .axi_r_rd_data_count(), .axi_r_sbiterr(), .axi_r_underflow(), .axi_r_wr_data_count(), .axi_w_data_count(), .axi_w_dbiterr(), .axi_w_injectdbiterr(1'b0), .axi_w_injectsbiterr(1'b0), .axi_w_overflow(), .axi_w_prog_empty(), .axi_w_prog_empty_thresh({P_WRITE_FIFO_DEPTH_LOG{1'b0}}), .axi_w_prog_full(), .axi_w_prog_full_thresh({P_WRITE_FIFO_DEPTH_LOG{1'b0}}), .axi_w_rd_data_count(), .axi_w_sbiterr(), .axi_w_underflow(), .axi_w_wr_data_count(), .backup(1'b0), .backup_marker(1'b0), .clk(1'b0), .data_count(), .dbiterr(), .din(18'b0), .dout(), .empty(), .full(), .injectdbiterr(1'b0), .injectsbiterr(1'b0), .int_clk(1'b0), .m_axis_tdata(), .m_axis_tdest(), .m_axis_tid(), .m_axis_tkeep(), .m_axis_tlast(), .m_axis_tready(1'b0), .m_axis_tstrb(), .m_axis_tuser(), .m_axis_tvalid(), .overflow(), .prog_empty(), .prog_empty_thresh(10'b0), .prog_empty_thresh_assert(10'b0), .prog_empty_thresh_negate(10'b0), .prog_full(), .prog_full_thresh(10'b0), .prog_full_thresh_assert(10'b0), .prog_full_thresh_negate(10'b0), .rd_clk(1'b0), .rd_data_count(), .rd_en(1'b0), .rd_rst(1'b0), .rst(1'b0), .sbiterr(), .srst(1'b0), .s_axis_tdata(64'b0), .s_axis_tdest(4'b0), .s_axis_tid(8'b0), .s_axis_tkeep(4'b0), .s_axis_tlast(1'b0), .s_axis_tready(), .s_axis_tstrb(4'b0), .s_axis_tuser(4'b0), .s_axis_tvalid(1'b0), .underflow(), .valid(), .wr_ack(), .wr_clk(1'b0), .wr_data_count(), .wr_en(1'b0), .wr_rst(1'b0), .wr_rst_busy(), .rd_rst_busy(), .sleep(1'b0) ); end endgenerate endmodule
module wb_arbiter_tb #(parameter NUM_MASTERS = 5) (input wb_clk_i, input wb_rst_i, output done); localparam aw = 32; localparam dw = 32; localparam MEMORY_SIZE_BITS = 8; localparam MEMORY_SIZE_WORDS = 2*MEMORY_SIZE_BITS; wire [aw-1:0] wbs_m2s_adr; wire [dw-1:0] wbs_m2s_dat; wire [3:0] wbs_m2s_sel; wire wbs_m2s_we ; wire wbs_m2s_cyc; wire wbs_m2s_stb; wire [2:0] wbs_m2s_cti; wire [1:0] wbs_m2s_bte; wire [dw-1:0] wbs_s2m_dat; wire wbs_s2m_ack; wire wbs_s2m_err; wire wbs_s2m_rty; wire [NUM_MASTERSaw-1:0] wbm_m2s_adr; wire [NUM_MASTERSdw-1:0] wbm_m2s_dat; wire [NUM_MASTERS4-1:0] wbm_m2s_sel; wire [NUM_MASTERS-1:0] wbm_m2s_we ; wire [NUM_MASTERS-1:0] wbm_m2s_cyc; wire [NUM_MASTERS-1:0] wbm_m2s_stb; wire [NUM_MASTERS3-1:0] wbm_m2s_cti; wire [NUM_MASTERS2-1:0] wbm_m2s_bte; wire [NUM_MASTERSdw-1:0] wbm_s2m_dat; wire [NUM_MASTERS-1:0] wbm_s2m_ack; wire [NUM_MASTERS-1:0] wbm_s2m_err; wire [NUM_MASTERS-1:0] wbm_s2m_rty; wire [31:0] slave_writes; wire [31:0] slave_reads; wire [NUM_MASTERS-1:0] done_int; genvar i; generate for(i=0;i<NUM_MASTERS;i=i+1) begin : masters wb_bfm_transactor #(.MEM_HIGH((i+1)MEMORY_SIZE_WORDS-1), .MEM_LOW (iMEMORY_SIZE_WORDS)) wb_bfm_transactor0 (.wb_clk_i (wb_clk_i), .wb_rst_i (wb_rst_i), .wb_adr_o (wbm_m2s_adr[iaw+:aw]), .wb_dat_o (wbm_m2s_dat[idw+:dw]), .wb_sel_o (wbm_m2s_sel[i4+:4]), .wb_we_o (wbm_m2s_we[i] ), .wb_cyc_o (wbm_m2s_cyc[i]), .wb_stb_o (wbm_m2s_stb[i]), .wb_cti_o (wbm_m2s_cti[i3+:3]), .wb_bte_o (wbm_m2s_bte[i2+:2]), .wb_dat_i (wbm_s2m_dat[idw+:dw]), .wb_ack_i (wbm_s2m_ack[i]), .wb_err_i (wbm_s2m_err[i]), .wb_rty_i (wbm_s2m_rty[i]), //Test Control .done(done_int[i])); end // block: slaves endgenerate integer idx; assign done = &done_int; always @(done) begin if(done === 1) begin $display("Average wait times"); for(idx=0;idx<NUM_MASTERS;idx=idx+1) $display("Master %0d : %f",idx, ack_delay[idx]/num_transactions[idx]); $display("All tests passed!"); end end wb_arbiter #(.num_masters(NUM_MASTERS)) wb_arbiter0 (.wb_clk_i (wb_clk_i), .wb_rst_i (wb_rst_i), // Master Interface .wbm_adr_i (wbm_m2s_adr), .wbm_dat_i (wbm_m2s_dat), .wbm_sel_i (wbm_m2s_sel), .wbm_we_i (wbm_m2s_we ), .wbm_cyc_i (wbm_m2s_cyc), .wbm_stb_i (wbm_m2s_stb), .wbm_cti_i (wbm_m2s_cti), .wbm_bte_i (wbm_m2s_bte), .wbm_dat_o (wbm_s2m_dat), .wbm_ack_o (wbm_s2m_ack), .wbm_err_o (wbm_s2m_err), .wbm_rty_o (wbm_s2m_rty), // Wishbone Slave interface .wbs_adr_o (wbs_m2s_adr), .wbs_dat_o (wbs_m2s_dat), .wbs_sel_o (wbs_m2s_sel), .wbs_we_o (wbs_m2s_we), .wbs_cyc_o (wbs_m2s_cyc), .wbs_stb_o (wbs_m2s_stb), .wbs_cti_o (wbs_m2s_cti), .wbs_bte_o (wbs_m2s_bte), .wbs_dat_i (wbs_s2m_dat), .wbs_ack_i (wbs_s2m_ack), .wbs_err_i (wbs_s2m_err), .wbs_rty_i (wbs_s2m_rty)); assign slave_writes = wb_mem_model0.writes; assign slave_reads = wb_mem_model0.reads; time start_time[NUM_MASTERS-1:0]; time ack_delay[NUM_MASTERS-1:0]; integer num_transactions[NUM_MASTERS-1:0]; generate for(i=0;i<NUM_MASTERS;i=i+1) begin : wait_time initial begin ack_delay[i] = 0; num_transactions[i] = 0; while(1) begin @(posedge wbm_m2s_cyc[i]); start_time[i] = $time; @(posedge wbm_s2m_ack[i]); ack_delay[i] = ack_delay[i] + $time-start_time[i]; num_transactions[i] = num_transactions[i]+1; end end end endgenerate wb_bfm_memory #(.DEBUG (0), .mem_size_bytes(MEMORY_SIZE_WORDS(dw/8)*NUM_MASTERS)) wb_mem_model0 (.wb_clk_i (wb_clk_i), .wb_rst_i (wb_rst_i), .wb_adr_i (wbs_m2s_adr), .wb_dat_i (wbs_m2s_dat), .wb_sel_i (wbs_m2s_sel), .wb_we_i (wbs_m2s_we), .wb_cyc_i (wbs_m2s_cyc), .wb_stb_i (wbs_m2s_stb), .wb_cti_i (wbs_m2s_cti), .wb_bte_i (wbs_m2s_bte), .wb_dat_o (wbs_s2m_dat), .wb_ack_o (wbs_s2m_ack), .wb_err_o (wbs_s2m_err), .wb_rty_o (wbs_s2m_rty)); endmodule
/** * This is written by Zhiyang Ong * and Andrew Mattheisen * for EE577b Troy WideWord Processor Project * * * @reminder December 1, 2007 * Remember to remove wrbyteen and ctrl_ppp from the inputs to * the ALU and its testbench / /* * Reference: * Nestoras Tzartzanis, EE 577B Verilog Example, Jan 25, 1996 * http://www-scf.usc.edu/~ee577/tutorial/verilog/alu.v / /* * Note that all instructions are 32-bits, and that Big-Endian * byte and bit labeling is used. Hence, a[0] is the most * significant bit, and a[31] is the least significant bit. * * Use of casex and casez may affect functionality, and produce * larger and slower designs that omit the full_case directive * * Reference: * Don Mills and Clifford E. Cummings, "RTL Coding Styles That * Yield Simulation and Synthesis Mismatches", SNUG 1999 * * ALU is a combinational logic block without clock signals / `include "/auto/home-scf-07/zhiyango/ee577b/projs/processor/syn/src/control.h" // Behavioral model for the ALU module alu (reg_A,reg_B,ctrl_ww,alu_op,result); // Output signals... // Result from copmputing an arithmetic or logical operation output [0:127] result; /* * Overflow fromn arithmetic operations are ignored; use * saturating mode for arithmetic operations - cap the value * at the maximum value. * * Also, an output signal to indicate that an overflow has * occurred will not be provided / // =============================================================== // Input signals // Input register A input [0:127] reg_A; // Input register B input [0:127] reg_B; // Control signal bits - ww input [0:1] ctrl_ww; /* * Control signal bits - determine which arithmetic or logic * operation to perform / input [0:4] alu_op; /* * May also include: branch_offset[n:0], is_branch * Size of branch offset is specified in the Instruction Set * Architecture * * The reset signal for the ALU is ignored / // Defining constants: parameter [name_of_constant] = value; // =============================================================== // Declare "wire" signals: //wire FSM_OUTPUT; // =============================================================== // Declare "reg" signals: reg [0:127] result; // Output signals // =============================================================== always @(reg_A or reg_B or ctrl_ww or alu_op) begin /* * Based on the assigned arithmetic or logic instruction, * carry out the appropriate function on the operands / case(alu_op) // ====================================================== // Unsigned Multiplication - even subfields `aluwmuleu: begin case(ctrl_ww) `w8: // aluwsrl AND `aa AND `w8 begin result[0:15]=reg_A[0:7]reg_B[0:7]; result[16:31]=reg_A[16:23]reg_B[16:23]; result[32:47]=reg_A[32:39]reg_B[32:39]; result[48:63]=reg_A[48:55]reg_B[48:55]; result[64:79]=reg_A[64:71]reg_B[64:71]; result[80:95]=reg_A[80:87]reg_B[80:87]; result[96:111]=reg_A[96:103]reg_B[96:103]; result[112:127]=reg_A[112:119]reg_B[112:119]; end `w16: // aluwsrl AND `aa AND `w16 begin result[0:31]=reg_A[0:15]reg_B[0:15]; result[32:63]=reg_A[32:47]reg_B[32:47]; result[64:95]=reg_A[64:79]reg_B[64:79]; result[96:127]=reg_A[96:111]reg_B[96:111]; end default: // aluwsrl AND `aa AND Default begin result=128'd0; end endcase end // Unsigned Multiplication - odd subfields `aluwmulou: begin case(ctrl_ww) `w8: // aluwsrl AND `aa AND `w8 begin result[0:15]=reg_A[8:15]reg_B[8:15]; result[16:31]=reg_A[24:31]reg_B[24:31]; result[32:47]=reg_A[40:47]reg_B[40:47]; result[48:63]=reg_A[56:63]reg_B[56:63]; result[64:79]=reg_A[72:79]reg_B[72:79]; result[80:95]=reg_A[88:95]reg_B[88:95]; result[96:111]=reg_A[104:111]reg_B[104:111]; result[112:127]=reg_A[120:127]reg_B[120:127]; end `w16: // aluwsrl AND `aa AND `w16 begin result[0:31]=reg_A[16:31]reg_B[16:31]; result[32:63]=reg_A[48:63]reg_B[48:63]; result[64:95]=reg_A[80:95]reg_B[80:95]; result[96:127]=reg_A[112:127]*reg_B[112:127]; end default: // aluwsrl AND `aa AND Default begin result=128'd0; end endcase end default: begin // Default arithmetic/logic operation result=128'd0; end endcase end endmodule
// -- verilog -- // // USRP - Universal Software Radio Peripheral // // Copyright (C) 2007 Corgan Enterprises LLC // // This program is free software; you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation; either version 2 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 51 Franklin Street, Boston, MA 02110-1301 USA // `include "../top/config.vh" module dac_interface(clk_i,rst_i,ena_i,strobe_i,tx_i_i,tx_q_i,tx_data_o,tx_sync_o); input clk_i; input rst_i; input ena_i; input strobe_i; input [13:0] tx_i_i; input [13:0] tx_q_i; output [13:0] tx_data_o; output tx_sync_o; `ifdef TX_RATE_MAX wire clk128; reg clk64_d; reg [13:0] tx_data_o; // Create a 128 MHz clock dacpll pll128(.areset(rst_i),.inclk0(clk_i),.c0(clk128)); // Register the clk64 clock in the clk128 domain always @(posedge clk128) clk64_d <= #1 clk_i; // Register the tx data in the clk128 domain always @(posedge clk128) tx_data_o <= #1 clk64_d ? tx_i_i : tx_q_i; assign tx_sync_o = clk64_d; `else // !`ifdef TX_RATE_MAX assign tx_data_o = strobe_i ? tx_q_i : tx_i_i; assign tx_sync_o = strobe_i; `endif // !`ifdef TX_RATE_MAX endmodule // dac_interface
//Legal Notice: (C)2019 Altera Corporation. All rights reserved. Your //use of Altera Corporation's design tools, logic functions and other //software and tools, and its AMPP partner logic functions, and any //output files any of the foregoing (including device programming or //simulation files), and any associated documentation or information are //expressly subject to the terms and conditions of the Altera Program //License Subscription Agreement or other applicable license agreement, //including, without limitation, that your use is for the sole purpose //of programming logic devices manufactured by Altera and sold by Altera //or its authorized distributors. Please refer to the applicable //agreement for further details. // synthesis translate_off `timescale 1ns / 1ps // synthesis translate_on // turn off superfluous verilog processor warnings // altera message_level Level1 // altera message_off 10034 10035 10036 10037 10230 10240 10030 module nios_dut_pio_0 ( // inputs: address, chipselect, clk, in_port, reset_n, write_n, writedata, // outputs: irq, readdata ) ; output irq; output [ 31: 0] readdata; input [ 1: 0] address; input chipselect; input clk; input in_port; input reset_n; input write_n; input [ 31: 0] writedata; wire clk_en; wire data_in; wire irq; reg irq_mask; wire read_mux_out; reg [ 31: 0] readdata; assign clk_en = 1; //s1, which is an e_avalon_slave assign read_mux_out = ({1 {(address == 0)}} & data_in) \| ({1 {(address == 2)}} & irq_mask); always @(posedge clk or negedge reset_n) begin if (reset_n == 0) readdata <= 0; else if (clk_en) readdata <= {32'b0 \| read_mux_out}; end assign data_in = in_port; always @(posedge clk or negedge reset_n) begin if (reset_n == 0) irq_mask <= 0; else if (chipselect && ~write_n && (address == 2)) irq_mask <= writedata; end assign irq = \|(data_in & irq_mask); endmodule
// -- (c) Copyright 2009 - 2011 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // File name: crossbar.v // // Description: // This module is a M-master to N-slave AXI axi_crossbar_v2_1_crossbar switch. // The interface of this module consists of a vectored slave and master interface // in which all slots are sized and synchronized to the native width and clock // of the interconnect. // The SAMD axi_crossbar_v2_1_crossbar supports only AXI4 and AXI3 protocols. // All width, clock and protocol conversions are done outside this block, as are // any pipeline registers or data FIFOs. // This module contains all arbitration, decoders and channel multiplexing logic. // It also contains the diagnostic registers and control interface. // //----------------------------------------------------------------------------- // // Structure: // crossbar // si_transactor // addr_decoder // comparator_static // mux_enc // axic_srl_fifo // arbiter_resp // splitter // wdata_router // axic_reg_srl_fifo // wdata_mux // axic_reg_srl_fifo // mux_enc // addr_decoder // comparator_static // axic_srl_fifo // axi_register_slice // addr_arbiter // mux_enc // decerr_slave // //----------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none (* DowngradeIPIdentifiedWarnings="yes" ) module axi_crossbar_v2_1_crossbar # ( parameter C_FAMILY = "none", parameter integer C_NUM_SLAVE_SLOTS = 1, parameter integer C_NUM_MASTER_SLOTS = 1, parameter integer C_NUM_ADDR_RANGES = 1, parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_ADDR_WIDTH = 32, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_PROTOCOL = 0, parameter [C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64-1:0] C_M_AXI_BASE_ADDR = {C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64{1'b1}}, parameter [C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64-1:0] C_M_AXI_HIGH_ADDR = {C_NUM_MASTER_SLOTSC_NUM_ADDR_RANGES64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS64-1:0] C_S_AXI_BASE_ID = {C_NUM_SLAVE_SLOTS64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS64-1:0] C_S_AXI_HIGH_ID = {C_NUM_SLAVE_SLOTS64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_THREAD_ID_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0, parameter integer C_AXI_AWUSER_WIDTH = 1, parameter integer C_AXI_ARUSER_WIDTH = 1, parameter integer C_AXI_WUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_BUSER_WIDTH = 1, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_WRITE = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_READ = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_WRITE = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_READ = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_WRITE_CONNECTIVITY = {C_NUM_MASTER_SLOTS32{1'b1}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_READ_CONNECTIVITY = {C_NUM_MASTER_SLOTS32{1'b1}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_SINGLE_THREAD = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_WRITE_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_READ_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_WRITE_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_READ_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_S_AXI_ARB_PRIORITY = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_SECURE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS32-1:0] C_M_AXI_ERR_MODE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter integer C_RANGE_CHECK = 0, parameter integer C_ADDR_DECODE = 0, parameter [(C_NUM_MASTER_SLOTS+1)32-1:0] C_W_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [(C_NUM_MASTER_SLOTS+1)32-1:0] C_R_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_W_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS32-1:0] C_R_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_DEBUG = 1 ) ( // Global Signals input wire ACLK, input wire ARESETN, // Slave Interface Write Address Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_AWID, input wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR, input wire [C_NUM_SLAVE_SLOTS8-1:0] S_AXI_AWLEN, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_AWSIZE, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_AWBURST, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_AWLOCK, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWCACHE, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_AWPROT, // input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWREGION, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_AWQOS, input wire [C_NUM_SLAVE_SLOTSC_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWREADY, // Slave Interface Write Data Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_WID, input wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH-1:0] S_AXI_WDATA, input wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WLAST, input wire [C_NUM_SLAVE_SLOTSC_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WREADY, // Slave Interface Write Response Ports output wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_BID, output wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_BRESP, output wire [C_NUM_SLAVE_SLOTSC_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BREADY, // Slave Interface Read Address Ports input wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_ARID, input wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR, input wire [C_NUM_SLAVE_SLOTS8-1:0] S_AXI_ARLEN, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_ARSIZE, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_ARBURST, input wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_ARLOCK, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARCACHE, input wire [C_NUM_SLAVE_SLOTS3-1:0] S_AXI_ARPROT, // input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARREGION, input wire [C_NUM_SLAVE_SLOTS4-1:0] S_AXI_ARQOS, input wire [C_NUM_SLAVE_SLOTSC_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARREADY, // Slave Interface Read Data Ports output wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] S_AXI_RID, output wire [C_NUM_SLAVE_SLOTSC_AXI_DATA_WIDTH-1:0] S_AXI_RDATA, output wire [C_NUM_SLAVE_SLOTS2-1:0] S_AXI_RRESP, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RLAST, output wire [C_NUM_SLAVE_SLOTSC_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RREADY, // Master Interface Write Address Port output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_AWID, output wire [C_NUM_MASTER_SLOTSC_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR, output wire [C_NUM_MASTER_SLOTS8-1:0] M_AXI_AWLEN, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_AWSIZE, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_AWBURST, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_AWLOCK, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWCACHE, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_AWPROT, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWREGION, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_AWQOS, output wire [C_NUM_MASTER_SLOTSC_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWREADY, // Master Interface Write Data Ports output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_WID, output wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH-1:0] M_AXI_WDATA, output wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WLAST, output wire [C_NUM_MASTER_SLOTSC_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WREADY, // Master Interface Write Response Ports input wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_BID, input wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_BRESP, input wire [C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BREADY, // Master Interface Read Address Port output wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_ARID, output wire [C_NUM_MASTER_SLOTSC_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR, output wire [C_NUM_MASTER_SLOTS8-1:0] M_AXI_ARLEN, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_ARSIZE, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_ARBURST, output wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_ARLOCK, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARCACHE, output wire [C_NUM_MASTER_SLOTS3-1:0] M_AXI_ARPROT, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARREGION, output wire [C_NUM_MASTER_SLOTS4-1:0] M_AXI_ARQOS, output wire [C_NUM_MASTER_SLOTSC_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARREADY, // Master Interface Read Data Ports input wire [C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH-1:0] M_AXI_RID, input wire [C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH-1:0] M_AXI_RDATA, input wire [C_NUM_MASTER_SLOTS2-1:0] M_AXI_RRESP, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RLAST, input wire [C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RREADY ); localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; localparam integer P_WRITE = 0; localparam integer P_READ = 1; localparam integer P_NUM_MASTER_SLOTS_LOG = f_ceil_log2(C_NUM_MASTER_SLOTS); localparam integer P_NUM_SLAVE_SLOTS_LOG = f_ceil_log2((C_NUM_SLAVE_SLOTS>1) ? C_NUM_SLAVE_SLOTS : 2); localparam integer P_AXI_WID_WIDTH = (C_AXI_PROTOCOL == P_AXI3) ? C_AXI_ID_WIDTH : 1; localparam integer P_ST_AWMESG_WIDTH = 2+4+4 + C_AXI_AWUSER_WIDTH; localparam integer P_AA_AWMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_AWMESG_WIDTH; localparam integer P_ST_ARMESG_WIDTH = 2+4+4 + C_AXI_ARUSER_WIDTH; localparam integer P_AA_ARMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_ARMESG_WIDTH; localparam integer P_ST_BMESG_WIDTH = 2 + C_AXI_BUSER_WIDTH; localparam integer P_ST_RMESG_WIDTH = 2 + C_AXI_RUSER_WIDTH + C_AXI_DATA_WIDTH; localparam integer P_WR_WMESG_WIDTH = C_AXI_DATA_WIDTH + C_AXI_DATA_WIDTH/8 + C_AXI_WUSER_WIDTH + P_AXI_WID_WIDTH; localparam [31:0] P_BYPASS = 32'h00000000; localparam [31:0] P_FWD_REV = 32'h00000001; localparam [31:0] P_SIMPLE = 32'h00000007; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_READ = {1'b1, C_M_AXI_SUPPORTS_READ[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_WRITE = {1'b1, C_M_AXI_SUPPORTS_WRITE[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_WRITE_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_WRITE_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS32]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_READ_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_READ_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS32]}; localparam [C_NUM_SLAVE_SLOTS32-1:0] P_S_AXI_WRITE_CONNECTIVITY = f_si_write_connectivity(0); localparam [C_NUM_SLAVE_SLOTS32-1:0] P_S_AXI_READ_CONNECTIVITY = f_si_read_connectivity(0); localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_READ_ISSUING = {32'h00000001, C_M_AXI_READ_ISSUING[0+:C_NUM_MASTER_SLOTS32]}; localparam [(C_NUM_MASTER_SLOTS+1)32-1:0] P_M_AXI_WRITE_ISSUING = {32'h00000001, C_M_AXI_WRITE_ISSUING[0+:C_NUM_MASTER_SLOTS32]}; localparam P_DECERR = 2'b11; //--------------------------------------------------------------------------- // Functions //--------------------------------------------------------------------------- // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2*acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction // Isolate thread bits of input S_ID and add to BASE_ID (RNG00) to form MI-side ID value // only for end-point SI-slots function [C_AXI_ID_WIDTH-1:0] f_extend_ID ( input [C_AXI_ID_WIDTH-1:0] s_id, input integer slot ); begin f_extend_ID = C_S_AXI_BASE_ID[slot64+:C_AXI_ID_WIDTH] \| (s_id & (C_S_AXI_BASE_ID[slot64+:C_AXI_ID_WIDTH] ^ C_S_AXI_HIGH_ID[slot64+:C_AXI_ID_WIDTH])); end endfunction // Write connectivity array transposed function [C_NUM_SLAVE_SLOTS32-1:0] f_si_write_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot32+mi_slot] = C_M_AXI_WRITE_CONNECTIVITY[mi_slot32+si_slot]; end end f_si_write_connectivity = result; end endfunction // Read connectivity array transposed function [C_NUM_SLAVE_SLOTS32-1:0] f_si_read_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot32+mi_slot] = C_M_AXI_READ_CONNECTIVITY[mi_slot32+si_slot]; end end f_si_read_connectivity = result; end endfunction genvar gen_si_slot; genvar gen_mi_slot; wire [C_NUM_SLAVE_SLOTSP_ST_AWMESG_WIDTH-1:0] si_st_awmesg ; wire [C_NUM_SLAVE_SLOTSP_ST_AWMESG_WIDTH-1:0] st_tmp_awmesg ; wire [C_NUM_SLAVE_SLOTSP_AA_AWMESG_WIDTH-1:0] tmp_aa_awmesg ; wire [P_AA_AWMESG_WIDTH-1:0] aa_mi_awmesg ; wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] st_aa_awid ; wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] st_aa_awaddr ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_awlen ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_awsize ; wire [C_NUM_SLAVE_SLOTS2-1:0] st_aa_awlock ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_awprot ; wire [C_NUM_SLAVE_SLOTS4-1:0] st_aa_awregion ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_awerror ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_awtarget_enc ; wire [P_NUM_SLAVE_SLOTS_LOG1-1:0] aa_wm_awgrant_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_awvalid_qual ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_ss_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_ss_awready ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_wr_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_wr_awready ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_aa_awvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] ss_aa_awready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] sa_wm_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] sa_wm_awready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awready ; wire aa_sa_awvalid ; wire aa_sa_awready ; wire aa_mi_arready ; wire mi_awvalid_en ; wire sa_wm_awvalid_en ; wire sa_wm_awready_mux ; wire [C_NUM_SLAVE_SLOTSP_ST_ARMESG_WIDTH-1:0] si_st_armesg ; wire [C_NUM_SLAVE_SLOTSP_ST_ARMESG_WIDTH-1:0] st_tmp_armesg ; wire [C_NUM_SLAVE_SLOTSP_AA_ARMESG_WIDTH-1:0] tmp_aa_armesg ; wire [P_AA_ARMESG_WIDTH-1:0] aa_mi_armesg ; wire [C_NUM_SLAVE_SLOTSC_AXI_ID_WIDTH-1:0] st_aa_arid ; wire [C_NUM_SLAVE_SLOTSC_AXI_ADDR_WIDTH-1:0] st_aa_araddr ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_arlen ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_arsize ; wire [C_NUM_SLAVE_SLOTS2-1:0] st_aa_arlock ; wire [C_NUM_SLAVE_SLOTS3-1:0] st_aa_arprot ; wire [C_NUM_SLAVE_SLOTS4-1:0] st_aa_arregion ; wire [C_NUM_SLAVE_SLOTS8-1:0] st_aa_arerror ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_artarget_hot ; wire [C_NUM_SLAVE_SLOTS(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_artarget_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_artarget_hot ; wire [P_NUM_SLAVE_SLOTS_LOG1-1:0] aa_mi_argrant_enc ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arvalid_qual ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arvalid ; wire [C_NUM_SLAVE_SLOTS1-1:0] st_aa_arready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_arvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_arready ; wire aa_mi_arvalid ; wire mi_awready_mux ; wire [C_NUM_SLAVE_SLOTSP_ST_BMESG_WIDTH-1:0] st_si_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)P_ST_BMESG_WIDTH-1:0] st_mr_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] st_mr_bid ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] st_mr_bresp ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_BUSER_WIDTH-1:0] st_mr_buser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_mr_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)P_NUM_SLAVE_SLOTS_LOG-1:0] debug_bid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] bid_match ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_bid ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] mi_bresp ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_BUSER_WIDTH-1:0] mi_buser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_bready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] bready_carry ; wire [C_NUM_SLAVE_SLOTSP_ST_RMESG_WIDTH-1:0] st_si_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)P_ST_RMESG_WIDTH-1:0] st_mr_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] st_mr_rid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] st_mr_rdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_RUSER_WIDTH-1:0] st_mr_ruser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rlast ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] st_mr_rresp ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] st_mr_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_mr_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)P_NUM_SLAVE_SLOTS_LOG-1:0] debug_rid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] rid_match ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_rid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] mi_rdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_RUSER_WIDTH-1:0] mi_ruser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rlast ; wire [(C_NUM_MASTER_SLOTS+1)2-1:0] mi_rresp ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_rready ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] rready_carry ; wire [C_NUM_SLAVE_SLOTSP_WR_WMESG_WIDTH-1:0] si_wr_wmesg ; wire [C_NUM_SLAVE_SLOTSP_WR_WMESG_WIDTH-1:0] wr_wm_wmesg ; wire [C_NUM_SLAVE_SLOTS1-1:0] wr_wm_wlast ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wvalid ; wire [C_NUM_SLAVE_SLOTS(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wready ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wready ; wire [(C_NUM_MASTER_SLOTS+1)P_WR_WMESG_WIDTH-1:0] wm_mr_wmesg ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] wm_mr_wdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH/8-1:0] wm_mr_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] wm_mr_wid ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_WUSER_WIDTH-1:0] wm_mr_wuser ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wlast ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] wm_mr_wready ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH-1:0] mi_wdata ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_DATA_WIDTH/8-1:0] mi_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_WUSER_WIDTH-1:0] mi_wuser ; wire [(C_NUM_MASTER_SLOTS+1)C_AXI_ID_WIDTH-1:0] mi_wid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wlast ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_wready ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] w_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] w_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] r_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] r_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_awmaxissuing ; wire [(C_NUM_MASTER_SLOTS+1)1-1:0] mi_armaxissuing ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] w_issuing_cnt ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] r_issuing_cnt ; reg [8-1:0] debug_aw_trans_seq_i ; reg [8-1:0] debug_ar_trans_seq_i ; wire [(C_NUM_MASTER_SLOTS+1)8-1:0] debug_w_trans_seq_i ; reg [(C_NUM_MASTER_SLOTS+1)8-1:0] debug_w_beat_cnt_i ; reg aresetn_d = 1'b0; // Reset delay register always @(posedge ACLK) begin if (~ARESETN) begin aresetn_d <= 1'b0; end else begin aresetn_d <= ARESETN; end end wire reset; assign reset = ~aresetn_d; generate for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_slave_slots if (C_S_AXI_SUPPORTS_READ[gen_si_slot]) begin : gen_si_read axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (read channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_READ), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_READ_ACCEPTANCE[gen_si_slot32+:32]), .C_ACCEPTANCE_LOG (C_R_ACCEPT_WIDTH[gen_si_slot32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_ARMESG_WIDTH), .C_RMESG_WIDTH (P_ST_RMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_READ_CONNECTIVITY[gen_si_slot32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_ar ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_ARID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_ARADDR[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_ARLEN[gen_si_slot8+:8]), .S_ASIZE (S_AXI_ARSIZE[gen_si_slot3+:3]), .S_ABURST (S_AXI_ARBURST[gen_si_slot2+:2]), .S_ALOCK (S_AXI_ARLOCK[gen_si_slot2+:2]), .S_APROT (S_AXI_ARPROT[gen_si_slot3+:3]), // .S_AREGION (S_AXI_ARREGION[gen_si_slot4+:4]), .S_AMESG (si_st_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .S_AVALID (S_AXI_ARVALID[gen_si_slot]), .S_AREADY (S_AXI_ARREADY[gen_si_slot]), .M_AID (st_aa_arid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_araddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_arlen[gen_si_slot8+:8]), .M_ASIZE (st_aa_arsize[gen_si_slot3+:3]), .M_ALOCK (st_aa_arlock[gen_si_slot2+:2]), .M_APROT (st_aa_arprot[gen_si_slot3+:3]), .M_AREGION (st_aa_arregion[gen_si_slot4+:4]), .M_AMESG (st_tmp_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .M_ATARGET_HOT (st_aa_artarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_artarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_arerror[gen_si_slot8+:8]), .M_AVALID_QUAL (st_aa_arvalid_qual[gen_si_slot]), .M_AVALID (st_aa_arvalid[gen_si_slot]), .M_AREADY (st_aa_arready[gen_si_slot]), .S_RID (S_AXI_RID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH]), .S_RLAST (S_AXI_RLAST[gen_si_slot]), .S_RVALID (S_AXI_RVALID[gen_si_slot]), .S_RREADY (S_AXI_RREADY[gen_si_slot]), .M_RID (st_mr_rid), .M_RLAST (st_mr_rlast), .M_RMESG (st_mr_rmesg), .M_RVALID (st_mr_rvalid), .M_RREADY (st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_rid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_ar_trans_seq_i : 8'h0) ); assign si_st_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH] = { S_AXI_ARUSER[gen_si_slotC_AXI_ARUSER_WIDTH+:C_AXI_ARUSER_WIDTH], S_AXI_ARQOS[gen_si_slot4+:4], S_AXI_ARCACHE[gen_si_slot4+:4], S_AXI_ARBURST[gen_si_slot2+:2] }; assign tmp_aa_armesg[gen_si_slotP_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = { st_tmp_armesg[gen_si_slotP_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH], st_aa_arregion[gen_si_slot4+:4], st_aa_arprot[gen_si_slot3+:3], st_aa_arlock[gen_si_slot2+:2], st_aa_arsize[gen_si_slot3+:3], st_aa_arlen[gen_si_slot8+:8], st_aa_araddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_arid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_RRESP[gen_si_slot2+:2] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+:2]; assign S_AXI_RUSER[gen_si_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+2 +: C_AXI_RUSER_WIDTH]; assign S_AXI_RDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = st_si_rmesg[gen_si_slotP_ST_RMESG_WIDTH+2+C_AXI_RUSER_WIDTH +: C_AXI_DATA_WIDTH]; end else begin : gen_no_si_read assign S_AXI_ARREADY[gen_si_slot] = 1'b0; assign st_aa_arvalid[gen_si_slot] = 1'b0; assign st_aa_arvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_armesg[gen_si_slotP_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = 0; assign S_AXI_RID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_RRESP[gen_si_slot2+:2] = 0; assign S_AXI_RUSER[gen_si_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign S_AXI_RDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign S_AXI_RVALID[gen_si_slot] = 1'b0; assign S_AXI_RLAST[gen_si_slot] = 1'b0; assign st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_artarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_read if (C_S_AXI_SUPPORTS_WRITE[gen_si_slot]) begin : gen_si_write axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (write channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_WRITE), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_WRITE_ACCEPTANCE[gen_si_slot32+:32]), .C_ACCEPTANCE_LOG (C_W_ACCEPT_WIDTH[gen_si_slot32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_AWMESG_WIDTH), .C_RMESG_WIDTH (P_ST_BMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_WRITE_CONNECTIVITY[gen_si_slot32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_aw ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_AWID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_AWADDR[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_AWLEN[gen_si_slot8+:8]), .S_ASIZE (S_AXI_AWSIZE[gen_si_slot3+:3]), .S_ABURST (S_AXI_AWBURST[gen_si_slot2+:2]), .S_ALOCK (S_AXI_AWLOCK[gen_si_slot2+:2]), .S_APROT (S_AXI_AWPROT[gen_si_slot3+:3]), // .S_AREGION (S_AXI_AWREGION[gen_si_slot4+:4]), .S_AMESG (si_st_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .S_AVALID (S_AXI_AWVALID[gen_si_slot]), .S_AREADY (S_AXI_AWREADY[gen_si_slot]), .M_AID (st_aa_awid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_awaddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_awlen[gen_si_slot8+:8]), .M_ASIZE (st_aa_awsize[gen_si_slot3+:3]), .M_ALOCK (st_aa_awlock[gen_si_slot2+:2]), .M_APROT (st_aa_awprot[gen_si_slot3+:3]), .M_AREGION (st_aa_awregion[gen_si_slot4+:4]), .M_AMESG (st_tmp_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .M_ATARGET_HOT (st_aa_awtarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_awtarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_awerror[gen_si_slot8+:8]), .M_AVALID_QUAL (st_aa_awvalid_qual[gen_si_slot]), .M_AVALID (st_ss_awvalid[gen_si_slot]), .M_AREADY (st_ss_awready[gen_si_slot]), .S_RID (S_AXI_BID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH]), .S_RLAST (), .S_RVALID (S_AXI_BVALID[gen_si_slot]), .S_RREADY (S_AXI_BREADY[gen_si_slot]), .M_RID (st_mr_bid), .M_RLAST ({(C_NUM_MASTER_SLOTS+1){1'b1}}), .M_RMESG (st_mr_bmesg), .M_RVALID (st_mr_bvalid), .M_RREADY (st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_bid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_aw_trans_seq_i : 8'h0) ); // Note: Concatenation of mesg signals is from MSB to LSB; assignments that chop mesg signals appear in opposite order. assign si_st_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH] = { S_AXI_AWUSER[gen_si_slotC_AXI_AWUSER_WIDTH+:C_AXI_AWUSER_WIDTH], S_AXI_AWQOS[gen_si_slot4+:4], S_AXI_AWCACHE[gen_si_slot4+:4], S_AXI_AWBURST[gen_si_slot2+:2] }; assign tmp_aa_awmesg[gen_si_slotP_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = { st_tmp_awmesg[gen_si_slotP_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH], st_aa_awregion[gen_si_slot4+:4], st_aa_awprot[gen_si_slot3+:3], st_aa_awlock[gen_si_slot2+:2], st_aa_awsize[gen_si_slot3+:3], st_aa_awlen[gen_si_slot8+:8], st_aa_awaddr[gen_si_slotC_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_awid[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_BRESP[gen_si_slot2+:2] = st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+:2]; assign S_AXI_BUSER[gen_si_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = st_si_bmesg[gen_si_slotP_ST_BMESG_WIDTH+2 +: C_AXI_BUSER_WIDTH]; // AW SI-transactor transfer completes upon completion of both W-router address acceptance (command push) and AW arbitration axi_crossbar_v2_1_splitter # // "SS": Splitter from SI-Transactor (write channel) ( .C_NUM_M (2) ) splitter_aw_si ( .ACLK (ACLK), .ARESET (reset), .S_VALID (st_ss_awvalid[gen_si_slot]), .S_READY (st_ss_awready[gen_si_slot]), .M_VALID ({ss_wr_awvalid[gen_si_slot], ss_aa_awvalid[gen_si_slot]}), .M_READY ({ss_wr_awready[gen_si_slot], ss_aa_awready[gen_si_slot]}) ); axi_crossbar_v2_1_wdata_router # // "WR": Write data Router ( .C_FAMILY (C_FAMILY), .C_NUM_MASTER_SLOTS (C_NUM_MASTER_SLOTS+1), .C_SELECT_WIDTH (P_NUM_MASTER_SLOTS_LOG+1), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ACCEPT_WIDTH[gen_si_slot32+:6]) ) wdata_router_w ( .ACLK (ACLK), .ARESET (reset), // Write transfer input from the current SI-slot .S_WMESG (si_wr_wmesg[gen_si_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .S_WLAST (S_AXI_WLAST[gen_si_slot]), .S_WVALID (S_AXI_WVALID[gen_si_slot]), .S_WREADY (S_AXI_WREADY[gen_si_slot]), // Vector of write transfer outputs to each MI-slot's W-mux .M_WMESG (wr_wm_wmesg[gen_si_slot(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH]), .M_WLAST (wr_wm_wlast[gen_si_slot]), .M_WVALID (wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_WREADY (wr_tmp_wready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), // AW command push from local SI-slot .S_ASELECT (st_aa_awtarget_enc[gen_si_slot(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), // Target MI-slot .S_AVALID (ss_wr_awvalid[gen_si_slot]), .S_AREADY (ss_wr_awready[gen_si_slot]) ); assign si_wr_wmesg[gen_si_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH] = { ((C_AXI_PROTOCOL == P_AXI3) ? f_extend_ID(S_AXI_WID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot) : 1'b0), S_AXI_WUSER[gen_si_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH], S_AXI_WSTRB[gen_si_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8], S_AXI_WDATA[gen_si_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] }; end else begin : gen_no_si_write assign S_AXI_AWREADY[gen_si_slot] = 1'b0; assign ss_aa_awvalid[gen_si_slot] = 1'b0; assign st_aa_awvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_awmesg[gen_si_slotP_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = 0; assign S_AXI_BID[gen_si_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_BRESP[gen_si_slot2+:2] = 0; assign S_AXI_BUSER[gen_si_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign S_AXI_BVALID[gen_si_slot] = 1'b0; assign st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign S_AXI_WREADY[gen_si_slot] = 1'b0; assign wr_wm_wmesg[gen_si_slot(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH] = 0; assign wr_wm_wlast[gen_si_slot] = 1'b0; assign wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_awtarget_hot[gen_si_slot(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_write end // gen_slave_slots for (gen_mi_slot=0; gen_mi_slot<C_NUM_MASTER_SLOTS+1; gen_mi_slot=gen_mi_slot+1) begin : gen_master_slots if (P_M_AXI_SUPPORTS_READ[gen_mi_slot]) begin : gen_mi_read if (C_NUM_SLAVE_SLOTS>1) begin : gen_rid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_READ_CONNECTIVITY[gen_mi_slot32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) rid_decoder_inst ( .ADDR (st_mr_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_rid_target_i[gen_mi_slotP_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (rid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_rid_decoder assign tmp_mr_rid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign rid_match[gen_mi_slot] = 1'b1; end assign st_mr_rmesg[gen_mi_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = { st_mr_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH], st_mr_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH], st_mr_rresp[gen_mi_slot2+:2] }; end else begin : gen_no_mi_read assign tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign rid_match[gen_mi_slot] = 1'b0; assign st_mr_rmesg[gen_mi_slotP_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = 0; end // gen_mi_read if (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]) begin : gen_mi_write if (C_NUM_SLAVE_SLOTS>1) begin : gen_bid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_WRITE_CONNECTIVITY[gen_mi_slot32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) bid_decoder_inst ( .ADDR (st_mr_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_bid_target_i[gen_mi_slotP_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (bid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_bid_decoder assign tmp_mr_bid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign bid_match[gen_mi_slot] = 1'b1; end axi_crossbar_v2_1_wdata_mux # // "WM": Write data Mux, per MI-slot (incl error-handler) ( .C_FAMILY (C_FAMILY), .C_NUM_SLAVE_SLOTS (C_NUM_SLAVE_SLOTS), .C_SELECT_WIDTH (P_NUM_SLAVE_SLOTS_LOG), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]) ) wdata_mux_w ( .ACLK (ACLK), .ARESET (reset), // Vector of write transfer inputs from each SI-slot's W-router .S_WMESG (wr_wm_wmesg), .S_WLAST (wr_wm_wlast), .S_WVALID (tmp_wm_wvalid[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .S_WREADY (tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), // Write transfer output to the current MI-slot .M_WMESG (wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .M_WLAST (wm_mr_wlast[gen_mi_slot]), .M_WVALID (wm_mr_wvalid[gen_mi_slot]), .M_WREADY (wm_mr_wready[gen_mi_slot]), // AW command push from AW arbiter output .S_ASELECT (aa_wm_awgrant_enc), // SI-slot selected by arbiter .S_AVALID (sa_wm_awvalid[gen_mi_slot]), .S_AREADY (sa_wm_awready[gen_mi_slot]) ); if (C_DEBUG) begin : gen_debug_w // DEBUG WRITE BEAT COUNTER always @(posedge ACLK) begin if (reset) begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= 0; end else begin if (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot]) begin if (mi_wlast[gen_mi_slot]) begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= 0; end else begin debug_w_beat_cnt_i[gen_mi_slot8+:8] <= debug_w_beat_cnt_i[gen_mi_slot8+:8] + 1; end end end end // clocked process // DEBUG W-CHANNEL TRANSACTION SEQUENCE QUEUE axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]), .C_USE_FULL (0) ) debug_w_seq_fifo ( .ACLK (ACLK), .ARESET (reset), .S_MESG (debug_aw_trans_seq_i), .S_VALID (sa_wm_awvalid[gen_mi_slot]), .S_READY (), .M_MESG (debug_w_trans_seq_i[gen_mi_slot8+:8]), .M_VALID (), .M_READY (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot] & mi_wlast[gen_mi_slot]) ); end // gen_debug_w assign wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH +: C_AXI_DATA_WIDTH]; assign wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH +: C_AXI_DATA_WIDTH/8]; assign wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+C_AXI_DATA_WIDTH/8 +: C_AXI_WUSER_WIDTH]; assign wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = wm_mr_wmesg[gen_mi_slotP_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+(C_AXI_DATA_WIDTH/8)+C_AXI_WUSER_WIDTH +: P_AXI_WID_WIDTH]; assign st_mr_bmesg[gen_mi_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = { st_mr_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH], st_mr_bresp[gen_mi_slot2+:2] }; end else begin : gen_no_mi_write assign tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign bid_match[gen_mi_slot] = 1'b0; assign wm_mr_wvalid[gen_mi_slot] = 0; assign wm_mr_wlast[gen_mi_slot] = 0; assign wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = 0; assign wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = 0; assign wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign st_mr_bmesg[gen_mi_slotP_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = 0; assign tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign sa_wm_awready[gen_mi_slot] = 0; end // gen_mi_write for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_trans_si // Transpose handshakes from W-router (SxM) to W-mux (MxS). assign tmp_wm_wvalid[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot] = wr_tmp_wvalid[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; assign wr_tmp_wready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_wm_wready[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; // Transpose response enables from ID decoders (MxS) to si_transactors (SxM). assign st_tmp_bid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_bid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; assign st_tmp_rid_target[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_rid_target[gen_mi_slotC_NUM_SLAVE_SLOTS+gen_si_slot]; end // gen_trans_si assign bready_carry[gen_mi_slot] = st_tmp_bready[gen_mi_slot]; assign rready_carry[gen_mi_slot] = st_tmp_rready[gen_mi_slot]; for (gen_si_slot=1; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_resp_carry_si assign bready_carry[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_BREADY if ... bready_carry[(gen_si_slot-1)(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] \| // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_bready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates BREADY for that MI-slot. assign rready_carry[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_RREADY if ... rready_carry[(gen_si_slot-1)(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] \| // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_rready[gen_si_slot(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates RREADY for that MI-slot. end // gen_resp_carry_si assign w_cmd_push[gen_mi_slot] = mi_awvalid[gen_mi_slot] && mi_awready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_push[gen_mi_slot] = mi_arvalid[gen_mi_slot] && mi_arready[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; assign w_cmd_pop[gen_mi_slot] = st_mr_bvalid[gen_mi_slot] && st_mr_bready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_pop[gen_mi_slot] = st_mr_rvalid[gen_mi_slot] && st_mr_rready[gen_mi_slot] && st_mr_rlast[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; // Disqualify arbitration of SI-slot if targeted MI-slot has reached its issuing limit. assign mi_awmaxissuing[gen_mi_slot] = (w_issuing_cnt[gen_mi_slot8 +: (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] == P_M_AXI_WRITE_ISSUING[gen_mi_slot32 +: (C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)]) & ~w_cmd_pop[gen_mi_slot]; assign mi_armaxissuing[gen_mi_slot] = (r_issuing_cnt[gen_mi_slot8 +: (C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] == P_M_AXI_READ_ISSUING[gen_mi_slot32 +: (C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)]) & ~r_cmd_pop[gen_mi_slot]; always @(posedge ACLK) begin if (reset) begin w_issuing_cnt[gen_mi_slot8+:8] <= 0; // Some high-order bits remain constant 0 r_issuing_cnt[gen_mi_slot8+:8] <= 0; // Some high-order bits remain constant 0 end else begin if (w_cmd_push[gen_mi_slot] && ~w_cmd_pop[gen_mi_slot]) begin w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] + 1; end else if (w_cmd_pop[gen_mi_slot] && ~w_cmd_push[gen_mi_slot] && (\|w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)])) begin w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= w_issuing_cnt[gen_mi_slot8+:(C_W_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] - 1; end if (r_cmd_push[gen_mi_slot] && ~r_cmd_pop[gen_mi_slot]) begin r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] + 1; end else if (r_cmd_pop[gen_mi_slot] && ~r_cmd_push[gen_mi_slot] && (\|r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)])) begin r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] <= r_issuing_cnt[gen_mi_slot8+:(C_R_ISSUE_WIDTH[gen_mi_slot32+:6]+1)] - 1; end end end // Clocked process // Reg-slice must break combinatorial path from M_BID and M_RID inputs to M_BREADY and M_RREADY outputs. // (See m_rready_i and m_resp_en combinatorial assignments in si_transactor.) // Reg-slice incurs +1 latency, but no bubble-cycles. axi_register_slice_v2_1_axi_register_slice # // "MR": MI-side R/B-channel Reg-slice, per MI-slot (pass-through if only 1 SI-slot configured) ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL ((C_AXI_PROTOCOL == P_AXI3) ? P_AXI3 : P_AXI4), .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_ADDR_WIDTH (1), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (C_AXI_SUPPORTS_USER_SIGNALS), .C_AXI_AWUSER_WIDTH (1), .C_AXI_ARUSER_WIDTH (1), .C_AXI_WUSER_WIDTH (C_AXI_WUSER_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_REG_CONFIG_AW (P_BYPASS), .C_REG_CONFIG_AR (P_BYPASS), .C_REG_CONFIG_W (P_BYPASS), .C_REG_CONFIG_R (P_M_AXI_SUPPORTS_READ[gen_mi_slot] ? P_FWD_REV : P_BYPASS), .C_REG_CONFIG_B (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot] ? P_SIMPLE : P_BYPASS) ) reg_slice_mi ( .aresetn (ARESETN), .aclk (ACLK), .s_axi_awid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_awaddr ({1{1'b0}}), .s_axi_awlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_awsize ({3{1'b0}}), .s_axi_awburst ({2{1'b0}}), .s_axi_awlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_awcache ({4{1'b0}}), .s_axi_awprot ({3{1'b0}}), .s_axi_awregion ({4{1'b0}}), .s_axi_awqos ({4{1'b0}}), .s_axi_awuser ({1{1'b0}}), .s_axi_awvalid ({1{1'b0}}), .s_axi_awready (), .s_axi_wid (wm_mr_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .s_axi_wdata (wm_mr_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .s_axi_wstrb (wm_mr_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .s_axi_wlast (wm_mr_wlast[gen_mi_slot]), .s_axi_wuser (wm_mr_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .s_axi_wvalid (wm_mr_wvalid[gen_mi_slot]), .s_axi_wready (wm_mr_wready[gen_mi_slot]), .s_axi_bid (st_mr_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_bresp (st_mr_bresp[gen_mi_slot2+:2] ), .s_axi_buser (st_mr_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .s_axi_bvalid (st_mr_bvalid[gen_mi_slot1+:1] ), .s_axi_bready (st_mr_bready[gen_mi_slot1+:1] ), .s_axi_arid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_araddr ({1{1'b0}}), .s_axi_arlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_arsize ({3{1'b0}}), .s_axi_arburst ({2{1'b0}}), .s_axi_arlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_arcache ({4{1'b0}}), .s_axi_arprot ({3{1'b0}}), .s_axi_arregion ({4{1'b0}}), .s_axi_arqos ({4{1'b0}}), .s_axi_aruser ({1{1'b0}}), .s_axi_arvalid ({1{1'b0}}), .s_axi_arready (), .s_axi_rid (st_mr_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_rdata (st_mr_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .s_axi_rresp (st_mr_rresp[gen_mi_slot2+:2] ), .s_axi_rlast (st_mr_rlast[gen_mi_slot1+:1] ), .s_axi_ruser (st_mr_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .s_axi_rvalid (st_mr_rvalid[gen_mi_slot1+:1] ), .s_axi_rready (st_mr_rready[gen_mi_slot1+:1] ), .m_axi_awid (), .m_axi_awaddr (), .m_axi_awlen (), .m_axi_awsize (), .m_axi_awburst (), .m_axi_awlock (), .m_axi_awcache (), .m_axi_awprot (), .m_axi_awregion (), .m_axi_awqos (), .m_axi_awuser (), .m_axi_awvalid (), .m_axi_awready ({1{1'b0}}), .m_axi_wid (mi_wid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .m_axi_wdata (mi_wdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .m_axi_wstrb (mi_wstrb[gen_mi_slotC_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .m_axi_wlast (mi_wlast[gen_mi_slot]), .m_axi_wuser (mi_wuser[gen_mi_slotC_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .m_axi_wvalid (mi_wvalid[gen_mi_slot]), .m_axi_wready (mi_wready[gen_mi_slot]), .m_axi_bid (mi_bid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_bresp (mi_bresp[gen_mi_slot2+:2] ), .m_axi_buser (mi_buser[gen_mi_slotC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .m_axi_bvalid (mi_bvalid[gen_mi_slot1+:1] ), .m_axi_bready (mi_bready[gen_mi_slot1+:1] ), .m_axi_arid (), .m_axi_araddr (), .m_axi_arlen (), .m_axi_arsize (), .m_axi_arburst (), .m_axi_arlock (), .m_axi_arcache (), .m_axi_arprot (), .m_axi_arregion (), .m_axi_arqos (), .m_axi_aruser (), .m_axi_arvalid (), .m_axi_arready ({1{1'b0}}), .m_axi_rid (mi_rid[gen_mi_slotC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_rdata (mi_rdata[gen_mi_slotC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .m_axi_rresp (mi_rresp[gen_mi_slot2+:2] ), .m_axi_rlast (mi_rlast[gen_mi_slot1+:1] ), .m_axi_ruser (mi_ruser[gen_mi_slotC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .m_axi_rvalid (mi_rvalid[gen_mi_slot1+:1] ), .m_axi_rready (mi_rready[gen_mi_slot1+:1] ) ); end // gen_master_slots (Next gen_mi_slot) // Highest row of ready_carry contains accumulated OR across all SI-slots, for each MI-slot. assign st_mr_bready = bready_carry[(C_NUM_SLAVE_SLOTS-1)(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; assign st_mr_rready = rready_carry[(C_NUM_SLAVE_SLOTS-1)(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; // Assign MI-side B, R and W channel ports (exclude error handler signals). assign mi_bid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] = M_AXI_BID; assign mi_bvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_BVALID; assign mi_bresp[0+:C_NUM_MASTER_SLOTS2] = M_AXI_BRESP; assign mi_buser[0+:C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH] = M_AXI_BUSER; assign M_AXI_BREADY = mi_bready[0+:C_NUM_MASTER_SLOTS]; assign mi_rid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] = M_AXI_RID; assign mi_rlast[0+:C_NUM_MASTER_SLOTS] = M_AXI_RLAST; assign mi_rvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_RVALID; assign mi_rresp[0+:C_NUM_MASTER_SLOTS2] = M_AXI_RRESP; assign mi_ruser[0+:C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH] = M_AXI_RUSER; assign mi_rdata[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH] = M_AXI_RDATA; assign M_AXI_RREADY = mi_rready[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WLAST = mi_wlast[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WVALID = mi_wvalid[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WUSER = mi_wuser[0+:C_NUM_MASTER_SLOTSC_AXI_WUSER_WIDTH]; assign M_AXI_WID = (C_AXI_PROTOCOL == P_AXI3) ? mi_wid[0+:C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH] : 0; assign M_AXI_WDATA = mi_wdata[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH]; assign M_AXI_WSTRB = mi_wstrb[0+:C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH/8]; assign mi_wready[0+:C_NUM_MASTER_SLOTS] = M_AXI_WREADY; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AW channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_AWMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_aw ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AW command request inputs .S_MESG (tmp_aa_awmesg), .S_TARGET_HOT (st_aa_awtarget_hot), .S_VALID (ss_aa_awvalid), .S_VALID_QUAL (st_aa_awvalid_qual), .S_READY (ss_aa_awready), // Granted AW command output .M_MESG (aa_mi_awmesg), .M_TARGET_HOT (aa_mi_awtarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_wm_awgrant_enc), // SI-slot index of granted command .M_VALID (aa_sa_awvalid), .M_READY (aa_sa_awready), .ISSUING_LIMIT (mi_awmaxissuing) ); // Broadcast AW transfer payload to all MI-slots assign M_AXI_AWID = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_AWADDR = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_AWLEN = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_AWSIZE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_AWLOCK = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_AWPROT = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_AWREGION = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_AWBURST = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_AWCACHE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_AWQOS = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_AWUSER = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_AWUSER_WIDTH]}}; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AR channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_ARMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_ar ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AR command request inputs .S_MESG (tmp_aa_armesg), .S_TARGET_HOT (st_aa_artarget_hot), .S_VALID_QUAL (st_aa_arvalid_qual), .S_VALID (st_aa_arvalid), .S_READY (st_aa_arready), // Granted AR command output .M_MESG (aa_mi_armesg), .M_TARGET_HOT (aa_mi_artarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_mi_argrant_enc), .M_VALID (aa_mi_arvalid), // SI-slot index of granted command .M_READY (aa_mi_arready), .ISSUING_LIMIT (mi_armaxissuing) ); if (C_DEBUG) begin : gen_debug_trans_seq // DEBUG WRITE TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_aw_trans_seq_i <= 1; end else begin if (aa_sa_awvalid && aa_sa_awready) begin debug_aw_trans_seq_i <= debug_aw_trans_seq_i + 1; end end end // DEBUG READ TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_ar_trans_seq_i <= 1; end else begin if (aa_mi_arvalid && aa_mi_arready) begin debug_ar_trans_seq_i <= debug_ar_trans_seq_i + 1; end end end end // gen_debug_trans_seq // Broadcast AR transfer payload to all MI-slots assign M_AXI_ARID = {C_NUM_MASTER_SLOTS{aa_mi_armesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_ARADDR = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_ARLEN = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_ARSIZE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_ARLOCK = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_ARPROT = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_ARREGION = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_ARBURST = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_ARCACHE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_ARQOS = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_ARUSER = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_ARUSER_WIDTH]}}; // AW arbiter command transfer completes upon completion of both M-side AW-channel transfer and W-mux address acceptance (command push). axi_crossbar_v2_1_splitter # // "SA": Splitter for Write Addr Arbiter ( .C_NUM_M (2) ) splitter_aw_mi ( .ACLK (ACLK), .ARESET (reset), .S_VALID (aa_sa_awvalid), .S_READY (aa_sa_awready), .M_VALID ({mi_awvalid_en, sa_wm_awvalid_en}), .M_READY ({mi_awready_mux, sa_wm_awready_mux}) ); assign mi_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{mi_awvalid_en}}; assign mi_awready_mux = \|(aa_mi_awtarget_hot & mi_awready); assign M_AXI_AWVALID = mi_awvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_awready[0+:C_NUM_MASTER_SLOTS] = M_AXI_AWREADY; assign sa_wm_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{sa_wm_awvalid_en}}; assign sa_wm_awready_mux = \|(aa_mi_awtarget_hot & sa_wm_awready); assign mi_arvalid = aa_mi_artarget_hot & {C_NUM_MASTER_SLOTS+1{aa_mi_arvalid}}; assign aa_mi_arready = \|(aa_mi_artarget_hot & mi_arready); assign M_AXI_ARVALID = mi_arvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_arready[0+:C_NUM_MASTER_SLOTS] = M_AXI_ARREADY; // MI-slot # C_NUM_MASTER_SLOTS is the error handler if (C_RANGE_CHECK) begin : gen_decerr_slave axi_crossbar_v2_1_decerr_slave # ( .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_RESP (P_DECERR) ) decerr_slave_inst ( .S_AXI_ACLK (ACLK), .S_AXI_ARESET (reset), .S_AXI_AWID (aa_mi_awmesg[0+:C_AXI_ID_WIDTH]), .S_AXI_AWVALID (mi_awvalid[C_NUM_MASTER_SLOTS]), .S_AXI_AWREADY (mi_awready[C_NUM_MASTER_SLOTS]), .S_AXI_WLAST (mi_wlast[C_NUM_MASTER_SLOTS]), .S_AXI_WVALID (mi_wvalid[C_NUM_MASTER_SLOTS]), .S_AXI_WREADY (mi_wready[C_NUM_MASTER_SLOTS]), .S_AXI_BID (mi_bid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_BRESP (mi_bresp[C_NUM_MASTER_SLOTS2+:2]), .S_AXI_BUSER (mi_buser[C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH]), .S_AXI_BVALID (mi_bvalid[C_NUM_MASTER_SLOTS]), .S_AXI_BREADY (mi_bready[C_NUM_MASTER_SLOTS]), .S_AXI_ARID (aa_mi_armesg[0+:C_AXI_ID_WIDTH]), .S_AXI_ARLEN (aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]), .S_AXI_ARVALID (mi_arvalid[C_NUM_MASTER_SLOTS]), .S_AXI_ARREADY (mi_arready[C_NUM_MASTER_SLOTS]), .S_AXI_RID (mi_rid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_RDATA (mi_rdata[C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .S_AXI_RRESP (mi_rresp[C_NUM_MASTER_SLOTS2+:2]), .S_AXI_RUSER (mi_ruser[C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH]), .S_AXI_RLAST (mi_rlast[C_NUM_MASTER_SLOTS]), .S_AXI_RVALID (mi_rvalid[C_NUM_MASTER_SLOTS]), .S_AXI_RREADY (mi_rready[C_NUM_MASTER_SLOTS]) ); end else begin : gen_no_decerr_slave assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_wready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_arready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_bid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_bresp[C_NUM_MASTER_SLOTS2+:2] = 0; assign mi_buser[C_NUM_MASTER_SLOTSC_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign mi_bvalid[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rid[C_NUM_MASTER_SLOTSC_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_rdata[C_NUM_MASTER_SLOTSC_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign mi_rresp[C_NUM_MASTER_SLOTS2+:2] = 0; assign mi_ruser[C_NUM_MASTER_SLOTSC_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign mi_rlast[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rvalid[C_NUM_MASTER_SLOTS] = 1'b0; end // gen_decerr_slave endgenerate endmodule `default_nettype wire
//----------------------------------------------------------------------------- // // (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. // // This file contains confidential and proprietary information // of Xilinx, Inc. and is protected under U.S. and // international copyright and other intellectual property // laws. // // DISCLAIMER // This disclaimer is not a license and does not grant any // rights to the materials distributed herewith. Except as // otherwise provided in a valid license issued to you by // Xilinx, and to the maximum extent permitted by applicable // law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // (2) Xilinx shall not be liable (whether in contract or tort, // including negligence, or under any other theory of // liability) for any loss or damage of any kind or nature // related to, arising under or in connection with these // materials, including for any direct, or any indirect, // special, incidental, or consequential loss or damage // (including loss of data, profits, goodwill, or any type of // loss or damage suffered as a result of any action brought // by a third party) even if such damage or loss was // reasonably foreseeable or Xilinx had been advised of the // possibility of the same. // // CRITICAL APPLICATIONS // Xilinx products are not designed or intended to be fail- // safe, or for use in any application requiring fail-safe // performance, such as life-support or safety devices or // systems, Class III medical devices, nuclear facilities, // applications related to the deployment of airbags, or any // other applications that could lead to death, personal // injury, or severe property or environmental damage // (individually and collectively, "Critical // Applications"). Customer assumes the sole risk and // liability of any use of Xilinx products in Critical // Applications, subject only to applicable laws and // regulations governing limitations on product liability. // // THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // PART OF THIS FILE AT ALL TIMES. // //----------------------------------------------------------------------------- // Project : Series-7 Integrated Block for PCI Express // File : pcie_7x_0_core_top_axi_basic_rx_null_gen.v // Version : 3.0 // // // Description: // // TRN to AXI RX null generator. Generates null packets for use in // // discontinue situations. // // // // Notes: // // Optional notes section. // // // // Hierarchical: // // axi_basic_top // // axi_basic_rx // // axi_basic_rx_null_gen // // // //----------------------------------------------------------------------------// `timescale 1ps/1ps (* DowngradeIPIdentifiedWarnings = "yes" ) module pcie_7x_0_core_top_axi_basic_rx_null_gen # ( parameter C_DATA_WIDTH = 128, // RX/TX interface data width parameter TCQ = 1, // Clock to Q time // Do not override parameters below this line parameter KEEP_WIDTH = C_DATA_WIDTH / 8 // KEEP width ) ( // AXI RX //----------- input [C_DATA_WIDTH-1:0] m_axis_rx_tdata, // RX data to user input m_axis_rx_tvalid, // RX data is valid input m_axis_rx_tready, // RX ready for data input m_axis_rx_tlast, // RX data is last input [21:0] m_axis_rx_tuser, // RX user signals // Null Inputs //----------- output null_rx_tvalid, // NULL generated tvalid output null_rx_tlast, // NULL generated tlast output [KEEP_WIDTH-1:0] null_rx_tkeep, // NULL generated tkeep output null_rdst_rdy, // NULL generated rdst_rdy output reg [4:0] null_is_eof, // NULL generated is_eof // System //----------- input user_clk, // user clock from block input user_rst // user reset from block ); localparam INTERFACE_WIDTH_DWORDS = (C_DATA_WIDTH == 128) ? 11'd4 : (C_DATA_WIDTH == 64) ? 11'd2 : 11'd1; //----------------------------------------------------------------------------// // NULL packet generator state machine // // This state machine shadows the AXI RX interface, tracking each packet as // // it's passed to the AXI user. When a multi-cycle packet is detected, the // // state machine automatically generates a "null" packet. In the event of a // // discontinue, the RX pipeline can switch over to this null packet as // // necessary. // //----------------------------------------------------------------------------// // State machine variables and states localparam IDLE = 0; localparam IN_PACKET = 1; reg cur_state; reg next_state; // Signals for tracking a packet on the AXI interface reg [11:0] reg_pkt_len_counter; reg [11:0] pkt_len_counter; wire [11:0] pkt_len_counter_dec; wire pkt_done; // Calculate packet fields, which are needed to determine total packet length. wire [11:0] new_pkt_len; wire [9:0] payload_len; wire [1:0] packet_fmt; wire packet_td; reg [3:0] packet_overhead; // Misc. wire [KEEP_WIDTH-1:0] eof_tkeep; wire straddle_sof; wire eof; // Create signals to detect sof and eof situations. These signals vary depending // on data width. assign eof = m_axis_rx_tuser[21]; generate if(C_DATA_WIDTH == 128) begin : sof_eof_128 assign straddle_sof = (m_axis_rx_tuser[14:13] == 2'b11); end else begin : sof_eof_64_32 assign straddle_sof = 1'b0; end endgenerate //----------------------------------------------------------------------------// // Calculate the length of the packet being presented on the RX interface. To // // do so, we need the relevent packet fields that impact total packet length. // // These are: // // - Header length: obtained from bit 1 of FMT field in 1st DWORD of header // // - Payload length: obtained from LENGTH field in 1st DWORD of header // // - TLP digest: obtained from TD field in 1st DWORD of header // // - Current data: the number of bytes that have already been presented // // on the data interface // // // // packet length = header + payload + tlp digest - # of DWORDS already // // transmitted // // // // packet_overhead is where we calculate everything except payload. // //----------------------------------------------------------------------------// generate if(C_DATA_WIDTH == 128) begin : len_calc_128 assign packet_fmt = straddle_sof ? m_axis_rx_tdata[94:93] : m_axis_rx_tdata[30:29]; assign packet_td = straddle_sof ? m_axis_rx_tdata[79] : m_axis_rx_tdata[15]; assign payload_len = packet_fmt[1] ? (straddle_sof ? m_axis_rx_tdata[73:64] : m_axis_rx_tdata[9:0]) : 10'h0; always @() begin // In 128-bit mode, the amount of data currently on the interface // depends on whether we're straddling or not. If so, 2 DWORDs have been // seen. If not, 4 DWORDs. case({packet_fmt[0], packet_td, straddle_sof}) // Header + TD - Data currently on interface 3'b0_0_0: packet_overhead = 4'd3 + 4'd0 - 4'd4; 3'b0_0_1: packet_overhead = 4'd3 + 4'd0 - 4'd2; 3'b0_1_0: packet_overhead = 4'd3 + 4'd1 - 4'd4; 3'b0_1_1: packet_overhead = 4'd3 + 4'd1 - 4'd2; 3'b1_0_0: packet_overhead = 4'd4 + 4'd0 - 4'd4; 3'b1_0_1: packet_overhead = 4'd4 + 4'd0 - 4'd2; 3'b1_1_0: packet_overhead = 4'd4 + 4'd1 - 4'd4; 3'b1_1_1: packet_overhead = 4'd4 + 4'd1 - 4'd2; endcase end assign new_pkt_len = {{9{packet_overhead[3]}}, packet_overhead[2:0]} + {2'b0, payload_len}; end else if(C_DATA_WIDTH == 64) begin : len_calc_64 assign packet_fmt = m_axis_rx_tdata[30:29]; assign packet_td = m_axis_rx_tdata[15]; assign payload_len = packet_fmt[1] ? m_axis_rx_tdata[9:0] : 10'h0; always @() begin // 64-bit mode: no straddling, so always 2 DWORDs case({packet_fmt[0], packet_td}) // Header + TD - Data currently on interface 2'b0_0: packet_overhead[1:0] = 2'b01 ;//4'd3 + 4'd0 - 4'd2; // 1 2'b0_1: packet_overhead[1:0] = 2'b10 ;//4'd3 + 4'd1 - 4'd2; // 2 2'b1_0: packet_overhead[1:0] = 2'b10 ;//4'd4 + 4'd0 - 4'd2; // 2 2'b1_1: packet_overhead[1:0] = 2'b11 ;//4'd4 + 4'd1 - 4'd2; // 3 endcase end assign new_pkt_len = {{10{1'b0}}, packet_overhead[1:0]} + {2'b0, payload_len}; end else begin : len_calc_32 assign packet_fmt = m_axis_rx_tdata[30:29]; assign packet_td = m_axis_rx_tdata[15]; assign payload_len = packet_fmt[1] ? m_axis_rx_tdata[9:0] : 10'h0; always @() begin // 32-bit mode: no straddling, so always 1 DWORD case({packet_fmt[0], packet_td}) // Header + TD - Data currently on interface 2'b0_0: packet_overhead = 4'd3 + 4'd0 - 4'd1; 2'b0_1: packet_overhead = 4'd3 + 4'd1 - 4'd1; 2'b1_0: packet_overhead = 4'd4 + 4'd0 - 4'd1; 2'b1_1: packet_overhead = 4'd4 + 4'd1 - 4'd1; endcase end assign new_pkt_len = {{9{packet_overhead[3]}}, packet_overhead[2:0]} + {2'b0, payload_len}; end endgenerate // Now calculate actual packet length, adding the packet overhead and the // payload length. This is signed math, so sign-extend packet_overhead. // NOTE: a payload length of zero means 1024 DW in the PCIe spec, but this // behavior isn't supported in our block. //assign new_pkt_len = // {{9{packet_overhead[3]}}, packet_overhead[2:0]} + {2'b0, payload_len}; // Math signals needed in the state machine below. These are seperate wires to // help ensure synthesis tools sre smart about optimizing them. assign pkt_len_counter_dec = reg_pkt_len_counter - INTERFACE_WIDTH_DWORDS; assign pkt_done = (reg_pkt_len_counter <= INTERFACE_WIDTH_DWORDS); //----------------------------------------------------------------------------// // Null generator Mealy state machine. Determine outputs based on: // // 1) current st // // 2) current inp // //----------------------------------------------------------------------------// always @() begin case (cur_state) // IDLE state: the interface is IDLE and we're waiting for a packet to // start. If a packet starts, move to state IN_PACKET and begin tracking // it as long as it's NOT a single cycle packet (indicated by assertion of // eof at packet start) IDLE: begin if(m_axis_rx_tvalid && m_axis_rx_tready && !eof) begin next_state = IN_PACKET; end else begin next_state = IDLE; end pkt_len_counter = new_pkt_len; end // IN_PACKET: a mutli-cycle packet is in progress and we're tracking it. We // are in lock-step with the AXI interface decrementing our packet length // tracking reg, and waiting for the packet to finish. // // If packet finished and a new one starts, this is a straddle situation. // Next state is IN_PACKET (128-bit only). // * If the current packet is done, next state is IDLE. // * Otherwise, next state is IN_PACKET. IN_PACKET: begin // Straddle packet if((C_DATA_WIDTH == 128) && straddle_sof && m_axis_rx_tvalid) begin pkt_len_counter = new_pkt_len; next_state = IN_PACKET; end // Current packet finished else if(m_axis_rx_tready && pkt_done) begin pkt_len_counter = new_pkt_len; next_state = IDLE; end // Packet in progress else begin if(m_axis_rx_tready) begin // Not throttled pkt_len_counter = pkt_len_counter_dec; end else begin // Throttled pkt_len_counter = reg_pkt_len_counter; end next_state = IN_PACKET; end end default: begin pkt_len_counter = reg_pkt_len_counter; next_state = IDLE; end endcase end // Synchronous NULL packet generator state machine logic always @(posedge user_clk) begin if(user_rst) begin cur_state <= #TCQ IDLE; reg_pkt_len_counter <= #TCQ 12'h0; end else begin cur_state <= #TCQ next_state; reg_pkt_len_counter <= #TCQ pkt_len_counter; end end // Generate tkeep/is_eof for an end-of-packet situation. generate if(C_DATA_WIDTH == 128) begin : strb_calc_128 always @() begin // Assign null_is_eof depending on how many DWORDs are left in the // packet. case(pkt_len_counter) 10'd1: null_is_eof = 5'b10011; 10'd2: null_is_eof = 5'b10111; 10'd3: null_is_eof = 5'b11011; 10'd4: null_is_eof = 5'b11111; default: null_is_eof = 5'b00011; endcase end // tkeep not used in 128-bit interface assign eof_tkeep = {KEEP_WIDTH{1'b0}}; end else if(C_DATA_WIDTH == 64) begin : strb_calc_64 always @() begin // Assign null_is_eof depending on how many DWORDs are left in the // packet. case(pkt_len_counter) 10'd1: null_is_eof = 5'b10011; 10'd2: null_is_eof = 5'b10111; default: null_is_eof = 5'b00011; endcase end // Assign tkeep to 0xFF or 0x0F depending on how many DWORDs are left in // the current packet. assign eof_tkeep = { ((pkt_len_counter == 12'd2) ? 4'hF:4'h0), 4'hF }; end else begin : strb_calc_32 always @(*) begin // is_eof is either on or off for 32-bit if(pkt_len_counter == 12'd1) begin null_is_eof = 5'b10011; end else begin null_is_eof = 5'b00011; end end // The entire DWORD is always valid in 32-bit mode, so tkeep is always 0xF assign eof_tkeep = 4'hF; end endgenerate // Finally, use everything we've generated to calculate our NULL outputs assign null_rx_tvalid = 1'b1; assign null_rx_tlast = (pkt_len_counter <= INTERFACE_WIDTH_DWORDS); assign null_rx_tkeep = null_rx_tlast ? eof_tkeep : {KEEP_WIDTH{1'b1}}; assign null_rdst_rdy = null_rx_tlast; endmodule
// // Copyright (c) 2012-2013 Jonathan Woodruff // Copyright (c) 2013 Bjoern A. Zeeb // Copyright (c) 2014 A. Theodore Markettos // Copyright (c) 2014 Robert M. Norton // All rights reserved. // // This software was developed by SRI International and the University of // Cambridge Computer Laboratory under DARPA/AFRL contract FA8750-10-C-0237 // ("CTSRD"), as part of the DARPA CRASH research programme. // // This software was developed by SRI International and the University of // Cambridge Computer Laboratory under DARPA/AFRL contract FA8750-11-C-0249 // ("MRC2"), as part of the DARPA MRC research programme. // // @BERI_LICENSE_HEADER_START@ // // Licensed to BERI Open Systems C.I.C. (BERI) under one or more contributor // license agreements. See the NOTICE file distributed with this work for // additional information regarding copyright ownership. BERI licenses this // file to you under the BERI Hardware-Software License, Version 1.0 (the // "License"); you may not use this file except in compliance with the // License. You may obtain a copy of the License at: // // http://www.beri-open-systems.org/legal/license-1-0.txt // // Unless required by applicable law or agreed to in writing, Work distributed // under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR // CONDITIONS OF ANY KIND, either express or implied. See the License for the // specific language governing permissions and limitations under the License. // // @BERI_LICENSE_HEADER_END@ // `define ENABLE_LED `define ENABLE_BUTTONS `define ENABLE_ETHERNET `define ENABLE_SDCARD `define ENABLE_UART `define ENABLE_DDR2_1 `define ENABLE_DIP `define ENABLE_SLIDE `define ENABLE_SEG `define ENABLE_TEMP `define ENABLE_CSENSE `define ENABLE_FLASH `define ENABLE_SSRAM `define ENABLE_USB `define ENABLE_HDMI `define ENABLE_MTL `ifndef ENABLE_DDR2_1 `ifndef ENABLE_DDR2_2 `define DISABLE_TERMINATION `endif `endif `ifndef ENABLE_FLASH `ifndef ENABLE_SSRAM `define DISABLE_FSM `endif `endif module DE4_BERI ( ////// clock inputs //input GCLKIN, //output GCLKOUT_FPGA, //inout [2:0] MAX_CONF_D, //output [2:0] MAX_PLL_D, input OSC_50_Bank2, input OSC_50_Bank3, input OSC_50_Bank4, //input OSC_50_Bank5, //input OSC_50_Bank6, //input OSC_50_Bank7, //input PLL_CLKIN_p, `ifdef ENABLE_LED output [7:0] LED, // 8x LEDs `endif `ifdef ENABLE_BUTTONS input [3:0] BUTTON, // 4x buttons `endif input CPU_RESET_n, //inout EXT_IO, `ifdef ENABLE_ETHERNET ////// Ethernet MAC x 4 input [3:0] ETH_INT_n, output [3:0] ETH_MDC, inout [3:0] ETH_MDIO, output ETH_RST_n, input [3:0] ETH_RX_p, output [3:0] ETH_TX_p, `endif `ifdef ENABLE_SDCARD ////// SD card socket output SD_CLK, inout SD_CMD, inout [3:0] SD_DAT, input SD_WP_n, `endif `ifdef ENABLE_UART ////// UART output UART_TXD, input UART_CTS, input UART_RXD, output UART_RTS, `endif `ifdef ENABLE_DDR2_1 ////// DDR2 SODIMM 1 output [15:0] M1_DDR2_addr, output [2:0] M1_DDR2_ba, output M1_DDR2_cas_n, output [1:0] M1_DDR2_cke, inout [1:0] M1_DDR2_clk, inout [1:0] M1_DDR2_clk_n, output [1:0] M1_DDR2_cs_n, output [7:0] M1_DDR2_dm, inout [63:0] M1_DDR2_dq, inout [7:0] M1_DDR2_dqs, inout [7:0] M1_DDR2_dqsn, output [1:0] M1_DDR2_odt, output M1_DDR2_ras_n, output [1:0] M1_DDR2_SA, output M1_DDR2_SCL, inout M1_DDR2_SDA, output M1_DDR2_we_n, `endif `ifdef ENABLE_DDR2_2 ////// DDR2 SODIMM 2 output [15:0] M2_DDR2_addr, output [2:0] M2_DDR2_ba, output M2_DDR2_cas_n, output [1:0] M2_DDR2_cke, inout [1:0] M2_DDR2_clk, inout [1:0] M2_DDR2_clk_n, output [1:0] M2_DDR2_cs_n, output [7:0] M2_DDR2_dm, inout [63:0] M2_DDR2_dq, inout [7:0] M2_DDR2_dqs, inout [7:0] M2_DDR2_dqsn, output [1:0] M2_DDR2_odt, output M2_DDR2_ras_n, output [1:0] M2_DDR2_SA, output M2_DDR2_SCL, inout M2_DDR2_SDA, output M2_DDR2_we_n, `endif `ifndef DISABLE_TERMINATION // termination for DDR2 DIMMs input termination_blk0_rup_pad, input termination_blk0_rdn_pad, `endif `ifdef ENABLE_DIP input [7:0] SW, // 8x DIP switches `endif `ifdef ENABLE_SLIDE input [3:0] SLIDE_SW, // 4x slide switches `endif `ifdef ENABLE_SEG // 2x 7-segment displays output [6:0] SEG0_D, output SEG0_DP, output [6:0] SEG1_D, output SEG1_DP, `endif `ifdef ENABLE_TEMP // temperature sensors input TEMP_INT_n, output TEMP_SMCLK, inout TEMP_SMDAT, `endif `ifdef ENABLE_CSENSE // current sensors output CSENSE_ADC_FO, output [1:0] CSENSE_CS_n, output CSENSE_SCK, output CSENSE_SDI, input CSENSE_SDO, `endif output FAN_CTRL, // fan control `ifndef DISABLE_FSM // flash and SRAM shared data bus output [25:1] FSM_A, inout [15:0] FSM_D, `endif `ifdef ENABLE_FLASH // Flash memory output FLASH_ADV_n, output FLASH_CE_n, output FLASH_CLK, output FLASH_OE_n, output FLASH_RESET_n, input FLASH_RYBY_n, output FLASH_WE_n, `endif `ifdef ENABLE_SSRAM // synchronous SRAM output SSRAM_ADV, output SSRAM_BWA_n, output SSRAM_BWB_n, output SSRAM_CE_n, output SSRAM_CKE_n, output SSRAM_CLK, output SSRAM_OE_n, output SSRAM_WE_n, `endif // HSMC port A and B `ifdef ENABLE_HDMI // HDMI interface board on HSMC port A //inout HDMI_SDA, //output HDMI_SCL, output [11:0] HDMI_TX_RD, output [11:0] HDMI_TX_GD, inout HDMI_TX_PCSCL, inout HDMI_TX_PCSDA, output HDMI_TX_RST_N, input HDMI_TX_INT_N, output [3:0] HDMI_TX_DSD_L, output [3:0] HDMI_TX_DSD_R, output [11:0] HDMI_TX_BD, output HDMI_TX_PCLK, output HDMI_TX_DCLK, output HDMI_TX_SCK, output HDMI_TX_WS, output HDMI_TX_MCLK, output [3:0] HDMI_TX_I2S, output HDMI_TX_DE, output HDMI_TX_VS, output HDMI_TX_HS, output HDMI_TX_SPDIF, inout HDMI_TX_CEC, `endif // GPIO port 0 input [31:0] GPIO0_D, `ifdef ENABLE_USB output [17:1] OTG_A, output OTG_CS_n, inout [31:0] OTG_D, output OTG_DC_DACK, input OTG_DC_DREQ, input OTG_DC_IRQ, output OTG_HC_DACK, input OTG_HC_DREQ, input OTG_HC_IRQ, output OTG_OE_n, output OTG_RESET_n, output OTG_WE_n, `endif `ifdef ENABLE_MTL // GPIO port 1 connect to MTL capacitive touch screen output mtl_dclk, output [7:0] mtl_r, output [7:0] mtl_g, output [7:0] mtl_b, output mtl_hsd, output mtl_vsd, output mtl_touch_i2cscl, inout mtl_touch_i2csda, input mtl_touch_int `endif `ifdef ENABLE_PCIE , //PCI Express input PCIE_PREST_n, input PCIE_REFCLK_p, //input HSMA_REFCLK_p, input [3:0] PCIE_RX_p, input PCIE_SMBCLK, inout PCIE_SMBDAT, output [3:0] PCIE_TX_p, output PCIE_WAKE_n `endif ); wire global_reset_n; wire enet_reset_n; //// Ethernet wire enet_mdc; wire enet_mdio_in; wire enet_mdio_oen; wire enet_mdio_out; wire enet_refclk_125MHz; wire lvds_rxp; wire lvds_txp; wire enet1_mdc; wire enet1_mdio_in; wire enet1_mdio_oen; wire enet1_mdio_out; wire lvds_rxp1; wire lvds_txp1; // Assign outputs that are not used to 0 //assign MAX_PLL_D = 3'b0; //assign ETH_MDC[3:1] = 3'b0; assign M1_DDR2_SA = 1'b0; assign CSENSE_CS_n = 1'b0; assign CSENSE_ADC_FO = 1'b0; assign CSENSE_SCK = 1'b0; assign CSENSE_SDI = 1'b0; //assign GCLKOUT_FPGA = 1'b0; assign M1_DDR2_SCL = 1'b0; //// Ethernet assign ETH_RST_n = rstn; assign ETH_TX_p[3:2] = 2'b0; assign lvds_rxp = ETH_RX_p[0]; assign ETH_TX_p[0] = lvds_txp; assign lvds_rxp1 = ETH_RX_p[1]; assign ETH_TX_p[1] = lvds_txp1; assign enet_mdio_in = ETH_MDIO[0]; assign enet1_mdio_in = ETH_MDIO[1]; assign ETH_MDIO[0] = (!enet_mdio_oen ? enet_mdio_out : 1'bz); assign ETH_MDIO[1] = (!enet1_mdio_oen ? enet1_mdio_out : 1'bz); // Allow the other two tri-state interfaces to float. assign ETH_MDIO[2] = 1'bz; assign ETH_MDIO[3] = 1'bz; assign ETH_MDC[0] = enet_mdc; assign ETH_MDC[1] = enet1_mdc; // Set unused interface clocks to high. assign ETH_MDC[2] = 1'b1; assign ETH_MDC[3] = 1'b1; wire clk100; wire [7:0] LED_n; assign LED = ~LED_n; // === Ethernet clock PLL pll_125 pll_125_ins ( .inclk0(OSC_50_Bank2), .c0(enet_refclk_125MHz) ); `ifdef ENABLE_PCIE wire clk125; //PCI Express clock pll_125 pll_125_pcie ( .inclk0(OSC_50_Bank2), .c0(clk125) ); assign reconfig_clk = OSC_50_Bank3; wire reconfig_fromgxb; wire reconfig_togxb; wire reconfig_busy; altgx_reconfig altgx_reconfig_pcie ( .reconfig_clk(reconfig_clk), .reconfig_fromgxb(reconfig_fromgxb), .busy(reconfig_busy), .reconfig_togxb(reconfig_togxb) ); `endif wire qsys_sysclk; wire qsys_sysreset_n; //wire sramClk; assign SSRAM_CLK = qsys_sysclk; (* keep = 1 ) wire clk27; display_pll display_pll_ins ( .inclk0(OSC_50_Bank2), .c0(clk27) ); assign HDMI_TX_PCLK = clk27; // synchronize reset signal reg rstn, rstn_metastable; always @(posedge OSC_50_Bank2) begin rstn_metastable <= CPU_RESET_n && GPIO0_D[2]; rstn <= rstn_metastable; end reg rstn100, rstn100_metastable; always @(posedge qsys_sysclk) begin rstn100_metastable <= CPU_RESET_n && GPIO0_D[2]; rstn100 <= rstn100_metastable; end ( noprune ) reg rstn27; reg rstn27sample; always @(posedge clk27) begin rstn27sample <= rstn; rstn27 <= rstn27sample; end reg [7:0] SW_P; always @(posedge OSC_50_Bank2) SW_P <= ~SW; // positive version of DIP switches assign SEG1_DP = ~1'b0; assign SEG0_DP = ~1'b0; reg [3:0] slide_sw_metastable, slide_sw_sync; always @(posedge OSC_50_Bank2) begin slide_sw_metastable <= SLIDE_SW; slide_sw_sync <= slide_sw_metastable; end // assign PCIE_WAKE_n = 1'b0; // assign PCIE_SMBDATA = 1'bz; / signals for the old Terasic resistive touch screen (currently unused) wire [7:0] vga_R, vga_G, vga_B; wire vga_DEN, vga_HD, vga_VD; assign vga_DEN = 1'b0; assign vga_HD = 1'b0; assign vga_VD = 1'b0; assign vga_R = 8'd0; assign vga_G = 8'd0; assign vga_B = 8'd0; assign lcdtouchLTM_R = vga_R; assign lcdtouchLTM_G = vga_G; assign lcdtouchLTM_B = vga_B; assign lcdtouchLTM_DEN = vga_DEN; assign lcdtouchLTM_HD = vga_HD; assign lcdtouchLTM_VD = vga_VD; assign lcdtouchLTM_GREST = rstn27; assign lcdtouchLTM_NCLK = clk27; assign lcdtouchLTM_SCEN = 1'b1; assign lcdtouchLTM_ADC_DCLK = 1'b1; assign lcdtouchLTM_ADC_DIN = 1'b1;/ // clock for multitouch screen assign mtl_dclk = clk27; ( keep = 1 ) wire ssram_data_outen; ( keep = 1 ) wire [15:0] ssram_data_out; // instantiate the touch screen controller provided by Terasic (encrypted block) reg touch_ready_0; reg [9:0] touch_x1_0, touch_x2_0; reg [8:0] touch_y1_0, touch_y2_0; reg [1:0] touch_count_0; reg [7:0] touch_gesture_0; reg touch_ready_1; reg [9:0] touch_x1_1, touch_x2_1; reg [8:0] touch_y1_1, touch_y2_1; reg [1:0] touch_count_1; reg [7:0] touch_gesture_1; wire touch_ready_2; wire [9:0] touch_x1_2, touch_x2_2; wire [8:0] touch_y1_2, touch_y2_2; wire [1:0] touch_count_2; wire [7:0] touch_gesture_2; i2c_touch_config touch( .iCLK(OSC_50_Bank2), .iRSTN(rstn), .iTRIG(!mtl_touch_int), // note that this signal is inverted .oREADY(touch_ready_2), .oREG_X1(touch_x1_2), .oREG_Y1(touch_y1_2), .oREG_X2(touch_x2_2), .oREG_Y2(touch_y2_2), .oREG_TOUCH_COUNT(touch_count_2), .oREG_GESTURE(touch_gesture_2), .I2C_SCLK(mtl_touch_i2cscl), .I2C_SDAT(mtl_touch_i2csda)); // synchronize signals to qsys system clock always @(posedge qsys_sysclk) begin touch_ready_1 <= touch_ready_2; touch_x1_1 <= touch_x1_2; touch_y1_1 <= touch_y1_2; touch_x2_1 <= touch_x2_2; touch_y2_1 <= touch_y2_2; touch_count_1 <= touch_count_2; touch_gesture_1 <= touch_gesture_2; touch_ready_0 <= touch_ready_1; touch_x1_0 <= touch_x1_1; touch_y1_0 <= touch_y1_1; touch_x2_0 <= touch_x2_1; touch_y2_0 <= touch_y2_1; touch_count_0 <= touch_count_1; touch_gesture_0 <= touch_gesture_1; end // touch screen controller end wire i2c_scl_oe_n; wire i2c_scl_o; wire i2c_scl_i = HDMI_TX_PCSCL; wire i2c_sda_oe_n; wire i2c_sda_o; wire i2c_sda_i = HDMI_TX_PCSDA; // tristate buffers assign HDMI_TX_PCSCL = i2c_scl_oe_n==1'b0 ? i2c_scl_o : 1'bz; assign HDMI_TX_PCSDA = i2c_sda_oe_n==1'b0 ? i2c_sda_o : 1'bz; //wire gen_sck; //wire gen_i2s; //wire gen_ws; assign HDMI_TX_SCK = 1'b0; assign HDMI_TX_I2S = 4'b0;//{gen_i2s, gen_i2s, gen_i2s, gen_i2s}; assign HDMI_TX_WS = 1'b0;//gen_ws; wire [31:0] otg_dout; assign OTG_D = (!OTG_CS_n & OTG_OE_n) ? otg_dout : 32'hzzzzzzzz; wire [16:0] otg_a_temp; assign OTG_A[17:1] = otg_a_temp[16:0]; DE4_SOC DE4_SOC_inst( // 1) global signals: .clk_50_clk(OSC_50_Bank2), .clk_125_clk(enet_refclk_125MHz), .reset_reset_n(rstn), .sysclk_clk(qsys_sysclk), //.sysreset_reset_n(qsys_sysreset_n), .leds_external_connection_export(LED_n), // the_ddr2 .ddr2_global_reset_reset_n(), .memory_mem_cke (M1_DDR2_cke), // ddr2.cke .memory_mem_ck_n (M1_DDR2_clk_n), // .ck_n .memory_mem_cas_n (M1_DDR2_cas_n), // .cas_n .memory_mem_dq (M1_DDR2_dq), // .dq .memory_mem_dqs (M1_DDR2_dqs), // .dqs .memory_mem_odt (M1_DDR2_odt), // .odt .memory_mem_cs_n (M1_DDR2_cs_n), // .cs_n .memory_mem_ba (M1_DDR2_ba), // .ba .memory_mem_dm (M1_DDR2_dm), // .dm .memory_mem_we_n (M1_DDR2_we_n), // .we_n .memory_mem_dqs_n (M1_DDR2_dqsn), // .dqs_n .memory_mem_ras_n (M1_DDR2_ras_n), // .ras_n .memory_mem_ck (M1_DDR2_clk), // .ck .memory_mem_a (M1_DDR2_addr), // .a .oct_rup (termination_blk0_rup_pad), // .oct_rup .oct_rdn (termination_blk0_rdn_pad), // .oct_rdn // ddr2 psd i2c // .out_port_from_the_ddr2_i2c_scl(M1_DDR2_SCL), // .out_port_from_the_ddr2_i2c_sa(M1_DDR2_SA), // .bidir_port_to_and_from_the_ddr2_i2c_sda(M1_DDR2_SDA) // --------------------------------------------------------------------- // MAC (TSE) 0 .mac_mac_mdio_mdc (enet_mdc), // mac_mac_mdio.mdc .mac_mac_mdio_mdio_in (enet_mdio_in), // .mdio_in .mac_mac_mdio_mdio_out (enet_mdio_out), // .mdio_out .mac_mac_mdio_mdio_oen (enet_mdio_oen), // .mdio_oen //.mac_mac_misc_xon_gen, (/ input /) // mac_mac_misc.xon_gen //.mac_mac_misc_xoff_gen, (/ input /) // .xoff_gen //.mac_mac_misc_magic_wakeup, (/ output /) // .magic_wakeup //.mac_mac_misc_magic_sleep_n, (/ input /) // .magic_sleep_n //.mac_mac_misc_ff_tx_crc_fwd, (/ input /) // .ff_tx_crc_fwd //.mac_mac_misc_ff_tx_septy, (/ output /) // .ff_tx_septy //.mac_mac_misc_tx_ff_uflow, (/ output /) // .tx_ff_uflow //.mac_mac_misc_ff_tx_a_full, (/ output /) // .ff_tx_a_full //.mac_mac_misc_ff_tx_a_empty, (/ output /) // .ff_tx_a_empty //.mac_mac_misc_rx_err_stat, (/ output[17:0] /) // .rx_err_stat //.mac_mac_misc_rx_frm_type, (/ output[3:0] /) // .rx_frm_type //.mac_mac_misc_ff_rx_dsav, (/ output /) // .ff_rx_dsav //.mac_mac_misc_ff_rx_a_full, (/ output /) // .ff_rx_a_full //.mac_mac_misc_ff_rx_a_empty, (/ output /) // .ff_rx_a_empty //.mac_status_led_crs, (/ output /) // mac_status_led.crs //.mac_status_led_link, (/ output /) // .link //.mac_status_led_col, (/ output /) // .col //.mac_status_led_an, (/ output /) // .an //.mac_status_led_char_err, (/ output /) // .char_err //.mac_status_led_disp_err, (/ output /) // .disp_err //.mac_serdes_control_export, (/ output */) // mac_serdes_control.export .mac_serial_txp (lvds_txp), // mac_serial.txp .mac_serial_rxp (lvds_rxp), // .rxp // --------------------------------------------------------------------- // MAC (TSE) 1 .mac1_mac_mdio_mdc (enet1_mdc), // mac1_mac_mdio.mdc .mac1_mac_mdio_mdio_in (enet1_mdio_in), // .mdio_in .mac1_mac_mdio_mdio_out (enet1_mdio_out), // .mdio_out .mac1_mac_mdio_mdio_oen (enet1_mdio_oen), // .mdio_oen //.mac1_mac_misc_xon_gen, ( input ) // mac1_mac_misc.xon_gen //.mac1_mac_misc_xoff_gen, ( input ) // .xoff_gen //.mac1_mac_misc_magic_wakeup, ( output ) // .magic_wakeup //.mac1_mac_misc_magic_sleep_n, ( input ) // .magic_sleep_n //.mac1_mac_misc_ff_tx_crc_fwd, ( input ) // .ff_tx_crc_fwd //.mac1_mac_misc_ff_tx_septy, ( output ) // .ff_tx_septy //.mac1_mac_misc_tx_ff_uflow, ( output ) // .tx_ff_uflow //.mac1_mac_misc_ff_tx_a_full, ( output ) // .ff_tx_a_full //.mac1_mac_misc_ff_tx_a_empty, ( output ) // .ff_tx_a_empty //.mac1_mac_misc_rx_err_stat, ( output[17:0] ) // .rx_err_stat //.mac1_mac_misc_rx_frm_type, ( output[3:0] ) // .rx_frm_type //.mac1_mac_misc_ff_rx_dsav, ( output ) // .ff_rx_dsav //.mac1_mac_misc_ff_rx_a_full, ( output ) // .ff_rx_a_full //.mac1_mac_misc_ff_rx_a_empty, ( output ) // .ff_rx_a_empty //.mac1_status_led_crs, ( output ) // mac1_status_led.crs //.mac1_status_led_link, ( output ) // .link //.mac1_status_led_col, ( output ) // .col //.mac1_status_led_an, ( output ) // .an //.mac1_status_led_char_err, ( output ) // .char_err //.mac1_status_led_disp_err, ( output ) // .disp_err //.mac1_serdes_control_export, ( output ) // mac1_serdes_control.export .mac1_serial_txp (lvds_txp1), // mac1_serial.txp .mac1_serial_rxp (lvds_rxp1), // .rxp // ---------------------------------------------------------------------/ .sd_b_SD_cmd (SD_CMD), // sd.b_SD_cmd .sd_b_SD_dat (SD_DAT[0]), // .b_SD_dat .sd_b_SD_dat3 (SD_DAT[3]), // .b_SD_dat3 .sd_o_SD_clock (SD_CLK), // .o_SD_clock .mem_ssram_adv (SSRAM_ADV), // fbssram_1.ssram_adv .mem_ssram_bwa_n (SSRAM_BWA_n), // .ssram_bwa_n .mem_ssram_bwb_n (SSRAM_BWB_n), // .ssram_bwb_n .mem_ssram_ce_n (SSRAM_CE_n), // .ssram_ce_n .mem_ssram_cke_n (SSRAM_CKE_n), // .ssram_cke_n .mem_ssram_oe_n (SSRAM_OE_n), // .ssram_oe_n .mem_ssram_we_n (SSRAM_WE_n), // .ssram_we_n .mem_fsm_a (FSM_A), // .fsm_a .mem_fsm_d_out (ssram_data_out), // .fsm_d_out .mem_fsm_d_in (FSM_D), // .fsm_d_in .mem_fsm_dout_req (ssram_data_outen), // .fsm_dout_req .mem_flash_adv_n (FLASH_ADV_n), .mem_flash_ce_n (FLASH_CE_n), .mem_flash_clk (FLASH_CLK), .mem_flash_oe_n (FLASH_OE_n), .mem_flash_we_n (FLASH_WE_n), .touch_x1 (touch_x1_0), // .touch_x1 .touch_y1 (touch_y1_0), // .touch_y1 .touch_x2 (touch_x2_0), // .touch_x2 .touch_y2 (touch_y2_0), // .touch_y2 .touch_count_gesture ({touch_count_0,touch_gesture_0}), // .touch_count_gesture .touch_touch_valid (touch_ready_0), // .touch_touch_valid // .sram_clk_clk (sramClk), // sram_clk.clk // .sram_clk_clk (SSRAM_CLK) // .display_clk_clk (clk27), .coe_hdmi_r(HDMI_TX_RD), .coe_hdmi_g(HDMI_TX_GD), .coe_hdmi_b(HDMI_TX_BD), .coe_hdmi_hsd(HDMI_TX_HS), .coe_hdmi_vsd(HDMI_TX_VS), .coe_hdmi_de(HDMI_TX_DE), .coe_tpadlcd_mtl_r(mtl_r), .coe_tpadlcd_mtl_g(mtl_g), .coe_tpadlcd_mtl_b(mtl_b), .coe_tpadlcd_mtl_hsd(mtl_hsd), .coe_tpadlcd_mtl_vsd(mtl_vsd), .clk_27_clk (clk27), .coe_i2c_scl_i (i2c_scl_i), .coe_i2c_scl_o (i2c_scl_o), .coe_i2c_scl_oe_n (i2c_scl_oe_n), .coe_i2c_sda_i (i2c_sda_i), .coe_i2c_sda_o (i2c_sda_o), .coe_i2c_sda_oe_n (i2c_sda_oe_n), .hdmi_tx_reset_n_external_connection_export (HDMI_TX_RST_N), // .i2s_tx_conduit_end_sck (gen_sck), // i2s_tx_conduit_end.sck // .i2s_tx_conduit_end_ws (gen_ws), // .ws // .i2s_tx_conduit_end_sd (gen_i2s), .usb_coe_cs_n (OTG_CS_n), // usb.coe_cs_n .usb_coe_rd_n (OTG_OE_n), // .coe_rd_n .usb_coe_din (OTG_D), // .coe_din .usb_coe_dout (otg_dout), // .coe_dout .usb_coe_a (otg_a_temp), // .coe_a .usb_coe_dc_irq_in (OTG_DC_IRQ), // .coe_dc_irq_in .usb_coe_hc_irq_in (OTG_HC_IRQ), // .coe_hc_irq_in //.usb_coe_dc_dreq_in (OTG_DC_DREQ), // .coe_dc_dreq_in //.usb_coe_hc_dreq_in (OTG_HC_DREQ), // .coe_hc_dreq_in //.usb_coe_dc_dack (OTG_DC_DACK), // .coe_dc_dack //.usb_coe_hc_dack (OTG_HC_DACK), // .coe_hc_dack .usb_coe_wr_n (OTG_WE_n), // .coe_wr_n .fan_fan_on_pwm (FAN_CTRL), // .fan_temp_lower_seg_n (SEG0_D), // .temp_lower_seg_n .fan_temp_upper_seg_n (SEG1_D), // .temp_upper_seg_n. .switches_export ({SLIDE_SW[3:0], BUTTON[3:0], SW_P[7:0]}), .rs232_stx_pad_o (UART_TXD), // rs232.stx_pad_o .rs232_srx_pad_i (UART_RXD), // .srx_pad_i .rs232_rts_pad_o (UART_RTS), // .rts_pad_o .rs232_cts_pad_i (UART_CTS), // .cts_pad_i .rs232_dtr_pad_o (), // .dtr_pad_o // I have no idea what these should be by default. Should see Simon's example project. .rs232_dsr_pad_i (1'b1), // .dsr_pad_i .rs232_ri_pad_i (1'b1), // .ri_pad_i .rs232_dcd_pad_i (1'b1) // .dcd_pad_i `ifdef ENABLE_PCIE , .pciexpressstream_0_refclk_export (PCIE_REFCLK_p), .pciexpressstream_0_fixedclk_clk (clk125), .pciexpressstream_0_cal_blk_clk_clk (reconfig_clk), .pciexpressstream_0_reconfig_gxbclk_clk (reconfig_clk), .pciexpressstream_0_reconfig_togxb_data (reconfig_togxb), .pciexpressstream_0_reconfig_fromgxb_0_data (reconfig_fromgxb), .pciexpressstream_0_reconfig_busy_busy_altgxb_reconfig (reconfig_busy), .pciexpressstream_0_pcie_rstn_export (PCIE_PREST_n), .pciexpressstream_0_rx_in_rx_datain_0 (PCIE_RX_p[0]), .pciexpressstream_0_rx_in_rx_datain_1 (PCIE_RX_p[1]), .pciexpressstream_0_rx_in_rx_datain_2 (PCIE_RX_p[2]), .pciexpressstream_0_rx_in_rx_datain_3 (PCIE_RX_p[3]), .pciexpressstream_0_tx_out_tx_dataout_0 (PCIE_TX_p[0]), .pciexpressstream_0_tx_out_tx_dataout_1 (PCIE_TX_p[1]), .pciexpressstream_0_tx_out_tx_dataout_2 (PCIE_TX_p[2]), .pciexpressstream_0_tx_out_tx_dataout_3 (PCIE_TX_p[3]) `endif ); // handle USB (OTG) reset signal assign OTG_RESET_n = rstn100; // handle unused flash reset signal assign FLASH_RESET_n = rstn100; // handle tristate ssram data bus assign FSM_D = ssram_data_outen ? ssram_data_out : 16'bzzzzzzzzzzzzzzzz; endmodule
module serial_rx #( parameter CLK_PER_BIT = 50 )( input clk, input rst, input rx, output [7:0] data, output new_data ); // clog2 is 'ceiling of log base 2' which gives you the number of bits needed to store a value parameter CTR_SIZE = $clog2(CLK_PER_BIT); localparam STATE_SIZE = 2; localparam IDLE = 2'd0, WAIT_HALF = 2'd1, WAIT_FULL = 2'd2, WAIT_HIGH = 2'd3; reg [CTR_SIZE-1:0] ctr_d, ctr_q; reg [2:0] bit_ctr_d, bit_ctr_q; reg [7:0] data_d, data_q; reg new_data_d, new_data_q; reg [STATE_SIZE-1:0] state_d, state_q = IDLE; reg rx_d, rx_q; assign new_data = new_data_q; assign data = data_q; always @(*) begin rx_d = rx; state_d = state_q; ctr_d = ctr_q; bit_ctr_d = bit_ctr_q; data_d = data_q; new_data_d = 1'b0; case (state_q) IDLE: begin bit_ctr_d = 3'b0; ctr_d = 1'b0; if (rx_q == 1'b0) begin state_d = WAIT_HALF; end end WAIT_HALF: begin ctr_d = ctr_q + 1'b1; if (ctr_q == (CLK_PER_BIT >> 1)) begin ctr_d = 1'b0; state_d = WAIT_FULL; end end WAIT_FULL: begin ctr_d = ctr_q + 1'b1; if (ctr_q == CLK_PER_BIT - 1) begin data_d = {rx_q, data_q[7:1]}; bit_ctr_d = bit_ctr_q + 1'b1; ctr_d = 1'b0; if (bit_ctr_q == 3'd7) begin state_d = WAIT_HIGH; new_data_d = 1'b1; end end end WAIT_HIGH: begin if (rx_q == 1'b1) begin state_d = IDLE; end end default: begin state_d = IDLE; end endcase end always @(posedge clk) begin if (rst) begin ctr_q <= 1'b0; bit_ctr_q <= 3'b0; new_data_q <= 1'b0; state_q <= IDLE; end else begin ctr_q <= ctr_d; bit_ctr_q <= bit_ctr_d; new_data_q <= new_data_d; state_q <= state_d; end rx_q <= rx_d; data_q <= data_d; end endmodule
// (C) 1992-2014 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. module acl_ic_slave_wrp #( parameter integer DATA_W = 32, // > 0 parameter integer BURSTCOUNT_W = 4, // > 0 parameter integer ADDRESS_W = 32, // > 0 parameter integer BYTEENA_W = DATA_W / 8, // > 0 parameter integer ID_W = 1, // > 0 parameter integer NUM_MASTERS = 1, // > 0 // If the fifo depth is zero, the module will perform the write ack here, // otherwise it will take the write ack from the input s_writeack. parameter integer FIFO_DEPTH = 0, // >= 0 (0 disables) parameter integer PIPELINE = 1 // 0\|1 ) ( input clock, input resetn, acl_arb_intf m_intf, input logic s_writeack, acl_ic_wrp_intf wrp_intf, output logic stall ); generate if( NUM_MASTERS > 1 ) begin // This slave endpoint may not directly talk to the ACTUAL slave. In // this case we need a fifo to store which master each write ack should // go to. If FIFO_DEPTH is 0 then we assume the writeack can be // generated right here (the way it was done originally) if( FIFO_DEPTH > 0 ) begin // We don't have to worry about bursts, we'll fifo each transaction // since writeack behaves like readdatavalid logic rf_empty, rf_full; acl_ll_fifo #( .WIDTH( ID_W ), .DEPTH( FIFO_DEPTH ) ) write_fifo( .clk( clock ), .reset( ~resetn ), .data_in( m_intf.req.id ), .write( ~m_intf.stall & m_intf.req.write ), .data_out( wrp_intf.id ), .read( wrp_intf.ack & ~rf_empty), .empty( rf_empty ), .full( rf_full ) ); // Register slave writeack to guarantee fifo output is ready always @( posedge clock or negedge resetn ) begin if( !resetn ) wrp_intf.ack <= 1'b0; else wrp_intf.ack <= s_writeack; end assign stall = rf_full; end else if( PIPELINE == 1 ) begin assign stall = 1'b0; always @( posedge clock or negedge resetn ) if( !resetn ) begin wrp_intf.ack <= 1'b0; wrp_intf.id <= 'x; // don't need to reset end else begin // Always register the id. The ack signal acts as the enable. wrp_intf.id <= m_intf.req.id; wrp_intf.ack <= 1'b0; if( ~m_intf.stall & m_intf.req.write ) // A valid write cycle. Ack it. wrp_intf.ack <= 1'b1; end end else begin assign wrp_intf.id = m_intf.req.id; assign wrp_intf.ack = ~m_intf.stall & m_intf.req.write; assign stall = 1'b0; end end else // NUM_MASTERS == 1 begin // Only one master so don't need to check the id. if ( FIFO_DEPTH == 0 ) begin assign wrp_intf.ack = ~m_intf.stall & m_intf.req.write; assign stall = 1'b0; end else begin assign wrp_intf.ack = s_writeack; assign stall = 1'b0; end end endgenerate endmodule
// (C) 2001-2016 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. // (C) 2001-2013 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. // $Id: //acds/rel/16.0/ip/merlin/altera_reset_controller/altera_reset_controller.v#1 $ // $Revision: #1 $ // $Date: 2016/02/08 $ // $Author: swbranch $ // -------------------------------------- // Reset controller // // Combines all the input resets and synchronizes // the result to the clk. // ACDS13.1 - Added reset request as part of reset sequencing // -------------------------------------- `timescale 1 ns / 1 ns module altera_reset_controller #( parameter NUM_RESET_INPUTS = 6, parameter USE_RESET_REQUEST_IN0 = 0, parameter USE_RESET_REQUEST_IN1 = 0, parameter USE_RESET_REQUEST_IN2 = 0, parameter USE_RESET_REQUEST_IN3 = 0, parameter USE_RESET_REQUEST_IN4 = 0, parameter USE_RESET_REQUEST_IN5 = 0, parameter USE_RESET_REQUEST_IN6 = 0, parameter USE_RESET_REQUEST_IN7 = 0, parameter USE_RESET_REQUEST_IN8 = 0, parameter USE_RESET_REQUEST_IN9 = 0, parameter USE_RESET_REQUEST_IN10 = 0, parameter USE_RESET_REQUEST_IN11 = 0, parameter USE_RESET_REQUEST_IN12 = 0, parameter USE_RESET_REQUEST_IN13 = 0, parameter USE_RESET_REQUEST_IN14 = 0, parameter USE_RESET_REQUEST_IN15 = 0, parameter OUTPUT_RESET_SYNC_EDGES = "deassert", parameter SYNC_DEPTH = 2, parameter RESET_REQUEST_PRESENT = 0, parameter RESET_REQ_WAIT_TIME = 3, parameter MIN_RST_ASSERTION_TIME = 11, parameter RESET_REQ_EARLY_DSRT_TIME = 4, parameter ADAPT_RESET_REQUEST = 0 ) ( // -------------------------------------- // We support up to 16 reset inputs, for now // -------------------------------------- input reset_in0, input reset_in1, input reset_in2, input reset_in3, input reset_in4, input reset_in5, input reset_in6, input reset_in7, input reset_in8, input reset_in9, input reset_in10, input reset_in11, input reset_in12, input reset_in13, input reset_in14, input reset_in15, input reset_req_in0, input reset_req_in1, input reset_req_in2, input reset_req_in3, input reset_req_in4, input reset_req_in5, input reset_req_in6, input reset_req_in7, input reset_req_in8, input reset_req_in9, input reset_req_in10, input reset_req_in11, input reset_req_in12, input reset_req_in13, input reset_req_in14, input reset_req_in15, input clk, output reg reset_out, output reg reset_req ); // Always use async reset synchronizer if reset_req is used localparam ASYNC_RESET = (OUTPUT_RESET_SYNC_EDGES == "deassert"); // -------------------------------------- // Local parameter to control the reset_req and reset_out timing when RESET_REQUEST_PRESENT==1 // -------------------------------------- localparam MIN_METASTABLE = 3; localparam RSTREQ_ASRT_SYNC_TAP = MIN_METASTABLE + RESET_REQ_WAIT_TIME; localparam LARGER = RESET_REQ_WAIT_TIME > RESET_REQ_EARLY_DSRT_TIME ? RESET_REQ_WAIT_TIME : RESET_REQ_EARLY_DSRT_TIME; localparam ASSERTION_CHAIN_LENGTH = (MIN_METASTABLE > LARGER) ? MIN_RST_ASSERTION_TIME + 1 : ( (MIN_RST_ASSERTION_TIME > LARGER)? MIN_RST_ASSERTION_TIME + (LARGER - MIN_METASTABLE + 1) + 1 : MIN_RST_ASSERTION_TIME + RESET_REQ_EARLY_DSRT_TIME + RESET_REQ_WAIT_TIME - MIN_METASTABLE + 2 ); localparam RESET_REQ_DRST_TAP = RESET_REQ_EARLY_DSRT_TIME + 1; // -------------------------------------- wire merged_reset; wire merged_reset_req_in; wire reset_out_pre; wire reset_req_pre; // Registers and Interconnect (preserve) reg [RSTREQ_ASRT_SYNC_TAP: 0] altera_reset_synchronizer_int_chain; reg [ASSERTION_CHAIN_LENGTH-1: 0] r_sync_rst_chain; reg r_sync_rst; reg r_early_rst; // -------------------------------------- // "Or" all the input resets together // -------------------------------------- assign merged_reset = ( reset_in0 \| reset_in1 \| reset_in2 \| reset_in3 \| reset_in4 \| reset_in5 \| reset_in6 \| reset_in7 \| reset_in8 \| reset_in9 \| reset_in10 \| reset_in11 \| reset_in12 \| reset_in13 \| reset_in14 \| reset_in15 ); assign merged_reset_req_in = ( ( (USE_RESET_REQUEST_IN0 == 1) ? reset_req_in0 : 1'b0) \| ( (USE_RESET_REQUEST_IN1 == 1) ? reset_req_in1 : 1'b0) \| ( (USE_RESET_REQUEST_IN2 == 1) ? reset_req_in2 : 1'b0) \| ( (USE_RESET_REQUEST_IN3 == 1) ? reset_req_in3 : 1'b0) \| ( (USE_RESET_REQUEST_IN4 == 1) ? reset_req_in4 : 1'b0) \| ( (USE_RESET_REQUEST_IN5 == 1) ? reset_req_in5 : 1'b0) \| ( (USE_RESET_REQUEST_IN6 == 1) ? reset_req_in6 : 1'b0) \| ( (USE_RESET_REQUEST_IN7 == 1) ? reset_req_in7 : 1'b0) \| ( (USE_RESET_REQUEST_IN8 == 1) ? reset_req_in8 : 1'b0) \| ( (USE_RESET_REQUEST_IN9 == 1) ? reset_req_in9 : 1'b0) \| ( (USE_RESET_REQUEST_IN10 == 1) ? reset_req_in10 : 1'b0) \| ( (USE_RESET_REQUEST_IN11 == 1) ? reset_req_in11 : 1'b0) \| ( (USE_RESET_REQUEST_IN12 == 1) ? reset_req_in12 : 1'b0) \| ( (USE_RESET_REQUEST_IN13 == 1) ? reset_req_in13 : 1'b0) \| ( (USE_RESET_REQUEST_IN14 == 1) ? reset_req_in14 : 1'b0) \| ( (USE_RESET_REQUEST_IN15 == 1) ? reset_req_in15 : 1'b0) ); // -------------------------------------- // And if required, synchronize it to the required clock domain, // with the correct synchronization type // -------------------------------------- generate if (OUTPUT_RESET_SYNC_EDGES == "none" && (RESET_REQUEST_PRESENT==0)) begin assign reset_out_pre = merged_reset; assign reset_req_pre = merged_reset_req_in; end else begin altera_reset_synchronizer #( .DEPTH (SYNC_DEPTH), .ASYNC_RESET(RESET_REQUEST_PRESENT? 1'b1 : ASYNC_RESET) ) alt_rst_sync_uq1 ( .clk (clk), .reset_in (merged_reset), .reset_out (reset_out_pre) ); altera_reset_synchronizer #( .DEPTH (SYNC_DEPTH), .ASYNC_RESET(0) ) alt_rst_req_sync_uq1 ( .clk (clk), .reset_in (merged_reset_req_in), .reset_out (reset_req_pre) ); end endgenerate generate if ( ( (RESET_REQUEST_PRESENT == 0) && (ADAPT_RESET_REQUEST==0) )\| ( (ADAPT_RESET_REQUEST == 1) && (OUTPUT_RESET_SYNC_EDGES != "deassert") ) ) begin always @* begin reset_out = reset_out_pre; reset_req = reset_req_pre; end end else if ( (RESET_REQUEST_PRESENT == 0) && (ADAPT_RESET_REQUEST==1) ) begin wire reset_out_pre2; altera_reset_synchronizer #( .DEPTH (SYNC_DEPTH+1), .ASYNC_RESET(0) ) alt_rst_sync_uq2 ( .clk (clk), .reset_in (reset_out_pre), .reset_out (reset_out_pre2) ); always @* begin reset_out = reset_out_pre2; reset_req = reset_req_pre; end end else begin // 3-FF Metastability Synchronizer initial begin altera_reset_synchronizer_int_chain <= {RSTREQ_ASRT_SYNC_TAP{1'b1}}; end always @(posedge clk) begin altera_reset_synchronizer_int_chain[RSTREQ_ASRT_SYNC_TAP:0] <= {altera_reset_synchronizer_int_chain[RSTREQ_ASRT_SYNC_TAP-1:0], reset_out_pre}; end // Synchronous reset pipe initial begin r_sync_rst_chain <= {ASSERTION_CHAIN_LENGTH{1'b1}}; end always @(posedge clk) begin if (altera_reset_synchronizer_int_chain[MIN_METASTABLE-1] == 1'b1) begin r_sync_rst_chain <= {ASSERTION_CHAIN_LENGTH{1'b1}}; end else begin r_sync_rst_chain <= {1'b0, r_sync_rst_chain[ASSERTION_CHAIN_LENGTH-1:1]}; end end // Standard synchronous reset output. From 0-1, the transition lags the early output. For 1->0, the transition // matches the early input. always @(posedge clk) begin case ({altera_reset_synchronizer_int_chain[RSTREQ_ASRT_SYNC_TAP], r_sync_rst_chain[1], r_sync_rst}) 3'b000: r_sync_rst <= 1'b0; // Not reset 3'b001: r_sync_rst <= 1'b0; 3'b010: r_sync_rst <= 1'b0; 3'b011: r_sync_rst <= 1'b1; 3'b100: r_sync_rst <= 1'b1; 3'b101: r_sync_rst <= 1'b1; 3'b110: r_sync_rst <= 1'b1; 3'b111: r_sync_rst <= 1'b1; // In Reset default: r_sync_rst <= 1'b1; endcase case ({r_sync_rst_chain[1], r_sync_rst_chain[RESET_REQ_DRST_TAP] \| reset_req_pre}) 2'b00: r_early_rst <= 1'b0; // Not reset 2'b01: r_early_rst <= 1'b1; // Coming out of reset 2'b10: r_early_rst <= 1'b0; // Spurious reset - should not be possible via synchronous design. 2'b11: r_early_rst <= 1'b1; // Held in reset default: r_early_rst <= 1'b1; endcase end always @* begin reset_out = r_sync_rst; reset_req = r_early_rst; end end endgenerate endmodule
// DESCRIPTION: Verilator: Verilog Test module // // This file ONLY is placed into the Public Domain, for any use, // without warranty, 2005 by Wilson Snyder. module t (clk); input clk; reg [2:0] a; reg [2:0] b; reg q; f6 f6 (/AUTOINST/ // Outputs .q (q), // Inputs .a (a[2:0]), .b (b[2:0]), .clk (clk)); integer cyc; initial cyc=1; always @ (posedge clk) begin if (cyc!=0) begin cyc <= cyc + 1; if (cyc==1) begin a <= 3'b000; b <= 3'b100; end if (cyc==2) begin a <= 3'b011; b <= 3'b001; if (q != 1'b0) $stop; end if (cyc==3) begin a <= 3'b011; b <= 3'b011; if (q != 1'b0) $stop; end if (cyc==9) begin if (q != 1'b1) $stop; $write("- All Finished -\n"); $finish; end end end endmodule module f6 (a, b, clk, q); input [2:0] a; input [2:0] b; input clk; output q; reg out; function func6; reg result; input [5:0] src; begin if (src[5:0] == 6'b011011) begin result = 1'b1; end else begin result = 1'b0; end func6 = result; end endfunction wire [5:0] w6 = {a, b}; always @(posedge clk) begin out <= func6(w6); end assign q = out; endmodule
// ============================================================== // File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC // Version: 2015.4 // Copyright (C) 2015 Xilinx Inc. All rights reserved. // // ============================================================== `timescale 1ns/1ps module ANN_AXILiteS_s_axi #(parameter C_S_AXI_ADDR_WIDTH = 6, C_S_AXI_DATA_WIDTH = 32 )( // axi4 lite slave signals input wire ACLK, input wire ARESET, input wire ACLK_EN, input wire [C_S_AXI_ADDR_WIDTH-1:0] AWADDR, input wire AWVALID, output wire AWREADY, input wire [C_S_AXI_DATA_WIDTH-1:0] WDATA, input wire [C_S_AXI_DATA_WIDTH/8-1:0] WSTRB, input wire WVALID, output wire WREADY, output wire [1:0] BRESP, output wire BVALID, input wire BREADY, input wire [C_S_AXI_ADDR_WIDTH-1:0] ARADDR, input wire ARVALID, output wire ARREADY, output wire [C_S_AXI_DATA_WIDTH-1:0] RDATA, output wire [1:0] RRESP, output wire RVALID, input wire RREADY, output wire interrupt, // user signals output wire ap_start, input wire ap_done, input wire ap_ready, input wire ap_idle, input wire [31:0] ap_return, output wire [31:0] P_mode, output wire [31:0] P_index1, output wire [31:0] P_index2, output wire [31:0] P_intIn_index3, output wire [31:0] P_floatIn ); //------------------------Address Info------------------- // 0x00 : Control signals // bit 0 - ap_start (Read/Write/COH) // bit 1 - ap_done (Read/COR) // bit 2 - ap_idle (Read) // bit 3 - ap_ready (Read) // bit 7 - auto_restart (Read/Write) // others - reserved // 0x04 : Global Interrupt Enable Register // bit 0 - Global Interrupt Enable (Read/Write) // others - reserved // 0x08 : IP Interrupt Enable Register (Read/Write) // bit 0 - Channel 0 (ap_done) // bit 1 - Channel 1 (ap_ready) // others - reserved // 0x0c : IP Interrupt Status Register (Read/TOW) // bit 0 - Channel 0 (ap_done) // bit 1 - Channel 1 (ap_ready) // others - reserved // 0x10 : Data signal of ap_return // bit 31~0 - ap_return[31:0] (Read) // 0x18 : Data signal of P_mode // bit 31~0 - P_mode[31:0] (Read/Write) // 0x1c : reserved // 0x20 : Data signal of P_index1 // bit 31~0 - P_index1[31:0] (Read/Write) // 0x24 : reserved // 0x28 : Data signal of P_index2 // bit 31~0 - P_index2[31:0] (Read/Write) // 0x2c : reserved // 0x30 : Data signal of P_intIn_index3 // bit 31~0 - P_intIn_index3[31:0] (Read/Write) // 0x34 : reserved // 0x38 : Data signal of P_floatIn // bit 31~0 - P_floatIn[31:0] (Read/Write) // 0x3c : reserved // (SC = Self Clear, COR = Clear on Read, TOW = Toggle on Write, COH = Clear on Handshake) //------------------------Parameter---------------------- localparam ADDR_AP_CTRL = 6'h00, ADDR_GIE = 6'h04, ADDR_IER = 6'h08, ADDR_ISR = 6'h0c, ADDR_AP_RETURN_0 = 6'h10, ADDR_P_MODE_DATA_0 = 6'h18, ADDR_P_MODE_CTRL = 6'h1c, ADDR_P_INDEX1_DATA_0 = 6'h20, ADDR_P_INDEX1_CTRL = 6'h24, ADDR_P_INDEX2_DATA_0 = 6'h28, ADDR_P_INDEX2_CTRL = 6'h2c, ADDR_P_INTIN_INDEX3_DATA_0 = 6'h30, ADDR_P_INTIN_INDEX3_CTRL = 6'h34, ADDR_P_FLOATIN_DATA_0 = 6'h38, ADDR_P_FLOATIN_CTRL = 6'h3c, WRIDLE = 2'd0, WRDATA = 2'd1, WRRESP = 2'd2, RDIDLE = 2'd0, RDDATA = 2'd1, ADDR_BITS = 6; //------------------------Local signal------------------- reg [1:0] wstate; reg [1:0] wnext; reg [ADDR_BITS-1:0] waddr; wire [31:0] wmask; wire aw_hs; wire w_hs; reg [1:0] rstate; reg [1:0] rnext; reg [31:0] rdata; wire ar_hs; wire [ADDR_BITS-1:0] raddr; // internal registers wire int_ap_idle; wire int_ap_ready; reg int_ap_done; reg int_ap_start; reg int_auto_restart; reg int_gie; reg [1:0] int_ier; reg [1:0] int_isr; reg [31:0] int_ap_return; reg [31:0] int_P_mode; reg [31:0] int_P_index1; reg [31:0] int_P_index2; reg [31:0] int_P_intIn_index3; reg [31:0] int_P_floatIn; //------------------------Instantiation------------------ //------------------------AXI write fsm------------------ assign AWREADY = (wstate == WRIDLE); assign WREADY = (wstate == WRDATA); assign BRESP = 2'b00; // OKAY assign BVALID = (wstate == WRRESP); assign wmask = { {8{WSTRB[3]}}, {8{WSTRB[2]}}, {8{WSTRB[1]}}, {8{WSTRB[0]}} }; assign aw_hs = AWVALID & AWREADY; assign w_hs = WVALID & WREADY; // wstate always @(posedge ACLK) begin if (ARESET) wstate <= WRIDLE; else if (ACLK_EN) wstate <= wnext; end // wnext always @() begin case (wstate) WRIDLE: if (AWVALID) wnext = WRDATA; else wnext = WRIDLE; WRDATA: if (WVALID) wnext = WRRESP; else wnext = WRDATA; WRRESP: if (BREADY) wnext = WRIDLE; else wnext = WRRESP; default: wnext = WRIDLE; endcase end // waddr always @(posedge ACLK) begin if (ACLK_EN) begin if (aw_hs) waddr <= AWADDR[ADDR_BITS-1:0]; end end //------------------------AXI read fsm------------------- assign ARREADY = (rstate == RDIDLE); assign RDATA = rdata; assign RRESP = 2'b00; // OKAY assign RVALID = (rstate == RDDATA); assign ar_hs = ARVALID & ARREADY; assign raddr = ARADDR[ADDR_BITS-1:0]; // rstate always @(posedge ACLK) begin if (ARESET) rstate <= RDIDLE; else if (ACLK_EN) rstate <= rnext; end // rnext always @() begin case (rstate) RDIDLE: if (ARVALID) rnext = RDDATA; else rnext = RDIDLE; RDDATA: if (RREADY & RVALID) rnext = RDIDLE; else rnext = RDDATA; default: rnext = RDIDLE; endcase end // rdata always @(posedge ACLK) begin if (ACLK_EN) begin if (ar_hs) begin rdata <= 1'b0; case (raddr) ADDR_AP_CTRL: begin rdata[0] <= int_ap_start; rdata[1] <= int_ap_done; rdata[2] <= int_ap_idle; rdata[3] <= int_ap_ready; rdata[7] <= int_auto_restart; end ADDR_GIE: begin rdata <= int_gie; end ADDR_IER: begin rdata <= int_ier; end ADDR_ISR: begin rdata <= int_isr; end ADDR_AP_RETURN_0: begin rdata <= int_ap_return[31:0]; end ADDR_P_MODE_DATA_0: begin rdata <= int_P_mode[31:0]; end ADDR_P_INDEX1_DATA_0: begin rdata <= int_P_index1[31:0]; end ADDR_P_INDEX2_DATA_0: begin rdata <= int_P_index2[31:0]; end ADDR_P_INTIN_INDEX3_DATA_0: begin rdata <= int_P_intIn_index3[31:0]; end ADDR_P_FLOATIN_DATA_0: begin rdata <= int_P_floatIn[31:0]; end endcase end end end //------------------------Register logic----------------- assign interrupt = int_gie & (\|int_isr); assign ap_start = int_ap_start; assign int_ap_idle = ap_idle; assign int_ap_ready = ap_ready; assign P_mode = int_P_mode; assign P_index1 = int_P_index1; assign P_index2 = int_P_index2; assign P_intIn_index3 = int_P_intIn_index3; assign P_floatIn = int_P_floatIn; // int_ap_start always @(posedge ACLK) begin if (ARESET) int_ap_start <= 1'b0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_AP_CTRL && WSTRB[0] && WDATA[0]) int_ap_start <= 1'b1; else if (int_ap_ready) int_ap_start <= int_auto_restart; // clear on handshake/auto restart end end // int_ap_done always @(posedge ACLK) begin if (ARESET) int_ap_done <= 1'b0; else if (ACLK_EN) begin if (ap_done) int_ap_done <= 1'b1; else if (ar_hs && raddr == ADDR_AP_CTRL) int_ap_done <= 1'b0; // clear on read end end // int_auto_restart always @(posedge ACLK) begin if (ARESET) int_auto_restart <= 1'b0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_AP_CTRL && WSTRB[0]) int_auto_restart <= WDATA[7]; end end // int_gie always @(posedge ACLK) begin if (ARESET) int_gie <= 1'b0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_GIE && WSTRB[0]) int_gie <= WDATA[0]; end end // int_ier always @(posedge ACLK) begin if (ARESET) int_ier <= 1'b0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_IER && WSTRB[0]) int_ier <= WDATA[1:0]; end end // int_isr[0] always @(posedge ACLK) begin if (ARESET) int_isr[0] <= 1'b0; else if (ACLK_EN) begin if (int_ier[0] & ap_done) int_isr[0] <= 1'b1; else if (w_hs && waddr == ADDR_ISR && WSTRB[0]) int_isr[0] <= int_isr[0] ^ WDATA[0]; // toggle on write end end // int_isr[1] always @(posedge ACLK) begin if (ARESET) int_isr[1] <= 1'b0; else if (ACLK_EN) begin if (int_ier[1] & ap_ready) int_isr[1] <= 1'b1; else if (w_hs && waddr == ADDR_ISR && WSTRB[0]) int_isr[1] <= int_isr[1] ^ WDATA[1]; // toggle on write end end // int_ap_return always @(posedge ACLK) begin if (ARESET) int_ap_return <= 0; else if (ACLK_EN) begin if (ap_done) int_ap_return <= ap_return; end end // int_P_mode[31:0] always @(posedge ACLK) begin if (ARESET) int_P_mode[31:0] <= 0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_P_MODE_DATA_0) int_P_mode[31:0] <= (WDATA[31:0] & wmask) \| (int_P_mode[31:0] & ~wmask); end end // int_P_index1[31:0] always @(posedge ACLK) begin if (ARESET) int_P_index1[31:0] <= 0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_P_INDEX1_DATA_0) int_P_index1[31:0] <= (WDATA[31:0] & wmask) \| (int_P_index1[31:0] & ~wmask); end end // int_P_index2[31:0] always @(posedge ACLK) begin if (ARESET) int_P_index2[31:0] <= 0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_P_INDEX2_DATA_0) int_P_index2[31:0] <= (WDATA[31:0] & wmask) \| (int_P_index2[31:0] & ~wmask); end end // int_P_intIn_index3[31:0] always @(posedge ACLK) begin if (ARESET) int_P_intIn_index3[31:0] <= 0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_P_INTIN_INDEX3_DATA_0) int_P_intIn_index3[31:0] <= (WDATA[31:0] & wmask) \| (int_P_intIn_index3[31:0] & ~wmask); end end // int_P_floatIn[31:0] always @(posedge ACLK) begin if (ARESET) int_P_floatIn[31:0] <= 0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_P_FLOATIN_DATA_0) int_P_floatIn[31:0] <= (WDATA[31:0] & wmask) \| (int_P_floatIn[31:0] & ~wmask); end end //------------------------Memory logic------------------- endmodule
/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 / `ifndef SKY130_FD_SC_LP__AND4B_1_V `define SKY130_FD_SC_LP__AND4B_1_V /* * and4b: 4-input AND, first input inverted. * * Verilog wrapper for and4b with size of 1 units. * * WARNING: This file is autogenerated, do not modify directly! / `timescale 1ns / 1ps `default_nettype none `include "sky130_fd_sc_lp__and4b.v" `ifdef USE_POWER_PINS /******************************************************/ `celldefine module sky130_fd_sc_lp__and4b_1 ( X , A_N , B , C , D , VPWR, VGND, VPB , VNB ); output X ; input A_N ; input B ; input C ; input D ; input VPWR; input VGND; input VPB ; input VNB ; sky130_fd_sc_lp__and4b base ( .X(X), .A_N(A_N), .B(B), .C(C), .D(D), .VPWR(VPWR), .VGND(VGND), .VPB(VPB), .VNB(VNB) ); endmodule `endcelldefine /*****************************************************/ `else // If not USE_POWER_PINS /*****************************************************/ `celldefine module sky130_fd_sc_lp__and4b_1 ( X , A_N, B , C , D ); output X ; input A_N; input B ; input C ; input D ; // Voltage supply signals supply1 VPWR; supply0 VGND; supply1 VPB ; supply0 VNB ; sky130_fd_sc_lp__and4b base ( .X(X), .A_N(A_N), .B(B), .C(C), .D(D) ); endmodule `endcelldefine /*******************************************************/ `endif // USE_POWER_PINS `default_nettype wire `endif // SKY130_FD_SC_LP__AND4B_1_V
/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 / `ifndef SKY130_FD_SC_LS__NAND3_SYMBOL_V `define SKY130_FD_SC_LS__NAND3_SYMBOL_V /* * nand3: 3-input NAND. * * Verilog stub (without power pins) for graphical symbol definition * generation. * * WARNING: This file is autogenerated, do not modify directly! / `timescale 1ns / 1ps `default_nettype none ( blackbox *) module sky130_fd_sc_ls__nand3 ( //# {{data\|Data Signals}} input A, input B, input C, output Y ); // Voltage supply signals supply1 VPWR; supply0 VGND; supply1 VPB ; supply0 VNB ; endmodule `default_nettype wire `endif // SKY130_FD_SC_LS__NAND3_SYMBOL_V
/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 / `ifndef SKY130_FD_SC_HS__SEDFXBP_1_V `define SKY130_FD_SC_HS__SEDFXBP_1_V /* * sedfxbp: Scan delay flop, data enable, non-inverted clock, * complementary outputs. * * Verilog wrapper for sedfxbp with size of 1 units. * * WARNING: This file is autogenerated, do not modify directly! / `timescale 1ns / 1ps `default_nettype none `include "sky130_fd_sc_hs__sedfxbp.v" `ifdef USE_POWER_PINS /******************************************************/ `celldefine module sky130_fd_sc_hs__sedfxbp_1 ( Q , Q_N , CLK , D , DE , SCD , SCE , VPWR, VGND ); output Q ; output Q_N ; input CLK ; input D ; input DE ; input SCD ; input SCE ; input VPWR; input VGND; sky130_fd_sc_hs__sedfxbp base ( .Q(Q), .Q_N(Q_N), .CLK(CLK), .D(D), .DE(DE), .SCD(SCD), .SCE(SCE), .VPWR(VPWR), .VGND(VGND) ); endmodule `endcelldefine /*****************************************************/ `else // If not USE_POWER_PINS /*****************************************************/ `celldefine module sky130_fd_sc_hs__sedfxbp_1 ( Q , Q_N, CLK, D , DE , SCD, SCE ); output Q ; output Q_N; input CLK; input D ; input DE ; input SCD; input SCE; // Voltage supply signals supply1 VPWR; supply0 VGND; sky130_fd_sc_hs__sedfxbp base ( .Q(Q), .Q_N(Q_N), .CLK(CLK), .D(D), .DE(DE), .SCD(SCD), .SCE(SCE) ); endmodule `endcelldefine /*******************************************************/ `endif // USE_POWER_PINS `default_nettype wire `endif // SKY130_FD_SC_HS__SEDFXBP_1_V
module ControlUnit(input[5:0] opcode, input[5:0] funct, output reg reg_dst, output reg reg_write, output reg[1:0] alu_src, output reg[3:0] alu_op, output reg branch, output reg mem_write, output reg mem_to_reg, output reg zero_sign_ext, output reg mult_op, output reg mfhi, output reg mflo); always @(opcode, funct) begin // Make sure that all output have an initial value assigned in // order to prevent synthesis of sequential logic. reg_dst = 1'bx; reg_write = 1'bx; alu_src = 2'bxx; alu_op = 4'bxxxx; branch = 1'bx; mem_write = 1'bx; mem_to_reg = 1'bx; zero_sign_ext = 1'bx; mult_op = 1'b0; // use the multiply/div alu mfhi = 1'b0; // move from hi mflo = 1'b0; // move from lo // Check opcode case (opcode) // If opcode is 0, check funct 6'h00: begin // Common signals reg_dst = 1; reg_write = 1; alu_src = 0; branch = 0; mem_write = 0; mem_to_reg = 0; // ALU operation depends on funct case (funct) // add 6'h20: begin alu_op = 4'b0000; $display("\tInstruction 'add'"); end //addu 6'h21: begin alu_op = 4'b0000; $display("\tInstruction 'addu'"); end // sub 6'h22: begin alu_op = 4'b0001; $display("\tInstruction 'sub'"); end // subu 6'h23: begin alu_op = 4'b0001; $display("\tInstruction 'subu'"); end // and 6'h24: begin alu_op = 4'b0010; $display("\tInstruction 'and'"); end // nor 6'h27: begin alu_op = 4'b0100; $display("\tInstruction 'nor'"); end // or 6'h25: begin alu_op = 4'b0011; $display("\tInstruction 'or'"); end // xor 6'h26: begin alu_op = 4'b0101; $display("\tInstruction 'xor'"); end // sll 6'h0: begin alu_op = 6; alu_src = 2; $display("\tInstruction 'sll'"); end // srl 6'h2: begin alu_op = 7; alu_src = 2; $display("\tInstruction 'srl'"); end // sra 6'h3: begin alu_op = 8; alu_src = 2; $display("\tInstruction 'sra'"); end // sllv 6'h4: begin alu_op = 6; $display("\tInstruction 'sllv'"); end // srlv 6'h6: begin alu_op = 7; $display("\tInstruction 'srlv'"); end // srav 6'h7: begin alu_op = 8; $display("\tInstruction 'srav'"); end // slt 6'h2a: begin alu_op = 4'b1001; $display("\tInstruction 'slt'"); end // sltu 6'h2b: begin alu_op = 4'b1010; $display("\tInstruction 'sltu'"); end // mult 6'h18: begin mult_op = 1; reg_write = 0; alu_op = 4'b0010; $display("\tInstruction 'mult'"); end // multu 6'h19: begin mult_op = 1; reg_write = 0; alu_op = 4'b0011; $display("\tInstruction 'multu'"); end // div 6'h1A: begin mult_op = 1; reg_write = 0; alu_op = 4'b0000; $display("\tInstruction 'div'"); end // divu 6'h1B: begin mult_op = 1; reg_write = 0; alu_op = 4'b0001; $display("\tInstruction 'divu'"); end // mfhi 6'h10: begin alu_op = 4'b1111; mfhi = 1; $display("\tInstruction 'mfhi'"); end // mflo 6'h12: begin alu_op = 4'b1111; mflo = 1; $display("\tInstruction 'mflo'"); end endcase end // lw 6'h23: begin reg_dst = 0; reg_write = 1; alu_src = 1; alu_op = 4'b0000; branch = 0; mem_write = 0; mem_to_reg = 1; zero_sign_ext = 0; $display("\tInstruction 'lw'"); end // sw 6'h2b: begin reg_write = 0; alu_src = 1; alu_op = 4'b0000; branch = 0; mem_write = 1; zero_sign_ext = 0; $display("\tInstruction 'sw'"); end // beq 6'h04: begin reg_write = 0; alu_src = 0; alu_op = 4'b0001; branch = 1; mem_write = 0; $display("\tInstruction 'beq'"); end endcase end endmodule
/* * File: imx_cbu.v * Project: pippo * Designer: kiss@pwrsemi * Mainteiner: kiss@pwrsemi * Checker: * Assigner: * Description: Core Bridge Unit - ÇÅ½ÓcoreµÄimxºÍÆ¬ÉÏ»¥Á¬ÐÒé * IMXºÍWBµÄÒìÍ¬ 1£¬IMXÎÞÐèslaveÊ¹ÓÃrtyÐÅºÅ£¬masterÔÚslaveÃ»ÓÐ·µ»ØackÇ°±£³ÖÇëÇó 2£¬IMXÐèÒª·µ»Øµ±Ç°ÇëÇóµÄaddrÐÅºÅ 3£¬IMXµÄÎ¨Ò»Íê³ÉÐÅºÅÎªack£¬errÔÚackÎªÓÐÐ§Ê±Öµ²ÅÓÐÒâÒå * Task.I: verification environment for complex imx-cbu-wb interaction 1, IMXÁ¬ÐøÇëÇóÇé¿ö 2, ²»Í¬×ÜÏßÊ±¿ÌÈ¡ÏûIMXÇëÇóµÄÇé¿ö£¬È¡Ïûºó»Ö¸´ÓÐÐ§»òÐÂÇëÇóÓÐÐ§µÄÇé¿ö 3, ÊÇ·ñ´æÔÚIMXÇëÇóÒ»Ö±ÓÐÐ§£¬µ«µØÖ··¢Éú±ä»¯µÄÇé¿ö£¿´¦ÀíÆ÷ÄÚºËÓ¦¸Ã²»»á³öÏÖ£¬ÇëÇóÈ¡ÏûÊ±±ØÐëÓÐÒ»ÅÄ¿ÕÏÐ * Task.II: ¿çÊ±ÖÓÓòÖ§³Ö Burst´«ÊäÖ§³Ö */ // synopsys translate_off `include "timescale.v" // synopsys translate_on `include "def_pippo.v" module imx_cbu( clk, rst, wb_cyc_o, wb_adr_o, wb_stb_o, wb_we_o, wb_sel_o, wb_dat_o, wb_cti_o, wb_bte_o, wb_ack_i, wb_err_i, wb_rty_i, wb_dat_i, cbu_dat_i, cbu_adr_i, cbu_rqt_i, cbu_we_i, cbu_sel_i, cbu_ack_o, cbu_dat_o, cbu_err_o, cbu_adr_o ); parameter dw = 32; parameter aw = 32; // currently no burst support `define WB_CTI 3'b000 `define WB_BTE 2'b00 // // core clock, reset and clock control // input clk; // core clock input rst; // core reset // // core-bridge unit interface // input [aw-1:0] cbu_adr_i; // core request address input [dw-1:0] cbu_dat_i; // core request data input cbu_rqt_i; // core request valid input cbu_we_i; // core request w/r flag input [3:0] cbu_sel_i; // core request byte selects output cbu_ack_o; // bus response valid(ack) output cbu_err_o; // bus response error output [dw-1:0] cbu_dat_o; // bus response data output [aw-1:0] cbu_adr_o; // bus response address // // WISHBONE interface // input wb_ack_i; // normal termination input wb_err_i; // termination with error input wb_rty_i; // termination with retry input [dw-1:0] wb_dat_i; // data input output wb_cyc_o; // cycle valid output output [aw-1:0] wb_adr_o; // address output output wb_stb_o; // strobe output output wb_we_o; // indicates write/read transfer output [3:0] wb_sel_o; // byte select output output [dw-1:0] wb_dat_o; // data output output [2:0] wb_cti_o; // cycle type identifier output [1:0] wb_bte_o; // burst type extension // // reg & wires // reg wb_cyc_o; reg [aw-1:0] wb_adr_o; reg wb_stb_o; reg wb_we_o; reg [3:0] wb_sel_o; reg [dw-1:0] wb_dat_o; reg [2:0] wb_cti_o; reg [1:0] wb_bte_o; reg [dw-1:0] cbu_dat_o; reg cbu_ack_o; reg cbu_err_o; reg [aw-1:0] cbu_adr_o; // // logic implementation // // registered request always @(posedge clk or posedge rst) begin if (rst) begin wb_cyc_o <= #1 1'b0; wb_stb_o <= #1 1'b0; wb_dat_o <= #1 32'd0; wb_adr_o <= #1 32'd0; wb_sel_o <= #1 4'd0; wb_we_o <= #1 1'd0; wb_cti_o <= #1 3'd0; wb_bte_o <= #1 2'd0; end else begin if (cbu_rqt_i) begin wb_cyc_o <= #1 cbu_rqt_i; wb_stb_o <= #1 cbu_rqt_i; wb_dat_o <= #1 cbu_dat_i; wb_adr_o <= #1 cbu_adr_i; wb_sel_o <= #1 cbu_sel_i; wb_we_o <= #1 cbu_we_i; wb_cti_o <= #1 `WB_CTI; wb_bte_o <= #1 `WB_BTE; end else begin // when core cancel bus request wb_cyc_o <= #1 1'b0; wb_stb_o <= #1 1'b0; wb_dat_o <= #1 32'd0; wb_adr_o <= #1 32'd0; wb_sel_o <= #1 4'd0; wb_we_o <= #1 1'd0; wb_cti_o <= #1 3'd0; wb_bte_o <= #1 2'd0; end end end // registered request always @(posedge clk or posedge rst) begin if (rst) begin cbu_ack_o <= #1 1'b0; cbu_err_o <= #1 1'b0; end else begin if (cbu_rqt_i) begin cbu_ack_o <= #1 wb_ack_i; cbu_err_o <= #1 wb_err_i; end else begin cbu_ack_o <= #1 1'b0; cbu_err_o <= #1 1'b0; end end end // special case for IMX always @(posedge clk or posedge rst) begin if (rst) begin cbu_dat_o <= #1 32'd0; end else begin cbu_dat_o <= #1 wb_dat_i; end end // special case for IMX always @(posedge clk or posedge rst) begin if (rst) begin cbu_adr_o <= #1 32'd0; end else begin cbu_adr_o <= #1 cbu_adr_i; end end endmodule
// ============================================================== // File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC // Version: 2018.2 // Copyright (C) 1986-2018 Xilinx, Inc. All Rights Reserved. // // ============================================================== `timescale 1 ns / 1 ps module AESL_automem_d ( clk, rst, ce0, we0, address0, din0, dout0, ce1, we1, address1, din1, dout1, ready, done ); //------------------------Parameter---------------------- localparam TV_IN = "c.array_arith.autotvin_d.dat", TV_OUT = "impl_rtl.array_arith.autotvout_d.dat"; //------------------------Local signal------------------- parameter DATA_WIDTH = 32'd 32; parameter ADDR_WIDTH = 32'd 3; parameter DEPTH = 32'd 5; parameter DLY = 0.1; // Input and Output input clk; input rst; input ce0, ce1; input we0, we1; input [ADDR_WIDTH - 1 : 0] address0, address1; input [DATA_WIDTH - 1 : 0] din0, din1; output reg [DATA_WIDTH - 1 : 0] dout0, dout1; input ready; input done; // Inner signals reg [DATA_WIDTH - 1 : 0] mem [0 : DEPTH - 1]; initial begin : initialize_mem integer i; for (i = 0; i < DEPTH; i = i + 1) begin mem[i] = 0; end end reg writed_flag; event write_process_done; //------------------------Task and function-------------- task read_token; input integer fp; output reg [127 :0] token; integer ret; begin token = ""; ret = 0; ret = $fscanf(fp,"%s",token); end endtask //------------------------Read array------------------- // Read data form file to array initial begin : read_file_process integer fp; integer err; integer ret; reg [127 : 0] token; reg [ 85 : 1] str; reg [ DATA_WIDTH - 1 : 0 ] mem_tmp; integer transaction_idx; integer i; transaction_idx = 0; wait(rst === 0); @(write_process_done); fp = $fopen(TV_IN,"r"); if(fp == 0) begin // Failed to open file $display("Failed to open file \"%s\"!", TV_IN); $finish; end read_token(fp, token); if (token != "[[[runtime]]]") begin // Illegal format $display("ERROR: Simulation using HLS TB failed."); $finish; end read_token(fp, token); while (token != "[[[/runtime]]]") begin if (token != "[[transaction]]") begin $display("ERROR: Simulation using HLS TB failed."); $finish; end read_token(fp, token); // skip transaction number while(ready == 0) begin @(write_process_done); end for(i = 0; i < DEPTH; i = i + 1) begin read_token(fp, token); ret = $sscanf(token, "0x%x", mem_tmp); mem[i] = mem_tmp; if (ret != 1) begin $display("Failed to parse token!"); $finish; end end @(write_process_done); read_token(fp, token); if(token != "[[/transaction]]") begin $display("ERROR: Simulation using HLS TB failed."); $finish; end read_token(fp, token); transaction_idx = transaction_idx + 1; end $fclose(fp); end // Read data from array to RTL always @ (posedge clk or rst) begin if(rst === 1) begin dout0 <= 0; end else begin if((we0 == 0) && (ce0 == 1) && (ce1 == 1) && (we1 == 1) && (address0 == address1)) dout0 <= #DLY din1; else if(ce0 == 1) dout0 <= #DLY mem[address0]; else ; end end always @ (posedge clk or rst) begin if(rst === 1) begin dout1 <= 0; end else begin if((we0 == 1) && (ce0 == 1) && (ce1 == 1) && (we1 == 0) && (address0 == address1)) dout1 <= #DLY din0; else if(ce1 == 1) dout1 <= #DLY mem[address1]; else ; end end //------------------------Write array------------------- // Write data from RTL to array always @ (posedge clk) begin if((we0 == 1) && (ce0 == 1) && (ce1 == 1) && (we1 == 1) && (address0 == address1)) mem[address0] <= #DLY din1; else if ((we0 == 1) && (ce0 == 1)) mem[address0] <= #DLY din0; end always @ (posedge clk) begin if((ce1 == 1) && (we1 == 1)) mem[address1] <= #DLY din1; end // Write data from array to file initial begin : write_file_proc integer fp; integer transaction_num; reg [ 85 : 1] str; integer i; transaction_num = 0; writed_flag = 1; wait(rst === 0); @(negedge clk); while(1) begin while(done == 0) begin -> write_process_done; @(negedge clk); end fp = $fopen(TV_OUT, "a"); if(fp == 0) begin // Failed to open file $display("Failed to open file \"%s\"!", TV_OUT); $finish; end $fdisplay(fp, "[[transaction]] %d", transaction_num); for (i = 0; i < DEPTH; i = i + 1) begin $fdisplay(fp,"0x%x",mem[i]); end $fdisplay(fp, "[[/transaction]]"); transaction_num = transaction_num + 1; $fclose(fp); writed_flag = 1; -> write_process_done; @(negedge clk); end end //------------------------conflict check------------------- always @ (posedge clk) begin if ((we0 == 1) && (ce0 == 1) && (ce1 == 1) && (we1 == 1) && (address0 == address1)) $display($time,"WARNING:write conflict----port0 and port1 write to the same address:%h at the same clock. Port1 has the high priority.",address0); end always @ (posedge clk) begin if ((we0 == 1) && (ce0 == 1) && (ce1 == 1) && (we1 == 0) && (address0 == address1)) $display($time,"NOTE:read & write conflict----port0 write and port1 read to the same address:%h at the same clock. Write first Mode.",address0); end always @ (posedge clk) begin if ((we0 == 0) && (ce0 == 1) && (ce1 == 1) && (we1 == 1) && (address0 == address1)) $display($time,"NOTE:read & write conflict----port0 read and port1 write to the same address:%h at the same clock. Write first Mode.",address0); end endmodule
// synthesis translate_off // synthesis translate_on // synthesis verilog_input_version verilog_2001 // turn off superfluous verilog processor warnings // altera message_level Level1 // altera message_off 10034 10035 10036 10037 10230 10240 10030 //----------------------------------------------------------------------------- // Title : PCI Express Reference Design Example Application // Project : PCI Express MegaCore function //----------------------------------------------------------------------------- // File : altpcierd_cdma_ecrc_check_128.v // Author : Altera Corporation //----------------------------------------------------------------------------- // Description : // This module performs the PCIE ECRC check on the 128-bit Avalon-ST RX data stream. //----------------------------------------------------------------------------- // Copyright (c) 2009 Altera Corporation. All rights reserved. Altera products are // protected under numerous U.S. and foreign patents, maskwork rights, copyrights and // other intellectual property laws. // // This reference design file, and your use thereof, is subject to and governed by // the terms and conditions of the applicable Altera Reference Design License Agreement. // By using this reference design file, you indicate your acceptance of such terms and // conditions between you and Altera Corporation. In the event that you do not agree with // such terms and conditions, you may not use the reference design file. Please promptly // destroy any copies you have made. // // This reference design file being provided on an "as-is" basis and as an accommodation // and therefore all warranties, representations or guarantees of any kind // (whether express, implied or statutory) including, without limitation, warranties of // merchantability, non-infringement, or fitness for a particular purpose, are // specifically disclaimed. By making this reference design file available, Altera // expressly does not recommend, suggest or require that this reference design file be // used in combination with any other product not provided by Altera. //----------------------------------------------------------------------------- module altpcierd_cdma_ecrc_check_128 ( input clk_in, input srst, input[139:0] rxdata, input[15:0] rxdata_be, input rx_stream_valid0, output rx_stream_ready0_ecrc, output reg [139:0] rxdata_ecrc, output reg [15:0] rxdata_be_ecrc, output reg rx_stream_valid0_ecrc, input rx_stream_ready0, output reg rx_ecrc_check_valid, output reg [15:0] ecrc_bad_cnt ); localparam RAM_DATA_WIDTH = 140; localparam RAM_ADDR_WIDTH = 8; localparam PIPELINE_DEPTH =4; // Bits in rxdata localparam SOP_BIT = 139; localparam EOP_BIT = 136; localparam EMPTY_BIT = 137; wire rx_sop; reg rx_sop_crc_in; wire rx_eop; reg rx_eop_reg; reg rx_eop_crc_in; reg [3:0] rx_empty; wire [31:0] crc_32; wire crcbad; wire crcvalid; // Set TLP length reg [9:0] ctrlrx_cnt_len_dw; reg [9:0] ctrlrx_cnt_len_dw_reg; // Set when TLP is 3 DW header wire ctrlrx_payload; reg ctrlrx_payload_reg; // Set when TLP is 3 DW header wire ctrlrx_3dw; reg ctrlrx_3dw_reg; // Set when TLP are qword aligned wire ctrlrx_qword_aligned; reg ctrlrx_qword_aligned_reg; // Set when the TD digest bit is set in the descriptor wire ctrlrx_digest; reg ctrlrx_digest_reg; reg [PIPELINE_DEPTH-1:0] ctrlrx_digest_pipe; reg[139:0] rxdata_pipeline [PIPELINE_DEPTH-1:0]; reg[15:0] rxdata_be_pipeline [PIPELINE_DEPTH-1:0]; reg[PIPELINE_DEPTH-1:0] rx_stream_valid_pipeline; wire ctrlrx_3dw_aligned; reg ctrlrx_3dw_aligned_reg; wire ctrlrx_3dw_nonaligned; reg ctrlrx_3dw_nonaligned_reg; wire ctrlrx_4dw_non_aligned; reg ctrlrx_4dw_non_aligned_reg; wire ctrlrx_4dw_aligned; reg ctrlrx_4dw_aligned_reg; reg ctrlrx_single_cycle_reg; integer i; reg [127:0] rxdata_crc_reg ; wire rx_valid_crc_in ; wire [127:0] rxdata_byte_swap ; wire [127:0] rxdata_crc_in ; wire ctrlrx_single_cycle; reg [10:0] rx_payld_remain_dw; wire [10:0] rx_payld_len; reg rx_valid_crc_pending; reg single_crc_cyc; reg send_rx_eop_crc_early; reg debug_ctrlrx_4dw_offset0; reg debug_ctrlrx_4dw_offset1; reg debug_ctrlrx_4dw_offset2; reg debug_ctrlrx_4dw_offset3; reg debug_ctrlrx_3dw_offset0; reg debug_ctrlrx_3dw_offset1; reg debug_ctrlrx_3dw_offset2; reg debug_ctrlrx_3dw_offset3; reg debug_ctrlrx_4dw_offset0_nopayld; reg debug_ctrlrx_4dw_offset1_nopayld; reg debug_ctrlrx_4dw_offset2_nopayld; reg debug_ctrlrx_4dw_offset3_nopayld; reg debug_ctrlrx_3dw_offset0_nopayld; reg debug_ctrlrx_3dw_offset1_nopayld; reg debug_ctrlrx_3dw_offset2_nopayld; reg debug_ctrlrx_3dw_offset3_nopayld; wire[11:0] zeros12; assign zeros12 = 12'h0; wire[7:0] zeros8; assign zeros8 = 8'h0; wire[3:0] zeros4; assign zeros4 = 4'h0; wire[15:0] rxdata_be_15_12; assign rxdata_be_15_12 = {rxdata_be[15:12], zeros12}; wire[15:0] rxdata_be_15_8; assign rxdata_be_15_8 = {rxdata_be[15:8], zeros8}; wire[15:0] rxdata_be_15_4; assign rxdata_be_15_4 = {rxdata_be[15:4], zeros4}; //////////////////////////////////////////////////////////////////////////// // // Drop ECRC field from the data stream/rx_be. // Regenerate rx_st_eop. // Set TD bit to 0. // assign rx_payld_len = (rxdata[105:96] == 0) ? 11'h400 : {1'b0, rxdata[105:96]}; // account for 1024DW always @ (posedge clk_in ) begin if (srst==1'b1) begin rxdata_ecrc <= 140'h0; rxdata_be_ecrc <= 16'h0; rx_payld_remain_dw <= 11'h0; rx_stream_valid0_ecrc <= 1'b0; end else begin rxdata_ecrc[138] <= 1'b0; rx_stream_valid0_ecrc <= 1'b0; // default ///////////////////////// // TLP has Digest // if (ctrlrx_digest==1'b1) begin if (rx_sop==1'b1) begin rxdata_ecrc[111] <= 1'b0; rxdata_ecrc[135:112] <= rxdata[135:112]; rxdata_ecrc[110:0] <= rxdata[110:0]; rxdata_ecrc[SOP_BIT] <= 1'b1; rxdata_ecrc[EOP_BIT] <= (rxdata[126]==1'b0) \| ((ctrlrx_3dw==1'b1) & (ctrlrx_qword_aligned==1'b0) & (rxdata[105:96]==10'h1)); rxdata_ecrc[EMPTY_BIT] <= 1'b0; rxdata_be_ecrc <= rxdata_be; rx_stream_valid0_ecrc <= 1'b1; // Load the # of payld DWs remaining in next cycles if (rxdata[126]==1'b1) begin // if there is payload if ((ctrlrx_3dw==1'b1) & (ctrlrx_qword_aligned==1'b0)) begin rx_payld_remain_dw <= rx_payld_len - 1; end // 3DW aligned, or 4DW nonaligned // Add 1 DW to account for empty field else if ( //((ctrlrx_3dw==1'b1) & (ctrlrx_qword_aligned==1'b1)) \| ((ctrlrx_3dw==1'b0) & (ctrlrx_qword_aligned==1'b0)) ) begin rx_payld_remain_dw <= rx_payld_len + 1; end else begin rx_payld_remain_dw <= rx_payld_len; end end else begin rx_payld_remain_dw <= 11'h0; end end else if (rx_stream_valid0==1'b1) begin rxdata_ecrc[SOP_BIT] <= 1'b0; rxdata_ecrc[135:0] <= rxdata[135:0]; case (rx_payld_remain_dw) 11'h1: begin rxdata_ecrc[EOP_BIT] <= 1'b1; rxdata_ecrc[EMPTY_BIT] <= 1'b1; rxdata_be_ecrc <= rxdata_be_15_12; end 11'h2: begin rxdata_ecrc[EOP_BIT] <= 1'b1; rxdata_ecrc[EMPTY_BIT] <= 1'b1; rxdata_be_ecrc <= rxdata_be_15_8; end 11'h3: begin rxdata_ecrc[EOP_BIT] <= 1'b1; rxdata_ecrc[EMPTY_BIT] <= 1'b0; rxdata_be_ecrc <= rxdata_be_15_4; end 11'h4: begin rxdata_ecrc[EOP_BIT] <= 1'b1; rxdata_ecrc[EMPTY_BIT] <= 1'b0; rxdata_be_ecrc <= rxdata_be[15:0]; end default: begin rxdata_ecrc[EOP_BIT] <= 1'b0; rxdata_ecrc[EMPTY_BIT] <= 1'b0; rxdata_be_ecrc <= rxdata_be[15:0]; end endcase rx_stream_valid0_ecrc <= (rx_payld_remain_dw > 11'h0) ? 1'b1 : 1'b0; // Decrement payld count as payld is received rx_payld_remain_dw <= (rx_payld_remain_dw < 4) ? 11'h0 : rx_payld_remain_dw - 11'h4; end end /////////////// // No Digest // else begin rxdata_ecrc <= rxdata; rxdata_be_ecrc <= rxdata_be; rx_stream_valid0_ecrc <= rx_stream_valid0; end end end //////////////////////////////////////////////////////////////////////////// // // RX Avalon-ST input delayed of PIPELINE_DEPTH to RX Avalon-ST output // assign rx_stream_ready0_ecrc = rx_stream_ready0; //////////////////////////////////////////////////////////////////////////// // // CRC MegaCore instanciation // altpcierd_rx_ecrc_128 rx_ecrc_128 ( .reset_n (~srst), .clk (clk_in), .data (rxdata_crc_in[127:0]), .datavalid (ctrlrx_digest_reg & rx_valid_crc_in), // use registered version of ctrlrx_digest since crc_in is delayed 1 cycle from input .startofpacket (rx_sop_crc_in), .endofpacket (rx_eop_crc_in), .empty (rx_empty), .crcbad (crcbad), .crcvalid (crcvalid)); assign rx_valid_crc_in = (rx_sop_crc_in & (ctrlrx_single_cycle \| rx_stream_valid0)) \| (rx_valid_crc_pending & rx_stream_valid0) \| (rx_eop_crc_in & ~send_rx_eop_crc_early); // Inputs to the MegaCore always @(posedge clk_in) begin if (srst==1'b1) begin rx_valid_crc_pending <= 1'b0; rx_sop_crc_in <= 1'b0; rx_eop_crc_in <= 1'b0; rx_empty <= 1'b0; send_rx_eop_crc_early <= 1'b0; ctrlrx_3dw_aligned_reg <= 1'b0; ctrlrx_3dw_nonaligned_reg <= 1'b0; ctrlrx_4dw_non_aligned_reg <= 1'b0; ctrlrx_4dw_aligned_reg <= 1'b0; debug_ctrlrx_4dw_offset0 <= 1'b0; debug_ctrlrx_4dw_offset1 <= 1'b0; debug_ctrlrx_4dw_offset2 <= 1'b0; debug_ctrlrx_4dw_offset3 <= 1'b0; debug_ctrlrx_3dw_offset0 <= 1'b0; debug_ctrlrx_3dw_offset1 <= 1'b0; debug_ctrlrx_3dw_offset2 <= 1'b0; debug_ctrlrx_3dw_offset3 <= 1'b0; debug_ctrlrx_4dw_offset0_nopayld <= 1'b0; debug_ctrlrx_4dw_offset1_nopayld <= 1'b0; debug_ctrlrx_4dw_offset2_nopayld <= 1'b0; debug_ctrlrx_4dw_offset3_nopayld <= 1'b0; debug_ctrlrx_3dw_offset0_nopayld <= 1'b0; debug_ctrlrx_3dw_offset1_nopayld <= 1'b0; debug_ctrlrx_3dw_offset2_nopayld <= 1'b0; debug_ctrlrx_3dw_offset3_nopayld <= 1'b0; end else begin if ((rx_sop==1'b1) & (rx_stream_valid0==1'b1) & (ctrlrx_digest==1'b1) ) begin rx_sop_crc_in <= 1'b1; end else if ((rx_sop_crc_in==1'b1) & (rx_valid_crc_in==1'b1)) begin rx_sop_crc_in <= 1'b0; end ctrlrx_3dw_aligned_reg <= ctrlrx_3dw_aligned; ctrlrx_3dw_nonaligned_reg <= ctrlrx_3dw_nonaligned; ctrlrx_4dw_non_aligned_reg <= ctrlrx_4dw_non_aligned; ctrlrx_4dw_aligned_reg <= ctrlrx_4dw_aligned; if ((rx_stream_valid0==1'b1) & (rx_sop==1'b1)) begin debug_ctrlrx_4dw_offset0 <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b1) & (rxdata[3:0]==4'h0); // no addr offset debug_ctrlrx_4dw_offset1 <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b1) & (rxdata[3:0]==4'h4); // 1DW addr offset debug_ctrlrx_4dw_offset2 <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b1) & (rxdata[3:0]==4'h8); // 2DW addr offset debug_ctrlrx_4dw_offset3 <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b1) & (rxdata[3:0]==4'hc); // 3DW addr offset debug_ctrlrx_3dw_offset0 <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b1) & (rxdata[35:32]==4'h0); // no addr offset debug_ctrlrx_3dw_offset1 <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b1) & (rxdata[35:32]==4'h4); // 1DW addr offset debug_ctrlrx_3dw_offset2 <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b1) & (rxdata[35:32]==4'h8); // 2DW addr offset debug_ctrlrx_3dw_offset3 <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b1) & (rxdata[35:32]==4'hc); // 3DW addr offset debug_ctrlrx_4dw_offset0_nopayld <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b0) & (rxdata[3:0]==4'h0); // no addr offset debug_ctrlrx_4dw_offset1_nopayld <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b0) & (rxdata[3:0]==4'h4); // 1DW addr offset debug_ctrlrx_4dw_offset2_nopayld <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b0) & (rxdata[3:0]==4'h8); // 2DW addr offset debug_ctrlrx_4dw_offset3_nopayld <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b0) & (rxdata[3:0]==4'hc); // 3DW addr offset debug_ctrlrx_3dw_offset0_nopayld <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b0) & (rxdata[35:32]==4'h0); // no addr offset debug_ctrlrx_3dw_offset1_nopayld <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b0) & (rxdata[35:32]==4'h4); // 1DW addr offset debug_ctrlrx_3dw_offset2_nopayld <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b0) & (rxdata[35:32]==4'h8); // 2DW addr offset debug_ctrlrx_3dw_offset3_nopayld <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b0) & (rxdata[35:32]==4'hc); // 3DW addr offset end if ((rx_sop==1'b1) & (rx_stream_valid0==1'b1) & (ctrlrx_digest==1'b1)) begin if ((ctrlrx_3dw==1'b1) & (ctrlrx_payload==1'b0)) begin rx_eop_crc_in <= 1'b1; // Pack ECRC into single cycle rx_empty <= 1'b0; rx_valid_crc_pending <= 1'b0; end else begin rx_eop_crc_in <= 1'b0; // multicycle rx_empty <= 1'b0; rx_valid_crc_pending <= 1'b1; // eop is sent 1 cycle early when the payld is a multiple // of 4DWs, and the TLP is 3DW Header aligned send_rx_eop_crc_early <= (ctrlrx_3dw_aligned==1'b1) & (ctrlrx_payload==1'b1) & (rxdata[97:96]==2'h0); end end else if (rx_valid_crc_pending == 1'b1) begin // end crc data early if (send_rx_eop_crc_early==1'b1) begin rx_valid_crc_pending <= ((ctrlrx_cnt_len_dw == 10'h0) & (rx_stream_valid0==1'b1)) ? 1'b0 : 1'b1; if ((ctrlrx_cnt_len_dw == 10'h4)& (rx_stream_valid0==1'b1)) begin rx_eop_crc_in <= 1'b1; rx_empty <= 4'h0; end end // end on eop else begin // rx_valid_crc_pending <= (rx_eop_crc_in==1'b1) ? 1'b0 : rx_valid_crc_pending; if ((rx_eop==1'b1) & (rx_stream_valid0==1'b1)) begin rx_eop_crc_in <= 1'b1; rx_valid_crc_pending <= 1'b0; case (ctrlrx_cnt_len_dw) 10'h1: rx_empty <= 4'hc; 10'h2: rx_empty <= 4'h8; 10'h3: rx_empty <= 4'h4; default: rx_empty <= 4'h0; endcase end end end else begin rx_eop_crc_in <= 1'b0; rx_empty <= 4'h0; end end end // rxdata_byte_swap is : // - Set variant bit to 1 The EP field is variant // - Byte swap the data and not the header // - The header is already byte order ready for the CRC (lower byte first) such as : // \| H0 byte 0,1,2,3 // rxdata[127:0] \| H1 byte 4,5,6,7 // \| H2 byte 8,9,10,11 // \| H3 byte 12,13,14,15 // - The Data requires byte swaping // rxdata // always @(posedge clk_in) begin if (rx_stream_valid0==1'b1) begin if (ctrlrx_3dw_aligned==1'b1) begin if (rx_sop==1'b1) begin rxdata_crc_reg[127:121] <= rxdata[127:121]; rxdata_crc_reg[120] <= 1'b1; rxdata_crc_reg[119:111] <= rxdata[119:111]; rxdata_crc_reg[110] <= 1'b1; rxdata_crc_reg[109:0] <= rxdata[109:0]; end else rxdata_crc_reg[127:0] <= { rxdata[71:64 ], rxdata[79 : 72], rxdata[87 : 80], rxdata[95 : 88], //D1 rxdata[39:32 ], rxdata[47 : 40], rxdata[55 : 48], rxdata[63 : 56], // D2 rxdata[7:0 ], rxdata[15 : 8], rxdata[23 : 16], rxdata[31 : 24], // D3 rxdata[103:96], rxdata[111:104], rxdata[119:112], rxdata[127:120]}; // D0 end else if (ctrlrx_4dw_non_aligned==1'b1) begin if (rx_sop==1'b1) begin rxdata_crc_reg[127:121] <= rxdata[127:121]; rxdata_crc_reg[120] <= 1'b1; rxdata_crc_reg[119:111] <= rxdata[119:111]; rxdata_crc_reg[110] <= 1'b1; rxdata_crc_reg[109:0] <= rxdata[109:0]; end else begin rxdata_crc_reg[127:0] <= { rxdata[71:64 ], rxdata[79 : 72], rxdata[87 : 80], rxdata[95 : 88], //D1 rxdata[39:32 ], rxdata[47 : 40], rxdata[55 : 48], rxdata[63 : 56], // D2 rxdata[7:0 ], rxdata[15 : 8], rxdata[23 : 16], rxdata[31 : 24], // D3 rxdata[103:96], rxdata[111:104], rxdata[119:112], rxdata[127:120]}; // D0 end end else if (ctrlrx_4dw_aligned==1'b1) begin if (rx_sop==1'b1) begin rxdata_crc_reg[127:121] <= rxdata[127:121]; rxdata_crc_reg[120] <= 1'b1; rxdata_crc_reg[119:111] <= rxdata[119:111]; rxdata_crc_reg[110] <= 1'b1; rxdata_crc_reg[109:0] <= rxdata[109:0]; end else begin rxdata_crc_reg[127:0] <= { rxdata[103:96], rxdata[111:104], rxdata[119:112], rxdata[127:120], // D0 rxdata[71:64 ], rxdata[79 : 72], rxdata[87 : 80], rxdata[95 : 88], //D1 rxdata[39:32 ], rxdata[47 : 40], rxdata[55 : 48], rxdata[63 : 56], // D2 rxdata[7:0 ], rxdata[15 : 8], rxdata[23 : 16], rxdata[31 : 24] // D3 }; end end else // 3DW nonaligned if (rx_sop==1'b1) begin rxdata_crc_reg[127:121] <= rxdata[127:121]; rxdata_crc_reg[120] <= 1'b1; rxdata_crc_reg[119:111] <= rxdata[119:111]; rxdata_crc_reg[110] <= 1'b1; rxdata_crc_reg[109:32] <= rxdata[109:32]; if (ctrlrx_3dw==1'b1) begin // 3 DWORD Header with payload byte swapping the first data D0 rxdata_crc_reg[31:24] <= rxdata[7:0]; rxdata_crc_reg[23:16] <= rxdata[15:8]; rxdata_crc_reg[15:8] <= rxdata[23:16]; rxdata_crc_reg[7:0] <= rxdata[31:24]; end else // 4 DWORD Header no need to swap bytes rxdata_crc_reg[31:0] <= rxdata[31:0]; end else rxdata_crc_reg[127:0] <= { rxdata[103:96], rxdata[111:104], rxdata[119:112], rxdata[127:120], rxdata[71 :64], rxdata[79 :72 ], rxdata[87 :80 ], rxdata[95 : 88], rxdata[39 :32], rxdata[47 :40 ], rxdata[55 :48 ], rxdata[63 : 56], rxdata[7 :0 ], rxdata[15 : 8 ], rxdata[23 :16 ], rxdata[31 : 24]}; end end assign rxdata_crc_in[127:0] = (ctrlrx_3dw_aligned_reg==1'b1) ? {rxdata_crc_reg[127:32], // previous 3DW rxdata[103:96 ], // current DW (byte flipped) rxdata[111:104], rxdata[119:112], rxdata[127:120]} : ((ctrlrx_4dw_non_aligned_reg==1'b1) & (rx_sop_crc_in==1'b0)) ? {rxdata_crc_reg[127:32], // previous 3DW rxdata[103:96 ], // current DW (byte flipped) rxdata[111:104], rxdata[119:112], rxdata[127:120]} : rxdata_crc_reg[127:0]; ////////////////////////////////////////////////////////////////////////// // // BAD ECRC Counter output (ecrc_bad_cnt // always @(posedge clk_in) begin if (srst==1'b1) begin rx_ecrc_check_valid <= 1'b1; ecrc_bad_cnt <= 0; end else if ((crcvalid==1'b1) && (crcbad==1'b1)) begin if (ecrc_bad_cnt<16'hFFFF) ecrc_bad_cnt <= ecrc_bad_cnt+1; if (rx_ecrc_check_valid==1'b1) rx_ecrc_check_valid <= 1'b0; end end //////////////////////////////////////////////////////////////////////////// // // Misc. Avalon-ST control signals // assign rx_sop = ((rxdata[139]==1'b1) && (rx_stream_valid0==1'b1))?1'b1:1'b0; assign rx_eop = ((rxdata[136]==1'b1) && (rx_stream_valid0==1'b1))?1'b1:1'b0; always @(posedge clk_in) begin if (srst==1'b1) begin ctrlrx_3dw_reg <=1'b0; ctrlrx_qword_aligned_reg <=1'b0; ctrlrx_digest_reg <=1'b0; ctrlrx_single_cycle_reg <= 1'b0; ctrlrx_payload_reg <=1'b0; end else begin ctrlrx_3dw_reg <=ctrlrx_3dw; ctrlrx_qword_aligned_reg <= ctrlrx_qword_aligned; ctrlrx_digest_reg <=ctrlrx_digest; ctrlrx_single_cycle_reg <= ctrlrx_single_cycle; ctrlrx_payload_reg <= ctrlrx_payload; end end assign ctrlrx_single_cycle = (rx_sop==1'b1) ? ((rx_eop==1'b1) ? 1'b1 : 1'b0) : ctrlrx_single_cycle_reg; // ctrlrx_payload is set when the TLP has payload assign ctrlrx_payload = (rx_sop==1'b1) ? ( (rxdata[126]==1'b1) ? 1'b1 : 1'b0) : ctrlrx_payload_reg; // ctrlrx_3dw is set when the TLP has 3 DWORD header assign ctrlrx_3dw = (rx_sop==1'b1) ? ((rxdata[125]==1'b0) ? 1'b1 : 1'b0) : ctrlrx_3dw_reg; // ctrlrx_qword_aligned is set when the data are address aligned assign ctrlrx_qword_aligned = (rx_sop==1'b1)? (( ((ctrlrx_3dw==1'b1) && (rxdata[34:32]==0)) \|\| ((ctrlrx_3dw==1'b0) && (rxdata[2:0]==0)) ) ? 1'b1: 1'b0 ) : ctrlrx_qword_aligned_reg; assign ctrlrx_digest = (rx_sop==1'b1) ? rxdata[111]:ctrlrx_digest_reg; assign ctrlrx_3dw_aligned = ((ctrlrx_3dw==1'b1) && (ctrlrx_qword_aligned==1'b1))?1'b1:1'b0; assign ctrlrx_3dw_nonaligned = ((ctrlrx_3dw==1'b1) && (ctrlrx_qword_aligned==1'b0))?1'b1:1'b0; assign ctrlrx_4dw_non_aligned = ((ctrlrx_3dw==1'b0) && (ctrlrx_qword_aligned==1'b0))?1'b1:1'b0; assign ctrlrx_4dw_aligned = ((ctrlrx_3dw==1'b0) && (ctrlrx_qword_aligned==1'b1))?1'b1:1'b0; always @(posedge clk_in) begin // ctrlrx_cnt_len_dw counts the number remaining // number of DWORD in rxdata_crc_reg ctrlrx_cnt_len_dw_reg <= (rx_stream_valid0) ? ctrlrx_cnt_len_dw : ctrlrx_cnt_len_dw_reg; if (srst==1'b1) ctrlrx_cnt_len_dw <= 0; else if (rx_sop==1'b1) begin single_crc_cyc <= 1'b0; // default if (rxdata[126]==1'b0) begin // No payload if (ctrlrx_3dw==1'b1) begin ctrlrx_cnt_len_dw <= 0; // 1DW ECRC, subtract 1 since ECRC is packed with descriptor. single_crc_cyc <= 1'b1; end else ctrlrx_cnt_len_dw <= 1; end else if (ctrlrx_3dw==1'b0) ctrlrx_cnt_len_dw <= rxdata[105:96] + 1; // Add ECRC field. else ctrlrx_cnt_len_dw <= rxdata[105:96]; // Add ECRC field. end else if (rx_stream_valid0) begin if (ctrlrx_cnt_len_dw>3) ctrlrx_cnt_len_dw <= ctrlrx_cnt_len_dw-4; else if (ctrlrx_cnt_len_dw>2) ctrlrx_cnt_len_dw <= ctrlrx_cnt_len_dw-3; else if (ctrlrx_cnt_len_dw>1) ctrlrx_cnt_len_dw <= ctrlrx_cnt_len_dw-2; else if (ctrlrx_cnt_len_dw>0) ctrlrx_cnt_len_dw <= ctrlrx_cnt_len_dw-1; end end // for internal monitoring assign crc_32 = (rx_eop_crc_in==1'b0)?0: (ctrlrx_cnt_len_dw_reg[1:0]==0)? rxdata_crc_in[127:96]: (ctrlrx_cnt_len_dw_reg[1:0]==1)? rxdata_crc_in[95:64]: (ctrlrx_cnt_len_dw_reg[1:0]==2)? rxdata_crc_in[63:32]: rxdata_crc_in[31:0]; endmodule
/* * Simple 8-bit FPGA softcore CPU. * Copyright (C) 2015 P. Heinonen. * Licensed under the MIT License. For more details, read the LICENSE file. * * compiler: Icarus Verilog 0.9.7 * Timing analysis with GTKWave * / module waterbear( input clk, input rst, output[7:0] PC); // Control Unit stages // Classic RISC type pipeline without MEM stage parameter IF=2'b00; parameter ID=2'b01; parameter EX=2'b10; parameter WB=2'b11; // index for memcopy in store step integer i; // Control Unit registers reg[1:0] control_unit_current; reg[1:0] control_unit_next; // mnemonics of opcodes parameter LDR = 4'b001; // load parameter STR = 4'b010; // store parameter ADD = 4'b011; // add parameter SUB = 4'b100; // substract parameter EQU = 4'b101; // compare equal parameter JMP = 4'b110; // jump parameter HLT = 4'b111; // halt // memory structure reg[15:0] MEM[0:255]; // Main Memory - 16 bit wide 256 memory cells reg[5:0] WORKMEM[0:127]; // ALU intermediate register reg[5:0] DESTMEM[0:127]; // destination register reg[5:0] R1; // accumulator reg[7:0] PC; // program counter reg[7:0] MAR; // Memory Address register reg[15:0] MDR; // Memory Data/Buffer Register reg[15:0] CIR; // Current Instruction Register // instruction set structure reg[4:0] reserved = 5'b00000; reg[3:0] op_code = 0; reg numbit = 0; reg[5:0] operand = 0; / RAM memory layout contains 256 memorycells which are 16-bit wide to store instruction set. +-----5----+---4----+---1----+---6-----+ INSTRUCTION SET \| \| \| \| \| STRUCTURE \| RESERVED \| OPCODE \| NUMBIT \| OPERAND \| \| \| \| \| \| +----------+--------+--------+---------+ / // initial cpu bootup initial begin // initialize memory and registers init_regs(); // memory initialization for testbench // Sample program calculates equation: x=5+7; / MEM[0] = {reserved, LDR, 1'b1, 6'b000101}; //Load value 5 into R1, mcode: 00000 001 1 000010 MEM[1] = {reserved, STR, 1'b0, 6'b001101}; //Store value from R1 in memory addr 13 MEM[2] = {reserved, LDR, 1'b1, 6'b000111}; //Load value 7 into R1 MEM[3] = {reserved, STR, 1'b0, 6'b001110}; //Store value from R1 in memory addr 14 MEM[4] = {reserved, LDR, 1'b0, 6'b001101}; //Load value from memory addr 13 into R1 MEM[5] = {reserved, ADD, 1'b0, 6'b001110}; //Add value from memory addr 14 to R1 MEM[6] = {reserved, STR, 1'b0, 6'b000010}; //Store value from R1 into memory addr 15 MEM[7] = {reserved, HLT, 1'b0, 6'b000000}; //Stop execution */ // Sample program: Counter to count from 0 to some user coded limit, here 5. MEM[0] = {reserved, LDR, 1'b1, 6'b000101}; //set count value to 5 MEM[1] = {reserved, STR, 1'b0, 6'b001111}; //store count value to address 15 MEM[2] = {reserved, LDR, 1'b1, 6'b000000}; //initialize count to zero MEM[3] = {reserved, EQU, 1'b0, 6'b001111}; //check if count is complete, if yes skip next MEM[4] = {reserved, JMP, 1'b1, 6'b000110}; //set PC to 6 MEM[5] = {reserved, HLT, 1'b0, 6'b000000}; //stop program MEM[6] = {reserved, ADD, 1'b1, 6'b000001}; //increment counter in accumulator MEM[7] = {reserved, JMP, 1'b1, 6'b000011}; //set PC to 3 end // clock cycles always @ (clk, rst) begin if(rst) begin init_regs(); end else begin // Control Unit Finite state machine case(control_unit_current) IF: begin MAR = PC; PC = PC +1; MDR = MEM[MAR]; CIR = MDR; control_unit_next=ID; end ID: begin control_unit_next=EX; InstructionDecoder(CIR, op_code, numbit, operand); end EX: begin // execute ALU instructions case(op_code) LDR: begin if(numbit==1) begin R1 = operand; // direct assign end else begin R1 = WORKMEM[operand]; // assign from address end control_unit_next=WB; end STR: begin WORKMEM[operand] = R1; control_unit_next=WB; end ADD: begin if(numbit==1) begin R1=R1+operand; end else begin R1=R1+WORKMEM[operand]; end control_unit_next=WB; end JMP : begin PC=operand; control_unit_next=WB; end EQU: begin if(R1 == WORKMEM[operand]) begin PC=PC+1; end control_unit_next=WB; end HLT: begin control_unit_next=EX; // continue loop end default: begin end endcase end // end of execute ALU instructions WB: begin // Loop is synthesizable: // http://www.lcdm-eng.com/papers/snug13_SNUG-SV-2013_Synthesizable-SystemVerilog_paper.pdf for (i=0; i<127; i=i+1 ) begin DESTMEM[i] <= WORKMEM[i]; end control_unit_next=IF; end default: begin end endcase control_unit_current=control_unit_next; end end // task to initialize registers and memory task init_regs; begin PC = 0; R1 = 0; MDR = 0; MAR = 0; CIR = 0; //WORKMEM = 0; //{0,128'h80}; //DESTMEM = 0; //{0,128'h80}; control_unit_current = IF; numbit = 0; operand = 0; op_code = 0; reserved = 0; end endtask // in execute, Control Unit task InstructionDecoder; input[15:0] CIR; output[3:0] op_code; output numbit; output[5:0] operand; begin op_code= CIR[10:7]; numbit=CIR[6:6]; operand=CIR[5:0]; end endtask endmodule // For the test 4 core test module multicore( input clk, input rst, output[7:0] PC); waterbear core1(clk, reset, PC); waterbear core2(clk, reset, PC); waterbear core3(clk, reset, PC); waterbear core4(clk, reset, PC); endmodule
/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 / `ifndef SKY130_FD_SC_LP__CLKDLYBUF4S50_PP_SYMBOL_V `define SKY130_FD_SC_LP__CLKDLYBUF4S50_PP_SYMBOL_V /* * clkdlybuf4s50: Clock Delay Buffer 4-stage 0.59um length inner stage * gates. * * Verilog stub (with power pins) for graphical symbol definition * generation. * * WARNING: This file is autogenerated, do not modify directly! / `timescale 1ns / 1ps `default_nettype none ( blackbox *) module sky130_fd_sc_lp__clkdlybuf4s50 ( //# {{data\|Data Signals}} input A , output X , //# {{power\|Power}} input VPB , input VPWR, input VGND, input VNB ); endmodule `default_nettype wire `endif // SKY130_FD_SC_LP__CLKDLYBUF4S50_PP_SYMBOL_V
// DESCRIPTION: Verilator: Verilog Test module module t (/AUTOARG/ // Inputs clk ); input clk; reg [63:0] d; reg [31:0] c; wire [31:0] q = crc (d, c); reg [31:0] q_r; integer cyc; initial cyc=1; always @ (posedge clk) begin if (cyc!=0) begin cyc <= cyc + 1; q_r <= q; c <= q; d <= {d[62:0], ^d[63:48]}; //$write("%d crc(%x,%x)=%x\n", cyc, d, c, q); if (cyc==1) begin // Assign inputs randomly q_r <= 32'h12345678; c <= 32'h12345678; d <= 64'hffffffff_ffffffff; end if (cyc==2) begin d <= 64'hffffffff_ffffffff; end if (cyc==3) begin d <= 64'hffffffff_ffffffff; end if (cyc==4) begin d <= 64'h50183721_81a04b1a; end if (cyc==5) begin end if (cyc==9) begin if (q !== 32'h38295e96) $stop; $write("- All Finished -\n"); $finish; end end end function [31:0] crc; input [63:0] di; input [31:0] ci; reg [63:0] drev; begin drev = reverse(di); crc = newcrc(drev, ci); end endfunction function [63:0] reverse; input [63:0] di; integer i; begin reverse = 64'b0; for (i=0; i<64; i=i+1) reverse[i] = di[63-i]; end endfunction function [31:0] newcrc; input [63:0] D; input [31:0] C; reg [31:0] N; reg [31:0] DT; begin N = 32'b0; // Note this isn't a real CRC code; it's been munged for privacy N[0] = D[59]^D[53]^D[52]^D[49]^D[44]^D[41]^D[40]^D[39]^D[37]^D[32]^D[29]^D[26]^D[22]^D[21]^D[20]^D[16]^D[15]^D[14]^D[9]^D[7]^D[0] ^C[29]^C[27]^C[24]^C[23]^C[22]^C[21]^C[19]^C[15]^C[13]^C[10]^C[8]^C[3]^C[1]; N[1] = D[61]^D[57]^D[51]^D[47]^D[43]^D[37]^D[35]^D[32]^D[28]^D[24]^D[22]^D[21]^D[20]^D[16]^D[12]^D[11]^D[10]^D[8]^D[7]^D[6]^D[1]^D[0] ^C[30]^C[27]^C[26]^C[20]^C[16]^C[14]^C[13]^C[11]^C[10]^C[8]^C[5]^C[0]; N[2] = D[63]^D[62]^D[61]^D[60]^D[55]^D[54]^D[52]^D[44]^D[43]^D[42]^D[37]^D[34]^D[33]^D[29]^D[28]^D[25]^D[24]^D[23]^D[22]^D[18]^D[16]^D[15]^D[13]^D[12]^D[11] ^C[31]^C[30]^C[27]^C[22]^C[21]^C[18]^C[15]^C[12]^C[11]^C[10]^C[7]; N[3] = D[62]^D[54]^D[50]^D[47]^D[46]^D[38]^D[36]^D[35]^D[34]^D[33]^D[32]^D[30]^D[27]^D[25]^D[21]^D[20]^D[19]^D[17]^D[15]^D[11]^D[8]^D[5]^D[3]^D[1]^D[0] ^C[28]^C[25]^C[24]^C[13]^C[11]^C[9]^C[8]^C[7]^C[3]^C[1]; N[4] = D[57]^D[54]^D[53]^D[52]^D[45]^D[44]^D[43]^D[39]^D[37]^D[34]^D[33]^D[32]^D[31]^D[28]^D[24]^D[23]^D[20]^D[19]^D[15]^D[14]^D[10]^D[6]^D[1]^D[0] ^C[30]^C[24]^C[20]^C[16]^C[14]^C[11]^C[8]^C[7]^C[6]^C[5]^C[2]; N[5] = D[58]^D[57]^D[50]^D[49]^D[48]^D[47]^D[43]^D[39]^D[29]^D[26]^D[23]^D[22]^D[20]^D[18]^D[14]^D[10]^D[9]^D[6]^D[5]^D[4]^D[1] ^C[27]^C[24]^C[20]^C[19]^C[18]^C[14]^C[13]^C[12]^C[11]^C[8]^C[7]^C[1]; N[6] = D[63]^D[62]^D[61]^D[57]^D[51]^D[50]^D[47]^D[38]^D[37]^D[34]^D[30]^D[28]^D[27]^D[25]^D[21]^D[16]^D[15]^D[10]^D[9]^D[6]^D[5]^D[2]^D[1] ^C[31]^C[27]^C[25]^C[16]^C[13]^C[9]^C[8]^C[7]^C[0]; N[7] = ^D[62]^D[61]^D[59]^D[54]^D[52]^D[51]^D[49]^D[46]^D[45]^D[42]^D[41]^D[38]^D[35]^D[29]^D[26]^D[24]^D[15]^D[12]^D[11]^D[9]^D[2]^D[0] ^C[28]^C[27]^C[26]^C[20]^C[19]^C[18]^C[15]^C[12]^C[7]^C[4]; N[8] = D[62]^D[61]^D[60]^D[59]^D[52]^D[50]^D[48]^D[47]^D[46]^D[45]^D[44]^D[42]^D[41]^D[40]^D[30]^D[24]^D[23]^D[22]^D[19]^D[17]^D[11]^D[10]^D[7]^D[6]^D[2] ^C[31]^C[29]^C[27]^C[22]^C[21]^C[19]^C[17]^C[11]^C[9]^C[7]^C[6]; N[9] = D[62]^D[59]^D[58]^D[57]^D[54]^D[51]^D[50]^D[43]^D[41]^D[39]^D[28]^D[25]^D[24]^D[23]^D[22]^D[21]^D[18]^D[16]^D[15]^D[7] ^C[30]^C[29]^C[27]^C[25]^C[23]^C[22]^C[13]^C[12]^C[7]^C[6]^C[5]^C[1]; N[10] = D[61]^D[60]^D[58]^D[56]^D[54]^D[53]^D[51]^D[48]^D[46]^D[43]^D[42]^D[38]^D[37]^D[35]^D[33]^D[31]^D[30]^D[27]^D[26]^D[24]^D[19]^D[10]^D[8]^D[6]^D[1] ^C[31]^C[30]^C[26]^C[25]^C[24]^C[21]^C[16]^C[12]^C[3]^C[2]; N[11] = D[59]^D[57]^D[56]^D[50]^D[49]^D[48]^D[47]^D[46]^D[45]^D[42]^D[41]^D[40]^D[33]^D[32]^D[30]^D[25]^D[21]^D[15]^D[14]^D[13]^D[12]^D[11]^D[5]^D[1] ^C[27]^C[25]^C[24]^C[21]^C[16]^C[12]^C[7]^C[3]^C[2]^C[1]; N[12] = D[62]^D[61]^D[59]^D[58]^D[56]^D[55]^D[53]^D[48]^D[47]^D[44]^D[43]^D[35]^D[31]^D[30]^D[28]^D[24]^D[23]^D[21]^D[14]^D[5]^D[2] ^C[28]^C[26]^C[25]^C[23]^C[22]^C[18]^C[16]^C[15]^C[6]; N[13] = D[63]^D[60]^D[58]^D[57]^D[55]^D[54]^D[53]^D[51]^D[47]^D[45]^D[42]^D[41]^D[38]^D[28]^D[26]^D[25]^D[22]^D[20]^D[18]^D[17]^D[15]^D[13]^D[12]^D[11] ^C[29]^C[28]^C[25]^C[22]^C[19]^C[17]^C[16]^C[15]^C[14]^C[12]^C[10]^C[9]; N[14] = D[58]^D[56]^D[55]^D[52]^D[47]^D[43]^D[41]^D[40]^D[39]^D[38]^D[30]^D[26]^D[25]^D[22]^D[19]^D[17]^D[13]^D[11]^D[10]^D[9]^D[8]^D[3]^D[2]^D[0] ^C[31]^C[28]^C[20]^C[18]^C[17]^C[16]^C[15]^C[13]^C[11]^C[4]^C[2]^C[1]; N[15] = D[63]^D[62]^D[61]^D[59]^D[58]^D[48]^D[47]^D[43]^D[42]^D[35]^D[28]^D[26]^D[25]^D[24]^D[23]^D[22]^D[21]^D[20]^D[19]^D[17]^D[11]^D[7]^D[2] ^C[30]^C[29]^C[27]^C[24]^C[20]^C[17]^C[16]^C[15]^C[11]^C[9]^C[5]; N[16] = D[60]^D[57]^D[49]^D[46]^D[45]^D[43]^D[39]^D[36]^D[32]^D[30]^D[29]^D[28]^D[27]^D[26]^D[23]^D[20]^D[19]^D[17]^D[11]^D[8]^D[5]^D[1] ^C[28]^C[26]^C[23]^C[22]^C[18]^C[16]^C[13]^C[12]^C[10]^C[9]^C[6]; N[17] = D[63]^D[62]^D[61]^D[60]^D[58]^D[54]^D[53]^D[51]^D[48]^D[42]^D[41]^D[37]^D[36]^D[34]^D[28]^D[27]^D[26]^D[24]^D[13]^D[12]^D[9]^D[7]^D[4]^D[0] ^C[31]^C[30]^C[27]^C[23]^C[20]^C[17]^C[14]^C[9]^C[6]^C[4]^C[3]^C[0]; N[18] = D[63]^D[61]^D[59]^D[56]^D[52]^D[50]^D[47]^D[42]^D[37]^D[35]^D[34]^D[31]^D[30]^D[29]^D[22]^D[19]^D[17]^D[16]^D[11]^D[9]^D[8]^D[7] ^C[26]^C[22]^C[20]^C[19]^C[16]^C[11]^C[8]^C[6]^C[5]^C[0]; N[19] = D[62]^D[60]^D[52]^D[49]^D[44]^D[43]^D[42]^D[37]^D[33]^D[32]^D[29]^D[26]^D[19]^D[17]^D[16]^D[12]^D[10]^D[7]^D[6]^D[4]^D[3]^D[2] ^C[30]^C[29]^C[26]^C[25]^C[22]^C[19]^C[14]^C[7]^C[6]^C[5]^C[2]^C[0]; N[20] = D[63]^D[58]^D[54]^D[48]^D[47]^D[40]^D[39]^D[35]^D[34]^D[32]^D[31]^D[28]^D[27]^D[25]^D[18]^D[12]^D[9]^D[7]^D[5]^D[4]^D[3]^D[2]^D[1] ^C[31]^C[29]^C[28]^C[25]^C[19]^C[18]^C[17]^C[15]^C[10]^C[9]^C[6]^C[4]; N[21] = D[61]^D[59]^D[57]^D[56]^D[53]^D[48]^D[44]^D[43]^D[41]^D[35]^D[29]^D[26]^D[25]^D[20]^D[18]^D[17]^D[16]^D[12]^D[9]^D[6]^D[5]^D[3]^D[1] ^C[30]^C[27]^C[24]^C[23]^C[22]^C[21]^C[20]^C[13]^C[9]^C[3]^C[2]; N[22] = D[63]^D[62]^D[60]^D[57]^D[53]^D[51]^D[45]^D[44]^D[42]^D[34]^D[33]^D[27]^D[20]^D[19]^D[18]^D[15]^D[10]^D[9]^D[8]^D[4]^D[3] ^C[24]^C[23]^C[18]^C[17]^C[16]^C[14]^C[12]^C[11]^C[10]^C[9]^C[6]^C[5]; N[23] = D[58]^D[56]^D[54]^D[51]^D[47]^D[43]^D[42]^D[40]^D[37]^D[36]^D[33]^D[25]^D[23]^D[20]^D[18]^D[16]^D[15]^D[12]^D[10]^D[8]^D[7]^D[5]^D[3] ^C[31]^C[27]^C[26]^C[23]^C[21]^C[18]^C[15]^C[11]^C[10]^C[8]^C[7]^C[1]; N[24] = D[60]^D[59]^D[52]^D[50]^D[48]^D[44]^D[39]^D[36]^D[35]^D[31]^D[30]^D[28]^D[27]^D[23]^D[22]^D[21]^D[19]^D[14]^D[13]^D[12]^D[9]^D[4]^D[1]^D[0] ^C[27]^C[25]^C[23]^C[21]^C[17]^C[11]^C[10]^C[4]^C[0]; N[25] = D[61]^D[60]^D[56]^D[54]^D[51]^D[46]^D[43]^D[41]^D[40]^D[38]^D[37]^D[36]^D[29]^D[28]^D[27]^D[22]^D[17]^D[15]^D[10]^D[7]^D[4]^D[2] ^C[29]^C[28]^C[26]^C[23]^C[18]^C[14]^C[13]^C[12]^C[11]^C[9]^C[8]^C[6]; N[26] = D[63]^D[62]^D[58]^D[55]^D[54]^D[52]^D[50]^D[39]^D[37]^D[36]^D[35]^D[33]^D[31]^D[29]^D[27]^D[18]^D[14]^D[10]^D[3]^D[2]^D[0] ^C[31]^C[27]^C[26]^C[25]^C[24]^C[21]^C[13]^C[12]^C[10]^C[1]; N[27] = D[62]^D[60]^D[58]^D[56]^D[55]^D[54]^D[51]^D[44]^D[41]^D[36]^D[34]^D[32]^D[31]^D[29]^D[28]^D[27]^D[23]^D[17]^D[12]^D[11]^D[8]^D[6]^D[4]^D[2] ^C[31]^C[30]^C[28]^C[27]^C[23]^C[19]^C[17]^C[16]^C[14]^C[12]^C[11]^C[10]^C[3]; N[28] = D[57]^D[54]^D[53]^D[51]^D[50]^D[48]^D[40]^D[38]^D[34]^D[33]^D[31]^D[30]^D[29]^D[27]^D[23]^D[21]^D[14]^D[9]^D[7]^D[6]^D[5]^D[4]^D[0] ^C[31]^C[30]^C[26]^C[24]^C[15]^C[14]^C[13]^C[7]^C[6]^C[4]^C[3]^C[0]; N[29] = D[62]^D[60]^D[55]^D[46]^D[45]^D[44]^D[43]^D[41]^D[40]^D[35]^D[33]^D[32]^D[30]^D[28]^D[25]^D[23]^D[22]^D[13]^D[8]^D[7]^D[6]^D[5]^D[4]^D[3]^D[1]^D[0] ^C[31]^C[28]^C[27]^C[18]^C[11]^C[8]^C[6]^C[4]^C[2]^C[1]^C[0]; N[30] = D[63]^D[62]^D[59]^D[58]^D[55]^D[52]^D[47]^D[44]^D[36]^D[35]^D[34]^D[31]^D[29]^D[22]^D[21]^D[20]^D[19]^D[15]^D[14]^D[10]^D[6]^D[3]^D[2]^D[0] ^C[28]^C[25]^C[24]^C[22]^C[20]^C[15]^C[14]^C[12]^C[10]^C[9]^C[4]^C[0]; N[31] = D[61]^D[58]^D[56]^D[55]^D[54]^D[52]^D[51]^D[50]^D[49]^D[42]^D[38]^D[37]^D[36]^D[34]^D[31]^D[30]^D[27]^D[26]^D[23]^D[22]^D[21]^D[19]^D[18]^D[12]^D[0] ^C[28]^C[26]^C[24]^C[21]^C[17]^C[16]^C[14]^C[13]^C[10]^C[8]^C[2]; newcrc = N; end endfunction endmodule
`include "config.v" module A2S_controller( // system reset rst, // stream clk Sclk, // system sync(reset) sync, // Buffer read Oen, Oaddr, obase, osize, oacnt, obcnt, // AXI Bus Signal AXI_clk, AXI_rst_n, AXI_araddr, AXI_arvalid, AXI_arready, AXI_rready, AXI_rvalid, AXI_rlast, // Buffer write a2s_addr, a2s_en ); parameter s0 = 3'd0; parameter s1 = 3'd1; parameter s2 = 3'd2; parameter s3 = 3'd3; input rst,Sclk,sync,Oen; output[4:0] Oaddr; input AXI_clk; input AXI_rst_n; output reg[31:0] AXI_araddr; input AXI_arready,AXI_rvalid; output reg AXI_rready,AXI_arvalid; input AXI_rlast; output reg[4:0] a2s_addr; output a2s_en; reg[21:0] cnt; reg[31:0] bcnt; reg start; wire axi_start; reg [2:0]state; reg [31:0]AXI_araddr_reg; input [31:0]obase; input [23:6]osize; output [23:6]oacnt; output [31:0]obcnt; assign Oaddr = cnt[4:0]; assign oacnt[23:6] = cnt[21:4]; assign obcnt = bcnt; edgesync #(.e("pos")) start_sync ( .clk(AXI_clk) , .async(start) , .sync(axi_start) ); always @(posedge Sclk or posedge rst) begin if( rst==1'b1 ) begin start <= 1'b0; cnt <= 22'h0; bcnt <= 32'h0; end else begin if ( sync==1'b1 ) begin start <= 1'b0; cnt <= 22'h0; bcnt <= 32'h0; end else if( Oen==1'b1 ) begin if( cnt[3:0]==4'hf ) begin AXI_araddr_reg[5:0] <= 6'b000000; AXI_araddr_reg[31:6] <= obase[31:6] + cnt[21:4]; cnt[3:0] <= 4'h0; if( cnt[21:4]==(osize[23:6]-1'b1) ) begin cnt[21:4] <= 18'h0; bcnt <= bcnt + 32'h1; end else cnt[21:4] <= cnt[21:4]+18'h1; end else cnt[3:0] <= cnt[3:0] + 4'h1; end if( Oen==1'b1 && cnt[3:0]==4'hf && start==1'b0 ) start <= 1'b1; else start <= 1'b0; end end assign a2s_en = AXI_rvalid & AXI_rready; always @(posedge AXI_clk) begin if( !AXI_rst_n ) begin a2s_addr <= 5'b00000; AXI_arvalid <= 1'b0; AXI_rready <= 1'b0; AXI_araddr <= obase; state <= s0; end else begin if( axi_start==1'b1 ) begin state <= s1; AXI_araddr <= AXI_araddr_reg; end else begin case( state ) s0 : begin AXI_rready <= AXI_rvalid; end s1 : begin AXI_arvalid <= 1'b1; if( AXI_arready==1'b1 && AXI_arvalid==1'b1 ) begin state <= s2; AXI_arvalid <= 1'b0; a2s_addr[4] <= AXI_araddr[6]; a2s_addr[3:0] <= 4'h0; AXI_rready <= 1'b1; end end s2 : begin if( a2s_en==1'b1 ) begin a2s_addr[3:0] <= a2s_addr[3:0] + 1'b1; if( AXI_rlast==1'b1 ) begin state <= s0; AXI_rready <= 1'b0; end end end endcase end end end endmodule
module datapath ( input CLK, input CLK_MEM, input RESET, input RUN, //Controller iface input WRITE_REG, //write to register file input WRITE_MEM, //write data memory input ALUORMEM_WR, //write regfile from alu or from memory input MEM_PARTIAL, //memory byte- or halfword access input [1:0] MEM_OPTYPE, //mem op: 00-ubyte, 01-uhalf, 10-sb, 11-sh input MULTIPLY, //do multiplication and write hi&lo input BRANCH_E, //branch equal input BRANCH_NE, //branch not equal input BRANCH_LEZ, //branch less than or equal zero input BRANCH_LTZ, //branch less than zero input BRANCH_GEZ, //branch greater than or equal zero input BRANCH_GTZ, //branch greater than zero input JUMP, //j-type jump input JUMP_R, //jr, jalr input ALU_SRC_B, //ALU Operand B 0 - reg_2, 1 - immediate input [6:0] ALU_OP, //ALU Operation select input [1:0] REG_DST, //write destination in regfile (0 - rt, 1 - rd, 1X -- 31) input [1:0] IMMED_EXT, //immediate extension type (sign, zero, swap) input [1:0] MFCOP_SEL, //move from cop sel. 0 - from alu, 1 - from HI, 2 - from LO, 3 -- from C0 output [5:0] OPCODE, //instruction opcode output [5:0] FCODE, //instruction fcode output [4:0] RT, //instruction RT field //External inst memory iface output [29:0] inst_mem_addr, input [31:0] inst_mem_data, //External data memory iface output data_mem_we, output [ 3:0] data_mem_be, output [29:0] data_mem_addr, output [31:0] data_mem_wdata, input [31:0] data_mem_rdata ); //------------------------WIRE DEFINITIONS-----------------------------------// //FETCH: wire [31:0] branch_target, jump_target, jumpr_target, next_pc_reg, pc, pc_plus_4; //DECODE: wire [31:0] inst_d, pc_plus_4_d, rd1, rd2, regfile_wdata, immed_extend_d, immed_extend_sl2_d, rd1_fwd, rd2_fwd; wire [4:0] reg_dst_addr_w, rs_d, rt_d; wire link_d, do_branch, stall, lw_stall, br_stall; //EXECUTE: wire [31:0] pc_plus_4_e, immed_extend_e, src_a_e, src_b_e, src_a_fwd_e, src_b_fwd_e, src_a, src_b, hi_e, lo_e, aluout_e, aluout_mux_e; wire [6:0] alu_op_e; wire [4:0] reg_dst_addr_e, rs_e, rt_e, rd_e, shamt_e; wire [1:0] reg_dst_e, mfcop_sel_e, mem_optype_e; wire write_reg_e, write_mem_e, aluormem_e, multiply_e, alu_src_b_e, link_e, alu_zero, mem_partial_e; //MEM: wire [31:0] aluout_m, src_b_m, mem_reordered_m; wire [4:0] reg_dst_addr_m; wire [1:0] mem_optype_m; wire write_reg_m, write_mem_m, aluormem_m, mem_partial_m; //WRITEBACK: wire [31:0] aluout_w, mem_reordered_w; wire write_reg_w, aluormem_w; //------------------------FETCH STAGE----------------------------------------// assign pc_plus_4 = pc + 4; assign stall = lw_stall \| br_stall; assign inst_mem_addr = pc[31:2]; wire [1:0] next_pc_select = JUMP ? 2'b11 : JUMP_R ? 2'b10 : do_branch ? 2'b01 : 2'b00 ; mux4 pc_src_mux( next_pc_select, pc_plus_4, //00: pc = pc + 4 branch_target, //01: conditional branch jumpr_target, //10: from register file jump_target, //11: from j-type instruction next_pc_reg ); ffd pc_reg(CLK, RESET, ~stall & RUN, next_pc_reg, pc ); ffd #(64) pipe_reg_D(CLK, RESET, ~stall & RUN, { inst_mem_data, pc_plus_4 }, { inst_d, pc_plus_4_d }); //---------------------------------------------------------------------------// //------------------------DECODE STAGE---------------------------------------// assign OPCODE = inst_d[31:26]; assign FCODE = inst_d [5:0]; assign RT = inst_d[20:16]; assign rs_d = inst_d[25:21]; assign rt_d = inst_d[20:16]; regfile rf_unit(.CLK (CLK_MEM ), .WE (write_reg_w ), .RD_ADDR_1 (rs_d ), //in_rd_addr .RD_ADDR_2 (rt_d ), //in_rd_addr .WR_ADDR_3 (reg_dst_addr_w ), //in_wr_addr .W_DATA (regfile_wdata ), //in .R_DATA_1 (rd1 ), //out .R_DATA_2 (rd2 )); //out //------IMMEDIATE EXTENSION-------- immed_extend immed_ext_unit(IMMED_EXT, inst_d[15:0], immed_extend_d); //------BRANCH LOGIC------- sl2 shl2_unit(immed_extend_d, immed_extend_sl2_d); wire fwd_br_a = (rs_d != 0) && (rs_d == reg_dst_addr_m) && write_reg_m; wire fwd_br_b = (rt_d != 0) && (rt_d == reg_dst_addr_m) && write_reg_m; mux2 fwd_br_a_mux(fwd_br_a, rd1, //0 -- no forwarding aluout_m, //1 -- forward from MEM rd1_fwd ); mux2 fwd_br_b_mux(fwd_br_b, rd2, //0 -- no forwarding aluout_m, //1 -- forward from MEM rd2_fwd ); wire br_inst = BRANCH_E \| BRANCH_NE \| BRANCH_LEZ \| BRANCH_LTZ \| BRANCH_GEZ \| BRANCH_GTZ \| JUMP \| JUMP_R; assign br_stall = (rs_d != 0) & br_inst & ((write_reg_e & ((reg_dst_addr_e == rs_d) \| (reg_dst_addr_e == rt_d) )) \| (aluormem_m & ((reg_dst_addr_m == rs_d) \| //lw (reg_dst_addr_m == rt_d) ))); assign branch_target = immed_extend_sl2_d + pc_plus_4_d; assign jump_target = {pc_plus_4_d[31:28], inst_d[25:0], 2'b00}; assign jumpr_target = rd1_fwd; wire regs_equal = (rd1_fwd == rd2_fwd); wire reg_zero = (rd1_fwd == 0); assign do_branch = ( (BRANCH_E & regs_equal) \| (BRANCH_NE & ~regs_equal) \| (BRANCH_LEZ & ( rd1_fwd[31] \| reg_zero)) \| // <= 0 (BRANCH_LTZ & rd1_fwd[31] ) \| // < 0 (BRANCH_GEZ & ~rd1_fwd[31] ) \| // >= 0 (BRANCH_GTZ & (~rd1_fwd[31] & ~reg_zero)) ); // > 0 assign link_d = JUMP \| JUMP_R \| BRANCH_GEZ \| BRANCH_LTZ; ffd #(168) pipe_reg_E(CLK, RESET \| stall, RUN, { WRITE_REG, // 1/ write to register file WRITE_MEM, // 1/ write data memory MEM_PARTIAL, // 1/ memory byte- or halfword access MEM_OPTYPE, // 2/ mem op: 00-ubyte, 01-uhalf, 10-sb, 11-sh ALUORMEM_WR, // 1/ write regfile from alu or from memory MULTIPLY, // 1/ do multiplication and write hi&lo link_d, // 1/ link ALU_SRC_B, // 1/ ALU Operand B 0 - reg_2, 1 - immediate ALU_OP, // 7/ ALU Operation select REG_DST, // 2/ write destination in regfile (0 - rt, 1 - rd) MFCOP_SEL, // 2/ mfrom coprocessor selector rd1, //32/ regfile_out_1 rd2, //32/ regfile_out_2 rs_d, // 5/ RS rt_d, // 5/ RT inst_d[15:11], // 5/ RD inst_d[10:06], // 5/ SHAMT immed_extend_d, //32/ immediate pc_plus_4_d }, //32/ pc plus 4 { write_reg_e, // 1/ write to register file write_mem_e, // 1/ write data memory mem_partial_e, // 1/ memory byte- or halfword access mem_optype_e, // 2/ mem op: 00-ubyte, 01-uhalf, 10-sb, 11-sh aluormem_e, // 1/ write regfile from alu or from memory multiply_e, // 1/ do multiplication and write hi&lo link_e, // 1/ link alu_src_b_e, // 1/ ALU Operand B 0 - reg_2, 1 - immediate alu_op_e, // 7/ ALU Operation select reg_dst_e, // 2/ write destination in regfile (0 - rt, 1 - rd) mfcop_sel_e, // 2/ mfrom coprocessor selector src_a_e, src_b_e, rs_e, rt_e, rd_e, shamt_e, immed_extend_e, pc_plus_4_e }); //---------------------------------------------------------------------------// //------------------------EXECUTE STAGE--------------------------------------// mux4 #(5) regfile_wr_addr_mux( reg_dst_e, rt_e, rd_e, 5'd31, //ra 5'd31, //ra reg_dst_addr_e); //forwarding mux's wire [1:0] fwd_a = ((rs_e != 0) && (rs_e == reg_dst_addr_m) && write_reg_m) ? 2'b10 : ((rs_e != 0) && (rs_e == reg_dst_addr_w) && write_reg_w) ? 2'b01 : 2'b00; wire [1:0] fwd_b = ((rt_e != 0) && (rt_e == reg_dst_addr_m) && write_reg_m) ? 2'b10 : ((rt_e != 0) && (rt_e == reg_dst_addr_w) && write_reg_w) ? 2'b01 : 2'b00; //lw stall logic assign lw_stall = aluormem_e & ((rs_d == rt_e) \| (rt_d == rt_e) ); mux4 fwd_src_a(fwd_a, src_a_e, //00 -- no forwarding regfile_wdata, //01 -- forward from WB aluout_m, //10 -- forward from MEM src_a_e, //11 -- no forwarding src_a_fwd_e ); mux4 fwd_src_b(fwd_b, src_b_e, //00 -- no forwarding regfile_wdata, //01 -- forward from WB aluout_m, //10 -- forward from MEM src_b_e, //11 -- no forwarding src_b_fwd_e ); //final alu muxes mux2 alu_src_a_mux( link_e, src_a_fwd_e, pc_plus_4_e, src_a ); mux4 alu_src_b_mux( {link_e, alu_src_b_e}, src_b_fwd_e, //00: forwarded src b immed_extend_e, //01: immediate 32'd4, //10: 4 for ret_addr calculation 32'd4, //11: 4 for ret_addr calculation src_b ); alu alu(alu_op_e, src_a, src_b, shamt_e, aluout_e, alu_zero); wire [63:0] product_e = src_a_fwd_e * src_b_fwd_e; ffd #( 64) hi_lo_reg(CLK, RESET, multiply_e & RUN, product_e, {hi_e, lo_e}); mux4 aluout_mux( mfcop_sel_e, aluout_e, hi_e, //MFHI lo_e, //MFLO 32'hXXXXXXXX, //MFC0 aluout_mux_e ); ffd #( 75) pipe_reg_M(CLK, RESET, RUN, { write_reg_e, // 1/ write to register file write_mem_e, // 1/ write data memory mem_partial_e, // 1/ memory byte- or halfword access mem_optype_e, // 2/ mem op: 00-ubyte, 01-uhalf, 10-sb, 11-sh aluormem_e, // 1/ write regfile from alu or from memory aluout_mux_e, //32/ ALU result src_b_fwd_e, //32/ regfile data B reg_dst_addr_e }, // 5/ destination reg addr { write_reg_m, write_mem_m, mem_partial_m, mem_optype_m, aluormem_m, aluout_m, src_b_m, reg_dst_addr_m }); //---------------------------------------------------------------------------// //------------------------MEMORY STAGE---------------------------------------// assign data_mem_we = write_mem_m; assign data_mem_addr = aluout_m[31:2]; store_reorder st_reorder_unit( .LO_ADDR ( aluout_m[1:0] ), .DATA_IN ( src_b_m ), .PARTIAL ( mem_partial_m ), .OP_TYPE ( mem_optype_m ), .BYTE_EN ( data_mem_be ), .DATA_OUT( data_mem_wdata )); load_reorder ld_reorder_unit( .LO_ADDR ( aluout_m[1:0] ), .DATA_IN ( data_mem_rdata ), .PARTIAL ( mem_partial_m ), .OP_TYPE ( mem_optype_m ), .DATA_OUT( mem_reordered_m)); ffd #( 71) pipe_reg_W(CLK, RESET, RUN, { write_reg_m, // 1/ write to register file aluormem_m, // 1/ write regfile from alu or from memory aluout_m, //32/ alu result mem_reordered_m, //32/ memory data reg_dst_addr_m}, // 5/ destination register { write_reg_w, // 1/ write to register file aluormem_w, // 1/ write regfile from alu or from memory aluout_w, //32/ alu result mem_reordered_w, //32/ memory data reg_dst_addr_w} ); // 5/ destination register //---------------------------------------------------------------------------// //-----------------------WRITEBACK STAGE-------------------------------------// mux2 regfile_wr_data_mux( aluormem_w, aluout_w, //0: ALU out mem_reordered_w, //1: MEM out regfile_wdata); //---------------------------------------------------------------------------// endmodule
/* * * Copyright (c) 2011-2012 [email protected] * * * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see <http://www.gnu.org/licenses/>. * */ // Top-level module that uses the unoptimized mining core and Virtual Wire // external interface. `timescale 1ns/1ps module fpgaminer_top ( input MAIN_CLK ); // The LOOP_LOG2 parameter determines how unrolled the SHA-256 // calculations are. For example, a setting of 0 will completely // unroll the calculations, resulting in 128 rounds and a large, but // fast design. // // A setting of 1 will result in 64 rounds, with half the size and // half the speed. 2 will be 32 rounds, with 1/4th the size and speed. // And so on. // // Valid range: [0, 5] `ifdef CONFIG_LOOP_LOG2 localparam LOOP_LOG2 = `CONFIG_LOOP_LOG2; `else localparam LOOP_LOG2 = 0; `endif // No need to adjust these parameters localparam [5:0] LOOP = (6'd1 << LOOP_LOG2); // The nonce will always be larger at the time we discover a valid // hash. This is its offset from the nonce that gave rise to the valid // hash (except when LOOP_LOG2 == 0 or 1, where the offset is 131 or // 66 respectively). localparam [31:0] GOLDEN_NONCE_OFFSET = (32'd1 << (7 - LOOP_LOG2)) + 32'd1; //// reg [255:0] state = 0; reg [511:0] data = 0; reg [31:0] nonce = 32'h00000000; //// PLL wire hash_clk; hashing_pll # ( .INPUT_FREQUENCY (`MAIN_CLK_FREQUENCY), .DIVIDE_BY (`MAIN_CLK_DIVIDE), .MULTIPLY_BY (`MAIN_CLK_MULTIPLY) ) pll_blk ( .rx_clk (MAIN_CLK), .tx_hash_clk (hash_clk) ); //// Hashers wire [255:0] hash, hash2; reg [5:0] cnt = 6'd0; reg feedback = 1'b0; sha256_transform #(.LOOP(LOOP)) uut ( .clk(hash_clk), .feedback(feedback), .cnt(cnt), .rx_state(state), .rx_input(data), .tx_hash(hash) ); sha256_transform #(.LOOP(LOOP)) uut2 ( .clk(hash_clk), .feedback(feedback), .cnt(cnt), .rx_state(256'h5be0cd191f83d9ab9b05688c510e527fa54ff53a3c6ef372bb67ae856a09e667), .rx_input({256'h0000010000000000000000000000000000000000000000000000000080000000, hash}), .tx_hash(hash2) ); //// Virtual Wire Control reg [255:0] midstate_buf = 0, data_buf = 0; wire [255:0] midstate_vw, data2_vw; virtual_wire # (.OUTPUT_WIDTH(256), .INSTANCE_ID("STAT")) midstate_vw_blk (.clk (hash_clk), .rx_data (), .tx_data (midstate_vw)); virtual_wire # (.OUTPUT_WIDTH(256), .INSTANCE_ID("DAT2")) data2_vw_blk (.clk (hash_clk), .rx_data (), .tx_data (data2_vw)); //// Virtual Wire Output reg [31:0] golden_nonce = 0; virtual_wire # (.INPUT_WIDTH(32), .INSTANCE_ID("GNON")) golden_nonce_vw_blk (.clk (hash_clk), .rx_data (golden_nonce), .tx_data ()); virtual_wire # (.INPUT_WIDTH(32), .INSTANCE_ID("NONC")) nonce_vw_blk (.clk (hash_clk), .rx_data (nonce), .tx_data ()); //// Control Unit reg is_golden_ticket = 1'b0; reg feedback_d1 = 1'b1; wire [5:0] cnt_next; wire [31:0] nonce_next; wire feedback_next; assign cnt_next = (LOOP == 1) ? 6'd0 : (cnt + 6'd1) & (LOOP-1); // On the first count (cnt==0), load data from previous stage (no feedback) // on 1..LOOP-1, take feedback from current stage // This reduces the throughput by a factor of (LOOP), but also reduces the design size by the same amount assign feedback_next = (LOOP == 1) ? 1'b0 : (cnt_next != {(LOOP_LOG2){1'b0}}); assign nonce_next = feedback_next ? nonce : (nonce + 32'd1); always @ (posedge hash_clk) begin midstate_buf <= midstate_vw; data_buf <= data2_vw; cnt <= cnt_next; feedback <= feedback_next; feedback_d1 <= feedback; // Give new data to the hasher state <= midstate_buf; data <= {384'h000002800000000000000000000000000000000000000000000000000000000000000000000000000000000080000000, nonce_next, data_buf[95:0]}; nonce <= nonce_next; // Check to see if the last hash generated is valid. is_golden_ticket <= (hash2[255:224] == 32'h00000000) && !feedback_d1; if(is_golden_ticket) begin // TODO: Find a more compact calculation for this if (LOOP == 1) golden_nonce <= nonce - 32'd131; else if (LOOP == 2) golden_nonce <= nonce - 32'd66; else golden_nonce <= nonce - GOLDEN_NONCE_OFFSET; end end endmodule
/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 / `ifndef SKY130_FD_SC_HS__TAPVPWRVGND_PP_BLACKBOX_V `define SKY130_FD_SC_HS__TAPVPWRVGND_PP_BLACKBOX_V /* * tapvpwrvgnd: Substrate and well tap cell. * * Verilog stub definition (black box with power pins). * * WARNING: This file is autogenerated, do not modify directly! / `timescale 1ns / 1ps `default_nettype none ( blackbox *) module sky130_fd_sc_hs__tapvpwrvgnd ( VPWR, VGND ); input VPWR; input VGND; endmodule `default_nettype wire `endif // SKY130_FD_SC_HS__TAPVPWRVGND_PP_BLACKBOX_V
//Jun.30.2004 NOP_DISABLE BUG FIX `include "define.h" module pc_module(clock,sync_reset,pc_commandD1,PCC,imm,ea_reg_source,takenD2, takenD3 ,branchQQ,jumpQ,NOP_Signal,control_state,IMMD1, PCCDD); input clock; input sync_reset; input [31:0] ea_reg_source; input [2:0] pc_commandD1; input takenD2; input [25:0] imm; input [25:0] IMMD1; `ifdef RAM4K output [11:0] PCC; `else output [25:0] PCC; `endif input takenD3; input branchQQ,jumpQ; input NOP_Signal; input [7:0] control_state; reg [2:0] pc_commandD2,pc_commandD3; `ifdef RAM4K reg [11:0] PC; reg [11:0] pcimm1D1,pcimm2D1; reg [15:0] immD1;// reg [11:0] pcimm1D2,pcimm2D2,pcimm2D3; reg [11:0] save_pc; wire [11:0] PCC; output [11:0] PCCDD; reg [11:0] PCCD,PCCDD; `else reg [25:0] PC; reg [25:0] pcimm1D1,pcimm2D1; reg [15:0] immD1;// reg [25:0] pcimm1D2,pcimm2D2,pcimm2D3; reg [25:0] save_pc; wire [25:0] PCC; output [25:0] PCCDD; reg [25:0] PCCD,PCCDD; `endif reg takenD4; reg branchQQQtakenD4; //combination always@(posedge clock) PCCD<=PCC; always@(posedge clock) PCCDD<=PCCD; always @(posedge clock) begin pc_commandD2 <=pc_commandD1; end // always @(posedge clock) begin if (NOP_Signal) pc_commandD3<=3'b000;//Jun.30.2004 else pc_commandD3 <=pc_commandD2; end always @(IMMD1 ) begin pcimm1D1={IMMD1,2'b00};//Jul.7.2004 {imm[23:0],2'b00};//+{PC[25:2],2'b00}; end `ifdef RAM4K always @(posedge clock) begin pcimm2D1<={PC[11:2],2'b00}; end `else always @(posedge clock) begin pcimm2D1<={PC[25:2],2'b00}; end `endif always @(posedge clock) begin pcimm1D2<=pcimm1D1; end always @(posedge clock) begin pcimm2D2<={{8 {immD1[15]}},immD1[15:0],2'b00}+pcimm2D1;//Jul.14.2004 end always @(posedge clock) begin pcimm2D3<=pcimm2D2; end always @(posedge clock) begin immD1<=imm[15:0];//Jul.14.2004 end always @(posedge clock) begin if (control_state==8'b00_000_010) save_pc<=PCCDD; end always @(posedge clock) begin if (sync_reset) PC<=26'h0_00_0000_0000; else if (branchQQQtakenD4) PC<=pcimm2D3+4;//NOP else if (jumpQ && !NOP_Signal) PC<=pcimm1D1+4; else if (pc_commandD3==`PC_REG) PC<=ea_reg_source[25:0]+4; else if (control_state[2:0]==3'b110) PC<=save_pc+4;//mul/div else case(pc_commandD1) `PC_INC: PC<=PC+4; default: PC<=PC+4; endcase end always @(posedge clock) begin if (sync_reset) takenD4<=1'b0; else takenD4<=takenD3; end always @(posedge clock) begin if (sync_reset) branchQQQtakenD4<=1'b0; else branchQQQtakenD4<=branchQQ && takenD3; end assign PCC= branchQQQtakenD4 ? pcimm2D3 : jumpQ && !NOP_Signal ? pcimm1D1 : pc_commandD3==`PC_REG ? ea_reg_source[25:0] : control_state[2:0] ==3'b110 ? save_pc:PC;//Jun.27.2004 endmodule
// DEFINES `define BITS 32 // Bit width of the operands module syn2(clock, reset, in1, in2, in3, in4, in5, out_1, out_2, out_3, out_4 ); // SIGNAL DECLARATIONS input clock; input reset; input [`BITS-1:0] in1; input [`BITS-1:0] in2; input [`BITS-1:0] in3; input [`BITS-1:0] in4; input [`BITS-1:0] in5; output [`BITS-1:0] out_1; output [`BITS-1:0] out_2; output [`BITS-1:0] out_3; output [`BITS-1:0] out_4; wire [`BITS-1:0] x1; wire [`BITS-1:0] x2; wire [`BITS-1:0] x3; wire [`BITS-1:0] x4; wire [`BITS-1:0] add1; wire [`BITS-1:0] add2; wire [`BITS-1:0] add3; wire [`BITS-1:0] add4; wire [`BITS-1:0] add5; reg [`BITS-1:0] reg1; reg [`BITS-1:0] reg2; reg [`BITS-1:0] reg3; reg [`BITS-1:0] reg4; reg [`BITS-1:0] reg5; reg [`BITS-1:0] reg6; wire [`BITS-1:0] out_1; wire [`BITS-1:0] out_2; wire [`BITS-1:0] out_3; wire [`BITS-1:0] out_4; // ASSIGN STATEMENTS //assign add1 = reg1 + in4; wire [7:0] add1_control; fpu_add add1_add ( .clk(clock), .opa(reg6), .opb(in4), .out(add1), .control(add1_control) ); //assign x1 = x3 * in1; wire [7:0] x1_control; fpu_mul x1_mul ( .clk(clock), .opa(x3), .opb(in1), .out(x1), .control(x1_control) ); //assign add2 = add5 + add1; wire [7:0] add2_control; fpu_add add2_add ( .clk(clock), .opa(add5), .opb(add1), .out(add2), .control(add2_control) ); //assign x2 = x1 * add2; wire [7:0] x2_control; fpu_mul x2_mul ( .clk(clock), .opa(x1), .opb(add2), .out(x2), .control(x2_control) ); //assign add3 = in1 + reg1; wire [7:0] add3_control; fpu_add add3_add ( .clk(clock), .opa(in1), .opb(reg6), .out(add3), .control(add3_control) ); //assign x3 = in3 * in1; wire [7:0] x3_control; fpu_mul x3_mul ( .clk(clock), .opa(in3), .opb(in1), .out(x3), .control(x3_control) ); //assign add4 = in5 + in3; wire [7:0] add4_control; fpu_add add4_add ( .clk(clock), .opa(in5), .opb(in3), .out(add4), .control(add4_control) ); //assign x4 = in5 * in4; wire [7:0] x4_control; fpu_mul x4_mul ( .clk(clock), .opa(in5), .opb(in4), .out(x4), .control(x4_control) ); //assign add5 = in5 + in4; wire [7:0] add5_control; fpu_add add5_add ( .clk(clock), .opa(in5), .opb(in4), .out(add5), .control(add5_control) ); assign out_1 = x2; assign out_2 = add3; assign out_3 = add4; assign out_4 = x4; always @(posedge clock) begin reg1 <= in2; reg2 <= reg1; reg3 <= reg2; reg4 <= reg3; reg5 <= reg4; reg6 <= reg5; end endmodule module fpu_mul( clk, //rmode, opa, opb, out, control /* inf, snan, qnan, ine, overflow, underflow, zero, div_by_zero / ); input clk; //input [1:0] rmode; input [31:0] opa, opb; output [31:0] out; output [7:0] control; / output inf, snan, qnan; output ine; output overflow, underflow; output zero; output div_by_zero; / //////////////////////////////////////////////////////////////////////// // // Local Wires // reg [2:0] fpu_op; reg zero; reg [31:0] opa_r, opb_r; // Input operand registers reg [31:0] out; // Output register reg div_by_zero; // Divide by zero output register wire signa, signb; // alias to opX sign wire sign_fasu; // sign output wire [26:0] fracta, fractb; // Fraction Outputs from EQU block wire [7:0] exp_fasu; // Exponent output from EQU block reg [7:0] exp_r; // Exponent output (registerd) wire [26:0] fract_out_d; // fraction output wire co; // carry output reg [27:0] fract_out_q; // fraction output (registerd) wire [30:0] out_d; // Intermediate final result output wire overflow_d, underflow_d;// Overflow/Underflow Indicators reg overflow, underflow; // Output registers for Overflow & Underflow reg inf, snan, qnan; // Output Registers for INF, SNAN and QNAN reg ine; // Output Registers for INE reg [1:0] rmode_r1, rmode_r2, // Pipeline registers for rounding mode rmode_r3; reg [2:0] fpu_op_r1, fpu_op_r2, // Pipeline registers for fp opration fpu_op_r3; wire mul_inf, div_inf; wire mul_00, div_00; / parameter INF = 31'h7f800000; parameter QNAN = 31'h7fc00001; parameter SNAN = 31'h7f800001; / wire [1:0] rmode; assign rmode = 2'b00; wire [30:0] INF; assign INF = 31'h7f800000; wire [30:0] QNAN; assign QNAN = 31'h7fc00001; wire [30:0] SNAN; assign SNAN = 31'h7f800001; // start output_reg reg [31:0] out_o1; reg inf_o1, snan_o1, qnan_o1; reg ine_o1; reg overflow_o1, underflow_o1; reg zero_o1; reg div_by_zero_o1; // end output_reg wire [7:0] contorl; assign control = {inf, snan, qnan, ine, overflow, underflow, zero, div_by_zero}; //////////////////////////////////////////////////////////////////////// // // Input Registers // always @(posedge clk) begin fpu_op[2:0] <= 3'b010; end always @(posedge clk) opa_r <= opa; always @(posedge clk) opb_r <= opb; always @(posedge clk) rmode_r1 <= rmode; always @(posedge clk) rmode_r2 <= rmode_r1; always @(posedge clk) rmode_r3 <= rmode_r2; always @(posedge clk) fpu_op_r1 <= fpu_op; always @(posedge clk) fpu_op_r2 <= fpu_op_r1; always @(posedge clk) fpu_op_r3 <= fpu_op_r2; //////////////////////////////////////////////////////////////////////// // // Exceptions block // wire inf_d, ind_d, qnan_d, snan_d, opa_nan, opb_nan; wire opa_00, opb_00; wire opa_inf, opb_inf; wire opa_dn, opb_dn; except u0( .clk(clk), .opa(opa_r[30:0]), .opb(opb_r[30:0]), .inf(inf_d), .ind(ind_d), .qnan(qnan_d), .snan(snan_d), .opa_nan(opa_nan), .opb_nan(opb_nan), .opa_00(opa_00), .opb_00(opb_00), .opa_inf(opa_inf), .opb_inf(opb_inf), .opa_dn(opa_dn), .opb_dn(opb_dn) ); //////////////////////////////////////////////////////////////////////// // // Pre-Normalize block // - Adjusts the numbers to equal exponents and sorts them // - determine result sign // - determine actual operation to perform (add or sub) // wire nan_sign_d, result_zero_sign_d; reg sign_fasu_r; wire [7:0] exp_mul; wire sign_mul; reg sign_mul_r; wire [23:0] fracta_mul, fractb_mul; wire inf_mul; reg inf_mul_r; wire [1:0] exp_ovf; reg [1:0] exp_ovf_r; wire sign_exe; reg sign_exe_r; wire [2:0] underflow_fmul_d; pre_norm_fmul u2( .clk(clk), .fpu_op(fpu_op_r1), .opa(opa_r), .opb(opb_r), .fracta(fracta_mul), .fractb(fractb_mul), .exp_out(exp_mul), // FMUL exponent output (registered) .sign(sign_mul), // FMUL sign output (registered) .sign_exe(sign_exe), // FMUL exception sign output (registered) .inf(inf_mul), // FMUL inf output (registered) .exp_ovf(exp_ovf), // FMUL exponnent overflow output (registered) .underflow(underflow_fmul_d) ); always @(posedge clk) sign_mul_r <= sign_mul; always @(posedge clk) sign_exe_r <= sign_exe; always @(posedge clk) inf_mul_r <= inf_mul; always @(posedge clk) exp_ovf_r <= exp_ovf; //////////////////////////////////////////////////////////////////////// // // Mul // wire [47:0] prod; mul_r2 u5(.clk(clk), .opa(fracta_mul), .opb(fractb_mul), .prod(prod)); //////////////////////////////////////////////////////////////////////// // // Normalize Result // wire ine_d; reg [47:0] fract_denorm; wire [47:0] fract_div; wire sign_d; reg sign; reg [30:0] opa_r1; reg [47:0] fract_i2f; reg opas_r1, opas_r2; wire f2i_out_sign; always @(posedge clk) // Exponent must be once cycle delayed exp_r <= exp_mul; always @(posedge clk) opa_r1 <= opa_r[30:0]; //always @(fpu_op_r3 or prod) always @(prod) fract_denorm = prod; always @(posedge clk) opas_r1 <= opa_r[31]; always @(posedge clk) opas_r2 <= opas_r1; assign sign_d = sign_mul; always @(posedge clk) sign <= (rmode_r2==2'h3) ? !sign_d : sign_d; wire or_result; assign or_result = mul_00 \| div_00; post_norm u4( //.clk(clk), // System Clock .fpu_op(fpu_op_r3), // Floating Point Operation .opas(opas_r2), // OPA Sign .sign(sign), // Sign of the result .rmode(rmode_r3), // Rounding mode .fract_in(fract_denorm), // Fraction Input .exp_in(exp_r), // Exponent Input .exp_ovf(exp_ovf_r), // Exponent Overflow .opa_dn(opa_dn), // Operand A Denormalized .opb_dn(opb_dn), // Operand A Denormalized .rem_00(1'b0), // Diveide Remainder is zero .div_opa_ldz(5'b00000), // Divide opa leading zeros count // .output_zero(mul_00 \| div_00), // Force output to Zero .output_zero(or_result), // Force output to Zero .out(out_d), // Normalized output (un-registered) .ine(ine_d), // Result Inexact output (un-registered) .overflow(overflow_d), // Overflow output (un-registered) .underflow(underflow_d), // Underflow output (un-registered) .f2i_out_sign(f2i_out_sign) // F2I Output Sign ); //////////////////////////////////////////////////////////////////////// // // FPU Outputs // wire [30:0] out_fixed; wire output_zero_fasu; wire output_zero_fdiv; wire output_zero_fmul; reg inf_mul2; wire overflow_fasu; wire overflow_fmul; wire overflow_fdiv; wire inf_fmul; wire sign_mul_final; wire out_d_00; wire sign_div_final; wire ine_mul, ine_mula, ine_div, ine_fasu; wire underflow_fasu, underflow_fmul, underflow_fdiv; wire underflow_fmul1; reg [2:0] underflow_fmul_r; reg opa_nan_r; always @(posedge clk) inf_mul2 <= exp_mul == 8'hff; // Force pre-set values for non numerical output assign mul_inf = (fpu_op_r3==3'b010) & (inf_mul_r \| inf_mul2) & (rmode_r3==2'h0); assign div_inf = (fpu_op_r3==3'b011) & (opb_00 \| opa_inf); assign mul_00 = (fpu_op_r3==3'b010) & (opa_00 \| opb_00); assign div_00 = (fpu_op_r3==3'b011) & (opa_00 \| opb_inf); assign out_fixed = ( (qnan_d \| snan_d) \| (opa_inf & opb_00)\| (opb_inf & opa_00 ) ) ? QNAN : INF; always @(posedge clk) out_o1[30:0] <= (mul_inf \| div_inf \| inf_d \| snan_d \| qnan_d) ? out_fixed : out_d; assign out_d_00 = !(\|out_d); assign sign_mul_final = (sign_exe_r & ((opa_00 & opb_inf) \| (opb_00 & opa_inf))) ? !sign_mul_r : sign_mul_r; assign sign_div_final = (sign_exe_r & (opa_inf & opb_inf)) ? !sign_mul_r : sign_mul_r \| (opa_00 & opb_00); always @(posedge clk) // out_o1[31] <= !(snan_d \| qnan_d) ? sign_mul_final : nan_sign_d ; out_o1[31] <= !(snan_d \| qnan_d) & sign_mul_final; // Exception Outputs assign ine_mula = ((inf_mul_r \| inf_mul2 \| opa_inf \| opb_inf) & (rmode_r3==2'h1) & !((opa_inf & opb_00) \| (opb_inf & opa_00 )) & fpu_op_r3[1]); assign ine_mul = (ine_mula \| ine_d \| inf_fmul \| out_d_00 \| overflow_d \| underflow_d) & !opa_00 & !opb_00 & !(snan_d \| qnan_d \| inf_d); always @(posedge clk) ine_o1 <= ine_mul; assign overflow_fmul = !inf_d & (inf_mul_r \| inf_mul2 \| overflow_d) & !(snan_d \| qnan_d); always @(posedge clk) overflow_o1 <= overflow_fmul; always @(posedge clk) underflow_fmul_r <= underflow_fmul_d; wire out_d_compare1; assign out_d_compare1 = (out_d[30:23]==8'b0); wire out_d_compare2; assign out_d_compare2 = (out_d[22:0]==23'b0); / assign underflow_fmul1 = underflow_fmul_r[0] \| (underflow_fmul_r[1] & underflow_d ) \| ((opa_dn \| opb_dn) & out_d_00 & (prod!=0) & sign) \| (underflow_fmul_r[2] & ((out_d[30:23]==8'b0) \| (out_d[22:0]==23'b0))); / assign underflow_fmul1 = underflow_fmul_r[0] \| (underflow_fmul_r[1] & underflow_d ) \| ((opa_dn \| opb_dn) & out_d_00 & (prod!=48'b0) & sign) \| (underflow_fmul_r[2] & (out_d_compare1 \| out_d_compare2)); assign underflow_fmul = underflow_fmul1 & !(snan_d \| qnan_d \| inf_mul_r); / always @(posedge clk) begin underflow_o1 <= 1'b0; snan_o1 <= 1'b0; qnan_o1 <= 1'b0; inf_fmul <= 1'b0; inf_o1 <= 1'b0; zero_o1 <= 1'b0; opa_nan_r <= 1'b0; div_by_zero_o1 <= 1'b0; end assign output_zero_fmul = 1'b0; / always @(posedge clk) underflow_o1 <= underflow_fmul; always @(posedge clk) snan_o1 <= snan_d; // Status Outputs always @(posedge clk) qnan_o1 <= ( snan_d \| qnan_d \| (((opa_inf & opb_00) \| (opb_inf & opa_00 )) & fpu_op_r3==3'b010) ); assign inf_fmul = (((inf_mul_r \| inf_mul2) & (rmode_r3==2'h0)) \| opa_inf \| opb_inf) & !((opa_inf & opb_00) \| (opb_inf & opa_00 )) & fpu_op_r3==3'b010; always @(posedge clk) / inf_o1 <= fpu_op_r3[2] ? 1'b0 : (!(qnan_d \| snan_d) & ( ((&out_d[30:23]) & !(\|out_d[22:0]) & !(opb_00 & fpu_op_r3==3'b011)) \| inf_fmul) ); / inf_o1 <= !fpu_op_r3[2] & (!(qnan_d \| snan_d) & ( ((&out_d[30:23]) & !(\|out_d[22:0]) & !(opb_00 & fpu_op_r3==3'b011)) \| inf_fmul) ); assign output_zero_fmul = (out_d_00 \| opa_00 \| opb_00) & !(inf_mul_r \| inf_mul2 \| opa_inf \| opb_inf \| snan_d \| qnan_d) & !(opa_inf & opb_00) & !(opb_inf & opa_00); always @(posedge clk) zero_o1 <= output_zero_fmul; always @(posedge clk) opa_nan_r <= (!opa_nan) & (fpu_op_r2==3'b011) ; always @(posedge clk) div_by_zero_o1 <= opa_nan_r & !opa_00 & !opa_inf & opb_00; // output register always @(posedge clk) begin qnan <= qnan_o1; out <= out_o1; inf <= inf_o1; snan <= snan_o1; //qnan <= qnan_o1; ine <= ine_o1; overflow <= overflow_o1; underflow <= underflow_o1; zero <= zero_o1; div_by_zero <= div_by_zero_o1; end endmodule //--------------------------------------------------------------------------------- module except( clk, opa, opb, inf, ind, qnan, snan, opa_nan, opb_nan, opa_00, opb_00, opa_inf, opb_inf, opa_dn, opb_dn); input clk; input [30:0] opa, opb; output inf, ind, qnan, snan, opa_nan, opb_nan; output opa_00, opb_00; output opa_inf, opb_inf; output opa_dn; output opb_dn; //////////////////////////////////////////////////////////////////////// // // Local Wires and registers // wire [7:0] expa, expb; // alias to opX exponent wire [22:0] fracta, fractb; // alias to opX fraction reg expa_ff, infa_f_r, qnan_r_a, snan_r_a; reg expb_ff, infb_f_r, qnan_r_b, snan_r_b; reg inf, ind, qnan, snan; // Output registers reg opa_nan, opb_nan; reg expa_00, expb_00, fracta_00, fractb_00; reg opa_00, opb_00; reg opa_inf, opb_inf; reg opa_dn, opb_dn; //////////////////////////////////////////////////////////////////////// // // Aliases // assign expa = opa[30:23]; assign expb = opb[30:23]; assign fracta = opa[22:0]; assign fractb = opb[22:0]; //////////////////////////////////////////////////////////////////////// // // Determine if any of the input operators is a INF or NAN or any other special number // always @(posedge clk) expa_ff <= &expa; always @(posedge clk) expb_ff <= &expb; always @(posedge clk) infa_f_r <= !(\|fracta); always @(posedge clk) infb_f_r <= !(\|fractb); always @(posedge clk) qnan_r_a <= fracta[22]; always @(posedge clk) snan_r_a <= !fracta[22] & \|fracta[21:0]; always @(posedge clk) qnan_r_b <= fractb[22]; always @(posedge clk) snan_r_b <= !fractb[22] & \|fractb[21:0]; always @(posedge clk) ind <= (expa_ff & infa_f_r) & (expb_ff & infb_f_r); always @(posedge clk) inf <= (expa_ff & infa_f_r) \| (expb_ff & infb_f_r); always @(posedge clk) qnan <= (expa_ff & qnan_r_a) \| (expb_ff & qnan_r_b); always @(posedge clk) snan <= (expa_ff & snan_r_a) \| (expb_ff & snan_r_b); always @(posedge clk) opa_nan <= &expa & (\|fracta[22:0]); always @(posedge clk) opb_nan <= &expb & (\|fractb[22:0]); always @(posedge clk) opa_inf <= (expa_ff & infa_f_r); always @(posedge clk) opb_inf <= (expb_ff & infb_f_r); always @(posedge clk) expa_00 <= !(\|expa); always @(posedge clk) expb_00 <= !(\|expb); always @(posedge clk) fracta_00 <= !(\|fracta); always @(posedge clk) fractb_00 <= !(\|fractb); always @(posedge clk) opa_00 <= expa_00 & fracta_00; always @(posedge clk) opb_00 <= expb_00 & fractb_00; always @(posedge clk) opa_dn <= expa_00; always @(posedge clk) opb_dn <= expb_00; endmodule //--------------------------------------------------------------------------------- module pre_norm_fmul(clk, fpu_op, opa, opb, fracta, fractb, exp_out, sign, sign_exe, inf, exp_ovf, underflow); input clk; input [2:0] fpu_op; input [31:0] opa, opb; output [23:0] fracta, fractb; output [7:0] exp_out; output sign, sign_exe; output inf; output [1:0] exp_ovf; output [2:0] underflow; //////////////////////////////////////////////////////////////////////// // // Local Wires and registers // reg [7:0] exp_out; wire signa, signb; reg sign, sign_d; reg sign_exe; reg inf; wire [1:0] exp_ovf_d; reg [1:0] exp_ovf; wire [7:0] expa, expb; wire [7:0] exp_tmp1, exp_tmp2; wire co1, co2; wire expa_dn, expb_dn; wire [7:0] exp_out_a; wire opa_00, opb_00, fracta_00, fractb_00; wire [7:0] exp_tmp3, exp_tmp4, exp_tmp5; wire [2:0] underflow_d; reg [2:0] underflow; wire op_div; wire [7:0] exp_out_mul, exp_out_div; assign op_div = (fpu_op == 3'b011); //////////////////////////////////////////////////////////////////////// // // Aliases // assign signa = opa[31]; assign signb = opb[31]; assign expa = opa[30:23]; assign expb = opb[30:23]; //////////////////////////////////////////////////////////////////////// // // Calculate Exponenet // assign expa_dn = !(\|expa); assign expb_dn = !(\|expb); assign opa_00 = !(\|opa[30:0]); assign opb_00 = !(\|opb[30:0]); assign fracta_00 = !(\|opa[22:0]); assign fractb_00 = !(\|opb[22:0]); assign fracta[22:0] = opa[22:0]; assign fractb[22:0] = opb[22:0]; assign fracta[23:23] = !expa_dn; assign fractb[23:23] = !expb_dn; //assign fracta = {!expa_dn,opa[22:0]}; // Recover hidden bit //assign fractb = {!expb_dn,opb[22:0]}; // Recover hidden bit assign {co1,exp_tmp1} = op_div ? ({1'b0,expa[7:0]} - {1'b0,expb[7:0]}) : ({1'b0,expa[7:0]} + {1'b0,expb[7:0]}); assign {co2,exp_tmp2} = op_div ? ({co1,exp_tmp1} + 9'h07f) : ({co1,exp_tmp1} - 9'h07f); assign exp_tmp3 = exp_tmp2 + 8'h01; assign exp_tmp4 = 8'h7f - exp_tmp1; assign exp_tmp5 = op_div ? (exp_tmp4+8'h01) : (exp_tmp4-8'h01); always@(posedge clk) exp_out <= op_div ? exp_out_div : exp_out_mul; assign exp_out_div = (expa_dn \| expb_dn) ? (co2 ? exp_tmp5 : exp_tmp3 ) : co2 ? exp_tmp4 : exp_tmp2; assign exp_out_mul = exp_ovf_d[1] ? exp_out_a : (expa_dn \| expb_dn) ? exp_tmp3 : exp_tmp2; assign exp_out_a = (expa_dn \| expb_dn) ? exp_tmp5 : exp_tmp4; assign exp_ovf_d[0] = op_div ? (expa[7] & !expb[7]) : (co2 & expa[7] & expb[7]); assign exp_ovf_d[1] = op_div ? co2 : ((!expa[7] & !expb[7] & exp_tmp2[7]) \| co2); always @(posedge clk) exp_ovf <= #1 exp_ovf_d; assign underflow_d[0] = (exp_tmp1 < 8'h7f) & !co1 & !(opa_00 \| opb_00 \| expa_dn \| expb_dn); assign underflow_d[1] = ((expa[7] \| expb[7]) & !opa_00 & !opb_00) \| (expa_dn & !fracta_00) \| (expb_dn & !fractb_00); assign underflow_d[2] = !opa_00 & !opb_00 & (exp_tmp1 == 8'h7f); always @(posedge clk) underflow <= underflow_d; always @(posedge clk) inf <= op_div ? (expb_dn & !expa[7]) : ({co1,exp_tmp1} > 9'h17e) ; //////////////////////////////////////////////////////////////////////// // // Determine sign for the output // // sign: 0=Posetive Number; 1=Negative Number always @(signa or signb) case({signa, signb}) // synopsys full_case parallel_case 2'b00: sign_d = 0; 2'b01: sign_d = 1; 2'b10: sign_d = 1; 2'b11: sign_d = 0; endcase always @(posedge clk) sign <= sign_d; always @(posedge clk) sign_exe <= signa & signb; endmodule //---------------------------------------------------------------------------- //////////////////////////////////////////////////////////////////////// // // Multiply // module mul_r2(clk, opa, opb, prod); input clk; input [23:0] opa, opb; output [47:0] prod; reg [47:0] prod1, prod; always @(posedge clk) prod1 <= #1 opa opb; always @(posedge clk) prod <= #1 prod1; endmodule //---------------------------------------------------------------------------- module post_norm( fpu_op, opas, sign, rmode, fract_in, exp_in, exp_ovf, opa_dn, opb_dn, rem_00, div_opa_ldz, output_zero, out, ine, overflow, underflow, f2i_out_sign); input [2:0] fpu_op; input opas; input sign; input [1:0] rmode; input [47:0] fract_in; input [7:0] exp_in; input [1:0] exp_ovf; input opa_dn, opb_dn; input rem_00; input [4:0] div_opa_ldz; input output_zero; output [30:0] out; output ine; output overflow, underflow; output f2i_out_sign; //////////////////////////////////////////////////////////////////////// // // Local Wires and registers // wire [22:0] fract_out; wire [7:0] exp_out; wire [30:0] out; wire exp_out1_co, overflow, underflow; wire [22:0] fract_out_final; reg [22:0] fract_out_rnd; wire [8:0] exp_next_mi; wire dn; wire exp_rnd_adj; wire [7:0] exp_out_final; reg [7:0] exp_out_rnd; wire op_dn; wire op_mul; wire op_div; wire op_i2f; wire op_f2i; //reg [5:0] fi_ldz; wire [5:0] fi_ldz; wire g, r, s; wire round, round2, round2a, round2_fasu, round2_fmul; wire [7:0] exp_out_rnd0, exp_out_rnd1, exp_out_rnd2, exp_out_rnd2a; wire [22:0] fract_out_rnd0, fract_out_rnd1, fract_out_rnd2, fract_out_rnd2a; wire exp_rnd_adj0, exp_rnd_adj2a; wire r_sign; wire ovf0, ovf1; wire [23:0] fract_out_pl1; wire [7:0] exp_out_pl1, exp_out_mi1; wire exp_out_00, exp_out_fe, exp_out_ff, exp_in_00, exp_in_ff; wire exp_out_final_ff, fract_out_7fffff; wire [24:0] fract_trunc; wire [7:0] exp_out1; wire grs_sel; wire fract_out_00, fract_in_00; wire shft_co; wire [8:0] exp_in_pl1, exp_in_mi1; wire [47:0] fract_in_shftr; wire [47:0] fract_in_shftl; // for block shifter wire [47:0] fract_in_shftr_1; wire [47:0] fract_in_shftl_1; // end for block shifter wire [7:0] exp_div; wire [7:0] shft2; wire [7:0] exp_out1_mi1; wire div_dn; wire div_nr; wire grs_sel_div; wire div_inf; wire [6:0] fi_ldz_2a; wire [7:0] fi_ldz_2; wire [7:0] div_shft1, div_shft2, div_shft3, div_shft4; wire div_shft1_co; wire [8:0] div_exp1; wire [7:0] div_exp2, div_exp3; wire left_right, lr_mul, lr_div; wire [7:0] shift_right, shftr_mul, shftr_div; wire [7:0] shift_left, shftl_mul, shftl_div; wire [7:0] fasu_shift; wire [7:0] exp_fix_div; wire [7:0] exp_fix_diva, exp_fix_divb; wire [5:0] fi_ldz_mi1; wire [5:0] fi_ldz_mi22; wire exp_zero; wire [6:0] ldz_all; wire [7:0] ldz_dif; wire [8:0] div_scht1a; wire [7:0] f2i_shft; wire [55:0] exp_f2i_1; wire f2i_zero, f2i_max; wire [7:0] f2i_emin; wire [7:0] conv_shft; wire [7:0] exp_i2f, exp_f2i, conv_exp; wire round2_f2i; assign op_mul = fpu_op[2:0]==3'b010; assign op_div = fpu_op[2:0]==3'b011; assign op_i2f = fpu_op[2:0]==3'b100; assign op_f2i = fpu_op[2:0]==3'b101; assign op_dn = opa_dn \| opb_dn; pri_encoder u6( .fract_in (fract_in), .fi_ldz (fi_ldz) ); // --------------------------------------------------------------------- // Normalize wire exp_in_80; wire rmode_00, rmode_01, rmode_10, rmode_11; // Misc common signals assign exp_in_ff = &exp_in; assign exp_in_00 = !(\|exp_in); assign exp_in_80 = exp_in[7] & !(\|exp_in[6:0]); assign exp_out_ff = &exp_out; assign exp_out_00 = !(\|exp_out); assign exp_out_fe = &exp_out[7:1] & !exp_out[0]; assign exp_out_final_ff = &exp_out_final; assign fract_out_7fffff = &fract_out; assign fract_out_00 = !(\|fract_out); assign fract_in_00 = !(\|fract_in); assign rmode_00 = (rmode==2'b00); assign rmode_01 = (rmode==2'b01); assign rmode_10 = (rmode==2'b10); assign rmode_11 = (rmode==2'b11); // Fasu Output will be denormalized ... assign dn = !op_mul & !op_div & (exp_in_00 \| (exp_next_mi[8] & !fract_in[47]) ); // --------------------------------------------------------------------- // Fraction Normalization wire[7:0] f2i_emax; assign f2i_emax = 8'h9d; //parameter f2i_emax = 8'h9d; // Incremented fraction for rounding assign fract_out_pl1 = {1'b0, fract_out} + 24'h000001; // Special Signals for f2i assign f2i_emin = rmode_00 ? 8'h7e : 8'h7f; assign f2i_zero = (!opas & (exp_in<f2i_emin)) \| (opas & (exp_in>f2i_emax)) \| (opas & (exp_in<f2i_emin) & (fract_in_00 \| !rmode_11)); assign f2i_max = (!opas & (exp_in>f2i_emax)) \| (opas & (exp_in<f2i_emin) & !fract_in_00 & rmode_11); // Calculate various shifting options assign {shft_co,shftr_mul} = (!exp_ovf[1] & exp_in_00) ? {1'b0, exp_out} : exp_in_mi1 ; assign {div_shft1_co, div_shft1} = exp_in_00 ? {1'b0, div_opa_ldz} : div_scht1a; assign div_scht1a = {1'b0, exp_in}-{4'b0, div_opa_ldz}; // 9 bits - includes carry out assign div_shft2 = exp_in+8'h02; assign div_shft3 = {3'b0, div_opa_ldz}+exp_in; assign div_shft4 = {3'b0, div_opa_ldz}-exp_in; assign div_dn = op_dn & div_shft1_co; assign div_nr = op_dn & exp_ovf[1] & !(\|fract_in[46:23]) & (div_shft3>8'h16); assign f2i_shft = exp_in-8'h7d; // Select shifting direction assign left_right = op_div ? lr_div : op_mul ? lr_mul :1'b1; assign lr_div = (op_dn & !exp_ovf[1] & exp_ovf[0]) ? 1'b1 : (op_dn & exp_ovf[1]) ? 1'b0 : (op_dn & div_shft1_co) ? 1'b0 : (op_dn & exp_out_00) ? 1'b1 : (!op_dn & exp_out_00 & !exp_ovf[1]) ? 1'b1 : exp_ovf[1] ? 1'b0 : 1'b1; assign lr_mul = (shft_co \| (!exp_ovf[1] & exp_in_00) \| (!exp_ovf[1] & !exp_in_00 & (exp_out1_co \| exp_out_00) )) ? 1'b1 : ( exp_ovf[1] \| exp_in_00 ) ? 1'b0 : 1'b1; // Select Left and Right shift value assign fasu_shift = (dn \| exp_out_00) ? (exp_in_00 ? 8'h02 : exp_in_pl1[7:0]) : {2'h0, fi_ldz}; assign shift_right = op_div ? shftr_div : shftr_mul; assign conv_shft = op_f2i ? f2i_shft : {2'h0, fi_ldz}; assign shift_left = op_div ? shftl_div : op_mul ? shftl_mul : (op_f2i \| op_i2f) ? conv_shft : fasu_shift; assign shftl_mul = (shft_co \| (!exp_ovf[1] & exp_in_00) \| (!exp_ovf[1] & !exp_in_00 & (exp_out1_co \| exp_out_00))) ? exp_in_pl1[7:0] : {2'h0, fi_ldz}; assign shftl_div = ( op_dn & exp_out_00 & !(!exp_ovf[1] & exp_ovf[0])) ? div_shft1[7:0] : (!op_dn & exp_out_00 & !exp_ovf[1]) ? exp_in[7:0] : {2'h0, fi_ldz}; assign shftr_div = (op_dn & exp_ovf[1]) ? div_shft3 : (op_dn & div_shft1_co) ? div_shft4 : div_shft2; // Do the actual shifting //assign fract_in_shftr = (\|shift_right[7:6]) ? 0 : fract_in>>shift_right[5:0]; //assign fract_in_shftl = (\|shift_left[7:6] \| (f2i_zero & op_f2i)) ? 0 : fract_in<<shift_left[5:0]; b_right_shifter u1( .shift_in (fract_in), .shift_value (shift_right[5:0]), .shift_out (fract_in_shftr_1) ); assign fract_in_shftr = (\|shift_right[7:6]) ? 48'b0 : fract_in_shftr_1; // fract_in>>shift_right[5:0]; b_left_shifter u7( .shift_in (fract_in), .shift_value (shift_left[5:0]), .shift_out (fract_in_shftl_1) ); assign fract_in_shftl = (\|shift_left[7:6] \| (f2i_zero & op_f2i)) ? 48'b0 : fract_in_shftl_1; // fract_in<<shift_left[5:0]; // Chose final fraction output assign {fract_out,fract_trunc} = left_right ? fract_in_shftl : fract_in_shftr; // --------------------------------------------------------------------- // Exponent Normalization assign fi_ldz_mi1 = fi_ldz - 6'h01; assign fi_ldz_mi22 = fi_ldz - 6'd22; assign exp_out_pl1 = exp_out + 8'h01; assign exp_out_mi1 = exp_out - 8'h01; assign exp_in_pl1 = {1'b0, exp_in} + 9'd1; // 9 bits - includes carry out assign exp_in_mi1 = {1'b0, exp_in} - 9'd1; // 9 bits - includes carry out assign exp_out1_mi1 = exp_out1 - 8'h01; assign exp_next_mi = exp_in_pl1 - {3'b0, fi_ldz_mi1}; // 9 bits - includes carry out assign exp_fix_diva = exp_in - {2'b0, fi_ldz_mi22}; assign exp_fix_divb = exp_in - {2'b0, fi_ldz_mi1}; //assign exp_zero = (exp_ovf[1] & !exp_ovf[0] & op_mul & (!exp_rnd_adj2a \| !rmode[1])) \| (op_mul & exp_out1_co); assign exp_zero = (exp_ovf[1] & !exp_ovf[0] & op_mul ) \| (op_mul & exp_out1_co); assign {exp_out1_co, exp_out1} = fract_in[47] ? exp_in_pl1 : exp_next_mi; assign f2i_out_sign = !opas ? ((exp_in<f2i_emin) ? 1'b0 : (exp_in>f2i_emax) ? 1'b0 : opas) : ((exp_in<f2i_emin) ? 1'b0 : (exp_in>f2i_emax) ? 1'b1 : opas); assign exp_i2f = fract_in_00 ? (opas ? 8'h9e : 8'h00) : (8'h9e-{2'b0, fi_ldz}); //assign exp_f2i_1 = {{8{fract_in[47]}}, fract_in }<<f2i_shft; b_left_shifter_new u3( .shift_in ({{8{fract_in[47]}}, fract_in }), .shift_value (f2i_shft[5:0]), .shift_out (exp_f2i_1) ); assign exp_f2i = f2i_zero ? 8'h00 : f2i_max ? 8'hff : exp_f2i_1[55:48]; assign conv_exp = op_f2i ? exp_f2i : exp_i2f; assign exp_out = op_div ? exp_div : (op_f2i \| op_i2f) ? conv_exp : exp_zero ? 8'h0 : dn ? {6'h0, fract_in[47:46]} : exp_out1; assign ldz_all = {2'b0, div_opa_ldz} + {1'b0, fi_ldz}; assign ldz_dif = fi_ldz_2 - {3'b0, div_opa_ldz}; assign fi_ldz_2a = 7'd23 - {1'b0,fi_ldz}; assign fi_ldz_2 = {fi_ldz_2a[6], fi_ldz_2a[6:0]}; assign div_exp1 = exp_in_mi1 + {1'b0, fi_ldz_2}; // 9 bits - includes carry out assign div_exp2 = exp_in_pl1[7:0] - {1'b0, ldz_all}; assign div_exp3 = exp_in + ldz_dif; assign exp_div =(opa_dn & opb_dn)? div_exp3 : opb_dn? div_exp1[7:0] : (opa_dn & !( (exp_in[4:0]<div_opa_ldz) \| (div_exp2>8'hfe) )) ? div_exp2 : (opa_dn \| (exp_in_00 & !exp_ovf[1]) ) ? 8'h00 : exp_out1_mi1; assign div_inf = opb_dn & !opa_dn & (div_exp1[7:0] < 8'h7f); // --------------------------------------------------------------------- // Round // Extract rounding (GRS) bits assign grs_sel_div = op_div & (exp_ovf[1] \| div_dn \| exp_out1_co \| exp_out_00); assign g = grs_sel_div ? fract_out[0] : fract_out[0]; assign r = grs_sel_div ? (fract_trunc[24] & !div_nr) : fract_trunc[24]; assign s = grs_sel_div ? \|fract_trunc[24:0] : (\|fract_trunc[23:0] \| (fract_trunc[24] & op_div)); // Round to nearest even assign round = (g & r) \| (r & s) ; assign {exp_rnd_adj0, fract_out_rnd0} = round ? fract_out_pl1 : {1'b0, fract_out}; assign exp_out_rnd0 = exp_rnd_adj0 ? exp_out_pl1 : exp_out; assign ovf0 = exp_out_final_ff & !rmode_01 & !op_f2i; // round to zero assign fract_out_rnd1 = (exp_out_ff & !op_div & !dn & !op_f2i) ? 23'h7fffff : fract_out; assign exp_fix_div = (fi_ldz>6'd22) ? exp_fix_diva : exp_fix_divb; assign exp_out_rnd1 = (g & r & s & exp_in_ff) ? (op_div ? exp_fix_div : exp_next_mi[7:0]) : (exp_out_ff & !op_f2i) ? exp_in : exp_out; assign ovf1 = exp_out_ff & !dn; // round to +inf (UP) and -inf (DOWN) assign r_sign = sign; assign round2a = !exp_out_fe \| !fract_out_7fffff \| (exp_out_fe & fract_out_7fffff); assign round2_fasu = ((r \| s) & !r_sign) & (!exp_out[7] \| (exp_out[7] & round2a)); assign round2_fmul = !r_sign & ( (exp_ovf[1] & !fract_in_00 & ( ((!exp_out1_co \| op_dn) & (r \| s \| (!rem_00 & op_div) )) \| fract_out_00 \| (!op_dn & !op_div)) ) \| ( (r \| s \| (!rem_00 & op_div)) & ( (!exp_ovf[1] & (exp_in_80 \| !exp_ovf[0])) \| op_div \| ( exp_ovf[1] & !exp_ovf[0] & exp_out1_co) ) ) ); //assign round2_f2i = rmode_10 & (( \|fract_in[23:0] & !opas & (exp_in<8'h80 )) \| (\|fract_trunc)); wire temp_fract_in; assign temp_fract_in = \|fract_in[23:0]; assign round2_f2i = rmode_10 & (( temp_fract_in & !opas & (exp_in<8'h80 )) \| (\|fract_trunc)); assign round2 = (op_mul \| op_div) ? round2_fmul : op_f2i ? round2_f2i : round2_fasu; assign {exp_rnd_adj2a, fract_out_rnd2a} = round2 ? fract_out_pl1 : {1'b0, fract_out}; assign exp_out_rnd2a = exp_rnd_adj2a ? ((exp_ovf[1] & op_mul) ? exp_out_mi1 : exp_out_pl1) : exp_out; assign fract_out_rnd2 = (r_sign & exp_out_ff & !op_div & !dn & !op_f2i) ? 23'h7fffff : fract_out_rnd2a; assign exp_out_rnd2 = (r_sign & exp_out_ff & !op_f2i) ? 8'hfe : exp_out_rnd2a; // Choose rounding mode always @(rmode or exp_out_rnd0 or exp_out_rnd1 or exp_out_rnd2) case(rmode) // synopsys full_case parallel_case 2'b00: exp_out_rnd = exp_out_rnd0; 2'b01: exp_out_rnd = exp_out_rnd1; 2'b10: exp_out_rnd = exp_out_rnd2; 2'b11: exp_out_rnd = exp_out_rnd2; endcase always @(rmode or fract_out_rnd0 or fract_out_rnd1 or fract_out_rnd2) case(rmode) // synopsys full_case parallel_case 2'b00: fract_out_rnd = fract_out_rnd0; 2'b01: fract_out_rnd = fract_out_rnd1; 2'b10: fract_out_rnd = fract_out_rnd2; 2'b11: fract_out_rnd = fract_out_rnd2; endcase // --------------------------------------------------------------------- // Final Output Mux // Fix Output for denormalized and special numbers wire max_num, inf_out; assign max_num = ( !rmode_00 & (op_mul \| op_div ) & ( ( exp_ovf[1] & exp_ovf[0]) \| (!exp_ovf[1] & !exp_ovf[0] & exp_in_ff & (fi_ldz_2<8'd24) & (exp_out!=8'hfe) ) ) ) \| ( op_div & ( ( rmode_01 & ( div_inf \| (exp_out_ff & !exp_ovf[1] ) \| (exp_ovf[1] & exp_ovf[0] ) ) ) \| ( rmode[1] & !exp_ovf[1] & ( ( exp_ovf[0] & exp_in_ff & r_sign & fract_in[47] ) \| ( r_sign & ( (fract_in[47] & div_inf) \| (exp_in[7] & !exp_out_rnd[7] & !exp_in_80 & exp_out!=8'h7f ) \| (exp_in[7] & exp_out_rnd[7] & r_sign & exp_out_ff & op_dn & div_exp1>9'h0fe ) ) ) \| ( exp_in_00 & r_sign & ( div_inf \| (r_sign & exp_out_ff & fi_ldz_2<8'h18) ) ) ) ) ) ); assign inf_out = (rmode[1] & (op_mul \| op_div) & !r_sign & ( (exp_in_ff & !op_div) \| (exp_ovf[1] & exp_ovf[0] & (exp_in_00 \| exp_in[7]) ) ) ) \| (div_inf & op_div & ( rmode_00 \| (rmode[1] & !exp_in_ff & !exp_ovf[1] & !exp_ovf[0] & !r_sign ) \| (rmode[1] & !exp_ovf[1] & exp_ovf[0] & exp_in_00 & !r_sign) ) ) \| (op_div & rmode[1] & exp_in_ff & op_dn & !r_sign & (fi_ldz_2 < 8'd24) & (exp_out_rnd!=8'hfe) ); assign fract_out_final = (inf_out \| ovf0 \| output_zero ) ? 23'h000000 : (max_num \| (f2i_max & op_f2i) ) ? 23'h7fffff : fract_out_rnd; assign exp_out_final = ((op_div & exp_ovf[1] & !exp_ovf[0]) \| output_zero ) ? 8'h00 : ((op_div & exp_ovf[1] & exp_ovf[0] & rmode_00) \| inf_out \| (f2i_max & op_f2i) ) ? 8'hff : max_num ? 8'hfe : exp_out_rnd; // --------------------------------------------------------------------- // Pack Result assign out = {exp_out_final, fract_out_final}; // --------------------------------------------------------------------- // Exceptions wire underflow_fmul; wire overflow_fdiv; wire undeflow_div; wire z; assign z = shft_co \| ( exp_ovf[1] \| exp_in_00) \| (!exp_ovf[1] & !exp_in_00 & (exp_out1_co \| exp_out_00)); assign underflow_fmul = ( (\|fract_trunc) & z & !exp_in_ff ) \| (fract_out_00 & !fract_in_00 & exp_ovf[1]); assign undeflow_div = !(exp_ovf[1] & exp_ovf[0] & rmode_00) & !inf_out & !max_num & exp_out_final!=8'hff & ( ((\|fract_trunc) & !opb_dn & ( ( op_dn & !exp_ovf[1] & exp_ovf[0]) \| ( op_dn & exp_ovf[1]) \| ( op_dn & div_shft1_co) \| exp_out_00 \| exp_ovf[1] ) ) \| ( exp_ovf[1] & !exp_ovf[0] & ( ( op_dn & exp_in>8'h16 & fi_ldz<6'd23) \| ( op_dn & exp_in<8'd23 & fi_ldz<6'd23 & !rem_00) \| ( !op_dn & (exp_in[7]==exp_div[7]) & !rem_00) \| ( !op_dn & exp_in_00 & (exp_div[7:1]==7'h7f) ) \| ( !op_dn & exp_in<8'h7f & exp_in>8'h20 ) ) ) \| (!exp_ovf[1] & !exp_ovf[0] & ( ( op_dn & fi_ldz<6'd23 & exp_out_00) \| ( exp_in_00 & !rem_00) \| ( !op_dn & ldz_all<7'd23 & exp_in==8'h01 & exp_out_00 & !rem_00) ) ) ); assign underflow = op_div ? undeflow_div : op_mul ? underflow_fmul : (!fract_in[47] & exp_out1_co) & !dn; assign overflow_fdiv = inf_out \| (!rmode_00 & max_num) \| (exp_in[7] & op_dn & exp_out_ff) \| (exp_ovf[0] & (exp_ovf[1] \| exp_out_ff) ); assign overflow = op_div ? overflow_fdiv : (ovf0 \| ovf1); wire f2i_ine; assign f2i_ine = (f2i_zero & !fract_in_00 & !opas) \| (\|fract_trunc) \| (f2i_zero & (exp_in<8'h80) & opas & !fract_in_00) \| (f2i_max & rmode_11 & (exp_in<8'h80)); assign ine = op_f2i ? f2i_ine : op_i2f ? (\|fract_trunc) : ((r & !dn) \| (s & !dn) \| max_num \| (op_div & !rem_00)); endmodule //------------------------------------------------------------------------------------- module pri_encoder ( fract_in, fi_ldz ); input [47:0] fract_in; output [5:0] fi_ldz; reg [5:0] fi_ldz_r0; assign fi_ldz = fi_ldz_r0; always @(fract_in) begin if (fract_in[47:47] == 1'b1) fi_ldz_r0 = 6'd1; else if (fract_in[47:46] == 2'b01) fi_ldz_r0 = 6'd2; else if (fract_in[47:45] == 3'b001) fi_ldz_r0 = 6'd3; else if (fract_in[47:44] == 4'b0001) fi_ldz_r0 = 6'd4; else if (fract_in[47:43] == 5'b00001) fi_ldz_r0 = 6'd5; else if (fract_in[47:42] == 6'b000001) fi_ldz_r0 = 6'd6; else if (fract_in[47:41] == 7'b0000001) fi_ldz_r0 = 6'd7; else if (fract_in[47:40] == 8'b00000001) fi_ldz_r0 = 6'd8; else if (fract_in[47:39] == 9'b000000001) fi_ldz_r0 = 6'd9; else if (fract_in[47:38] == 10'b0000000001) fi_ldz_r0 = 6'd10; else if (fract_in[47:37] == 11'b00000000001) fi_ldz_r0 = 6'd11; else if (fract_in[47:36] == 12'b000000000001) fi_ldz_r0 = 6'd12; else if (fract_in[47:35] == 13'b0000000000001) fi_ldz_r0 = 6'd13; else if (fract_in[47:34] == 14'b00000000000001) fi_ldz_r0 = 6'd14; else if (fract_in[47:33] == 15'b000000000000001) fi_ldz_r0 = 6'd15; else if (fract_in[47:32] == 16'b0000000000000001) fi_ldz_r0 = 6'd16; else if (fract_in[47:31] == 17'b00000000000000001) fi_ldz_r0 = 6'd17; else if (fract_in[47:30] == 18'b000000000000000001) fi_ldz_r0 = 6'd18; else if (fract_in[47:29] == 19'b0000000000000000001) fi_ldz_r0 = 6'd19; else if (fract_in[47:28] == 20'b00000000000000000001) fi_ldz_r0 = 6'd20; else if (fract_in[47:27] == 21'b000000000000000000001) fi_ldz_r0 = 6'd21; else if (fract_in[47:26] == 22'b0000000000000000000001) fi_ldz_r0 = 6'd22; else if (fract_in[47:25] == 23'b00000000000000000000001) fi_ldz_r0 = 6'd23; else if (fract_in[47:24] == 24'b000000000000000000000001) fi_ldz_r0 = 6'd24; else if (fract_in[47:23] == 25'b0000000000000000000000001) fi_ldz_r0 = 6'd25; else if (fract_in[47:22] == 26'b00000000000000000000000001) fi_ldz_r0 = 6'd26; else if (fract_in[47:21] == 27'b000000000000000000000000001) fi_ldz_r0 = 6'd27; else if (fract_in[47:20] == 28'b0000000000000000000000000001) fi_ldz_r0 = 6'd28; else if (fract_in[47:19] == 29'b00000000000000000000000000001) fi_ldz_r0 = 6'd29; else if (fract_in[47:18] == 30'b000000000000000000000000000001) fi_ldz_r0 = 6'd30; else if (fract_in[47:17] == 31'b0000000000000000000000000000001) fi_ldz_r0 = 6'd31; else if (fract_in[47:16] == 32'b00000000000000000000000000000001) fi_ldz_r0 = 6'd32; else if (fract_in[47:15] == 33'b000000000000000000000000000000001) fi_ldz_r0 = 6'd33; else if (fract_in[47:14] == 34'b0000000000000000000000000000000001) fi_ldz_r0 = 6'd34; else if (fract_in[47:13] == 35'b00000000000000000000000000000000001) fi_ldz_r0 = 6'd35; else if (fract_in[47:12] == 36'b000000000000000000000000000000000001) fi_ldz_r0 = 6'd36; else if (fract_in[47:11] == 37'b0000000000000000000000000000000000001) fi_ldz_r0 = 6'd37; else if (fract_in[47:10] == 38'b00000000000000000000000000000000000001) fi_ldz_r0 = 6'd38; else if (fract_in[47:9] == 39'b000000000000000000000000000000000000001) fi_ldz_r0 = 6'd39; else if (fract_in[47:8] == 40'b0000000000000000000000000000000000000001) fi_ldz_r0 = 6'd40; else if (fract_in[47:7] == 41'b00000000000000000000000000000000000000001) fi_ldz_r0 = 6'd41; else if (fract_in[47:6] == 42'b000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd42; else if (fract_in[47:5] == 43'b0000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd43; else if (fract_in[47:4] == 44'b00000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd44; else if (fract_in[47:3] == 45'b000000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd45; else if (fract_in[47:2] == 46'b0000000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd46; else if (fract_in[47:1] == 47'b00000000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd47; else if (fract_in[47:0] == 48'b000000000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd48; else if (fract_in[47:0] == 48'b000000000000000000000000000000000000000000000000) fi_ldz_r0 = 6'd48; end endmodule module b_right_shifter ( shift_in, shift_value, shift_out ); input [47:0] shift_in; input [5:0] shift_value; output [47:0] shift_out; reg [47:0] shift_out; always @(shift_value) begin case (shift_value) 6'b000000: shift_out = shift_in; 6'b000001: shift_out = shift_in >> 1; 6'b000010: shift_out = shift_in >> 2; 6'b000011: shift_out = shift_in >> 3; 6'b000100: shift_out = shift_in >> 4; 6'b000101: shift_out = shift_in >> 5; 6'b000110: shift_out = shift_in >> 6; 6'b000111: shift_out = shift_in >> 7; 6'b001000: shift_out = shift_in >> 8; 6'b001001: shift_out = shift_in >> 9; 6'b001010: shift_out = shift_in >> 10; 6'b001011: shift_out = shift_in >> 11; 6'b001100: shift_out = shift_in >> 12; 6'b001101: shift_out = shift_in >> 13; 6'b001110: shift_out = shift_in >> 14; 6'b001111: shift_out = shift_in >> 15; 6'b010000: shift_out = shift_in >> 16; 6'b010001: shift_out = shift_in >> 17; 6'b010010: shift_out = shift_in >> 18; 6'b010011: shift_out = shift_in >> 19; 6'b010100: shift_out = shift_in >> 20; 6'b010101: shift_out = shift_in >> 21; 6'b010110: shift_out = shift_in >> 22; 6'b010111: shift_out = shift_in >> 23; 6'b011000: shift_out = shift_in >> 24; 6'b011001: shift_out = shift_in >> 25; 6'b011010: shift_out = shift_in >> 26; 6'b011011: shift_out = shift_in >> 27; 6'b011100: shift_out = shift_in >> 28; 6'b011101: shift_out = shift_in >> 29; 6'b011110: shift_out = shift_in >> 30; 6'b011111: shift_out = shift_in >> 31; 6'b100000: shift_out = shift_in >> 32; 6'b100001: shift_out = shift_in >> 33; 6'b100010: shift_out = shift_in >> 34; 6'b100011: shift_out = shift_in >> 35; 6'b100100: shift_out = shift_in >> 36; 6'b100101: shift_out = shift_in >> 37; 6'b100110: shift_out = shift_in >> 38; 6'b100111: shift_out = shift_in >> 39; 6'b101000: shift_out = shift_in >> 40; 6'b101001: shift_out = shift_in >> 41; 6'b101010: shift_out = shift_in >> 42; 6'b101011: shift_out = shift_in >> 43; 6'b101100: shift_out = shift_in >> 44; 6'b101101: shift_out = shift_in >> 45; 6'b101110: shift_out = shift_in >> 46; 6'b101111: shift_out = shift_in >> 47; 6'b110000: shift_out = shift_in >> 48; endcase end //assign shift_out = shift_in >> shift_value; endmodule module b_left_shifter ( shift_in, shift_value, shift_out ); input [47:0] shift_in; input [5:0] shift_value; output [47:0] shift_out; reg [47:0] shift_out; always @(shift_value) begin case (shift_value) 6'b000000: shift_out = shift_in; 6'b000001: shift_out = shift_in << 1; 6'b000010: shift_out = shift_in << 2; 6'b000011: shift_out = shift_in << 3; 6'b000100: shift_out = shift_in << 4; 6'b000101: shift_out = shift_in << 5; 6'b000110: shift_out = shift_in << 6; 6'b000111: shift_out = shift_in << 7; 6'b001000: shift_out = shift_in << 8; 6'b001001: shift_out = shift_in << 9; 6'b001010: shift_out = shift_in << 10; 6'b001011: shift_out = shift_in << 11; 6'b001100: shift_out = shift_in << 12; 6'b001101: shift_out = shift_in << 13; 6'b001110: shift_out = shift_in << 14; 6'b001111: shift_out = shift_in << 15; 6'b010000: shift_out = shift_in << 16; 6'b010001: shift_out = shift_in << 17; 6'b010010: shift_out = shift_in << 18; 6'b010011: shift_out = shift_in << 19; 6'b010100: shift_out = shift_in << 20; 6'b010101: shift_out = shift_in << 21; 6'b010110: shift_out = shift_in << 22; 6'b010111: shift_out = shift_in << 23; 6'b011000: shift_out = shift_in << 24; 6'b011001: shift_out = shift_in << 25; 6'b011010: shift_out = shift_in << 26; 6'b011011: shift_out = shift_in << 27; 6'b011100: shift_out = shift_in << 28; 6'b011101: shift_out = shift_in << 29; 6'b011110: shift_out = shift_in << 30; 6'b011111: shift_out = shift_in << 31; 6'b100000: shift_out = shift_in << 32; 6'b100001: shift_out = shift_in << 33; 6'b100010: shift_out = shift_in << 34; 6'b100011: shift_out = shift_in << 35; 6'b100100: shift_out = shift_in << 36; 6'b100101: shift_out = shift_in << 37; 6'b100110: shift_out = shift_in << 38; 6'b100111: shift_out = shift_in << 39; 6'b101000: shift_out = shift_in << 40; 6'b101001: shift_out = shift_in << 41; 6'b101010: shift_out = shift_in << 42; 6'b101011: shift_out = shift_in << 43; 6'b101100: shift_out = shift_in << 44; 6'b101101: shift_out = shift_in << 45; 6'b101110: shift_out = shift_in << 46; 6'b101111: shift_out = shift_in << 47; 6'b110000: shift_out = shift_in << 48; endcase end endmodule module b_left_shifter_new ( shift_in, shift_value, shift_out ); input [55:0] shift_in; input [5:0] shift_value; output [55:0] shift_out; reg [47:0] shift_out; always @(shift_value) begin case (shift_value) 6'b000000: shift_out = shift_in; 6'b000001: shift_out = shift_in << 1; 6'b000010: shift_out = shift_in << 2; 6'b000011: shift_out = shift_in << 3; 6'b000100: shift_out = shift_in << 4; 6'b000101: shift_out = shift_in << 5; 6'b000110: shift_out = shift_in << 6; 6'b000111: shift_out = shift_in << 7; 6'b001000: shift_out = shift_in << 8; 6'b001001: shift_out = shift_in << 9; 6'b001010: shift_out = shift_in << 10; 6'b001011: shift_out = shift_in << 11; 6'b001100: shift_out = shift_in << 12; 6'b001101: shift_out = shift_in << 13; 6'b001110: shift_out = shift_in << 14; 6'b001111: shift_out = shift_in << 15; 6'b010000: shift_out = shift_in << 16; 6'b010001: shift_out = shift_in << 17; 6'b010010: shift_out = shift_in << 18; 6'b010011: shift_out = shift_in << 19; 6'b010100: shift_out = shift_in << 20; 6'b010101: shift_out = shift_in << 21; 6'b010110: shift_out = shift_in << 22; 6'b010111: shift_out = shift_in << 23; 6'b011000: shift_out = shift_in << 24; 6'b011001: shift_out = shift_in << 25; 6'b011010: shift_out = shift_in << 26; 6'b011011: shift_out = shift_in << 27; 6'b011100: shift_out = shift_in << 28; 6'b011101: shift_out = shift_in << 29; 6'b011110: shift_out = shift_in << 30; 6'b011111: shift_out = shift_in << 31; 6'b100000: shift_out = shift_in << 32; 6'b100001: shift_out = shift_in << 33; 6'b100010: shift_out = shift_in << 34; 6'b100011: shift_out = shift_in << 35; 6'b100100: shift_out = shift_in << 36; 6'b100101: shift_out = shift_in << 37; 6'b100110: shift_out = shift_in << 38; 6'b100111: shift_out = shift_in << 39; 6'b101000: shift_out = shift_in << 40; 6'b101001: shift_out = shift_in << 41; 6'b101010: shift_out = shift_in << 42; 6'b101011: shift_out = shift_in << 43; 6'b101100: shift_out = shift_in << 44; 6'b101101: shift_out = shift_in << 45; 6'b101110: shift_out = shift_in << 46; 6'b101111: shift_out = shift_in << 47; 6'b110000: shift_out = shift_in << 48; 6'b110001: shift_out = shift_in << 49; 6'b110010: shift_out = shift_in << 50; 6'b110011: shift_out = shift_in << 51; 6'b110100: shift_out = shift_in << 52; 6'b110101: shift_out = shift_in << 53; 6'b110110: shift_out = shift_in << 54; 6'b110111: shift_out = shift_in << 55; 6'b111000: shift_out = shift_in << 56; endcase end endmodule module fpu_add( clk, //rmode, opa, opb, out, control //inf, snan, qnan, ine, overflow, underflow, zero, div_by_zero ); input clk; //input [1:0] rmode; //input [2:0] fpu_op; input [31:0] opa, opb; output [31:0] out; /* output inf, snan, qnan; output ine; output overflow, underflow; output zero; output div_by_zero; / output [7:0] control; / parameter INF = 31'h7f800000; parameter QNAN = 31'h7fc00001; parameter SNAN = 31'h7f800001; */ wire [30:0] INF; assign INF = 31'h7f800000; wire [30:0] QNAN; assign QNAN = 31'h7fc00001; wire [30:0] SNAN; assign SNAN = 31'h7f800001; //////////////////////////////////////////////////////////////////////// // // Local Wires // reg [2:0] fpu_op; reg zero; reg [31:0] opa_r, opb_r; // Input operand registers reg [31:0] out; // Output register reg div_by_zero; // Divide by zero output register // wire signa, signb; // alias to opX sign wire sign_fasu; // sign output wire [26:0] fracta, fractb; // Fraction Outputs from EQU block wire [7:0] exp_fasu; // Exponent output from EQU block reg [7:0] exp_r; // Exponent output (registerd) wire [26:0] fract_out_d; // fraction output // wire co; // carry output reg [27:0] fract_out_q; // fraction output (registerd) wire [30:0] out_d; // Intermediate final result output wire overflow_d, underflow_d;// Overflow/Underflow Indicators reg overflow, underflow; // Output registers for Overflow & Underflow reg inf, snan, qnan; // Output Registers for INF, SNAN and QNAN reg ine; // Output Registers for INE reg [1:0] rmode_r1, rmode_r2, // Pipeline registers for rounding mode rmode_r3; reg [2:0] fpu_op_r1, fpu_op_r2, // Pipeline registers for fp opration fpu_op_r3; // wire mul_inf, div_inf; // wire mul_00, div_00; // start output_reg reg [31:0] out_o1; reg inf_o1, snan_o1, qnan_o1; reg ine_o1; reg overflow_o1, underflow_o1; reg zero_o1; reg div_by_zero_o1; // end output_reg wire [7:0] contorl; assign control = {inf, snan, qnan, ine, overflow, underflow, zero, div_by_zero}; wire [1:0] rmode; assign rmode= 2'b00; always@(posedge clk) begin fpu_op[2:0] <= 3'b000; end //////////////////////////////////////////////////////////////////////// // // Input Registers // always @(posedge clk) opa_r <= opa; always @(posedge clk) opb_r <= opb; always @(posedge clk) rmode_r1 <= rmode; always @(posedge clk) rmode_r2 <= rmode_r1; always @(posedge clk) rmode_r3 <= rmode_r2; always @(posedge clk) fpu_op_r1 <= fpu_op; always @(posedge clk) fpu_op_r2 <= fpu_op_r1; always @(posedge clk) fpu_op_r3 <= fpu_op_r2; //////////////////////////////////////////////////////////////////////// // // Exceptions block // wire inf_d, ind_d, qnan_d, snan_d, opa_nan, opb_nan; wire opa_00, opb_00; wire opa_inf, opb_inf; wire opa_dn, opb_dn; except u0( .clk(clk), .opa(opa_r), .opb(opb_r), .inf(inf_d), .ind(ind_d), .qnan(qnan_d), .snan(snan_d), .opa_nan(opa_nan), .opb_nan(opb_nan), .opa_00(opa_00), .opb_00(opb_00), .opa_inf(opa_inf), .opb_inf(opb_inf), .opa_dn(opa_dn), .opb_dn(opb_dn) ); //////////////////////////////////////////////////////////////////////// // // Pre-Normalize block // - Adjusts the numbers to equal exponents and sorts them // - determine result sign // - determine actual operation to perform (add or sub) // wire nan_sign_d, result_zero_sign_d; reg sign_fasu_r; wire fasu_op; wire add_input; assign add_input=!fpu_op_r1[0]; pre_norm u1(.clk(clk), // System Clock .rmode(rmode_r2), // Roundin Mode // .add(!fpu_op_r1[0]), // Add/Sub Input .add(add_input), .opa(opa_r), .opb(opb_r), // Registered OP Inputs .opa_nan(opa_nan), // OpA is a NAN indicator .opb_nan(opb_nan), // OpB is a NAN indicator .fracta_out(fracta), // Equalized and sorted fraction .fractb_out(fractb), // outputs (Registered) .exp_dn_out(exp_fasu), // Selected exponent output (registered); .sign(sign_fasu), // Encoded output Sign (registered) .nan_sign(nan_sign_d), // Output Sign for NANs (registered) .result_zero_sign(result_zero_sign_d), // Output Sign for zero result (registered) .fasu_op(fasu_op) // Actual fasu operation output (registered) ); always @(posedge clk) sign_fasu_r <= #1 sign_fasu; wire co_d; //////////////////////////////////////////////////////////////////////// // // Add/Sub // add_sub27 u3( .add(fasu_op), // Add/Sub .opa(fracta), // Fraction A input .opb(fractb), // Fraction B Input .sum(fract_out_d), // SUM output .co(co_d) ); // Carry Output always @(posedge clk) fract_out_q <= #1 {co_d, fract_out_d}; //////////////////////////////////////////////////////////////////////// // // Normalize Result // wire ine_d; //reg [47:0] fract_denorm; wire [47:0] fract_denorm; wire sign_d; reg sign; reg [30:0] opa_r1; reg [47:0] fract_i2f; reg opas_r1, opas_r2; wire f2i_out_sign; always @(posedge clk) // Exponent must be once cycle delayed exp_r <= #1 exp_fasu; always @(posedge clk) opa_r1 <= #1 opa_r[30:0]; //always @(fpu_op_r3 or fract_out_q) assign fract_denorm = {fract_out_q, 20'h0}; always @(posedge clk) opas_r1 <= #1 opa_r[31]; always @(posedge clk) opas_r2 <= #1 opas_r1; assign sign_d = sign_fasu; always @(posedge clk) sign <= #1 (rmode_r2==2'h3) ? !sign_d : sign_d; post_norm u4( //.clk(clk), // System Clock .fpu_op(fpu_op_r3), // Floating Point Operation .opas(opas_r2), // OPA Sign .sign(sign), // Sign of the result .rmode(rmode_r3), // Rounding mode .fract_in(fract_denorm), // Fraction Input .exp_in(exp_r), // Exponent Input .exp_ovf(2'b00), // Exponent Overflow .opa_dn(opa_dn), // Operand A Denormalized .opb_dn(opb_dn), // Operand A Denormalized .rem_00(1'b0), // Diveide Remainder is zero .div_opa_ldz(5'b00000), // Divide opa leading zeros count .output_zero(1'b0), // Force output to Zero .out(out_d), // Normalized output (un-registered) .ine(ine_d), // Result Inexact output (un-registered) .overflow(overflow_d), // Overflow output (un-registered) .underflow(underflow_d), // Underflow output (un-registered) .f2i_out_sign(f2i_out_sign) // F2I Output Sign ); //////////////////////////////////////////////////////////////////////// // // FPU Outputs // reg fasu_op_r1, fasu_op_r2; wire [30:0] out_fixed; wire output_zero_fasu; wire overflow_fasu; wire out_d_00; wire ine_fasu; wire underflow_fasu; reg opa_nan_r; always @(posedge clk) fasu_op_r1 <= #1 fasu_op; always @(posedge clk) fasu_op_r2 <= #1 fasu_op_r1; // Force pre-set values for non numerical output assign out_fixed = ( (qnan_d \| snan_d) \| (ind_d & !fasu_op_r2) ) ? QNAN : INF; always @(posedge clk) out_o1[30:0] <= #1 (inf_d \| snan_d \| qnan_d) ? out_fixed : out_d; assign out_d_00 = !(\|out_d); always @(posedge clk) out_o1[31] <= #1 (snan_d \| qnan_d \| ind_d) ? nan_sign_d : output_zero_fasu ? result_zero_sign_d : sign_fasu_r; assign ine_fasu = (ine_d \| overflow_d \| underflow_d) & !(snan_d \| qnan_d \| inf_d); always @(posedge clk) ine_o1 <= #1 ine_fasu ; assign overflow_fasu = overflow_d & !(snan_d \| qnan_d \| inf_d); always @(posedge clk) overflow_o1 <= #1 overflow_fasu ; assign underflow_fasu = underflow_d & !(inf_d \| snan_d \| qnan_d); always @(posedge clk) underflow_o1 <= #1 underflow_fasu ; always @(posedge clk) snan_o1 <= #1 snan_d; // Status Outputs always @(posedge clk) qnan_o1 <= #1 ( snan_d \| qnan_d \| (ind_d & !fasu_op_r2) ); always @(posedge clk) inf_o1 <= #1 (!(qnan_d \| snan_d) & (( (&out_d[30:23]) & !(\|out_d[22:0] ) ) \| (inf_d & !(ind_d & !fasu_op_r2) & !fpu_op_r3[1]) )); assign output_zero_fasu = out_d_00 & !(inf_d \| snan_d \| qnan_d); always @(posedge clk) zero_o1 <= #1 output_zero_fasu ; always @(posedge clk) opa_nan_r <= #1 !opa_nan & fpu_op_r2==3'b011; always @(posedge clk) div_by_zero_o1 <= #1 1'b0; // output register always @(posedge clk) begin qnan <= #1 qnan_o1; out <= #1 out_o1; inf <= #1 inf_o1; snan <= #1 snan_o1; //qnan <= #1 qnan_o1; ine <= #1 ine_o1; overflow <= #1 overflow_o1; underflow <= #1 underflow_o1; zero <= #1 zero_o1; div_by_zero <= #1 div_by_zero_o1; end endmodule //--------------------------------------------------------------------------------- module pre_norm(clk, rmode, add, opa, opb, opa_nan, opb_nan, fracta_out, fractb_out, exp_dn_out, sign, nan_sign, result_zero_sign, fasu_op); input clk; input [1:0] rmode; input add; input [31:0] opa, opb; input opa_nan, opb_nan; output [26:0] fracta_out, fractb_out; output [7:0] exp_dn_out; output sign; output nan_sign, result_zero_sign; output fasu_op; // Operation Output //////////////////////////////////////////////////////////////////////// // // Local Wires and registers // wire signa, signb; // alias to opX sign wire [7:0] expa, expb; // alias to opX exponent wire [22:0] fracta, fractb; // alias to opX fraction wire expa_lt_expb; // expa is larger than expb indicator wire fractb_lt_fracta; // fractb is larger than fracta indicator reg [7:0] exp_dn_out; // de normalized exponent output wire [7:0] exp_small, exp_large; wire [7:0] exp_diff; // Numeric difference of the two exponents wire [22:0] adj_op; // Fraction adjustment: input wire [26:0] adj_op_tmp; wire [26:0] adj_op_out; // Fraction adjustment: output wire [26:0] fracta_n, fractb_n; // Fraction selection after normalizing wire [26:0] fracta_s, fractb_s; // Fraction Sorting out reg [26:0] fracta_out, fractb_out; // Fraction Output reg sign, sign_d; // Sign Output reg add_d; // operation (add/sub) reg fasu_op; // operation (add/sub) register wire expa_dn, expb_dn; reg sticky; reg result_zero_sign; reg add_r, signa_r, signb_r; wire [4:0] exp_diff_sft; wire exp_lt_27; wire op_dn; wire [26:0] adj_op_out_sft; reg fracta_lt_fractb, fracta_eq_fractb; wire nan_sign1; reg nan_sign; //////////////////////////////////////////////////////////////////////// // // Aliases // assign signa = opa[31]; assign signb = opb[31]; assign expa = opa[30:23]; assign expb = opb[30:23]; assign fracta = opa[22:0]; assign fractb = opb[22:0]; //////////////////////////////////////////////////////////////////////// // // Pre-Normalize exponents (and fractions) // assign expa_lt_expb = expa > expb; // expa is larger than expb // --------------------------------------------------------------------- // Normalize assign expa_dn = !(\|expa); // opa denormalized assign expb_dn = !(\|expb); // opb denormalized // --------------------------------------------------------------------- // Calculate the difference between the smaller and larger exponent wire [7:0] exp_diff1, exp_diff1a, exp_diff2; assign exp_small = expa_lt_expb ? expb : expa; assign exp_large = expa_lt_expb ? expa : expb; assign exp_diff1 = exp_large - exp_small; assign exp_diff1a = exp_diff1-8'h01; assign exp_diff2 = (expa_dn \| expb_dn) ? exp_diff1a : exp_diff1; assign exp_diff = (expa_dn & expb_dn) ? 8'h0 : exp_diff2; always @(posedge clk) // If numbers are equal we should return zero exp_dn_out <= #1 (!add_d & expa==expb & fracta==fractb) ? 8'h0 : exp_large; // --------------------------------------------------------------------- // Adjust the smaller fraction assign op_dn = expa_lt_expb ? expb_dn : expa_dn; assign adj_op = expa_lt_expb ? fractb : fracta; wire temp1; assign temp1 = ~op_dn; //assign adj_op_tmp[26:0] = {~op_dn, adj_op, 3'b000}; // recover hidden bit (op_dn) assign adj_op_tmp[26:0] = {temp1, adj_op, 3'b000}; // recover hidden bit (op_dn) // adj_op_out is 27 bits wide, so can only be shifted 27 bits to the right assign exp_lt_27 = exp_diff > 8'd27; assign exp_diff_sft = exp_lt_27 ? 5'd27 : exp_diff[4:0]; //assign adj_op_out_sft = adj_op_tmp >> exp_diff_sft; b_right_shifter_new u7( .shift_in(adj_op_tmp), .shift_value(exp_diff_sft), .shift_out(adj_op_out_sft) ); wire temp2; assign temp2 = adj_op_out_sft[0] \| sticky; //assign adj_op_out[26:0] = {adj_op_out_sft[26:1], adj_op_out_sft[0] \| sticky }; assign adj_op_out[26:0] = {adj_op_out_sft[26:1], temp2 }; // --------------------------------------------------------------------- // Get truncated portion (sticky bit) always @(exp_diff_sft or adj_op_tmp) case(exp_diff_sft) // synopsys full_case parallel_case 5'd00: sticky = 1'h0; 5'd01: sticky = adj_op_tmp[0]; 5'd02: sticky = \|adj_op_tmp[01:0]; 5'd03: sticky = \|adj_op_tmp[02:0]; 5'd04: sticky = \|adj_op_tmp[03:0]; 5'd05: sticky = \|adj_op_tmp[04:0]; 5'd06: sticky = \|adj_op_tmp[05:0]; 5'd07: sticky = \|adj_op_tmp[06:0]; 5'd08: sticky = \|adj_op_tmp[07:0]; 5'd09: sticky = \|adj_op_tmp[08:0]; 5'd10: sticky = \|adj_op_tmp[09:0]; 5'd11: sticky = \|adj_op_tmp[10:0]; 5'd12: sticky = \|adj_op_tmp[11:0]; 5'd13: sticky = \|adj_op_tmp[12:0]; 5'd14: sticky = \|adj_op_tmp[13:0]; 5'd15: sticky = \|adj_op_tmp[14:0]; 5'd16: sticky = \|adj_op_tmp[15:0]; 5'd17: sticky = \|adj_op_tmp[16:0]; 5'd18: sticky = \|adj_op_tmp[17:0]; 5'd19: sticky = \|adj_op_tmp[18:0]; 5'd20: sticky = \|adj_op_tmp[19:0]; 5'd21: sticky = \|adj_op_tmp[20:0]; 5'd22: sticky = \|adj_op_tmp[21:0]; 5'd23: sticky = \|adj_op_tmp[22:0]; 5'd24: sticky = \|adj_op_tmp[23:0]; 5'd25: sticky = \|adj_op_tmp[24:0]; 5'd26: sticky = \|adj_op_tmp[25:0]; 5'd27: sticky = \|adj_op_tmp[26:0]; endcase // --------------------------------------------------------------------- // Select operands for add/sub (recover hidden bit) assign fracta_n = expa_lt_expb ? {~expa_dn, fracta, 3'b0} : adj_op_out; assign fractb_n = expa_lt_expb ? adj_op_out : {~expb_dn, fractb, 3'b0}; // --------------------------------------------------------------------- // Sort operands (for sub only) assign fractb_lt_fracta = fractb_n > fracta_n; // fractb is larger than fracta assign fracta_s = fractb_lt_fracta ? fractb_n : fracta_n; assign fractb_s = fractb_lt_fracta ? fracta_n : fractb_n; always @(posedge clk) fracta_out <= #1 fracta_s; always @(posedge clk) fractb_out <= #1 fractb_s; // --------------------------------------------------------------------- // Determine sign for the output // sign: 0=Positive Number; 1=Negative Number always @(signa or signb or add or fractb_lt_fracta) case({signa, signb, add}) // synopsys full_case parallel_case // Add 3'b001: sign_d = 0; 3'b011: sign_d = fractb_lt_fracta; 3'b101: sign_d = !fractb_lt_fracta; 3'b111: sign_d = 1; // Sub 3'b000: sign_d = fractb_lt_fracta; 3'b010: sign_d = 0; 3'b100: sign_d = 1; 3'b110: sign_d = !fractb_lt_fracta; endcase always @(posedge clk) sign <= #1 sign_d; // Fix sign for ZERO result always @(posedge clk) signa_r <= #1 signa; always @(posedge clk) signb_r <= #1 signb; always @(posedge clk) add_r <= #1 add; always @(posedge clk) result_zero_sign <= #1 ( add_r & signa_r & signb_r) \| (!add_r & signa_r & !signb_r) \| ( add_r & (signa_r \| signb_r) & (rmode==3)) \| (!add_r & (signa_r == signb_r) & (rmode==3)); // Fix sign for NAN result always @(posedge clk) fracta_lt_fractb <= #1 fracta < fractb; always @(posedge clk) fracta_eq_fractb <= #1 fracta == fractb; assign nan_sign1 = fracta_eq_fractb ? (signa_r & signb_r) : fracta_lt_fractb ? signb_r : signa_r; always @(posedge clk) nan_sign <= #1 (opa_nan & opb_nan) ? nan_sign1 : opb_nan ? signb_r : signa_r; //////////////////////////////////////////////////////////////////////// // // Decode Add/Sub operation // // add: 1=Add; 0=Subtract always @(signa or signb or add) case({signa, signb, add}) // synopsys full_case parallel_case // Add 3'b001: add_d = 1; 3'b011: add_d = 0; 3'b101: add_d = 0; 3'b111: add_d = 1; // Sub 3'b000: add_d = 0; 3'b010: add_d = 1; 3'b100: add_d = 1; 3'b110: add_d = 0; endcase always @(posedge clk) fasu_op <= #1 add_d; endmodule module b_right_shifter_new ( shift_in, shift_value, shift_out ); input [26:0] shift_in; input [4:0] shift_value; output [26:0] shift_out; reg [47:0] shift_out; always @(shift_value) begin case (shift_value) 5'b00000: shift_out = shift_in; 5'b00001: shift_out = shift_in >> 1; 5'b00010: shift_out = shift_in >> 2; 5'b00011: shift_out = shift_in >> 3; 5'b00100: shift_out = shift_in >> 4; 5'b00101: shift_out = shift_in >> 5; 5'b00110: shift_out = shift_in >> 6; 5'b00111: shift_out = shift_in >> 7; 5'b01000: shift_out = shift_in >> 8; 5'b01001: shift_out = shift_in >> 9; 5'b01010: shift_out = shift_in >> 10; 5'b01011: shift_out = shift_in >> 11; 5'b01100: shift_out = shift_in >> 12; 5'b01101: shift_out = shift_in >> 13; 5'b01110: shift_out = shift_in >> 14; 5'b01111: shift_out = shift_in >> 15; 5'b10000: shift_out = shift_in >> 16; 5'b10001: shift_out = shift_in >> 17; 5'b10010: shift_out = shift_in >> 18; 5'b10011: shift_out = shift_in >> 19; 5'b10100: shift_out = shift_in >> 20; 5'b10101: shift_out = shift_in >> 21; 5'b10110: shift_out = shift_in >> 22; 5'b10111: shift_out = shift_in >> 23; 5'b11000: shift_out = shift_in >> 24; 5'b11001: shift_out = shift_in >> 25; 5'b11010: shift_out = shift_in >> 26; 5'b11011: shift_out = shift_in >> 27; endcase end endmodule //---------------------------------------------------------------------------- //////////////////////////////////////////////////////////////////////// // // Add/Sub // module add_sub27(add, opa, opb, sum, co); input add; input [26:0] opa, opb; output [26:0] sum; output co; assign {co, sum} = add ? ({1'b0, opa} + {1'b0, opb}) : ({1'b0, opa} - {1'b0, opb}); endmodule
////////////////////////////////////////////////////////////////////// //// //// //// spi_clgen.v //// //// //// //// This file is part of the SPI IP core project //// //// http://www.opencores.org/projects/spi/ //// //// //// //// Author(s): //// //// - Simon Srot ([email protected]) //// //// //// //// All additional information is avaliable in the Readme.txt //// //// file. //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2002 Authors //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source is distributed in the hope that it will be //// //// useful, but WITHOUT ANY WARRANTY; without even the implied //// //// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR //// //// PURPOSE. See the GNU Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// module spi_clgen (clk_in, rst, go, enable, last_clk, divider, clk_out, pos_edge, neg_edge); parameter Tp = 1; input clk_in; // input clock (system clock) input rst; // reset input enable; // clock enable input go; // start transfer input last_clk; // last clock input [3:0] divider; // clock divider (output clock is divided by this value) output clk_out; // output clock output pos_edge; // pulse marking positive edge of clk_out output neg_edge; // pulse marking negative edge of clk_out reg clk_out; reg pos_edge; reg neg_edge; reg [3:0] cnt; // clock counter wire cnt_zero; // conter is equal to zero wire cnt_one; // conter is equal to one assign cnt_zero = cnt == {4{1'b0}}; assign cnt_one = cnt == {{3{1'b0}}, 1'b1}; // Counter counts half period always @(posedge clk_in or posedge rst) begin if(rst) cnt <= #Tp {4{1'b1}}; else begin if(!enable \|\| cnt_zero) cnt <= #Tp divider; else cnt <= #Tp cnt - {{3{1'b0}}, 1'b1}; end end // clk_out is asserted every other half period always @(posedge clk_in or posedge rst) begin if(rst) clk_out <= #Tp 1'b0; else clk_out <= #Tp (enable && cnt_zero && (!last_clk \|\| clk_out)) ? ~clk_out : clk_out; end // Pos and neg edge signals always @(posedge clk_in or posedge rst) begin if(rst) begin pos_edge <= #Tp 1'b0; neg_edge <= #Tp 1'b0; end else begin pos_edge <= #Tp (enable && !clk_out && cnt_one) \|\| (!(\|divider) && clk_out) \|\| (!(\|divider) && go && !enable); neg_edge <= #Tp (enable && clk_out && cnt_one) \|\| (!(\|divider) && !clk_out && enable); end end endmodule
/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 / `ifndef SKY130_FD_SC_LS__INV_4_V `define SKY130_FD_SC_LS__INV_4_V /* * inv: Inverter. * * Verilog wrapper for inv with size of 4 units. * * WARNING: This file is autogenerated, do not modify directly! / `timescale 1ns / 1ps `default_nettype none `include "sky130_fd_sc_ls__inv.v" `ifdef USE_POWER_PINS /******************************************************/ `celldefine module sky130_fd_sc_ls__inv_4 ( Y , A , VPWR, VGND, VPB , VNB ); output Y ; input A ; input VPWR; input VGND; input VPB ; input VNB ; sky130_fd_sc_ls__inv base ( .Y(Y), .A(A), .VPWR(VPWR), .VGND(VGND), .VPB(VPB), .VNB(VNB) ); endmodule `endcelldefine /*****************************************************/ `else // If not USE_POWER_PINS /*****************************************************/ `celldefine module sky130_fd_sc_ls__inv_4 ( Y, A ); output Y; input A; // Voltage supply signals supply1 VPWR; supply0 VGND; supply1 VPB ; supply0 VNB ; sky130_fd_sc_ls__inv base ( .Y(Y), .A(A) ); endmodule `endcelldefine /*******************************************************/ `endif // USE_POWER_PINS `default_nettype wire `endif // SKY130_FD_SC_LS__INV_4_V
// Copyright 1986-2016 Xilinx, Inc. All Rights Reserved. // -------------------------------------------------------------------------------- // Tool Version: Vivado v.2016.4 (win64) Build 1733598 Wed Dec 14 22:35:39 MST 2016 // Date : Tue Jun 06 02:45:58 2017 // Host : GILAMONSTER running 64-bit major release (build 9200) // Command : write_verilog -force -mode synth_stub // c:/ZyboIP/examples/zed_dual_fusion/zed_dual_fusion.srcs/sources_1/bd/system/ip/system_vga_transform_0_0/system_vga_transform_0_0_stub.v // Design : system_vga_transform_0_0 // Purpose : Stub declaration of top-level module interface // Device : xc7z020clg484-1 // -------------------------------------------------------------------------------- // This empty module with port declaration file causes synthesis tools to infer a black box for IP. // The synthesis directives are for Synopsys Synplify support to prevent IO buffer insertion. // Please paste the declaration into a Verilog source file or add the file as an additional source. (* x_core_info = "vga_transform,Vivado 2016.4" ) module system_vga_transform_0_0(clk, enable, x_addr_in, y_addr_in, rot_m00, rot_m01, rot_m10, rot_m11, t_x, t_y, x_addr_out, y_addr_out) / synthesis syn_black_box black_box_pad_pin="clk,enable,x_addr_in[9:0],y_addr_in[9:0],rot_m00[15:0],rot_m01[15:0],rot_m10[15:0],rot_m11[15:0],t_x[9:0],t_y[9:0],x_addr_out[9:0],y_addr_out[9:0]" */; input clk; input enable; input [9:0]x_addr_in; input [9:0]y_addr_in; input [15:0]rot_m00; input [15:0]rot_m01; input [15:0]rot_m10; input [15:0]rot_m11; input [9:0]t_x; input [9:0]t_y; output [9:0]x_addr_out; output [9:0]y_addr_out; endmodule
// (C) 2001-2017 Intel Corporation. All rights reserved. // Your use of Intel Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files from any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Intel Program License Subscription // Agreement, Intel FPGA IP License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Intel and sold by // Intel or its authorized distributors. Please refer to the applicable // agreement for further details. // $Id: //acds/main/ip/sopc/components/primitives/altera_std_synchronizer/altera_std_synchronizer.v#8 $ // $Revision: #8 $ // $Date: 2009/02/18 $ // $Author: pscheidt $ //----------------------------------------------------------------------------- // // File: altera_std_synchronizer_nocut.v // // Abstract: Single bit clock domain crossing synchronizer. Exactly the same // as altera_std_synchronizer.v, except that the embedded false // path constraint is removed in this module. If you use this // module, you will have to apply the appropriate timing // constraints. // // We expect to make this a standard Quartus atom eventually. // // Composed of two or more flip flops connected in series. // Random metastable condition is simulated when the // __ALTERA_STD__METASTABLE_SIM macro is defined. // Use +define+__ALTERA_STD__METASTABLE_SIM argument // on the Verilog simulator compiler command line to // enable this mode. In addition, define the macro // __ALTERA_STD__METASTABLE_SIM_VERBOSE to get console output // with every metastable event generated in the synchronizer. // // Copyright (C) Altera Corporation 2009, All Rights Reserved //----------------------------------------------------------------------------- `timescale 1ns / 1ns module altera_std_synchronizer_nocut ( clk, reset_n, din, dout ); parameter depth = 3; // This value must be >= 2 ! parameter rst_value = 0; input clk; input reset_n; input din; output dout; // QuartusII synthesis directives: // 1. Preserve all registers ie. do not touch them. // 2. Do not merge other flip-flops with synchronizer flip-flops. // QuartusII TimeQuest directives: // 1. Identify all flip-flops in this module as members of the synchronizer // to enable automatic metastability MTBF analysis. (* altera_attribute = {"-name ADV_NETLIST_OPT_ALLOWED NEVER_ALLOW; -name SYNCHRONIZER_IDENTIFICATION FORCED; -name DONT_MERGE_REGISTER ON; -name PRESERVE_REGISTER ON "} ) reg din_s1; ( altera_attribute = {"-name ADV_NETLIST_OPT_ALLOWED NEVER_ALLOW; -name DONT_MERGE_REGISTER ON; -name PRESERVE_REGISTER ON"} ) reg [depth-2:0] dreg; //synthesis translate_off initial begin if (depth <2) begin $display("%m: Error: synchronizer length: %0d less than 2.", depth); end end // the first synchronizer register is either a simple D flop for synthesis // and non-metastable simulation or a D flop with a method to inject random // metastable events resulting in random delay of [0,1] cycles `ifdef __ALTERA_STD__METASTABLE_SIM reg[31:0] RANDOM_SEED = 123456; wire next_din_s1; wire dout; reg din_last; reg random; event metastable_event; // hook for debug monitoring initial begin $display("%m: Info: Metastable event injection simulation mode enabled"); end always @(posedge clk) begin if (reset_n == 0) random <= $random(RANDOM_SEED); else random <= $random; end assign next_din_s1 = (din_last ^ din) ? random : din; always @(posedge clk or negedge reset_n) begin if (reset_n == 0) din_last <= (rst_value == 0)? 1'b0 : 1'b1; else din_last <= din; end always @(posedge clk or negedge reset_n) begin if (reset_n == 0) din_s1 <= (rst_value == 0)? 1'b0 : 1'b1; else din_s1 <= next_din_s1; end `else //synthesis translate_on generate if (rst_value == 0) always @(posedge clk or negedge reset_n) begin if (reset_n == 0) din_s1 <= 1'b0; else din_s1 <= din; end endgenerate generate if (rst_value == 1) always @(posedge clk or negedge reset_n) begin if (reset_n == 0) din_s1 <= 1'b1; else din_s1 <= din; end endgenerate //synthesis translate_off `endif `ifdef __ALTERA_STD__METASTABLE_SIM_VERBOSE always @() begin if (reset_n && (din_last != din) && (random != din)) begin $display("%m: Verbose Info: metastable event @ time %t", $time); ->metastable_event; end end `endif //synthesis translate_on // the remaining synchronizer registers form a simple shift register // of length depth-1 generate if (rst_value == 0) if (depth < 3) begin always @(posedge clk or negedge reset_n) begin if (reset_n == 0) dreg <= {depth-1{1'b0}}; else dreg <= din_s1; end end else begin always @(posedge clk or negedge reset_n) begin if (reset_n == 0) dreg <= {depth-1{1'b0}}; else dreg <= {dreg[depth-3:0], din_s1}; end end endgenerate generate if (rst_value == 1) if (depth < 3) begin always @(posedge clk or negedge reset_n) begin if (reset_n == 0) dreg <= {depth-1{1'b1}}; else dreg <= din_s1; end end else begin always @(posedge clk or negedge reset_n) begin if (reset_n == 0) dreg <= {depth-1{1'b1}}; else dreg <= {dreg[depth-3:0], din_s1}; end end endgenerate assign dout = dreg[depth-2]; endmodule
module paddle_control( input clock, reset, enable, rotary_event, rotary_right, input [4:0] speed, input [5:0] radius, input middle, output reg [9:0] paddle_x, paddle_y ); localparam PD_H = 8; localparam MAXX = 320; localparam MAXY = 480; localparam LEFT = 160; localparam TOP = 0; reg [9:0] next_x, next_y; always @() begin if (middle) paddle_y = TOP+MAXY/2-PD_H; else paddle_y = TOP+MAXY-PD_H; end always @(posedge clock) begin if (reset) begin paddle_x <= LEFT + MAXX/2; end else begin paddle_x <= next_x; end end always @() begin if (enable && rotary_event) begin if (rotary_right) begin if (paddle_x + radius + speed < LEFT + MAXX) next_x = paddle_x + radius + speed; else next_x = LEFT + MAXX - radius; end else begin if (paddle_x > LEFT + radius + speed) next_x = paddle_x - radius - speed; else next_x = LEFT + radius; end end else begin if (paddle_x + radius >= LEFT + MAXX) next_x = LEFT + MAXX - radius; else if (paddle_x < LEFT + radius) next_x = LEFT + radius; else next_x = paddle_x; end end endmodule
/* * PicoSoC - A simple example SoC using PicoRV32 * * Copyright (C) 2017 Claire Xenia Wolf <[email protected]> * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. * */ module hx8kdemo ( input clk, output ser_tx, input ser_rx, output [7:0] leds, output flash_csb, output flash_clk, inout flash_io0, inout flash_io1, inout flash_io2, inout flash_io3, output debug_ser_tx, output debug_ser_rx, output debug_flash_csb, output debug_flash_clk, output debug_flash_io0, output debug_flash_io1, output debug_flash_io2, output debug_flash_io3 ); reg [5:0] reset_cnt = 0; wire resetn = &reset_cnt; always @(posedge clk) begin reset_cnt <= reset_cnt + !resetn; end wire flash_io0_oe, flash_io0_do, flash_io0_di; wire flash_io1_oe, flash_io1_do, flash_io1_di; wire flash_io2_oe, flash_io2_do, flash_io2_di; wire flash_io3_oe, flash_io3_do, flash_io3_di; SB_IO #( .PIN_TYPE(6'b 1010_01), .PULLUP(1'b 0) ) flash_io_buf [3:0] ( .PACKAGE_PIN({flash_io3, flash_io2, flash_io1, flash_io0}), .OUTPUT_ENABLE({flash_io3_oe, flash_io2_oe, flash_io1_oe, flash_io0_oe}), .D_OUT_0({flash_io3_do, flash_io2_do, flash_io1_do, flash_io0_do}), .D_IN_0({flash_io3_di, flash_io2_di, flash_io1_di, flash_io0_di}) ); wire iomem_valid; reg iomem_ready; wire [3:0] iomem_wstrb; wire [31:0] iomem_addr; wire [31:0] iomem_wdata; reg [31:0] iomem_rdata; reg [31:0] gpio; assign leds = gpio; always @(posedge clk) begin if (!resetn) begin gpio <= 0; end else begin iomem_ready <= 0; if (iomem_valid && !iomem_ready && iomem_addr[31:24] == 8'h 03) begin iomem_ready <= 1; iomem_rdata <= gpio; if (iomem_wstrb[0]) gpio[ 7: 0] <= iomem_wdata[ 7: 0]; if (iomem_wstrb[1]) gpio[15: 8] <= iomem_wdata[15: 8]; if (iomem_wstrb[2]) gpio[23:16] <= iomem_wdata[23:16]; if (iomem_wstrb[3]) gpio[31:24] <= iomem_wdata[31:24]; end end end picosoc soc ( .clk (clk ), .resetn (resetn ), .ser_tx (ser_tx ), .ser_rx (ser_rx ), .flash_csb (flash_csb ), .flash_clk (flash_clk ), .flash_io0_oe (flash_io0_oe), .flash_io1_oe (flash_io1_oe), .flash_io2_oe (flash_io2_oe), .flash_io3_oe (flash_io3_oe), .flash_io0_do (flash_io0_do), .flash_io1_do (flash_io1_do), .flash_io2_do (flash_io2_do), .flash_io3_do (flash_io3_do), .flash_io0_di (flash_io0_di), .flash_io1_di (flash_io1_di), .flash_io2_di (flash_io2_di), .flash_io3_di (flash_io3_di), .irq_5 (1'b0 ), .irq_6 (1'b0 ), .irq_7 (1'b0 ), .iomem_valid (iomem_valid ), .iomem_ready (iomem_ready ), .iomem_wstrb (iomem_wstrb ), .iomem_addr (iomem_addr ), .iomem_wdata (iomem_wdata ), .iomem_rdata (iomem_rdata ) ); assign debug_ser_tx = ser_tx; assign debug_ser_rx = ser_rx; assign debug_flash_csb = flash_csb; assign debug_flash_clk = flash_clk; assign debug_flash_io0 = flash_io0_di; assign debug_flash_io1 = flash_io1_di; assign debug_flash_io2 = flash_io2_di; assign debug_flash_io3 = flash_io3_di; endmodule
/* * Milkymist SoC * Copyright (C) 2007, 2008, 2009, 2010, 2011 Sebastien Bourdeauducq * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, version 3 of the License. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see <http://www.gnu.org/licenses/>. / module conbus_arb5( input sys_clk, input sys_rst, input [4:0] req, output [2:0] gnt ); reg [2:0] state; reg [2:0] next_state; assign gnt = state; always @(posedge sys_clk) begin if(sys_rst) state <= 3'd0; else state <= next_state; end always @() begin next_state = state; case(state) 3'd0: begin if(~req[0]) begin if(req[1]) next_state = 3'd1; else if(req[2]) next_state = 3'd2; else if(req[3]) next_state = 3'd3; else if(req[4]) next_state = 3'd4; end end 3'd1: begin if(~req[1]) begin if(req[2]) next_state = 3'd2; else if(req[3]) next_state = 3'd3; else if(req[4]) next_state = 3'd4; else if(req[0]) next_state = 3'd0; end end 3'd2: begin if(~req[2]) begin if(req[3]) next_state = 3'd3; else if(req[4]) next_state = 3'd4; else if(req[0]) next_state = 3'd0; else if(req[1]) next_state = 3'd1; end end 3'd3: begin if(~req[3]) begin if(req[4]) next_state = 3'd4; else if(req[0]) next_state = 3'd0; else if(req[1]) next_state = 3'd1; else if(req[2]) next_state = 3'd2; end end 3'd4: begin if(~req[4]) begin if(req[0]) next_state = 3'd0; else if(req[1]) next_state = 3'd1; else if(req[2]) next_state = 3'd2; else if(req[3]) next_state = 3'd3; end end endcase end endmodule
// // Copyright 2011-2012 Ettus Research LLC // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see <http://www.gnu.org/licenses/>. // module vita_tx_chain #(parameter BASE=0, parameter FIFOSIZE=10, parameter POST_ENGINE_FIFOSIZE=10, parameter REPORT_ERROR=0, parameter DO_FLOW_CONTROL=0, parameter PROT_ENG_FLAGS=0, parameter USE_TRANS_HEADER=0, parameter DSP_NUMBER=0) (input clk, input reset, input set_stb, input [7:0] set_addr, input [31:0] set_data, input set_stb_user, input [7:0] set_addr_user, input [31:0] set_data_user, input [63:0] vita_time, input [35:0] tx_data_i, input tx_src_rdy_i, output tx_dst_rdy_o, output [35:0] err_data_o, output err_src_rdy_o, input err_dst_rdy_i, output [31:0] sample, input strobe, output underrun, output run, output clear_o, output [31:0] debug); localparam MAXCHAN = 1; localparam FIFOWIDTH = 5+64+16+(32MAXCHAN); wire [FIFOWIDTH-1:0] tx1_data; wire tx1_src_rdy, tx1_dst_rdy; wire [31:0] streamid, message; wire trigger, sent; wire [31:0] debug_vtc, debug_vtd, debug_tx_dsp; wire error, packet_consumed, ack; wire [31:0] error_code; wire clear_seqnum; wire [31:0] current_seqnum; wire clear, flush; assign clear_o = clear; assign underrun = error; assign message = error_code; setting_reg #(.my_addr(BASE+0), .width(1)) sr (.clk(clk),.rst(reset),.strobe(set_stb),.addr(set_addr), .in(set_data),.out(flush),.changed(clear)); setting_reg #(.my_addr(BASE+2), .at_reset(0)) sr_streamid (.clk(clk),.rst(reset),.strobe(set_stb),.addr(set_addr), .in(set_data),.out(streamid),.changed(clear_seqnum)); //flush control - full rate vacuum of input until flush cleared wire tx_dst_rdy_int, tx_src_rdy_int; wire [35:0] tx_data_int; valve36 flusher_valve (.clk(clk), .reset(reset), .clear(clear & flush), .shutoff(flush), .data_i(tx_data_i), .src_rdy_i(tx_src_rdy_i), .dst_rdy_o(tx_dst_rdy_o), .data_o(tx_data_int), .src_rdy_o(tx_src_rdy_int), .dst_rdy_i(tx_dst_rdy_int)); wire [35:0] tx_data_int1; wire tx_src_rdy_int1, tx_dst_rdy_int1; generate if (FIFOSIZE==0) begin assign tx_data_int1 = tx_data_int; assign tx_src_rdy_int1 = tx_src_rdy_int; assign tx_dst_rdy_int = tx_dst_rdy_int1; end else begin wire [FIFOSIZE-1:0] access_adr, access_len; wire access_we, access_stb, access_ok, access_done, access_skip_read; wire [35:0] dsp_to_buf, buf_to_dsp; wire [35:0] tx_data_int0; wire tx_src_rdy_int0, tx_dst_rdy_int0; double_buffer #(.BUF_SIZE(FIFOSIZE)) db (.clk(clk),.reset(reset),.clear(clear), .access_we(access_we), .access_stb(access_stb), .access_ok(access_ok), .access_done(access_done), .access_skip_read(access_skip_read), .access_adr(access_adr), .access_len(access_len), .access_dat_i(dsp_to_buf), .access_dat_o(buf_to_dsp), .data_i(tx_data_int), .src_rdy_i(tx_src_rdy_int), .dst_rdy_o(tx_dst_rdy_int), .data_o(tx_data_int0), .src_rdy_o(tx_src_rdy_int0), .dst_rdy_i(tx_dst_rdy_int0)); vita_tx_engine_glue #(.DSPNO(DSP_NUMBER), .MAIN_SETTINGS_BASE(BASE+1), .BUF_SIZE(FIFOSIZE), .HEADER_OFFSET(USE_TRANS_HEADER)) dspengine_tx (.clock(clk),.reset(reset),.clear(clear), .set_stb_main(set_stb), .set_addr_main(set_addr), .set_data_main(set_data), .set_stb_user(set_stb_user), .set_addr_user(set_addr_user), .set_data_user(set_data_user), .access_we(access_we), .access_stb(access_stb), .access_ok(access_ok), .access_done(access_done), .access_skip_read(access_skip_read), .access_adr(access_adr), .access_len(access_len), .access_dat_i(buf_to_dsp), .access_dat_o(dsp_to_buf)); fifo_cascade #(.WIDTH(36), .SIZE(POST_ENGINE_FIFOSIZE)) post_engine_buffering( .clk(clk), .reset(reset), .clear(clear), .datain(tx_data_int0), .src_rdy_i(tx_src_rdy_int0), .dst_rdy_o(tx_dst_rdy_int0), .dataout(tx_data_int1), .src_rdy_o(tx_src_rdy_int1), .dst_rdy_i(tx_dst_rdy_int1)); end endgenerate vita_tx_deframer #(.BASE(BASE), .MAXCHAN(MAXCHAN), .USE_TRANS_HEADER(USE_TRANS_HEADER)) vita_tx_deframer (.clk(clk), .reset(reset), .clear(clear), .clear_seqnum(clear_seqnum), .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data), .data_i(tx_data_int1), .src_rdy_i(tx_src_rdy_int1), .dst_rdy_o(tx_dst_rdy_int1), .sample_fifo_o(tx1_data), .sample_fifo_src_rdy_o(tx1_src_rdy), .sample_fifo_dst_rdy_i(tx1_dst_rdy), .current_seqnum(current_seqnum), .debug(debug_vtd) ); vita_tx_control #(.BASE(BASE), .WIDTH(32MAXCHAN)) vita_tx_control (.clk(clk), .reset(reset), .clear(clear), .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data), .vita_time(vita_time), .error(error), .ack(ack), .error_code(error_code), .sample_fifo_i(tx1_data), .sample_fifo_src_rdy_i(tx1_src_rdy), .sample_fifo_dst_rdy_o(tx1_dst_rdy), .sample(sample), .run(run), .strobe(strobe), .packet_consumed(packet_consumed), .debug(debug_vtc) ); wire [35:0] flow_data, err_data_int; wire flow_src_rdy, flow_dst_rdy, err_src_rdy_int, err_dst_rdy_int; gen_context_pkt #(.PROT_ENG_FLAGS(PROT_ENG_FLAGS),.DSP_NUMBER(DSP_NUMBER)) gen_flow_pkt (.clk(clk), .reset(reset), .clear(clear), .trigger(trigger & (DO_FLOW_CONTROL==1)), .sent(), .streamid(streamid), .vita_time(vita_time), .message(32'd0), .seqnum(current_seqnum), .data_o(flow_data), .src_rdy_o(flow_src_rdy), .dst_rdy_i(flow_dst_rdy)); trigger_context_pkt #(.BASE(BASE)) trigger_context_pkt (.clk(clk), .reset(reset), .clear(clear), .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data), .packet_consumed(packet_consumed), .trigger(trigger)); gen_context_pkt #(.PROT_ENG_FLAGS(PROT_ENG_FLAGS),.DSP_NUMBER(DSP_NUMBER)) gen_tx_err_pkt (.clk(clk), .reset(reset), .clear(clear), .trigger((error\|ack) & (REPORT_ERROR==1)), .sent(), .streamid(streamid), .vita_time(vita_time), .message(message), .seqnum(current_seqnum), .data_o(err_data_int), .src_rdy_o(err_src_rdy_int), .dst_rdy_i(err_dst_rdy_int)); assign debug = debug_vtc \| debug_vtd; fifo36_mux #(.prio(1)) mux_err_and_flow // Priority to err messages (.clk(clk), .reset(reset), .clear(0), // Don't clear this or it could get clogged .data0_i(err_data_int), .src0_rdy_i(err_src_rdy_int), .dst0_rdy_o(err_dst_rdy_int), .data1_i(flow_data), .src1_rdy_i(flow_src_rdy), .dst1_rdy_o(flow_dst_rdy), .data_o(err_data_o), .src_rdy_o(err_src_rdy_o), .dst_rdy_i(err_dst_rdy_i)); endmodule // vita_tx_chain
module control ( start, clk, rst, data, data_out, parameter_Block parameter_Block2 ); input wire start; input wire clk; input wire rst; input wire [63:0] data; input wire [31:0] parameter_Block; input wire [63:0] parameter_Block2; output reg [63:0]data_out; reg [7:0] bmRequestType ; reg [7:0] bRequest ; reg [11:0] count; reg local; reg global; reg specific; reg [7:0] debug_Unit_ID; reg [7:0] interface_ID; reg [15:0] wValue; reg [15:0] wIndex; reg [15:0] wLength; reg [63:0] address; reg [63:0] dato; reg [3:0]state,next_state; parameter [3:0] IDLE = 4'b0001, RECEIVE = 4'b0010, SET = 4'b0011, GET = 4'b0100, DATA = 4'b0101, HANDSHAKE = 4'b0110, SETUP_TOKEN = 4'b0111, OUT_TOKEN = 4'b1000, IN_TOKEN = 4'b1001, ACK_TOKEN = 4'b1010; always @(posedge clk) begin case (state) IDLE : begin if (start== 0 ) next_state = IDLE; else begin next_state = RECEIVE; bmRequestType = data [63:55]; bRequest = data [55:47]; wValue = data [48:33]; wIndex = data [32:16]; wLength = data [15:0]; end end RECEIVE : begin if (bmRequestType == 8'b00100001 ) begin next_state = SET; end if (bmRequestType == 8'b00100001 ) begin next_state = GET; end end SET : begin if (bRequest == 8'h01 )//Set_config_data begin next_state = SET_CONFIG_DATA; /* if (wIndex[15:8] == 0) begin if (wValue[7:0] == 8'h00 ) // global DBclass begin global = 1 ; ext_state = GET; end if (wValue[7:0] == 8'h01 ) // global vendor begin //Si lector este tamaño lo define usted global = 1 ; end if (wValue[7:0] == 8'h02 ) // local DBclass begin local = 1 ; //ask for inter face end if (wValue[7:0] == 8'h03 ) // local vendor begin //ask for inter face //Si lector este tamaño lo define usted //this is the espace to selec your own local = 1 ; end end if (wIndex[15:8] == 0) begin if (wValue[7:0] == 8'h00 )// specific DBclass begin specific = 1 ; debug_Unit_ID = wIndex[15:8] ; interface_ID = wIndex[7:0] ; end if (wValue[7:0] == 8'h01 ) // specific vendor begin //Si lector este tamaño lo define usted debug_Unit_ID = wIndex[15:8] ; interface_ID = wIndex[7:0] ; specific = 1 ; end / end end if (bRequest == 8'h02 )//set_config_data_single begin next_state = SET_CONFIG_DATA_SINGLE; end if (bRequest == 8'h03 )//set_config_address begin next_state = SET_CONFIG_ADDRESS; end if (bRequest == 8'h04 )//set_alt_stack begin next_state = SET_ALT_STACK; end if (bRequest == 8'h05 )//set_operating_mode begin // this is for allow the trace ,dfx,ect modes next_state = SET_OPERATING_MODE; end if (bRequest == 8'h06 )//set_trace begin next_state = SET_TRACE ; // this is for allow the trace ,dfx,ect modes end if (bRequest == 8'h09 )//set_buffer begin next_state = SET_BUFFER ; end if (bRequest == 8'h0A )//set_rest begin next_state = SET_RESET; end end GET : begin if (bRequest == 8'h81 ) //get_config data begin next_state = GET_CONFIG; end if (bRequest == 8'h82 ) //get_config data single begin next_state = GET_CONFIG_SINGLE; end if (bRequest == 8'h83 ) // get_config address begin next_state = GET_CONFIG_ADDRESS; end if (bRequest == 8'h84 ) // get_alt stack begin next_state = GET_ALT_STACK; end if (bRequest == 8'h85 ) //get oprating mode begin next_state = GET_OPERATION_MODE; end if (bRequest == 8'h86 ) //get_trace begin //this is no able next_state = GET_TRACE; end if (bRequest == 8'h87 ) //get_INFO begin / bit support_capability 0 set_config data single 1 set config data 2 get config data 3 set config address 4 get config address 5 set alt stack 6 get alt stack 7 set operating mode 8 get operating mode 9 set trace configuration 10 get trace configuration 11 set buffer 12 get buffer 13 set reset 14-28 reseved set = 0 29 disable automatic mode 30 self generate control 31 slow control / next_state = GET_INFO ; end if (bRequest == 8'h88 ) //get_error begin /0x00: No error 0x01: Not ready 0x02: Wrong state 0x03: Insufficient Power Available 0x04: Max Power Violation 0x05: Operating-mode unavailable 0x06: Out of range 0x07: Invalid unit 0x08: Invalid control 0x09: Invalid Request 0x0A: Permission denied 0x0B-0xFE: reserved 0xFF: Unknown*/ end if (bRequest == 8'h89 ) //get_buffer begin end end SET_CONFIG_DATA_SINGLE : begin end SET_ALT_STACK : begin end SET_OPERATING_MODE : begin end SET_TRACE : begin end SET_BUFFER : begin end SET_RESET : begin end GET_CONFIG : begin end GET_CONFIG_SINGLE : begin end GET_CONFIG_ADDRESS : begin end GET_ALT_STACK : begin end GET_OPERATION_MODE : begin end GET_TRACE : begin end GET_INFO : begin end endcase end endmodule
`timescale 1ns / 1ps ////////////////////////////////////////////////////////////////////////////////// // Company: Case Western Reserve University // Engineer: Matt McConnell // // Create Date: 20:17:00 09/09/2017 // Project Name: EECS301 Digital Design // Design Name: Lab #4 Project // Module Name: FxP_ABS_Function // Target Devices: Altera Cyclone V // Tool versions: Quartus v17.0 // Description: Fixed Point Absolute Value Function // // Input Data in Fixed Point Two's Complement Format // Output Data is positive value integer // // Dependencies: // ////////////////////////////////////////////////////////////////////////////////// module FxP_ABS_Function #( parameter DATA_WIDTH = 16 ) ( // Data Signals input [DATA_WIDTH-1:0] DATA_IN, output [DATA_WIDTH-1:0] DATA_ABS ); // // Two's Complement Absolute Function // // If the sign-bit (MSB) is high, then // DATA_ABS = ~DATA_IN + 1'b1 // Else // DATA_ABS = DATA_IN // assign DATA_ABS = DATA_IN[DATA_WIDTH-1] ? ~DATA_IN + 1'b1 : DATA_IN; endmodule
// ---------------------------------------------------------------------- // Copyright (c) 2015, The Regents of the University of California All // rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following // disclaimer in the documentation and/or other materials provided // with the distribution. // // * Neither the name of The Regents of the University of California // nor the names of its contributors may be used to endorse or // promote products derived from this software without specific // prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL REGENTS OF THE // UNIVERSITY OF CALIFORNIA BE LIABLE FOR ANY DIRECT, INDIRECT, // INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, // BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS // OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND // ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR // TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE // USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH // DAMAGE. // ---------------------------------------------------------------------- //----------------------------------------------------------------------------- // Filename: tx_data_pipeline.v // Version: 1.0 // Verilog Standard: Verilog-2001 // // Description: The tx_data_fifo takes 0-bit aligned packet data and // puts each DW into one of N FIFOs where N = (C_DATA_WIDTH/32). // // The data interface (TX_DATA) is an interface for N 32-bit FIFOs, where N = // (C_DATA_WIDTH/32). The START_FLAG signal indicates that the first dword of // a packet is in FIFO 0 (TX_DATA[31:0]). Each FIFO interface also contains an // END_FLAG signal in the END_FLAGS bus. When a bit in END_FLAGS bus is asserted, // its corresponding fifo contains the last dword of data for the current // packet. START_FLAG, END_FLAG and DATA are all qualified by the VALID signal, // and read by the READY signal. // // The write interface (WR_TX) differs slightly from the read interface because it // produces a READY signal and consumes a VALID signal. VALID is asserted when an // entire packet has been packed into a FIFO. // // TODO: // - Make sure that the synthesis tool is removing the other three start // flag wires (and modifying the width of the FIFOs) // // Author: Dustin Richmond (@darichmond) //----------------------------------------------------------------------------- `timescale 1ns/1ns `include "trellis.vh" // Defines the user-facing signal widths. module tx_data_fifo #(parameter C_DEPTH_PACKETS = 10, parameter C_DATA_WIDTH = 128, parameter C_PIPELINE_INPUT = 1, parameter C_PIPELINE_OUTPUT = 1, parameter C_MAX_PAYLOAD = 256 // BYTES ) ( // Interface: Clocks input CLK, // Interface: Reset input RST_IN, // Interface: WR TX DATA input [C_DATA_WIDTH-1:0] WR_TX_DATA, input WR_TX_DATA_VALID, input WR_TX_DATA_START_FLAG, input [(C_DATA_WIDTH/32)-1:0] WR_TX_DATA_WORD_VALID, input [(C_DATA_WIDTH/32)-1:0] WR_TX_DATA_END_FLAGS, output WR_TX_DATA_READY, // Interface: RD TX DATA input [(C_DATA_WIDTH/32)-1:0] RD_TX_DATA_WORD_READY, output [C_DATA_WIDTH-1:0] RD_TX_DATA, output RD_TX_DATA_START_FLAG, output [(C_DATA_WIDTH/32)-1:0] RD_TX_DATA_END_FLAGS, output [(C_DATA_WIDTH/32)-1:0] RD_TX_DATA_WORD_VALID, output RD_TX_DATA_PACKET_VALID ); localparam C_FIFO_OUTPUT_DEPTH = 1; localparam C_INPUT_DEPTH = C_PIPELINE_INPUT != 0 ? 1 : 0; localparam C_OUTPUT_DEPTH = C_PIPELINE_OUTPUT != 0 ? 1 : 0; localparam C_MAXPACKET_LINES = (C_MAX_PAYLOAD8)/C_DATA_WIDTH; localparam C_FIFO_DEPTH = C_MAXPACKET_LINESC_DEPTH_PACKETS; localparam C_FIFO_DATA_WIDTH = 32; localparam C_REGISTER_WIDTH = C_FIFO_DATA_WIDTH + 2; localparam C_FIFO_WIDTH = C_FIFO_DATA_WIDTH + 2; // Data, end flag and start flag localparam C_NUM_FIFOS = (C_DATA_WIDTH/32); genvar i; wire RST; wire [C_FIFO_DATA_WIDTH-1:0] wWrTxData[C_NUM_FIFOS-1:0]; wire [C_NUM_FIFOS-1:0] wWrTxDataValid; wire [C_NUM_FIFOS-1:0] wWrTxDataReady; wire [C_NUM_FIFOS-1:0] wWrTxDataStartFlags; wire [C_NUM_FIFOS-1:0] wWrTxDataEndFlags; wire [C_NUM_FIFOS-1:0] _wRdTxDataStartFlags; wire [C_FIFO_DATA_WIDTH-1:0] wRdTxData[C_NUM_FIFOS-1:0]; wire [C_NUM_FIFOS-1:0] wRdTxDataValid; wire [C_NUM_FIFOS-1:0] wRdTxDataReady; wire [C_NUM_FIFOS-1:0] wRdTxDataStartFlags; wire [C_NUM_FIFOS-1:0] wRdTxDataEndFlags; wire wRdTxDataPacketValid; wire wWrTxEndFlagValid; wire wWrTxEndFlagReady; wire wRdTxEndFlagValid; wire wRdTxEndFlagReady; wire wPacketDecrement; wire wPacketIncrement; reg [clog2(C_DEPTH_PACKETS+1)-1:0] rPacketCounter,_rPacketCounter; /AUTOINPUT/ /AUTOWIRE/ ///AUTOOUTPUT/ assign RST = RST_IN; assign wWrTxEndFlagValid = (wWrTxDataEndFlags & wWrTxDataValid) != {C_NUM_FIFOS{1'b0}}; assign wWrTxEndFlagReady = rPacketCounter != C_DEPTH_PACKETS;// Designed a small bit of latency here to help timing... assign wPacketIncrement = wWrTxEndFlagValid & wWrTxEndFlagReady; assign wPacketDecrement = wRdTxEndFlagValid & wRdTxEndFlagReady; assign WR_TX_DATA_READY = wWrTxEndFlagReady; assign wRdTxEndFlagValid = rPacketCounter != 0; assign wRdTxEndFlagReady = (wRdTxDataReady & wRdTxDataEndFlags & wRdTxDataValid) != {C_NUM_FIFOS{1'b0}}; assign wRdTxDataPacketValid = rPacketCounter != 0; assign RD_TX_DATA_START_FLAG = _wRdTxDataStartFlags[0]; always @() begin _rPacketCounter = rPacketCounter; if(wPacketIncrement & wPacketDecrement) begin _rPacketCounter = rPacketCounter + 0; end else if(wPacketIncrement) begin _rPacketCounter = rPacketCounter + 1; end else if(wPacketDecrement) begin _rPacketCounter = rPacketCounter - 1; end end // always @ () always @(posedge CLK) begin if(RST_IN) begin rPacketCounter <= #1 0; end else begin rPacketCounter <= #1 _rPacketCounter; end end generate for( i = 0 ; i < C_NUM_FIFOS ; i = i + 1 ) begin : gen_regs_fifos pipeline #( .C_DEPTH (C_INPUT_DEPTH), .C_USE_MEMORY (0), .C_WIDTH (C_REGISTER_WIDTH) /AUTOINSTPARAM/) input_pipeline_inst_ ( // Outputs .WR_DATA_READY (), .RD_DATA ({wWrTxData[i], wWrTxDataEndFlags[i],wWrTxDataStartFlags[i]}), .RD_DATA_VALID (wWrTxDataValid[i]), // Inputs .CLK (CLK), .RST_IN (RST_IN), .WR_DATA ({WR_TX_DATA[C_FIFO_DATA_WIDTHi +: C_FIFO_DATA_WIDTH], WR_TX_DATA_END_FLAGS[i], (i == 0) ? WR_TX_DATA_START_FLAG: 1'b0}), .WR_DATA_VALID (WR_TX_DATA_VALID & WR_TX_DATA_WORD_VALID[i]), .RD_DATA_READY (wWrTxDataReady[i])); fifo #( // Parameters .C_WIDTH (C_FIFO_WIDTH), .C_DEPTH (C_FIFO_DEPTH), .C_DELAY (0) /AUTOINSTPARAM/) fifo_inst_ ( // Outputs .RD_DATA ({wRdTxData[i], wRdTxDataStartFlags[i], wRdTxDataEndFlags[i]}), .WR_READY (wWrTxDataReady[i]), .RD_VALID (wRdTxDataValid[i]), // Inputs .WR_DATA ({wWrTxData[i], wWrTxDataStartFlags[i], wWrTxDataEndFlags[i]}), .WR_VALID (wWrTxDataValid[i]), .RD_READY (wRdTxDataReady[i]), /AUTOINST/ // Inputs .CLK (CLK), .RST (RST)); pipeline #( .C_DEPTH (C_FIFO_OUTPUT_DEPTH), .C_USE_MEMORY (0), .C_WIDTH (C_FIFO_WIDTH) /AUTOINSTPARAM/) fifo_pipeline_inst_ ( // Outputs .WR_DATA_READY (wRdTxDataReady[i]), .RD_DATA ({RD_TX_DATA[i32 +: 32], _wRdTxDataStartFlags[i], RD_TX_DATA_END_FLAGS[i]}), .RD_DATA_VALID (RD_TX_DATA_WORD_VALID[i]), // Inputs .WR_DATA ({wRdTxData[i], wRdTxDataStartFlags[i], wRdTxDataEndFlags[i]}), .WR_DATA_VALID (wRdTxDataValid[i]), .RD_DATA_READY (RD_TX_DATA_WORD_READY[i]), /AUTOINST/ // Inputs .CLK (CLK), .RST_IN (RST_IN)); end // for ( i = 0 ; i < C_NUM_FIFOS ; i = i + 1 ) endgenerate endmodule // Local Variables: // verilog-library-directories:("." "../../common/") // End:
// $Header: /devl/xcs/repo/env/Databases/CAEInterfaces/verunilibs/data/glbl.v,v 1.14 2010/10/28 20:44:00 fphillip Exp $ `ifndef GLBL `define GLBL `timescale 1 ps / 1 ps module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule `endif
// (c) Copyright 1995-2017 Xilinx, Inc. All rights reserved. // // This file contains confidential and proprietary information // of Xilinx, Inc. and is protected under U.S. and // international copyright and other intellectual property // laws. // // DISCLAIMER // This disclaimer is not a license and does not grant any // rights to the materials distributed herewith. Except as // otherwise provided in a valid license issued to you by // Xilinx, and to the maximum extent permitted by applicable // law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // (2) Xilinx shall not be liable (whether in contract or tort, // including negligence, or under any other theory of // liability) for any loss or damage of any kind or nature // related to, arising under or in connection with these // materials, including for any direct, or any indirect, // special, incidental, or consequential loss or damage // (including loss of data, profits, goodwill, or any type of // loss or damage suffered as a result of any action brought // by a third party) even if such damage or loss was // reasonably foreseeable or Xilinx had been advised of the // possibility of the same. // // CRITICAL APPLICATIONS // Xilinx products are not designed or intended to be fail- // safe, or for use in any application requiring fail-safe // performance, such as life-support or safety devices or // systems, Class III medical devices, nuclear facilities, // applications related to the deployment of airbags, or any // other applications that could lead to death, personal // injury, or severe property or environmental damage // (individually and collectively, "Critical // Applications"). Customer assumes the sole risk and // liability of any use of Xilinx products in Critical // Applications, subject only to applicable laws and // regulations governing limitations on product liability. // // THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // PART OF THIS FILE AT ALL TIMES. // // DO NOT MODIFY THIS FILE. // IP VLNV: xilinx.com:ip:axi_protocol_converter:2.1 // IP Revision: 4 `timescale 1ns/1ps (* DowngradeIPIdentifiedWarnings = "yes" ) module OpenSSD2_auto_pc_3 ( aclk, aresetn, s_axi_awid, s_axi_awaddr, s_axi_awlen, s_axi_awsize, s_axi_awburst, s_axi_awlock, s_axi_awcache, s_axi_awprot, s_axi_awregion, s_axi_awqos, s_axi_awvalid, s_axi_awready, s_axi_wdata, s_axi_wstrb, s_axi_wlast, s_axi_wvalid, s_axi_wready, s_axi_bid, s_axi_bresp, s_axi_bvalid, s_axi_bready, s_axi_arid, s_axi_araddr, s_axi_arlen, s_axi_arsize, s_axi_arburst, s_axi_arlock, s_axi_arcache, s_axi_arprot, s_axi_arregion, s_axi_arqos, s_axi_arvalid, s_axi_arready, s_axi_rid, s_axi_rdata, s_axi_rresp, s_axi_rlast, s_axi_rvalid, s_axi_rready, m_axi_awid, m_axi_awaddr, m_axi_awlen, m_axi_awsize, m_axi_awburst, m_axi_awlock, m_axi_awcache, m_axi_awprot, m_axi_awqos, m_axi_awvalid, m_axi_awready, m_axi_wid, m_axi_wdata, m_axi_wstrb, m_axi_wlast, m_axi_wvalid, m_axi_wready, m_axi_bid, m_axi_bresp, m_axi_bvalid, m_axi_bready, m_axi_arid, m_axi_araddr, m_axi_arlen, m_axi_arsize, m_axi_arburst, m_axi_arlock, m_axi_arcache, m_axi_arprot, m_axi_arqos, m_axi_arvalid, m_axi_arready, m_axi_rid, m_axi_rdata, m_axi_rresp, m_axi_rlast, m_axi_rvalid, m_axi_rready ); ( X_INTERFACE_INFO = "xilinx.com:signal:clock:1.0 CLK CLK" ) input wire aclk; ( X_INTERFACE_INFO = "xilinx.com:signal:reset:1.0 RST RST" ) input wire aresetn; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWID" ) input wire [0 : 0] s_axi_awid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWADDR" ) input wire [31 : 0] s_axi_awaddr; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWLEN" ) input wire [7 : 0] s_axi_awlen; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWSIZE" ) input wire [2 : 0] s_axi_awsize; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWBURST" ) input wire [1 : 0] s_axi_awburst; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWLOCK" ) input wire [0 : 0] s_axi_awlock; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWCACHE" ) input wire [3 : 0] s_axi_awcache; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWPROT" ) input wire [2 : 0] s_axi_awprot; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWREGION" ) input wire [3 : 0] s_axi_awregion; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWQOS" ) input wire [3 : 0] s_axi_awqos; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWVALID" ) input wire s_axi_awvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWREADY" ) output wire s_axi_awready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI WDATA" ) input wire [63 : 0] s_axi_wdata; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI WSTRB" ) input wire [7 : 0] s_axi_wstrb; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI WLAST" ) input wire s_axi_wlast; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI WVALID" ) input wire s_axi_wvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI WREADY" ) output wire s_axi_wready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI BID" ) output wire [0 : 0] s_axi_bid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI BRESP" ) output wire [1 : 0] s_axi_bresp; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI BVALID" ) output wire s_axi_bvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI BREADY" ) input wire s_axi_bready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARID" ) input wire [0 : 0] s_axi_arid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARADDR" ) input wire [31 : 0] s_axi_araddr; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARLEN" ) input wire [7 : 0] s_axi_arlen; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARSIZE" ) input wire [2 : 0] s_axi_arsize; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARBURST" ) input wire [1 : 0] s_axi_arburst; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARLOCK" ) input wire [0 : 0] s_axi_arlock; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARCACHE" ) input wire [3 : 0] s_axi_arcache; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARPROT" ) input wire [2 : 0] s_axi_arprot; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARREGION" ) input wire [3 : 0] s_axi_arregion; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARQOS" ) input wire [3 : 0] s_axi_arqos; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARVALID" ) input wire s_axi_arvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARREADY" ) output wire s_axi_arready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RID" ) output wire [0 : 0] s_axi_rid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RDATA" ) output wire [63 : 0] s_axi_rdata; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RRESP" ) output wire [1 : 0] s_axi_rresp; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RLAST" ) output wire s_axi_rlast; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RVALID" ) output wire s_axi_rvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RREADY" ) input wire s_axi_rready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWID" ) output wire [0 : 0] m_axi_awid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWADDR" ) output wire [31 : 0] m_axi_awaddr; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWLEN" ) output wire [3 : 0] m_axi_awlen; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWSIZE" ) output wire [2 : 0] m_axi_awsize; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWBURST" ) output wire [1 : 0] m_axi_awburst; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWLOCK" ) output wire [1 : 0] m_axi_awlock; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWCACHE" ) output wire [3 : 0] m_axi_awcache; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWPROT" ) output wire [2 : 0] m_axi_awprot; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWQOS" ) output wire [3 : 0] m_axi_awqos; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWVALID" ) output wire m_axi_awvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWREADY" ) input wire m_axi_awready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WID" ) output wire [0 : 0] m_axi_wid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WDATA" ) output wire [63 : 0] m_axi_wdata; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WSTRB" ) output wire [7 : 0] m_axi_wstrb; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WLAST" ) output wire m_axi_wlast; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WVALID" ) output wire m_axi_wvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WREADY" ) input wire m_axi_wready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI BID" ) input wire [0 : 0] m_axi_bid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI BRESP" ) input wire [1 : 0] m_axi_bresp; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI BVALID" ) input wire m_axi_bvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI BREADY" ) output wire m_axi_bready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARID" ) output wire [0 : 0] m_axi_arid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARADDR" ) output wire [31 : 0] m_axi_araddr; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARLEN" ) output wire [3 : 0] m_axi_arlen; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARSIZE" ) output wire [2 : 0] m_axi_arsize; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARBURST" ) output wire [1 : 0] m_axi_arburst; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARLOCK" ) output wire [1 : 0] m_axi_arlock; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARCACHE" ) output wire [3 : 0] m_axi_arcache; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARPROT" ) output wire [2 : 0] m_axi_arprot; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARQOS" ) output wire [3 : 0] m_axi_arqos; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARVALID" ) output wire m_axi_arvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARREADY" ) input wire m_axi_arready; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RID" ) input wire [0 : 0] m_axi_rid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RDATA" ) input wire [63 : 0] m_axi_rdata; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RRESP" ) input wire [1 : 0] m_axi_rresp; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RLAST" ) input wire m_axi_rlast; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RVALID" ) input wire m_axi_rvalid; ( X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RREADY" *) output wire m_axi_rready; axi_protocol_converter_v2_1_axi_protocol_converter #( .C_FAMILY("zynq"), .C_M_AXI_PROTOCOL(1), .C_S_AXI_PROTOCOL(0), .C_IGNORE_ID(0), .C_AXI_ID_WIDTH(1), .C_AXI_ADDR_WIDTH(32), .C_AXI_DATA_WIDTH(64), .C_AXI_SUPPORTS_WRITE(1), .C_AXI_SUPPORTS_READ(1), .C_AXI_SUPPORTS_USER_SIGNALS(0), .C_AXI_AWUSER_WIDTH(1), .C_AXI_ARUSER_WIDTH(1), .C_AXI_WUSER_WIDTH(1), .C_AXI_RUSER_WIDTH(1), .C_AXI_BUSER_WIDTH(1), .C_TRANSLATION_MODE(2) ) inst ( .aclk(aclk), .aresetn(aresetn), .s_axi_awid(s_axi_awid), .s_axi_awaddr(s_axi_awaddr), .s_axi_awlen(s_axi_awlen), .s_axi_awsize(s_axi_awsize), .s_axi_awburst(s_axi_awburst), .s_axi_awlock(s_axi_awlock), .s_axi_awcache(s_axi_awcache), .s_axi_awprot(s_axi_awprot), .s_axi_awregion(s_axi_awregion), .s_axi_awqos(s_axi_awqos), .s_axi_awuser(1'H0), .s_axi_awvalid(s_axi_awvalid), .s_axi_awready(s_axi_awready), .s_axi_wid(1'H0), .s_axi_wdata(s_axi_wdata), .s_axi_wstrb(s_axi_wstrb), .s_axi_wlast(s_axi_wlast), .s_axi_wuser(1'H0), .s_axi_wvalid(s_axi_wvalid), .s_axi_wready(s_axi_wready), .s_axi_bid(s_axi_bid), .s_axi_bresp(s_axi_bresp), .s_axi_buser(), .s_axi_bvalid(s_axi_bvalid), .s_axi_bready(s_axi_bready), .s_axi_arid(s_axi_arid), .s_axi_araddr(s_axi_araddr), .s_axi_arlen(s_axi_arlen), .s_axi_arsize(s_axi_arsize), .s_axi_arburst(s_axi_arburst), .s_axi_arlock(s_axi_arlock), .s_axi_arcache(s_axi_arcache), .s_axi_arprot(s_axi_arprot), .s_axi_arregion(s_axi_arregion), .s_axi_arqos(s_axi_arqos), .s_axi_aruser(1'H0), .s_axi_arvalid(s_axi_arvalid), .s_axi_arready(s_axi_arready), .s_axi_rid(s_axi_rid), .s_axi_rdata(s_axi_rdata), .s_axi_rresp(s_axi_rresp), .s_axi_rlast(s_axi_rlast), .s_axi_ruser(), .s_axi_rvalid(s_axi_rvalid), .s_axi_rready(s_axi_rready), .m_axi_awid(m_axi_awid), .m_axi_awaddr(m_axi_awaddr), .m_axi_awlen(m_axi_awlen), .m_axi_awsize(m_axi_awsize), .m_axi_awburst(m_axi_awburst), .m_axi_awlock(m_axi_awlock), .m_axi_awcache(m_axi_awcache), .m_axi_awprot(m_axi_awprot), .m_axi_awregion(), .m_axi_awqos(m_axi_awqos), .m_axi_awuser(), .m_axi_awvalid(m_axi_awvalid), .m_axi_awready(m_axi_awready), .m_axi_wid(m_axi_wid), .m_axi_wdata(m_axi_wdata), .m_axi_wstrb(m_axi_wstrb), .m_axi_wlast(m_axi_wlast), .m_axi_wuser(), .m_axi_wvalid(m_axi_wvalid), .m_axi_wready(m_axi_wready), .m_axi_bid(m_axi_bid), .m_axi_bresp(m_axi_bresp), .m_axi_buser(1'H0), .m_axi_bvalid(m_axi_bvalid), .m_axi_bready(m_axi_bready), .m_axi_arid(m_axi_arid), .m_axi_araddr(m_axi_araddr), .m_axi_arlen(m_axi_arlen), .m_axi_arsize(m_axi_arsize), .m_axi_arburst(m_axi_arburst), .m_axi_arlock(m_axi_arlock), .m_axi_arcache(m_axi_arcache), .m_axi_arprot(m_axi_arprot), .m_axi_arregion(), .m_axi_arqos(m_axi_arqos), .m_axi_aruser(), .m_axi_arvalid(m_axi_arvalid), .m_axi_arready(m_axi_arready), .m_axi_rid(m_axi_rid), .m_axi_rdata(m_axi_rdata), .m_axi_rresp(m_axi_rresp), .m_axi_rlast(m_axi_rlast), .m_axi_ruser(1'H0), .m_axi_rvalid(m_axi_rvalid), .m_axi_rready(m_axi_rready) ); endmodule
/////////////////////////////////////////////////////// // Copyright (c) 2008 Xilinx Inc. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. /////////////////////////////////////////////////////// // // ____ ___ // / /\/ / // /___/ \ / Vendor : Xilinx // \ \ \/ Version : 12.i (O.4) // \ \ Description : // / / // /__/ /\ Filename : PLLE2_BASE.v // \ \ / \ // \__\/\__ \ // // Revision: 1.0 // 12/09/09 - Initial version // 03/23/10 - Change CLKFBOUT_MULT default from 1 to 5. /////////////////////////////////////////////////////// `timescale 1 ps / 1 ps `celldefine module PLLE2_BASE ( CLKFBOUT, CLKOUT0, CLKOUT1, CLKOUT2, CLKOUT3, CLKOUT4, CLKOUT5, LOCKED, CLKFBIN, CLKIN1, PWRDWN, RST ); parameter BANDWIDTH = "OPTIMIZED"; parameter integer CLKFBOUT_MULT = 5; parameter real CLKFBOUT_PHASE = 0.000; parameter real CLKIN1_PERIOD = 0.000; parameter integer CLKOUT0_DIVIDE = 1; parameter real CLKOUT0_DUTY_CYCLE = 0.500; parameter real CLKOUT0_PHASE = 0.000; parameter integer CLKOUT1_DIVIDE = 1; parameter real CLKOUT1_DUTY_CYCLE = 0.500; parameter real CLKOUT1_PHASE = 0.000; parameter integer CLKOUT2_DIVIDE = 1; parameter real CLKOUT2_DUTY_CYCLE = 0.500; parameter real CLKOUT2_PHASE = 0.000; parameter integer CLKOUT3_DIVIDE = 1; parameter real CLKOUT3_DUTY_CYCLE = 0.500; parameter real CLKOUT3_PHASE = 0.000; parameter integer CLKOUT4_DIVIDE = 1; parameter real CLKOUT4_DUTY_CYCLE = 0.500; parameter real CLKOUT4_PHASE = 0.000; parameter integer CLKOUT5_DIVIDE = 1; parameter real CLKOUT5_DUTY_CYCLE = 0.500; parameter real CLKOUT5_PHASE = 0.000; parameter integer DIVCLK_DIVIDE = 1; parameter real REF_JITTER1 = 0.010; parameter STARTUP_WAIT = "FALSE"; `ifdef XIL_TIMING parameter LOC = "UNPLACED"; `endif // output CLKFBOUT; output CLKOUT0; output CLKOUT1; output CLKOUT2; output CLKOUT3; output CLKOUT4; output CLKOUT5; output LOCKED; input CLKFBIN; input CLKIN1; input PWRDWN; input RST; wire OPEN_DRDY; wire OPEN_PSDONE; wire OPEN_FBS; wire OPEN_INS; wire [15:0] OPEN_DO; PLLE2_ADV #( .BANDWIDTH(BANDWIDTH), .STARTUP_WAIT(STARTUP_WAIT), .CLKOUT1_DIVIDE(CLKOUT1_DIVIDE), .CLKOUT2_DIVIDE(CLKOUT2_DIVIDE), .CLKOUT3_DIVIDE(CLKOUT3_DIVIDE), .CLKOUT4_DIVIDE(CLKOUT4_DIVIDE), .CLKOUT5_DIVIDE(CLKOUT5_DIVIDE), .DIVCLK_DIVIDE(DIVCLK_DIVIDE), .CLKFBOUT_MULT(CLKFBOUT_MULT), .CLKFBOUT_PHASE(CLKFBOUT_PHASE), .CLKIN1_PERIOD(CLKIN1_PERIOD), .CLKIN2_PERIOD(10), .CLKOUT0_DIVIDE(CLKOUT0_DIVIDE), .CLKOUT0_DUTY_CYCLE(CLKOUT0_DUTY_CYCLE), .CLKOUT0_PHASE(CLKOUT0_PHASE), .CLKOUT1_DUTY_CYCLE(CLKOUT1_DUTY_CYCLE), .CLKOUT1_PHASE(CLKOUT1_PHASE), .CLKOUT2_DUTY_CYCLE(CLKOUT2_DUTY_CYCLE), .CLKOUT2_PHASE(CLKOUT2_PHASE), .CLKOUT3_DUTY_CYCLE(CLKOUT3_DUTY_CYCLE), .CLKOUT3_PHASE(CLKOUT3_PHASE), .CLKOUT4_DUTY_CYCLE(CLKOUT4_DUTY_CYCLE), .CLKOUT4_PHASE(CLKOUT4_PHASE), .CLKOUT5_DUTY_CYCLE(CLKOUT5_DUTY_CYCLE), .CLKOUT5_PHASE(CLKOUT5_PHASE), .REF_JITTER1(REF_JITTER1) ) plle2_adv_1 ( .CLKFBIN (CLKFBIN), .CLKFBOUT (CLKFBOUT), .CLKIN1 (CLKIN1), .CLKIN2 (1'b0), .CLKOUT0 (CLKOUT0), .CLKOUT1 (CLKOUT1), .CLKOUT2 (CLKOUT2), .CLKOUT3 (CLKOUT3), .CLKOUT4 (CLKOUT4), .CLKOUT5 (CLKOUT5), .DADDR (7'b0), .DCLK (1'b0), .DEN (1'b0), .DI (16'b0), .DO (OPEN_DO), .DRDY (OPEN_DRDY), .DWE (1'b0), .LOCKED (LOCKED), .CLKINSEL(1'b1), .PWRDWN(PWRDWN), .RST (RST) ); endmodule `endcelldefine
/* This file is part of JT12. JT12 program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. JT12 program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with JT12. If not, see <http://www.gnu.org/licenses/>. Author: Jose Tejada Gomez. Twitter: @topapate Version: 1.0 Date: 21-03-2019 Each channel can use the full range of the DAC as they do not get summed in the real chip. Operator data is summed up without adding extra bits. This is the case of real YM3438, which was used on Megadrive 2 models. / // YM2610 // ADPCM inputs // Full OP resolution // No PCM // 4 OP channels // ADPCM-A input is added for the time assigned to FM channel 0_10 (i.e. 3) module jt10_acc( input clk, input clk_en / synthesis direct_enable /, input signed [13:0] op_result, input [ 1:0] rl, input zero, input s1_enters, input s2_enters, input s3_enters, input s4_enters, input [2:0] cur_ch, input [1:0] cur_op, input [2:0] alg, input signed [15:0] adpcmA_l, input signed [15:0] adpcmA_r, input signed [15:0] adpcmB_l, input signed [15:0] adpcmB_r, // combined output output signed [15:0] left, output signed [15:0] right ); reg sum_en; always @() begin case ( alg ) default: sum_en = s4_enters; 3'd4: sum_en = s2_enters \| s4_enters; 3'd5,3'd6: sum_en = ~s1_enters; 3'd7: sum_en = 1'b1; endcase end wire left_en = rl[1]; wire right_en= rl[0]; wire signed [15:0] opext = { {2{op_result[13]}}, op_result }; reg signed [15:0] acc_input_l, acc_input_r; reg acc_en_l, acc_en_r; // YM2610 mode: // uses channels 0 and 4 for ADPCM data, throwing away FM data for those channels // reference: YM2610 Application Notes. always @(*) case( {cur_op,cur_ch} ) {2'd0,3'd0}: begin // ADPCM-A: acc_input_l = (adpcmA_l <<< 2) + (adpcmA_l <<< 1); acc_input_r = (adpcmA_r <<< 2) + (adpcmA_r <<< 1); `ifndef NOMIX acc_en_l = 1'b1; acc_en_r = 1'b1; `else acc_en_l = 1'b0; acc_en_r = 1'b0; `endif end {2'd0,3'd4}: begin // ADPCM-B: acc_input_l = adpcmB_l >>> 1; // Operator width is 14 bit, ADPCM-B is 16 bit acc_input_r = adpcmB_r >>> 1; // accumulator width per input channel is 14 bit `ifndef NOMIX acc_en_l = 1'b1; acc_en_r = 1'b1; `else acc_en_l = 1'b0; acc_en_r = 1'b0; `endif end default: begin // Note by Jose Tejada: // I don't think we should divide down the FM output // but someone was looking at the balance of the different // channels and made this arrangement // I suppose ADPCM-A would saturate if taken up a factor of 8 instead of 4 // I'll leave it as it is but I think it is worth revisiting this: acc_input_l = opext >>> 1; acc_input_r = opext >>> 1; acc_en_l = sum_en & left_en; acc_en_r = sum_en & right_en; end endcase // Continuous output jt12_single_acc #(.win(16),.wout(16)) u_left( .clk ( clk ), .clk_en ( clk_en ), .op_result ( acc_input_l ), .sum_en ( acc_en_l ), .zero ( zero ), .snd ( left ) ); jt12_single_acc #(.win(16),.wout(16)) u_right( .clk ( clk ), .clk_en ( clk_en ), .op_result ( acc_input_r ), .sum_en ( acc_en_r ), .zero ( zero ), .snd ( right ) ); `ifdef SIMULATION // Dump each channel independently // It dumps values in decimal, left and right integer f0,f1,f2,f4,f5,f6; reg signed [15:0] sum_l[7], sum_r[7]; initial begin f0=$fopen("fm0.raw","w"); f1=$fopen("fm1.raw","w"); f2=$fopen("fm2.raw","w"); f4=$fopen("fm4.raw","w"); f5=$fopen("fm5.raw","w"); f6=$fopen("fm6.raw","w"); end always @(posedge clk) begin if(cur_op==2'b0) begin sum_l[cur_ch] <= acc_en_l ? acc_input_l : 16'd0; sum_r[cur_ch] <= acc_en_r ? acc_input_r : 16'd0; end else begin sum_l[cur_ch] <= sum_l[cur_ch] + (acc_en_l ? acc_input_l : 16'd0); sum_r[cur_ch] <= sum_r[cur_ch] + (acc_en_r ? acc_input_r : 16'd0); end end always @(posedge zero) begin $fwrite(f0,"%d,%d\n", sum_l[0], sum_r[0]); $fwrite(f1,"%d,%d\n", sum_l[1], sum_r[1]); $fwrite(f2,"%d,%d\n", sum_l[2], sum_r[2]); $fwrite(f4,"%d,%d\n", sum_l[4], sum_r[4]); $fwrite(f5,"%d,%d\n", sum_l[5], sum_r[5]); $fwrite(f6,"%d,%d\n", sum_l[6], sum_r[6]); end `endif endmodule
// DESCRIPTION: Verilator: Verilog Test module // // This file ONLY is placed into the Public Domain, for any use, // without warranty, 2013 by Wilson Snyder. // Very simple test for interface pathclearing `ifdef VCS `define UNSUPPORTED_MOD_IN_GENS `endif `ifdef VERILATOR `define UNSUPPORTED_MOD_IN_GENS `endif module t (/AUTOARG/ // Inputs clk ); input clk; integer cyc=1; ifc #(1) itopa(); ifc #(2) itopb(); sub #(1) ca (.isub(itopa), .i_value(4)); sub #(2) cb (.isub(itopb), .i_value(5)); always @ (posedge clk) begin cyc <= cyc + 1; if (cyc==1) begin if (itopa.MODE != 1) $stop; if (itopb.MODE != 2) $stop; end if (cyc==20) begin if (itopa.get_value() != 4) $stop; if (itopb.get_value() != 5) $stop; $write("- All Finished -\n"); $finish; end end endmodule module sub #(parameter MODE = 0) ( ifc.out_modport isub, input integer i_value ); `ifdef UNSUPPORTED_MOD_IN_GENS always @* isub.value = i_value; `else generate if (MODE == 1) begin always @* isub.valuea = i_value; end else if (MODE == 2) begin always @* isub.valueb = i_value; end endgenerate `endif endmodule interface ifc; parameter MODE = 0; // Modports under generates not supported by all commercial simulators `ifdef UNSUPPORTED_MOD_IN_GENS integer value; modport out_modport (output value); function integer get_value(); return value; endfunction `else generate if (MODE == 0) begin integer valuea; modport out_modport (output valuea); function integer get_valuea(); return valuea; endfunction end else begin integer valueb; modport out_modport (output valueb); function integer get_valueb(); return valueb; endfunction end endgenerate `endif endinterface
//////////////////////////////////////////////////////////////////////////////// // Original Author: Schuyler Eldridge // Contact Point: Schuyler Eldridge ([email protected]) // t_sqrt_pipelined.v // Created: 4.2.2012 // Modified: 4.5.2012 // // Testbench for generic sqrt operation // // Copyright (C) 2012 Schuyler Eldridge, Boston University // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see <http://www.gnu.org/licenses/>. //////////////////////////////////////////////////////////////////////////////// `timescale 1ns / 1ps module t_sqrt_pipelined(); parameter INPUT_BITS = 4; localparam OUTPUT_BITS = INPUT_BITS / 2 + INPUT_BITS % 2; reg [INPUT_BITS-1:0] radicand; reg clk, start, reset_n; wire [OUTPUT_BITS-1:0] root; wire data_valid; // wire [7:0] root_good; sqrt_pipelined #( .INPUT_BITS(INPUT_BITS) ) sqrt_pipelined ( .clk(clk), .reset_n(reset_n), .start(start), .radicand(radicand), .data_valid(data_valid), .root(root) ); initial begin radicand = 16'bx; clk = 1'bx; start = 1'bx; reset_n = 1'bx;; #10 reset_n = 0; clk = 0; #50 reset_n = 1; radicand = 0; // #40 radicand = 81; start = 1; // #10 radicand = 16'bx; start = 0; #10000 $finish; end always #5 clk = ~clk; always begin #10 radicand = radicand + 1; start = 1; #10 start = 0; end // always begin // #80 start = 1; // #10 start = 0; // end endmodule
// Copyright (c) 2000 Stephen Williams ([email protected]) // // This source code is free software; you can redistribute it // and/or modify it in source code form under the terms of the GNU // General Public License as published by the Free Software // Foundation; either version 2 of the License, or (at your option) // any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA // // This tests DFF-like behavior. The clocked always block acts like a // DFF, and if the -Fsynth flag to ivl is used, actually generates an // LPM_FF device. module main () ; reg clk; reg D, Q; always #10 clk = ~clk; always @(posedge clk) Q = D; initial begin clk = 0; D = 0; @(negedge clk) if (Q !== 1'b0) begin $display("FAILED: %b !== %b", Q, D); $finish; end D = 1; @(negedge clk) if (Q !== 1'b1) begin $display("FAILED: %b !== %b", Q, D); $finish; end D = 'bx; @(negedge clk) if (Q !== 1'bx) begin $display("FAILED: %b !== %b", Q, D); $finish; end D = 'bz; @(negedge clk) if (Q !== 1'bz) begin $display("FAILED: %b !== %b", Q, D); $finish; end $display("PASSED"); $finish; end // initial begin endmodule

// (C) 2001-2016 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. // THIS FILE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL // THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING // FROM, OUT OF OR IN CONNECTION WITH THIS FILE OR THE USE OR OTHER DEALINGS // IN THIS FILE. /****************************************************************************** * * * This module is a FIFO with same clock for both reads and writes. * * * ******************************************************************************/ module altera_up_sync_fifo ( // Inputs clk, reset, write_en, write_data, read_en, // Bidirectionals // Outputs fifo_is_empty, fifo_is_full, words_used, read_data ); /***************************************************************************** * Parameter Declarations * *****************************************************************************/ parameter DW = 31; // Data width parameter DATA_DEPTH = 128; parameter AW = 6; // Address width /***************************************************************************** * Port Declarations * *****************************************************************************/ // Inputs input clk; input reset; input write_en; input [DW: 0] write_data; input read_en; // Bidirectionals // Outputs output fifo_is_empty; output fifo_is_full; output [AW: 0] words_used; output [DW: 0] read_data; /***************************************************************************** * Constant Declarations * *****************************************************************************/ /***************************************************************************** * Internal Wires and Registers Declarations * *****************************************************************************/ // Internal Wires // Internal Registers // State Machine Registers /***************************************************************************** * Finite State Machine(s) * *****************************************************************************/ /***************************************************************************** * Sequential Logic * *****************************************************************************/ /***************************************************************************** * Combinational Logic * *****************************************************************************/ /***************************************************************************** * Internal Modules * *****************************************************************************/ scfifo Sync_FIFO ( // Inputs .clock (clk), .sclr (reset), .data (write_data), .wrreq (write_en), .rdreq (read_en), // Bidirectionals // Outputs .empty (fifo_is_empty), .full (fifo_is_full), .usedw (words_used), .q (read_data), // Unused // synopsys translate_off .aclr (), .almost_empty (), .almost_full () // synopsys translate_on ); defparam Sync_FIFO.add_ram_output_register = "OFF", Sync_FIFO.intended_device_family = "Cyclone II", Sync_FIFO.lpm_numwords = DATA_DEPTH, Sync_FIFO.lpm_showahead = "ON", Sync_FIFO.lpm_type = "scfifo", Sync_FIFO.lpm_width = DW + 1, Sync_FIFO.lpm_widthu = AW + 1, Sync_FIFO.overflow_checking = "OFF", Sync_FIFO.underflow_checking = "OFF", Sync_FIFO.use_eab = "ON"; endmodule

// Copyright 1986-2014 Xilinx, Inc. All Rights Reserved. // -------------------------------------------------------------------------------- // Tool Version: Vivado v.2014.1 (lin64) Build 881834 Fri Apr 4 14:00:25 MDT 2014 // Date : Thu May 1 14:05:15 2014 // Host : macbook running 64-bit Arch Linux // Command : write_verilog -force -mode synth_stub /home/keith/Documents/VHDL-lib/top/lab_7/part_3/ip/bram/bram_stub.v // Design : bram // Purpose : Stub declaration of top-level module interface // Device : xc7z020clg484-1 // -------------------------------------------------------------------------------- // This empty module with port declaration file causes synthesis tools to infer a black box for IP. // The synthesis directives are for Synopsys Synplify support to prevent IO buffer insertion. // Please paste the declaration into a Verilog source file or add the file as an additional source. (* x_core_info = "blk_mem_gen_v8_2,Vivado 2014.1" *) module bram(clka, wea, addra, dina, clkb, addrb, doutb) /* synthesis syn_black_box black_box_pad_pin="clka,wea[0:0],addra[10:0],dina[15:0],clkb,addrb[10:0],doutb[15:0]" */; input clka; input [0:0]wea; input [10:0]addra; input [15:0]dina; input clkb; input [10:0]addrb; output [15:0]doutb; endmodule

/** * $Id: bus_clk_bridge.v 961 2014-01-21 11:40:39Z matej.oblak $ * * @brief Red Pitaya system bus clock crossing bridge. * * @Author Matej Oblak * * (c) Red Pitaya http://www.redpitaya.com * * This part of code is written in Verilog hardware description language (HDL). * Please visit http://en.wikipedia.org/wiki/Verilog * for more details on the language used herein. */ /** * GENERAL DESCRIPTION: * * Clock domain bridge for system bus. * * * /------\ * SYSTEM | | PROCESSING * BUS <-----> | SYNC | <-----> BUS * | | * \------/ * * * System bus runs on one clock domain while processing runs on separate. To * simplify transition of writing and reading data this bridge was created. * */ module bus_clk_bridge ( // system bus input sys_clk_i , //!< bus clock input sys_rstn_i , //!< bus reset - active low input [ 32-1: 0] sys_addr_i , //!< bus address input [ 32-1: 0] sys_wdata_i , //!< bus write data input [ 4-1: 0] sys_sel_i , //!< bus write byte select input sys_wen_i , //!< bus write enable input sys_ren_i , //!< bus read enable output [ 32-1: 0] sys_rdata_o , //!< bus read data output sys_err_o , //!< bus error indicator output sys_ack_o , //!< bus acknowledge signal // Destination bus input clk_i , //!< clock input rstn_i , //!< reset - active low output reg [ 32-1: 0] addr_o , //!< address output reg [ 32-1: 0] wdata_o , //!< write data output wen_o , //!< write enable output ren_o , //!< read enable input [ 32-1: 0] rdata_i , //!< read data input err_i , //!< error indicator input ack_i //!< acknowledge signal ); //--------------------------------------------------------------------------------- // Synchronize signals between clock domains reg sys_rd ; reg sys_wr ; reg sys_do ; reg [ 2-1: 0] sys_sync ; reg sys_done ; reg dst_do ; reg [ 2-1: 0] dst_sync ; reg dst_done ; always @(posedge sys_clk_i) begin if (sys_rstn_i == 1'b0) begin sys_rd <= 1'b0 ; sys_wr <= 1'b0 ; sys_do <= 1'b0 ; sys_sync <= 2'h0 ; sys_done <= 1'b0 ; end else begin if ((sys_do == sys_done) && (sys_wen_i || sys_ren_i)) begin addr_o <= sys_addr_i ; wdata_o <= sys_wdata_i ; sys_rd <= sys_ren_i ; sys_wr <= sys_wen_i ; sys_do <= !sys_do ; end sys_sync <= {sys_sync[0], dst_done}; sys_done <= sys_sync[1]; end end always @(posedge clk_i) begin if (rstn_i == 1'b0) begin dst_do <= 1'b0 ; dst_sync <= 2'h0 ; dst_done <= 1'b0 ; end else begin dst_sync <= {dst_sync[0], sys_do}; dst_do <= dst_sync[1]; if (ack_i && (dst_do != dst_done)) dst_done <= dst_do; end end assign ren_o = sys_rd && (dst_sync[1]^dst_do); assign wen_o = sys_wr && (dst_sync[1]^dst_do); assign sys_rdata_o = rdata_i ; assign sys_err_o = err_i ; assign sys_ack_o = sys_done ^ sys_sync[1] ; endmodule

//***************************************************************************** // (c) Copyright 2009 - 2013 Xilinx, Inc. All rights reserved. // // This file contains confidential and proprietary information // of Xilinx, Inc. and is protected under U.S. and // international copyright and other intellectual property // laws. // // DISCLAIMER // This disclaimer is not a license and does not grant any // rights to the materials distributed herewith. Except as // otherwise provided in a valid license issued to you by // Xilinx, and to the maximum extent permitted by applicable // law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // (2) Xilinx shall not be liable (whether in contract or tort, // including negligence, or under any other theory of // liability) for any loss or damage of any kind or nature // related to, arising under or in connection with these // materials, including for any direct, or any indirect, // special, incidental, or consequential loss or damage // (including loss of data, profits, goodwill, or any type of // loss or damage suffered as a result of any action brought // by a third party) even if such damage or loss was // reasonably foreseeable or Xilinx had been advised of the // possibility of the same. // // CRITICAL APPLICATIONS // Xilinx products are not designed or intended to be fail- // safe, or for use in any application requiring fail-safe // performance, such as life-support or safety devices or // systems, Class III medical devices, nuclear facilities, // applications related to the deployment of airbags, or any // other applications that could lead to death, personal // injury, or severe property or environmental damage // (individually and collectively, "Critical // Applications"). Customer assumes the sole risk and // liability of any use of Xilinx products in Critical // Applications, subject only to applicable laws and // regulations governing limitations on product liability. // // THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // PART OF THIS FILE AT ALL TIMES. // //***************************************************************************** // ____ ____ // / /\/ / // /___/ \ / Vendor: Xilinx // \ \ \/ Version: // \ \ Application: MIG // / / Filename: ddr_phy_dqs_found_cal.v // /___/ /\ Date Last Modified: $Date: 2011/06/02 08:35:08 $ // \ \ / \ Date Created: // \___\/\___\ // //Device: 7 Series //Design Name: DDR3 SDRAM //Purpose: // Read leveling calibration logic // NOTES: // 1. Phaser_In DQSFOUND calibration //Reference: //Revision History: //***************************************************************************** /****************************************************************************** **$Id: ddr_phy_dqs_found_cal.v,v 1.1 2011/06/02 08:35:08 mishra Exp $ **$Date: 2011/06/02 08:35:08 $ **$Author: **$Revision: **$Source: ******************************************************************************/ `timescale 1ps/1ps module mig_7series_v2_3_ddr_phy_dqs_found_cal_hr # ( parameter TCQ = 100, // clk->out delay (sim only) parameter nCK_PER_CLK = 2, // # of memory clocks per CLK parameter nCL = 5, // Read CAS latency parameter AL = "0", parameter nCWL = 5, // Write CAS latency parameter DRAM_TYPE = "DDR3", // Memory I/F type: "DDR3", "DDR2" parameter RANKS = 1, // # of memory ranks in the system parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH)) parameter DQS_WIDTH = 8, // # of DQS (strobe) parameter DRAM_WIDTH = 8, // # of DQ per DQS parameter REG_CTRL = "ON", // "ON" for registered DIMM parameter SIM_CAL_OPTION = "NONE", // Performs all calibration steps parameter NUM_DQSFOUND_CAL = 3, // Number of times to iterate parameter N_CTL_LANES = 3, // Number of control byte lanes parameter HIGHEST_LANE = 12, // Sum of byte lanes (Data + Ctrl) parameter HIGHEST_BANK = 3, // Sum of I/O Banks parameter BYTE_LANES_B0 = 4'b1111, parameter BYTE_LANES_B1 = 4'b0000, parameter BYTE_LANES_B2 = 4'b0000, parameter BYTE_LANES_B3 = 4'b0000, parameter BYTE_LANES_B4 = 4'b0000, parameter DATA_CTL_B0 = 4'hc, parameter DATA_CTL_B1 = 4'hf, parameter DATA_CTL_B2 = 4'hf, parameter DATA_CTL_B3 = 4'hf, parameter DATA_CTL_B4 = 4'hf ) ( input clk, input rst, input dqsfound_retry, // From phy_init input pi_dqs_found_start, input detect_pi_found_dqs, input prech_done, // DQSFOUND per Phaser_IN input [HIGHEST_LANE-1:0] pi_dqs_found_lanes, output reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal, // To phy_init output [5:0] rd_data_offset_0, output [5:0] rd_data_offset_1, output [5:0] rd_data_offset_2, output pi_dqs_found_rank_done, output pi_dqs_found_done, output reg pi_dqs_found_err, output [6*RANKS-1:0] rd_data_offset_ranks_0, output [6*RANKS-1:0] rd_data_offset_ranks_1, output [6*RANKS-1:0] rd_data_offset_ranks_2, output reg dqsfound_retry_done, output reg dqs_found_prech_req, //To MC output [6*RANKS-1:0] rd_data_offset_ranks_mc_0, output [6*RANKS-1:0] rd_data_offset_ranks_mc_1, output [6*RANKS-1:0] rd_data_offset_ranks_mc_2, input [8:0] po_counter_read_val, output rd_data_offset_cal_done, output fine_adjust_done, output [N_CTL_LANES-1:0] fine_adjust_lane_cnt, output reg ck_po_stg2_f_indec, output reg ck_po_stg2_f_en, output [255:0] dbg_dqs_found_cal ); // For non-zero AL values localparam nAL = (AL == "CL-1") ? nCL - 1 : 0; // Adding the register dimm latency to write latency localparam CWL_M = (REG_CTRL == "ON") ? nCWL + nAL + 1 : nCWL + nAL; // Added to reduce simulation time localparam LATENCY_FACTOR = 13; localparam NUM_READS = (SIM_CAL_OPTION == "NONE") ? 7 : 1; localparam [19:0] DATA_PRESENT = {(DATA_CTL_B4[3] & BYTE_LANES_B4[3]), (DATA_CTL_B4[2] & BYTE_LANES_B4[2]), (DATA_CTL_B4[1] & BYTE_LANES_B4[1]), (DATA_CTL_B4[0] & BYTE_LANES_B4[0]), (DATA_CTL_B3[3] & BYTE_LANES_B3[3]), (DATA_CTL_B3[2] & BYTE_LANES_B3[2]), (DATA_CTL_B3[1] & BYTE_LANES_B3[1]), (DATA_CTL_B3[0] & BYTE_LANES_B3[0]), (DATA_CTL_B2[3] & BYTE_LANES_B2[3]), (DATA_CTL_B2[2] & BYTE_LANES_B2[2]), (DATA_CTL_B2[1] & BYTE_LANES_B2[1]), (DATA_CTL_B2[0] & BYTE_LANES_B2[0]), (DATA_CTL_B1[3] & BYTE_LANES_B1[3]), (DATA_CTL_B1[2] & BYTE_LANES_B1[2]), (DATA_CTL_B1[1] & BYTE_LANES_B1[1]), (DATA_CTL_B1[0] & BYTE_LANES_B1[0]), (DATA_CTL_B0[3] & BYTE_LANES_B0[3]), (DATA_CTL_B0[2] & BYTE_LANES_B0[2]), (DATA_CTL_B0[1] & BYTE_LANES_B0[1]), (DATA_CTL_B0[0] & BYTE_LANES_B0[0])}; localparam FINE_ADJ_IDLE = 4'h0; localparam RST_POSTWAIT = 4'h1; localparam RST_POSTWAIT1 = 4'h2; localparam RST_WAIT = 4'h3; localparam FINE_ADJ_INIT = 4'h4; localparam FINE_INC = 4'h5; localparam FINE_INC_WAIT = 4'h6; localparam FINE_INC_PREWAIT = 4'h7; localparam DETECT_PREWAIT = 4'h8; localparam DETECT_DQSFOUND = 4'h9; localparam PRECH_WAIT = 4'hA; localparam FINE_DEC = 4'hB; localparam FINE_DEC_WAIT = 4'hC; localparam FINE_DEC_PREWAIT = 4'hD; localparam FINAL_WAIT = 4'hE; localparam FINE_ADJ_DONE = 4'hF; integer k,l,m,n,p,q,r,s; reg dqs_found_start_r; reg [6*HIGHEST_BANK-1:0] rd_byte_data_offset[0:RANKS-1]; reg rank_done_r; reg rank_done_r1; reg dqs_found_done_r; (* ASYNC_REG = "TRUE" *) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r1; (* ASYNC_REG = "TRUE" *) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r2; (* ASYNC_REG = "TRUE" *) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r3; reg init_dqsfound_done_r; reg init_dqsfound_done_r1; reg init_dqsfound_done_r2; reg init_dqsfound_done_r3; reg init_dqsfound_done_r4; reg init_dqsfound_done_r5; reg [1:0] rnk_cnt_r; reg [2:0 ] final_do_index[0:RANKS-1]; reg [5:0 ] final_do_max[0:RANKS-1]; reg [6*HIGHEST_BANK-1:0] final_data_offset[0:RANKS-1]; reg [6*HIGHEST_BANK-1:0] final_data_offset_mc[0:RANKS-1]; reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal_r; reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal_r1; reg [10*HIGHEST_BANK-1:0] retry_cnt; reg dqsfound_retry_r1; wire [4*HIGHEST_BANK-1:0] pi_dqs_found_lanes_int; reg [HIGHEST_BANK-1:0] pi_dqs_found_all_bank; reg [HIGHEST_BANK-1:0] pi_dqs_found_all_bank_r; reg [HIGHEST_BANK-1:0] pi_dqs_found_any_bank; reg [HIGHEST_BANK-1:0] pi_dqs_found_any_bank_r; reg [HIGHEST_BANK-1:0] pi_dqs_found_err_r; // CK/Control byte lanes fine adjust stage reg fine_adjust; reg [N_CTL_LANES-1:0] ctl_lane_cnt; reg [3:0] fine_adj_state_r; reg fine_adjust_done_r; reg rst_dqs_find; reg rst_dqs_find_r1; reg rst_dqs_find_r2; reg [5:0] init_dec_cnt; reg [5:0] dec_cnt; reg [5:0] inc_cnt; reg final_dec_done; reg init_dec_done; reg first_fail_detect; reg second_fail_detect; reg [5:0] first_fail_taps; reg [5:0] second_fail_taps; reg [5:0] stable_pass_cnt; reg [3:0] detect_rd_cnt; //*************************************************************************** // Debug signals // //*************************************************************************** assign dbg_dqs_found_cal[5:0] = first_fail_taps; assign dbg_dqs_found_cal[11:6] = second_fail_taps; assign dbg_dqs_found_cal[12] = first_fail_detect; assign dbg_dqs_found_cal[13] = second_fail_detect; assign dbg_dqs_found_cal[14] = fine_adjust_done_r; assign pi_dqs_found_rank_done = rank_done_r; assign pi_dqs_found_done = dqs_found_done_r; generate genvar rnk_cnt; if (HIGHEST_BANK == 3) begin // Three Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][11:6]; assign rd_data_offset_ranks_2[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][17:12]; assign rd_data_offset_ranks_mc_0[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][11:6]; assign rd_data_offset_ranks_mc_2[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][17:12]; end end else if (HIGHEST_BANK == 2) begin // Two Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][11:6]; assign rd_data_offset_ranks_2[6*rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_0[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][11:6]; assign rd_data_offset_ranks_mc_2[6*rnk_cnt+:6] = 'd0; end end else begin // Single Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6*rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_2[6*rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_0[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6*rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_2[6*rnk_cnt+:6] = 'd0; end end endgenerate // final_data_offset is used during write calibration and during // normal operation. One rd_data_offset value per rank for entire // interface generate if (HIGHEST_BANK == 3) begin // Three I/O Bank interface assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][6+:6] : final_data_offset[rnk_cnt_r][6+:6]; assign rd_data_offset_2 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][12+:6] : final_data_offset[rnk_cnt_r][12+:6]; end else if (HIGHEST_BANK == 2) begin // Two I/O Bank interface assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][6+:6] : final_data_offset[rnk_cnt_r][6+:6]; assign rd_data_offset_2 = 'd0; end else begin assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = 'd0; assign rd_data_offset_2 = 'd0; end endgenerate assign rd_data_offset_cal_done = init_dqsfound_done_r; assign fine_adjust_lane_cnt = ctl_lane_cnt; //************************************************************************** // DQSFOUND all and any generation // pi_dqs_found_all_bank[x] asserted when all Phaser_INs in Bankx are // asserted // pi_dqs_found_any_bank[x] asserted when at least one Phaser_IN in Bankx // is asserted //************************************************************************** generate if ((HIGHEST_LANE == 4) || (HIGHEST_LANE == 8) || (HIGHEST_LANE == 12)) assign pi_dqs_found_lanes_int = pi_dqs_found_lanes_r3; else if ((HIGHEST_LANE == 7) || (HIGHEST_LANE == 11)) assign pi_dqs_found_lanes_int = {1'b0, pi_dqs_found_lanes_r3}; else if ((HIGHEST_LANE == 6) || (HIGHEST_LANE == 10)) assign pi_dqs_found_lanes_int = {2'b00, pi_dqs_found_lanes_r3}; else if ((HIGHEST_LANE == 5) || (HIGHEST_LANE == 9)) assign pi_dqs_found_lanes_int = {3'b000, pi_dqs_found_lanes_r3}; endgenerate always @(posedge clk) begin if (rst) begin for (k = 0; k < HIGHEST_BANK; k = k + 1) begin: rst_pi_dqs_found pi_dqs_found_all_bank[k] <= #TCQ 'b0; pi_dqs_found_any_bank[k] <= #TCQ 'b0; end end else if (pi_dqs_found_start) begin for (p = 0; p < HIGHEST_BANK; p = p +1) begin: assign_pi_dqs_found pi_dqs_found_all_bank[p] <= #TCQ (!DATA_PRESENT[4*p+0] | pi_dqs_found_lanes_int[4*p+0]) & (!DATA_PRESENT[4*p+1] | pi_dqs_found_lanes_int[4*p+1]) & (!DATA_PRESENT[4*p+2] | pi_dqs_found_lanes_int[4*p+2]) & (!DATA_PRESENT[4*p+3] | pi_dqs_found_lanes_int[4*p+3]); pi_dqs_found_any_bank[p] <= #TCQ (DATA_PRESENT[4*p+0] & pi_dqs_found_lanes_int[4*p+0]) | (DATA_PRESENT[4*p+1] & pi_dqs_found_lanes_int[4*p+1]) | (DATA_PRESENT[4*p+2] & pi_dqs_found_lanes_int[4*p+2]) | (DATA_PRESENT[4*p+3] & pi_dqs_found_lanes_int[4*p+3]); end end end always @(posedge clk) begin pi_dqs_found_all_bank_r <= #TCQ pi_dqs_found_all_bank; pi_dqs_found_any_bank_r <= #TCQ pi_dqs_found_any_bank; end //***************************************************************************** // Counter to increase number of 4 back-to-back reads per rd_data_offset and // per CK/A/C tap value //***************************************************************************** always @(posedge clk) begin if (rst || (detect_rd_cnt == 'd0)) detect_rd_cnt <= #TCQ NUM_READS; else if (detect_pi_found_dqs && (detect_rd_cnt > 'd0)) detect_rd_cnt <= #TCQ detect_rd_cnt - 1; end //************************************************************************** // Adjust Phaser_Out stage 2 taps on CK/Address/Command/Controls // //************************************************************************** assign fine_adjust_done = fine_adjust_done_r; always @(posedge clk) begin rst_dqs_find_r1 <= #TCQ rst_dqs_find; rst_dqs_find_r2 <= #TCQ rst_dqs_find_r1; end always @(posedge clk) begin if(rst)begin fine_adjust <= #TCQ 1'b0; ctl_lane_cnt <= #TCQ 'd0; fine_adj_state_r <= #TCQ FINE_ADJ_IDLE; fine_adjust_done_r <= #TCQ 1'b0; ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; rst_dqs_find <= #TCQ 1'b0; init_dec_cnt <= #TCQ 'd31; dec_cnt <= #TCQ 'd0; inc_cnt <= #TCQ 'd0; init_dec_done <= #TCQ 1'b0; final_dec_done <= #TCQ 1'b0; first_fail_detect <= #TCQ 1'b0; second_fail_detect <= #TCQ 1'b0; first_fail_taps <= #TCQ 'd0; second_fail_taps <= #TCQ 'd0; stable_pass_cnt <= #TCQ 'd0; dqs_found_prech_req<= #TCQ 1'b0; end else begin case (fine_adj_state_r) FINE_ADJ_IDLE: begin if (init_dqsfound_done_r5) begin if (SIM_CAL_OPTION == "FAST_CAL") begin fine_adjust <= #TCQ 1'b1; fine_adj_state_r <= #TCQ FINE_ADJ_DONE; rst_dqs_find <= #TCQ 1'b0; end else begin fine_adjust <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; rst_dqs_find <= #TCQ 1'b1; end end end RST_WAIT: begin if (~(|pi_dqs_found_any_bank) && rst_dqs_find_r2) begin rst_dqs_find <= #TCQ 1'b0; if (|init_dec_cnt) fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; else if (final_dec_done) fine_adj_state_r <= #TCQ FINE_ADJ_DONE; else fine_adj_state_r <= #TCQ RST_POSTWAIT; end end RST_POSTWAIT: begin fine_adj_state_r <= #TCQ RST_POSTWAIT1; end RST_POSTWAIT1: begin fine_adj_state_r <= #TCQ FINE_ADJ_INIT; end FINE_ADJ_INIT: begin //if (detect_pi_found_dqs && (inc_cnt < 'd63)) fine_adj_state_r <= #TCQ FINE_INC; end FINE_INC: begin fine_adj_state_r <= #TCQ FINE_INC_WAIT; ck_po_stg2_f_indec <= #TCQ 1'b1; ck_po_stg2_f_en <= #TCQ 1'b1; if (ctl_lane_cnt == N_CTL_LANES-1) inc_cnt <= #TCQ inc_cnt + 1; end FINE_INC_WAIT: begin ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; if (ctl_lane_cnt != N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ ctl_lane_cnt + 1; fine_adj_state_r <= #TCQ FINE_INC_PREWAIT; end else if (ctl_lane_cnt == N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ 'd0; fine_adj_state_r <= #TCQ DETECT_PREWAIT; end end FINE_INC_PREWAIT: begin fine_adj_state_r <= #TCQ FINE_INC; end DETECT_PREWAIT: begin if (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) fine_adj_state_r <= #TCQ DETECT_DQSFOUND; else fine_adj_state_r <= #TCQ DETECT_PREWAIT; end DETECT_DQSFOUND: begin if (detect_pi_found_dqs && ~(&pi_dqs_found_all_bank)) begin stable_pass_cnt <= #TCQ 'd0; if (~first_fail_detect && (inc_cnt == 'd63)) begin // First failing tap detected at 63 taps // then decrement to 31 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ 'd32; end else if (~first_fail_detect && (inc_cnt > 'd30) && (stable_pass_cnt > 'd29)) begin // First failing tap detected at greater than 30 taps // then stop looking for second edge and decrement first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ (inc_cnt>>1) + 1; end else if (~first_fail_detect || (first_fail_detect && (stable_pass_cnt < 'd30) && (inc_cnt <= 'd32))) begin // First failing tap detected, continue incrementing // until either second failing tap detected or 63 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; rst_dqs_find <= #TCQ 1'b1; if ((inc_cnt == 'd12) || (inc_cnt == 'd24)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else fine_adj_state_r <= #TCQ RST_WAIT; end else if (first_fail_detect && (inc_cnt > 'd32) && (inc_cnt < 'd63) && (stable_pass_cnt < 'd30)) begin // Consecutive 30 taps of passing region was not found // continue incrementing first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; rst_dqs_find <= #TCQ 1'b1; if ((inc_cnt == 'd36) || (inc_cnt == 'd48) || (inc_cnt == 'd60)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else fine_adj_state_r <= #TCQ RST_WAIT; end else if (first_fail_detect && (inc_cnt == 'd63)) begin if (stable_pass_cnt < 'd30) begin // Consecutive 30 taps of passing region was not found // from tap 0 to 63 so decrement back to 31 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ 'd32; end else begin // Consecutive 30 taps of passing region was found // between first_fail_taps and 63 fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); end end else begin // Second failing tap detected, decrement to center of // failing taps second_fail_detect <= #TCQ 1'b1; second_fail_taps <= #TCQ inc_cnt; dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); fine_adj_state_r <= #TCQ FINE_DEC; end end else if (detect_pi_found_dqs && (&pi_dqs_found_all_bank)) begin stable_pass_cnt <= #TCQ stable_pass_cnt + 1; if ((inc_cnt == 'd12) || (inc_cnt == 'd24) || (inc_cnt == 'd36) || (inc_cnt == 'd48) || (inc_cnt == 'd60)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else if (inc_cnt < 'd63) begin rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end else begin fine_adj_state_r <= #TCQ FINE_DEC; if (~first_fail_detect || (first_fail_taps > 'd33)) // No failing taps detected, decrement by 31 dec_cnt <= #TCQ 'd32; //else if (first_fail_detect && (stable_pass_cnt > 'd28)) // // First failing tap detected between 0 and 34 // // decrement midpoint between 63 and failing tap // dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); else // First failing tap detected // decrement to midpoint between 63 and failing tap dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); end end end PRECH_WAIT: begin if (prech_done) begin dqs_found_prech_req <= #TCQ 1'b0; rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end end FINE_DEC: begin fine_adj_state_r <= #TCQ FINE_DEC_WAIT; ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b1; if ((ctl_lane_cnt == N_CTL_LANES-1) && (init_dec_cnt > 'd0)) init_dec_cnt <= #TCQ init_dec_cnt - 1; else if ((ctl_lane_cnt == N_CTL_LANES-1) && (dec_cnt > 'd0)) dec_cnt <= #TCQ dec_cnt - 1; end FINE_DEC_WAIT: begin ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; if (ctl_lane_cnt != N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ ctl_lane_cnt + 1; fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; end else if (ctl_lane_cnt == N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ 'd0; if ((dec_cnt > 'd0) || (init_dec_cnt > 'd0)) fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; else begin fine_adj_state_r <= #TCQ FINAL_WAIT; if ((init_dec_cnt == 'd0) && ~init_dec_done) init_dec_done <= #TCQ 1'b1; else final_dec_done <= #TCQ 1'b1; end end end FINE_DEC_PREWAIT: begin fine_adj_state_r <= #TCQ FINE_DEC; end FINAL_WAIT: begin rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end FINE_ADJ_DONE: begin if (&pi_dqs_found_all_bank) begin fine_adjust_done_r <= #TCQ 1'b1; rst_dqs_find <= #TCQ 1'b0; fine_adj_state_r <= #TCQ FINE_ADJ_DONE; end end endcase end end //***************************************************************************** always@(posedge clk) dqs_found_start_r <= #TCQ pi_dqs_found_start; always @(posedge clk) begin if (rst) rnk_cnt_r <= #TCQ 2'b00; else if (init_dqsfound_done_r) rnk_cnt_r <= #TCQ rnk_cnt_r; else if (rank_done_r) rnk_cnt_r <= #TCQ rnk_cnt_r + 1; end //***************************************************************** // Read data_offset calibration done signal //***************************************************************** always @(posedge clk) begin if (rst || (|pi_rst_stg1_cal_r)) init_dqsfound_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank) begin if (rnk_cnt_r == RANKS-1) init_dqsfound_done_r <= #TCQ 1'b1; else init_dqsfound_done_r <= #TCQ 1'b0; end end always @(posedge clk) begin if (rst || (init_dqsfound_done_r && (rnk_cnt_r == RANKS-1))) rank_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank && ~(&pi_dqs_found_all_bank_r)) rank_done_r <= #TCQ 1'b1; else rank_done_r <= #TCQ 1'b0; end always @(posedge clk) begin pi_dqs_found_lanes_r1 <= #TCQ pi_dqs_found_lanes; pi_dqs_found_lanes_r2 <= #TCQ pi_dqs_found_lanes_r1; pi_dqs_found_lanes_r3 <= #TCQ pi_dqs_found_lanes_r2; init_dqsfound_done_r1 <= #TCQ init_dqsfound_done_r; init_dqsfound_done_r2 <= #TCQ init_dqsfound_done_r1; init_dqsfound_done_r3 <= #TCQ init_dqsfound_done_r2; init_dqsfound_done_r4 <= #TCQ init_dqsfound_done_r3; init_dqsfound_done_r5 <= #TCQ init_dqsfound_done_r4; rank_done_r1 <= #TCQ rank_done_r; dqsfound_retry_r1 <= #TCQ dqsfound_retry; end always @(posedge clk) begin if (rst) dqs_found_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank && (rnk_cnt_r == RANKS-1) && init_dqsfound_done_r1 && (fine_adj_state_r == FINE_ADJ_DONE)) dqs_found_done_r <= #TCQ 1'b1; else dqs_found_done_r <= #TCQ 1'b0; end generate if (HIGHEST_BANK == 3) begin // Three I/O Bank interface // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[0] || fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[0]) || (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) || (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[1] || fine_adjust) pi_rst_stg1_cal_r[1] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[1]) || (pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) || (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[2] || fine_adjust) pi_rst_stg1_cal_r[2] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[2]) || (pi_dqs_found_any_bank_r[2] && ~pi_dqs_found_all_bank[2]) || (rd_byte_data_offset[rnk_cnt_r][12+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[2] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[2]) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[2] && ~pi_dqs_found_all_bank[2]) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b0; end //***************************************************************************** // Retry counter to track number of DQSFOUND retries //***************************************************************************** always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[10+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[1]) retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10] + 1; else retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10]; end always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[20+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][12+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[2]) retry_cnt[20+:10] <= #TCQ retry_cnt[20+:10] + 1; else retry_cnt[20+:10] <= #TCQ retry_cnt[20+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[1] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[1] && (retry_cnt[10+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[2] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[2] && (retry_cnt[20+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][12+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[2] <= #TCQ 1'b1; end // Read data offset value for all DQS in a Bank always @(posedge clk) begin if (rst) begin for (q = 0; q < RANKS; q = q + 1) begin: three_bank0_rst_loop rd_byte_data_offset[q][0+:6] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][0+:6] + 1; end always @(posedge clk) begin if (rst) begin for (r = 0; r < RANKS; r = r + 1) begin: three_bank1_rst_loop rd_byte_data_offset[r][6+:6] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[1] && //(rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][6+:6] + 1; end always @(posedge clk) begin if (rst) begin for (s = 0; s < RANKS; s = s + 1) begin: three_bank2_rst_loop rd_byte_data_offset[s][12+:6] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r][12+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r][12+:6] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[2] && //(rd_byte_data_offset[rnk_cnt_r][12+:6] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][12+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][12+:6] + 1; end //***************************************************************************** // Two I/O Bank Interface //***************************************************************************** end else if (HIGHEST_BANK == 2) begin // Two I/O Bank interface // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[0] || fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[0]) || (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) || (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[1] || fine_adjust) pi_rst_stg1_cal_r[1] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[1]) || (pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) || (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; end //***************************************************************************** // Retry counter to track number of DQSFOUND retries //***************************************************************************** always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[10+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[1]) retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10] + 1; else retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[1] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[1] && (retry_cnt[10+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[1] <= #TCQ 1'b1; end // Read data offset value for all DQS in a Bank always @(posedge clk) begin if (rst) begin for (q = 0; q < RANKS; q = q + 1) begin: two_bank0_rst_loop rd_byte_data_offset[q][0+:6] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][0+:6] + 1; end always @(posedge clk) begin if (rst) begin for (r = 0; r < RANKS; r = r + 1) begin: two_bank1_rst_loop rd_byte_data_offset[r][6+:6] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[1] && //(rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][6+:6] + 1; end //***************************************************************************** // One I/O Bank Interface //***************************************************************************** end else begin // One I/O Bank Interface // Read data offset value for all DQS in Bank0 always @(posedge clk) begin if (rst) begin for (l = 0; l < RANKS; l = l + 1) begin: bank_rst_loop rd_byte_data_offset[l] <= #TCQ nCL + nAL - 2; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r] > (nCL + nAL + LATENCY_FACTOR - 1))) rd_byte_data_offset[rnk_cnt_r] <= #TCQ nCL + nAL - 2; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r] < (nCL + nAL + LATENCY_FACTOR)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r] <= #TCQ rd_byte_data_offset[rnk_cnt_r] + 1; end // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[0] || fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[0]) || (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) || (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end //***************************************************************************** // Retry counter to track number of DQSFOUND retries //***************************************************************************** always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted even with 3 dqfound retries always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL + LATENCY_FACTOR - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end end endgenerate always @(posedge clk) begin if (rst) pi_rst_stg1_cal <= #TCQ {HIGHEST_BANK{1'b0}}; else if (rst_dqs_find) pi_rst_stg1_cal <= #TCQ {HIGHEST_BANK{1'b1}}; else pi_rst_stg1_cal <= #TCQ pi_rst_stg1_cal_r; end // Final read data offset value to be used during write calibration and // normal operation generate genvar i; genvar j; for (i = 0; i < RANKS; i = i + 1) begin: rank_final_loop reg [5:0] final_do_cand [RANKS-1:0]; // combinatorially select the candidate offset for the bank // indexed by final_do_index if (HIGHEST_BANK == 3) begin always @(*) begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = final_data_offset[i][11:6]; 3'b010: final_do_cand[i] = final_data_offset[i][17:12]; default: final_do_cand[i] = 'd0; endcase end end else if (HIGHEST_BANK == 2) begin always @(*) begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = final_data_offset[i][11:6]; 3'b010: final_do_cand[i] = 'd0; default: final_do_cand[i] = 'd0; endcase end end else begin always @(*) begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = 'd0; 3'b010: final_do_cand[i] = 'd0; default: final_do_cand[i] = 'd0; endcase end end always @(posedge clk) begin if (rst) final_do_max[i] <= #TCQ 0; else begin final_do_max[i] <= #TCQ final_do_max[i]; // default case (final_do_index[i]) 3'b000: if ( | DATA_PRESENT[3:0]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; 3'b001: if ( | DATA_PRESENT[7:4]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; 3'b010: if ( | DATA_PRESENT[11:8]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; default: final_do_max[i] <= #TCQ final_do_max[i]; endcase end end always @(posedge clk) if (rst) begin final_do_index[i] <= #TCQ 0; end else begin final_do_index[i] <= #TCQ final_do_index[i] + 1; end for (j = 0; j < HIGHEST_BANK; j = j + 1) begin: bank_final_loop always @(posedge clk) begin if (rst) begin final_data_offset[i][6*j+:6] <= #TCQ 'b0; end else begin //if (dqsfound_retry[j]) // final_data_offset[i][6*j+:6] <= #TCQ rd_byte_data_offset[i][6*j+:6]; //else if (init_dqsfound_done_r && ~init_dqsfound_done_r1) begin if ( DATA_PRESENT [ j*4+:4] != 0) begin // has a data lane final_data_offset[i][6*j+:6] <= #TCQ rd_byte_data_offset[i][6*j+:6]; if (CWL_M % 2) // odd latency CAS slot 1 final_data_offset_mc[i][6*j+:6] <= #TCQ rd_byte_data_offset[i][6*j+:6] - 1; else // even latency CAS slot 0 final_data_offset_mc[i][6*j+:6] <= #TCQ rd_byte_data_offset[i][6*j+:6]; end end else if (init_dqsfound_done_r5 ) begin if ( DATA_PRESENT [ j*4+:4] == 0) begin // all control lanes final_data_offset[i][6*j+:6] <= #TCQ final_do_max[i]; final_data_offset_mc[i][6*j+:6] <= #TCQ final_do_max[i]; end end end end end end endgenerate // Error generation in case pi_found_dqs signal from Phaser_IN // is not asserted when a common rddata_offset value is used always @(posedge clk) begin pi_dqs_found_err <= #TCQ |pi_dqs_found_err_r; end endmodule

`include "hi_simulate.v" /* pck0 - input main 24Mhz clock (PLL / 4) [7:0] adc_d - input data from A/D converter mod_type - modulation type pwr_lo - output to coil drivers (ssp_clk / 8) adc_clk - output A/D clock signal ssp_frame - output SSS frame indicator (goes high while the 8 bits are shifted) ssp_din - output SSP data to ARM (shifts 8 bit A/D value serially to ARM MSB first) ssp_clk - output SSP clock signal ck_1356meg - input unused ck_1356megb - input unused ssp_dout - input unused cross_hi - input unused cross_lo - input unused pwr_hi - output unused, tied low pwr_oe1 - output unused, undefined pwr_oe2 - output unused, undefined pwr_oe3 - output unused, undefined pwr_oe4 - output unused, undefined dbg - output alias for adc_clk */ module testbed_hi_simulate; reg pck0; reg [7:0] adc_d; reg mod_type; wire pwr_lo; wire adc_clk; reg ck_1356meg; reg ck_1356megb; wire ssp_frame; wire ssp_din; wire ssp_clk; reg ssp_dout; wire pwr_hi; wire pwr_oe1; wire pwr_oe2; wire pwr_oe3; wire pwr_oe4; wire cross_lo; wire cross_hi; wire dbg; hi_simulate #(5,200) dut( .pck0(pck0), .ck_1356meg(ck_1356meg), .ck_1356megb(ck_1356megb), .pwr_lo(pwr_lo), .pwr_hi(pwr_hi), .pwr_oe1(pwr_oe1), .pwr_oe2(pwr_oe2), .pwr_oe3(pwr_oe3), .pwr_oe4(pwr_oe4), .adc_d(adc_d), .adc_clk(adc_clk), .ssp_frame(ssp_frame), .ssp_din(ssp_din), .ssp_dout(ssp_dout), .ssp_clk(ssp_clk), .cross_hi(cross_hi), .cross_lo(cross_lo), .dbg(dbg), .mod_type(mod_type) ); integer idx, i; // main clock always #5 begin ck_1356megb = !ck_1356megb; ck_1356meg = ck_1356megb; end always begin @(negedge adc_clk) ; adc_d = $random; end //crank DUT task crank_dut; begin @(negedge ssp_clk) ; ssp_dout = $random; end endtask initial begin // init inputs ck_1356megb = 0; // random values adc_d = 0; ssp_dout=1; // shallow modulation off mod_type=0; for (i = 0 ; i < 16 ; i = i + 1) begin crank_dut; end // shallow modulation on mod_type=1; for (i = 0 ; i < 16 ; i = i + 1) begin crank_dut; end $finish; end endmodule // main

module shift_in ( data_in, wr_en, shift_en, data_out, clk, rst ); parameter WIDTH=1; input [(64*WIDTH)-1:0] data_in; input wr_en; input shift_en; output [(16*WIDTH)-1:0] data_out; input clk; input rst; wire [(64*WIDTH)-1:0] reg_in; wire [(64*WIDTH)-1:0] reg_out; reg line_wr_en; reg s_or_w_; always @ (shift_en or wr_en) begin casex({shift_en,wr_en}) 2'b00: begin line_wr_en <= 1'b0; s_or_w_ <= 1'bx; end 2'b01: begin line_wr_en <= 1'b1; s_or_w_ <= 1'b0; end 2'b10: begin line_wr_en <= 1'b1; s_or_w_ <= 1'b1; end default: begin line_wr_en <= 1'bx; s_or_w_ <= 1'bx; end endcase end register #(WIDTH*16) reg_line[3:0](.out(reg_out), .in(reg_in), .wr_en(line_wr_en), .clk(clk), .rst(rst)); mux_2_to_1 #(WIDTH*16) line3_mux(.out(reg_in[(WIDTH*64)-1:(WIDTH*48)]), .in({{WIDTH*16{1'bx}},data_in[(WIDTH*64)-1:(WIDTH*48)]}), .select(s_or_w_)); mux_2_to_1 #(WIDTH*16) line2_mux(.out(reg_in[(WIDTH*48)-1:(WIDTH*32)]), .in({reg_out[(WIDTH*64)-1:WIDTH*48],data_in[(WIDTH*48)-1:(WIDTH*32)]}), .select(s_or_w_)); mux_2_to_1 #(WIDTH*16) line1_mux(.out(reg_in[(WIDTH*32)-1:(WIDTH*16)]), .in({reg_out[(WIDTH*48)-1:WIDTH*32],data_in[(WIDTH*32)-1:(WIDTH*16)]}), .select(s_or_w_)); mux_2_to_1 #(WIDTH*16) line0_mux(.out(reg_in[(WIDTH*16)-1:0]), .in({reg_out[(WIDTH*32)-1:WIDTH*16],data_in[(WIDTH*16)-1:0]}), .select(s_or_w_)); assign data_out = reg_out[(WIDTH*16)-1:0]; endmodule

// DESCRIPTION: Verilator: Verilog Test module // // This file ONLY is placed under the Creative Commons Public Domain, for // any use, without warranty, 2011 by Wilson Snyder. // SPDX-License-Identifier: CC0-1.0 module t_embed1_wrap (/*AUTOARG*/ // Outputs bit_out, vec_out, wide_out, did_init_out, // Inputs clk, bit_in, vec_in, wide_in, is_ref ); /*AUTOINOUTMODULE("t_embed1_child")*/ // Beginning of automatic in/out/inouts (from specific module) output bit bit_out; output bit [30:0] vec_out; output bit [123:0] wide_out; output bit did_init_out; input clk; input bit_in; input [30:0] vec_in; input [123:0] wide_in; input is_ref; // End of automatics `ifdef verilator // Import $t_embed_child__initial etc as a DPI function `endif //TODO would like __'s as in {PREFIX}__initial but presently illegal for users to do this import "DPI-C" context function void t_embed_child_initial(); import "DPI-C" context function void t_embed_child_final(); import "DPI-C" context function void t_embed_child_eval(); import "DPI-C" context function void t_embed_child_io_eval ( //TODO we support bit, but not logic input bit clk, input bit bit_in, input bit [30:0] vec_in, input bit [123:0] wide_in, input bit is_ref, output bit bit_out, output bit [30:0] vec_out, output bit [123:0] wide_out, output bit did_init_out); initial begin // Load all values t_embed_child_initial(); end // Only if system verilog, and if a "final" block in the code final begin t_embed_child_final(); end bit _temp_bit_out; bit _temp_did_init_out; bit [30:0] _temp_vec_out; bit [123:0] _temp_wide_out; always @* begin t_embed_child_io_eval( clk, bit_in, vec_in, wide_in, is_ref, _temp_bit_out, _temp_vec_out, _temp_wide_out, _temp_did_init_out ); // TODO might eliminate these temporaries bit_out = _temp_bit_out; did_init_out = _temp_did_init_out; end // Send all variables every cycle, // or have a sensitivity routine for each? // How to make sure we call eval at end of variable changes? // #0 (though not verilator compatible!) // TODO for now, we know what changes when always @ (posedge clk) begin vec_out <= _temp_vec_out; wide_out <= _temp_wide_out; end endmodule

///////////////////////////////////////////////////////////////////// //// //// //// Non-restoring unsigned divider //// //// //// //// Author: Richard Herveille //// //// [email protected] //// //// www.asics.ws //// //// //// ///////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2002 Richard Herveille //// //// [email protected] //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer.//// //// //// //// THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY //// //// EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED //// //// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS //// //// FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL THE AUTHOR //// //// OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, //// //// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES //// //// (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE //// //// GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR //// //// BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF //// //// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT //// //// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT //// //// OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE //// //// POSSIBILITY OF SUCH DAMAGE. //// //// //// ///////////////////////////////////////////////////////////////////// // CVS Log // // $Id: div_uu.v,v 1.3 2003-09-17 13:08:53 rherveille Exp $ // // $Date: 2003-09-17 13:08:53 $ // $Revision: 1.3 $ // $Author: rherveille $ // $Locker: $ // $State: Exp $ // // Change History: // $Log: not supported by cvs2svn $ // Revision 1.2 2002/10/31 13:54:58 rherveille // Fixed a bug in the remainder output of div_su.v // // Revision 1.1.1.1 2002/10/29 20:29:10 rherveille // // // //synopsys translate_off `include "timescale.v" //synopsys translate_on module div_uu(clk, ena, z, d, q, s, div0, ovf); // // parameters // parameter z_width = 16; parameter d_width = z_width /2; // // inputs & outputs // input clk; // system clock input ena; // clock enable input [z_width -1:0] z; // divident input [d_width -1:0] d; // divisor output [d_width -1:0] q; // quotient output [d_width -1:0] s; // remainder output div0; output ovf; reg [d_width-1:0] q; reg [d_width-1:0] s; reg div0; reg ovf; // // functions // function [z_width:0] gen_s; input [z_width:0] si; input [z_width:0] di; begin if(si[z_width]) gen_s = {si[z_width-1:0], 1'b0} + di; else gen_s = {si[z_width-1:0], 1'b0} - di; end endfunction function [d_width-1:0] gen_q; input [d_width-1:0] qi; input [z_width:0] si; begin gen_q = {qi[d_width-2:0], ~si[z_width]}; end endfunction function [d_width-1:0] assign_s; input [z_width:0] si; input [z_width:0] di; reg [z_width:0] tmp; begin if(si[z_width]) tmp = si + di; else tmp = si; assign_s = tmp[z_width-1:z_width-d_width]; end endfunction // // variables // reg [d_width-1:0] q_pipe [d_width-1:0]; reg [z_width:0] s_pipe [d_width:0]; reg [z_width:0] d_pipe [d_width:0]; reg [d_width:0] div0_pipe, ovf_pipe; // // perform parameter checks // // synopsys translate_off initial begin if(d_width !== z_width / 2) $display("div.v parameter error (d_width != z_width/2)."); end // synopsys translate_on integer n0, n1, n2, n3; // generate divisor (d) pipe always @(d) d_pipe[0] <= {1'b0, d, {(z_width-d_width){1'b0}} }; always @(posedge clk) if(ena) for(n0=1; n0 <= d_width; n0=n0+1) d_pipe[n0] <= #1 d_pipe[n0-1]; // generate internal remainder pipe always @(z) s_pipe[0] <= z; always @(posedge clk) if(ena) for(n1=1; n1 <= d_width; n1=n1+1) s_pipe[n1] <= #1 gen_s(s_pipe[n1-1], d_pipe[n1-1]); // generate quotient pipe always @(posedge clk) q_pipe[0] <= #1 0; always @(posedge clk) if(ena) for(n2=1; n2 < d_width; n2=n2+1) q_pipe[n2] <= #1 gen_q(q_pipe[n2-1], s_pipe[n2]); // flags (divide_by_zero, overflow) always @(z or d) begin ovf_pipe[0] <= !(z[z_width-1:d_width] < d); div0_pipe[0] <= ~|d; end always @(posedge clk) if(ena) for(n3=1; n3 <= d_width; n3=n3+1) begin ovf_pipe[n3] <= #1 ovf_pipe[n3-1]; div0_pipe[n3] <= #1 div0_pipe[n3-1]; end // assign outputs always @(posedge clk) if(ena) ovf <= #1 ovf_pipe[d_width]; always @(posedge clk) if(ena) div0 <= #1 div0_pipe[d_width]; always @(posedge clk) if(ena) q <= #1 gen_q(q_pipe[d_width-1], s_pipe[d_width]); always @(posedge clk) if(ena) s <= #1 assign_s(s_pipe[d_width], d_pipe[d_width]); endmodule

//----------------------------------------------------------------------------- //-- Baudrate generator //-- It generates a square signal, with a frequency for communicating at the //-- given baudrate //-- The output is set to 1 only during one clock cycle. The rest of the // time is 0 //-- Once enabled, the pulse is generated just in the middle of the period //-- This is necessary for the implementation of the receptor //------------------------------------------------------------------------------ //-- (c) Juan Gonzalez (obijuan) //----------------------------------------------------------------------------- //-- GPL license //----------------------------------------------------------------------------- `include "baudgen.vh" //------------------------------------------------------------------------------ //-- baudgen module //-- //-- INPUTS: //-- -clk: System clock (12 MHZ in the iceStick board) //-- -clk_ena: clock enable: //-- 1. Normal working: The squeare signal is generated //-- 0: stoped. Output always 0 //-- OUTPUTS: //-- - clk_out: Output signal. Pulse width: 1 clock cycle. //-- Output not registered //-- It tells the uart_rx when to sample the next bit //-- __ __ //-- _____| |________________________________________| |_____________________ //-- | -> <- 1 clock cycle | //-- <------- Period ------------------------> //-- //------------------------------------------------------------------------------ module baudgen_rx #( parameter BAUDRATE = `B115200 //-- Default baudrate )( input wire clk, //-- System clock input wire clk_ena, //-- Clock enable output wire clk_out //-- Bitrate Clock output ); //-- Number of bits needed for storing the baudrate divisor localparam N = $clog2(BAUDRATE); //-- Value for generating the pulse in the middle of the period localparam M2 = (BAUDRATE >> 1); //-- Counter for implementing the divisor (it is a BAUDRATE module counter) //-- (when BAUDRATE is reached, it start again from 0) reg [N-1:0] divcounter = 0; //-- Contador módulo M always @(posedge clk) if (clk_ena) //-- Normal working: counting. When the maximum count is reached, it starts from 0 divcounter <= (divcounter == BAUDRATE - 1) ? 0 : divcounter + 1; else //-- Counter fixed to its maximum value //-- When it is resumed it start from 0 divcounter <= BAUDRATE - 1; //-- The output is 1 when the counter is in the middle of the period, if clk_ena is active //-- It is 1 only for one system clock cycle assign clk_out = (divcounter == M2) ? clk_ena : 0; endmodule

// wasca_nios2_gen2_0.v // This file was auto-generated from altera_nios2_hw.tcl. If you edit it your changes // will probably be lost. // // Generated using ACDS version 15.1 193 `timescale 1 ps / 1 ps module wasca_nios2_gen2_0 ( input wire clk, // clk.clk input wire reset_n, // reset.reset_n output wire [27:0] d_address, // data_master.address output wire [3:0] d_byteenable, // .byteenable output wire d_read, // .read input wire [31:0] d_readdata, // .readdata input wire d_waitrequest, // .waitrequest output wire d_write, // .write output wire [31:0] d_writedata, // .writedata output wire debug_mem_slave_debugaccess_to_roms, // .debugaccess output wire [24:0] i_address, // instruction_master.address output wire i_read, // .read input wire [31:0] i_readdata, // .readdata input wire i_waitrequest, // .waitrequest input wire [31:0] irq, // irq.irq output wire debug_reset_request, // debug_reset_request.reset input wire [8:0] debug_mem_slave_address, // debug_mem_slave.address input wire [3:0] debug_mem_slave_byteenable, // .byteenable input wire debug_mem_slave_debugaccess, // .debugaccess input wire debug_mem_slave_read, // .read output wire [31:0] debug_mem_slave_readdata, // .readdata output wire debug_mem_slave_waitrequest, // .waitrequest input wire debug_mem_slave_write, // .write input wire [31:0] debug_mem_slave_writedata, // .writedata output wire dummy_ci_port // custom_instruction_master.readra ); wasca_nios2_gen2_0_cpu cpu ( .clk (clk), // clk.clk .reset_n (reset_n), // reset.reset_n .d_address (d_address), // data_master.address .d_byteenable (d_byteenable), // .byteenable .d_read (d_read), // .read .d_readdata (d_readdata), // .readdata .d_waitrequest (d_waitrequest), // .waitrequest .d_write (d_write), // .write .d_writedata (d_writedata), // .writedata .debug_mem_slave_debugaccess_to_roms (debug_mem_slave_debugaccess_to_roms), // .debugaccess .i_address (i_address), // instruction_master.address .i_read (i_read), // .read .i_readdata (i_readdata), // .readdata .i_waitrequest (i_waitrequest), // .waitrequest .irq (irq), // irq.irq .debug_reset_request (debug_reset_request), // debug_reset_request.reset .debug_mem_slave_address (debug_mem_slave_address), // debug_mem_slave.address .debug_mem_slave_byteenable (debug_mem_slave_byteenable), // .byteenable .debug_mem_slave_debugaccess (debug_mem_slave_debugaccess), // .debugaccess .debug_mem_slave_read (debug_mem_slave_read), // .read .debug_mem_slave_readdata (debug_mem_slave_readdata), // .readdata .debug_mem_slave_waitrequest (debug_mem_slave_waitrequest), // .waitrequest .debug_mem_slave_write (debug_mem_slave_write), // .write .debug_mem_slave_writedata (debug_mem_slave_writedata), // .writedata .dummy_ci_port (dummy_ci_port), // custom_instruction_master.readra .reset_req (1'b0) // (terminated) ); endmodule

/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 */ `ifndef SKY130_FD_SC_MS__O311A_4_V `define SKY130_FD_SC_MS__O311A_4_V /** * o311a: 3-input OR into 3-input AND. * * X = ((A1 | A2 | A3) & B1 & C1) * * Verilog wrapper for o311a with size of 4 units. * * WARNING: This file is autogenerated, do not modify directly! */ `timescale 1ns / 1ps `default_nettype none `include "sky130_fd_sc_ms__o311a.v" `ifdef USE_POWER_PINS /*********************************************************/ `celldefine module sky130_fd_sc_ms__o311a_4 ( X , A1 , A2 , A3 , B1 , C1 , VPWR, VGND, VPB , VNB ); output X ; input A1 ; input A2 ; input A3 ; input B1 ; input C1 ; input VPWR; input VGND; input VPB ; input VNB ; sky130_fd_sc_ms__o311a base ( .X(X), .A1(A1), .A2(A2), .A3(A3), .B1(B1), .C1(C1), .VPWR(VPWR), .VGND(VGND), .VPB(VPB), .VNB(VNB) ); endmodule `endcelldefine /*********************************************************/ `else // If not USE_POWER_PINS /*********************************************************/ `celldefine module sky130_fd_sc_ms__o311a_4 ( X , A1, A2, A3, B1, C1 ); output X ; input A1; input A2; input A3; input B1; input C1; // Voltage supply signals supply1 VPWR; supply0 VGND; supply1 VPB ; supply0 VNB ; sky130_fd_sc_ms__o311a base ( .X(X), .A1(A1), .A2(A2), .A3(A3), .B1(B1), .C1(C1) ); endmodule `endcelldefine /*********************************************************/ `endif // USE_POWER_PINS `default_nettype wire `endif // SKY130_FD_SC_MS__O311A_4_V

//***************************************************************************** // (c) Copyright 2009 - 2013 Xilinx, Inc. All rights reserved. // // This file contains confidential and proprietary information // of Xilinx, Inc. and is protected under U.S. and // international copyright and other intellectual property // laws. // // DISCLAIMER // This disclaimer is not a license and does not grant any // rights to the materials distributed herewith. Except as // otherwise provided in a valid license issued to you by // Xilinx, and to the maximum extent permitted by applicable // law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // (2) Xilinx shall not be liable (whether in contract or tort, // including negligence, or under any other theory of // liability) for any loss or damage of any kind or nature // related to, arising under or in connection with these // materials, including for any direct, or any indirect, // special, incidental, or consequential loss or damage // (including loss of data, profits, goodwill, or any type of // loss or damage suffered as a result of any action brought // by a third party) even if such damage or loss was // reasonably foreseeable or Xilinx had been advised of the // possibility of the same. // // CRITICAL APPLICATIONS // Xilinx products are not designed or intended to be fail- // safe, or for use in any application requiring fail-safe // performance, such as life-support or safety devices or // systems, Class III medical devices, nuclear facilities, // applications related to the deployment of airbags, or any // other applications that could lead to death, personal // injury, or severe property or environmental damage // (individually and collectively, "Critical // Applications"). Customer assumes the sole risk and // liability of any use of Xilinx products in Critical // Applications, subject only to applicable laws and // regulations governing limitations on product liability. // // THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // PART OF THIS FILE AT ALL TIMES. // //***************************************************************************** // ____ ____ // / /\/ / // /___/ \ / Vendor: Xilinx // \ \ \/ Version: // \ \ Application: MIG // / / Filename: ddr_phy_dqs_found_cal.v // /___/ /\ Date Last Modified: $Date: 2011/06/02 08:35:08 $ // \ \ / \ Date Created: // \___\/\___\ // //Device: 7 Series //Design Name: DDR3 SDRAM //Purpose: // Read leveling calibration logic // NOTES: // 1. Phaser_In DQSFOUND calibration //Reference: //Revision History: //***************************************************************************** /****************************************************************************** **$Id: ddr_phy_dqs_found_cal.v,v 1.1 2011/06/02 08:35:08 mishra Exp $ **$Date: 2011/06/02 08:35:08 $ **$Author: **$Revision: **$Source: ******************************************************************************/ `timescale 1ps/1ps module mig_7series_v1_9_ddr_phy_dqs_found_cal # ( parameter TCQ = 100, // clk->out delay (sim only) parameter nCK_PER_CLK = 2, // # of memory clocks per CLK parameter nCL = 5, // Read CAS latency parameter AL = "0", parameter nCWL = 5, // Write CAS latency parameter DRAM_TYPE = "DDR3", // Memory I/F type: "DDR3", "DDR2" parameter RANKS = 1, // # of memory ranks in the system parameter DQS_CNT_WIDTH = 3, // = ceil(log2(DQS_WIDTH)) parameter DQS_WIDTH = 8, // # of DQS (strobe) parameter DRAM_WIDTH = 8, // # of DQ per DQS parameter REG_CTRL = "ON", // "ON" for registered DIMM parameter SIM_CAL_OPTION = "NONE", // Performs all calibration steps parameter NUM_DQSFOUND_CAL = 3, // Number of times to iterate parameter N_CTL_LANES = 3, // Number of control byte lanes parameter HIGHEST_LANE = 12, // Sum of byte lanes (Data + Ctrl) parameter HIGHEST_BANK = 3, // Sum of I/O Banks parameter BYTE_LANES_B0 = 4'b1111, parameter BYTE_LANES_B1 = 4'b0000, parameter BYTE_LANES_B2 = 4'b0000, parameter BYTE_LANES_B3 = 4'b0000, parameter BYTE_LANES_B4 = 4'b0000, parameter DATA_CTL_B0 = 4'hc, parameter DATA_CTL_B1 = 4'hf, parameter DATA_CTL_B2 = 4'hf, parameter DATA_CTL_B3 = 4'hf, parameter DATA_CTL_B4 = 4'hf ) ( input clk, input rst, input dqsfound_retry, // From phy_init input pi_dqs_found_start, input detect_pi_found_dqs, input prech_done, // DQSFOUND per Phaser_IN input [HIGHEST_LANE-1:0] pi_dqs_found_lanes, output reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal, // To phy_init output [5:0] rd_data_offset_0, output [5:0] rd_data_offset_1, output [5:0] rd_data_offset_2, output pi_dqs_found_rank_done, output pi_dqs_found_done, output reg pi_dqs_found_err, output [6*RANKS-1:0] rd_data_offset_ranks_0, output [6*RANKS-1:0] rd_data_offset_ranks_1, output [6*RANKS-1:0] rd_data_offset_ranks_2, output reg dqsfound_retry_done, output reg dqs_found_prech_req, //To MC output [6*RANKS-1:0] rd_data_offset_ranks_mc_0, output [6*RANKS-1:0] rd_data_offset_ranks_mc_1, output [6*RANKS-1:0] rd_data_offset_ranks_mc_2, input [8:0] po_counter_read_val, output rd_data_offset_cal_done, output fine_adjust_done, output [N_CTL_LANES-1:0] fine_adjust_lane_cnt, output reg ck_po_stg2_f_indec, output reg ck_po_stg2_f_en, output [255:0] dbg_dqs_found_cal ); // For non-zero AL values localparam nAL = (AL == "CL-1") ? nCL - 1 : 0; // Adding the register dimm latency to write latency localparam CWL_M = (REG_CTRL == "ON") ? nCWL + nAL + 1 : nCWL + nAL; // Added to reduce simulation time localparam LATENCY_FACTOR = 13; localparam NUM_READS = (SIM_CAL_OPTION == "NONE") ? 7 : 1; localparam [19:0] DATA_PRESENT = {(DATA_CTL_B4[3] & BYTE_LANES_B4[3]), (DATA_CTL_B4[2] & BYTE_LANES_B4[2]), (DATA_CTL_B4[1] & BYTE_LANES_B4[1]), (DATA_CTL_B4[0] & BYTE_LANES_B4[0]), (DATA_CTL_B3[3] & BYTE_LANES_B3[3]), (DATA_CTL_B3[2] & BYTE_LANES_B3[2]), (DATA_CTL_B3[1] & BYTE_LANES_B3[1]), (DATA_CTL_B3[0] & BYTE_LANES_B3[0]), (DATA_CTL_B2[3] & BYTE_LANES_B2[3]), (DATA_CTL_B2[2] & BYTE_LANES_B2[2]), (DATA_CTL_B2[1] & BYTE_LANES_B2[1]), (DATA_CTL_B2[0] & BYTE_LANES_B2[0]), (DATA_CTL_B1[3] & BYTE_LANES_B1[3]), (DATA_CTL_B1[2] & BYTE_LANES_B1[2]), (DATA_CTL_B1[1] & BYTE_LANES_B1[1]), (DATA_CTL_B1[0] & BYTE_LANES_B1[0]), (DATA_CTL_B0[3] & BYTE_LANES_B0[3]), (DATA_CTL_B0[2] & BYTE_LANES_B0[2]), (DATA_CTL_B0[1] & BYTE_LANES_B0[1]), (DATA_CTL_B0[0] & BYTE_LANES_B0[0])}; localparam FINE_ADJ_IDLE = 4'h0; localparam RST_POSTWAIT = 4'h1; localparam RST_POSTWAIT1 = 4'h2; localparam RST_WAIT = 4'h3; localparam FINE_ADJ_INIT = 4'h4; localparam FINE_INC = 4'h5; localparam FINE_INC_WAIT = 4'h6; localparam FINE_INC_PREWAIT = 4'h7; localparam DETECT_PREWAIT = 4'h8; localparam DETECT_DQSFOUND = 4'h9; localparam PRECH_WAIT = 4'hA; localparam FINE_DEC = 4'hB; localparam FINE_DEC_WAIT = 4'hC; localparam FINE_DEC_PREWAIT = 4'hD; localparam FINAL_WAIT = 4'hE; localparam FINE_ADJ_DONE = 4'hF; integer k,l,m,n,p,q,r,s; reg dqs_found_start_r; reg [6*HIGHEST_BANK-1:0] rd_byte_data_offset[0:RANKS-1]; reg rank_done_r; reg rank_done_r1; reg dqs_found_done_r; (* ASYNC_REG = "TRUE" *) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r1; (* ASYNC_REG = "TRUE" *) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r2; (* ASYNC_REG = "TRUE" *) reg [HIGHEST_LANE-1:0] pi_dqs_found_lanes_r3; reg init_dqsfound_done_r; reg init_dqsfound_done_r1; reg init_dqsfound_done_r2; reg init_dqsfound_done_r3; reg init_dqsfound_done_r4; reg init_dqsfound_done_r5; reg [1:0] rnk_cnt_r; reg [2:0 ] final_do_index[0:RANKS-1]; reg [5:0 ] final_do_max[0:RANKS-1]; reg [6*HIGHEST_BANK-1:0] final_data_offset[0:RANKS-1]; reg [6*HIGHEST_BANK-1:0] final_data_offset_mc[0:RANKS-1]; reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal_r; reg [HIGHEST_BANK-1:0] pi_rst_stg1_cal_r1; reg [10*HIGHEST_BANK-1:0] retry_cnt; reg dqsfound_retry_r1; wire [4*HIGHEST_BANK-1:0] pi_dqs_found_lanes_int; reg [HIGHEST_BANK-1:0] pi_dqs_found_all_bank; reg [HIGHEST_BANK-1:0] pi_dqs_found_all_bank_r; reg [HIGHEST_BANK-1:0] pi_dqs_found_any_bank; reg [HIGHEST_BANK-1:0] pi_dqs_found_any_bank_r; reg [HIGHEST_BANK-1:0] pi_dqs_found_err_r; // CK/Control byte lanes fine adjust stage reg fine_adjust; reg [N_CTL_LANES-1:0] ctl_lane_cnt; reg [3:0] fine_adj_state_r; reg fine_adjust_done_r; reg rst_dqs_find; reg rst_dqs_find_r1; reg rst_dqs_find_r2; reg [5:0] init_dec_cnt; reg [5:0] dec_cnt; reg [5:0] inc_cnt; reg final_dec_done; reg init_dec_done; reg first_fail_detect; reg second_fail_detect; reg [5:0] first_fail_taps; reg [5:0] second_fail_taps; reg [5:0] stable_pass_cnt; reg [3:0] detect_rd_cnt; //*************************************************************************** // Debug signals // //*************************************************************************** assign dbg_dqs_found_cal[5:0] = first_fail_taps; assign dbg_dqs_found_cal[11:6] = second_fail_taps; assign dbg_dqs_found_cal[12] = first_fail_detect; assign dbg_dqs_found_cal[13] = second_fail_detect; assign dbg_dqs_found_cal[14] = fine_adjust_done_r; assign pi_dqs_found_rank_done = rank_done_r; assign pi_dqs_found_done = dqs_found_done_r; generate genvar rnk_cnt; if (HIGHEST_BANK == 3) begin // Three Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][11:6]; assign rd_data_offset_ranks_2[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][17:12]; assign rd_data_offset_ranks_mc_0[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][11:6]; assign rd_data_offset_ranks_mc_2[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][17:12]; end end else if (HIGHEST_BANK == 2) begin // Two Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][11:6]; assign rd_data_offset_ranks_2[6*rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_0[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][11:6]; assign rd_data_offset_ranks_mc_2[6*rnk_cnt+:6] = 'd0; end end else begin // Single Bank Interface for (rnk_cnt = 0; rnk_cnt < RANKS; rnk_cnt = rnk_cnt + 1) begin: rnk_loop assign rd_data_offset_ranks_0[6*rnk_cnt+:6] = final_data_offset[rnk_cnt][5:0]; assign rd_data_offset_ranks_1[6*rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_2[6*rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_0[6*rnk_cnt+:6] = final_data_offset_mc[rnk_cnt][5:0]; assign rd_data_offset_ranks_mc_1[6*rnk_cnt+:6] = 'd0; assign rd_data_offset_ranks_mc_2[6*rnk_cnt+:6] = 'd0; end end endgenerate // final_data_offset is used during write calibration and during // normal operation. One rd_data_offset value per rank for entire // interface generate if (HIGHEST_BANK == 3) begin // Three I/O Bank interface assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][6+:6] : final_data_offset[rnk_cnt_r][6+:6]; assign rd_data_offset_2 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][12+:6] : final_data_offset[rnk_cnt_r][12+:6]; end else if (HIGHEST_BANK == 2) begin // Two I/O Bank interface assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][6+:6] : final_data_offset[rnk_cnt_r][6+:6]; assign rd_data_offset_2 = 'd0; end else begin assign rd_data_offset_0 = (~init_dqsfound_done_r2) ? rd_byte_data_offset[rnk_cnt_r][0+:6] : final_data_offset[rnk_cnt_r][0+:6]; assign rd_data_offset_1 = 'd0; assign rd_data_offset_2 = 'd0; end endgenerate assign rd_data_offset_cal_done = init_dqsfound_done_r; assign fine_adjust_lane_cnt = ctl_lane_cnt; //************************************************************************** // DQSFOUND all and any generation // pi_dqs_found_all_bank[x] asserted when all Phaser_INs in Bankx are // asserted // pi_dqs_found_any_bank[x] asserted when at least one Phaser_IN in Bankx // is asserted //************************************************************************** generate if ((HIGHEST_LANE == 4) || (HIGHEST_LANE == 8) || (HIGHEST_LANE == 12)) assign pi_dqs_found_lanes_int = pi_dqs_found_lanes_r3; else if ((HIGHEST_LANE == 7) || (HIGHEST_LANE == 11)) assign pi_dqs_found_lanes_int = {1'b0, pi_dqs_found_lanes_r3}; else if ((HIGHEST_LANE == 6) || (HIGHEST_LANE == 10)) assign pi_dqs_found_lanes_int = {2'b00, pi_dqs_found_lanes_r3}; else if ((HIGHEST_LANE == 5) || (HIGHEST_LANE == 9)) assign pi_dqs_found_lanes_int = {3'b000, pi_dqs_found_lanes_r3}; endgenerate always @(posedge clk) begin if (rst) begin for (k = 0; k < HIGHEST_BANK; k = k + 1) begin: rst_pi_dqs_found pi_dqs_found_all_bank[k] <= #TCQ 'b0; pi_dqs_found_any_bank[k] <= #TCQ 'b0; end end else if (pi_dqs_found_start) begin for (p = 0; p < HIGHEST_BANK; p = p +1) begin: assign_pi_dqs_found pi_dqs_found_all_bank[p] <= #TCQ (!DATA_PRESENT[4*p+0] | pi_dqs_found_lanes_int[4*p+0]) & (!DATA_PRESENT[4*p+1] | pi_dqs_found_lanes_int[4*p+1]) & (!DATA_PRESENT[4*p+2] | pi_dqs_found_lanes_int[4*p+2]) & (!DATA_PRESENT[4*p+3] | pi_dqs_found_lanes_int[4*p+3]); pi_dqs_found_any_bank[p] <= #TCQ (DATA_PRESENT[4*p+0] & pi_dqs_found_lanes_int[4*p+0]) | (DATA_PRESENT[4*p+1] & pi_dqs_found_lanes_int[4*p+1]) | (DATA_PRESENT[4*p+2] & pi_dqs_found_lanes_int[4*p+2]) | (DATA_PRESENT[4*p+3] & pi_dqs_found_lanes_int[4*p+3]); end end end always @(posedge clk) begin pi_dqs_found_all_bank_r <= #TCQ pi_dqs_found_all_bank; pi_dqs_found_any_bank_r <= #TCQ pi_dqs_found_any_bank; end //***************************************************************************** // Counter to increase number of 4 back-to-back reads per rd_data_offset and // per CK/A/C tap value //***************************************************************************** always @(posedge clk) begin if (rst || (detect_rd_cnt == 'd0)) detect_rd_cnt <= #TCQ NUM_READS; else if (detect_pi_found_dqs && (detect_rd_cnt > 'd0)) detect_rd_cnt <= #TCQ detect_rd_cnt - 1; end //************************************************************************** // Adjust Phaser_Out stage 2 taps on CK/Address/Command/Controls // //************************************************************************** assign fine_adjust_done = fine_adjust_done_r; always @(posedge clk) begin rst_dqs_find_r1 <= #TCQ rst_dqs_find; rst_dqs_find_r2 <= #TCQ rst_dqs_find_r1; end always @(posedge clk) begin if(rst)begin fine_adjust <= #TCQ 1'b0; ctl_lane_cnt <= #TCQ 'd0; fine_adj_state_r <= #TCQ FINE_ADJ_IDLE; fine_adjust_done_r <= #TCQ 1'b0; ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; rst_dqs_find <= #TCQ 1'b0; init_dec_cnt <= #TCQ 'd31; dec_cnt <= #TCQ 'd0; inc_cnt <= #TCQ 'd0; init_dec_done <= #TCQ 1'b0; final_dec_done <= #TCQ 1'b0; first_fail_detect <= #TCQ 1'b0; second_fail_detect <= #TCQ 1'b0; first_fail_taps <= #TCQ 'd0; second_fail_taps <= #TCQ 'd0; stable_pass_cnt <= #TCQ 'd0; dqs_found_prech_req<= #TCQ 1'b0; end else begin case (fine_adj_state_r) FINE_ADJ_IDLE: begin if (init_dqsfound_done_r5) begin if (SIM_CAL_OPTION == "FAST_CAL") begin fine_adjust <= #TCQ 1'b1; fine_adj_state_r <= #TCQ FINE_ADJ_DONE; rst_dqs_find <= #TCQ 1'b0; end else begin fine_adjust <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; rst_dqs_find <= #TCQ 1'b1; end end end RST_WAIT: begin if (~(|pi_dqs_found_any_bank) && rst_dqs_find_r2) begin rst_dqs_find <= #TCQ 1'b0; if (|init_dec_cnt) fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; else if (final_dec_done) fine_adj_state_r <= #TCQ FINE_ADJ_DONE; else fine_adj_state_r <= #TCQ RST_POSTWAIT; end end RST_POSTWAIT: begin fine_adj_state_r <= #TCQ RST_POSTWAIT1; end RST_POSTWAIT1: begin fine_adj_state_r <= #TCQ FINE_ADJ_INIT; end FINE_ADJ_INIT: begin //if (detect_pi_found_dqs && (inc_cnt < 'd63)) fine_adj_state_r <= #TCQ FINE_INC; end FINE_INC: begin fine_adj_state_r <= #TCQ FINE_INC_WAIT; ck_po_stg2_f_indec <= #TCQ 1'b1; ck_po_stg2_f_en <= #TCQ 1'b1; if (ctl_lane_cnt == N_CTL_LANES-1) inc_cnt <= #TCQ inc_cnt + 1; end FINE_INC_WAIT: begin ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; if (ctl_lane_cnt != N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ ctl_lane_cnt + 1; fine_adj_state_r <= #TCQ FINE_INC_PREWAIT; end else if (ctl_lane_cnt == N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ 'd0; fine_adj_state_r <= #TCQ DETECT_PREWAIT; end end FINE_INC_PREWAIT: begin fine_adj_state_r <= #TCQ FINE_INC; end DETECT_PREWAIT: begin if (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) fine_adj_state_r <= #TCQ DETECT_DQSFOUND; else fine_adj_state_r <= #TCQ DETECT_PREWAIT; end DETECT_DQSFOUND: begin if (detect_pi_found_dqs && ~(&pi_dqs_found_all_bank)) begin stable_pass_cnt <= #TCQ 'd0; if (~first_fail_detect && (inc_cnt == 'd63)) begin // First failing tap detected at 63 taps // then decrement to 31 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ 'd32; end else if (~first_fail_detect && (inc_cnt > 'd30) && (stable_pass_cnt > 'd29)) begin // First failing tap detected at greater than 30 taps // then stop looking for second edge and decrement first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ (inc_cnt>>1) + 1; end else if (~first_fail_detect || (first_fail_detect && (stable_pass_cnt < 'd30) && (inc_cnt <= 'd32))) begin // First failing tap detected, continue incrementing // until either second failing tap detected or 63 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; rst_dqs_find <= #TCQ 1'b1; if ((inc_cnt == 'd12) || (inc_cnt == 'd24)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else fine_adj_state_r <= #TCQ RST_WAIT; end else if (first_fail_detect && (inc_cnt > 'd32) && (inc_cnt < 'd63) && (stable_pass_cnt < 'd30)) begin // Consecutive 30 taps of passing region was not found // continue incrementing first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; rst_dqs_find <= #TCQ 1'b1; if ((inc_cnt == 'd36) || (inc_cnt == 'd48) || (inc_cnt == 'd60)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else fine_adj_state_r <= #TCQ RST_WAIT; end else if (first_fail_detect && (inc_cnt == 'd63)) begin if (stable_pass_cnt < 'd30) begin // Consecutive 30 taps of passing region was not found // from tap 0 to 63 so decrement back to 31 first_fail_detect <= #TCQ 1'b1; first_fail_taps <= #TCQ inc_cnt; fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ 'd32; end else begin // Consecutive 30 taps of passing region was found // between first_fail_taps and 63 fine_adj_state_r <= #TCQ FINE_DEC; dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); end end else begin // Second failing tap detected, decrement to center of // failing taps second_fail_detect <= #TCQ 1'b1; second_fail_taps <= #TCQ inc_cnt; dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); fine_adj_state_r <= #TCQ FINE_DEC; end end else if (detect_pi_found_dqs && (&pi_dqs_found_all_bank)) begin stable_pass_cnt <= #TCQ stable_pass_cnt + 1; if ((inc_cnt == 'd12) || (inc_cnt == 'd24) || (inc_cnt == 'd36) || (inc_cnt == 'd48) || (inc_cnt == 'd60)) begin dqs_found_prech_req <= #TCQ 1'b1; fine_adj_state_r <= #TCQ PRECH_WAIT; end else if (inc_cnt < 'd63) begin rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end else begin fine_adj_state_r <= #TCQ FINE_DEC; if (~first_fail_detect || (first_fail_taps > 'd33)) // No failing taps detected, decrement by 31 dec_cnt <= #TCQ 'd32; //else if (first_fail_detect && (stable_pass_cnt > 'd28)) // // First failing tap detected between 0 and 34 // // decrement midpoint between 63 and failing tap // dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); else // First failing tap detected // decrement to midpoint between 63 and failing tap dec_cnt <= #TCQ ((inc_cnt - first_fail_taps)>>1); end end end PRECH_WAIT: begin if (prech_done) begin dqs_found_prech_req <= #TCQ 1'b0; rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end end FINE_DEC: begin fine_adj_state_r <= #TCQ FINE_DEC_WAIT; ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b1; if ((ctl_lane_cnt == N_CTL_LANES-1) && (init_dec_cnt > 'd0)) init_dec_cnt <= #TCQ init_dec_cnt - 1; else if ((ctl_lane_cnt == N_CTL_LANES-1) && (dec_cnt > 'd0)) dec_cnt <= #TCQ dec_cnt - 1; end FINE_DEC_WAIT: begin ck_po_stg2_f_indec <= #TCQ 1'b0; ck_po_stg2_f_en <= #TCQ 1'b0; if (ctl_lane_cnt != N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ ctl_lane_cnt + 1; fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; end else if (ctl_lane_cnt == N_CTL_LANES-1) begin ctl_lane_cnt <= #TCQ 'd0; if ((dec_cnt > 'd0) || (init_dec_cnt > 'd0)) fine_adj_state_r <= #TCQ FINE_DEC_PREWAIT; else begin fine_adj_state_r <= #TCQ FINAL_WAIT; if ((init_dec_cnt == 'd0) && ~init_dec_done) init_dec_done <= #TCQ 1'b1; else final_dec_done <= #TCQ 1'b1; end end end FINE_DEC_PREWAIT: begin fine_adj_state_r <= #TCQ FINE_DEC; end FINAL_WAIT: begin rst_dqs_find <= #TCQ 1'b1; fine_adj_state_r <= #TCQ RST_WAIT; end FINE_ADJ_DONE: begin if (&pi_dqs_found_all_bank) begin fine_adjust_done_r <= #TCQ 1'b1; rst_dqs_find <= #TCQ 1'b0; fine_adj_state_r <= #TCQ FINE_ADJ_DONE; end end endcase end end //***************************************************************************** always@(posedge clk) dqs_found_start_r <= #TCQ pi_dqs_found_start; always @(posedge clk) begin if (rst) rnk_cnt_r <= #TCQ 2'b00; else if (init_dqsfound_done_r) rnk_cnt_r <= #TCQ rnk_cnt_r; else if (rank_done_r) rnk_cnt_r <= #TCQ rnk_cnt_r + 1; end //***************************************************************** // Read data_offset calibration done signal //***************************************************************** always @(posedge clk) begin if (rst || (|pi_rst_stg1_cal_r)) init_dqsfound_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank) begin if (rnk_cnt_r == RANKS-1) init_dqsfound_done_r <= #TCQ 1'b1; else init_dqsfound_done_r <= #TCQ 1'b0; end end always @(posedge clk) begin if (rst || (init_dqsfound_done_r && (rnk_cnt_r == RANKS-1))) rank_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank && ~(&pi_dqs_found_all_bank_r)) rank_done_r <= #TCQ 1'b1; else rank_done_r <= #TCQ 1'b0; end always @(posedge clk) begin pi_dqs_found_lanes_r1 <= #TCQ pi_dqs_found_lanes; pi_dqs_found_lanes_r2 <= #TCQ pi_dqs_found_lanes_r1; pi_dqs_found_lanes_r3 <= #TCQ pi_dqs_found_lanes_r2; init_dqsfound_done_r1 <= #TCQ init_dqsfound_done_r; init_dqsfound_done_r2 <= #TCQ init_dqsfound_done_r1; init_dqsfound_done_r3 <= #TCQ init_dqsfound_done_r2; init_dqsfound_done_r4 <= #TCQ init_dqsfound_done_r3; init_dqsfound_done_r5 <= #TCQ init_dqsfound_done_r4; rank_done_r1 <= #TCQ rank_done_r; dqsfound_retry_r1 <= #TCQ dqsfound_retry; end always @(posedge clk) begin if (rst) dqs_found_done_r <= #TCQ 1'b0; else if (&pi_dqs_found_all_bank && (rnk_cnt_r == RANKS-1) && init_dqsfound_done_r1 && (fine_adj_state_r == FINE_ADJ_DONE)) dqs_found_done_r <= #TCQ 1'b1; else dqs_found_done_r <= #TCQ 1'b0; end generate if (HIGHEST_BANK == 3) begin // Three I/O Bank interface // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[0] || fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[0]) || (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) || (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[1] || fine_adjust) pi_rst_stg1_cal_r[1] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[1]) || (pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) || (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[2] || fine_adjust) pi_rst_stg1_cal_r[2] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[2]) || (pi_dqs_found_any_bank_r[2] && ~pi_dqs_found_all_bank[2]) || (rd_byte_data_offset[rnk_cnt_r][12+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[2] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[2]) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[2] && ~pi_dqs_found_all_bank[2]) pi_rst_stg1_cal_r1[2] <= #TCQ 1'b0; end //***************************************************************************** // Retry counter to track number of DQSFOUND retries //***************************************************************************** always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[10+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[1]) retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10] + 1; else retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10]; end always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[20+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][12+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[2]) retry_cnt[20+:10] <= #TCQ retry_cnt[20+:10] + 1; else retry_cnt[20+:10] <= #TCQ retry_cnt[20+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[1] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[1] && (retry_cnt[10+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[2] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[2] && (retry_cnt[20+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][12+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[2] <= #TCQ 1'b1; end // Read data offset value for all DQS in a Bank always @(posedge clk) begin if (rst) begin for (q = 0; q < RANKS; q = q + 1) begin: three_bank0_rst_loop rd_byte_data_offset[q][0+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][0+:6] - 1; end always @(posedge clk) begin if (rst) begin for (r = 0; r < RANKS; r = r + 1) begin: three_bank1_rst_loop rd_byte_data_offset[r][6+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[1] && //(rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][6+:6] - 1; end always @(posedge clk) begin if (rst) begin for (s = 0; s < RANKS; s = s + 1) begin: three_bank2_rst_loop rd_byte_data_offset[s][12+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r][12+:6] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r][12+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[2] && //(rd_byte_data_offset[rnk_cnt_r][12+:6] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][12+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][12+:6] - 1; end //***************************************************************************** // Two I/O Bank Interface //***************************************************************************** end else if (HIGHEST_BANK == 2) begin // Two I/O Bank interface // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[0] || fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[0]) || (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) || (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[1] || fine_adjust) pi_rst_stg1_cal_r[1] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[1]) || (pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) || (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[1] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[1] && ~pi_dqs_found_all_bank[1]) pi_rst_stg1_cal_r1[1] <= #TCQ 1'b0; end //***************************************************************************** // Retry counter to track number of DQSFOUND retries //***************************************************************************** always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[10+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[1]) retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10] + 1; else retry_cnt[10+:10] <= #TCQ retry_cnt[10+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst) pi_dqs_found_err_r[1] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[1] && (retry_cnt[10+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[1] <= #TCQ 1'b1; end // Read data offset value for all DQS in a Bank always @(posedge clk) begin if (rst) begin for (q = 0; q < RANKS; q = q + 1) begin: two_bank0_rst_loop rd_byte_data_offset[q][0+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r][0+:6] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][0+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][0+:6] - 1; end always @(posedge clk) begin if (rst) begin for (r = 0; r < RANKS; r = r + 1) begin: two_bank1_rst_loop rd_byte_data_offset[r][6+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r][6+:6] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[1] && //(rd_byte_data_offset[rnk_cnt_r][6+:6] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r][6+:6] <= #TCQ rd_byte_data_offset[rnk_cnt_r][6+:6] - 1; end //***************************************************************************** // One I/O Bank Interface //***************************************************************************** end else begin // One I/O Bank Interface // Read data offset value for all DQS in Bank0 always @(posedge clk) begin if (rst) begin for (l = 0; l < RANKS; l = l + 1) begin: bank_rst_loop rd_byte_data_offset[l] <= #TCQ nCL + nAL + LATENCY_FACTOR; end end else if ((rank_done_r1 && ~init_dqsfound_done_r) || (rd_byte_data_offset[rnk_cnt_r] < (nCL + nAL - 1))) rd_byte_data_offset[rnk_cnt_r] <= #TCQ nCL + nAL + LATENCY_FACTOR; else if (dqs_found_start_r && ~pi_dqs_found_all_bank[0] && //(rd_byte_data_offset[rnk_cnt_r] > (nCL + nAL -1)) && (detect_pi_found_dqs && (detect_rd_cnt == 'd1)) && ~init_dqsfound_done_r && ~fine_adjust) rd_byte_data_offset[rnk_cnt_r] <= #TCQ rd_byte_data_offset[rnk_cnt_r] - 1; end // Reset read data offset calibration in all DQS Phaser_INs // in a Bank after the read data offset value for a rank is determined // or if within a Bank DQSFOUND is not asserted for all DQSs always @(posedge clk) begin if (rst || pi_rst_stg1_cal_r1[0] || fine_adjust) pi_rst_stg1_cal_r[0] <= #TCQ 1'b0; else if ((pi_dqs_found_start && ~dqs_found_start_r) || //(dqsfound_retry[0]) || (pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) || (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_rst_stg1_cal_r[0] <= #TCQ 1'b1; end always @(posedge clk) begin if (rst || fine_adjust) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; else if (pi_rst_stg1_cal_r[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b1; else if (~pi_dqs_found_any_bank_r[0] && ~pi_dqs_found_all_bank[0]) pi_rst_stg1_cal_r1[0] <= #TCQ 1'b0; end //***************************************************************************** // Retry counter to track number of DQSFOUND retries //***************************************************************************** always @(posedge clk) begin if (rst || rank_done_r) retry_cnt[0+:10] <= #TCQ 'b0; else if ((rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1)) && ~pi_dqs_found_all_bank[0]) retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10] + 1; else retry_cnt[0+:10] <= #TCQ retry_cnt[0+:10]; end // Error generation in case pi_dqs_found_all_bank // is not asserted even with 3 dqfound retries always @(posedge clk) begin if (rst) pi_dqs_found_err_r[0] <= #TCQ 1'b0; else if (~pi_dqs_found_all_bank[0] && (retry_cnt[0+:10] == NUM_DQSFOUND_CAL) && (rd_byte_data_offset[rnk_cnt_r][0+:6] < (nCL + nAL - 1))) pi_dqs_found_err_r[0] <= #TCQ 1'b1; end end endgenerate always @(posedge clk) begin if (rst) pi_rst_stg1_cal <= #TCQ {HIGHEST_BANK{1'b0}}; else if (rst_dqs_find) pi_rst_stg1_cal <= #TCQ {HIGHEST_BANK{1'b1}}; else pi_rst_stg1_cal <= #TCQ pi_rst_stg1_cal_r; end // Final read data offset value to be used during write calibration and // normal operation generate genvar i; genvar j; for (i = 0; i < RANKS; i = i + 1) begin: rank_final_loop reg [5:0] final_do_cand [RANKS-1:0]; // combinatorially select the candidate offset for the bank // indexed by final_do_index if (HIGHEST_BANK == 3) begin always @(*) begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = final_data_offset[i][11:6]; 3'b010: final_do_cand[i] = final_data_offset[i][17:12]; default: final_do_cand[i] = 'd0; endcase end end else if (HIGHEST_BANK == 2) begin always @(*) begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = final_data_offset[i][11:6]; 3'b010: final_do_cand[i] = 'd0; default: final_do_cand[i] = 'd0; endcase end end else begin always @(*) begin case (final_do_index[i]) 3'b000: final_do_cand[i] = final_data_offset[i][5:0]; 3'b001: final_do_cand[i] = 'd0; 3'b010: final_do_cand[i] = 'd0; default: final_do_cand[i] = 'd0; endcase end end always @(posedge clk or posedge rst) begin if (rst) final_do_max[i] <= #TCQ 0; else begin final_do_max[i] <= #TCQ final_do_max[i]; // default case (final_do_index[i]) 3'b000: if ( | DATA_PRESENT[3:0]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; 3'b001: if ( | DATA_PRESENT[7:4]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; 3'b010: if ( | DATA_PRESENT[11:8]) if (final_do_max[i] < final_do_cand[i]) if (CWL_M % 2) // odd latency CAS slot 1 final_do_max[i] <= #TCQ final_do_cand[i] - 1; else final_do_max[i] <= #TCQ final_do_cand[i]; default: final_do_max[i] <= #TCQ final_do_max[i]; endcase end end always @(posedge clk) if (rst) begin final_do_index[i] <= #TCQ 0; end else begin final_do_index[i] <= #TCQ final_do_index[i] + 1; end for (j = 0; j < HIGHEST_BANK; j = j + 1) begin: bank_final_loop always @(posedge clk) begin if (rst) begin final_data_offset[i][6*j+:6] <= #TCQ 'b0; end else begin //if (dqsfound_retry[j]) // final_data_offset[i][6*j+:6] <= #TCQ rd_byte_data_offset[i][6*j+:6]; //else if (init_dqsfound_done_r && ~init_dqsfound_done_r1) begin if ( DATA_PRESENT [ j*4+:4] != 0) begin // has a data lane final_data_offset[i][6*j+:6] <= #TCQ rd_byte_data_offset[i][6*j+:6]; if (CWL_M % 2) // odd latency CAS slot 1 final_data_offset_mc[i][6*j+:6] <= #TCQ rd_byte_data_offset[i][6*j+:6] - 1; else // even latency CAS slot 0 final_data_offset_mc[i][6*j+:6] <= #TCQ rd_byte_data_offset[i][6*j+:6]; end end else if (init_dqsfound_done_r5 ) begin if ( DATA_PRESENT [ j*4+:4] == 0) begin // all control lanes final_data_offset[i][6*j+:6] <= #TCQ final_do_max[i]; final_data_offset_mc[i][6*j+:6] <= #TCQ final_do_max[i]; end end end end end end endgenerate // Error generation in case pi_found_dqs signal from Phaser_IN // is not asserted when a common rddata_offset value is used always @(posedge clk) begin pi_dqs_found_err <= #TCQ |pi_dqs_found_err_r; end endmodule

// $Id: testbench.v 1853 2010-03-24 03:06:21Z dub $ /* Copyright (c) 2007-2009, Trustees of The Leland Stanford Junior University All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. Neither the name of the Stanford University nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ `default_nettype none module testbench (); `include "c_functions.v" `include "c_constants.v" `include "vcr_constants.v" `include "parameters.v" parameter Tclk = 4; // total number of packet classes localparam num_packet_classes = num_message_classes * num_resource_classes; // number of VCs localparam num_vcs = num_packet_classes * num_vcs_per_class; // width required to select individual VC localparam vc_idx_width = clogb(num_vcs); // total number of routers localparam num_routers = (num_nodes + num_nodes_per_router - 1) / num_nodes_per_router; // number of routers in each dimension localparam num_routers_per_dim = croot(num_routers, num_dimensions); // width required to select individual router in a dimension localparam dim_addr_width = clogb(num_routers_per_dim); // width required to select individual router in entire network localparam router_addr_width = num_dimensions * dim_addr_width; // width required to select individual node at current router localparam node_addr_width = clogb(num_nodes_per_router); // width of global addresses localparam addr_width = router_addr_width + node_addr_width; // connectivity within each dimension localparam connectivity = (topology == `TOPOLOGY_MESH) ? `CONNECTIVITY_LINE : (topology == `TOPOLOGY_TORUS) ? `CONNECTIVITY_RING : (topology == `TOPOLOGY_FBFLY) ? `CONNECTIVITY_FULL : -1; // number of adjacent routers in each dimension localparam num_neighbors_per_dim = ((connectivity == `CONNECTIVITY_LINE) || (connectivity == `CONNECTIVITY_RING)) ? 2 : (connectivity == `CONNECTIVITY_FULL) ? (num_routers_per_dim - 1) : -1; // number of input and output ports on router localparam num_ports = num_dimensions * num_neighbors_per_dim + num_nodes_per_router; // width required to select individual port localparam port_idx_width = clogb(num_ports); // width required for lookahead routing information localparam la_route_info_width = port_idx_width + ((num_resource_classes > 1) ? 1 : 0); // total number of bits required for storing routing information localparam route_info_width = num_resource_classes * router_addr_width + node_addr_width; // number of bits required to represent all possible payload sizes localparam payload_length_width = clogb(max_payload_length-min_payload_length+1); // width of counter for remaining flits localparam flit_ctr_width = clogb(max_payload_length); // total number of bits required for storing header information localparam header_info_width = (packet_format == `PACKET_FORMAT_HEAD_TAIL) ? (la_route_info_width + route_info_width) : (packet_format == `PACKET_FORMAT_EXPLICIT_LENGTH) ? (la_route_info_width + route_info_width + payload_length_width) : -1; // width of flit control signals localparam flit_ctrl_width = (packet_format == `PACKET_FORMAT_HEAD_TAIL) ? (1 + vc_idx_width + 1 + 1) : (packet_format == `PACKET_FORMAT_EXPLICIT_LENGTH) ? (1 + vc_idx_width + 1) : -1; // width of flow control signals localparam flow_ctrl_width = 1 + vc_idx_width; // select set of feedback polynomials used for LFSRs parameter lfsr_index = 0; // number of bits in address that are considered base address parameter cfg_node_addr_width = 10; // width of register selector part of control register address parameter cfg_reg_addr_width = 6; // width of configuration bus addresses localparam cfg_addr_width = cfg_node_addr_width + cfg_reg_addr_width; // width of control register data parameter cfg_data_width = 32; // base address width for interface bus localparam io_node_addr_width = cfg_node_addr_width; // register index width for interface bus localparam io_reg_addr_width = cfg_reg_addr_width; // width of interface bus addresses localparam io_addr_width = cfg_addr_width; // width of interface bus datapath localparam io_data_width = cfg_data_width; // width of run cycle counter parameter num_packets_width = 16; // width of arrival rate LFSR parameter arrival_rv_width = 16; // width of message class selection LFSR parameter mc_idx_rv_width = 4; // width of resource class selection LFSR parameter rc_idx_rv_width = 4; // width of payload length selection LFSR parameter plength_idx_rv_width = 4; // number of selectable payload lengths parameter num_plength_vals = 2; // width of register that holds the number of outstanding packets parameter packet_count_width = 8; // number of bits in delay counter for acknowledgement (i.e., log2 of // interval before acknowledgement is sent) parameter done_delay_width = 4; // number of node control signals to generate parameter node_ctrl_width = 2; // number of node status signals to accept parameter node_status_width = 1; // RNG seed value parameter initial_seed = 0; reg reset; reg clk; reg [0:io_node_addr_width-1] io_node_addr_base; reg io_write; reg io_read; reg [0:cfg_addr_width-1] io_addr; reg [0:cfg_data_width-1] io_write_data; wire [0:cfg_data_width-1] io_read_data; wire io_done; wire error; tc_router_wrap #(.topology(topology), .num_flit_buffers(num_flit_buffers), .num_header_buffers(num_header_buffers), .num_message_classes(num_message_classes), .num_resource_classes(num_resource_classes), .num_vcs_per_class(num_vcs_per_class), .num_nodes(num_nodes), .num_dimensions(num_dimensions), .num_nodes_per_router(num_nodes_per_router), .packet_format(packet_format), .max_payload_length(max_payload_length), .min_payload_length(min_payload_length), .perf_ctr_enable(perf_ctr_enable), .perf_ctr_width(perf_ctr_width), .error_capture_mode(error_capture_mode), .track_vcs_at_output(track_vcs_at_output), .router_type(router_type), .flit_data_width(flit_data_width), .dim_order(dim_order), .int_flow_ctrl_type(int_flow_ctrl_type), .header_fifo_type(header_fifo_type), .fbf_regfile_type(fbf_regfile_type), .vc_alloc_type(vc_alloc_type), .vc_alloc_arbiter_type(vc_alloc_arbiter_type), .sw_alloc_type(sw_alloc_type), .sw_alloc_arbiter_type(sw_alloc_arbiter_type), .sw_alloc_spec_type(sw_alloc_spec_type), .ctrl_crossbar_type(ctrl_crossbar_type), .data_crossbar_type(data_crossbar_type), .reset_type(reset_type), .lfsr_index(lfsr_index), .cfg_node_addr_width(cfg_node_addr_width), .cfg_reg_addr_width(cfg_reg_addr_width), .cfg_data_width(cfg_data_width), .num_packets_width(num_packets_width), .arrival_rv_width(arrival_rv_width), .mc_idx_rv_width(mc_idx_rv_width), .rc_idx_rv_width(rc_idx_rv_width), .plength_idx_rv_width(plength_idx_rv_width), .num_plength_vals(num_plength_vals), .packet_count_width(packet_count_width)) dut (.clk(clk), .reset(reset), .io_node_addr_base(io_node_addr_base), .io_write(io_write), .io_read(io_read), .io_addr(io_addr), .io_write_data(io_write_data), .io_read_data(io_read_data), .io_done(io_done), .error(error)); reg clk_en; always begin clk <= clk_en; #(Tclk/2); clk <= 1'b0; #(Tclk/2); end always @(posedge clk) begin if(error) begin $display("error detected, cyc=%d", $time); $stop; end end reg done; integer i, j; integer seed = initial_seed; initial begin reset = 1'b0; clk_en = 1'b0; io_node_addr_base = 'd0; #(Tclk); #(Tclk/4); reset = 1'b1; io_write = 1'b0; io_read = 1'b0; io_addr = 'b0; io_write_data = 'b0; done = 1'b0; #(Tclk); reset = 1'b0; #(Tclk); clk_en = 1'b1; #(Tclk); // disable reset (i.e., enable reset_b) io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 'd0; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; io_write_data[0] = 1'b1; io_write_data[2] = 1'b1; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // enable clocks io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 'd0; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; io_write_data[0] = 1'b1; io_write_data[1] = 1'b1; io_write_data[2] = 1'b1; io_write_data[3] = 1'b1; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set LFSR seeds for(j = (num_ports - num_nodes_per_router); j < num_ports; j = j + 1) begin io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + j; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd3; for(i = 0; i < cfg_data_width; i = i + 1) io_write_data[i] = $dist_uniform(seed, 0, 1); while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); end // set number of packets io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd4; io_write_data = 'd0; io_write_data[0:num_packets_width-1] = 'd1024; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set arrival rate threshold io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd5; io_write_data = 'd0; io_write_data[0:arrival_rv_width-1] = 'd4096; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set packet length selection threshold io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd6; io_write_data = 'd0; io_write_data[0:plength_idx_rv_width-1] = 'd8; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set packet length values io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd7; io_write_data = 'd0; io_write_data[0:payload_length_width-1] = 'd0; io_write_data[payload_length_width:2*payload_length_width-1] = 'd4; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set message class selection thresholds io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd8; io_write_data = 'd0; io_write_data[0:mc_idx_rv_width-1] = 'd10; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // set resource class selection thresholds io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd9; io_write_data = 'd0; io_write_data[0:rc_idx_rv_width-1] = 'd12; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(10*Tclk); // start experiment io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; io_write_data[0] = 'd1; io_write_data[1] = 'd0; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); // wait for experiment to finish while(!done) begin #(10*Tclk); io_read = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd1; io_write_data = 'd0; while(!io_done) #(Tclk); done = ~io_read_data[0]; #(Tclk); io_read = 1'b0; while(io_done) #(Tclk); end done = 1'b0; #(Tclk); // disable nodes io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // disable router clocks io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 'd0; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; io_write_data[0] = 1'b1; io_write_data[1] = 1'b1; io_write_data[2] = 1'b1; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(Tclk); // reset number of packets io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd4; io_write_data = 'd0; io_write_data[0:num_packets_width-1] = 'd1024; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(10*Tclk); // restart experiment in loopback mode io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; io_write_data[0] = 'd1; io_write_data[1] = 'd1; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); // wait for experiment to finish while(!done) begin #(10*Tclk); io_read = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd1; io_write_data = 'd0; while(!io_done) #(Tclk); done = ~io_read_data[0]; #(Tclk); io_read = 1'b0; while(io_done) #(Tclk); end done = 1'b0; #(Tclk); // disable nodes io_write = 1'b1; io_addr[0:cfg_node_addr_width-1] = 1 + num_ports; io_addr[cfg_node_addr_width:cfg_addr_width-1] = 'd0; io_write_data = 'd0; while(!io_done) #(Tclk); #(Tclk); io_write = 1'b0; while(io_done) #(Tclk); #(3*Tclk/4); #(Tclk); $finish; end endmodule

// megafunction wizard: %FIFO%VBB% // GENERATION: STANDARD // VERSION: WM1.0 // MODULE: dcfifo // ============================================================ // File Name: fifo_4kx16_dc.v // Megafunction Name(s): // dcfifo // ============================================================ // ************************************************************ // THIS IS A WIZARD-GENERATED FILE. DO NOT EDIT THIS FILE! // // 5.1 Build 213 01/19/2006 SP 1 SJ Web Edition // ************************************************************ //Copyright (C) 1991-2006 Altera Corporation //Your use of Altera Corporation's design tools, logic functions //and other software and tools, and its AMPP partner logic //functions, and any output files any of the foregoing //(including device programming or simulation files), and any //associated documentation or information are expressly subject //to the terms and conditions of the Altera Program License //Subscription Agreement, Altera MegaCore Function License //Agreement, or other applicable license agreement, including, //without limitation, that your use is for the sole purpose of //programming logic devices manufactured by Altera and sold by //Altera or its authorized distributors. Please refer to the //applicable agreement for further details. module fifo_4kx16_dc ( aclr, data, rdclk, rdreq, wrclk, wrreq, q, rdempty, rdusedw, wrfull, wrusedw); input aclr; input [15:0] data; input rdclk; input rdreq; input wrclk; input wrreq; output [15:0] q; output rdempty; output [11:0] rdusedw; output wrfull; output [11:0] wrusedw; endmodule // ============================================================ // CNX file retrieval info // ============================================================ // Retrieval info: PRIVATE: AlmostEmpty NUMERIC "0" // Retrieval info: PRIVATE: AlmostEmptyThr NUMERIC "-1" // Retrieval info: PRIVATE: AlmostFull NUMERIC "0" // Retrieval info: PRIVATE: AlmostFullThr NUMERIC "-1" // Retrieval info: PRIVATE: CLOCKS_ARE_SYNCHRONIZED NUMERIC "0" // Retrieval info: PRIVATE: Clock NUMERIC "4" // Retrieval info: PRIVATE: Depth NUMERIC "4096" // Retrieval info: PRIVATE: Empty NUMERIC "1" // Retrieval info: PRIVATE: Full NUMERIC "1" // Retrieval info: PRIVATE: INTENDED_DEVICE_FAMILY STRING "Cyclone" // Retrieval info: PRIVATE: LE_BasedFIFO NUMERIC "0" // Retrieval info: PRIVATE: LegacyRREQ NUMERIC "0" // Retrieval info: PRIVATE: MAX_DEPTH_BY_9 NUMERIC "0" // Retrieval info: PRIVATE: OVERFLOW_CHECKING NUMERIC "1" // Retrieval info: PRIVATE: Optimize NUMERIC "2" // Retrieval info: PRIVATE: RAM_BLOCK_TYPE NUMERIC "0" // Retrieval info: PRIVATE: UNDERFLOW_CHECKING NUMERIC "1" // Retrieval info: PRIVATE: UsedW NUMERIC "1" // Retrieval info: PRIVATE: Width NUMERIC "16" // Retrieval info: PRIVATE: dc_aclr NUMERIC "1" // Retrieval info: PRIVATE: rsEmpty NUMERIC "1" // Retrieval info: PRIVATE: rsFull NUMERIC "0" // Retrieval info: PRIVATE: rsUsedW NUMERIC "1" // Retrieval info: PRIVATE: sc_aclr NUMERIC "0" // Retrieval info: PRIVATE: sc_sclr NUMERIC "0" // Retrieval info: PRIVATE: wsEmpty NUMERIC "0" // Retrieval info: PRIVATE: wsFull NUMERIC "1" // Retrieval info: PRIVATE: wsUsedW NUMERIC "1" // Retrieval info: CONSTANT: ADD_RAM_OUTPUT_REGISTER STRING "OFF" // Retrieval info: CONSTANT: CLOCKS_ARE_SYNCHRONIZED STRING "FALSE" // Retrieval info: CONSTANT: INTENDED_DEVICE_FAMILY STRING "Cyclone" // Retrieval info: CONSTANT: LPM_NUMWORDS NUMERIC "4096" // Retrieval info: CONSTANT: LPM_SHOWAHEAD STRING "ON" // Retrieval info: CONSTANT: LPM_TYPE STRING "dcfifo" // Retrieval info: CONSTANT: LPM_WIDTH NUMERIC "16" // Retrieval info: CONSTANT: LPM_WIDTHU NUMERIC "12" // Retrieval info: CONSTANT: OVERFLOW_CHECKING STRING "OFF" // Retrieval info: CONSTANT: UNDERFLOW_CHECKING STRING "OFF" // Retrieval info: CONSTANT: USE_EAB STRING "ON" // Retrieval info: USED_PORT: aclr 0 0 0 0 INPUT GND aclr // Retrieval info: USED_PORT: data 0 0 16 0 INPUT NODEFVAL data[15..0] // Retrieval info: USED_PORT: q 0 0 16 0 OUTPUT NODEFVAL q[15..0] // Retrieval info: USED_PORT: rdclk 0 0 0 0 INPUT NODEFVAL rdclk // Retrieval info: USED_PORT: rdempty 0 0 0 0 OUTPUT NODEFVAL rdempty // Retrieval info: USED_PORT: rdreq 0 0 0 0 INPUT NODEFVAL rdreq // Retrieval info: USED_PORT: rdusedw 0 0 12 0 OUTPUT NODEFVAL rdusedw[11..0] // Retrieval info: USED_PORT: wrclk 0 0 0 0 INPUT NODEFVAL wrclk // Retrieval info: USED_PORT: wrfull 0 0 0 0 OUTPUT NODEFVAL wrfull // Retrieval info: USED_PORT: wrreq 0 0 0 0 INPUT NODEFVAL wrreq // Retrieval info: USED_PORT: wrusedw 0 0 12 0 OUTPUT NODEFVAL wrusedw[11..0] // Retrieval info: CONNECT: @data 0 0 16 0 data 0 0 16 0 // Retrieval info: CONNECT: q 0 0 16 0 @q 0 0 16 0 // Retrieval info: CONNECT: @wrreq 0 0 0 0 wrreq 0 0 0 0 // Retrieval info: CONNECT: @rdreq 0 0 0 0 rdreq 0 0 0 0 // Retrieval info: CONNECT: @rdclk 0 0 0 0 rdclk 0 0 0 0 // Retrieval info: CONNECT: @wrclk 0 0 0 0 wrclk 0 0 0 0 // Retrieval info: CONNECT: rdempty 0 0 0 0 @rdempty 0 0 0 0 // Retrieval info: CONNECT: rdusedw 0 0 12 0 @rdusedw 0 0 12 0 // Retrieval info: CONNECT: wrfull 0 0 0 0 @wrfull 0 0 0 0 // Retrieval info: CONNECT: wrusedw 0 0 12 0 @wrusedw 0 0 12 0 // Retrieval info: CONNECT: @aclr 0 0 0 0 aclr 0 0 0 0 // Retrieval info: LIBRARY: altera_mf altera_mf.altera_mf_components.all // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc.v TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc.inc TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc.cmp TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc.bsf TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc_inst.v TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc_bb.v TRUE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc_waveforms.html FALSE // Retrieval info: GEN_FILE: TYPE_NORMAL fifo_4kx16_dc_wave*.jpg FALSE

/* * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 */ `ifndef SKY130_FD_SC_MS__DLYGATE4SD1_FUNCTIONAL_V `define SKY130_FD_SC_MS__DLYGATE4SD1_FUNCTIONAL_V /** * dlygate4sd1: Delay Buffer 4-stage 0.15um length inner stage gates. * * Verilog simulation functional model. */ `timescale 1ns / 1ps `default_nettype none `celldefine module sky130_fd_sc_ms__dlygate4sd1 ( X, A ); // Module ports output X; input A; // Local signals wire buf0_out_X; // Name Output Other arguments buf buf0 (buf0_out_X, A ); buf buf1 (X , buf0_out_X ); endmodule `endcelldefine `default_nettype wire `endif // SKY130_FD_SC_MS__DLYGATE4SD1_FUNCTIONAL_V

////////////////////////////////////////////////////////////////////////////// // File name : mt48lc4m16.v ////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2008 Free Model Foundry; http://www.freemodelfoundry.com // // This program is free software; you can redistribute it and/or modify // it under the terms of the GNU General Public License version 2 as // published by the Free Software Foundation. // // MODIFICATION HISTORY: // // version: | author: | mod date: | changes made: // V1.0 S.Janevski 08 Feb 27 Initial release // V1.1 S.Janevski 08 Mar 26 Assertions of wrong DQM settings during powerup removed ////////////////////////////////////////////////////////////////////////////// // PART DESCRIPTION: // // Library: RAM // Technology: LVTTL // Part: mt48lc4m16 // // Description: 1M x 16 x 4Banks SDRAM // ////////////////////////////////////////////////////////////////////////////// // Known Bugs: // ////////////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////////// // MODULE DECLARATION // ////////////////////////////////////////////////////////////////////////////// `timescale 1 ns/100 ps module mt48lc4m16 ( A11 , A10 , A9 , A8 , A7 , A6 , A5 , A4 , A3 , A2 , A1 , A0 , DQ15 , DQ14 , DQ13 , DQ12 , DQ11 , DQ10 , DQ9 , DQ8 , DQ7 , DQ6 , DQ5 , DQ4 , DQ3 , DQ2 , DQ1 , DQ0 , BA0 , BA1 , DQMH , DQML , CLK , CKE , WENeg , RASNeg , CSNeg , CASNeg ); //////////////////////////////////////////////////////////////////////// // Port / Part Pin Declarations //////////////////////////////////////////////////////////////////////// input A11 ; input A10 ; input A9 ; input A8 ; input A7 ; input A6 ; input A5 ; input A4 ; input A3 ; input A2 ; input A1 ; input A0 ; inout DQ15 ; inout DQ14 ; inout DQ13 ; inout DQ12 ; inout DQ11 ; inout DQ10 ; inout DQ9 ; inout DQ8 ; inout DQ7 ; inout DQ6 ; inout DQ5 ; inout DQ4 ; inout DQ3 ; inout DQ2 ; inout DQ1 ; inout DQ0 ; input BA0 ; input BA1 ; input DQMH ; input DQML ; input CLK ; input CKE ; input WENeg ; input RASNeg ; input CSNeg ; input CASNeg ; // interconnect path delay signals wire A11_ipd ; wire A10_ipd ; wire A9_ipd ; wire A8_ipd ; wire A7_ipd ; wire A6_ipd ; wire A5_ipd ; wire A4_ipd ; wire A3_ipd ; wire A2_ipd ; wire A1_ipd ; wire A0_ipd ; wire [11 : 0] A; assign A = {A11_ipd, A10_ipd, A9_ipd, A8_ipd, A7_ipd, A6_ipd, A5_ipd, A4_ipd, A3_ipd, A2_ipd, A1_ipd, A0_ipd }; wire DQ15_ipd ; wire DQ14_ipd ; wire DQ13_ipd ; wire DQ12_ipd ; wire DQ11_ipd ; wire DQ10_ipd ; wire DQ9_ipd ; wire DQ8_ipd ; wire DQ7_ipd ; wire DQ6_ipd ; wire DQ5_ipd ; wire DQ4_ipd ; wire DQ3_ipd ; wire DQ2_ipd ; wire DQ1_ipd ; wire DQ0_ipd ; wire [15 : 0 ] DQIn; assign DQIn = { DQ15_ipd, DQ14_ipd, DQ13_ipd, DQ12_ipd, DQ11_ipd, DQ10_ipd, DQ9_ipd, DQ8_ipd, DQ7_ipd, DQ6_ipd, DQ5_ipd, DQ4_ipd, DQ3_ipd, DQ2_ipd, DQ1_ipd, DQ0_ipd }; wire [15 : 0] DQOut; assign DQOut = { DQ15, DQ14, DQ13, DQ12, DQ11, DQ10, DQ9, DQ8, DQ7, DQ6, DQ5, DQ4, DQ3, DQ2, DQ1, DQ0 }; wire BA0_ipd ; wire BA1_ipd ; wire DQM1_ipd ; wire DQM0_ipd ; wire CLK_ipd ; wire CKE_ipd ; wire WENeg_ipd ; wire RASNeg_ipd ; wire CSNeg_ipd ; wire CASNeg_ipd ; integer bank; integer bank_tmp; // internal delays reg rct_in ; reg rct_out; reg [3:0] rcdt_in ; reg [3:0] rcdt_out; reg pre_in ; reg pre_out ; reg refreshed_in ; reg refreshed_out ; reg rcar_out ; reg rcar_in ; reg [3:0] ras_in = 1'b0; reg [3:0] ras_out = 1'b0; reg [15 : 0] DQ_zd = 16'bz; assign {DQ15_zd, DQ14_zd, DQ13_zd, DQ12_zd, DQ11_zd, DQ10_zd, DQ9_zd, DQ8_zd, DQ7_zd, DQ6_zd, DQ5_zd, DQ4_zd, DQ3_zd, DQ2_zd, DQ1_zd, DQ0_zd } = DQ_zd; parameter UserPreload = 1'b1; // parameter mem_file_name = "none"; //"mt48lc4m16.mem"; parameter mem_file_name = "mt48lc4m16.mem"; parameter TimingModel = "DefaultTimingModel"; parameter PartID = "mt48lc4m16"; parameter hi_bank = 3; parameter depth = 25'h100000; reg PoweredUp = 1'b0; reg CKEreg = 1'b0; reg CAS_Lat ; reg CAS_Lat2; reg [15:0] DataDrive = 16'bz ; // Memory array declaration integer Mem [0:(hi_bank+1)*depth*2-1]; // Type definition for state machine parameter pwron = 5'd0; parameter precharge = 5'd1; parameter idle = 5'd2; parameter mode_set = 5'd3; parameter self_refresh = 5'd4; parameter auto_refresh = 5'd5; parameter pwrdwn = 5'd6; parameter bank_act = 5'd7; parameter bank_act_pwrdwn = 5'd8; parameter write = 5'd9; parameter write_suspend = 5'd10; parameter read = 5'd11; parameter read_suspend = 5'd12; parameter write_auto_pre = 5'd13; parameter read_auto_pre = 5'd14; reg [4:0] statebank [hi_bank:0]; reg [4:0] debug_state; // Type definition for commands parameter desl = 4'd0; parameter nop = 4'd1; parameter bst = 4'd2; parameter rd = 4'd3; parameter writ = 4'd4; parameter act = 4'd5; parameter pre = 4'd6; parameter mrs = 4'd7; parameter ref = 4'd8; reg [3:0] command = desl; // burst type parameter sequential = 1'b0; parameter interleave = 1'b1; reg Burst ; // write burst mode parameter programmed = 1'b0; parameter single = 1'b1; reg WB ; //burst sequences integer intab [0:63]; reg [19:0] MemAddr [hi_bank:0]; integer BurstCnt [hi_bank:0]; integer StartAddr [hi_bank:0]; integer BurstInc [hi_bank:0]; integer BaseLoc [hi_bank:0]; integer Loc; integer BurstLen; integer Burst_Bits; reg written = 1'b0; reg chip_en = 1'b0; integer cur_bank; reg [11:0] ModeReg ; integer Ref_Cnt = 0; time Next_Ref = 0; reg [8*8:1] BankString ; reg Viol = 1'b0; reg [15:0] DataDriveOut = 16'bz; reg [15:0] DataDrive1 = 16'bz; reg [15:0] DataDrive2 = 16'bz; reg [15:0] DataDrive3 = 16'bz; reg DQM0_reg0 ; reg DQM0_reg1 ; reg DQM0_reg2 ; reg DQM1_reg0 ; reg DQM1_reg1 ; reg DQM1_reg2 ; // tdevice values: values for internal delays parameter TRAS_VAL = 37; parameter TRCD_VAL = 15; time tdevice_TRASmin = 37; time tdevice_TRASmax = 1200000; time tdevice_TRC = 66; time tdevice_TRCAR = 60; time tdevice_TRCD = TRCD_VAL; time tdevice_TRP = 15; /////////////////////////////////////////////////////////////////////////// //Interconnect Path Delay Section /////////////////////////////////////////////////////////////////////////// buf (A11_ipd, A11); buf (A10_ipd, A10); buf (A9_ipd , A9 ); buf (A8_ipd , A8 ); buf (A7_ipd , A7 ); buf (A6_ipd , A6 ); buf (A5_ipd , A5 ); buf (A4_ipd , A4 ); buf (A3_ipd , A3 ); buf (A2_ipd , A2 ); buf (A1_ipd , A1 ); buf (A0_ipd , A0 ); buf (DQ15_ipd , DQ15 ); buf (DQ14_ipd , DQ14 ); buf (DQ13_ipd , DQ13 ); buf (DQ12_ipd , DQ12 ); buf (DQ11_ipd , DQ11 ); buf (DQ10_ipd , DQ10 ); buf (DQ9_ipd , DQ9 ); buf (DQ8_ipd , DQ8 ); buf (DQ7_ipd , DQ7 ); buf (DQ6_ipd , DQ6 ); buf (DQ5_ipd , DQ5 ); buf (DQ4_ipd , DQ4 ); buf (DQ3_ipd , DQ3 ); buf (DQ2_ipd , DQ2 ); buf (DQ1_ipd , DQ1 ); buf (DQ0_ipd , DQ0 ); buf (CASNeg_ipd, CASNeg); buf (RASNeg_ipd, RASNeg); buf (BA0_ipd , BA0 ); buf (BA1_ipd , BA1 ); buf (DQM0_ipd , DQML ); buf (DQM1_ipd , DQMH ); buf (CLK_ipd , CLK ); buf (CKE_ipd , CKE ); buf (WENeg_ipd , WENeg ); buf (CSNeg_ipd , CSNeg ); /////////////////////////////////////////////////////////////////////////// // Propagation delay Section /////////////////////////////////////////////////////////////////////////// nmos (DQ15 , DQ15_zd , 1); nmos (DQ14 , DQ14_zd , 1); nmos (DQ13 , DQ13_zd , 1); nmos (DQ12 , DQ12_zd , 1); nmos (DQ11 , DQ11_zd , 1); nmos (DQ10 , DQ10_zd , 1); nmos (DQ9 , DQ9_zd , 1); nmos (DQ8 , DQ8_zd , 1); nmos (DQ7 , DQ7_zd , 1); nmos (DQ6 , DQ6_zd , 1); nmos (DQ5 , DQ5_zd , 1); nmos (DQ4 , DQ4_zd , 1); nmos (DQ3 , DQ3_zd , 1); nmos (DQ2 , DQ2_zd , 1); nmos (DQ1 , DQ1_zd , 1); nmos (DQ0 , DQ0_zd , 1); wire deg; wire chip_act; assign chip_act = chip_en; wire chip_act_deg; assign chip_act_deg = chip_act && deg; wire cas_latency2; wire cas_latency3; assign cas_latency2 = ~CAS_Lat && CAS_Lat2; assign cas_latency3 = CAS_Lat && CAS_Lat2; specify // tipd delays: interconnect path delays, mapped to input port delays. // In Verilog it is not necessary to declare any tipd delay variables, // they can be taken from SDF file // With all the other delays real delays would be taken from SDF file // tpd delays specparam tpd_CLK_DQ0 = 1; specparam tpd_CLK_DQ1 = 1; // tpw values: pulse widths specparam tpw_CLK_posedge = 1; specparam tpw_CLK_negedge = 1; // tsetup values: setup times specparam tsetup_DQ0_CLK = 1; // tDS // thold values: hold times specparam thold_DQ0_CLK = 1; // tDH // tperiod_min: minimum clock period = 1/max freq specparam tperiod_CLK_cl1_eq_1_posedge = 1; specparam tperiod_CLK_cl2_eq_1_posedge = 1; // tdevice values: values for internal delays specparam tdevice_REF = 15625 ; /////////////////////////////////////////////////////////////////////// // Input Port Delays don't require Verilog description /////////////////////////////////////////////////////////////////////// // Path delays // /////////////////////////////////////////////////////////////////////// if (~CAS_Lat && CAS_Lat2) (CLK *> DQ0) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ1) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ2) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ3) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ4) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ5) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ6) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ7) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ8) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ9) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ10) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ11) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ12) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ13) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ14) = tpd_CLK_DQ0; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ15) = tpd_CLK_DQ0; if (CAS_Lat && CAS_Lat2) (CLK *> DQ0) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ1) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ2) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ3) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ4) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ5) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ6) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ7) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ8) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ9) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ10) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ11) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ12) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ13) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ14) = tpd_CLK_DQ1; if (CAS_Lat && CAS_Lat2) (CLK *> DQ15) = tpd_CLK_DQ1; //////////////////////////////////////////////////////////////////////// // Timing Check Section //////////////////////////////////////////////////////////////////////// $setup (BA0 , posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (BA1 , posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (DQML, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (DQMH, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (CKE , posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (WENeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (CSNeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (CASNeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (RASNeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (DQ0 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ1 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ2 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ3 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ4 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ5 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ6 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ7 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ8 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ9 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ10 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ11 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ12 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ13 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ14 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ15 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (A0, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A1, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A2, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A3, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A4, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A5, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A6, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A7, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A8, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A9, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A10, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A11, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, BA0, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, BA1, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, DQML, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, DQMH, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, CKE , thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, CASNeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, RASNeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, WENeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, CSNeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A0, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A1, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A2, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A3, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A4, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A5, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A6, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A7, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A8, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A9, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A10, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A11, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ0, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ1, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ2, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ3, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ4, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ5, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ6, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ7, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ8, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ9, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ10, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ11, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ12, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ13, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ14, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ15, thold_DQ0_CLK, Viol); $width (posedge CLK &&& chip_act, tpw_CLK_posedge); $width (negedge CLK &&& chip_act, tpw_CLK_negedge); $period (posedge CLK &&& cas_latency2, tperiod_CLK_cl1_eq_1_posedge); $period (posedge CLK &&& cas_latency3, tperiod_CLK_cl2_eq_1_posedge); endspecify task generate_out ; output [15:0] DataDrive; input Bank; integer Bank; integer location; begin location = Bank * depth * 2 + Loc; DataDrive[7:0] = 8'bx; if (Mem[location] > -1) DataDrive[7:0] = Mem[location]; DataDrive[15:8] = 8'bx; if (Mem[location+1] > -1) DataDrive[15:8] = Mem[location+1]; end endtask task MemWrite; input Bank; integer Bank; integer location; begin location = Bank * depth * 2 + Loc; if (~DQM0_ipd) begin Mem[location] = -1; if (~Viol) Mem[location] = DQIn[7:0]; end if (~DQM1_ipd) begin Mem[location+1] = -1; if (~Viol) Mem[location+1] = DQIn[15:8]; end end endtask task BurstIncProc; input Bank; integer Bank; begin BurstInc[Bank] = 0; if (Burst_Bits == 1) BurstInc[Bank] = A[0:0]; if (Burst_Bits == 2) BurstInc[Bank] = A[1:0]; if (Burst_Bits == 3) BurstInc[Bank] = A[2:0]; if (Burst_Bits == 7) BurstInc[Bank] = A[6:0]; end endtask task NextStateAuto; input Bank; input state; integer Bank; reg [4:0] state; begin if (~A[10]) statebank[Bank] = state; else if (A[10]) if (state == write) statebank[Bank] = write_auto_pre; else statebank[Bank] = read_auto_pre; end endtask ////////////////////////////////////////////////////////////////////////// // Main Behavior Block // ////////////////////////////////////////////////////////////////////////// // chech when data is generated from model to avoid setup/hold check in // those occasion reg deq; always @(DQIn, DQOut) begin if (DQIn==DQOut) deq=1'b1; else deq=1'b0; end assign deg=deq; // initialize burst sequences initial begin intab[0] = 0; intab[1] = 1; intab[2] = 2; intab[3] = 3; intab[4] = 4; intab[5] = 5; intab[6] = 6; intab[7] = 7; intab[8] = 1; intab[9] = 0; intab[10] = 3; intab[11] = 2; intab[12] = 5; intab[13] = 4; intab[14] = 7; intab[15] = 6; intab[16] = 2; intab[17] = 3; intab[18] = 0; intab[19] = 1; intab[20] = 6; intab[21] = 7; intab[22] = 4; intab[23] = 5; intab[24] = 3; intab[25] = 2; intab[26] = 1; intab[27] = 0; intab[28] = 7; intab[29] = 6; intab[30] = 5; intab[31] = 4; intab[32] = 4; intab[33] = 5; intab[34] = 6; intab[35] = 7; intab[36] = 0; intab[37] = 1; intab[38] = 2; intab[39] = 3; intab[40] = 5; intab[41] = 4; intab[42] = 7; intab[43] = 6; intab[44] = 1; intab[45] = 0; intab[46] = 3; intab[47] = 2; intab[48] = 6; intab[49] = 7; intab[50] = 4; intab[51] = 5; intab[52] = 2; intab[53] = 3; intab[54] = 0; intab[55] = 1; intab[56] = 7; intab[57] = 6; intab[58] = 5; intab[59] = 4; intab[60] = 3; intab[61] = 2; intab[62] = 1; intab[63] = 0; end // initialize memory and load preload files if any initial begin: InitMemory integer i; for (i=0; i<=((hi_bank+1)*depth*2 - 1); i=i+1) begin Mem[i] = -1; end // Memory preload file // mt48lc4m16.mem file // @bbbbbb - <bbbbbb> stands for address within memory, // dd - <dd> is word to be written at Mem(bbbbbb++) // (bbbbbb is incremented at every load) if (UserPreload && !(mem_file_name == "none")) $readmemh(mem_file_name,Mem); end //Power Up time 100 us; initial begin PoweredUp = 1'b0; statebank[0] = pwron; statebank[1] = pwron; statebank[2] = pwron; statebank[3] = pwron; $display ("Powering up! Time: %d", $time); #100 PoweredUp = 1'b1; $display ("Powerup Finished at %d", $time); end always @(posedge ras_in[0]) begin:TRASrise0 // $display ("ras in for bank 0 high, tdevice_TRASmin = %d", tdevice_TRASmin); ras_out[0] <= #tdevice_TRASmin ras_in[0]; end always @(negedge ras_in[0]) begin:TRASfall0 ras_out[0] <= #tdevice_TRASmax ras_in[0]; end always @(posedge ras_in[1]) begin:TRASrise1 ras_out[1] <= #tdevice_TRASmin ras_in[1]; end always @(negedge ras_in[1]) begin:TRASfall1 ras_out[1] <= #tdevice_TRASmax ras_in[1]; end always @(posedge ras_in[2]) begin:TRASrise2 ras_out[2] <= #tdevice_TRASmin ras_in[2]; end always @(negedge ras_in[2]) begin:TRASfall2 ras_out[2] <= #tdevice_TRASmax ras_in[2]; end always @(posedge ras_in[3]) begin:TRASrise3 ras_out[3] <= #tdevice_TRASmin ras_in[3]; end always @(negedge ras_in[3]) begin:TRASfall3 ras_out[3] <= #tdevice_TRASmax ras_in[3]; end always @(posedge rcdt_in[0]) begin:TRCDrise0 // $display ("TRD went high"); rcdt_out[0] <= #5 1'b1; end always @(negedge rcdt_in[0]) begin:TRCDfall0 // $display ("TRD went low"); rcdt_out[0] <= #tdevice_TRCD 1'b0; end always @(posedge rcdt_in[1]) begin:TRCDrise1 rcdt_out[1] <= #5 1'b1; end always @(negedge rcdt_in[1]) begin:TRCDfall1 rcdt_out[1] <= #tdevice_TRCD 1'b0; end always @(posedge rcdt_in[2]) begin:TRCDrise2 rcdt_out[2] <= #5 1'b1; end always @(negedge rcdt_in[2]) begin:TRCDfall2 rcdt_out[2] <= #tdevice_TRCD 1'b0; end always @(posedge rcdt_in[3]) begin:TRCDrise3 rcdt_out[3] <= #5 1'b1; end always @(negedge rcdt_in[3]) begin:TRCDfall3 rcdt_out[3] <= #tdevice_TRCD 1'b0; end ///////////////////////////////////////////////////////////////////////// // Functional Section ///////////////////////////////////////////////////////////////////////// always @(posedge CLK) begin if ($time > Next_Ref && PoweredUp && Ref_Cnt > 0) begin Ref_Cnt = Ref_Cnt - 1; // Next_Ref = $time + tdevice_REF; Next_Ref = $time + 15625; end if (CKEreg) begin if (~CSNeg_ipd) chip_en = 1; else chip_en = 0; end if (CKEreg && ~CSNeg_ipd) begin if (WENeg_ipd == 1'bx) $display(" Unusable value for WENeg "); if (RASNeg_ipd == 1'bx) $display(" Unusable value for RASNeg "); if (CASNeg_ipd == 1'bx) $display(" Unusable value for CASNeg "); // Command Decode if (RASNeg_ipd && CASNeg_ipd && WENeg_ipd) command = nop; else if (~RASNeg_ipd && CASNeg_ipd && WENeg_ipd) command = act; else if (RASNeg_ipd && ~CASNeg_ipd && WENeg_ipd) command = rd; else if (RASNeg_ipd && ~CASNeg_ipd && ~WENeg_ipd) command = writ; else if (RASNeg_ipd && CASNeg_ipd && ~WENeg_ipd) command = bst; else if (~RASNeg_ipd && CASNeg_ipd && ~WENeg_ipd) command = pre; else if (~RASNeg_ipd && ~CASNeg_ipd && WENeg_ipd) command = ref; else if (~RASNeg_ipd && ~CASNeg_ipd && ~WENeg_ipd) command = mrs; // PowerUp Check if (~(PoweredUp) && command != nop) begin $display (" Incorrect power up. Command %h issued before ", command); $display (" power up complete. "); end // Bank Decode if (~BA0_ipd && ~BA1_ipd) cur_bank = 0; else if (BA0_ipd && ~BA1_ipd) cur_bank = 1; else if (~BA0_ipd && BA1_ipd) cur_bank = 2; else if (BA0_ipd && BA1_ipd) cur_bank = 3; else begin $display ("Could not decode bank selection - results"); $display ("may be incorrect."); end end // The Big State Machine if (CKEreg) begin if (CSNeg_ipd == 1'bx) $display ("Unusable value for CSNeg"); if (CSNeg_ipd) command = nop; // DQM pipeline DQM0_reg2 = DQM0_reg1; DQM0_reg1 = DQM0_reg0; DQM0_reg0 = DQM0_ipd; DQM1_reg2 = DQM1_reg1; DQM1_reg1 = DQM1_reg0; DQM1_reg0 = DQM1_ipd; // by default data drive is Z, might get over written in one // of the passes below DataDrive = 16'bz; debug_state <= statebank[0]; for (bank = 0; bank <= hi_bank; bank = bank + 1) begin case (statebank[bank]) pwron : begin if (~PoweredUp) begin if (command != nop) $display ("Only NOPs allowed during power up."); DataDrive = 16'bz; end else if (command == pre && (cur_bank == bank || A[10])) begin statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end end precharge : begin //$display ("\tRAM: Precharge"); if (cur_bank == bank) // It is only an error if this bank is selected if (command != nop && command != pre) begin $display ("Illegal command received "); $display ("during precharge.",$time); end end idle : begin if (command == nop || command == bst || command == pre || cur_bank != bank) begin end else if (command == mrs) begin if (statebank[0] == idle && statebank[1] == idle && statebank[2] == idle && statebank[3] == idle) begin ModeReg = A; statebank[bank] = mode_set; end end else if (command == ref) begin if (statebank[0] == idle && statebank[1] == idle && statebank[2] == idle && statebank[3] == idle) if (CKE) begin statebank[bank] = auto_refresh; statebank[bank] <= #tdevice_TRCAR idle; end else begin statebank[0] = self_refresh; statebank[1] = self_refresh; statebank[2] = self_refresh; statebank[3] = self_refresh; end end else if (command == act) begin $display ("\tRAM: Activate Command Received"); statebank[bank] = bank_act; ras_in[bank] = 1'b1; ras_in [bank] <= #70 1'b0; rct_in = 1'b1; rct_in <= #1 1'b0; rcdt_in[bank] = 1'b1; rcdt_in[bank] <= #1 1'b0; MemAddr[bank][19:8] = A; // latch row addr end else $display ("Illegal command received in idle state.",$time); end mode_set : begin $display ("\tRAM: Setting mode to %h", ModeReg); if (ModeReg[7] != 0 || ModeReg[8] != 0) $display ("Illegal operating mode set."); if (command != nop) begin $display ("Illegal command received during mode"); $display ("set.",$time); end // read burst length if (ModeReg[2:0] == 3'b000) begin BurstLen = 1; Burst_Bits = 0; end else if (ModeReg[2:0] == 3'b001) begin BurstLen = 2; Burst_Bits = 1; end else if (ModeReg[2:0] == 3'b010) begin BurstLen = 4; Burst_Bits = 2; end else if (ModeReg[2:0] == 3'b011) begin BurstLen = 8; Burst_Bits = 3; end else if (ModeReg[2:0] == 3'b111) begin BurstLen = 256; Burst_Bits = 7; end else $display ("Invalid burst length specified."); $display ("Burst Length set to %d", BurstLen); // read burst type if (~ModeReg[3]) begin Burst = sequential; $display ("Burst Type == Sequential"); end else if (ModeReg[3]) Burst = interleave; else $display ("Invalid burst type specified."); // read CAS latency if (ModeReg[6:4] == 3'b010) begin CAS_Lat = 1'b0; CAS_Lat2 = 1'b1; end else if (ModeReg[6:4] == 3'b011) begin CAS_Lat = 1'b1; CAS_Lat2 = 1'b1; end else $display ("CAS Latency set incorrecty"); // write burst mode if (~ModeReg[9]) WB = programmed; else if (ModeReg[9]) WB = single; else $display ("Invalid burst type specified."); statebank[bank] = idle; end auto_refresh : begin //$display ("\tRAM: Auto Refresh Entered"); if (Ref_Cnt < 8192) Ref_Cnt = Ref_Cnt + 1; if (command != nop) begin //$display ("Illegal command received during autorefresh: %h", command); //$display ("auto_refresh.",$time); end end bank_act : begin $display ("\tRAM: Bank Activate"); if (command == pre && (cur_bank == bank || A[10])) begin if (~ras_out[bank]) begin $display ("precharge command does not meet tRAS"); $display ("time", $time); end statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else if (command == nop || command == bst || cur_bank != bank) begin end else if (command == rd) begin if (rcdt_out[bank]) begin $display ("read command received too soon"); $display ("after active",$time); $display ("rcdt_out[bank] == %d", rcdt_out[bank]); end if (A[10] == 1'bx) begin $display ("A(10) = X during read command."); $display ("Next state unknown."); end MemAddr[bank][7:0] = 8'b0;// clr old addr // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; BurstIncProc(bank); StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2*(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive,bank); BurstCnt[bank] = 1; NextStateAuto(bank, read); bank_tmp = bank; end else if (command == writ) begin if (rcdt_out[bank]) begin $display ("write command received too soon"); $display ("after active",$time); $display ("bank: %h", bank); $display ("rcdt_out[bank] = %d", rcdt_out[bank]); end if (A[10] == 1'bx) begin $display ("A(10) = X during write command."); $display ("Next state unknown."); end MemAddr[bank][7:0] = 8'b0; // clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2*(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = 1'b1; NextStateAuto(bank, write); written = 1'b1; end else if (cur_bank == bank || command == mrs) begin $display ("Illegal command received in"); $display ("active state",$time); end end write : begin $display ("\tRAM: Write: %h", DQIn); if (command == bst) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; end else if (command == rd) if (cur_bank == bank) begin MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2*(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = 1'b1; NextStateAuto(bank, read); end else statebank[bank] = bank_act; else if (command == writ) if (cur_bank == bank) begin MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2*(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = 1'b1; if (A[10]) statebank[bank] = write_auto_pre; end else statebank[bank] = bank_act; else if (command == pre && (cur_bank == bank || A[10])) begin if (~ras_out[bank]) begin $display ("precharge command does not meet tRAS time",$time); end if (~DQM0_ipd) begin $display ("DQM0 should be held high, data is"); $display ("lost.",$time); end if (~DQM1_ipd) begin $display ("DQM1 should be held high, data is"); $display ("lost.",$time); end statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else if (command == nop || cur_bank != bank) if (BurstCnt[bank] == BurstLen || WB == single) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]*8 + BurstCnt[bank]]; Loc = 2*(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = BurstCnt[bank] + 1; end else if (cur_bank == bank) $display ("Illegal command received in write state",$time); end read : begin $display ("\tRAM: Read"); if (command == bst) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; end else if (command == rd) if (cur_bank == bank) begin MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2*(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = 1'b1; NextStateAuto(bank, read); end else statebank[bank] = bank_act; else if (command == writ) if (cur_bank == bank) begin if (rcdt_out[bank]) begin $display ("write command received too soon after active",$time); $display ("Bank: %h", bank); $display ("rcdt_out[bank]: %h", rcdt_out[bank]); end if (A[10] == 1'bx) begin $display ("A(10) = X during write command."); $display ("Next state unknown."); end MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 2*(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = 1'b1; NextStateAuto(bank,write); end else statebank[bank] = bank_act; else if (command == pre && (cur_bank == bank || A[10])) begin if (~ras_out[bank]) begin $display ("Precharge command does not meet tRAS time",$time); end statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else if (command == nop || cur_bank != bank) begin if (BurstCnt[bank] == BurstLen) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]*8 + BurstCnt[bank]]; Loc = 2*(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = BurstCnt[bank] + 1; end end else if (cur_bank == bank) $display ("Illegal command received in read state",$time); end write_auto_pre : begin $display ("\tRAM: Write with auto precharge"); if (command == nop || cur_bank != bank) if (BurstCnt[bank] == BurstLen || WB == single) begin statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]*8 + BurstCnt[bank]]; Loc = 2*(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = BurstCnt[bank] + 1; end else $display ("Illegal command received in write state.",$time); end read_auto_pre : begin $display ("\tRAM: Read with auto precharge"); if (command == nop || (cur_bank != bank && command != rd && command != writ)) if (BurstCnt[bank] == BurstLen) begin $display ("\tRAM: Read W/ SP Continue Reading"); statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin $display ("\tRAM: Read W/ AP Start Reading"); if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]*8 + BurstCnt[bank]]; Loc = 2*(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = BurstCnt[bank] + 1; end else if ((command == rd || command == writ) && cur_bank != bank) begin $display ("\tRAM: Case 3"); statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else $display ("Illegal command received in read state",$time); end endcase end // Check Refresh Status if (written && (Ref_Cnt == 0)) $display ("memory not refreshed (by ref_cnt)", $time); DataDrive3 = DataDrive2; DataDrive2 = DataDrive1; DataDrive1 = DataDrive; end // Latency adjustments and DQM read masking if (~DQM0_reg1) if (CAS_Lat && CAS_Lat2) DataDriveOut[7:0] = DataDrive3[7:0]; else DataDriveOut[7:0] = DataDrive2[7:0]; else DataDriveOut[7:0] = 8'bz; if (~DQM1_reg1) if (CAS_Lat && CAS_Lat2) DataDriveOut[15:8] = DataDrive3[15:8]; else DataDriveOut[15:8] = DataDrive2[15:8]; else DataDriveOut[15:8] = 8'bz; // The Powering-up State Machine if (~CKEreg && CKE_ipd) begin if (CSNeg_ipd == 1'bx) $display ("Unusable value for CSNeg"); if (CSNeg_ipd) command = nop; case (statebank[cur_bank]) write_suspend : begin statebank[cur_bank] = write; end read_suspend : begin statebank[cur_bank] = read; end self_refresh : begin statebank[0] <= #tdevice_TRP idle; statebank[1] <= #tdevice_TRP idle; statebank[2] <= #tdevice_TRP idle; statebank[3] <= #tdevice_TRP idle; Ref_Cnt = 8192; if (command != nop) begin $display ("Illegal command received during self"); $display ("refresh",$time); end end pwrdwn : begin statebank[0] = idle; statebank[1] = idle; statebank[2] = idle; statebank[3] = idle; end bank_act_pwrdwn : begin statebank[cur_bank] = bank_act; end endcase end // The Powering-down State Machine if (CKEreg && ~CKE_ipd) begin if (CSNeg_ipd == 1'bx) $display ("Unusable value for CSNeg"); if (CSNeg_ipd) command = nop; case (statebank[cur_bank]) idle : begin if (command == nop) begin statebank[0] = pwrdwn; statebank[1] = pwrdwn; statebank[2] = pwrdwn; statebank[3] = pwrdwn; end end write : begin statebank[cur_bank] = write_suspend; end read : begin statebank[cur_bank] = read_suspend; end bank_act : begin statebank[cur_bank] = bank_act_pwrdwn; end endcase end CKEreg = CKE_ipd; end always @(DataDriveOut) begin DQ_zd = DataDriveOut; end reg TRASMIN_In, TRASMAX_In, TRC_In , TRCAR_In; reg TRCD_In , TRP_In , TWR_In; wire TRASMIN_Out,TRASMAX_Out,TRC_Out,TRCAR_Out, TRCD_Out, TRP_Out, TWR_Out; BUFFER BUF_TRASMIN (TRASMIN_Out , TRASMIN_In); BUFFER BUF_TRASMAX (TRASMAX_Out , TRASMAX_In); BUFFER BUF_TRC (TRC_Out , TRC_In); BUFFER BUF_TRCAR (TRCAR_Out, TRCAR_In); BUFFER BUF_TRCD (TRCD_Out , TRCD_In); BUFFER BUF_TRP (TRP_Out , TRP_In); initial begin TRASMIN_In = 1; TRASMAX_In = 1; TRC_In = 1; TRCAR_In = 1; TRCD_In = 1'b1; TRP_In = 1; TWR_In = 1; end /* always @(posedge TRC_Out) begin tdevice_TRC = $time; end always @(posedge TRASMIN_Out) begin tdevice_TRASmin = $time; end always @(posedge TRASMAX_Out) begin tdevice_TRASmax = $time; end always @(posedge TRCAR_Out) begin tdevice_TRCAR = $time; end always @(posedge TRCD_Out) begin tdevice_TRCD = $time; end always @(posedge TRP_Out) begin tdevice_TRP = $time; end */ endmodule module BUFFER (OUT,IN); input IN; output OUT; buf (OUT, IN); endmodule

// ============================================================== // File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC // Version: 2014.4 // Copyright (C) 2014 Xilinx Inc. All rights reserved. // // ============================================================== `timescale 1 ns / 1 ps module image_filter_Loop_1_proc_line_buffer_0_0_val_ram (addr0, ce0, q0, addr1, ce1, d1, we1, clk); parameter DWIDTH = 8; parameter AWIDTH = 11; parameter MEM_SIZE = 1921; input[AWIDTH-1:0] addr0; input ce0; output reg[DWIDTH-1:0] q0; input[AWIDTH-1:0] addr1; input ce1; input[DWIDTH-1:0] d1; input we1; input clk; (* ram_style = "block" *)reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) begin ram[addr1] <= d1; end end end endmodule `timescale 1 ns / 1 ps module image_filter_Loop_1_proc_line_buffer_0_0_val( reset, clk, address0, ce0, q0, address1, ce1, we1, d1); parameter DataWidth = 32'd8; parameter AddressRange = 32'd1921; parameter AddressWidth = 32'd11; input reset; input clk; input[AddressWidth - 1:0] address0; input ce0; output[DataWidth - 1:0] q0; input[AddressWidth - 1:0] address1; input ce1; input we1; input[DataWidth - 1:0] d1; image_filter_Loop_1_proc_line_buffer_0_0_val_ram image_filter_Loop_1_proc_line_buffer_0_0_val_ram_U( .clk( clk ), .addr0( address0 ), .ce0( ce0 ), .q0( q0 ), .addr1( address1 ), .ce1( ce1 ), .d1( d1 ), .we1( we1 )); endmodule

`timescale 1ns / 1ps // KCP53002 Furcula to Wishbone bus bridge // // Note that Furcula is, in reality, a slight modification of Wishbone. // Since these two interconnects share so many signals in common, the // interface to the bridge is kept very small. module bridge( // FURCULA BUS input f_signed_i, input [1:0] f_siz_i, input [2:0] f_adr_i, input [63:0] f_dat_i, output [63:0] f_dat_o, // WISHBONE BUS output [7:0] wb_sel_o, output [63:0] wb_dat_o, input [63:0] wb_dat_i ); // Wishbone SEL_O signal generation. wire size_byte = (f_siz_i == 2'b00); wire size_hword = (f_siz_i == 2'b01); wire size_word = (f_siz_i == 2'b10); wire size_dword = (f_siz_i == 2'b11); wire ab7 = f_adr_i[2:0] == 3'b111; wire ab6 = f_adr_i[2:0] == 3'b110; wire ab5 = f_adr_i[2:0] == 3'b101; wire ab4 = f_adr_i[2:0] == 3'b100; wire ab3 = f_adr_i[2:0] == 3'b011; wire ab2 = f_adr_i[2:0] == 3'b010; wire ab1 = f_adr_i[2:0] == 3'b001; wire ab0 = f_adr_i[2:0] == 3'b000; wire ah3 = f_adr_i[2:1] == 2'b11; wire ah2 = f_adr_i[2:1] == 2'b10; wire ah1 = f_adr_i[2:1] == 2'b01; wire ah0 = f_adr_i[2:1] == 2'b00; wire aw1 = f_adr_i[2] == 1'b1; wire aw0 = f_adr_i[2] == 1'b0; wire den = size_dword; wire wen1 = size_word & aw1; wire wen0 = size_word & aw0; wire hen3 = size_hword & ah3; wire hen2 = size_hword & ah2; wire hen1 = size_hword & ah1; wire hen0 = size_hword & ah0; wire ben7 = size_byte & ab7; wire ben6 = size_byte & ab6; wire ben5 = size_byte & ab5; wire ben4 = size_byte & ab4; wire ben3 = size_byte & ab3; wire ben2 = size_byte & ab2; wire ben1 = size_byte & ab1; wire ben0 = size_byte & ab0; wire sel7 = den | wen1 | hen3 | ben7; wire sel6 = den | wen1 | hen3 | ben6; wire sel5 = den | wen1 | hen2 | ben5; wire sel4 = den | wen1 | hen2 | ben4; wire sel3 = den | wen0 | hen1 | ben3; wire sel2 = den | wen0 | hen1 | ben2; wire sel1 = den | wen0 | hen0 | ben1; wire sel0 = den | wen0 | hen0 | ben0; assign wb_sel_o = {sel7, sel6, sel5, sel4, sel3, sel2, sel1, sel0}; // Furcula-to-Wishbone Data Routing wire [7:0] od7 = (size_byte ? f_dat_i[7:0] : 0) | (size_hword ? f_dat_i[15:8] : 0) | (size_word ? f_dat_i[31:24] : 0) | (size_dword ? f_dat_i[63:56] : 0); wire [7:0] od6 = (size_byte ? f_dat_i[7:0] : 0) | (size_hword ? f_dat_i[7:0] : 0) | (size_word ? f_dat_i[23:16] : 0) | (size_dword ? f_dat_i[55:48] : 0); wire [7:0] od5 = (size_byte ? f_dat_i[7:0] : 0) | (size_hword ? f_dat_i[15:8] : 0) | (size_word ? f_dat_i[15:8] : 0) | (size_dword ? f_dat_i[47:40] : 0); wire [7:0] od4 = (size_byte ? f_dat_i[7:0] : 0) | (size_hword ? f_dat_i[7:0] : 0) | (size_word ? f_dat_i[7:0] : 0) | (size_dword ? f_dat_i[39:32] : 0); wire [7:0] od3 = (size_byte ? f_dat_i[7:0] : 0) | (size_hword ? f_dat_i[15:8] : 0) | (size_word ? f_dat_i[31:24] : 0) | (size_dword ? f_dat_i[31:24] : 0); wire [7:0] od2 = (size_byte ? f_dat_i[7:0] : 0) | (size_hword ? f_dat_i[7:0] : 0) | (size_word ? f_dat_i[23:16] : 0) | (size_dword ? f_dat_i[23:16] : 0); wire [7:0] od1 = (size_byte ? f_dat_i[7:0] : 0) | (size_hword ? f_dat_i[15:8] : 0) | (size_word ? f_dat_i[15:8] : 0) | (size_dword ? f_dat_i[15:8] : 0); wire [7:0] od0 = f_dat_i[7:0]; assign wb_dat_o = {od7, od6, od5, od4, od3, od2, od1, od0}; // Wishbone to Furcula Data Routing wire [31:0] id2 = (wen1 ? wb_dat_i[63:32] : 0) | (wen0 ? wb_dat_i[31:0] : 0); wire [15:0] id1 = (hen3 ? wb_dat_i[63:48] : 0) | (hen2 ? wb_dat_i[47:32] : 0) | (hen1 ? wb_dat_i[31:16] : 0) | (hen0 ? wb_dat_i[15:0] : 0); wire [7:0] id0 = (ben7 ? wb_dat_i[63:56] : 0) | (ben6 ? wb_dat_i[55:48] : 0) | (ben5 ? wb_dat_i[47:40] : 0) | (ben4 ? wb_dat_i[39:32] : 0) | (ben3 ? wb_dat_i[31:24] : 0) | (ben2 ? wb_dat_i[23:16] : 0) | (ben1 ? wb_dat_i[15:8] : 0) | (ben0 ? wb_dat_i[7:0] : 0); wire [63:32] id2s = (f_signed_i ? {32{id2[31]}} : 32'd0); wire [63:16] id1s = (f_signed_i ? {48{id1[15]}} : 48'd0); wire [63:8] id0s = (f_signed_i ? {56{id0[7]}} : 56'd0); assign f_dat_o = (size_dword ? wb_dat_i : 0) | (size_word ? {id2s, id2} : 0) | (size_hword ? {id1s, id1} : 0) | (size_byte ? {id0s, id0} : 0); endmodule

/* File: eproto_tx.v This file is part of the Parallella Project. Copyright (C) 2014 Adapteva, Inc. Contributed by Fred Huettig <[email protected]> This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program (see the file COPYING). If not, see <http://www.gnu.org/licenses/>. */ /* ######################################################################## EPIPHANY eLink TX Protocol block ######################################################################## This block takes standard eMesh protocol (104-bit transactions) and encodes the bytes into 8-byte parallel outputs for the output serializers. */ module eproto_tx (/*AUTOARG*/ // Outputs emtx_rd_wait, emtx_wr_wait, emtx_ack, txframe_p, txdata_p, // Inputs reset, emtx_access, emtx_write, emtx_datamode, emtx_ctrlmode, emtx_dstaddr, emtx_srcaddr, emtx_data, txlclk_p, tx_rd_wait, tx_wr_wait ); // System reset input input reset; // Input from TX Arbiter input emtx_access; input emtx_write; input [1:0] emtx_datamode; input [3:0] emtx_ctrlmode; input [31:0] emtx_dstaddr; input [31:0] emtx_srcaddr; input [31:0] emtx_data; output emtx_rd_wait; output emtx_wr_wait; output emtx_ack; // Parallel interface, 8 eLink bytes at a time input txlclk_p; // Parallel-rate clock from eClock block output [7:0] txframe_p; output [63:0] txdata_p; input tx_rd_wait; // The wait signals are passed through input tx_wr_wait; // to the emesh interfaces //############# //# Configuration bits //############# //############ //# Local regs & wires //############ reg emtx_ack; // Acknowledge transaction reg [7:0] txframe_p; reg [63:0] txdata_p; //############ //# Logic //############ // TODO: Bursts always @( posedge txlclk_p or posedge reset ) begin if( reset ) begin emtx_ack <= 1'b0; txframe_p <= 'd0; txdata_p <= 'd0; end else begin if( emtx_access & ~emtx_ack ) begin emtx_ack <= 1'b1; txframe_p <= 8'h3F; txdata_p <= { 8'd0, // Not used 8'd0, ~emtx_write, 7'd0, // B0- TODO: For bursts, add the inc bit emtx_ctrlmode, emtx_dstaddr[31:28], // B1 emtx_dstaddr[27:4], // B2, B3, B4 emtx_dstaddr[3:0], emtx_datamode, emtx_write, emtx_access // B5 }; end else if( emtx_ack ) begin // if ( emtx_access & ~emtx_ack ) emtx_ack <= 1'b0; txframe_p <= 8'hFF; txdata_p <= { emtx_data, emtx_srcaddr }; end else begin emtx_ack <= 1'b0; txframe_p <= 8'h00; txdata_p <= 64'd0; end end // else: !if( reset ) end // always @ ( posedge txlclk_p or reset ) //############################# //# Wait signals //############################# reg rd_wait_sync; reg wr_wait_sync; reg emtx_rd_wait; reg emtx_wr_wait; always @( posedge txlclk_p ) begin rd_wait_sync <= tx_rd_wait; emtx_rd_wait <= rd_wait_sync; wr_wait_sync <= tx_wr_wait; emtx_wr_wait <= wr_wait_sync; end endmodule // eproto_tx

`timescale 1ns / 1ps //////////////////////////////////////////////////////////////////////////////// // Company: // Engineer: // // Create Date: 14:40:38 05/31/2011 // Design Name: main // Module Name: /home/ikari/prj/sd2snes/verilog/sd2snes/main_tf.v // Project Name: sd2snes // Target Device: // Tool versions: // Description: // // Verilog Test Fixture created by ISE for module: main // // Dependencies: // // Revision: // Revision 0.01 - File Created // Additional Comments: // //////////////////////////////////////////////////////////////////////////////// module main_tf; // Inputs reg CLKIN; reg [23:0] SNES_ADDR; reg SNES_READ; reg SNES_WRITE; reg SNES_CS; reg SNES_CPU_CLK; reg SNES_REFRESH; reg SNES_SYSCLK; reg SPI_MOSI; reg SPI_SS; reg MCU_OVR; reg [3:0] SD_DAT; // Outputs wire SNES_DATABUS_OE; wire SNES_DATABUS_DIR; wire IRQ_DIR; wire [22:0] ROM_ADDR; wire ROM_CE; wire ROM_OE; wire ROM_WE; wire ROM_BHE; wire ROM_BLE; wire [18:0] RAM_ADDR; wire RAM_CE; wire RAM_OE; wire RAM_WE; wire DAC_MCLK; wire DAC_LRCK; wire DAC_SDOUT; // Bidirs wire [7:0] SNES_DATA; wire SNES_IRQ; wire [15:0] ROM_DATA; wire [7:0] RAM_DATA; wire SPI_MISO; wire SPI_SCK; wire SD_CMD; wire SD_CLK; // Instantiate the Unit Under Test (UUT) main uut ( .CLKIN(CLKIN), .SNES_ADDR(SNES_ADDR), .SNES_READ(SNES_READ), .SNES_WRITE(SNES_WRITE), .SNES_CS(SNES_CS), .SNES_DATA(SNES_DATA), .SNES_CPU_CLK(SNES_CPU_CLK), .SNES_REFRESH(SNES_REFRESH), .SNES_IRQ(SNES_IRQ), .SNES_DATABUS_OE(SNES_DATABUS_OE), .SNES_DATABUS_DIR(SNES_DATABUS_DIR), .IRQ_DIR(IRQ_DIR), .SNES_SYSCLK(SNES_SYSCLK), .ROM_DATA(ROM_DATA), .ROM_ADDR(ROM_ADDR), .ROM_CE(ROM_CE), .ROM_OE(ROM_OE), .ROM_WE(ROM_WE), .ROM_BHE(ROM_BHE), .ROM_BLE(ROM_BLE), .RAM_DATA(RAM_DATA), .RAM_ADDR(RAM_ADDR), .RAM_CE(RAM_CE), .RAM_OE(RAM_OE), .RAM_WE(RAM_WE), .SPI_MOSI(SPI_MOSI), .SPI_MISO(SPI_MISO), .SPI_SS(SPI_SS), .SPI_SCK(SPI_SCK), .MCU_OVR(MCU_OVR), .DAC_MCLK(DAC_MCLK), .DAC_LRCK(DAC_LRCK), .DAC_SDOUT(DAC_SDOUT), .SD_DAT(SD_DAT), .SD_CMD(SD_CMD), .SD_CLK(SD_CLK) ); integer i; reg [7:0] SNES_DATA_OUT; reg [7:0] SNES_DATA_IN; assign SNES_DATA = (!SNES_READ) ? 8'bZ : SNES_DATA_IN; initial begin // Initialize Inputs CLKIN = 0; SNES_ADDR = 0; SNES_READ = 1; SNES_WRITE = 1; SNES_CS = 0; SNES_CPU_CLK = 0; SNES_REFRESH = 0; SNES_SYSCLK = 0; SPI_MOSI = 0; SPI_SS = 0; MCU_OVR = 1; SD_DAT = 0; // Wait 100 ns for global reset to finish #500; // Add stimulus here SNES_ADDR = 24'h208000; SNES_DATA_IN = 8'h1f; SNES_WRITE = 0; #100 SNES_WRITE = 1; #100; for (i = 0; i < 4096; i = i + 1) begin #140 SNES_READ = 0; SNES_CPU_CLK = 1; #140 SNES_READ = 1; SNES_CPU_CLK = 0; end end always #24 CLKIN = ~CLKIN; endmodule

// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Description: Read Data Response AXI3 Slave Converter // Forwards and re-assembles split transactions. // // Verilog-standard: Verilog 2001 //-------------------------------------------------------------------------- // // Structure: // r_axi3_conv // //-------------------------------------------------------------------------- `timescale 1ps/1ps (* DowngradeIPIdentifiedWarnings="yes" *) module axi_protocol_converter_v2_1_r_axi3_conv # ( parameter C_FAMILY = "none", parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_ADDR_WIDTH = 32, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_SUPPORT_SPLITTING = 1, // Implement transaction splitting logic. // Disabled whan all connected masters are AXI3 and have same or narrower data width. parameter integer C_SUPPORT_BURSTS = 1 // Disabled when all connected masters are AxiLite, // allowing logic to be simplified. ) ( // System Signals input wire ACLK, input wire ARESET, // Command Interface input wire cmd_valid, input wire cmd_split, output wire cmd_ready, // Slave Interface Read Data Ports output wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID, output wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA, output wire [2-1:0] S_AXI_RRESP, output wire S_AXI_RLAST, output wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire S_AXI_RVALID, input wire S_AXI_RREADY, // Master Interface Read Data Ports input wire [C_AXI_ID_WIDTH-1:0] M_AXI_RID, input wire [C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA, input wire [2-1:0] M_AXI_RRESP, input wire M_AXI_RLAST, input wire [C_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER, input wire M_AXI_RVALID, output wire M_AXI_RREADY ); ///////////////////////////////////////////////////////////////////////////// // Variables for generating parameter controlled instances. ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Local params ///////////////////////////////////////////////////////////////////////////// // Constants for packing levels. localparam [2-1:0] C_RESP_OKAY = 2'b00; localparam [2-1:0] C_RESP_EXOKAY = 2'b01; localparam [2-1:0] C_RESP_SLVERROR = 2'b10; localparam [2-1:0] C_RESP_DECERR = 2'b11; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// // Throttling help signals. wire cmd_ready_i; wire pop_si_data; wire si_stalling; // Internal MI-side control signals. wire M_AXI_RREADY_I; // Internal signals for SI-side. wire [C_AXI_ID_WIDTH-1:0] S_AXI_RID_I; wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA_I; wire [2-1:0] S_AXI_RRESP_I; wire S_AXI_RLAST_I; wire [C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER_I; wire S_AXI_RVALID_I; wire S_AXI_RREADY_I; ///////////////////////////////////////////////////////////////////////////// // Handle interface handshaking: // // Forward data from MI-Side to SI-Side while a command is available. When // the transaction has completed the command is popped from the Command FIFO. // // ///////////////////////////////////////////////////////////////////////////// // Pop word from SI-side. assign M_AXI_RREADY_I = ~si_stalling & cmd_valid; assign M_AXI_RREADY = M_AXI_RREADY_I; // Indicate when there is data available @ SI-side. assign S_AXI_RVALID_I = M_AXI_RVALID & cmd_valid; // Get SI-side data. assign pop_si_data = S_AXI_RVALID_I & S_AXI_RREADY_I; // Signal that the command is done (so that it can be poped from command queue). assign cmd_ready_i = cmd_valid & pop_si_data & M_AXI_RLAST; assign cmd_ready = cmd_ready_i; // Detect when MI-side is stalling. assign si_stalling = S_AXI_RVALID_I & ~S_AXI_RREADY_I; ///////////////////////////////////////////////////////////////////////////// // Simple AXI signal forwarding: // // USER, ID, DATA and RRESP passes through untouched. // // LAST has to be filtered to remove any intermediate LAST (due to split // trasactions). LAST is only removed for the first parts of a split // transaction. When splitting is unsupported is the LAST filtering completely // completely removed. // ///////////////////////////////////////////////////////////////////////////// // Calculate last, i.e. mask from split transactions. assign S_AXI_RLAST_I = M_AXI_RLAST & ( ~cmd_split | ( C_SUPPORT_SPLITTING == 0 ) ); // Data is passed through. assign S_AXI_RID_I = M_AXI_RID; assign S_AXI_RUSER_I = M_AXI_RUSER; assign S_AXI_RDATA_I = M_AXI_RDATA; assign S_AXI_RRESP_I = M_AXI_RRESP; ///////////////////////////////////////////////////////////////////////////// // SI-side output handling // ///////////////////////////////////////////////////////////////////////////// // TODO: registered? assign S_AXI_RREADY_I = S_AXI_RREADY; assign S_AXI_RVALID = S_AXI_RVALID_I; assign S_AXI_RID = S_AXI_RID_I; assign S_AXI_RDATA = S_AXI_RDATA_I; assign S_AXI_RRESP = S_AXI_RRESP_I; assign S_AXI_RLAST = S_AXI_RLAST_I; assign S_AXI_RUSER = S_AXI_RUSER_I; endmodule

/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 */ `ifndef SKY130_FD_SC_LP__A32OI_BLACKBOX_V `define SKY130_FD_SC_LP__A32OI_BLACKBOX_V /** * a32oi: 3-input AND into first input, and 2-input AND into * 2nd input of 2-input NOR. * * Y = !((A1 & A2 & A3) | (B1 & B2)) * * Verilog stub definition (black box without power pins). * * WARNING: This file is autogenerated, do not modify directly! */ `timescale 1ns / 1ps `default_nettype none (* blackbox *) module sky130_fd_sc_lp__a32oi ( Y , A1, A2, A3, B1, B2 ); output Y ; input A1; input A2; input A3; input B1; input B2; // Voltage supply signals supply1 VPWR; supply0 VGND; supply1 VPB ; supply0 VNB ; endmodule `default_nettype wire `endif // SKY130_FD_SC_LP__A32OI_BLACKBOX_V

//----------------------------------------------------------------------------- //-- (c) Copyright 2010 Xilinx, Inc. All rights reserved. //-- //-- This file contains confidential and proprietary information //-- of Xilinx, Inc. and is protected under U.S. and //-- international copyright and other intellectual property //-- laws. //-- //-- DISCLAIMER //-- This disclaimer is not a license and does not grant any //-- rights to the materials distributed herewith. Except as //-- otherwise provided in a valid license issued to you by //-- Xilinx, and to the maximum extent permitted by applicable //-- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND //-- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES //-- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING //-- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- //-- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and //-- (2) Xilinx shall not be liable (whether in contract or tort, //-- including negligence, or under any other theory of //-- liability) for any loss or damage of any kind or nature //-- related to, arising under or in connection with these //-- materials, including for any direct, or any indirect, //-- special, incidental, or consequential loss or damage //-- (including loss of data, profits, goodwill, or any type of //-- loss or damage suffered as a result of any action brought //-- by a third party) even if such damage or loss was //-- reasonably foreseeable or Xilinx had been advised of the //-- possibility of the same. //-- //-- CRITICAL APPLICATIONS //-- Xilinx products are not designed or intended to be fail- //-- safe, or for use in any application requiring fail-safe //-- performance, such as life-support or safety devices or //-- systems, Class III medical devices, nuclear facilities, //-- applications related to the deployment of airbags, or any //-- other applications that could lead to death, personal //-- injury, or severe property or environmental damage //-- (individually and collectively, "Critical //-- Applications"). Customer assumes the sole risk and //-- liability of any use of Xilinx products in Critical //-- Applications, subject only to applicable laws and //-- regulations governing limitations on product liability. //-- //-- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS //-- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Description: Up-Sizer // Up-Sizer for generic SI- and MI-side data widths. This module instantiates // Address, Write Data and Read Data Up-Sizer modules, each one taking care // of the channel specific tasks. // The Address Up-Sizer can handle both AR and AW channels. // // Verilog-standard: Verilog 2001 //-------------------------------------------------------------------------- // // Structure: // axi_upsizer // a_upsizer // fifo // fifo_gen // fifo_coregen // w_upsizer // r_upsizer // //-------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none (* DowngradeIPIdentifiedWarnings="yes" *) module axi_dwidth_converter_v2_1_axi_upsizer # ( parameter C_FAMILY = "virtex7", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_AXI_PROTOCOL = 0, // Protocol of SI and MI (0=AXI4, 1=AXI3). parameter integer C_S_AXI_ID_WIDTH = 1, // Width of all ID signals on SI side of converter. // Range: 1 - 32. parameter integer C_SUPPORTS_ID = 0, // Indicates whether SI-side ID needs to be stored and compared. // 0 = No, SI is single-threaded, propagate all transactions. // 1 = Yes, stall any transaction with ID different than outstanding transactions. parameter integer C_AXI_ADDR_WIDTH = 32, // Width of all ADDR signals on SI and MI. // Range (AXI4, AXI3): 12 - 64. parameter integer C_S_AXI_DATA_WIDTH = 32, // Width of s_axi_wdata and s_axi_rdata. // Range: 32, 64, 128, 256, 512, 1024. parameter integer C_M_AXI_DATA_WIDTH = 64, // Width of m_axi_wdata and m_axi_rdata. // Assume always >= than C_S_AXI_DATA_WIDTH. // Range: 32, 64, 128, 256, 512, 1024. parameter integer C_AXI_SUPPORTS_WRITE = 1, parameter integer C_AXI_SUPPORTS_READ = 1, /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // parameter integer C_FIFO_MODE = 0, parameter integer C_FIFO_MODE = 1, // 0=None, 1=Packet_FIFO, 2=Clock_conversion_Packet_FIFO, 3=Simple_FIFO (FUTURE), 4=Clock_conversion_Simple_FIFO (FUTURE) parameter integer C_S_AXI_ACLK_RATIO = 1, // Clock frequency ratio of SI w.r.t. MI. // Range = [1..16]. parameter integer C_M_AXI_ACLK_RATIO = 2, // Clock frequency ratio of MI w.r.t. SI. // Range = [2..16] if C_S_AXI_ACLK_RATIO = 1; else must be 1. parameter integer C_AXI_IS_ACLK_ASYNC = 0, // Indicates whether S and M clocks are asynchronous. // FUTURE FEATURE // Range = [0, 1]. parameter integer C_PACKING_LEVEL = 1, // 0 = Never pack (expander only); packing logic is omitted. // 1 = Pack only when CACHE[1] (Modifiable) is high. // 2 = Always pack, regardless of sub-size transaction or Modifiable bit. // (Required when used as helper-core by mem-con. Same size AXI interfaces // should only be used when always packing) parameter integer C_SYNCHRONIZER_STAGE = 3 ) ( // Slave Interface input wire s_axi_aresetn, input wire s_axi_aclk, // Slave Interface Write Address Ports input wire [C_S_AXI_ID_WIDTH-1:0] s_axi_awid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr, input wire [8-1:0] s_axi_awlen, input wire [3-1:0] s_axi_awsize, input wire [2-1:0] s_axi_awburst, input wire [2-1:0] s_axi_awlock, input wire [4-1:0] s_axi_awcache, input wire [3-1:0] s_axi_awprot, input wire [4-1:0] s_axi_awregion, input wire [4-1:0] s_axi_awqos, input wire s_axi_awvalid, output wire s_axi_awready, // Slave Interface Write Data Ports input wire [C_S_AXI_DATA_WIDTH-1:0] s_axi_wdata, input wire [C_S_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb, input wire s_axi_wlast, input wire s_axi_wvalid, output wire s_axi_wready, // Slave Interface Write Response Ports output wire [C_S_AXI_ID_WIDTH-1:0] s_axi_bid, output wire [2-1:0] s_axi_bresp, output wire s_axi_bvalid, input wire s_axi_bready, // Slave Interface Read Address Ports input wire [C_S_AXI_ID_WIDTH-1:0] s_axi_arid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr, input wire [8-1:0] s_axi_arlen, input wire [3-1:0] s_axi_arsize, input wire [2-1:0] s_axi_arburst, input wire [2-1:0] s_axi_arlock, input wire [4-1:0] s_axi_arcache, input wire [3-1:0] s_axi_arprot, input wire [4-1:0] s_axi_arregion, input wire [4-1:0] s_axi_arqos, input wire s_axi_arvalid, output wire s_axi_arready, // Slave Interface Read Data Ports output wire [C_S_AXI_ID_WIDTH-1:0] s_axi_rid, output wire [C_S_AXI_DATA_WIDTH-1:0] s_axi_rdata, output wire [2-1:0] s_axi_rresp, output wire s_axi_rlast, output wire s_axi_rvalid, input wire s_axi_rready, // Master Interface input wire m_axi_aresetn, input wire m_axi_aclk, // Master Interface Write Address Port output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr, output wire [8-1:0] m_axi_awlen, output wire [3-1:0] m_axi_awsize, output wire [2-1:0] m_axi_awburst, output wire [2-1:0] m_axi_awlock, output wire [4-1:0] m_axi_awcache, output wire [3-1:0] m_axi_awprot, output wire [4-1:0] m_axi_awregion, output wire [4-1:0] m_axi_awqos, output wire m_axi_awvalid, input wire m_axi_awready, // Master Interface Write Data Ports output wire [C_M_AXI_DATA_WIDTH-1:0] m_axi_wdata, output wire [C_M_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb, output wire m_axi_wlast, output wire m_axi_wvalid, input wire m_axi_wready, // Master Interface Write Response Ports input wire [2-1:0] m_axi_bresp, input wire m_axi_bvalid, output wire m_axi_bready, // Master Interface Read Address Port output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr, output wire [8-1:0] m_axi_arlen, output wire [3-1:0] m_axi_arsize, output wire [2-1:0] m_axi_arburst, output wire [2-1:0] m_axi_arlock, output wire [4-1:0] m_axi_arcache, output wire [3-1:0] m_axi_arprot, output wire [4-1:0] m_axi_arregion, output wire [4-1:0] m_axi_arqos, output wire m_axi_arvalid, input wire m_axi_arready, // Master Interface Read Data Ports input wire [C_M_AXI_DATA_WIDTH-1:0] m_axi_rdata, input wire [2-1:0] m_axi_rresp, input wire m_axi_rlast, input wire m_axi_rvalid, output wire m_axi_rready ); // Log2 of number of 32bit word on SI-side. localparam integer C_S_AXI_BYTES_LOG = log2(C_S_AXI_DATA_WIDTH/8); // Log2 of number of 32bit word on MI-side. localparam integer C_M_AXI_BYTES_LOG = log2(C_M_AXI_DATA_WIDTH/8); // Log2 of Up-Sizing ratio for data. localparam integer C_RATIO = C_M_AXI_DATA_WIDTH / C_S_AXI_DATA_WIDTH; localparam integer C_RATIO_LOG = log2(C_RATIO); localparam P_BYPASS = 32'h0; localparam P_LIGHTWT = 32'h7; localparam P_FWD_REV = 32'h1; localparam integer P_CONV_LIGHT_WT = 0; localparam integer P_AXI4 = 0; localparam integer C_FIFO_DEPTH_LOG = 5; localparam P_SI_LT_MI = (C_S_AXI_ACLK_RATIO < C_M_AXI_ACLK_RATIO); localparam integer P_ACLK_RATIO = P_SI_LT_MI ? (C_M_AXI_ACLK_RATIO / C_S_AXI_ACLK_RATIO) : (C_S_AXI_ACLK_RATIO / C_M_AXI_ACLK_RATIO); localparam integer P_NO_FIFO = 0; localparam integer P_PKTFIFO = 1; localparam integer P_PKTFIFO_CLK = 2; localparam integer P_DATAFIFO = 3; localparam integer P_DATAFIFO_CLK = 4; localparam P_CLK_CONV = ((C_FIFO_MODE == P_PKTFIFO_CLK) || (C_FIFO_MODE == P_DATAFIFO_CLK)); localparam integer C_M_AXI_AW_REGISTER = 0; // Simple register AW output. // Range: 0, 1 localparam integer C_M_AXI_W_REGISTER = 1; // Parameter not used; W reg always implemented. localparam integer C_M_AXI_AR_REGISTER = 0; // Simple register AR output. // Range: 0, 1 localparam integer C_S_AXI_R_REGISTER = 0; // Simple register R output (SI). // Range: 0, 1 localparam integer C_M_AXI_R_REGISTER = 1; // Register slice on R input (MI) side. // 0 = Bypass (not recommended due to combinatorial M_RVALID -> M_RREADY path) // 1 = Fully-registered (needed only when upsizer propagates bursts at 1:1 width ratio) // 7 = Light-weight (safe when upsizer always packs at 1:n width ratio, as in interconnect) localparam integer P_RID_QUEUE = ((C_SUPPORTS_ID != 0) && !((C_FIFO_MODE == P_PKTFIFO) || (C_FIFO_MODE == P_PKTFIFO_CLK))) ? 1 : 0; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// // Log2. function integer log2 ( input integer x ); integer acc; begin acc=0; while ((2**acc) < x) acc = acc + 1; log2 = acc; end endfunction ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire aclk; wire m_aclk; wire sample_cycle; wire sample_cycle_early; wire sm_aresetn; wire s_aresetn_i; wire [C_S_AXI_ID_WIDTH-1:0] sr_awid ; wire [C_AXI_ADDR_WIDTH-1:0] sr_awaddr ; wire [8-1:0] sr_awlen ; wire [3-1:0] sr_awsize ; wire [2-1:0] sr_awburst ; wire [2-1:0] sr_awlock ; wire [4-1:0] sr_awcache ; wire [3-1:0] sr_awprot ; wire [4-1:0] sr_awregion ; wire [4-1:0] sr_awqos ; wire sr_awvalid ; wire sr_awready ; wire [C_S_AXI_ID_WIDTH-1:0] sr_arid ; wire [C_AXI_ADDR_WIDTH-1:0] sr_araddr ; wire [8-1:0] sr_arlen ; wire [3-1:0] sr_arsize ; wire [2-1:0] sr_arburst ; wire [2-1:0] sr_arlock ; wire [4-1:0] sr_arcache ; wire [3-1:0] sr_arprot ; wire [4-1:0] sr_arregion ; wire [4-1:0] sr_arqos ; wire sr_arvalid ; wire sr_arready ; wire [C_S_AXI_DATA_WIDTH-1:0] sr_wdata ; wire [(C_S_AXI_DATA_WIDTH/8)-1:0] sr_wstrb ; wire sr_wlast ; wire sr_wvalid ; wire sr_wready ; wire [C_M_AXI_DATA_WIDTH-1:0] mr_rdata ; wire [2-1:0] mr_rresp ; wire mr_rlast ; wire mr_rvalid ; wire mr_rready ; wire m_axi_rready_i; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_awlen_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_arlen_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_awlock_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_arlock_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_awlen_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_arlen_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_awlock_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_arlock_ii ; wire [3:0] s_axi_awregion_ii; wire [3:0] s_axi_arregion_ii; assign s_axi_awlen_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlen : s_axi_awlen[3:0]; assign s_axi_awlock_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlock[0] : s_axi_awlock; assign s_axi_arlen_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlen : s_axi_arlen[3:0]; assign s_axi_arlock_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlock[0] : s_axi_arlock; assign sr_awlen = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlen_ii: {4'b0, s_axi_awlen_ii}; assign sr_awlock = (C_AXI_PROTOCOL == P_AXI4) ? {1'b0, s_axi_awlock_ii} : s_axi_awlock_ii; assign sr_arlen = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlen_ii: {4'b0, s_axi_arlen_ii}; assign sr_arlock = (C_AXI_PROTOCOL == P_AXI4) ? {1'b0, s_axi_arlock_ii} : s_axi_arlock_ii; assign sr_awregion = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awregion_ii : 4'b0; assign sr_arregion = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arregion_ii : 4'b0; assign aclk = s_axi_aclk; assign sm_aresetn = s_axi_aresetn & m_axi_aresetn; generate if (P_CLK_CONV) begin : gen_clock_conv if (C_AXI_IS_ACLK_ASYNC) begin : gen_async_conv assign m_aclk = m_axi_aclk; assign s_aresetn_i = s_axi_aresetn; assign sample_cycle_early = 1'b1; assign sample_cycle = 1'b1; end else begin : gen_sync_conv wire fast_aclk; wire slow_aclk; reg s_aresetn_r; if (P_SI_LT_MI) begin : gen_fastclk_mi assign fast_aclk = m_axi_aclk; assign slow_aclk = s_axi_aclk; end else begin : gen_fastclk_si assign fast_aclk = s_axi_aclk; assign slow_aclk = m_axi_aclk; end assign m_aclk = m_axi_aclk; assign s_aresetn_i = s_aresetn_r; always @(negedge sm_aresetn, posedge fast_aclk) begin if (~sm_aresetn) begin s_aresetn_r <= 1'b0; end else if (s_axi_aresetn & m_axi_aresetn & sample_cycle_early) begin s_aresetn_r <= 1'b1; end end // Sample cycle used to determine when to assert a signal on a fast clock // to be flopped onto a slow clock. axi_clock_converter_v2_1_axic_sample_cycle_ratio #( .C_RATIO ( P_ACLK_RATIO ) ) axic_sample_cycle_inst ( .SLOW_ACLK ( slow_aclk ) , .FAST_ACLK ( fast_aclk ) , .SAMPLE_CYCLE_EARLY ( sample_cycle_early ) , .SAMPLE_CYCLE ( sample_cycle ) ); end end else begin : gen_no_clk_conv assign m_aclk = s_axi_aclk; assign s_aresetn_i = s_axi_aresetn; assign sample_cycle_early = 1'b1; assign sample_cycle = 1'b1; end // gen_clock_conv axi_register_slice_v2_1_axi_register_slice # ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (0), .C_REG_CONFIG_AW (C_AXI_SUPPORTS_WRITE ? P_LIGHTWT : P_BYPASS), .C_REG_CONFIG_AR (C_AXI_SUPPORTS_READ ? P_LIGHTWT : P_BYPASS) ) si_register_slice_inst ( .aresetn (s_aresetn_i), .aclk (aclk), .s_axi_awid (s_axi_awid ), .s_axi_awaddr (s_axi_awaddr ), .s_axi_awlen (s_axi_awlen_i ), .s_axi_awsize (s_axi_awsize ), .s_axi_awburst (s_axi_awburst ), .s_axi_awlock (s_axi_awlock_i ), .s_axi_awcache (s_axi_awcache ), .s_axi_awprot (s_axi_awprot ), .s_axi_awregion (s_axi_awregion ), .s_axi_awqos (s_axi_awqos ), .s_axi_awuser (1'b0 ), .s_axi_awvalid (s_axi_awvalid ), .s_axi_awready (s_axi_awready ), .s_axi_wid ( {C_S_AXI_ID_WIDTH{1'b0}}), .s_axi_wdata ( {C_S_AXI_DATA_WIDTH{1'b0}} ), .s_axi_wstrb ( {C_S_AXI_DATA_WIDTH/8{1'b0}} ), .s_axi_wlast ( 1'b0 ), .s_axi_wuser ( 1'b0 ), .s_axi_wvalid ( 1'b0 ), .s_axi_wready ( ), .s_axi_bid ( ), .s_axi_bresp ( ), .s_axi_buser ( ), .s_axi_bvalid ( ), .s_axi_bready ( 1'b0 ), .s_axi_arid (s_axi_arid ), .s_axi_araddr (s_axi_araddr ), .s_axi_arlen (s_axi_arlen_i ), .s_axi_arsize (s_axi_arsize ), .s_axi_arburst (s_axi_arburst ), .s_axi_arlock (s_axi_arlock_i ), .s_axi_arcache (s_axi_arcache ), .s_axi_arprot (s_axi_arprot ), .s_axi_arregion (s_axi_arregion ), .s_axi_arqos (s_axi_arqos ), .s_axi_aruser (1'b0 ), .s_axi_arvalid (s_axi_arvalid ), .s_axi_arready (s_axi_arready ), .s_axi_rid ( ) , .s_axi_rdata ( ) , .s_axi_rresp ( ) , .s_axi_rlast ( ) , .s_axi_ruser ( ) , .s_axi_rvalid ( ) , .s_axi_rready ( 1'b0 ) , .m_axi_awid (sr_awid ), .m_axi_awaddr (sr_awaddr ), .m_axi_awlen (s_axi_awlen_ii), .m_axi_awsize (sr_awsize ), .m_axi_awburst (sr_awburst ), .m_axi_awlock (s_axi_awlock_ii), .m_axi_awcache (sr_awcache ), .m_axi_awprot (sr_awprot ), .m_axi_awregion (s_axi_awregion_ii ), .m_axi_awqos (sr_awqos ), .m_axi_awuser (), .m_axi_awvalid (sr_awvalid ), .m_axi_awready (sr_awready ), .m_axi_wid () , .m_axi_wdata (), .m_axi_wstrb (), .m_axi_wlast (), .m_axi_wuser (), .m_axi_wvalid (), .m_axi_wready (1'b0), .m_axi_bid ( {C_S_AXI_ID_WIDTH{1'b0}} ) , .m_axi_bresp ( 2'b0 ) , .m_axi_buser ( 1'b0 ) , .m_axi_bvalid ( 1'b0 ) , .m_axi_bready ( ) , .m_axi_arid (sr_arid ), .m_axi_araddr (sr_araddr ), .m_axi_arlen (s_axi_arlen_ii), .m_axi_arsize (sr_arsize ), .m_axi_arburst (sr_arburst ), .m_axi_arlock (s_axi_arlock_ii), .m_axi_arcache (sr_arcache ), .m_axi_arprot (sr_arprot ), .m_axi_arregion (s_axi_arregion_ii ), .m_axi_arqos (sr_arqos ), .m_axi_aruser (), .m_axi_arvalid (sr_arvalid ), .m_axi_arready (sr_arready ), .m_axi_rid ( {C_S_AXI_ID_WIDTH{1'b0}}), .m_axi_rdata ( {C_S_AXI_DATA_WIDTH{1'b0}} ), .m_axi_rresp ( 2'b00 ), .m_axi_rlast ( 1'b0 ), .m_axi_ruser ( 1'b0 ), .m_axi_rvalid ( 1'b0 ), .m_axi_rready ( ) ); ///////////////////////////////////////////////////////////////////////////// // Handle Write Channels (AW/W/B) ///////////////////////////////////////////////////////////////////////////// if (C_AXI_SUPPORTS_WRITE == 1) begin : USE_WRITE wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr_i ; wire [8-1:0] m_axi_awlen_i ; wire [3-1:0] m_axi_awsize_i ; wire [2-1:0] m_axi_awburst_i ; wire [2-1:0] m_axi_awlock_i ; wire [4-1:0] m_axi_awcache_i ; wire [3-1:0] m_axi_awprot_i ; wire [4-1:0] m_axi_awregion_i ; wire [4-1:0] m_axi_awqos_i ; wire m_axi_awvalid_i ; wire m_axi_awready_i ; wire s_axi_bvalid_i ; wire [2-1:0] s_axi_bresp_i ; wire [C_AXI_ADDR_WIDTH-1:0] wr_cmd_si_addr; wire [8-1:0] wr_cmd_si_len; wire [3-1:0] wr_cmd_si_size; wire [2-1:0] wr_cmd_si_burst; // Write Channel Signals for Commands Queue Interface. wire wr_cmd_valid; wire wr_cmd_fix; wire wr_cmd_modified; wire wr_cmd_complete_wrap; wire wr_cmd_packed_wrap; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_first_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_next_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_last_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_offset; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_mask; wire [C_S_AXI_BYTES_LOG:0] wr_cmd_step; wire [8-1:0] wr_cmd_length; wire wr_cmd_ready; wire wr_cmd_id_ready; wire [C_S_AXI_ID_WIDTH-1:0] wr_cmd_id; wire wpush; wire wpop; reg [C_FIFO_DEPTH_LOG-1:0] wcnt; // Write Address Channel. axi_dwidth_converter_v2_1_a_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_SUPPORTS_ID (C_SUPPORTS_ID), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (C_M_AXI_AW_REGISTER), .C_AXI_CHANNEL (0), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_FIFO_MODE (C_FIFO_MODE), .C_ID_QUEUE (C_SUPPORTS_ID), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG) ) write_addr_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (wr_cmd_valid), .cmd_fix (wr_cmd_fix), .cmd_modified (wr_cmd_modified), .cmd_complete_wrap (wr_cmd_complete_wrap), .cmd_packed_wrap (wr_cmd_packed_wrap), .cmd_first_word (wr_cmd_first_word), .cmd_next_word (wr_cmd_next_word), .cmd_last_word (wr_cmd_last_word), .cmd_offset (wr_cmd_offset), .cmd_mask (wr_cmd_mask), .cmd_step (wr_cmd_step), .cmd_length (wr_cmd_length), .cmd_ready (wr_cmd_ready), .cmd_id (wr_cmd_id), .cmd_id_ready (wr_cmd_id_ready), .cmd_si_addr (wr_cmd_si_addr ), .cmd_si_id (), .cmd_si_len (wr_cmd_si_len ), .cmd_si_size (wr_cmd_si_size ), .cmd_si_burst (wr_cmd_si_burst), // Slave Interface Write Address Ports .S_AXI_AID (sr_awid), .S_AXI_AADDR (sr_awaddr), .S_AXI_ALEN (sr_awlen), .S_AXI_ASIZE (sr_awsize), .S_AXI_ABURST (sr_awburst), .S_AXI_ALOCK (sr_awlock), .S_AXI_ACACHE (sr_awcache), .S_AXI_APROT (sr_awprot), .S_AXI_AREGION (sr_awregion), .S_AXI_AQOS (sr_awqos), .S_AXI_AVALID (sr_awvalid), .S_AXI_AREADY (sr_awready), // Master Interface Write Address Port .M_AXI_AADDR (m_axi_awaddr_i ), .M_AXI_ALEN (m_axi_awlen_i ), .M_AXI_ASIZE (m_axi_awsize_i ), .M_AXI_ABURST (m_axi_awburst_i ), .M_AXI_ALOCK (m_axi_awlock_i ), .M_AXI_ACACHE (m_axi_awcache_i ), .M_AXI_APROT (m_axi_awprot_i ), .M_AXI_AREGION (m_axi_awregion_i ), .M_AXI_AQOS (m_axi_awqos_i ), .M_AXI_AVALID (m_axi_awvalid_i ), .M_AXI_AREADY (m_axi_awready_i ) ); if ((C_FIFO_MODE == P_PKTFIFO) || (C_FIFO_MODE == P_PKTFIFO_CLK)) begin : gen_pktfifo_w_upsizer // Packet FIFO Write Data channel. axi_dwidth_converter_v2_1_w_upsizer_pktfifo # ( .C_FAMILY (C_FAMILY), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG), .C_CLK_CONV (P_CLK_CONV), .C_S_AXI_ACLK_RATIO (C_S_AXI_ACLK_RATIO), .C_M_AXI_ACLK_RATIO (C_M_AXI_ACLK_RATIO), .C_AXI_IS_ACLK_ASYNC (C_AXI_IS_ACLK_ASYNC), .C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE) ) pktfifo_write_data_inst ( .S_AXI_ARESETN ( s_axi_aresetn ) , .S_AXI_ACLK ( s_axi_aclk ) , .M_AXI_ARESETN ( m_axi_aresetn ) , .M_AXI_ACLK ( m_axi_aclk ) , // Command Interface .cmd_si_addr (wr_cmd_si_addr ), .cmd_si_len (wr_cmd_si_len ), .cmd_si_size (wr_cmd_si_size ), .cmd_si_burst (wr_cmd_si_burst), .cmd_ready (wr_cmd_ready), // Slave Interface Write Address Ports .S_AXI_AWADDR (m_axi_awaddr_i ), .S_AXI_AWLEN (m_axi_awlen_i ), .S_AXI_AWSIZE (m_axi_awsize_i ), .S_AXI_AWBURST (m_axi_awburst_i ), .S_AXI_AWLOCK (m_axi_awlock_i ), .S_AXI_AWCACHE (m_axi_awcache_i ), .S_AXI_AWPROT (m_axi_awprot_i ), .S_AXI_AWREGION (m_axi_awregion_i ), .S_AXI_AWQOS (m_axi_awqos_i ), .S_AXI_AWVALID (m_axi_awvalid_i ), .S_AXI_AWREADY (m_axi_awready_i ), // Master Interface Write Address Port .M_AXI_AWADDR (m_axi_awaddr), .M_AXI_AWLEN (m_axi_awlen), .M_AXI_AWSIZE (m_axi_awsize), .M_AXI_AWBURST (m_axi_awburst), .M_AXI_AWLOCK (m_axi_awlock), .M_AXI_AWCACHE (m_axi_awcache), .M_AXI_AWPROT (m_axi_awprot), .M_AXI_AWREGION (m_axi_awregion), .M_AXI_AWQOS (m_axi_awqos), .M_AXI_AWVALID (m_axi_awvalid), .M_AXI_AWREADY (m_axi_awready), // Slave Interface Write Data Ports .S_AXI_WDATA (s_axi_wdata), .S_AXI_WSTRB (s_axi_wstrb), .S_AXI_WLAST (s_axi_wlast), .S_AXI_WVALID (s_axi_wvalid), .S_AXI_WREADY (s_axi_wready), // Master Interface Write Data Ports .M_AXI_WDATA (m_axi_wdata), .M_AXI_WSTRB (m_axi_wstrb), .M_AXI_WLAST (m_axi_wlast), .M_AXI_WVALID (m_axi_wvalid), .M_AXI_WREADY (m_axi_wready), .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early) ); end else begin : gen_non_fifo_w_upsizer // Write Data channel. axi_dwidth_converter_v2_1_w_upsizer # ( .C_FAMILY ("rtl"), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (1), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG) ) write_data_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (wr_cmd_valid), .cmd_fix (wr_cmd_fix), .cmd_modified (wr_cmd_modified), .cmd_complete_wrap (wr_cmd_complete_wrap), .cmd_packed_wrap (wr_cmd_packed_wrap), .cmd_first_word (wr_cmd_first_word), .cmd_next_word (wr_cmd_next_word), .cmd_last_word (wr_cmd_last_word), .cmd_offset (wr_cmd_offset), .cmd_mask (wr_cmd_mask), .cmd_step (wr_cmd_step), .cmd_length (wr_cmd_length), .cmd_ready (wr_cmd_ready), // Slave Interface Write Data Ports .S_AXI_WDATA (s_axi_wdata), .S_AXI_WSTRB (s_axi_wstrb), .S_AXI_WLAST (s_axi_wlast), .S_AXI_WVALID (s_axi_wvalid), .S_AXI_WREADY (s_axi_wready), // Master Interface Write Data Ports .M_AXI_WDATA (m_axi_wdata), .M_AXI_WSTRB (m_axi_wstrb), .M_AXI_WLAST (m_axi_wlast), .M_AXI_WVALID (m_axi_wvalid), .M_AXI_WREADY (m_axi_wready) ); assign m_axi_awaddr = m_axi_awaddr_i ; assign m_axi_awlen = m_axi_awlen_i ; assign m_axi_awsize = m_axi_awsize_i ; assign m_axi_awburst = m_axi_awburst_i ; assign m_axi_awlock = m_axi_awlock_i ; assign m_axi_awcache = m_axi_awcache_i ; assign m_axi_awprot = m_axi_awprot_i ; assign m_axi_awregion = m_axi_awregion_i ; assign m_axi_awqos = m_axi_awqos_i ; assign m_axi_awvalid = m_axi_awvalid_i ; assign m_axi_awready_i = m_axi_awready ; end // gen_w_upsizer // Write Response channel. assign wr_cmd_id_ready = s_axi_bvalid_i & s_axi_bready; assign s_axi_bid = wr_cmd_id; assign s_axi_bresp = s_axi_bresp_i; assign s_axi_bvalid = s_axi_bvalid_i; if (P_CLK_CONV) begin : gen_b_clk_conv if (C_AXI_IS_ACLK_ASYNC == 0) begin : gen_b_sync_conv axi_clock_converter_v2_1_axic_sync_clock_converter #( .C_FAMILY ( C_FAMILY ) , .C_PAYLOAD_WIDTH ( 2 ) , .C_M_ACLK_RATIO ( P_SI_LT_MI ? 1 : P_ACLK_RATIO ) , .C_S_ACLK_RATIO ( P_SI_LT_MI ? P_ACLK_RATIO : 1 ) , .C_MODE(P_CONV_LIGHT_WT) ) b_sync_clock_converter ( .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early), .S_ACLK ( m_axi_aclk ) , .S_ARESETN ( m_axi_aresetn ) , .S_PAYLOAD ( m_axi_bresp ) , .S_VALID ( m_axi_bvalid ) , .S_READY ( m_axi_bready ) , .M_ACLK ( s_axi_aclk ) , .M_ARESETN ( s_axi_aresetn ) , .M_PAYLOAD ( s_axi_bresp_i ) , .M_VALID ( s_axi_bvalid_i ) , .M_READY ( s_axi_bready ) ); end else begin : gen_b_async_conv fifo_generator_v12_0 #( .C_COMMON_CLOCK(0), .C_SYNCHRONIZER_STAGE(C_SYNCHRONIZER_STAGE), .C_INTERFACE_TYPE(2), .C_AXI_TYPE(1), .C_HAS_AXI_ID(1), .C_AXI_LEN_WIDTH(8), .C_AXI_LOCK_WIDTH(2), .C_DIN_WIDTH_WACH(63), .C_DIN_WIDTH_WDCH(38), .C_DIN_WIDTH_WRCH(3), .C_DIN_WIDTH_RACH(63), .C_DIN_WIDTH_RDCH(36), .C_COUNT_TYPE(0), .C_DATA_COUNT_WIDTH(10), .C_DEFAULT_VALUE("BlankString"), .C_DIN_WIDTH(18), .C_DOUT_RST_VAL("0"), .C_DOUT_WIDTH(18), .C_ENABLE_RLOCS(0), .C_FAMILY(C_FAMILY), .C_FULL_FLAGS_RST_VAL(1), .C_HAS_ALMOST_EMPTY(0), .C_HAS_ALMOST_FULL(0), .C_HAS_BACKUP(0), .C_HAS_DATA_COUNT(0), .C_HAS_INT_CLK(0), .C_HAS_MEMINIT_FILE(0), .C_HAS_OVERFLOW(0), .C_HAS_RD_DATA_COUNT(0), .C_HAS_RD_RST(0), .C_HAS_RST(1), .C_HAS_SRST(0), .C_HAS_UNDERFLOW(0), .C_HAS_VALID(0), .C_HAS_WR_ACK(0), .C_HAS_WR_DATA_COUNT(0), .C_HAS_WR_RST(0), .C_IMPLEMENTATION_TYPE(0), .C_INIT_WR_PNTR_VAL(0), .C_MEMORY_TYPE(1), .C_MIF_FILE_NAME("BlankString"), .C_OPTIMIZATION_MODE(0), .C_OVERFLOW_LOW(0), .C_PRELOAD_LATENCY(1), .C_PRELOAD_REGS(0), .C_PRIM_FIFO_TYPE("4kx4"), .C_PROG_EMPTY_THRESH_ASSERT_VAL(2), .C_PROG_EMPTY_THRESH_NEGATE_VAL(3), .C_PROG_EMPTY_TYPE(0), .C_PROG_FULL_THRESH_ASSERT_VAL(1022), .C_PROG_FULL_THRESH_NEGATE_VAL(1021), .C_PROG_FULL_TYPE(0), .C_RD_DATA_COUNT_WIDTH(10), .C_RD_DEPTH(1024), .C_RD_FREQ(1), .C_RD_PNTR_WIDTH(10), .C_UNDERFLOW_LOW(0), .C_USE_DOUT_RST(1), .C_USE_ECC(0), .C_USE_EMBEDDED_REG(0), .C_USE_FIFO16_FLAGS(0), .C_USE_FWFT_DATA_COUNT(0), .C_VALID_LOW(0), .C_WR_ACK_LOW(0), .C_WR_DATA_COUNT_WIDTH(10), .C_WR_DEPTH(1024), .C_WR_FREQ(1), .C_WR_PNTR_WIDTH(10), .C_WR_RESPONSE_LATENCY(1), .C_MSGON_VAL(1), .C_ENABLE_RST_SYNC(1), .C_ERROR_INJECTION_TYPE(0), .C_HAS_AXI_WR_CHANNEL(1), .C_HAS_AXI_RD_CHANNEL(0), .C_HAS_SLAVE_CE(0), .C_HAS_MASTER_CE(0), .C_ADD_NGC_CONSTRAINT(0), .C_USE_COMMON_OVERFLOW(0), .C_USE_COMMON_UNDERFLOW(0), .C_USE_DEFAULT_SETTINGS(0), .C_AXI_ID_WIDTH(1), .C_AXI_ADDR_WIDTH(32), .C_AXI_DATA_WIDTH(32), .C_HAS_AXI_AWUSER(0), .C_HAS_AXI_WUSER(0), .C_HAS_AXI_BUSER(0), .C_HAS_AXI_ARUSER(0), .C_HAS_AXI_RUSER(0), .C_AXI_ARUSER_WIDTH(1), .C_AXI_AWUSER_WIDTH(1), .C_AXI_WUSER_WIDTH(1), .C_AXI_BUSER_WIDTH(1), .C_AXI_RUSER_WIDTH(1), .C_HAS_AXIS_TDATA(0), .C_HAS_AXIS_TID(0), .C_HAS_AXIS_TDEST(0), .C_HAS_AXIS_TUSER(0), .C_HAS_AXIS_TREADY(1), .C_HAS_AXIS_TLAST(0), .C_HAS_AXIS_TSTRB(0), .C_HAS_AXIS_TKEEP(0), .C_AXIS_TDATA_WIDTH(64), .C_AXIS_TID_WIDTH(8), .C_AXIS_TDEST_WIDTH(4), .C_AXIS_TUSER_WIDTH(4), .C_AXIS_TSTRB_WIDTH(4), .C_AXIS_TKEEP_WIDTH(4), .C_WACH_TYPE(2), .C_WDCH_TYPE(2), .C_WRCH_TYPE(0), .C_RACH_TYPE(0), .C_RDCH_TYPE(0), .C_AXIS_TYPE(0), .C_IMPLEMENTATION_TYPE_WACH(12), .C_IMPLEMENTATION_TYPE_WDCH(11), .C_IMPLEMENTATION_TYPE_WRCH(12), .C_IMPLEMENTATION_TYPE_RACH(12), .C_IMPLEMENTATION_TYPE_RDCH(11), .C_IMPLEMENTATION_TYPE_AXIS(11), .C_APPLICATION_TYPE_WACH(0), .C_APPLICATION_TYPE_WDCH(0), .C_APPLICATION_TYPE_WRCH(0), .C_APPLICATION_TYPE_RACH(0), .C_APPLICATION_TYPE_RDCH(0), .C_APPLICATION_TYPE_AXIS(0), .C_USE_ECC_WACH(0), .C_USE_ECC_WDCH(0), .C_USE_ECC_WRCH(0), .C_USE_ECC_RACH(0), .C_USE_ECC_RDCH(0), .C_USE_ECC_AXIS(0), .C_ERROR_INJECTION_TYPE_WACH(0), .C_ERROR_INJECTION_TYPE_WDCH(0), .C_ERROR_INJECTION_TYPE_WRCH(0), .C_ERROR_INJECTION_TYPE_RACH(0), .C_ERROR_INJECTION_TYPE_RDCH(0), .C_ERROR_INJECTION_TYPE_AXIS(0), .C_DIN_WIDTH_AXIS(1), .C_WR_DEPTH_WACH(16), .C_WR_DEPTH_WDCH(1024), .C_WR_DEPTH_WRCH(32), .C_WR_DEPTH_RACH(16), .C_WR_DEPTH_RDCH(1024), .C_WR_DEPTH_AXIS(1024), .C_WR_PNTR_WIDTH_WACH(4), .C_WR_PNTR_WIDTH_WDCH(10), .C_WR_PNTR_WIDTH_WRCH(5), .C_WR_PNTR_WIDTH_RACH(4), .C_WR_PNTR_WIDTH_RDCH(10), .C_WR_PNTR_WIDTH_AXIS(10), .C_HAS_DATA_COUNTS_WACH(0), .C_HAS_DATA_COUNTS_WDCH(0), .C_HAS_DATA_COUNTS_WRCH(0), .C_HAS_DATA_COUNTS_RACH(0), .C_HAS_DATA_COUNTS_RDCH(0), .C_HAS_DATA_COUNTS_AXIS(0), .C_HAS_PROG_FLAGS_WACH(0), .C_HAS_PROG_FLAGS_WDCH(0), .C_HAS_PROG_FLAGS_WRCH(0), .C_HAS_PROG_FLAGS_RACH(0), .C_HAS_PROG_FLAGS_RDCH(0), .C_HAS_PROG_FLAGS_AXIS(0), .C_PROG_FULL_TYPE_WACH(0), .C_PROG_FULL_TYPE_WDCH(0), .C_PROG_FULL_TYPE_WRCH(0), .C_PROG_FULL_TYPE_RACH(0), .C_PROG_FULL_TYPE_RDCH(0), .C_PROG_FULL_TYPE_AXIS(0), .C_PROG_FULL_THRESH_ASSERT_VAL_WACH(15), .C_PROG_FULL_THRESH_ASSERT_VAL_WDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_WRCH(31), .C_PROG_FULL_THRESH_ASSERT_VAL_RACH(15), .C_PROG_FULL_THRESH_ASSERT_VAL_RDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_AXIS(1023), .C_PROG_EMPTY_TYPE_WACH(0), .C_PROG_EMPTY_TYPE_WDCH(0), .C_PROG_EMPTY_TYPE_WRCH(0), .C_PROG_EMPTY_TYPE_RACH(0), .C_PROG_EMPTY_TYPE_RDCH(0), .C_PROG_EMPTY_TYPE_AXIS(0), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH(13), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH(1021), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH(29), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH(13), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH(1021), .C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS(1021), .C_REG_SLICE_MODE_WACH(0), .C_REG_SLICE_MODE_WDCH(0), .C_REG_SLICE_MODE_WRCH(0), .C_REG_SLICE_MODE_RACH(0), .C_REG_SLICE_MODE_RDCH(0), .C_REG_SLICE_MODE_AXIS(0) ) dw_fifogen_b_async ( .m_aclk(m_axi_aclk), .s_aclk(s_axi_aclk), .s_aresetn(sm_aresetn), .s_axi_awid(1'b0), .s_axi_awaddr(32'b0), .s_axi_awlen(8'b0), .s_axi_awsize(3'b0), .s_axi_awburst(2'b0), .s_axi_awlock(2'b0), .s_axi_awcache(4'b0), .s_axi_awprot(3'b0), .s_axi_awqos(4'b0), .s_axi_awregion(4'b0), .s_axi_awuser(1'b0), .s_axi_awvalid(1'b0), .s_axi_awready(), .s_axi_wid(1'b0), .s_axi_wdata(32'b0), .s_axi_wstrb(4'b0), .s_axi_wlast(1'b0), .s_axi_wuser(1'b0), .s_axi_wvalid(1'b0), .s_axi_wready(), .s_axi_bid(), .s_axi_bresp(s_axi_bresp_i), .s_axi_buser(), .s_axi_bvalid(s_axi_bvalid_i), .s_axi_bready(s_axi_bready), .m_axi_awid(), .m_axi_awaddr(), .m_axi_awlen(), .m_axi_awsize(), .m_axi_awburst(), .m_axi_awlock(), .m_axi_awcache(), .m_axi_awprot(), .m_axi_awqos(), .m_axi_awregion(), .m_axi_awuser(), .m_axi_awvalid(), .m_axi_awready(1'b0), .m_axi_wid(), .m_axi_wdata(), .m_axi_wstrb(), .m_axi_wlast(), .m_axi_wuser(), .m_axi_wvalid(), .m_axi_wready(1'b0), .m_axi_bid(1'b0), .m_axi_bresp(m_axi_bresp), .m_axi_buser(1'b0), .m_axi_bvalid(m_axi_bvalid), .m_axi_bready(m_axi_bready), .s_axi_arid(1'b0), .s_axi_araddr(32'b0), .s_axi_arlen(8'b0), .s_axi_arsize(3'b0), .s_axi_arburst(2'b0), .s_axi_arlock(2'b0), .s_axi_arcache(4'b0), .s_axi_arprot(3'b0), .s_axi_arqos(4'b0), .s_axi_arregion(4'b0), .s_axi_aruser(1'b0), .s_axi_arvalid(1'b0), .s_axi_arready(), .s_axi_rid(), .s_axi_rdata(), .s_axi_rresp(), .s_axi_rlast(), .s_axi_ruser(), .s_axi_rvalid(), .s_axi_rready(1'b0), .m_axi_arid(), .m_axi_araddr(), .m_axi_arlen(), .m_axi_arsize(), .m_axi_arburst(), .m_axi_arlock(), .m_axi_arcache(), .m_axi_arprot(), .m_axi_arqos(), .m_axi_arregion(), .m_axi_aruser(), .m_axi_arvalid(), .m_axi_arready(1'b0), .m_axi_rid(1'b0), .m_axi_rdata(32'b0), .m_axi_rresp(2'b0), .m_axi_rlast(1'b0), .m_axi_ruser(1'b0), .m_axi_rvalid(1'b0), .m_axi_rready(), .m_aclk_en(1'b0), .s_aclk_en(1'b0), .backup(1'b0), .backup_marker(1'b0), .clk(1'b0), .rst(1'b0), .srst(1'b0), .wr_clk(1'b0), .wr_rst(1'b0), .rd_clk(1'b0), .rd_rst(1'b0), .din(18'b0), .wr_en(1'b0), .rd_en(1'b0), .prog_empty_thresh(10'b0), .prog_empty_thresh_assert(10'b0), .prog_empty_thresh_negate(10'b0), .prog_full_thresh(10'b0), .prog_full_thresh_assert(10'b0), .prog_full_thresh_negate(10'b0), .int_clk(1'b0), .injectdbiterr(1'b0), .injectsbiterr(1'b0), .dout(), .full(), .almost_full(), .wr_ack(), .overflow(), .empty(), .almost_empty(), .valid(), .underflow(), .data_count(), .rd_data_count(), .wr_data_count(), .prog_full(), .prog_empty(), .sbiterr(), .dbiterr(), .s_axis_tvalid(1'b0), .s_axis_tready(), .s_axis_tdata(64'b0), .s_axis_tstrb(4'b0), .s_axis_tkeep(4'b0), .s_axis_tlast(1'b0), .s_axis_tid(8'b0), .s_axis_tdest(4'b0), .s_axis_tuser(4'b0), .m_axis_tvalid(), .m_axis_tready(1'b0), .m_axis_tdata(), .m_axis_tstrb(), .m_axis_tkeep(), .m_axis_tlast(), .m_axis_tid(), .m_axis_tdest(), .m_axis_tuser(), .axi_aw_injectsbiterr(1'b0), .axi_aw_injectdbiterr(1'b0), .axi_aw_prog_full_thresh(4'b0), .axi_aw_prog_empty_thresh(4'b0), .axi_aw_data_count(), .axi_aw_wr_data_count(), .axi_aw_rd_data_count(), .axi_aw_sbiterr(), .axi_aw_dbiterr(), .axi_aw_overflow(), .axi_aw_underflow(), .axi_aw_prog_full(), .axi_aw_prog_empty(), .axi_w_injectsbiterr(1'b0), .axi_w_injectdbiterr(1'b0), .axi_w_prog_full_thresh(10'b0), .axi_w_prog_empty_thresh(10'b0), .axi_w_data_count(), .axi_w_wr_data_count(), .axi_w_rd_data_count(), .axi_w_sbiterr(), .axi_w_dbiterr(), .axi_w_overflow(), .axi_w_underflow(), .axi_b_injectsbiterr(1'b0), .axi_w_prog_full(), .axi_w_prog_empty(), .axi_b_injectdbiterr(1'b0), .axi_b_prog_full_thresh(5'b0), .axi_b_prog_empty_thresh(5'b0), .axi_b_data_count(), .axi_b_wr_data_count(), .axi_b_rd_data_count(), .axi_b_sbiterr(), .axi_b_dbiterr(), .axi_b_overflow(), .axi_b_underflow(), .axi_ar_injectsbiterr(1'b0), .axi_b_prog_full(), .axi_b_prog_empty(), .axi_ar_injectdbiterr(1'b0), .axi_ar_prog_full_thresh(4'b0), .axi_ar_prog_empty_thresh(4'b0), .axi_ar_data_count(), .axi_ar_wr_data_count(), .axi_ar_rd_data_count(), .axi_ar_sbiterr(), .axi_ar_dbiterr(), .axi_ar_overflow(), .axi_ar_underflow(), .axi_ar_prog_full(), .axi_ar_prog_empty(), .axi_r_injectsbiterr(1'b0), .axi_r_injectdbiterr(1'b0), .axi_r_prog_full_thresh(10'b0), .axi_r_prog_empty_thresh(10'b0), .axi_r_data_count(), .axi_r_wr_data_count(), .axi_r_rd_data_count(), .axi_r_sbiterr(), .axi_r_dbiterr(), .axi_r_overflow(), .axi_r_underflow(), .axis_injectsbiterr(1'b0), .axi_r_prog_full(), .axi_r_prog_empty(), .axis_injectdbiterr(1'b0), .axis_prog_full_thresh(10'b0), .axis_prog_empty_thresh(10'b0), .axis_data_count(), .axis_wr_data_count(), .axis_rd_data_count(), .axis_sbiterr(), .axis_dbiterr(), .axis_overflow(), .axis_underflow(), .axis_prog_full(), .axis_prog_empty(), .wr_rst_busy(), .rd_rst_busy(), .sleep(1'b0) ); end end else begin : gen_b_passthru assign m_axi_bready = s_axi_bready; assign s_axi_bresp_i = m_axi_bresp; assign s_axi_bvalid_i = m_axi_bvalid; end // gen_b end else begin : NO_WRITE assign sr_awready = 1'b0; assign s_axi_wready = 1'b0; assign s_axi_bid = {C_S_AXI_ID_WIDTH{1'b0}}; assign s_axi_bresp = 2'b0; assign s_axi_bvalid = 1'b0; assign m_axi_awaddr = {C_AXI_ADDR_WIDTH{1'b0}}; assign m_axi_awlen = 8'b0; assign m_axi_awsize = 3'b0; assign m_axi_awburst = 2'b0; assign m_axi_awlock = 2'b0; assign m_axi_awcache = 4'b0; assign m_axi_awprot = 3'b0; assign m_axi_awregion = 4'b0; assign m_axi_awqos = 4'b0; assign m_axi_awvalid = 1'b0; assign m_axi_wdata = {C_M_AXI_DATA_WIDTH{1'b0}}; assign m_axi_wstrb = {C_M_AXI_DATA_WIDTH/8{1'b0}}; assign m_axi_wlast = 1'b0; assign m_axi_wvalid = 1'b0; assign m_axi_bready = 1'b0; end endgenerate ///////////////////////////////////////////////////////////////////////////// // Handle Read Channels (AR/R) ///////////////////////////////////////////////////////////////////////////// generate if (C_AXI_SUPPORTS_READ == 1) begin : USE_READ wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr_i ; wire [8-1:0] m_axi_arlen_i ; wire [3-1:0] m_axi_arsize_i ; wire [2-1:0] m_axi_arburst_i ; wire [2-1:0] m_axi_arlock_i ; wire [4-1:0] m_axi_arcache_i ; wire [3-1:0] m_axi_arprot_i ; wire [4-1:0] m_axi_arregion_i ; wire [4-1:0] m_axi_arqos_i ; wire m_axi_arvalid_i ; wire m_axi_arready_i ; // Read Channel Signals for Commands Queue Interface. wire rd_cmd_valid; wire rd_cmd_fix; wire rd_cmd_modified; wire rd_cmd_complete_wrap; wire rd_cmd_packed_wrap; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_first_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_next_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_last_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_offset; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_mask; wire [C_S_AXI_BYTES_LOG:0] rd_cmd_step; wire [8-1:0] rd_cmd_length; wire rd_cmd_ready; wire [C_S_AXI_ID_WIDTH-1:0] rd_cmd_id; wire [C_AXI_ADDR_WIDTH-1:0] rd_cmd_si_addr; wire [C_S_AXI_ID_WIDTH-1:0] rd_cmd_si_id; wire [8-1:0] rd_cmd_si_len; wire [3-1:0] rd_cmd_si_size; wire [2-1:0] rd_cmd_si_burst; // Read Address Channel. axi_dwidth_converter_v2_1_a_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_SUPPORTS_ID (C_SUPPORTS_ID), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (C_M_AXI_AR_REGISTER), .C_AXI_CHANNEL (1), .C_PACKING_LEVEL (C_PACKING_LEVEL), // .C_FIFO_MODE (0), .C_FIFO_MODE (C_FIFO_MODE), .C_ID_QUEUE (P_RID_QUEUE), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG) ) read_addr_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (rd_cmd_valid), .cmd_fix (rd_cmd_fix), .cmd_modified (rd_cmd_modified), .cmd_complete_wrap (rd_cmd_complete_wrap), .cmd_packed_wrap (rd_cmd_packed_wrap), .cmd_first_word (rd_cmd_first_word), .cmd_next_word (rd_cmd_next_word), .cmd_last_word (rd_cmd_last_word), .cmd_offset (rd_cmd_offset), .cmd_mask (rd_cmd_mask), .cmd_step (rd_cmd_step), .cmd_length (rd_cmd_length), .cmd_ready (rd_cmd_ready), .cmd_id_ready (rd_cmd_ready), .cmd_id (rd_cmd_id), .cmd_si_addr (rd_cmd_si_addr ), .cmd_si_id (rd_cmd_si_id ), .cmd_si_len (rd_cmd_si_len ), .cmd_si_size (rd_cmd_si_size ), .cmd_si_burst (rd_cmd_si_burst), // Slave Interface Write Address Ports .S_AXI_AID (sr_arid), .S_AXI_AADDR (sr_araddr), .S_AXI_ALEN (sr_arlen), .S_AXI_ASIZE (sr_arsize), .S_AXI_ABURST (sr_arburst), .S_AXI_ALOCK (sr_arlock), .S_AXI_ACACHE (sr_arcache), .S_AXI_APROT (sr_arprot), .S_AXI_AREGION (sr_arregion), .S_AXI_AQOS (sr_arqos), .S_AXI_AVALID (sr_arvalid), .S_AXI_AREADY (sr_arready), // Master Interface Write Address Port .M_AXI_AADDR (m_axi_araddr_i ), .M_AXI_ALEN (m_axi_arlen_i ), .M_AXI_ASIZE (m_axi_arsize_i ), .M_AXI_ABURST (m_axi_arburst_i ), .M_AXI_ALOCK (m_axi_arlock_i ), .M_AXI_ACACHE (m_axi_arcache_i ), .M_AXI_APROT (m_axi_arprot_i ), .M_AXI_AREGION (m_axi_arregion_i ), .M_AXI_AQOS (m_axi_arqos_i ), .M_AXI_AVALID (m_axi_arvalid_i ), .M_AXI_AREADY (m_axi_arready_i ) ); if ((C_FIFO_MODE == P_PKTFIFO) || (C_FIFO_MODE == P_PKTFIFO_CLK)) begin : gen_pktfifo_r_upsizer // Packet FIFO Read Data channel. axi_dwidth_converter_v2_1_r_upsizer_pktfifo # ( .C_FAMILY (C_FAMILY), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG), .C_CLK_CONV (P_CLK_CONV), .C_S_AXI_ACLK_RATIO (C_S_AXI_ACLK_RATIO), .C_M_AXI_ACLK_RATIO (C_M_AXI_ACLK_RATIO), .C_AXI_IS_ACLK_ASYNC (C_AXI_IS_ACLK_ASYNC), .C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE) ) pktfifo_read_data_inst ( .S_AXI_ARESETN ( s_axi_aresetn ) , .S_AXI_ACLK ( s_axi_aclk ) , .M_AXI_ARESETN ( m_axi_aresetn ) , .M_AXI_ACLK ( m_axi_aclk ) , // Command Interface .cmd_si_addr (rd_cmd_si_addr ), .cmd_si_id (rd_cmd_si_id ), .cmd_si_len (rd_cmd_si_len ), .cmd_si_size (rd_cmd_si_size ), .cmd_si_burst (rd_cmd_si_burst), .cmd_ready (rd_cmd_ready), // Slave Interface Write Address Ports .S_AXI_ARADDR (m_axi_araddr_i ), .S_AXI_ARLEN (m_axi_arlen_i ), .S_AXI_ARSIZE (m_axi_arsize_i ), .S_AXI_ARBURST (m_axi_arburst_i ), .S_AXI_ARLOCK (m_axi_arlock_i ), .S_AXI_ARCACHE (m_axi_arcache_i ), .S_AXI_ARPROT (m_axi_arprot_i ), .S_AXI_ARREGION (m_axi_arregion_i ), .S_AXI_ARQOS (m_axi_arqos_i ), .S_AXI_ARVALID (m_axi_arvalid_i ), .S_AXI_ARREADY (m_axi_arready_i ), // Master Interface Write Address Port .M_AXI_ARADDR (m_axi_araddr), .M_AXI_ARLEN (m_axi_arlen), .M_AXI_ARSIZE (m_axi_arsize), .M_AXI_ARBURST (m_axi_arburst), .M_AXI_ARLOCK (m_axi_arlock), .M_AXI_ARCACHE (m_axi_arcache), .M_AXI_ARPROT (m_axi_arprot), .M_AXI_ARREGION (m_axi_arregion), .M_AXI_ARQOS (m_axi_arqos), .M_AXI_ARVALID (m_axi_arvalid), .M_AXI_ARREADY (m_axi_arready), // Slave Interface Write Data Ports .S_AXI_RID (s_axi_rid), .S_AXI_RDATA (s_axi_rdata), .S_AXI_RRESP (s_axi_rresp), .S_AXI_RLAST (s_axi_rlast), .S_AXI_RVALID (s_axi_rvalid), .S_AXI_RREADY (s_axi_rready), // Master Interface Write Data Ports .M_AXI_RDATA (m_axi_rdata), .M_AXI_RRESP (m_axi_rresp), .M_AXI_RLAST (m_axi_rlast), .M_AXI_RVALID (m_axi_rvalid), .M_AXI_RREADY (m_axi_rready), .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early) ); end else begin : gen_non_fifo_r_upsizer // Read Data channel. axi_dwidth_converter_v2_1_r_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_S_AXI_REGISTER (C_S_AXI_R_REGISTER), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG) ) read_data_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (rd_cmd_valid), .cmd_fix (rd_cmd_fix), .cmd_modified (rd_cmd_modified), .cmd_complete_wrap (rd_cmd_complete_wrap), .cmd_packed_wrap (rd_cmd_packed_wrap), .cmd_first_word (rd_cmd_first_word), .cmd_next_word (rd_cmd_next_word), .cmd_last_word (rd_cmd_last_word), .cmd_offset (rd_cmd_offset), .cmd_mask (rd_cmd_mask), .cmd_step (rd_cmd_step), .cmd_length (rd_cmd_length), .cmd_ready (rd_cmd_ready), .cmd_id (rd_cmd_id), // Slave Interface Read Data Ports .S_AXI_RID (s_axi_rid), .S_AXI_RDATA (s_axi_rdata), .S_AXI_RRESP (s_axi_rresp), .S_AXI_RLAST (s_axi_rlast), .S_AXI_RVALID (s_axi_rvalid), .S_AXI_RREADY (s_axi_rready), // Master Interface Read Data Ports .M_AXI_RDATA (mr_rdata), .M_AXI_RRESP (mr_rresp), .M_AXI_RLAST (mr_rlast), .M_AXI_RVALID (mr_rvalid), .M_AXI_RREADY (mr_rready) ); axi_register_slice_v2_1_axi_register_slice # ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL (0), .C_AXI_ID_WIDTH (1), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (0), .C_REG_CONFIG_R (C_M_AXI_R_REGISTER) ) mi_register_slice_inst ( .aresetn (s_aresetn_i), .aclk (m_aclk), .s_axi_awid ( 1'b0 ), .s_axi_awaddr ( {C_AXI_ADDR_WIDTH{1'b0}} ), .s_axi_awlen ( 8'b0 ), .s_axi_awsize ( 3'b0 ), .s_axi_awburst ( 2'b0 ), .s_axi_awlock ( 1'b0 ), .s_axi_awcache ( 4'b0 ), .s_axi_awprot ( 3'b0 ), .s_axi_awregion ( 4'b0 ), .s_axi_awqos ( 4'b0 ), .s_axi_awuser ( 1'b0 ), .s_axi_awvalid ( 1'b0 ), .s_axi_awready ( ), .s_axi_wid ( 1'b0 ), .s_axi_wdata ( {C_M_AXI_DATA_WIDTH{1'b0}} ), .s_axi_wstrb ( {C_M_AXI_DATA_WIDTH/8{1'b0}} ), .s_axi_wlast ( 1'b0 ), .s_axi_wuser ( 1'b0 ), .s_axi_wvalid ( 1'b0 ), .s_axi_wready ( ), .s_axi_bid ( ), .s_axi_bresp ( ), .s_axi_buser ( ), .s_axi_bvalid ( ), .s_axi_bready ( 1'b0 ), .s_axi_arid ( 1'b0 ), .s_axi_araddr ( {C_AXI_ADDR_WIDTH{1'b0}} ), .s_axi_arlen ( 8'b0 ), .s_axi_arsize ( 3'b0 ), .s_axi_arburst ( 2'b0 ), .s_axi_arlock ( 1'b0 ), .s_axi_arcache ( 4'b0 ), .s_axi_arprot ( 3'b0 ), .s_axi_arregion ( 4'b0 ), .s_axi_arqos ( 4'b0 ), .s_axi_aruser ( 1'b0 ), .s_axi_arvalid ( 1'b0 ), .s_axi_arready ( ), .s_axi_rid (), .s_axi_rdata (mr_rdata ), .s_axi_rresp (mr_rresp ), .s_axi_rlast (mr_rlast ), .s_axi_ruser (), .s_axi_rvalid (mr_rvalid ), .s_axi_rready (mr_rready ), .m_axi_awid (), .m_axi_awaddr (), .m_axi_awlen (), .m_axi_awsize (), .m_axi_awburst (), .m_axi_awlock (), .m_axi_awcache (), .m_axi_awprot (), .m_axi_awregion (), .m_axi_awqos (), .m_axi_awuser (), .m_axi_awvalid (), .m_axi_awready (1'b0), .m_axi_wid () , .m_axi_wdata (), .m_axi_wstrb (), .m_axi_wlast (), .m_axi_wuser (), .m_axi_wvalid (), .m_axi_wready (1'b0), .m_axi_bid ( 1'b0 ) , .m_axi_bresp ( 2'b0 ) , .m_axi_buser ( 1'b0 ) , .m_axi_bvalid ( 1'b0 ) , .m_axi_bready ( ) , .m_axi_arid (), .m_axi_araddr (), .m_axi_arlen (), .m_axi_arsize (), .m_axi_arburst (), .m_axi_arlock (), .m_axi_arcache (), .m_axi_arprot (), .m_axi_arregion (), .m_axi_arqos (), .m_axi_aruser (), .m_axi_arvalid (), .m_axi_arready (1'b0), .m_axi_rid (1'b0 ), .m_axi_rdata (m_axi_rdata ), .m_axi_rresp (m_axi_rresp ), .m_axi_rlast (m_axi_rlast ), .m_axi_ruser (1'b0 ), .m_axi_rvalid (m_axi_rvalid ), .m_axi_rready (m_axi_rready_i ) ); assign m_axi_araddr = m_axi_araddr_i ; assign m_axi_arlen = m_axi_arlen_i ; assign m_axi_arsize = m_axi_arsize_i ; assign m_axi_arburst = m_axi_arburst_i ; assign m_axi_arlock = m_axi_arlock_i ; assign m_axi_arcache = m_axi_arcache_i ; assign m_axi_arprot = m_axi_arprot_i ; assign m_axi_arregion = m_axi_arregion_i ; assign m_axi_arqos = m_axi_arqos_i ; assign m_axi_arvalid = m_axi_arvalid_i ; assign m_axi_arready_i = m_axi_arready ; assign m_axi_rready = m_axi_rready_i; end // gen_r_upsizer end else begin : NO_READ assign sr_arready = 1'b0; assign s_axi_rid = {C_S_AXI_ID_WIDTH{1'b0}}; assign s_axi_rdata = {C_S_AXI_DATA_WIDTH{1'b0}}; assign s_axi_rresp = 2'b0; assign s_axi_rlast = 1'b0; assign s_axi_rvalid = 1'b0; assign m_axi_araddr = {C_AXI_ADDR_WIDTH{1'b0}}; assign m_axi_arlen = 8'b0; assign m_axi_arsize = 3'b0; assign m_axi_arburst = 2'b0; assign m_axi_arlock = 2'b0; assign m_axi_arcache = 4'b0; assign m_axi_arprot = 3'b0; assign m_axi_arregion = 4'b0; assign m_axi_arqos = 4'b0; assign m_axi_arvalid = 1'b0; assign mr_rready = 1'b0; end endgenerate endmodule `default_nettype wire

//deps: sdram_controller3.v, IS42S16160.v `timescale 1ns/1ps module sdram_controller3_tb; /*AUTOWIRE*/ // Beginning of automatic wires (for undeclared instantiated-module outputs) wire [12:0] DRAM_ADDR; // From controller of sdram_controller3.v wire [1:0] DRAM_BA; // From controller of sdram_controller3.v wire DRAM_CAS_N; // From controller of sdram_controller3.v wire DRAM_CKE; // From controller of sdram_controller3.v wire DRAM_CLK; // From controller of sdram_controller3.v wire DRAM_CS_N; // From controller of sdram_controller3.v wire [15:0] DRAM_DQ; // To/From controller of sdram_controller3.v wire [1:0] DRAM_DQM; // From controller of sdram_controller3.v wire DRAM_RAS_N; // From controller of sdram_controller3.v wire DRAM_WE_N; // From controller of sdram_controller3.v wire [31:0] data_out; // From controller of sdram_controller3.v wire data_valid; // From controller of sdram_controller3.v wire write_complete; // From controller of sdram_controller3.v // End of automatics /*AUTOREGINPUT*/ // Beginning of automatic reg inputs (for undeclared instantiated-module inputs) reg CLOCK_100; // To controller of sdram_controller3.v reg CLOCK_100_del_3ns; // To controller of sdram_controller3.v reg CLOCK_50; // To controller of sdram_controller3.v reg [23:0] address; // To controller of sdram_controller3.v reg [31:0] data_in; // To controller of sdram_controller3.v reg req_read; // To controller of sdram_controller3.v reg req_write; // To controller of sdram_controller3.v reg rst; // To controller of sdram_controller3.v // End of automatics sdram_controller3 controller(/*AUTOINST*/ // Outputs .data_out (data_out[31:0]), .data_valid (data_valid), .write_complete (write_complete), .DRAM_ADDR (DRAM_ADDR[12:0]), .DRAM_BA (DRAM_BA[1:0]), .DRAM_CAS_N (DRAM_CAS_N), .DRAM_CKE (DRAM_CKE), .DRAM_CLK (DRAM_CLK), .DRAM_CS_N (DRAM_CS_N), .DRAM_DQM (DRAM_DQM[1:0]), .DRAM_RAS_N (DRAM_RAS_N), .DRAM_WE_N (DRAM_WE_N), // Inouts .DRAM_DQ (DRAM_DQ[15:0]), // Inputs .CLOCK_50 (CLOCK_50), .CLOCK_100 (CLOCK_100), .CLOCK_100_del_3ns(CLOCK_100_del_3ns), .rst (rst), .address (address[23:0]), .req_read (req_read), .req_write (req_write), .data_in (data_in[31:0])); IS42S16160 RAM ( // Inouts .Dq (DRAM_DQ[15:0]), // Inputs .Addr (DRAM_ADDR[12:0]), .Ba (DRAM_BA[1:0]), .Clk (DRAM_CLK), .Cke (DRAM_CKE), .Cs_n (DRAM_CS_N), .Ras_n (DRAM_RAS_N), .Cas_n (DRAM_CAS_N), .We_n (DRAM_WE_N), .Dqm (DRAM_DQM[1:0])); initial begin rst = 1; CLOCK_50 = 0; CLOCK_100 = 0; CLOCK_100_del_3ns = 0; address = 0; req_read = 0; req_write = 0; data_in = 0; $dumpfile("dump.vcd"); $dumpvars; #3000 $finish; end always #10 CLOCK_50 <= ~CLOCK_50; always #5 begin CLOCK_100 <= ~CLOCK_100; end always @(CLOCK_100) begin #3 CLOCK_100_del_3ns <= CLOCK_100; end initial begin #20 rst = 0; #1000 address = 16; data_in = 32'h12345678; req_write = 1; #20 req_write = 0; @(posedge write_complete) #60 address = 16; req_read = 1; #20 req_read = 0; end // initial begin endmodule

//------------------------------------------------------------------------------ // This confidential and proprietary software may be used only as authorized by // a licensing agreement from Altera Corporation. // // Legal Notice: (C)2010 Altera Corporation. All rights reserved. Your // use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any // output files any of the foregoing (including device programming or // simulation files), and any associated documentation or information are // expressly subject to the terms and conditions of the Altera Program // License Subscription Agreement or other applicable license agreement, // including, without limitation, that your use is for the sole purpose // of programming logic devices manufactured by Altera and sold by Altera // or its authorized distributors. Please refer to the applicable // agreement for further details. // // The entire notice above must be reproduced on all authorized copies and any // such reproduction must be pursuant to a licensing agreement from Altera. // // Title : Example top level testbench for ddr3_int DDR/2/3 SDRAM High Performance Controller // Project : DDR/2/3 SDRAM High Performance Controller // // File : ddr3_int_example_top_tb.v // // Revision : V10.0 // // Abstract: // Automatically generated testbench for the example top level design to allow // functional and timing simulation. // //------------------------------------------------------------------------------ // // *************** This is a MegaWizard generated file **************** // // If you need to edit this file make sure the edits are not inside any 'MEGAWIZARD' // text insertion areas. // (between "<< START MEGAWIZARD INSERT" and "<< END MEGAWIZARD INSERT" comments) // // Any edits inside these delimiters will be overwritten by the megawizard if you // re-run it. // // If you really need to make changes inside these delimiters then delete // both 'START' and 'END' delimiters. This will stop the megawizard updating this // section again. // //---------------------------------------------------------------------------------- // << START MEGAWIZARD INSERT PARAMETER_LIST // Parameters: // // Device Family : arria ii gx // local Interface Data Width : 128 // MEM_CHIPSELS : 1 // MEM_CS_PER_RANK : 1 // MEM_BANK_BITS : 3 // MEM_ROW_BITS : 13 // MEM_COL_BITS : 10 // LOCAL_DATA_BITS : 128 // NUM_CLOCK_PAIRS : 1 // CLOCK_TICK_IN_PS : 3333 // REGISTERED_DIMM : false // TINIT_CLOCKS : 75008 // Data_Width_Ratio : 4 // << END MEGAWIZARD INSERT PARAMETER_LIST //---------------------------------------------------------------------------------- // << MEGAWIZARD PARSE FILE DDR10.0 `timescale 1 ps/1 ps // << START MEGAWIZARD INSERT MODULE module ddr3_int_example_top_tb (); // << END MEGAWIZARD INSERT MODULE // << START MEGAWIZARD INSERT PARAMS parameter gMEM_CHIPSELS = 1; parameter gMEM_CS_PER_RANK = 1; parameter gMEM_NUM_RANKS = 1 / 1; parameter gMEM_BANK_BITS = 3; parameter gMEM_ROW_BITS = 13; parameter gMEM_COL_BITS = 10; parameter gMEM_ADDR_BITS = 13; parameter gMEM_DQ_PER_DQS = 8; parameter DM_DQS_WIDTH = 4; parameter gLOCAL_DATA_BITS = 128; parameter gLOCAL_IF_DWIDTH_AFTER_ECC = 128; parameter gNUM_CLOCK_PAIRS = 1; parameter RTL_ROUNDTRIP_CLOCKS = 0.0; parameter CLOCK_TICK_IN_PS = 3333; parameter REGISTERED_DIMM = 1'b0; parameter BOARD_DQS_DELAY = 0; parameter BOARD_CLK_DELAY = 0; parameter DWIDTH_RATIO = 4; parameter TINIT_CLOCKS = 75008; parameter REF_CLOCK_TICK_IN_PS = 40000; // Parameters below are for generic memory model parameter gMEM_TQHS_PS = 300; parameter gMEM_TAC_PS = 400; parameter gMEM_TDQSQ_PS = 125; parameter gMEM_IF_TRCD_NS = 13.5; parameter gMEM_IF_TWTR_CK = 4; parameter gMEM_TDSS_CK = 0.2; parameter gMEM_IF_TRFC_NS = 110.0; parameter gMEM_IF_TRP_NS = 13.5; parameter gMEM_IF_TRCD_PS = gMEM_IF_TRCD_NS * 1000.0; parameter gMEM_IF_TWTR_PS = gMEM_IF_TWTR_CK * CLOCK_TICK_IN_PS; parameter gMEM_IF_TRFC_PS = gMEM_IF_TRFC_NS * 1000.0; parameter gMEM_IF_TRP_PS = gMEM_IF_TRP_NS * 1000.0; parameter CLOCK_TICK_IN_NS = CLOCK_TICK_IN_PS / 1000.0; parameter gMEM_TDQSQ_NS = gMEM_TDQSQ_PS / 1000.0; parameter gMEM_TDSS_NS = gMEM_TDSS_CK * CLOCK_TICK_IN_NS; // << END MEGAWIZARD INSERT PARAMS // set to zero for Gatelevel parameter RTL_DELAYS = 1; parameter USE_GENERIC_MEMORY_MODEL = 1'b0; // The round trip delay is now modeled inside the datapath (<your core name>_auk_ddr_dqs_group.v/vhd) for RTL simulation. parameter D90_DEG_DELAY = 0; //RTL only parameter GATE_BOARD_DQS_DELAY = BOARD_DQS_DELAY * (RTL_DELAYS ? 0 : 1); // Gate level timing only parameter GATE_BOARD_CLK_DELAY = BOARD_CLK_DELAY * (RTL_DELAYS ? 0 : 1); // Gate level timing only // Below 5 lines for SPR272543: // Testbench workaround for tests with "dedicated memory clock phase shift" failing, // because dqs delay isnt' being modelled in simulations parameter gMEM_CLK_PHASE_EN = "false"; parameter real gMEM_CLK_PHASE = 0; parameter real MEM_CLK_RATIO = ((360.0-gMEM_CLK_PHASE)/360.0); parameter MEM_CLK_DELAY = MEM_CLK_RATIO*CLOCK_TICK_IN_PS * ((gMEM_CLK_PHASE_EN=="true") ? 1 : 0); wire clk_to_ram0, clk_to_ram1, clk_to_ram2; wire cmd_bus_watcher_enabled; reg clk; reg clk_n; reg reset_n; wire mem_reset_n; wire[gMEM_ADDR_BITS - 1:0] a; wire[gMEM_BANK_BITS - 1:0] ba; wire[gMEM_CHIPSELS - 1:0] cs_n; wire[gMEM_NUM_RANKS - 1:0] cke; wire[gMEM_NUM_RANKS - 1:0] odt; //DDR2 only wire ras_n; wire cas_n; wire we_n; wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dm; //wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dqs; //wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dqs_n; //wire stratix_dqs_ref_clk; // only used on stratix to provide external dll reference clock wire[gNUM_CLOCK_PAIRS - 1:0] clk_to_sdram; wire[gNUM_CLOCK_PAIRS - 1:0] clk_to_sdram_n; wire #(GATE_BOARD_CLK_DELAY * 1) clk_to_ram; wire clk_to_ram_n; wire[gMEM_ROW_BITS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) a_delayed; wire[gMEM_BANK_BITS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) ba_delayed; wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) cke_delayed; wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) odt_delayed; //DDR2 only wire[gMEM_NUM_RANKS - 1:0] #(GATE_BOARD_CLK_DELAY * 1 + 1) cs_n_delayed; wire #(GATE_BOARD_CLK_DELAY * 1 + 1) ras_n_delayed; wire #(GATE_BOARD_CLK_DELAY * 1 + 1) cas_n_delayed; wire #(GATE_BOARD_CLK_DELAY * 1 + 1) we_n_delayed; wire[gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] dm_delayed; // DDR3 parity only wire ac_parity; wire mem_err_out_n; assign mem_err_out_n = 1'b1; // pulldown (dm); assign (weak1, weak0) dm = 0; tri [gLOCAL_DATA_BITS / DWIDTH_RATIO - 1:0] mem_dq = 100'bz; tri [gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] mem_dqs = 100'bz; tri [gLOCAL_DATA_BITS / DWIDTH_RATIO / gMEM_DQ_PER_DQS - 1:0] mem_dqs_n = 100'bz; assign (weak1, weak0) mem_dq = 0; assign (weak1, weak0) mem_dqs = 0; assign (weak1, weak0) mem_dqs_n = 1; wire [gMEM_BANK_BITS - 1:0] zero_one; //"01"; assign zero_one = 1; wire test_complete; wire [7:0] test_status; // counter to count the number of sucessful read and write loops integer test_complete_count; wire pnf; wire [gLOCAL_IF_DWIDTH_AFTER_ECC / 8 - 1:0] pnf_per_byte; assign cmd_bus_watcher_enabled = 1'b0; // Below 5 lines for SPR272543: // Testbench workaround for tests with "dedicated memory clock phase shift" failing, // because dqs delay isnt' being modelled in simulations assign #(MEM_CLK_DELAY/4.0) clk_to_ram2 = clk_to_sdram[0]; assign #(MEM_CLK_DELAY/4.0) clk_to_ram1 = clk_to_ram2; assign #(MEM_CLK_DELAY/4.0) clk_to_ram0 = clk_to_ram1; assign #((MEM_CLK_DELAY/4.0)) clk_to_ram = clk_to_ram0; assign clk_to_ram_n = ~clk_to_ram ; // mem model ignores clk_n ? // ddr sdram interface // << START MEGAWIZARD INSERT ENTITY ddr3_int_example_top dut ( // << END MEGAWIZARD INSERT ENTITY .clock_source(clk), .global_reset_n(reset_n), // << START MEGAWIZARD INSERT PORT_MAP .mem_clk(clk_to_sdram), .mem_clk_n(clk_to_sdram_n), .mem_odt(odt), .mem_dqsn(mem_dqs_n), .mem_reset_n(mem_reset_n), .mem_cke(cke), .mem_cs_n(cs_n), .mem_ras_n(ras_n), .mem_cas_n(cas_n), .mem_we_n(we_n), .mem_ba(ba), .mem_addr(a), .mem_dq(mem_dq), .mem_dqs(mem_dqs), .mem_dm(dm), // << END MEGAWIZARD INSERT PORT_MAP .test_complete(test_complete), .test_status(test_status), .pnf_per_byte(pnf_per_byte), .pnf(pnf) ); // << START MEGAWIZARD INSERT MEMORY_ARRAY // This will need updating to match the memory models you are using. // Instantiate a generated DDR memory model to match the datawidth & chipselect requirements ddr3_int_mem_model mem ( .mem_rst_n (mem_reset_n), .mem_dq (mem_dq), .mem_dqs (mem_dqs), .mem_dqs_n (mem_dqs_n), .mem_addr (a_delayed), .mem_ba (ba_delayed), .mem_clk (clk_to_ram), .mem_clk_n (clk_to_ram_n), .mem_cke (cke_delayed), .mem_cs_n (cs_n_delayed), .mem_ras_n (ras_n_delayed), .mem_cas_n (cas_n_delayed), .mem_we_n (we_n_delayed), .mem_dm (dm_delayed), .mem_odt (odt_delayed) ); // << END MEGAWIZARD INSERT MEMORY_ARRAY always begin clk <= 1'b0 ; clk_n <= 1'b1 ; while (1'b1) begin #((REF_CLOCK_TICK_IN_PS / 2) * 1); clk <= ~clk ; clk_n <= ~clk_n ; end end initial begin reset_n <= 1'b0 ; @(clk); @(clk); @(clk); @(clk); @(clk); @(clk); reset_n <= 1'b1 ; end // control and data lines = 3 inches assign a_delayed = a[gMEM_ROW_BITS - 1:0] ; assign ba_delayed = ba ; assign cke_delayed = cke ; assign odt_delayed = odt ; assign cs_n_delayed = cs_n ; assign ras_n_delayed = ras_n ; assign cas_n_delayed = cas_n ; assign we_n_delayed = we_n ; assign dm_delayed = dm ; // --------------------------------------------------------------- initial begin : endit integer count; reg ln; count = 0; // Stop simulation after test_complete or TINIT + 600000 clocks while ((count < (TINIT_CLOCKS + 600000)) & (test_complete !== 1)) begin count = count + 1; @(negedge clk_to_sdram[0]); end if (test_complete === 1) begin if (pnf) begin $write($time); $write(" --- SIMULATION PASSED --- "); $stop; end else begin $write($time); $write(" --- SIMULATION FAILED --- "); $stop; end end else begin $write($time); $write(" --- SIMULATION FAILED, DID NOT COMPLETE --- "); $stop; end end always @(clk_to_sdram[0] or reset_n) begin if (!reset_n) begin test_complete_count <= 0 ; end else if ((clk_to_sdram[0])) begin if (test_complete) begin test_complete_count <= test_complete_count + 1 ; end end end reg[2:0] cmd_bus; //*********************************************************** // Watch the SDRAM command bus always @(clk_to_ram) begin if (clk_to_ram) begin if (1'b1) begin cmd_bus = {ras_n_delayed, cas_n_delayed, we_n_delayed}; case (cmd_bus) 3'b000 : begin // LMR command $write($time); if (ba_delayed == zero_one) begin $write(" ELMR settings = "); if (!(a_delayed[0])) begin $write("DLL enable"); end end else begin $write(" LMR settings = "); case (a_delayed[1:0]) 3'b00 : $write("BL = 8,"); 3'b01 : $write("BL = On The Fly,"); 3'b10 : $write("BL = 4,"); default : $write("BL = ??,"); endcase case (a_delayed[6:4]) 3'b001 : $write(" CL = 5.0,"); 3'b010 : $write(" CL = 6.0,"); 3'b011 : $write(" CL = 7.0,"); 3'b100 : $write(" CL = 8.0,"); 3'b101 : $write(" CL = 9.0,"); 3'b110 : $write(" CL = 10.0,"); default : $write(" CL = ??,"); endcase if ((a_delayed[8])) $write(" DLL reset"); end $write("\n"); end 3'b001 : begin // ARF command $write($time); $write(" ARF\n"); end 3'b010 : begin // PCH command $write($time); $write(" PCH"); if ((a_delayed[10])) begin $write(" all banks \n"); end else begin $write(" bank "); $write("%H\n", ba_delayed); end end 3'b011 : begin // ACT command $write($time); $write(" ACT row address "); $write("%H", a_delayed); $write(" bank "); $write("%H\n", ba_delayed); end 3'b100 : begin // WR command $write($time); $write(" WR to col address "); $write("%H", a_delayed); $write(" bank "); $write("%H\n", ba_delayed); end 3'b101 : begin // RD command $write($time); $write(" RD from col address "); $write("%H", a_delayed); $write(" bank "); $write("%H\n", ba_delayed); end 3'b110 : begin // BT command $write($time); $write(" BT "); end 3'b111 : begin // NOP command end endcase end else begin end // if enabled end end endmodule

//wishbone master interconnect testbench /* Distributed under the MIT licesnse. Copyright (c) 2011 Dave McCoy ([email protected]) Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /* Log 04/16/2013 -implement naming convention 08/30/2012 -Major overhall of the testbench -modfied the way reads and writes happen, now each write requires the number of 32-bit data packets even if the user sends only 1 -there is no more streaming as the data_count will implicity declare that a read/write is streaming -added the ih_reset which has not been formally defined within the system, but will more than likely reset the entire statemachine 11/12/2011 -overhauled the design to behave more similar to a real I/O handler -changed the timeout to 40 seconds to allow the wishbone master to catch nacks 11/08/2011 -added interrupt support */ `timescale 1 ns/1 ps `define TIMEOUT_COUNT 40 `define INPUT_FILE "sim/master_input_test_data.txt" `define OUTPUT_FILE "sim/master_output_test_data.txt" `define CLK_HALF_PERIOD 10 `define CLK_PERIOD (2 * `CLK_HALF_PERIOD) `define SLEEP_HALF_CLK #(`CLK_HALF_PERIOD) `define SLEEP_FULL_CLK #(`CLK_PERIOD) //Sleep a number of clock cycles `define SLEEP_CLK(x) #(x * `CLK_PERIOD) //`define VERBOSE module wishbone_master_tb ( ); //Virtual Host Interface Signals reg clk = 0; reg rst = 0; wire w_master_ready; reg r_in_ready = 0; reg [31:0] r_in_command = 32'h00000000; reg [31:0] r_in_address = 32'h00000000; reg [31:0] r_in_data = 32'h00000000; reg [27:0] r_in_data_count = 0; reg r_out_ready = 0; wire w_out_en; wire [31:0] w_out_status; wire [31:0] w_out_address; wire [31:0] w_out_data; wire [27:0] w_out_data_count; reg r_ih_reset = 0; //wishbone signals wire w_wbm_we; wire w_wbm_cyc; wire w_wbm_stb; wire [3:0] w_wbm_sel; wire [31:0] w_wbm_adr; wire [31:0] w_wbm_dat_o; wire [31:0] w_wbm_dat_i; wire w_wbm_ack; wire w_wbm_int; //Wishbone Slave 0 (SDB) signals wire w_wbs0_we; wire w_wbs0_cyc; wire [31:0] w_wbs0_dat_o; wire w_wbs0_stb; wire [3:0] w_wbs0_sel; wire w_wbs0_ack; wire [31:0] w_wbs0_dat_i; wire [31:0] w_wbs0_adr; wire w_wbs0_int; //wishbone slave 1 (Unit Under Test) signals wire w_wbs1_we; wire w_wbs1_cyc; wire w_wbs1_stb; wire [3:0] w_wbs1_sel; wire w_wbs1_ack; wire [31:0] w_wbs1_dat_i; wire [31:0] w_wbs1_dat_o; wire [31:0] w_wbs1_adr; wire w_wbs1_int; //Local Parameters localparam WAIT_FOR_SDRAM = 8'h00; localparam IDLE = 8'h01; localparam SEND_COMMAND = 8'h02; localparam MASTER_READ_COMMAND = 8'h03; localparam RESET = 8'h04; localparam PING_RESPONSE = 8'h05; localparam WRITE_DATA = 8'h06; localparam WRITE_RESPONSE = 8'h07; localparam GET_WRITE_DATA = 8'h08; localparam READ_RESPONSE = 8'h09; localparam READ_MORE_DATA = 8'h0A; localparam FINISHED = 8'h0B; //Registers/Wires/Simulation Integers integer fd_in; integer fd_out; integer read_count; integer timeout_count; integer ch; integer data_count; reg [3:0] state = IDLE; reg prev_int = 0; wire start; reg execute_command; reg command_finished; reg request_more_data; reg request_more_data_ack; reg [27:0] data_write_count; reg [27:0] data_read_count; //Submodules wishbone_master wm ( .clk (clk ), .rst (rst ), .i_ih_rst (r_ih_reset ), .i_ready (r_in_ready ), .i_command (r_in_command ), .i_address (r_in_address ), .i_data (r_in_data ), .i_data_count (r_in_data_count ), .i_out_ready (r_out_ready ), .o_en (w_out_en ), .o_status (w_out_status ), .o_address (w_out_address ), .o_data (w_out_data ), .o_data_count (w_out_data_count ), .o_master_ready (w_master_ready ), .o_per_we (w_wbm_we ), .o_per_adr (w_wbm_adr ), .o_per_dat (w_wbm_dat_i ), .i_per_dat (w_wbm_dat_o ), .o_per_stb (w_wbm_stb ), .o_per_cyc (w_wbm_cyc ), .o_per_msk (w_wbm_msk ), .o_per_sel (w_wbm_sel ), .i_per_ack (w_wbm_ack ), .i_per_int (w_wbm_int ) ); //slave 1 wb_hs_demo s1 ( .clk (clk ), .rst (rst ), .i_wbs_we (w_wbs1_we ), .i_wbs_cyc (w_wbs1_cyc ), .i_wbs_dat (w_wbs1_dat_i ), .i_wbs_stb (w_wbs1_stb ), .o_wbs_ack (w_wbs1_ack ), .o_wbs_dat (w_wbs1_dat_o ), .i_wbs_adr (w_wbs1_adr ), .o_wbs_int (w_wbs1_int ) ); wishbone_interconnect wi ( .clk (clk ), .rst (rst ), .i_m_we (w_wbm_we ), .i_m_cyc (w_wbm_cyc ), .i_m_stb (w_wbm_stb ), .o_m_ack (w_wbm_ack ), .i_m_dat (w_wbm_dat_i ), .o_m_dat (w_wbm_dat_o ), .i_m_adr (w_wbm_adr ), .o_m_int (w_wbm_int ), .o_s0_we (w_wbs0_we ), .o_s0_cyc (w_wbs0_cyc ), .o_s0_stb (w_wbs0_stb ), .i_s0_ack (w_wbs0_ack ), .o_s0_dat (w_wbs0_dat_i ), .i_s0_dat (w_wbs0_dat_o ), .o_s0_adr (w_wbs0_adr ), .i_s0_int (w_wbs0_int ), .o_s1_we (w_wbs1_we ), .o_s1_cyc (w_wbs1_cyc ), .o_s1_stb (w_wbs1_stb ), .i_s1_ack (w_wbs1_ack ), .o_s1_dat (w_wbs1_dat_i ), .i_s1_dat (w_wbs1_dat_o ), .o_s1_adr (w_wbs1_adr ), .i_s1_int (w_wbs1_int ) ); assign w_wbs0_ack = 0; assign w_wbs0_dat_o = 0; assign start = 1; always #`CLK_HALF_PERIOD clk = ~clk; initial begin fd_out = 0; read_count = 0; data_count = 0; timeout_count = 0; request_more_data_ack <= 0; execute_command <= 0; $dumpfile ("design.vcd"); $dumpvars (0, wishbone_master_tb); fd_in = $fopen(`INPUT_FILE, "r"); fd_out = $fopen(`OUTPUT_FILE, "w"); `SLEEP_HALF_CLK; rst <= 0; `SLEEP_CLK(100); rst <= 1; //clear the handler signals r_in_ready <= 0; r_in_command <= 0; r_in_address <= 32'h0; r_in_data <= 32'h0; r_in_data_count <= 0; r_out_ready <= 0; //clear wishbone signals `SLEEP_CLK(10); rst <= 0; r_out_ready <= 1; if (fd_in == 0) begin $display ("TB: input stimulus file was not found"); end else begin //while there is still data to be read from the file while (!$feof(fd_in)) begin //read in a command read_count = $fscanf (fd_in, "%h:%h:%h:%h\n", r_in_data_count, r_in_command, r_in_address, r_in_data); //Handle Frindge commands/comments if (read_count != 4) begin if (read_count == 0) begin ch = $fgetc(fd_in); if (ch == "\#") begin //$display ("Eat a comment"); //Eat the line while (ch != "\n") begin ch = $fgetc(fd_in); end `ifdef VERBOSE $display (""); `endif end else begin `ifdef VERBOSE $display ("Error unrecognized line: %h" % ch); `endif //Eat the line while (ch != "\n") begin ch = $fgetc(fd_in); end end end else if (read_count == 1) begin `ifdef VERBOSE $display ("Sleep for %h Clock cycles", r_in_data_count); `endif `SLEEP_CLK(r_in_data_count); `ifdef VERBOSE $display ("Sleep Finished"); `endif end else begin `ifdef VERBOSE $display ("Error: read_count = %h != 4", read_count); `endif `ifdef VERBOSE $display ("Character: %h", ch); `endif end end else begin `ifdef VERBOSE case (r_in_command) 0: $display ("TB: Executing PING commad"); 1: $display ("TB: Executing WRITE command"); 2: $display ("TB: Executing READ command"); 3: $display ("TB: Executing RESET command"); endcase `endif `ifdef VERBOSE $display ("Execute Command"); `endif execute_command <= 1; `SLEEP_CLK(1); while (~command_finished) begin request_more_data_ack <= 0; if ((r_in_command & 32'h0000FFFF) == 1) begin if (request_more_data && ~request_more_data_ack) begin read_count = $fscanf(fd_in, "%h\n", r_in_data); `ifdef VERBOSE $display ("TB: reading a new double word: %h", r_in_data); `endif request_more_data_ack <= 1; end end //so time porgresses wait a tick `SLEEP_CLK(1); //this doesn't need to be here, but there is a weird behavior in iverilog //that wont allow me to put a delay in right before an 'end' statement //execute_command <= 1; end //while command is not finished execute_command <= 0; while (command_finished) begin `ifdef VERBOSE $display ("Command Finished"); `endif `SLEEP_CLK(1); execute_command <= 0; end `SLEEP_CLK(50); `ifdef VERBOSE $display ("TB: finished command"); `endif end //end read_count == 4 end //end while ! eof end //end not reset `SLEEP_CLK(50); $fclose (fd_in); $fclose (fd_out); $finish(); end //initial begin // $monitor("%t, state: %h", $time, state); //end //initial begin // $monitor("%t, data: %h, state: %h, execute command: %h", $time, w_wbm_dat_o, state, execute_command); //end //initial begin //$monitor("%t, state: %h, execute: %h, cmd_fin: %h", $time, state, execute_command, command_finished); //$monitor("%t, state: %h, write_size: %d, write_count: %d, execute: %h", $time, state, r_in_data_count, data_write_count, execute_command); //end always @ (posedge clk) begin if (rst) begin state <= WAIT_FOR_SDRAM; request_more_data <= 0; timeout_count <= 0; prev_int <= 0; r_ih_reset <= 0; data_write_count <= 0; data_read_count <= 1; command_finished <= 0; end else begin r_ih_reset <= 0; r_in_ready <= 0; r_out_ready <= 1; command_finished <= 0; //Countdown the NACK timeout if (execute_command && timeout_count < `TIMEOUT_COUNT) begin timeout_count <= timeout_count + 1; end if (execute_command && timeout_count >= `TIMEOUT_COUNT) begin `ifdef VERBOSE case (r_in_command) 0: $display ("TB: Master timed out while executing PING commad"); 1: $display ("TB: Master timed out while executing WRITE command"); 2: $display ("TB: Master timed out while executing READ command"); 3: $display ("TB: Master timed out while executing RESET command"); endcase `endif command_finished <= 1; state <= IDLE; timeout_count <= 0; end //end reached the end of a timeout case (state) WAIT_FOR_SDRAM: begin timeout_count <= 0; r_in_ready <= 0; //Uncomment 'start' conditional to wait for SDRAM to finish starting //up if (start) begin `ifdef VERBOSE $display ("TB: sdram is ready"); `endif state <= IDLE; end end IDLE: begin timeout_count <= 0; command_finished <= 0; data_write_count <= 1; if (execute_command && !command_finished) begin state <= SEND_COMMAND; end data_read_count <= 1; end SEND_COMMAND: begin timeout_count <= 0; if (w_master_ready) begin r_in_ready <= 1; state <= MASTER_READ_COMMAND; end end MASTER_READ_COMMAND: begin r_in_ready <= 1; if (!w_master_ready) begin r_in_ready <= 0; case (r_in_command & 32'h0000FFFF) 0: begin state <= PING_RESPONSE; end 1: begin if (r_in_data_count > 1) begin `ifdef VERBOSE $display ("TB:\tWrote Double Word %d: %h", data_write_count, r_in_data); `endif if (data_write_count < r_in_data_count) begin state <= WRITE_DATA; timeout_count <= 0; data_write_count<= data_write_count + 1; end else begin `ifdef VERBOSE $display ("TB: Finished Writing: %d 32bit words of %d size", r_in_data_count, data_write_count); `endif state <= WRITE_RESPONSE; end end else begin `ifdef VERBOSE $display ("TB:\tWrote Double Word %d: %h", data_write_count, r_in_data); `endif `ifdef VERBOSE $display ("TB: Finished Writing: %d 32bit words of %d size", r_in_data_count, data_write_count); `endif state <= WRITE_RESPONSE; end end 2: begin state <= READ_RESPONSE; end 3: begin state <= RESET; end endcase end end RESET: begin r_ih_reset <= 1; state <= RESET; end PING_RESPONSE: begin if (w_out_en) begin if (w_out_status[7:0] == 8'hFF) begin `ifdef VERBOSE $display ("TB: Ping Response Good"); `endif end else begin `ifdef VERBOSE $display ("TB: Ping Response Bad (Malformed response: %h)", w_out_status); `endif end `ifdef VERBOSE $display ("TB: \tS:A:D = %h:%h:%h\n", w_out_status, w_out_address, w_out_data); `endif state <= FINISHED; end end WRITE_DATA: begin if (!r_in_ready && w_master_ready) begin state <= GET_WRITE_DATA; request_more_data <= 1; end end WRITE_RESPONSE: begin `ifdef VERBOSE $display ("In Write Response"); `endif if (w_out_en) begin if (w_out_status[7:0] == (~(8'h01))) begin `ifdef VERBOSE $display ("TB: Write Response Good"); `endif end else begin `ifdef VERBOSE $display ("TB: Write Response Bad (Malformed response: %h)", w_out_status); `endif end `ifdef VERBOSE $display ("TB: \tS:A:D = %h:%h:%h\n", w_out_status, w_out_address, w_out_data); `endif state <= FINISHED; end end GET_WRITE_DATA: begin if (request_more_data_ack) begin request_more_data <= 0; r_in_ready <= 1; state <= SEND_COMMAND; end end READ_RESPONSE: begin if (w_out_en) begin if (w_out_status[7:0] == (~(8'h02))) begin `ifdef VERBOSE $display ("TB: Read Response Good"); `endif if (w_out_data_count > 0) begin if (data_read_count < w_out_data_count) begin state <= READ_MORE_DATA; timeout_count <= 0; data_read_count <= data_read_count + 1; end else begin state <= FINISHED; end end end else begin `ifdef VERBOSE $display ("TB: Read Response Bad (Malformed response: %h)", w_out_status); `endif state <= FINISHED; end `ifdef VERBOSE $display ("TB: \tS:A:D = %h:%h:%h\n", w_out_status, w_out_address, w_out_data); `endif end end READ_MORE_DATA: begin if (w_out_en) begin timeout_count <= 0; r_out_ready <= 0; `ifdef VERBOSE $display ("TB: Read a 32bit data packet"); `endif `ifdef VERBOSE $display ("TB: \tRead Data: %h", w_out_data); `endif data_read_count <= data_read_count + 1; end if (data_read_count >= r_in_data_count) begin state <= FINISHED; end end FINISHED: begin command_finished <= 1; if (!execute_command) begin `ifdef VERBOSE $display ("Execute Command is low"); `endif command_finished <= 0; state <= IDLE; end end endcase if (w_out_en && w_out_status == `PERIPH_INTERRUPT) begin `ifdef VERBOSE $display("TB: Output Handler Recieved interrupt"); `endif `ifdef VERBOSE $display("TB:\tcommand: %h", w_out_status); `endif `ifdef VERBOSE $display("TB:\taddress: %h", w_out_address); `endif `ifdef VERBOSE $display("TB:\tdata: %h", w_out_data); `endif end end//not reset end endmodule

// Copyright 1986-2017 Xilinx, Inc. All Rights Reserved. // -------------------------------------------------------------------------------- // Tool Version: Vivado v.2017.2 (win64) Build 1909853 Thu Jun 15 18:39:09 MDT 2017 // Date : Tue Sep 19 09:38:30 2017 // Host : DarkCube running 64-bit major release (build 9200) // Command : write_verilog -force -mode synth_stub -rename_top decalper_eb_ot_sdeen_pot_pi_dehcac_xnilix -prefix // decalper_eb_ot_sdeen_pot_pi_dehcac_xnilix_ zynq_design_1_processing_system7_0_0_stub.v // Design : zynq_design_1_processing_system7_0_0 // Purpose : Stub declaration of top-level module interface // Device : xc7z020clg484-1 // -------------------------------------------------------------------------------- // This empty module with port declaration file causes synthesis tools to infer a black box for IP. // The synthesis directives are for Synopsys Synplify support to prevent IO buffer insertion. // Please paste the declaration into a Verilog source file or add the file as an additional source. (* X_CORE_INFO = "processing_system7_v5_5_processing_system7,Vivado 2017.2" *) module decalper_eb_ot_sdeen_pot_pi_dehcac_xnilix(TTC0_WAVE0_OUT, TTC0_WAVE1_OUT, TTC0_WAVE2_OUT, USB0_PORT_INDCTL, USB0_VBUS_PWRSELECT, USB0_VBUS_PWRFAULT, M_AXI_GP0_ARVALID, M_AXI_GP0_AWVALID, M_AXI_GP0_BREADY, M_AXI_GP0_RREADY, M_AXI_GP0_WLAST, M_AXI_GP0_WVALID, M_AXI_GP0_ARID, M_AXI_GP0_AWID, M_AXI_GP0_WID, M_AXI_GP0_ARBURST, M_AXI_GP0_ARLOCK, M_AXI_GP0_ARSIZE, M_AXI_GP0_AWBURST, M_AXI_GP0_AWLOCK, M_AXI_GP0_AWSIZE, M_AXI_GP0_ARPROT, M_AXI_GP0_AWPROT, M_AXI_GP0_ARADDR, M_AXI_GP0_AWADDR, M_AXI_GP0_WDATA, M_AXI_GP0_ARCACHE, M_AXI_GP0_ARLEN, M_AXI_GP0_ARQOS, M_AXI_GP0_AWCACHE, M_AXI_GP0_AWLEN, M_AXI_GP0_AWQOS, M_AXI_GP0_WSTRB, M_AXI_GP0_ACLK, M_AXI_GP0_ARREADY, M_AXI_GP0_AWREADY, M_AXI_GP0_BVALID, M_AXI_GP0_RLAST, M_AXI_GP0_RVALID, M_AXI_GP0_WREADY, M_AXI_GP0_BID, M_AXI_GP0_RID, M_AXI_GP0_BRESP, M_AXI_GP0_RRESP, M_AXI_GP0_RDATA, FCLK_CLK0, FCLK_RESET0_N, FTMT_F2P_TRIG_0, FTMT_F2P_TRIGACK_0, FTMT_P2F_TRIGACK_0, FTMT_P2F_TRIG_0, MIO, DDR_CAS_n, DDR_CKE, DDR_Clk_n, DDR_Clk, DDR_CS_n, DDR_DRSTB, DDR_ODT, DDR_RAS_n, DDR_WEB, DDR_BankAddr, DDR_Addr, DDR_VRN, DDR_VRP, DDR_DM, DDR_DQ, DDR_DQS_n, DDR_DQS, PS_SRSTB, PS_CLK, PS_PORB) /* synthesis syn_black_box black_box_pad_pin="TTC0_WAVE0_OUT,TTC0_WAVE1_OUT,TTC0_WAVE2_OUT,USB0_PORT_INDCTL[1:0],USB0_VBUS_PWRSELECT,USB0_VBUS_PWRFAULT,M_AXI_GP0_ARVALID,M_AXI_GP0_AWVALID,M_AXI_GP0_BREADY,M_AXI_GP0_RREADY,M_AXI_GP0_WLAST,M_AXI_GP0_WVALID,M_AXI_GP0_ARID[11:0],M_AXI_GP0_AWID[11:0],M_AXI_GP0_WID[11:0],M_AXI_GP0_ARBURST[1:0],M_AXI_GP0_ARLOCK[1:0],M_AXI_GP0_ARSIZE[2:0],M_AXI_GP0_AWBURST[1:0],M_AXI_GP0_AWLOCK[1:0],M_AXI_GP0_AWSIZE[2:0],M_AXI_GP0_ARPROT[2:0],M_AXI_GP0_AWPROT[2:0],M_AXI_GP0_ARADDR[31:0],M_AXI_GP0_AWADDR[31:0],M_AXI_GP0_WDATA[31:0],M_AXI_GP0_ARCACHE[3:0],M_AXI_GP0_ARLEN[3:0],M_AXI_GP0_ARQOS[3:0],M_AXI_GP0_AWCACHE[3:0],M_AXI_GP0_AWLEN[3:0],M_AXI_GP0_AWQOS[3:0],M_AXI_GP0_WSTRB[3:0],M_AXI_GP0_ACLK,M_AXI_GP0_ARREADY,M_AXI_GP0_AWREADY,M_AXI_GP0_BVALID,M_AXI_GP0_RLAST,M_AXI_GP0_RVALID,M_AXI_GP0_WREADY,M_AXI_GP0_BID[11:0],M_AXI_GP0_RID[11:0],M_AXI_GP0_BRESP[1:0],M_AXI_GP0_RRESP[1:0],M_AXI_GP0_RDATA[31:0],FCLK_CLK0,FCLK_RESET0_N,FTMT_F2P_TRIG_0,FTMT_F2P_TRIGACK_0,FTMT_P2F_TRIGACK_0,FTMT_P2F_TRIG_0,MIO[53:0],DDR_CAS_n,DDR_CKE,DDR_Clk_n,DDR_Clk,DDR_CS_n,DDR_DRSTB,DDR_ODT,DDR_RAS_n,DDR_WEB,DDR_BankAddr[2:0],DDR_Addr[14:0],DDR_VRN,DDR_VRP,DDR_DM[3:0],DDR_DQ[31:0],DDR_DQS_n[3:0],DDR_DQS[3:0],PS_SRSTB,PS_CLK,PS_PORB" */; output TTC0_WAVE0_OUT; output TTC0_WAVE1_OUT; output TTC0_WAVE2_OUT; output [1:0]USB0_PORT_INDCTL; output USB0_VBUS_PWRSELECT; input USB0_VBUS_PWRFAULT; output M_AXI_GP0_ARVALID; output M_AXI_GP0_AWVALID; output M_AXI_GP0_BREADY; output M_AXI_GP0_RREADY; output M_AXI_GP0_WLAST; output M_AXI_GP0_WVALID; output [11:0]M_AXI_GP0_ARID; output [11:0]M_AXI_GP0_AWID; output [11:0]M_AXI_GP0_WID; output [1:0]M_AXI_GP0_ARBURST; output [1:0]M_AXI_GP0_ARLOCK; output [2:0]M_AXI_GP0_ARSIZE; output [1:0]M_AXI_GP0_AWBURST; output [1:0]M_AXI_GP0_AWLOCK; output [2:0]M_AXI_GP0_AWSIZE; output [2:0]M_AXI_GP0_ARPROT; output [2:0]M_AXI_GP0_AWPROT; output [31:0]M_AXI_GP0_ARADDR; output [31:0]M_AXI_GP0_AWADDR; output [31:0]M_AXI_GP0_WDATA; output [3:0]M_AXI_GP0_ARCACHE; output [3:0]M_AXI_GP0_ARLEN; output [3:0]M_AXI_GP0_ARQOS; output [3:0]M_AXI_GP0_AWCACHE; output [3:0]M_AXI_GP0_AWLEN; output [3:0]M_AXI_GP0_AWQOS; output [3:0]M_AXI_GP0_WSTRB; input M_AXI_GP0_ACLK; input M_AXI_GP0_ARREADY; input M_AXI_GP0_AWREADY; input M_AXI_GP0_BVALID; input M_AXI_GP0_RLAST; input M_AXI_GP0_RVALID; input M_AXI_GP0_WREADY; input [11:0]M_AXI_GP0_BID; input [11:0]M_AXI_GP0_RID; input [1:0]M_AXI_GP0_BRESP; input [1:0]M_AXI_GP0_RRESP; input [31:0]M_AXI_GP0_RDATA; output FCLK_CLK0; output FCLK_RESET0_N; input FTMT_F2P_TRIG_0; output FTMT_F2P_TRIGACK_0; input FTMT_P2F_TRIGACK_0; output FTMT_P2F_TRIG_0; inout [53:0]MIO; inout DDR_CAS_n; inout DDR_CKE; inout DDR_Clk_n; inout DDR_Clk; inout DDR_CS_n; inout DDR_DRSTB; inout DDR_ODT; inout DDR_RAS_n; inout DDR_WEB; inout [2:0]DDR_BankAddr; inout [14:0]DDR_Addr; inout DDR_VRN; inout DDR_VRP; inout [3:0]DDR_DM; inout [31:0]DDR_DQ; inout [3:0]DDR_DQS_n; inout [3:0]DDR_DQS; inout PS_SRSTB; inout PS_CLK; inout PS_PORB; endmodule

// *************************************************************************** // *************************************************************************** // Copyright 2011(c) Analog Devices, Inc. // // All rights reserved. // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // - Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // - Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in // the documentation and/or other materials provided with the // distribution. // - Neither the name of Analog Devices, Inc. nor the names of its // contributors may be used to endorse or promote products derived // from this software without specific prior written permission. // - The use of this software may or may not infringe the patent rights // of one or more patent holders. This license does not release you // from the requirement that you obtain separate licenses from these // patent holders to use this software. // - Use of the software either in source or binary form, must be run // on or directly connected to an Analog Devices Inc. component. // // THIS SOFTWARE IS PROVIDED BY ANALOG DEVICES "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, // INCLUDING, BUT NOT LIMITED TO, NON-INFRINGEMENT, MERCHANTABILITY AND FITNESS FOR A // PARTICULAR PURPOSE ARE DISCLAIMED. // // IN NO EVENT SHALL ANALOG DEVICES BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, // EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, INTELLECTUAL PROPERTY // RIGHTS, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR // BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, // STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF // THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // *************************************************************************** // *************************************************************************** // *************************************************************************** // *************************************************************************** // both inputs are considered unsigned 16 bits- // ddata is delay matched generic data `timescale 1ps/1ps module ad_mul_u16 ( // data_p = data_a * data_b; clk, data_a, data_b, data_p, // delay interface ddata_in, ddata_out); // delayed data bus width parameter DELAY_DATA_WIDTH = 16; localparam DW = DELAY_DATA_WIDTH - 1; // data_p = data_a * data_b; input clk; input [15:0] data_a; input [15:0] data_b; output [31:0] data_p; // delay interface input [DW:0] ddata_in; output [DW:0] ddata_out; // internal registers reg [DW:0] p1_ddata = 'd0; reg [DW:0] p2_ddata = 'd0; reg [DW:0] ddata_out = 'd0; // internal signals wire [33:0] data_p_s; // a/b reg, m-reg, p-reg delay match always @(posedge clk) begin p1_ddata <= ddata_in; p2_ddata <= p1_ddata; ddata_out <= p2_ddata; end assign data_p = data_p_s[31:0]; MULT_MACRO #( .LATENCY (3), .A_DATA_WIDTH (17), .B_DATA_WIDTH (17)) i_mult_macro ( .CE (1'b1), .RST (1'b0), .CLK (clk), .A ({1'b0, data_a}), .B ({1'b0, data_b}), .P (data_p_s)); endmodule // *************************************************************************** // ***************************************************************************

module ADC_CTRL ( iRST, iCLK, iCLK_n, iGO, oDIN, oCS_n, oSCLK, iDOUT, oADC_12_bit_channel_0, oADC_12_bit_channel_1, oADC_12_bit_channel_2, oADC_12_bit_channel_3, oADC_12_bit_channel_4, oADC_12_bit_channel_5, oADC_12_bit_channel_6, oADC_12_bit_channel_7 ); input iRST; input iCLK; input iCLK_n; input iGO; output oDIN; output oCS_n; output oSCLK; input iDOUT; output reg [11:0] oADC_12_bit_channel_0; output reg [11:0] oADC_12_bit_channel_1; output reg [11:0] oADC_12_bit_channel_2; output reg [11:0] oADC_12_bit_channel_3; output reg [11:0] oADC_12_bit_channel_4; output reg [11:0] oADC_12_bit_channel_5; output reg [11:0] oADC_12_bit_channel_6; output reg [11:0] oADC_12_bit_channel_7; reg [2:0] channel; reg data; reg go_en; reg sclk; reg [3:0] cont; reg [3:0] m_cont; reg [11:0] adc_data; reg [31:0] adc_counter; assign oCS_n = ~go_en; assign oSCLK = (go_en)? iCLK:1; assign oDIN = data; always@( iCLK )//posedge iGO or posedge iRST) begin if(iRST) go_en <= 0; else begin if(iGO) go_en <= 1; end end always@(posedge iCLK or negedge go_en) begin if(!go_en) cont <= 0; else begin if(iCLK) cont <= cont + 1; end end always@(posedge iCLK_n) begin if(iCLK_n) m_cont <= cont; end always@(posedge iCLK_n or negedge go_en) begin if(!go_en) data <= 0; else begin if(iCLK_n) begin if (cont == 2) data <= channel[2]; else if (cont == 3) data <= channel[1]; else if (cont == 4) data <= channel[0]; else data <= 0; end end end always@(posedge iCLK or negedge go_en) begin if(!go_en) begin adc_data <= 0; end else if(iCLK) begin if (m_cont == 4) adc_data[11] <= iDOUT; else if (m_cont == 5) adc_data[10] <= iDOUT; else if (m_cont == 6) adc_data[9] <= iDOUT; else if (m_cont == 7) adc_data[8] <= iDOUT; else if (m_cont == 8) adc_data[7] <= iDOUT; else if (m_cont == 9) adc_data[6] <= iDOUT; else if (m_cont == 10) adc_data[5] <= iDOUT; else if (m_cont == 11) adc_data[4] <= iDOUT; else if (m_cont == 12) adc_data[3] <= iDOUT; else if (m_cont == 13) adc_data[2] <= iDOUT; else if (m_cont == 14) adc_data[1] <= iDOUT; else if (m_cont == 15) adc_data[0] <= iDOUT; else if (m_cont == 1) begin if ( adc_counter < 32'd20 ) begin adc_counter <= adc_counter + 1'b1; end else begin if (channel == 3'd0) oADC_12_bit_channel_0 <= adc_data; else if (channel == 3'd1) oADC_12_bit_channel_1 <= adc_data; else if (channel == 3'd2) oADC_12_bit_channel_2 <= adc_data; else if (channel == 3'd3) oADC_12_bit_channel_3 <= adc_data; else if (channel == 3'd4) oADC_12_bit_channel_4 <= adc_data; else if (channel == 3'd5) oADC_12_bit_channel_5 <= adc_data; else if (channel == 3'd6) oADC_12_bit_channel_6 <= adc_data; else if (channel == 3'd7) oADC_12_bit_channel_7 <= adc_data; adc_counter <= 32'd0; channel <= channel + 1'b1; end end end end endmodule

`timescale 1ns/1ns `define IDLE 2'b00 `define LOAD 2'b01 `define CNTING 2'b10 `define INT 2'b11 `define MODE_0 2'b00 `define MODE_1 2'b01 module coco_timer (clk_i,rst_i,add_i,we_i,dat_i,dat_o,irq); input [3:2] add_i; input clk_i,rst_i,we_i; input [31:0] dat_i; output [31:0] dat_o; output irq; reg [31:0] count; reg [31:0] preset; reg [31:0] ctrl; reg _irq; reg [1:0] curr_state,next_state; assign dat_o=(add_i==2'b00)?ctrl: (add_i==2'b01)?preset: (add_i==2'b10)?count: 32'h12345678; assign irq=_irq; always @(posedge clk_i or posedge rst_i) begin if (rst_i) begin count<=31'h0000_0000; preset<=31'h0000_0000; ctrl<=31'h0000_0000; _irq<=0; curr_state<=`IDLE; end // if(rst) else if (we_i) begin if (add_i==2'b00) begin ctrl<=dat_i; curr_state<=next_state; end // if(dat_i) else if (add_i==2'b01) begin preset<=dat_i; _irq<=0; next_state<=`LOAD; end // if(add_i=2'b01) else if (add_i==2'b10) begin count<=dat_i; curr_state<=next_state; end else begin curr_state<=next_state; end end // if(we) else begin curr_state<=next_state; end end // always @ (posedge clk_i or posedge rst_i) always @(curr_state or ctrl or count) begin next_state=`IDLE; if (!ctrl[0]) begin next_state=`IDLE; end // if(ctrl[0]) else begin case (curr_state) `IDLE: begin if (ctrl[2:1]==`MODE_1) begin next_state=`LOAD; end // if(ctrl[2:1]) //ctrl[2:1]==`MODE_0 else if (ctrl[0] && count>1) begin next_state=`CNTING; end else begin next_state=`IDLE; end end // case: IDLE `LOAD: begin next_state=`CNTING; end `CNTING: begin if (count==1) begin next_state=`INT; end // if(count==1) else begin next_state=`CNTING; end end default: begin next_state=`IDLE; end endcase // case(curr_state) end end // always @ (curr_state) always @(posedge clk_i or posedge rst_i) begin case (next_state) `CNTING: begin count<=count-1; end `INT: begin _irq<=(ctrl[3]&&ctrl[2:1]==`MODE_0); end `LOAD: begin count<=preset; _irq<=0; end default: begin //do nothing end endcase // case(next_state) end endmodule // cp0

`include "hi_read_tx.v" /* pck0 - input main 24Mhz clock (PLL / 4) [7:0] adc_d - input data from A/D converter shallow_modulation - modulation type pwr_lo - output to coil drivers (ssp_clk / 8) adc_clk - output A/D clock signal ssp_frame - output SSS frame indicator (goes high while the 8 bits are shifted) ssp_din - output SSP data to ARM (shifts 8 bit A/D value serially to ARM MSB first) ssp_clk - output SSP clock signal ck_1356meg - input unused ck_1356megb - input unused ssp_dout - input unused cross_hi - input unused cross_lo - input unused pwr_hi - output unused, tied low pwr_oe1 - output unused, undefined pwr_oe2 - output unused, undefined pwr_oe3 - output unused, undefined pwr_oe4 - output unused, undefined dbg - output alias for adc_clk */ module testbed_hi_read_tx; reg pck0; reg [7:0] adc_d; reg shallow_modulation; wire pwr_lo; wire adc_clk; reg ck_1356meg; reg ck_1356megb; wire ssp_frame; wire ssp_din; wire ssp_clk; reg ssp_dout; wire pwr_hi; wire pwr_oe1; wire pwr_oe2; wire pwr_oe3; wire pwr_oe4; wire cross_lo; wire cross_hi; wire dbg; hi_read_tx #(5,200) dut( .pck0(pck0), .ck_1356meg(ck_1356meg), .ck_1356megb(ck_1356megb), .pwr_lo(pwr_lo), .pwr_hi(pwr_hi), .pwr_oe1(pwr_oe1), .pwr_oe2(pwr_oe2), .pwr_oe3(pwr_oe3), .pwr_oe4(pwr_oe4), .adc_d(adc_d), .adc_clk(adc_clk), .ssp_frame(ssp_frame), .ssp_din(ssp_din), .ssp_dout(ssp_dout), .ssp_clk(ssp_clk), .cross_hi(cross_hi), .cross_lo(cross_lo), .dbg(dbg), .shallow_modulation(shallow_modulation) ); integer idx, i; // main clock always #5 begin ck_1356megb = !ck_1356megb; ck_1356meg = ck_1356megb; end //crank DUT task crank_dut; begin @(posedge ssp_clk) ; ssp_dout = $random; end endtask initial begin // init inputs ck_1356megb = 0; adc_d = 0; ssp_dout=0; // shallow modulation off shallow_modulation=0; for (i = 0 ; i < 16 ; i = i + 1) begin crank_dut; end // shallow modulation on shallow_modulation=1; for (i = 0 ; i < 16 ; i = i + 1) begin crank_dut; end $finish; end endmodule // main

// // Copyright (c) 1999 Steven Wilson ([email protected]) // // This source code is free software; you can redistribute it // and/or modify it in source code form under the terms of the GNU // General Public License as published by the Free Software // Foundation; either version 2 of the License, or (at your option) // any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA // // SDW - Validate unary nor ~|(value) // SJW - ~| in behavioral assignment to reg. module main; reg [3:0] vect; reg error; reg result; initial begin error = 0; for(vect=4'b0001;vect<4'b1111;vect = vect + 1) begin result = ~| vect; if(result !== 1'b0) begin $display("FAILED - Unary nor ~|(%b)=%b",vect,result); error = 1'b1; end end #1; vect = 4'b0000; result = ~| vect; if(result !== 1'b1) begin $display("FAILED - Unary nor |~(%b)=%b",vect,result); error = 1'b1; end if(error === 0 ) $display("PASSED"); end endmodule // main

`timescale 1ns / 1ps ////////////////////////////////////////////////////////////////////////////////// // Company: // Engineer: // // Create Date: 22:40:46 12/20/2010 // Design Name: // Module Name: clk_test // Project Name: // Target Devices: // Tool versions: // Description: // // Dependencies: // // Revision: // Revision 0.01 - File Created // Additional Comments: // ////////////////////////////////////////////////////////////////////////////////// module clk_test( input clk, input sysclk, output [31:0] snes_sysclk_freq ); reg [31:0] snes_sysclk_freq_r; assign snes_sysclk_freq = snes_sysclk_freq_r; reg [31:0] sysclk_counter; reg [31:0] sysclk_value; initial snes_sysclk_freq_r = 32'hFFFFFFFF; initial sysclk_counter = 0; initial sysclk_value = 0; reg [1:0] sysclk_sreg; always @(posedge clk) sysclk_sreg <= {sysclk_sreg[0], sysclk}; wire sysclk_rising = (sysclk_sreg == 2'b01); always @(posedge clk) begin if(sysclk_counter < 96000000) begin sysclk_counter <= sysclk_counter + 1; if(sysclk_rising) sysclk_value <= sysclk_value + 1; end else begin snes_sysclk_freq_r <= sysclk_value; sysclk_counter <= 0; sysclk_value <= 0; end end endmodule

// (C) 2001-2016 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. // synthesis translate_off `timescale 1ns / 1ps // synthesis translate_on // turn off superfluous verilog processor warnings // altera message_level Level1 // altera message_off 10034 10035 10036 10037 10230 10240 10030 module efifo_module #( parameter DATA_WIDTH = 16, parameter DEPTH = 2 )( // inputs: clk, rd, rst_n, wr, wr_data, // outputs: almost_empty, almost_full, empty, full, rd_data ) ; output almost_empty; output almost_full; output empty; output full; output [ DATA_WIDTH - 1 : 0 ] rd_data; input clk; input rd; input rst_n; input wr; input [ DATA_WIDTH - 1 : 0 ] wr_data; wire almost_empty; wire almost_full; wire empty; reg [ DEPTH - 1 : 0 ] entries; reg [ DATA_WIDTH - 1 : 0 ] entry_0; reg [ DATA_WIDTH - 1 : 0 ] entry_1; wire full; reg rd_address; reg [ DATA_WIDTH - 1 : 0 ] rd_data; wire [ 1: 0] rdwr; reg wr_address; assign rdwr = {rd, wr}; assign full = entries == DEPTH; assign almost_full = entries >= DEPTH - 1; assign empty = entries == 0; assign almost_empty = entries <= DEPTH - 1; always @(entry_0 or entry_1 or rd_address) begin case (rd_address) // synthesis parallel_case full_case 1'd0: begin rd_data = entry_0; end // 1'd0 1'd1: begin rd_data = entry_1; end // 1'd1 default: begin end // default endcase // rd_address end always @(posedge clk or negedge rst_n) begin if (rst_n == 0) begin wr_address <= 0; rd_address <= 0; entries <= 0; end else case (rdwr) // synthesis parallel_case full_case 2'd1: begin // Write data if (!full) begin entries <= entries + 1; wr_address <= (wr_address == 1) ? 0 : (wr_address + 1); end end // 2'd1 2'd2: begin // Read data if (!empty) begin entries <= entries - 1; rd_address <= (rd_address == 1) ? 0 : (rd_address + 1); end end // 2'd2 2'd3: begin wr_address <= (wr_address == 1) ? 0 : (wr_address + 1); rd_address <= (rd_address == 1) ? 0 : (rd_address + 1); end // 2'd3 default: begin end // default endcase // rdwr end always @(posedge clk) begin //Write data if (wr & !full) case (wr_address) // synthesis parallel_case full_case 1'd0: begin entry_0 <= wr_data; end // 1'd0 1'd1: begin entry_1 <= wr_data; end // 1'd1 default: begin end // default endcase // wr_address end endmodule

/** * This is written by Zhiyang Ong * and Andrew Mattheisen * for EE577b Troy WideWord Processor Project */ // Behavioral model for the 32-bit program counter module program_counter2 (next_pc,rst,clk); // Output signals... // Incremented value of the program counter output [0:31] next_pc; // =============================================================== // Input signals // Clock signal for the program counter input clk; // Reset signal for the program counter input rst; /** * May also include: branch_offset[n:0], is_branch * Size of branch offset is specified in the Instruction Set * Architecture */ // =============================================================== // Declare "wire" signals: //wire FSM_OUTPUT; // =============================================================== // Declare "reg" signals: reg [0:31] next_pc; // Output signals // =============================================================== always @(posedge clk) begin // If the reset signal sis set to HIGH if(rst) begin // Set its value to ZERO next_pc<=32'd0; end else begin next_pc<=next_pc+32'd4; end end endmodule

(** * Poly: Polymorphism and Higher-Order Functions *) (** In this chapter we continue our development of basic concepts of functional programming. The critical new ideas are _polymorphism_ (abstracting functions over the types of the data they manipulate) and _higher-order functions_ (treating functions as data). *) Require Export Lists. (* ###################################################### *) (** * Polymorphism *) (* ###################################################### *) (** ** Polymorphic Lists *) (** For the last couple of chapters, we've been working just with lists of numbers. Obviously, interesting programs also need to be able to manipulate lists with elements from other types -- lists of strings, lists of booleans, lists of lists, etc. We _could_ just define a new inductive datatype for each of these, for example... *) Inductive boollist : Type := | bool_nil : boollist | bool_cons : bool -> boollist -> boollist. (** ... but this would quickly become tedious, partly because we have to make up different constructor names for each datatype, but mostly because we would also need to define new versions of all our list manipulating functions ([length], [rev], etc.) for each new datatype definition. *) (** *** *) (** To avoid all this repetition, Coq supports _polymorphic_ inductive type definitions. For example, here is a _polymorphic list_ datatype. *) Inductive list (X:Type) : Type := | nil : list X | cons : X -> list X -> list X. (** This is exactly like the definition of [natlist] from the previous chapter, except that the [nat] argument to the [cons] constructor has been replaced by an arbitrary type [X], a binding for [X] has been added to the header, and the occurrences of [natlist] in the types of the constructors have been replaced by [list X]. (We can re-use the constructor names [nil] and [cons] because the earlier definition of [natlist] was inside of a [Module] definition that is now out of scope.) *) (** What sort of thing is [list] itself? One good way to think about it is that [list] is a _function_ from [Type]s to [Inductive] definitions; or, to put it another way, [list] is a function from [Type]s to [Type]s. For any particular type [X], the type [list X] is an [Inductive]ly defined set of lists whose elements are things of type [X]. *) (** With this definition, when we use the constructors [nil] and [cons] to build lists, we need to tell Coq the type of the elements in the lists we are building -- that is, [nil] and [cons] are now _polymorphic constructors_. Observe the types of these constructors: *) Check nil. (* ===> nil : forall X : Type, list X *) Check cons. (* ===> cons : forall X : Type, X -> list X -> list X *) (** The "[forall X]" in these types can be read as an additional argument to the constructors that determines the expected types of the arguments that follow. When [nil] and [cons] are used, these arguments are supplied in the same way as the others. For example, the list containing [2] and [1] is written like this: *) Check (cons nat 2 (cons nat 1 (nil nat))). (** (We've gone back to writing [nil] and [cons] explicitly here because we haven't yet defined the [ [] ] and [::] notations for the new version of lists. We'll do that in a bit.) *) (** We can now go back and make polymorphic (or "generic") versions of all the list-processing functions that we wrote before. Here is [length], for example: *) (** *** *) Fixpoint length (X:Type) (l:list X) : nat := match l with | nil => 0 | cons h t => S (length X t) end. (** Note that the uses of [nil] and [cons] in [match] patterns do not require any type annotations: Coq already knows that the list [l] contains elements of type [X], so there's no reason to include [X] in the pattern. (More precisely, the type [X] is a parameter of the whole definition of [list], not of the individual constructors. We'll come back to this point later.) As with [nil] and [cons], we can use [length] by applying it first to a type and then to its list argument: *) Example test_length1 : length nat (cons nat 1 (cons nat 2 (nil nat))) = 2. Proof. reflexivity. Qed. (** To use our length with other kinds of lists, we simply instantiate it with an appropriate type parameter: *) Example test_length2 : length bool (cons bool true (nil bool)) = 1. Proof. reflexivity. Qed. (** *** *) (** Let's close this subsection by re-implementing a few other standard list functions on our new polymorphic lists: *) Fixpoint app (X : Type) (l1 l2 : list X) : (list X) := match l1 with | nil => l2 | cons h t => cons X h (app X t l2) end. Fixpoint snoc (X:Type) (l:list X) (v:X) : (list X) := match l with | nil => cons X v (nil X) | cons h t => cons X h (snoc X t v) end. Fixpoint rev (X:Type) (l:list X) : list X := match l with | nil => nil X | cons h t => snoc X (rev X t) h end. Example test_rev1 : rev nat (cons nat 1 (cons nat 2 (nil nat))) = (cons nat 2 (cons nat 1 (nil nat))). Proof. reflexivity. Qed. Example test_rev2: rev bool (nil bool) = nil bool. Proof. reflexivity. Qed. Module MumbleBaz. (** **** Exercise: 2 stars (mumble_grumble) *) (** Consider the following two inductively defined types. *) Inductive mumble : Type := | a : mumble | b : mumble -> nat -> mumble | c : mumble. Inductive grumble (X:Type) : Type := | d : mumble -> grumble X | e : X -> grumble X. (** Which of the following are well-typed elements of [grumble X] for some type [X]? - [d (b a 5)] : No. - [d mumble (b a 5)] : Yes (grumble mumble). - [d bool (b a 5)] : Yes (grumble bool). - [e bool true] : Yes (grumble bool). - [e mumble (b c 0)] : Yes (grumble mumble). - [e bool (b c 0)] : No. - [c] : No (type mumble). [] *) (** **** Exercise: 2 stars (baz_num_elts) *) (** Consider the following inductive definition: *) Inductive baz : Type := | x : baz -> baz | y : baz -> bool -> baz. (** How _many_ elements does the type [baz] have? Confused by definition of "element" here. x: 0 elements (just the continuation of the data structure) y: 1 element (a bool, and the continuation of baz) [] *) End MumbleBaz. (* ###################################################### *) (** *** Type Annotation Inference *) (** Let's write the definition of [app] again, but this time we won't specify the types of any of the arguments. Will Coq still accept it? *) Fixpoint app' X l1 l2 : list X := match l1 with | nil => l2 | cons h t => cons X h (app' X t l2) end. (** Indeed it will. Let's see what type Coq has assigned to [app']: *) Check app'. (* ===> forall X : Type, list X -> list X -> list X *) Check app. (* ===> forall X : Type, list X -> list X -> list X *) (** It has exactly the same type type as [app]. Coq was able to use a process called _type inference_ to deduce what the types of [X], [l1], and [l2] must be, based on how they are used. For example, since [X] is used as an argument to [cons], it must be a [Type], since [cons] expects a [Type] as its first argument; matching [l1] with [nil] and [cons] means it must be a [list]; and so on. This powerful facility means we don't always have to write explicit type annotations everywhere, although explicit type annotations are still quite useful as documentation and sanity checks. You should try to find a balance in your own code between too many type annotations (so many that they clutter and distract) and too few (which forces readers to perform type inference in their heads in order to understand your code). *) (* ###################################################### *) (** *** Type Argument Synthesis *) (** Whenever we use a polymorphic function, we need to pass it one or more types in addition to its other arguments. For example, the recursive call in the body of the [length] function above must pass along the type [X]. But just like providing explicit type annotations everywhere, this is heavy and verbose. Since the second argument to [length] is a list of [X]s, it seems entirely obvious that the first argument can only be [X] -- why should we have to write it explicitly? Fortunately, Coq permits us to avoid this kind of redundancy. In place of any type argument we can write the "implicit argument" [_], which can be read as "Please figure out for yourself what type belongs here." More precisely, when Coq encounters a [_], it will attempt to _unify_ all locally available information -- the type of the function being applied, the types of the other arguments, and the type expected by the context in which the application appears -- to determine what concrete type should replace the [_]. This may sound similar to type annotation inference -- and, indeed, the two procedures rely on the same underlying mechanisms. Instead of simply omitting the types of some arguments to a function, like app' X l1 l2 : list X := we can also replace the types with [_], like app' (X : _) (l1 l2 : _) : list X := which tells Coq to attempt to infer the missing information, just as with argument synthesis. Using implicit arguments, the [length] function can be written like this: *) Fixpoint length' (X:Type) (l:list X) : nat := match l with | nil => 0 | cons h t => S (length' _ t) end. (** In this instance, we don't save much by writing [_] instead of [X]. But in many cases the difference can be significant. For example, suppose we want to write down a list containing the numbers [1], [2], and [3]. Instead of writing this... *) Definition list123 := cons nat 1 (cons nat 2 (cons nat 3 (nil nat))). (** ...we can use argument synthesis to write this: *) Definition list123' := cons _ 1 (cons _ 2 (cons _ 3 (nil _))). (* ###################################################### *) (** *** Implicit Arguments *) (** If fact, we can go further. To avoid having to sprinkle [_]'s throughout our programs, we can tell Coq _always_ to infer the type argument(s) of a given function. The [Arguments] directive specifies the name of the function or constructor, and then lists its argument names, with curly braces around any arguments to be treated as implicit. *) Arguments nil {X}. Arguments cons {X} _ _. (* use underscore for argument position that has no name *) Arguments length {X} l. Arguments app {X} l1 l2. Arguments rev {X} l. Arguments snoc {X} l v. (* note: no _ arguments required... *) Definition list123'' := cons 1 (cons 2 (cons 3 nil)). Check (length list123''). (** *** *) (** Alternatively, we can declare an argument to be implicit while defining the function itself, by surrounding the argument in curly braces. For example: *) Fixpoint length'' {X:Type} (l:list X) : nat := match l with | nil => 0 | cons h t => S (length'' t) end. (** (Note that we didn't even have to provide a type argument to the recursive call to [length'']; indeed, it is invalid to provide one.) We will use this style whenever possible, although we will continue to use use explicit [Argument] declarations for [Inductive] constructors. *) (** *** *) (** One small problem with declaring arguments [Implicit] is that, occasionally, Coq does not have enough local information to determine a type argument; in such cases, we need to tell Coq that we want to give the argument explicitly this time, even though we've globally declared it to be [Implicit]. For example, suppose we write this: *) (* Definition mynil := nil. *) (** If we uncomment this definition, Coq will give us an error, because it doesn't know what type argument to supply to [nil]. We can help it by providing an explicit type declaration (so that Coq has more information available when it gets to the "application" of [nil]): *) Definition mynil : list nat := nil. (** Alternatively, we can force the implicit arguments to be explicit by prefixing the function name with [@]. *) Check @nil. Definition mynil' := @nil nat. (** *** *) (** Using argument synthesis and implicit arguments, we can define convenient notation for lists, as before. Since we have made the constructor type arguments implicit, Coq will know to automatically infer these when we use the notations. *) Notation "x :: y" := (cons x y) (at level 60, right associativity). Notation "[ ]" := nil. Notation "[ x ; .. ; y ]" := (cons x .. (cons y []) ..). Notation "x ++ y" := (app x y) (at level 60, right associativity). (** Now lists can be written just the way we'd hope: *) Definition list123''' := [1; 2; 3]. Check ([3 + 4] ++ nil). (* ###################################################### *) (** *** Exercises: Polymorphic Lists *) (** **** Exercise: 2 stars, optional (poly_exercises) *) (** Here are a few simple exercises, just like ones in the [Lists] chapter, for practice with polymorphism. Fill in the definitions and complete the proofs below. *) Fixpoint repeat {X : Type} (n : X) (count : nat) : list X := match count with | 0 => nil | S count' => n :: repeat n count' end. Example test_repeat1: repeat true 2 = cons true (cons true nil). reflexivity. Qed. Theorem nil_app : forall X:Type, forall l:list X, app [] l = l. Proof. reflexivity. Qed. Theorem rev_snoc : forall X : Type, forall v : X, forall s : list X, rev (snoc s v) = v :: (rev s). Proof. intros X v s. induction s as [|h t]. Case "s = []". simpl. reflexivity. Case "s = h::t". simpl. rewrite IHt. simpl. reflexivity. Qed. Theorem rev_involutive : forall X : Type, forall l : list X, rev (rev l) = l. Proof. intros X l. induction l as [|v l']. Case "l = []". simpl. reflexivity. Case "l = v::l'". simpl. rewrite rev_snoc. rewrite IHl'. reflexivity. Qed. Theorem snoc_append : forall X (l:list X) x, snoc l x = l ++ [x]. Proof. intros X l x. induction l as [|y l']. Case "l=[]". reflexivity. Case "l=y::l'". simpl. rewrite IHl'. reflexivity. Qed. Theorem snoc_with_append : forall X : Type, forall l1 l2 : list X, forall v : X, snoc (l1 ++ l2) v = l1 ++ (snoc l2 v). Proof. intros X l1 l2 v. induction l1 as [|x l']. Case "l1 = []". simpl. reflexivity. Case "l1=x::l'". simpl. rewrite IHl'. reflexivity. Qed. Theorem rev_app : forall X (l:list X) x, x :: rev l = rev (l ++ [x]). Proof. intros X l. induction l as [|y l']. Case "l=[]". simpl. reflexivity. Case "l=y::l'". intros. simpl. rewrite snoc_append. rewrite <- IHl'. simpl. rewrite snoc_append. reflexivity. Qed. (** [] *) Theorem cons_app_assoc : forall X (l1 l2:list X) x, (x :: l1) ++ l2 = x :: (l1 ++ l2). Proof. intros. reflexivity. Qed. (* ###################################################### *) (** ** Polymorphic Pairs *) (** Following the same pattern, the type definition we gave in the last chapter for pairs of numbers can be generalized to _polymorphic pairs_ (or _products_): *) Inductive prod (X Y : Type) : Type := pair : X -> Y -> prod X Y. Arguments pair {X} {Y} _ _. (** As with lists, we make the type arguments implicit and define the familiar concrete notation. *) Notation "( x , y )" := (pair x y). (** We can also use the [Notation] mechanism to define the standard notation for pair _types_: *) Notation "X * Y" := (prod X Y) : type_scope. (** (The annotation [: type_scope] tells Coq that this abbreviation should be used when parsing types. This avoids a clash with the multiplication symbol.) *) (** *** *) (** A note of caution: it is easy at first to get [(x,y)] and [X*Y] confused. Remember that [(x,y)] is a _value_ built from two other values; [X*Y] is a _type_ built from two other types. If [x] has type [X] and [y] has type [Y], then [(x,y)] has type [X*Y]. *) (** The first and second projection functions now look pretty much as they would in any functional programming language. *) Definition fst {X Y : Type} (p : X * Y) : X := match p with (x,y) => x end. Definition snd {X Y : Type} (p : X * Y) : Y := match p with (x,y) => y end. (** The following function takes two lists and combines them into a list of pairs. In many functional programming languages, it is called [zip]. We call it [combine] for consistency with Coq's standard library. *) (** Note that the pair notation can be used both in expressions and in patterns... *) Fixpoint combine {X Y : Type} (lx : list X) (ly : list Y) : list (X*Y) := match (lx,ly) with | ([],_) => [] | (_,[]) => [] | (x::tx, y::ty) => (x,y) :: (combine tx ty) end. (** **** Exercise: 1 star, optional (combine_checks) *) (** Try answering the following questions on paper and checking your answers in coq: - What is the type of [combine] (i.e., what does [Check @combine] print?) forall X Y : Type, list X -> list Y -> list (X*Y) - What does Eval compute in (combine [1;2] [false;false;true;true]). print? [(1,false);(2,false)] : list (nat*bool) *) (** **** Exercise: 2 stars (split) *) (** The function [split] is the right inverse of combine: it takes a list of pairs and returns a pair of lists. In many functional programing languages, this function is called [unzip]. Uncomment the material below and fill in the definition of [split]. Make sure it passes the given unit tests. *) Fixpoint split {X Y : Type} (l : list (X*Y)) : (list X) * (list Y) := match l with | [] => ([],[]) | (x,y) :: ls => (x :: fst (split ls), y :: snd (split ls)) end. Example test_split: split [(1,false);(2,false)] = ([1;2],[false;false]). Proof. reflexivity. Qed. (** [] *) (* ###################################################### *) (** ** Polymorphic Options *) (** One last polymorphic type for now: _polymorphic options_. The type declaration generalizes the one for [natoption] in the previous chapter: *) Inductive option (X:Type) : Type := | Some : X -> option X | None : option X. Arguments Some {X} _. Arguments None {X}. (** *** *) (** We can now rewrite the [index] function so that it works with any type of lists. *) Fixpoint index {X : Type} (n : nat) (l : list X) : option X := match l with | [] => None | a :: l' => if beq_nat n O then Some a else index (pred n) l' end. Example test_index1 : index 0 [4;5;6;7] = Some 4. Proof. reflexivity. Qed. Example test_index2 : index 1 [[1];[2]] = Some [2]. Proof. reflexivity. Qed. Example test_index3 : index 2 [true] = None. Proof. reflexivity. Qed. (** **** Exercise: 1 star, optional (hd_opt_poly) *) (** Complete the definition of a polymorphic version of the [hd_opt] function from the last chapter. Be sure that it passes the unit tests below. *) Definition hd_opt {X : Type} (l : list X) : option X := match l with | [] => None | x :: _ => Some x end. (** Once again, to force the implicit arguments to be explicit, we can use [@] before the name of the function. *) Check @hd_opt. Example test_hd_opt1 : hd_opt [1;2] = Some 1. reflexivity. Qed. Example test_hd_opt2 : hd_opt [[1];[2]] = Some [1]. reflexivity. Qed. (** [] *) (* ###################################################### *) (** * Functions as Data *) (* ###################################################### *) (** ** Higher-Order Functions *) (** Like many other modern programming languages -- including all _functional languages_ (ML, Haskell, Scheme, etc.) -- Coq treats functions as first-class citizens, allowing functions to be passed as arguments to other functions, returned as results, stored in data structures, etc. Functions that manipulate other functions are often called _higher-order_ functions. Here's a simple one: *) Definition doit3times {X:Type} (f:X->X) (n:X) : X := f (f (f n)). (** The argument [f] here is itself a function (from [X] to [X]); the body of [doit3times] applies [f] three times to some value [n]. *) Check @doit3times. (* ===> doit3times : forall X : Type, (X -> X) -> X -> X *) Example test_doit3times: doit3times minustwo 9 = 3. Proof. reflexivity. Qed. Example test_doit3times': doit3times negb true = false. Proof. reflexivity. Qed. (* ###################################################### *) (** ** Partial Application *) (** In fact, the multiple-argument functions we have already seen are also examples of passing functions as data. To see why, recall the type of [plus]. *) Check plus. (* ==> nat -> nat -> nat *) (** Each [->] in this expression is actually a _binary_ operator on types. (This is the same as saying that Coq primitively supports only one-argument functions -- do you see why?) This operator is _right-associative_, so the type of [plus] is really a shorthand for [nat -> (nat -> nat)] -- i.e., it can be read as saying that "[plus] is a one-argument function that takes a [nat] and returns a one-argument function that takes another [nat] and returns a [nat]." In the examples above, we have always applied [plus] to both of its arguments at once, but if we like we can supply just the first. This is called _partial application_. *) Definition plus3 := plus 3. Check plus3. Example test_plus3 : plus3 4 = 7. Proof. reflexivity. Qed. Example test_plus3' : doit3times plus3 0 = 9. Proof. reflexivity. Qed. Example test_plus3'' : doit3times (plus 3) 0 = 9. Proof. reflexivity. Qed. (* ###################################################### *) (** ** Digression: Currying *) (** **** Exercise: 2 stars, advanced (currying) *) (** In Coq, a function [f : A -> B -> C] really has the type [A -> (B -> C)]. That is, if you give [f] a value of type [A], it will give you function [f' : B -> C]. If you then give [f'] a value of type [B], it will return a value of type [C]. This allows for partial application, as in [plus3]. Processing a list of arguments with functions that return functions is called _currying_, in honor of the logician Haskell Curry. Conversely, we can reinterpret the type [A -> B -> C] as [(A * B) -> C]. This is called _uncurrying_. With an uncurried binary function, both arguments must be given at once as a pair; there is no partial application. *) (** We can define currying as follows: *) Definition prod_curry {X Y Z : Type} (f : X * Y -> Z) (x : X) (y : Y) : Z := f (x, y). (** As an exercise, define its inverse, [prod_uncurry]. Then prove the theorems below to show that the two are inverses. *) Definition prod_uncurry {X Y Z : Type} (f : X -> Y -> Z) (p : X * Y) : Z := f (fst p) (snd p). (** (Thought exercise: before running these commands, can you calculate the types of [prod_curry] and [prod_uncurry]?) *) Check @prod_curry. Check @prod_uncurry. Theorem uncurry_curry : forall (X Y Z : Type) (f : X -> Y -> Z) x y, prod_curry (prod_uncurry f) x y = f x y. Proof. reflexivity. Qed. Theorem curry_uncurry : forall (X Y Z : Type) (f : (X * Y) -> Z) (p : X * Y), prod_uncurry (prod_curry f) p = f p. Proof. intros X Y Z f p. destruct p. reflexivity. Qed. (** [] *) (* ###################################################### *) (** ** Filter *) (** Here is a useful higher-order function, which takes a list of [X]s and a _predicate_ on [X] (a function from [X] to [bool]) and "filters" the list, returning a new list containing just those elements for which the predicate returns [true]. *) Fixpoint filter {X:Type} (test: X->bool) (l:list X) : (list X) := match l with | [] => [] | h :: t => if test h then h :: (filter test t) else filter test t end. (** For example, if we apply [filter] to the predicate [evenb] and a list of numbers [l], it returns a list containing just the even members of [l]. *) Example test_filter1: filter evenb [1;2;3;4] = [2;4]. Proof. reflexivity. Qed. (** *** *) Definition length_is_1 {X : Type} (l : list X) : bool := beq_nat (length l) 1. Example test_filter2: filter length_is_1 [ [1; 2]; [3]; [4]; [5;6;7]; []; [8] ] = [ [3]; [4]; [8] ]. Proof. reflexivity. Qed. (** *** *) (** We can use [filter] to give a concise version of the [countoddmembers] function from the [Lists] chapter. *) Definition countoddmembers' (l:list nat) : nat := length (filter oddb l). Example test_countoddmembers'1: countoddmembers' [1;0;3;1;4;5] = 4. Proof. reflexivity. Qed. Example test_countoddmembers'2: countoddmembers' [0;2;4] = 0. Proof. reflexivity. Qed. Example test_countoddmembers'3: countoddmembers' nil = 0. Proof. reflexivity. Qed. (* ###################################################### *) (** ** Anonymous Functions *) (** It is a little annoying to be forced to define the function [length_is_1] and give it a name just to be able to pass it as an argument to [filter], since we will probably never use it again. Moreover, this is not an isolated example. When using higher-order functions, we often want to pass as arguments "one-off" functions that we will never use again; having to give each of these functions a name would be tedious. Fortunately, there is a better way. It is also possible to construct a function "on the fly" without declaring it at the top level or giving it a name; this is analogous to the notation we've been using for writing down constant lists, natural numbers, and so on. *) Example test_anon_fun': doit3times (fun n => n * n) 2 = 256. Proof. reflexivity. Qed. (** Here is the motivating example from before, rewritten to use an anonymous function. *) Example test_filter2': filter (fun l => beq_nat (length l) 1) [ [1; 2]; [3]; [4]; [5;6;7]; []; [8] ] = [ [3]; [4]; [8] ]. Proof. reflexivity. Qed. (** **** Exercise: 2 stars (filter_even_gt7) *) (** Use [filter] (instead of [Fixpoint]) to write a Coq function [filter_even_gt7] that takes a list of natural numbers as input and returns a list of just those that are even and greater than 7. *) Definition filter_even_gt7 (l : list nat) : list nat := filter (fun n => andb (negb (ble_nat n 7)) (evenb n)) l. Example test_filter_even_gt7_1 : filter_even_gt7 [1;2;6;9;10;3;12;8] = [10;12;8]. reflexivity. Qed. Example test_filter_even_gt7_2 : filter_even_gt7 [5;2;6;19;129] = []. reflexivity. Qed. (** [] *) (** **** Exercise: 3 stars (partition) *) (** Use [filter] to write a Coq function [partition]: partition : forall X : Type, (X -> bool) -> list X -> list X * list X Given a set [X], a test function of type [X -> bool] and a [list X], [partition] should return a pair of lists. The first member of the pair is the sublist of the original list containing the elements that satisfy the test, and the second is the sublist containing those that fail the test. The order of elements in the two sublists should be the same as their order in the original list. *) Definition partition {X : Type} (test : X -> bool) (l : list X) : list X * list X := (filter test l, filter (fun n => negb (test n)) l). Example test_partition1: partition oddb [1;2;3;4;5] = ([1;3;5], [2;4]). reflexivity. Qed. Example test_partition2: partition (fun x => false) [5;9;0] = ([], [5;9;0]). reflexivity. Qed. (** [] *) (* ###################################################### *) (** ** Map *) (** Another handy higher-order function is called [map]. *) Fixpoint map {X Y:Type} (f:X->Y) (l:list X) : (list Y) := match l with | [] => [] | h :: t => (f h) :: (map f t) end. (** *** *) (** It takes a function [f] and a list [ l = [n1, n2, n3, ...] ] and returns the list [ [f n1, f n2, f n3,...] ], where [f] has been applied to each element of [l] in turn. For example: *) Example test_map1: map (plus 3) [2;0;2] = [5;3;5]. Proof. reflexivity. Qed. (** The element types of the input and output lists need not be the same ([map] takes _two_ type arguments, [X] and [Y]). This version of [map] can thus be applied to a list of numbers and a function from numbers to booleans to yield a list of booleans: *) Example test_map2: map oddb [2;1;2;5] = [false;true;false;true]. Proof. reflexivity. Qed. (** It can even be applied to a list of numbers and a function from numbers to _lists_ of booleans to yield a list of lists of booleans: *) Example test_map3: map (fun n => [evenb n;oddb n]) [2;1;2;5] = [[true;false];[false;true];[true;false];[false;true]]. Proof. reflexivity. Qed. (** ** Map for options *) (** **** Exercise: 3 stars (map_rev) *) (** Show that [map] and [rev] commute. You may need to define an auxiliary lemma. *) Theorem map_snoc : forall (X Y : Type) (f : X -> Y) (l : list X) (x : X), map f (snoc l x) = snoc (map f l) (f x). Proof. intros X Y f l x. induction l as [|h l']. Case "l = []". simpl. reflexivity. Case "l=h::l'". simpl. rewrite IHl'. reflexivity. Qed. Theorem map_rev : forall (X Y : Type) (f : X -> Y) (l : list X), map f (rev l) = rev (map f l). Proof. intros X Y f l. induction l as [|x l']. Case "l = []". simpl. reflexivity. Case "l=x::l'". simpl. rewrite map_snoc. rewrite IHl'. reflexivity. Qed. (** [] *) (** **** Exercise: 2 stars (flat_map) *) (** The function [map] maps a [list X] to a [list Y] using a function of type [X -> Y]. We can define a similar function, [flat_map], which maps a [list X] to a [list Y] using a function [f] of type [X -> list Y]. Your definition should work by 'flattening' the results of [f], like so: flat_map (fun n => [n;n+1;n+2]) [1;5;10] = [1; 2; 3; 5; 6; 7; 10; 11; 12]. *) Fixpoint flat_map {X Y:Type} (f:X -> list Y) (l:list X) : (list Y) := match l with | [] => [] | x :: ls => (f x) ++ (flat_map f ls) end. Example test_flat_map1: flat_map (fun n => [n;n;n]) [1;5;4] = [1; 1; 1; 5; 5; 5; 4; 4; 4]. reflexivity. Qed. (** [] *) (** Lists are not the only inductive type that we can write a [map] function for. Here is the definition of [map] for the [option] type: *) Definition option_map {X Y : Type} (f : X -> Y) (xo : option X) : option Y := match xo with | None => None | Some x => Some (f x) end. (** **** Exercise: 2 stars, optional (implicit_args) *) (** The definitions and uses of [filter] and [map] use implicit arguments in many places. Replace the curly braces around the implicit arguments with parentheses, and then fill in explicit type parameters where necessary and use Coq to check that you've done so correctly. (This exercise is not to be turned in; it is probably easiest to do it on a _copy_ of this file that you can throw away afterwards.) [] *) (* ###################################################### *) (** ** Fold *) (** An even more powerful higher-order function is called [fold]. This function is the inspiration for the "[reduce]" operation that lies at the heart of Google's map/reduce distributed programming framework. *) Fixpoint fold {X Y:Type} (f: X->Y->Y) (l:list X) (b:Y) : Y := match l with | nil => b | h :: t => f h (fold f t b) end. (** *** *) (** Intuitively, the behavior of the [fold] operation is to insert a given binary operator [f] between every pair of elements in a given list. For example, [ fold plus [1;2;3;4] ] intuitively means [1+2+3+4]. To make this precise, we also need a "starting element" that serves as the initial second input to [f]. So, for example, fold plus [1;2;3;4] 0 yields 1 + (2 + (3 + (4 + 0))). Here are some more examples: *) Check (fold andb). (* ===> fold andb : list bool -> bool -> bool *) Example fold_example1 : fold mult [1;2;3;4] 1 = 24. Proof. reflexivity. Qed. Example fold_example2 : fold andb [true;true;false;true] true = false. Proof. reflexivity. Qed. Example fold_example3 : fold app [[1];[];[2;3];[4]] [] = [1;2;3;4]. Proof. reflexivity. Qed. (** **** Exercise: 1 star, advanced (fold_types_different) *) (** Observe that the type of [fold] is parameterized by _two_ type variables, [X] and [Y], and the parameter [f] is a binary operator that takes an [X] and a [Y] and returns a [Y]. Can you think of a situation where it would be useful for [X] and [Y] to be different? List flattening *) (* ###################################################### *) (** ** Functions For Constructing Functions *) (** Most of the higher-order functions we have talked about so far take functions as _arguments_. Now let's look at some examples involving _returning_ functions as the results of other functions. To begin, here is a function that takes a value [x] (drawn from some type [X]) and returns a function from [nat] to [X] that yields [x] whenever it is called, ignoring its [nat] argument. *) Definition constfun {X: Type} (x: X) : nat->X := fun (k:nat) => x. Definition ftrue := constfun true. Example constfun_example1 : ftrue 0 = true. Proof. reflexivity. Qed. Example constfun_example2 : (constfun 5) 99 = 5. Proof. reflexivity. Qed. (** *** *) (** Similarly, but a bit more interestingly, here is a function that takes a function [f] from numbers to some type [X], a number [k], and a value [x], and constructs a function that behaves exactly like [f] except that, when called with the argument [k], it returns [x]. *) Definition override {X: Type} (f: nat->X) (k:nat) (x:X) : nat->X:= fun (k':nat) => if beq_nat k k' then x else f k'. (** For example, we can apply [override] twice to obtain a function from numbers to booleans that returns [false] on [1] and [3] and returns [true] on all other arguments. *) Definition fmostlytrue := override (override ftrue 1 false) 3 false. (** *** *) Example override_example1 : fmostlytrue 0 = true. Proof. reflexivity. Qed. Example override_example2 : fmostlytrue 1 = false. Proof. reflexivity. Qed. Example override_example3 : fmostlytrue 2 = true. Proof. reflexivity. Qed. Example override_example4 : fmostlytrue 3 = false. Proof. reflexivity. Qed. (** *** *) (** **** Exercise: 1 star (override_example) *) (** Before starting to work on the following proof, make sure you understand exactly what the theorem is saying and can paraphrase it in your own words. The proof itself is straightforward. *) Theorem override_example : forall (b:bool), (override (constfun b) 3 true) 2 = b. Proof. reflexivity. Qed. (** [] *) (** We'll use function overriding heavily in parts of the rest of the course, and we will end up needing to know quite a bit about its properties. To prove these properties, though, we need to know about a few more of Coq's tactics; developing these is the main topic of the next chapter. For now, though, let's introduce just one very useful tactic that will also help us with proving properties of some of the other functions we have introduced in this chapter. *) (* ###################################################### *) (* ###################################################### *) (** * The [unfold] Tactic *) (** Sometimes, a proof will get stuck because Coq doesn't automatically expand a function call into its definition. (This is a feature, not a bug: if Coq automatically expanded everything possible, our proof goals would quickly become enormous -- hard to read and slow for Coq to manipulate!) *) Theorem unfold_example_bad : forall m n, 3 + n = m -> plus3 n + 1 = m + 1. Proof. intros m n H. (* At this point, we'd like to do [rewrite -> H], since [plus3 n] is definitionally equal to [3 + n]. However, Coq doesn't automatically expand [plus3 n] to its definition. *) Abort. (** The [unfold] tactic can be used to explicitly replace a defined name by the right-hand side of its definition. *) Theorem unfold_example : forall m n, 3 + n = m -> plus3 n + 1 = m + 1. Proof. intros m n H. unfold plus3. rewrite -> H. reflexivity. Qed. (** Now we can prove a first property of [override]: If we override a function at some argument [k] and then look up [k], we get back the overridden value. *) Theorem override_eq : forall {X:Type} x k (f:nat->X), (override f k x) k = x. Proof. intros X x k f. unfold override. rewrite <- beq_nat_refl. reflexivity. Qed. (** This proof was straightforward, but note that it requires [unfold] to expand the definition of [override]. *) (** **** Exercise: 2 stars (override_neq) *) Theorem override_neq : forall (X:Type) x1 x2 k1 k2 (f : nat->X), f k1 = x1 -> beq_nat k2 k1 = false -> (override f k2 x2) k1 = x1. Proof. intros X x1 x2 k1 k2 f H H0. unfold override. rewrite H0. rewrite H. reflexivity. Qed. (** [] *) (** As the inverse of [unfold], Coq also provides a tactic [fold], which can be used to "unexpand" a definition. It is used much less often. *) (* ##################################################### *) (** * Additional Exercises *) (** **** Exercise: 2 stars (fold_length) *) (** Many common functions on lists can be implemented in terms of [fold]. For example, here is an alternative definition of [length]: *) Definition fold_length {X : Type} (l : list X) : nat := fold (fun _ n => S n) l 0. Example test_fold_length1 : fold_length [4;7;0] = 3. Proof. reflexivity. Qed. (** Prove the correctness of [fold_length]. *) Theorem fold_length_correct : forall X (l : list X), fold_length l = length l. Proof. intros X l. induction l as [|x l']. Case "l = []". reflexivity. Case "l=x::l'". simpl. unfold fold_length. simpl. rewrite <- IHl'. reflexivity. Qed. (** [] *) (** **** Exercise: 3 stars (fold_map) *) (** We can also define [map] in terms of [fold]. Finish [fold_map] below. *) Definition fold_map {X Y:Type} (f : X -> Y) (l : list X) : list Y := fold (fun x ly => (f x) :: ly) l []. (** Write down a theorem in Coq stating that [fold_map] is correct, and prove it. *) Theorem fold_map_correct : forall X Y (f : X -> Y) (l : list X), map f l = fold_map f l. Proof. intros X Y f l. induction l as [|x l']. Case "l = []". reflexivity. Case "l = x::l'". simpl. rewrite IHl'. unfold fold_map. simpl. reflexivity. Qed. (** [] *) (* $Date: 2013-09-26 14:40:26 -0400 (Thu, 26 Sep 2013) $ *)

extern "C" int checkWgAvailable(); extern "C" void prepareNextWg(); extern "C" int hardDisGetWgId(); extern "C" int hardDisGetWfCnt(); extern "C" int hardDisGetWfNumThrds(); extern "C" int hardDisGetVregSize(); extern "C" int hardDisGetVregSizePerWf(); extern "C" int hardDisGetSregSize() ; extern "C" int hardDisGetSregSizePerWf(); extern "C" int hardDisGetLdsSize(); extern "C" int hardDisGetGdsSize(); extern "C" int hardDisGetPc(); module dispatcher_hard_host (/*AUTOARG*/ // Outputs host_wg_valid, host_wg_id, host_num_wf, host_wf_size, host_vgpr_size_total, host_sgpr_size_total, host_lds_size_total, host_gds_size_total, host_vgpr_size_per_wf, host_sgpr_size_per_wf, host_start_pc, // Inputs inflight_wg_buffer_host_rcvd_ack, inflight_wg_buffer_host_wf_done, inflight_wg_buffer_host_wf_done_wg_id, clk, rst ) ; // Resource accounting parameters parameter WG_ID_WIDTH = 6; parameter WG_SLOT_ID_WIDTH = 6; parameter WF_COUNT_WIDTH = 4; parameter WAVE_ITEM_WIDTH = 6; parameter VGPR_ID_WIDTH = 8; parameter SGPR_ID_WIDTH = 4; parameter LDS_ID_WIDTH = 8; parameter GDS_ID_WIDTH = 14; parameter MEM_ADDR_WIDTH = 32; // Output from cu output host_wg_valid; output [WG_ID_WIDTH-1:0] host_wg_id; output [WF_COUNT_WIDTH-1:0] host_num_wf; output [WAVE_ITEM_WIDTH-1:0] host_wf_size; // number of work itens in the last wf output [VGPR_ID_WIDTH :0] host_vgpr_size_total; output [SGPR_ID_WIDTH :0] host_sgpr_size_total; output [LDS_ID_WIDTH :0] host_lds_size_total; output [GDS_ID_WIDTH :0] host_gds_size_total; output [VGPR_ID_WIDTH :0] host_vgpr_size_per_wf; output [SGPR_ID_WIDTH :0] host_sgpr_size_per_wf; output [MEM_ADDR_WIDTH-1:0] host_start_pc; // Input from CU input inflight_wg_buffer_host_rcvd_ack; input inflight_wg_buffer_host_wf_done; input [WG_ID_WIDTH-1:0] inflight_wg_buffer_host_wf_done_wg_id; input clk,rst; reg host_wg_valid_i; reg [WG_ID_WIDTH-1:0] host_wg_id_i; reg [WF_COUNT_WIDTH-1:0] host_num_wf_i; reg [WAVE_ITEM_WIDTH-1:0] host_wf_size_i; // number of work itens in the last wf reg [VGPR_ID_WIDTH :0] host_vgpr_size_total_i; reg [SGPR_ID_WIDTH :0] host_sgpr_size_total_i; reg [LDS_ID_WIDTH :0] host_lds_size_total_i; reg [GDS_ID_WIDTH :0] host_gds_size_total_i; reg [VGPR_ID_WIDTH :0] host_vgpr_size_per_wf_i; reg [SGPR_ID_WIDTH :0] host_sgpr_size_per_wf_i; reg [MEM_ADDR_WIDTH-1:0] host_start_pc_i; reg initialized; always @ ( posedge clk or posedge rst ) begin if(rst) begin host_wg_valid_i = 0; host_wg_id_i = 0; host_num_wf_i = 0; host_wf_size_i = 0; host_vgpr_size_total_i = 0; host_sgpr_size_total_i = 0; host_lds_size_total_i = 0; host_gds_size_total_i = 0; host_vgpr_size_per_wf_i = 0; host_sgpr_size_per_wf_i = 0; host_start_pc_i = 0; initialized = 0; end else begin if(inflight_wg_buffer_host_rcvd_ack || !initialized) begin if(checkWgAvailable()) begin host_wg_valid_i = 1'b1; host_wg_id_i = hardDisGetWgId(); host_num_wf_i = hardDisGetWfCnt(); host_wf_size_i = hardDisGetWfNumThrds(); host_vgpr_size_total_i = hardDisGetVregSize(); host_sgpr_size_total_i = hardDisGetSregSize(); host_lds_size_total_i = hardDisGetLdsSize(); host_gds_size_total_i = hardDisGetGdsSize(); host_vgpr_size_per_wf_i = hardDisGetVregSizePerWf(); host_sgpr_size_per_wf_i = hardDisGetSregSizePerWf(); host_start_pc_i = hardDisGetPc(); prepareNextWg(); initialized = 1'b1; end else begin host_wg_valid_i = 1'b0; end // else: !if(checkWgAvailable()) end // if (inflight_wg_buffer_host_rcvd_ack ||... end // else: !if(rst) end // always @ ( posedge clk or posedge rst ) assign host_wg_valid = host_wg_valid_i; assign host_wg_id = host_wg_id_i; assign host_num_wf = host_num_wf_i; assign host_wf_size = host_wf_size_i; assign host_vgpr_size_total = host_vgpr_size_total_i; assign host_sgpr_size_total = host_sgpr_size_total_i; assign host_lds_size_total = host_lds_size_total_i; assign host_gds_size_total = host_gds_size_total_i; assign host_vgpr_size_per_wf = host_vgpr_size_per_wf_i; assign host_sgpr_size_per_wf = host_sgpr_size_per_wf_i; assign host_start_pc = host_start_pc_i; endmodule // dispatcher_hard_host

// ============================================================== // File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC // Version: 2014.4 // Copyright (C) 2014 Xilinx Inc. All rights reserved. // // ============================================================== `timescale 1ns/1ps `define AUTOTB_DUT adder `define AUTOTB_DUT_INST AESL_inst_adder `define AUTOTB_TOP apatb_adder_top `define AUTOTB_LAT_RESULT_FILE "adder.result.lat.rb" `define AUTOTB_PER_RESULT_TRANS_FILE "adder.performance.result.transaction.xml" `define AUTOTB_TOP_INST AESL_inst_apatb_adder_top `define AUTOTB_MAX_ALLOW_LATENCY 15000000 `define AUTOTB_TRANSACTION_NUM 1 `define AUTOTB_CLOCK_PERIOD 10.000000 `define LENGTH_a 1 `define LENGTH_b 1 `define LENGTH_c 1 `define AESL_DEPTH_a 1 `define AESL_DEPTH_b 1 `define AESL_DEPTH_c 1 `define AUTOTB_TVIN_a "../tv/cdatafile/c.adder.autotvin_a.dat" `define AUTOTB_TVIN_b "../tv/cdatafile/c.adder.autotvin_b.dat" `define AUTOTB_TVIN_a_out_wrapc "../tv/rtldatafile/rtl.adder.autotvin_a.dat" `define AUTOTB_TVIN_b_out_wrapc "../tv/rtldatafile/rtl.adder.autotvin_b.dat" `define AUTOTB_TVOUT_c "../tv/cdatafile/c.adder.autotvout_c.dat" `define AUTOTB_TVOUT_c_out_wrapc "../tv/rtldatafile/rtl.adder.autotvout_c.dat" module `AUTOTB_TOP; task read_token; input integer fp; output reg [199 : 0] token; reg [7:0] c; reg intoken; reg done; begin token = ""; intoken = 0; done = 0; while (!done) begin c = $fgetc(fp); if (c == 8'hff) begin // EOF done = 1; end else if (c == " " || c == "\011" || c == "\012" || c == "\015") begin // blank if (intoken) begin done = 1; end end else begin // valid character intoken = 1; token = (token << 8) | c; end end end endtask reg AESL_clock; reg rst; reg start; reg ce; reg continue; wire AESL_start; wire AESL_reset; wire AESL_ce; wire AESL_ready; wire AESL_idle; wire AESL_continue; wire AESL_done; reg AESL_done_delay = 0; reg AESL_done_delay2 = 0; reg AESL_ready_delay = 0; wire ready; wire ready_wire; reg [31 : 0] AESL_mLatCnterIn [0 : `AUTOTB_TRANSACTION_NUM + 1]; reg [31 : 0] AESL_mLatCnterIn_addr; reg [31 : 0] AESL_mLatCnterOut [0 : `AUTOTB_TRANSACTION_NUM + 1]; reg [31 : 0] AESL_mLatCnterOut_addr ; reg [31 : 0] AESL_clk_counter ; wire s_axi_AXI_CTRL_AWVALID; wire s_axi_AXI_CTRL_AWREADY; wire [5 : 0] s_axi_AXI_CTRL_AWADDR; wire s_axi_AXI_CTRL_WVALID; wire s_axi_AXI_CTRL_WREADY; wire [31 : 0] s_axi_AXI_CTRL_WDATA; wire [3 : 0] s_axi_AXI_CTRL_WSTRB; wire s_axi_AXI_CTRL_ARVALID; wire s_axi_AXI_CTRL_ARREADY; wire [5 : 0] s_axi_AXI_CTRL_ARADDR; wire s_axi_AXI_CTRL_RVALID; wire s_axi_AXI_CTRL_RREADY; wire [31 : 0] s_axi_AXI_CTRL_RDATA; wire [1 : 0] s_axi_AXI_CTRL_RRESP; wire s_axi_AXI_CTRL_BVALID; wire s_axi_AXI_CTRL_BREADY; wire [1 : 0] s_axi_AXI_CTRL_BRESP; wire ap_clk; wire ap_rst_n; wire interrupt; integer done_cnt = 0; integer AESL_ready_cnt = 0; integer ready_cnt = 0; reg ready_initial; reg ready_initial_n; reg ready_last_n; reg ready_delay_last_n; reg done_delay_last_n; reg interface_done = 0; wire AXI_CTRL_read_data_finish; wire AXI_CTRL_write_data_finish; wire AESL_slave_start; wire AESL_slave_write_start_in; wire AESL_slave_write_start_finish; reg AESL_slave_ready; wire AESL_slave_output_done; reg ready_rise = 0; reg start_rise = 0; reg slave_start_status = 0; reg slave_done_status = 0; `AUTOTB_DUT `AUTOTB_DUT_INST( .s_axi_AXI_CTRL_AWVALID(s_axi_AXI_CTRL_AWVALID), .s_axi_AXI_CTRL_AWREADY(s_axi_AXI_CTRL_AWREADY), .s_axi_AXI_CTRL_AWADDR(s_axi_AXI_CTRL_AWADDR), .s_axi_AXI_CTRL_WVALID(s_axi_AXI_CTRL_WVALID), .s_axi_AXI_CTRL_WREADY(s_axi_AXI_CTRL_WREADY), .s_axi_AXI_CTRL_WDATA(s_axi_AXI_CTRL_WDATA), .s_axi_AXI_CTRL_WSTRB(s_axi_AXI_CTRL_WSTRB), .s_axi_AXI_CTRL_ARVALID(s_axi_AXI_CTRL_ARVALID), .s_axi_AXI_CTRL_ARREADY(s_axi_AXI_CTRL_ARREADY), .s_axi_AXI_CTRL_ARADDR(s_axi_AXI_CTRL_ARADDR), .s_axi_AXI_CTRL_RVALID(s_axi_AXI_CTRL_RVALID), .s_axi_AXI_CTRL_RREADY(s_axi_AXI_CTRL_RREADY), .s_axi_AXI_CTRL_RDATA(s_axi_AXI_CTRL_RDATA), .s_axi_AXI_CTRL_RRESP(s_axi_AXI_CTRL_RRESP), .s_axi_AXI_CTRL_BVALID(s_axi_AXI_CTRL_BVALID), .s_axi_AXI_CTRL_BREADY(s_axi_AXI_CTRL_BREADY), .s_axi_AXI_CTRL_BRESP(s_axi_AXI_CTRL_BRESP), .ap_clk(ap_clk), .ap_rst_n(ap_rst_n), .interrupt(interrupt) ); // Assignment for control signal assign ap_clk = AESL_clock; assign ap_rst_n = AESL_reset; assign ap_rst_n_n = ~AESL_reset; assign AESL_reset = rst; assign AESL_start = start; assign AESL_ce = ce; assign AESL_continue = continue; assign AESL_slave_write_start_in = slave_start_status & AXI_CTRL_write_data_finish; assign AESL_slave_start = AESL_slave_write_start_finish; assign AESL_done = slave_done_status & AXI_CTRL_read_data_finish; always @(posedge AESL_clock) begin if(AESL_reset === 0) begin slave_start_status <= 1; end else begin if (AESL_start == 1 ) begin start_rise = 1; end if (start_rise == 1 && AESL_done == 1 ) begin slave_start_status <= 1; end if (AESL_slave_write_start_in == 1) begin slave_start_status <= 0; start_rise = 0; end end end always @(posedge AESL_clock) begin if(AESL_reset === 0) begin AESL_slave_ready <= 0; ready_rise = 0; end else begin if (AESL_ready == 1 ) begin ready_rise = 1; end if (ready_rise == 1 && AESL_done_delay == 1 ) begin AESL_slave_ready <= 1; end if (AESL_slave_ready == 1) begin AESL_slave_ready <= 0; ready_rise = 0; end end end always @ (posedge AESL_clock) begin if (AESL_done == 1) begin slave_done_status <= 0; end else if (AESL_slave_output_done == 1 ) begin slave_done_status <= 1; end end AESL_axi_slave_AXI_CTRL AESL_AXI_SLAVE_AXI_CTRL( .clk (AESL_clock), .reset (AESL_reset), .TRAN_s_axi_AXI_CTRL_AWADDR (s_axi_AXI_CTRL_AWADDR), .TRAN_s_axi_AXI_CTRL_AWVALID (s_axi_AXI_CTRL_AWVALID), .TRAN_s_axi_AXI_CTRL_AWREADY (s_axi_AXI_CTRL_AWREADY), .TRAN_s_axi_AXI_CTRL_WVALID (s_axi_AXI_CTRL_WVALID), .TRAN_s_axi_AXI_CTRL_WREADY (s_axi_AXI_CTRL_WREADY), .TRAN_s_axi_AXI_CTRL_WDATA (s_axi_AXI_CTRL_WDATA), .TRAN_s_axi_AXI_CTRL_WSTRB (s_axi_AXI_CTRL_WSTRB), .TRAN_s_axi_AXI_CTRL_ARADDR (s_axi_AXI_CTRL_ARADDR), .TRAN_s_axi_AXI_CTRL_ARVALID (s_axi_AXI_CTRL_ARVALID), .TRAN_s_axi_AXI_CTRL_ARREADY (s_axi_AXI_CTRL_ARREADY), .TRAN_s_axi_AXI_CTRL_RVALID (s_axi_AXI_CTRL_RVALID), .TRAN_s_axi_AXI_CTRL_RREADY (s_axi_AXI_CTRL_RREADY), .TRAN_s_axi_AXI_CTRL_RDATA (s_axi_AXI_CTRL_RDATA), .TRAN_s_axi_AXI_CTRL_RRESP (s_axi_AXI_CTRL_RRESP), .TRAN_s_axi_AXI_CTRL_BVALID (s_axi_AXI_CTRL_BVALID), .TRAN_s_axi_AXI_CTRL_BREADY (s_axi_AXI_CTRL_BREADY), .TRAN_s_axi_AXI_CTRL_BRESP (s_axi_AXI_CTRL_BRESP), .TRAN_AXI_CTRL_read_data_finish(AXI_CTRL_read_data_finish), .TRAN_AXI_CTRL_write_data_finish(AXI_CTRL_write_data_finish), .TRAN_AXI_CTRL_ready_out (AESL_ready), .TRAN_AXI_CTRL_ready_in (AESL_slave_ready), .TRAN_AXI_CTRL_done_out (AESL_slave_output_done), .TRAN_AXI_CTRL_idle_out (AESL_idle), .TRAN_AXI_CTRL_write_start_in (AESL_slave_write_start_in), .TRAN_AXI_CTRL_write_start_finish (AESL_slave_write_start_finish), .TRAN_AXI_CTRL_transaction_done_in (AESL_done_delay), .TRAN_AXI_CTRL_interrupt (interrupt), .TRAN_AXI_CTRL_start_in (AESL_slave_start) ); initial begin : generate_AESL_ready_cnt_proc AESL_ready_cnt = 0; wait(AESL_reset === 1); while(AESL_ready_cnt != `AUTOTB_TRANSACTION_NUM) begin while(AESL_ready !== 1) begin @(posedge AESL_clock); # 0.4; end @(negedge AESL_clock); AESL_ready_cnt = AESL_ready_cnt + 1; @(posedge AESL_clock); # 0.4; end end initial begin : generate_ready_cnt_proc ready_cnt = 0; wait(AESL_reset === 1); while(ready_cnt != `AUTOTB_TRANSACTION_NUM) begin while(ready !== 1) begin @(posedge AESL_clock); # 0.4; end @(negedge AESL_clock); ready_cnt = ready_cnt + 1; @(posedge AESL_clock); # 0.4; end end initial begin : generate_done_cnt_proc done_cnt = 0; wait(AESL_reset === 1); while(done_cnt != `AUTOTB_TRANSACTION_NUM) begin while(AESL_done !== 1) begin @(posedge AESL_clock); # 0.4; end @(negedge AESL_clock); done_cnt = done_cnt + 1; @(posedge AESL_clock); # 0.4; end @(posedge AESL_clock); # 0.4; $finish; end initial fork AESL_clock = 0; forever #(`AUTOTB_CLOCK_PERIOD/2) AESL_clock = ~AESL_clock; join initial begin : initial_process integer rand; rst = 0; # 100; repeat(3) @(posedge AESL_clock); rst = 1; end initial begin : start_process integer rand; start = 0; ce = 1; wait(AESL_reset === 1); @(posedge AESL_clock); start <= 1; while(done_cnt != `AUTOTB_TRANSACTION_NUM) begin @(posedge AESL_clock); end start <= 0; end always @(AESL_done) begin if(done_cnt < `AUTOTB_TRANSACTION_NUM - 1) continue = AESL_done; else continue = 0; end initial begin : ready_initial_process ready_initial = 0; wait (AESL_start === 1); ready_initial = 1; @(posedge AESL_clock); ready_initial = 0; end initial begin : ready_last_n_process ready_last_n = 1; wait(ready_cnt == `AUTOTB_TRANSACTION_NUM) @(posedge AESL_clock); ready_last_n <= 0; end assign ready = (ready_initial | AESL_done_delay); always @(posedge AESL_clock) begin if(AESL_reset === 0) ready_delay_last_n = 0; else ready_delay_last_n <= ready_last_n; end assign ready_wire = (ready_initial | AESL_done_delay); initial begin : done_delay_last_n_process done_delay_last_n = 1; while(done_cnt != `AUTOTB_TRANSACTION_NUM) @(posedge AESL_clock); # 0.1; done_delay_last_n = 0; end always @(posedge AESL_clock) begin if(AESL_reset === 0) begin AESL_done_delay <= 0; AESL_done_delay2 <= 0; end else begin AESL_done_delay <= AESL_done & done_delay_last_n; AESL_done_delay2 <= AESL_done_delay; end end always @(posedge AESL_clock) begin if(AESL_reset === 0) interface_done = 0; else begin # 0.01; if(ready === 1 && ready_cnt > 0 && ready_cnt < `AUTOTB_TRANSACTION_NUM) interface_done = 1; else if(AESL_done_delay === 1 && done_cnt == `AUTOTB_TRANSACTION_NUM) interface_done = 1; else interface_done = 0; end end // Write "[[[runtime]]]" and "[[[/runtime]]]" for output-only transactor initial begin : write_output_transactor_c_runtime_process integer fp; fp = $fopen(`AUTOTB_TVOUT_c_out_wrapc, "w"); if(fp == 0) begin // Failed to open file $display("Failed to open file \"%s\"!", `AUTOTB_TVOUT_c_out_wrapc); $display("ERROR: Simulation using HLS TB failed."); $finish; end $fdisplay(fp,"[[[runtime]]]"); $fclose(fp); wait(done_cnt == `AUTOTB_TRANSACTION_NUM) repeat(2) @(posedge AESL_clock); # 0.2; fp = $fopen(`AUTOTB_TVOUT_c_out_wrapc, "a"); if(fp == 0) begin // Failed to open file $display("Failed to open file \"%s\"!", `AUTOTB_TVOUT_c_out_wrapc); $display("ERROR: Simulation using HLS TB failed."); $finish; end $fdisplay(fp,"[[[/runtime]]]"); $fclose(fp); end always @(posedge AESL_clock) begin if(AESL_reset === 0) begin AESL_clk_counter <= 0; end else begin AESL_clk_counter = AESL_clk_counter + 1; end end always @ (posedge AESL_clock or negedge AESL_reset) begin if(AESL_reset === 0) begin AESL_mLatCnterOut_addr = 0; AESL_mLatCnterOut[AESL_mLatCnterOut_addr] = AESL_clk_counter + 1; end else if (AESL_done && AESL_mLatCnterOut_addr < `AUTOTB_TRANSACTION_NUM + 1) begin AESL_mLatCnterOut[AESL_mLatCnterOut_addr] = AESL_clk_counter; AESL_mLatCnterOut_addr = AESL_mLatCnterOut_addr + 1; end end always @ (posedge AESL_clock or negedge AESL_reset) begin if(AESL_reset === 0) begin AESL_mLatCnterIn_addr = 0; end else if (AESL_slave_write_start_finish && AESL_mLatCnterIn_addr < `AUTOTB_TRANSACTION_NUM + 1) begin AESL_mLatCnterIn[AESL_mLatCnterIn_addr] = AESL_clk_counter; AESL_mLatCnterIn_addr = AESL_mLatCnterIn_addr + 1; end end initial begin : performance_check integer transaction_counter; integer i; integer fp; integer latthistime; integer lattotal; integer latmax; integer latmin; integer thrthistime; integer thrtotal; integer thrmax; integer thrmin; integer lataver; integer thraver; reg [31 : 0] lat_array [0 : `AUTOTB_TRANSACTION_NUM]; reg [31 : 0] thr_array [0 : `AUTOTB_TRANSACTION_NUM]; i = 0; lattotal = 0; latmax = 0; latmin = 32'h 7fffffff; lataver = 0; thrtotal = 0; thrmax = 0; thrmin = 32'h 7fffffff; thraver = 0; @(negedge AESL_clock); @(posedge AESL_reset); while (done_cnt != `AUTOTB_TRANSACTION_NUM) begin @(posedge AESL_clock); end #0.001 latmax = 0; latmin = 0; lataver = 0; thrmax = 0; thrmin = 0; thraver = 0; fp = $fopen(`AUTOTB_LAT_RESULT_FILE, "w"); $fdisplay(fp, "$MAX_LATENCY = \"%0d\"", latmax); $fdisplay(fp, "$MIN_LATENCY = \"%0d\"", latmin); $fdisplay(fp, "$AVER_LATENCY = \"%0d\"", lataver); $fdisplay(fp, "$MAX_THROUGHPUT = \"%0d\"", latmax); $fdisplay(fp, "$MIN_THROUGHPUT = \"%0d\"", latmin); $fdisplay(fp, "$AVER_THROUGHPUT = \"%0d\"", lataver); $fclose(fp); fp = $fopen(`AUTOTB_PER_RESULT_TRANS_FILE, "w"); $fdisplay (fp,"%20s%16s%16s","","latency","interval"); for (i = 0; i < AESL_mLatCnterOut_addr; i = i + 1) begin $fdisplay (fp,"transaction%8d: 0 0",i ); end $fclose(fp); end endmodule

(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2017 *) (* \VV/ **************************************************************) (* // * This file is distributed under the terms of the *) (* * GNU Lesser General Public License Version 2.1 *) (************************************************************************) Require Setoid. Require Import PeanoNat Le Gt Minus Bool Lt. Set Implicit Arguments. (* Set Universe Polymorphism. *) (******************************************************************) (** * Basics: definition of polymorphic lists and some operations *) (******************************************************************) (** The definition of [list] is now in [Init/Datatypes], as well as the definitions of [length] and [app] *) Open Scope list_scope. (** Standard notations for lists. In a special module to avoid conflicts. *) Module ListNotations. Notation "[ ]" := nil (format "[ ]") : list_scope. Notation "[ x ]" := (cons x nil) : list_scope. Notation "[ x ; y ; .. ; z ]" := (cons x (cons y .. (cons z nil) ..)) : list_scope. Notation "[ x ; .. ; y ]" := (cons x .. (cons y nil) ..) (compat "8.4") : list_scope. End ListNotations. Import ListNotations. Section Lists. Variable A : Type. (** Head and tail *) Definition hd (default:A) (l:list A) := match l with | [] => default | x :: _ => x end. Definition hd_error (l:list A) := match l with | [] => None | x :: _ => Some x end. Definition tl (l:list A) := match l with | [] => nil | a :: m => m end. (** The [In] predicate *) Fixpoint In (a:A) (l:list A) : Prop := match l with | [] => False | b :: m => b = a \/ In a m end. End Lists. Section Facts. Variable A : Type. (** *** Generic facts *) (** Discrimination *) Theorem nil_cons : forall (x:A) (l:list A), [] <> x :: l. Proof. intros; discriminate. Qed. (** Destruction *) Theorem destruct_list : forall l : list A, {x:A & {tl:list A | l = x::tl}}+{l = []}. Proof. induction l as [|a tail]. right; reflexivity. left; exists a, tail; reflexivity. Qed. Lemma hd_error_tl_repr : forall l (a:A) r, hd_error l = Some a /\ tl l = r <-> l = a :: r. Proof. destruct l as [|x xs]. - unfold hd_error, tl; intros a r. split; firstorder discriminate. - intros. simpl. split. * intros (H1, H2). inversion H1. rewrite H2. reflexivity. * inversion 1. subst. auto. Qed. Lemma hd_error_some_nil : forall l (a:A), hd_error l = Some a -> l <> nil. Proof. unfold hd_error. destruct l; now discriminate. Qed. Theorem length_zero_iff_nil (l : list A): length l = 0 <-> l=[]. Proof. split; [now destruct l | now intros ->]. Qed. (** *** Head and tail *) Theorem hd_error_nil : hd_error (@nil A) = None. Proof. simpl; reflexivity. Qed. Theorem hd_error_cons : forall (l : list A) (x : A), hd_error (x::l) = Some x. Proof. intros; simpl; reflexivity. Qed. (************************) (** *** Facts about [In] *) (************************) (** Characterization of [In] *) Theorem in_eq : forall (a:A) (l:list A), In a (a :: l). Proof. simpl; auto. Qed. Theorem in_cons : forall (a b:A) (l:list A), In b l -> In b (a :: l). Proof. simpl; auto. Qed. Theorem not_in_cons (x a : A) (l : list A): ~ In x (a::l) <-> x<>a /\ ~ In x l. Proof. simpl. intuition. Qed. Theorem in_nil : forall a:A, ~ In a []. Proof. unfold not; intros a H; inversion_clear H. Qed. Theorem in_split : forall x (l:list A), In x l -> exists l1 l2, l = l1++x::l2. Proof. induction l; simpl; destruct 1. subst a; auto. exists [], l; auto. destruct (IHl H) as (l1,(l2,H0)). exists (a::l1), l2; simpl. apply f_equal. auto. Qed. (** Inversion *) Lemma in_inv : forall (a b:A) (l:list A), In b (a :: l) -> a = b \/ In b l. Proof. intros a b l H; inversion_clear H; auto. Qed. (** Decidability of [In] *) Theorem in_dec : (forall x y:A, {x = y} + {x <> y}) -> forall (a:A) (l:list A), {In a l} + {~ In a l}. Proof. intro H; induction l as [| a0 l IHl]. right; apply in_nil. destruct (H a0 a); simpl; auto. destruct IHl; simpl; auto. right; unfold not; intros [Hc1| Hc2]; auto. Defined. (**************************) (** *** Facts about [app] *) (**************************) (** Discrimination *) Theorem app_cons_not_nil : forall (x y:list A) (a:A), [] <> x ++ a :: y. Proof. unfold not. destruct x as [| a l]; simpl; intros. discriminate H. discriminate H. Qed. (** Concat with [nil] *) Theorem app_nil_l : forall l:list A, [] ++ l = l. Proof. reflexivity. Qed. Theorem app_nil_r : forall l:list A, l ++ [] = l. Proof. induction l; simpl; f_equal; auto. Qed. (* begin hide *) (* Deprecated *) Theorem app_nil_end : forall (l:list A), l = l ++ []. Proof. symmetry; apply app_nil_r. Qed. (* end hide *) (** [app] is associative *) Theorem app_assoc : forall l m n:list A, l ++ m ++ n = (l ++ m) ++ n. Proof. intros l m n; induction l; simpl; f_equal; auto. Qed. (* begin hide *) (* Deprecated *) Theorem app_assoc_reverse : forall l m n:list A, (l ++ m) ++ n = l ++ m ++ n. Proof. auto using app_assoc. Qed. Hint Resolve app_assoc_reverse. (* end hide *) (** [app] commutes with [cons] *) Theorem app_comm_cons : forall (x y:list A) (a:A), a :: (x ++ y) = (a :: x) ++ y. Proof. auto. Qed. (** Facts deduced from the result of a concatenation *) Theorem app_eq_nil : forall l l':list A, l ++ l' = [] -> l = [] /\ l' = []. Proof. destruct l as [| x l]; destruct l' as [| y l']; simpl; auto. intro; discriminate. intros H; discriminate H. Qed. Theorem app_eq_unit : forall (x y:list A) (a:A), x ++ y = [a] -> x = [] /\ y = [a] \/ x = [a] /\ y = []. Proof. destruct x as [| a l]; [ destruct y as [| a l] | destruct y as [| a0 l0] ]; simpl. intros a H; discriminate H. left; split; auto. right; split; auto. generalize H. generalize (app_nil_r l); intros E. rewrite -> E; auto. intros. injection H as H H0. assert ([] = l ++ a0 :: l0) by auto. apply app_cons_not_nil in H1 as []. Qed. Lemma app_inj_tail : forall (x y:list A) (a b:A), x ++ [a] = y ++ [b] -> x = y /\ a = b. Proof. induction x as [| x l IHl]; [ destruct y as [| a l] | destruct y as [| a l0] ]; simpl; auto. - intros a b H. injection H. auto. - intros a0 b H. injection H as H1 H0. apply app_cons_not_nil in H0 as []. - intros a b H. injection H as H1 H0. assert ([] = l ++ [a]) by auto. apply app_cons_not_nil in H as []. - intros a0 b H. injection H as <- H0. destruct (IHl l0 a0 b H0) as (<-,<-). split; auto. Qed. (** Compatibility with other operations *) Lemma app_length : forall l l' : list A, length (l++l') = length l + length l'. Proof. induction l; simpl; auto. Qed. Lemma in_app_or : forall (l m:list A) (a:A), In a (l ++ m) -> In a l \/ In a m. Proof. intros l m a. elim l; simpl; auto. intros a0 y H H0. now_show ((a0 = a \/ In a y) \/ In a m). elim H0; auto. intro H1. now_show ((a0 = a \/ In a y) \/ In a m). elim (H H1); auto. Qed. Lemma in_or_app : forall (l m:list A) (a:A), In a l \/ In a m -> In a (l ++ m). Proof. intros l m a. elim l; simpl; intro H. now_show (In a m). elim H; auto; intro H0. now_show (In a m). elim H0. (* subProof completed *) intros y H0 H1. now_show (H = a \/ In a (y ++ m)). elim H1; auto 4. intro H2. now_show (H = a \/ In a (y ++ m)). elim H2; auto. Qed. Lemma in_app_iff : forall l l' (a:A), In a (l++l') <-> In a l \/ In a l'. Proof. split; auto using in_app_or, in_or_app. Qed. Lemma app_inv_head: forall l l1 l2 : list A, l ++ l1 = l ++ l2 -> l1 = l2. Proof. induction l; simpl; auto; injection 1; auto. Qed. Lemma app_inv_tail: forall l l1 l2 : list A, l1 ++ l = l2 ++ l -> l1 = l2. Proof. intros l l1 l2; revert l1 l2 l. induction l1 as [ | x1 l1]; destruct l2 as [ | x2 l2]; simpl; auto; intros l H. absurd (length (x2 :: l2 ++ l) <= length l). simpl; rewrite app_length; auto with arith. rewrite <- H; auto with arith. absurd (length (x1 :: l1 ++ l) <= length l). simpl; rewrite app_length; auto with arith. rewrite H; auto with arith. injection H as H H0; f_equal; eauto. Qed. End Facts. Hint Resolve app_assoc app_assoc_reverse: datatypes. Hint Resolve app_comm_cons app_cons_not_nil: datatypes. Hint Immediate app_eq_nil: datatypes. Hint Resolve app_eq_unit app_inj_tail: datatypes. Hint Resolve in_eq in_cons in_inv in_nil in_app_or in_or_app: datatypes. (*******************************************) (** * Operations on the elements of a list *) (*******************************************) Section Elts. Variable A : Type. (*****************************) (** ** Nth element of a list *) (*****************************) Fixpoint nth (n:nat) (l:list A) (default:A) {struct l} : A := match n, l with | O, x :: l' => x | O, other => default | S m, [] => default | S m, x :: t => nth m t default end. Fixpoint nth_ok (n:nat) (l:list A) (default:A) {struct l} : bool := match n, l with | O, x :: l' => true | O, other => false | S m, [] => false | S m, x :: t => nth_ok m t default end. Lemma nth_in_or_default : forall (n:nat) (l:list A) (d:A), {In (nth n l d) l} + {nth n l d = d}. Proof. intros n l d; revert n; induction l. - right; destruct n; trivial. - intros [|n]; simpl. * left; auto. * destruct (IHl n); auto. Qed. Lemma nth_S_cons : forall (n:nat) (l:list A) (d a:A), In (nth n l d) l -> In (nth (S n) (a :: l) d) (a :: l). Proof. simpl; auto. Qed. Fixpoint nth_error (l:list A) (n:nat) {struct n} : option A := match n, l with | O, x :: _ => Some x | S n, _ :: l => nth_error l n | _, _ => None end. Definition nth_default (default:A) (l:list A) (n:nat) : A := match nth_error l n with | Some x => x | None => default end. Lemma nth_default_eq : forall n l (d:A), nth_default d l n = nth n l d. Proof. unfold nth_default; induction n; intros [ | ] ?; simpl; auto. Qed. (** Results about [nth] *) Lemma nth_In : forall (n:nat) (l:list A) (d:A), n < length l -> In (nth n l d) l. Proof. unfold lt; induction n as [| n hn]; simpl. - destruct l; simpl; [ inversion 2 | auto ]. - destruct l; simpl. * inversion 2. * intros d ie; right; apply hn; auto with arith. Qed. Lemma In_nth l x d : In x l -> exists n, n < length l /\ nth n l d = x. Proof. induction l as [|a l IH]. - easy. - intros [H|H]. * subst; exists 0; simpl; auto with arith. * destruct (IH H) as (n & Hn & Hn'). exists (S n); simpl; auto with arith. Qed. Lemma nth_overflow : forall l n d, length l <= n -> nth n l d = d. Proof. induction l; destruct n; simpl; intros; auto. - inversion H. - apply IHl; auto with arith. Qed. Lemma nth_indep : forall l n d d', n < length l -> nth n l d = nth n l d'. Proof. induction l. - inversion 1. - intros [|n] d d'; simpl; auto with arith. Qed. Lemma app_nth1 : forall l l' d n, n < length l -> nth n (l++l') d = nth n l d. Proof. induction l. - inversion 1. - intros l' d [|n]; simpl; auto with arith. Qed. Lemma app_nth2 : forall l l' d n, n >= length l -> nth n (l++l') d = nth (n-length l) l' d. Proof. induction l; intros l' d [|n]; auto. - inversion 1. - intros; simpl; rewrite IHl; auto with arith. Qed. Lemma nth_split n l d : n < length l -> exists l1, exists l2, l = l1 ++ nth n l d :: l2 /\ length l1 = n. Proof. revert l. induction n as [|n IH]; intros [|a l] H; try easy. - exists nil; exists l; now simpl. - destruct (IH l) as (l1 & l2 & Hl & Hl1); auto with arith. exists (a::l1); exists l2; simpl; split; now f_equal. Qed. (** Results about [nth_error] *) Lemma nth_error_In l n x : nth_error l n = Some x -> In x l. Proof. revert n. induction l as [|a l IH]; intros [|n]; simpl; try easy. - injection 1; auto. - eauto. Qed. Lemma In_nth_error l x : In x l -> exists n, nth_error l n = Some x. Proof. induction l as [|a l IH]. - easy. - intros [H|H]. * subst; exists 0; simpl; auto with arith. * destruct (IH H) as (n,Hn). exists (S n); simpl; auto with arith. Qed. Lemma nth_error_None l n : nth_error l n = None <-> length l <= n. Proof. revert n. induction l; destruct n; simpl. - split; auto. - split; auto with arith. - split; now auto with arith. - rewrite IHl; split; auto with arith. Qed. Lemma nth_error_Some l n : nth_error l n <> None <-> n < length l. Proof. revert n. induction l; destruct n; simpl. - split; [now destruct 1 | inversion 1]. - split; [now destruct 1 | inversion 1]. - split; now auto with arith. - rewrite IHl; split; auto with arith. Qed. Lemma nth_error_split l n a : nth_error l n = Some a -> exists l1, exists l2, l = l1 ++ a :: l2 /\ length l1 = n. Proof. revert l. induction n as [|n IH]; intros [|x l] H; simpl in *; try easy. - exists nil; exists l. now injection H as ->. - destruct (IH _ H) as (l1 & l2 & H1 & H2). exists (x::l1); exists l2; simpl; split; now f_equal. Qed. Lemma nth_error_app1 l l' n : n < length l -> nth_error (l++l') n = nth_error l n. Proof. revert l. induction n; intros [|a l] H; auto; try solve [inversion H]. simpl in *. apply IHn. auto with arith. Qed. Lemma nth_error_app2 l l' n : length l <= n -> nth_error (l++l') n = nth_error l' (n-length l). Proof. revert l. induction n; intros [|a l] H; auto; try solve [inversion H]. simpl in *. apply IHn. auto with arith. Qed. (*****************) (** ** Remove *) (*****************) Hypothesis eq_dec : forall x y : A, {x = y}+{x <> y}. Fixpoint remove (x : A) (l : list A) : list A := match l with | [] => [] | y::tl => if (eq_dec x y) then remove x tl else y::(remove x tl) end. Theorem remove_In : forall (l : list A) (x : A), ~ In x (remove x l). Proof. induction l as [|x l]; auto. intro y; simpl; destruct (eq_dec y x) as [yeqx | yneqx]. apply IHl. unfold not; intro HF; simpl in HF; destruct HF; auto. apply (IHl y); assumption. Qed. (******************************) (** ** Last element of a list *) (******************************) (** [last l d] returns the last element of the list [l], or the default value [d] if [l] is empty. *) Fixpoint last (l:list A) (d:A) : A := match l with | [] => d | [a] => a | a :: l => last l d end. (** [removelast l] remove the last element of [l] *) Fixpoint removelast (l:list A) : list A := match l with | [] => [] | [a] => [] | a :: l => a :: removelast l end. Lemma app_removelast_last : forall l d, l <> [] -> l = removelast l ++ [last l d]. Proof. induction l. destruct 1; auto. intros d _. destruct l; auto. pattern (a0::l) at 1; rewrite IHl with d; auto; discriminate. Qed. Lemma exists_last : forall l, l <> [] -> { l' : (list A) & { a : A | l = l' ++ [a]}}. Proof. induction l. destruct 1; auto. intros _. destruct l. exists [], a; auto. destruct IHl as [l' (a',H)]; try discriminate. rewrite H. exists (a::l'), a'; auto. Qed. Lemma removelast_app : forall l l', l' <> [] -> removelast (l++l') = l ++ removelast l'. Proof. induction l. simpl; auto. simpl; intros. assert (l++l' <> []). destruct l. simpl; auto. simpl; discriminate. specialize (IHl l' H). destruct (l++l'); [elim H0; auto|f_equal; auto]. Qed. (******************************************) (** ** Counting occurrences of an element *) (******************************************) Fixpoint count_occ (l : list A) (x : A) : nat := match l with | [] => 0 | y :: tl => let n := count_occ tl x in if eq_dec y x then S n else n end. (** Compatibility of count_occ with operations on list *) Theorem count_occ_In l x : In x l <-> count_occ l x > 0. Proof. induction l as [|y l]; simpl. - split; [destruct 1 | apply gt_irrefl]. - destruct eq_dec as [->|Hneq]; rewrite IHl; intuition. Qed. Theorem count_occ_not_In l x : ~ In x l <-> count_occ l x = 0. Proof. rewrite count_occ_In. unfold gt. now rewrite Nat.nlt_ge, Nat.le_0_r. Qed. Lemma count_occ_nil x : count_occ [] x = 0. Proof. reflexivity. Qed. Theorem count_occ_inv_nil l : (forall x:A, count_occ l x = 0) <-> l = []. Proof. split. - induction l as [|x l]; trivial. intros H. specialize (H x). simpl in H. destruct eq_dec as [_|NEQ]; [discriminate|now elim NEQ]. - now intros ->. Qed. Lemma count_occ_cons_eq l x y : x = y -> count_occ (x::l) y = S (count_occ l y). Proof. intros H. simpl. now destruct (eq_dec x y). Qed. Lemma count_occ_cons_neq l x y : x <> y -> count_occ (x::l) y = count_occ l y. Proof. intros H. simpl. now destruct (eq_dec x y). Qed. End Elts. (*******************************) (** * Manipulating whole lists *) (*******************************) Section ListOps. Variable A : Type. (*************************) (** ** Reverse *) (*************************) Fixpoint rev (l:list A) : list A := match l with | [] => [] | x :: l' => rev l' ++ [x] end. Lemma rev_app_distr : forall x y:list A, rev (x ++ y) = rev y ++ rev x. Proof. induction x as [| a l IHl]. destruct y as [| a l]. simpl. auto. simpl. rewrite app_nil_r; auto. intro y. simpl. rewrite (IHl y). rewrite app_assoc; trivial. Qed. Remark rev_unit : forall (l:list A) (a:A), rev (l ++ [a]) = a :: rev l. Proof. intros. apply (rev_app_distr l [a]); simpl; auto. Qed. Lemma rev_involutive : forall l:list A, rev (rev l) = l. Proof. induction l as [| a l IHl]. simpl; auto. simpl. rewrite (rev_unit (rev l) a). rewrite IHl; auto. Qed. (** Compatibility with other operations *) Lemma in_rev : forall l x, In x l <-> In x (rev l). Proof. induction l. simpl; intuition. intros. simpl. intuition. subst. apply in_or_app; right; simpl; auto. apply in_or_app; left; firstorder. destruct (in_app_or _ _ _ H); firstorder. Qed. Lemma rev_length : forall l, length (rev l) = length l. Proof. induction l;simpl; auto. rewrite app_length. rewrite IHl. simpl. elim (length l); simpl; auto. Qed. Lemma rev_nth : forall l d n, n < length l -> nth n (rev l) d = nth (length l - S n) l d. Proof. induction l. intros; inversion H. intros. simpl in H. simpl (rev (a :: l)). simpl (length (a :: l) - S n). inversion H. rewrite <- minus_n_n; simpl. rewrite <- rev_length. rewrite app_nth2; auto. rewrite <- minus_n_n; auto. rewrite app_nth1; auto. rewrite (minus_plus_simpl_l_reverse (length l) n 1). replace (1 + length l) with (S (length l)); auto with arith. rewrite <- minus_Sn_m; auto with arith. apply IHl ; auto with arith. rewrite rev_length; auto. Qed. (** An alternative tail-recursive definition for reverse *) Fixpoint rev_append (l l': list A) : list A := match l with | [] => l' | a::l => rev_append l (a::l') end. Definition rev' l : list A := rev_append l []. Lemma rev_append_rev : forall l l', rev_append l l' = rev l ++ l'. Proof. induction l; simpl; auto; intros. rewrite <- app_assoc; firstorder. Qed. Lemma rev_alt : forall l, rev l = rev_append l []. Proof. intros; rewrite rev_append_rev. rewrite app_nil_r; trivial. Qed. (*********************************************) (** Reverse Induction Principle on Lists *) (*********************************************) Section Reverse_Induction. Lemma rev_list_ind : forall P:list A-> Prop, P [] -> (forall (a:A) (l:list A), P (rev l) -> P (rev (a :: l))) -> forall l:list A, P (rev l). Proof. induction l; auto. Qed. Theorem rev_ind : forall P:list A -> Prop, P [] -> (forall (x:A) (l:list A), P l -> P (l ++ [x])) -> forall l:list A, P l. Proof. intros. generalize (rev_involutive l). intros E; rewrite <- E. apply (rev_list_ind P). auto. simpl. intros. apply (H0 a (rev l0)). auto. Qed. End Reverse_Induction. (*************************) (** ** Concatenation *) (*************************) Fixpoint concat (l : list (list A)) : list A := match l with | nil => nil | cons x l => x ++ concat l end. Lemma concat_nil : concat nil = nil. Proof. reflexivity. Qed. Lemma concat_cons : forall x l, concat (cons x l) = x ++ concat l. Proof. reflexivity. Qed. Lemma concat_app : forall l1 l2, concat (l1 ++ l2) = concat l1 ++ concat l2. Proof. intros l1; induction l1 as [|x l1 IH]; intros l2; simpl. + reflexivity. + rewrite IH; apply app_assoc. Qed. (***********************************) (** ** Decidable equality on lists *) (***********************************) Hypothesis eq_dec : forall (x y : A), {x = y}+{x <> y}. Lemma list_eq_dec : forall l l':list A, {l = l'} + {l <> l'}. Proof. decide equality. Defined. End ListOps. (***************************************************) (** * Applying functions to the elements of a list *) (***************************************************) (************) (** ** Map *) (************) Section Map. Variables (A : Type) (B : Type). Variable f : A -> B. Fixpoint map (l:list A) : list B := match l with | [] => [] | a :: t => (f a) :: (map t) end. Lemma map_cons (x:A)(l:list A) : map (x::l) = (f x) :: (map l). Proof. reflexivity. Qed. Lemma in_map : forall (l:list A) (x:A), In x l -> In (f x) (map l). Proof. induction l; firstorder (subst; auto). Qed. Lemma in_map_iff : forall l y, In y (map l) <-> exists x, f x = y /\ In x l. Proof. induction l; firstorder (subst; auto). Qed. Lemma map_length : forall l, length (map l) = length l. Proof. induction l; simpl; auto. Qed. Lemma map_nth : forall l d n, nth n (map l) (f d) = f (nth n l d). Proof. induction l; simpl map; destruct n; firstorder. Qed. Lemma map_nth_error : forall n l d, nth_error l n = Some d -> nth_error (map l) n = Some (f d). Proof. induction n; intros [ | ] ? Heq; simpl in *; inversion Heq; auto. Qed. Lemma map_app : forall l l', map (l++l') = (map l)++(map l'). Proof. induction l; simpl; auto. intros; rewrite IHl; auto. Qed. Lemma map_rev : forall l, map (rev l) = rev (map l). Proof. induction l; simpl; auto. rewrite map_app. rewrite IHl; auto. Qed. Lemma map_eq_nil : forall l, map l = [] -> l = []. Proof. destruct l; simpl; reflexivity || discriminate. Qed. (** [map] and count of occurrences *) Hypothesis decA: forall x1 x2 : A, {x1 = x2} + {x1 <> x2}. Hypothesis decB: forall y1 y2 : B, {y1 = y2} + {y1 <> y2}. Hypothesis Hfinjective: forall x1 x2: A, (f x1) = (f x2) -> x1 = x2. Theorem count_occ_map x l: count_occ decA l x = count_occ decB (map l) (f x). Proof. revert x. induction l as [| a l' Hrec]; intro x; simpl. - reflexivity. - specialize (Hrec x). destruct (decA a x) as [H1|H1], (decB (f a) (f x)) as [H2|H2]. * rewrite Hrec. reflexivity. * contradiction H2. rewrite H1. reflexivity. * specialize (Hfinjective H2). contradiction H1. * assumption. Qed. (** [flat_map] *) Definition flat_map (f:A -> list B) := fix flat_map (l:list A) : list B := match l with | nil => nil | cons x t => (f x)++(flat_map t) end. Lemma in_flat_map : forall (f:A->list B)(l:list A)(y:B), In y (flat_map f l) <-> exists x, In x l /\ In y (f x). Proof using A B. clear Hfinjective. induction l; simpl; split; intros. contradiction. destruct H as (x,(H,_)); contradiction. destruct (in_app_or _ _ _ H). exists a; auto. destruct (IHl y) as (H1,_); destruct (H1 H0) as (x,(H2,H3)). exists x; auto. apply in_or_app. destruct H as (x,(H0,H1)); destruct H0. subst; auto. right; destruct (IHl y) as (_,H2); apply H2. exists x; auto. Qed. End Map. Lemma flat_map_concat_map : forall A B (f : A -> list B) l, flat_map f l = concat (map f l). Proof. intros A B f l; induction l as [|x l IH]; simpl. + reflexivity. + rewrite IH; reflexivity. Qed. Lemma concat_map : forall A B (f : A -> B) l, map f (concat l) = concat (map (map f) l). Proof. intros A B f l; induction l as [|x l IH]; simpl. + reflexivity. + rewrite map_app, IH; reflexivity. Qed. Lemma map_id : forall (A :Type) (l : list A), map (fun x => x) l = l. Proof. induction l; simpl; auto; rewrite IHl; auto. Qed. Lemma map_map : forall (A B C:Type)(f:A->B)(g:B->C) l, map g (map f l) = map (fun x => g (f x)) l. Proof. induction l; simpl; auto. rewrite IHl; auto. Qed. Lemma map_ext_in : forall (A B : Type)(f g:A->B) l, (forall a, In a l -> f a = g a) -> map f l = map g l. Proof. induction l; simpl; auto. intros; rewrite H by intuition; rewrite IHl; auto. Qed. Lemma map_ext : forall (A B : Type)(f g:A->B), (forall a, f a = g a) -> forall l, map f l = map g l. Proof. intros; apply map_ext_in; auto. Qed. (************************************) (** Left-to-right iterator on lists *) (************************************) Section Fold_Left_Recursor. Variables (A : Type) (B : Type). Variable f : A -> B -> A. Fixpoint fold_left (l:list B) (a0:A) : A := match l with | nil => a0 | cons b t => fold_left t (f a0 b) end. Lemma fold_left_app : forall (l l':list B)(i:A), fold_left (l++l') i = fold_left l' (fold_left l i). Proof. induction l. simpl; auto. intros. simpl. auto. Qed. End Fold_Left_Recursor. Lemma fold_left_length : forall (A:Type)(l:list A), fold_left (fun x _ => S x) l 0 = length l. Proof. intros A l. enough (H : forall n, fold_left (fun x _ => S x) l n = n + length l) by exact (H 0). induction l; simpl; auto. intros; rewrite IHl. simpl; auto with arith. Qed. (************************************) (** Right-to-left iterator on lists *) (************************************) Section Fold_Right_Recursor. Variables (A : Type) (B : Type). Variable f : B -> A -> A. Variable a0 : A. Fixpoint fold_right (l:list B) : A := match l with | nil => a0 | cons b t => f b (fold_right t) end. End Fold_Right_Recursor. Lemma fold_right_app : forall (A B:Type)(f:A->B->B) l l' i, fold_right f i (l++l') = fold_right f (fold_right f i l') l. Proof. induction l. simpl; auto. simpl; intros. f_equal; auto. Qed. Lemma fold_left_rev_right : forall (A B:Type)(f:A->B->B) l i, fold_right f i (rev l) = fold_left (fun x y => f y x) l i. Proof. induction l. simpl; auto. intros. simpl. rewrite fold_right_app; simpl; auto. Qed. Theorem fold_symmetric : forall (A : Type) (f : A -> A -> A), (forall x y z : A, f x (f y z) = f (f x y) z) -> forall (a0 : A), (forall y : A, f a0 y = f y a0) -> forall (l : list A), fold_left f l a0 = fold_right f a0 l. Proof. intros A f assoc a0 comma0 l. induction l as [ | a1 l ]; [ simpl; reflexivity | ]. simpl. rewrite <- IHl. clear IHl. revert a1. induction l; [ auto | ]. simpl. intro. rewrite <- assoc. rewrite IHl. rewrite IHl. auto. Qed. (** [(list_power x y)] is [y^x], or the set of sequences of elts of [y] indexed by elts of [x], sorted in lexicographic order. *) Fixpoint list_power (A B:Type)(l:list A) (l':list B) : list (list (A * B)) := match l with | nil => cons nil nil | cons x t => flat_map (fun f:list (A * B) => map (fun y:B => cons (x, y) f) l') (list_power t l') end. (*************************************) (** ** Boolean operations over lists *) (*************************************) Section Bool. Variable A : Type. Variable f : A -> bool. (** find whether a boolean function can be satisfied by an elements of the list. *) Fixpoint existsb (l:list A) : bool := match l with | nil => false | a::l => f a || existsb l end. Lemma existsb_exists : forall l, existsb l = true <-> exists x, In x l /\ f x = true. Proof. induction l; simpl; intuition. inversion H. firstorder. destruct (orb_prop _ _ H1); firstorder. firstorder. subst. rewrite H2; auto. Qed. Lemma existsb_nth : forall l n d, n < length l -> existsb l = false -> f (nth n l d) = false. Proof. induction l. inversion 1. simpl; intros. destruct (orb_false_elim _ _ H0); clear H0; auto. destruct n ; auto. rewrite IHl; auto with arith. Qed. Lemma existsb_app : forall l1 l2, existsb (l1++l2) = existsb l1 || existsb l2. Proof. induction l1; intros l2; simpl. solve[auto]. case (f a); simpl; solve[auto]. Qed. (** find whether a boolean function is satisfied by all the elements of a list. *) Fixpoint forallb (l:list A) : bool := match l with | nil => true | a::l => f a && forallb l end. Lemma forallb_forall : forall l, forallb l = true <-> (forall x, In x l -> f x = true). Proof. induction l; simpl; intuition. destruct (andb_prop _ _ H1). congruence. destruct (andb_prop _ _ H1); auto. assert (forallb l = true). apply H0; intuition. rewrite H1; auto. Qed. Lemma forallb_app : forall l1 l2, forallb (l1++l2) = forallb l1 && forallb l2. Proof. induction l1; simpl. solve[auto]. case (f a); simpl; solve[auto]. Qed. (** [filter] *) Fixpoint filter (l:list A) : list A := match l with | nil => nil | x :: l => if f x then x::(filter l) else filter l end. Lemma filter_In : forall x l, In x (filter l) <-> In x l /\ f x = true. Proof. induction l; simpl. intuition. intros. case_eq (f a); intros; simpl; intuition congruence. Qed. (** [find] *) Fixpoint find (l:list A) : option A := match l with | nil => None | x :: tl => if f x then Some x else find tl end. Lemma find_some l x : find l = Some x -> In x l /\ f x = true. Proof. induction l as [|a l IH]; simpl; [easy| ]. case_eq (f a); intros Ha Eq. * injection Eq as ->; auto. * destruct (IH Eq); auto. Qed. Lemma find_none l : find l = None -> forall x, In x l -> f x = false. Proof. induction l as [|a l IH]; simpl; [easy|]. case_eq (f a); intros Ha Eq x IN; [easy|]. destruct IN as [<-|IN]; auto. Qed. (** [partition] *) Fixpoint partition (l:list A) : list A * list A := match l with | nil => (nil, nil) | x :: tl => let (g,d) := partition tl in if f x then (x::g,d) else (g,x::d) end. Theorem partition_cons1 a l l1 l2: partition l = (l1, l2) -> f a = true -> partition (a::l) = (a::l1, l2). Proof. simpl. now intros -> ->. Qed. Theorem partition_cons2 a l l1 l2: partition l = (l1, l2) -> f a=false -> partition (a::l) = (l1, a::l2). Proof. simpl. now intros -> ->. Qed. Theorem partition_length l l1 l2: partition l = (l1, l2) -> length l = length l1 + length l2. Proof. revert l1 l2. induction l as [ | a l' Hrec]; intros l1 l2. - now intros [= <- <- ]. - simpl. destruct (f a), (partition l') as (left, right); intros [= <- <- ]; simpl; rewrite (Hrec left right); auto. Qed. Theorem partition_inv_nil (l : list A): partition l = ([], []) <-> l = []. Proof. split. - destruct l as [|a l']. * intuition. * simpl. destruct (f a), (partition l'); now intros [= -> ->]. - now intros ->. Qed. Theorem elements_in_partition l l1 l2: partition l = (l1, l2) -> forall x:A, In x l <-> In x l1 \/ In x l2. Proof. revert l1 l2. induction l as [| a l' Hrec]; simpl; intros l1 l2 Eq x. - injection Eq as <- <-. tauto. - destruct (partition l') as (left, right). specialize (Hrec left right eq_refl x). destruct (f a); injection Eq as <- <-; simpl; tauto. Qed. End Bool. (******************************************************) (** ** Operations on lists of pairs or lists of lists *) (******************************************************) Section ListPairs. Variables (A : Type) (B : Type). (** [split] derives two lists from a list of pairs *) Fixpoint split (l:list (A*B)) : list A * list B := match l with | [] => ([], []) | (x,y) :: tl => let (left,right) := split tl in (x::left, y::right) end. Lemma in_split_l : forall (l:list (A*B))(p:A*B), In p l -> In (fst p) (fst (split l)). Proof. induction l; simpl; intros; auto. destruct p; destruct a; destruct (split l); simpl in *. destruct H. injection H; auto. right; apply (IHl (a0,b) H). Qed. Lemma in_split_r : forall (l:list (A*B))(p:A*B), In p l -> In (snd p) (snd (split l)). Proof. induction l; simpl; intros; auto. destruct p; destruct a; destruct (split l); simpl in *. destruct H. injection H; auto. right; apply (IHl (a0,b) H). Qed. Lemma split_nth : forall (l:list (A*B))(n:nat)(d:A*B), nth n l d = (nth n (fst (split l)) (fst d), nth n (snd (split l)) (snd d)). Proof. induction l. destruct n; destruct d; simpl; auto. destruct n; destruct d; simpl; auto. destruct a; destruct (split l); simpl; auto. destruct a; destruct (split l); simpl in *; auto. apply IHl. Qed. Lemma split_length_l : forall (l:list (A*B)), length (fst (split l)) = length l. Proof. induction l; simpl; auto. destruct a; destruct (split l); simpl; auto. Qed. Lemma split_length_r : forall (l:list (A*B)), length (snd (split l)) = length l. Proof. induction l; simpl; auto. destruct a; destruct (split l); simpl; auto. Qed. (** [combine] is the opposite of [split]. Lists given to [combine] are meant to be of same length. If not, [combine] stops on the shorter list *) Fixpoint combine (l : list A) (l' : list B) : list (A*B) := match l,l' with | x::tl, y::tl' => (x,y)::(combine tl tl') | _, _ => nil end. Lemma split_combine : forall (l: list (A*B)), let (l1,l2) := split l in combine l1 l2 = l. Proof. induction l. simpl; auto. destruct a; simpl. destruct (split l); simpl in *. f_equal; auto. Qed. Lemma combine_split : forall (l:list A)(l':list B), length l = length l' -> split (combine l l') = (l,l'). Proof. induction l, l'; simpl; trivial; try discriminate. now intros [= ->%IHl]. Qed. Lemma in_combine_l : forall (l:list A)(l':list B)(x:A)(y:B), In (x,y) (combine l l') -> In x l. Proof. induction l. simpl; auto. destruct l'; simpl; auto; intros. contradiction. destruct H. injection H; auto. right; apply IHl with l' y; auto. Qed. Lemma in_combine_r : forall (l:list A)(l':list B)(x:A)(y:B), In (x,y) (combine l l') -> In y l'. Proof. induction l. simpl; intros; contradiction. destruct l'; simpl; auto; intros. destruct H. injection H; auto. right; apply IHl with x; auto. Qed. Lemma combine_length : forall (l:list A)(l':list B), length (combine l l') = min (length l) (length l'). Proof. induction l. simpl; auto. destruct l'; simpl; auto. Qed. Lemma combine_nth : forall (l:list A)(l':list B)(n:nat)(x:A)(y:B), length l = length l' -> nth n (combine l l') (x,y) = (nth n l x, nth n l' y). Proof. induction l; destruct l'; intros; try discriminate. destruct n; simpl; auto. destruct n; simpl in *; auto. Qed. (** [list_prod] has the same signature as [combine], but unlike [combine], it adds every possible pairs, not only those at the same position. *) Fixpoint list_prod (l:list A) (l':list B) : list (A * B) := match l with | nil => nil | cons x t => (map (fun y:B => (x, y)) l')++(list_prod t l') end. Lemma in_prod_aux : forall (x:A) (y:B) (l:list B), In y l -> In (x, y) (map (fun y0:B => (x, y0)) l). Proof. induction l; [ simpl; auto | simpl; destruct 1 as [H1| ]; [ left; rewrite H1; trivial | right; auto ] ]. Qed. Lemma in_prod : forall (l:list A) (l':list B) (x:A) (y:B), In x l -> In y l' -> In (x, y) (list_prod l l'). Proof. induction l; [ simpl; tauto | simpl; intros; apply in_or_app; destruct H; [ left; rewrite H; apply in_prod_aux; assumption | right; auto ] ]. Qed. Lemma in_prod_iff : forall (l:list A)(l':list B)(x:A)(y:B), In (x,y) (list_prod l l') <-> In x l /\ In y l'. Proof. split; [ | intros; apply in_prod; intuition ]. induction l; simpl; intros. intuition. destruct (in_app_or _ _ _ H); clear H. destruct (in_map_iff (fun y : B => (a, y)) l' (x,y)) as (H1,_). destruct (H1 H0) as (z,(H2,H3)); clear H0 H1. injection H2 as -> ->; intuition. intuition. Qed. Lemma prod_length : forall (l:list A)(l':list B), length (list_prod l l') = (length l) * (length l'). Proof. induction l; simpl; auto. intros. rewrite app_length. rewrite map_length. auto. Qed. End ListPairs. (*****************************************) (** * Miscellaneous operations on lists *) (*****************************************) (******************************) (** ** Length order of lists *) (******************************) Section length_order. Variable A : Type. Definition lel (l m:list A) := length l <= length m. Variables a b : A. Variables l m n : list A. Lemma lel_refl : lel l l. Proof. unfold lel; auto with arith. Qed. Lemma lel_trans : lel l m -> lel m n -> lel l n. Proof. unfold lel; intros. now_show (length l <= length n). apply le_trans with (length m); auto with arith. Qed. Lemma lel_cons_cons : lel l m -> lel (a :: l) (b :: m). Proof. unfold lel; simpl; auto with arith. Qed. Lemma lel_cons : lel l m -> lel l (b :: m). Proof. unfold lel; simpl; auto with arith. Qed. Lemma lel_tail : lel (a :: l) (b :: m) -> lel l m. Proof. unfold lel; simpl; auto with arith. Qed. Lemma lel_nil : forall l':list A, lel l' nil -> nil = l'. Proof. intro l'; elim l'; auto with arith. intros a' y H H0. now_show (nil = a' :: y). absurd (S (length y) <= 0); auto with arith. Qed. End length_order. Hint Resolve lel_refl lel_cons_cons lel_cons lel_nil lel_nil nil_cons: datatypes. (******************************) (** ** Set inclusion on list *) (******************************) Section SetIncl. Variable A : Type. Definition incl (l m:list A) := forall a:A, In a l -> In a m. Hint Unfold incl. Lemma incl_refl : forall l:list A, incl l l. Proof. auto. Qed. Hint Resolve incl_refl. Lemma incl_tl : forall (a:A) (l m:list A), incl l m -> incl l (a :: m). Proof. auto with datatypes. Qed. Hint Immediate incl_tl. Lemma incl_tran : forall l m n:list A, incl l m -> incl m n -> incl l n. Proof. auto. Qed. Lemma incl_appl : forall l m n:list A, incl l n -> incl l (n ++ m). Proof. auto with datatypes. Qed. Hint Immediate incl_appl. Lemma incl_appr : forall l m n:list A, incl l n -> incl l (m ++ n). Proof. auto with datatypes. Qed. Hint Immediate incl_appr. Lemma incl_cons : forall (a:A) (l m:list A), In a m -> incl l m -> incl (a :: l) m. Proof. unfold incl; simpl; intros a l m H H0 a0 H1. now_show (In a0 m). elim H1. now_show (a = a0 -> In a0 m). elim H1; auto; intro H2. now_show (a = a0 -> In a0 m). elim H2; auto. (* solves subgoal *) now_show (In a0 l -> In a0 m). auto. Qed. Hint Resolve incl_cons. Lemma incl_app : forall l m n:list A, incl l n -> incl m n -> incl (l ++ m) n. Proof. unfold incl; simpl; intros l m n H H0 a H1. now_show (In a n). elim (in_app_or _ _ _ H1); auto. Qed. Hint Resolve incl_app. End SetIncl. Hint Resolve incl_refl incl_tl incl_tran incl_appl incl_appr incl_cons incl_app: datatypes. (**************************************) (** * Cutting a list at some position *) (**************************************) Section Cutting. Variable A : Type. Fixpoint firstn (n:nat)(l:list A) : list A := match n with | 0 => nil | S n => match l with | nil => nil | a::l => a::(firstn n l) end end. Lemma firstn_nil n: firstn n [] = []. Proof. induction n; now simpl. Qed. Lemma firstn_cons n a l: firstn (S n) (a::l) = a :: (firstn n l). Proof. now simpl. Qed. Lemma firstn_all l: firstn (length l) l = l. Proof. induction l as [| ? ? H]; simpl; [reflexivity | now rewrite H]. Qed. Lemma firstn_all2 n: forall (l:list A), (length l) <= n -> firstn n l = l. Proof. induction n as [|k iHk]. - intro. inversion 1 as [H1|?]. rewrite (length_zero_iff_nil l) in H1. subst. now simpl. - destruct l as [|x xs]; simpl. * now reflexivity. * simpl. intro H. apply Peano.le_S_n in H. f_equal. apply iHk, H. Qed. Lemma firstn_O l: firstn 0 l = []. Proof. now simpl. Qed. Lemma firstn_le_length n: forall l:list A, length (firstn n l) <= n. Proof. induction n as [|k iHk]; simpl; [auto | destruct l as [|x xs]; simpl]. - auto with arith. - apply Peano.le_n_S, iHk. Qed. Lemma firstn_length_le: forall l:list A, forall n:nat, n <= length l -> length (firstn n l) = n. Proof. induction l as [|x xs Hrec]. - simpl. intros n H. apply le_n_0_eq in H. rewrite <- H. now simpl. - destruct n. * now simpl. * simpl. intro H. apply le_S_n in H. now rewrite (Hrec n H). Qed. Lemma firstn_app n: forall l1 l2, firstn n (l1 ++ l2) = (firstn n l1) ++ (firstn (n - length l1) l2). Proof. induction n as [|k iHk]; intros l1 l2. - now simpl. - destruct l1 as [|x xs]. * unfold firstn at 2, length. now rewrite 2!app_nil_l, <- minus_n_O. * rewrite <- app_comm_cons. simpl. f_equal. apply iHk. Qed. Lemma firstn_app_2 n: forall l1 l2, firstn ((length l1) + n) (l1 ++ l2) = l1 ++ firstn n l2. Proof. induction n as [| k iHk];intros l1 l2. - unfold firstn at 2. rewrite <- plus_n_O, app_nil_r. rewrite firstn_app. rewrite <- minus_diag_reverse. unfold firstn at 2. rewrite app_nil_r. apply firstn_all. - destruct l2 as [|x xs]. * simpl. rewrite app_nil_r. apply firstn_all2. auto with arith. * rewrite firstn_app. assert (H0 : (length l1 + S k - length l1) = S k). auto with arith. rewrite H0, firstn_all2; [reflexivity | auto with arith]. Qed. Lemma firstn_firstn: forall l:list A, forall i j : nat, firstn i (firstn j l) = firstn (min i j) l. Proof. induction l as [|x xs Hl]. - intros. simpl. now rewrite ?firstn_nil. - destruct i. * intro. now simpl. * destruct j. + now simpl. + simpl. f_equal. apply Hl. Qed. Fixpoint skipn (n:nat)(l:list A) : list A := match n with | 0 => l | S n => match l with | nil => nil | a::l => skipn n l end end. Lemma firstn_skipn : forall n l, firstn n l ++ skipn n l = l. Proof. induction n. simpl; auto. destruct l; simpl; auto. f_equal; auto. Qed. Lemma firstn_length : forall n l, length (firstn n l) = min n (length l). Proof. induction n; destruct l; simpl; auto. Qed. Lemma removelast_firstn : forall n l, n < length l -> removelast (firstn (S n) l) = firstn n l. Proof. induction n; destruct l. simpl; auto. simpl; auto. simpl; auto. intros. simpl in H. change (firstn (S (S n)) (a::l)) with ((a::nil)++firstn (S n) l). change (firstn (S n) (a::l)) with (a::firstn n l). rewrite removelast_app. rewrite IHn; auto with arith. clear IHn; destruct l; simpl in *; try discriminate. inversion_clear H. inversion_clear H0. Qed. Lemma firstn_removelast : forall n l, n < length l -> firstn n (removelast l) = firstn n l. Proof. induction n; destruct l. simpl; auto. simpl; auto. simpl; auto. intros. simpl in H. change (removelast (a :: l)) with (removelast ((a::nil)++l)). rewrite removelast_app. simpl; f_equal; auto with arith. intro H0; rewrite H0 in H; inversion_clear H; inversion_clear H1. Qed. End Cutting. (**********************************************************************) (** ** Predicate for List addition/removal (no need for decidability) *) (**********************************************************************) Section Add. Variable A : Type. (* [Add a l l'] means that [l'] is exactly [l], with [a] added once somewhere *) Inductive Add (a:A) : list A -> list A -> Prop := | Add_head l : Add a l (a::l) | Add_cons x l l' : Add a l l' -> Add a (x::l) (x::l'). Lemma Add_app a l1 l2 : Add a (l1++l2) (l1++a::l2). Proof. induction l1; simpl; now constructor. Qed. Lemma Add_split a l l' : Add a l l' -> exists l1 l2, l = l1++l2 /\ l' = l1++a::l2. Proof. induction 1. - exists nil; exists l; split; trivial. - destruct IHAdd as (l1 & l2 & Hl & Hl'). exists (x::l1); exists l2; split; simpl; f_equal; trivial. Qed. Lemma Add_in a l l' : Add a l l' -> forall x, In x l' <-> In x (a::l). Proof. induction 1; intros; simpl in *; rewrite ?IHAdd; tauto. Qed. Lemma Add_length a l l' : Add a l l' -> length l' = S (length l). Proof. induction 1; simpl; auto with arith. Qed. Lemma Add_inv a l : In a l -> exists l', Add a l' l. Proof. intro Ha. destruct (in_split _ _ Ha) as (l1 & l2 & ->). exists (l1 ++ l2). apply Add_app. Qed. Lemma incl_Add_inv a l u v : ~In a l -> incl (a::l) v -> Add a u v -> incl l u. Proof. intros Ha H AD y Hy. assert (Hy' : In y (a::u)). { rewrite <- (Add_in AD). apply H; simpl; auto. } destruct Hy'; [ subst; now elim Ha | trivial ]. Qed. End Add. (********************************) (** ** Lists without redundancy *) (********************************) Section ReDun. Variable A : Type. Inductive NoDup : list A -> Prop := | NoDup_nil : NoDup nil | NoDup_cons : forall x l, ~ In x l -> NoDup l -> NoDup (x::l). Lemma NoDup_Add a l l' : Add a l l' -> (NoDup l' <-> NoDup l /\ ~In a l). Proof. induction 1 as [l|x l l' AD IH]. - split; [ inversion_clear 1; now split | now constructor ]. - split. + inversion_clear 1. rewrite IH in *. rewrite (Add_in AD) in *. simpl in *; split; try constructor; intuition. + intros (N,IN). inversion_clear N. constructor. * rewrite (Add_in AD); simpl in *; intuition. * apply IH. split; trivial. simpl in *; intuition. Qed. Lemma NoDup_remove l l' a : NoDup (l++a::l') -> NoDup (l++l') /\ ~In a (l++l'). Proof. apply NoDup_Add. apply Add_app. Qed. Lemma NoDup_remove_1 l l' a : NoDup (l++a::l') -> NoDup (l++l'). Proof. intros. now apply NoDup_remove with a. Qed. Lemma NoDup_remove_2 l l' a : NoDup (l++a::l') -> ~In a (l++l'). Proof. intros. now apply NoDup_remove. Qed. Theorem NoDup_cons_iff a l: NoDup (a::l) <-> ~ In a l /\ NoDup l. Proof. split. + inversion_clear 1. now split. + now constructor. Qed. (** Effective computation of a list without duplicates *) Hypothesis decA: forall x y : A, {x = y} + {x <> y}. Fixpoint nodup (l : list A) : list A := match l with | [] => [] | x::xs => if in_dec decA x xs then nodup xs else x::(nodup xs) end. Lemma nodup_In l x : In x (nodup l) <-> In x l. Proof. induction l as [|a l' Hrec]; simpl. - reflexivity. - destruct (in_dec decA a l'); simpl; rewrite Hrec. * intuition; now subst. * reflexivity. Qed. Lemma NoDup_nodup l: NoDup (nodup l). Proof. induction l as [|a l' Hrec]; simpl. - constructor. - destruct (in_dec decA a l'); simpl. * assumption. * constructor; [ now rewrite nodup_In | assumption]. Qed. Lemma nodup_inv k l a : nodup k = a :: l -> ~ In a l. Proof. intros H. assert (H' : NoDup (a::l)). { rewrite <- H. apply NoDup_nodup. } now inversion_clear H'. Qed. Theorem NoDup_count_occ l: NoDup l <-> (forall x:A, count_occ decA l x <= 1). Proof. induction l as [| a l' Hrec]. - simpl; split; auto. constructor. - rewrite NoDup_cons_iff, Hrec, (count_occ_not_In decA). clear Hrec. split. + intros (Ha, H) x. simpl. destruct (decA a x); auto. subst; now rewrite Ha. + split. * specialize (H a). rewrite count_occ_cons_eq in H; trivial. now inversion H. * intros x. specialize (H x). simpl in *. destruct (decA a x); auto. now apply Nat.lt_le_incl. Qed. Theorem NoDup_count_occ' l: NoDup l <-> (forall x:A, In x l -> count_occ decA l x = 1). Proof. rewrite NoDup_count_occ. setoid_rewrite (count_occ_In decA). unfold gt, lt in *. split; intros H x; specialize (H x); set (n := count_occ decA l x) in *; clearbody n. (* the rest would be solved by omega if we had it here... *) - now apply Nat.le_antisymm. - destruct (Nat.le_gt_cases 1 n); trivial. + rewrite H; trivial. + now apply Nat.lt_le_incl. Qed. (** Alternative characterisations of being without duplicates, thanks to [nth_error] and [nth] *) Lemma NoDup_nth_error l : NoDup l <-> (forall i j, i<length l -> nth_error l i = nth_error l j -> i = j). Proof. split. { intros H; induction H as [|a l Hal Hl IH]; intros i j Hi E. - inversion Hi. - destruct i, j; simpl in *; auto. * elim Hal. eapply nth_error_In; eauto. * elim Hal. eapply nth_error_In; eauto. * f_equal. apply IH; auto with arith. } { induction l as [|a l]; intros H; constructor. * intro Ha. apply In_nth_error in Ha. destruct Ha as (n,Hn). assert (n < length l) by (now rewrite <- nth_error_Some, Hn). specialize (H 0 (S n)). simpl in H. discriminate H; auto with arith. * apply IHl. intros i j Hi E. apply eq_add_S, H; simpl; auto with arith. } Qed. Lemma NoDup_nth l d : NoDup l <-> (forall i j, i<length l -> j<length l -> nth i l d = nth j l d -> i = j). Proof. split. { intros H; induction H as [|a l Hal Hl IH]; intros i j Hi Hj E. - inversion Hi. - destruct i, j; simpl in *; auto. * elim Hal. subst a. apply nth_In; auto with arith. * elim Hal. subst a. apply nth_In; auto with arith. * f_equal. apply IH; auto with arith. } { induction l as [|a l]; intros H; constructor. * intro Ha. eapply In_nth in Ha. destruct Ha as (n & Hn & Hn'). specialize (H 0 (S n)). simpl in H. discriminate H; eauto with arith. * apply IHl. intros i j Hi Hj E. apply eq_add_S, H; simpl; auto with arith. } Qed. (** Having [NoDup] hypotheses bring more precise facts about [incl]. *) Lemma NoDup_incl_length l l' : NoDup l -> incl l l' -> length l <= length l'. Proof. intros N. revert l'. induction N as [|a l Hal N IH]; simpl. - auto with arith. - intros l' H. destruct (Add_inv a l') as (l'', AD). { apply H; simpl; auto. } rewrite (Add_length AD). apply le_n_S. apply IH. now apply incl_Add_inv with a l'. Qed. Lemma NoDup_length_incl l l' : NoDup l -> length l' <= length l -> incl l l' -> incl l' l. Proof. intros N. revert l'. induction N as [|a l Hal N IH]. - destruct l'; easy. - intros l' E H x Hx. destruct (Add_inv a l') as (l'', AD). { apply H; simpl; auto. } rewrite (Add_in AD) in Hx. simpl in Hx. destruct Hx as [Hx|Hx]; [left; trivial|right]. revert x Hx. apply (IH l''); trivial. * apply le_S_n. now rewrite <- (Add_length AD). * now apply incl_Add_inv with a l'. Qed. End ReDun. (** NoDup and map *) (** NB: the reciprocal result holds only for injective functions, see FinFun.v *) Lemma NoDup_map_inv A B (f:A->B) l : NoDup (map f l) -> NoDup l. Proof. induction l; simpl; inversion_clear 1; subst; constructor; auto. intro H. now apply (in_map f) in H. Qed. (***********************************) (** ** Sequence of natural numbers *) (***********************************) Section NatSeq. (** [seq] computes the sequence of [len] contiguous integers that starts at [start]. For instance, [seq 2 3] is [2::3::4::nil]. *) Fixpoint seq (start len:nat) : list nat := match len with | 0 => nil | S len => start :: seq (S start) len end. Lemma seq_length : forall len start, length (seq start len) = len. Proof. induction len; simpl; auto. Qed. Lemma seq_nth : forall len start n d, n < len -> nth n (seq start len) d = start+n. Proof. induction len; intros. inversion H. simpl seq. destruct n; simpl. auto with arith. rewrite IHlen;simpl; auto with arith. Qed. Lemma seq_shift : forall len start, map S (seq start len) = seq (S start) len. Proof. induction len; simpl; auto. intros. rewrite IHlen. auto with arith. Qed. Lemma in_seq len start n : In n (seq start len) <-> start <= n < start+len. Proof. revert start. induction len; simpl; intros. - rewrite <- plus_n_O. split;[easy|]. intros (H,H'). apply (Lt.lt_irrefl _ (Lt.le_lt_trans _ _ _ H H')). - rewrite IHlen, <- plus_n_Sm; simpl; split. * intros [H|H]; subst; intuition auto with arith. * intros (H,H'). destruct (Lt.le_lt_or_eq _ _ H); intuition. Qed. Lemma seq_NoDup len start : NoDup (seq start len). Proof. revert start; induction len; simpl; constructor; trivial. rewrite in_seq. intros (H,_). apply (Lt.lt_irrefl _ H). Qed. End NatSeq. Section Exists_Forall. (** * Existential and universal predicates over lists *) Variable A:Type. Section One_predicate. Variable P:A->Prop. Inductive Exists : list A -> Prop := | Exists_cons_hd : forall x l, P x -> Exists (x::l) | Exists_cons_tl : forall x l, Exists l -> Exists (x::l). Hint Constructors Exists. Lemma Exists_exists (l:list A) : Exists l <-> (exists x, In x l /\ P x). Proof. split. - induction 1; firstorder. - induction l; firstorder; subst; auto. Qed. Lemma Exists_nil : Exists nil <-> False. Proof. split; inversion 1. Qed. Lemma Exists_cons x l: Exists (x::l) <-> P x \/ Exists l. Proof. split; inversion 1; auto. Qed. Lemma Exists_dec l: (forall x:A, {P x} + { ~ P x }) -> {Exists l} + {~ Exists l}. Proof. intro Pdec. induction l as [|a l' Hrec]. - right. now rewrite Exists_nil. - destruct Hrec as [Hl'|Hl']. * left. now apply Exists_cons_tl. * destruct (Pdec a) as [Ha|Ha]. + left. now apply Exists_cons_hd. + right. now inversion_clear 1. Qed. Inductive Forall : list A -> Prop := | Forall_nil : Forall nil | Forall_cons : forall x l, P x -> Forall l -> Forall (x::l). Hint Constructors Forall. Lemma Forall_forall (l:list A): Forall l <-> (forall x, In x l -> P x). Proof. split. - induction 1; firstorder; subst; auto. - induction l; firstorder. Qed. Lemma Forall_inv : forall (a:A) l, Forall (a :: l) -> P a. Proof. intros; inversion H; trivial. Qed. Lemma Forall_rect : forall (Q : list A -> Type), Q [] -> (forall b l, P b -> Q (b :: l)) -> forall l, Forall l -> Q l. Proof. intros Q H H'; induction l; intro; [|eapply H', Forall_inv]; eassumption. Qed. Lemma Forall_dec : (forall x:A, {P x} + { ~ P x }) -> forall l:list A, {Forall l} + {~ Forall l}. Proof. intro Pdec. induction l as [|a l' Hrec]. - left. apply Forall_nil. - destruct Hrec as [Hl'|Hl']. + destruct (Pdec a) as [Ha|Ha]. * left. now apply Forall_cons. * right. now inversion_clear 1. + right. now inversion_clear 1. Qed. End One_predicate. Lemma Forall_Exists_neg (P:A->Prop)(l:list A) : Forall (fun x => ~ P x) l <-> ~(Exists P l). Proof. rewrite Forall_forall, Exists_exists. firstorder. Qed. Lemma Exists_Forall_neg (P:A->Prop)(l:list A) : (forall x, P x \/ ~P x) -> Exists (fun x => ~ P x) l <-> ~(Forall P l). Proof. intro Dec. split. - rewrite Forall_forall, Exists_exists; firstorder. - intros NF. induction l as [|a l IH]. + destruct NF. constructor. + destruct (Dec a) as [Ha|Ha]. * apply Exists_cons_tl, IH. contradict NF. now constructor. * now apply Exists_cons_hd. Qed. Lemma Forall_Exists_dec (P:A->Prop) : (forall x:A, {P x} + { ~ P x }) -> forall l:list A, {Forall P l} + {Exists (fun x => ~ P x) l}. Proof. intros Pdec l. destruct (Forall_dec P Pdec l); [left|right]; trivial. apply Exists_Forall_neg; trivial. intro x. destruct (Pdec x); [now left|now right]. Qed. Lemma Forall_impl : forall (P Q : A -> Prop), (forall a, P a -> Q a) -> forall l, Forall P l -> Forall Q l. Proof. intros P Q H l. rewrite !Forall_forall. firstorder. Qed. End Exists_Forall. Hint Constructors Exists. Hint Constructors Forall. Section Forall2. (** [Forall2]: stating that elements of two lists are pairwise related. *) Variables A B : Type. Variable R : A -> B -> Prop. Inductive Forall2 : list A -> list B -> Prop := | Forall2_nil : Forall2 [] [] | Forall2_cons : forall x y l l', R x y -> Forall2 l l' -> Forall2 (x::l) (y::l'). Hint Constructors Forall2. Theorem Forall2_refl : Forall2 [] []. Proof. intros; apply Forall2_nil. Qed. Theorem Forall2_app_inv_l : forall l1 l2 l', Forall2 (l1 ++ l2) l' -> exists l1' l2', Forall2 l1 l1' /\ Forall2 l2 l2' /\ l' = l1' ++ l2'. Proof. induction l1; intros. exists [], l'; auto. simpl in H; inversion H; subst; clear H. apply IHl1 in H4 as (l1' & l2' & Hl1 & Hl2 & ->). exists (y::l1'), l2'; simpl; auto. Qed. Theorem Forall2_app_inv_r : forall l1' l2' l, Forall2 l (l1' ++ l2') -> exists l1 l2, Forall2 l1 l1' /\ Forall2 l2 l2' /\ l = l1 ++ l2. Proof. induction l1'; intros. exists [], l; auto. simpl in H; inversion H; subst; clear H. apply IHl1' in H4 as (l1 & l2 & Hl1 & Hl2 & ->). exists (x::l1), l2; simpl; auto. Qed. Theorem Forall2_app : forall l1 l2 l1' l2', Forall2 l1 l1' -> Forall2 l2 l2' -> Forall2 (l1 ++ l2) (l1' ++ l2'). Proof. intros. induction l1 in l1', H, H0 |- *; inversion H; subst; simpl; auto. Qed. End Forall2. Hint Constructors Forall2. Section ForallPairs. (** [ForallPairs] : specifies that a certain relation should always hold when inspecting all possible pairs of elements of a list. *) Variable A : Type. Variable R : A -> A -> Prop. Definition ForallPairs l := forall a b, In a l -> In b l -> R a b. (** [ForallOrdPairs] : we still check a relation over all pairs of elements of a list, but now the order of elements matters. *) Inductive ForallOrdPairs : list A -> Prop := | FOP_nil : ForallOrdPairs nil | FOP_cons : forall a l, Forall (R a) l -> ForallOrdPairs l -> ForallOrdPairs (a::l). Hint Constructors ForallOrdPairs. Lemma ForallOrdPairs_In : forall l, ForallOrdPairs l -> forall x y, In x l -> In y l -> x=y \/ R x y \/ R y x. Proof. induction 1. inversion 1. simpl; destruct 1; destruct 1; subst; auto. right; left. apply -> Forall_forall; eauto. right; right. apply -> Forall_forall; eauto. Qed. (** [ForallPairs] implies [ForallOrdPairs]. The reverse implication is true only when [R] is symmetric and reflexive. *) Lemma ForallPairs_ForallOrdPairs l: ForallPairs l -> ForallOrdPairs l. Proof. induction l; auto. intros H. constructor. apply <- Forall_forall. intros; apply H; simpl; auto. apply IHl. red; intros; apply H; simpl; auto. Qed. Lemma ForallOrdPairs_ForallPairs : (forall x, R x x) -> (forall x y, R x y -> R y x) -> forall l, ForallOrdPairs l -> ForallPairs l. Proof. intros Refl Sym l Hl x y Hx Hy. destruct (ForallOrdPairs_In Hl _ _ Hx Hy); subst; intuition. Qed. End ForallPairs. (** * Inversion of predicates over lists based on head symbol *) Ltac is_list_constr c := match c with | nil => idtac | (_::_) => idtac | _ => fail end. Ltac invlist f := match goal with | H:f ?l |- _ => is_list_constr l; inversion_clear H; invlist f | H:f _ ?l |- _ => is_list_constr l; inversion_clear H; invlist f | H:f _ _ ?l |- _ => is_list_constr l; inversion_clear H; invlist f | H:f _ _ _ ?l |- _ => is_list_constr l; inversion_clear H; invlist f | H:f _ _ _ _ ?l |- _ => is_list_constr l; inversion_clear H; invlist f | _ => idtac end. (** * Exporting hints and tactics *) Hint Rewrite rev_involutive (* rev (rev l) = l *) rev_unit (* rev (l ++ a :: nil) = a :: rev l *) map_nth (* nth n (map f l) (f d) = f (nth n l d) *) map_length (* length (map f l) = length l *) seq_length (* length (seq start len) = len *) app_length (* length (l ++ l') = length l + length l' *) rev_length (* length (rev l) = length l *) app_nil_r (* l ++ nil = l *) : list. Ltac simpl_list := autorewrite with list. Ltac ssimpl_list := autorewrite with list using simpl. (* begin hide *) (* Compatibility notations after the migration of [list] to [Datatypes] *) Notation list := list (only parsing). Notation list_rect := list_rect (only parsing). Notation list_rec := list_rec (only parsing). Notation list_ind := list_ind (only parsing). Notation nil := nil (only parsing). Notation cons := cons (only parsing). Notation length := length (only parsing). Notation app := app (only parsing). (* Compatibility Names *) Notation tail := tl (only parsing). Notation head := hd_error (only parsing). Notation head_nil := hd_error_nil (only parsing). Notation head_cons := hd_error_cons (only parsing). Notation ass_app := app_assoc (only parsing). Notation app_ass := app_assoc_reverse (only parsing). Notation In_split := in_split (only parsing). Notation In_rev := in_rev (only parsing). Notation In_dec := in_dec (only parsing). Notation distr_rev := rev_app_distr (only parsing). Notation rev_acc := rev_append (only parsing). Notation rev_acc_rev := rev_append_rev (only parsing). Notation AllS := Forall (only parsing). (* was formerly in TheoryList *) Hint Resolve app_nil_end : datatypes. (* end hide *) Section Repeat. Variable A : Type. Fixpoint repeat (x : A) (n: nat ) := match n with | O => [] | S k => x::(repeat x k) end. Theorem repeat_length x n: length (repeat x n) = n. Proof. induction n as [| k Hrec]; simpl; rewrite ?Hrec; reflexivity. Qed. Theorem repeat_spec n x y: In y (repeat x n) -> y=x. Proof. induction n as [|k Hrec]; simpl; destruct 1; auto. Qed. End Repeat. (* Unset Universe Polymorphism. *)

// -- (c) Copyright 2009 - 2011 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // Filename: trace_buffer.v // Description: Trace port buffer //----------------------------------------------------------------------------- // Structure: This section shows the hierarchical structure of // pss_wrapper. // // --processing_system7 // | // --trace_buffer //----------------------------------------------------------------------------- module processing_system7_v5_5_trace_buffer # ( parameter integer FIFO_SIZE = 128, parameter integer USE_TRACE_DATA_EDGE_DETECTOR = 0, parameter integer C_DELAY_CLKS = 12 ) ( input wire TRACE_CLK, input wire RST, input wire TRACE_VALID_IN, input wire [3:0] TRACE_ATID_IN, input wire [31:0] TRACE_DATA_IN, output wire TRACE_VALID_OUT, output wire [3:0] TRACE_ATID_OUT, output wire [31:0] TRACE_DATA_OUT ); //------------------------------------------------------------ // Architecture section //------------------------------------------------------------ // function called clogb2 that returns an integer which has the // value of the ceiling of the log base 2. function integer clogb2 (input integer bit_depth); integer i; integer temp_log; begin temp_log = 0; for(i=bit_depth; i > 0; i = i>>1) clogb2 = temp_log; temp_log=temp_log+1; end endfunction localparam DEPTH = clogb2(FIFO_SIZE-1); wire [31:0] reset_zeros; reg [31:0] trace_pedge; // write enable for FIFO reg [31:0] ti; reg [31:0] tom; reg [3:0] atid; reg [31:0] trace_fifo [FIFO_SIZE-1:0];//Memory reg [4:0] dly_ctr; reg [DEPTH-1:0] fifo_wp; reg [DEPTH-1:0] fifo_rp; reg fifo_re; wire fifo_empty; wire fifo_full; reg fifo_full_reg; assign reset_zeros = 32'h0; // Pipeline Stage for Traceport ATID ports always @(posedge TRACE_CLK) begin // process pedge_ti // rising clock edge if((RST == 1'b1)) begin atid <= reset_zeros; end else begin atid <= TRACE_ATID_IN; end end assign TRACE_ATID_OUT = atid; ///////////////////////////////////////////// // Generate FIFO data based on TRACE_VALID_IN ///////////////////////////////////////////// generate if (USE_TRACE_DATA_EDGE_DETECTOR == 0) begin : gen_no_data_edge_detector ///////////////////////////////////////////// // memory update process // Update memory when positive edge detected and FIFO not full always @(posedge TRACE_CLK) begin if (TRACE_VALID_IN == 1'b1 && fifo_full_reg != 1'b1) begin trace_fifo[fifo_wp] <= TRACE_DATA_IN; end end // fifo write pointer always @(posedge TRACE_CLK) begin // process if(RST == 1'b1) begin fifo_wp <= {DEPTH{1'b0}}; end else if(TRACE_VALID_IN ) begin if(fifo_wp == (FIFO_SIZE - 1)) begin if (fifo_empty) begin fifo_wp <= {DEPTH{1'b0}}; end end else begin fifo_wp <= fifo_wp + 1; end end end ///////////////////////////////////////////// // Generate FIFO data based on data edge ///////////////////////////////////////////// end else begin : gen_data_edge_detector ///////////////////////////////////////////// // purpose: check for pos edge on any trace input always @(posedge TRACE_CLK) begin // process pedge_ti // rising clock edge if((RST == 1'b1)) begin ti <= reset_zeros; trace_pedge <= reset_zeros; end else begin ti <= TRACE_DATA_IN; trace_pedge <= (~ti & TRACE_DATA_IN); //trace_pedge <= ((~ti ^ TRACE_DATA_IN)) & ~ti; // posedge only end end // memory update process // Update memory when positive edge detected and FIFO not full always @(posedge TRACE_CLK) begin if(|(trace_pedge) == 1'b1 && fifo_full_reg != 1'b1) begin trace_fifo[fifo_wp] <= trace_pedge; end end // fifo write pointer always @(posedge TRACE_CLK) begin // process if(RST == 1'b1) begin fifo_wp <= {DEPTH{1'b0}}; end else if(|(trace_pedge) == 1'b1) begin if(fifo_wp == (FIFO_SIZE - 1)) begin if (fifo_empty) begin fifo_wp <= {DEPTH{1'b0}}; end end else begin fifo_wp <= fifo_wp + 1; end end end end endgenerate always @(posedge TRACE_CLK) begin tom <= trace_fifo[fifo_rp] ; end // // fifo write pointer // always @(posedge TRACE_CLK) begin // // process // if(RST == 1'b1) begin // fifo_wp <= {DEPTH{1'b0}}; // end // else if(|(trace_pedge) == 1'b1) begin // if(fifo_wp == (FIFO_SIZE - 1)) begin // fifo_wp <= {DEPTH{1'b0}}; // end // else begin // fifo_wp <= fifo_wp + 1; // end // end // end // fifo read pointer update always @(posedge TRACE_CLK) begin if(RST == 1'b1) begin fifo_rp <= {DEPTH{1'b0}}; fifo_re <= 1'b0; end else if(fifo_empty != 1'b1 && dly_ctr == 5'b00000 && fifo_re == 1'b0) begin fifo_re <= 1'b1; if(fifo_rp == (FIFO_SIZE - 1)) begin fifo_rp <= {DEPTH{1'b0}}; end else begin fifo_rp <= fifo_rp + 1; end end else begin fifo_re <= 1'b0; end end // delay counter update always @(posedge TRACE_CLK) begin if(RST == 1'b1) begin dly_ctr <= 5'h0; end else if (fifo_re == 1'b1) begin dly_ctr <= C_DELAY_CLKS-1; end else if(dly_ctr != 5'h0) begin dly_ctr <= dly_ctr - 1; end end // fifo empty update assign fifo_empty = (fifo_wp == fifo_rp) ? 1'b1 : 1'b0; // fifo full update assign fifo_full = (fifo_wp == FIFO_SIZE-1)? 1'b1 : 1'b0; always @(posedge TRACE_CLK) begin if(RST == 1'b1) begin fifo_full_reg <= 1'b0; end else if (fifo_empty) begin fifo_full_reg <= 1'b0; end else begin fifo_full_reg <= fifo_full; end end // always @(posedge TRACE_CLK) begin // if(RST == 1'b1) begin // fifo_full_reg <= 1'b0; // end // else if ((fifo_wp == FIFO_SIZE-1) && (|(trace_pedge) == 1'b1)) begin // fifo_full_reg <= 1'b1; // end // else begin // fifo_full_reg <= 1'b0; // end // end // assign TRACE_DATA_OUT = tom; assign TRACE_VALID_OUT = fifo_re; endmodule

// (c) Copyright 1995-2015 Xilinx, Inc. All rights reserved. // // This file contains confidential and proprietary information // of Xilinx, Inc. and is protected under U.S. and // international copyright and other intellectual property // laws. // // DISCLAIMER // This disclaimer is not a license and does not grant any // rights to the materials distributed herewith. Except as // otherwise provided in a valid license issued to you by // Xilinx, and to the maximum extent permitted by applicable // law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // (2) Xilinx shall not be liable (whether in contract or tort, // including negligence, or under any other theory of // liability) for any loss or damage of any kind or nature // related to, arising under or in connection with these // materials, including for any direct, or any indirect, // special, incidental, or consequential loss or damage // (including loss of data, profits, goodwill, or any type of // loss or damage suffered as a result of any action brought // by a third party) even if such damage or loss was // reasonably foreseeable or Xilinx had been advised of the // possibility of the same. // // CRITICAL APPLICATIONS // Xilinx products are not designed or intended to be fail- // safe, or for use in any application requiring fail-safe // performance, such as life-support or safety devices or // systems, Class III medical devices, nuclear facilities, // applications related to the deployment of airbags, or any // other applications that could lead to death, personal // injury, or severe property or environmental damage // (individually and collectively, "Critical // Applications"). Customer assumes the sole risk and // liability of any use of Xilinx products in Critical // Applications, subject only to applicable laws and // regulations governing limitations on product liability. // // THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // PART OF THIS FILE AT ALL TIMES. // // DO NOT MODIFY THIS FILE. // IP VLNV: xilinx.com:ip:axi_crossbar:2.1 // IP Revision: 5 `timescale 1ns/1ps (* DowngradeIPIdentifiedWarnings = "yes" *) module tutorial_xbar_1 ( aclk, aresetn, s_axi_awid, s_axi_awaddr, s_axi_awlen, s_axi_awsize, s_axi_awburst, s_axi_awlock, s_axi_awcache, s_axi_awprot, s_axi_awqos, s_axi_awvalid, s_axi_awready, s_axi_wdata, s_axi_wstrb, s_axi_wlast, s_axi_wvalid, s_axi_wready, s_axi_bid, s_axi_bresp, s_axi_bvalid, s_axi_bready, s_axi_arid, s_axi_araddr, s_axi_arlen, s_axi_arsize, s_axi_arburst, s_axi_arlock, s_axi_arcache, s_axi_arprot, s_axi_arqos, s_axi_arvalid, s_axi_arready, s_axi_rid, s_axi_rdata, s_axi_rresp, s_axi_rlast, s_axi_rvalid, s_axi_rready, m_axi_awid, m_axi_awaddr, m_axi_awlen, m_axi_awsize, m_axi_awburst, m_axi_awlock, m_axi_awcache, m_axi_awprot, m_axi_awregion, m_axi_awqos, m_axi_awvalid, m_axi_awready, m_axi_wdata, m_axi_wstrb, m_axi_wlast, m_axi_wvalid, m_axi_wready, m_axi_bid, m_axi_bresp, m_axi_bvalid, m_axi_bready, m_axi_arid, m_axi_araddr, m_axi_arlen, m_axi_arsize, m_axi_arburst, m_axi_arlock, m_axi_arcache, m_axi_arprot, m_axi_arregion, m_axi_arqos, m_axi_arvalid, m_axi_arready, m_axi_rid, m_axi_rdata, m_axi_rresp, m_axi_rlast, m_axi_rvalid, m_axi_rready ); (* X_INTERFACE_INFO = "xilinx.com:signal:clock:1.0 CLKIF CLK" *) input wire aclk; (* X_INTERFACE_INFO = "xilinx.com:signal:reset:1.0 RSTIF RST" *) input wire aresetn; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI AWID [0:0] [1:1]" *) input wire [1 : 0] s_axi_awid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWADDR [31:0] [31:0], xilinx.com:interface:aximm:1.0 S01_AXI AWADDR [31:0] [63:32]" *) input wire [63 : 0] s_axi_awaddr; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWLEN [7:0] [7:0], xilinx.com:interface:aximm:1.0 S01_AXI AWLEN [7:0] [15:8]" *) input wire [15 : 0] s_axi_awlen; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWSIZE [2:0] [2:0], xilinx.com:interface:aximm:1.0 S01_AXI AWSIZE [2:0] [5:3]" *) input wire [5 : 0] s_axi_awsize; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWBURST [1:0] [1:0], xilinx.com:interface:aximm:1.0 S01_AXI AWBURST [1:0] [3:2]" *) input wire [3 : 0] s_axi_awburst; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWLOCK [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI AWLOCK [0:0] [1:1]" *) input wire [1 : 0] s_axi_awlock; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWCACHE [3:0] [3:0], xilinx.com:interface:aximm:1.0 S01_AXI AWCACHE [3:0] [7:4]" *) input wire [7 : 0] s_axi_awcache; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWPROT [2:0] [2:0], xilinx.com:interface:aximm:1.0 S01_AXI AWPROT [2:0] [5:3]" *) input wire [5 : 0] s_axi_awprot; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWQOS [3:0] [3:0], xilinx.com:interface:aximm:1.0 S01_AXI AWQOS [3:0] [7:4]" *) input wire [7 : 0] s_axi_awqos; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWVALID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI AWVALID [0:0] [1:1]" *) input wire [1 : 0] s_axi_awvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI AWREADY [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI AWREADY [0:0] [1:1]" *) output wire [1 : 0] s_axi_awready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI WDATA [63:0] [63:0], xilinx.com:interface:aximm:1.0 S01_AXI WDATA [63:0] [127:64]" *) input wire [127 : 0] s_axi_wdata; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI WSTRB [7:0] [7:0], xilinx.com:interface:aximm:1.0 S01_AXI WSTRB [7:0] [15:8]" *) input wire [15 : 0] s_axi_wstrb; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI WLAST [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI WLAST [0:0] [1:1]" *) input wire [1 : 0] s_axi_wlast; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI WVALID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI WVALID [0:0] [1:1]" *) input wire [1 : 0] s_axi_wvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI WREADY [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI WREADY [0:0] [1:1]" *) output wire [1 : 0] s_axi_wready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI BID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI BID [0:0] [1:1]" *) output wire [1 : 0] s_axi_bid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI BRESP [1:0] [1:0], xilinx.com:interface:aximm:1.0 S01_AXI BRESP [1:0] [3:2]" *) output wire [3 : 0] s_axi_bresp; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI BVALID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI BVALID [0:0] [1:1]" *) output wire [1 : 0] s_axi_bvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI BREADY [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI BREADY [0:0] [1:1]" *) input wire [1 : 0] s_axi_bready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI ARID [0:0] [1:1]" *) input wire [1 : 0] s_axi_arid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARADDR [31:0] [31:0], xilinx.com:interface:aximm:1.0 S01_AXI ARADDR [31:0] [63:32]" *) input wire [63 : 0] s_axi_araddr; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARLEN [7:0] [7:0], xilinx.com:interface:aximm:1.0 S01_AXI ARLEN [7:0] [15:8]" *) input wire [15 : 0] s_axi_arlen; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARSIZE [2:0] [2:0], xilinx.com:interface:aximm:1.0 S01_AXI ARSIZE [2:0] [5:3]" *) input wire [5 : 0] s_axi_arsize; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARBURST [1:0] [1:0], xilinx.com:interface:aximm:1.0 S01_AXI ARBURST [1:0] [3:2]" *) input wire [3 : 0] s_axi_arburst; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARLOCK [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI ARLOCK [0:0] [1:1]" *) input wire [1 : 0] s_axi_arlock; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARCACHE [3:0] [3:0], xilinx.com:interface:aximm:1.0 S01_AXI ARCACHE [3:0] [7:4]" *) input wire [7 : 0] s_axi_arcache; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARPROT [2:0] [2:0], xilinx.com:interface:aximm:1.0 S01_AXI ARPROT [2:0] [5:3]" *) input wire [5 : 0] s_axi_arprot; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARQOS [3:0] [3:0], xilinx.com:interface:aximm:1.0 S01_AXI ARQOS [3:0] [7:4]" *) input wire [7 : 0] s_axi_arqos; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARVALID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI ARVALID [0:0] [1:1]" *) input wire [1 : 0] s_axi_arvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI ARREADY [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI ARREADY [0:0] [1:1]" *) output wire [1 : 0] s_axi_arready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI RID [0:0] [1:1]" *) output wire [1 : 0] s_axi_rid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RDATA [63:0] [63:0], xilinx.com:interface:aximm:1.0 S01_AXI RDATA [63:0] [127:64]" *) output wire [127 : 0] s_axi_rdata; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RRESP [1:0] [1:0], xilinx.com:interface:aximm:1.0 S01_AXI RRESP [1:0] [3:2]" *) output wire [3 : 0] s_axi_rresp; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RLAST [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI RLAST [0:0] [1:1]" *) output wire [1 : 0] s_axi_rlast; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RVALID [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI RVALID [0:0] [1:1]" *) output wire [1 : 0] s_axi_rvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S00_AXI RREADY [0:0] [0:0], xilinx.com:interface:aximm:1.0 S01_AXI RREADY [0:0] [1:1]" *) input wire [1 : 0] s_axi_rready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWID" *) output wire [0 : 0] m_axi_awid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWADDR" *) output wire [31 : 0] m_axi_awaddr; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWLEN" *) output wire [7 : 0] m_axi_awlen; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWSIZE" *) output wire [2 : 0] m_axi_awsize; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWBURST" *) output wire [1 : 0] m_axi_awburst; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWLOCK" *) output wire [0 : 0] m_axi_awlock; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWCACHE" *) output wire [3 : 0] m_axi_awcache; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWPROT" *) output wire [2 : 0] m_axi_awprot; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWREGION" *) output wire [3 : 0] m_axi_awregion; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWQOS" *) output wire [3 : 0] m_axi_awqos; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWVALID" *) output wire [0 : 0] m_axi_awvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI AWREADY" *) input wire [0 : 0] m_axi_awready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI WDATA" *) output wire [63 : 0] m_axi_wdata; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI WSTRB" *) output wire [7 : 0] m_axi_wstrb; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI WLAST" *) output wire [0 : 0] m_axi_wlast; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI WVALID" *) output wire [0 : 0] m_axi_wvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI WREADY" *) input wire [0 : 0] m_axi_wready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI BID" *) input wire [0 : 0] m_axi_bid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI BRESP" *) input wire [1 : 0] m_axi_bresp; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI BVALID" *) input wire [0 : 0] m_axi_bvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI BREADY" *) output wire [0 : 0] m_axi_bready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARID" *) output wire [0 : 0] m_axi_arid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARADDR" *) output wire [31 : 0] m_axi_araddr; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARLEN" *) output wire [7 : 0] m_axi_arlen; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARSIZE" *) output wire [2 : 0] m_axi_arsize; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARBURST" *) output wire [1 : 0] m_axi_arburst; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARLOCK" *) output wire [0 : 0] m_axi_arlock; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARCACHE" *) output wire [3 : 0] m_axi_arcache; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARPROT" *) output wire [2 : 0] m_axi_arprot; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARREGION" *) output wire [3 : 0] m_axi_arregion; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARQOS" *) output wire [3 : 0] m_axi_arqos; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARVALID" *) output wire [0 : 0] m_axi_arvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI ARREADY" *) input wire [0 : 0] m_axi_arready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RID" *) input wire [0 : 0] m_axi_rid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RDATA" *) input wire [63 : 0] m_axi_rdata; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RRESP" *) input wire [1 : 0] m_axi_rresp; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RLAST" *) input wire [0 : 0] m_axi_rlast; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RVALID" *) input wire [0 : 0] m_axi_rvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M00_AXI RREADY" *) output wire [0 : 0] m_axi_rready; axi_crossbar_v2_1_axi_crossbar #( .C_FAMILY("zynq"), .C_NUM_SLAVE_SLOTS(2), .C_NUM_MASTER_SLOTS(1), .C_AXI_ID_WIDTH(1), .C_AXI_ADDR_WIDTH(32), .C_AXI_DATA_WIDTH(64), .C_AXI_PROTOCOL(0), .C_NUM_ADDR_RANGES(1), .C_M_AXI_BASE_ADDR(64'H0000000000000000), .C_M_AXI_ADDR_WIDTH(32'H0000001d), .C_S_AXI_BASE_ID(64'H0000000100000000), .C_S_AXI_THREAD_ID_WIDTH(64'H0000000100000000), .C_AXI_SUPPORTS_USER_SIGNALS(0), .C_AXI_AWUSER_WIDTH(1), .C_AXI_ARUSER_WIDTH(1), .C_AXI_WUSER_WIDTH(1), .C_AXI_RUSER_WIDTH(1), .C_AXI_BUSER_WIDTH(1), .C_M_AXI_WRITE_CONNECTIVITY(32'H00000002), .C_M_AXI_READ_CONNECTIVITY(32'H00000003), .C_R_REGISTER(0), .C_S_AXI_SINGLE_THREAD(64'H0000000000000000), .C_S_AXI_WRITE_ACCEPTANCE(64'H0000000200000004), .C_S_AXI_READ_ACCEPTANCE(64'H0000000200000002), .C_M_AXI_WRITE_ISSUING(32'H00000008), .C_M_AXI_READ_ISSUING(32'H00000008), .C_S_AXI_ARB_PRIORITY(64'H0000000000000000), .C_M_AXI_SECURE(32'H00000000), .C_CONNECTIVITY_MODE(1) ) inst ( .aclk(aclk), .aresetn(aresetn), .s_axi_awid(s_axi_awid), .s_axi_awaddr(s_axi_awaddr), .s_axi_awlen(s_axi_awlen), .s_axi_awsize(s_axi_awsize), .s_axi_awburst(s_axi_awburst), .s_axi_awlock(s_axi_awlock), .s_axi_awcache(s_axi_awcache), .s_axi_awprot(s_axi_awprot), .s_axi_awqos(s_axi_awqos), .s_axi_awuser(2'H0), .s_axi_awvalid(s_axi_awvalid), .s_axi_awready(s_axi_awready), .s_axi_wid(2'H0), .s_axi_wdata(s_axi_wdata), .s_axi_wstrb(s_axi_wstrb), .s_axi_wlast(s_axi_wlast), .s_axi_wuser(2'H0), .s_axi_wvalid(s_axi_wvalid), .s_axi_wready(s_axi_wready), .s_axi_bid(s_axi_bid), .s_axi_bresp(s_axi_bresp), .s_axi_buser(), .s_axi_bvalid(s_axi_bvalid), .s_axi_bready(s_axi_bready), .s_axi_arid(s_axi_arid), .s_axi_araddr(s_axi_araddr), .s_axi_arlen(s_axi_arlen), .s_axi_arsize(s_axi_arsize), .s_axi_arburst(s_axi_arburst), .s_axi_arlock(s_axi_arlock), .s_axi_arcache(s_axi_arcache), .s_axi_arprot(s_axi_arprot), .s_axi_arqos(s_axi_arqos), .s_axi_aruser(2'H0), .s_axi_arvalid(s_axi_arvalid), .s_axi_arready(s_axi_arready), .s_axi_rid(s_axi_rid), .s_axi_rdata(s_axi_rdata), .s_axi_rresp(s_axi_rresp), .s_axi_rlast(s_axi_rlast), .s_axi_ruser(), .s_axi_rvalid(s_axi_rvalid), .s_axi_rready(s_axi_rready), .m_axi_awid(m_axi_awid), .m_axi_awaddr(m_axi_awaddr), .m_axi_awlen(m_axi_awlen), .m_axi_awsize(m_axi_awsize), .m_axi_awburst(m_axi_awburst), .m_axi_awlock(m_axi_awlock), .m_axi_awcache(m_axi_awcache), .m_axi_awprot(m_axi_awprot), .m_axi_awregion(m_axi_awregion), .m_axi_awqos(m_axi_awqos), .m_axi_awuser(), .m_axi_awvalid(m_axi_awvalid), .m_axi_awready(m_axi_awready), .m_axi_wid(), .m_axi_wdata(m_axi_wdata), .m_axi_wstrb(m_axi_wstrb), .m_axi_wlast(m_axi_wlast), .m_axi_wuser(), .m_axi_wvalid(m_axi_wvalid), .m_axi_wready(m_axi_wready), .m_axi_bid(m_axi_bid), .m_axi_bresp(m_axi_bresp), .m_axi_buser(1'H0), .m_axi_bvalid(m_axi_bvalid), .m_axi_bready(m_axi_bready), .m_axi_arid(m_axi_arid), .m_axi_araddr(m_axi_araddr), .m_axi_arlen(m_axi_arlen), .m_axi_arsize(m_axi_arsize), .m_axi_arburst(m_axi_arburst), .m_axi_arlock(m_axi_arlock), .m_axi_arcache(m_axi_arcache), .m_axi_arprot(m_axi_arprot), .m_axi_arregion(m_axi_arregion), .m_axi_arqos(m_axi_arqos), .m_axi_aruser(), .m_axi_arvalid(m_axi_arvalid), .m_axi_arready(m_axi_arready), .m_axi_rid(m_axi_rid), .m_axi_rdata(m_axi_rdata), .m_axi_rresp(m_axi_rresp), .m_axi_rlast(m_axi_rlast), .m_axi_ruser(1'H0), .m_axi_rvalid(m_axi_rvalid), .m_axi_rready(m_axi_rready) ); endmodule

//---------------------------------------------------------------------- // my6502mc: my6502 mpu microcode decoder //---------------------------------------------------------------------- module my6502mc ( input [7:0] opcode, // opcode input [2:0] cyc_cnt, // execution cycle count output reg [55:0] opc_inst, // opcode decode by instruction output reg [7:0] opc_flag, // modified flag indicator output opc_src_a_ar, // alu source a indicator (a reg) output opc_src_a_xr, // alu source a indicator (x reg) output opc_src_a_yr, // alu source a indicator (y reg) output opc_src_a_sp, // alu source a indicator (sp reg) output opc_src_a_ps, // alu source a indicator (ps reg) output opc_src_a_din, // alu source a indicator (din) output opc_src_b_din, // alu source b indicator (din) output opc_dst_ar, // alu destination indicator (a reg) output opc_dst_xr, // alu destination indicator (x reg) output opc_dst_yr, // alu destination indicator (y reg) output opc_dst_sp, // alu destination indicator (sp reg) output opc_dst_ps, // alu destination indicator (ps reg) output opc_dst_dout, // alu destination indicator (dout) output mc_fetch_en, // opcode fetch enable output mc_din_le, // data input latch enable output mc_pc_chg, // change program counter value output mc_addr_pc, // output program counter value output mc_addr_zp, // output zero page address output mc_addr_abs, // output absolute address output mc_addr_sp, // output stack address output mc_addr_vl, // output interrupt vector(low) address output mc_addr_vh, // output interrupt vector(high) address output mc_dout_pch, // output pc value(high) to data bus output mc_dout_pcl, // output pc value(low) to data bus output mc_oe_next, // set output enable in next cycle output mc_alu_inst_op, // use alu for instruction operation output mc_alu_add_xr, // add x to input data output mc_alu_add_yr, // add y to input data output mc_alu_add_z, // add 0 to input data output mc_alu_inc_din, // increment input data output mc_alu_inc_reg, // increment saved data output mc_alu_inc_sp, // increment stack pointer value output mc_alu_dec_sp, // decrement stack pointer value output mc_brk_if_set, // interrupt i flag setting timing output mc_br_chk // branch condition check timing ); //---------------------------------------------------------------------- // internal regs and nets //---------------------------------------------------------------------- // number of decoded instructions parameter NUM_OF_INST = 56; // internal nets reg [12:0] src_dst; reg [15:0] mc_exec; //---------------------------------------------------------------------- // instruction bit position //---------------------------------------------------------------------- parameter I_ADC = 0; parameter I_AND = 1; parameter I_ASL = 2; parameter I_BCC = 3; parameter I_BCS = 4; parameter I_BEQ = 5; parameter I_BIT = 6; parameter I_BMI = 7; parameter I_BNE = 8; parameter I_BPL = 9; parameter I_BRK = 10; parameter I_BVC = 11; parameter I_BVS = 12; parameter I_CLC = 13; parameter I_CLD = 14; parameter I_CLI = 15; parameter I_CLV = 16; parameter I_CMP = 17; parameter I_CPX = 18; parameter I_CPY = 19; parameter I_DEC = 20; parameter I_DEX = 21; parameter I_DEY = 22; parameter I_EOR = 23; parameter I_INC = 24; parameter I_INX = 25; parameter I_INY = 26; parameter I_JMP = 27; parameter I_JSR = 28; parameter I_LDA = 29; parameter I_LDX = 30; parameter I_LDY = 31; parameter I_LSR = 32; parameter I_NOP = 33; parameter I_ORA = 34; parameter I_PHA = 35; parameter I_PHP = 36; parameter I_PLA = 37; parameter I_PLP = 38; parameter I_ROL = 39; parameter I_ROR = 40; parameter I_RTI = 41; parameter I_RTS = 42; parameter I_SBC = 43; parameter I_SEC = 44; parameter I_SED = 45; parameter I_SEI = 46; parameter I_STA = 47; parameter I_STX = 48; parameter I_STY = 49; parameter I_TAX = 50; parameter I_TAY = 51; parameter I_TSX = 52; parameter I_TXA = 53; parameter I_TXS = 54; parameter I_TYA = 55; //---------------------------------------------------------------------- // opcodes //---------------------------------------------------------------------- parameter ADC_IMM = 8'h69; parameter ADC_ZP = 8'h65; parameter ADC_ZX = 8'h75; parameter ADC_ABS = 8'h6D; parameter ADC_AX = 8'h7D; parameter ADC_AY = 8'h79; parameter ADC_IX = 8'h61; parameter ADC_IY = 8'h71; parameter AND_IMM = 8'h29; parameter AND_ZP = 8'h25; parameter AND_ZX = 8'h35; parameter AND_ABS = 8'h2D; parameter AND_AX = 8'h3D; parameter AND_AY = 8'h39; parameter AND_IX = 8'h21; parameter AND_IY = 8'h31; parameter ASL_ACC = 8'h0A; parameter ASL_ZP = 8'h06; parameter ASL_ZX = 8'h16; parameter ASL_ABS = 8'h0E; parameter ASL_AX = 8'h1E; parameter BCC = 8'h90; parameter BCS = 8'hB0; parameter BEQ = 8'hF0; parameter BIT_ZP = 8'h24; parameter BIT_ABS = 8'h2C; parameter BMI = 8'h30; parameter BNE = 8'hD0; parameter BPL = 8'h10; parameter BRK = 8'h00; parameter BVC = 8'h50; parameter BVS = 8'h70; parameter CLC = 8'h18; parameter CLD = 8'hD8; parameter CLI = 8'h58; parameter CLV = 8'hB8; parameter CMP_IMM = 8'hC9; parameter CMP_ZP = 8'hC5; parameter CMP_ZX = 8'hD5; parameter CMP_ABS = 8'hCD; parameter CMP_AX = 8'hDD; parameter CMP_AY = 8'hD9; parameter CMP_IX = 8'hC1; parameter CMP_IY = 8'hD1; parameter CPX_IMM = 8'hE0; parameter CPX_ZP = 8'hE4; parameter CPX_ABS = 8'hEC; parameter CPY_IMM = 8'hC0; parameter CPY_ZP = 8'hC4; parameter CPY_ABS = 8'hCC; parameter DEC_ZP = 8'hC6; parameter DEC_ZX = 8'hD6; parameter DEC_ABS = 8'hCE; parameter DEC_AX = 8'hDE; parameter DEX = 8'hCA; parameter DEY = 8'h88; parameter EOR_IMM = 8'h49; parameter EOR_ZP = 8'h45; parameter EOR_ZX = 8'h55; parameter EOR_ABS = 8'h4D; parameter EOR_AX = 8'h5D; parameter EOR_AY = 8'h59; parameter EOR_IX = 8'h41; parameter EOR_IY = 8'h51; parameter INC_ZP = 8'hE6; parameter INC_ZX = 8'hF6; parameter INC_ABS = 8'hEE; parameter INC_AX = 8'hFE; parameter INX = 8'hE8; parameter INY = 8'hC8; parameter JMP_ABS = 8'h4C; parameter JMP_IND = 8'h6C; parameter JSR_ABS = 8'h20; parameter LDA_IMM = 8'hA9; parameter LDA_ZP = 8'hA5; parameter LDA_ZX = 8'hB5; parameter LDA_ABS = 8'hAD; parameter LDA_AX = 8'hBD; parameter LDA_AY = 8'hB9; parameter LDA_IX = 8'hA1; parameter LDA_IY = 8'hB1; parameter LDX_IMM = 8'hA2; parameter LDX_ZP = 8'hA6; parameter LDX_ZY = 8'hB6; parameter LDX_ABS = 8'hAE; parameter LDX_AY = 8'hBE; parameter LDY_IMM = 8'hA0; parameter LDY_ZP = 8'hA4; parameter LDY_ZX = 8'hB4; parameter LDY_ABS = 8'hAC; parameter LDY_AX = 8'hBC; parameter LSR_ACC = 8'h4A; parameter LSR_ZP = 8'h46; parameter LSR_ZX = 8'h56; parameter LSR_ABS = 8'h4E; parameter LSR_AX = 8'h5E; parameter NOP = 8'hEA; parameter ORA_IMM = 8'h09; parameter ORA_ZP = 8'h05; parameter ORA_ZX = 8'h15; parameter ORA_ABS = 8'h0D; parameter ORA_AX = 8'h1D; parameter ORA_AY = 8'h19; parameter ORA_IX = 8'h01; parameter ORA_IY = 8'h11; parameter PHA = 8'h48; parameter PHP = 8'h08; parameter PLA = 8'h68; parameter PLP = 8'h28; parameter ROL_ACC = 8'h2A; parameter ROL_ZP = 8'h26; parameter ROL_ZX = 8'h36; parameter ROL_ABS = 8'h2E; parameter ROL_AX = 8'h3E; parameter ROR_ACC = 8'h6A; parameter ROR_ZP = 8'h66; parameter ROR_ZX = 8'h76; parameter ROR_ABS = 8'h6E; parameter ROR_AX = 8'h7E; parameter RTI = 8'h40; parameter RTS = 8'h60; parameter SBC_IMM = 8'hE9; parameter SBC_ZP = 8'hE5; parameter SBC_ZX = 8'hF5; parameter SBC_ABS = 8'hED; parameter SBC_AX = 8'hFD; parameter SBC_AY = 8'hF9; parameter SBC_IX = 8'hE1; parameter SBC_IY = 8'hF1; parameter SEC = 8'h38; parameter SED = 8'hF8; parameter SEI = 8'h78; parameter STA_ZP = 8'h85; parameter STA_ZX = 8'h95; parameter STA_ABS = 8'h8D; parameter STA_AX = 8'h9D; parameter STA_AY = 8'h99; parameter STA_IX = 8'h81; parameter STA_IY = 8'h91; parameter STX_ZP = 8'h86; parameter STX_ZY = 8'h96; parameter STX_ABS = 8'h8E; parameter STY_ZP = 8'h84; parameter STY_ZX = 8'h94; parameter STY_ABS = 8'h8C; parameter TAX = 8'hAA; parameter TAY = 8'hA8; parameter TSX = 8'hBA; parameter TXA = 8'h8A; parameter TXS = 8'h9A; parameter TYA = 8'h98; //---------------------------------------------------------------------- // opcode decode by instruction //---------------------------------------------------------------------- always @* begin opc_inst = {NUM_OF_INST{1'b0}}; case (opcode) ADC_IMM : opc_inst[I_ADC] = 1'b1; ADC_ZP : opc_inst[I_ADC] = 1'b1; ADC_ZX : opc_inst[I_ADC] = 1'b1; ADC_ABS : opc_inst[I_ADC] = 1'b1; ADC_AX : opc_inst[I_ADC] = 1'b1; ADC_AY : opc_inst[I_ADC] = 1'b1; ADC_IX : opc_inst[I_ADC] = 1'b1; ADC_IY : opc_inst[I_ADC] = 1'b1; AND_IMM : opc_inst[I_AND] = 1'b1; AND_ZP : opc_inst[I_AND] = 1'b1; AND_ZX : opc_inst[I_AND] = 1'b1; AND_ABS : opc_inst[I_AND] = 1'b1; AND_AX : opc_inst[I_AND] = 1'b1; AND_AY : opc_inst[I_AND] = 1'b1; AND_IX : opc_inst[I_AND] = 1'b1; AND_IY : opc_inst[I_AND] = 1'b1; ASL_ACC : opc_inst[I_ASL] = 1'b1; ASL_ZP : opc_inst[I_ASL] = 1'b1; ASL_ZX : opc_inst[I_ASL] = 1'b1; ASL_ABS : opc_inst[I_ASL] = 1'b1; ASL_AX : opc_inst[I_ASL] = 1'b1; BCC : opc_inst[I_BCC] = 1'b1; BCS : opc_inst[I_BCS] = 1'b1; BEQ : opc_inst[I_BEQ] = 1'b1; BIT_ZP : opc_inst[I_BIT] = 1'b1; BIT_ABS : opc_inst[I_BIT] = 1'b1; BMI : opc_inst[I_BMI] = 1'b1; BNE : opc_inst[I_BNE] = 1'b1; BPL : opc_inst[I_BPL] = 1'b1; BRK : opc_inst[I_BRK] = 1'b1; BVC : opc_inst[I_BVC] = 1'b1; BVS : opc_inst[I_BVS] = 1'b1; CLC : opc_inst[I_CLC] = 1'b1; CLD : opc_inst[I_CLD] = 1'b1; CLI : opc_inst[I_CLI] = 1'b1; CLV : opc_inst[I_CLV] = 1'b1; CMP_IMM : opc_inst[I_CMP] = 1'b1; CMP_ZP : opc_inst[I_CMP] = 1'b1; CMP_ZX : opc_inst[I_CMP] = 1'b1; CMP_ABS : opc_inst[I_CMP] = 1'b1; CMP_AX : opc_inst[I_CMP] = 1'b1; CMP_AY : opc_inst[I_CMP] = 1'b1; CMP_IX : opc_inst[I_CMP] = 1'b1; CMP_IY : opc_inst[I_CMP] = 1'b1; CPX_IMM : opc_inst[I_CPX] = 1'b1; CPX_ZP : opc_inst[I_CPX] = 1'b1; CPX_ABS : opc_inst[I_CPX] = 1'b1; CPY_IMM : opc_inst[I_CPY] = 1'b1; CPY_ZP : opc_inst[I_CPY] = 1'b1; CPY_ABS : opc_inst[I_CPY] = 1'b1; DEC_ZP : opc_inst[I_DEC] = 1'b1; DEC_ZX : opc_inst[I_DEC] = 1'b1; DEC_ABS : opc_inst[I_DEC] = 1'b1; DEC_AX : opc_inst[I_DEC] = 1'b1; DEX : opc_inst[I_DEX] = 1'b1; DEY : opc_inst[I_DEY] = 1'b1; EOR_IMM : opc_inst[I_EOR] = 1'b1; EOR_ZP : opc_inst[I_EOR] = 1'b1; EOR_ZX : opc_inst[I_EOR] = 1'b1; EOR_ABS : opc_inst[I_EOR] = 1'b1; EOR_AX : opc_inst[I_EOR] = 1'b1; EOR_AY : opc_inst[I_EOR] = 1'b1; EOR_IX : opc_inst[I_EOR] = 1'b1; EOR_IY : opc_inst[I_EOR] = 1'b1; INC_ZP : opc_inst[I_INC] = 1'b1; INC_ZX : opc_inst[I_INC] = 1'b1; INC_ABS : opc_inst[I_INC] = 1'b1; INC_AX : opc_inst[I_INC] = 1'b1; INX : opc_inst[I_INX] = 1'b1; INY : opc_inst[I_INY] = 1'b1; JMP_ABS : opc_inst[I_JMP] = 1'b1; JMP_IND : opc_inst[I_JMP] = 1'b1; JSR_ABS : opc_inst[I_JSR] = 1'b1; LDA_IMM : opc_inst[I_LDA] = 1'b1; LDA_ZP : opc_inst[I_LDA] = 1'b1; LDA_ZX : opc_inst[I_LDA] = 1'b1; LDA_ABS : opc_inst[I_LDA] = 1'b1; LDA_AX : opc_inst[I_LDA] = 1'b1; LDA_AY : opc_inst[I_LDA] = 1'b1; LDA_IX : opc_inst[I_LDA] = 1'b1; LDA_IY : opc_inst[I_LDA] = 1'b1; LDX_IMM : opc_inst[I_LDX] = 1'b1; LDX_ZP : opc_inst[I_LDX] = 1'b1; LDX_ZY : opc_inst[I_LDX] = 1'b1; LDX_ABS : opc_inst[I_LDX] = 1'b1; LDX_AY : opc_inst[I_LDX] = 1'b1; LDY_IMM : opc_inst[I_LDY] = 1'b1; LDY_ZP : opc_inst[I_LDY] = 1'b1; LDY_ZX : opc_inst[I_LDY] = 1'b1; LDY_ABS : opc_inst[I_LDY] = 1'b1; LDY_AX : opc_inst[I_LDY] = 1'b1; LSR_ACC : opc_inst[I_LSR] = 1'b1; LSR_ZP : opc_inst[I_LSR] = 1'b1; LSR_ZX : opc_inst[I_LSR] = 1'b1; LSR_ABS : opc_inst[I_LSR] = 1'b1; LSR_AX : opc_inst[I_LSR] = 1'b1; NOP : opc_inst[I_NOP] = 1'b1; ORA_IMM : opc_inst[I_ORA] = 1'b1; ORA_ZP : opc_inst[I_ORA] = 1'b1; ORA_ZX : opc_inst[I_ORA] = 1'b1; ORA_ABS : opc_inst[I_ORA] = 1'b1; ORA_AX : opc_inst[I_ORA] = 1'b1; ORA_AY : opc_inst[I_ORA] = 1'b1; ORA_IX : opc_inst[I_ORA] = 1'b1; ORA_IY : opc_inst[I_ORA] = 1'b1; PHA : opc_inst[I_PHA] = 1'b1; PHP : opc_inst[I_PHP] = 1'b1; PLA : opc_inst[I_PLA] = 1'b1; PLP : opc_inst[I_PLP] = 1'b1; ROL_ACC : opc_inst[I_ROL] = 1'b1; ROL_ZP : opc_inst[I_ROL] = 1'b1; ROL_ZX : opc_inst[I_ROL] = 1'b1; ROL_ABS : opc_inst[I_ROL] = 1'b1; ROL_AX : opc_inst[I_ROL] = 1'b1; ROR_ACC : opc_inst[I_ROR] = 1'b1; ROR_ZP : opc_inst[I_ROR] = 1'b1; ROR_ZX : opc_inst[I_ROR] = 1'b1; ROR_ABS : opc_inst[I_ROR] = 1'b1; ROR_AX : opc_inst[I_ROR] = 1'b1; RTI : opc_inst[I_RTI] = 1'b1; RTS : opc_inst[I_RTS] = 1'b1; SBC_IMM : opc_inst[I_SBC] = 1'b1; SBC_ZP : opc_inst[I_SBC] = 1'b1; SBC_ZX : opc_inst[I_SBC] = 1'b1; SBC_ABS : opc_inst[I_SBC] = 1'b1; SBC_AX : opc_inst[I_SBC] = 1'b1; SBC_AY : opc_inst[I_SBC] = 1'b1; SBC_IX : opc_inst[I_SBC] = 1'b1; SBC_IY : opc_inst[I_SBC] = 1'b1; SEC : opc_inst[I_SEC] = 1'b1; SED : opc_inst[I_SED] = 1'b1; SEI : opc_inst[I_SEI] = 1'b1; STA_ZP : opc_inst[I_STA] = 1'b1; STA_ZX : opc_inst[I_STA] = 1'b1; STA_ABS : opc_inst[I_STA] = 1'b1; STA_AX : opc_inst[I_STA] = 1'b1; STA_AY : opc_inst[I_STA] = 1'b1; STA_IX : opc_inst[I_STA] = 1'b1; STA_IY : opc_inst[I_STA] = 1'b1; STX_ZP : opc_inst[I_STX] = 1'b1; STX_ZY : opc_inst[I_STX] = 1'b1; STX_ABS : opc_inst[I_STX] = 1'b1; STY_ZP : opc_inst[I_STY] = 1'b1; STY_ZX : opc_inst[I_STY] = 1'b1; STY_ABS : opc_inst[I_STY] = 1'b1; TAX : opc_inst[I_TAX] = 1'b1; TAY : opc_inst[I_TAY] = 1'b1; TSX : opc_inst[I_TSX] = 1'b1; TXA : opc_inst[I_TXA] = 1'b1; TXS : opc_inst[I_TXS] = 1'b1; TYA : opc_inst[I_TYA] = 1'b1; endcase end //---------------------------------------------------------------------- // alu source/dest and modified flag decoder //---------------------------------------------------------------------- // alu source/dest indicator assignments assign opc_src_a_ar = src_dst[12]; // alu source a indicator (a reg) assign opc_src_a_xr = src_dst[11]; // alu source a indicator (x reg) assign opc_src_a_yr = src_dst[10]; // alu source a indicator (y reg) assign opc_src_a_sp = src_dst[ 9]; // alu source a indicator (sp reg) assign opc_src_a_ps = src_dst[ 8]; // alu source a indicator (ps reg) assign opc_src_a_din = src_dst[ 7]; // alu source a indicator (din) assign opc_src_b_din = src_dst[ 6]; // alu source b indicator (din) assign opc_dst_ar = src_dst[ 5]; // alu destination indicator (a reg) assign opc_dst_xr = src_dst[ 4]; // alu destination indicator (x reg) assign opc_dst_yr = src_dst[ 3]; // alu destination indicator (y reg) assign opc_dst_sp = src_dst[ 2]; // alu destination indicator (sp reg) assign opc_dst_ps = src_dst[ 1]; // alu destination indicator (ps reg) assign opc_dst_dout = src_dst[ 0]; // alu destination indicator (dout) // alu source/dest and modified flag decoder always @* begin case (opcode) // AXYSPD D AXYSPD NV-B DIZC ADC_IMM : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_ZP : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_ZX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_ABS : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_AX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_AY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_IX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; ADC_IY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; // AXYSPD D AXYSPD NV-B DIZC AND_IMM : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_ZP : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_ZX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_ABS : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_AX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_AY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_IX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; AND_IY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC ASL_ACC : {src_dst, opc_flag} = {13'b 100000_0_100000, 8'b 1000_0011}; ASL_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ASL_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ASL_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ASL_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC BCC : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BCS : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BEQ : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BMI : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BNE : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BPL : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BVC : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; BVS : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC BIT_ZP : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1100_0010}; BIT_ABS : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1100_0010}; // AXYSPD D AXYSPD NV-B DIZC BRK : {src_dst, opc_flag} = {13'b 000010_0_000001, 8'b 0001_0100}; // AXYSPD D AXYSPD NV-B DIZC CLC : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0001}; CLD : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_1000}; CLI : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0100}; CLV : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0100_0000}; // AXYSPD D AXYSPD NV-B DIZC CMP_IMM : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_ZP : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_ZX : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_ABS : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_AX : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_AY : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_IX : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; CMP_IY : {src_dst, opc_flag} = {13'b 100000_1_000000, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC CPX_IMM : {src_dst, opc_flag} = {13'b 010000_1_000000, 8'b 1000_0011}; CPX_ZP : {src_dst, opc_flag} = {13'b 010000_1_000000, 8'b 1000_0011}; CPX_ABS : {src_dst, opc_flag} = {13'b 010000_1_000000, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC CPY_IMM : {src_dst, opc_flag} = {13'b 001000_1_000000, 8'b 1000_0011}; CPY_ZP : {src_dst, opc_flag} = {13'b 001000_1_000000, 8'b 1000_0011}; CPY_ABS : {src_dst, opc_flag} = {13'b 001000_1_000000, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC DEC_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; DEC_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; DEC_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; DEC_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC DEX : {src_dst, opc_flag} = {13'b 010000_0_010000, 8'b 1000_0010}; DEY : {src_dst, opc_flag} = {13'b 001000_0_001000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC EOR_IMM : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_ZP : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_ZX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_ABS : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_AX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_AY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_IX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; EOR_IY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC INC_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; INC_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; INC_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; INC_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC INX : {src_dst, opc_flag} = {13'b 010000_0_010000, 8'b 1000_0010}; INY : {src_dst, opc_flag} = {13'b 001000_0_001000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC JMP_ABS : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; JMP_IND : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC JSR_ABS : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC LDA_IMM : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_ZP : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_ZX : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_ABS : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_AX : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_AY : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_IX : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; LDA_IY : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC LDX_IMM : {src_dst, opc_flag} = {13'b 000000_1_010000, 8'b 1000_0010}; LDX_ZP : {src_dst, opc_flag} = {13'b 000000_1_010000, 8'b 1000_0010}; LDX_ZY : {src_dst, opc_flag} = {13'b 000000_1_010000, 8'b 1000_0010}; LDX_ABS : {src_dst, opc_flag} = {13'b 000000_1_010000, 8'b 1000_0010}; LDX_AY : {src_dst, opc_flag} = {13'b 000000_1_010000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC LDY_IMM : {src_dst, opc_flag} = {13'b 000000_1_001000, 8'b 1000_0010}; LDY_ZP : {src_dst, opc_flag} = {13'b 000000_1_001000, 8'b 1000_0010}; LDY_ZX : {src_dst, opc_flag} = {13'b 000000_1_001000, 8'b 1000_0010}; LDY_ABS : {src_dst, opc_flag} = {13'b 000000_1_001000, 8'b 1000_0010}; LDY_AX : {src_dst, opc_flag} = {13'b 000000_1_001000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC LSR_ACC : {src_dst, opc_flag} = {13'b 100000_0_100000, 8'b 1000_0011}; LSR_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; LSR_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; LSR_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; LSR_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC NOP : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC ORA_IMM : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_ZP : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_ZX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_ABS : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_AX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_AY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_IX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; ORA_IY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC PHA : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; PHP : {src_dst, opc_flag} = {13'b 000010_0_000001, 8'b 0000_0000}; PLA : {src_dst, opc_flag} = {13'b 000000_1_100000, 8'b 1000_0010}; PLP : {src_dst, opc_flag} = {13'b 000000_1_000010, 8'b 1111_1111}; // AXYSPD D AXYSPD NV-B DIZC ROL_ACC : {src_dst, opc_flag} = {13'b 100000_0_100000, 8'b 1000_0011}; ROL_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROL_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROL_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROL_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC ROR_ACC : {src_dst, opc_flag} = {13'b 100000_0_100000, 8'b 1000_0011}; ROR_ZP : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROR_ZX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROR_ABS : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; ROR_AX : {src_dst, opc_flag} = {13'b 000001_0_000001, 8'b 1000_0011}; // AXYSPD D AXYSPD NV-B DIZC RTI : {src_dst, opc_flag} = {13'b 000000_1_000010, 8'b 1111_1111}; // AXYSPD D AXYSPD NV-B DIZC RTS : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC SBC_IMM : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_ZP : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_ZX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_ABS : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_AX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_AY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_IX : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; SBC_IY : {src_dst, opc_flag} = {13'b 100000_1_100000, 8'b 1100_0011}; // AXYSPD D AXYSPD NV-B DIZC SEC : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0001}; SED : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_1000}; SEI : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0100}; // AXYSPD D AXYSPD NV-B DIZC STA_ZP : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_ZX : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_ABS : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_AX : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_AY : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_IX : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; STA_IY : {src_dst, opc_flag} = {13'b 100000_0_000001, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC STX_ZP : {src_dst, opc_flag} = {13'b 010000_0_000001, 8'b 0000_0000}; STX_ZY : {src_dst, opc_flag} = {13'b 010000_0_000001, 8'b 0000_0000}; STX_ABS : {src_dst, opc_flag} = {13'b 010000_0_000001, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC STY_ZP : {src_dst, opc_flag} = {13'b 001000_0_000001, 8'b 0000_0000}; STY_ZX : {src_dst, opc_flag} = {13'b 001000_0_000001, 8'b 0000_0000}; STY_ABS : {src_dst, opc_flag} = {13'b 001000_0_000001, 8'b 0000_0000}; // AXYSPD D AXYSPD NV-B DIZC TAX : {src_dst, opc_flag} = {13'b 100000_0_010000, 8'b 1000_0010}; TAY : {src_dst, opc_flag} = {13'b 100000_0_001000, 8'b 1000_0010}; TSX : {src_dst, opc_flag} = {13'b 000100_0_010000, 8'b 1000_0010}; TXA : {src_dst, opc_flag} = {13'b 010000_0_100000, 8'b 1000_0010}; TXS : {src_dst, opc_flag} = {13'b 010000_0_000100, 8'b 0000_0000}; TYA : {src_dst, opc_flag} = {13'b 001000_0_100000, 8'b 1000_0010}; // AXYSPD D AXYSPD NV-B DIZC default : {src_dst, opc_flag} = {13'b 000000_0_000000, 8'b 0000_0000}; endcase end //---------------------------------------------------------------------- // execution timing decoder //---------------------------------------------------------------------- // microcode assignments assign mc_fetch_en = mc_exec[15]; // opcode fetch enable assign mc_din_le = mc_exec[14]; // data input latch enable assign mc_pc_chg = mc_exec[13]; // change program counter value assign mc_addr_pc = mc_exec[12]; // output program counter value assign mc_addr_zp = mc_exec[11]; // output zero page address assign mc_addr_abs = mc_exec[10]; // output absolute address assign mc_addr_sp = mc_exec[ 9]; // output stack address assign mc_oe_next = mc_exec[ 8]; // set output enable in next cycle assign mc_alu_inst_op = mc_exec[ 7]; // use alu for instruction operation assign mc_alu_add_xr = mc_exec[ 6]; // add x to input data assign mc_alu_add_yr = mc_exec[ 5]; // add y to input data assign mc_alu_add_z = mc_exec[ 4]; // add 0 to input data assign mc_alu_inc_din = mc_exec[ 3]; // increment input data assign mc_alu_inc_reg = mc_exec[ 2]; // increment saved data assign mc_alu_inc_sp = mc_exec[ 1]; // increment stack pointer value assign mc_alu_dec_sp = mc_exec[ 0]; // decrement stack pointer value // execution timing decoder always @* begin mc_exec = {16{1'b0}}; case (opcode) //-------------------------------------------------- // accumulator //-------------------------------------------------- ASL_ACC, LSR_ACC, ROL_ACC, ROR_ACC: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0000; // PC+1 -- R - - 3'd1: mc_exec = 16'b 101_1000_0_1000_0000; // PC+1 OP R a 0 endcase //-------------------------------------------------- // immediate //-------------------------------------------------- AND_IMM, ORA_IMM, EOR_IMM, ADC_IMM, SBC_IMM, CMP_IMM, CPX_IMM, CPY_IMM, LDA_IMM, LDX_IMM, LDY_IMM: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 DATA R - - 3'd1: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R *a d endcase //-------------------------------------------------- // zero page //-------------------------------------------------- AND_ZP, ORA_ZP, EOR_ZP, ADC_ZP, SBC_ZP, CMP_ZP, CPX_ZP, CPY_ZP, LDA_ZP, LDX_ZP, LDY_ZP, BIT_ZP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0100_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 011_1000_0_0000_0000; // ZA DATA R - - 3'd2: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R *a d endcase STA_ZP, STX_ZP, STY_ZP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0100_1_1000_0000; // PC+1 ZA R *a 0 3'd1: mc_exec = 16'b 001_1000_0_0000_0000; // ZA DATA W - - 3'd2: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase ASL_ZP, LSR_ZP, ROL_ZP, ROR_ZP, INC_ZP, DEC_ZP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0100_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 010_0000_0_0000_0000; // ZA DATA R - - 3'd2: mc_exec = 16'b 000_0000_1_1000_0000; // ZA -- R d 0 3'd3: mc_exec = 16'b 001_1000_0_0000_0000; // ZA DATA W - - 3'd4: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase //-------------------------------------------------- // zero page, x //-------------------------------------------------- AND_ZX, ORA_ZX, EOR_ZX, ADC_ZX, SBC_ZX, CMP_ZX, LDA_ZX, LDY_ZX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 000_0100_0_0100_0000; // PC+1 -- R x d 3'd2: mc_exec = 16'b 011_1000_0_0000_0000; // ZA+X DATA R - - 3'd3: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R *a d endcase STA_ZX, STY_ZX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_1000_0000; // PC+1 ZA R *a 0 3'd1: mc_exec = 16'b 000_0100_1_0100_0000; // PC+1 -- R x d 3'd2: mc_exec = 16'b 001_1000_0_0000_0000; // ZA+X DATA W - - 3'd3: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase ASL_ZX, LSR_ZX, ROL_ZX, ROR_ZX, INC_ZX, DEC_ZX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 000_0100_0_0100_0000; // PC+1 -- R x d 3'd2: mc_exec = 16'b 010_0000_0_0000_0000; // ZA+X DATA R - - 3'd3: mc_exec = 16'b 000_0000_1_1000_0000; // ZA+X -- R d 0 3'd4: mc_exec = 16'b 001_1000_0_0000_0000; // ZA+X DATA W - - 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase //-------------------------------------------------- // zero page, y //-------------------------------------------------- LDX_ZY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 000_0100_0_0010_0000; // PC+1 -- R y d 3'd2: mc_exec = 16'b 011_1000_0_0000_0000; // ZA+Y DATA R - - 3'd3: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R 0 d endcase STX_ZY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_1000_0000; // PC+1 ZA R x 0 3'd1: mc_exec = 16'b 000_0100_1_0010_0000; // PC+1 -- R y d 3'd2: mc_exec = 16'b 001_1000_0_0000_0000; // ZA+Y DATA W - - 3'd3: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase //-------------------------------------------------- // absolute //-------------------------------------------------- AND_ABS, ORA_ABS, EOR_ABS, ADC_ABS, SBC_ABS, CMP_ABS, CPX_ABS, CPY_ABS, LDA_ABS, LDX_ABS, LDY_ABS, BIT_ABS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0001_0000; // PC+2 AH R 0 d 3'd2: mc_exec = 16'b 011_1000_0_0000_0000; // A DATA R - - 3'd3: mc_exec = 16'b 101_1000_0_1000_0000; // PC+3 OP R *a d endcase STA_ABS, STX_ABS, STY_ABS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_1000_0000; // PC+1 AL R *a 0 3'd1: mc_exec = 16'b 010_0010_1_0001_0000; // PC+2 AH R 0 d 3'd2: mc_exec = 16'b 001_1000_0_0000_0000; // A DATA W - - 3'd3: mc_exec = 16'b 101_1000_0_0000_0000; // PC+3 OP R - - endcase ASL_ABS, LSR_ABS, ROL_ABS, ROR_ABS, INC_ABS, DEC_ABS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0001_0000; // PC+2 AH R 0 d 3'd2: mc_exec = 16'b 010_0000_0_0000_0000; // A DATA R - - 3'd3: mc_exec = 16'b 000_0000_1_1000_0000; // A -- R d 0 3'd4: mc_exec = 16'b 001_1000_0_0000_0000; // A DATA W - - 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // PC+3 OP R - - endcase JMP_ABS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 newPCL R - - 3'd1: mc_exec = 16'b 011_0010_0_0001_0000; // PC+2 newPCH R 0 d 3'd2: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - endcase JSR_ABS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 newPCL R - - 3'd1: mc_exec = 16'b 000_0001_1_0000_0001; // PC+1 -- R s 0 3'd2: mc_exec = 16'b 000_0001_1_0000_0001; // S PCH W s 0 3'd3: mc_exec = 16'b 001_1000_0_0000_0000; // S-1 PCL+2 W - - 3'd4: mc_exec = 16'b 011_0010_0_0001_0000; // PC+2 newPCH R 0 d 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - endcase //-------------------------------------------------- // absolute, x //-------------------------------------------------- AND_AX, ORA_AX, EOR_AX, ADC_AX, SBC_AX, CMP_AX, LDA_AX, LDY_AX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0100_0000; // PC+2 AH R x d 3'd2: mc_exec = 16'b 011_1000_0_0000_0000; // A+X DATA R - - 3'd3: mc_exec = 16'b 101_1000_0_1000_0000; // PC+3 OP R *a d endcase STA_AX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_1000_0000; // PC+1 AL R a 0 3'd1: mc_exec = 16'b 010_0010_1_0100_0000; // PC+2 AH R x d 3'd2: mc_exec = 16'b 001_1000_0_0000_0000; // A+X DATA W - - 3'd3: mc_exec = 16'b 101_1000_0_0000_0000; // PC+3 OP R - - endcase ASL_AX, LSR_AX, ROL_AX, ROR_AX, INC_AX, DEC_AX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0100_0000; // PC+2 AH R x d 3'd2: mc_exec = 16'b 010_0000_0_0000_0000; // A+X DATA R - - 3'd3: mc_exec = 16'b 000_0000_1_1000_0000; // A+X -- R d 0 3'd4: mc_exec = 16'b 001_1000_0_0000_0000; // A+X DATA W - - 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // PC+3 OP R - - endcase //-------------------------------------------------- // absolute, y //-------------------------------------------------- AND_AY, ORA_AY, EOR_AY, ADC_AY, SBC_AY, CMP_AY, LDA_AY, LDX_AY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0010_0000; // PC+2 AH R y d 3'd2: mc_exec = 16'b 011_1000_0_0000_0000; // A+Y DATA R - - 3'd3: mc_exec = 16'b 101_1000_0_1000_0000; // PC+3 OP R *a d endcase STA_AY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_1000_0000; // PC+1 AL R a 0 3'd1: mc_exec = 16'b 010_0010_1_0010_0000; // PC+2 AH R y d 3'd2: mc_exec = 16'b 001_1000_0_0000_0000; // A+Y DATA W - - 3'd3: mc_exec = 16'b 101_1000_0_0000_0000; // PC+3 OP R - - endcase //-------------------------------------------------- // indirect, x //-------------------------------------------------- AND_IX, ORA_IX, EOR_IX, ADC_IX, SBC_IX, CMP_IX, LDA_IX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 000_0100_0_0100_0000; // PC+1 -- R x d 3'd2: mc_exec = 16'b 010_0100_0_0000_0100; // ZA+X AL R r 0 3'd3: mc_exec = 16'b 010_0010_0_0001_0000; // ZA+X+1 AH R 0 d 3'd4: mc_exec = 16'b 011_1000_0_0000_0000; // A DATA R - - 3'd5: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R *a d endcase STA_IX: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0000_0_1000_0000; // PC+1 ZA R a 0 3'd1: mc_exec = 16'b 000_0100_0_0100_0000; // PC+1 -- R x d 3'd2: mc_exec = 16'b 010_0100_0_0000_0100; // ZA+X AL R r 0 3'd3: mc_exec = 16'b 010_0010_1_0001_0000; // ZA+X+1 AH R 0 d 3'd4: mc_exec = 16'b 001_1000_0_0000_0000; // A DATA W - - 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase //-------------------------------------------------- // indirect, y //-------------------------------------------------- AND_IY, ORA_IY, EOR_IY, ADC_IY, SBC_IY, CMP_IY, LDA_IY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0100_0_0000_0000; // PC+1 ZA R - - 3'd1: mc_exec = 16'b 010_0100_0_0000_1000; // ZA AL R d 0 3'd2: mc_exec = 16'b 010_0010_0_0010_0000; // ZA+1 AH R y d 3'd3: mc_exec = 16'b 011_1000_0_0000_0000; // A+Y DATA R - - 3'd4: mc_exec = 16'b 101_1000_0_1000_0000; // PC+2 OP R *a d endcase STA_IY: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 010_0100_0_1000_0000; // PC+1 ZA R a 0 3'd1: mc_exec = 16'b 010_0100_0_0000_1000; // ZA AL R d 0 3'd2: mc_exec = 16'b 010_0010_1_0010_0000; // ZA+1 AH R y d 3'd3: mc_exec = 16'b 001_1000_0_0000_0000; // A+Y DATA W - - 3'd4: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - endcase //-------------------------------------------------- // indirect //-------------------------------------------------- JMP_IND: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 AL R - - 3'd1: mc_exec = 16'b 010_0010_0_0001_0000; // PC+2 AH R 0 d 3'd2: mc_exec = 16'b 010_0010_0_0000_0100; // A newPCL R r 0 3'd3: mc_exec = 16'b 011_0010_0_0001_0000; // A+1 newPCH R 0 d 3'd4: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - endcase //-------------------------------------------------- // implied //-------------------------------------------------- TAX, TXA, TAY, TYA, TSX, TXS, INX, INY, DEX, DEY, CLC, CLD, CLI, CLV, SEC, SED, SEI, NOP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0000; // PC+1 -- R - - 3'd1: mc_exec = 16'b 101_1000_0_1000_0000; // PC+1 OP R *a 0 endcase PHA, PHP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0001_1_1000_0000; // PC+1 -- R *a 0 3'd1: mc_exec = 16'b 000_1000_0_0000_0001; // S REG W s 0 3'd2: mc_exec = 16'b 101_1000_0_0000_0000; // PC+1 OP R - - endcase PLA, PLP: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0010; // PC+1 -- R s 0 3'd1: mc_exec = 16'b 000_0001_0_0000_0000; // PC+1 -- R - - 3'd2: mc_exec = 16'b 010_1000_0_0000_0000; // S+1 REG R - - 3'd3: mc_exec = 16'b 101_1000_0_1001_0000; // PC+1 OP R 0 d endcase RTI: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0010; // PC+1 -- R s 0 3'd1: mc_exec = 16'b 000_0001_0_0000_0010; // PC+1 -- R s 0 3'd2: mc_exec = 16'b 010_0001_0_0000_0010; // S+1 P R s 0 3'd3: mc_exec = 16'b 010_0001_0_1001_0000; // S+2 newPCL R 0 d 3'd4: mc_exec = 16'b 011_0010_0_0001_0000; // S+3 newPCH R 0 d 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - endcase RTS: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0010; // PC+1 -- R s 0 3'd1: mc_exec = 16'b 000_0001_0_0000_0010; // PC+1 -- R s 0 3'd2: mc_exec = 16'b 010_0001_0_0000_0000; // S+1 newPCL R - - 3'd3: mc_exec = 16'b 011_0010_0_0001_0000; // S+2 newPCH R 0 d 3'd4: mc_exec = 16'b 001_1000_0_0000_0000; // newPC -- R - - 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // newPC+1 OP R - - endcase BRK: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0001_1_0000_0001; // PC+1 -- R s 0 3'd1: mc_exec = 16'b 000_0001_1_0000_0001; // S PCH W s 0 3'd2: mc_exec = 16'b 000_0001_1_1000_0000; // S-1 PCL+2 W p 0 3'd3: mc_exec = 16'b 000_0000_0_0000_0001; // S-2 P W s 0 3'd4: mc_exec = 16'b 010_0000_0_0000_0000; // VA newPCL R - - 3'd5: mc_exec = 16'b 011_0010_0_0001_0000; // VA+1 newPCH R 0 d 3'd6: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - endcase // // nmi/irq cycle // case (cyc_cnt) // // // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // // EIC CPBP E PDDD NNNE // a b // // TNC S XYZ DRSS // PC OP R // 3'd0: mc_exec = 16'b 000_0001_1_0000_0001; // *PC -- R s 0 // 3'd1: mc_exec = 16'b 000_0001_1_0000_0001; // S *PCH W s 0 // 3'd2: mc_exec = 16'b 000_0001_1_1000_0000; // S-1 *PCL W p 0 // 3'd3: mc_exec = 16'b 000_0000_0_0000_0001; // S-2 P W s 0 // 3'd4: mc_exec = 16'b 010_0000_0_0000_0000; // VA newPCL R - - // 3'd5: mc_exec = 16'b 011_0010_0_0001_0000; // VA+1 newPCH R 0 d // 3'd6: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - // endcase // // reset cycle // case (cyc_cnt) // // // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // // EIC CPBP E PDDD NNNE // a b // // TNC S XYZ DRSS // PC OP R // 3'd0: mc_exec = 16'b 000_0001_0_0000_0001; // *PC -- R s 0 // 3'd1: mc_exec = 16'b 000_0001_0_0000_0001; // S -- *R s 0 // 3'd2: mc_exec = 16'b 000_0001_0_1000_0000; // S-1 -- *R p 0 // 3'd3: mc_exec = 16'b 000_0000_0_0000_0001; // S-2 -- *R s 0 // 3'd4: mc_exec = 16'b 010_0000_0_0000_0000; // VA newPCL R - - // 3'd5: mc_exec = 16'b 011_0010_0_0001_0000; // VA+1 newPCH R 0 d // 3'd6: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - // endcase //-------------------------------------------------- // relative //-------------------------------------------------- BEQ, BNE, BCS, BCC, BVS, BVC, BMI, BPL: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 OFS R - - 3'd1: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R pcl d endcase //-------------------------------------------------- // undefined opcode (same as nop) //-------------------------------------------------- default: case (cyc_cnt) // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // EIC CPBP E PDDD NNNE // a b // TNC S XYZ DRSS // PC OP R 3'd0: mc_exec = 16'b 000_0000_0_0000_0000; // PC+1 -- R - - 3'd1: mc_exec = 16'b 101_1000_0_0000_0000; // PC+1 OP R - - endcase endcase end //---------------------------------------------------------------------- // other microcodes //---------------------------------------------------------------------- // BRK: // case (cyc_cnt) // // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // // EIC CPBP E PDDD NNNE // a b // // TNC S XYZ DRSS // PC OP R // 3'd0: mc_exec = 16'b 000_0001_1_0000_0001; // PC+1 -- R s 0 // 3'd1: mc_exec = 16'b 000_0001_1_0000_0001; // S PCH W s 0 // 3'd2: mc_exec = 16'b 000_0001_1_1000_0000; // S-1 PCL+2 W p 0 // 3'd3: mc_exec = 16'b 000_0000_0_0000_0001; // S-2 P W s 0 // 3'd4: mc_exec = 16'b 010_0000_0_0000_0000; // VA newPCL R - - // 3'd5: mc_exec = 16'b 011_0010_0_0001_0000; // VA+1 newPCH R 0 d // 3'd6: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - // endcase // JSR_ABS: // case (cyc_cnt) // // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // // EIC CPBP E PDDD NNNE // a b // // TNC S XYZ DRSS // PC OP R // 3'd0: mc_exec = 16'b 010_0000_0_0000_0000; // PC+1 newPCL R - - // 3'd1: mc_exec = 16'b 000_0001_1_0000_0001; // PC+1 -- R s 0 // 3'd2: mc_exec = 16'b 000_0001_1_0000_0001; // S PCH W s 0 // 3'd3: mc_exec = 16'b 001_1000_0_0000_0000; // S-1 PCL+2 W - - // 3'd4: mc_exec = 16'b 011_0010_0_0001_0000; // PC+2 newPCH R 0 d // 3'd5: mc_exec = 16'b 101_1000_0_0000_0000; // newPC OP R - - // endcase // interrupt vector address timing assign mc_addr_vl = (opcode == BRK ) & (cyc_cnt == 3'd3); assign mc_addr_vh = (opcode == BRK ) & (cyc_cnt == 3'd4); // pc value(high/low) data output timing assign mc_dout_pch = (opcode == BRK ) & (cyc_cnt == 3'd0) | (opcode == JSR_ABS) & (cyc_cnt == 3'd1); assign mc_dout_pcl = (opcode == BRK ) & (cyc_cnt == 3'd1) | (opcode == JSR_ABS) & (cyc_cnt == 3'd2); // interrupt i flag setting timing assign mc_brk_if_set = (opcode == BRK ) & (cyc_cnt == 3'd2); // BEQ, // BNE, // BCS, // BCC, // BVS, // BVC, // BMI, // BPL: // case (cyc_cnt) // // FDP PZAS O OAAA IIID // ADDR DIO R/W ALU // // EIC CPBP E PDDD NNNE // a b // // TNC S XYZ DRSS // PC OP R // 3'd0: mc_exec = 16'b 011_1000_0_0000_0000; // PC+1 OFS R - - // 3'd1: mc_exec = 16'b 101_1000_0_0000_0000; // PC+2 OP R - - // endcase // branch condition check timing assign mc_br_chk = (opcode == BEQ) & (cyc_cnt == 3'd1) | (opcode == BNE) & (cyc_cnt == 3'd1) | (opcode == BCS) & (cyc_cnt == 3'd1) | (opcode == BCC) & (cyc_cnt == 3'd1) | (opcode == BVS) & (cyc_cnt == 3'd1) | (opcode == BVC) & (cyc_cnt == 3'd1) | (opcode == BMI) & (cyc_cnt == 3'd1) | (opcode == BPL) & (cyc_cnt == 3'd1); endmodule

// DESCRIPTION: Verilator: Verilog Test module // // This file ONLY is placed into the Public Domain, for any use, // without warranty, 2003-2007 by Wilson Snyder. module t (/*AUTOARG*/ // Inputs clk ); input clk; integer cyc; initial cyc=1; // verilator lint_on GENCLK reg [31:0] long; reg [63:0] quad; wire [31:0] longout; wire [63:0] quadout; wire [7:0] narrow = long[7:0]; sub sub (/*AUTOINST*/ // Outputs .longout (longout[31:0]), .quadout (quadout[63:0]), // Inputs .narrow (narrow[7:0]), .quad (quad[63:0])); always @ (posedge clk) begin if (cyc!=0) begin cyc <= cyc + 1; if (cyc==1) begin long <= 32'h12345678; quad <= 64'h12345678_abcdef12; end if (cyc==2) begin if (longout !== 32'h79) $stop; if (quadout !== 64'h12345678_abcdef13) $stop; $write("*-* All Finished *-*\n"); $finish; end end end endmodule module sub (input [7:0] narrow, input [63:0] quad, output [31:0] longout, output [63:0] quadout); // verilator public_module `ifdef verilator wire [31:0] longout = $c32("(",narrow,"+1)"); wire [63:0] quadout = $c64("(",quad,"+1)"); `else wire [31:0] longout = narrow + 8'd1; wire [63:0] quadout = quad + 64'd1; `endif endmodule

//Legal Notice: (C)2016 Altera Corporation. All rights reserved. Your //use of Altera Corporation's design tools, logic functions and other //software and tools, and its AMPP partner logic functions, and any //output files any of the foregoing (including device programming or //simulation files), and any associated documentation or information are //expressly subject to the terms and conditions of the Altera Program //License Subscription Agreement or other applicable license agreement, //including, without limitation, that your use is for the sole purpose //of programming logic devices manufactured by Altera and sold by Altera //or its authorized distributors. Please refer to the applicable //agreement for further details. // synthesis translate_off `timescale 1ns / 1ps // synthesis translate_on // turn off superfluous verilog processor warnings // altera message_level Level1 // altera message_off 10034 10035 10036 10037 10230 10240 10030 module niosii_pio_0 ( // inputs: address, chipselect, clk, reset_n, write_n, writedata, // outputs: out_port, readdata ) ; output [ 7: 0] out_port; output [ 31: 0] readdata; input [ 1: 0] address; input chipselect; input clk; input reset_n; input write_n; input [ 31: 0] writedata; wire clk_en; reg [ 7: 0] data_out; wire [ 7: 0] out_port; wire [ 7: 0] read_mux_out; wire [ 31: 0] readdata; assign clk_en = 1; //s1, which is an e_avalon_slave assign read_mux_out = {8 {(address == 0)}} & data_out; always @(posedge clk or negedge reset_n) begin if (reset_n == 0) data_out <= 0; else if (chipselect && ~write_n && (address == 0)) data_out <= writedata[7 : 0]; end assign readdata = {32'b0 | read_mux_out}; assign out_port = data_out; endmodule

//////////////////////////////////////////////////////////////////////////////// // Copyright (c) 1995-2011 Xilinx, Inc. All rights reserved. //////////////////////////////////////////////////////////////////////////////// // ____ ____ // / /\/ / // /___/ \ / Vendor: Xilinx // \ \ \/ Version : 13.1 // \ \ Application : xaw2verilog // / / Filename : main_pll.v // /___/ /\ Timestamp : 06/03/2011 01:58:13 // \ \ / \ // \___\/\___\ // //Command: xaw2verilog -st /home/teknohog/dcm2/ipcore_dir/./main_pll.xaw /home/teknohog/dcm2/ipcore_dir/./main_pll //Design Name: main_pll //Device: xc3s500e-4fg320 // // Module main_pll // Generated by Xilinx Architecture Wizard // Written for synthesis tool: XST `timescale 1ns / 1ps module dyn_pll # (parameter SPEED_MHZ = 25 ) (CLKIN_IN, CLKFX1_OUT, CLKFX2_OUT, CLKDV_OUT, DCM_SP_LOCKED_OUT, dcm_progclk, dcm_progdata, dcm_progen, dcm_reset, dcm_progdone, dcm_locked, dcm_status); input CLKIN_IN; wire CLKIN_IBUFG_OUT; wire CLK0_OUT; output CLKFX1_OUT; output CLKFX2_OUT; output CLKDV_OUT; output DCM_SP_LOCKED_OUT; input dcm_progclk; input dcm_progdata; input dcm_progen; input dcm_reset; output dcm_progdone; output dcm_locked; output [2:1] dcm_status; wire CLKFB_IN; wire CLKIN_IBUFG; wire CLK0_BUF; wire CLKFX1_BUF; wire CLKFX2_BUF; wire CLKDV_BUF; wire GND_BIT; wire dcm_progclk_buf; assign GND_BIT = 0; assign CLKIN_IBUFG_OUT = CLKIN_IBUFG; assign CLK0_OUT = CLKFB_IN; IBUFG CLKIN_IBUFG_INST (.I(CLKIN_IN), .O(CLKIN_IBUFG)); BUFG CLK0_BUFG_INST (.I(CLK0_BUF), .O(CLKFB_IN)); BUFG CLKFX1_BUFG_INST (.I(CLKFX1_BUF), .O(CLKFX1_OUT)); BUFG CLKFX2_BUFG_INST (.I(CLKFX2_BUF), .O(CLKFX2_OUT)); BUFG CLKDV_BUFG_INST (.I(CLKDV_BUF), .O(CLKDV_OUT)); BUFG DCMPROGCLK_BUFG_INST (.I(dcm_progclk), .O(dcm_progclk_buf)); // 100 MHZ osc gives fixed 50MHz CLKFX1, 12.5MHZ CLKDV DCM_SP #( .CLK_FEEDBACK("1X"), .CLKDV_DIVIDE(8.0), .CLKFX_DIVIDE(8), .CLKFX_MULTIPLY(4), .CLKIN_DIVIDE_BY_2("FALSE"), .CLKIN_PERIOD(10.000), .CLKOUT_PHASE_SHIFT("NONE"), .DESKEW_ADJUST("SYSTEM_SYNCHRONOUS"), .DFS_FREQUENCY_MODE("LOW"), .DLL_FREQUENCY_MODE("LOW"), .DUTY_CYCLE_CORRECTION("TRUE"), .FACTORY_JF(16'hC080), .PHASE_SHIFT(0), .STARTUP_WAIT("FALSE") ) DCM_SP_INST (.CLKFB(CLKFB_IN), .CLKIN(CLKIN_IBUFG), .DSSEN(GND_BIT), .PSCLK(GND_BIT), .PSEN(GND_BIT), .PSINCDEC(GND_BIT), .RST(GND_BIT), .CLKDV(CLKDV_BUF), .CLKFX(CLKFX1_BUF), .CLKFX180(), .CLK0(CLK0_BUF), .CLK2X(), .CLK2X180(), .CLK90(), .CLK180(), .CLK270(), .LOCKED(DCM_SP_LOCKED_OUT), .PSDONE(), .STATUS()); DCM_CLKGEN #( .CLKFX_DIVIDE(100), // 100Mhz osc so gives steps of 1MHz .CLKFX_MULTIPLY(SPEED_MHZ), .CLKFXDV_DIVIDE(2), // Unused .CLKIN_PERIOD(10.0), .CLKFX_MD_MAX(0.000), .SPREAD_SPECTRUM("NONE"), .STARTUP_WAIT("FALSE") ) DCM_CLKGEN_INST ( .CLKIN(CLKIN_IBUFG), .CLKFX(CLKFX2_BUF), .FREEZEDCM(1'b0), .PROGCLK(dcm_progclk_buf), .PROGDATA(dcm_progdata), .PROGEN(dcm_progen), .PROGDONE(dcm_progdone), .LOCKED(dcm_locked), .STATUS(dcm_status), .RST(dcm_reset) ); endmodule

module opc8cpu(input[23:0] din,input clk,input reset_b,input[1:0] int_b,input clken,output vpa,output vda,output[23:0] dout,output[23:0] address,output rnw); parameter HALT=5'h00,NOT=5'h01,OR=5'h02,XOR=5'h03,BPERM=5'h04,ROR=5'h05,LSR=5'h06,ASR=5'h07,ROL=5'h08,RTI=5'h09,PPSR=5'h0A,GPSR=5'h0B; parameter BROR=5'h0C, BROL=5'h0D,MOV=5'h10,JSR=5'h11,CMP=5'h12,SUB=5'h13,ADD=5'h14,AND=5'h15,STO=5'h16,LD=5'h17; parameter FET=3'h0,FET1=3'h1,EAD=3'h2,RDM=3'h3,EXEC=3'h4,WRM=3'h5,INT=3'h6,EI=3,S=2,C=1,Z=0,INT_VECTOR0=24'h2,INT_VECTOR1=24'h4; reg [7:0] PSR_q; (* RAM_STYLE="DISTRIBUTED" *) reg [23:0] PC_q,PCI_q, RF_q[14:0], RF_pipe_q, OR_q, result; reg [4:0] IR_q; reg [3:0] swiid,PSRI_q,dst_q,src_q, pred_q; reg [2:0] FSM_q, FSM_d; reg zero,carry,sign,enable_int,reset_s0_b,reset_s1_b,subnotadd_q, rnw_q, vpa_q, vda_q; wire pred = (pred_q[0] ^ (pred_q[1]?(pred_q[2]?PSR_q[S]:PSR_q[Z]):(pred_q[2]?PSR_q[C]:1))); wire [23:0] RF_sout = {24{(|src_q)&&IR_q[4:2]!=3'b111}} & ((src_q==4'hF)? PC_q : RF_q[src_q]); wire [23:0] bytes = (IR_q==BROL)?{OR_q[15:0],OR_q[23:16]}:{OR_q[7:0],OR_q[23:8]}; assign {rnw,dout,address}= {rnw_q, RF_pipe_q, (vpa_q)? PC_q : OR_q}; assign {vpa,vda} = {vpa_q, vda_q}; always @( * ) begin case (IR_q) AND,OR :{carry,result} = {PSR_q[C],(IR_q==AND)?(RF_pipe_q & OR_q):(RF_pipe_q | OR_q)}; ROL,NOT :{carry,result} = (IR_q==NOT)? {PSR_q[C], ~OR_q} : {OR_q, PSR_q[C]}; ADD,SUB,CMP :{carry,result} = RF_pipe_q + OR_q + subnotadd_q; // OR_q negated in EAD if required for sub/cmp XOR,GPSR :{carry,result} = (IR_q==GPSR)?{PSR_q[C],8'b0,PSR_q}:{PSR_q[C],RF_pipe_q ^ OR_q}; ROR,ASR,LSR :{result,carry} = {(IR_q==ROR)?PSR_q[C]:(IR_q==ASR)?OR_q[23]:1'b0,OR_q}; BROL,BROR :{carry,result} = { (IR_q==BROL)? (|OR_q[23:16]): (|OR_q[7:0]), OR_q}; default :{carry,result} = {PSR_q[C],OR_q} ; endcase // case ( IR_q ) {swiid,enable_int,sign,carry,zero} = (IR_q==PPSR)?OR_q[7:0]:(dst_q!=4'hF)?{PSR_q[7:3],result[23],carry,!(|result)}:PSR_q; case (FSM_q) FET : FSM_d = (din[20:19]==2'b11)? FET1 : EAD; FET1 : FSM_d = EAD; // Could check predicates here to speed up skipped double word instructions EAD : FSM_d = (!pred) ? FET : (IR_q==LD) ? RDM : (IR_q==STO) ? WRM : EXEC; EXEC : FSM_d = ((!(&int_b) & PSR_q[EI])||(IR_q==PPSR&&(|swiid)))?INT:(dst_q==4'hF||IR_q==JSR)?FET:(din[20:19]==2'b11)?FET1:EAD; WRM : FSM_d = (!(&int_b) & PSR_q[EI])?INT:FET; default: FSM_d = (FSM_q==RDM)? EXEC : FET; endcase end // always @ ( * ) always @(posedge clk) if (clken) begin RF_pipe_q <= (dst_q==4'hF)? PC_q : RF_q[dst_q] & {24{(|dst_q)}}; // Sign extension on short immediates only if source field==0 being done on reading memory - may move this to EAD state... OR_q <= (FSM_q==EAD)?(IR_q==BROL||IR_q==BROR)? bytes: ((RF_sout+OR_q)^{24{(IR_q==SUB||IR_q==CMP)}}):(FSM_q==FET||FSM_q==EXEC)?{{16{(din[7]&(|din[11:8]))}}, din[7:0]}:din; {reset_s0_b,reset_s1_b, subnotadd_q} <= {reset_b,reset_s0_b, IR_q!=ADD}; if (!reset_s1_b) begin {PC_q,PCI_q,PSRI_q,PSR_q,FSM_q,vda_q} <= 0; {rnw_q, vpa_q} <= 2'b11; end else begin {FSM_q, rnw_q} <= {FSM_d, !(FSM_d==WRM) } ; {vpa_q, vda_q} <= {FSM_d==FET||FSM_d==FET1||FSM_d==EXEC,FSM_d==RDM||FSM_d==WRM}; if ((FSM_q==FET)||(FSM_q==EXEC)) {pred_q, IR_q, dst_q, src_q} <= { din[23:21],(din[20:19]==2'b11)?2'b10: din[20:19], din[18:8]}; // Alias 'long' opcodes to short equivalent else if (FSM_q==EAD & IR_q==CMP ) dst_q <= 4'b0; // Zero dest address after reading it in EAD for CMP operations if ( FSM_q == INT ) {PC_q,PCI_q,PSRI_q,PSR_q[EI]} <= {(!int_b[1])?INT_VECTOR1:INT_VECTOR0,PC_q,PSR_q[3:0],1'b0}; else if (FSM_q==FET||FSM_q==FET1) PC_q <= PC_q + 1; else if ( FSM_q == EXEC) begin PC_q <= (IR_q==RTI)?PCI_q: (dst_q==4'hF) ? result[23:0] : (IR_q==JSR)?OR_q:((!(&int_b)&&PSR_q[EI])||(IR_q==PPSR&&(|swiid)))?PC_q:PC_q + 1; PSR_q <= (IR_q==RTI)?{4'b0,PSRI_q}:{swiid,enable_int,sign,carry,zero}; RF_q[dst_q] <= (IR_q==JSR)? PC_q : result ; end end end endmodule // opc8cpu

//====================================================================== // // rosc_entropy_core.v // ------------------- // Digitial ring oscillator based entropy generation core. // This version implements 32 separate oscillators where each // oscillator can be enabled or disabled. // // // Author: Joachim Strombergson // Copyright (c) 2014, Secworks Sweden AB // All rights reserved. // // Redistribution and use in source and binary forms, with or // without modification, are permitted provided that the following // conditions are met: // // 1. Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // // 2. Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in // the documentation and/or other materials provided with the // distribution. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS // FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE // COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, // INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, // BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; // LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER // CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, // STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) // ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF // ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // //====================================================================== module rosc_entropy_core( input wire clk, input wire reset_n, input wire [31 : 0] opa, input wire [31 : 0] opb, input wire [31 : 0] rosc_en, input wire [7 : 0] rosc_cycles, output wire [31 : 0] raw_entropy, output wire [31 : 0] rosc_outputs, output wire [31 : 0] entropy_data, output wire entropy_valid, input wire entropy_ack, output wire [7 : 0] debug, input wire debug_update ); //---------------------------------------------------------------- // Parameters. //---------------------------------------------------------------- localparam ADDER_WIDTH = 2; localparam DEBUG_DELAY = 32'h002c4b40; localparam NUM_SHIFT_BITS = 8'h20; localparam SAMPLE_CLK_CYCLES = 8'hff; //---------------------------------------------------------------- // Registers including update variables and write enable. //---------------------------------------------------------------- reg [31 : 0] ent_shift_reg; reg [31 : 0] ent_shift_new; reg ent_shift_we; reg [31 : 0] entropy_reg; reg entropy_we; reg entropy_valid_reg; reg entropy_valid_new; reg entropy_valid_we; reg bit_we_reg; reg bit_we_new; reg [7 : 0] bit_ctr_reg; reg [7 : 0] bit_ctr_new; reg bit_ctr_inc; reg bit_ctr_we; reg [7 : 0] sample_ctr_reg; reg [7 : 0] sample_ctr_new; reg [31 : 0] debug_delay_ctr_reg; reg [31 : 0] debug_delay_ctr_new; reg debug_delay_ctr_we; reg [7 : 0] debug_reg; reg debug_we; reg debug_update_reg; //---------------------------------------------------------------- // Wires. //---------------------------------------------------------------- reg [31 : 0] rosc_we; // Ugly in-line Xilinx attribute to preserve the registers. (* equivalent_register_removal = "no" *) wire [31 : 0] rosc_dout; //---------------------------------------------------------------- // Concurrent connectivity for ports etc. //---------------------------------------------------------------- assign rosc_outputs = rosc_dout; assign raw_entropy = ent_shift_reg; assign entropy_data = entropy_reg; assign entropy_valid = entropy_valid_reg; assign debug = debug_reg; //---------------------------------------------------------------- // module instantiations. // // 32 oscillators each ADDER_WIDTH wide. We want them to run // as fast as possible to maximize differences over time. // We also only sample the oscillators SAMPLE_CLK_CYCLES number // of cycles. //---------------------------------------------------------------- genvar i; generate for(i = 0 ; i < 32 ; i = i + 1) begin: oscillators rosc #(.WIDTH(ADDER_WIDTH)) rosc_array(.clk(clk), .we(rosc_we[i]), .reset_n(reset_n), .opa(opa[(ADDER_WIDTH - 1) : 0]), .opb(opb[(ADDER_WIDTH - 1) : 0]), .dout(rosc_dout[i]) ); end endgenerate //---------------------------------------------------------------- // reg_update // // Update functionality for all registers in the core. // All registers are positive edge triggered with asynchronous // active low reset. //---------------------------------------------------------------- always @ (posedge clk or negedge reset_n) begin if (!reset_n) begin ent_shift_reg <= 32'h00000000; entropy_reg <= 32'h00000000; entropy_valid_reg <= 0; bit_ctr_reg <= 8'h00; sample_ctr_reg <= 8'h00; debug_delay_ctr_reg <= 32'h00000000; debug_reg <= 8'h00; debug_update_reg <= 0; end else begin sample_ctr_reg <= sample_ctr_new; debug_update_reg <= debug_update; if (ent_shift_we) begin ent_shift_reg <= ent_shift_new; end if (bit_ctr_we) begin bit_ctr_reg <= bit_ctr_new; end if (entropy_we) begin entropy_reg <= ent_shift_reg; end if (entropy_valid_we) begin entropy_valid_reg <= entropy_valid_new; end if (debug_delay_ctr_we) begin debug_delay_ctr_reg <= debug_delay_ctr_new; end if (debug_we) begin debug_reg <= ent_shift_reg[7 : 0]; end end end // reg_update //---------------------------------------------------------------- // debug_out // // Logic that updates the debug port. //---------------------------------------------------------------- always @* begin : debug_out debug_delay_ctr_new = 32'h00000000; debug_delay_ctr_we = 0; debug_we = 0; if (debug_update_reg) begin debug_delay_ctr_new = debug_delay_ctr_reg + 1'b1; debug_delay_ctr_we = 1; end if (debug_delay_ctr_reg == DEBUG_DELAY) begin debug_delay_ctr_new = 32'h00000000; debug_delay_ctr_we = 1; debug_we = 1; end end //---------------------------------------------------------------- // entropy_out // // Logic that implements the random output control. If we have // added more than NUM_SHIFT_BITS we raise the entropy_valid flag. // When we detect and ACK, the valid flag is dropped. //---------------------------------------------------------------- always @* begin : entropy_out bit_ctr_new = 8'h00; bit_ctr_we = 0; entropy_we = 0; entropy_valid_new = 0; entropy_valid_we = 0; if (bit_ctr_inc) begin if (bit_ctr_reg < NUM_SHIFT_BITS) begin bit_ctr_new = bit_ctr_reg + 1'b1; bit_ctr_we = 1; end else begin entropy_we = 1; entropy_valid_new = 1; entropy_valid_we = 1; end end if (entropy_ack) begin bit_ctr_new = 8'h00; bit_ctr_we = 1; entropy_valid_new = 0; entropy_valid_we = 1; end end //---------------------------------------------------------------- // entropy_gen // // Logic that implements the actual entropy bit value generator // by XOR mixing the oscillator outputs. These outputs are // sampled once every SAMPLE_CLK_CYCLES. //---------------------------------------------------------------- always @* begin : entropy_gen reg ent_bit; bit_ctr_inc = 0; rosc_we = 32'h00000000; ent_shift_we = 0; ent_bit = ^rosc_dout; ent_shift_new = {ent_shift_reg[30 : 0], ent_bit}; sample_ctr_new = sample_ctr_reg + 1'b1; if (sample_ctr_reg == SAMPLE_CLK_CYCLES) begin sample_ctr_new = 8'h00; bit_ctr_inc = 1; rosc_we = rosc_en; ent_shift_we = 1; end end endmodule // rosc_entropy_core //====================================================================== // EOF rosc_entropy_core.v //======================================================================

/* File: ewrapper_link_receiver.v This file is part of the Parallella FPGA Reference Design. Copyright (C) 2013 Adapteva, Inc. Contributed by Roman Trogan <[email protected]> This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program (see the file COPYING). If not, see <http://www.gnu.org/licenses/>. */ module ewrapper_link_receiver (/*AUTOARG*/ // Outputs rxi_wr_wait, rxi_rd_wait, emesh_clk_inb, emesh_access_inb, emesh_write_inb, emesh_datamode_inb, emesh_ctrlmode_inb, emesh_dstaddr_inb, emesh_srcaddr_inb, emesh_data_inb, // Inputs reset, rxi_data, rxi_lclk, rxi_frame, emesh_wr_wait_outb, emesh_rd_wait_outb ); //######### //# INPUTS //######### input reset; //reset input //# From the lvds-serdes input [63:0] rxi_data; //Eight Parallel Byte words input rxi_lclk; //receive clock (synchronized to the data) input [7:0] rxi_frame; //Parallel frame signals representing // 4 transmission clock cycles //# From the emesh interface input emesh_wr_wait_outb; input emesh_rd_wait_outb; //########## //# OUTPUTS //########## //# To the transmitter output rxi_wr_wait; //wait indicator output rxi_rd_wait; //wait indicator //# To the emesh interface output emesh_clk_inb; output emesh_access_inb; output emesh_write_inb; output [1:0] emesh_datamode_inb; output [3:0] emesh_ctrlmode_inb; output [31:0] emesh_dstaddr_inb; output [31:0] emesh_srcaddr_inb; output [31:0] emesh_data_inb; /*AUTOINPUT*/ /*AUTOWIRE*/ //######### //# Wires //######### wire emesh_wr_access_inb; wire emesh_wr_write_inb; wire [1:0] emesh_wr_datamode_inb; wire [3:0] emesh_wr_ctrlmode_inb; wire [31:0] emesh_wr_dstaddr_inb; wire [31:0] emesh_wr_srcaddr_inb; wire [31:0] emesh_wr_data_inb; wire emesh_rd_access_inb; wire emesh_rd_write_inb; wire [1:0] emesh_rd_datamode_inb; wire [3:0] emesh_rd_ctrlmode_inb; wire [31:0] emesh_rd_dstaddr_inb; wire [31:0] emesh_rd_srcaddr_inb; wire [31:0] emesh_rd_data_inb; wire select_write_tran; wire wr_wait; wire rd_wait; wire emesh_access_tmp; //############### //# Emesh clock //############### assign emesh_clk_inb = rxi_lclk; //###################################### //# Write-Read Transactions Arbitration //# Write has a higher priority ALWAYS //###################################### assign select_write_tran = emesh_wr_access_inb & ~emesh_wr_wait_outb; assign emesh_access_inb = emesh_access_tmp & ~emesh_wr_wait_outb; assign wr_wait = emesh_wr_wait_outb; assign rd_wait = emesh_rd_access_inb & select_write_tran | (emesh_wr_wait_outb | emesh_rd_wait_outb); assign emesh_srcaddr_inb[31:0] = select_write_tran ? emesh_wr_srcaddr_inb[31:0] : emesh_rd_srcaddr_inb[31:0]; assign emesh_dstaddr_inb[31:0] = select_write_tran ? emesh_wr_dstaddr_inb[31:0] : emesh_rd_dstaddr_inb[31:0]; assign emesh_datamode_inb[1:0] = select_write_tran ? emesh_wr_datamode_inb[1:0] : emesh_rd_datamode_inb[1:0]; assign emesh_ctrlmode_inb[3:0] = select_write_tran ? emesh_wr_ctrlmode_inb[3:0] : emesh_rd_ctrlmode_inb[3:0]; assign emesh_data_inb[31:0] = select_write_tran ? emesh_wr_data_inb[31:0] : emesh_rd_data_inb[31:0]; assign emesh_access_tmp = select_write_tran ? emesh_wr_access_inb : emesh_rd_access_inb; assign emesh_write_inb = select_write_tran ? emesh_wr_write_inb : emesh_rd_write_inb; //############################################ //# Write Transactions Receiver Instantiation //############################################ /*ewrapper_link_rxi AUTO_TEMPLATE( .rxi_rd (1'b0), .emesh_wait_outb (wr_wait), .rxi_wait (rxi_wr_wait), .emesh_$.*$ (emesh_wr_\1[]), ); */ ewrapper_link_rxi wr_rxi(/*AUTOINST*/ // Outputs .rxi_wait (rxi_wr_wait), // Templated .emesh_access_inb (emesh_wr_access_inb), // Templated .emesh_write_inb (emesh_wr_write_inb), // Templated .emesh_datamode_inb (emesh_wr_datamode_inb[1:0]), // Templated .emesh_ctrlmode_inb (emesh_wr_ctrlmode_inb[3:0]), // Templated .emesh_dstaddr_inb (emesh_wr_dstaddr_inb[31:0]), // Templated .emesh_srcaddr_inb (emesh_wr_srcaddr_inb[31:0]), // Templated .emesh_data_inb (emesh_wr_data_inb[31:0]), // Templated // Inputs .reset (reset), .rxi_data (rxi_data[63:0]), .rxi_lclk (rxi_lclk), .rxi_frame (rxi_frame[7:0]), .emesh_wait_outb (wr_wait), // Templated .rxi_rd (1'b0)); // Templated //############################################ //# Read Transactions Receiver Instantiation //############################################ /*ewrapper_link_rxi AUTO_TEMPLATE( .rxi_rd (1'b1), .emesh_wait_outb (rd_wait), .rxi_wait (rxi_rd_wait), .emesh_$.*$ (emesh_rd_\1[]), ); */ ewrapper_link_rxi rd_rxi(/*AUTOINST*/ // Outputs .rxi_wait (rxi_rd_wait), // Templated .emesh_access_inb (emesh_rd_access_inb), // Templated .emesh_write_inb (emesh_rd_write_inb), // Templated .emesh_datamode_inb (emesh_rd_datamode_inb[1:0]), // Templated .emesh_ctrlmode_inb (emesh_rd_ctrlmode_inb[3:0]), // Templated .emesh_dstaddr_inb (emesh_rd_dstaddr_inb[31:0]), // Templated .emesh_srcaddr_inb (emesh_rd_srcaddr_inb[31:0]), // Templated .emesh_data_inb (emesh_rd_data_inb[31:0]), // Templated // Inputs .reset (reset), .rxi_data (rxi_data[63:0]), .rxi_lclk (rxi_lclk), .rxi_frame (rxi_frame[7:0]), .emesh_wait_outb (rd_wait), // Templated .rxi_rd (1'b1)); // Templated endmodule // ewrapper_link_receiver

// (C) 1992-2014 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. module vfabric_icmp(clock, resetn, i_dataa, i_dataa_valid, o_dataa_stall, i_datab, i_datab_valid, o_datab_stall, o_dataout, o_dataout_valid, i_stall, i_settings); parameter DATA_WIDTH = 32; parameter MODE_WIDTH = 4; parameter FIFO_DEPTH = 64; input clock, resetn; input [DATA_WIDTH-1:0] i_dataa; input [DATA_WIDTH-1:0] i_datab; input i_dataa_valid, i_datab_valid; output o_dataa_stall, o_datab_stall; output reg o_dataout; output o_dataout_valid; input i_stall; input [MODE_WIDTH-1:0] i_settings; wire [DATA_WIDTH-1:0] dataa; wire [DATA_WIDTH-1:0] datab; wire signed [DATA_WIDTH-1:0] sdataa; wire signed [DATA_WIDTH-1:0] sdatab; wire is_fifo_a_valid; wire is_fifo_b_valid; wire is_stalled; vfabric_buffered_fifo fifo_a ( .clock(clock), .resetn(resetn), .data_in(i_dataa), .data_out(dataa), .valid_in(i_dataa_valid), .valid_out( is_fifo_a_valid ), .stall_in(is_stalled), .stall_out(o_dataa_stall) ); defparam fifo_a.DATA_WIDTH = DATA_WIDTH; defparam fifo_a.DEPTH = FIFO_DEPTH; vfabric_buffered_fifo fifo_b ( .clock(clock), .resetn(resetn), .data_in(i_datab), .data_out(datab), .valid_in(i_datab_valid), .valid_out( is_fifo_b_valid ), .stall_in(is_stalled), .stall_out(o_datab_stall) ); defparam fifo_b.DATA_WIDTH = DATA_WIDTH; defparam fifo_b.DEPTH = FIFO_DEPTH; assign is_stalled = ~(is_fifo_a_valid & is_fifo_b_valid & ~i_stall); assign sdataa = dataa; assign sdatab = datab; always @(*) begin case (i_settings) 5'h0: // EQ begin o_dataout <= (dataa == datab) ? 1'b1 : 1'b0; end 5'h1: // NE begin o_dataout <= (dataa != datab) ? 1'b1 : 1'b0; end 5'h2: // UGT begin o_dataout <= (dataa > datab) ? 1'b1 : 1'b0; end 5'h3: // UGE begin o_dataout <= (dataa >= datab) ? 1'b1 : 1'b0; end 5'h4: // ULT begin o_dataout <= (dataa < datab) ? 1'b1 : 1'b0; end 5'h5: // ULE begin o_dataout <= (dataa <= datab) ? 1'b1 : 1'b0; end 5'h6: // SGT begin o_dataout <= (sdataa > sdatab) ? 1'b1 : 1'b0; end 5'h7: // SGE begin o_dataout <= (sdataa >= sdatab) ? 1'b1 : 1'b0; end 5'h8: // SLT begin o_dataout <= (sdataa < sdatab) ? 1'b1 : 1'b0; end 5'h9: // SLE begin o_dataout <= (sdataa <= sdatab) ? 1'b1 : 1'b0; end default: begin o_dataout <= 1'b0; end endcase end assign o_dataout_valid = is_fifo_a_valid & is_fifo_b_valid; endmodule

//----------------------------------------------------------------------------- //-- Baudrate generator //-- It generates a square signal, with a frequency for communicating at the given //-- given baudrate //-- The output is set to 1 only during one clock cycle. The rest of the time is 0 //-------------------------------------------------------------------------------- //-- (c) BQ. December 2015. written by Juan Gonzalez (obijuan) //----------------------------------------------------------------------------- //-- GPL license //----------------------------------------------------------------------------- `default_nettype none `include "baudgen.vh" //---------------------------------------------------------------------------------------- //-- baudgen module //-- //-- INPUTS: //-- -clk: System clock (12 MHZ in the iceStick board) //-- -clk_ena: clock enable: //-- 1. Normal working: The squeare signal is generated //-- 0: stoped. Output always 0 //-- OUTPUTS: //-- - clk_out: Output signal. Pulse width: 1 clock cycle. Output not registered //-- It tells the uart_tx when to transmit the next bit //-- __ __ //-- __| |________________________________________________________| |________________ //-- -> <- 1 clock cycle //-- //--------------------------------------------------------------------------------------- module baudgen_tx #( parameter BAUDRATE = `B115200 //-- Default baudrate )( input wire rstn, //-- Reset (active low) input wire clk, //-- System clock input wire clk_ena, //-- Clock enable output wire clk_out //-- Bitrate Clock output ); //-- Number of bits needed for storing the baudrate divisor localparam N = $clog2(BAUDRATE); //-- Counter for implementing the divisor (it is a BAUDRATE module counter) //-- (when BAUDRATE is reached, it start again from 0) reg [N-1:0] divcounter = 0; always @(posedge clk) if (!rstn) divcounter <= 0; else if (clk_ena) //-- Normal working: counting. When the maximum count is reached, it starts from 0 divcounter <= (divcounter == BAUDRATE - 1) ? 0 : divcounter + 1; else //-- Counter fixed to its maximum value //-- When it is resumed it start from 0 divcounter <= BAUDRATE - 1; //-- The output is 1 when the counter is 0, if clk_ena is active //-- It is 1 only for one system clock cycle assign clk_out = (divcounter == 0) ? clk_ena : 0; endmodule

/////////////////////////////////////////////////////////////////////////////// // vim:set shiftwidth=3 softtabstop=3 expandtab: // $Id: unused_reg.v 1914 2007-07-11 23:58:33Z grg $ // // Module: unused_reg.v // Project: NetFPGA // Description: Unused register block // /////////////////////////////////////////////////////////////////////////////// module unused_reg #( parameter REG_ADDR_WIDTH = 5 ) ( // Register interface signals input reg_req, output reg_ack, input reg_rd_wr_L, input [REG_ADDR_WIDTH - 1:0] reg_addr, output [`CPCI_NF2_DATA_WIDTH - 1:0] reg_rd_data, input [`CPCI_NF2_DATA_WIDTH - 1:0] reg_wr_data, // input clk, input reset ); reg reg_req_d1; assign reg_rd_data = 'h dead_beef; // Only generate an ack on a new request assign reg_ack = reg_req && !reg_req_d1; always @(posedge clk) begin reg_req_d1 <= reg_req; end endmodule // unused_reg

module bts ( z , a , e); inout z ; wire z ; input a ; wire a ; input e ; wire e ; assign #4 z= ( (e==1'b1)? a : 1'bz ); endmodule module test(); reg [1:0] aa; wire [1:0] zz; reg [1:0] ee; bts sub1 (.z(zz[1]), .a(aa[1]), .e(ee[1])); bts sub0 (.z(zz[0]), .a(aa[0]), .e(ee[0])); initial begin // $dumpvars; ee=2'b00; aa=2'b00; #100; if (zz !== 2'bzz) begin $display("FAILED -- (1) All disabled, expected HiZ, got %b", zz); $finish; end aa=2'b11; #100; if (zz !== 2'bzz) begin $display("FAILED -- (2) All disabled, expected HiZ, got %b", zz); $finish; end aa=2'b00; #100; if (zz !== 2'bzz) begin $display("FAILED -- (3) All disabled, expected HiZ, got %b", zz); $finish; end aa=2'b11; #100; if (zz !== 2'bzz) begin $display("FAILED -- (4) All disabled, expected HiZ, got %b", zz); $finish; end ee=2'b11; aa=2'b00; #100; if (zz !== 2'b00) begin $display("FAILED -- (5) All enabled, expected 00, got %b", zz); $finish; end aa=2'b11; #100; if (zz !== 2'b11) begin $display("FAILED -- (6) All enabled, expected 11, got %b", zz); $finish; end aa=2'b00; #100; if (zz !== 2'b00) begin $display("FAILED -- (7) All enabled, expected 00, got %b", zz); $finish; end aa=2'b11; #100; if (zz !== 2'b11) begin $display("FAILED -- (8) All enabled, expected 11, got %b", zz); $finish; end $display("PASSED"); end endmodule

//----------------------------------------------------------------------------- //-- (c) Copyright 2010 Xilinx, Inc. All rights reserved. //-- //-- This file contains confidential and proprietary information //-- of Xilinx, Inc. and is protected under U.S. and //-- international copyright and other intellectual property //-- laws. //-- //-- DISCLAIMER //-- This disclaimer is not a license and does not grant any //-- rights to the materials distributed herewith. Except as //-- otherwise provided in a valid license issued to you by //-- Xilinx, and to the maximum extent permitted by applicable //-- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND //-- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES //-- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING //-- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- //-- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and //-- (2) Xilinx shall not be liable (whether in contract or tort, //-- including negligence, or under any other theory of //-- liability) for any loss or damage of any kind or nature //-- related to, arising under or in connection with these //-- materials, including for any direct, or any indirect, //-- special, incidental, or consequential loss or damage //-- (including loss of data, profits, goodwill, or any type of //-- loss or damage suffered as a result of any action brought //-- by a third party) even if such damage or loss was //-- reasonably foreseeable or Xilinx had been advised of the //-- possibility of the same. //-- //-- CRITICAL APPLICATIONS //-- Xilinx products are not designed or intended to be fail- //-- safe, or for use in any application requiring fail-safe //-- performance, such as life-support or safety devices or //-- systems, Class III medical devices, nuclear facilities, //-- applications related to the deployment of airbags, or any //-- other applications that could lead to death, personal //-- injury, or severe property or environmental damage //-- (individually and collectively, "Critical //-- Applications"). Customer assumes the sole risk and //-- liability of any use of Xilinx products in Critical //-- Applications, subject only to applicable laws and //-- regulations governing limitations on product liability. //-- //-- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS //-- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Description: Up-Sizer // Up-Sizer for generic SI- and MI-side data widths. This module instantiates // Address, Write Data and Read Data Up-Sizer modules, each one taking care // of the channel specific tasks. // The Address Up-Sizer can handle both AR and AW channels. // // Verilog-standard: Verilog 2001 //-------------------------------------------------------------------------- // // Structure: // axi_upsizer // a_upsizer // fifo // fifo_gen // fifo_coregen // w_upsizer // r_upsizer // //-------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none (* DowngradeIPIdentifiedWarnings="yes" *) module axi_dwidth_converter_v2_1_7_axi_upsizer # ( parameter C_FAMILY = "virtex7", // FPGA Family. Current version: virtex6 or spartan6. parameter integer C_AXI_PROTOCOL = 0, // Protocol of SI and MI (0=AXI4, 1=AXI3). parameter integer C_S_AXI_ID_WIDTH = 1, // Width of all ID signals on SI side of converter. // Range: 1 - 32. parameter integer C_SUPPORTS_ID = 0, // Indicates whether SI-side ID needs to be stored and compared. // 0 = No, SI is single-threaded, propagate all transactions. // 1 = Yes, stall any transaction with ID different than outstanding transactions. parameter integer C_AXI_ADDR_WIDTH = 32, // Width of all ADDR signals on SI and MI. // Range (AXI4, AXI3): 12 - 64. parameter integer C_S_AXI_DATA_WIDTH = 32, // Width of s_axi_wdata and s_axi_rdata. // Range: 32, 64, 128, 256, 512, 1024. parameter integer C_M_AXI_DATA_WIDTH = 64, // Width of m_axi_wdata and m_axi_rdata. // Assume always >= than C_S_AXI_DATA_WIDTH. // Range: 32, 64, 128, 256, 512, 1024. parameter integer C_AXI_SUPPORTS_WRITE = 1, parameter integer C_AXI_SUPPORTS_READ = 1, /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // parameter integer C_FIFO_MODE = 0, parameter integer C_FIFO_MODE = 1, // 0=None, 1=Packet_FIFO, 2=Clock_conversion_Packet_FIFO, 3=Simple_FIFO (FUTURE), 4=Clock_conversion_Simple_FIFO (FUTURE) parameter integer C_S_AXI_ACLK_RATIO = 1, // Clock frequency ratio of SI w.r.t. MI. // Range = [1..16]. parameter integer C_M_AXI_ACLK_RATIO = 2, // Clock frequency ratio of MI w.r.t. SI. // Range = [2..16] if C_S_AXI_ACLK_RATIO = 1; else must be 1. parameter integer C_AXI_IS_ACLK_ASYNC = 0, // Indicates whether S and M clocks are asynchronous. // FUTURE FEATURE // Range = [0, 1]. parameter integer C_PACKING_LEVEL = 1, // 0 = Never pack (expander only); packing logic is omitted. // 1 = Pack only when CACHE[1] (Modifiable) is high. // 2 = Always pack, regardless of sub-size transaction or Modifiable bit. // (Required when used as helper-core by mem-con. Same size AXI interfaces // should only be used when always packing) parameter integer C_SYNCHRONIZER_STAGE = 3 ) ( // Slave Interface input wire s_axi_aresetn, input wire s_axi_aclk, // Slave Interface Write Address Ports input wire [C_S_AXI_ID_WIDTH-1:0] s_axi_awid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr, input wire [8-1:0] s_axi_awlen, input wire [3-1:0] s_axi_awsize, input wire [2-1:0] s_axi_awburst, input wire [2-1:0] s_axi_awlock, input wire [4-1:0] s_axi_awcache, input wire [3-1:0] s_axi_awprot, input wire [4-1:0] s_axi_awregion, input wire [4-1:0] s_axi_awqos, input wire s_axi_awvalid, output wire s_axi_awready, // Slave Interface Write Data Ports input wire [C_S_AXI_DATA_WIDTH-1:0] s_axi_wdata, input wire [C_S_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb, input wire s_axi_wlast, input wire s_axi_wvalid, output wire s_axi_wready, // Slave Interface Write Response Ports output wire [C_S_AXI_ID_WIDTH-1:0] s_axi_bid, output wire [2-1:0] s_axi_bresp, output wire s_axi_bvalid, input wire s_axi_bready, // Slave Interface Read Address Ports input wire [C_S_AXI_ID_WIDTH-1:0] s_axi_arid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr, input wire [8-1:0] s_axi_arlen, input wire [3-1:0] s_axi_arsize, input wire [2-1:0] s_axi_arburst, input wire [2-1:0] s_axi_arlock, input wire [4-1:0] s_axi_arcache, input wire [3-1:0] s_axi_arprot, input wire [4-1:0] s_axi_arregion, input wire [4-1:0] s_axi_arqos, input wire s_axi_arvalid, output wire s_axi_arready, // Slave Interface Read Data Ports output wire [C_S_AXI_ID_WIDTH-1:0] s_axi_rid, output wire [C_S_AXI_DATA_WIDTH-1:0] s_axi_rdata, output wire [2-1:0] s_axi_rresp, output wire s_axi_rlast, output wire s_axi_rvalid, input wire s_axi_rready, // Master Interface input wire m_axi_aresetn, input wire m_axi_aclk, // Master Interface Write Address Port output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr, output wire [8-1:0] m_axi_awlen, output wire [3-1:0] m_axi_awsize, output wire [2-1:0] m_axi_awburst, output wire [2-1:0] m_axi_awlock, output wire [4-1:0] m_axi_awcache, output wire [3-1:0] m_axi_awprot, output wire [4-1:0] m_axi_awregion, output wire [4-1:0] m_axi_awqos, output wire m_axi_awvalid, input wire m_axi_awready, // Master Interface Write Data Ports output wire [C_M_AXI_DATA_WIDTH-1:0] m_axi_wdata, output wire [C_M_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb, output wire m_axi_wlast, output wire m_axi_wvalid, input wire m_axi_wready, // Master Interface Write Response Ports input wire [2-1:0] m_axi_bresp, input wire m_axi_bvalid, output wire m_axi_bready, // Master Interface Read Address Port output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr, output wire [8-1:0] m_axi_arlen, output wire [3-1:0] m_axi_arsize, output wire [2-1:0] m_axi_arburst, output wire [2-1:0] m_axi_arlock, output wire [4-1:0] m_axi_arcache, output wire [3-1:0] m_axi_arprot, output wire [4-1:0] m_axi_arregion, output wire [4-1:0] m_axi_arqos, output wire m_axi_arvalid, input wire m_axi_arready, // Master Interface Read Data Ports input wire [C_M_AXI_DATA_WIDTH-1:0] m_axi_rdata, input wire [2-1:0] m_axi_rresp, input wire m_axi_rlast, input wire m_axi_rvalid, output wire m_axi_rready ); // Log2 of number of 32bit word on SI-side. localparam integer C_S_AXI_BYTES_LOG = log2(C_S_AXI_DATA_WIDTH/8); // Log2 of number of 32bit word on MI-side. localparam integer C_M_AXI_BYTES_LOG = log2(C_M_AXI_DATA_WIDTH/8); // Log2 of Up-Sizing ratio for data. localparam integer C_RATIO = C_M_AXI_DATA_WIDTH / C_S_AXI_DATA_WIDTH; localparam integer C_RATIO_LOG = log2(C_RATIO); localparam P_BYPASS = 32'h0; localparam P_LIGHTWT = 32'h7; localparam P_FWD_REV = 32'h1; localparam integer P_CONV_LIGHT_WT = 0; localparam integer P_AXI4 = 0; localparam integer C_FIFO_DEPTH_LOG = 5; localparam P_SI_LT_MI = (C_S_AXI_ACLK_RATIO < C_M_AXI_ACLK_RATIO); localparam integer P_ACLK_RATIO = P_SI_LT_MI ? (C_M_AXI_ACLK_RATIO / C_S_AXI_ACLK_RATIO) : (C_S_AXI_ACLK_RATIO / C_M_AXI_ACLK_RATIO); localparam integer P_NO_FIFO = 0; localparam integer P_PKTFIFO = 1; localparam integer P_PKTFIFO_CLK = 2; localparam integer P_DATAFIFO = 3; localparam integer P_DATAFIFO_CLK = 4; localparam P_CLK_CONV = ((C_FIFO_MODE == P_PKTFIFO_CLK) || (C_FIFO_MODE == P_DATAFIFO_CLK)); localparam integer C_M_AXI_AW_REGISTER = 0; // Simple register AW output. // Range: 0, 1 localparam integer C_M_AXI_W_REGISTER = 1; // Parameter not used; W reg always implemented. localparam integer C_M_AXI_AR_REGISTER = 0; // Simple register AR output. // Range: 0, 1 localparam integer C_S_AXI_R_REGISTER = 0; // Simple register R output (SI). // Range: 0, 1 localparam integer C_M_AXI_R_REGISTER = 1; // Register slice on R input (MI) side. // 0 = Bypass (not recommended due to combinatorial M_RVALID -> M_RREADY path) // 1 = Fully-registered (needed only when upsizer propagates bursts at 1:1 width ratio) // 7 = Light-weight (safe when upsizer always packs at 1:n width ratio, as in interconnect) localparam integer P_RID_QUEUE = ((C_SUPPORTS_ID != 0) && !((C_FIFO_MODE == P_PKTFIFO) || (C_FIFO_MODE == P_PKTFIFO_CLK))) ? 1 : 0; ///////////////////////////////////////////////////////////////////////////// // Functions ///////////////////////////////////////////////////////////////////////////// // Log2. function integer log2 ( input integer x ); integer acc; begin acc=0; while ((2**acc) < x) acc = acc + 1; log2 = acc; end endfunction ///////////////////////////////////////////////////////////////////////////// // Internal signals ///////////////////////////////////////////////////////////////////////////// wire aclk; wire m_aclk; wire sample_cycle; wire sample_cycle_early; wire sm_aresetn; wire s_aresetn_i; wire [C_S_AXI_ID_WIDTH-1:0] sr_awid ; wire [C_AXI_ADDR_WIDTH-1:0] sr_awaddr ; wire [8-1:0] sr_awlen ; wire [3-1:0] sr_awsize ; wire [2-1:0] sr_awburst ; wire [2-1:0] sr_awlock ; wire [4-1:0] sr_awcache ; wire [3-1:0] sr_awprot ; wire [4-1:0] sr_awregion ; wire [4-1:0] sr_awqos ; wire sr_awvalid ; wire sr_awready ; wire [C_S_AXI_ID_WIDTH-1:0] sr_arid ; wire [C_AXI_ADDR_WIDTH-1:0] sr_araddr ; wire [8-1:0] sr_arlen ; wire [3-1:0] sr_arsize ; wire [2-1:0] sr_arburst ; wire [2-1:0] sr_arlock ; wire [4-1:0] sr_arcache ; wire [3-1:0] sr_arprot ; wire [4-1:0] sr_arregion ; wire [4-1:0] sr_arqos ; wire sr_arvalid ; wire sr_arready ; wire [C_S_AXI_DATA_WIDTH-1:0] sr_wdata ; wire [(C_S_AXI_DATA_WIDTH/8)-1:0] sr_wstrb ; wire sr_wlast ; wire sr_wvalid ; wire sr_wready ; wire [C_M_AXI_DATA_WIDTH-1:0] mr_rdata ; wire [2-1:0] mr_rresp ; wire mr_rlast ; wire mr_rvalid ; wire mr_rready ; wire m_axi_rready_i; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_awlen_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_arlen_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_awlock_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_arlock_i ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_awlen_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?8:4)-1:0] s_axi_arlen_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_awlock_ii ; wire [((C_AXI_PROTOCOL==P_AXI4)?1:2)-1:0] s_axi_arlock_ii ; wire [3:0] s_axi_awregion_ii; wire [3:0] s_axi_arregion_ii; assign s_axi_awlen_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlen : s_axi_awlen[3:0]; assign s_axi_awlock_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlock[0] : s_axi_awlock; assign s_axi_arlen_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlen : s_axi_arlen[3:0]; assign s_axi_arlock_i = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlock[0] : s_axi_arlock; assign sr_awlen = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awlen_ii: {4'b0, s_axi_awlen_ii}; assign sr_awlock = (C_AXI_PROTOCOL == P_AXI4) ? {1'b0, s_axi_awlock_ii} : s_axi_awlock_ii; assign sr_arlen = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arlen_ii: {4'b0, s_axi_arlen_ii}; assign sr_arlock = (C_AXI_PROTOCOL == P_AXI4) ? {1'b0, s_axi_arlock_ii} : s_axi_arlock_ii; assign sr_awregion = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_awregion_ii : 4'b0; assign sr_arregion = (C_AXI_PROTOCOL == P_AXI4) ? s_axi_arregion_ii : 4'b0; assign aclk = s_axi_aclk; assign sm_aresetn = s_axi_aresetn & m_axi_aresetn; generate if (P_CLK_CONV) begin : gen_clock_conv if (C_AXI_IS_ACLK_ASYNC) begin : gen_async_conv assign m_aclk = m_axi_aclk; assign s_aresetn_i = s_axi_aresetn; assign sample_cycle_early = 1'b1; assign sample_cycle = 1'b1; end else begin : gen_sync_conv wire fast_aclk; wire slow_aclk; reg s_aresetn_r; if (P_SI_LT_MI) begin : gen_fastclk_mi assign fast_aclk = m_axi_aclk; assign slow_aclk = s_axi_aclk; end else begin : gen_fastclk_si assign fast_aclk = s_axi_aclk; assign slow_aclk = m_axi_aclk; end assign m_aclk = m_axi_aclk; assign s_aresetn_i = s_aresetn_r; always @(negedge sm_aresetn, posedge fast_aclk) begin if (~sm_aresetn) begin s_aresetn_r <= 1'b0; end else if (s_axi_aresetn & m_axi_aresetn & sample_cycle_early) begin s_aresetn_r <= 1'b1; end end // Sample cycle used to determine when to assert a signal on a fast clock // to be flopped onto a slow clock. axi_clock_converter_v2_1_6_axic_sample_cycle_ratio #( .C_RATIO ( P_ACLK_RATIO ) ) axic_sample_cycle_inst ( .SLOW_ACLK ( slow_aclk ) , .FAST_ACLK ( fast_aclk ) , .SAMPLE_CYCLE_EARLY ( sample_cycle_early ) , .SAMPLE_CYCLE ( sample_cycle ) ); end end else begin : gen_no_clk_conv assign m_aclk = s_axi_aclk; assign s_aresetn_i = s_axi_aresetn; assign sample_cycle_early = 1'b1; assign sample_cycle = 1'b1; end // gen_clock_conv axi_register_slice_v2_1_7_axi_register_slice # ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (0), .C_REG_CONFIG_AW (C_AXI_SUPPORTS_WRITE ? P_LIGHTWT : P_BYPASS), .C_REG_CONFIG_AR (C_AXI_SUPPORTS_READ ? P_LIGHTWT : P_BYPASS) ) si_register_slice_inst ( .aresetn (s_aresetn_i), .aclk (aclk), .s_axi_awid (s_axi_awid ), .s_axi_awaddr (s_axi_awaddr ), .s_axi_awlen (s_axi_awlen_i ), .s_axi_awsize (s_axi_awsize ), .s_axi_awburst (s_axi_awburst ), .s_axi_awlock (s_axi_awlock_i ), .s_axi_awcache (s_axi_awcache ), .s_axi_awprot (s_axi_awprot ), .s_axi_awregion (s_axi_awregion ), .s_axi_awqos (s_axi_awqos ), .s_axi_awuser (1'b0 ), .s_axi_awvalid (s_axi_awvalid ), .s_axi_awready (s_axi_awready ), .s_axi_wid ( {C_S_AXI_ID_WIDTH{1'b0}}), .s_axi_wdata ( {C_S_AXI_DATA_WIDTH{1'b0}} ), .s_axi_wstrb ( {C_S_AXI_DATA_WIDTH/8{1'b0}} ), .s_axi_wlast ( 1'b0 ), .s_axi_wuser ( 1'b0 ), .s_axi_wvalid ( 1'b0 ), .s_axi_wready ( ), .s_axi_bid ( ), .s_axi_bresp ( ), .s_axi_buser ( ), .s_axi_bvalid ( ), .s_axi_bready ( 1'b0 ), .s_axi_arid (s_axi_arid ), .s_axi_araddr (s_axi_araddr ), .s_axi_arlen (s_axi_arlen_i ), .s_axi_arsize (s_axi_arsize ), .s_axi_arburst (s_axi_arburst ), .s_axi_arlock (s_axi_arlock_i ), .s_axi_arcache (s_axi_arcache ), .s_axi_arprot (s_axi_arprot ), .s_axi_arregion (s_axi_arregion ), .s_axi_arqos (s_axi_arqos ), .s_axi_aruser (1'b0 ), .s_axi_arvalid (s_axi_arvalid ), .s_axi_arready (s_axi_arready ), .s_axi_rid ( ) , .s_axi_rdata ( ) , .s_axi_rresp ( ) , .s_axi_rlast ( ) , .s_axi_ruser ( ) , .s_axi_rvalid ( ) , .s_axi_rready ( 1'b0 ) , .m_axi_awid (sr_awid ), .m_axi_awaddr (sr_awaddr ), .m_axi_awlen (s_axi_awlen_ii), .m_axi_awsize (sr_awsize ), .m_axi_awburst (sr_awburst ), .m_axi_awlock (s_axi_awlock_ii), .m_axi_awcache (sr_awcache ), .m_axi_awprot (sr_awprot ), .m_axi_awregion (s_axi_awregion_ii ), .m_axi_awqos (sr_awqos ), .m_axi_awuser (), .m_axi_awvalid (sr_awvalid ), .m_axi_awready (sr_awready ), .m_axi_wid () , .m_axi_wdata (), .m_axi_wstrb (), .m_axi_wlast (), .m_axi_wuser (), .m_axi_wvalid (), .m_axi_wready (1'b0), .m_axi_bid ( {C_S_AXI_ID_WIDTH{1'b0}} ) , .m_axi_bresp ( 2'b0 ) , .m_axi_buser ( 1'b0 ) , .m_axi_bvalid ( 1'b0 ) , .m_axi_bready ( ) , .m_axi_arid (sr_arid ), .m_axi_araddr (sr_araddr ), .m_axi_arlen (s_axi_arlen_ii), .m_axi_arsize (sr_arsize ), .m_axi_arburst (sr_arburst ), .m_axi_arlock (s_axi_arlock_ii), .m_axi_arcache (sr_arcache ), .m_axi_arprot (sr_arprot ), .m_axi_arregion (s_axi_arregion_ii ), .m_axi_arqos (sr_arqos ), .m_axi_aruser (), .m_axi_arvalid (sr_arvalid ), .m_axi_arready (sr_arready ), .m_axi_rid ( {C_S_AXI_ID_WIDTH{1'b0}}), .m_axi_rdata ( {C_S_AXI_DATA_WIDTH{1'b0}} ), .m_axi_rresp ( 2'b00 ), .m_axi_rlast ( 1'b0 ), .m_axi_ruser ( 1'b0 ), .m_axi_rvalid ( 1'b0 ), .m_axi_rready ( ) ); ///////////////////////////////////////////////////////////////////////////// // Handle Write Channels (AW/W/B) ///////////////////////////////////////////////////////////////////////////// if (C_AXI_SUPPORTS_WRITE == 1) begin : USE_WRITE wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr_i ; wire [8-1:0] m_axi_awlen_i ; wire [3-1:0] m_axi_awsize_i ; wire [2-1:0] m_axi_awburst_i ; wire [2-1:0] m_axi_awlock_i ; wire [4-1:0] m_axi_awcache_i ; wire [3-1:0] m_axi_awprot_i ; wire [4-1:0] m_axi_awregion_i ; wire [4-1:0] m_axi_awqos_i ; wire m_axi_awvalid_i ; wire m_axi_awready_i ; wire s_axi_bvalid_i ; wire [2-1:0] s_axi_bresp_i ; wire [C_AXI_ADDR_WIDTH-1:0] wr_cmd_si_addr; wire [8-1:0] wr_cmd_si_len; wire [3-1:0] wr_cmd_si_size; wire [2-1:0] wr_cmd_si_burst; // Write Channel Signals for Commands Queue Interface. wire wr_cmd_valid; wire wr_cmd_fix; wire wr_cmd_modified; wire wr_cmd_complete_wrap; wire wr_cmd_packed_wrap; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_first_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_next_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_last_word; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_offset; wire [C_M_AXI_BYTES_LOG-1:0] wr_cmd_mask; wire [C_S_AXI_BYTES_LOG:0] wr_cmd_step; wire [8-1:0] wr_cmd_length; wire wr_cmd_ready; wire wr_cmd_id_ready; wire [C_S_AXI_ID_WIDTH-1:0] wr_cmd_id; wire wpush; wire wpop; reg [C_FIFO_DEPTH_LOG-1:0] wcnt; // Write Address Channel. axi_dwidth_converter_v2_1_7_a_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_SUPPORTS_ID (C_SUPPORTS_ID), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (C_M_AXI_AW_REGISTER), .C_AXI_CHANNEL (0), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_FIFO_MODE (C_FIFO_MODE), .C_ID_QUEUE (C_SUPPORTS_ID), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG) ) write_addr_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (wr_cmd_valid), .cmd_fix (wr_cmd_fix), .cmd_modified (wr_cmd_modified), .cmd_complete_wrap (wr_cmd_complete_wrap), .cmd_packed_wrap (wr_cmd_packed_wrap), .cmd_first_word (wr_cmd_first_word), .cmd_next_word (wr_cmd_next_word), .cmd_last_word (wr_cmd_last_word), .cmd_offset (wr_cmd_offset), .cmd_mask (wr_cmd_mask), .cmd_step (wr_cmd_step), .cmd_length (wr_cmd_length), .cmd_ready (wr_cmd_ready), .cmd_id (wr_cmd_id), .cmd_id_ready (wr_cmd_id_ready), .cmd_si_addr (wr_cmd_si_addr ), .cmd_si_id (), .cmd_si_len (wr_cmd_si_len ), .cmd_si_size (wr_cmd_si_size ), .cmd_si_burst (wr_cmd_si_burst), // Slave Interface Write Address Ports .S_AXI_AID (sr_awid), .S_AXI_AADDR (sr_awaddr), .S_AXI_ALEN (sr_awlen), .S_AXI_ASIZE (sr_awsize), .S_AXI_ABURST (sr_awburst), .S_AXI_ALOCK (sr_awlock), .S_AXI_ACACHE (sr_awcache), .S_AXI_APROT (sr_awprot), .S_AXI_AREGION (sr_awregion), .S_AXI_AQOS (sr_awqos), .S_AXI_AVALID (sr_awvalid), .S_AXI_AREADY (sr_awready), // Master Interface Write Address Port .M_AXI_AADDR (m_axi_awaddr_i ), .M_AXI_ALEN (m_axi_awlen_i ), .M_AXI_ASIZE (m_axi_awsize_i ), .M_AXI_ABURST (m_axi_awburst_i ), .M_AXI_ALOCK (m_axi_awlock_i ), .M_AXI_ACACHE (m_axi_awcache_i ), .M_AXI_APROT (m_axi_awprot_i ), .M_AXI_AREGION (m_axi_awregion_i ), .M_AXI_AQOS (m_axi_awqos_i ), .M_AXI_AVALID (m_axi_awvalid_i ), .M_AXI_AREADY (m_axi_awready_i ) ); if ((C_FIFO_MODE == P_PKTFIFO) || (C_FIFO_MODE == P_PKTFIFO_CLK)) begin : gen_pktfifo_w_upsizer // Packet FIFO Write Data channel. axi_dwidth_converter_v2_1_7_w_upsizer_pktfifo # ( .C_FAMILY (C_FAMILY), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG), .C_CLK_CONV (P_CLK_CONV), .C_S_AXI_ACLK_RATIO (C_S_AXI_ACLK_RATIO), .C_M_AXI_ACLK_RATIO (C_M_AXI_ACLK_RATIO), .C_AXI_IS_ACLK_ASYNC (C_AXI_IS_ACLK_ASYNC), .C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE) ) pktfifo_write_data_inst ( .S_AXI_ARESETN ( s_axi_aresetn ) , .S_AXI_ACLK ( s_axi_aclk ) , .M_AXI_ARESETN ( m_axi_aresetn ) , .M_AXI_ACLK ( m_axi_aclk ) , // Command Interface .cmd_si_addr (wr_cmd_si_addr ), .cmd_si_len (wr_cmd_si_len ), .cmd_si_size (wr_cmd_si_size ), .cmd_si_burst (wr_cmd_si_burst), .cmd_ready (wr_cmd_ready), // Slave Interface Write Address Ports .S_AXI_AWADDR (m_axi_awaddr_i ), .S_AXI_AWLEN (m_axi_awlen_i ), .S_AXI_AWSIZE (m_axi_awsize_i ), .S_AXI_AWBURST (m_axi_awburst_i ), .S_AXI_AWLOCK (m_axi_awlock_i ), .S_AXI_AWCACHE (m_axi_awcache_i ), .S_AXI_AWPROT (m_axi_awprot_i ), .S_AXI_AWREGION (m_axi_awregion_i ), .S_AXI_AWQOS (m_axi_awqos_i ), .S_AXI_AWVALID (m_axi_awvalid_i ), .S_AXI_AWREADY (m_axi_awready_i ), // Master Interface Write Address Port .M_AXI_AWADDR (m_axi_awaddr), .M_AXI_AWLEN (m_axi_awlen), .M_AXI_AWSIZE (m_axi_awsize), .M_AXI_AWBURST (m_axi_awburst), .M_AXI_AWLOCK (m_axi_awlock), .M_AXI_AWCACHE (m_axi_awcache), .M_AXI_AWPROT (m_axi_awprot), .M_AXI_AWREGION (m_axi_awregion), .M_AXI_AWQOS (m_axi_awqos), .M_AXI_AWVALID (m_axi_awvalid), .M_AXI_AWREADY (m_axi_awready), // Slave Interface Write Data Ports .S_AXI_WDATA (s_axi_wdata), .S_AXI_WSTRB (s_axi_wstrb), .S_AXI_WLAST (s_axi_wlast), .S_AXI_WVALID (s_axi_wvalid), .S_AXI_WREADY (s_axi_wready), // Master Interface Write Data Ports .M_AXI_WDATA (m_axi_wdata), .M_AXI_WSTRB (m_axi_wstrb), .M_AXI_WLAST (m_axi_wlast), .M_AXI_WVALID (m_axi_wvalid), .M_AXI_WREADY (m_axi_wready), .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early) ); end else begin : gen_non_fifo_w_upsizer // Write Data channel. axi_dwidth_converter_v2_1_7_w_upsizer # ( .C_FAMILY ("rtl"), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (1), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG) ) write_data_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (wr_cmd_valid), .cmd_fix (wr_cmd_fix), .cmd_modified (wr_cmd_modified), .cmd_complete_wrap (wr_cmd_complete_wrap), .cmd_packed_wrap (wr_cmd_packed_wrap), .cmd_first_word (wr_cmd_first_word), .cmd_next_word (wr_cmd_next_word), .cmd_last_word (wr_cmd_last_word), .cmd_offset (wr_cmd_offset), .cmd_mask (wr_cmd_mask), .cmd_step (wr_cmd_step), .cmd_length (wr_cmd_length), .cmd_ready (wr_cmd_ready), // Slave Interface Write Data Ports .S_AXI_WDATA (s_axi_wdata), .S_AXI_WSTRB (s_axi_wstrb), .S_AXI_WLAST (s_axi_wlast), .S_AXI_WVALID (s_axi_wvalid), .S_AXI_WREADY (s_axi_wready), // Master Interface Write Data Ports .M_AXI_WDATA (m_axi_wdata), .M_AXI_WSTRB (m_axi_wstrb), .M_AXI_WLAST (m_axi_wlast), .M_AXI_WVALID (m_axi_wvalid), .M_AXI_WREADY (m_axi_wready) ); assign m_axi_awaddr = m_axi_awaddr_i ; assign m_axi_awlen = m_axi_awlen_i ; assign m_axi_awsize = m_axi_awsize_i ; assign m_axi_awburst = m_axi_awburst_i ; assign m_axi_awlock = m_axi_awlock_i ; assign m_axi_awcache = m_axi_awcache_i ; assign m_axi_awprot = m_axi_awprot_i ; assign m_axi_awregion = m_axi_awregion_i ; assign m_axi_awqos = m_axi_awqos_i ; assign m_axi_awvalid = m_axi_awvalid_i ; assign m_axi_awready_i = m_axi_awready ; end // gen_w_upsizer // Write Response channel. assign wr_cmd_id_ready = s_axi_bvalid_i & s_axi_bready; assign s_axi_bid = wr_cmd_id; assign s_axi_bresp = s_axi_bresp_i; assign s_axi_bvalid = s_axi_bvalid_i; if (P_CLK_CONV) begin : gen_b_clk_conv if (C_AXI_IS_ACLK_ASYNC == 0) begin : gen_b_sync_conv axi_clock_converter_v2_1_6_axic_sync_clock_converter #( .C_FAMILY ( C_FAMILY ) , .C_PAYLOAD_WIDTH ( 2 ) , .C_M_ACLK_RATIO ( P_SI_LT_MI ? 1 : P_ACLK_RATIO ) , .C_S_ACLK_RATIO ( P_SI_LT_MI ? P_ACLK_RATIO : 1 ) , .C_MODE(P_CONV_LIGHT_WT) ) b_sync_clock_converter ( .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early), .S_ACLK ( m_axi_aclk ) , .S_ARESETN ( m_axi_aresetn ) , .S_PAYLOAD ( m_axi_bresp ) , .S_VALID ( m_axi_bvalid ) , .S_READY ( m_axi_bready ) , .M_ACLK ( s_axi_aclk ) , .M_ARESETN ( s_axi_aresetn ) , .M_PAYLOAD ( s_axi_bresp_i ) , .M_VALID ( s_axi_bvalid_i ) , .M_READY ( s_axi_bready ) ); end else begin : gen_b_async_conv fifo_generator_v13_0_1 #( .C_COMMON_CLOCK(0), .C_SYNCHRONIZER_STAGE(C_SYNCHRONIZER_STAGE), .C_INTERFACE_TYPE(2), .C_AXI_TYPE(1), .C_HAS_AXI_ID(1), .C_AXI_LEN_WIDTH(8), .C_AXI_LOCK_WIDTH(2), .C_DIN_WIDTH_WACH(63), .C_DIN_WIDTH_WDCH(38), .C_DIN_WIDTH_WRCH(3), .C_DIN_WIDTH_RACH(63), .C_DIN_WIDTH_RDCH(36), .C_COUNT_TYPE(0), .C_DATA_COUNT_WIDTH(10), .C_DEFAULT_VALUE("BlankString"), .C_DIN_WIDTH(18), .C_DOUT_RST_VAL("0"), .C_DOUT_WIDTH(18), .C_ENABLE_RLOCS(0), .C_FAMILY(C_FAMILY), .C_FULL_FLAGS_RST_VAL(1), .C_HAS_ALMOST_EMPTY(0), .C_HAS_ALMOST_FULL(0), .C_HAS_BACKUP(0), .C_HAS_DATA_COUNT(0), .C_HAS_INT_CLK(0), .C_HAS_MEMINIT_FILE(0), .C_HAS_OVERFLOW(0), .C_HAS_RD_DATA_COUNT(0), .C_HAS_RD_RST(0), .C_HAS_RST(1), .C_HAS_SRST(0), .C_HAS_UNDERFLOW(0), .C_HAS_VALID(0), .C_HAS_WR_ACK(0), .C_HAS_WR_DATA_COUNT(0), .C_HAS_WR_RST(0), .C_IMPLEMENTATION_TYPE(0), .C_INIT_WR_PNTR_VAL(0), .C_MEMORY_TYPE(1), .C_MIF_FILE_NAME("BlankString"), .C_OPTIMIZATION_MODE(0), .C_OVERFLOW_LOW(0), .C_PRELOAD_LATENCY(1), .C_PRELOAD_REGS(0), .C_PRIM_FIFO_TYPE("4kx4"), .C_PROG_EMPTY_THRESH_ASSERT_VAL(2), .C_PROG_EMPTY_THRESH_NEGATE_VAL(3), .C_PROG_EMPTY_TYPE(0), .C_PROG_FULL_THRESH_ASSERT_VAL(1022), .C_PROG_FULL_THRESH_NEGATE_VAL(1021), .C_PROG_FULL_TYPE(0), .C_RD_DATA_COUNT_WIDTH(10), .C_RD_DEPTH(1024), .C_RD_FREQ(1), .C_RD_PNTR_WIDTH(10), .C_UNDERFLOW_LOW(0), .C_USE_DOUT_RST(1), .C_USE_ECC(0), .C_USE_EMBEDDED_REG(0), .C_USE_FIFO16_FLAGS(0), .C_USE_FWFT_DATA_COUNT(0), .C_VALID_LOW(0), .C_WR_ACK_LOW(0), .C_WR_DATA_COUNT_WIDTH(10), .C_WR_DEPTH(1024), .C_WR_FREQ(1), .C_WR_PNTR_WIDTH(10), .C_WR_RESPONSE_LATENCY(1), .C_MSGON_VAL(1), .C_ENABLE_RST_SYNC(1), .C_ERROR_INJECTION_TYPE(0), .C_HAS_AXI_WR_CHANNEL(1), .C_HAS_AXI_RD_CHANNEL(0), .C_HAS_SLAVE_CE(0), .C_HAS_MASTER_CE(0), .C_ADD_NGC_CONSTRAINT(0), .C_USE_COMMON_OVERFLOW(0), .C_USE_COMMON_UNDERFLOW(0), .C_USE_DEFAULT_SETTINGS(0), .C_AXI_ID_WIDTH(1), .C_AXI_ADDR_WIDTH(32), .C_AXI_DATA_WIDTH(32), .C_HAS_AXI_AWUSER(0), .C_HAS_AXI_WUSER(0), .C_HAS_AXI_BUSER(0), .C_HAS_AXI_ARUSER(0), .C_HAS_AXI_RUSER(0), .C_AXI_ARUSER_WIDTH(1), .C_AXI_AWUSER_WIDTH(1), .C_AXI_WUSER_WIDTH(1), .C_AXI_BUSER_WIDTH(1), .C_AXI_RUSER_WIDTH(1), .C_HAS_AXIS_TDATA(0), .C_HAS_AXIS_TID(0), .C_HAS_AXIS_TDEST(0), .C_HAS_AXIS_TUSER(0), .C_HAS_AXIS_TREADY(1), .C_HAS_AXIS_TLAST(0), .C_HAS_AXIS_TSTRB(0), .C_HAS_AXIS_TKEEP(0), .C_AXIS_TDATA_WIDTH(64), .C_AXIS_TID_WIDTH(8), .C_AXIS_TDEST_WIDTH(4), .C_AXIS_TUSER_WIDTH(4), .C_AXIS_TSTRB_WIDTH(4), .C_AXIS_TKEEP_WIDTH(4), .C_WACH_TYPE(2), .C_WDCH_TYPE(2), .C_WRCH_TYPE(0), .C_RACH_TYPE(0), .C_RDCH_TYPE(0), .C_AXIS_TYPE(0), .C_IMPLEMENTATION_TYPE_WACH(12), .C_IMPLEMENTATION_TYPE_WDCH(11), .C_IMPLEMENTATION_TYPE_WRCH(12), .C_IMPLEMENTATION_TYPE_RACH(12), .C_IMPLEMENTATION_TYPE_RDCH(11), .C_IMPLEMENTATION_TYPE_AXIS(11), .C_APPLICATION_TYPE_WACH(0), .C_APPLICATION_TYPE_WDCH(0), .C_APPLICATION_TYPE_WRCH(0), .C_APPLICATION_TYPE_RACH(0), .C_APPLICATION_TYPE_RDCH(0), .C_APPLICATION_TYPE_AXIS(0), .C_USE_ECC_WACH(0), .C_USE_ECC_WDCH(0), .C_USE_ECC_WRCH(0), .C_USE_ECC_RACH(0), .C_USE_ECC_RDCH(0), .C_USE_ECC_AXIS(0), .C_ERROR_INJECTION_TYPE_WACH(0), .C_ERROR_INJECTION_TYPE_WDCH(0), .C_ERROR_INJECTION_TYPE_WRCH(0), .C_ERROR_INJECTION_TYPE_RACH(0), .C_ERROR_INJECTION_TYPE_RDCH(0), .C_ERROR_INJECTION_TYPE_AXIS(0), .C_DIN_WIDTH_AXIS(1), .C_WR_DEPTH_WACH(16), .C_WR_DEPTH_WDCH(1024), .C_WR_DEPTH_WRCH(32), .C_WR_DEPTH_RACH(16), .C_WR_DEPTH_RDCH(1024), .C_WR_DEPTH_AXIS(1024), .C_WR_PNTR_WIDTH_WACH(4), .C_WR_PNTR_WIDTH_WDCH(10), .C_WR_PNTR_WIDTH_WRCH(5), .C_WR_PNTR_WIDTH_RACH(4), .C_WR_PNTR_WIDTH_RDCH(10), .C_WR_PNTR_WIDTH_AXIS(10), .C_HAS_DATA_COUNTS_WACH(0), .C_HAS_DATA_COUNTS_WDCH(0), .C_HAS_DATA_COUNTS_WRCH(0), .C_HAS_DATA_COUNTS_RACH(0), .C_HAS_DATA_COUNTS_RDCH(0), .C_HAS_DATA_COUNTS_AXIS(0), .C_HAS_PROG_FLAGS_WACH(0), .C_HAS_PROG_FLAGS_WDCH(0), .C_HAS_PROG_FLAGS_WRCH(0), .C_HAS_PROG_FLAGS_RACH(0), .C_HAS_PROG_FLAGS_RDCH(0), .C_HAS_PROG_FLAGS_AXIS(0), .C_PROG_FULL_TYPE_WACH(0), .C_PROG_FULL_TYPE_WDCH(0), .C_PROG_FULL_TYPE_WRCH(0), .C_PROG_FULL_TYPE_RACH(0), .C_PROG_FULL_TYPE_RDCH(0), .C_PROG_FULL_TYPE_AXIS(0), .C_PROG_FULL_THRESH_ASSERT_VAL_WACH(15), .C_PROG_FULL_THRESH_ASSERT_VAL_WDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_WRCH(31), .C_PROG_FULL_THRESH_ASSERT_VAL_RACH(15), .C_PROG_FULL_THRESH_ASSERT_VAL_RDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_AXIS(1023), .C_PROG_EMPTY_TYPE_WACH(0), .C_PROG_EMPTY_TYPE_WDCH(0), .C_PROG_EMPTY_TYPE_WRCH(0), .C_PROG_EMPTY_TYPE_RACH(0), .C_PROG_EMPTY_TYPE_RDCH(0), .C_PROG_EMPTY_TYPE_AXIS(0), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH(13), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH(1021), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH(29), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH(13), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH(1021), .C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS(1021), .C_REG_SLICE_MODE_WACH(0), .C_REG_SLICE_MODE_WDCH(0), .C_REG_SLICE_MODE_WRCH(0), .C_REG_SLICE_MODE_RACH(0), .C_REG_SLICE_MODE_RDCH(0), .C_REG_SLICE_MODE_AXIS(0) ) dw_fifogen_b_async ( .m_aclk(m_axi_aclk), .s_aclk(s_axi_aclk), .s_aresetn(sm_aresetn), .s_axi_awid(1'b0), .s_axi_awaddr(32'b0), .s_axi_awlen(8'b0), .s_axi_awsize(3'b0), .s_axi_awburst(2'b0), .s_axi_awlock(2'b0), .s_axi_awcache(4'b0), .s_axi_awprot(3'b0), .s_axi_awqos(4'b0), .s_axi_awregion(4'b0), .s_axi_awuser(1'b0), .s_axi_awvalid(1'b0), .s_axi_awready(), .s_axi_wid(1'b0), .s_axi_wdata(32'b0), .s_axi_wstrb(4'b0), .s_axi_wlast(1'b0), .s_axi_wuser(1'b0), .s_axi_wvalid(1'b0), .s_axi_wready(), .s_axi_bid(), .s_axi_bresp(s_axi_bresp_i), .s_axi_buser(), .s_axi_bvalid(s_axi_bvalid_i), .s_axi_bready(s_axi_bready), .m_axi_awid(), .m_axi_awaddr(), .m_axi_awlen(), .m_axi_awsize(), .m_axi_awburst(), .m_axi_awlock(), .m_axi_awcache(), .m_axi_awprot(), .m_axi_awqos(), .m_axi_awregion(), .m_axi_awuser(), .m_axi_awvalid(), .m_axi_awready(1'b0), .m_axi_wid(), .m_axi_wdata(), .m_axi_wstrb(), .m_axi_wlast(), .m_axi_wuser(), .m_axi_wvalid(), .m_axi_wready(1'b0), .m_axi_bid(1'b0), .m_axi_bresp(m_axi_bresp), .m_axi_buser(1'b0), .m_axi_bvalid(m_axi_bvalid), .m_axi_bready(m_axi_bready), .s_axi_arid(1'b0), .s_axi_araddr(32'b0), .s_axi_arlen(8'b0), .s_axi_arsize(3'b0), .s_axi_arburst(2'b0), .s_axi_arlock(2'b0), .s_axi_arcache(4'b0), .s_axi_arprot(3'b0), .s_axi_arqos(4'b0), .s_axi_arregion(4'b0), .s_axi_aruser(1'b0), .s_axi_arvalid(1'b0), .s_axi_arready(), .s_axi_rid(), .s_axi_rdata(), .s_axi_rresp(), .s_axi_rlast(), .s_axi_ruser(), .s_axi_rvalid(), .s_axi_rready(1'b0), .m_axi_arid(), .m_axi_araddr(), .m_axi_arlen(), .m_axi_arsize(), .m_axi_arburst(), .m_axi_arlock(), .m_axi_arcache(), .m_axi_arprot(), .m_axi_arqos(), .m_axi_arregion(), .m_axi_aruser(), .m_axi_arvalid(), .m_axi_arready(1'b0), .m_axi_rid(1'b0), .m_axi_rdata(32'b0), .m_axi_rresp(2'b0), .m_axi_rlast(1'b0), .m_axi_ruser(1'b0), .m_axi_rvalid(1'b0), .m_axi_rready(), .m_aclk_en(1'b0), .s_aclk_en(1'b0), .backup(1'b0), .backup_marker(1'b0), .clk(1'b0), .rst(1'b0), .srst(1'b0), .wr_clk(1'b0), .wr_rst(1'b0), .rd_clk(1'b0), .rd_rst(1'b0), .din(18'b0), .wr_en(1'b0), .rd_en(1'b0), .prog_empty_thresh(10'b0), .prog_empty_thresh_assert(10'b0), .prog_empty_thresh_negate(10'b0), .prog_full_thresh(10'b0), .prog_full_thresh_assert(10'b0), .prog_full_thresh_negate(10'b0), .int_clk(1'b0), .injectdbiterr(1'b0), .injectsbiterr(1'b0), .dout(), .full(), .almost_full(), .wr_ack(), .overflow(), .empty(), .almost_empty(), .valid(), .underflow(), .data_count(), .rd_data_count(), .wr_data_count(), .prog_full(), .prog_empty(), .sbiterr(), .dbiterr(), .s_axis_tvalid(1'b0), .s_axis_tready(), .s_axis_tdata(64'b0), .s_axis_tstrb(4'b0), .s_axis_tkeep(4'b0), .s_axis_tlast(1'b0), .s_axis_tid(8'b0), .s_axis_tdest(4'b0), .s_axis_tuser(4'b0), .m_axis_tvalid(), .m_axis_tready(1'b0), .m_axis_tdata(), .m_axis_tstrb(), .m_axis_tkeep(), .m_axis_tlast(), .m_axis_tid(), .m_axis_tdest(), .m_axis_tuser(), .axi_aw_injectsbiterr(1'b0), .axi_aw_injectdbiterr(1'b0), .axi_aw_prog_full_thresh(4'b0), .axi_aw_prog_empty_thresh(4'b0), .axi_aw_data_count(), .axi_aw_wr_data_count(), .axi_aw_rd_data_count(), .axi_aw_sbiterr(), .axi_aw_dbiterr(), .axi_aw_overflow(), .axi_aw_underflow(), .axi_aw_prog_full(), .axi_aw_prog_empty(), .axi_w_injectsbiterr(1'b0), .axi_w_injectdbiterr(1'b0), .axi_w_prog_full_thresh(10'b0), .axi_w_prog_empty_thresh(10'b0), .axi_w_data_count(), .axi_w_wr_data_count(), .axi_w_rd_data_count(), .axi_w_sbiterr(), .axi_w_dbiterr(), .axi_w_overflow(), .axi_w_underflow(), .axi_b_injectsbiterr(1'b0), .axi_w_prog_full(), .axi_w_prog_empty(), .axi_b_injectdbiterr(1'b0), .axi_b_prog_full_thresh(5'b0), .axi_b_prog_empty_thresh(5'b0), .axi_b_data_count(), .axi_b_wr_data_count(), .axi_b_rd_data_count(), .axi_b_sbiterr(), .axi_b_dbiterr(), .axi_b_overflow(), .axi_b_underflow(), .axi_ar_injectsbiterr(1'b0), .axi_b_prog_full(), .axi_b_prog_empty(), .axi_ar_injectdbiterr(1'b0), .axi_ar_prog_full_thresh(4'b0), .axi_ar_prog_empty_thresh(4'b0), .axi_ar_data_count(), .axi_ar_wr_data_count(), .axi_ar_rd_data_count(), .axi_ar_sbiterr(), .axi_ar_dbiterr(), .axi_ar_overflow(), .axi_ar_underflow(), .axi_ar_prog_full(), .axi_ar_prog_empty(), .axi_r_injectsbiterr(1'b0), .axi_r_injectdbiterr(1'b0), .axi_r_prog_full_thresh(10'b0), .axi_r_prog_empty_thresh(10'b0), .axi_r_data_count(), .axi_r_wr_data_count(), .axi_r_rd_data_count(), .axi_r_sbiterr(), .axi_r_dbiterr(), .axi_r_overflow(), .axi_r_underflow(), .axis_injectsbiterr(1'b0), .axi_r_prog_full(), .axi_r_prog_empty(), .axis_injectdbiterr(1'b0), .axis_prog_full_thresh(10'b0), .axis_prog_empty_thresh(10'b0), .axis_data_count(), .axis_wr_data_count(), .axis_rd_data_count(), .axis_sbiterr(), .axis_dbiterr(), .axis_overflow(), .axis_underflow(), .axis_prog_full(), .axis_prog_empty(), .wr_rst_busy(), .rd_rst_busy(), .sleep(1'b0) ); end end else begin : gen_b_passthru assign m_axi_bready = s_axi_bready; assign s_axi_bresp_i = m_axi_bresp; assign s_axi_bvalid_i = m_axi_bvalid; end // gen_b end else begin : NO_WRITE assign sr_awready = 1'b0; assign s_axi_wready = 1'b0; assign s_axi_bid = {C_S_AXI_ID_WIDTH{1'b0}}; assign s_axi_bresp = 2'b0; assign s_axi_bvalid = 1'b0; assign m_axi_awaddr = {C_AXI_ADDR_WIDTH{1'b0}}; assign m_axi_awlen = 8'b0; assign m_axi_awsize = 3'b0; assign m_axi_awburst = 2'b0; assign m_axi_awlock = 2'b0; assign m_axi_awcache = 4'b0; assign m_axi_awprot = 3'b0; assign m_axi_awregion = 4'b0; assign m_axi_awqos = 4'b0; assign m_axi_awvalid = 1'b0; assign m_axi_wdata = {C_M_AXI_DATA_WIDTH{1'b0}}; assign m_axi_wstrb = {C_M_AXI_DATA_WIDTH/8{1'b0}}; assign m_axi_wlast = 1'b0; assign m_axi_wvalid = 1'b0; assign m_axi_bready = 1'b0; end endgenerate ///////////////////////////////////////////////////////////////////////////// // Handle Read Channels (AR/R) ///////////////////////////////////////////////////////////////////////////// generate if (C_AXI_SUPPORTS_READ == 1) begin : USE_READ wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr_i ; wire [8-1:0] m_axi_arlen_i ; wire [3-1:0] m_axi_arsize_i ; wire [2-1:0] m_axi_arburst_i ; wire [2-1:0] m_axi_arlock_i ; wire [4-1:0] m_axi_arcache_i ; wire [3-1:0] m_axi_arprot_i ; wire [4-1:0] m_axi_arregion_i ; wire [4-1:0] m_axi_arqos_i ; wire m_axi_arvalid_i ; wire m_axi_arready_i ; // Read Channel Signals for Commands Queue Interface. wire rd_cmd_valid; wire rd_cmd_fix; wire rd_cmd_modified; wire rd_cmd_complete_wrap; wire rd_cmd_packed_wrap; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_first_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_next_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_last_word; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_offset; wire [C_M_AXI_BYTES_LOG-1:0] rd_cmd_mask; wire [C_S_AXI_BYTES_LOG:0] rd_cmd_step; wire [8-1:0] rd_cmd_length; wire rd_cmd_ready; wire [C_S_AXI_ID_WIDTH-1:0] rd_cmd_id; wire [C_AXI_ADDR_WIDTH-1:0] rd_cmd_si_addr; wire [C_S_AXI_ID_WIDTH-1:0] rd_cmd_si_id; wire [8-1:0] rd_cmd_si_len; wire [3-1:0] rd_cmd_si_size; wire [2-1:0] rd_cmd_si_burst; // Read Address Channel. axi_dwidth_converter_v2_1_7_a_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_SUPPORTS_ID (C_SUPPORTS_ID), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_M_AXI_REGISTER (C_M_AXI_AR_REGISTER), .C_AXI_CHANNEL (1), .C_PACKING_LEVEL (C_PACKING_LEVEL), // .C_FIFO_MODE (0), .C_FIFO_MODE (C_FIFO_MODE), .C_ID_QUEUE (P_RID_QUEUE), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG) ) read_addr_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (rd_cmd_valid), .cmd_fix (rd_cmd_fix), .cmd_modified (rd_cmd_modified), .cmd_complete_wrap (rd_cmd_complete_wrap), .cmd_packed_wrap (rd_cmd_packed_wrap), .cmd_first_word (rd_cmd_first_word), .cmd_next_word (rd_cmd_next_word), .cmd_last_word (rd_cmd_last_word), .cmd_offset (rd_cmd_offset), .cmd_mask (rd_cmd_mask), .cmd_step (rd_cmd_step), .cmd_length (rd_cmd_length), .cmd_ready (rd_cmd_ready), .cmd_id_ready (rd_cmd_ready), .cmd_id (rd_cmd_id), .cmd_si_addr (rd_cmd_si_addr ), .cmd_si_id (rd_cmd_si_id ), .cmd_si_len (rd_cmd_si_len ), .cmd_si_size (rd_cmd_si_size ), .cmd_si_burst (rd_cmd_si_burst), // Slave Interface Write Address Ports .S_AXI_AID (sr_arid), .S_AXI_AADDR (sr_araddr), .S_AXI_ALEN (sr_arlen), .S_AXI_ASIZE (sr_arsize), .S_AXI_ABURST (sr_arburst), .S_AXI_ALOCK (sr_arlock), .S_AXI_ACACHE (sr_arcache), .S_AXI_APROT (sr_arprot), .S_AXI_AREGION (sr_arregion), .S_AXI_AQOS (sr_arqos), .S_AXI_AVALID (sr_arvalid), .S_AXI_AREADY (sr_arready), // Master Interface Write Address Port .M_AXI_AADDR (m_axi_araddr_i ), .M_AXI_ALEN (m_axi_arlen_i ), .M_AXI_ASIZE (m_axi_arsize_i ), .M_AXI_ABURST (m_axi_arburst_i ), .M_AXI_ALOCK (m_axi_arlock_i ), .M_AXI_ACACHE (m_axi_arcache_i ), .M_AXI_APROT (m_axi_arprot_i ), .M_AXI_AREGION (m_axi_arregion_i ), .M_AXI_AQOS (m_axi_arqos_i ), .M_AXI_AVALID (m_axi_arvalid_i ), .M_AXI_AREADY (m_axi_arready_i ) ); if ((C_FIFO_MODE == P_PKTFIFO) || (C_FIFO_MODE == P_PKTFIFO_CLK)) begin : gen_pktfifo_r_upsizer // Packet FIFO Read Data channel. axi_dwidth_converter_v2_1_7_r_upsizer_pktfifo # ( .C_FAMILY (C_FAMILY), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG), .C_CLK_CONV (P_CLK_CONV), .C_S_AXI_ACLK_RATIO (C_S_AXI_ACLK_RATIO), .C_M_AXI_ACLK_RATIO (C_M_AXI_ACLK_RATIO), .C_AXI_IS_ACLK_ASYNC (C_AXI_IS_ACLK_ASYNC), .C_SYNCHRONIZER_STAGE (C_SYNCHRONIZER_STAGE) ) pktfifo_read_data_inst ( .S_AXI_ARESETN ( s_axi_aresetn ) , .S_AXI_ACLK ( s_axi_aclk ) , .M_AXI_ARESETN ( m_axi_aresetn ) , .M_AXI_ACLK ( m_axi_aclk ) , // Command Interface .cmd_si_addr (rd_cmd_si_addr ), .cmd_si_id (rd_cmd_si_id ), .cmd_si_len (rd_cmd_si_len ), .cmd_si_size (rd_cmd_si_size ), .cmd_si_burst (rd_cmd_si_burst), .cmd_ready (rd_cmd_ready), // Slave Interface Write Address Ports .S_AXI_ARADDR (m_axi_araddr_i ), .S_AXI_ARLEN (m_axi_arlen_i ), .S_AXI_ARSIZE (m_axi_arsize_i ), .S_AXI_ARBURST (m_axi_arburst_i ), .S_AXI_ARLOCK (m_axi_arlock_i ), .S_AXI_ARCACHE (m_axi_arcache_i ), .S_AXI_ARPROT (m_axi_arprot_i ), .S_AXI_ARREGION (m_axi_arregion_i ), .S_AXI_ARQOS (m_axi_arqos_i ), .S_AXI_ARVALID (m_axi_arvalid_i ), .S_AXI_ARREADY (m_axi_arready_i ), // Master Interface Write Address Port .M_AXI_ARADDR (m_axi_araddr), .M_AXI_ARLEN (m_axi_arlen), .M_AXI_ARSIZE (m_axi_arsize), .M_AXI_ARBURST (m_axi_arburst), .M_AXI_ARLOCK (m_axi_arlock), .M_AXI_ARCACHE (m_axi_arcache), .M_AXI_ARPROT (m_axi_arprot), .M_AXI_ARREGION (m_axi_arregion), .M_AXI_ARQOS (m_axi_arqos), .M_AXI_ARVALID (m_axi_arvalid), .M_AXI_ARREADY (m_axi_arready), // Slave Interface Write Data Ports .S_AXI_RID (s_axi_rid), .S_AXI_RDATA (s_axi_rdata), .S_AXI_RRESP (s_axi_rresp), .S_AXI_RLAST (s_axi_rlast), .S_AXI_RVALID (s_axi_rvalid), .S_AXI_RREADY (s_axi_rready), // Master Interface Write Data Ports .M_AXI_RDATA (m_axi_rdata), .M_AXI_RRESP (m_axi_rresp), .M_AXI_RLAST (m_axi_rlast), .M_AXI_RVALID (m_axi_rvalid), .M_AXI_RREADY (m_axi_rready), .SAMPLE_CYCLE (sample_cycle), .SAMPLE_CYCLE_EARLY (sample_cycle_early) ); end else begin : gen_non_fifo_r_upsizer // Read Data channel. axi_dwidth_converter_v2_1_7_r_upsizer # ( .C_FAMILY ("rtl"), .C_AXI_ID_WIDTH (C_S_AXI_ID_WIDTH), .C_S_AXI_DATA_WIDTH (C_S_AXI_DATA_WIDTH), .C_M_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_S_AXI_REGISTER (C_S_AXI_R_REGISTER), .C_PACKING_LEVEL (C_PACKING_LEVEL), .C_S_AXI_BYTES_LOG (C_S_AXI_BYTES_LOG), .C_M_AXI_BYTES_LOG (C_M_AXI_BYTES_LOG), .C_RATIO (C_RATIO), .C_RATIO_LOG (C_RATIO_LOG) ) read_data_inst ( // Global Signals .ARESET (~s_aresetn_i), .ACLK (aclk), // Command Interface .cmd_valid (rd_cmd_valid), .cmd_fix (rd_cmd_fix), .cmd_modified (rd_cmd_modified), .cmd_complete_wrap (rd_cmd_complete_wrap), .cmd_packed_wrap (rd_cmd_packed_wrap), .cmd_first_word (rd_cmd_first_word), .cmd_next_word (rd_cmd_next_word), .cmd_last_word (rd_cmd_last_word), .cmd_offset (rd_cmd_offset), .cmd_mask (rd_cmd_mask), .cmd_step (rd_cmd_step), .cmd_length (rd_cmd_length), .cmd_ready (rd_cmd_ready), .cmd_id (rd_cmd_id), // Slave Interface Read Data Ports .S_AXI_RID (s_axi_rid), .S_AXI_RDATA (s_axi_rdata), .S_AXI_RRESP (s_axi_rresp), .S_AXI_RLAST (s_axi_rlast), .S_AXI_RVALID (s_axi_rvalid), .S_AXI_RREADY (s_axi_rready), // Master Interface Read Data Ports .M_AXI_RDATA (mr_rdata), .M_AXI_RRESP (mr_rresp), .M_AXI_RLAST (mr_rlast), .M_AXI_RVALID (mr_rvalid), .M_AXI_RREADY (mr_rready) ); axi_register_slice_v2_1_7_axi_register_slice # ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL (0), .C_AXI_ID_WIDTH (1), .C_AXI_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AXI_DATA_WIDTH (C_M_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (0), .C_REG_CONFIG_R (C_M_AXI_R_REGISTER) ) mi_register_slice_inst ( .aresetn (s_aresetn_i), .aclk (m_aclk), .s_axi_awid ( 1'b0 ), .s_axi_awaddr ( {C_AXI_ADDR_WIDTH{1'b0}} ), .s_axi_awlen ( 8'b0 ), .s_axi_awsize ( 3'b0 ), .s_axi_awburst ( 2'b0 ), .s_axi_awlock ( 1'b0 ), .s_axi_awcache ( 4'b0 ), .s_axi_awprot ( 3'b0 ), .s_axi_awregion ( 4'b0 ), .s_axi_awqos ( 4'b0 ), .s_axi_awuser ( 1'b0 ), .s_axi_awvalid ( 1'b0 ), .s_axi_awready ( ), .s_axi_wid ( 1'b0 ), .s_axi_wdata ( {C_M_AXI_DATA_WIDTH{1'b0}} ), .s_axi_wstrb ( {C_M_AXI_DATA_WIDTH/8{1'b0}} ), .s_axi_wlast ( 1'b0 ), .s_axi_wuser ( 1'b0 ), .s_axi_wvalid ( 1'b0 ), .s_axi_wready ( ), .s_axi_bid ( ), .s_axi_bresp ( ), .s_axi_buser ( ), .s_axi_bvalid ( ), .s_axi_bready ( 1'b0 ), .s_axi_arid ( 1'b0 ), .s_axi_araddr ( {C_AXI_ADDR_WIDTH{1'b0}} ), .s_axi_arlen ( 8'b0 ), .s_axi_arsize ( 3'b0 ), .s_axi_arburst ( 2'b0 ), .s_axi_arlock ( 1'b0 ), .s_axi_arcache ( 4'b0 ), .s_axi_arprot ( 3'b0 ), .s_axi_arregion ( 4'b0 ), .s_axi_arqos ( 4'b0 ), .s_axi_aruser ( 1'b0 ), .s_axi_arvalid ( 1'b0 ), .s_axi_arready ( ), .s_axi_rid (), .s_axi_rdata (mr_rdata ), .s_axi_rresp (mr_rresp ), .s_axi_rlast (mr_rlast ), .s_axi_ruser (), .s_axi_rvalid (mr_rvalid ), .s_axi_rready (mr_rready ), .m_axi_awid (), .m_axi_awaddr (), .m_axi_awlen (), .m_axi_awsize (), .m_axi_awburst (), .m_axi_awlock (), .m_axi_awcache (), .m_axi_awprot (), .m_axi_awregion (), .m_axi_awqos (), .m_axi_awuser (), .m_axi_awvalid (), .m_axi_awready (1'b0), .m_axi_wid () , .m_axi_wdata (), .m_axi_wstrb (), .m_axi_wlast (), .m_axi_wuser (), .m_axi_wvalid (), .m_axi_wready (1'b0), .m_axi_bid ( 1'b0 ) , .m_axi_bresp ( 2'b0 ) , .m_axi_buser ( 1'b0 ) , .m_axi_bvalid ( 1'b0 ) , .m_axi_bready ( ) , .m_axi_arid (), .m_axi_araddr (), .m_axi_arlen (), .m_axi_arsize (), .m_axi_arburst (), .m_axi_arlock (), .m_axi_arcache (), .m_axi_arprot (), .m_axi_arregion (), .m_axi_arqos (), .m_axi_aruser (), .m_axi_arvalid (), .m_axi_arready (1'b0), .m_axi_rid (1'b0 ), .m_axi_rdata (m_axi_rdata ), .m_axi_rresp (m_axi_rresp ), .m_axi_rlast (m_axi_rlast ), .m_axi_ruser (1'b0 ), .m_axi_rvalid (m_axi_rvalid ), .m_axi_rready (m_axi_rready_i ) ); assign m_axi_araddr = m_axi_araddr_i ; assign m_axi_arlen = m_axi_arlen_i ; assign m_axi_arsize = m_axi_arsize_i ; assign m_axi_arburst = m_axi_arburst_i ; assign m_axi_arlock = m_axi_arlock_i ; assign m_axi_arcache = m_axi_arcache_i ; assign m_axi_arprot = m_axi_arprot_i ; assign m_axi_arregion = m_axi_arregion_i ; assign m_axi_arqos = m_axi_arqos_i ; assign m_axi_arvalid = m_axi_arvalid_i ; assign m_axi_arready_i = m_axi_arready ; assign m_axi_rready = m_axi_rready_i; end // gen_r_upsizer end else begin : NO_READ assign sr_arready = 1'b0; assign s_axi_rid = {C_S_AXI_ID_WIDTH{1'b0}}; assign s_axi_rdata = {C_S_AXI_DATA_WIDTH{1'b0}}; assign s_axi_rresp = 2'b0; assign s_axi_rlast = 1'b0; assign s_axi_rvalid = 1'b0; assign m_axi_araddr = {C_AXI_ADDR_WIDTH{1'b0}}; assign m_axi_arlen = 8'b0; assign m_axi_arsize = 3'b0; assign m_axi_arburst = 2'b0; assign m_axi_arlock = 2'b0; assign m_axi_arcache = 4'b0; assign m_axi_arprot = 3'b0; assign m_axi_arregion = 4'b0; assign m_axi_arqos = 4'b0; assign m_axi_arvalid = 1'b0; assign mr_rready = 1'b0; end endgenerate endmodule `default_nettype wire

// -- (c) Copyright 2010 - 2011 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Generic single-channel AXI FIFO // Synchronous FIFO is implemented using either LUTs (SRL) or BRAM. // Transfers received on the AXI slave port are pushed onto the FIFO. // FIFO output, when available, is presented on the AXI master port and // popped when the master port responds (M_READY). // // Verilog-standard: Verilog 2001 //-------------------------------------------------------------------------- // Structure: // axic_fifo // fifo_gen //-------------------------------------------------------------------------- `timescale 1ps/1ps (* DowngradeIPIdentifiedWarnings="yes" *) module axi_data_fifo_v2_1_12_axic_fifo # ( parameter C_FAMILY = "virtex6", parameter integer C_FIFO_DEPTH_LOG = 5, // FIFO depth = 2**C_FIFO_DEPTH_LOG // Range = [5:9] when TYPE="lut", // Range = [5:12] when TYPE="bram", parameter integer C_FIFO_WIDTH = 64, // Width of payload [1:512] parameter C_FIFO_TYPE = "lut" // "lut" = LUT (SRL) based, // "bram" = BRAM based ) ( // Global inputs input wire ACLK, // Clock input wire ARESET, // Reset // Slave Port input wire [C_FIFO_WIDTH-1:0] S_MESG, // Payload (may be any set of channel signals) input wire S_VALID, // FIFO push output wire S_READY, // FIFO not full // Master Port output wire [C_FIFO_WIDTH-1:0] M_MESG, // Payload output wire M_VALID, // FIFO not empty input wire M_READY // FIFO pop ); axi_data_fifo_v2_1_12_fifo_gen #( .C_FAMILY(C_FAMILY), .C_COMMON_CLOCK(1), .C_FIFO_DEPTH_LOG(C_FIFO_DEPTH_LOG), .C_FIFO_WIDTH(C_FIFO_WIDTH), .C_FIFO_TYPE(C_FIFO_TYPE)) inst ( .clk(ACLK), .rst(ARESET), .wr_clk(1'b0), .wr_en(S_VALID), .wr_ready(S_READY), .wr_data(S_MESG), .rd_clk(1'b0), .rd_en(M_READY), .rd_valid(M_VALID), .rd_data(M_MESG)); endmodule // -- (c) Copyright 1995 - 2012 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------- // The synthesis directives "translate_off/translate_on" specified below are // supported by Xilinx, Mentor Graphics and Synplicity synthesis // tools. Ensure they are correct for your synthesis tool(s). // You must compile the fifo_generator wrapper file when simulating // the core. When compiling the wrapper file, be sure to // reference the XilinxCoreLib Verilog simulation library. For detailed // instructions, please refer to the "CORE Generator Help". `timescale 1ps/1ps (* DowngradeIPIdentifiedWarnings="yes" *) module axi_data_fifo_v2_1_12_fifo_gen #( parameter C_FAMILY = "virtex7", parameter integer C_COMMON_CLOCK = 1, parameter integer C_SYNCHRONIZER_STAGE = 3, parameter integer C_FIFO_DEPTH_LOG = 5, parameter integer C_FIFO_WIDTH = 64, parameter C_FIFO_TYPE = "lut" )( clk, rst, wr_clk, wr_en, wr_ready, wr_data, rd_clk, rd_en, rd_valid, rd_data); input clk; input wr_clk; input rd_clk; input rst; input [C_FIFO_WIDTH-1 : 0] wr_data; input wr_en; input rd_en; output [C_FIFO_WIDTH-1 : 0] rd_data; output wr_ready; output rd_valid; wire full; wire empty; wire rd_valid = ~empty; wire wr_ready = ~full; localparam C_MEMORY_TYPE = (C_FIFO_TYPE == "bram")? 1 : 2; localparam C_IMPLEMENTATION_TYPE = (C_COMMON_CLOCK == 1)? 0 : 2; fifo_generator_v13_1_4 #( .C_COMMON_CLOCK(C_COMMON_CLOCK), .C_DIN_WIDTH(C_FIFO_WIDTH), .C_DOUT_WIDTH(C_FIFO_WIDTH), .C_FAMILY(C_FAMILY), .C_IMPLEMENTATION_TYPE(C_IMPLEMENTATION_TYPE), .C_MEMORY_TYPE(C_MEMORY_TYPE), .C_RD_DEPTH(1<<C_FIFO_DEPTH_LOG), .C_RD_PNTR_WIDTH(C_FIFO_DEPTH_LOG), .C_WR_DEPTH(1<<C_FIFO_DEPTH_LOG), .C_WR_PNTR_WIDTH(C_FIFO_DEPTH_LOG), .C_ADD_NGC_CONSTRAINT(0), .C_APPLICATION_TYPE_AXIS(0), .C_APPLICATION_TYPE_RACH(0), .C_APPLICATION_TYPE_RDCH(0), .C_APPLICATION_TYPE_WACH(0), .C_APPLICATION_TYPE_WDCH(0), .C_APPLICATION_TYPE_WRCH(0), .C_AXIS_TDATA_WIDTH(64), .C_AXIS_TDEST_WIDTH(4), .C_AXIS_TID_WIDTH(8), .C_AXIS_TKEEP_WIDTH(4), .C_AXIS_TSTRB_WIDTH(4), .C_AXIS_TUSER_WIDTH(4), .C_AXIS_TYPE(0), .C_AXI_ADDR_WIDTH(32), .C_AXI_ARUSER_WIDTH(1), .C_AXI_AWUSER_WIDTH(1), .C_AXI_BUSER_WIDTH(1), .C_AXI_DATA_WIDTH(64), .C_AXI_ID_WIDTH(4), .C_AXI_LEN_WIDTH(8), .C_AXI_LOCK_WIDTH(2), .C_AXI_RUSER_WIDTH(1), .C_AXI_TYPE(0), .C_AXI_WUSER_WIDTH(1), .C_COUNT_TYPE(0), .C_DATA_COUNT_WIDTH(6), .C_DEFAULT_VALUE("BlankString"), .C_DIN_WIDTH_AXIS(1), .C_DIN_WIDTH_RACH(32), .C_DIN_WIDTH_RDCH(64), .C_DIN_WIDTH_WACH(32), .C_DIN_WIDTH_WDCH(64), .C_DIN_WIDTH_WRCH(2), .C_DOUT_RST_VAL("0"), .C_ENABLE_RLOCS(0), .C_ENABLE_RST_SYNC(1), .C_ERROR_INJECTION_TYPE(0), .C_ERROR_INJECTION_TYPE_AXIS(0), .C_ERROR_INJECTION_TYPE_RACH(0), .C_ERROR_INJECTION_TYPE_RDCH(0), .C_ERROR_INJECTION_TYPE_WACH(0), .C_ERROR_INJECTION_TYPE_WDCH(0), .C_ERROR_INJECTION_TYPE_WRCH(0), .C_FULL_FLAGS_RST_VAL(0), .C_HAS_ALMOST_EMPTY(0), .C_HAS_ALMOST_FULL(0), .C_HAS_AXIS_TDATA(0), .C_HAS_AXIS_TDEST(0), .C_HAS_AXIS_TID(0), .C_HAS_AXIS_TKEEP(0), .C_HAS_AXIS_TLAST(0), .C_HAS_AXIS_TREADY(1), .C_HAS_AXIS_TSTRB(0), .C_HAS_AXIS_TUSER(0), .C_HAS_AXI_ARUSER(0), .C_HAS_AXI_AWUSER(0), .C_HAS_AXI_BUSER(0), .C_HAS_AXI_RD_CHANNEL(0), .C_HAS_AXI_RUSER(0), .C_HAS_AXI_WR_CHANNEL(0), .C_HAS_AXI_WUSER(0), .C_HAS_BACKUP(0), .C_HAS_DATA_COUNT(0), .C_HAS_DATA_COUNTS_AXIS(0), .C_HAS_DATA_COUNTS_RACH(0), .C_HAS_DATA_COUNTS_RDCH(0), .C_HAS_DATA_COUNTS_WACH(0), .C_HAS_DATA_COUNTS_WDCH(0), .C_HAS_DATA_COUNTS_WRCH(0), .C_HAS_INT_CLK(0), .C_HAS_MASTER_CE(0), .C_HAS_MEMINIT_FILE(0), .C_HAS_OVERFLOW(0), .C_HAS_PROG_FLAGS_AXIS(0), .C_HAS_PROG_FLAGS_RACH(0), .C_HAS_PROG_FLAGS_RDCH(0), .C_HAS_PROG_FLAGS_WACH(0), .C_HAS_PROG_FLAGS_WDCH(0), .C_HAS_PROG_FLAGS_WRCH(0), .C_HAS_RD_DATA_COUNT(0), .C_HAS_RD_RST(0), .C_HAS_RST(1), .C_HAS_SLAVE_CE(0), .C_HAS_SRST(0), .C_HAS_UNDERFLOW(0), .C_HAS_VALID(0), .C_HAS_WR_ACK(0), .C_HAS_WR_DATA_COUNT(0), .C_HAS_WR_RST(0), .C_IMPLEMENTATION_TYPE_AXIS(1), .C_IMPLEMENTATION_TYPE_RACH(1), .C_IMPLEMENTATION_TYPE_RDCH(1), .C_IMPLEMENTATION_TYPE_WACH(1), .C_IMPLEMENTATION_TYPE_WDCH(1), .C_IMPLEMENTATION_TYPE_WRCH(1), .C_INIT_WR_PNTR_VAL(0), .C_INTERFACE_TYPE(0), .C_MIF_FILE_NAME("BlankString"), .C_MSGON_VAL(1), .C_OPTIMIZATION_MODE(0), .C_OVERFLOW_LOW(0), .C_PRELOAD_LATENCY(0), .C_PRELOAD_REGS(1), .C_PRIM_FIFO_TYPE("512x36"), .C_PROG_EMPTY_THRESH_ASSERT_VAL(4), .C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH(1022), .C_PROG_EMPTY_THRESH_NEGATE_VAL(5), .C_PROG_EMPTY_TYPE(0), .C_PROG_EMPTY_TYPE_AXIS(0), .C_PROG_EMPTY_TYPE_RACH(0), .C_PROG_EMPTY_TYPE_RDCH(0), .C_PROG_EMPTY_TYPE_WACH(0), .C_PROG_EMPTY_TYPE_WDCH(0), .C_PROG_EMPTY_TYPE_WRCH(0), .C_PROG_FULL_THRESH_ASSERT_VAL(31), .C_PROG_FULL_THRESH_ASSERT_VAL_AXIS(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_RACH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_RDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_WACH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_WDCH(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_WRCH(1023), .C_PROG_FULL_THRESH_NEGATE_VAL(30), .C_PROG_FULL_TYPE(0), .C_PROG_FULL_TYPE_AXIS(0), .C_PROG_FULL_TYPE_RACH(0), .C_PROG_FULL_TYPE_RDCH(0), .C_PROG_FULL_TYPE_WACH(0), .C_PROG_FULL_TYPE_WDCH(0), .C_PROG_FULL_TYPE_WRCH(0), .C_RACH_TYPE(0), .C_RDCH_TYPE(0), .C_RD_DATA_COUNT_WIDTH(6), .C_RD_FREQ(1), .C_REG_SLICE_MODE_AXIS(0), .C_REG_SLICE_MODE_RACH(0), .C_REG_SLICE_MODE_RDCH(0), .C_REG_SLICE_MODE_WACH(0), .C_REG_SLICE_MODE_WDCH(0), .C_REG_SLICE_MODE_WRCH(0), .C_SYNCHRONIZER_STAGE(C_SYNCHRONIZER_STAGE), .C_UNDERFLOW_LOW(0), .C_USE_COMMON_OVERFLOW(0), .C_USE_COMMON_UNDERFLOW(0), .C_USE_DEFAULT_SETTINGS(0), .C_USE_DOUT_RST(0), .C_USE_ECC(0), .C_USE_ECC_AXIS(0), .C_USE_ECC_RACH(0), .C_USE_ECC_RDCH(0), .C_USE_ECC_WACH(0), .C_USE_ECC_WDCH(0), .C_USE_ECC_WRCH(0), .C_USE_EMBEDDED_REG(0), .C_USE_FIFO16_FLAGS(0), .C_USE_FWFT_DATA_COUNT(1), .C_VALID_LOW(0), .C_WACH_TYPE(0), .C_WDCH_TYPE(0), .C_WRCH_TYPE(0), .C_WR_ACK_LOW(0), .C_WR_DATA_COUNT_WIDTH(6), .C_WR_DEPTH_AXIS(1024), .C_WR_DEPTH_RACH(16), .C_WR_DEPTH_RDCH(1024), .C_WR_DEPTH_WACH(16), .C_WR_DEPTH_WDCH(1024), .C_WR_DEPTH_WRCH(16), .C_WR_FREQ(1), .C_WR_PNTR_WIDTH_AXIS(10), .C_WR_PNTR_WIDTH_RACH(4), .C_WR_PNTR_WIDTH_RDCH(10), .C_WR_PNTR_WIDTH_WACH(4), .C_WR_PNTR_WIDTH_WDCH(10), .C_WR_PNTR_WIDTH_WRCH(4), .C_WR_RESPONSE_LATENCY(1) ) fifo_gen_inst ( .clk(clk), .din(wr_data), .dout(rd_data), .empty(empty), .full(full), .rd_clk(rd_clk), .rd_en(rd_en), .rst(rst), .wr_clk(wr_clk), .wr_en(wr_en), .almost_empty(), .almost_full(), .axi_ar_data_count(), .axi_ar_dbiterr(), .axi_ar_injectdbiterr(1'b0), .axi_ar_injectsbiterr(1'b0), .axi_ar_overflow(), .axi_ar_prog_empty(), .axi_ar_prog_empty_thresh(4'b0), .axi_ar_prog_full(), .axi_ar_prog_full_thresh(4'b0), .axi_ar_rd_data_count(), .axi_ar_sbiterr(), .axi_ar_underflow(), .axi_ar_wr_data_count(), .axi_aw_data_count(), .axi_aw_dbiterr(), .axi_aw_injectdbiterr(1'b0), .axi_aw_injectsbiterr(1'b0), .axi_aw_overflow(), .axi_aw_prog_empty(), .axi_aw_prog_empty_thresh(4'b0), .axi_aw_prog_full(), .axi_aw_prog_full_thresh(4'b0), .axi_aw_rd_data_count(), .axi_aw_sbiterr(), .axi_aw_underflow(), .axi_aw_wr_data_count(), .axi_b_data_count(), .axi_b_dbiterr(), .axi_b_injectdbiterr(1'b0), .axi_b_injectsbiterr(1'b0), .axi_b_overflow(), .axi_b_prog_empty(), .axi_b_prog_empty_thresh(4'b0), .axi_b_prog_full(), .axi_b_prog_full_thresh(4'b0), .axi_b_rd_data_count(), .axi_b_sbiterr(), .axi_b_underflow(), .axi_b_wr_data_count(), .axi_r_data_count(), .axi_r_dbiterr(), .axi_r_injectdbiterr(1'b0), .axi_r_injectsbiterr(1'b0), .axi_r_overflow(), .axi_r_prog_empty(), .axi_r_prog_empty_thresh(10'b0), .axi_r_prog_full(), .axi_r_prog_full_thresh(10'b0), .axi_r_rd_data_count(), .axi_r_sbiterr(), .axi_r_underflow(), .axi_r_wr_data_count(), .axi_w_data_count(), .axi_w_dbiterr(), .axi_w_injectdbiterr(1'b0), .axi_w_injectsbiterr(1'b0), .axi_w_overflow(), .axi_w_prog_empty(), .axi_w_prog_empty_thresh(10'b0), .axi_w_prog_full(), .axi_w_prog_full_thresh(10'b0), .axi_w_rd_data_count(), .axi_w_sbiterr(), .axi_w_underflow(), .axi_w_wr_data_count(), .axis_data_count(), .axis_dbiterr(), .axis_injectdbiterr(1'b0), .axis_injectsbiterr(1'b0), .axis_overflow(), .axis_prog_empty(), .axis_prog_empty_thresh(10'b0), .axis_prog_full(), .axis_prog_full_thresh(10'b0), .axis_rd_data_count(), .axis_sbiterr(), .axis_underflow(), .axis_wr_data_count(), .backup(1'b0), .backup_marker(1'b0), .data_count(), .dbiterr(), .injectdbiterr(1'b0), .injectsbiterr(1'b0), .int_clk(1'b0), .m_aclk(1'b0), .m_aclk_en(1'b0), .m_axi_araddr(), .m_axi_arburst(), .m_axi_arcache(), .m_axi_arid(), .m_axi_arlen(), .m_axi_arlock(), .m_axi_arprot(), .m_axi_arqos(), .m_axi_arready(1'b0), .m_axi_arregion(), .m_axi_arsize(), .m_axi_aruser(), .m_axi_arvalid(), .m_axi_awaddr(), .m_axi_awburst(), .m_axi_awcache(), .m_axi_awid(), .m_axi_awlen(), .m_axi_awlock(), .m_axi_awprot(), .m_axi_awqos(), .m_axi_awready(1'b0), .m_axi_awregion(), .m_axi_awsize(), .m_axi_awuser(), .m_axi_awvalid(), .m_axi_bid(4'b0), .m_axi_bready(), .m_axi_bresp(2'b0), .m_axi_buser(1'b0), .m_axi_bvalid(1'b0), .m_axi_rdata(64'b0), .m_axi_rid(4'b0), .m_axi_rlast(1'b0), .m_axi_rready(), .m_axi_rresp(2'b0), .m_axi_ruser(1'b0), .m_axi_rvalid(1'b0), .m_axi_wdata(), .m_axi_wid(), .m_axi_wlast(), .m_axi_wready(1'b0), .m_axi_wstrb(), .m_axi_wuser(), .m_axi_wvalid(), .m_axis_tdata(), .m_axis_tdest(), .m_axis_tid(), .m_axis_tkeep(), .m_axis_tlast(), .m_axis_tready(1'b0), .m_axis_tstrb(), .m_axis_tuser(), .m_axis_tvalid(), .overflow(), .prog_empty(), .prog_empty_thresh(5'b0), .prog_empty_thresh_assert(5'b0), .prog_empty_thresh_negate(5'b0), .prog_full(), .prog_full_thresh(5'b0), .prog_full_thresh_assert(5'b0), .prog_full_thresh_negate(5'b0), .rd_data_count(), .rd_rst(1'b0), .s_aclk(1'b0), .s_aclk_en(1'b0), .s_aresetn(1'b0), .s_axi_araddr(32'b0), .s_axi_arburst(2'b0), .s_axi_arcache(4'b0), .s_axi_arid(4'b0), .s_axi_arlen(8'b0), .s_axi_arlock(2'b0), .s_axi_arprot(3'b0), .s_axi_arqos(4'b0), .s_axi_arready(), .s_axi_arregion(4'b0), .s_axi_arsize(3'b0), .s_axi_aruser(1'b0), .s_axi_arvalid(1'b0), .s_axi_awaddr(32'b0), .s_axi_awburst(2'b0), .s_axi_awcache(4'b0), .s_axi_awid(4'b0), .s_axi_awlen(8'b0), .s_axi_awlock(2'b0), .s_axi_awprot(3'b0), .s_axi_awqos(4'b0), .s_axi_awready(), .s_axi_awregion(4'b0), .s_axi_awsize(3'b0), .s_axi_awuser(1'b0), .s_axi_awvalid(1'b0), .s_axi_bid(), .s_axi_bready(1'b0), .s_axi_bresp(), .s_axi_buser(), .s_axi_bvalid(), .s_axi_rdata(), .s_axi_rid(), .s_axi_rlast(), .s_axi_rready(1'b0), .s_axi_rresp(), .s_axi_ruser(), .s_axi_rvalid(), .s_axi_wdata(64'b0), .s_axi_wid(4'b0), .s_axi_wlast(1'b0), .s_axi_wready(), .s_axi_wstrb(8'b0), .s_axi_wuser(1'b0), .s_axi_wvalid(1'b0), .s_axis_tdata(64'b0), .s_axis_tdest(4'b0), .s_axis_tid(8'b0), .s_axis_tkeep(4'b0), .s_axis_tlast(1'b0), .s_axis_tready(), .s_axis_tstrb(4'b0), .s_axis_tuser(4'b0), .s_axis_tvalid(1'b0), .sbiterr(), .srst(1'b0), .underflow(), .valid(), .wr_ack(), .wr_data_count(), .wr_rst(1'b0), .wr_rst_busy(), .rd_rst_busy(), .sleep(1'b0) ); endmodule // -- (c) Copyright 2008 - 2012 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Description: N-deep SRL pipeline element with generic single-channel AXI interfaces. // Verilog-standard: Verilog 2001 //-------------------------------------------------------------------------- // Structure: // axic_srl_fifo // ndeep_srl // nto1_mux //-------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none (* DowngradeIPIdentifiedWarnings="yes" *) module axi_data_fifo_v2_1_12_axic_srl_fifo # ( parameter C_FAMILY = "none", // FPGA Family parameter integer C_FIFO_WIDTH = 1, // Width of S_MESG/M_MESG. parameter integer C_MAX_CTRL_FANOUT = 33, // Maximum number of mesg bits // the control logic can be used // on before the control logic // needs to be replicated. parameter integer C_FIFO_DEPTH_LOG = 2, // Depth of FIFO is 2**C_FIFO_DEPTH_LOG. // The minimum size fifo generated is 4-deep. parameter C_USE_FULL = 1 // Prevent overwrite by throttling S_READY. ) ( input wire ACLK, // Clock input wire ARESET, // Reset input wire [C_FIFO_WIDTH-1:0] S_MESG, // Input data input wire S_VALID, // Input data valid output wire S_READY, // Input data ready output wire [C_FIFO_WIDTH-1:0] M_MESG, // Output data output wire M_VALID, // Output data valid input wire M_READY // Output data ready ); localparam P_FIFO_DEPTH_LOG = (C_FIFO_DEPTH_LOG>1) ? C_FIFO_DEPTH_LOG : 2; localparam P_EMPTY = {P_FIFO_DEPTH_LOG{1'b1}}; localparam P_ALMOSTEMPTY = {P_FIFO_DEPTH_LOG{1'b0}}; localparam P_ALMOSTFULL_TEMP = {P_EMPTY, 1'b0}; localparam P_ALMOSTFULL = P_ALMOSTFULL_TEMP[0+:P_FIFO_DEPTH_LOG]; localparam P_NUM_REPS = (((C_FIFO_WIDTH+1)%C_MAX_CTRL_FANOUT) == 0) ? (C_FIFO_WIDTH+1)/C_MAX_CTRL_FANOUT : ((C_FIFO_WIDTH+1)/C_MAX_CTRL_FANOUT)+1; (* syn_keep = "1" *) reg [P_NUM_REPS*P_FIFO_DEPTH_LOG-1:0] fifoaddr; (* syn_keep = "1" *) wire [P_NUM_REPS*P_FIFO_DEPTH_LOG-1:0] fifoaddr_i; genvar i; genvar j; reg M_VALID_i; reg S_READY_i; wire push; // FIFO push wire pop; // FIFO pop reg areset_d1; // Reset delay register wire [C_FIFO_WIDTH-1:0] m_axi_mesg_i; // Intermediate SRL data assign M_VALID = M_VALID_i; assign S_READY = C_USE_FULL ? S_READY_i : 1'b1; assign M_MESG = m_axi_mesg_i; assign push = S_VALID & (C_USE_FULL ? S_READY_i : 1'b1); assign pop = M_VALID_i & M_READY; always @(posedge ACLK) begin areset_d1 <= ARESET; end generate //--------------------------------------------------------------------------- // Create count of number of elements in FIFOs //--------------------------------------------------------------------------- for (i=0;i<P_NUM_REPS;i=i+1) begin : gen_rep assign fifoaddr_i[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i] = push ? fifoaddr[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i] + 1 : fifoaddr[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i] - 1; always @(posedge ACLK) begin if (ARESET) fifoaddr[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i] <= {P_FIFO_DEPTH_LOG{1'b1}}; else if (push ^ pop) fifoaddr[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i] <= fifoaddr_i[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i]; end end //--------------------------------------------------------------------------- // When FIFO is empty, reset master valid bit. When not empty set valid bit. // When FIFO is full, reset slave ready bit. When not full set ready bit. //--------------------------------------------------------------------------- always @(posedge ACLK) begin if (ARESET) begin M_VALID_i <= 1'b0; end else if ((fifoaddr[P_FIFO_DEPTH_LOG*P_NUM_REPS-1:P_FIFO_DEPTH_LOG*(P_NUM_REPS-1)] == P_ALMOSTEMPTY) && pop && ~push) begin M_VALID_i <= 1'b0; end else if (push) begin M_VALID_i <= 1'b1; end end always @(posedge ACLK) begin if (ARESET) begin S_READY_i <= 1'b0; end else if (areset_d1) begin S_READY_i <= 1'b1; end else if (C_USE_FULL && ((fifoaddr[P_FIFO_DEPTH_LOG*P_NUM_REPS-1:P_FIFO_DEPTH_LOG*(P_NUM_REPS-1)] == P_ALMOSTFULL) && push && ~pop)) begin S_READY_i <= 1'b0; end else if (C_USE_FULL && pop) begin S_READY_i <= 1'b1; end end //--------------------------------------------------------------------------- // Instantiate SRLs //--------------------------------------------------------------------------- for (i=0;i<(C_FIFO_WIDTH/C_MAX_CTRL_FANOUT)+((C_FIFO_WIDTH%C_MAX_CTRL_FANOUT)>0);i=i+1) begin : gen_srls for (j=0;((j<C_MAX_CTRL_FANOUT)&&(i*C_MAX_CTRL_FANOUT+j<C_FIFO_WIDTH));j=j+1) begin : gen_rep axi_data_fifo_v2_1_12_ndeep_srl # ( .C_FAMILY (C_FAMILY), .C_A_WIDTH (P_FIFO_DEPTH_LOG) ) srl_nx1 ( .CLK (ACLK), .A (fifoaddr[P_FIFO_DEPTH_LOG*(i+1)-1: P_FIFO_DEPTH_LOG*(i)]), .CE (push), .D (S_MESG[i*C_MAX_CTRL_FANOUT+j]), .Q (m_axi_mesg_i[i*C_MAX_CTRL_FANOUT+j]) ); end end endgenerate endmodule `default_nettype wire // -- (c) Copyright 2010 - 2012 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // Description: N-deep SRL pipeline element with generic single-channel AXI interfaces. // Interface outputs are synchronized using ordinary flops for improved timing. //-------------------------------------------------------------------------- // Structure: // axic_reg_srl_fifo // ndeep_srl // nto1_mux //-------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none (* DowngradeIPIdentifiedWarnings="yes" *) module axi_data_fifo_v2_1_12_axic_reg_srl_fifo # ( parameter C_FAMILY = "none", // FPGA Family parameter integer C_FIFO_WIDTH = 1, // Width of S_MESG/M_MESG. parameter integer C_MAX_CTRL_FANOUT = 33, // Maximum number of mesg bits // the control logic can be used // on before the control logic // needs to be replicated. parameter integer C_FIFO_DEPTH_LOG = 2, // Depth of FIFO is 2**C_FIFO_DEPTH_LOG. // The minimum size fifo generated is 4-deep. parameter C_USE_FULL = 1 // Prevent overwrite by throttling S_READY. ) ( input wire ACLK, // Clock input wire ARESET, // Reset input wire [C_FIFO_WIDTH-1:0] S_MESG, // Input data input wire S_VALID, // Input data valid output wire S_READY, // Input data ready output wire [C_FIFO_WIDTH-1:0] M_MESG, // Output data output wire M_VALID, // Output data valid input wire M_READY // Output data ready ); localparam P_FIFO_DEPTH_LOG = (C_FIFO_DEPTH_LOG>1) ? C_FIFO_DEPTH_LOG : 2; localparam P_EMPTY = {P_FIFO_DEPTH_LOG{1'b1}}; localparam P_ALMOSTEMPTY = {P_FIFO_DEPTH_LOG{1'b0}}; localparam P_ALMOSTFULL_TEMP = {P_EMPTY, 1'b0}; localparam P_ALMOSTFULL = P_ALMOSTFULL_TEMP[0+:P_FIFO_DEPTH_LOG]; localparam P_NUM_REPS = (((C_FIFO_WIDTH+1)%C_MAX_CTRL_FANOUT) == 0) ? (C_FIFO_WIDTH+1)/C_MAX_CTRL_FANOUT : ((C_FIFO_WIDTH+1)/C_MAX_CTRL_FANOUT)+1; (* syn_keep = "1" *) reg [P_NUM_REPS*P_FIFO_DEPTH_LOG-1:0] fifoaddr; (* syn_keep = "1" *) wire [P_NUM_REPS*P_FIFO_DEPTH_LOG-1:0] fifoaddr_i; genvar i; genvar j; reg m_valid_i = 1'b0; reg s_ready_i; wire push; // FIFO push wire pop; // FIFO pop reg areset_d1; // Reset delay register reg [C_FIFO_WIDTH-1:0] storage_data1; wire [C_FIFO_WIDTH-1:0] storage_data2; // Intermediate SRL data reg load_s1; wire load_s1_from_s2; reg [1:0] state; localparam [1:0] ZERO = 2'b10, ONE = 2'b11, TWO = 2'b01; assign M_VALID = m_valid_i; assign S_READY = C_USE_FULL ? s_ready_i : 1'b1; assign push = (S_VALID & (C_USE_FULL ? s_ready_i : 1'b1) & (state == TWO)) | (~M_READY & S_VALID & (state == ONE)); assign pop = M_READY & (state == TWO); assign M_MESG = storage_data1; always @(posedge ACLK) begin areset_d1 <= ARESET; end // Load storage1 with either slave side data or from storage2 always @(posedge ACLK) begin if (load_s1) if (load_s1_from_s2) storage_data1 <= storage_data2; else storage_data1 <= S_MESG; end // Loading s1 always @ * begin if ( ((state == ZERO) && (S_VALID == 1)) || // Load when empty on slave transaction // Load when ONE if we both have read and write at the same time ((state == ONE) && (S_VALID == 1) && (M_READY == 1)) || // Load when TWO and we have a transaction on Master side ((state == TWO) && (M_READY == 1))) load_s1 = 1'b1; else load_s1 = 1'b0; end // always @ * assign load_s1_from_s2 = (state == TWO); // State Machine for handling output signals always @(posedge ACLK) begin if (areset_d1) begin state <= ZERO; m_valid_i <= 1'b0; end else begin case (state) // No transaction stored locally ZERO: begin if (S_VALID) begin state <= ONE; // Got one so move to ONE m_valid_i <= 1'b1; end end // One transaction stored locally ONE: begin if (M_READY & ~S_VALID) begin state <= ZERO; // Read out one so move to ZERO m_valid_i <= 1'b0; end else if (~M_READY & S_VALID) begin state <= TWO; // Got another one so move to TWO m_valid_i <= 1'b1; end end // TWO transaction stored locally TWO: begin if ((fifoaddr[P_FIFO_DEPTH_LOG*P_NUM_REPS-1:P_FIFO_DEPTH_LOG*(P_NUM_REPS-1)] == P_ALMOSTEMPTY) && pop && ~push) begin state <= ONE; // Read out one so move to ONE m_valid_i <= 1'b1; end end endcase // case (state) end end // always @ (posedge ACLK) generate //--------------------------------------------------------------------------- // Create count of number of elements in FIFOs //--------------------------------------------------------------------------- for (i=0;i<P_NUM_REPS;i=i+1) begin : gen_rep assign fifoaddr_i[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i] = push ? fifoaddr[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i] + 1 : fifoaddr[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i] - 1; always @(posedge ACLK) begin if (ARESET) fifoaddr[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i] <= {P_FIFO_DEPTH_LOG{1'b1}}; else if (push ^ pop) fifoaddr[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i] <= fifoaddr_i[P_FIFO_DEPTH_LOG*(i+1)-1:P_FIFO_DEPTH_LOG*i]; end end always @(posedge ACLK) begin if (ARESET) begin s_ready_i <= 1'b0; end else if (areset_d1) begin s_ready_i <= 1'b1; end else if (C_USE_FULL && ((fifoaddr[P_FIFO_DEPTH_LOG*P_NUM_REPS-1:P_FIFO_DEPTH_LOG*(P_NUM_REPS-1)] == P_ALMOSTFULL) && push && ~pop)) begin s_ready_i <= 1'b0; end else if (C_USE_FULL && pop) begin s_ready_i <= 1'b1; end end //--------------------------------------------------------------------------- // Instantiate SRLs //--------------------------------------------------------------------------- for (i=0;i<(C_FIFO_WIDTH/C_MAX_CTRL_FANOUT)+((C_FIFO_WIDTH%C_MAX_CTRL_FANOUT)>0);i=i+1) begin : gen_srls for (j=0;((j<C_MAX_CTRL_FANOUT)&&(i*C_MAX_CTRL_FANOUT+j<C_FIFO_WIDTH));j=j+1) begin : gen_rep axi_data_fifo_v2_1_12_ndeep_srl # ( .C_FAMILY (C_FAMILY), .C_A_WIDTH (P_FIFO_DEPTH_LOG) ) srl_nx1 ( .CLK (ACLK), .A (fifoaddr[P_FIFO_DEPTH_LOG*(i+1)-1: P_FIFO_DEPTH_LOG*(i)]), .CE (push), .D (S_MESG[i*C_MAX_CTRL_FANOUT+j]), .Q (storage_data2[i*C_MAX_CTRL_FANOUT+j]) ); end end endgenerate endmodule `default_nettype wire // -- (c) Copyright 2008 - 2014 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // Description: This is a generic n-deep SRL instantiation // Verilog-standard: Verilog 2001 // $Revision: // $Date: // //----------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none (* DowngradeIPIdentifiedWarnings="yes" *) module axi_data_fifo_v2_1_12_ndeep_srl # ( parameter C_FAMILY = "rtl", // FPGA Family parameter C_A_WIDTH = 1 // Address Width (>= 1) ) ( input wire CLK, // Clock input wire [C_A_WIDTH-1:0] A, // Address input wire CE, // Clock Enable input wire D, // Input Data output wire Q // Output Data ); localparam integer P_SRLASIZE = 5; localparam integer P_SRLDEPTH = 32; localparam integer P_NUMSRLS = (C_A_WIDTH>P_SRLASIZE) ? (2**(C_A_WIDTH-P_SRLASIZE)) : 1; localparam integer P_SHIFT_DEPTH = 2**C_A_WIDTH; wire [P_NUMSRLS:0] d_i; wire [P_NUMSRLS-1:0] q_i; wire [(C_A_WIDTH>P_SRLASIZE) ? (C_A_WIDTH-1) : (P_SRLASIZE-1) : 0] a_i; genvar i; // Instantiate SRLs in carry chain format assign d_i[0] = D; assign a_i = A; generate if (C_FAMILY == "rtl") begin : gen_rtl_shifter if (C_A_WIDTH <= P_SRLASIZE) begin : gen_inferred_srl reg [P_SRLDEPTH-1:0] shift_reg = {P_SRLDEPTH{1'b0}}; always @(posedge CLK) if (CE) shift_reg <= {shift_reg[P_SRLDEPTH-2:0], D}; assign Q = shift_reg[a_i]; end else begin : gen_logic_shifter // Very wasteful reg [P_SHIFT_DEPTH-1:0] shift_reg = {P_SHIFT_DEPTH{1'b0}}; always @(posedge CLK) if (CE) shift_reg <= {shift_reg[P_SHIFT_DEPTH-2:0], D}; assign Q = shift_reg[a_i]; end end else begin : gen_primitive_shifter for (i=0;i<P_NUMSRLS;i=i+1) begin : gen_srls SRLC32E srl_inst ( .CLK (CLK), .A (a_i[P_SRLASIZE-1:0]), .CE (CE), .D (d_i[i]), .Q (q_i[i]), .Q31 (d_i[i+1]) ); end if (C_A_WIDTH>P_SRLASIZE) begin : gen_srl_mux generic_baseblocks_v2_1_0_nto1_mux # ( .C_RATIO (2**(C_A_WIDTH-P_SRLASIZE)), .C_SEL_WIDTH (C_A_WIDTH-P_SRLASIZE), .C_DATAOUT_WIDTH (1), .C_ONEHOT (0) ) srl_q_mux_inst ( .SEL_ONEHOT ({2**(C_A_WIDTH-P_SRLASIZE){1'b0}}), .SEL (a_i[C_A_WIDTH-1:P_SRLASIZE]), .IN (q_i), .OUT (Q) ); end else begin : gen_no_srl_mux assign Q = q_i[0]; end end endgenerate endmodule `default_nettype wire // -- (c) Copyright 2010 - 2012 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // AXI data fifo module: // 5-channel memory-mapped AXI4 interfaces. // SRL or BRAM based FIFO on AXI W and/or R channels. // FIFO to accommodate various data flow rates through the AXI interconnect // // Verilog-standard: Verilog 2001 //----------------------------------------------------------------------------- // // Structure: // axi_data_fifo // fifo_generator // //----------------------------------------------------------------------------- `timescale 1ps/1ps (* DowngradeIPIdentifiedWarnings="yes" *) module axi_data_fifo_v2_1_12_axi_data_fifo # ( parameter C_FAMILY = "virtex7", parameter integer C_AXI_PROTOCOL = 0, parameter integer C_AXI_ID_WIDTH = 4, parameter integer C_AXI_ADDR_WIDTH = 32, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0, parameter integer C_AXI_AWUSER_WIDTH = 1, parameter integer C_AXI_ARUSER_WIDTH = 1, parameter integer C_AXI_WUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_BUSER_WIDTH = 1, parameter integer C_AXI_WRITE_FIFO_DEPTH = 0, // Range: (0, 32, 512) parameter C_AXI_WRITE_FIFO_TYPE = "lut", // "lut" = LUT (SRL) based, // "bram" = BRAM based parameter integer C_AXI_WRITE_FIFO_DELAY = 0, // 0 = No, 1 = Yes // Indicates whether AWVALID and WVALID assertion is delayed until: // a. the corresponding WLAST is stored in the FIFO, or // b. no WLAST is stored and the FIFO is full. // 0 means AW channel is pass-through and // WVALID is asserted whenever FIFO is not empty. parameter integer C_AXI_READ_FIFO_DEPTH = 0, // Range: (0, 32, 512) parameter C_AXI_READ_FIFO_TYPE = "lut", // "lut" = LUT (SRL) based, // "bram" = BRAM based parameter integer C_AXI_READ_FIFO_DELAY = 0) // 0 = No, 1 = Yes // Indicates whether ARVALID assertion is delayed until the // the remaining vacancy of the FIFO is at least the burst length // as indicated by ARLEN. // 0 means AR channel is pass-through. // System Signals (input wire aclk, input wire aresetn, // Slave Interface Write Address Ports input wire [C_AXI_ID_WIDTH-1:0] s_axi_awid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_awaddr, input wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] s_axi_awlen, input wire [3-1:0] s_axi_awsize, input wire [2-1:0] s_axi_awburst, input wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] s_axi_awlock, input wire [4-1:0] s_axi_awcache, input wire [3-1:0] s_axi_awprot, input wire [4-1:0] s_axi_awregion, input wire [4-1:0] s_axi_awqos, input wire [C_AXI_AWUSER_WIDTH-1:0] s_axi_awuser, input wire s_axi_awvalid, output wire s_axi_awready, // Slave Interface Write Data Ports input wire [C_AXI_ID_WIDTH-1:0] s_axi_wid, input wire [C_AXI_DATA_WIDTH-1:0] s_axi_wdata, input wire [C_AXI_DATA_WIDTH/8-1:0] s_axi_wstrb, input wire s_axi_wlast, input wire [C_AXI_WUSER_WIDTH-1:0] s_axi_wuser, input wire s_axi_wvalid, output wire s_axi_wready, // Slave Interface Write Response Ports output wire [C_AXI_ID_WIDTH-1:0] s_axi_bid, output wire [2-1:0] s_axi_bresp, output wire [C_AXI_BUSER_WIDTH-1:0] s_axi_buser, output wire s_axi_bvalid, input wire s_axi_bready, // Slave Interface Read Address Ports input wire [C_AXI_ID_WIDTH-1:0] s_axi_arid, input wire [C_AXI_ADDR_WIDTH-1:0] s_axi_araddr, input wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] s_axi_arlen, input wire [3-1:0] s_axi_arsize, input wire [2-1:0] s_axi_arburst, input wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] s_axi_arlock, input wire [4-1:0] s_axi_arcache, input wire [3-1:0] s_axi_arprot, input wire [4-1:0] s_axi_arregion, input wire [4-1:0] s_axi_arqos, input wire [C_AXI_ARUSER_WIDTH-1:0] s_axi_aruser, input wire s_axi_arvalid, output wire s_axi_arready, // Slave Interface Read Data Ports output wire [C_AXI_ID_WIDTH-1:0] s_axi_rid, output wire [C_AXI_DATA_WIDTH-1:0] s_axi_rdata, output wire [2-1:0] s_axi_rresp, output wire s_axi_rlast, output wire [C_AXI_RUSER_WIDTH-1:0] s_axi_ruser, output wire s_axi_rvalid, input wire s_axi_rready, // Master Interface Write Address Port output wire [C_AXI_ID_WIDTH-1:0] m_axi_awid, output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_awaddr, output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_awlen, output wire [3-1:0] m_axi_awsize, output wire [2-1:0] m_axi_awburst, output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_awlock, output wire [4-1:0] m_axi_awcache, output wire [3-1:0] m_axi_awprot, output wire [4-1:0] m_axi_awregion, output wire [4-1:0] m_axi_awqos, output wire [C_AXI_AWUSER_WIDTH-1:0] m_axi_awuser, output wire m_axi_awvalid, input wire m_axi_awready, // Master Interface Write Data Ports output wire [C_AXI_ID_WIDTH-1:0] m_axi_wid, output wire [C_AXI_DATA_WIDTH-1:0] m_axi_wdata, output wire [C_AXI_DATA_WIDTH/8-1:0] m_axi_wstrb, output wire m_axi_wlast, output wire [C_AXI_WUSER_WIDTH-1:0] m_axi_wuser, output wire m_axi_wvalid, input wire m_axi_wready, // Master Interface Write Response Ports input wire [C_AXI_ID_WIDTH-1:0] m_axi_bid, input wire [2-1:0] m_axi_bresp, input wire [C_AXI_BUSER_WIDTH-1:0] m_axi_buser, input wire m_axi_bvalid, output wire m_axi_bready, // Master Interface Read Address Port output wire [C_AXI_ID_WIDTH-1:0] m_axi_arid, output wire [C_AXI_ADDR_WIDTH-1:0] m_axi_araddr, output wire [((C_AXI_PROTOCOL == 1) ? 4 : 8)-1:0] m_axi_arlen, output wire [3-1:0] m_axi_arsize, output wire [2-1:0] m_axi_arburst, output wire [((C_AXI_PROTOCOL == 1) ? 2 : 1)-1:0] m_axi_arlock, output wire [4-1:0] m_axi_arcache, output wire [3-1:0] m_axi_arprot, output wire [4-1:0] m_axi_arregion, output wire [4-1:0] m_axi_arqos, output wire [C_AXI_ARUSER_WIDTH-1:0] m_axi_aruser, output wire m_axi_arvalid, input wire m_axi_arready, // Master Interface Read Data Ports input wire [C_AXI_ID_WIDTH-1:0] m_axi_rid, input wire [C_AXI_DATA_WIDTH-1:0] m_axi_rdata, input wire [2-1:0] m_axi_rresp, input wire m_axi_rlast, input wire [C_AXI_RUSER_WIDTH-1:0] m_axi_ruser, input wire m_axi_rvalid, output wire m_axi_rready); localparam integer P_WIDTH_RACH = 4+4+3+4+2+3+((C_AXI_PROTOCOL==1)?6:9)+C_AXI_ADDR_WIDTH+C_AXI_ID_WIDTH+C_AXI_ARUSER_WIDTH; localparam integer P_WIDTH_WACH = 4+4+3+4+2+3+((C_AXI_PROTOCOL==1)?6:9)+C_AXI_ADDR_WIDTH+C_AXI_ID_WIDTH+C_AXI_AWUSER_WIDTH; localparam integer P_WIDTH_RDCH = 1 + 2 + C_AXI_DATA_WIDTH + C_AXI_ID_WIDTH + C_AXI_RUSER_WIDTH; localparam integer P_WIDTH_WDCH = 1+C_AXI_DATA_WIDTH+C_AXI_DATA_WIDTH/8+((C_AXI_PROTOCOL==1)?C_AXI_ID_WIDTH:0)+C_AXI_WUSER_WIDTH; localparam integer P_WIDTH_WRCH = 2 + C_AXI_ID_WIDTH + C_AXI_BUSER_WIDTH; localparam P_PRIM_FIFO_TYPE = "512x72" ; localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; localparam integer P_WRITE_FIFO_DEPTH_LOG = (C_AXI_WRITE_FIFO_DEPTH > 1) ? f_ceil_log2(C_AXI_WRITE_FIFO_DEPTH) : 1; localparam integer P_READ_FIFO_DEPTH_LOG = (C_AXI_READ_FIFO_DEPTH > 1) ? f_ceil_log2(C_AXI_READ_FIFO_DEPTH) : 1; // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2**acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction generate if (((C_AXI_WRITE_FIFO_DEPTH == 0) && (C_AXI_READ_FIFO_DEPTH == 0)) || (C_AXI_PROTOCOL == P_AXILITE)) begin : gen_bypass assign m_axi_awid = s_axi_awid; assign m_axi_awaddr = s_axi_awaddr; assign m_axi_awlen = s_axi_awlen; assign m_axi_awsize = s_axi_awsize; assign m_axi_awburst = s_axi_awburst; assign m_axi_awlock = s_axi_awlock; assign m_axi_awcache = s_axi_awcache; assign m_axi_awprot = s_axi_awprot; assign m_axi_awregion = s_axi_awregion; assign m_axi_awqos = s_axi_awqos; assign m_axi_awuser = s_axi_awuser; assign m_axi_awvalid = s_axi_awvalid; assign s_axi_awready = m_axi_awready; assign m_axi_wid = s_axi_wid; assign m_axi_wdata = s_axi_wdata; assign m_axi_wstrb = s_axi_wstrb; assign m_axi_wlast = s_axi_wlast; assign m_axi_wuser = s_axi_wuser; assign m_axi_wvalid = s_axi_wvalid; assign s_axi_wready = m_axi_wready; assign s_axi_bid = m_axi_bid; assign s_axi_bresp = m_axi_bresp; assign s_axi_buser = m_axi_buser; assign s_axi_bvalid = m_axi_bvalid; assign m_axi_bready = s_axi_bready; assign m_axi_arid = s_axi_arid; assign m_axi_araddr = s_axi_araddr; assign m_axi_arlen = s_axi_arlen; assign m_axi_arsize = s_axi_arsize; assign m_axi_arburst = s_axi_arburst; assign m_axi_arlock = s_axi_arlock; assign m_axi_arcache = s_axi_arcache; assign m_axi_arprot = s_axi_arprot; assign m_axi_arregion = s_axi_arregion; assign m_axi_arqos = s_axi_arqos; assign m_axi_aruser = s_axi_aruser; assign m_axi_arvalid = s_axi_arvalid; assign s_axi_arready = m_axi_arready; assign s_axi_rid = m_axi_rid; assign s_axi_rdata = m_axi_rdata; assign s_axi_rresp = m_axi_rresp; assign s_axi_rlast = m_axi_rlast; assign s_axi_ruser = m_axi_ruser; assign s_axi_rvalid = m_axi_rvalid; assign m_axi_rready = s_axi_rready; end else begin : gen_fifo wire [4-1:0] s_axi_awregion_i; wire [4-1:0] s_axi_arregion_i; wire [4-1:0] m_axi_awregion_i; wire [4-1:0] m_axi_arregion_i; wire [C_AXI_ID_WIDTH-1:0] s_axi_wid_i; wire [C_AXI_ID_WIDTH-1:0] m_axi_wid_i; assign s_axi_awregion_i = (C_AXI_PROTOCOL == P_AXI3) ? 4'b0 : s_axi_awregion; assign s_axi_arregion_i = (C_AXI_PROTOCOL == P_AXI3) ? 4'b0 : s_axi_arregion; assign m_axi_awregion = (C_AXI_PROTOCOL == P_AXI3) ? 4'b0 : m_axi_awregion_i; assign m_axi_arregion = (C_AXI_PROTOCOL == P_AXI3) ? 4'b0 : m_axi_arregion_i; assign s_axi_wid_i = (C_AXI_PROTOCOL == P_AXI3) ? s_axi_wid : {C_AXI_ID_WIDTH{1'b0}}; assign m_axi_wid = (C_AXI_PROTOCOL == P_AXI3) ? m_axi_wid_i : {C_AXI_ID_WIDTH{1'b0}}; fifo_generator_v13_1_4 #( .C_INTERFACE_TYPE(2), .C_AXI_TYPE((C_AXI_PROTOCOL == P_AXI4) ? 1 : 3), .C_AXI_DATA_WIDTH(C_AXI_DATA_WIDTH), .C_AXI_ID_WIDTH(C_AXI_ID_WIDTH), .C_HAS_AXI_ID(1), .C_AXI_LEN_WIDTH((C_AXI_PROTOCOL == P_AXI4) ? 8 : 4), .C_AXI_LOCK_WIDTH((C_AXI_PROTOCOL == P_AXI4) ? 1 : 2), .C_HAS_AXI_ARUSER(1), .C_HAS_AXI_AWUSER(1), .C_HAS_AXI_BUSER(1), .C_HAS_AXI_RUSER(1), .C_HAS_AXI_WUSER(1), .C_AXI_ADDR_WIDTH(C_AXI_ADDR_WIDTH), .C_AXI_ARUSER_WIDTH(C_AXI_ARUSER_WIDTH), .C_AXI_AWUSER_WIDTH(C_AXI_AWUSER_WIDTH), .C_AXI_BUSER_WIDTH(C_AXI_BUSER_WIDTH), .C_AXI_RUSER_WIDTH(C_AXI_RUSER_WIDTH), .C_AXI_WUSER_WIDTH(C_AXI_WUSER_WIDTH), .C_DIN_WIDTH_RACH(P_WIDTH_RACH), .C_DIN_WIDTH_RDCH(P_WIDTH_RDCH), .C_DIN_WIDTH_WACH(P_WIDTH_WACH), .C_DIN_WIDTH_WDCH(P_WIDTH_WDCH), .C_DIN_WIDTH_WRCH(P_WIDTH_WDCH), .C_RACH_TYPE(((C_AXI_READ_FIFO_DEPTH != 0) && C_AXI_READ_FIFO_DELAY) ? 0 : 2), .C_WACH_TYPE(((C_AXI_WRITE_FIFO_DEPTH != 0) && C_AXI_WRITE_FIFO_DELAY) ? 0 : 2), .C_WDCH_TYPE((C_AXI_WRITE_FIFO_DEPTH != 0) ? 0 : 2), .C_RDCH_TYPE((C_AXI_READ_FIFO_DEPTH != 0) ? 0 : 2), .C_WRCH_TYPE(2), .C_COMMON_CLOCK(1), .C_ADD_NGC_CONSTRAINT(0), .C_APPLICATION_TYPE_AXIS(0), .C_APPLICATION_TYPE_RACH(C_AXI_READ_FIFO_DELAY ? 1 : 0), .C_APPLICATION_TYPE_RDCH(0), .C_APPLICATION_TYPE_WACH(C_AXI_WRITE_FIFO_DELAY ? 1 : 0), .C_APPLICATION_TYPE_WDCH(0), .C_APPLICATION_TYPE_WRCH(0), .C_AXIS_TDATA_WIDTH(64), .C_AXIS_TDEST_WIDTH(4), .C_AXIS_TID_WIDTH(8), .C_AXIS_TKEEP_WIDTH(4), .C_AXIS_TSTRB_WIDTH(4), .C_AXIS_TUSER_WIDTH(4), .C_AXIS_TYPE(0), .C_COUNT_TYPE(0), .C_DATA_COUNT_WIDTH(10), .C_DEFAULT_VALUE("BlankString"), .C_DIN_WIDTH(18), .C_DIN_WIDTH_AXIS(1), .C_DOUT_RST_VAL("0"), .C_DOUT_WIDTH(18), .C_ENABLE_RLOCS(0), .C_ENABLE_RST_SYNC(1), .C_ERROR_INJECTION_TYPE(0), .C_ERROR_INJECTION_TYPE_AXIS(0), .C_ERROR_INJECTION_TYPE_RACH(0), .C_ERROR_INJECTION_TYPE_RDCH(0), .C_ERROR_INJECTION_TYPE_WACH(0), .C_ERROR_INJECTION_TYPE_WDCH(0), .C_ERROR_INJECTION_TYPE_WRCH(0), .C_FAMILY(C_FAMILY), .C_FULL_FLAGS_RST_VAL(1), .C_HAS_ALMOST_EMPTY(0), .C_HAS_ALMOST_FULL(0), .C_HAS_AXI_RD_CHANNEL(1), .C_HAS_AXI_WR_CHANNEL(1), .C_HAS_AXIS_TDATA(0), .C_HAS_AXIS_TDEST(0), .C_HAS_AXIS_TID(0), .C_HAS_AXIS_TKEEP(0), .C_HAS_AXIS_TLAST(0), .C_HAS_AXIS_TREADY(1), .C_HAS_AXIS_TSTRB(0), .C_HAS_AXIS_TUSER(0), .C_HAS_BACKUP(0), .C_HAS_DATA_COUNT(0), .C_HAS_DATA_COUNTS_AXIS(0), .C_HAS_DATA_COUNTS_RACH(0), .C_HAS_DATA_COUNTS_RDCH(0), .C_HAS_DATA_COUNTS_WACH(0), .C_HAS_DATA_COUNTS_WDCH(0), .C_HAS_DATA_COUNTS_WRCH(0), .C_HAS_INT_CLK(0), .C_HAS_MASTER_CE(0), .C_HAS_MEMINIT_FILE(0), .C_HAS_OVERFLOW(0), .C_HAS_PROG_FLAGS_AXIS(0), .C_HAS_PROG_FLAGS_RACH(0), .C_HAS_PROG_FLAGS_RDCH(0), .C_HAS_PROG_FLAGS_WACH(0), .C_HAS_PROG_FLAGS_WDCH(0), .C_HAS_PROG_FLAGS_WRCH(0), .C_HAS_RD_DATA_COUNT(0), .C_HAS_RD_RST(0), .C_HAS_RST(1), .C_HAS_SLAVE_CE(0), .C_HAS_SRST(0), .C_HAS_UNDERFLOW(0), .C_HAS_VALID(0), .C_HAS_WR_ACK(0), .C_HAS_WR_DATA_COUNT(0), .C_HAS_WR_RST(0), .C_IMPLEMENTATION_TYPE(0), .C_IMPLEMENTATION_TYPE_AXIS(1), .C_IMPLEMENTATION_TYPE_RACH(2), .C_IMPLEMENTATION_TYPE_RDCH((C_AXI_READ_FIFO_TYPE == "bram") ? 1 : 2), .C_IMPLEMENTATION_TYPE_WACH(2), .C_IMPLEMENTATION_TYPE_WDCH((C_AXI_WRITE_FIFO_TYPE == "bram") ? 1 : 2), .C_IMPLEMENTATION_TYPE_WRCH(2), .C_INIT_WR_PNTR_VAL(0), .C_MEMORY_TYPE(1), .C_MIF_FILE_NAME("BlankString"), .C_MSGON_VAL(1), .C_OPTIMIZATION_MODE(0), .C_OVERFLOW_LOW(0), .C_PRELOAD_LATENCY(1), .C_PRELOAD_REGS(0), .C_PRIM_FIFO_TYPE(P_PRIM_FIFO_TYPE), .C_PROG_EMPTY_THRESH_ASSERT_VAL(2), .C_PROG_EMPTY_THRESH_ASSERT_VAL_AXIS(1022), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RACH(30), .C_PROG_EMPTY_THRESH_ASSERT_VAL_RDCH(510), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WACH(30), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WDCH(510), .C_PROG_EMPTY_THRESH_ASSERT_VAL_WRCH(14), .C_PROG_EMPTY_THRESH_NEGATE_VAL(3), .C_PROG_EMPTY_TYPE(0), .C_PROG_EMPTY_TYPE_AXIS(5), .C_PROG_EMPTY_TYPE_RACH(5), .C_PROG_EMPTY_TYPE_RDCH(5), .C_PROG_EMPTY_TYPE_WACH(5), .C_PROG_EMPTY_TYPE_WDCH(5), .C_PROG_EMPTY_TYPE_WRCH(5), .C_PROG_FULL_THRESH_ASSERT_VAL(1022), .C_PROG_FULL_THRESH_ASSERT_VAL_AXIS(1023), .C_PROG_FULL_THRESH_ASSERT_VAL_RACH(31), .C_PROG_FULL_THRESH_ASSERT_VAL_RDCH(511), .C_PROG_FULL_THRESH_ASSERT_VAL_WACH(31), .C_PROG_FULL_THRESH_ASSERT_VAL_WDCH(511), .C_PROG_FULL_THRESH_ASSERT_VAL_WRCH(15), .C_PROG_FULL_THRESH_NEGATE_VAL(1021), .C_PROG_FULL_TYPE(0), .C_PROG_FULL_TYPE_AXIS(5), .C_PROG_FULL_TYPE_RACH(5), .C_PROG_FULL_TYPE_RDCH(5), .C_PROG_FULL_TYPE_WACH(5), .C_PROG_FULL_TYPE_WDCH(5), .C_PROG_FULL_TYPE_WRCH(5), .C_RD_DATA_COUNT_WIDTH(10), .C_RD_DEPTH(1024), .C_RD_FREQ(1), .C_RD_PNTR_WIDTH(10), .C_REG_SLICE_MODE_AXIS(0), .C_REG_SLICE_MODE_RACH(0), .C_REG_SLICE_MODE_RDCH(0), .C_REG_SLICE_MODE_WACH(0), .C_REG_SLICE_MODE_WDCH(0), .C_REG_SLICE_MODE_WRCH(0), .C_UNDERFLOW_LOW(0), .C_USE_COMMON_OVERFLOW(0), .C_USE_COMMON_UNDERFLOW(0), .C_USE_DEFAULT_SETTINGS(0), .C_USE_DOUT_RST(1), .C_USE_ECC(0), .C_USE_ECC_AXIS(0), .C_USE_ECC_RACH(0), .C_USE_ECC_RDCH(0), .C_USE_ECC_WACH(0), .C_USE_ECC_WDCH(0), .C_USE_ECC_WRCH(0), .C_USE_EMBEDDED_REG(0), .C_USE_FIFO16_FLAGS(0), .C_USE_FWFT_DATA_COUNT(0), .C_VALID_LOW(0), .C_WR_ACK_LOW(0), .C_WR_DATA_COUNT_WIDTH(10), .C_WR_DEPTH(1024), .C_WR_DEPTH_AXIS(1024), .C_WR_DEPTH_RACH(32), .C_WR_DEPTH_RDCH(C_AXI_READ_FIFO_DEPTH), .C_WR_DEPTH_WACH(32), .C_WR_DEPTH_WDCH(C_AXI_WRITE_FIFO_DEPTH), .C_WR_DEPTH_WRCH(16), .C_WR_FREQ(1), .C_WR_PNTR_WIDTH(10), .C_WR_PNTR_WIDTH_AXIS(10), .C_WR_PNTR_WIDTH_RACH(5), .C_WR_PNTR_WIDTH_RDCH((C_AXI_READ_FIFO_DEPTH> 1) ? f_ceil_log2(C_AXI_READ_FIFO_DEPTH) : 1), .C_WR_PNTR_WIDTH_WACH(5), .C_WR_PNTR_WIDTH_WDCH((C_AXI_WRITE_FIFO_DEPTH > 1) ? f_ceil_log2(C_AXI_WRITE_FIFO_DEPTH) : 1), .C_WR_PNTR_WIDTH_WRCH(4), .C_WR_RESPONSE_LATENCY(1) ) fifo_gen_inst ( .s_aclk(aclk), .s_aresetn(aresetn), .s_axi_awid(s_axi_awid), .s_axi_awaddr(s_axi_awaddr), .s_axi_awlen(s_axi_awlen), .s_axi_awsize(s_axi_awsize), .s_axi_awburst(s_axi_awburst), .s_axi_awlock(s_axi_awlock), .s_axi_awcache(s_axi_awcache), .s_axi_awprot(s_axi_awprot), .s_axi_awqos(s_axi_awqos), .s_axi_awregion(s_axi_awregion_i), .s_axi_awuser(s_axi_awuser), .s_axi_awvalid(s_axi_awvalid), .s_axi_awready(s_axi_awready), .s_axi_wid(s_axi_wid_i), .s_axi_wdata(s_axi_wdata), .s_axi_wstrb(s_axi_wstrb), .s_axi_wlast(s_axi_wlast), .s_axi_wvalid(s_axi_wvalid), .s_axi_wready(s_axi_wready), .s_axi_bid(s_axi_bid), .s_axi_bresp(s_axi_bresp), .s_axi_bvalid(s_axi_bvalid), .s_axi_bready(s_axi_bready), .m_axi_awid(m_axi_awid), .m_axi_awaddr(m_axi_awaddr), .m_axi_awlen(m_axi_awlen), .m_axi_awsize(m_axi_awsize), .m_axi_awburst(m_axi_awburst), .m_axi_awlock(m_axi_awlock), .m_axi_awcache(m_axi_awcache), .m_axi_awprot(m_axi_awprot), .m_axi_awqos(m_axi_awqos), .m_axi_awregion(m_axi_awregion_i), .m_axi_awuser(m_axi_awuser), .m_axi_awvalid(m_axi_awvalid), .m_axi_awready(m_axi_awready), .m_axi_wid(m_axi_wid_i), .m_axi_wdata(m_axi_wdata), .m_axi_wstrb(m_axi_wstrb), .m_axi_wlast(m_axi_wlast), .m_axi_wvalid(m_axi_wvalid), .m_axi_wready(m_axi_wready), .m_axi_bid(m_axi_bid), .m_axi_bresp(m_axi_bresp), .m_axi_bvalid(m_axi_bvalid), .m_axi_bready(m_axi_bready), .s_axi_arid(s_axi_arid), .s_axi_araddr(s_axi_araddr), .s_axi_arlen(s_axi_arlen), .s_axi_arsize(s_axi_arsize), .s_axi_arburst(s_axi_arburst), .s_axi_arlock(s_axi_arlock), .s_axi_arcache(s_axi_arcache), .s_axi_arprot(s_axi_arprot), .s_axi_arqos(s_axi_arqos), .s_axi_arregion(s_axi_arregion_i), .s_axi_arvalid(s_axi_arvalid), .s_axi_arready(s_axi_arready), .s_axi_rid(s_axi_rid), .s_axi_rdata(s_axi_rdata), .s_axi_rresp(s_axi_rresp), .s_axi_rlast(s_axi_rlast), .s_axi_rvalid(s_axi_rvalid), .s_axi_rready(s_axi_rready), .m_axi_arid(m_axi_arid), .m_axi_araddr(m_axi_araddr), .m_axi_arlen(m_axi_arlen), .m_axi_arsize(m_axi_arsize), .m_axi_arburst(m_axi_arburst), .m_axi_arlock(m_axi_arlock), .m_axi_arcache(m_axi_arcache), .m_axi_arprot(m_axi_arprot), .m_axi_arqos(m_axi_arqos), .m_axi_arregion(m_axi_arregion_i), .m_axi_arvalid(m_axi_arvalid), .m_axi_arready(m_axi_arready), .m_axi_rid(m_axi_rid), .m_axi_rdata(m_axi_rdata), .m_axi_rresp(m_axi_rresp), .m_axi_rlast(m_axi_rlast), .m_axi_rvalid(m_axi_rvalid), .m_axi_rready(m_axi_rready), .m_aclk(aclk), .m_aclk_en(1'b1), .s_aclk_en(1'b1), .s_axi_wuser(s_axi_wuser), .s_axi_buser(s_axi_buser), .m_axi_wuser(m_axi_wuser), .m_axi_buser(m_axi_buser), .s_axi_aruser(s_axi_aruser), .s_axi_ruser(s_axi_ruser), .m_axi_aruser(m_axi_aruser), .m_axi_ruser(m_axi_ruser), .almost_empty(), .almost_full(), .axis_data_count(), .axis_dbiterr(), .axis_injectdbiterr(1'b0), .axis_injectsbiterr(1'b0), .axis_overflow(), .axis_prog_empty(), .axis_prog_empty_thresh(10'b0), .axis_prog_full(), .axis_prog_full_thresh(10'b0), .axis_rd_data_count(), .axis_sbiterr(), .axis_underflow(), .axis_wr_data_count(), .axi_ar_data_count(), .axi_ar_dbiterr(), .axi_ar_injectdbiterr(1'b0), .axi_ar_injectsbiterr(1'b0), .axi_ar_overflow(), .axi_ar_prog_empty(), .axi_ar_prog_empty_thresh(5'b0), .axi_ar_prog_full(), .axi_ar_prog_full_thresh(5'b0), .axi_ar_rd_data_count(), .axi_ar_sbiterr(), .axi_ar_underflow(), .axi_ar_wr_data_count(), .axi_aw_data_count(), .axi_aw_dbiterr(), .axi_aw_injectdbiterr(1'b0), .axi_aw_injectsbiterr(1'b0), .axi_aw_overflow(), .axi_aw_prog_empty(), .axi_aw_prog_empty_thresh(5'b0), .axi_aw_prog_full(), .axi_aw_prog_full_thresh(5'b0), .axi_aw_rd_data_count(), .axi_aw_sbiterr(), .axi_aw_underflow(), .axi_aw_wr_data_count(), .axi_b_data_count(), .axi_b_dbiterr(), .axi_b_injectdbiterr(1'b0), .axi_b_injectsbiterr(1'b0), .axi_b_overflow(), .axi_b_prog_empty(), .axi_b_prog_empty_thresh(4'b0), .axi_b_prog_full(), .axi_b_prog_full_thresh(4'b0), .axi_b_rd_data_count(), .axi_b_sbiterr(), .axi_b_underflow(), .axi_b_wr_data_count(), .axi_r_data_count(), .axi_r_dbiterr(), .axi_r_injectdbiterr(1'b0), .axi_r_injectsbiterr(1'b0), .axi_r_overflow(), .axi_r_prog_empty(), .axi_r_prog_empty_thresh({P_READ_FIFO_DEPTH_LOG{1'b0}}), .axi_r_prog_full(), .axi_r_prog_full_thresh({P_READ_FIFO_DEPTH_LOG{1'b0}}), .axi_r_rd_data_count(), .axi_r_sbiterr(), .axi_r_underflow(), .axi_r_wr_data_count(), .axi_w_data_count(), .axi_w_dbiterr(), .axi_w_injectdbiterr(1'b0), .axi_w_injectsbiterr(1'b0), .axi_w_overflow(), .axi_w_prog_empty(), .axi_w_prog_empty_thresh({P_WRITE_FIFO_DEPTH_LOG{1'b0}}), .axi_w_prog_full(), .axi_w_prog_full_thresh({P_WRITE_FIFO_DEPTH_LOG{1'b0}}), .axi_w_rd_data_count(), .axi_w_sbiterr(), .axi_w_underflow(), .axi_w_wr_data_count(), .backup(1'b0), .backup_marker(1'b0), .clk(1'b0), .data_count(), .dbiterr(), .din(18'b0), .dout(), .empty(), .full(), .injectdbiterr(1'b0), .injectsbiterr(1'b0), .int_clk(1'b0), .m_axis_tdata(), .m_axis_tdest(), .m_axis_tid(), .m_axis_tkeep(), .m_axis_tlast(), .m_axis_tready(1'b0), .m_axis_tstrb(), .m_axis_tuser(), .m_axis_tvalid(), .overflow(), .prog_empty(), .prog_empty_thresh(10'b0), .prog_empty_thresh_assert(10'b0), .prog_empty_thresh_negate(10'b0), .prog_full(), .prog_full_thresh(10'b0), .prog_full_thresh_assert(10'b0), .prog_full_thresh_negate(10'b0), .rd_clk(1'b0), .rd_data_count(), .rd_en(1'b0), .rd_rst(1'b0), .rst(1'b0), .sbiterr(), .srst(1'b0), .s_axis_tdata(64'b0), .s_axis_tdest(4'b0), .s_axis_tid(8'b0), .s_axis_tkeep(4'b0), .s_axis_tlast(1'b0), .s_axis_tready(), .s_axis_tstrb(4'b0), .s_axis_tuser(4'b0), .s_axis_tvalid(1'b0), .underflow(), .valid(), .wr_ack(), .wr_clk(1'b0), .wr_data_count(), .wr_en(1'b0), .wr_rst(1'b0), .wr_rst_busy(), .rd_rst_busy(), .sleep(1'b0) ); end endgenerate endmodule

module wb_arbiter_tb #(parameter NUM_MASTERS = 5) (input wb_clk_i, input wb_rst_i, output done); localparam aw = 32; localparam dw = 32; localparam MEMORY_SIZE_BITS = 8; localparam MEMORY_SIZE_WORDS = 2**MEMORY_SIZE_BITS; wire [aw-1:0] wbs_m2s_adr; wire [dw-1:0] wbs_m2s_dat; wire [3:0] wbs_m2s_sel; wire wbs_m2s_we ; wire wbs_m2s_cyc; wire wbs_m2s_stb; wire [2:0] wbs_m2s_cti; wire [1:0] wbs_m2s_bte; wire [dw-1:0] wbs_s2m_dat; wire wbs_s2m_ack; wire wbs_s2m_err; wire wbs_s2m_rty; wire [NUM_MASTERS*aw-1:0] wbm_m2s_adr; wire [NUM_MASTERS*dw-1:0] wbm_m2s_dat; wire [NUM_MASTERS*4-1:0] wbm_m2s_sel; wire [NUM_MASTERS-1:0] wbm_m2s_we ; wire [NUM_MASTERS-1:0] wbm_m2s_cyc; wire [NUM_MASTERS-1:0] wbm_m2s_stb; wire [NUM_MASTERS*3-1:0] wbm_m2s_cti; wire [NUM_MASTERS*2-1:0] wbm_m2s_bte; wire [NUM_MASTERS*dw-1:0] wbm_s2m_dat; wire [NUM_MASTERS-1:0] wbm_s2m_ack; wire [NUM_MASTERS-1:0] wbm_s2m_err; wire [NUM_MASTERS-1:0] wbm_s2m_rty; wire [31:0] slave_writes; wire [31:0] slave_reads; wire [NUM_MASTERS-1:0] done_int; genvar i; generate for(i=0;i<NUM_MASTERS;i=i+1) begin : masters wb_bfm_transactor #(.MEM_HIGH((i+1)*MEMORY_SIZE_WORDS-1), .MEM_LOW (i*MEMORY_SIZE_WORDS)) wb_bfm_transactor0 (.wb_clk_i (wb_clk_i), .wb_rst_i (wb_rst_i), .wb_adr_o (wbm_m2s_adr[i*aw+:aw]), .wb_dat_o (wbm_m2s_dat[i*dw+:dw]), .wb_sel_o (wbm_m2s_sel[i*4+:4]), .wb_we_o (wbm_m2s_we[i] ), .wb_cyc_o (wbm_m2s_cyc[i]), .wb_stb_o (wbm_m2s_stb[i]), .wb_cti_o (wbm_m2s_cti[i*3+:3]), .wb_bte_o (wbm_m2s_bte[i*2+:2]), .wb_dat_i (wbm_s2m_dat[i*dw+:dw]), .wb_ack_i (wbm_s2m_ack[i]), .wb_err_i (wbm_s2m_err[i]), .wb_rty_i (wbm_s2m_rty[i]), //Test Control .done(done_int[i])); end // block: slaves endgenerate integer idx; assign done = &done_int; always @(done) begin if(done === 1) begin $display("Average wait times"); for(idx=0;idx<NUM_MASTERS;idx=idx+1) $display("Master %0d : %f",idx, ack_delay[idx]/num_transactions[idx]); $display("All tests passed!"); end end wb_arbiter #(.num_masters(NUM_MASTERS)) wb_arbiter0 (.wb_clk_i (wb_clk_i), .wb_rst_i (wb_rst_i), // Master Interface .wbm_adr_i (wbm_m2s_adr), .wbm_dat_i (wbm_m2s_dat), .wbm_sel_i (wbm_m2s_sel), .wbm_we_i (wbm_m2s_we ), .wbm_cyc_i (wbm_m2s_cyc), .wbm_stb_i (wbm_m2s_stb), .wbm_cti_i (wbm_m2s_cti), .wbm_bte_i (wbm_m2s_bte), .wbm_dat_o (wbm_s2m_dat), .wbm_ack_o (wbm_s2m_ack), .wbm_err_o (wbm_s2m_err), .wbm_rty_o (wbm_s2m_rty), // Wishbone Slave interface .wbs_adr_o (wbs_m2s_adr), .wbs_dat_o (wbs_m2s_dat), .wbs_sel_o (wbs_m2s_sel), .wbs_we_o (wbs_m2s_we), .wbs_cyc_o (wbs_m2s_cyc), .wbs_stb_o (wbs_m2s_stb), .wbs_cti_o (wbs_m2s_cti), .wbs_bte_o (wbs_m2s_bte), .wbs_dat_i (wbs_s2m_dat), .wbs_ack_i (wbs_s2m_ack), .wbs_err_i (wbs_s2m_err), .wbs_rty_i (wbs_s2m_rty)); assign slave_writes = wb_mem_model0.writes; assign slave_reads = wb_mem_model0.reads; time start_time[NUM_MASTERS-1:0]; time ack_delay[NUM_MASTERS-1:0]; integer num_transactions[NUM_MASTERS-1:0]; generate for(i=0;i<NUM_MASTERS;i=i+1) begin : wait_time initial begin ack_delay[i] = 0; num_transactions[i] = 0; while(1) begin @(posedge wbm_m2s_cyc[i]); start_time[i] = $time; @(posedge wbm_s2m_ack[i]); ack_delay[i] = ack_delay[i] + $time-start_time[i]; num_transactions[i] = num_transactions[i]+1; end end end endgenerate wb_bfm_memory #(.DEBUG (0), .mem_size_bytes(MEMORY_SIZE_WORDS*(dw/8)*NUM_MASTERS)) wb_mem_model0 (.wb_clk_i (wb_clk_i), .wb_rst_i (wb_rst_i), .wb_adr_i (wbs_m2s_adr), .wb_dat_i (wbs_m2s_dat), .wb_sel_i (wbs_m2s_sel), .wb_we_i (wbs_m2s_we), .wb_cyc_i (wbs_m2s_cyc), .wb_stb_i (wbs_m2s_stb), .wb_cti_i (wbs_m2s_cti), .wb_bte_i (wbs_m2s_bte), .wb_dat_o (wbs_s2m_dat), .wb_ack_o (wbs_s2m_ack), .wb_err_o (wbs_s2m_err), .wb_rty_o (wbs_s2m_rty)); endmodule

/** * This is written by Zhiyang Ong * and Andrew Mattheisen * for EE577b Troy WideWord Processor Project * * * @reminder December 1, 2007 * Remember to remove wrbyteen and ctrl_ppp from the inputs to * the ALU and its testbench */ /** * Reference: * Nestoras Tzartzanis, EE 577B Verilog Example, Jan 25, 1996 * http://www-scf.usc.edu/~ee577/tutorial/verilog/alu.v */ /** * Note that all instructions are 32-bits, and that Big-Endian * byte and bit labeling is used. Hence, a[0] is the most * significant bit, and a[31] is the least significant bit. * * Use of casex and casez may affect functionality, and produce * larger and slower designs that omit the full_case directive * * Reference: * Don Mills and Clifford E. Cummings, "RTL Coding Styles That * Yield Simulation and Synthesis Mismatches", SNUG 1999 * * ALU is a combinational logic block without clock signals */ `include "/auto/home-scf-07/zhiyango/ee577b/projs/processor/syn/src/control.h" // Behavioral model for the ALU module alu (reg_A,reg_B,ctrl_ww,alu_op,result); // Output signals... // Result from copmputing an arithmetic or logical operation output [0:127] result; /** * Overflow fromn arithmetic operations are ignored; use * saturating mode for arithmetic operations - cap the value * at the maximum value. * * Also, an output signal to indicate that an overflow has * occurred will not be provided */ // =============================================================== // Input signals // Input register A input [0:127] reg_A; // Input register B input [0:127] reg_B; // Control signal bits - ww input [0:1] ctrl_ww; /** * Control signal bits - determine which arithmetic or logic * operation to perform */ input [0:4] alu_op; /** * May also include: branch_offset[n:0], is_branch * Size of branch offset is specified in the Instruction Set * Architecture * * The reset signal for the ALU is ignored */ // Defining constants: parameter [name_of_constant] = value; // =============================================================== // Declare "wire" signals: //wire FSM_OUTPUT; // =============================================================== // Declare "reg" signals: reg [0:127] result; // Output signals // =============================================================== always @(reg_A or reg_B or ctrl_ww or alu_op) begin /** * Based on the assigned arithmetic or logic instruction, * carry out the appropriate function on the operands */ case(alu_op) // ====================================================== // Unsigned Multiplication - even subfields `aluwmuleu: begin case(ctrl_ww) `w8: // aluwsrl AND `aa AND `w8 begin result[0:15]=reg_A[0:7]*reg_B[0:7]; result[16:31]=reg_A[16:23]*reg_B[16:23]; result[32:47]=reg_A[32:39]*reg_B[32:39]; result[48:63]=reg_A[48:55]*reg_B[48:55]; result[64:79]=reg_A[64:71]*reg_B[64:71]; result[80:95]=reg_A[80:87]*reg_B[80:87]; result[96:111]=reg_A[96:103]*reg_B[96:103]; result[112:127]=reg_A[112:119]*reg_B[112:119]; end `w16: // aluwsrl AND `aa AND `w16 begin result[0:31]=reg_A[0:15]*reg_B[0:15]; result[32:63]=reg_A[32:47]*reg_B[32:47]; result[64:95]=reg_A[64:79]*reg_B[64:79]; result[96:127]=reg_A[96:111]*reg_B[96:111]; end default: // aluwsrl AND `aa AND Default begin result=128'd0; end endcase end // Unsigned Multiplication - odd subfields `aluwmulou: begin case(ctrl_ww) `w8: // aluwsrl AND `aa AND `w8 begin result[0:15]=reg_A[8:15]*reg_B[8:15]; result[16:31]=reg_A[24:31]*reg_B[24:31]; result[32:47]=reg_A[40:47]*reg_B[40:47]; result[48:63]=reg_A[56:63]*reg_B[56:63]; result[64:79]=reg_A[72:79]*reg_B[72:79]; result[80:95]=reg_A[88:95]*reg_B[88:95]; result[96:111]=reg_A[104:111]*reg_B[104:111]; result[112:127]=reg_A[120:127]*reg_B[120:127]; end `w16: // aluwsrl AND `aa AND `w16 begin result[0:31]=reg_A[16:31]*reg_B[16:31]; result[32:63]=reg_A[48:63]*reg_B[48:63]; result[64:95]=reg_A[80:95]*reg_B[80:95]; result[96:127]=reg_A[112:127]*reg_B[112:127]; end default: // aluwsrl AND `aa AND Default begin result=128'd0; end endcase end default: begin // Default arithmetic/logic operation result=128'd0; end endcase end endmodule

// -*- verilog -*- // // USRP - Universal Software Radio Peripheral // // Copyright (C) 2007 Corgan Enterprises LLC // // This program is free software; you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation; either version 2 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 51 Franklin Street, Boston, MA 02110-1301 USA // `include "../top/config.vh" module dac_interface(clk_i,rst_i,ena_i,strobe_i,tx_i_i,tx_q_i,tx_data_o,tx_sync_o); input clk_i; input rst_i; input ena_i; input strobe_i; input [13:0] tx_i_i; input [13:0] tx_q_i; output [13:0] tx_data_o; output tx_sync_o; `ifdef TX_RATE_MAX wire clk128; reg clk64_d; reg [13:0] tx_data_o; // Create a 128 MHz clock dacpll pll128(.areset(rst_i),.inclk0(clk_i),.c0(clk128)); // Register the clk64 clock in the clk128 domain always @(posedge clk128) clk64_d <= #1 clk_i; // Register the tx data in the clk128 domain always @(posedge clk128) tx_data_o <= #1 clk64_d ? tx_i_i : tx_q_i; assign tx_sync_o = clk64_d; `else // !`ifdef TX_RATE_MAX assign tx_data_o = strobe_i ? tx_q_i : tx_i_i; assign tx_sync_o = strobe_i; `endif // !`ifdef TX_RATE_MAX endmodule // dac_interface

//Legal Notice: (C)2019 Altera Corporation. All rights reserved. Your //use of Altera Corporation's design tools, logic functions and other //software and tools, and its AMPP partner logic functions, and any //output files any of the foregoing (including device programming or //simulation files), and any associated documentation or information are //expressly subject to the terms and conditions of the Altera Program //License Subscription Agreement or other applicable license agreement, //including, without limitation, that your use is for the sole purpose //of programming logic devices manufactured by Altera and sold by Altera //or its authorized distributors. Please refer to the applicable //agreement for further details. // synthesis translate_off `timescale 1ns / 1ps // synthesis translate_on // turn off superfluous verilog processor warnings // altera message_level Level1 // altera message_off 10034 10035 10036 10037 10230 10240 10030 module nios_dut_pio_0 ( // inputs: address, chipselect, clk, in_port, reset_n, write_n, writedata, // outputs: irq, readdata ) ; output irq; output [ 31: 0] readdata; input [ 1: 0] address; input chipselect; input clk; input in_port; input reset_n; input write_n; input [ 31: 0] writedata; wire clk_en; wire data_in; wire irq; reg irq_mask; wire read_mux_out; reg [ 31: 0] readdata; assign clk_en = 1; //s1, which is an e_avalon_slave assign read_mux_out = ({1 {(address == 0)}} & data_in) | ({1 {(address == 2)}} & irq_mask); always @(posedge clk or negedge reset_n) begin if (reset_n == 0) readdata <= 0; else if (clk_en) readdata <= {32'b0 | read_mux_out}; end assign data_in = in_port; always @(posedge clk or negedge reset_n) begin if (reset_n == 0) irq_mask <= 0; else if (chipselect && ~write_n && (address == 2)) irq_mask <= writedata; end assign irq = |(data_in & irq_mask); endmodule

// -- (c) Copyright 2009 - 2011 Xilinx, Inc. All rights reserved. // -- // -- This file contains confidential and proprietary information // -- of Xilinx, Inc. and is protected under U.S. and // -- international copyright and other intellectual property // -- laws. // -- // -- DISCLAIMER // -- This disclaimer is not a license and does not grant any // -- rights to the materials distributed herewith. Except as // -- otherwise provided in a valid license issued to you by // -- Xilinx, and to the maximum extent permitted by applicable // -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // -- (2) Xilinx shall not be liable (whether in contract or tort, // -- including negligence, or under any other theory of // -- liability) for any loss or damage of any kind or nature // -- related to, arising under or in connection with these // -- materials, including for any direct, or any indirect, // -- special, incidental, or consequential loss or damage // -- (including loss of data, profits, goodwill, or any type of // -- loss or damage suffered as a result of any action brought // -- by a third party) even if such damage or loss was // -- reasonably foreseeable or Xilinx had been advised of the // -- possibility of the same. // -- // -- CRITICAL APPLICATIONS // -- Xilinx products are not designed or intended to be fail- // -- safe, or for use in any application requiring fail-safe // -- performance, such as life-support or safety devices or // -- systems, Class III medical devices, nuclear facilities, // -- applications related to the deployment of airbags, or any // -- other applications that could lead to death, personal // -- injury, or severe property or environmental damage // -- (individually and collectively, "Critical // -- Applications"). Customer assumes the sole risk and // -- liability of any use of Xilinx products in Critical // -- Applications, subject only to applicable laws and // -- regulations governing limitations on product liability. // -- // -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // -- PART OF THIS FILE AT ALL TIMES. //----------------------------------------------------------------------------- // // File name: crossbar.v // // Description: // This module is a M-master to N-slave AXI axi_crossbar_v2_1_crossbar switch. // The interface of this module consists of a vectored slave and master interface // in which all slots are sized and synchronized to the native width and clock // of the interconnect. // The SAMD axi_crossbar_v2_1_crossbar supports only AXI4 and AXI3 protocols. // All width, clock and protocol conversions are done outside this block, as are // any pipeline registers or data FIFOs. // This module contains all arbitration, decoders and channel multiplexing logic. // It also contains the diagnostic registers and control interface. // //----------------------------------------------------------------------------- // // Structure: // crossbar // si_transactor // addr_decoder // comparator_static // mux_enc // axic_srl_fifo // arbiter_resp // splitter // wdata_router // axic_reg_srl_fifo // wdata_mux // axic_reg_srl_fifo // mux_enc // addr_decoder // comparator_static // axic_srl_fifo // axi_register_slice // addr_arbiter // mux_enc // decerr_slave // //----------------------------------------------------------------------------- `timescale 1ps/1ps `default_nettype none (* DowngradeIPIdentifiedWarnings="yes" *) module axi_crossbar_v2_1_crossbar # ( parameter C_FAMILY = "none", parameter integer C_NUM_SLAVE_SLOTS = 1, parameter integer C_NUM_MASTER_SLOTS = 1, parameter integer C_NUM_ADDR_RANGES = 1, parameter integer C_AXI_ID_WIDTH = 1, parameter integer C_AXI_ADDR_WIDTH = 32, parameter integer C_AXI_DATA_WIDTH = 32, parameter integer C_AXI_PROTOCOL = 0, parameter [C_NUM_MASTER_SLOTS*C_NUM_ADDR_RANGES*64-1:0] C_M_AXI_BASE_ADDR = {C_NUM_MASTER_SLOTS*C_NUM_ADDR_RANGES*64{1'b1}}, parameter [C_NUM_MASTER_SLOTS*C_NUM_ADDR_RANGES*64-1:0] C_M_AXI_HIGH_ADDR = {C_NUM_MASTER_SLOTS*C_NUM_ADDR_RANGES*64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS*64-1:0] C_S_AXI_BASE_ID = {C_NUM_SLAVE_SLOTS*64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS*64-1:0] C_S_AXI_HIGH_ID = {C_NUM_SLAVE_SLOTS*64{1'b0}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_S_AXI_THREAD_ID_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_AXI_SUPPORTS_USER_SIGNALS = 0, parameter integer C_AXI_AWUSER_WIDTH = 1, parameter integer C_AXI_ARUSER_WIDTH = 1, parameter integer C_AXI_WUSER_WIDTH = 1, parameter integer C_AXI_RUSER_WIDTH = 1, parameter integer C_AXI_BUSER_WIDTH = 1, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_WRITE = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_SLAVE_SLOTS-1:0] C_S_AXI_SUPPORTS_READ = {C_NUM_SLAVE_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_WRITE = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS-1:0] C_M_AXI_SUPPORTS_READ = {C_NUM_MASTER_SLOTS{1'b1}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_WRITE_CONNECTIVITY = {C_NUM_MASTER_SLOTS*32{1'b1}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_READ_CONNECTIVITY = {C_NUM_MASTER_SLOTS*32{1'b1}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_S_AXI_SINGLE_THREAD = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_S_AXI_WRITE_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_S_AXI_READ_ACCEPTANCE = {C_NUM_SLAVE_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_WRITE_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_READ_ISSUING = {C_NUM_MASTER_SLOTS{32'h00000001}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_S_AXI_ARB_PRIORITY = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_SECURE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter [C_NUM_MASTER_SLOTS*32-1:0] C_M_AXI_ERR_MODE = {C_NUM_MASTER_SLOTS{32'h00000000}}, parameter integer C_RANGE_CHECK = 0, parameter integer C_ADDR_DECODE = 0, parameter [(C_NUM_MASTER_SLOTS+1)*32-1:0] C_W_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [(C_NUM_MASTER_SLOTS+1)*32-1:0] C_R_ISSUE_WIDTH = {C_NUM_MASTER_SLOTS+1{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_W_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter [C_NUM_SLAVE_SLOTS*32-1:0] C_R_ACCEPT_WIDTH = {C_NUM_SLAVE_SLOTS{32'h00000000}}, parameter integer C_DEBUG = 1 ) ( // Global Signals input wire ACLK, input wire ARESETN, // Slave Interface Write Address Ports input wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] S_AXI_AWID, input wire [C_NUM_SLAVE_SLOTS*C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR, input wire [C_NUM_SLAVE_SLOTS*8-1:0] S_AXI_AWLEN, input wire [C_NUM_SLAVE_SLOTS*3-1:0] S_AXI_AWSIZE, input wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_AWBURST, input wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_AWLOCK, input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_AWCACHE, input wire [C_NUM_SLAVE_SLOTS*3-1:0] S_AXI_AWPROT, // input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_AWREGION, input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_AWQOS, input wire [C_NUM_SLAVE_SLOTS*C_AXI_AWUSER_WIDTH-1:0] S_AXI_AWUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_AWREADY, // Slave Interface Write Data Ports input wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] S_AXI_WID, input wire [C_NUM_SLAVE_SLOTS*C_AXI_DATA_WIDTH-1:0] S_AXI_WDATA, input wire [C_NUM_SLAVE_SLOTS*C_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WLAST, input wire [C_NUM_SLAVE_SLOTS*C_AXI_WUSER_WIDTH-1:0] S_AXI_WUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_WREADY, // Slave Interface Write Response Ports output wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] S_AXI_BID, output wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_BRESP, output wire [C_NUM_SLAVE_SLOTS*C_AXI_BUSER_WIDTH-1:0] S_AXI_BUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_BREADY, // Slave Interface Read Address Ports input wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] S_AXI_ARID, input wire [C_NUM_SLAVE_SLOTS*C_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR, input wire [C_NUM_SLAVE_SLOTS*8-1:0] S_AXI_ARLEN, input wire [C_NUM_SLAVE_SLOTS*3-1:0] S_AXI_ARSIZE, input wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_ARBURST, input wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_ARLOCK, input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_ARCACHE, input wire [C_NUM_SLAVE_SLOTS*3-1:0] S_AXI_ARPROT, // input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_ARREGION, input wire [C_NUM_SLAVE_SLOTS*4-1:0] S_AXI_ARQOS, input wire [C_NUM_SLAVE_SLOTS*C_AXI_ARUSER_WIDTH-1:0] S_AXI_ARUSER, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARVALID, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_ARREADY, // Slave Interface Read Data Ports output wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] S_AXI_RID, output wire [C_NUM_SLAVE_SLOTS*C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA, output wire [C_NUM_SLAVE_SLOTS*2-1:0] S_AXI_RRESP, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RLAST, output wire [C_NUM_SLAVE_SLOTS*C_AXI_RUSER_WIDTH-1:0] S_AXI_RUSER, output wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RVALID, input wire [C_NUM_SLAVE_SLOTS-1:0] S_AXI_RREADY, // Master Interface Write Address Port output wire [C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH-1:0] M_AXI_AWID, output wire [C_NUM_MASTER_SLOTS*C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR, output wire [C_NUM_MASTER_SLOTS*8-1:0] M_AXI_AWLEN, output wire [C_NUM_MASTER_SLOTS*3-1:0] M_AXI_AWSIZE, output wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_AWBURST, output wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_AWLOCK, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_AWCACHE, output wire [C_NUM_MASTER_SLOTS*3-1:0] M_AXI_AWPROT, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_AWREGION, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_AWQOS, output wire [C_NUM_MASTER_SLOTS*C_AXI_AWUSER_WIDTH-1:0] M_AXI_AWUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_AWREADY, // Master Interface Write Data Ports output wire [C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH-1:0] M_AXI_WID, output wire [C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH-1:0] M_AXI_WDATA, output wire [C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WLAST, output wire [C_NUM_MASTER_SLOTS*C_AXI_WUSER_WIDTH-1:0] M_AXI_WUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_WREADY, // Master Interface Write Response Ports input wire [C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH-1:0] M_AXI_BID, input wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_BRESP, input wire [C_NUM_MASTER_SLOTS*C_AXI_BUSER_WIDTH-1:0] M_AXI_BUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_BREADY, // Master Interface Read Address Port output wire [C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH-1:0] M_AXI_ARID, output wire [C_NUM_MASTER_SLOTS*C_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR, output wire [C_NUM_MASTER_SLOTS*8-1:0] M_AXI_ARLEN, output wire [C_NUM_MASTER_SLOTS*3-1:0] M_AXI_ARSIZE, output wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_ARBURST, output wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_ARLOCK, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_ARCACHE, output wire [C_NUM_MASTER_SLOTS*3-1:0] M_AXI_ARPROT, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_ARREGION, output wire [C_NUM_MASTER_SLOTS*4-1:0] M_AXI_ARQOS, output wire [C_NUM_MASTER_SLOTS*C_AXI_ARUSER_WIDTH-1:0] M_AXI_ARUSER, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARVALID, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_ARREADY, // Master Interface Read Data Ports input wire [C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH-1:0] M_AXI_RID, input wire [C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA, input wire [C_NUM_MASTER_SLOTS*2-1:0] M_AXI_RRESP, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RLAST, input wire [C_NUM_MASTER_SLOTS*C_AXI_RUSER_WIDTH-1:0] M_AXI_RUSER, input wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RVALID, output wire [C_NUM_MASTER_SLOTS-1:0] M_AXI_RREADY ); localparam integer P_AXI4 = 0; localparam integer P_AXI3 = 1; localparam integer P_AXILITE = 2; localparam integer P_WRITE = 0; localparam integer P_READ = 1; localparam integer P_NUM_MASTER_SLOTS_LOG = f_ceil_log2(C_NUM_MASTER_SLOTS); localparam integer P_NUM_SLAVE_SLOTS_LOG = f_ceil_log2((C_NUM_SLAVE_SLOTS>1) ? C_NUM_SLAVE_SLOTS : 2); localparam integer P_AXI_WID_WIDTH = (C_AXI_PROTOCOL == P_AXI3) ? C_AXI_ID_WIDTH : 1; localparam integer P_ST_AWMESG_WIDTH = 2+4+4 + C_AXI_AWUSER_WIDTH; localparam integer P_AA_AWMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_AWMESG_WIDTH; localparam integer P_ST_ARMESG_WIDTH = 2+4+4 + C_AXI_ARUSER_WIDTH; localparam integer P_AA_ARMESG_WIDTH = C_AXI_ID_WIDTH + C_AXI_ADDR_WIDTH + 8+3+2+3+4 + P_ST_ARMESG_WIDTH; localparam integer P_ST_BMESG_WIDTH = 2 + C_AXI_BUSER_WIDTH; localparam integer P_ST_RMESG_WIDTH = 2 + C_AXI_RUSER_WIDTH + C_AXI_DATA_WIDTH; localparam integer P_WR_WMESG_WIDTH = C_AXI_DATA_WIDTH + C_AXI_DATA_WIDTH/8 + C_AXI_WUSER_WIDTH + P_AXI_WID_WIDTH; localparam [31:0] P_BYPASS = 32'h00000000; localparam [31:0] P_FWD_REV = 32'h00000001; localparam [31:0] P_SIMPLE = 32'h00000007; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_READ = {1'b1, C_M_AXI_SUPPORTS_READ[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)-1:0] P_M_AXI_SUPPORTS_WRITE = {1'b1, C_M_AXI_SUPPORTS_WRITE[0+:C_NUM_MASTER_SLOTS]}; localparam [(C_NUM_MASTER_SLOTS+1)*32-1:0] P_M_AXI_WRITE_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_WRITE_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS*32]}; localparam [(C_NUM_MASTER_SLOTS+1)*32-1:0] P_M_AXI_READ_CONNECTIVITY = {{32{1'b1}}, C_M_AXI_READ_CONNECTIVITY[0+:C_NUM_MASTER_SLOTS*32]}; localparam [C_NUM_SLAVE_SLOTS*32-1:0] P_S_AXI_WRITE_CONNECTIVITY = f_si_write_connectivity(0); localparam [C_NUM_SLAVE_SLOTS*32-1:0] P_S_AXI_READ_CONNECTIVITY = f_si_read_connectivity(0); localparam [(C_NUM_MASTER_SLOTS+1)*32-1:0] P_M_AXI_READ_ISSUING = {32'h00000001, C_M_AXI_READ_ISSUING[0+:C_NUM_MASTER_SLOTS*32]}; localparam [(C_NUM_MASTER_SLOTS+1)*32-1:0] P_M_AXI_WRITE_ISSUING = {32'h00000001, C_M_AXI_WRITE_ISSUING[0+:C_NUM_MASTER_SLOTS*32]}; localparam P_DECERR = 2'b11; //--------------------------------------------------------------------------- // Functions //--------------------------------------------------------------------------- // Ceiling of log2(x) function integer f_ceil_log2 ( input integer x ); integer acc; begin acc=0; while ((2**acc) < x) acc = acc + 1; f_ceil_log2 = acc; end endfunction // Isolate thread bits of input S_ID and add to BASE_ID (RNG00) to form MI-side ID value // only for end-point SI-slots function [C_AXI_ID_WIDTH-1:0] f_extend_ID ( input [C_AXI_ID_WIDTH-1:0] s_id, input integer slot ); begin f_extend_ID = C_S_AXI_BASE_ID[slot*64+:C_AXI_ID_WIDTH] | (s_id & (C_S_AXI_BASE_ID[slot*64+:C_AXI_ID_WIDTH] ^ C_S_AXI_HIGH_ID[slot*64+:C_AXI_ID_WIDTH])); end endfunction // Write connectivity array transposed function [C_NUM_SLAVE_SLOTS*32-1:0] f_si_write_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS*32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS*32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot*32+mi_slot] = C_M_AXI_WRITE_CONNECTIVITY[mi_slot*32+si_slot]; end end f_si_write_connectivity = result; end endfunction // Read connectivity array transposed function [C_NUM_SLAVE_SLOTS*32-1:0] f_si_read_connectivity ( input integer null_arg ); integer si_slot; integer mi_slot; reg [C_NUM_SLAVE_SLOTS*32-1:0] result; begin result = {C_NUM_SLAVE_SLOTS*32{1'b1}}; for (si_slot=0; si_slot<C_NUM_SLAVE_SLOTS; si_slot=si_slot+1) begin for (mi_slot=0; mi_slot<C_NUM_MASTER_SLOTS; mi_slot=mi_slot+1) begin result[si_slot*32+mi_slot] = C_M_AXI_READ_CONNECTIVITY[mi_slot*32+si_slot]; end end f_si_read_connectivity = result; end endfunction genvar gen_si_slot; genvar gen_mi_slot; wire [C_NUM_SLAVE_SLOTS*P_ST_AWMESG_WIDTH-1:0] si_st_awmesg ; wire [C_NUM_SLAVE_SLOTS*P_ST_AWMESG_WIDTH-1:0] st_tmp_awmesg ; wire [C_NUM_SLAVE_SLOTS*P_AA_AWMESG_WIDTH-1:0] tmp_aa_awmesg ; wire [P_AA_AWMESG_WIDTH-1:0] aa_mi_awmesg ; wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] st_aa_awid ; wire [C_NUM_SLAVE_SLOTS*C_AXI_ADDR_WIDTH-1:0] st_aa_awaddr ; wire [C_NUM_SLAVE_SLOTS*8-1:0] st_aa_awlen ; wire [C_NUM_SLAVE_SLOTS*3-1:0] st_aa_awsize ; wire [C_NUM_SLAVE_SLOTS*2-1:0] st_aa_awlock ; wire [C_NUM_SLAVE_SLOTS*3-1:0] st_aa_awprot ; wire [C_NUM_SLAVE_SLOTS*4-1:0] st_aa_awregion ; wire [C_NUM_SLAVE_SLOTS*8-1:0] st_aa_awerror ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS*(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_awtarget_enc ; wire [P_NUM_SLAVE_SLOTS_LOG*1-1:0] aa_wm_awgrant_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_awtarget_hot ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_aa_awvalid_qual ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_ss_awvalid ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_ss_awready ; wire [C_NUM_SLAVE_SLOTS*1-1:0] ss_wr_awvalid ; wire [C_NUM_SLAVE_SLOTS*1-1:0] ss_wr_awready ; wire [C_NUM_SLAVE_SLOTS*1-1:0] ss_aa_awvalid ; wire [C_NUM_SLAVE_SLOTS*1-1:0] ss_aa_awready ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] sa_wm_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] sa_wm_awready ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_awvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_awready ; wire aa_sa_awvalid ; wire aa_sa_awready ; wire aa_mi_arready ; wire mi_awvalid_en ; wire sa_wm_awvalid_en ; wire sa_wm_awready_mux ; wire [C_NUM_SLAVE_SLOTS*P_ST_ARMESG_WIDTH-1:0] si_st_armesg ; wire [C_NUM_SLAVE_SLOTS*P_ST_ARMESG_WIDTH-1:0] st_tmp_armesg ; wire [C_NUM_SLAVE_SLOTS*P_AA_ARMESG_WIDTH-1:0] tmp_aa_armesg ; wire [P_AA_ARMESG_WIDTH-1:0] aa_mi_armesg ; wire [C_NUM_SLAVE_SLOTS*C_AXI_ID_WIDTH-1:0] st_aa_arid ; wire [C_NUM_SLAVE_SLOTS*C_AXI_ADDR_WIDTH-1:0] st_aa_araddr ; wire [C_NUM_SLAVE_SLOTS*8-1:0] st_aa_arlen ; wire [C_NUM_SLAVE_SLOTS*3-1:0] st_aa_arsize ; wire [C_NUM_SLAVE_SLOTS*2-1:0] st_aa_arlock ; wire [C_NUM_SLAVE_SLOTS*3-1:0] st_aa_arprot ; wire [C_NUM_SLAVE_SLOTS*4-1:0] st_aa_arregion ; wire [C_NUM_SLAVE_SLOTS*8-1:0] st_aa_arerror ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_aa_artarget_hot ; wire [C_NUM_SLAVE_SLOTS*(P_NUM_MASTER_SLOTS_LOG+1)-1:0] st_aa_artarget_enc ; wire [(C_NUM_MASTER_SLOTS+1)-1:0] aa_mi_artarget_hot ; wire [P_NUM_SLAVE_SLOTS_LOG*1-1:0] aa_mi_argrant_enc ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_aa_arvalid_qual ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_aa_arvalid ; wire [C_NUM_SLAVE_SLOTS*1-1:0] st_aa_arready ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_arvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_arready ; wire aa_mi_arvalid ; wire mi_awready_mux ; wire [C_NUM_SLAVE_SLOTS*P_ST_BMESG_WIDTH-1:0] st_si_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)*P_ST_BMESG_WIDTH-1:0] st_mr_bmesg ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] st_mr_bid ; wire [(C_NUM_MASTER_SLOTS+1)*2-1:0] st_mr_bresp ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_BUSER_WIDTH-1:0] st_mr_buser ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] st_mr_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] st_mr_bready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)*C_NUM_SLAVE_SLOTS-1:0] tmp_mr_bid_target ; wire [(C_NUM_MASTER_SLOTS+1)*P_NUM_SLAVE_SLOTS_LOG-1:0] debug_bid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] bid_match ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] mi_bid ; wire [(C_NUM_MASTER_SLOTS+1)*2-1:0] mi_bresp ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_BUSER_WIDTH-1:0] mi_buser ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_bvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_bready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] bready_carry ; wire [C_NUM_SLAVE_SLOTS*P_ST_RMESG_WIDTH-1:0] st_si_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)*P_ST_RMESG_WIDTH-1:0] st_mr_rmesg ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] st_mr_rid ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH-1:0] st_mr_rdata ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_RUSER_WIDTH-1:0] st_mr_ruser ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] st_mr_rlast ; wire [(C_NUM_MASTER_SLOTS+1)*2-1:0] st_mr_rresp ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] st_mr_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] st_mr_rready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] st_tmp_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)*C_NUM_SLAVE_SLOTS-1:0] tmp_mr_rid_target ; wire [(C_NUM_MASTER_SLOTS+1)*P_NUM_SLAVE_SLOTS_LOG-1:0] debug_rid_target_i ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] rid_match ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] mi_rid ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH-1:0] mi_rdata ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_RUSER_WIDTH-1:0] mi_ruser ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_rlast ; wire [(C_NUM_MASTER_SLOTS+1)*2-1:0] mi_rresp ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_rvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_rready ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] rready_carry ; wire [C_NUM_SLAVE_SLOTS*P_WR_WMESG_WIDTH-1:0] si_wr_wmesg ; wire [C_NUM_SLAVE_SLOTS*P_WR_WMESG_WIDTH-1:0] wr_wm_wmesg ; wire [C_NUM_SLAVE_SLOTS*1-1:0] wr_wm_wlast ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wvalid ; wire [C_NUM_SLAVE_SLOTS*(C_NUM_MASTER_SLOTS+1)-1:0] wr_tmp_wready ; wire [(C_NUM_MASTER_SLOTS+1)*C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)*C_NUM_SLAVE_SLOTS-1:0] tmp_wm_wready ; wire [(C_NUM_MASTER_SLOTS+1)*P_WR_WMESG_WIDTH-1:0] wm_mr_wmesg ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH-1:0] wm_mr_wdata ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH/8-1:0] wm_mr_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] wm_mr_wid ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_WUSER_WIDTH-1:0] wm_mr_wuser ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] wm_mr_wlast ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] wm_mr_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] wm_mr_wready ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH-1:0] mi_wdata ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_DATA_WIDTH/8-1:0] mi_wstrb ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_WUSER_WIDTH-1:0] mi_wuser ; wire [(C_NUM_MASTER_SLOTS+1)*C_AXI_ID_WIDTH-1:0] mi_wid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_wlast ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_wvalid ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_wready ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] w_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] w_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] r_cmd_push ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] r_cmd_pop ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_awmaxissuing ; wire [(C_NUM_MASTER_SLOTS+1)*1-1:0] mi_armaxissuing ; reg [(C_NUM_MASTER_SLOTS+1)*8-1:0] w_issuing_cnt ; reg [(C_NUM_MASTER_SLOTS+1)*8-1:0] r_issuing_cnt ; reg [8-1:0] debug_aw_trans_seq_i ; reg [8-1:0] debug_ar_trans_seq_i ; wire [(C_NUM_MASTER_SLOTS+1)*8-1:0] debug_w_trans_seq_i ; reg [(C_NUM_MASTER_SLOTS+1)*8-1:0] debug_w_beat_cnt_i ; reg aresetn_d = 1'b0; // Reset delay register always @(posedge ACLK) begin if (~ARESETN) begin aresetn_d <= 1'b0; end else begin aresetn_d <= ARESETN; end end wire reset; assign reset = ~aresetn_d; generate for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_slave_slots if (C_S_AXI_SUPPORTS_READ[gen_si_slot]) begin : gen_si_read axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (read channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_READ), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_READ_ACCEPTANCE[gen_si_slot*32+:32]), .C_ACCEPTANCE_LOG (C_R_ACCEPT_WIDTH[gen_si_slot*32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot*32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_ARMESG_WIDTH), .C_RMESG_WIDTH (P_ST_RMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot*64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot*64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot*32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_READ_CONNECTIVITY[gen_si_slot*32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_ar ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_ARID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_ARADDR[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_ARLEN[gen_si_slot*8+:8]), .S_ASIZE (S_AXI_ARSIZE[gen_si_slot*3+:3]), .S_ABURST (S_AXI_ARBURST[gen_si_slot*2+:2]), .S_ALOCK (S_AXI_ARLOCK[gen_si_slot*2+:2]), .S_APROT (S_AXI_ARPROT[gen_si_slot*3+:3]), // .S_AREGION (S_AXI_ARREGION[gen_si_slot*4+:4]), .S_AMESG (si_st_armesg[gen_si_slot*P_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .S_AVALID (S_AXI_ARVALID[gen_si_slot]), .S_AREADY (S_AXI_ARREADY[gen_si_slot]), .M_AID (st_aa_arid[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_araddr[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_arlen[gen_si_slot*8+:8]), .M_ASIZE (st_aa_arsize[gen_si_slot*3+:3]), .M_ALOCK (st_aa_arlock[gen_si_slot*2+:2]), .M_APROT (st_aa_arprot[gen_si_slot*3+:3]), .M_AREGION (st_aa_arregion[gen_si_slot*4+:4]), .M_AMESG (st_tmp_armesg[gen_si_slot*P_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH]), .M_ATARGET_HOT (st_aa_artarget_hot[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_artarget_enc[gen_si_slot*(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_arerror[gen_si_slot*8+:8]), .M_AVALID_QUAL (st_aa_arvalid_qual[gen_si_slot]), .M_AVALID (st_aa_arvalid[gen_si_slot]), .M_AREADY (st_aa_arready[gen_si_slot]), .S_RID (S_AXI_RID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_rmesg[gen_si_slot*P_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH]), .S_RLAST (S_AXI_RLAST[gen_si_slot]), .S_RVALID (S_AXI_RVALID[gen_si_slot]), .S_RREADY (S_AXI_RREADY[gen_si_slot]), .M_RID (st_mr_rid), .M_RLAST (st_mr_rlast), .M_RMESG (st_mr_rmesg), .M_RVALID (st_mr_rvalid), .M_RREADY (st_tmp_rready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_rid_target[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_ar_trans_seq_i : 8'h0) ); assign si_st_armesg[gen_si_slot*P_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH] = { S_AXI_ARUSER[gen_si_slot*C_AXI_ARUSER_WIDTH+:C_AXI_ARUSER_WIDTH], S_AXI_ARQOS[gen_si_slot*4+:4], S_AXI_ARCACHE[gen_si_slot*4+:4], S_AXI_ARBURST[gen_si_slot*2+:2] }; assign tmp_aa_armesg[gen_si_slot*P_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = { st_tmp_armesg[gen_si_slot*P_ST_ARMESG_WIDTH+:P_ST_ARMESG_WIDTH], st_aa_arregion[gen_si_slot*4+:4], st_aa_arprot[gen_si_slot*3+:3], st_aa_arlock[gen_si_slot*2+:2], st_aa_arsize[gen_si_slot*3+:3], st_aa_arlen[gen_si_slot*8+:8], st_aa_araddr[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_arid[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_RRESP[gen_si_slot*2+:2] = st_si_rmesg[gen_si_slot*P_ST_RMESG_WIDTH+:2]; assign S_AXI_RUSER[gen_si_slot*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = st_si_rmesg[gen_si_slot*P_ST_RMESG_WIDTH+2 +: C_AXI_RUSER_WIDTH]; assign S_AXI_RDATA[gen_si_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = st_si_rmesg[gen_si_slot*P_ST_RMESG_WIDTH+2+C_AXI_RUSER_WIDTH +: C_AXI_DATA_WIDTH]; end else begin : gen_no_si_read assign S_AXI_ARREADY[gen_si_slot] = 1'b0; assign st_aa_arvalid[gen_si_slot] = 1'b0; assign st_aa_arvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_armesg[gen_si_slot*P_AA_ARMESG_WIDTH+:P_AA_ARMESG_WIDTH] = 0; assign S_AXI_RID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_RRESP[gen_si_slot*2+:2] = 0; assign S_AXI_RUSER[gen_si_slot*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign S_AXI_RDATA[gen_si_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign S_AXI_RVALID[gen_si_slot] = 1'b0; assign S_AXI_RLAST[gen_si_slot] = 1'b0; assign st_tmp_rready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_artarget_hot[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_read if (C_S_AXI_SUPPORTS_WRITE[gen_si_slot]) begin : gen_si_write axi_crossbar_v2_1_si_transactor # // "ST": SI Transactor (write channel) ( .C_FAMILY (C_FAMILY), .C_SI (gen_si_slot), .C_DIR (P_WRITE), .C_NUM_ADDR_RANGES (C_NUM_ADDR_RANGES), .C_NUM_M (C_NUM_MASTER_SLOTS), .C_NUM_M_LOG (P_NUM_MASTER_SLOTS_LOG), .C_ACCEPTANCE (C_S_AXI_WRITE_ACCEPTANCE[gen_si_slot*32+:32]), .C_ACCEPTANCE_LOG (C_W_ACCEPT_WIDTH[gen_si_slot*32+:32]), .C_ID_WIDTH (C_AXI_ID_WIDTH), .C_THREAD_ID_WIDTH (C_S_AXI_THREAD_ID_WIDTH[gen_si_slot*32+:32]), .C_ADDR_WIDTH (C_AXI_ADDR_WIDTH), .C_AMESG_WIDTH (P_ST_AWMESG_WIDTH), .C_RMESG_WIDTH (P_ST_BMESG_WIDTH), .C_BASE_ID (C_S_AXI_BASE_ID[gen_si_slot*64+:C_AXI_ID_WIDTH]), .C_HIGH_ID (C_S_AXI_HIGH_ID[gen_si_slot*64+:C_AXI_ID_WIDTH]), .C_SINGLE_THREAD (C_S_AXI_SINGLE_THREAD[gen_si_slot*32+:32]), .C_BASE_ADDR (C_M_AXI_BASE_ADDR), .C_HIGH_ADDR (C_M_AXI_HIGH_ADDR), .C_TARGET_QUAL (P_S_AXI_WRITE_CONNECTIVITY[gen_si_slot*32+:C_NUM_MASTER_SLOTS]), .C_M_AXI_SECURE (C_M_AXI_SECURE), .C_RANGE_CHECK (C_RANGE_CHECK), .C_ADDR_DECODE (C_ADDR_DECODE), .C_ERR_MODE (C_M_AXI_ERR_MODE), .C_DEBUG (C_DEBUG) ) si_transactor_aw ( .ACLK (ACLK), .ARESET (reset), .S_AID (f_extend_ID(S_AXI_AWID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot)), .S_AADDR (S_AXI_AWADDR[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .S_ALEN (S_AXI_AWLEN[gen_si_slot*8+:8]), .S_ASIZE (S_AXI_AWSIZE[gen_si_slot*3+:3]), .S_ABURST (S_AXI_AWBURST[gen_si_slot*2+:2]), .S_ALOCK (S_AXI_AWLOCK[gen_si_slot*2+:2]), .S_APROT (S_AXI_AWPROT[gen_si_slot*3+:3]), // .S_AREGION (S_AXI_AWREGION[gen_si_slot*4+:4]), .S_AMESG (si_st_awmesg[gen_si_slot*P_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .S_AVALID (S_AXI_AWVALID[gen_si_slot]), .S_AREADY (S_AXI_AWREADY[gen_si_slot]), .M_AID (st_aa_awid[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .M_AADDR (st_aa_awaddr[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH]), .M_ALEN (st_aa_awlen[gen_si_slot*8+:8]), .M_ASIZE (st_aa_awsize[gen_si_slot*3+:3]), .M_ALOCK (st_aa_awlock[gen_si_slot*2+:2]), .M_APROT (st_aa_awprot[gen_si_slot*3+:3]), .M_AREGION (st_aa_awregion[gen_si_slot*4+:4]), .M_AMESG (st_tmp_awmesg[gen_si_slot*P_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH]), .M_ATARGET_HOT (st_aa_awtarget_hot[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_ATARGET_ENC (st_aa_awtarget_enc[gen_si_slot*(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), .M_AERROR (st_aa_awerror[gen_si_slot*8+:8]), .M_AVALID_QUAL (st_aa_awvalid_qual[gen_si_slot]), .M_AVALID (st_ss_awvalid[gen_si_slot]), .M_AREADY (st_ss_awready[gen_si_slot]), .S_RID (S_AXI_BID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_RMESG (st_si_bmesg[gen_si_slot*P_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH]), .S_RLAST (), .S_RVALID (S_AXI_BVALID[gen_si_slot]), .S_RREADY (S_AXI_BREADY[gen_si_slot]), .M_RID (st_mr_bid), .M_RLAST ({(C_NUM_MASTER_SLOTS+1){1'b1}}), .M_RMESG (st_mr_bmesg), .M_RVALID (st_mr_bvalid), .M_RREADY (st_tmp_bready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_RTARGET (st_tmp_bid_target[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .DEBUG_A_TRANS_SEQ (C_DEBUG ? debug_aw_trans_seq_i : 8'h0) ); // Note: Concatenation of mesg signals is from MSB to LSB; assignments that chop mesg signals appear in opposite order. assign si_st_awmesg[gen_si_slot*P_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH] = { S_AXI_AWUSER[gen_si_slot*C_AXI_AWUSER_WIDTH+:C_AXI_AWUSER_WIDTH], S_AXI_AWQOS[gen_si_slot*4+:4], S_AXI_AWCACHE[gen_si_slot*4+:4], S_AXI_AWBURST[gen_si_slot*2+:2] }; assign tmp_aa_awmesg[gen_si_slot*P_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = { st_tmp_awmesg[gen_si_slot*P_ST_AWMESG_WIDTH+:P_ST_AWMESG_WIDTH], st_aa_awregion[gen_si_slot*4+:4], st_aa_awprot[gen_si_slot*3+:3], st_aa_awlock[gen_si_slot*2+:2], st_aa_awsize[gen_si_slot*3+:3], st_aa_awlen[gen_si_slot*8+:8], st_aa_awaddr[gen_si_slot*C_AXI_ADDR_WIDTH+:C_AXI_ADDR_WIDTH], st_aa_awid[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] }; assign S_AXI_BRESP[gen_si_slot*2+:2] = st_si_bmesg[gen_si_slot*P_ST_BMESG_WIDTH+:2]; assign S_AXI_BUSER[gen_si_slot*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = st_si_bmesg[gen_si_slot*P_ST_BMESG_WIDTH+2 +: C_AXI_BUSER_WIDTH]; // AW SI-transactor transfer completes upon completion of both W-router address acceptance (command push) and AW arbitration axi_crossbar_v2_1_splitter # // "SS": Splitter from SI-Transactor (write channel) ( .C_NUM_M (2) ) splitter_aw_si ( .ACLK (ACLK), .ARESET (reset), .S_VALID (st_ss_awvalid[gen_si_slot]), .S_READY (st_ss_awready[gen_si_slot]), .M_VALID ({ss_wr_awvalid[gen_si_slot], ss_aa_awvalid[gen_si_slot]}), .M_READY ({ss_wr_awready[gen_si_slot], ss_aa_awready[gen_si_slot]}) ); axi_crossbar_v2_1_wdata_router # // "WR": Write data Router ( .C_FAMILY (C_FAMILY), .C_NUM_MASTER_SLOTS (C_NUM_MASTER_SLOTS+1), .C_SELECT_WIDTH (P_NUM_MASTER_SLOTS_LOG+1), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ACCEPT_WIDTH[gen_si_slot*32+:6]) ) wdata_router_w ( .ACLK (ACLK), .ARESET (reset), // Write transfer input from the current SI-slot .S_WMESG (si_wr_wmesg[gen_si_slot*P_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .S_WLAST (S_AXI_WLAST[gen_si_slot]), .S_WVALID (S_AXI_WVALID[gen_si_slot]), .S_WREADY (S_AXI_WREADY[gen_si_slot]), // Vector of write transfer outputs to each MI-slot's W-mux .M_WMESG (wr_wm_wmesg[gen_si_slot*(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH]), .M_WLAST (wr_wm_wlast[gen_si_slot]), .M_WVALID (wr_tmp_wvalid[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), .M_WREADY (wr_tmp_wready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)]), // AW command push from local SI-slot .S_ASELECT (st_aa_awtarget_enc[gen_si_slot*(P_NUM_MASTER_SLOTS_LOG+1)+:(P_NUM_MASTER_SLOTS_LOG+1)]), // Target MI-slot .S_AVALID (ss_wr_awvalid[gen_si_slot]), .S_AREADY (ss_wr_awready[gen_si_slot]) ); assign si_wr_wmesg[gen_si_slot*P_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH] = { ((C_AXI_PROTOCOL == P_AXI3) ? f_extend_ID(S_AXI_WID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH], gen_si_slot) : 1'b0), S_AXI_WUSER[gen_si_slot*C_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH], S_AXI_WSTRB[gen_si_slot*C_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8], S_AXI_WDATA[gen_si_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] }; end else begin : gen_no_si_write assign S_AXI_AWREADY[gen_si_slot] = 1'b0; assign ss_aa_awvalid[gen_si_slot] = 1'b0; assign st_aa_awvalid_qual[gen_si_slot] = 1'b1; assign tmp_aa_awmesg[gen_si_slot*P_AA_AWMESG_WIDTH+:P_AA_AWMESG_WIDTH] = 0; assign S_AXI_BID[gen_si_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign S_AXI_BRESP[gen_si_slot*2+:2] = 0; assign S_AXI_BUSER[gen_si_slot*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign S_AXI_BVALID[gen_si_slot] = 1'b0; assign st_tmp_bready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign S_AXI_WREADY[gen_si_slot] = 1'b0; assign wr_wm_wmesg[gen_si_slot*(P_WR_WMESG_WIDTH)+:P_WR_WMESG_WIDTH] = 0; assign wr_wm_wlast[gen_si_slot] = 1'b0; assign wr_tmp_wvalid[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; assign st_aa_awtarget_hot[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+:(C_NUM_MASTER_SLOTS+1)] = 0; end // gen_si_write end // gen_slave_slots for (gen_mi_slot=0; gen_mi_slot<C_NUM_MASTER_SLOTS+1; gen_mi_slot=gen_mi_slot+1) begin : gen_master_slots if (P_M_AXI_SUPPORTS_READ[gen_mi_slot]) begin : gen_mi_read if (C_NUM_SLAVE_SLOTS>1) begin : gen_rid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_READ_CONNECTIVITY[gen_mi_slot*32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) rid_decoder_inst ( .ADDR (st_mr_rid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_rid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_rid_target_i[gen_mi_slot*P_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (rid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_rid_decoder assign tmp_mr_rid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign rid_match[gen_mi_slot] = 1'b1; end assign st_mr_rmesg[gen_mi_slot*P_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = { st_mr_rdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH], st_mr_ruser[gen_mi_slot*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH], st_mr_rresp[gen_mi_slot*2+:2] }; end else begin : gen_no_mi_read assign tmp_mr_rid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign rid_match[gen_mi_slot] = 1'b0; assign st_mr_rmesg[gen_mi_slot*P_ST_RMESG_WIDTH+:P_ST_RMESG_WIDTH] = 0; end // gen_mi_read if (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]) begin : gen_mi_write if (C_NUM_SLAVE_SLOTS>1) begin : gen_bid_decoder axi_crossbar_v2_1_addr_decoder # ( .C_FAMILY (C_FAMILY), .C_NUM_TARGETS (C_NUM_SLAVE_SLOTS), .C_NUM_TARGETS_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_NUM_RANGES (1), .C_ADDR_WIDTH (C_AXI_ID_WIDTH), .C_TARGET_ENC (C_DEBUG), .C_TARGET_HOT (1), .C_REGION_ENC (0), .C_BASE_ADDR (C_S_AXI_BASE_ID), .C_HIGH_ADDR (C_S_AXI_HIGH_ID), .C_TARGET_QUAL (P_M_AXI_WRITE_CONNECTIVITY[gen_mi_slot*32+:C_NUM_SLAVE_SLOTS]), .C_RESOLUTION (0) ) bid_decoder_inst ( .ADDR (st_mr_bid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .TARGET_HOT (tmp_mr_bid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .TARGET_ENC (debug_bid_target_i[gen_mi_slot*P_NUM_SLAVE_SLOTS_LOG+:P_NUM_SLAVE_SLOTS_LOG]), .MATCH (bid_match[gen_mi_slot]), .REGION () ); end else begin : gen_no_bid_decoder assign tmp_mr_bid_target[gen_mi_slot] = 1'b1; // All response transfers route to solo SI-slot. assign bid_match[gen_mi_slot] = 1'b1; end axi_crossbar_v2_1_wdata_mux # // "WM": Write data Mux, per MI-slot (incl error-handler) ( .C_FAMILY (C_FAMILY), .C_NUM_SLAVE_SLOTS (C_NUM_SLAVE_SLOTS), .C_SELECT_WIDTH (P_NUM_SLAVE_SLOTS_LOG), .C_WMESG_WIDTH (P_WR_WMESG_WIDTH), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]) ) wdata_mux_w ( .ACLK (ACLK), .ARESET (reset), // Vector of write transfer inputs from each SI-slot's W-router .S_WMESG (wr_wm_wmesg), .S_WLAST (wr_wm_wlast), .S_WVALID (tmp_wm_wvalid[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), .S_WREADY (tmp_wm_wready[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS]), // Write transfer output to the current MI-slot .M_WMESG (wm_mr_wmesg[gen_mi_slot*P_WR_WMESG_WIDTH+:P_WR_WMESG_WIDTH]), .M_WLAST (wm_mr_wlast[gen_mi_slot]), .M_WVALID (wm_mr_wvalid[gen_mi_slot]), .M_WREADY (wm_mr_wready[gen_mi_slot]), // AW command push from AW arbiter output .S_ASELECT (aa_wm_awgrant_enc), // SI-slot selected by arbiter .S_AVALID (sa_wm_awvalid[gen_mi_slot]), .S_AREADY (sa_wm_awready[gen_mi_slot]) ); if (C_DEBUG) begin : gen_debug_w // DEBUG WRITE BEAT COUNTER always @(posedge ACLK) begin if (reset) begin debug_w_beat_cnt_i[gen_mi_slot*8+:8] <= 0; end else begin if (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot]) begin if (mi_wlast[gen_mi_slot]) begin debug_w_beat_cnt_i[gen_mi_slot*8+:8] <= 0; end else begin debug_w_beat_cnt_i[gen_mi_slot*8+:8] <= debug_w_beat_cnt_i[gen_mi_slot*8+:8] + 1; end end end end // clocked process // DEBUG W-CHANNEL TRANSACTION SEQUENCE QUEUE axi_data_fifo_v2_1_axic_srl_fifo # ( .C_FAMILY (C_FAMILY), .C_FIFO_WIDTH (8), .C_FIFO_DEPTH_LOG (C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]), .C_USE_FULL (0) ) debug_w_seq_fifo ( .ACLK (ACLK), .ARESET (reset), .S_MESG (debug_aw_trans_seq_i), .S_VALID (sa_wm_awvalid[gen_mi_slot]), .S_READY (), .M_MESG (debug_w_trans_seq_i[gen_mi_slot*8+:8]), .M_VALID (), .M_READY (mi_wvalid[gen_mi_slot] & mi_wready[gen_mi_slot] & mi_wlast[gen_mi_slot]) ); end // gen_debug_w assign wm_mr_wdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = wm_mr_wmesg[gen_mi_slot*P_WR_WMESG_WIDTH +: C_AXI_DATA_WIDTH]; assign wm_mr_wstrb[gen_mi_slot*C_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = wm_mr_wmesg[gen_mi_slot*P_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH +: C_AXI_DATA_WIDTH/8]; assign wm_mr_wuser[gen_mi_slot*C_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = wm_mr_wmesg[gen_mi_slot*P_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+C_AXI_DATA_WIDTH/8 +: C_AXI_WUSER_WIDTH]; assign wm_mr_wid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = wm_mr_wmesg[gen_mi_slot*P_WR_WMESG_WIDTH+C_AXI_DATA_WIDTH+(C_AXI_DATA_WIDTH/8)+C_AXI_WUSER_WIDTH +: P_AXI_WID_WIDTH]; assign st_mr_bmesg[gen_mi_slot*P_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = { st_mr_buser[gen_mi_slot*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH], st_mr_bresp[gen_mi_slot*2+:2] }; end else begin : gen_no_mi_write assign tmp_mr_bid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign bid_match[gen_mi_slot] = 1'b0; assign wm_mr_wvalid[gen_mi_slot] = 0; assign wm_mr_wlast[gen_mi_slot] = 0; assign wm_mr_wdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign wm_mr_wstrb[gen_mi_slot*C_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8] = 0; assign wm_mr_wuser[gen_mi_slot*C_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH] = 0; assign wm_mr_wid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign st_mr_bmesg[gen_mi_slot*P_ST_BMESG_WIDTH+:P_ST_BMESG_WIDTH] = 0; assign tmp_wm_wready[gen_mi_slot*C_NUM_SLAVE_SLOTS+:C_NUM_SLAVE_SLOTS] = 0; assign sa_wm_awready[gen_mi_slot] = 0; end // gen_mi_write for (gen_si_slot=0; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_trans_si // Transpose handshakes from W-router (SxM) to W-mux (MxS). assign tmp_wm_wvalid[gen_mi_slot*C_NUM_SLAVE_SLOTS+gen_si_slot] = wr_tmp_wvalid[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; assign wr_tmp_wready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_wm_wready[gen_mi_slot*C_NUM_SLAVE_SLOTS+gen_si_slot]; // Transpose response enables from ID decoders (MxS) to si_transactors (SxM). assign st_tmp_bid_target[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_bid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+gen_si_slot]; assign st_tmp_rid_target[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = tmp_mr_rid_target[gen_mi_slot*C_NUM_SLAVE_SLOTS+gen_si_slot]; end // gen_trans_si assign bready_carry[gen_mi_slot] = st_tmp_bready[gen_mi_slot]; assign rready_carry[gen_mi_slot] = st_tmp_rready[gen_mi_slot]; for (gen_si_slot=1; gen_si_slot<C_NUM_SLAVE_SLOTS; gen_si_slot=gen_si_slot+1) begin : gen_resp_carry_si assign bready_carry[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_BREADY if ... bready_carry[(gen_si_slot-1)*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] | // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_bready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates BREADY for that MI-slot. assign rready_carry[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] = // Generate M_RREADY if ... rready_carry[(gen_si_slot-1)*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot] | // For any SI-slot (OR carry-chain across all SI-slots), ... st_tmp_rready[gen_si_slot*(C_NUM_MASTER_SLOTS+1)+gen_mi_slot]; // The write SI transactor indicates RREADY for that MI-slot. end // gen_resp_carry_si assign w_cmd_push[gen_mi_slot] = mi_awvalid[gen_mi_slot] && mi_awready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_push[gen_mi_slot] = mi_arvalid[gen_mi_slot] && mi_arready[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; assign w_cmd_pop[gen_mi_slot] = st_mr_bvalid[gen_mi_slot] && st_mr_bready[gen_mi_slot] && P_M_AXI_SUPPORTS_WRITE[gen_mi_slot]; assign r_cmd_pop[gen_mi_slot] = st_mr_rvalid[gen_mi_slot] && st_mr_rready[gen_mi_slot] && st_mr_rlast[gen_mi_slot] && P_M_AXI_SUPPORTS_READ[gen_mi_slot]; // Disqualify arbitration of SI-slot if targeted MI-slot has reached its issuing limit. assign mi_awmaxissuing[gen_mi_slot] = (w_issuing_cnt[gen_mi_slot*8 +: (C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] == P_M_AXI_WRITE_ISSUING[gen_mi_slot*32 +: (C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)]) & ~w_cmd_pop[gen_mi_slot]; assign mi_armaxissuing[gen_mi_slot] = (r_issuing_cnt[gen_mi_slot*8 +: (C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] == P_M_AXI_READ_ISSUING[gen_mi_slot*32 +: (C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)]) & ~r_cmd_pop[gen_mi_slot]; always @(posedge ACLK) begin if (reset) begin w_issuing_cnt[gen_mi_slot*8+:8] <= 0; // Some high-order bits remain constant 0 r_issuing_cnt[gen_mi_slot*8+:8] <= 0; // Some high-order bits remain constant 0 end else begin if (w_cmd_push[gen_mi_slot] && ~w_cmd_pop[gen_mi_slot]) begin w_issuing_cnt[gen_mi_slot*8+:(C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] <= w_issuing_cnt[gen_mi_slot*8+:(C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] + 1; end else if (w_cmd_pop[gen_mi_slot] && ~w_cmd_push[gen_mi_slot] && (|w_issuing_cnt[gen_mi_slot*8+:(C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)])) begin w_issuing_cnt[gen_mi_slot*8+:(C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] <= w_issuing_cnt[gen_mi_slot*8+:(C_W_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] - 1; end if (r_cmd_push[gen_mi_slot] && ~r_cmd_pop[gen_mi_slot]) begin r_issuing_cnt[gen_mi_slot*8+:(C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] <= r_issuing_cnt[gen_mi_slot*8+:(C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] + 1; end else if (r_cmd_pop[gen_mi_slot] && ~r_cmd_push[gen_mi_slot] && (|r_issuing_cnt[gen_mi_slot*8+:(C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)])) begin r_issuing_cnt[gen_mi_slot*8+:(C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] <= r_issuing_cnt[gen_mi_slot*8+:(C_R_ISSUE_WIDTH[gen_mi_slot*32+:6]+1)] - 1; end end end // Clocked process // Reg-slice must break combinatorial path from M_BID and M_RID inputs to M_BREADY and M_RREADY outputs. // (See m_rready_i and m_resp_en combinatorial assignments in si_transactor.) // Reg-slice incurs +1 latency, but no bubble-cycles. axi_register_slice_v2_1_axi_register_slice # // "MR": MI-side R/B-channel Reg-slice, per MI-slot (pass-through if only 1 SI-slot configured) ( .C_FAMILY (C_FAMILY), .C_AXI_PROTOCOL ((C_AXI_PROTOCOL == P_AXI3) ? P_AXI3 : P_AXI4), .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_ADDR_WIDTH (1), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_SUPPORTS_USER_SIGNALS (C_AXI_SUPPORTS_USER_SIGNALS), .C_AXI_AWUSER_WIDTH (1), .C_AXI_ARUSER_WIDTH (1), .C_AXI_WUSER_WIDTH (C_AXI_WUSER_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_REG_CONFIG_AW (P_BYPASS), .C_REG_CONFIG_AR (P_BYPASS), .C_REG_CONFIG_W (P_BYPASS), .C_REG_CONFIG_R (P_M_AXI_SUPPORTS_READ[gen_mi_slot] ? P_FWD_REV : P_BYPASS), .C_REG_CONFIG_B (P_M_AXI_SUPPORTS_WRITE[gen_mi_slot] ? P_SIMPLE : P_BYPASS) ) reg_slice_mi ( .aresetn (ARESETN), .aclk (ACLK), .s_axi_awid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_awaddr ({1{1'b0}}), .s_axi_awlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_awsize ({3{1'b0}}), .s_axi_awburst ({2{1'b0}}), .s_axi_awlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_awcache ({4{1'b0}}), .s_axi_awprot ({3{1'b0}}), .s_axi_awregion ({4{1'b0}}), .s_axi_awqos ({4{1'b0}}), .s_axi_awuser ({1{1'b0}}), .s_axi_awvalid ({1{1'b0}}), .s_axi_awready (), .s_axi_wid (wm_mr_wid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .s_axi_wdata (wm_mr_wdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .s_axi_wstrb (wm_mr_wstrb[gen_mi_slot*C_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .s_axi_wlast (wm_mr_wlast[gen_mi_slot]), .s_axi_wuser (wm_mr_wuser[gen_mi_slot*C_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .s_axi_wvalid (wm_mr_wvalid[gen_mi_slot]), .s_axi_wready (wm_mr_wready[gen_mi_slot]), .s_axi_bid (st_mr_bid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_bresp (st_mr_bresp[gen_mi_slot*2+:2] ), .s_axi_buser (st_mr_buser[gen_mi_slot*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .s_axi_bvalid (st_mr_bvalid[gen_mi_slot*1+:1] ), .s_axi_bready (st_mr_bready[gen_mi_slot*1+:1] ), .s_axi_arid ({C_AXI_ID_WIDTH{1'b0}}), .s_axi_araddr ({1{1'b0}}), .s_axi_arlen ({((C_AXI_PROTOCOL == P_AXI3) ? 4 : 8){1'b0}}), .s_axi_arsize ({3{1'b0}}), .s_axi_arburst ({2{1'b0}}), .s_axi_arlock ({((C_AXI_PROTOCOL == P_AXI3) ? 2 : 1){1'b0}}), .s_axi_arcache ({4{1'b0}}), .s_axi_arprot ({3{1'b0}}), .s_axi_arregion ({4{1'b0}}), .s_axi_arqos ({4{1'b0}}), .s_axi_aruser ({1{1'b0}}), .s_axi_arvalid ({1{1'b0}}), .s_axi_arready (), .s_axi_rid (st_mr_rid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .s_axi_rdata (st_mr_rdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .s_axi_rresp (st_mr_rresp[gen_mi_slot*2+:2] ), .s_axi_rlast (st_mr_rlast[gen_mi_slot*1+:1] ), .s_axi_ruser (st_mr_ruser[gen_mi_slot*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .s_axi_rvalid (st_mr_rvalid[gen_mi_slot*1+:1] ), .s_axi_rready (st_mr_rready[gen_mi_slot*1+:1] ), .m_axi_awid (), .m_axi_awaddr (), .m_axi_awlen (), .m_axi_awsize (), .m_axi_awburst (), .m_axi_awlock (), .m_axi_awcache (), .m_axi_awprot (), .m_axi_awregion (), .m_axi_awqos (), .m_axi_awuser (), .m_axi_awvalid (), .m_axi_awready ({1{1'b0}}), .m_axi_wid (mi_wid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .m_axi_wdata (mi_wdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .m_axi_wstrb (mi_wstrb[gen_mi_slot*C_AXI_DATA_WIDTH/8+:C_AXI_DATA_WIDTH/8]), .m_axi_wlast (mi_wlast[gen_mi_slot]), .m_axi_wuser (mi_wuser[gen_mi_slot*C_AXI_WUSER_WIDTH+:C_AXI_WUSER_WIDTH]), .m_axi_wvalid (mi_wvalid[gen_mi_slot]), .m_axi_wready (mi_wready[gen_mi_slot]), .m_axi_bid (mi_bid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_bresp (mi_bresp[gen_mi_slot*2+:2] ), .m_axi_buser (mi_buser[gen_mi_slot*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] ), .m_axi_bvalid (mi_bvalid[gen_mi_slot*1+:1] ), .m_axi_bready (mi_bready[gen_mi_slot*1+:1] ), .m_axi_arid (), .m_axi_araddr (), .m_axi_arlen (), .m_axi_arsize (), .m_axi_arburst (), .m_axi_arlock (), .m_axi_arcache (), .m_axi_arprot (), .m_axi_arregion (), .m_axi_arqos (), .m_axi_aruser (), .m_axi_arvalid (), .m_axi_arready ({1{1'b0}}), .m_axi_rid (mi_rid[gen_mi_slot*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] ), .m_axi_rdata (mi_rdata[gen_mi_slot*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] ), .m_axi_rresp (mi_rresp[gen_mi_slot*2+:2] ), .m_axi_rlast (mi_rlast[gen_mi_slot*1+:1] ), .m_axi_ruser (mi_ruser[gen_mi_slot*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] ), .m_axi_rvalid (mi_rvalid[gen_mi_slot*1+:1] ), .m_axi_rready (mi_rready[gen_mi_slot*1+:1] ) ); end // gen_master_slots (Next gen_mi_slot) // Highest row of *ready_carry contains accumulated OR across all SI-slots, for each MI-slot. assign st_mr_bready = bready_carry[(C_NUM_SLAVE_SLOTS-1)*(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; assign st_mr_rready = rready_carry[(C_NUM_SLAVE_SLOTS-1)*(C_NUM_MASTER_SLOTS+1) +: C_NUM_MASTER_SLOTS+1]; // Assign MI-side B, R and W channel ports (exclude error handler signals). assign mi_bid[0+:C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH] = M_AXI_BID; assign mi_bvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_BVALID; assign mi_bresp[0+:C_NUM_MASTER_SLOTS*2] = M_AXI_BRESP; assign mi_buser[0+:C_NUM_MASTER_SLOTS*C_AXI_BUSER_WIDTH] = M_AXI_BUSER; assign M_AXI_BREADY = mi_bready[0+:C_NUM_MASTER_SLOTS]; assign mi_rid[0+:C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH] = M_AXI_RID; assign mi_rlast[0+:C_NUM_MASTER_SLOTS] = M_AXI_RLAST; assign mi_rvalid[0+:C_NUM_MASTER_SLOTS] = M_AXI_RVALID; assign mi_rresp[0+:C_NUM_MASTER_SLOTS*2] = M_AXI_RRESP; assign mi_ruser[0+:C_NUM_MASTER_SLOTS*C_AXI_RUSER_WIDTH] = M_AXI_RUSER; assign mi_rdata[0+:C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH] = M_AXI_RDATA; assign M_AXI_RREADY = mi_rready[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WLAST = mi_wlast[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WVALID = mi_wvalid[0+:C_NUM_MASTER_SLOTS]; assign M_AXI_WUSER = mi_wuser[0+:C_NUM_MASTER_SLOTS*C_AXI_WUSER_WIDTH]; assign M_AXI_WID = (C_AXI_PROTOCOL == P_AXI3) ? mi_wid[0+:C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH] : 0; assign M_AXI_WDATA = mi_wdata[0+:C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH]; assign M_AXI_WSTRB = mi_wstrb[0+:C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH/8]; assign mi_wready[0+:C_NUM_MASTER_SLOTS] = M_AXI_WREADY; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AW channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_AWMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_aw ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AW command request inputs .S_MESG (tmp_aa_awmesg), .S_TARGET_HOT (st_aa_awtarget_hot), .S_VALID (ss_aa_awvalid), .S_VALID_QUAL (st_aa_awvalid_qual), .S_READY (ss_aa_awready), // Granted AW command output .M_MESG (aa_mi_awmesg), .M_TARGET_HOT (aa_mi_awtarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_wm_awgrant_enc), // SI-slot index of granted command .M_VALID (aa_sa_awvalid), .M_READY (aa_sa_awready), .ISSUING_LIMIT (mi_awmaxissuing) ); // Broadcast AW transfer payload to all MI-slots assign M_AXI_AWID = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_AWADDR = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_AWLEN = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_AWSIZE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_AWLOCK = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_AWPROT = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_AWREGION = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_AWBURST = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_AWCACHE = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_AWQOS = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_AWUSER = {C_NUM_MASTER_SLOTS{aa_mi_awmesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_AWUSER_WIDTH]}}; axi_crossbar_v2_1_addr_arbiter # // "AA": Addr Arbiter (AR channel) ( .C_FAMILY (C_FAMILY), .C_NUM_M (C_NUM_MASTER_SLOTS+1), .C_NUM_S (C_NUM_SLAVE_SLOTS), .C_NUM_S_LOG (P_NUM_SLAVE_SLOTS_LOG), .C_MESG_WIDTH (P_AA_ARMESG_WIDTH), .C_ARB_PRIORITY (C_S_AXI_ARB_PRIORITY) ) addr_arbiter_ar ( .ACLK (ACLK), .ARESET (reset), // Vector of SI-side AR command request inputs .S_MESG (tmp_aa_armesg), .S_TARGET_HOT (st_aa_artarget_hot), .S_VALID_QUAL (st_aa_arvalid_qual), .S_VALID (st_aa_arvalid), .S_READY (st_aa_arready), // Granted AR command output .M_MESG (aa_mi_armesg), .M_TARGET_HOT (aa_mi_artarget_hot), // MI-slot targeted by granted command .M_GRANT_ENC (aa_mi_argrant_enc), .M_VALID (aa_mi_arvalid), // SI-slot index of granted command .M_READY (aa_mi_arready), .ISSUING_LIMIT (mi_armaxissuing) ); if (C_DEBUG) begin : gen_debug_trans_seq // DEBUG WRITE TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_aw_trans_seq_i <= 1; end else begin if (aa_sa_awvalid && aa_sa_awready) begin debug_aw_trans_seq_i <= debug_aw_trans_seq_i + 1; end end end // DEBUG READ TRANSACTION SEQUENCE COUNTER always @(posedge ACLK) begin if (reset) begin debug_ar_trans_seq_i <= 1; end else begin if (aa_mi_arvalid && aa_mi_arready) begin debug_ar_trans_seq_i <= debug_ar_trans_seq_i + 1; end end end end // gen_debug_trans_seq // Broadcast AR transfer payload to all MI-slots assign M_AXI_ARID = {C_NUM_MASTER_SLOTS{aa_mi_armesg[0+:C_AXI_ID_WIDTH]}}; assign M_AXI_ARADDR = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+:C_AXI_ADDR_WIDTH]}}; assign M_AXI_ARLEN = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]}}; assign M_AXI_ARSIZE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8 +:3]}}; assign M_AXI_ARLOCK = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3 +:2]}}; assign M_AXI_ARPROT = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2 +:3]}}; assign M_AXI_ARREGION = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3 +:4]}}; assign M_AXI_ARBURST = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4 +:2]}}; assign M_AXI_ARCACHE = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2 +:4]}}; assign M_AXI_ARQOS = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4 +:4]}}; assign M_AXI_ARUSER = {C_NUM_MASTER_SLOTS{aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH+8+3+2+3+4+2+4+4 +:C_AXI_ARUSER_WIDTH]}}; // AW arbiter command transfer completes upon completion of both M-side AW-channel transfer and W-mux address acceptance (command push). axi_crossbar_v2_1_splitter # // "SA": Splitter for Write Addr Arbiter ( .C_NUM_M (2) ) splitter_aw_mi ( .ACLK (ACLK), .ARESET (reset), .S_VALID (aa_sa_awvalid), .S_READY (aa_sa_awready), .M_VALID ({mi_awvalid_en, sa_wm_awvalid_en}), .M_READY ({mi_awready_mux, sa_wm_awready_mux}) ); assign mi_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{mi_awvalid_en}}; assign mi_awready_mux = |(aa_mi_awtarget_hot & mi_awready); assign M_AXI_AWVALID = mi_awvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_awready[0+:C_NUM_MASTER_SLOTS] = M_AXI_AWREADY; assign sa_wm_awvalid = aa_mi_awtarget_hot & {C_NUM_MASTER_SLOTS+1{sa_wm_awvalid_en}}; assign sa_wm_awready_mux = |(aa_mi_awtarget_hot & sa_wm_awready); assign mi_arvalid = aa_mi_artarget_hot & {C_NUM_MASTER_SLOTS+1{aa_mi_arvalid}}; assign aa_mi_arready = |(aa_mi_artarget_hot & mi_arready); assign M_AXI_ARVALID = mi_arvalid[0+:C_NUM_MASTER_SLOTS]; // Slot C_NUM_MASTER_SLOTS+1 is the error handler assign mi_arready[0+:C_NUM_MASTER_SLOTS] = M_AXI_ARREADY; // MI-slot # C_NUM_MASTER_SLOTS is the error handler if (C_RANGE_CHECK) begin : gen_decerr_slave axi_crossbar_v2_1_decerr_slave # ( .C_AXI_ID_WIDTH (C_AXI_ID_WIDTH), .C_AXI_DATA_WIDTH (C_AXI_DATA_WIDTH), .C_AXI_RUSER_WIDTH (C_AXI_RUSER_WIDTH), .C_AXI_BUSER_WIDTH (C_AXI_BUSER_WIDTH), .C_AXI_PROTOCOL (C_AXI_PROTOCOL), .C_RESP (P_DECERR) ) decerr_slave_inst ( .S_AXI_ACLK (ACLK), .S_AXI_ARESET (reset), .S_AXI_AWID (aa_mi_awmesg[0+:C_AXI_ID_WIDTH]), .S_AXI_AWVALID (mi_awvalid[C_NUM_MASTER_SLOTS]), .S_AXI_AWREADY (mi_awready[C_NUM_MASTER_SLOTS]), .S_AXI_WLAST (mi_wlast[C_NUM_MASTER_SLOTS]), .S_AXI_WVALID (mi_wvalid[C_NUM_MASTER_SLOTS]), .S_AXI_WREADY (mi_wready[C_NUM_MASTER_SLOTS]), .S_AXI_BID (mi_bid[C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_BRESP (mi_bresp[C_NUM_MASTER_SLOTS*2+:2]), .S_AXI_BUSER (mi_buser[C_NUM_MASTER_SLOTS*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH]), .S_AXI_BVALID (mi_bvalid[C_NUM_MASTER_SLOTS]), .S_AXI_BREADY (mi_bready[C_NUM_MASTER_SLOTS]), .S_AXI_ARID (aa_mi_armesg[0+:C_AXI_ID_WIDTH]), .S_AXI_ARLEN (aa_mi_armesg[C_AXI_ID_WIDTH+C_AXI_ADDR_WIDTH +:8]), .S_AXI_ARVALID (mi_arvalid[C_NUM_MASTER_SLOTS]), .S_AXI_ARREADY (mi_arready[C_NUM_MASTER_SLOTS]), .S_AXI_RID (mi_rid[C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH]), .S_AXI_RDATA (mi_rdata[C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH]), .S_AXI_RRESP (mi_rresp[C_NUM_MASTER_SLOTS*2+:2]), .S_AXI_RUSER (mi_ruser[C_NUM_MASTER_SLOTS*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH]), .S_AXI_RLAST (mi_rlast[C_NUM_MASTER_SLOTS]), .S_AXI_RVALID (mi_rvalid[C_NUM_MASTER_SLOTS]), .S_AXI_RREADY (mi_rready[C_NUM_MASTER_SLOTS]) ); end else begin : gen_no_decerr_slave assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_wready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_arready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_awready[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_bid[C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_bresp[C_NUM_MASTER_SLOTS*2+:2] = 0; assign mi_buser[C_NUM_MASTER_SLOTS*C_AXI_BUSER_WIDTH+:C_AXI_BUSER_WIDTH] = 0; assign mi_bvalid[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rid[C_NUM_MASTER_SLOTS*C_AXI_ID_WIDTH+:C_AXI_ID_WIDTH] = 0; assign mi_rdata[C_NUM_MASTER_SLOTS*C_AXI_DATA_WIDTH+:C_AXI_DATA_WIDTH] = 0; assign mi_rresp[C_NUM_MASTER_SLOTS*2+:2] = 0; assign mi_ruser[C_NUM_MASTER_SLOTS*C_AXI_RUSER_WIDTH+:C_AXI_RUSER_WIDTH] = 0; assign mi_rlast[C_NUM_MASTER_SLOTS] = 1'b0; assign mi_rvalid[C_NUM_MASTER_SLOTS] = 1'b0; end // gen_decerr_slave endgenerate endmodule `default_nettype wire

//----------------------------------------------------------------------------- // // (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. // // This file contains confidential and proprietary information // of Xilinx, Inc. and is protected under U.S. and // international copyright and other intellectual property // laws. // // DISCLAIMER // This disclaimer is not a license and does not grant any // rights to the materials distributed herewith. Except as // otherwise provided in a valid license issued to you by // Xilinx, and to the maximum extent permitted by applicable // law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // (2) Xilinx shall not be liable (whether in contract or tort, // including negligence, or under any other theory of // liability) for any loss or damage of any kind or nature // related to, arising under or in connection with these // materials, including for any direct, or any indirect, // special, incidental, or consequential loss or damage // (including loss of data, profits, goodwill, or any type of // loss or damage suffered as a result of any action brought // by a third party) even if such damage or loss was // reasonably foreseeable or Xilinx had been advised of the // possibility of the same. // // CRITICAL APPLICATIONS // Xilinx products are not designed or intended to be fail- // safe, or for use in any application requiring fail-safe // performance, such as life-support or safety devices or // systems, Class III medical devices, nuclear facilities, // applications related to the deployment of airbags, or any // other applications that could lead to death, personal // injury, or severe property or environmental damage // (individually and collectively, "Critical // Applications"). Customer assumes the sole risk and // liability of any use of Xilinx products in Critical // Applications, subject only to applicable laws and // regulations governing limitations on product liability. // // THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // PART OF THIS FILE AT ALL TIMES. // //----------------------------------------------------------------------------- // Project : Series-7 Integrated Block for PCI Express // File : pcie_7x_0_core_top_axi_basic_rx_null_gen.v // Version : 3.0 // // // Description: // // TRN to AXI RX null generator. Generates null packets for use in // // discontinue situations. // // // // Notes: // // Optional notes section. // // // // Hierarchical: // // axi_basic_top // // axi_basic_rx // // axi_basic_rx_null_gen // // // //----------------------------------------------------------------------------// `timescale 1ps/1ps (* DowngradeIPIdentifiedWarnings = "yes" *) module pcie_7x_0_core_top_axi_basic_rx_null_gen # ( parameter C_DATA_WIDTH = 128, // RX/TX interface data width parameter TCQ = 1, // Clock to Q time // Do not override parameters below this line parameter KEEP_WIDTH = C_DATA_WIDTH / 8 // KEEP width ) ( // AXI RX //----------- input [C_DATA_WIDTH-1:0] m_axis_rx_tdata, // RX data to user input m_axis_rx_tvalid, // RX data is valid input m_axis_rx_tready, // RX ready for data input m_axis_rx_tlast, // RX data is last input [21:0] m_axis_rx_tuser, // RX user signals // Null Inputs //----------- output null_rx_tvalid, // NULL generated tvalid output null_rx_tlast, // NULL generated tlast output [KEEP_WIDTH-1:0] null_rx_tkeep, // NULL generated tkeep output null_rdst_rdy, // NULL generated rdst_rdy output reg [4:0] null_is_eof, // NULL generated is_eof // System //----------- input user_clk, // user clock from block input user_rst // user reset from block ); localparam INTERFACE_WIDTH_DWORDS = (C_DATA_WIDTH == 128) ? 11'd4 : (C_DATA_WIDTH == 64) ? 11'd2 : 11'd1; //----------------------------------------------------------------------------// // NULL packet generator state machine // // This state machine shadows the AXI RX interface, tracking each packet as // // it's passed to the AXI user. When a multi-cycle packet is detected, the // // state machine automatically generates a "null" packet. In the event of a // // discontinue, the RX pipeline can switch over to this null packet as // // necessary. // //----------------------------------------------------------------------------// // State machine variables and states localparam IDLE = 0; localparam IN_PACKET = 1; reg cur_state; reg next_state; // Signals for tracking a packet on the AXI interface reg [11:0] reg_pkt_len_counter; reg [11:0] pkt_len_counter; wire [11:0] pkt_len_counter_dec; wire pkt_done; // Calculate packet fields, which are needed to determine total packet length. wire [11:0] new_pkt_len; wire [9:0] payload_len; wire [1:0] packet_fmt; wire packet_td; reg [3:0] packet_overhead; // Misc. wire [KEEP_WIDTH-1:0] eof_tkeep; wire straddle_sof; wire eof; // Create signals to detect sof and eof situations. These signals vary depending // on data width. assign eof = m_axis_rx_tuser[21]; generate if(C_DATA_WIDTH == 128) begin : sof_eof_128 assign straddle_sof = (m_axis_rx_tuser[14:13] == 2'b11); end else begin : sof_eof_64_32 assign straddle_sof = 1'b0; end endgenerate //----------------------------------------------------------------------------// // Calculate the length of the packet being presented on the RX interface. To // // do so, we need the relevent packet fields that impact total packet length. // // These are: // // - Header length: obtained from bit 1 of FMT field in 1st DWORD of header // // - Payload length: obtained from LENGTH field in 1st DWORD of header // // - TLP digest: obtained from TD field in 1st DWORD of header // // - Current data: the number of bytes that have already been presented // // on the data interface // // // // packet length = header + payload + tlp digest - # of DWORDS already // // transmitted // // // // packet_overhead is where we calculate everything except payload. // //----------------------------------------------------------------------------// generate if(C_DATA_WIDTH == 128) begin : len_calc_128 assign packet_fmt = straddle_sof ? m_axis_rx_tdata[94:93] : m_axis_rx_tdata[30:29]; assign packet_td = straddle_sof ? m_axis_rx_tdata[79] : m_axis_rx_tdata[15]; assign payload_len = packet_fmt[1] ? (straddle_sof ? m_axis_rx_tdata[73:64] : m_axis_rx_tdata[9:0]) : 10'h0; always @(*) begin // In 128-bit mode, the amount of data currently on the interface // depends on whether we're straddling or not. If so, 2 DWORDs have been // seen. If not, 4 DWORDs. case({packet_fmt[0], packet_td, straddle_sof}) // Header + TD - Data currently on interface 3'b0_0_0: packet_overhead = 4'd3 + 4'd0 - 4'd4; 3'b0_0_1: packet_overhead = 4'd3 + 4'd0 - 4'd2; 3'b0_1_0: packet_overhead = 4'd3 + 4'd1 - 4'd4; 3'b0_1_1: packet_overhead = 4'd3 + 4'd1 - 4'd2; 3'b1_0_0: packet_overhead = 4'd4 + 4'd0 - 4'd4; 3'b1_0_1: packet_overhead = 4'd4 + 4'd0 - 4'd2; 3'b1_1_0: packet_overhead = 4'd4 + 4'd1 - 4'd4; 3'b1_1_1: packet_overhead = 4'd4 + 4'd1 - 4'd2; endcase end assign new_pkt_len = {{9{packet_overhead[3]}}, packet_overhead[2:0]} + {2'b0, payload_len}; end else if(C_DATA_WIDTH == 64) begin : len_calc_64 assign packet_fmt = m_axis_rx_tdata[30:29]; assign packet_td = m_axis_rx_tdata[15]; assign payload_len = packet_fmt[1] ? m_axis_rx_tdata[9:0] : 10'h0; always @(*) begin // 64-bit mode: no straddling, so always 2 DWORDs case({packet_fmt[0], packet_td}) // Header + TD - Data currently on interface 2'b0_0: packet_overhead[1:0] = 2'b01 ;//4'd3 + 4'd0 - 4'd2; // 1 2'b0_1: packet_overhead[1:0] = 2'b10 ;//4'd3 + 4'd1 - 4'd2; // 2 2'b1_0: packet_overhead[1:0] = 2'b10 ;//4'd4 + 4'd0 - 4'd2; // 2 2'b1_1: packet_overhead[1:0] = 2'b11 ;//4'd4 + 4'd1 - 4'd2; // 3 endcase end assign new_pkt_len = {{10{1'b0}}, packet_overhead[1:0]} + {2'b0, payload_len}; end else begin : len_calc_32 assign packet_fmt = m_axis_rx_tdata[30:29]; assign packet_td = m_axis_rx_tdata[15]; assign payload_len = packet_fmt[1] ? m_axis_rx_tdata[9:0] : 10'h0; always @(*) begin // 32-bit mode: no straddling, so always 1 DWORD case({packet_fmt[0], packet_td}) // Header + TD - Data currently on interface 2'b0_0: packet_overhead = 4'd3 + 4'd0 - 4'd1; 2'b0_1: packet_overhead = 4'd3 + 4'd1 - 4'd1; 2'b1_0: packet_overhead = 4'd4 + 4'd0 - 4'd1; 2'b1_1: packet_overhead = 4'd4 + 4'd1 - 4'd1; endcase end assign new_pkt_len = {{9{packet_overhead[3]}}, packet_overhead[2:0]} + {2'b0, payload_len}; end endgenerate // Now calculate actual packet length, adding the packet overhead and the // payload length. This is signed math, so sign-extend packet_overhead. // NOTE: a payload length of zero means 1024 DW in the PCIe spec, but this // behavior isn't supported in our block. //assign new_pkt_len = // {{9{packet_overhead[3]}}, packet_overhead[2:0]} + {2'b0, payload_len}; // Math signals needed in the state machine below. These are seperate wires to // help ensure synthesis tools sre smart about optimizing them. assign pkt_len_counter_dec = reg_pkt_len_counter - INTERFACE_WIDTH_DWORDS; assign pkt_done = (reg_pkt_len_counter <= INTERFACE_WIDTH_DWORDS); //----------------------------------------------------------------------------// // Null generator Mealy state machine. Determine outputs based on: // // 1) current st // // 2) current inp // //----------------------------------------------------------------------------// always @(*) begin case (cur_state) // IDLE state: the interface is IDLE and we're waiting for a packet to // start. If a packet starts, move to state IN_PACKET and begin tracking // it as long as it's NOT a single cycle packet (indicated by assertion of // eof at packet start) IDLE: begin if(m_axis_rx_tvalid && m_axis_rx_tready && !eof) begin next_state = IN_PACKET; end else begin next_state = IDLE; end pkt_len_counter = new_pkt_len; end // IN_PACKET: a mutli-cycle packet is in progress and we're tracking it. We // are in lock-step with the AXI interface decrementing our packet length // tracking reg, and waiting for the packet to finish. // // * If packet finished and a new one starts, this is a straddle situation. // Next state is IN_PACKET (128-bit only). // * If the current packet is done, next state is IDLE. // * Otherwise, next state is IN_PACKET. IN_PACKET: begin // Straddle packet if((C_DATA_WIDTH == 128) && straddle_sof && m_axis_rx_tvalid) begin pkt_len_counter = new_pkt_len; next_state = IN_PACKET; end // Current packet finished else if(m_axis_rx_tready && pkt_done) begin pkt_len_counter = new_pkt_len; next_state = IDLE; end // Packet in progress else begin if(m_axis_rx_tready) begin // Not throttled pkt_len_counter = pkt_len_counter_dec; end else begin // Throttled pkt_len_counter = reg_pkt_len_counter; end next_state = IN_PACKET; end end default: begin pkt_len_counter = reg_pkt_len_counter; next_state = IDLE; end endcase end // Synchronous NULL packet generator state machine logic always @(posedge user_clk) begin if(user_rst) begin cur_state <= #TCQ IDLE; reg_pkt_len_counter <= #TCQ 12'h0; end else begin cur_state <= #TCQ next_state; reg_pkt_len_counter <= #TCQ pkt_len_counter; end end // Generate tkeep/is_eof for an end-of-packet situation. generate if(C_DATA_WIDTH == 128) begin : strb_calc_128 always @(*) begin // Assign null_is_eof depending on how many DWORDs are left in the // packet. case(pkt_len_counter) 10'd1: null_is_eof = 5'b10011; 10'd2: null_is_eof = 5'b10111; 10'd3: null_is_eof = 5'b11011; 10'd4: null_is_eof = 5'b11111; default: null_is_eof = 5'b00011; endcase end // tkeep not used in 128-bit interface assign eof_tkeep = {KEEP_WIDTH{1'b0}}; end else if(C_DATA_WIDTH == 64) begin : strb_calc_64 always @(*) begin // Assign null_is_eof depending on how many DWORDs are left in the // packet. case(pkt_len_counter) 10'd1: null_is_eof = 5'b10011; 10'd2: null_is_eof = 5'b10111; default: null_is_eof = 5'b00011; endcase end // Assign tkeep to 0xFF or 0x0F depending on how many DWORDs are left in // the current packet. assign eof_tkeep = { ((pkt_len_counter == 12'd2) ? 4'hF:4'h0), 4'hF }; end else begin : strb_calc_32 always @(*) begin // is_eof is either on or off for 32-bit if(pkt_len_counter == 12'd1) begin null_is_eof = 5'b10011; end else begin null_is_eof = 5'b00011; end end // The entire DWORD is always valid in 32-bit mode, so tkeep is always 0xF assign eof_tkeep = 4'hF; end endgenerate // Finally, use everything we've generated to calculate our NULL outputs assign null_rx_tvalid = 1'b1; assign null_rx_tlast = (pkt_len_counter <= INTERFACE_WIDTH_DWORDS); assign null_rx_tkeep = null_rx_tlast ? eof_tkeep : {KEEP_WIDTH{1'b1}}; assign null_rdst_rdy = null_rx_tlast; endmodule

// // Copyright (c) 2012-2013 Jonathan Woodruff // Copyright (c) 2013 Bjoern A. Zeeb // Copyright (c) 2014 A. Theodore Markettos // Copyright (c) 2014 Robert M. Norton // All rights reserved. // // This software was developed by SRI International and the University of // Cambridge Computer Laboratory under DARPA/AFRL contract FA8750-10-C-0237 // ("CTSRD"), as part of the DARPA CRASH research programme. // // This software was developed by SRI International and the University of // Cambridge Computer Laboratory under DARPA/AFRL contract FA8750-11-C-0249 // ("MRC2"), as part of the DARPA MRC research programme. // // @BERI_LICENSE_HEADER_START@ // // Licensed to BERI Open Systems C.I.C. (BERI) under one or more contributor // license agreements. See the NOTICE file distributed with this work for // additional information regarding copyright ownership. BERI licenses this // file to you under the BERI Hardware-Software License, Version 1.0 (the // "License"); you may not use this file except in compliance with the // License. You may obtain a copy of the License at: // // http://www.beri-open-systems.org/legal/license-1-0.txt // // Unless required by applicable law or agreed to in writing, Work distributed // under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR // CONDITIONS OF ANY KIND, either express or implied. See the License for the // specific language governing permissions and limitations under the License. // // @BERI_LICENSE_HEADER_END@ // `define ENABLE_LED `define ENABLE_BUTTONS `define ENABLE_ETHERNET `define ENABLE_SDCARD `define ENABLE_UART `define ENABLE_DDR2_1 `define ENABLE_DIP `define ENABLE_SLIDE `define ENABLE_SEG `define ENABLE_TEMP `define ENABLE_CSENSE `define ENABLE_FLASH `define ENABLE_SSRAM `define ENABLE_USB `define ENABLE_HDMI `define ENABLE_MTL `ifndef ENABLE_DDR2_1 `ifndef ENABLE_DDR2_2 `define DISABLE_TERMINATION `endif `endif `ifndef ENABLE_FLASH `ifndef ENABLE_SSRAM `define DISABLE_FSM `endif `endif module DE4_BERI ( ////// clock inputs //input GCLKIN, //output GCLKOUT_FPGA, //inout [2:0] MAX_CONF_D, //output [2:0] MAX_PLL_D, input OSC_50_Bank2, input OSC_50_Bank3, input OSC_50_Bank4, //input OSC_50_Bank5, //input OSC_50_Bank6, //input OSC_50_Bank7, //input PLL_CLKIN_p, `ifdef ENABLE_LED output [7:0] LED, // 8x LEDs `endif `ifdef ENABLE_BUTTONS input [3:0] BUTTON, // 4x buttons `endif input CPU_RESET_n, //inout EXT_IO, `ifdef ENABLE_ETHERNET ////// Ethernet MAC x 4 input [3:0] ETH_INT_n, output [3:0] ETH_MDC, inout [3:0] ETH_MDIO, output ETH_RST_n, input [3:0] ETH_RX_p, output [3:0] ETH_TX_p, `endif `ifdef ENABLE_SDCARD ////// SD card socket output SD_CLK, inout SD_CMD, inout [3:0] SD_DAT, input SD_WP_n, `endif `ifdef ENABLE_UART ////// UART output UART_TXD, input UART_CTS, input UART_RXD, output UART_RTS, `endif `ifdef ENABLE_DDR2_1 ////// DDR2 SODIMM 1 output [15:0] M1_DDR2_addr, output [2:0] M1_DDR2_ba, output M1_DDR2_cas_n, output [1:0] M1_DDR2_cke, inout [1:0] M1_DDR2_clk, inout [1:0] M1_DDR2_clk_n, output [1:0] M1_DDR2_cs_n, output [7:0] M1_DDR2_dm, inout [63:0] M1_DDR2_dq, inout [7:0] M1_DDR2_dqs, inout [7:0] M1_DDR2_dqsn, output [1:0] M1_DDR2_odt, output M1_DDR2_ras_n, output [1:0] M1_DDR2_SA, output M1_DDR2_SCL, inout M1_DDR2_SDA, output M1_DDR2_we_n, `endif `ifdef ENABLE_DDR2_2 ////// DDR2 SODIMM 2 output [15:0] M2_DDR2_addr, output [2:0] M2_DDR2_ba, output M2_DDR2_cas_n, output [1:0] M2_DDR2_cke, inout [1:0] M2_DDR2_clk, inout [1:0] M2_DDR2_clk_n, output [1:0] M2_DDR2_cs_n, output [7:0] M2_DDR2_dm, inout [63:0] M2_DDR2_dq, inout [7:0] M2_DDR2_dqs, inout [7:0] M2_DDR2_dqsn, output [1:0] M2_DDR2_odt, output M2_DDR2_ras_n, output [1:0] M2_DDR2_SA, output M2_DDR2_SCL, inout M2_DDR2_SDA, output M2_DDR2_we_n, `endif `ifndef DISABLE_TERMINATION // termination for DDR2 DIMMs input termination_blk0_rup_pad, input termination_blk0_rdn_pad, `endif `ifdef ENABLE_DIP input [7:0] SW, // 8x DIP switches `endif `ifdef ENABLE_SLIDE input [3:0] SLIDE_SW, // 4x slide switches `endif `ifdef ENABLE_SEG // 2x 7-segment displays output [6:0] SEG0_D, output SEG0_DP, output [6:0] SEG1_D, output SEG1_DP, `endif `ifdef ENABLE_TEMP // temperature sensors input TEMP_INT_n, output TEMP_SMCLK, inout TEMP_SMDAT, `endif `ifdef ENABLE_CSENSE // current sensors output CSENSE_ADC_FO, output [1:0] CSENSE_CS_n, output CSENSE_SCK, output CSENSE_SDI, input CSENSE_SDO, `endif output FAN_CTRL, // fan control `ifndef DISABLE_FSM // flash and SRAM shared data bus output [25:1] FSM_A, inout [15:0] FSM_D, `endif `ifdef ENABLE_FLASH // Flash memory output FLASH_ADV_n, output FLASH_CE_n, output FLASH_CLK, output FLASH_OE_n, output FLASH_RESET_n, input FLASH_RYBY_n, output FLASH_WE_n, `endif `ifdef ENABLE_SSRAM // synchronous SRAM output SSRAM_ADV, output SSRAM_BWA_n, output SSRAM_BWB_n, output SSRAM_CE_n, output SSRAM_CKE_n, output SSRAM_CLK, output SSRAM_OE_n, output SSRAM_WE_n, `endif // HSMC port A and B `ifdef ENABLE_HDMI // HDMI interface board on HSMC port A //inout HDMI_SDA, //output HDMI_SCL, output [11:0] HDMI_TX_RD, output [11:0] HDMI_TX_GD, inout HDMI_TX_PCSCL, inout HDMI_TX_PCSDA, output HDMI_TX_RST_N, input HDMI_TX_INT_N, output [3:0] HDMI_TX_DSD_L, output [3:0] HDMI_TX_DSD_R, output [11:0] HDMI_TX_BD, output HDMI_TX_PCLK, output HDMI_TX_DCLK, output HDMI_TX_SCK, output HDMI_TX_WS, output HDMI_TX_MCLK, output [3:0] HDMI_TX_I2S, output HDMI_TX_DE, output HDMI_TX_VS, output HDMI_TX_HS, output HDMI_TX_SPDIF, inout HDMI_TX_CEC, `endif // GPIO port 0 input [31:0] GPIO0_D, `ifdef ENABLE_USB output [17:1] OTG_A, output OTG_CS_n, inout [31:0] OTG_D, output OTG_DC_DACK, input OTG_DC_DREQ, input OTG_DC_IRQ, output OTG_HC_DACK, input OTG_HC_DREQ, input OTG_HC_IRQ, output OTG_OE_n, output OTG_RESET_n, output OTG_WE_n, `endif `ifdef ENABLE_MTL // GPIO port 1 connect to MTL capacitive touch screen output mtl_dclk, output [7:0] mtl_r, output [7:0] mtl_g, output [7:0] mtl_b, output mtl_hsd, output mtl_vsd, output mtl_touch_i2cscl, inout mtl_touch_i2csda, input mtl_touch_int `endif `ifdef ENABLE_PCIE , //PCI Express input PCIE_PREST_n, input PCIE_REFCLK_p, //input HSMA_REFCLK_p, input [3:0] PCIE_RX_p, input PCIE_SMBCLK, inout PCIE_SMBDAT, output [3:0] PCIE_TX_p, output PCIE_WAKE_n `endif ); wire global_reset_n; wire enet_reset_n; //// Ethernet wire enet_mdc; wire enet_mdio_in; wire enet_mdio_oen; wire enet_mdio_out; wire enet_refclk_125MHz; wire lvds_rxp; wire lvds_txp; wire enet1_mdc; wire enet1_mdio_in; wire enet1_mdio_oen; wire enet1_mdio_out; wire lvds_rxp1; wire lvds_txp1; // Assign outputs that are not used to 0 //assign MAX_PLL_D = 3'b0; //assign ETH_MDC[3:1] = 3'b0; assign M1_DDR2_SA = 1'b0; assign CSENSE_CS_n = 1'b0; assign CSENSE_ADC_FO = 1'b0; assign CSENSE_SCK = 1'b0; assign CSENSE_SDI = 1'b0; //assign GCLKOUT_FPGA = 1'b0; assign M1_DDR2_SCL = 1'b0; //// Ethernet assign ETH_RST_n = rstn; assign ETH_TX_p[3:2] = 2'b0; assign lvds_rxp = ETH_RX_p[0]; assign ETH_TX_p[0] = lvds_txp; assign lvds_rxp1 = ETH_RX_p[1]; assign ETH_TX_p[1] = lvds_txp1; assign enet_mdio_in = ETH_MDIO[0]; assign enet1_mdio_in = ETH_MDIO[1]; assign ETH_MDIO[0] = (!enet_mdio_oen ? enet_mdio_out : 1'bz); assign ETH_MDIO[1] = (!enet1_mdio_oen ? enet1_mdio_out : 1'bz); // Allow the other two tri-state interfaces to float. assign ETH_MDIO[2] = 1'bz; assign ETH_MDIO[3] = 1'bz; assign ETH_MDC[0] = enet_mdc; assign ETH_MDC[1] = enet1_mdc; // Set unused interface clocks to high. assign ETH_MDC[2] = 1'b1; assign ETH_MDC[3] = 1'b1; wire clk100; wire [7:0] LED_n; assign LED = ~LED_n; // === Ethernet clock PLL pll_125 pll_125_ins ( .inclk0(OSC_50_Bank2), .c0(enet_refclk_125MHz) ); `ifdef ENABLE_PCIE wire clk125; //PCI Express clock pll_125 pll_125_pcie ( .inclk0(OSC_50_Bank2), .c0(clk125) ); assign reconfig_clk = OSC_50_Bank3; wire reconfig_fromgxb; wire reconfig_togxb; wire reconfig_busy; altgx_reconfig altgx_reconfig_pcie ( .reconfig_clk(reconfig_clk), .reconfig_fromgxb(reconfig_fromgxb), .busy(reconfig_busy), .reconfig_togxb(reconfig_togxb) ); `endif wire qsys_sysclk; wire qsys_sysreset_n; //wire sramClk; assign SSRAM_CLK = qsys_sysclk; (* keep = 1 *) wire clk27; display_pll display_pll_ins ( .inclk0(OSC_50_Bank2), .c0(clk27) ); assign HDMI_TX_PCLK = clk27; // synchronize reset signal reg rstn, rstn_metastable; always @(posedge OSC_50_Bank2) begin rstn_metastable <= CPU_RESET_n && GPIO0_D[2]; rstn <= rstn_metastable; end reg rstn100, rstn100_metastable; always @(posedge qsys_sysclk) begin rstn100_metastable <= CPU_RESET_n && GPIO0_D[2]; rstn100 <= rstn100_metastable; end (* noprune *) reg rstn27; reg rstn27sample; always @(posedge clk27) begin rstn27sample <= rstn; rstn27 <= rstn27sample; end reg [7:0] SW_P; always @(posedge OSC_50_Bank2) SW_P <= ~SW; // positive version of DIP switches assign SEG1_DP = ~1'b0; assign SEG0_DP = ~1'b0; reg [3:0] slide_sw_metastable, slide_sw_sync; always @(posedge OSC_50_Bank2) begin slide_sw_metastable <= SLIDE_SW; slide_sw_sync <= slide_sw_metastable; end // assign PCIE_WAKE_n = 1'b0; // assign PCIE_SMBDATA = 1'bz; /* signals for the old Terasic resistive touch screen (currently unused) wire [7:0] vga_R, vga_G, vga_B; wire vga_DEN, vga_HD, vga_VD; assign vga_DEN = 1'b0; assign vga_HD = 1'b0; assign vga_VD = 1'b0; assign vga_R = 8'd0; assign vga_G = 8'd0; assign vga_B = 8'd0; assign lcdtouchLTM_R = vga_R; assign lcdtouchLTM_G = vga_G; assign lcdtouchLTM_B = vga_B; assign lcdtouchLTM_DEN = vga_DEN; assign lcdtouchLTM_HD = vga_HD; assign lcdtouchLTM_VD = vga_VD; assign lcdtouchLTM_GREST = rstn27; assign lcdtouchLTM_NCLK = clk27; assign lcdtouchLTM_SCEN = 1'b1; assign lcdtouchLTM_ADC_DCLK = 1'b1; assign lcdtouchLTM_ADC_DIN = 1'b1;*/ // clock for multitouch screen assign mtl_dclk = clk27; (* keep = 1 *) wire ssram_data_outen; (* keep = 1 *) wire [15:0] ssram_data_out; // instantiate the touch screen controller provided by Terasic (encrypted block) reg touch_ready_0; reg [9:0] touch_x1_0, touch_x2_0; reg [8:0] touch_y1_0, touch_y2_0; reg [1:0] touch_count_0; reg [7:0] touch_gesture_0; reg touch_ready_1; reg [9:0] touch_x1_1, touch_x2_1; reg [8:0] touch_y1_1, touch_y2_1; reg [1:0] touch_count_1; reg [7:0] touch_gesture_1; wire touch_ready_2; wire [9:0] touch_x1_2, touch_x2_2; wire [8:0] touch_y1_2, touch_y2_2; wire [1:0] touch_count_2; wire [7:0] touch_gesture_2; i2c_touch_config touch( .iCLK(OSC_50_Bank2), .iRSTN(rstn), .iTRIG(!mtl_touch_int), // note that this signal is inverted .oREADY(touch_ready_2), .oREG_X1(touch_x1_2), .oREG_Y1(touch_y1_2), .oREG_X2(touch_x2_2), .oREG_Y2(touch_y2_2), .oREG_TOUCH_COUNT(touch_count_2), .oREG_GESTURE(touch_gesture_2), .I2C_SCLK(mtl_touch_i2cscl), .I2C_SDAT(mtl_touch_i2csda)); // synchronize signals to qsys system clock always @(posedge qsys_sysclk) begin touch_ready_1 <= touch_ready_2; touch_x1_1 <= touch_x1_2; touch_y1_1 <= touch_y1_2; touch_x2_1 <= touch_x2_2; touch_y2_1 <= touch_y2_2; touch_count_1 <= touch_count_2; touch_gesture_1 <= touch_gesture_2; touch_ready_0 <= touch_ready_1; touch_x1_0 <= touch_x1_1; touch_y1_0 <= touch_y1_1; touch_x2_0 <= touch_x2_1; touch_y2_0 <= touch_y2_1; touch_count_0 <= touch_count_1; touch_gesture_0 <= touch_gesture_1; end // touch screen controller end wire i2c_scl_oe_n; wire i2c_scl_o; wire i2c_scl_i = HDMI_TX_PCSCL; wire i2c_sda_oe_n; wire i2c_sda_o; wire i2c_sda_i = HDMI_TX_PCSDA; // tristate buffers assign HDMI_TX_PCSCL = i2c_scl_oe_n==1'b0 ? i2c_scl_o : 1'bz; assign HDMI_TX_PCSDA = i2c_sda_oe_n==1'b0 ? i2c_sda_o : 1'bz; //wire gen_sck; //wire gen_i2s; //wire gen_ws; assign HDMI_TX_SCK = 1'b0; assign HDMI_TX_I2S = 4'b0;//{gen_i2s, gen_i2s, gen_i2s, gen_i2s}; assign HDMI_TX_WS = 1'b0;//gen_ws; wire [31:0] otg_dout; assign OTG_D = (!OTG_CS_n & OTG_OE_n) ? otg_dout : 32'hzzzzzzzz; wire [16:0] otg_a_temp; assign OTG_A[17:1] = otg_a_temp[16:0]; DE4_SOC DE4_SOC_inst( // 1) global signals: .clk_50_clk(OSC_50_Bank2), .clk_125_clk(enet_refclk_125MHz), .reset_reset_n(rstn), .sysclk_clk(qsys_sysclk), //.sysreset_reset_n(qsys_sysreset_n), .leds_external_connection_export(LED_n), // the_ddr2 .ddr2_global_reset_reset_n(), .memory_mem_cke (M1_DDR2_cke), // ddr2.cke .memory_mem_ck_n (M1_DDR2_clk_n), // .ck_n .memory_mem_cas_n (M1_DDR2_cas_n), // .cas_n .memory_mem_dq (M1_DDR2_dq), // .dq .memory_mem_dqs (M1_DDR2_dqs), // .dqs .memory_mem_odt (M1_DDR2_odt), // .odt .memory_mem_cs_n (M1_DDR2_cs_n), // .cs_n .memory_mem_ba (M1_DDR2_ba), // .ba .memory_mem_dm (M1_DDR2_dm), // .dm .memory_mem_we_n (M1_DDR2_we_n), // .we_n .memory_mem_dqs_n (M1_DDR2_dqsn), // .dqs_n .memory_mem_ras_n (M1_DDR2_ras_n), // .ras_n .memory_mem_ck (M1_DDR2_clk), // .ck .memory_mem_a (M1_DDR2_addr), // .a .oct_rup (termination_blk0_rup_pad), // .oct_rup .oct_rdn (termination_blk0_rdn_pad), // .oct_rdn // ddr2 psd i2c // .out_port_from_the_ddr2_i2c_scl(M1_DDR2_SCL), // .out_port_from_the_ddr2_i2c_sa(M1_DDR2_SA), // .bidir_port_to_and_from_the_ddr2_i2c_sda(M1_DDR2_SDA) // --------------------------------------------------------------------- // MAC (TSE) 0 .mac_mac_mdio_mdc (enet_mdc), // mac_mac_mdio.mdc .mac_mac_mdio_mdio_in (enet_mdio_in), // .mdio_in .mac_mac_mdio_mdio_out (enet_mdio_out), // .mdio_out .mac_mac_mdio_mdio_oen (enet_mdio_oen), // .mdio_oen //.mac_mac_misc_xon_gen, (/* input */) // mac_mac_misc.xon_gen //.mac_mac_misc_xoff_gen, (/* input */) // .xoff_gen //.mac_mac_misc_magic_wakeup, (/* output */) // .magic_wakeup //.mac_mac_misc_magic_sleep_n, (/* input */) // .magic_sleep_n //.mac_mac_misc_ff_tx_crc_fwd, (/* input */) // .ff_tx_crc_fwd //.mac_mac_misc_ff_tx_septy, (/* output */) // .ff_tx_septy //.mac_mac_misc_tx_ff_uflow, (/* output */) // .tx_ff_uflow //.mac_mac_misc_ff_tx_a_full, (/* output */) // .ff_tx_a_full //.mac_mac_misc_ff_tx_a_empty, (/* output */) // .ff_tx_a_empty //.mac_mac_misc_rx_err_stat, (/* output[17:0] */) // .rx_err_stat //.mac_mac_misc_rx_frm_type, (/* output[3:0] */) // .rx_frm_type //.mac_mac_misc_ff_rx_dsav, (/* output */) // .ff_rx_dsav //.mac_mac_misc_ff_rx_a_full, (/* output */) // .ff_rx_a_full //.mac_mac_misc_ff_rx_a_empty, (/* output */) // .ff_rx_a_empty //.mac_status_led_crs, (/* output */) // mac_status_led.crs //.mac_status_led_link, (/* output */) // .link //.mac_status_led_col, (/* output */) // .col //.mac_status_led_an, (/* output */) // .an //.mac_status_led_char_err, (/* output */) // .char_err //.mac_status_led_disp_err, (/* output */) // .disp_err //.mac_serdes_control_export, (/* output */) // mac_serdes_control.export .mac_serial_txp (lvds_txp), // mac_serial.txp .mac_serial_rxp (lvds_rxp), // .rxp // --------------------------------------------------------------------- // MAC (TSE) 1 .mac1_mac_mdio_mdc (enet1_mdc), // mac1_mac_mdio.mdc .mac1_mac_mdio_mdio_in (enet1_mdio_in), // .mdio_in .mac1_mac_mdio_mdio_out (enet1_mdio_out), // .mdio_out .mac1_mac_mdio_mdio_oen (enet1_mdio_oen), // .mdio_oen //.mac1_mac_misc_xon_gen, ( input ) // mac1_mac_misc.xon_gen //.mac1_mac_misc_xoff_gen, ( input ) // .xoff_gen //.mac1_mac_misc_magic_wakeup, ( output ) // .magic_wakeup //.mac1_mac_misc_magic_sleep_n, ( input ) // .magic_sleep_n //.mac1_mac_misc_ff_tx_crc_fwd, ( input ) // .ff_tx_crc_fwd //.mac1_mac_misc_ff_tx_septy, ( output ) // .ff_tx_septy //.mac1_mac_misc_tx_ff_uflow, ( output ) // .tx_ff_uflow //.mac1_mac_misc_ff_tx_a_full, ( output ) // .ff_tx_a_full //.mac1_mac_misc_ff_tx_a_empty, ( output ) // .ff_tx_a_empty //.mac1_mac_misc_rx_err_stat, ( output[17:0] ) // .rx_err_stat //.mac1_mac_misc_rx_frm_type, ( output[3:0] ) // .rx_frm_type //.mac1_mac_misc_ff_rx_dsav, ( output ) // .ff_rx_dsav //.mac1_mac_misc_ff_rx_a_full, ( output ) // .ff_rx_a_full //.mac1_mac_misc_ff_rx_a_empty, ( output ) // .ff_rx_a_empty //.mac1_status_led_crs, ( output ) // mac1_status_led.crs //.mac1_status_led_link, ( output ) // .link //.mac1_status_led_col, ( output ) // .col //.mac1_status_led_an, ( output ) // .an //.mac1_status_led_char_err, ( output ) // .char_err //.mac1_status_led_disp_err, ( output ) // .disp_err //.mac1_serdes_control_export, ( output ) // mac1_serdes_control.export .mac1_serial_txp (lvds_txp1), // mac1_serial.txp .mac1_serial_rxp (lvds_rxp1), // .rxp // ---------------------------------------------------------------------/ .sd_b_SD_cmd (SD_CMD), // sd.b_SD_cmd .sd_b_SD_dat (SD_DAT[0]), // .b_SD_dat .sd_b_SD_dat3 (SD_DAT[3]), // .b_SD_dat3 .sd_o_SD_clock (SD_CLK), // .o_SD_clock .mem_ssram_adv (SSRAM_ADV), // fbssram_1.ssram_adv .mem_ssram_bwa_n (SSRAM_BWA_n), // .ssram_bwa_n .mem_ssram_bwb_n (SSRAM_BWB_n), // .ssram_bwb_n .mem_ssram_ce_n (SSRAM_CE_n), // .ssram_ce_n .mem_ssram_cke_n (SSRAM_CKE_n), // .ssram_cke_n .mem_ssram_oe_n (SSRAM_OE_n), // .ssram_oe_n .mem_ssram_we_n (SSRAM_WE_n), // .ssram_we_n .mem_fsm_a (FSM_A), // .fsm_a .mem_fsm_d_out (ssram_data_out), // .fsm_d_out .mem_fsm_d_in (FSM_D), // .fsm_d_in .mem_fsm_dout_req (ssram_data_outen), // .fsm_dout_req .mem_flash_adv_n (FLASH_ADV_n), .mem_flash_ce_n (FLASH_CE_n), .mem_flash_clk (FLASH_CLK), .mem_flash_oe_n (FLASH_OE_n), .mem_flash_we_n (FLASH_WE_n), .touch_x1 (touch_x1_0), // .touch_x1 .touch_y1 (touch_y1_0), // .touch_y1 .touch_x2 (touch_x2_0), // .touch_x2 .touch_y2 (touch_y2_0), // .touch_y2 .touch_count_gesture ({touch_count_0,touch_gesture_0}), // .touch_count_gesture .touch_touch_valid (touch_ready_0), // .touch_touch_valid // .sram_clk_clk (sramClk), // sram_clk.clk // .sram_clk_clk (SSRAM_CLK) // .display_clk_clk (clk27), .coe_hdmi_r(HDMI_TX_RD), .coe_hdmi_g(HDMI_TX_GD), .coe_hdmi_b(HDMI_TX_BD), .coe_hdmi_hsd(HDMI_TX_HS), .coe_hdmi_vsd(HDMI_TX_VS), .coe_hdmi_de(HDMI_TX_DE), .coe_tpadlcd_mtl_r(mtl_r), .coe_tpadlcd_mtl_g(mtl_g), .coe_tpadlcd_mtl_b(mtl_b), .coe_tpadlcd_mtl_hsd(mtl_hsd), .coe_tpadlcd_mtl_vsd(mtl_vsd), .clk_27_clk (clk27), .coe_i2c_scl_i (i2c_scl_i), .coe_i2c_scl_o (i2c_scl_o), .coe_i2c_scl_oe_n (i2c_scl_oe_n), .coe_i2c_sda_i (i2c_sda_i), .coe_i2c_sda_o (i2c_sda_o), .coe_i2c_sda_oe_n (i2c_sda_oe_n), .hdmi_tx_reset_n_external_connection_export (HDMI_TX_RST_N), // .i2s_tx_conduit_end_sck (gen_sck), // i2s_tx_conduit_end.sck // .i2s_tx_conduit_end_ws (gen_ws), // .ws // .i2s_tx_conduit_end_sd (gen_i2s), .usb_coe_cs_n (OTG_CS_n), // usb.coe_cs_n .usb_coe_rd_n (OTG_OE_n), // .coe_rd_n .usb_coe_din (OTG_D), // .coe_din .usb_coe_dout (otg_dout), // .coe_dout .usb_coe_a (otg_a_temp), // .coe_a .usb_coe_dc_irq_in (OTG_DC_IRQ), // .coe_dc_irq_in .usb_coe_hc_irq_in (OTG_HC_IRQ), // .coe_hc_irq_in //.usb_coe_dc_dreq_in (OTG_DC_DREQ), // .coe_dc_dreq_in //.usb_coe_hc_dreq_in (OTG_HC_DREQ), // .coe_hc_dreq_in //.usb_coe_dc_dack (OTG_DC_DACK), // .coe_dc_dack //.usb_coe_hc_dack (OTG_HC_DACK), // .coe_hc_dack .usb_coe_wr_n (OTG_WE_n), // .coe_wr_n .fan_fan_on_pwm (FAN_CTRL), // .fan_temp_lower_seg_n (SEG0_D), // .temp_lower_seg_n .fan_temp_upper_seg_n (SEG1_D), // .temp_upper_seg_n. .switches_export ({SLIDE_SW[3:0], BUTTON[3:0], SW_P[7:0]}), .rs232_stx_pad_o (UART_TXD), // rs232.stx_pad_o .rs232_srx_pad_i (UART_RXD), // .srx_pad_i .rs232_rts_pad_o (UART_RTS), // .rts_pad_o .rs232_cts_pad_i (UART_CTS), // .cts_pad_i .rs232_dtr_pad_o (), // .dtr_pad_o // I have no idea what these should be by default. Should see Simon's example project. .rs232_dsr_pad_i (1'b1), // .dsr_pad_i .rs232_ri_pad_i (1'b1), // .ri_pad_i .rs232_dcd_pad_i (1'b1) // .dcd_pad_i `ifdef ENABLE_PCIE , .pciexpressstream_0_refclk_export (PCIE_REFCLK_p), .pciexpressstream_0_fixedclk_clk (clk125), .pciexpressstream_0_cal_blk_clk_clk (reconfig_clk), .pciexpressstream_0_reconfig_gxbclk_clk (reconfig_clk), .pciexpressstream_0_reconfig_togxb_data (reconfig_togxb), .pciexpressstream_0_reconfig_fromgxb_0_data (reconfig_fromgxb), .pciexpressstream_0_reconfig_busy_busy_altgxb_reconfig (reconfig_busy), .pciexpressstream_0_pcie_rstn_export (PCIE_PREST_n), .pciexpressstream_0_rx_in_rx_datain_0 (PCIE_RX_p[0]), .pciexpressstream_0_rx_in_rx_datain_1 (PCIE_RX_p[1]), .pciexpressstream_0_rx_in_rx_datain_2 (PCIE_RX_p[2]), .pciexpressstream_0_rx_in_rx_datain_3 (PCIE_RX_p[3]), .pciexpressstream_0_tx_out_tx_dataout_0 (PCIE_TX_p[0]), .pciexpressstream_0_tx_out_tx_dataout_1 (PCIE_TX_p[1]), .pciexpressstream_0_tx_out_tx_dataout_2 (PCIE_TX_p[2]), .pciexpressstream_0_tx_out_tx_dataout_3 (PCIE_TX_p[3]) `endif ); // handle USB (OTG) reset signal assign OTG_RESET_n = rstn100; // handle unused flash reset signal assign FLASH_RESET_n = rstn100; // handle tristate ssram data bus assign FSM_D = ssram_data_outen ? ssram_data_out : 16'bzzzzzzzzzzzzzzzz; endmodule

module serial_rx #( parameter CLK_PER_BIT = 50 )( input clk, input rst, input rx, output [7:0] data, output new_data ); // clog2 is 'ceiling of log base 2' which gives you the number of bits needed to store a value parameter CTR_SIZE = $clog2(CLK_PER_BIT); localparam STATE_SIZE = 2; localparam IDLE = 2'd0, WAIT_HALF = 2'd1, WAIT_FULL = 2'd2, WAIT_HIGH = 2'd3; reg [CTR_SIZE-1:0] ctr_d, ctr_q; reg [2:0] bit_ctr_d, bit_ctr_q; reg [7:0] data_d, data_q; reg new_data_d, new_data_q; reg [STATE_SIZE-1:0] state_d, state_q = IDLE; reg rx_d, rx_q; assign new_data = new_data_q; assign data = data_q; always @(*) begin rx_d = rx; state_d = state_q; ctr_d = ctr_q; bit_ctr_d = bit_ctr_q; data_d = data_q; new_data_d = 1'b0; case (state_q) IDLE: begin bit_ctr_d = 3'b0; ctr_d = 1'b0; if (rx_q == 1'b0) begin state_d = WAIT_HALF; end end WAIT_HALF: begin ctr_d = ctr_q + 1'b1; if (ctr_q == (CLK_PER_BIT >> 1)) begin ctr_d = 1'b0; state_d = WAIT_FULL; end end WAIT_FULL: begin ctr_d = ctr_q + 1'b1; if (ctr_q == CLK_PER_BIT - 1) begin data_d = {rx_q, data_q[7:1]}; bit_ctr_d = bit_ctr_q + 1'b1; ctr_d = 1'b0; if (bit_ctr_q == 3'd7) begin state_d = WAIT_HIGH; new_data_d = 1'b1; end end end WAIT_HIGH: begin if (rx_q == 1'b1) begin state_d = IDLE; end end default: begin state_d = IDLE; end endcase end always @(posedge clk) begin if (rst) begin ctr_q <= 1'b0; bit_ctr_q <= 3'b0; new_data_q <= 1'b0; state_q <= IDLE; end else begin ctr_q <= ctr_d; bit_ctr_q <= bit_ctr_d; new_data_q <= new_data_d; state_q <= state_d; end rx_q <= rx_d; data_q <= data_d; end endmodule

// (C) 1992-2014 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. module acl_ic_slave_wrp #( parameter integer DATA_W = 32, // > 0 parameter integer BURSTCOUNT_W = 4, // > 0 parameter integer ADDRESS_W = 32, // > 0 parameter integer BYTEENA_W = DATA_W / 8, // > 0 parameter integer ID_W = 1, // > 0 parameter integer NUM_MASTERS = 1, // > 0 // If the fifo depth is zero, the module will perform the write ack here, // otherwise it will take the write ack from the input s_writeack. parameter integer FIFO_DEPTH = 0, // >= 0 (0 disables) parameter integer PIPELINE = 1 // 0|1 ) ( input clock, input resetn, acl_arb_intf m_intf, input logic s_writeack, acl_ic_wrp_intf wrp_intf, output logic stall ); generate if( NUM_MASTERS > 1 ) begin // This slave endpoint may not directly talk to the ACTUAL slave. In // this case we need a fifo to store which master each write ack should // go to. If FIFO_DEPTH is 0 then we assume the writeack can be // generated right here (the way it was done originally) if( FIFO_DEPTH > 0 ) begin // We don't have to worry about bursts, we'll fifo each transaction // since writeack behaves like readdatavalid logic rf_empty, rf_full; acl_ll_fifo #( .WIDTH( ID_W ), .DEPTH( FIFO_DEPTH ) ) write_fifo( .clk( clock ), .reset( ~resetn ), .data_in( m_intf.req.id ), .write( ~m_intf.stall & m_intf.req.write ), .data_out( wrp_intf.id ), .read( wrp_intf.ack & ~rf_empty), .empty( rf_empty ), .full( rf_full ) ); // Register slave writeack to guarantee fifo output is ready always @( posedge clock or negedge resetn ) begin if( !resetn ) wrp_intf.ack <= 1'b0; else wrp_intf.ack <= s_writeack; end assign stall = rf_full; end else if( PIPELINE == 1 ) begin assign stall = 1'b0; always @( posedge clock or negedge resetn ) if( !resetn ) begin wrp_intf.ack <= 1'b0; wrp_intf.id <= 'x; // don't need to reset end else begin // Always register the id. The ack signal acts as the enable. wrp_intf.id <= m_intf.req.id; wrp_intf.ack <= 1'b0; if( ~m_intf.stall & m_intf.req.write ) // A valid write cycle. Ack it. wrp_intf.ack <= 1'b1; end end else begin assign wrp_intf.id = m_intf.req.id; assign wrp_intf.ack = ~m_intf.stall & m_intf.req.write; assign stall = 1'b0; end end else // NUM_MASTERS == 1 begin // Only one master so don't need to check the id. if ( FIFO_DEPTH == 0 ) begin assign wrp_intf.ack = ~m_intf.stall & m_intf.req.write; assign stall = 1'b0; end else begin assign wrp_intf.ack = s_writeack; assign stall = 1'b0; end end endgenerate endmodule

// (C) 2001-2016 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. // (C) 2001-2013 Altera Corporation. All rights reserved. // Your use of Altera Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Altera Program License Subscription // Agreement, Altera MegaCore Function License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Altera and sold by // Altera or its authorized distributors. Please refer to the applicable // agreement for further details. // $Id: //acds/rel/16.0/ip/merlin/altera_reset_controller/altera_reset_controller.v#1 $ // $Revision: #1 $ // $Date: 2016/02/08 $ // $Author: swbranch $ // -------------------------------------- // Reset controller // // Combines all the input resets and synchronizes // the result to the clk. // ACDS13.1 - Added reset request as part of reset sequencing // -------------------------------------- `timescale 1 ns / 1 ns module altera_reset_controller #( parameter NUM_RESET_INPUTS = 6, parameter USE_RESET_REQUEST_IN0 = 0, parameter USE_RESET_REQUEST_IN1 = 0, parameter USE_RESET_REQUEST_IN2 = 0, parameter USE_RESET_REQUEST_IN3 = 0, parameter USE_RESET_REQUEST_IN4 = 0, parameter USE_RESET_REQUEST_IN5 = 0, parameter USE_RESET_REQUEST_IN6 = 0, parameter USE_RESET_REQUEST_IN7 = 0, parameter USE_RESET_REQUEST_IN8 = 0, parameter USE_RESET_REQUEST_IN9 = 0, parameter USE_RESET_REQUEST_IN10 = 0, parameter USE_RESET_REQUEST_IN11 = 0, parameter USE_RESET_REQUEST_IN12 = 0, parameter USE_RESET_REQUEST_IN13 = 0, parameter USE_RESET_REQUEST_IN14 = 0, parameter USE_RESET_REQUEST_IN15 = 0, parameter OUTPUT_RESET_SYNC_EDGES = "deassert", parameter SYNC_DEPTH = 2, parameter RESET_REQUEST_PRESENT = 0, parameter RESET_REQ_WAIT_TIME = 3, parameter MIN_RST_ASSERTION_TIME = 11, parameter RESET_REQ_EARLY_DSRT_TIME = 4, parameter ADAPT_RESET_REQUEST = 0 ) ( // -------------------------------------- // We support up to 16 reset inputs, for now // -------------------------------------- input reset_in0, input reset_in1, input reset_in2, input reset_in3, input reset_in4, input reset_in5, input reset_in6, input reset_in7, input reset_in8, input reset_in9, input reset_in10, input reset_in11, input reset_in12, input reset_in13, input reset_in14, input reset_in15, input reset_req_in0, input reset_req_in1, input reset_req_in2, input reset_req_in3, input reset_req_in4, input reset_req_in5, input reset_req_in6, input reset_req_in7, input reset_req_in8, input reset_req_in9, input reset_req_in10, input reset_req_in11, input reset_req_in12, input reset_req_in13, input reset_req_in14, input reset_req_in15, input clk, output reg reset_out, output reg reset_req ); // Always use async reset synchronizer if reset_req is used localparam ASYNC_RESET = (OUTPUT_RESET_SYNC_EDGES == "deassert"); // -------------------------------------- // Local parameter to control the reset_req and reset_out timing when RESET_REQUEST_PRESENT==1 // -------------------------------------- localparam MIN_METASTABLE = 3; localparam RSTREQ_ASRT_SYNC_TAP = MIN_METASTABLE + RESET_REQ_WAIT_TIME; localparam LARGER = RESET_REQ_WAIT_TIME > RESET_REQ_EARLY_DSRT_TIME ? RESET_REQ_WAIT_TIME : RESET_REQ_EARLY_DSRT_TIME; localparam ASSERTION_CHAIN_LENGTH = (MIN_METASTABLE > LARGER) ? MIN_RST_ASSERTION_TIME + 1 : ( (MIN_RST_ASSERTION_TIME > LARGER)? MIN_RST_ASSERTION_TIME + (LARGER - MIN_METASTABLE + 1) + 1 : MIN_RST_ASSERTION_TIME + RESET_REQ_EARLY_DSRT_TIME + RESET_REQ_WAIT_TIME - MIN_METASTABLE + 2 ); localparam RESET_REQ_DRST_TAP = RESET_REQ_EARLY_DSRT_TIME + 1; // -------------------------------------- wire merged_reset; wire merged_reset_req_in; wire reset_out_pre; wire reset_req_pre; // Registers and Interconnect (*preserve*) reg [RSTREQ_ASRT_SYNC_TAP: 0] altera_reset_synchronizer_int_chain; reg [ASSERTION_CHAIN_LENGTH-1: 0] r_sync_rst_chain; reg r_sync_rst; reg r_early_rst; // -------------------------------------- // "Or" all the input resets together // -------------------------------------- assign merged_reset = ( reset_in0 | reset_in1 | reset_in2 | reset_in3 | reset_in4 | reset_in5 | reset_in6 | reset_in7 | reset_in8 | reset_in9 | reset_in10 | reset_in11 | reset_in12 | reset_in13 | reset_in14 | reset_in15 ); assign merged_reset_req_in = ( ( (USE_RESET_REQUEST_IN0 == 1) ? reset_req_in0 : 1'b0) | ( (USE_RESET_REQUEST_IN1 == 1) ? reset_req_in1 : 1'b0) | ( (USE_RESET_REQUEST_IN2 == 1) ? reset_req_in2 : 1'b0) | ( (USE_RESET_REQUEST_IN3 == 1) ? reset_req_in3 : 1'b0) | ( (USE_RESET_REQUEST_IN4 == 1) ? reset_req_in4 : 1'b0) | ( (USE_RESET_REQUEST_IN5 == 1) ? reset_req_in5 : 1'b0) | ( (USE_RESET_REQUEST_IN6 == 1) ? reset_req_in6 : 1'b0) | ( (USE_RESET_REQUEST_IN7 == 1) ? reset_req_in7 : 1'b0) | ( (USE_RESET_REQUEST_IN8 == 1) ? reset_req_in8 : 1'b0) | ( (USE_RESET_REQUEST_IN9 == 1) ? reset_req_in9 : 1'b0) | ( (USE_RESET_REQUEST_IN10 == 1) ? reset_req_in10 : 1'b0) | ( (USE_RESET_REQUEST_IN11 == 1) ? reset_req_in11 : 1'b0) | ( (USE_RESET_REQUEST_IN12 == 1) ? reset_req_in12 : 1'b0) | ( (USE_RESET_REQUEST_IN13 == 1) ? reset_req_in13 : 1'b0) | ( (USE_RESET_REQUEST_IN14 == 1) ? reset_req_in14 : 1'b0) | ( (USE_RESET_REQUEST_IN15 == 1) ? reset_req_in15 : 1'b0) ); // -------------------------------------- // And if required, synchronize it to the required clock domain, // with the correct synchronization type // -------------------------------------- generate if (OUTPUT_RESET_SYNC_EDGES == "none" && (RESET_REQUEST_PRESENT==0)) begin assign reset_out_pre = merged_reset; assign reset_req_pre = merged_reset_req_in; end else begin altera_reset_synchronizer #( .DEPTH (SYNC_DEPTH), .ASYNC_RESET(RESET_REQUEST_PRESENT? 1'b1 : ASYNC_RESET) ) alt_rst_sync_uq1 ( .clk (clk), .reset_in (merged_reset), .reset_out (reset_out_pre) ); altera_reset_synchronizer #( .DEPTH (SYNC_DEPTH), .ASYNC_RESET(0) ) alt_rst_req_sync_uq1 ( .clk (clk), .reset_in (merged_reset_req_in), .reset_out (reset_req_pre) ); end endgenerate generate if ( ( (RESET_REQUEST_PRESENT == 0) && (ADAPT_RESET_REQUEST==0) )| ( (ADAPT_RESET_REQUEST == 1) && (OUTPUT_RESET_SYNC_EDGES != "deassert") ) ) begin always @* begin reset_out = reset_out_pre; reset_req = reset_req_pre; end end else if ( (RESET_REQUEST_PRESENT == 0) && (ADAPT_RESET_REQUEST==1) ) begin wire reset_out_pre2; altera_reset_synchronizer #( .DEPTH (SYNC_DEPTH+1), .ASYNC_RESET(0) ) alt_rst_sync_uq2 ( .clk (clk), .reset_in (reset_out_pre), .reset_out (reset_out_pre2) ); always @* begin reset_out = reset_out_pre2; reset_req = reset_req_pre; end end else begin // 3-FF Metastability Synchronizer initial begin altera_reset_synchronizer_int_chain <= {RSTREQ_ASRT_SYNC_TAP{1'b1}}; end always @(posedge clk) begin altera_reset_synchronizer_int_chain[RSTREQ_ASRT_SYNC_TAP:0] <= {altera_reset_synchronizer_int_chain[RSTREQ_ASRT_SYNC_TAP-1:0], reset_out_pre}; end // Synchronous reset pipe initial begin r_sync_rst_chain <= {ASSERTION_CHAIN_LENGTH{1'b1}}; end always @(posedge clk) begin if (altera_reset_synchronizer_int_chain[MIN_METASTABLE-1] == 1'b1) begin r_sync_rst_chain <= {ASSERTION_CHAIN_LENGTH{1'b1}}; end else begin r_sync_rst_chain <= {1'b0, r_sync_rst_chain[ASSERTION_CHAIN_LENGTH-1:1]}; end end // Standard synchronous reset output. From 0-1, the transition lags the early output. For 1->0, the transition // matches the early input. always @(posedge clk) begin case ({altera_reset_synchronizer_int_chain[RSTREQ_ASRT_SYNC_TAP], r_sync_rst_chain[1], r_sync_rst}) 3'b000: r_sync_rst <= 1'b0; // Not reset 3'b001: r_sync_rst <= 1'b0; 3'b010: r_sync_rst <= 1'b0; 3'b011: r_sync_rst <= 1'b1; 3'b100: r_sync_rst <= 1'b1; 3'b101: r_sync_rst <= 1'b1; 3'b110: r_sync_rst <= 1'b1; 3'b111: r_sync_rst <= 1'b1; // In Reset default: r_sync_rst <= 1'b1; endcase case ({r_sync_rst_chain[1], r_sync_rst_chain[RESET_REQ_DRST_TAP] | reset_req_pre}) 2'b00: r_early_rst <= 1'b0; // Not reset 2'b01: r_early_rst <= 1'b1; // Coming out of reset 2'b10: r_early_rst <= 1'b0; // Spurious reset - should not be possible via synchronous design. 2'b11: r_early_rst <= 1'b1; // Held in reset default: r_early_rst <= 1'b1; endcase end always @* begin reset_out = r_sync_rst; reset_req = r_early_rst; end end endgenerate endmodule

// DESCRIPTION: Verilator: Verilog Test module // // This file ONLY is placed into the Public Domain, for any use, // without warranty, 2005 by Wilson Snyder. module t (clk); input clk; reg [2:0] a; reg [2:0] b; reg q; f6 f6 (/*AUTOINST*/ // Outputs .q (q), // Inputs .a (a[2:0]), .b (b[2:0]), .clk (clk)); integer cyc; initial cyc=1; always @ (posedge clk) begin if (cyc!=0) begin cyc <= cyc + 1; if (cyc==1) begin a <= 3'b000; b <= 3'b100; end if (cyc==2) begin a <= 3'b011; b <= 3'b001; if (q != 1'b0) $stop; end if (cyc==3) begin a <= 3'b011; b <= 3'b011; if (q != 1'b0) $stop; end if (cyc==9) begin if (q != 1'b1) $stop; $write("*-* All Finished *-*\n"); $finish; end end end endmodule module f6 (a, b, clk, q); input [2:0] a; input [2:0] b; input clk; output q; reg out; function func6; reg result; input [5:0] src; begin if (src[5:0] == 6'b011011) begin result = 1'b1; end else begin result = 1'b0; end func6 = result; end endfunction wire [5:0] w6 = {a, b}; always @(posedge clk) begin out <= func6(w6); end assign q = out; endmodule

// ============================================================== // File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC // Version: 2015.4 // Copyright (C) 2015 Xilinx Inc. All rights reserved. // // ============================================================== `timescale 1ns/1ps module ANN_AXILiteS_s_axi #(parameter C_S_AXI_ADDR_WIDTH = 6, C_S_AXI_DATA_WIDTH = 32 )( // axi4 lite slave signals input wire ACLK, input wire ARESET, input wire ACLK_EN, input wire [C_S_AXI_ADDR_WIDTH-1:0] AWADDR, input wire AWVALID, output wire AWREADY, input wire [C_S_AXI_DATA_WIDTH-1:0] WDATA, input wire [C_S_AXI_DATA_WIDTH/8-1:0] WSTRB, input wire WVALID, output wire WREADY, output wire [1:0] BRESP, output wire BVALID, input wire BREADY, input wire [C_S_AXI_ADDR_WIDTH-1:0] ARADDR, input wire ARVALID, output wire ARREADY, output wire [C_S_AXI_DATA_WIDTH-1:0] RDATA, output wire [1:0] RRESP, output wire RVALID, input wire RREADY, output wire interrupt, // user signals output wire ap_start, input wire ap_done, input wire ap_ready, input wire ap_idle, input wire [31:0] ap_return, output wire [31:0] P_mode, output wire [31:0] P_index1, output wire [31:0] P_index2, output wire [31:0] P_intIn_index3, output wire [31:0] P_floatIn ); //------------------------Address Info------------------- // 0x00 : Control signals // bit 0 - ap_start (Read/Write/COH) // bit 1 - ap_done (Read/COR) // bit 2 - ap_idle (Read) // bit 3 - ap_ready (Read) // bit 7 - auto_restart (Read/Write) // others - reserved // 0x04 : Global Interrupt Enable Register // bit 0 - Global Interrupt Enable (Read/Write) // others - reserved // 0x08 : IP Interrupt Enable Register (Read/Write) // bit 0 - Channel 0 (ap_done) // bit 1 - Channel 1 (ap_ready) // others - reserved // 0x0c : IP Interrupt Status Register (Read/TOW) // bit 0 - Channel 0 (ap_done) // bit 1 - Channel 1 (ap_ready) // others - reserved // 0x10 : Data signal of ap_return // bit 31~0 - ap_return[31:0] (Read) // 0x18 : Data signal of P_mode // bit 31~0 - P_mode[31:0] (Read/Write) // 0x1c : reserved // 0x20 : Data signal of P_index1 // bit 31~0 - P_index1[31:0] (Read/Write) // 0x24 : reserved // 0x28 : Data signal of P_index2 // bit 31~0 - P_index2[31:0] (Read/Write) // 0x2c : reserved // 0x30 : Data signal of P_intIn_index3 // bit 31~0 - P_intIn_index3[31:0] (Read/Write) // 0x34 : reserved // 0x38 : Data signal of P_floatIn // bit 31~0 - P_floatIn[31:0] (Read/Write) // 0x3c : reserved // (SC = Self Clear, COR = Clear on Read, TOW = Toggle on Write, COH = Clear on Handshake) //------------------------Parameter---------------------- localparam ADDR_AP_CTRL = 6'h00, ADDR_GIE = 6'h04, ADDR_IER = 6'h08, ADDR_ISR = 6'h0c, ADDR_AP_RETURN_0 = 6'h10, ADDR_P_MODE_DATA_0 = 6'h18, ADDR_P_MODE_CTRL = 6'h1c, ADDR_P_INDEX1_DATA_0 = 6'h20, ADDR_P_INDEX1_CTRL = 6'h24, ADDR_P_INDEX2_DATA_0 = 6'h28, ADDR_P_INDEX2_CTRL = 6'h2c, ADDR_P_INTIN_INDEX3_DATA_0 = 6'h30, ADDR_P_INTIN_INDEX3_CTRL = 6'h34, ADDR_P_FLOATIN_DATA_0 = 6'h38, ADDR_P_FLOATIN_CTRL = 6'h3c, WRIDLE = 2'd0, WRDATA = 2'd1, WRRESP = 2'd2, RDIDLE = 2'd0, RDDATA = 2'd1, ADDR_BITS = 6; //------------------------Local signal------------------- reg [1:0] wstate; reg [1:0] wnext; reg [ADDR_BITS-1:0] waddr; wire [31:0] wmask; wire aw_hs; wire w_hs; reg [1:0] rstate; reg [1:0] rnext; reg [31:0] rdata; wire ar_hs; wire [ADDR_BITS-1:0] raddr; // internal registers wire int_ap_idle; wire int_ap_ready; reg int_ap_done; reg int_ap_start; reg int_auto_restart; reg int_gie; reg [1:0] int_ier; reg [1:0] int_isr; reg [31:0] int_ap_return; reg [31:0] int_P_mode; reg [31:0] int_P_index1; reg [31:0] int_P_index2; reg [31:0] int_P_intIn_index3; reg [31:0] int_P_floatIn; //------------------------Instantiation------------------ //------------------------AXI write fsm------------------ assign AWREADY = (wstate == WRIDLE); assign WREADY = (wstate == WRDATA); assign BRESP = 2'b00; // OKAY assign BVALID = (wstate == WRRESP); assign wmask = { {8{WSTRB[3]}}, {8{WSTRB[2]}}, {8{WSTRB[1]}}, {8{WSTRB[0]}} }; assign aw_hs = AWVALID & AWREADY; assign w_hs = WVALID & WREADY; // wstate always @(posedge ACLK) begin if (ARESET) wstate <= WRIDLE; else if (ACLK_EN) wstate <= wnext; end // wnext always @(*) begin case (wstate) WRIDLE: if (AWVALID) wnext = WRDATA; else wnext = WRIDLE; WRDATA: if (WVALID) wnext = WRRESP; else wnext = WRDATA; WRRESP: if (BREADY) wnext = WRIDLE; else wnext = WRRESP; default: wnext = WRIDLE; endcase end // waddr always @(posedge ACLK) begin if (ACLK_EN) begin if (aw_hs) waddr <= AWADDR[ADDR_BITS-1:0]; end end //------------------------AXI read fsm------------------- assign ARREADY = (rstate == RDIDLE); assign RDATA = rdata; assign RRESP = 2'b00; // OKAY assign RVALID = (rstate == RDDATA); assign ar_hs = ARVALID & ARREADY; assign raddr = ARADDR[ADDR_BITS-1:0]; // rstate always @(posedge ACLK) begin if (ARESET) rstate <= RDIDLE; else if (ACLK_EN) rstate <= rnext; end // rnext always @(*) begin case (rstate) RDIDLE: if (ARVALID) rnext = RDDATA; else rnext = RDIDLE; RDDATA: if (RREADY & RVALID) rnext = RDIDLE; else rnext = RDDATA; default: rnext = RDIDLE; endcase end // rdata always @(posedge ACLK) begin if (ACLK_EN) begin if (ar_hs) begin rdata <= 1'b0; case (raddr) ADDR_AP_CTRL: begin rdata[0] <= int_ap_start; rdata[1] <= int_ap_done; rdata[2] <= int_ap_idle; rdata[3] <= int_ap_ready; rdata[7] <= int_auto_restart; end ADDR_GIE: begin rdata <= int_gie; end ADDR_IER: begin rdata <= int_ier; end ADDR_ISR: begin rdata <= int_isr; end ADDR_AP_RETURN_0: begin rdata <= int_ap_return[31:0]; end ADDR_P_MODE_DATA_0: begin rdata <= int_P_mode[31:0]; end ADDR_P_INDEX1_DATA_0: begin rdata <= int_P_index1[31:0]; end ADDR_P_INDEX2_DATA_0: begin rdata <= int_P_index2[31:0]; end ADDR_P_INTIN_INDEX3_DATA_0: begin rdata <= int_P_intIn_index3[31:0]; end ADDR_P_FLOATIN_DATA_0: begin rdata <= int_P_floatIn[31:0]; end endcase end end end //------------------------Register logic----------------- assign interrupt = int_gie & (|int_isr); assign ap_start = int_ap_start; assign int_ap_idle = ap_idle; assign int_ap_ready = ap_ready; assign P_mode = int_P_mode; assign P_index1 = int_P_index1; assign P_index2 = int_P_index2; assign P_intIn_index3 = int_P_intIn_index3; assign P_floatIn = int_P_floatIn; // int_ap_start always @(posedge ACLK) begin if (ARESET) int_ap_start <= 1'b0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_AP_CTRL && WSTRB[0] && WDATA[0]) int_ap_start <= 1'b1; else if (int_ap_ready) int_ap_start <= int_auto_restart; // clear on handshake/auto restart end end // int_ap_done always @(posedge ACLK) begin if (ARESET) int_ap_done <= 1'b0; else if (ACLK_EN) begin if (ap_done) int_ap_done <= 1'b1; else if (ar_hs && raddr == ADDR_AP_CTRL) int_ap_done <= 1'b0; // clear on read end end // int_auto_restart always @(posedge ACLK) begin if (ARESET) int_auto_restart <= 1'b0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_AP_CTRL && WSTRB[0]) int_auto_restart <= WDATA[7]; end end // int_gie always @(posedge ACLK) begin if (ARESET) int_gie <= 1'b0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_GIE && WSTRB[0]) int_gie <= WDATA[0]; end end // int_ier always @(posedge ACLK) begin if (ARESET) int_ier <= 1'b0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_IER && WSTRB[0]) int_ier <= WDATA[1:0]; end end // int_isr[0] always @(posedge ACLK) begin if (ARESET) int_isr[0] <= 1'b0; else if (ACLK_EN) begin if (int_ier[0] & ap_done) int_isr[0] <= 1'b1; else if (w_hs && waddr == ADDR_ISR && WSTRB[0]) int_isr[0] <= int_isr[0] ^ WDATA[0]; // toggle on write end end // int_isr[1] always @(posedge ACLK) begin if (ARESET) int_isr[1] <= 1'b0; else if (ACLK_EN) begin if (int_ier[1] & ap_ready) int_isr[1] <= 1'b1; else if (w_hs && waddr == ADDR_ISR && WSTRB[0]) int_isr[1] <= int_isr[1] ^ WDATA[1]; // toggle on write end end // int_ap_return always @(posedge ACLK) begin if (ARESET) int_ap_return <= 0; else if (ACLK_EN) begin if (ap_done) int_ap_return <= ap_return; end end // int_P_mode[31:0] always @(posedge ACLK) begin if (ARESET) int_P_mode[31:0] <= 0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_P_MODE_DATA_0) int_P_mode[31:0] <= (WDATA[31:0] & wmask) | (int_P_mode[31:0] & ~wmask); end end // int_P_index1[31:0] always @(posedge ACLK) begin if (ARESET) int_P_index1[31:0] <= 0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_P_INDEX1_DATA_0) int_P_index1[31:0] <= (WDATA[31:0] & wmask) | (int_P_index1[31:0] & ~wmask); end end // int_P_index2[31:0] always @(posedge ACLK) begin if (ARESET) int_P_index2[31:0] <= 0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_P_INDEX2_DATA_0) int_P_index2[31:0] <= (WDATA[31:0] & wmask) | (int_P_index2[31:0] & ~wmask); end end // int_P_intIn_index3[31:0] always @(posedge ACLK) begin if (ARESET) int_P_intIn_index3[31:0] <= 0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_P_INTIN_INDEX3_DATA_0) int_P_intIn_index3[31:0] <= (WDATA[31:0] & wmask) | (int_P_intIn_index3[31:0] & ~wmask); end end // int_P_floatIn[31:0] always @(posedge ACLK) begin if (ARESET) int_P_floatIn[31:0] <= 0; else if (ACLK_EN) begin if (w_hs && waddr == ADDR_P_FLOATIN_DATA_0) int_P_floatIn[31:0] <= (WDATA[31:0] & wmask) | (int_P_floatIn[31:0] & ~wmask); end end //------------------------Memory logic------------------- endmodule

/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 */ `ifndef SKY130_FD_SC_LP__AND4B_1_V `define SKY130_FD_SC_LP__AND4B_1_V /** * and4b: 4-input AND, first input inverted. * * Verilog wrapper for and4b with size of 1 units. * * WARNING: This file is autogenerated, do not modify directly! */ `timescale 1ns / 1ps `default_nettype none `include "sky130_fd_sc_lp__and4b.v" `ifdef USE_POWER_PINS /*********************************************************/ `celldefine module sky130_fd_sc_lp__and4b_1 ( X , A_N , B , C , D , VPWR, VGND, VPB , VNB ); output X ; input A_N ; input B ; input C ; input D ; input VPWR; input VGND; input VPB ; input VNB ; sky130_fd_sc_lp__and4b base ( .X(X), .A_N(A_N), .B(B), .C(C), .D(D), .VPWR(VPWR), .VGND(VGND), .VPB(VPB), .VNB(VNB) ); endmodule `endcelldefine /*********************************************************/ `else // If not USE_POWER_PINS /*********************************************************/ `celldefine module sky130_fd_sc_lp__and4b_1 ( X , A_N, B , C , D ); output X ; input A_N; input B ; input C ; input D ; // Voltage supply signals supply1 VPWR; supply0 VGND; supply1 VPB ; supply0 VNB ; sky130_fd_sc_lp__and4b base ( .X(X), .A_N(A_N), .B(B), .C(C), .D(D) ); endmodule `endcelldefine /*********************************************************/ `endif // USE_POWER_PINS `default_nettype wire `endif // SKY130_FD_SC_LP__AND4B_1_V

/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 */ `ifndef SKY130_FD_SC_LS__NAND3_SYMBOL_V `define SKY130_FD_SC_LS__NAND3_SYMBOL_V /** * nand3: 3-input NAND. * * Verilog stub (without power pins) for graphical symbol definition * generation. * * WARNING: This file is autogenerated, do not modify directly! */ `timescale 1ns / 1ps `default_nettype none (* blackbox *) module sky130_fd_sc_ls__nand3 ( //# {{data|Data Signals}} input A, input B, input C, output Y ); // Voltage supply signals supply1 VPWR; supply0 VGND; supply1 VPB ; supply0 VNB ; endmodule `default_nettype wire `endif // SKY130_FD_SC_LS__NAND3_SYMBOL_V

/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 */ `ifndef SKY130_FD_SC_HS__SEDFXBP_1_V `define SKY130_FD_SC_HS__SEDFXBP_1_V /** * sedfxbp: Scan delay flop, data enable, non-inverted clock, * complementary outputs. * * Verilog wrapper for sedfxbp with size of 1 units. * * WARNING: This file is autogenerated, do not modify directly! */ `timescale 1ns / 1ps `default_nettype none `include "sky130_fd_sc_hs__sedfxbp.v" `ifdef USE_POWER_PINS /*********************************************************/ `celldefine module sky130_fd_sc_hs__sedfxbp_1 ( Q , Q_N , CLK , D , DE , SCD , SCE , VPWR, VGND ); output Q ; output Q_N ; input CLK ; input D ; input DE ; input SCD ; input SCE ; input VPWR; input VGND; sky130_fd_sc_hs__sedfxbp base ( .Q(Q), .Q_N(Q_N), .CLK(CLK), .D(D), .DE(DE), .SCD(SCD), .SCE(SCE), .VPWR(VPWR), .VGND(VGND) ); endmodule `endcelldefine /*********************************************************/ `else // If not USE_POWER_PINS /*********************************************************/ `celldefine module sky130_fd_sc_hs__sedfxbp_1 ( Q , Q_N, CLK, D , DE , SCD, SCE ); output Q ; output Q_N; input CLK; input D ; input DE ; input SCD; input SCE; // Voltage supply signals supply1 VPWR; supply0 VGND; sky130_fd_sc_hs__sedfxbp base ( .Q(Q), .Q_N(Q_N), .CLK(CLK), .D(D), .DE(DE), .SCD(SCD), .SCE(SCE) ); endmodule `endcelldefine /*********************************************************/ `endif // USE_POWER_PINS `default_nettype wire `endif // SKY130_FD_SC_HS__SEDFXBP_1_V

module ControlUnit(input[5:0] opcode, input[5:0] funct, output reg reg_dst, output reg reg_write, output reg[1:0] alu_src, output reg[3:0] alu_op, output reg branch, output reg mem_write, output reg mem_to_reg, output reg zero_sign_ext, output reg mult_op, output reg mfhi, output reg mflo); always @(opcode, funct) begin // Make sure that all output have an initial value assigned in // order to prevent synthesis of sequential logic. reg_dst = 1'bx; reg_write = 1'bx; alu_src = 2'bxx; alu_op = 4'bxxxx; branch = 1'bx; mem_write = 1'bx; mem_to_reg = 1'bx; zero_sign_ext = 1'bx; mult_op = 1'b0; // use the multiply/div alu mfhi = 1'b0; // move from hi mflo = 1'b0; // move from lo // Check opcode case (opcode) // If opcode is 0, check funct 6'h00: begin // Common signals reg_dst = 1; reg_write = 1; alu_src = 0; branch = 0; mem_write = 0; mem_to_reg = 0; // ALU operation depends on funct case (funct) // add 6'h20: begin alu_op = 4'b0000; $display("\tInstruction 'add'"); end //addu 6'h21: begin alu_op = 4'b0000; $display("\tInstruction 'addu'"); end // sub 6'h22: begin alu_op = 4'b0001; $display("\tInstruction 'sub'"); end // subu 6'h23: begin alu_op = 4'b0001; $display("\tInstruction 'subu'"); end // and 6'h24: begin alu_op = 4'b0010; $display("\tInstruction 'and'"); end // nor 6'h27: begin alu_op = 4'b0100; $display("\tInstruction 'nor'"); end // or 6'h25: begin alu_op = 4'b0011; $display("\tInstruction 'or'"); end // xor 6'h26: begin alu_op = 4'b0101; $display("\tInstruction 'xor'"); end // sll 6'h0: begin alu_op = 6; alu_src = 2; $display("\tInstruction 'sll'"); end // srl 6'h2: begin alu_op = 7; alu_src = 2; $display("\tInstruction 'srl'"); end // sra 6'h3: begin alu_op = 8; alu_src = 2; $display("\tInstruction 'sra'"); end // sllv 6'h4: begin alu_op = 6; $display("\tInstruction 'sllv'"); end // srlv 6'h6: begin alu_op = 7; $display("\tInstruction 'srlv'"); end // srav 6'h7: begin alu_op = 8; $display("\tInstruction 'srav'"); end // slt 6'h2a: begin alu_op = 4'b1001; $display("\tInstruction 'slt'"); end // sltu 6'h2b: begin alu_op = 4'b1010; $display("\tInstruction 'sltu'"); end // mult 6'h18: begin mult_op = 1; reg_write = 0; alu_op = 4'b0010; $display("\tInstruction 'mult'"); end // multu 6'h19: begin mult_op = 1; reg_write = 0; alu_op = 4'b0011; $display("\tInstruction 'multu'"); end // div 6'h1A: begin mult_op = 1; reg_write = 0; alu_op = 4'b0000; $display("\tInstruction 'div'"); end // divu 6'h1B: begin mult_op = 1; reg_write = 0; alu_op = 4'b0001; $display("\tInstruction 'divu'"); end // mfhi 6'h10: begin alu_op = 4'b1111; mfhi = 1; $display("\tInstruction 'mfhi'"); end // mflo 6'h12: begin alu_op = 4'b1111; mflo = 1; $display("\tInstruction 'mflo'"); end endcase end // lw 6'h23: begin reg_dst = 0; reg_write = 1; alu_src = 1; alu_op = 4'b0000; branch = 0; mem_write = 0; mem_to_reg = 1; zero_sign_ext = 0; $display("\tInstruction 'lw'"); end // sw 6'h2b: begin reg_write = 0; alu_src = 1; alu_op = 4'b0000; branch = 0; mem_write = 1; zero_sign_ext = 0; $display("\tInstruction 'sw'"); end // beq 6'h04: begin reg_write = 0; alu_src = 0; alu_op = 4'b0001; branch = 1; mem_write = 0; $display("\tInstruction 'beq'"); end endcase end endmodule

/* * File: imx_cbu.v * Project: pippo * Designer: kiss@pwrsemi * Mainteiner: kiss@pwrsemi * Checker: * Assigner: * Description: Core Bridge Unit - ÇÅ½ÓcoreµÄimxºÍÆ¬ÉÏ»¥Á¬ÐÒé * IMXºÍWBµÄÒìÍ¬ 1£¬IMXÎÞÐèslaveÊ¹ÓÃrtyÐÅºÅ£¬masterÔÚslaveÃ»ÓÐ·µ»ØackÇ°±£³ÖÇëÇó 2£¬IMXÐèÒª·µ»Øµ±Ç°ÇëÇóµÄaddrÐÅºÅ 3£¬IMXµÄÎ¨Ò»Íê³ÉÐÅºÅÎªack£¬errÔÚackÎªÓÐÐ§Ê±Öµ²ÅÓÐÒâÒå * Task.I: verification environment for complex imx-cbu-wb interaction 1, IMXÁ¬ÐøÇëÇóÇé¿ö 2, ²»Í¬×ÜÏßÊ±¿ÌÈ¡ÏûIMXÇëÇóµÄÇé¿ö£¬È¡Ïûºó»Ö¸´ÓÐÐ§»òÐÂÇëÇóÓÐÐ§µÄÇé¿ö 3, ÊÇ·ñ´æÔÚIMXÇëÇóÒ»Ö±ÓÐÐ§£¬µ«µØÖ··¢Éú±ä»¯µÄÇé¿ö£¿´¦ÀíÆ÷ÄÚºËÓ¦¸Ã²»»á³öÏÖ£¬ÇëÇóÈ¡ÏûÊ±±ØÐëÓÐÒ»ÅÄ¿ÕÏÐ * Task.II: ¿çÊ±ÖÓÓòÖ§³Ö Burst´«ÊäÖ§³Ö */ // synopsys translate_off `include "timescale.v" // synopsys translate_on `include "def_pippo.v" module imx_cbu( clk, rst, wb_cyc_o, wb_adr_o, wb_stb_o, wb_we_o, wb_sel_o, wb_dat_o, wb_cti_o, wb_bte_o, wb_ack_i, wb_err_i, wb_rty_i, wb_dat_i, cbu_dat_i, cbu_adr_i, cbu_rqt_i, cbu_we_i, cbu_sel_i, cbu_ack_o, cbu_dat_o, cbu_err_o, cbu_adr_o ); parameter dw = 32; parameter aw = 32; // currently no burst support `define WB_CTI 3'b000 `define WB_BTE 2'b00 // // core clock, reset and clock control // input clk; // core clock input rst; // core reset // // core-bridge unit interface // input [aw-1:0] cbu_adr_i; // core request address input [dw-1:0] cbu_dat_i; // core request data input cbu_rqt_i; // core request valid input cbu_we_i; // core request w/r flag input [3:0] cbu_sel_i; // core request byte selects output cbu_ack_o; // bus response valid(ack) output cbu_err_o; // bus response error output [dw-1:0] cbu_dat_o; // bus response data output [aw-1:0] cbu_adr_o; // bus response address // // WISHBONE interface // input wb_ack_i; // normal termination input wb_err_i; // termination with error input wb_rty_i; // termination with retry input [dw-1:0] wb_dat_i; // data input output wb_cyc_o; // cycle valid output output [aw-1:0] wb_adr_o; // address output output wb_stb_o; // strobe output output wb_we_o; // indicates write/read transfer output [3:0] wb_sel_o; // byte select output output [dw-1:0] wb_dat_o; // data output output [2:0] wb_cti_o; // cycle type identifier output [1:0] wb_bte_o; // burst type extension // // reg & wires // reg wb_cyc_o; reg [aw-1:0] wb_adr_o; reg wb_stb_o; reg wb_we_o; reg [3:0] wb_sel_o; reg [dw-1:0] wb_dat_o; reg [2:0] wb_cti_o; reg [1:0] wb_bte_o; reg [dw-1:0] cbu_dat_o; reg cbu_ack_o; reg cbu_err_o; reg [aw-1:0] cbu_adr_o; // // logic implementation // // registered request always @(posedge clk or posedge rst) begin if (rst) begin wb_cyc_o <= #1 1'b0; wb_stb_o <= #1 1'b0; wb_dat_o <= #1 32'd0; wb_adr_o <= #1 32'd0; wb_sel_o <= #1 4'd0; wb_we_o <= #1 1'd0; wb_cti_o <= #1 3'd0; wb_bte_o <= #1 2'd0; end else begin if (cbu_rqt_i) begin wb_cyc_o <= #1 cbu_rqt_i; wb_stb_o <= #1 cbu_rqt_i; wb_dat_o <= #1 cbu_dat_i; wb_adr_o <= #1 cbu_adr_i; wb_sel_o <= #1 cbu_sel_i; wb_we_o <= #1 cbu_we_i; wb_cti_o <= #1 `WB_CTI; wb_bte_o <= #1 `WB_BTE; end else begin // when core cancel bus request wb_cyc_o <= #1 1'b0; wb_stb_o <= #1 1'b0; wb_dat_o <= #1 32'd0; wb_adr_o <= #1 32'd0; wb_sel_o <= #1 4'd0; wb_we_o <= #1 1'd0; wb_cti_o <= #1 3'd0; wb_bte_o <= #1 2'd0; end end end // registered request always @(posedge clk or posedge rst) begin if (rst) begin cbu_ack_o <= #1 1'b0; cbu_err_o <= #1 1'b0; end else begin if (cbu_rqt_i) begin cbu_ack_o <= #1 wb_ack_i; cbu_err_o <= #1 wb_err_i; end else begin cbu_ack_o <= #1 1'b0; cbu_err_o <= #1 1'b0; end end end // special case for IMX always @(posedge clk or posedge rst) begin if (rst) begin cbu_dat_o <= #1 32'd0; end else begin cbu_dat_o <= #1 wb_dat_i; end end // special case for IMX always @(posedge clk or posedge rst) begin if (rst) begin cbu_adr_o <= #1 32'd0; end else begin cbu_adr_o <= #1 cbu_adr_i; end end endmodule

// ============================================================== // File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC // Version: 2018.2 // Copyright (C) 1986-2018 Xilinx, Inc. All Rights Reserved. // // ============================================================== `timescale 1 ns / 1 ps module AESL_automem_d ( clk, rst, ce0, we0, address0, din0, dout0, ce1, we1, address1, din1, dout1, ready, done ); //------------------------Parameter---------------------- localparam TV_IN = "c.array_arith.autotvin_d.dat", TV_OUT = "impl_rtl.array_arith.autotvout_d.dat"; //------------------------Local signal------------------- parameter DATA_WIDTH = 32'd 32; parameter ADDR_WIDTH = 32'd 3; parameter DEPTH = 32'd 5; parameter DLY = 0.1; // Input and Output input clk; input rst; input ce0, ce1; input we0, we1; input [ADDR_WIDTH - 1 : 0] address0, address1; input [DATA_WIDTH - 1 : 0] din0, din1; output reg [DATA_WIDTH - 1 : 0] dout0, dout1; input ready; input done; // Inner signals reg [DATA_WIDTH - 1 : 0] mem [0 : DEPTH - 1]; initial begin : initialize_mem integer i; for (i = 0; i < DEPTH; i = i + 1) begin mem[i] = 0; end end reg writed_flag; event write_process_done; //------------------------Task and function-------------- task read_token; input integer fp; output reg [127 :0] token; integer ret; begin token = ""; ret = 0; ret = $fscanf(fp,"%s",token); end endtask //------------------------Read array------------------- // Read data form file to array initial begin : read_file_process integer fp; integer err; integer ret; reg [127 : 0] token; reg [ 8*5 : 1] str; reg [ DATA_WIDTH - 1 : 0 ] mem_tmp; integer transaction_idx; integer i; transaction_idx = 0; wait(rst === 0); @(write_process_done); fp = $fopen(TV_IN,"r"); if(fp == 0) begin // Failed to open file $display("Failed to open file \"%s\"!", TV_IN); $finish; end read_token(fp, token); if (token != "[[[runtime]]]") begin // Illegal format $display("ERROR: Simulation using HLS TB failed."); $finish; end read_token(fp, token); while (token != "[[[/runtime]]]") begin if (token != "[[transaction]]") begin $display("ERROR: Simulation using HLS TB failed."); $finish; end read_token(fp, token); // skip transaction number while(ready == 0) begin @(write_process_done); end for(i = 0; i < DEPTH; i = i + 1) begin read_token(fp, token); ret = $sscanf(token, "0x%x", mem_tmp); mem[i] = mem_tmp; if (ret != 1) begin $display("Failed to parse token!"); $finish; end end @(write_process_done); read_token(fp, token); if(token != "[[/transaction]]") begin $display("ERROR: Simulation using HLS TB failed."); $finish; end read_token(fp, token); transaction_idx = transaction_idx + 1; end $fclose(fp); end // Read data from array to RTL always @ (posedge clk or rst) begin if(rst === 1) begin dout0 <= 0; end else begin if((we0 == 0) && (ce0 == 1) && (ce1 == 1) && (we1 == 1) && (address0 == address1)) dout0 <= #DLY din1; else if(ce0 == 1) dout0 <= #DLY mem[address0]; else ; end end always @ (posedge clk or rst) begin if(rst === 1) begin dout1 <= 0; end else begin if((we0 == 1) && (ce0 == 1) && (ce1 == 1) && (we1 == 0) && (address0 == address1)) dout1 <= #DLY din0; else if(ce1 == 1) dout1 <= #DLY mem[address1]; else ; end end //------------------------Write array------------------- // Write data from RTL to array always @ (posedge clk) begin if((we0 == 1) && (ce0 == 1) && (ce1 == 1) && (we1 == 1) && (address0 == address1)) mem[address0] <= #DLY din1; else if ((we0 == 1) && (ce0 == 1)) mem[address0] <= #DLY din0; end always @ (posedge clk) begin if((ce1 == 1) && (we1 == 1)) mem[address1] <= #DLY din1; end // Write data from array to file initial begin : write_file_proc integer fp; integer transaction_num; reg [ 8*5 : 1] str; integer i; transaction_num = 0; writed_flag = 1; wait(rst === 0); @(negedge clk); while(1) begin while(done == 0) begin -> write_process_done; @(negedge clk); end fp = $fopen(TV_OUT, "a"); if(fp == 0) begin // Failed to open file $display("Failed to open file \"%s\"!", TV_OUT); $finish; end $fdisplay(fp, "[[transaction]] %d", transaction_num); for (i = 0; i < DEPTH; i = i + 1) begin $fdisplay(fp,"0x%x",mem[i]); end $fdisplay(fp, "[[/transaction]]"); transaction_num = transaction_num + 1; $fclose(fp); writed_flag = 1; -> write_process_done; @(negedge clk); end end //------------------------conflict check------------------- always @ (posedge clk) begin if ((we0 == 1) && (ce0 == 1) && (ce1 == 1) && (we1 == 1) && (address0 == address1)) $display($time,"WARNING:write conflict----port0 and port1 write to the same address:%h at the same clock. Port1 has the high priority.",address0); end always @ (posedge clk) begin if ((we0 == 1) && (ce0 == 1) && (ce1 == 1) && (we1 == 0) && (address0 == address1)) $display($time,"NOTE:read & write conflict----port0 write and port1 read to the same address:%h at the same clock. Write first Mode.",address0); end always @ (posedge clk) begin if ((we0 == 0) && (ce0 == 1) && (ce1 == 1) && (we1 == 1) && (address0 == address1)) $display($time,"NOTE:read & write conflict----port0 read and port1 write to the same address:%h at the same clock. Write first Mode.",address0); end endmodule

// synthesis translate_off // synthesis translate_on // synthesis verilog_input_version verilog_2001 // turn off superfluous verilog processor warnings // altera message_level Level1 // altera message_off 10034 10035 10036 10037 10230 10240 10030 //----------------------------------------------------------------------------- // Title : PCI Express Reference Design Example Application // Project : PCI Express MegaCore function //----------------------------------------------------------------------------- // File : altpcierd_cdma_ecrc_check_128.v // Author : Altera Corporation //----------------------------------------------------------------------------- // Description : // This module performs the PCIE ECRC check on the 128-bit Avalon-ST RX data stream. //----------------------------------------------------------------------------- // Copyright (c) 2009 Altera Corporation. All rights reserved. Altera products are // protected under numerous U.S. and foreign patents, maskwork rights, copyrights and // other intellectual property laws. // // This reference design file, and your use thereof, is subject to and governed by // the terms and conditions of the applicable Altera Reference Design License Agreement. // By using this reference design file, you indicate your acceptance of such terms and // conditions between you and Altera Corporation. In the event that you do not agree with // such terms and conditions, you may not use the reference design file. Please promptly // destroy any copies you have made. // // This reference design file being provided on an "as-is" basis and as an accommodation // and therefore all warranties, representations or guarantees of any kind // (whether express, implied or statutory) including, without limitation, warranties of // merchantability, non-infringement, or fitness for a particular purpose, are // specifically disclaimed. By making this reference design file available, Altera // expressly does not recommend, suggest or require that this reference design file be // used in combination with any other product not provided by Altera. //----------------------------------------------------------------------------- module altpcierd_cdma_ecrc_check_128 ( input clk_in, input srst, input[139:0] rxdata, input[15:0] rxdata_be, input rx_stream_valid0, output rx_stream_ready0_ecrc, output reg [139:0] rxdata_ecrc, output reg [15:0] rxdata_be_ecrc, output reg rx_stream_valid0_ecrc, input rx_stream_ready0, output reg rx_ecrc_check_valid, output reg [15:0] ecrc_bad_cnt ); localparam RAM_DATA_WIDTH = 140; localparam RAM_ADDR_WIDTH = 8; localparam PIPELINE_DEPTH =4; // Bits in rxdata localparam SOP_BIT = 139; localparam EOP_BIT = 136; localparam EMPTY_BIT = 137; wire rx_sop; reg rx_sop_crc_in; wire rx_eop; reg rx_eop_reg; reg rx_eop_crc_in; reg [3:0] rx_empty; wire [31:0] crc_32; wire crcbad; wire crcvalid; // Set TLP length reg [9:0] ctrlrx_cnt_len_dw; reg [9:0] ctrlrx_cnt_len_dw_reg; // Set when TLP is 3 DW header wire ctrlrx_payload; reg ctrlrx_payload_reg; // Set when TLP is 3 DW header wire ctrlrx_3dw; reg ctrlrx_3dw_reg; // Set when TLP are qword aligned wire ctrlrx_qword_aligned; reg ctrlrx_qword_aligned_reg; // Set when the TD digest bit is set in the descriptor wire ctrlrx_digest; reg ctrlrx_digest_reg; reg [PIPELINE_DEPTH-1:0] ctrlrx_digest_pipe; reg[139:0] rxdata_pipeline [PIPELINE_DEPTH-1:0]; reg[15:0] rxdata_be_pipeline [PIPELINE_DEPTH-1:0]; reg[PIPELINE_DEPTH-1:0] rx_stream_valid_pipeline; wire ctrlrx_3dw_aligned; reg ctrlrx_3dw_aligned_reg; wire ctrlrx_3dw_nonaligned; reg ctrlrx_3dw_nonaligned_reg; wire ctrlrx_4dw_non_aligned; reg ctrlrx_4dw_non_aligned_reg; wire ctrlrx_4dw_aligned; reg ctrlrx_4dw_aligned_reg; reg ctrlrx_single_cycle_reg; integer i; reg [127:0] rxdata_crc_reg ; wire rx_valid_crc_in ; wire [127:0] rxdata_byte_swap ; wire [127:0] rxdata_crc_in ; wire ctrlrx_single_cycle; reg [10:0] rx_payld_remain_dw; wire [10:0] rx_payld_len; reg rx_valid_crc_pending; reg single_crc_cyc; reg send_rx_eop_crc_early; reg debug_ctrlrx_4dw_offset0; reg debug_ctrlrx_4dw_offset1; reg debug_ctrlrx_4dw_offset2; reg debug_ctrlrx_4dw_offset3; reg debug_ctrlrx_3dw_offset0; reg debug_ctrlrx_3dw_offset1; reg debug_ctrlrx_3dw_offset2; reg debug_ctrlrx_3dw_offset3; reg debug_ctrlrx_4dw_offset0_nopayld; reg debug_ctrlrx_4dw_offset1_nopayld; reg debug_ctrlrx_4dw_offset2_nopayld; reg debug_ctrlrx_4dw_offset3_nopayld; reg debug_ctrlrx_3dw_offset0_nopayld; reg debug_ctrlrx_3dw_offset1_nopayld; reg debug_ctrlrx_3dw_offset2_nopayld; reg debug_ctrlrx_3dw_offset3_nopayld; wire[11:0] zeros12; assign zeros12 = 12'h0; wire[7:0] zeros8; assign zeros8 = 8'h0; wire[3:0] zeros4; assign zeros4 = 4'h0; wire[15:0] rxdata_be_15_12; assign rxdata_be_15_12 = {rxdata_be[15:12], zeros12}; wire[15:0] rxdata_be_15_8; assign rxdata_be_15_8 = {rxdata_be[15:8], zeros8}; wire[15:0] rxdata_be_15_4; assign rxdata_be_15_4 = {rxdata_be[15:4], zeros4}; //////////////////////////////////////////////////////////////////////////// // // Drop ECRC field from the data stream/rx_be. // Regenerate rx_st_eop. // Set TD bit to 0. // assign rx_payld_len = (rxdata[105:96] == 0) ? 11'h400 : {1'b0, rxdata[105:96]}; // account for 1024DW always @ (posedge clk_in ) begin if (srst==1'b1) begin rxdata_ecrc <= 140'h0; rxdata_be_ecrc <= 16'h0; rx_payld_remain_dw <= 11'h0; rx_stream_valid0_ecrc <= 1'b0; end else begin rxdata_ecrc[138] <= 1'b0; rx_stream_valid0_ecrc <= 1'b0; // default ///////////////////////// // TLP has Digest // if (ctrlrx_digest==1'b1) begin if (rx_sop==1'b1) begin rxdata_ecrc[111] <= 1'b0; rxdata_ecrc[135:112] <= rxdata[135:112]; rxdata_ecrc[110:0] <= rxdata[110:0]; rxdata_ecrc[SOP_BIT] <= 1'b1; rxdata_ecrc[EOP_BIT] <= (rxdata[126]==1'b0) | ((ctrlrx_3dw==1'b1) & (ctrlrx_qword_aligned==1'b0) & (rxdata[105:96]==10'h1)); rxdata_ecrc[EMPTY_BIT] <= 1'b0; rxdata_be_ecrc <= rxdata_be; rx_stream_valid0_ecrc <= 1'b1; // Load the # of payld DWs remaining in next cycles if (rxdata[126]==1'b1) begin // if there is payload if ((ctrlrx_3dw==1'b1) & (ctrlrx_qword_aligned==1'b0)) begin rx_payld_remain_dw <= rx_payld_len - 1; end // 3DW aligned, or 4DW nonaligned // Add 1 DW to account for empty field else if ( //((ctrlrx_3dw==1'b1) & (ctrlrx_qword_aligned==1'b1)) | ((ctrlrx_3dw==1'b0) & (ctrlrx_qword_aligned==1'b0)) ) begin rx_payld_remain_dw <= rx_payld_len + 1; end else begin rx_payld_remain_dw <= rx_payld_len; end end else begin rx_payld_remain_dw <= 11'h0; end end else if (rx_stream_valid0==1'b1) begin rxdata_ecrc[SOP_BIT] <= 1'b0; rxdata_ecrc[135:0] <= rxdata[135:0]; case (rx_payld_remain_dw) 11'h1: begin rxdata_ecrc[EOP_BIT] <= 1'b1; rxdata_ecrc[EMPTY_BIT] <= 1'b1; rxdata_be_ecrc <= rxdata_be_15_12; end 11'h2: begin rxdata_ecrc[EOP_BIT] <= 1'b1; rxdata_ecrc[EMPTY_BIT] <= 1'b1; rxdata_be_ecrc <= rxdata_be_15_8; end 11'h3: begin rxdata_ecrc[EOP_BIT] <= 1'b1; rxdata_ecrc[EMPTY_BIT] <= 1'b0; rxdata_be_ecrc <= rxdata_be_15_4; end 11'h4: begin rxdata_ecrc[EOP_BIT] <= 1'b1; rxdata_ecrc[EMPTY_BIT] <= 1'b0; rxdata_be_ecrc <= rxdata_be[15:0]; end default: begin rxdata_ecrc[EOP_BIT] <= 1'b0; rxdata_ecrc[EMPTY_BIT] <= 1'b0; rxdata_be_ecrc <= rxdata_be[15:0]; end endcase rx_stream_valid0_ecrc <= (rx_payld_remain_dw > 11'h0) ? 1'b1 : 1'b0; // Decrement payld count as payld is received rx_payld_remain_dw <= (rx_payld_remain_dw < 4) ? 11'h0 : rx_payld_remain_dw - 11'h4; end end /////////////// // No Digest // else begin rxdata_ecrc <= rxdata; rxdata_be_ecrc <= rxdata_be; rx_stream_valid0_ecrc <= rx_stream_valid0; end end end //////////////////////////////////////////////////////////////////////////// // // RX Avalon-ST input delayed of PIPELINE_DEPTH to RX Avalon-ST output // assign rx_stream_ready0_ecrc = rx_stream_ready0; //////////////////////////////////////////////////////////////////////////// // // CRC MegaCore instanciation // altpcierd_rx_ecrc_128 rx_ecrc_128 ( .reset_n (~srst), .clk (clk_in), .data (rxdata_crc_in[127:0]), .datavalid (ctrlrx_digest_reg & rx_valid_crc_in), // use registered version of ctrlrx_digest since crc_in is delayed 1 cycle from input .startofpacket (rx_sop_crc_in), .endofpacket (rx_eop_crc_in), .empty (rx_empty), .crcbad (crcbad), .crcvalid (crcvalid)); assign rx_valid_crc_in = (rx_sop_crc_in & (ctrlrx_single_cycle | rx_stream_valid0)) | (rx_valid_crc_pending & rx_stream_valid0) | (rx_eop_crc_in & ~send_rx_eop_crc_early); // Inputs to the MegaCore always @(posedge clk_in) begin if (srst==1'b1) begin rx_valid_crc_pending <= 1'b0; rx_sop_crc_in <= 1'b0; rx_eop_crc_in <= 1'b0; rx_empty <= 1'b0; send_rx_eop_crc_early <= 1'b0; ctrlrx_3dw_aligned_reg <= 1'b0; ctrlrx_3dw_nonaligned_reg <= 1'b0; ctrlrx_4dw_non_aligned_reg <= 1'b0; ctrlrx_4dw_aligned_reg <= 1'b0; debug_ctrlrx_4dw_offset0 <= 1'b0; debug_ctrlrx_4dw_offset1 <= 1'b0; debug_ctrlrx_4dw_offset2 <= 1'b0; debug_ctrlrx_4dw_offset3 <= 1'b0; debug_ctrlrx_3dw_offset0 <= 1'b0; debug_ctrlrx_3dw_offset1 <= 1'b0; debug_ctrlrx_3dw_offset2 <= 1'b0; debug_ctrlrx_3dw_offset3 <= 1'b0; debug_ctrlrx_4dw_offset0_nopayld <= 1'b0; debug_ctrlrx_4dw_offset1_nopayld <= 1'b0; debug_ctrlrx_4dw_offset2_nopayld <= 1'b0; debug_ctrlrx_4dw_offset3_nopayld <= 1'b0; debug_ctrlrx_3dw_offset0_nopayld <= 1'b0; debug_ctrlrx_3dw_offset1_nopayld <= 1'b0; debug_ctrlrx_3dw_offset2_nopayld <= 1'b0; debug_ctrlrx_3dw_offset3_nopayld <= 1'b0; end else begin if ((rx_sop==1'b1) & (rx_stream_valid0==1'b1) & (ctrlrx_digest==1'b1) ) begin rx_sop_crc_in <= 1'b1; end else if ((rx_sop_crc_in==1'b1) & (rx_valid_crc_in==1'b1)) begin rx_sop_crc_in <= 1'b0; end ctrlrx_3dw_aligned_reg <= ctrlrx_3dw_aligned; ctrlrx_3dw_nonaligned_reg <= ctrlrx_3dw_nonaligned; ctrlrx_4dw_non_aligned_reg <= ctrlrx_4dw_non_aligned; ctrlrx_4dw_aligned_reg <= ctrlrx_4dw_aligned; if ((rx_stream_valid0==1'b1) & (rx_sop==1'b1)) begin debug_ctrlrx_4dw_offset0 <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b1) & (rxdata[3:0]==4'h0); // no addr offset debug_ctrlrx_4dw_offset1 <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b1) & (rxdata[3:0]==4'h4); // 1DW addr offset debug_ctrlrx_4dw_offset2 <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b1) & (rxdata[3:0]==4'h8); // 2DW addr offset debug_ctrlrx_4dw_offset3 <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b1) & (rxdata[3:0]==4'hc); // 3DW addr offset debug_ctrlrx_3dw_offset0 <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b1) & (rxdata[35:32]==4'h0); // no addr offset debug_ctrlrx_3dw_offset1 <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b1) & (rxdata[35:32]==4'h4); // 1DW addr offset debug_ctrlrx_3dw_offset2 <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b1) & (rxdata[35:32]==4'h8); // 2DW addr offset debug_ctrlrx_3dw_offset3 <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b1) & (rxdata[35:32]==4'hc); // 3DW addr offset debug_ctrlrx_4dw_offset0_nopayld <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b0) & (rxdata[3:0]==4'h0); // no addr offset debug_ctrlrx_4dw_offset1_nopayld <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b0) & (rxdata[3:0]==4'h4); // 1DW addr offset debug_ctrlrx_4dw_offset2_nopayld <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b0) & (rxdata[3:0]==4'h8); // 2DW addr offset debug_ctrlrx_4dw_offset3_nopayld <= (ctrlrx_3dw==1'b0) & (rxdata[126]==1'b0) & (rxdata[3:0]==4'hc); // 3DW addr offset debug_ctrlrx_3dw_offset0_nopayld <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b0) & (rxdata[35:32]==4'h0); // no addr offset debug_ctrlrx_3dw_offset1_nopayld <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b0) & (rxdata[35:32]==4'h4); // 1DW addr offset debug_ctrlrx_3dw_offset2_nopayld <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b0) & (rxdata[35:32]==4'h8); // 2DW addr offset debug_ctrlrx_3dw_offset3_nopayld <= (ctrlrx_3dw==1'b1) & (rxdata[126]==1'b0) & (rxdata[35:32]==4'hc); // 3DW addr offset end if ((rx_sop==1'b1) & (rx_stream_valid0==1'b1) & (ctrlrx_digest==1'b1)) begin if ((ctrlrx_3dw==1'b1) & (ctrlrx_payload==1'b0)) begin rx_eop_crc_in <= 1'b1; // Pack ECRC into single cycle rx_empty <= 1'b0; rx_valid_crc_pending <= 1'b0; end else begin rx_eop_crc_in <= 1'b0; // multicycle rx_empty <= 1'b0; rx_valid_crc_pending <= 1'b1; // eop is sent 1 cycle early when the payld is a multiple // of 4DWs, and the TLP is 3DW Header aligned send_rx_eop_crc_early <= (ctrlrx_3dw_aligned==1'b1) & (ctrlrx_payload==1'b1) & (rxdata[97:96]==2'h0); end end else if (rx_valid_crc_pending == 1'b1) begin // end crc data early if (send_rx_eop_crc_early==1'b1) begin rx_valid_crc_pending <= ((ctrlrx_cnt_len_dw == 10'h0) & (rx_stream_valid0==1'b1)) ? 1'b0 : 1'b1; if ((ctrlrx_cnt_len_dw == 10'h4)& (rx_stream_valid0==1'b1)) begin rx_eop_crc_in <= 1'b1; rx_empty <= 4'h0; end end // end on eop else begin // rx_valid_crc_pending <= (rx_eop_crc_in==1'b1) ? 1'b0 : rx_valid_crc_pending; if ((rx_eop==1'b1) & (rx_stream_valid0==1'b1)) begin rx_eop_crc_in <= 1'b1; rx_valid_crc_pending <= 1'b0; case (ctrlrx_cnt_len_dw) 10'h1: rx_empty <= 4'hc; 10'h2: rx_empty <= 4'h8; 10'h3: rx_empty <= 4'h4; default: rx_empty <= 4'h0; endcase end end end else begin rx_eop_crc_in <= 1'b0; rx_empty <= 4'h0; end end end // rxdata_byte_swap is : // - Set variant bit to 1 The EP field is variant // - Byte swap the data and not the header // - The header is already byte order ready for the CRC (lower byte first) such as : // | H0 byte 0,1,2,3 // rxdata[127:0] | H1 byte 4,5,6,7 // | H2 byte 8,9,10,11 // | H3 byte 12,13,14,15 // - The Data requires byte swaping // rxdata // always @(posedge clk_in) begin if (rx_stream_valid0==1'b1) begin if (ctrlrx_3dw_aligned==1'b1) begin if (rx_sop==1'b1) begin rxdata_crc_reg[127:121] <= rxdata[127:121]; rxdata_crc_reg[120] <= 1'b1; rxdata_crc_reg[119:111] <= rxdata[119:111]; rxdata_crc_reg[110] <= 1'b1; rxdata_crc_reg[109:0] <= rxdata[109:0]; end else rxdata_crc_reg[127:0] <= { rxdata[71:64 ], rxdata[79 : 72], rxdata[87 : 80], rxdata[95 : 88], //D1 rxdata[39:32 ], rxdata[47 : 40], rxdata[55 : 48], rxdata[63 : 56], // D2 rxdata[7:0 ], rxdata[15 : 8], rxdata[23 : 16], rxdata[31 : 24], // D3 rxdata[103:96], rxdata[111:104], rxdata[119:112], rxdata[127:120]}; // D0 end else if (ctrlrx_4dw_non_aligned==1'b1) begin if (rx_sop==1'b1) begin rxdata_crc_reg[127:121] <= rxdata[127:121]; rxdata_crc_reg[120] <= 1'b1; rxdata_crc_reg[119:111] <= rxdata[119:111]; rxdata_crc_reg[110] <= 1'b1; rxdata_crc_reg[109:0] <= rxdata[109:0]; end else begin rxdata_crc_reg[127:0] <= { rxdata[71:64 ], rxdata[79 : 72], rxdata[87 : 80], rxdata[95 : 88], //D1 rxdata[39:32 ], rxdata[47 : 40], rxdata[55 : 48], rxdata[63 : 56], // D2 rxdata[7:0 ], rxdata[15 : 8], rxdata[23 : 16], rxdata[31 : 24], // D3 rxdata[103:96], rxdata[111:104], rxdata[119:112], rxdata[127:120]}; // D0 end end else if (ctrlrx_4dw_aligned==1'b1) begin if (rx_sop==1'b1) begin rxdata_crc_reg[127:121] <= rxdata[127:121]; rxdata_crc_reg[120] <= 1'b1; rxdata_crc_reg[119:111] <= rxdata[119:111]; rxdata_crc_reg[110] <= 1'b1; rxdata_crc_reg[109:0] <= rxdata[109:0]; end else begin rxdata_crc_reg[127:0] <= { rxdata[103:96], rxdata[111:104], rxdata[119:112], rxdata[127:120], // D0 rxdata[71:64 ], rxdata[79 : 72], rxdata[87 : 80], rxdata[95 : 88], //D1 rxdata[39:32 ], rxdata[47 : 40], rxdata[55 : 48], rxdata[63 : 56], // D2 rxdata[7:0 ], rxdata[15 : 8], rxdata[23 : 16], rxdata[31 : 24] // D3 }; end end else // 3DW nonaligned if (rx_sop==1'b1) begin rxdata_crc_reg[127:121] <= rxdata[127:121]; rxdata_crc_reg[120] <= 1'b1; rxdata_crc_reg[119:111] <= rxdata[119:111]; rxdata_crc_reg[110] <= 1'b1; rxdata_crc_reg[109:32] <= rxdata[109:32]; if (ctrlrx_3dw==1'b1) begin // 3 DWORD Header with payload byte swapping the first data D0 rxdata_crc_reg[31:24] <= rxdata[7:0]; rxdata_crc_reg[23:16] <= rxdata[15:8]; rxdata_crc_reg[15:8] <= rxdata[23:16]; rxdata_crc_reg[7:0] <= rxdata[31:24]; end else // 4 DWORD Header no need to swap bytes rxdata_crc_reg[31:0] <= rxdata[31:0]; end else rxdata_crc_reg[127:0] <= { rxdata[103:96], rxdata[111:104], rxdata[119:112], rxdata[127:120], rxdata[71 :64], rxdata[79 :72 ], rxdata[87 :80 ], rxdata[95 : 88], rxdata[39 :32], rxdata[47 :40 ], rxdata[55 :48 ], rxdata[63 : 56], rxdata[7 :0 ], rxdata[15 : 8 ], rxdata[23 :16 ], rxdata[31 : 24]}; end end assign rxdata_crc_in[127:0] = (ctrlrx_3dw_aligned_reg==1'b1) ? {rxdata_crc_reg[127:32], // previous 3DW rxdata[103:96 ], // current DW (byte flipped) rxdata[111:104], rxdata[119:112], rxdata[127:120]} : ((ctrlrx_4dw_non_aligned_reg==1'b1) & (rx_sop_crc_in==1'b0)) ? {rxdata_crc_reg[127:32], // previous 3DW rxdata[103:96 ], // current DW (byte flipped) rxdata[111:104], rxdata[119:112], rxdata[127:120]} : rxdata_crc_reg[127:0]; ////////////////////////////////////////////////////////////////////////// // // BAD ECRC Counter output (ecrc_bad_cnt // always @(posedge clk_in) begin if (srst==1'b1) begin rx_ecrc_check_valid <= 1'b1; ecrc_bad_cnt <= 0; end else if ((crcvalid==1'b1) && (crcbad==1'b1)) begin if (ecrc_bad_cnt<16'hFFFF) ecrc_bad_cnt <= ecrc_bad_cnt+1; if (rx_ecrc_check_valid==1'b1) rx_ecrc_check_valid <= 1'b0; end end //////////////////////////////////////////////////////////////////////////// // // Misc. Avalon-ST control signals // assign rx_sop = ((rxdata[139]==1'b1) && (rx_stream_valid0==1'b1))?1'b1:1'b0; assign rx_eop = ((rxdata[136]==1'b1) && (rx_stream_valid0==1'b1))?1'b1:1'b0; always @(posedge clk_in) begin if (srst==1'b1) begin ctrlrx_3dw_reg <=1'b0; ctrlrx_qword_aligned_reg <=1'b0; ctrlrx_digest_reg <=1'b0; ctrlrx_single_cycle_reg <= 1'b0; ctrlrx_payload_reg <=1'b0; end else begin ctrlrx_3dw_reg <=ctrlrx_3dw; ctrlrx_qword_aligned_reg <= ctrlrx_qword_aligned; ctrlrx_digest_reg <=ctrlrx_digest; ctrlrx_single_cycle_reg <= ctrlrx_single_cycle; ctrlrx_payload_reg <= ctrlrx_payload; end end assign ctrlrx_single_cycle = (rx_sop==1'b1) ? ((rx_eop==1'b1) ? 1'b1 : 1'b0) : ctrlrx_single_cycle_reg; // ctrlrx_payload is set when the TLP has payload assign ctrlrx_payload = (rx_sop==1'b1) ? ( (rxdata[126]==1'b1) ? 1'b1 : 1'b0) : ctrlrx_payload_reg; // ctrlrx_3dw is set when the TLP has 3 DWORD header assign ctrlrx_3dw = (rx_sop==1'b1) ? ((rxdata[125]==1'b0) ? 1'b1 : 1'b0) : ctrlrx_3dw_reg; // ctrlrx_qword_aligned is set when the data are address aligned assign ctrlrx_qword_aligned = (rx_sop==1'b1)? (( ((ctrlrx_3dw==1'b1) && (rxdata[34:32]==0)) || ((ctrlrx_3dw==1'b0) && (rxdata[2:0]==0)) ) ? 1'b1: 1'b0 ) : ctrlrx_qword_aligned_reg; assign ctrlrx_digest = (rx_sop==1'b1) ? rxdata[111]:ctrlrx_digest_reg; assign ctrlrx_3dw_aligned = ((ctrlrx_3dw==1'b1) && (ctrlrx_qword_aligned==1'b1))?1'b1:1'b0; assign ctrlrx_3dw_nonaligned = ((ctrlrx_3dw==1'b1) && (ctrlrx_qword_aligned==1'b0))?1'b1:1'b0; assign ctrlrx_4dw_non_aligned = ((ctrlrx_3dw==1'b0) && (ctrlrx_qword_aligned==1'b0))?1'b1:1'b0; assign ctrlrx_4dw_aligned = ((ctrlrx_3dw==1'b0) && (ctrlrx_qword_aligned==1'b1))?1'b1:1'b0; always @(posedge clk_in) begin // ctrlrx_cnt_len_dw counts the number remaining // number of DWORD in rxdata_crc_reg ctrlrx_cnt_len_dw_reg <= (rx_stream_valid0) ? ctrlrx_cnt_len_dw : ctrlrx_cnt_len_dw_reg; if (srst==1'b1) ctrlrx_cnt_len_dw <= 0; else if (rx_sop==1'b1) begin single_crc_cyc <= 1'b0; // default if (rxdata[126]==1'b0) begin // No payload if (ctrlrx_3dw==1'b1) begin ctrlrx_cnt_len_dw <= 0; // 1DW ECRC, subtract 1 since ECRC is packed with descriptor. single_crc_cyc <= 1'b1; end else ctrlrx_cnt_len_dw <= 1; end else if (ctrlrx_3dw==1'b0) ctrlrx_cnt_len_dw <= rxdata[105:96] + 1; // Add ECRC field. else ctrlrx_cnt_len_dw <= rxdata[105:96]; // Add ECRC field. end else if (rx_stream_valid0) begin if (ctrlrx_cnt_len_dw>3) ctrlrx_cnt_len_dw <= ctrlrx_cnt_len_dw-4; else if (ctrlrx_cnt_len_dw>2) ctrlrx_cnt_len_dw <= ctrlrx_cnt_len_dw-3; else if (ctrlrx_cnt_len_dw>1) ctrlrx_cnt_len_dw <= ctrlrx_cnt_len_dw-2; else if (ctrlrx_cnt_len_dw>0) ctrlrx_cnt_len_dw <= ctrlrx_cnt_len_dw-1; end end // for internal monitoring assign crc_32 = (rx_eop_crc_in==1'b0)?0: (ctrlrx_cnt_len_dw_reg[1:0]==0)? rxdata_crc_in[127:96]: (ctrlrx_cnt_len_dw_reg[1:0]==1)? rxdata_crc_in[95:64]: (ctrlrx_cnt_len_dw_reg[1:0]==2)? rxdata_crc_in[63:32]: rxdata_crc_in[31:0]; endmodule

/* * Simple 8-bit FPGA softcore CPU. * Copyright (C) 2015 P. Heinonen. * Licensed under the MIT License. For more details, read the LICENSE file. * * compiler: Icarus Verilog 0.9.7 * Timing analysis with GTKWave * */ module waterbear( input clk, input rst, output[7:0] PC); // Control Unit stages // Classic RISC type pipeline without MEM stage parameter IF=2'b00; parameter ID=2'b01; parameter EX=2'b10; parameter WB=2'b11; // index for memcopy in store step integer i; // Control Unit registers reg[1:0] control_unit_current; reg[1:0] control_unit_next; // mnemonics of opcodes parameter LDR = 4'b001; // load parameter STR = 4'b010; // store parameter ADD = 4'b011; // add parameter SUB = 4'b100; // substract parameter EQU = 4'b101; // compare equal parameter JMP = 4'b110; // jump parameter HLT = 4'b111; // halt // memory structure reg[15:0] MEM[0:255]; // Main Memory - 16 bit wide 256 memory cells reg[5:0] WORKMEM[0:127]; // ALU intermediate register reg[5:0] DESTMEM[0:127]; // destination register reg[5:0] R1; // accumulator reg[7:0] PC; // program counter reg[7:0] MAR; // Memory Address register reg[15:0] MDR; // Memory Data/Buffer Register reg[15:0] CIR; // Current Instruction Register // instruction set structure reg[4:0] reserved = 5'b00000; reg[3:0] op_code = 0; reg numbit = 0; reg[5:0] operand = 0; /* RAM memory layout contains 256 memorycells which are 16-bit wide to store instruction set. +-----5----+---4----+---1----+---6-----+ INSTRUCTION SET | | | | | STRUCTURE | RESERVED | OPCODE | NUMBIT | OPERAND | | | | | | +----------+--------+--------+---------+ */ // initial cpu bootup initial begin // initialize memory and registers init_regs(); // memory initialization for testbench // Sample program calculates equation: x=5+7; /* MEM[0] = {reserved, LDR, 1'b1, 6'b000101}; //Load value 5 into R1, mcode: 00000 001 1 000010 MEM[1] = {reserved, STR, 1'b0, 6'b001101}; //Store value from R1 in memory addr 13 MEM[2] = {reserved, LDR, 1'b1, 6'b000111}; //Load value 7 into R1 MEM[3] = {reserved, STR, 1'b0, 6'b001110}; //Store value from R1 in memory addr 14 MEM[4] = {reserved, LDR, 1'b0, 6'b001101}; //Load value from memory addr 13 into R1 MEM[5] = {reserved, ADD, 1'b0, 6'b001110}; //Add value from memory addr 14 to R1 MEM[6] = {reserved, STR, 1'b0, 6'b000010}; //Store value from R1 into memory addr 15 MEM[7] = {reserved, HLT, 1'b0, 6'b000000}; //Stop execution */ // Sample program: Counter to count from 0 to some user coded limit, here 5. MEM[0] = {reserved, LDR, 1'b1, 6'b000101}; //set count value to 5 MEM[1] = {reserved, STR, 1'b0, 6'b001111}; //store count value to address 15 MEM[2] = {reserved, LDR, 1'b1, 6'b000000}; //initialize count to zero MEM[3] = {reserved, EQU, 1'b0, 6'b001111}; //check if count is complete, if yes skip next MEM[4] = {reserved, JMP, 1'b1, 6'b000110}; //set PC to 6 MEM[5] = {reserved, HLT, 1'b0, 6'b000000}; //stop program MEM[6] = {reserved, ADD, 1'b1, 6'b000001}; //increment counter in accumulator MEM[7] = {reserved, JMP, 1'b1, 6'b000011}; //set PC to 3 end // clock cycles always @ (clk, rst) begin if(rst) begin init_regs(); end else begin // Control Unit Finite state machine case(control_unit_current) IF: begin MAR = PC; PC = PC +1; MDR = MEM[MAR]; CIR = MDR; control_unit_next=ID; end ID: begin control_unit_next=EX; InstructionDecoder(CIR, op_code, numbit, operand); end EX: begin // execute ALU instructions case(op_code) LDR: begin if(numbit==1) begin R1 = operand; // direct assign end else begin R1 = WORKMEM[operand]; // assign from address end control_unit_next=WB; end STR: begin WORKMEM[operand] = R1; control_unit_next=WB; end ADD: begin if(numbit==1) begin R1=R1+operand; end else begin R1=R1+WORKMEM[operand]; end control_unit_next=WB; end JMP : begin PC=operand; control_unit_next=WB; end EQU: begin if(R1 == WORKMEM[operand]) begin PC=PC+1; end control_unit_next=WB; end HLT: begin control_unit_next=EX; // continue loop end default: begin end endcase end // end of execute ALU instructions WB: begin // Loop is synthesizable: // http://www.lcdm-eng.com/papers/snug13_SNUG-SV-2013_Synthesizable-SystemVerilog_paper.pdf for (i=0; i<127; i=i+1 ) begin DESTMEM[i] <= WORKMEM[i]; end control_unit_next=IF; end default: begin end endcase control_unit_current=control_unit_next; end end // task to initialize registers and memory task init_regs; begin PC = 0; R1 = 0; MDR = 0; MAR = 0; CIR = 0; //WORKMEM = 0; //{0,128'h80}; //DESTMEM = 0; //{0,128'h80}; control_unit_current = IF; numbit = 0; operand = 0; op_code = 0; reserved = 0; end endtask // in execute, Control Unit task InstructionDecoder; input[15:0] CIR; output[3:0] op_code; output numbit; output[5:0] operand; begin op_code= CIR[10:7]; numbit=CIR[6:6]; operand=CIR[5:0]; end endtask endmodule // For the test 4 core test module multicore( input clk, input rst, output[7:0] PC); waterbear core1(clk, reset, PC); waterbear core2(clk, reset, PC); waterbear core3(clk, reset, PC); waterbear core4(clk, reset, PC); endmodule

/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 */ `ifndef SKY130_FD_SC_LP__CLKDLYBUF4S50_PP_SYMBOL_V `define SKY130_FD_SC_LP__CLKDLYBUF4S50_PP_SYMBOL_V /** * clkdlybuf4s50: Clock Delay Buffer 4-stage 0.59um length inner stage * gates. * * Verilog stub (with power pins) for graphical symbol definition * generation. * * WARNING: This file is autogenerated, do not modify directly! */ `timescale 1ns / 1ps `default_nettype none (* blackbox *) module sky130_fd_sc_lp__clkdlybuf4s50 ( //# {{data|Data Signals}} input A , output X , //# {{power|Power}} input VPB , input VPWR, input VGND, input VNB ); endmodule `default_nettype wire `endif // SKY130_FD_SC_LP__CLKDLYBUF4S50_PP_SYMBOL_V

// DESCRIPTION: Verilator: Verilog Test module module t (/*AUTOARG*/ // Inputs clk ); input clk; reg [63:0] d; reg [31:0] c; wire [31:0] q = crc (d, c); reg [31:0] q_r; integer cyc; initial cyc=1; always @ (posedge clk) begin if (cyc!=0) begin cyc <= cyc + 1; q_r <= q; c <= q; d <= {d[62:0], ^d[63:48]}; //$write("%d crc(%x,%x)=%x\n", cyc, d, c, q); if (cyc==1) begin // Assign inputs randomly q_r <= 32'h12345678; c <= 32'h12345678; d <= 64'hffffffff_ffffffff; end if (cyc==2) begin d <= 64'hffffffff_ffffffff; end if (cyc==3) begin d <= 64'hffffffff_ffffffff; end if (cyc==4) begin d <= 64'h50183721_81a04b1a; end if (cyc==5) begin end if (cyc==9) begin if (q !== 32'h38295e96) $stop; $write("*-* All Finished *-*\n"); $finish; end end end function [31:0] crc; input [63:0] di; input [31:0] ci; reg [63:0] drev; begin drev = reverse(di); crc = newcrc(drev, ci); end endfunction function [63:0] reverse; input [63:0] di; integer i; begin reverse = 64'b0; for (i=0; i<64; i=i+1) reverse[i] = di[63-i]; end endfunction function [31:0] newcrc; input [63:0] D; input [31:0] C; reg [31:0] N; reg [31:0] DT; begin N = 32'b0; // Note this isn't a real CRC code; it's been munged for privacy N[0] = D[59]^D[53]^D[52]^D[49]^D[44]^D[41]^D[40]^D[39]^D[37]^D[32]^D[29]^D[26]^D[22]^D[21]^D[20]^D[16]^D[15]^D[14]^D[9]^D[7]^D[0] ^C[29]^C[27]^C[24]^C[23]^C[22]^C[21]^C[19]^C[15]^C[13]^C[10]^C[8]^C[3]^C[1]; N[1] = D[61]^D[57]^D[51]^D[47]^D[43]^D[37]^D[35]^D[32]^D[28]^D[24]^D[22]^D[21]^D[20]^D[16]^D[12]^D[11]^D[10]^D[8]^D[7]^D[6]^D[1]^D[0] ^C[30]^C[27]^C[26]^C[20]^C[16]^C[14]^C[13]^C[11]^C[10]^C[8]^C[5]^C[0]; N[2] = D[63]^D[62]^D[61]^D[60]^D[55]^D[54]^D[52]^D[44]^D[43]^D[42]^D[37]^D[34]^D[33]^D[29]^D[28]^D[25]^D[24]^D[23]^D[22]^D[18]^D[16]^D[15]^D[13]^D[12]^D[11] ^C[31]^C[30]^C[27]^C[22]^C[21]^C[18]^C[15]^C[12]^C[11]^C[10]^C[7]; N[3] = D[62]^D[54]^D[50]^D[47]^D[46]^D[38]^D[36]^D[35]^D[34]^D[33]^D[32]^D[30]^D[27]^D[25]^D[21]^D[20]^D[19]^D[17]^D[15]^D[11]^D[8]^D[5]^D[3]^D[1]^D[0] ^C[28]^C[25]^C[24]^C[13]^C[11]^C[9]^C[8]^C[7]^C[3]^C[1]; N[4] = D[57]^D[54]^D[53]^D[52]^D[45]^D[44]^D[43]^D[39]^D[37]^D[34]^D[33]^D[32]^D[31]^D[28]^D[24]^D[23]^D[20]^D[19]^D[15]^D[14]^D[10]^D[6]^D[1]^D[0] ^C[30]^C[24]^C[20]^C[16]^C[14]^C[11]^C[8]^C[7]^C[6]^C[5]^C[2]; N[5] = D[58]^D[57]^D[50]^D[49]^D[48]^D[47]^D[43]^D[39]^D[29]^D[26]^D[23]^D[22]^D[20]^D[18]^D[14]^D[10]^D[9]^D[6]^D[5]^D[4]^D[1] ^C[27]^C[24]^C[20]^C[19]^C[18]^C[14]^C[13]^C[12]^C[11]^C[8]^C[7]^C[1]; N[6] = D[63]^D[62]^D[61]^D[57]^D[51]^D[50]^D[47]^D[38]^D[37]^D[34]^D[30]^D[28]^D[27]^D[25]^D[21]^D[16]^D[15]^D[10]^D[9]^D[6]^D[5]^D[2]^D[1] ^C[31]^C[27]^C[25]^C[16]^C[13]^C[9]^C[8]^C[7]^C[0]; N[7] = ^D[62]^D[61]^D[59]^D[54]^D[52]^D[51]^D[49]^D[46]^D[45]^D[42]^D[41]^D[38]^D[35]^D[29]^D[26]^D[24]^D[15]^D[12]^D[11]^D[9]^D[2]^D[0] ^C[28]^C[27]^C[26]^C[20]^C[19]^C[18]^C[15]^C[12]^C[7]^C[4]; N[8] = D[62]^D[61]^D[60]^D[59]^D[52]^D[50]^D[48]^D[47]^D[46]^D[45]^D[44]^D[42]^D[41]^D[40]^D[30]^D[24]^D[23]^D[22]^D[19]^D[17]^D[11]^D[10]^D[7]^D[6]^D[2] ^C[31]^C[29]^C[27]^C[22]^C[21]^C[19]^C[17]^C[11]^C[9]^C[7]^C[6]; N[9] = D[62]^D[59]^D[58]^D[57]^D[54]^D[51]^D[50]^D[43]^D[41]^D[39]^D[28]^D[25]^D[24]^D[23]^D[22]^D[21]^D[18]^D[16]^D[15]^D[7] ^C[30]^C[29]^C[27]^C[25]^C[23]^C[22]^C[13]^C[12]^C[7]^C[6]^C[5]^C[1]; N[10] = D[61]^D[60]^D[58]^D[56]^D[54]^D[53]^D[51]^D[48]^D[46]^D[43]^D[42]^D[38]^D[37]^D[35]^D[33]^D[31]^D[30]^D[27]^D[26]^D[24]^D[19]^D[10]^D[8]^D[6]^D[1] ^C[31]^C[30]^C[26]^C[25]^C[24]^C[21]^C[16]^C[12]^C[3]^C[2]; N[11] = D[59]^D[57]^D[56]^D[50]^D[49]^D[48]^D[47]^D[46]^D[45]^D[42]^D[41]^D[40]^D[33]^D[32]^D[30]^D[25]^D[21]^D[15]^D[14]^D[13]^D[12]^D[11]^D[5]^D[1] ^C[27]^C[25]^C[24]^C[21]^C[16]^C[12]^C[7]^C[3]^C[2]^C[1]; N[12] = D[62]^D[61]^D[59]^D[58]^D[56]^D[55]^D[53]^D[48]^D[47]^D[44]^D[43]^D[35]^D[31]^D[30]^D[28]^D[24]^D[23]^D[21]^D[14]^D[5]^D[2] ^C[28]^C[26]^C[25]^C[23]^C[22]^C[18]^C[16]^C[15]^C[6]; N[13] = D[63]^D[60]^D[58]^D[57]^D[55]^D[54]^D[53]^D[51]^D[47]^D[45]^D[42]^D[41]^D[38]^D[28]^D[26]^D[25]^D[22]^D[20]^D[18]^D[17]^D[15]^D[13]^D[12]^D[11] ^C[29]^C[28]^C[25]^C[22]^C[19]^C[17]^C[16]^C[15]^C[14]^C[12]^C[10]^C[9]; N[14] = D[58]^D[56]^D[55]^D[52]^D[47]^D[43]^D[41]^D[40]^D[39]^D[38]^D[30]^D[26]^D[25]^D[22]^D[19]^D[17]^D[13]^D[11]^D[10]^D[9]^D[8]^D[3]^D[2]^D[0] ^C[31]^C[28]^C[20]^C[18]^C[17]^C[16]^C[15]^C[13]^C[11]^C[4]^C[2]^C[1]; N[15] = D[63]^D[62]^D[61]^D[59]^D[58]^D[48]^D[47]^D[43]^D[42]^D[35]^D[28]^D[26]^D[25]^D[24]^D[23]^D[22]^D[21]^D[20]^D[19]^D[17]^D[11]^D[7]^D[2] ^C[30]^C[29]^C[27]^C[24]^C[20]^C[17]^C[16]^C[15]^C[11]^C[9]^C[5]; N[16] = D[60]^D[57]^D[49]^D[46]^D[45]^D[43]^D[39]^D[36]^D[32]^D[30]^D[29]^D[28]^D[27]^D[26]^D[23]^D[20]^D[19]^D[17]^D[11]^D[8]^D[5]^D[1] ^C[28]^C[26]^C[23]^C[22]^C[18]^C[16]^C[13]^C[12]^C[10]^C[9]^C[6]; N[17] = D[63]^D[62]^D[61]^D[60]^D[58]^D[54]^D[53]^D[51]^D[48]^D[42]^D[41]^D[37]^D[36]^D[34]^D[28]^D[27]^D[26]^D[24]^D[13]^D[12]^D[9]^D[7]^D[4]^D[0] ^C[31]^C[30]^C[27]^C[23]^C[20]^C[17]^C[14]^C[9]^C[6]^C[4]^C[3]^C[0]; N[18] = D[63]^D[61]^D[59]^D[56]^D[52]^D[50]^D[47]^D[42]^D[37]^D[35]^D[34]^D[31]^D[30]^D[29]^D[22]^D[19]^D[17]^D[16]^D[11]^D[9]^D[8]^D[7] ^C[26]^C[22]^C[20]^C[19]^C[16]^C[11]^C[8]^C[6]^C[5]^C[0]; N[19] = D[62]^D[60]^D[52]^D[49]^D[44]^D[43]^D[42]^D[37]^D[33]^D[32]^D[29]^D[26]^D[19]^D[17]^D[16]^D[12]^D[10]^D[7]^D[6]^D[4]^D[3]^D[2] ^C[30]^C[29]^C[26]^C[25]^C[22]^C[19]^C[14]^C[7]^C[6]^C[5]^C[2]^C[0]; N[20] = D[63]^D[58]^D[54]^D[48]^D[47]^D[40]^D[39]^D[35]^D[34]^D[32]^D[31]^D[28]^D[27]^D[25]^D[18]^D[12]^D[9]^D[7]^D[5]^D[4]^D[3]^D[2]^D[1] ^C[31]^C[29]^C[28]^C[25]^C[19]^C[18]^C[17]^C[15]^C[10]^C[9]^C[6]^C[4]; N[21] = D[61]^D[59]^D[57]^D[56]^D[53]^D[48]^D[44]^D[43]^D[41]^D[35]^D[29]^D[26]^D[25]^D[20]^D[18]^D[17]^D[16]^D[12]^D[9]^D[6]^D[5]^D[3]^D[1] ^C[30]^C[27]^C[24]^C[23]^C[22]^C[21]^C[20]^C[13]^C[9]^C[3]^C[2]; N[22] = D[63]^D[62]^D[60]^D[57]^D[53]^D[51]^D[45]^D[44]^D[42]^D[34]^D[33]^D[27]^D[20]^D[19]^D[18]^D[15]^D[10]^D[9]^D[8]^D[4]^D[3] ^C[24]^C[23]^C[18]^C[17]^C[16]^C[14]^C[12]^C[11]^C[10]^C[9]^C[6]^C[5]; N[23] = D[58]^D[56]^D[54]^D[51]^D[47]^D[43]^D[42]^D[40]^D[37]^D[36]^D[33]^D[25]^D[23]^D[20]^D[18]^D[16]^D[15]^D[12]^D[10]^D[8]^D[7]^D[5]^D[3] ^C[31]^C[27]^C[26]^C[23]^C[21]^C[18]^C[15]^C[11]^C[10]^C[8]^C[7]^C[1]; N[24] = D[60]^D[59]^D[52]^D[50]^D[48]^D[44]^D[39]^D[36]^D[35]^D[31]^D[30]^D[28]^D[27]^D[23]^D[22]^D[21]^D[19]^D[14]^D[13]^D[12]^D[9]^D[4]^D[1]^D[0] ^C[27]^C[25]^C[23]^C[21]^C[17]^C[11]^C[10]^C[4]^C[0]; N[25] = D[61]^D[60]^D[56]^D[54]^D[51]^D[46]^D[43]^D[41]^D[40]^D[38]^D[37]^D[36]^D[29]^D[28]^D[27]^D[22]^D[17]^D[15]^D[10]^D[7]^D[4]^D[2] ^C[29]^C[28]^C[26]^C[23]^C[18]^C[14]^C[13]^C[12]^C[11]^C[9]^C[8]^C[6]; N[26] = D[63]^D[62]^D[58]^D[55]^D[54]^D[52]^D[50]^D[39]^D[37]^D[36]^D[35]^D[33]^D[31]^D[29]^D[27]^D[18]^D[14]^D[10]^D[3]^D[2]^D[0] ^C[31]^C[27]^C[26]^C[25]^C[24]^C[21]^C[13]^C[12]^C[10]^C[1]; N[27] = D[62]^D[60]^D[58]^D[56]^D[55]^D[54]^D[51]^D[44]^D[41]^D[36]^D[34]^D[32]^D[31]^D[29]^D[28]^D[27]^D[23]^D[17]^D[12]^D[11]^D[8]^D[6]^D[4]^D[2] ^C[31]^C[30]^C[28]^C[27]^C[23]^C[19]^C[17]^C[16]^C[14]^C[12]^C[11]^C[10]^C[3]; N[28] = D[57]^D[54]^D[53]^D[51]^D[50]^D[48]^D[40]^D[38]^D[34]^D[33]^D[31]^D[30]^D[29]^D[27]^D[23]^D[21]^D[14]^D[9]^D[7]^D[6]^D[5]^D[4]^D[0] ^C[31]^C[30]^C[26]^C[24]^C[15]^C[14]^C[13]^C[7]^C[6]^C[4]^C[3]^C[0]; N[29] = D[62]^D[60]^D[55]^D[46]^D[45]^D[44]^D[43]^D[41]^D[40]^D[35]^D[33]^D[32]^D[30]^D[28]^D[25]^D[23]^D[22]^D[13]^D[8]^D[7]^D[6]^D[5]^D[4]^D[3]^D[1]^D[0] ^C[31]^C[28]^C[27]^C[18]^C[11]^C[8]^C[6]^C[4]^C[2]^C[1]^C[0]; N[30] = D[63]^D[62]^D[59]^D[58]^D[55]^D[52]^D[47]^D[44]^D[36]^D[35]^D[34]^D[31]^D[29]^D[22]^D[21]^D[20]^D[19]^D[15]^D[14]^D[10]^D[6]^D[3]^D[2]^D[0] ^C[28]^C[25]^C[24]^C[22]^C[20]^C[15]^C[14]^C[12]^C[10]^C[9]^C[4]^C[0]; N[31] = D[61]^D[58]^D[56]^D[55]^D[54]^D[52]^D[51]^D[50]^D[49]^D[42]^D[38]^D[37]^D[36]^D[34]^D[31]^D[30]^D[27]^D[26]^D[23]^D[22]^D[21]^D[19]^D[18]^D[12]^D[0] ^C[28]^C[26]^C[24]^C[21]^C[17]^C[16]^C[14]^C[13]^C[10]^C[8]^C[2]; newcrc = N; end endfunction endmodule

`include "config.v" module A2S_controller( // system reset rst, // stream clk Sclk, // system sync(reset) sync, // Buffer read Oen, Oaddr, obase, osize, oacnt, obcnt, // AXI Bus Signal AXI_clk, AXI_rst_n, AXI_araddr, AXI_arvalid, AXI_arready, AXI_rready, AXI_rvalid, AXI_rlast, // Buffer write a2s_addr, a2s_en ); parameter s0 = 3'd0; parameter s1 = 3'd1; parameter s2 = 3'd2; parameter s3 = 3'd3; input rst,Sclk,sync,Oen; output[4:0] Oaddr; input AXI_clk; input AXI_rst_n; output reg[31:0] AXI_araddr; input AXI_arready,AXI_rvalid; output reg AXI_rready,AXI_arvalid; input AXI_rlast; output reg[4:0] a2s_addr; output a2s_en; reg[21:0] cnt; reg[31:0] bcnt; reg start; wire axi_start; reg [2:0]state; reg [31:0]AXI_araddr_reg; input [31:0]obase; input [23:6]osize; output [23:6]oacnt; output [31:0]obcnt; assign Oaddr = cnt[4:0]; assign oacnt[23:6] = cnt[21:4]; assign obcnt = bcnt; edgesync #(.e("pos")) start_sync ( .clk(AXI_clk) , .async(start) , .sync(axi_start) ); always @(posedge Sclk or posedge rst) begin if( rst==1'b1 ) begin start <= 1'b0; cnt <= 22'h0; bcnt <= 32'h0; end else begin if ( sync==1'b1 ) begin start <= 1'b0; cnt <= 22'h0; bcnt <= 32'h0; end else if( Oen==1'b1 ) begin if( cnt[3:0]==4'hf ) begin AXI_araddr_reg[5:0] <= 6'b000000; AXI_araddr_reg[31:6] <= obase[31:6] + cnt[21:4]; cnt[3:0] <= 4'h0; if( cnt[21:4]==(osize[23:6]-1'b1) ) begin cnt[21:4] <= 18'h0; bcnt <= bcnt + 32'h1; end else cnt[21:4] <= cnt[21:4]+18'h1; end else cnt[3:0] <= cnt[3:0] + 4'h1; end if( Oen==1'b1 && cnt[3:0]==4'hf && start==1'b0 ) start <= 1'b1; else start <= 1'b0; end end assign a2s_en = AXI_rvalid & AXI_rready; always @(posedge AXI_clk) begin if( !AXI_rst_n ) begin a2s_addr <= 5'b00000; AXI_arvalid <= 1'b0; AXI_rready <= 1'b0; AXI_araddr <= obase; state <= s0; end else begin if( axi_start==1'b1 ) begin state <= s1; AXI_araddr <= AXI_araddr_reg; end else begin case( state ) s0 : begin AXI_rready <= AXI_rvalid; end s1 : begin AXI_arvalid <= 1'b1; if( AXI_arready==1'b1 && AXI_arvalid==1'b1 ) begin state <= s2; AXI_arvalid <= 1'b0; a2s_addr[4] <= AXI_araddr[6]; a2s_addr[3:0] <= 4'h0; AXI_rready <= 1'b1; end end s2 : begin if( a2s_en==1'b1 ) begin a2s_addr[3:0] <= a2s_addr[3:0] + 1'b1; if( AXI_rlast==1'b1 ) begin state <= s0; AXI_rready <= 1'b0; end end end endcase end end end endmodule

module datapath ( input CLK, input CLK_MEM, input RESET, input RUN, //Controller iface input WRITE_REG, //write to register file input WRITE_MEM, //write data memory input ALUORMEM_WR, //write regfile from alu or from memory input MEM_PARTIAL, //memory byte- or halfword access input [1:0] MEM_OPTYPE, //mem op: 00-ubyte, 01-uhalf, 10-sb, 11-sh input MULTIPLY, //do multiplication and write hi&lo input BRANCH_E, //branch equal input BRANCH_NE, //branch not equal input BRANCH_LEZ, //branch less than or equal zero input BRANCH_LTZ, //branch less than zero input BRANCH_GEZ, //branch greater than or equal zero input BRANCH_GTZ, //branch greater than zero input JUMP, //j-type jump input JUMP_R, //jr, jalr input ALU_SRC_B, //ALU Operand B 0 - reg_2, 1 - immediate input [6:0] ALU_OP, //ALU Operation select input [1:0] REG_DST, //write destination in regfile (0 - rt, 1 - rd, 1X -- 31) input [1:0] IMMED_EXT, //immediate extension type (sign, zero, swap) input [1:0] MFCOP_SEL, //move from cop sel. 0 - from alu, 1 - from HI, 2 - from LO, 3 -- from C0 output [5:0] OPCODE, //instruction opcode output [5:0] FCODE, //instruction fcode output [4:0] RT, //instruction RT field //External inst memory iface output [29:0] inst_mem_addr, input [31:0] inst_mem_data, //External data memory iface output data_mem_we, output [ 3:0] data_mem_be, output [29:0] data_mem_addr, output [31:0] data_mem_wdata, input [31:0] data_mem_rdata ); //------------------------WIRE DEFINITIONS-----------------------------------// //FETCH: wire [31:0] branch_target, jump_target, jumpr_target, next_pc_reg, pc, pc_plus_4; //DECODE: wire [31:0] inst_d, pc_plus_4_d, rd1, rd2, regfile_wdata, immed_extend_d, immed_extend_sl2_d, rd1_fwd, rd2_fwd; wire [4:0] reg_dst_addr_w, rs_d, rt_d; wire link_d, do_branch, stall, lw_stall, br_stall; //EXECUTE: wire [31:0] pc_plus_4_e, immed_extend_e, src_a_e, src_b_e, src_a_fwd_e, src_b_fwd_e, src_a, src_b, hi_e, lo_e, aluout_e, aluout_mux_e; wire [6:0] alu_op_e; wire [4:0] reg_dst_addr_e, rs_e, rt_e, rd_e, shamt_e; wire [1:0] reg_dst_e, mfcop_sel_e, mem_optype_e; wire write_reg_e, write_mem_e, aluormem_e, multiply_e, alu_src_b_e, link_e, alu_zero, mem_partial_e; //MEM: wire [31:0] aluout_m, src_b_m, mem_reordered_m; wire [4:0] reg_dst_addr_m; wire [1:0] mem_optype_m; wire write_reg_m, write_mem_m, aluormem_m, mem_partial_m; //WRITEBACK: wire [31:0] aluout_w, mem_reordered_w; wire write_reg_w, aluormem_w; //------------------------FETCH STAGE----------------------------------------// assign pc_plus_4 = pc + 4; assign stall = lw_stall | br_stall; assign inst_mem_addr = pc[31:2]; wire [1:0] next_pc_select = JUMP ? 2'b11 : JUMP_R ? 2'b10 : do_branch ? 2'b01 : 2'b00 ; mux4 pc_src_mux( next_pc_select, pc_plus_4, //00: pc = pc + 4 branch_target, //01: conditional branch jumpr_target, //10: from register file jump_target, //11: from j-type instruction next_pc_reg ); ffd pc_reg(CLK, RESET, ~stall & RUN, next_pc_reg, pc ); ffd #(64) pipe_reg_D(CLK, RESET, ~stall & RUN, { inst_mem_data, pc_plus_4 }, { inst_d, pc_plus_4_d }); //---------------------------------------------------------------------------// //------------------------DECODE STAGE---------------------------------------// assign OPCODE = inst_d[31:26]; assign FCODE = inst_d [5:0]; assign RT = inst_d[20:16]; assign rs_d = inst_d[25:21]; assign rt_d = inst_d[20:16]; regfile rf_unit(.CLK (CLK_MEM ), .WE (write_reg_w ), .RD_ADDR_1 (rs_d ), //in_rd_addr .RD_ADDR_2 (rt_d ), //in_rd_addr .WR_ADDR_3 (reg_dst_addr_w ), //in_wr_addr .W_DATA (regfile_wdata ), //in .R_DATA_1 (rd1 ), //out .R_DATA_2 (rd2 )); //out //------IMMEDIATE EXTENSION-------- immed_extend immed_ext_unit(IMMED_EXT, inst_d[15:0], immed_extend_d); //------BRANCH LOGIC------- sl2 shl2_unit(immed_extend_d, immed_extend_sl2_d); wire fwd_br_a = (rs_d != 0) && (rs_d == reg_dst_addr_m) && write_reg_m; wire fwd_br_b = (rt_d != 0) && (rt_d == reg_dst_addr_m) && write_reg_m; mux2 fwd_br_a_mux(fwd_br_a, rd1, //0 -- no forwarding aluout_m, //1 -- forward from MEM rd1_fwd ); mux2 fwd_br_b_mux(fwd_br_b, rd2, //0 -- no forwarding aluout_m, //1 -- forward from MEM rd2_fwd ); wire br_inst = BRANCH_E | BRANCH_NE | BRANCH_LEZ | BRANCH_LTZ | BRANCH_GEZ | BRANCH_GTZ | JUMP | JUMP_R; assign br_stall = (rs_d != 0) & br_inst & ((write_reg_e & ((reg_dst_addr_e == rs_d) | (reg_dst_addr_e == rt_d) )) | (aluormem_m & ((reg_dst_addr_m == rs_d) | //lw (reg_dst_addr_m == rt_d) ))); assign branch_target = immed_extend_sl2_d + pc_plus_4_d; assign jump_target = {pc_plus_4_d[31:28], inst_d[25:0], 2'b00}; assign jumpr_target = rd1_fwd; wire regs_equal = (rd1_fwd == rd2_fwd); wire reg_zero = (rd1_fwd == 0); assign do_branch = ( (BRANCH_E & regs_equal) | (BRANCH_NE & ~regs_equal) | (BRANCH_LEZ & ( rd1_fwd[31] | reg_zero)) | // <= 0 (BRANCH_LTZ & rd1_fwd[31] ) | // < 0 (BRANCH_GEZ & ~rd1_fwd[31] ) | // >= 0 (BRANCH_GTZ & (~rd1_fwd[31] & ~reg_zero)) ); // > 0 assign link_d = JUMP | JUMP_R | BRANCH_GEZ | BRANCH_LTZ; ffd #(168) pipe_reg_E(CLK, RESET | stall, RUN, { WRITE_REG, // 1/ write to register file WRITE_MEM, // 1/ write data memory MEM_PARTIAL, // 1/ memory byte- or halfword access MEM_OPTYPE, // 2/ mem op: 00-ubyte, 01-uhalf, 10-sb, 11-sh ALUORMEM_WR, // 1/ write regfile from alu or from memory MULTIPLY, // 1/ do multiplication and write hi&lo link_d, // 1/ link ALU_SRC_B, // 1/ ALU Operand B 0 - reg_2, 1 - immediate ALU_OP, // 7/ ALU Operation select REG_DST, // 2/ write destination in regfile (0 - rt, 1 - rd) MFCOP_SEL, // 2/ mfrom coprocessor selector rd1, //32/ regfile_out_1 rd2, //32/ regfile_out_2 rs_d, // 5/ RS rt_d, // 5/ RT inst_d[15:11], // 5/ RD inst_d[10:06], // 5/ SHAMT immed_extend_d, //32/ immediate pc_plus_4_d }, //32/ pc plus 4 { write_reg_e, // 1/ write to register file write_mem_e, // 1/ write data memory mem_partial_e, // 1/ memory byte- or halfword access mem_optype_e, // 2/ mem op: 00-ubyte, 01-uhalf, 10-sb, 11-sh aluormem_e, // 1/ write regfile from alu or from memory multiply_e, // 1/ do multiplication and write hi&lo link_e, // 1/ link alu_src_b_e, // 1/ ALU Operand B 0 - reg_2, 1 - immediate alu_op_e, // 7/ ALU Operation select reg_dst_e, // 2/ write destination in regfile (0 - rt, 1 - rd) mfcop_sel_e, // 2/ mfrom coprocessor selector src_a_e, src_b_e, rs_e, rt_e, rd_e, shamt_e, immed_extend_e, pc_plus_4_e }); //---------------------------------------------------------------------------// //------------------------EXECUTE STAGE--------------------------------------// mux4 #(5) regfile_wr_addr_mux( reg_dst_e, rt_e, rd_e, 5'd31, //ra 5'd31, //ra reg_dst_addr_e); //forwarding mux's wire [1:0] fwd_a = ((rs_e != 0) && (rs_e == reg_dst_addr_m) && write_reg_m) ? 2'b10 : ((rs_e != 0) && (rs_e == reg_dst_addr_w) && write_reg_w) ? 2'b01 : 2'b00; wire [1:0] fwd_b = ((rt_e != 0) && (rt_e == reg_dst_addr_m) && write_reg_m) ? 2'b10 : ((rt_e != 0) && (rt_e == reg_dst_addr_w) && write_reg_w) ? 2'b01 : 2'b00; //lw stall logic assign lw_stall = aluormem_e & ((rs_d == rt_e) | (rt_d == rt_e) ); mux4 fwd_src_a(fwd_a, src_a_e, //00 -- no forwarding regfile_wdata, //01 -- forward from WB aluout_m, //10 -- forward from MEM src_a_e, //11 -- no forwarding src_a_fwd_e ); mux4 fwd_src_b(fwd_b, src_b_e, //00 -- no forwarding regfile_wdata, //01 -- forward from WB aluout_m, //10 -- forward from MEM src_b_e, //11 -- no forwarding src_b_fwd_e ); //final alu muxes mux2 alu_src_a_mux( link_e, src_a_fwd_e, pc_plus_4_e, src_a ); mux4 alu_src_b_mux( {link_e, alu_src_b_e}, src_b_fwd_e, //00: forwarded src b immed_extend_e, //01: immediate 32'd4, //10: 4 for ret_addr calculation 32'd4, //11: 4 for ret_addr calculation src_b ); alu alu(alu_op_e, src_a, src_b, shamt_e, aluout_e, alu_zero); wire [63:0] product_e = src_a_fwd_e * src_b_fwd_e; ffd #( 64) hi_lo_reg(CLK, RESET, multiply_e & RUN, product_e, {hi_e, lo_e}); mux4 aluout_mux( mfcop_sel_e, aluout_e, hi_e, //MFHI lo_e, //MFLO 32'hXXXXXXXX, //MFC0 aluout_mux_e ); ffd #( 75) pipe_reg_M(CLK, RESET, RUN, { write_reg_e, // 1/ write to register file write_mem_e, // 1/ write data memory mem_partial_e, // 1/ memory byte- or halfword access mem_optype_e, // 2/ mem op: 00-ubyte, 01-uhalf, 10-sb, 11-sh aluormem_e, // 1/ write regfile from alu or from memory aluout_mux_e, //32/ ALU result src_b_fwd_e, //32/ regfile data B reg_dst_addr_e }, // 5/ destination reg addr { write_reg_m, write_mem_m, mem_partial_m, mem_optype_m, aluormem_m, aluout_m, src_b_m, reg_dst_addr_m }); //---------------------------------------------------------------------------// //------------------------MEMORY STAGE---------------------------------------// assign data_mem_we = write_mem_m; assign data_mem_addr = aluout_m[31:2]; store_reorder st_reorder_unit( .LO_ADDR ( aluout_m[1:0] ), .DATA_IN ( src_b_m ), .PARTIAL ( mem_partial_m ), .OP_TYPE ( mem_optype_m ), .BYTE_EN ( data_mem_be ), .DATA_OUT( data_mem_wdata )); load_reorder ld_reorder_unit( .LO_ADDR ( aluout_m[1:0] ), .DATA_IN ( data_mem_rdata ), .PARTIAL ( mem_partial_m ), .OP_TYPE ( mem_optype_m ), .DATA_OUT( mem_reordered_m)); ffd #( 71) pipe_reg_W(CLK, RESET, RUN, { write_reg_m, // 1/ write to register file aluormem_m, // 1/ write regfile from alu or from memory aluout_m, //32/ alu result mem_reordered_m, //32/ memory data reg_dst_addr_m}, // 5/ destination register { write_reg_w, // 1/ write to register file aluormem_w, // 1/ write regfile from alu or from memory aluout_w, //32/ alu result mem_reordered_w, //32/ memory data reg_dst_addr_w} ); // 5/ destination register //---------------------------------------------------------------------------// //-----------------------WRITEBACK STAGE-------------------------------------// mux2 regfile_wr_data_mux( aluormem_w, aluout_w, //0: ALU out mem_reordered_w, //1: MEM out regfile_wdata); //---------------------------------------------------------------------------// endmodule

/* * * Copyright (c) 2011-2012 [email protected] * * * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see <http://www.gnu.org/licenses/>. * */ // Top-level module that uses the unoptimized mining core and Virtual Wire // external interface. `timescale 1ns/1ps module fpgaminer_top ( input MAIN_CLK ); // The LOOP_LOG2 parameter determines how unrolled the SHA-256 // calculations are. For example, a setting of 0 will completely // unroll the calculations, resulting in 128 rounds and a large, but // fast design. // // A setting of 1 will result in 64 rounds, with half the size and // half the speed. 2 will be 32 rounds, with 1/4th the size and speed. // And so on. // // Valid range: [0, 5] `ifdef CONFIG_LOOP_LOG2 localparam LOOP_LOG2 = `CONFIG_LOOP_LOG2; `else localparam LOOP_LOG2 = 0; `endif // No need to adjust these parameters localparam [5:0] LOOP = (6'd1 << LOOP_LOG2); // The nonce will always be larger at the time we discover a valid // hash. This is its offset from the nonce that gave rise to the valid // hash (except when LOOP_LOG2 == 0 or 1, where the offset is 131 or // 66 respectively). localparam [31:0] GOLDEN_NONCE_OFFSET = (32'd1 << (7 - LOOP_LOG2)) + 32'd1; //// reg [255:0] state = 0; reg [511:0] data = 0; reg [31:0] nonce = 32'h00000000; //// PLL wire hash_clk; hashing_pll # ( .INPUT_FREQUENCY (`MAIN_CLK_FREQUENCY), .DIVIDE_BY (`MAIN_CLK_DIVIDE), .MULTIPLY_BY (`MAIN_CLK_MULTIPLY) ) pll_blk ( .rx_clk (MAIN_CLK), .tx_hash_clk (hash_clk) ); //// Hashers wire [255:0] hash, hash2; reg [5:0] cnt = 6'd0; reg feedback = 1'b0; sha256_transform #(.LOOP(LOOP)) uut ( .clk(hash_clk), .feedback(feedback), .cnt(cnt), .rx_state(state), .rx_input(data), .tx_hash(hash) ); sha256_transform #(.LOOP(LOOP)) uut2 ( .clk(hash_clk), .feedback(feedback), .cnt(cnt), .rx_state(256'h5be0cd191f83d9ab9b05688c510e527fa54ff53a3c6ef372bb67ae856a09e667), .rx_input({256'h0000010000000000000000000000000000000000000000000000000080000000, hash}), .tx_hash(hash2) ); //// Virtual Wire Control reg [255:0] midstate_buf = 0, data_buf = 0; wire [255:0] midstate_vw, data2_vw; virtual_wire # (.OUTPUT_WIDTH(256), .INSTANCE_ID("STAT")) midstate_vw_blk (.clk (hash_clk), .rx_data (), .tx_data (midstate_vw)); virtual_wire # (.OUTPUT_WIDTH(256), .INSTANCE_ID("DAT2")) data2_vw_blk (.clk (hash_clk), .rx_data (), .tx_data (data2_vw)); //// Virtual Wire Output reg [31:0] golden_nonce = 0; virtual_wire # (.INPUT_WIDTH(32), .INSTANCE_ID("GNON")) golden_nonce_vw_blk (.clk (hash_clk), .rx_data (golden_nonce), .tx_data ()); virtual_wire # (.INPUT_WIDTH(32), .INSTANCE_ID("NONC")) nonce_vw_blk (.clk (hash_clk), .rx_data (nonce), .tx_data ()); //// Control Unit reg is_golden_ticket = 1'b0; reg feedback_d1 = 1'b1; wire [5:0] cnt_next; wire [31:0] nonce_next; wire feedback_next; assign cnt_next = (LOOP == 1) ? 6'd0 : (cnt + 6'd1) & (LOOP-1); // On the first count (cnt==0), load data from previous stage (no feedback) // on 1..LOOP-1, take feedback from current stage // This reduces the throughput by a factor of (LOOP), but also reduces the design size by the same amount assign feedback_next = (LOOP == 1) ? 1'b0 : (cnt_next != {(LOOP_LOG2){1'b0}}); assign nonce_next = feedback_next ? nonce : (nonce + 32'd1); always @ (posedge hash_clk) begin midstate_buf <= midstate_vw; data_buf <= data2_vw; cnt <= cnt_next; feedback <= feedback_next; feedback_d1 <= feedback; // Give new data to the hasher state <= midstate_buf; data <= {384'h000002800000000000000000000000000000000000000000000000000000000000000000000000000000000080000000, nonce_next, data_buf[95:0]}; nonce <= nonce_next; // Check to see if the last hash generated is valid. is_golden_ticket <= (hash2[255:224] == 32'h00000000) && !feedback_d1; if(is_golden_ticket) begin // TODO: Find a more compact calculation for this if (LOOP == 1) golden_nonce <= nonce - 32'd131; else if (LOOP == 2) golden_nonce <= nonce - 32'd66; else golden_nonce <= nonce - GOLDEN_NONCE_OFFSET; end end endmodule

/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 */ `ifndef SKY130_FD_SC_HS__TAPVPWRVGND_PP_BLACKBOX_V `define SKY130_FD_SC_HS__TAPVPWRVGND_PP_BLACKBOX_V /** * tapvpwrvgnd: Substrate and well tap cell. * * Verilog stub definition (black box with power pins). * * WARNING: This file is autogenerated, do not modify directly! */ `timescale 1ns / 1ps `default_nettype none (* blackbox *) module sky130_fd_sc_hs__tapvpwrvgnd ( VPWR, VGND ); input VPWR; input VGND; endmodule `default_nettype wire `endif // SKY130_FD_SC_HS__TAPVPWRVGND_PP_BLACKBOX_V

//Jun.30.2004 NOP_DISABLE BUG FIX `include "define.h" module pc_module(clock,sync_reset,pc_commandD1,PCC,imm,ea_reg_source,takenD2, takenD3 ,branchQQ,jumpQ,NOP_Signal,control_state,IMMD1, PCCDD); input clock; input sync_reset; input [31:0] ea_reg_source; input [2:0] pc_commandD1; input takenD2; input [25:0] imm; input [25:0] IMMD1; `ifdef RAM4K output [11:0] PCC; `else output [25:0] PCC; `endif input takenD3; input branchQQ,jumpQ; input NOP_Signal; input [7:0] control_state; reg [2:0] pc_commandD2,pc_commandD3; `ifdef RAM4K reg [11:0] PC; reg [11:0] pcimm1D1,pcimm2D1; reg [15:0] immD1;// reg [11:0] pcimm1D2,pcimm2D2,pcimm2D3; reg [11:0] save_pc; wire [11:0] PCC; output [11:0] PCCDD; reg [11:0] PCCD,PCCDD; `else reg [25:0] PC; reg [25:0] pcimm1D1,pcimm2D1; reg [15:0] immD1;// reg [25:0] pcimm1D2,pcimm2D2,pcimm2D3; reg [25:0] save_pc; wire [25:0] PCC; output [25:0] PCCDD; reg [25:0] PCCD,PCCDD; `endif reg takenD4; reg branchQQQtakenD4; //combination always@(posedge clock) PCCD<=PCC; always@(posedge clock) PCCDD<=PCCD; always @(posedge clock) begin pc_commandD2 <=pc_commandD1; end // always @(posedge clock) begin if (NOP_Signal) pc_commandD3<=3'b000;//Jun.30.2004 else pc_commandD3 <=pc_commandD2; end always @(IMMD1 ) begin pcimm1D1={IMMD1,2'b00};//Jul.7.2004 {imm[23:0],2'b00};//+{PC[25:2],2'b00}; end `ifdef RAM4K always @(posedge clock) begin pcimm2D1<={PC[11:2],2'b00}; end `else always @(posedge clock) begin pcimm2D1<={PC[25:2],2'b00}; end `endif always @(posedge clock) begin pcimm1D2<=pcimm1D1; end always @(posedge clock) begin pcimm2D2<={{8 {immD1[15]}},immD1[15:0],2'b00}+pcimm2D1;//Jul.14.2004 end always @(posedge clock) begin pcimm2D3<=pcimm2D2; end always @(posedge clock) begin immD1<=imm[15:0];//Jul.14.2004 end always @(posedge clock) begin if (control_state==8'b00_000_010) save_pc<=PCCDD; end always @(posedge clock) begin if (sync_reset) PC<=26'h0_00_0000_0000; else if (branchQQQtakenD4) PC<=pcimm2D3+4;//NOP else if (jumpQ && !NOP_Signal) PC<=pcimm1D1+4; else if (pc_commandD3==`PC_REG) PC<=ea_reg_source[25:0]+4; else if (control_state[2:0]==3'b110) PC<=save_pc+4;//mul/div else case(pc_commandD1) `PC_INC: PC<=PC+4; default: PC<=PC+4; endcase end always @(posedge clock) begin if (sync_reset) takenD4<=1'b0; else takenD4<=takenD3; end always @(posedge clock) begin if (sync_reset) branchQQQtakenD4<=1'b0; else branchQQQtakenD4<=branchQQ && takenD3; end assign PCC= branchQQQtakenD4 ? pcimm2D3 : jumpQ && !NOP_Signal ? pcimm1D1 : pc_commandD3==`PC_REG ? ea_reg_source[25:0] : control_state[2:0] ==3'b110 ? save_pc:PC;//Jun.27.2004 endmodule

// DEFINES `define BITS 32 // Bit width of the operands module syn2(clock, reset, in1, in2, in3, in4, in5, out_1, out_2, out_3, out_4 ); // SIGNAL DECLARATIONS input clock; input reset; input [`BITS-1:0] in1; input [`BITS-1:0] in2; input [`BITS-1:0] in3; input [`BITS-1:0] in4; input [`BITS-1:0] in5; output [`BITS-1:0] out_1; output [`BITS-1:0] out_2; output [`BITS-1:0] out_3; output [`BITS-1:0] out_4; wire [`BITS-1:0] x1; wire [`BITS-1:0] x2; wire [`BITS-1:0] x3; wire [`BITS-1:0] x4; wire [`BITS-1:0] add1; wire [`BITS-1:0] add2; wire [`BITS-1:0] add3; wire [`BITS-1:0] add4; wire [`BITS-1:0] add5; reg [`BITS-1:0] reg1; reg [`BITS-1:0] reg2; reg [`BITS-1:0] reg3; reg [`BITS-1:0] reg4; reg [`BITS-1:0] reg5; reg [`BITS-1:0] reg6; wire [`BITS-1:0] out_1; wire [`BITS-1:0] out_2; wire [`BITS-1:0] out_3; wire [`BITS-1:0] out_4; // ASSIGN STATEMENTS //assign add1 = reg1 + in4; wire [7:0] add1_control; fpu_add add1_add ( .clk(clock), .opa(reg6), .opb(in4), .out(add1), .control(add1_control) ); //assign x1 = x3 * in1; wire [7:0] x1_control; fpu_mul x1_mul ( .clk(clock), .opa(x3), .opb(in1), .out(x1), .control(x1_control) ); //assign add2 = add5 + add1; wire [7:0] add2_control; fpu_add add2_add ( .clk(clock), .opa(add5), .opb(add1), .out(add2), .control(add2_control) ); //assign x2 = x1 * add2; wire [7:0] x2_control; fpu_mul x2_mul ( .clk(clock), .opa(x1), .opb(add2), .out(x2), .control(x2_control) ); //assign add3 = in1 + reg1; wire [7:0] add3_control; fpu_add add3_add ( .clk(clock), .opa(in1), .opb(reg6), .out(add3), .control(add3_control) ); //assign x3 = in3 * in1; wire [7:0] x3_control; fpu_mul x3_mul ( .clk(clock), .opa(in3), .opb(in1), .out(x3), .control(x3_control) ); //assign add4 = in5 + in3; wire [7:0] add4_control; fpu_add add4_add ( .clk(clock), .opa(in5), .opb(in3), .out(add4), .control(add4_control) ); //assign x4 = in5 * in4; wire [7:0] x4_control; fpu_mul x4_mul ( .clk(clock), .opa(in5), .opb(in4), .out(x4), .control(x4_control) ); //assign add5 = in5 + in4; wire [7:0] add5_control; fpu_add add5_add ( .clk(clock), .opa(in5), .opb(in4), .out(add5), .control(add5_control) ); assign out_1 = x2; assign out_2 = add3; assign out_3 = add4; assign out_4 = x4; always @(posedge clock) begin reg1 <= in2; reg2 <= reg1; reg3 <= reg2; reg4 <= reg3; reg5 <= reg4; reg6 <= reg5; end endmodule module fpu_mul( clk, //rmode, opa, opb, out, control /* inf, snan, qnan, ine, overflow, underflow, zero, div_by_zero */ ); input clk; //input [1:0] rmode; input [31:0] opa, opb; output [31:0] out; output [7:0] control; /* output inf, snan, qnan; output ine; output overflow, underflow; output zero; output div_by_zero; */ //////////////////////////////////////////////////////////////////////// // // Local Wires // reg [2:0] fpu_op; reg zero; reg [31:0] opa_r, opb_r; // Input operand registers reg [31:0] out; // Output register reg div_by_zero; // Divide by zero output register wire signa, signb; // alias to opX sign wire sign_fasu; // sign output wire [26:0] fracta, fractb; // Fraction Outputs from EQU block wire [7:0] exp_fasu; // Exponent output from EQU block reg [7:0] exp_r; // Exponent output (registerd) wire [26:0] fract_out_d; // fraction output wire co; // carry output reg [27:0] fract_out_q; // fraction output (registerd) wire [30:0] out_d; // Intermediate final result output wire overflow_d, underflow_d;// Overflow/Underflow Indicators reg overflow, underflow; // Output registers for Overflow & Underflow reg inf, snan, qnan; // Output Registers for INF, SNAN and QNAN reg ine; // Output Registers for INE reg [1:0] rmode_r1, rmode_r2, // Pipeline registers for rounding mode rmode_r3; reg [2:0] fpu_op_r1, fpu_op_r2, // Pipeline registers for fp opration fpu_op_r3; wire mul_inf, div_inf; wire mul_00, div_00; /* parameter INF = 31'h7f800000; parameter QNAN = 31'h7fc00001; parameter SNAN = 31'h7f800001; */ wire [1:0] rmode; assign rmode = 2'b00; wire [30:0] INF; assign INF = 31'h7f800000; wire [30:0] QNAN; assign QNAN = 31'h7fc00001; wire [30:0] SNAN; assign SNAN = 31'h7f800001; // start output_reg reg [31:0] out_o1; reg inf_o1, snan_o1, qnan_o1; reg ine_o1; reg overflow_o1, underflow_o1; reg zero_o1; reg div_by_zero_o1; // end output_reg wire [7:0] contorl; assign control = {inf, snan, qnan, ine, overflow, underflow, zero, div_by_zero}; //////////////////////////////////////////////////////////////////////// // // Input Registers // always @(posedge clk) begin fpu_op[2:0] <= 3'b010; end always @(posedge clk) opa_r <= opa; always @(posedge clk) opb_r <= opb; always @(posedge clk) rmode_r1 <= rmode; always @(posedge clk) rmode_r2 <= rmode_r1; always @(posedge clk) rmode_r3 <= rmode_r2; always @(posedge clk) fpu_op_r1 <= fpu_op; always @(posedge clk) fpu_op_r2 <= fpu_op_r1; always @(posedge clk) fpu_op_r3 <= fpu_op_r2; //////////////////////////////////////////////////////////////////////// // // Exceptions block // wire inf_d, ind_d, qnan_d, snan_d, opa_nan, opb_nan; wire opa_00, opb_00; wire opa_inf, opb_inf; wire opa_dn, opb_dn; except u0( .clk(clk), .opa(opa_r[30:0]), .opb(opb_r[30:0]), .inf(inf_d), .ind(ind_d), .qnan(qnan_d), .snan(snan_d), .opa_nan(opa_nan), .opb_nan(opb_nan), .opa_00(opa_00), .opb_00(opb_00), .opa_inf(opa_inf), .opb_inf(opb_inf), .opa_dn(opa_dn), .opb_dn(opb_dn) ); //////////////////////////////////////////////////////////////////////// // // Pre-Normalize block // - Adjusts the numbers to equal exponents and sorts them // - determine result sign // - determine actual operation to perform (add or sub) // wire nan_sign_d, result_zero_sign_d; reg sign_fasu_r; wire [7:0] exp_mul; wire sign_mul; reg sign_mul_r; wire [23:0] fracta_mul, fractb_mul; wire inf_mul; reg inf_mul_r; wire [1:0] exp_ovf; reg [1:0] exp_ovf_r; wire sign_exe; reg sign_exe_r; wire [2:0] underflow_fmul_d; pre_norm_fmul u2( .clk(clk), .fpu_op(fpu_op_r1), .opa(opa_r), .opb(opb_r), .fracta(fracta_mul), .fractb(fractb_mul), .exp_out(exp_mul), // FMUL exponent output (registered) .sign(sign_mul), // FMUL sign output (registered) .sign_exe(sign_exe), // FMUL exception sign output (registered) .inf(inf_mul), // FMUL inf output (registered) .exp_ovf(exp_ovf), // FMUL exponnent overflow output (registered) .underflow(underflow_fmul_d) ); always @(posedge clk) sign_mul_r <= sign_mul; always @(posedge clk) sign_exe_r <= sign_exe; always @(posedge clk) inf_mul_r <= inf_mul; always @(posedge clk) exp_ovf_r <= exp_ovf; //////////////////////////////////////////////////////////////////////// // // Mul // wire [47:0] prod; mul_r2 u5(.clk(clk), .opa(fracta_mul), .opb(fractb_mul), .prod(prod)); //////////////////////////////////////////////////////////////////////// // // Normalize Result // wire ine_d; reg [47:0] fract_denorm; wire [47:0] fract_div; wire sign_d; reg sign; reg [30:0] opa_r1; reg [47:0] fract_i2f; reg opas_r1, opas_r2; wire f2i_out_sign; always @(posedge clk) // Exponent must be once cycle delayed exp_r <= exp_mul; always @(posedge clk) opa_r1 <= opa_r[30:0]; //always @(fpu_op_r3 or prod) always @(prod) fract_denorm = prod; always @(posedge clk) opas_r1 <= opa_r[31]; always @(posedge clk) opas_r2 <= opas_r1; assign sign_d = sign_mul; always @(posedge clk) sign <= (rmode_r2==2'h3) ? !sign_d : sign_d; wire or_result; assign or_result = mul_00 | div_00; post_norm u4( //.clk(clk), // System Clock .fpu_op(fpu_op_r3), // Floating Point Operation .opas(opas_r2), // OPA Sign .sign(sign), // Sign of the result .rmode(rmode_r3), // Rounding mode .fract_in(fract_denorm), // Fraction Input .exp_in(exp_r), // Exponent Input .exp_ovf(exp_ovf_r), // Exponent Overflow .opa_dn(opa_dn), // Operand A Denormalized .opb_dn(opb_dn), // Operand A Denormalized .rem_00(1'b0), // Diveide Remainder is zero .div_opa_ldz(5'b00000), // Divide opa leading zeros count // .output_zero(mul_00 | div_00), // Force output to Zero .output_zero(or_result), // Force output to Zero .out(out_d), // Normalized output (un-registered) .ine(ine_d), // Result Inexact output (un-registered) .overflow(overflow_d), // Overflow output (un-registered) .underflow(underflow_d), // Underflow output (un-registered) .f2i_out_sign(f2i_out_sign) // F2I Output Sign ); //////////////////////////////////////////////////////////////////////// // // FPU Outputs // wire [30:0] out_fixed; wire output_zero_fasu; wire output_zero_fdiv; wire output_zero_fmul; reg inf_mul2; wire overflow_fasu; wire overflow_fmul; wire overflow_fdiv; wire inf_fmul; wire sign_mul_final; wire out_d_00; wire sign_div_final; wire ine_mul, ine_mula, ine_div, ine_fasu; wire underflow_fasu, underflow_fmul, underflow_fdiv; wire underflow_fmul1; reg [2:0] underflow_fmul_r; reg opa_nan_r; always @(posedge clk) inf_mul2 <= exp_mul == 8'hff; // Force pre-set values for non numerical output assign mul_inf = (fpu_op_r3==3'b010) & (inf_mul_r | inf_mul2) & (rmode_r3==2'h0); assign div_inf = (fpu_op_r3==3'b011) & (opb_00 | opa_inf); assign mul_00 = (fpu_op_r3==3'b010) & (opa_00 | opb_00); assign div_00 = (fpu_op_r3==3'b011) & (opa_00 | opb_inf); assign out_fixed = ( (qnan_d | snan_d) | (opa_inf & opb_00)| (opb_inf & opa_00 ) ) ? QNAN : INF; always @(posedge clk) out_o1[30:0] <= (mul_inf | div_inf | inf_d | snan_d | qnan_d) ? out_fixed : out_d; assign out_d_00 = !(|out_d); assign sign_mul_final = (sign_exe_r & ((opa_00 & opb_inf) | (opb_00 & opa_inf))) ? !sign_mul_r : sign_mul_r; assign sign_div_final = (sign_exe_r & (opa_inf & opb_inf)) ? !sign_mul_r : sign_mul_r | (opa_00 & opb_00); always @(posedge clk) // out_o1[31] <= !(snan_d | qnan_d) ? sign_mul_final : nan_sign_d ; out_o1[31] <= !(snan_d | qnan_d) & sign_mul_final; // Exception Outputs assign ine_mula = ((inf_mul_r | inf_mul2 | opa_inf | opb_inf) & (rmode_r3==2'h1) & !((opa_inf & opb_00) | (opb_inf & opa_00 )) & fpu_op_r3[1]); assign ine_mul = (ine_mula | ine_d | inf_fmul | out_d_00 | overflow_d | underflow_d) & !opa_00 & !opb_00 & !(snan_d | qnan_d | inf_d); always @(posedge clk) ine_o1 <= ine_mul; assign overflow_fmul = !inf_d & (inf_mul_r | inf_mul2 | overflow_d) & !(snan_d | qnan_d); always @(posedge clk) overflow_o1 <= overflow_fmul; always @(posedge clk) underflow_fmul_r <= underflow_fmul_d; wire out_d_compare1; assign out_d_compare1 = (out_d[30:23]==8'b0); wire out_d_compare2; assign out_d_compare2 = (out_d[22:0]==23'b0); /* assign underflow_fmul1 = underflow_fmul_r[0] | (underflow_fmul_r[1] & underflow_d ) | ((opa_dn | opb_dn) & out_d_00 & (prod!=0) & sign) | (underflow_fmul_r[2] & ((out_d[30:23]==8'b0) | (out_d[22:0]==23'b0))); */ assign underflow_fmul1 = underflow_fmul_r[0] | (underflow_fmul_r[1] & underflow_d ) | ((opa_dn | opb_dn) & out_d_00 & (prod!=48'b0) & sign) | (underflow_fmul_r[2] & (out_d_compare1 | out_d_compare2)); assign underflow_fmul = underflow_fmul1 & !(snan_d | qnan_d | inf_mul_r); /* always @(posedge clk) begin underflow_o1 <= 1'b0; snan_o1 <= 1'b0; qnan_o1 <= 1'b0; inf_fmul <= 1'b0; inf_o1 <= 1'b0; zero_o1 <= 1'b0; opa_nan_r <= 1'b0; div_by_zero_o1 <= 1'b0; end assign output_zero_fmul = 1'b0; */ always @(posedge clk) underflow_o1 <= underflow_fmul; always @(posedge clk) snan_o1 <= snan_d; // Status Outputs always @(posedge clk) qnan_o1 <= ( snan_d | qnan_d | (((opa_inf & opb_00) | (opb_inf & opa_00 )) & fpu_op_r3==3'b010) ); assign inf_fmul = (((inf_mul_r | inf_mul2) & (rmode_r3==2'h0)) | opa_inf | opb_inf) & !((opa_inf & opb_00) | (opb_inf & opa_00 )) & fpu_op_r3==3'b010; always @(posedge clk) /* inf_o1 <= fpu_op_r3[2] ? 1'b0 : (!(qnan_d | snan_d) & ( ((&out_d[30:23]) & !(|out_d[22:0]) & !(opb_00 & fpu_op_r3==3'b011)) | inf_fmul) ); */ inf_o1 <= !fpu_op_r3[2] & (!(qnan_d | snan_d) & ( ((&out_d[30:23]) & !(|out_d[22:0]) & !(opb_00 & fpu_op_r3==3'b011)) | inf_fmul) ); assign output_zero_fmul = (out_d_00 | opa_00 | opb_00) & !(inf_mul_r | inf_mul2 | opa_inf | opb_inf | snan_d | qnan_d) & !(opa_inf & opb_00) & !(opb_inf & opa_00); always @(posedge clk) zero_o1 <= output_zero_fmul; always @(posedge clk) opa_nan_r <= (!opa_nan) & (fpu_op_r2==3'b011) ; always @(posedge clk) div_by_zero_o1 <= opa_nan_r & !opa_00 & !opa_inf & opb_00; // output register always @(posedge clk) begin qnan <= qnan_o1; out <= out_o1; inf <= inf_o1; snan <= snan_o1; //qnan <= qnan_o1; ine <= ine_o1; overflow <= overflow_o1; underflow <= underflow_o1; zero <= zero_o1; div_by_zero <= div_by_zero_o1; end endmodule //--------------------------------------------------------------------------------- module except( clk, opa, opb, inf, ind, qnan, snan, opa_nan, opb_nan, opa_00, opb_00, opa_inf, opb_inf, opa_dn, opb_dn); input clk; input [30:0] opa, opb; output inf, ind, qnan, snan, opa_nan, opb_nan; output opa_00, opb_00; output opa_inf, opb_inf; output opa_dn; output opb_dn; //////////////////////////////////////////////////////////////////////// // // Local Wires and registers // wire [7:0] expa, expb; // alias to opX exponent wire [22:0] fracta, fractb; // alias to opX fraction reg expa_ff, infa_f_r, qnan_r_a, snan_r_a; reg expb_ff, infb_f_r, qnan_r_b, snan_r_b; reg inf, ind, qnan, snan; // Output registers reg opa_nan, opb_nan; reg expa_00, expb_00, fracta_00, fractb_00; reg opa_00, opb_00; reg opa_inf, opb_inf; reg opa_dn, opb_dn; //////////////////////////////////////////////////////////////////////// // // Aliases // assign expa = opa[30:23]; assign expb = opb[30:23]; assign fracta = opa[22:0]; assign fractb = opb[22:0]; //////////////////////////////////////////////////////////////////////// // // Determine if any of the input operators is a INF or NAN or any other special number // always @(posedge clk) expa_ff <= &expa; always @(posedge clk) expb_ff <= &expb; always @(posedge clk) infa_f_r <= !(|fracta); always @(posedge clk) infb_f_r <= !(|fractb); always @(posedge clk) qnan_r_a <= fracta[22]; always @(posedge clk) snan_r_a <= !fracta[22] & |fracta[21:0]; always @(posedge clk) qnan_r_b <= fractb[22]; always @(posedge clk) snan_r_b <= !fractb[22] & |fractb[21:0]; always @(posedge clk) ind <= (expa_ff & infa_f_r) & (expb_ff & infb_f_r); always @(posedge clk) inf <= (expa_ff & infa_f_r) | (expb_ff & infb_f_r); always @(posedge clk) qnan <= (expa_ff & qnan_r_a) | (expb_ff & qnan_r_b); always @(posedge clk) snan <= (expa_ff & snan_r_a) | (expb_ff & snan_r_b); always @(posedge clk) opa_nan <= &expa & (|fracta[22:0]); always @(posedge clk) opb_nan <= &expb & (|fractb[22:0]); always @(posedge clk) opa_inf <= (expa_ff & infa_f_r); always @(posedge clk) opb_inf <= (expb_ff & infb_f_r); always @(posedge clk) expa_00 <= !(|expa); always @(posedge clk) expb_00 <= !(|expb); always @(posedge clk) fracta_00 <= !(|fracta); always @(posedge clk) fractb_00 <= !(|fractb); always @(posedge clk) opa_00 <= expa_00 & fracta_00; always @(posedge clk) opb_00 <= expb_00 & fractb_00; always @(posedge clk) opa_dn <= expa_00; always @(posedge clk) opb_dn <= expb_00; endmodule //--------------------------------------------------------------------------------- module pre_norm_fmul(clk, fpu_op, opa, opb, fracta, fractb, exp_out, sign, sign_exe, inf, exp_ovf, underflow); input clk; input [2:0] fpu_op; input [31:0] opa, opb; output [23:0] fracta, fractb; output [7:0] exp_out; output sign, sign_exe; output inf; output [1:0] exp_ovf; output [2:0] underflow; //////////////////////////////////////////////////////////////////////// // // Local Wires and registers // reg [7:0] exp_out; wire signa, signb; reg sign, sign_d; reg sign_exe; reg inf; wire [1:0] exp_ovf_d; reg [1:0] exp_ovf; wire [7:0] expa, expb; wire [7:0] exp_tmp1, exp_tmp2; wire co1, co2; wire expa_dn, expb_dn; wire [7:0] exp_out_a; wire opa_00, opb_00, fracta_00, fractb_00; wire [7:0] exp_tmp3, exp_tmp4, exp_tmp5; wire [2:0] underflow_d; reg [2:0] underflow; wire op_div; wire [7:0] exp_out_mul, exp_out_div; assign op_div = (fpu_op == 3'b011); //////////////////////////////////////////////////////////////////////// // // Aliases // assign signa = opa[31]; assign signb = opb[31]; assign expa = opa[30:23]; assign expb = opb[30:23]; //////////////////////////////////////////////////////////////////////// // // Calculate Exponenet // assign expa_dn = !(|expa); assign expb_dn = !(|expb); assign opa_00 = !(|opa[30:0]); assign opb_00 = !(|opb[30:0]); assign fracta_00 = !(|opa[22:0]); assign fractb_00 = !(|opb[22:0]); assign fracta[22:0] = opa[22:0]; assign fractb[22:0] = opb[22:0]; assign fracta[23:23] = !expa_dn; assign fractb[23:23] = !expb_dn; //assign fracta = {!expa_dn,opa[22:0]}; // Recover hidden bit //assign fractb = {!expb_dn,opb[22:0]}; // Recover hidden bit assign {co1,exp_tmp1} = op_div ? ({1'b0,expa[7:0]} - {1'b0,expb[7:0]}) : ({1'b0,expa[7:0]} + {1'b0,expb[7:0]}); assign {co2,exp_tmp2} = op_div ? ({co1,exp_tmp1} + 9'h07f) : ({co1,exp_tmp1} - 9'h07f); assign exp_tmp3 = exp_tmp2 + 8'h01; assign exp_tmp4 = 8'h7f - exp_tmp1; assign exp_tmp5 = op_div ? (exp_tmp4+8'h01) : (exp_tmp4-8'h01); always@(posedge clk) exp_out <= op_div ? exp_out_div : exp_out_mul; assign exp_out_div = (expa_dn | expb_dn) ? (co2 ? exp_tmp5 : exp_tmp3 ) : co2 ? exp_tmp4 : exp_tmp2; assign exp_out_mul = exp_ovf_d[1] ? exp_out_a : (expa_dn | expb_dn) ? exp_tmp3 : exp_tmp2; assign exp_out_a = (expa_dn | expb_dn) ? exp_tmp5 : exp_tmp4; assign exp_ovf_d[0] = op_div ? (expa[7] & !expb[7]) : (co2 & expa[7] & expb[7]); assign exp_ovf_d[1] = op_div ? co2 : ((!expa[7] & !expb[7] & exp_tmp2[7]) | co2); always @(posedge clk) exp_ovf <= #1 exp_ovf_d; assign underflow_d[0] = (exp_tmp1 < 8'h7f) & !co1 & !(opa_00 | opb_00 | expa_dn | expb_dn); assign underflow_d[1] = ((expa[7] | expb[7]) & !opa_00 & !opb_00) | (expa_dn & !fracta_00) | (expb_dn & !fractb_00); assign underflow_d[2] = !opa_00 & !opb_00 & (exp_tmp1 == 8'h7f); always @(posedge clk) underflow <= underflow_d; always @(posedge clk) inf <= op_div ? (expb_dn & !expa[7]) : ({co1,exp_tmp1} > 9'h17e) ; //////////////////////////////////////////////////////////////////////// // // Determine sign for the output // // sign: 0=Posetive Number; 1=Negative Number always @(signa or signb) case({signa, signb}) // synopsys full_case parallel_case 2'b00: sign_d = 0; 2'b01: sign_d = 1; 2'b10: sign_d = 1; 2'b11: sign_d = 0; endcase always @(posedge clk) sign <= sign_d; always @(posedge clk) sign_exe <= signa & signb; endmodule //---------------------------------------------------------------------------- //////////////////////////////////////////////////////////////////////// // // Multiply // module mul_r2(clk, opa, opb, prod); input clk; input [23:0] opa, opb; output [47:0] prod; reg [47:0] prod1, prod; always @(posedge clk) prod1 <= #1 opa * opb; always @(posedge clk) prod <= #1 prod1; endmodule //---------------------------------------------------------------------------- module post_norm( fpu_op, opas, sign, rmode, fract_in, exp_in, exp_ovf, opa_dn, opb_dn, rem_00, div_opa_ldz, output_zero, out, ine, overflow, underflow, f2i_out_sign); input [2:0] fpu_op; input opas; input sign; input [1:0] rmode; input [47:0] fract_in; input [7:0] exp_in; input [1:0] exp_ovf; input opa_dn, opb_dn; input rem_00; input [4:0] div_opa_ldz; input output_zero; output [30:0] out; output ine; output overflow, underflow; output f2i_out_sign; //////////////////////////////////////////////////////////////////////// // // Local Wires and registers // wire [22:0] fract_out; wire [7:0] exp_out; wire [30:0] out; wire exp_out1_co, overflow, underflow; wire [22:0] fract_out_final; reg [22:0] fract_out_rnd; wire [8:0] exp_next_mi; wire dn; wire exp_rnd_adj; wire [7:0] exp_out_final; reg [7:0] exp_out_rnd; wire op_dn; wire op_mul; wire op_div; wire op_i2f; wire op_f2i; //reg [5:0] fi_ldz; wire [5:0] fi_ldz; wire g, r, s; wire round, round2, round2a, round2_fasu, round2_fmul; wire [7:0] exp_out_rnd0, exp_out_rnd1, exp_out_rnd2, exp_out_rnd2a; wire [22:0] fract_out_rnd0, fract_out_rnd1, fract_out_rnd2, fract_out_rnd2a; wire exp_rnd_adj0, exp_rnd_adj2a; wire r_sign; wire ovf0, ovf1; wire [23:0] fract_out_pl1; wire [7:0] exp_out_pl1, exp_out_mi1; wire exp_out_00, exp_out_fe, exp_out_ff, exp_in_00, exp_in_ff; wire exp_out_final_ff, fract_out_7fffff; wire [24:0] fract_trunc; wire [7:0] exp_out1; wire grs_sel; wire fract_out_00, fract_in_00; wire shft_co; wire [8:0] exp_in_pl1, exp_in_mi1; wire [47:0] fract_in_shftr; wire [47:0] fract_in_shftl; // for block shifter wire [47:0] fract_in_shftr_1; wire [47:0] fract_in_shftl_1; // end for block shifter wire [7:0] exp_div; wire [7:0] shft2; wire [7:0] exp_out1_mi1; wire div_dn; wire div_nr; wire grs_sel_div; wire div_inf; wire [6:0] fi_ldz_2a; wire [7:0] fi_ldz_2; wire [7:0] div_shft1, div_shft2, div_shft3, div_shft4; wire div_shft1_co; wire [8:0] div_exp1; wire [7:0] div_exp2, div_exp3; wire left_right, lr_mul, lr_div; wire [7:0] shift_right, shftr_mul, shftr_div; wire [7:0] shift_left, shftl_mul, shftl_div; wire [7:0] fasu_shift; wire [7:0] exp_fix_div; wire [7:0] exp_fix_diva, exp_fix_divb; wire [5:0] fi_ldz_mi1; wire [5:0] fi_ldz_mi22; wire exp_zero; wire [6:0] ldz_all; wire [7:0] ldz_dif; wire [8:0] div_scht1a; wire [7:0] f2i_shft; wire [55:0] exp_f2i_1; wire f2i_zero, f2i_max; wire [7:0] f2i_emin; wire [7:0] conv_shft; wire [7:0] exp_i2f, exp_f2i, conv_exp; wire round2_f2i; assign op_mul = fpu_op[2:0]==3'b010; assign op_div = fpu_op[2:0]==3'b011; assign op_i2f = fpu_op[2:0]==3'b100; assign op_f2i = fpu_op[2:0]==3'b101; assign op_dn = opa_dn | opb_dn; pri_encoder u6( .fract_in (fract_in), .fi_ldz (fi_ldz) ); // --------------------------------------------------------------------- // Normalize wire exp_in_80; wire rmode_00, rmode_01, rmode_10, rmode_11; // Misc common signals assign exp_in_ff = &exp_in; assign exp_in_00 = !(|exp_in); assign exp_in_80 = exp_in[7] & !(|exp_in[6:0]); assign exp_out_ff = &exp_out; assign exp_out_00 = !(|exp_out); assign exp_out_fe = &exp_out[7:1] & !exp_out[0]; assign exp_out_final_ff = &exp_out_final; assign fract_out_7fffff = &fract_out; assign fract_out_00 = !(|fract_out); assign fract_in_00 = !(|fract_in); assign rmode_00 = (rmode==2'b00); assign rmode_01 = (rmode==2'b01); assign rmode_10 = (rmode==2'b10); assign rmode_11 = (rmode==2'b11); // Fasu Output will be denormalized ... assign dn = !op_mul & !op_div & (exp_in_00 | (exp_next_mi[8] & !fract_in[47]) ); // --------------------------------------------------------------------- // Fraction Normalization wire[7:0] f2i_emax; assign f2i_emax = 8'h9d; //parameter f2i_emax = 8'h9d; // Incremented fraction for rounding assign fract_out_pl1 = {1'b0, fract_out} + 24'h000001; // Special Signals for f2i assign f2i_emin = rmode_00 ? 8'h7e : 8'h7f; assign f2i_zero = (!opas & (exp_in<f2i_emin)) | (opas & (exp_in>f2i_emax)) | (opas & (exp_in<f2i_emin) & (fract_in_00 | !rmode_11)); assign f2i_max = (!opas & (exp_in>f2i_emax)) | (opas & (exp_in<f2i_emin) & !fract_in_00 & rmode_11); // Calculate various shifting options assign {shft_co,shftr_mul} = (!exp_ovf[1] & exp_in_00) ? {1'b0, exp_out} : exp_in_mi1 ; assign {div_shft1_co, div_shft1} = exp_in_00 ? {1'b0, div_opa_ldz} : div_scht1a; assign div_scht1a = {1'b0, exp_in}-{4'b0, div_opa_ldz}; // 9 bits - includes carry out assign div_shft2 = exp_in+8'h02; assign div_shft3 = {3'b0, div_opa_ldz}+exp_in; assign div_shft4 = {3'b0, div_opa_ldz}-exp_in; assign div_dn = op_dn & div_shft1_co; assign div_nr = op_dn & exp_ovf[1] & !(|fract_in[46:23]) & (div_shft3>8'h16); assign f2i_shft = exp_in-8'h7d; // Select shifting direction assign left_right = op_div ? lr_div : op_mul ? lr_mul :1'b1; assign lr_div = (op_dn & !exp_ovf[1] & exp_ovf[0]) ? 1'b1 : (op_dn & exp_ovf[1]) ? 1'b0 : (op_dn & div_shft1_co) ? 1'b0 : (op_dn & exp_out_00) ? 1'b1 : (!op_dn & exp_out_00 & !exp_ovf[1]) ? 1'b1 : exp_ovf[1] ? 1'b0 : 1'b1; assign lr_mul = (shft_co | (!exp_ovf[1] & exp_in_00) | (!exp_ovf[1] & !exp_in_00 & (exp_out1_co | exp_out_00) )) ? 1'b1 : ( exp_ovf[1] | exp_in_00 ) ? 1'b0 : 1'b1; // Select Left and Right shift value assign fasu_shift = (dn | exp_out_00) ? (exp_in_00 ? 8'h02 : exp_in_pl1[7:0]) : {2'h0, fi_ldz}; assign shift_right = op_div ? shftr_div : shftr_mul; assign conv_shft = op_f2i ? f2i_shft : {2'h0, fi_ldz}; assign shift_left = op_div ? shftl_div : op_mul ? shftl_mul : (op_f2i | op_i2f) ? conv_shft : fasu_shift; assign shftl_mul = (shft_co | (!exp_ovf[1] & exp_in_00) | (!exp_ovf[1] & !exp_in_00 & (exp_out1_co | exp_out_00))) ? exp_in_pl1[7:0] : {2'h0, fi_ldz}; assign shftl_div = ( op_dn & exp_out_00 & !(!exp_ovf[1] & exp_ovf[0])) ? div_shft1[7:0] : (!op_dn & exp_out_00 & !exp_ovf[1]) ? exp_in[7:0] : {2'h0, fi_ldz}; assign shftr_div = (op_dn & exp_ovf[1]) ? div_shft3 : (op_dn & div_shft1_co) ? div_shft4 : div_shft2; // Do the actual shifting //assign fract_in_shftr = (|shift_right[7:6]) ? 0 : fract_in>>shift_right[5:0]; //assign fract_in_shftl = (|shift_left[7:6] | (f2i_zero & op_f2i)) ? 0 : fract_in<<shift_left[5:0]; b_right_shifter u1( .shift_in (fract_in), .shift_value (shift_right[5:0]), .shift_out (fract_in_shftr_1) ); assign fract_in_shftr = (|shift_right[7:6]) ? 48'b0 : fract_in_shftr_1; // fract_in>>shift_right[5:0]; b_left_shifter u7( .shift_in (fract_in), .shift_value (shift_left[5:0]), .shift_out (fract_in_shftl_1) ); assign fract_in_shftl = (|shift_left[7:6] | (f2i_zero & op_f2i)) ? 48'b0 : fract_in_shftl_1; // fract_in<<shift_left[5:0]; // Chose final fraction output assign {fract_out,fract_trunc} = left_right ? fract_in_shftl : fract_in_shftr; // --------------------------------------------------------------------- // Exponent Normalization assign fi_ldz_mi1 = fi_ldz - 6'h01; assign fi_ldz_mi22 = fi_ldz - 6'd22; assign exp_out_pl1 = exp_out + 8'h01; assign exp_out_mi1 = exp_out - 8'h01; assign exp_in_pl1 = {1'b0, exp_in} + 9'd1; // 9 bits - includes carry out assign exp_in_mi1 = {1'b0, exp_in} - 9'd1; // 9 bits - includes carry out assign exp_out1_mi1 = exp_out1 - 8'h01; assign exp_next_mi = exp_in_pl1 - {3'b0, fi_ldz_mi1}; // 9 bits - includes carry out assign exp_fix_diva = exp_in - {2'b0, fi_ldz_mi22}; assign exp_fix_divb = exp_in - {2'b0, fi_ldz_mi1}; //assign exp_zero = (exp_ovf[1] & !exp_ovf[0] & op_mul & (!exp_rnd_adj2a | !rmode[1])) | (op_mul & exp_out1_co); assign exp_zero = (exp_ovf[1] & !exp_ovf[0] & op_mul ) | (op_mul & exp_out1_co); assign {exp_out1_co, exp_out1} = fract_in[47] ? exp_in_pl1 : exp_next_mi; assign f2i_out_sign = !opas ? ((exp_in<f2i_emin) ? 1'b0 : (exp_in>f2i_emax) ? 1'b0 : opas) : ((exp_in<f2i_emin) ? 1'b0 : (exp_in>f2i_emax) ? 1'b1 : opas); assign exp_i2f = fract_in_00 ? (opas ? 8'h9e : 8'h00) : (8'h9e-{2'b0, fi_ldz}); //assign exp_f2i_1 = {{8{fract_in[47]}}, fract_in }<<f2i_shft; b_left_shifter_new u3( .shift_in ({{8{fract_in[47]}}, fract_in }), .shift_value (f2i_shft[5:0]), .shift_out (exp_f2i_1) ); assign exp_f2i = f2i_zero ? 8'h00 : f2i_max ? 8'hff : exp_f2i_1[55:48]; assign conv_exp = op_f2i ? exp_f2i : exp_i2f; assign exp_out = op_div ? exp_div : (op_f2i | op_i2f) ? conv_exp : exp_zero ? 8'h0 : dn ? {6'h0, fract_in[47:46]} : exp_out1; assign ldz_all = {2'b0, div_opa_ldz} + {1'b0, fi_ldz}; assign ldz_dif = fi_ldz_2 - {3'b0, div_opa_ldz}; assign fi_ldz_2a = 7'd23 - {1'b0,fi_ldz}; assign fi_ldz_2 = {fi_ldz_2a[6], fi_ldz_2a[6:0]}; assign div_exp1 = exp_in_mi1 + {1'b0, fi_ldz_2}; // 9 bits - includes carry out assign div_exp2 = exp_in_pl1[7:0] - {1'b0, ldz_all}; assign div_exp3 = exp_in + ldz_dif; assign exp_div =(opa_dn & opb_dn)? div_exp3 : opb_dn? div_exp1[7:0] : (opa_dn & !( (exp_in[4:0]<div_opa_ldz) | (div_exp2>8'hfe) )) ? div_exp2 : (opa_dn | (exp_in_00 & !exp_ovf[1]) ) ? 8'h00 : exp_out1_mi1; assign div_inf = opb_dn & !opa_dn & (div_exp1[7:0] < 8'h7f); // --------------------------------------------------------------------- // Round // Extract rounding (GRS) bits assign grs_sel_div = op_div & (exp_ovf[1] | div_dn | exp_out1_co | exp_out_00); assign g = grs_sel_div ? fract_out[0] : fract_out[0]; assign r = grs_sel_div ? (fract_trunc[24] & !div_nr) : fract_trunc[24]; assign s = grs_sel_div ? |fract_trunc[24:0] : (|fract_trunc[23:0] | (fract_trunc[24] & op_div)); // Round to nearest even assign round = (g & r) | (r & s) ; assign {exp_rnd_adj0, fract_out_rnd0} = round ? fract_out_pl1 : {1'b0, fract_out}; assign exp_out_rnd0 = exp_rnd_adj0 ? exp_out_pl1 : exp_out; assign ovf0 = exp_out_final_ff & !rmode_01 & !op_f2i; // round to zero assign fract_out_rnd1 = (exp_out_ff & !op_div & !dn & !op_f2i) ? 23'h7fffff : fract_out; assign exp_fix_div = (fi_ldz>6'd22) ? exp_fix_diva : exp_fix_divb; assign exp_out_rnd1 = (g & r & s & exp_in_ff) ? (op_div ? exp_fix_div : exp_next_mi[7:0]) : (exp_out_ff & !op_f2i) ? exp_in : exp_out; assign ovf1 = exp_out_ff & !dn; // round to +inf (UP) and -inf (DOWN) assign r_sign = sign; assign round2a = !exp_out_fe | !fract_out_7fffff | (exp_out_fe & fract_out_7fffff); assign round2_fasu = ((r | s) & !r_sign) & (!exp_out[7] | (exp_out[7] & round2a)); assign round2_fmul = !r_sign & ( (exp_ovf[1] & !fract_in_00 & ( ((!exp_out1_co | op_dn) & (r | s | (!rem_00 & op_div) )) | fract_out_00 | (!op_dn & !op_div)) ) | ( (r | s | (!rem_00 & op_div)) & ( (!exp_ovf[1] & (exp_in_80 | !exp_ovf[0])) | op_div | ( exp_ovf[1] & !exp_ovf[0] & exp_out1_co) ) ) ); //assign round2_f2i = rmode_10 & (( |fract_in[23:0] & !opas & (exp_in<8'h80 )) | (|fract_trunc)); wire temp_fract_in; assign temp_fract_in = |fract_in[23:0]; assign round2_f2i = rmode_10 & (( temp_fract_in & !opas & (exp_in<8'h80 )) | (|fract_trunc)); assign round2 = (op_mul | op_div) ? round2_fmul : op_f2i ? round2_f2i : round2_fasu; assign {exp_rnd_adj2a, fract_out_rnd2a} = round2 ? fract_out_pl1 : {1'b0, fract_out}; assign exp_out_rnd2a = exp_rnd_adj2a ? ((exp_ovf[1] & op_mul) ? exp_out_mi1 : exp_out_pl1) : exp_out; assign fract_out_rnd2 = (r_sign & exp_out_ff & !op_div & !dn & !op_f2i) ? 23'h7fffff : fract_out_rnd2a; assign exp_out_rnd2 = (r_sign & exp_out_ff & !op_f2i) ? 8'hfe : exp_out_rnd2a; // Choose rounding mode always @(rmode or exp_out_rnd0 or exp_out_rnd1 or exp_out_rnd2) case(rmode) // synopsys full_case parallel_case 2'b00: exp_out_rnd = exp_out_rnd0; 2'b01: exp_out_rnd = exp_out_rnd1; 2'b10: exp_out_rnd = exp_out_rnd2; 2'b11: exp_out_rnd = exp_out_rnd2; endcase always @(rmode or fract_out_rnd0 or fract_out_rnd1 or fract_out_rnd2) case(rmode) // synopsys full_case parallel_case 2'b00: fract_out_rnd = fract_out_rnd0; 2'b01: fract_out_rnd = fract_out_rnd1; 2'b10: fract_out_rnd = fract_out_rnd2; 2'b11: fract_out_rnd = fract_out_rnd2; endcase // --------------------------------------------------------------------- // Final Output Mux // Fix Output for denormalized and special numbers wire max_num, inf_out; assign max_num = ( !rmode_00 & (op_mul | op_div ) & ( ( exp_ovf[1] & exp_ovf[0]) | (!exp_ovf[1] & !exp_ovf[0] & exp_in_ff & (fi_ldz_2<8'd24) & (exp_out!=8'hfe) ) ) ) | ( op_div & ( ( rmode_01 & ( div_inf | (exp_out_ff & !exp_ovf[1] ) | (exp_ovf[1] & exp_ovf[0] ) ) ) | ( rmode[1] & !exp_ovf[1] & ( ( exp_ovf[0] & exp_in_ff & r_sign & fract_in[47] ) | ( r_sign & ( (fract_in[47] & div_inf) | (exp_in[7] & !exp_out_rnd[7] & !exp_in_80 & exp_out!=8'h7f ) | (exp_in[7] & exp_out_rnd[7] & r_sign & exp_out_ff & op_dn & div_exp1>9'h0fe ) ) ) | ( exp_in_00 & r_sign & ( div_inf | (r_sign & exp_out_ff & fi_ldz_2<8'h18) ) ) ) ) ) ); assign inf_out = (rmode[1] & (op_mul | op_div) & !r_sign & ( (exp_in_ff & !op_div) | (exp_ovf[1] & exp_ovf[0] & (exp_in_00 | exp_in[7]) ) ) ) | (div_inf & op_div & ( rmode_00 | (rmode[1] & !exp_in_ff & !exp_ovf[1] & !exp_ovf[0] & !r_sign ) | (rmode[1] & !exp_ovf[1] & exp_ovf[0] & exp_in_00 & !r_sign) ) ) | (op_div & rmode[1] & exp_in_ff & op_dn & !r_sign & (fi_ldz_2 < 8'd24) & (exp_out_rnd!=8'hfe) ); assign fract_out_final = (inf_out | ovf0 | output_zero ) ? 23'h000000 : (max_num | (f2i_max & op_f2i) ) ? 23'h7fffff : fract_out_rnd; assign exp_out_final = ((op_div & exp_ovf[1] & !exp_ovf[0]) | output_zero ) ? 8'h00 : ((op_div & exp_ovf[1] & exp_ovf[0] & rmode_00) | inf_out | (f2i_max & op_f2i) ) ? 8'hff : max_num ? 8'hfe : exp_out_rnd; // --------------------------------------------------------------------- // Pack Result assign out = {exp_out_final, fract_out_final}; // --------------------------------------------------------------------- // Exceptions wire underflow_fmul; wire overflow_fdiv; wire undeflow_div; wire z; assign z = shft_co | ( exp_ovf[1] | exp_in_00) | (!exp_ovf[1] & !exp_in_00 & (exp_out1_co | exp_out_00)); assign underflow_fmul = ( (|fract_trunc) & z & !exp_in_ff ) | (fract_out_00 & !fract_in_00 & exp_ovf[1]); assign undeflow_div = !(exp_ovf[1] & exp_ovf[0] & rmode_00) & !inf_out & !max_num & exp_out_final!=8'hff & ( ((|fract_trunc) & !opb_dn & ( ( op_dn & !exp_ovf[1] & exp_ovf[0]) | ( op_dn & exp_ovf[1]) | ( op_dn & div_shft1_co) | exp_out_00 | exp_ovf[1] ) ) | ( exp_ovf[1] & !exp_ovf[0] & ( ( op_dn & exp_in>8'h16 & fi_ldz<6'd23) | ( op_dn & exp_in<8'd23 & fi_ldz<6'd23 & !rem_00) | ( !op_dn & (exp_in[7]==exp_div[7]) & !rem_00) | ( !op_dn & exp_in_00 & (exp_div[7:1]==7'h7f) ) | ( !op_dn & exp_in<8'h7f & exp_in>8'h20 ) ) ) | (!exp_ovf[1] & !exp_ovf[0] & ( ( op_dn & fi_ldz<6'd23 & exp_out_00) | ( exp_in_00 & !rem_00) | ( !op_dn & ldz_all<7'd23 & exp_in==8'h01 & exp_out_00 & !rem_00) ) ) ); assign underflow = op_div ? undeflow_div : op_mul ? underflow_fmul : (!fract_in[47] & exp_out1_co) & !dn; assign overflow_fdiv = inf_out | (!rmode_00 & max_num) | (exp_in[7] & op_dn & exp_out_ff) | (exp_ovf[0] & (exp_ovf[1] | exp_out_ff) ); assign overflow = op_div ? overflow_fdiv : (ovf0 | ovf1); wire f2i_ine; assign f2i_ine = (f2i_zero & !fract_in_00 & !opas) | (|fract_trunc) | (f2i_zero & (exp_in<8'h80) & opas & !fract_in_00) | (f2i_max & rmode_11 & (exp_in<8'h80)); assign ine = op_f2i ? f2i_ine : op_i2f ? (|fract_trunc) : ((r & !dn) | (s & !dn) | max_num | (op_div & !rem_00)); endmodule //------------------------------------------------------------------------------------- module pri_encoder ( fract_in, fi_ldz ); input [47:0] fract_in; output [5:0] fi_ldz; reg [5:0] fi_ldz_r0; assign fi_ldz = fi_ldz_r0; always @(fract_in) begin if (fract_in[47:47] == 1'b1) fi_ldz_r0 = 6'd1; else if (fract_in[47:46] == 2'b01) fi_ldz_r0 = 6'd2; else if (fract_in[47:45] == 3'b001) fi_ldz_r0 = 6'd3; else if (fract_in[47:44] == 4'b0001) fi_ldz_r0 = 6'd4; else if (fract_in[47:43] == 5'b00001) fi_ldz_r0 = 6'd5; else if (fract_in[47:42] == 6'b000001) fi_ldz_r0 = 6'd6; else if (fract_in[47:41] == 7'b0000001) fi_ldz_r0 = 6'd7; else if (fract_in[47:40] == 8'b00000001) fi_ldz_r0 = 6'd8; else if (fract_in[47:39] == 9'b000000001) fi_ldz_r0 = 6'd9; else if (fract_in[47:38] == 10'b0000000001) fi_ldz_r0 = 6'd10; else if (fract_in[47:37] == 11'b00000000001) fi_ldz_r0 = 6'd11; else if (fract_in[47:36] == 12'b000000000001) fi_ldz_r0 = 6'd12; else if (fract_in[47:35] == 13'b0000000000001) fi_ldz_r0 = 6'd13; else if (fract_in[47:34] == 14'b00000000000001) fi_ldz_r0 = 6'd14; else if (fract_in[47:33] == 15'b000000000000001) fi_ldz_r0 = 6'd15; else if (fract_in[47:32] == 16'b0000000000000001) fi_ldz_r0 = 6'd16; else if (fract_in[47:31] == 17'b00000000000000001) fi_ldz_r0 = 6'd17; else if (fract_in[47:30] == 18'b000000000000000001) fi_ldz_r0 = 6'd18; else if (fract_in[47:29] == 19'b0000000000000000001) fi_ldz_r0 = 6'd19; else if (fract_in[47:28] == 20'b00000000000000000001) fi_ldz_r0 = 6'd20; else if (fract_in[47:27] == 21'b000000000000000000001) fi_ldz_r0 = 6'd21; else if (fract_in[47:26] == 22'b0000000000000000000001) fi_ldz_r0 = 6'd22; else if (fract_in[47:25] == 23'b00000000000000000000001) fi_ldz_r0 = 6'd23; else if (fract_in[47:24] == 24'b000000000000000000000001) fi_ldz_r0 = 6'd24; else if (fract_in[47:23] == 25'b0000000000000000000000001) fi_ldz_r0 = 6'd25; else if (fract_in[47:22] == 26'b00000000000000000000000001) fi_ldz_r0 = 6'd26; else if (fract_in[47:21] == 27'b000000000000000000000000001) fi_ldz_r0 = 6'd27; else if (fract_in[47:20] == 28'b0000000000000000000000000001) fi_ldz_r0 = 6'd28; else if (fract_in[47:19] == 29'b00000000000000000000000000001) fi_ldz_r0 = 6'd29; else if (fract_in[47:18] == 30'b000000000000000000000000000001) fi_ldz_r0 = 6'd30; else if (fract_in[47:17] == 31'b0000000000000000000000000000001) fi_ldz_r0 = 6'd31; else if (fract_in[47:16] == 32'b00000000000000000000000000000001) fi_ldz_r0 = 6'd32; else if (fract_in[47:15] == 33'b000000000000000000000000000000001) fi_ldz_r0 = 6'd33; else if (fract_in[47:14] == 34'b0000000000000000000000000000000001) fi_ldz_r0 = 6'd34; else if (fract_in[47:13] == 35'b00000000000000000000000000000000001) fi_ldz_r0 = 6'd35; else if (fract_in[47:12] == 36'b000000000000000000000000000000000001) fi_ldz_r0 = 6'd36; else if (fract_in[47:11] == 37'b0000000000000000000000000000000000001) fi_ldz_r0 = 6'd37; else if (fract_in[47:10] == 38'b00000000000000000000000000000000000001) fi_ldz_r0 = 6'd38; else if (fract_in[47:9] == 39'b000000000000000000000000000000000000001) fi_ldz_r0 = 6'd39; else if (fract_in[47:8] == 40'b0000000000000000000000000000000000000001) fi_ldz_r0 = 6'd40; else if (fract_in[47:7] == 41'b00000000000000000000000000000000000000001) fi_ldz_r0 = 6'd41; else if (fract_in[47:6] == 42'b000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd42; else if (fract_in[47:5] == 43'b0000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd43; else if (fract_in[47:4] == 44'b00000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd44; else if (fract_in[47:3] == 45'b000000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd45; else if (fract_in[47:2] == 46'b0000000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd46; else if (fract_in[47:1] == 47'b00000000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd47; else if (fract_in[47:0] == 48'b000000000000000000000000000000000000000000000001) fi_ldz_r0 = 6'd48; else if (fract_in[47:0] == 48'b000000000000000000000000000000000000000000000000) fi_ldz_r0 = 6'd48; end endmodule module b_right_shifter ( shift_in, shift_value, shift_out ); input [47:0] shift_in; input [5:0] shift_value; output [47:0] shift_out; reg [47:0] shift_out; always @(shift_value) begin case (shift_value) 6'b000000: shift_out = shift_in; 6'b000001: shift_out = shift_in >> 1; 6'b000010: shift_out = shift_in >> 2; 6'b000011: shift_out = shift_in >> 3; 6'b000100: shift_out = shift_in >> 4; 6'b000101: shift_out = shift_in >> 5; 6'b000110: shift_out = shift_in >> 6; 6'b000111: shift_out = shift_in >> 7; 6'b001000: shift_out = shift_in >> 8; 6'b001001: shift_out = shift_in >> 9; 6'b001010: shift_out = shift_in >> 10; 6'b001011: shift_out = shift_in >> 11; 6'b001100: shift_out = shift_in >> 12; 6'b001101: shift_out = shift_in >> 13; 6'b001110: shift_out = shift_in >> 14; 6'b001111: shift_out = shift_in >> 15; 6'b010000: shift_out = shift_in >> 16; 6'b010001: shift_out = shift_in >> 17; 6'b010010: shift_out = shift_in >> 18; 6'b010011: shift_out = shift_in >> 19; 6'b010100: shift_out = shift_in >> 20; 6'b010101: shift_out = shift_in >> 21; 6'b010110: shift_out = shift_in >> 22; 6'b010111: shift_out = shift_in >> 23; 6'b011000: shift_out = shift_in >> 24; 6'b011001: shift_out = shift_in >> 25; 6'b011010: shift_out = shift_in >> 26; 6'b011011: shift_out = shift_in >> 27; 6'b011100: shift_out = shift_in >> 28; 6'b011101: shift_out = shift_in >> 29; 6'b011110: shift_out = shift_in >> 30; 6'b011111: shift_out = shift_in >> 31; 6'b100000: shift_out = shift_in >> 32; 6'b100001: shift_out = shift_in >> 33; 6'b100010: shift_out = shift_in >> 34; 6'b100011: shift_out = shift_in >> 35; 6'b100100: shift_out = shift_in >> 36; 6'b100101: shift_out = shift_in >> 37; 6'b100110: shift_out = shift_in >> 38; 6'b100111: shift_out = shift_in >> 39; 6'b101000: shift_out = shift_in >> 40; 6'b101001: shift_out = shift_in >> 41; 6'b101010: shift_out = shift_in >> 42; 6'b101011: shift_out = shift_in >> 43; 6'b101100: shift_out = shift_in >> 44; 6'b101101: shift_out = shift_in >> 45; 6'b101110: shift_out = shift_in >> 46; 6'b101111: shift_out = shift_in >> 47; 6'b110000: shift_out = shift_in >> 48; endcase end //assign shift_out = shift_in >> shift_value; endmodule module b_left_shifter ( shift_in, shift_value, shift_out ); input [47:0] shift_in; input [5:0] shift_value; output [47:0] shift_out; reg [47:0] shift_out; always @(shift_value) begin case (shift_value) 6'b000000: shift_out = shift_in; 6'b000001: shift_out = shift_in << 1; 6'b000010: shift_out = shift_in << 2; 6'b000011: shift_out = shift_in << 3; 6'b000100: shift_out = shift_in << 4; 6'b000101: shift_out = shift_in << 5; 6'b000110: shift_out = shift_in << 6; 6'b000111: shift_out = shift_in << 7; 6'b001000: shift_out = shift_in << 8; 6'b001001: shift_out = shift_in << 9; 6'b001010: shift_out = shift_in << 10; 6'b001011: shift_out = shift_in << 11; 6'b001100: shift_out = shift_in << 12; 6'b001101: shift_out = shift_in << 13; 6'b001110: shift_out = shift_in << 14; 6'b001111: shift_out = shift_in << 15; 6'b010000: shift_out = shift_in << 16; 6'b010001: shift_out = shift_in << 17; 6'b010010: shift_out = shift_in << 18; 6'b010011: shift_out = shift_in << 19; 6'b010100: shift_out = shift_in << 20; 6'b010101: shift_out = shift_in << 21; 6'b010110: shift_out = shift_in << 22; 6'b010111: shift_out = shift_in << 23; 6'b011000: shift_out = shift_in << 24; 6'b011001: shift_out = shift_in << 25; 6'b011010: shift_out = shift_in << 26; 6'b011011: shift_out = shift_in << 27; 6'b011100: shift_out = shift_in << 28; 6'b011101: shift_out = shift_in << 29; 6'b011110: shift_out = shift_in << 30; 6'b011111: shift_out = shift_in << 31; 6'b100000: shift_out = shift_in << 32; 6'b100001: shift_out = shift_in << 33; 6'b100010: shift_out = shift_in << 34; 6'b100011: shift_out = shift_in << 35; 6'b100100: shift_out = shift_in << 36; 6'b100101: shift_out = shift_in << 37; 6'b100110: shift_out = shift_in << 38; 6'b100111: shift_out = shift_in << 39; 6'b101000: shift_out = shift_in << 40; 6'b101001: shift_out = shift_in << 41; 6'b101010: shift_out = shift_in << 42; 6'b101011: shift_out = shift_in << 43; 6'b101100: shift_out = shift_in << 44; 6'b101101: shift_out = shift_in << 45; 6'b101110: shift_out = shift_in << 46; 6'b101111: shift_out = shift_in << 47; 6'b110000: shift_out = shift_in << 48; endcase end endmodule module b_left_shifter_new ( shift_in, shift_value, shift_out ); input [55:0] shift_in; input [5:0] shift_value; output [55:0] shift_out; reg [47:0] shift_out; always @(shift_value) begin case (shift_value) 6'b000000: shift_out = shift_in; 6'b000001: shift_out = shift_in << 1; 6'b000010: shift_out = shift_in << 2; 6'b000011: shift_out = shift_in << 3; 6'b000100: shift_out = shift_in << 4; 6'b000101: shift_out = shift_in << 5; 6'b000110: shift_out = shift_in << 6; 6'b000111: shift_out = shift_in << 7; 6'b001000: shift_out = shift_in << 8; 6'b001001: shift_out = shift_in << 9; 6'b001010: shift_out = shift_in << 10; 6'b001011: shift_out = shift_in << 11; 6'b001100: shift_out = shift_in << 12; 6'b001101: shift_out = shift_in << 13; 6'b001110: shift_out = shift_in << 14; 6'b001111: shift_out = shift_in << 15; 6'b010000: shift_out = shift_in << 16; 6'b010001: shift_out = shift_in << 17; 6'b010010: shift_out = shift_in << 18; 6'b010011: shift_out = shift_in << 19; 6'b010100: shift_out = shift_in << 20; 6'b010101: shift_out = shift_in << 21; 6'b010110: shift_out = shift_in << 22; 6'b010111: shift_out = shift_in << 23; 6'b011000: shift_out = shift_in << 24; 6'b011001: shift_out = shift_in << 25; 6'b011010: shift_out = shift_in << 26; 6'b011011: shift_out = shift_in << 27; 6'b011100: shift_out = shift_in << 28; 6'b011101: shift_out = shift_in << 29; 6'b011110: shift_out = shift_in << 30; 6'b011111: shift_out = shift_in << 31; 6'b100000: shift_out = shift_in << 32; 6'b100001: shift_out = shift_in << 33; 6'b100010: shift_out = shift_in << 34; 6'b100011: shift_out = shift_in << 35; 6'b100100: shift_out = shift_in << 36; 6'b100101: shift_out = shift_in << 37; 6'b100110: shift_out = shift_in << 38; 6'b100111: shift_out = shift_in << 39; 6'b101000: shift_out = shift_in << 40; 6'b101001: shift_out = shift_in << 41; 6'b101010: shift_out = shift_in << 42; 6'b101011: shift_out = shift_in << 43; 6'b101100: shift_out = shift_in << 44; 6'b101101: shift_out = shift_in << 45; 6'b101110: shift_out = shift_in << 46; 6'b101111: shift_out = shift_in << 47; 6'b110000: shift_out = shift_in << 48; 6'b110001: shift_out = shift_in << 49; 6'b110010: shift_out = shift_in << 50; 6'b110011: shift_out = shift_in << 51; 6'b110100: shift_out = shift_in << 52; 6'b110101: shift_out = shift_in << 53; 6'b110110: shift_out = shift_in << 54; 6'b110111: shift_out = shift_in << 55; 6'b111000: shift_out = shift_in << 56; endcase end endmodule module fpu_add( clk, //rmode, opa, opb, out, control //inf, snan, qnan, ine, overflow, underflow, zero, div_by_zero ); input clk; //input [1:0] rmode; //input [2:0] fpu_op; input [31:0] opa, opb; output [31:0] out; /* output inf, snan, qnan; output ine; output overflow, underflow; output zero; output div_by_zero; */ output [7:0] control; /* parameter INF = 31'h7f800000; parameter QNAN = 31'h7fc00001; parameter SNAN = 31'h7f800001; */ wire [30:0] INF; assign INF = 31'h7f800000; wire [30:0] QNAN; assign QNAN = 31'h7fc00001; wire [30:0] SNAN; assign SNAN = 31'h7f800001; //////////////////////////////////////////////////////////////////////// // // Local Wires // reg [2:0] fpu_op; reg zero; reg [31:0] opa_r, opb_r; // Input operand registers reg [31:0] out; // Output register reg div_by_zero; // Divide by zero output register // wire signa, signb; // alias to opX sign wire sign_fasu; // sign output wire [26:0] fracta, fractb; // Fraction Outputs from EQU block wire [7:0] exp_fasu; // Exponent output from EQU block reg [7:0] exp_r; // Exponent output (registerd) wire [26:0] fract_out_d; // fraction output // wire co; // carry output reg [27:0] fract_out_q; // fraction output (registerd) wire [30:0] out_d; // Intermediate final result output wire overflow_d, underflow_d;// Overflow/Underflow Indicators reg overflow, underflow; // Output registers for Overflow & Underflow reg inf, snan, qnan; // Output Registers for INF, SNAN and QNAN reg ine; // Output Registers for INE reg [1:0] rmode_r1, rmode_r2, // Pipeline registers for rounding mode rmode_r3; reg [2:0] fpu_op_r1, fpu_op_r2, // Pipeline registers for fp opration fpu_op_r3; // wire mul_inf, div_inf; // wire mul_00, div_00; // start output_reg reg [31:0] out_o1; reg inf_o1, snan_o1, qnan_o1; reg ine_o1; reg overflow_o1, underflow_o1; reg zero_o1; reg div_by_zero_o1; // end output_reg wire [7:0] contorl; assign control = {inf, snan, qnan, ine, overflow, underflow, zero, div_by_zero}; wire [1:0] rmode; assign rmode= 2'b00; always@(posedge clk) begin fpu_op[2:0] <= 3'b000; end //////////////////////////////////////////////////////////////////////// // // Input Registers // always @(posedge clk) opa_r <= opa; always @(posedge clk) opb_r <= opb; always @(posedge clk) rmode_r1 <= rmode; always @(posedge clk) rmode_r2 <= rmode_r1; always @(posedge clk) rmode_r3 <= rmode_r2; always @(posedge clk) fpu_op_r1 <= fpu_op; always @(posedge clk) fpu_op_r2 <= fpu_op_r1; always @(posedge clk) fpu_op_r3 <= fpu_op_r2; //////////////////////////////////////////////////////////////////////// // // Exceptions block // wire inf_d, ind_d, qnan_d, snan_d, opa_nan, opb_nan; wire opa_00, opb_00; wire opa_inf, opb_inf; wire opa_dn, opb_dn; except u0( .clk(clk), .opa(opa_r), .opb(opb_r), .inf(inf_d), .ind(ind_d), .qnan(qnan_d), .snan(snan_d), .opa_nan(opa_nan), .opb_nan(opb_nan), .opa_00(opa_00), .opb_00(opb_00), .opa_inf(opa_inf), .opb_inf(opb_inf), .opa_dn(opa_dn), .opb_dn(opb_dn) ); //////////////////////////////////////////////////////////////////////// // // Pre-Normalize block // - Adjusts the numbers to equal exponents and sorts them // - determine result sign // - determine actual operation to perform (add or sub) // wire nan_sign_d, result_zero_sign_d; reg sign_fasu_r; wire fasu_op; wire add_input; assign add_input=!fpu_op_r1[0]; pre_norm u1(.clk(clk), // System Clock .rmode(rmode_r2), // Roundin Mode // .add(!fpu_op_r1[0]), // Add/Sub Input .add(add_input), .opa(opa_r), .opb(opb_r), // Registered OP Inputs .opa_nan(opa_nan), // OpA is a NAN indicator .opb_nan(opb_nan), // OpB is a NAN indicator .fracta_out(fracta), // Equalized and sorted fraction .fractb_out(fractb), // outputs (Registered) .exp_dn_out(exp_fasu), // Selected exponent output (registered); .sign(sign_fasu), // Encoded output Sign (registered) .nan_sign(nan_sign_d), // Output Sign for NANs (registered) .result_zero_sign(result_zero_sign_d), // Output Sign for zero result (registered) .fasu_op(fasu_op) // Actual fasu operation output (registered) ); always @(posedge clk) sign_fasu_r <= #1 sign_fasu; wire co_d; //////////////////////////////////////////////////////////////////////// // // Add/Sub // add_sub27 u3( .add(fasu_op), // Add/Sub .opa(fracta), // Fraction A input .opb(fractb), // Fraction B Input .sum(fract_out_d), // SUM output .co(co_d) ); // Carry Output always @(posedge clk) fract_out_q <= #1 {co_d, fract_out_d}; //////////////////////////////////////////////////////////////////////// // // Normalize Result // wire ine_d; //reg [47:0] fract_denorm; wire [47:0] fract_denorm; wire sign_d; reg sign; reg [30:0] opa_r1; reg [47:0] fract_i2f; reg opas_r1, opas_r2; wire f2i_out_sign; always @(posedge clk) // Exponent must be once cycle delayed exp_r <= #1 exp_fasu; always @(posedge clk) opa_r1 <= #1 opa_r[30:0]; //always @(fpu_op_r3 or fract_out_q) assign fract_denorm = {fract_out_q, 20'h0}; always @(posedge clk) opas_r1 <= #1 opa_r[31]; always @(posedge clk) opas_r2 <= #1 opas_r1; assign sign_d = sign_fasu; always @(posedge clk) sign <= #1 (rmode_r2==2'h3) ? !sign_d : sign_d; post_norm u4( //.clk(clk), // System Clock .fpu_op(fpu_op_r3), // Floating Point Operation .opas(opas_r2), // OPA Sign .sign(sign), // Sign of the result .rmode(rmode_r3), // Rounding mode .fract_in(fract_denorm), // Fraction Input .exp_in(exp_r), // Exponent Input .exp_ovf(2'b00), // Exponent Overflow .opa_dn(opa_dn), // Operand A Denormalized .opb_dn(opb_dn), // Operand A Denormalized .rem_00(1'b0), // Diveide Remainder is zero .div_opa_ldz(5'b00000), // Divide opa leading zeros count .output_zero(1'b0), // Force output to Zero .out(out_d), // Normalized output (un-registered) .ine(ine_d), // Result Inexact output (un-registered) .overflow(overflow_d), // Overflow output (un-registered) .underflow(underflow_d), // Underflow output (un-registered) .f2i_out_sign(f2i_out_sign) // F2I Output Sign ); //////////////////////////////////////////////////////////////////////// // // FPU Outputs // reg fasu_op_r1, fasu_op_r2; wire [30:0] out_fixed; wire output_zero_fasu; wire overflow_fasu; wire out_d_00; wire ine_fasu; wire underflow_fasu; reg opa_nan_r; always @(posedge clk) fasu_op_r1 <= #1 fasu_op; always @(posedge clk) fasu_op_r2 <= #1 fasu_op_r1; // Force pre-set values for non numerical output assign out_fixed = ( (qnan_d | snan_d) | (ind_d & !fasu_op_r2) ) ? QNAN : INF; always @(posedge clk) out_o1[30:0] <= #1 (inf_d | snan_d | qnan_d) ? out_fixed : out_d; assign out_d_00 = !(|out_d); always @(posedge clk) out_o1[31] <= #1 (snan_d | qnan_d | ind_d) ? nan_sign_d : output_zero_fasu ? result_zero_sign_d : sign_fasu_r; assign ine_fasu = (ine_d | overflow_d | underflow_d) & !(snan_d | qnan_d | inf_d); always @(posedge clk) ine_o1 <= #1 ine_fasu ; assign overflow_fasu = overflow_d & !(snan_d | qnan_d | inf_d); always @(posedge clk) overflow_o1 <= #1 overflow_fasu ; assign underflow_fasu = underflow_d & !(inf_d | snan_d | qnan_d); always @(posedge clk) underflow_o1 <= #1 underflow_fasu ; always @(posedge clk) snan_o1 <= #1 snan_d; // Status Outputs always @(posedge clk) qnan_o1 <= #1 ( snan_d | qnan_d | (ind_d & !fasu_op_r2) ); always @(posedge clk) inf_o1 <= #1 (!(qnan_d | snan_d) & (( (&out_d[30:23]) & !(|out_d[22:0] ) ) | (inf_d & !(ind_d & !fasu_op_r2) & !fpu_op_r3[1]) )); assign output_zero_fasu = out_d_00 & !(inf_d | snan_d | qnan_d); always @(posedge clk) zero_o1 <= #1 output_zero_fasu ; always @(posedge clk) opa_nan_r <= #1 !opa_nan & fpu_op_r2==3'b011; always @(posedge clk) div_by_zero_o1 <= #1 1'b0; // output register always @(posedge clk) begin qnan <= #1 qnan_o1; out <= #1 out_o1; inf <= #1 inf_o1; snan <= #1 snan_o1; //qnan <= #1 qnan_o1; ine <= #1 ine_o1; overflow <= #1 overflow_o1; underflow <= #1 underflow_o1; zero <= #1 zero_o1; div_by_zero <= #1 div_by_zero_o1; end endmodule //--------------------------------------------------------------------------------- module pre_norm(clk, rmode, add, opa, opb, opa_nan, opb_nan, fracta_out, fractb_out, exp_dn_out, sign, nan_sign, result_zero_sign, fasu_op); input clk; input [1:0] rmode; input add; input [31:0] opa, opb; input opa_nan, opb_nan; output [26:0] fracta_out, fractb_out; output [7:0] exp_dn_out; output sign; output nan_sign, result_zero_sign; output fasu_op; // Operation Output //////////////////////////////////////////////////////////////////////// // // Local Wires and registers // wire signa, signb; // alias to opX sign wire [7:0] expa, expb; // alias to opX exponent wire [22:0] fracta, fractb; // alias to opX fraction wire expa_lt_expb; // expa is larger than expb indicator wire fractb_lt_fracta; // fractb is larger than fracta indicator reg [7:0] exp_dn_out; // de normalized exponent output wire [7:0] exp_small, exp_large; wire [7:0] exp_diff; // Numeric difference of the two exponents wire [22:0] adj_op; // Fraction adjustment: input wire [26:0] adj_op_tmp; wire [26:0] adj_op_out; // Fraction adjustment: output wire [26:0] fracta_n, fractb_n; // Fraction selection after normalizing wire [26:0] fracta_s, fractb_s; // Fraction Sorting out reg [26:0] fracta_out, fractb_out; // Fraction Output reg sign, sign_d; // Sign Output reg add_d; // operation (add/sub) reg fasu_op; // operation (add/sub) register wire expa_dn, expb_dn; reg sticky; reg result_zero_sign; reg add_r, signa_r, signb_r; wire [4:0] exp_diff_sft; wire exp_lt_27; wire op_dn; wire [26:0] adj_op_out_sft; reg fracta_lt_fractb, fracta_eq_fractb; wire nan_sign1; reg nan_sign; //////////////////////////////////////////////////////////////////////// // // Aliases // assign signa = opa[31]; assign signb = opb[31]; assign expa = opa[30:23]; assign expb = opb[30:23]; assign fracta = opa[22:0]; assign fractb = opb[22:0]; //////////////////////////////////////////////////////////////////////// // // Pre-Normalize exponents (and fractions) // assign expa_lt_expb = expa > expb; // expa is larger than expb // --------------------------------------------------------------------- // Normalize assign expa_dn = !(|expa); // opa denormalized assign expb_dn = !(|expb); // opb denormalized // --------------------------------------------------------------------- // Calculate the difference between the smaller and larger exponent wire [7:0] exp_diff1, exp_diff1a, exp_diff2; assign exp_small = expa_lt_expb ? expb : expa; assign exp_large = expa_lt_expb ? expa : expb; assign exp_diff1 = exp_large - exp_small; assign exp_diff1a = exp_diff1-8'h01; assign exp_diff2 = (expa_dn | expb_dn) ? exp_diff1a : exp_diff1; assign exp_diff = (expa_dn & expb_dn) ? 8'h0 : exp_diff2; always @(posedge clk) // If numbers are equal we should return zero exp_dn_out <= #1 (!add_d & expa==expb & fracta==fractb) ? 8'h0 : exp_large; // --------------------------------------------------------------------- // Adjust the smaller fraction assign op_dn = expa_lt_expb ? expb_dn : expa_dn; assign adj_op = expa_lt_expb ? fractb : fracta; wire temp1; assign temp1 = ~op_dn; //assign adj_op_tmp[26:0] = {~op_dn, adj_op, 3'b000}; // recover hidden bit (op_dn) assign adj_op_tmp[26:0] = {temp1, adj_op, 3'b000}; // recover hidden bit (op_dn) // adj_op_out is 27 bits wide, so can only be shifted 27 bits to the right assign exp_lt_27 = exp_diff > 8'd27; assign exp_diff_sft = exp_lt_27 ? 5'd27 : exp_diff[4:0]; //assign adj_op_out_sft = adj_op_tmp >> exp_diff_sft; b_right_shifter_new u7( .shift_in(adj_op_tmp), .shift_value(exp_diff_sft), .shift_out(adj_op_out_sft) ); wire temp2; assign temp2 = adj_op_out_sft[0] | sticky; //assign adj_op_out[26:0] = {adj_op_out_sft[26:1], adj_op_out_sft[0] | sticky }; assign adj_op_out[26:0] = {adj_op_out_sft[26:1], temp2 }; // --------------------------------------------------------------------- // Get truncated portion (sticky bit) always @(exp_diff_sft or adj_op_tmp) case(exp_diff_sft) // synopsys full_case parallel_case 5'd00: sticky = 1'h0; 5'd01: sticky = adj_op_tmp[0]; 5'd02: sticky = |adj_op_tmp[01:0]; 5'd03: sticky = |adj_op_tmp[02:0]; 5'd04: sticky = |adj_op_tmp[03:0]; 5'd05: sticky = |adj_op_tmp[04:0]; 5'd06: sticky = |adj_op_tmp[05:0]; 5'd07: sticky = |adj_op_tmp[06:0]; 5'd08: sticky = |adj_op_tmp[07:0]; 5'd09: sticky = |adj_op_tmp[08:0]; 5'd10: sticky = |adj_op_tmp[09:0]; 5'd11: sticky = |adj_op_tmp[10:0]; 5'd12: sticky = |adj_op_tmp[11:0]; 5'd13: sticky = |adj_op_tmp[12:0]; 5'd14: sticky = |adj_op_tmp[13:0]; 5'd15: sticky = |adj_op_tmp[14:0]; 5'd16: sticky = |adj_op_tmp[15:0]; 5'd17: sticky = |adj_op_tmp[16:0]; 5'd18: sticky = |adj_op_tmp[17:0]; 5'd19: sticky = |adj_op_tmp[18:0]; 5'd20: sticky = |adj_op_tmp[19:0]; 5'd21: sticky = |adj_op_tmp[20:0]; 5'd22: sticky = |adj_op_tmp[21:0]; 5'd23: sticky = |adj_op_tmp[22:0]; 5'd24: sticky = |adj_op_tmp[23:0]; 5'd25: sticky = |adj_op_tmp[24:0]; 5'd26: sticky = |adj_op_tmp[25:0]; 5'd27: sticky = |adj_op_tmp[26:0]; endcase // --------------------------------------------------------------------- // Select operands for add/sub (recover hidden bit) assign fracta_n = expa_lt_expb ? {~expa_dn, fracta, 3'b0} : adj_op_out; assign fractb_n = expa_lt_expb ? adj_op_out : {~expb_dn, fractb, 3'b0}; // --------------------------------------------------------------------- // Sort operands (for sub only) assign fractb_lt_fracta = fractb_n > fracta_n; // fractb is larger than fracta assign fracta_s = fractb_lt_fracta ? fractb_n : fracta_n; assign fractb_s = fractb_lt_fracta ? fracta_n : fractb_n; always @(posedge clk) fracta_out <= #1 fracta_s; always @(posedge clk) fractb_out <= #1 fractb_s; // --------------------------------------------------------------------- // Determine sign for the output // sign: 0=Positive Number; 1=Negative Number always @(signa or signb or add or fractb_lt_fracta) case({signa, signb, add}) // synopsys full_case parallel_case // Add 3'b001: sign_d = 0; 3'b011: sign_d = fractb_lt_fracta; 3'b101: sign_d = !fractb_lt_fracta; 3'b111: sign_d = 1; // Sub 3'b000: sign_d = fractb_lt_fracta; 3'b010: sign_d = 0; 3'b100: sign_d = 1; 3'b110: sign_d = !fractb_lt_fracta; endcase always @(posedge clk) sign <= #1 sign_d; // Fix sign for ZERO result always @(posedge clk) signa_r <= #1 signa; always @(posedge clk) signb_r <= #1 signb; always @(posedge clk) add_r <= #1 add; always @(posedge clk) result_zero_sign <= #1 ( add_r & signa_r & signb_r) | (!add_r & signa_r & !signb_r) | ( add_r & (signa_r | signb_r) & (rmode==3)) | (!add_r & (signa_r == signb_r) & (rmode==3)); // Fix sign for NAN result always @(posedge clk) fracta_lt_fractb <= #1 fracta < fractb; always @(posedge clk) fracta_eq_fractb <= #1 fracta == fractb; assign nan_sign1 = fracta_eq_fractb ? (signa_r & signb_r) : fracta_lt_fractb ? signb_r : signa_r; always @(posedge clk) nan_sign <= #1 (opa_nan & opb_nan) ? nan_sign1 : opb_nan ? signb_r : signa_r; //////////////////////////////////////////////////////////////////////// // // Decode Add/Sub operation // // add: 1=Add; 0=Subtract always @(signa or signb or add) case({signa, signb, add}) // synopsys full_case parallel_case // Add 3'b001: add_d = 1; 3'b011: add_d = 0; 3'b101: add_d = 0; 3'b111: add_d = 1; // Sub 3'b000: add_d = 0; 3'b010: add_d = 1; 3'b100: add_d = 1; 3'b110: add_d = 0; endcase always @(posedge clk) fasu_op <= #1 add_d; endmodule module b_right_shifter_new ( shift_in, shift_value, shift_out ); input [26:0] shift_in; input [4:0] shift_value; output [26:0] shift_out; reg [47:0] shift_out; always @(shift_value) begin case (shift_value) 5'b00000: shift_out = shift_in; 5'b00001: shift_out = shift_in >> 1; 5'b00010: shift_out = shift_in >> 2; 5'b00011: shift_out = shift_in >> 3; 5'b00100: shift_out = shift_in >> 4; 5'b00101: shift_out = shift_in >> 5; 5'b00110: shift_out = shift_in >> 6; 5'b00111: shift_out = shift_in >> 7; 5'b01000: shift_out = shift_in >> 8; 5'b01001: shift_out = shift_in >> 9; 5'b01010: shift_out = shift_in >> 10; 5'b01011: shift_out = shift_in >> 11; 5'b01100: shift_out = shift_in >> 12; 5'b01101: shift_out = shift_in >> 13; 5'b01110: shift_out = shift_in >> 14; 5'b01111: shift_out = shift_in >> 15; 5'b10000: shift_out = shift_in >> 16; 5'b10001: shift_out = shift_in >> 17; 5'b10010: shift_out = shift_in >> 18; 5'b10011: shift_out = shift_in >> 19; 5'b10100: shift_out = shift_in >> 20; 5'b10101: shift_out = shift_in >> 21; 5'b10110: shift_out = shift_in >> 22; 5'b10111: shift_out = shift_in >> 23; 5'b11000: shift_out = shift_in >> 24; 5'b11001: shift_out = shift_in >> 25; 5'b11010: shift_out = shift_in >> 26; 5'b11011: shift_out = shift_in >> 27; endcase end endmodule //---------------------------------------------------------------------------- //////////////////////////////////////////////////////////////////////// // // Add/Sub // module add_sub27(add, opa, opb, sum, co); input add; input [26:0] opa, opb; output [26:0] sum; output co; assign {co, sum} = add ? ({1'b0, opa} + {1'b0, opb}) : ({1'b0, opa} - {1'b0, opb}); endmodule

////////////////////////////////////////////////////////////////////// //// //// //// spi_clgen.v //// //// //// //// This file is part of the SPI IP core project //// //// http://www.opencores.org/projects/spi/ //// //// //// //// Author(s): //// //// - Simon Srot ([email protected]) //// //// //// //// All additional information is avaliable in the Readme.txt //// //// file. //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2002 Authors //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source is distributed in the hope that it will be //// //// useful, but WITHOUT ANY WARRANTY; without even the implied //// //// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR //// //// PURPOSE. See the GNU Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// module spi_clgen (clk_in, rst, go, enable, last_clk, divider, clk_out, pos_edge, neg_edge); parameter Tp = 1; input clk_in; // input clock (system clock) input rst; // reset input enable; // clock enable input go; // start transfer input last_clk; // last clock input [3:0] divider; // clock divider (output clock is divided by this value) output clk_out; // output clock output pos_edge; // pulse marking positive edge of clk_out output neg_edge; // pulse marking negative edge of clk_out reg clk_out; reg pos_edge; reg neg_edge; reg [3:0] cnt; // clock counter wire cnt_zero; // conter is equal to zero wire cnt_one; // conter is equal to one assign cnt_zero = cnt == {4{1'b0}}; assign cnt_one = cnt == {{3{1'b0}}, 1'b1}; // Counter counts half period always @(posedge clk_in or posedge rst) begin if(rst) cnt <= #Tp {4{1'b1}}; else begin if(!enable || cnt_zero) cnt <= #Tp divider; else cnt <= #Tp cnt - {{3{1'b0}}, 1'b1}; end end // clk_out is asserted every other half period always @(posedge clk_in or posedge rst) begin if(rst) clk_out <= #Tp 1'b0; else clk_out <= #Tp (enable && cnt_zero && (!last_clk || clk_out)) ? ~clk_out : clk_out; end // Pos and neg edge signals always @(posedge clk_in or posedge rst) begin if(rst) begin pos_edge <= #Tp 1'b0; neg_edge <= #Tp 1'b0; end else begin pos_edge <= #Tp (enable && !clk_out && cnt_one) || (!(|divider) && clk_out) || (!(|divider) && go && !enable); neg_edge <= #Tp (enable && clk_out && cnt_one) || (!(|divider) && !clk_out && enable); end end endmodule

/** * Copyright 2020 The SkyWater PDK Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 */ `ifndef SKY130_FD_SC_LS__INV_4_V `define SKY130_FD_SC_LS__INV_4_V /** * inv: Inverter. * * Verilog wrapper for inv with size of 4 units. * * WARNING: This file is autogenerated, do not modify directly! */ `timescale 1ns / 1ps `default_nettype none `include "sky130_fd_sc_ls__inv.v" `ifdef USE_POWER_PINS /*********************************************************/ `celldefine module sky130_fd_sc_ls__inv_4 ( Y , A , VPWR, VGND, VPB , VNB ); output Y ; input A ; input VPWR; input VGND; input VPB ; input VNB ; sky130_fd_sc_ls__inv base ( .Y(Y), .A(A), .VPWR(VPWR), .VGND(VGND), .VPB(VPB), .VNB(VNB) ); endmodule `endcelldefine /*********************************************************/ `else // If not USE_POWER_PINS /*********************************************************/ `celldefine module sky130_fd_sc_ls__inv_4 ( Y, A ); output Y; input A; // Voltage supply signals supply1 VPWR; supply0 VGND; supply1 VPB ; supply0 VNB ; sky130_fd_sc_ls__inv base ( .Y(Y), .A(A) ); endmodule `endcelldefine /*********************************************************/ `endif // USE_POWER_PINS `default_nettype wire `endif // SKY130_FD_SC_LS__INV_4_V

// Copyright 1986-2016 Xilinx, Inc. All Rights Reserved. // -------------------------------------------------------------------------------- // Tool Version: Vivado v.2016.4 (win64) Build 1733598 Wed Dec 14 22:35:39 MST 2016 // Date : Tue Jun 06 02:45:58 2017 // Host : GILAMONSTER running 64-bit major release (build 9200) // Command : write_verilog -force -mode synth_stub // c:/ZyboIP/examples/zed_dual_fusion/zed_dual_fusion.srcs/sources_1/bd/system/ip/system_vga_transform_0_0/system_vga_transform_0_0_stub.v // Design : system_vga_transform_0_0 // Purpose : Stub declaration of top-level module interface // Device : xc7z020clg484-1 // -------------------------------------------------------------------------------- // This empty module with port declaration file causes synthesis tools to infer a black box for IP. // The synthesis directives are for Synopsys Synplify support to prevent IO buffer insertion. // Please paste the declaration into a Verilog source file or add the file as an additional source. (* x_core_info = "vga_transform,Vivado 2016.4" *) module system_vga_transform_0_0(clk, enable, x_addr_in, y_addr_in, rot_m00, rot_m01, rot_m10, rot_m11, t_x, t_y, x_addr_out, y_addr_out) /* synthesis syn_black_box black_box_pad_pin="clk,enable,x_addr_in[9:0],y_addr_in[9:0],rot_m00[15:0],rot_m01[15:0],rot_m10[15:0],rot_m11[15:0],t_x[9:0],t_y[9:0],x_addr_out[9:0],y_addr_out[9:0]" */; input clk; input enable; input [9:0]x_addr_in; input [9:0]y_addr_in; input [15:0]rot_m00; input [15:0]rot_m01; input [15:0]rot_m10; input [15:0]rot_m11; input [9:0]t_x; input [9:0]t_y; output [9:0]x_addr_out; output [9:0]y_addr_out; endmodule

// (C) 2001-2017 Intel Corporation. All rights reserved. // Your use of Intel Corporation's design tools, logic functions and other // software and tools, and its AMPP partner logic functions, and any output // files from any of the foregoing (including device programming or simulation // files), and any associated documentation or information are expressly subject // to the terms and conditions of the Intel Program License Subscription // Agreement, Intel FPGA IP License Agreement, or other applicable // license agreement, including, without limitation, that your use is for the // sole purpose of programming logic devices manufactured by Intel and sold by // Intel or its authorized distributors. Please refer to the applicable // agreement for further details. // $Id: //acds/main/ip/sopc/components/primitives/altera_std_synchronizer/altera_std_synchronizer.v#8 $ // $Revision: #8 $ // $Date: 2009/02/18 $ // $Author: pscheidt $ //----------------------------------------------------------------------------- // // File: altera_std_synchronizer_nocut.v // // Abstract: Single bit clock domain crossing synchronizer. Exactly the same // as altera_std_synchronizer.v, except that the embedded false // path constraint is removed in this module. If you use this // module, you will have to apply the appropriate timing // constraints. // // We expect to make this a standard Quartus atom eventually. // // Composed of two or more flip flops connected in series. // Random metastable condition is simulated when the // __ALTERA_STD__METASTABLE_SIM macro is defined. // Use +define+__ALTERA_STD__METASTABLE_SIM argument // on the Verilog simulator compiler command line to // enable this mode. In addition, define the macro // __ALTERA_STD__METASTABLE_SIM_VERBOSE to get console output // with every metastable event generated in the synchronizer. // // Copyright (C) Altera Corporation 2009, All Rights Reserved //----------------------------------------------------------------------------- `timescale 1ns / 1ns module altera_std_synchronizer_nocut ( clk, reset_n, din, dout ); parameter depth = 3; // This value must be >= 2 ! parameter rst_value = 0; input clk; input reset_n; input din; output dout; // QuartusII synthesis directives: // 1. Preserve all registers ie. do not touch them. // 2. Do not merge other flip-flops with synchronizer flip-flops. // QuartusII TimeQuest directives: // 1. Identify all flip-flops in this module as members of the synchronizer // to enable automatic metastability MTBF analysis. (* altera_attribute = {"-name ADV_NETLIST_OPT_ALLOWED NEVER_ALLOW; -name SYNCHRONIZER_IDENTIFICATION FORCED; -name DONT_MERGE_REGISTER ON; -name PRESERVE_REGISTER ON "} *) reg din_s1; (* altera_attribute = {"-name ADV_NETLIST_OPT_ALLOWED NEVER_ALLOW; -name DONT_MERGE_REGISTER ON; -name PRESERVE_REGISTER ON"} *) reg [depth-2:0] dreg; //synthesis translate_off initial begin if (depth <2) begin $display("%m: Error: synchronizer length: %0d less than 2.", depth); end end // the first synchronizer register is either a simple D flop for synthesis // and non-metastable simulation or a D flop with a method to inject random // metastable events resulting in random delay of [0,1] cycles `ifdef __ALTERA_STD__METASTABLE_SIM reg[31:0] RANDOM_SEED = 123456; wire next_din_s1; wire dout; reg din_last; reg random; event metastable_event; // hook for debug monitoring initial begin $display("%m: Info: Metastable event injection simulation mode enabled"); end always @(posedge clk) begin if (reset_n == 0) random <= $random(RANDOM_SEED); else random <= $random; end assign next_din_s1 = (din_last ^ din) ? random : din; always @(posedge clk or negedge reset_n) begin if (reset_n == 0) din_last <= (rst_value == 0)? 1'b0 : 1'b1; else din_last <= din; end always @(posedge clk or negedge reset_n) begin if (reset_n == 0) din_s1 <= (rst_value == 0)? 1'b0 : 1'b1; else din_s1 <= next_din_s1; end `else //synthesis translate_on generate if (rst_value == 0) always @(posedge clk or negedge reset_n) begin if (reset_n == 0) din_s1 <= 1'b0; else din_s1 <= din; end endgenerate generate if (rst_value == 1) always @(posedge clk or negedge reset_n) begin if (reset_n == 0) din_s1 <= 1'b1; else din_s1 <= din; end endgenerate //synthesis translate_off `endif `ifdef __ALTERA_STD__METASTABLE_SIM_VERBOSE always @(*) begin if (reset_n && (din_last != din) && (random != din)) begin $display("%m: Verbose Info: metastable event @ time %t", $time); ->metastable_event; end end `endif //synthesis translate_on // the remaining synchronizer registers form a simple shift register // of length depth-1 generate if (rst_value == 0) if (depth < 3) begin always @(posedge clk or negedge reset_n) begin if (reset_n == 0) dreg <= {depth-1{1'b0}}; else dreg <= din_s1; end end else begin always @(posedge clk or negedge reset_n) begin if (reset_n == 0) dreg <= {depth-1{1'b0}}; else dreg <= {dreg[depth-3:0], din_s1}; end end endgenerate generate if (rst_value == 1) if (depth < 3) begin always @(posedge clk or negedge reset_n) begin if (reset_n == 0) dreg <= {depth-1{1'b1}}; else dreg <= din_s1; end end else begin always @(posedge clk or negedge reset_n) begin if (reset_n == 0) dreg <= {depth-1{1'b1}}; else dreg <= {dreg[depth-3:0], din_s1}; end end endgenerate assign dout = dreg[depth-2]; endmodule

module paddle_control( input clock, reset, enable, rotary_event, rotary_right, input [4:0] speed, input [5:0] radius, input middle, output reg [9:0] paddle_x, paddle_y ); localparam PD_H = 8; localparam MAXX = 320; localparam MAXY = 480; localparam LEFT = 160; localparam TOP = 0; reg [9:0] next_x, next_y; always @(*) begin if (middle) paddle_y = TOP+MAXY/2-PD_H; else paddle_y = TOP+MAXY-PD_H; end always @(posedge clock) begin if (reset) begin paddle_x <= LEFT + MAXX/2; end else begin paddle_x <= next_x; end end always @(*) begin if (enable && rotary_event) begin if (rotary_right) begin if (paddle_x + radius + speed < LEFT + MAXX) next_x = paddle_x + radius + speed; else next_x = LEFT + MAXX - radius; end else begin if (paddle_x > LEFT + radius + speed) next_x = paddle_x - radius - speed; else next_x = LEFT + radius; end end else begin if (paddle_x + radius >= LEFT + MAXX) next_x = LEFT + MAXX - radius; else if (paddle_x < LEFT + radius) next_x = LEFT + radius; else next_x = paddle_x; end end endmodule

/* * PicoSoC - A simple example SoC using PicoRV32 * * Copyright (C) 2017 Claire Xenia Wolf <[email protected]> * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. * */ module hx8kdemo ( input clk, output ser_tx, input ser_rx, output [7:0] leds, output flash_csb, output flash_clk, inout flash_io0, inout flash_io1, inout flash_io2, inout flash_io3, output debug_ser_tx, output debug_ser_rx, output debug_flash_csb, output debug_flash_clk, output debug_flash_io0, output debug_flash_io1, output debug_flash_io2, output debug_flash_io3 ); reg [5:0] reset_cnt = 0; wire resetn = &reset_cnt; always @(posedge clk) begin reset_cnt <= reset_cnt + !resetn; end wire flash_io0_oe, flash_io0_do, flash_io0_di; wire flash_io1_oe, flash_io1_do, flash_io1_di; wire flash_io2_oe, flash_io2_do, flash_io2_di; wire flash_io3_oe, flash_io3_do, flash_io3_di; SB_IO #( .PIN_TYPE(6'b 1010_01), .PULLUP(1'b 0) ) flash_io_buf [3:0] ( .PACKAGE_PIN({flash_io3, flash_io2, flash_io1, flash_io0}), .OUTPUT_ENABLE({flash_io3_oe, flash_io2_oe, flash_io1_oe, flash_io0_oe}), .D_OUT_0({flash_io3_do, flash_io2_do, flash_io1_do, flash_io0_do}), .D_IN_0({flash_io3_di, flash_io2_di, flash_io1_di, flash_io0_di}) ); wire iomem_valid; reg iomem_ready; wire [3:0] iomem_wstrb; wire [31:0] iomem_addr; wire [31:0] iomem_wdata; reg [31:0] iomem_rdata; reg [31:0] gpio; assign leds = gpio; always @(posedge clk) begin if (!resetn) begin gpio <= 0; end else begin iomem_ready <= 0; if (iomem_valid && !iomem_ready && iomem_addr[31:24] == 8'h 03) begin iomem_ready <= 1; iomem_rdata <= gpio; if (iomem_wstrb[0]) gpio[ 7: 0] <= iomem_wdata[ 7: 0]; if (iomem_wstrb[1]) gpio[15: 8] <= iomem_wdata[15: 8]; if (iomem_wstrb[2]) gpio[23:16] <= iomem_wdata[23:16]; if (iomem_wstrb[3]) gpio[31:24] <= iomem_wdata[31:24]; end end end picosoc soc ( .clk (clk ), .resetn (resetn ), .ser_tx (ser_tx ), .ser_rx (ser_rx ), .flash_csb (flash_csb ), .flash_clk (flash_clk ), .flash_io0_oe (flash_io0_oe), .flash_io1_oe (flash_io1_oe), .flash_io2_oe (flash_io2_oe), .flash_io3_oe (flash_io3_oe), .flash_io0_do (flash_io0_do), .flash_io1_do (flash_io1_do), .flash_io2_do (flash_io2_do), .flash_io3_do (flash_io3_do), .flash_io0_di (flash_io0_di), .flash_io1_di (flash_io1_di), .flash_io2_di (flash_io2_di), .flash_io3_di (flash_io3_di), .irq_5 (1'b0 ), .irq_6 (1'b0 ), .irq_7 (1'b0 ), .iomem_valid (iomem_valid ), .iomem_ready (iomem_ready ), .iomem_wstrb (iomem_wstrb ), .iomem_addr (iomem_addr ), .iomem_wdata (iomem_wdata ), .iomem_rdata (iomem_rdata ) ); assign debug_ser_tx = ser_tx; assign debug_ser_rx = ser_rx; assign debug_flash_csb = flash_csb; assign debug_flash_clk = flash_clk; assign debug_flash_io0 = flash_io0_di; assign debug_flash_io1 = flash_io1_di; assign debug_flash_io2 = flash_io2_di; assign debug_flash_io3 = flash_io3_di; endmodule

/* * Milkymist SoC * Copyright (C) 2007, 2008, 2009, 2010, 2011 Sebastien Bourdeauducq * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, version 3 of the License. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see <http://www.gnu.org/licenses/>. */ module conbus_arb5( input sys_clk, input sys_rst, input [4:0] req, output [2:0] gnt ); reg [2:0] state; reg [2:0] next_state; assign gnt = state; always @(posedge sys_clk) begin if(sys_rst) state <= 3'd0; else state <= next_state; end always @(*) begin next_state = state; case(state) 3'd0: begin if(~req[0]) begin if(req[1]) next_state = 3'd1; else if(req[2]) next_state = 3'd2; else if(req[3]) next_state = 3'd3; else if(req[4]) next_state = 3'd4; end end 3'd1: begin if(~req[1]) begin if(req[2]) next_state = 3'd2; else if(req[3]) next_state = 3'd3; else if(req[4]) next_state = 3'd4; else if(req[0]) next_state = 3'd0; end end 3'd2: begin if(~req[2]) begin if(req[3]) next_state = 3'd3; else if(req[4]) next_state = 3'd4; else if(req[0]) next_state = 3'd0; else if(req[1]) next_state = 3'd1; end end 3'd3: begin if(~req[3]) begin if(req[4]) next_state = 3'd4; else if(req[0]) next_state = 3'd0; else if(req[1]) next_state = 3'd1; else if(req[2]) next_state = 3'd2; end end 3'd4: begin if(~req[4]) begin if(req[0]) next_state = 3'd0; else if(req[1]) next_state = 3'd1; else if(req[2]) next_state = 3'd2; else if(req[3]) next_state = 3'd3; end end endcase end endmodule

// // Copyright 2011-2012 Ettus Research LLC // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see <http://www.gnu.org/licenses/>. // module vita_tx_chain #(parameter BASE=0, parameter FIFOSIZE=10, parameter POST_ENGINE_FIFOSIZE=10, parameter REPORT_ERROR=0, parameter DO_FLOW_CONTROL=0, parameter PROT_ENG_FLAGS=0, parameter USE_TRANS_HEADER=0, parameter DSP_NUMBER=0) (input clk, input reset, input set_stb, input [7:0] set_addr, input [31:0] set_data, input set_stb_user, input [7:0] set_addr_user, input [31:0] set_data_user, input [63:0] vita_time, input [35:0] tx_data_i, input tx_src_rdy_i, output tx_dst_rdy_o, output [35:0] err_data_o, output err_src_rdy_o, input err_dst_rdy_i, output [31:0] sample, input strobe, output underrun, output run, output clear_o, output [31:0] debug); localparam MAXCHAN = 1; localparam FIFOWIDTH = 5+64+16+(32*MAXCHAN); wire [FIFOWIDTH-1:0] tx1_data; wire tx1_src_rdy, tx1_dst_rdy; wire [31:0] streamid, message; wire trigger, sent; wire [31:0] debug_vtc, debug_vtd, debug_tx_dsp; wire error, packet_consumed, ack; wire [31:0] error_code; wire clear_seqnum; wire [31:0] current_seqnum; wire clear, flush; assign clear_o = clear; assign underrun = error; assign message = error_code; setting_reg #(.my_addr(BASE+0), .width(1)) sr (.clk(clk),.rst(reset),.strobe(set_stb),.addr(set_addr), .in(set_data),.out(flush),.changed(clear)); setting_reg #(.my_addr(BASE+2), .at_reset(0)) sr_streamid (.clk(clk),.rst(reset),.strobe(set_stb),.addr(set_addr), .in(set_data),.out(streamid),.changed(clear_seqnum)); //flush control - full rate vacuum of input until flush cleared wire tx_dst_rdy_int, tx_src_rdy_int; wire [35:0] tx_data_int; valve36 flusher_valve (.clk(clk), .reset(reset), .clear(clear & flush), .shutoff(flush), .data_i(tx_data_i), .src_rdy_i(tx_src_rdy_i), .dst_rdy_o(tx_dst_rdy_o), .data_o(tx_data_int), .src_rdy_o(tx_src_rdy_int), .dst_rdy_i(tx_dst_rdy_int)); wire [35:0] tx_data_int1; wire tx_src_rdy_int1, tx_dst_rdy_int1; generate if (FIFOSIZE==0) begin assign tx_data_int1 = tx_data_int; assign tx_src_rdy_int1 = tx_src_rdy_int; assign tx_dst_rdy_int = tx_dst_rdy_int1; end else begin wire [FIFOSIZE-1:0] access_adr, access_len; wire access_we, access_stb, access_ok, access_done, access_skip_read; wire [35:0] dsp_to_buf, buf_to_dsp; wire [35:0] tx_data_int0; wire tx_src_rdy_int0, tx_dst_rdy_int0; double_buffer #(.BUF_SIZE(FIFOSIZE)) db (.clk(clk),.reset(reset),.clear(clear), .access_we(access_we), .access_stb(access_stb), .access_ok(access_ok), .access_done(access_done), .access_skip_read(access_skip_read), .access_adr(access_adr), .access_len(access_len), .access_dat_i(dsp_to_buf), .access_dat_o(buf_to_dsp), .data_i(tx_data_int), .src_rdy_i(tx_src_rdy_int), .dst_rdy_o(tx_dst_rdy_int), .data_o(tx_data_int0), .src_rdy_o(tx_src_rdy_int0), .dst_rdy_i(tx_dst_rdy_int0)); vita_tx_engine_glue #(.DSPNO(DSP_NUMBER), .MAIN_SETTINGS_BASE(BASE+1), .BUF_SIZE(FIFOSIZE), .HEADER_OFFSET(USE_TRANS_HEADER)) dspengine_tx (.clock(clk),.reset(reset),.clear(clear), .set_stb_main(set_stb), .set_addr_main(set_addr), .set_data_main(set_data), .set_stb_user(set_stb_user), .set_addr_user(set_addr_user), .set_data_user(set_data_user), .access_we(access_we), .access_stb(access_stb), .access_ok(access_ok), .access_done(access_done), .access_skip_read(access_skip_read), .access_adr(access_adr), .access_len(access_len), .access_dat_i(buf_to_dsp), .access_dat_o(dsp_to_buf)); fifo_cascade #(.WIDTH(36), .SIZE(POST_ENGINE_FIFOSIZE)) post_engine_buffering( .clk(clk), .reset(reset), .clear(clear), .datain(tx_data_int0), .src_rdy_i(tx_src_rdy_int0), .dst_rdy_o(tx_dst_rdy_int0), .dataout(tx_data_int1), .src_rdy_o(tx_src_rdy_int1), .dst_rdy_i(tx_dst_rdy_int1)); end endgenerate vita_tx_deframer #(.BASE(BASE), .MAXCHAN(MAXCHAN), .USE_TRANS_HEADER(USE_TRANS_HEADER)) vita_tx_deframer (.clk(clk), .reset(reset), .clear(clear), .clear_seqnum(clear_seqnum), .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data), .data_i(tx_data_int1), .src_rdy_i(tx_src_rdy_int1), .dst_rdy_o(tx_dst_rdy_int1), .sample_fifo_o(tx1_data), .sample_fifo_src_rdy_o(tx1_src_rdy), .sample_fifo_dst_rdy_i(tx1_dst_rdy), .current_seqnum(current_seqnum), .debug(debug_vtd) ); vita_tx_control #(.BASE(BASE), .WIDTH(32*MAXCHAN)) vita_tx_control (.clk(clk), .reset(reset), .clear(clear), .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data), .vita_time(vita_time), .error(error), .ack(ack), .error_code(error_code), .sample_fifo_i(tx1_data), .sample_fifo_src_rdy_i(tx1_src_rdy), .sample_fifo_dst_rdy_o(tx1_dst_rdy), .sample(sample), .run(run), .strobe(strobe), .packet_consumed(packet_consumed), .debug(debug_vtc) ); wire [35:0] flow_data, err_data_int; wire flow_src_rdy, flow_dst_rdy, err_src_rdy_int, err_dst_rdy_int; gen_context_pkt #(.PROT_ENG_FLAGS(PROT_ENG_FLAGS),.DSP_NUMBER(DSP_NUMBER)) gen_flow_pkt (.clk(clk), .reset(reset), .clear(clear), .trigger(trigger & (DO_FLOW_CONTROL==1)), .sent(), .streamid(streamid), .vita_time(vita_time), .message(32'd0), .seqnum(current_seqnum), .data_o(flow_data), .src_rdy_o(flow_src_rdy), .dst_rdy_i(flow_dst_rdy)); trigger_context_pkt #(.BASE(BASE)) trigger_context_pkt (.clk(clk), .reset(reset), .clear(clear), .set_stb(set_stb),.set_addr(set_addr),.set_data(set_data), .packet_consumed(packet_consumed), .trigger(trigger)); gen_context_pkt #(.PROT_ENG_FLAGS(PROT_ENG_FLAGS),.DSP_NUMBER(DSP_NUMBER)) gen_tx_err_pkt (.clk(clk), .reset(reset), .clear(clear), .trigger((error|ack) & (REPORT_ERROR==1)), .sent(), .streamid(streamid), .vita_time(vita_time), .message(message), .seqnum(current_seqnum), .data_o(err_data_int), .src_rdy_o(err_src_rdy_int), .dst_rdy_i(err_dst_rdy_int)); assign debug = debug_vtc | debug_vtd; fifo36_mux #(.prio(1)) mux_err_and_flow // Priority to err messages (.clk(clk), .reset(reset), .clear(0), // Don't clear this or it could get clogged .data0_i(err_data_int), .src0_rdy_i(err_src_rdy_int), .dst0_rdy_o(err_dst_rdy_int), .data1_i(flow_data), .src1_rdy_i(flow_src_rdy), .dst1_rdy_o(flow_dst_rdy), .data_o(err_data_o), .src_rdy_o(err_src_rdy_o), .dst_rdy_i(err_dst_rdy_i)); endmodule // vita_tx_chain

module control ( start, clk, rst, data, data_out, parameter_Block parameter_Block2 ); input wire start; input wire clk; input wire rst; input wire [63:0] data; input wire [31:0] parameter_Block; input wire [63:0] parameter_Block2; output reg [63:0]data_out; reg [7:0] bmRequestType ; reg [7:0] bRequest ; reg [11:0] count; reg local; reg global; reg specific; reg [7:0] debug_Unit_ID; reg [7:0] interface_ID; reg [15:0] wValue; reg [15:0] wIndex; reg [15:0] wLength; reg [63:0] address; reg [63:0] dato; reg [3:0]state,next_state; parameter [3:0] IDLE = 4'b0001, RECEIVE = 4'b0010, SET = 4'b0011, GET = 4'b0100, DATA = 4'b0101, HANDSHAKE = 4'b0110, SETUP_TOKEN = 4'b0111, OUT_TOKEN = 4'b1000, IN_TOKEN = 4'b1001, ACK_TOKEN = 4'b1010; always @(posedge clk) begin case (state) IDLE : begin if (start== 0 ) next_state = IDLE; else begin next_state = RECEIVE; bmRequestType = data [63:55]; bRequest = data [55:47]; wValue = data [48:33]; wIndex = data [32:16]; wLength = data [15:0]; end end RECEIVE : begin if (bmRequestType == 8'b00100001 ) begin next_state = SET; end if (bmRequestType == 8'b00100001 ) begin next_state = GET; end end SET : begin if (bRequest == 8'h01 )//Set_config_data begin next_state = SET_CONFIG_DATA; /* if (wIndex[15:8] == 0) begin if (wValue[7:0] == 8'h00 ) // global DBclass begin global = 1 ; ext_state = GET; end if (wValue[7:0] == 8'h01 ) // global vendor begin //Si lector este tamaño lo define usted global = 1 ; end if (wValue[7:0] == 8'h02 ) // local DBclass begin local = 1 ; //ask for inter face end if (wValue[7:0] == 8'h03 ) // local vendor begin //ask for inter face //Si lector este tamaño lo define usted //this is the espace to selec your own local = 1 ; end end if (wIndex[15:8] == 0) begin if (wValue[7:0] == 8'h00 )// specific DBclass begin specific = 1 ; debug_Unit_ID = wIndex[15:8] ; interface_ID = wIndex[7:0] ; end if (wValue[7:0] == 8'h01 ) // specific vendor begin //Si lector este tamaño lo define usted debug_Unit_ID = wIndex[15:8] ; interface_ID = wIndex[7:0] ; specific = 1 ; end */ end end if (bRequest == 8'h02 )//set_config_data_single begin next_state = SET_CONFIG_DATA_SINGLE; end if (bRequest == 8'h03 )//set_config_address begin next_state = SET_CONFIG_ADDRESS; end if (bRequest == 8'h04 )//set_alt_stack begin next_state = SET_ALT_STACK; end if (bRequest == 8'h05 )//set_operating_mode begin // this is for allow the trace ,dfx,ect modes next_state = SET_OPERATING_MODE; end if (bRequest == 8'h06 )//set_trace begin next_state = SET_TRACE ; // this is for allow the trace ,dfx,ect modes end if (bRequest == 8'h09 )//set_buffer begin next_state = SET_BUFFER ; end if (bRequest == 8'h0A )//set_rest begin next_state = SET_RESET; end end GET : begin if (bRequest == 8'h81 ) //get_config data begin next_state = GET_CONFIG; end if (bRequest == 8'h82 ) //get_config data single begin next_state = GET_CONFIG_SINGLE; end if (bRequest == 8'h83 ) // get_config address begin next_state = GET_CONFIG_ADDRESS; end if (bRequest == 8'h84 ) // get_alt stack begin next_state = GET_ALT_STACK; end if (bRequest == 8'h85 ) //get oprating mode begin next_state = GET_OPERATION_MODE; end if (bRequest == 8'h86 ) //get_trace begin //this is no able next_state = GET_TRACE; end if (bRequest == 8'h87 ) //get_INFO begin /* bit support_capability 0 set_config data single 1 set config data 2 get config data 3 set config address 4 get config address 5 set alt stack 6 get alt stack 7 set operating mode 8 get operating mode 9 set trace configuration 10 get trace configuration 11 set buffer 12 get buffer 13 set reset 14-28 reseved set = 0 29 disable automatic mode 30 self generate control 31 slow control */ next_state = GET_INFO ; end if (bRequest == 8'h88 ) //get_error begin /*0x00: No error 0x01: Not ready 0x02: Wrong state 0x03: Insufficient Power Available 0x04: Max Power Violation 0x05: Operating-mode unavailable 0x06: Out of range 0x07: Invalid unit 0x08: Invalid control 0x09: Invalid Request 0x0A: Permission denied 0x0B-0xFE: reserved 0xFF: Unknown*/ end if (bRequest == 8'h89 ) //get_buffer begin end end SET_CONFIG_DATA_SINGLE : begin end SET_ALT_STACK : begin end SET_OPERATING_MODE : begin end SET_TRACE : begin end SET_BUFFER : begin end SET_RESET : begin end GET_CONFIG : begin end GET_CONFIG_SINGLE : begin end GET_CONFIG_ADDRESS : begin end GET_ALT_STACK : begin end GET_OPERATION_MODE : begin end GET_TRACE : begin end GET_INFO : begin end endcase end endmodule

`timescale 1ns / 1ps ////////////////////////////////////////////////////////////////////////////////// // Company: Case Western Reserve University // Engineer: Matt McConnell // // Create Date: 20:17:00 09/09/2017 // Project Name: EECS301 Digital Design // Design Name: Lab #4 Project // Module Name: FxP_ABS_Function // Target Devices: Altera Cyclone V // Tool versions: Quartus v17.0 // Description: Fixed Point Absolute Value Function // // Input Data in Fixed Point Two's Complement Format // Output Data is positive value integer // // Dependencies: // ////////////////////////////////////////////////////////////////////////////////// module FxP_ABS_Function #( parameter DATA_WIDTH = 16 ) ( // Data Signals input [DATA_WIDTH-1:0] DATA_IN, output [DATA_WIDTH-1:0] DATA_ABS ); // // Two's Complement Absolute Function // // If the sign-bit (MSB) is high, then // DATA_ABS = ~DATA_IN + 1'b1 // Else // DATA_ABS = DATA_IN // assign DATA_ABS = DATA_IN[DATA_WIDTH-1] ? ~DATA_IN + 1'b1 : DATA_IN; endmodule

// ---------------------------------------------------------------------- // Copyright (c) 2015, The Regents of the University of California All // rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following // disclaimer in the documentation and/or other materials provided // with the distribution. // // * Neither the name of The Regents of the University of California // nor the names of its contributors may be used to endorse or // promote products derived from this software without specific // prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL REGENTS OF THE // UNIVERSITY OF CALIFORNIA BE LIABLE FOR ANY DIRECT, INDIRECT, // INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, // BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS // OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND // ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR // TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE // USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH // DAMAGE. // ---------------------------------------------------------------------- //----------------------------------------------------------------------------- // Filename: tx_data_pipeline.v // Version: 1.0 // Verilog Standard: Verilog-2001 // // Description: The tx_data_fifo takes 0-bit aligned packet data and // puts each DW into one of N FIFOs where N = (C_DATA_WIDTH/32). // // The data interface (TX_DATA) is an interface for N 32-bit FIFOs, where N = // (C_DATA_WIDTH/32). The START_FLAG signal indicates that the first dword of // a packet is in FIFO 0 (TX_DATA[31:0]). Each FIFO interface also contains an // END_FLAG signal in the END_FLAGS bus. When a bit in END_FLAGS bus is asserted, // its corresponding fifo contains the last dword of data for the current // packet. START_FLAG, END_FLAG and DATA are all qualified by the VALID signal, // and read by the READY signal. // // The write interface (WR_TX) differs slightly from the read interface because it // produces a READY signal and consumes a VALID signal. VALID is asserted when an // entire packet has been packed into a FIFO. // // TODO: // - Make sure that the synthesis tool is removing the other three start // flag wires (and modifying the width of the FIFOs) // // Author: Dustin Richmond (@darichmond) //----------------------------------------------------------------------------- `timescale 1ns/1ns `include "trellis.vh" // Defines the user-facing signal widths. module tx_data_fifo #(parameter C_DEPTH_PACKETS = 10, parameter C_DATA_WIDTH = 128, parameter C_PIPELINE_INPUT = 1, parameter C_PIPELINE_OUTPUT = 1, parameter C_MAX_PAYLOAD = 256 // BYTES ) ( // Interface: Clocks input CLK, // Interface: Reset input RST_IN, // Interface: WR TX DATA input [C_DATA_WIDTH-1:0] WR_TX_DATA, input WR_TX_DATA_VALID, input WR_TX_DATA_START_FLAG, input [(C_DATA_WIDTH/32)-1:0] WR_TX_DATA_WORD_VALID, input [(C_DATA_WIDTH/32)-1:0] WR_TX_DATA_END_FLAGS, output WR_TX_DATA_READY, // Interface: RD TX DATA input [(C_DATA_WIDTH/32)-1:0] RD_TX_DATA_WORD_READY, output [C_DATA_WIDTH-1:0] RD_TX_DATA, output RD_TX_DATA_START_FLAG, output [(C_DATA_WIDTH/32)-1:0] RD_TX_DATA_END_FLAGS, output [(C_DATA_WIDTH/32)-1:0] RD_TX_DATA_WORD_VALID, output RD_TX_DATA_PACKET_VALID ); localparam C_FIFO_OUTPUT_DEPTH = 1; localparam C_INPUT_DEPTH = C_PIPELINE_INPUT != 0 ? 1 : 0; localparam C_OUTPUT_DEPTH = C_PIPELINE_OUTPUT != 0 ? 1 : 0; localparam C_MAXPACKET_LINES = (C_MAX_PAYLOAD*8)/C_DATA_WIDTH; localparam C_FIFO_DEPTH = C_MAXPACKET_LINES*C_DEPTH_PACKETS; localparam C_FIFO_DATA_WIDTH = 32; localparam C_REGISTER_WIDTH = C_FIFO_DATA_WIDTH + 2; localparam C_FIFO_WIDTH = C_FIFO_DATA_WIDTH + 2; // Data, end flag and start flag localparam C_NUM_FIFOS = (C_DATA_WIDTH/32); genvar i; wire RST; wire [C_FIFO_DATA_WIDTH-1:0] wWrTxData[C_NUM_FIFOS-1:0]; wire [C_NUM_FIFOS-1:0] wWrTxDataValid; wire [C_NUM_FIFOS-1:0] wWrTxDataReady; wire [C_NUM_FIFOS-1:0] wWrTxDataStartFlags; wire [C_NUM_FIFOS-1:0] wWrTxDataEndFlags; wire [C_NUM_FIFOS-1:0] _wRdTxDataStartFlags; wire [C_FIFO_DATA_WIDTH-1:0] wRdTxData[C_NUM_FIFOS-1:0]; wire [C_NUM_FIFOS-1:0] wRdTxDataValid; wire [C_NUM_FIFOS-1:0] wRdTxDataReady; wire [C_NUM_FIFOS-1:0] wRdTxDataStartFlags; wire [C_NUM_FIFOS-1:0] wRdTxDataEndFlags; wire wRdTxDataPacketValid; wire wWrTxEndFlagValid; wire wWrTxEndFlagReady; wire wRdTxEndFlagValid; wire wRdTxEndFlagReady; wire wPacketDecrement; wire wPacketIncrement; reg [clog2(C_DEPTH_PACKETS+1)-1:0] rPacketCounter,_rPacketCounter; /*AUTOINPUT*/ /*AUTOWIRE*/ ///*AUTOOUTPUT*/ assign RST = RST_IN; assign wWrTxEndFlagValid = (wWrTxDataEndFlags & wWrTxDataValid) != {C_NUM_FIFOS{1'b0}}; assign wWrTxEndFlagReady = rPacketCounter != C_DEPTH_PACKETS;// Designed a small bit of latency here to help timing... assign wPacketIncrement = wWrTxEndFlagValid & wWrTxEndFlagReady; assign wPacketDecrement = wRdTxEndFlagValid & wRdTxEndFlagReady; assign WR_TX_DATA_READY = wWrTxEndFlagReady; assign wRdTxEndFlagValid = rPacketCounter != 0; assign wRdTxEndFlagReady = (wRdTxDataReady & wRdTxDataEndFlags & wRdTxDataValid) != {C_NUM_FIFOS{1'b0}}; assign wRdTxDataPacketValid = rPacketCounter != 0; assign RD_TX_DATA_START_FLAG = _wRdTxDataStartFlags[0]; always @(*) begin _rPacketCounter = rPacketCounter; if(wPacketIncrement & wPacketDecrement) begin _rPacketCounter = rPacketCounter + 0; end else if(wPacketIncrement) begin _rPacketCounter = rPacketCounter + 1; end else if(wPacketDecrement) begin _rPacketCounter = rPacketCounter - 1; end end // always @ (*) always @(posedge CLK) begin if(RST_IN) begin rPacketCounter <= #1 0; end else begin rPacketCounter <= #1 _rPacketCounter; end end generate for( i = 0 ; i < C_NUM_FIFOS ; i = i + 1 ) begin : gen_regs_fifos pipeline #( .C_DEPTH (C_INPUT_DEPTH), .C_USE_MEMORY (0), .C_WIDTH (C_REGISTER_WIDTH) /*AUTOINSTPARAM*/) input_pipeline_inst_ ( // Outputs .WR_DATA_READY (), .RD_DATA ({wWrTxData[i], wWrTxDataEndFlags[i],wWrTxDataStartFlags[i]}), .RD_DATA_VALID (wWrTxDataValid[i]), // Inputs .CLK (CLK), .RST_IN (RST_IN), .WR_DATA ({WR_TX_DATA[C_FIFO_DATA_WIDTH*i +: C_FIFO_DATA_WIDTH], WR_TX_DATA_END_FLAGS[i], (i == 0) ? WR_TX_DATA_START_FLAG: 1'b0}), .WR_DATA_VALID (WR_TX_DATA_VALID & WR_TX_DATA_WORD_VALID[i]), .RD_DATA_READY (wWrTxDataReady[i])); fifo #( // Parameters .C_WIDTH (C_FIFO_WIDTH), .C_DEPTH (C_FIFO_DEPTH), .C_DELAY (0) /*AUTOINSTPARAM*/) fifo_inst_ ( // Outputs .RD_DATA ({wRdTxData[i], wRdTxDataStartFlags[i], wRdTxDataEndFlags[i]}), .WR_READY (wWrTxDataReady[i]), .RD_VALID (wRdTxDataValid[i]), // Inputs .WR_DATA ({wWrTxData[i], wWrTxDataStartFlags[i], wWrTxDataEndFlags[i]}), .WR_VALID (wWrTxDataValid[i]), .RD_READY (wRdTxDataReady[i]), /*AUTOINST*/ // Inputs .CLK (CLK), .RST (RST)); pipeline #( .C_DEPTH (C_FIFO_OUTPUT_DEPTH), .C_USE_MEMORY (0), .C_WIDTH (C_FIFO_WIDTH) /*AUTOINSTPARAM*/) fifo_pipeline_inst_ ( // Outputs .WR_DATA_READY (wRdTxDataReady[i]), .RD_DATA ({RD_TX_DATA[i*32 +: 32], _wRdTxDataStartFlags[i], RD_TX_DATA_END_FLAGS[i]}), .RD_DATA_VALID (RD_TX_DATA_WORD_VALID[i]), // Inputs .WR_DATA ({wRdTxData[i], wRdTxDataStartFlags[i], wRdTxDataEndFlags[i]}), .WR_DATA_VALID (wRdTxDataValid[i]), .RD_DATA_READY (RD_TX_DATA_WORD_READY[i]), /*AUTOINST*/ // Inputs .CLK (CLK), .RST_IN (RST_IN)); end // for ( i = 0 ; i < C_NUM_FIFOS ; i = i + 1 ) endgenerate endmodule // Local Variables: // verilog-library-directories:("." "../../common/") // End:

// $Header: /devl/xcs/repo/env/Databases/CAEInterfaces/verunilibs/data/glbl.v,v 1.14 2010/10/28 20:44:00 fphillip Exp $ `ifndef GLBL `define GLBL `timescale 1 ps / 1 ps module glbl (); parameter ROC_WIDTH = 100000; parameter TOC_WIDTH = 0; //-------- STARTUP Globals -------------- wire GSR; wire GTS; wire GWE; wire PRLD; tri1 p_up_tmp; tri (weak1, strong0) PLL_LOCKG = p_up_tmp; wire PROGB_GLBL; wire CCLKO_GLBL; wire FCSBO_GLBL; wire [3:0] DO_GLBL; wire [3:0] DI_GLBL; reg GSR_int; reg GTS_int; reg PRLD_int; //-------- JTAG Globals -------------- wire JTAG_TDO_GLBL; wire JTAG_TCK_GLBL; wire JTAG_TDI_GLBL; wire JTAG_TMS_GLBL; wire JTAG_TRST_GLBL; reg JTAG_CAPTURE_GLBL; reg JTAG_RESET_GLBL; reg JTAG_SHIFT_GLBL; reg JTAG_UPDATE_GLBL; reg JTAG_RUNTEST_GLBL; reg JTAG_SEL1_GLBL = 0; reg JTAG_SEL2_GLBL = 0 ; reg JTAG_SEL3_GLBL = 0; reg JTAG_SEL4_GLBL = 0; reg JTAG_USER_TDO1_GLBL = 1'bz; reg JTAG_USER_TDO2_GLBL = 1'bz; reg JTAG_USER_TDO3_GLBL = 1'bz; reg JTAG_USER_TDO4_GLBL = 1'bz; assign (weak1, weak0) GSR = GSR_int; assign (weak1, weak0) GTS = GTS_int; assign (weak1, weak0) PRLD = PRLD_int; initial begin GSR_int = 1'b1; PRLD_int = 1'b1; #(ROC_WIDTH) GSR_int = 1'b0; PRLD_int = 1'b0; end initial begin GTS_int = 1'b1; #(TOC_WIDTH) GTS_int = 1'b0; end endmodule `endif

// (c) Copyright 1995-2017 Xilinx, Inc. All rights reserved. // // This file contains confidential and proprietary information // of Xilinx, Inc. and is protected under U.S. and // international copyright and other intellectual property // laws. // // DISCLAIMER // This disclaimer is not a license and does not grant any // rights to the materials distributed herewith. Except as // otherwise provided in a valid license issued to you by // Xilinx, and to the maximum extent permitted by applicable // law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND // WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES // AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING // BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- // INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and // (2) Xilinx shall not be liable (whether in contract or tort, // including negligence, or under any other theory of // liability) for any loss or damage of any kind or nature // related to, arising under or in connection with these // materials, including for any direct, or any indirect, // special, incidental, or consequential loss or damage // (including loss of data, profits, goodwill, or any type of // loss or damage suffered as a result of any action brought // by a third party) even if such damage or loss was // reasonably foreseeable or Xilinx had been advised of the // possibility of the same. // // CRITICAL APPLICATIONS // Xilinx products are not designed or intended to be fail- // safe, or for use in any application requiring fail-safe // performance, such as life-support or safety devices or // systems, Class III medical devices, nuclear facilities, // applications related to the deployment of airbags, or any // other applications that could lead to death, personal // injury, or severe property or environmental damage // (individually and collectively, "Critical // Applications"). Customer assumes the sole risk and // liability of any use of Xilinx products in Critical // Applications, subject only to applicable laws and // regulations governing limitations on product liability. // // THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS // PART OF THIS FILE AT ALL TIMES. // // DO NOT MODIFY THIS FILE. // IP VLNV: xilinx.com:ip:axi_protocol_converter:2.1 // IP Revision: 4 `timescale 1ns/1ps (* DowngradeIPIdentifiedWarnings = "yes" *) module OpenSSD2_auto_pc_3 ( aclk, aresetn, s_axi_awid, s_axi_awaddr, s_axi_awlen, s_axi_awsize, s_axi_awburst, s_axi_awlock, s_axi_awcache, s_axi_awprot, s_axi_awregion, s_axi_awqos, s_axi_awvalid, s_axi_awready, s_axi_wdata, s_axi_wstrb, s_axi_wlast, s_axi_wvalid, s_axi_wready, s_axi_bid, s_axi_bresp, s_axi_bvalid, s_axi_bready, s_axi_arid, s_axi_araddr, s_axi_arlen, s_axi_arsize, s_axi_arburst, s_axi_arlock, s_axi_arcache, s_axi_arprot, s_axi_arregion, s_axi_arqos, s_axi_arvalid, s_axi_arready, s_axi_rid, s_axi_rdata, s_axi_rresp, s_axi_rlast, s_axi_rvalid, s_axi_rready, m_axi_awid, m_axi_awaddr, m_axi_awlen, m_axi_awsize, m_axi_awburst, m_axi_awlock, m_axi_awcache, m_axi_awprot, m_axi_awqos, m_axi_awvalid, m_axi_awready, m_axi_wid, m_axi_wdata, m_axi_wstrb, m_axi_wlast, m_axi_wvalid, m_axi_wready, m_axi_bid, m_axi_bresp, m_axi_bvalid, m_axi_bready, m_axi_arid, m_axi_araddr, m_axi_arlen, m_axi_arsize, m_axi_arburst, m_axi_arlock, m_axi_arcache, m_axi_arprot, m_axi_arqos, m_axi_arvalid, m_axi_arready, m_axi_rid, m_axi_rdata, m_axi_rresp, m_axi_rlast, m_axi_rvalid, m_axi_rready ); (* X_INTERFACE_INFO = "xilinx.com:signal:clock:1.0 CLK CLK" *) input wire aclk; (* X_INTERFACE_INFO = "xilinx.com:signal:reset:1.0 RST RST" *) input wire aresetn; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWID" *) input wire [0 : 0] s_axi_awid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWADDR" *) input wire [31 : 0] s_axi_awaddr; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWLEN" *) input wire [7 : 0] s_axi_awlen; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWSIZE" *) input wire [2 : 0] s_axi_awsize; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWBURST" *) input wire [1 : 0] s_axi_awburst; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWLOCK" *) input wire [0 : 0] s_axi_awlock; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWCACHE" *) input wire [3 : 0] s_axi_awcache; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWPROT" *) input wire [2 : 0] s_axi_awprot; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWREGION" *) input wire [3 : 0] s_axi_awregion; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWQOS" *) input wire [3 : 0] s_axi_awqos; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWVALID" *) input wire s_axi_awvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI AWREADY" *) output wire s_axi_awready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI WDATA" *) input wire [63 : 0] s_axi_wdata; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI WSTRB" *) input wire [7 : 0] s_axi_wstrb; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI WLAST" *) input wire s_axi_wlast; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI WVALID" *) input wire s_axi_wvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI WREADY" *) output wire s_axi_wready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI BID" *) output wire [0 : 0] s_axi_bid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI BRESP" *) output wire [1 : 0] s_axi_bresp; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI BVALID" *) output wire s_axi_bvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI BREADY" *) input wire s_axi_bready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARID" *) input wire [0 : 0] s_axi_arid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARADDR" *) input wire [31 : 0] s_axi_araddr; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARLEN" *) input wire [7 : 0] s_axi_arlen; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARSIZE" *) input wire [2 : 0] s_axi_arsize; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARBURST" *) input wire [1 : 0] s_axi_arburst; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARLOCK" *) input wire [0 : 0] s_axi_arlock; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARCACHE" *) input wire [3 : 0] s_axi_arcache; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARPROT" *) input wire [2 : 0] s_axi_arprot; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARREGION" *) input wire [3 : 0] s_axi_arregion; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARQOS" *) input wire [3 : 0] s_axi_arqos; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARVALID" *) input wire s_axi_arvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI ARREADY" *) output wire s_axi_arready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RID" *) output wire [0 : 0] s_axi_rid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RDATA" *) output wire [63 : 0] s_axi_rdata; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RRESP" *) output wire [1 : 0] s_axi_rresp; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RLAST" *) output wire s_axi_rlast; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RVALID" *) output wire s_axi_rvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 S_AXI RREADY" *) input wire s_axi_rready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWID" *) output wire [0 : 0] m_axi_awid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWADDR" *) output wire [31 : 0] m_axi_awaddr; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWLEN" *) output wire [3 : 0] m_axi_awlen; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWSIZE" *) output wire [2 : 0] m_axi_awsize; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWBURST" *) output wire [1 : 0] m_axi_awburst; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWLOCK" *) output wire [1 : 0] m_axi_awlock; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWCACHE" *) output wire [3 : 0] m_axi_awcache; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWPROT" *) output wire [2 : 0] m_axi_awprot; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWQOS" *) output wire [3 : 0] m_axi_awqos; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWVALID" *) output wire m_axi_awvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI AWREADY" *) input wire m_axi_awready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WID" *) output wire [0 : 0] m_axi_wid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WDATA" *) output wire [63 : 0] m_axi_wdata; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WSTRB" *) output wire [7 : 0] m_axi_wstrb; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WLAST" *) output wire m_axi_wlast; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WVALID" *) output wire m_axi_wvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI WREADY" *) input wire m_axi_wready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI BID" *) input wire [0 : 0] m_axi_bid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI BRESP" *) input wire [1 : 0] m_axi_bresp; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI BVALID" *) input wire m_axi_bvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI BREADY" *) output wire m_axi_bready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARID" *) output wire [0 : 0] m_axi_arid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARADDR" *) output wire [31 : 0] m_axi_araddr; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARLEN" *) output wire [3 : 0] m_axi_arlen; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARSIZE" *) output wire [2 : 0] m_axi_arsize; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARBURST" *) output wire [1 : 0] m_axi_arburst; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARLOCK" *) output wire [1 : 0] m_axi_arlock; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARCACHE" *) output wire [3 : 0] m_axi_arcache; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARPROT" *) output wire [2 : 0] m_axi_arprot; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARQOS" *) output wire [3 : 0] m_axi_arqos; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARVALID" *) output wire m_axi_arvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI ARREADY" *) input wire m_axi_arready; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RID" *) input wire [0 : 0] m_axi_rid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RDATA" *) input wire [63 : 0] m_axi_rdata; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RRESP" *) input wire [1 : 0] m_axi_rresp; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RLAST" *) input wire m_axi_rlast; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RVALID" *) input wire m_axi_rvalid; (* X_INTERFACE_INFO = "xilinx.com:interface:aximm:1.0 M_AXI RREADY" *) output wire m_axi_rready; axi_protocol_converter_v2_1_axi_protocol_converter #( .C_FAMILY("zynq"), .C_M_AXI_PROTOCOL(1), .C_S_AXI_PROTOCOL(0), .C_IGNORE_ID(0), .C_AXI_ID_WIDTH(1), .C_AXI_ADDR_WIDTH(32), .C_AXI_DATA_WIDTH(64), .C_AXI_SUPPORTS_WRITE(1), .C_AXI_SUPPORTS_READ(1), .C_AXI_SUPPORTS_USER_SIGNALS(0), .C_AXI_AWUSER_WIDTH(1), .C_AXI_ARUSER_WIDTH(1), .C_AXI_WUSER_WIDTH(1), .C_AXI_RUSER_WIDTH(1), .C_AXI_BUSER_WIDTH(1), .C_TRANSLATION_MODE(2) ) inst ( .aclk(aclk), .aresetn(aresetn), .s_axi_awid(s_axi_awid), .s_axi_awaddr(s_axi_awaddr), .s_axi_awlen(s_axi_awlen), .s_axi_awsize(s_axi_awsize), .s_axi_awburst(s_axi_awburst), .s_axi_awlock(s_axi_awlock), .s_axi_awcache(s_axi_awcache), .s_axi_awprot(s_axi_awprot), .s_axi_awregion(s_axi_awregion), .s_axi_awqos(s_axi_awqos), .s_axi_awuser(1'H0), .s_axi_awvalid(s_axi_awvalid), .s_axi_awready(s_axi_awready), .s_axi_wid(1'H0), .s_axi_wdata(s_axi_wdata), .s_axi_wstrb(s_axi_wstrb), .s_axi_wlast(s_axi_wlast), .s_axi_wuser(1'H0), .s_axi_wvalid(s_axi_wvalid), .s_axi_wready(s_axi_wready), .s_axi_bid(s_axi_bid), .s_axi_bresp(s_axi_bresp), .s_axi_buser(), .s_axi_bvalid(s_axi_bvalid), .s_axi_bready(s_axi_bready), .s_axi_arid(s_axi_arid), .s_axi_araddr(s_axi_araddr), .s_axi_arlen(s_axi_arlen), .s_axi_arsize(s_axi_arsize), .s_axi_arburst(s_axi_arburst), .s_axi_arlock(s_axi_arlock), .s_axi_arcache(s_axi_arcache), .s_axi_arprot(s_axi_arprot), .s_axi_arregion(s_axi_arregion), .s_axi_arqos(s_axi_arqos), .s_axi_aruser(1'H0), .s_axi_arvalid(s_axi_arvalid), .s_axi_arready(s_axi_arready), .s_axi_rid(s_axi_rid), .s_axi_rdata(s_axi_rdata), .s_axi_rresp(s_axi_rresp), .s_axi_rlast(s_axi_rlast), .s_axi_ruser(), .s_axi_rvalid(s_axi_rvalid), .s_axi_rready(s_axi_rready), .m_axi_awid(m_axi_awid), .m_axi_awaddr(m_axi_awaddr), .m_axi_awlen(m_axi_awlen), .m_axi_awsize(m_axi_awsize), .m_axi_awburst(m_axi_awburst), .m_axi_awlock(m_axi_awlock), .m_axi_awcache(m_axi_awcache), .m_axi_awprot(m_axi_awprot), .m_axi_awregion(), .m_axi_awqos(m_axi_awqos), .m_axi_awuser(), .m_axi_awvalid(m_axi_awvalid), .m_axi_awready(m_axi_awready), .m_axi_wid(m_axi_wid), .m_axi_wdata(m_axi_wdata), .m_axi_wstrb(m_axi_wstrb), .m_axi_wlast(m_axi_wlast), .m_axi_wuser(), .m_axi_wvalid(m_axi_wvalid), .m_axi_wready(m_axi_wready), .m_axi_bid(m_axi_bid), .m_axi_bresp(m_axi_bresp), .m_axi_buser(1'H0), .m_axi_bvalid(m_axi_bvalid), .m_axi_bready(m_axi_bready), .m_axi_arid(m_axi_arid), .m_axi_araddr(m_axi_araddr), .m_axi_arlen(m_axi_arlen), .m_axi_arsize(m_axi_arsize), .m_axi_arburst(m_axi_arburst), .m_axi_arlock(m_axi_arlock), .m_axi_arcache(m_axi_arcache), .m_axi_arprot(m_axi_arprot), .m_axi_arregion(), .m_axi_arqos(m_axi_arqos), .m_axi_aruser(), .m_axi_arvalid(m_axi_arvalid), .m_axi_arready(m_axi_arready), .m_axi_rid(m_axi_rid), .m_axi_rdata(m_axi_rdata), .m_axi_rresp(m_axi_rresp), .m_axi_rlast(m_axi_rlast), .m_axi_ruser(1'H0), .m_axi_rvalid(m_axi_rvalid), .m_axi_rready(m_axi_rready) ); endmodule

/////////////////////////////////////////////////////// // Copyright (c) 2008 Xilinx Inc. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. /////////////////////////////////////////////////////// // // ____ ___ // / /\/ / // /___/ \ / Vendor : Xilinx // \ \ \/ Version : 12.i (O.4) // \ \ Description : // / / // /__/ /\ Filename : PLLE2_BASE.v // \ \ / \ // \__\/\__ \ // // Revision: 1.0 // 12/09/09 - Initial version // 03/23/10 - Change CLKFBOUT_MULT default from 1 to 5. /////////////////////////////////////////////////////// `timescale 1 ps / 1 ps `celldefine module PLLE2_BASE ( CLKFBOUT, CLKOUT0, CLKOUT1, CLKOUT2, CLKOUT3, CLKOUT4, CLKOUT5, LOCKED, CLKFBIN, CLKIN1, PWRDWN, RST ); parameter BANDWIDTH = "OPTIMIZED"; parameter integer CLKFBOUT_MULT = 5; parameter real CLKFBOUT_PHASE = 0.000; parameter real CLKIN1_PERIOD = 0.000; parameter integer CLKOUT0_DIVIDE = 1; parameter real CLKOUT0_DUTY_CYCLE = 0.500; parameter real CLKOUT0_PHASE = 0.000; parameter integer CLKOUT1_DIVIDE = 1; parameter real CLKOUT1_DUTY_CYCLE = 0.500; parameter real CLKOUT1_PHASE = 0.000; parameter integer CLKOUT2_DIVIDE = 1; parameter real CLKOUT2_DUTY_CYCLE = 0.500; parameter real CLKOUT2_PHASE = 0.000; parameter integer CLKOUT3_DIVIDE = 1; parameter real CLKOUT3_DUTY_CYCLE = 0.500; parameter real CLKOUT3_PHASE = 0.000; parameter integer CLKOUT4_DIVIDE = 1; parameter real CLKOUT4_DUTY_CYCLE = 0.500; parameter real CLKOUT4_PHASE = 0.000; parameter integer CLKOUT5_DIVIDE = 1; parameter real CLKOUT5_DUTY_CYCLE = 0.500; parameter real CLKOUT5_PHASE = 0.000; parameter integer DIVCLK_DIVIDE = 1; parameter real REF_JITTER1 = 0.010; parameter STARTUP_WAIT = "FALSE"; `ifdef XIL_TIMING parameter LOC = "UNPLACED"; `endif // output CLKFBOUT; output CLKOUT0; output CLKOUT1; output CLKOUT2; output CLKOUT3; output CLKOUT4; output CLKOUT5; output LOCKED; input CLKFBIN; input CLKIN1; input PWRDWN; input RST; wire OPEN_DRDY; wire OPEN_PSDONE; wire OPEN_FBS; wire OPEN_INS; wire [15:0] OPEN_DO; PLLE2_ADV #( .BANDWIDTH(BANDWIDTH), .STARTUP_WAIT(STARTUP_WAIT), .CLKOUT1_DIVIDE(CLKOUT1_DIVIDE), .CLKOUT2_DIVIDE(CLKOUT2_DIVIDE), .CLKOUT3_DIVIDE(CLKOUT3_DIVIDE), .CLKOUT4_DIVIDE(CLKOUT4_DIVIDE), .CLKOUT5_DIVIDE(CLKOUT5_DIVIDE), .DIVCLK_DIVIDE(DIVCLK_DIVIDE), .CLKFBOUT_MULT(CLKFBOUT_MULT), .CLKFBOUT_PHASE(CLKFBOUT_PHASE), .CLKIN1_PERIOD(CLKIN1_PERIOD), .CLKIN2_PERIOD(10), .CLKOUT0_DIVIDE(CLKOUT0_DIVIDE), .CLKOUT0_DUTY_CYCLE(CLKOUT0_DUTY_CYCLE), .CLKOUT0_PHASE(CLKOUT0_PHASE), .CLKOUT1_DUTY_CYCLE(CLKOUT1_DUTY_CYCLE), .CLKOUT1_PHASE(CLKOUT1_PHASE), .CLKOUT2_DUTY_CYCLE(CLKOUT2_DUTY_CYCLE), .CLKOUT2_PHASE(CLKOUT2_PHASE), .CLKOUT3_DUTY_CYCLE(CLKOUT3_DUTY_CYCLE), .CLKOUT3_PHASE(CLKOUT3_PHASE), .CLKOUT4_DUTY_CYCLE(CLKOUT4_DUTY_CYCLE), .CLKOUT4_PHASE(CLKOUT4_PHASE), .CLKOUT5_DUTY_CYCLE(CLKOUT5_DUTY_CYCLE), .CLKOUT5_PHASE(CLKOUT5_PHASE), .REF_JITTER1(REF_JITTER1) ) plle2_adv_1 ( .CLKFBIN (CLKFBIN), .CLKFBOUT (CLKFBOUT), .CLKIN1 (CLKIN1), .CLKIN2 (1'b0), .CLKOUT0 (CLKOUT0), .CLKOUT1 (CLKOUT1), .CLKOUT2 (CLKOUT2), .CLKOUT3 (CLKOUT3), .CLKOUT4 (CLKOUT4), .CLKOUT5 (CLKOUT5), .DADDR (7'b0), .DCLK (1'b0), .DEN (1'b0), .DI (16'b0), .DO (OPEN_DO), .DRDY (OPEN_DRDY), .DWE (1'b0), .LOCKED (LOCKED), .CLKINSEL(1'b1), .PWRDWN(PWRDWN), .RST (RST) ); endmodule `endcelldefine

/* This file is part of JT12. JT12 program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. JT12 program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with JT12. If not, see <http://www.gnu.org/licenses/>. Author: Jose Tejada Gomez. Twitter: @topapate Version: 1.0 Date: 21-03-2019 Each channel can use the full range of the DAC as they do not get summed in the real chip. Operator data is summed up without adding extra bits. This is the case of real YM3438, which was used on Megadrive 2 models. */ // YM2610 // ADPCM inputs // Full OP resolution // No PCM // 4 OP channels // ADPCM-A input is added for the time assigned to FM channel 0_10 (i.e. 3) module jt10_acc( input clk, input clk_en /* synthesis direct_enable */, input signed [13:0] op_result, input [ 1:0] rl, input zero, input s1_enters, input s2_enters, input s3_enters, input s4_enters, input [2:0] cur_ch, input [1:0] cur_op, input [2:0] alg, input signed [15:0] adpcmA_l, input signed [15:0] adpcmA_r, input signed [15:0] adpcmB_l, input signed [15:0] adpcmB_r, // combined output output signed [15:0] left, output signed [15:0] right ); reg sum_en; always @(*) begin case ( alg ) default: sum_en = s4_enters; 3'd4: sum_en = s2_enters | s4_enters; 3'd5,3'd6: sum_en = ~s1_enters; 3'd7: sum_en = 1'b1; endcase end wire left_en = rl[1]; wire right_en= rl[0]; wire signed [15:0] opext = { {2{op_result[13]}}, op_result }; reg signed [15:0] acc_input_l, acc_input_r; reg acc_en_l, acc_en_r; // YM2610 mode: // uses channels 0 and 4 for ADPCM data, throwing away FM data for those channels // reference: YM2610 Application Notes. always @(*) case( {cur_op,cur_ch} ) {2'd0,3'd0}: begin // ADPCM-A: acc_input_l = (adpcmA_l <<< 2) + (adpcmA_l <<< 1); acc_input_r = (adpcmA_r <<< 2) + (adpcmA_r <<< 1); `ifndef NOMIX acc_en_l = 1'b1; acc_en_r = 1'b1; `else acc_en_l = 1'b0; acc_en_r = 1'b0; `endif end {2'd0,3'd4}: begin // ADPCM-B: acc_input_l = adpcmB_l >>> 1; // Operator width is 14 bit, ADPCM-B is 16 bit acc_input_r = adpcmB_r >>> 1; // accumulator width per input channel is 14 bit `ifndef NOMIX acc_en_l = 1'b1; acc_en_r = 1'b1; `else acc_en_l = 1'b0; acc_en_r = 1'b0; `endif end default: begin // Note by Jose Tejada: // I don't think we should divide down the FM output // but someone was looking at the balance of the different // channels and made this arrangement // I suppose ADPCM-A would saturate if taken up a factor of 8 instead of 4 // I'll leave it as it is but I think it is worth revisiting this: acc_input_l = opext >>> 1; acc_input_r = opext >>> 1; acc_en_l = sum_en & left_en; acc_en_r = sum_en & right_en; end endcase // Continuous output jt12_single_acc #(.win(16),.wout(16)) u_left( .clk ( clk ), .clk_en ( clk_en ), .op_result ( acc_input_l ), .sum_en ( acc_en_l ), .zero ( zero ), .snd ( left ) ); jt12_single_acc #(.win(16),.wout(16)) u_right( .clk ( clk ), .clk_en ( clk_en ), .op_result ( acc_input_r ), .sum_en ( acc_en_r ), .zero ( zero ), .snd ( right ) ); `ifdef SIMULATION // Dump each channel independently // It dumps values in decimal, left and right integer f0,f1,f2,f4,f5,f6; reg signed [15:0] sum_l[7], sum_r[7]; initial begin f0=$fopen("fm0.raw","w"); f1=$fopen("fm1.raw","w"); f2=$fopen("fm2.raw","w"); f4=$fopen("fm4.raw","w"); f5=$fopen("fm5.raw","w"); f6=$fopen("fm6.raw","w"); end always @(posedge clk) begin if(cur_op==2'b0) begin sum_l[cur_ch] <= acc_en_l ? acc_input_l : 16'd0; sum_r[cur_ch] <= acc_en_r ? acc_input_r : 16'd0; end else begin sum_l[cur_ch] <= sum_l[cur_ch] + (acc_en_l ? acc_input_l : 16'd0); sum_r[cur_ch] <= sum_r[cur_ch] + (acc_en_r ? acc_input_r : 16'd0); end end always @(posedge zero) begin $fwrite(f0,"%d,%d\n", sum_l[0], sum_r[0]); $fwrite(f1,"%d,%d\n", sum_l[1], sum_r[1]); $fwrite(f2,"%d,%d\n", sum_l[2], sum_r[2]); $fwrite(f4,"%d,%d\n", sum_l[4], sum_r[4]); $fwrite(f5,"%d,%d\n", sum_l[5], sum_r[5]); $fwrite(f6,"%d,%d\n", sum_l[6], sum_r[6]); end `endif endmodule

// DESCRIPTION: Verilator: Verilog Test module // // This file ONLY is placed into the Public Domain, for any use, // without warranty, 2013 by Wilson Snyder. // Very simple test for interface pathclearing `ifdef VCS `define UNSUPPORTED_MOD_IN_GENS `endif `ifdef VERILATOR `define UNSUPPORTED_MOD_IN_GENS `endif module t (/*AUTOARG*/ // Inputs clk ); input clk; integer cyc=1; ifc #(1) itopa(); ifc #(2) itopb(); sub #(1) ca (.isub(itopa), .i_value(4)); sub #(2) cb (.isub(itopb), .i_value(5)); always @ (posedge clk) begin cyc <= cyc + 1; if (cyc==1) begin if (itopa.MODE != 1) $stop; if (itopb.MODE != 2) $stop; end if (cyc==20) begin if (itopa.get_value() != 4) $stop; if (itopb.get_value() != 5) $stop; $write("*-* All Finished *-*\n"); $finish; end end endmodule module sub #(parameter MODE = 0) ( ifc.out_modport isub, input integer i_value ); `ifdef UNSUPPORTED_MOD_IN_GENS always @* isub.value = i_value; `else generate if (MODE == 1) begin always @* isub.valuea = i_value; end else if (MODE == 2) begin always @* isub.valueb = i_value; end endgenerate `endif endmodule interface ifc; parameter MODE = 0; // Modports under generates not supported by all commercial simulators `ifdef UNSUPPORTED_MOD_IN_GENS integer value; modport out_modport (output value); function integer get_value(); return value; endfunction `else generate if (MODE == 0) begin integer valuea; modport out_modport (output valuea); function integer get_valuea(); return valuea; endfunction end else begin integer valueb; modport out_modport (output valueb); function integer get_valueb(); return valueb; endfunction end endgenerate `endif endinterface

//////////////////////////////////////////////////////////////////////////////// // Original Author: Schuyler Eldridge // Contact Point: Schuyler Eldridge ([email protected]) // t_sqrt_pipelined.v // Created: 4.2.2012 // Modified: 4.5.2012 // // Testbench for generic sqrt operation // // Copyright (C) 2012 Schuyler Eldridge, Boston University // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see <http://www.gnu.org/licenses/>. //////////////////////////////////////////////////////////////////////////////// `timescale 1ns / 1ps module t_sqrt_pipelined(); parameter INPUT_BITS = 4; localparam OUTPUT_BITS = INPUT_BITS / 2 + INPUT_BITS % 2; reg [INPUT_BITS-1:0] radicand; reg clk, start, reset_n; wire [OUTPUT_BITS-1:0] root; wire data_valid; // wire [7:0] root_good; sqrt_pipelined #( .INPUT_BITS(INPUT_BITS) ) sqrt_pipelined ( .clk(clk), .reset_n(reset_n), .start(start), .radicand(radicand), .data_valid(data_valid), .root(root) ); initial begin radicand = 16'bx; clk = 1'bx; start = 1'bx; reset_n = 1'bx;; #10 reset_n = 0; clk = 0; #50 reset_n = 1; radicand = 0; // #40 radicand = 81; start = 1; // #10 radicand = 16'bx; start = 0; #10000 $finish; end always #5 clk = ~clk; always begin #10 radicand = radicand + 1; start = 1; #10 start = 0; end // always begin // #80 start = 1; // #10 start = 0; // end endmodule

// Copyright (c) 2000 Stephen Williams ([email protected]) // // This source code is free software; you can redistribute it // and/or modify it in source code form under the terms of the GNU // General Public License as published by the Free Software // Foundation; either version 2 of the License, or (at your option) // any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA // // This tests DFF-like behavior. The clocked always block acts like a // DFF, and if the -Fsynth flag to ivl is used, actually generates an // LPM_FF device. module main () ; reg clk; reg D, Q; always #10 clk = ~clk; always @(posedge clk) Q = D; initial begin clk = 0; D = 0; @(negedge clk) if (Q !== 1'b0) begin $display("FAILED: %b !== %b", Q, D); $finish; end D = 1; @(negedge clk) if (Q !== 1'b1) begin $display("FAILED: %b !== %b", Q, D); $finish; end D = 'bx; @(negedge clk) if (Q !== 1'bx) begin $display("FAILED: %b !== %b", Q, D); $finish; end D = 'bz; @(negedge clk) if (Q !== 1'bz) begin $display("FAILED: %b !== %b", Q, D); $finish; end $display("PASSED"); $finish; end // initial begin endmodule