#!/usr/bin/env python import torch import cupy import re kernel_Correlation_rearrange = ''' extern "C" __global__ void kernel_Correlation_rearrange( const int n, const float* input, float* output ) { int intIndex = (blockIdx.x * blockDim.x) + threadIdx.x; if (intIndex >= n) { return; } int intSample = blockIdx.z; int intChannel = blockIdx.y; float fltValue = input[(((intSample * SIZE_1(input)) + intChannel) * SIZE_2(input) * SIZE_3(input)) + intIndex]; __syncthreads(); int intPaddedY = (intIndex / SIZE_3(input)) + 4; int intPaddedX = (intIndex % SIZE_3(input)) + 4; int intRearrange = ((SIZE_3(input) + 8) * intPaddedY) + intPaddedX; output[(((intSample * SIZE_1(output) * SIZE_2(output)) + intRearrange) * SIZE_1(input)) + intChannel] = fltValue; } ''' kernel_Correlation_updateOutput = ''' extern "C" __global__ void kernel_Correlation_updateOutput( const int n, const float* rbot0, const float* rbot1, float* top ) { extern __shared__ char patch_data_char[]; float *patch_data = (float *)patch_data_char; // First (upper left) position of kernel upper-left corner in current center position of neighborhood in image 1 int x1 = blockIdx.x + 4; int y1 = blockIdx.y + 4; int item = blockIdx.z; int ch_off = threadIdx.x; // Load 3D patch into shared shared memory for (int j = 0; j < 1; j++) { // HEIGHT for (int i = 0; i < 1; i++) { // WIDTH int ji_off = (j + i) * SIZE_3(rbot0); for (int ch = ch_off; ch < SIZE_3(rbot0); ch += 32) { // CHANNELS int idx1 = ((item * SIZE_1(rbot0) + y1+j) * SIZE_2(rbot0) + x1+i) * SIZE_3(rbot0) + ch; int idxPatchData = ji_off + ch; patch_data[idxPatchData] = rbot0[idx1]; } } } __syncthreads(); __shared__ float sum[32]; // Compute correlation for (int top_channel = 0; top_channel < SIZE_1(top); top_channel++) { sum[ch_off] = 0; int s2o = top_channel % 9 - 4; int s2p = top_channel / 9 - 4; for (int j = 0; j < 1; j++) { // HEIGHT for (int i = 0; i < 1; i++) { // WIDTH int ji_off = (j + i) * SIZE_3(rbot0); for (int ch = ch_off; ch < SIZE_3(rbot0); ch += 32) { // CHANNELS int x2 = x1 + s2o; int y2 = y1 + s2p; int idxPatchData = ji_off + ch; int idx2 = ((item * SIZE_1(rbot0) + y2+j) * SIZE_2(rbot0) + x2+i) * SIZE_3(rbot0) + ch; sum[ch_off] += patch_data[idxPatchData] * rbot1[idx2]; } } } __syncthreads(); if (ch_off == 0) { float total_sum = 0; for (int idx = 0; idx < 32; idx++) { total_sum += sum[idx]; } const int sumelems = SIZE_3(rbot0); const int index = ((top_channel*SIZE_2(top) + blockIdx.y)*SIZE_3(top))+blockIdx.x; top[index + item*SIZE_1(top)*SIZE_2(top)*SIZE_3(top)] = total_sum / (float)sumelems; } } } ''' kernel_Correlation_updateGradFirst = ''' #define ROUND_OFF 50000 extern "C" __global__ void kernel_Correlation_updateGradFirst( const int n, const int intSample, const float* rbot0, const float* rbot1, const float* gradOutput, float* gradFirst, float* gradSecond ) { for (int intIndex = (blockIdx.x * blockDim.x) + threadIdx.x; intIndex < n; intIndex += blockDim.x * gridDim.x) { int n = intIndex % SIZE_1(gradFirst); // channels int l = (intIndex / SIZE_1(gradFirst)) % SIZE_3(gradFirst) + 4; // w-pos int m = (intIndex / SIZE_1(gradFirst) / SIZE_3(gradFirst)) % SIZE_2(gradFirst) + 4; // h-pos // round_off is a trick to enable integer division with ceil, even for negative numbers // We use a large offset, for the inner part not to become negative. const int round_off = ROUND_OFF; const int round_off_s1 = round_off; // We add round_off before_s1 the int division and subtract round_off after it, to ensure the formula matches ceil behavior: int xmin = (l - 4 + round_off_s1 - 1) + 1 - round_off; // ceil (l - 4) int ymin = (m - 4 + round_off_s1 - 1) + 1 - round_off; // ceil (l - 4) // Same here: int xmax = (l - 4 + round_off_s1) - round_off; // floor (l - 4) int ymax = (m - 4 + round_off_s1) - round_off; // floor (m - 4) float sum = 0; if (xmax>=0 && ymax>=0 && (xmin<=SIZE_3(gradOutput)-1) && (ymin<=SIZE_2(gradOutput)-1)) { xmin = max(0,xmin); xmax = min(SIZE_3(gradOutput)-1,xmax); ymin = max(0,ymin); ymax = min(SIZE_2(gradOutput)-1,ymax); for (int p = -4; p <= 4; p++) { for (int o = -4; o <= 4; o++) { // Get rbot1 data: int s2o = o; int s2p = p; int idxbot1 = ((intSample * SIZE_1(rbot0) + (m+s2p)) * SIZE_2(rbot0) + (l+s2o)) * SIZE_3(rbot0) + n; float bot1tmp = rbot1[idxbot1]; // rbot1[l+s2o,m+s2p,n] // Index offset for gradOutput in following loops: int op = (p+4) * 9 + (o+4); // index[o,p] int idxopoffset = (intSample * SIZE_1(gradOutput) + op); for (int y = ymin; y <= ymax; y++) { for (int x = xmin; x <= xmax; x++) { int idxgradOutput = (idxopoffset * SIZE_2(gradOutput) + y) * SIZE_3(gradOutput) + x; // gradOutput[x,y,o,p] sum += gradOutput[idxgradOutput] * bot1tmp; } } } } } const int sumelems = SIZE_1(gradFirst); const int bot0index = ((n * SIZE_2(gradFirst)) + (m-4)) * SIZE_3(gradFirst) + (l-4); gradFirst[bot0index + intSample*SIZE_1(gradFirst)*SIZE_2(gradFirst)*SIZE_3(gradFirst)] = sum / (float)sumelems; } } ''' kernel_Correlation_updateGradSecond = ''' #define ROUND_OFF 50000 extern "C" __global__ void kernel_Correlation_updateGradSecond( const int n, const int intSample, const float* rbot0, const float* rbot1, const float* gradOutput, float* gradFirst, float* gradSecond ) { for (int intIndex = (blockIdx.x * blockDim.x) + threadIdx.x; intIndex < n; intIndex += blockDim.x * gridDim.x) { int n = intIndex % SIZE_1(gradSecond); // channels int l = (intIndex / SIZE_1(gradSecond)) % SIZE_3(gradSecond) + 4; // w-pos int m = (intIndex / SIZE_1(gradSecond) / SIZE_3(gradSecond)) % SIZE_2(gradSecond) + 4; // h-pos // round_off is a trick to enable integer division with ceil, even for negative numbers // We use a large offset, for the inner part not to become negative. const int round_off = ROUND_OFF; const int round_off_s1 = round_off; float sum = 0; for (int p = -4; p <= 4; p++) { for (int o = -4; o <= 4; o++) { int s2o = o; int s2p = p; //Get X,Y ranges and clamp // We add round_off before_s1 the int division and subtract round_off after it, to ensure the formula matches ceil behavior: int xmin = (l - 4 - s2o + round_off_s1 - 1) + 1 - round_off; // ceil (l - 4 - s2o) int ymin = (m - 4 - s2p + round_off_s1 - 1) + 1 - round_off; // ceil (l - 4 - s2o) // Same here: int xmax = (l - 4 - s2o + round_off_s1) - round_off; // floor (l - 4 - s2o) int ymax = (m - 4 - s2p + round_off_s1) - round_off; // floor (m - 4 - s2p) if (xmax>=0 && ymax>=0 && (xmin<=SIZE_3(gradOutput)-1) && (ymin<=SIZE_2(gradOutput)-1)) { xmin = max(0,xmin); xmax = min(SIZE_3(gradOutput)-1,xmax); ymin = max(0,ymin); ymax = min(SIZE_2(gradOutput)-1,ymax); // Get rbot0 data: int idxbot0 = ((intSample * SIZE_1(rbot0) + (m-s2p)) * SIZE_2(rbot0) + (l-s2o)) * SIZE_3(rbot0) + n; float bot0tmp = rbot0[idxbot0]; // rbot1[l+s2o,m+s2p,n] // Index offset for gradOutput in following loops: int op = (p+4) * 9 + (o+4); // index[o,p] int idxopoffset = (intSample * SIZE_1(gradOutput) + op); for (int y = ymin; y <= ymax; y++) { for (int x = xmin; x <= xmax; x++) { int idxgradOutput = (idxopoffset * SIZE_2(gradOutput) + y) * SIZE_3(gradOutput) + x; // gradOutput[x,y,o,p] sum += gradOutput[idxgradOutput] * bot0tmp; } } } } } const int sumelems = SIZE_1(gradSecond); const int bot1index = ((n * SIZE_2(gradSecond)) + (m-4)) * SIZE_3(gradSecond) + (l-4); gradSecond[bot1index + intSample*SIZE_1(gradSecond)*SIZE_2(gradSecond)*SIZE_3(gradSecond)] = sum / (float)sumelems; } } ''' def cupy_kernel(strFunction, objVariables): strKernel = globals()[strFunction] while True: objMatch = re.search('(SIZE_)([0-4])(\()([^\)]*)(\))', strKernel) if objMatch is None: break # end intArg = int(objMatch.group(2)) strTensor = objMatch.group(4) intSizes = objVariables[strTensor].size() strKernel = strKernel.replace(objMatch.group(), str(intSizes[intArg])) # end while True: objMatch = re.search('(VALUE_)([0-4])(\()([^\)]+)(\))', strKernel) if objMatch is None: break # end intArgs = int(objMatch.group(2)) strArgs = objMatch.group(4).split(',') strTensor = strArgs[0] intStrides = objVariables[strTensor].stride() strIndex = [ '((' + strArgs[intArg + 1].replace('{', '(').replace('}', ')').strip() + ')*' + str(intStrides[intArg]) + ')' for intArg in range(intArgs) ] strKernel = strKernel.replace(objMatch.group(0), strTensor + '[' + str.join('+', strIndex) + ']') # end return strKernel # end @cupy.memoize(for_each_device=True) def cupy_launch(strFunction, strKernel): return cupy.cuda.compile_with_cache(strKernel).get_function(strFunction) # end class _FunctionCorrelation(torch.autograd.Function): @staticmethod def forward(self, first, second): rbot0 = first.new_zeros([ first.shape[0], first.shape[2] + 8, first.shape[3] + 8, first.shape[1] ]) rbot1 = first.new_zeros([ first.shape[0], first.shape[2] + 8, first.shape[3] + 8, first.shape[1] ]) self.save_for_backward(first, second, rbot0, rbot1) assert(first.is_contiguous() == True) assert(second.is_contiguous() == True) output = first.new_zeros([ first.shape[0], 81, first.shape[2], first.shape[3] ]) if first.is_cuda == True: n = first.shape[2] * first.shape[3] cupy_launch('kernel_Correlation_rearrange', cupy_kernel('kernel_Correlation_rearrange', { 'input': first, 'output': rbot0 }))( grid=tuple([ int((n + 16 - 1) / 16), first.shape[1], first.shape[0] ]), block=tuple([ 16, 1, 1 ]), args=[ n, first.data_ptr(), rbot0.data_ptr() ] ) n = second.shape[2] * second.shape[3] cupy_launch('kernel_Correlation_rearrange', cupy_kernel('kernel_Correlation_rearrange', { 'input': second, 'output': rbot1 }))( grid=tuple([ int((n + 16 - 1) / 16), second.shape[1], second.shape[0] ]), block=tuple([ 16, 1, 1 ]), args=[ n, second.data_ptr(), rbot1.data_ptr() ] ) n = output.shape[1] * output.shape[2] * output.shape[3] cupy_launch('kernel_Correlation_updateOutput', cupy_kernel('kernel_Correlation_updateOutput', { 'rbot0': rbot0, 'rbot1': rbot1, 'top': output }))( grid=tuple([ output.shape[3], output.shape[2], output.shape[0] ]), block=tuple([ 32, 1, 1 ]), shared_mem=first.shape[1] * 4, args=[ n, rbot0.data_ptr(), rbot1.data_ptr(), output.data_ptr() ] ) elif first.is_cuda == False: raise NotImplementedError() # end return output # end @staticmethod def backward(self, gradOutput): first, second, rbot0, rbot1 = self.saved_tensors assert(gradOutput.is_contiguous() == True) gradFirst = first.new_zeros([ first.shape[0], first.shape[1], first.shape[2], first.shape[3] ]) if self.needs_input_grad[0] == True else None gradSecond = first.new_zeros([ first.shape[0], first.shape[1], first.shape[2], first.shape[3] ]) if self.needs_input_grad[1] == True else None if first.is_cuda == True: if gradFirst is not None: for intSample in range(first.shape[0]): n = first.shape[1] * first.shape[2] * first.shape[3] cupy_launch('kernel_Correlation_updateGradFirst', cupy_kernel('kernel_Correlation_updateGradFirst', { 'rbot0': rbot0, 'rbot1': rbot1, 'gradOutput': gradOutput, 'gradFirst': gradFirst, 'gradSecond': None }))( grid=tuple([ int((n + 512 - 1) / 512), 1, 1 ]), block=tuple([ 512, 1, 1 ]), args=[ n, intSample, rbot0.data_ptr(), rbot1.data_ptr(), gradOutput.data_ptr(), gradFirst.data_ptr(), None ] ) # end # end if gradSecond is not None: for intSample in range(first.shape[0]): n = first.shape[1] * first.shape[2] * first.shape[3] cupy_launch('kernel_Correlation_updateGradSecond', cupy_kernel('kernel_Correlation_updateGradSecond', { 'rbot0': rbot0, 'rbot1': rbot1, 'gradOutput': gradOutput, 'gradFirst': None, 'gradSecond': gradSecond }))( grid=tuple([ int((n + 512 - 1) / 512), 1, 1 ]), block=tuple([ 512, 1, 1 ]), args=[ n, intSample, rbot0.data_ptr(), rbot1.data_ptr(), gradOutput.data_ptr(), None, gradSecond.data_ptr() ] ) # end # end elif first.is_cuda == False: raise NotImplementedError() # end return gradFirst, gradSecond # end # end def FunctionCorrelation(tenFirst, tenSecond): return _FunctionCorrelation.apply(tenFirst, tenSecond) # end class ModuleCorrelation(torch.nn.Module): def __init__(self): super(ModuleCorrelation, self).__init__() # end def forward(self, tenFirst, tenSecond): return _FunctionCorrelation.apply(tenFirst, tenSecond) # end # end