# Copyright (c) 2024 Alibaba Inc (authors: Xiang Lyu, Zhihao Du) # # 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. import logging from typing import Dict, Optional import torch import torch.nn as nn from torch.nn import functional as F from omegaconf import DictConfig from cosyvoice.utils.mask import make_pad_mask class MaskedDiffWithXvec(torch.nn.Module): def __init__(self, input_size: int = 512, output_size: int = 80, spk_embed_dim: int = 192, output_type: str = "mel", vocab_size: int = 4096, input_frame_rate: int = 50, only_mask_loss: bool = True, encoder: torch.nn.Module = None, length_regulator: torch.nn.Module = None, decoder: torch.nn.Module = None, decoder_conf: Dict = {'in_channels': 240, 'out_channel': 80, 'spk_emb_dim': 80, 'n_spks': 1, 'cfm_params': DictConfig({'sigma_min': 1e-06, 'solver': 'euler', 't_scheduler': 'cosine', 'training_cfg_rate': 0.2, 'inference_cfg_rate': 0.7, 'reg_loss_type': 'l1'}), 'decoder_params': {'channels': [256, 256], 'dropout': 0.0, 'attention_head_dim': 64, 'n_blocks': 4, 'num_mid_blocks': 12, 'num_heads': 8, 'act_fn': 'gelu'}}, mel_feat_conf: Dict = {'n_fft': 1024, 'num_mels': 80, 'sampling_rate': 22050, 'hop_size': 256, 'win_size': 1024, 'fmin': 0, 'fmax': 8000}): super().__init__() self.input_size = input_size self.output_size = output_size self.decoder_conf = decoder_conf self.mel_feat_conf = mel_feat_conf self.vocab_size = vocab_size self.output_type = output_type self.input_frame_rate = input_frame_rate logging.info(f"input frame rate={self.input_frame_rate}") self.input_embedding = nn.Embedding(vocab_size, input_size) self.spk_embed_affine_layer = torch.nn.Linear(spk_embed_dim, output_size) self.encoder = encoder self.encoder_proj = torch.nn.Linear(self.encoder.output_size(), output_size) self.decoder = decoder self.length_regulator = length_regulator self.only_mask_loss = only_mask_loss def forward( self, batch: dict, device: torch.device, ) -> Dict[str, Optional[torch.Tensor]]: token = batch['speech_token'].to(device) token_len = batch['speech_token_len'].to(device) feat = batch['speech_feat'].to(device) feat_len = batch['speech_feat_len'].to(device) embedding = batch['embedding'].to(device) # xvec projection embedding = F.normalize(embedding, dim=1) embedding = self.spk_embed_affine_layer(embedding) # concat text and prompt_text mask = (~make_pad_mask(token_len)).float().unsqueeze(-1).to(device) token = self.input_embedding(torch.clamp(token, min=0)) * mask # text encode h, h_lengths = self.encoder(token, token_len) h = self.encoder_proj(h) h, h_lengths = self.length_regulator(h, feat_len) # get conditions conds = torch.zeros(feat.shape, device=token.device) conds = conds.transpose(1, 2) mask = (~make_pad_mask(feat_len)).to(h) feat = F.interpolate(feat.unsqueeze(dim=1), size=h.shape[1:], mode="nearest").squeeze(dim=1) loss, _ = self.decoder.compute_loss( feat.transpose(1, 2).contiguous(), mask.unsqueeze(1), h.transpose(1, 2).contiguous(), embedding, cond=conds ) return {'loss': loss} @torch.inference_mode() def inference(self, token, token_len, prompt_token, prompt_token_len, prompt_feat, prompt_feat_len, embedding): assert token.shape[0] == 1 # xvec projection embedding = F.normalize(embedding, dim=1) embedding = self.spk_embed_affine_layer(embedding) # concat text and prompt_text token_len1, token_len2 = prompt_token.shape[1], token.shape[1] token, token_len = torch.concat([prompt_token, token], dim=1), prompt_token_len + token_len mask = (~make_pad_mask(token_len)).to(embedding.dtype).unsqueeze(-1).to(embedding) token = self.input_embedding(torch.clamp(token, min=0)) * mask # text encode h, h_lengths = self.encoder(token, token_len) h = self.encoder_proj(h) mel_len1, mel_len2 = prompt_feat.shape[1], int(token_len2 / 50 * 22050 / 256) h, h_lengths = self.length_regulator.inference(h[:, :token_len1], h[:, token_len1:], mel_len1, mel_len2) # get conditions conds = torch.zeros([1, mel_len1 + mel_len2, self.output_size], device=token.device) conds[:, :mel_len1] = prompt_feat conds = conds.transpose(1, 2) # mask = (~make_pad_mask(feat_len)).to(h) mask = (~make_pad_mask(torch.tensor([mel_len1 + mel_len2]))).to(h) feat = self.decoder( mu=h.transpose(1, 2).contiguous(), mask=mask.unsqueeze(1), spks=embedding, cond=conds, n_timesteps=10 ) feat = feat[:, :, mel_len1:] assert feat.shape[2] == mel_len2 return feat