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| import logging | |
| import torch | |
| import torch.nn.functional as F | |
| class CTC(torch.nn.Module): | |
| """CTC module. | |
| Args: | |
| odim: dimension of outputs | |
| encoder_output_size: number of encoder projection units | |
| dropout_rate: dropout rate (0.0 ~ 1.0) | |
| ctc_type: builtin or warpctc | |
| reduce: reduce the CTC loss into a scalar | |
| """ | |
| def __init__( | |
| self, | |
| odim: int, | |
| encoder_output_size: int, | |
| dropout_rate: float = 0.0, | |
| ctc_type: str = "builtin", | |
| reduce: bool = True, | |
| ignore_nan_grad: bool = True, | |
| ): | |
| super().__init__() | |
| eprojs = encoder_output_size | |
| self.dropout_rate = dropout_rate | |
| self.ctc_lo = torch.nn.Linear(eprojs, odim) | |
| self.ctc_type = ctc_type | |
| self.ignore_nan_grad = ignore_nan_grad | |
| if self.ctc_type == "builtin": | |
| self.ctc_loss = torch.nn.CTCLoss(reduction="none") | |
| elif self.ctc_type == "warpctc": | |
| import warpctc_pytorch as warp_ctc | |
| if ignore_nan_grad: | |
| logging.warning("ignore_nan_grad option is not supported for warp_ctc") | |
| self.ctc_loss = warp_ctc.CTCLoss(size_average=True, reduce=reduce) | |
| else: | |
| raise ValueError( | |
| f'ctc_type must be "builtin" or "warpctc": {self.ctc_type}' | |
| ) | |
| self.reduce = reduce | |
| def loss_fn(self, th_pred, th_target, th_ilen, th_olen) -> torch.Tensor: | |
| if self.ctc_type == "builtin": | |
| th_pred = th_pred.log_softmax(2) | |
| loss = self.ctc_loss(th_pred, th_target, th_ilen, th_olen) | |
| if loss.requires_grad and self.ignore_nan_grad: | |
| # ctc_grad: (L, B, O) | |
| ctc_grad = loss.grad_fn(torch.ones_like(loss)) | |
| ctc_grad = ctc_grad.sum([0, 2]) | |
| indices = torch.isfinite(ctc_grad) | |
| size = indices.long().sum() | |
| if size == 0: | |
| # Return as is | |
| logging.warning( | |
| "All samples in this mini-batch got nan grad." | |
| " Returning nan value instead of CTC loss" | |
| ) | |
| elif size != th_pred.size(1): | |
| logging.warning( | |
| f"{th_pred.size(1) - size}/{th_pred.size(1)}" | |
| " samples got nan grad." | |
| " These were ignored for CTC loss." | |
| ) | |
| # Create mask for target | |
| target_mask = torch.full( | |
| [th_target.size(0)], | |
| 1, | |
| dtype=torch.bool, | |
| device=th_target.device, | |
| ) | |
| s = 0 | |
| for ind, le in enumerate(th_olen): | |
| if not indices[ind]: | |
| target_mask[s : s + le] = 0 | |
| s += le | |
| # Calc loss again using maksed data | |
| loss = self.ctc_loss( | |
| th_pred[:, indices, :], | |
| th_target[target_mask], | |
| th_ilen[indices], | |
| th_olen[indices], | |
| ) | |
| else: | |
| size = th_pred.size(1) | |
| if self.reduce: | |
| # Batch-size average | |
| loss = loss.sum() / size | |
| else: | |
| loss = loss / size | |
| return loss | |
| elif self.ctc_type == "warpctc": | |
| # warpctc only supports float32 | |
| th_pred = th_pred.to(dtype=torch.float32) | |
| th_target = th_target.cpu().int() | |
| th_ilen = th_ilen.cpu().int() | |
| th_olen = th_olen.cpu().int() | |
| loss = self.ctc_loss(th_pred, th_target, th_ilen, th_olen) | |
| if self.reduce: | |
| # NOTE: sum() is needed to keep consistency since warpctc | |
| # return as tensor w/ shape (1,) | |
| # but builtin return as tensor w/o shape (scalar). | |
| loss = loss.sum() | |
| return loss | |
| elif self.ctc_type == "gtnctc": | |
| log_probs = torch.nn.functional.log_softmax(th_pred, dim=2) | |
| return self.ctc_loss(log_probs, th_target, th_ilen, 0, "none") | |
| else: | |
| raise NotImplementedError | |
| def forward(self, hs_pad, hlens, ys_pad, ys_lens): | |
| """Calculate CTC loss. | |
| Args: | |
| hs_pad: batch of padded hidden state sequences (B, Tmax, D) | |
| hlens: batch of lengths of hidden state sequences (B) | |
| ys_pad: batch of padded character id sequence tensor (B, Lmax) | |
| ys_lens: batch of lengths of character sequence (B) | |
| """ | |
| # hs_pad: (B, L, NProj) -> ys_hat: (B, L, Nvocab) | |
| ys_hat = self.ctc_lo(F.dropout(hs_pad, p=self.dropout_rate)) | |
| if self.ctc_type == "gtnctc": | |
| # gtn expects list form for ys | |
| ys_true = [y[y != -1] for y in ys_pad] # parse padded ys | |
| else: | |
| # ys_hat: (B, L, D) -> (L, B, D) | |
| ys_hat = ys_hat.transpose(0, 1) | |
| # (B, L) -> (BxL,) | |
| ys_true = torch.cat([ys_pad[i, :l] for i, l in enumerate(ys_lens)]) | |
| loss = self.loss_fn(ys_hat, ys_true, hlens, ys_lens).to( | |
| device=hs_pad.device, dtype=hs_pad.dtype | |
| ) | |
| return loss | |
| def softmax(self, hs_pad): | |
| """softmax of frame activations | |
| Args: | |
| Tensor hs_pad: 3d tensor (B, Tmax, eprojs) | |
| Returns: | |
| torch.Tensor: softmax applied 3d tensor (B, Tmax, odim) | |
| """ | |
| return F.softmax(self.ctc_lo(hs_pad), dim=2) | |
| def log_softmax(self, hs_pad): | |
| """log_softmax of frame activations | |
| Args: | |
| Tensor hs_pad: 3d tensor (B, Tmax, eprojs) | |
| Returns: | |
| torch.Tensor: log softmax applied 3d tensor (B, Tmax, odim) | |
| """ | |
| return F.log_softmax(self.ctc_lo(hs_pad), dim=2) | |
| def argmax(self, hs_pad): | |
| """argmax of frame activations | |
| Args: | |
| torch.Tensor hs_pad: 3d tensor (B, Tmax, eprojs) | |
| Returns: | |
| torch.Tensor: argmax applied 2d tensor (B, Tmax) | |
| """ | |
| return torch.argmax(self.ctc_lo(hs_pad), dim=2) | |