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# This module is from [WeNet](https://github.com/wenet-e2e/wenet).
# ## Citations
# ```bibtex
# @inproceedings{yao2021wenet,
# title={WeNet: Production oriented Streaming and Non-streaming End-to-End Speech Recognition Toolkit},
# author={Yao, Zhuoyuan and Wu, Di and Wang, Xiong and Zhang, Binbin and Yu, Fan and Yang, Chao and Peng, Zhendong and Chen, Xiaoyu and Xie, Lei and Lei, Xin},
# booktitle={Proc. Interspeech},
# year={2021},
# address={Brno, Czech Republic },
# organization={IEEE}
# }
# @article{zhang2022wenet,
# title={WeNet 2.0: More Productive End-to-End Speech Recognition Toolkit},
# author={Zhang, Binbin and Wu, Di and Peng, Zhendong and Song, Xingchen and Yao, Zhuoyuan and Lv, Hang and Xie, Lei and Yang, Chao and Pan, Fuping and Niu, Jianwei},
# journal={arXiv preprint arXiv:2203.15455},
# year={2022}
# }
#
from collections import defaultdict
from typing import Dict, List, Optional, Tuple
import torch
import torch.nn.functional as F
from torch.nn.utils.rnn import pad_sequence
from modules.wenet_extractor.transformer.ctc import CTC
from modules.wenet_extractor.transformer.decoder import TransformerDecoder
from modules.wenet_extractor.transformer.encoder import TransformerEncoder
from modules.wenet_extractor.transformer.label_smoothing_loss import LabelSmoothingLoss
from modules.wenet_extractor.utils.common import (
IGNORE_ID,
add_sos_eos,
log_add,
remove_duplicates_and_blank,
th_accuracy,
reverse_pad_list,
)
from modules.wenet_extractor.utils.mask import (
make_pad_mask,
mask_finished_preds,
mask_finished_scores,
subsequent_mask,
)
class ASRModel(torch.nn.Module):
"""CTC-attention hybrid Encoder-Decoder model"""
def __init__(
self,
vocab_size: int,
encoder: TransformerEncoder,
decoder: TransformerDecoder,
ctc: CTC,
ctc_weight: float = 0.5,
ignore_id: int = IGNORE_ID,
reverse_weight: float = 0.0,
lsm_weight: float = 0.0,
length_normalized_loss: bool = False,
lfmmi_dir: str = "",
):
assert 0.0 <= ctc_weight <= 1.0, ctc_weight
super().__init__()
# note that eos is the same as sos (equivalent ID)
self.sos = vocab_size - 1
self.eos = vocab_size - 1
self.vocab_size = vocab_size
self.ignore_id = ignore_id
self.ctc_weight = ctc_weight
self.reverse_weight = reverse_weight
self.encoder = encoder
self.decoder = decoder
self.ctc = ctc
self.criterion_att = LabelSmoothingLoss(
size=vocab_size,
padding_idx=ignore_id,
smoothing=lsm_weight,
normalize_length=length_normalized_loss,
)
self.lfmmi_dir = lfmmi_dir
if self.lfmmi_dir != "":
self.load_lfmmi_resource()
def forward(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
text: torch.Tensor,
text_lengths: torch.Tensor,
) -> Dict[str, Optional[torch.Tensor]]:
"""Frontend + Encoder + Decoder + Calc loss
Args:
speech: (Batch, Length, ...)
speech_lengths: (Batch, )
text: (Batch, Length)
text_lengths: (Batch,)
"""
assert text_lengths.dim() == 1, text_lengths.shape
# Check that batch_size is unified
assert (
speech.shape[0]
== speech_lengths.shape[0]
== text.shape[0]
== text_lengths.shape[0]
), (speech.shape, speech_lengths.shape, text.shape, text_lengths.shape)
# 1. Encoder
encoder_out, encoder_mask = self.encoder(speech, speech_lengths)
encoder_out_lens = encoder_mask.squeeze(1).sum(1)
# 2a. Attention-decoder branch
if self.ctc_weight != 1.0:
loss_att, acc_att = self._calc_att_loss(
encoder_out, encoder_mask, text, text_lengths
)
else:
loss_att = None
# 2b. CTC branch or LF-MMI loss
if self.ctc_weight != 0.0:
if self.lfmmi_dir != "":
loss_ctc = self._calc_lfmmi_loss(encoder_out, encoder_mask, text)
else:
loss_ctc = self.ctc(encoder_out, encoder_out_lens, text, text_lengths)
else:
loss_ctc = None
if loss_ctc is None:
loss = loss_att
elif loss_att is None:
loss = loss_ctc
else:
loss = self.ctc_weight * loss_ctc + (1 - self.ctc_weight) * loss_att
return {"loss": loss, "loss_att": loss_att, "loss_ctc": loss_ctc}
def _calc_att_loss(
self,
encoder_out: torch.Tensor,
encoder_mask: torch.Tensor,
ys_pad: torch.Tensor,
ys_pad_lens: torch.Tensor,
) -> Tuple[torch.Tensor, float]:
ys_in_pad, ys_out_pad = add_sos_eos(ys_pad, self.sos, self.eos, self.ignore_id)
ys_in_lens = ys_pad_lens + 1
# reverse the seq, used for right to left decoder
r_ys_pad = reverse_pad_list(ys_pad, ys_pad_lens, float(self.ignore_id))
r_ys_in_pad, r_ys_out_pad = add_sos_eos(
r_ys_pad, self.sos, self.eos, self.ignore_id
)
# 1. Forward decoder
decoder_out, r_decoder_out, _ = self.decoder(
encoder_out,
encoder_mask,
ys_in_pad,
ys_in_lens,
r_ys_in_pad,
self.reverse_weight,
)
# 2. Compute attention loss
loss_att = self.criterion_att(decoder_out, ys_out_pad)
r_loss_att = torch.tensor(0.0)
if self.reverse_weight > 0.0:
r_loss_att = self.criterion_att(r_decoder_out, r_ys_out_pad)
loss_att = (
loss_att * (1 - self.reverse_weight) + r_loss_att * self.reverse_weight
)
acc_att = th_accuracy(
decoder_out.view(-1, self.vocab_size),
ys_out_pad,
ignore_label=self.ignore_id,
)
return loss_att, acc_att
def _forward_encoder(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
decoding_chunk_size: int = -1,
num_decoding_left_chunks: int = -1,
simulate_streaming: bool = False,
) -> Tuple[torch.Tensor, torch.Tensor]:
# Let's assume B = batch_size
# 1. Encoder
if simulate_streaming and decoding_chunk_size > 0:
encoder_out, encoder_mask = self.encoder.forward_chunk_by_chunk(
speech,
decoding_chunk_size=decoding_chunk_size,
num_decoding_left_chunks=num_decoding_left_chunks,
) # (B, maxlen, encoder_dim)
else:
encoder_out, encoder_mask = self.encoder(
speech,
speech_lengths,
decoding_chunk_size=decoding_chunk_size,
num_decoding_left_chunks=num_decoding_left_chunks,
) # (B, maxlen, encoder_dim)
return encoder_out, encoder_mask
def encoder_extractor(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
decoding_chunk_size: int = -1,
num_decoding_left_chunks: int = -1,
simulate_streaming: bool = False,
) -> Tuple[torch.Tensor, torch.Tensor]:
# assert speech.shape[0] == speech_lengths[0]
assert decoding_chunk_size != 0
batch_size = speech.shape[0]
encoder_out, encoder_mask = self._forward_encoder(
speech,
speech_lengths,
decoding_chunk_size,
num_decoding_left_chunks,
simulate_streaming,
) # (B, maxlen, encoder_dim)
return encoder_out
def recognize(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
beam_size: int = 10,
decoding_chunk_size: int = -1,
num_decoding_left_chunks: int = -1,
simulate_streaming: bool = False,
) -> torch.Tensor:
"""Apply beam search on attention decoder
Args:
speech (torch.Tensor): (batch, max_len, feat_dim)
speech_length (torch.Tensor): (batch, )
beam_size (int): beam size for beam search
decoding_chunk_size (int): decoding chunk for dynamic chunk
trained model.
<0: for decoding, use full chunk.
>0: for decoding, use fixed chunk size as set.
0: used for training, it's prohibited here
simulate_streaming (bool): whether do encoder forward in a
streaming fashion
Returns:
torch.Tensor: decoding result, (batch, max_result_len)
"""
assert speech.shape[0] == speech_lengths.shape[0]
assert decoding_chunk_size != 0
device = speech.device
batch_size = speech.shape[0]
# Let's assume B = batch_size and N = beam_size
# 1. Encoder
encoder_out, encoder_mask = self._forward_encoder(
speech,
speech_lengths,
decoding_chunk_size,
num_decoding_left_chunks,
simulate_streaming,
) # (B, maxlen, encoder_dim)
maxlen = encoder_out.size(1)
encoder_dim = encoder_out.size(2)
running_size = batch_size * beam_size
encoder_out = (
encoder_out.unsqueeze(1)
.repeat(1, beam_size, 1, 1)
.view(running_size, maxlen, encoder_dim)
) # (B*N, maxlen, encoder_dim)
encoder_mask = (
encoder_mask.unsqueeze(1)
.repeat(1, beam_size, 1, 1)
.view(running_size, 1, maxlen)
) # (B*N, 1, max_len)
hyps = torch.ones([running_size, 1], dtype=torch.long, device=device).fill_(
self.sos
) # (B*N, 1)
scores = torch.tensor(
[0.0] + [-float("inf")] * (beam_size - 1), dtype=torch.float
)
scores = (
scores.to(device).repeat([batch_size]).unsqueeze(1).to(device)
) # (B*N, 1)
end_flag = torch.zeros_like(scores, dtype=torch.bool, device=device)
cache: Optional[List[torch.Tensor]] = None
# 2. Decoder forward step by step
for i in range(1, maxlen + 1):
# Stop if all batch and all beam produce eos
if end_flag.sum() == running_size:
break
# 2.1 Forward decoder step
hyps_mask = (
subsequent_mask(i).unsqueeze(0).repeat(running_size, 1, 1).to(device)
) # (B*N, i, i)
# logp: (B*N, vocab)
logp, cache = self.decoder.forward_one_step(
encoder_out, encoder_mask, hyps, hyps_mask, cache
)
# 2.2 First beam prune: select topk best prob at current time
top_k_logp, top_k_index = logp.topk(beam_size) # (B*N, N)
top_k_logp = mask_finished_scores(top_k_logp, end_flag)
top_k_index = mask_finished_preds(top_k_index, end_flag, self.eos)
# 2.3 Second beam prune: select topk score with history
scores = scores + top_k_logp # (B*N, N), broadcast add
scores = scores.view(batch_size, beam_size * beam_size) # (B, N*N)
scores, offset_k_index = scores.topk(k=beam_size) # (B, N)
# Update cache to be consistent with new topk scores / hyps
cache_index = (offset_k_index // beam_size).view(-1) # (B*N)
base_cache_index = (
torch.arange(batch_size, device=device)
.view(-1, 1)
.repeat([1, beam_size])
* beam_size
).view(
-1
) # (B*N)
cache_index = base_cache_index + cache_index
cache = [torch.index_select(c, dim=0, index=cache_index) for c in cache]
scores = scores.view(-1, 1) # (B*N, 1)
# 2.4. Compute base index in top_k_index,
# regard top_k_index as (B*N*N),regard offset_k_index as (B*N),
# then find offset_k_index in top_k_index
base_k_index = (
torch.arange(batch_size, device=device)
.view(-1, 1)
.repeat([1, beam_size])
) # (B, N)
base_k_index = base_k_index * beam_size * beam_size
best_k_index = base_k_index.view(-1) + offset_k_index.view(-1) # (B*N)
# 2.5 Update best hyps
best_k_pred = torch.index_select(
top_k_index.view(-1), dim=-1, index=best_k_index
) # (B*N)
best_hyps_index = best_k_index // beam_size
last_best_k_hyps = torch.index_select(
hyps, dim=0, index=best_hyps_index
) # (B*N, i)
hyps = torch.cat(
(last_best_k_hyps, best_k_pred.view(-1, 1)), dim=1
) # (B*N, i+1)
# 2.6 Update end flag
end_flag = torch.eq(hyps[:, -1], self.eos).view(-1, 1)
# 3. Select best of best
scores = scores.view(batch_size, beam_size)
# TODO: length normalization
best_scores, best_index = scores.max(dim=-1)
best_hyps_index = (
best_index
+ torch.arange(batch_size, dtype=torch.long, device=device) * beam_size
)
best_hyps = torch.index_select(hyps, dim=0, index=best_hyps_index)
best_hyps = best_hyps[:, 1:]
return best_hyps, best_scores
def ctc_greedy_search(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
decoding_chunk_size: int = -1,
num_decoding_left_chunks: int = -1,
simulate_streaming: bool = False,
) -> List[List[int]]:
"""Apply CTC greedy search
Args:
speech (torch.Tensor): (batch, max_len, feat_dim)
speech_length (torch.Tensor): (batch, )
beam_size (int): beam size for beam search
decoding_chunk_size (int): decoding chunk for dynamic chunk
trained model.
<0: for decoding, use full chunk.
>0: for decoding, use fixed chunk size as set.
0: used for training, it's prohibited here
simulate_streaming (bool): whether do encoder forward in a
streaming fashion
Returns:
List[List[int]]: best path result
"""
assert speech.shape[0] == speech_lengths.shape[0]
assert decoding_chunk_size != 0
batch_size = speech.shape[0]
# Let's assume B = batch_size
encoder_out, encoder_mask = self._forward_encoder(
speech,
speech_lengths,
decoding_chunk_size,
num_decoding_left_chunks,
simulate_streaming,
) # (B, maxlen, encoder_dim)
maxlen = encoder_out.size(1)
encoder_out_lens = encoder_mask.squeeze(1).sum(1)
ctc_probs = self.ctc.log_softmax(encoder_out) # (B, maxlen, vocab_size)
topk_prob, topk_index = ctc_probs.topk(1, dim=2) # (B, maxlen, 1)
topk_index = topk_index.view(batch_size, maxlen) # (B, maxlen)
mask = make_pad_mask(encoder_out_lens, maxlen) # (B, maxlen)
topk_index = topk_index.masked_fill_(mask, self.eos) # (B, maxlen)
hyps = [hyp.tolist() for hyp in topk_index]
scores = topk_prob.max(1)
hyps = [remove_duplicates_and_blank(hyp) for hyp in hyps]
return hyps, scores
def _ctc_prefix_beam_search(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
beam_size: int,
decoding_chunk_size: int = -1,
num_decoding_left_chunks: int = -1,
simulate_streaming: bool = False,
) -> Tuple[List[List[int]], torch.Tensor]:
"""CTC prefix beam search inner implementation
Args:
speech (torch.Tensor): (batch, max_len, feat_dim)
speech_length (torch.Tensor): (batch, )
beam_size (int): beam size for beam search
decoding_chunk_size (int): decoding chunk for dynamic chunk
trained model.
<0: for decoding, use full chunk.
>0: for decoding, use fixed chunk size as set.
0: used for training, it's prohibited here
simulate_streaming (bool): whether do encoder forward in a
streaming fashion
Returns:
List[List[int]]: nbest results
torch.Tensor: encoder output, (1, max_len, encoder_dim),
it will be used for rescoring in attention rescoring mode
"""
assert speech.shape[0] == speech_lengths.shape[0]
assert decoding_chunk_size != 0
batch_size = speech.shape[0]
# For CTC prefix beam search, we only support batch_size=1
assert batch_size == 1
# Let's assume B = batch_size and N = beam_size
# 1. Encoder forward and get CTC score
encoder_out, encoder_mask = self._forward_encoder(
speech,
speech_lengths,
decoding_chunk_size,
num_decoding_left_chunks,
simulate_streaming,
) # (B, maxlen, encoder_dim)
maxlen = encoder_out.size(1)
ctc_probs = self.ctc.log_softmax(encoder_out) # (1, maxlen, vocab_size)
ctc_probs = ctc_probs.squeeze(0)
# cur_hyps: (prefix, (blank_ending_score, none_blank_ending_score))
cur_hyps = [(tuple(), (0.0, -float("inf")))]
# 2. CTC beam search step by step
for t in range(0, maxlen):
logp = ctc_probs[t] # (vocab_size,)
# key: prefix, value (pb, pnb), default value(-inf, -inf)
next_hyps = defaultdict(lambda: (-float("inf"), -float("inf")))
# 2.1 First beam prune: select topk best
top_k_logp, top_k_index = logp.topk(beam_size) # (beam_size,)
for s in top_k_index:
s = s.item()
ps = logp[s].item()
for prefix, (pb, pnb) in cur_hyps:
last = prefix[-1] if len(prefix) > 0 else None
if s == 0: # blank
n_pb, n_pnb = next_hyps[prefix]
n_pb = log_add([n_pb, pb + ps, pnb + ps])
next_hyps[prefix] = (n_pb, n_pnb)
elif s == last:
# Update *ss -> *s;
n_pb, n_pnb = next_hyps[prefix]
n_pnb = log_add([n_pnb, pnb + ps])
next_hyps[prefix] = (n_pb, n_pnb)
# Update *s-s -> *ss, - is for blank
n_prefix = prefix + (s,)
n_pb, n_pnb = next_hyps[n_prefix]
n_pnb = log_add([n_pnb, pb + ps])
next_hyps[n_prefix] = (n_pb, n_pnb)
else:
n_prefix = prefix + (s,)
n_pb, n_pnb = next_hyps[n_prefix]
n_pnb = log_add([n_pnb, pb + ps, pnb + ps])
next_hyps[n_prefix] = (n_pb, n_pnb)
# 2.2 Second beam prune
next_hyps = sorted(
next_hyps.items(), key=lambda x: log_add(list(x[1])), reverse=True
)
cur_hyps = next_hyps[:beam_size]
hyps = [(y[0], log_add([y[1][0], y[1][1]])) for y in cur_hyps]
return hyps, encoder_out
def ctc_prefix_beam_search(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
beam_size: int,
decoding_chunk_size: int = -1,
num_decoding_left_chunks: int = -1,
simulate_streaming: bool = False,
) -> List[int]:
"""Apply CTC prefix beam search
Args:
speech (torch.Tensor): (batch, max_len, feat_dim)
speech_length (torch.Tensor): (batch, )
beam_size (int): beam size for beam search
decoding_chunk_size (int): decoding chunk for dynamic chunk
trained model.
<0: for decoding, use full chunk.
>0: for decoding, use fixed chunk size as set.
0: used for training, it's prohibited here
simulate_streaming (bool): whether do encoder forward in a
streaming fashion
Returns:
List[int]: CTC prefix beam search nbest results
"""
hyps, _ = self._ctc_prefix_beam_search(
speech,
speech_lengths,
beam_size,
decoding_chunk_size,
num_decoding_left_chunks,
simulate_streaming,
)
return hyps[0]
def attention_rescoring(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
beam_size: int,
decoding_chunk_size: int = -1,
num_decoding_left_chunks: int = -1,
ctc_weight: float = 0.0,
simulate_streaming: bool = False,
reverse_weight: float = 0.0,
) -> List[int]:
"""Apply attention rescoring decoding, CTC prefix beam search
is applied first to get nbest, then we resoring the nbest on
attention decoder with corresponding encoder out
Args:
speech (torch.Tensor): (batch, max_len, feat_dim)
speech_length (torch.Tensor): (batch, )
beam_size (int): beam size for beam search
decoding_chunk_size (int): decoding chunk for dynamic chunk
trained model.
<0: for decoding, use full chunk.
>0: for decoding, use fixed chunk size as set.
0: used for training, it's prohibited here
simulate_streaming (bool): whether do encoder forward in a
streaming fashion
reverse_weight (float): right to left decoder weight
ctc_weight (float): ctc score weight
Returns:
List[int]: Attention rescoring result
"""
assert speech.shape[0] == speech_lengths.shape[0]
assert decoding_chunk_size != 0
if reverse_weight > 0.0:
# decoder should be a bitransformer decoder if reverse_weight > 0.0
assert hasattr(self.decoder, "right_decoder")
device = speech.device
batch_size = speech.shape[0]
# For attention rescoring we only support batch_size=1
assert batch_size == 1
# encoder_out: (1, maxlen, encoder_dim), len(hyps) = beam_size
hyps, encoder_out = self._ctc_prefix_beam_search(
speech,
speech_lengths,
beam_size,
decoding_chunk_size,
num_decoding_left_chunks,
simulate_streaming,
)
assert len(hyps) == beam_size
hyps_pad = pad_sequence(
[torch.tensor(hyp[0], device=device, dtype=torch.long) for hyp in hyps],
True,
self.ignore_id,
) # (beam_size, max_hyps_len)
ori_hyps_pad = hyps_pad
hyps_lens = torch.tensor(
[len(hyp[0]) for hyp in hyps], device=device, dtype=torch.long
) # (beam_size,)
hyps_pad, _ = add_sos_eos(hyps_pad, self.sos, self.eos, self.ignore_id)
hyps_lens = hyps_lens + 1 # Add <sos> at begining
encoder_out = encoder_out.repeat(beam_size, 1, 1)
encoder_mask = torch.ones(
beam_size, 1, encoder_out.size(1), dtype=torch.bool, device=device
)
# used for right to left decoder
r_hyps_pad = reverse_pad_list(ori_hyps_pad, hyps_lens, self.ignore_id)
r_hyps_pad, _ = add_sos_eos(r_hyps_pad, self.sos, self.eos, self.ignore_id)
decoder_out, r_decoder_out, _ = self.decoder(
encoder_out, encoder_mask, hyps_pad, hyps_lens, r_hyps_pad, reverse_weight
) # (beam_size, max_hyps_len, vocab_size)
decoder_out = torch.nn.functional.log_softmax(decoder_out, dim=-1)
decoder_out = decoder_out.cpu().numpy()
# r_decoder_out will be 0.0, if reverse_weight is 0.0 or decoder is a
# conventional transformer decoder.
r_decoder_out = torch.nn.functional.log_softmax(r_decoder_out, dim=-1)
r_decoder_out = r_decoder_out.cpu().numpy()
# Only use decoder score for rescoring
best_score = -float("inf")
best_index = 0
for i, hyp in enumerate(hyps):
score = 0.0
for j, w in enumerate(hyp[0]):
score += decoder_out[i][j][w]
score += decoder_out[i][len(hyp[0])][self.eos]
# add right to left decoder score
if reverse_weight > 0:
r_score = 0.0
for j, w in enumerate(hyp[0]):
r_score += r_decoder_out[i][len(hyp[0]) - j - 1][w]
r_score += r_decoder_out[i][len(hyp[0])][self.eos]
score = score * (1 - reverse_weight) + r_score * reverse_weight
# add ctc score
score += hyp[1] * ctc_weight
if score > best_score:
best_score = score
best_index = i
return hyps[best_index][0], best_score
@torch.jit.unused
def load_lfmmi_resource(self):
with open("{}/tokens.txt".format(self.lfmmi_dir), "r") as fin:
for line in fin:
arr = line.strip().split()
if arr[0] == "<sos/eos>":
self.sos_eos_id = int(arr[1])
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
self.graph_compiler = MmiTrainingGraphCompiler(
self.lfmmi_dir,
device=device,
oov="<UNK>",
sos_id=self.sos_eos_id,
eos_id=self.sos_eos_id,
)
self.lfmmi = LFMMILoss(
graph_compiler=self.graph_compiler,
den_scale=1,
use_pruned_intersect=False,
)
self.word_table = {}
with open("{}/words.txt".format(self.lfmmi_dir), "r") as fin:
for line in fin:
arr = line.strip().split()
assert len(arr) == 2
self.word_table[int(arr[1])] = arr[0]
@torch.jit.unused
def _calc_lfmmi_loss(self, encoder_out, encoder_mask, text):
ctc_probs = self.ctc.log_softmax(encoder_out)
supervision_segments = torch.stack(
(
torch.arange(len(encoder_mask)),
torch.zeros(len(encoder_mask)),
encoder_mask.squeeze(dim=1).sum(dim=1).to("cpu"),
),
1,
).to(torch.int32)
dense_fsa_vec = k2.DenseFsaVec(
ctc_probs,
supervision_segments,
allow_truncate=3,
)
text = [
" ".join([self.word_table[j.item()] for j in i if j != -1]) for i in text
]
loss = self.lfmmi(dense_fsa_vec=dense_fsa_vec, texts=text) / len(text)
return loss
def load_hlg_resource_if_necessary(self, hlg, word):
if not hasattr(self, "hlg"):
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
self.hlg = k2.Fsa.from_dict(torch.load(hlg, map_location=device))
if not hasattr(self.hlg, "lm_scores"):
self.hlg.lm_scores = self.hlg.scores.clone()
if not hasattr(self, "word_table"):
self.word_table = {}
with open(word, "r") as fin:
for line in fin:
arr = line.strip().split()
assert len(arr) == 2
self.word_table[int(arr[1])] = arr[0]
@torch.no_grad()
def hlg_onebest(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
decoding_chunk_size: int = -1,
num_decoding_left_chunks: int = -1,
simulate_streaming: bool = False,
hlg: str = "",
word: str = "",
symbol_table: Dict[str, int] = None,
) -> List[int]:
self.load_hlg_resource_if_necessary(hlg, word)
encoder_out, encoder_mask = self._forward_encoder(
speech,
speech_lengths,
decoding_chunk_size,
num_decoding_left_chunks,
simulate_streaming,
) # (B, maxlen, encoder_dim)
ctc_probs = self.ctc.log_softmax(encoder_out) # (1, maxlen, vocab_size)
supervision_segments = torch.stack(
(
torch.arange(len(encoder_mask)),
torch.zeros(len(encoder_mask)),
encoder_mask.squeeze(dim=1).sum(dim=1).cpu(),
),
1,
).to(torch.int32)
lattice = get_lattice(
nnet_output=ctc_probs,
decoding_graph=self.hlg,
supervision_segments=supervision_segments,
search_beam=20,
output_beam=7,
min_active_states=30,
max_active_states=10000,
subsampling_factor=4,
)
best_path = one_best_decoding(lattice=lattice, use_double_scores=True)
hyps = get_texts(best_path)
hyps = [[symbol_table[k] for j in i for k in self.word_table[j]] for i in hyps]
return hyps
@torch.no_grad()
def hlg_rescore(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
decoding_chunk_size: int = -1,
num_decoding_left_chunks: int = -1,
simulate_streaming: bool = False,
lm_scale: float = 0,
decoder_scale: float = 0,
r_decoder_scale: float = 0,
hlg: str = "",
word: str = "",
symbol_table: Dict[str, int] = None,
) -> List[int]:
self.load_hlg_resource_if_necessary(hlg, word)
device = speech.device
encoder_out, encoder_mask = self._forward_encoder(
speech,
speech_lengths,
decoding_chunk_size,
num_decoding_left_chunks,
simulate_streaming,
) # (B, maxlen, encoder_dim)
ctc_probs = self.ctc.log_softmax(encoder_out) # (1, maxlen, vocab_size)
supervision_segments = torch.stack(
(
torch.arange(len(encoder_mask)),
torch.zeros(len(encoder_mask)),
encoder_mask.squeeze(dim=1).sum(dim=1).cpu(),
),
1,
).to(torch.int32)
lattice = get_lattice(
nnet_output=ctc_probs,
decoding_graph=self.hlg,
supervision_segments=supervision_segments,
search_beam=20,
output_beam=7,
min_active_states=30,
max_active_states=10000,
subsampling_factor=4,
)
nbest = Nbest.from_lattice(
lattice=lattice,
num_paths=100,
use_double_scores=True,
nbest_scale=0.5,
)
nbest = nbest.intersect(lattice)
assert hasattr(nbest.fsa, "lm_scores")
assert hasattr(nbest.fsa, "tokens")
assert isinstance(nbest.fsa.tokens, torch.Tensor)
tokens_shape = nbest.fsa.arcs.shape().remove_axis(1)
tokens = k2.RaggedTensor(tokens_shape, nbest.fsa.tokens)
tokens = tokens.remove_values_leq(0)
hyps = tokens.tolist()
# cal attention_score
hyps_pad = pad_sequence(
[torch.tensor(hyp, device=device, dtype=torch.long) for hyp in hyps],
True,
self.ignore_id,
) # (beam_size, max_hyps_len)
ori_hyps_pad = hyps_pad
hyps_lens = torch.tensor(
[len(hyp) for hyp in hyps], device=device, dtype=torch.long
) # (beam_size,)
hyps_pad, _ = add_sos_eos(hyps_pad, self.sos, self.eos, self.ignore_id)
hyps_lens = hyps_lens + 1 # Add <sos> at begining
encoder_out_repeat = []
tot_scores = nbest.tot_scores()
repeats = [tot_scores[i].shape[0] for i in range(tot_scores.dim0)]
for i in range(len(encoder_out)):
encoder_out_repeat.append(encoder_out[i : i + 1].repeat(repeats[i], 1, 1))
encoder_out = torch.concat(encoder_out_repeat, dim=0)
encoder_mask = torch.ones(
encoder_out.size(0), 1, encoder_out.size(1), dtype=torch.bool, device=device
)
# used for right to left decoder
r_hyps_pad = reverse_pad_list(ori_hyps_pad, hyps_lens, self.ignore_id)
r_hyps_pad, _ = add_sos_eos(r_hyps_pad, self.sos, self.eos, self.ignore_id)
reverse_weight = 0.5
decoder_out, r_decoder_out, _ = self.decoder(
encoder_out, encoder_mask, hyps_pad, hyps_lens, r_hyps_pad, reverse_weight
) # (beam_size, max_hyps_len, vocab_size)
decoder_out = torch.nn.functional.log_softmax(decoder_out, dim=-1)
decoder_out = decoder_out
# r_decoder_out will be 0.0, if reverse_weight is 0.0 or decoder is a
# conventional transformer decoder.
r_decoder_out = torch.nn.functional.log_softmax(r_decoder_out, dim=-1)
r_decoder_out = r_decoder_out
decoder_scores = torch.tensor(
[
sum([decoder_out[i, j, hyps[i][j]] for j in range(len(hyps[i]))])
for i in range(len(hyps))
],
device=device,
)
r_decoder_scores = []
for i in range(len(hyps)):
score = 0
for j in range(len(hyps[i])):
score += r_decoder_out[i, len(hyps[i]) - j - 1, hyps[i][j]]
score += r_decoder_out[i, len(hyps[i]), self.eos]
r_decoder_scores.append(score)
r_decoder_scores = torch.tensor(r_decoder_scores, device=device)
am_scores = nbest.compute_am_scores()
ngram_lm_scores = nbest.compute_lm_scores()
tot_scores = (
am_scores.values
+ lm_scale * ngram_lm_scores.values
+ decoder_scale * decoder_scores
+ r_decoder_scale * r_decoder_scores
)
ragged_tot_scores = k2.RaggedTensor(nbest.shape, tot_scores)
max_indexes = ragged_tot_scores.argmax()
best_path = k2.index_fsa(nbest.fsa, max_indexes)
hyps = get_texts(best_path)
hyps = [[symbol_table[k] for j in i for k in self.word_table[j]] for i in hyps]
return hyps
@torch.jit.export
def subsampling_rate(self) -> int:
"""Export interface for c++ call, return subsampling_rate of the
model
"""
return self.encoder.embed.subsampling_rate
@torch.jit.export
def right_context(self) -> int:
"""Export interface for c++ call, return right_context of the model"""
return self.encoder.embed.right_context
@torch.jit.export
def sos_symbol(self) -> int:
"""Export interface for c++ call, return sos symbol id of the model"""
return self.sos
@torch.jit.export
def eos_symbol(self) -> int:
"""Export interface for c++ call, return eos symbol id of the model"""
return self.eos
@torch.jit.export
def forward_encoder_chunk(
self,
xs: torch.Tensor,
offset: int,
required_cache_size: int,
att_cache: torch.Tensor = torch.zeros(0, 0, 0, 0),
cnn_cache: torch.Tensor = torch.zeros(0, 0, 0, 0),
) -> Tuple[torch.Tensor, torch.Tensor, torch.Tensor]:
""" Export interface for c++ call, give input chunk xs, and return
output from time 0 to current chunk.
Args:
xs (torch.Tensor): chunk input, with shape (b=1, time, mel-dim),
where `time == (chunk_size - 1) * subsample_rate + \
subsample.right_context + 1`
offset (int): current offset in encoder output time stamp
required_cache_size (int): cache size required for next chunk
compuation
>=0: actual cache size
<0: means all history cache is required
att_cache (torch.Tensor): cache tensor for KEY & VALUE in
transformer/conformer attention, with shape
(elayers, head, cache_t1, d_k * 2), where
`head * d_k == hidden-dim` and
`cache_t1 == chunk_size * num_decoding_left_chunks`.
cnn_cache (torch.Tensor): cache tensor for cnn_module in conformer,
(elayers, b=1, hidden-dim, cache_t2), where
`cache_t2 == cnn.lorder - 1`
Returns:
torch.Tensor: output of current input xs,
with shape (b=1, chunk_size, hidden-dim).
torch.Tensor: new attention cache required for next chunk, with
dynamic shape (elayers, head, ?, d_k * 2)
depending on required_cache_size.
torch.Tensor: new conformer cnn cache required for next chunk, with
same shape as the original cnn_cache.
"""
return self.encoder.forward_chunk(
xs, offset, required_cache_size, att_cache, cnn_cache
)
@torch.jit.export
def ctc_activation(self, xs: torch.Tensor) -> torch.Tensor:
"""Export interface for c++ call, apply linear transform and log
softmax before ctc
Args:
xs (torch.Tensor): encoder output
Returns:
torch.Tensor: activation before ctc
"""
return self.ctc.log_softmax(xs)
@torch.jit.export
def is_bidirectional_decoder(self) -> bool:
"""
Returns:
torch.Tensor: decoder output
"""
if hasattr(self.decoder, "right_decoder"):
return True
else:
return False
@torch.jit.export
def forward_attention_decoder(
self,
hyps: torch.Tensor,
hyps_lens: torch.Tensor,
encoder_out: torch.Tensor,
reverse_weight: float = 0,
) -> Tuple[torch.Tensor, torch.Tensor]:
"""Export interface for c++ call, forward decoder with multiple
hypothesis from ctc prefix beam search and one encoder output
Args:
hyps (torch.Tensor): hyps from ctc prefix beam search, already
pad sos at the begining
hyps_lens (torch.Tensor): length of each hyp in hyps
encoder_out (torch.Tensor): corresponding encoder output
r_hyps (torch.Tensor): hyps from ctc prefix beam search, already
pad eos at the begining which is used fo right to left decoder
reverse_weight: used for verfing whether used right to left decoder,
> 0 will use.
Returns:
torch.Tensor: decoder output
"""
assert encoder_out.size(0) == 1
num_hyps = hyps.size(0)
assert hyps_lens.size(0) == num_hyps
encoder_out = encoder_out.repeat(num_hyps, 1, 1)
encoder_mask = torch.ones(
num_hyps,
1,
encoder_out.size(1),
dtype=torch.bool,
device=encoder_out.device,
)
# input for right to left decoder
# this hyps_lens has count <sos> token, we need minus it.
r_hyps_lens = hyps_lens - 1
# this hyps has included <sos> token, so it should be
# convert the original hyps.
r_hyps = hyps[:, 1:]
# >>> r_hyps
# >>> tensor([[ 1, 2, 3],
# >>> [ 9, 8, 4],
# >>> [ 2, -1, -1]])
# >>> r_hyps_lens
# >>> tensor([3, 3, 1])
# NOTE(Mddct): `pad_sequence` is not supported by ONNX, it is used
# in `reverse_pad_list` thus we have to refine the below code.
# Issue: https://github.com/wenet-e2e/wenet/issues/1113
# Equal to:
# >>> r_hyps = reverse_pad_list(r_hyps, r_hyps_lens, float(self.ignore_id))
# >>> r_hyps, _ = add_sos_eos(r_hyps, self.sos, self.eos, self.ignore_id)
max_len = torch.max(r_hyps_lens)
index_range = torch.arange(0, max_len, 1).to(encoder_out.device)
seq_len_expand = r_hyps_lens.unsqueeze(1)
seq_mask = seq_len_expand > index_range # (beam, max_len)
# >>> seq_mask
# >>> tensor([[ True, True, True],
# >>> [ True, True, True],
# >>> [ True, False, False]])
index = (seq_len_expand - 1) - index_range # (beam, max_len)
# >>> index
# >>> tensor([[ 2, 1, 0],
# >>> [ 2, 1, 0],
# >>> [ 0, -1, -2]])
index = index * seq_mask
# >>> index
# >>> tensor([[2, 1, 0],
# >>> [2, 1, 0],
# >>> [0, 0, 0]])
r_hyps = torch.gather(r_hyps, 1, index)
# >>> r_hyps
# >>> tensor([[3, 2, 1],
# >>> [4, 8, 9],
# >>> [2, 2, 2]])
r_hyps = torch.where(seq_mask, r_hyps, self.eos)
# >>> r_hyps
# >>> tensor([[3, 2, 1],
# >>> [4, 8, 9],
# >>> [2, eos, eos]])
r_hyps = torch.cat([hyps[:, 0:1], r_hyps], dim=1)
# >>> r_hyps
# >>> tensor([[sos, 3, 2, 1],
# >>> [sos, 4, 8, 9],
# >>> [sos, 2, eos, eos]])
decoder_out, r_decoder_out, _ = self.decoder(
encoder_out, encoder_mask, hyps, hyps_lens, r_hyps, reverse_weight
) # (num_hyps, max_hyps_len, vocab_size)
decoder_out = torch.nn.functional.log_softmax(decoder_out, dim=-1)
# right to left decoder may be not used during decoding process,
# which depends on reverse_weight param.
# r_dccoder_out will be 0.0, if reverse_weight is 0.0
r_decoder_out = torch.nn.functional.log_softmax(r_decoder_out, dim=-1)
return decoder_out, r_decoder_out
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