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#!/usr/bin/env python3
# -*- encoding: utf-8 -*-
# Copyright FunASR (https://github.com/alibaba-damo-academy/FunASR). All Rights Reserved.
# MIT License (https://opensource.org/licenses/MIT)
import logging
from typing import Union, Dict, List, Tuple, Optional
import time
import torch
import torch.nn as nn
from torch.cuda.amp import autocast
from funasr.losses.label_smoothing_loss import LabelSmoothingLoss
from funasr.models.ctc.ctc import CTC
from funasr.models.transformer.utils.add_sos_eos import add_sos_eos
from funasr.metrics.compute_acc import th_accuracy
# from funasr.models.e2e_asr_common import ErrorCalculator
from funasr.train_utils.device_funcs import force_gatherable
from funasr.utils.load_utils import load_audio_text_image_video, extract_fbank
from funasr.utils import postprocess_utils
from funasr.utils.datadir_writer import DatadirWriter
from funasr.register import tables
@tables.register("model_classes", "LCBNet")
class LCBNet(nn.Module):
"""LCBNet: Lightweight Convolutional Block Network for ASR.
Efficient model design using depthwise separable convolutions
for low-resource deployment scenarios.
Inherits Paraformer pipeline.
"""
def __init__(
self,
specaug: str = None,
specaug_conf: dict = None,
normalize: str = None,
normalize_conf: dict = None,
encoder: str = None,
encoder_conf: dict = None,
decoder: str = None,
decoder_conf: dict = None,
text_encoder: str = None,
text_encoder_conf: dict = None,
bias_predictor: str = None,
bias_predictor_conf: dict = None,
fusion_encoder: str = None,
fusion_encoder_conf: dict = None,
ctc: str = None,
ctc_conf: dict = None,
ctc_weight: float = 0.5,
interctc_weight: float = 0.0,
select_num: int = 2,
select_length: int = 3,
insert_blank: bool = True,
input_size: int = 80,
vocab_size: int = -1,
ignore_id: int = -1,
blank_id: int = 0,
sos: int = 1,
eos: int = 2,
lsm_weight: float = 0.0,
length_normalized_loss: bool = False,
report_cer: bool = True,
report_wer: bool = True,
sym_space: str = "<space>",
sym_blank: str = "<blank>",
# extract_feats_in_collect_stats: bool = True,
share_embedding: bool = False,
# preencoder: Optional[AbsPreEncoder] = None,
# postencoder: Optional[AbsPostEncoder] = None,
**kwargs,
):
"""Initialize LCBNet.
Args:
specaug: TODO.
specaug_conf: Configuration dict for specaug.
normalize: TODO.
normalize_conf: Configuration dict for normalize.
encoder: TODO.
encoder_conf: Configuration dict for encoder.
decoder: TODO.
decoder_conf: Configuration dict for decoder.
text_encoder: TODO.
text_encoder_conf: Configuration dict for text_encoder.
bias_predictor: TODO.
bias_predictor_conf: Configuration dict for bias_predictor.
fusion_encoder: TODO.
fusion_encoder_conf: Configuration dict for fusion_encoder.
ctc: TODO.
ctc_conf: Configuration dict for ctc.
ctc_weight: TODO.
interctc_weight: TODO.
select_num: TODO.
select_length: TODO.
insert_blank: TODO.
input_size: Size/dimension parameter.
vocab_size: Size/dimension parameter.
ignore_id: TODO.
blank_id: TODO.
sos: TODO.
eos: TODO.
lsm_weight: TODO.
length_normalized_loss: TODO.
report_cer: TODO.
report_wer: TODO.
sym_space: TODO.
sym_blank: TODO.
share_embedding: TODO.
**kwargs: Additional keyword arguments.
"""
super().__init__()
if specaug is not None:
specaug_class = tables.specaug_classes.get(specaug)
specaug = specaug_class(**specaug_conf)
if normalize is not None:
normalize_class = tables.normalize_classes.get(normalize)
normalize = normalize_class(**normalize_conf)
encoder_class = tables.encoder_classes.get(encoder)
encoder = encoder_class(input_size=input_size, **encoder_conf)
encoder_output_size = encoder.output_size()
# lcbnet modules: text encoder, fusion encoder and bias predictor
text_encoder_class = tables.encoder_classes.get(text_encoder)
text_encoder = text_encoder_class(input_size=vocab_size, **text_encoder_conf)
fusion_encoder_class = tables.encoder_classes.get(fusion_encoder)
fusion_encoder = fusion_encoder_class(**fusion_encoder_conf)
bias_predictor_class = tables.encoder_classes.get(bias_predictor)
bias_predictor = bias_predictor_class(**bias_predictor_conf)
if decoder is not None:
decoder_class = tables.decoder_classes.get(decoder)
decoder = decoder_class(
vocab_size=vocab_size,
encoder_output_size=encoder_output_size,
**decoder_conf,
)
if ctc_weight > 0.0:
if ctc_conf is None:
ctc_conf = {}
ctc = CTC(odim=vocab_size, encoder_output_size=encoder_output_size, **ctc_conf)
self.blank_id = blank_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.specaug = specaug
self.normalize = normalize
self.encoder = encoder
# lcbnet
self.text_encoder = text_encoder
self.fusion_encoder = fusion_encoder
self.bias_predictor = bias_predictor
self.select_num = select_num
self.select_length = select_length
self.insert_blank = insert_blank
if not hasattr(self.encoder, "interctc_use_conditioning"):
self.encoder.interctc_use_conditioning = False
if self.encoder.interctc_use_conditioning:
self.encoder.conditioning_layer = torch.nn.Linear(
vocab_size, self.encoder.output_size()
)
self.interctc_weight = interctc_weight
# self.error_calculator = None
if ctc_weight == 1.0:
self.decoder = None
else:
self.decoder = decoder
self.criterion_att = LabelSmoothingLoss(
size=vocab_size,
padding_idx=ignore_id,
smoothing=lsm_weight,
normalize_length=length_normalized_loss,
)
#
# if report_cer or report_wer:
# self.error_calculator = ErrorCalculator(
# token_list, sym_space, sym_blank, report_cer, report_wer
# )
#
self.error_calculator = None
if ctc_weight == 0.0:
self.ctc = None
else:
self.ctc = ctc
self.share_embedding = share_embedding
if self.share_embedding:
self.decoder.embed = None
self.length_normalized_loss = length_normalized_loss
self.beam_search = None
def forward(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
text: torch.Tensor,
text_lengths: torch.Tensor,
**kwargs,
) -> Tuple[torch.Tensor, Dict[str, torch.Tensor], torch.Tensor]:
"""Encoder + Decoder + Calc loss
Args:
speech: (Batch, Length, ...)
speech_lengths: (Batch, )
text: (Batch, Length)
text_lengths: (Batch,)
"""
if len(text_lengths.size()) > 1:
text_lengths = text_lengths[:, 0]
if len(speech_lengths.size()) > 1:
speech_lengths = speech_lengths[:, 0]
batch_size = speech.shape[0]
# 1. Encoder
encoder_out, encoder_out_lens = self.encode(speech, speech_lengths)
intermediate_outs = None
if isinstance(encoder_out, tuple):
intermediate_outs = encoder_out[1]
encoder_out = encoder_out[0]
loss_att, acc_att, cer_att, wer_att = None, None, None, None
loss_ctc, cer_ctc = None, None
stats = dict()
# decoder: CTC branch
if self.ctc_weight != 0.0:
loss_ctc, cer_ctc = self._calc_ctc_loss(
encoder_out, encoder_out_lens, text, text_lengths
)
# Collect CTC branch stats
stats["loss_ctc"] = loss_ctc.detach() if loss_ctc is not None else None
stats["cer_ctc"] = cer_ctc
# Intermediate CTC (optional)
loss_interctc = 0.0
if self.interctc_weight != 0.0 and intermediate_outs is not None:
for layer_idx, intermediate_out in intermediate_outs:
# we assume intermediate_out has the same length & padding
# as those of encoder_out
loss_ic, cer_ic = self._calc_ctc_loss(
intermediate_out, encoder_out_lens, text, text_lengths
)
loss_interctc = loss_interctc + loss_ic
# Collect Intermedaite CTC stats
stats["loss_interctc_layer{}".format(layer_idx)] = (
loss_ic.detach() if loss_ic is not None else None
)
stats["cer_interctc_layer{}".format(layer_idx)] = cer_ic
loss_interctc = loss_interctc / len(intermediate_outs)
# calculate whole encoder loss
loss_ctc = (1 - self.interctc_weight) * loss_ctc + self.interctc_weight * loss_interctc
# decoder: Attention decoder branch
loss_att, acc_att, cer_att, wer_att = self._calc_att_loss(
encoder_out, encoder_out_lens, text, text_lengths
)
# 3. CTC-Att loss definition
if self.ctc_weight == 0.0:
loss = loss_att
elif self.ctc_weight == 1.0:
loss = loss_ctc
else:
loss = self.ctc_weight * loss_ctc + (1 - self.ctc_weight) * loss_att
# Collect Attn branch stats
stats["loss_att"] = loss_att.detach() if loss_att is not None else None
stats["acc"] = acc_att
stats["cer"] = cer_att
stats["wer"] = wer_att
# Collect total loss stats
stats["loss"] = torch.clone(loss.detach())
# force_gatherable: to-device and to-tensor if scalar for DataParallel
if self.length_normalized_loss:
batch_size = int((text_lengths + 1).sum())
loss, stats, weight = force_gatherable((loss, stats, batch_size), loss.device)
return loss, stats, weight
def encode(
self,
speech: torch.Tensor,
speech_lengths: torch.Tensor,
**kwargs,
) -> Tuple[torch.Tensor, torch.Tensor]:
"""Frontend + Encoder. Note that this method is used by asr_inference.py
Args:
speech: (Batch, Length, ...)
speech_lengths: (Batch, )
ind: int
"""
with autocast(False):
# Data augmentation
if self.specaug is not None and self.training:
speech, speech_lengths = self.specaug(speech, speech_lengths)
# Normalization for feature: e.g. Global-CMVN, Utterance-CMVN
if self.normalize is not None:
speech, speech_lengths = self.normalize(speech, speech_lengths)
# Forward encoder
# feats: (Batch, Length, Dim)
# -> encoder_out: (Batch, Length2, Dim2)
if self.encoder.interctc_use_conditioning:
encoder_out, encoder_out_lens, _ = self.encoder(speech, speech_lengths, ctc=self.ctc)
else:
encoder_out, encoder_out_lens, _ = self.encoder(speech, speech_lengths)
intermediate_outs = None
if isinstance(encoder_out, tuple):
intermediate_outs = encoder_out[1]
encoder_out = encoder_out[0]
if intermediate_outs is not None:
return (encoder_out, intermediate_outs), encoder_out_lens
return encoder_out, encoder_out_lens
def _calc_att_loss(
self,
encoder_out: torch.Tensor,
encoder_out_lens: torch.Tensor,
ys_pad: torch.Tensor,
ys_pad_lens: torch.Tensor,
):
"""Internal: calc att loss.
Args:
encoder_out: Encoder output tensor.
encoder_out_lens: Encoder output lengths.
ys_pad: TODO.
ys_pad_lens: Lengths of ys_pad.
"""
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
# 1. Forward decoder
decoder_out, _ = self.decoder(encoder_out, encoder_out_lens, ys_in_pad, ys_in_lens)
# 2. Compute attention loss
loss_att = self.criterion_att(decoder_out, ys_out_pad)
acc_att = th_accuracy(
decoder_out.view(-1, self.vocab_size),
ys_out_pad,
ignore_label=self.ignore_id,
)
# Compute cer/wer using attention-decoder
if self.training or self.error_calculator is None:
cer_att, wer_att = None, None
else:
ys_hat = decoder_out.argmax(dim=-1)
cer_att, wer_att = self.error_calculator(ys_hat.cpu(), ys_pad.cpu())
return loss_att, acc_att, cer_att, wer_att
def _calc_ctc_loss(
self,
encoder_out: torch.Tensor,
encoder_out_lens: torch.Tensor,
ys_pad: torch.Tensor,
ys_pad_lens: torch.Tensor,
):
# Calc CTC loss
"""Internal: calc ctc loss.
Args:
encoder_out: Encoder output tensor.
encoder_out_lens: Encoder output lengths.
ys_pad: TODO.
ys_pad_lens: Lengths of ys_pad.
"""
loss_ctc = self.ctc(encoder_out, encoder_out_lens, ys_pad, ys_pad_lens)
# Calc CER using CTC
cer_ctc = None
if not self.training and self.error_calculator is not None:
ys_hat = self.ctc.argmax(encoder_out).data
cer_ctc = self.error_calculator(ys_hat.cpu(), ys_pad.cpu(), is_ctc=True)
return loss_ctc, cer_ctc
def init_beam_search(
self,
**kwargs,
):
"""Init beam search.
Args:
**kwargs: Additional keyword arguments.
"""
from funasr.models.transformer.search import BeamSearch
from funasr.models.transformer.scorers.ctc import CTCPrefixScorer
from funasr.models.transformer.scorers.length_bonus import LengthBonus
# 1. Build ASR model
scorers = {}
if self.ctc != None:
ctc = CTCPrefixScorer(ctc=self.ctc, eos=self.eos)
scorers.update(ctc=ctc)
token_list = kwargs.get("token_list")
scorers.update(
decoder=self.decoder,
length_bonus=LengthBonus(len(token_list)),
)
# 3. Build ngram model
# ngram is not supported now
ngram = None
scorers["ngram"] = ngram
weights = dict(
decoder=1.0 - kwargs.get("decoding_ctc_weight", 0.3),
ctc=kwargs.get("decoding_ctc_weight", 0.3),
lm=kwargs.get("lm_weight", 0.0),
ngram=kwargs.get("ngram_weight", 0.0),
length_bonus=kwargs.get("penalty", 0.0),
)
beam_search = BeamSearch(
beam_size=kwargs.get("beam_size", 20),
weights=weights,
scorers=scorers,
sos=self.sos,
eos=self.eos,
vocab_size=len(token_list),
token_list=token_list,
pre_beam_score_key=None if self.ctc_weight == 1.0 else "full",
)
self.beam_search = beam_search
def inference(
self,
data_in,
data_lengths=None,
key: list = None,
tokenizer=None,
frontend=None,
**kwargs,
):
"""Run inference on input data.
Args:
data_in: Input data (audio samples, file paths, or text).
data_lengths: Lengths of each input sample in the batch.
key: Sample identifiers.
tokenizer: Tokenizer instance for text encoding/decoding.
frontend: Audio frontend for feature extraction.
**kwargs: Additional keyword arguments.
"""
if kwargs.get("batch_size", 1) > 1:
raise NotImplementedError("batch decoding is not implemented")
# init beamsearch
if self.beam_search is None:
logging.info("enable beam_search")
self.init_beam_search(**kwargs)
self.nbest = kwargs.get("nbest", 1)
meta_data = {}
if (
isinstance(data_in, torch.Tensor) and kwargs.get("data_type", "sound") == "fbank"
): # fbank
speech, speech_lengths = data_in, data_lengths
if len(speech.shape) < 3:
speech = speech[None, :, :]
if speech_lengths is None:
speech_lengths = speech.shape[1]
else:
# extract fbank feats
time1 = time.perf_counter()
sample_list = load_audio_text_image_video(
data_in,
fs=frontend.fs,
audio_fs=kwargs.get("fs", 16000),
data_type=kwargs.get("data_type", "sound"),
tokenizer=tokenizer,
)
time2 = time.perf_counter()
meta_data["load_data"] = f"{time2 - time1:0.3f}"
audio_sample_list = sample_list[0]
if len(sample_list) > 1:
ocr_sample_list = sample_list[1]
else:
ocr_sample_list = [[294, 0]]
speech, speech_lengths = extract_fbank(
audio_sample_list, data_type=kwargs.get("data_type", "sound"), frontend=frontend
)
time3 = time.perf_counter()
meta_data["extract_feat"] = f"{time3 - time2:0.3f}"
frame_shift = 10
meta_data["batch_data_time"] = speech_lengths.sum().item() * frame_shift / 1000
speech = speech.to(device=kwargs["device"])
speech_lengths = speech_lengths.to(device=kwargs["device"])
# Encoder
encoder_out, encoder_out_lens = self.encode(speech, speech_lengths)
if isinstance(encoder_out, tuple):
encoder_out = encoder_out[0]
ocr_list_new = [[x + 1 if x != 0 else x for x in sublist] for sublist in ocr_sample_list]
ocr = torch.tensor(ocr_list_new).to(device=kwargs["device"])
ocr_lengths = ocr.new_full([1], dtype=torch.long, fill_value=ocr.size(1)).to(
device=kwargs["device"]
)
ocr, ocr_lens, _ = self.text_encoder(ocr, ocr_lengths)
fusion_out, _, _, _ = self.fusion_encoder(encoder_out, None, ocr, None)
encoder_out = encoder_out + fusion_out
# c. Passed the encoder result and the beam search
nbest_hyps = self.beam_search(
x=encoder_out[0],
maxlenratio=kwargs.get("maxlenratio", 0.0),
minlenratio=kwargs.get("minlenratio", 0.0),
)
nbest_hyps = nbest_hyps[: self.nbest]
results = []
b, n, d = encoder_out.size()
for i in range(b):
for nbest_idx, hyp in enumerate(nbest_hyps):
ibest_writer = None
if kwargs.get("output_dir") is not None:
if not hasattr(self, "writer"):
self.writer = DatadirWriter(kwargs.get("output_dir"))
ibest_writer = self.writer[f"{nbest_idx + 1}best_recog"]
# remove sos/eos and get results
last_pos = -1
if isinstance(hyp.yseq, list):
token_int = hyp.yseq[1:last_pos]
else:
token_int = hyp.yseq[1:last_pos].tolist()
# remove blank symbol id, which is assumed to be 0
token_int = list(
filter(
lambda x: x != self.eos and x != self.sos and x != self.blank_id, token_int
)
)
# Change integer-ids to tokens
token = tokenizer.ids2tokens(token_int)
text = tokenizer.tokens2text(token)
text_postprocessed, _ = postprocess_utils.sentence_postprocess(token)
result_i = {"key": key[i], "token": token, "text": text_postprocessed}
results.append(result_i)
if ibest_writer is not None:
ibest_writer["token"][key[i]] = " ".join(token)
ibest_writer["text"][key[i]] = text_postprocessed
return results, meta_data