#!/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 os import re import time import torch import codecs import logging import tempfile import requests import numpy as np from typing import Dict, Tuple from contextlib import contextmanager from distutils.version import LooseVersion from funasr.register import tables from funasr.utils import postprocess_utils from funasr.metrics.compute_acc import th_accuracy from funasr.models.paraformer.model import Paraformer from funasr.utils.datadir_writer import DatadirWriter from funasr.models.paraformer.search import Hypothesis from funasr.train_utils.device_funcs import force_gatherable from funasr.models.transformer.utils.add_sos_eos import add_sos_eos from funasr.models.transformer.utils.nets_utils import make_pad_mask, pad_list from funasr.utils.load_utils import load_audio_text_image_video, extract_fbank if LooseVersion(torch.__version__) >= LooseVersion("1.6.0"): from torch.cuda.amp import autocast else: # Nothing to do if torch<1.6.0 @contextmanager def autocast(enabled=True): yield @tables.register("model_classes", "ContextualParaformer") class ContextualParaformer(Paraformer): """ Author: Speech Lab of DAMO Academy, Alibaba Group FunASR: A Fundamental End-to-End Speech Recognition Toolkit https://arxiv.org/abs/2305.11013 """ def __init__( self, *args, **kwargs, ): super().__init__(*args, **kwargs) self.target_buffer_length = kwargs.get("target_buffer_length", -1) inner_dim = kwargs.get("inner_dim", 256) bias_encoder_type = kwargs.get("bias_encoder_type", "lstm") use_decoder_embedding = kwargs.get("use_decoder_embedding", False) crit_attn_weight = kwargs.get("crit_attn_weight", 0.0) crit_attn_smooth = kwargs.get("crit_attn_smooth", 0.0) bias_encoder_dropout_rate = kwargs.get("bias_encoder_dropout_rate", 0.0) if bias_encoder_type == "lstm": self.bias_encoder = torch.nn.LSTM( inner_dim, inner_dim, 1, batch_first=True, dropout=bias_encoder_dropout_rate ) self.bias_embed = torch.nn.Embedding(self.vocab_size, inner_dim) elif bias_encoder_type == "mean": self.bias_embed = torch.nn.Embedding(self.vocab_size, inner_dim) else: logging.error("Unsupport bias encoder type: {}".format(bias_encoder_type)) if self.target_buffer_length > 0: self.hotword_buffer = None self.length_record = [] self.current_buffer_length = 0 self.use_decoder_embedding = use_decoder_embedding self.crit_attn_weight = crit_attn_weight if self.crit_attn_weight > 0: self.attn_loss = torch.nn.L1Loss() self.crit_attn_smooth = crit_attn_smooth 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]: """Frontend + Encoder + Decoder + Calc loss Args: speech: (Batch, Length, ...) speech_lengths: (Batch, ) text: (Batch, Length) text_lengths: (Batch,) """ text_lengths = text_lengths.squeeze() speech_lengths = speech_lengths.squeeze() batch_size = speech.shape[0] hotword_pad = kwargs.get("hotword_pad") hotword_lengths = kwargs.get("hotword_lengths") # dha_pad = kwargs.get("dha_pad") # 1. Encoder encoder_out, encoder_out_lens = self.encode(speech, speech_lengths) loss_ctc, cer_ctc = None, None stats = dict() # 1. 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 # 2b. Attention decoder branch loss_att, acc_att, cer_att, wer_att, loss_pre, loss_ideal = self._calc_att_clas_loss( encoder_out, encoder_out_lens, text, text_lengths, hotword_pad, hotword_lengths ) # 3. CTC-Att loss definition if self.ctc_weight == 0.0: loss = loss_att + loss_pre * self.predictor_weight else: loss = ( self.ctc_weight * loss_ctc + (1 - self.ctc_weight) * loss_att + loss_pre * self.predictor_weight ) if loss_ideal is not None: loss = loss + loss_ideal * self.crit_attn_weight stats["loss_ideal"] = loss_ideal.detach().cpu() # 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 stats["loss_pre"] = loss_pre.detach().cpu() if loss_pre is not None else None 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 + self.predictor_bias).sum()) loss, stats, weight = force_gatherable((loss, stats, batch_size), loss.device) return loss, stats, weight def _calc_att_clas_loss( self, encoder_out: torch.Tensor, encoder_out_lens: torch.Tensor, ys_pad: torch.Tensor, ys_pad_lens: torch.Tensor, hotword_pad: torch.Tensor, hotword_lengths: torch.Tensor, ): encoder_out_mask = ( ~make_pad_mask(encoder_out_lens, maxlen=encoder_out.size(1))[:, None, :] ).to(encoder_out.device) if self.predictor_bias == 1: _, ys_pad = add_sos_eos(ys_pad, self.sos, self.eos, self.ignore_id) ys_pad_lens = ys_pad_lens + self.predictor_bias pre_acoustic_embeds, pre_token_length, _, _ = self.predictor( encoder_out, ys_pad, encoder_out_mask, ignore_id=self.ignore_id ) # -1. bias encoder if self.use_decoder_embedding: hw_embed = self.decoder.embed(hotword_pad) else: hw_embed = self.bias_embed(hotword_pad) hw_embed, (_, _) = self.bias_encoder(hw_embed) _ind = np.arange(0, hotword_pad.shape[0]).tolist() selected = hw_embed[_ind, [i - 1 for i in hotword_lengths.detach().cpu().tolist()]] contextual_info = selected.squeeze(0).repeat(ys_pad.shape[0], 1, 1).to(ys_pad.device) # 0. sampler decoder_out_1st = None if self.sampling_ratio > 0.0: sematic_embeds, decoder_out_1st = self.sampler( encoder_out, encoder_out_lens, ys_pad, ys_pad_lens, pre_acoustic_embeds, contextual_info, ) else: sematic_embeds = pre_acoustic_embeds # 1. Forward decoder decoder_outs = self.decoder( encoder_out, encoder_out_lens, sematic_embeds, ys_pad_lens, contextual_info=contextual_info, ) decoder_out, _ = decoder_outs[0], decoder_outs[1] """ if self.crit_attn_weight > 0 and attn.shape[-1] > 1: ideal_attn = ideal_attn + self.crit_attn_smooth / (self.crit_attn_smooth + 1.0) attn_non_blank = attn[:,:,:,:-1] ideal_attn_non_blank = ideal_attn[:,:,:-1] loss_ideal = self.attn_loss(attn_non_blank.max(1)[0], ideal_attn_non_blank.to(attn.device)) else: loss_ideal = None """ loss_ideal = None if decoder_out_1st is None: decoder_out_1st = decoder_out # 2. Compute attention loss loss_att = self.criterion_att(decoder_out, ys_pad) acc_att = th_accuracy( decoder_out_1st.view(-1, self.vocab_size), ys_pad, ignore_label=self.ignore_id, ) loss_pre = self.criterion_pre(ys_pad_lens.type_as(pre_token_length), pre_token_length) # 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_1st.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, loss_pre, loss_ideal def sampler( self, encoder_out, encoder_out_lens, ys_pad, ys_pad_lens, pre_acoustic_embeds, contextual_info, ): tgt_mask = (~make_pad_mask(ys_pad_lens, maxlen=ys_pad_lens.max())[:, :, None]).to( ys_pad.device ) ys_pad = ys_pad * tgt_mask[:, :, 0] if self.share_embedding: ys_pad_embed = self.decoder.output_layer.weight[ys_pad] else: ys_pad_embed = self.decoder.embed(ys_pad) with torch.no_grad(): decoder_outs = self.decoder( encoder_out, encoder_out_lens, pre_acoustic_embeds, ys_pad_lens, contextual_info=contextual_info, ) decoder_out, _ = decoder_outs[0], decoder_outs[1] pred_tokens = decoder_out.argmax(-1) nonpad_positions = ys_pad.ne(self.ignore_id) seq_lens = (nonpad_positions).sum(1) same_num = ((pred_tokens == ys_pad) & nonpad_positions).sum(1) input_mask = torch.ones_like(nonpad_positions) bsz, seq_len = ys_pad.size() for li in range(bsz): target_num = ( ((seq_lens[li] - same_num[li].sum()).float()) * self.sampling_ratio ).long() if target_num > 0: input_mask[li].scatter_( dim=0, index=torch.randperm(seq_lens[li])[:target_num].to( pre_acoustic_embeds.device ), value=0, ) input_mask = input_mask.eq(1) input_mask = input_mask.masked_fill(~nonpad_positions, False) input_mask_expand_dim = input_mask.unsqueeze(2).to(pre_acoustic_embeds.device) sematic_embeds = pre_acoustic_embeds.masked_fill( ~input_mask_expand_dim, 0 ) + ys_pad_embed.masked_fill(input_mask_expand_dim, 0) return sematic_embeds * tgt_mask, decoder_out * tgt_mask def cal_decoder_with_predictor( self, encoder_out, encoder_out_lens, sematic_embeds, ys_pad_lens, hw_list=None, clas_scale=1.0, ): if hw_list is None: hw_list = [torch.Tensor([1]).long().to(encoder_out.device)] # empty hotword list hw_list_pad = pad_list(hw_list, 0) if self.use_decoder_embedding: hw_embed = self.decoder.embed(hw_list_pad) else: hw_embed = self.bias_embed(hw_list_pad) hw_embed, (h_n, _) = self.bias_encoder(hw_embed) hw_embed = h_n.repeat(encoder_out.shape[0], 1, 1) else: hw_lengths = [len(i) for i in hw_list] hw_list_pad = pad_list([torch.Tensor(i).long() for i in hw_list], 0).to( encoder_out.device ) if self.use_decoder_embedding: hw_embed = self.decoder.embed(hw_list_pad) else: hw_embed = self.bias_embed(hw_list_pad) hw_embed = torch.nn.utils.rnn.pack_padded_sequence( hw_embed, hw_lengths, batch_first=True, enforce_sorted=False ) _, (h_n, _) = self.bias_encoder(hw_embed) hw_embed = h_n.repeat(encoder_out.shape[0], 1, 1) decoder_outs = self.decoder( encoder_out, encoder_out_lens, sematic_embeds, ys_pad_lens, contextual_info=hw_embed, clas_scale=clas_scale, ) decoder_out = decoder_outs[0] decoder_out = torch.log_softmax(decoder_out, dim=-1) return decoder_out, ys_pad_lens def inference( self, data_in, data_lengths=None, key: list = None, tokenizer=None, frontend=None, **kwargs, ): # init beamsearch is_use_ctc = kwargs.get("decoding_ctc_weight", 0.0) > 0.00001 and self.ctc != None is_use_lm = ( kwargs.get("lm_weight", 0.0) > 0.00001 and kwargs.get("lm_file", None) is not None ) if self.beam_search is None and (is_use_lm or is_use_ctc): logging.info("enable beam_search") self.init_beam_search(**kwargs) self.nbest = kwargs.get("nbest", 1) meta_data = {} # extract fbank feats time1 = time.perf_counter() audio_sample_list = load_audio_text_image_video( data_in, fs=frontend.fs, audio_fs=kwargs.get("fs", 16000) ) time2 = time.perf_counter() meta_data["load_data"] = f"{time2 - time1:0.3f}" 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}" meta_data["batch_data_time"] = ( speech_lengths.sum().item() * frontend.frame_shift * frontend.lfr_n / 1000 ) speech = speech.to(device=kwargs["device"]) speech_lengths = speech_lengths.to(device=kwargs["device"]) # hotword self.hotword_list = self.generate_hotwords_list( kwargs.get("hotword", None), tokenizer=tokenizer, frontend=frontend ) # Encoder encoder_out, encoder_out_lens = self.encode(speech, speech_lengths) if isinstance(encoder_out, tuple): encoder_out = encoder_out[0] # predictor predictor_outs = self.calc_predictor(encoder_out, encoder_out_lens) pre_acoustic_embeds, pre_token_length, alphas, pre_peak_index = ( predictor_outs[0], predictor_outs[1], predictor_outs[2], predictor_outs[3], ) pre_token_length = pre_token_length.round().long() if torch.max(pre_token_length) < 1: return [] decoder_outs = self.cal_decoder_with_predictor( encoder_out, encoder_out_lens, pre_acoustic_embeds, pre_token_length, hw_list=self.hotword_list, clas_scale=kwargs.get("clas_scale", 1.0), ) decoder_out, ys_pad_lens = decoder_outs[0], decoder_outs[1] results = [] b, n, d = decoder_out.size() for i in range(b): x = encoder_out[i, : encoder_out_lens[i], :] am_scores = decoder_out[i, : pre_token_length[i], :] if self.beam_search is not None: nbest_hyps = self.beam_search( x=x, am_scores=am_scores, maxlenratio=kwargs.get("maxlenratio", 0.0), minlenratio=kwargs.get("minlenratio", 0.0), ) nbest_hyps = nbest_hyps[: self.nbest] else: yseq = am_scores.argmax(dim=-1) score = am_scores.max(dim=-1)[0] score = torch.sum(score, dim=-1) # pad with mask tokens to ensure compatibility with sos/eos tokens yseq = torch.tensor([self.sos] + yseq.tolist() + [self.eos], device=yseq.device) nbest_hyps = [Hypothesis(yseq=yseq, score=score)] 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 ) ) if tokenizer is not None: # 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], "text": text_postprocessed} if ibest_writer is not None: ibest_writer["token"][key[i]] = " ".join(token) ibest_writer["text"][key[i]] = text ibest_writer["text_postprocessed"][key[i]] = text_postprocessed else: result_i = {"key": key[i], "token_int": token_int} results.append(result_i) return results, meta_data def generate_hotwords_list(self, hotword_list_or_file, tokenizer=None, frontend=None): def load_seg_dict(seg_dict_file): seg_dict = {} assert isinstance(seg_dict_file, str) with open(seg_dict_file, "r", encoding="utf8") as f: lines = f.readlines() for line in lines: s = line.strip().split() key = s[0] value = s[1:] seg_dict[key] = " ".join(value) return seg_dict def seg_tokenize(txt, seg_dict): pattern = re.compile(r"^[\u4E00-\u9FA50-9]+$") out_txt = "" for word in txt: word = word.lower() if word in seg_dict: out_txt += seg_dict[word] + " " else: if pattern.match(word): for char in word: if char in seg_dict: out_txt += seg_dict[char] + " " else: out_txt += "" + " " else: out_txt += "" + " " return out_txt.strip().split() seg_dict = None if frontend.cmvn_file is not None: model_dir = os.path.dirname(frontend.cmvn_file) seg_dict_file = os.path.join(model_dir, "seg_dict") if os.path.exists(seg_dict_file): seg_dict = load_seg_dict(seg_dict_file) else: seg_dict = None # for None if hotword_list_or_file is None: hotword_list = None # for local txt inputs elif os.path.exists(hotword_list_or_file) and hotword_list_or_file.endswith(".txt"): logging.info("Attempting to parse hotwords from local txt...") hotword_list = [] hotword_str_list = [] with codecs.open(hotword_list_or_file, "r") as fin: for line in fin.readlines(): hw = line.strip() hw_list = hw.split() if seg_dict is not None: hw_list = seg_tokenize(hw_list, seg_dict) hotword_str_list.append(hw) hotword_list.append(tokenizer.tokens2ids(hw_list)) hotword_list.append([self.sos]) hotword_str_list.append("") logging.info( "Initialized hotword list from file: {}, hotword list: {}.".format( hotword_list_or_file, hotword_str_list ) ) # for url, download and generate txt elif hotword_list_or_file.startswith("http"): logging.info("Attempting to parse hotwords from url...") work_dir = tempfile.TemporaryDirectory().name if not os.path.exists(work_dir): os.makedirs(work_dir) text_file_path = os.path.join(work_dir, os.path.basename(hotword_list_or_file)) local_file = requests.get(hotword_list_or_file) open(text_file_path, "wb").write(local_file.content) hotword_list_or_file = text_file_path hotword_list = [] hotword_str_list = [] with codecs.open(hotword_list_or_file, "r") as fin: for line in fin.readlines(): hw = line.strip() hw_list = hw.split() if seg_dict is not None: hw_list = seg_tokenize(hw_list, seg_dict) hotword_str_list.append(hw) hotword_list.append(tokenizer.tokens2ids(hw_list)) hotword_list.append([self.sos]) hotword_str_list.append("") logging.info( "Initialized hotword list from file: {}, hotword list: {}.".format( hotword_list_or_file, hotword_str_list ) ) # for text str input elif not hotword_list_or_file.endswith(".txt"): logging.info("Attempting to parse hotwords as str...") hotword_list = [] hotword_str_list = [] for hw in hotword_list_or_file.strip().split(): hotword_str_list.append(hw) hw_list = hw.strip().split() if seg_dict is not None: hw_list = seg_tokenize(hw_list, seg_dict) hotword_list.append(tokenizer.tokens2ids(hw_list)) hotword_list.append([self.sos]) hotword_str_list.append("") logging.info("Hotword list: {}.".format(hotword_str_list)) else: hotword_list = None return hotword_list def export( self, **kwargs, ): if "max_seq_len" not in kwargs: kwargs["max_seq_len"] = 512 from .export_meta import export_rebuild_model models = export_rebuild_model(model=self, **kwargs) return models