#!/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 copy import torch import numpy as np import torch.nn.functional as F from contextlib import contextmanager from distutils.version import LooseVersion from typing import Any, List, Tuple, Optional from funasr.register import tables from funasr.train_utils.device_funcs import to_device from funasr.train_utils.device_funcs import force_gatherable from funasr.utils.load_utils import load_audio_text_image_video from funasr.models.transformer.utils.nets_utils import make_pad_mask from funasr.models.ct_transformer.utils import split_to_mini_sentence, split_words try: import jieba except: pass 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", "CTTransformer") class CTTransformer(torch.nn.Module): """ Author: Speech Lab of DAMO Academy, Alibaba Group CT-Transformer: Controllable time-delay transformer for real-time punctuation prediction and disfluency detection https://arxiv.org/pdf/2003.01309.pdf """ def __init__( self, encoder: str = None, encoder_conf: dict = None, vocab_size: int = -1, punc_list: list = None, punc_weight: list = None, embed_unit: int = 128, att_unit: int = 256, dropout_rate: float = 0.5, ignore_id: int = -1, sos: int = 1, eos: int = 2, sentence_end_id: int = 3, **kwargs, ): super().__init__() punc_size = len(punc_list) if punc_weight is None: punc_weight = [1] * punc_size self.embed = torch.nn.Embedding(vocab_size, embed_unit) encoder_class = tables.encoder_classes.get(encoder) encoder = encoder_class(**encoder_conf) self.decoder = torch.nn.Linear(att_unit, punc_size) self.encoder = encoder self.punc_list = punc_list self.punc_weight = punc_weight self.ignore_id = ignore_id self.sos = sos self.eos = eos self.sentence_end_id = sentence_end_id self.jieba_usr_dict = None if kwargs.get("jieba_usr_dict", None) is not None: jieba.load_userdict(kwargs["jieba_usr_dict"]) self.jieba_usr_dict = jieba def punc_forward(self, text: torch.Tensor, text_lengths: torch.Tensor, **kwargs): """Compute loss value from buffer sequences. Args: input (torch.Tensor): Input ids. (batch, len) hidden (torch.Tensor): Target ids. (batch, len) """ x = self.embed(text) # mask = self._target_mask(input) h, _, _ = self.encoder(x, text_lengths) y = self.decoder(h) return y, None def with_vad(self): return False def score(self, y: torch.Tensor, state: Any, x: torch.Tensor) -> Tuple[torch.Tensor, Any]: """Score new token. Args: y (torch.Tensor): 1D torch.int64 prefix tokens. state: Scorer state for prefix tokens x (torch.Tensor): encoder feature that generates ys. Returns: tuple[torch.Tensor, Any]: Tuple of torch.float32 scores for next token (vocab_size) and next state for ys """ y = y.unsqueeze(0) h, _, cache = self.encoder.forward_one_step( self.embed(y), self._target_mask(y), cache=state ) h = self.decoder(h[:, -1]) logp = h.log_softmax(dim=-1).squeeze(0) return logp, cache def batch_score( self, ys: torch.Tensor, states: List[Any], xs: torch.Tensor ) -> Tuple[torch.Tensor, List[Any]]: """Score new token batch. Args: ys (torch.Tensor): torch.int64 prefix tokens (n_batch, ylen). states (List[Any]): Scorer states for prefix tokens. xs (torch.Tensor): The encoder feature that generates ys (n_batch, xlen, n_feat). Returns: tuple[torch.Tensor, List[Any]]: Tuple of batchfied scores for next token with shape of `(n_batch, vocab_size)` and next state list for ys. """ # merge states n_batch = len(ys) n_layers = len(self.encoder.encoders) if states[0] is None: batch_state = None else: # transpose state of [batch, layer] into [layer, batch] batch_state = [ torch.stack([states[b][i] for b in range(n_batch)]) for i in range(n_layers) ] # batch decoding h, _, states = self.encoder.forward_one_step( self.embed(ys), self._target_mask(ys), cache=batch_state ) h = self.decoder(h[:, -1]) logp = h.log_softmax(dim=-1) # transpose state of [layer, batch] into [batch, layer] state_list = [[states[i][b] for i in range(n_layers)] for b in range(n_batch)] return logp, state_list def nll( self, text: torch.Tensor, punc: torch.Tensor, text_lengths: torch.Tensor, punc_lengths: torch.Tensor, max_length: Optional[int] = None, vad_indexes: Optional[torch.Tensor] = None, vad_indexes_lengths: Optional[torch.Tensor] = None, ) -> Tuple[torch.Tensor, torch.Tensor]: """Compute negative log likelihood(nll) Normally, this function is called in batchify_nll. Args: text: (Batch, Length) punc: (Batch, Length) text_lengths: (Batch,) max_lengths: int """ batch_size = text.size(0) # For data parallel if max_length is None: text = text[:, : text_lengths.max()] punc = punc[:, : text_lengths.max()] else: text = text[:, :max_length] punc = punc[:, :max_length] if self.with_vad(): # Should be VadRealtimeTransformer assert vad_indexes is not None y, _ = self.punc_forward(text, text_lengths, vad_indexes) else: # Should be TargetDelayTransformer, y, _ = self.punc_forward(text, text_lengths) # Calc negative log likelihood # nll: (BxL,) if self.training == False: _, indices = y.view(-1, y.shape[-1]).topk(1, dim=1) from sklearn.metrics import f1_score f1_score = f1_score( punc.view(-1).detach().cpu().numpy(), indices.squeeze(-1).detach().cpu().numpy(), average="micro", ) nll = torch.Tensor([f1_score]).repeat(text_lengths.sum()) return nll, text_lengths else: self.punc_weight = self.punc_weight.to(punc.device) nll = F.cross_entropy( y.view(-1, y.shape[-1]), punc.view(-1), self.punc_weight, reduction="none", ignore_index=self.ignore_id, ) # nll: (BxL,) -> (BxL,) if max_length is None: nll.masked_fill_(make_pad_mask(text_lengths).to(nll.device).view(-1), 0.0) else: nll.masked_fill_( make_pad_mask(text_lengths, maxlen=max_length + 1).to(nll.device).view(-1), 0.0, ) # nll: (BxL,) -> (B, L) nll = nll.view(batch_size, -1) return nll, text_lengths def forward( self, text: torch.Tensor, punc: torch.Tensor, text_lengths: torch.Tensor, punc_lengths: torch.Tensor, vad_indexes: Optional[torch.Tensor] = None, vad_indexes_lengths: Optional[torch.Tensor] = None, ): nll, y_lengths = self.nll(text, punc, text_lengths, punc_lengths, vad_indexes=vad_indexes) ntokens = y_lengths.sum() loss = nll.sum() / ntokens stats = dict(loss=loss.detach()) # force_gatherable: to-device and to-tensor if scalar for DataParallel loss, stats, weight = force_gatherable((loss, stats, ntokens), loss.device) return loss, stats, weight def inference( self, data_in, data_lengths=None, key: list = None, tokenizer=None, frontend=None, **kwargs, ): assert len(data_in) == 1 text = load_audio_text_image_video(data_in, data_type=kwargs.get("kwargs", "text"))[0] vad_indexes = kwargs.get("vad_indexes", None) # text = data_in[0] # text_lengths = data_lengths[0] if data_lengths is not None else None split_size = kwargs.get("split_size", 20) tokens = split_words(text, jieba_usr_dict=self.jieba_usr_dict) tokens_int = tokenizer.encode(tokens) mini_sentences = split_to_mini_sentence(tokens, split_size) mini_sentences_id = split_to_mini_sentence(tokens_int, split_size) assert len(mini_sentences) == len(mini_sentences_id) cache_sent = [] cache_sent_id = torch.from_numpy(np.array([], dtype="int32")) new_mini_sentence = "" new_mini_sentence_punc = [] cache_pop_trigger_limit = 200 results = [] meta_data = {} punc_array = None for mini_sentence_i in range(len(mini_sentences)): mini_sentence = mini_sentences[mini_sentence_i] mini_sentence_id = mini_sentences_id[mini_sentence_i] mini_sentence = cache_sent + mini_sentence mini_sentence_id = np.concatenate((cache_sent_id, mini_sentence_id), axis=0) data = { "text": torch.unsqueeze(torch.from_numpy(mini_sentence_id), 0), "text_lengths": torch.from_numpy(np.array([len(mini_sentence_id)], dtype="int32")), } data = to_device(data, kwargs["device"]) # y, _ = self.wrapped_model(**data) y, _ = self.punc_forward(**data) _, indices = y.view(-1, y.shape[-1]).topk(1, dim=1) punctuations = torch.squeeze(indices, dim=1) assert punctuations.size()[0] == len(mini_sentence) # Search for the last Period/QuestionMark as cache if mini_sentence_i < len(mini_sentences) - 1: sentenceEnd = -1 last_comma_index = -1 for i in range(len(punctuations) - 2, 1, -1): if ( self.punc_list[punctuations[i]] == "。" or self.punc_list[punctuations[i]] == "?" ): sentenceEnd = i break if last_comma_index < 0 and self.punc_list[punctuations[i]] == ",": last_comma_index = i if ( sentenceEnd < 0 and len(mini_sentence) > cache_pop_trigger_limit and last_comma_index >= 0 ): # The sentence it too long, cut off at a comma. sentenceEnd = last_comma_index punctuations[sentenceEnd] = self.sentence_end_id cache_sent = mini_sentence[sentenceEnd + 1 :] cache_sent_id = mini_sentence_id[sentenceEnd + 1 :] mini_sentence = mini_sentence[0 : sentenceEnd + 1] punctuations = punctuations[0 : sentenceEnd + 1] # if len(punctuations) == 0: # continue punctuations_np = punctuations.cpu().numpy() new_mini_sentence_punc += [int(x) for x in punctuations_np] words_with_punc = [] for i in range(len(mini_sentence)): if ( i == 0 or self.punc_list[punctuations[i - 1]] == "。" or self.punc_list[punctuations[i - 1]] == "?" ) and len(mini_sentence[i][0].encode()) == 1: mini_sentence[i] = mini_sentence[i].capitalize() if i == 0: if len(mini_sentence[i][0].encode()) == 1: mini_sentence[i] = " " + mini_sentence[i] if i > 0: if ( len(mini_sentence[i][0].encode()) == 1 and len(mini_sentence[i - 1][0].encode()) == 1 ): mini_sentence[i] = " " + mini_sentence[i] words_with_punc.append(mini_sentence[i]) if self.punc_list[punctuations[i]] != "_": punc_res = self.punc_list[punctuations[i]] if len(mini_sentence[i][0].encode()) == 1: if punc_res == ",": punc_res = "," elif punc_res == "。": punc_res = "." elif punc_res == "?": punc_res = "?" words_with_punc.append(punc_res) new_mini_sentence += "".join(words_with_punc) # Add Period for the end of the sentence new_mini_sentence_out = new_mini_sentence new_mini_sentence_punc_out = new_mini_sentence_punc if mini_sentence_i == len(mini_sentences) - 1: if new_mini_sentence[-1] == "," or new_mini_sentence[-1] == "、": new_mini_sentence_out = new_mini_sentence[:-1] + "。" new_mini_sentence_punc_out = new_mini_sentence_punc[:-1] + [ self.sentence_end_id ] elif new_mini_sentence[-1] == ",": new_mini_sentence_out = new_mini_sentence[:-1] + "." new_mini_sentence_punc_out = new_mini_sentence_punc[:-1] + [ self.sentence_end_id ] elif ( new_mini_sentence[-1] != "。" and new_mini_sentence[-1] != "?" and len(new_mini_sentence[-1].encode()) != 1 ): new_mini_sentence_out = new_mini_sentence + "。" new_mini_sentence_punc_out = new_mini_sentence_punc[:-1] + [ self.sentence_end_id ] if len(punctuations): punctuations[-1] = 2 elif ( new_mini_sentence[-1] != "." and new_mini_sentence[-1] != "?" and len(new_mini_sentence[-1].encode()) == 1 ): new_mini_sentence_out = new_mini_sentence + "." new_mini_sentence_punc_out = new_mini_sentence_punc[:-1] + [ self.sentence_end_id ] if len(punctuations): punctuations[-1] = 2 # keep a punctuations array for punc segment if punc_array is None: punc_array = punctuations else: punc_array = torch.cat([punc_array, punctuations], dim=0) # post processing when using word level punc model if self.jieba_usr_dict is not None: punc_array = punc_array.reshape(-1) len_tokens = len(tokens) new_punc_array = copy.copy(punc_array).tolist() # for i, (token, punc_id) in enumerate(zip(tokens[::-1], punc_array.tolist()[::-1])): for i, token in enumerate(tokens[::-1]): if "\u0e00" <= token[0] <= "\u9fa5": # ignore en words if len(token) > 1: num_append = len(token) - 1 ind_append = len_tokens - i - 1 for _ in range(num_append): new_punc_array.insert(ind_append, 1) punc_array = torch.tensor(new_punc_array) result_i = {"key": key[0], "text": new_mini_sentence_out, "punc_array": punc_array} results.append(result_i) return results, meta_data def export(self, **kwargs): from .export_meta import export_rebuild_model models = export_rebuild_model(model=self, **kwargs) return models