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import torch |
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import torch.nn as nn |
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import torch |
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from torch.autograd import Variable |
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import copy |
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class Seq2Seq(nn.Module): |
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""" |
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Build Seqence-to-Sequence. |
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Parameters: |
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* `encoder`- encoder of seq2seq model. e.g. roberta |
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* `decoder`- decoder of seq2seq model. e.g. transformer |
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* `config`- configuration of encoder model. |
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* `beam_size`- beam size for beam search. |
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* `max_length`- max length of target for beam search. |
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* `sos_id`- start of symbol ids in target for beam search. |
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* `eos_id`- end of symbol ids in target for beam search. |
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""" |
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def __init__(self, encoder,decoder,config,beam_size=None,max_length=None,sos_id=None,eos_id=None): |
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super(Seq2Seq, self).__init__() |
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self.encoder = encoder |
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self.decoder=decoder |
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self.config=config |
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self.register_buffer("bias", torch.tril(torch.ones(2048, 2048))) |
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self.dense = nn.Linear(config.hidden_size, config.hidden_size) |
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self.lm_head = nn.Linear(config.hidden_size, config.vocab_size, bias=False) |
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self.lsm = nn.LogSoftmax(dim=-1) |
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self.tie_weights() |
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self.beam_size=beam_size |
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self.max_length=max_length |
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self.sos_id=sos_id |
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self.eos_id=eos_id |
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def _tie_or_clone_weights(self, first_module, second_module): |
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""" Tie or clone module weights depending of weither we are using TorchScript or not |
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""" |
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if self.config.torchscript: |
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first_module.weight = nn.Parameter(second_module.weight.clone()) |
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else: |
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first_module.weight = second_module.weight |
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def tie_weights(self): |
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""" Make sure we are sharing the input and output embeddings. |
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Export to TorchScript can't handle parameter sharing so we are cloning them instead. |
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""" |
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self._tie_or_clone_weights(self.lm_head, |
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self.encoder.embeddings.word_embeddings) |
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def forward(self, source_ids=None,source_mask=None,target_ids=None,target_mask=None,args=None, return_vec=None): |
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outputs = self.encoder(source_ids, attention_mask=source_mask) |
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if return_vec: |
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return outputs.pooler_output |
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encoder_output = outputs[0].permute([1,0,2]).contiguous() |
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if target_ids is not None: |
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attn_mask=-1e4 *(1-self.bias[:target_ids.shape[1],:target_ids.shape[1]]) |
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tgt_embeddings = self.encoder.embeddings(target_ids).permute([1,0,2]).contiguous() |
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out = self.decoder(tgt_embeddings,encoder_output,tgt_mask=attn_mask,memory_key_padding_mask=(1-source_mask).bool()) |
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hidden_states = torch.tanh(self.dense(out)).permute([1,0,2]).contiguous() |
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lm_logits = self.lm_head(hidden_states) |
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active_loss = target_mask[..., 1:].ne(0).view(-1) == 1 |
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shift_logits = lm_logits[..., :-1, :].contiguous() |
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shift_labels = target_ids[..., 1:].contiguous() |
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loss_fct = nn.CrossEntropyLoss(ignore_index=-1) |
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loss = loss_fct(shift_logits.view(-1, shift_logits.size(-1))[active_loss], |
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shift_labels.view(-1)[active_loss]) |
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outputs = loss,loss*active_loss.sum(),active_loss.sum() |
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return outputs |
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else: |
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preds=[] |
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zero=torch.cuda.LongTensor(1).fill_(0) |
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for i in range(source_ids.shape[0]): |
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context=encoder_output[:,i:i+1] |
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context_mask=source_mask[i:i+1,:] |
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beam = Beam(self.beam_size,self.sos_id,self.eos_id) |
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input_ids=beam.getCurrentState() |
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context=context.repeat(1, self.beam_size,1) |
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context_mask=context_mask.repeat(self.beam_size,1) |
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for _ in range(self.max_length): |
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if beam.done(): |
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break |
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attn_mask=-1e4 *(1-self.bias[:input_ids.shape[1],:input_ids.shape[1]]) |
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tgt_embeddings = self.encoder.embeddings(input_ids).permute([1,0,2]).contiguous() |
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out = self.decoder(tgt_embeddings,context,tgt_mask=attn_mask,memory_key_padding_mask=(1-context_mask).bool()) |
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out = torch.tanh(self.dense(out)) |
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hidden_states=out.permute([1,0,2]).contiguous()[:,-1,:] |
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out = self.lsm(self.lm_head(hidden_states)).data |
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beam.advance(out) |
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input_ids.data.copy_(input_ids.data.index_select(0, beam.getCurrentOrigin())) |
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input_ids=torch.cat((input_ids,beam.getCurrentState()),-1) |
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hyp= beam.getHyp(beam.getFinal()) |
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pred=beam.buildTargetTokens(hyp)[:self.beam_size] |
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pred=[torch.cat([x.view(-1) for x in p]+[zero]*(self.max_length-len(p))).view(1,-1) for p in pred] |
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preds.append(torch.cat(pred,0).unsqueeze(0)) |
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preds=torch.cat(preds,0) |
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return preds |
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class Beam(object): |
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def __init__(self, size,sos,eos): |
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self.size = size |
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self.tt = torch.cuda |
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self.scores = self.tt.FloatTensor(size).zero_() |
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self.prevKs = [] |
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self.nextYs = [self.tt.LongTensor(size) |
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.fill_(0)] |
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self.nextYs[0][0] = sos |
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self._eos = eos |
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self.eosTop = False |
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self.finished = [] |
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def getCurrentState(self): |
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"Get the outputs for the current timestep." |
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batch = self.tt.LongTensor(self.nextYs[-1]).view(-1, 1) |
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return batch |
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def getCurrentOrigin(self): |
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"Get the backpointers for the current timestep." |
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return self.prevKs[-1] |
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def advance(self, wordLk): |
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""" |
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Given prob over words for every last beam `wordLk` and attention |
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`attnOut`: Compute and update the beam search. |
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Parameters: |
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* `wordLk`- probs of advancing from the last step (K x words) |
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* `attnOut`- attention at the last step |
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Returns: True if beam search is complete. |
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""" |
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numWords = wordLk.size(1) |
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if len(self.prevKs) > 0: |
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beamLk = wordLk + self.scores.unsqueeze(1).expand_as(wordLk) |
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for i in range(self.nextYs[-1].size(0)): |
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if self.nextYs[-1][i] == self._eos: |
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beamLk[i] = -1e20 |
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else: |
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beamLk = wordLk[0] |
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flatBeamLk = beamLk.view(-1) |
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bestScores, bestScoresId = flatBeamLk.topk(self.size, 0, True, True) |
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self.scores = bestScores |
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prevK = bestScoresId // numWords |
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self.prevKs.append(prevK) |
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self.nextYs.append((bestScoresId - prevK * numWords)) |
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for i in range(self.nextYs[-1].size(0)): |
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if self.nextYs[-1][i] == self._eos: |
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s = self.scores[i] |
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self.finished.append((s, len(self.nextYs) - 1, i)) |
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if self.nextYs[-1][0] == self._eos: |
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self.eosTop = True |
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def done(self): |
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return self.eosTop and len(self.finished) >=self.size |
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def getFinal(self): |
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if len(self.finished) == 0: |
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self.finished.append((self.scores[0], len(self.nextYs) - 1, 0)) |
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self.finished.sort(key=lambda a: -a[0]) |
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if len(self.finished) != self.size: |
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unfinished=[] |
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for i in range(self.nextYs[-1].size(0)): |
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if self.nextYs[-1][i] != self._eos: |
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s = self.scores[i] |
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unfinished.append((s, len(self.nextYs) - 1, i)) |
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unfinished.sort(key=lambda a: -a[0]) |
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self.finished+=unfinished[:self.size-len(self.finished)] |
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return self.finished[:self.size] |
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def getHyp(self, beam_res): |
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""" |
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Walk back to construct the full hypothesis. |
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""" |
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hyps=[] |
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for _,timestep, k in beam_res: |
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hyp = [] |
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for j in range(len(self.prevKs[:timestep]) - 1, -1, -1): |
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hyp.append(self.nextYs[j+1][k]) |
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k = self.prevKs[j][k] |
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hyps.append(hyp[::-1]) |
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return hyps |
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def buildTargetTokens(self, preds): |
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sentence=[] |
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for pred in preds: |
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tokens = [] |
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for tok in pred: |
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if tok==self._eos: |
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break |
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tokens.append(tok) |
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sentence.append(tokens) |
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return sentence |
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