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import os |
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from typing import Optional, Union, List |
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from transformers import AutoModel, PreTrainedModel, AutoConfig, AutoModel, RobertaModel, BertModel |
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from transformers.modeling_outputs import TokenClassifierOutput |
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from torch import nn |
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from torch.nn import CrossEntropyLoss |
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import torch |
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from itertools import islice |
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from.configuration_multiheadcrf import MultiHeadCRFConfig |
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NUM_PER_LAYER = 16 |
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class RobertaMultiHeadCRFModel(PreTrainedModel): |
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config_class = MultiHeadCRFConfig |
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transformers_backbone_name = "roberta" |
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transformers_backbone_class = RobertaModel |
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_keys_to_ignore_on_load_unexpected = [r"pooler"] |
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def __init__(self, config): |
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super().__init__(config) |
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self.num_labels = config.num_labels |
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self.number_of_layer_per_head = config.number_of_layer_per_head |
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self.heads = config.classes |
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setattr(self, self.transformers_backbone_name, self.transformers_backbone_class(config, add_pooling_layer=False)) |
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self.dropout = nn.Dropout(config.hidden_dropout_prob) |
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print(sorted(self.heads)) |
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for ent in self.heads: |
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for i in range(self.number_of_layer_per_head): |
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setattr(self, f"{ent}_dense_{i}", nn.Linear(config.hidden_size, config.hidden_size)) |
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setattr(self, f"{ent}_dense_activation_{i}", nn.GELU(approximate='none')) |
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setattr(self, f"{ent}_classifier", nn.Linear(config.hidden_size, config.num_labels)) |
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setattr(self, f"{ent}_crf", CRF(num_tags=config.num_labels, batch_first=True)) |
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setattr(self, f"{ent}_reduction", config.crf_reduction) |
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self.reduction=config.crf_reduction |
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if self.config.freeze == True: |
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self.manage_freezing() |
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def training_mode(self): |
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for ent in self.heads: |
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for i in range(self.number_of_layer_per_head): |
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getattr(self, f"{ent}_dense_{i}").reset_parameters() |
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getattr(self, f"{ent}_classifier").reset_parameters() |
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getattr(self, f"{ent}_crf").reset_parameters() |
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getattr(self, f"{ent}_crf").mask_impossible_transitions() |
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def manage_freezing(self): |
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for _, param in getattr(self, self.transformers_backbone_name).embeddings.named_parameters(): |
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param.requires_grad = False |
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num_encoders_to_freeze = self.config.num_frozen_encoder |
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if num_encoders_to_freeze > 0: |
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for _, param in islice(getattr(self, self.transformers_backbone_name).encoder.named_parameters(), num_encoders_to_freeze*NUM_PER_LAYER): |
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param.requires_grad = False |
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def forward(self, |
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input_ids=None, |
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attention_mask=None, |
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token_type_ids=None, |
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position_ids=None, |
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head_mask=None, |
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inputs_embeds=None, |
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labels=None, |
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output_attentions=None, |
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output_hidden_states=None, |
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return_dict=None |
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): |
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return_dict = return_dict if return_dict is not None else self.config.use_return_dict |
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outputs = getattr(self, self.transformers_backbone_name)(input_ids, |
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attention_mask=attention_mask, |
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token_type_ids=token_type_ids, |
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position_ids=position_ids, |
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head_mask=head_mask, |
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inputs_embeds=inputs_embeds, |
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output_attentions=output_attentions, |
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output_hidden_states=output_hidden_states, |
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return_dict=return_dict) |
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sequence_output = outputs[0] |
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sequence_output = self.dropout(sequence_output) |
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logits = {k:0 for k in self.heads} |
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for ent in self.heads: |
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for i in range(self.number_of_layer_per_head): |
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dense_output = getattr(self, f"{ent}_dense_{i}")(sequence_output) |
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dense_output = getattr(self, f"{ent}_dense_activation_{i}")(dense_output) |
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logits[ent] = getattr(self, f"{ent}_classifier")(dense_output) |
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loss = None |
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if labels is not None: |
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outputs = {k:0 for k in self.heads} |
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for ent in self.heads: |
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outputs[ent] = getattr(self, f"{ent}_crf")(logits[ent],labels[ent], reduction=self.reduction) |
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return sum(outputs.values()), logits |
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else: |
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outputs = {k:0 for k in self.heads} |
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for ent in self.heads: |
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outputs[ent] = torch.Tensor(getattr(self, f"{ent}_crf").decode(logits[ent])) |
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return [outputs[ent] for ent in sorted(self.heads)] |
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class BertMultiHeadCRFModel(RobertaMultiHeadCRFModel): |
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config_class = MultiHeadCRFConfig |
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transformers_backbone_name = "bert" |
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transformers_backbone_class = BertModel |
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_keys_to_ignore_on_load_unexpected = [r"pooler"] |
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LARGE_NEGATIVE_NUMBER = -1e9 |
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class CRF(nn.Module): |
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"""Conditional random field. |
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This module implements a conditional random field [LMP01]_. The forward computation |
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of this class computes the log likelihood of the given sequence of tags and |
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emission score tensor. This class also has `~CRF.decode` method which finds |
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the best tag sequence given an emission score tensor using `Viterbi algorithm`_. |
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Args: |
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num_tags: Number of tags. |
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batch_first: Whether the first dimension corresponds to the size of a minibatch. |
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Attributes: |
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start_transitions (`~torch.nn.Parameter`): Start transition score tensor of size |
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``(num_tags,)``. |
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end_transitions (`~torch.nn.Parameter`): End transition score tensor of size |
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``(num_tags,)``. |
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transitions (`~torch.nn.Parameter`): Transition score tensor of size |
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``(num_tags, num_tags)``. |
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.. [LMP01] Lafferty, J., McCallum, A., Pereira, F. (2001). |
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"Conditional random fields: Probabilistic models for segmenting and |
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labeling sequence data". *Proc. 18th International Conf. on Machine |
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Learning*. Morgan Kaufmann. pp. 282–289. |
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.. _Viterbi algorithm: https://en.wikipedia.org/wiki/Viterbi_algorithm |
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""" |
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def __init__(self, num_tags: int, batch_first: bool = False) -> None: |
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if num_tags <= 0: |
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raise ValueError(f'invalid number of tags: {num_tags}') |
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super().__init__() |
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self.num_tags = num_tags |
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self.batch_first = batch_first |
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self.start_transitions = nn.Parameter(torch.empty(num_tags)) |
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self.end_transitions = nn.Parameter(torch.empty(num_tags)) |
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self.transitions = nn.Parameter(torch.empty(num_tags, num_tags)) |
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self.reset_parameters() |
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self.mask_impossible_transitions() |
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def reset_parameters(self) -> None: |
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"""Initialize the transition parameters. |
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The parameters will be initialized randomly from a uniform distribution |
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between -0.1 and 0.1. |
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""" |
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nn.init.uniform_(self.start_transitions, -0.1, 0.1) |
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nn.init.uniform_(self.end_transitions, -0.1, 0.1) |
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nn.init.uniform_(self.transitions, -0.1, 0.1) |
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def mask_impossible_transitions(self) -> None: |
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"""Set the value of impossible transitions to LARGE_NEGATIVE_NUMBER |
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- start transition value of I-X |
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- transition score of O -> I |
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""" |
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with torch.no_grad(): |
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self.start_transitions[2] = LARGE_NEGATIVE_NUMBER |
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self.transitions[0][2] = LARGE_NEGATIVE_NUMBER |
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def __repr__(self) -> str: |
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return f'{self.__class__.__name__}(num_tags={self.num_tags})' |
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def forward( |
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self, |
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emissions: torch.Tensor, |
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tags: torch.LongTensor, |
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mask: Optional[torch.ByteTensor] = None, |
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reduction: str = 'sum', |
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) -> torch.Tensor: |
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"""Compute the conditional log likelihood of a sequence of tags given emission scores. |
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Args: |
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emissions (`~torch.Tensor`): Emission score tensor of size |
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``(seq_length, batch_size, num_tags)`` if ``batch_first`` is ``False``, |
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``(batch_size, seq_length, num_tags)`` otherwise. |
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tags (`~torch.LongTensor`): Sequence of tags tensor of size |
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``(seq_length, batch_size)`` if ``batch_first`` is ``False``, |
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``(batch_size, seq_length)`` otherwise. |
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mask (`~torch.ByteTensor`): Mask tensor of size ``(seq_length, batch_size)`` |
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if ``batch_first`` is ``False``, ``(batch_size, seq_length)`` otherwise. |
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reduction: Specifies the reduction to apply to the output: |
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``none|sum|mean|token_mean``. ``none``: no reduction will be applied. |
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``sum``: the output will be summed over batches. ``mean``: the output will be |
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averaged over batches. ``token_mean``: the output will be averaged over tokens. |
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Returns: |
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`~torch.Tensor`: The log likelihood. This will have size ``(batch_size,)`` if |
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reduction is ``none``, ``()`` otherwise. |
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""" |
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self._validate(emissions, tags=tags, mask=mask) |
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if reduction not in ('none', 'sum', 'mean', 'token_mean'): |
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raise ValueError(f'invalid reduction: {reduction}') |
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if mask is None: |
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mask = torch.ones_like(tags, dtype=torch.uint8) |
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if self.batch_first: |
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emissions = emissions.transpose(0, 1) |
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tags = tags.transpose(0, 1) |
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mask = mask.transpose(0, 1) |
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numerator = self._compute_score(emissions, tags, mask) |
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denominator = self._compute_normalizer(emissions, mask) |
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llh = numerator - denominator |
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nllh = -llh |
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if reduction == 'none': |
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return nllh |
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if reduction == 'sum': |
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return nllh.sum() |
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if reduction == 'mean': |
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return nllh.mean() |
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assert reduction == 'token_mean' |
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return nllh.sum() / mask.type_as(emissions).sum() |
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def decode(self, emissions: torch.Tensor, |
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mask: Optional[torch.ByteTensor] = None) -> List[List[int]]: |
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"""Find the most likely tag sequence using Viterbi algorithm. |
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Args: |
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emissions (`~torch.Tensor`): Emission score tensor of size |
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``(seq_length, batch_size, num_tags)`` if ``batch_first`` is ``False``, |
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``(batch_size, seq_length, num_tags)`` otherwise. |
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mask (`~torch.ByteTensor`): Mask tensor of size ``(seq_length, batch_size)`` |
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if ``batch_first`` is ``False``, ``(batch_size, seq_length)`` otherwise. |
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Returns: |
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List of list containing the best tag sequence for each batch. |
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""" |
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self._validate(emissions, mask=mask) |
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if mask is None: |
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mask = emissions.new_ones(emissions.shape[:2], dtype=torch.uint8) |
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if self.batch_first: |
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emissions = emissions.transpose(0, 1) |
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mask = mask.transpose(0, 1) |
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return self._viterbi_decode(emissions, mask) |
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def _validate( |
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self, |
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emissions: torch.Tensor, |
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tags: Optional[torch.LongTensor] = None, |
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mask: Optional[torch.ByteTensor] = None) -> None: |
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if emissions.dim() != 3: |
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raise ValueError(f'emissions must have dimension of 3, got {emissions.dim()}') |
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if emissions.size(2) != self.num_tags: |
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raise ValueError( |
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f'expected last dimension of emissions is {self.num_tags}, ' |
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f'got {emissions.size(2)}') |
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if tags is not None: |
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if emissions.shape[:2] != tags.shape: |
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raise ValueError( |
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'the first two dimensions of emissions and tags must match, ' |
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f'got {tuple(emissions.shape[:2])} and {tuple(tags.shape)}') |
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if mask is not None: |
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if emissions.shape[:2] != mask.shape: |
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raise ValueError( |
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'the first two dimensions of emissions and mask must match, ' |
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f'got {tuple(emissions.shape[:2])} and {tuple(mask.shape)}') |
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no_empty_seq = not self.batch_first and mask[0].all() |
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no_empty_seq_bf = self.batch_first and mask[:, 0].all() |
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if not no_empty_seq and not no_empty_seq_bf: |
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raise ValueError('mask of the first timestep must all be on') |
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def _compute_score( |
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self, emissions: torch.Tensor, tags: torch.LongTensor, |
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mask: torch.ByteTensor) -> torch.Tensor: |
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assert emissions.dim() == 3 and tags.dim() == 2 |
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assert emissions.shape[:2] == tags.shape |
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assert emissions.size(2) == self.num_tags |
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assert mask.shape == tags.shape |
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assert mask[0].all() |
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seq_length, batch_size = tags.shape |
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mask = mask.type_as(emissions) |
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score = self.start_transitions[tags[0]] |
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score += emissions[0, torch.arange(batch_size), tags[0]] |
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for i in range(1, seq_length): |
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score += self.transitions[tags[i - 1], tags[i]] * mask[i] |
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score += emissions[i, torch.arange(batch_size), tags[i]] * mask[i] |
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seq_ends = mask.long().sum(dim=0) - 1 |
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last_tags = tags[seq_ends, torch.arange(batch_size)] |
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score += self.end_transitions[last_tags] |
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return score |
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def _compute_normalizer( |
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self, emissions: torch.Tensor, mask: torch.ByteTensor) -> torch.Tensor: |
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assert emissions.dim() == 3 and mask.dim() == 2 |
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assert emissions.shape[:2] == mask.shape |
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assert emissions.size(2) == self.num_tags |
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assert mask[0].all() |
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seq_length = emissions.size(0) |
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score = self.start_transitions + emissions[0] |
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for i in range(1, seq_length): |
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broadcast_score = score.unsqueeze(2) |
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broadcast_emissions = emissions[i].unsqueeze(1) |
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next_score = broadcast_score + self.transitions + broadcast_emissions |
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next_score = torch.logsumexp(next_score, dim=1) |
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score = torch.where(mask[i].unsqueeze(1).bool(), next_score, score) |
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score += self.end_transitions |
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return torch.logsumexp(score, dim=1) |
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def _viterbi_decode(self, emissions: torch.FloatTensor, |
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mask: torch.ByteTensor) -> List[List[int]]: |
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assert emissions.dim() == 3 and mask.dim() == 2 |
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assert emissions.shape[:2] == mask.shape |
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assert emissions.size(2) == self.num_tags |
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assert mask[0].all() |
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seq_length, batch_size = mask.shape |
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score = self.start_transitions + emissions[0] |
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history = [] |
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for i in range(1, seq_length): |
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broadcast_score = score.unsqueeze(2) |
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broadcast_emission = emissions[i].unsqueeze(1) |
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next_score = broadcast_score + self.transitions + broadcast_emission |
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next_score, indices = next_score.max(dim=1) |
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score = torch.where(mask[i].unsqueeze(1).bool(), next_score, score) |
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history.append(indices) |
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score += self.end_transitions |
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seq_ends = mask.long().sum(dim=0) - 1 |
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best_tags_list = [] |
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for idx in range(batch_size): |
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_, best_last_tag = score[idx].max(dim=0) |
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best_tags = [best_last_tag.item()] |
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for hist in reversed(history[:seq_ends[idx]]): |
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best_last_tag = hist[idx][best_tags[-1]] |
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best_tags.append(best_last_tag.item()) |
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best_tags.reverse() |
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best_tags_list.append(best_tags) |
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return best_tags_list |