# Copyright (c) Facebook, Inc. and its affiliates. # # This source code is licensed under the MIT license found in the # LICENSE file in the root directory of this source tree. from dataclasses import dataclass, field import torch from fairseq import utils from fairseq.data import LanguagePairDataset from fairseq.dataclass import ChoiceEnum from fairseq.tasks import register_task from fairseq.tasks.translation import ( TranslationConfig, TranslationTask, load_langpair_dataset, ) from fairseq.utils import new_arange NOISE_CHOICES = ChoiceEnum(["random_delete", "random_mask", "no_noise", "full_mask"]) @dataclass class TranslationLevenshteinConfig(TranslationConfig): noise: NOISE_CHOICES = field( default="random_delete", metadata={"help": "type of noise"}, ) @register_task("translation_lev", dataclass=TranslationLevenshteinConfig) class TranslationLevenshteinTask(TranslationTask): """ Translation (Sequence Generation) task for Levenshtein Transformer See `"Levenshtein Transformer" `_. """ cfg: TranslationLevenshteinConfig def load_dataset(self, split, epoch=1, combine=False, **kwargs): """Load a given dataset split. Args: split (str): name of the split (e.g., train, valid, test) """ paths = utils.split_paths(self.cfg.data) assert len(paths) > 0 data_path = paths[(epoch - 1) % len(paths)] # infer langcode src, tgt = self.cfg.source_lang, self.cfg.target_lang self.datasets[split] = load_langpair_dataset( data_path, split, src, self.src_dict, tgt, self.tgt_dict, combine=combine, dataset_impl=self.cfg.dataset_impl, upsample_primary=self.cfg.upsample_primary, left_pad_source=self.cfg.left_pad_source, left_pad_target=self.cfg.left_pad_target, max_source_positions=self.cfg.max_source_positions, max_target_positions=self.cfg.max_target_positions, prepend_bos=True, ) def inject_noise(self, target_tokens): def _random_delete(target_tokens): pad = self.tgt_dict.pad() bos = self.tgt_dict.bos() eos = self.tgt_dict.eos() max_len = target_tokens.size(1) target_mask = target_tokens.eq(pad) target_score = target_tokens.clone().float().uniform_() target_score.masked_fill_( target_tokens.eq(bos) | target_tokens.eq(eos), 0.0 ) target_score.masked_fill_(target_mask, 1) target_score, target_rank = target_score.sort(1) target_length = target_mask.size(1) - target_mask.float().sum( 1, keepdim=True ) # do not delete and (we assign 0 score for them) target_cutoff = ( 2 + ( (target_length - 2) * target_score.new_zeros(target_score.size(0), 1).uniform_() ).long() ) target_cutoff = target_score.sort(1)[1] >= target_cutoff prev_target_tokens = ( target_tokens.gather(1, target_rank) .masked_fill_(target_cutoff, pad) .gather(1, target_rank.masked_fill_(target_cutoff, max_len).sort(1)[1]) ) prev_target_tokens = prev_target_tokens[ :, : prev_target_tokens.ne(pad).sum(1).max() ] return prev_target_tokens def _random_mask(target_tokens): pad = self.tgt_dict.pad() bos = self.tgt_dict.bos() eos = self.tgt_dict.eos() unk = self.tgt_dict.unk() target_masks = ( target_tokens.ne(pad) & target_tokens.ne(bos) & target_tokens.ne(eos) ) target_score = target_tokens.clone().float().uniform_() target_score.masked_fill_(~target_masks, 2.0) target_length = target_masks.sum(1).float() target_length = target_length * target_length.clone().uniform_() target_length = target_length + 1 # make sure to mask at least one token. _, target_rank = target_score.sort(1) target_cutoff = new_arange(target_rank) < target_length[:, None].long() prev_target_tokens = target_tokens.masked_fill( target_cutoff.scatter(1, target_rank, target_cutoff), unk ) return prev_target_tokens def _full_mask(target_tokens): pad = self.tgt_dict.pad() bos = self.tgt_dict.bos() eos = self.tgt_dict.eos() unk = self.tgt_dict.unk() target_mask = ( target_tokens.eq(bos) | target_tokens.eq(eos) | target_tokens.eq(pad) ) return target_tokens.masked_fill(~target_mask, unk) if self.cfg.noise == "random_delete": return _random_delete(target_tokens) elif self.cfg.noise == "random_mask": return _random_mask(target_tokens) elif self.cfg.noise == "full_mask": return _full_mask(target_tokens) elif self.cfg.noise == "no_noise": return target_tokens else: raise NotImplementedError def build_generator(self, models, args, **unused): # add models input to match the API for SequenceGenerator from fairseq.iterative_refinement_generator import IterativeRefinementGenerator return IterativeRefinementGenerator( self.target_dictionary, eos_penalty=getattr(args, "iter_decode_eos_penalty", 0.0), max_iter=getattr(args, "iter_decode_max_iter", 10), beam_size=getattr(args, "iter_decode_with_beam", 1), reranking=getattr(args, "iter_decode_with_external_reranker", False), decoding_format=getattr(args, "decoding_format", None), adaptive=not getattr(args, "iter_decode_force_max_iter", False), retain_history=getattr(args, "retain_iter_history", False), ) def build_dataset_for_inference(self, src_tokens, src_lengths, constraints=None): if constraints is not None: # Though see Susanto et al. (ACL 2020): https://www.aclweb.org/anthology/2020.acl-main.325/ raise NotImplementedError( "Constrained decoding with the translation_lev task is not supported" ) return LanguagePairDataset( src_tokens, src_lengths, self.source_dictionary, append_bos=True ) def train_step( self, sample, model, criterion, optimizer, update_num, ignore_grad=False ): model.train() sample["prev_target"] = self.inject_noise(sample["target"]) loss, sample_size, logging_output = criterion(model, sample) if ignore_grad: loss *= 0 optimizer.backward(loss) return loss, sample_size, logging_output def valid_step(self, sample, model, criterion): model.eval() with torch.no_grad(): sample["prev_target"] = self.inject_noise(sample["target"]) loss, sample_size, logging_output = criterion(model, sample) return loss, sample_size, logging_output