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import math |
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import string |
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from dataclasses import dataclass, field |
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from collections import OrderedDict |
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from typing import Optional |
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import torch |
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from fairseq import metrics, utils |
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from fairseq.criterions import FairseqCriterion, register_criterion |
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from fairseq.dataclass import FairseqDataclass |
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from omegaconf import II |
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from data import data_utils |
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from utils.cider.pyciderevalcap.ciderD.ciderD import CiderD |
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def scst_loss(lprobs, target, reward, ignore_index=None, reduce=True): |
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loss = -lprobs.gather(dim=-1, index=target.unsqueeze(-1)).squeeze() * reward.unsqueeze(-1) |
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if ignore_index is not None: |
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pad_mask = target.eq(ignore_index) |
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loss.masked_fill_(pad_mask, 0.0) |
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ntokens = (~pad_mask).sum() |
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else: |
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loss = loss.squeeze(-1) |
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ntokens = target.numel() |
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if reduce: |
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loss = loss.sum() |
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return loss, ntokens |
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@dataclass |
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class ScstRewardCriterionConfig(FairseqDataclass): |
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scst_cider_cached_tokens: str = field( |
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default="coco-train-words.p", |
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metadata={"help": "path to cached cPickle file used to calculate CIDEr scores"}, |
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) |
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ignore_prefix_size: int = field( |
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default=0, |
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metadata={"help": "Ignore first N tokens"}, |
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) |
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sentence_avg: bool = II("optimization.sentence_avg") |
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constraint_range: Optional[str] = field( |
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default=None, |
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metadata={"help": "constraint range"} |
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) |
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@register_criterion( |
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"scst_reward_criterion", dataclass=ScstRewardCriterionConfig |
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) |
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class ScstRewardCriterion(FairseqCriterion): |
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CIDER_REWARD_WEIGHT = 1 |
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def __init__( |
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self, |
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task, |
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scst_cider_cached_tokens, |
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sentence_avg, |
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ignore_prefix_size=0, |
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constraint_range=None |
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): |
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super().__init__(task) |
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self.scst_cider_scorer = CiderD(df=scst_cider_cached_tokens) |
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self.sentence_avg = sentence_avg |
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self.ignore_prefix_size = ignore_prefix_size |
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self.transtab = str.maketrans({key: None for key in string.punctuation}) |
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self.constraint_start = None |
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self.constraint_end = None |
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if constraint_range is not None: |
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constraint_start, constraint_end = constraint_range.split(',') |
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self.constraint_start = int(constraint_start) |
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self.constraint_end = int(constraint_end) |
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def forward(self, model, sample, reduce=True): |
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"""Compute the loss for the given sample. |
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Returns a tuple with three elements: |
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1) the loss |
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2) the sample size, which is used as the denominator for the gradient |
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3) logging outputs to display while training |
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""" |
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loss, score, ntokens, nsentences = self.compute_loss(model, sample, reduce=reduce) |
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sample_size = ( |
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nsentences if self.sentence_avg else ntokens |
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) |
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logging_output = { |
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"loss": loss.data, |
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"score": score, |
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"ntokens": ntokens, |
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"nsentences": nsentences, |
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"sample_size": sample_size, |
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} |
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return loss, sample_size, logging_output |
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def _calculate_eval_scores(self, gen_res, gt_idx, gt_res): |
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''' |
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gen_res: generated captions, list of str |
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gt_idx: list of int, of the same length as gen_res |
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gt_res: ground truth captions, list of list of str. |
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gen_res[i] corresponds to gt_res[gt_idx[i]] |
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Each image can have multiple ground truth captions |
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''' |
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gen_res_size = len(gen_res) |
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res = OrderedDict() |
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for i in range(gen_res_size): |
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res[i] = [self._wrap_sentence(gen_res[i].strip().translate(self.transtab))] |
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gts = OrderedDict() |
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gt_res_ = [ |
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[self._wrap_sentence(gt_res[i][j].strip().translate(self.transtab)) for j in range(len(gt_res[i]))] |
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for i in range(len(gt_res)) |
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] |
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for i in range(gen_res_size): |
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gts[i] = gt_res_[gt_idx[i]] |
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res_ = [{'image_id':i, 'caption': res[i]} for i in range(len(res))] |
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_, batch_cider_scores = self.scst_cider_scorer.compute_score(gts, res_) |
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scores = self.CIDER_REWARD_WEIGHT * batch_cider_scores |
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return scores |
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@classmethod |
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def _wrap_sentence(self, s): |
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r = s.strip() |
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if r.endswith('.'): |
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r = r[:-1] |
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r += ' <eos>' |
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return r |
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def get_generator_out(self, model, sample): |
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def decode(toks): |
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hypo = toks.int().cpu() |
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hypo_str = self.task.tgt_dict.string(hypo) |
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hypo_str = self.task.bpe.decode(hypo_str).strip() |
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return hypo, hypo_str |
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model.eval() |
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with torch.no_grad(): |
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self.task.scst_generator.model.eval() |
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gen_out = self.task.scst_generator.generate([model], sample) |
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gen_target = [] |
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gen_res = [] |
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gt_res = [] |
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for i in range(len(gen_out)): |
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for j in range(len(gen_out[i])): |
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hypo, hypo_str = decode(gen_out[i][j]["tokens"]) |
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gen_target.append(hypo) |
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gen_res.append(hypo_str) |
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gt_res.append( |
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decode(utils.strip_pad(sample["target"][i], self.padding_idx))[1].split('&&') |
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) |
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return gen_target, gen_res, gt_res |
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def get_reward_and_scores(self, gen_res, gt_res, device): |
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batch_size = len(gt_res) |
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gen_res_size = len(gen_res) |
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seq_per_img = gen_res_size // batch_size |
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gt_idx = [i // seq_per_img for i in range(gen_res_size)] |
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scores = self._calculate_eval_scores(gen_res, gt_idx, gt_res) |
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sc_ = scores.reshape(batch_size, seq_per_img) |
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baseline = (sc_.sum(1, keepdims=True) - sc_) / (sc_.shape[1] - 1) |
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reward = scores.reshape(batch_size, seq_per_img) |
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reward = reward - baseline |
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reward = reward.reshape(gen_res_size) |
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reward = torch.as_tensor(reward, device=device, dtype=torch.float64) |
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return reward, scores |
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def get_net_output(self, model, sample, gen_target): |
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def merge(sample_list, eos=self.task.tgt_dict.eos(), move_eos_to_beginning=False): |
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return data_utils.collate_tokens( |
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sample_list, |
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pad_idx=self.padding_idx, |
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eos_idx=eos, |
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left_pad=False, |
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move_eos_to_beginning=move_eos_to_beginning, |
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) |
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batch_size = len(sample["target"]) |
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gen_target_size = len(gen_target) |
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seq_per_img = gen_target_size // batch_size |
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model.train() |
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sample_src_tokens = torch.repeat_interleave( |
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sample['net_input']['src_tokens'], seq_per_img, dim=0 |
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) |
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sample_src_lengths = torch.repeat_interleave( |
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sample['net_input']['src_lengths'], seq_per_img, dim=0 |
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) |
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sample_patch_images = torch.repeat_interleave( |
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sample['net_input']['patch_images'], seq_per_img, dim=0 |
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) |
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sample_patch_masks = torch.repeat_interleave( |
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sample['net_input']['patch_masks'], seq_per_img, dim=0 |
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) |
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gen_prev_output_tokens = torch.as_tensor( |
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merge(gen_target, eos=self.task.tgt_dict.bos(), move_eos_to_beginning=True), |
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device=sample["target"].device, dtype=torch.int64 |
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) |
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gen_target_tokens = torch.as_tensor( |
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merge(gen_target), device=sample["target"].device, dtype=torch.int64 |
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) |
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net_output = model( |
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src_tokens=sample_src_tokens, src_lengths=sample_src_lengths, |
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patch_images=sample_patch_images, patch_masks=sample_patch_masks, |
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prev_output_tokens=gen_prev_output_tokens |
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) |
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return net_output, gen_target_tokens |
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def get_lprobs_and_target(self, model, net_output, gen_target): |
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if self.constraint_start is not None and self.constraint_end is not None: |
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net_output[0][:, :, 4:self.constraint_start] = -math.inf |
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net_output[0][:, :, self.constraint_end:] = -math.inf |
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lprobs = model.get_normalized_probs(net_output, log_probs=True) |
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if self.ignore_prefix_size > 0: |
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if getattr(lprobs, "batch_first", False): |
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lprobs = lprobs[:, self.ignore_prefix_size :, :].contiguous() |
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gen_target = gen_target[:, self.ignore_prefix_size :].contiguous() |
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else: |
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lprobs = lprobs[self.ignore_prefix_size :, :, :].contiguous() |
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gen_target = gen_target[self.ignore_prefix_size :, :].contiguous() |
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return lprobs, gen_target |
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def compute_loss(self, model, sample, reduce=True): |
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gen_target, gen_res, gt_res = self.get_generator_out(model, sample) |
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reward, scores = self.get_reward_and_scores(gen_res, gt_res, device=sample["target"].device) |
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net_output, gen_target_tokens = self.get_net_output(model, sample, gen_target) |
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gen_lprobs, gen_target_tokens = self.get_lprobs_and_target(model, net_output, gen_target_tokens) |
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loss, ntokens = scst_loss(gen_lprobs, gen_target_tokens, reward, ignore_index=self.padding_idx, reduce=reduce) |
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nsentences = gen_target_tokens.size(0) |
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return loss, scores.sum(), ntokens, nsentences |
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@classmethod |
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def reduce_metrics(cls, logging_outputs) -> None: |
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"""Aggregate logging outputs from data parallel training.""" |
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loss_sum = sum(log.get("loss", 0) for log in logging_outputs) |
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score_sum = sum(log.get("score", 0) for log in logging_outputs) |
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ntokens = sum(log.get("ntokens", 0) for log in logging_outputs) |
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nsentences = sum(log.get("nsentences", 0) for log in logging_outputs) |
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sample_size = sum(log.get("sample_size", 0) for log in logging_outputs) |
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metrics.log_scalar( |
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"loss", loss_sum / sample_size, sample_size, round=3 |
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) |
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metrics.log_scalar( |
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"score", score_sum / nsentences, nsentences, round=3 |
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) |
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metrics.log_scalar( |
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"ntokens", ntokens, 1, round=3 |
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) |
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metrics.log_scalar( |
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"nsentences", nsentences, 1, round=3 |
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) |
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metrics.log_scalar( |
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"sample_size", sample_size, 1, round=3 |
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) |
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@staticmethod |
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def logging_outputs_can_be_summed() -> bool: |
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""" |
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Whether the logging outputs returned by `forward` can be summed |
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across workers prior to calling `reduce_metrics`. Setting this |
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to True will improves distributed training speed. |
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""" |
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return True |
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