# 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. import argparse import unittest import tests.utils as test_utils import torch from fairseq.sequence_scorer import SequenceScorer class TestSequenceScorer(unittest.TestCase): def test_sequence_scorer(self): # construct dummy dictionary d = test_utils.dummy_dictionary(vocab_size=2) self.assertEqual(d.pad(), 1) self.assertEqual(d.eos(), 2) self.assertEqual(d.unk(), 3) eos = d.eos() w1 = 4 w2 = 5 # construct dataloader data = [ { "source": torch.LongTensor([w1, w2, eos]), "target": torch.LongTensor([w1, w2, w1, eos]), }, { "source": torch.LongTensor([w2, eos]), "target": torch.LongTensor([w2, w1, eos]), }, { "source": torch.LongTensor([w2, eos]), "target": torch.LongTensor([w2, eos]), }, ] data_itr = test_utils.dummy_dataloader(data) # specify expected output probabilities args = argparse.Namespace() unk = 0.0 args.beam_probs = [ # step 0: torch.FloatTensor( [ # eos w1 w2 [0.0, unk, 0.6, 0.4], # sentence 1 [0.0, unk, 0.4, 0.6], # sentence 2 [0.0, unk, 0.7, 0.3], # sentence 3 ] ), # step 1: torch.FloatTensor( [ # eos w1 w2 [0.0, unk, 0.2, 0.7], # sentence 1 [0.0, unk, 0.8, 0.2], # sentence 2 [0.7, unk, 0.1, 0.2], # sentence 3 ] ), # step 2: torch.FloatTensor( [ # eos w1 w2 [0.10, unk, 0.50, 0.4], # sentence 1 [0.15, unk, 0.15, 0.7], # sentence 2 [0.00, unk, 0.00, 0.0], # sentence 3 ] ), # step 3: torch.FloatTensor( [ # eos w1 w2 [0.9, unk, 0.05, 0.05], # sentence 1 [0.0, unk, 0.00, 0.0], # sentence 2 [0.0, unk, 0.00, 0.0], # sentence 3 ] ), ] expected_scores = [ [0.6, 0.7, 0.5, 0.9], # sentence 1 [0.6, 0.8, 0.15], # sentence 2 [0.3, 0.7], # sentence 3 ] task = test_utils.TestTranslationTask.setup_task(args, d, d) model = task.build_model(args) scorer = SequenceScorer(task.target_dictionary) for sample in data_itr: hypos = task.inference_step(scorer, [model], sample) for id, hypos_id in zip(sample["id"].tolist(), hypos): self.assertHypoTokens(hypos_id[0], data[id]["target"]) self.assertHypoScore(hypos_id[0], expected_scores[id]) def assertHypoTokens(self, hypo, tokens): self.assertTensorEqual(hypo["tokens"], torch.LongTensor(tokens)) def assertHypoScore(self, hypo, pos_probs, normalized=True, lenpen=1.0): pos_scores = torch.FloatTensor(pos_probs).log() self.assertAlmostEqual(hypo["positional_scores"], pos_scores) self.assertEqual(pos_scores.numel(), hypo["tokens"].numel()) score = pos_scores.sum() if normalized: score /= pos_scores.numel() ** lenpen self.assertLess(abs(score - hypo["score"]), 1e-6) def assertAlmostEqual(self, t1, t2): self.assertEqual(t1.size(), t2.size(), "size mismatch") self.assertLess((t1 - t2).abs().max(), 1e-4) def assertTensorEqual(self, t1, t2): self.assertEqual(t1.size(), t2.size(), "size mismatch") self.assertEqual(t1.ne(t2).long().sum(), 0) if __name__ == "__main__": unittest.main()