# coding=utf-8 # Copyright 2020 The HuggingFace Team Inc. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a clone of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import unittest from typing import List, Union from parameterized import parameterized from transformers import is_torch_available from transformers.testing_utils import require_torch, torch_device from ..test_modeling_common import ids_tensor if is_torch_available(): import torch from torch import nn from transformers.generation import ( EncoderNoRepeatNGramLogitsProcessor, EncoderRepetitionPenaltyLogitsProcessor, EpsilonLogitsWarper, EtaLogitsWarper, ExponentialDecayLengthPenalty, ForcedBOSTokenLogitsProcessor, ForcedEOSTokenLogitsProcessor, HammingDiversityLogitsProcessor, InfNanRemoveLogitsProcessor, LogitNormalization, LogitsProcessorList, MinLengthLogitsProcessor, MinNewTokensLengthLogitsProcessor, NoBadWordsLogitsProcessor, NoRepeatNGramLogitsProcessor, PrefixConstrainedLogitsProcessor, RepetitionPenaltyLogitsProcessor, SequenceBiasLogitsProcessor, TemperatureLogitsWarper, TopKLogitsWarper, TopPLogitsWarper, TypicalLogitsWarper, UnbatchedClassifierFreeGuidanceLogitsProcessor, ) @require_torch class LogitsProcessorTest(unittest.TestCase): def _get_uniform_logits(self, batch_size: int, length: int): scores = torch.ones((batch_size, length), device=torch_device, dtype=torch.float) / length return scores def test_min_length_dist_processor(self): vocab_size = 20 batch_size = 4 eos_token_id = 0 min_dist_processor = MinLengthLogitsProcessor(min_length=10, eos_token_id=eos_token_id) # check that min length is applied at length 5 input_ids = ids_tensor((batch_size, 5), vocab_size=20) scores = self._get_uniform_logits(batch_size, vocab_size) scores_before_min_length = min_dist_processor(input_ids, scores) self.assertListEqual(scores_before_min_length[:, eos_token_id].tolist(), 4 * [-float("inf")]) # check that min length is not applied anymore at length 15 input_ids = ids_tensor((batch_size, 15), vocab_size=20) scores = self._get_uniform_logits(batch_size, vocab_size) scores_before_min_length = min_dist_processor(input_ids, scores) self.assertFalse(torch.isinf(scores_before_min_length).any()) @parameterized.expand([(0,), ([0, 18],)]) def test_new_min_length_dist_processor(self, eos_token_id: Union[int, List[int]]): vocab_size = 20 batch_size = 4 # check that first input is skipped (min new length applying) input_ids = ids_tensor((batch_size, 5), vocab_size=20) new_min_dist_processor = MinNewTokensLengthLogitsProcessor( prompt_length_to_skip=input_ids.shape[-1], min_new_tokens=3, eos_token_id=eos_token_id ) expected_eos_scores_before_min_length = batch_size * [-float("inf")] if isinstance(eos_token_id, list): expected_eos_scores_before_min_length *= len(eos_token_id) scores = self._get_uniform_logits(batch_size, vocab_size) scores_before_min_length = new_min_dist_processor(input_ids, scores) self.assertListEqual( scores_before_min_length[:, eos_token_id].flatten().tolist(), expected_eos_scores_before_min_length ) # check that, for skipping, now prompt length is 5, after that we expect first 5 tokens will be skipped self.assertTrue(new_min_dist_processor.prompt_length_to_skip == 5) # check that min length is applied at length 2 input_ids = ids_tensor((batch_size, 2), vocab_size=20) scores = self._get_uniform_logits(batch_size, vocab_size) scores_before_min_length = new_min_dist_processor(input_ids, scores) self.assertListEqual( scores_before_min_length[:, eos_token_id].flatten().tolist(), expected_eos_scores_before_min_length ) # check that min new length is applied at length 6 (because it has only 1 new token) input_ids = ids_tensor((batch_size, 6), vocab_size=20) scores = self._get_uniform_logits(batch_size, vocab_size) scores_before_min_length = new_min_dist_processor(input_ids, scores) self.assertListEqual( scores_before_min_length[:, eos_token_id].flatten().tolist(), expected_eos_scores_before_min_length ) # check that min new length is applied at length 7 (because it has only 2 new tokens) input_ids = ids_tensor((batch_size, 7), vocab_size=20) scores = self._get_uniform_logits(batch_size, vocab_size) scores_before_min_length = new_min_dist_processor(input_ids, scores) self.assertListEqual( scores_before_min_length[:, eos_token_id].flatten().tolist(), expected_eos_scores_before_min_length ) # check that min new length is not applied anymore at length 8 input_ids = ids_tensor((batch_size, 8), vocab_size=20) scores = self._get_uniform_logits(batch_size, vocab_size) scores_before_min_length = new_min_dist_processor(input_ids, scores) self.assertFalse(torch.isinf(scores_before_min_length).any()) # check that min new length is not applied anymore at length 15 input_ids = ids_tensor((batch_size, 15), vocab_size=20) scores = self._get_uniform_logits(batch_size, vocab_size) scores_before_min_length = new_min_dist_processor(input_ids, scores) self.assertFalse(torch.isinf(scores_before_min_length).any()) def test_temperature_dist_warper(self): input_ids = None length = 20 scores = self._get_uniform_logits(batch_size=2, length=length) # tweak scores to not be uniform anymore scores[1, 5] = (1 / length) + 0.1 # peak, 1st batch scores[1, 10] = (1 / length) - 0.4 # valley, 1st batch # compute softmax probs = nn.functional.softmax(scores, dim=-1) temp_dist_warper_sharper = TemperatureLogitsWarper(temperature=0.5) temp_dist_warper_smoother = TemperatureLogitsWarper(temperature=1.3) warped_prob_sharp = nn.functional.softmax(temp_dist_warper_sharper(input_ids, scores.clone()), dim=-1) warped_prob_smooth = nn.functional.softmax(temp_dist_warper_smoother(input_ids, scores.clone()), dim=-1) # uniform distribution stays uniform self.assertTrue(torch.allclose(probs[0, :], warped_prob_sharp[0, :], atol=1e-3)) self.assertTrue(torch.allclose(probs[0, :], warped_prob_smooth[0, :], atol=1e-3)) # sharp peaks get higher, valleys get lower self.assertLess(probs[1, :].max(), warped_prob_sharp[1, :].max()) self.assertGreater(probs[1, :].min(), warped_prob_sharp[1, :].min()) # smooth peaks get lower, valleys get higher self.assertGreater(probs[1, :].max(), warped_prob_smooth[1, :].max()) self.assertLess(probs[1, :].min(), warped_prob_smooth[1, :].min()) def test_repetition_penalty_dist_process(self): input_ids = torch.tensor([[0, 1], [5, 0]], device=torch_device, dtype=torch.long) vocab_size = 10 scores = self._get_uniform_logits(batch_size=2, length=vocab_size) # give values special values scores[0, 0] = -(1 / vocab_size) scores[1, 5] = 4 / vocab_size rep_penalty_proc = RepetitionPenaltyLogitsProcessor(penalty=2.0) scores = rep_penalty_proc(input_ids, scores.clone()) # check that values were correctly changed self.assertAlmostEqual(scores[0, 0].item(), -(1 / vocab_size) * 2) self.assertAlmostEqual(scores[0, 1].item(), (1 / vocab_size) / 2) self.assertAlmostEqual(scores[1, 0].item(), (1 / vocab_size) / 2) self.assertAlmostEqual(scores[1, 5].item(), (4 / vocab_size) / 2) def test_encoder_repetition_penalty_dist_process(self): input_ids = torch.tensor([[0, 1], [5, 0]], device=torch_device, dtype=torch.long) vocab_size = 10 scores = self._get_uniform_logits(batch_size=2, length=vocab_size) # give values special values scores[0, 0] = -(1 / vocab_size) scores[1, 5] = 4 / vocab_size rep_penalty_proc = EncoderRepetitionPenaltyLogitsProcessor(penalty=2.0, encoder_input_ids=input_ids) scores = rep_penalty_proc(input_ids, scores.clone()) # check that values were correctly changed self.assertAlmostEqual(scores[0, 0].item(), -(1 / vocab_size) / 2) self.assertAlmostEqual(scores[0, 1].item(), (1 / vocab_size) * 2) self.assertAlmostEqual(scores[1, 0].item(), (1 / vocab_size) * 2) self.assertAlmostEqual(scores[1, 5].item(), (4 / vocab_size) * 2) # check that values not in the encoder ids were NOT changed self.assertAlmostEqual(scores[0, 2].item(), (1 / vocab_size)) self.assertAlmostEqual(scores[1, 2].item(), (1 / vocab_size)) def test_top_k_dist_warper(self): input_ids = None vocab_size = 10 batch_size = 2 # create ramp distribution ramp_logits = ( torch.arange(vocab_size, device=torch_device, dtype=torch.float).unsqueeze(0).repeat(batch_size, 1) ) ramp_logits[1:, : vocab_size // 2] = ramp_logits[1:, : vocab_size // 2] + vocab_size top_k_warp = TopKLogitsWarper(3) scores = top_k_warp(input_ids, ramp_logits) # check that correct tokens are filtered self.assertListEqual(torch.isinf(scores[0]).tolist(), 7 * [True] + 3 * [False]) self.assertListEqual(torch.isinf(scores[1]).tolist(), 2 * [True] + 3 * [False] + 5 * [True]) # check special cases length = 5 logits = self._get_uniform_logits(batch_size=batch_size, length=length) top_k_warp_safety_check = TopKLogitsWarper(top_k=1, filter_value=0.0, min_tokens_to_keep=3) scores = top_k_warp_safety_check(input_ids, logits) # uniform dist is not changed self.assertListEqual((scores == 0.0).to(torch.long).sum(dim=-1).tolist(), [0, 0]) ramp_logits = torch.arange(length, device=torch_device, dtype=torch.float).unsqueeze(0).repeat(batch_size, 1) scores = top_k_warp_safety_check(input_ids, ramp_logits) # min_tokens overwrites k: 3 tokens are kept => 2 tokens are nullified self.assertListEqual((scores == 0.0).to(torch.long).sum(dim=-1).tolist(), [2, 2]) def test_top_p_dist_warper(self): input_ids = None vocab_size = 10 batch_size = 2 # create distribution and take log (inverse to Softmax as taken in TopPLogitsWarper) dist = torch.log( torch.tensor([[0.3, 0.1, 0.1, 0.5], [0.15, 0.3, 0.3, 0.25]], device=torch_device, dtype=torch.float) ) top_p_warp = TopPLogitsWarper(0.8) filtered_dist = torch.exp(top_p_warp(input_ids, dist)) # dist should be filtered to keep min num values so that sum is >= top_p # exp (-inf) => 0 EXPECTED_FILTERED_DIST = torch.tensor( [[0.3, 0.0, 0.0, 0.5], [0.0, 0.3, 0.3, 0.25]], device=torch_device, dtype=torch.float ) self.assertTrue(torch.allclose(filtered_dist, EXPECTED_FILTERED_DIST, atol=1e-3)) # check edge cases with negative and extreme logits ramp_logits = torch.arange(vocab_size, device=torch_device, dtype=torch.float).unsqueeze(0).repeat( batch_size, 1 ) - (vocab_size // 2) # make ramp_logits more extreme ramp_logits[1] = ramp_logits[1] * 100.0 # make sure at least 2 tokens are kept top_p_warp = TopPLogitsWarper(0.9, min_tokens_to_keep=2, filter_value=0.0) filtered_dist = top_p_warp(input_ids, ramp_logits) # first batch should keep three tokens, second batch would keep only 1, but due to `min_tokens_to_keep=2` keeps 2. self.assertListEqual((filtered_dist != 0.0).to(torch.long).sum(dim=-1).tolist(), [3, 2]) def test_typical_dist_warper(self): input_ids = None vocab_size = 10 batch_size = 2 # create distribution and take log (inverse to Softmax as taken in TopPLogitsWarper) dist = torch.log( torch.tensor([[0.97, 0.01, 0.01, 0.01], [0.4, 0.2, 0.2, 0.2]], device=torch_device, dtype=torch.float) ) typical_warp = TypicalLogitsWarper(0.5) filtered_dist = torch.exp(typical_warp(input_ids, dist)) # dist should be filtered to keep min num values so that sum is >= 0.7 # exp (-inf) => 0 EXPECTED_FILTERED_DIST = torch.tensor( [[0.97, 0.0, 0.0, 0.0], [0.0, 0.2, 0.2, 0.2]], device=torch_device, dtype=torch.float ) self.assertTrue(torch.allclose(filtered_dist, EXPECTED_FILTERED_DIST, atol=1e-3)) # check special cases length = 5 logits = self._get_uniform_logits(batch_size=batch_size, length=length) typical_warp_safety_check = TypicalLogitsWarper(mass=0.5, filter_value=0.0, min_tokens_to_keep=3) scores = typical_warp_safety_check(input_ids, logits) # uniform dist is not changed self.assertListEqual((scores == 0.0).to(torch.long).sum(dim=-1).tolist(), [0, 0]) # check edge cases with negative and extreme logits ramp_logits = torch.arange(vocab_size, device=torch_device, dtype=torch.float).unsqueeze(0).repeat( batch_size, 1 ) - (vocab_size // 2) # make ramp_logits more extreme ramp_logits[1] = ramp_logits[1] * 100.0 # make sure at least 2 tokens are kept typical_warp = TypicalLogitsWarper(0.7, min_tokens_to_keep=2, filter_value=0.0) filtered_dist = typical_warp(input_ids, ramp_logits) # first batch should keep two tokens, second batch would keep only 1, but due to `min_tokens_to_keep=2` keeps 2. self.assertListEqual((filtered_dist != 0.0).to(torch.long).sum(dim=-1).tolist(), [2, 2]) def test_epsilon_dist_warper(self): input_ids = None vocab_size = 10 batch_size = 2 # create distribution and take log (inverse to Softmax as taken in TopPLogitsWarper) dist = torch.log( torch.tensor( [[0.87, 0.099, 0.001, 0.03], [0.4, 0.299, 0.101, 0.2]], device=torch_device, dtype=torch.float ) ) epsilon_warp = EpsilonLogitsWarper(0.1) filtered_dist = torch.exp(epsilon_warp(input_ids, dist)) # dist should be filtered to only keep values with proba >= 0.1 # exp (-inf) => 0 EXPECTED_FILTERED_DIST = torch.tensor( [[0.87, 0, 0, 0], [0.4, 0.299, 0.101, 0.2]], device=torch_device, dtype=torch.float ) self.assertTrue(torch.allclose(filtered_dist, EXPECTED_FILTERED_DIST, atol=1e-3)) # check edge cases with negative and extreme logits ramp_logits = torch.arange(vocab_size, device=torch_device, dtype=torch.float).unsqueeze(0).repeat( batch_size, 1 ) - (vocab_size // 2) # make ramp_logits more extreme ramp_logits[1] = ramp_logits[1] * 100.0 # make sure at least 2 tokens are kept epsilon_warp = EpsilonLogitsWarper(5e-2, min_tokens_to_keep=2, filter_value=0.0) filtered_dist = epsilon_warp(input_ids, ramp_logits) # first batch should keep 3 tokens, second batch would keep only 1, but due to `min_tokens_to_keep=2` keeps 2. self.assertListEqual((filtered_dist != 0.0).to(torch.long).sum(dim=-1).tolist(), [3, 2]) def test_eta_dist_warper(self): input_ids = None vocab_size = 10 batch_size = 2 # create distribution and take log (inverse to Softmax as taken in TopPLogitsWarper) dist = torch.log( torch.tensor([[0.0, 0.1, 0.8, 0.1], [0.01, 0.04, 0.9, 0.05]], device=torch_device, dtype=torch.float) ) eta_warp = EtaLogitsWarper(0.0625) filtered_dist = torch.exp(eta_warp(input_ids, dist)) # dist should be filtered to only keep values with proba >= min(0.0625, sqrt(0.0625) * e^-H(p)) # min(0.0625, 0.1320) is the cutoff for the first row and min(0.0625, 0.1644) is for the second # where H is the entropy function and p is the probability vector. # exp (-inf) => 0 EXPECTED_FILTERED_DIST = torch.tensor( [[0.0, 0.1, 0.8, 0.1], [0.0, 0.0, 0.9, 0.0]], device=torch_device, dtype=torch.float ) self.assertTrue(torch.allclose(filtered_dist, EXPECTED_FILTERED_DIST, atol=1e-3)) # check edge cases with negative and extreme logits ramp_logits = torch.arange(vocab_size, device=torch_device, dtype=torch.float).unsqueeze(0).repeat( batch_size, 1 ) - (vocab_size // 2) # make ramp_logits more extreme ramp_logits[1] = ramp_logits[1] * 100.0 # make sure at least 2 tokens are kept eta_warp = EtaLogitsWarper(0.1, min_tokens_to_keep=2, filter_value=0.0) filtered_dist = eta_warp(input_ids, ramp_logits) # first batch should keep 2 tokens, second batch would keep only 1, but due to `min_tokens_to_keep=2` keeps 2. self.assertListEqual((filtered_dist != 0.0).to(torch.long).sum(dim=-1).tolist(), [2, 2]) def test_no_repeat_ngram_dist_processor(self): vocab_size = 3 batch_size = 2 input_ids = torch.tensor([[1, 1, 2, 1], [0, 1, 0, 1]], device=torch_device, dtype=torch.long) scores = self._get_uniform_logits(batch_size, vocab_size) no_repeat_proc_2_gram = NoRepeatNGramLogitsProcessor(2) no_repeat_proc_3_gram = NoRepeatNGramLogitsProcessor(3) filtered_scores_2_gram = no_repeat_proc_2_gram(input_ids, scores.clone()) filtered_scores_3_gram = no_repeat_proc_3_gram(input_ids, scores.clone()) # 2-gram would forbid 2nd and 3rd token (1,2) at 1st batch and 1st token (0) at 2nd batch self.assertListEqual(torch.isinf(filtered_scores_2_gram).tolist(), [[False, True, True], [True, False, False]]) # 3-gram would forbid no token at 1st batch and 1st token (0) at 2nd batch self.assertListEqual( torch.isinf(filtered_scores_3_gram).tolist(), [[False, False, False], [True, False, False]] ) def test_encoder_no_repeat_ngram_dist_processor(self): vocab_size = 3 num_beams = 2 batch_size = 1 encoder_input_ids = torch.tensor([1, 2, 1, 1], device=torch_device, dtype=torch.long) input_ids = torch.tensor([[1, 2, 1], [8, 0, 2]], device=torch_device, dtype=torch.long) scores = self._get_uniform_logits(batch_size * num_beams, vocab_size) no_repeat_proc_2_gram = EncoderNoRepeatNGramLogitsProcessor(2, encoder_input_ids=encoder_input_ids) no_repeat_proc_3_gram = EncoderNoRepeatNGramLogitsProcessor(3, encoder_input_ids=encoder_input_ids) filtered_scores_2_gram = no_repeat_proc_2_gram(input_ids, scores.clone()) filtered_scores_3_gram = no_repeat_proc_3_gram(input_ids, scores.clone()) # 2-gram would forbid 1st and 2nd token at 1st beam and 1st token (0) at 2nd beam self.assertListEqual(torch.isinf(filtered_scores_2_gram).tolist(), [[False, True, True], [False, True, False]]) # 3-gram would forbid 1st token at 1st beam and no token at 2nd beam self.assertListEqual( torch.isinf(filtered_scores_3_gram).tolist(), [[False, True, False], [False, False, False]] ) # Batched input vocab_size = 3 num_beams = 2 batch_size = 2 encoder_input_ids = torch.tensor([[1, 2, 1, 1], [0, 0, 2, 1]], device=torch_device, dtype=torch.long) input_ids = torch.tensor([[1, 2, 1], [1, 0, 2], [0, 0, 0], [0, 2, 2]], device=torch_device, dtype=torch.long) scores = self._get_uniform_logits(batch_size * num_beams, vocab_size) no_repeat_proc_2_gram = EncoderNoRepeatNGramLogitsProcessor(2, encoder_input_ids=encoder_input_ids) no_repeat_proc_3_gram = EncoderNoRepeatNGramLogitsProcessor(3, encoder_input_ids=encoder_input_ids) filtered_scores_2_gram = no_repeat_proc_2_gram(input_ids, scores.clone()) filtered_scores_3_gram = no_repeat_proc_3_gram(input_ids, scores.clone()) # 2gram # Batch 1 # - Beam 1: tokens (1, 2) forbidden # - Beam 2: tokens (1) forbidden # Batch 2 # - Beam 1: tokens (0, 2) forbidden # - Beam 2: tokens (1) forbidden self.assertListEqual( torch.isinf(filtered_scores_2_gram).tolist(), [[False, True, True], [False, True, False], [True, False, True], [False, True, False]], ) # Batch 1 # - Beam 1: tokens (1) forbidden # - Beam 2: tokens () forbidden # Batch 2 # - Beam 1: tokens (2) forbidden # - Beam 2: tokens () forbidden self.assertListEqual( torch.isinf(filtered_scores_3_gram).tolist(), [[False, True, False], [False, False, False], [False, False, True], [False, False, False]], ) def test_no_bad_words_dist_processor(self): vocab_size = 5 batch_size = 2 eos_token_id = 4 input_ids = torch.tensor([[0, 1, 3, 1], [0, 1, 0, 1]], device=torch_device, dtype=torch.long) bad_word_tokens = [[1], [4], [1, 0], [0, 1, 2], [1, 3, 1, 3]] scores = self._get_uniform_logits(batch_size, vocab_size) no_bad_words_dist_proc = NoBadWordsLogitsProcessor(bad_words_ids=bad_word_tokens, eos_token_id=eos_token_id) filtered_scores = no_bad_words_dist_proc(input_ids, scores.clone()) # batch 1: 1st, 2nd, and 4th (0, 1, 3) token are forbidden # batch 2: 1st, 2nd, and 3rd (0, 1, 2) token are forbidden # Note that 5th element cannot be forbidden as it is EOS token self.assertListEqual( torch.isinf(filtered_scores).tolist(), [[True, True, False, True, False], [True, True, True, False, False]] ) # check edge case no_bad_words_dist_proc = NoBadWordsLogitsProcessor(bad_words_ids=[[4]], eos_token_id=eos_token_id) filtered_scores = no_bad_words_dist_proc(input_ids, scores.clone()) self.assertTrue(torch.allclose(scores, filtered_scores, atol=1e-3)) def test_bias_dist_processor(self): vocab_size = 5 batch_size = 2 input_ids = torch.tensor([[0, 1, 3, 1], [0, 1, 0, 1]], device=torch_device, dtype=torch.long) positive_bias = {(1,): 100.0, (4,): 100.0} negative_bias = {(1, 0): -100.0, (0, 1, 2): -100.0, (1, 3, 1, 3): -100.0} # biases the same termination twice, to ensure we can handle overlapping terminations (it won't have an effect # on the test cases, though) negative_bias.update({(1, 3, 1, 3, 1, 3): -100.0}) sequence_bias = {**positive_bias, **negative_bias} # scores = 0 to facilitate checks scores = torch.zeros((batch_size, vocab_size), dtype=torch.float, device=torch_device) bias_dist_proc = SequenceBiasLogitsProcessor(sequence_bias=sequence_bias) filtered_scores = bias_dist_proc(input_ids, scores.clone()) # batch 1: positive bias: tokens (1, 4); negative bias: tokens (0, 3); neutral: tokens (2) # batch 2: positive bias: tokens (1, 4); negative bias: tokens (0, 2); neutral: tokens (3) self.assertListEqual( filtered_scores.tolist(), [[-100.0, 100.0, 0.0, -100.0, 100.0], [-100.0, 100.0, -100.0, 0.0, 100.0]] ) def test_processor_list(self): batch_size = 4 sequence_length = 10 vocab_size = 15 eos_token_id = 0 # dummy input_ids and scores input_ids = ids_tensor((batch_size, sequence_length), vocab_size) input_ids_comp = input_ids.clone() scores = self._get_uniform_logits(batch_size, vocab_size) scores_comp = scores.clone() # instantiate all dist processors min_dist_proc = MinLengthLogitsProcessor(min_length=10, eos_token_id=eos_token_id) temp_dist_warp = TemperatureLogitsWarper(temperature=0.5) rep_penalty_proc = RepetitionPenaltyLogitsProcessor(penalty=2.0) top_k_warp = TopKLogitsWarper(3) top_p_warp = TopPLogitsWarper(0.8) no_repeat_proc = NoRepeatNGramLogitsProcessor(2) no_bad_words_dist_proc = NoBadWordsLogitsProcessor(bad_words_ids=[[1]], eos_token_id=eos_token_id) # no processor list scores = min_dist_proc(input_ids, scores) scores = temp_dist_warp(input_ids, scores) scores = rep_penalty_proc(input_ids, scores) scores = top_k_warp(input_ids, scores) scores = top_p_warp(input_ids, scores) scores = no_repeat_proc(input_ids, scores) scores = no_bad_words_dist_proc(input_ids, scores) # with processor list processor = LogitsProcessorList( [ min_dist_proc, temp_dist_warp, rep_penalty_proc, top_k_warp, top_p_warp, no_repeat_proc, no_bad_words_dist_proc, ] ) scores_comp = processor(input_ids, scores_comp) # scores should be equal self.assertTrue(torch.allclose(scores, scores_comp, atol=1e-3)) # input_ids should never be changed self.assertListEqual(input_ids.tolist(), input_ids_comp.tolist()) def test_prefix_constrained_logits_processor(self): vocab_size = 5 batch_size = 2 input_ids = torch.tensor([[0, 1, 3, 1], [0, 1, 0, 1]], device=torch_device, dtype=torch.long) scores = self._get_uniform_logits(batch_size, vocab_size) def prefix_allowed_tokens_fn(batch_id, inputs_ids): return [[0, 1], [2, 3]][batch_id] prefix_constrained_logits_proc = PrefixConstrainedLogitsProcessor(prefix_allowed_tokens_fn, 1) filtered_scores = prefix_constrained_logits_proc(input_ids, scores.clone()) # batch 1: 1st, 2nd (0, 1) token are allowed # batch 2: 3rd, 4th (2, 3) token are allowed self.assertListEqual( torch.isinf(filtered_scores).tolist(), [[False, False, True, True, True], [True, True, False, False, True]] ) def test_hamming_diversity(self): vocab_size = 4 num_beams = 2 num_beam_groups = 2 scores = self._get_uniform_logits(num_beams, vocab_size) # batch_idx = 0 -> index batch_idx * num_beam_groups -> idx = 0 * 2 = 0 -> penalises tokens 1 # batch_idx = 1 -> index batch_idx * num_beam_groups -> idx = 1 * 2 = 2 -> penalises tokens 1 current_tokens = torch.tensor([0, 3, 1, 2], device=torch_device, dtype=torch.long) diversity_logits_processor = HammingDiversityLogitsProcessor( diversity_penalty=1.0, num_beams=num_beams, num_beam_groups=num_beam_groups ) processed_scores = diversity_logits_processor(None, scores, current_tokens, 1) self.assertTrue( torch.allclose( processed_scores[0], torch.tensor([-0.7500, 0.2500, 0.2500, 0.2500], device=torch_device), atol=1e-3 ) ) self.assertTrue( torch.allclose( processed_scores[1], torch.tensor([0.2500, -0.7500, 0.2500, 0.2500], device=torch_device), atol=1e-3 ) ) def test_forced_bos_token_logits_processor(self): vocab_size = 20 batch_size = 4 bos_token_id = 0 logits_processor = ForcedBOSTokenLogitsProcessor(bos_token_id=bos_token_id) # check that all scores are -inf except the bos_token_id score input_ids = ids_tensor((batch_size, 1), vocab_size=20) scores = self._get_uniform_logits(batch_size, vocab_size) scores = logits_processor(input_ids, scores) self.assertTrue(torch.isneginf(scores[:, bos_token_id + 1 :]).all()) self.assertListEqual(scores[:, bos_token_id].tolist(), 4 * [0]) # score for bos_token_id shold be zero # check that bos_token_id is not forced if current length is greater than 1 input_ids = ids_tensor((batch_size, 4), vocab_size=20) scores = self._get_uniform_logits(batch_size, vocab_size) scores = logits_processor(input_ids, scores) self.assertFalse(torch.isinf(scores).any()) def test_forced_eos_token_logits_processor(self): vocab_size = 20 batch_size = 4 eos_token_id = 0 max_length = 5 logits_processor = ForcedEOSTokenLogitsProcessor(max_length=max_length, eos_token_id=eos_token_id) # check that all scores are -inf except the eos_token_id when max_length-1 is reached input_ids = ids_tensor((batch_size, 4), vocab_size=20) scores = self._get_uniform_logits(batch_size, vocab_size) scores = logits_processor(input_ids, scores) self.assertTrue(torch.isneginf(scores[:, eos_token_id + 1 :]).all()) self.assertListEqual(scores[:, eos_token_id].tolist(), 4 * [0]) # score for eos_token_id should be zero # check that eos_token_id is not forced if max_length-1 is not reached input_ids = ids_tensor((batch_size, 3), vocab_size=20) scores = self._get_uniform_logits(batch_size, vocab_size) scores = logits_processor(input_ids, scores) self.assertFalse(torch.isinf(scores).any()) def test_remove_nan_inf_logits_processor(self): scores = torch.tensor( [[0.0, 0.7, 0.8, float("nan")], [0.1, float("inf"), 0.3, float("-inf")]], device=torch_device ) input_ids = ids_tensor((2, 4), vocab_size=20) logits_processor = InfNanRemoveLogitsProcessor() scores = logits_processor(input_ids, scores) self.assertTrue( torch.allclose( scores, torch.tensor( [[0.0, 0.7, 0.8, 0.0], [0.1, torch.finfo(scores.dtype).max, 0.3, float("-inf")]], device=torch_device, ), atol=1e-6, ) ) def test_exponential_decay_length_penalty(self): vocab_size = 20 batch_size = 4 eos_token_id = 0 penalty_start = 5 penalty_factor = 1.1 input_ids = ids_tensor((batch_size, 2), vocab_size=vocab_size) input_ids_seq_length = input_ids.shape[-1] length_decay_processor = ExponentialDecayLengthPenalty( exponential_decay_length_penalty=(penalty_start, penalty_factor), eos_token_id=eos_token_id, input_ids_seq_length=input_ids_seq_length, ) # check that penalty is not applied before start scores = self._get_uniform_logits(batch_size, vocab_size) scores_before_start = torch.clone(scores) # clone scores as precessor updates them inplace scores_before_start = length_decay_processor(input_ids, scores_before_start) self.assertListEqual(scores_before_start[:, eos_token_id].tolist(), scores[:, eos_token_id].tolist()) # check that penalty is applied after start input_ids = ids_tensor((batch_size, 20), vocab_size=vocab_size) scores = self._get_uniform_logits(batch_size, vocab_size) scores_after_start = torch.clone(scores) # clone scores as precessor updates them inplace scores_after_start = length_decay_processor(input_ids, scores_after_start) self.assertTrue(torch.gt(scores_after_start[:, eos_token_id], scores[:, eos_token_id]).all()) # check the penalty increases negative scores input_ids = ids_tensor((batch_size, 20), vocab_size=vocab_size) scores = torch.neg(self._get_uniform_logits(batch_size, vocab_size)) scores_after_start = torch.clone(scores) # clone scores as precessor updates them inplace scores_after_start = length_decay_processor(input_ids, scores_after_start) self.assertTrue(torch.gt(scores_after_start[:, eos_token_id], scores[:, eos_token_id]).all()) def test_normalization(self): input_ids = None scores = torch.tensor( [[-23.18, -29.96, -43.54, 47.77], [-33.58, -26.87, -32.96, 22.51]], device=torch_device, dtype=torch.float ) logit_normalization = LogitNormalization() normalized_scores = logit_normalization(input_ids, scores).exp() ones = torch.ones(scores.shape[0], device=torch_device, dtype=torch.float) self.assertTrue(normalized_scores.sum(dim=-1).allclose(ones)) self.assertTrue(normalized_scores.allclose(scores.softmax(dim=-1))) def test_classifier_free_guidance(self): class Namespace(dict): pass logits_uncond = torch.tensor([[[1.0, 0, 1.5]]]) logits_cond = torch.tensor([[[1.0, 1.0, 1.0]]]) def dummy_model(input_ids, attention_mask, use_cache=True, past_key_values=None): out = Namespace() out.logits = logits_uncond out.past_key_values = None return out def lsm(x): return torch.nn.functional.log_softmax(x, dim=-1) # explicit unconditional prompt + attention mask input_ids = torch.LongTensor([[0]]) cfg = UnbatchedClassifierFreeGuidanceLogitsProcessor( 1.5, dummy_model, input_ids, torch.ones_like(input_ids, dtype=torch.long) ) out = cfg(input_ids, logits_cond)[0, -1] res = (lsm(logits_uncond) + 1.5 * (lsm(logits_cond) - lsm(logits_uncond)))[0, -1] self.assertAlmostEqual(out[0].item(), res[0].item()) self.assertAlmostEqual(out[1].item(), res[1].item()) self.assertAlmostEqual(out[2].item(), res[2].item()) # explicit unconditional prompt input_ids = torch.LongTensor([[0]]) cfg = UnbatchedClassifierFreeGuidanceLogitsProcessor(1.5, dummy_model, input_ids) out = cfg(input_ids, logits_cond)[0, -1] res = (lsm(logits_uncond) + 1.5 * (lsm(logits_cond) - lsm(logits_uncond)))[0, -1] self.assertAlmostEqual(out[0].item(), res[0].item()) self.assertAlmostEqual(out[1].item(), res[1].item()) self.assertAlmostEqual(out[2].item(), res[2].item()) # all implicit input_ids = torch.LongTensor([[0]]) cfg = UnbatchedClassifierFreeGuidanceLogitsProcessor(1.5, dummy_model) out = cfg(input_ids, logits_cond)[0, -1] res = (lsm(logits_uncond) + 1.5 * (lsm(logits_cond) - lsm(logits_uncond)))[0, -1] self.assertAlmostEqual(out[0].item(), res[0].item()) self.assertAlmostEqual(out[1].item(), res[1].item()) self.assertAlmostEqual(out[2].item(), res[2].item())