import statistics import unittest import numpy as np import torch from numpy.testing import assert_almost_equal from sentence_transformers import SentenceTransformer from sklearn.metrics.pairwise import cosine_similarity from .encoder_models import SBertEncoder, get_encoder from .semf1 import SemF1, _compute_cosine_similarity, _validate_input_format from .utils import get_gpu, slice_embeddings, is_nested_list_of_type, flatten_list, compute_f1, Scores class TestUtils(unittest.TestCase): def test_get_gpu(self): gpu_count = torch.cuda.device_count() gpu_available = torch.cuda.is_available() # Test single boolean input self.assertEqual(get_gpu(True), 0 if gpu_available else "cpu") self.assertEqual(get_gpu(False), "cpu") # Test single string input self.assertEqual(get_gpu("cpu"), "cpu") self.assertEqual(get_gpu("gpu"), 0 if gpu_available else "cpu") self.assertEqual(get_gpu("cuda"), 0 if gpu_available else "cpu") # Test single integer input self.assertEqual(get_gpu(0), 0 if gpu_available else "cpu") self.assertEqual(get_gpu(1), 1 if gpu_available else "cpu") # Test list input with unique elements self.assertEqual(get_gpu([True, "cpu", 0]), [0, "cpu"] if gpu_available else ["cpu", "cpu", "cpu"]) # Test list input with duplicate elements self.assertEqual(get_gpu([0, 0, "gpu"]), 0 if gpu_available else ["cpu", "cpu", "cpu"]) # Test list input with duplicate elements of different types self.assertEqual(get_gpu([True, 0, "gpu"]), 0 if gpu_available else ["cpu", "cpu", "cpu"]) # Test list input but only one element self.assertEqual(get_gpu([True]), 0 if gpu_available else "cpu") # Test list input with all integers self.assertEqual(get_gpu(list(range(gpu_count))), list(range(gpu_count)) if gpu_available else gpu_count * ["cpu"]) with self.assertRaises(ValueError): get_gpu("invalid") with self.assertRaises(ValueError): get_gpu(torch.cuda.device_count()) def test_slice_embeddings(self): embeddings = np.random.rand(10, 5) num_sentences = [3, 2, 5] expected_output = [embeddings[:3], embeddings[3:5], embeddings[5:]] self.assertTrue( all(np.array_equal(a, b) for a, b in zip(slice_embeddings(embeddings, num_sentences), expected_output)) ) num_sentences_nested = [[2, 1], [3, 4]] expected_output_nested = [[embeddings[:2], embeddings[2:3]], [embeddings[3:6], embeddings[6:]]] self.assertTrue( slice_embeddings(embeddings, num_sentences_nested), expected_output_nested ) with self.assertRaises(TypeError): slice_embeddings(embeddings, "invalid") def test_is_nested_list_of_type(self): # Test case: Depth 0, single element matching element_type self.assertEqual(is_nested_list_of_type("test", str, 0), (True, "")) # Test case: Depth 0, single element not matching element_type is_valid, err_msg = is_nested_list_of_type("test", int, 0) self.assertEqual(is_valid, False) # Test case: Depth 1, list of elements matching element_type self.assertEqual(is_nested_list_of_type(["apple", "banana"], str, 1), (True, "")) # Test case: Depth 1, list of elements not matching element_type is_valid, err_msg = is_nested_list_of_type([1, 2, 3], str, 1) self.assertEqual(is_valid, False) # Test case: Depth 0 (Wrong), list of elements matching element_type is_valid, err_msg = is_nested_list_of_type([1, 2, 3], str, 0) self.assertEqual(is_valid, False) # Depth 2 self.assertEqual(is_nested_list_of_type([[1, 2], [3, 4]], int, 2), (True, "")) self.assertEqual(is_nested_list_of_type([['1', '2'], ['3', '4']], str, 2), (True, "")) is_valid, err_msg = is_nested_list_of_type([[1, 2], ["a", "b"]], int, 2) self.assertEqual(is_valid, False) # Depth 3 is_valid, err_msg = is_nested_list_of_type([[[1], [2]], [[3], [4]]], list, 3) self.assertEqual(is_valid, False) self.assertEqual(is_nested_list_of_type([[[1], [2]], [[3], [4]]], int, 3), (True, "")) # Test case: Depth is negative, expecting ValueError with self.assertRaises(ValueError): is_nested_list_of_type([1, 2], int, -1) def test_flatten_list(self): self.assertEqual(flatten_list([1, [2, 3], [[4], 5]]), [1, 2, 3, 4, 5]) self.assertEqual(flatten_list([]), []) self.assertEqual(flatten_list([1, 2, 3]), [1, 2, 3]) self.assertEqual(flatten_list([[[[1]]]]), [1]) def test_compute_f1(self): self.assertAlmostEqual(compute_f1(0.5, 0.5), 0.5) self.assertAlmostEqual(compute_f1(1, 0), 0.0) self.assertAlmostEqual(compute_f1(0, 1), 0.0) self.assertAlmostEqual(compute_f1(1, 1), 1.0) def test_scores(self): scores = Scores(precision=0.8, recall=[0.7, 0.9]) self.assertAlmostEqual(scores.f1, compute_f1(0.8, statistics.fmean([0.7, 0.9]))) class TestSBertEncoder(unittest.TestCase): def setUp(self, device=None): if device is None: self.device = torch.device("cuda" if torch.cuda.is_available() else "cpu") else: self.device = device self.model_name = "stsb-roberta-large" self.batch_size = 8 self.verbose = False self.encoder = SBertEncoder(self.model_name, self.device, self.batch_size, self.verbose) def test_initialization(self): self.assertIsInstance(self.encoder.model, SentenceTransformer) self.assertEqual(self.encoder.device, self.device) self.assertEqual(self.encoder.batch_size, self.batch_size) self.assertEqual(self.encoder.verbose, self.verbose) def test_encode_single_device(self): sentences = ["This is a test sentence.", "Here is another sentence."] embeddings = self.encoder.encode(sentences) self.assertIsInstance(embeddings, np.ndarray) self.assertEqual(embeddings.shape[0], len(sentences)) self.assertEqual(embeddings.shape[1], self.encoder.model.get_sentence_embedding_dimension()) def test_encode_multi_device(self): if torch.cuda.device_count() < 2: self.skipTest("Multi-GPU test requires at least 2 GPUs.") else: devices = ["cuda:0", "cuda:1"] self.setUp(devices) sentences = ["This is a test sentence.", "Here is another sentence.", "This is a test sentence."] embeddings = self.encoder.encode(sentences) self.assertIsInstance(embeddings, np.ndarray) self.assertEqual(embeddings.shape[0], 3) self.assertEqual(embeddings.shape[1], self.encoder.model.get_sentence_embedding_dimension()) class TestGetEncoder(unittest.TestCase): def setUp(self): self.device = "cuda" if torch.cuda.is_available() else "cpu" self.batch_size = 8 self.verbose = False def _base_test(self, model_name): encoder = get_encoder(model_name, self.device, self.batch_size, self.verbose) # Assert self.assertIsInstance(encoder, SBertEncoder) self.assertEqual(encoder.device, self.device) self.assertEqual(encoder.batch_size, self.batch_size) self.assertEqual(encoder.verbose, self.verbose) def test_get_sbert_encoder(self): model_name = "stsb-roberta-large" self._base_test(model_name) def test_sbert_model(self): model_name = "all-mpnet-base-v2" self._base_test(model_name) def test_huggingface_model(self): """Test Huggingface models which work with SBert library""" model_name = "roberta-base" self._base_test(model_name) def test_get_encoder_environment_error(self): # This parameter is used when using patch decorator model_name = "abc" # Wrong model_name with self.assertRaises(EnvironmentError): get_encoder(model_name, self.device, self.batch_size, self.verbose) def test_get_encoder_other_exception(self): model_name = "apple/OpenELM-270M" # This model is not supported by SentenceTransformer lib with self.assertRaises(RuntimeError): get_encoder(model_name, self.device, self.batch_size, self.verbose) class TestSemF1(unittest.TestCase): def setUp(self): self.semf1_metric = SemF1() # semf1_metric # Example cases, #Samples = 1 self.untokenized_single_reference_predictions = [ "This is a prediction sentence 1. This is a prediction sentence 2."] self.untokenized_single_reference_references = [ "This is a reference sentence 1. This is a reference sentence 2."] self.tokenized_single_reference_predictions = [ ["This is a prediction sentence 1.", "This is a prediction sentence 2."], ] self.tokenized_single_reference_references = [ ["This is a reference sentence 1.", "This is a reference sentence 2."], ] self.untokenized_multi_reference_predictions = [ "Prediction sentence 1. Prediction sentence 2." ] self.untokenized_multi_reference_references = [ ["Reference sentence 1. Reference sentence 2.", "Alternative reference 1. Alternative reference 2."], ] self.tokenized_multi_reference_predictions = [ ["Prediction sentence 1.", "Prediction sentence 2."], ] self.tokenized_multi_reference_references = [ [ ["Reference sentence 1.", "Reference sentence 2."], ["Alternative reference 1.", "Alternative reference 2."] ], ] def test_untokenized_single_reference(self): scores = self.semf1_metric.compute( predictions=self.untokenized_single_reference_predictions, references=self.untokenized_single_reference_references, tokenize_sentences=True, multi_references=False, gpu=False, batch_size=32, verbose=False ) self.assertIsInstance(scores, list) self.assertEqual(len(scores), len(self.untokenized_single_reference_predictions)) def test_tokenized_single_reference(self): scores = self.semf1_metric.compute( predictions=self.tokenized_single_reference_predictions, references=self.tokenized_single_reference_references, tokenize_sentences=False, multi_references=False, gpu=False, batch_size=32, verbose=False ) self.assertIsInstance(scores, list) self.assertEqual(len(scores), len(self.tokenized_single_reference_predictions)) for score in scores: self.assertIsInstance(score, Scores) self.assertTrue(0.0 <= score.precision <= 1.0) self.assertTrue(all(0.0 <= recall <= 1.0 for recall in score.recall)) def test_untokenized_multi_reference(self): scores = self.semf1_metric.compute( predictions=self.untokenized_multi_reference_predictions, references=self.untokenized_multi_reference_references, tokenize_sentences=True, multi_references=True, gpu=False, batch_size=32, verbose=False ) self.assertIsInstance(scores, list) self.assertEqual(len(scores), len(self.untokenized_multi_reference_predictions)) def test_tokenized_multi_reference(self): scores = self.semf1_metric.compute( predictions=self.tokenized_multi_reference_predictions, references=self.tokenized_multi_reference_references, tokenize_sentences=False, multi_references=True, gpu=False, batch_size=32, verbose=False ) self.assertIsInstance(scores, list) self.assertEqual(len(scores), len(self.tokenized_multi_reference_predictions)) for score in scores: self.assertIsInstance(score, Scores) self.assertTrue(0.0 <= score.precision <= 1.0) self.assertTrue(all(0.0 <= recall <= 1.0 for recall in score.recall)) def test_same_predictions_and_references(self): scores = self.semf1_metric.compute( predictions=self.tokenized_single_reference_predictions, references=self.tokenized_single_reference_predictions, tokenize_sentences=False, multi_references=False, gpu=False, batch_size=32, verbose=False ) self.assertIsInstance(scores, list) self.assertEqual(len(scores), len(self.tokenized_single_reference_predictions)) for score in scores: self.assertIsInstance(score, Scores) self.assertAlmostEqual(score.precision, 1.0, places=6) assert_almost_equal(score.recall, 1, decimal=5, err_msg="Not all values are almost equal to 1") def test_exact_output_scores(self): predictions = [ ["I go to School.", "You are stupid."], ["I love adventure sports."], ] references = [ ["I go to playground.", "You are genius.", "You need to be admired."], ["I love adventure sports."], ] scores = self.semf1_metric.compute( predictions=predictions, references=references, tokenize_sentences=False, multi_references=False, gpu=False, batch_size=32, verbose=False, model_type="use", ) self.assertIsInstance(scores, list) self.assertEqual(len(scores), len(predictions)) score = scores[0] self.assertIsInstance(score, Scores) self.assertAlmostEqual(score.precision, 0.73, places=2) self.assertAlmostEqual(score.recall[0], 0.63, places=2) def test_none_input(self): def _call_metric(preds, refs, tok, mul_ref): with self.assertRaises(Exception) as ctx: _ = self.semf1_metric.compute( predictions=preds, references=refs, tokenize_sentences=tok, multi_references=mul_ref, gpu=False, batch_size=32, verbose=False, model_type="use", ) print(f"Raised Exception with message: {ctx.exception}") return "" # # Case 1: tokenize_sentences = True, multi_references = True tokenize_sentences = True multi_references = True predictions = [ "I go to School. You are stupid.", "I go to School. You are stupid.", ] references = [ ["I am", "I am"], [None, "I am"], ] print(f"Case I\n{_call_metric(predictions, references, tokenize_sentences, multi_references)}\n") # Case 2: tokenize_sentences = False, multi_references = True tokenize_sentences = False multi_references = True predictions = [ ["I go to School.", "You are stupid."], ["I go to School.", "You are stupid."], ] references = [ [["I am", "I am"], [None, "I am"]], [[None, "I am"]], ] print(f"Case II\n{_call_metric(predictions, references, tokenize_sentences, multi_references)}\n") # Case 3: tokenize_sentences = True, multi_references = False tokenize_sentences = True multi_references = False predictions = [ None, "I go to School. You are stupid.", ] references = [ "I am. I am.", "I am. I am.", ] print(f"Case III\n{_call_metric(predictions, references, tokenize_sentences, multi_references)}\n") # Case 4: tokenize_sentences = False, multi_references = False # This is taken care by the library itself tokenize_sentences = False multi_references = False predictions = [ ["I go to School.", None], ["I go to School.", "You are stupid."], ] references = [ ["I am.", "I am."], ["I am.", "I am."], ] print(f"Case IV\n{_call_metric(predictions, references, tokenize_sentences, multi_references)}\n") def test_empty_input(self): predictions = ["", ""] references = ["I go to School. You are stupid.", "I am"] scores = self.semf1_metric.compute( predictions=predictions, references=references, ) print(scores) # # Test with Gibberish Cases # predictions = ["lth cgezawrxretxdr", "dsfgsdfhsdfh"] # references = ["dzfgzeWfnAfse", "dtjsrtzerZJSEWr"] # scores = self.semf1_metric.compute( # predictions=predictions, # references=references, # ) # print(scores) class TestCosineSimilarity(unittest.TestCase): def setUp(self): # Sample embeddings for testing self.pred_embeds = np.array([ [1, 0, 0], [0, 1, 0], [0, 0, 1] ]) self.ref_embeds = np.array([ [1, 0, 0], [0, 1, 0], [0, 0, 1] ]) self.pred_embeds_random = np.random.rand(3, 3) self.ref_embeds_random = np.random.rand(3, 3) def test_cosine_similarity_perfect_match(self): precision, recall = _compute_cosine_similarity(self.pred_embeds, self.ref_embeds) # Expected values are 1.0 for both precision and recall since embeddings are identical self.assertAlmostEqual(precision, 1.0, places=5) self.assertAlmostEqual(recall, 1.0, places=5) def _test_cosine_similarity_base(self, pred_embeds, ref_embeds): precision, recall = _compute_cosine_similarity(pred_embeds, ref_embeds) # Calculate expected precision and recall using sklearn's cosine similarity function cosine_scores = cosine_similarity(pred_embeds, ref_embeds) expected_precision = np.mean(np.max(cosine_scores, axis=-1)).item() expected_recall = np.mean(np.max(cosine_scores, axis=0)).item() self.assertAlmostEqual(precision, expected_precision, places=5) self.assertAlmostEqual(recall, expected_recall, places=5) def test_cosine_similarity_random(self): self._test_cosine_similarity_base(self.pred_embeds_random, self.ref_embeds_random) def test_cosine_similarity_different_shapes(self): pred_embeds_diff = np.random.rand(5, 3) ref_embeds_diff = np.random.rand(3, 3) self._test_cosine_similarity_base(pred_embeds_diff, ref_embeds_diff) class TestValidateInputFormat(unittest.TestCase): def setUp(self): # Sample predictions and references for different scenarios where number of samples = 1 # Note: Naming Convention: # When tokenize_sentences = True (i.e. input is untokenized) and vice-versa # When tokenize_sentences = True (untokenized input) and multi_references = False self.untokenized_single_reference_predictions = [ "This is a prediction sentence 1. This is a prediction sentence 2." ] self.untokenized_single_reference_references = [ "This is a reference sentence 1. This is a reference sentence 2." ] # When tokenize_sentences = False (tokenized input) and multi_references = False self.tokenized_single_reference_predictions = [ ["This is a prediction sentence 1.", "This is a prediction sentence 2."] ] self.tokenized_single_reference_references = [ ["This is a reference sentence 1.", "This is a reference sentence 2."] ] # When tokenize_sentences = True (untokenized input) and multi_references = True self.untokenized_multi_reference_predictions = [ "This is a prediction sentence 1. This is a prediction sentence 2." ] self.untokenized_multi_reference_references = [ [ "This is a reference sentence 1. This is a reference sentence 2.", "Another reference sentence." ] ] # When tokenize_sentences = False (tokenized input) and multi_references = True self.tokenized_multi_reference_predictions = [ ["This is a prediction sentence 1.", "This is a prediction sentence 2."] ] self.tokenized_multi_reference_references = [ [ ["This is a reference sentence 1.", "This is a reference sentence 2."], ["Another reference sentence."] ] ] def test_tokenized_sentences_true_multi_references_true(self): # Invalid format should raise an error with self.assertRaises(ValueError): _validate_input_format( True, True, self.tokenized_single_reference_predictions, self.tokenized_single_reference_references, ) # Valid format should pass without error _validate_input_format( True, True, self.untokenized_multi_reference_predictions, self.untokenized_multi_reference_references, ) def test_tokenized_sentences_false_multi_references_true(self): # Invalid format should raise an error with self.assertRaises(ValueError): _validate_input_format( False, True, self.untokenized_single_reference_predictions, self.untokenized_multi_reference_references, ) # Valid format should pass without error _validate_input_format( False, True, self.tokenized_multi_reference_predictions, self.tokenized_multi_reference_references, ) def test_tokenized_sentences_true_multi_references_false(self): # Invalid format should raise an error with self.assertRaises(ValueError): _validate_input_format( True, False, self.tokenized_single_reference_predictions, self.tokenized_single_reference_references, ) # Valid format should pass without error _validate_input_format( True, False, self.untokenized_single_reference_predictions, self.untokenized_single_reference_references, ) def test_tokenized_sentences_false_multi_references_false(self): # Invalid format should raise an error with self.assertRaises(ValueError): _validate_input_format( False, False, self.untokenized_single_reference_predictions, self.untokenized_single_reference_references, ) # Valid format should pass without error _validate_input_format( False, False, self.tokenized_single_reference_predictions, self.tokenized_single_reference_references, ) def test_mismatched_lengths(self): # Length mismatch should raise an error with self.assertRaises(ValueError): _validate_input_format( True, True, self.untokenized_single_reference_predictions, [self.untokenized_single_reference_predictions[0], self.untokenized_single_reference_predictions[0]], ) if __name__ == '__main__': unittest.main(verbosity=2)