# Copyright 2023 The TensorFlow Authors. All Rights Reserved. # # 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 copy 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. """Tests for BERT trainer network.""" from absl.testing import parameterized import tensorflow as tf, tf_keras from official.nlp.modeling import layers from official.nlp.modeling import networks from official.nlp.modeling.models import bert_classifier class BertClassifierTest(tf.test.TestCase, parameterized.TestCase): @parameterized.named_parameters(('single_cls', 1, False), ('3_cls', 3, False), ('3_cls_dictoutputs', 3, True)) def test_bert_trainer(self, num_classes, dict_outputs): """Validate that the Keras object can be created.""" # Build a transformer network to use within the BERT trainer. vocab_size = 100 sequence_length = 512 test_network = networks.BertEncoder( vocab_size=vocab_size, num_layers=2, dict_outputs=dict_outputs) # Create a BERT trainer with the created network. bert_trainer_model = bert_classifier.BertClassifier( test_network, num_classes=num_classes) # Create a set of 2-dimensional inputs (the first dimension is implicit). word_ids = tf_keras.Input(shape=(sequence_length,), dtype=tf.int32) mask = tf_keras.Input(shape=(sequence_length,), dtype=tf.int32) type_ids = tf_keras.Input(shape=(sequence_length,), dtype=tf.int32) # Invoke the trainer model on the inputs. This causes the layer to be built. cls_outs = bert_trainer_model([word_ids, mask, type_ids]) # Validate that the outputs are of the expected shape. expected_classification_shape = [None, num_classes] self.assertAllEqual(expected_classification_shape, cls_outs.shape.as_list()) @parameterized.named_parameters( ('single_cls', 1, False), ('2_cls', 2, False), ('single_cls_custom_head', 1, True), ('2_cls_custom_head', 2, True)) def test_bert_trainer_tensor_call(self, num_classes, use_custom_head): """Validate that the Keras object can be invoked.""" # Build a transformer network to use within the BERT trainer. (Here, we use # a short sequence_length for convenience.) test_network = networks.BertEncoder(vocab_size=100, num_layers=2) cls_head = layers.GaussianProcessClassificationHead( inner_dim=0, num_classes=num_classes) if use_custom_head else None # Create a BERT trainer with the created network. bert_trainer_model = bert_classifier.BertClassifier( test_network, num_classes=num_classes, cls_head=cls_head) # Create a set of 2-dimensional data tensors to feed into the model. word_ids = tf.constant([[1, 1], [2, 2]], dtype=tf.int32) mask = tf.constant([[1, 1], [1, 0]], dtype=tf.int32) type_ids = tf.constant([[1, 1], [2, 2]], dtype=tf.int32) # Invoke the trainer model on the tensors. In Eager mode, this does the # actual calculation. (We can't validate the outputs, since the network is # too complex: this simply ensures we're not hitting runtime errors.) _ = bert_trainer_model([word_ids, mask, type_ids]) @parameterized.named_parameters( ('default_cls_head', None), ('sngp_cls_head', layers.GaussianProcessClassificationHead( inner_dim=0, num_classes=4))) def test_serialize_deserialize(self, cls_head): """Validate that the BERT trainer can be serialized and deserialized.""" # Build a transformer network to use within the BERT trainer. test_network = networks.BertEncoder(vocab_size=100, num_layers=2) # Create a BERT trainer with the created network. (Note that all the args # are different, so we can catch any serialization mismatches.) bert_trainer_model = bert_classifier.BertClassifier( test_network, num_classes=4, initializer='zeros', cls_head=cls_head) # Create another BERT trainer via serialization and deserialization. config = bert_trainer_model.get_config() new_bert_trainer_model = bert_classifier.BertClassifier.from_config(config) # Validate that the config can be forced to JSON. _ = new_bert_trainer_model.to_json() # If the serialization was successful, the new config should match the old. self.assertAllEqual(bert_trainer_model.get_config(), new_bert_trainer_model.get_config()) if __name__ == '__main__': tf.test.main()