# Copyright 2025 The Scenic Authors. # # 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. """Unit tests for encoder_decoder_model.py.""" from absl.testing import absltest from flax import jax_utils import jax import jax.numpy as jnp import ml_collections import numpy as np from scenic.model_lib.base_models import encoder_decoder_model VOCAB_SIZE = 4_000 TARGET_LENGTH = 32 BATCH_SIZE = 4 class FakeEncoderDecoderModel(encoder_decoder_model.EncoderDecoderModel): """A dummy encoder-decoder model for testing purposes.""" def __init__(self): dataset_meta_data = {'num_classes': VOCAB_SIZE, 'target_is_onehot': False} super().__init__( ml_collections.ConfigDict(), # An empty config dict. dataset_meta_data) def build_flax_model(self): pass def default_flax_model_config(self): pass def get_fake_batch_output(): """Generates a fake `batch`. Returns: `batch`: Dictionary of None inputs and fake ground truth targets. outputs_noaux.pop('aux_outputs') `output`: Dictionary of a fake output logits. """ batch = { 'inputs': None, 'label': jnp.array( np.random.randint(VOCAB_SIZE, size=(BATCH_SIZE, TARGET_LENGTH))), } output = np.random.random(size=(BATCH_SIZE, TARGET_LENGTH, VOCAB_SIZE)) return batch, output class TestEncoderDecoderModel(absltest.TestCase): """Tests for the EncoderDecoderModel.""" def is_valid(self, t, value_name): """Helper function to assert that tensor `t` does not have `nan`, `inf`.""" self.assertFalse( jnp.isnan(t).any(), msg=f'Found nan\'s in {t} for {value_name}') self.assertFalse( jnp.isinf(t).any(), msg=f'Found inf\'s in {t} for {value_name}') def test_loss_function(self): """Tests loss_function by checking its output's validity.""" model = FakeEncoderDecoderModel() batch, output = get_fake_batch_output() batch_replicated, outputs_replicated = (jax_utils.replicate(batch), jax_utils.replicate(output)) # Test loss function in the pmapped setup: loss_function_pmapped = jax.pmap(model.loss_function, axis_name='batch') total_loss = loss_function_pmapped(outputs_replicated, batch_replicated) # Check that loss is returning valid values: self.is_valid(jax_utils.unreplicate(total_loss), value_name='loss') def test_metric_function(self): """Tests metric_function by checking its output's format and validity.""" model = FakeEncoderDecoderModel() batch, output = get_fake_batch_output() batch_replicated, outputs_replicated = (jax_utils.replicate(batch), jax_utils.replicate(output)) # Test metric function in the pmapped setup metrics_fn_pmapped = jax.pmap(model.get_metrics_fn(), axis_name='batch') all_metrics = metrics_fn_pmapped(outputs_replicated, batch_replicated) # Check expected metrics exist in the output: expected_metrics_keys = ['accuracy', 'loss', 'perplexity'] self.assertSameElements(expected_metrics_keys, all_metrics.keys()) # For each metric, check that it is a valid value. all_metrics = jax_utils.unreplicate(all_metrics) for k, v in all_metrics.items(): self.is_valid(v[0], value_name=f'numerator of {k}') self.is_valid(v[1], value_name=f'denominator of {k}') if __name__ == '__main__': absltest.main()