# coding=utf-8 # Copyright 2024 The HuggingFace Inc. team. 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. """Testing suite for the PyTorch Dac model.""" import inspect import os import tempfile import unittest from typing import Dict, List, Tuple import numpy as np from datasets import Audio, load_dataset from transformers import AutoProcessor, DacConfig, DacModel from transformers.testing_utils import is_torch_available, require_torch, slow, torch_device from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, _config_zero_init, floats_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch @require_torch # Copied from transformers.tests.encodec.test_modeling_encodec.EncodecModelTester with Encodec->Dac class DacModelTester: # Ignore copy def __init__( self, parent, batch_size=3, num_channels=1, is_training=False, intermediate_size=1024, encoder_hidden_size=16, downsampling_ratios=[2, 4, 4], decoder_hidden_size=16, n_codebooks=6, codebook_size=512, codebook_dim=4, quantizer_dropout=0.0, commitment_loss_weight=0.25, codebook_loss_weight=1.0, sample_rate=16000, ): self.parent = parent self.batch_size = batch_size self.num_channels = num_channels self.is_training = is_training self.intermediate_size = intermediate_size self.sample_rate = sample_rate self.encoder_hidden_size = encoder_hidden_size self.downsampling_ratios = downsampling_ratios self.decoder_hidden_size = decoder_hidden_size self.n_codebooks = n_codebooks self.codebook_size = codebook_size self.codebook_dim = codebook_dim self.quantizer_dropout = quantizer_dropout self.commitment_loss_weight = commitment_loss_weight self.codebook_loss_weight = codebook_loss_weight def prepare_config_and_inputs(self): input_values = floats_tensor([self.batch_size, self.num_channels, self.intermediate_size], scale=1.0) config = self.get_config() inputs_dict = {"input_values": input_values} return config, inputs_dict def prepare_config_and_inputs_for_common(self): config, inputs_dict = self.prepare_config_and_inputs() return config, inputs_dict def prepare_config_and_inputs_for_model_class(self, model_class): input_values = floats_tensor([self.batch_size, self.num_channels, self.intermediate_size], scale=1.0) config = self.get_config() inputs_dict = {"input_values": input_values} return config, inputs_dict # Ignore copy def get_config(self): return DacConfig( encoder_hidden_size=self.encoder_hidden_size, downsampling_ratios=self.downsampling_ratios, decoder_hidden_size=self.decoder_hidden_size, n_codebooks=self.n_codebooks, codebook_size=self.codebook_size, codebook_dim=self.codebook_dim, quantizer_dropout=self.quantizer_dropout, commitment_loss_weight=self.commitment_loss_weight, codebook_loss_weight=self.codebook_loss_weight, ) # Ignore copy def create_and_check_model_forward(self, config, inputs_dict): model = DacModel(config=config).to(torch_device).eval() input_values = inputs_dict["input_values"] result = model(input_values) self.parent.assertEqual(result.audio_values.shape, (self.batch_size, self.intermediate_size)) @require_torch # Copied from transformers.tests.encodec.test_modeling_encodec.EncodecModelTest with Encodec->Dac class DacModelTest(ModelTesterMixin, PipelineTesterMixin, unittest.TestCase): all_model_classes = (DacModel,) if is_torch_available() else () is_encoder_decoder = True test_pruning = False test_headmasking = False test_resize_embeddings = False pipeline_model_mapping = {"feature-extraction": DacModel} if is_torch_available() else {} def _prepare_for_class(self, inputs_dict, model_class, return_labels=False): # model does not have attention and does not support returning hidden states inputs_dict = super()._prepare_for_class(inputs_dict, model_class, return_labels=return_labels) if "output_attentions" in inputs_dict: inputs_dict.pop("output_attentions") if "output_hidden_states" in inputs_dict: inputs_dict.pop("output_hidden_states") return inputs_dict def setUp(self): self.model_tester = DacModelTester(self) self.config_tester = ConfigTester( self, config_class=DacConfig, hidden_size=37, common_properties=[], has_text_modality=False ) def test_config(self): self.config_tester.run_common_tests() def test_model_forward(self): config_and_inputs = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model_forward(*config_and_inputs) def test_forward_signature(self): config, _ = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: model = model_class(config) signature = inspect.signature(model.forward) # signature.parameters is an OrderedDict => so arg_names order is deterministic arg_names = [*signature.parameters.keys()] # Ignore copy expected_arg_names = ["input_values", "n_quantizers", "return_dict"] self.assertListEqual(arg_names[: len(expected_arg_names)], expected_arg_names) @unittest.skip("The DacModel is not transformers based, thus it does not have `inputs_embeds` logics") def test_inputs_embeds(self): pass @unittest.skip("The DacModel is not transformers based, thus it does not have `inputs_embeds` logics") def test_model_get_set_embeddings(self): pass @unittest.skip("The DacModel is not transformers based, thus it does not have the usual `attention` logic") def test_retain_grad_hidden_states_attentions(self): pass @unittest.skip("The DacModel is not transformers based, thus it does not have the usual `attention` logic") def test_torchscript_output_attentions(self): pass @unittest.skip("The DacModel is not transformers based, thus it does not have the usual `hidden_states` logic") def test_torchscript_output_hidden_state(self): pass def _create_and_check_torchscript(self, config, inputs_dict): if not self.test_torchscript: return configs_no_init = _config_zero_init(config) # To be sure we have no Nan configs_no_init.torchscript = True configs_no_init.return_dict = False for model_class in self.all_model_classes: model = model_class(config=configs_no_init) model.to(torch_device) model.eval() inputs = self._prepare_for_class(inputs_dict, model_class) main_input_name = model_class.main_input_name try: main_input = inputs[main_input_name] model(main_input) traced_model = torch.jit.trace(model, main_input) except RuntimeError: self.fail("Couldn't trace module.") with tempfile.TemporaryDirectory() as tmp_dir_name: pt_file_name = os.path.join(tmp_dir_name, "traced_model.pt") try: torch.jit.save(traced_model, pt_file_name) except Exception: self.fail("Couldn't save module.") try: loaded_model = torch.jit.load(pt_file_name) except Exception: self.fail("Couldn't load module.") model.to(torch_device) model.eval() loaded_model.to(torch_device) loaded_model.eval() model_state_dict = model.state_dict() loaded_model_state_dict = loaded_model.state_dict() non_persistent_buffers = {} for key in loaded_model_state_dict.keys(): if key not in model_state_dict.keys(): non_persistent_buffers[key] = loaded_model_state_dict[key] loaded_model_state_dict = { key: value for key, value in loaded_model_state_dict.items() if key not in non_persistent_buffers } self.assertEqual(set(model_state_dict.keys()), set(loaded_model_state_dict.keys())) model_buffers = list(model.buffers()) for non_persistent_buffer in non_persistent_buffers.values(): found_buffer = False for i, model_buffer in enumerate(model_buffers): if torch.equal(non_persistent_buffer, model_buffer): found_buffer = True break self.assertTrue(found_buffer) model_buffers.pop(i) model_buffers = list(model.buffers()) for non_persistent_buffer in non_persistent_buffers.values(): found_buffer = False for i, model_buffer in enumerate(model_buffers): if torch.equal(non_persistent_buffer, model_buffer): found_buffer = True break self.assertTrue(found_buffer) model_buffers.pop(i) models_equal = True for layer_name, p1 in model_state_dict.items(): if layer_name in loaded_model_state_dict: p2 = loaded_model_state_dict[layer_name] if p1.data.ne(p2.data).sum() > 0: models_equal = False self.assertTrue(models_equal) # Avoid memory leak. Without this, each call increase RAM usage by ~20MB. # (Even with this call, there are still memory leak by ~0.04MB) self.clear_torch_jit_class_registry() @unittest.skip("The DacModel is not transformers based, thus it does not have the usual `attention` logic") def test_attention_outputs(self): pass @unittest.skip("The DacModel is not transformers based, thus it does not have the usual `hidden_states` logic") def test_hidden_states_output(self): pass @unittest.skip("No support for low_cpu_mem_usage=True.") def test_save_load_low_cpu_mem_usage(self): pass @unittest.skip("No support for low_cpu_mem_usage=True.") def test_save_load_low_cpu_mem_usage_checkpoints(self): pass @unittest.skip("No support for low_cpu_mem_usage=True.") def test_save_load_low_cpu_mem_usage_no_safetensors(self): pass def test_determinism(self): config, inputs_dict = self.model_tester.prepare_config_and_inputs_for_common() def check_determinism(first, second): # outputs are not tensors but list (since each sequence don't have the same frame_length) out_1 = first.cpu().numpy() out_2 = second.cpu().numpy() out_1 = out_1[~np.isnan(out_1)] out_2 = out_2[~np.isnan(out_2)] max_diff = np.amax(np.abs(out_1 - out_2)) self.assertLessEqual(max_diff, 1e-5) for model_class in self.all_model_classes: model = model_class(config) model.to(torch_device) model.eval() with torch.no_grad(): first = model(**self._prepare_for_class(inputs_dict, model_class))[0] second = model(**self._prepare_for_class(inputs_dict, model_class))[0] if isinstance(first, tuple) and isinstance(second, tuple): for tensor1, tensor2 in zip(first, second): check_determinism(tensor1, tensor2) else: check_determinism(first, second) def test_model_outputs_equivalence(self): config, inputs_dict = self.model_tester.prepare_config_and_inputs_for_common() def set_nan_tensor_to_zero(t): t[t != t] = 0 return t def check_equivalence(model, tuple_inputs, dict_inputs, additional_kwargs={}): with torch.no_grad(): tuple_output = model(**tuple_inputs, return_dict=False, **additional_kwargs) dict_output = model(**dict_inputs, return_dict=True, **additional_kwargs).to_tuple() def recursive_check(tuple_object, dict_object): if isinstance(tuple_object, (List, Tuple)): for tuple_iterable_value, dict_iterable_value in zip(tuple_object, dict_object): recursive_check(tuple_iterable_value, dict_iterable_value) elif isinstance(tuple_object, Dict): for tuple_iterable_value, dict_iterable_value in zip( tuple_object.values(), dict_object.values() ): recursive_check(tuple_iterable_value, dict_iterable_value) elif tuple_object is None: return else: self.assertTrue( torch.allclose( set_nan_tensor_to_zero(tuple_object), set_nan_tensor_to_zero(dict_object), atol=1e-5 ), msg=( "Tuple and dict output are not equal. Difference:" f" {torch.max(torch.abs(tuple_object - dict_object))}. Tuple has `nan`:" f" {torch.isnan(tuple_object).any()} and `inf`: {torch.isinf(tuple_object)}. Dict has" f" `nan`: {torch.isnan(dict_object).any()} and `inf`: {torch.isinf(dict_object)}." ), ) recursive_check(tuple_output, dict_output) for model_class in self.all_model_classes: model = model_class(config) model.to(torch_device) model.eval() tuple_inputs = self._prepare_for_class(inputs_dict, model_class) dict_inputs = self._prepare_for_class(inputs_dict, model_class) check_equivalence(model, tuple_inputs, dict_inputs) # Ignore copy def test_initialization(self): config, inputs_dict = self.model_tester.prepare_config_and_inputs_for_common() configs_no_init = _config_zero_init(config) for model_class in self.all_model_classes: model = model_class(config=configs_no_init) for name, param in model.named_parameters(): uniform_init_parms = ["conv", "in_proj", "out_proj", "codebook"] if param.requires_grad: if any(x in name for x in uniform_init_parms): self.assertTrue( -1.0 <= ((param.data.mean() * 1e9).round() / 1e9).item() <= 1.0, msg=f"Parameter {name} of model {model_class} seems not properly initialized", ) def test_identity_shortcut(self): config, inputs_dict = self.model_tester.prepare_config_and_inputs() config.use_conv_shortcut = False self.model_tester.create_and_check_model_forward(config, inputs_dict) def normalize(arr): norm = np.linalg.norm(arr) normalized_arr = arr / norm return normalized_arr def compute_rmse(arr1, arr2): arr1_normalized = normalize(arr1) arr2_normalized = normalize(arr2) return np.sqrt(((arr1_normalized - arr2_normalized) ** 2).mean()) @slow @require_torch class DacIntegrationTest(unittest.TestCase): def test_integration_16khz(self): expected_rmse = 0.004 expected_encoder_sums_dict = { "loss": 24.8596, "quantized_representation": -0.0745, "audio_codes": 504.0948, "projected_latents": 0.0682, } librispeech_dummy = load_dataset("hf-internal-testing/librispeech_asr_dummy", "clean", split="validation") model_name = "dac_16khz" model_id = "descript/{}".format(model_name) model = DacModel.from_pretrained(model_id, force_download=True).to(torch_device).eval() processor = AutoProcessor.from_pretrained(model_id) librispeech_dummy = librispeech_dummy.cast_column("audio", Audio(sampling_rate=processor.sampling_rate)) audio_sample = librispeech_dummy[0]["audio"]["array"] inputs = processor( raw_audio=audio_sample, sampling_rate=processor.sampling_rate, return_tensors="pt", ).to(torch_device) with torch.no_grad(): encoder_outputs = model.encode(inputs["input_values"]) expected_encoder_sums = torch.tensor(list(expected_encoder_sums_dict.values()), dtype=torch.float32) encoder_outputs_mean = torch.tensor([v.float().mean().cpu().item() for v in encoder_outputs.to_tuple()]) # make sure audio encoded codes are correct self.assertTrue(torch.allclose(encoder_outputs_mean, expected_encoder_sums, atol=1e-3)) _, quantized_representation, _, _ = encoder_outputs.to_tuple() input_values_dec = model.decode(quantized_representation)[0] input_values_enc_dec = model(inputs["input_values"])[1] # make sure forward and decode gives same result self.assertTrue(torch.allclose(input_values_dec, input_values_enc_dec, atol=1e-3)) arr = inputs["input_values"][0].cpu().numpy() arr_enc_dec = input_values_enc_dec[0].cpu().numpy() max_length = min(arr_enc_dec.shape[-1], arr.shape[-1]) arr_cut = arr[0, :max_length].copy() arr_enc_dec_cut = arr_enc_dec[:max_length].copy() # make sure audios are more or less equal rmse = compute_rmse(arr_cut, arr_enc_dec_cut) self.assertTrue(rmse < expected_rmse) def test_integration_24khz(self): expected_rmse = 0.0039 expected_encoder_output_dict = { "quantized_representation": torch.tensor([0.9807, 2.8212, 5.2514, 2.7241, 1.0426]), "audio_codes": torch.tensor([919, 919, 234, 777, 234]), "projected_latents": torch.tensor([-4.7822, -5.0046, -4.5574, -5.0363, -5.4271]), } librispeech_dummy = load_dataset("hf-internal-testing/librispeech_asr_dummy", "clean", split="validation") model_name = "dac_24khz" model_id = "descript/{}".format(model_name) model = DacModel.from_pretrained(model_id, force_download=True).to(torch_device).eval() processor = AutoProcessor.from_pretrained(model_id) librispeech_dummy = librispeech_dummy.cast_column("audio", Audio(sampling_rate=processor.sampling_rate)) audio_sample = librispeech_dummy[0]["audio"]["array"] inputs = processor( raw_audio=audio_sample, sampling_rate=processor.sampling_rate, return_tensors="pt", ).to(torch_device) with torch.no_grad(): encoder_outputs = model.encode(inputs["input_values"]) expected_quantized_representation = encoder_outputs["quantized_representation"][0, 0, :5].cpu() expected_audio_codes = encoder_outputs["audio_codes"][0, 0, :5].cpu() expected_projected_latents = encoder_outputs["projected_latents"][0, 0, :5].cpu() # make sure values are correct for audios slices self.assertTrue( torch.allclose( expected_quantized_representation, expected_encoder_output_dict["quantized_representation"], atol=1e-3, ) ) self.assertTrue( torch.allclose(expected_audio_codes, expected_encoder_output_dict["audio_codes"], atol=1e-3) ) self.assertTrue( torch.allclose( expected_projected_latents, expected_encoder_output_dict["projected_latents"], atol=1e-3 ) ) _, quantized_representation, _, _ = encoder_outputs.to_tuple() input_values_dec = model.decode(quantized_representation)[0] input_values_enc_dec = model(inputs["input_values"])[1] # make sure forward and decode gives same result self.assertTrue(torch.allclose(input_values_dec, input_values_enc_dec, atol=1e-3)) arr = inputs["input_values"][0].cpu().numpy() arr_enc_dec = input_values_enc_dec[0].cpu().numpy() max_length = min(arr_enc_dec.shape[-1], arr.shape[-1]) arr_cut = arr[0, :max_length].copy() arr_enc_dec_cut = arr_enc_dec[:max_length].copy() # make sure audios are more or less equal rmse = compute_rmse(arr_cut, arr_enc_dec_cut) self.assertTrue(rmse < expected_rmse) def test_integration_44khz(self): expected_rmse = 0.002 expected_encoder_sums_dict = { "loss": 34.3612, "quantized_representation": 0.0078, "audio_codes": 509.6812, "projected_latents": -0.1054, } librispeech_dummy = load_dataset("hf-internal-testing/librispeech_asr_dummy", "clean", split="validation") model_name = "dac_44khz" model_id = "descript/{}".format(model_name) model = DacModel.from_pretrained(model_id).to(torch_device).eval() processor = AutoProcessor.from_pretrained(model_id) librispeech_dummy = librispeech_dummy.cast_column("audio", Audio(sampling_rate=processor.sampling_rate)) audio_sample = librispeech_dummy[0]["audio"]["array"] inputs = processor( raw_audio=audio_sample, sampling_rate=processor.sampling_rate, return_tensors="pt", ).to(torch_device) with torch.no_grad(): encoder_outputs = model.encode(inputs["input_values"]) expected_encoder_sums = torch.tensor(list(expected_encoder_sums_dict.values()), dtype=torch.float32) encoder_outputs_mean = torch.tensor([v.float().mean().cpu().item() for v in encoder_outputs.to_tuple()]) # make sure audio encoded codes are correct self.assertTrue(torch.allclose(encoder_outputs_mean, expected_encoder_sums, atol=1e-3)) _, quantized_representation, _, _ = encoder_outputs.to_tuple() input_values_dec = model.decode(quantized_representation)[0] input_values_enc_dec = model(inputs["input_values"])[1] # make sure forward and decode gives same result self.assertTrue(torch.allclose(input_values_dec, input_values_enc_dec, atol=1e-3)) arr = inputs["input_values"][0].cpu().numpy() arr_enc_dec = input_values_enc_dec[0].cpu().numpy() max_length = min(arr_enc_dec.shape[-1], arr.shape[-1]) arr_cut = arr[0, :max_length].copy() arr_enc_dec_cut = arr_enc_dec[:max_length].copy() # make sure audios are more or less equal rmse = compute_rmse(arr_cut, arr_enc_dec_cut) self.assertTrue(rmse < expected_rmse) def test_integration_batch_16khz(self): expected_rmse = 0.002 expected_encoder_sums_dict = { "loss": 20.3913, "quantized_representation": -0.0538, "audio_codes": 487.8470, "projected_latents": 0.0237, } librispeech_dummy = load_dataset("hf-internal-testing/librispeech_asr_dummy", "clean", split="validation") model_name = "dac_16khz" model_id = "descript/{}".format(model_name) model = DacModel.from_pretrained(model_id).to(torch_device) processor = AutoProcessor.from_pretrained(model_id) librispeech_dummy = librispeech_dummy.cast_column("audio", Audio(sampling_rate=processor.sampling_rate)) audio_samples = [np.array([audio_sample["array"]])[0] for audio_sample in librispeech_dummy[-2:]["audio"]] inputs = processor( raw_audio=audio_samples, sampling_rate=processor.sampling_rate, truncation=False, return_tensors="pt", ).to(torch_device) with torch.no_grad(): encoder_outputs = model.encode(inputs["input_values"]) expected_encoder_sums = torch.tensor(list(expected_encoder_sums_dict.values()), dtype=torch.float32) encoder_outputs_mean = torch.tensor([v.float().mean().item() for v in encoder_outputs.to_tuple()]) # make sure audio encoded codes are correct self.assertTrue(torch.allclose(encoder_outputs_mean, expected_encoder_sums, atol=1e-3)) _, quantized_representation, _, _ = encoder_outputs.to_tuple() input_values_dec = model.decode(quantized_representation)[0] input_values_enc_dec = model(inputs["input_values"])[1] # make sure forward and decode gives same result self.assertTrue(torch.allclose(input_values_dec, input_values_enc_dec, atol=1e-3)) arr = inputs["input_values"].cpu().numpy() arr_enc_dec = input_values_enc_dec.cpu().numpy() max_length = min(arr_enc_dec.shape[-1], arr.shape[-1]) arr_cut = arr[:, 0, :max_length].copy() arr_enc_dec_cut = arr_enc_dec[:, :max_length].copy() # make sure audios are more or less equal rmse = compute_rmse(arr_cut, arr_enc_dec_cut) self.assertTrue(rmse < expected_rmse) def test_integration_batch_24khz(self): expected_rmse = 0.002 expected_encoder_sums_dict = { "loss": 24.2309, "quantized_representation": 0.0520, "audio_codes": 510.2700, "projected_latents": -0.0076, } librispeech_dummy = load_dataset("hf-internal-testing/librispeech_asr_dummy", "clean", split="validation") model_name = "dac_24khz" model_id = "descript/{}".format(model_name) model = DacModel.from_pretrained(model_id).to(torch_device) processor = AutoProcessor.from_pretrained(model_id) librispeech_dummy = librispeech_dummy.cast_column("audio", Audio(sampling_rate=processor.sampling_rate)) audio_samples = [np.array([audio_sample["array"]])[0] for audio_sample in librispeech_dummy[-2:]["audio"]] inputs = processor( raw_audio=audio_samples, sampling_rate=processor.sampling_rate, truncation=False, return_tensors="pt", ).to(torch_device) with torch.no_grad(): encoder_outputs = model.encode(inputs["input_values"]) expected_encoder_sums = torch.tensor(list(expected_encoder_sums_dict.values()), dtype=torch.float32) encoder_outputs_mean = torch.tensor([v.float().mean().cpu().item() for v in encoder_outputs.to_tuple()]) # make sure audio encoded codes are correct self.assertTrue(torch.allclose(encoder_outputs_mean, expected_encoder_sums, atol=1e-3)) _, quantized_representation, _, _ = encoder_outputs.to_tuple() input_values_dec = model.decode(quantized_representation)[0] input_values_enc_dec = model(inputs["input_values"])[1] # make sure forward and decode gives same result self.assertTrue(torch.allclose(input_values_dec, input_values_enc_dec, atol=1e-3)) arr = inputs["input_values"].cpu().numpy() arr_enc_dec = input_values_enc_dec.cpu().numpy() max_length = min(arr_enc_dec.shape[-1], arr.shape[-1]) arr_cut = arr[:, 0, :max_length].copy() arr_enc_dec_cut = arr_enc_dec[:, :max_length].copy() # make sure audios are more or less equal rmse = compute_rmse(arr_cut, arr_enc_dec_cut) self.assertTrue(rmse < expected_rmse) def test_integration_batch_44khz(self): expected_rmse = 0.001 expected_encoder_sums_dict = { "loss": 25.9233, "quantized_representation": 0.0013, "audio_codes": 528.5620, "projected_latents": -0.1194, } librispeech_dummy = load_dataset("hf-internal-testing/librispeech_asr_dummy", "clean", split="validation") model_name = "dac_44khz" model_id = "descript/{}".format(model_name) model = DacModel.from_pretrained(model_id).to(torch_device) processor = AutoProcessor.from_pretrained(model_id) librispeech_dummy = librispeech_dummy.cast_column("audio", Audio(sampling_rate=processor.sampling_rate)) audio_samples = [np.array([audio_sample["array"]])[0] for audio_sample in librispeech_dummy[-2:]["audio"]] inputs = processor( raw_audio=audio_samples, sampling_rate=processor.sampling_rate, truncation=False, return_tensors="pt", ).to(torch_device) with torch.no_grad(): encoder_outputs = model.encode(inputs["input_values"]) expected_encoder_sums = torch.tensor(list(expected_encoder_sums_dict.values()), dtype=torch.float32) encoder_outputs_mean = torch.tensor([v.float().mean().cpu().item() for v in encoder_outputs.to_tuple()]) # make sure audio encoded codes are correct self.assertTrue(torch.allclose(encoder_outputs_mean, expected_encoder_sums, atol=1e-3)) _, quantized_representation, _, _ = encoder_outputs.to_tuple() input_values_dec = model.decode(quantized_representation)[0] input_values_enc_dec = model(inputs["input_values"])[1] # make sure forward and decode gives same result self.assertTrue(torch.allclose(input_values_dec, input_values_enc_dec, atol=1e-3)) arr = inputs["input_values"].cpu().numpy() arr_enc_dec = input_values_enc_dec.cpu().numpy() max_length = min(arr_enc_dec.shape[-1], arr.shape[-1]) arr_cut = arr[:, 0, :max_length].copy() arr_enc_dec_cut = arr_enc_dec[:, :max_length].copy() # make sure audios are more or less equal rmse = compute_rmse(arr_cut, arr_enc_dec_cut) self.assertTrue(rmse < expected_rmse)