# Copyright (c) 2025, NVIDIA CORPORATION. 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. import itertools import json import einops import lhotse import lightning.pytorch as pl import numpy as np import pytest import soundfile as sf import torch from omegaconf import DictConfig from nemo.collections.audio.models import SchroedingerBridgeAudioToAudioModel @pytest.fixture(params=["nemo_manifest", "lhotse_cuts"]) def mock_dataset_config(tmp_path, request): num_files = 8 num_samples = 16000 for i in range(num_files): data = np.random.randn(num_samples, 1) sf.write(tmp_path / f"audio_{i}.wav", data, 16000) if request.param == "lhotse_cuts": with lhotse.CutSet.open_writer(tmp_path / "cuts.jsonl") as writer: for i in range(num_files): recording = lhotse.Recording.from_file(tmp_path / f"audio_{i}.wav") cut = lhotse.MonoCut( id=f"audio_{i}", start=0, channel=0, duration=num_samples / 16000, recording=recording, custom={"target_recording": recording}, ) writer.write(cut) return { 'cuts_path': str(tmp_path / "cuts.jsonl"), 'use_lhotse': True, 'batch_size': 2, 'num_workers': 1, } elif request.param == "nemo_manifest": with (tmp_path / "small_manifest.jsonl").open("w") as f: for i in range(num_files): entry = { "noisy_filepath": str(tmp_path / f"audio_{i}.wav"), "clean_filepath": str(tmp_path / f"audio_{i}.wav"), "duration": num_samples / 16000, "offset": 0, } f.write(f"{json.dumps(entry)}\n") return { 'manifest_filepath': str(tmp_path / "small_manifest.jsonl"), 'input_key': 'noisy_filepath', 'target_key': 'clean_filepath', 'use_lhotse': False, 'batch_size': 2, 'num_workers': 1, } else: raise NotImplementedError(f"Dataset type {request.param} not implemented") @pytest.fixture() def schroedinger_bridge_model_ncsn_params(): model = { 'sample_rate': 16000, 'num_outputs': 1, 'normalize_input': True, 'max_utts_evaluation_metrics': 50, } encoder = { '_target_': 'nemo.collections.audio.modules.transforms.AudioToSpectrogram', 'fft_length': 510, 'hop_length': 128, 'magnitude_power': 0.5, 'scale': 0.33, } decoder = { '_target_': 'nemo.collections.audio.modules.transforms.SpectrogramToAudio', 'fft_length': encoder['fft_length'], 'hop_length': encoder['hop_length'], 'magnitude_power': encoder['magnitude_power'], 'scale': encoder['scale'], } estimator = { '_target_': 'nemo.collections.audio.parts.submodules.ncsnpp.SpectrogramNoiseConditionalScoreNetworkPlusPlus', 'in_channels': 2, # single-channel noisy input 'out_channels': 1, # single-channel estimate 'conditioned_on_time': True, 'channels': [8, 8, 8, 8, 8], 'num_res_blocks': 3, # increased number of res blocks 'pad_time_to': 64, # pad to 64 frames for the time dimension 'pad_dimension_to': 0, # no padding in the frequency dimension } loss_encoded = {'_target_': 'nemo.collections.audio.losses.MSELoss', 'ndim': 4} # computed in the time domain loss_time = {'_target_': 'nemo.collections.audio.losses.MAELoss'} noise_schedule = { '_target_': 'nemo.collections.audio.parts.submodules.schroedinger_bridge.SBNoiseScheduleVE', 'k': 2.6, 'c': 0.4, 'time_min': 1e-4, 'time_max': 1.0, 'num_steps': 1000, # num steps for the forward process } sampler = { '_target_': 'nemo.collections.audio.parts.submodules.schroedinger_bridge.SBSampler', 'time_min': 1e-4, 'time_max': 1.0, 'num_steps': 5, # num steps for the reverse process } metrics = { 'val': { 'sisdr': { '_target_': 'torchmetrics.audio.ScaleInvariantSignalDistortionRatio', }, }, } model_config = DictConfig( { 'sample_rate': model['sample_rate'], 'num_outputs': model['num_outputs'], 'normalize_input': model['normalize_input'], 'max_utts_evaluation_metrics': model['max_utts_evaluation_metrics'], 'encoder': DictConfig(encoder), 'decoder': DictConfig(decoder), 'estimator': DictConfig(estimator), 'loss_encoded': DictConfig(loss_encoded), 'loss_time': DictConfig(loss_time), 'loss_time_weight': 0.001, 'estimator_output': 'data_prediction', 'noise_schedule': DictConfig(noise_schedule), 'sampler': DictConfig(sampler), 'metrics': metrics, 'optim': { 'name': 'adam', 'lr': 0.001, 'betas': (0.9, 0.98), }, } ) return model_config @pytest.fixture() def schroedinger_bridge_model_ncsn(schroedinger_bridge_model_ncsn_params): with torch.random.fork_rng(): torch.random.manual_seed(0) model = SchroedingerBridgeAudioToAudioModel(cfg=schroedinger_bridge_model_ncsn_params) return model @pytest.fixture() def schroedinger_bridge_model_ncsn_with_trainer_and_mock_dataset( schroedinger_bridge_model_ncsn_params, mock_dataset_config ): # Add train and validation dataset configs schroedinger_bridge_model_ncsn_params["train_ds"] = {**mock_dataset_config, "shuffle": True} schroedinger_bridge_model_ncsn_params["validation_ds"] = {**mock_dataset_config, "shuffle": False} # Trainer config trainer_cfg = { "max_epochs": -1, "max_steps": 8, "logger": False, "use_distributed_sampler": False, "val_check_interval": 2, "limit_train_batches": 4, "accelerator": "cpu", "enable_checkpointing": False, } schroedinger_bridge_model_ncsn_params["trainer"] = trainer_cfg trainer = pl.Trainer(**trainer_cfg) with torch.random.fork_rng(): torch.random.manual_seed(0) model = SchroedingerBridgeAudioToAudioModel(cfg=schroedinger_bridge_model_ncsn_params, trainer=trainer) return model, trainer class TestSchroedingerBridgeModelNCSN: """Test Schroedinger Bridge model with NCSN estimator.""" @pytest.mark.unit def test_constructor(self, schroedinger_bridge_model_ncsn): """Test that the model can be constructed from a config dict.""" model = schroedinger_bridge_model_ncsn.train() confdict = model.to_config_dict() instance2 = SchroedingerBridgeAudioToAudioModel.from_config_dict(confdict) assert isinstance(instance2, SchroedingerBridgeAudioToAudioModel) @pytest.mark.unit @pytest.mark.parametrize( "batch_size, sample_len", [ (4, 4), # Example 1 (2, 8), # Example 2 (1, 10), # Example 3 ], ) def test_forward_infer(self, schroedinger_bridge_model_ncsn, batch_size, sample_len): """Test that the model can run forward inference.""" model = schroedinger_bridge_model_ncsn.eval() confdict = model.to_config_dict() sampling_rate = confdict['sample_rate'] rng = torch.Generator() rng.manual_seed(0) input_signal = torch.randn(size=(batch_size, 1, sample_len * sampling_rate), generator=rng) input_signal_length = (sample_len * sampling_rate) * torch.ones(batch_size, dtype=torch.int) with torch.no_grad(): # batch size 1 output_list = [] output_length_list = [] for i in range(input_signal.size(0)): output, output_length = model.forward( input_signal=input_signal[i : i + 1], input_length=input_signal_length[i : i + 1] ) output_list.append(output) output_length_list.append(output_length) output_instance = torch.cat(output_list, 0) output_length_instance = torch.cat(output_length_list, 0) # batch size batch_size output_batch, output_length_batch = model.forward( input_signal=input_signal, input_length=input_signal_length ) # It is generative model so we do not check the diffenence between output_instance and output_batch # Check that the output and output length are the same for the instance and batch assert output_instance.shape == output_batch.shape assert output_length_instance.shape == output_length_batch.shape def test_training_step(self, schroedinger_bridge_model_ncsn_with_trainer_and_mock_dataset): model, _ = schroedinger_bridge_model_ncsn_with_trainer_and_mock_dataset model = model.train() for batch in itertools.islice(model._train_dl, 2): # start boilerplate from SchroedingerBridgeAudioToAudioModel.training_step if isinstance(batch, dict): # lhotse batches are dictionaries input_signal = batch['input_signal'] input_length = batch['input_length'] target_signal = batch.get('target_signal', input_signal) else: input_signal, input_length, target_signal, _ = batch if input_signal.ndim == 2: input_signal = einops.rearrange(input_signal, 'B T -> B 1 T') if target_signal.ndim == 2: target_signal = einops.rearrange(target_signal, 'B T -> B 1 T') # end boilerplate loss, _, _ = model._step(target_signal=target_signal, input_signal=input_signal, input_length=input_length) loss.backward() def test_model_training(self, schroedinger_bridge_model_ncsn_with_trainer_and_mock_dataset): """ Test that the model can be trained for a few steps. An evaluation step is also expected. """ model, trainer = schroedinger_bridge_model_ncsn_with_trainer_and_mock_dataset model = model.train() trainer.fit(model)