import json import random from tqdm import tqdm import torch import torch.nn.functional as F from torch.utils.data import Dataset, Sampler import torchaudio from datasets import load_dataset, load_from_disk from datasets import Dataset as Dataset_ from model.modules import MelSpec class HFDataset(Dataset): def __init__( self, hf_dataset: Dataset, target_sample_rate = 24_000, n_mel_channels = 100, hop_length = 256, ): self.data = hf_dataset self.target_sample_rate = target_sample_rate self.hop_length = hop_length self.mel_spectrogram = MelSpec(target_sample_rate=target_sample_rate, n_mel_channels=n_mel_channels, hop_length=hop_length) def get_frame_len(self, index): row = self.data[index] audio = row['audio']['array'] sample_rate = row['audio']['sampling_rate'] return audio.shape[-1] / sample_rate * self.target_sample_rate / self.hop_length def __len__(self): return len(self.data) def __getitem__(self, index): row = self.data[index] audio = row['audio']['array'] # logger.info(f"Audio shape: {audio.shape}") sample_rate = row['audio']['sampling_rate'] duration = audio.shape[-1] / sample_rate if duration > 30 or duration < 0.3: return self.__getitem__((index + 1) % len(self.data)) audio_tensor = torch.from_numpy(audio).float() if sample_rate != self.target_sample_rate: resampler = torchaudio.transforms.Resample(sample_rate, self.target_sample_rate) audio_tensor = resampler(audio_tensor) audio_tensor = audio_tensor.unsqueeze(0) # 't -> 1 t') mel_spec = self.mel_spectrogram(audio_tensor) mel_spec = mel_spec.squeeze(0) # '1 d t -> d t' text = row['text'] return dict( mel_spec = mel_spec, text = text, ) class CustomDataset(Dataset): def __init__( self, custom_dataset: Dataset, durations = None, target_sample_rate = 24_000, hop_length = 256, n_mel_channels = 100, preprocessed_mel = False, ): self.data = custom_dataset self.durations = durations self.target_sample_rate = target_sample_rate self.hop_length = hop_length self.preprocessed_mel = preprocessed_mel if not preprocessed_mel: self.mel_spectrogram = MelSpec(target_sample_rate=target_sample_rate, hop_length=hop_length, n_mel_channels=n_mel_channels) def get_frame_len(self, index): if self.durations is not None: # Please make sure the separately provided durations are correct, otherwise 99.99% OOM return self.durations[index] * self.target_sample_rate / self.hop_length return self.data[index]["duration"] * self.target_sample_rate / self.hop_length def __len__(self): return len(self.data) def __getitem__(self, index): row = self.data[index] audio_path = row["audio_path"] text = row["text"] duration = row["duration"] if self.preprocessed_mel: mel_spec = torch.tensor(row["mel_spec"]) else: audio, source_sample_rate = torchaudio.load(audio_path) if audio.shape[0] > 1: audio = torch.mean(audio, dim=0, keepdim=True) if duration > 30 or duration < 0.3: return self.__getitem__((index + 1) % len(self.data)) if source_sample_rate != self.target_sample_rate: resampler = torchaudio.transforms.Resample(source_sample_rate, self.target_sample_rate) audio = resampler(audio) mel_spec = self.mel_spectrogram(audio) mel_spec = mel_spec.squeeze(0) # '1 d t -> d t') return dict( mel_spec = mel_spec, text = text, ) # Dynamic Batch Sampler class DynamicBatchSampler(Sampler[list[int]]): """ Extension of Sampler that will do the following: 1. Change the batch size (essentially number of sequences) in a batch to ensure that the total number of frames are less than a certain threshold. 2. Make sure the padding efficiency in the batch is high. """ def __init__(self, sampler: Sampler[int], frames_threshold: int, max_samples=0, random_seed=None, drop_last: bool = False): self.sampler = sampler self.frames_threshold = frames_threshold self.max_samples = max_samples indices, batches = [], [] data_source = self.sampler.data_source for idx in tqdm(self.sampler, desc=f"Sorting with sampler... if slow, check whether dataset is provided with duration"): indices.append((idx, data_source.get_frame_len(idx))) indices.sort(key=lambda elem : elem[1]) batch = [] batch_frames = 0 for idx, frame_len in tqdm(indices, desc=f"Creating dynamic batches with {frames_threshold} audio frames per gpu"): if batch_frames + frame_len <= self.frames_threshold and (max_samples == 0 or len(batch) < max_samples): batch.append(idx) batch_frames += frame_len else: if len(batch) > 0: batches.append(batch) if frame_len <= self.frames_threshold: batch = [idx] batch_frames = frame_len else: batch = [] batch_frames = 0 if not drop_last and len(batch) > 0: batches.append(batch) del indices # if want to have different batches between epochs, may just set a seed and log it in ckpt # cuz during multi-gpu training, although the batch on per gpu not change between epochs, the formed general minibatch is different # e.g. for epoch n, use (random_seed + n) random.seed(random_seed) random.shuffle(batches) self.batches = batches def __iter__(self): return iter(self.batches) def __len__(self): return len(self.batches) # Load dataset def load_dataset( dataset_name: str, tokenizer: str = "pinyin", dataset_type: str = "CustomDataset", audio_type: str = "raw", mel_spec_kwargs: dict = dict() ) -> CustomDataset | HFDataset: ''' dataset_type - "CustomDataset" if you want to use tokenizer name and default data path to load for train_dataset - "CustomDatasetPath" if you just want to pass the full path to a preprocessed dataset without relying on tokenizer ''' print("Loading dataset ...") if dataset_type == "CustomDataset": if audio_type == "raw": try: train_dataset = load_from_disk(f"data/{dataset_name}_{tokenizer}/raw") except: train_dataset = Dataset_.from_file(f"data/{dataset_name}_{tokenizer}/raw.arrow") preprocessed_mel = False elif audio_type == "mel": train_dataset = Dataset_.from_file(f"data/{dataset_name}_{tokenizer}/mel.arrow") preprocessed_mel = True with open(f"data/{dataset_name}_{tokenizer}/duration.json", 'r', encoding='utf-8') as f: data_dict = json.load(f) durations = data_dict["duration"] train_dataset = CustomDataset(train_dataset, durations=durations, preprocessed_mel=preprocessed_mel, **mel_spec_kwargs) elif dataset_type == "CustomDatasetPath": try: train_dataset = load_from_disk(f"{dataset_name}/raw") except: train_dataset = Dataset_.from_file(f"{dataset_name}/raw.arrow") with open(f"{dataset_name}/duration.json", 'r', encoding='utf-8') as f: data_dict = json.load(f) durations = data_dict["duration"] train_dataset = CustomDataset(train_dataset, durations=durations, preprocessed_mel=preprocessed_mel, **mel_spec_kwargs) elif dataset_type == "HFDataset": print("Should manually modify the path of huggingface dataset to your need.\n" + "May also the corresponding script cuz different dataset may have different format.") pre, post = dataset_name.split("_") train_dataset = HFDataset(load_dataset(f"{pre}/{pre}", split=f"train.{post}", cache_dir="./data"),) return train_dataset # collation def collate_fn(batch): mel_specs = [item['mel_spec'].squeeze(0) for item in batch] mel_lengths = torch.LongTensor([spec.shape[-1] for spec in mel_specs]) max_mel_length = mel_lengths.amax() padded_mel_specs = [] for spec in mel_specs: # TODO. maybe records mask for attention here padding = (0, max_mel_length - spec.size(-1)) padded_spec = F.pad(spec, padding, value = 0) padded_mel_specs.append(padded_spec) mel_specs = torch.stack(padded_mel_specs) text = [item['text'] for item in batch] text_lengths = torch.LongTensor([len(item) for item in text]) return dict( mel = mel_specs, mel_lengths = mel_lengths, text = text, text_lengths = text_lengths, )