190 lines
8.5 KiB
Python
190 lines
8.5 KiB
Python
import random
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import torch
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import torch.nn.functional as F
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import torchaudio
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from trainer.inject import Injector
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from utils.util import opt_get, load_model_from_config
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TACOTRON_MEL_MAX = 2.3143386840820312
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TACOTRON_MEL_MIN = -11.512925148010254
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def normalize_tacotron_mel(mel):
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return 2 * ((mel - TACOTRON_MEL_MIN) / (TACOTRON_MEL_MAX - TACOTRON_MEL_MIN)) - 1
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def denormalize_tacotron_mel(norm_mel):
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return ((norm_mel+1)/2)*(TACOTRON_MEL_MAX-TACOTRON_MEL_MIN)+TACOTRON_MEL_MIN
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class MelSpectrogramInjector(Injector):
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def __init__(self, opt, env):
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super().__init__(opt, env)
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from models.audio.tts.tacotron2 import TacotronSTFT
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# These are the default tacotron values for the MEL spectrogram.
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filter_length = opt_get(opt, ['filter_length'], 1024)
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hop_length = opt_get(opt, ['hop_length'], 256)
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win_length = opt_get(opt, ['win_length'], 1024)
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n_mel_channels = opt_get(opt, ['n_mel_channels'], 80)
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mel_fmin = opt_get(opt, ['mel_fmin'], 0)
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mel_fmax = opt_get(opt, ['mel_fmax'], 8000)
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sampling_rate = opt_get(opt, ['sampling_rate'], 22050)
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self.stft = TacotronSTFT(filter_length, hop_length, win_length, n_mel_channels, sampling_rate, mel_fmin, mel_fmax)
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self.do_normalization = opt_get(opt, ['do_normalization'], None) # This is different from the TorchMelSpectrogramInjector. This just normalizes to the range [-1,1]
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def forward(self, state):
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inp = state[self.input]
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if len(inp.shape) == 3: # Automatically squeeze out the channels dimension if it is present (assuming mono-audio)
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inp = inp.squeeze(1)
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assert len(inp.shape) == 2
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self.stft = self.stft.to(inp.device)
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mel = self.stft.mel_spectrogram(inp)
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if self.do_normalization:
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mel = normalize_tacotron_mel(mel)
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return {self.output: mel}
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class TorchMelSpectrogramInjector(Injector):
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def __init__(self, opt, env):
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super().__init__(opt, env)
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# These are the default tacotron values for the MEL spectrogram.
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self.filter_length = opt_get(opt, ['filter_length'], 1024)
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self.hop_length = opt_get(opt, ['hop_length'], 256)
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self.win_length = opt_get(opt, ['win_length'], 1024)
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self.n_mel_channels = opt_get(opt, ['n_mel_channels'], 80)
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self.mel_fmin = opt_get(opt, ['mel_fmin'], 0)
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self.mel_fmax = opt_get(opt, ['mel_fmax'], 8000)
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self.sampling_rate = opt_get(opt, ['sampling_rate'], 22050)
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norm = opt_get(opt, ['normalize'], False)
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self.mel_stft = torchaudio.transforms.MelSpectrogram(n_fft=self.filter_length, hop_length=self.hop_length,
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win_length=self.win_length, power=2, normalized=norm,
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sample_rate=self.sampling_rate, f_min=self.mel_fmin,
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f_max=self.mel_fmax, n_mels=self.n_mel_channels,
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norm="slaney")
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self.mel_norm_file = opt_get(opt, ['mel_norm_file'], None)
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if self.mel_norm_file is not None:
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self.mel_norms = torch.load(self.mel_norm_file)
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else:
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self.mel_norms = None
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def forward(self, state):
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inp = state[self.input]
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if len(inp.shape) == 3: # Automatically squeeze out the channels dimension if it is present (assuming mono-audio)
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inp = inp.squeeze(1)
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assert len(inp.shape) == 2
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self.mel_stft = self.mel_stft.to(inp.device)
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mel = self.mel_stft(inp)
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# Perform dynamic range compression
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mel = torch.log(torch.clamp(mel, min=1e-5))
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if self.mel_norms is not None:
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self.mel_norms = self.mel_norms.to(mel.device)
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mel = mel / self.mel_norms.unsqueeze(0).unsqueeze(-1)
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return {self.output: mel}
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class RandomAudioCropInjector(Injector):
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def __init__(self, opt, env):
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super().__init__(opt, env)
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self.crop_sz = opt['crop_size']
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self.lengths_key = opt['lengths_key']
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def forward(self, state):
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inp = state[self.input]
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lens = state[self.lengths_key]
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len = torch.min(lens)
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margin = len - self.crop_sz
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if margin < 0:
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return {self.output: inp}
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start = random.randint(0, margin)
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return {self.output: inp[:, :, start:start+self.crop_sz]}
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class AudioClipInjector(Injector):
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def __init__(self, opt, env):
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super().__init__(opt, env)
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self.clip_size = opt['clip_size']
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self.ctc_codes = opt['ctc_codes_key']
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self.output_ctc = opt['ctc_out_key']
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def forward(self, state):
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inp = state[self.input]
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ctc = state[self.ctc_codes]
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len = inp.shape[-1]
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if len > self.clip_size:
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proportion_inp_remaining = self.clip_size/len
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inp = inp[:, :, :self.clip_size]
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ctc = ctc[:,:int(proportion_inp_remaining*ctc.shape[-1])]
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return {self.output: inp, self.output_ctc: ctc}
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class AudioResampleInjector(Injector):
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def __init__(self, opt, env):
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super().__init__(opt, env)
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self.input_sr = opt['input_sample_rate']
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self.output_sr = opt['output_sample_rate']
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def forward(self, state):
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inp = state[self.input]
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return {self.output: torchaudio.functional.resample(inp, self.input_sr, self.output_sr)}
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class DiscreteTokenInjector(Injector):
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def __init__(self, opt, env):
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super().__init__(opt, env)
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cfg = opt_get(opt, ['dvae_config'], "../experiments/train_diffusion_vocoder_22k_level.yml")
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dvae_name = opt_get(opt, ['dvae_name'], 'dvae')
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self.dvae = load_model_from_config(cfg, dvae_name, device=env['device']).eval()
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def forward(self, state):
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inp = state[self.input]
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with torch.no_grad():
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self.dvae = self.dvae.to(inp.device)
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codes = self.dvae.get_codebook_indices(inp)
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return {self.output: codes}
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class GptVoiceLatentInjector(Injector):
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"""
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This injector does all the legwork to generate latents out of a UnifiedVoice model, including encoding all audio
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inputs into a MEL spectrogram and discretizing the inputs.
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"""
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def __init__(self, opt, env):
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super().__init__(opt, env)
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# For discrete tokenization.
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cfg = opt_get(opt, ['dvae_config'], "../experiments/train_diffusion_vocoder_22k_level.yml")
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dvae_name = opt_get(opt, ['dvae_name'], 'dvae')
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self.dvae = load_model_from_config(cfg, dvae_name).cuda().eval()
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# The unified_voice model.
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cfg = opt_get(opt, ['gpt_config'], "../experiments/train_gpt_tts_unified.yml")
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model_name = opt_get(opt, ['gpt_name'], 'gpt')
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pretrained_path = opt['gpt_path']
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self.gpt = load_model_from_config(cfg, model_name=model_name,
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also_load_savepoint=False, load_path=pretrained_path).cuda().eval()
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# Mel converter
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self.mel_inj = TorchMelSpectrogramInjector({'in': 'wav', 'out': 'mel', 'mel_norm_file': '../experiments/clips_mel_norms.pth'},{})
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# Aux input keys.
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self.conditioning_key = opt['conditioning_clip']
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self.text_input_key = opt['text']
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self.text_lengths_key = opt['text_lengths']
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self.input_lengths_key = opt['input_lengths']
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def to_mel(self, t):
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return self.mel_inj({'wav': t})['mel']
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def forward(self, state):
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with torch.no_grad():
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mel_inputs = self.to_mel(state[self.input])
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mel_cond = self.to_mel(state[self.conditioning_key])
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# Use the input as a conditioning input as well. This is fine because we are not actually training the GPT network so it can't learn to cheat.
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max_mel_len = max(mel_inputs.shape[-1], mel_cond.shape[-1])
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mel_cond = F.pad(mel_cond, (0, max_mel_len-mel_cond.shape[-1]))
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mel_cond2 = F.pad(mel_inputs, (0, max_mel_len-mel_inputs.shape[-1]))
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mel_cond = torch.cat([mel_cond.unsqueeze(1), mel_cond2.unsqueeze(1)], dim=1)
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self.dvae = self.dvae.to(mel_inputs.device)
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codes = self.dvae.get_codebook_indices(mel_inputs)
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self.gpt = self.gpt.to(codes.device)
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latents = self.gpt.forward(mel_cond, state[self.text_input_key],
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state[self.text_lengths_key], codes, state[self.input_lengths_key],
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text_first=True, raw_mels=None, return_attentions=False, return_latent=True)
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return {self.output: latents}
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