| | import numpy as np |
| | import torch |
| | import torch.nn.functional as F |
| | from vdecoder.nsf_hifigan.nvSTFT import STFT |
| | from vdecoder.nsf_hifigan.models import load_model |
| | from torchaudio.transforms import Resample |
| |
|
| | class Enhancer: |
| | def __init__(self, enhancer_type, enhancer_ckpt, device=None): |
| | if device is None: |
| | device = 'cuda' if torch.cuda.is_available() else 'cpu' |
| | self.device = device |
| | |
| | if enhancer_type == 'nsf-hifigan': |
| | self.enhancer = NsfHifiGAN(enhancer_ckpt, device=self.device) |
| | else: |
| | raise ValueError(f" [x] Unknown enhancer: {enhancer_type}") |
| | |
| | self.resample_kernel = {} |
| | self.enhancer_sample_rate = self.enhancer.sample_rate() |
| | self.enhancer_hop_size = self.enhancer.hop_size() |
| | |
| | def enhance(self, |
| | audio, |
| | sample_rate, |
| | f0, |
| | hop_size, |
| | adaptive_key = 0, |
| | silence_front = 0 |
| | ): |
| | |
| | start_frame = int(silence_front * sample_rate / hop_size) |
| | real_silence_front = start_frame * hop_size / sample_rate |
| | audio = audio[:, int(np.round(real_silence_front * sample_rate)) : ] |
| | f0 = f0[: , start_frame :, :] |
| | |
| | |
| | adaptive_factor = 2 ** ( -adaptive_key / 12) |
| | adaptive_sample_rate = 100 * int(np.round(self.enhancer_sample_rate / adaptive_factor / 100)) |
| | real_factor = self.enhancer_sample_rate / adaptive_sample_rate |
| | |
| | |
| | if sample_rate == adaptive_sample_rate: |
| | audio_res = audio |
| | else: |
| | key_str = str(sample_rate) + str(adaptive_sample_rate) |
| | if key_str not in self.resample_kernel: |
| | self.resample_kernel[key_str] = Resample(sample_rate, adaptive_sample_rate, lowpass_filter_width = 128).to(self.device) |
| | audio_res = self.resample_kernel[key_str](audio) |
| | |
| | n_frames = int(audio_res.size(-1) // self.enhancer_hop_size + 1) |
| | |
| | |
| | f0_np = f0.squeeze(0).squeeze(-1).cpu().numpy() |
| | f0_np *= real_factor |
| | time_org = (hop_size / sample_rate) * np.arange(len(f0_np)) / real_factor |
| | time_frame = (self.enhancer_hop_size / self.enhancer_sample_rate) * np.arange(n_frames) |
| | f0_res = np.interp(time_frame, time_org, f0_np, left=f0_np[0], right=f0_np[-1]) |
| | f0_res = torch.from_numpy(f0_res).unsqueeze(0).float().to(self.device) |
| |
|
| | |
| | enhanced_audio, enhancer_sample_rate = self.enhancer(audio_res, f0_res) |
| | |
| | |
| | if adaptive_factor != 0: |
| | key_str = str(adaptive_sample_rate) + str(enhancer_sample_rate) |
| | if key_str not in self.resample_kernel: |
| | self.resample_kernel[key_str] = Resample(adaptive_sample_rate, enhancer_sample_rate, lowpass_filter_width = 128).to(self.device) |
| | enhanced_audio = self.resample_kernel[key_str](enhanced_audio) |
| | |
| | |
| | if start_frame > 0: |
| | enhanced_audio = F.pad(enhanced_audio, (int(np.round(enhancer_sample_rate * real_silence_front)), 0)) |
| | |
| | return enhanced_audio, enhancer_sample_rate |
| | |
| | |
| | class NsfHifiGAN(torch.nn.Module): |
| | def __init__(self, model_path, device=None): |
| | super().__init__() |
| | if device is None: |
| | device = 'cuda' if torch.cuda.is_available() else 'cpu' |
| | self.device = device |
| | print('| Load HifiGAN: ', model_path) |
| | self.model, self.h = load_model(model_path, device=self.device) |
| | |
| | def sample_rate(self): |
| | return self.h.sampling_rate |
| | |
| | def hop_size(self): |
| | return self.h.hop_size |
| | |
| | def forward(self, audio, f0): |
| | stft = STFT( |
| | self.h.sampling_rate, |
| | self.h.num_mels, |
| | self.h.n_fft, |
| | self.h.win_size, |
| | self.h.hop_size, |
| | self.h.fmin, |
| | self.h.fmax) |
| | with torch.no_grad(): |
| | mel = stft.get_mel(audio) |
| | enhanced_audio = self.model(mel, f0[:,:mel.size(-1)]).view(-1) |
| | return enhanced_audio, self.h.sampling_rate |
