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app_vc.py
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app_vc.py
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import os
os.environ['HF_HUB_CACHE'] = './checkpoints/hf_cache'
import gradio as gr
import torch
import torchaudio
import librosa
from modules.commons import build_model, load_checkpoint, recursive_munch, str2bool
import yaml
from hf_utils import load_custom_model_from_hf
import numpy as np
from pydub import AudioSegment
import argparse
# Load model and configuration
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
fp16 = False
def load_models(args):
global sr, hop_length, fp16
fp16 = args.fp16
print(f"Using device: {device}")
print(f"Using fp16: {fp16}")
if args.checkpoint_path is None or args.checkpoint_path == "":
dit_checkpoint_path, dit_config_path = load_custom_model_from_hf("Plachta/Seed-VC",
"DiT_seed_v2_uvit_whisper_small_wavenet_bigvgan_pruned.pth",
"config_dit_mel_seed_uvit_whisper_small_wavenet.yml")
else:
dit_checkpoint_path = args.checkpoint_path
dit_config_path = args.config_path
config = yaml.safe_load(open(dit_config_path, "r"))
model_params = recursive_munch(config["model_params"])
model_params.dit_type = 'DiT'
model = build_model(model_params, stage="DiT")
hop_length = config["preprocess_params"]["spect_params"]["hop_length"]
sr = config["preprocess_params"]["sr"]
# Load checkpoints
model, _, _, _ = load_checkpoint(
model,
None,
dit_checkpoint_path,
load_only_params=True,
ignore_modules=[],
is_distributed=False,
)
for key in model:
model[key].eval()
model[key].to(device)
model.cfm.estimator.setup_caches(max_batch_size=1, max_seq_length=8192)
# Load additional modules
from modules.campplus.DTDNN import CAMPPlus
campplus_ckpt_path = load_custom_model_from_hf(
"funasr/campplus", "campplus_cn_common.bin", config_filename=None
)
campplus_model = CAMPPlus(feat_dim=80, embedding_size=192)
campplus_model.load_state_dict(torch.load(campplus_ckpt_path, map_location="cpu"))
campplus_model.eval()
campplus_model.to(device)
vocoder_type = model_params.vocoder.type
if vocoder_type == 'bigvgan':
from modules.bigvgan import bigvgan
bigvgan_name = model_params.vocoder.name
bigvgan_model = bigvgan.BigVGAN.from_pretrained(bigvgan_name, use_cuda_kernel=False)
# remove weight norm in the model and set to eval mode
bigvgan_model.remove_weight_norm()
bigvgan_model = bigvgan_model.eval().to(device)
vocoder_fn = bigvgan_model
elif vocoder_type == 'hifigan':
from modules.hifigan.generator import HiFTGenerator
from modules.hifigan.f0_predictor import ConvRNNF0Predictor
hift_config = yaml.safe_load(open('configs/hifigan.yml', 'r'))
hift_gen = HiFTGenerator(**hift_config['hift'], f0_predictor=ConvRNNF0Predictor(**hift_config['f0_predictor']))
hift_path = load_custom_model_from_hf("FunAudioLLM/CosyVoice-300M", 'hift.pt', None)
hift_gen.load_state_dict(torch.load(hift_path, map_location='cpu'))
hift_gen.eval()
hift_gen.to(device)
vocoder_fn = hift_gen
elif vocoder_type == "vocos":
vocos_config = yaml.safe_load(open(model_params.vocoder.vocos.config, 'r'))
vocos_path = model_params.vocoder.vocos.path
vocos_model_params = recursive_munch(vocos_config['model_params'])
vocos = build_model(vocos_model_params, stage='mel_vocos')
vocos_checkpoint_path = vocos_path
vocos, _, _, _ = load_checkpoint(vocos, None, vocos_checkpoint_path,
load_only_params=True, ignore_modules=[], is_distributed=False)
_ = [vocos[key].eval().to(device) for key in vocos]
_ = [vocos[key].to(device) for key in vocos]
total_params = sum(sum(p.numel() for p in vocos[key].parameters() if p.requires_grad) for key in vocos.keys())
print(f"Vocoder model total parameters: {total_params / 1_000_000:.2f}M")
vocoder_fn = vocos.decoder
else:
raise ValueError(f"Unknown vocoder type: {vocoder_type}")
speech_tokenizer_type = model_params.speech_tokenizer.type
if speech_tokenizer_type == 'whisper':
# whisper
from transformers import AutoFeatureExtractor, WhisperModel
whisper_name = model_params.speech_tokenizer.name
whisper_model = WhisperModel.from_pretrained(whisper_name, torch_dtype=torch.float16).to(device)
del whisper_model.decoder
whisper_feature_extractor = AutoFeatureExtractor.from_pretrained(whisper_name)
def semantic_fn(waves_16k):
ori_inputs = whisper_feature_extractor([waves_16k.squeeze(0).cpu().numpy()],
return_tensors="pt",
return_attention_mask=True)
ori_input_features = whisper_model._mask_input_features(
ori_inputs.input_features, attention_mask=ori_inputs.attention_mask).to(device)
with torch.no_grad():
ori_outputs = whisper_model.encoder(
ori_input_features.to(whisper_model.encoder.dtype),
head_mask=None,
output_attentions=False,
output_hidden_states=False,
return_dict=True,
)
S_ori = ori_outputs.last_hidden_state.to(torch.float32)
S_ori = S_ori[:, :waves_16k.size(-1) // 320 + 1]
return S_ori
elif speech_tokenizer_type == 'cnhubert':
from transformers import (
Wav2Vec2FeatureExtractor,
HubertModel,
)
hubert_model_name = config['model_params']['speech_tokenizer']['name']
hubert_feature_extractor = Wav2Vec2FeatureExtractor.from_pretrained(hubert_model_name)
hubert_model = HubertModel.from_pretrained(hubert_model_name)
hubert_model = hubert_model.to(device)
hubert_model = hubert_model.eval()
hubert_model = hubert_model.half()
def semantic_fn(waves_16k):
ori_waves_16k_input_list = [
waves_16k[bib].cpu().numpy()
for bib in range(len(waves_16k))
]
ori_inputs = hubert_feature_extractor(ori_waves_16k_input_list,
return_tensors="pt",
return_attention_mask=True,
padding=True,
sampling_rate=16000).to(device)
with torch.no_grad():
ori_outputs = hubert_model(
ori_inputs.input_values.half(),
)
S_ori = ori_outputs.last_hidden_state.float()
return S_ori
elif speech_tokenizer_type == 'xlsr':
from transformers import (
Wav2Vec2FeatureExtractor,
Wav2Vec2Model,
)
model_name = config['model_params']['speech_tokenizer']['name']
output_layer = config['model_params']['speech_tokenizer']['output_layer']
wav2vec_feature_extractor = Wav2Vec2FeatureExtractor.from_pretrained(model_name)
wav2vec_model = Wav2Vec2Model.from_pretrained(model_name)
wav2vec_model.encoder.layers = wav2vec_model.encoder.layers[:output_layer]
wav2vec_model = wav2vec_model.to(device)
wav2vec_model = wav2vec_model.eval()
wav2vec_model = wav2vec_model.half()
def semantic_fn(waves_16k):
ori_waves_16k_input_list = [
waves_16k[bib].cpu().numpy()
for bib in range(len(waves_16k))
]
ori_inputs = wav2vec_feature_extractor(ori_waves_16k_input_list,
return_tensors="pt",
return_attention_mask=True,
padding=True,
sampling_rate=16000).to(device)
with torch.no_grad():
ori_outputs = wav2vec_model(
ori_inputs.input_values.half(),
)
S_ori = ori_outputs.last_hidden_state.float()
return S_ori
else:
raise ValueError(f"Unknown speech tokenizer type: {speech_tokenizer_type}")
# Generate mel spectrograms
mel_fn_args = {
"n_fft": config['preprocess_params']['spect_params']['n_fft'],
"win_size": config['preprocess_params']['spect_params']['win_length'],
"hop_size": config['preprocess_params']['spect_params']['hop_length'],
"num_mels": config['preprocess_params']['spect_params']['n_mels'],
"sampling_rate": sr,
"fmin": config['preprocess_params']['spect_params'].get('fmin', 0),
"fmax": None if config['preprocess_params']['spect_params'].get('fmax', "None") == "None" else 8000,
"center": False
}
from modules.audio import mel_spectrogram
to_mel = lambda x: mel_spectrogram(x, **mel_fn_args)
return (
model,
semantic_fn,
vocoder_fn,
campplus_model,
to_mel,
mel_fn_args,
)
def crossfade(chunk1, chunk2, overlap):
fade_out = np.cos(np.linspace(0, np.pi / 2, overlap)) ** 2
fade_in = np.cos(np.linspace(np.pi / 2, 0, overlap)) ** 2
chunk2[:overlap] = chunk2[:overlap] * fade_in + chunk1[-overlap:] * fade_out
return chunk2
bitrate = "320k"
model, semantic_fn, vocoder_fn, campplus_model, to_mel, mel_fn_args = None, None, None, None, None, None
overlap_wave_len = None
max_context_window = None
sr = None
hop_length = None
overlap_frame_len = 16
@torch.no_grad()
@torch.inference_mode()
def voice_conversion(source, target, diffusion_steps, length_adjust, inference_cfg_rate):
inference_module = model
mel_fn = to_mel
# Load audio
source_audio = librosa.load(source, sr=sr)[0]
ref_audio = librosa.load(target, sr=sr)[0]
# Process audio
source_audio = torch.tensor(source_audio).unsqueeze(0).float().to(device)
ref_audio = torch.tensor(ref_audio[:sr * 25]).unsqueeze(0).float().to(device)
# Resample
ref_waves_16k = torchaudio.functional.resample(ref_audio, sr, 16000)
converted_waves_16k = torchaudio.functional.resample(source_audio, sr, 16000)
# if source audio less than 30 seconds, whisper can handle in one forward
if converted_waves_16k.size(-1) <= 16000 * 30:
S_alt = semantic_fn(converted_waves_16k)
else:
overlapping_time = 5 # 5 seconds
S_alt_list = []
buffer = None
traversed_time = 0
while traversed_time < converted_waves_16k.size(-1):
if buffer is None: # first chunk
chunk = converted_waves_16k[:, traversed_time:traversed_time + 16000 * 30]
else:
chunk = torch.cat([buffer, converted_waves_16k[:, traversed_time:traversed_time + 16000 * (30 - overlapping_time)]], dim=-1)
S_alt = semantic_fn(chunk)
if traversed_time == 0:
S_alt_list.append(S_alt)
else:
S_alt_list.append(S_alt[:, 50 * overlapping_time:])
buffer = chunk[:, -16000 * overlapping_time:]
traversed_time += 30 * 16000 if traversed_time == 0 else chunk.size(-1) - 16000 * overlapping_time
S_alt = torch.cat(S_alt_list, dim=1)
ori_waves_16k = torchaudio.functional.resample(ref_audio, sr, 16000)
S_ori = semantic_fn(ori_waves_16k)
mel = mel_fn(source_audio.to(device).float())
mel2 = mel_fn(ref_audio.to(device).float())
target_lengths = torch.LongTensor([int(mel.size(2) * length_adjust)]).to(mel.device)
target2_lengths = torch.LongTensor([mel2.size(2)]).to(mel2.device)
feat2 = torchaudio.compliance.kaldi.fbank(ref_waves_16k,
num_mel_bins=80,
dither=0,
sample_frequency=16000)
feat2 = feat2 - feat2.mean(dim=0, keepdim=True)
style2 = campplus_model(feat2.unsqueeze(0))
F0_ori = None
F0_alt = None
shifted_f0_alt = None
# Length regulation
cond, _, codes, commitment_loss, codebook_loss = inference_module.length_regulator(S_alt, ylens=target_lengths, n_quantizers=3, f0=shifted_f0_alt)
prompt_condition, _, codes, commitment_loss, codebook_loss = inference_module.length_regulator(S_ori, ylens=target2_lengths, n_quantizers=3, f0=F0_ori)
max_source_window = max_context_window - mel2.size(2)
# split source condition (cond) into chunks
processed_frames = 0
generated_wave_chunks = []
# generate chunk by chunk and stream the output
while processed_frames < cond.size(1):
chunk_cond = cond[:, processed_frames:processed_frames + max_source_window]
is_last_chunk = processed_frames + max_source_window >= cond.size(1)
cat_condition = torch.cat([prompt_condition, chunk_cond], dim=1)
with torch.autocast(device_type=device.type, dtype=torch.float16 if fp16 else torch.float32):
# Voice Conversion
vc_target = inference_module.cfm.inference(cat_condition,
torch.LongTensor([cat_condition.size(1)]).to(mel2.device),
mel2, style2, None, diffusion_steps,
inference_cfg_rate=inference_cfg_rate)
vc_target = vc_target[:, :, mel2.size(-1):]
vc_wave = vocoder_fn(vc_target.float())[0]
if vc_wave.ndim == 1:
vc_wave = vc_wave.unsqueeze(0)
if processed_frames == 0:
if is_last_chunk:
output_wave = vc_wave[0].cpu().numpy()
generated_wave_chunks.append(output_wave)
output_wave = (output_wave * 32768.0).astype(np.int16)
mp3_bytes = AudioSegment(
output_wave.tobytes(), frame_rate=sr,
sample_width=output_wave.dtype.itemsize, channels=1
).export(format="mp3", bitrate=bitrate).read()
yield mp3_bytes, (sr, np.concatenate(generated_wave_chunks))
break
output_wave = vc_wave[0, :-overlap_wave_len].cpu().numpy()
generated_wave_chunks.append(output_wave)
previous_chunk = vc_wave[0, -overlap_wave_len:]
processed_frames += vc_target.size(2) - overlap_frame_len
output_wave = (output_wave * 32768.0).astype(np.int16)
mp3_bytes = AudioSegment(
output_wave.tobytes(), frame_rate=sr,
sample_width=output_wave.dtype.itemsize, channels=1
).export(format="mp3", bitrate=bitrate).read()
yield mp3_bytes, None
elif is_last_chunk:
output_wave = crossfade(previous_chunk.cpu().numpy(), vc_wave[0].cpu().numpy(), overlap_wave_len)
generated_wave_chunks.append(output_wave)
processed_frames += vc_target.size(2) - overlap_frame_len
output_wave = (output_wave * 32768.0).astype(np.int16)
mp3_bytes = AudioSegment(
output_wave.tobytes(), frame_rate=sr,
sample_width=output_wave.dtype.itemsize, channels=1
).export(format="mp3", bitrate=bitrate).read()
yield mp3_bytes, (sr, np.concatenate(generated_wave_chunks))
break
else:
output_wave = crossfade(previous_chunk.cpu().numpy(), vc_wave[0, :-overlap_wave_len].cpu().numpy(), overlap_wave_len)
generated_wave_chunks.append(output_wave)
previous_chunk = vc_wave[0, -overlap_wave_len:]
processed_frames += vc_target.size(2) - overlap_frame_len
output_wave = (output_wave * 32768.0).astype(np.int16)
mp3_bytes = AudioSegment(
output_wave.tobytes(), frame_rate=sr,
sample_width=output_wave.dtype.itemsize, channels=1
).export(format="mp3", bitrate=bitrate).read()
yield mp3_bytes, None
def main(args):
global model, semantic_fn, vocoder_fn, campplus_model, to_mel, mel_fn_args
global overlap_wave_len, max_context_window, sr, hop_length
model, semantic_fn, vocoder_fn, campplus_model, to_mel, mel_fn_args = load_models(args)
# streaming and chunk processing related params
max_context_window = sr // hop_length * 30
overlap_wave_len = overlap_frame_len * hop_length
description = ("Zero-shot voice conversion with in-context learning. For local deployment please check [GitHub repository](https://github.com/Plachtaa/seed-vc) "
"for details and updates.<br>Note that any reference audio will be forcefully clipped to 25s if beyond this length.<br> "
"If total duration of source and reference audio exceeds 30s, source audio will be processed in chunks.<br> "
"无需训练的 zero-shot 语音/歌声转换模型,若需本地部署查看[GitHub页面](https://github.com/Plachtaa/seed-vc)<br>"
"请注意,参考音频若超过 25 秒,则会被自动裁剪至此长度。<br>若源音频和参考音频的总时长超过 30 秒,源音频将被分段处理。")
inputs = [
gr.Audio(type="filepath", label="Source Audio / 源音频"),
gr.Audio(type="filepath", label="Reference Audio / 参考音频"),
gr.Slider(minimum=1, maximum=200, value=10, step=1, label="Diffusion Steps / 扩散步数", info="10 by default, 50~100 for best quality / 默认为 10,50~100 为最佳质量"),
gr.Slider(minimum=0.5, maximum=2.0, step=0.1, value=1.0, label="Length Adjust / 长度调整", info="<1.0 for speed-up speech, >1.0 for slow-down speech / <1.0 加速语速,>1.0 减慢语速"),
gr.Slider(minimum=0.0, maximum=1.0, step=0.1, value=0.7, label="Inference CFG Rate", info="has subtle influence / 有微小影响"),
]
examples = [["examples/source/yae_0.wav", "examples/reference/dingzhen_0.wav", 25, 1.0, 0.7, False, True, 0],
["examples/source/jay_0.wav", "examples/reference/azuma_0.wav", 25, 1.0, 0.7, True, True, 0],
]
outputs = [gr.Audio(label="Stream Output Audio / 流式输出", streaming=True, format='mp3'),
gr.Audio(label="Full Output Audio / 完整输出", streaming=False, format='wav')]
gr.Interface(fn=voice_conversion,
description=description,
inputs=inputs,
outputs=outputs,
title="Seed Voice Conversion",
examples=examples,
cache_examples=False,
).launch(share=args.share,)
if __name__ == "__main__":
parser = argparse.ArgumentParser()
parser.add_argument("--checkpoint-path", type=str, help="Path to the checkpoint file", default=None)
parser.add_argument("--config-path", type=str, help="Path to the config file", default=None)
parser.add_argument("--share", type=str2bool, nargs="?", const=True, default=False, help="Whether to share the app")
parser.add_argument("--fp16", type=str2bool, nargs="?", const=True, help="Whether to use fp16", default=True)
args = parser.parse_args()
main(args)