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import spaces |
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import gradio as gr |
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from huggingface_hub import hf_hub_download |
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import json |
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import torch |
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import os |
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from env import AttrDict |
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from meldataset import get_mel_spectrogram, MAX_WAV_VALUE |
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from bigvgan import BigVGAN |
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import librosa |
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import numpy as np |
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from utils import plot_spectrogram |
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import PIL |
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if torch.cuda.is_available(): |
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device = torch.device('cuda') |
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torch.backends.cudnn.benchmark = False |
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print(f"using GPU") |
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else: |
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device = torch.device('cpu') |
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print(f"using CPU") |
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def load_checkpoint(filepath): |
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assert os.path.isfile(filepath) |
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print("Loading '{}'".format(filepath)) |
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checkpoint_dict = torch.load(filepath, map_location='cpu') |
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print("Complete.") |
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return checkpoint_dict |
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def inference_gradio(input, model_choice): |
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sr, audio = input |
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audio = np.transpose(audio) |
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audio = audio / MAX_WAV_VALUE |
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model = dict_model[model_choice] |
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if sr != model.h.sampling_rate: |
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audio = librosa.resample(audio, orig_sr=sr, target_sr=model.h.sampling_rate) |
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if len(audio.shape) == 2: |
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audio = librosa.to_mono(audio) |
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audio = librosa.util.normalize(audio) * 0.95 |
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output, spec_gen = inference_model( |
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audio, model |
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) |
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spec_plot_gen = plot_spectrogram(spec_gen) |
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output_audio = (model.h.sampling_rate, output) |
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buffer = spec_plot_gen.canvas.buffer_rgba() |
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output_image = PIL.Image.frombuffer( |
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"RGBA", |
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spec_plot_gen.canvas.get_width_height(), |
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buffer, |
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"raw", |
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"RGBA", |
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0, |
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1 |
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) |
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return output_audio, output_image |
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@spaces.GPU(duration=120) |
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def inference_model(audio_input, model): |
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model.to(device) |
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with torch.inference_mode(): |
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wav = torch.FloatTensor(audio_input) |
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spec_gt = get_mel_spectrogram(wav.unsqueeze(0), model.h).to(device) |
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y_g_hat = model(spec_gt) |
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audio_gen = y_g_hat.squeeze().cpu() |
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spec_gen = get_mel_spectrogram(audio_gen.unsqueeze(0), model.h) |
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audio_gen = audio_gen.numpy() |
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audio_gen = (audio_gen * MAX_WAV_VALUE).astype("int16") |
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spec_gen = spec_gen.squeeze().numpy() |
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model.to("cpu") |
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del spec_gt, y_g_hat |
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return audio_gen, spec_gen |
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css = """ |
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a { |
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color: inherit; |
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text-decoration: underline; |
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} |
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.gradio-container { |
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font-family: 'IBM Plex Sans', sans-serif; |
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} |
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.gr-button { |
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color: white; |
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border-color: #000000; |
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background: #000000; |
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} |
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input[type='range'] { |
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accent-color: #000000; |
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} |
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.dark input[type='range'] { |
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accent-color: #dfdfdf; |
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} |
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.container { |
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max-width: 730px; |
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margin: auto; |
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padding-top: 1.5rem; |
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} |
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#gallery { |
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min-height: 22rem; |
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margin-bottom: 15px; |
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margin-left: auto; |
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margin-right: auto; |
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border-bottom-right-radius: .5rem !important; |
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border-bottom-left-radius: .5rem !important; |
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} |
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#gallery>div>.h-full { |
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min-height: 20rem; |
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} |
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.details:hover { |
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text-decoration: underline; |
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} |
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.gr-button { |
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white-space: nowrap; |
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} |
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.gr-button:focus { |
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border-color: rgb(147 197 253 / var(--tw-border-opacity)); |
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outline: none; |
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box-shadow: var(--tw-ring-offset-shadow), var(--tw-ring-shadow), var(--tw-shadow, 0 0 #0000); |
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--tw-border-opacity: 1; |
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--tw-ring-offset-shadow: var(--tw-ring-inset) 0 0 0 var(--tw-ring-offset-width) var(--tw-ring-offset-color); |
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--tw-ring-shadow: var(--tw-ring-inset) 0 0 0 calc(3px var(--tw-ring-offset-width)) var(--tw-ring-color); |
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--tw-ring-color: rgb(191 219 254 / var(--tw-ring-opacity)); |
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--tw-ring-opacity: .5; |
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} |
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#advanced-btn { |
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font-size: .7rem !important; |
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line-height: 19px; |
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margin-top: 12px; |
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margin-bottom: 12px; |
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padding: 2px 8px; |
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border-radius: 14px !important; |
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} |
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#advanced-options { |
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margin-bottom: 20px; |
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} |
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.footer { |
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margin-bottom: 45px; |
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margin-top: 35px; |
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text-align: center; |
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border-bottom: 1px solid #e5e5e5; |
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} |
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.footer>p { |
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font-size: .8rem; |
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display: inline-block; |
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padding: 0 10px; |
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transform: translateY(10px); |
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background: white; |
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} |
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.dark .footer { |
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border-color: #303030; |
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} |
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.dark .footer>p { |
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background: #0b0f19; |
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} |
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.acknowledgments h4{ |
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margin: 1.25em 0 .25em 0; |
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font-weight: bold; |
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font-size: 115%; |
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} |
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#container-advanced-btns{ |
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display: flex; |
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flex-wrap: wrap; |
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justify-content: space-between; |
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align-items: center; |
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} |
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.animate-spin { |
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animation: spin 1s linear infinite; |
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} |
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@keyframes spin { |
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from { |
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transform: rotate(0deg); |
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} |
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to { |
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transform: rotate(360deg); |
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} |
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} |
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#share-btn-container { |
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display: flex; padding-left: 0.5rem !important; padding-right: 0.5rem !important; background-color: #000000; justify-content: center; align-items: center; border-radius: 9999px !important; width: 13rem; |
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margin-top: 10px; |
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margin-left: auto; |
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} |
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#share-btn { |
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all: initial; color: #ffffff;font-weight: 600; cursor:pointer; font-family: 'IBM Plex Sans', sans-serif; margin-left: 0.5rem !important; padding-top: 0.25rem !important; padding-bottom: 0.25rem !important;right:0; |
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} |
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#share-btn * { |
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all: unset; |
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} |
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#share-btn-container div:nth-child(-n+2){ |
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width: auto !important; |
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min-height: 0px !important; |
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} |
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#share-btn-container .wrap { |
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display: none !important; |
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} |
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.gr-form{ |
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flex: 1 1 50%; border-top-right-radius: 0; border-bottom-right-radius: 0; |
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} |
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#prompt-container{ |
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gap: 0; |
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} |
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#generated_id{ |
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min-height: 700px |
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} |
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#setting_id{ |
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margin-bottom: 12px; |
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text-align: center; |
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font-weight: 900; |
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} |
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""" |
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LIST_MODEL_ID = [ |
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"bigvgan_24khz_100band", |
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"bigvgan_base_24khz_100band", |
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"bigvgan_22khz_80band", |
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"bigvgan_base_22khz_80band", |
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"bigvgan_v2_22khz_80band_256x", |
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"bigvgan_v2_22khz_80band_fmax8k_256x", |
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"bigvgan_v2_24khz_100band_256x", |
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"bigvgan_v2_44khz_128band_256x", |
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"bigvgan_v2_44khz_128band_512x" |
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] |
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dict_model = {} |
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dict_config = {} |
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for model_name in LIST_MODEL_ID: |
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generator = BigVGAN.from_pretrained('nvidia/'+model_name, token=os.environ['TOKEN']) |
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generator.eval() |
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generator.remove_weight_norm() |
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dict_model[model_name] = generator |
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dict_config[model_name] = generator.h |
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iface = gr.Blocks(css=css) |
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with iface: |
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gr.HTML( |
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""" |
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<div style="text-align: center; max-width: 900px; margin: 0 auto;"> |
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<div |
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style=" |
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display: inline-flex; |
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align-items: center; |
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gap: 0.8rem; |
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font-size: 1.75rem; |
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" |
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> |
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<h1 style="font-weight: 900; margin-bottom: 7px; line-height: normal;"> |
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BigVGAN: A Universal Neural Vocoder with Large-Scale Training |
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</h1> |
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</div> |
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<p style="margin-bottom: 10px; font-size: 125%"> |
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<a href="https://arxiv.org/abs/2206.04658">[Paper]</a> <a href="https://github.com/NVIDIA/BigVGAN">[Code]</a> <a href="https://bigvgan-demo.github.io/">[Demo]</a> <a href="https://research.nvidia.com/labs/adlr/projects/bigvgan/">[Project page]</a> |
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</p> |
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</div> |
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""" |
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) |
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gr.HTML( |
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""" |
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<div> |
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<h3>News</h3> |
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<p>[Jul 2024] We release BigVGAN-v2 along with pretrained checkpoints. Below are the highlights:</p> |
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<ul> |
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<li>Custom CUDA kernel for inference: we provide a fused upsampling + activation kernel written in CUDA for accelerated inference speed. Our test shows 1.5 - 3x faster speed on a single A100 GPU.</li> |
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<li>Improved discriminator and loss: BigVGAN-v2 is trained using a <a href="https://arxiv.org/abs/2311.14957" target="_blank">multi-scale sub-band CQT discriminator</a> and a <a href="https://arxiv.org/abs/2306.06546" target="_blank">multi-scale mel spectrogram loss</a>.</li> |
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<li>Larger training data: BigVGAN-v2 is trained using datasets containing diverse audio types, including speech in multiple languages, environmental sounds, and instruments.</li> |
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<li>We provide <a href="https://huggingface.co/nvidia/BigVGAN" target="_blank">pretrained checkpoints</a> of BigVGAN-v2 using diverse audio configurations, supporting up to 44 kHz sampling rate and 512x upsampling ratio.</li> |
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</ul> |
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</div> |
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""" |
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) |
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gr.HTML( |
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""" |
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<div> |
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<h3>Model Overview</h3> |
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BigVGAN is a neural vocoder model that generates audio waveforms using mel spectrogram as inputs. |
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<center><img src="https://user-images.githubusercontent.com/15963413/218609148-881e39df-33af-4af9-ab95-1427c4ebf062.png" width="800" style="margin-top: 20px;"></center> |
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</div> |
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""" |
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) |
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with gr.Group(): |
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model_choice = gr.Dropdown( |
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label="Select the model. Default: bigvgan_v2_24khz_100band_256x", |
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value="bigvgan_v2_24khz_100band_256x", |
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choices=[m for m in LIST_MODEL_ID], |
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interactive=True, |
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) |
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audio_input = gr.Audio( |
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label="Input Audio", elem_id="input-audio", interactive=True |
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) |
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button = gr.Button("Submit") |
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output_audio = gr.Audio(label="Output Audio", elem_id="output-audio") |
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output_image = gr.Image(label="Output Mel Spectrogram", elem_id="output-image-gen") |
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button.click( |
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inference_gradio, |
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inputs=[audio_input, model_choice], |
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outputs=[output_audio, output_image], |
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concurrency_limit=10, |
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) |
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gr.Examples( |
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[ |
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[os.path.join(os.path.dirname(__file__), "examples/jensen_24k.wav"), "bigvgan_v2_24khz_100band_256x"], |
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[os.path.join(os.path.dirname(__file__), "examples/libritts_24k.wav"), "bigvgan_v2_24khz_100band_256x"], |
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[os.path.join(os.path.dirname(__file__), "examples/queen_24k.wav"), "bigvgan_v2_24khz_100band_256x"], |
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[os.path.join(os.path.dirname(__file__), "examples/dance_24k.wav"), "bigvgan_v2_24khz_100band_256x"], |
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[os.path.join(os.path.dirname(__file__), "examples/megalovania_24k.wav"), "bigvgan_v2_24khz_100band_256x"], |
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[os.path.join(os.path.dirname(__file__), "examples/hifitts_44k.wav"), "bigvgan_v2_44khz_128band_256x"], |
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[os.path.join(os.path.dirname(__file__), "examples/musdbhq_44k.wav"), "bigvgan_v2_44khz_128band_256x"], |
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[os.path.join(os.path.dirname(__file__), "examples/musiccaps1_44k.wav"), "bigvgan_v2_44khz_128band_256x"], |
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[os.path.join(os.path.dirname(__file__), "examples/musiccaps2_44k.wav"), "bigvgan_v2_44khz_128band_256x"], |
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], |
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fn=inference_gradio, |
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inputs=[audio_input, model_choice], |
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outputs=[output_audio, output_image] |
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) |
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gr.HTML( |
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""" |
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<table border="1" cellspacing="0" cellpadding="5"> |
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<thead> |
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<tr> |
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<th>Model Name</th> |
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<th>Sampling Rate</th> |
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<th>Mel band</th> |
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<th>fmax</th> |
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<th>Upsampling Ratio</th> |
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<th>Parameters</th> |
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<th>Dataset</th> |
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<th>Fine-Tuned</th> |
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</tr> |
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</thead> |
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<tbody> |
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<tr> |
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<td>bigvgan_v2_44khz_128band_512x</td> |
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<td>44 kHz</td> |
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<td>128</td> |
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<td>22050</td> |
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<td>512</td> |
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<td>122M</td> |
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<td>Large-scale Compilation</td> |
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<td>No</td> |
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</tr> |
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<tr> |
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<td>bigvgan_v2_44khz_128band_256x</td> |
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<td>44 kHz</td> |
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<td>128</td> |
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<td>22050</td> |
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<td>256</td> |
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<td>112M</td> |
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<td>Large-scale Compilation</td> |
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<td>No</td> |
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</tr> |
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<tr> |
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<td>bigvgan_v2_24khz_100band_256x</td> |
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<td>24 kHz</td> |
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<td>100</td> |
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<td>12000</td> |
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<td>256</td> |
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<td>112M</td> |
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<td>Large-scale Compilation</td> |
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<td>No</td> |
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</tr> |
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<tr> |
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<td>bigvgan_v2_22khz_80band_256x</td> |
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<td>22 kHz</td> |
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<td>80</td> |
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<td>11025</td> |
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<td>256</td> |
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<td>112M</td> |
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<td>Large-scale Compilation</td> |
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<td>No</td> |
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</tr> |
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<tr> |
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<td>bigvgan_v2_22khz_80band_fmax8k_256x</td> |
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<td>22 kHz</td> |
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<td>80</td> |
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<td>8000</td> |
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<td>256</td> |
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<td>112M</td> |
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<td>Large-scale Compilation</td> |
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<td>No</td> |
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</tr> |
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<tr> |
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<td>bigvgan_24khz_100band</td> |
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<td>24 kHz</td> |
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<td>100</td> |
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<td>12000</td> |
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<td>256</td> |
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<td>112M</td> |
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<td>LibriTTS</td> |
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<td>No</td> |
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</tr> |
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<tr> |
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<td>bigvgan_base_24khz_100band</td> |
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<td>24 kHz</td> |
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<td>100</td> |
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<td>12000</td> |
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<td>256</td> |
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<td>14M</td> |
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<td>LibriTTS</td> |
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<td>No</td> |
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</tr> |
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<tr> |
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<td>bigvgan_22khz_80band</td> |
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<td>22 kHz</td> |
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<td>80</td> |
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<td>8000</td> |
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<td>256</td> |
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<td>112M</td> |
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<td>LibriTTS + VCTK + LJSpeech</td> |
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<td>No</td> |
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</tr> |
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<tr> |
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<td>bigvgan_base_22khz_80band</td> |
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<td>22 kHz</td> |
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<td>80</td> |
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<td>8000</td> |
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<td>256</td> |
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<td>14M</td> |
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<td>LibriTTS + VCTK + LJSpeech</td> |
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<td>No</td> |
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</tr> |
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</tbody> |
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</table> |
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<p><b>NOTE: The v1 models are trained using speech audio datasets ONLY! (24kHz models: LibriTTS, 22kHz models: LibriTTS + VCTK + LJSpeech).</b></p> |
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</div> |
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""" |
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) |
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iface.queue() |
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iface.launch() |
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