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main_diff.py
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main_diff.py
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import os
import torch
import librosa
import argparse
import numpy as np
import soundfile as sf
import pyworld as pw
import parselmouth
import hashlib
from ast import literal_eval
from slicer import Slicer
from ddsp.vocoder import load_model, F0_Extractor, Volume_Extractor, Units_Encoder
from ddsp.core import upsample
from diffusion.vocoder import load_model_vocoder
from tqdm import tqdm
def check_args(ddsp_args, diff_args):
if ddsp_args.data.sampling_rate != diff_args.data.sampling_rate:
print("Unmatch data.sampling_rate!")
return False
if ddsp_args.data.block_size != diff_args.data.block_size:
print("Unmatch data.block_size!")
return False
if ddsp_args.data.encoder != diff_args.data.encoder:
print("Unmatch data.encoder!")
return False
return True
def parse_args(args=None, namespace=None):
"""Parse command-line arguments."""
parser = argparse.ArgumentParser()
parser.add_argument(
"-diff",
"--diff_ckpt",
type=str,
required=True,
help="path to the diffusion model checkpoint",
)
parser.add_argument(
"-ddsp",
"--ddsp_ckpt",
type=str,
required=False,
default=None,
help="path to the DDSP model checkpoint (for shallow diffusion)",
)
parser.add_argument(
"-d",
"--device",
type=str,
default=None,
required=False,
help="cpu or cuda, auto if not set")
parser.add_argument(
"-i",
"--input",
type=str,
required=True,
help="path to the input audio file",
)
parser.add_argument(
"-o",
"--output",
type=str,
required=True,
help="path to the output audio file",
)
parser.add_argument(
"-id",
"--spk_id",
type=str,
required=False,
default=1,
help="speaker id (for multi-speaker model) | default: 1",
)
parser.add_argument(
"-mix",
"--spk_mix_dict",
type=str,
required=False,
default="None",
help="mix-speaker dictionary (for multi-speaker model) | default: None",
)
parser.add_argument(
"-k",
"--key",
type=str,
required=False,
default=0,
help="key changed (number of semitones) | default: 0",
)
parser.add_argument(
"-f",
"--formant_shift_key",
type=str,
required=False,
default=0,
help="formant changed (number of semitones) , only for pitch-augmented model| default: 0",
)
parser.add_argument(
"-pe",
"--pitch_extractor",
type=str,
required=False,
default='rmvpe',
help="pitch extrator type: parselmouth, dio, harvest, crepe, fcpe, rmvpe (default)",
)
parser.add_argument(
"-fmin",
"--f0_min",
type=str,
required=False,
default=50,
help="min f0 (Hz) | default: 50",
)
parser.add_argument(
"-fmax",
"--f0_max",
type=str,
required=False,
default=1100,
help="max f0 (Hz) | default: 1100",
)
parser.add_argument(
"-th",
"--threhold",
type=str,
required=False,
default=-60,
help="response threhold (dB) | default: -60",
)
parser.add_argument(
"-diffid",
"--diff_spk_id",
type=str,
required=False,
default='auto',
help="diffusion speaker id (for multi-speaker model) | default: auto",
)
parser.add_argument(
"-speedup",
"--speedup",
type=str,
required=False,
default='auto',
help="speed up | default: auto",
)
parser.add_argument(
"-method",
"--method",
type=str,
required=False,
default='auto',
help="ddim, pndm, dpm-solver or unipc | default: auto",
)
parser.add_argument(
"-kstep",
"--k_step",
type=str,
required=False,
default=None,
help="shallow diffusion steps | default: None",
)
return parser.parse_args(args=args, namespace=namespace)
def split(audio, sample_rate, hop_size, db_thresh = -40, min_len = 5000):
slicer = Slicer(
sr=sample_rate,
threshold=db_thresh,
min_length=min_len)
chunks = dict(slicer.slice(audio))
result = []
for k, v in chunks.items():
tag = v["split_time"].split(",")
if tag[0] != tag[1]:
start_frame = int(int(tag[0]) // hop_size)
end_frame = int(int(tag[1]) // hop_size)
if end_frame > start_frame:
result.append((
start_frame,
audio[int(start_frame * hop_size) : int(end_frame * hop_size)]))
return result
def cross_fade(a: np.ndarray, b: np.ndarray, idx: int):
result = np.zeros(idx + b.shape[0])
fade_len = a.shape[0] - idx
np.copyto(dst=result[:idx], src=a[:idx])
k = np.linspace(0, 1.0, num=fade_len, endpoint=True)
result[idx: a.shape[0]] = (1 - k) * a[idx:] + k * b[: fade_len]
np.copyto(dst=result[a.shape[0]:], src=b[fade_len:])
return result
if __name__ == '__main__':
# parse commands
cmd = parse_args()
#device = 'cpu'
device = cmd.device
if device is None:
device = 'cuda' if torch.cuda.is_available() else 'cpu'
# load diffusion model
model, vocoder, args = load_model_vocoder(cmd.diff_ckpt, device=device)
# load input
audio, sample_rate = librosa.load(cmd.input, sr=None)
if len(audio.shape) > 1:
audio = librosa.to_mono(audio)
hop_size = args.data.block_size * sample_rate / args.data.sampling_rate
# get MD5 hash from wav file
md5_hash = ""
with open(cmd.input, 'rb') as f:
data = f.read()
md5_hash = hashlib.md5(data).hexdigest()
print("MD5: " + md5_hash)
cache_dir_path = os.path.join(os.path.dirname(__file__), "cache")
cache_file_path = os.path.join(cache_dir_path, f"{cmd.pitch_extractor}_{hop_size}_{cmd.f0_min}_{cmd.f0_max}_{md5_hash}.npy")
is_cache_available = os.path.exists(cache_file_path)
if is_cache_available:
# f0 cache load
print('Loading pitch curves for input audio from cache directory...')
f0 = np.load(cache_file_path, allow_pickle=False)
else:
# extract f0
print('Pitch extractor type: ' + cmd.pitch_extractor)
pitch_extractor = F0_Extractor(
cmd.pitch_extractor,
sample_rate,
hop_size,
float(cmd.f0_min),
float(cmd.f0_max))
print('Extracting the pitch curve of the input audio...')
f0 = pitch_extractor.extract(audio, uv_interp = True, device = device)
# f0 cache save
os.makedirs(cache_dir_path, exist_ok=True)
np.save(cache_file_path, f0, allow_pickle=False)
f0 = torch.from_numpy(f0).float().to(device).unsqueeze(-1).unsqueeze(0)
# key change
f0 = f0 * 2 ** (float(cmd.key) / 12)
# formant change
formant_shift_key = torch.from_numpy(np.array([[float(cmd.formant_shift_key)]])).float().to(device)
# extract volume
print('Extracting the volume envelope of the input audio...')
volume_extractor = Volume_Extractor(hop_size)
volume = volume_extractor.extract(audio)
mask = (volume > 10 ** (float(cmd.threhold) / 20)).astype('float')
mask = np.pad(mask, (4, 4), constant_values=(mask[0], mask[-1]))
mask = np.array([np.max(mask[n : n + 9]) for n in range(len(mask) - 8)])
mask = torch.from_numpy(mask).float().to(device).unsqueeze(-1).unsqueeze(0)
mask = upsample(mask, args.data.block_size).squeeze(-1)
volume = torch.from_numpy(volume).float().to(device).unsqueeze(-1).unsqueeze(0)
# load units encoder
if args.data.encoder == 'cnhubertsoftfish':
cnhubertsoft_gate = args.data.cnhubertsoft_gate
else:
cnhubertsoft_gate = 10
units_encoder = Units_Encoder(
args.data.encoder,
args.data.encoder_ckpt,
args.data.encoder_sample_rate,
args.data.encoder_hop_size,
cnhubertsoft_gate=cnhubertsoft_gate,
device = device)
# speaker id or mix-speaker dictionary
spk_mix_dict = literal_eval(cmd.spk_mix_dict)
spk_id = torch.LongTensor(np.array([[int(cmd.spk_id)]])).to(device)
if cmd.diff_spk_id == 'auto':
diff_spk_id = spk_id
else:
diff_spk_id = torch.LongTensor(np.array([[int(cmd.diff_spk_id)]])).to(device)
if spk_mix_dict is not None:
print('Mix-speaker mode')
else:
print('DDSP Speaker ID: '+ str(int(cmd.spk_id)))
print('Diffusion Speaker ID: '+ str(cmd.diff_spk_id))
# speed up
if cmd.speedup == 'auto':
infer_speedup = args.infer.speedup
else:
infer_speedup = int(cmd.speedup)
if cmd.method == 'auto':
method = args.infer.method
else:
method = cmd.method
if infer_speedup > 1:
print('Sampling method: '+ method)
print('Speed up: '+ str(infer_speedup))
else:
print('Sampling method: DDPM')
ddsp = None
input_mel = None
k_step = None
if args.model.type == 'DiffusionNew' or args.model.type == 'DiffusionFast':
if cmd.k_step is not None:
k_step = int(cmd.k_step)
if k_step > args.model.k_step_max:
k_step = args.model.k_step_max
else:
k_step = args.model.k_step_max
print('Shallow diffusion step: ' + str(k_step))
if cmd.ddsp_ckpt is not None:
# load ddsp model
ddsp, ddsp_args = load_model(cmd.ddsp_ckpt, device=device)
if not check_args(ddsp_args, args):
print("Cannot use this DDSP model for shallow diffusion, the built-in DDSP model will be used!")
ddsp = None
else:
print("DDSP model is not identified, the built-in DDSP model will be used!")
else:
if cmd.k_step is not None:
k_step = int(cmd.k_step)
print('Shallow diffusion step: ' + str(k_step))
if cmd.ddsp_ckpt is not None:
# load ddsp model
ddsp, ddsp_args = load_model(cmd.ddsp_ckpt, device=device)
if not check_args(ddsp_args, args):
print("Cannot use this DDSP model for shallow diffusion, gaussian diffusion will be used!")
ddsp = None
else:
print('DDSP model is not identified!')
print('Extracting the mel spectrum of the input audio for shallow diffusion...')
audio_t = torch.from_numpy(audio).float().unsqueeze(0).to(device)
input_mel = vocoder.extract(audio_t, sample_rate)
input_mel = torch.cat((input_mel, input_mel[:,-1:,:]), 1)
else:
print('Shallow diffusion step is not identified, gaussian diffusion will be used!')
# forward and save the output
result = np.zeros(0)
current_length = 0
segments = split(audio, sample_rate, hop_size)
print('Cut the input audio into ' + str(len(segments)) + ' slices')
with torch.no_grad():
for segment in tqdm(segments):
start_frame = segment[0]
seg_input = torch.from_numpy(segment[1]).float().unsqueeze(0).to(device)
seg_units = units_encoder.encode(seg_input, sample_rate, hop_size)
seg_f0 = f0[:, start_frame : start_frame + seg_units.size(1), :]
seg_volume = volume[:, start_frame : start_frame + seg_units.size(1), :]
if ddsp is not None:
seg_ddsp_f0 = 2 ** (-float(cmd.formant_shift_key) / 12) * seg_f0
seg_ddsp_output, _ , (_, _) = ddsp(seg_units, seg_ddsp_f0, seg_volume, spk_id = spk_id, spk_mix_dict = spk_mix_dict)
seg_input_mel = vocoder.extract(seg_ddsp_output, args.data.sampling_rate, keyshift=float(cmd.formant_shift_key))
elif input_mel is not None:
seg_input_mel = input_mel[:, start_frame : start_frame + seg_units.size(1), :]
else:
seg_input_mel = None
seg_mel = model(
seg_units,
seg_f0,
seg_volume,
spk_id = diff_spk_id,
spk_mix_dict = spk_mix_dict,
aug_shift = formant_shift_key,
vocoder=vocoder,
gt_spec=seg_input_mel,
infer=True,
infer_speedup=infer_speedup,
method=method,
k_step=k_step)
seg_output = vocoder.infer(seg_mel, seg_f0)
seg_output *= mask[:, start_frame * args.data.block_size : (start_frame + seg_units.size(1)) * args.data.block_size]
seg_output = seg_output.squeeze().cpu().numpy()
silent_length = round(start_frame * args.data.block_size) - current_length
if silent_length >= 0:
result = np.append(result, np.zeros(silent_length))
result = np.append(result, seg_output)
else:
result = cross_fade(result, seg_output, current_length + silent_length)
current_length = current_length + silent_length + len(seg_output)
sf.write(cmd.output, result, args.data.sampling_rate)