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import torch | |
import torch.nn as nn | |
from torch.nn import functional as F | |
import torch.fft as fft | |
import numpy as np | |
import librosa as li | |
import math | |
from scipy.signal import get_window | |
def safe_log(x): | |
return torch.log(x + 1e-7) | |
def mean_std_loudness(dataset): | |
mean = 0 | |
std = 0 | |
n = 0 | |
for _, _, l in dataset: | |
n += 1 | |
mean += (l.mean().item() - mean) / n | |
std += (l.std().item() - std) / n | |
return mean, std | |
def multiscale_fft(signal, scales, overlap): | |
stfts = [] | |
for s in scales: | |
S = torch.stft( | |
signal, | |
s, | |
int(s * (1 - overlap)), | |
s, | |
torch.hann_window(s).to(signal), | |
True, | |
normalized=True, | |
return_complex=True, | |
).abs() | |
stfts.append(S) | |
return stfts | |
def resample(x, factor: int): | |
batch, frame, channel = x.shape | |
x = x.permute(0, 2, 1).reshape(batch * channel, 1, frame) | |
window = torch.hann_window( | |
factor * 2, | |
dtype=x.dtype, | |
device=x.device, | |
).reshape(1, 1, -1) | |
y = torch.zeros(x.shape[0], x.shape[1], factor * x.shape[2]).to(x) | |
y[..., ::factor] = x | |
y[..., -1:] = x[..., -1:] | |
y = torch.nn.functional.pad(y, [factor, factor]) | |
y = torch.nn.functional.conv1d(y, window)[..., :-1] | |
y = y.reshape(batch, channel, factor * frame).permute(0, 2, 1) | |
return y | |
def upsample(signal, factor): | |
signal = signal.permute(0, 2, 1) | |
signal = nn.functional.interpolate(signal, size=signal.shape[-1] * factor) | |
return signal.permute(0, 2, 1) | |
def remove_above_nyquist(amplitudes, pitch, sampling_rate): | |
n_harm = amplitudes.shape[-1] | |
pitches = pitch * torch.arange(1, n_harm + 1).to(pitch) | |
aa = (pitches < sampling_rate / 2).float() + 1e-4 | |
return amplitudes * aa | |
def scale_function(x): | |
return 2 * torch.sigmoid(x) ** (math.log(10)) + 1e-7 | |
def extract_loudness(signal, sampling_rate, block_size, n_fft=2048): | |
S = li.stft( | |
signal, | |
n_fft=n_fft, | |
hop_length=block_size, | |
win_length=n_fft, | |
center=True, | |
) | |
S = np.log(abs(S) + 1e-7) | |
f = li.fft_frequencies(sampling_rate, n_fft) | |
a_weight = li.A_weighting(f) | |
S = S + a_weight.reshape(-1, 1) | |
S = np.mean(S, 0)[..., :-1] | |
return S | |
def extract_pitch(signal, sampling_rate, block_size): | |
length = signal.shape[-1] // block_size | |
f0 = crepe.predict( | |
signal, | |
sampling_rate, | |
step_size=int(1000 * block_size / sampling_rate), | |
verbose=1, | |
center=True, | |
viterbi=True, | |
) | |
f0 = f0[1].reshape(-1)[:-1] | |
if f0.shape[-1] != length: | |
f0 = np.interp( | |
np.linspace(0, 1, length, endpoint=False), | |
np.linspace(0, 1, f0.shape[-1], endpoint=False), | |
f0, | |
) | |
return f0 | |
def mlp(in_size, hidden_size, n_layers): | |
channels = [in_size] + (n_layers) * [hidden_size] | |
net = [] | |
for i in range(n_layers): | |
net.append(nn.Linear(channels[i], channels[i + 1])) | |
net.append(nn.LayerNorm(channels[i + 1])) | |
net.append(nn.LeakyReLU()) | |
return nn.Sequential(*net) | |
def gru(n_input, hidden_size): | |
return nn.GRU(n_input * hidden_size, hidden_size, batch_first=True) | |
def harmonic_synth(pitch, amplitudes, sampling_rate): | |
n_harmonic = amplitudes.shape[-1] | |
omega = torch.cumsum(2 * math.pi * pitch / sampling_rate, 1) | |
omegas = omega * torch.arange(1, n_harmonic + 1).to(omega) | |
signal = (torch.sin(omegas) * amplitudes).sum(-1, keepdim=True) | |
return signal | |
def amp_to_impulse_response(amp, target_size): | |
amp = torch.stack([amp, torch.zeros_like(amp)], -1) | |
amp = torch.view_as_complex(amp) | |
amp = fft.irfft(amp) | |
filter_size = amp.shape[-1] | |
amp = torch.roll(amp, filter_size // 2, -1) | |
win = torch.hann_window(filter_size, dtype=amp.dtype, device=amp.device) | |
amp = amp * win | |
amp = nn.functional.pad(amp, (0, int(target_size) - int(filter_size))) | |
amp = torch.roll(amp, -filter_size // 2, -1) | |
return amp | |
def fft_convolve(signal, kernel): | |
signal = nn.functional.pad(signal, (0, signal.shape[-1])) | |
kernel = nn.functional.pad(kernel, (kernel.shape[-1], 0)) | |
output = fft.irfft(fft.rfft(signal) * fft.rfft(kernel)) | |
output = output[..., output.shape[-1] // 2:] | |
return output | |
def init_kernels(win_len, win_inc, fft_len, win_type=None, invers=False): | |
if win_type == 'None' or win_type is None: | |
window = np.ones(win_len) | |
else: | |
window = get_window(win_type, win_len, fftbins=True) # **0.5 | |
N = fft_len | |
fourier_basis = np.fft.rfft(np.eye(N))[:win_len] | |
real_kernel = np.real(fourier_basis) | |
imag_kernel = np.imag(fourier_basis) | |
kernel = np.concatenate([real_kernel, imag_kernel], 1).T | |
if invers: | |
kernel = np.linalg.pinv(kernel).T | |
kernel = kernel * window | |
kernel = kernel[:, None, :] | |
return torch.from_numpy(kernel.astype(np.float32)), torch.from_numpy(window[None, :, None].astype(np.float32)) | |