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| import math | |
| import numpy as np | |
| import librosa | |
| import vocoder.hparams as hp | |
| from scipy.signal import lfilter | |
| import soundfile as sf | |
| def label_2_float(x, bits) : | |
| return 2 * x / (2**bits - 1.) - 1. | |
| def float_2_label(x, bits) : | |
| assert abs(x).max() <= 1.0 | |
| x = (x + 1.) * (2**bits - 1) / 2 | |
| return x.clip(0, 2**bits - 1) | |
| def load_wav(path) : | |
| return librosa.load(str(path), sr=hp.sample_rate)[0] | |
| def save_wav(x, path) : | |
| sf.write(path, x.astype(np.float32), hp.sample_rate) | |
| def split_signal(x) : | |
| unsigned = x + 2**15 | |
| coarse = unsigned // 256 | |
| fine = unsigned % 256 | |
| return coarse, fine | |
| def combine_signal(coarse, fine) : | |
| return coarse * 256 + fine - 2**15 | |
| def encode_16bits(x) : | |
| return np.clip(x * 2**15, -2**15, 2**15 - 1).astype(np.int16) | |
| mel_basis = None | |
| def linear_to_mel(spectrogram): | |
| global mel_basis | |
| if mel_basis is None: | |
| mel_basis = build_mel_basis() | |
| return np.dot(mel_basis, spectrogram) | |
| def build_mel_basis(): | |
| return librosa.filters.mel(hp.sample_rate, hp.n_fft, n_mels=hp.num_mels, fmin=hp.fmin) | |
| def normalize(S): | |
| return np.clip((S - hp.min_level_db) / -hp.min_level_db, 0, 1) | |
| def denormalize(S): | |
| return (np.clip(S, 0, 1) * -hp.min_level_db) + hp.min_level_db | |
| def amp_to_db(x): | |
| return 20 * np.log10(np.maximum(1e-5, x)) | |
| def db_to_amp(x): | |
| return np.power(10.0, x * 0.05) | |
| def spectrogram(y): | |
| D = stft(y) | |
| S = amp_to_db(np.abs(D)) - hp.ref_level_db | |
| return normalize(S) | |
| def melspectrogram(y): | |
| D = stft(y) | |
| S = amp_to_db(linear_to_mel(np.abs(D))) | |
| return normalize(S) | |
| def stft(y): | |
| return librosa.stft(y=y, n_fft=hp.n_fft, hop_length=hp.hop_length, win_length=hp.win_length) | |
| def pre_emphasis(x): | |
| return lfilter([1, -hp.preemphasis], [1], x) | |
| def de_emphasis(x): | |
| return lfilter([1], [1, -hp.preemphasis], x) | |
| def encode_mu_law(x, mu) : | |
| mu = mu - 1 | |
| fx = np.sign(x) * np.log(1 + mu * np.abs(x)) / np.log(1 + mu) | |
| return np.floor((fx + 1) / 2 * mu + 0.5) | |
| def decode_mu_law(y, mu, from_labels=True) : | |
| if from_labels: | |
| y = label_2_float(y, math.log2(mu)) | |
| mu = mu - 1 | |
| x = np.sign(y) / mu * ((1 + mu) ** np.abs(y) - 1) | |
| return x | |