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"""Griffin-Lim related modules.""" |
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import logging |
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from distutils.version import LooseVersion |
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from functools import partial |
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from typeguard import check_argument_types |
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from typing import Optional |
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import librosa |
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import numpy as np |
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EPS = 1e-10 |
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def logmel2linear( |
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lmspc: np.ndarray, |
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fs: int, |
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n_fft: int, |
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n_mels: int, |
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fmin: int = None, |
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fmax: int = None, |
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) -> np.ndarray: |
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"""Convert log Mel filterbank to linear spectrogram. |
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Args: |
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lmspc: Log Mel filterbank (T, n_mels). |
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fs: Sampling frequency. |
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n_fft: The number of FFT points. |
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n_mels: The number of mel basis. |
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f_min: Minimum frequency to analyze. |
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f_max: Maximum frequency to analyze. |
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Returns: |
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Linear spectrogram (T, n_fft // 2 + 1). |
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""" |
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assert lmspc.shape[1] == n_mels |
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fmin = 0 if fmin is None else fmin |
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fmax = fs / 2 if fmax is None else fmax |
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mspc = np.power(10.0, lmspc) |
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mel_basis = librosa.filters.mel(fs, n_fft, n_mels, fmin, fmax) |
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inv_mel_basis = np.linalg.pinv(mel_basis) |
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return np.maximum(EPS, np.dot(inv_mel_basis, mspc.T).T) |
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def griffin_lim( |
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spc: np.ndarray, |
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n_fft: int, |
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n_shift: int, |
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win_length: int = None, |
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window: Optional[str] = "hann", |
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n_iter: Optional[int] = 32, |
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) -> np.ndarray: |
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"""Convert linear spectrogram into waveform using Griffin-Lim. |
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Args: |
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spc: Linear spectrogram (T, n_fft // 2 + 1). |
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n_fft: The number of FFT points. |
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n_shift: Shift size in points. |
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win_length: Window length in points. |
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window: Window function type. |
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n_iter: The number of iterations. |
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Returns: |
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Reconstructed waveform (N,). |
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""" |
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assert spc.shape[1] == n_fft // 2 + 1 |
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if LooseVersion(librosa.__version__) >= LooseVersion("0.7.0"): |
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spc = np.abs(spc.T) |
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y = librosa.griffinlim( |
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S=spc, |
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n_iter=n_iter, |
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hop_length=n_shift, |
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win_length=win_length, |
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window=window, |
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center=True if spc.shape[1] > 1 else False, |
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) |
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else: |
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logging.warning( |
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"librosa version is old. use slow version of Grriffin-Lim algorithm." |
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"if you want to use fast Griffin-Lim, please update librosa via " |
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"`source ./path.sh && pip install librosa==0.7.0`." |
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) |
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cspc = np.abs(spc).astype(np.complex).T |
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angles = np.exp(2j * np.pi * np.random.rand(*cspc.shape)) |
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y = librosa.istft(cspc * angles, n_shift, win_length, window=window) |
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for i in range(n_iter): |
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angles = np.exp( |
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1j |
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* np.angle(librosa.stft(y, n_fft, n_shift, win_length, window=window)) |
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) |
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y = librosa.istft(cspc * angles, n_shift, win_length, window=window) |
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return y |
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class Spectrogram2Waveform(object): |
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"""Spectrogram to waveform conversion module.""" |
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def __init__( |
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self, |
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n_fft: int, |
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n_shift: int, |
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fs: int = None, |
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n_mels: int = None, |
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win_length: int = None, |
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window: Optional[str] = "hann", |
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fmin: int = None, |
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fmax: int = None, |
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griffin_lim_iters: Optional[int] = 32, |
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): |
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"""Initialize module. |
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Args: |
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fs: Sampling frequency. |
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n_fft: The number of FFT points. |
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n_shift: Shift size in points. |
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n_mels: The number of mel basis. |
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win_length: Window length in points. |
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window: Window function type. |
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f_min: Minimum frequency to analyze. |
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f_max: Maximum frequency to analyze. |
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griffin_lim_iters: The number of iterations. |
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""" |
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assert check_argument_types() |
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self.fs = fs |
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self.logmel2linear = ( |
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partial( |
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logmel2linear, fs=fs, n_fft=n_fft, n_mels=n_mels, fmin=fmin, fmax=fmax |
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) |
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if n_mels is not None |
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else None |
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) |
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self.griffin_lim = partial( |
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griffin_lim, |
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n_fft=n_fft, |
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n_shift=n_shift, |
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win_length=win_length, |
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window=window, |
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n_iter=griffin_lim_iters, |
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) |
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self.params = dict( |
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n_fft=n_fft, |
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n_shift=n_shift, |
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win_length=win_length, |
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window=window, |
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n_iter=griffin_lim_iters, |
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) |
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if n_mels is not None: |
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self.params.update(fs=fs, n_mels=n_mels, fmin=fmin, fmax=fmax) |
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def __repr__(self): |
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retval = f"{self.__class__.__name__}(" |
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for k, v in self.params.items(): |
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retval += f"{k}={v}, " |
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retval += ")" |
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return retval |
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def __call__(self, spc): |
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"""Convert spectrogram to waveform. |
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Args: |
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spc: Log Mel filterbank (T, n_mels) |
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or linear spectrogram (T, n_fft // 2 + 1). |
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Returns: |
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Reconstructed waveform (N,). |
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""" |
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if self.logmel2linear is not None: |
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spc = self.logmel2linear(spc) |
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return self.griffin_lim(spc) |
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