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import librosa |
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import torch |
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from torch import nn |
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class TorchSTFT(nn.Module): |
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"""Some of the audio processing funtions using Torch for faster batch processing. |
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Args: |
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n_fft (int): |
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FFT window size for STFT. |
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hop_length (int): |
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number of frames between STFT columns. |
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win_length (int, optional): |
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STFT window length. |
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pad_wav (bool, optional): |
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If True pad the audio with (n_fft - hop_length) / 2). Defaults to False. |
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window (str, optional): |
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The name of a function to create a window tensor that is applied/multiplied to each frame/window. Defaults to "hann_window" |
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sample_rate (int, optional): |
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target audio sampling rate. Defaults to None. |
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mel_fmin (int, optional): |
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minimum filter frequency for computing melspectrograms. Defaults to None. |
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mel_fmax (int, optional): |
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maximum filter frequency for computing melspectrograms. Defaults to None. |
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n_mels (int, optional): |
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number of melspectrogram dimensions. Defaults to None. |
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use_mel (bool, optional): |
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If True compute the melspectrograms otherwise. Defaults to False. |
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do_amp_to_db_linear (bool, optional): |
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enable/disable amplitude to dB conversion of linear spectrograms. Defaults to False. |
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spec_gain (float, optional): |
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gain applied when converting amplitude to DB. Defaults to 1.0. |
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power (float, optional): |
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Exponent for the magnitude spectrogram, e.g., 1 for energy, 2 for power, etc. Defaults to None. |
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use_htk (bool, optional): |
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Use HTK formula in mel filter instead of Slaney. |
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mel_norm (None, 'slaney', or number, optional): |
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If 'slaney', divide the triangular mel weights by the width of the mel band |
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(area normalization). |
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If numeric, use `librosa.util.normalize` to normalize each filter by to unit l_p norm. |
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See `librosa.util.normalize` for a full description of supported norm values |
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(including `+-np.inf`). |
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Otherwise, leave all the triangles aiming for a peak value of 1.0. Defaults to "slaney". |
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""" |
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def __init__( |
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self, |
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n_fft, |
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hop_length, |
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win_length, |
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pad_wav=False, |
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window="hann_window", |
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sample_rate=None, |
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mel_fmin=0, |
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mel_fmax=None, |
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n_mels=80, |
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use_mel=False, |
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do_amp_to_db=False, |
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spec_gain=1.0, |
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power=None, |
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use_htk=False, |
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mel_norm="slaney", |
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): |
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super().__init__() |
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self.n_fft = n_fft |
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self.hop_length = hop_length |
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self.win_length = win_length |
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self.pad_wav = pad_wav |
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self.sample_rate = sample_rate |
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self.mel_fmin = mel_fmin |
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self.mel_fmax = mel_fmax |
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self.n_mels = n_mels |
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self.use_mel = use_mel |
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self.do_amp_to_db = do_amp_to_db |
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self.spec_gain = spec_gain |
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self.power = power |
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self.use_htk = use_htk |
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self.mel_norm = mel_norm |
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self.window = nn.Parameter(getattr(torch, window)(win_length), requires_grad=False) |
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self.mel_basis = None |
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if use_mel: |
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self._build_mel_basis() |
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def __call__(self, x): |
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"""Compute spectrogram frames by torch based stft. |
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Args: |
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x (Tensor): input waveform |
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Returns: |
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Tensor: spectrogram frames. |
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Shapes: |
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x: [B x T] or [:math:`[B, 1, T]`] |
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""" |
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if x.ndim == 2: |
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x = x.unsqueeze(1) |
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if self.pad_wav: |
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padding = int((self.n_fft - self.hop_length) / 2) |
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x = torch.nn.functional.pad(x, (padding, padding), mode="reflect") |
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o = torch.stft( |
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x.squeeze(1), |
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self.n_fft, |
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self.hop_length, |
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self.win_length, |
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self.window, |
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center=True, |
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pad_mode="reflect", |
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normalized=False, |
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onesided=True, |
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return_complex=False, |
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) |
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M = o[:, :, :, 0] |
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P = o[:, :, :, 1] |
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S = torch.sqrt(torch.clamp(M**2 + P**2, min=1e-8)) |
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if self.power is not None: |
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S = S**self.power |
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if self.use_mel: |
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S = torch.matmul(self.mel_basis.to(x), S) |
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if self.do_amp_to_db: |
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S = self._amp_to_db(S, spec_gain=self.spec_gain) |
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return S |
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def _build_mel_basis(self): |
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mel_basis = librosa.filters.mel( |
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self.sample_rate, |
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self.n_fft, |
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n_mels=self.n_mels, |
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fmin=self.mel_fmin, |
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fmax=self.mel_fmax, |
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htk=self.use_htk, |
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norm=self.mel_norm, |
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) |
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self.mel_basis = torch.from_numpy(mel_basis).float() |
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@staticmethod |
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def _amp_to_db(x, spec_gain=1.0): |
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return torch.log(torch.clamp(x, min=1e-5) * spec_gain) |
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@staticmethod |
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def _db_to_amp(x, spec_gain=1.0): |
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return torch.exp(x) / spec_gain |
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