Source code for torchaudio.transforms._transforms
# -*- coding: utf-8 -*-
import math
import warnings
from typing import Callable, Optional, Union
import torch
from torch import Tensor
from torch.nn.modules.lazy import LazyModuleMixin
from torch.nn.parameter import UninitializedParameter
from torchaudio import functional as F
from torchaudio.functional.functional import (
_apply_sinc_resample_kernel,
_fix_waveform_shape,
_get_sinc_resample_kernel,
_stretch_waveform,
)
__all__ = []
[docs]class Spectrogram(torch.nn.Module):
r"""Create a spectrogram from a audio signal.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
Args:
n_fft (int, optional): Size of FFT, creates ``n_fft // 2 + 1`` bins. (Default: ``400``)
win_length (int or None, optional): Window size. (Default: ``n_fft``)
hop_length (int or None, optional): Length of hop between STFT windows. (Default: ``win_length // 2``)
pad (int, optional): Two sided padding of signal. (Default: ``0``)
window_fn (Callable[..., Tensor], optional): A function to create a window tensor
that is applied/multiplied to each frame/window. (Default: ``torch.hann_window``)
power (float or None, optional): Exponent for the magnitude spectrogram,
(must be > 0) e.g., 1 for energy, 2 for power, etc.
If None, then the complex spectrum is returned instead. (Default: ``2``)
normalized (bool or str, optional): Whether to normalize by magnitude after stft. If input is str, choices are
``"window"`` and ``"frame_length"``, if specific normalization type is desirable. ``True`` maps to
``"window"``. (Default: ``False``)
wkwargs (dict or None, optional): Arguments for window function. (Default: ``None``)
center (bool, optional): whether to pad :attr:`waveform` on both sides so
that the :math:`t`-th frame is centered at time :math:`t \times \text{hop\_length}`.
(Default: ``True``)
pad_mode (string, optional): controls the padding method used when
:attr:`center` is ``True``. (Default: ``"reflect"``)
onesided (bool, optional): controls whether to return half of results to
avoid redundancy (Default: ``True``)
return_complex (bool, optional):
Deprecated and not used.
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = torchaudio.transforms.Spectrogram(n_fft=800)
>>> spectrogram = transform(waveform)
"""
__constants__ = ["n_fft", "win_length", "hop_length", "pad", "power", "normalized"]
def __init__(
self,
n_fft: int = 400,
win_length: Optional[int] = None,
hop_length: Optional[int] = None,
pad: int = 0,
window_fn: Callable[..., Tensor] = torch.hann_window,
power: Optional[float] = 2.0,
normalized: Union[bool, str] = False,
wkwargs: Optional[dict] = None,
center: bool = True,
pad_mode: str = "reflect",
onesided: bool = True,
return_complex: Optional[bool] = None,
) -> None:
super(Spectrogram, self).__init__()
self.n_fft = n_fft
# number of FFT bins. the returned STFT result will have n_fft // 2 + 1
# number of frequencies due to onesided=True in torch.stft
self.win_length = win_length if win_length is not None else n_fft
self.hop_length = hop_length if hop_length is not None else self.win_length // 2
window = window_fn(self.win_length) if wkwargs is None else window_fn(self.win_length, **wkwargs)
self.register_buffer("window", window)
self.pad = pad
self.power = power
self.normalized = normalized
self.center = center
self.pad_mode = pad_mode
self.onesided = onesided
if return_complex is not None:
warnings.warn(
"`return_complex` argument is now deprecated and is not effective."
"`torchaudio.transforms.Spectrogram(power=None)` always returns a tensor with "
"complex dtype. Please remove the argument in the function call."
)
[docs] def forward(self, waveform: Tensor) -> Tensor:
r"""
Args:
waveform (Tensor): Tensor of audio of dimension (..., time).
Returns:
Tensor: Dimension (..., freq, time), where freq is
``n_fft // 2 + 1`` where ``n_fft`` is the number of
Fourier bins, and time is the number of window hops (n_frame).
"""
return F.spectrogram(
waveform,
self.pad,
self.window,
self.n_fft,
self.hop_length,
self.win_length,
self.power,
self.normalized,
self.center,
self.pad_mode,
self.onesided,
)
[docs]class InverseSpectrogram(torch.nn.Module):
r"""Create an inverse spectrogram to recover an audio signal from a spectrogram.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
Args:
n_fft (int, optional): Size of FFT, creates ``n_fft // 2 + 1`` bins. (Default: ``400``)
win_length (int or None, optional): Window size. (Default: ``n_fft``)
hop_length (int or None, optional): Length of hop between STFT windows. (Default: ``win_length // 2``)
pad (int, optional): Two sided padding of signal. (Default: ``0``)
window_fn (Callable[..., Tensor], optional): A function to create a window tensor
that is applied/multiplied to each frame/window. (Default: ``torch.hann_window``)
normalized (bool or str, optional): Whether the stft output was normalized by magnitude. If input is str,
choices are ``"window"`` and ``"frame_length"``, dependent on normalization mode. ``True`` maps to
``"window"``. (Default: ``False``)
wkwargs (dict or None, optional): Arguments for window function. (Default: ``None``)
center (bool, optional): whether the signal in spectrogram was padded on both sides so
that the :math:`t`-th frame is centered at time :math:`t \times \text{hop\_length}`.
(Default: ``True``)
pad_mode (string, optional): controls the padding method used when
:attr:`center` is ``True``. (Default: ``"reflect"``)
onesided (bool, optional): controls whether spectrogram was used to return half of results to
avoid redundancy (Default: ``True``)
Example
>>> batch, freq, time = 2, 257, 100
>>> length = 25344
>>> spectrogram = torch.randn(batch, freq, time, dtype=torch.cdouble)
>>> transform = transforms.InverseSpectrogram(n_fft=512)
>>> waveform = transform(spectrogram, length)
"""
__constants__ = ["n_fft", "win_length", "hop_length", "pad", "power", "normalized"]
def __init__(
self,
n_fft: int = 400,
win_length: Optional[int] = None,
hop_length: Optional[int] = None,
pad: int = 0,
window_fn: Callable[..., Tensor] = torch.hann_window,
normalized: Union[bool, str] = False,
wkwargs: Optional[dict] = None,
center: bool = True,
pad_mode: str = "reflect",
onesided: bool = True,
) -> None:
super(InverseSpectrogram, self).__init__()
self.n_fft = n_fft
# number of FFT bins. the returned STFT result will have n_fft // 2 + 1
# number of frequencies due to onesided=True in torch.stft
self.win_length = win_length if win_length is not None else n_fft
self.hop_length = hop_length if hop_length is not None else self.win_length // 2
window = window_fn(self.win_length) if wkwargs is None else window_fn(self.win_length, **wkwargs)
self.register_buffer("window", window)
self.pad = pad
self.normalized = normalized
self.center = center
self.pad_mode = pad_mode
self.onesided = onesided
[docs] def forward(self, spectrogram: Tensor, length: Optional[int] = None) -> Tensor:
r"""
Args:
spectrogram (Tensor): Complex tensor of audio of dimension (..., freq, time).
length (int or None, optional): The output length of the waveform.
Returns:
Tensor: Dimension (..., time), Least squares estimation of the original signal.
"""
return F.inverse_spectrogram(
spectrogram,
length,
self.pad,
self.window,
self.n_fft,
self.hop_length,
self.win_length,
self.normalized,
self.center,
self.pad_mode,
self.onesided,
)
[docs]class GriffinLim(torch.nn.Module):
r"""Compute waveform from a linear scale magnitude spectrogram using the Griffin-Lim transformation.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
Implementation ported from
*librosa* :cite:`brian_mcfee-proc-scipy-2015`, *A fast Griffin-Lim algorithm* :cite:`6701851`
and *Signal estimation from modified short-time Fourier transform* :cite:`1172092`.
Args:
n_fft (int, optional): Size of FFT, creates ``n_fft // 2 + 1`` bins. (Default: ``400``)
n_iter (int, optional): Number of iteration for phase recovery process. (Default: ``32``)
win_length (int or None, optional): Window size. (Default: ``n_fft``)
hop_length (int or None, optional): Length of hop between STFT windows. (Default: ``win_length // 2``)
window_fn (Callable[..., Tensor], optional): A function to create a window tensor
that is applied/multiplied to each frame/window. (Default: ``torch.hann_window``)
power (float, optional): Exponent for the magnitude spectrogram,
(must be > 0) e.g., 1 for energy, 2 for power, etc. (Default: ``2``)
wkwargs (dict or None, optional): Arguments for window function. (Default: ``None``)
momentum (float, optional): The momentum parameter for fast Griffin-Lim.
Setting this to 0 recovers the original Griffin-Lim method.
Values near 1 can lead to faster convergence, but above 1 may not converge. (Default: ``0.99``)
length (int, optional): Array length of the expected output. (Default: ``None``)
rand_init (bool, optional): Initializes phase randomly if True and to zero otherwise. (Default: ``True``)
Example
>>> batch, freq, time = 2, 257, 100
>>> spectrogram = torch.randn(batch, freq, time)
>>> transform = transforms.GriffinLim(n_fft=512)
>>> waveform = transform(spectrogram)
"""
__constants__ = ["n_fft", "n_iter", "win_length", "hop_length", "power", "length", "momentum", "rand_init"]
def __init__(
self,
n_fft: int = 400,
n_iter: int = 32,
win_length: Optional[int] = None,
hop_length: Optional[int] = None,
window_fn: Callable[..., Tensor] = torch.hann_window,
power: float = 2.0,
wkwargs: Optional[dict] = None,
momentum: float = 0.99,
length: Optional[int] = None,
rand_init: bool = True,
) -> None:
super(GriffinLim, self).__init__()
if not (0 <= momentum < 1):
raise ValueError("momentum must be in the range [0, 1). Found: {}".format(momentum))
self.n_fft = n_fft
self.n_iter = n_iter
self.win_length = win_length if win_length is not None else n_fft
self.hop_length = hop_length if hop_length is not None else self.win_length // 2
window = window_fn(self.win_length) if wkwargs is None else window_fn(self.win_length, **wkwargs)
self.register_buffer("window", window)
self.length = length
self.power = power
self.momentum = momentum
self.rand_init = rand_init
[docs] def forward(self, specgram: Tensor) -> Tensor:
r"""
Args:
specgram (Tensor):
A magnitude-only STFT spectrogram of dimension (..., freq, frames)
where freq is ``n_fft // 2 + 1``.
Returns:
Tensor: waveform of (..., time), where time equals the ``length`` parameter if given.
"""
return F.griffinlim(
specgram,
self.window,
self.n_fft,
self.hop_length,
self.win_length,
self.power,
self.n_iter,
self.momentum,
self.length,
self.rand_init,
)
[docs]class AmplitudeToDB(torch.nn.Module):
r"""Turn a tensor from the power/amplitude scale to the decibel scale.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
This output depends on the maximum value in the input tensor, and so
may return different values for an audio clip split into snippets vs. a
a full clip.
Args:
stype (str, optional): scale of input tensor (``"power"`` or ``"magnitude"``). The
power being the elementwise square of the magnitude. (Default: ``"power"``)
top_db (float or None, optional): minimum negative cut-off in decibels. A reasonable
number is 80. (Default: ``None``)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = transforms.AmplitudeToDB(stype="amplitude", top_db=80)
>>> waveform_db = transform(waveform)
"""
__constants__ = ["multiplier", "amin", "ref_value", "db_multiplier"]
def __init__(self, stype: str = "power", top_db: Optional[float] = None) -> None:
super(AmplitudeToDB, self).__init__()
self.stype = stype
if top_db is not None and top_db < 0:
raise ValueError("top_db must be positive value")
self.top_db = top_db
self.multiplier = 10.0 if stype == "power" else 20.0
self.amin = 1e-10
self.ref_value = 1.0
self.db_multiplier = math.log10(max(self.amin, self.ref_value))
[docs] def forward(self, x: Tensor) -> Tensor:
r"""Numerically stable implementation from Librosa.
https://librosa.org/doc/latest/generated/librosa.amplitude_to_db.html
Args:
x (Tensor): Input tensor before being converted to decibel scale.
Returns:
Tensor: Output tensor in decibel scale.
"""
return F.amplitude_to_DB(x, self.multiplier, self.amin, self.db_multiplier, self.top_db)
[docs]class MelScale(torch.nn.Module):
r"""Turn a normal STFT into a mel frequency STFT with triangular filter banks.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
Args:
n_mels (int, optional): Number of mel filterbanks. (Default: ``128``)
sample_rate (int, optional): Sample rate of audio signal. (Default: ``16000``)
f_min (float, optional): Minimum frequency. (Default: ``0.``)
f_max (float or None, optional): Maximum frequency. (Default: ``sample_rate // 2``)
n_stft (int, optional): Number of bins in STFT. See ``n_fft`` in :class:`Spectrogram`. (Default: ``201``)
norm (str or None, optional): If ``"slaney"``, divide the triangular mel weights by the width of the mel band
(area normalization). (Default: ``None``)
mel_scale (str, optional): Scale to use: ``htk`` or ``slaney``. (Default: ``htk``)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> spectrogram_transform = transforms.Spectrogram(n_fft=1024)
>>> spectrogram = spectrogram_transform(waveform)
>>> melscale_transform = transforms.MelScale(sample_rate=sample_rate, n_stft=1024 // 2 + 1)
>>> melscale_spectrogram = melscale_transform(spectrogram)
See also:
:py:func:`torchaudio.functional.melscale_fbanks` - The function used to
generate the filter banks.
"""
__constants__ = ["n_mels", "sample_rate", "f_min", "f_max"]
def __init__(
self,
n_mels: int = 128,
sample_rate: int = 16000,
f_min: float = 0.0,
f_max: Optional[float] = None,
n_stft: int = 201,
norm: Optional[str] = None,
mel_scale: str = "htk",
) -> None:
super(MelScale, self).__init__()
self.n_mels = n_mels
self.sample_rate = sample_rate
self.f_max = f_max if f_max is not None else float(sample_rate // 2)
self.f_min = f_min
self.norm = norm
self.mel_scale = mel_scale
if f_min > self.f_max:
raise ValueError("Require f_min: {} <= f_max: {}".format(f_min, self.f_max))
fb = F.melscale_fbanks(n_stft, self.f_min, self.f_max, self.n_mels, self.sample_rate, self.norm, self.mel_scale)
self.register_buffer("fb", fb)
[docs] def forward(self, specgram: Tensor) -> Tensor:
r"""
Args:
specgram (Tensor): A spectrogram STFT of dimension (..., freq, time).
Returns:
Tensor: Mel frequency spectrogram of size (..., ``n_mels``, time).
"""
# (..., time, freq) dot (freq, n_mels) -> (..., n_mels, time)
mel_specgram = torch.matmul(specgram.transpose(-1, -2), self.fb).transpose(-1, -2)
return mel_specgram
[docs]class InverseMelScale(torch.nn.Module):
r"""Estimate a STFT in normal frequency domain from mel frequency domain.
.. devices:: CPU CUDA
It minimizes the euclidian norm between the input mel-spectrogram and the product between
the estimated spectrogram and the filter banks using SGD.
Args:
n_stft (int): Number of bins in STFT. See ``n_fft`` in :class:`Spectrogram`.
n_mels (int, optional): Number of mel filterbanks. (Default: ``128``)
sample_rate (int, optional): Sample rate of audio signal. (Default: ``16000``)
f_min (float, optional): Minimum frequency. (Default: ``0.``)
f_max (float or None, optional): Maximum frequency. (Default: ``sample_rate // 2``)
max_iter (int, optional): Maximum number of optimization iterations. (Default: ``100000``)
tolerance_loss (float, optional): Value of loss to stop optimization at. (Default: ``1e-5``)
tolerance_change (float, optional): Difference in losses to stop optimization at. (Default: ``1e-8``)
sgdargs (dict or None, optional): Arguments for the SGD optimizer. (Default: ``None``)
norm (str or None, optional): If "slaney", divide the triangular mel weights by the width of the mel band
(area normalization). (Default: ``None``)
mel_scale (str, optional): Scale to use: ``htk`` or ``slaney``. (Default: ``htk``)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> mel_spectrogram_transform = transforms.MelSpectrogram(sample_rate, n_fft=1024)
>>> mel_spectrogram = mel_spectrogram_transform(waveform)
>>> inverse_melscale_transform = transforms.InverseMelScale(n_stft=1024 // 2 + 1)
>>> spectrogram = inverse_melscale_transform(mel_spectrogram)
"""
__constants__ = [
"n_stft",
"n_mels",
"sample_rate",
"f_min",
"f_max",
"max_iter",
"tolerance_loss",
"tolerance_change",
"sgdargs",
]
def __init__(
self,
n_stft: int,
n_mels: int = 128,
sample_rate: int = 16000,
f_min: float = 0.0,
f_max: Optional[float] = None,
max_iter: int = 100000,
tolerance_loss: float = 1e-5,
tolerance_change: float = 1e-8,
sgdargs: Optional[dict] = None,
norm: Optional[str] = None,
mel_scale: str = "htk",
) -> None:
super(InverseMelScale, self).__init__()
self.n_mels = n_mels
self.sample_rate = sample_rate
self.f_max = f_max or float(sample_rate // 2)
self.f_min = f_min
self.max_iter = max_iter
self.tolerance_loss = tolerance_loss
self.tolerance_change = tolerance_change
self.sgdargs = sgdargs or {"lr": 0.1, "momentum": 0.9}
if f_min > self.f_max:
raise ValueError("Require f_min: {} <= f_max: {}".format(f_min, self.f_max))
fb = F.melscale_fbanks(n_stft, self.f_min, self.f_max, self.n_mels, self.sample_rate, norm, mel_scale)
self.register_buffer("fb", fb)
[docs] def forward(self, melspec: Tensor) -> Tensor:
r"""
Args:
melspec (Tensor): A Mel frequency spectrogram of dimension (..., ``n_mels``, time)
Returns:
Tensor: Linear scale spectrogram of size (..., freq, time)
"""
# pack batch
shape = melspec.size()
melspec = melspec.view(-1, shape[-2], shape[-1])
n_mels, time = shape[-2], shape[-1]
freq, _ = self.fb.size() # (freq, n_mels)
melspec = melspec.transpose(-1, -2)
if self.n_mels != n_mels:
raise ValueError("Expected an input with {} mel bins. Found: {}".format(self.n_mels, n_mels))
specgram = torch.rand(
melspec.size()[0], time, freq, requires_grad=True, dtype=melspec.dtype, device=melspec.device
)
optim = torch.optim.SGD([specgram], **self.sgdargs)
loss = float("inf")
for _ in range(self.max_iter):
optim.zero_grad()
diff = melspec - specgram.matmul(self.fb)
new_loss = diff.pow(2).sum(axis=-1).mean()
# take sum over mel-frequency then average over other dimensions
# so that loss threshold is applied par unit timeframe
new_loss.backward()
optim.step()
specgram.data = specgram.data.clamp(min=0)
new_loss = new_loss.item()
if new_loss < self.tolerance_loss or abs(loss - new_loss) < self.tolerance_change:
break
loss = new_loss
specgram.requires_grad_(False)
specgram = specgram.clamp(min=0).transpose(-1, -2)
# unpack batch
specgram = specgram.view(shape[:-2] + (freq, time))
return specgram
[docs]class MelSpectrogram(torch.nn.Module):
r"""Create MelSpectrogram for a raw audio signal.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
This is a composition of :py:func:`torchaudio.transforms.Spectrogram` and
and :py:func:`torchaudio.transforms.MelScale`.
Sources
* https://gist.github.com/kastnerkyle/179d6e9a88202ab0a2fe
* https://timsainb.github.io/spectrograms-mfccs-and-inversion-in-python.html
* http://haythamfayek.com/2016/04/21/speech-processing-for-machine-learning.html
Args:
sample_rate (int, optional): Sample rate of audio signal. (Default: ``16000``)
n_fft (int, optional): Size of FFT, creates ``n_fft // 2 + 1`` bins. (Default: ``400``)
win_length (int or None, optional): Window size. (Default: ``n_fft``)
hop_length (int or None, optional): Length of hop between STFT windows. (Default: ``win_length // 2``)
f_min (float, optional): Minimum frequency. (Default: ``0.``)
f_max (float or None, optional): Maximum frequency. (Default: ``None``)
pad (int, optional): Two sided padding of signal. (Default: ``0``)
n_mels (int, optional): Number of mel filterbanks. (Default: ``128``)
window_fn (Callable[..., Tensor], optional): A function to create a window tensor
that is applied/multiplied to each frame/window. (Default: ``torch.hann_window``)
power (float, optional): Exponent for the magnitude spectrogram,
(must be > 0) e.g., 1 for energy, 2 for power, etc. (Default: ``2``)
normalized (bool, optional): Whether to normalize by magnitude after stft. (Default: ``False``)
wkwargs (Dict[..., ...] or None, optional): Arguments for window function. (Default: ``None``)
center (bool, optional): whether to pad :attr:`waveform` on both sides so
that the :math:`t`-th frame is centered at time :math:`t \times \text{hop\_length}`.
(Default: ``True``)
pad_mode (string, optional): controls the padding method used when
:attr:`center` is ``True``. (Default: ``"reflect"``)
onesided (bool, optional): controls whether to return half of results to
avoid redundancy. (Default: ``True``)
norm (str or None, optional): If "slaney", divide the triangular mel weights by the width of the mel band
(area normalization). (Default: ``None``)
mel_scale (str, optional): Scale to use: ``htk`` or ``slaney``. (Default: ``htk``)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = transforms.MelSpectrogram(sample_rate)
>>> mel_specgram = transform(waveform) # (channel, n_mels, time)
See also:
:py:func:`torchaudio.functional.melscale_fbanks` - The function used to
generate the filter banks.
"""
__constants__ = ["sample_rate", "n_fft", "win_length", "hop_length", "pad", "n_mels", "f_min"]
def __init__(
self,
sample_rate: int = 16000,
n_fft: int = 400,
win_length: Optional[int] = None,
hop_length: Optional[int] = None,
f_min: float = 0.0,
f_max: Optional[float] = None,
pad: int = 0,
n_mels: int = 128,
window_fn: Callable[..., Tensor] = torch.hann_window,
power: float = 2.0,
normalized: bool = False,
wkwargs: Optional[dict] = None,
center: bool = True,
pad_mode: str = "reflect",
onesided: bool = True,
norm: Optional[str] = None,
mel_scale: str = "htk",
) -> None:
super(MelSpectrogram, self).__init__()
self.sample_rate = sample_rate
self.n_fft = n_fft
self.win_length = win_length if win_length is not None else n_fft
self.hop_length = hop_length if hop_length is not None else self.win_length // 2
self.pad = pad
self.power = power
self.normalized = normalized
self.n_mels = n_mels # number of mel frequency bins
self.f_max = f_max
self.f_min = f_min
self.spectrogram = Spectrogram(
n_fft=self.n_fft,
win_length=self.win_length,
hop_length=self.hop_length,
pad=self.pad,
window_fn=window_fn,
power=self.power,
normalized=self.normalized,
wkwargs=wkwargs,
center=center,
pad_mode=pad_mode,
onesided=onesided,
)
self.mel_scale = MelScale(
self.n_mels, self.sample_rate, self.f_min, self.f_max, self.n_fft // 2 + 1, norm, mel_scale
)
[docs] def forward(self, waveform: Tensor) -> Tensor:
r"""
Args:
waveform (Tensor): Tensor of audio of dimension (..., time).
Returns:
Tensor: Mel frequency spectrogram of size (..., ``n_mels``, time).
"""
specgram = self.spectrogram(waveform)
mel_specgram = self.mel_scale(specgram)
return mel_specgram
[docs]class MFCC(torch.nn.Module):
r"""Create the Mel-frequency cepstrum coefficients from an audio signal.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
By default, this calculates the MFCC on the DB-scaled Mel spectrogram.
This is not the textbook implementation, but is implemented here to
give consistency with librosa.
This output depends on the maximum value in the input spectrogram, and so
may return different values for an audio clip split into snippets vs. a
a full clip.
Args:
sample_rate (int, optional): Sample rate of audio signal. (Default: ``16000``)
n_mfcc (int, optional): Number of mfc coefficients to retain. (Default: ``40``)
dct_type (int, optional): type of DCT (discrete cosine transform) to use. (Default: ``2``)
norm (str, optional): norm to use. (Default: ``"ortho"``)
log_mels (bool, optional): whether to use log-mel spectrograms instead of db-scaled. (Default: ``False``)
melkwargs (dict or None, optional): arguments for MelSpectrogram. (Default: ``None``)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = transforms.MFCC(
>>> sample_rate=sample_rate,
>>> n_mfcc=13,
>>> melkwargs={"n_fft": 400, "hop_length": 160, "n_mels": 23, "center": False},
>>> )
>>> mfcc = transform(waveform)
See also:
:py:func:`torchaudio.functional.melscale_fbanks` - The function used to
generate the filter banks.
"""
__constants__ = ["sample_rate", "n_mfcc", "dct_type", "top_db", "log_mels"]
def __init__(
self,
sample_rate: int = 16000,
n_mfcc: int = 40,
dct_type: int = 2,
norm: str = "ortho",
log_mels: bool = False,
melkwargs: Optional[dict] = None,
) -> None:
super(MFCC, self).__init__()
supported_dct_types = [2]
if dct_type not in supported_dct_types:
raise ValueError("DCT type not supported: {}".format(dct_type))
self.sample_rate = sample_rate
self.n_mfcc = n_mfcc
self.dct_type = dct_type
self.norm = norm
self.top_db = 80.0
self.amplitude_to_DB = AmplitudeToDB("power", self.top_db)
melkwargs = melkwargs or {}
self.MelSpectrogram = MelSpectrogram(sample_rate=self.sample_rate, **melkwargs)
if self.n_mfcc > self.MelSpectrogram.n_mels:
raise ValueError("Cannot select more MFCC coefficients than # mel bins")
dct_mat = F.create_dct(self.n_mfcc, self.MelSpectrogram.n_mels, self.norm)
self.register_buffer("dct_mat", dct_mat)
self.log_mels = log_mels
[docs] def forward(self, waveform: Tensor) -> Tensor:
r"""
Args:
waveform (Tensor): Tensor of audio of dimension (..., time).
Returns:
Tensor: specgram_mel_db of size (..., ``n_mfcc``, time).
"""
mel_specgram = self.MelSpectrogram(waveform)
if self.log_mels:
log_offset = 1e-6
mel_specgram = torch.log(mel_specgram + log_offset)
else:
mel_specgram = self.amplitude_to_DB(mel_specgram)
# (..., time, n_mels) dot (n_mels, n_mfcc) -> (..., n_nfcc, time)
mfcc = torch.matmul(mel_specgram.transpose(-1, -2), self.dct_mat).transpose(-1, -2)
return mfcc
[docs]class LFCC(torch.nn.Module):
r"""Create the linear-frequency cepstrum coefficients from an audio signal.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
By default, this calculates the LFCC on the DB-scaled linear filtered spectrogram.
This is not the textbook implementation, but is implemented here to
give consistency with librosa.
This output depends on the maximum value in the input spectrogram, and so
may return different values for an audio clip split into snippets vs. a
a full clip.
Args:
sample_rate (int, optional): Sample rate of audio signal. (Default: ``16000``)
n_filter (int, optional): Number of linear filters to apply. (Default: ``128``)
n_lfcc (int, optional): Number of lfc coefficients to retain. (Default: ``40``)
f_min (float, optional): Minimum frequency. (Default: ``0.``)
f_max (float or None, optional): Maximum frequency. (Default: ``None``)
dct_type (int, optional): type of DCT (discrete cosine transform) to use. (Default: ``2``)
norm (str, optional): norm to use. (Default: ``"ortho"``)
log_lf (bool, optional): whether to use log-lf spectrograms instead of db-scaled. (Default: ``False``)
speckwargs (dict or None, optional): arguments for Spectrogram. (Default: ``None``)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = transforms.LFCC(
>>> sample_rate=sample_rate,
>>> n_lfcc=13,
>>> speckwargs={"n_fft": 400, "hop_length": 160, "center": False},
>>> )
>>> lfcc = transform(waveform)
See also:
:py:func:`torchaudio.functional.linear_fbanks` - The function used to
generate the filter banks.
"""
__constants__ = ["sample_rate", "n_filter", "n_lfcc", "dct_type", "top_db", "log_lf"]
def __init__(
self,
sample_rate: int = 16000,
n_filter: int = 128,
f_min: float = 0.0,
f_max: Optional[float] = None,
n_lfcc: int = 40,
dct_type: int = 2,
norm: str = "ortho",
log_lf: bool = False,
speckwargs: Optional[dict] = None,
) -> None:
super(LFCC, self).__init__()
supported_dct_types = [2]
if dct_type not in supported_dct_types:
raise ValueError("DCT type not supported: {}".format(dct_type))
self.sample_rate = sample_rate
self.f_min = f_min
self.f_max = f_max if f_max is not None else float(sample_rate // 2)
self.n_filter = n_filter
self.n_lfcc = n_lfcc
self.dct_type = dct_type
self.norm = norm
self.top_db = 80.0
self.amplitude_to_DB = AmplitudeToDB("power", self.top_db)
speckwargs = speckwargs or {}
self.Spectrogram = Spectrogram(**speckwargs)
if self.n_lfcc > self.Spectrogram.n_fft:
raise ValueError("Cannot select more LFCC coefficients than # fft bins")
filter_mat = F.linear_fbanks(
n_freqs=self.Spectrogram.n_fft // 2 + 1,
f_min=self.f_min,
f_max=self.f_max,
n_filter=self.n_filter,
sample_rate=self.sample_rate,
)
self.register_buffer("filter_mat", filter_mat)
dct_mat = F.create_dct(self.n_lfcc, self.n_filter, self.norm)
self.register_buffer("dct_mat", dct_mat)
self.log_lf = log_lf
[docs] def forward(self, waveform: Tensor) -> Tensor:
r"""
Args:
waveform (Tensor): Tensor of audio of dimension (..., time).
Returns:
Tensor: Linear Frequency Cepstral Coefficients of size (..., ``n_lfcc``, time).
"""
specgram = self.Spectrogram(waveform)
# (..., time, freq) dot (freq, n_filter) -> (..., n_filter, time)
specgram = torch.matmul(specgram.transpose(-1, -2), self.filter_mat).transpose(-1, -2)
if self.log_lf:
log_offset = 1e-6
specgram = torch.log(specgram + log_offset)
else:
specgram = self.amplitude_to_DB(specgram)
# (..., time, n_filter) dot (n_filter, n_lfcc) -> (..., n_lfcc, time)
lfcc = torch.matmul(specgram.transpose(-1, -2), self.dct_mat).transpose(-1, -2)
return lfcc
[docs]class MuLawEncoding(torch.nn.Module):
r"""Encode signal based on mu-law companding.
.. devices:: CPU CUDA
.. properties:: TorchScript
For more info see the
`Wikipedia Entry <https://en.wikipedia.org/wiki/%CE%9C-law_algorithm>`_
This algorithm assumes the signal has been scaled to between -1 and 1 and
returns a signal encoded with values from 0 to quantization_channels - 1
Args:
quantization_channels (int, optional): Number of channels. (Default: ``256``)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = torchaudio.transforms.MuLawEncoding(quantization_channels=512)
>>> mulawtrans = transform(waveform)
"""
__constants__ = ["quantization_channels"]
def __init__(self, quantization_channels: int = 256) -> None:
super(MuLawEncoding, self).__init__()
self.quantization_channels = quantization_channels
[docs] def forward(self, x: Tensor) -> Tensor:
r"""
Args:
x (Tensor): A signal to be encoded.
Returns:
Tensor: An encoded signal.
"""
return F.mu_law_encoding(x, self.quantization_channels)
[docs]class MuLawDecoding(torch.nn.Module):
r"""Decode mu-law encoded signal.
.. devices:: CPU CUDA
.. properties:: TorchScript
For more info see the
`Wikipedia Entry <https://en.wikipedia.org/wiki/%CE%9C-law_algorithm>`_
This expects an input with values between 0 and ``quantization_channels - 1``
and returns a signal scaled between -1 and 1.
Args:
quantization_channels (int, optional): Number of channels. (Default: ``256``)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = torchaudio.transforms.MuLawDecoding(quantization_channels=512)
>>> mulawtrans = transform(waveform)
"""
__constants__ = ["quantization_channels"]
def __init__(self, quantization_channels: int = 256) -> None:
super(MuLawDecoding, self).__init__()
self.quantization_channels = quantization_channels
[docs] def forward(self, x_mu: Tensor) -> Tensor:
r"""
Args:
x_mu (Tensor): A mu-law encoded signal which needs to be decoded.
Returns:
Tensor: The signal decoded.
"""
return F.mu_law_decoding(x_mu, self.quantization_channels)
[docs]class Resample(torch.nn.Module):
r"""Resample a signal from one frequency to another. A resampling method can be given.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
Note:
If resampling on waveforms of higher precision than float32, there may be a small loss of precision
because the kernel is cached once as float32. If high precision resampling is important for your application,
the functional form will retain higher precision, but run slower because it does not cache the kernel.
Alternatively, you could rewrite a transform that caches a higher precision kernel.
Args:
orig_freq (int, optional): The original frequency of the signal. (Default: ``16000``)
new_freq (int, optional): The desired frequency. (Default: ``16000``)
resampling_method (str, optional): The resampling method to use.
Options: [``sinc_interpolation``, ``kaiser_window``] (Default: ``"sinc_interpolation"``)
lowpass_filter_width (int, optional): Controls the sharpness of the filter, more == sharper
but less efficient. (Default: ``6``)
rolloff (float, optional): The roll-off frequency of the filter, as a fraction of the Nyquist.
Lower values reduce anti-aliasing, but also reduce some of the highest frequencies. (Default: ``0.99``)
beta (float or None, optional): The shape parameter used for kaiser window.
dtype (torch.device, optional):
Determnines the precision that resampling kernel is pre-computed and cached. If not provided,
kernel is computed with ``torch.float64`` then cached as ``torch.float32``.
If you need higher precision, provide ``torch.float64``, and the pre-computed kernel is computed and
cached as ``torch.float64``. If you use resample with lower precision, then instead of providing this
providing this argument, please use ``Resample.to(dtype)``, so that the kernel generation is still
carried out on ``torch.float64``.
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = transforms.Resample(sample_rate, sample_rate/10)
>>> waveform = transform(waveform)
"""
def __init__(
self,
orig_freq: int = 16000,
new_freq: int = 16000,
resampling_method: str = "sinc_interpolation",
lowpass_filter_width: int = 6,
rolloff: float = 0.99,
beta: Optional[float] = None,
*,
dtype: Optional[torch.dtype] = None,
) -> None:
super().__init__()
self.orig_freq = orig_freq
self.new_freq = new_freq
self.gcd = math.gcd(int(self.orig_freq), int(self.new_freq))
self.resampling_method = resampling_method
self.lowpass_filter_width = lowpass_filter_width
self.rolloff = rolloff
self.beta = beta
if self.orig_freq != self.new_freq:
kernel, self.width = _get_sinc_resample_kernel(
self.orig_freq,
self.new_freq,
self.gcd,
self.lowpass_filter_width,
self.rolloff,
self.resampling_method,
beta,
dtype=dtype,
)
self.register_buffer("kernel", kernel)
[docs] def forward(self, waveform: Tensor) -> Tensor:
r"""
Args:
waveform (Tensor): Tensor of audio of dimension (..., time).
Returns:
Tensor: Output signal of dimension (..., time).
"""
if self.orig_freq == self.new_freq:
return waveform
return _apply_sinc_resample_kernel(waveform, self.orig_freq, self.new_freq, self.gcd, self.kernel, self.width)
[docs]class ComputeDeltas(torch.nn.Module):
r"""Compute delta coefficients of a tensor, usually a spectrogram.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
See `torchaudio.functional.compute_deltas` for more details.
Args:
win_length (int, optional): The window length used for computing delta. (Default: ``5``)
mode (str, optional): Mode parameter passed to padding. (Default: ``"replicate"``)
"""
__constants__ = ["win_length"]
def __init__(self, win_length: int = 5, mode: str = "replicate") -> None:
super(ComputeDeltas, self).__init__()
self.win_length = win_length
self.mode = mode
[docs] def forward(self, specgram: Tensor) -> Tensor:
r"""
Args:
specgram (Tensor): Tensor of audio of dimension (..., freq, time).
Returns:
Tensor: Tensor of deltas of dimension (..., freq, time).
"""
return F.compute_deltas(specgram, win_length=self.win_length, mode=self.mode)
[docs]class TimeStretch(torch.nn.Module):
r"""Stretch stft in time without modifying pitch for a given rate.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
Proposed in *SpecAugment* :cite:`specaugment`.
Args:
hop_length (int or None, optional): Length of hop between STFT windows. (Default: ``win_length // 2``)
n_freq (int, optional): number of filter banks from stft. (Default: ``201``)
fixed_rate (float or None, optional): rate to speed up or slow down by.
If None is provided, rate must be passed to the forward method. (Default: ``None``)
Example
>>> spectrogram = torchaudio.transforms.Spectrogram()
>>> stretch = torchaudio.transforms.TimeStretch()
>>>
>>> original = spectrogram(waveform)
>>> streched_1_2 = stretch(original, 1.2)
>>> streched_0_9 = stretch(original, 0.9)
.. image:: https://download.pytorch.org/torchaudio/doc-assets/specaugment_time_stretch_1.png
:width: 600
:alt: Spectrogram streched by 1.2
.. image:: https://download.pytorch.org/torchaudio/doc-assets/specaugment_time_stretch_2.png
:width: 600
:alt: The original spectrogram
.. image:: https://download.pytorch.org/torchaudio/doc-assets/specaugment_time_stretch_3.png
:width: 600
:alt: Spectrogram streched by 0.9
"""
__constants__ = ["fixed_rate"]
def __init__(self, hop_length: Optional[int] = None, n_freq: int = 201, fixed_rate: Optional[float] = None) -> None:
super(TimeStretch, self).__init__()
self.fixed_rate = fixed_rate
n_fft = (n_freq - 1) * 2
hop_length = hop_length if hop_length is not None else n_fft // 2
self.register_buffer("phase_advance", torch.linspace(0, math.pi * hop_length, n_freq)[..., None])
[docs] def forward(self, complex_specgrams: Tensor, overriding_rate: Optional[float] = None) -> Tensor:
r"""
Args:
complex_specgrams (Tensor):
A tensor of dimension `(..., freq, num_frame)` with complex dtype.
overriding_rate (float or None, optional): speed up to apply to this batch.
If no rate is passed, use ``self.fixed_rate``. (Default: ``None``)
Returns:
Tensor:
Stretched spectrogram. The resulting tensor is of the same dtype as the input
spectrogram, but the number of frames is changed to ``ceil(num_frame / rate)``.
"""
if overriding_rate is None:
if self.fixed_rate is None:
raise ValueError("If no fixed_rate is specified, must pass a valid rate to the forward method.")
rate = self.fixed_rate
else:
rate = overriding_rate
return F.phase_vocoder(complex_specgrams, rate, self.phase_advance)
[docs]class Fade(torch.nn.Module):
r"""Add a fade in and/or fade out to an waveform.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
Args:
fade_in_len (int, optional): Length of fade-in (time frames). (Default: ``0``)
fade_out_len (int, optional): Length of fade-out (time frames). (Default: ``0``)
fade_shape (str, optional): Shape of fade. Must be one of: "quarter_sine",
``"half_sine"``, ``"linear"``, ``"logarithmic"``, ``"exponential"``.
(Default: ``"linear"``)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = transforms.Fade(fade_in_len=sample_rate, fade_out_len=2 * sample_rate, fade_shape="linear")
>>> faded_waveform = transform(waveform)
"""
def __init__(self, fade_in_len: int = 0, fade_out_len: int = 0, fade_shape: str = "linear") -> None:
super(Fade, self).__init__()
self.fade_in_len = fade_in_len
self.fade_out_len = fade_out_len
self.fade_shape = fade_shape
[docs] def forward(self, waveform: Tensor) -> Tensor:
r"""
Args:
waveform (Tensor): Tensor of audio of dimension `(..., time)`.
Returns:
Tensor: Tensor of audio of dimension `(..., time)`.
"""
waveform_length = waveform.size()[-1]
device = waveform.device
return self._fade_in(waveform_length, device) * self._fade_out(waveform_length, device) * waveform
def _fade_in(self, waveform_length: int, device: torch.device) -> Tensor:
fade = torch.linspace(0, 1, self.fade_in_len, device=device)
ones = torch.ones(waveform_length - self.fade_in_len, device=device)
if self.fade_shape == "linear":
fade = fade
if self.fade_shape == "exponential":
fade = torch.pow(2, (fade - 1)) * fade
if self.fade_shape == "logarithmic":
fade = torch.log10(0.1 + fade) + 1
if self.fade_shape == "quarter_sine":
fade = torch.sin(fade * math.pi / 2)
if self.fade_shape == "half_sine":
fade = torch.sin(fade * math.pi - math.pi / 2) / 2 + 0.5
return torch.cat((fade, ones)).clamp_(0, 1)
def _fade_out(self, waveform_length: int, device: torch.device) -> Tensor:
fade = torch.linspace(0, 1, self.fade_out_len, device=device)
ones = torch.ones(waveform_length - self.fade_out_len, device=device)
if self.fade_shape == "linear":
fade = -fade + 1
if self.fade_shape == "exponential":
fade = torch.pow(2, -fade) * (1 - fade)
if self.fade_shape == "logarithmic":
fade = torch.log10(1.1 - fade) + 1
if self.fade_shape == "quarter_sine":
fade = torch.sin(fade * math.pi / 2 + math.pi / 2)
if self.fade_shape == "half_sine":
fade = torch.sin(fade * math.pi + math.pi / 2) / 2 + 0.5
return torch.cat((ones, fade)).clamp_(0, 1)
class _AxisMasking(torch.nn.Module):
r"""Apply masking to a spectrogram.
Args:
mask_param (int): Maximum possible length of the mask.
axis (int): What dimension the mask is applied on.
iid_masks (bool): Applies iid masks to each of the examples in the batch dimension.
This option is applicable only when the input tensor is 4D.
p (float, optional): maximum proportion of columns that can be masked. (Default: 1.0)
"""
__constants__ = ["mask_param", "axis", "iid_masks", "p"]
def __init__(self, mask_param: int, axis: int, iid_masks: bool, p: float = 1.0) -> None:
super(_AxisMasking, self).__init__()
self.mask_param = mask_param
self.axis = axis
self.iid_masks = iid_masks
self.p = p
def forward(self, specgram: Tensor, mask_value: float = 0.0) -> Tensor:
r"""
Args:
specgram (Tensor): Tensor of dimension `(..., freq, time)`.
mask_value (float): Value to assign to the masked columns.
Returns:
Tensor: Masked spectrogram of dimensions `(..., freq, time)`.
"""
# if iid_masks flag marked and specgram has a batch dimension
if self.iid_masks and specgram.dim() == 4:
return F.mask_along_axis_iid(specgram, self.mask_param, mask_value, self.axis + 1, p=self.p)
else:
return F.mask_along_axis(specgram, self.mask_param, mask_value, self.axis, p=self.p)
[docs]class FrequencyMasking(_AxisMasking):
r"""Apply masking to a spectrogram in the frequency domain.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
Proposed in *SpecAugment* :cite:`specaugment`.
Args:
freq_mask_param (int): maximum possible length of the mask.
Indices uniformly sampled from [0, freq_mask_param).
iid_masks (bool, optional): whether to apply different masks to each
example/channel in the batch. (Default: ``False``)
This option is applicable only when the input tensor is 4D.
Example
>>> spectrogram = torchaudio.transforms.Spectrogram()
>>> masking = torchaudio.transforms.FrequencyMasking(freq_mask_param=80)
>>>
>>> original = spectrogram(waveform)
>>> masked = masking(original)
.. image:: https://download.pytorch.org/torchaudio/doc-assets/specaugment_freq_masking1.png
:alt: The original spectrogram
.. image:: https://download.pytorch.org/torchaudio/doc-assets/specaugment_freq_masking2.png
:alt: The spectrogram masked along frequency axis
"""
def __init__(self, freq_mask_param: int, iid_masks: bool = False) -> None:
super(FrequencyMasking, self).__init__(freq_mask_param, 1, iid_masks)
[docs]class TimeMasking(_AxisMasking):
r"""Apply masking to a spectrogram in the time domain.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
Proposed in *SpecAugment* :cite:`specaugment`.
Args:
time_mask_param (int): maximum possible length of the mask.
Indices uniformly sampled from [0, time_mask_param).
iid_masks (bool, optional): whether to apply different masks to each
example/channel in the batch. (Default: ``False``)
This option is applicable only when the input tensor is 4D.
p (float, optional): maximum proportion of time steps that can be masked.
Must be within range [0.0, 1.0]. (Default: 1.0)
Example
>>> spectrogram = torchaudio.transforms.Spectrogram()
>>> masking = torchaudio.transforms.TimeMasking(time_mask_param=80)
>>>
>>> original = spectrogram(waveform)
>>> masked = masking(original)
.. image:: https://download.pytorch.org/torchaudio/doc-assets/specaugment_time_masking1.png
:alt: The original spectrogram
.. image:: https://download.pytorch.org/torchaudio/doc-assets/specaugment_time_masking2.png
:alt: The spectrogram masked along time axis
"""
def __init__(self, time_mask_param: int, iid_masks: bool = False, p: float = 1.0) -> None:
if not 0.0 <= p <= 1.0:
raise ValueError(f"The value of p must be between 0.0 and 1.0 ({p} given).")
super(TimeMasking, self).__init__(time_mask_param, 2, iid_masks, p=p)
[docs]class Loudness(torch.nn.Module):
r"""Measure audio loudness according to the ITU-R BS.1770-4 recommendation.
.. devices:: CPU CUDA
.. properties:: TorchScript
Args:
sample_rate (int): Sample rate of audio signal.
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = transforms.Loudness(sample_rate)
>>> loudness = transform(waveform)
Reference:
- https://www.itu.int/rec/R-REC-BS.1770-4-201510-I/en
"""
__constants__ = ["sample_rate"]
def __init__(self, sample_rate: int):
super(Loudness, self).__init__()
self.sample_rate = sample_rate
[docs] def forward(self, wavefrom: Tensor):
r"""
Args:
waveform(torch.Tensor): audio waveform of dimension `(..., channels, time)`
Returns:
Tensor: loudness estimates (LKFS)
"""
return F.loudness(wavefrom, self.sample_rate)
[docs]class Vol(torch.nn.Module):
r"""Adjust volume of waveform.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
Args:
gain (float): Interpreted according to the given gain_type:
If ``gain_type`` = ``amplitude``, ``gain`` is a positive amplitude ratio.
If ``gain_type`` = ``power``, ``gain`` is a power (voltage squared).
If ``gain_type`` = ``db``, ``gain`` is in decibels.
gain_type (str, optional): Type of gain. One of: ``amplitude``, ``power``, ``db`` (Default: ``amplitude``)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = transforms.Vol(gain=0.5, gain_type="amplitude")
>>> quieter_waveform = transform(waveform)
"""
def __init__(self, gain: float, gain_type: str = "amplitude"):
super(Vol, self).__init__()
self.gain = gain
self.gain_type = gain_type
if gain_type in ["amplitude", "power"] and gain < 0:
raise ValueError("If gain_type = amplitude or power, gain must be positive.")
[docs] def forward(self, waveform: Tensor) -> Tensor:
r"""
Args:
waveform (Tensor): Tensor of audio of dimension `(..., time)`.
Returns:
Tensor: Tensor of audio of dimension `(..., time)`.
"""
if self.gain_type == "amplitude":
waveform = waveform * self.gain
if self.gain_type == "db":
waveform = F.gain(waveform, self.gain)
if self.gain_type == "power":
waveform = F.gain(waveform, 10 * math.log10(self.gain))
return torch.clamp(waveform, -1, 1)
[docs]class SlidingWindowCmn(torch.nn.Module):
r"""
Apply sliding-window cepstral mean (and optionally variance) normalization per utterance.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
Args:
cmn_window (int, optional): Window in frames for running average CMN computation (int, default = 600)
min_cmn_window (int, optional): Minimum CMN window used at start of decoding (adds latency only at start).
Only applicable if center == false, ignored if center==true (int, default = 100)
center (bool, optional): If true, use a window centered on the current frame
(to the extent possible, modulo end effects). If false, window is to the left. (bool, default = false)
norm_vars (bool, optional): If true, normalize variance to one. (bool, default = false)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = transforms.SlidingWindowCmn(cmn_window=1000)
>>> cmn_waveform = transform(waveform)
"""
def __init__(
self, cmn_window: int = 600, min_cmn_window: int = 100, center: bool = False, norm_vars: bool = False
) -> None:
super().__init__()
self.cmn_window = cmn_window
self.min_cmn_window = min_cmn_window
self.center = center
self.norm_vars = norm_vars
[docs] def forward(self, specgram: Tensor) -> Tensor:
r"""
Args:
specgram (Tensor): Tensor of spectrogram of dimension `(..., time, freq)`.
Returns:
Tensor: Tensor of spectrogram of dimension `(..., time, freq)`.
"""
cmn_specgram = F.sliding_window_cmn(specgram, self.cmn_window, self.min_cmn_window, self.center, self.norm_vars)
return cmn_specgram
[docs]class Vad(torch.nn.Module):
r"""Voice Activity Detector. Similar to SoX implementation.
.. devices:: CPU CUDA
.. properties:: TorchScript
Attempts to trim silence and quiet background sounds from the ends of recordings of speech.
The algorithm currently uses a simple cepstral power measurement to detect voice,
so may be fooled by other things, especially music.
The effect can trim only from the front of the audio,
so in order to trim from the back, the reverse effect must also be used.
Args:
sample_rate (int): Sample rate of audio signal.
trigger_level (float, optional): The measurement level used to trigger activity detection.
This may need to be changed depending on the noise level, signal level,
and other characteristics of the input audio. (Default: 7.0)
trigger_time (float, optional): The time constant (in seconds)
used to help ignore short bursts of sound. (Default: 0.25)
search_time (float, optional): The amount of audio (in seconds)
to search for quieter/shorter bursts of audio to include prior
to the detected trigger point. (Default: 1.0)
allowed_gap (float, optional): The allowed gap (in seconds) between
quiteter/shorter bursts of audio to include prior
to the detected trigger point. (Default: 0.25)
pre_trigger_time (float, optional): The amount of audio (in seconds) to preserve
before the trigger point and any found quieter/shorter bursts. (Default: 0.0)
boot_time (float, optional) The algorithm (internally) uses adaptive noise
estimation/reduction in order to detect the start of the wanted audio.
This option sets the time for the initial noise estimate. (Default: 0.35)
noise_up_time (float, optional) Time constant used by the adaptive noise estimator
for when the noise level is increasing. (Default: 0.1)
noise_down_time (float, optional) Time constant used by the adaptive noise estimator
for when the noise level is decreasing. (Default: 0.01)
noise_reduction_amount (float, optional) Amount of noise reduction to use in
the detection algorithm (e.g. 0, 0.5, ...). (Default: 1.35)
measure_freq (float, optional) Frequency of the algorithm’s
processing/measurements. (Default: 20.0)
measure_duration: (float or None, optional) Measurement duration.
(Default: Twice the measurement period; i.e. with overlap.)
measure_smooth_time (float, optional) Time constant used to smooth
spectral measurements. (Default: 0.4)
hp_filter_freq (float, optional) "Brick-wall" frequency of high-pass filter applied
at the input to the detector algorithm. (Default: 50.0)
lp_filter_freq (float, optional) "Brick-wall" frequency of low-pass filter applied
at the input to the detector algorithm. (Default: 6000.0)
hp_lifter_freq (float, optional) "Brick-wall" frequency of high-pass lifter used
in the detector algorithm. (Default: 150.0)
lp_lifter_freq (float, optional) "Brick-wall" frequency of low-pass lifter used
in the detector algorithm. (Default: 2000.0)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> waveform_reversed, sample_rate = apply_effects_tensor(waveform, sample_rate, [["reverse"]])
>>> transform = transforms.Vad(sample_rate=sample_rate, trigger_level=7.5)
>>> waveform_reversed_front_trim = transform(waveform_reversed)
>>> waveform_end_trim, sample_rate = apply_effects_tensor(
>>> waveform_reversed_front_trim, sample_rate, [["reverse"]]
>>> )
Reference:
- http://sox.sourceforge.net/sox.html
"""
def __init__(
self,
sample_rate: int,
trigger_level: float = 7.0,
trigger_time: float = 0.25,
search_time: float = 1.0,
allowed_gap: float = 0.25,
pre_trigger_time: float = 0.0,
boot_time: float = 0.35,
noise_up_time: float = 0.1,
noise_down_time: float = 0.01,
noise_reduction_amount: float = 1.35,
measure_freq: float = 20.0,
measure_duration: Optional[float] = None,
measure_smooth_time: float = 0.4,
hp_filter_freq: float = 50.0,
lp_filter_freq: float = 6000.0,
hp_lifter_freq: float = 150.0,
lp_lifter_freq: float = 2000.0,
) -> None:
super().__init__()
self.sample_rate = sample_rate
self.trigger_level = trigger_level
self.trigger_time = trigger_time
self.search_time = search_time
self.allowed_gap = allowed_gap
self.pre_trigger_time = pre_trigger_time
self.boot_time = boot_time
self.noise_up_time = noise_up_time
self.noise_down_time = noise_down_time
self.noise_reduction_amount = noise_reduction_amount
self.measure_freq = measure_freq
self.measure_duration = measure_duration
self.measure_smooth_time = measure_smooth_time
self.hp_filter_freq = hp_filter_freq
self.lp_filter_freq = lp_filter_freq
self.hp_lifter_freq = hp_lifter_freq
self.lp_lifter_freq = lp_lifter_freq
[docs] def forward(self, waveform: Tensor) -> Tensor:
r"""
Args:
waveform (Tensor): Tensor of audio of dimension `(channels, time)` or `(time)`
Tensor of shape `(channels, time)` is treated as a multi-channel recording
of the same event and the resulting output will be trimmed to the earliest
voice activity in any channel.
"""
return F.vad(
waveform=waveform,
sample_rate=self.sample_rate,
trigger_level=self.trigger_level,
trigger_time=self.trigger_time,
search_time=self.search_time,
allowed_gap=self.allowed_gap,
pre_trigger_time=self.pre_trigger_time,
boot_time=self.boot_time,
noise_up_time=self.noise_up_time,
noise_down_time=self.noise_down_time,
noise_reduction_amount=self.noise_reduction_amount,
measure_freq=self.measure_freq,
measure_duration=self.measure_duration,
measure_smooth_time=self.measure_smooth_time,
hp_filter_freq=self.hp_filter_freq,
lp_filter_freq=self.lp_filter_freq,
hp_lifter_freq=self.hp_lifter_freq,
lp_lifter_freq=self.lp_lifter_freq,
)
[docs]class SpectralCentroid(torch.nn.Module):
r"""Compute the spectral centroid for each channel along the time axis.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
The spectral centroid is defined as the weighted average of the
frequency values, weighted by their magnitude.
Args:
sample_rate (int): Sample rate of audio signal.
n_fft (int, optional): Size of FFT, creates ``n_fft // 2 + 1`` bins. (Default: ``400``)
win_length (int or None, optional): Window size. (Default: ``n_fft``)
hop_length (int or None, optional): Length of hop between STFT windows. (Default: ``win_length // 2``)
pad (int, optional): Two sided padding of signal. (Default: ``0``)
window_fn (Callable[..., Tensor], optional): A function to create a window tensor
that is applied/multiplied to each frame/window. (Default: ``torch.hann_window``)
wkwargs (dict or None, optional): Arguments for window function. (Default: ``None``)
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = transforms.SpectralCentroid(sample_rate)
>>> spectral_centroid = transform(waveform) # (channel, time)
"""
__constants__ = ["sample_rate", "n_fft", "win_length", "hop_length", "pad"]
def __init__(
self,
sample_rate: int,
n_fft: int = 400,
win_length: Optional[int] = None,
hop_length: Optional[int] = None,
pad: int = 0,
window_fn: Callable[..., Tensor] = torch.hann_window,
wkwargs: Optional[dict] = None,
) -> None:
super(SpectralCentroid, self).__init__()
self.sample_rate = sample_rate
self.n_fft = n_fft
self.win_length = win_length if win_length is not None else n_fft
self.hop_length = hop_length if hop_length is not None else self.win_length // 2
window = window_fn(self.win_length) if wkwargs is None else window_fn(self.win_length, **wkwargs)
self.register_buffer("window", window)
self.pad = pad
[docs] def forward(self, waveform: Tensor) -> Tensor:
r"""
Args:
waveform (Tensor): Tensor of audio of dimension `(..., time)`.
Returns:
Tensor: Spectral Centroid of size `(..., time)`.
"""
return F.spectral_centroid(
waveform, self.sample_rate, self.pad, self.window, self.n_fft, self.hop_length, self.win_length
)
[docs]class PitchShift(LazyModuleMixin, torch.nn.Module):
r"""Shift the pitch of a waveform by ``n_steps`` steps.
.. devices:: CPU CUDA
.. properties:: TorchScript
Args:
waveform (Tensor): The input waveform of shape `(..., time)`.
sample_rate (int): Sample rate of `waveform`.
n_steps (int): The (fractional) steps to shift `waveform`.
bins_per_octave (int, optional): The number of steps per octave (Default : ``12``).
n_fft (int, optional): Size of FFT, creates ``n_fft // 2 + 1`` bins (Default: ``512``).
win_length (int or None, optional): Window size. If None, then ``n_fft`` is used. (Default: ``None``).
hop_length (int or None, optional): Length of hop between STFT windows. If None, then ``win_length // 4``
is used (Default: ``None``).
window (Tensor or None, optional): Window tensor that is applied/multiplied to each frame/window.
If None, then ``torch.hann_window(win_length)`` is used (Default: ``None``).
Example
>>> waveform, sample_rate = torchaudio.load("test.wav", normalize=True)
>>> transform = transforms.PitchShift(sample_rate, 4)
>>> waveform_shift = transform(waveform) # (channel, time)
"""
__constants__ = ["sample_rate", "n_steps", "bins_per_octave", "n_fft", "win_length", "hop_length"]
kernel: UninitializedParameter
width: int
def __init__(
self,
sample_rate: int,
n_steps: int,
bins_per_octave: int = 12,
n_fft: int = 512,
win_length: Optional[int] = None,
hop_length: Optional[int] = None,
window_fn: Callable[..., Tensor] = torch.hann_window,
wkwargs: Optional[dict] = None,
) -> None:
super().__init__()
self.n_steps = n_steps
self.bins_per_octave = bins_per_octave
self.sample_rate = sample_rate
self.n_fft = n_fft
self.win_length = win_length if win_length is not None else n_fft
self.hop_length = hop_length if hop_length is not None else self.win_length // 4
window = window_fn(self.win_length) if wkwargs is None else window_fn(self.win_length, **wkwargs)
self.register_buffer("window", window)
rate = 2.0 ** (-float(n_steps) / bins_per_octave)
self.orig_freq = int(sample_rate / rate)
self.gcd = math.gcd(int(self.orig_freq), int(sample_rate))
if self.orig_freq != sample_rate:
self.width = -1
self.kernel = UninitializedParameter(device=None, dtype=None)
[docs] def initialize_parameters(self, input):
if self.has_uninitialized_params():
if self.orig_freq != self.sample_rate:
with torch.no_grad():
kernel, self.width = _get_sinc_resample_kernel(
self.orig_freq,
self.sample_rate,
self.gcd,
dtype=input.dtype,
device=input.device,
)
self.kernel.materialize(kernel.shape)
self.kernel.copy_(kernel)
[docs] def forward(self, waveform: Tensor) -> Tensor:
r"""
Args:
waveform (Tensor): Tensor of audio of dimension `(..., time)`.
Returns:
Tensor: The pitch-shifted audio of shape `(..., time)`.
"""
shape = waveform.size()
waveform_stretch = _stretch_waveform(
waveform,
self.n_steps,
self.bins_per_octave,
self.n_fft,
self.win_length,
self.hop_length,
self.window,
)
if self.orig_freq != self.sample_rate:
waveform_shift = _apply_sinc_resample_kernel(
waveform_stretch,
self.orig_freq,
self.sample_rate,
self.gcd,
self.kernel,
self.width,
)
else:
waveform_shift = waveform_stretch
return _fix_waveform_shape(
waveform_shift,
shape,
)
[docs]class RNNTLoss(torch.nn.Module):
"""Compute the RNN Transducer loss from *Sequence Transduction with Recurrent Neural Networks*
:cite:`graves2012sequence`.
.. devices:: CPU CUDA
.. properties:: Autograd TorchScript
The RNN Transducer loss extends the CTC loss by defining a distribution over output
sequences of all lengths, and by jointly modelling both input-output and output-output
dependencies.
Args:
blank (int, optional): blank label (Default: ``-1``)
clamp (float, optional): clamp for gradients (Default: ``-1``)
reduction (string, optional): Specifies the reduction to apply to the output:
``"none"`` | ``"mean"`` | ``"sum"``. (Default: ``"mean"``)
Example
>>> # Hypothetical values
>>> logits = torch.tensor([[[[0.1, 0.6, 0.1, 0.1, 0.1],
>>> [0.1, 0.1, 0.6, 0.1, 0.1],
>>> [0.1, 0.1, 0.2, 0.8, 0.1]],
>>> [[0.1, 0.6, 0.1, 0.1, 0.1],
>>> [0.1, 0.1, 0.2, 0.1, 0.1],
>>> [0.7, 0.1, 0.2, 0.1, 0.1]]]],
>>> dtype=torch.float32,
>>> requires_grad=True)
>>> targets = torch.tensor([[1, 2]], dtype=torch.int)
>>> logit_lengths = torch.tensor([2], dtype=torch.int)
>>> target_lengths = torch.tensor([2], dtype=torch.int)
>>> transform = transforms.RNNTLoss(blank=0)
>>> loss = transform(logits, targets, logit_lengths, target_lengths)
>>> loss.backward()
"""
def __init__(
self,
blank: int = -1,
clamp: float = -1.0,
reduction: str = "mean",
):
super().__init__()
self.blank = blank
self.clamp = clamp
self.reduction = reduction
[docs] def forward(
self,
logits: Tensor,
targets: Tensor,
logit_lengths: Tensor,
target_lengths: Tensor,
):
"""
Args:
logits (Tensor): Tensor of dimension `(batch, max seq length, max target length + 1, class)`
containing output from joiner
targets (Tensor): Tensor of dimension `(batch, max target length)` containing targets with zero padded
logit_lengths (Tensor): Tensor of dimension `(batch)` containing lengths of each sequence from encoder
target_lengths (Tensor): Tensor of dimension `(batch)` containing lengths of targets for each sequence
Returns:
Tensor: Loss with the reduction option applied. If ``reduction`` is ``"none"``, then size (batch),
otherwise scalar.
"""
return F.rnnt_loss(logits, targets, logit_lengths, target_lengths, self.blank, self.clamp, self.reduction)