forked from mrq/DL-Art-School
249 lines
12 KiB
Python
249 lines
12 KiB
Python
import torch
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import numpy as np
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from scipy import special
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# Courtesy of https://www.kaggle.com/smallyellowduck/fast-audio-resampling-layer-in-pytorch
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class AudioResampler(torch.nn.Module):
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"""
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Efficiently resample audio signals
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This module is much faster than resampling with librosa because it exploits pytorch's efficient conv1d operations
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This module is also faster than the existing pytorch resample function in
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https://github.com/pytorch/audio/blob/b6a61c3f7d0267c77f8626167cc1eda0335f2753/torchaudio/compliance/kaldi.py#L892
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Based on
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https://github.com/danpovey/filtering/blob/master/lilfilter/resampler.py
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with improvements to include additional filter types and input parameters that align with the librosa api
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"""
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def __init__(self,
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input_sr, output_sr, dtype,
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num_zeros=64, cutoff_ratio=0.95, filter='kaiser', beta=14.0):
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super().__init__() # init the base class
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"""
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This creates an object that can apply a symmetric FIR filter
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based on torch.nn.functional.conv1d.
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Args:
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input_sr: The input sampling rate, AS AN INTEGER..
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does not have to be the real sampling rate but should
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have the correct ratio with output_sr.
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output_sr: The output sampling rate, AS AN INTEGER.
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It is the ratio with the input sampling rate that is
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important here.
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dtype: The torch dtype to use for computations (would be preferrable to
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set things up so passing the dtype isn't necessary)
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num_zeros: The number of zeros per side in the (sinc*hanning-window)
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filter function. More is more accurate, but 64 is already
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quite a lot. The kernel size is 2*num_zeros + 1.
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cutoff_ratio: The filter rolloff point as a fraction of the
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Nyquist frequency.
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filter: one of ['kaiser', 'kaiser_best', 'kaiser_fast', 'hann']
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beta: parameter for 'kaiser' filter
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You can think of this algorithm as dividing up the signals
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(input,output) into blocks where there are `input_sr` input
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samples and `output_sr` output samples. Then we treat it
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using convolutional code, imagining there are `input_sr`
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input channels and `output_sr` output channels per time step.
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"""
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assert isinstance(input_sr, int) and isinstance(output_sr, int)
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if input_sr == output_sr:
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self.resample_type = 'trivial'
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return
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def gcd(a, b):
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""" Return the greatest common divisor of a and b"""
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assert isinstance(a, int) and isinstance(b, int)
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if b == 0:
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return a
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else:
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return gcd(b, a % b)
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d = gcd(input_sr, output_sr)
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input_sr, output_sr = input_sr // d, output_sr // d
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assert dtype in [torch.float32, torch.float64]
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assert num_zeros > 3 # a reasonable bare minimum
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np_dtype = np.float32 if dtype == torch.float32 else np.float64
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assert filter in ['hann', 'kaiser', 'kaiser_best', 'kaiser_fast']
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if filter == 'kaiser_best':
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num_zeros = 64
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beta = 14.769656459379492
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cutoff_ratio = 0.9475937167399596
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filter = 'kaiser'
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elif filter == 'kaiser_fast':
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num_zeros = 16
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beta = 8.555504641634386
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cutoff_ratio = 0.85
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filter = 'kaiser'
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# Define one 'block' of samples `input_sr` input samples
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# and `output_sr` output samples. We can divide up
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# the samples into these blocks and have the blocks be
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# in correspondence.
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# The sinc function will have, on average, `zeros_per_block`
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# zeros per block.
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zeros_per_block = min(input_sr, output_sr) * cutoff_ratio
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# The convolutional kernel size will be n = (blocks_per_side*2 + 1),
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# i.e. we add that many blocks on each side of the central block. The
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# window radius (defined as distance from center to edge)
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# is `blocks_per_side` blocks. This ensures that each sample in the
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# central block can "see" all the samples in its window.
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#
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# Assuming the following division is not exact, adding 1
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# will have the same effect as rounding up.
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# blocks_per_side = 1 + int(num_zeros / zeros_per_block)
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blocks_per_side = int(np.ceil(num_zeros / zeros_per_block))
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kernel_width = 2 * blocks_per_side + 1
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# We want the weights as used by torch's conv1d code; format is
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# (out_channels, in_channels, kernel_width)
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# https://pytorch.org/docs/stable/nn.functional.html
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weights = torch.tensor((output_sr, input_sr, kernel_width), dtype=dtype)
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# Computations involving time will be in units of 1 block. Actually this
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# is the same as the `canonical` time axis since each block has input_sr
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# input samples, so it would be one of whatever time unit we are using
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window_radius_in_blocks = blocks_per_side
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# The `times` below will end up being the args to the sinc function.
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# For the shapes of the things below, look at the args to `view`. The terms
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# below will get expanded to shape (output_sr, input_sr, kernel_width) through
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# broadcasting
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# We want it so that, assuming input_sr == output_sr, along the diagonal of
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# the central block we have t == 0.
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# The signs of the output_sr and input_sr terms need to be opposite. The
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# sign that the kernel_width term needs to be will depend on whether it's
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# convolution or correlation, and the logic is tricky.. I will just find
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# which sign works.
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times = (
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np.arange(output_sr, dtype=np_dtype).reshape((output_sr, 1, 1)) / output_sr -
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np.arange(input_sr, dtype=np_dtype).reshape((1, input_sr, 1)) / input_sr -
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(np.arange(kernel_width, dtype=np_dtype).reshape((1, 1, kernel_width)) - blocks_per_side))
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def hann_window(a):
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"""
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hann_window returns the Hann window on [-1,1], which is zero
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if a < -1 or a > 1, and otherwise 0.5 + 0.5 cos(a*pi).
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This is applied elementwise to a, which should be a NumPy array.
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The heaviside function returns (a > 0 ? 1 : 0).
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"""
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return np.heaviside(1 - np.abs(a), 0.0) * (0.5 + 0.5 * np.cos(a * np.pi))
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def kaiser_window(a, beta):
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w = special.i0(beta * np.sqrt(np.clip(1 - ((a - 0.0) / 1.0) ** 2.0, 0.0, 1.0))) / special.i0(beta)
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return np.heaviside(1 - np.abs(a), 0.0) * w
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# The weights below are a sinc function times a Hann-window function.
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#
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# Multiplication by zeros_per_block normalizes the sinc function
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# (to compensate for scaling on the x-axis), so that the integral is 1.
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#
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# Division by input_sr normalizes the input function. Think of the input
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# as a stream of dirac deltas passing through a low pass filter:
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# in order to have the same magnitude as the original input function,
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# we need to divide by the number of those deltas per unit time.
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if filter == 'hann':
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weights = (np.sinc(times * zeros_per_block)
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* hann_window(times / window_radius_in_blocks)
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* zeros_per_block / input_sr)
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else:
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weights = (np.sinc(times * zeros_per_block)
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* kaiser_window(times / window_radius_in_blocks, beta)
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* zeros_per_block / input_sr)
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self.input_sr = input_sr
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self.output_sr = output_sr
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# weights has dim (output_sr, input_sr, kernel_width).
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# If output_sr == 1, we can fold the input_sr into the
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# kernel_width (i.e. have just 1 input channel); this will make the
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# convolution faster and avoid unnecessary reshaping.
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assert weights.shape == (output_sr, input_sr, kernel_width)
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if output_sr == 1:
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self.resample_type = 'integer_downsample'
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self.padding = input_sr * blocks_per_side
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weights = torch.tensor(weights, dtype=dtype, requires_grad=False)
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self.weights = weights.transpose(1, 2).contiguous().view(1, 1, input_sr * kernel_width)
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elif input_sr == 1:
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# In this case we'll be doing conv_transpose, so we want the same weights that
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# we would have if we were *downsampling* by this factor-- i.e. as if input_sr,
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# output_sr had been swapped.
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self.resample_type = 'integer_upsample'
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self.padding = output_sr * blocks_per_side
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weights = torch.tensor(weights, dtype=dtype, requires_grad=False)
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self.weights = weights.flip(2).transpose(0, 2).contiguous().view(1, 1, output_sr * kernel_width)
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else:
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self.resample_type = 'general'
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self.reshaped = False
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self.padding = blocks_per_side
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self.weights = torch.tensor(weights, dtype=dtype, requires_grad=False)
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self.weights = torch.nn.Parameter(self.weights, requires_grad=False)
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@torch.no_grad()
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def forward(self, data):
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"""
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Resample the data
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Args:
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input: a torch.Tensor with the same dtype as was passed to the
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constructor.
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There must be 2 axes, interpreted as (minibatch_size, sequence_length)...
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the minibatch_size may in practice be the number of channels.
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Return: Returns a torch.Tensor with the same dtype as the input, and
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dimension (minibatch_size, (sequence_length//input_sr)*output_sr),
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where input_sr and output_sr are the corresponding constructor args,
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modified to remove any common factors.
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"""
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if self.resample_type == 'trivial':
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return data
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elif self.resample_type == 'integer_downsample':
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(minibatch_size, seq_len) = data.shape
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# will be shape (minibatch_size, in_channels, seq_len) with in_channels == 1
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data = data.unsqueeze(1)
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data = torch.nn.functional.conv1d(data,
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self.weights,
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stride=self.input_sr,
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padding=self.padding)
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# shape will be (minibatch_size, out_channels = 1, seq_len);
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# return as (minibatch_size, seq_len)
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return data.squeeze(1)
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elif self.resample_type == 'integer_upsample':
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data = data.unsqueeze(1)
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data = torch.nn.functional.conv_transpose1d(data,
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self.weights,
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stride=self.output_sr,
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padding=self.padding)
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return data.squeeze(1)
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else:
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assert self.resample_type == 'general'
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(minibatch_size, seq_len) = data.shape
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num_blocks = seq_len // self.input_sr
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if num_blocks == 0:
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# TODO: pad with zeros.
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raise RuntimeError("Signal is too short to resample")
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# data = data[:, 0:(num_blocks*self.input_sr)] # Truncate input
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data = data[:, 0:(num_blocks * self.input_sr)].view(minibatch_size, num_blocks, self.input_sr)
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# Torch's conv1d expects input data with shape (minibatch, in_channels, time_steps), so transpose
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data = data.transpose(1, 2)
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data = torch.nn.functional.conv1d(data, self.weights,
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padding=self.padding)
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assert data.shape == (minibatch_size, self.output_sr, num_blocks)
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return data.transpose(1, 2).contiguous().view(minibatch_size, num_blocks * self.output_sr) |