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ApplioRVC-Inference / modules /parallel_wavegan /layers /pqmf.py

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	# -- coding: utf-8 --

	# Copyright 2020 Tomoki Hayashi
	# MIT License (https://opensource.org/licenses/MIT)

	"""Pseudo QMF modules."""

	import numpy as np
	import torch
	import torch.nn.functional as F

	from scipy.signal import kaiser


	def design_prototype_filter(taps=62, cutoff_ratio=0.15, beta=9.0):
	"""Design prototype filter for PQMF.

	This method is based on `A Kaiser window approach for the design of prototype
	filters of cosine modulated filterbanks`_.

	Args:
	taps (int): The number of filter taps.
	cutoff_ratio (float): Cut-off frequency ratio.
	beta (float): Beta coefficient for kaiser window.

	Returns:
	ndarray: Impluse response of prototype filter (taps + 1,).

	.. _`A Kaiser window approach for the design of prototype filters of cosine modulated filterbanks`:
	https://ieeexplore.ieee.org/abstract/document/681427

	"""
	# check the arguments are valid
	assert taps % 2 == 0, "The number of taps mush be even number."
	assert 0.0 < cutoff_ratio < 1.0, "Cutoff ratio must be > 0.0 and < 1.0."

	# make initial filter
	omega_c = np.pi * cutoff_ratio
	with np.errstate(invalid='ignore'):
	h_i = np.sin(omega_c * (np.arange(taps + 1) - 0.5 * taps)) \
	/ (np.pi * (np.arange(taps + 1) - 0.5 * taps))
	h_i[taps // 2] = np.cos(0) * cutoff_ratio # fix nan due to indeterminate form

	# apply kaiser window
	w = kaiser(taps + 1, beta)
	h = h_i * w

	return h


	class PQMF(torch.nn.Module):
	"""PQMF module.

	This module is based on `Near-perfect-reconstruction pseudo-QMF banks`_.

	.. _`Near-perfect-reconstruction pseudo-QMF banks`:
	https://ieeexplore.ieee.org/document/258122

	"""

	def __init__(self, subbands=4, taps=62, cutoff_ratio=0.15, beta=9.0):
	"""Initilize PQMF module.

	Args:
	subbands (int): The number of subbands.
	taps (int): The number of filter taps.
	cutoff_ratio (float): Cut-off frequency ratio.
	beta (float): Beta coefficient for kaiser window.

	"""
	super(PQMF, self).__init__()

	# define filter coefficient
	h_proto = design_prototype_filter(taps, cutoff_ratio, beta)
	h_analysis = np.zeros((subbands, len(h_proto)))
	h_synthesis = np.zeros((subbands, len(h_proto)))
	for k in range(subbands):
	h_analysis[k] = 2 * h_proto * np.cos(
	(2 * k + 1) * (np.pi / (2 * subbands)) *
	(np.arange(taps + 1) - ((taps - 1) / 2)) +
	(-1) ** k * np.pi / 4)
	h_synthesis[k] = 2 * h_proto * np.cos(
	(2 * k + 1) * (np.pi / (2 * subbands)) *
	(np.arange(taps + 1) - ((taps - 1) / 2)) -
	(-1) ** k * np.pi / 4)

	# convert to tensor
	analysis_filter = torch.from_numpy(h_analysis).float().unsqueeze(1)
	synthesis_filter = torch.from_numpy(h_synthesis).float().unsqueeze(0)

	# register coefficients as beffer
	self.register_buffer("analysis_filter", analysis_filter)
	self.register_buffer("synthesis_filter", synthesis_filter)

	# filter for downsampling & upsampling
	updown_filter = torch.zeros((subbands, subbands, subbands)).float()
	for k in range(subbands):
	updown_filter[k, k, 0] = 1.0
	self.register_buffer("updown_filter", updown_filter)
	self.subbands = subbands

	# keep padding info
	self.pad_fn = torch.nn.ConstantPad1d(taps // 2, 0.0)

	def analysis(self, x):
	"""Analysis with PQMF.

	Args:
	x (Tensor): Input tensor (B, 1, T).

	Returns:
	Tensor: Output tensor (B, subbands, T // subbands).

	"""
	x = F.conv1d(self.pad_fn(x), self.analysis_filter)
	return F.conv1d(x, self.updown_filter, stride=self.subbands)

	def synthesis(self, x):
	"""Synthesis with PQMF.

	Args:
	x (Tensor): Input tensor (B, subbands, T // subbands).

	Returns:
	Tensor: Output tensor (B, 1, T).

	"""
	x = F.conv_transpose1d(x, self.updown_filter * self.subbands, stride=self.subbands)
	return F.conv1d(self.pad_fn(x), self.synthesis_filter)