# -*- coding: utf-8 -*- """Upsampling module. This code is modified from https://github.com/r9y9/wavenet_vocoder. """ import numpy as np import torch import torch.nn.functional as F from . import Conv1d class Stretch2d(torch.nn.Module): """Stretch2d module.""" def __init__(self, x_scale, y_scale, mode="nearest"): """Initialize Stretch2d module. Args: x_scale (int): X scaling factor (Time axis in spectrogram). y_scale (int): Y scaling factor (Frequency axis in spectrogram). mode (str): Interpolation mode. """ super(Stretch2d, self).__init__() self.x_scale = x_scale self.y_scale = y_scale self.mode = mode def forward(self, x): """Calculate forward propagation. Args: x (Tensor): Input tensor (B, C, F, T). Returns: Tensor: Interpolated tensor (B, C, F * y_scale, T * x_scale), """ return F.interpolate( x, scale_factor=(self.y_scale, self.x_scale), mode=self.mode) class Conv2d(torch.nn.Conv2d): """Conv2d module with customized initialization.""" def __init__(self, *args, **kwargs): """Initialize Conv2d module.""" super(Conv2d, self).__init__(*args, **kwargs) def reset_parameters(self): """Reset parameters.""" self.weight.data.fill_(1. / np.prod(self.kernel_size)) if self.bias is not None: torch.nn.init.constant_(self.bias, 0.0) class UpsampleNetwork(torch.nn.Module): """Upsampling network module.""" def __init__(self, upsample_scales, nonlinear_activation=None, nonlinear_activation_params={}, interpolate_mode="nearest", freq_axis_kernel_size=1, use_causal_conv=False, ): """Initialize upsampling network module. Args: upsample_scales (list): List of upsampling scales. nonlinear_activation (str): Activation function name. nonlinear_activation_params (dict): Arguments for specified activation function. interpolate_mode (str): Interpolation mode. freq_axis_kernel_size (int): Kernel size in the direction of frequency axis. """ super(UpsampleNetwork, self).__init__() self.use_causal_conv = use_causal_conv self.up_layers = torch.nn.ModuleList() for scale in upsample_scales: # interpolation layer stretch = Stretch2d(scale, 1, interpolate_mode) self.up_layers += [stretch] # conv layer assert (freq_axis_kernel_size - 1) % 2 == 0, "Not support even number freq axis kernel size." freq_axis_padding = (freq_axis_kernel_size - 1) // 2 kernel_size = (freq_axis_kernel_size, scale * 2 + 1) if use_causal_conv: padding = (freq_axis_padding, scale * 2) else: padding = (freq_axis_padding, scale) conv = Conv2d(1, 1, kernel_size=kernel_size, padding=padding, bias=False) self.up_layers += [conv] # nonlinear if nonlinear_activation is not None: nonlinear = getattr(torch.nn, nonlinear_activation)(**nonlinear_activation_params) self.up_layers += [nonlinear] def forward(self, c): """Calculate forward propagation. Args: c : Input tensor (B, C, T). Returns: Tensor: Upsampled tensor (B, C, T'), where T' = T * prod(upsample_scales). """ c = c.unsqueeze(1) # (B, 1, C, T) for f in self.up_layers: if self.use_causal_conv and isinstance(f, Conv2d): c = f(c)[..., :c.size(-1)] else: c = f(c) return c.squeeze(1) # (B, C, T') class ConvInUpsampleNetwork(torch.nn.Module): """Convolution + upsampling network module.""" def __init__(self, upsample_scales, nonlinear_activation=None, nonlinear_activation_params={}, interpolate_mode="nearest", freq_axis_kernel_size=1, aux_channels=80, aux_context_window=0, use_causal_conv=False ): """Initialize convolution + upsampling network module. Args: upsample_scales (list): List of upsampling scales. nonlinear_activation (str): Activation function name. nonlinear_activation_params (dict): Arguments for specified activation function. mode (str): Interpolation mode. freq_axis_kernel_size (int): Kernel size in the direction of frequency axis. aux_channels (int): Number of channels of pre-convolutional layer. aux_context_window (int): Context window size of the pre-convolutional layer. use_causal_conv (bool): Whether to use causal structure. """ super(ConvInUpsampleNetwork, self).__init__() self.aux_context_window = aux_context_window self.use_causal_conv = use_causal_conv and aux_context_window > 0 # To capture wide-context information in conditional features kernel_size = aux_context_window + 1 if use_causal_conv else 2 * aux_context_window + 1 # NOTE(kan-bayashi): Here do not use padding because the input is already padded self.conv_in = Conv1d(aux_channels, aux_channels, kernel_size=kernel_size, bias=False) self.upsample = UpsampleNetwork( upsample_scales=upsample_scales, nonlinear_activation=nonlinear_activation, nonlinear_activation_params=nonlinear_activation_params, interpolate_mode=interpolate_mode, freq_axis_kernel_size=freq_axis_kernel_size, use_causal_conv=use_causal_conv, ) def forward(self, c): """Calculate forward propagation. Args: c : Input tensor (B, C, T'). Returns: Tensor: Upsampled tensor (B, C, T), where T = (T' - aux_context_window * 2) * prod(upsample_scales). Note: The length of inputs considers the context window size. """ c_ = self.conv_in(c) c = c_[:, :, :-self.aux_context_window] if self.use_causal_conv else c_ return self.upsample(c)