# Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # Modified from espnet(https://github.com/espnet/espnet) """StyleMelGAN Modules.""" import copy from typing import Any from typing import Dict from typing import List import numpy as np import paddle import paddle.nn.functional as F from paddle import nn from paddlespeech.t2s.models.melgan import MelGANDiscriminator as BaseDiscriminator from paddlespeech.t2s.modules.activation import get_activation from paddlespeech.t2s.modules.nets_utils import initialize from paddlespeech.t2s.modules.pqmf import PQMF from paddlespeech.t2s.modules.tade_res_block import TADEResBlock class StyleMelGANGenerator(nn.Layer): """Style MelGAN generator module.""" def __init__( self, in_channels: int=128, aux_channels: int=80, channels: int=64, out_channels: int=1, kernel_size: int=9, dilation: int=2, bias: bool=True, noise_upsample_scales: List[int]=[11, 2, 2, 2], noise_upsample_activation: str="leakyrelu", noise_upsample_activation_params: Dict[str, Any]={"negative_slope": 0.2}, upsample_scales: List[int]=[2, 2, 2, 2, 2, 2, 2, 2, 1], upsample_mode: str="linear", gated_function: str="softmax", use_weight_norm: bool=True, init_type: str="xavier_uniform", ): """Initilize Style MelGAN generator. Args: in_channels (int): Number of input noise channels. aux_channels (int): Number of auxiliary input channels. channels (int): Number of channels for conv layer. out_channels (int): Number of output channels. kernel_size (int): Kernel size of conv layers. dilation (int): Dilation factor for conv layers. bias (bool): Whether to add bias parameter in convolution layers. noise_upsample_scales (list): List of noise upsampling scales. noise_upsample_activation (str): Activation function module name for noise upsampling. noise_upsample_activation_params (dict): Hyperparameters for the above activation function. upsample_scales (list): List of upsampling scales. upsample_mode (str): Upsampling mode in TADE layer. gated_function (str): Gated function in TADEResBlock ("softmax" or "sigmoid"). use_weight_norm (bool): Whether to use weight norm. If set to true, it will be applied to all of the conv layers. """ super().__init__() # initialize parameters initialize(self, init_type) self.in_channels = in_channels noise_upsample = [] in_chs = in_channels for noise_upsample_scale in noise_upsample_scales: noise_upsample.append( nn.Conv1DTranspose( in_chs, channels, noise_upsample_scale * 2, stride=noise_upsample_scale, padding=noise_upsample_scale // 2 + noise_upsample_scale % 2, output_padding=noise_upsample_scale % 2, bias_attr=bias, )) noise_upsample.append( get_activation(noise_upsample_activation, ** noise_upsample_activation_params)) in_chs = channels self.noise_upsample = nn.Sequential(*noise_upsample) self.noise_upsample_factor = np.prod(noise_upsample_scales) self.blocks = nn.LayerList() aux_chs = aux_channels for upsample_scale in upsample_scales: self.blocks.append( TADEResBlock( in_channels=channels, aux_channels=aux_chs, kernel_size=kernel_size, dilation=dilation, bias=bias, upsample_factor=upsample_scale, upsample_mode=upsample_mode, gated_function=gated_function, ), ) aux_chs = channels self.upsample_factor = np.prod(upsample_scales) self.output_conv = nn.Sequential( nn.Conv1D( channels, out_channels, kernel_size, 1, bias_attr=bias, padding=(kernel_size - 1) // 2, ), nn.Tanh(), ) nn.initializer.set_global_initializer(None) # apply weight norm if use_weight_norm: self.apply_weight_norm() # reset parameters self.reset_parameters() def forward(self, c, z=None): """Calculate forward propagation. Args: c (Tensor): Auxiliary input tensor (B, channels, T). z (Tensor): Input noise tensor (B, in_channels, 1). Returns: Tensor: Output tensor (B, out_channels, T ** prod(upsample_scales)). """ # batch_max_steps(24000) == noise_upsample_factor(80) * upsample_factor(300) if z is None: z = paddle.randn([paddle.shape(c)[0], self.in_channels, 1]) # (B, in_channels, noise_upsample_factor). x = self.noise_upsample(z) for block in self.blocks: x, c = block(x, c) x = self.output_conv(x) return x def apply_weight_norm(self): """Recursively apply weight normalization to all the Convolution layers in the sublayers. """ def _apply_weight_norm(layer): if isinstance(layer, (nn.Conv1D, nn.Conv1DTranspose)): nn.utils.weight_norm(layer) self.apply(_apply_weight_norm) def remove_weight_norm(self): """Recursively remove weight normalization from all the Convolution layers in the sublayers. """ def _remove_weight_norm(layer): try: if layer: nn.utils.remove_weight_norm(layer) # add AttributeError to bypass https://github.com/PaddlePaddle/Paddle/issues/38532 temporarily except (ValueError, AttributeError): pass self.apply(_remove_weight_norm) def reset_parameters(self): """Reset parameters. This initialization follows official implementation manner. https://github.com/descriptinc/melgan-neurips/blob/master/mel2wav/modules.py """ # 定义参数为float的正态分布。 dist = paddle.distribution.Normal(loc=0.0, scale=0.02) def _reset_parameters(m): if isinstance(m, nn.Conv1D) or isinstance(m, nn.Conv1DTranspose): w = dist.sample(m.weight.shape) m.weight.set_value(w) self.apply(_reset_parameters) def inference(self, c): """Perform inference. Args: c (Tensor): Input tensor (T, in_channels). Returns: Tensor: Output tensor (T ** prod(upsample_scales), out_channels). """ # (1, in_channels, T) c = c.transpose([1, 0]).unsqueeze(0) c_shape = paddle.shape(c) # prepare noise input # there is a bug in Paddle int division, we must convert a int tensor to int here noise_T = paddle.cast( paddle.ceil(c_shape[2] / int(self.noise_upsample_factor)), dtype='int64') noise_size = (1, self.in_channels, noise_T) # (1, in_channels, T/noise_upsample_factor) noise = paddle.randn(noise_size) # (1, in_channels, T) x = self.noise_upsample(noise) x_shape = paddle.shape(x) total_length = c_shape[2] * self.upsample_factor # Dygraph to Static Graph bug here, 2021.12.15 c = F.pad( c, (0, x_shape[2] - c_shape[2]), "replicate", data_format="NCL") # c.shape[2] == x.shape[2] here # (1, in_channels, T*prod(upsample_scales)) for block in self.blocks: x, c = block(x, c) x = self.output_conv(x)[..., :total_length] return x.squeeze(0).transpose([1, 0]) class StyleMelGANDiscriminator(nn.Layer): """Style MelGAN disciminator module.""" def __init__( self, repeats: int=2, window_sizes: List[int]=[512, 1024, 2048, 4096], pqmf_params: List[List[int]]=[ [1, None, None, None], [2, 62, 0.26700, 9.0], [4, 62, 0.14200, 9.0], [8, 62, 0.07949, 9.0], ], discriminator_params: Dict[str, Any]={ "out_channels": 1, "kernel_sizes": [5, 3], "channels": 16, "max_downsample_channels": 512, "bias": True, "downsample_scales": [4, 4, 4, 1], "nonlinear_activation": "leakyrelu", "nonlinear_activation_params": { "negative_slope": 0.2 }, "pad": "Pad1D", "pad_params": { "mode": "reflect" }, }, use_weight_norm: bool=True, init_type: str="xavier_uniform", ): """Initilize Style MelGAN discriminator. Args: repeats (int): Number of repititons to apply RWD. window_sizes (list): List of random window sizes. pqmf_params (list): List of list of Parameters for PQMF modules discriminator_params (dict): Parameters for base discriminator module. use_weight_nom (bool): Whether to apply weight normalization. """ super().__init__() # initialize parameters initialize(self, init_type) # window size check assert len(window_sizes) == len(pqmf_params) sizes = [ws // p[0] for ws, p in zip(window_sizes, pqmf_params)] assert len(window_sizes) == sum([sizes[0] == size for size in sizes]) self.repeats = repeats self.window_sizes = window_sizes self.pqmfs = nn.LayerList() self.discriminators = nn.LayerList() for pqmf_param in pqmf_params: d_params = copy.deepcopy(discriminator_params) d_params["in_channels"] = pqmf_param[0] if pqmf_param[0] == 1: self.pqmfs.append(nn.Identity()) else: self.pqmfs.append(PQMF(*pqmf_param)) self.discriminators.append(BaseDiscriminator(**d_params)) nn.initializer.set_global_initializer(None) # apply weight norm if use_weight_norm: self.apply_weight_norm() # reset parameters self.reset_parameters() def forward(self, x): """Calculate forward propagation. Args: x (Tensor): Input tensor (B, 1, T). Returns: List: List of discriminator outputs, #items in the list will be equal to repeats * #discriminators. """ outs = [] for _ in range(self.repeats): outs += self._forward(x) return outs def _forward(self, x): outs = [] for idx, (ws, pqmf, disc) in enumerate( zip(self.window_sizes, self.pqmfs, self.discriminators)): start_idx = int(np.random.randint(paddle.shape(x)[-1] - ws)) x_ = x[:, :, start_idx:start_idx + ws] if idx == 0: # nn.Identity() x_ = pqmf(x_) else: x_ = pqmf.analysis(x_) outs += [disc(x_)] return outs def apply_weight_norm(self): """Recursively apply weight normalization to all the Convolution layers in the sublayers. """ def _apply_weight_norm(layer): if isinstance(layer, (nn.Conv1D, nn.Conv1DTranspose)): nn.utils.weight_norm(layer) self.apply(_apply_weight_norm) def remove_weight_norm(self): """Recursively remove weight normalization from all the Convolution layers in the sublayers. """ def _remove_weight_norm(layer): try: nn.utils.remove_weight_norm(layer) except ValueError: pass self.apply(_remove_weight_norm) def reset_parameters(self): """Reset parameters. This initialization follows official implementation manner. https://github.com/descriptinc/melgan-neurips/blob/master/mel2wav/modules.py """ # 定义参数为float的正态分布。 dist = paddle.distribution.Normal(loc=0.0, scale=0.02) def _reset_parameters(m): if isinstance(m, nn.Conv1D) or isinstance(m, nn.Conv1DTranspose): w = dist.sample(m.weight.shape) m.weight.set_value(w) self.apply(_reset_parameters) class StyleMelGANInference(nn.Layer): def __init__(self, normalizer, style_melgan_generator): super().__init__() self.normalizer = normalizer self.style_melgan_generator = style_melgan_generator def forward(self, logmel): normalized_mel = self.normalizer(logmel) wav = self.style_melgan_generator.inference(normalized_mel) return wav