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572 lines
20 KiB
572 lines
20 KiB
# Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved.
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#
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# Licensed under the Apache License, Version 2.0 (the "License");
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# you may not use this file except in compliance with the License.
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# You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing, software
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# distributed under the License is distributed on an "AS IS" BASIS,
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# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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# See the License for the specific language governing permissions and
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# limitations under the License.
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# Modified from espnet(https://github.com/espnet/espnet)
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"""MelGAN Modules."""
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from typing import Any
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from typing import Dict
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from typing import List
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import numpy as np
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import paddle
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from paddle import nn
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from paddlespeech.t2s.modules.activation import get_activation
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from paddlespeech.t2s.modules.causal_conv import CausalConv1D
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from paddlespeech.t2s.modules.causal_conv import CausalConv1DTranspose
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from paddlespeech.t2s.modules.nets_utils import initialize
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from paddlespeech.t2s.modules.pqmf import PQMF
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from paddlespeech.t2s.modules.residual_stack import ResidualStack
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class MelGANGenerator(nn.Layer):
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"""MelGAN generator module."""
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def __init__(
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self,
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in_channels: int=80,
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out_channels: int=1,
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kernel_size: int=7,
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channels: int=512,
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bias: bool=True,
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upsample_scales: List[int]=[8, 8, 2, 2],
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stack_kernel_size: int=3,
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stacks: int=3,
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nonlinear_activation: str="leakyrelu",
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nonlinear_activation_params: Dict[str, Any]={"negative_slope": 0.2},
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pad: str="Pad1D",
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pad_params: Dict[str, Any]={"mode": "reflect"},
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use_final_nonlinear_activation: bool=True,
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use_weight_norm: bool=True,
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use_causal_conv: bool=False,
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init_type: str="xavier_uniform", ):
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"""Initialize MelGANGenerator module.
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Args:
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in_channels (int):
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Number of input channels.
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out_channels (int):
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Number of output channels,
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the number of sub-band is out_channels in multi-band melgan.
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kernel_size (int):
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Kernel size of initial and final conv layer.
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channels (int):
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Initial number of channels for conv layer.
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bias (bool):
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Whether to add bias parameter in convolution layers.
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upsample_scales (List[int]):
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List of upsampling scales.
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stack_kernel_size (int):
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Kernel size of dilated conv layers in residual stack.
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stacks (int):
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Number of stacks in a single residual stack.
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nonlinear_activation (Optional[str], optional):
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Non linear activation in upsample network, by default None
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nonlinear_activation_params (Dict[str, Any], optional):
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Parameters passed to the linear activation in the upsample network, by default {}
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pad (str):
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Padding function module name before dilated convolution layer.
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pad_params (dict):
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Hyperparameters for padding function.
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use_final_nonlinear_activation (nn.Layer):
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Activation function for the final layer.
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use_weight_norm (bool):
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Whether to use weight norm.
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If set to true, it will be applied to all of the conv layers.
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use_causal_conv (bool):
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Whether to use causal convolution.
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"""
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super().__init__()
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# initialize parameters
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initialize(self, init_type)
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# for compatibility
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if nonlinear_activation:
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nonlinear_activation = nonlinear_activation.lower()
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# check hyper parameters is valid
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assert channels >= np.prod(upsample_scales)
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assert channels % (2**len(upsample_scales)) == 0
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if not use_causal_conv:
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assert (kernel_size - 1
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) % 2 == 0, "Not support even number kernel size."
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layers = []
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if not use_causal_conv:
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layers += [
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getattr(paddle.nn, pad)((kernel_size - 1) // 2, **pad_params),
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nn.Conv1D(in_channels, channels, kernel_size, bias_attr=bias),
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]
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else:
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layers += [
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CausalConv1D(
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in_channels,
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channels,
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kernel_size,
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bias=bias,
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pad=pad,
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pad_params=pad_params, ),
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]
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for i, upsample_scale in enumerate(upsample_scales):
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# add upsampling layer
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layers += [
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get_activation(nonlinear_activation,
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**nonlinear_activation_params)
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]
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if not use_causal_conv:
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layers += [
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nn.Conv1DTranspose(
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channels // (2**i),
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channels // (2**(i + 1)),
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upsample_scale * 2,
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stride=upsample_scale,
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padding=upsample_scale // 2 + upsample_scale % 2,
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output_padding=upsample_scale % 2,
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bias_attr=bias, )
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]
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else:
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layers += [
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CausalConv1DTranspose(
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channels // (2**i),
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channels // (2**(i + 1)),
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upsample_scale * 2,
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stride=upsample_scale,
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bias=bias, )
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]
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# add residual stack
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for j in range(stacks):
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layers += [
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ResidualStack(
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kernel_size=stack_kernel_size,
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channels=channels // (2**(i + 1)),
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dilation=stack_kernel_size**j,
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bias=bias,
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nonlinear_activation=nonlinear_activation,
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nonlinear_activation_params=nonlinear_activation_params,
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pad=pad,
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pad_params=pad_params,
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use_causal_conv=use_causal_conv, )
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]
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# add final layer
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layers += [
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get_activation(nonlinear_activation, **nonlinear_activation_params)
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]
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if not use_causal_conv:
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layers += [
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getattr(nn, pad)((kernel_size - 1) // 2, **pad_params),
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nn.Conv1D(
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channels // (2**(i + 1)),
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out_channels,
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kernel_size,
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bias_attr=bias),
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]
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else:
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layers += [
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CausalConv1D(
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channels // (2**(i + 1)),
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out_channels,
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kernel_size,
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bias=bias,
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pad=pad,
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pad_params=pad_params, ),
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]
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if use_final_nonlinear_activation:
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layers += [nn.Tanh()]
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# define the model as a single function
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self.melgan = nn.Sequential(*layers)
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nn.initializer.set_global_initializer(None)
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# apply weight norm
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if use_weight_norm:
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self.apply_weight_norm()
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# reset parameters
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self.reset_parameters()
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# initialize pqmf for multi-band melgan inference
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if out_channels > 1:
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self.pqmf = PQMF(subbands=out_channels)
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else:
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self.pqmf = None
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def forward(self, c):
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"""Calculate forward propagation.
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Args:
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c (Tensor):
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Input tensor (B, in_channels, T).
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Returns:
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Tensor: Output tensor (B, out_channels, T ** prod(upsample_scales)).
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"""
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out = self.melgan(c)
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return out
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def apply_weight_norm(self):
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"""Recursively apply weight normalization to all the Convolution layers
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in the sublayers.
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"""
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def _apply_weight_norm(layer):
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if isinstance(layer, (nn.Conv1D, nn.Conv2D, nn.Conv1DTranspose)):
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nn.utils.weight_norm(layer)
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self.apply(_apply_weight_norm)
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def remove_weight_norm(self):
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"""Recursively remove weight normalization from all the Convolution
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layers in the sublayers.
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"""
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def _remove_weight_norm(layer):
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try:
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nn.utils.remove_weight_norm(layer)
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except ValueError:
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pass
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self.apply(_remove_weight_norm)
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def reset_parameters(self):
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"""Reset parameters.
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This initialization follows official implementation manner.
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https://github.com/descriptinc/melgan-neurips/blob/master/mel2wav/modules.py
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"""
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# 定义参数为float的正态分布。
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dist = paddle.distribution.Normal(loc=0.0, scale=0.02)
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def _reset_parameters(m):
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if isinstance(m, nn.Conv1D) or isinstance(m, nn.Conv1DTranspose):
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w = dist.sample(m.weight.shape)
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m.weight.set_value(w)
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self.apply(_reset_parameters)
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def inference(self, c):
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"""Perform inference.
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Args:
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c (Union[Tensor, ndarray]):
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Input tensor (T, in_channels).
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Returns:
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Tensor: Output tensor (out_channels*T ** prod(upsample_scales), 1).
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"""
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# pseudo batch
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c = c.transpose([1, 0]).unsqueeze(0)
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# (B, out_channels, T ** prod(upsample_scales)
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out = self.melgan(c)
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if self.pqmf is not None:
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# (B, 1, out_channels * T ** prod(upsample_scales)
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out = self.pqmf(out)
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out = out.squeeze(0).transpose([1, 0])
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return out
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class MelGANDiscriminator(nn.Layer):
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"""MelGAN discriminator module."""
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def __init__(
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self,
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in_channels: int=1,
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out_channels: int=1,
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kernel_sizes: List[int]=[5, 3],
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channels: int=16,
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max_downsample_channels: int=1024,
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bias: bool=True,
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downsample_scales: List[int]=[4, 4, 4, 4],
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nonlinear_activation: str="leakyrelu",
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nonlinear_activation_params: Dict[str, Any]={"negative_slope": 0.2},
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pad: str="Pad1D",
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pad_params: Dict[str, Any]={"mode": "reflect"},
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init_type: str="xavier_uniform", ):
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"""Initilize MelGAN discriminator module.
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Args:
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in_channels (int):
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Number of input channels.
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out_channels (int):
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Number of output channels.
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kernel_sizes (List[int]): List of two kernel sizes. The prod will be used for the first conv layer,
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and the first and the second kernel sizes will be used for the last two layers.
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For example if kernel_sizes = [5, 3], the first layer kernel size will be 5 * 3 = 15,
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the last two layers' kernel size will be 5 and 3, respectively.
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channels (int):
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Initial number of channels for conv layer.
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max_downsample_channels (int):
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Maximum number of channels for downsampling layers.
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bias (bool):
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Whether to add bias parameter in convolution layers.
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downsample_scales (List[int]):
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List of downsampling scales.
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nonlinear_activation (str):
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Activation function module name.
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nonlinear_activation_params (dict):
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Hyperparameters for activation function.
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pad (str):
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Padding function module name before dilated convolution layer.
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pad_params (dict):
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Hyperparameters for padding function.
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"""
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super().__init__()
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# for compatibility
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if nonlinear_activation:
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nonlinear_activation = nonlinear_activation.lower()
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# initialize parameters
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initialize(self, init_type)
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self.layers = nn.LayerList()
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# check kernel size is valid
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assert len(kernel_sizes) == 2
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assert kernel_sizes[0] % 2 == 1
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assert kernel_sizes[1] % 2 == 1
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# add first layer
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self.layers.append(
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nn.Sequential(
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getattr(nn, pad)((np.prod(kernel_sizes) - 1) // 2, **
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pad_params),
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nn.Conv1D(
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in_channels,
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channels,
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int(np.prod(kernel_sizes)),
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bias_attr=bias),
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get_activation(nonlinear_activation, **
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nonlinear_activation_params), ))
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# add downsample layers
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in_chs = channels
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for downsample_scale in downsample_scales:
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out_chs = min(in_chs * downsample_scale, max_downsample_channels)
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self.layers.append(
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nn.Sequential(
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nn.Conv1D(
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in_chs,
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out_chs,
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kernel_size=downsample_scale * 10 + 1,
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stride=downsample_scale,
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padding=downsample_scale * 5,
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groups=in_chs // 4,
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bias_attr=bias, ),
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get_activation(nonlinear_activation, **
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nonlinear_activation_params), ))
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in_chs = out_chs
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# add final layers
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out_chs = min(in_chs * 2, max_downsample_channels)
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self.layers.append(
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nn.Sequential(
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nn.Conv1D(
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in_chs,
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out_chs,
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kernel_sizes[0],
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padding=(kernel_sizes[0] - 1) // 2,
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bias_attr=bias, ),
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get_activation(nonlinear_activation, **
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nonlinear_activation_params), ))
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self.layers.append(
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nn.Conv1D(
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out_chs,
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out_channels,
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kernel_sizes[1],
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padding=(kernel_sizes[1] - 1) // 2,
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bias_attr=bias, ), )
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def forward(self, x):
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"""Calculate forward propagation.
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Args:
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x (Tensor):
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Input noise signal (B, 1, T).
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Returns:
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List: List of output tensors of each layer (for feat_match_loss).
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"""
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outs = []
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for f in self.layers:
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x = f(x)
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outs += [x]
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return outs
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class MelGANMultiScaleDiscriminator(nn.Layer):
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"""MelGAN multi-scale discriminator module."""
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def __init__(
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self,
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in_channels: int=1,
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out_channels: int=1,
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scales: int=3,
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downsample_pooling: str="AvgPool1D",
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# follow the official implementation setting
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downsample_pooling_params: Dict[str, Any]={
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"kernel_size": 4,
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"stride": 2,
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"padding": 1,
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"exclusive": True,
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},
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kernel_sizes: List[int]=[5, 3],
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channels: int=16,
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max_downsample_channels: int=1024,
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bias: bool=True,
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downsample_scales: List[int]=[4, 4, 4, 4],
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nonlinear_activation: str="leakyrelu",
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nonlinear_activation_params: Dict[str, Any]={"negative_slope": 0.2},
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pad: str="Pad1D",
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pad_params: Dict[str, Any]={"mode": "reflect"},
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use_weight_norm: bool=True,
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init_type: str="xavier_uniform", ):
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"""Initilize MelGAN multi-scale discriminator module.
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Args:
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in_channels (int):
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Number of input channels.
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out_channels (int):
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Number of output channels.
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scales (int):
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Number of multi-scales.
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downsample_pooling (str):
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Pooling module name for downsampling of the inputs.
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downsample_pooling_params (dict):
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Parameters for the above pooling module.
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kernel_sizes (List[int]):
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List of two kernel sizes. The sum will be used for the first conv layer,
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and the first and the second kernel sizes will be used for the last two layers.
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channels (int):
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Initial number of channels for conv layer.
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max_downsample_channels (int):
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Maximum number of channels for downsampling layers.
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bias (bool):
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Whether to add bias parameter in convolution layers.
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downsample_scales (List[int]):
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List of downsampling scales.
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nonlinear_activation (str):
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Activation function module name.
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nonlinear_activation_params (dict):
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Hyperparameters for activation function.
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pad (str):
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Padding function module name before dilated convolution layer.
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pad_params (dict):
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Hyperparameters for padding function.
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use_causal_conv (bool):
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Whether to use causal convolution.
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"""
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super().__init__()
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# initialize parameters
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initialize(self, init_type)
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# for
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if nonlinear_activation:
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nonlinear_activation = nonlinear_activation.lower()
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self.discriminators = nn.LayerList()
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# add discriminators
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for _ in range(scales):
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self.discriminators.append(
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MelGANDiscriminator(
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in_channels=in_channels,
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out_channels=out_channels,
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kernel_sizes=kernel_sizes,
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channels=channels,
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max_downsample_channels=max_downsample_channels,
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bias=bias,
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downsample_scales=downsample_scales,
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nonlinear_activation=nonlinear_activation,
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nonlinear_activation_params=nonlinear_activation_params,
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pad=pad,
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pad_params=pad_params, ))
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self.pooling = getattr(nn, downsample_pooling)(
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**downsample_pooling_params)
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nn.initializer.set_global_initializer(None)
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# apply weight norm
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if use_weight_norm:
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self.apply_weight_norm()
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# reset parameters
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self.reset_parameters()
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def forward(self, x):
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"""Calculate forward propagation.
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Args:
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x (Tensor):
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Input noise signal (B, 1, T).
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Returns:
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List: List of list of each discriminator outputs, which consists of each layer output tensors.
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"""
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outs = []
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for f in self.discriminators:
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outs += [f(x)]
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x = self.pooling(x)
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return outs
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def apply_weight_norm(self):
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"""Recursively apply weight normalization to all the Convolution layers
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in the sublayers.
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"""
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def _apply_weight_norm(layer):
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if isinstance(layer, (nn.Conv1D, nn.Conv2D, nn.Conv1DTranspose)):
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nn.utils.weight_norm(layer)
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self.apply(_apply_weight_norm)
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def remove_weight_norm(self):
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"""Recursively remove weight normalization from all the Convolution
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layers in the sublayers.
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"""
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def _remove_weight_norm(layer):
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try:
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nn.utils.remove_weight_norm(layer)
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except ValueError:
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pass
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self.apply(_remove_weight_norm)
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def reset_parameters(self):
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"""Reset parameters.
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This initialization follows official implementation manner.
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https://github.com/descriptinc/melgan-neurips/blob/master/mel2wav/modules.py
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"""
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# 定义参数为float的正态分布。
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dist = paddle.distribution.Normal(loc=0.0, scale=0.02)
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def _reset_parameters(m):
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if isinstance(m, nn.Conv1D) or isinstance(m, nn.Conv1DTranspose):
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w = dist.sample(m.weight.shape)
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m.weight.set_value(w)
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self.apply(_reset_parameters)
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|
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class MelGANInference(nn.Layer):
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def __init__(self, normalizer, melgan_generator):
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super().__init__()
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self.normalizer = normalizer
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self.melgan_generator = melgan_generator
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|
|
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def forward(self, logmel):
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|
normalized_mel = self.normalizer(logmel)
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|
wav = self.melgan_generator.inference(normalized_mel)
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|
return wav
|