mirror of
https://github.com/babysor/MockingBird.git
synced 2024-03-22 13:11:31 +08:00
520 lines
20 KiB
Python
520 lines
20 KiB
Python
import os
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import numpy as np
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import torch
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import torch.nn as nn
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import torch.nn.functional as F
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from pathlib import Path
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from typing import Union
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class HighwayNetwork(nn.Module):
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def __init__(self, size):
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super().__init__()
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self.W1 = nn.Linear(size, size)
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self.W2 = nn.Linear(size, size)
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self.W1.bias.data.fill_(0.)
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def forward(self, x):
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x1 = self.W1(x)
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x2 = self.W2(x)
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g = torch.sigmoid(x2)
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y = g * F.relu(x1) + (1. - g) * x
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return y
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class Encoder(nn.Module):
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def __init__(self, embed_dims, num_chars, encoder_dims, K, num_highways, dropout):
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super().__init__()
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prenet_dims = (encoder_dims, encoder_dims)
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cbhg_channels = encoder_dims
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self.embedding = nn.Embedding(num_chars, embed_dims)
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self.pre_net = PreNet(embed_dims, fc1_dims=prenet_dims[0], fc2_dims=prenet_dims[1],
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dropout=dropout)
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self.cbhg = CBHG(K=K, in_channels=cbhg_channels, channels=cbhg_channels,
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proj_channels=[cbhg_channels, cbhg_channels],
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num_highways=num_highways)
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def forward(self, x, speaker_embedding=None):
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x = self.embedding(x)
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x = self.pre_net(x)
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x.transpose_(1, 2)
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x = self.cbhg(x)
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if speaker_embedding is not None:
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x = self.add_speaker_embedding(x, speaker_embedding)
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return x
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def add_speaker_embedding(self, x, speaker_embedding):
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# SV2TTS
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# The input x is the encoder output and is a 3D tensor with size (batch_size, num_chars, tts_embed_dims)
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# When training, speaker_embedding is also a 2D tensor with size (batch_size, speaker_embedding_size)
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# (for inference, speaker_embedding is a 1D tensor with size (speaker_embedding_size))
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# This concats the speaker embedding for each char in the encoder output
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# Save the dimensions as human-readable names
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batch_size = x.size()[0]
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num_chars = x.size()[1]
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if speaker_embedding.dim() == 1:
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idx = 0
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else:
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idx = 1
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# Start by making a copy of each speaker embedding to match the input text length
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# The output of this has size (batch_size, num_chars * tts_embed_dims)
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speaker_embedding_size = speaker_embedding.size()[idx]
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e = speaker_embedding.repeat_interleave(num_chars, dim=idx)
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# Reshape it and transpose
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e = e.reshape(batch_size, speaker_embedding_size, num_chars)
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e = e.transpose(1, 2)
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# Concatenate the tiled speaker embedding with the encoder output
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x = torch.cat((x, e), 2)
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return x
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class BatchNormConv(nn.Module):
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def __init__(self, in_channels, out_channels, kernel, relu=True):
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super().__init__()
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self.conv = nn.Conv1d(in_channels, out_channels, kernel, stride=1, padding=kernel // 2, bias=False)
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self.bnorm = nn.BatchNorm1d(out_channels)
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self.relu = relu
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def forward(self, x):
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x = self.conv(x)
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x = F.relu(x) if self.relu is True else x
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return self.bnorm(x)
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class CBHG(nn.Module):
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def __init__(self, K, in_channels, channels, proj_channels, num_highways):
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super().__init__()
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# List of all rnns to call `flatten_parameters()` on
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self._to_flatten = []
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self.bank_kernels = [i for i in range(1, K + 1)]
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self.conv1d_bank = nn.ModuleList()
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for k in self.bank_kernels:
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conv = BatchNormConv(in_channels, channels, k)
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self.conv1d_bank.append(conv)
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self.maxpool = nn.MaxPool1d(kernel_size=2, stride=1, padding=1)
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self.conv_project1 = BatchNormConv(len(self.bank_kernels) * channels, proj_channels[0], 3)
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self.conv_project2 = BatchNormConv(proj_channels[0], proj_channels[1], 3, relu=False)
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# Fix the highway input if necessary
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if proj_channels[-1] != channels:
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self.highway_mismatch = True
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self.pre_highway = nn.Linear(proj_channels[-1], channels, bias=False)
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else:
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self.highway_mismatch = False
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self.highways = nn.ModuleList()
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for i in range(num_highways):
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hn = HighwayNetwork(channels)
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self.highways.append(hn)
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self.rnn = nn.GRU(channels, channels // 2, batch_first=True, bidirectional=True)
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self._to_flatten.append(self.rnn)
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# Avoid fragmentation of RNN parameters and associated warning
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self._flatten_parameters()
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def forward(self, x):
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# Although we `_flatten_parameters()` on init, when using DataParallel
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# the model gets replicated, making it no longer guaranteed that the
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# weights are contiguous in GPU memory. Hence, we must call it again
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self._flatten_parameters()
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# Save these for later
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residual = x
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seq_len = x.size(-1)
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conv_bank = []
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# Convolution Bank
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for conv in self.conv1d_bank:
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c = conv(x) # Convolution
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conv_bank.append(c[:, :, :seq_len])
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# Stack along the channel axis
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conv_bank = torch.cat(conv_bank, dim=1)
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# dump the last padding to fit residual
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x = self.maxpool(conv_bank)[:, :, :seq_len]
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# Conv1d projections
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x = self.conv_project1(x)
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x = self.conv_project2(x)
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# Residual Connect
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x = x + residual
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# Through the highways
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x = x.transpose(1, 2)
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if self.highway_mismatch is True:
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x = self.pre_highway(x)
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for h in self.highways: x = h(x)
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# And then the RNN
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x, _ = self.rnn(x)
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return x
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def _flatten_parameters(self):
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"""Calls `flatten_parameters` on all the rnns used by the WaveRNN. Used
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to improve efficiency and avoid PyTorch yelling at us."""
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[m.flatten_parameters() for m in self._to_flatten]
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class PreNet(nn.Module):
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def __init__(self, in_dims, fc1_dims=256, fc2_dims=128, dropout=0.5):
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super().__init__()
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self.fc1 = nn.Linear(in_dims, fc1_dims)
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self.fc2 = nn.Linear(fc1_dims, fc2_dims)
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self.p = dropout
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def forward(self, x):
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x = self.fc1(x)
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x = F.relu(x)
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x = F.dropout(x, self.p, training=True)
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x = self.fc2(x)
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x = F.relu(x)
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x = F.dropout(x, self.p, training=True)
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return x
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class Attention(nn.Module):
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def __init__(self, attn_dims):
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super().__init__()
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self.W = nn.Linear(attn_dims, attn_dims, bias=False)
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self.v = nn.Linear(attn_dims, 1, bias=False)
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def forward(self, encoder_seq_proj, query, t):
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# print(encoder_seq_proj.shape)
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# Transform the query vector
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query_proj = self.W(query).unsqueeze(1)
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# Compute the scores
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u = self.v(torch.tanh(encoder_seq_proj + query_proj))
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scores = F.softmax(u, dim=1)
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return scores.transpose(1, 2)
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class LSA(nn.Module):
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def __init__(self, attn_dim, kernel_size=31, filters=32):
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super().__init__()
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self.conv = nn.Conv1d(1, filters, padding=(kernel_size - 1) // 2, kernel_size=kernel_size, bias=True)
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self.L = nn.Linear(filters, attn_dim, bias=False)
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self.W = nn.Linear(attn_dim, attn_dim, bias=True) # Include the attention bias in this term
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self.v = nn.Linear(attn_dim, 1, bias=False)
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self.cumulative = None
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self.attention = None
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def init_attention(self, encoder_seq_proj):
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device = next(self.parameters()).device # use same device as parameters
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b, t, c = encoder_seq_proj.size()
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self.cumulative = torch.zeros(b, t, device=device)
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self.attention = torch.zeros(b, t, device=device)
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def forward(self, encoder_seq_proj, query, t, chars):
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if t == 0: self.init_attention(encoder_seq_proj)
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processed_query = self.W(query).unsqueeze(1)
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location = self.cumulative.unsqueeze(1)
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processed_loc = self.L(self.conv(location).transpose(1, 2))
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u = self.v(torch.tanh(processed_query + encoder_seq_proj + processed_loc))
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u = u.squeeze(-1)
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# Mask zero padding chars
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u = u * (chars != 0).float()
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# Smooth Attention
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# scores = torch.sigmoid(u) / torch.sigmoid(u).sum(dim=1, keepdim=True)
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scores = F.softmax(u, dim=1)
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self.attention = scores
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self.cumulative = self.cumulative + self.attention
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return scores.unsqueeze(-1).transpose(1, 2)
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class Decoder(nn.Module):
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# Class variable because its value doesn't change between classes
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# yet ought to be scoped by class because its a property of a Decoder
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max_r = 20
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def __init__(self, n_mels, encoder_dims, decoder_dims, lstm_dims,
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dropout, speaker_embedding_size):
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super().__init__()
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self.register_buffer("r", torch.tensor(1, dtype=torch.int))
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self.n_mels = n_mels
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prenet_dims = (decoder_dims * 2, decoder_dims * 2)
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self.prenet = PreNet(n_mels, fc1_dims=prenet_dims[0], fc2_dims=prenet_dims[1],
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dropout=dropout)
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self.attn_net = LSA(decoder_dims)
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self.attn_rnn = nn.GRUCell(encoder_dims + prenet_dims[1] + speaker_embedding_size, decoder_dims)
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self.rnn_input = nn.Linear(encoder_dims + decoder_dims + speaker_embedding_size, lstm_dims)
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self.res_rnn1 = nn.LSTMCell(lstm_dims, lstm_dims)
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self.res_rnn2 = nn.LSTMCell(lstm_dims, lstm_dims)
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self.mel_proj = nn.Linear(lstm_dims, n_mels * self.max_r, bias=False)
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self.stop_proj = nn.Linear(encoder_dims + speaker_embedding_size + lstm_dims, 1)
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def zoneout(self, prev, current, p=0.1):
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device = next(self.parameters()).device # Use same device as parameters
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mask = torch.zeros(prev.size(), device=device).bernoulli_(p)
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return prev * mask + current * (1 - mask)
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def forward(self, encoder_seq, encoder_seq_proj, prenet_in,
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hidden_states, cell_states, context_vec, t, chars):
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# Need this for reshaping mels
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batch_size = encoder_seq.size(0)
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# Unpack the hidden and cell states
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attn_hidden, rnn1_hidden, rnn2_hidden = hidden_states
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rnn1_cell, rnn2_cell = cell_states
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# PreNet for the Attention RNN
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prenet_out = self.prenet(prenet_in)
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# Compute the Attention RNN hidden state
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attn_rnn_in = torch.cat([context_vec, prenet_out], dim=-1)
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attn_hidden = self.attn_rnn(attn_rnn_in.squeeze(1), attn_hidden)
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# Compute the attention scores
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scores = self.attn_net(encoder_seq_proj, attn_hidden, t, chars)
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# Dot product to create the context vector
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context_vec = scores @ encoder_seq
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context_vec = context_vec.squeeze(1)
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# Concat Attention RNN output w. Context Vector & project
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x = torch.cat([context_vec, attn_hidden], dim=1)
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x = self.rnn_input(x)
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# Compute first Residual RNN
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rnn1_hidden_next, rnn1_cell = self.res_rnn1(x, (rnn1_hidden, rnn1_cell))
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if self.training:
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rnn1_hidden = self.zoneout(rnn1_hidden, rnn1_hidden_next)
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else:
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rnn1_hidden = rnn1_hidden_next
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x = x + rnn1_hidden
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# Compute second Residual RNN
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rnn2_hidden_next, rnn2_cell = self.res_rnn2(x, (rnn2_hidden, rnn2_cell))
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if self.training:
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rnn2_hidden = self.zoneout(rnn2_hidden, rnn2_hidden_next)
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else:
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rnn2_hidden = rnn2_hidden_next
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x = x + rnn2_hidden
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# Project Mels
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mels = self.mel_proj(x)
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mels = mels.view(batch_size, self.n_mels, self.max_r)[:, :, :self.r]
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hidden_states = (attn_hidden, rnn1_hidden, rnn2_hidden)
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cell_states = (rnn1_cell, rnn2_cell)
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# Stop token prediction
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s = torch.cat((x, context_vec), dim=1)
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s = self.stop_proj(s)
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stop_tokens = torch.sigmoid(s)
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return mels, scores, hidden_states, cell_states, context_vec, stop_tokens
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class Tacotron(nn.Module):
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def __init__(self, embed_dims, num_chars, encoder_dims, decoder_dims, n_mels,
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fft_bins, postnet_dims, encoder_K, lstm_dims, postnet_K, num_highways,
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dropout, stop_threshold, speaker_embedding_size):
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super().__init__()
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self.n_mels = n_mels
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self.lstm_dims = lstm_dims
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self.encoder_dims = encoder_dims
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self.decoder_dims = decoder_dims
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self.speaker_embedding_size = speaker_embedding_size
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self.encoder = Encoder(embed_dims, num_chars, encoder_dims,
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encoder_K, num_highways, dropout)
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self.encoder_proj = nn.Linear(encoder_dims + speaker_embedding_size, decoder_dims, bias=False)
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self.decoder = Decoder(n_mels, encoder_dims, decoder_dims, lstm_dims,
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dropout, speaker_embedding_size)
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self.postnet = CBHG(postnet_K, n_mels, postnet_dims,
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[postnet_dims, fft_bins], num_highways)
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self.post_proj = nn.Linear(postnet_dims, fft_bins, bias=False)
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self.init_model()
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self.num_params()
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self.register_buffer("step", torch.zeros(1, dtype=torch.long))
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self.register_buffer("stop_threshold", torch.tensor(stop_threshold, dtype=torch.float32))
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@property
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def r(self):
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return self.decoder.r.item()
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@r.setter
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def r(self, value):
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self.decoder.r = self.decoder.r.new_tensor(value, requires_grad=False)
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def forward(self, x, m, speaker_embedding):
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device = next(self.parameters()).device # use same device as parameters
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self.step += 1
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batch_size, _, steps = m.size()
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# Initialise all hidden states and pack into tuple
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attn_hidden = torch.zeros(batch_size, self.decoder_dims, device=device)
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rnn1_hidden = torch.zeros(batch_size, self.lstm_dims, device=device)
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rnn2_hidden = torch.zeros(batch_size, self.lstm_dims, device=device)
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hidden_states = (attn_hidden, rnn1_hidden, rnn2_hidden)
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# Initialise all lstm cell states and pack into tuple
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rnn1_cell = torch.zeros(batch_size, self.lstm_dims, device=device)
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rnn2_cell = torch.zeros(batch_size, self.lstm_dims, device=device)
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cell_states = (rnn1_cell, rnn2_cell)
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# <GO> Frame for start of decoder loop
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go_frame = torch.zeros(batch_size, self.n_mels, device=device)
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# Need an initial context vector
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context_vec = torch.zeros(batch_size, self.encoder_dims + self.speaker_embedding_size, device=device)
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# SV2TTS: Run the encoder with the speaker embedding
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# The projection avoids unnecessary matmuls in the decoder loop
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encoder_seq = self.encoder(x, speaker_embedding)
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encoder_seq_proj = self.encoder_proj(encoder_seq)
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# Need a couple of lists for outputs
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mel_outputs, attn_scores, stop_outputs = [], [], []
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# Run the decoder loop
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for t in range(0, steps, self.r):
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prenet_in = m[:, :, t - 1] if t > 0 else go_frame
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mel_frames, scores, hidden_states, cell_states, context_vec, stop_tokens = \
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self.decoder(encoder_seq, encoder_seq_proj, prenet_in,
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hidden_states, cell_states, context_vec, t, x)
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mel_outputs.append(mel_frames)
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attn_scores.append(scores)
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stop_outputs.extend([stop_tokens] * self.r)
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# Concat the mel outputs into sequence
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mel_outputs = torch.cat(mel_outputs, dim=2)
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# Post-Process for Linear Spectrograms
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postnet_out = self.postnet(mel_outputs)
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linear = self.post_proj(postnet_out)
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linear = linear.transpose(1, 2)
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# For easy visualisation
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attn_scores = torch.cat(attn_scores, 1)
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# attn_scores = attn_scores.cpu().data.numpy()
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stop_outputs = torch.cat(stop_outputs, 1)
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return mel_outputs, linear, attn_scores, stop_outputs
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def generate(self, x, speaker_embedding=None, steps=2000):
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self.eval()
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device = next(self.parameters()).device # use same device as parameters
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batch_size, _ = x.size()
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# Need to initialise all hidden states and pack into tuple for tidyness
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attn_hidden = torch.zeros(batch_size, self.decoder_dims, device=device)
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rnn1_hidden = torch.zeros(batch_size, self.lstm_dims, device=device)
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rnn2_hidden = torch.zeros(batch_size, self.lstm_dims, device=device)
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hidden_states = (attn_hidden, rnn1_hidden, rnn2_hidden)
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# Need to initialise all lstm cell states and pack into tuple for tidyness
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rnn1_cell = torch.zeros(batch_size, self.lstm_dims, device=device)
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rnn2_cell = torch.zeros(batch_size, self.lstm_dims, device=device)
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cell_states = (rnn1_cell, rnn2_cell)
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|
|
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# Need a <GO> Frame for start of decoder loop
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go_frame = torch.zeros(batch_size, self.n_mels, device=device)
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|
|
|
# Need an initial context vector
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context_vec = torch.zeros(batch_size, self.encoder_dims + self.speaker_embedding_size, device=device)
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|
|
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# SV2TTS: Run the encoder with the speaker embedding
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# The projection avoids unnecessary matmuls in the decoder loop
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encoder_seq = self.encoder(x, speaker_embedding)
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encoder_seq_proj = self.encoder_proj(encoder_seq)
|
|
|
|
# Need a couple of lists for outputs
|
|
mel_outputs, attn_scores, stop_outputs = [], [], []
|
|
|
|
# Run the decoder loop
|
|
for t in range(0, steps, self.r):
|
|
prenet_in = mel_outputs[-1][:, :, -1] if t > 0 else go_frame
|
|
mel_frames, scores, hidden_states, cell_states, context_vec, stop_tokens = \
|
|
self.decoder(encoder_seq, encoder_seq_proj, prenet_in,
|
|
hidden_states, cell_states, context_vec, t, x)
|
|
mel_outputs.append(mel_frames)
|
|
attn_scores.append(scores)
|
|
stop_outputs.extend([stop_tokens] * self.r)
|
|
# Stop the loop when all stop tokens in batch exceed threshold
|
|
if (stop_tokens > 0.5).all() and t > 10: break
|
|
|
|
# Concat the mel outputs into sequence
|
|
mel_outputs = torch.cat(mel_outputs, dim=2)
|
|
|
|
# Post-Process for Linear Spectrograms
|
|
postnet_out = self.postnet(mel_outputs)
|
|
linear = self.post_proj(postnet_out)
|
|
|
|
|
|
linear = linear.transpose(1, 2)
|
|
|
|
# For easy visualisation
|
|
attn_scores = torch.cat(attn_scores, 1)
|
|
stop_outputs = torch.cat(stop_outputs, 1)
|
|
|
|
self.train()
|
|
|
|
return mel_outputs, linear, attn_scores
|
|
|
|
def init_model(self):
|
|
for p in self.parameters():
|
|
if p.dim() > 1: nn.init.xavier_uniform_(p)
|
|
|
|
def get_step(self):
|
|
return self.step.data.item()
|
|
|
|
def reset_step(self):
|
|
# assignment to parameters or buffers is overloaded, updates internal dict entry
|
|
self.step = self.step.data.new_tensor(1)
|
|
|
|
def log(self, path, msg):
|
|
with open(path, "a") as f:
|
|
print(msg, file=f)
|
|
|
|
def load(self, path, optimizer=None):
|
|
# Use device of model params as location for loaded state
|
|
device = next(self.parameters()).device
|
|
checkpoint = torch.load(str(path), map_location=device)
|
|
self.load_state_dict(checkpoint["model_state"])
|
|
|
|
if "optimizer_state" in checkpoint and optimizer is not None:
|
|
optimizer.load_state_dict(checkpoint["optimizer_state"])
|
|
|
|
def save(self, path, optimizer=None):
|
|
if optimizer is not None:
|
|
torch.save({
|
|
"model_state": self.state_dict(),
|
|
"optimizer_state": optimizer.state_dict(),
|
|
}, str(path))
|
|
else:
|
|
torch.save({
|
|
"model_state": self.state_dict(),
|
|
}, str(path))
|
|
|
|
|
|
def num_params(self, print_out=True):
|
|
parameters = filter(lambda p: p.requires_grad, self.parameters())
|
|
parameters = sum([np.prod(p.size()) for p in parameters]) / 1_000_000
|
|
if print_out:
|
|
print("Trainable Parameters: %.3fM" % parameters)
|
|
return parameters
|