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# Copyright (c) 2024 Amphion. | |
# | |
# This source code is licensed under the MIT license found in the | |
# LICENSE file in the root directory of this source tree. | |
from typing import Union | |
import numpy as np | |
import torch | |
import torch.nn as nn | |
import torch.nn.functional as F | |
from einops import rearrange | |
from torch.nn.utils import weight_norm | |
from models.codec.amphion_codec.quantize.factorized_vector_quantize import ( | |
FactorizedVectorQuantize, | |
) | |
from models.codec.amphion_codec.quantize.vector_quantize import VectorQuantize | |
from models.codec.amphion_codec.quantize.lookup_free_quantize import LookupFreeQuantize | |
class ResidualVQ(nn.Module): | |
""" | |
Introduced in SoundStream: An end2end neural audio codec | |
https://arxiv.org/abs/2107.03312 | |
""" | |
def __init__( | |
self, | |
input_dim: int = 256, | |
num_quantizers: int = 8, | |
codebook_size: int = 1024, | |
codebook_dim: int = 256, | |
quantizer_type: str = "vq", # "vq" or "fvq" or "lfq" | |
quantizer_dropout: float = 0.5, | |
**kwargs, | |
): | |
super().__init__() | |
self.input_dim = input_dim | |
self.num_quantizers = num_quantizers | |
self.codebook_size = codebook_size | |
self.codebook_dim = codebook_dim | |
self.quantizer_type = quantizer_type | |
self.quantizer_dropout = quantizer_dropout | |
if quantizer_type == "vq": | |
VQ = VectorQuantize | |
elif quantizer_type == "fvq": | |
VQ = FactorizedVectorQuantize | |
elif quantizer_type == "lfq": | |
VQ = LookupFreeQuantize | |
else: | |
raise ValueError(f"Unknown quantizer type {quantizer_type}") | |
self.quantizers = nn.ModuleList( | |
[ | |
VQ( | |
input_dim=input_dim, | |
codebook_size=codebook_size, | |
codebook_dim=codebook_dim, | |
**kwargs, | |
) | |
for _ in range(num_quantizers) | |
] | |
) | |
def forward(self, z, n_quantizers: int = None): | |
""" | |
Parameters | |
---------- | |
z : Tensor[B x D x T] | |
n_quantizers : int, optional | |
No. of quantizers to use | |
(n_quantizers < self.n_codebooks ex: for quantizer dropout) | |
Note: if `self.quantizer_dropout` is True, this argument is ignored | |
when in training mode, and a random number of quantizers is used. | |
Returns | |
------- | |
"quantized_out" : Tensor[B x D x T] | |
Quantized continuous representation of input | |
"all_indices" : Tensor[N x B x T] | |
Codebook indices for each codebook | |
(quantized discrete representation of input) | |
"all_commit_losses" : Tensor[N] | |
"all_codebook_losses" : Tensor[N] | |
"all_quantized" : Tensor[N x B x D x T] | |
""" | |
quantized_out = 0.0 | |
residual = z | |
all_commit_losses = [] | |
all_codebook_losses = [] | |
all_indices = [] | |
all_quantized = [] | |
if n_quantizers is None: | |
n_quantizers = self.num_quantizers | |
if self.training: | |
n_quantizers = torch.ones((z.shape[0],)) * self.num_quantizers + 1 | |
dropout = torch.randint(1, self.num_quantizers + 1, (z.shape[0],)) | |
n_dropout = int(z.shape[0] * self.quantizer_dropout) | |
n_quantizers[:n_dropout] = dropout[:n_dropout] | |
n_quantizers = n_quantizers.to(z.device) | |
for i, quantizer in enumerate(self.quantizers): | |
if self.training is False and i >= n_quantizers: | |
break | |
z_q_i, commit_loss_i, codebook_loss_i, indices_i, z_e_i = quantizer( | |
residual | |
) | |
# Create mask to apply quantizer dropout | |
mask = ( | |
torch.full((z.shape[0],), fill_value=i, device=z.device) < n_quantizers | |
) | |
quantized_out = quantized_out + z_q_i * mask[:, None, None] | |
residual = residual - z_q_i | |
commit_loss_i = (commit_loss_i * mask).mean() | |
codebook_loss_i = (codebook_loss_i * mask).mean() | |
all_commit_losses.append(commit_loss_i) | |
all_codebook_losses.append(codebook_loss_i) | |
all_indices.append(indices_i) | |
all_quantized.append(z_q_i) | |
all_commit_losses, all_codebook_losses, all_indices, all_quantized = map( | |
torch.stack, | |
(all_commit_losses, all_codebook_losses, all_indices, all_quantized), | |
) | |
return ( | |
quantized_out, | |
all_indices, | |
all_commit_losses, | |
all_codebook_losses, | |
all_quantized, | |
) | |
def vq2emb(self, vq, n_quantizers=None): | |
quantized_out = 0.0 | |
if n_quantizers is None: | |
n_quantizers = self.num_quantizers | |
for idx, quantizer in enumerate(self.quantizers): | |
if idx >= n_quantizers: | |
break | |
quantized_out += quantizer.vq2emb(vq[idx]) | |
return quantized_out | |
def latent2dist(self, z, n_quantizers=None): | |
quantized_out = 0.0 | |
residual = z | |
all_dists = [] | |
all_indices = [] | |
if n_quantizers is None: | |
n_quantizers = self.num_quantizers | |
for i, quantizer in enumerate(self.quantizers): | |
if self.training is False and i >= n_quantizers: | |
break | |
dist_i, indices_i, z_q_i = quantizer.latent2dist(residual) | |
all_dists.append(dist_i) | |
all_indices.append(indices_i) | |
quantized_out = quantized_out + z_q_i | |
residual = residual - z_q_i | |
all_dists = torch.stack(all_dists) | |
all_indices = torch.stack(all_indices) | |
return all_dists, all_indices | |