beats/quantizer.py

# --------------------------------------------------------
# BEATs: Audio Pre-Training with Acoustic Tokenizers (https://arxiv.org/abs/2212.09058)
# Github source: https://github.com/microsoft/unilm/tree/master/beats
# Copyright (c) 2022 Microsoft
# Licensed under The MIT License [see LICENSE for details]
# Based on VQGAN code bases
# https://github.com/CompVis/taming-transformers
# --------------------------------------------------------'

import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.distributed as distributed

try:
    from einops import rearrange, repeat
except ImportError:
    pass


def l2norm(t):
    return F.normalize(t, p=2, dim=-1)


def ema_inplace(moving_avg, new, decay):
    moving_avg.data.mul_(decay).add_(new, alpha=(1 - decay))


def sample_vectors(samples, num):
    num_samples, device = samples.shape[0], samples.device

    if num_samples >= num:
        indices = torch.randperm(num_samples, device=device)[:num]
    else:
        indices = torch.randint(0, num_samples, (num,), device=device)

    return samples[indices]


def kmeans(samples, num_clusters, num_iters=10, use_cosine_sim=False):
    dim, dtype, device = samples.shape[-1], samples.dtype, samples.device

    means = sample_vectors(samples, num_clusters)

    for _ in range(num_iters):
        if use_cosine_sim:
            dists = samples @ means.t()
        else:
            diffs = rearrange(samples, 'n d -> n () d') \
                    - rearrange(means, 'c d -> () c d')
            dists = -(diffs ** 2).sum(dim=-1)

        buckets = dists.max(dim=-1).indices
        bins = torch.bincount(buckets, minlength=num_clusters)
        zero_mask = bins == 0
        bins_min_clamped = bins.masked_fill(zero_mask, 1)

        new_means = buckets.new_zeros(num_clusters, dim, dtype=dtype)
        new_means.scatter_add_(0, repeat(buckets, 'n -> n d', d=dim), samples)
        new_means = new_means / bins_min_clamped[..., None]

        if use_cosine_sim:
            new_means = l2norm(new_means)

        means = torch.where(zero_mask[..., None], means, new_means)

    return means, bins


class EmbeddingEMA(nn.Module):
    def __init__(self, num_tokens, codebook_dim, decay=0.99, eps=1e-5, kmeans_init=True, codebook_init_path=''):
        super().__init__()
        self.num_tokens = num_tokens
        self.codebook_dim = codebook_dim
        self.decay = decay
        self.eps = eps
        if codebook_init_path == '':
            if not kmeans_init:
                weight = torch.randn(num_tokens, codebook_dim)
                weight = l2norm(weight)
            else:
                weight = torch.zeros(num_tokens, codebook_dim)
            self.register_buffer('initted', torch.Tensor([not kmeans_init]))
        else:
            print(f"load init codebook weight from {codebook_init_path}")
            codebook_ckpt_weight = torch.load(codebook_init_path, map_location='cpu')
            weight = codebook_ckpt_weight.clone()
            self.register_buffer('initted', torch.Tensor([True]))

        self.weight = nn.Parameter(weight, requires_grad=False)
        self.cluster_size = nn.Parameter(torch.zeros(num_tokens), requires_grad=False)
        self.embed_avg = nn.Parameter(weight.clone(), requires_grad=False)
        # self.register_buffer('initted', torch.Tensor([not kmeans_init]))
        self.update = True

    @torch.jit.ignore
    def init_embed_(self, data):
        if self.initted:
            return
        print("Performing Kemans init for codebook")
        embed, cluster_size = kmeans(data, self.num_tokens, 10, use_cosine_sim=True)
        self.weight.data.copy_(embed)
        self.cluster_size.data.copy_(cluster_size)
        self.initted.data.copy_(torch.Tensor([True]))

    def forward(self, embed_id):
        return F.embedding(embed_id, self.weight)

    def cluster_size_ema_update(self, new_cluster_size):
        self.cluster_size.data.mul_(self.decay).add_(new_cluster_size, alpha=1 - self.decay)

    def embed_avg_ema_update(self, new_embed_avg):
        self.embed_avg.data.mul_(self.decay).add_(new_embed_avg, alpha=1 - self.decay)

    def weight_update(self, num_tokens):
        n = self.cluster_size.sum()
        smoothed_cluster_size = (
                (self.cluster_size + self.eps) / (n + num_tokens * self.eps) * n
        )
        # normalize embedding average with smoothed cluster size
        embed_normalized = self.embed_avg / smoothed_cluster_size.unsqueeze(1)
        # embed_normalized = l2norm(self.embed_avg / smoothed_cluster_size.unsqueeze(1))
        self.weight.data.copy_(embed_normalized)


def norm_ema_inplace(moving_avg, new, decay):
    moving_avg.data.mul_(decay).add_(new, alpha=(1 - decay))
    moving_avg.data.copy_(l2norm(moving_avg.data))


class NormEMAVectorQuantizer(nn.Module):
    def __init__(self, n_embed, embedding_dim, beta, decay=0.99, eps=1e-5,
                 statistic_code_usage=True, kmeans_init=False, codebook_init_path=''):
        super().__init__()
        self.codebook_dim = embedding_dim
        self.num_tokens = n_embed
        self.beta = beta
        self.decay = decay

        # learnable = True if orthogonal_reg_weight > 0 else False
        self.embedding = EmbeddingEMA(self.num_tokens, self.codebook_dim, decay, eps, kmeans_init, codebook_init_path)

        self.statistic_code_usage = statistic_code_usage
        if statistic_code_usage:
            self.register_buffer('cluster_size', torch.zeros(n_embed))
        if distributed.is_available() and distributed.is_initialized():
            print("ddp is enable, so use ddp_reduce to sync the statistic_code_usage for each gpu!")
            self.all_reduce_fn = distributed.all_reduce
        else:
            self.all_reduce_fn = nn.Identity()

    def reset_cluster_size(self, device):
        if self.statistic_code_usage:
            self.register_buffer('cluster_size', torch.zeros(self.num_tokens))
            self.cluster_size = self.cluster_size.to(device)

    def forward(self, z):
        # reshape z -> (batch, height, width, channel) and flatten
        # z, 'b c h w -> b h w c'
        # z = rearrange(z, 'b c h w -> b h w c')
        # z = z.transpose(1, 2)
        z = l2norm(z)
        z_flattened = z.reshape(-1, self.codebook_dim)

        self.embedding.init_embed_(z_flattened)

        d = z_flattened.pow(2).sum(dim=1, keepdim=True) + \
            self.embedding.weight.pow(2).sum(dim=1) - 2 * \
            torch.einsum('bd,nd->bn', z_flattened, self.embedding.weight)  # 'n d -> d n'

        encoding_indices = torch.argmin(d, dim=1)

        z_q = self.embedding(encoding_indices).view(z.shape)

        encodings = F.one_hot(encoding_indices, self.num_tokens).type(z.dtype)

        if not self.training:
            with torch.no_grad():
                cluster_size = encodings.sum(0)
                self.all_reduce_fn(cluster_size)
                ema_inplace(self.cluster_size, cluster_size, self.decay)

        if self.training and self.embedding.update:
            # EMA cluster size

            bins = encodings.sum(0)
            self.all_reduce_fn(bins)

            # self.embedding.cluster_size_ema_update(bins)
            ema_inplace(self.cluster_size, bins, self.decay)

            zero_mask = (bins == 0)
            bins = bins.masked_fill(zero_mask, 1.)

            embed_sum = z_flattened.t() @ encodings
            self.all_reduce_fn(embed_sum)

            embed_normalized = (embed_sum / bins.unsqueeze(0)).t()
            embed_normalized = l2norm(embed_normalized)

            embed_normalized = torch.where(zero_mask[..., None], self.embedding.weight,
                                           embed_normalized)
            norm_ema_inplace(self.embedding.weight, embed_normalized, self.decay)

        # compute loss for embedding
        loss = self.beta * F.mse_loss(z_q.detach(), z)

        # preserve gradients
        z_q = z + (z_q - z).detach()

        # reshape back to match original input shape
        # z_q, 'b h w c -> b c h w'
        # z_q = rearrange(z_q, 'b h w c -> b c h w')
        # z_q = z_q.transpose(1, 2)
        return z_q, loss, encoding_indices