446 lines
15 KiB
Python
446 lines
15 KiB
Python
import functools
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import torch
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from torch import nn, einsum
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import torch.nn.functional as F
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import torch.distributed as distributed
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from torch.cuda.amp import autocast
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from einops import rearrange, repeat
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from contextlib import contextmanager
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import torch_intermediary as ml
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def par(t, nm):
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print(f'grad report {nm}: {t}')
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return t
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def reg(t, nm):
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l = torch.tensor([0], requires_grad=True, device=t.device, dtype=torch.float)
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l.register_hook(functools.partial(par, nm=nm))
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t = t + l
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return t
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def exists(val):
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return val is not None
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def default(val, d):
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return val if exists(val) else d
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def noop(*args, **kwargs):
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pass
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def l2norm(t):
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return F.normalize(t, p = 2, dim = -1)
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def log(t, eps = 1e-20):
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return torch.log(t.clamp(min = eps))
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def gumbel_noise(t):
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noise = torch.zeros_like(t).uniform_(0, 1)
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return -log(-log(noise))
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def gumbel_sample(t, temperature = 1., dim = -1):
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if temperature == 0:
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return t.argmax(dim = dim)
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return ((t / temperature) + gumbel_noise(t)).argmax(dim = dim)
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def ema_inplace(moving_avg, new, decay):
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moving_avg.data.mul_(decay).add_(new, alpha = (1 - decay))
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def laplace_smoothing(x, n_categories, eps = 1e-5):
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return (x + eps) / (x.sum() + n_categories * eps)
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def sample_vectors(samples, num):
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num_samples, device = samples.shape[0], samples.device
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if num_samples >= num:
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indices = torch.randperm(num_samples, device = device)[:num]
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else:
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indices = torch.randint(0, num_samples, (num,), device = device)
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return samples[indices]
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def kmeans(samples, num_clusters, num_iters = 10, use_cosine_sim = False):
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dim, dtype, device = samples.shape[-1], samples.dtype, samples.device
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means = sample_vectors(samples, num_clusters)
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for _ in range(num_iters):
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if use_cosine_sim:
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dists = samples @ means.t()
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else:
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diffs = rearrange(samples, 'n d -> n () d') \
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- rearrange(means, 'c d -> () c d')
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dists = -(diffs ** 2).sum(dim = -1)
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buckets = dists.max(dim = -1).indices
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bins = torch.bincount(buckets, minlength = num_clusters)
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zero_mask = bins == 0
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bins_min_clamped = bins.masked_fill(zero_mask, 1)
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new_means = buckets.new_zeros(num_clusters, dim, dtype = dtype)
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new_means.scatter_add_(0, repeat(buckets, 'n -> n d', d = dim), samples)
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new_means = new_means / bins_min_clamped[..., None]
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if use_cosine_sim:
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new_means = l2norm(new_means)
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means = torch.where(zero_mask[..., None], means, new_means)
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return means, bins
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# regularization losses
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def orthgonal_loss_fn(t):
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# eq (2) from https://arxiv.org/abs/2112.00384
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n = t.shape[0]
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normed_codes = l2norm(t)
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identity = torch.eye(n, device = t.device)
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cosine_sim = einsum('i d, j d -> i j', normed_codes, normed_codes)
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return ((cosine_sim - identity) ** 2).sum() / (n ** 2)
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# distance types
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class EuclideanCodebook(nn.Module):
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def __init__(
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self,
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dim,
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codebook_size,
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kmeans_init = False,
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kmeans_iters = 10,
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decay = 0.8,
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eps = 1e-5,
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threshold_ema_dead_code = 2,
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use_ddp = False,
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learnable_codebook = False,
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sample_codebook_temp = 0
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):
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super().__init__()
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self.decay = decay
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init_fn = torch.randn if not kmeans_init else torch.zeros
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embed = init_fn(codebook_size, dim)
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self.codebook_size = codebook_size
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self.kmeans_iters = kmeans_iters
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self.eps = eps
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self.threshold_ema_dead_code = threshold_ema_dead_code
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self.sample_codebook_temp = sample_codebook_temp
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self.all_reduce_fn = distributed.all_reduce if use_ddp else noop
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self.register_buffer('initted', torch.Tensor([not kmeans_init]))
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self.register_buffer('cluster_size', torch.zeros(codebook_size))
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self.register_buffer('embed_avg', embed.clone())
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self.learnable_codebook = learnable_codebook
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if learnable_codebook:
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self.embed = nn.Parameter(embed)
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else:
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self.register_buffer('embed', embed)
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@torch.jit.ignore
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def init_embed_(self, data):
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if self.initted:
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return
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embed, cluster_size = kmeans(data, self.codebook_size, self.kmeans_iters)
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self.embed.data.copy_(embed)
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self.embed_avg.data.copy_(embed.clone())
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self.cluster_size.data.copy_(cluster_size)
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self.initted.data.copy_(torch.Tensor([True]))
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def replace(self, samples, mask):
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modified_codebook = torch.where(
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mask[..., None],
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sample_vectors(samples, self.codebook_size),
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self.embed
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)
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self.embed.data.copy_(modified_codebook)
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def expire_codes_(self, batch_samples):
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if self.threshold_ema_dead_code == 0:
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return
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expired_codes = self.cluster_size < self.threshold_ema_dead_code
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if not torch.any(expired_codes):
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return
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batch_samples = rearrange(batch_samples, '... d -> (...) d')
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self.replace(batch_samples, mask = expired_codes)
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@autocast(enabled = False)
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def forward(self, x, used_codes=[]):
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shape, dtype = x.shape, x.dtype
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flatten = rearrange(x, '... d -> (...) d')
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self.init_embed_(flatten)
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embed = self.embed if not self.learnable_codebook else self.embed.detach()
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embed = embed.t()
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dist = -(
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flatten.pow(2).sum(1, keepdim=True)
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- 2 * flatten @ embed
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+ embed.pow(2).sum(0, keepdim=True)
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)
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for uc in used_codes:
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mask = torch.arange(0, self.codebook_size, device=x.device).unsqueeze(0).repeat(x.shape[0],1) == uc.unsqueeze(1)
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dist[mask] = -torch.inf
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embed_ind = gumbel_sample(dist, dim = -1, temperature = self.sample_codebook_temp)
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embed_onehot = F.one_hot(embed_ind, self.codebook_size).type(dtype)
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embed_ind = embed_ind.view(*shape[:-1])
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quantize = F.embedding(embed_ind, self.embed)
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# Perform the gumbel trick on the end result (during training)
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if self.training:
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quantize = flatten + (quantize - flatten).detach()
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if self.training:
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cluster_size = embed_onehot.sum(0)
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self.all_reduce_fn(cluster_size)
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ema_inplace(self.cluster_size, cluster_size, self.decay)
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embed_sum = flatten.t() @ embed_onehot
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self.all_reduce_fn(embed_sum)
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ema_inplace(self.embed_avg, embed_sum.t(), self.decay)
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cluster_size = laplace_smoothing(self.cluster_size, self.codebook_size, self.eps) * self.cluster_size.sum()
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embed_normalized = self.embed_avg / cluster_size.unsqueeze(1)
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self.embed.data.copy_(embed_normalized)
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self.expire_codes_(x)
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return quantize, embed_ind
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class CosineSimCodebook(nn.Module):
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def __init__(
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self,
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dim,
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codebook_size,
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kmeans_init = False,
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kmeans_iters = 10,
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decay = 0.8,
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eps = 1e-5,
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threshold_ema_dead_code = 2,
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use_ddp = False,
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learnable_codebook = False,
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sample_codebook_temp = 0.
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):
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super().__init__()
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self.decay = decay
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if not kmeans_init:
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embed = l2norm(torch.randn(codebook_size, dim))
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else:
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embed = torch.zeros(codebook_size, dim)
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self.codebook_size = codebook_size
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self.kmeans_iters = kmeans_iters
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self.eps = eps
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self.threshold_ema_dead_code = threshold_ema_dead_code
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self.sample_codebook_temp = sample_codebook_temp
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self.all_reduce_fn = distributed.all_reduce if use_ddp else noop
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self.register_buffer('initted', torch.Tensor([not kmeans_init]))
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self.register_buffer('cluster_size', torch.zeros(codebook_size))
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self.learnable_codebook = learnable_codebook
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if learnable_codebook:
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self.embed = nn.Parameter(embed)
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else:
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self.register_buffer('embed', embed)
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@torch.jit.ignore
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def init_embed_(self, data):
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if self.initted:
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return
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embed, cluster_size = kmeans(data, self.codebook_size, self.kmeans_iters,
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use_cosine_sim = True)
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self.embed.data.copy_(embed)
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self.cluster_size.data.copy_(cluster_size)
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self.initted.data.copy_(torch.Tensor([True]))
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def replace(self, samples, mask):
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samples = l2norm(samples)
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modified_codebook = torch.where(
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mask[..., None],
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sample_vectors(samples, self.codebook_size),
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self.embed
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)
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self.embed.data.copy_(modified_codebook)
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def expire_codes_(self, batch_samples):
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if self.threshold_ema_dead_code == 0:
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return
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expired_codes = self.cluster_size < self.threshold_ema_dead_code
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if not torch.any(expired_codes):
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return
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batch_samples = rearrange(batch_samples, '... d -> (...) d')
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self.replace(batch_samples, mask = expired_codes)
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@autocast(enabled = False)
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def forward(self, x, used_codes=[]):
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shape, dtype = x.shape, x.dtype
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flatten = rearrange(x, '... d -> (...) d')
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flatten = l2norm(flatten)
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self.init_embed_(flatten)
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embed = self.embed if not self.learnable_codebook else self.embed.detach()
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embed = l2norm(embed)
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dist = flatten @ embed.t()
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for uc in used_codes:
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mask = torch.arange(0, self.codebook_size, device=x.device).unsqueeze(0).repeat(x.shape[0],1) == uc.unsqueeze(1)
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dist[mask] = -torch.inf
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embed_ind = gumbel_sample(dist, dim = -1, temperature = self.sample_codebook_temp)
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embed_onehot = F.one_hot(embed_ind, self.codebook_size).type(dtype)
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embed_ind = embed_ind.view(*shape[:-1])
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quantize = F.embedding(embed_ind, self.embed)
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# Perform the gumbel trick on the end result (during training)
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if self.training:
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quantize = flatten + (quantize - flatten).detach()
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if self.training:
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bins = embed_onehot.sum(0)
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self.all_reduce_fn(bins)
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ema_inplace(self.cluster_size, bins, self.decay)
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zero_mask = (bins == 0)
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bins = bins.masked_fill(zero_mask, 1.)
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embed_sum = flatten.t() @ embed_onehot
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self.all_reduce_fn(embed_sum)
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embed_normalized = (embed_sum / bins.unsqueeze(0)).t()
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embed_normalized = l2norm(embed_normalized)
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embed_normalized = torch.where(zero_mask[..., None], embed,
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embed_normalized)
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ema_inplace(self.embed, embed_normalized, self.decay)
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self.expire_codes_(x)
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return quantize, embed_ind
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# main class
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class VectorQuantize(nn.Module):
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def __init__(
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self,
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dim,
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codebook_size,
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n_embed = None,
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codebook_dim = None,
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decay = 0.8,
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eps = 1e-5,
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kmeans_init = False,
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kmeans_iters = 10,
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use_cosine_sim = False,
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threshold_ema_dead_code = 0,
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channel_last = True,
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accept_image_fmap = False,
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commitment_weight = None,
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commitment = 1., # deprecate in next version, turn off by default
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orthogonal_reg_weight = 0.,
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orthogonal_reg_active_codes_only = False,
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orthogonal_reg_max_codes = None,
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sample_codebook_temp = 0.,
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sync_codebook = False
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):
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super().__init__()
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n_embed = default(n_embed, codebook_size)
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codebook_dim = default(codebook_dim, dim)
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requires_projection = codebook_dim != dim
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self.project_in = ml.Linear(dim, codebook_dim) if requires_projection \
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else nn.Identity()
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self.project_out = ml.Linear(codebook_dim, dim) if requires_projection \
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else nn.Identity()
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self.eps = eps
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self.commitment_weight = default(commitment_weight, commitment)
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has_codebook_orthogonal_loss = orthogonal_reg_weight > 0
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self.orthogonal_reg_weight = orthogonal_reg_weight
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self.orthogonal_reg_active_codes_only = orthogonal_reg_active_codes_only
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self.orthogonal_reg_max_codes = orthogonal_reg_max_codes
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codebook_class = EuclideanCodebook if not use_cosine_sim \
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else CosineSimCodebook
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self._codebook = codebook_class(
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dim = codebook_dim,
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codebook_size = n_embed,
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kmeans_init = kmeans_init,
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kmeans_iters = kmeans_iters,
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decay = decay,
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eps = eps,
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threshold_ema_dead_code = threshold_ema_dead_code,
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use_ddp = sync_codebook,
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learnable_codebook = has_codebook_orthogonal_loss,
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sample_codebook_temp = sample_codebook_temp
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)
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self.codebook_size = codebook_size
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self.accept_image_fmap = accept_image_fmap
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self.channel_last = channel_last
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@property
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def codebook(self):
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return self._codebook.embed
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def forward(self, x, used_codes=None):
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shape, device, codebook_size = x.shape, x.device, self.codebook_size
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need_transpose = not self.channel_last and not self.accept_image_fmap
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if self.accept_image_fmap:
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height, width = x.shape[-2:]
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x = rearrange(x, 'b c h w -> b (h w) c')
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if need_transpose:
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x = rearrange(x, 'b d n -> b n d')
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x = self.project_in(x)
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quantize, embed_ind = self._codebook(x, used_codes)
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loss = torch.tensor([0.], device = device, requires_grad = self.training)
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if self.training:
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if self.commitment_weight > 0:
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commit_loss = F.mse_loss(quantize.detach(), x)
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loss = loss + commit_loss * self.commitment_weight
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if self.orthogonal_reg_weight > 0:
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codebook = self.codebook
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if self.orthogonal_reg_active_codes_only:
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# only calculate orthogonal loss for the activated codes for this batch
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unique_code_ids = torch.unique(embed_ind)
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codebook = codebook[unique_code_ids]
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num_codes = codebook.shape[0]
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if exists(self.orthogonal_reg_max_codes) and num_codes > self.orthogonal_reg_max_codes:
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rand_ids = torch.randperm(num_codes, device = device)[:self.orthogonal_reg_max_codes]
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codebook = codebook[rand_ids]
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orthogonal_reg_loss = orthgonal_loss_fn(codebook)
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loss = loss + orthogonal_reg_loss * self.orthogonal_reg_weight
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quantize = self.project_out(quantize)
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if need_transpose:
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quantize = rearrange(quantize, 'b n d -> b d n')
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if self.accept_image_fmap:
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quantize = rearrange(quantize, 'b (h w) c -> b c h w', h = height, w = width)
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embed_ind = rearrange(embed_ind, 'b (h w) -> b h w', h = height, w = width)
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return quantize, embed_ind, loss
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