import torch from torch import nn from torch.nn import functional as F from einops import rearrange from vector_quantize_pytorch import ResidualVQ, FSQ from dac.nn.quantize import ResidualVectorQuantize as DACResidualVQ class Bottleneck(nn.Module): def __init__(self, is_discrete: bool = False): super().__init__() self.is_discrete = is_discrete def encode(self, x, return_info=False, **kwargs): raise NotImplementedError def decode(self, x): raise NotImplementedError class DiscreteBottleneck(Bottleneck): def __init__(self, num_quantizers, codebook_size, tokens_id): super().__init__(is_discrete=True) self.num_quantizers = num_quantizers self.codebook_size = codebook_size self.tokens_id = tokens_id def decode_tokens(self, codes, **kwargs): raise NotImplementedError class TanhBottleneck(Bottleneck): def __init__(self): super().__init__(is_discrete=False) self.tanh = nn.Tanh() def encode(self, x, return_info=False): info = {} x = torch.tanh(x) if return_info: return x, info else: return x def decode(self, x): return x def vae_sample(mean, scale): stdev = nn.functional.softplus(scale) + 1e-4 var = stdev * stdev logvar = torch.log(var) latents = torch.randn_like(mean) * stdev + mean kl = (mean * mean + var - logvar - 1).sum(1).mean() return latents, kl class VAEBottleneck(Bottleneck): def __init__(self): super().__init__(is_discrete=False) def encode(self, x, return_info=False, **kwargs): info = {} mean, scale = x.chunk(2, dim=1) x, kl = vae_sample(mean, scale) info["kl"] = kl if return_info: return x, info else: return x def decode(self, x): return x def compute_mean_kernel(x, y): kernel_input = (x[:, None] - y[None]).pow(2).mean(2) / x.shape[-1] return torch.exp(-kernel_input).mean() def compute_mmd(latents): latents_reshaped = latents.permute(0, 2, 1).reshape(-1, latents.shape[1]) noise = torch.randn_like(latents_reshaped) latents_kernel = compute_mean_kernel(latents_reshaped, latents_reshaped) noise_kernel = compute_mean_kernel(noise, noise) latents_noise_kernel = compute_mean_kernel(latents_reshaped, noise) mmd = latents_kernel + noise_kernel - 2 * latents_noise_kernel return mmd.mean() class WassersteinBottleneck(Bottleneck): def __init__(self, noise_augment_dim: int = 0): super().__init__(is_discrete=False) self.noise_augment_dim = noise_augment_dim def encode(self, x, return_info=False): info = {} if self.training and return_info: mmd = compute_mmd(x) info["mmd"] = mmd if return_info: return x, info return x def decode(self, x): if self.noise_augment_dim > 0: noise = torch.randn(x.shape[0], self.noise_augment_dim, x.shape[-1]).type_as(x) x = torch.cat([x, noise], dim=1) return x class L2Bottleneck(Bottleneck): def __init__(self): super().__init__(is_discrete=False) def encode(self, x, return_info=False): info = {} x = F.normalize(x, dim=1) if return_info: return x, info else: return x def decode(self, x): return F.normalize(x, dim=1) class RVQBottleneck(DiscreteBottleneck): def __init__(self, **quantizer_kwargs): super().__init__(num_quantizers = quantizer_kwargs["num_quantizers"], codebook_size = quantizer_kwargs["codebook_size"], tokens_id = "quantizer_indices") self.quantizer = ResidualVQ(**quantizer_kwargs) self.num_quantizers = quantizer_kwargs["num_quantizers"] def encode(self, x, return_info=False, **kwargs): info = {} x = rearrange(x, "b c n -> b n c") x, indices, loss = self.quantizer(x) x = rearrange(x, "b n c -> b c n") info["quantizer_indices"] = indices info["quantizer_loss"] = loss.mean() if return_info: return x, info else: return x def decode(self, x): return x def decode_tokens(self, codes, **kwargs): latents = self.quantizer.get_outputs_from_indices(codes) return self.decode(latents, **kwargs) class RVQVAEBottleneck(DiscreteBottleneck): def __init__(self, **quantizer_kwargs): super().__init__(num_quantizers = quantizer_kwargs["num_quantizers"], codebook_size = quantizer_kwargs["codebook_size"], tokens_id = "quantizer_indices") self.quantizer = ResidualVQ(**quantizer_kwargs) self.num_quantizers = quantizer_kwargs["num_quantizers"] def encode(self, x, return_info=False): info = {} x, kl = vae_sample(*x.chunk(2, dim=1)) info["kl"] = kl x = rearrange(x, "b c n -> b n c") x, indices, loss = self.quantizer(x) x = rearrange(x, "b n c -> b c n") info["quantizer_indices"] = indices info["quantizer_loss"] = loss.mean() if return_info: return x, info else: return x def decode(self, x): return x def decode_tokens(self, codes, **kwargs): latents = self.quantizer.get_outputs_from_indices(codes) return self.decode(latents, **kwargs) class DACRVQBottleneck(DiscreteBottleneck): def __init__(self, quantize_on_decode=False, **quantizer_kwargs): super().__init__(num_quantizers = quantizer_kwargs["n_codebooks"], codebook_size = quantizer_kwargs["codebook_size"], tokens_id = "codes") self.quantizer = DACResidualVQ(**quantizer_kwargs) self.num_quantizers = quantizer_kwargs["n_codebooks"] self.quantize_on_decode = quantize_on_decode def encode(self, x, return_info=False, **kwargs): info = {} info["pre_quantizer"] = x if self.quantize_on_decode: return x, info if return_info else x z, codes, latents, commitment_loss, codebook_loss = self.quantizer(x, **kwargs) output = { "z": z, "codes": codes, "latents": latents, "vq/commitment_loss": commitment_loss, "vq/codebook_loss": codebook_loss, } output["vq/commitment_loss"] /= self.num_quantizers output["vq/codebook_loss"] /= self.num_quantizers info.update(output) if return_info: return output["z"], info return output["z"] def decode(self, x): if self.quantize_on_decode: x = self.quantizer(x)[0] return x def decode_tokens(self, codes, **kwargs): latents, _, _ = self.quantizer.from_codes(codes) return self.decode(latents, **kwargs) class DACRVQVAEBottleneck(DiscreteBottleneck): def __init__(self, quantize_on_decode=False, **quantizer_kwargs): super().__init__(num_quantizers = quantizer_kwargs["n_codebooks"], codebook_size = quantizer_kwargs["codebook_size"], tokens_id = "codes") self.quantizer = DACResidualVQ(**quantizer_kwargs) self.num_quantizers = quantizer_kwargs["n_codebooks"] self.quantize_on_decode = quantize_on_decode def encode(self, x, return_info=False, n_quantizers: int = None): info = {} mean, scale = x.chunk(2, dim=1) x, kl = vae_sample(mean, scale) info["pre_quantizer"] = x info["kl"] = kl if self.quantize_on_decode: return x, info if return_info else x z, codes, latents, commitment_loss, codebook_loss = self.quantizer(x, n_quantizers=n_quantizers) output = { "z": z, "codes": codes, "latents": latents, "vq/commitment_loss": commitment_loss, "vq/codebook_loss": codebook_loss, } output["vq/commitment_loss"] /= self.num_quantizers output["vq/codebook_loss"] /= self.num_quantizers info.update(output) if return_info: return output["z"], info return output["z"] def decode(self, x): if self.quantize_on_decode: x = self.quantizer(x)[0] return x def decode_tokens(self, codes, **kwargs): latents, _, _ = self.quantizer.from_codes(codes) return self.decode(latents, **kwargs) class FSQBottleneck(DiscreteBottleneck): def __init__(self, dim, levels): super().__init__(num_quantizers = 1, codebook_size = levels ** dim, tokens_id = "quantizer_indices") self.quantizer = FSQ(levels=[levels] * dim) def encode(self, x, return_info=False): info = {} x = rearrange(x, "b c n -> b n c") x, indices = self.quantizer(x) x = rearrange(x, "b n c -> b c n") info["quantizer_indices"] = indices if return_info: return x, info else: return x def decode(self, x): return x def decode_tokens(self, tokens, **kwargs): latents = self.quantizer.indices_to_codes(tokens) return self.decode(latents, **kwargs)