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from __future__ import annotations | |
from functools import partial | |
from contextlib import nullcontext | |
from typing import List, Tuple | |
from math import ceil | |
import torch as T | |
import torch.nn as nn | |
import torch.nn.functional as F | |
import torch.distributed as dist | |
from torch import Tensor, int32 | |
from torch.amp import autocast | |
from einops import rearrange, pack, unpack | |
from utils import si_module, exists, default, maybe | |
class GaussianMixtureIOLayer(nn.Module): | |
class Config: | |
latent_dim: int | |
dim: int | |
num_components: int | |
def __init__(self, c: Config): | |
super().__init__() | |
self.latent_dim = c.latent_dim | |
self.num_components = c.num_components | |
self.input_projection = nn.Linear(c.latent_dim, c.dim) | |
self.fc_loc = nn.Linear(c.dim, c.num_components * c.latent_dim) | |
self.fc_scale = nn.Linear(c.dim, c.num_components * c.latent_dim) | |
self.fc_weight = nn.Linear(c.dim, c.num_components) | |
def _square_plus(self, x): | |
return (x + T.sqrt(T.square(x) + 4)) / 2 | |
def input(self, sampled_latents: T.Tensor) -> T.Tensor: | |
"""Pre-sampled latents T.Tensor (B, L, Z) -> float tensor (B, L, D)""" | |
hidden = self.input_projection(sampled_latents) | |
return hidden | |
def output(self, h: T.Tensor) -> Tuple[T.Tensor, T.Tensor, T.Tensor]: | |
"""float tensor (B, L, D) -> Tuple of locs, scales, and weights""" | |
batch_size, seq_len, _ = h.shape | |
locs = self.fc_loc(h).view(batch_size, seq_len, self.num_components, self.latent_dim) | |
scales = T.clamp(self._square_plus(self.fc_scale(h)), min=1e-6).view(batch_size, seq_len, self.num_components, self.latent_dim) | |
weights = self.fc_weight(h).view(batch_size, seq_len, self.num_components) | |
return (locs, scales, weights) | |
def loss(self, data, dataHat): | |
locs, scales, weights = dataHat | |
log_probs = -0.5 * T.sum( | |
(data.unsqueeze(-2) - locs).pow(2) / scales.pow(2) + | |
2 * T.log(scales) + | |
T.log(T.tensor(2 * T.pi)), | |
dim=-1 | |
) | |
log_weights = F.log_softmax(weights, dim=-1) | |
return -T.logsumexp(log_weights + log_probs, dim=-1) | |
def temp_sample(self, orig_pdist, temp): | |
locs, scales, weights = orig_pdist | |
if temp is None: | |
component_samples = locs + scales * T.randn_like(scales) | |
mixture_samples = F.gumbel_softmax(weights, hard=True) | |
sampled = (component_samples * mixture_samples.unsqueeze(-1)).sum(dim=-2) | |
elif isinstance(temp, tuple): | |
assert len(temp) == 2 | |
categorical_temp, gaussian_temp = temp | |
component_samples = locs + scales * gaussian_temp * T.randn_like(scales) | |
mixture_samples = F.gumbel_softmax(weights / categorical_temp, hard=True) | |
sampled = (component_samples * mixture_samples.unsqueeze(-1)).sum(dim=-2) | |
else: | |
component_samples = locs + scales * temp * T.randn_like(scales) | |
mixture_samples = F.gumbel_softmax(weights / temp, hard=True) | |
sampled = (component_samples * mixture_samples.unsqueeze(-1)).sum(dim=-2) | |
return sampled | |
class GPTOutput(nn.Module): | |
def __init__(self, dim, vocab_size): | |
super().__init__() | |
self.output = nn.Linear(dim, vocab_size, bias=False) | |
def forward(self, x): | |
return self.output(x) | |
# helper functions | |
def pack_one(t, pattern): | |
return pack([t], pattern) | |
def unpack_one(t, ps, pattern): | |
return unpack(t, ps, pattern)[0] | |
def first(l): | |
return l[0] | |
def round_up_multiple(num, mult): | |
return ceil(num / mult) * mult | |
def get_code_utilization(codes, codebook_size, get_global=False): | |
if get_global and dist.is_initialized(): | |
world_size = dist.get_world_size() | |
else: | |
world_size = 1 | |
if world_size > 1: | |
gathered_tokens = [T.zeros_like(codes) for _ in range(world_size)] | |
dist.all_gather(gathered_tokens, codes) | |
gathered_tokens = T.cat(gathered_tokens, dim=0) | |
else: | |
gathered_tokens = codes | |
unique_tokens = len(T.unique(gathered_tokens)) | |
code_utilization = unique_tokens / min(gathered_tokens.numel(), codebook_size) | |
return code_utilization | |
# tensor helpers | |
def round_ste(z: Tensor) -> Tensor: | |
"""Round with straight through gradients.""" | |
zhat = z.round() | |
return z + (zhat - z).detach() | |
# main class | |
# lucidrains fsq | |
class FSQ(nn.Module): | |
def needs_float32_params(self): | |
return True | |
class Config: | |
levels: List[int] | |
dim: int | None = None | |
num_codebooks: int = 1 | |
keep_num_codebooks_dim: bool | None = None | |
scale: float | None = None | |
allowed_dtypes: Tuple[str, ...] = ('float32', 'float64') | |
channel_first: bool = False | |
projection_has_bias: bool = True | |
return_indices: bool = True | |
force_quantization_f32: bool = True | |
use_rms: bool = False | |
def __init__(self, c: Config): | |
super().__init__() | |
_levels = T.tensor(c.levels, dtype=int32) | |
self.register_buffer("_levels", _levels, persistent = False) | |
_basis = T.cumprod(T.tensor([1] + c.levels[:-1]), dim=0, dtype=int32) | |
self.register_buffer("_basis", _basis, persistent = False) | |
self.scale = c.scale | |
codebook_dim = len(c.levels) | |
self.codebook_dim = codebook_dim | |
effective_codebook_dim = codebook_dim * c.num_codebooks | |
self.num_codebooks = c.num_codebooks | |
self.allowed_dtypes = [] | |
for dtype_str in c.allowed_dtypes: | |
if hasattr(T, dtype_str): | |
self.allowed_dtypes.append(getattr(T, dtype_str)) | |
else: | |
raise ValueError(f"Invalid dtype string: {dtype_str}") | |
self.effective_codebook_dim = effective_codebook_dim | |
keep_num_codebooks_dim = default(c.keep_num_codebooks_dim, c.num_codebooks > 1) | |
assert not (c.num_codebooks > 1 and not keep_num_codebooks_dim) | |
self.keep_num_codebooks_dim = keep_num_codebooks_dim | |
self.dim = default(c.dim, len(_levels) * c.num_codebooks) | |
self.channel_first = c.channel_first | |
has_projections = self.dim != effective_codebook_dim | |
self.project_in = nn.Linear(self.dim, effective_codebook_dim, bias = c.projection_has_bias) if has_projections else nn.Identity() | |
self.project_out = nn.Linear(effective_codebook_dim, self.dim, bias = c.projection_has_bias) if has_projections else nn.Identity() | |
self.has_projections = has_projections | |
self.return_indices = c.return_indices | |
if c.return_indices: | |
self.codebook_size = self._levels.prod().item() | |
implicit_codebook = self._indices_to_codes(T.arange(self.codebook_size)) | |
self.register_buffer("implicit_codebook", implicit_codebook, persistent = False) | |
self.allowed_dtypes = c.allowed_dtypes | |
self.force_quantization_f32 = c.force_quantization_f32 | |
self.latent_loss = None | |
def latent_metric(self, codes, get_global=False): | |
return {'code_util_estimate': get_code_utilization(codes, self.codebook_size, get_global)} | |
def repr_from_latent(self, latent): | |
return self.indices_to_codes(latent) | |
def bound(self, z, eps: float = 1e-3): | |
""" Bound `z`, an array of shape (..., d). """ | |
half_l = (self._levels - 1) * (1 + eps) / 2 | |
offset = T.where(self._levels % 2 == 0, 0.5, 0.0) | |
shift = (offset / half_l).atanh() | |
return (z + shift).tanh() * half_l - offset | |
def quantize(self, z): | |
""" Quantizes z, returns quantized zhat, same shape as z. """ | |
quantized = round_ste(self.bound(z)) | |
half_width = self._levels // 2 # Renormalize to [-1, 1]. | |
return quantized / half_width | |
def _scale_and_shift(self, zhat_normalized): | |
half_width = self._levels // 2 | |
return (zhat_normalized * half_width) + half_width | |
def _scale_and_shift_inverse(self, zhat): | |
half_width = self._levels // 2 | |
return (zhat - half_width) / half_width | |
def _indices_to_codes(self, indices): | |
level_indices = self.indices_to_level_indices(indices) | |
codes = self._scale_and_shift_inverse(level_indices) | |
return codes | |
def codes_to_indices(self, zhat): | |
""" Converts a `code` to an index in the codebook. """ | |
assert zhat.shape[-1] == self.codebook_dim | |
zhat = self._scale_and_shift(zhat) | |
return (zhat * self._basis).sum(dim=-1).to(int32) | |
def indices_to_level_indices(self, indices): | |
""" Converts indices to indices at each level, perhaps needed for a transformer with factorized embeddings """ | |
indices = rearrange(indices, '... -> ... 1') | |
codes_non_centered = (indices // self._basis) % self._levels | |
return codes_non_centered | |
def indices_to_codes(self, indices): | |
""" Inverse of `codes_to_indices`. """ | |
assert exists(indices) | |
is_img_or_video = indices.ndim >= (3 + int(self.keep_num_codebooks_dim)) | |
codes = self._indices_to_codes(indices) | |
if self.keep_num_codebooks_dim: | |
codes = rearrange(codes, '... c d -> ... (c d)') | |
codes = self.project_out(codes) | |
if is_img_or_video or self.channel_first: | |
codes = rearrange(codes, 'b ... d -> b d ...') | |
return codes | |
# @autocast(device_type='cuda', enabled = False) | |
def forward(self, z, return_codes=False): | |
""" | |
einstein notation | |
b - batch | |
n - sequence (or flattened spatial dimensions) | |
d - feature dimension | |
c - number of codebook dim | |
""" | |
is_img_or_video = z.ndim >= 4 | |
need_move_channel_last = is_img_or_video or self.channel_first | |
# standardize image or video into (batch, seq, dimension) | |
if need_move_channel_last: | |
z = rearrange(z, 'b d ... -> b ... d') | |
z, ps = pack_one(z, 'b * d') | |
assert z.shape[-1] == self.dim, f'expected dimension of {self.dim} but found dimension of {z.shape[-1]}' | |
z = self.project_in(z) | |
z = rearrange(z, 'b n (c d) -> b n c d', c = self.num_codebooks) | |
# whether to force quantization step to be full precision or not | |
force_f32 = self.force_quantization_f32 | |
quantization_context = partial(autocast, device_type='cuda', enabled = False) if force_f32 else nullcontext | |
with quantization_context(): | |
orig_dtype = z.dtype | |
if force_f32 and orig_dtype not in self.allowed_dtypes: | |
z = z.float() | |
codes = self.quantize(z) | |
# returning indices could be optional | |
indices = None | |
if self.return_indices: | |
indices = self.codes_to_indices(codes) | |
codes = rearrange(codes, 'b n c d -> b n (c d)') | |
codes = codes.type(orig_dtype) | |
# project out | |
if return_codes: | |
return codes, indices | |
out = self.project_out(codes) | |
# reconstitute image or video dimensions | |
if need_move_channel_last: | |
out = unpack_one(out, ps, 'b * d') | |
out = rearrange(out, 'b ... d -> b d ...') | |
indices = maybe(unpack_one)(indices, ps, 'b * c') | |
if not self.keep_num_codebooks_dim and self.return_indices: | |
indices = maybe(rearrange)(indices, '... 1 -> ...') | |
# return quantized output and indices | |
return out, indices |