LLCaps / data /networks /ReverseDiffusion.py
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import torch
import os
from torch import nn, einsum
import torch.nn.functional as F
from functools import partial
from einops.layers.torch import Rearrange
from einops import rearrange, reduce
import math
from random import random
from tqdm.auto import tqdm
from collections import namedtuple
def exists(x):
return x is not None
def default(val, d):
if exists(val):
return val
return d() if callable(d) else d
class Residual(nn.Module):
def __init__(self, fn):
super().__init__()
self.fn = fn
def forward(self, x, *args, **kwargs):
return self.fn(x, *args, **kwargs) + x
def Upsample(dim, dim_out = None):
return nn.Sequential(
nn.Upsample(scale_factor = 2, mode = 'nearest'),
nn.Conv2d(dim, default(dim_out, dim), 3, padding = 1)
)
def Downsample(dim, dim_out = None):
return nn.Sequential(
Rearrange('b c (h p1) (w p2) -> b (c p1 p2) h w', p1 = 2, p2 = 2),
nn.Conv2d(dim * 4, default(dim_out, dim), 1)
)
class RandomOrLearnedSinusoidalPosEmb(nn.Module):
""" following @crowsonkb 's lead with random (learned optional) sinusoidal pos emb """
""" https://github.com/crowsonkb/v-diffusion-jax/blob/master/diffusion/models/danbooru_128.py#L8 """
def __init__(self, dim, is_random = False):
super().__init__()
assert (dim % 2) == 0
half_dim = dim // 2
self.weights = nn.Parameter(torch.randn(half_dim), requires_grad = not is_random)
def forward(self, x):
x = rearrange(x, 'b -> b 1')
freqs = x * rearrange(self.weights, 'd -> 1 d') * 2 * math.pi
fouriered = torch.cat((freqs.sin(), freqs.cos()), dim = -1)
fouriered = torch.cat((x, fouriered), dim = -1)
return fouriered
class WeightStandardizedConv2d(nn.Conv2d):
"""
https://arxiv.org/abs/1903.10520
weight standardization purportedly works synergistically with group normalization
"""
def forward(self, x):
eps = 1e-5 if x.dtype == torch.float32 else 1e-3
weight = self.weight
mean = reduce(weight, 'o ... -> o 1 1 1', 'mean')
var = reduce(weight, 'o ... -> o 1 1 1', partial(torch.var, unbiased = False))
normalized_weight = (weight - mean) * (var + eps).rsqrt()
return F.conv2d(x, normalized_weight, self.bias, self.stride, self.padding, self.dilation, self.groups)
class LayerNorm(nn.Module):
def __init__(self, dim):
super().__init__()
self.g = nn.Parameter(torch.ones(1, dim, 1, 1))
def forward(self, x):
eps = 1e-5 if x.dtype == torch.float32 else 1e-3
var = torch.var(x, dim = 1, unbiased = False, keepdim = True)
mean = torch.mean(x, dim = 1, keepdim = True)
return (x - mean) * (var + eps).rsqrt() * self.g
class PreNorm(nn.Module):
def __init__(self, dim, fn):
super().__init__()
self.fn = fn
self.norm = LayerNorm(dim)
def forward(self, x):
x = self.norm(x)
return self.fn(x)
class SinusoidalPosEmb(nn.Module):
def __init__(self, dim):
super().__init__()
self.dim = dim
def forward(self, x):
device = x.device
half_dim = self.dim // 2
emb = math.log(10000) / (half_dim - 1)
emb = torch.exp(torch.arange(half_dim, device=device) * -emb)
emb = x[:, None] * emb[None, :]
emb = torch.cat((emb.sin(), emb.cos()), dim=-1)
return emb
class Block(nn.Module):
def __init__(self, dim, dim_out, groups = 6):
super().__init__()
self.proj = WeightStandardizedConv2d(dim, dim_out, 3, padding = 1)
self.norm = nn.GroupNorm(groups, dim_out)
self.act = nn.SiLU()
def forward(self, x, scale_shift = None):
x = self.proj(x)
x = self.norm(x)
if exists(scale_shift):
scale, shift = scale_shift
x = x * (scale + 1) + shift
x = self.act(x)
return x
class ResnetBlock(nn.Module):
def __init__(self, dim, dim_out, *, time_emb_dim = None, groups = 6):
super().__init__()
self.mlp = nn.Sequential(
nn.SiLU(),
nn.Linear(time_emb_dim, dim_out * 2)
) if exists(time_emb_dim) else None
self.block1 = Block(dim, dim_out, groups = groups)
self.block2 = Block(dim_out, dim_out, groups = groups)
self.res_conv = nn.Conv2d(dim, dim_out, 1) if dim != dim_out else nn.Identity()
def forward(self, x, time_emb = None):
scale_shift = None
if exists(self.mlp) and exists(time_emb):
time_emb = self.mlp(time_emb)
time_emb = rearrange(time_emb, 'b c -> b c 1 1')
scale_shift = time_emb.chunk(2, dim = 1)
h = self.block1(x, scale_shift = scale_shift)
h = self.block2(h)
return h + self.res_conv(x)
class LinearAttention(nn.Module):
def __init__(self, dim, heads = 4, dim_head = 32):
super().__init__()
self.scale = dim_head ** -0.5
self.heads = heads
hidden_dim = dim_head * heads
self.to_qkv = nn.Conv2d(dim, hidden_dim * 3, 1, bias = False)
self.to_out = nn.Sequential(
nn.Conv2d(hidden_dim, dim, 1),
LayerNorm(dim)
)
def forward(self, x):
b, c, h, w = x.shape
qkv = self.to_qkv(x).chunk(3, dim = 1)
q, k, v = map(lambda t: rearrange(t, 'b (h c) x y -> b h c (x y)', h = self.heads), qkv)
q = q.softmax(dim = -2)
k = k.softmax(dim = -1)
q = q * self.scale
v = v / (h * w)
context = torch.einsum('b h d n, b h e n -> b h d e', k, v)
out = torch.einsum('b h d e, b h d n -> b h e n', context, q)
out = rearrange(out, 'b h c (x y) -> b (h c) x y', h = self.heads, x = h, y = w)
return self.to_out(out)
class Attention(nn.Module):
def __init__(self, dim, heads = 4, dim_head = 32):
super().__init__()
self.scale = dim_head ** -0.5
self.heads = heads
hidden_dim = dim_head * heads
self.to_qkv = nn.Conv2d(dim, hidden_dim * 3, 1, bias = False)
self.to_out = nn.Conv2d(hidden_dim, dim, 1)
def forward(self, x):
b, c, h, w = x.shape
qkv = self.to_qkv(x).chunk(3, dim = 1)
q, k, v = map(lambda t: rearrange(t, 'b (h c) x y -> b h c (x y)', h = self.heads), qkv)
q = q * self.scale
sim = einsum('b h d i, b h d j -> b h i j', q, k)
attn = sim.softmax(dim = -1)
out = einsum('b h i j, b h d j -> b h i d', attn, v)
out = rearrange(out, 'b h (x y) d -> b (h d) x y', x = h, y = w)
return self.to_out(out)
class Unet(nn.Module):
def __init__(
self,
dim ,
init_dim = None,
out_dim = None,
dim_mults=(1, 2, 4, 8),
channels = 3,
self_condition = False,
resnet_block_groups = 8,
learned_variance = False,
learned_sinusoidal_cond = False,
random_fourier_features = False,
learned_sinusoidal_dim = 16
):
super().__init__()
# determine dimensions
self.channels = channels
self.self_condition = self_condition
input_channels = channels * (2 if self_condition else 1)
init_dim = default(init_dim, dim)
self.init_conv = nn.Conv2d(input_channels, init_dim, 7, padding = 3)
dims = [init_dim, *map(lambda m: dim * m, dim_mults)]
in_out = list(zip(dims[:-1], dims[1:]))
block_klass = partial(ResnetBlock, groups = resnet_block_groups)
# time embeddings
time_dim = dim * 4
self.random_or_learned_sinusoidal_cond = learned_sinusoidal_cond or random_fourier_features
if self.random_or_learned_sinusoidal_cond:
sinu_pos_emb = RandomOrLearnedSinusoidalPosEmb(learned_sinusoidal_dim, random_fourier_features)
fourier_dim = learned_sinusoidal_dim + 1
else:
sinu_pos_emb = SinusoidalPosEmb(dim)
fourier_dim = dim
self.time_mlp = nn.Sequential(
sinu_pos_emb,
nn.Linear(fourier_dim, time_dim),
nn.GELU(),
nn.Linear(time_dim, time_dim)
)
# layers
self.downs = nn.ModuleList([])
self.ups = nn.ModuleList([])
num_resolutions = len(in_out)
for ind, (dim_in, dim_out) in enumerate(in_out):
is_last = ind >= (num_resolutions - 1)
self.downs.append(nn.ModuleList([
block_klass(dim_in, dim_in, time_emb_dim = time_dim),
block_klass(dim_in, dim_in, time_emb_dim = time_dim),
Residual(PreNorm(dim_in, LinearAttention(dim_in))),
Downsample(dim_in, dim_out) if not is_last else nn.Conv2d(dim_in, dim_out, 3, padding = 1)
]))
mid_dim = dims[-1]
self.mid_block1 = block_klass(mid_dim, mid_dim, time_emb_dim = time_dim)
self.mid_attn = Residual(PreNorm(mid_dim, Attention(mid_dim)))
self.mid_block2 = block_klass(mid_dim, mid_dim, time_emb_dim = time_dim)
for ind, (dim_in, dim_out) in enumerate(reversed(in_out)):
is_last = ind == (len(in_out) - 1)
self.ups.append(nn.ModuleList([
block_klass(dim_out + dim_in, dim_out, time_emb_dim = time_dim),
block_klass(dim_out + dim_in, dim_out, time_emb_dim = time_dim),
Residual(PreNorm(dim_out, LinearAttention(dim_out))),
Upsample(dim_out, dim_in) if not is_last else nn.Conv2d(dim_out, dim_in, 3, padding = 1)
]))
default_out_dim = channels * (1 if not learned_variance else 2)
self.out_dim = default(out_dim, default_out_dim)
self.final_res_block = block_klass(dim * 2, dim, time_emb_dim = time_dim)
self.final_conv = nn.Conv2d(dim, self.out_dim, 1)
def forward(self, x, time, x_self_cond = None):
if self.self_condition:
x_self_cond = default(x_self_cond, lambda: torch.zeros_like(x))
x = torch.cat((x_self_cond, x), dim = 1)
x = self.init_conv(x)
r = x.clone()
t = self.time_mlp(time)
h = []
for block1, block2, attn, downsample in self.downs:
x = block1(x, t)
h.append(x)
x = block2(x, t)
x = attn(x)
h.append(x)
x = downsample(x)
x = self.mid_block1(x, t)
x = self.mid_attn(x)
x = self.mid_block2(x, t)
for block1, block2, attn, upsample in self.ups:
x = torch.cat((x, h.pop()), dim = 1)
x = block1(x, t)
x = torch.cat((x, h.pop()), dim = 1)
x = block2(x, t)
x = attn(x)
x = upsample(x)
x = torch.cat((x, r), dim = 1)
x = self.final_res_block(x, t)
return self.final_conv(x)
###############################################
## Gaussian Diffusion
ModelPrediction = namedtuple('ModelPrediction', ['pred_noise', 'pred_x_start'])
def extract(a, t, x_shape):
b, *_ = t.shape
out = a.gather(-1, t)
return out.reshape(b, *((1,) * (len(x_shape) - 1)))
def linear_beta_schedule(timesteps):
"""
linear schedule, proposed in original ddpm paper
"""
scale = 1000 / timesteps
beta_start = scale * 0.0001
beta_end = scale * 0.02
return torch.linspace(beta_start, beta_end, timesteps, dtype = torch.float64)
def cosine_beta_schedule(timesteps, s = 0.008):
"""
cosine schedule
as proposed in https://openreview.net/forum?id=-NEXDKk8gZ
"""
steps = timesteps + 1
t = torch.linspace(0, timesteps, steps, dtype = torch.float64) / timesteps
alphas_cumprod = torch.cos((t + s) / (1 + s) * math.pi * 0.5) ** 2
alphas_cumprod = alphas_cumprod / alphas_cumprod[0]
betas = 1 - (alphas_cumprod[1:] / alphas_cumprod[:-1])
return torch.clip(betas, 0, 0.999)
def sigmoid_beta_schedule(timesteps, start = -3, end = 3, tau = 1, clamp_min = 1e-5):
"""
sigmoid schedule
proposed in https://arxiv.org/abs/2212.11972 - Figure 8
better for images > 64x64, when used during training
"""
steps = timesteps + 1
t = torch.linspace(0, timesteps, steps, dtype = torch.float64) / timesteps
v_start = torch.tensor(start / tau).sigmoid()
v_end = torch.tensor(end / tau).sigmoid()
alphas_cumprod = (-((t * (end - start) + start) / tau).sigmoid() + v_end) / (v_end - v_start)
alphas_cumprod = alphas_cumprod / alphas_cumprod[0]
betas = 1 - (alphas_cumprod[1:] / alphas_cumprod[:-1])
return torch.clip(betas, 0, 0.999)
def identity(t, *args, **kwargs):
return t
def normalize_to_neg_one_to_one(img):
return img * 2 - 1
def unnormalize_to_zero_to_one(t):
return (t + 1) * 0.5
class GaussianDiffusion(nn.Module):
def __init__(
self,
model,
*,
image_size,
timesteps = 1000,
sampling_timesteps = None,
loss_type = 'l1',
objective = 'pred_noise',
beta_schedule = 'sigmoid',
schedule_fn_kwargs = dict(),
ddim_sampling_eta = 0.,
auto_normalize = True
):
super().__init__()
assert not (type(self) == GaussianDiffusion and model.channels != model.out_dim)
assert not model.random_or_learned_sinusoidal_cond
self.model = model
self.channels = self.model.channels
self.self_condition = self.model.self_condition
self.image_size = image_size
self.objective = objective
assert objective in {'pred_noise', 'pred_x0', 'pred_v'}, 'objective must be either pred_noise (predict noise) or pred_x0 (predict image start) or pred_v (predict v [v-parameterization as defined in appendix D of progressive distillation paper, used in imagen-video successfully])'
if beta_schedule == 'linear':
beta_schedule_fn = linear_beta_schedule
elif beta_schedule == 'cosine':
beta_schedule_fn = cosine_beta_schedule
elif beta_schedule == 'sigmoid':
beta_schedule_fn = sigmoid_beta_schedule
else:
raise ValueError(f'unknown beta schedule {beta_schedule}')
betas = beta_schedule_fn(timesteps, **schedule_fn_kwargs)
alphas = 1. - betas
alphas_cumprod = torch.cumprod(alphas, dim=0)
alphas_cumprod_prev = F.pad(alphas_cumprod[:-1], (1, 0), value = 1.)
timesteps, = betas.shape
self.num_timesteps = int(timesteps)
self.loss_type = loss_type
# sampling related parameters
self.sampling_timesteps = default(sampling_timesteps, timesteps) # default num sampling timesteps to number of timesteps at training
assert self.sampling_timesteps <= timesteps
self.is_ddim_sampling = self.sampling_timesteps < timesteps
self.ddim_sampling_eta = ddim_sampling_eta
# helper function to register buffer from float64 to float32
register_buffer = lambda name, val: self.register_buffer(name, val.to(torch.float32))
register_buffer('betas', betas)
register_buffer('alphas_cumprod', alphas_cumprod)
register_buffer('alphas_cumprod_prev', alphas_cumprod_prev)
# calculations for diffusion q(x_t | x_{t-1}) and others
register_buffer('sqrt_alphas_cumprod', torch.sqrt(alphas_cumprod))
register_buffer('sqrt_one_minus_alphas_cumprod', torch.sqrt(1. - alphas_cumprod))
register_buffer('log_one_minus_alphas_cumprod', torch.log(1. - alphas_cumprod))
register_buffer('sqrt_recip_alphas_cumprod', torch.sqrt(1. / alphas_cumprod))
register_buffer('sqrt_recipm1_alphas_cumprod', torch.sqrt(1. / alphas_cumprod - 1))
# calculations for posterior q(x_{t-1} | x_t, x_0)
posterior_variance = betas * (1. - alphas_cumprod_prev) / (1. - alphas_cumprod)
# above: equal to 1. / (1. / (1. - alpha_cumprod_tm1) + alpha_t / beta_t)
register_buffer('posterior_variance', posterior_variance)
# below: log calculation clipped because the posterior variance is 0 at the beginning of the diffusion chain
register_buffer('posterior_log_variance_clipped', torch.log(posterior_variance.clamp(min =1e-20)))
register_buffer('posterior_mean_coef1', betas * torch.sqrt(alphas_cumprod_prev) / (1. - alphas_cumprod))
register_buffer('posterior_mean_coef2', (1. - alphas_cumprod_prev) * torch.sqrt(alphas) / (1. - alphas_cumprod))
# auto-normalization of data [0, 1] -> [-1, 1] - can turn off by setting it to be False
self.normalize = normalize_to_neg_one_to_one if auto_normalize else identity
self.unnormalize = unnormalize_to_zero_to_one if auto_normalize else identity
def predict_start_from_noise(self, x_t, t, noise):
return (
extract(self.sqrt_recip_alphas_cumprod, t, x_t.shape) * x_t -
extract(self.sqrt_recipm1_alphas_cumprod, t, x_t.shape) * noise
)
def predict_noise_from_start(self, x_t, t, x0):
return (
(extract(self.sqrt_recip_alphas_cumprod, t, x_t.shape) * x_t - x0) / \
extract(self.sqrt_recipm1_alphas_cumprod, t, x_t.shape)
)
def predict_v(self, x_start, t, noise):
return (
extract(self.sqrt_alphas_cumprod, t, x_start.shape) * noise -
extract(self.sqrt_one_minus_alphas_cumprod, t, x_start.shape) * x_start
)
def predict_start_from_v(self, x_t, t, v):
return (
extract(self.sqrt_alphas_cumprod, t, x_t.shape) * x_t -
extract(self.sqrt_one_minus_alphas_cumprod, t, x_t.shape) * v
)
def q_posterior(self, x_start, x_t, t):
posterior_mean = (
extract(self.posterior_mean_coef1, t, x_t.shape) * x_start +
extract(self.posterior_mean_coef2, t, x_t.shape) * x_t
)
posterior_variance = extract(self.posterior_variance, t, x_t.shape)
posterior_log_variance_clipped = extract(self.posterior_log_variance_clipped, t, x_t.shape)
return posterior_mean, posterior_variance, posterior_log_variance_clipped
def model_predictions(self, x, t, x_self_cond = None, clip_x_start = False):
model_output = self.model(x, t, x_self_cond)
maybe_clip = partial(torch.clamp, min = -1., max = 1.) if clip_x_start else identity
if self.objective == 'pred_noise':
pred_noise = model_output
x_start = self.predict_start_from_noise(x, t, pred_noise)
x_start = maybe_clip(x_start)
elif self.objective == 'pred_x0':
x_start = model_output
x_start = maybe_clip(x_start)
pred_noise = self.predict_noise_from_start(x, t, x_start)
elif self.objective == 'pred_v':
v = model_output
x_start = self.predict_start_from_v(x, t, v)
x_start = maybe_clip(x_start)
pred_noise = self.predict_noise_from_start(x, t, x_start)
return ModelPrediction(pred_noise, x_start)
def p_mean_variance(self, x, t, x_self_cond = None, clip_denoised = True):
preds = self.model_predictions(x, t, x_self_cond)
x_start = preds.pred_x_start
if clip_denoised:
x_start.clamp_(-1., 1.)
model_mean, posterior_variance, posterior_log_variance = self.q_posterior(x_start = x_start, x_t = x, t = t)
return model_mean, posterior_variance, posterior_log_variance, x_start
@torch.no_grad()
def p_sample(self, x, t: int, x_self_cond = None):
b, *_, device = *x.shape, x.device
batched_times = torch.full((b,), t, device = x.device, dtype = torch.long)
model_mean, _, model_log_variance, x_start = self.p_mean_variance(x = x, t = batched_times, x_self_cond = x_self_cond, clip_denoised = True)
noise = torch.randn_like(x) if t > 0 else 0. # no noise if t == 0
pred_img = model_mean + (0.5 * model_log_variance).exp() * noise
return pred_img, x_start
@torch.no_grad()
def p_sample_loop(self, shape, return_all_timesteps = False):
batch, device = shape[0], self.betas.device
img = torch.randn(shape, device = device)
imgs = [img]
x_start = None
for t in tqdm(reversed(range(0, self.num_timesteps)), desc = 'sampling loop time step', total = self.num_timesteps):
self_cond = x_start if self.self_condition else None
img, x_start = self.p_sample(img, t, self_cond)
imgs.append(img)
ret = img if not return_all_timesteps else torch.stack(imgs, dim = 1)
ret = self.unnormalize(ret)
return ret
@torch.no_grad()
def ddim_sample(self, shape, return_all_timesteps = False):
batch, device, total_timesteps, sampling_timesteps, eta, objective = shape[0], self.betas.device, self.num_timesteps, self.sampling_timesteps, self.ddim_sampling_eta, self.objective
times = torch.linspace(-1, total_timesteps - 1, steps = sampling_timesteps + 1) # [-1, 0, 1, 2, ..., T-1] when sampling_timesteps == total_timesteps
times = list(reversed(times.int().tolist()))
time_pairs = list(zip(times[:-1], times[1:])) # [(T-1, T-2), (T-2, T-3), ..., (1, 0), (0, -1)]
img = torch.randn(shape, device = device)
imgs = [img]
x_start = None
for time, time_next in tqdm(time_pairs, desc = 'sampling loop time step'):
time_cond = torch.full((batch,), time, device = device, dtype = torch.long)
self_cond = x_start if self.self_condition else None
pred_noise, x_start, *_ = self.model_predictions(img, time_cond, self_cond, clip_x_start = True)
if time_next < 0:
img = x_start
imgs.append(img)
continue
alpha = self.alphas_cumprod[time]
alpha_next = self.alphas_cumprod[time_next]
sigma = eta * ((1 - alpha / alpha_next) * (1 - alpha_next) / (1 - alpha)).sqrt()
c = (1 - alpha_next - sigma ** 2).sqrt()
noise = torch.randn_like(img)
img = x_start * alpha_next.sqrt() + \
c * pred_noise + \
sigma * noise
imgs.append(img)
ret = img if not return_all_timesteps else torch.stack(imgs, dim = 1)
ret = self.unnormalize(ret)
return ret
@torch.no_grad()
def sample(self, batch_size = 16, return_all_timesteps = False):
image_size, channels = self.image_size, self.channels
sample_fn = self.p_sample_loop if not self.is_ddim_sampling else self.ddim_sample
return sample_fn((batch_size, channels, image_size, image_size), return_all_timesteps = return_all_timesteps)
@torch.no_grad()
def interpolate(self, x1, x2, t = None, lam = 0.5):
b, *_, device = *x1.shape, x1.device
t = default(t, self.num_timesteps - 1)
assert x1.shape == x2.shape
t_batched = torch.full((b,), t, device = device)
xt1, xt2 = map(lambda x: self.q_sample(x, t = t_batched), (x1, x2))
img = (1 - lam) * xt1 + lam * xt2
x_start = None
for i in tqdm(reversed(range(0, t)), desc = 'interpolation sample time step', total = t):
self_cond = x_start if self.self_condition else None
img, x_start = self.p_sample(img, i, self_cond)
return img
def q_sample(self, x_start, t, noise=None):
noise = default(noise, lambda: torch.randn_like(x_start))
return (
extract(self.sqrt_alphas_cumprod, t, x_start.shape) * x_start +
extract(self.sqrt_one_minus_alphas_cumprod, t, x_start.shape) * noise
)
@property
def loss_fn(self):
if self.loss_type == 'l1':
return F.l1_loss
elif self.loss_type == 'l2':
return F.mse_loss
else:
raise ValueError(f'invalid loss type {self.loss_type}')
def diffusion_output(self, x_start, t, noise = None):
b, c, h, w = x_start.shape
noise = default(noise, lambda: torch.randn_like(x_start))
# noise sample
x = self.q_sample(x_start = x_start, t = t, noise = noise)
# if doing self-conditioning, 50% of the time, predict x_start from current set of times
# and condition with unet with that
# this technique will slow down training by 25%, but seems to lower FID significantly
x_self_cond = None
if self.self_condition and random() < 0.5:
with torch.no_grad():
x_self_cond = self.model_predictions(x, t).pred_x_start
x_self_cond.detach_()
# predict and take gradient step
model_out = self.model(x, t, x_self_cond)
return model_out
def forward(self, img, *args, **kwargs):
b, c, h, w, device, img_size, = *img.shape, img.device, self.image_size
assert h == img_size and w == img_size, f'height and width of image must be {img_size}'
t = torch.randint(0, self.num_timesteps, (b,), device=device).long()
img = self.normalize(img)
return self.diffusion_output(img, t, *args, **kwargs)