DiffAE_diffusion_base.py · GlastonburyGroup/UKBBLatent_Cardiac_20208_DiffAE3D_L128_S1994 at 485c2ee422cb53a948acd2b46128710b2fcb2a91

UKBBLatent_Cardiac_20208_DiffAE3D_L128_S1994 / DiffAE_diffusion_base.py

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	"""
	This code started out as a PyTorch port of Ho et al's diffusion models:
	https://github.com/hojonathanho/diffusion/blob/1e0dceb3b3495bbe19116a5e1b3596cd0706c543/diffusion_tf/diffusion_utils_2.py

	Docstrings have been added, as well as DDIM sampling and a new collection of beta schedules.
	"""

	from .DiffAE_model_unet_autoenc import AutoencReturn
	from .DiffAE_support_config_base import BaseConfig
	import enum
	import math

	import numpy as np
	import torch as th
	from .DiffAE_model import *
	from .DiffAE_model_nn import mean_flat
	from typing import NamedTuple, Tuple
	from .DiffAE_support_choices import *
	from torch.cuda.amp import autocast
	import torch.nn.functional as F

	from dataclasses import dataclass


	@dataclass
	class GaussianDiffusionBeatGansConfig(BaseConfig):
	gen_type: GenerativeType
	betas: Tuple[float]
	model_type: ModelType
	model_mean_type: ModelMeanType
	model_var_type: ModelVarType
	loss_type: LossType
	rescale_timesteps: bool
	fp16: bool
	train_pred_xstart_detach: bool = True

	def make_sampler(self):
	return GaussianDiffusionBeatGans(self)


	class GaussianDiffusionBeatGans:
	"""
	Utilities for training and sampling diffusion models.

	Ported directly from here, and then adapted over time to further experimentation.
	https://github.com/hojonathanho/diffusion/blob/1e0dceb3b3495bbe19116a5e1b3596cd0706c543/diffusion_tf/diffusion_utils_2.py#L42

	:param betas: a 1-D numpy array of betas for each diffusion timestep,
	starting at T and going to 1.
	:param model_mean_type: a ModelMeanType determining what the model outputs.
	:param model_var_type: a ModelVarType determining how variance is output.
	:param loss_type: a LossType determining the loss function to use.
	:param rescale_timesteps: if True, pass floating point timesteps into the
	model so that they are always scaled like in the
	original paper (0 to 1000).
	"""
	def __init__(self, conf: GaussianDiffusionBeatGansConfig):
	self.conf = conf
	self.model_mean_type = conf.model_mean_type
	self.model_var_type = conf.model_var_type
	self.loss_type = conf.loss_type
	self.rescale_timesteps = conf.rescale_timesteps

	# Use float64 for accuracy.
	betas = np.array(conf.betas, dtype=np.float64)
	self.betas = betas
	assert len(betas.shape) == 1, "betas must be 1-D"
	assert (betas > 0).all() and (betas <= 1).all()

	self.num_timesteps = int(betas.shape[0])

	alphas = 1.0 - betas
	self.alphas_cumprod = np.cumprod(alphas, axis=0)
	self.alphas_cumprod_prev = np.append(1.0, self.alphas_cumprod[:-1])
	self.alphas_cumprod_next = np.append(self.alphas_cumprod[1:], 0.0)
	assert self.alphas_cumprod_prev.shape == (self.num_timesteps, )

	# calculations for diffusion q(x_t \| x_{t-1}) and others
	self.sqrt_alphas_cumprod = np.sqrt(self.alphas_cumprod)
	self.sqrt_one_minus_alphas_cumprod = np.sqrt(1.0 - self.alphas_cumprod)
	self.log_one_minus_alphas_cumprod = np.log(1.0 - self.alphas_cumprod)
	self.sqrt_recip_alphas_cumprod = np.sqrt(1.0 / self.alphas_cumprod)
	self.sqrt_recipm1_alphas_cumprod = np.sqrt(1.0 / self.alphas_cumprod -
	1)

	# calculations for posterior q(x_{t-1} \| x_t, x_0)
	self.posterior_variance = (betas * (1.0 - self.alphas_cumprod_prev) /
	(1.0 - self.alphas_cumprod))
	# log calculation clipped because the posterior variance is 0 at the
	# beginning of the diffusion chain.
	self.posterior_log_variance_clipped = np.log(
	np.append(self.posterior_variance[1], self.posterior_variance[1:]))
	self.posterior_mean_coef1 = (betas *
	np.sqrt(self.alphas_cumprod_prev) /
	(1.0 - self.alphas_cumprod))
	self.posterior_mean_coef2 = ((1.0 - self.alphas_cumprod_prev) *
	np.sqrt(alphas) /
	(1.0 - self.alphas_cumprod))

	def training_losses(self,
	model: Model,
	x_start: th.Tensor,
	t: th.Tensor,
	model_kwargs=None,
	noise: th.Tensor = None):
	"""
	Compute training losses for a single timestep.

	:param model: the model to evaluate loss on.
	:param x_start: the [N x C x ...] tensor of inputs.
	:param t: a batch of timestep indices.
	:param model_kwargs: if not None, a dict of extra keyword arguments to
	pass to the model. This can be used for conditioning.
	:param noise: if specified, the specific Gaussian noise to try to remove.
	:return: a dict with the key "loss" containing a tensor of shape [N].
	Some mean or variance settings may also have other keys.
	"""
	if model_kwargs is None:
	model_kwargs = {}
	if noise is None:
	noise = th.randn_like(x_start)

	x_t = self.q_sample(x_start, t, noise=noise)

	terms = {'x_t': x_t}

	if self.loss_type in [
	LossType.mse,
	LossType.l1,
	]:
	with autocast(self.conf.fp16):
	# x_t is static wrt. to the diffusion process
	model_forward = model.forward(x=x_t.detach(),
	t=self._scale_timesteps(t),
	x_start=x_start.detach(),
	**model_kwargs)
	model_output = model_forward.pred

	_model_output = model_output
	if self.conf.train_pred_xstart_detach:
	_model_output = _model_output.detach()
	# get the pred xstart
	p_mean_var = self.p_mean_variance(
	model=DummyModel(pred=_model_output),
	# gradient goes through x_t
	x=x_t,
	t=t,
	clip_denoised=False)
	terms['pred_xstart'] = p_mean_var['pred_xstart']

	# model_output = model(x_t, self._scale_timesteps(t), **model_kwargs)

	target_types = {
	ModelMeanType.eps: noise,
	}
	target = target_types[self.model_mean_type]
	assert model_output.shape == target.shape == x_start.shape

	if self.loss_type == LossType.mse:
	if self.model_mean_type == ModelMeanType.eps:
	# (n, c, h, w) => (n, )
	terms["mse"] = mean_flat((target - model_output)**2)
	else:
	raise NotImplementedError()
	elif self.loss_type == LossType.l1:
	# (n, c, h, w) => (n, )
	terms["mse"] = mean_flat((target - model_output).abs())
	else:
	raise NotImplementedError()

	if "vb" in terms:
	# if learning the variance also use the vlb loss
	terms["loss"] = terms["mse"] + terms["vb"]
	else:
	terms["loss"] = terms["mse"]
	else:
	raise NotImplementedError(self.loss_type)

	return terms

	def sample(self,
	model: Model,
	shape=None,
	noise=None,
	cond=None,
	x_start=None,
	clip_denoised=True,
	model_kwargs=None,
	progress=False):
	"""
	Args:
	x_start: given for the autoencoder
	"""
	if model_kwargs is None:
	model_kwargs = {}
	if self.conf.model_type.has_autoenc():
	model_kwargs['x_start'] = x_start
	model_kwargs['cond'] = cond

	if self.conf.gen_type == GenerativeType.ddpm:
	return self.p_sample_loop(model,
	shape=shape,
	noise=noise,
	clip_denoised=clip_denoised,
	model_kwargs=model_kwargs,
	progress=progress)
	elif self.conf.gen_type == GenerativeType.ddim:
	return self.ddim_sample_loop(model,
	shape=shape,
	noise=noise,
	clip_denoised=clip_denoised,
	model_kwargs=model_kwargs,
	progress=progress)
	else:
	raise NotImplementedError()

	def q_mean_variance(self, x_start, t):
	"""
	Get the distribution q(x_t \| x_0).

	:param x_start: the [N x C x ...] tensor of noiseless inputs.
	:param t: the number of diffusion steps (minus 1). Here, 0 means one step.
	:return: A tuple (mean, variance, log_variance), all of x_start's shape.
	"""
	mean = (
	_extract_into_tensor(self.sqrt_alphas_cumprod, t, x_start.shape) *
	x_start)
	variance = _extract_into_tensor(1.0 - self.alphas_cumprod, t,
	x_start.shape)
	log_variance = _extract_into_tensor(self.log_one_minus_alphas_cumprod,
	t, x_start.shape)
	return mean, variance, log_variance

	def q_sample(self, x_start, t, noise=None):
	"""
	Diffuse the data for a given number of diffusion steps.

	In other words, sample from q(x_t \| x_0).

	:param x_start: the initial data batch.
	:param t: the number of diffusion steps (minus 1). Here, 0 means one step.
	:param noise: if specified, the split-out normal noise.
	:return: A noisy version of x_start.
	"""
	if noise is None:
	noise = th.randn_like(x_start)
	assert noise.shape == x_start.shape
	return (
	_extract_into_tensor(self.sqrt_alphas_cumprod, t, x_start.shape) *
	x_start + _extract_into_tensor(self.sqrt_one_minus_alphas_cumprod,
	t, x_start.shape) * noise)

	def q_posterior_mean_variance(self, x_start, x_t, t):
	"""
	Compute the mean and variance of the diffusion posterior:

	q(x_{t-1} \| x_t, x_0)

	"""
	assert x_start.shape == x_t.shape
	posterior_mean = (
	_extract_into_tensor(self.posterior_mean_coef1, t, x_t.shape) *
	x_start +
	_extract_into_tensor(self.posterior_mean_coef2, t, x_t.shape) *
	x_t)
	posterior_variance = _extract_into_tensor(self.posterior_variance, t,
	x_t.shape)
	posterior_log_variance_clipped = _extract_into_tensor(
	self.posterior_log_variance_clipped, t, x_t.shape)
	assert (posterior_mean.shape[0] == posterior_variance.shape[0] ==
	posterior_log_variance_clipped.shape[0] == x_start.shape[0])
	return posterior_mean, posterior_variance, posterior_log_variance_clipped

	def p_mean_variance(self,
	model: Model,
	x,
	t,
	clip_denoised=True,
	denoised_fn=None,
	model_kwargs=None):
	"""
	Apply the model to get p(x_{t-1} \| x_t), as well as a prediction of
	the initial x, x_0.

	:param model: the model, which takes a signal and a batch of timesteps
	as input.
	:param x: the [N x C x ...] tensor at time t.
	:param t: a 1-D Tensor of timesteps.
	:param clip_denoised: if True, clip the denoised signal into [-1, 1].
	:param denoised_fn: if not None, a function which applies to the
	x_start prediction before it is used to sample. Applies before
	clip_denoised.
	:param model_kwargs: if not None, a dict of extra keyword arguments to
	pass to the model. This can be used for conditioning.
	:return: a dict with the following keys:
	- 'mean': the model mean output.
	- 'variance': the model variance output.
	- 'log_variance': the log of 'variance'.
	- 'pred_xstart': the prediction for x_0.
	"""
	if model_kwargs is None:
	model_kwargs = {}

	B, C = x.shape[:2]
	assert t.shape == (B, )
	with autocast(self.conf.fp16):
	model_forward = model.forward(x=x,
	t=self._scale_timesteps(t),
	**model_kwargs)
	model_output = model_forward.pred

	if self.model_var_type in [
	ModelVarType.fixed_large, ModelVarType.fixed_small
	]:
	model_variance, model_log_variance = {
	# for fixedlarge, we set the initial (log-)variance like so
	# to get a better decoder log likelihood.
	ModelVarType.fixed_large: (
	np.append(self.posterior_variance[1], self.betas[1:]),
	np.log(
	np.append(self.posterior_variance[1], self.betas[1:])),
	),
	ModelVarType.fixed_small: (
	self.posterior_variance,
	self.posterior_log_variance_clipped,
	),
	}[self.model_var_type]
	model_variance = _extract_into_tensor(model_variance, t, x.shape)
	model_log_variance = _extract_into_tensor(model_log_variance, t,
	x.shape)

	def process_xstart(x):
	if denoised_fn is not None:
	x = denoised_fn(x)
	if clip_denoised:
	return x.clamp(-1, 1)
	return x

	if self.model_mean_type in [
	ModelMeanType.eps,
	]:
	if self.model_mean_type == ModelMeanType.eps:
	pred_xstart = process_xstart(
	self._predict_xstart_from_eps(x_t=x, t=t,
	eps=model_output))
	else:
	raise NotImplementedError()
	model_mean, _, _ = self.q_posterior_mean_variance(
	x_start=pred_xstart, x_t=x, t=t)
	else:
	raise NotImplementedError(self.model_mean_type)

	assert (model_mean.shape == model_log_variance.shape ==
	pred_xstart.shape == x.shape)
	return {
	"mean": model_mean,
	"variance": model_variance,
	"log_variance": model_log_variance,
	"pred_xstart": pred_xstart,
	'model_forward': model_forward,
	}

	def _predict_xstart_from_eps(self, x_t, t, eps):
	assert x_t.shape == eps.shape
	return (_extract_into_tensor(self.sqrt_recip_alphas_cumprod, t,
	x_t.shape) * x_t -
	_extract_into_tensor(self.sqrt_recipm1_alphas_cumprod, t,
	x_t.shape) * eps)

	def _predict_xstart_from_xprev(self, x_t, t, xprev):
	assert x_t.shape == xprev.shape
	return ( # (xprev - coef2*x_t) / coef1
	_extract_into_tensor(1.0 / self.posterior_mean_coef1, t, x_t.shape)
	* xprev - _extract_into_tensor(
	self.posterior_mean_coef2 / self.posterior_mean_coef1, t,
	x_t.shape) * x_t)

	def _predict_xstart_from_scaled_xstart(self, t, scaled_xstart):
	return scaled_xstart * _extract_into_tensor(
	self.sqrt_recip_alphas_cumprod, t, scaled_xstart.shape)

	def _predict_eps_from_xstart(self, x_t, t, pred_xstart):
	return (_extract_into_tensor(self.sqrt_recip_alphas_cumprod, t,
	x_t.shape) * x_t -
	pred_xstart) / _extract_into_tensor(
	self.sqrt_recipm1_alphas_cumprod, t, x_t.shape)

	def _predict_eps_from_scaled_xstart(self, x_t, t, scaled_xstart):
	"""
	Args:
	scaled_xstart: is supposed to be sqrt(alphacum) * x_0
	"""
	# 1 / sqrt(1-alphabar) * (x_t - scaled xstart)
	return (x_t - scaled_xstart) / _extract_into_tensor(
	self.sqrt_one_minus_alphas_cumprod, t, x_t.shape)

	def _scale_timesteps(self, t):
	if self.rescale_timesteps:
	# scale t to be maxed out at 1000 steps
	return t.float() * (1000.0 / self.num_timesteps)
	return t

	def condition_mean(self, cond_fn, p_mean_var, x, t, model_kwargs=None):
	"""
	Compute the mean for the previous step, given a function cond_fn that
	computes the gradient of a conditional log probability with respect to
	x. In particular, cond_fn computes grad(log(p(y\|x))), and we want to
	condition on y.

	This uses the conditioning strategy from Sohl-Dickstein et al. (2015).
	"""
	gradient = cond_fn(x, self._scale_timesteps(t), **model_kwargs)
	new_mean = (p_mean_var["mean"].float() +
	p_mean_var["variance"] * gradient.float())
	return new_mean

	def condition_score(self, cond_fn, p_mean_var, x, t, model_kwargs=None):
	"""
	Compute what the p_mean_variance output would have been, should the
	model's score function be conditioned by cond_fn.

	See condition_mean() for details on cond_fn.

	Unlike condition_mean(), this instead uses the conditioning strategy
	from Song et al (2020).
	"""
	alpha_bar = _extract_into_tensor(self.alphas_cumprod, t, x.shape)

	eps = self._predict_eps_from_xstart(x, t, p_mean_var["pred_xstart"])
	eps = eps - (1 - alpha_bar).sqrt() * cond_fn(
	x, self._scale_timesteps(t), **model_kwargs)

	out = p_mean_var.copy()
	out["pred_xstart"] = self._predict_xstart_from_eps(x, t, eps)
	out["mean"], _, _ = self.q_posterior_mean_variance(
	x_start=out["pred_xstart"], x_t=x, t=t)
	return out

	def p_sample(
	self,
	model: Model,
	x,
	t,
	clip_denoised=True,
	denoised_fn=None,
	cond_fn=None,
	model_kwargs=None,
	):
	"""
	Sample x_{t-1} from the model at the given timestep.

	:param model: the model to sample from.
	:param x: the current tensor at x_{t-1}.
	:param t: the value of t, starting at 0 for the first diffusion step.
	:param clip_denoised: if True, clip the x_start prediction to [-1, 1].
	:param denoised_fn: if not None, a function which applies to the
	x_start prediction before it is used to sample.
	:param cond_fn: if not None, this is a gradient function that acts
	similarly to the model.
	:param model_kwargs: if not None, a dict of extra keyword arguments to
	pass to the model. This can be used for conditioning.
	:return: a dict containing the following keys:
	- 'sample': a random sample from the model.
	- 'pred_xstart': a prediction of x_0.
	"""
	out = self.p_mean_variance(
	model,
	x,
	t,
	clip_denoised=clip_denoised,
	denoised_fn=denoised_fn,
	model_kwargs=model_kwargs,
	)
	noise = th.randn_like(x)
	nonzero_mask = ((t != 0).float().view(-1, ([1] (len(x.shape) - 1)))
	) # no noise when t == 0
	if cond_fn is not None:
	out["mean"] = self.condition_mean(cond_fn,
	out,
	x,
	t,
	model_kwargs=model_kwargs)
	sample = out["mean"] + nonzero_mask * th.exp(
	0.5 * out["log_variance"]) * noise
	return {"sample": sample, "pred_xstart": out["pred_xstart"]}

	def p_sample_loop(
	self,
	model: Model,
	shape=None,
	noise=None,
	clip_denoised=True,
	denoised_fn=None,
	cond_fn=None,
	model_kwargs=None,
	device=None,
	progress=False,
	):
	"""
	Generate samples from the model.

	:param model: the model module.
	:param shape: the shape of the samples, (N, C, H, W).
	:param noise: if specified, the noise from the encoder to sample.
	Should be of the same shape as `shape`.
	:param clip_denoised: if True, clip x_start predictions to [-1, 1].
	:param denoised_fn: if not None, a function which applies to the
	x_start prediction before it is used to sample.
	:param cond_fn: if not None, this is a gradient function that acts
	similarly to the model.
	:param model_kwargs: if not None, a dict of extra keyword arguments to
	pass to the model. This can be used for conditioning.
	:param device: if specified, the device to create the samples on.
	If not specified, use a model parameter's device.
	:param progress: if True, show a tqdm progress bar.
	:return: a non-differentiable batch of samples.
	"""
	final = None
	for sample in self.p_sample_loop_progressive(
	model,
	shape,
	noise=noise,
	clip_denoised=clip_denoised,
	denoised_fn=denoised_fn,
	cond_fn=cond_fn,
	model_kwargs=model_kwargs,
	device=device,
	progress=progress,
	):
	final = sample
	return final["sample"]

	def p_sample_loop_progressive(
	self,
	model: Model,
	shape=None,
	noise=None,
	clip_denoised=True,
	denoised_fn=None,
	cond_fn=None,
	model_kwargs=None,
	device=None,
	progress=False,
	):
	"""
	Generate samples from the model and yield intermediate samples from
	each timestep of diffusion.

	Arguments are the same as p_sample_loop().
	Returns a generator over dicts, where each dict is the return value of
	p_sample().
	"""
	if device is None:
	device = next(model.parameters()).device
	if noise is not None:
	img = noise
	else:
	assert isinstance(shape, (tuple, list))
	img = th.randn(*shape, device=device)
	indices = list(range(self.num_timesteps))[::-1]

	if progress:
	# Lazy import so that we don't depend on tqdm.
	from tqdm.auto import tqdm

	indices = tqdm(indices)

	for i in indices:
	# t = th.tensor([i] * shape[0], device=device)
	t = th.tensor([i] * len(img), device=device)
	with th.no_grad():
	out = self.p_sample(
	model,
	img,
	t,
	clip_denoised=clip_denoised,
	denoised_fn=denoised_fn,
	cond_fn=cond_fn,
	model_kwargs=model_kwargs,
	)
	yield out
	img = out["sample"]

	def ddim_sample(
	self,
	model: Model,
	x,
	t,
	clip_denoised=True,
	denoised_fn=None,
	cond_fn=None,
	model_kwargs=None,
	eta=0.0,
	):
	"""
	Sample x_{t-1} from the model using DDIM.

	Same usage as p_sample().
	"""
	out = self.p_mean_variance(
	model,
	x,
	t,
	clip_denoised=clip_denoised,
	denoised_fn=denoised_fn,
	model_kwargs=model_kwargs,
	)
	if cond_fn is not None:
	out = self.condition_score(cond_fn,
	out,
	x,
	t,
	model_kwargs=model_kwargs)

	# Usually our model outputs epsilon, but we re-derive it
	# in case we used x_start or x_prev prediction.
	eps = self._predict_eps_from_xstart(x, t, out["pred_xstart"])

	alpha_bar = _extract_into_tensor(self.alphas_cumprod, t, x.shape)
	alpha_bar_prev = _extract_into_tensor(self.alphas_cumprod_prev, t,
	x.shape)
	sigma = (eta * th.sqrt((1 - alpha_bar_prev) / (1 - alpha_bar)) *
	th.sqrt(1 - alpha_bar / alpha_bar_prev))
	# Equation 12.
	noise = th.randn_like(x)
	mean_pred = (out["pred_xstart"] * th.sqrt(alpha_bar_prev) +
	th.sqrt(1 - alpha_bar_prev - sigma*2) eps)
	nonzero_mask = ((t != 0).float().view(-1, ([1] (len(x.shape) - 1)))
	) # no noise when t == 0
	sample = mean_pred + nonzero_mask * sigma * noise
	return {"sample": sample, "pred_xstart": out["pred_xstart"]}

	def ddim_reverse_sample(
	self,
	model: Model,
	x,
	t,
	clip_denoised=True,
	denoised_fn=None,
	model_kwargs=None,
	eta=0.0,
	):
	"""
	Sample x_{t+1} from the model using DDIM reverse ODE.
	NOTE: never used ?
	"""
	assert eta == 0.0, "Reverse ODE only for deterministic path"
	out = self.p_mean_variance(
	model,
	x,
	t,
	clip_denoised=clip_denoised,
	denoised_fn=denoised_fn,
	model_kwargs=model_kwargs,
	)
	# Usually our model outputs epsilon, but we re-derive it
	# in case we used x_start or x_prev prediction.
	eps = (_extract_into_tensor(self.sqrt_recip_alphas_cumprod, t, x.shape)
	* x - out["pred_xstart"]) / _extract_into_tensor(
	self.sqrt_recipm1_alphas_cumprod, t, x.shape)
	alpha_bar_next = _extract_into_tensor(self.alphas_cumprod_next, t,
	x.shape)

	# Equation 12. reversed (DDIM paper) (th.sqrt == torch.sqrt)
	mean_pred = (out["pred_xstart"] * th.sqrt(alpha_bar_next) +
	th.sqrt(1 - alpha_bar_next) * eps)

	return {"sample": mean_pred, "pred_xstart": out["pred_xstart"]}

	def ddim_reverse_sample_loop(
	self,
	model: Model,
	x,
	clip_denoised=True,
	denoised_fn=None,
	model_kwargs=None,
	eta=0.0,
	device=None,
	):
	if device is None:
	device = next(model.parameters()).device
	sample_t = []
	xstart_t = []
	T = []
	indices = list(range(self.num_timesteps))
	sample = x
	for i in indices:
	t = th.tensor([i] * len(sample), device=device)
	with th.no_grad():
	out = self.ddim_reverse_sample(model,
	sample,
	t=t,
	clip_denoised=clip_denoised,
	denoised_fn=denoised_fn,
	model_kwargs=model_kwargs,
	eta=eta)
	sample = out['sample']
	# [1, ..., T]
	sample_t.append(sample)
	# [0, ...., T-1]
	xstart_t.append(out['pred_xstart'])
	# [0, ..., T-1] ready to use
	T.append(t)

	return {
	# xT "
	'sample': sample,
	# (1, ..., T)
	'sample_t': sample_t,
	# xstart here is a bit different from sampling from T = T-1 to T = 0
	# may not be exact
	'xstart_t': xstart_t,
	'T': T,
	}

	def ddim_sample_loop(
	self,
	model: Model,
	shape=None,
	noise=None,
	clip_denoised=True,
	denoised_fn=None,
	cond_fn=None,
	model_kwargs=None,
	device=None,
	progress=False,
	eta=0.0,
	):
	"""
	Generate samples from the model using DDIM.

	Same usage as p_sample_loop().
	"""
	final = None
	for sample in self.ddim_sample_loop_progressive(
	model,
	shape,
	noise=noise,
	clip_denoised=clip_denoised,
	denoised_fn=denoised_fn,
	cond_fn=cond_fn,
	model_kwargs=model_kwargs,
	device=device,
	progress=progress,
	eta=eta,
	):
	final = sample
	return final["sample"]

	def ddim_sample_loop_progressive(
	self,
	model: Model,
	shape=None,
	noise=None,
	clip_denoised=True,
	denoised_fn=None,
	cond_fn=None,
	model_kwargs=None,
	device=None,
	progress=False,
	eta=0.0,
	):
	"""
	Use DDIM to sample from the model and yield intermediate samples from
	each timestep of DDIM.

	Same usage as p_sample_loop_progressive().
	"""
	if device is None:
	device = next(model.parameters()).device
	if noise is not None:
	img = noise
	else:
	assert isinstance(shape, (tuple, list))
	img = th.randn(*shape, device=device)
	indices = list(range(self.num_timesteps))[::-1]

	if progress:
	# Lazy import so that we don't depend on tqdm.
	from tqdm.auto import tqdm

	indices = tqdm(indices)

	for i in indices:

	if isinstance(model_kwargs, list):
	# index dependent model kwargs
	# (T-1, ..., 0)
	_kwargs = model_kwargs[i]
	else:
	_kwargs = model_kwargs

	t = th.tensor([i] * len(img), device=device)
	with th.no_grad():
	out = self.ddim_sample(
	model,
	img,
	t,
	clip_denoised=clip_denoised,
	denoised_fn=denoised_fn,
	cond_fn=cond_fn,
	model_kwargs=_kwargs,
	eta=eta,
	)
	out['t'] = t
	yield out
	img = out["sample"]

	def _vb_terms_bpd(self,
	model: Model,
	x_start,
	x_t,
	t,
	clip_denoised=True,
	model_kwargs=None):
	"""
	Get a term for the variational lower-bound.

	The resulting units are bits (rather than nats, as one might expect).
	This allows for comparison to other papers.

	:return: a dict with the following keys:
	- 'output': a shape [N] tensor of NLLs or KLs.
	- 'pred_xstart': the x_0 predictions.
	"""
	true_mean, _, true_log_variance_clipped = self.q_posterior_mean_variance(
	x_start=x_start, x_t=x_t, t=t)
	out = self.p_mean_variance(model,
	x_t,
	t,
	clip_denoised=clip_denoised,
	model_kwargs=model_kwargs)
	kl = normal_kl(true_mean, true_log_variance_clipped, out["mean"],
	out["log_variance"])
	kl = mean_flat(kl) / np.log(2.0)

	decoder_nll = -discretized_gaussian_log_likelihood(
	x_start, means=out["mean"], log_scales=0.5 * out["log_variance"])
	assert decoder_nll.shape == x_start.shape
	decoder_nll = mean_flat(decoder_nll) / np.log(2.0)

	# At the first timestep return the decoder NLL,
	# otherwise return KL(q(x_{t-1}\|x_t,x_0) \|\| p(x_{t-1}\|x_t))
	output = th.where((t == 0), decoder_nll, kl)
	return {
	"output": output,
	"pred_xstart": out["pred_xstart"],
	'model_forward': out['model_forward'],
	}

	def _prior_bpd(self, x_start):
	"""
	Get the prior KL term for the variational lower-bound, measured in
	bits-per-dim.

	This term can't be optimized, as it only depends on the encoder.

	:param x_start: the [N x C x ...] tensor of inputs.
	:return: a batch of [N] KL values (in bits), one per batch element.
	"""
	batch_size = x_start.shape[0]
	t = th.tensor([self.num_timesteps - 1] * batch_size,
	device=x_start.device)
	qt_mean, _, qt_log_variance = self.q_mean_variance(x_start, t)
	kl_prior = normal_kl(mean1=qt_mean,
	logvar1=qt_log_variance,
	mean2=0.0,
	logvar2=0.0)
	return mean_flat(kl_prior) / np.log(2.0)

	def calc_bpd_loop(self,
	model: Model,
	x_start,
	clip_denoised=True,
	model_kwargs=None):
	"""
	Compute the entire variational lower-bound, measured in bits-per-dim,
	as well as other related quantities.

	:param model: the model to evaluate loss on.
	:param x_start: the [N x C x ...] tensor of inputs.
	:param clip_denoised: if True, clip denoised samples.
	:param model_kwargs: if not None, a dict of extra keyword arguments to
	pass to the model. This can be used for conditioning.

	:return: a dict containing the following keys:
	- total_bpd: the total variational lower-bound, per batch element.
	- prior_bpd: the prior term in the lower-bound.
	- vb: an [N x T] tensor of terms in the lower-bound.
	- xstart_mse: an [N x T] tensor of x_0 MSEs for each timestep.
	- mse: an [N x T] tensor of epsilon MSEs for each timestep.
	"""
	device = x_start.device
	batch_size = x_start.shape[0]

	vb = []
	xstart_mse = []
	mse = []
	for t in list(range(self.num_timesteps))[::-1]:
	t_batch = th.tensor([t] * batch_size, device=device)
	noise = th.randn_like(x_start)
	x_t = self.q_sample(x_start=x_start, t=t_batch, noise=noise)
	# Calculate VLB term at the current timestep
	with th.no_grad():
	out = self._vb_terms_bpd(
	model,
	x_start=x_start,
	x_t=x_t,
	t=t_batch,
	clip_denoised=clip_denoised,
	model_kwargs=model_kwargs,
	)
	vb.append(out["output"])
	xstart_mse.append(mean_flat((out["pred_xstart"] - x_start)**2))
	eps = self._predict_eps_from_xstart(x_t, t_batch,
	out["pred_xstart"])
	mse.append(mean_flat((eps - noise)**2))

	vb = th.stack(vb, dim=1)
	xstart_mse = th.stack(xstart_mse, dim=1)
	mse = th.stack(mse, dim=1)

	prior_bpd = self._prior_bpd(x_start)
	total_bpd = vb.sum(dim=1) + prior_bpd
	return {
	"total_bpd": total_bpd,
	"prior_bpd": prior_bpd,
	"vb": vb,
	"xstart_mse": xstart_mse,
	"mse": mse,
	}


	def _extract_into_tensor(arr, timesteps, broadcast_shape):
	"""
	Extract values from a 1-D numpy array for a batch of indices.

	:param arr: the 1-D numpy array.
	:param timesteps: a tensor of indices into the array to extract.
	:param broadcast_shape: a larger shape of K dimensions with the batch
	dimension equal to the length of timesteps.
	:return: a tensor of shape [batch_size, 1, ...] where the shape has K dims.
	"""
	res = th.from_numpy(arr).to(device=timesteps.device)[timesteps].float()
	while len(res.shape) < len(broadcast_shape):
	res = res[..., None]
	return res.expand(broadcast_shape)


	def get_named_beta_schedule(schedule_name, num_diffusion_timesteps):
	"""
	Get a pre-defined beta schedule for the given name.

	The beta schedule library consists of beta schedules which remain similar
	in the limit of num_diffusion_timesteps.
	Beta schedules may be added, but should not be removed or changed once
	they are committed to maintain backwards compatibility.
	"""
	if schedule_name == "linear":
	# Linear schedule from Ho et al, extended to work for any number of
	# diffusion steps.
	scale = 1000 / num_diffusion_timesteps
	beta_start = scale * 0.0001
	beta_end = scale * 0.02
	return np.linspace(beta_start,
	beta_end,
	num_diffusion_timesteps,
	dtype=np.float64)
	elif schedule_name == "cosine":
	return betas_for_alpha_bar(
	num_diffusion_timesteps,
	lambda t: math.cos((t + 0.008) / 1.008 * math.pi / 2)**2,
	)
	elif schedule_name == "const0.01":
	scale = 1000 / num_diffusion_timesteps
	return np.array([scale * 0.01] * num_diffusion_timesteps,
	dtype=np.float64)
	elif schedule_name == "const0.015":
	scale = 1000 / num_diffusion_timesteps
	return np.array([scale * 0.015] * num_diffusion_timesteps,
	dtype=np.float64)
	elif schedule_name == "const0.008":
	scale = 1000 / num_diffusion_timesteps
	return np.array([scale * 0.008] * num_diffusion_timesteps,
	dtype=np.float64)
	elif schedule_name == "const0.0065":
	scale = 1000 / num_diffusion_timesteps
	return np.array([scale * 0.0065] * num_diffusion_timesteps,
	dtype=np.float64)
	elif schedule_name == "const0.0055":
	scale = 1000 / num_diffusion_timesteps
	return np.array([scale * 0.0055] * num_diffusion_timesteps,
	dtype=np.float64)
	elif schedule_name == "const0.0045":
	scale = 1000 / num_diffusion_timesteps
	return np.array([scale * 0.0045] * num_diffusion_timesteps,
	dtype=np.float64)
	elif schedule_name == "const0.0035":
	scale = 1000 / num_diffusion_timesteps
	return np.array([scale * 0.0035] * num_diffusion_timesteps,
	dtype=np.float64)
	elif schedule_name == "const0.0025":
	scale = 1000 / num_diffusion_timesteps
	return np.array([scale * 0.0025] * num_diffusion_timesteps,
	dtype=np.float64)
	elif schedule_name == "const0.0015":
	scale = 1000 / num_diffusion_timesteps
	return np.array([scale * 0.0015] * num_diffusion_timesteps,
	dtype=np.float64)
	else:
	raise NotImplementedError(f"unknown beta schedule: {schedule_name}")


	def betas_for_alpha_bar(num_diffusion_timesteps, alpha_bar, max_beta=0.999):
	"""
	Create a beta schedule that discretizes the given alpha_t_bar function,
	which defines the cumulative product of (1-beta) over time from t = [0,1].

	:param num_diffusion_timesteps: the number of betas to produce.
	:param alpha_bar: a lambda that takes an argument t from 0 to 1 and
	produces the cumulative product of (1-beta) up to that
	part of the diffusion process.
	:param max_beta: the maximum beta to use; use values lower than 1 to
	prevent singularities.
	"""
	betas = []
	for i in range(num_diffusion_timesteps):
	t1 = i / num_diffusion_timesteps
	t2 = (i + 1) / num_diffusion_timesteps
	betas.append(min(1 - alpha_bar(t2) / alpha_bar(t1), max_beta))
	return np.array(betas)


	def normal_kl(mean1, logvar1, mean2, logvar2):
	"""
	Compute the KL divergence between two gaussians.

	Shapes are automatically broadcasted, so batches can be compared to
	scalars, among other use cases.
	"""
	tensor = None
	for obj in (mean1, logvar1, mean2, logvar2):
	if isinstance(obj, th.Tensor):
	tensor = obj
	break
	assert tensor is not None, "at least one argument must be a Tensor"

	# Force variances to be Tensors. Broadcasting helps convert scalars to
	# Tensors, but it does not work for th.exp().
	logvar1, logvar2 = [
	x if isinstance(x, th.Tensor) else th.tensor(x).to(tensor)
	for x in (logvar1, logvar2)
	]

	return 0.5 * (-1.0 + logvar2 - logvar1 + th.exp(logvar1 - logvar2) +
	((mean1 - mean2)*2) th.exp(-logvar2))


	def approx_standard_normal_cdf(x):
	"""
	A fast approximation of the cumulative distribution function of the
	standard normal.
	"""
	return 0.5 * (
	1.0 + th.tanh(np.sqrt(2.0 / np.pi) * (x + 0.044715 * th.pow(x, 3))))


	def discretized_gaussian_log_likelihood(x, *, means, log_scales):
	"""
	Compute the log-likelihood of a Gaussian distribution discretizing to a
	given image.

	:param x: the target images. It is assumed that this was uint8 values,
	rescaled to the range [-1, 1].
	:param means: the Gaussian mean Tensor.
	:param log_scales: the Gaussian log stddev Tensor.
	:return: a tensor like x of log probabilities (in nats).
	"""
	assert x.shape == means.shape == log_scales.shape
	centered_x = x - means
	inv_stdv = th.exp(-log_scales)
	plus_in = inv_stdv * (centered_x + 1.0 / 255.0)
	cdf_plus = approx_standard_normal_cdf(plus_in)
	min_in = inv_stdv * (centered_x - 1.0 / 255.0)
	cdf_min = approx_standard_normal_cdf(min_in)
	log_cdf_plus = th.log(cdf_plus.clamp(min=1e-12))
	log_one_minus_cdf_min = th.log((1.0 - cdf_min).clamp(min=1e-12))
	cdf_delta = cdf_plus - cdf_min
	log_probs = th.where(
	x < -0.999,
	log_cdf_plus,
	th.where(x > 0.999, log_one_minus_cdf_min,
	th.log(cdf_delta.clamp(min=1e-12))),
	)
	assert log_probs.shape == x.shape
	return log_probs


	class DummyModel(th.nn.Module):
	def __init__(self, pred):
	super().__init__()
	self.pred = pred

	def forward(self, args, *kwargs):
	return DummyReturn(pred=self.pred)


	class DummyReturn(NamedTuple):
	pred: th.Tensor