PSHuman / mvdiffusion /pipelines /pipeline_mvdiffusion_unclip.py
fffiloni's picture
Migrated from GitHub
2252f3d verified
raw
history blame
32.8 kB
import inspect
import warnings
from typing import Callable, List, Optional, Union, Dict, Any
import PIL
import torch
from packaging import version
from transformers import CLIPImageProcessor, CLIPVisionModelWithProjection, CLIPFeatureExtractor, CLIPTokenizer, CLIPTextModel
from diffusers.utils.import_utils import is_accelerate_available
from diffusers.configuration_utils import FrozenDict
from diffusers.image_processor import VaeImageProcessor
from diffusers.models import AutoencoderKL, UNet2DConditionModel
from diffusers.models.embeddings import get_timestep_embedding
from diffusers.schedulers import KarrasDiffusionSchedulers
from diffusers.utils import deprecate, logging
from diffusers.utils.torch_utils import randn_tensor
from diffusers.pipelines.pipeline_utils import DiffusionPipeline, ImagePipelineOutput
from diffusers.pipelines.stable_diffusion.stable_unclip_image_normalizer import StableUnCLIPImageNormalizer
import os
import torchvision.transforms.functional as TF
from einops import rearrange
logger = logging.get_logger(__name__)
class StableUnCLIPImg2ImgPipeline(DiffusionPipeline):
"""
Pipeline for text-guided image to image generation using stable unCLIP.
This model inherits from [`DiffusionPipeline`]. Check the superclass documentation for the generic methods the
library implements for all the pipelines (such as downloading or saving, running on a particular device, etc.)
Args:
feature_extractor ([`CLIPFeatureExtractor`]):
Feature extractor for image pre-processing before being encoded.
image_encoder ([`CLIPVisionModelWithProjection`]):
CLIP vision model for encoding images.
image_normalizer ([`StableUnCLIPImageNormalizer`]):
Used to normalize the predicted image embeddings before the noise is applied and un-normalize the image
embeddings after the noise has been applied.
image_noising_scheduler ([`KarrasDiffusionSchedulers`]):
Noise schedule for adding noise to the predicted image embeddings. The amount of noise to add is determined
by `noise_level` in `StableUnCLIPPipeline.__call__`.
tokenizer (`CLIPTokenizer`):
Tokenizer of class
[CLIPTokenizer](https://huggingface.co/docs/transformers/v4.21.0/en/model_doc/clip#transformers.CLIPTokenizer).
text_encoder ([`CLIPTextModel`]):
Frozen text-encoder.
unet ([`UNet2DConditionModel`]): Conditional U-Net architecture to denoise the encoded image latents.
scheduler ([`KarrasDiffusionSchedulers`]):
A scheduler to be used in combination with `unet` to denoise the encoded image latents.
vae ([`AutoencoderKL`]):
Variational Auto-Encoder (VAE) Model to encode and decode images to and from latent representations.
"""
# image encoding components
feature_extractor: CLIPFeatureExtractor
image_encoder: CLIPVisionModelWithProjection
# image noising components
image_normalizer: StableUnCLIPImageNormalizer
image_noising_scheduler: KarrasDiffusionSchedulers
# regular denoising components
tokenizer: CLIPTokenizer
text_encoder: CLIPTextModel
unet: UNet2DConditionModel
scheduler: KarrasDiffusionSchedulers
vae: AutoencoderKL
def __init__(
self,
# image encoding components
feature_extractor: CLIPFeatureExtractor,
image_encoder: CLIPVisionModelWithProjection,
# image noising components
image_normalizer: StableUnCLIPImageNormalizer,
image_noising_scheduler: KarrasDiffusionSchedulers,
# regular denoising components
tokenizer: CLIPTokenizer,
text_encoder: CLIPTextModel,
unet: UNet2DConditionModel,
scheduler: KarrasDiffusionSchedulers,
# vae
vae: AutoencoderKL,
num_views: int = 7,
):
super().__init__()
self.register_modules(
feature_extractor=feature_extractor,
image_encoder=image_encoder,
image_normalizer=image_normalizer,
image_noising_scheduler=image_noising_scheduler,
tokenizer=tokenizer,
text_encoder=text_encoder,
unet=unet,
scheduler=scheduler,
vae=vae,
)
self.vae_scale_factor = 2 ** (len(self.vae.config.block_out_channels) - 1)
self.image_processor = VaeImageProcessor(vae_scale_factor=self.vae_scale_factor)
self.num_views: int = num_views
# Copied from diffusers.pipelines.stable_diffusion.pipeline_stable_diffusion.StableDiffusionPipeline.enable_vae_slicing
def enable_vae_slicing(self):
r"""
Enable sliced VAE decoding.
When this option is enabled, the VAE will split the input tensor in slices to compute decoding in several
steps. This is useful to save some memory and allow larger batch sizes.
"""
self.vae.enable_slicing()
# Copied from diffusers.pipelines.stable_diffusion.pipeline_stable_diffusion.StableDiffusionPipeline.disable_vae_slicing
def disable_vae_slicing(self):
r"""
Disable sliced VAE decoding. If `enable_vae_slicing` was previously invoked, this method will go back to
computing decoding in one step.
"""
self.vae.disable_slicing()
def enable_sequential_cpu_offload(self, gpu_id=0):
r"""
Offloads all models to CPU using accelerate, significantly reducing memory usage. When called, the pipeline's
models have their state dicts saved to CPU and then are moved to a `torch.device('meta') and loaded to GPU only
when their specific submodule has its `forward` method called.
"""
if is_accelerate_available():
from accelerate import cpu_offload
else:
raise ImportError("Please install accelerate via `pip install accelerate`")
device = torch.device(f"cuda:{gpu_id}")
# TODO: self.image_normalizer.{scale,unscale} are not covered by the offload hooks, so they fails if added to the list
models = [
self.image_encoder,
self.text_encoder,
self.unet,
self.vae,
]
for cpu_offloaded_model in models:
if cpu_offloaded_model is not None:
cpu_offload(cpu_offloaded_model, device)
@property
# Copied from diffusers.pipelines.stable_diffusion.pipeline_stable_diffusion.StableDiffusionPipeline._execution_device
def _execution_device(self):
r"""
Returns the device on which the pipeline's models will be executed. After calling
`pipeline.enable_sequential_cpu_offload()` the execution device can only be inferred from Accelerate's module
hooks.
"""
if not hasattr(self.unet, "_hf_hook"):
return self.device
for module in self.unet.modules():
if (
hasattr(module, "_hf_hook")
and hasattr(module._hf_hook, "execution_device")
and module._hf_hook.execution_device is not None
):
return torch.device(module._hf_hook.execution_device)
return self.device
# Copied from diffusers.pipelines.stable_diffusion.pipeline_stable_diffusion.StableDiffusionPipeline._encode_prompt
def _encode_prompt(
self,
prompt,
device,
num_images_per_prompt,
do_classifier_free_guidance,
negative_prompt=None,
prompt_embeds: Optional[torch.FloatTensor] = None,
negative_prompt_embeds: Optional[torch.FloatTensor] = None,
lora_scale: Optional[float] = None,
):
r"""
Encodes the prompt into text encoder hidden states.
Args:
prompt (`str` or `List[str]`, *optional*):
prompt to be encoded
device: (`torch.device`):
torch device
num_images_per_prompt (`int`):
number of images that should be generated per prompt
do_classifier_free_guidance (`bool`):
whether to use classifier free guidance or not
negative_prompt (`str` or `List[str]`, *optional*):
The prompt or prompts not to guide the image generation. If not defined, one has to pass
`negative_prompt_embeds`. instead. If not defined, one has to pass `negative_prompt_embeds`. instead.
Ignored when not using guidance (i.e., ignored if `guidance_scale` is less than `1`).
prompt_embeds (`torch.FloatTensor`, *optional*):
Pre-generated text embeddings. Can be used to easily tweak text inputs, *e.g.* prompt weighting. If not
provided, text embeddings will be generated from `prompt` input argument.
negative_prompt_embeds (`torch.FloatTensor`, *optional*):
Pre-generated negative text embeddings. Can be used to easily tweak text inputs, *e.g.* prompt
weighting. If not provided, negative_prompt_embeds will be generated from `negative_prompt` input
argument.
"""
prompt_embeds = prompt_embeds.to(dtype=self.text_encoder.dtype, device=device)
if do_classifier_free_guidance:
normal_prompt_embeds, color_prompt_embeds = torch.chunk(prompt_embeds, 2, dim=0)
prompt_embeds = torch.cat([normal_prompt_embeds, normal_prompt_embeds, color_prompt_embeds, color_prompt_embeds], 0)
return prompt_embeds
def _encode_image(
self,
image_pil,
smpl_pil,
device,
num_images_per_prompt,
do_classifier_free_guidance,
noise_level: int=0,
generator: Optional[torch.Generator] = None
):
dtype = next(self.image_encoder.parameters()).dtype
# ______________________________clip image embedding______________________________
image = self.feature_extractor(images=image_pil, return_tensors="pt").pixel_values
image = image.to(device=device, dtype=dtype)
image_embeds = self.image_encoder(image).image_embeds
image_embeds = self.noise_image_embeddings(
image_embeds=image_embeds,
noise_level=noise_level,
generator=generator,
)
# duplicate image embeddings for each generation per prompt, using mps friendly method
# image_embeds = image_embeds.unsqueeze(1)
# note: the condition input is same
image_embeds = image_embeds.repeat(num_images_per_prompt, 1)
if do_classifier_free_guidance:
normal_image_embeds, color_image_embeds = torch.chunk(image_embeds, 2, dim=0)
negative_prompt_embeds = torch.zeros_like(normal_image_embeds)
# For classifier free guidance, we need to do two forward passes.
# Here we concatenate the unconditional and text embeddings into a single batch
# to avoid doing two forward passes
image_embeds = torch.cat([negative_prompt_embeds, normal_image_embeds, negative_prompt_embeds, color_image_embeds], 0)
# _____________________________vae input latents__________________________________________________
def vae_encode(tensor):
image_pt = torch.stack([TF.to_tensor(img) for img in tensor], dim=0).to(device)
image_pt = image_pt * 2.0 - 1.0
image_latents = self.vae.encode(image_pt).latent_dist.mode() * self.vae.config.scaling_factor
# Note: repeat differently from official pipelines
image_latents = image_latents.repeat(num_images_per_prompt, 1, 1, 1)
return image_latents
image_latents = vae_encode(image_pil)
if smpl_pil is not None:
smpl_latents = vae_encode(smpl_pil)
image_latents = torch.cat([image_latents, smpl_latents], 1)
if do_classifier_free_guidance:
normal_image_latents, color_image_latents = torch.chunk(image_latents, 2, dim=0)
image_latents = torch.cat([torch.zeros_like(normal_image_latents), normal_image_latents,
torch.zeros_like(color_image_latents), color_image_latents], 0)
return image_embeds, image_latents
# Copied from diffusers.pipelines.stable_diffusion.pipeline_stable_diffusion.StableDiffusionPipeline.decode_latents
def decode_latents(self, latents):
latents = 1 / self.vae.config.scaling_factor * latents
image = self.vae.decode(latents).sample
image = (image / 2 + 0.5).clamp(0, 1)
# we always cast to float32 as this does not cause significant overhead and is compatible with bfloat16
image = image.cpu().permute(0, 2, 3, 1).float().numpy()
return image
# Copied from diffusers.pipelines.stable_diffusion.pipeline_stable_diffusion.StableDiffusionPipeline.prepare_extra_step_kwargs
def prepare_extra_step_kwargs(self, generator, eta):
# prepare extra kwargs for the scheduler step, since not all schedulers have the same signature
# eta (η) is only used with the DDIMScheduler, it will be ignored for other schedulers.
# eta corresponds to η in DDIM paper: https://arxiv.org/abs/2010.02502
# and should be between [0, 1]
accepts_eta = "eta" in set(inspect.signature(self.scheduler.step).parameters.keys())
extra_step_kwargs = {}
if accepts_eta:
extra_step_kwargs["eta"] = eta
# check if the scheduler accepts generator
accepts_generator = "generator" in set(inspect.signature(self.scheduler.step).parameters.keys())
if accepts_generator:
extra_step_kwargs["generator"] = generator
return extra_step_kwargs
def check_inputs(
self,
prompt,
image,
height,
width,
callback_steps,
noise_level,
):
if height % 8 != 0 or width % 8 != 0:
raise ValueError(f"`height` and `width` have to be divisible by 8 but are {height} and {width}.")
if (callback_steps is None) or (
callback_steps is not None and (not isinstance(callback_steps, int) or callback_steps <= 0)
):
raise ValueError(
f"`callback_steps` has to be a positive integer but is {callback_steps} of type"
f" {type(callback_steps)}."
)
if prompt is not None and (not isinstance(prompt, str) and not isinstance(prompt, list)):
raise ValueError(f"`prompt` has to be of type `str` or `list` but is {type(prompt)}")
if noise_level < 0 or noise_level >= self.image_noising_scheduler.config.num_train_timesteps:
raise ValueError(
f"`noise_level` must be between 0 and {self.image_noising_scheduler.config.num_train_timesteps - 1}, inclusive."
)
# Copied from diffusers.pipelines.stable_diffusion.pipeline_stable_diffusion.StableDiffusionPipeline.prepare_latents
def prepare_latents(self, batch_size, num_channels_latents, height, width, dtype, device, generator, latents=None):
shape = (batch_size, num_channels_latents, height // self.vae_scale_factor, width // self.vae_scale_factor)
if isinstance(generator, list) and len(generator) != batch_size:
raise ValueError(
f"You have passed a list of generators of length {len(generator)}, but requested an effective batch"
f" size of {batch_size}. Make sure the batch size matches the length of the generators."
)
if latents is None:
latents = randn_tensor(shape, generator=generator, device=device, dtype=dtype)
else:
latents = latents.to(device)
# scale the initial noise by the standard deviation required by the scheduler
latents = latents * self.scheduler.init_noise_sigma
return latents
# Copied from diffusers.pipelines.stable_diffusion.pipeline_stable_unclip.StableUnCLIPPipeline.noise_image_embeddings
def noise_image_embeddings(
self,
image_embeds: torch.Tensor,
noise_level: int,
noise: Optional[torch.FloatTensor] = None,
generator: Optional[torch.Generator] = None,
):
"""
Add noise to the image embeddings. The amount of noise is controlled by a `noise_level` input. A higher
`noise_level` increases the variance in the final un-noised images.
The noise is applied in two ways
1. A noise schedule is applied directly to the embeddings
2. A vector of sinusoidal time embeddings are appended to the output.
In both cases, the amount of noise is controlled by the same `noise_level`.
The embeddings are normalized before the noise is applied and un-normalized after the noise is applied.
"""
if noise is None:
noise = randn_tensor(
image_embeds.shape, generator=generator, device=image_embeds.device, dtype=image_embeds.dtype
)
noise_level = torch.tensor([noise_level] * image_embeds.shape[0], device=image_embeds.device)
image_embeds = self.image_normalizer.scale(image_embeds)
image_embeds = self.image_noising_scheduler.add_noise(image_embeds, timesteps=noise_level, noise=noise)
image_embeds = self.image_normalizer.unscale(image_embeds)
noise_level = get_timestep_embedding(
timesteps=noise_level, embedding_dim=image_embeds.shape[-1], flip_sin_to_cos=True, downscale_freq_shift=0
)
# `get_timestep_embeddings` does not contain any weights and will always return f32 tensors,
# but we might actually be running in fp16. so we need to cast here.
# there might be better ways to encapsulate this.
noise_level = noise_level.to(image_embeds.dtype)
image_embeds = torch.cat((image_embeds, noise_level), 1)
return image_embeds
def process_dino_feature(self, feat, device, num_images_per_prompt, do_classifier_free_guidance):
feat = feat.to(dtype=self.text_encoder.dtype, device=device)
if do_classifier_free_guidance:
# # duplicate unconditional embeddings for each generation per prompt, using mps friendly method
# seq_len = negative_prompt_embeds.shape[1]
# negative_prompt_embeds = negative_prompt_embeds.to(dtype=self.text_encoder.dtype, device=device)
# negative_prompt_embeds = negative_prompt_embeds.repeat(1, num_images_per_prompt, 1)
# negative_prompt_embeds = negative_prompt_embeds.view(batch_size * num_images_per_prompt, seq_len, -1)
# For classifier free guidance, we need to do two forward passes.
# Here we concatenate the unconditional and text embeddings into a single batch
# to avoid doing two forward passes
feat = torch.cat([feat, feat], 0)
return feat
@torch.no_grad()
# @replace_example_docstring(EXAMPLE_DOC_STRING)
def __call__(
self,
image: Union[torch.FloatTensor, PIL.Image.Image],
prompt: Union[str, List[str]],
prompt_embeds: torch.FloatTensor = None,
dino_feature: torch.FloatTensor = None,
height: Optional[int] = None,
width: Optional[int] = None,
num_inference_steps: int = 20,
guidance_scale: float = 10,
negative_prompt: Optional[Union[str, List[str]]] = None,
num_images_per_prompt: Optional[int] = 1,
eta: float = 0.0,
generator: Optional[torch.Generator] = None,
latents: Optional[torch.FloatTensor] = None,
negative_prompt_embeds: Optional[torch.FloatTensor] = None,
output_type: Optional[str] = "pil",
return_dict: bool = True,
callback: Optional[Callable[[int, int, torch.FloatTensor], None]] = None,
callback_steps: int = 1,
cross_attention_kwargs: Optional[Dict[str, Any]] = None,
noise_level: int = 0,
image_embeds: Optional[torch.FloatTensor] = None,
gt_img_in: Optional[torch.FloatTensor] = None,
smpl_in: Optional[torch.FloatTensor] = None,
):
r"""
Function invoked when calling the pipeline for generation.
Args:
prompt (`str` or `List[str]`, *optional*):
The prompt or prompts to guide the image generation. If not defined, one has to pass `prompt_embeds`.
instead.
image (`torch.FloatTensor` or `PIL.Image.Image`):
`Image`, or tensor representing an image batch. The image will be encoded to its CLIP embedding which
the unet will be conditioned on. Note that the image is _not_ encoded by the vae and then used as the
latents in the denoising process such as in the standard stable diffusion text guided image variation
process.
height (`int`, *optional*, defaults to self.unet.config.sample_size * self.vae_scale_factor):
The height in pixels of the generated image.
width (`int`, *optional*, defaults to self.unet.config.sample_size * self.vae_scale_factor):
The width in pixels of the generated image.
num_inference_steps (`int`, *optional*, defaults to 20):
The number of denoising steps. More denoising steps usually lead to a higher quality image at the
expense of slower inference.
guidance_scale (`float`, *optional*, defaults to 10.0):
Guidance scale as defined in [Classifier-Free Diffusion Guidance](https://arxiv.org/abs/2207.12598).
`guidance_scale` is defined as `w` of equation 2. of [Imagen
Paper](https://arxiv.org/pdf/2205.11487.pdf). Guidance scale is enabled by setting `guidance_scale >
1`. Higher guidance scale encourages to generate images that are closely linked to the text `prompt`,
usually at the expense of lower image quality.
negative_prompt (`str` or `List[str]`, *optional*):
The prompt or prompts not to guide the image generation. If not defined, one has to pass
`negative_prompt_embeds`. instead. If not defined, one has to pass `negative_prompt_embeds`. instead.
Ignored when not using guidance (i.e., ignored if `guidance_scale` is less than `1`).
num_images_per_prompt (`int`, *optional*, defaults to 1):
The number of images to generate per prompt.
eta (`float`, *optional*, defaults to 0.0):
Corresponds to parameter eta (η) in the DDIM paper: https://arxiv.org/abs/2010.02502. Only applies to
[`schedulers.DDIMScheduler`], will be ignored for others.
generator (`torch.Generator` or `List[torch.Generator]`, *optional*):
One or a list of [torch generator(s)](https://pytorch.org/docs/stable/generated/torch.Generator.html)
to make generation deterministic.
latents (`torch.FloatTensor`, *optional*):
Pre-generated noisy latents, sampled from a Gaussian distribution, to be used as inputs for image
generation. Can be used to tweak the same generation with different prompts. If not provided, a latents
tensor will ge generated by sampling using the supplied random `generator`.
prompt_embeds (`torch.FloatTensor`, *optional*):
Pre-generated text embeddings. Can be used to easily tweak text inputs, *e.g.* prompt weighting. If not
provided, text embeddings will be generated from `prompt` input argument.
negative_prompt_embeds (`torch.FloatTensor`, *optional*):
Pre-generated negative text embeddings. Can be used to easily tweak text inputs, *e.g.* prompt
weighting. If not provided, negative_prompt_embeds will be generated from `negative_prompt` input
argument.
output_type (`str`, *optional*, defaults to `"pil"`):
The output format of the generate image. Choose between
[PIL](https://pillow.readthedocs.io/en/stable/): `PIL.Image.Image` or `np.array`.
return_dict (`bool`, *optional*, defaults to `True`):
Whether or not to return a [`~pipelines.stable_diffusion.StableDiffusionPipelineOutput`] instead of a
plain tuple.
callback (`Callable`, *optional*):
A function that will be called every `callback_steps` steps during inference. The function will be
called with the following arguments: `callback(step: int, timestep: int, latents: torch.FloatTensor)`.
callback_steps (`int`, *optional*, defaults to 1):
The frequency at which the `callback` function will be called. If not specified, the callback will be
called at every step.
cross_attention_kwargs (`dict`, *optional*):
A kwargs dictionary that if specified is passed along to the `AttnProcessor` as defined under
`self.processor` in
[diffusers.cross_attention](https://github.com/huggingface/diffusers/blob/main/src/diffusers/models/cross_attention.py).
noise_level (`int`, *optional*, defaults to `0`):
The amount of noise to add to the image embeddings. A higher `noise_level` increases the variance in
the final un-noised images. See `StableUnCLIPPipeline.noise_image_embeddings` for details.
image_embeds (`torch.FloatTensor`, *optional*):
Pre-generated CLIP embeddings to condition the unet on. Note that these are not latents to be used in
the denoising process. If you want to provide pre-generated latents, pass them to `__call__` as
`latents`.
Examples:
Returns:
[`~pipelines.ImagePipelineOutput`] or `tuple`: [`~ pipeline_utils.ImagePipelineOutput`] if `return_dict` is
True, otherwise a `tuple`. When returning a tuple, the first element is a list with the generated images.
"""
# 0. Default height and width to unet
height = height or self.unet.config.sample_size * self.vae_scale_factor
width = width or self.unet.config.sample_size * self.vae_scale_factor
# 1. Check inputs. Raise error if not correct
self.check_inputs(
prompt=prompt,
image=image,
height=height,
width=width,
callback_steps=callback_steps,
noise_level=noise_level
)
# 2. Define call parameters
if isinstance(image, list):
batch_size = len(image)
elif isinstance(image, torch.Tensor):
batch_size = image.shape[0]
assert batch_size >= self.num_views and batch_size % self.num_views == 0
elif isinstance(image, PIL.Image.Image):
image = [image]*self.num_views*2
batch_size = self.num_views*2
if isinstance(prompt, str):
prompt = [prompt] * self.num_views * 2
device = self._execution_device
# here `guidance_scale` is defined analog to the guidance weight `w` of equation (2)
# of the Imagen paper: https://arxiv.org/pdf/2205.11487.pdf . `guidance_scale = 1`
# corresponds to doing no classifier free guidance.
do_classifier_free_guidance = guidance_scale != 1.0
# 3. Encode input prompt
text_encoder_lora_scale = (
cross_attention_kwargs.get("scale", None) if cross_attention_kwargs is not None else None
)
prompt_embeds = self._encode_prompt(
prompt=prompt,
device=device,
num_images_per_prompt=num_images_per_prompt,
do_classifier_free_guidance=do_classifier_free_guidance,
negative_prompt=negative_prompt,
prompt_embeds=prompt_embeds,
negative_prompt_embeds=negative_prompt_embeds,
lora_scale=text_encoder_lora_scale,
)
if dino_feature is not None:
dino_feature = self.process_dino_feature(dino_feature, device=device,
do_classifier_free_guidance=do_classifier_free_guidance,
num_images_per_prompt=num_images_per_prompt)
# 4. Encoder input image
if isinstance(image, list):
image_pil = image
smpl_pil = smpl_in
elif isinstance(image, torch.Tensor):
image_pil = [TF.to_pil_image(image[i]) for i in range(image.shape[0])]
smpl_pil = [TF.to_pil_image(smpl_in[i]) for i in range(smpl_in.shape[0])] if smpl_in is not None else None
noise_level = torch.tensor([noise_level], device=device)
image_embeds, image_latents = self._encode_image(
image_pil=image_pil,
smpl_pil=smpl_pil,
device=device,
num_images_per_prompt=num_images_per_prompt,
do_classifier_free_guidance=do_classifier_free_guidance,
noise_level=noise_level,
generator=generator,
)
# 5. Prepare timesteps
self.scheduler.set_timesteps(num_inference_steps, device=device)
timesteps = self.scheduler.timesteps
# 6. Prepare latent variables
num_channels_latents = self.unet.config.out_channels
if gt_img_in is not None:
latents = gt_img_in * self.scheduler.init_noise_sigma
else:
latents = self.prepare_latents(
batch_size=batch_size,
num_channels_latents=num_channels_latents,
height=height,
width=width,
dtype=prompt_embeds.dtype,
device=device,
generator=generator,
latents=latents,
)
# 7. Prepare extra step kwargs. TODO: Logic should ideally just be moved out of the pipeline
extra_step_kwargs = self.prepare_extra_step_kwargs(generator, eta)
eles, focals = [], []
# 8. Denoising loop
for i, t in enumerate(self.progress_bar(timesteps)):
if do_classifier_free_guidance:
normal_latents, color_latents = torch.chunk(latents, 2, dim=0)
latent_model_input = torch.cat([normal_latents, normal_latents, color_latents, color_latents], 0)
else:
latent_model_input = latents
latent_model_input = torch.cat([
latent_model_input, image_latents
], dim=1)
latent_model_input = self.scheduler.scale_model_input(latent_model_input, t)
# predict the noise residual
unet_out = self.unet(
latent_model_input,
t,
encoder_hidden_states=prompt_embeds,
dino_feature=dino_feature,
class_labels=image_embeds,
cross_attention_kwargs=cross_attention_kwargs,
return_dict=False)
noise_pred = unet_out[0]
# perform guidance
if do_classifier_free_guidance:
normal_noise_pred_uncond, normal_noise_pred_text, color_noise_pred_uncond, color_noise_pred_text = torch.chunk(noise_pred, 4, dim=0)
noise_pred_uncond, noise_pred_text = torch.cat([normal_noise_pred_uncond, color_noise_pred_uncond], 0), torch.cat([normal_noise_pred_text, color_noise_pred_text], 0)
noise_pred = noise_pred_uncond + guidance_scale * (noise_pred_text - noise_pred_uncond)
# compute the previous noisy sample x_t -> x_t-1
latents = self.scheduler.step(noise_pred, t, latents, **extra_step_kwargs, return_dict=False)[0]
if callback is not None and i % callback_steps == 0:
callback(i, t, latents)
# 9. Post-processing
if not output_type == "latent":
if num_channels_latents == 8:
latents = torch.cat([latents[:, :4], latents[:, 4:]], dim=0)
with torch.no_grad():
image = self.vae.decode(latents / self.vae.config.scaling_factor, return_dict=False)[0]
else:
image = latents
image = self.image_processor.postprocess(image, output_type=output_type)
# Offload last model to CPU
# if hasattr(self, "final_offload_hook") and self.final_offload_hook is not None:
# self.final_offload_hook.offload()
if not return_dict:
return (image, )
return ImagePipelineOutput(images=image)