InvokeAI/invokeai/app/invocations/denoise_latents.py
2024-06-25 11:31:52 -07:00

847 lines
37 KiB
Python

# Copyright (c) 2023 Kyle Schouviller (https://github.com/kyle0654)
import inspect
from contextlib import ExitStack
from typing import Any, Dict, Iterator, List, Optional, Tuple, Union
import torch
import torchvision
import torchvision.transforms as T
from diffusers.configuration_utils import ConfigMixin
from diffusers.models.adapter import T2IAdapter
from diffusers.models.unets.unet_2d_condition import UNet2DConditionModel
from diffusers.schedulers.scheduling_dpmsolver_sde import DPMSolverSDEScheduler
from diffusers.schedulers.scheduling_tcd import TCDScheduler
from diffusers.schedulers.scheduling_utils import SchedulerMixin as Scheduler
from pydantic import field_validator
from torchvision.transforms.functional import resize as tv_resize
from transformers import CLIPVisionModelWithProjection
from invokeai.app.invocations.baseinvocation import BaseInvocation, invocation
from invokeai.app.invocations.constants import LATENT_SCALE_FACTOR, SCHEDULER_NAME_VALUES
from invokeai.app.invocations.controlnet_image_processors import ControlField
from invokeai.app.invocations.fields import (
ConditioningField,
DenoiseMaskField,
FieldDescriptions,
Input,
InputField,
LatentsField,
UIType,
)
from invokeai.app.invocations.ip_adapter import IPAdapterField
from invokeai.app.invocations.model import ModelIdentifierField, UNetField
from invokeai.app.invocations.primitives import LatentsOutput
from invokeai.app.invocations.t2i_adapter import T2IAdapterField
from invokeai.app.services.shared.invocation_context import InvocationContext
from invokeai.app.util.controlnet_utils import prepare_control_image
from invokeai.backend.ip_adapter.ip_adapter import IPAdapter
from invokeai.backend.lora import LoRAModelRaw
from invokeai.backend.model_manager import BaseModelType
from invokeai.backend.model_patcher import ModelPatcher
from invokeai.backend.stable_diffusion import PipelineIntermediateState, set_seamless
from invokeai.backend.stable_diffusion.diffusers_pipeline import (
ControlNetData,
StableDiffusionGeneratorPipeline,
T2IAdapterData,
)
from invokeai.backend.stable_diffusion.diffusion.conditioning_data import (
BasicConditioningInfo,
IPAdapterConditioningInfo,
IPAdapterData,
Range,
SDXLConditioningInfo,
TextConditioningData,
TextConditioningRegions,
)
from invokeai.backend.stable_diffusion.schedulers import SCHEDULER_MAP
from invokeai.backend.util.devices import TorchDevice
from invokeai.backend.util.hotfixes import ControlNetModel
from invokeai.backend.util.mask import to_standard_float_mask
from invokeai.backend.util.silence_warnings import SilenceWarnings
def get_scheduler(
context: InvocationContext,
scheduler_info: ModelIdentifierField,
scheduler_name: str,
seed: int,
) -> Scheduler:
"""Load a scheduler and apply some scheduler-specific overrides."""
# TODO(ryand): Silently falling back to ddim seems like a bad idea. Look into why this was added and remove if
# possible.
scheduler_class, scheduler_extra_config = SCHEDULER_MAP.get(scheduler_name, SCHEDULER_MAP["ddim"])
orig_scheduler_info = context.models.load(scheduler_info)
with orig_scheduler_info as orig_scheduler:
scheduler_config = orig_scheduler.config
if "_backup" in scheduler_config:
scheduler_config = scheduler_config["_backup"]
scheduler_config = {
**scheduler_config,
**scheduler_extra_config, # FIXME
"_backup": scheduler_config,
}
# make dpmpp_sde reproducable(seed can be passed only in initializer)
if scheduler_class is DPMSolverSDEScheduler:
scheduler_config["noise_sampler_seed"] = seed
scheduler = scheduler_class.from_config(scheduler_config)
# hack copied over from generate.py
if not hasattr(scheduler, "uses_inpainting_model"):
scheduler.uses_inpainting_model = lambda: False
assert isinstance(scheduler, Scheduler)
return scheduler
@invocation(
"denoise_latents",
title="Denoise Latents",
tags=["latents", "denoise", "txt2img", "t2i", "t2l", "img2img", "i2i", "l2l"],
category="latents",
version="1.5.3",
)
class DenoiseLatentsInvocation(BaseInvocation):
"""Denoises noisy latents to decodable images"""
positive_conditioning: Union[ConditioningField, list[ConditioningField]] = InputField(
description=FieldDescriptions.positive_cond, input=Input.Connection, ui_order=0
)
negative_conditioning: Union[ConditioningField, list[ConditioningField]] = InputField(
description=FieldDescriptions.negative_cond, input=Input.Connection, ui_order=1
)
noise: Optional[LatentsField] = InputField(
default=None,
description=FieldDescriptions.noise,
input=Input.Connection,
ui_order=3,
)
steps: int = InputField(default=10, gt=0, description=FieldDescriptions.steps)
cfg_scale: Union[float, List[float]] = InputField(
default=7.5, description=FieldDescriptions.cfg_scale, title="CFG Scale"
)
denoising_start: float = InputField(
default=0.0,
ge=0,
le=1,
description=FieldDescriptions.denoising_start,
)
denoising_end: float = InputField(default=1.0, ge=0, le=1, description=FieldDescriptions.denoising_end)
scheduler: SCHEDULER_NAME_VALUES = InputField(
default="euler",
description=FieldDescriptions.scheduler,
ui_type=UIType.Scheduler,
)
unet: UNetField = InputField(
description=FieldDescriptions.unet,
input=Input.Connection,
title="UNet",
ui_order=2,
)
control: Optional[Union[ControlField, list[ControlField]]] = InputField(
default=None,
input=Input.Connection,
ui_order=5,
)
ip_adapter: Optional[Union[IPAdapterField, list[IPAdapterField]]] = InputField(
description=FieldDescriptions.ip_adapter,
title="IP-Adapter",
default=None,
input=Input.Connection,
ui_order=6,
)
t2i_adapter: Optional[Union[T2IAdapterField, list[T2IAdapterField]]] = InputField(
description=FieldDescriptions.t2i_adapter,
title="T2I-Adapter",
default=None,
input=Input.Connection,
ui_order=7,
)
cfg_rescale_multiplier: float = InputField(
title="CFG Rescale Multiplier", default=0, ge=0, lt=1, description=FieldDescriptions.cfg_rescale_multiplier
)
latents: Optional[LatentsField] = InputField(
default=None,
description=FieldDescriptions.latents,
input=Input.Connection,
ui_order=4,
)
denoise_mask: Optional[DenoiseMaskField] = InputField(
default=None,
description=FieldDescriptions.mask,
input=Input.Connection,
ui_order=8,
)
@field_validator("cfg_scale")
def ge_one(cls, v: Union[List[float], float]) -> Union[List[float], float]:
"""validate that all cfg_scale values are >= 1"""
if isinstance(v, list):
for i in v:
if i < 1:
raise ValueError("cfg_scale must be greater than 1")
else:
if v < 1:
raise ValueError("cfg_scale must be greater than 1")
return v
@staticmethod
def _get_text_embeddings_and_masks(
cond_list: list[ConditioningField],
context: InvocationContext,
device: torch.device,
dtype: torch.dtype,
) -> tuple[Union[list[BasicConditioningInfo], list[SDXLConditioningInfo]], list[Optional[torch.Tensor]]]:
"""Get the text embeddings and masks from the input conditioning fields."""
text_embeddings: Union[list[BasicConditioningInfo], list[SDXLConditioningInfo]] = []
text_embeddings_masks: list[Optional[torch.Tensor]] = []
for cond in cond_list:
cond_data = context.conditioning.load(cond.conditioning_name)
text_embeddings.append(cond_data.conditionings[0].to(device=device, dtype=dtype))
mask = cond.mask
if mask is not None:
mask = context.tensors.load(mask.tensor_name)
text_embeddings_masks.append(mask)
return text_embeddings, text_embeddings_masks
@staticmethod
def _preprocess_regional_prompt_mask(
mask: Optional[torch.Tensor], target_height: int, target_width: int, dtype: torch.dtype
) -> torch.Tensor:
"""Preprocess a regional prompt mask to match the target height and width.
If mask is None, returns a mask of all ones with the target height and width.
If mask is not None, resizes the mask to the target height and width using 'nearest' interpolation.
Returns:
torch.Tensor: The processed mask. shape: (1, 1, target_height, target_width).
"""
if mask is None:
return torch.ones((1, 1, target_height, target_width), dtype=dtype)
mask = to_standard_float_mask(mask, out_dtype=dtype)
tf = torchvision.transforms.Resize(
(target_height, target_width), interpolation=torchvision.transforms.InterpolationMode.NEAREST
)
# Add a batch dimension to the mask, because torchvision expects shape (batch, channels, h, w).
mask = mask.unsqueeze(0) # Shape: (1, h, w) -> (1, 1, h, w)
resized_mask = tf(mask)
return resized_mask
@staticmethod
def _concat_regional_text_embeddings(
text_conditionings: Union[list[BasicConditioningInfo], list[SDXLConditioningInfo]],
masks: Optional[list[Optional[torch.Tensor]]],
latent_height: int,
latent_width: int,
dtype: torch.dtype,
) -> tuple[Union[BasicConditioningInfo, SDXLConditioningInfo], Optional[TextConditioningRegions]]:
"""Concatenate regional text embeddings into a single embedding and track the region masks accordingly."""
if masks is None:
masks = [None] * len(text_conditionings)
assert len(text_conditionings) == len(masks)
is_sdxl = type(text_conditionings[0]) is SDXLConditioningInfo
all_masks_are_none = all(mask is None for mask in masks)
text_embedding = []
pooled_embedding = None
add_time_ids = None
cur_text_embedding_len = 0
processed_masks = []
embedding_ranges = []
for prompt_idx, text_embedding_info in enumerate(text_conditionings):
mask = masks[prompt_idx]
if is_sdxl:
# We choose a random SDXLConditioningInfo's pooled_embeds and add_time_ids here, with a preference for
# prompts without a mask. We prefer prompts without a mask, because they are more likely to contain
# global prompt information. In an ideal case, there should be exactly one global prompt without a
# mask, but we don't enforce this.
# HACK(ryand): The fact that we have to choose a single pooled_embedding and add_time_ids here is a
# fundamental interface issue. The SDXL Compel nodes are not designed to be used in the way that we use
# them for regional prompting. Ideally, the DenoiseLatents invocation should accept a single
# pooled_embeds tensor and a list of standard text embeds with region masks. This change would be a
# pretty major breaking change to a popular node, so for now we use this hack.
if pooled_embedding is None or mask is None:
pooled_embedding = text_embedding_info.pooled_embeds
if add_time_ids is None or mask is None:
add_time_ids = text_embedding_info.add_time_ids
text_embedding.append(text_embedding_info.embeds)
if not all_masks_are_none:
embedding_ranges.append(
Range(
start=cur_text_embedding_len, end=cur_text_embedding_len + text_embedding_info.embeds.shape[1]
)
)
processed_masks.append(
DenoiseLatentsInvocation._preprocess_regional_prompt_mask(
mask, latent_height, latent_width, dtype=dtype
)
)
cur_text_embedding_len += text_embedding_info.embeds.shape[1]
text_embedding = torch.cat(text_embedding, dim=1)
assert len(text_embedding.shape) == 3 # batch_size, seq_len, token_len
regions = None
if not all_masks_are_none:
regions = TextConditioningRegions(
masks=torch.cat(processed_masks, dim=1),
ranges=embedding_ranges,
)
if is_sdxl:
return (
SDXLConditioningInfo(embeds=text_embedding, pooled_embeds=pooled_embedding, add_time_ids=add_time_ids),
regions,
)
return BasicConditioningInfo(embeds=text_embedding), regions
@staticmethod
def get_conditioning_data(
context: InvocationContext,
positive_conditioning_field: Union[ConditioningField, list[ConditioningField]],
negative_conditioning_field: Union[ConditioningField, list[ConditioningField]],
unet: UNet2DConditionModel,
latent_height: int,
latent_width: int,
cfg_scale: float | list[float],
steps: int,
cfg_rescale_multiplier: float,
) -> TextConditioningData:
# Normalize positive_conditioning_field and negative_conditioning_field to lists.
cond_list = positive_conditioning_field
if not isinstance(cond_list, list):
cond_list = [cond_list]
uncond_list = negative_conditioning_field
if not isinstance(uncond_list, list):
uncond_list = [uncond_list]
cond_text_embeddings, cond_text_embedding_masks = DenoiseLatentsInvocation._get_text_embeddings_and_masks(
cond_list, context, unet.device, unet.dtype
)
uncond_text_embeddings, uncond_text_embedding_masks = DenoiseLatentsInvocation._get_text_embeddings_and_masks(
uncond_list, context, unet.device, unet.dtype
)
cond_text_embedding, cond_regions = DenoiseLatentsInvocation._concat_regional_text_embeddings(
text_conditionings=cond_text_embeddings,
masks=cond_text_embedding_masks,
latent_height=latent_height,
latent_width=latent_width,
dtype=unet.dtype,
)
uncond_text_embedding, uncond_regions = DenoiseLatentsInvocation._concat_regional_text_embeddings(
text_conditionings=uncond_text_embeddings,
masks=uncond_text_embedding_masks,
latent_height=latent_height,
latent_width=latent_width,
dtype=unet.dtype,
)
if isinstance(cfg_scale, list):
assert len(cfg_scale) == steps, "cfg_scale (list) must have the same length as the number of steps"
conditioning_data = TextConditioningData(
uncond_text=uncond_text_embedding,
cond_text=cond_text_embedding,
uncond_regions=uncond_regions,
cond_regions=cond_regions,
guidance_scale=cfg_scale,
guidance_rescale_multiplier=cfg_rescale_multiplier,
)
return conditioning_data
@staticmethod
def create_pipeline(
unet: UNet2DConditionModel,
scheduler: Scheduler,
) -> StableDiffusionGeneratorPipeline:
class FakeVae:
class FakeVaeConfig:
def __init__(self) -> None:
self.block_out_channels = [0]
def __init__(self) -> None:
self.config = FakeVae.FakeVaeConfig()
return StableDiffusionGeneratorPipeline(
vae=FakeVae(), # TODO: oh...
text_encoder=None,
tokenizer=None,
unet=unet,
scheduler=scheduler,
safety_checker=None,
feature_extractor=None,
requires_safety_checker=False,
)
@staticmethod
def prep_control_data(
context: InvocationContext,
control_input: ControlField | list[ControlField] | None,
latents_shape: List[int],
exit_stack: ExitStack,
do_classifier_free_guidance: bool = True,
) -> list[ControlNetData] | None:
# Normalize control_input to a list.
control_list: list[ControlField]
if isinstance(control_input, ControlField):
control_list = [control_input]
elif isinstance(control_input, list):
control_list = control_input
elif control_input is None:
control_list = []
else:
raise ValueError(f"Unexpected control_input type: {type(control_input)}")
if len(control_list) == 0:
return None
# Assuming fixed dimensional scaling of LATENT_SCALE_FACTOR.
_, _, latent_height, latent_width = latents_shape
control_height_resize = latent_height * LATENT_SCALE_FACTOR
control_width_resize = latent_width * LATENT_SCALE_FACTOR
controlnet_data: list[ControlNetData] = []
for control_info in control_list:
control_model = exit_stack.enter_context(context.models.load(control_info.control_model))
assert isinstance(control_model, ControlNetModel)
control_image_field = control_info.image
input_image = context.images.get_pil(control_image_field.image_name)
# self.image.image_type, self.image.image_name
# FIXME: still need to test with different widths, heights, devices, dtypes
# and add in batch_size, num_images_per_prompt?
# and do real check for classifier_free_guidance?
# prepare_control_image should return torch.Tensor of shape(batch_size, 3, height, width)
control_image = prepare_control_image(
image=input_image,
do_classifier_free_guidance=do_classifier_free_guidance,
width=control_width_resize,
height=control_height_resize,
# batch_size=batch_size * num_images_per_prompt,
# num_images_per_prompt=num_images_per_prompt,
device=control_model.device,
dtype=control_model.dtype,
control_mode=control_info.control_mode,
resize_mode=control_info.resize_mode,
)
control_item = ControlNetData(
model=control_model,
image_tensor=control_image,
weight=control_info.control_weight,
begin_step_percent=control_info.begin_step_percent,
end_step_percent=control_info.end_step_percent,
control_mode=control_info.control_mode,
# any resizing needed should currently be happening in prepare_control_image(),
# but adding resize_mode to ControlNetData in case needed in the future
resize_mode=control_info.resize_mode,
)
controlnet_data.append(control_item)
# MultiControlNetModel has been refactored out, just need list[ControlNetData]
return controlnet_data
def prep_ip_adapter_image_prompts(
self,
context: InvocationContext,
ip_adapters: List[IPAdapterField],
) -> List[Tuple[torch.Tensor, torch.Tensor]]:
"""Run the IPAdapter CLIPVisionModel, returning image prompt embeddings."""
image_prompts = []
for single_ip_adapter in ip_adapters:
with context.models.load(single_ip_adapter.ip_adapter_model) as ip_adapter_model:
assert isinstance(ip_adapter_model, IPAdapter)
image_encoder_model_info = context.models.load(single_ip_adapter.image_encoder_model)
# `single_ip_adapter.image` could be a list or a single ImageField. Normalize to a list here.
single_ipa_image_fields = single_ip_adapter.image
if not isinstance(single_ipa_image_fields, list):
single_ipa_image_fields = [single_ipa_image_fields]
single_ipa_images = [context.images.get_pil(image.image_name) for image in single_ipa_image_fields]
with image_encoder_model_info as image_encoder_model:
assert isinstance(image_encoder_model, CLIPVisionModelWithProjection)
# Get image embeddings from CLIP and ImageProjModel.
image_prompt_embeds, uncond_image_prompt_embeds = ip_adapter_model.get_image_embeds(
single_ipa_images, image_encoder_model
)
image_prompts.append((image_prompt_embeds, uncond_image_prompt_embeds))
return image_prompts
def prep_ip_adapter_data(
self,
context: InvocationContext,
ip_adapters: List[IPAdapterField],
image_prompts: List[Tuple[torch.Tensor, torch.Tensor]],
exit_stack: ExitStack,
latent_height: int,
latent_width: int,
dtype: torch.dtype,
) -> Optional[List[IPAdapterData]]:
"""If IP-Adapter is enabled, then this function loads the requisite models and adds the image prompt conditioning data."""
ip_adapter_data_list = []
for single_ip_adapter, (image_prompt_embeds, uncond_image_prompt_embeds) in zip(
ip_adapters, image_prompts, strict=True
):
ip_adapter_model = exit_stack.enter_context(context.models.load(single_ip_adapter.ip_adapter_model))
mask_field = single_ip_adapter.mask
mask = context.tensors.load(mask_field.tensor_name) if mask_field is not None else None
mask = self._preprocess_regional_prompt_mask(mask, latent_height, latent_width, dtype=dtype)
ip_adapter_data_list.append(
IPAdapterData(
ip_adapter_model=ip_adapter_model,
weight=single_ip_adapter.weight,
target_blocks=single_ip_adapter.target_blocks,
begin_step_percent=single_ip_adapter.begin_step_percent,
end_step_percent=single_ip_adapter.end_step_percent,
ip_adapter_conditioning=IPAdapterConditioningInfo(image_prompt_embeds, uncond_image_prompt_embeds),
mask=mask,
)
)
return ip_adapter_data_list if len(ip_adapter_data_list) > 0 else None
def run_t2i_adapters(
self,
context: InvocationContext,
t2i_adapter: Optional[Union[T2IAdapterField, list[T2IAdapterField]]],
latents_shape: list[int],
do_classifier_free_guidance: bool,
) -> Optional[list[T2IAdapterData]]:
if t2i_adapter is None:
return None
# Handle the possibility that t2i_adapter could be a list or a single T2IAdapterField.
if isinstance(t2i_adapter, T2IAdapterField):
t2i_adapter = [t2i_adapter]
if len(t2i_adapter) == 0:
return None
t2i_adapter_data = []
for t2i_adapter_field in t2i_adapter:
t2i_adapter_model_config = context.models.get_config(t2i_adapter_field.t2i_adapter_model.key)
t2i_adapter_loaded_model = context.models.load(t2i_adapter_field.t2i_adapter_model)
image = context.images.get_pil(t2i_adapter_field.image.image_name)
# The max_unet_downscale is the maximum amount that the UNet model downscales the latent image internally.
if t2i_adapter_model_config.base == BaseModelType.StableDiffusion1:
max_unet_downscale = 8
elif t2i_adapter_model_config.base == BaseModelType.StableDiffusionXL:
max_unet_downscale = 4
else:
raise ValueError(f"Unexpected T2I-Adapter base model type: '{t2i_adapter_model_config.base}'.")
t2i_adapter_model: T2IAdapter
with t2i_adapter_loaded_model as t2i_adapter_model:
total_downscale_factor = t2i_adapter_model.total_downscale_factor
# Resize the T2I-Adapter input image.
# We select the resize dimensions so that after the T2I-Adapter's total_downscale_factor is applied, the
# result will match the latent image's dimensions after max_unet_downscale is applied.
t2i_input_height = latents_shape[2] // max_unet_downscale * total_downscale_factor
t2i_input_width = latents_shape[3] // max_unet_downscale * total_downscale_factor
# Note: We have hard-coded `do_classifier_free_guidance=False`. This is because we only want to prepare
# a single image. If CFG is enabled, we will duplicate the resultant tensor after applying the
# T2I-Adapter model.
#
# Note: We re-use the `prepare_control_image(...)` from ControlNet for T2I-Adapter, because it has many
# of the same requirements (e.g. preserving binary masks during resize).
t2i_image = prepare_control_image(
image=image,
do_classifier_free_guidance=False,
width=t2i_input_width,
height=t2i_input_height,
num_channels=t2i_adapter_model.config["in_channels"], # mypy treats this as a FrozenDict
device=t2i_adapter_model.device,
dtype=t2i_adapter_model.dtype,
resize_mode=t2i_adapter_field.resize_mode,
)
adapter_state = t2i_adapter_model(t2i_image)
if do_classifier_free_guidance:
for idx, value in enumerate(adapter_state):
adapter_state[idx] = torch.cat([value] * 2, dim=0)
t2i_adapter_data.append(
T2IAdapterData(
adapter_state=adapter_state,
weight=t2i_adapter_field.weight,
begin_step_percent=t2i_adapter_field.begin_step_percent,
end_step_percent=t2i_adapter_field.end_step_percent,
)
)
return t2i_adapter_data
# original idea by https://github.com/AmericanPresidentJimmyCarter
# TODO: research more for second order schedulers timesteps
@staticmethod
def init_scheduler(
scheduler: Union[Scheduler, ConfigMixin],
device: torch.device,
steps: int,
denoising_start: float,
denoising_end: float,
seed: int,
) -> Tuple[torch.Tensor, torch.Tensor, Dict[str, Any]]:
assert isinstance(scheduler, ConfigMixin)
if scheduler.config.get("cpu_only", False):
scheduler.set_timesteps(steps, device="cpu")
timesteps = scheduler.timesteps.to(device=device)
else:
scheduler.set_timesteps(steps, device=device)
timesteps = scheduler.timesteps
# skip greater order timesteps
_timesteps = timesteps[:: scheduler.order]
# get start timestep index
t_start_val = int(round(scheduler.config["num_train_timesteps"] * (1 - denoising_start)))
t_start_idx = len(list(filter(lambda ts: ts >= t_start_val, _timesteps)))
# get end timestep index
t_end_val = int(round(scheduler.config["num_train_timesteps"] * (1 - denoising_end)))
t_end_idx = len(list(filter(lambda ts: ts >= t_end_val, _timesteps[t_start_idx:])))
# apply order to indexes
t_start_idx *= scheduler.order
t_end_idx *= scheduler.order
timesteps = timesteps[t_start_idx : t_start_idx + t_end_idx]
scheduler_step_kwargs: Dict[str, Any] = {}
scheduler_step_signature = inspect.signature(scheduler.step)
if "generator" in scheduler_step_signature.parameters:
# At some point, someone decided that schedulers that accept a generator should use the original seed with
# all bits flipped. I don't know the original rationale for this, but now we must keep it like this for
# reproducibility.
#
# These Invoke-supported schedulers accept a generator as of 2024-06-04:
# - DDIMScheduler
# - DDPMScheduler
# - DPMSolverMultistepScheduler
# - EulerAncestralDiscreteScheduler
# - EulerDiscreteScheduler
# - KDPM2AncestralDiscreteScheduler
# - LCMScheduler
# - TCDScheduler
scheduler_step_kwargs.update({"generator": torch.Generator(device=device).manual_seed(seed ^ 0xFFFFFFFF)})
if isinstance(scheduler, TCDScheduler):
scheduler_step_kwargs.update({"eta": 1.0})
return timesteps, scheduler_step_kwargs
def prep_inpaint_mask(
self, context: InvocationContext, latents: torch.Tensor
) -> Tuple[Optional[torch.Tensor], Optional[torch.Tensor], bool]:
if self.denoise_mask is None:
return None, None, False
mask = context.tensors.load(self.denoise_mask.mask_name)
mask = tv_resize(mask, latents.shape[-2:], T.InterpolationMode.BILINEAR, antialias=False)
if self.denoise_mask.masked_latents_name is not None:
masked_latents = context.tensors.load(self.denoise_mask.masked_latents_name)
else:
masked_latents = torch.where(mask < 0.5, 0.0, latents)
return 1 - mask, masked_latents, self.denoise_mask.gradient
@staticmethod
def prepare_noise_and_latents(
context: InvocationContext, noise_field: LatentsField | None, latents_field: LatentsField | None
) -> Tuple[int, torch.Tensor | None, torch.Tensor]:
"""Depending on the workflow, we expect different combinations of noise and latents to be provided. This
function handles preparing these values accordingly.
Expected workflows:
- Text-to-Image Denoising: `noise` is provided, `latents` is not. `latents` is initialized to zeros.
- Image-to-Image Denoising: `noise` and `latents` are both provided.
- Text-to-Image SDXL Refiner Denoising: `latents` is provided, `noise` is not.
- Image-to-Image SDXL Refiner Denoising: `latents` is provided, `noise` is not.
NOTE(ryand): I wrote this docstring, but I am not the original author of this code. There may be other workflows
I haven't considered.
"""
noise = None
if noise_field is not None:
noise = context.tensors.load(noise_field.latents_name)
if latents_field is not None:
latents = context.tensors.load(latents_field.latents_name)
elif noise is not None:
latents = torch.zeros_like(noise)
else:
raise ValueError("'latents' or 'noise' must be provided!")
if noise is not None and noise.shape[1:] != latents.shape[1:]:
raise ValueError(f"Incompatible 'noise' and 'latents' shapes: {latents.shape=} {noise.shape=}")
# The seed comes from (in order of priority): the noise field, the latents field, or 0.
seed = 0
if noise_field is not None and noise_field.seed is not None:
seed = noise_field.seed
elif latents_field is not None and latents_field.seed is not None:
seed = latents_field.seed
else:
seed = 0
return seed, noise, latents
@torch.no_grad()
@SilenceWarnings() # This quenches the NSFW nag from diffusers.
def invoke(self, context: InvocationContext) -> LatentsOutput:
seed, noise, latents = self.prepare_noise_and_latents(context, self.noise, self.latents)
mask, masked_latents, gradient_mask = self.prep_inpaint_mask(context, latents)
# TODO(ryand): I have hard-coded `do_classifier_free_guidance=True` to mirror the behaviour of ControlNets,
# below. Investigate whether this is appropriate.
t2i_adapter_data = self.run_t2i_adapters(
context,
self.t2i_adapter,
latents.shape,
do_classifier_free_guidance=True,
)
ip_adapters: List[IPAdapterField] = []
if self.ip_adapter is not None:
# ip_adapter could be a list or a single IPAdapterField. Normalize to a list here.
if isinstance(self.ip_adapter, list):
ip_adapters = self.ip_adapter
else:
ip_adapters = [self.ip_adapter]
# If there are IP adapters, the following line runs the adapters' CLIPVision image encoders to return
# a series of image conditioning embeddings. This is being done here rather than in the
# big model context below in order to use less VRAM on low-VRAM systems.
# The image prompts are then passed to prep_ip_adapter_data().
image_prompts = self.prep_ip_adapter_image_prompts(context=context, ip_adapters=ip_adapters)
# get the unet's config so that we can pass the base to sd_step_callback()
unet_config = context.models.get_config(self.unet.unet.key)
def step_callback(state: PipelineIntermediateState) -> None:
context.util.sd_step_callback(state, unet_config.base)
def _lora_loader() -> Iterator[Tuple[LoRAModelRaw, float]]:
for lora in self.unet.loras:
lora_info = context.models.load(lora.lora)
assert isinstance(lora_info.model, LoRAModelRaw)
yield (lora_info.model, lora.weight)
del lora_info
return
unet_info = context.models.load(self.unet.unet)
assert isinstance(unet_info.model, UNet2DConditionModel)
with (
ExitStack() as exit_stack,
unet_info.model_on_device() as (model_state_dict, unet),
ModelPatcher.apply_freeu(unet, self.unet.freeu_config),
set_seamless(unet, self.unet.seamless_axes), # FIXME
# Apply the LoRA after unet has been moved to its target device for faster patching.
ModelPatcher.apply_lora_unet(
unet,
loras=_lora_loader(),
model_state_dict=model_state_dict,
),
):
assert isinstance(unet, UNet2DConditionModel)
latents = latents.to(device=unet.device, dtype=unet.dtype)
if noise is not None:
noise = noise.to(device=unet.device, dtype=unet.dtype)
if mask is not None:
mask = mask.to(device=unet.device, dtype=unet.dtype)
if masked_latents is not None:
masked_latents = masked_latents.to(device=unet.device, dtype=unet.dtype)
scheduler = get_scheduler(
context=context,
scheduler_info=self.unet.scheduler,
scheduler_name=self.scheduler,
seed=seed,
)
pipeline = self.create_pipeline(unet, scheduler)
_, _, latent_height, latent_width = latents.shape
conditioning_data = self.get_conditioning_data(
context=context,
positive_conditioning_field=self.positive_conditioning,
negative_conditioning_field=self.negative_conditioning,
unet=unet,
latent_height=latent_height,
latent_width=latent_width,
cfg_scale=self.cfg_scale,
steps=self.steps,
cfg_rescale_multiplier=self.cfg_rescale_multiplier,
)
controlnet_data = self.prep_control_data(
context=context,
control_input=self.control,
latents_shape=latents.shape,
# do_classifier_free_guidance=(self.cfg_scale >= 1.0))
do_classifier_free_guidance=True,
exit_stack=exit_stack,
)
ip_adapter_data = self.prep_ip_adapter_data(
context=context,
ip_adapters=ip_adapters,
image_prompts=image_prompts,
exit_stack=exit_stack,
latent_height=latent_height,
latent_width=latent_width,
dtype=unet.dtype,
)
timesteps, scheduler_step_kwargs = self.init_scheduler(
scheduler,
device=unet.device,
steps=self.steps,
denoising_start=self.denoising_start,
denoising_end=self.denoising_end,
seed=seed,
)
result_latents = pipeline.latents_from_embeddings(
latents=latents,
timesteps=timesteps,
noise=noise,
seed=seed,
mask=mask,
masked_latents=masked_latents,
is_gradient_mask=gradient_mask,
scheduler_step_kwargs=scheduler_step_kwargs,
conditioning_data=conditioning_data,
control_data=controlnet_data,
ip_adapter_data=ip_adapter_data,
t2i_adapter_data=t2i_adapter_data,
callback=step_callback,
)
# https://discuss.huggingface.co/t/memory-usage-by-later-pipeline-stages/23699
result_latents = result_latents.to("cpu")
TorchDevice.empty_cache()
name = context.tensors.save(tensor=result_latents)
return LatentsOutput.build(latents_name=name, latents=result_latents, seed=None)