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CapsAdmin/IPAdapterPlus.py

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replace comfyui/custom_nodes/ComfyUI_IPAdapter_plus/IPAdapterPlus.py
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IPAdapterPlus.py
import torch
import contextlib
import os
import math
import comfy.utils
import comfy.model_management
from comfy.clip_vision import clip_preprocess
from comfy.ldm.modules.attention import optimized_attention
import folder_paths
from torch import nn
from PIL import Image
import torch.nn.functional as F
import torchvision.transforms as TT
from .resampler import Resampler
# set the models directory backward compatible
GLOBAL_MODELS_DIR = os.path.join(folder_paths.models_dir, "ipadapter")
MODELS_DIR = GLOBAL_MODELS_DIR if os.path.isdir(GLOBAL_MODELS_DIR) else os.path.join(os.path.dirname(os.path.realpath(__file__)), "models")
if "ipadapter" not in folder_paths.folder_names_and_paths:
folder_paths.folder_names_and_paths["ipadapter"] = ([MODELS_DIR], folder_paths.supported_pt_extensions)
else:
folder_paths.folder_names_and_paths["ipadapter"][1].update(folder_paths.supported_pt_extensions)
class MLPProjModel(torch.nn.Module):
"""SD model with image prompt"""
def __init__(self, cross_attention_dim=1024, clip_embeddings_dim=1024):
super().__init__()
self.proj = torch.nn.Sequential(
torch.nn.Linear(clip_embeddings_dim, clip_embeddings_dim),
torch.nn.GELU(),
torch.nn.Linear(clip_embeddings_dim, cross_attention_dim),
torch.nn.LayerNorm(cross_attention_dim)
)
def forward(self, image_embeds):
clip_extra_context_tokens = self.proj(image_embeds)
return clip_extra_context_tokens
class ImageProjModel(nn.Module):
def __init__(self, cross_attention_dim=1024, clip_embeddings_dim=1024, clip_extra_context_tokens=4):
super().__init__()
self.cross_attention_dim = cross_attention_dim
self.clip_extra_context_tokens = clip_extra_context_tokens
self.proj = nn.Linear(clip_embeddings_dim, self.clip_extra_context_tokens * cross_attention_dim)
self.norm = nn.LayerNorm(cross_attention_dim)
def forward(self, image_embeds):
embeds = image_embeds
clip_extra_context_tokens = self.proj(embeds).reshape(-1, self.clip_extra_context_tokens, self.cross_attention_dim)
clip_extra_context_tokens = self.norm(clip_extra_context_tokens)
return clip_extra_context_tokens
class To_KV(nn.Module):
def __init__(self, state_dict):
super().__init__()
self.to_kvs = nn.ModuleDict()
for key, value in state_dict.items():
self.to_kvs[key.replace(".weight", "").replace(".", "_")] = nn.Linear(value.shape[1], value.shape[0], bias=False)
self.to_kvs[key.replace(".weight", "").replace(".", "_")].weight.data = value
def set_model_patch_replace(model, patch_kwargs, key):
to = model.model_options["transformer_options"]
if "patches_replace" not in to:
to["patches_replace"] = {}
if "attn2" not in to["patches_replace"]:
to["patches_replace"]["attn2"] = {}
if key not in to["patches_replace"]["attn2"]:
patch = CrossAttentionPatch(**patch_kwargs)
to["patches_replace"]["attn2"][key] = patch
else:
to["patches_replace"]["attn2"][key].set_new_condition(**patch_kwargs)
def image_add_noise(image, noise):
image = image.permute([0,3,1,2])
torch.manual_seed(0) # use a fixed random for reproducible results
transforms = TT.Compose([
TT.CenterCrop(min(image.shape[2], image.shape[3])),
TT.Resize((224, 224), interpolation=TT.InterpolationMode.BICUBIC, antialias=True),
TT.ElasticTransform(alpha=75.0, sigma=noise*3.5), # shuffle the image
TT.RandomVerticalFlip(p=1.0), # flip the image to change the geometry even more
TT.RandomHorizontalFlip(p=1.0),
])
image = transforms(image.cpu())
image = image.permute([0,2,3,1])
image = image + ((0.25*(1-noise)+0.05) * torch.randn_like(image) ) # add further random noise
return image
def zeroed_hidden_states(clip_vision, batch_size):
image = torch.zeros([batch_size, 224, 224, 3])
comfy.model_management.load_model_gpu(clip_vision.patcher)
pixel_values = clip_preprocess(image.to(clip_vision.load_device))
if clip_vision.dtype != torch.float32:
precision_scope = torch.autocast
else:
precision_scope = lambda a, b: contextlib.nullcontext(a)
with precision_scope(comfy.model_management.get_autocast_device(clip_vision.load_device), torch.float32):
outputs = clip_vision.model(pixel_values, intermediate_output=-2)
# we only need the penultimate hidden states
outputs = outputs[1].to(comfy.model_management.intermediate_device())
return outputs
def min_(tensor_list):
# return the element-wise min of the tensor list.
x = torch.stack(tensor_list)
mn = x.min(axis=0)[0]
return torch.clamp(mn, min=0)
def max_(tensor_list):
# return the element-wise max of the tensor list.
x = torch.stack(tensor_list)
mx = x.max(axis=0)[0]
return torch.clamp(mx, max=1)
# From https://github.com/Jamy-L/Pytorch-Contrast-Adaptive-Sharpening/
def contrast_adaptive_sharpening(image, amount):
img = F.pad(image, pad=(1, 1, 1, 1)).cpu()
a = img[..., :-2, :-2]
b = img[..., :-2, 1:-1]
c = img[..., :-2, 2:]
d = img[..., 1:-1, :-2]
e = img[..., 1:-1, 1:-1]
f = img[..., 1:-1, 2:]
g = img[..., 2:, :-2]
h = img[..., 2:, 1:-1]
i = img[..., 2:, 2:]
# Computing contrast
cross = (b, d, e, f, h)
mn = min_(cross)
mx = max_(cross)
diag = (a, c, g, i)
mn2 = min_(diag)
mx2 = max_(diag)
mx = mx + mx2
mn = mn + mn2
# Computing local weight
inv_mx = torch.reciprocal(mx)
amp = inv_mx * torch.minimum(mn, (2 - mx))
# scaling
amp = torch.sqrt(amp)
w = - amp * (amount * (1/5 - 1/8) + 1/8)
div = torch.reciprocal(1 + 4*w)
output = ((b + d + f + h)*w + e) * div
output = output.clamp(0, 1)
output = torch.nan_to_num(output)
return (output)
class IPAdapter(nn.Module):
def __init__(self, ipadapter_model, cross_attention_dim=1024, output_cross_attention_dim=1024, clip_embeddings_dim=1024, clip_extra_context_tokens=4, is_sdxl=False, is_plus=False, is_full=False):
super().__init__()
self.clip_embeddings_dim = clip_embeddings_dim
self.cross_attention_dim = cross_attention_dim
self.output_cross_attention_dim = output_cross_attention_dim
self.clip_extra_context_tokens = clip_extra_context_tokens
self.is_sdxl = is_sdxl
self.is_full = is_full
self.image_proj_model = self.init_proj() if not is_plus else self.init_proj_plus()
self.image_proj_model.load_state_dict(ipadapter_model["image_proj"])
self.ip_layers = To_KV(ipadapter_model["ip_adapter"])
def init_proj(self):
image_proj_model = ImageProjModel(
cross_attention_dim=self.cross_attention_dim,
clip_embeddings_dim=self.clip_embeddings_dim,
clip_extra_context_tokens=self.clip_extra_context_tokens
)
return image_proj_model
def init_proj_plus(self):
if self.is_full:
image_proj_model = MLPProjModel(
cross_attention_dim=self.cross_attention_dim,
clip_embeddings_dim=self.clip_embeddings_dim
)
else:
image_proj_model = Resampler(
dim=self.cross_attention_dim,
depth=4,
dim_head=64,
heads=20 if self.is_sdxl else 12,
num_queries=self.clip_extra_context_tokens,
embedding_dim=self.clip_embeddings_dim,
output_dim=self.output_cross_attention_dim,
ff_mult=4
)
return image_proj_model
@torch.inference_mode()
def get_image_embeds(self, clip_embed, clip_embed_zeroed):
image_prompt_embeds = self.image_proj_model(clip_embed)
uncond_image_prompt_embeds = self.image_proj_model(clip_embed_zeroed)
return image_prompt_embeds, uncond_image_prompt_embeds
def lerp(a, b, t):
"""Linear interpolation between values a and b with t in [0, 1]."""
return a + (b - a) * t
def interpolate_values(values, T):
T = max(0, min(T, 1))
total_values = len(values)
if total_values < 2:
raise ValueError("At least two values are required for interpolation.")
position = T * (total_values - 1)
index = int(position)
next_index = min(index + 1, total_values - 1)
T_mapped = position - index
return lerp(values[index], values[next_index], T_mapped)
class CrossAttentionPatch:
# forward for patching
def __init__(self, weight, weight_interpolation, ipadapter, device, dtype, number, cond, uncond, weight_type, mask=None, sigma_start=0.0, sigma_end=1.0, unfold_batch=False):
self.weights = [weight]
self.weight_interpolation = [weight_interpolation]
self.ipadapters = [ipadapter]
self.conds = [cond]
self.unconds = [uncond]
self.device = 'cuda' if 'cuda' in device.type else 'cpu'
self.dtype = dtype if 'cuda' in self.device else torch.bfloat16
self.number = number
self.weight_type = [weight_type]
self.masks = [mask]
self.sigma_start = [sigma_start]
self.sigma_end = [sigma_end]
self.unfold_batch = [unfold_batch]
self.k_key = str(self.number*2+1) + "_to_k_ip"
self.v_key = str(self.number*2+1) + "_to_v_ip"
def set_new_condition(self, weight, weight_interpolation, ipadapter, device, dtype, number, cond, uncond, weight_type, mask=None, sigma_start=0.0, sigma_end=1.0, unfold_batch=False):
self.weights.append(weight)
self.weight_interpolation.append(weights)
self.ipadapters.append(ipadapter)
self.conds.append(cond)
self.unconds.append(uncond)
self.masks.append(mask)
self.device = 'cuda' if 'cuda' in device.type else 'cpu'
self.dtype = dtype if 'cuda' in self.device else torch.bfloat16
self.weight_type.append(weight_type)
self.sigma_start.append(sigma_start)
self.sigma_end.append(sigma_end)
self.unfold_batch.append(unfold_batch)
def __call__(self, n, context_attn2, value_attn2, extra_options):
org_dtype = n.dtype
cond_or_uncond = extra_options["cond_or_uncond"]
sigma = extra_options["sigmas"][0].item() if 'sigmas' in extra_options else 999999999.9
# extra options for AnimateDiff
ad_params = extra_options['ad_params'] if "ad_params" in extra_options else None
with torch.autocast(device_type=self.device, dtype=self.dtype):
q = n
k = context_attn2
v = value_attn2
b = q.shape[0]
qs = q.shape[1]
batch_prompt = b // len(cond_or_uncond)
out = optimized_attention(q, k, v, extra_options["n_heads"])
_, _, lh, lw = extra_options["original_shape"]
for weight, weight_interpolation, cond, uncond, ipadapter, mask, weight_type, sigma_start, sigma_end, unfold_batch in zip(self.weights, self.weight_interpolation, self.conds, self.unconds, self.ipadapters, self.masks, self.weight_type, self.sigma_start, self.sigma_end, self.unfold_batch):
if sigma > sigma_start or sigma < sigma_end:
continue
if unfold_batch and cond.shape[0] > 1:
# Check AnimateDiff context window
if ad_params is not None and ad_params["sub_idxs"] is not None:
# if images length matches or exceeds full_length get sub_idx images
if cond.shape[0] >= ad_params["full_length"]:
cond = torch.Tensor(cond[ad_params["sub_idxs"]])
uncond = torch.Tensor(uncond[ad_params["sub_idxs"]])
# otherwise, need to do more to get proper sub_idxs masks
else:
# check if images length matches full_length - if not, make it match
if cond.shape[0] < ad_params["full_length"]:
cond = torch.cat((cond, cond[-1:].repeat((ad_params["full_length"]-cond.shape[0], 1, 1))), dim=0)
uncond = torch.cat((uncond, uncond[-1:].repeat((ad_params["full_length"]-uncond.shape[0], 1, 1))), dim=0)
# if we have too many remove the excess (should not happen, but just in case)
if cond.shape[0] > ad_params["full_length"]:
cond = cond[:ad_params["full_length"]]
uncond = uncond[:ad_params["full_length"]]
cond = cond[ad_params["sub_idxs"]]
uncond = uncond[ad_params["sub_idxs"]]
# if we don't have enough reference images repeat the last one until we reach the right size
if cond.shape[0] < batch_prompt:
cond = torch.cat((cond, cond[-1:].repeat((batch_prompt-cond.shape[0], 1, 1))), dim=0)
uncond = torch.cat((uncond, uncond[-1:].repeat((batch_prompt-uncond.shape[0], 1, 1))), dim=0)
# if we have too many remove the exceeding
elif cond.shape[0] > batch_prompt:
cond = cond[:batch_prompt]
uncond = uncond[:batch_prompt]
k_cond = ipadapter.ip_layers.to_kvs[self.k_key](cond)
k_uncond = ipadapter.ip_layers.to_kvs[self.k_key](uncond)
v_cond = ipadapter.ip_layers.to_kvs[self.v_key](cond)
v_uncond = ipadapter.ip_layers.to_kvs[self.v_key](uncond)
else:
k_cond = ipadapter.ip_layers.to_kvs[self.k_key](cond).repeat(batch_prompt, 1, 1)
k_uncond = ipadapter.ip_layers.to_kvs[self.k_key](uncond).repeat(batch_prompt, 1, 1)
v_cond = ipadapter.ip_layers.to_kvs[self.v_key](cond).repeat(batch_prompt, 1, 1)
v_uncond = ipadapter.ip_layers.to_kvs[self.v_key](uncond).repeat(batch_prompt, 1, 1)
if weight_interpolation:
# TODO: how to get 14.614? it's not sigma_start or sigma_end
f = -(sigma / 14.614643096923828)+1
weight = weight * interpolate_values(weight_interpolation, f)
if weight_type.startswith("linear"):
ip_k = torch.cat([(k_cond, k_uncond)[i] for i in cond_or_uncond], dim=0) * weight
ip_v = torch.cat([(v_cond, v_uncond)[i] for i in cond_or_uncond], dim=0) * weight
else:
ip_k = torch.cat([(k_cond, k_uncond)[i] for i in cond_or_uncond], dim=0)
ip_v = torch.cat([(v_cond, v_uncond)[i] for i in cond_or_uncond], dim=0)
if weight_type.startswith("channel"):
# code by Lvmin Zhang at Stanford University as also seen on Fooocus IPAdapter implementation
# please read licensing notes https://github.com/lllyasviel/Fooocus/blob/main/fooocus_extras/ip_adapter.py#L225
ip_v_mean = torch.mean(ip_v, dim=1, keepdim=True)
ip_v_offset = ip_v - ip_v_mean
_, _, C = ip_k.shape
channel_penalty = float(C) / 1280.0
W = weight * channel_penalty
ip_k = ip_k * W
ip_v = ip_v_offset + ip_v_mean * W
out_ip = optimized_attention(q, ip_k, ip_v, extra_options["n_heads"])
if weight_type.startswith("original"):
out_ip = out_ip * weight
if mask is not None:
# TODO: needs checking
mask_h = max(1, round(lh / math.sqrt(lh * lw / qs)))
mask_w = qs // mask_h
# check if using AnimateDiff and sliding context window
if (mask.shape[0] > 1 and ad_params is not None and ad_params["sub_idxs"] is not None):
# if mask length matches or exceeds full_length, just get sub_idx masks, resize, and continue
if mask.shape[0] >= ad_params["full_length"]:
mask_downsample = torch.Tensor(mask[ad_params["sub_idxs"]])
mask_downsample = F.interpolate(mask_downsample.unsqueeze(1), size=(mask_h, mask_w), mode="bicubic").squeeze(1)
# otherwise, need to do more to get proper sub_idxs masks
else:
# resize to needed attention size (to save on memory)
mask_downsample = F.interpolate(mask.unsqueeze(1), size=(mask_h, mask_w), mode="bicubic").squeeze(1)
# check if mask length matches full_length - if not, make it match
if mask_downsample.shape[0] < ad_params["full_length"]:
mask_downsample = torch.cat((mask_downsample, mask_downsample[-1:].repeat((ad_params["full_length"]-mask_downsample.shape[0], 1, 1))), dim=0)
# if we have too many remove the excess (should not happen, but just in case)
if mask_downsample.shape[0] > ad_params["full_length"]:
mask_downsample = mask_downsample[:ad_params["full_length"]]
# now, select sub_idxs masks
mask_downsample = mask_downsample[ad_params["sub_idxs"]]
# otherwise, perform usual mask interpolation
else:
mask_downsample = F.interpolate(mask.unsqueeze(1), size=(mask_h, mask_w), mode="bicubic").squeeze(1)
# if we don't have enough masks repeat the last one until we reach the right size
if mask_downsample.shape[0] < batch_prompt:
mask_downsample = torch.cat((mask_downsample, mask_downsample[-1:, :, :].repeat((batch_prompt-mask_downsample.shape[0], 1, 1))), dim=0)
# if we have too many remove the exceeding
elif mask_downsample.shape[0] > batch_prompt:
mask_downsample = mask_downsample[:batch_prompt, :, :]
# repeat the masks
mask_downsample = mask_downsample.repeat(len(cond_or_uncond), 1, 1)
mask_downsample = mask_downsample.view(mask_downsample.shape[0], -1, 1).repeat(1, 1, out.shape[2])
out_ip = out_ip * mask_downsample
out = out + out_ip
return out.to(dtype=org_dtype)
class IPAdapterModelLoader:
@classmethod
def INPUT_TYPES(s):
return {"required": { "ipadapter_file": (folder_paths.get_filename_list("ipadapter"), )}}
RETURN_TYPES = ("IPADAPTER",)
FUNCTION = "load_ipadapter_model"
CATEGORY = "ipadapter"
def load_ipadapter_model(self, ipadapter_file):
ckpt_path = folder_paths.get_full_path("ipadapter", ipadapter_file)
model = comfy.utils.load_torch_file(ckpt_path, safe_load=True)
if ckpt_path.lower().endswith(".safetensors"):
st_model = {"image_proj": {}, "ip_adapter": {}}
for key in model.keys():
if key.startswith("image_proj."):
st_model["image_proj"][key.replace("image_proj.", "")] = model[key]
elif key.startswith("ip_adapter."):
st_model["ip_adapter"][key.replace("ip_adapter.", "")] = model[key]
model = st_model
if not "ip_adapter" in model.keys() or not model["ip_adapter"]:
raise Exception("invalid IPAdapter model {}".format(ckpt_path))
return (model,)
class IPAdapterApply:
@classmethod
def INPUT_TYPES(s):
return {
"required": {
"ipadapter": ("IPADAPTER", ),
"clip_vision": ("CLIP_VISION",),
"image": ("IMAGE",),
"model": ("MODEL", ),
"weight": ("FLOAT", { "default": 1.0, "min": -1, "max": 3, "step": 0.05 }),
"weight_interpolation": ("STRING", {"default": ""}),
"noise": ("FLOAT", { "default": 0.0, "min": 0.0, "max": 1.0, "step": 0.01 }),
"weight_type": (["original", "linear", "channel penalty"], ),
"start_at": ("FLOAT", { "default": 0.0, "min": 0.0, "max": 1.0, "step": 0.001 }),
"end_at": ("FLOAT", { "default": 1.0, "min": 0.0, "max": 1.0, "step": 0.001 }),
"unfold_batch": ("BOOLEAN", { "default": False }),
},
"optional": {
"attn_mask": ("MASK",),
}
}
RETURN_TYPES = ("MODEL",)
FUNCTION = "apply_ipadapter"
CATEGORY = "ipadapter"
def apply_ipadapter(self, ipadapter, model, weight, weight_interpolation, clip_vision=None, image=None, weight_type="original", noise=None, embeds=None, attn_mask=None, start_at=0.0, end_at=1.0, unfold_batch=False):
self.dtype = model.model.diffusion_model.dtype
self.device = comfy.model_management.get_torch_device()
self.weight = weight
try:
self.weight_interpolation = [float(item) for item in weight_interpolation.split(',')]
except ValueError as e:
print(f"error parsing ipadapter weight_interpolation: {e}")
self.weight_interpolation = []
self.is_full = "proj.0.weight" in ipadapter["image_proj"]
self.is_plus = self.is_full or "latents" in ipadapter["image_proj"]
output_cross_attention_dim = ipadapter["ip_adapter"]["1.to_k_ip.weight"].shape[1]
self.is_sdxl = output_cross_attention_dim == 2048
cross_attention_dim = 1280 if self.is_plus and self.is_sdxl else output_cross_attention_dim
clip_extra_context_tokens = 16 if self.is_plus else 4
if embeds is not None:
embeds = torch.unbind(embeds)
clip_embed = embeds[0].cpu()
clip_embed_zeroed = embeds[1].cpu()
else:
if image.shape[1] != image.shape[2]:
print("\033[33mINFO: the IPAdapter reference image is not a square, CLIPImageProcessor will resize and crop it at the center. If the main focus of the picture is not in the middle the result might not be what you are expecting.\033[0m")
clip_embed = clip_vision.encode_image(image)
neg_image = image_add_noise(image, noise) if noise > 0 else None
if self.is_plus:
clip_embed = clip_embed.penultimate_hidden_states
if noise > 0:
clip_embed_zeroed = clip_vision.encode_image(neg_image).penultimate_hidden_states
else:
clip_embed_zeroed = zeroed_hidden_states(clip_vision, image.shape[0])
else:
clip_embed = clip_embed.image_embeds
if noise > 0:
clip_embed_zeroed = clip_vision.encode_image(neg_image).image_embeds
else:
clip_embed_zeroed = torch.zeros_like(clip_embed)
clip_embeddings_dim = clip_embed.shape[-1]
self.ipadapter = IPAdapter(
ipadapter,
cross_attention_dim=cross_attention_dim,
output_cross_attention_dim=output_cross_attention_dim,
clip_embeddings_dim=clip_embeddings_dim,
clip_extra_context_tokens=clip_extra_context_tokens,
is_sdxl=self.is_sdxl,
is_plus=self.is_plus,
is_full=self.is_full,
)
self.ipadapter.to(self.device, dtype=self.dtype)
image_prompt_embeds, uncond_image_prompt_embeds = self.ipadapter.get_image_embeds(clip_embed.to(self.device, self.dtype), clip_embed_zeroed.to(self.device, self.dtype))
image_prompt_embeds = image_prompt_embeds.to(self.device, dtype=self.dtype)
uncond_image_prompt_embeds = uncond_image_prompt_embeds.to(self.device, dtype=self.dtype)
work_model = model.clone()
if attn_mask is not None:
attn_mask = attn_mask.to(self.device)
sigma_start = model.model.model_sampling.percent_to_sigma(start_at)
sigma_end = model.model.model_sampling.percent_to_sigma(end_at)
patch_kwargs = {
"number": 0,
"weight": self.weight,
"weight_interpolation": self.weight_interpolation,
"ipadapter": self.ipadapter,
"device": self.device,
"dtype": self.dtype,
"cond": image_prompt_embeds,
"uncond": uncond_image_prompt_embeds,
"weight_type": weight_type,
"mask": attn_mask,
"sigma_start": sigma_start,
"sigma_end": sigma_end,
"unfold_batch": unfold_batch,
}
if not self.is_sdxl:
for id in [1,2,4,5,7,8]: # id of input_blocks that have cross attention
set_model_patch_replace(work_model, patch_kwargs, ("input", id))
patch_kwargs["number"] += 1
for id in [3,4,5,6,7,8,9,10,11]: # id of output_blocks that have cross attention
set_model_patch_replace(work_model, patch_kwargs, ("output", id))
patch_kwargs["number"] += 1
set_model_patch_replace(work_model, patch_kwargs, ("middle", 0))
else:
for id in [4,5,7,8]: # id of input_blocks that have cross attention
block_indices = range(2) if id in [4, 5] else range(10) # transformer_depth
for index in block_indices:
set_model_patch_replace(work_model, patch_kwargs, ("input", id, index))
patch_kwargs["number"] += 1
for id in range(6): # id of output_blocks that have cross attention
block_indices = range(2) if id in [3, 4, 5] else range(10) # transformer_depth
for index in block_indices:
set_model_patch_replace(work_model, patch_kwargs, ("output", id, index))
patch_kwargs["number"] += 1
for index in range(10):
set_model_patch_replace(work_model, patch_kwargs, ("middle", 0, index))
patch_kwargs["number"] += 1
return (work_model, )
class PrepImageForClipVision:
@classmethod
def INPUT_TYPES(s):
return {"required": {
"image": ("IMAGE",),
"interpolation": (["LANCZOS", "BICUBIC", "HAMMING", "BILINEAR", "BOX", "NEAREST"],),
"crop_position": (["top", "bottom", "left", "right", "center", "pad"],),
"sharpening": ("FLOAT", {"default": 0.0, "min": 0, "max": 1, "step": 0.05}),
},
}
RETURN_TYPES = ("IMAGE",)
FUNCTION = "prep_image"
CATEGORY = "ipadapter"
def prep_image(self, image, interpolation="LANCZOS", crop_position="center", sharpening=0.0):
_, oh, ow, _ = image.shape
output = image.permute([0,3,1,2])
if "pad" in crop_position:
target_length = max(oh, ow)
pad_l = (target_length - ow) // 2
pad_r = (target_length - ow) - pad_l
pad_t = (target_length - oh) // 2
pad_b = (target_length - oh) - pad_t
output = F.pad(output, (pad_l, pad_r, pad_t, pad_b), value=0, mode="constant")
else:
crop_size = min(oh, ow)
x = (ow-crop_size) // 2
y = (oh-crop_size) // 2
if "top" in crop_position:
y = 0
elif "bottom" in crop_position:
y = oh-crop_size
elif "left" in crop_position:
x = 0
elif "right" in crop_position:
x = ow-crop_size
x2 = x+crop_size
y2 = y+crop_size
# crop
output = output[:, :, y:y2, x:x2]
# resize (apparently PIL resize is better than tourchvision interpolate)
imgs = []
for i in range(output.shape[0]):
img = TT.ToPILImage()(output[i])
img = img.resize((224,224), resample=Image.Resampling[interpolation])
imgs.append(TT.ToTensor()(img))
output = torch.stack(imgs, dim=0)
if sharpening > 0:
output = contrast_adaptive_sharpening(output, sharpening)
output = output.permute([0,2,3,1])
return (output,)
class IPAdapterEncoder:
@classmethod
def INPUT_TYPES(s):
return {"required": {
"clip_vision": ("CLIP_VISION",),
"image_1": ("IMAGE",),
"ipadapter_plus": ("BOOLEAN", { "default": False }),
"noise": ("FLOAT", { "default": 0.0, "min": 0.0, "max": 1.0, "step": 0.01 }),
"weight_1": ("FLOAT", { "default": 1.0, "min": 0, "max": 1.0, "step": 0.01 }),
},
"optional": {
"image_2": ("IMAGE",),
"image_3": ("IMAGE",),
"image_4": ("IMAGE",),
"weight_2": ("FLOAT", { "default": 1.0, "min": 0, "max": 1.0, "step": 0.01 }),
"weight_3": ("FLOAT", { "default": 1.0, "min": 0, "max": 1.0, "step": 0.01 }),
"weight_4": ("FLOAT", { "default": 1.0, "min": 0, "max": 1.0, "step": 0.01 }),
}
}
RETURN_TYPES = ("EMBEDS",)
FUNCTION = "preprocess"
CATEGORY = "ipadapter"
def preprocess(self, clip_vision, image_1, ipadapter_plus, noise, weight_1, image_2=None, image_3=None, image_4=None, weight_2=1.0, weight_3=1.0, weight_4=1.0):
weight_1 *= (0.1 + (weight_1 - 0.1))
weight_1 = 1.19e-05 if weight_1 <= 1.19e-05 else weight_1
weight_2 *= (0.1 + (weight_2 - 0.1))
weight_2 = 1.19e-05 if weight_2 <= 1.19e-05 else weight_2
weight_3 *= (0.1 + (weight_3 - 0.1))
weight_3 = 1.19e-05 if weight_3 <= 1.19e-05 else weight_3
weight_4 *= (0.1 + (weight_4 - 0.1))
weight_5 = 1.19e-05 if weight_4 <= 1.19e-05 else weight_4
image = image_1
weight = [weight_1]*image_1.shape[0]
if image_2 is not None:
if image_1.shape[1:] != image_2.shape[1:]:
image_2 = comfy.utils.common_upscale(image_2.movedim(-1,1), image.shape[2], image.shape[1], "bilinear", "center").movedim(1,-1)
image = torch.cat((image, image_2), dim=0)
weight += [weight_2]*image_2.shape[0]
if image_3 is not None:
if image.shape[1:] != image_3.shape[1:]:
image_3 = comfy.utils.common_upscale(image_3.movedim(-1,1), image.shape[2], image.shape[1], "bilinear", "center").movedim(1,-1)
image = torch.cat((image, image_3), dim=0)
weight += [weight_3]*image_3.shape[0]
if image_4 is not None:
if image.shape[1:] != image_4.shape[1:]:
image_4 = comfy.utils.common_upscale(image_4.movedim(-1,1), image.shape[2], image.shape[1], "bilinear", "center").movedim(1,-1)
image = torch.cat((image, image_4), dim=0)
weight += [weight_4]*image_4.shape[0]
clip_embed = clip_vision.encode_image(image)
neg_image = image_add_noise(image, noise) if noise > 0 else None
if ipadapter_plus:
clip_embed = clip_embed.penultimate_hidden_states
if noise > 0:
clip_embed_zeroed = clip_vision.encode_image(neg_image).penultimate_hidden_states
else:
clip_embed_zeroed = zeroed_hidden_states(clip_vision, image.shape[0])
else:
clip_embed = clip_embed.image_embeds
if noise > 0:
clip_embed_zeroed = clip_vision.encode_image(neg_image).image_embeds
else:
clip_embed_zeroed = torch.zeros_like(clip_embed)
if any(e != 1.0 for e in weight):
weight = torch.tensor(weight).unsqueeze(-1) if not ipadapter_plus else torch.tensor(weight).unsqueeze(-1).unsqueeze(-1)
clip_embed = clip_embed * weight
output = torch.stack((clip_embed, clip_embed_zeroed))
return( output, )
class IPAdapterApplyEncoded(IPAdapterApply):
@classmethod
def INPUT_TYPES(s):
return {
"required": {
"ipadapter": ("IPADAPTER", ),
"embeds": ("EMBEDS",),
"model": ("MODEL", ),
"weight": ("FLOAT", { "default": 1.0, "min": -1, "max": 3, "step": 0.05 }),
"weight_type": (["original", "linear", "channel penalty"], ),
"start_at": ("FLOAT", { "default": 0.0, "min": 0.0, "max": 1.0, "step": 0.001 }),
"end_at": ("FLOAT", { "default": 1.0, "min": 0.0, "max": 1.0, "step": 0.001 }),
"unfold_batch": ("BOOLEAN", { "default": False }),
},
"optional": {
"attn_mask": ("MASK",),
}
}
class IPAdapterSaveEmbeds:
def __init__(self):
self.output_dir = folder_paths.get_output_directory()
@classmethod
def INPUT_TYPES(s):
return {"required": {
"embeds": ("EMBEDS",),
"filename_prefix": ("STRING", {"default": "embeds/IPAdapter"})
},
}
RETURN_TYPES = ()
FUNCTION = "save"
OUTPUT_NODE = True
CATEGORY = "ipadapter"
def save(self, embeds, filename_prefix):
full_output_folder, filename, counter, subfolder, filename_prefix = folder_paths.get_save_image_path(filename_prefix, self.output_dir)
file = f"{filename}_{counter:05}_.ipadpt"
file = os.path.join(full_output_folder, file)
torch.save(embeds, file)
return (None, )
class IPAdapterLoadEmbeds:
@classmethod
def INPUT_TYPES(s):
input_dir = folder_paths.get_input_directory()
files = [os.path.relpath(os.path.join(root, file), input_dir) for root, dirs, files in os.walk(input_dir) for file in files if file.endswith('.ipadpt')]
return {"required": {"embeds": [sorted(files), ]}, }
RETURN_TYPES = ("EMBEDS", )
FUNCTION = "load"
CATEGORY = "ipadapter"
def load(self, embeds):
path = folder_paths.get_annotated_filepath(embeds)
output = torch.load(path).cpu()
return (output, )
class IPAdapterBatchEmbeds:
@classmethod
def INPUT_TYPES(s):
return {"required": {
"embed1": ("EMBEDS",),
"embed2": ("EMBEDS",),
}}
RETURN_TYPES = ("EMBEDS",)
FUNCTION = "batch"
CATEGORY = "ipadapter"
def batch(self, embed1, embed2):
output = torch.cat((embed1, embed2), dim=1)
return (output, )
NODE_CLASS_MAPPINGS = {
"IPAdapterModelLoader": IPAdapterModelLoader,
"IPAdapterApply": IPAdapterApply,
"IPAdapterApplyEncoded": IPAdapterApplyEncoded,
"PrepImageForClipVision": PrepImageForClipVision,
"IPAdapterEncoder": IPAdapterEncoder,
"IPAdapterSaveEmbeds": IPAdapterSaveEmbeds,
"IPAdapterLoadEmbeds": IPAdapterLoadEmbeds,
"IPAdapterBatchEmbeds": IPAdapterBatchEmbeds,
}
NODE_DISPLAY_NAME_MAPPINGS = {
"IPAdapterModelLoader": "Load IPAdapter Model",
"IPAdapterApply": "Apply IPAdapter",
"IPAdapterApplyEncoded": "Apply IPAdapter from Encoded",
"PrepImageForClipVision": "Prepare Image For Clip Vision",
"IPAdapterEncoder": "Encode IPAdapter Image",
"IPAdapterSaveEmbeds": "Save IPAdapter Embeds",
"IPAdapterLoadEmbeds": "Load IPAdapter Embeds",
"IPAdapterBatchEmbeds": "IPAdapter Batch Embeds",
}
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