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good_upscaler / Backend /custom_nodes /ComfyUI-KJNodes /nodes /mask_nodes.py

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	import torch
	import torch.nn.functional as F
	from torchvision.transforms import functional as TF
	from PIL import Image, ImageDraw, ImageFilter, ImageFont
	import scipy.ndimage
	import numpy as np
	from contextlib import nullcontext
	import os

	import model_management
	from comfy.utils import ProgressBar
	from nodes import MAX_RESOLUTION

	import folder_paths

	from ..utility.utility import tensor2pil, pil2tensor

	script_directory = os.path.dirname(os.path.dirname(os.path.abspath(__file__)))

	class BatchCLIPSeg:

	def __init__(self):
	pass

	@classmethod
	def INPUT_TYPES(s):

	return {"required":
	{
	"images": ("IMAGE",),
	"text": ("STRING", {"multiline": False}),
	"threshold": ("FLOAT", {"default": 0.5,"min": 0.0, "max": 10.0, "step": 0.001}),
	"binary_mask": ("BOOLEAN", {"default": True}),
	"combine_mask": ("BOOLEAN", {"default": False}),
	"use_cuda": ("BOOLEAN", {"default": True}),
	},
	"optional":
	{
	"blur_sigma": ("FLOAT", {"default": 0.0, "min": 0.0, "max": 100.0, "step": 0.1}),
	"opt_model": ("CLIPSEGMODEL", ),
	"prev_mask": ("MASK", {"default": None}),
	"image_bg_level": ("FLOAT", {"default": 0.5, "min": 0.0, "max": 1.0, "step": 0.01}),
	"invert": ("BOOLEAN", {"default": False}),
	}
	}

	CATEGORY = "KJNodes/masking"
	RETURN_TYPES = ("MASK", "IMAGE", )
	RETURN_NAMES = ("Mask", "Image", )
	FUNCTION = "segment_image"
	DESCRIPTION = """
	Segments an image or batch of images using CLIPSeg.
	"""

	def segment_image(self, images, text, threshold, binary_mask, combine_mask, use_cuda, blur_sigma=0.0, opt_model=None, prev_mask=None, invert= False, image_bg_level=0.5):
	from transformers import CLIPSegProcessor, CLIPSegForImageSegmentation
	import torchvision.transforms as transforms
	offload_device = model_management.unet_offload_device()
	device = model_management.get_torch_device()
	if not use_cuda:
	device = torch.device("cpu")
	dtype = model_management.unet_dtype()

	if opt_model is None:
	checkpoint_path = os.path.join(folder_paths.models_dir,'clip_seg', 'clipseg-rd64-refined-fp16')
	if not hasattr(self, "model"):
	try:
	if not os.path.exists(checkpoint_path):
	from huggingface_hub import snapshot_download
	snapshot_download(repo_id="Kijai/clipseg-rd64-refined-fp16", local_dir=checkpoint_path, local_dir_use_symlinks=False)
	self.model = CLIPSegForImageSegmentation.from_pretrained(checkpoint_path)
	except:
	checkpoint_path = "CIDAS/clipseg-rd64-refined"
	self.model = CLIPSegForImageSegmentation.from_pretrained(checkpoint_path)
	processor = CLIPSegProcessor.from_pretrained(checkpoint_path)

	else:
	self.model = opt_model['model']
	processor = opt_model['processor']

	self.model.to(dtype).to(device)

	B, H, W, C = images.shape
	images = images.to(device)

	autocast_condition = (dtype != torch.float32) and not model_management.is_device_mps(device)
	with torch.autocast(model_management.get_autocast_device(device), dtype=dtype) if autocast_condition else nullcontext():

	PIL_images = [Image.fromarray(np.clip(255. * image.cpu().numpy().squeeze(), 0, 255).astype(np.uint8)) for image in images ]
	prompt = [text] * len(images)
	input_prc = processor(text=prompt, images=PIL_images, return_tensors="pt")

	for key in input_prc:
	input_prc[key] = input_prc[key].to(device)
	outputs = self.model(**input_prc)

	mask_tensor = torch.sigmoid(outputs.logits)
	mask_tensor = (mask_tensor - mask_tensor.min()) / (mask_tensor.max() - mask_tensor.min())
	mask_tensor = torch.where(mask_tensor > (threshold), mask_tensor, torch.tensor(0, dtype=torch.float))
	print(mask_tensor.shape)
	if len(mask_tensor.shape) == 2:
	mask_tensor = mask_tensor.unsqueeze(0)
	mask_tensor = F.interpolate(mask_tensor.unsqueeze(1), size=(H, W), mode='nearest')
	mask_tensor = mask_tensor.squeeze(1)

	self.model.to(offload_device)

	if binary_mask:
	mask_tensor = (mask_tensor > 0).float()
	if blur_sigma > 0:
	kernel_size = int(6 * int(blur_sigma) + 1)
	blur = transforms.GaussianBlur(kernel_size=(kernel_size, kernel_size), sigma=(blur_sigma, blur_sigma))
	mask_tensor = blur(mask_tensor)

	if combine_mask:
	mask_tensor = torch.max(mask_tensor, dim=0)[0]
	mask_tensor = mask_tensor.unsqueeze(0).repeat(len(images),1,1)

	del outputs
	model_management.soft_empty_cache()

	if prev_mask is not None:
	if prev_mask.shape != mask_tensor.shape:
	prev_mask = F.interpolate(prev_mask.unsqueeze(1), size=(H, W), mode='nearest')
	mask_tensor = mask_tensor + prev_mask.to(device)
	torch.clamp(mask_tensor, min=0.0, max=1.0)

	if invert:
	mask_tensor = 1 - mask_tensor

	image_tensor = images * mask_tensor.unsqueeze(-1) + (1 - mask_tensor.unsqueeze(-1)) * image_bg_level
	image_tensor = torch.clamp(image_tensor, min=0.0, max=1.0).cpu().float()

	mask_tensor = mask_tensor.cpu().float()

	return mask_tensor, image_tensor,

	class DownloadAndLoadCLIPSeg:

	def __init__(self):
	pass

	@classmethod
	def INPUT_TYPES(s):

	return {"required":
	{
	"model": (
	[ 'Kijai/clipseg-rd64-refined-fp16',
	'CIDAS/clipseg-rd64-refined',
	],
	),
	},
	}

	CATEGORY = "KJNodes/masking"
	RETURN_TYPES = ("CLIPSEGMODEL",)
	RETURN_NAMES = ("clipseg_model",)
	FUNCTION = "segment_image"
	DESCRIPTION = """
	Downloads and loads CLIPSeg model with huggingface_hub,
	to ComfyUI/models/clip_seg
	"""

	def segment_image(self, model):
	from transformers import CLIPSegProcessor, CLIPSegForImageSegmentation
	checkpoint_path = os.path.join(folder_paths.models_dir,'clip_seg', os.path.basename(model))
	if not hasattr(self, "model"):
	if not os.path.exists(checkpoint_path):
	from huggingface_hub import snapshot_download
	snapshot_download(repo_id=model, local_dir=checkpoint_path, local_dir_use_symlinks=False)
	self.model = CLIPSegForImageSegmentation.from_pretrained(checkpoint_path)

	processor = CLIPSegProcessor.from_pretrained(checkpoint_path)

	clipseg_model = {}
	clipseg_model['model'] = self.model
	clipseg_model['processor'] = processor

	return clipseg_model,

	class CreateTextMask:

	RETURN_TYPES = ("IMAGE", "MASK",)
	FUNCTION = "createtextmask"
	CATEGORY = "KJNodes/text"
	DESCRIPTION = """
	Creates a text image and mask.
	Looks for fonts from this folder:
	ComfyUI/custom_nodes/ComfyUI-KJNodes/fonts

	If start_rotation and/or end_rotation are different values,
	creates animation between them.
	"""

	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"invert": ("BOOLEAN", {"default": False}),
	"frames": ("INT", {"default": 1,"min": 1, "max": 4096, "step": 1}),
	"text_x": ("INT", {"default": 0,"min": 0, "max": 4096, "step": 1}),
	"text_y": ("INT", {"default": 0,"min": 0, "max": 4096, "step": 1}),
	"font_size": ("INT", {"default": 32,"min": 8, "max": 4096, "step": 1}),
	"font_color": ("STRING", {"default": "white"}),
	"text": ("STRING", {"default": "HELLO!", "multiline": True}),
	"font": (folder_paths.get_filename_list("kjnodes_fonts"), ),
	"width": ("INT", {"default": 512,"min": 16, "max": 4096, "step": 1}),
	"height": ("INT", {"default": 512,"min": 16, "max": 4096, "step": 1}),
	"start_rotation": ("INT", {"default": 0,"min": 0, "max": 359, "step": 1}),
	"end_rotation": ("INT", {"default": 0,"min": -359, "max": 359, "step": 1}),
	},
	}

	def createtextmask(self, frames, width, height, invert, text_x, text_y, text, font_size, font_color, font, start_rotation, end_rotation):
	# Define the number of images in the batch
	batch_size = frames
	out = []
	masks = []
	rotation = start_rotation
	if start_rotation != end_rotation:
	rotation_increment = (end_rotation - start_rotation) / (batch_size - 1)

	font_path = folder_paths.get_full_path("kjnodes_fonts", font)
	# Generate the text
	for i in range(batch_size):
	image = Image.new("RGB", (width, height), "black")
	draw = ImageDraw.Draw(image)
	font = ImageFont.truetype(font_path, font_size)

	# Split the text into words
	words = text.split()

	# Initialize variables for line creation
	lines = []
	current_line = []
	current_line_width = 0
	try: #new pillow
	# Iterate through words to create lines
	for word in words:
	word_width = font.getbbox(word)[2]
	if current_line_width + word_width <= width - 2 * text_x:
	current_line.append(word)
	current_line_width += word_width + font.getbbox(" ")[2] # Add space width
	else:
	lines.append(" ".join(current_line))
	current_line = [word]
	current_line_width = word_width
	except: #old pillow
	for word in words:
	word_width = font.getsize(word)[0]
	if current_line_width + word_width <= width - 2 * text_x:
	current_line.append(word)
	current_line_width += word_width + font.getsize(" ")[0] # Add space width
	else:
	lines.append(" ".join(current_line))
	current_line = [word]
	current_line_width = word_width

	# Add the last line if it's not empty
	if current_line:
	lines.append(" ".join(current_line))

	# Draw each line of text separately
	y_offset = text_y
	for line in lines:
	text_width = font.getlength(line)
	text_height = font_size
	text_center_x = text_x + text_width / 2
	text_center_y = y_offset + text_height / 2
	try:
	draw.text((text_x, y_offset), line, font=font, fill=font_color, features=['-liga'])
	except:
	draw.text((text_x, y_offset), line, font=font, fill=font_color)
	y_offset += text_height # Move to the next line

	if start_rotation != end_rotation:
	image = image.rotate(rotation, center=(text_center_x, text_center_y))
	rotation += rotation_increment

	image = np.array(image).astype(np.float32) / 255.0
	image = torch.from_numpy(image)[None,]
	mask = image[:, :, :, 0]
	masks.append(mask)
	out.append(image)

	if invert:
	return (1.0 - torch.cat(out, dim=0), 1.0 - torch.cat(masks, dim=0),)
	return (torch.cat(out, dim=0),torch.cat(masks, dim=0),)

	class ColorToMask:

	RETURN_TYPES = ("MASK",)
	FUNCTION = "clip"
	CATEGORY = "KJNodes/masking"
	DESCRIPTION = """
	Converts chosen RGB value to a mask.
	With batch inputs, the per_batch
	controls the number of images processed at once.
	"""

	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"images": ("IMAGE",),
	"invert": ("BOOLEAN", {"default": False}),
	"red": ("INT", {"default": 0,"min": 0, "max": 255, "step": 1}),
	"green": ("INT", {"default": 0,"min": 0, "max": 255, "step": 1}),
	"blue": ("INT", {"default": 0,"min": 0, "max": 255, "step": 1}),
	"threshold": ("INT", {"default": 10,"min": 0, "max": 255, "step": 1}),
	"per_batch": ("INT", {"default": 16, "min": 1, "max": 4096, "step": 1}),
	},
	}

	def clip(self, images, red, green, blue, threshold, invert, per_batch):

	color = torch.tensor([red, green, blue], dtype=torch.uint8)
	black = torch.tensor([0, 0, 0], dtype=torch.uint8)
	white = torch.tensor([255, 255, 255], dtype=torch.uint8)

	if invert:
	black, white = white, black

	steps = images.shape[0]
	pbar = ProgressBar(steps)
	tensors_out = []

	for start_idx in range(0, images.shape[0], per_batch):

	# Calculate color distances
	color_distances = torch.norm(images[start_idx:start_idx+per_batch] * 255 - color, dim=-1)

	# Create a mask based on the threshold
	mask = color_distances <= threshold

	# Apply the mask to create new images
	mask_out = torch.where(mask.unsqueeze(-1), white, black).float()
	mask_out = mask_out.mean(dim=-1)

	tensors_out.append(mask_out.cpu())
	batch_count = mask_out.shape[0]
	pbar.update(batch_count)

	tensors_out = torch.cat(tensors_out, dim=0)
	tensors_out = torch.clamp(tensors_out, min=0.0, max=1.0)
	return tensors_out,

	class CreateFluidMask:

	RETURN_TYPES = ("IMAGE", "MASK")
	FUNCTION = "createfluidmask"
	CATEGORY = "KJNodes/masking/generate"

	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"invert": ("BOOLEAN", {"default": False}),
	"frames": ("INT", {"default": 1,"min": 1, "max": 4096, "step": 1}),
	"width": ("INT", {"default": 256,"min": 16, "max": 4096, "step": 1}),
	"height": ("INT", {"default": 256,"min": 16, "max": 4096, "step": 1}),
	"inflow_count": ("INT", {"default": 3,"min": 0, "max": 255, "step": 1}),
	"inflow_velocity": ("INT", {"default": 1,"min": 0, "max": 255, "step": 1}),
	"inflow_radius": ("INT", {"default": 8,"min": 0, "max": 255, "step": 1}),
	"inflow_padding": ("INT", {"default": 50,"min": 0, "max": 255, "step": 1}),
	"inflow_duration": ("INT", {"default": 60,"min": 0, "max": 255, "step": 1}),
	},
	}
	#using code from https://github.com/GregTJ/stable-fluids
	def createfluidmask(self, frames, width, height, invert, inflow_count, inflow_velocity, inflow_radius, inflow_padding, inflow_duration):
	from ..utility.fluid import Fluid
	try:
	from scipy.special import erf
	except:
	from scipy.spatial import erf
	out = []
	masks = []
	RESOLUTION = width, height
	DURATION = frames

	INFLOW_PADDING = inflow_padding
	INFLOW_DURATION = inflow_duration
	INFLOW_RADIUS = inflow_radius
	INFLOW_VELOCITY = inflow_velocity
	INFLOW_COUNT = inflow_count

	print('Generating fluid solver, this may take some time.')
	fluid = Fluid(RESOLUTION, 'dye')

	center = np.floor_divide(RESOLUTION, 2)
	r = np.min(center) - INFLOW_PADDING

	points = np.linspace(-np.pi, np.pi, INFLOW_COUNT, endpoint=False)
	points = tuple(np.array((np.cos(p), np.sin(p))) for p in points)
	normals = tuple(-p for p in points)
	points = tuple(r * p + center for p in points)

	inflow_velocity = np.zeros_like(fluid.velocity)
	inflow_dye = np.zeros(fluid.shape)
	for p, n in zip(points, normals):
	mask = np.linalg.norm(fluid.indices - p[:, None, None], axis=0) <= INFLOW_RADIUS
	inflow_velocity[:, mask] += n[:, None] * INFLOW_VELOCITY
	inflow_dye[mask] = 1


	for f in range(DURATION):
	print(f'Computing frame {f + 1} of {DURATION}.')
	if f <= INFLOW_DURATION:
	fluid.velocity += inflow_velocity
	fluid.dye += inflow_dye

	curl = fluid.step()[1]
	# Using the error function to make the contrast a bit higher.
	# Any other sigmoid function e.g. smoothstep would work.
	curl = (erf(curl * 2) + 1) / 4

	color = np.dstack((curl, np.ones(fluid.shape), fluid.dye))
	color = (np.clip(color, 0, 1) * 255).astype('uint8')
	image = np.array(color).astype(np.float32) / 255.0
	image = torch.from_numpy(image)[None,]
	mask = image[:, :, :, 0]
	masks.append(mask)
	out.append(image)

	if invert:
	return (1.0 - torch.cat(out, dim=0),1.0 - torch.cat(masks, dim=0),)
	return (torch.cat(out, dim=0),torch.cat(masks, dim=0),)

	class CreateAudioMask:

	RETURN_TYPES = ("IMAGE",)
	FUNCTION = "createaudiomask"
	CATEGORY = "KJNodes/deprecated"

	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"invert": ("BOOLEAN", {"default": False}),
	"frames": ("INT", {"default": 16,"min": 1, "max": 255, "step": 1}),
	"scale": ("FLOAT", {"default": 0.5,"min": 0.0, "max": 2.0, "step": 0.01}),
	"audio_path": ("STRING", {"default": "audio.wav"}),
	"width": ("INT", {"default": 256,"min": 16, "max": 4096, "step": 1}),
	"height": ("INT", {"default": 256,"min": 16, "max": 4096, "step": 1}),
	},
	}

	def createaudiomask(self, frames, width, height, invert, audio_path, scale):
	try:
	import librosa
	except ImportError:
	raise Exception("Can not import librosa. Install it with 'pip install librosa'")
	batch_size = frames
	out = []
	masks = []
	if audio_path == "audio.wav": #I don't know why relative path won't work otherwise...
	audio_path = os.path.join(script_directory, audio_path)
	audio, sr = librosa.load(audio_path)
	spectrogram = np.abs(librosa.stft(audio))

	for i in range(batch_size):
	image = Image.new("RGB", (width, height), "black")
	draw = ImageDraw.Draw(image)
	frame = spectrogram[:, i]
	circle_radius = int(height * np.mean(frame))
	circle_radius *= scale
	circle_center = (width // 2, height // 2) # Calculate the center of the image

	draw.ellipse([(circle_center[0] - circle_radius, circle_center[1] - circle_radius),
	(circle_center[0] + circle_radius, circle_center[1] + circle_radius)],
	fill='white')

	image = np.array(image).astype(np.float32) / 255.0
	image = torch.from_numpy(image)[None,]
	mask = image[:, :, :, 0]
	masks.append(mask)
	out.append(image)

	if invert:
	return (1.0 - torch.cat(out, dim=0),)
	return (torch.cat(out, dim=0),torch.cat(masks, dim=0),)

	class CreateGradientMask:

	RETURN_TYPES = ("MASK",)
	FUNCTION = "createmask"
	CATEGORY = "KJNodes/masking/generate"

	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"invert": ("BOOLEAN", {"default": False}),
	"frames": ("INT", {"default": 0,"min": 0, "max": 255, "step": 1}),
	"width": ("INT", {"default": 256,"min": 16, "max": 4096, "step": 1}),
	"height": ("INT", {"default": 256,"min": 16, "max": 4096, "step": 1}),
	},
	}
	def createmask(self, frames, width, height, invert):
	# Define the number of images in the batch
	batch_size = frames
	out = []
	# Create an empty array to store the image batch
	image_batch = np.zeros((batch_size, height, width), dtype=np.float32)
	# Generate the black to white gradient for each image
	for i in range(batch_size):
	gradient = np.linspace(1.0, 0.0, width, dtype=np.float32)
	time = i / frames # Calculate the time variable
	offset_gradient = gradient - time # Offset the gradient values based on time
	image_batch[i] = offset_gradient.reshape(1, -1)
	output = torch.from_numpy(image_batch)
	mask = output
	out.append(mask)
	if invert:
	return (1.0 - torch.cat(out, dim=0),)
	return (torch.cat(out, dim=0),)

	class CreateFadeMask:

	RETURN_TYPES = ("MASK",)
	FUNCTION = "createfademask"
	CATEGORY = "KJNodes/deprecated"

	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"invert": ("BOOLEAN", {"default": False}),
	"frames": ("INT", {"default": 2,"min": 2, "max": 255, "step": 1}),
	"width": ("INT", {"default": 256,"min": 16, "max": 4096, "step": 1}),
	"height": ("INT", {"default": 256,"min": 16, "max": 4096, "step": 1}),
	"interpolation": (["linear", "ease_in", "ease_out", "ease_in_out"],),
	"start_level": ("FLOAT", {"default": 1.0,"min": 0.0, "max": 1.0, "step": 0.01}),
	"midpoint_level": ("FLOAT", {"default": 0.5,"min": 0.0, "max": 1.0, "step": 0.01}),
	"end_level": ("FLOAT", {"default": 0.0,"min": 0.0, "max": 1.0, "step": 0.01}),
	"midpoint_frame": ("INT", {"default": 0,"min": 0, "max": 4096, "step": 1}),
	},
	}

	def createfademask(self, frames, width, height, invert, interpolation, start_level, midpoint_level, end_level, midpoint_frame):
	def ease_in(t):
	return t * t

	def ease_out(t):
	return 1 - (1 - t) * (1 - t)

	def ease_in_out(t):
	return 3 * t * t - 2 * t * t * t

	batch_size = frames
	out = []
	image_batch = np.zeros((batch_size, height, width), dtype=np.float32)

	if midpoint_frame == 0:
	midpoint_frame = batch_size // 2

	for i in range(batch_size):
	if i <= midpoint_frame:
	t = i / midpoint_frame
	if interpolation == "ease_in":
	t = ease_in(t)
	elif interpolation == "ease_out":
	t = ease_out(t)
	elif interpolation == "ease_in_out":
	t = ease_in_out(t)
	color = start_level - t * (start_level - midpoint_level)
	else:
	t = (i - midpoint_frame) / (batch_size - midpoint_frame)
	if interpolation == "ease_in":
	t = ease_in(t)
	elif interpolation == "ease_out":
	t = ease_out(t)
	elif interpolation == "ease_in_out":
	t = ease_in_out(t)
	color = midpoint_level - t * (midpoint_level - end_level)

	color = np.clip(color, 0, 255)
	image = np.full((height, width), color, dtype=np.float32)
	image_batch[i] = image

	output = torch.from_numpy(image_batch)
	mask = output
	out.append(mask)

	if invert:
	return (1.0 - torch.cat(out, dim=0),)
	return (torch.cat(out, dim=0),)

	class CreateFadeMaskAdvanced:

	RETURN_TYPES = ("MASK",)
	FUNCTION = "createfademask"
	CATEGORY = "KJNodes/masking/generate"
	DESCRIPTION = """
	Create a batch of masks interpolated between given frames and values.
	Uses same syntax as Fizz' BatchValueSchedule.
	First value is the frame index (not that this starts from 0, not 1)
	and the second value inside the brackets is the float value of the mask in range 0.0 - 1.0

	For example the default values:
	0:(0.0)
	7:(1.0)
	15:(0.0)

	Would create a mask batch fo 16 frames, starting from black,
	interpolating with the chosen curve to fully white at the 8th frame,
	and interpolating from that to fully black at the 16th frame.
	"""

	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"points_string": ("STRING", {"default": "0:(0.0),\n7:(1.0),\n15:(0.0)\n", "multiline": True}),
	"invert": ("BOOLEAN", {"default": False}),
	"frames": ("INT", {"default": 16,"min": 2, "max": 255, "step": 1}),
	"width": ("INT", {"default": 512,"min": 1, "max": 4096, "step": 1}),
	"height": ("INT", {"default": 512,"min": 1, "max": 4096, "step": 1}),
	"interpolation": (["linear", "ease_in", "ease_out", "ease_in_out"],),
	},
	}

	def createfademask(self, frames, width, height, invert, points_string, interpolation):
	def ease_in(t):
	return t * t

	def ease_out(t):
	return 1 - (1 - t) * (1 - t)

	def ease_in_out(t):
	return 3 * t * t - 2 * t * t * t

	# Parse the input string into a list of tuples
	points = []
	points_string = points_string.rstrip(',\n')
	for point_str in points_string.split(','):
	frame_str, color_str = point_str.split(':')
	frame = int(frame_str.strip())
	color = float(color_str.strip()[1:-1]) # Remove parentheses around color
	points.append((frame, color))

	# Check if the last frame is already in the points
	if len(points) == 0 or points[-1][0] != frames - 1:
	# If not, add it with the color of the last specified frame
	points.append((frames - 1, points[-1][1] if points else 0))

	# Sort the points by frame number
	points.sort(key=lambda x: x[0])

	batch_size = frames
	out = []
	image_batch = np.zeros((batch_size, height, width), dtype=np.float32)

	# Index of the next point to interpolate towards
	next_point = 1

	for i in range(batch_size):
	while next_point < len(points) and i > points[next_point][0]:
	next_point += 1

	# Interpolate between the previous point and the next point
	prev_point = next_point - 1
	t = (i - points[prev_point][0]) / (points[next_point][0] - points[prev_point][0])
	if interpolation == "ease_in":
	t = ease_in(t)
	elif interpolation == "ease_out":
	t = ease_out(t)
	elif interpolation == "ease_in_out":
	t = ease_in_out(t)
	elif interpolation == "linear":
	pass # No need to modify `t` for linear interpolation

	color = points[prev_point][1] - t * (points[prev_point][1] - points[next_point][1])
	color = np.clip(color, 0, 255)
	image = np.full((height, width), color, dtype=np.float32)
	image_batch[i] = image

	output = torch.from_numpy(image_batch)
	mask = output
	out.append(mask)

	if invert:
	return (1.0 - torch.cat(out, dim=0),)
	return (torch.cat(out, dim=0),)

	class CreateMagicMask:

	RETURN_TYPES = ("MASK", "MASK",)
	RETURN_NAMES = ("mask", "mask_inverted",)
	FUNCTION = "createmagicmask"
	CATEGORY = "KJNodes/masking/generate"

	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"frames": ("INT", {"default": 16,"min": 2, "max": 4096, "step": 1}),
	"depth": ("INT", {"default": 12,"min": 1, "max": 500, "step": 1}),
	"distortion": ("FLOAT", {"default": 1.5,"min": 0.0, "max": 100.0, "step": 0.01}),
	"seed": ("INT", {"default": 123,"min": 0, "max": 99999999, "step": 1}),
	"transitions": ("INT", {"default": 1,"min": 1, "max": 20, "step": 1}),
	"frame_width": ("INT", {"default": 512,"min": 16, "max": 4096, "step": 1}),
	"frame_height": ("INT", {"default": 512,"min": 16, "max": 4096, "step": 1}),
	},
	}

	def createmagicmask(self, frames, transitions, depth, distortion, seed, frame_width, frame_height):
	from ..utility.magictex import coordinate_grid, random_transform, magic
	import matplotlib.pyplot as plt
	rng = np.random.default_rng(seed)
	out = []
	coords = coordinate_grid((frame_width, frame_height))

	# Calculate the number of frames for each transition
	frames_per_transition = frames // transitions

	# Generate a base set of parameters
	base_params = {
	"coords": random_transform(coords, rng),
	"depth": depth,
	"distortion": distortion,
	}
	for t in range(transitions):
	# Generate a second set of parameters that is at most max_diff away from the base parameters
	params1 = base_params.copy()
	params2 = base_params.copy()

	params1['coords'] = random_transform(coords, rng)
	params2['coords'] = random_transform(coords, rng)

	for i in range(frames_per_transition):
	# Compute the interpolation factor
	alpha = i / frames_per_transition

	# Interpolate between the two sets of parameters
	params = params1.copy()
	params['coords'] = (1 - alpha) * params1['coords'] + alpha * params2['coords']

	tex = magic(**params)

	dpi = frame_width / 10
	fig = plt.figure(figsize=(10, 10), dpi=dpi)

	ax = fig.add_subplot(111)
	plt.subplots_adjust(left=0, right=1, bottom=0, top=1)

	ax.get_yaxis().set_ticks([])
	ax.get_xaxis().set_ticks([])
	ax.imshow(tex, aspect='auto')

	fig.canvas.draw()
	img = np.array(fig.canvas.renderer._renderer)

	plt.close(fig)

	pil_img = Image.fromarray(img).convert("L")
	mask = torch.tensor(np.array(pil_img)) / 255.0

	out.append(mask)

	return (torch.stack(out, dim=0), 1.0 - torch.stack(out, dim=0),)

	class CreateShapeMask:

	RETURN_TYPES = ("MASK", "MASK",)
	RETURN_NAMES = ("mask", "mask_inverted",)
	FUNCTION = "createshapemask"
	CATEGORY = "KJNodes/masking/generate"
	DESCRIPTION = """
	Creates a mask or batch of masks with the specified shape.
	Locations are center locations.
	Grow value is the amount to grow the shape on each frame, creating animated masks.
	"""

	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"shape": (
	[ 'circle',
	'square',
	'triangle',
	],
	{
	"default": 'circle'
	}),
	"frames": ("INT", {"default": 1,"min": 1, "max": 4096, "step": 1}),
	"location_x": ("INT", {"default": 256,"min": 0, "max": 4096, "step": 1}),
	"location_y": ("INT", {"default": 256,"min": 0, "max": 4096, "step": 1}),
	"grow": ("INT", {"default": 0, "min": -512, "max": 512, "step": 1}),
	"frame_width": ("INT", {"default": 512,"min": 16, "max": 4096, "step": 1}),
	"frame_height": ("INT", {"default": 512,"min": 16, "max": 4096, "step": 1}),
	"shape_width": ("INT", {"default": 128,"min": 8, "max": 4096, "step": 1}),
	"shape_height": ("INT", {"default": 128,"min": 8, "max": 4096, "step": 1}),
	},
	}

	def createshapemask(self, frames, frame_width, frame_height, location_x, location_y, shape_width, shape_height, grow, shape):
	# Define the number of images in the batch
	batch_size = frames
	out = []
	color = "white"
	for i in range(batch_size):
	image = Image.new("RGB", (frame_width, frame_height), "black")
	draw = ImageDraw.Draw(image)

	# Calculate the size for this frame and ensure it's not less than 0
	current_width = max(0, shape_width + i*grow)
	current_height = max(0, shape_height + i*grow)

	if shape == 'circle' or shape == 'square':
	# Define the bounding box for the shape
	left_up_point = (location_x - current_width // 2, location_y - current_height // 2)
	right_down_point = (location_x + current_width // 2, location_y + current_height // 2)
	two_points = [left_up_point, right_down_point]

	if shape == 'circle':
	draw.ellipse(two_points, fill=color)
	elif shape == 'square':
	draw.rectangle(two_points, fill=color)

	elif shape == 'triangle':
	# Define the points for the triangle
	left_up_point = (location_x - current_width // 2, location_y + current_height // 2) # bottom left
	right_down_point = (location_x + current_width // 2, location_y + current_height // 2) # bottom right
	top_point = (location_x, location_y - current_height // 2) # top point
	draw.polygon([top_point, left_up_point, right_down_point], fill=color)

	image = pil2tensor(image)
	mask = image[:, :, :, 0]
	out.append(mask)
	outstack = torch.cat(out, dim=0)
	return (outstack, 1.0 - outstack,)

	class CreateVoronoiMask:

	RETURN_TYPES = ("MASK", "MASK",)
	RETURN_NAMES = ("mask", "mask_inverted",)
	FUNCTION = "createvoronoi"
	CATEGORY = "KJNodes/masking/generate"

	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"frames": ("INT", {"default": 16,"min": 2, "max": 4096, "step": 1}),
	"num_points": ("INT", {"default": 15,"min": 1, "max": 4096, "step": 1}),
	"line_width": ("INT", {"default": 4,"min": 1, "max": 4096, "step": 1}),
	"speed": ("FLOAT", {"default": 0.5,"min": 0.0, "max": 1.0, "step": 0.01}),
	"frame_width": ("INT", {"default": 512,"min": 16, "max": 4096, "step": 1}),
	"frame_height": ("INT", {"default": 512,"min": 16, "max": 4096, "step": 1}),
	},
	}

	def createvoronoi(self, frames, num_points, line_width, speed, frame_width, frame_height):
	from scipy.spatial import Voronoi
	# Define the number of images in the batch
	batch_size = frames
	out = []

	# Calculate aspect ratio
	aspect_ratio = frame_width / frame_height

	# Create start and end points for each point, considering the aspect ratio
	start_points = np.random.rand(num_points, 2)
	start_points[:, 0] *= aspect_ratio

	end_points = np.random.rand(num_points, 2)
	end_points[:, 0] *= aspect_ratio

	for i in range(batch_size):
	# Interpolate the points' positions based on the current frame
	t = (i * speed) / (batch_size - 1) # normalize to [0, 1] over the frames
	t = np.clip(t, 0, 1) # ensure t is in [0, 1]
	points = (1 - t) * start_points + t * end_points # lerp

	# Adjust points for aspect ratio
	points[:, 0] *= aspect_ratio

	vor = Voronoi(points)

	# Create a blank image with a white background
	fig, ax = plt.subplots()
	plt.subplots_adjust(left=0, right=1, bottom=0, top=1)
	ax.set_xlim([0, aspect_ratio]); ax.set_ylim([0, 1]) # adjust x limits
	ax.axis('off')
	ax.margins(0, 0)
	fig.set_size_inches(aspect_ratio * frame_height/100, frame_height/100) # adjust figure size
	ax.fill_between([0, 1], [0, 1], color='white')

	# Plot each Voronoi ridge
	for simplex in vor.ridge_vertices:
	simplex = np.asarray(simplex)
	if np.all(simplex >= 0):
	plt.plot(vor.vertices[simplex, 0], vor.vertices[simplex, 1], 'k-', linewidth=line_width)

	fig.canvas.draw()
	img = np.array(fig.canvas.renderer._renderer)

	plt.close(fig)

	pil_img = Image.fromarray(img).convert("L")
	mask = torch.tensor(np.array(pil_img)) / 255.0

	out.append(mask)

	return (torch.stack(out, dim=0), 1.0 - torch.stack(out, dim=0),)

	class GetMaskSizeAndCount:
	@classmethod
	def INPUT_TYPES(s):
	return {"required": {
	"mask": ("MASK",),
	}}

	RETURN_TYPES = ("MASK","INT", "INT", "INT",)
	RETURN_NAMES = ("mask", "width", "height", "count",)
	FUNCTION = "getsize"
	CATEGORY = "KJNodes/masking"
	DESCRIPTION = """
	Returns the width, height and batch size of the mask,
	and passes it through unchanged.

	"""

	def getsize(self, mask):
	width = mask.shape[2]
	height = mask.shape[1]
	count = mask.shape[0]
	return {"ui": {
	"text": [f"{count}x{width}x{height}"]},
	"result": (mask, width, height, count)
	}

	class GrowMaskWithBlur:
	@classmethod
	def INPUT_TYPES(cls):
	return {
	"required": {
	"mask": ("MASK",),
	"expand": ("INT", {"default": 0, "min": -MAX_RESOLUTION, "max": MAX_RESOLUTION, "step": 1}),
	"incremental_expandrate": ("FLOAT", {"default": 0.0, "min": 0.0, "max": 100.0, "step": 0.1}),
	"tapered_corners": ("BOOLEAN", {"default": True}),
	"flip_input": ("BOOLEAN", {"default": False}),
	"blur_radius": ("FLOAT", {
	"default": 0.0,
	"min": 0.0,
	"max": 100,
	"step": 0.1
	}),
	"lerp_alpha": ("FLOAT", {"default": 1.0, "min": 0.0, "max": 1.0, "step": 0.01}),
	"decay_factor": ("FLOAT", {"default": 1.0, "min": 0.0, "max": 1.0, "step": 0.01}),
	},
	"optional": {
	"fill_holes": ("BOOLEAN", {"default": False}),
	},
	}

	CATEGORY = "KJNodes/masking"
	RETURN_TYPES = ("MASK", "MASK",)
	RETURN_NAMES = ("mask", "mask_inverted",)
	FUNCTION = "expand_mask"
	DESCRIPTION = """
	# GrowMaskWithBlur
	- mask: Input mask or mask batch
	- expand: Expand or contract mask or mask batch by a given amount
	- incremental_expandrate: increase expand rate by a given amount per frame
	- tapered_corners: use tapered corners
	- flip_input: flip input mask
	- blur_radius: value higher than 0 will blur the mask
	- lerp_alpha: alpha value for interpolation between frames
	- decay_factor: decay value for interpolation between frames
	- fill_holes: fill holes in the mask (slow)"""

	def expand_mask(self, mask, expand, tapered_corners, flip_input, blur_radius, incremental_expandrate, lerp_alpha, decay_factor, fill_holes=False):
	alpha = lerp_alpha
	decay = decay_factor
	if flip_input:
	mask = 1.0 - mask
	c = 0 if tapered_corners else 1
	kernel = np.array([[c, 1, c],
	[1, 1, 1],
	[c, 1, c]])
	growmask = mask.reshape((-1, mask.shape[-2], mask.shape[-1])).cpu()
	out = []
	previous_output = None
	current_expand = expand
	for m in growmask:
	output = m.numpy().astype(np.float32)
	for _ in range(abs(round(current_expand))):
	if current_expand < 0:
	output = scipy.ndimage.grey_erosion(output, footprint=kernel)
	else:
	output = scipy.ndimage.grey_dilation(output, footprint=kernel)
	if current_expand < 0:
	current_expand -= abs(incremental_expandrate)
	else:
	current_expand += abs(incremental_expandrate)
	if fill_holes:
	binary_mask = output > 0
	output = scipy.ndimage.binary_fill_holes(binary_mask)
	output = output.astype(np.float32) * 255
	output = torch.from_numpy(output)
	if alpha < 1.0 and previous_output is not None:
	# Interpolate between the previous and current frame
	output = alpha * output + (1 - alpha) * previous_output
	if decay < 1.0 and previous_output is not None:
	# Add the decayed previous output to the current frame
	output += decay * previous_output
	output = output / output.max()
	previous_output = output
	out.append(output)

	if blur_radius != 0:
	# Convert the tensor list to PIL images, apply blur, and convert back
	for idx, tensor in enumerate(out):
	# Convert tensor to PIL image
	pil_image = tensor2pil(tensor.cpu().detach())[0]
	# Apply Gaussian blur
	pil_image = pil_image.filter(ImageFilter.GaussianBlur(blur_radius))
	# Convert back to tensor
	out[idx] = pil2tensor(pil_image)
	blurred = torch.cat(out, dim=0)
	return (blurred, 1.0 - blurred)
	else:
	return (torch.stack(out, dim=0), 1.0 - torch.stack(out, dim=0),)

	class MaskBatchMulti:
	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"inputcount": ("INT", {"default": 2, "min": 2, "max": 1000, "step": 1}),
	"mask_1": ("MASK", ),
	"mask_2": ("MASK", ),
	},
	}

	RETURN_TYPES = ("MASK",)
	RETURN_NAMES = ("masks",)
	FUNCTION = "combine"
	CATEGORY = "KJNodes/masking"
	DESCRIPTION = """
	Creates an image batch from multiple masks.
	You can set how many inputs the node has,
	with the inputcount and clicking update.
	"""

	def combine(self, inputcount, **kwargs):
	mask = kwargs["mask_1"]
	for c in range(1, inputcount):
	new_mask = kwargs[f"mask_{c + 1}"]
	if mask.shape[1:] != new_mask.shape[1:]:
	new_mask = F.interpolate(new_mask.unsqueeze(1), size=(mask.shape[1], mask.shape[2]), mode="bicubic").squeeze(1)
	mask = torch.cat((mask, new_mask), dim=0)
	return (mask,)

	class OffsetMask:
	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"mask": ("MASK",),
	"x": ("INT", { "default": 0, "min": -4096, "max": MAX_RESOLUTION, "step": 1, "display": "number" }),
	"y": ("INT", { "default": 0, "min": -4096, "max": MAX_RESOLUTION, "step": 1, "display": "number" }),
	"angle": ("INT", { "default": 0, "min": -360, "max": 360, "step": 1, "display": "number" }),
	"duplication_factor": ("INT", { "default": 1, "min": 1, "max": 1000, "step": 1, "display": "number" }),
	"roll": ("BOOLEAN", { "default": False }),
	"incremental": ("BOOLEAN", { "default": False }),
	"padding_mode": (
	[
	'empty',
	'border',
	'reflection',

	], {
	"default": 'empty'
	}),
	}
	}

	RETURN_TYPES = ("MASK",)
	RETURN_NAMES = ("mask",)
	FUNCTION = "offset"
	CATEGORY = "KJNodes/masking"
	DESCRIPTION = """
	Offsets the mask by the specified amount.
	- mask: Input mask or mask batch
	- x: Horizontal offset
	- y: Vertical offset
	- angle: Angle in degrees
	- roll: roll edge wrapping
	- duplication_factor: Number of times to duplicate the mask to form a batch
	- border padding_mode: Padding mode for the mask
	"""

	def offset(self, mask, x, y, angle, roll=False, incremental=False, duplication_factor=1, padding_mode="empty"):
	# Create duplicates of the mask batch
	mask = mask.repeat(duplication_factor, 1, 1).clone()

	batch_size, height, width = mask.shape

	if angle != 0 and incremental:
	for i in range(batch_size):
	rotation_angle = angle * (i+1)
	mask[i] = TF.rotate(mask[i].unsqueeze(0), rotation_angle).squeeze(0)
	elif angle > 0:
	for i in range(batch_size):
	mask[i] = TF.rotate(mask[i].unsqueeze(0), angle).squeeze(0)

	if roll:
	if incremental:
	for i in range(batch_size):
	shift_x = min(x*(i+1), width-1)
	shift_y = min(y*(i+1), height-1)
	if shift_x != 0:
	mask[i] = torch.roll(mask[i], shifts=shift_x, dims=1)
	if shift_y != 0:
	mask[i] = torch.roll(mask[i], shifts=shift_y, dims=0)
	else:
	shift_x = min(x, width-1)
	shift_y = min(y, height-1)
	if shift_x != 0:
	mask = torch.roll(mask, shifts=shift_x, dims=2)
	if shift_y != 0:
	mask = torch.roll(mask, shifts=shift_y, dims=1)
	else:

	for i in range(batch_size):
	if incremental:
	temp_x = min(x * (i+1), width-1)
	temp_y = min(y * (i+1), height-1)
	else:
	temp_x = min(x, width-1)
	temp_y = min(y, height-1)
	if temp_x > 0:
	if padding_mode == 'empty':
	mask[i] = torch.cat([torch.zeros((height, temp_x)), mask[i, :, :-temp_x]], dim=1)
	elif padding_mode in ['replicate', 'reflect']:
	mask[i] = F.pad(mask[i, :, :-temp_x], (0, temp_x), mode=padding_mode)
	elif temp_x < 0:
	if padding_mode == 'empty':
	mask[i] = torch.cat([mask[i, :, :temp_x], torch.zeros((height, -temp_x))], dim=1)
	elif padding_mode in ['replicate', 'reflect']:
	mask[i] = F.pad(mask[i, :, -temp_x:], (temp_x, 0), mode=padding_mode)

	if temp_y > 0:
	if padding_mode == 'empty':
	mask[i] = torch.cat([torch.zeros((temp_y, width)), mask[i, :-temp_y, :]], dim=0)
	elif padding_mode in ['replicate', 'reflect']:
	mask[i] = F.pad(mask[i, :-temp_y, :], (0, temp_y), mode=padding_mode)
	elif temp_y < 0:
	if padding_mode == 'empty':
	mask[i] = torch.cat([mask[i, :temp_y, :], torch.zeros((-temp_y, width))], dim=0)
	elif padding_mode in ['replicate', 'reflect']:
	mask[i] = F.pad(mask[i, -temp_y:, :], (temp_y, 0), mode=padding_mode)

	return mask,

	class RoundMask:
	@classmethod
	def INPUT_TYPES(s):
	return {"required": {
	"mask": ("MASK",),
	}}

	RETURN_TYPES = ("MASK",)
	FUNCTION = "round"
	CATEGORY = "KJNodes/masking"
	DESCRIPTION = """
	Rounds the mask or batch of masks to a binary mask.
	<img src="https://github.com/kijai/ComfyUI-KJNodes/assets/40791699/52c85202-f74e-4b96-9dac-c8bda5ddcc40" width="300" height="250" alt="RoundMask example">

	"""

	def round(self, mask):
	mask = mask.round()
	return (mask,)

	class ResizeMask:
	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"mask": ("MASK",),
	"width": ("INT", { "default": 512, "min": 0, "max": MAX_RESOLUTION, "step": 8, "display": "number" }),
	"height": ("INT", { "default": 512, "min": 0, "max": MAX_RESOLUTION, "step": 8, "display": "number" }),
	"keep_proportions": ("BOOLEAN", { "default": False }),
	}
	}

	RETURN_TYPES = ("MASK", "INT", "INT",)
	RETURN_NAMES = ("mask", "width", "height",)
	FUNCTION = "resize"
	CATEGORY = "KJNodes/masking"
	DESCRIPTION = """
	Resizes the mask or batch of masks to the specified width and height.
	"""

	def resize(self, mask, width, height, keep_proportions):
	if keep_proportions:
	_, oh, ow = mask.shape
	width = ow if width == 0 else width
	height = oh if height == 0 else height
	ratio = min(width / ow, height / oh)
	width = round(ow*ratio)
	height = round(oh*ratio)
	outputs = mask.unsqueeze(1)
	outputs = F.interpolate(outputs, size=(height, width), mode="nearest")
	outputs = outputs.squeeze(1)

	return(outputs, outputs.shape[2], outputs.shape[1],)

	class RemapMaskRange:
	@classmethod
	def INPUT_TYPES(s):
	return {
	"required": {
	"mask": ("MASK",),
	"min": ("FLOAT", {"default": 0.0,"min": -10.0, "max": 1.0, "step": 0.01}),
	"max": ("FLOAT", {"default": 1.0,"min": 0.0, "max": 10.0, "step": 0.01}),
	}
	}

	RETURN_TYPES = ("MASK",)
	RETURN_NAMES = ("mask",)
	FUNCTION = "remap"
	CATEGORY = "KJNodes/masking"
	DESCRIPTION = """
	Sets new min and max values for the mask.
	"""

	def remap(self, mask, min, max):

	# Find the maximum value in the mask
	mask_max = torch.max(mask)

	# If the maximum mask value is zero, avoid division by zero by setting it to 1
	mask_max = mask_max if mask_max > 0 else 1

	# Scale the mask values to the new range defined by min and max
	# The highest pixel value in the mask will be scaled to max
	scaled_mask = (mask / mask_max) * (max - min) + min

	# Clamp the values to ensure they are within [0.0, 1.0]
	scaled_mask = torch.clamp(scaled_mask, min=0.0, max=1.0)

	return (scaled_mask, )