from typing_extensions import override import numpy as np import torch import torch.nn.functional as F from PIL import Image import math from enum import Enum from typing import TypedDict, Literal import kornia import comfy.utils import comfy.model_management from comfy_extras.nodes_latent import reshape_latent_to import node_helpers from comfy_api.latest import ComfyExtension, io from nodes import MAX_RESOLUTION class Blend(io.ComfyNode): @classmethod def define_schema(cls): return io.Schema( node_id="ImageBlend", search_aliases=["mix images"], display_name="Blend Images", category="image/filters", essentials_category="Image Tools", inputs=[ io.Image.Input("image1"), io.Image.Input("image2"), io.Float.Input("blend_factor", default=0.5, min=0.0, max=1.0, step=0.01), io.Combo.Input("blend_mode", options=["normal", "multiply", "screen", "overlay", "soft_light", "difference"]), ], outputs=[ io.Image.Output(), ], ) @classmethod def execute(cls, image1: torch.Tensor, image2: torch.Tensor, blend_factor: float, blend_mode: str) -> io.NodeOutput: image1, image2 = node_helpers.image_alpha_fix(image1, image2) image2 = image2.to(image1.device) if image1.shape != image2.shape: image2 = image2.permute(0, 3, 1, 2) image2 = comfy.utils.common_upscale(image2, image1.shape[2], image1.shape[1], upscale_method='bicubic', crop='center') image2 = image2.permute(0, 2, 3, 1) blended_image = cls.blend_mode(image1, image2, blend_mode) blended_image = image1 * (1 - blend_factor) + blended_image * blend_factor blended_image = torch.clamp(blended_image, 0, 1) return io.NodeOutput(blended_image) @classmethod def blend_mode(cls, img1, img2, mode): if mode == "normal": return img2 elif mode == "multiply": return img1 * img2 elif mode == "screen": return 1 - (1 - img1) * (1 - img2) elif mode == "overlay": return torch.where(img1 <= 0.5, 2 * img1 * img2, 1 - 2 * (1 - img1) * (1 - img2)) elif mode == "soft_light": return torch.where(img2 <= 0.5, img1 - (1 - 2 * img2) * img1 * (1 - img1), img1 + (2 * img2 - 1) * (cls.g(img1) - img1)) elif mode == "difference": return img1 - img2 raise ValueError(f"Unsupported blend mode: {mode}") @classmethod def g(cls, x): return torch.where(x <= 0.25, ((16 * x - 12) * x + 4) * x, torch.sqrt(x)) def gaussian_kernel(kernel_size: int, sigma: float, device=None, dtype=torch.float32): x, y = torch.meshgrid(torch.linspace(-1, 1, kernel_size, device=device), torch.linspace(-1, 1, kernel_size, device=device), indexing="ij") d = torch.sqrt(x * x + y * y) g = torch.exp(-(d * d) / (2.0 * sigma * sigma)) return (g / g.sum()).to(dtype) class Blur(io.ComfyNode): @classmethod def define_schema(cls): return io.Schema( node_id="ImageBlur", display_name="Blur Image", category="image/filters", inputs=[ io.Image.Input("image"), io.Int.Input("blur_radius", default=1, min=1, max=31, step=1), io.Float.Input("sigma", default=1.0, min=0.1, max=10.0, step=0.1), ], outputs=[ io.Image.Output(), ], ) @classmethod def execute(cls, image: torch.Tensor, blur_radius: int, sigma: float) -> io.NodeOutput: if blur_radius == 0: return io.NodeOutput(image) image = image.to(comfy.model_management.get_torch_device()) batch_size, height, width, channels = image.shape kernel_size = blur_radius * 2 + 1 kernel = gaussian_kernel(kernel_size, sigma, device=image.device, dtype=image.dtype).repeat(channels, 1, 1).unsqueeze(1) image = image.permute(0, 3, 1, 2) # Torch wants (B, C, H, W) we use (B, H, W, C) padded_image = F.pad(image, (blur_radius,blur_radius,blur_radius,blur_radius), 'reflect') blurred = F.conv2d(padded_image, kernel, padding=kernel_size // 2, groups=channels)[:,:,blur_radius:-blur_radius, blur_radius:-blur_radius] blurred = blurred.permute(0, 2, 3, 1) return io.NodeOutput(blurred.to(comfy.model_management.intermediate_device())) class Quantize(io.ComfyNode): @classmethod def define_schema(cls): return io.Schema( node_id="ImageQuantize", display_name="Quantize Image", category="image/filters", inputs=[ io.Image.Input("image"), io.Int.Input("colors", default=256, min=1, max=256, step=1), io.Combo.Input("dither", options=["none", "floyd-steinberg", "bayer-2", "bayer-4", "bayer-8", "bayer-16"]), ], outputs=[ io.Image.Output(), ], ) @staticmethod def bayer(im, pal_im, order): def normalized_bayer_matrix(n): if n == 0: return np.zeros((1,1), "float32") else: q = 4 ** n m = q * normalized_bayer_matrix(n - 1) return np.bmat(((m-1.5, m+0.5), (m+1.5, m-0.5))) / q num_colors = len(pal_im.getpalette()) // 3 spread = 2 * 256 / num_colors bayer_n = int(math.log2(order)) bayer_matrix = torch.from_numpy(spread * normalized_bayer_matrix(bayer_n) + 0.5) result = torch.from_numpy(np.array(im).astype(np.float32)) tw = math.ceil(result.shape[0] / bayer_matrix.shape[0]) th = math.ceil(result.shape[1] / bayer_matrix.shape[1]) tiled_matrix = bayer_matrix.tile(tw, th).unsqueeze(-1) result.add_(tiled_matrix[:result.shape[0],:result.shape[1]]).clamp_(0, 255) result = result.to(dtype=torch.uint8) im = Image.fromarray(result.cpu().numpy()) im = im.quantize(palette=pal_im, dither=Image.Dither.NONE) return im @classmethod def execute(cls, image: torch.Tensor, colors: int, dither: str) -> io.NodeOutput: batch_size, height, width, _ = image.shape result = torch.zeros_like(image) for b in range(batch_size): im = Image.fromarray((image[b] * 255).to(torch.uint8).numpy(), mode='RGB') pal_im = im.quantize(colors=colors) # Required as described in https://github.com/python-pillow/Pillow/issues/5836 if dither == "none": quantized_image = im.quantize(palette=pal_im, dither=Image.Dither.NONE) elif dither == "floyd-steinberg": quantized_image = im.quantize(palette=pal_im, dither=Image.Dither.FLOYDSTEINBERG) elif dither.startswith("bayer"): order = int(dither.split('-')[-1]) quantized_image = Quantize.bayer(im, pal_im, order) quantized_array = torch.tensor(np.array(quantized_image.convert("RGB"))).float() / 255 result[b] = quantized_array return io.NodeOutput(result) class Sharpen(io.ComfyNode): @classmethod def define_schema(cls): return io.Schema( node_id="ImageSharpen", display_name="Sharpen Image", category="image/filters", inputs=[ io.Image.Input("image"), io.Int.Input("sharpen_radius", default=1, min=1, max=31, step=1, advanced=True), io.Float.Input("sigma", default=1.0, min=0.1, max=10.0, step=0.01, advanced=True), io.Float.Input("alpha", default=1.0, min=0.0, max=5.0, step=0.01, advanced=True), ], outputs=[ io.Image.Output(), ], ) @classmethod def execute(cls, image: torch.Tensor, sharpen_radius: int, sigma:float, alpha: float) -> io.NodeOutput: if sharpen_radius == 0: return io.NodeOutput(image) batch_size, height, width, channels = image.shape image = image.to(comfy.model_management.get_torch_device()) kernel_size = sharpen_radius * 2 + 1 kernel = gaussian_kernel(kernel_size, sigma, device=image.device, dtype=image.dtype) * -(alpha*10) kernel = kernel.to(dtype=image.dtype) center = kernel_size // 2 kernel[center, center] = kernel[center, center] - kernel.sum() + 1.0 kernel = kernel.repeat(channels, 1, 1).unsqueeze(1) tensor_image = image.permute(0, 3, 1, 2) # Torch wants (B, C, H, W) we use (B, H, W, C) tensor_image = F.pad(tensor_image, (sharpen_radius,sharpen_radius,sharpen_radius,sharpen_radius), 'reflect') sharpened = F.conv2d(tensor_image, kernel, padding=center, groups=channels)[:,:,sharpen_radius:-sharpen_radius, sharpen_radius:-sharpen_radius] sharpened = sharpened.permute(0, 2, 3, 1) result = torch.clamp(sharpened, 0, 1) return io.NodeOutput(result.to(comfy.model_management.intermediate_device())) class ImageScaleToTotalPixels(io.ComfyNode): upscale_methods = ["nearest-exact", "bilinear", "area", "bicubic", "lanczos"] crop_methods = ["disabled", "center"] @classmethod def define_schema(cls): return io.Schema( node_id="ImageScaleToTotalPixels", display_name="Scale Image to Total Pixels", category="image/upscaling", inputs=[ io.Image.Input("image"), io.Combo.Input("upscale_method", options=cls.upscale_methods), io.Float.Input("megapixels", default=1.0, min=0.01, max=16.0, step=0.01), io.Int.Input("resolution_steps", default=1, min=1, max=256, advanced=True), ], outputs=[ io.Image.Output(), ], ) @classmethod def execute(cls, image, upscale_method, megapixels, resolution_steps) -> io.NodeOutput: samples = image.movedim(-1,1) total = megapixels * 1024 * 1024 scale_by = math.sqrt(total / (samples.shape[3] * samples.shape[2])) width = round(samples.shape[3] * scale_by / resolution_steps) * resolution_steps height = round(samples.shape[2] * scale_by / resolution_steps) * resolution_steps s = comfy.utils.common_upscale(samples, int(width), int(height), upscale_method, "disabled") s = s.movedim(1,-1) return io.NodeOutput(s) class ResizeType(str, Enum): SCALE_BY = "scale by multiplier" SCALE_DIMENSIONS = "scale dimensions" SCALE_LONGER_DIMENSION = "scale longer dimension" SCALE_SHORTER_DIMENSION = "scale shorter dimension" SCALE_WIDTH = "scale width" SCALE_HEIGHT = "scale height" SCALE_TOTAL_PIXELS = "scale total pixels" MATCH_SIZE = "match size" SCALE_TO_MULTIPLE = "scale to multiple" def is_image(input: torch.Tensor) -> bool: # images have 4 dimensions: [batch, height, width, channels] # masks have 3 dimensions: [batch, height, width] return len(input.shape) == 4 def init_image_mask_input(input: torch.Tensor, is_type_image: bool) -> torch.Tensor: if is_type_image: input = input.movedim(-1, 1) else: input = input.unsqueeze(1) return input def finalize_image_mask_input(input: torch.Tensor, is_type_image: bool) -> torch.Tensor: if is_type_image: input = input.movedim(1, -1) else: input = input.squeeze(1) return input def scale_by(input: torch.Tensor, multiplier: float, scale_method: str) -> torch.Tensor: is_type_image = is_image(input) input = init_image_mask_input(input, is_type_image) width = round(input.shape[-1] * multiplier) height = round(input.shape[-2] * multiplier) input = comfy.utils.common_upscale(input, width, height, scale_method, "disabled") input = finalize_image_mask_input(input, is_type_image) return input def scale_dimensions(input: torch.Tensor, width: int, height: int, scale_method: str, crop: str="disabled") -> torch.Tensor: if width == 0 and height == 0: return input is_type_image = is_image(input) input = init_image_mask_input(input, is_type_image) if width == 0: width = max(1, round(input.shape[-1] * height / input.shape[-2])) elif height == 0: height = max(1, round(input.shape[-2] * width / input.shape[-1])) input = comfy.utils.common_upscale(input, width, height, scale_method, crop) input = finalize_image_mask_input(input, is_type_image) return input def scale_longer_dimension(input: torch.Tensor, longer_size: int, scale_method: str) -> torch.Tensor: is_type_image = is_image(input) input = init_image_mask_input(input, is_type_image) width = input.shape[-1] height = input.shape[-2] if height > width: width = round((width / height) * longer_size) height = longer_size elif width > height: height = round((height / width) * longer_size) width = longer_size else: height = longer_size width = longer_size input = comfy.utils.common_upscale(input, width, height, scale_method, "disabled") input = finalize_image_mask_input(input, is_type_image) return input def scale_shorter_dimension(input: torch.Tensor, shorter_size: int, scale_method: str) -> torch.Tensor: is_type_image = is_image(input) input = init_image_mask_input(input, is_type_image) width = input.shape[-1] height = input.shape[-2] if height < width: width = round((width / height) * shorter_size) height = shorter_size elif width < height: height = round((height / width) * shorter_size) width = shorter_size else: height = shorter_size width = shorter_size input = comfy.utils.common_upscale(input, width, height, scale_method, "disabled") input = finalize_image_mask_input(input, is_type_image) return input def scale_total_pixels(input: torch.Tensor, megapixels: float, scale_method: str) -> torch.Tensor: is_type_image = is_image(input) input = init_image_mask_input(input, is_type_image) total = int(megapixels * 1024 * 1024) scale_by = math.sqrt(total / (input.shape[-1] * input.shape[-2])) width = round(input.shape[-1] * scale_by) height = round(input.shape[-2] * scale_by) input = comfy.utils.common_upscale(input, width, height, scale_method, "disabled") input = finalize_image_mask_input(input, is_type_image) return input def scale_match_size(input: torch.Tensor, match: torch.Tensor, scale_method: str, crop: str) -> torch.Tensor: is_type_image = is_image(input) input = init_image_mask_input(input, is_type_image) match = init_image_mask_input(match, is_image(match)) width = match.shape[-1] height = match.shape[-2] input = comfy.utils.common_upscale(input, width, height, scale_method, crop) input = finalize_image_mask_input(input, is_type_image) return input def scale_to_multiple_cover(input: torch.Tensor, multiple: int, scale_method: str) -> torch.Tensor: if multiple <= 1: return input is_type_image = is_image(input) if is_type_image: _, height, width, _ = input.shape else: _, height, width = input.shape target_w = (width // multiple) * multiple target_h = (height // multiple) * multiple if target_w == 0 or target_h == 0: return input if target_w == width and target_h == height: return input s_w = target_w / width s_h = target_h / height if s_w >= s_h: scaled_w = target_w scaled_h = int(math.ceil(height * s_w)) if scaled_h < target_h: scaled_h = target_h else: scaled_h = target_h scaled_w = int(math.ceil(width * s_h)) if scaled_w < target_w: scaled_w = target_w input = init_image_mask_input(input, is_type_image) input = comfy.utils.common_upscale(input, scaled_w, scaled_h, scale_method, "disabled") input = finalize_image_mask_input(input, is_type_image) x0 = (scaled_w - target_w) // 2 y0 = (scaled_h - target_h) // 2 x1 = x0 + target_w y1 = y0 + target_h if is_type_image: return input[:, y0:y1, x0:x1, :] return input[:, y0:y1, x0:x1] class ResizeImageMaskNode(io.ComfyNode): scale_methods = ["nearest-exact", "bilinear", "area", "bicubic", "lanczos"] crop_methods = ["disabled", "center"] class ResizeTypedDict(TypedDict): resize_type: ResizeType scale_method: Literal["nearest-exact", "bilinear", "area", "bicubic", "lanczos"] crop: Literal["disabled", "center"] multiplier: float width: int height: int longer_size: int shorter_size: int megapixels: float multiple: int @classmethod def define_schema(cls): template = io.MatchType.Template("input_type", [io.Image, io.Mask]) crop_combo = io.Combo.Input( "crop", options=cls.crop_methods, default="center", tooltip="How to handle aspect ratio mismatch: 'disabled' stretches to fit, 'center' crops to maintain aspect ratio.", ) return io.Schema( node_id="ResizeImageMaskNode", display_name="Resize Image/Mask", description="Resize an image or mask using various scaling methods.", category="image/transform", search_aliases=["resize", "resize image", "resize mask", "scale", "scale image", "scale mask", "image resize", "change size", "dimensions", "shrink", "enlarge"], inputs=[ io.MatchType.Input("input", template=template), io.DynamicCombo.Input( "resize_type", tooltip="Select how to resize: by exact dimensions, scale factor, matching another image, etc.", options=[ io.DynamicCombo.Option(ResizeType.SCALE_DIMENSIONS, [ io.Int.Input("width", default=512, min=0, max=MAX_RESOLUTION, step=1, tooltip="Target width in pixels. Set to 0 to auto-calculate from height while preserving aspect ratio."), io.Int.Input("height", default=512, min=0, max=MAX_RESOLUTION, step=1, tooltip="Target height in pixels. Set to 0 to auto-calculate from width while preserving aspect ratio."), crop_combo, ]), io.DynamicCombo.Option(ResizeType.SCALE_BY, [ io.Float.Input("multiplier", default=1.00, min=0.01, max=8.0, step=0.01, tooltip="Scale factor (e.g., 2.0 doubles size, 0.5 halves size)."), ]), io.DynamicCombo.Option(ResizeType.SCALE_LONGER_DIMENSION, [ io.Int.Input("longer_size", default=512, min=0, max=MAX_RESOLUTION, step=1, tooltip="The longer edge will be resized to this value. Aspect ratio is preserved."), ]), io.DynamicCombo.Option(ResizeType.SCALE_SHORTER_DIMENSION, [ io.Int.Input("shorter_size", default=512, min=0, max=MAX_RESOLUTION, step=1, tooltip="The shorter edge will be resized to this value. Aspect ratio is preserved."), ]), io.DynamicCombo.Option(ResizeType.SCALE_WIDTH, [ io.Int.Input("width", default=512, min=0, max=MAX_RESOLUTION, step=1, tooltip="Target width in pixels. Height auto-adjusts to preserve aspect ratio."), ]), io.DynamicCombo.Option(ResizeType.SCALE_HEIGHT, [ io.Int.Input("height", default=512, min=0, max=MAX_RESOLUTION, step=1, tooltip="Target height in pixels. Width auto-adjusts to preserve aspect ratio."), ]), io.DynamicCombo.Option(ResizeType.SCALE_TOTAL_PIXELS, [ io.Float.Input("megapixels", default=1.0, min=0.01, max=16.0, step=0.01, tooltip="Target total megapixels (e.g., 1.0 ≈ 1024×1024). Aspect ratio is preserved."), ]), io.DynamicCombo.Option(ResizeType.MATCH_SIZE, [ io.MultiType.Input("match", [io.Image, io.Mask], tooltip="Resize input to match the dimensions of this reference image or mask."), crop_combo, ]), io.DynamicCombo.Option(ResizeType.SCALE_TO_MULTIPLE, [ io.Int.Input("multiple", default=8, min=1, max=MAX_RESOLUTION, step=1, tooltip="Resize so width and height are divisible by this number. Useful for latent alignment (e.g., 8 or 64)."), ]), ], ), io.Combo.Input( "scale_method", options=cls.scale_methods, default="area", tooltip="Interpolation algorithm. 'area' is best for downscaling, 'lanczos' for upscaling, 'nearest-exact' for pixel art.", ), ], outputs=[io.MatchType.Output(template=template, display_name="resized")] ) @classmethod def execute(cls, input: io.Image.Type | io.Mask.Type, scale_method: io.Combo.Type, resize_type: ResizeTypedDict) -> io.NodeOutput: selected_type = resize_type["resize_type"] if selected_type == ResizeType.SCALE_BY: return io.NodeOutput(scale_by(input, resize_type["multiplier"], scale_method)) elif selected_type == ResizeType.SCALE_DIMENSIONS: return io.NodeOutput(scale_dimensions(input, resize_type["width"], resize_type["height"], scale_method, resize_type["crop"])) elif selected_type == ResizeType.SCALE_LONGER_DIMENSION: return io.NodeOutput(scale_longer_dimension(input, resize_type["longer_size"], scale_method)) elif selected_type == ResizeType.SCALE_SHORTER_DIMENSION: return io.NodeOutput(scale_shorter_dimension(input, resize_type["shorter_size"], scale_method)) elif selected_type == ResizeType.SCALE_WIDTH: return io.NodeOutput(scale_dimensions(input, resize_type["width"], 0, scale_method)) elif selected_type == ResizeType.SCALE_HEIGHT: return io.NodeOutput(scale_dimensions(input, 0, resize_type["height"], scale_method)) elif selected_type == ResizeType.SCALE_TOTAL_PIXELS: return io.NodeOutput(scale_total_pixels(input, resize_type["megapixels"], scale_method)) elif selected_type == ResizeType.MATCH_SIZE: return io.NodeOutput(scale_match_size(input, resize_type["match"], scale_method, resize_type["crop"])) elif selected_type == ResizeType.SCALE_TO_MULTIPLE: return io.NodeOutput(scale_to_multiple_cover(input, resize_type["multiple"], scale_method)) raise ValueError(f"Unsupported resize type: {selected_type}") def batch_images(images: list[torch.Tensor]) -> torch.Tensor | None: if len(images) == 0: return None # first, get the max channels count max_channels = max(image.shape[-1] for image in images) # then, pad all images to have the same channels count padded_images: list[torch.Tensor] = [] for image in images: if image.shape[-1] < max_channels: padded_images.append(torch.nn.functional.pad(image, (0,1), mode='constant', value=1.0)) else: padded_images.append(image) # resize all images to be the same size as the first image resized_images: list[torch.Tensor] = [] first_image_shape = padded_images[0].shape for image in padded_images: if image.shape[1:] != first_image_shape[1:]: resized_images.append(comfy.utils.common_upscale(image.movedim(-1,1), first_image_shape[2], first_image_shape[1], "bilinear", "center").movedim(1,-1)) else: resized_images.append(image) # batch the images in the format [b, h, w, c] return torch.cat(resized_images, dim=0) def batch_masks(masks: list[torch.Tensor]) -> torch.Tensor | None: if len(masks) == 0: return None # resize all masks to be the same size as the first mask resized_masks: list[torch.Tensor] = [] first_mask_shape = masks[0].shape for mask in masks: if mask.shape[1:] != first_mask_shape[1:]: mask = init_image_mask_input(mask, is_type_image=False) mask = comfy.utils.common_upscale(mask, first_mask_shape[2], first_mask_shape[1], "bilinear", "center") resized_masks.append(finalize_image_mask_input(mask, is_type_image=False)) else: resized_masks.append(mask) # batch the masks in the format [b, h, w] return torch.cat(resized_masks, dim=0) def batch_latents(latents: list[dict[str, torch.Tensor]]) -> dict[str, torch.Tensor] | None: if len(latents) == 0: return None samples_out = latents[0].copy() samples_out["batch_index"] = [] first_samples = latents[0]["samples"] tensors: list[torch.Tensor] = [] for latent in latents: # first, deal with latent tensors tensors.append(reshape_latent_to(first_samples.shape, latent["samples"], repeat_batch=False)) # next, deal with batch_index samples_out["batch_index"].extend(latent.get("batch_index", [x for x in range(0, latent["samples"].shape[0])])) samples_out["samples"] = torch.cat(tensors, dim=0) return samples_out class BatchImagesNode(io.ComfyNode): @classmethod def define_schema(cls): autogrow_template = io.Autogrow.TemplatePrefix(io.Image.Input("image"), prefix="image", min=1, max=50) return io.Schema( node_id="BatchImagesNode", display_name="Batch Images", category="image/batch", essentials_category="Image Tools", search_aliases=["batch", "image batch", "batch images", "combine images", "merge images", "stack images"], inputs=[ io.Autogrow.Input("images", template=autogrow_template) ], outputs=[ io.Image.Output() ] ) @classmethod def execute(cls, images: io.Autogrow.Type) -> io.NodeOutput: return io.NodeOutput(batch_images(list(images.values()))) class BatchMasksNode(io.ComfyNode): @classmethod def define_schema(cls): autogrow_template = io.Autogrow.TemplatePrefix(io.Mask.Input("mask"), prefix="mask", min=1, max=50) return io.Schema( node_id="BatchMasksNode", search_aliases=["combine masks", "stack masks", "merge masks"], display_name="Batch Masks", category="image/mask", inputs=[ io.Autogrow.Input("masks", template=autogrow_template) ], outputs=[ io.Mask.Output() ] ) @classmethod def execute(cls, masks: io.Autogrow.Type) -> io.NodeOutput: return io.NodeOutput(batch_masks(list(masks.values()))) class BatchLatentsNode(io.ComfyNode): @classmethod def define_schema(cls): autogrow_template = io.Autogrow.TemplatePrefix(io.Latent.Input("latent"), prefix="latent", min=1, max=50) return io.Schema( node_id="BatchLatentsNode", search_aliases=["combine latents", "stack latents", "merge latents"], display_name="Batch Latents", category="model/latent", inputs=[ io.Autogrow.Input("latents", template=autogrow_template) ], outputs=[ io.Latent.Output() ] ) @classmethod def execute(cls, latents: io.Autogrow.Type) -> io.NodeOutput: return io.NodeOutput(batch_latents(list(latents.values()))) class BatchImagesMasksLatentsNode(io.ComfyNode): @classmethod def define_schema(cls): matchtype_template = io.MatchType.Template("input", allowed_types=[io.Image, io.Mask, io.Latent]) autogrow_template = io.Autogrow.TemplatePrefix( io.MatchType.Input("input", matchtype_template), prefix="input", min=1, max=50) return io.Schema( node_id="BatchImagesMasksLatentsNode", search_aliases=["combine batch", "merge batch", "stack inputs"], display_name="Batch Images/Masks/Latents", category="util", inputs=[ io.Autogrow.Input("inputs", template=autogrow_template) ], outputs=[ io.MatchType.Output(id=None, template=matchtype_template) ] ) @classmethod def execute(cls, inputs: io.Autogrow.Type) -> io.NodeOutput: batched = None values = list(inputs.values()) # latents if isinstance(values[0], dict): batched = batch_latents(values) # images elif is_image(values[0]): batched = batch_images(values) # masks else: batched = batch_masks(values) return io.NodeOutput(batched) class ColorTransfer(io.ComfyNode): @classmethod def define_schema(cls): return io.Schema( node_id="ColorTransfer", display_name="Transfer Color", category="image/filters", description="Match the colors of one image to another using various algorithms.", search_aliases=["color match", "color grading", "color correction", "match colors", "color transform", "mkl", "reinhard", "histogram"], inputs=[ io.Image.Input("image_target", tooltip="Image(s) to apply the color transform to."), io.Image.Input("image_ref", tooltip="Reference image(s) to match colors to."), io.Combo.Input("method", options=['reinhard_lab', 'mkl_lab', 'histogram'],), io.DynamicCombo.Input("source_stats", tooltip="per_frame: each frame matched to image_ref individually. uniform: pool stats across all source frames as baseline, match to image_ref. target_frame: use one chosen frame as the baseline for the transform to image_ref, applied uniformly to all frames (preserves relative differences)", options=[ io.DynamicCombo.Option("per_frame", []), io.DynamicCombo.Option("uniform", []), io.DynamicCombo.Option("target_frame", [ io.Int.Input("target_index", default=0, min=0, max=10000, tooltip="Frame index used as the source baseline for computing the transform to image_ref"), ]), ]), io.Float.Input("strength", default=1.0, min=0.0, max=10.0, step=0.01), ], outputs=[ io.Image.Output(display_name="image"), ], ) @staticmethod def _to_lab(images, i, device): return kornia.color.rgb_to_lab( images[i:i+1].to(device, dtype=torch.float32).permute(0, 3, 1, 2)) @staticmethod def _pool_stats(images, device, is_reinhard, eps): """Two-pass pooled mean + std/cov across all frames.""" N, C = images.shape[0], images.shape[3] HW = images.shape[1] * images.shape[2] mean = torch.zeros(C, 1, device=device, dtype=torch.float32) for i in range(N): mean += ColorTransfer._to_lab(images, i, device).view(C, -1).mean(dim=-1, keepdim=True) mean /= N acc = torch.zeros(C, 1 if is_reinhard else C, device=device, dtype=torch.float32) for i in range(N): centered = ColorTransfer._to_lab(images, i, device).view(C, -1) - mean if is_reinhard: acc += (centered * centered).mean(dim=-1, keepdim=True) else: acc += centered @ centered.T / HW if is_reinhard: return mean, torch.sqrt(acc / N).clamp_min_(eps) return mean, acc / N @staticmethod def _frame_stats(lab_flat, hw, is_reinhard, eps): """Per-frame mean + std/cov.""" mean = lab_flat.mean(dim=-1, keepdim=True) if is_reinhard: return mean, lab_flat.std(dim=-1, keepdim=True, unbiased=False).clamp_min_(eps) centered = lab_flat - mean return mean, centered @ centered.T / hw @staticmethod def _mkl_matrix(cov_s, cov_r, eps): """Compute MKL 3x3 transform matrix from source and ref covariances.""" eig_val_s, eig_vec_s = torch.linalg.eigh(cov_s) sqrt_val_s = torch.sqrt(eig_val_s.clamp_min(0)).clamp_min_(eps) scaled_V = eig_vec_s * sqrt_val_s.unsqueeze(0) mid = scaled_V.T @ cov_r @ scaled_V eig_val_m, eig_vec_m = torch.linalg.eigh(mid) sqrt_m = torch.sqrt(eig_val_m.clamp_min(0)) inv_sqrt_s = 1.0 / sqrt_val_s inv_scaled_V = eig_vec_s * inv_sqrt_s.unsqueeze(0) M_half = (eig_vec_m * sqrt_m.unsqueeze(0)) @ eig_vec_m.T return inv_scaled_V @ M_half @ inv_scaled_V.T @staticmethod def _histogram_lut(src, ref, bins=256): """Build per-channel LUT from source and ref histograms. src/ref: (C, HW) in [0,1].""" s_bins = (src * (bins - 1)).long().clamp(0, bins - 1) r_bins = (ref * (bins - 1)).long().clamp(0, bins - 1) s_hist = torch.zeros(src.shape[0], bins, device=src.device, dtype=src.dtype) r_hist = torch.zeros(src.shape[0], bins, device=src.device, dtype=src.dtype) ones_s = torch.ones_like(src) ones_r = torch.ones_like(ref) s_hist.scatter_add_(1, s_bins, ones_s) r_hist.scatter_add_(1, r_bins, ones_r) s_cdf = s_hist.cumsum(1) s_cdf = s_cdf / s_cdf[:, -1:] r_cdf = r_hist.cumsum(1) r_cdf = r_cdf / r_cdf[:, -1:] return torch.searchsorted(r_cdf, s_cdf).clamp_max_(bins - 1).float() / (bins - 1) @classmethod def _pooled_cdf(cls, images, device, num_bins=256): """Build pooled CDF across all frames, one frame at a time.""" C = images.shape[3] hist = torch.zeros(C, num_bins, device=device, dtype=torch.float32) for i in range(images.shape[0]): frame = images[i].to(device, dtype=torch.float32).permute(2, 0, 1).reshape(C, -1) bins = (frame * (num_bins - 1)).long().clamp(0, num_bins - 1) hist.scatter_add_(1, bins, torch.ones_like(frame)) cdf = hist.cumsum(1) return cdf / cdf[:, -1:] @classmethod def _build_histogram_transform(cls, image_target, image_ref, device, stats_mode, target_index, B): """Build per-frame or uniform LUT transform for histogram mode.""" if stats_mode == 'per_frame': return None # LUT computed per-frame in the apply loop r_cdf = cls._pooled_cdf(image_ref, device) if stats_mode == 'target_frame': ti = min(target_index, B - 1) s_cdf = cls._pooled_cdf(image_target[ti:ti+1], device) else: s_cdf = cls._pooled_cdf(image_target, device) return torch.searchsorted(r_cdf, s_cdf).clamp_max_(255).float() / 255.0 @classmethod def _build_lab_transform(cls, image_target, image_ref, device, stats_mode, target_index, is_reinhard): """Build transform parameters for Lab-based methods. Returns a transform function.""" eps = 1e-6 B, H, W, C = image_target.shape B_ref = image_ref.shape[0] single_ref = B_ref == 1 HW = H * W HW_ref = image_ref.shape[1] * image_ref.shape[2] # Precompute ref stats if single_ref or stats_mode in ('uniform', 'target_frame'): ref_mean, ref_sc = cls._pool_stats(image_ref, device, is_reinhard, eps) # Uniform/target_frame: precompute single affine transform if stats_mode in ('uniform', 'target_frame'): if stats_mode == 'target_frame': ti = min(target_index, B - 1) s_lab = cls._to_lab(image_target, ti, device).view(C, -1) s_mean, s_sc = cls._frame_stats(s_lab, HW, is_reinhard, eps) else: s_mean, s_sc = cls._pool_stats(image_target, device, is_reinhard, eps) if is_reinhard: scale = ref_sc / s_sc offset = ref_mean - scale * s_mean return lambda src_flat, **_: src_flat * scale + offset T = cls._mkl_matrix(s_sc, ref_sc, eps) offset = ref_mean - T @ s_mean return lambda src_flat, **_: T @ src_flat + offset # per_frame def per_frame_transform(src_flat, frame_idx): s_mean, s_sc = cls._frame_stats(src_flat, HW, is_reinhard, eps) if single_ref: r_mean, r_sc = ref_mean, ref_sc else: ri = min(frame_idx, B_ref - 1) r_mean, r_sc = cls._frame_stats(cls._to_lab(image_ref, ri, device).view(C, -1), HW_ref, is_reinhard, eps) centered = src_flat - s_mean if is_reinhard: return centered * (r_sc / s_sc) + r_mean T = cls._mkl_matrix(centered @ centered.T / HW, r_sc, eps) return T @ centered + r_mean return per_frame_transform @classmethod def execute(cls, image_target, image_ref, method, source_stats, strength=1.0) -> io.NodeOutput: stats_mode = source_stats["source_stats"] target_index = source_stats.get("target_index", 0) if strength == 0 or image_ref is None: return io.NodeOutput(image_target) device = comfy.model_management.get_torch_device() intermediate_device = comfy.model_management.intermediate_device() intermediate_dtype = comfy.model_management.intermediate_dtype() B, H, W, C = image_target.shape B_ref = image_ref.shape[0] pbar = comfy.utils.ProgressBar(B) out = torch.empty(B, H, W, C, device=intermediate_device, dtype=intermediate_dtype) if method == 'histogram': uniform_lut = cls._build_histogram_transform( image_target, image_ref, device, stats_mode, target_index, B) for i in range(B): src = image_target[i].to(device, dtype=torch.float32).permute(2, 0, 1) src_flat = src.reshape(C, -1) if uniform_lut is not None: lut = uniform_lut else: ri = min(i, B_ref - 1) ref = image_ref[ri].to(device, dtype=torch.float32).permute(2, 0, 1).reshape(C, -1) lut = cls._histogram_lut(src_flat, ref) bin_idx = (src_flat * 255).long().clamp(0, 255) matched = lut.gather(1, bin_idx).view(C, H, W) result = matched if strength == 1.0 else torch.lerp(src, matched, strength) out[i] = result.permute(1, 2, 0).clamp_(0, 1).to(device=intermediate_device, dtype=intermediate_dtype) pbar.update(1) else: transform = cls._build_lab_transform(image_target, image_ref, device, stats_mode, target_index, is_reinhard=method == "reinhard_lab") for i in range(B): src_frame = cls._to_lab(image_target, i, device) corrected = transform(src_frame.view(C, -1), frame_idx=i) if strength == 1.0: result = kornia.color.lab_to_rgb(corrected.view(1, C, H, W)) else: result = kornia.color.lab_to_rgb(torch.lerp(src_frame, corrected.view(1, C, H, W), strength)) out[i] = result.squeeze(0).permute(1, 2, 0).clamp_(0, 1).to(device=intermediate_device, dtype=intermediate_dtype) pbar.update(1) return io.NodeOutput(out) class PostProcessingExtension(ComfyExtension): @override async def get_node_list(self) -> list[type[io.ComfyNode]]: return [ Blend, Blur, Quantize, Sharpen, ImageScaleToTotalPixels, ResizeImageMaskNode, BatchImagesNode, BatchMasksNode, BatchLatentsNode, ColorTransfer, # BatchImagesMasksLatentsNode, ] async def comfy_entrypoint() -> PostProcessingExtension: return PostProcessingExtension()