from __future__ import annotations import nodes import folder_paths import json import os import re import math import torch import comfy.utils from server import PromptServer from comfy_api.latest import ComfyExtension, IO, UI from typing_extensions import override SVG = IO.SVG.Type # TODO: temporary solution for backward compatibility, will be removed later. MAX_RESOLUTION = nodes.MAX_RESOLUTION class ImageCrop(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="ImageCrop", search_aliases=["trim"], display_name="Image Crop (Deprecated)", category="image/transform", is_deprecated=True, essentials_category="Image Tools", inputs=[ IO.Image.Input("image"), IO.Int.Input("width", default=512, min=1, max=nodes.MAX_RESOLUTION, step=1), IO.Int.Input("height", default=512, min=1, max=nodes.MAX_RESOLUTION, step=1), IO.Int.Input("x", default=0, min=0, max=nodes.MAX_RESOLUTION, step=1), IO.Int.Input("y", default=0, min=0, max=nodes.MAX_RESOLUTION, step=1), ], outputs=[IO.Image.Output()], ) @classmethod def execute(cls, image, width, height, x, y) -> IO.NodeOutput: x = min(x, image.shape[2] - 1) y = min(y, image.shape[1] - 1) to_x = width + x to_y = height + y img = image[:,y:to_y, x:to_x, :] return IO.NodeOutput(img) crop = execute # TODO: remove class ImageCropV2(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="ImageCropV2", search_aliases=["trim"], display_name="Image Crop", category="image/transform", essentials_category="Image Tools", has_intermediate_output=True, inputs=[ IO.Image.Input("image"), IO.BoundingBox.Input("crop_region", component="ImageCrop"), ], outputs=[IO.Image.Output()], ) @classmethod def execute(cls, image, crop_region) -> IO.NodeOutput: x = crop_region.get("x", 0) y = crop_region.get("y", 0) width = crop_region.get("width", 512) height = crop_region.get("height", 512) x = min(x, image.shape[2] - 1) y = min(y, image.shape[1] - 1) to_x = width + x to_y = height + y img = image[:,y:to_y, x:to_x, :] return IO.NodeOutput(img, ui=UI.PreviewImage(img)) class BoundingBox(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="PrimitiveBoundingBox", display_name="Bounding Box", category="utils/primitive", inputs=[ IO.Int.Input("x", default=0, min=0, max=MAX_RESOLUTION), IO.Int.Input("y", default=0, min=0, max=MAX_RESOLUTION), IO.Int.Input("width", default=512, min=1, max=MAX_RESOLUTION), IO.Int.Input("height", default=512, min=1, max=MAX_RESOLUTION), ], outputs=[IO.BoundingBox.Output()], ) @classmethod def execute(cls, x, y, width, height) -> IO.NodeOutput: return IO.NodeOutput({"x": x, "y": y, "width": width, "height": height}) class RepeatImageBatch(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="RepeatImageBatch", search_aliases=["duplicate image", "clone image"], category="image/batch", inputs=[ IO.Image.Input("image"), IO.Int.Input("amount", default=1, min=1, max=4096), ], outputs=[IO.Image.Output()], ) @classmethod def execute(cls, image, amount) -> IO.NodeOutput: s = image.repeat((amount, 1,1,1)) return IO.NodeOutput(s) repeat = execute # TODO: remove class ImageFromBatch(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="ImageFromBatch", search_aliases=["select image", "pick from batch", "extract image"], category="image/batch", inputs=[ IO.Image.Input("image"), IO.Int.Input("batch_index", default=0, min=0, max=4095), IO.Int.Input("length", default=1, min=1, max=4096), ], outputs=[IO.Image.Output()], ) @classmethod def execute(cls, image, batch_index, length) -> IO.NodeOutput: s_in = image batch_index = min(s_in.shape[0] - 1, batch_index) length = min(s_in.shape[0] - batch_index, length) s = s_in[batch_index:batch_index + length].clone() return IO.NodeOutput(s) frombatch = execute # TODO: remove class ImageAddNoise(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="ImageAddNoise", search_aliases=["film grain"], category="image", inputs=[ IO.Image.Input("image"), IO.Int.Input( "seed", default=0, min=0, max=0xFFFFFFFFFFFFFFFF, control_after_generate=True, tooltip="The random seed used for creating the noise.", ), IO.Float.Input("strength", default=0.5, min=0.0, max=1.0, step=0.01), ], outputs=[IO.Image.Output()], ) @classmethod def execute(cls, image, seed, strength) -> IO.NodeOutput: generator = torch.manual_seed(seed) s = torch.clip((image + strength * torch.randn(image.size(), generator=generator, device="cpu").to(image)), min=0.0, max=1.0) return IO.NodeOutput(s) repeat = execute # TODO: remove class SaveAnimatedWEBP(IO.ComfyNode): COMPRESS_METHODS = {"default": 4, "fastest": 0, "slowest": 6} @classmethod def define_schema(cls): return IO.Schema( node_id="SaveAnimatedWEBP", category="image/animation", inputs=[ IO.Image.Input("images"), IO.String.Input("filename_prefix", default="ComfyUI"), IO.Float.Input("fps", default=6.0, min=0.01, max=1000.0, step=0.01), IO.Boolean.Input("lossless", default=True), IO.Int.Input("quality", default=80, min=0, max=100), IO.Combo.Input("method", options=list(cls.COMPRESS_METHODS.keys())), # "num_frames": ("INT", {"default": 0, "min": 0, "max": 8192}), ], hidden=[IO.Hidden.prompt, IO.Hidden.extra_pnginfo], is_output_node=True, ) @classmethod def execute(cls, images, fps, filename_prefix, lossless, quality, method, num_frames=0) -> IO.NodeOutput: return IO.NodeOutput( ui=UI.ImageSaveHelper.get_save_animated_webp_ui( images=images, filename_prefix=filename_prefix, cls=cls, fps=fps, lossless=lossless, quality=quality, method=cls.COMPRESS_METHODS.get(method) ) ) save_images = execute # TODO: remove class SaveAnimatedPNG(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="SaveAnimatedPNG", category="image/animation", inputs=[ IO.Image.Input("images"), IO.String.Input("filename_prefix", default="ComfyUI"), IO.Float.Input("fps", default=6.0, min=0.01, max=1000.0, step=0.01), IO.Int.Input("compress_level", default=4, min=0, max=9, advanced=True), ], hidden=[IO.Hidden.prompt, IO.Hidden.extra_pnginfo], is_output_node=True, ) @classmethod def execute(cls, images, fps, compress_level, filename_prefix="ComfyUI") -> IO.NodeOutput: return IO.NodeOutput( ui=UI.ImageSaveHelper.get_save_animated_png_ui( images=images, filename_prefix=filename_prefix, cls=cls, fps=fps, compress_level=compress_level, ) ) save_images = execute # TODO: remove class ImageStitch(IO.ComfyNode): """Upstreamed from https://github.com/kijai/ComfyUI-KJNodes""" @classmethod def define_schema(cls): return IO.Schema( node_id="ImageStitch", search_aliases=["combine images", "join images", "concatenate images", "side by side"], display_name="Image Stitch", description="Stitches image2 to image1 in the specified direction.\n" "If image2 is not provided, returns image1 unchanged.\n" "Optional spacing can be added between images.", category="image/transform", inputs=[ IO.Image.Input("image1"), IO.Combo.Input("direction", options=["right", "down", "left", "up"], default="right"), IO.Boolean.Input("match_image_size", default=True), IO.Int.Input("spacing_width", default=0, min=0, max=1024, step=2, advanced=True), IO.Combo.Input("spacing_color", options=["white", "black", "red", "green", "blue"], default="white", advanced=True), IO.Image.Input("image2", optional=True), ], outputs=[IO.Image.Output()], ) @classmethod def execute( cls, image1, direction, match_image_size, spacing_width, spacing_color, image2=None, ) -> IO.NodeOutput: if image2 is None: return IO.NodeOutput(image1) # Handle batch size differences if image1.shape[0] != image2.shape[0]: max_batch = max(image1.shape[0], image2.shape[0]) if image1.shape[0] < max_batch: image1 = torch.cat( [image1, image1[-1:].repeat(max_batch - image1.shape[0], 1, 1, 1)] ) if image2.shape[0] < max_batch: image2 = torch.cat( [image2, image2[-1:].repeat(max_batch - image2.shape[0], 1, 1, 1)] ) # Match image sizes if requested if match_image_size: h1, w1 = image1.shape[1:3] h2, w2 = image2.shape[1:3] aspect_ratio = w2 / h2 if direction in ["left", "right"]: target_h, target_w = h1, int(h1 * aspect_ratio) else: # up, down target_w, target_h = w1, int(w1 / aspect_ratio) image2 = comfy.utils.common_upscale( image2.movedim(-1, 1), target_w, target_h, "lanczos", "disabled" ).movedim(1, -1) color_map = { "white": 1.0, "black": 0.0, "red": (1.0, 0.0, 0.0), "green": (0.0, 1.0, 0.0), "blue": (0.0, 0.0, 1.0), } color_val = color_map[spacing_color] # When not matching sizes, pad to align non-concat dimensions if not match_image_size: h1, w1 = image1.shape[1:3] h2, w2 = image2.shape[1:3] pad_value = 0.0 if not isinstance(color_val, tuple): pad_value = color_val if direction in ["left", "right"]: # For horizontal concat, pad heights to match if h1 != h2: target_h = max(h1, h2) if h1 < target_h: pad_h = target_h - h1 pad_top, pad_bottom = pad_h // 2, pad_h - pad_h // 2 image1 = torch.nn.functional.pad(image1, (0, 0, 0, 0, pad_top, pad_bottom), mode='constant', value=pad_value) if h2 < target_h: pad_h = target_h - h2 pad_top, pad_bottom = pad_h // 2, pad_h - pad_h // 2 image2 = torch.nn.functional.pad(image2, (0, 0, 0, 0, pad_top, pad_bottom), mode='constant', value=pad_value) else: # up, down # For vertical concat, pad widths to match if w1 != w2: target_w = max(w1, w2) if w1 < target_w: pad_w = target_w - w1 pad_left, pad_right = pad_w // 2, pad_w - pad_w // 2 image1 = torch.nn.functional.pad(image1, (0, 0, pad_left, pad_right), mode='constant', value=pad_value) if w2 < target_w: pad_w = target_w - w2 pad_left, pad_right = pad_w // 2, pad_w - pad_w // 2 image2 = torch.nn.functional.pad(image2, (0, 0, pad_left, pad_right), mode='constant', value=pad_value) # Ensure same number of channels if image1.shape[-1] != image2.shape[-1]: max_channels = max(image1.shape[-1], image2.shape[-1]) if image1.shape[-1] < max_channels: image1 = torch.cat( [ image1, torch.ones( *image1.shape[:-1], max_channels - image1.shape[-1], device=image1.device, ), ], dim=-1, ) if image2.shape[-1] < max_channels: image2 = torch.cat( [ image2, torch.ones( *image2.shape[:-1], max_channels - image2.shape[-1], device=image2.device, ), ], dim=-1, ) # Add spacing if specified if spacing_width > 0: spacing_width = spacing_width + (spacing_width % 2) # Ensure even if direction in ["left", "right"]: spacing_shape = ( image1.shape[0], max(image1.shape[1], image2.shape[1]), spacing_width, image1.shape[-1], ) else: spacing_shape = ( image1.shape[0], spacing_width, max(image1.shape[2], image2.shape[2]), image1.shape[-1], ) spacing = torch.full(spacing_shape, 0.0, device=image1.device) if isinstance(color_val, tuple): for i, c in enumerate(color_val): if i < spacing.shape[-1]: spacing[..., i] = c if spacing.shape[-1] == 4: # Add alpha spacing[..., 3] = 1.0 else: spacing[..., : min(3, spacing.shape[-1])] = color_val if spacing.shape[-1] == 4: spacing[..., 3] = 1.0 # Concatenate images images = [image2, image1] if direction in ["left", "up"] else [image1, image2] if spacing_width > 0: images.insert(1, spacing) concat_dim = 2 if direction in ["left", "right"] else 1 return IO.NodeOutput(torch.cat(images, dim=concat_dim)) stitch = execute # TODO: remove class ResizeAndPadImage(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="ResizeAndPadImage", search_aliases=["fit to size"], category="image/transform", inputs=[ IO.Image.Input("image"), IO.Int.Input("target_width", default=512, min=1, max=nodes.MAX_RESOLUTION, step=1), IO.Int.Input("target_height", default=512, min=1, max=nodes.MAX_RESOLUTION, step=1), IO.Combo.Input("padding_color", options=["white", "black"], advanced=True), IO.Combo.Input("interpolation", options=["area", "bicubic", "nearest-exact", "bilinear", "lanczos"], advanced=True), ], outputs=[IO.Image.Output()], ) @classmethod def execute(cls, image, target_width, target_height, padding_color, interpolation) -> IO.NodeOutput: batch_size, orig_height, orig_width, channels = image.shape scale_w = target_width / orig_width scale_h = target_height / orig_height scale = min(scale_w, scale_h) new_width = int(orig_width * scale) new_height = int(orig_height * scale) image_permuted = image.permute(0, 3, 1, 2) resized = comfy.utils.common_upscale(image_permuted, new_width, new_height, interpolation, "disabled") pad_value = 0.0 if padding_color == "black" else 1.0 padded = torch.full( (batch_size, channels, target_height, target_width), pad_value, dtype=image.dtype, device=image.device ) y_offset = (target_height - new_height) // 2 x_offset = (target_width - new_width) // 2 padded[:, :, y_offset:y_offset + new_height, x_offset:x_offset + new_width] = resized output = padded.permute(0, 2, 3, 1) return IO.NodeOutput(output) resize_and_pad = execute # TODO: remove class SaveSVGNode(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="SaveSVGNode", search_aliases=["export vector", "save vector graphics"], description="Save SVG files on disk.", category="image/save", inputs=[ IO.SVG.Input("svg"), IO.String.Input( "filename_prefix", default="svg/ComfyUI", tooltip="The prefix for the file to save. This may include formatting information such as %date:yyyy-MM-dd% or %Empty Latent Image.width% to include values from nodes.", ), ], hidden=[IO.Hidden.prompt, IO.Hidden.extra_pnginfo], is_output_node=True, ) @classmethod def execute(cls, svg: IO.SVG.Type, filename_prefix="svg/ComfyUI") -> IO.NodeOutput: full_output_folder, filename, counter, subfolder, filename_prefix = folder_paths.get_save_image_path(filename_prefix, folder_paths.get_output_directory()) results: list[UI.SavedResult] = [] # Prepare metadata JSON metadata_dict = {} if cls.hidden.prompt is not None: metadata_dict["prompt"] = cls.hidden.prompt if cls.hidden.extra_pnginfo is not None: metadata_dict.update(cls.hidden.extra_pnginfo) # Convert metadata to JSON string metadata_json = json.dumps(metadata_dict, indent=2) if metadata_dict else None for batch_number, svg_bytes in enumerate(svg.data): filename_with_batch_num = filename.replace("%batch_num%", str(batch_number)) file = f"{filename_with_batch_num}_{counter:05}_.svg" # Read SVG content svg_bytes.seek(0) svg_content = svg_bytes.read().decode('utf-8') # Inject metadata if available if metadata_json: # Create metadata element with CDATA section metadata_element = f""" """ # Insert metadata after opening svg tag using regex with a replacement function def replacement(match): # match.group(1) contains the captured tag return match.group(1) + '\n' + metadata_element # Apply the substitution svg_content = re.sub(r'(]*>)', replacement, svg_content, flags=re.UNICODE) # Write the modified SVG to file with open(os.path.join(full_output_folder, file), 'wb') as svg_file: svg_file.write(svg_content.encode('utf-8')) results.append(UI.SavedResult(filename=file, subfolder=subfolder, type=IO.FolderType.output)) counter += 1 return IO.NodeOutput(ui={"images": results}) save_svg = execute # TODO: remove class GetImageSize(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="GetImageSize", search_aliases=["dimensions", "resolution", "image info"], display_name="Get Image Size", description="Returns width and height of the image, and passes it through unchanged.", category="image", inputs=[ IO.Image.Input("image"), ], outputs=[ IO.Int.Output(display_name="width"), IO.Int.Output(display_name="height"), IO.Int.Output(display_name="batch_size"), ], hidden=[IO.Hidden.unique_id], ) @classmethod def execute(cls, image) -> IO.NodeOutput: height = image.shape[1] width = image.shape[2] batch_size = image.shape[0] # Send progress text to display size on the node if cls.hidden.unique_id: PromptServer.instance.send_progress_text(f"width: {width}, height: {height}\n batch size: {batch_size}", cls.hidden.unique_id) return IO.NodeOutput(width, height, batch_size) get_size = execute # TODO: remove class ImageRotate(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="ImageRotate", display_name="Image Rotate", search_aliases=["turn", "flip orientation"], category="image/transform", essentials_category="Image Tools", inputs=[ IO.Image.Input("image"), IO.Combo.Input("rotation", options=["none", "90 degrees", "180 degrees", "270 degrees"]), ], outputs=[IO.Image.Output()], ) @classmethod def execute(cls, image, rotation) -> IO.NodeOutput: rotate_by = 0 if rotation.startswith("90"): rotate_by = 1 elif rotation.startswith("180"): rotate_by = 2 elif rotation.startswith("270"): rotate_by = 3 image = torch.rot90(image, k=rotate_by, dims=[2, 1]) return IO.NodeOutput(image) rotate = execute # TODO: remove class ImageFlip(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="ImageFlip", search_aliases=["mirror", "reflect"], category="image/transform", inputs=[ IO.Image.Input("image"), IO.Combo.Input("flip_method", options=["x-axis: vertically", "y-axis: horizontally"]), ], outputs=[IO.Image.Output()], ) @classmethod def execute(cls, image, flip_method) -> IO.NodeOutput: if flip_method.startswith("x"): image = torch.flip(image, dims=[1]) elif flip_method.startswith("y"): image = torch.flip(image, dims=[2]) return IO.NodeOutput(image) flip = execute # TODO: remove class ImageScaleToMaxDimension(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="ImageScaleToMaxDimension", category="image/upscaling", inputs=[ IO.Image.Input("image"), IO.Combo.Input( "upscale_method", options=["area", "lanczos", "bilinear", "nearest-exact", "bilinear", "bicubic"], ), IO.Int.Input("largest_size", default=512, min=0, max=MAX_RESOLUTION, step=1), ], outputs=[IO.Image.Output()], ) @classmethod def execute(cls, image, upscale_method, largest_size) -> IO.NodeOutput: height = image.shape[1] width = image.shape[2] if height > width: width = round((width / height) * largest_size) height = largest_size elif width > height: height = round((height / width) * largest_size) width = largest_size else: height = largest_size width = largest_size samples = image.movedim(-1, 1) s = comfy.utils.common_upscale(samples, width, height, upscale_method, "disabled") s = s.movedim(1, -1) return IO.NodeOutput(s) upscale = execute # TODO: remove class SplitImageToTileList(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="SplitImageToTileList", category="image/batch", search_aliases=["split image", "tile image", "slice image"], display_name="Split Image into List of Tiles", description="Splits an image into a batched list of tiles with a specified overlap.", inputs=[ IO.Image.Input("image"), IO.Int.Input("tile_width", default=1024, min=64, max=MAX_RESOLUTION), IO.Int.Input("tile_height", default=1024, min=64, max=MAX_RESOLUTION), IO.Int.Input("overlap", default=128, min=0, max=4096), ], outputs=[ IO.Image.Output(is_output_list=True), ], ) @staticmethod def get_grid_coords(width, height, tile_width, tile_height, overlap): coords = [] stride_x = round(max(tile_width * 0.25, tile_width - overlap)) stride_y = round(max(tile_width * 0.25, tile_height - overlap)) y = 0 while y < height: x = 0 y_end = min(y + tile_height, height) y_start = max(0, y_end - tile_height) while x < width: x_end = min(x + tile_width, width) x_start = max(0, x_end - tile_width) coords.append((x_start, y_start, x_end, y_end)) if x_end >= width: break x += stride_x if y_end >= height: break y += stride_y return coords @classmethod def execute(cls, image, tile_width, tile_height, overlap): b, h, w, c = image.shape coords = cls.get_grid_coords(w, h, tile_width, tile_height, overlap) output_list = [] for (x_start, y_start, x_end, y_end) in coords: tile = image[:, y_start:y_end, x_start:x_end, :] output_list.append(tile) return IO.NodeOutput(output_list) class ImageMergeTileList(IO.ComfyNode): @classmethod def define_schema(cls): return IO.Schema( node_id="ImageMergeTileList", display_name="Merge List of Tiles to Image", category="image/batch", search_aliases=["split image", "tile image", "slice image"], is_input_list=True, inputs=[ IO.Image.Input("image_list"), IO.Int.Input("final_width", default=1024, min=64, max=32768), IO.Int.Input("final_height", default=1024, min=64, max=32768), IO.Int.Input("overlap", default=128, min=0, max=4096), ], outputs=[ IO.Image.Output(is_output_list=False), ], ) @classmethod def execute(cls, image_list, final_width, final_height, overlap): w = final_width[0] h = final_height[0] ovlp = overlap[0] feather_str = 1.0 first_tile = image_list[0] b, t_h, t_w, c = first_tile.shape device = first_tile.device dtype = first_tile.dtype coords = SplitImageToTileList.get_grid_coords(w, h, t_w, t_h, ovlp) canvas = torch.zeros((b, h, w, c), device=device, dtype=dtype) weights = torch.zeros((b, h, w, 1), device=device, dtype=dtype) if ovlp > 0: y_w = torch.sin(math.pi * torch.linspace(0, 1, t_h, device=device, dtype=dtype)) x_w = torch.sin(math.pi * torch.linspace(0, 1, t_w, device=device, dtype=dtype)) y_w = torch.clamp(y_w, min=1e-5) x_w = torch.clamp(x_w, min=1e-5) sine_mask = (y_w.unsqueeze(1) * x_w.unsqueeze(0)).unsqueeze(0).unsqueeze(-1) flat_mask = torch.ones_like(sine_mask) weight_mask = torch.lerp(flat_mask, sine_mask, feather_str) else: weight_mask = torch.ones((1, t_h, t_w, 1), device=device, dtype=dtype) for i, (x_start, y_start, x_end, y_end) in enumerate(coords): if i >= len(image_list): break tile = image_list[i] region_h = y_end - y_start region_w = x_end - x_start real_h = min(region_h, tile.shape[1]) real_w = min(region_w, tile.shape[2]) y_end_actual = y_start + real_h x_end_actual = x_start + real_w tile_crop = tile[:, :real_h, :real_w, :] mask_crop = weight_mask[:, :real_h, :real_w, :] canvas[:, y_start:y_end_actual, x_start:x_end_actual, :] += tile_crop * mask_crop weights[:, y_start:y_end_actual, x_start:x_end_actual, :] += mask_crop weights[weights == 0] = 1.0 merged_image = canvas / weights return IO.NodeOutput(merged_image) class ImagesExtension(ComfyExtension): @override async def get_node_list(self) -> list[type[IO.ComfyNode]]: return [ ImageCrop, ImageCropV2, BoundingBox, RepeatImageBatch, ImageFromBatch, ImageAddNoise, SaveAnimatedWEBP, SaveAnimatedPNG, SaveSVGNode, ImageStitch, ResizeAndPadImage, GetImageSize, ImageRotate, ImageFlip, ImageScaleToMaxDimension, SplitImageToTileList, ImageMergeTileList, ] async def comfy_entrypoint() -> ImagesExtension: return ImagesExtension()