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from ..utility.utility import tensor2pil, pil2tensor | |
from PIL import Image, ImageDraw, ImageFilter | |
import numpy as np | |
import torch | |
from torchvision.transforms import Resize, CenterCrop, InterpolationMode | |
import math | |
#based on nodes from mtb https://github.com/melMass/comfy_mtb | |
def bbox_to_region(bbox, target_size=None): | |
bbox = bbox_check(bbox, target_size) | |
return (bbox[0], bbox[1], bbox[0] + bbox[2], bbox[1] + bbox[3]) | |
def bbox_check(bbox, target_size=None): | |
if not target_size: | |
return bbox | |
new_bbox = ( | |
bbox[0], | |
bbox[1], | |
min(target_size[0] - bbox[0], bbox[2]), | |
min(target_size[1] - bbox[1], bbox[3]), | |
) | |
return new_bbox | |
class BatchCropFromMask: | |
def INPUT_TYPES(cls): | |
return { | |
"required": { | |
"original_images": ("IMAGE",), | |
"masks": ("MASK",), | |
"crop_size_mult": ("FLOAT", {"default": 1.0, "min": 0.0, "max": 10.0, "step": 0.001}), | |
"bbox_smooth_alpha": ("FLOAT", {"default": 0.5, "min": 0.0, "max": 1.0, "step": 0.01}), | |
}, | |
} | |
RETURN_TYPES = ( | |
"IMAGE", | |
"IMAGE", | |
"BBOX", | |
"INT", | |
"INT", | |
) | |
RETURN_NAMES = ( | |
"original_images", | |
"cropped_images", | |
"bboxes", | |
"width", | |
"height", | |
) | |
FUNCTION = "crop" | |
CATEGORY = "KJNodes/masking" | |
def smooth_bbox_size(self, prev_bbox_size, curr_bbox_size, alpha): | |
if alpha == 0: | |
return prev_bbox_size | |
return round(alpha * curr_bbox_size + (1 - alpha) * prev_bbox_size) | |
def smooth_center(self, prev_center, curr_center, alpha=0.5): | |
if alpha == 0: | |
return prev_center | |
return ( | |
round(alpha * curr_center[0] + (1 - alpha) * prev_center[0]), | |
round(alpha * curr_center[1] + (1 - alpha) * prev_center[1]) | |
) | |
def crop(self, masks, original_images, crop_size_mult, bbox_smooth_alpha): | |
bounding_boxes = [] | |
cropped_images = [] | |
self.max_bbox_width = 0 | |
self.max_bbox_height = 0 | |
# First, calculate the maximum bounding box size across all masks | |
curr_max_bbox_width = 0 | |
curr_max_bbox_height = 0 | |
for mask in masks: | |
_mask = tensor2pil(mask)[0] | |
non_zero_indices = np.nonzero(np.array(_mask)) | |
min_x, max_x = np.min(non_zero_indices[1]), np.max(non_zero_indices[1]) | |
min_y, max_y = np.min(non_zero_indices[0]), np.max(non_zero_indices[0]) | |
width = max_x - min_x | |
height = max_y - min_y | |
curr_max_bbox_width = max(curr_max_bbox_width, width) | |
curr_max_bbox_height = max(curr_max_bbox_height, height) | |
# Smooth the changes in the bounding box size | |
self.max_bbox_width = self.smooth_bbox_size(self.max_bbox_width, curr_max_bbox_width, bbox_smooth_alpha) | |
self.max_bbox_height = self.smooth_bbox_size(self.max_bbox_height, curr_max_bbox_height, bbox_smooth_alpha) | |
# Apply the crop size multiplier | |
self.max_bbox_width = round(self.max_bbox_width * crop_size_mult) | |
self.max_bbox_height = round(self.max_bbox_height * crop_size_mult) | |
bbox_aspect_ratio = self.max_bbox_width / self.max_bbox_height | |
# Then, for each mask and corresponding image... | |
for i, (mask, img) in enumerate(zip(masks, original_images)): | |
_mask = tensor2pil(mask)[0] | |
non_zero_indices = np.nonzero(np.array(_mask)) | |
min_x, max_x = np.min(non_zero_indices[1]), np.max(non_zero_indices[1]) | |
min_y, max_y = np.min(non_zero_indices[0]), np.max(non_zero_indices[0]) | |
# Calculate center of bounding box | |
center_x = np.mean(non_zero_indices[1]) | |
center_y = np.mean(non_zero_indices[0]) | |
curr_center = (round(center_x), round(center_y)) | |
# If this is the first frame, initialize prev_center with curr_center | |
if not hasattr(self, 'prev_center'): | |
self.prev_center = curr_center | |
# Smooth the changes in the center coordinates from the second frame onwards | |
if i > 0: | |
center = self.smooth_center(self.prev_center, curr_center, bbox_smooth_alpha) | |
else: | |
center = curr_center | |
# Update prev_center for the next frame | |
self.prev_center = center | |
# Create bounding box using max_bbox_width and max_bbox_height | |
half_box_width = round(self.max_bbox_width / 2) | |
half_box_height = round(self.max_bbox_height / 2) | |
min_x = max(0, center[0] - half_box_width) | |
max_x = min(img.shape[1], center[0] + half_box_width) | |
min_y = max(0, center[1] - half_box_height) | |
max_y = min(img.shape[0], center[1] + half_box_height) | |
# Append bounding box coordinates | |
bounding_boxes.append((min_x, min_y, max_x - min_x, max_y - min_y)) | |
# Crop the image from the bounding box | |
cropped_img = img[min_y:max_y, min_x:max_x, :] | |
# Calculate the new dimensions while maintaining the aspect ratio | |
new_height = min(cropped_img.shape[0], self.max_bbox_height) | |
new_width = round(new_height * bbox_aspect_ratio) | |
# Resize the image | |
resize_transform = Resize((new_height, new_width)) | |
resized_img = resize_transform(cropped_img.permute(2, 0, 1)) | |
# Perform the center crop to the desired size | |
crop_transform = CenterCrop((self.max_bbox_height, self.max_bbox_width)) # swap the order here if necessary | |
cropped_resized_img = crop_transform(resized_img) | |
cropped_images.append(cropped_resized_img.permute(1, 2, 0)) | |
cropped_out = torch.stack(cropped_images, dim=0) | |
return (original_images, cropped_out, bounding_boxes, self.max_bbox_width, self.max_bbox_height, ) | |
class BatchUncrop: | |
def INPUT_TYPES(cls): | |
return { | |
"required": { | |
"original_images": ("IMAGE",), | |
"cropped_images": ("IMAGE",), | |
"bboxes": ("BBOX",), | |
"border_blending": ("FLOAT", {"default": 0.25, "min": 0.0, "max": 1.0, "step": 0.01}, ), | |
"crop_rescale": ("FLOAT", {"default": 1.0, "min": 0.0, "max": 10.0, "step": 0.01}), | |
"border_top": ("BOOLEAN", {"default": True}), | |
"border_bottom": ("BOOLEAN", {"default": True}), | |
"border_left": ("BOOLEAN", {"default": True}), | |
"border_right": ("BOOLEAN", {"default": True}), | |
} | |
} | |
RETURN_TYPES = ("IMAGE",) | |
FUNCTION = "uncrop" | |
CATEGORY = "KJNodes/masking" | |
def uncrop(self, original_images, cropped_images, bboxes, border_blending, crop_rescale, border_top, border_bottom, border_left, border_right): | |
def inset_border(image, border_width, border_color, border_top, border_bottom, border_left, border_right): | |
draw = ImageDraw.Draw(image) | |
width, height = image.size | |
if border_top: | |
draw.rectangle((0, 0, width, border_width), fill=border_color) | |
if border_bottom: | |
draw.rectangle((0, height - border_width, width, height), fill=border_color) | |
if border_left: | |
draw.rectangle((0, 0, border_width, height), fill=border_color) | |
if border_right: | |
draw.rectangle((width - border_width, 0, width, height), fill=border_color) | |
return image | |
if len(original_images) != len(cropped_images): | |
raise ValueError(f"The number of original_images ({len(original_images)}) and cropped_images ({len(cropped_images)}) should be the same") | |
# Ensure there are enough bboxes, but drop the excess if there are more bboxes than images | |
if len(bboxes) > len(original_images): | |
print(f"Warning: Dropping excess bounding boxes. Expected {len(original_images)}, but got {len(bboxes)}") | |
bboxes = bboxes[:len(original_images)] | |
elif len(bboxes) < len(original_images): | |
raise ValueError("There should be at least as many bboxes as there are original and cropped images") | |
input_images = tensor2pil(original_images) | |
crop_imgs = tensor2pil(cropped_images) | |
out_images = [] | |
for i in range(len(input_images)): | |
img = input_images[i] | |
crop = crop_imgs[i] | |
bbox = bboxes[i] | |
# uncrop the image based on the bounding box | |
bb_x, bb_y, bb_width, bb_height = bbox | |
paste_region = bbox_to_region((bb_x, bb_y, bb_width, bb_height), img.size) | |
# scale factors | |
scale_x = crop_rescale | |
scale_y = crop_rescale | |
# scaled paste_region | |
paste_region = (round(paste_region[0]*scale_x), round(paste_region[1]*scale_y), round(paste_region[2]*scale_x), round(paste_region[3]*scale_y)) | |
# rescale the crop image to fit the paste_region | |
crop = crop.resize((round(paste_region[2]-paste_region[0]), round(paste_region[3]-paste_region[1]))) | |
crop_img = crop.convert("RGB") | |
if border_blending > 1.0: | |
border_blending = 1.0 | |
elif border_blending < 0.0: | |
border_blending = 0.0 | |
blend_ratio = (max(crop_img.size) / 2) * float(border_blending) | |
blend = img.convert("RGBA") | |
mask = Image.new("L", img.size, 0) | |
mask_block = Image.new("L", (paste_region[2]-paste_region[0], paste_region[3]-paste_region[1]), 255) | |
mask_block = inset_border(mask_block, round(blend_ratio / 2), (0), border_top, border_bottom, border_left, border_right) | |
mask.paste(mask_block, paste_region) | |
blend.paste(crop_img, paste_region) | |
mask = mask.filter(ImageFilter.BoxBlur(radius=blend_ratio / 4)) | |
mask = mask.filter(ImageFilter.GaussianBlur(radius=blend_ratio / 4)) | |
blend.putalpha(mask) | |
img = Image.alpha_composite(img.convert("RGBA"), blend) | |
out_images.append(img.convert("RGB")) | |
return (pil2tensor(out_images),) | |
class BatchCropFromMaskAdvanced: | |
def INPUT_TYPES(cls): | |
return { | |
"required": { | |
"original_images": ("IMAGE",), | |
"masks": ("MASK",), | |
"crop_size_mult": ("FLOAT", {"default": 1.0, "min": 0.0, "max": 10.0, "step": 0.01}), | |
"bbox_smooth_alpha": ("FLOAT", {"default": 0.5, "min": 0.0, "max": 1.0, "step": 0.01}), | |
}, | |
} | |
RETURN_TYPES = ( | |
"IMAGE", | |
"IMAGE", | |
"MASK", | |
"IMAGE", | |
"MASK", | |
"BBOX", | |
"BBOX", | |
"INT", | |
"INT", | |
) | |
RETURN_NAMES = ( | |
"original_images", | |
"cropped_images", | |
"cropped_masks", | |
"combined_crop_image", | |
"combined_crop_masks", | |
"bboxes", | |
"combined_bounding_box", | |
"bbox_width", | |
"bbox_height", | |
) | |
FUNCTION = "crop" | |
CATEGORY = "KJNodes/masking" | |
def smooth_bbox_size(self, prev_bbox_size, curr_bbox_size, alpha): | |
return round(alpha * curr_bbox_size + (1 - alpha) * prev_bbox_size) | |
def smooth_center(self, prev_center, curr_center, alpha=0.5): | |
return (round(alpha * curr_center[0] + (1 - alpha) * prev_center[0]), | |
round(alpha * curr_center[1] + (1 - alpha) * prev_center[1])) | |
def crop(self, masks, original_images, crop_size_mult, bbox_smooth_alpha): | |
bounding_boxes = [] | |
combined_bounding_box = [] | |
cropped_images = [] | |
cropped_masks = [] | |
cropped_masks_out = [] | |
combined_crop_out = [] | |
combined_cropped_images = [] | |
combined_cropped_masks = [] | |
def calculate_bbox(mask): | |
non_zero_indices = np.nonzero(np.array(mask)) | |
# handle empty masks | |
min_x, max_x, min_y, max_y = 0, 0, 0, 0 | |
if len(non_zero_indices[1]) > 0 and len(non_zero_indices[0]) > 0: | |
min_x, max_x = np.min(non_zero_indices[1]), np.max(non_zero_indices[1]) | |
min_y, max_y = np.min(non_zero_indices[0]), np.max(non_zero_indices[0]) | |
width = max_x - min_x | |
height = max_y - min_y | |
bbox_size = max(width, height) | |
return min_x, max_x, min_y, max_y, bbox_size | |
combined_mask = torch.max(masks, dim=0)[0] | |
_mask = tensor2pil(combined_mask)[0] | |
new_min_x, new_max_x, new_min_y, new_max_y, combined_bbox_size = calculate_bbox(_mask) | |
center_x = (new_min_x + new_max_x) / 2 | |
center_y = (new_min_y + new_max_y) / 2 | |
half_box_size = round(combined_bbox_size // 2) | |
new_min_x = max(0, round(center_x - half_box_size)) | |
new_max_x = min(original_images[0].shape[1], round(center_x + half_box_size)) | |
new_min_y = max(0, round(center_y - half_box_size)) | |
new_max_y = min(original_images[0].shape[0], round(center_y + half_box_size)) | |
combined_bounding_box.append((new_min_x, new_min_y, new_max_x - new_min_x, new_max_y - new_min_y)) | |
self.max_bbox_size = 0 | |
# First, calculate the maximum bounding box size across all masks | |
curr_max_bbox_size = max(calculate_bbox(tensor2pil(mask)[0])[-1] for mask in masks) | |
# Smooth the changes in the bounding box size | |
self.max_bbox_size = self.smooth_bbox_size(self.max_bbox_size, curr_max_bbox_size, bbox_smooth_alpha) | |
# Apply the crop size multiplier | |
self.max_bbox_size = round(self.max_bbox_size * crop_size_mult) | |
# Make sure max_bbox_size is divisible by 16, if not, round it upwards so it is | |
self.max_bbox_size = math.ceil(self.max_bbox_size / 16) * 16 | |
if self.max_bbox_size > original_images[0].shape[0] or self.max_bbox_size > original_images[0].shape[1]: | |
# max_bbox_size can only be as big as our input's width or height, and it has to be even | |
self.max_bbox_size = math.floor(min(original_images[0].shape[0], original_images[0].shape[1]) / 2) * 2 | |
# Then, for each mask and corresponding image... | |
for i, (mask, img) in enumerate(zip(masks, original_images)): | |
_mask = tensor2pil(mask)[0] | |
non_zero_indices = np.nonzero(np.array(_mask)) | |
# check for empty masks | |
if len(non_zero_indices[0]) > 0 and len(non_zero_indices[1]) > 0: | |
min_x, max_x = np.min(non_zero_indices[1]), np.max(non_zero_indices[1]) | |
min_y, max_y = np.min(non_zero_indices[0]), np.max(non_zero_indices[0]) | |
# Calculate center of bounding box | |
center_x = np.mean(non_zero_indices[1]) | |
center_y = np.mean(non_zero_indices[0]) | |
curr_center = (round(center_x), round(center_y)) | |
# If this is the first frame, initialize prev_center with curr_center | |
if not hasattr(self, 'prev_center'): | |
self.prev_center = curr_center | |
# Smooth the changes in the center coordinates from the second frame onwards | |
if i > 0: | |
center = self.smooth_center(self.prev_center, curr_center, bbox_smooth_alpha) | |
else: | |
center = curr_center | |
# Update prev_center for the next frame | |
self.prev_center = center | |
# Create bounding box using max_bbox_size | |
half_box_size = self.max_bbox_size // 2 | |
min_x = max(0, center[0] - half_box_size) | |
max_x = min(img.shape[1], center[0] + half_box_size) | |
min_y = max(0, center[1] - half_box_size) | |
max_y = min(img.shape[0], center[1] + half_box_size) | |
# Append bounding box coordinates | |
bounding_boxes.append((min_x, min_y, max_x - min_x, max_y - min_y)) | |
# Crop the image from the bounding box | |
cropped_img = img[min_y:max_y, min_x:max_x, :] | |
cropped_mask = mask[min_y:max_y, min_x:max_x] | |
# Resize the cropped image to a fixed size | |
new_size = max(cropped_img.shape[0], cropped_img.shape[1]) | |
resize_transform = Resize(new_size, interpolation=InterpolationMode.NEAREST, max_size=max(img.shape[0], img.shape[1])) | |
resized_mask = resize_transform(cropped_mask.unsqueeze(0).unsqueeze(0)).squeeze(0).squeeze(0) | |
resized_img = resize_transform(cropped_img.permute(2, 0, 1)) | |
# Perform the center crop to the desired size | |
# Constrain the crop to the smaller of our bbox or our image so we don't expand past the image dimensions. | |
crop_transform = CenterCrop((min(self.max_bbox_size, resized_img.shape[1]), min(self.max_bbox_size, resized_img.shape[2]))) | |
cropped_resized_img = crop_transform(resized_img) | |
cropped_images.append(cropped_resized_img.permute(1, 2, 0)) | |
cropped_resized_mask = crop_transform(resized_mask) | |
cropped_masks.append(cropped_resized_mask) | |
combined_cropped_img = original_images[i][new_min_y:new_max_y, new_min_x:new_max_x, :] | |
combined_cropped_images.append(combined_cropped_img) | |
combined_cropped_mask = masks[i][new_min_y:new_max_y, new_min_x:new_max_x] | |
combined_cropped_masks.append(combined_cropped_mask) | |
else: | |
bounding_boxes.append((0, 0, img.shape[1], img.shape[0])) | |
cropped_images.append(img) | |
cropped_masks.append(mask) | |
combined_cropped_images.append(img) | |
combined_cropped_masks.append(mask) | |
cropped_out = torch.stack(cropped_images, dim=0) | |
combined_crop_out = torch.stack(combined_cropped_images, dim=0) | |
cropped_masks_out = torch.stack(cropped_masks, dim=0) | |
combined_crop_mask_out = torch.stack(combined_cropped_masks, dim=0) | |
return (original_images, cropped_out, cropped_masks_out, combined_crop_out, combined_crop_mask_out, bounding_boxes, combined_bounding_box, self.max_bbox_size, self.max_bbox_size) | |
class FilterZeroMasksAndCorrespondingImages: | |
def INPUT_TYPES(cls): | |
return { | |
"required": { | |
"masks": ("MASK",), | |
}, | |
"optional": { | |
"original_images": ("IMAGE",), | |
}, | |
} | |
RETURN_TYPES = ("MASK", "IMAGE", "IMAGE", "INDEXES",) | |
RETURN_NAMES = ("non_zero_masks_out", "non_zero_mask_images_out", "zero_mask_images_out", "zero_mask_images_out_indexes",) | |
FUNCTION = "filter" | |
CATEGORY = "KJNodes/masking" | |
DESCRIPTION = """ | |
Filter out all the empty (i.e. all zero) mask in masks | |
Also filter out all the corresponding images in original_images by indexes if provide | |
original_images (optional): If provided, need have same length as masks. | |
""" | |
def filter(self, masks, original_images=None): | |
non_zero_masks = [] | |
non_zero_mask_images = [] | |
zero_mask_images = [] | |
zero_mask_images_indexes = [] | |
masks_num = len(masks) | |
also_process_images = False | |
if original_images is not None: | |
imgs_num = len(original_images) | |
if len(original_images) == masks_num: | |
also_process_images = True | |
else: | |
print(f"[WARNING] ignore input: original_images, due to number of original_images ({imgs_num}) is not equal to number of masks ({masks_num})") | |
for i in range(masks_num): | |
non_zero_num = np.count_nonzero(np.array(masks[i])) | |
if non_zero_num > 0: | |
non_zero_masks.append(masks[i]) | |
if also_process_images: | |
non_zero_mask_images.append(original_images[i]) | |
else: | |
zero_mask_images.append(original_images[i]) | |
zero_mask_images_indexes.append(i) | |
non_zero_masks_out = torch.stack(non_zero_masks, dim=0) | |
non_zero_mask_images_out = zero_mask_images_out = zero_mask_images_out_indexes = None | |
if also_process_images: | |
non_zero_mask_images_out = torch.stack(non_zero_mask_images, dim=0) | |
if len(zero_mask_images) > 0: | |
zero_mask_images_out = torch.stack(zero_mask_images, dim=0) | |
zero_mask_images_out_indexes = zero_mask_images_indexes | |
return (non_zero_masks_out, non_zero_mask_images_out, zero_mask_images_out, zero_mask_images_out_indexes) | |
class InsertImageBatchByIndexes: | |
def INPUT_TYPES(cls): | |
return { | |
"required": { | |
"images": ("IMAGE",), | |
"images_to_insert": ("IMAGE",), | |
"insert_indexes": ("INDEXES",), | |
}, | |
} | |
RETURN_TYPES = ("IMAGE", ) | |
RETURN_NAMES = ("images_after_insert", ) | |
FUNCTION = "insert" | |
CATEGORY = "KJNodes/image" | |
DESCRIPTION = """ | |
This node is designed to be use with node FilterZeroMasksAndCorrespondingImages | |
It inserts the images_to_insert into images according to insert_indexes | |
Returns: | |
images_after_insert: updated original images with origonal sequence order | |
""" | |
def insert(self, images, images_to_insert, insert_indexes): | |
images_after_insert = images | |
if images_to_insert is not None and insert_indexes is not None: | |
images_to_insert_num = len(images_to_insert) | |
insert_indexes_num = len(insert_indexes) | |
if images_to_insert_num == insert_indexes_num: | |
images_after_insert = [] | |
i_images = 0 | |
for i in range(len(images) + images_to_insert_num): | |
if i in insert_indexes: | |
images_after_insert.append(images_to_insert[insert_indexes.index(i)]) | |
else: | |
images_after_insert.append(images[i_images]) | |
i_images += 1 | |
images_after_insert = torch.stack(images_after_insert, dim=0) | |
else: | |
print(f"[WARNING] skip this node, due to number of images_to_insert ({images_to_insert_num}) is not equal to number of insert_indexes ({insert_indexes_num})") | |
return (images_after_insert, ) | |
class BatchUncropAdvanced: | |
def INPUT_TYPES(cls): | |
return { | |
"required": { | |
"original_images": ("IMAGE",), | |
"cropped_images": ("IMAGE",), | |
"cropped_masks": ("MASK",), | |
"combined_crop_mask": ("MASK",), | |
"bboxes": ("BBOX",), | |
"border_blending": ("FLOAT", {"default": 0.25, "min": 0.0, "max": 1.0, "step": 0.01}, ), | |
"crop_rescale": ("FLOAT", {"default": 1.0, "min": 0.0, "max": 10.0, "step": 0.01}), | |
"use_combined_mask": ("BOOLEAN", {"default": False}), | |
"use_square_mask": ("BOOLEAN", {"default": True}), | |
}, | |
"optional": { | |
"combined_bounding_box": ("BBOX", {"default": None}), | |
}, | |
} | |
RETURN_TYPES = ("IMAGE",) | |
FUNCTION = "uncrop" | |
CATEGORY = "KJNodes/masking" | |
def uncrop(self, original_images, cropped_images, cropped_masks, combined_crop_mask, bboxes, border_blending, crop_rescale, use_combined_mask, use_square_mask, combined_bounding_box = None): | |
def inset_border(image, border_width=20, border_color=(0)): | |
width, height = image.size | |
bordered_image = Image.new(image.mode, (width, height), border_color) | |
bordered_image.paste(image, (0, 0)) | |
draw = ImageDraw.Draw(bordered_image) | |
draw.rectangle((0, 0, width - 1, height - 1), outline=border_color, width=border_width) | |
return bordered_image | |
if len(original_images) != len(cropped_images): | |
raise ValueError(f"The number of original_images ({len(original_images)}) and cropped_images ({len(cropped_images)}) should be the same") | |
# Ensure there are enough bboxes, but drop the excess if there are more bboxes than images | |
if len(bboxes) > len(original_images): | |
print(f"Warning: Dropping excess bounding boxes. Expected {len(original_images)}, but got {len(bboxes)}") | |
bboxes = bboxes[:len(original_images)] | |
elif len(bboxes) < len(original_images): | |
raise ValueError("There should be at least as many bboxes as there are original and cropped images") | |
crop_imgs = tensor2pil(cropped_images) | |
input_images = tensor2pil(original_images) | |
out_images = [] | |
for i in range(len(input_images)): | |
img = input_images[i] | |
crop = crop_imgs[i] | |
bbox = bboxes[i] | |
if use_combined_mask: | |
bb_x, bb_y, bb_width, bb_height = combined_bounding_box[0] | |
paste_region = bbox_to_region((bb_x, bb_y, bb_width, bb_height), img.size) | |
mask = combined_crop_mask[i] | |
else: | |
bb_x, bb_y, bb_width, bb_height = bbox | |
paste_region = bbox_to_region((bb_x, bb_y, bb_width, bb_height), img.size) | |
mask = cropped_masks[i] | |
# scale paste_region | |
scale_x = scale_y = crop_rescale | |
paste_region = (round(paste_region[0]*scale_x), round(paste_region[1]*scale_y), round(paste_region[2]*scale_x), round(paste_region[3]*scale_y)) | |
# rescale the crop image to fit the paste_region | |
crop = crop.resize((round(paste_region[2]-paste_region[0]), round(paste_region[3]-paste_region[1]))) | |
crop_img = crop.convert("RGB") | |
#border blending | |
if border_blending > 1.0: | |
border_blending = 1.0 | |
elif border_blending < 0.0: | |
border_blending = 0.0 | |
blend_ratio = (max(crop_img.size) / 2) * float(border_blending) | |
blend = img.convert("RGBA") | |
if use_square_mask: | |
mask = Image.new("L", img.size, 0) | |
mask_block = Image.new("L", (paste_region[2]-paste_region[0], paste_region[3]-paste_region[1]), 255) | |
mask_block = inset_border(mask_block, round(blend_ratio / 2), (0)) | |
mask.paste(mask_block, paste_region) | |
else: | |
original_mask = tensor2pil(mask)[0] | |
original_mask = original_mask.resize((paste_region[2]-paste_region[0], paste_region[3]-paste_region[1])) | |
mask = Image.new("L", img.size, 0) | |
mask.paste(original_mask, paste_region) | |
mask = mask.filter(ImageFilter.BoxBlur(radius=blend_ratio / 4)) | |
mask = mask.filter(ImageFilter.GaussianBlur(radius=blend_ratio / 4)) | |
blend.paste(crop_img, paste_region) | |
blend.putalpha(mask) | |
img = Image.alpha_composite(img.convert("RGBA"), blend) | |
out_images.append(img.convert("RGB")) | |
return (pil2tensor(out_images),) | |
class SplitBboxes: | |
def INPUT_TYPES(cls): | |
return { | |
"required": { | |
"bboxes": ("BBOX",), | |
"index": ("INT", {"default": 0,"min": 0, "max": 99999999, "step": 1}), | |
}, | |
} | |
RETURN_TYPES = ("BBOX","BBOX",) | |
RETURN_NAMES = ("bboxes_a","bboxes_b",) | |
FUNCTION = "splitbbox" | |
CATEGORY = "KJNodes/masking" | |
DESCRIPTION = """ | |
Splits the specified bbox list at the given index into two lists. | |
""" | |
def splitbbox(self, bboxes, index): | |
bboxes_a = bboxes[:index] # Sub-list from the start of bboxes up to (but not including) the index | |
bboxes_b = bboxes[index:] # Sub-list from the index to the end of bboxes | |
return (bboxes_a, bboxes_b,) | |
class BboxToInt: | |
def INPUT_TYPES(cls): | |
return { | |
"required": { | |
"bboxes": ("BBOX",), | |
"index": ("INT", {"default": 0,"min": 0, "max": 99999999, "step": 1}), | |
}, | |
} | |
RETURN_TYPES = ("INT","INT","INT","INT","INT","INT",) | |
RETURN_NAMES = ("x_min","y_min","width","height", "center_x","center_y",) | |
FUNCTION = "bboxtoint" | |
CATEGORY = "KJNodes/masking" | |
DESCRIPTION = """ | |
Returns selected index from bounding box list as integers. | |
""" | |
def bboxtoint(self, bboxes, index): | |
x_min, y_min, width, height = bboxes[index] | |
center_x = int(x_min + width / 2) | |
center_y = int(y_min + height / 2) | |
return (x_min, y_min, width, height, center_x, center_y,) | |
class BboxVisualize: | |
def INPUT_TYPES(cls): | |
return { | |
"required": { | |
"images": ("IMAGE",), | |
"bboxes": ("BBOX",), | |
"line_width": ("INT", {"default": 1,"min": 1, "max": 10, "step": 1}), | |
}, | |
} | |
RETURN_TYPES = ("IMAGE",) | |
RETURN_NAMES = ("images",) | |
FUNCTION = "visualizebbox" | |
DESCRIPTION = """ | |
Visualizes the specified bbox on the image. | |
""" | |
CATEGORY = "KJNodes/masking" | |
def visualizebbox(self, bboxes, images, line_width): | |
image_list = [] | |
for image, bbox in zip(images, bboxes): | |
x_min, y_min, width, height = bbox | |
# Ensure bbox coordinates are integers | |
x_min = int(x_min) | |
y_min = int(y_min) | |
width = int(width) | |
height = int(height) | |
# Permute the image dimensions | |
image = image.permute(2, 0, 1) | |
# Clone the image to draw bounding boxes | |
img_with_bbox = image.clone() | |
# Define the color for the bbox, e.g., red | |
color = torch.tensor([1, 0, 0], dtype=torch.float32) | |
# Ensure color tensor matches the image channels | |
if color.shape[0] != img_with_bbox.shape[0]: | |
color = color.unsqueeze(1).expand(-1, line_width) | |
# Draw lines for each side of the bbox with the specified line width | |
for lw in range(line_width): | |
# Top horizontal line | |
if y_min + lw < img_with_bbox.shape[1]: | |
img_with_bbox[:, y_min + lw, x_min:x_min + width] = color[:, None] | |
# Bottom horizontal line | |
if y_min + height - lw < img_with_bbox.shape[1]: | |
img_with_bbox[:, y_min + height - lw, x_min:x_min + width] = color[:, None] | |
# Left vertical line | |
if x_min + lw < img_with_bbox.shape[2]: | |
img_with_bbox[:, y_min:y_min + height, x_min + lw] = color[:, None] | |
# Right vertical line | |
if x_min + width - lw < img_with_bbox.shape[2]: | |
img_with_bbox[:, y_min:y_min + height, x_min + width - lw] = color[:, None] | |
# Permute the image dimensions back | |
img_with_bbox = img_with_bbox.permute(1, 2, 0).unsqueeze(0) | |
image_list.append(img_with_bbox) | |
return (torch.cat(image_list, dim=0),) | |
return (torch.cat(image_list, dim=0),) |