abeec4b630
This algorithm plots a bunch of points of interest on the source image and averages their locations to find a center. Most points come from OpenCV. One point comes from an entropy model. OpenCV points account for 50% of the weight and the entropy based point is the other 50%. The center of all weighted points is calculated and a bounding box is drawn as close to centered over that point as possible.
258 lines
7.6 KiB
Python
258 lines
7.6 KiB
Python
import os
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import cv2
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import numpy as np
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from PIL import Image, ImageOps, ImageDraw
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import platform
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import sys
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import tqdm
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import time
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from modules import shared, images
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from modules.shared import opts, cmd_opts
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if cmd_opts.deepdanbooru:
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import modules.deepbooru as deepbooru
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def preprocess(process_src, process_dst, process_width, process_height, process_flip, process_split, process_caption, process_caption_deepbooru=False, process_entropy_focus=False):
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try:
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if process_caption:
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shared.interrogator.load()
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if process_caption_deepbooru:
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db_opts = deepbooru.create_deepbooru_opts()
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db_opts[deepbooru.OPT_INCLUDE_RANKS] = False
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deepbooru.create_deepbooru_process(opts.interrogate_deepbooru_score_threshold, db_opts)
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preprocess_work(process_src, process_dst, process_width, process_height, process_flip, process_split, process_caption, process_caption_deepbooru, process_entropy_focus)
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finally:
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if process_caption:
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shared.interrogator.send_blip_to_ram()
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if process_caption_deepbooru:
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deepbooru.release_process()
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def preprocess_work(process_src, process_dst, process_width, process_height, process_flip, process_split, process_caption, process_caption_deepbooru=False, process_entropy_focus=False):
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width = process_width
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height = process_height
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src = os.path.abspath(process_src)
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dst = os.path.abspath(process_dst)
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assert src != dst, 'same directory specified as source and destination'
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os.makedirs(dst, exist_ok=True)
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files = os.listdir(src)
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shared.state.textinfo = "Preprocessing..."
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shared.state.job_count = len(files)
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def save_pic_with_caption(image, index):
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caption = ""
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if process_caption:
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caption += shared.interrogator.generate_caption(image)
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if process_caption_deepbooru:
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if len(caption) > 0:
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caption += ", "
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caption += deepbooru.get_tags_from_process(image)
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filename_part = filename
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filename_part = os.path.splitext(filename_part)[0]
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filename_part = os.path.basename(filename_part)
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basename = f"{index:05}-{subindex[0]}-{filename_part}"
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image.save(os.path.join(dst, f"{basename}.png"))
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if len(caption) > 0:
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with open(os.path.join(dst, f"{basename}.txt"), "w", encoding="utf8") as file:
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file.write(caption)
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subindex[0] += 1
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def save_pic(image, index):
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save_pic_with_caption(image, index)
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if process_flip:
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save_pic_with_caption(ImageOps.mirror(image), index)
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for index, imagefile in enumerate(tqdm.tqdm(files)):
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subindex = [0]
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filename = os.path.join(src, imagefile)
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try:
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img = Image.open(filename).convert("RGB")
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except Exception:
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continue
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if shared.state.interrupted:
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break
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ratio = img.height / img.width
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is_tall = ratio > 1.35
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is_wide = ratio < 1 / 1.35
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processing_option_ran = False
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if process_split and is_tall:
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img = img.resize((width, height * img.height // img.width))
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top = img.crop((0, 0, width, height))
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save_pic(top, index)
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bot = img.crop((0, img.height - height, width, img.height))
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save_pic(bot, index)
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processing_option_ran = True
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elif process_split and is_wide:
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img = img.resize((width * img.width // img.height, height))
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left = img.crop((0, 0, width, height))
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save_pic(left, index)
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right = img.crop((img.width - width, 0, img.width, height))
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save_pic(right, index)
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processing_option_ran = True
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if process_entropy_focus and (is_tall or is_wide):
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if is_tall:
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img = img.resize((width, height * img.height // img.width))
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else:
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img = img.resize((width * img.width // img.height, height))
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x_focal_center, y_focal_center = image_central_focal_point(img, width, height)
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# take the focal point and turn it into crop coordinates that try to center over the focal
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# point but then get adjusted back into the frame
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y_half = int(height / 2)
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x_half = int(width / 2)
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x1 = x_focal_center - x_half
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if x1 < 0:
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x1 = 0
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elif x1 + width > img.width:
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x1 = img.width - width
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y1 = y_focal_center - y_half
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if y1 < 0:
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y1 = 0
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elif y1 + height > img.height:
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y1 = img.height - height
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x2 = x1 + width
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y2 = y1 + height
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crop = [x1, y1, x2, y2]
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focal = img.crop(tuple(crop))
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save_pic(focal, index)
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processing_option_ran = True
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if not processing_option_ran:
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img = images.resize_image(1, img, width, height)
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save_pic(img, index)
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shared.state.nextjob()
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def image_central_focal_point(im, target_width, target_height):
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focal_points = []
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focal_points.extend(
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image_focal_points(im)
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)
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fp_entropy = image_entropy_point(im, target_width, target_height)
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fp_entropy['weight'] = len(focal_points) + 1 # about half of the weight to entropy
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focal_points.append(fp_entropy)
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weight = 0.0
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x = 0.0
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y = 0.0
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for focal_point in focal_points:
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weight += focal_point['weight']
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x += focal_point['x'] * focal_point['weight']
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y += focal_point['y'] * focal_point['weight']
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avg_x = round(x // weight)
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avg_y = round(y // weight)
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return avg_x, avg_y
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def image_focal_points(im):
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grayscale = im.convert("L")
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# naive attempt at preventing focal points from collecting at watermarks near the bottom
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gd = ImageDraw.Draw(grayscale)
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gd.rectangle([0, im.height*.9, im.width, im.height], fill="#999")
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np_im = np.array(grayscale)
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points = cv2.goodFeaturesToTrack(
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np_im,
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maxCorners=50,
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qualityLevel=0.04,
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minDistance=min(grayscale.width, grayscale.height)*0.05,
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useHarrisDetector=False,
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)
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if points is None:
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return []
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focal_points = []
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for point in points:
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x, y = point.ravel()
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focal_points.append({
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'x': x,
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'y': y,
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'weight': 1.0
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})
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return focal_points
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def image_entropy_point(im, crop_width, crop_height):
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img = im.copy()
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# just make it easier to slide the test crop with images oriented the same way
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if (img.size[0] < img.size[1]):
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portrait = True
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img = img.rotate(90, expand=1)
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e_max = 0
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crop_current = [0, 0, crop_width, crop_height]
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crop_best = crop_current
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while crop_current[2] < img.size[0]:
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crop = img.crop(tuple(crop_current))
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e = image_entropy(crop)
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if (e_max < e):
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e_max = e
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crop_best = list(crop_current)
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crop_current[0] += 4
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crop_current[2] += 4
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x_mid = int((crop_best[2] - crop_best[0])/2)
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y_mid = int((crop_best[3] - crop_best[1])/2)
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return {
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'x': x_mid,
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'y': y_mid,
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'weight': 1.0
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}
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def image_entropy(im):
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# greyscale image entropy
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band = np.asarray(im.convert("L"))
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hist, _ = np.histogram(band, bins=range(0, 256))
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hist = hist[hist > 0]
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return -np.log2(hist / hist.sum()).sum()
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