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	import cv2
	import requests
	import os
	from collections import defaultdict
	from math import log, sqrt
	import numpy as np
	from PIL import Image, ImageDraw

	GREEN = "#0F0"
	BLUE = "#00F"
	RED = "#F00"


	def crop_image(im, settings):
	""" Intelligently crop an image to the subject matter """

	scale_by = 1
	if is_landscape(im.width, im.height):
	scale_by = settings.crop_height / im.height
	elif is_portrait(im.width, im.height):
	scale_by = settings.crop_width / im.width
	elif is_square(im.width, im.height):
	if is_square(settings.crop_width, settings.crop_height):
	scale_by = settings.crop_width / im.width
	elif is_landscape(settings.crop_width, settings.crop_height):
	scale_by = settings.crop_width / im.width
	elif is_portrait(settings.crop_width, settings.crop_height):
	scale_by = settings.crop_height / im.height

	im = im.resize((int(im.width * scale_by), int(im.height * scale_by)))
	im_debug = im.copy()

	focus = focal_point(im_debug, settings)

	# take the focal point and turn it into crop coordinates that try to center over the focal
	# point but then get adjusted back into the frame
	y_half = int(settings.crop_height / 2)
	x_half = int(settings.crop_width / 2)

	x1 = focus.x - x_half
	if x1 < 0:
	x1 = 0
	elif x1 + settings.crop_width > im.width:
	x1 = im.width - settings.crop_width

	y1 = focus.y - y_half
	if y1 < 0:
	y1 = 0
	elif y1 + settings.crop_height > im.height:
	y1 = im.height - settings.crop_height

	x2 = x1 + settings.crop_width
	y2 = y1 + settings.crop_height

	crop = [x1, y1, x2, y2]

	results = []

	results.append(im.crop(tuple(crop)))

	if settings.annotate_image:
	d = ImageDraw.Draw(im_debug)
	rect = list(crop)
	rect[2] -= 1
	rect[3] -= 1
	d.rectangle(rect, outline=GREEN)
	results.append(im_debug)
	if settings.destop_view_image:
	im_debug.show()

	return results

	def focal_point(im, settings):
	corner_points = image_corner_points(im, settings) if settings.corner_points_weight > 0 else []
	entropy_points = image_entropy_points(im, settings) if settings.entropy_points_weight > 0 else []
	face_points = image_face_points(im, settings) if settings.face_points_weight > 0 else []

	pois = []

	weight_pref_total = 0
	if len(corner_points) > 0:
	weight_pref_total += settings.corner_points_weight
	if len(entropy_points) > 0:
	weight_pref_total += settings.entropy_points_weight
	if len(face_points) > 0:
	weight_pref_total += settings.face_points_weight

	corner_centroid = None
	if len(corner_points) > 0:
	corner_centroid = centroid(corner_points)
	corner_centroid.weight = settings.corner_points_weight / weight_pref_total
	pois.append(corner_centroid)

	entropy_centroid = None
	if len(entropy_points) > 0:
	entropy_centroid = centroid(entropy_points)
	entropy_centroid.weight = settings.entropy_points_weight / weight_pref_total
	pois.append(entropy_centroid)

	face_centroid = None
	if len(face_points) > 0:
	face_centroid = centroid(face_points)
	face_centroid.weight = settings.face_points_weight / weight_pref_total
	pois.append(face_centroid)

	average_point = poi_average(pois, settings)

	if settings.annotate_image:
	d = ImageDraw.Draw(im)
	max_size = min(im.width, im.height) * 0.07
	if corner_centroid is not None:
	color = BLUE
	box = corner_centroid.bounding(max_size * corner_centroid.weight)
	d.text((box[0], box[1]-15), f"Edge: {corner_centroid.weight:.02f}", fill=color)
	d.ellipse(box, outline=color)
	if len(corner_points) > 1:
	for f in corner_points:
	d.rectangle(f.bounding(4), outline=color)
	if entropy_centroid is not None:
	color = "#ff0"
	box = entropy_centroid.bounding(max_size * entropy_centroid.weight)
	d.text((box[0], box[1]-15), f"Entropy: {entropy_centroid.weight:.02f}", fill=color)
	d.ellipse(box, outline=color)
	if len(entropy_points) > 1:
	for f in entropy_points:
	d.rectangle(f.bounding(4), outline=color)
	if face_centroid is not None:
	color = RED
	box = face_centroid.bounding(max_size * face_centroid.weight)
	d.text((box[0], box[1]-15), f"Face: {face_centroid.weight:.02f}", fill=color)
	d.ellipse(box, outline=color)
	if len(face_points) > 1:
	for f in face_points:
	d.rectangle(f.bounding(4), outline=color)

	d.ellipse(average_point.bounding(max_size), outline=GREEN)

	return average_point


	def image_face_points(im, settings):
	if settings.dnn_model_path is not None:
	detector = cv2.FaceDetectorYN.create(
	settings.dnn_model_path,
	"",
	(im.width, im.height),
	0.9, # score threshold
	0.3, # nms threshold
	5000 # keep top k before nms
	)
	faces = detector.detect(np.array(im))
	results = []
	if faces[1] is not None:
	for face in faces[1]:
	x = face[0]
	y = face[1]
	w = face[2]
	h = face[3]
	results.append(
	PointOfInterest(
	int(x + (w * 0.5)), # face focus left/right is center
	int(y + (h * 0.33)), # face focus up/down is close to the top of the head
	size = w,
	weight = 1/len(faces[1])
	)
	)
	return results
	else:
	np_im = np.array(im)
	gray = cv2.cvtColor(np_im, cv2.COLOR_BGR2GRAY)

	tries = [
	[ f'{cv2.data.haarcascades}haarcascade_eye.xml', 0.01 ],
	[ f'{cv2.data.haarcascades}haarcascade_frontalface_default.xml', 0.05 ],
	[ f'{cv2.data.haarcascades}haarcascade_profileface.xml', 0.05 ],
	[ f'{cv2.data.haarcascades}haarcascade_frontalface_alt.xml', 0.05 ],
	[ f'{cv2.data.haarcascades}haarcascade_frontalface_alt2.xml', 0.05 ],
	[ f'{cv2.data.haarcascades}haarcascade_frontalface_alt_tree.xml', 0.05 ],
	[ f'{cv2.data.haarcascades}haarcascade_eye_tree_eyeglasses.xml', 0.05 ],
	[ f'{cv2.data.haarcascades}haarcascade_upperbody.xml', 0.05 ]
	]
	for t in tries:
	classifier = cv2.CascadeClassifier(t[0])
	minsize = int(min(im.width, im.height) * t[1]) # at least N percent of the smallest side
	try:
	faces = classifier.detectMultiScale(gray, scaleFactor=1.1,
	minNeighbors=7, minSize=(minsize, minsize), flags=cv2.CASCADE_SCALE_IMAGE)
	except:
	continue

	if len(faces) > 0:
	rects = [[f[0], f[1], f[0] + f[2], f[1] + f[3]] for f in faces]
	return [PointOfInterest((r[0] +r[2]) // 2, (r[1] + r[3]) // 2, size=abs(r[0]-r[2]), weight=1/len(rects)) for r in rects]
	return []


	def image_corner_points(im, settings):
	grayscale = im.convert("L")

	# naive attempt at preventing focal points from collecting at watermarks near the bottom
	gd = ImageDraw.Draw(grayscale)
	gd.rectangle([0, im.height*.9, im.width, im.height], fill="#999")

	np_im = np.array(grayscale)

	points = cv2.goodFeaturesToTrack(
	np_im,
	maxCorners=100,
	qualityLevel=0.04,
	minDistance=min(grayscale.width, grayscale.height)*0.06,
	useHarrisDetector=False,
	)

	if points is None:
	return []

	focal_points = []
	for point in points:
	x, y = point.ravel()
	focal_points.append(PointOfInterest(x, y, size=4, weight=1/len(points)))

	return focal_points


	def image_entropy_points(im, settings):
	landscape = im.height < im.width
	portrait = im.height > im.width
	if landscape:
	move_idx = [0, 2]
	move_max = im.size[0]
	elif portrait:
	move_idx = [1, 3]
	move_max = im.size[1]
	else:
	return []

	e_max = 0
	crop_current = [0, 0, settings.crop_width, settings.crop_height]
	crop_best = crop_current
	while crop_current[move_idx[1]] < move_max:
	crop = im.crop(tuple(crop_current))
	e = image_entropy(crop)

	if (e > e_max):
	e_max = e
	crop_best = list(crop_current)

	crop_current[move_idx[0]] += 4
	crop_current[move_idx[1]] += 4

	x_mid = int(crop_best[0] + settings.crop_width/2)
	y_mid = int(crop_best[1] + settings.crop_height/2)

	return [PointOfInterest(x_mid, y_mid, size=25, weight=1.0)]


	def image_entropy(im):
	# greyscale image entropy
	# band = np.asarray(im.convert("L"))
	band = np.asarray(im.convert("1"), dtype=np.uint8)
	hist, _ = np.histogram(band, bins=range(0, 256))
	hist = hist[hist > 0]
	return -np.log2(hist / hist.sum()).sum()

	def centroid(pois):
	x = [poi.x for poi in pois]
	y = [poi.y for poi in pois]
	return PointOfInterest(sum(x)/len(pois), sum(y)/len(pois))


	def poi_average(pois, settings):
	weight = 0.0
	x = 0.0
	y = 0.0
	for poi in pois:
	weight += poi.weight
	x += poi.x * poi.weight
	y += poi.y * poi.weight
	avg_x = round(weight and x / weight)
	avg_y = round(weight and y / weight)

	return PointOfInterest(avg_x, avg_y)


	def is_landscape(w, h):
	return w > h


	def is_portrait(w, h):
	return h > w


	def is_square(w, h):
	return w == h


	def download_and_cache_models(dirname):
	download_url = 'https://github.com/opencv/opencv_zoo/blob/91fb0290f50896f38a0ab1e558b74b16bc009428/models/face_detection_yunet/face_detection_yunet_2022mar.onnx?raw=true'
	model_file_name = 'face_detection_yunet.onnx'

	if not os.path.exists(dirname):
	os.makedirs(dirname)

	cache_file = os.path.join(dirname, model_file_name)
	if not os.path.exists(cache_file):
	print(f"downloading face detection model from '{download_url}' to '{cache_file}'")
	response = requests.get(download_url)
	with open(cache_file, "wb") as f:
	f.write(response.content)

	if os.path.exists(cache_file):
	return cache_file
	return None


	class PointOfInterest:
	def __init__(self, x, y, weight=1.0, size=10):
	self.x = x
	self.y = y
	self.weight = weight
	self.size = size

	def bounding(self, size):
	return [
	self.x - size//2,
	self.y - size//2,
	self.x + size//2,
	self.y + size//2
	]


	class Settings:
	def __init__(self, crop_width=512, crop_height=512, corner_points_weight=0.5, entropy_points_weight=0.5, face_points_weight=0.5, annotate_image=False, dnn_model_path=None):
	self.crop_width = crop_width
	self.crop_height = crop_height
	self.corner_points_weight = corner_points_weight
	self.entropy_points_weight = entropy_points_weight
	self.face_points_weight = face_points_weight
	self.annotate_image = annotate_image
	self.destop_view_image = False
	self.dnn_model_path = dnn_model_path