~speedprog/mtg/mtg_card_detector.git

			@@ -7,10 +7,30 @@
			import fetch_data
			import generate_data
			from shapely import geometry
			import pytesseract

			card_mask = cv2.imread('data/mask.png')


			def key_pts_to_yolo(key_pts, w_img, h_img):
			"""
			Convert a list of keypoints into a yolo training format
			:param key_pts: list of keypoints
			:param w_img: width of the entire image
			:param h_img: height of the entire image
			:return: <x> <y> <width> <height>
			"""
			x1 = min([pt[0] for pt in key_pts])
			x2 = max([pt[0] for pt in key_pts])
			y1 = min([pt[1] for pt in key_pts])
			y2 = max([pt[1] for pt in key_pts])
			x = (x2 + x1) / 2 / w_img
			y = (y2 + y1) / 2 / h_img
			width = (x2 - x1) / w_img
			height = (y2 - y1) / h_img
			return x, y, width, height


			class ImageGenerator:
			"""
			A template for generating a training image.
			@@ -29,7 +49,7 @@
			self.height = height
			pass

			def add_card(self, card, x=0, y=0, theta=0.0, scale=1.0):
			def add_card(self, card, x=None, y=None, theta=0.0, scale=1.0):
			"""
			Add a card to this generator scenario.
			:param card: card to be added
			@@ -39,6 +59,10 @@
			:param scale: new scale for the card
			:return: none
			"""
			if x is None:
			x = -len(card.img[0]) / 2
			if y is None:
			y = -len(card.img) / 2
			self.cards.append(card)
			card.x = x
			card.y = y
			@@ -46,15 +70,17 @@
			card.scale = scale
			pass

			def display(self):
			def display(self, debug=False):
			"""
			Display the current state of the generator
			:return: none
			"""
			self.check_visibility()
			img_bg = cv2.resize(self.img_bg, (self.width, self.height))
			img_result = cv2.resize(self.img_bg, (self.width, self.height))

			for card in self.cards:
			if card.x == 0.0 and card.y == 0.0 and card.theta == 0.0 and card.scale == 1.0:
			continue
			card_x = int(card.x + 0.5)
			card_y = int(card.y + 0.5)
			print(card_x, card_y, card.theta, card.scale)
			@@ -70,83 +96,204 @@
			card_w = len(img_rotate[0])
			card_h = len(img_rotate)
			card_crop_x1 = max(0, card_w // 2 - card_x)
			card_crop_x2 = min(card_w, card_w // 2 + len(img_bg[0]) - card_x)
			card_crop_x2 = min(card_w, card_w // 2 + len(img_result[0]) - card_x)
			card_crop_y1 = max(0, card_h // 2 - card_y)
			card_crop_y2 = min(card_h, card_h // 2 + len(img_bg) - card_y)
			card_crop_y2 = min(card_h, card_h // 2 + len(img_result) - card_y)
			img_card_crop = img_rotate[card_crop_y1:card_crop_y2, card_crop_x1:card_crop_x2]

			# Calculate the position of the corresponding area in the background
			bg_crop_x1 = max(0, card_x - (card_w // 2))
			bg_crop_x2 = min(len(img_bg[0]), int(card_x + (card_w / 2) + 0.5))
			bg_crop_x2 = min(len(img_result[0]), int(card_x + (card_w / 2) + 0.5))
			bg_crop_y1 = max(0, card_y - (card_h // 2))
			bg_crop_y2 = min(len(img_bg), int(card_y + (card_h / 2) + 0.5))
			img_bg_crop = img_bg[bg_crop_y1:bg_crop_y2, bg_crop_x1:bg_crop_x2]
			bg_crop_y2 = min(len(img_result), int(card_y + (card_h / 2) + 0.5))
			img_result_crop = img_result[bg_crop_y1:bg_crop_y2, bg_crop_x1:bg_crop_x2]

			# Override the background with the current card
			img_bg_crop = np.where(img_card_crop, img_card_crop, img_bg_crop)
			img_bg[bg_crop_y1:bg_crop_y2, bg_crop_x1:bg_crop_x2] = img_bg_crop
			img_result_crop = np.where(img_card_crop, img_card_crop, img_result_crop)
			img_result[bg_crop_y1:bg_crop_y2, bg_crop_x1:bg_crop_x2] = img_result_crop

			if debug:
			for ext_obj in card.objects:
			if ext_obj.visible:
			for pt in ext_obj.key_pts:
			cv2.circle(img_bg, card.coordinate_in_generator(pt[0], pt[1]), 2, (0, 0, 255), 2)
			cv2.circle(img_result, card.coordinate_in_generator(pt[0], pt[1]), 2, (0, 0, 255), 2)
			bounding_box = card.bb_in_generator(ext_obj.key_pts)
			cv2.rectangle(img_bg, bounding_box[0], bounding_box[2], (0, 255, 0), 2)
			cv2.rectangle(img_result, bounding_box[0], bounding_box[2], (0, 255, 0), 2)

			cv2.imshow('Result', img_bg)
			try:
			text = pytesseract.image_to_string(img_result, output_type=pytesseract.Output.DICT)
			print(text)
			except pytesseract.pytesseract.TesseractError:
			pass
			img_result = cv2.GaussianBlur(img_result, (5, 5), 0)
			cv2.imshow('Result', img_result)
			cv2.waitKey(0)
			self.img_result = img_result
			pass

			def generate_horizontal_span(self):
			def generate_horizontal_span(self, gap=None, scale=None, shift=None, jitter=None):
			"""
			Generating the first scenario where the cards are laid out in a straight horizontal line
			:return: none
			"""
			# Set scale of the cards, variance of shift & jitter to be applied if they're not given
			card_size = (len(self.cards[0].img[0]), len(self.cards[0].img))
			if scale is None:
			# Scale the cards so that card takes about 50% of the image's height
			coverage_ratio = 0.5
			scale = self.height * coverage_ratio / card_size[1]
			if shift is None:
			# Plus minus 5% of the card's height
			shift = [-card_size[1] * scale * 0.05, card_size[1] * scale * 0.05]
			pass
			if jitter is None:
			jitter = [-math.pi / 18, math.pi / 18] # Plus minus 10 degrees
			if gap is None:
			# 25% of the card's width - set symbol and 1-2 mana symbols will be visible on each card
			gap = card_size[0] * scale * 0.25

			# Determine the location of the first card
			# The cards will cover (width of a card + (# of cards - 1) * gap) pixels wide and (height of a card) pixels high
			x_anchor = int(self.width / 2 + (len(self.cards) - 1) * gap / 2)
			y_anchor = self.height // 2
			for card in self.cards:
			card.scale = scale
			card.x = x_anchor
			card.y = y_anchor
			card.theta = 0
			card.shift(shift, shift)
			card.rotate(jitter)
			x_anchor -= gap
			pass

			def generate_vertical_span(self):
			def generate_vertical_span(self, gap=None, scale=None, shift=None, jitter=None):
			"""
			Generating the second scenario where the cards are laid out in a straight vertical line
			:return: none
			"""
			# Set scale of the cards, variance of shift & jitter to be applied if they're not given
			card_size = (len(self.cards[0].img[0]), len(self.cards[0].img))
			if scale is None:
			# Scale the cards so that card takes about 50% of the image's height
			coverage_ratio = 0.5
			scale = self.height * coverage_ratio / card_size[1]
			if shift is None:
			# Plus minus 5% of the card's height
			shift = [-card_size[1] * scale * 0.05, card_size[1] * scale * 0.05]
			pass
			if jitter is None:
			# Plus minus 5 degrees
			jitter = [-math.pi / 36, math.pi / 36]
			if gap is None:
			# 15% of the card's height - the title bar (with mana symbols) will be visible
			gap = card_size[1] * scale * 0.15

			# Determine the location of the first card
			# The cards will cover (width of a card) pixels wide and (height of a card + (# of cards - 1) * gap) pixels high
			x_anchor = self.width // 2
			y_anchor = int(self.height / 2 - (len(self.cards) - 1) * gap / 2)
			for card in self.cards:
			card.scale = scale
			card.x = x_anchor
			card.y = y_anchor
			card.theta = 0
			card.shift(shift, shift)
			card.rotate(jitter)
			y_anchor += gap
			pass

			def generate_fan_out(self):
			pass

			def generate_fan_out(self, centre, theta_between_cards=None, scale=None, shift=None, jitter=None):
			"""
			Generating the third scenario where the cards are laid out in a fan shape
			:return: none
			"""
			pass

			def check_visibility(self, visibility=0.5):
			def generate_non_obstructive(self, tolerance=0.85, scale=None):
			"""
			Generating the fourth scenario where the cards are laid in arbitrary position that doesn't obstruct other cards
			:param tolerance: minimum level of visibility for each cards
			:return:
			"""
			card_size = (len(self.cards[0].img[0]), len(self.cards[0].img))
			if scale is None:
			# Total area of the cards should cover about 25-40% of the entire image, depending on the number of cards
			scale = math.sqrt(self.width * self.height * min(0.25 + 0.02 * len(self.cards), 0.4)
			/ (card_size[0] * card_size[1] * len(self.cards)))
			# Position each card at random location that doesn't obstruct other cards
			for i in range(len(self.cards)):
			card = self.cards[i]
			card.scale = scale
			while True:
			card.x = random.uniform(card_size[1] * scale / 2, self.width - card_size[1] * scale)
			card.y = random.uniform(card_size[1] * scale / 2, self.height - card_size[1] * scale)
			card.theta = random.uniform(-math.pi, math.pi)
			self.check_visibility(self.cards[:i + 1], visibility=tolerance)
			# This position is not obstructive if all of the cards are visible
			is_visible = [other_card.objects[0].visible for other_card in self.cards[:i + 1]]
			non_obstructive = all(is_visible)
			if non_obstructive:
			break

			def check_visibility(self, cards=None, i_check=None, visibility=0.5):
			"""
			Check whether if extracted objects in each card are visible in the current scenario, and update their status
			:param cards: list of cards (in a correct order)
			:param i_check: indices of cards that needs to be checked. Cards that aren't in this list will only be used
			to check visibility of other cards. All cards are checked by default.
			:param visibility: minimum ratio of the object's area that aren't covered by another card to be visible
			:return: none
			"""
			if cards is None:
			cards = self.cards
			if i_check is None:
			i_check = range(len(cards))
			card_poly_list = [geometry.Polygon([card.coordinate_in_generator(0, 0),
			card.coordinate_in_generator(0, len(card.img)),
			card.coordinate_in_generator(len(card.img[0]), len(card.img)),
			card.coordinate_in_generator(len(card.img[0]), 0)]) for card in self.cards]
			template_poly = geometry.Polygon([(0, 0), (self.width, 0), (self.width, self.height), (0, self.height)])

			# First card in the list is overlaid on the bottom of the card pile
			for i in range(len(self.cards)):
			card = self.cards[i]
			for i in i_check:
			card = cards[i]
			for ext_obj in card.objects:
			obj_poly = geometry.Polygon([card.coordinate_in_generator(pt[0], pt[1]) for pt in ext_obj.key_pts])
			obj_area = obj_poly.area
			# Check if the other cards are blocking this object
			# Check if the other cards are blocking this object or if it's out of the template
			for card_poly in card_poly_list[i + 1:]:
			obj_poly = obj_poly.difference(card_poly)
			obj_poly = obj_poly.intersection(template_poly)
			visible_area = obj_poly.area
			print("%s: %.1f visible" % (ext_obj.label, visible_area / obj_area))
			#print(visible_area, obj_area, len(card.img[0]) * len(card.img) * card.scale * card.scale)
			#print("%s: %.1f visible" % (ext_obj.label, visible_area / obj_area * 100))
			ext_obj.visible = obj_area * visibility <= visible_area

			def export_training_data(self, out_dir):
			def export_training_data(self, out_name):
			"""
			Export the generated training image along with the txt file for all bounding boxes
			:return: none
			"""
			cv2.imwrite(out_name + '.jpg', self.img_result)
			out_txt = open(out_name+ '.txt', 'w')
			for card in self.cards:
			for ext_obj in card.objects:
			if not ext_obj.visible:
			continue
			coords_in_gen = [card.coordinate_in_generator(key_pt[0], key_pt[1]) for key_pt in ext_obj.key_pts]
			obj_yolo_info = key_pts_to_yolo(coords_in_gen, self.width, self.height)
			if ext_obj.label == 'card':
			out_txt.write('0 %.6f %.6f %.6f %.6f\n' % obj_yolo_info)
			pass
			elif ext_obj.label[:ext_obj.label.find[':']] == 'mana_symbol':
			# TODO
			pass
			elif ext_obj.label[:ext_obj.label.find[':']] == 'set_symbol':
			# TODO
			pass
			out_txt.close()
			pass


			@@ -191,17 +338,20 @@
			self.y += y
			pass

			def rotate(self, centre, theta=None):
			def rotate(self, theta, centre=(0, 0)):
			"""
			Apply a rotation on this image with a centre
			:param centre: coordinate of the centre of the rotation in relation to the centre of this card
			:param theta: amount of rotation in radian (clockwise). If a range is given, rotate by a random amount within
			:param centre: coordinate of the centre of the rotation in relation to the centre of this card
			that range
			:return: none
			"""
			if isinstance(theta, tuple) or (isinstance(theta, list) and len(theta) == 2):
			theta = random.uniform(theta[0], theta[1])

			# If the centre given is the centre of this card, the whole math simplifies a bit
			# (This still works without the if statement, but let's not do useless trigs if we know the answer already)
			if centre is not (0, 0):
			# Rotation math
			self.x -= -centre[1] * math.sin(theta) + centre[0] * math.cos(theta)
			self.y -= centre[1] * math.cos(theta) + centre[0] * math.sin(theta)
			@@ -248,6 +398,12 @@
			:param key_pts: keypoints of the bounding box
			:return: bounding box represented by 4 points in the generator
			"""
			coords_in_gen = [self.coordinate_in_generator(key_pt[0], key_pt[1]) for key_pt in key_pts]
			x1 = min([pt[0] for pt in coords_in_gen])
			x2 = max([pt[0] for pt in coords_in_gen])
			y1 = min([pt[1] for pt in coords_in_gen])
			y2 = max([pt[1] for pt in coords_in_gen])
			'''
			x1 = -math.inf
			x2 = math.inf
			y1 = -math.inf
			@@ -258,6 +414,7 @@
			x2 = min(x2, coord_in_gen[0])
			y1 = max(y1, coord_in_gen[1])
			y2 = min(y2, coord_in_gen[1])
			'''
			return [(x1, y1), (x2, y1), (x2, y2), (x1, y2)]


			@@ -283,8 +440,7 @@
			is_planeswalker = 'Planeswalker' in card_info['type_line']
			if not is_planeswalker:
			card_pool = card_pool.append(card_info)
			a = 1
			for i in [random.randrange(0, card_pool.shape[0] - 1, 1) for _ in range(20)]:
			for i in [random.randrange(0, card_pool.shape[0] - 1, 1) for _ in range(4)]:
			card_info = card_pool.iloc[i]
			img_name = '../usb/data/png/%s/%s_%s.png' % (card_info['set'], card_info['collector_number'],
			fetch_data.get_valid_filename(card_info['name']))
			@@ -296,12 +452,21 @@
			detected_object_list = generate_data.apply_bounding_box(card_img, card_info)
			card = Card(card_img, card_info, detected_object_list)

			generator.add_card(card, x=random.uniform(200, generator.width - 200),
			y=random.uniform(200, generator.height - 200), theta=random.uniform(-math.pi, math.pi), scale=0.5)
			generator.add_card(card)
			#generator.add_card(card, x=random.uniform(200, generator.width - 200),
			# y=random.uniform(200, generator.height - 200), theta=random.uniform(-math.pi, math.pi), scale=0.5)
			#card.shift([-100, 100], [-100, 100])
			#card.rotate((0, 0), [-math.pi / 4, math.pi / 4])
			a += 1
			generator.display()
			import time

			for i in range(100):
			generator.generate_vertical_span()
			generator.display(debug=False)
			generator.export_training_data(out_name='data/test')
			#generator.generate_horizontal_span()
			#generator.display(debug=True)
			#generator.generate_vertical_span()
			#generator.display(debug=True)
			pass