~speedprog/mtg/mtg_card_detector.git

			@@ -2,6 +2,8 @@
			import numpy as np
			import os
			import sys
			import math
			from operator import itemgetter


			# Disclaimer: majority of the basic framework in this file is modified from the following tutorial:
			@@ -17,7 +19,7 @@


			# Remove the bounding boxes with low confidence using non-maxima suppression
			def postprocess(frame, outs, classes, thresh_conf, thresh_nms):
			def post_process(frame, outs, thresh_conf, thresh_nms):
			frame_height = frame.shape[0]
			frame_width = frame.shape[1]

			@@ -42,17 +44,11 @@
			confidences.append(float(confidence))
			boxes.append([left, top, width, height])

			# Perform non maximum suppression to eliminate redundant overlapping boxes with
			# lower confidences.
			indices = cv2.dnn.NMSBoxes(boxes, confidences, thresh_conf, thresh_nms)
			for i in indices:
			i = i[0]
			box = boxes[i]
			left = box[0]
			top = box[1]
			width = box[2]
			height = box[3]
			draw_pred(frame, class_ids[i], classes, confidences[i], left, top, left + width, top + height)
			# Perform non maximum suppression to eliminate redundant overlapping boxes with lower confidences.
			indices = [ind[0] for ind in cv2.dnn.NMSBoxes(boxes, confidences, thresh_conf, thresh_nms)]

			ret = [[class_ids[i], confidences[i], boxes[i]] for i in indices]
			return ret


			# Draw the predicted bounding box
			@@ -73,7 +69,104 @@
			cv2.putText(frame, label, (left, top), cv2.FONT_HERSHEY_SIMPLEX, 0.5, (255, 255, 255))


			def detect_frame(net, classes, img, thresh_conf=0.5, thresh_nms=0.4, in_dim=(416, 416), out_path=None):
			def remove_glare(img):
			"""
			Inspired from:
			http://www.amphident.de/en/blog/preprocessing-for-automatic-pattern-identification-in-wildlife-removing-glare.html
			The idea is to find area that has low saturation but high value, which is what a glare usually look like.
			"""
			img_hsv = cv2.cvtColor(img, cv2.COLOR_BGR2HSV)
			_, s, v = cv2.split(img_hsv)
			non_sat = (s < 32) * 255 # Find all pixels that are not very saturated

			# Slightly decrease the area of the non-satuared pixels by a erosion operation.
			disk = cv2.getStructuringElement(cv2.MORPH_ELLIPSE, (3, 3))
			non_sat = cv2.erode(non_sat.astype(np.uint8), disk)

			# Set all brightness values, where the pixels are still saturated to 0.
			v[non_sat == 0] = 0
			# filter out very bright pixels.
			glare = (v > 240) * 255

			# Slightly increase the area for each pixel
			glare = cv2.dilate(glare.astype(np.uint8), disk)
			glare_reduced = np.ones((img.shape[0], img.shape[1], 3), dtype=np.uint8) * 200
			glare = cv2.cvtColor(glare, cv2.COLOR_GRAY2BGR)
			corrected = np.where(glare, glare_reduced, img)
			return corrected


			def find_card(img, thresh_val=80, blur_radius=None, dilate_radius=None, min_hyst=80, max_hyst=200, min_line_length=None, max_line_gap=None, debug=False):
			# Default values
			if blur_radius is None:
			blur_radius = math.floor(min(img.shape[:2]) / 100 + 0.5) // 2 * 2 + 1 # Rounded to the nearest odd
			if dilate_radius is None:
			dilate_radius = math.floor(min(img.shape[:2]) / 67 + 0.5)
			if min_line_length is None:
			min_line_length = min(img.shape[:2]) / 3
			if max_line_gap is None:
			max_line_gap = min(img.shape[:2]) / 10

			thresh_radius = math.floor(min(img.shape[:2]) / 50 + 0.5) // 2 * 2 + 1 # Rounded to the nearest odd

			print(blur_radius, dilate_radius, thresh_radius, min_line_length, max_line_gap)
			'''
			blur_radius = 3
			dilate_radius = 3
			thresh_radius = 3
			min_line_length = 5
			max_line_gap = 5
			'''

			img_gray = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)
			# Median blur better removes background textures than Gaussian blur
			img_blur = cv2.medianBlur(img_gray, blur_radius)
			# Truncate the bright area while detecting the border
			img_thresh = cv2.adaptiveThreshold(img_blur, 128, cv2.ADAPTIVE_THRESH_MEAN_C, cv2.THRESH_BINARY_INV, thresh_radius, 5)
			# _, img_thresh = cv2.threshold(img_blur, thresh_val, 255, cv2.THRESH_TRUNC)

			# Dilate the image to emphasize thick borders around the card
			kernel_dilate = np.ones((dilate_radius, dilate_radius), np.uint8)
			img_dilate = cv2.dilate(img_thresh, kernel_dilate, iterations=1)
			img_dilate = cv2.erode(img_dilate, kernel_dilate, iterations=1)

			img_contour = img_dilate.copy()
			_, contours, _ = cv2.findContours(img_contour, cv2.RETR_TREE, cv2.CHAIN_APPROX_SIMPLE)
			img_contour = cv2.cvtColor(img_contour, cv2.COLOR_GRAY2BGR)
			img_contour = cv2.drawContours(img_contour, contours, -1, (128, 0, 0), 1)

			# find the biggest area
			c = max(contours, key=cv2.contourArea)

			x, y, w, h = cv2.boundingRect(c)
			# draw the book contour (in green)
			img_contour = cv2.drawContours(img_contour, [c], -1, (0, 255, 0), 1)

			# Canny edge - low minimum hysteresis to detect glowed area,
			# and high maximum hysteresis to compensate for high false positives.
			img_canny = cv2.Canny(img_dilate, min_hyst, max_hyst)

			detected_lines = cv2.HoughLinesP(img_dilate, 1, np.pi / 180, threshold=300,
			minLineLength=min_line_length,
			maxLineGap=max_line_gap)
			card_found = detected_lines is not None
			if card_found:
			print(len(detected_lines))

			img_hough = cv2.cvtColor(img_canny.copy(), cv2.COLOR_GRAY2BGR)
			if card_found:
			for line in detected_lines:
			x1, y1, x2, y2 = line[0]
			cv2.line(img_hough, (x1, y1), (x2, y2), (0, 0, 255), 1)

			img_thresh = cv2.cvtColor(img_thresh, cv2.COLOR_GRAY2BGR)
			img_dilate = cv2.cvtColor(img_dilate, cv2.COLOR_GRAY2BGR)
			#img_canny = cv2.cvtColor(img_canny, cv2.COLOR_GRAY2BGR)
			return img_thresh, img_dilate, img_contour, img_hough


			def detect_frame(net, classes, img, thresh_conf=0.5, thresh_nms=0.4, in_dim=(416, 416), display=True, out_path=None):
			img_copy = img.copy()
			# Create a 4D blob from a frame.
			blob = cv2.dnn.blobFromImage(img, 1 / 255, in_dim, [0, 0, 0], 1, crop=False)

			@@ -84,7 +177,11 @@
			outs = net.forward(get_outputs_names(net))

			# Remove the bounding boxes with low confidence
			postprocess(img, outs, classes, thresh_conf, thresh_nms)
			obj_list = post_process(img, outs, thresh_conf, thresh_nms)
			for obj in obj_list:
			class_id, confidence, box = obj
			left, top, width, height = box
			draw_pred(img, class_id, classes, confidence, left, top, left + width, top + height)

			# Put efficiency information. The function getPerfProfile returns the
			# overall time for inference(t) and the timings for each of the layers(in layersTimes)
			@@ -94,13 +191,30 @@

			if out_path is not None:
			cv2.imwrite(out_path, img.astype(np.uint8))
			if display:
			no_glare = remove_glare(img_copy)
			img_concat = np.concatenate((img, no_glare), axis=1)
			cv2.imshow('result', img_concat)
			for i in range(len(obj_list)):
			class_id, confidence, box = obj_list[i]
			left, top, width, height = box
			img_snip = img_copy[max(0, top):min(img.shape[0], top + height),
			max(0, left):min(img.shape[1], left + width)]
			img_thresh, img_dilate, img_canny, img_hough = find_card(img_snip)
			img_concat = np.concatenate((img_snip, img_thresh, img_dilate, img_canny, img_hough), axis=1)
			cv2.imshow('feature#%d' % i, img_concat)
			cv2.waitKey(0)
			cv2.destroyAllWindows()

			return obj_list


			def detect_video(net, classes, capture, thresh_conf=0.5, thresh_nms=0.4, in_dim=(416, 416), out_path=None):
			def detect_video(net, classes, capture, thresh_conf=0.5, thresh_nms=0.4, in_dim=(416, 416), display=True, out_path=None):
			if out_path is not None:
			vid_writer = cv2.VideoWriter(out_path, cv2.VideoWriter_fourcc('M', 'J', 'P', 'G'), 30,
			(round(capture.get(cv2.CAP_PROP_FRAME_WIDTH)),
			round(capture.get(cv2.CAP_PROP_FRAME_HEIGHT))))
			max_num_obj = 0
			while True:
			ret, frame = capture.read()
			if not ret:
			@@ -108,28 +222,26 @@
			print("End of video. Press any key to exit")
			cv2.waitKey(0)
			break
			'''
			# Create a 4D blob from a frame.
			blob = cv2.dnn.blobFromImage(frame, 1 / 255, in_dim, [0, 0, 0], 1, crop=False)

			# Sets the input to the network
			net.setInput(blob)

			# Runs the forward pass to get output of the output layers
			outs = net.forward(get_outputs_names(net))

			# Remove the bounding boxes with low confidence
			postprocess(frame, outs, classes, thresh_conf, thresh_nms)

			# Put efficiency information. The function getPerfProfile returns the
			# overall time for inference(t) and the timings for each of the layers(in layersTimes)
			t, _ = net.getPerfProfile()
			label = 'Inference time: %.2f ms' % (t * 1000.0 / cv2.getTickFrequency())
			cv2.putText(frame, label, (0, 15), cv2.FONT_HERSHEY_SIMPLEX, 0.5, (0, 0, 255))
			'''
			detect_frame(net, classes, frame,
			thresh_conf=thresh_conf, thresh_nms=thresh_nms, in_dim=in_dim, out_path=None)
			cv2.imshow('result', frame)
			img = frame.copy()
			obj_list = detect_frame(net, classes, frame, thresh_conf=thresh_conf, thresh_nms=thresh_nms, in_dim=in_dim,
			display=False, out_path=None)
			max_num_obj = max(max_num_obj, len(obj_list))
			if display:
			no_glare = remove_glare(img)
			img_concat = np.concatenate((frame, no_glare), axis=1)
			cv2.imshow('result', img_concat)
			for i in range(len(obj_list)):
			class_id, confidence, box = obj_list[i]
			left, top, width, height = box
			img_snip = img[max(0, top):min(img.shape[0], top + height),
			max(0, left):min(img.shape[1], left + width)]
			img_thresh, img_dilate, img_canny, img_hough = find_card(img_snip)
			img_concat = np.concatenate((img_snip, img_thresh, img_dilate, img_canny, img_hough), axis=1)
			cv2.imshow('feature#%d' % i, img_concat)
			for i in range(len(obj_list), max_num_obj):
			cv2.imshow('feature#%d' % i, np.zeros((1, 1), dtype=np.uint8))
			if len(obj_list) > 0:
			cv2.waitKey(0)
			if out_path is not None:
			vid_writer.write(frame.astype(np.uint8))
			cv2.waitKey(1)
			@@ -137,24 +249,27 @@
			if out_path is not None:
			vid_writer.release()
			cv2.destroyAllWindows()
			pass


			def main():
			# Specify paths for all necessary files
			test_path = '../data/test1.mp4'
			test_path = os.path.abspath('../data/test1.jpg')
			weight_path = 'weights/second_general/tiny_yolo_final.weights'
			cfg_path = 'cfg/tiny_yolo.cfg'
			class_path = "data/obj.names"
			out_dir = 'out'
			if not os.path.isfile(test_path):
			print('The test file %s doesn\'t exist!' % os.path.abspath(test_path))
			return
			if not os.path.isfile(weight_path):
			print('The weight file %s doesn\'t exist!' % os.path.abspath(test_path))
			return
			if not os.path.isfile(cfg_path):
			print('The config file %s doesn\'t exist!' % os.path.abspath(test_path))
			return
			if not os.path.isfile(class_path):
			print('The class file %s doesn\'t exist!' % os.path.abspath(test_path))
			return

			# Setup
			# Read class names from text file
			@@ -162,8 +277,8 @@
			classes = [line.strip() for line in f.readlines()]
			# Load up the neural net using the config and weights
			net = cv2.dnn.readNetFromDarknet(cfg_path, weight_path)
			#net.setPreferableBackend(cv2.dnn.DNN_BACKEND_OPENCV)
			#net.setPreferableTarget(cv2.dnn.DNN_TARGET_CPU)
			net.setPreferableBackend(cv2.dnn.DNN_BACKEND_OPENCV)
			net.setPreferableTarget(cv2.dnn.DNN_TARGET_CPU)

			# Save the detection result if out_dir is provided
			if out_dir is None or out_dir == '':
			@@ -172,6 +287,7 @@
			out_path = out_dir + '/' + os.path.split(test_path)[1]
			# Check if test file is image or video
			test_ext = test_path[test_path.find('.') + 1:]

			if test_ext in ['jpg', 'jpeg', 'bmp', 'png', 'tiff']:
			img = cv2.imread(test_path)
			detect_frame(net, classes, img, out_path=out_path)