markjay4k/drawlines_kmeans.py

## drawlines_kmeans.py
import cv2
from directkeys import PressKey, ReleaseKey
from grabscreen import grab_screen
import numpy as np
import pyautogui
from sklearn.cluster import KMeans
import threading
import time

uhd_x = 1520
uhd_y = 792
BOX = (uhd_x, uhd_y, uhd_x + 800, uhd_y + 600)

hood_y = 410
horizon_y = 260
side_y = 50
keytime = 0.1

STRAIGHT = 0x11
RIGHT = 0x20
LEFT = 0x1E

VERTICES = np.array([[4, horizon_y + side_y],
                     [220, horizon_y], [580, horizon_y],
                     [800, horizon_y + side_y],
                     [800, hood_y], [4, hood_y]])

for i in range(3, 0, -1):
    time.sleep(.4)
    print(i)


def t_key(key_a, key_b, key_c):
    PressKey(key_a)
    ReleaseKey(key_b)
    ReleaseKey(key_c)
    time.sleep(keytime)


def straight():
    thread_straight = threading.Thread(target=t_key,
                                       args=(STRAIGHT, RIGHT, LEFT))
    thread_straight.start()


def right():
    thread_right = threading.Thread(target=t_key,
                                    args=(RIGHT, STRAIGHT, LEFT))
    thread_right.start()


def left():
    thread_left = threading.Thread(target=t_key,
                                   args=(LEFT, STRAIGHT, RIGHT))
    thread_left.start()


def slope(line):
    try:
        y = line[1] - line[3]
        x = line[0] - line[2]
        slope = np.divide(y, x)
    except ZeroDivisionError:
        slope = 100000
    finally:
        return slope


def drive(m=None):
    sign = np.sum(np.sign(m))
    if sign == -2:
        right()
    elif sign == 2:
        left()
    else:
        straight()


def draw_lines(img, lines):
    try:
        m = []
        for coords in lines:
            m.append(slope(coords))
            coords = np.array(coords, dtype='uint32')
            cv2.line(img,
                     (coords[0], coords[1]),
                     (coords[2], coords[3]),
                     [255, 255, 255], 20)
    except TypeError as e:
        print('draw lines error: {}'.format(e))
    else:
        pass
        drive(m)


def roi(img, vertices):
    mask = np.zeros_like(img)
    cv2.fillPoly(mask, vertices, 255)
    masked = cv2.bitwise_and(img, mask)
    return masked


def process_img(original_img):

    processed_img = cv2.Canny(original_img,
                              threshold1=100, threshold2=300)

    processed_img = roi(processed_img, [VERTICES])

    processed_img = cv2.GaussianBlur(processed_img, (5, 5), 0)
    lines = cv2.HoughLinesP(processed_img, 1,
                            np.pi / 180, 180, np.array([]), 120, 20)

    # draw_lines(processed_img, nlines)

    try:
        nlines = np.array([l[0] for l in lines])
        kmeans = KMeans(n_clusters=2, random_state=0).fit(nlines)
        draw_lines(processed_img, kmeans.cluster_centers_)
    except (ValueError, TypeError) as e:
        print('Kmeans error: {}'.format(e))

    return processed_img


def main():
    while True:
        ti = time.time()
        screen = grab_screen(region=BOX)
        cv2.imshow('window', cv2.cvtColor(screen,
                                          cv2.COLOR_BGR2RGB))

        new_screen = process_img(screen)
        cv2.imshow('window2', new_screen)

        print('{:.2f} FPS'.format(1 / (time.time() - ti)))
        if cv2.waitKey(25) & 0xFF == ord('q'):
            cv2.destroyAllWindows()
            break


if __name__ == '__main__':
    main()
	import cv2
	from directkeys import PressKey, ReleaseKey
	from grabscreen import grab_screen
	import numpy as np
	import pyautogui
	from sklearn.cluster import KMeans
	import threading
	import time

	uhd_x = 1520
	uhd_y = 792
	BOX = (uhd_x, uhd_y, uhd_x + 800, uhd_y + 600)

	hood_y = 410
	horizon_y = 260
	side_y = 50
	keytime = 0.1

	STRAIGHT = 0x11
	RIGHT = 0x20
	LEFT = 0x1E

	VERTICES = np.array([[4, horizon_y + side_y],
	[220, horizon_y], [580, horizon_y],
	[800, horizon_y + side_y],
	[800, hood_y], [4, hood_y]])

	for i in range(3, 0, -1):
	time.sleep(.4)
	print(i)


	def t_key(key_a, key_b, key_c):
	PressKey(key_a)
	ReleaseKey(key_b)
	ReleaseKey(key_c)
	time.sleep(keytime)


	def straight():
	thread_straight = threading.Thread(target=t_key,
	args=(STRAIGHT, RIGHT, LEFT))
	thread_straight.start()


	def right():
	thread_right = threading.Thread(target=t_key,
	args=(RIGHT, STRAIGHT, LEFT))
	thread_right.start()


	def left():
	thread_left = threading.Thread(target=t_key,
	args=(LEFT, STRAIGHT, RIGHT))
	thread_left.start()


	def slope(line):
	try:
	y = line[1] - line[3]
	x = line[0] - line[2]
	slope = np.divide(y, x)
	except ZeroDivisionError:
	slope = 100000
	finally:
	return slope


	def drive(m=None):
	sign = np.sum(np.sign(m))
	if sign == -2:
	right()
	elif sign == 2:
	left()
	else:
	straight()


	def draw_lines(img, lines):
	try:
	m = []
	for coords in lines:
	m.append(slope(coords))
	coords = np.array(coords, dtype='uint32')
	cv2.line(img,
	(coords[0], coords[1]),
	(coords[2], coords[3]),
	[255, 255, 255], 20)
	except TypeError as e:
	print('draw lines error: {}'.format(e))
	else:
	pass
	drive(m)


	def roi(img, vertices):
	mask = np.zeros_like(img)
	cv2.fillPoly(mask, vertices, 255)
	masked = cv2.bitwise_and(img, mask)
	return masked


	def process_img(original_img):

	processed_img = cv2.Canny(original_img,
	threshold1=100, threshold2=300)

	processed_img = roi(processed_img, [VERTICES])

	processed_img = cv2.GaussianBlur(processed_img, (5, 5), 0)
	lines = cv2.HoughLinesP(processed_img, 1,
	np.pi / 180, 180, np.array([]), 120, 20)

	# draw_lines(processed_img, nlines)

	try:
	nlines = np.array([l[0] for l in lines])
	kmeans = KMeans(n_clusters=2, random_state=0).fit(nlines)
	draw_lines(processed_img, kmeans.cluster_centers_)
	except (ValueError, TypeError) as e:
	print('Kmeans error: {}'.format(e))

	return processed_img


	def main():
	while True:
	ti = time.time()
	screen = grab_screen(region=BOX)
	cv2.imshow('window', cv2.cvtColor(screen,
	cv2.COLOR_BGR2RGB))

	new_screen = process_img(screen)
	cv2.imshow('window2', new_screen)

	print('{:.2f} FPS'.format(1 / (time.time() - ti)))
	if cv2.waitKey(25) & 0xFF == ord('q'):
	cv2.destroyAllWindows()
	break


	if __name__ == '__main__':
	main()