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road_line_mean_poit.py
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road_line_mean_poit.py
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#!/usr/bin/env python
# coding:utf-8
import cv2
import numpy as np
import os
from modules.sensors.proto.sensor_image_pb2 import Image
from modules.planning.proto.planning_pb2 import Trajectory
from modules.planning.proto.planning_pb2 import Point
from cyber_py import cyber
import sys
sys.path.append("../")
mask_right_cor = np.array([[[443, 300], [443, 342], [375, 342]]], dtype=np.int32)
mask_right_cor_a = (mask_right_cor[0][0][1] - mask_right_cor[0][2][1])/(mask_right_cor[0][0][0] - mask_right_cor[0][2][0])
mask_right_cor_b = (mask_right_cor[0][0][1]) - (mask_right_cor[0][0][0])*mask_right_cor_a
road_weight = 260
# roll
src_corners = [[191, 223], [272, 223], [182, 269], [297, 269]]
# turn to
dst_corners = [[152, 270], [267, 270], [152, 339], [267, 339]]
M = cv2.getPerspectiveTransform(np.float32(src_corners), np.float32(dst_corners))
car_mid_point = 228
def perspective_transform(image, m, img_size=None):
if img_size is None:
img_size = (image.shape[1], image.shape[0])
warped = cv2.warpPerspective(image, m, img_size, flags=cv2.INTER_LINEAR)
return warped
def clean_right(x_c, y_c):
val_ri_x = [tesd(x_c[ir], y_c[ir]) for ir in range(len(x_c))]
rightx_d = []
righty_d = []
for i_i, ir in enumerate(val_ri_x):
if ir == 0:
rightx_d.append(x_c[i_i])
righty_d.append(y_c[i_i])
return np.array(rightx_d), np.array(righty_d)
def get_midpoint(leftx, lefty, rightx, righty, shape):
mean_x = []
mean_y = []
tag_y = shape[0] - 1
left_tmp = -1
right_tmp = -1
get_polt_tag = 0
bs_tag = int(shape[1] / 50)
pox_arr_x_l = []
pox_arr_x_r = []
pox_arr_y = []
while tag_y >= 0:
left_x_0 = -1
right_x_0 = shape[1]
if tag_y in lefty:
for i_y, ic in enumerate(lefty):
if ic == tag_y:
left_x_0 = leftx[i_y]
break
if tag_y in righty:
for i_y, ic in enumerate(righty):
if ic == tag_y:
right_x_0 = rightx[i_y]
break
if left_x_0 == -1 and right_x_0 == shape[1]:
tag_y -= 1
get_polt_tag += 1
continue
# left no
if right_x_0 < shape[1] and left_x_0 == -1:
if left_tmp > 0:
left_x_0 = left_tmp
else:
left_x_0 = right_x_0 - road_weight
if right_x_0 == shape[1] and left_x_0 > -1:
if right_tmp > 0:
right_x_0 = right_tmp
else:
right_x_0 = left_x_0 + road_weight
left_tmp = left_x_0
right_tmp = right_x_0
if get_polt_tag < bs_tag:
pox_arr_x_l.append(left_x_0)
pox_arr_x_r.append(right_x_0)
pox_arr_y.append(tag_y)
else:
if len(pox_arr_y) > 0:
x_l = int(np.sum(pox_arr_x_l)//len(pox_arr_x_l))
x_r = int(np.sum(pox_arr_x_r) // len(pox_arr_x_r))
mean_x.append(int((x_r - x_l) / 2 + x_l))
mean_y.append(int(np.average(pox_arr_y)))
pox_arr_x_l = []
pox_arr_x_r = []
pox_arr_y = []
get_polt_tag = 0
tag_y -= 1
get_polt_tag += 1
return mean_x, mean_y
def abs_sobel_thresh(image, sobel_kernel=3, orient='x', thresh=(0, 255)):
gray = cv2.cvtColor(image, cv2.COLOR_RGB2GRAY)
if orient == 'x':
sobel = cv2.Sobel(gray, cv2.CV_64F, 1, 0, ksize=sobel_kernel)
else:
sobel = cv2.Sobel(gray, cv2.CV_64F, 0, 1, ksize=sobel_kernel)
abs_sobel = np.absolute(sobel)
scaled_sobel = np.uint8(255 * abs_sobel / np.max(abs_sobel))
sxbinary = np.zeros_like(scaled_sobel)
sxbinary[(scaled_sobel >= thresh[0]) & (scaled_sobel <= thresh[1])] = 1
return sxbinary
def get_tag_mask(image_input, tag_roi=(228, 340)):
# 转灰度
gray_d = cv2.cvtColor(image_input, cv2.COLOR_BGR2GRAY)
# 二值化
img_d = cv2.threshold(gray_d, 100, 220, cv2.THRESH_BINARY_INV)[1]
# 2次腐蚀,3次膨胀
kernel = cv2.getStructuringElement(cv2.MORPH_RECT, (3, 3))
img_d = cv2.erode(img_d, kernel, iterations=2)
img_d = cv2.dilate(img_d, kernel, iterations=3)
cv2.fillPoly(img_d, mask_right_cor, 0)
#cv2.imshow("np_bew", img_d)
# 查找轮廓
image, contours, hierarchy = cv2.findContours(img_d, cv2.RETR_EXTERNAL,
cv2.CHAIN_APPROX_TC89_KCOS)
vis = np.array([(tag_roi[0], tag_roi[1]), (tag_roi[0]-20, tag_roi[1]), (tag_roi[0]+20, tag_roi[1])])
c_max = []
max_area = 0
max_cnt = contours[0]
for i in range(len(contours)):
cnt = contours[i]
loca_tem = np.array([cv2.pointPolygonTest(cnt, (vis[0][0], vis[0][1]), False),
cv2.pointPolygonTest(cnt, (vis[1][0], vis[1][1]), False),
cv2.pointPolygonTest(cnt, (vis[2][0], vis[2][1]), False)])
is_black = 0
if loca_tem.max() <= 0:
continue
for i_i, poi in enumerate(loca_tem):
if poi == 1 and img_d[vis[i_i][1]][vis[i_i][0]] == 220:
is_black = 1
break
if is_black == 1:
area = cv2.contourArea(cnt)
if loca_tem.sum() == 3:
max_cnt = cnt
max_area = area
break
if area > max_area:
max_cnt = cnt
max_area = area
else:
continue
temp = np.ones(image_input.shape, np.uint8) * 255
if max_area > 0:
c_max.append(max_cnt)
cv2.drawContours(temp, c_max, -1, (255, 0, 0), thickness=-1)
else:
temp = np.dstack((img_d, img_d, img_d)) * 255
return temp
def translation_view(x, y):
# x2 = 100.7 + 0.00305 * x1 - 0.1677 * y1
# y2 = 28.43 - 0.1554 * x1 + 0.008986 * y1
x_r = (x * 0.00305 - y * 0.1677 + 100.7) / 100.00
y_r = (x * (-0.1554) + y * 0.008986 + 28.43) / 100.00
return x_r, y_r
def tesd(x, y):
if (mask_right_cor_b + x*mask_right_cor_a - 4) < y:
return 1
else:
return 0
def find_line_fit(img, midpoint=None, nwindows=9, margin=100, minpix=30):
histogram = np.sum(img[img.shape[0]//2:, :], axis=0)
# Create an output image to draw on and visualize the result
out_img = np.dstack((img, img, img)) * 255
# Find the peak of the left and right halves of the histogram
# These will be the starting point for the left and right lines
if midpoint is None:
midpoint = np.int(histogram.shape[0]/2)
else:
midpoint = np.int(midpoint)
leftx_base = np.argmax(histogram[:midpoint])
rightx_base = np.argmax(histogram[midpoint:]) + midpoint
# Set height of windows
window_height = np.int(img.shape[0]/nwindows)
# Identify the x and y positions of all nonzero pixels in the image
nonzero = img.nonzero()
nonzeroy = np.array(nonzero[0])
nonzerox = np.array(nonzero[1])
# Current positions to be updated for each window
leftx_current = leftx_base
rightx_current = rightx_base
# Create empty lists to receive left and right lane pixel indices
left_lane_inds = []
right_lane_inds = []
# Step through the windows one by one
for window in range(nwindows):
# Identify window boundaries in x and y (and right and left)
win_y_low = img.shape[0] - (window+1)*window_height
win_y_high = img.shape[0] - window*window_height
win_xleft_low = leftx_current - margin
win_xleft_high = leftx_current + margin
win_xright_low = rightx_current - margin
win_xright_high = rightx_current + margin
good_left_inds = ((nonzeroy >= win_y_low) & (nonzeroy < win_y_high) &
(nonzerox >= win_xleft_low) & (nonzerox < win_xleft_high)).nonzero()[0]
good_right_inds = ((nonzeroy >= win_y_low) & (nonzeroy < win_y_high) &
(nonzerox >= win_xright_low) & (nonzerox < win_xright_high)).nonzero()[0]
# Append these indices to the lists
left_lane_inds.append(good_left_inds)
right_lane_inds.append(good_right_inds)
# If you found > minpix pixels, recenter next window on their mean position
if len(good_left_inds) > minpix:
leftx_current = np.int(np.mean(nonzerox[good_left_inds]))
if len(good_right_inds) > minpix:
rightx_current = np.int(np.mean(nonzerox[good_right_inds]))
# Concatenate the arrays of indices
left_lane_inds = np.concatenate(left_lane_inds)
right_lane_inds = np.concatenate(right_lane_inds)
# Extract left and right line pixel positions
leftx = nonzerox[left_lane_inds]
lefty = nonzeroy[left_lane_inds]
rightx = nonzerox[right_lane_inds]
righty = nonzeroy[right_lane_inds]
rightx, righty = clean_right(rightx, righty)
out_img[lefty, leftx] = [255, 0, 0]
out_img[righty, rightx] = [0, 0, 255]
if len(leftx) == 0:
if len(rightx) > 0:
leftx = rightx-road_weight
lefty = righty
else:
leftx = [[0] for x_t in range(0, 9)]
lefty = [[img.shape[0]-y_t*10] for y_t in range(0,9)]
rightx = [[img.shape[1]-1] for x_t in range(0, 9)]
righty = [[img.shape[0] - y_t * 10] for y_t in range(0, 9)]
if len(righty) == 0:
if len(leftx) > 0:
rightx = leftx + road_weight
righty = lefty
mean_x, mean_y = get_midpoint(leftx, lefty, rightx, righty, img.shape)
out_img[mean_y, mean_x] = [255, 255, 0]
return mean_x, mean_y, out_img
class Exercise(object):
def __init__(self, node):
self.node = node
self.planning_path = Trajectory()
# TODO create reader
self.node.create_reader("/realsense/compressed_image", Image, self.callback)
# TODO create writer
self.writer = self.node.create_writer(
#"/perception/road_mean_point", Trajectory)
"/planning/trajectory", Trajectory)
def callback(self, data):
# TODO
# print(data.frame_no)
# TODO reshape
self.getmeanpoint(data)
# TODO publish, write to channel
if not cyber.is_shutdown():
self.write_to_channel()
def write_to_channel(self):
# TODO
self.writer.write(self.planning_path)
def getmeanpoint(self, data):
#print(data)
new_image = np.frombuffer(data.data, dtype=np.uint8)
new_image = cv2.imdecode(new_image, cv2.IMREAD_COLOR)
img = cv2.resize(new_image, (424, 408))
wrap_img = perspective_transform(img, M, img_size=(444, 343))
wrap_img3 = get_tag_mask(wrap_img)
binary = abs_sobel_thresh(wrap_img3, orient='y', sobel_kernel=3, thresh=(20, 255))
mean_x, mean_y, out_img2 = find_line_fit(binary, midpoint=car_mid_point, margin=100)
self.planning_path = Trajectory()
if len(mean_y) > 0:
mean_x_real, mean_y_real = translation_view(np.asarray(mean_x), np.asarray(mean_y))
print(mean_x_real, mean_y_real)
for i, point in enumerate(mean_y_real):
point_xy = Point()
point_xy.x = mean_x_real[i]
point_xy.y = point
self.planning_path.point.append(point_xy)
if __name__ == '__main__':
cyber.init()
# TODO update node to your name
exercise_node = cyber.Node("to_mid_point")
exercise = Exercise(exercise_node)
exercise_node.spin()
cyber.shutdown()