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line_utils.py
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line_utils.py
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import numpy as np
import cv2
import glob
import collections
import matplotlib.pyplot as plt
from calibration_utils import calibrate_camera, undistort
from binarization_utils import binarize
from perspective_utils import birdeye
from globals import ym_per_pix, xm_per_pix
class Line:
"""
Class to model a lane-line.
"""
def __init__(self, buffer_len=10):
# flag to mark if the line was detected the last iteration
self.detected = False
# polynomial coefficients fitted on the last iteration
self.last_fit_pixel = None
self.last_fit_meter = None
# list of polynomial coefficients of the last N iterations
self.recent_fits_pixel = collections.deque(maxlen=buffer_len)
self.recent_fits_meter = collections.deque(maxlen=2 * buffer_len)
self.radius_of_curvature = None
# store all pixels coords (x, y) of line detected
self.all_x = None
self.all_y = None
def update_line(self, new_fit_pixel, new_fit_meter, detected, clear_buffer=False):
"""
Update Line with new fitted coefficients.
:param new_fit_pixel: new polynomial coefficients (pixel)
:param new_fit_meter: new polynomial coefficients (meter)
:param detected: if the Line was detected or inferred
:param clear_buffer: if True, reset state
:return: None
"""
self.detected = detected
if clear_buffer:
self.recent_fits_pixel = []
self.recent_fits_meter = []
self.last_fit_pixel = new_fit_pixel
self.last_fit_meter = new_fit_meter
self.recent_fits_pixel.append(self.last_fit_pixel)
self.recent_fits_meter.append(self.last_fit_meter)
def draw(self, mask, color=(255, 0, 0), line_width=50, average=False):
"""
Draw the line on a color mask image.
"""
h, w, c = mask.shape
plot_y = np.linspace(0, h - 1, h)
coeffs = self.average_fit if average else self.last_fit_pixel
line_center = coeffs[0] * plot_y ** 2 + coeffs[1] * plot_y + coeffs[2]
line_left_side = line_center - line_width // 2
line_right_side = line_center + line_width // 2
# Some magic here to recast the x and y points into usable format for cv2.fillPoly()
pts_left = np.array(list(zip(line_left_side, plot_y)))
pts_right = np.array(np.flipud(list(zip(line_right_side, plot_y))))
pts = np.vstack([pts_left, pts_right])
# Draw the lane onto the warped blank image
return cv2.fillPoly(mask, [np.int32(pts)], color)
@property
# average of polynomial coefficients of the last N iterations
def average_fit(self):
return np.mean(self.recent_fits_pixel, axis=0)
@property
# radius of curvature of the line (averaged)
def curvature(self):
y_eval = 0
coeffs = self.average_fit
return ((1 + (2 * coeffs[0] * y_eval + coeffs[1]) ** 2) ** 1.5) / np.absolute(2 * coeffs[0])
@property
# radius of curvature of the line (averaged)
def curvature_meter(self):
y_eval = 0
coeffs = np.mean(self.recent_fits_meter, axis=0)
return ((1 + (2 * coeffs[0] * y_eval + coeffs[1]) ** 2) ** 1.5) / np.absolute(2 * coeffs[0])
def get_fits_by_sliding_windows(birdeye_binary, line_lt, line_rt, n_windows=9, verbose=False):
"""
Get polynomial coefficients for lane-lines detected in an binary image.
:param birdeye_binary: input bird's eye view binary image
:param line_lt: left lane-line previously detected
:param line_rt: left lane-line previously detected
:param n_windows: number of sliding windows used to search for the lines
:param verbose: if True, display intermediate output
:return: updated lane lines and output image
"""
height, width = birdeye_binary.shape
# Assuming you have created a warped binary image called "binary_warped"
# Take a histogram of the bottom half of the image
histogram = np.sum(birdeye_binary[height//2:-30, :], axis=0)
# Create an output image to draw on and visualize the result
out_img = np.dstack((birdeye_binary, birdeye_binary, birdeye_binary)) * 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
midpoint = len(histogram) // 2
leftx_base = np.argmax(histogram[:midpoint])
rightx_base = np.argmax(histogram[midpoint:]) + midpoint
# Set height of windows
window_height = np.int(height / n_windows)
# Identify the x and y positions of all nonzero pixels in the image
nonzero = birdeye_binary.nonzero()
nonzero_y = np.array(nonzero[0])
nonzero_x = np.array(nonzero[1])
# Current positions to be updated for each window
leftx_current = leftx_base
rightx_current = rightx_base
margin = 100 # width of the windows +/- margin
minpix = 50 # minimum number of pixels found to recenter window
# 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(n_windows):
# Identify window boundaries in x and y (and right and left)
win_y_low = height - (window + 1) * window_height
win_y_high = height - 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
# Draw the windows on the visualization image
cv2.rectangle(out_img, (win_xleft_low, win_y_low), (win_xleft_high, win_y_high), (0, 255, 0), 2)
cv2.rectangle(out_img, (win_xright_low, win_y_low), (win_xright_high, win_y_high), (0, 255, 0), 2)
# Identify the nonzero pixels in x and y within the window
good_left_inds = ((nonzero_y >= win_y_low) & (nonzero_y < win_y_high) & (nonzero_x >= win_xleft_low)
& (nonzero_x < win_xleft_high)).nonzero()[0]
good_right_inds = ((nonzero_y >= win_y_low) & (nonzero_y < win_y_high) & (nonzero_x >= win_xright_low)
& (nonzero_x < 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(nonzero_x[good_left_inds]))
if len(good_right_inds) > minpix:
rightx_current = np.int(np.mean(nonzero_x[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
line_lt.all_x, line_lt.all_y = nonzero_x[left_lane_inds], nonzero_y[left_lane_inds]
line_rt.all_x, line_rt.all_y = nonzero_x[right_lane_inds], nonzero_y[right_lane_inds]
detected = True
if not list(line_lt.all_x) or not list(line_lt.all_y):
left_fit_pixel = line_lt.last_fit_pixel
left_fit_meter = line_lt.last_fit_meter
detected = False
else:
left_fit_pixel = np.polyfit(line_lt.all_y, line_lt.all_x, 2)
left_fit_meter = np.polyfit(line_lt.all_y * ym_per_pix, line_lt.all_x * xm_per_pix, 2)
if not list(line_rt.all_x) or not list(line_rt.all_y):
right_fit_pixel = line_rt.last_fit_pixel
right_fit_meter = line_rt.last_fit_meter
detected = False
else:
right_fit_pixel = np.polyfit(line_rt.all_y, line_rt.all_x, 2)
right_fit_meter = np.polyfit(line_rt.all_y * ym_per_pix, line_rt.all_x * xm_per_pix, 2)
line_lt.update_line(left_fit_pixel, left_fit_meter, detected=detected)
line_rt.update_line(right_fit_pixel, right_fit_meter, detected=detected)
# Generate x and y values for plotting
ploty = np.linspace(0, height - 1, height)
left_fitx = left_fit_pixel[0] * ploty ** 2 + left_fit_pixel[1] * ploty + left_fit_pixel[2]
right_fitx = right_fit_pixel[0] * ploty ** 2 + right_fit_pixel[1] * ploty + right_fit_pixel[2]
out_img[nonzero_y[left_lane_inds], nonzero_x[left_lane_inds]] = [255, 0, 0]
out_img[nonzero_y[right_lane_inds], nonzero_x[right_lane_inds]] = [0, 0, 255]
if verbose:
f, ax = plt.subplots(1, 2)
f.set_facecolor('white')
ax[0].imshow(birdeye_binary, cmap='gray')
ax[1].imshow(out_img)
ax[1].plot(left_fitx, ploty, color='yellow')
ax[1].plot(right_fitx, ploty, color='yellow')
ax[1].set_xlim(0, 1280)
ax[1].set_ylim(720, 0)
plt.show()
return line_lt, line_rt, out_img
def get_fits_by_previous_fits(birdeye_binary, line_lt, line_rt, verbose=False):
"""
Get polynomial coefficients for lane-lines detected in an binary image.
This function starts from previously detected lane-lines to speed-up the search of lane-lines in the current frame.
:param birdeye_binary: input bird's eye view binary image
:param line_lt: left lane-line previously detected
:param line_rt: left lane-line previously detected
:param verbose: if True, display intermediate output
:return: updated lane lines and output image
"""
height, width = birdeye_binary.shape
left_fit_pixel = line_lt.last_fit_pixel
right_fit_pixel = line_rt.last_fit_pixel
nonzero = birdeye_binary.nonzero()
nonzero_y = np.array(nonzero[0])
nonzero_x = np.array(nonzero[1])
margin = 100
left_lane_inds = (
(nonzero_x > (left_fit_pixel[0] * (nonzero_y ** 2) + left_fit_pixel[1] * nonzero_y + left_fit_pixel[2] - margin)) & (
nonzero_x < (left_fit_pixel[0] * (nonzero_y ** 2) + left_fit_pixel[1] * nonzero_y + left_fit_pixel[2] + margin)))
right_lane_inds = (
(nonzero_x > (right_fit_pixel[0] * (nonzero_y ** 2) + right_fit_pixel[1] * nonzero_y + right_fit_pixel[2] - margin)) & (
nonzero_x < (right_fit_pixel[0] * (nonzero_y ** 2) + right_fit_pixel[1] * nonzero_y + right_fit_pixel[2] + margin)))
# Extract left and right line pixel positions
line_lt.all_x, line_lt.all_y = nonzero_x[left_lane_inds], nonzero_y[left_lane_inds]
line_rt.all_x, line_rt.all_y = nonzero_x[right_lane_inds], nonzero_y[right_lane_inds]
detected = True
if not list(line_lt.all_x) or not list(line_lt.all_y):
left_fit_pixel = line_lt.last_fit_pixel
left_fit_meter = line_lt.last_fit_meter
detected = False
else:
left_fit_pixel = np.polyfit(line_lt.all_y, line_lt.all_x, 2)
left_fit_meter = np.polyfit(line_lt.all_y * ym_per_pix, line_lt.all_x * xm_per_pix, 2)
if not list(line_rt.all_x) or not list(line_rt.all_y):
right_fit_pixel = line_rt.last_fit_pixel
right_fit_meter = line_rt.last_fit_meter
detected = False
else:
right_fit_pixel = np.polyfit(line_rt.all_y, line_rt.all_x, 2)
right_fit_meter = np.polyfit(line_rt.all_y * ym_per_pix, line_rt.all_x * xm_per_pix, 2)
line_lt.update_line(left_fit_pixel, left_fit_meter, detected=detected)
line_rt.update_line(right_fit_pixel, right_fit_meter, detected=detected)
# Generate x and y values for plotting
ploty = np.linspace(0, height - 1, height)
left_fitx = left_fit_pixel[0] * ploty ** 2 + left_fit_pixel[1] * ploty + left_fit_pixel[2]
right_fitx = right_fit_pixel[0] * ploty ** 2 + right_fit_pixel[1] * ploty + right_fit_pixel[2]
# Create an image to draw on and an image to show the selection window
img_fit = np.dstack((birdeye_binary, birdeye_binary, birdeye_binary)) * 255
window_img = np.zeros_like(img_fit)
# Color in left and right line pixels
img_fit[nonzero_y[left_lane_inds], nonzero_x[left_lane_inds]] = [255, 0, 0]
img_fit[nonzero_y[right_lane_inds], nonzero_x[right_lane_inds]] = [0, 0, 255]
# Generate a polygon to illustrate the search window area
# And recast the x and y points into usable format for cv2.fillPoly()
left_line_window1 = np.array([np.transpose(np.vstack([left_fitx - margin, ploty]))])
left_line_window2 = np.array([np.flipud(np.transpose(np.vstack([left_fitx + margin, ploty])))])
left_line_pts = np.hstack((left_line_window1, left_line_window2))
right_line_window1 = np.array([np.transpose(np.vstack([right_fitx - margin, ploty]))])
right_line_window2 = np.array([np.flipud(np.transpose(np.vstack([right_fitx + margin, ploty])))])
right_line_pts = np.hstack((right_line_window1, right_line_window2))
# Draw the lane onto the warped blank image
cv2.fillPoly(window_img, np.int_([left_line_pts]), (0, 255, 0))
cv2.fillPoly(window_img, np.int_([right_line_pts]), (0, 255, 0))
result = cv2.addWeighted(img_fit, 1, window_img, 0.3, 0)
if verbose:
plt.imshow(result)
plt.plot(left_fitx, ploty, color='yellow')
plt.plot(right_fitx, ploty, color='yellow')
plt.xlim(0, 1280)
plt.ylim(720, 0)
plt.show()
return line_lt, line_rt, img_fit
def draw_back_onto_the_road(img_undistorted, Minv, line_lt, line_rt, keep_state):
"""
Draw both the drivable lane area and the detected lane-lines onto the original (undistorted) frame.
:param img_undistorted: original undistorted color frame
:param Minv: (inverse) perspective transform matrix used to re-project on original frame
:param line_lt: left lane-line previously detected
:param line_rt: right lane-line previously detected
:param keep_state: if True, line state is maintained
:return: color blend
"""
height, width, _ = img_undistorted.shape
left_fit = line_lt.average_fit if keep_state else line_lt.last_fit_pixel
right_fit = line_rt.average_fit if keep_state else line_rt.last_fit_pixel
# Generate x and y values for plotting
ploty = np.linspace(0, height - 1, height)
left_fitx = left_fit[0] * ploty ** 2 + left_fit[1] * ploty + left_fit[2]
right_fitx = right_fit[0] * ploty ** 2 + right_fit[1] * ploty + right_fit[2]
# draw road as green polygon on original frame
road_warp = np.zeros_like(img_undistorted, dtype=np.uint8)
pts_left = np.array([np.transpose(np.vstack([left_fitx, ploty]))])
pts_right = np.array([np.flipud(np.transpose(np.vstack([right_fitx, ploty])))])
pts = np.hstack((pts_left, pts_right))
cv2.fillPoly(road_warp, np.int_([pts]), (0, 255, 0))
road_dewarped = cv2.warpPerspective(road_warp, Minv, (width, height)) # Warp back to original image space
blend_onto_road = cv2.addWeighted(img_undistorted, 1., road_dewarped, 0.3, 0)
# now separately draw solid lines to highlight them
line_warp = np.zeros_like(img_undistorted)
line_warp = line_lt.draw(line_warp, color=(255, 0, 0), average=keep_state)
line_warp = line_rt.draw(line_warp, color=(0, 0, 255), average=keep_state)
line_dewarped = cv2.warpPerspective(line_warp, Minv, (width, height))
lines_mask = blend_onto_road.copy()
idx = np.any([line_dewarped != 0][0], axis=2)
lines_mask[idx] = line_dewarped[idx]
blend_onto_road = cv2.addWeighted(src1=lines_mask, alpha=0.8, src2=blend_onto_road, beta=0.5, gamma=0.)
return blend_onto_road
if __name__ == '__main__':
line_lt, line_rt = Line(buffer_len=10), Line(buffer_len=10)
ret, mtx, dist, rvecs, tvecs = calibrate_camera(calib_images_dir='camera_cal')
# show result on test images
for test_img in glob.glob('test_images/*.jpg'):
img = cv2.imread(test_img)
img_undistorted = undistort(img, mtx, dist, verbose=False)
img_binary = binarize(img_undistorted, verbose=False)
img_birdeye, M, Minv = birdeye(img_binary, verbose=False)
line_lt, line_rt, img_out = get_fits_by_sliding_windows(img_birdeye, line_lt, line_rt, n_windows=7, verbose=True)