def __init__(self, car, angle, x, y):
# sensor itself
self.direction_relative_to_car = angle
self.position_relative_to_car = Point(x, y)
self.direction = 0
self.position = Point(0, 0)
self.sensor_line_id = None
# connection to car
self.car = car
self.car.sensors.append(self)
def __init__(self, track, brain, color="red"):
self.canvas = track.canvas
self.canvas_shape_id = None
self.track = track
self.position = Point(*track.startpoint)
self.direction = track.startdirection
self.steeringwheel = 0 # -90 ... left, 0 ... forward, 90 ... right
self.acceleration = 0 # -10 ... slow down, 0 ... keep, 10 ... speed up
self.speed = 0
self.brain = brain
self.color = color
self.isalive = True
self.sensors = []
self.brain.initialize(self)
def update(self):
'''Update the car status (brain, sensors, position, speed, direction, ...).'''
if self.isalive:
self.brain.update()
# update speed and direction
self.speed = self.speed + self.acceleration
self.direction = (self.direction + self.steeringwheel) % 360
# update position
relativeposition = Point(0, self.speed).rotate(self.direction)
self.position = self.position.move(relativeposition.x, -relativeposition.y)
# update sensor
for s in self.sensors:
s.update()
# check position
if any([not self.track.intrack(*p) for p in self.points()]):
#print("!!!!!!!!!!!!!OUT OF TRACK!!!!!!!!!!!!!")
self.isalive = False
self.canvas.itemconfig(self.canvas_shape_id, fill="black")
elif self.track.ingoal(*self.position):
#print("!!!!!!!!!!!!! WON !!!!!!!!!!!!!")
self.isalive = False
self.canvas.itemconfig(self.canvas_shape_id, fill="blue")
self.acceleration = 0
self.steeringwheel = 0
def __init__(self, track, brain, level, color="red"):
self.canvas = track.canvas
self.canvas_shape_id = None
self.track = track
self.position = Point(*track.startpoint)
self.direction = track.startdirection
self.steeringwheel = 0 # -90 ... left, 0 ... forward, 90 ... right
self.acceleration = 0 # -10 ... slow down, 0 ... keep, 10 ... speed up
self.speed = 0
self.brain = brain
self.color = color
self.isalive = True
self.sensors = []
self.brain.initialize(self)
self.totalReward = 0.0
self.reward = 0.0
self.level = level
self.middlePoints = [
# level 1
[(100, 535), (100, 100), (700, 100), (700, 500), (200, 500)],
# level 2
[(72, 503), (82, 98), (662, 86), (653, 237), (368, 233),
(358, 336), (643, 343), (636, 464), (203, 488), (205, 191)],
# level 3
[(461, 127), (286, 301), (461, 408), (723, 143), (424, 18),
(84, 295), (486, 562)],
# level 4
[(24, 372), (129, 252), (220, 165), (272, 148), (321, 148),
(386, 195), (429, 270), (446, 337), (481, 391), (532, 405),
(604, 377), (646, 337), (679, 279), (747, 215)],
# Level 5
[(166, 447), (136, 387), (136, 330), (148, 266), (180, 226),
(223, 196), (285, 171), (352, 141), (436, 136), (510, 144),
(561, 178), (602, 222), (623, 278), (626, 325), (620, 377),
(586, 415), (526, 451), (446, 467), (360, 477)],
# Level 6
[(152, 448), (144, 295), (166, 177), (236, 125), (342, 97),
(505, 89), (629, 97), (704, 193), (700, 337), (692, 420),
(629, 500), (548, 549), (415, 550), (296, 551), (253, 485),
(252, 414), (268, 338), (296, 250), (370, 217), (428, 202),
(520, 202), (577, 220), (605, 269), (587, 341), (548, 398),
(486, 421), (384, 405)]
]
self.nextMiddlePoint = self.middlePoints[self.level - 1][0]
self.nextMiddlePointIndex = 0
def intersections(self, polynom, frompoint, topoint):
'''Return intersections of the line (frompoint,topoint) with the polynom.'''
points_of_shape = [Point(x,y) for x,y in [polynom[-1]] + polynom]
points = []
for i in range(0,len(points_of_shape)-1):
s = Line(frompoint, topoint).intersection(Line(points_of_shape[i], points_of_shape[i+1]))
if s is not None:
points.append(s)
return points
def update(self):
self.reward = 0
'''Update the car status (brain, sensors, position, speed, direction, ...).'''
if self.isalive:
self.brain.update()
self.totalReward = self.totalReward - 0.1
self.reward -= 0.1
self.speed = self.speed + self.acceleration
self.direction = (self.direction + self.steeringwheel) % 360
relativeposition = Point(0, self.speed).rotate(self.direction)
self.position = self.position.move(relativeposition.x,
-relativeposition.y)
for s in self.sensors:
s.update()
self.distanceToCheckpoint = sqrt(
(self.position.x - self.nextMiddlePoint[0]) *
(self.position.x - self.nextMiddlePoint[0]) +
(self.position.y - self.nextMiddlePoint[1]) *
(self.position.y - self.nextMiddlePoint[1]))
if self.distanceToCheckpoint < 100 and self.nextMiddlePointIndex < len(
self.middlePoints[self.level - 1]):
self.nextMiddlePoint = self.middlePoints[self.level - 1][
self.nextMiddlePointIndex]
self.nextMiddlePointIndex = self.nextMiddlePointIndex + 1
self.totalReward = self.totalReward + 1
self.reward = self.reward + 1
# check position
if any([not self.track.intrack(*p) for p in self.points()]):
#print("!!!!!!!!!!!!!OUT OF TRACK!!!!!!!!!!!!!")
self.totalReward = self.totalReward - 10
self.reward = self.reward - 10
self.isalive = False
self.canvas.itemconfig(self.canvas_shape_id, fill="black")
elif self.track.ingoal(*self.position):
#print("!!!!!!!!!!!!! WON !!!!!!!!!!!!!")
self.totalReward = self.totalReward + 10
self.reward = self.reward + 10
self.isalive = False
self.canvas.itemconfig(self.canvas_shape_id, fill="blue")
self.acceleration = 0
self.steeringwheel = 0
def measure(self):
'''Measure distance to goal.'''
x = self.car.position.x
y = self.car.position.y
min_distance = 9999
min_distance_point_on_midline = None
min_distance_line_index = None
midline_lines = [
Line(Point(*self.car.track.midline_points[i]),
Point(*self.car.track.midline_points[i + 1]))
for i in range(0,
len(self.car.track.midline_points) - 1)
]
for i in range(0, len(midline_lines)):
l = Line(
Point(x, y),
Point(x, y).move(*Vector.from_points(
*midline_lines[i]).normal_vector()))
s = midline_lines[i].intersection(l, treat_as_line_segments=False)
if s is not None and midline_lines[i].inline(s):
d = Vector.from_points(Point(x, y), s).length()
if min_distance > d:
min_distance = d
min_distance_point_on_midline = s
min_distance_line_index = i
# if outside of line use distance to endpoints
ad = Vector.from_points(midline_lines[i].a, Point(x, y)).length()
bd = Vector.from_points(midline_lines[i].b, Point(x, y)).length()
if min_distance > ad:
min_distance = ad
min_distance_point_on_midline = midline_lines[i].a
min_distance_line_index = i
if min_distance > bd:
min_distance = bd
min_distance_point_on_midline = midline_lines[i].b
min_distance_line_index = i
# sum up distances
distance = Vector.from_points(
min_distance_point_on_midline,
midline_lines[min_distance_line_index].b).length()
for i in range(min_distance_line_index + 1, len(midline_lines)):
distance = distance + midline_lines[i].length()
return distance - 25 # remove length of goal area
def update(self):
'''Update the position of the sensor and its measurements.'''
# update direction
self.direction = self.car.direction + self.direction_relative_to_car
# update position
relativesensor = self.position_relative_to_car.rotate(
self.car.direction)
self.position = self.car.position.move(relativesensor.x,
-relativesensor.y)
# update distance & obstacle
relativeray = Point(0, 1000).rotate(self.direction)
ray = self.position.move(relativeray.x, -relativeray.y)
nearest_point_meassured = self.measure(self.car.track.shapes(),
self.position, ray)
if nearest_point_meassured is None:
self.distance = 1000
self.obstacle = None
else:
self.obstacle, self.distance = nearest_point_meassured
self.is_obstacle_goal = self.car.track.ingoal(*self.obstacle)
def points(self):
'''Points of the car shape.'''
return [(self.position.x + x, self.position.y - y) for x, y in
[Point(x, y).rotate(self.direction) for x, y in self._shape]]
class Car:
'''A car.'''
_shape = [(-10, -15), (-10, 15), (10, 15), (10, -15)]
def __lt__(self, other):
return self.totalReward > other.reward
def __init__(self, track, brain, level, color="red"):
self.canvas = track.canvas
self.canvas_shape_id = None
self.track = track
self.position = Point(*track.startpoint)
self.direction = track.startdirection
self.steeringwheel = 0 # -90 ... left, 0 ... forward, 90 ... right
self.acceleration = 0 # -10 ... slow down, 0 ... keep, 10 ... speed up
self.speed = 0
self.brain = brain
self.color = color
self.isalive = True
self.sensors = []
self.brain.initialize(self)
self.totalReward = 0.0
self.reward = 0.0
self.level = level
self.middlePoints = [
# level 1
[(100, 535), (100, 100), (700, 100), (700, 500), (200, 500)],
# level 2
[(72, 503), (82, 98), (662, 86), (653, 237), (368, 233),
(358, 336), (643, 343), (636, 464), (203, 488), (205, 191)],
# level 3
[(461, 127), (286, 301), (461, 408), (723, 143), (424, 18),
(84, 295), (486, 562)],
# level 4
[(24, 372), (129, 252), (220, 165), (272, 148), (321, 148),
(386, 195), (429, 270), (446, 337), (481, 391), (532, 405),
(604, 377), (646, 337), (679, 279), (747, 215)],
# Level 5
[(166, 447), (136, 387), (136, 330), (148, 266), (180, 226),
(223, 196), (285, 171), (352, 141), (436, 136), (510, 144),
(561, 178), (602, 222), (623, 278), (626, 325), (620, 377),
(586, 415), (526, 451), (446, 467), (360, 477)],
# Level 6
[(152, 448), (144, 295), (166, 177), (236, 125), (342, 97),
(505, 89), (629, 97), (704, 193), (700, 337), (692, 420),
(629, 500), (548, 549), (415, 550), (296, 551), (253, 485),
(252, 414), (268, 338), (296, 250), (370, 217), (428, 202),
(520, 202), (577, 220), (605, 269), (587, 341), (548, 398),
(486, 421), (384, 405)]
]
self.nextMiddlePoint = self.middlePoints[self.level - 1][0]
self.nextMiddlePointIndex = 0
def points(self):
'''Points of the car shape.'''
return [(self.position.x + x, self.position.y - y) for x, y in
[Point(x, y).rotate(self.direction) for x, y in self._shape]]
def accelerate(self, units):
'''Accelerate the car about units.'''
self.acceleration = max(-10, min(10, units))
def turn(self, units):
'''Turn the car about units to the left (negative) or right (positive).'''
self.steeringwheel = max(-90, min(90, units))
def update(self):
self.reward = 0
'''Update the car status (brain, sensors, position, speed, direction, ...).'''
if self.isalive:
self.brain.update()
self.totalReward = self.totalReward - 0.1
self.reward -= 0.1
self.speed = self.speed + self.acceleration
self.direction = (self.direction + self.steeringwheel) % 360
relativeposition = Point(0, self.speed).rotate(self.direction)
self.position = self.position.move(relativeposition.x,
-relativeposition.y)
for s in self.sensors:
s.update()
self.distanceToCheckpoint = sqrt(
(self.position.x - self.nextMiddlePoint[0]) *
(self.position.x - self.nextMiddlePoint[0]) +
(self.position.y - self.nextMiddlePoint[1]) *
(self.position.y - self.nextMiddlePoint[1]))
if self.distanceToCheckpoint < 100 and self.nextMiddlePointIndex < len(
self.middlePoints[self.level - 1]):
self.nextMiddlePoint = self.middlePoints[self.level - 1][
self.nextMiddlePointIndex]
self.nextMiddlePointIndex = self.nextMiddlePointIndex + 1
self.totalReward = self.totalReward + 1
self.reward = self.reward + 1
# check position
if any([not self.track.intrack(*p) for p in self.points()]):
#print("!!!!!!!!!!!!!OUT OF TRACK!!!!!!!!!!!!!")
self.totalReward = self.totalReward - 10
self.reward = self.reward - 10
self.isalive = False
self.canvas.itemconfig(self.canvas_shape_id, fill="black")
elif self.track.ingoal(*self.position):
#print("!!!!!!!!!!!!! WON !!!!!!!!!!!!!")
self.totalReward = self.totalReward + 10
self.reward = self.reward + 10
self.isalive = False
self.canvas.itemconfig(self.canvas_shape_id, fill="blue")
self.acceleration = 0
self.steeringwheel = 0
def draw(self):
'''Draw the car on the canvas.'''
if self.canvas_shape_id is None:
self.canvas_shape_id = self.canvas.create_polygon(*self.points(),
fill=self.color)
else:
self.canvas.coords(
self.canvas_shape_id,
*[item for sublist in self.points() for item in sublist])
for s in self.sensors:
s.draw()
def removeFromCanvas(self):
self.canvas.delete(self.canvas_shape_id)
for sensor in self.sensors:
sensor.removeFromCanvas()
class Track:
'''Represents the track.'''
def __init__(self, canvas : tkinter.Canvas, draw_midline: bool, midline_points: list((int,int))):
self.canvas = canvas
self.draw_midline = draw_midline
self.midline_points = midline_points
self.track_width = 35
self.points = []
self.lines = []
self.startpoint = None
self.startdirection = None
self.endpoint = None
self.endarea_points = None
self.track_canvas_id = None
self.goal_canvas_id = None
self.midline_canvas_ids = None
self.calculate_points(self.midline_points)
@classmethod
def level(cls, canvas : tkinter.Canvas, draw_midline: bool, level_number : int):
'''Return the track of the specified level.'''
levels = [
# level 1
[(100,535), (100,100),(700,100), (700,500), (200, 500)],
# level 2
[(72,503), (82,98), (662,86), (653,237), (368,233), (358,336), (643,343), (636,464), (203,488), (205,191)],
# level 3
[(461,127), (286,301), (461,408), (723,143), (424,18), (84,295), (486,562)],
# level 4
[(24,372), (129,252), (220,165), (272,148), (321,148), (386,195), (429,270), (446,337), (481,391), (532,405), (604,377), (646,337), (679,279), (747,215)],
# Level 5
[(166,447), (136,387), (136,330), (148,266), (180,226), (223,196), (285,171), (352,141), (436,136), (510,144), (561,178), (602,222), (623,278), (626,325), (620,377), (586,415), (526,451), (446,467), (360,477)],
# Level 6
[(152,448), (144,295), (166,177), (236,125), (342,97), (505,89), (629,97), (704,193), (700,337), (692,420), (629,500), (548,549), (415,550), (296,551), (253,485), (252,414), (268,338), (296,250), (370,217), (428,202), (520,202), (577,220), (605,269), (587,341), (548,398), (486,421), (384,405)]
]
return Track(canvas, draw_midline, levels[level_number-1])
def calculate_points(self,midline_points):
'''Calculate the track shape, goal and start point based on the provided midline points.'''
inner_lines = []
outer_lines = []
# create inner/outer lines
for i in range(0, len(midline_points)-1):
a = Point(*midline_points[i])
b = Point(*midline_points[i+1])
v = Vector.from_points(a, b)
left_vector = v.normal_vector(direction='left').normalize().multiply(self.track_width)
right_vector = v.normal_vector(direction='right').normalize().multiply(self.track_width)
outer_line = Line(a.move(left_vector.x, left_vector.y), b.move(left_vector.x, left_vector.y))
inner_line = Line(a.move(right_vector.x, right_vector.y), b.move(right_vector.x, right_vector.y))
inner_lines.append(inner_line)
outer_lines.append(outer_line)
self.lines = outer_lines + [Line(inner_lines[-1].b, outer_lines[-1].b)] + list(reversed(inner_lines)) + [Line(inner_lines[0].a, outer_lines[0].a)]
# intersect lines
lines_points = []
for i in range(0, len(self.lines) - 1):
l1 = self.lines[i]
l2 = self.lines[i+1]
s = l1.intersection(l2, treat_as_line_segments=False)
lines_points.append(s)
# points of track
self.points = [self.lines[0].a] + lines_points + [self.lines[-1].b]
# start point (25 from start)
self.startpoint = Point(*Vector.from_points(Point(*midline_points[0]), Point(*midline_points[1])).normalize().multiply(25)).move(*midline_points[0])
# start direction
startvector = Vector.from_points(Point(*midline_points[0]), Point(*midline_points[1])).normalize()
self.startdirection = startvector.angle(Vector(0,1))
self.startdirection = -(180-self.startdirection) if startvector.x <= 0 else 180 - self.startdirection
# end polynom
end_vector = Vector.from_points(Point(*midline_points[-1]), Point(*midline_points[-2])).normalize()
end_vector_left = end_vector.normal_vector(direction='left').multiply(self.track_width*0.80)
end_vector_right = end_vector.normal_vector(direction='right').multiply(self.track_width*0.80)
self.endpoint = Point(*end_vector.multiply(25)).move(*midline_points[-1])
self.endarea_points = [
Point(*midline_points[-1]).move(*end_vector_left).astuple(),
self.endpoint.move(*end_vector_left).astuple(),
self.endpoint.move(*end_vector_right).astuple(),
Point(*midline_points[-1]).move(*end_vector_right).astuple()
]
def shapes(self):
'''Return the shapes that are used for the track.'''
return [self.points, self.endarea_points]
def intrack(self, x, y):
'''Return True if point (x,y) is within track.'''
return self.track_canvas_id in self.canvas.find_overlapping(x,y,x,y)
def ingoal(self, x, y):
'''Return True if point (x,y) is within goal.'''
return self.goal_canvas_id in self.canvas.find_overlapping(x,y,x,y)
def intersections(self, polynom, frompoint, topoint):
'''Return intersections of the line (frompoint,topoint) with the polynom.'''
points_of_shape = [Point(x,y) for x,y in [polynom[-1]] + polynom]
points = []
for i in range(0,len(points_of_shape)-1):
s = Line(frompoint, topoint).intersection(Line(points_of_shape[i], points_of_shape[i+1]))
if s is not None:
points.append(s)
return points
def draw(self):
'''Draw the track.'''
if self.track_canvas_id is None:
self.track_canvas_id = self.canvas.create_polygon(*[p.astuple() for p in self.points], fill="cornsilk2")
if self.midline_canvas_ids is None and self.draw_midline:
self.midline_canvas_ids = []
for i in range(0, len(self.midline_points)-1):
self.midline_canvas_ids.append(self.canvas.create_line(*self.midline_points[i], *self.midline_points[i+1], fill="cornsilk4", dash=(6,6), width=1))
if self.goal_canvas_id is None:
self.goal_canvas_id = self.canvas.create_polygon(*self.endarea_points, fill="gray50")
def calculate_points(self,midline_points):
'''Calculate the track shape, goal and start point based on the provided midline points.'''
inner_lines = []
outer_lines = []
# create inner/outer lines
for i in range(0, len(midline_points)-1):
a = Point(*midline_points[i])
b = Point(*midline_points[i+1])
v = Vector.from_points(a, b)
left_vector = v.normal_vector(direction='left').normalize().multiply(self.track_width)
right_vector = v.normal_vector(direction='right').normalize().multiply(self.track_width)
outer_line = Line(a.move(left_vector.x, left_vector.y), b.move(left_vector.x, left_vector.y))
inner_line = Line(a.move(right_vector.x, right_vector.y), b.move(right_vector.x, right_vector.y))
inner_lines.append(inner_line)
outer_lines.append(outer_line)
self.lines = outer_lines + [Line(inner_lines[-1].b, outer_lines[-1].b)] + list(reversed(inner_lines)) + [Line(inner_lines[0].a, outer_lines[0].a)]
# intersect lines
lines_points = []
for i in range(0, len(self.lines) - 1):
l1 = self.lines[i]
l2 = self.lines[i+1]
s = l1.intersection(l2, treat_as_line_segments=False)
lines_points.append(s)
# points of track
self.points = [self.lines[0].a] + lines_points + [self.lines[-1].b]
# start point (25 from start)
self.startpoint = Point(*Vector.from_points(Point(*midline_points[0]), Point(*midline_points[1])).normalize().multiply(25)).move(*midline_points[0])
# start direction
startvector = Vector.from_points(Point(*midline_points[0]), Point(*midline_points[1])).normalize()
self.startdirection = startvector.angle(Vector(0,1))
self.startdirection = -(180-self.startdirection) if startvector.x <= 0 else 180 - self.startdirection
# end polynom
end_vector = Vector.from_points(Point(*midline_points[-1]), Point(*midline_points[-2])).normalize()
end_vector_left = end_vector.normal_vector(direction='left').multiply(self.track_width*0.80)
end_vector_right = end_vector.normal_vector(direction='right').multiply(self.track_width*0.80)
self.endpoint = Point(*end_vector.multiply(25)).move(*midline_points[-1])
self.endarea_points = [
Point(*midline_points[-1]).move(*end_vector_left).astuple(),
self.endpoint.move(*end_vector_left).astuple(),
self.endpoint.move(*end_vector_right).astuple(),
Point(*midline_points[-1]).move(*end_vector_right).astuple()
]
class Sensor:
'''Sensor that measures the distance to the edge of roadway.'''
# measured values
distance = 1000
obstacle = None
is_obstacle_goal = False
def __init__(self, car, angle, x, y):
# sensor itself
self.direction_relative_to_car = angle
self.position_relative_to_car = Point(x, y)
self.direction = 0
self.position = Point(0, 0)
self.sensor_line_id = None
# connection to car
self.car = car
self.car.sensors.append(self)
def update(self):
'''Update the position of the sensor and its measurements.'''
# update direction
self.direction = self.car.direction + self.direction_relative_to_car
# update position
relativesensor = self.position_relative_to_car.rotate(
self.car.direction)
self.position = self.car.position.move(relativesensor.x,
-relativesensor.y)
# update distance & obstacle
relativeray = Point(0, 1000).rotate(self.direction)
ray = self.position.move(relativeray.x, -relativeray.y)
nearest_point_meassured = self.measure(self.car.track.shapes(),
self.position, ray)
if nearest_point_meassured is None:
self.distance = 1000
self.obstacle = None
else:
self.obstacle, self.distance = nearest_point_meassured
self.is_obstacle_goal = self.car.track.ingoal(*self.obstacle)
def draw(self):
'''Draw the sensor.'''
if self.sensor_line_id is None:
if self.obstacle is not None:
self.sensor_line_id = self.car.canvas.create_line(
*self.position, *self.obstacle, fill="orange", dash=(1, 1))
elif self.obstacle is not None:
self.car.canvas.coords(self.sensor_line_id, *self.position,
*self.obstacle)
self.car.canvas.itemconfig(
self.sensor_line_id,
fill="blue" if self.is_obstacle_goal else "orange")
def measure(self, shapes, frompoint, topoint):
'''Measure the distance from point frompoint to the first intersection of line (frompoint,topoint) with shapes.'''
nearest_point = (None, None)
for shape in shapes:
points = self.car.track.intersections(shape, frompoint, topoint)
points = [(p, frompoint.distance(p)) for p in points
if p is not None]
points.sort(key=lambda p: p[1]) # by distance
if len(points) > 0:
if nearest_point[1] is None or nearest_point[1] > points[0][1]:
nearest_point = points[0]
return nearest_point if nearest_point[1] is not None else None
def __repr__(self):
return f"(sensor position on car: {self.position}, distance: {self.distance})"
class Car:
'''A car.'''
_shape = [(-10,-15),(-10,15), (10,15), (10,-15)]
def __init__(self, track, brain, color="red"):
self.canvas = track.canvas
self.canvas_shape_id = None
self.track = track
self.position = Point(*track.startpoint)
self.direction = track.startdirection
self.steeringwheel = 0 # -90 ... left, 0 ... forward, 90 ... right
self.acceleration = 0 # -10 ... slow down, 0 ... keep, 10 ... speed up
self.speed = 0
self.brain = brain
self.color = color
self.isalive = True
self.sensors = []
self.brain.initialize(self)
self.isInGoal = False
def points(self):
'''Points of the car shape.'''
return [(self.position.x + x, self.position.y - y) for x,y in [Point(x,y).rotate(self.direction) for x,y in self._shape]]
def accelerate(self, units):
'''Accelerate the car about units.'''
self.acceleration = max(-10, min(10, units))
def turn(self, units):
'''Turn the car about units to the left (negative) or right (positive).'''
self.steeringwheel = max(-90, min(90, units))
def update(self):
'''Update the car status (brain, sensors, position, speed, direction, ...).'''
if self.isalive:
self.brain.update()
# update speed and direction
self.speed = self.speed + self.acceleration
self.direction = (self.direction + self.steeringwheel) % 360
# update position
relativeposition = Point(0, self.speed).rotate(self.direction)
self.position = self.position.move(relativeposition.x, -relativeposition.y)
# update sensor
for s in self.sensors:
s.update()
# check position
if any([not self.track.intrack(*p) for p in self.points()]):
#print("!!!!!!!!!!!!!OUT OF TRACK!!!!!!!!!!!!!")
self.isalive = False
self.canvas.itemconfig(self.canvas_shape_id, fill="black")
elif self.track.ingoal(*self.position):
#print("!!!!!!!!!!!!! WON !!!!!!!!!!!!!")
self.isalive = False
self.canvas.itemconfig(self.canvas_shape_id, fill="blue")
self.acceleration = 0
self.steeringwheel = 0
def draw(self):
'''Draw the car on the canvas.'''
if self.canvas_shape_id is None:
self.canvas_shape_id = self.canvas.create_polygon(*self.points(), fill=self.color)
else:
self.canvas.coords(self.canvas_shape_id, *[item for sublist in self.points() for item in sublist])
for s in self.sensors:
s.draw()
