Exemplo n.º 1
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 def square(cls, size):
     '''Creates square FP. size [int] square side length'''
     obj = cls.__new__(cls)
     obj.size = size
     points = []
     center = Point(0, 0)
     for x in range(-size // 2, (size // 2)):
         for y in range(-size // 2, (size // 2)):
             points += [Point(x + 1, y + 1)]
     obj.points = points
     obj.is_square = True
     return obj
Exemplo n.º 2
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 def __init__(self, sess, coords, ftprint, \
         heal_pts, owner, armor, weapon, speed):
     if speed is None:
         raise ValueError('Unit speed was not specified')
     super().__init__(sess, coords, ftprint, heal_pts, owner, armor, weapon)
     self.speed = speed
     self.dest = self.coords
     self.node = Point(-1, -1)
     self.direction = Point(0, 0)
     self.nodes = []
     self.otype = 'U'
     self.add_cmd('stop', self.session.cmds.stop, (1,0))
     self.add_cmd('move', self.session.cmds.move, (2,0))
Exemplo n.º 3
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    def test_point_and_vector_addition(self):
        p = Point(3, 5)
        v = Vector(0, 1)

        p2 = p + v
        self.assertEqual(3, p2.x)
        self.assertEqual(6, p2.y)
Exemplo n.º 4
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    def export_grid(self, filename):
        print('export_grid')

        print(self.grid.x_range)
        print(self.grid.y_range)

        for cell in self.grid.cells:
            print('cell: %s - color:%s' % (cell, self.grid.cells[cell].color))

        x_min = self.grid.x_range[0] - 2
        x_max = self.grid.x_range[1] + 2
        y_min = self.grid.y_range[0] - 2
        y_max = self.grid.y_range[1] + 2

        with open(filename, "w") as simulation_file:
            simulation_file.write('x range: [%d,%d]\n' % (x_min, x_max))
            simulation_file.write('y range: [%d,%d]\n' % (y_min, y_max))
            simulation_file.write('\n')

            y = y_max
            while y >= y_min:
                simulation_file.write('|')
                x = x_min
                while x <= x_max:
                    cell = self.grid.cells.get(Point(x, y))
                    if cell is None or cell.color == Color.WHITE:
                        simulation_file.write('W|')
                    elif cell.color == Color.BLACK:
                        simulation_file.write('B|')
                    x = x + 1
                y = y - 1
                simulation_file.write('\n')
Exemplo n.º 5
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class Simulator:
    ORIGIN = Point(0, 0)

    def __init__(self):
        self.robot = Robot(Simulator.ORIGIN, WindRose.NORTH_INDEX)
        self.grid = Grid()

    def run(self, steps):
        step = 0
        if steps < 0:
            raise Exception('number of steps must be positive(%d)' % steps)

        while step < steps:
            print('Step %d' % step)

            original_cell = self.robot.position
            cell = self.grid.add_cell(original_cell)

            if cell.color == Color.WHITE:
                self.robot.clockwise_rotate()
            elif cell.color == Color.BLACK:
                self.robot.anti_clockwise_rotate()

            cell.flip()
            self.robot.move()
            step = step + 1

    def export_grid(self, filename):
        print('export_grid')

        print(self.grid.x_range)
        print(self.grid.y_range)

        for cell in self.grid.cells:
            print('cell: %s - color:%s' % (cell, self.grid.cells[cell].color))

        x_min = self.grid.x_range[0] - 2
        x_max = self.grid.x_range[1] + 2
        y_min = self.grid.y_range[0] - 2
        y_max = self.grid.y_range[1] + 2

        with open(filename, "w") as simulation_file:
            simulation_file.write('x range: [%d,%d]\n' % (x_min, x_max))
            simulation_file.write('y range: [%d,%d]\n' % (y_min, y_max))
            simulation_file.write('\n')

            y = y_max
            while y >= y_min:
                simulation_file.write('|')
                x = x_min
                while x <= x_max:
                    cell = self.grid.cells.get(Point(x, y))
                    if cell is None or cell.color == Color.WHITE:
                        simulation_file.write('W|')
                    elif cell.color == Color.BLACK:
                        simulation_file.write('B|')
                    x = x + 1
                y = y - 1
                simulation_file.write('\n')
Exemplo n.º 6
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    def project_to_image(self, image, camera):
        # TODO: project circle to image
        ### your code starts  ###
        w_center = self.center.to_vector()
        x0 = int(w_center[0][0])
        y0 = int(w_center[1][0])
        z0 = int(w_center[2][0])
        p0 = np.array([x0, y0, z0])
        p1 = np.array([x0 + self.radius, y0, z0])
        p2 = np.array([x0, y0 + self.radius,
                       z0])  # Need to trans P1, P2(type:ndarray) to Point
        print('Center Point of the circle:' + str(p0))
        print('One of the perpendicular radius cross circle-rim point is:' +
              str(p1))
        print('Another perpendicular radius cross circle-rim point is:' +
              str(p2))
        P0 = Point(x0, y0, z0)
        P1 = Point(x0 + self.radius, y0, z0)
        P2 = Point(x0, y0 + self.radius, z0)
        r0 = camera.project(P0)
        r1 = camera.project(P1)
        r2 = camera.project(P2)
        R0 = r0.to_vector()
        R00 = np.array([R0[0][0][0], R0[1][0][0], R0[2][0]])
        R1 = r1.to_vector()
        R11 = np.array([R1[0][0][0], R1[1][0][0], R1[2][0]])
        #R1 = np.array([r1.to_vector()[0][0][0], r1.to_vector()[1][0][0]], r1.to_vector()[2][0]])
        R2 = r2.to_vector()
        #R2 = np.array([r2.to_vector()[0][0][0], r2.to_vector()[1][0][0]], r2.to_vector()[2][0]])
        R22 = np.array([R2[0][0][0], R2[1][0][0], R2[2][0]])
        print('Center Point of the projected ellipse:' + str(R00))
        print(
            'One of the perpendicular radius cross ellipse-rim point after projection is:'
            + str(R11))
        print(
            'Another perpendicular radius cross ellipse-rim point after projection is:'
            + str(R22))
        e_center = (int(R00[0]), int(R00[1]))
        d1 = int(np.linalg.norm(R11 - R00))
        d2 = int(np.linalg.norm(R22 - R00))
        image = cv.ellipse(image, e_center, (d1, d2), 0, 0, 360, self.color, 5)

        ### your code ends    ###
        return image
Exemplo n.º 7
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 def update(self, tick):
     super().update(tick)
     points = 0
     while self.coords != self.dest and points < self.speed:
         prev = self.coords.copy()
         self.session.board.release_fp(self)
         self.session.tell_tell_dirty()
         if self._get_direction(self.coords, self.node) != self.direction:
             self.node = self.nodes[0]
             self.nodes = self.nodes[1:]
             self.direction = self._get_direction(self.coords, self.node)
             self.direction_cost = self._get_dir_cost(self.direction)
         points += self.direction_cost
         self.coords = self.coords + self.direction
         self.coords.round(2)
         if not self.session.board.apply_fp(self):
             self.coords = prev
             self.session.board.apply_fp(self)
             self.dest = self.coords.copy()
             self.node = Point(-1, -1)
             self.direction = Point(0, 0)
             self.nodes = []
def load_lane_markings():
    xs = [float(i) for i in range(100)]

    def left_y(x):
        return 1.5 + 0.025 * x + 0.001 * x * x + 0.1 * np.sin(x * 0.1) + random.random() * 0.5

    def right_y(x):
        return -1.5 + 0.01 * x + 0.001 * x * x + 0.1 * np.sin(x * 0.2) + random.random() * 0.5

    left_ys = [left_y(x) for x in xs]
    right_ys = [right_y(x) for x in xs]

    raw_points = [Point(x, y, 0.0) for x, y in zip(xs + xs, left_ys + right_ys)]

    first_left = [Point(x, y, 0.0) for x, y in zip(xs[:60], left_ys[:60])]
    first_right = [Point(x, y, 0.0) for x, y in zip(xs[:60], right_ys[:60])]
    first_left_lane_marking = LaneMarking(first_left)
    first_right_lane_marking = LaneMarking(first_right)

    trans_x = 50.0
    trans_y = 0.5 * (left_y(trans_x) + right_y(trans_x))
    yaw = 1.46
    pose = Transform(Rotation.from_rpy(0.0, 0.0, yaw), Translation(trans_x, trans_y, 0.0))
    pose_inv = np.linalg.inv(pose.homogeneous)
    second_left = []
    second_right = []
    for x, left_y, right_y in zip(xs[40:], left_ys[40:], right_ys[40:]):
        left_p = np.array([x, left_y, 0.0, 1.0])
        left_p = left_p.reshape((4, 1))
        right_p = np.array([x, right_y, 0.0, 1.0])
        right_p = right_p.reshape((4, 1))
        left_p_inv = np.dot(pose_inv, left_p)
        right_p_inv = np.dot(pose_inv, right_p)
        second_left.append(Point(left_p_inv[0, 0], left_p_inv[1, 0] + 0.5 * random.random(), 0.0))
        second_right.append(Point(right_p_inv[0, 0], right_p_inv[1, 0] + 0.5 * random.random(), 0.0))
    second_left_lane_marking = LaneMarking(second_left, pose=pose)
    second_right_lane_marking = LaneMarking(second_right, pose=pose)

    return (first_left_lane_marking, first_right_lane_marking), (second_left_lane_marking, second_right_lane_marking), raw_points
Exemplo n.º 9
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 def sub_occupy(self, obj):
     if not self.crossable: return False
     if self.occupied == 2: return False
     size = obj.footprint.size / 2 # Radius
     for x in range(self.size):
         for y in range(self.size):
             sx, sy = self.coords.get()
             coords = Point(sx+(x/self.size), sy+(y/self.size))
             v = Vector.from_abs(obj.coords, coords)
             if v.magnitude > size:
                 continue
             if self.subcells[y][x] is not None:
                 return False
             self.subcells[y][x] = obj
     self.occupied = 1
     return True
Exemplo n.º 10
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 def load_png(self, filename):
     defines = {k:tuple(v) for k,v in self.CLRS.board_file_defines.items()}
     pillow = Image.open(filename)
     self.size = pillow.size
     width, height = pillow.size
     pixels = pillow.load()
     self.cells = [[None for x in range(width)] for y in range(height)]
     var_count = self.CORE.variant_count
     sub_per_cell = self.CORE.sub_per_cell
     for y in range(height):
         for x in range(width):
             point = Point(x, y)
             try: key = self.find_key(defines, pixels[x, y])
             except KeyError:
                 Log.info('Invalid color {} in map "{}"' + \
                     ' at position {}'.format( pixels[x, y],
                     path.split('/')[-1], (x,y)))
                 raise
             if key == 'start_pos': self.starts += [point]
             elif 'norm' in key or 'rich' in key:
                 self.toplace+=[(point, key)]
             crossable = key != 'not_crsbl'
             cell = Cell(point, crossable, sub_per_cell, var_count)
             self.cells[y][x] = cell
Exemplo n.º 11
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        print(
            'Another perpendicular radius cross ellipse-rim point after projection is:'
            + str(R22))
        e_center = (int(R00[0]), int(R00[1]))
        d1 = int(np.linalg.norm(R11 - R00))
        d2 = int(np.linalg.norm(R22 - R00))
        image = cv.ellipse(image, e_center, (d1, d2), 0, 0, 360, self.color, 5)

        ### your code ends    ###
        return image


if __name__ == "__main__":
    camera = create_test_camera_model()

    line = ColoredLine(Point(-1.0, -0.5, 1.5), Point(-0.5, -1.0, 3.5))

    points = [
        Point(-0.5, 0.0, 2.0),
        Point(-0.5, 0.0, 4.0),
        Point(0.5, 0.5, 4.0),
        Point(0.5, 0.5, 2.0)
    ]
    polygon = ColoredPolygon(points)

    circle = Circle(Point(0.0, 0.0, 0.0), 0.5)

    image = np.ones((768, 1024, 3)) * 255
    image = polygon.project_to_image(image, camera)
    image = line.project_to_image(image, camera)
    image = circle.project_to_image(image, camera)
Exemplo n.º 12
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 def _get_direction(self, orig, dest):
     dx = (1 if orig.x < dest.x else -1) if orig.x != dest.x else 0
     dy = (1 if orig.y < dest.y else -1) if orig.y != dest.y else 0
     sub_per_cell = self.session.request_subpercell()
     return Point(dx/sub_per_cell, dy/sub_per_cell)
Exemplo n.º 13
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 def request_path(self):
     self.nodes = self.session.board.request_path( \
         self.footprint, self.coords, self.dest)
     self.node = Point(-1, -1)
     self.direction = Point(0, 0)
Exemplo n.º 14
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 def _stop_inst(session, actor):
     actor.dest = actor.coords.copy()
     actor.node = Point(-1, -1)
     actor.nodes = []
     actor.direction = Point(0, 0)
Exemplo n.º 15
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 def _move_inst(session, actor, coords):
     actor.dest = Point(*coords)
     actor.request_path()
Exemplo n.º 16
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 def _train_soldier_deld(session, actor, coords):
     obj = o.Soldier(session, Point(*coords), actor.owner)
     session.add_object(obj)
Exemplo n.º 17
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 def request_path(self, fp, orig, dest):
     orig.to_ints()
     dest.to_ints()
     return [Point(*pt) for pt in self.finder.find(fp, orig, dest)]
Exemplo n.º 18
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    def test_two_point_addition(self):
        p1 = Point(3, 5)
        p2 = Point(0, 1)

        with self.assertRaises(TypeError) as context:
            p3 = p1 + p2
Exemplo n.º 19
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def main():
    """Main function.

    After providing a sample subdivision, its trapezoidal map and search structure are built.
    Then, points can be queried to find which faces contain them.
    """

    example = 2  # Number of the example

    # Create a sample subdivision.
    print("\n\n*** INITIALIZATION ***")

    segments = set()

    if example == 1:
        p1 = Point(2, 4)
        q1 = Point(9, 6)
        p2 = Point(6, 3)
        q2 = Point(12, 2)
        s1 = Segment(p1, q1)
        s2 = Segment(p2, q2)
        segments = {s1, s2}
    elif example == 2:
        p1 = Point(10, 8)
        p2 = Point(2, 4)
        p3 = Point(6, 2)
        p4 = Point(20, 4)
        p5 = Point(12, 10)
        p6 = Point(16, 6)
        s1 = Segment(p1, p2)
        s2 = Segment(p2, p3)
        s3 = Segment(p3, p4)
        s4 = Segment(p4, p5)
        s5 = Segment(p2, p6)
        segments = {s1, s2, s3, s4, s5}

    S = Subdivision(segments)

    # Build the trapezoidal map and the search structure.
    print("\n\n*** CONSTRUCTION ***")

    S.trapezoidal_map()

    # Query a sample point.
    print("\n\n*** QUERY ***")

    query_point = Point(4, 2)
    face = S.T.D.query(query_point)

    print("\nPoint " + str(query_point) + " is located here:\n" + str(face))
Exemplo n.º 20
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from src.geometry import Point, Segment, Trapezoid
from src.nodes import XNode, YNode, LeafNode

# ---GEOMETRY----

# Points
p1 = Point(1, 3)
q1 = Point(5, 4)
p2 = Point(3, 2)
q2 = Point(6, 1)
ll = Point(0, 0)
lr = Point(7, 0)
ul = Point(0, 6)
ur = Point(7, 6)

# Segments
s1 = Segment(p1, q1)
s2 = Segment(p2, q2)
ls = Segment(ll, lr)
us = Segment(ul, ur)

# Trapezoids
A = Trapezoid(us, ls, ll, p1)
B = Trapezoid(us, s1, p1, q1)
C = Trapezoid(s1, ls, p1, p2)
D = Trapezoid(s1, s2, p2, q1)
E = Trapezoid(us, s2, q1, q2)
F = Trapezoid(s2, ls, p2, q2)
G = Trapezoid(us, ls, q2, lr)
A.set_neighbors(None, None, B, C)
B.set_neighbors(A, None, E, None)
Exemplo n.º 21
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 def get_point(self, s):
     s_vector = np.array([1.0, s, s * s, s * s * s])
     x = np.dot(s_vector, self.coeff_x)
     y = np.dot(s_vector, self.coeff_y)
     return Point(x, y, 0.0)