Ejemplo n.º 1
0
def sol(input_obj: Input) -> Output:
    rides = sorted(
        input_obj.rides,
        key=lambda x:
        (x.earliest_start, x.latest_finish, -distance(x.from_cell, x.to_cell)))

    num_vehicles = input_obj.vehicles

    id2vehicles = {k: Vehicle(k) for k in range(num_vehicles)}

    for ride in rides:
        # select vehicles for the current round
        current_vehicles = list(id2vehicles.values())
        compatible_vehicles = list(
            filter(
                lambda x: x.time + distance(x.position, ride.from_cell) <
                input_obj.steps, current_vehicles))
        if not compatible_vehicles:
            continue
        best_vehicle = min(compatible_vehicles,
                           key=lambda x:
                           (distance(x.position, ride.from_cell), x.time))
        id2vehicles[best_vehicle.id].rides.append(ride.id)
        id2vehicles[best_vehicle.id].move(ride.to_cell)

    o = Output({v.id: v.rides for v in id2vehicles.values()})
    return o
Ejemplo n.º 2
0
    def get_move(self, state):
        target_x, target_y, minion_x, minion_y = state
        current_distance = distance(target_x, minion_x, target_y, minion_y)

        moves = []
        moves.append((LEFT, distance(target_x, minion_x - 1, target_y,
                                     minion_y)))
        moves.append(
            (RIGHT, distance(target_x, minion_x + 1, target_y, minion_y)))
        moves.append((UP, distance(target_x, minion_x, target_y,
                                   minion_y - 1)))
        moves.append(
            (DOWN, distance(target_x - 1, minion_x, target_y, minion_y + 1)))

        return min(moves, key=lambda x: x[1])[0]
Ejemplo n.º 3
0
    def reset(self):
        if self.randomize_starts_pos:
            player_start = (
                np.random.randint(10, WIDTH - 10),
                np.random.randint(10, HEIGHT - 10),
            )
            minion_start = player_start
            while (distance(player_start[0], minion_start[0], player_start[1],
                            minion_start[1]) < 25):
                minion_start = (
                    np.random.randint(10, WIDTH - 10),
                    np.random.randint(10, HEIGHT - 10),
                )
        else:
            player_start = (0, 0)
            minion_start = (WIDTH, HEIGHT)

        self.t = 0
        self.player = GameObject(self.player_sprite,
                                 SPEED,
                                 start_pos=player_start,
                                 offset="topleft")
        self.minion = GameObject(
            self.minion_sprite,
            SPEED / 4,
            start_pos=minion_start,
            offset="bottomright",
        )
        return self.get_state()
Ejemplo n.º 4
0
def sol(input_obj: Input) -> Output:
    rides = sorted(input_obj.rides,
                   key=lambda x: (x.earliest_start, x.latest_finish))

    num_vehicles = input_obj.vehicles

    vehicles = [Vehicle(k) for k in range(num_vehicles)]

    for ride in rides:
        # select vehicles for the current round
        best_vehicle = min(vehicles,
                           key=lambda x:
                           (distance(x.position, ride.from_cell), x.time))
        best_vehicle.rides.append(ride.id)
        best_vehicle.move(ride.to_cell)

    o = Output({v.id: v.rides for v in vehicles})
    return o
Ejemplo n.º 5
0
def add_balls_before_SORT(frames, detected, tracked, tracker_min_hits):
    distance_threshold = 100
    first_ball = tracked[0]
    color = first_ball[2]
    balls_to_add = []

    # Get the untracked balls that's close enough to the first tracked ball
    for untracked in detected[-(tracker_min_hits+1):]:
        if(distance(untracked, first_ball) < distance_threshold):
            untracked.append(color)
            balls_to_add.append(untracked)

    # Add the untracked balls to frame
    modify_frames = frames[-(tracker_min_hits+1):]
    balls_to_add_temp = copy.deepcopy(balls_to_add)

    for point in balls_to_add_temp:
        del point[2]
    balls_to_add_temp = np.array(balls_to_add_temp, dtype='int32')

    for idx, frame in enumerate(modify_frames):
        # cv2.polylines(frame.frame, [balls_to_add_temp[:idx+1]], False, color, 22, lineType=cv2.LINE_AA)
        frames[-((tracker_min_hits+1)-idx)] = FrameInfo(frame.frame, True, tuple(balls_to_add_temp[idx]), color)
Ejemplo n.º 6
0
 def move(self, position):
     self.time = distance(position, self.position)
     self.position = position
Ejemplo n.º 7
0
 def distance(self, x, y):
     """Return the distance between the current entity and the given (x, y) coordinate.
     """
     return utils.distance(self.x, self.y, x, y)
Ejemplo n.º 8
0
 def get_distance(self):
     state = self.get_state()
     return distance(state[0], state[2], state[1], state[3])
Ejemplo n.º 9
0
def test_distance__1_sq_east_1():
    assert utils.distance(0, 0, 1, 0) == 1
Ejemplo n.º 10
0
def test_distance__same_point_0():
    assert utils.distance(0, 0, 0, 0) == 0
Ejemplo n.º 11
0
def test_distance__1_sq_diagonal():
    result = utils.distance(0, 0, 1, 1)
    assert round(result, 2) == 1.41
Ejemplo n.º 12
0
def do_unit_tests():
    """
    Cette méthode lance tous les tests unitaires pour vérifier si les algorithmes et les fonctions utiles font bien leur
    boulot
    """

    # On teste la fonction de calcul de distance entre 2 points
    assert distance((0, 0), (0, 0)) == 0
    assert distance((521, 12), (521, 12)) == 0
    assert distance((0, 0), (1, 0)) == 1
    assert distance((-1, -1), (1, -1)) == 2
    assert distance((0, 0), (0, 256)) == 256

    # On teste la fonction de création du plus petit cercle passant par deux point
    assert diameter_circle((0, 0), (0, 0)).center == (0, 0)
    assert diameter_circle((0, 0), (0, 0)).radius == 0

    assert diameter_circle((0, 0), (0, 1)).center == (0, 0.5)
    assert diameter_circle((0, 0), (0, 1)).radius == 0.5

    assert diameter_circle((-5, 0), (5, 0)).center == (0, 0)
    assert diameter_circle((-5, 0), (5, 0)).radius == 5

    # On teste la fonction de creation d'un cercle circonscrit
    assert circumscribed_circle((0, 0), (0, 0), (0, 0)) is None

    assert circumscribed_circle((0, 0), (0, 1), (1, 0)).center == (0.5, 0.5)
    assert circumscribed_circle((0, 0), (0, 1), (1, 0)).radius == distance(
        (0.5, 0.5), (0, 0))

    # On teste la fonction de vérification d'un point dans un cercle
    assert point_in_circle((0, 0), Circle((0, 0), 0))
    assert point_in_circle((1, 1), Circle((0, 0), 2))
    assert not point_in_circle((1, 1), Circle((0, 0), 1))

    # On déclare tous les ensemble de points de test
    point_set1 = {(0, 0), (0, 1)}
    point_set2 = {(0, 0), (0, 2)}
    point_set3 = {(0, -1), (0, 0)}
    point_set4 = {(0, 0), (0, 1), (0, 2)}
    point_set5 = {(0, 0), (4, 0), (0, 4)}
    point_set6 = {(0, 0), (4, 0), (0, 4), (3, 3)}
    point_set7 = {(1, 1)}
    point_set8 = set()

    # On teste l'algorithme naif
    assert naive_circle(point_set1).center == (0, 0.5)
    assert naive_circle(point_set1).radius == 0.5

    assert naive_circle(point_set2).center == (0, 1)
    assert naive_circle(point_set2).radius == 1

    assert naive_circle(point_set3).center == (0, -0.5)
    assert naive_circle(point_set3).radius == 0.5

    assert naive_circle(point_set4).center == (0, 1)
    assert naive_circle(point_set4).radius == 1

    assert naive_circle(point_set5).center == (2, 2)
    assert naive_circle(point_set5).radius == distance((2, 2), (0, 0))

    assert naive_circle(point_set6).center == (2, 2)
    assert naive_circle(point_set6).radius == distance((2, 2), (0, 0))

    # On teste la fonction trivial utilisée pour l'algorithme de Welzl
    assert trivial(point_set1).center == (0, 0.5)
    assert trivial(point_set1).radius == 0.5

    assert trivial(point_set7).center == (1, 1)
    assert trivial(point_set7).radius == 0

    assert trivial(point_set8).center == (0, 0)
    assert trivial(point_set8).radius == 0

    assert trivial(point_set4).center == (0, 1)
    assert trivial(point_set4).radius == 1

    assert trivial(point_set6) is None

    # On affiche que tous les tests sont passés
    print("Tous les tests unitaires sont passés !")
Ejemplo n.º 13
0
    def constant_run(self):
        self.shop_pos[0] = self.start_shop_pos[0] - game_data.camera_offset[0]
        self.shop_pos[1] = self.start_shop_pos[1] - game_data.camera_offset[1]

        player_rect = pygame.Rect(
            game_data.player.pos[0] - game_data.camera_offset[0],
            game_data.player.pos[1] - game_data.camera_offset[1],
            20,
            20,
        )
        self.shop_rect = pygame.Rect(self.shop_pos[0], self.shop_pos[1], 60,
                                     60)

        if player_rect.colliderect(self.shop_rect):
            self.check_collision(player_rect)
            self.player_collide = True

            if self.do_collision:
                if abs(
                        self.shop_rect.right - player_rect.left
                ) < game_data.player.player_speed and game_data.player.change[
                        0] < 0:
                    print('right')
                    player_rect.left = self.shop_rect.right
                    game_data.player.redraw_body = False
                if abs(
                        self.shop_rect.left - player_rect.right
                ) < game_data.player.player_speed and game_data.player.change[
                        0] > 0:
                    print('left')
                    player_rect.right = self.shop_rect.left
                    game_data.player.redraw_body = False
                if abs(
                        self.shop_rect.top - player_rect.bottom
                ) < game_data.player.player_speed and game_data.player.change[
                        1] > 0:
                    print('top')
                    player_rect.bottom = self.shop_rect.top
                    game_data.player.redraw_body = False
                if abs(
                        self.shop_rect.bottom - player_rect.top
                ) < game_data.player.player_speed and game_data.player.change[
                        1] < 0:
                    print('bottom')
                    player_rect.top = self.shop_rect.bottom
                    game_data.player.redraw_body = False

                player_rect.x -= game_data.player.change[0]
                player_rect.y -= game_data.player.change[1]

                game_data.player.pos = [
                    player_rect.x + game_data.camera_offset[0],
                    player_rect.y + game_data.camera_offset[1]
                ]
        elif (self.do_collision and utils.distance(
                self.shop_rect.centerx, player_rect.centerx,
                self.shop_rect.centery, player_rect.centery) <= 100):
            self.player_collide = True
        else:
            self.player_collide = False
            game_data.player.redraw_body = True
            self.text_message.reset_current_text()