Example #1
0
    def calibrate(self, sense):
        is_calibrated = False
        front_direction = self.robot.direction
        right_direction = (front_direction + 1) % 4
        front_direction_vector = Direction.get_direction_vector(
            front_direction)
        right_direction_vector = Direction.get_direction_vector(
            right_direction)

        # Check front
        can_calibrate_front = False
        for i in range(-1, 2):
            c = self.robot.pos[0] + 2 * front_direction_vector[
                0] + i * right_direction_vector[0]
            r = self.robot.pos[1] + 2 * front_direction_vector[
                1] + i * right_direction_vector[1]

            if c < 0 or c > NUM_COLS - 1 or r < 0 or r > NUM_ROWS - 1 or self.explored_map[
                    r][c] == Cell.OBSTACLE:
                can_calibrate_front = True
                break

        if can_calibrate_front:
            self.on_calibrate(is_front=True)
            is_calibrated = True

        # Check right
        if self.steps_without_calibration >= MIN_STEPS_WITHOUT_CALIBRATION:
            can_calibrate_right = True
            for i in [-1, 1]:
                c = self.robot.pos[0] + i * front_direction_vector[
                    0] + 2 * right_direction_vector[0]
                r = self.robot.pos[1] + i * front_direction_vector[
                    1] + 2 * right_direction_vector[1]

                if 0 <= c < NUM_COLS and 0 <= r < NUM_ROWS and self.explored_map[
                        r][c] != Cell.OBSTACLE:
                    can_calibrate_right = False

            if can_calibrate_right:
                self.on_calibrate(is_front=False)
                self.steps_without_calibration = 0
                is_calibrated = True

        if is_calibrated and sense:
            self.sense_and_repaint()
Example #2
0
    def sense_and_repaint(self, sensor_values=None):
        if sensor_values is None:
            sensor_values = self.robot.sense()

        for i in range(len(sensor_values)):
            sensor_value = sensor_values[i]
            sensor = self.robot.sensors[i]
            direction_vector = Direction.get_direction_vector(
                sensor.get_current_direction(self.robot))
            current_sensor_pos = sensor.get_current_pos(self.robot)

            if sensor_value == -1:
                continue

            elif sensor_value is None:
                for j in range(*sensor.get_range()):
                    pos_to_mark = (current_sensor_pos[0] +
                                   j * direction_vector[0],
                                   current_sensor_pos[1] +
                                   j * direction_vector[1])

                    if 0 <= pos_to_mark[0] <= NUM_COLS - 1 and 0 <= pos_to_mark[
                            1] <= NUM_ROWS - 1:
                        self.explored_map[pos_to_mark[1]][
                            pos_to_mark[0]] = Cell.FREE

            else:
                for j in range(sensor.get_range()[0],
                               min(sensor.get_range()[1], sensor_value + 1)):
                    pos_to_mark = (current_sensor_pos[0] +
                                   j * direction_vector[0],
                                   current_sensor_pos[1] +
                                   j * direction_vector[1])

                    if 0 <= pos_to_mark[0] <= NUM_COLS - 1 and 0 <= pos_to_mark[
                            1] <= NUM_ROWS - 1:
                        if j != sensor_value:
                            self.explored_map[pos_to_mark[1]][
                                pos_to_mark[0]] = Cell.FREE
                        else:
                            self.explored_map[pos_to_mark[1]][
                                pos_to_mark[0]] = Cell.OBSTACLE
                            if pos_to_mark not in self.obstacles:
                                self.obstacles[pos_to_mark] = {0, 1, 2, 3}
                                self.remove_obstacle_side(pos_to_mark)

        for r in range(START_POS[1] - 1, START_POS[1] + 2):
            for c in range(START_POS[0] - 1, START_POS[0] + 2):
                self.explored_map[r][c] = Cell.FREE

        for r in range(GOAL_POS[1] - 1, GOAL_POS[1] + 2):
            for c in range(GOAL_POS[0] - 1, GOAL_POS[0] + 2):
                self.explored_map[r][c] = Cell.FREE

        self.on_update_map()
    def check_if_contains_corners(self, obstacles, direction):
        obstacle_direction = (direction + 2) % 4
        direction_vector = Direction.get_direction_vector(obstacle_direction)
        for obstacle in obstacles:
            pos = (obstacle[0] + 2 * direction_vector[0],
                   obstacle[1] + 2 * direction_vector[1])

            if not self.is_pos_safe(pos, consider_unexplored=False):
                print(pos, obstacle)
                return True

        return False
Example #4
0
    def move(self, movement, sense=False):
        if not isinstance(movement, Movement):
            if self.direction == Direction.NORTH:
                self.pos = (self.pos[0], self.pos[1] + movement)
            elif self.direction == Direction.EAST:
                self.pos = (self.pos[0] + movement, self.pos[1])
            elif self.direction == Direction.SOUTH:
                self.pos = (self.pos[0], self.pos[1] - movement)
            elif self.direction == Direction.WEST:
                self.pos = (self.pos[0] - movement, self.pos[1])

        elif movement == Movement.FORWARD:
            if self.direction == Direction.NORTH:
                self.pos = (self.pos[0], self.pos[1] + 1)
            elif self.direction == Direction.EAST:
                self.pos = (self.pos[0] + 1, self.pos[1])
            elif self.direction == Direction.SOUTH:
                self.pos = (self.pos[0], self.pos[1] - 1)
            elif self.direction == Direction.WEST:
                self.pos = (self.pos[0] - 1, self.pos[1])

        elif movement == Movement.BACKWARD:
            if self.direction == Direction.NORTH:
                self.pos = (self.pos[0], self.pos[1] - 1)
            elif self.direction == Direction.EAST:
                self.pos = (self.pos[0] - 1, self.pos[1])
            elif self.direction == Direction.SOUTH:
                self.pos = (self.pos[0], self.pos[1] + 1)
            elif self.direction == Direction.WEST:
                self.pos = (self.pos[0] + 1, self.pos[1])

        elif movement == Movement.RIGHT:
            self.direction = Direction((self.direction + 1) % 4)

        elif movement == Movement.LEFT:
            self.direction = Direction((self.direction - 1) % 4)

        return self.on_move(movement)
Example #5
0
    def send_movement(self, movement, robot):
        print(movement)
        if movement == Movement.FORWARD:
            movement_str = "1"
        elif isinstance(movement, Movement):
            movement_str = Movement.convert_to_string(movement)
        else:
            movement_str = str(movement)

        # Sample message: M:R 1,2 E
        msg = "{} {},{} {}".format(
            movement_str,
            robot.pos[0],
            robot.pos[1],
            Direction.convert_to_string(robot.direction),
        )
        self.send_msg_with_type(RPi.MOVEMENT_MSG, msg)
        return self.receive_sensor_values(send_msg=False)
Example #6
0
def display(dic):
    symbol_len = Symbol.max_len("Symbol")
    new_state_len = State.max_len("New State")
    new_symbol_len = Symbol.max_len("New Symbol")
    direction_len = Direction.max_len("Direction")
    total = symbol_len + new_state_len + new_symbol_len + direction_len + 11

    for state, value in dic.items():
        print(f"State: {state.name}")
        print("+" + "-" * total + "+")
        pprint("Symbol", symbol_len)
        pprint("New State", new_state_len)
        pprint("New Symbol", new_symbol_len)
        pprint("Direction", direction_len, last=True)
        for symbol, tupl in value.items():
            pprint(symbol.name[4], symbol_len)
            pprint(tupl[0].name, new_state_len)
            pprint(tupl[1].name[4], new_symbol_len)
            pprint(tupl[2].name, direction_len, last=True)

        print("+" + "-" * total + "+")
        print("")
Example #7
0
    def possible_remaining_unexplored(self, goal):
        d = set()

        for direction in range(4):
            for sensor in self.robot.sensors:
                sensor_direction = (direction + sensor.direction -
                                    Direction.EAST) % 4
                reverse_sensor_direction = (sensor_direction + 2) % 4
                direction_vector = Direction.get_direction_vector(
                    reverse_sensor_direction)

                for i in range(*sensor.get_range()):
                    sensor_pos = (goal[0] + i * direction_vector[0],
                                  goal[1] + i * direction_vector[1])

                    if sensor_pos[0] < 0 or sensor_pos[
                            0] >= NUM_COLS or sensor_pos[1] < 0 or sensor_pos[
                                1] >= NUM_ROWS or self.explored_map[sensor_pos[
                                    1]][sensor_pos[0]] == Cell.OBSTACLE:
                        break

                    if direction == Direction.NORTH:
                        pos = sensor_pos[0] + sensor.pos[1], sensor_pos[
                            1] - sensor.pos[0]
                    elif direction == Direction.EAST:
                        pos = sensor_pos[0] - sensor.pos[0], sensor_pos[
                            1] - sensor.pos[1]
                    elif direction == Direction.SOUTH:
                        pos = sensor_pos[0] - sensor.pos[1], sensor_pos[
                            1] + sensor.pos[0]
                    else:  # Direction.WEST
                        pos = sensor_pos[0] + sensor.pos[0], sensor_pos[
                            1] + sensor.pos[1]

                    if self.is_pos_safe(pos):
                        d.add((pos, direction))

        return d
Example #8
0
    def sense(self):
        sensor_values = []

        for sensor in self.sensors:
            direction_vector = Direction.get_direction_vector(
                sensor.get_current_direction(self))
            sensor_pos = sensor.get_current_pos(self)
            sensor_range = sensor.get_range()

            for i in range(1, sensor_range[1]):
                pos_to_check = (sensor_pos[0] + i * direction_vector[0],
                                sensor_pos[1] + i * direction_vector[1])
                if pos_to_check[0] < 0 or pos_to_check[0] >= NUM_COLS or pos_to_check[1] < 0 or pos_to_check[1] >= NUM_ROWS or\
                 self.map[pos_to_check[1]][pos_to_check[0]] == Cell.OBSTACLE:
                    if i < sensor_range[0]:
                        sensor_values.append(-1)
                    else:
                        sensor_values.append(i)
                    break

            else:
                sensor_values.append(None)

        return sensor_values
Example #9
0
def make_tuple(dst):
    state, symbol, direc = dst.split(",")
    return (State.by_rep(state), Symbol.by_rep(symbol),
            Direction.by_rep(direc))
Example #10
0
 def get_current_direction(self, robot):
     return Direction(
         (robot.direction + self.direction - Direction.EAST) % 4)
Example #11
0
 def getCapturedPosition(self, move):
     if (self.isInPossibleCaptures(move)):
         return self.getAdjacentPosition(move[0], Adjacent[Direction(move[1] - move[0]).name])
Example #12
0
 def find_right_pos(self):
     direction_vector = Direction.get_direction_vector(
         (self.robot.direction + 1) % 4)
     current_pos = self.robot.pos
     return current_pos[0] + direction_vector[0], current_pos[
         1] + direction_vector[1]