Exemplo n.º 1
0
    def parse_move(self, move_list, line):
        m = re.match(self.move_regex, line)
        if m is not None:
            pos = parse_position(self.board_size, m.group(1))
            visits = int(m.group(2))
            winrate = self.flip_winrate(str_to_percent(m.group(3)))
            mc_winrate = self.flip_winrate(str_to_percent(m.group(4)))
            nn_winrate = self.flip_winrate(str_to_percent(m.group(5)))
            nn_count = int(m.group(6))
            policy_prob = str_to_percent(m.group(7))
            pv = [
                parse_position(self.board_size, p) for p in m.group(8).split()
            ]

            info = {
                'pos': pos,
                'visits': visits,
                'winrate': winrate,
                'mc_winrate': mc_winrate,
                'nn_winrate': nn_winrate,
                'nn_count': nn_count,
                'policy_prob': policy_prob,
                'pv': pv,
                'color': self.whose_turn()
            }
            move_list.append(info)

        m = re.match(self.move_regex_no_vn, line)
        if m is not None:
            pos = parse_position(self.board_size, m.group(1))
            visits = int(m.group(2))
            mc_winrate = self.flip_winrate(str_to_percent(m.group(3)))
            r_winrate = self.flip_winrate(str_to_percent(m.group(4)))
            r_count = int(m.group(5))
            policy_prob = str_to_percent(m.group(6))
            pv = m.group(7)
            pv = [parse_position(self.board_size, p) for p in pv.split()]

            info = {
                'pos': pos,
                'visits': visits,
                'winrate': mc_winrate,
                'mc_winrate': mc_winrate,
                'r_winrate': r_winrate,
                'r_count': r_count,
                'policy_prob': policy_prob,
                'pv': pv,
                'color': self.whose_turn()
            }
            move_list.append(info)
        return move_list
Exemplo n.º 2
0
def find_path(initial_state: str,
              target_position: str,
              iterations=60,
              debug=False):
    """
    Вычисляет путь из начального состояния в конечное.
    :param initial_state:
        трёх-символьное сочетание -- буквенная координата, числовай координата, ориентация.
        Примеры: 'a3f', 'f2r', 'e4b', 'g1l'
    :param target_position:
        двух-символьное сочетание -- буквенная координата, числовай координата.
        Примеры: 'a3', 'f2', 'e4', 'g1'
    :param iterations:
        количество итераций достаточных для вычисления q-таблицы
    :param debug:
        если True то распечатается путь на карте и подробный план (с промежуточными состояниями)
    :return:
    """

    target = parse_position(target_position)
    vi = ValueIterator(target)

    # вычислим Q-таблицу
    for _ in range(iterations):
        vi.update()

    # вычислим путь к цели из задонного состояния
    path = vi.path(parse_state(initial_state))

    pretty_path = pformat_path(path, include_state=False)

    if debug:
        visualize_plan(path, target)

    return pretty_path
Exemplo n.º 3
0
 def parse_best(self, stats, line):
     m = re.match(self.best_regex, line)
     if m is not None:
         stats['best'] = parse_position(self.board_size,
                                        m.group(3).split()[0])
         stats['winrate'] = self.flip_winrate(str_to_percent(m.group(2)))
     return stats
Exemplo n.º 4
0
def telemetry(sid, data):
    global recorded_points

    if data:
        # steering_angle = float(data["steering_angle"])
        # throttle = float(data["throttle"])

        x, y, z = parse_position(data["Position"])
        recorded_points.append([x, y, z])

        if lap_definition is not None:
            completion = find_completion([x, y, z], lap_definition)
            sys.stderr.write("\rTrack position: {0:3.2f}%".format(completion *
                                                                  100))

        speed = float(data["speed"])
        image = Image.open(BytesIO(base64.b64decode(data["image"])))
        try:
            image = np.asarray(image)
            image = preprocess_image(image)
            image = np.array([image])
            image = 2.0 * image / 255 - 1

            steering_angle = float(model.predict(image, batch_size=1))

            global speed_limit
            if speed > speed_limit:
                speed_limit = MIN_SPEED  # slow down
            else:
                speed_limit = MAX_SPEED

            throttle = 1.0 - steering_angle**2 - (speed / speed_limit)**2

            # print('{} {} {}'.format(steering_angle, throttle, speed))
            send_control(steering_angle, throttle)
        except Exception as e:
            print(e)

        if args.image_folder != '':
            timestamp = datetime.utcnow().strftime('%Y_%m_%d_%H_%M_%S_%f')[:-3]
            image_filename = os.path.join(args.image_folder, timestamp)
            lycon.save(path='{}.jpg'.format(image_filename), image=image)
    else:
        sio.emit('manual', data={}, skip_sid=True)
Exemplo n.º 5
0
def telemetry(sid, data):
    global recorded_points
    global no_manual_input

    if data:

        x, y, z = parse_position(data["Position"])

        if no_manual_input:
            recorded_points.append([x, y, z])

        speed = float(data["speed"])
        image = Image.open(BytesIO(base64.b64decode(data["image"])))
        try:

            image = preprocess_image(image)
            image = np.array([np.asarray(image)])
            image = 2.0 * image / 255 - 1.0

            steering_angle = float(model.predict(image, batch_size=1))

            global speed_limit
            if speed > speed_limit:
                speed_limit = MIN_SPEED  # slow down
            else:
                speed_limit = MAX_SPEED

            throttle = 1.0 - steering_angle**2 - (speed / speed_limit)**2

            # print('{} {} {}'.format(steering_angle, throttle, speed))
            send_control(steering_angle, throttle)
        except Exception as e:
            print(e)

        if args.image_folder != '':
            timestamp = datetime.utcnow().strftime('%Y_%m_%d_%H_%M_%S_%f')[:-3]
            image_filename = os.path.join(args.image_folder, timestamp)
            lycon.save(path='{}.jpg'.format(image_filename), image=image)
    else:
        no_manual_input = False
        sio.emit('manual', data={}, skip_sid=True)
Exemplo n.º 6
0
    game.bot.go_to_position()
    # c_node = game.cursor.node
    # nnode = Node()
    # game.cursor.append_node(nnode)
    for i in range(1):
        stdout, stderr = game.bot.genmove()

        # Drain and parse Leela stdout & stderr
        stats, move_list = game.bot.parse_analysis(stdout, stderr)

        if stats.get('winrate') and move_list:
            best_move = convert_position(19, move_list[0]['pos'])

        print("result={}".format(best_move))
        color = game.bot.whose_turn()
        best_move = parse_position(19, best_move)
        command = f"play {color} {best_move}"
        print("index is {},play is {}".format(i, command))
        # game.bot.send_command(command)
        # this_move = game.add_moves_to_bot()
        game.bot.add_move_to_history(color, best_move)
        clr = 'W' if color == 'white' else 'B'
        nnode = Node()
        nnode.add_property(Property(clr, [best_move]))
        game.cursor.append_node(nnode)
        game.cursor.next(len(game.cursor.children) - 1)

    game.bot.go_to_position()
    game.save_to_file()
    game.bot.stop()
Exemplo n.º 7
0
def test_parse_position_valid():
    assert parse_position(19, 'A19') == 'aa'
    assert parse_position(19, 'A1') == 'as'
    assert parse_position(19, 'T19') == 'sa'
    assert parse_position(19, 'T1') == 'ss'
    assert parse_position(19, 'K10') == 'jj'
    assert parse_position(19, 'pass') == ''

    assert parse_position(13, 'A13') == 'aa'
    assert parse_position(13, 'A1') == 'am'
    assert parse_position(13, 'N13') == 'ma'
    assert parse_position(13, 'N1') == 'mm'
    assert parse_position(13, 'G7') == 'gg'
    assert parse_position(13, 'pass') == ''

    assert parse_position(9, 'A9') == 'aa'
    assert parse_position(9, 'A1') == 'ai'
    assert parse_position(9, 'J9') == 'ia'
    assert parse_position(9, 'J1') == 'ii'
    assert parse_position(9, 'E5') == 'ee'
    assert parse_position(9, 'pass') == ''
Exemplo n.º 8
0
 def parse_finished(self, stats, stdout):
     m = re.search(self.finished_regex, "".join(stdout))
     if m is not None:
         stats['chosen'] = "resign" if m.group(1) == "resign" else parse_position(
             self.board_size, m.group(1))
     return stats
Exemplo n.º 9
0
        # преобразуем переход между состояниями в переход между позициями, т.е. убираем ориентацию
        edge = self._to_positions(transition)

        # ищем ревард по таблице (по словарю)
        reward = self._reward.get(edge)
        if not reward:  # если ревард НЕ найден то возвращаем значение по умолчанию
            reward = Config.edge_default_reward

        # тут вознаграждается переход в целевую позицию, если она заданна (т.е. не None)
        if self.target_position and edge[1] == self.target_position:
            reward += Config.target_transition_reward

        return reward

    @staticmethod
    def _to_positions(transition):
        s1, s2 = transition  # переход между состояниями

        i1, j1, _o1 = s1
        i2, j2, _o2 = s2

        p1 = (i1, j1)  # ориентация _o1 "выкинута"
        p2 = (i2, j2)  # ориентация _o2 "выкинута"

        edge = (p1, p2)  # переход между позициями
        return edge


if __name__ == '__main__':
    pprint_map(data={parse_position('e4'): '$'})
Exemplo n.º 10
0
    def _proc_inline_move(self, move):
        """Process an inline move, e.g. I5-H5.

        Returns a tuple of: the new board position, T if a black marble was removed, T if a white marble was removed"""

        #########
        # Check 1 - Are we moving a distance of 1?
        start, end = move.split('-')

        start_row, start_col = utils.parse_position(start)
        end_row, end_col = utils.parse_position(end)

        direction, distance = utils.get_direction(start_row, start_col, end_row, end_col)
        #print "Direction is", direction
        if distance != 1:
            raise ValueError("Invalid move - can only move a distance of 1")

        marble = self.turn

        #########
        # Check 2 - Is there a matching marble in the starting position?
        try:
            if self._get_marble(start_row, start_col) != marble:
                raise ValueError("Invalid move - start marble is not yours!")
        #######
        # Check 3 - If we're here, the starting position is not on the board.
        except IndexError:
            raise ValueError("Invalid move - start position is off the board")

        #########
        # Check 4 - The end position can't have a marble of the opposite color.
        try:
            if self._get_marble(end_row, end_col) == utils.get_opposite_marble(marble):
                # Clearly illegal. Is this a pac, though?
                if self._get_marble(start_row, start_col, direction, 2, True) == empty:
                    raise ValueError("Pac - 1 v 1")
                else:
                    raise ValueError("Invalid move - don't have superior strength to push")
        #######
        # Check 5 - If we're here, the end position is not on the board.
        except IndexError:
            raise ValueError("Invalid move - end position is off the board")

        # For documentation, we'll assume our marble is white

        if self._get_marble(start_row, start_col, direction, 1) == empty:
            # We're pushing one white into an empty space - Legal move
            board = self._set_marble(start_row, start_col, empty)
            r, c = utils.calc_position_at_distance(start_row, start_col, direction, 1)
            board = self._set_marble(r, c, marble, board)
            return board, False
        else:
            # Two white marbles in a row. We dealt with black in check 4.
            if self._get_marble(start_row, start_col, direction, 2) == empty:
                # We're pushing two whites into an empty space - Legal move
                board = self._set_marble(start_row, start_col, empty)
                r, c = utils.calc_position_at_distance(start_row, start_col, direction, 2)
                board = self._set_marble(r, c, marble, board)
                return board, False
            elif self._get_marble(start_row, start_col, direction, 2) == utils.get_opposite_marble(marble):
                # Two whites against one black. What's in the next space?
                if self._get_marble(start_row, start_col, direction, 3, True) == empty:
                    # Two whites pushing one black into an empty space - Legal move
                    board = self._set_marble(start_row, start_col, empty)
                    r, c = utils.calc_position_at_distance(start_row, start_col, direction, 2)
                    board = self._set_marble(r, c, marble, board)
                    try:
                        r, c = utils.calc_position_at_distance(start_row, start_col, direction, 3)
                        board = self._set_marble(r, c, utils.get_opposite_marble(marble), board)
                    except IndexError:
                        # We just pushed a black off the edge
                        return board, True
                    return board, False
                elif self._get_marble(start_row, start_col, direction, 3) == utils.get_opposite_marble(marble):
                    # Two whites against two blacks. Can't do this, but is this a pac or just an invalid move?
                    if self._get_marble(start_row, start_col, direction, 4) == empty:
                        # We're pushing two whites against two blacks followed by an empty space
                        raise ValueError("Pac - 2 v 2")
                    else:
                        # We're pushing two whites against two blacks and some other stuff
                        raise ValueError("Invalid move - blocked by other marbles behind it")
                else:
                    # Two whites, one black, one white
                    raise ValueError("Invalid move - blocked by one of your marbles behind it")
            else:
                # Three white marbles in a row.
                if self._get_marble(start_row, start_col, direction, 3) == empty:
                    # We're pushing three whites into an empty space - Legal move
                    board = self._set_marble(start_row, start_col, empty)
                    r, c = utils.calc_position_at_distance(start_row, start_col, direction, 3)
                    board = self._set_marble(r, c, marble, board)
                    return board, False
                elif self._get_marble(start_row, start_col, direction, 3) == utils.get_opposite_marble(marble):
                    # Three whites against one black. What's in the next space?
                    if self._get_marble(start_row, start_col, direction, 4, True) == empty:
                        # Three whites pushing one black into an empty space - Legal move
                        board = self._set_marble(start_row, start_col, empty)
                        r, c = utils.calc_position_at_distance(start_row, start_col, direction, 3)
                        board = self._set_marble(r, c, marble, board)
                        try:
                            r, c = utils.calc_position_at_distance(start_row, start_col, direction, 4)
                            board = self._set_marble(r, c, utils.get_opposite_marble(marble), board)
                        except IndexError:
                            # We just pushed a black off the edge
                            return board, True
                        return board, False
                    elif self._get_marble(start_row, start_col, direction, 4) == utils.get_opposite_marble(marble):
                        # Three whites against two blacks. What's in the next space?
                        if self._get_marble(start_row, start_col, direction, 5, True) == empty:
                            # Three whites pushing two blacks into an empty space - Legal move
                            board = self._set_marble(start_row, start_col, empty)
                            r, c = utils.calc_position_at_distance(start_row, start_col, direction, 3)
                            board = self._set_marble(r, c, marble, board)
                            try:
                                r, c = utils.calc_position_at_distance(start_row, start_col, direction, 5)
                                board = self._set_marble(r, c, utils.get_opposite_marble(marble), board)
                            except IndexError:
                                # We just pushed a black off the edge
                                return board, True
                            return board, False
                        elif self._get_marble(start_row, start_col, direction, 5) == utils.get_opposite_marble(marble):
                            # Three whites against three blacks. Can't do this, but is this a pac or just an invalid move?
                            if self._get_marble(start_row, start_col, direction, 6) == empty:
                                # We're pushing three whites against three blacks followed by an empty space
                                raise ValueError("Pac - 3 v 3")
                            else:
                                # We're pushing three whites against three blacks and some other stuff
                                raise ValueError("Invalid move - blocked by other marbles behind it")
                        else:
                            # Three whites, two blacks, white
                            raise ValueError("Invalid move - blocked by your marble behind it")
                    else:
                        # Three whites, one black, white
                        raise ValueError("Invalid move - blocked by your marble behind it")
                else:
                    # Four whites
                    raise ValueError("Invalid move - can't push 4 marbles")
Exemplo n.º 11
0
    def _proc_broadside_move(self, move):
        """Process an broadside move, e.g. I5-I7-H5"""

        line_start, line_end, end = move.split('-')

        line_start_row, line_start_col = utils.parse_position(line_start)
        line_end_row, line_end_col = utils.parse_position(line_end)
        end_row, end_col = utils.parse_position(end)

        #########
        # Check 1 - Is the line actually a line and <= 3 in length?
        line_direction, line_distance = utils.get_direction(line_start_row, line_start_col, line_end_row, line_end_col)
        if line_distance > 2:
            raise ValueError("Invalid move - can only move 1, 2, or 3 marbles broadside")
        if line_distance == 2:
            # Direction:
            #  NE = 1, E = 2, SE = 3
            #  SW = 4, W = 5, NW = 6

            # Col changes in all cases except for SE and NW
            if line_direction not in (3, 6):
                line_mid_col = max(line_start_col, line_end_col) - 1
            else:
                line_mid_col = line_start_col

            # Row changes in all cases except for E and W
            if line_direction not in (2, 5):
                line_mid_row = max(line_start_row, line_end_row) - 1
            else:
                line_mid_row = line_start_row

        if line_distance == 0:
            # This is the same as an inline push of 1 marble
            inline_result, inline_was_pushed = self._proc_inline_move(move[3:8])
            return inline_result

        marble = self.turn

        #########
        # Check 2 - Is there a matching marble in the line start position?
        try:
            if self._get_marble(line_start_row, line_start_col) != marble:
                raise ValueError("Invalid move - line start marble is not yours!")
        #######
        # Check 3 - If we're here, the line start position is not on the board.
        except IndexError:
            raise ValueError("Invalid move - line start position is off the board")

        #########
        # Check 4 - Is there a matching marble in the line end position?
        try:
            if self._get_marble(line_end_row, line_end_col) != marble:
                raise ValueError("Invalid move - line end marble is not yours!")
        #######
        # Check 5 - If we're here, the line end position is not on the board.
        except IndexError:
            raise ValueError("Invalid move - line end position is off the board")

        #########
        # Check 6 - If the line is of length 3, is there a matching marble in the middle position?
        try:
            if line_distance == 2 and self._get_marble(line_mid_row, line_mid_col) != marble:
                raise ValueError("Invalid move - middle marble is not yours!")
        #######
        # Check 7 - If we're here, the middle position is not on the board... defying the laws of physics, somehow
        except IndexError:
            raise ValueError("Invalid move - middle marble position is off the board")

        move_direction, move_distance = utils.get_direction(line_start_row, line_start_col, end_row, end_col)
        if move_distance != 1:
            raise ValueError("Invalid move - can only move a distance of 1")

        ######
        # Check 8 - Is the end position of the first marble empty?
        try:
            if self._get_marble(end_row, end_col) != empty:
                raise ValueError("Invalid move - end position of the first marble is not empty")
        ######
        # Check 9 - If we're here, the end position of the first marble is not on the board.
        except IndexError:
            raise ValueError("Invalid move - end position of the first marble is off the board")

        ######
        # Check 10 - Is the end position of the last marble empty?
        try:
            if self._get_marble(line_end_row, line_end_col, move_direction, 1) != empty:
                raise ValueError("Invalid move - end position of the last marble is not empty")
        ######
        # Check 11 - If we're here, the end position of the last marble is not on the board.
        except IndexError:
            raise ValueError("Invalid move - end position of the last marble is off the board")

        if line_distance == 2:
            ######
            # Check 14 - Is the end position of the middle marble empty?
            try:
                if self._get_marble(line_mid_row, line_mid_col, move_direction, 1) != empty:
                    raise ValueError("Invalid move - end position of the middle marble is not empty")
            ######
            # Check 15 - If we're here, the end position of the middle marble is not on the board - somehow.
            except IndexError:
                raise ValueError("Invalid move - end position of the middle marble is off the board")

        board = self._set_marble(line_start_row, line_start_col, empty)
        board = self._set_marble(end_row, end_col, marble, board)

        board = self._set_marble(line_end_row, line_end_col, empty, board)
        r, c = utils.calc_position_at_distance(line_end_row, line_end_col, move_direction, 1)
        board = self._set_marble(r, c, marble, board)

        if line_distance == 2:
            board = self._set_marble(line_mid_row, line_mid_col, empty, board)
            r, c = utils.calc_position_at_distance(line_mid_row, line_mid_col, move_direction, 1)
            board = self._set_marble(r, c, marble, board)

        return board