예제 #1
0
    def _run_single_playout(self,
                            state: GameState,
                            parent_node: Node,
                            depth=1,
                            mv_list=[]):  #, pipe_id):
        """
        This function works recursively until a terminal node is reached

        :param state: Current game-state for the evaluation. This state differs between the treads
        :param parent_node: Current parent-node of the selected node. In the first  expansion this is the root node.
        :param depth: Current depth for the evaluation. Depth is increased by 1 for every recusive call
        :param mv_list: List of moves which have been taken in the current path. For each selected child node this list
                        is expanded by one move recursively.
        :return: -value: The inverse value prediction of the current board state. The flipping by -1 each turn is needed
                        because the point of view changes each half-move
                depth: Current depth reach by this evaluation
                mv_list: List of moves which have been selected
        """

        # select a legal move on the chess board
        node, move, child_idx = self._select_node(parent_node)

        if move is None:
            raise Exception(
                "Illegal tree setup. A 'None' move was selected which souldn't be possible"
            )

        # update the visit counts to this node
        # temporarily reduce the attraction of this node by applying a virtual loss /
        # the effect of virtual loss will be undone if the playout is over
        parent_node.apply_virtual_loss_to_child(child_idx, self.virtual_loss)

        # apply the selected move on the board
        state.apply_move(move)

        # append the selected move to the move list
        mv_list.append(move)

        if node is None:

            # get the board-fen which is used as an identifier for the board positions in the look-up table
            board_fen = state.get_board_fen()

            # check if the addressed fen exist in the look-up table
            if board_fen in self.node_lookup:
                # get the node from the look-up list
                node = self.node_lookup[board_fen]

                with parent_node.lock:
                    # setup a new connection from the parent to the child
                    parent_node.child_nodes[child_idx] = node

                # get the prior value from the leaf node which has already been expanded
                #value = node.v

                # get the value from the leaf node (the current function is called recursively)
                value, depth, mv_list = self._run_single_playout(
                    state, node, depth + 1, mv_list)

            else:
                # expand and evaluate the new board state (the node wasn't found in the look-up table)
                # its value will be backpropagated through the tree and flipped after every layer

                # receive a free available pipe
                my_pipe = self.my_pipe_endings.pop()
                my_pipe.send(state.get_state_planes())
                # this pipe waits for the predictions of the network inference service
                [value, policy_vec] = my_pipe.recv()
                # put the used pipe back into the list
                self.my_pipe_endings.append(my_pipe)

                # initialize is_leaf by default to false
                is_leaf = False

                # check if the current player has won the game
                # (we don't need to check for is_lost() because the game is already over
                #  if the current player checkmated his opponent)
                if state.is_won() is True:
                    value = -1
                    is_leaf = True
                    legal_moves = []
                    p_vec_small = None

                # check if you can claim a draw - its assumed that the draw is always claimed
                elif state.is_draw() is True:
                    value = 0
                    is_leaf = True
                    legal_moves = []
                    p_vec_small = None
                else:
                    # get the current legal move of its board state
                    legal_moves = list(state.get_legal_moves())
                    if len(legal_moves) < 1:
                        raise Exception(
                            'No legal move is available for state: %s' % state)

                    # extract a sparse policy vector with normalized probabilities
                    try:
                        p_vec_small = get_probs_of_move_list(
                            policy_vec,
                            legal_moves,
                            is_white_to_move=state.is_white_to_move(),
                            normalize=True)

                    except KeyError:
                        raise Exception('Key Error for state: %s' % state)

                # convert all legal moves to a string if the option check_mate_in_one was enabled
                if self.check_mate_in_one is True:
                    str_legal_moves = str(state.get_legal_moves())
                else:
                    str_legal_moves = ''

                # create a new node
                new_node = Node(value, p_vec_small, legal_moves,
                                str_legal_moves, is_leaf)

                #if is_leaf is False:
                # test of adding dirichlet noise to a new node
                #    new_node.apply_dirichlet_noise_to_prior_policy(epsilon=self.dirichlet_epsilon/4, alpha=self.dirichlet_alpha)

                # include a reference to the new node in the look-up table
                self.node_lookup[board_fen] = new_node

                with parent_node.lock:
                    # add the new node to its parent
                    parent_node.child_nodes[child_idx] = new_node

                # check if the new node has a mate_in_one connection (if yes overwrite the network prediction)
                if new_node.mate_child_idx is not None:
                    value = 1

        # check if we have reached a leaf node
        elif node.is_leaf is True:
            value = node.v
            # receive a free available pipe
            my_pipe = self.my_pipe_endings.pop()
            my_pipe.send(state.get_state_planes())
            # this pipe waits for the predictions of the network inference service
            [_, _] = my_pipe.recv()
            # put the used pipe back into the list
            self.my_pipe_endings.append(my_pipe)

        else:
            # get the value from the leaf node (the current function is called recursively)
            value, depth, mv_list = self._run_single_playout(
                state, node, depth + 1, mv_list)

        # revert the virtual loss and apply the predicted value by the network to the node
        parent_node.revert_virtual_loss_and_update(child_idx,
                                                   self.virtual_loss, -value)

        # we invert the value prediction for the parent of the above node layer because the player's turn is flipped every turn
        return -value, depth, mv_list
예제 #2
0
    def _run_single_playout(self,
                            state: GameState,
                            parent_node: Node,
                            pipe_id=0,
                            depth=1,
                            chosen_nodes=[]):
        """
        This function works recursively until a leaf or terminal node is reached.
        It ends by backpropagating the value of the new expanded node or by propagating the value of a terminal state.

        :param state_: Current game-state for the evaluation. This state differs between the treads
        :param parent_node: Current parent-node of the selected node. In the first  expansion this is the root node.
        :param depth: Current depth for the evaluation. Depth is increased by 1 for every recusive call
        :param chosen_nodes: List of moves which have been taken in the current path. For each selected child node this list
                        is expanded by one move recursively.
        :param chosen_nodes: List of all nodes that this thread has explored with respect to the root node
        :return: -value: The inverse value prediction of the current board state. The flipping by -1 each turn is needed
                        because the point of view changes each half-move
                depth: Current depth reach by this evaluation
                mv_list: List of moves which have been selected
        """

        # select a legal move on the chess board
        node, move, child_idx = self._select_node(parent_node)

        if move is None:
            raise Exception(
                "Illegal tree setup. A 'None' move was selected which souldn't be possible"
            )

        # update the visit counts to this node
        # temporarily reduce the attraction of this node by applying a virtual loss /
        # the effect of virtual loss will be undone if the playout is over
        parent_node.apply_virtual_loss_to_child(child_idx, self.virtual_loss)

        if depth == 1:
            state = GameState(deepcopy(state.get_pythonchess_board()))

        # apply the selected move on the board
        state.apply_move(move)

        # append the selected move to the move list
        # append the chosen child idx to the chosen_nodes list
        chosen_nodes.append(child_idx)

        if node is None:

            # get the transposition-key which is used as an identifier for the board positions in the look-up table
            transposition_key = state.get_transposition_key()

            # check if the addressed fen exist in the look-up table
            # note: It's important to use also the halfmove-counter here, otherwise the system can create an infinite
            # feed-back-loop
            key = (transposition_key, state.get_halfmove_counter())

            # expand and evaluate the new board state (the node wasn't found in the look-up table)
            # its value will be backpropagated through the tree and flipped after every layer
            # receive a free available pipe
            my_pipe = self.my_pipe_endings[pipe_id]

            if self.send_batches is True:
                my_pipe.send(state.get_state_planes())
                # this pipe waits for the predictions of the network inference service
                [value, policy_vec] = my_pipe.recv()
            else:
                state_planes = state.get_state_planes()
                self.batch_state_planes[pipe_id] = state_planes

                my_pipe.send(pipe_id)

                result_channel = my_pipe.recv()

                value = np.array(self.batch_value_results[result_channel])
                policy_vec = np.array(
                    self.batch_policy_results[result_channel])

            # initialize is_leaf by default to false
            is_leaf = False

            # check if the current player has won the game
            # (we don't need to check for is_lost() because the game is already over
            #  if the current player checkmated his opponent)
            is_won = False
            is_check = False

            if state.is_check() is True:
                is_check = True
                if state.is_won() is True:
                    is_won = True

            if is_won is True:
                value = -1
                is_leaf = True
                legal_moves = []
                p_vec_small = None
                # establish a mate in one connection in order to stop exploring different alternatives
                parent_node.mate_child_idx = child_idx

            # get the value from the leaf node (the current function is called recursively)
            # check if you can claim a draw - its assumed that the draw is always claimed
            elif self.can_claim_threefold_repetition(transposition_key, chosen_nodes) or \
                    state.get_pythonchess_board().can_claim_fifty_moves() is True:
                value = 0
                is_leaf = True
                legal_moves = []
                p_vec_small = None
            else:
                # get the current legal move of its board state
                legal_moves = state.get_legal_moves()

                if len(legal_moves) < 1:
                    raise Exception(
                        'No legal move is available for state: %s' % state)

                # extract a sparse policy vector with normalized probabilities
                try:
                    p_vec_small = get_probs_of_move_list(
                        policy_vec,
                        legal_moves,
                        is_white_to_move=state.is_white_to_move(),
                        normalize=True)

                except KeyError:
                    raise Exception('Key Error for state: %s' % state)

            # convert all legal moves to a string if the option check_mate_in_one was enabled
            if self.check_mate_in_one is True:
                str_legal_moves = str(state.get_legal_moves())
            else:
                str_legal_moves = ''

            # clip the visit nodes for all nodes in the search tree except the director opp. move
            clip_low_visit = self.use_pruning and depth != 1

            # create a new node
            new_node = Node(value, p_vec_small, legal_moves, str_legal_moves,
                            is_leaf, transposition_key, clip_low_visit)

            if depth == 1:

                # disable uncertain moves from being visited by giving them a very bad score
                if is_leaf is False:
                    if self.root_node_prior_policy[
                            child_idx] < 1e-3 and value * -1 < self.root_node.v:
                        with parent_node.lock:
                            value = 99

                if value < 0:  # and state.are_pocket_empty(): #and pipe_id == 0:
                    # test of adding dirichlet noise to a new node
                    new_node.apply_dirichlet_noise_to_prior_policy(
                        epsilon=self.dirichlet_epsilon * .02,
                        alpha=self.dirichlet_alpha)

            if self.use_pruning is False:
                # include a reference to the new node in the look-up table
                self.node_lookup[key] = new_node

            with parent_node.lock:
                # add the new node to its parent
                parent_node.child_nodes[child_idx] = new_node

        # check if we have reached a leaf node
        elif node.is_leaf is True:
            value = node.v

        else:
            # get the value from the leaf node (the current function is called recursively)
            value, depth, chosen_nodes = self._run_single_playout(
                state, node, pipe_id, depth + 1, chosen_nodes)

        # revert the virtual loss and apply the predicted value by the network to the node
        parent_node.revert_virtual_loss_and_update(child_idx,
                                                   self.virtual_loss, -value)

        # we invert the value prediction for the parent of the above node layer because the player's turn is flipped every turn
        return -value, depth, chosen_nodes