Change card after taking action.

[naja.git] / naja / gameboard.py

from random import choice

from naja.constants import(
    BITS, DIRECTION_BITS, CONDITION_BITS, PLAYER_DEFAULTS,
    MOVE, ACT)
from naja.player import Player
from naja import actions


class GameBoard(object):
    """
    A representation of the game board.
    """

    def __init__(self, state, player, board_locations):
        self.max_health = state['max_health']
        self.wins_required = state['wins_required']
        self.health = state['health']
        self.wins = state['wins']
        self.locations = [item.copy() for item in state['locations']]
        self.player = player
        self.board_locations = board_locations
        self.player_mode = MOVE

    @classmethod
    def new_game(cls, locations_definition,
                 initial_bits=PLAYER_DEFAULTS.INITIAL_BITS,
                 initial_pos=PLAYER_DEFAULTS.INITIAL_POS,
                 max_health=PLAYER_DEFAULTS.MAX_HEALTH,
                 wins_required=PLAYER_DEFAULTS.WINS_REQUIRED):
        state = {
            'max_health': max_health,
            'health': max_health,
            'wins_required': wins_required,
            'wins': 0,
            'locations': locations_definition,
        }
        player = Player(initial_bits, initial_pos)
        board_locations = cls.import_board_locations(
            cls.generate_board(locations_definition))
        return cls(state, player, board_locations)

    @classmethod
    def import_game(cls, definition):
        state = definition.copy()
        player = Player.import_player(state.pop('player'))
        board_locations = cls.import_board_locations(
            state.pop('board_locations'))
        return cls(state, player, board_locations)

    def export(self):
        return {
            'max_health': self.max_health,
            'health': self.health,
            'wins_required': self.wins_required,
            'wins': self.wins,
            'locations': [item.copy() for item in self.locations],
            'player': self.player.export(),
            'board_locations': self.export_board_locations(),
        }

    @classmethod
    def import_locations(cls, locations_definition):
        return [
            LocationCard.import_location(definition)
            for definition in locations_definition]

    def export_board_locations(self):
        return dict(
            (position, location.export())
            for position, location in self.board_locations.iteritems())

    @classmethod
    def import_board_locations(cls, board_locations_definition):
        return dict(
            (position, LocationCard.import_location(definition))
            for position, definition in board_locations_definition.iteritems())

    @classmethod
    def generate_board(cls, locations_definition):
        board_locations = {}
        for x in range(5):
            for y in range(5):
                board_location = LocationCard.new_location(
                    choice(locations_definition).copy())
                board_locations[(x, y)] = board_location.export()
        return board_locations

    def lose_health(self):
        self.health -= 1
        # TODO: Check win/lose

    def replace_card(self, position):
        location = LocationCard.new_location(choice(self.locations).copy())
        self.board_locations[position] = location

    def change_mode(self):
        """Advance to the next mode"""
        if self.player_mode == MOVE:
            self.player_mode = ACT
        elif self.player_mode == ACT:
            self.player_mode = MOVE
        else:
            raise RuntimeError("Illegal player mode %s" % self.player_mode)


class LocationCard(object):
    """
    A particular set of options available on a location.
    """

    def __init__(self, bitwise_operand, location_actions):
        self.bitwise_operand = bitwise_operand
        self.actions = location_actions
        self.check_actions()

    @classmethod
    def import_location(cls, state):
        location_actions = [
            cls.build_action(definition) for definition in state['actions']]
        return cls(state['bitwise_operand'], location_actions)

    @classmethod
    def build_action(cls, definition):
        action_class = getattr(actions, definition['action_class'])
        required_bits = definition['required_bits']
        data = definition.get('data', {})
        return action_class(required_bits, **data)

    @classmethod
    def new_location(cls, definition):
        return cls.import_location({
            'bitwise_operand': cls.generate_bitwise_operand(),
            'actions': definition['actions'],
        })

    def export(self):
        return {
            'bitwise_operand': self.bitwise_operand,
            'actions': [action.export() for action in self.actions],
        }

    def check_actions(self):
        if not self.actions:
            print "Warning: Location has no actions."
            self.insert_default_default_action()
        if self.actions[0].required_bits:
            self.insert_default_default_action()

    def insert_default_default_action(self):
        self.actions.insert(0, self.build_action({
            'action_class': 'DoNothing',
            'required_bits': [],
        }))

    @staticmethod
    def generate_bitwise_operand():
        """
        Generate a set of two or three bits. At least one direction and one
        condition bit will be included. There is a low probability of choosing
        a third bit from the complete set.
        """
        bits = set()
        bits.add(choice(DIRECTION_BITS.values()))
        bits.add(choice(CONDITION_BITS.values()))
        # One in three chance of adding a third bit, with a further one in four
        # chance that it will match a bit already chosen.
        if choice(range(3)) == 0:
            bits.add(choice(BITS.values()))
        return frozenset(bits)