def __init__(self, player_one_id):
"""
:return:
"""
self.__game_id = str(uuid.uuid4().hex)
self.__deck = Deck(Game.__TOTAL_CARDS_IN_DECK)
self.__board = Board(Game.__BOARD_SIZE, self.__deck)
self.__player_one = Player(player_one_id)
self.__current_player = self.__player_one
self.__player_two = None
self.__is_opponent_automated = True
self.__is_ready = False
self.__winner = None
Game.__LOGGER.debug('Initializing a new game: %s', self.__game_id)
def join(self, player_two_id, is_ai_opponent):
"""
Joins the game as player two.
:param player_two_id: The id of player two
:type player_two_id: str
:param is_ai_opponent: Whether or not the opponent is an AI
:type is_ai_opponent: bool
:precondition: len(player_two_name) > 0
:precondition: self.__player_two is None
"""
assert isinstance(player_two_id, str)
assert len(player_two_id) > 0
assert isinstance(is_ai_opponent, bool)
assert self.__player_two is None
Game.__LOGGER.debug("Game %s - Player Two Join: %s.", self.__game_id, player_two_id)
self.__player_two = Player(player_two_id)
self.__is_opponent_automated = is_ai_opponent
self.__deal()
self.__is_ready = True
class Game(object):
"""
Class representing a 'synapse' game.
"""
def __init__(self, player_one_id):
"""
:return:
"""
self.__game_id = str(uuid.uuid4().hex)
self.__deck = Deck(Game.__TOTAL_CARDS_IN_DECK)
self.__board = Board(Game.__BOARD_SIZE, self.__deck)
self.__player_one = Player(player_one_id)
self.__current_player = self.__player_one
self.__player_two = None
self.__is_opponent_automated = True
self.__is_ready = False
self.__winner = None
Game.__LOGGER.debug('Initializing a new game: %s', self.__game_id)
def join(self, player_two_id, is_ai_opponent):
"""
Joins the game as player two.
:param player_two_id: The id of player two
:type player_two_id: str
:param is_ai_opponent: Whether or not the opponent is an AI
:type is_ai_opponent: bool
:precondition: len(player_two_name) > 0
:precondition: self.__player_two is None
"""
assert isinstance(player_two_id, str)
assert len(player_two_id) > 0
assert isinstance(is_ai_opponent, bool)
assert self.__player_two is None
Game.__LOGGER.debug("Game %s - Player Two Join: %s.", self.__game_id, player_two_id)
self.__player_two = Player(player_two_id)
self.__is_opponent_automated = is_ai_opponent
self.__deal()
self.__is_ready = True
def __deal(self):
"""
Deals out the cards to the various players.
:precondition: self.__player_one is not None and self.__player_two is not None
"""
assert self.__player_one is not None and self.__player_two is not None
Game.__LOGGER.debug("Game: %s - Dealing", self.__game_id)
(player_one_cards, player_two_cards) = self.__deck.deal(2, Game.__NUMBER_OF_CARDS_DEALT)
for card in player_one_cards:
self.__player_one.add_card(card)
for card in player_two_cards:
self.__player_two.add_card(card)
def __get_player_by_id(self, player_id):
"""
Gets a player by id.
:param player_id: The player id
:type player_id: str
:precondition: len(player_id) > 0
:postcondition: ret is None or isinstance(ret, None)
"""
assert isinstance(player_id, str)
assert player_id
for player in {self.__player_one, self.__player_two}:
if player.player_id == player_id:
return Player(player_id)
def test(self):
self.__board.find_sequence(4)
def take_ai_turn(self):
"""
Takes the turn for the AI player
"""
assert self.__is_opponent_automated
# Assumption, AI is always player2...this is bad.
assert self.__player_two == self.__current_player
# Determine what move to make and call self.take_turn
# For now, just choose the first card.
card_to_play = self.__player_two.cards[0]
# find the correct sphere to play
sphere_to_play = self.__board.get_sphere_by_value(card_to_play.value)
self.take_turn(self.__player_two.player_id, card_to_play.card_id, sphere_to_play.sphere_id)
def take_turn(self, player_id, card_id, sphere_id):
"""
Takes the current turn for the given player
:param player_id: The player taking the turn
:type player_id: str
:param card_id: The card being played
:type card_id: str
:param sphere_id: The sphere being chosen
:type sphere_id: str
:precondition: self.__current_player is player
"""
assert isinstance(player_id, str)
assert isinstance(card_id, str)
assert isinstance(sphere_id, str)
assert player_id
assert card_id
assert sphere_id
card = self.__deck.get_card_by_id(card_id)
assert isinstance(card, Card)
sphere = self.__board.get_sphere_by_id(sphere_id)
assert isinstance(sphere, Sphere)
player = self.__get_player_by_id(player_id)
assert isinstance(player, Player)
assert card.value == sphere.value
assert self.__current_player == player
assert self.__winner is None
assert self.__is_ready is True
assert self.__current_player.has_card(card)
assert self.__board.is_sphere_selectable(card, sphere)
self.__board.select_sphere(player, sphere)
self.__current_player.remove_card(card)
self.__deck.discard(card)
self.__current_player.add_card(self.__deck.draw())
self.__check_for_sequence()
if self.__current_player == self.__player_one:
self.__current_player = self.__player_two
else:
self.__current_player = self.__player_one
def to_json(self):
return {
'game_id': self.__game_id,
'board': self.__board,
'player_one': self.__player_one,
'player_two': self.__player_two,
'current_player': self.__current_player,
'winner': self.__winner,
}
def __check_for_sequence(self):
"""
Checks to see if someone has won
"""
sequence_found = False
matrix = self.__board.matrix
for winning_sequence in Game.__WINNING_SEQUENCES:
sphere_sequence = [matrix[point.x][point.y][point.z].owner == self.__current_player for point in winning_sequence]
if all(sphere_sequence):
sequence_found = True
break
else:
assert all(sphere_sequence) is False
if sequence_found:
self.__winner = self.__current_player
else:
assert self.__winner is None
@property
def is_ready(self):
"""
Returns whether or not the game is ready to start
:rtype: bool
"""
return self.__is_ready
@property
def game_id(self):
"""
Returns the id of the game
:rtype: str
:postcondition: len(ret) > 0
"""
return self.__game_id
@property
def is_opponent_automated(self):
"""
Returns true if this game is being played against the CPU
:rtype: bool
"""
return self.__is_opponent_automated
@property
def players(self):
"""
Returns a list of players.
:rtype: list
:postcondition: all(isinstance(p, Player) for p in ret)
"""
return [p for p in {self.__player_one, self.__player_two} if p is not None]
__NUMBER_OF_CARDS_DEALT = 7
"""
Number of cards dealt to each player
"""
__TOTAL_CARDS_IN_DECK = 64
"""
Numbers of cards in the deck
"""
__BOARD_SIZE = 4
"""
The size of the board
"""
__POINT = collections.namedtuple('Point', ['x', 'y', 'z'])
"""
Named tuple to hold a 3d point coordinate.
"""
__VERTICAL_WINNING_ENTRIES = set((
(__POINT(0, 0, 0), __POINT(0, 1, 0), __POINT(0, 2, 0), __POINT(0, 3, 0)),
(__POINT(1, 0, 0), __POINT(1, 1, 0), __POINT(1, 2, 0), __POINT(1, 3, 0)),
(__POINT(2, 0, 0), __POINT(2, 1, 0), __POINT(2, 2, 0), __POINT(2, 3, 0)),
(__POINT(3, 0, 0), __POINT(3, 1, 0), __POINT(3, 2, 0), __POINT(3, 3, 0)),
(__POINT(0, 0, 1), __POINT(0, 1, 1), __POINT(0, 2, 1), __POINT(0, 3, 1)),
(__POINT(1, 0, 1), __POINT(1, 1, 1), __POINT(1, 2, 1), __POINT(1, 3, 1)),
(__POINT(2, 0, 1), __POINT(2, 1, 1), __POINT(2, 2, 1), __POINT(2, 3, 1)),
(__POINT(3, 0, 1), __POINT(3, 1, 1), __POINT(3, 2, 1), __POINT(3, 3, 1)),
(__POINT(0, 0, 2), __POINT(0, 1, 2), __POINT(0, 2, 2), __POINT(0, 3, 2)),
(__POINT(1, 0, 2), __POINT(1, 1, 2), __POINT(1, 2, 2), __POINT(1, 3, 2)),
(__POINT(2, 0, 2), __POINT(2, 1, 2), __POINT(2, 2, 2), __POINT(2, 3, 2)),
(__POINT(3, 0, 2), __POINT(3, 1, 2), __POINT(3, 2, 2), __POINT(3, 3, 2)),
(__POINT(0, 0, 3), __POINT(0, 1, 3), __POINT(0, 2, 3), __POINT(0, 3, 3)),
(__POINT(1, 0, 3), __POINT(1, 1, 3), __POINT(1, 2, 3), __POINT(1, 3, 3)),
(__POINT(2, 0, 3), __POINT(2, 1, 3), __POINT(2, 2, 3), __POINT(2, 3, 3)),
(__POINT(3, 0, 3), __POINT(3, 1, 3), __POINT(3, 2, 3), __POINT(3, 3, 3)),
#### DIAGONAL ####
(__POINT(0, 0, 0), __POINT(1, 1, 0), __POINT(2, 2, 0), __POINT(3, 3, 0)),
(__POINT(0, 3, 0), __POINT(1, 2, 0), __POINT(2, 1, 0), __POINT(3, 0, 0)),
(__POINT(0, 0, 1), __POINT(1, 1, 1), __POINT(2, 2, 1), __POINT(3, 3, 1)),
(__POINT(0, 3, 1), __POINT(1, 2, 1), __POINT(2, 1, 1), __POINT(3, 0, 1)),
(__POINT(0, 0, 2), __POINT(1, 1, 2), __POINT(2, 2, 2), __POINT(3, 3, 2)),
(__POINT(0, 3, 2), __POINT(1, 2, 2), __POINT(2, 1, 2), __POINT(3, 0, 2)),
(__POINT(0, 0, 3), __POINT(1, 1, 3), __POINT(2, 2, 3), __POINT(3, 3, 3)),
(__POINT(0, 3, 3), __POINT(1, 2, 3), __POINT(2, 1, 3), __POINT(3, 0, 3)),
))
__HORIZONTAL_WINNING_ENTRIES = set((
(__POINT(0, 0, 0), __POINT(1, 0, 0), __POINT(2, 0, 0), __POINT(3, 0, 0)),
(__POINT(0, 1, 0), __POINT(1, 1, 0), __POINT(2, 1, 0), __POINT(3, 1, 0)),
(__POINT(0, 2, 0), __POINT(1, 2, 0), __POINT(2, 2, 0), __POINT(3, 2, 0)),
(__POINT(0, 3, 0), __POINT(1, 3, 0), __POINT(2, 3, 0), __POINT(3, 3, 0)),
(__POINT(0, 0, 1), __POINT(1, 0, 1), __POINT(2, 0, 1), __POINT(3, 0, 1)),
(__POINT(0, 1, 1), __POINT(1, 1, 1), __POINT(2, 1, 1), __POINT(3, 1, 1)),
(__POINT(0, 2, 1), __POINT(1, 2, 1), __POINT(2, 2, 1), __POINT(3, 2, 1)),
(__POINT(0, 3, 1), __POINT(1, 3, 1), __POINT(2, 3, 1), __POINT(3, 3, 1)),
(__POINT(0, 0, 2), __POINT(1, 0, 2), __POINT(2, 0, 2), __POINT(3, 0, 2)),
(__POINT(0, 1, 2), __POINT(1, 1, 2), __POINT(2, 1, 2), __POINT(3, 1, 2)),
(__POINT(0, 2, 2), __POINT(1, 2, 2), __POINT(2, 2, 2), __POINT(3, 2, 2)),
(__POINT(0, 3, 2), __POINT(1, 3, 2), __POINT(2, 3, 2), __POINT(3, 3, 2)),
(__POINT(0, 0, 3), __POINT(1, 0, 3), __POINT(2, 0, 3), __POINT(3, 0, 3)),
(__POINT(0, 1, 3), __POINT(1, 1, 3), __POINT(2, 1, 3), __POINT(3, 1, 3)),
(__POINT(0, 2, 3), __POINT(1, 2, 3), __POINT(2, 2, 3), __POINT(3, 2, 3)),
(__POINT(0, 3, 3), __POINT(1, 3, 3), __POINT(2, 3, 3), __POINT(3, 3, 3)),
#### DIAGONAL ####
(__POINT(0, 3, 0), __POINT(1, 3, 1), __POINT(2, 3, 2), __POINT(3, 3, 3)),
(__POINT(0, 3, 3), __POINT(1, 3, 2), __POINT(2, 3, 1), __POINT(3, 3, 0)),
(__POINT(0, 2, 0), __POINT(1, 2, 1), __POINT(2, 2, 2), __POINT(3, 2, 3)),
(__POINT(0, 2, 3), __POINT(1, 2, 2), __POINT(2, 2, 1), __POINT(3, 2, 0)),
(__POINT(0, 1, 0), __POINT(1, 1, 1), __POINT(2, 1, 2), __POINT(3, 1, 3)),
(__POINT(0, 1, 3), __POINT(1, 1, 2), __POINT(2, 1, 1), __POINT(3, 1, 0)),
(__POINT(0, 0, 0), __POINT(1, 0, 1), __POINT(2, 0, 2), __POINT(3, 0, 3)),
(__POINT(0, 0, 3), __POINT(1, 0, 2), __POINT(2, 0, 1), __POINT(3, 0, 0)),
))
__WINNING_SEQUENCES = __VERTICAL_WINNING_ENTRIES | __HORIZONTAL_WINNING_ENTRIES
__LOGGER = logging.getLogger(__name__)
"""
