Exemplo n.º 1
0
    def init_game(self):
        ''' Initialilze the game of Limit Texas Hold'em

        This version supports two-player limit texas hold'em

        Returns:
            (tuple): Tuple containing:

                (dict): The first state of the game
                (int): Current player's id
        '''
        # Initilize a dealer that can deal cards
        self.dealer = Dealer(self.np_random)

        # Initilize players to play the game
        self.players = [
            Player(i, self.init_chips[i], self.np_random)
            for i in range(self.num_players)
        ]

        # Initialize a judger class which will decide who wins in the end
        self.judger = Judger(self.np_random)

        # Deal cards to each  player to prepare for the first round
        for i in range(2 * self.num_players):
            self.players[i % self.num_players].hand.append(
                self.dealer.deal_card())

        # Initilize public cards
        self.public_cards = []
        self.stage = Stage.PREFLOP

        # Randomly choose a big blind and a small blind
        s = self.np_random.randint(0, self.num_players)
        b = (s + 1) % self.num_players
        self.players[b].bet(chips=self.big_blind)
        self.players[s].bet(chips=self.small_blind)

        # The player next to the small blind plays the first
        self.game_pointer = (b + 1) % self.num_players

        # Initilize a bidding round, in the first round, the big blind and the small blind needs to
        # be passed to the round for processing.
        self.round = Round(self.num_players,
                           self.big_blind,
                           dealer=self.dealer,
                           np_random=self.np_random)

        self.round.start_new_round(game_pointer=self.game_pointer,
                                   raised=[p.in_chips for p in self.players])

        # Count the round. There are 4 rounds in each game.
        self.round_counter = 0

        # Save the hisory for stepping back to the last state.
        self.history = []

        state = self.get_state(self.game_pointer)

        return state, self.game_pointer
Exemplo n.º 2
0
class NolimitholdemGame(Game):
    def __init__(self, allow_step_back=False, num_players=2):
        ''' Initialize the class nolimitholdem Game
        '''
        self.allow_step_back = allow_step_back
        self.np_random = np.random.RandomState()

        # small blind and big blind
        self.small_blind = 1
        self.big_blind = 2 * self.small_blind

        # config players
        self.num_players = num_players
        self.init_chips = [100] * num_players

        # If None, the dealer will be randomly chosen
        self.dealer_id = None

    def configure(self, game_config):
        ''' Specifiy some game specific parameters, such as player number, initial chips, and dealer id.
        If dealer_id is None, he will be randomly chosen
        '''
        self.num_players = game_config['game_player_num']
        self.init_chips = game_config['chips_for_each']
        self.dealer_id = game_config['dealer_id']

    def init_game(self):
        ''' Initialilze the game of Limit Texas Hold'em

        This version supports two-player limit texas hold'em

        Returns:
            (tuple): Tuple containing:

                (dict): The first state of the game
                (int): Current player's id
        '''
        if self.dealer_id is None:
            self.dealer_id = self.np_random.randint(0, self.num_players)

        # Initilize a dealer that can deal cards
        self.dealer = Dealer(self.np_random)

        # Initilize players to play the game
        self.players = [
            Player(i, self.init_chips[i], self.np_random)
            for i in range(self.num_players)
        ]

        # Initialize a judger class which will decide who wins in the end
        self.judger = Judger(self.np_random)

        # Deal cards to each  player to prepare for the first round
        for i in range(2 * self.num_players):
            self.players[i % self.num_players].hand.append(
                self.dealer.deal_card())

        # Initilize public cards
        self.public_cards = []
        self.stage = Stage.PREFLOP

        # Big blind and small blind
        s = (self.dealer_id + 1) % self.num_players
        b = (self.dealer_id + 2) % self.num_players
        self.players[b].bet(chips=self.big_blind)
        self.players[s].bet(chips=self.small_blind)

        # The player next to the small blind plays the first
        self.game_pointer = (b + 1) % self.num_players

        # Initilize a bidding round, in the first round, the big blind and the small blind needs to
        # be passed to the round for processing.
        self.round = Round(self.num_players,
                           self.big_blind,
                           dealer=self.dealer,
                           np_random=self.np_random)

        self.round.start_new_round(game_pointer=self.game_pointer,
                                   raised=[p.in_chips for p in self.players])

        # Count the round. There are 4 rounds in each game.
        self.round_counter = 0

        # Save the hisory for stepping back to the last state.
        self.history = []

        state = self.get_state(self.game_pointer)

        return state, self.game_pointer

    def get_legal_actions(self):
        ''' Return the legal actions for current player

        Returns:
            (list): A list of legal actions
        '''
        return self.round.get_nolimit_legal_actions(players=self.players)

    def step(self, action):
        ''' Get the next state

        Args:
            action (str): a specific action. (call, raise, fold, or check)

        Returns:
            (tuple): Tuple containing:

                (dict): next player's state
                (int): next plater's id
        '''

        if action not in self.get_legal_actions():
            print(action, self.get_legal_actions())
            print(self.get_state(self.game_pointer))
            raise Exception('Action not allowed')

        if self.allow_step_back:
            # First snapshot the current state
            r = deepcopy(self.round)
            b = self.game_pointer
            r_c = self.round_counter
            d = deepcopy(self.dealer)
            p = deepcopy(self.public_cards)
            ps = deepcopy(self.players)
            self.history.append((r, b, r_c, d, p, ps))

        # Then we proceed to the next round
        self.game_pointer = self.round.proceed_round(self.players, action)

        players_in_bypass = [
            1 if player.status in (PlayerStatus.FOLDED,
                                   PlayerStatus.ALLIN) else 0
            for player in self.players
        ]
        if self.num_players - sum(players_in_bypass) == 1:
            last_player = players_in_bypass.index(0)
            if self.round.raised[last_player] >= max(self.round.raised):
                # If the last player has put enough chips, he is also bypassed
                players_in_bypass[last_player] = 1

        # If a round is over, we deal more public cards
        if self.round.is_over():
            # Game pointer goes to the first player not in bypass after the dealer, if there is one
            self.game_pointer = (self.dealer_id + 1) % self.num_players
            if sum(players_in_bypass) < self.num_players:
                while players_in_bypass[self.game_pointer]:
                    self.game_pointer = (self.game_pointer +
                                         1) % self.num_players

            # For the first round, we deal 3 cards
            if self.round_counter == 0:
                self.stage = Stage.FLOP
                self.public_cards.append(self.dealer.deal_card())
                self.public_cards.append(self.dealer.deal_card())
                self.public_cards.append(self.dealer.deal_card())
                if len(self.players) == np.sum(players_in_bypass):
                    self.round_counter += 1
            # For the following rounds, we deal only 1 card
            if self.round_counter == 1:
                self.stage = Stage.TURN
                self.public_cards.append(self.dealer.deal_card())
                if len(self.players) == np.sum(players_in_bypass):
                    self.round_counter += 1
            if self.round_counter == 2:
                self.stage = Stage.RIVER
                self.public_cards.append(self.dealer.deal_card())
                if len(self.players) == np.sum(players_in_bypass):
                    self.round_counter += 1

            self.round_counter += 1
            self.round.start_new_round(self.game_pointer)

        state = self.get_state(self.game_pointer)

        return state, self.game_pointer

    def get_state(self, player_id):
        ''' Return player's state

        Args:
            player_id (int): player id

        Returns:
            (dict): The state of the player
        '''
        self.dealer.pot = np.sum([player.in_chips for player in self.players])

        chips = [self.players[i].in_chips for i in range(self.num_players)]
        legal_actions = self.get_legal_actions()
        state = self.players[player_id].get_state(self.public_cards, chips,
                                                  legal_actions)
        state['stakes'] = [
            self.players[i].remained_chips for i in range(self.num_players)
        ]
        state['current_player'] = self.game_pointer
        state['pot'] = self.dealer.pot
        state['stage'] = self.stage
        return state

    def step_back(self):
        ''' Return to the previous state of the game

        Returns:
            (bool): True if the game steps back successfully
        '''
        if len(self.history) > 0:
            self.round, self.game_pointer, self.round_counter, self.dealer, self.public_cards, self.players = self.history.pop(
            )
            return True
        return False

    def get_player_num(self):
        ''' Return the number of players in No Limit Texas Hold'em

        Returns:
            (int): The number of players in the game
        '''
        return self.num_players

    def get_payoffs(self):
        ''' Return the payoffs of the game

        Returns:
            (list): Each entry corresponds to the payoff of one player
        '''
        hands = [
            p.hand +
            self.public_cards if p.status in (PlayerStatus.ALIVE,
                                              PlayerStatus.ALLIN) else None
            for p in self.players
        ]
        chips_payoffs = self.judger.judge_game(self.players, hands)
        return chips_payoffs

    @staticmethod
    def get_action_num():
        ''' Return the number of applicable actions

        Returns:
            (int): The number of actions. There are 6 actions (call, raise_half_pot, raise_pot, all_in, check and fold)
        '''
        return len(Action)
Exemplo n.º 3
0
class NolimitholdemGame(Game):
    def __init__(self, allow_step_back=False, num_players=2):
        ''' Initialize the class nolimitholdem Game
        '''
        self.allow_step_back = allow_step_back
        self.np_random = np.random.RandomState()

        # small blind and big blind
        self.small_blind = 1
        self.big_blind = 2 * self.small_blind

        # config players
        self.num_players = num_players
        self.init_chips = 100

    def init_game(self):
        ''' Initialilze the game of Limit Texas Hold'em

        This version supports two-player limit texas hold'em

        Returns:
            (tuple): Tuple containing:

                (dict): The first state of the game
                (int): Current player's id
        '''
        # Initilize a dealer that can deal cards
        self.dealer = Dealer(self.np_random)

        # Initilize two players to play the game
        self.players = [
            Player(i, self.init_chips, self.np_random)
            for i in range(self.num_players)
        ]

        # Initialize a judger class which will decide who wins in the end
        self.judger = Judger(self.np_random)

        # Deal cards to each  player to prepare for the first round
        for i in range(2 * self.num_players):
            self.players[i % self.num_players].hand.append(
                self.dealer.deal_card())

        # Initilize public cards
        self.public_cards = []
        self.stage = Stage.PREFLOP

        # Randomly choose a big blind and a small blind
        s = self.np_random.randint(0, self.num_players)
        b = (s + 1) % self.num_players
        self.players[b].bet(chips=self.big_blind)
        self.players[s].bet(chips=self.small_blind)

        # The player next to the small blind plays the first
        self.game_pointer = (b + 1) % self.num_players

        # Initilize a bidding round, in the first round, the big blind and the small blind needs to
        # be passed to the round for processing.
        self.round = Round(self.num_players,
                           self.big_blind,
                           dealer=self.dealer,
                           np_random=self.np_random)

        self.round.start_new_round(game_pointer=self.game_pointer,
                                   raised=[p.in_chips for p in self.players])

        # Count the round. There are 4 rounds in each game.
        self.round_counter = 0

        # Save the hisory for stepping back to the last state.
        self.history = []
        self.action_history = []

        state = self.get_state(self.game_pointer)

        return state, self.game_pointer

    def get_legal_actions(self):
        ''' Return the legal actions for current player

        Returns:
            (list): A list of legal actions
        '''
        return self.round.get_nolimit_legal_actions(players=self.players)

    def step(self, action):
        ''' Get the next state

        Args:
            action (str): a specific action. (call, raise, fold, or check)

        Returns:
            (tuple): Tuple containing:

                (dict): next player's state
                (int): next plater's id
        '''

        if action not in self.get_legal_actions():
            print(action, self.get_legal_actions())
            print(self.get_state(self.game_pointer))
            raise Exception('Action not allowed')

        if self.allow_step_back:
            # First snapshot the current state
            r = deepcopy(self.round)
            b = self.game_pointer
            r_c = self.round_counter
            d = deepcopy(self.dealer)
            p = deepcopy(self.public_cards)
            ps = deepcopy(self.players)
            ac = deepcopy(self.action_history)
            self.history.append((r, b, r_c, d, p, ps, ac))

        # Then we proceed to the next round
        self.action_history.append(
            [self.game_pointer, self.round_counter, action])
        self.game_pointer = self.round.proceed_round(self.players, action)

        players_in_bypass = [
            1 if player.status in (PlayerStatus.FOLDED,
                                   PlayerStatus.ALLIN) else 0
            for player in self.players
        ]

        # If a round is over, we deal more public cards
        if self.round.is_over():
            # For the first round, we deal 3 cards
            if self.round_counter == 0:
                self.stage = Stage.FLOP
                self.public_cards.append(self.dealer.deal_card())
                self.public_cards.append(self.dealer.deal_card())
                self.public_cards.append(self.dealer.deal_card())
                if len(self.players) == np.sum(players_in_bypass):
                    self.round_counter += 1
                    self.stage = Stage.TURN
                    self.public_cards.append(self.dealer.deal_card())
                    self.round_counter += 1
                    self.stage = Stage.RIVER
                    self.public_cards.append(self.dealer.deal_card())
                    self.round_counter += 1
            # For the following rounds, we deal only 1 card
            elif self.round_counter == 1:
                self.stage = Stage.TURN
                self.public_cards.append(self.dealer.deal_card())
                if len(self.players) == np.sum(players_in_bypass):
                    self.round_counter += 1
                    self.stage = Stage.RIVER
                    self.public_cards.append(self.dealer.deal_card())
                    self.round_counter += 1
            elif self.round_counter == 2:
                self.stage = Stage.RIVER
                self.public_cards.append(self.dealer.deal_card())
                if len(self.players) == np.sum(players_in_bypass):
                    self.round_counter += 1

            self.round_counter += 1
            self.round.start_new_round(self.game_pointer)

        state = self.get_state(self.game_pointer)

        return state, self.game_pointer

    def get_state(self, player_id):
        ''' Return player's state

        Args:
            player_id (int): player id

        Returns:
            (dict): The state of the player
        '''
        self.dealer.pot = np.sum([player.in_chips for player in self.players])

        chips = [self.players[i].in_chips for i in range(self.num_players)]
        legal_actions = self.get_legal_actions()
        state = self.players[player_id].get_state(self.public_cards, chips,
                                                  legal_actions)

        state['to_call'] = min(
            max(chips) - self.players[player_id].in_chips,
            self.players[player_id].remained_chips
        ) / self.dealer.pot  # New - %pot to call
        state['to_allin'] = self.players[
            player_id].remained_chips / self.dealer.pot  # New - %pot to all-in. Not strictly true, since you might have the most chips. But fixable.

        players_still_in = []
        state['n_others'] = -1  # New - number of others that haven't folded.
        for i, p in enumerate(self.players):
            if p.status in (PlayerStatus.ALIVE, PlayerStatus.ALLIN):
                state['n_others'] += 1
                players_still_in.append(i)
        this_player_i = self.players.index(self.players[player_id])

        state['already_called'] = 0
        for p in self.players:
            if p.in_chips == max(chips):
                state['already_called'] += 1

        people_before = 0
        state['action_history'] = self.action_history

        for action in state['action_history']:
            if action[0] in players_still_in:
                people_before += 1
            if action[0] == player_id:
                break
        state['position'] = people_before / len(players_still_in)

        state['past_aggression'] = 0
        state['street_aggression'] = 0
        for action in state['action_history']:

            if action[0] in players_still_in and action[0] != player_id:
                if action[2] == Action.RAISE_HALF_POT:
                    aggro = 0.5
                elif action[2] == Action.RAISE_POT:
                    aggro = 1
                elif action[2] == Action.ALL_IN:
                    aggro = 2.5
                else:
                    aggro = 0
                if action[1] != self.round_counter:
                    state['past_aggression'] += aggro
                else:
                    state['street_aggression'] += aggro

        state['need_to_call'] = (state['n_others'] +
                                 1) - state['already_called']

        state['stakes'] = [
            self.players[i].remained_chips / self.dealer.pot
            for i in range(self.num_players)
        ]  # Edited: normalized to pot
        state['current_player'] = self.game_pointer
        state['pot'] = self.dealer.pot
        state['stage'] = self.stage
        return state

    def step_back(self):
        ''' Return to the previous state of the game

        Returns:
            (bool): True if the game steps back successfully
        '''
        if len(self.history) > 0:
            self.round, self.game_pointer, self.round_counter, self.dealer, self.public_cards, self.players, self.action_history = self.history.pop(
            )
            return True
        return False

    def get_payoffs(self):
        ''' Return the payoffs of the game

        Returns:
            (list): Each entry corresponds to the payoff of one player
        '''
        hands = [
            p.hand +
            self.public_cards if p.status in (PlayerStatus.ALIVE,
                                              PlayerStatus.ALLIN) else None
            for p in self.players
        ]
        chips_payoffs = self.judger.judge_game(self.players, hands)
        self.action_history = []
        return chips_payoffs

    @staticmethod
    def get_action_num():
        ''' Return the number of applicable actions

        Returns:
            (int): The number of actions. There are 6 actions (call, raise_half_pot, raise_pot, all_in, check and fold)
        '''
        return len(Action)