def test_is_suukantsu(self):
hand = FinishedHand()
tiles = self._string_to_34_array(sou='111333', man='222', pin='44555')
called_kan_indices = [
self._string_to_34_tile(sou='1'),
self._string_to_34_tile(sou='3'),
self._string_to_34_tile(pin='5'),
self._string_to_34_tile(man='2')
]
self.assertTrue(
hand.is_suukantsu(self._hand(tiles, 0), called_kan_indices))
tiles = self._string_to_136_array(sou='111333', man='222', pin='44555')
win_tile = self._string_to_136_tile(pin='4')
open_sets = [
self._string_to_open_34_set(sou='111'),
self._string_to_open_34_set(sou='333')
]
called_kan_indices = [
self._string_to_136_tile(sou='1'),
self._string_to_136_tile(sou='3'),
self._string_to_136_tile(pin='5'),
self._string_to_136_tile(man='2')
]
result = hand.estimate_hand_value(
tiles,
win_tile,
open_sets=open_sets,
called_kan_indices=called_kan_indices)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 13)
self.assertEqual(result['fu'], 80)
self.assertEqual(len(result['hand_yaku']), 1)
def test_is_kokushi(self):
hand = FinishedHand()
tiles = self._string_to_34_array(sou='119',
man='19',
pin='19',
honors='1234567')
self.assertTrue(hand.is_kokushi(tiles))
tiles = self._string_to_136_array(sou='119',
man='19',
pin='19',
honors='1234567')
win_tile = self._string_to_136_tile(sou='9')
result = hand.estimate_hand_value(tiles, win_tile)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 13)
self.assertEqual(result['fu'], 0)
self.assertEqual(len(result['hand_yaku']), 1)
tiles = self._string_to_136_array(sou='119',
man='19',
pin='19',
honors='1234567')
win_tile = self._string_to_136_tile(sou='1')
result = hand.estimate_hand_value(tiles, win_tile)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 26)
self.assertEqual(result['fu'], 0)
self.assertEqual(len(result['hand_yaku']), 1)
def __init__(self, clients):
self.tiles = []
self.dead_wall = []
self.dora_indicators = []
self.clients = clients
self._set_client_names()
self.agari = Agari()
self.finished_hand = FinishedHand()
def test_is_tenhou(self):
hand = FinishedHand()
tiles = self._string_to_136_array(sou='123444', man='234456', pin='66')
win_tile = self._string_to_136_tile(sou='4')
result = hand.estimate_hand_value(tiles, win_tile, is_tenhou=True)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 13)
self.assertEqual(result['fu'], 40)
self.assertEqual(len(result['hand_yaku']), 1)
def __init__(self, player):
super(MainAI, self).__init__(player)
self.agari = Agari()
self.shanten = Shanten()
self.defence = DefenceHandler(player)
self.hand_divider = HandDivider()
self.finished_hand = FinishedHand()
self.previous_shanten = 7
self.current_strategy = None
self.waiting = []
self.in_defence = False
def test_is_chinroto(self):
hand = FinishedHand()
tiles = self._string_to_34_array(sou='111999', man='111999', pin='99')
self.assertTrue(hand.is_chinroto(self._hand(tiles, 0)))
tiles = self._string_to_136_array(sou='111222', man='111999', pin='99')
win_tile = self._string_to_136_tile(pin='9')
result = hand.estimate_hand_value(tiles, win_tile)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 26)
self.assertEqual(result['fu'], 60)
self.assertEqual(len(result['hand_yaku']), 1)
def test_is_daisuushi(self):
hand = FinishedHand()
tiles = self._string_to_34_array(sou='22', honors='111222333444')
self.assertTrue(hand.is_daisuushi(self._hand(tiles, 0)))
tiles = self._string_to_136_array(sou='22', honors='111222333444')
win_tile = self._string_to_136_tile(honors='4')
result = hand.estimate_hand_value(tiles, win_tile)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 26)
self.assertEqual(result['fu'], 60)
self.assertEqual(len(result['hand_yaku']), 1)
def test_is_ryuisou(self):
hand = FinishedHand()
tiles = self._string_to_34_array(sou='22334466888', honors='666')
self.assertTrue(hand.is_ryuisou(self._hand(tiles, 0)))
tiles = self._string_to_136_array(sou='22334466888', honors='666')
win_tile = self._string_to_136_tile(honors='6')
result = hand.estimate_hand_value(tiles, win_tile)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 13)
self.assertEqual(result['fu'], 40)
self.assertEqual(len(result['hand_yaku']), 1)
def test_is_daisangen(self):
hand = FinishedHand()
tiles = self._string_to_34_array(sou='123',
man='22',
honors='555666777')
self.assertTrue(hand.is_daisangen(self._hand(tiles, 0)))
tiles = self._string_to_136_array(sou='123',
man='22',
honors='555666777')
win_tile = self._string_to_136_tile(honors='7')
result = hand.estimate_hand_value(tiles, win_tile)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 13)
self.assertEqual(result['fu'], 50)
self.assertEqual(len(result['hand_yaku']), 1)
def test_is_chuuren_poutou(self):
hand = FinishedHand()
tiles = self._string_to_34_array(man='11122345678999')
self.assertTrue(hand.is_chuuren_poutou(self._hand(tiles, 0)))
tiles = self._string_to_34_array(pin='11123345678999')
self.assertTrue(hand.is_chuuren_poutou(self._hand(tiles, 0)))
tiles = self._string_to_34_array(sou='11123456678999')
self.assertTrue(hand.is_chuuren_poutou(self._hand(tiles, 0)))
tiles = self._string_to_34_array(sou='11123456678999')
self.assertTrue(hand.is_chuuren_poutou(self._hand(tiles, 0)))
tiles = self._string_to_34_array(sou='11123456678999')
self.assertTrue(hand.is_chuuren_poutou(self._hand(tiles, 0)))
tiles = self._string_to_34_array(sou='11123456789999')
self.assertTrue(hand.is_chuuren_poutou(self._hand(tiles, 0)))
tiles = self._string_to_136_array(man='11123456789999')
win_tile = self._string_to_136_tile(man='1')
result = hand.estimate_hand_value(tiles, win_tile)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 13)
self.assertEqual(result['fu'], 40)
self.assertEqual(len(result['hand_yaku']), 1)
tiles = self._string_to_136_array(man='11122345678999')
win_tile = self._string_to_136_tile(man='2')
result = hand.estimate_hand_value(tiles, win_tile)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 26)
self.assertEqual(result['fu'], 50)
self.assertEqual(len(result['hand_yaku']), 1)
class CheckWaiting(object):
def __init__(self):
self.finished_hand = FinishedHand()
def check(self,
hand,
win_tile,
is_tsumo=False,
is_riichi=False,
is_dealer=False,
is_ippatsu=False,
is_rinshan=False,
is_chankan=False,
is_haitei=False,
is_houtei=False,
is_daburu_riichi=False,
is_nagashi_mangan=False,
is_tenhou=False,
is_renhou=False,
is_chiihou=False,
open_sets=None,
dora_indicators=None,
called_kan_indices=None,
player_wind=None,
round_wind=None):
result = self.finished_hand.estimate_hand_value(
hand,
win_tile,
is_tsumo=is_tsumo,
is_riichi=is_riichi,
is_dealer=is_dealer,
is_ippatsu=is_ippatsu,
is_rinshan=is_rinshan,
is_chankan=is_chankan,
is_haitei=is_haitei,
is_houtei=is_houtei,
is_daburu_riichi=is_daburu_riichi,
is_nagashi_mangan=is_nagashi_mangan,
is_tenhou=is_tenhou,
is_renhou=is_renhou,
is_chiihou=is_chiihou,
open_sets=open_sets,
dora_indicators=dora_indicators,
called_kan_indices=called_kan_indices,
player_wind=player_wind,
round_wind=round_wind)
return result
def test_is_suuankou(self):
hand = FinishedHand()
tiles = self._string_to_34_array(sou='111444', man='333', pin='44555')
win_tile = self._string_to_136_tile(sou='4')
self.assertTrue(hand.is_suuankou(win_tile, self._hand(tiles, 0), True))
self.assertFalse(
hand.is_suuankou(win_tile, self._hand(tiles, 0), False))
tiles = self._string_to_136_array(sou='111444', man='333', pin='44555')
win_tile = self._string_to_136_tile(pin='5')
result = hand.estimate_hand_value(tiles, win_tile, is_tsumo=True)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 13)
self.assertEqual(result['fu'], 50)
self.assertEqual(len(result['hand_yaku']), 1)
result = hand.estimate_hand_value(tiles, win_tile, is_tsumo=False)
self.assertNotEqual(result['han'], 13)
tiles = self._string_to_136_array(sou='111444', man='333', pin='44455')
win_tile = self._string_to_136_tile(pin='5')
result = hand.estimate_hand_value(tiles, win_tile, is_tsumo=True)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 26)
self.assertEqual(result['fu'], 50)
self.assertEqual(len(result['hand_yaku']), 1)
tiles = self._string_to_136_array(man='33344455577799')
win_tile = self._string_to_136_tile(man='9')
result = hand.estimate_hand_value(tiles, win_tile, is_tsumo=False)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 26)
self.assertEqual(result['fu'], 50)
self.assertEqual(len(result['hand_yaku']), 1)
def test_is_tsuisou(self):
hand = FinishedHand()
tiles = self._string_to_34_array(honors='11122233366677')
self.assertTrue(hand.is_tsuisou(self._hand(tiles, 0)))
tiles = self._string_to_34_array(honors='11223344556677')
self.assertTrue(hand.is_tsuisou(self._hand(tiles, 0)))
tiles = self._string_to_34_array(honors='1133445577',
pin='88',
sou='11')
self.assertFalse(hand.is_tsuisou(self._hand(tiles, 0)))
tiles = self._string_to_136_array(honors='11223344556677')
win_tile = self._string_to_136_tile(honors='7')
result = hand.estimate_hand_value(tiles, win_tile)
self.assertEqual(result['error'], None)
self.assertEqual(result['han'], 13)
self.assertEqual(result['fu'], 25)
self.assertEqual(len(result['hand_yaku']), 1)
def test_calculate_scores_and_ron(self):
hand = FinishedHand()
result = hand.calculate_scores(han=1,
fu=30,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 1000)
result = hand.calculate_scores(han=1,
fu=110,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 3600)
result = hand.calculate_scores(han=2,
fu=30,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 2000)
result = hand.calculate_scores(han=3,
fu=30,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 3900)
result = hand.calculate_scores(han=4,
fu=30,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 7700)
result = hand.calculate_scores(han=4,
fu=40,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 8000)
result = hand.calculate_scores(han=4,
fu=40,
is_tsumo=False,
is_dealer=True)
self.assertEqual(result['main'], 12000)
result = hand.calculate_scores(han=5,
fu=0,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 8000)
result = hand.calculate_scores(han=6,
fu=0,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 12000)
result = hand.calculate_scores(han=8,
fu=0,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 16000)
result = hand.calculate_scores(han=11,
fu=0,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 24000)
result = hand.calculate_scores(han=13,
fu=0,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 32000)
result = hand.calculate_scores(han=26,
fu=0,
is_tsumo=False,
is_dealer=False)
self.assertEqual(result['main'], 64000)
def test_calculate_scores_and_tsumo_by_dealer(self):
hand = FinishedHand()
result = hand.calculate_scores(han=1,
fu=30,
is_tsumo=True,
is_dealer=True)
self.assertEqual(result['main'], 500)
self.assertEqual(result['additional'], 500)
result = hand.calculate_scores(han=3,
fu=30,
is_tsumo=True,
is_dealer=True)
self.assertEqual(result['main'], 2000)
self.assertEqual(result['additional'], 2000)
result = hand.calculate_scores(han=4,
fu=30,
is_tsumo=True,
is_dealer=True)
self.assertEqual(result['main'], 3900)
self.assertEqual(result['additional'], 3900)
result = hand.calculate_scores(han=5,
fu=0,
is_tsumo=True,
is_dealer=True)
self.assertEqual(result['main'], 4000)
self.assertEqual(result['additional'], 4000)
result = hand.calculate_scores(han=6,
fu=0,
is_tsumo=True,
is_dealer=True)
self.assertEqual(result['main'], 6000)
self.assertEqual(result['additional'], 6000)
result = hand.calculate_scores(han=8,
fu=0,
is_tsumo=True,
is_dealer=True)
self.assertEqual(result['main'], 8000)
self.assertEqual(result['additional'], 8000)
result = hand.calculate_scores(han=11,
fu=0,
is_tsumo=True,
is_dealer=True)
self.assertEqual(result['main'], 12000)
self.assertEqual(result['additional'], 12000)
result = hand.calculate_scores(han=13,
fu=0,
is_tsumo=True,
is_dealer=True)
self.assertEqual(result['main'], 16000)
self.assertEqual(result['additional'], 16000)
result = hand.calculate_scores(han=26,
fu=0,
is_tsumo=True,
is_dealer=True)
self.assertEqual(result['main'], 32000)
self.assertEqual(result['additional'], 32000)
def __init__(self):
self.finished_hand = FinishedHand()
class GameManager(object):
"""
Allow to play bots between each other
To have a metrics how new version plays agains old versions
"""
tiles = []
dead_wall = []
clients = []
dora_indicators = []
dealer = None
current_client = None
round_number = 0
honba_sticks = 0
riichi_sticks = 0
_unique_dealers = 0
def __init__(self, clients):
self.tiles = []
self.dead_wall = []
self.dora_indicators = []
self.clients = clients
self._set_client_names()
self.agari = Agari()
self.finished_hand = FinishedHand()
def init_game(self):
"""
Initial of the game.
Clients random placement and dealer selection
"""
shuffle(self.clients, shuffle_seed)
for i in range(0, len(self.clients)):
self.clients[i].position = i
dealer = randint(0, 3)
self.set_dealer(dealer)
for client in self.clients:
client.player.scores = 25000
self._unique_dealers = 1
def init_round(self):
# each round should have personal seed
global seed_value
seed_value = random()
self.tiles = [i for i in range(0, 136)]
# need to change random function in future
shuffle(self.tiles, shuffle_seed)
self.dead_wall = self._cut_tiles(14)
self.dora_indicators.append(self.dead_wall[8])
for x in range(0, len(self.clients)):
client = self.clients[x]
# each client think that he is a player with position = 0
# so, we need to move dealer position for each client
# and shift scores array
client_dealer = self.dealer - x
player_scores = deque([i.player.scores / 100 for i in self.clients])
player_scores.rotate(x * -1)
player_scores = list(player_scores)
client.table.init_round(
self.round_number,
self.honba_sticks,
self.riichi_sticks,
self.dora_indicators[0],
client_dealer,
player_scores
)
# each player by rotation draw 4 tiles until they have 12
# after this each player draw one more tile
# and this is will be their initial hand
# we do it to make the tiles allocation in hands
# more random
for x in range(0, 3):
for client in self.clients:
client.player.tiles += self._cut_tiles(4)
for client in self.clients:
client.player.tiles += self._cut_tiles(1)
client.init_hand(client.player.tiles)
logger.info('Seed: {0}'.format(shuffle_seed()))
logger.info('Dealer: {0}'.format(self.dealer))
logger.info('Wind: {0}. Riichi sticks: {1}. Honba sticks: {2}'.format(
self._unique_dealers,
self.riichi_sticks,
self.honba_sticks
))
logger.info('Players: {0}'.format(self.players_sorted_by_scores()))
def play_round(self):
continue_to_play = True
while continue_to_play:
client = self._get_current_client()
in_tempai = client.player.in_tempai
tile = self._cut_tiles(1)[0]
# we don't need to add tile to the hand when we are in riichi
if client.player.in_riichi:
tiles = client.player.tiles + [tile]
else:
client.draw_tile(tile)
tiles = client.player.tiles
is_win = self.agari.is_agari(TilesConverter.to_34_array(tiles))
# win by tsumo after tile draw
if is_win:
result = self.process_the_end_of_the_round(tiles=client.player.tiles,
win_tile=tile,
winner=client,
loser=None,
is_tsumo=True)
return result
# if not in riichi, let's decide what tile to discard
if not client.player.in_riichi:
tile = client.discard_tile()
in_tempai = client.player.in_tempai
# after tile discard let's check all other players can they win or not
# at this tile
for other_client in self.clients:
# there is no need to check the current client
if other_client == client:
continue
# let's store other players discards
other_client.enemy_discard(other_client.position - client.position, tile)
# TODO support multiple ron
if self.can_call_ron(other_client, tile):
# the end of the round
result = self.process_the_end_of_the_round(tiles=other_client.player.tiles,
win_tile=tile,
winner=other_client,
loser=client,
is_tsumo=False)
return result
# if there is no challenger to ron, let's check can we call riichi with tile discard or not
if in_tempai and client.player.can_call_riichi():
self.call_riichi(client)
self.current_client = self._move_position(self.current_client)
# retake
if not len(self.tiles):
continue_to_play = False
result = self.process_the_end_of_the_round([], 0, None, None, False)
return result
def play_game(self, total_results):
"""
:param total_results: a dictionary with keys as client ids
:return: game results
"""
logger.info('The start of the game')
logger.info('')
is_game_end = False
self.init_game()
played_rounds = 0
while not is_game_end:
self.init_round()
result = self.play_round()
is_game_end = result['is_game_end']
loser = result['loser']
winner = result['winner']
if loser:
total_results[loser.id]['lose_rounds'] += 1
if winner:
total_results[winner.id]['win_rounds'] += 1
for client in self.clients:
if client.player.in_riichi:
total_results[client.id]['riichi_rounds'] += 1
played_rounds += 1
self.recalculate_players_position()
logger.info('Final Scores: {0}'.format(self.players_sorted_by_scores()))
logger.info('The end of the game')
return {'played_rounds': played_rounds}
def recalculate_players_position(self):
"""
For players with same count of scores we need
to set position based on their initial seat on the table
"""
temp_clients = sorted(self.clients, key=lambda x: x.player.scores, reverse=True)
for i in range(0, len(temp_clients)):
temp_client = temp_clients[i]
for client in self.clients:
if client.id == temp_client.id:
client.player.position = i + 1
def can_call_ron(self, client, win_tile):
if not client.player.in_tempai or not client.player.in_riichi:
return False
tiles = client.player.tiles
is_ron = self.agari.is_agari(TilesConverter.to_34_array(tiles + [win_tile]))
return is_ron
def call_riichi(self, client):
client.player.in_riichi = True
client.player.scores -= 1000
self.riichi_sticks += 1
who_called_riichi = client.position
for client in self.clients:
client.enemy_riichi(who_called_riichi - client.position)
logger.info('Riichi: {0} - 1,000'.format(client.player.name))
def set_dealer(self, dealer):
self.dealer = dealer
self._unique_dealers += 1
for x in range(0, len(self.clients)):
client = self.clients[x]
# each client think that he is a player with position = 0
# so, we need to move dealer position for each client
# and shift scores array
client.player.dealer_seat = dealer - x
# first move should be dealer's move
self.current_client = dealer
def process_the_end_of_the_round(self, tiles, win_tile, winner, loser, is_tsumo):
"""
Increment a round number and do a scores calculations
"""
if winner:
logger.info('{0}: {1} + {2}'.format(
is_tsumo and 'Tsumo' or 'Ron',
TilesConverter.to_one_line_string(tiles),
TilesConverter.to_one_line_string([win_tile])),
)
else:
logger.info('Retake')
is_game_end = False
self.round_number += 1
if winner:
hand_value = self.finished_hand.estimate_hand_value(tiles + [win_tile],
win_tile,
is_tsumo,
winner.player.in_riichi,
winner.player.is_dealer,
False)
if hand_value['cost']:
hand_value = hand_value['cost']['main']
else:
logger.error('Can\'t estimate a hand: {0}. Error: {1}'.format(
TilesConverter.to_one_line_string(tiles + [win_tile]),
hand_value['error']
))
hand_value = 1000
scores_to_pay = hand_value + self.honba_sticks * 300
riichi_bonus = self.riichi_sticks * 1000
self.riichi_sticks = 0
# if dealer won we need to increment honba sticks
if winner.player.is_dealer:
self.honba_sticks += 1
else:
self.honba_sticks = 0
new_dealer = self._move_position(self.dealer)
self.set_dealer(new_dealer)
# win by ron
if loser:
win_amount = scores_to_pay + riichi_bonus
winner.player.scores += win_amount
loser.player.scores -= scores_to_pay
logger.info('Win: {0} + {1:,d}'.format(winner.player.name, win_amount))
logger.info('Lose: {0} - {1:,d}'.format(loser.player.name, scores_to_pay))
# win by tsumo
else:
scores_to_pay /= 3
# will be changed when real hand calculation will be implemented
# round to nearest 100. 333 -> 300
scores_to_pay = 100 * round(float(scores_to_pay) / 100)
win_amount = scores_to_pay * 3 + riichi_bonus
winner.player.scores += win_amount
for client in self.clients:
if client != winner:
client.player.scores -= scores_to_pay
logger.info('Win: {0} + {1:,d}'.format(winner.player.name, win_amount))
# retake
else:
tempai_users = 0
for client in self.clients:
if client.player.in_tempai:
tempai_users += 1
if tempai_users == 0 or tempai_users == 4:
self.honba_sticks += 1
# no one in tempai, so deal should move
if tempai_users == 0:
new_dealer = self._move_position(self.dealer)
self.set_dealer(new_dealer)
else:
# 1 tempai user will get 3000
# 2 tempai users will get 1500 each
# 3 tempai users will get 1000 each
scores_to_pay = 3000 / tempai_users
for client in self.clients:
if client.player.in_tempai:
client.player.scores += scores_to_pay
logger.info('{0} + {1:,d}'.format(client.player.name, int(scores_to_pay)))
# dealer was tempai, we need to add honba stick
if client.player.is_dealer:
self.honba_sticks += 1
else:
client.player.scores -= 3000 / (4 - tempai_users)
# if someone has negative scores,
# we need to end the game
for client in self.clients:
if client.player.scores < 0:
is_game_end = True
# we have played all 8 winds, let's finish the game
if self._unique_dealers > 8:
is_game_end = True
logger.info('')
return {
'winner': winner,
'loser': loser,
'is_tsumo': is_tsumo,
'is_game_end': is_game_end
}
def players_sorted_by_scores(self):
return sorted([i.player for i in self.clients], key=lambda x: x.scores, reverse=True)
def _set_client_names(self):
"""
For better tests output
"""
names = ['Sato', 'Suzuki', 'Takahashi', 'Tanaka', 'Watanabe', 'Ito',
'Yamamoto', 'Nakamura', 'Kobayashi', 'Kato', 'Yoshida', 'Yamada']
for client in self.clients:
name = names[randint(0, len(names) - 1)]
names.remove(name)
from mahjong.myAI.SLCNNPlayer import SLCNNPlayer
print(isinstance(client.player.ai, SLCNNPlayer))
#if isinstance(client.player.ai, SLCNNPlayer):
# client.player.name = "Suu"
#else:
# client.player.name = name
def _get_current_client(self) -> Client:
return self.clients[self.current_client]
def _cut_tiles(self, count_of_tiles) -> []:
"""
Cut the tiles array
:param count_of_tiles: how much tiles to cut
:return: the array with specified count of tiles
"""
result = self.tiles[0:count_of_tiles]
self.tiles = self.tiles[count_of_tiles:len(self.tiles)]
return result
def _move_position(self, current_position):
"""
loop 0 -> 1 -> 2 -> 3 -> 0
"""
current_position += 1
if current_position > 3:
current_position = 0
return current_position
class MonteCarlo(object):
"""A simulator to run Monte Carlo simulation on Mahjong game
"""
decoder = TenhouDecoder()
agari = Agari()
finished_hand = FinishedHand()
hand_calculator = HandCalculator()
verbose = False
def __init__(self):
previous_ai = False
table = MCVisibleTable(previous_ai)
self.table = table
self.initialize()
# We load the classifiers and regressors here
self.clf_one_player = []
for n in range(34):
clf = pickle.load(
open(
abs_data_path +
"/train_model/trained_models/one_player_{}.sav".format(n),
"rb"))
self.clf_one_player.append(clf)
def initialize(self):
# Mahjong table is ready
# previous_ai = False
# table = MCVisibleTable(previous_ai)
# self.table = table
self.table.erase_state()
self.table.turn_number = [0, 0, 0, 0]
# Prepare a new deck of mahjong tiles
tiles = list(range(136))
# shuffle the tiles
random.shuffle(tiles)
# seperate dead wall and dora indicator
dead_wall = tiles[-14:]
dora_indicator = dead_wall[4] # random.choice(dead_wall)
self.table.dead_wall = dead_wall
# generate init hands for 4 players
tiles = tiles[0:-14]
hands = []
for n in range(4):
init_tiles = tiles[0:13]
hands.append(init_tiles)
tiles = tiles[13:]
self.table.remaining_tiles = tiles
# formulate the init message
dice1 = random.choice([1, 2, 3, 4, 5, 6])
dice2 = random.choice([1, 2, 3, 4, 5, 6])
dealer = (dice1 - 1 + dice2 - 1) % 4
message = "<INIT "
# TODO: You may need round number, number of combo sticks, and number of
# riichi sticks other than 0?
message += 'seed="{},{},{},{},{},{}" '.format(0, 0, 0, dice1 - 1,
dice2 - 1,
dora_indicator)
message += 'ten="250,250,250,250" '
message += 'oya="{}" '.format(dealer)
message += 'hai0="{}" '.format(",".join(str(t) for t in hands[0]))
message += 'hai1="{}" '.format(",".join(str(t) for t in hands[1]))
message += 'hai2="{}" '.format(",".join(str(t) for t in hands[2]))
message += 'hai3="{}"/>'.format(",".join(str(t) for t in hands[3]))
# once message is ready, we decoder the info and initialize the table
values = self.decoder.parse_initial_values(message)
self.table.init_round(
values['round_number'],
values['count_of_honba_sticks'],
values['count_of_riichi_sticks'],
values['dora_indicator'],
values['dealer'],
values['scores'],
)
# TODO: this part is unnecessary, since we have already the hands list
hands = [
[
int(x) for x in self.decoder.get_attribute_content(
message, 'hai0').split(',')
],
[
int(x) for x in self.decoder.get_attribute_content(
message, 'hai1').split(',')
],
[
int(x) for x in self.decoder.get_attribute_content(
message, 'hai2').split(',')
],
[
int(x) for x in self.decoder.get_attribute_content(
message, 'hai3').split(',')
],
]
# Initialize all players on the table
# TODO: ok, we always assume we are sitting at seat 0
self.player_position = 0
self.table.players[0].init_hand(hands[self.player_position])
self.table.players[1].init_hand(hands[(self.player_position + 1) % 4])
self.table.players[2].init_hand(hands[(self.player_position + 2) % 4])
self.table.players[3].init_hand(hands[(self.player_position + 3) % 4])
# main_player = self.table.player
# print(self.table.__str__())
# print('Players: {}'.format(self.table.get_players_sorted_by_scores()))
# print('Dealer: {}'.format(self.table.get_player(values['dealer'])))
# print('Round wind: {}'.format(DISPLAY_WINDS[self.table.round_wind]))
# print('Player wind: {}'.format(DISPLAY_WINDS[main_player.player_wind]))
# TODO: this part may not be necessary. Basically we need to erase the
# melds information since it is a new game.
# If we are using opponent_model, we need to reset the melds
# when a new game initiated. For other model, this function
# may not exist. [Joseph]
try:
self.table.player.ai.reset_melds()
except:
pass
def _check_win(self, player_hand, melds):
""" check the hand to see whether it's a win hand or not
:param player_hand: list of int (0-33), the player's hand tiles in 34 format
:return: True if win, else False.
"""
return self.agari.is_agari(player_hand, melds)
def check_win(self, p):
"""check win hand
:param p: int (0-3), player index
:return: True if win, False if not.
"""
player_hand = self.table.players[p].tiles
player_hand_34 = TilesConverter.to_34_array(player_hand)
melds = [meld.tiles for meld in self.table.players[p].melds
] # self.table.players[p].melds is [list of Meld()]
melds_34 = list(map(lambda lst: [l // 4 for l in lst], melds))
return self._check_win(player_hand_34, melds_34)
def _check_waiting(self, player_hand):
"""Check whether a player is waiting or not based on his hand
:param player_hand: list of elements in [0,133], the hand tiles of player
:return: True for waiting, False for not waiting
"""
# If we need one more tile to complete our hand, and this specific tile
# we want is known to be within the wall tiles, then the hand is waiting.
current_hand = TilesConverter.to_34_array(player_hand)
#winning_tiles = []
for n in range(34):
table_revealed_tiles_34 = self.table.revealed_tiles
if table_revealed_tiles_34[n] < 4:
completed_hand = current_hand[:]
completed_hand[n] += 1
can_be_waiting = self.agari.is_agari(completed_hand)
if can_be_waiting:
return True
#winning_tiles.append(n) # n is the winning tile we want
# If there exists winnint tiles, the player is waitinng
#if len(winning_tiles)>0:
# return True
return False
def check_waiting(self, p):
"""check whether the player `p` is waiting or not
:param p: int (0-3), player index
:return: True for waiting, False for not waiting
"""
player_hand = self.table.players[p].tiles
return self._check_waiting(player_hand)
def discard_tile(self, p):
"""choose a tile to discard based on hand tiles of player `p`
:param p: int(0-3), player index
:return: int(0-135), tile to discard
"""
tiles = self.table.players[p].tiles
closed_hand = self.table.players[p].closed_hand
open_sets_34 = self.table.players[p].open_hand_34_tiles
table_revealed_tiles_34 = self.table.revealed_tiles
discarded_tile = self.table.players[p].ai.discard_tile(
tiles, closed_hand, open_sets_34, table_revealed_tiles_34)
return discarded_tile
def call_meld(self, type, who, from_who, opened, tiles, called_tile):
meld = Meld()
meld.type = type
meld.who = who
meld.from_who = from_who
meld.opened = opened
meld.tiles = tiles
meld.called_tile = called_tile
return meld
def sim_WPET(self):
"""Simulation of a riichi mahjong game, and record the bw and r parameters
"""
# We don't need to fix the seed now.
#seed = random.randint(1,100000)
#seed = 73823
#random.seed(seed)
bw_riichi = 0
bw_stealing = 0
r = 0
# start a new game
self.initialize()
# rinshan
rinshan = self.table.dead_wall[0:4]
# start from dealer
p = self.table.dealer_seat
#logger.info("seed: %d"%seed)
logger.info("dealer seat: %d" % p)
# Fixed: self.table.count_of_remaining_tiles>0 may not be accurate here
while self.table.count_of_remaining_tiles > 0: #len(self.table.remaining_tiles)>0:
# our perspective of view is from the program's turn
if p == 0:
r += 1
if self.check_waiting(0):
# TODO: Why don't we use in_riichi here?
if self.table.players[0].is_open_hand:
bw_stealing = 1
else:
bw_riichi = 1
break
logger.debug("[begin]:%s,%s" %
(self.table.count_of_remaining_tiles,
len(self.table.remaining_tiles)))
# p draw a tile
drawn_tile = self.table.remaining_tiles[0]
self.table.players[p].draw_tile(drawn_tile)
# check p win
if self.check_win(p):
logger.info("player {} wins (tsumo)!".format(p))
break
# TODO: we only apply discard_tile strategy to our program, for the
# opponent players, we assume they simply discard what they draw
# if not win, we do the followings
if True: #p==0:
if not self.table.players[p].in_riichi:
# choose a discard tile for playe `p`
discarded_tile = self.discard_tile(p)
# see if we can call riichi
if self.table.players[p].can_call_riichi():
logger.debug("player {} call riichi.".format(p))
self.table.players[p].in_riichi = True
else: # if riichi, we have to discard whatever we draw
discarded_tile = drawn_tile
else:
discarded_tile = drawn_tile
# remove the tile from player's hand
discarded_tile_tmp = discarded_tile
drawn_tile_tmp = drawn_tile
is_tsumogiri = (discarded_tile == drawn_tile)
self.table.players[p].tiles.remove(discarded_tile)
logger.debug("player {} discards {}".format(p, discarded_tile))
logger.debug("\tclosed hand: %s" %
self.table.players[0].closed_hand)
logger.debug("\topen hand: %s" %
self.table.players[0].open_hand_34_tiles)
logger.debug("\tmeld tiles: %s" % self.table.players[0].meld_tiles)
# now we check call meld
# TODO: Ok, here we only allow our program to call meld. But maybe
# we should allow the opponents to call meld too?
if p != 0:
previous_drawn_tile = drawn_tile
tile = discarded_tile
is_kamicha_discard = (p == 3)
meld, discard_option = self.table.players[0].try_to_call_meld(
tile, is_kamicha_discard)
kan_type = self.table.players[0].can_call_kan(tile, True)
if kan_type: # kan or chankan
tiles = [(tile // 4) * 4, (tile // 4) * 4 + 1,
(tile // 4) * 4 + 2, (tile // 4) * 4 + 3]
meld = self.call_meld(kan_type, 0, p, True, tiles, tile)
logger.debug("player 0 call kan from %d: %s" % (p, meld))
player_seat = meld.who
self.table.add_called_meld(player_seat, meld)
# we had to delete called tile from hand
# to have correct tiles count in the hand
# TODO[joseph]: I still don't know why we need this
# if meld type is: chi, pon, or nuki
# maybe no use here, b/c the meld type is always Meld.KAN here
if meld.type != Meld.KAN and meld.type != Meld.CHANKAN:
self.table.players[player_seat].draw_tile(
meld.called_tile)
# draw a tile from dead wall
if len(rinshan) > 0:
drawn_tile = rinshan.pop(0)
self.table.players[0].draw_tile(drawn_tile)
# check p win
if self.check_win(0):
logger.info(
"player {} wins (rinshan tsumo)!".format(0))
break
# if not win, we do the followings
if not self.table.players[0].in_riichi:
# choose a discard tile for playe `p`
discarded_tile = self.discard_tile(0)
# see if we can call riichi
if self.table.players[0].can_call_riichi():
logger.info("player {} call riichi.".format(0))
self.table.players[0].in_riichi = True
else: # if riichi, we have to discard whatever we draw
discarded_tile = drawn_tile
# remove the tile from player's hand
self.table.players[0].tiles.remove(discarded_tile)
logger.debug("player {} discards {} after kan".format(
0, discarded_tile))
logger.debug("\tclosed hand: %s" %
self.table.players[0].closed_hand)
logger.debug("\topen hand: %s" %
self.table.players[0].open_hand_34_tiles)
logger.debug("\tmeld tiles: %s" %
self.table.players[0].meld_tiles)
# we had to add it to discards, to calculate remaining tiles correctly
# drawn tile is not the one drawn from rinshan, but
# the one previously discarded by player `p`
self.table.add_discarded_tile(0, discarded_tile, True,
previous_drawn_tile)
# after program discarding a card, next player is 1
p = 1
continue
else: # ryuukyoku
logger.debug("Rinshan empty. Ryuukyoku!")
break
elif meld: # pon, chi
logger.debug("player 0 %s from %d: %s" %
(meld.type, p, meld))
player_seat = 0
# DEBUG: we change the add_called_meld method, delete the
# part that changes self.table.count_of_remaining_tiles
self.table.add_called_meld(player_seat, meld)
# Equivalently, program draws the tile discarded by opponent
self.table.players[0].draw_tile(tile)
# check p win
if self.check_win(0):
logger.info("player {} wins (by {})!".format(
0, meld.type))
break
# if not win, we do the followings
if not self.table.players[0].in_riichi:
# choose a discard tile for playe `p`
discarded_tile = self.discard_tile(0)
# see if we can call riichi
if self.table.players[0].can_call_riichi():
logger.debug("player {} call riichi.".format(0))
self.table.players[0].in_riichi = True
else: # if riichi, we can not call meld
raise ("Riichi player can not call meld!")
# remove the tile from player's hand
self.table.players[0].tiles.remove(discarded_tile)
# discarded tile added to table
self.table.add_discarded_tile(0, discarded_tile, True,
previous_drawn_tile)
logger.debug("player {} discards {} after {}".format(
0, discarded_tile, meld.type))
logger.debug("\tclosed hand: %s" %
self.table.players[0].closed_hand)
logger.debug("\topen hand: %s" %
self.table.players[0].open_hand_34_tiles)
logger.debug("\tmeld tiles: %s" %
self.table.players[0].meld_tiles)
# after program discarding a card, next player is 1
p = 1
continue
# we had to add it to discards, to calculate remaining tiles correctly
self.table.add_discarded_tile(p, discarded_tile_tmp, is_tsumogiri,
drawn_tile_tmp)
# next player
p = (p + 1) % 4
logger.debug("[after]:%s,%s" %
(self.table.count_of_remaining_tiles,
len(self.table.remaining_tiles)))
# output results
logger.debug('\n')
for p in range(4):
logger.info("\tPlayer %d: %s (%s)" %
(p,
TilesConverter.to_one_line_string(
self.table.players[p].tiles),
TilesConverter.to_one_line_string(
self.table.players[p].closed_hand)))
return bw_riichi, bw_stealing, r
def get_WPET(self, Nsim):
"""Waiting probability at Each Turn
"""
R = [0] * 19
BW_riichi = [0] * 19
BW_stealing = [0] * 19
n = 0
while n < Nsim:
bw_riichi, bw_stealing, r = self.sim_WPET()
print("%d. bw_riichi=%s, bw_stealing=%s, r=%s" %
(n + 1, bw_riichi, bw_stealing, r))
for m in range(r + 1): # from 0 to r
R[m] += 1
BW_riichi[r] += bw_riichi
BW_stealing[r] += bw_stealing
n += 1
Wpet_riichi = [
BW_riichi[n] * 1.0 / R[n] for n in range(len(BW_riichi))
]
Wpet_stealing = [
BW_stealing[n] * 1.0 / R[n] for n in range(len(BW_stealing))
]
return BW_riichi, BW_stealing, R, Wpet_riichi, Wpet_stealing
def sim_game(self):
"""Simulation of a riichi mahjong game, and record the bw and r parameters
"""
# We don't need to fix the seed now.
#seed = random.randint(1,100000)
#seed = 73823
#random.seed(seed)
# start a new game
self.initialize()
# rinshan
rinshan = self.table.dead_wall[0:4]
# start from dealer
p = self.table.dealer_seat
#logger.info("seed: %d"%seed)
logger.info("dealer seat: %d" % p)
# Fixed: self.table.count_of_remaining_tiles>0 may not be accurate here
while self.table.count_of_remaining_tiles > 0: #len(self.table.remaining_tiles)>0:
logger.debug("[begin]:%s,%s" %
(self.table.count_of_remaining_tiles,
len(self.table.remaining_tiles)))
# update turn number
self.table.turn_number[p] += 1
# p draw a tile
drawn_tile = self.table.remaining_tiles[0]
self.table.players[p].draw_tile(drawn_tile)
# check p win
if self.check_win(p):
logger.info("player {} wins (tsumo)!".format(p))
tiles = self.table.players[p].tiles
win_tile = drawn_tile
(is_tsumo, is_riichi, is_dealer, open_sets, dora_indicators,
player_wind, round_wind) = self.check_status(p)
## TODO: Wait to be finished!
result = self.finished_hand.estimate_hand_value(
tiles,
win_tile,
is_tsumo=is_tsumo,
is_riichi=is_riichi,
is_dealer=is_dealer,
is_ippatsu=False,
is_rinshan=False,
is_chankan=False,
is_haitei=False,
is_houtei=False,
is_daburu_riichi=False,
is_nagashi_mangan=False,
is_tenhou=False,
is_renhou=False,
is_chiihou=False,
open_sets=open_sets,
dora_indicators=dora_indicators,
called_kan_indices=None,
player_wind=player_wind,
round_wind=round_wind)
logger.info(result)
melds = self.table.players[p].melds
result = self.hand_calculator.estimate_hand_value(
tiles,
win_tile,
melds=melds,
dora_indicators=dora_indicators,
config=HandConfig(is_tsumo=is_tsumo,
is_riichi=is_riichi,
player_wind=player_wind,
round_wind=round_wind))
logger.info(result)
break
# TODO: we only apply discard_tile strategy to our program, for the
# opponent players, we assume they simply discard what they draw
# if not win, we do the followings
if True: #p==0:
if not self.table.players[p].in_riichi:
# choose a discard tile for playe `p`
discarded_tile = self.discard_tile(p)
# see if we can call riichi
if self.table.players[p].can_call_riichi():
logger.debug("player {} call riichi.".format(p))
self.table.players[p].in_riichi = True
else: # if riichi, we have to discard whatever we draw
discarded_tile = drawn_tile
else:
discarded_tile = drawn_tile
# remove the tile from player's hand
discarded_tile_tmp = discarded_tile
drawn_tile_tmp = drawn_tile
is_tsumogiri = (discarded_tile == drawn_tile)
self.table.players[p].tiles.remove(discarded_tile)
logger.debug("player {} discards {}".format(p, discarded_tile))
logger.debug("\tclosed hand: %s" %
self.table.players[0].closed_hand)
logger.debug("\topen hand: %s" %
self.table.players[0].open_hand_34_tiles)
logger.debug("\tmeld tiles: %s" % self.table.players[0].meld_tiles)
# now we check call meld
# TODO: Ok, here we only allow our program to call meld. But maybe
# we should allow the opponents to call meld too?
if p != 0:
previous_drawn_tile = drawn_tile
tile = discarded_tile
is_kamicha_discard = (p == 3)
meld, discard_option = self.table.players[0].try_to_call_meld(
tile, is_kamicha_discard)
kan_type = self.table.players[0].can_call_kan(tile, True)
if kan_type: # kan or chankan
tiles = [(tile // 4) * 4, (tile // 4) * 4 + 1,
(tile // 4) * 4 + 2, (tile // 4) * 4 + 3]
meld = self.call_meld(kan_type, 0, p, True, tiles, tile)
logger.debug("player 0 call kan from %d: %s" % (p, meld))
player_seat = meld.who
self.table.add_called_meld(player_seat, meld)
# we had to delete called tile from hand
# to have correct tiles count in the hand
# TODO[joseph]: I still don't know why we need this
# if meld type is: chi, pon, or nuki
# maybe no use here, b/c the meld type is always Meld.KAN here
if meld.type != Meld.KAN and meld.type != Meld.CHANKAN:
self.table.players[player_seat].draw_tile(
meld.called_tile)
# draw a tile from dead wall
if len(rinshan) > 0:
drawn_tile = rinshan.pop(0)
self.table.players[0].draw_tile(drawn_tile)
# check p win
if self.check_win(0):
logger.info(
"player {} wins (rinshan tsumo)!".format(0))
tiles = self.table.players[p].tiles
win_tile = drawn_tile
(is_tsumo, is_riichi, is_dealer, open_sets,
dora_indicators, player_wind,
round_wind) = self.check_status(p)
is_rinshan = True
## TODO: Wait to be finished!
result = self.finished_hand.estimate_hand_value(
tiles,
win_tile,
is_tsumo=is_tsumo,
is_riichi=is_riichi,
is_dealer=is_dealer,
is_ippatsu=False,
is_rinshan=is_rinshan,
is_chankan=False,
is_haitei=False,
is_houtei=False,
is_daburu_riichi=False,
is_nagashi_mangan=False,
is_tenhou=False,
is_renhou=False,
is_chiihou=False,
open_sets=open_sets,
dora_indicators=dora_indicators,
called_kan_indices=None,
player_wind=player_wind,
round_wind=round_wind)
logger.info(result)
melds = self.table.players[p].melds
result = self.hand_calculator.estimate_hand_value(
tiles,
win_tile,
melds=melds,
dora_indicators=dora_indicators,
config=HandConfig(is_tsumo=is_tsumo,
is_riichi=is_riichi,
player_wind=player_wind,
round_wind=round_wind,
is_rinshan=is_rinshan))
logger.info(result)
break
# if not win, we do the followings
if not self.table.players[0].in_riichi:
# choose a discard tile for playe `p`
discarded_tile = self.discard_tile(0)
# see if we can call riichi
if self.table.players[0].can_call_riichi():
logger.info("player {} call riichi.".format(0))
self.table.players[0].in_riichi = True
else: # if riichi, we have to discard whatever we draw
discarded_tile = drawn_tile
# remove the tile from player's hand
self.table.players[0].tiles.remove(discarded_tile)
logger.debug("player {} discards {} after kan".format(
0, discarded_tile))
logger.debug("\tclosed hand: %s" %
self.table.players[0].closed_hand)
logger.debug("\topen hand: %s" %
self.table.players[0].open_hand_34_tiles)
logger.debug("\tmeld tiles: %s" %
self.table.players[0].meld_tiles)
# we had to add it to discards, to calculate remaining tiles correctly
# drawn tile is not the one drawn from rinshan, but
# the one previously discarded by player `p`
self.table.add_discarded_tile(0, discarded_tile, True,
previous_drawn_tile)
# after program discarding a card, next player is 1
p = 1
continue
else: # ryuukyoku
logger.debug("Rinshan empty. Ryuukyoku!")
break
elif meld: # pon, chi
logger.debug("player 0 %s from %d: %s" %
(meld.type, p, meld))
player_seat = 0
# DEBUG: we change the add_called_meld method, delete the
# part that changes self.table.count_of_remaining_tiles
self.table.add_called_meld(player_seat, meld)
# Equivalently, program draws the tile discarded by opponent
self.table.players[0].draw_tile(tile)
# check p win
if self.check_win(0):
logger.info("player {} wins (by {})!".format(
0, meld.type))
tiles = self.table.players[p].tiles
win_tile = tile
(is_tsumo, is_riichi, is_dealer, open_sets,
dora_indicators, player_wind,
round_wind) = self.check_status(p)
## TODO: Wait to be finished!
result = self.finished_hand.estimate_hand_value(
tiles,
win_tile,
is_tsumo=is_tsumo,
is_riichi=is_riichi,
is_dealer=is_dealer,
is_ippatsu=False,
is_rinshan=False,
is_chankan=False,
is_haitei=False,
is_houtei=False,
is_daburu_riichi=False,
is_nagashi_mangan=False,
is_tenhou=False,
is_renhou=False,
is_chiihou=False,
open_sets=open_sets,
dora_indicators=dora_indicators,
called_kan_indices=None,
player_wind=player_wind,
round_wind=round_wind)
logger.info(result)
melds = self.table.players[p].melds
result = self.hand_calculator.estimate_hand_value(
tiles,
win_tile,
melds=melds,
dora_indicators=dora_indicators,
config=HandConfig(is_tsumo=is_tsumo,
is_riichi=is_riichi,
player_wind=player_wind,
round_wind=round_wind))
logger.info(result)
break
# if not win, we do the followings
if not self.table.players[0].in_riichi:
# choose a discard tile for playe `p`
discarded_tile = self.discard_tile(0)
# see if we can call riichi
if self.table.players[0].can_call_riichi():
logger.debug("player {} call riichi.".format(0))
self.table.players[0].in_riichi = True
else: # if riichi, we can not call meld
raise ("Riichi player can not call meld!")
# remove the tile from player's hand
self.table.players[0].tiles.remove(discarded_tile)
# discarded tile added to table
self.table.add_discarded_tile(0, discarded_tile, True,
previous_drawn_tile)
logger.debug("player {} discards {} after {}".format(
0, discarded_tile, meld.type))
logger.debug("\tclosed hand: %s" %
self.table.players[0].closed_hand)
logger.debug("\topen hand: %s" %
self.table.players[0].open_hand_34_tiles)
logger.debug("\tmeld tiles: %s" %
self.table.players[0].meld_tiles)
# after program discarding a card, next player is 1
p = 1
continue
# we had to add it to discards, to calculate remaining tiles correctly
self.table.add_discarded_tile(p, discarded_tile_tmp, is_tsumogiri,
drawn_tile_tmp)
# next player
p = (p + 1) % 4
logger.debug("[after]:%s,%s" %
(self.table.count_of_remaining_tiles,
len(self.table.remaining_tiles)))
# output results
logger.debug('\n')
for p in range(4):
logger.info("\tPlayer %d: %s (%s)" %
(p,
TilesConverter.to_one_line_string(
self.table.players[p].tiles),
TilesConverter.to_one_line_string(
self.table.players[p].closed_hand)))
## TODO: finish this part!
def check_status(self, p, is_tsumo=False):
""" We want to check the status of player `p`
:param is_tsumo:
:param is_riichi:
:param is_dealer:
:param is_ippatsu:
:param is_rinshan:
:param is_chankan:
:param is_haitei:
:param is_houtei:
:param is_tenhou:
:param is_renhou:
:param is_chiihou:
:param is_daburu_riichi:
:param is_nagashi_mangan:
:param open_sets: array of array with open sets in 34-tile format
:param dora_indicators: array of tiles in 136-tile format
:param called_kan_indices: array of tiles in 136-tile format
:param player_wind: index of player wind
:param round_wind: index of round wind
"""
is_tsumo = is_tsumo
is_riichi = self.table.players[p].in_riichi
is_dealer = (self.table.dealer_seat == p)
open_sets = [
meld.tiles for meld in self.table.players[p].melds
if meld.opened == True
]
open_sets = list(map(lambda lst: [l // 4 for l in lst],
open_sets)) # convert to 34 format
dora_indicators = self.table.dora_indicators
player_wind = self.table.players[p].player_wind
round_wind = self.table.round_wind
return (is_tsumo, is_riichi, is_dealer, open_sets, dora_indicators,
player_wind, round_wind)
def _check2(self):
self.sim_game()
def _check(self):
BW_riichi, BW_stealing, R, Wpet_riichi, Wpet_stealing = self.get_WPET(
500)
print("BW riichi: %s" % BW_riichi)
print("BW stealing: %s" % BW_stealing)
print("R: %s" % R)
print("WPET riichi: %s" % Wpet_riichi)
print("WPET stealing: %s" % Wpet_stealing)
import matplotlib.pyplot as plt
plt.plot(range(19), Wpet_riichi, '*-r', range(19), Wpet_stealing,
'o-b')
def test_calculate_scores_and_ron_by_dealer(self):
hand = FinishedHand()
result = hand.calculate_scores(han=1,
fu=30,
is_tsumo=False,
is_dealer=True)
self.assertEqual(result['main'], 1500)
result = hand.calculate_scores(han=2,
fu=30,
is_tsumo=False,
is_dealer=True)
self.assertEqual(result['main'], 2900)
result = hand.calculate_scores(han=3,
fu=30,
is_tsumo=False,
is_dealer=True)
self.assertEqual(result['main'], 5800)
result = hand.calculate_scores(han=4,
fu=30,
is_tsumo=False,
is_dealer=True)
self.assertEqual(result['main'], 11600)
result = hand.calculate_scores(han=5,
fu=0,
is_tsumo=False,
is_dealer=True)
self.assertEqual(result['main'], 12000)
result = hand.calculate_scores(han=6,
fu=0,
is_tsumo=False,
is_dealer=True)
self.assertEqual(result['main'], 18000)
result = hand.calculate_scores(han=8,
fu=0,
is_tsumo=False,
is_dealer=True)
self.assertEqual(result['main'], 24000)
result = hand.calculate_scores(han=11,
fu=0,
is_tsumo=False,
is_dealer=True)
self.assertEqual(result['main'], 36000)
result = hand.calculate_scores(han=13,
fu=0,
is_tsumo=False,
is_dealer=True)
self.assertEqual(result['main'], 48000)
result = hand.calculate_scores(han=26,
fu=0,
is_tsumo=False,
is_dealer=True)
self.assertEqual(result['main'], 96000)
def parse_log(self, log_data, log_id):
decoder = TenhouDecoder()
finished_hand = FinishedHand()
soup = BeautifulSoup(log_data, 'html.parser')
elements = soup.find_all()
settings.FIVE_REDS = True
settings.OPEN_TANYAO = True
total_hand = 0
successful_hand = 0
played_rounds = 0
dealer = 0
round_wind = EAST
for tag in elements:
if tag.name == 'go':
game_rule_temp = int(tag.attrs['type'])
# let's skip hirosima games
hirosima = [177, 185, 241, 249]
if game_rule_temp in hirosima:
print('0,0')
return
# one round games
skip_games = [2113]
if game_rule_temp in skip_games:
print('0,0')
return
no_red_five = [163, 167, 171, 175]
if game_rule_temp in no_red_five:
settings.FIVE_REDS = False
no_open_tanyao = [167, 175]
if game_rule_temp in no_open_tanyao:
settings.OPEN_TANYAO = False
if tag.name == 'taikyoku':
dealer = int(tag.attrs['oya'])
if tag.name == 'init':
dealer = int(tag.attrs['oya'])
seed = [int(i) for i in tag.attrs['seed'].split(',')]
round_number = seed[0]
if round_number < 4:
round_wind = EAST
elif 4 <= round_number < 8:
round_wind = SOUTH
elif 8 <= round_number < 12:
round_wind = WEST
else:
round_wind = NORTH
played_rounds += 1
if tag.name == 'agari':
success = True
winner = int(tag.attrs['who'])
from_who = int(tag.attrs['fromwho'])
closed_hand = [int(i) for i in tag.attrs['hai'].split(',')]
ten = [int(i) for i in tag.attrs['ten'].split(',')]
dora_indicators = [
int(i) for i in tag.attrs['dorahai'].split(',')
]
if 'dorahaiura' in tag.attrs:
dora_indicators += [
int(i) for i in tag.attrs['dorahaiura'].split(',')
]
yaku_list = []
yakuman_list = []
if 'yaku' in tag.attrs:
yaku_temp = [int(i) for i in tag.attrs['yaku'].split(',')]
yaku_list = yaku_temp[::2]
han = sum(yaku_temp[1::2])
else:
yakuman_list = [
int(i) for i in tag.attrs['yakuman'].split(',')
]
han = len(yakuman_list) * 13
fu = ten[0]
cost = ten[1]
melds = []
called_kan_indices = []
if 'm' in tag.attrs:
for x in tag.attrs['m'].split(','):
#message = '<N who={} m={}>'.format(tag.attrs['who'], x)
# Modified[joseph]: added quotes to the params
message = '<N who="{}" m="{}">'.format(
tag.attrs['who'], x)
meld = decoder.parse_meld(message)
tiles = meld.tiles
if len(tiles) == 4:
called_kan_indices.append(tiles[0])
tiles = tiles[1:4]
# closed kan
if meld.from_who == 0:
closed_hand.extend(tiles)
else:
melds.append(tiles)
# Modified[joseph]: We need to turn tile in 136 format to 34 format here
melds34 = []
for mld in melds:
mld34 = [tile_136_to_34(m) for m in mld]
melds34.append(mld34)
hand = closed_hand
if melds:
hand += reduce(lambda z, y: z + y, melds)
win_tile = int(tag.attrs['machi'])
is_tsumo = winner == from_who
is_riichi = 1 in yaku_list
is_ippatsu = 2 in yaku_list
is_chankan = 3 in yaku_list
is_rinshan = 4 in yaku_list
is_haitei = 5 in yaku_list
is_houtei = 6 in yaku_list
is_daburu_riichi = 21 in yaku_list
is_dealer = winner == dealer
is_renhou = 36 in yakuman_list
is_tenhou = 37 in yakuman_list
is_chiihou = 38 in yakuman_list
dif = winner - dealer
winds = [EAST, SOUTH, WEST, NORTH]
player_wind = winds[dif]
result = finished_hand.estimate_hand_value(
hand,
win_tile,
is_tsumo=is_tsumo,
is_riichi=is_riichi,
is_dealer=is_dealer,
is_ippatsu=is_ippatsu,
is_rinshan=is_rinshan,
is_chankan=is_chankan,
is_haitei=is_haitei,
is_houtei=is_houtei,
is_daburu_riichi=is_daburu_riichi,
is_tenhou=is_tenhou,
is_renhou=is_renhou,
is_chiihou=is_chiihou,
round_wind=round_wind,
player_wind=player_wind,
called_kan_indices=called_kan_indices,
open_sets=melds34, # melds, we use tile in 34 format
dora_indicators=dora_indicators)
if result['error']:
logger.error('Error with hand calculation: {}'.format(
result['error']))
calculated_cost = 0
success = False
else:
calculated_cost = result['cost'][
'main'] + result['cost']['additional'] * 2
if success:
if result['fu'] != fu:
logger.error('Wrong fu: {} != {}'.format(
result['fu'], fu))
success = False
if result['han'] != han:
logger.error('Wrong han: {} != {}'.format(
result['han'], han))
success = False
if cost != calculated_cost:
logger.error('Wrong cost: {} != {}'.format(
cost, calculated_cost))
success = False
if not success:
logger.error('http://e.mjv.jp/0/log/?{}'.format(log_id))
logger.error(
'http://tenhou.net/0/?log={}&tw={}&ts={}'.format(
log_id, winner, played_rounds - 1))
logger.error('Winner: {}, Dealer: {}'.format(
winner, dealer))
logger.error('Hand: {}'.format(
TilesConverter.to_one_line_string(hand)))
logger.error('Win tile: {}'.format(
TilesConverter.to_one_line_string([win_tile])))
logger.error('Open sets: {}'.format(melds))
logger.error('Called kans: {}'.format(
TilesConverter.to_one_line_string(called_kan_indices)))
logger.error('Our results: {}'.format(result))
logger.error('Tenhou results: {}'.format(tag.attrs))
logger.error('Dora: {}'.format(
TilesConverter.to_one_line_string(dora_indicators)))
logger.error('')
else:
successful_hand += 1
print('Our results: {}'.format(result))
print("\t* dealer:{}, winner:{}, is_dealer:{}".format(
dealer, winner, is_dealer))
print("\t* Calculated cost: {}".format(calculated_cost))
print('Tenhou results: {}'.format(tag.attrs))
print("-----------------------------------\n")
total_hand += 1
print('{},{}'.format(successful_hand, total_hand))
class MainAI(BaseAI):
version = '0.2.7'
agari = None
shanten = None
defence = None
hand_divider = None
finished_hand = None
previous_shanten = 7
in_defence = False
waiting = None
current_strategy = None
def __init__(self, player):
super(MainAI, self).__init__(player)
self.agari = Agari()
self.shanten = Shanten()
self.defence = DefenceHandler(player)
self.hand_divider = HandDivider()
self.finished_hand = FinishedHand()
self.previous_shanten = 7
self.current_strategy = None
self.waiting = []
self.in_defence = False
def erase_state(self):
self.current_strategy = None
self.in_defence = False
def discard_tile(self):
results, shanten = self.calculate_outs(self.player.tiles,
self.player.closed_hand,
self.player.open_hand_34_tiles)
selected_tile = self.process_discard_options_and_select_tile_to_discard(
results, shanten)
# bot think that there is a threat on the table
# and better to fold
# if we can't find safe tiles, let's continue to build our hand
if self.defence.should_go_to_defence_mode(selected_tile):
if not self.in_defence:
logger.info('We decided to fold against other players')
self.in_defence = True
defence_tile = self.defence.try_to_find_safe_tile_to_discard(
results)
if defence_tile:
return self.process_discard_option(defence_tile,
self.player.closed_hand)
else:
self.in_defence = False
return self.process_discard_option(selected_tile,
self.player.closed_hand)
def process_discard_options_and_select_tile_to_discard(
self, results, shanten):
tiles_34 = TilesConverter.to_34_array(self.player.tiles)
# we had to update tiles value there
# because it is related with shanten number
for result in results:
result.tiles_count = self.count_tiles(result.waiting, tiles_34)
result.calculate_value(shanten)
# current strategy can affect on our discard options
# so, don't use strategy specific choices for calling riichi
if self.current_strategy:
results = self.current_strategy.determine_what_to_discard(
self.player.closed_hand, results, shanten, False, None)
return self.chose_tile_to_discard(results)
def calculate_outs(self, tiles, closed_hand, open_sets_34=None):
"""
:param tiles: array of tiles in 136 format
:param closed_hand: array of tiles in 136 format
:param open_sets_34: array of array with tiles in 34 format
:return:
"""
tiles_34 = TilesConverter.to_34_array(tiles)
closed_tiles_34 = TilesConverter.to_34_array(closed_hand)
is_agari = self.agari.is_agari(tiles_34,
self.player.open_hand_34_tiles)
results = []
for hand_tile in range(0, 34):
if not closed_tiles_34[hand_tile]:
continue
tiles_34[hand_tile] -= 1
shanten = self.shanten.calculate_shanten(tiles_34, open_sets_34)
waiting = []
for j in range(0, 34):
if hand_tile == j or tiles_34[j] == 4:
continue
tiles_34[j] += 1
if self.shanten.calculate_shanten(tiles_34,
open_sets_34) == shanten - 1:
waiting.append(j)
tiles_34[j] -= 1
tiles_34[hand_tile] += 1
if waiting:
results.append(
DiscardOption(player=self.player,
shanten=shanten,
tile_to_discard=hand_tile,
waiting=waiting,
tiles_count=self.count_tiles(
waiting, tiles_34)))
if is_agari:
shanten = Shanten.AGARI_STATE
else:
shanten = self.shanten.calculate_shanten(tiles_34, open_sets_34)
return results, shanten
def count_tiles(self, waiting, tiles_34):
n = 0
for item in waiting:
n += 4 - self.player.total_tiles(item, tiles_34)
return n
def try_to_call_meld(self, tile, is_kamicha_discard):
if not self.current_strategy:
return None, None
return self.current_strategy.try_to_call_meld(tile, is_kamicha_discard)
def determine_strategy(self):
# for already opened hand we don't need to give up on selected strategy
if self.player.is_open_hand and self.current_strategy:
return False
old_strategy = self.current_strategy
self.current_strategy = None
# order is important
strategies = [
YakuhaiStrategy(BaseStrategy.YAKUHAI, self.player),
HonitsuStrategy(BaseStrategy.HONITSU, self.player),
]
if settings.OPEN_TANYAO:
strategies.append(TanyaoStrategy(BaseStrategy.TANYAO, self.player))
for strategy in strategies:
if strategy.should_activate_strategy():
self.current_strategy = strategy
if self.current_strategy:
if not old_strategy or self.current_strategy.type != old_strategy.type:
message = '{} switched to {} strategy'.format(
self.player.name, self.current_strategy)
if old_strategy:
message += ' from {}'.format(old_strategy)
logger.debug(message)
logger.debug('With hand: {}'.format(
TilesConverter.to_one_line_string(self.player.tiles)))
if not self.current_strategy and old_strategy:
logger.debug('{} gave up on {}'.format(self.player.name,
old_strategy))
return self.current_strategy and True or False
def chose_tile_to_discard(self, results: [DiscardOption]) -> DiscardOption:
"""
Try to find best tile to discard, based on different valuations
"""
def sorting(x):
# - is important for x.tiles_count
# in that case we will discard tile that will give for us more tiles
# to complete a hand
return x.shanten, -x.tiles_count, x.valuation
had_to_be_discarded_tiles = [
x for x in results if x.had_to_be_discarded
]
if had_to_be_discarded_tiles:
had_to_be_discarded_tiles = sorted(had_to_be_discarded_tiles,
key=sorting)
selected_tile = had_to_be_discarded_tiles[0]
else:
results = sorted(results, key=sorting)
# remove needed tiles from discard options
results = [x for x in results if not x.had_to_be_saved]
# let's chose most valuable tile first
temp_tile = results[0]
# and let's find all tiles with same shanten
results_with_same_shanten = [
x for x in results if x.shanten == temp_tile.shanten
]
possible_options = [temp_tile]
for discard_option in results_with_same_shanten:
# there is no sense to check already chosen tile
if discard_option.tile_to_discard == temp_tile.tile_to_discard:
continue
# we don't need to select tiles almost dead waits
if discard_option.tiles_count <= 2:
continue
# let's check all other tiles with same shanten
# maybe we can find tiles that have almost same tiles count number
if temp_tile.tiles_count - 2 < discard_option.tiles_count < temp_tile.tiles_count + 2:
possible_options.append(discard_option)
# let's sort got tiles by value and let's chose less valuable tile to discard
possible_options = sorted(possible_options,
key=lambda x: x.valuation)
selected_tile = possible_options[0]
return selected_tile
def process_discard_option(self, selected_tile, closed_hand):
self.waiting = selected_tile.waiting
self.player.ai.previous_shanten = selected_tile.shanten
self.player.in_tempai = self.player.ai.previous_shanten == 0
return selected_tile.find_tile_in_hand(closed_hand)
def estimate_hand_value(self, win_tile, tiles=None, call_riichi=False):
"""
:param win_tile: 34 tile format
:param tiles:
:param call_riichi:
:return:
"""
win_tile *= 4
# we don't need to think, that our waiting is aka dora
if win_tile in AKA_DORA_LIST:
win_tile += 1
if not tiles:
tiles = self.player.tiles
tiles += [win_tile]
result = self.finished_hand.estimate_hand_value(
tiles=tiles,
win_tile=win_tile,
is_tsumo=False,
is_riichi=call_riichi,
is_dealer=self.player.is_dealer,
open_sets=self.player.open_hand_34_tiles,
player_wind=self.player.player_wind,
round_wind=self.player.table.round_wind,
dora_indicators=self.player.table.dora_indicators)
return result
def should_call_riichi(self):
# empty waiting can be found in some cases
if not self.waiting:
return False
# we have a good wait, let's riichi
if len(self.waiting) > 1:
return True
waiting = self.waiting[0]
tiles = self.player.closed_hand + [waiting * 4]
closed_melds = [x for x in self.player.melds if not x.opened]
for meld in closed_melds:
tiles.extend(meld.tiles[:3])
tiles_34 = TilesConverter.to_34_array(tiles)
results = self.hand_divider.divide_hand(tiles_34, [], [])
result = results[0]
count_of_pairs = len([x for x in result if is_pair(x)])
# with chitoitsu we can call a riichi with pair wait
if count_of_pairs == 7:
return True
for hand_set in result:
# better to not call a riichi for a pair wait
# it can be easily improved
if is_pair(hand_set) and waiting in hand_set:
return False
return True
def can_call_kan(self, tile, open_kan):
"""
Method will decide should we call a kan,
or upgrade pon to kan
:param tile: 136 tile format
:param open_kan: boolean
:return: kan type
"""
# we don't need to add dora for other players
if self.player.ai.in_defence:
return None
if open_kan:
# we don't want to start open our hand from called kan
if not self.player.is_open_hand:
return None
# there is no sense to call open kan when we are not in tempai
if not self.player.in_tempai:
return None
# we have a bad wait, rinshan chance is low
if len(self.waiting) < 2:
return None
tile_34 = tile // 4
tiles_34 = TilesConverter.to_34_array(self.player.tiles)
closed_hand_34 = TilesConverter.to_34_array(self.player.closed_hand)
pon_melds = [x for x in self.player.open_hand_34_tiles if is_pon(x)]
# let's check can we upgrade opened pon to the kan
if pon_melds:
for meld in pon_melds:
# tile is equal to our already opened pon,
# so let's call chankan!
if tile_34 in meld:
return Meld.CHANKAN
count_of_needed_tiles = 4
# for open kan 3 tiles is enough to call a kan
if open_kan:
count_of_needed_tiles = 3
# we have 3 tiles in our hand,
# so we can try to call closed meld
if closed_hand_34[tile_34] == count_of_needed_tiles:
if not open_kan:
# to correctly count shanten in the hand
# we had do subtract drown tile
tiles_34[tile_34] -= 1
melds = self.player.open_hand_34_tiles
previous_shanten = self.shanten.calculate_shanten(tiles_34, melds)
melds += [[tile_34, tile_34, tile_34]]
new_shanten = self.shanten.calculate_shanten(tiles_34, melds)
# called kan will not ruin our hand
if new_shanten <= previous_shanten:
return Meld.KAN
return None
@property
def valued_honors(self):
return [
CHUN, HAKU, HATSU, self.player.table.round_wind,
self.player.player_wind
]
