import collections from compress import DeckCard, Action, ActionType, link, decompress_deck from enum import Enum from database import conn from time import sleep COLORS = 'rygbp' STANDARD_HAND_SIZE = {2: 5, 3: 5, 4: 4, 5: 4, 6: 3} NUM_STRIKES_TO_LOSE = 3 class CardType(Enum): Trash = 0 Playable = 1 Critical = 2 Dispensable = 3 class CardState(): def __init__(self, card_type: CardType, card: DeckCard, weight=1): self.card_type = card_type self.card = card self.weight = weight def __repr__(self): match self.card_type: case CardType.Trash: return "Trash ({})".format(self.card) case CardType.Playable: return "Playable ({}) with weight {}".format(self.card, self.weight) case CardType.Critical: return "Critical ({})".format(self.card) case CardType.Dispensable: return "Dispensable ({}) with weight {}".format(self.card, self.weight) class GameState(): def __init__(self, num_players, deck, debug=False): assert ( 2 <= num_players <= 6) self.debug = debug self.num_players = num_players self.deck = deck for (idx, card) in enumerate(self.deck): card.deck_index = idx self.deck_size = len(deck) self.num_suits = max(map(lambda c: c.suitIndex, deck)) + 1 self.hand_size = STANDARD_HAND_SIZE[self.num_players] self.players = ["Alice", "Bob", "Cathy", "Donald", "Emily"][:self.num_players] # dynamic game state self.progress = self.num_players * self.hand_size # index of next card to be drawn self.hands = [deck[self.hand_size * p : self.hand_size * (p+1)] for p in range(0, num_players)] self.stacks = [0 for i in range(0, self.num_suits)] self.strikes = 0 self.clues = 8 self.turn = 0 self.pace = self.deck_size - 5 * self.num_suits - self.num_players * (self.hand_size - 1) self.remaining_extra_turns = self.num_players + 1 self.trash = [] # will track replay as game progresses self.actions = [] @property def cur_hand(self): return self.hands[self.turn] def __make_turn(self): assert(self.remaining_extra_turns > 0) self.turn = (self.turn + 1) % self.num_players if self.progress == self.deck_size: self.remaining_extra_turns -= 1 if self.debug: print("Elapsed {} turns, last action was {}. Current board state:\n{} with stacks:{}".format( len(self.actions), self.actions[-1], self.hands, self.stacks )) def __replace(self, card_idx): idx_in_hand = next(i for (i, card) in enumerate(self.cur_hand) if card.deck_index == card_idx) for i in range(idx_in_hand, self.hand_size - 1): self.cur_hand[i] = self.cur_hand[i + 1] if self.progress < self.deck_size: self.cur_hand[self.hand_size - 1] = self.deck[self.progress] self.progress += 1 def play(self, card_idx): card = self.deck[card_idx] if card.rank == self.stacks[card.suitIndex] + 1: self.stacks[card.suitIndex] += 1 if card.rank == 5 and self.clues != 8: self.clues += 1 else: self.strikes += 1 self.trash.append(self.deck[card_idx]) self.actions.append(Action(ActionType.Play, target=card_idx)) self.__replace(card_idx) self.__make_turn() def discard(self, card_idx): assert(self.clues < 8) self.actions.append(Action(ActionType.Discard, target=card_idx)) self.clues += 1 self.pace -= 1 self.trash.append(self.deck[card_idx]) self.__replace(card_idx) self.__make_turn() def clue(self): assert(self.clues > 0) self.actions.append( Action( ActionType.RankClue, target=(self.turn +1) % self.num_players, # clue next plyaer value=self.hands[(self.turn +1) % self.num_players][0].rank # clue index 0 ) ) self.clues -= 1 self.__make_turn() def to_json(self): return { "deck": self.deck, "players": self.players, "actions": self.actions, "first_player": 0, "options": { "variant": "No Variant", } } def card_type(self, card): played = self.stacks[card.suitIndex] if card.rank <= played: return CardType.Trash elif card.rank == played + 1: return CardType.Playable elif card.rank == 5 or card in self.trash: return CardType.Critical else: return CardType.Dispensable def is_over(self): return all(s == 5 for s in self.stacks) or self.remaining_extra_turns == 0 def holding_players(self, card): for (player, hand) in enumerate(self.hands): if card in hand: yield player def score(self): return sum(self.stacks) class GreedyStrategy(): def __init__(self, game_state: GameState): self.game_state = game_state self.earliest_draw_times = [] for s in range(0, game_state.num_suits): self.earliest_draw_times.append([]) for r in range(1, 6): self.earliest_draw_times[s].append(max( game_state.deck.index(DeckCard(s,r)) - game_state.hand_size * game_state.num_players + 1, 0 if r == 1 else self.earliest_draw_times[s][r - 2] )) # Currently, we do not add the time the 5 gets drawn to this, since this is rather a measurument on how # bad a suit is in terms of having to hold on to other cards that are not playable *yet* self.suit_badness = [sum(self.earliest_draw_times[s][:-1]) for s in range(0, game_state.num_suits)] def make_move(self): hand_states = [[CardState(self.game_state.card_type(card), card, None) for card in self.game_state.hands[p]] for p in range(self.game_state.num_players)] # find dupes in players hands, marke one card crit and the other one trash p = False for states in hand_states: counter = collections.Counter(map(lambda state: state.card, states)) for card in counter: if counter[card] >= 2: dupes = (cstate for cstate in states if cstate.card == card) first = next(dupes) if first.card_type == CardType.Dispensable: first.card_type = CardType.Critical for dupe in dupes: dupe.card_type = CardType.Trash for (player, states) in enumerate(hand_states): for state in states: if state.card_type == CardType.Playable: copy_holders = list(self.game_state.holding_players(state.card)) copy_holders.remove(player) connecting_holders = list(self.game_state.holding_players(DeckCard(state.card.suitIndex, state.card.rank + 1))) if len(copy_holders) == 0: state.weight = (3 if len(connecting_holders) > 0 else 1) * state.card.rank else: # TODO state.weight = 0.5 * state.card.rank elif state.card_type == CardType.Dispensable: try: # TODO: consider duplicate in hand copy_holders = list(self.game_state.holding_players(state.card)) copy_holders.remove(player) nextCopy = self.game_state.deck[self.game_state.progress:].index(card) except: nextCopy = 1 # state.weight = self.suit_badness[state.card.suitIndex] * nextCopy + 2 * (5 - state.card.rank) state.weight = nextCopy + 2 * (5 - state.card.rank) cur_hand = hand_states[self.game_state.turn] plays = [cstate for cstate in cur_hand if cstate.card_type == CardType.Playable] trash = next((cstate for cstate in cur_hand if cstate.card_type == CardType.Trash), None) # actual decision on what to do if len(plays) > 0: play = max(plays, key=lambda s: s.weight) self.game_state.play(play.card.deck_index) elif self.game_state.clues == 8: self.game_state.clue() elif trash is not None: self.game_state.discard(trash.card.deck_index) elif self.game_state.clues == 0: dispensable = [cstate for cstate in cur_hand if cstate.card_type == CardType.Dispensable] if len(dispensable) == 0: raise ValueError("Lost critical card") else: discard = min(dispensable, key=lambda s: s.weight) self.game_state.discard(discard.card.deck_index) else: self.game_state.clue() def test(): # seed p4v0s148 deck = decompress_deck("15wpspaodknlftabkpixbxiudqvrumhsgeakqucvgcrfmfhynwlj") gs = GameState(5, deck) print(gs.deck) strat = GreedyStrategy(gs) while not gs.is_over(): strat.make_move() # print(strat.suit_badness) # print(COLORS) # strat.make_move() print(gs.actions) print(link(gs.to_json())) wins = open("won_seeds.txt", "a") losses = open("lost_seeds.txt", "a") crits = open("crits_lost.txt", "a") lost = 0 won = 0 crits_lost = 0 def run_deck(seed, num_players, deck_str): global lost global won global crits_lost deck = decompress_deck(deck_str) gs = GameState(num_players, deck) strat = GreedyStrategy(gs) try: while not gs.is_over(): strat.make_move() if not gs.score() == 25: losses.write("Seed {:10} {}:\n{}\n".format(seed, str(deck), link(gs.to_json()))) lost += 1 else: # wins.write("Seed {:10} {}:\n{}\n".format(seed, str(deck), link(gs.to_json()))) won += 1 except ValueError: crits.write("Seed {} {}lost crit:\n{}\n".format(seed, str(deck), link(gs.to_json()))) crits_lost += 1 if __name__ == "__main__": cur = conn.cursor() cur.execute("SELECT seed, num_players, deck FROM seeds WHERE variant_id = 0 AND num_players = 3 limit 1000") print() for r in cur: run_deck(*r) print("won: {:4}, lost: {:4}, crits lost: {:3}".format(won, lost, crits_lost), end = "\r") print() print("Total wins: {}%".format(round(100 * won / (lost + won + crits_lost), 2)))