Py-Hanabi/src/hanabi/live/check_game.py

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import copy
from typing import Tuple
2023-07-04 18:53:18 +02:00
from hanabi import logger
from hanabi import database
from hanabi import hanab_game
from hanabi.live import hanab_live
from hanabi.live import compress
from hanabi.solvers import sat
# returns minimal number T of turns (from game) after which instance was infeasible
# and a replay achieving maximum score while following the replay for the first (T-1) turns:
# if instance is feasible, returns number of turns + 1
# returns 0 if instance is infeasible
# returns 1 if instance is feasible but first turn is suboptimal
# ...
# # turns + 1 if the final state is still winning
def check_game(game_id: int) -> Tuple[int, hanab_game.GameState]:
logger.debug("Analysing game {}".format(game_id))
with database.conn.cursor() as cur:
cur.execute("SELECT games.num_players, deck, actions, score, games.variant_id, starting_player FROM games "
"INNER JOIN seeds ON seeds.seed = games.seed "
"WHERE games.id = (%s)",
(game_id,)
)
res = cur.fetchone()
if res is None:
raise ValueError("No game associated with id {} in database.".format(game_id))
(num_players, compressed_deck, compressed_actions, score, variant_id, starting_player) = res
deck = compress.decompress_deck(compressed_deck)
actions = compress.decompress_actions(compressed_actions)
instance = hanab_live.HanabLiveInstance(
deck,
num_players,
variant_id=variant_id,
starting_player=starting_player
)
# check if the instance is already won
if instance.max_score == score:
game = hanab_live.HanabLiveGameState(instance)
for action in actions:
game.make_action(action)
# instance has been won, nothing to compute here
return len(actions) + 1, game
# first, check if the instance itself is feasible:
game = hanab_live.HanabLiveGameState(instance)
solvable, solution = sat.solve_sat(game)
if not solvable:
return 0, solution
logger.verbose("Instance {} is feasible after 0 turns: {}".format(game_id, compress.link(solution)))
# store lower and upper bounds of numbers of turns after which we know the game was feasible / infeasible
solvable_turn = 0
unsolvable_turn = len(actions)
while unsolvable_turn - solvable_turn > 1:
try_turn = (unsolvable_turn + solvable_turn) // 2
try_game = copy.deepcopy(game)
assert len(try_game.actions) == solvable_turn
for a in range(solvable_turn, try_turn):
try_game.make_action(actions[a])
logger.debug("Checking if instance {} is feasible after {} turns.".format(game_id, try_turn))
solvable, potential_sol = sat.solve_sat(try_game)
if solvable:
solution = potential_sol
game = try_game
solvable_turn = try_turn
logger.verbose("Instance {} is feasible after {} turns: {}#{}"
.format(game_id, solvable_turn, compress.link(solution), solvable_turn + 1))
else:
unsolvable_turn = try_turn
logger.verbose("Instance {} is not feasible after {} turns.".format(game_id, unsolvable_turn))
assert unsolvable_turn - 1 == solvable_turn
return unsolvable_turn, solution