+ if self.health <= 0:
+ self.end_game(win=False)
+
+ def gain_health(self):
+ if self.health < self.max_health:
+ self.health += 1
+
+ def acquire_win_token(self):
+ self.wins += 1
+ if self.wins >= self.wins_required:
+ self.end_game(win=True)
+
+ def card_used(self, position):
+ if not self.puzzle:
+ self.replace_card(position)
+
+ def replace_card(self, position):
+ new_choice = self.choose_card(self.locations,
+ self.board_locations.items(),
+ position)
+ location = LocationCard.new_location(new_choice.copy(),
+ self.replacement_params)
+ self.board_locations[position] = location
+
+ @classmethod
+ def choose_card(cls, cards, board_locations, position=None):
+ # Find which cards are at their maximum and exclude them from
+ # the choice list
+ counts = {}
+ choices = dict((card['card_name'], card) for card in cards)
+ for pos, card in board_locations:
+ if pos == position:
+ # skip the card we're replacing if appropriate
+ continue
+ if isinstance(card, LocationCard):
+ key = card.card_name
+ max_num = card.max_number
+ else:
+ key = card['card_name']
+ max_num = card.get('max_number', 25)
+ counts.setdefault(key, 0)
+ counts[key] += 1
+ if counts[key] >= max_num:
+ if key in choices:
+ del choices[key]
+ return choice(choices.values())
+
+ def shift_location_row(self, change, is_vertical):
+ px, py = self.player.position
+ shifted_locations = {}
+ mkpos = lambda i: (px, i) if is_vertical else (i, py)
+
+ for i in range(5):
+ if (px, py) == mkpos(i):
+ continue
+ new_i = (i + change) % 5
+ if (px, py) == mkpos(new_i):
+ new_i = (new_i + change) % 5
+ shifted_locations[mkpos(new_i)] = self.board_locations[mkpos(i)]