from collections import defaultdict from typing import Any, Dict, List, Optional, Set, Tuple from Utils import cache_argsless from .item_definition_classes import ( CATEGORY_NAME_MAPPINGS, DoorItemDefinition, ItemCategory, ItemDefinition, ProgressiveItemDefinition, WeightedItemDefinition, ) from .utils import ( WitnessRule, define_new_region, get_items, get_sigma_expert_logic, get_sigma_normal_logic, get_umbra_variety_logic, get_vanilla_logic, logical_or_witness_rules, parse_lambda, ) class StaticWitnessLogicObj: def __init__(self, lines: Optional[List[str]] = None) -> None: if lines is None: lines = get_sigma_normal_logic() # All regions with a list of panels in them and the connections to other regions, before logic adjustments self.ALL_REGIONS_BY_NAME: Dict[str, Dict[str, Any]] = {} self.ALL_AREAS_BY_NAME: Dict[str, Dict[str, Any]] = {} self.CONNECTIONS_WITH_DUPLICATES: Dict[str, Dict[str, Set[WitnessRule]]] = defaultdict(lambda: defaultdict(set)) self.STATIC_CONNECTIONS_BY_REGION_NAME: Dict[str, Set[Tuple[str, WitnessRule]]] = {} self.ENTITIES_BY_HEX: Dict[str, Dict[str, Any]] = {} self.ENTITIES_BY_NAME: Dict[str, Dict[str, Any]] = {} self.STATIC_DEPENDENT_REQUIREMENTS_BY_HEX: Dict[str, Dict[str, WitnessRule]] = {} self.OBELISK_SIDE_ID_TO_EP_HEXES: Dict[int, Set[int]] = {} self.EP_TO_OBELISK_SIDE: Dict[str, str] = {} self.ENTITY_ID_TO_NAME: Dict[str, str] = {} self.read_logic_file(lines) self.reverse_connections() self.combine_connections() def read_logic_file(self, lines: List[str]) -> None: """ Reads the logic file and does the initial population of data structures """ current_region = {} current_area: Dict[str, Any] = { "name": "Misc", "regions": [], } self.ALL_AREAS_BY_NAME["Misc"] = current_area for line in lines: if line == "" or line[0] == "#": continue if line[-1] == ":": new_region_and_connections = define_new_region(line) current_region = new_region_and_connections[0] region_name = current_region["name"] self.ALL_REGIONS_BY_NAME[region_name] = current_region for connection in new_region_and_connections[1]: self.CONNECTIONS_WITH_DUPLICATES[region_name][connection[0]].add(connection[1]) current_area["regions"].append(region_name) continue if line[0] == "=": area_name = line[2:-2] current_area = { "name": area_name, "regions": [], } self.ALL_AREAS_BY_NAME[area_name] = current_area continue line_split = line.split(" - ") location_id = line_split.pop(0) entity_name_full = line_split.pop(0) entity_hex = entity_name_full[0:7] entity_name = entity_name_full[9:-1] required_panel_lambda = line_split.pop(0) full_entity_name = current_region["shortName"] + " " + entity_name if location_id == "Door" or location_id == "Laser": self.ENTITIES_BY_HEX[entity_hex] = { "checkName": full_entity_name, "entity_hex": entity_hex, "region": None, "id": None, "entityType": location_id, "locationType": None, "area": current_area, } self.ENTITIES_BY_NAME[self.ENTITIES_BY_HEX[entity_hex]["checkName"]] = self.ENTITIES_BY_HEX[entity_hex] self.STATIC_DEPENDENT_REQUIREMENTS_BY_HEX[entity_hex] = { "entities": parse_lambda(required_panel_lambda) } # Lasers and Doors exist in a region, but don't have a regional *requirement* # If a laser is activated, you don't need to physically walk up to it for it to count # As such, logically, they behave more as if they were part of the "Entry" region self.ALL_REGIONS_BY_NAME["Entry"]["entities"].append(entity_hex) # However, it will also be important to keep track of their physical location for postgame purposes. current_region["physical_entities"].append(entity_hex) continue required_item_lambda = line_split.pop(0) laser_names = { "Laser", "Laser Hedges", "Laser Pressure Plates", } if "Discard" in entity_name: entity_type = "Panel" location_type = "Discard" elif "Vault" in entity_name: entity_type = "Panel" location_type = "Vault" elif entity_name in laser_names: entity_type = "Laser" location_type = None elif "Obelisk Side" in entity_name: entity_type = "Obelisk Side" location_type = "Obelisk Side" elif "Obelisk" in entity_name: entity_type = "Obelisk" location_type = None elif "EP" in entity_name: entity_type = "EP" location_type = "EP" elif "Pet the Dog" in entity_name: entity_type = "Event" location_type = "Good Boi" elif entity_hex.startswith("0xFF"): entity_type = "Event" location_type = None else: entity_type = "Panel" location_type = "General" required_items = parse_lambda(required_item_lambda) required_panels = parse_lambda(required_panel_lambda) required_items = frozenset(required_items) requirement = { "entities": required_panels, "items": required_items } if entity_type == "Obelisk Side": eps = set(next(iter(required_panels))) eps -= {"Theater to Tunnels"} eps_ints = {int(h, 16) for h in eps} self.OBELISK_SIDE_ID_TO_EP_HEXES[int(entity_hex, 16)] = eps_ints for ep_hex in eps: self.EP_TO_OBELISK_SIDE[ep_hex] = entity_hex self.ENTITIES_BY_HEX[entity_hex] = { "checkName": full_entity_name, "entity_hex": entity_hex, "region": current_region, "id": int(location_id), "entityType": entity_type, "locationType": location_type, "area": current_area, } self.ENTITY_ID_TO_NAME[entity_hex] = full_entity_name self.ENTITIES_BY_NAME[self.ENTITIES_BY_HEX[entity_hex]["checkName"]] = self.ENTITIES_BY_HEX[entity_hex] self.STATIC_DEPENDENT_REQUIREMENTS_BY_HEX[entity_hex] = requirement current_region["entities"].append(entity_hex) current_region["physical_entities"].append(entity_hex) def reverse_connection(self, source_region: str, connection: Tuple[str, Set[WitnessRule]]) -> None: target = connection[0] traversal_options = connection[1] # Reverse this connection with all its possibilities, except the ones marked as "OneWay". for requirement in traversal_options: remaining_options = set() for option in requirement: if not any(req == "TrueOneWay" for req in option): remaining_options.add(option) if remaining_options: self.CONNECTIONS_WITH_DUPLICATES[target][source_region].add(frozenset(remaining_options)) def reverse_connections(self) -> None: # Iterate all connections for region_name, connections in list(self.CONNECTIONS_WITH_DUPLICATES.items()): for connection in connections.items(): self.reverse_connection(region_name, connection) def combine_connections(self) -> None: # All regions need to be present, and this dict is copied later - Thus, defaultdict is not the correct choice. self.STATIC_CONNECTIONS_BY_REGION_NAME = {region_name: set() for region_name in self.ALL_REGIONS_BY_NAME} for source, connections in self.CONNECTIONS_WITH_DUPLICATES.items(): for target, requirement in connections.items(): combined_req = logical_or_witness_rules(requirement) self.STATIC_CONNECTIONS_BY_REGION_NAME[source].add((target, combined_req)) # Item data parsed from WitnessItems.txt ALL_ITEMS: Dict[str, ItemDefinition] = {} _progressive_lookup: Dict[str, str] = {} def parse_items() -> None: """ Parses currently defined items from WitnessItems.txt """ lines: List[str] = get_items() current_category: ItemCategory = ItemCategory.SYMBOL for line in lines: # Skip empty lines and comments. if line == "" or line[0] == "#": continue # If this line is a category header, update our cached category. if line in CATEGORY_NAME_MAPPINGS.keys(): current_category = CATEGORY_NAME_MAPPINGS[line] continue line_split = line.split(" - ") item_code = int(line_split[0]) item_name = line_split[1] arguments: List[str] = line_split[2].split(",") if len(line_split) >= 3 else [] if current_category in [ItemCategory.DOOR, ItemCategory.LASER]: # Map doors to IDs. ALL_ITEMS[item_name] = DoorItemDefinition(item_code, current_category, arguments) elif current_category == ItemCategory.TRAP or current_category == ItemCategory.FILLER: # Read filler weights. weight = int(arguments[0]) if len(arguments) >= 1 else 1 ALL_ITEMS[item_name] = WeightedItemDefinition(item_code, current_category, weight) elif arguments: # Progressive items. ALL_ITEMS[item_name] = ProgressiveItemDefinition(item_code, current_category, arguments) for child_item in arguments: _progressive_lookup[child_item] = item_name else: ALL_ITEMS[item_name] = ItemDefinition(item_code, current_category) def get_parent_progressive_item(item_name: str) -> str: """ Returns the name of the item's progressive parent, if there is one, or the item's name if not. """ return _progressive_lookup.get(item_name, item_name) @cache_argsless def get_vanilla() -> StaticWitnessLogicObj: return StaticWitnessLogicObj(get_vanilla_logic()) @cache_argsless def get_sigma_normal() -> StaticWitnessLogicObj: return StaticWitnessLogicObj(get_sigma_normal_logic()) @cache_argsless def get_sigma_expert() -> StaticWitnessLogicObj: return StaticWitnessLogicObj(get_sigma_expert_logic()) @cache_argsless def get_umbra_variety() -> StaticWitnessLogicObj: return StaticWitnessLogicObj(get_umbra_variety_logic()) def __getattr__(name: str) -> StaticWitnessLogicObj: if name == "vanilla": return get_vanilla() if name == "sigma_normal": return get_sigma_normal() if name == "sigma_expert": return get_sigma_expert() if name == "umbra_variety": return get_umbra_variety() raise AttributeError(f"module '{__name__}' has no attribute '{name}'") parse_items() ALL_REGIONS_BY_NAME = get_sigma_normal().ALL_REGIONS_BY_NAME ALL_AREAS_BY_NAME = get_sigma_normal().ALL_AREAS_BY_NAME STATIC_CONNECTIONS_BY_REGION_NAME = get_sigma_normal().STATIC_CONNECTIONS_BY_REGION_NAME ENTITIES_BY_HEX = get_sigma_normal().ENTITIES_BY_HEX ENTITIES_BY_NAME = get_sigma_normal().ENTITIES_BY_NAME STATIC_DEPENDENT_REQUIREMENTS_BY_HEX = get_sigma_normal().STATIC_DEPENDENT_REQUIREMENTS_BY_HEX OBELISK_SIDE_ID_TO_EP_HEXES = get_sigma_normal().OBELISK_SIDE_ID_TO_EP_HEXES EP_TO_OBELISK_SIDE = get_sigma_normal().EP_TO_OBELISK_SIDE ENTITY_ID_TO_NAME = get_sigma_normal().ENTITY_ID_TO_NAME