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BaseClasses.py
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BaseClasses.py
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from __future__ import annotations
import copy
import itertools
import functools
import logging
import random
import secrets
import typing # this can go away when Python 3.8 support is dropped
from argparse import Namespace
from collections import Counter, deque
from collections.abc import Collection, MutableSequence
from enum import IntEnum, IntFlag
from typing import Any, Callable, Dict, Iterable, Iterator, List, Mapping, NamedTuple, Optional, Set, Tuple, \
TypedDict, Union, Type, ClassVar
import NetUtils
import Options
import Utils
if typing.TYPE_CHECKING:
from worlds import AutoWorld
class Group(TypedDict, total=False):
name: str
game: str
world: "AutoWorld.World"
players: Set[int]
item_pool: Set[str]
replacement_items: Dict[int, Optional[str]]
local_items: Set[str]
non_local_items: Set[str]
link_replacement: bool
class ThreadBarrierProxy:
"""Passes through getattr while passthrough is True"""
def __init__(self, obj: object) -> None:
self.passthrough = True
self.obj = obj
def __getattr__(self, name: str) -> Any:
if self.passthrough:
return getattr(self.obj, name)
else:
raise RuntimeError("You are in a threaded context and global random state was removed for your safety. "
"Please use multiworld.per_slot_randoms[player] or randomize ahead of output.")
class MultiWorld():
debug_types = False
player_name: Dict[int, str]
plando_texts: List[Dict[str, str]]
plando_items: List[List[Dict[str, Any]]]
plando_connections: List
worlds: Dict[int, "AutoWorld.World"]
groups: Dict[int, Group]
regions: RegionManager
itempool: List[Item]
is_race: bool = False
precollected_items: Dict[int, List[Item]]
state: CollectionState
plando_options: PlandoOptions
accessibility: Dict[int, Options.Accessibility]
early_items: Dict[int, Dict[str, int]]
local_early_items: Dict[int, Dict[str, int]]
local_items: Dict[int, Options.LocalItems]
non_local_items: Dict[int, Options.NonLocalItems]
progression_balancing: Dict[int, Options.ProgressionBalancing]
completion_condition: Dict[int, Callable[[CollectionState], bool]]
indirect_connections: Dict[Region, Set[Entrance]]
exclude_locations: Dict[int, Options.ExcludeLocations]
priority_locations: Dict[int, Options.PriorityLocations]
start_inventory: Dict[int, Options.StartInventory]
start_hints: Dict[int, Options.StartHints]
start_location_hints: Dict[int, Options.StartLocationHints]
item_links: Dict[int, Options.ItemLinks]
game: Dict[int, str]
random: random.Random
per_slot_randoms: Utils.DeprecateDict[int, random.Random]
"""Deprecated. Please use `self.random` instead."""
class AttributeProxy():
def __init__(self, rule):
self.rule = rule
def __getitem__(self, player) -> bool:
return self.rule(player)
class RegionManager:
region_cache: Dict[int, Dict[str, Region]]
entrance_cache: Dict[int, Dict[str, Entrance]]
location_cache: Dict[int, Dict[str, Location]]
def __init__(self, players: int):
self.region_cache = {player: {} for player in range(1, players+1)}
self.entrance_cache = {player: {} for player in range(1, players+1)}
self.location_cache = {player: {} for player in range(1, players+1)}
def __iadd__(self, other: Iterable[Region]):
self.extend(other)
return self
def append(self, region: Region):
assert region.name not in self.region_cache[region.player], \
f"{region.name} already exists in region cache."
self.region_cache[region.player][region.name] = region
def extend(self, regions: Iterable[Region]):
for region in regions:
assert region.name not in self.region_cache[region.player], \
f"{region.name} already exists in region cache."
self.region_cache[region.player][region.name] = region
def add_group(self, new_id: int):
self.region_cache[new_id] = {}
self.entrance_cache[new_id] = {}
self.location_cache[new_id] = {}
def __iter__(self) -> Iterator[Region]:
for regions in self.region_cache.values():
yield from regions.values()
def __len__(self):
return sum(len(regions) for regions in self.region_cache.values())
def __init__(self, players: int):
# world-local random state is saved for multiple generations running concurrently
self.random = ThreadBarrierProxy(random.Random())
self.players = players
self.player_types = {player: NetUtils.SlotType.player for player in self.player_ids}
self.algorithm = 'balanced'
self.groups = {}
self.regions = self.RegionManager(players)
self.shops = []
self.itempool = []
self.seed = None
self.seed_name: str = "Unavailable"
self.precollected_items = {player: [] for player in self.player_ids}
self.required_locations = []
self.light_world_light_cone = False
self.dark_world_light_cone = False
self.rupoor_cost = 10
self.aga_randomness = True
self.save_and_quit_from_boss = True
self.custom = False
self.customitemarray = []
self.shuffle_ganon = True
self.spoiler = Spoiler(self)
self.early_items = {player: {} for player in self.player_ids}
self.local_early_items = {player: {} for player in self.player_ids}
self.indirect_connections = {}
self.start_inventory_from_pool: Dict[int, Options.StartInventoryPool] = {}
for player in range(1, players + 1):
def set_player_attr(attr, val):
self.__dict__.setdefault(attr, {})[player] = val
set_player_attr('plando_items', [])
set_player_attr('plando_texts', {})
set_player_attr('plando_connections', [])
set_player_attr('game', "Archipelago")
set_player_attr('completion_condition', lambda state: True)
self.worlds = {}
self.per_slot_randoms = Utils.DeprecateDict("Using per_slot_randoms is now deprecated. Please use the "
"world's random object instead (usually self.random)")
self.plando_options = PlandoOptions.none
def get_all_ids(self) -> Tuple[int, ...]:
return self.player_ids + tuple(self.groups)
def add_group(self, name: str, game: str, players: Set[int] = frozenset()) -> Tuple[int, Group]:
"""Create a group with name and return the assigned player ID and group.
If a group of this name already exists, the set of players is extended instead of creating a new one."""
from worlds import AutoWorld
for group_id, group in self.groups.items():
if group["name"] == name:
group["players"] |= players
return group_id, group
new_id: int = self.players + len(self.groups) + 1
self.regions.add_group(new_id)
self.game[new_id] = game
self.player_types[new_id] = NetUtils.SlotType.group
world_type = AutoWorld.AutoWorldRegister.world_types[game]
self.worlds[new_id] = world_type.create_group(self, new_id, players)
self.worlds[new_id].collect_item = classmethod(AutoWorld.World.collect_item).__get__(self.worlds[new_id])
self.player_name[new_id] = name
new_group = self.groups[new_id] = Group(name=name, game=game, players=players,
world=self.worlds[new_id])
return new_id, new_group
def get_player_groups(self, player) -> Set[int]:
return {group_id for group_id, group in self.groups.items() if player in group["players"]}
def set_seed(self, seed: Optional[int] = None, secure: bool = False, name: Optional[str] = None):
assert not self.worlds, "seed needs to be initialized before Worlds"
self.seed = get_seed(seed)
if secure:
self.secure()
else:
self.random.seed(self.seed)
self.seed_name = name if name else str(self.seed)
def set_options(self, args: Namespace) -> None:
# TODO - remove this section once all worlds use options dataclasses
from worlds import AutoWorld
all_keys: Set[str] = {key for player in self.player_ids for key in
AutoWorld.AutoWorldRegister.world_types[self.game[player]].options_dataclass.type_hints}
for option_key in all_keys:
option = Utils.DeprecateDict(f"Getting options from multiworld is now deprecated. "
f"Please use `self.options.{option_key}` instead.")
option.update(getattr(args, option_key, {}))
setattr(self, option_key, option)
for player in self.player_ids:
world_type = AutoWorld.AutoWorldRegister.world_types[self.game[player]]
self.worlds[player] = world_type(self, player)
options_dataclass: typing.Type[Options.PerGameCommonOptions] = world_type.options_dataclass
self.worlds[player].options = options_dataclass(**{option_key: getattr(args, option_key)[player]
for option_key in options_dataclass.type_hints})
def set_item_links(self):
from worlds import AutoWorld
item_links = {}
replacement_prio = [False, True, None]
for player in self.player_ids:
for item_link in self.worlds[player].options.item_links.value:
if item_link["name"] in item_links:
if item_links[item_link["name"]]["game"] != self.game[player]:
raise Exception(f"Cannot ItemLink across games. Link: {item_link['name']}")
current_link = item_links[item_link["name"]]
current_link["players"][player] = item_link["replacement_item"]
current_link["item_pool"] &= set(item_link["item_pool"])
current_link["exclude"] |= set(item_link.get("exclude", []))
current_link["local_items"] &= set(item_link.get("local_items", []))
current_link["non_local_items"] &= set(item_link.get("non_local_items", []))
current_link["link_replacement"] = min(current_link["link_replacement"],
replacement_prio.index(item_link["link_replacement"]))
else:
if item_link["name"] in self.player_name.values():
raise Exception(f"Cannot name a ItemLink group the same as a player ({item_link['name']}) "
f"({self.get_player_name(player)}).")
item_links[item_link["name"]] = {
"players": {player: item_link["replacement_item"]},
"item_pool": set(item_link["item_pool"]),
"exclude": set(item_link.get("exclude", [])),
"game": self.game[player],
"local_items": set(item_link.get("local_items", [])),
"non_local_items": set(item_link.get("non_local_items", [])),
"link_replacement": replacement_prio.index(item_link["link_replacement"]),
}
for name, item_link in item_links.items():
current_item_name_groups = AutoWorld.AutoWorldRegister.world_types[item_link["game"]].item_name_groups
pool = set()
local_items = set()
non_local_items = set()
for item in item_link["item_pool"]:
pool |= current_item_name_groups.get(item, {item})
for item in item_link["exclude"]:
pool -= current_item_name_groups.get(item, {item})
for item in item_link["local_items"]:
local_items |= current_item_name_groups.get(item, {item})
for item in item_link["non_local_items"]:
non_local_items |= current_item_name_groups.get(item, {item})
local_items &= pool
non_local_items &= pool
item_link["item_pool"] = pool
item_link["local_items"] = local_items
item_link["non_local_items"] = non_local_items
for group_name, item_link in item_links.items():
game = item_link["game"]
group_id, group = self.add_group(group_name, game, set(item_link["players"]))
group["item_pool"] = item_link["item_pool"]
group["replacement_items"] = item_link["players"]
group["local_items"] = item_link["local_items"]
group["non_local_items"] = item_link["non_local_items"]
group["link_replacement"] = replacement_prio[item_link["link_replacement"]]
def secure(self):
self.random = ThreadBarrierProxy(secrets.SystemRandom())
self.is_race = True
@functools.cached_property
def player_ids(self) -> Tuple[int, ...]:
return tuple(range(1, self.players + 1))
@Utils.cache_self1
def get_game_players(self, game_name: str) -> Tuple[int, ...]:
return tuple(player for player in self.player_ids if self.game[player] == game_name)
@Utils.cache_self1
def get_game_groups(self, game_name: str) -> Tuple[int, ...]:
return tuple(group_id for group_id in self.groups if self.game[group_id] == game_name)
@Utils.cache_self1
def get_game_worlds(self, game_name: str):
return tuple(world for player, world in self.worlds.items() if
player not in self.groups and self.game[player] == game_name)
def get_name_string_for_object(self, obj) -> str:
return obj.name if self.players == 1 else f'{obj.name} ({self.get_player_name(obj.player)})'
def get_player_name(self, player: int) -> str:
return self.player_name[player]
def get_file_safe_player_name(self, player: int) -> str:
return Utils.get_file_safe_name(self.get_player_name(player))
def get_out_file_name_base(self, player: int) -> str:
""" the base name (without file extension) for each player's output file for a seed """
return f"AP_{self.seed_name}_P{player}_{self.get_file_safe_player_name(player).replace(' ', '_')}"
@functools.cached_property
def world_name_lookup(self):
return {self.player_name[player_id]: player_id for player_id in self.player_ids}
def get_regions(self, player: Optional[int] = None) -> Collection[Region]:
return self.regions if player is None else self.regions.region_cache[player].values()
def get_region(self, region_name: str, player: int) -> Region:
return self.regions.region_cache[player][region_name]
def get_entrance(self, entrance_name: str, player: int) -> Entrance:
return self.regions.entrance_cache[player][entrance_name]
def get_location(self, location_name: str, player: int) -> Location:
return self.regions.location_cache[player][location_name]
def get_all_state(self, use_cache: bool) -> CollectionState:
cached = getattr(self, "_all_state", None)
if use_cache and cached:
return cached.copy()
ret = CollectionState(self)
for item in self.itempool:
self.worlds[item.player].collect(ret, item)
for player in self.player_ids:
subworld = self.worlds[player]
for item in subworld.get_pre_fill_items():
subworld.collect(ret, item)
ret.sweep_for_events()
if use_cache:
self._all_state = ret
return ret
def get_items(self) -> List[Item]:
return [loc.item for loc in self.get_filled_locations()] + self.itempool
def find_item_locations(self, item, player: int, resolve_group_locations: bool = False) -> List[Location]:
if resolve_group_locations:
player_groups = self.get_player_groups(player)
return [location for location in self.get_locations() if
location.item and location.item.name == item and location.player not in player_groups and
(location.item.player == player or location.item.player in player_groups)]
return [location for location in self.get_locations() if
location.item and location.item.name == item and location.item.player == player]
def find_item(self, item, player: int) -> Location:
return next(location for location in self.get_locations() if
location.item and location.item.name == item and location.item.player == player)
def find_items_in_locations(self, items: Set[str], player: int, resolve_group_locations: bool = False) -> List[Location]:
if resolve_group_locations:
player_groups = self.get_player_groups(player)
return [location for location in self.get_locations() if
location.item and location.item.name in items and location.player not in player_groups and
(location.item.player == player or location.item.player in player_groups)]
return [location for location in self.get_locations() if
location.item and location.item.name in items and location.item.player == player]
def create_item(self, item_name: str, player: int) -> Item:
return self.worlds[player].create_item(item_name)
def push_precollected(self, item: Item):
self.precollected_items[item.player].append(item)
self.state.collect(item, True)
def push_item(self, location: Location, item: Item, collect: bool = True):
location.item = item
item.location = location
if collect:
self.state.collect(item, location.advancement, location)
logging.debug('Placed %s at %s', item, location)
def get_entrances(self, player: Optional[int] = None) -> Iterable[Entrance]:
if player is not None:
return self.regions.entrance_cache[player].values()
return Utils.RepeatableChain(tuple(self.regions.entrance_cache[player].values()
for player in self.regions.entrance_cache))
def register_indirect_condition(self, region: Region, entrance: Entrance):
"""Report that access to this Region can result in unlocking this Entrance,
state.can_reach(Region) in the Entrance's traversal condition, as opposed to pure transition logic."""
self.indirect_connections.setdefault(region, set()).add(entrance)
def get_locations(self, player: Optional[int] = None) -> Iterable[Location]:
if player is not None:
return self.regions.location_cache[player].values()
return Utils.RepeatableChain(tuple(self.regions.location_cache[player].values()
for player in self.regions.location_cache))
def get_unfilled_locations(self, player: Optional[int] = None) -> List[Location]:
return [location for location in self.get_locations(player) if location.item is None]
def get_filled_locations(self, player: Optional[int] = None) -> List[Location]:
return [location for location in self.get_locations(player) if location.item is not None]
def get_reachable_locations(self, state: Optional[CollectionState] = None, player: Optional[int] = None) -> List[Location]:
state: CollectionState = state if state else self.state
return [location for location in self.get_locations(player) if location.can_reach(state)]
def get_placeable_locations(self, state=None, player=None) -> List[Location]:
state: CollectionState = state if state else self.state
return [location for location in self.get_locations(player) if location.item is None and location.can_reach(state)]
def get_unfilled_locations_for_players(self, location_names: List[str], players: Iterable[int]):
for player in players:
if not location_names:
valid_locations = [location.name for location in self.get_unfilled_locations(player)]
else:
valid_locations = location_names
relevant_cache = self.regions.location_cache[player]
for location_name in valid_locations:
location = relevant_cache.get(location_name, None)
if location and location.item is None:
yield location
def unlocks_new_location(self, item: Item) -> bool:
temp_state = self.state.copy()
temp_state.collect(item, True)
for location in self.get_unfilled_locations(item.player):
if temp_state.can_reach(location) and not self.state.can_reach(location):
return True
return False
def has_beaten_game(self, state: CollectionState, player: Optional[int] = None) -> bool:
if player:
return self.completion_condition[player](state)
else:
return all((self.has_beaten_game(state, p) for p in range(1, self.players + 1)))
def can_beat_game(self, starting_state: Optional[CollectionState] = None) -> bool:
if starting_state:
if self.has_beaten_game(starting_state):
return True
state = starting_state.copy()
else:
if self.has_beaten_game(self.state):
return True
state = CollectionState(self)
prog_locations = {location for location in self.get_locations() if location.item
and location.item.advancement and location not in state.locations_checked}
while prog_locations:
sphere: Set[Location] = set()
# build up spheres of collection radius.
# Everything in each sphere is independent from each other in dependencies and only depends on lower spheres
for location in prog_locations:
if location.can_reach(state):
sphere.add(location)
if not sphere:
# ran out of places and did not finish yet, quit
return False
for location in sphere:
state.collect(location.item, True, location)
prog_locations -= sphere
if self.has_beaten_game(state):
return True
return False
def get_spheres(self) -> Iterator[Set[Location]]:
"""
yields a set of locations for each logical sphere
If there are unreachable locations, the last sphere of reachable
locations is followed by an empty set, and then a set of all of the
unreachable locations.
"""
state = CollectionState(self)
locations = set(self.get_filled_locations())
while locations:
sphere: Set[Location] = set()
for location in locations:
if location.can_reach(state):
sphere.add(location)
yield sphere
if not sphere:
if locations:
yield locations # unreachable locations
break
for location in sphere:
state.collect(location.item, True, location)
locations -= sphere
def fulfills_accessibility(self, state: Optional[CollectionState] = None):
"""Check if accessibility rules are fulfilled with current or supplied state."""
if not state:
state = CollectionState(self)
players: Dict[str, Set[int]] = {
"minimal": set(),
"items": set(),
"locations": set()
}
for player, access in self.accessibility.items():
players[access.current_key].add(player)
beatable_fulfilled = False
def location_condition(location: Location):
"""Determine if this location has to be accessible, location is already filtered by location_relevant"""
if location.player in players["locations"] or (location.item and location.item.player not in
players["minimal"]):
return True
return False
def location_relevant(location: Location):
"""Determine if this location is relevant to sweep."""
if location.progress_type != LocationProgressType.EXCLUDED \
and (location.player in players["locations"] or location.advancement):
return True
return False
def all_done() -> bool:
"""Check if all access rules are fulfilled"""
if not beatable_fulfilled:
return False
if any(location_condition(location) for location in locations):
return False # still locations required to be collected
return True
locations = [location for location in self.get_locations() if location_relevant(location)]
while locations:
sphere: List[Location] = []
for n in range(len(locations) - 1, -1, -1):
if locations[n].can_reach(state):
sphere.append(locations.pop(n))
if not sphere:
# ran out of places and did not finish yet, quit
logging.warning(f"Could not access required locations for accessibility check."
f" Missing: {locations}")
return False
for location in sphere:
if location.item:
state.collect(location.item, True, location)
if self.has_beaten_game(state):
beatable_fulfilled = True
if all_done():
return True
return False
PathValue = Tuple[str, Optional["PathValue"]]
class CollectionState():
prog_items: Dict[int, Counter[str]]
multiworld: MultiWorld
reachable_regions: Dict[int, Set[Region]]
blocked_connections: Dict[int, Set[Entrance]]
events: Set[Location]
path: Dict[Union[Region, Entrance], PathValue]
locations_checked: Set[Location]
stale: Dict[int, bool]
additional_init_functions: List[Callable[[CollectionState, MultiWorld], None]] = []
additional_copy_functions: List[Callable[[CollectionState, CollectionState], CollectionState]] = []
def __init__(self, parent: MultiWorld):
self.prog_items = {player: Counter() for player in parent.get_all_ids()}
self.multiworld = parent
self.reachable_regions = {player: set() for player in parent.get_all_ids()}
self.blocked_connections = {player: set() for player in parent.get_all_ids()}
self.events = set()
self.path = {}
self.locations_checked = set()
self.stale = {player: True for player in parent.get_all_ids()}
for function in self.additional_init_functions:
function(self, parent)
for items in parent.precollected_items.values():
for item in items:
self.collect(item, True)
def update_reachable_regions(self, player: int):
self.stale[player] = False
reachable_regions = self.reachable_regions[player]
blocked_connections = self.blocked_connections[player]
queue = deque(self.blocked_connections[player])
start = self.multiworld.get_region("Menu", player)
# init on first call - this can't be done on construction since the regions don't exist yet
if start not in reachable_regions:
reachable_regions.add(start)
blocked_connections.update(start.exits)
queue.extend(start.exits)
# run BFS on all connections, and keep track of those blocked by missing items
while queue:
connection = queue.popleft()
new_region = connection.connected_region
if new_region in reachable_regions:
blocked_connections.remove(connection)
elif connection.can_reach(self):
assert new_region, f"tried to search through an Entrance \"{connection}\" with no Region"
reachable_regions.add(new_region)
blocked_connections.remove(connection)
blocked_connections.update(new_region.exits)
queue.extend(new_region.exits)
self.path[new_region] = (new_region.name, self.path.get(connection, None))
# Retry connections if the new region can unblock them
for new_entrance in self.multiworld.indirect_connections.get(new_region, set()):
if new_entrance in blocked_connections and new_entrance not in queue:
queue.append(new_entrance)
def copy(self) -> CollectionState:
ret = CollectionState(self.multiworld)
ret.prog_items = copy.deepcopy(self.prog_items)
ret.reachable_regions = {player: copy.copy(self.reachable_regions[player]) for player in
self.reachable_regions}
ret.blocked_connections = {player: copy.copy(self.blocked_connections[player]) for player in
self.blocked_connections}
ret.events = copy.copy(self.events)
ret.path = copy.copy(self.path)
ret.locations_checked = copy.copy(self.locations_checked)
for function in self.additional_copy_functions:
ret = function(self, ret)
return ret
def can_reach(self,
spot: Union[Location, Entrance, Region, str],
resolution_hint: Optional[str] = None,
player: Optional[int] = None) -> bool:
if isinstance(spot, str):
assert isinstance(player, int), "can_reach: player is required if spot is str"
# try to resolve a name
if resolution_hint == 'Location':
return self.can_reach_location(spot, player)
elif resolution_hint == 'Entrance':
return self.can_reach_entrance(spot, player)
else:
# default to Region
return self.can_reach_region(spot, player)
return spot.can_reach(self)
def can_reach_location(self, spot: str, player: int) -> bool:
return self.multiworld.get_location(spot, player).can_reach(self)
def can_reach_entrance(self, spot: str, player: int) -> bool:
return self.multiworld.get_entrance(spot, player).can_reach(self)
def can_reach_region(self, spot: str, player: int) -> bool:
return self.multiworld.get_region(spot, player).can_reach(self)
def sweep_for_events(self, key_only: bool = False, locations: Optional[Iterable[Location]] = None) -> None:
if locations is None:
locations = self.multiworld.get_filled_locations()
reachable_events = True
# since the loop has a good chance to run more than once, only filter the events once
locations = {location for location in locations if location.advancement and location not in self.events and
not key_only or getattr(location.item, "locked_dungeon_item", False)}
while reachable_events:
reachable_events = {location for location in locations if location.can_reach(self)}
locations -= reachable_events
for event in reachable_events:
self.events.add(event)
assert isinstance(event.item, Item), "tried to collect Event with no Item"
self.collect(event.item, True, event)
# item name related
def has(self, item: str, player: int, count: int = 1) -> bool:
return self.prog_items[player][item] >= count
def has_all(self, items: Iterable[str], player: int) -> bool:
"""Returns True if each item name of items is in state at least once."""
return all(self.prog_items[player][item] for item in items)
def has_any(self, items: Iterable[str], player: int) -> bool:
"""Returns True if at least one item name of items is in state at least once."""
return any(self.prog_items[player][item] for item in items)
def has_all_counts(self, item_counts: Mapping[str, int], player: int) -> bool:
"""Returns True if each item name is in the state at least as many times as specified."""
return all(self.prog_items[player][item] >= count for item, count in item_counts.items())
def has_any_count(self, item_counts: Mapping[str, int], player: int) -> bool:
"""Returns True if at least one item name is in the state at least as many times as specified."""
return any(self.prog_items[player][item] >= count for item, count in item_counts.items())
def count(self, item: str, player: int) -> int:
return self.prog_items[player][item]
def has_from_list(self, items: Iterable[str], player: int, count: int) -> bool:
"""Returns True if the state contains at least `count` items matching any of the item names from a list."""
found: int = 0
player_prog_items = self.prog_items[player]
for item_name in items:
found += player_prog_items[item_name]
if found >= count:
return True
return False
def has_from_list_unique(self, items: Iterable[str], player: int, count: int) -> bool:
"""Returns True if the state contains at least `count` items matching any of the item names from a list.
Ignores duplicates of the same item."""
found: int = 0
player_prog_items = self.prog_items[player]
for item_name in items:
found += player_prog_items[item_name] > 0
if found >= count:
return True
return False
def count_from_list(self, items: Iterable[str], player: int) -> int:
"""Returns the cumulative count of items from a list present in state."""
return sum(self.prog_items[player][item_name] for item_name in items)
def count_from_list_unique(self, items: Iterable[str], player: int) -> int:
"""Returns the cumulative count of items from a list present in state. Ignores duplicates of the same item."""
return sum(self.prog_items[player][item_name] > 0 for item_name in items)
# item name group related
def has_group(self, item_name_group: str, player: int, count: int = 1) -> bool:
"""Returns True if the state contains at least `count` items present in a specified item group."""
found: int = 0
player_prog_items = self.prog_items[player]
for item_name in self.multiworld.worlds[player].item_name_groups[item_name_group]:
found += player_prog_items[item_name]
if found >= count:
return True
return False
def has_group_unique(self, item_name_group: str, player: int, count: int = 1) -> bool:
"""Returns True if the state contains at least `count` items present in a specified item group.
Ignores duplicates of the same item.
"""
found: int = 0
player_prog_items = self.prog_items[player]
for item_name in self.multiworld.worlds[player].item_name_groups[item_name_group]:
found += player_prog_items[item_name] > 0
if found >= count:
return True
return False
def count_group(self, item_name_group: str, player: int) -> int:
"""Returns the cumulative count of items from an item group present in state."""
player_prog_items = self.prog_items[player]
return sum(
player_prog_items[item_name]
for item_name in self.multiworld.worlds[player].item_name_groups[item_name_group]
)
def count_group_unique(self, item_name_group: str, player: int) -> int:
"""Returns the cumulative count of items from an item group present in state.
Ignores duplicates of the same item."""
player_prog_items = self.prog_items[player]
return sum(
player_prog_items[item_name] > 0
for item_name in self.multiworld.worlds[player].item_name_groups[item_name_group]
)
# Item related
def collect(self, item: Item, event: bool = False, location: Optional[Location] = None) -> bool:
if location:
self.locations_checked.add(location)
changed = self.multiworld.worlds[item.player].collect(self, item)
if not changed and event:
self.prog_items[item.player][item.name] += 1
changed = True
self.stale[item.player] = True
if changed and not event:
self.sweep_for_events()
return changed
def remove(self, item: Item):
changed = self.multiworld.worlds[item.player].remove(self, item)
if changed:
# invalidate caches, nothing can be trusted anymore now
self.reachable_regions[item.player] = set()
self.blocked_connections[item.player] = set()
self.stale[item.player] = True
class Entrance:
access_rule: Callable[[CollectionState], bool] = staticmethod(lambda state: True)
hide_path: bool = False
player: int
name: str
parent_region: Optional[Region]
connected_region: Optional[Region] = None
# LttP specific, TODO: should make a LttPEntrance
addresses = None
target = None
def __init__(self, player: int, name: str = '', parent: Region = None):
self.name = name
self.parent_region = parent
self.player = player
def can_reach(self, state: CollectionState) -> bool:
if self.parent_region.can_reach(state) and self.access_rule(state):
if not self.hide_path and not self in state.path:
state.path[self] = (self.name, state.path.get(self.parent_region, (self.parent_region.name, None)))
return True
return False
def connect(self, region: Region, addresses: Any = None, target: Any = None) -> None:
self.connected_region = region
self.target = target
self.addresses = addresses
region.entrances.append(self)
def __repr__(self):
return self.__str__()
def __str__(self):
multiworld = self.parent_region.multiworld if self.parent_region else None
return multiworld.get_name_string_for_object(self) if multiworld else f'{self.name} (Player {self.player})'
class Region:
name: str
_hint_text: str
player: int
multiworld: Optional[MultiWorld]
entrances: List[Entrance]
exits: List[Entrance]
locations: List[Location]
entrance_type: ClassVar[Type[Entrance]] = Entrance
class Register(MutableSequence):
region_manager: MultiWorld.RegionManager
def __init__(self, region_manager: MultiWorld.RegionManager):
self._list = []
self.region_manager = region_manager
def __getitem__(self, index: int) -> Location:
return self._list.__getitem__(index)
def __setitem__(self, index: int, value: Location) -> None:
raise NotImplementedError()
def __len__(self) -> int:
return self._list.__len__()
# This seems to not be needed, but that's a bit suspicious.
# def __del__(self):
# self.clear()
def copy(self):
return self._list.copy()
class LocationRegister(Register):
def __delitem__(self, index: int) -> None:
location: Location = self._list.__getitem__(index)
self._list.__delitem__(index)
del(self.region_manager.location_cache[location.player][location.name])
def insert(self, index: int, value: Location) -> None:
assert value.name not in self.region_manager.location_cache[value.player], \
f"{value.name} already exists in the location cache."
self._list.insert(index, value)
self.region_manager.location_cache[value.player][value.name] = value
class EntranceRegister(Register):
def __delitem__(self, index: int) -> None:
entrance: Entrance = self._list.__getitem__(index)
self._list.__delitem__(index)
del(self.region_manager.entrance_cache[entrance.player][entrance.name])
def insert(self, index: int, value: Entrance) -> None:
assert value.name not in self.region_manager.entrance_cache[value.player], \
f"{value.name} already exists in the entrance cache."
self._list.insert(index, value)
self.region_manager.entrance_cache[value.player][value.name] = value
_locations: LocationRegister[Location]
_exits: EntranceRegister[Entrance]
def __init__(self, name: str, player: int, multiworld: MultiWorld, hint: Optional[str] = None):
self.name = name
self.entrances = []
self._exits = self.EntranceRegister(multiworld.regions)
self._locations = self.LocationRegister(multiworld.regions)
self.multiworld = multiworld
self._hint_text = hint
self.player = player
def get_locations(self):
return self._locations
def set_locations(self, new):
if new is self._locations:
return
self._locations.clear()
self._locations.extend(new)
locations = property(get_locations, set_locations)
def get_exits(self):
return self._exits
def set_exits(self, new):
if new is self._exits:
return
self._exits.clear()
self._exits.extend(new)
exits = property(get_exits, set_exits)
def can_reach(self, state: CollectionState) -> bool:
if state.stale[self.player]:
state.update_reachable_regions(self.player)
return self in state.reachable_regions[self.player]
@property
def hint_text(self) -> str:
return self._hint_text if self._hint_text else self.name
def get_connecting_entrance(self, is_main_entrance: Callable[[Entrance], bool]) -> Entrance:
for entrance in self.entrances:
if is_main_entrance(entrance):
return entrance
for entrance in self.entrances: # BFS might be better here, trying DFS for now.
return entrance.parent_region.get_connecting_entrance(is_main_entrance)
def add_locations(self, locations: Dict[str, Optional[int]],
location_type: Optional[Type[Location]] = None) -> None:
"""
Adds locations to the Region object, where location_type is your Location class and locations is a dict of
location names to address.
:param locations: dictionary of locations to be created and added to this Region `{name: ID}`
:param location_type: Location class to be used to create the locations with"""
if location_type is None:
location_type = Location
for location, address in locations.items():
self.locations.append(location_type(self.player, location, address, self))
def connect(self, connecting_region: Region, name: Optional[str] = None,
rule: Optional[Callable[[CollectionState], bool]] = None) -> entrance_type:
"""
Connects this Region to another Region, placing the provided rule on the connection.
:param connecting_region: Region object to connect to path is `self -> exiting_region`
:param name: name of the connection being created
:param rule: callable to determine access of this connection to go from self to the exiting_region"""
exit_ = self.create_exit(name if name else f"{self.name} -> {connecting_region.name}")
if rule:
exit_.access_rule = rule
exit_.connect(connecting_region)
return exit_
def create_exit(self, name: str) -> Entrance:
"""
Creates and returns an Entrance object as an exit of this region.
:param name: name of the Entrance being created
"""
exit_ = self.entrance_type(self.player, name, self)
self.exits.append(exit_)
return exit_
def add_exits(self, exits: Union[Iterable[str], Dict[str, Optional[str]]],
rules: Dict[str, Callable[[CollectionState], bool]] = None) -> None: