from collections import defaultdict
from enum import Enum
from typing import Union
import networkx as nx
import numpy as np
from environments.helpers import Constants as c
import itertools
class Object:
_u_idx = defaultdict(lambda: 0)
def __bool__(self):
return True
@property
def is_blocking_light(self):
return self._is_blocking_light
@property
def name(self):
return self._name
@property
def identifier(self):
if self._enum_ident is not None:
return self._enum_ident
elif self._str_ident is not None:
return self._str_ident
else:
return self._name
def __init__(self, str_ident: Union[str, None] = None, enum_ident: Union[Enum, None] = None, is_blocking_light=False, **kwargs):
self._str_ident = str_ident
self._enum_ident = enum_ident
if self._enum_ident is not None and self._str_ident is None:
self._name = f'{self.__class__.__name__}[{self._enum_ident.name}]'
elif self._str_ident is not None and self._enum_ident is None:
self._name = f'{self.__class__.__name__}[{self._str_ident}]'
elif self._str_ident is None and self._enum_ident is None:
self._name = f'{self.__class__.__name__}#{self._u_idx[self.__class__.__name__]}'
Object._u_idx[self.__class__.__name__] += 1
else:
raise ValueError('Please use either of the idents.')
self._is_blocking_light = is_blocking_light
if kwargs:
print(f'Following kwargs were passed, but ignored: {kwargs}')
def __repr__(self):
return f'{self.name}'
def __eq__(self, other) -> bool:
if self._enum_ident is not None:
if isinstance(other, Enum):
return other == self._enum_ident
elif isinstance(other, Object):
return other._enum_ident == self._enum_ident
else:
raise ValueError('Must be evaluated against an Enunm Identifier or Object with such.')
else:
assert isinstance(other, Object), ' This Object can only be compared to other Objects.'
return other.name == self.name
class Entity(Object):
@property
def can_collide(self):
return True
@property
def encoding(self):
return c.OCCUPIED_CELL.value
@property
def x(self):
return self.pos[0]
@property
def y(self):
return self.pos[1]
@property
def pos(self):
return self._tile.pos
@property
def tile(self):
return self._tile
def __init__(self, tile, **kwargs):
super().__init__(**kwargs)
self._tile = tile
tile.enter(self)
def summarize_state(self, **_) -> dict:
return dict(name=str(self.name), x=int(self.x), y=int(self.y),
tile=str(self.tile.name), can_collide=bool(self.can_collide))
def __repr__(self):
return f'{self.name}(@{self.pos})'
class MoveableEntity(Entity):
@property
def last_tile(self):
return self._last_tile
@property
def last_pos(self):
if self._last_tile:
return self._last_tile.pos
else:
return c.NO_POS
@property
def direction_of_view(self):
last_x, last_y = self.last_pos
curr_x, curr_y = self.pos
return last_x-curr_x, last_y-curr_y
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
self._last_tile = None
def move(self, next_tile):
curr_tile = self.tile
if curr_tile != next_tile:
next_tile.enter(self)
curr_tile.leave(self)
self._tile = next_tile
self._last_tile = curr_tile
return True
else:
return False
class Action(Object):
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
class PlaceHolder(MoveableEntity):
def __init__(self, *args, fill_value=0, **kwargs):
super().__init__(*args, **kwargs)
self._fill_value = fill_value
@property
def last_tile(self):
return self.tile
@property
def direction_of_view(self):
return self.pos
@property
def can_collide(self):
return False
@property
def encoding(self):
return c.NO_POS.value[0]
@property
def name(self):
return "PlaceHolder"
class Tile(Object):
@property
def guests_that_can_collide(self):
return [x for x in self.guests if x.can_collide]
@property
def guests(self):
return self._guests.values()
@property
def x(self):
return self.pos[0]
@property
def y(self):
return self.pos[1]
@property
def pos(self):
return self._pos
def __init__(self, pos, **kwargs):
super(Tile, self).__init__(**kwargs)
self._guests = dict()
self._pos = tuple(pos)
def __len__(self):
return len(self._guests)
def is_empty(self):
return not len(self._guests)
def is_occupied(self):
return len(self._guests)
def enter(self, guest):
if guest.name not in self._guests:
self._guests.update({guest.name: guest})
return True
else:
return False
def leave(self, guest):
try:
del self._guests[guest.name]
except (ValueError, KeyError):
return False
return True
def __repr__(self):
return f'{self.name}(@{self.pos})'
def summarize_state(self, **_):
return dict(name=self.name, x=int(self.x), y=int(self.y))
class Wall(Tile):
pass
class Door(Entity):
@property
def can_collide(self):
if self.has_area:
return False if self.is_open else True
else:
return False
@property
def encoding(self):
return 1 if self.is_closed else 2
@property
def str_state(self):
return 'open' if self.is_open else 'closed'
@property
def access_area(self):
return [node for node in self.connectivity.nodes
if node not in range(len(self.connectivity_subgroups)) and node != self.pos]
def __init__(self, *args, context, closed_on_init=True, auto_close_interval=10, has_area=False, **kwargs):
super(Door, self).__init__(*args, **kwargs)
self._state = c.CLOSED_DOOR
self.has_area = has_area
self.auto_close_interval = auto_close_interval
self.time_to_close = -1
neighbor_pos = list(itertools.product([-1, 1, 0], repeat=2))[:-1]
neighbor_tiles = [context.by_pos(tuple([sum(x) for x in zip(self.pos, diff)])) for diff in neighbor_pos]
neighbor_pos = [x.pos for x in neighbor_tiles if x]
possible_connections = itertools.combinations(neighbor_pos, 2)
self.connectivity = nx.Graph()
for a, b in possible_connections:
if not max(abs(np.subtract(a, b))) > 1:
self.connectivity.add_edge(a, b)
self.connectivity_subgroups = list(nx.algorithms.components.connected_components(self.connectivity))
for idx, group in enumerate(self.connectivity_subgroups):
for tile_pos in group:
self.connectivity.add_edge(tile_pos, idx)
if not closed_on_init:
self._open()
def summarize_state(self, **kwargs):
state_dict = super().summarize_state(**kwargs)
state_dict.update(state=str(self.str_state), time_to_close=int(self.time_to_close))
return state_dict
@property
def is_closed(self):
return self._state == c.CLOSED_DOOR
@property
def is_open(self):
return self._state == c.OPEN_DOOR
@property
def status(self):
return self._state
def use(self):
if self._state == c.OPEN_DOOR:
self._close()
else:
self._open()
def tick(self):
if self.is_open and len(self.tile) == 1 and self.time_to_close:
self.time_to_close -= 1
elif self.is_open and not self.time_to_close and len(self.tile) == 1:
self.use()
def _open(self):
self.connectivity.add_edges_from([(self.pos, x) for x in range(len(self.connectivity_subgroups))])
self._state = c.OPEN_DOOR
self.time_to_close = self.auto_close_interval
def _close(self):
self.connectivity.remove_node(self.pos)
self._state = c.CLOSED_DOOR
def is_linked(self, old_pos, new_pos):
try:
_ = nx.shortest_path(self.connectivity, old_pos, new_pos)
return True
except nx.exception.NetworkXNoPath:
return False
class Agent(MoveableEntity):
def __init__(self, *args, **kwargs):
super(Agent, self).__init__(*args, **kwargs)
self.clear_temp_state()
# noinspection PyAttributeOutsideInit
def clear_temp_state(self):
# for attr in self.__dict__:
# if attr.startswith('temp'):
self.temp_collisions = []
self.temp_valid = None
self.temp_action = None
self.temp_light_map = None
def summarize_state(self, **kwargs):
state_dict = super().summarize_state(**kwargs)
state_dict.update(valid=bool(self.temp_valid), action=str(self.temp_action))
return state_dict