FIKS_Entwicklungsumgebung/environments/factory/base/registers.py

import numbers
import random
from abc import ABC
from typing import List, Union, Dict

import numpy as np

from environments.factory.base.objects import Entity, Tile, Agent, Door, Action, Wall, Object, PlaceHolder
from environments.utility_classes import MovementProperties
from environments import helpers as h
from environments.helpers import Constants as c


class Register:
    _accepted_objects = Entity

    @property
    def name(self):
        return f'{self.__class__.__name__}'

    def __init__(self, *args, **kwargs):
        self._register = dict()

    def __len__(self):
        return len(self._register)

    def __iter__(self):
        return iter(self.values())

    def register_item(self, other: _accepted_objects):
        assert isinstance(other, self._accepted_objects), f'All item names have to be of type ' \
                                                          f'{self._accepted_objects}, ' \
                                                          f'but were {other.__class__}.,'
        self._register.update({other.name: other})
        return self

    def register_additional_items(self, others: List[_accepted_objects]):
        for other in others:
            self.register_item(other)
        return self

    def keys(self):
        return self._register.keys()

    def values(self):
        return self._register.values()

    def items(self):
        return self._register.items()

    def __getitem__(self, item):
        if isinstance(item, (int, np.int64, np.int32)):
            try:
                return next(v for i, v in enumerate(self._register.values()) if i == item)
            except StopIteration:
                return None
        try:
            return self._register[item]
        except KeyError:
            return None

    def __repr__(self):
        return f'{self.__class__.__name__}({self._register})'


class ObjectRegister(Register):

    hide_from_obs_builder = False

    def __init__(self, level_shape: (int, int), *args, individual_slices=False, is_per_agent=False, **kwargs):
        super(ObjectRegister, self).__init__(*args, **kwargs)
        self.is_per_agent = is_per_agent
        self.individual_slices = individual_slices
        self._level_shape = level_shape
        self._array = None

    def register_item(self, other):
        super(ObjectRegister, self).register_item(other)
        if self._array is None:
            self._array = np.zeros((1, *self._level_shape))
        else:
            if self.individual_slices:
                self._array = np.concatenate((self._array, np.zeros((1, *self._array.shape[1:]))))

    def summarize_states(self, n_steps=None):
        return [val.summarize_state(n_steps=n_steps) for val in self.values()]


class EntityObjectRegister(ObjectRegister, ABC):

    def as_array(self):
        raise NotImplementedError

    @classmethod
    def from_tiles(cls, tiles, *args, entity_kwargs=None, **kwargs):
        # objects_name = cls._accepted_objects.__name__
        register_obj = cls(*args, **kwargs)
        entities = [cls._accepted_objects(tile, str_ident=i, **entity_kwargs if entity_kwargs is not None else {})
                    for i, tile in enumerate(tiles)]
        register_obj.register_additional_items(entities)
        return register_obj

    @classmethod
    def from_argwhere_coordinates(cls, positions: [(int, int)], tiles, *args, entity_kwargs=None, **kwargs, ):
        return cls.from_tiles([tiles.by_pos(position) for position in positions], *args, entity_kwargs=entity_kwargs,
                              **kwargs)

    @property
    def positions(self):
        return [x.pos for x in self]

    @property
    def tiles(self):
        return [entity.tile for entity in self]

    def __init__(self, *args, is_blocking_light=False, is_observable=True, can_be_shadowed=True, **kwargs):
        super(EntityObjectRegister, self).__init__(*args, **kwargs)
        self.can_be_shadowed = can_be_shadowed
        self.is_blocking_light = is_blocking_light
        self.is_observable = is_observable

    def by_pos(self, pos):
        if isinstance(pos, np.ndarray):
            pos = tuple(pos)
        try:
            return next(item for item in self.values() if item.pos == pos)
        except StopIteration:
            return None


class MovingEntityObjectRegister(EntityObjectRegister, ABC):

    def __init__(self, *args, **kwargs):
        super(MovingEntityObjectRegister, self).__init__(*args, **kwargs)

    def by_pos(self, pos):
        if isinstance(pos, np.ndarray):
            pos = tuple(pos)
        try:
            return next(x for x in self if x.pos == pos)
        except StopIteration:
            return None

    def __delitem__(self, name):
        idx = next(i for i, entity in enumerate(self) if entity.name == name)
        del self._register[name]
        if self.individual_slices:
            self._array = np.delete(self._array, idx, axis=0)

    def delete_item(self, item):
        self.delete_item_by_name(item.name)

    def delete_item_by_name(self, name):
        del self[name]


class PlaceHolders(MovingEntityObjectRegister):

    _accepted_objects = PlaceHolder

    def __init__(self, *args, fill_value: Union[str, int] = 0, **kwargs):
        super().__init__(*args, **kwargs)
        self.fill_value = fill_value

    # noinspection DuplicatedCode
    def as_array(self):
        if isinstance(self.fill_value, numbers.Number):
            self._array[:] = self.fill_value
        elif isinstance(self.fill_value, str):
            if self.fill_value.lower() in ['normal', 'n']:
                self._array = np.random.normal(size=self._array.shape)
            else:
                raise ValueError('Choose one of: ["normal", "N"]')
        else:
            raise TypeError('Objects of type "str" or "number" is required here.')

        if self.individual_slices:
            return self._array
        else:
            return self._array[None, 0]


class Entities(Register):

    _accepted_objects = EntityObjectRegister

    @property
    def observable_arrays(self):
        # FIXME: Find a better name
        return {key: val.as_array() for key, val in self.items() if val.is_observable}

    @property
    def obs_arrays(self):
        # FIXME: Find a better name
        return {key: val.as_array() for key, val in self.items() if val.is_observable and not val.hide_from_obs_builder}

    @property
    def names(self):
        return list(self._register.keys())

    def __init__(self):
        super(Entities, self).__init__()

    def iter_individual_entitites(self):
        return iter((x for sublist in self.values() for x in sublist))

    def register_item(self, other: dict):
        assert not any([key for key in other.keys() if key in self.keys()]), \
            "This group of entities has already been registered!"
        self._register.update(other)
        return self

    def register_additional_items(self, others: Dict):
        return self.register_item(others)

    def by_pos(self, pos: (int, int)):
        found_entities = [y for y in (x.by_pos(pos) for x in self.values() if hasattr(x, 'by_pos')) if y is not None]
        return found_entities


class WallTiles(EntityObjectRegister):
    _accepted_objects = Wall
    _light_blocking = True

    def as_array(self):
        if not np.any(self._array):
            x, y = zip(*[x.pos for x in self])
            self._array[0, x, y] = self.encoding
        return self._array

    def __init__(self, *args, **kwargs):
        super(WallTiles, self).__init__(*args, individual_slices=False,
                                        is_blocking_light=self._light_blocking, **kwargs)

    @property
    def encoding(self):
        return c.OCCUPIED_CELL.value

    @property
    def array(self):
        return self._array

    @classmethod
    def from_argwhere_coordinates(cls, argwhere_coordinates, *args, **kwargs):
        tiles = cls(*args, **kwargs)
        # noinspection PyTypeChecker
        tiles.register_additional_items(
            [cls._accepted_objects(pos, is_blocking_light=cls._light_blocking)
             for pos in argwhere_coordinates]
        )
        return tiles

    @classmethod
    def from_tiles(cls, tiles, *args, **kwargs):
        raise RuntimeError()

    def summarize_states(self, n_steps=None):
        if n_steps == h.STEPS_START:
            return super(WallTiles, self).summarize_states(n_steps=n_steps)
        else:
            return {}


class FloorTiles(WallTiles):

    _accepted_objects = Tile
    _light_blocking = False

    def __init__(self, *args, **kwargs):
        super(FloorTiles, self).__init__(*args, is_observable=False, **kwargs)

    @property
    def encoding(self):
        return c.FREE_CELL.value

    @property
    def occupied_tiles(self):
        tiles = [tile for tile in self if tile.is_occupied()]
        random.shuffle(tiles)
        return tiles

    @property
    def empty_tiles(self) -> List[Tile]:
        tiles = [tile for tile in self if tile.is_empty()]
        random.shuffle(tiles)
        return tiles

    @classmethod
    def from_tiles(cls, tiles, *args, **kwargs):
        raise RuntimeError()

    def summarize_states(self, n_steps=None):
        # Do not summarize
        return {}


class Agents(MovingEntityObjectRegister):

    _accepted_objects = Agent

    def __init__(self, *args, hide_from_obs_builder=False, **kwargs):
        super().__init__(*args, **kwargs)
        self.hide_from_obs_builder = hide_from_obs_builder

    # noinspection DuplicatedCode
    def as_array(self):
        self._array[:] = c.FREE_CELL.value
        # noinspection PyTupleAssignmentBalance
        for z, x, y, v in zip(range(len(self)), *zip(*[x.pos for x in self]), [x.encoding for x in self]):
            if self.individual_slices:
                self._array[z, x, y] += v
            else:
                self._array[0, x, y] += v
        if self.individual_slices:
            return self._array
        else:
            return self._array.sum(axis=0, keepdims=True)

    @property
    def positions(self):
        return [agent.pos for agent in self]

    def __setitem__(self, key, value):
        self._register[self[key].name] = value


class Doors(EntityObjectRegister):

    def __init__(self, *args, **kwargs):
        super(Doors, self).__init__(*args, is_blocking_light=True, **kwargs)

    def as_array(self):
        self._array[:] = 0
        for door in self:
            self._array[0, door.x, door.y] = door.encoding
        return self._array

    _accepted_objects = Door

    def get_near_position(self, position: (int, int)) -> Union[None, Door]:
        try:
            return next(door for door in self if position in door.access_area)
        except StopIteration:
            return None

    def tick_doors(self):
        for door in self:
            door.tick()


class Actions(Register):

    _accepted_objects = Action

    @property
    def movement_actions(self):
        return self._movement_actions

    # noinspection PyTypeChecker
    def __init__(self, movement_properties: MovementProperties, can_use_doors=False):
        self.allow_no_op = movement_properties.allow_no_op
        self.allow_diagonal_movement = movement_properties.allow_diagonal_movement
        self.allow_square_movement = movement_properties.allow_square_movement
        self.can_use_doors = can_use_doors
        super(Actions, self).__init__()

        if self.allow_square_movement:
            self.register_additional_items([self._accepted_objects(enum_ident=direction)
                                            for direction in h.MovingAction.square()])
        if self.allow_diagonal_movement:
            self.register_additional_items([self._accepted_objects(enum_ident=direction)
                                            for direction in h.MovingAction.diagonal()])
        self._movement_actions = self._register.copy()
        if self.can_use_doors:
            self.register_additional_items([self._accepted_objects(enum_ident=h.EnvActions.USE_DOOR)])
        if self.allow_no_op:
            self.register_additional_items([self._accepted_objects(enum_ident=h.EnvActions.NOOP)])

    def is_moving_action(self, action: Union[int]):
        return action in self.movement_actions.values()


class Zones(Register):

    @property
    def accounting_zones(self):
        return [self[idx] for idx, name in self.items() if name != c.DANGER_ZONE.value]

    def __init__(self, parsed_level):
        raise NotImplementedError('This needs a Rework')
        super(Zones, self).__init__()
        slices = list()
        self._accounting_zones = list()
        self._danger_zones = list()
        for symbol in np.unique(parsed_level):
            if symbol == c.WALL.value:
                continue
            elif symbol == c.DANGER_ZONE.value:
                self + symbol
                slices.append(h.one_hot_level(parsed_level, symbol))
                self._danger_zones.append(symbol)
            else:
                self + symbol
                slices.append(h.one_hot_level(parsed_level, symbol))
                self._accounting_zones.append(symbol)

        self._zone_slices = np.stack(slices)

    def __getitem__(self, item):
        return self._zone_slices[item]

    def register_additional_items(self, other: Union[str, List[str]]):
        raise AttributeError('You are not allowed to add additional Zones in runtime.')