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A type-hinted Entity Component System based on Python dictionaries and sets.

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tcod-ecs is a Sparse-set Entity-component-system implemented using Python's dict and set types. See the ECS FAQ for more info.

This implementation focuses on type-hinting, organization, and is designed to work well with Python. The following features are currently implemented:

  • Entities can store components which are instances of any Python object. Components are looked up by their type.
  • Entities can have one instance of a type, or multiple instances of a type using a hashable tag to differentiate them.
  • Entity relationships are supported, either as many-to-many or many-to-one relationships.
  • ECS Queries can be made to fetch entities having a combination of components/tags/relations or excluding such.
  • The ECS World object can be serialized with Python's pickle module for easy storage.

A lightweight version which implements only the entity-component framework exists called tcod-ec. tcod-ec was geared towards a dynamic-typed-dict style of syntax and is missing a lot of important features such as queries and named components.

Installation

Use pip to install this library:

pip install tcod-ecs

If tcod is installed and the version is less than 14.0.0 then import tcod.ecs will fail. Remove or update tcod to fix this issue.

Examples

World

>>> import tcod.ecs
>>> world = tcod.ecs.World()  # New empty world

Entity

Each Entity is identified by its unique id (uid) which can be any hashable object combined with the world it belongs. New unique entities can be created with World.new_entity which uses a new object() as the uid, this guarantees uniqueness which is not always desireable. An entity always knows about its assigned world, which can be access with the Entity.world property from any Entity instance. Worlds only know about their entities once the entity is assigned a name, component, tag, or relation.

>>> entity = world.new_entity()  # Creates a unique entity using `object()` as the uid
>>> entity
<Entity(uid=object at ...)>
>>> entity.world is world  # Worlds can always be accessed from their entity
True
>>> world[entity.uid] is entity  # Entities with the same world/uid are compared using `is`
True

# Reference an entity with the given uid, can be any hashable object:
>>> entity = world["MyEntity"]
>>> entity
<Entity(uid='MyEntity')>
>>> world["MyEntity"] is entity  # Matching entities ALWAYS share a single identity
True

Use World.new_entity to create unique entities and use World[x] to reference a global entity or relation with an id. World[None] is recommend for use as a global entity when you want to store components in the world itself.

Do not save the uid's of entities to be used later with World[uid], this process is slower than holding onto the Entity instance.

Serialization

Worlds are normal Python objects and can be pickled as long as all stored components are pickleable.

>>> import pickle
>>> pickled_data: bytes = pickle.dumps(world)
>>> world = pickle.loads(pickled_data)

Stability is a priority but changes may still break older saves. Backwards compatibility is not a priority, pickled worlds should not be unpickled with an older version of the library. This project follows Semantic Versioning, major version increments will break the API, the save format or both, minor version increments may break backwards compatibility. Check the changelog to be aware of format changes and breaks. There should always be a transition period before a format break, so keeping up with the latest version is a good idea.

Components

Components are instances of any Python type. These can be accessed, assigned, or removed from entities via the dict-like Entity.components attribute. The type is used as the key to access the component. The types used can be custom classes or standard Python types.

>>> import attrs
>>> entity = world.new_entity()
>>> entity.components[int] = 42
>>> entity.components[int]
42
>>> int in entity.components
True
>>> del entity.components[int]
>>> entity.components[int]  # Missing keys raise KeyError
Traceback (most recent call last):
  ...
KeyError: <class 'int'>
>>> entity.components.get(int, "default")  # Test keys with `.get()` like a dictionary
'default'
>>> @attrs.define
... class Vector2:
...     x: int = 0
...     y: int = 0
>>> entity.components[Vector2] = Vector2(1, 2)
>>> entity.components[Vector2]
Vector2(x=1, y=2)
>>> entity.components |= {int: 11, Vector2: Vector2(0, 0)}  # Multiple values can be assigned like a dict
>>> entity.components[int]
11
>>> entity.components[Vector2]
Vector2(x=0, y=0)

# Queries can be made on all entities of a world with matching components
>>> for e in world.Q.all_of(components=[Vector2]):
...     e.components[Vector2].x += 10
>>> entity.components[Vector2]
Vector2(x=10, y=0)

# You can match components and iterate over them at the same time.  This can be combined with the above
>>> for pos, i in world.Q[Vector2, int]:
...     print((pos, i))
(Vector2(x=10, y=0), 11)

# You can include `Entity` to iterate over entities with their components
# This always iterates over the entity itself instead of an Entity component
>>> for e, pos, i in world.Q[tcod.ecs.Entity, Vector2, int]:
...     print((e, pos, i))
(<Entity...>, Vector2(x=10, y=0), 11)

Named Components

Only one component can be assigned unless that component is given a unique name. You can name components with the key syntax (name, type) when assigning components. Names are not limited to strings, they are a tag equivalent and can be any hashable or frozen object. The syntax [type] and [(name, type)] can be used interchangeably in all places accepting a component key. Queries on components access named components with the same syntax and must use names explicitly.

>>> entity = world.new_entity()
>>> entity.components[Vector2] = Vector2(0, 0)
>>> entity.components[("velocity", Vector2)] = Vector2(1, 1)
>>> entity.components[("velocity", Vector2)]
Vector2(x=1, y=1)
>>> @attrs.define(frozen=True)
... class Slot:
...     index: int
>>> entity.components |= {  # Like a dict Entity.components can use |= to update items in-place
...     ("hp", int): 10,
...     ("max_hp", int): 12,
...     ("atk", int): 1,
...     str: "foo",
...     (Slot(1), str): "empty",
... }
>>> entity.components[("hp", int)]
10
>>> entity.components[str]
'foo'
>>> entity.components[(Slot(1), str)]
'empty'

# Queries can be made on all named components with the same syntax as normal ones
>>> for e in world.Q.all_of(components=[("hp", int), ("max_hp", int)]):
...     e.components[("hp", int)] = e.components[("max_hp", int)]
>>> entity.components[("hp", int)]
12
>>> for e, pos, delta in world.Q[tcod.ecs.Entity, Vector2, ("velocity", Vector2)]:
...     e.components[Vector2] = Vector2(pos.x + delta.x, pos.y + delta.y)
>>> entity.components[Vector2]
Vector2(x=1, y=1)

Tags

Tags are hashable objects stored in the set-like Entity.tags. These are useful as flags or to group entities together.

>>> entity = world.new_entity()
>>> entity.tags.add("player")  # Works well for groups
>>> "player" in entity.tags
True
>>> entity.tags.add(("eats", "fruit"))
>>> entity.tags.add(("eats", "meat"))
>>> set(world.Q.all_of(tags=["player"])) == {entity}
True

Relations

Use Entity.relation_components[component_key][target] = component to associate a target entity with a component. Use Entity.relation_tag[tag] = target to associate a tag exclusively with a target entity. Use Entity.relation_tags_many[tag].add(target) to associate a tag with multiple targets.

Relation queries are a little more complex than other queries. Relation tags and relation components share the same space then queried, so 'normal' tags should not be in the format of a component key. Relations are unidirectional, but you can query either end of a relation.

>>> @attrs.define
... class OrbitOf:  # OrbitOf component
...     dist: int
>>> LandedOn = "LandedOn"  # LandedOn tag
>>> star = world.new_entity()
>>> planet = world.new_entity()
>>> moon = world.new_entity()
>>> ship = world.new_entity()
>>> player = world.new_entity()
>>> moon_rock = world.new_entity()
>>> planet.relation_components[OrbitOf][star] = OrbitOf(dist=1000)
>>> moon.relation_components[OrbitOf][planet] = OrbitOf(dist=10)
>>> ship.relation_tag[LandedOn] = moon
>>> moon_rock.relation_tag[LandedOn] = moon
>>> player.relation_tag[LandedOn] = moon_rock
>>> set(world.Q.all_of(relations=[(OrbitOf, planet)])) == {moon}
True
>>> set(world.Q.all_of(relations=[(OrbitOf, ...)])) == {planet, moon}  # Get objects in an orbit
True
>>> set(world.Q.all_of(relations=[(..., OrbitOf, None)])) == {star, planet}  # Get objects being orbited
True
>>> set(world.Q.all_of(relations=[(LandedOn, ...)])) == {ship, moon_rock, player}
True
>>> set(world.Q.all_of(relations=[(LandedOn, ...)]).none_of(relations=[(LandedOn, moon)])) == {player}
True

Relation queries

You can use the following table to help with constructing relation queries. tag is a component key if you are querying for a component relation.

Includes Syntax
Entities with a relation tag to the given target (tag, target_entity)
Entities with a relation tag to any target (tag, ...) (Literal dot-dot-dot)
Entities with a relation tag to the targets in the given query (tag, world.Q.all_of(...))
The target entities of a relation of a given entity (origin_entity, tag, None)
The target entities of any entity with the given relation tag (..., tag, None) (Literal dot-dot-dot)
The target entities of the queried entities with the given relation (tag, world.Q.all_of(...))

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