esper is a lightweight Entity System (ECS) for Python, with a focus on performance
Project description
Esper is a lightweight Entity System module for Python, with a focus on performance
Esper is an MIT licensed Entity System, or, Entity Component System (ECS). The design is based on the Entity System concepts originally popularized by Adam Martin and others. The primary focus for esper is to maximize perfomance, while handling most common use cases.
For more information on the ECS pattern, you might find the following resources interesting: https://github.com/SanderMertens/ecs-faq/blob/master/README.md https://github.com/jslee02/awesome-entity-component-system/blob/master/README.md https://en.wikipedia.org/wiki/Entity_component_system
API documentation is hosted at ReadTheDocs: https://esper.readthedocs.io Due to the small size of the project, this README currently serves as general usage documentation.
:warning: Esper 3.0 introduces breaking changes. Version 3.0 removes the World object, and migrates its methods to module level functions. Multiple contexts can be created and switched between. The v2.x README can be found here: https://github.com/benmoran56/esper/blob/v2_maintenance/README.md
Compatibility
Esper attempts to target all currently supported Python releases (any Python version that is not EOL). Esper is written in 100% pure Python, so any compliant interpreter should work. Automated testing is currently done for both CPython and PyPy3.
Installation
Esper is a pure Python package with no dependencies, so installation is flexible.
You can simply copy the esper folder right into your project, and import esper.
You can also install into your site-packages from PyPi via pip
::
pip install --user --upgrade esper
Or from the source directory::
pip install . --user
Design
- World Context
Esper uses the concept of "World" contexts. When you first import esper
, a default context is
active. You create Entities, assign Components, register Processesors, etc., by calling functions
on the esper
module. Entities, Components and Processors can be created, assigned, or deleted
while your game is running. A simple call to esper.process()
is all that's needed for each
iteration of your game loop. Advanced users can switch contexts, which can be useful for
isolating different game scenes that have different Processor requirements.
- Entities
Entities are simple integer IDs (1, 2, 3, 4, etc.).
Entities are "created", but they are generally not used directly. Instead, they are
simply used as IDs in the internal Component database to track collections of Components.
Creating an Entity is done with the esper.create_entity()
function.
- Components
Components are defined as simple Python classes. In keeping with a pure Entity System design philosophy, they should not contain any logic. They might have initialization code or perhaps Python properties, but no processing logic whatsoever. A simple Component can be defined as::
class Position:
def __init__(self, x=0.0, y=0.0):
self.x = x
self.y = y
To save on typing, the standard library dataclass decorator is quite useful. https://docs.python.org/3/library/dataclasses.html#module-dataclasses This decorator simplifies defining your Component classes. The attribute names don't need to be repeated, and you can still instantiate the Component with positional or keyword arguments::
from dataclasses import dataclass as component
@component
class Position:
x: float = 0.0
y: float = 0.0
- Processors
Processors, also commonly known as "Systems", are where all processing logic is defined and executed. All Processors must inherit from the esper.Processor class, and have a method called process. Other than that, there are no restrictions. You can define any additional methods you might need. A simple Processor might look like::
class MovementProcessor(esper.Processor):
def process(self):
for ent, (vel, pos) in esper.get_components(Velocity, Position):
pos.x += vel.x
pos.y += vel.y
In the above code, you can see the standard usage of the esper.get_components() function. This function allows efficient iteration over all Entities that contain the specified Component types. This function can be used for querying two or more components at once. Note that tuple unpacking is necessary for the return component pairs: (vel, pos). In addition the Components, you also get a reference to the Entity ID (the ent object) for the current pair of Velocity/Position Components. This entity ID can be useful in a variety of cases. For example, if your Processor will need to delete certain Entites, you can call the esper.delete_entity() function on this Entity ID. Another common use is if you wish to add or remove a Component on this Entity as a result of some condition being met.
Quick Start
To get started, simply import esper::
import esper
From there, define some Components, and create Entities that use them::
player = esper.create_entity()
esper.add_component(player, Velocity(x=0.9, y=1.2))
esper.add_component(player, Position(x=5, y=5))
Optionally, Component instances can be assigned directly to the Entity on creation::
player = esper.create_entity(Velocity(x=0.9, y=1.2), Position(x=5, y=5))
Design some Processors that operate on these Component types, and then register them with Esper for processing. You can specify an optional priority (higher numbers are processed first). All Processors are priority "0" by default::
movement_processor = MovementProcessor()
collision_processor = CollisionProcessor()
rendering_processor = RenderingProcessor()
esper.add_processor(collision_processor, priority=2)
esper.add_processor(movement_processor, priority=3)
esper.add_processor(rendering_processor)
# or just add them in one line:
esper.add_processor(SomeProcessor())
Executing all Processors is done with a single call to esper.process(). This will call the
process
method on all assigned Processors, in order of their priority. This is usually called
once per frame update of your game (every tick of the clock).::
esper.process()
Note: You can pass any arguments (or keyword arguments) you need to esper.process(), but you must also make sure to receive them properly in the process() methods of your Processors. For example, if you pass a delta time argument as esper.process(dt), your Processor's process() methods should all receive it as: def process(self, dt): This is appropriate for libraries such as pyglet, which automatically pass a delta time value into scheduled functions.
General Usage
World Contexts
Esper has the capability of supporting multiple "World" contexts. On import, a "default" World is active. All creation of Entities, assignment of Processors, and all other operations occur within the confines of the active World. In other words, the World contexts are completely isolated from each other. For basic games and designs, you may not need to bother with this functionality. A single default World context can often be enough. For advanced use cases, such as when different scenes in your game have different Entities and Processor requirements, this functionality can be quite useful. World context operations are done with the following functions:: *
- esper.list_worlds()
- esper.switch_world(name)
- esper.delete_world(name)
When switching Worlds, be mindful of the name
. If a World doesn't exist, it will be created when
you first switch to it. You can delete old Worlds if they are no longer needed, but you can not
delete the currently active World.
Adding and Removing Processors
You have already seen examples of adding Processors in an earlier section. There is also a remove_processor function available:
- esper.add_processor(processor_instance)
- esper.remove_processor(ProcessorClass)
Depending on the structure of your game, you may want to add or remove certain Processors when changing scenes, etc.
Adding and Removing Components
In addition to adding Components to Entities when you're creating them, it's a common pattern to add or remove Components inside your Processors. The following functions are available for this purpose:
- esper.add_component(entity_id, component_instance)
- esper.remove_component(entity_id, ComponentClass)
As an example of this, you could have a "Blink" component with a duration attribute. This can be used to make certain things blink for s specific period of time, then disappear. For example, the code below shows a simplified case of adding this Component to an Entity when it takes damage in one processor. A dedicated BlinkProcessor handles the effect, and then removes the Component after the duration expires::
class BlinkComponent:
def __init__(self, duration):
self.duration = duration
.....
class CollisionProcessor(esper.Processor):
def process(self, dt):
for ent, enemy in esper.get_component(Enemy):
...
is_damaged = self._some_method()
if is_damaged:
esper.add_component(ent, BlinkComponent(duration=1))
...
class BlinkProcessor(esper.Processor):
def process(self, dt):
for ent, (rend, blink) in esper.get_components(Renderable, BlinkComponent):
if blink.duration < 0:
# Times up. Remove the Component:
rend.sprite.visible = True
esper.remove_component(ent, BlinkComponent)
else:
blink.duration -= dt
# Toggle between visible and not visible each frame:
rend.sprite.visible = not rend.sprite.visible
Querying Specific Components
If you have an Entity ID and wish to query one specific, or ALL Components that are assigned to it, the following functions are available:
- esper.component_for_entity
- esper.components_for_entity
The component_for_entity function is useful in a limited number of cases where you know a specific Entity ID, and wish to get a specific Component for it. An error is raised if the Component does not exist for the Entity ID, so it may be more useful when combined with the has_component function that is explained in the next section. For example::
if esper.has_component(ent, SFX):
sfx = esper.component_for_entity(ent, SFX)
sfx.play()
The components_for_entity function is a special function that returns ALL the Components that are
assigned to a specific Entity, as a tuple. This is a heavy operation, and not something you would
want to do each frame or inside your Processor.process
method. It can be useful, however, if
you wanted to transfer all of a specific Entity's Components between two separate contexts
(such as when changing Scenes, or levels). For example::
player_components = esper.components_for_entity(player_entity_id)
esper.switch_world('context_name')
player_entity_id = esper.create_entity(player_components)
Boolean and Conditional Checks
In some cases you may wish to check if an Entity has a specific Component before performing some action. The following functions are available for this task:
- esper.has_component(entity, ComponentType)
- esper.has_components(entity, ComponentTypeA, ComponentTypeB)
- esper.try_component(entity, ComponentType)
- esper.try_components(entity, ComponentTypeA, ComponentTypeB)
For example, you may want projectiles (and only projectiles) to disappear when hitting a wall in
your game. We can do this by checking if the Entity has a Projectile
Component. We don't want
to do anything to this Component, simply check if it's there. Consider this example::
class CollisionProcessor(esper.Processor):
def process(self, dt):
for ent, body in esper.get_component(PhysicsBody):
...
colliding_with_wall = self._some_method(body):
if colliding_with_wall and esper.has_component(ent, Projectile):
esper.delete_entity(ent)
...
In a different scenario, we may want to perform some action on an Entity's Component, if it has
one. For example, a MovementProcessor that skips over Entities that have a Stun
Component::
class MovementProcessor(esper.Processor):
def process(self, dt):
for ent, (body, vel) in esper.get_components(PhysicsBody, Velocity):
if esper.has_component(ent, Stun):
stun = esper.component_for_entity(ent, Stun)
stun.duration -= dt
if stun.duration <= 0:
esper.remove_component(ent, Stun)
continue # Continue to the next Entity
movement_code_here()
...
Let's look at the core part of the code::
if esper.has_component(ent, Stun):
stun = esper.component_for_entity(ent, Stun)
stun.duration -= dt
This code works fine, but the try_component function can accomplish the same thing with one less function call. The following example will get a specific Component if it exists, or return None if it does not::
stun = esper.try_component(ent, Stun)
if stun:
stun.duration -= dt
With Python 3.8+, the new "walrus" operator (:=
) can also be used, making the try_component
functions even more concise ::
if stun := esper.try_component(ent, Stun):
stun.duration -= dt
More Examples
See the /examples folder to get an idea of how the basic structure of a game might look.
Event Dispatching
Esper includes basic support for event dispatching and handling. This functionality is provided by three functions to set (register), remove, and dispatch events. Minimal error checking is done, so it's left up to the user to ensure correct naming and number of arguments are used when dispatching and receiving events.
Events are dispatched by name::
esper.dispatch_event('event_name', arg1, arg2)
In order to receive the above event, you must register handlers. An event handler can be a function or class method. Registering a handler is also done by name::
esper.set_handler('event_name', my_func)
# or
esper.set_handler('event_name', self.my_method)
Note: Only weak-references are kept to the registered handlers. If a handler is garbage collected, it will be automatically un-registered by an internal callback.
Handlers can also be removed at any time, if you no longer want them to receive events::
esper.remove_handler('event_name', my_func)
# or
esper.remove_handler('event_name', self.my_method)
Registered events and handlers are part of the current World
context.
Contributing
Contributions to Esper are always welcome, but there are some specific project goals to keep in mind:
- Pure Python code only: no binary extensions, Cython, etc.
- Try to target all non-EOL Python versions. Exceptions can be made if there is a compelling reason.
- Avoid bloat as much as possible. New features will be considered if they are commonly useful. Generally speaking, we don't want to add functionality that is better served by another module or library.
- Performance is preferrable to readability. The public API should remain clean, but ugly internal code is acceptable if it provides a performance benefit. Every cycle counts!
If you have any questions before contributing, feel free to open an issue.
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