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type_data.rs
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type_data.rs
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//! The example demonstrates what type data is, how to create it, and how to use it.
use bevy::prelude::*;
use bevy::reflect::{FromType, TypeRegistry};
// It's recommended to read this example from top to bottom.
// Comments are provided to explain the code and its purpose as you go along.
fn main() {
trait Damageable {
type Health;
fn damage(&mut self, damage: Self::Health);
}
#[derive(Reflect, PartialEq, Debug)]
struct Zombie {
health: u32,
}
impl Damageable for Zombie {
type Health = u32;
fn damage(&mut self, damage: Self::Health) {
self.health -= damage;
}
}
// Let's say we have a reflected value.
// Here we know it's a `Zombie`, but for demonstration purposes let's pretend we don't.
// Pretend it's just some `Box<dyn Reflect>` value.
let mut value: Box<dyn Reflect> = Box::new(Zombie { health: 100 });
// We think `value` might contain a type that implements `Damageable`
// and now we want to call `Damageable::damage` on it.
// How can we do this without knowing in advance the concrete type is `Zombie`?
// This is where type data comes in.
// Type data is a way of associating type-specific data with a type for use in dynamic contexts.
// This type data can then be used at runtime to perform type-specific operations.
// Let's create a type data struct for `Damageable` that we can associate with `Zombie`!
// Firstly, type data must be cloneable.
#[derive(Clone)]
// Next, they are usually named with the `Reflect` prefix (we'll see why in a bit).
struct ReflectDamageable {
// Type data can contain whatever you want, but it's common to include function pointers
// to the type-specific operations you want to perform (such as trait methods).
// Just remember that we're working with `Reflect` data,
// so we can't use `Self`, generics, or associated types.
// In those cases, we'll have to use `dyn Reflect` trait objects.
damage: fn(&mut dyn Reflect, damage: Box<dyn Reflect>),
}
// Now, we can create a blanket implementation of the `FromType` trait to construct our type data
// for any type that implements `Reflect` and `Damageable`.
impl<T: Reflect + Damageable<Health: Reflect>> FromType<T> for ReflectDamageable {
fn from_type() -> Self {
Self {
damage: |reflect, damage| {
// This requires that `reflect` is `T` and not a dynamic representation like `DynamicStruct`.
// We could have the function pointer return a `Result`, but we'll just `unwrap` for simplicity.
let damageable = reflect.downcast_mut::<T>().unwrap();
let damage = damage.take::<T::Health>().unwrap();
damageable.damage(damage);
},
}
}
}
// It's also common to provide convenience methods for calling the type-specific operations.
impl ReflectDamageable {
pub fn damage(&self, reflect: &mut dyn Reflect, damage: Box<dyn Reflect>) {
(self.damage)(reflect, damage);
}
}
// With all this done, we're ready to make use of `ReflectDamageable`!
// It starts with registering our type along with its type data:
let mut registry = TypeRegistry::default();
registry.register::<Zombie>();
registry.register_type_data::<Zombie, ReflectDamageable>();
// Then at any point we can retrieve the type data from the registry:
let type_id = value.get_represented_type_info().unwrap().type_id();
let reflect_damageable = registry
.get_type_data::<ReflectDamageable>(type_id)
.unwrap();
// And call our method:
reflect_damageable.damage(value.as_reflect_mut(), Box::new(25u32));
assert_eq!(value.take::<Zombie>().unwrap(), Zombie { health: 75 });
// This is a simple example, but type data can be used for much more complex operations.
// Bevy also provides some useful shorthand for working with type data.
// For example, we can have the type data be automatically registered when we register the type
// by using the `#[reflect(MyTrait)]` attribute when defining our type.
#[derive(Reflect)]
// Notice that we don't need to type out `ReflectDamageable`.
// This is why we named it with the `Reflect` prefix:
// the derive macro will automatically look for a type named `ReflectDamageable` in the current scope.
#[reflect(Damageable)]
struct Skeleton {
health: u32,
}
impl Damageable for Skeleton {
type Health = u32;
fn damage(&mut self, damage: Self::Health) {
self.health -= damage;
}
}
// This will now register `Skeleton` along with its `ReflectDamageable` type data.
registry.register::<Skeleton>();
// And for object-safe traits (see https://doc.rust-lang.org/reference/items/traits.html#object-safety),
// Bevy provides a convenience macro for generating type data that converts `dyn Reflect` into `dyn MyTrait`.
#[reflect_trait]
trait Health {
fn health(&self) -> u32;
}
impl Health for Skeleton {
fn health(&self) -> u32 {
self.health
}
}
// Using the `#[reflect_trait]` macro we're able to automatically generate a `ReflectHealth` type data struct,
// which can then be registered like any other type data:
registry.register_type_data::<Skeleton, ReflectHealth>();
// Now we can use `ReflectHealth` to convert `dyn Reflect` into `dyn Health`:
let value: Box<dyn Reflect> = Box::new(Skeleton { health: 50 });
let type_id = value.get_represented_type_info().unwrap().type_id();
let reflect_health = registry.get_type_data::<ReflectHealth>(type_id).unwrap();
// Type data generated by `#[reflect_trait]` comes with a `get`, `get_mut`, and `get_boxed` method,
// which convert `&dyn Reflect` into `&dyn MyTrait`, `&mut dyn Reflect` into `&mut dyn MyTrait`,
// and `Box<dyn Reflect>` into `Box<dyn MyTrait>`, respectively.
let value: &dyn Health = reflect_health.get(value.as_reflect()).unwrap();
assert_eq!(value.health(), 50);
// Lastly, here's a list of some useful type data provided by Bevy that you might want to register for your types:
// - `ReflectDefault` for types that implement `Default`
// - `ReflectFromWorld` for types that implement `FromWorld`
// - `ReflectComponent` for types that implement `Component`
// - `ReflectResource` for types that implement `Resource`
// - `ReflectSerialize` for types that implement `Serialize`
// - `ReflectDeserialize` for types that implement `Deserialize`
//
// And here are some that are automatically registered by the `Reflect` derive macro:
// - `ReflectFromPtr`
// - `ReflectFromReflect` (if not `#[reflect(from_reflect = false)]`)
}