bevy/crates/bevy_reflect/src/generics.rs

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bevy_reflect: Generic parameter info (#15475) # Objective Currently, reflecting a generic type provides no information about the generic parameters. This means that you can't get access to the type of `T` in `Foo<T>` without creating custom type data (we do this for [`ReflectHandle`](https://docs.rs/bevy/0.14.2/bevy/asset/struct.ReflectHandle.html#method.asset_type_id)). ## Solution This PR makes it so that generic type parameters and generic const parameters are tracked in a `Generics` struct stored on the `TypeInfo` for a type. For example, `struct Foo<T, const N: usize>` will store `T` and `N` as a `TypeParamInfo` and `ConstParamInfo`, respectively. The stored information includes: - The name of the generic parameter (i.e. `T`, `N`, etc.) - The type of the generic parameter (remember that we're dealing with monomorphized types, so this will actually be a concrete type) - The default type/value, if any (e.g. `f32` in `T = f32` or `10` in `const N: usize = 10`) ### Caveats The only requirement for this to work is that the user does not opt-out of the automatic `TypePath` derive with `#[reflect(type_path = false)]`. Doing so prevents the macro code from 100% knowing that the generic type implements `TypePath`. This in turn means the generated `Typed` impl can't add generics to the type. There are two solutions for this—both of which I think we should explore in a future PR: 1. We could just not use `TypePath`. This would mean that we can't store the `Type` of the generic, but we can at least store the `TypeId`. 2. We could provide a way to opt out of the automatic `Typed` derive with a `#[reflect(typed = false)]` attribute. This would allow users to manually implement `Typed` to add whatever generic information they need (e.g. skipping a parameter that can't implement `TypePath` while the rest can). I originally thought about making `Generics` an enum with `Generic`, `NonGeneric`, and `Unavailable` variants to signify whether there are generics, no generics, or generics that cannot be added due to opting out of `TypePath`. I ultimately decided against this as I think it adds a bit too much complexity for such an uncommon problem. Additionally, user's don't necessarily _have_ to know the generics of a type, so just skipping them should generally be fine for now. ## Testing You can test locally by running: ``` cargo test --package bevy_reflect ``` --- ## Showcase You can now access generic parameters via `TypeInfo`! ```rust #[derive(Reflect)] struct MyStruct<T, const N: usize>([T; N]); let generics = MyStruct::<f32, 10>::type_info().generics(); // Get by index: let t = generics.get(0).unwrap(); assert_eq!(t.name(), "T"); assert!(t.ty().is::<f32>()); assert!(!t.is_const()); // Or by name: let n = generics.get_named("N").unwrap(); assert_eq!(n.name(), "N"); assert!(n.ty().is::<usize>()); assert!(n.is_const()); ``` You can even access parameter defaults: ```rust #[derive(Reflect)] struct MyStruct<T = String, const N: usize = 10>([T; N]); let generics = MyStruct::<f32, 5>::type_info().generics(); let GenericInfo::Type(info) = generics.get_named("T").unwrap() else { panic!("expected a type parameter"); }; let default = info.default().unwrap(); assert!(default.is::<String>()); let GenericInfo::Const(info) = generics.get_named("N").unwrap() else { panic!("expected a const parameter"); }; let default = info.default().unwrap(); assert_eq!(default.downcast_ref::<usize>().unwrap(), &10); ```
2024-09-30 17:58:37 +00:00
use crate::type_info::impl_type_methods;
use crate::{Reflect, Type, TypePath};
use alloc::{borrow::Cow, boxed::Box, sync::Arc};
bevy_reflect: Generic parameter info (#15475) # Objective Currently, reflecting a generic type provides no information about the generic parameters. This means that you can't get access to the type of `T` in `Foo<T>` without creating custom type data (we do this for [`ReflectHandle`](https://docs.rs/bevy/0.14.2/bevy/asset/struct.ReflectHandle.html#method.asset_type_id)). ## Solution This PR makes it so that generic type parameters and generic const parameters are tracked in a `Generics` struct stored on the `TypeInfo` for a type. For example, `struct Foo<T, const N: usize>` will store `T` and `N` as a `TypeParamInfo` and `ConstParamInfo`, respectively. The stored information includes: - The name of the generic parameter (i.e. `T`, `N`, etc.) - The type of the generic parameter (remember that we're dealing with monomorphized types, so this will actually be a concrete type) - The default type/value, if any (e.g. `f32` in `T = f32` or `10` in `const N: usize = 10`) ### Caveats The only requirement for this to work is that the user does not opt-out of the automatic `TypePath` derive with `#[reflect(type_path = false)]`. Doing so prevents the macro code from 100% knowing that the generic type implements `TypePath`. This in turn means the generated `Typed` impl can't add generics to the type. There are two solutions for this—both of which I think we should explore in a future PR: 1. We could just not use `TypePath`. This would mean that we can't store the `Type` of the generic, but we can at least store the `TypeId`. 2. We could provide a way to opt out of the automatic `Typed` derive with a `#[reflect(typed = false)]` attribute. This would allow users to manually implement `Typed` to add whatever generic information they need (e.g. skipping a parameter that can't implement `TypePath` while the rest can). I originally thought about making `Generics` an enum with `Generic`, `NonGeneric`, and `Unavailable` variants to signify whether there are generics, no generics, or generics that cannot be added due to opting out of `TypePath`. I ultimately decided against this as I think it adds a bit too much complexity for such an uncommon problem. Additionally, user's don't necessarily _have_ to know the generics of a type, so just skipping them should generally be fine for now. ## Testing You can test locally by running: ``` cargo test --package bevy_reflect ``` --- ## Showcase You can now access generic parameters via `TypeInfo`! ```rust #[derive(Reflect)] struct MyStruct<T, const N: usize>([T; N]); let generics = MyStruct::<f32, 10>::type_info().generics(); // Get by index: let t = generics.get(0).unwrap(); assert_eq!(t.name(), "T"); assert!(t.ty().is::<f32>()); assert!(!t.is_const()); // Or by name: let n = generics.get_named("N").unwrap(); assert_eq!(n.name(), "N"); assert!(n.ty().is::<usize>()); assert!(n.is_const()); ``` You can even access parameter defaults: ```rust #[derive(Reflect)] struct MyStruct<T = String, const N: usize = 10>([T; N]); let generics = MyStruct::<f32, 5>::type_info().generics(); let GenericInfo::Type(info) = generics.get_named("T").unwrap() else { panic!("expected a type parameter"); }; let default = info.default().unwrap(); assert!(default.is::<String>()); let GenericInfo::Const(info) = generics.get_named("N").unwrap() else { panic!("expected a const parameter"); }; let default = info.default().unwrap(); assert_eq!(default.downcast_ref::<usize>().unwrap(), &10); ```
2024-09-30 17:58:37 +00:00
use core::ops::Deref;
use derive_more::derive::From;
bevy_reflect: Generic parameter info (#15475) # Objective Currently, reflecting a generic type provides no information about the generic parameters. This means that you can't get access to the type of `T` in `Foo<T>` without creating custom type data (we do this for [`ReflectHandle`](https://docs.rs/bevy/0.14.2/bevy/asset/struct.ReflectHandle.html#method.asset_type_id)). ## Solution This PR makes it so that generic type parameters and generic const parameters are tracked in a `Generics` struct stored on the `TypeInfo` for a type. For example, `struct Foo<T, const N: usize>` will store `T` and `N` as a `TypeParamInfo` and `ConstParamInfo`, respectively. The stored information includes: - The name of the generic parameter (i.e. `T`, `N`, etc.) - The type of the generic parameter (remember that we're dealing with monomorphized types, so this will actually be a concrete type) - The default type/value, if any (e.g. `f32` in `T = f32` or `10` in `const N: usize = 10`) ### Caveats The only requirement for this to work is that the user does not opt-out of the automatic `TypePath` derive with `#[reflect(type_path = false)]`. Doing so prevents the macro code from 100% knowing that the generic type implements `TypePath`. This in turn means the generated `Typed` impl can't add generics to the type. There are two solutions for this—both of which I think we should explore in a future PR: 1. We could just not use `TypePath`. This would mean that we can't store the `Type` of the generic, but we can at least store the `TypeId`. 2. We could provide a way to opt out of the automatic `Typed` derive with a `#[reflect(typed = false)]` attribute. This would allow users to manually implement `Typed` to add whatever generic information they need (e.g. skipping a parameter that can't implement `TypePath` while the rest can). I originally thought about making `Generics` an enum with `Generic`, `NonGeneric`, and `Unavailable` variants to signify whether there are generics, no generics, or generics that cannot be added due to opting out of `TypePath`. I ultimately decided against this as I think it adds a bit too much complexity for such an uncommon problem. Additionally, user's don't necessarily _have_ to know the generics of a type, so just skipping them should generally be fine for now. ## Testing You can test locally by running: ``` cargo test --package bevy_reflect ``` --- ## Showcase You can now access generic parameters via `TypeInfo`! ```rust #[derive(Reflect)] struct MyStruct<T, const N: usize>([T; N]); let generics = MyStruct::<f32, 10>::type_info().generics(); // Get by index: let t = generics.get(0).unwrap(); assert_eq!(t.name(), "T"); assert!(t.ty().is::<f32>()); assert!(!t.is_const()); // Or by name: let n = generics.get_named("N").unwrap(); assert_eq!(n.name(), "N"); assert!(n.ty().is::<usize>()); assert!(n.is_const()); ``` You can even access parameter defaults: ```rust #[derive(Reflect)] struct MyStruct<T = String, const N: usize = 10>([T; N]); let generics = MyStruct::<f32, 5>::type_info().generics(); let GenericInfo::Type(info) = generics.get_named("T").unwrap() else { panic!("expected a type parameter"); }; let default = info.default().unwrap(); assert!(default.is::<String>()); let GenericInfo::Const(info) = generics.get_named("N").unwrap() else { panic!("expected a const parameter"); }; let default = info.default().unwrap(); assert_eq!(default.downcast_ref::<usize>().unwrap(), &10); ```
2024-09-30 17:58:37 +00:00
/// The generic parameters of a type.
///
/// This is automatically generated via the [`Reflect` derive macro]
/// and stored on the [`TypeInfo`] returned by [`Typed::type_info`]
/// for types that have generics.
///
/// It supports both type parameters and const parameters
/// so long as they implement [`TypePath`].
///
/// If the type has no generics, this will be empty.
///
/// If the type is marked with `#[reflect(type_path = false)]`,
/// the generics will be empty even if the type has generics.
///
/// [`Reflect` derive macro]: bevy_reflect_derive::Reflect
/// [`TypeInfo`]: crate::type_info::TypeInfo
/// [`Typed::type_info`]: crate::Typed::type_info
#[derive(Clone, Default, Debug)]
pub struct Generics(Box<[GenericInfo]>);
impl Generics {
/// Creates an empty set of generics.
pub fn new() -> Self {
Self(Box::new([]))
}
/// Finds the generic parameter with the given name.
///
/// Returns `None` if no such parameter exists.
pub fn get_named(&self, name: &str) -> Option<&GenericInfo> {
// For small sets of generics (the most common case),
// a linear search is often faster using a `HashMap`.
self.0.iter().find(|info| info.name() == name)
}
/// Adds the given generic parameter to the set.
pub fn with(mut self, info: impl Into<GenericInfo>) -> Self {
self.0 = IntoIterator::into_iter(self.0)
.chain(core::iter::once(info.into()))
.collect();
self
}
}
impl<T: Into<GenericInfo>> FromIterator<T> for Generics {
fn from_iter<I: IntoIterator<Item = T>>(iter: I) -> Self {
Self(iter.into_iter().map(Into::into).collect())
}
}
impl Deref for Generics {
type Target = [GenericInfo];
fn deref(&self) -> &Self::Target {
&self.0
}
}
/// An enum representing a generic parameter.
#[derive(Clone, Debug, From)]
bevy_reflect: Generic parameter info (#15475) # Objective Currently, reflecting a generic type provides no information about the generic parameters. This means that you can't get access to the type of `T` in `Foo<T>` without creating custom type data (we do this for [`ReflectHandle`](https://docs.rs/bevy/0.14.2/bevy/asset/struct.ReflectHandle.html#method.asset_type_id)). ## Solution This PR makes it so that generic type parameters and generic const parameters are tracked in a `Generics` struct stored on the `TypeInfo` for a type. For example, `struct Foo<T, const N: usize>` will store `T` and `N` as a `TypeParamInfo` and `ConstParamInfo`, respectively. The stored information includes: - The name of the generic parameter (i.e. `T`, `N`, etc.) - The type of the generic parameter (remember that we're dealing with monomorphized types, so this will actually be a concrete type) - The default type/value, if any (e.g. `f32` in `T = f32` or `10` in `const N: usize = 10`) ### Caveats The only requirement for this to work is that the user does not opt-out of the automatic `TypePath` derive with `#[reflect(type_path = false)]`. Doing so prevents the macro code from 100% knowing that the generic type implements `TypePath`. This in turn means the generated `Typed` impl can't add generics to the type. There are two solutions for this—both of which I think we should explore in a future PR: 1. We could just not use `TypePath`. This would mean that we can't store the `Type` of the generic, but we can at least store the `TypeId`. 2. We could provide a way to opt out of the automatic `Typed` derive with a `#[reflect(typed = false)]` attribute. This would allow users to manually implement `Typed` to add whatever generic information they need (e.g. skipping a parameter that can't implement `TypePath` while the rest can). I originally thought about making `Generics` an enum with `Generic`, `NonGeneric`, and `Unavailable` variants to signify whether there are generics, no generics, or generics that cannot be added due to opting out of `TypePath`. I ultimately decided against this as I think it adds a bit too much complexity for such an uncommon problem. Additionally, user's don't necessarily _have_ to know the generics of a type, so just skipping them should generally be fine for now. ## Testing You can test locally by running: ``` cargo test --package bevy_reflect ``` --- ## Showcase You can now access generic parameters via `TypeInfo`! ```rust #[derive(Reflect)] struct MyStruct<T, const N: usize>([T; N]); let generics = MyStruct::<f32, 10>::type_info().generics(); // Get by index: let t = generics.get(0).unwrap(); assert_eq!(t.name(), "T"); assert!(t.ty().is::<f32>()); assert!(!t.is_const()); // Or by name: let n = generics.get_named("N").unwrap(); assert_eq!(n.name(), "N"); assert!(n.ty().is::<usize>()); assert!(n.is_const()); ``` You can even access parameter defaults: ```rust #[derive(Reflect)] struct MyStruct<T = String, const N: usize = 10>([T; N]); let generics = MyStruct::<f32, 5>::type_info().generics(); let GenericInfo::Type(info) = generics.get_named("T").unwrap() else { panic!("expected a type parameter"); }; let default = info.default().unwrap(); assert!(default.is::<String>()); let GenericInfo::Const(info) = generics.get_named("N").unwrap() else { panic!("expected a const parameter"); }; let default = info.default().unwrap(); assert_eq!(default.downcast_ref::<usize>().unwrap(), &10); ```
2024-09-30 17:58:37 +00:00
pub enum GenericInfo {
/// A type parameter.
///
/// An example would be `T` in `struct Foo<T, U>`.
Type(TypeParamInfo),
/// A const parameter.
///
/// An example would be `N` in `struct Foo<const N: usize>`.
Const(ConstParamInfo),
}
impl GenericInfo {
/// The name of the generic parameter.
pub fn name(&self) -> &Cow<'static, str> {
match self {
Self::Type(info) => info.name(),
Self::Const(info) => info.name(),
}
}
/// Whether the generic parameter is a const parameter.
pub fn is_const(&self) -> bool {
match self {
Self::Type(_) => false,
Self::Const(_) => true,
}
}
impl_type_methods!(self => {
match self {
Self::Type(info) => info.ty(),
Self::Const(info) => info.ty(),
}
});
}
/// Type information for a generic type parameter.
///
/// An example of a type parameter would be `T` in `struct Foo<T>`.
#[derive(Clone, Debug)]
pub struct TypeParamInfo {
name: Cow<'static, str>,
ty: Type,
default: Option<Type>,
}
impl TypeParamInfo {
/// Creates a new type parameter with the given name.
pub fn new<T: TypePath + ?Sized>(name: impl Into<Cow<'static, str>>) -> Self {
Self {
name: name.into(),
ty: Type::of::<T>(),
default: None,
}
}
/// Sets the default type for the parameter.
pub fn with_default<T: TypePath + ?Sized>(mut self) -> Self {
self.default = Some(Type::of::<T>());
self
}
/// The name of the type parameter.
pub fn name(&self) -> &Cow<'static, str> {
&self.name
}
/// The default type for the parameter, if any.
///
/// # Example
///
/// ```
/// # use bevy_reflect::{GenericInfo, Reflect, Typed};
/// #[derive(Reflect)]
/// struct Foo<T = f32>(T);
///
/// let generics = Foo::<String>::type_info().generics();
/// let GenericInfo::Type(info) = generics.get_named("T").unwrap() else {
/// panic!("expected a type parameter");
/// };
///
/// let default = info.default().unwrap();
///
/// assert!(default.is::<f32>());
/// ```
pub fn default(&self) -> Option<&Type> {
self.default.as_ref()
}
impl_type_methods!(ty);
}
/// Type information for a const generic parameter.
///
/// An example of a const parameter would be `N` in `struct Foo<const N: usize>`.
#[derive(Clone, Debug)]
pub struct ConstParamInfo {
name: Cow<'static, str>,
ty: Type,
// Rust currently only allows certain primitive types in const generic position,
// meaning that `Reflect` is guaranteed to be implemented for the default value.
default: Option<Arc<dyn Reflect>>,
}
impl ConstParamInfo {
/// Creates a new const parameter with the given name.
pub fn new<T: TypePath + ?Sized>(name: impl Into<Cow<'static, str>>) -> Self {
Self {
name: name.into(),
ty: Type::of::<T>(),
default: None,
}
}
/// Sets the default value for the parameter.
pub fn with_default<T: Reflect + 'static>(mut self, default: T) -> Self {
self.default = Some(Arc::new(default));
self
}
/// The name of the const parameter.
pub fn name(&self) -> &Cow<'static, str> {
&self.name
}
/// The default value for the parameter, if any.
///
/// # Example
///
/// ```
/// # use bevy_reflect::{GenericInfo, Reflect, Typed};
/// #[derive(Reflect)]
/// struct Foo<const N: usize = 10>([u8; N]);
///
/// let generics = Foo::<5>::type_info().generics();
/// let GenericInfo::Const(info) = generics.get_named("N").unwrap() else {
/// panic!("expected a const parameter");
/// };
///
/// let default = info.default().unwrap();
///
/// assert_eq!(default.downcast_ref::<usize>().unwrap(), &10);
/// ```
pub fn default(&self) -> Option<&dyn Reflect> {
self.default.as_deref()
}
impl_type_methods!(ty);
}
macro_rules! impl_generic_info_methods {
// Implements both getter and setter methods for the given field.
($field:ident) => {
$crate::generics::impl_generic_info_methods!(self => &self.$field);
/// Sets the generic parameters for this type.
pub fn with_generics(mut self, generics: crate::generics::Generics) -> Self {
self.$field = generics;
self
}
};
// Implements only a getter method for the given expression.
($self:ident => $expr:expr) => {
/// Gets the generic parameters for this type.
pub fn generics(&$self) -> &crate::generics::Generics {
$expr
}
};
}
pub(crate) use impl_generic_info_methods;
#[cfg(test)]
mod tests {
use super::*;
use crate as bevy_reflect;
use crate::{Reflect, Typed};
use core::fmt::Debug;
#[test]
fn should_maintain_order() {
#[derive(Reflect)]
struct Test<T, U: Debug, const N: usize>([(T, U); N]);
let generics = <Test<f32, String, 10> as Typed>::type_info()
.as_tuple_struct()
.unwrap()
.generics();
assert_eq!(generics.len(), 3);
let mut iter = generics.iter();
let t = iter.next().unwrap();
assert_eq!(t.name(), "T");
assert!(t.ty().is::<f32>());
assert!(!t.is_const());
let u = iter.next().unwrap();
assert_eq!(u.name(), "U");
assert!(u.ty().is::<String>());
assert!(!u.is_const());
let n = iter.next().unwrap();
assert_eq!(n.name(), "N");
assert!(n.ty().is::<usize>());
assert!(n.is_const());
assert!(iter.next().is_none());
}
#[test]
fn should_get_by_name() {
#[derive(Reflect)]
enum Test<T, U: Debug, const N: usize> {
Array([(T, U); N]),
}
let generics = <Test<f32, String, 10> as Typed>::type_info()
.as_enum()
.unwrap()
.generics();
let t = generics.get_named("T").unwrap();
assert_eq!(t.name(), "T");
assert!(t.ty().is::<f32>());
assert!(!t.is_const());
let u = generics.get_named("U").unwrap();
assert_eq!(u.name(), "U");
assert!(u.ty().is::<String>());
assert!(!u.is_const());
let n = generics.get_named("N").unwrap();
assert_eq!(n.name(), "N");
assert!(n.ty().is::<usize>());
assert!(n.is_const());
}
#[test]
fn should_store_defaults() {
#[derive(Reflect)]
struct Test<T, U: Debug = String, const N: usize = 10>([(T, U); N]);
let generics = <Test<f32> as Typed>::type_info()
.as_tuple_struct()
.unwrap()
.generics();
let GenericInfo::Type(u) = generics.get_named("U").unwrap() else {
panic!("expected a type parameter");
};
assert_eq!(u.default().unwrap(), &Type::of::<String>());
let GenericInfo::Const(n) = generics.get_named("N").unwrap() else {
panic!("expected a const parameter");
};
assert_eq!(n.default().unwrap().downcast_ref::<usize>().unwrap(), &10);
}
}