use crate::{ array_debug, enum_debug, list_debug, map_debug, serde::Serializable, struct_debug, tuple_debug, tuple_struct_debug, Array, Enum, List, Map, Struct, Tuple, TupleStruct, TypeInfo, Typed, ValueInfo, }; use std::{ any::{self, Any, TypeId}, fmt::Debug, }; use crate::utility::NonGenericTypeInfoCell; pub use bevy_utils::AHasher as ReflectHasher; /// An immutable enumeration of "kinds" of reflected type. /// /// Each variant contains a trait object with methods specific to a kind of /// type. /// /// A `ReflectRef` is obtained via [`Reflect::reflect_ref`]. pub enum ReflectRef<'a> { Struct(&'a dyn Struct), TupleStruct(&'a dyn TupleStruct), Tuple(&'a dyn Tuple), List(&'a dyn List), Array(&'a dyn Array), Map(&'a dyn Map), Enum(&'a dyn Enum), Value(&'a dyn Reflect), } /// A mutable enumeration of "kinds" of reflected type. /// /// Each variant contains a trait object with methods specific to a kind of /// type. /// /// A `ReflectMut` is obtained via [`Reflect::reflect_mut`]. pub enum ReflectMut<'a> { Struct(&'a mut dyn Struct), TupleStruct(&'a mut dyn TupleStruct), Tuple(&'a mut dyn Tuple), List(&'a mut dyn List), Array(&'a mut dyn Array), Map(&'a mut dyn Map), Enum(&'a mut dyn Enum), Value(&'a mut dyn Reflect), } /// An owned enumeration of "kinds" of reflected type. /// /// Each variant contains a trait object with methods specific to a kind of /// type. /// /// A `ReflectOwned` is obtained via [`Reflect::reflect_owned`]. pub enum ReflectOwned { Struct(Box), TupleStruct(Box), Tuple(Box), List(Box), Array(Box), Map(Box), Enum(Box), Value(Box), } /// A reflected Rust type. /// /// Methods for working with particular kinds of Rust type are available using the [`Array`], [`List`], /// [`Map`], [`Tuple`], [`TupleStruct`], [`Struct`], and [`Enum`] subtraits. /// /// When using `#[derive(Reflect)]` on a struct, tuple struct or enum, the suitable subtrait for that /// type (`Struct`, `TupleStruct` or `Enum`) is derived automatically. pub trait Reflect: Any + Send + Sync { /// Returns the [type name][std::any::type_name] of the underlying type. fn type_name(&self) -> &str; /// Returns the [`TypeInfo`] of the underlying type. /// /// This method is great if you have an instance of a type or a `dyn Reflect`, /// and want to access its [`TypeInfo`]. However, if this method is to be called /// frequently, consider using [`TypeRegistry::get_type_info`] as it can be more /// performant for such use cases. /// /// [`TypeRegistry::get_type_info`]: crate::TypeRegistry::get_type_info fn get_type_info(&self) -> &'static TypeInfo; /// Returns the value as a [`Box`][std::any::Any]. fn into_any(self: Box) -> Box; /// Returns the value as a [`&dyn Any`][std::any::Any]. fn as_any(&self) -> &dyn Any; /// Returns the value as a [`&mut dyn Any`][std::any::Any]. fn as_any_mut(&mut self) -> &mut dyn Any; /// Casts this type to a boxed reflected value. fn into_reflect(self: Box) -> Box; /// Casts this type to a reflected value. fn as_reflect(&self) -> &dyn Reflect; /// Casts this type to a mutable reflected value. fn as_reflect_mut(&mut self) -> &mut dyn Reflect; /// Applies a reflected value to this value. /// /// If a type implements a subtrait of `Reflect`, then the semantics of this /// method are as follows: /// - If `T` is a [`Struct`], then the value of each named field of `value` is /// applied to the corresponding named field of `self`. Fields which are /// not present in both structs are ignored. /// - If `T` is a [`TupleStruct`] or [`Tuple`], then the value of each /// numbered field is applied to the corresponding numbered field of /// `self.` Fields which are not present in both values are ignored. /// - If `T` is an [`Enum`], then the variant of `self` is `updated` to match /// the variant of `value`. The corresponding fields of that variant are /// applied from `value` onto `self`. Fields which are not present in both /// values are ignored. /// - If `T` is a [`List`] or [`Array`], then each element of `value` is applied /// to the corresponding element of `self`. Up to `self.len()` items are applied, /// and excess elements in `value` are appended to `self`. /// - If `T` is a [`Map`], then for each key in `value`, the associated /// value is applied to the value associated with the same key in `self`. /// Keys which are not present in `self` are inserted. /// - If `T` is none of these, then `value` is downcast to `T`, cloned, and /// assigned to `self`. /// /// Note that `Reflect` must be implemented manually for [`List`]s and /// [`Map`]s in order to achieve the correct semantics, as derived /// implementations will have the semantics for [`Struct`], [`TupleStruct`], [`Enum`] /// or none of the above depending on the kind of type. For lists and maps, use the /// [`list_apply`] and [`map_apply`] helper functions when implementing this method. /// /// [`list_apply`]: crate::list_apply /// [`map_apply`]: crate::map_apply /// /// # Panics /// /// Derived implementations of this method will panic: /// - If the type of `value` is not of the same kind as `T` (e.g. if `T` is /// a `List`, while `value` is a `Struct`). /// - If `T` is any complex type and the corresponding fields or elements of /// `self` and `value` are not of the same type. /// - If `T` is a value type and `self` cannot be downcast to `T` fn apply(&mut self, value: &dyn Reflect); /// Performs a type-checked assignment of a reflected value to this value. /// /// If `value` does not contain a value of type `T`, returns an `Err` /// containing the trait object. fn set(&mut self, value: Box) -> Result<(), Box>; /// Returns an enumeration of "kinds" of type. /// /// See [`ReflectRef`]. fn reflect_ref(&self) -> ReflectRef; /// Returns a mutable enumeration of "kinds" of type. /// /// See [`ReflectMut`]. fn reflect_mut(&mut self) -> ReflectMut; /// Returns an owned enumeration of "kinds" of type. /// /// See [`ReflectOwned`]. fn reflect_owned(self: Box) -> ReflectOwned; /// Clones the value as a `Reflect` trait object. /// /// When deriving `Reflect` for a struct, tuple struct or enum, the value is /// cloned via [`Struct::clone_dynamic`], [`TupleStruct::clone_dynamic`], /// or [`Enum::clone_dynamic`], respectively. /// Implementors of other `Reflect` subtraits (e.g. [`List`], [`Map`]) should /// use those subtraits' respective `clone_dynamic` methods. fn clone_value(&self) -> Box; /// Returns a hash of the value (which includes the type). /// /// If the underlying type does not support hashing, returns `None`. fn reflect_hash(&self) -> Option { None } /// Returns a "partial equality" comparison result. /// /// If the underlying type does not support equality testing, returns `None`. fn reflect_partial_eq(&self, _value: &dyn Reflect) -> Option { None } /// Debug formatter for the value. /// /// Any value that is not an implementor of other `Reflect` subtraits /// (e.g. [`List`], [`Map`]), will default to the format: `"Reflect(type_name)"`, /// where `type_name` is the [type name] of the underlying type. /// /// [type name]: Self::type_name fn debug(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { match self.reflect_ref() { ReflectRef::Struct(dyn_struct) => struct_debug(dyn_struct, f), ReflectRef::TupleStruct(dyn_tuple_struct) => tuple_struct_debug(dyn_tuple_struct, f), ReflectRef::Tuple(dyn_tuple) => tuple_debug(dyn_tuple, f), ReflectRef::List(dyn_list) => list_debug(dyn_list, f), ReflectRef::Array(dyn_array) => array_debug(dyn_array, f), ReflectRef::Map(dyn_map) => map_debug(dyn_map, f), ReflectRef::Enum(dyn_enum) => enum_debug(dyn_enum, f), _ => write!(f, "Reflect({})", self.type_name()), } } /// Returns a serializable version of the value. /// /// If the underlying type does not support serialization, returns `None`. fn serializable(&self) -> Option { None } } impl Debug for dyn Reflect { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { self.debug(f) } } impl Typed for dyn Reflect { fn type_info() -> &'static TypeInfo { static CELL: NonGenericTypeInfoCell = NonGenericTypeInfoCell::new(); CELL.get_or_set(|| TypeInfo::Value(ValueInfo::new::())) } } #[deny(rustdoc::broken_intra_doc_links)] impl dyn Reflect { /// Downcasts the value to type `T`, consuming the trait object. /// /// If the underlying value is not of type `T`, returns `Err(self)`. pub fn downcast(self: Box) -> Result, Box> { if self.is::() { Ok(self.into_any().downcast().unwrap()) } else { Err(self) } } /// Downcasts the value to type `T`, unboxing and consuming the trait object. /// /// If the underlying value is not of type `T`, returns `Err(self)`. pub fn take(self: Box) -> Result> { self.downcast::().map(|value| *value) } /// Returns `true` if the underlying value represents a value of type `T`, or `false` /// otherwise. /// /// Read `is` for more information on underlying values and represented types. #[inline] pub fn represents(&self) -> bool { self.type_name() == any::type_name::() } /// Returns `true` if the underlying value is of type `T`, or `false` /// otherwise. /// /// The underlying value is the concrete type that is stored in this `dyn` object; /// it can be downcasted to. In the case that this underlying value "represents" /// a different type, like the Dynamic\*\*\* types do, you can call `represents` /// to determine what type they represent. Represented types cannot be downcasted /// to, but you can use [`FromReflect`] to create a value of the represented type from them. /// /// [`FromReflect`]: crate::FromReflect #[inline] pub fn is(&self) -> bool { self.type_id() == TypeId::of::() } /// Downcasts the value to type `T` by reference. /// /// If the underlying value is not of type `T`, returns `None`. #[inline] pub fn downcast_ref(&self) -> Option<&T> { self.as_any().downcast_ref::() } /// Downcasts the value to type `T` by mutable reference. /// /// If the underlying value is not of type `T`, returns `None`. #[inline] pub fn downcast_mut(&mut self) -> Option<&mut T> { self.as_any_mut().downcast_mut::() } }