core/marker.rs
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//! Primitive traits and types representing basic properties of types.
//!
//! Rust types can be classified in various useful ways according to
//! their intrinsic properties. These classifications are represented
//! as traits.
#![stable(feature = "rust1", since = "1.0.0")]
use crate::cell::UnsafeCell;
use crate::cmp;
use crate::fmt::Debug;
use crate::hash::{Hash, Hasher};
/// Implements a given marker trait for multiple types at the same time.
///
/// The basic syntax looks like this:
/// ```ignore private macro
/// marker_impls! { MarkerTrait for u8, i8 }
/// ```
/// You can also implement `unsafe` traits
/// ```ignore private macro
/// marker_impls! { unsafe MarkerTrait for u8, i8 }
/// ```
/// Add attributes to all impls:
/// ```ignore private macro
/// marker_impls! {
/// #[allow(lint)]
/// #[unstable(feature = "marker_trait", issue = "none")]
/// MarkerTrait for u8, i8
/// }
/// ```
/// And use generics:
/// ```ignore private macro
/// marker_impls! {
/// MarkerTrait for
/// u8, i8,
/// {T: ?Sized} *const T,
/// {T: ?Sized} *mut T,
/// {T: MarkerTrait} PhantomData<T>,
/// u32,
/// }
/// ```
#[unstable(feature = "internal_impls_macro", issue = "none")]
// Allow implementations of `UnsizedConstParamTy` even though std cannot use that feature.
#[allow_internal_unstable(unsized_const_params)]
macro marker_impls {
( $(#[$($meta:tt)*])* $Trait:ident for $({$($bounds:tt)*})? $T:ty $(, $($rest:tt)*)? ) => {
$(#[$($meta)*])* impl< $($($bounds)*)? > $Trait for $T {}
marker_impls! { $(#[$($meta)*])* $Trait for $($($rest)*)? }
},
( $(#[$($meta:tt)*])* $Trait:ident for ) => {},
( $(#[$($meta:tt)*])* unsafe $Trait:ident for $({$($bounds:tt)*})? $T:ty $(, $($rest:tt)*)? ) => {
$(#[$($meta)*])* unsafe impl< $($($bounds)*)? > $Trait for $T {}
marker_impls! { $(#[$($meta)*])* unsafe $Trait for $($($rest)*)? }
},
( $(#[$($meta:tt)*])* unsafe $Trait:ident for ) => {},
}
/// Types that can be transferred across thread boundaries.
///
/// This trait is automatically implemented when the compiler determines it's
/// appropriate.
///
/// An example of a non-`Send` type is the reference-counting pointer
/// [`rc::Rc`][`Rc`]. If two threads attempt to clone [`Rc`]s that point to the same
/// reference-counted value, they might try to update the reference count at the
/// same time, which is [undefined behavior][ub] because [`Rc`] doesn't use atomic
/// operations. Its cousin [`sync::Arc`][arc] does use atomic operations (incurring
/// some overhead) and thus is `Send`.
///
/// See [the Nomicon](../../nomicon/send-and-sync.html) and the [`Sync`] trait for more details.
///
/// [`Rc`]: ../../std/rc/struct.Rc.html
/// [arc]: ../../std/sync/struct.Arc.html
/// [ub]: ../../reference/behavior-considered-undefined.html
#[stable(feature = "rust1", since = "1.0.0")]
#[cfg_attr(not(test), rustc_diagnostic_item = "Send")]
#[diagnostic::on_unimplemented(
message = "`{Self}` cannot be sent between threads safely",
label = "`{Self}` cannot be sent between threads safely"
)]
pub unsafe auto trait Send {
// empty.
}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> !Send for *const T {}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> !Send for *mut T {}
// Most instances arise automatically, but this instance is needed to link up `T: Sync` with
// `&T: Send` (and it also removes the unsound default instance `T Send` -> `&T: Send` that would
// otherwise exist).
#[stable(feature = "rust1", since = "1.0.0")]
unsafe impl<T: Sync + ?Sized> Send for &T {}
/// Types with a constant size known at compile time.
///
/// All type parameters have an implicit bound of `Sized`. The special syntax
/// `?Sized` can be used to remove this bound if it's not appropriate.
///
/// ```
/// # #![allow(dead_code)]
/// struct Foo<T>(T);
/// struct Bar<T: ?Sized>(T);
///
/// // struct FooUse(Foo<[i32]>); // error: Sized is not implemented for [i32]
/// struct BarUse(Bar<[i32]>); // OK
/// ```
///
/// The one exception is the implicit `Self` type of a trait. A trait does not
/// have an implicit `Sized` bound as this is incompatible with [trait object]s
/// where, by definition, the trait needs to work with all possible implementors,
/// and thus could be any size.
///
/// Although Rust will let you bind `Sized` to a trait, you won't
/// be able to use it to form a trait object later:
///
/// ```
/// # #![allow(unused_variables)]
/// trait Foo { }
/// trait Bar: Sized { }
///
/// struct Impl;
/// impl Foo for Impl { }
/// impl Bar for Impl { }
///
/// let x: &dyn Foo = &Impl; // OK
/// // let y: &dyn Bar = &Impl; // error: the trait `Bar` cannot
/// // be made into an object
/// ```
///
/// [trait object]: ../../book/ch17-02-trait-objects.html
#[doc(alias = "?", alias = "?Sized")]
#[stable(feature = "rust1", since = "1.0.0")]
#[lang = "sized"]
#[diagnostic::on_unimplemented(
message = "the size for values of type `{Self}` cannot be known at compilation time",
label = "doesn't have a size known at compile-time"
)]
#[fundamental] // for Default, for example, which requires that `[T]: !Default` be evaluatable
#[rustc_specialization_trait]
#[rustc_deny_explicit_impl(implement_via_object = false)]
#[rustc_coinductive]
pub trait Sized {
// Empty.
}
/// Types that can be "unsized" to a dynamically-sized type.
///
/// For example, the sized array type `[i8; 2]` implements `Unsize<[i8]>` and
/// `Unsize<dyn fmt::Debug>`.
///
/// All implementations of `Unsize` are provided automatically by the compiler.
/// Those implementations are:
///
/// - Arrays `[T; N]` implement `Unsize<[T]>`.
/// - A type implements `Unsize<dyn Trait + 'a>` if all of these conditions are met:
/// - The type implements `Trait`.
/// - `Trait` is dyn-compatible[^1].
/// - The type is sized.
/// - The type outlives `'a`.
/// - Structs `Foo<..., T1, ..., Tn, ...>` implement `Unsize<Foo<..., U1, ..., Un, ...>>`
/// where any number of (type and const) parameters may be changed if all of these conditions
/// are met:
/// - Only the last field of `Foo` has a type involving the parameters `T1`, ..., `Tn`.
/// - All other parameters of the struct are equal.
/// - `Field<T1, ..., Tn>: Unsize<Field<U1, ..., Un>>`, where `Field<...>` stands for the actual
/// type of the struct's last field.
///
/// `Unsize` is used along with [`ops::CoerceUnsized`] to allow
/// "user-defined" containers such as [`Rc`] to contain dynamically-sized
/// types. See the [DST coercion RFC][RFC982] and [the nomicon entry on coercion][nomicon-coerce]
/// for more details.
///
/// [`ops::CoerceUnsized`]: crate::ops::CoerceUnsized
/// [`Rc`]: ../../std/rc/struct.Rc.html
/// [RFC982]: https://github.com/rust-lang/rfcs/blob/master/text/0982-dst-coercion.md
/// [nomicon-coerce]: ../../nomicon/coercions.html
/// [^1]: Formerly known as *object safe*.
#[unstable(feature = "unsize", issue = "18598")]
#[lang = "unsize"]
#[rustc_deny_explicit_impl(implement_via_object = false)]
pub trait Unsize<T: ?Sized> {
// Empty.
}
/// Required trait for constants used in pattern matches.
///
/// Any type that derives `PartialEq` automatically implements this trait,
/// *regardless* of whether its type-parameters implement `PartialEq`.
///
/// If a `const` item contains some type that does not implement this trait,
/// then that type either (1.) does not implement `PartialEq` (which means the
/// constant will not provide that comparison method, which code generation
/// assumes is available), or (2.) it implements *its own* version of
/// `PartialEq` (which we assume does not conform to a structural-equality
/// comparison).
///
/// In either of the two scenarios above, we reject usage of such a constant in
/// a pattern match.
///
/// See also the [structural match RFC][RFC1445], and [issue 63438] which
/// motivated migrating from an attribute-based design to this trait.
///
/// [RFC1445]: https://github.com/rust-lang/rfcs/blob/master/text/1445-restrict-constants-in-patterns.md
/// [issue 63438]: https://github.com/rust-lang/rust/issues/63438
#[unstable(feature = "structural_match", issue = "31434")]
#[diagnostic::on_unimplemented(message = "the type `{Self}` does not `#[derive(PartialEq)]`")]
#[lang = "structural_peq"]
pub trait StructuralPartialEq {
// Empty.
}
marker_impls! {
#[unstable(feature = "structural_match", issue = "31434")]
StructuralPartialEq for
usize, u8, u16, u32, u64, u128,
isize, i8, i16, i32, i64, i128,
bool,
char,
str /* Technically requires `[u8]: StructuralPartialEq` */,
(),
{T, const N: usize} [T; N],
{T} [T],
{T: ?Sized} &T,
}
/// Types whose values can be duplicated simply by copying bits.
///
/// By default, variable bindings have 'move semantics.' In other
/// words:
///
/// ```
/// #[derive(Debug)]
/// struct Foo;
///
/// let x = Foo;
///
/// let y = x;
///
/// // `x` has moved into `y`, and so cannot be used
///
/// // println!("{x:?}"); // error: use of moved value
/// ```
///
/// However, if a type implements `Copy`, it instead has 'copy semantics':
///
/// ```
/// // We can derive a `Copy` implementation. `Clone` is also required, as it's
/// // a supertrait of `Copy`.
/// #[derive(Debug, Copy, Clone)]
/// struct Foo;
///
/// let x = Foo;
///
/// let y = x;
///
/// // `y` is a copy of `x`
///
/// println!("{x:?}"); // A-OK!
/// ```
///
/// It's important to note that in these two examples, the only difference is whether you
/// are allowed to access `x` after the assignment. Under the hood, both a copy and a move
/// can result in bits being copied in memory, although this is sometimes optimized away.
///
/// ## How can I implement `Copy`?
///
/// There are two ways to implement `Copy` on your type. The simplest is to use `derive`:
///
/// ```
/// #[derive(Copy, Clone)]
/// struct MyStruct;
/// ```
///
/// You can also implement `Copy` and `Clone` manually:
///
/// ```
/// struct MyStruct;
///
/// impl Copy for MyStruct { }
///
/// impl Clone for MyStruct {
/// fn clone(&self) -> MyStruct {
/// *self
/// }
/// }
/// ```
///
/// There is a small difference between the two. The `derive` strategy will also place a `Copy`
/// bound on type parameters:
///
/// ```
/// #[derive(Clone)]
/// struct MyStruct<T>(T);
///
/// impl<T: Copy> Copy for MyStruct<T> { }
/// ```
///
/// This isn't always desired. For example, shared references (`&T`) can be copied regardless of
/// whether `T` is `Copy`. Likewise, a generic struct containing markers such as [`PhantomData`]
/// could potentially be duplicated with a bit-wise copy.
///
/// ## What's the difference between `Copy` and `Clone`?
///
/// Copies happen implicitly, for example as part of an assignment `y = x`. The behavior of
/// `Copy` is not overloadable; it is always a simple bit-wise copy.
///
/// Cloning is an explicit action, `x.clone()`. The implementation of [`Clone`] can
/// provide any type-specific behavior necessary to duplicate values safely. For example,
/// the implementation of [`Clone`] for [`String`] needs to copy the pointed-to string
/// buffer in the heap. A simple bitwise copy of [`String`] values would merely copy the
/// pointer, leading to a double free down the line. For this reason, [`String`] is [`Clone`]
/// but not `Copy`.
///
/// [`Clone`] is a supertrait of `Copy`, so everything which is `Copy` must also implement
/// [`Clone`]. If a type is `Copy` then its [`Clone`] implementation only needs to return `*self`
/// (see the example above).
///
/// ## When can my type be `Copy`?
///
/// A type can implement `Copy` if all of its components implement `Copy`. For example, this
/// struct can be `Copy`:
///
/// ```
/// # #[allow(dead_code)]
/// #[derive(Copy, Clone)]
/// struct Point {
/// x: i32,
/// y: i32,
/// }
/// ```
///
/// A struct can be `Copy`, and [`i32`] is `Copy`, therefore `Point` is eligible to be `Copy`.
/// By contrast, consider
///
/// ```
/// # #![allow(dead_code)]
/// # struct Point;
/// struct PointList {
/// points: Vec<Point>,
/// }
/// ```
///
/// The struct `PointList` cannot implement `Copy`, because [`Vec<T>`] is not `Copy`. If we
/// attempt to derive a `Copy` implementation, we'll get an error:
///
/// ```text
/// the trait `Copy` cannot be implemented for this type; field `points` does not implement `Copy`
/// ```
///
/// Shared references (`&T`) are also `Copy`, so a type can be `Copy`, even when it holds
/// shared references of types `T` that are *not* `Copy`. Consider the following struct,
/// which can implement `Copy`, because it only holds a *shared reference* to our non-`Copy`
/// type `PointList` from above:
///
/// ```
/// # #![allow(dead_code)]
/// # struct PointList;
/// #[derive(Copy, Clone)]
/// struct PointListWrapper<'a> {
/// point_list_ref: &'a PointList,
/// }
/// ```
///
/// ## When *can't* my type be `Copy`?
///
/// Some types can't be copied safely. For example, copying `&mut T` would create an aliased
/// mutable reference. Copying [`String`] would duplicate responsibility for managing the
/// [`String`]'s buffer, leading to a double free.
///
/// Generalizing the latter case, any type implementing [`Drop`] can't be `Copy`, because it's
/// managing some resource besides its own [`size_of::<T>`] bytes.
///
/// If you try to implement `Copy` on a struct or enum containing non-`Copy` data, you will get
/// the error [E0204].
///
/// [E0204]: ../../error_codes/E0204.html
///
/// ## When *should* my type be `Copy`?
///
/// Generally speaking, if your type _can_ implement `Copy`, it should. Keep in mind, though,
/// that implementing `Copy` is part of the public API of your type. If the type might become
/// non-`Copy` in the future, it could be prudent to omit the `Copy` implementation now, to
/// avoid a breaking API change.
///
/// ## Additional implementors
///
/// In addition to the [implementors listed below][impls],
/// the following types also implement `Copy`:
///
/// * Function item types (i.e., the distinct types defined for each function)
/// * Function pointer types (e.g., `fn() -> i32`)
/// * Closure types, if they capture no value from the environment
/// or if all such captured values implement `Copy` themselves.
/// Note that variables captured by shared reference always implement `Copy`
/// (even if the referent doesn't),
/// while variables captured by mutable reference never implement `Copy`.
///
/// [`Vec<T>`]: ../../std/vec/struct.Vec.html
/// [`String`]: ../../std/string/struct.String.html
/// [`size_of::<T>`]: crate::mem::size_of
/// [impls]: #implementors
#[stable(feature = "rust1", since = "1.0.0")]
#[lang = "copy"]
// FIXME(matthewjasper) This allows copying a type that doesn't implement
// `Copy` because of unsatisfied lifetime bounds (copying `A<'_>` when only
// `A<'static>: Copy` and `A<'_>: Clone`).
// We have this attribute here for now only because there are quite a few
// existing specializations on `Copy` that already exist in the standard
// library, and there's no way to safely have this behavior right now.
#[rustc_unsafe_specialization_marker]
#[rustc_diagnostic_item = "Copy"]
pub trait Copy: Clone {
// Empty.
}
/// Derive macro generating an impl of the trait `Copy`.
#[rustc_builtin_macro]
#[stable(feature = "builtin_macro_prelude", since = "1.38.0")]
#[allow_internal_unstable(core_intrinsics, derive_clone_copy)]
pub macro Copy($item:item) {
/* compiler built-in */
}
// Implementations of `Copy` for primitive types.
//
// Implementations that cannot be described in Rust
// are implemented in `traits::SelectionContext::copy_clone_conditions()`
// in `rustc_trait_selection`.
marker_impls! {
#[stable(feature = "rust1", since = "1.0.0")]
Copy for
usize, u8, u16, u32, u64, u128,
isize, i8, i16, i32, i64, i128,
f16, f32, f64, f128,
bool, char,
{T: ?Sized} *const T,
{T: ?Sized} *mut T,
}
#[unstable(feature = "never_type", issue = "35121")]
impl Copy for ! {}
/// Shared references can be copied, but mutable references *cannot*!
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> Copy for &T {}
/// Types for which it is safe to share references between threads.
///
/// This trait is automatically implemented when the compiler determines
/// it's appropriate.
///
/// The precise definition is: a type `T` is [`Sync`] if and only if `&T` is
/// [`Send`]. In other words, if there is no possibility of
/// [undefined behavior][ub] (including data races) when passing
/// `&T` references between threads.
///
/// As one would expect, primitive types like [`u8`] and [`f64`]
/// are all [`Sync`], and so are simple aggregate types containing them,
/// like tuples, structs and enums. More examples of basic [`Sync`]
/// types include "immutable" types like `&T`, and those with simple
/// inherited mutability, such as [`Box<T>`][box], [`Vec<T>`][vec] and
/// most other collection types. (Generic parameters need to be [`Sync`]
/// for their container to be [`Sync`].)
///
/// A somewhat surprising consequence of the definition is that `&mut T`
/// is `Sync` (if `T` is `Sync`) even though it seems like that might
/// provide unsynchronized mutation. The trick is that a mutable
/// reference behind a shared reference (that is, `& &mut T`)
/// becomes read-only, as if it were a `& &T`. Hence there is no risk
/// of a data race.
///
/// A shorter overview of how [`Sync`] and [`Send`] relate to referencing:
/// * `&T` is [`Send`] if and only if `T` is [`Sync`]
/// * `&mut T` is [`Send`] if and only if `T` is [`Send`]
/// * `&T` and `&mut T` are [`Sync`] if and only if `T` is [`Sync`]
///
/// Types that are not `Sync` are those that have "interior
/// mutability" in a non-thread-safe form, such as [`Cell`][cell]
/// and [`RefCell`][refcell]. These types allow for mutation of
/// their contents even through an immutable, shared reference. For
/// example the `set` method on [`Cell<T>`][cell] takes `&self`, so it requires
/// only a shared reference [`&Cell<T>`][cell]. The method performs no
/// synchronization, thus [`Cell`][cell] cannot be `Sync`.
///
/// Another example of a non-`Sync` type is the reference-counting
/// pointer [`Rc`][rc]. Given any reference [`&Rc<T>`][rc], you can clone
/// a new [`Rc<T>`][rc], modifying the reference counts in a non-atomic way.
///
/// For cases when one does need thread-safe interior mutability,
/// Rust provides [atomic data types], as well as explicit locking via
/// [`sync::Mutex`][mutex] and [`sync::RwLock`][rwlock]. These types
/// ensure that any mutation cannot cause data races, hence the types
/// are `Sync`. Likewise, [`sync::Arc`][arc] provides a thread-safe
/// analogue of [`Rc`][rc].
///
/// Any types with interior mutability must also use the
/// [`cell::UnsafeCell`][unsafecell] wrapper around the value(s) which
/// can be mutated through a shared reference. Failing to doing this is
/// [undefined behavior][ub]. For example, [`transmute`][transmute]-ing
/// from `&T` to `&mut T` is invalid.
///
/// See [the Nomicon][nomicon-send-and-sync] for more details about `Sync`.
///
/// [box]: ../../std/boxed/struct.Box.html
/// [vec]: ../../std/vec/struct.Vec.html
/// [cell]: crate::cell::Cell
/// [refcell]: crate::cell::RefCell
/// [rc]: ../../std/rc/struct.Rc.html
/// [arc]: ../../std/sync/struct.Arc.html
/// [atomic data types]: crate::sync::atomic
/// [mutex]: ../../std/sync/struct.Mutex.html
/// [rwlock]: ../../std/sync/struct.RwLock.html
/// [unsafecell]: crate::cell::UnsafeCell
/// [ub]: ../../reference/behavior-considered-undefined.html
/// [transmute]: crate::mem::transmute
/// [nomicon-send-and-sync]: ../../nomicon/send-and-sync.html
#[stable(feature = "rust1", since = "1.0.0")]
#[cfg_attr(not(test), rustc_diagnostic_item = "Sync")]
#[lang = "sync"]
#[rustc_on_unimplemented(
on(
_Self = "core::cell::once::OnceCell<T>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::OnceLock` instead"
),
on(
_Self = "core::cell::Cell<u8>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` or `std::sync::atomic::AtomicU8` instead",
),
on(
_Self = "core::cell::Cell<u16>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` or `std::sync::atomic::AtomicU16` instead",
),
on(
_Self = "core::cell::Cell<u32>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` or `std::sync::atomic::AtomicU32` instead",
),
on(
_Self = "core::cell::Cell<u64>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` or `std::sync::atomic::AtomicU64` instead",
),
on(
_Self = "core::cell::Cell<usize>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` or `std::sync::atomic::AtomicUsize` instead",
),
on(
_Self = "core::cell::Cell<i8>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` or `std::sync::atomic::AtomicI8` instead",
),
on(
_Self = "core::cell::Cell<i16>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` or `std::sync::atomic::AtomicI16` instead",
),
on(
_Self = "core::cell::Cell<i32>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` or `std::sync::atomic::AtomicI32` instead",
),
on(
_Self = "core::cell::Cell<i64>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` or `std::sync::atomic::AtomicI64` instead",
),
on(
_Self = "core::cell::Cell<isize>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` or `std::sync::atomic::AtomicIsize` instead",
),
on(
_Self = "core::cell::Cell<bool>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` or `std::sync::atomic::AtomicBool` instead",
),
on(
all(
_Self = "core::cell::Cell<T>",
not(_Self = "core::cell::Cell<u8>"),
not(_Self = "core::cell::Cell<u16>"),
not(_Self = "core::cell::Cell<u32>"),
not(_Self = "core::cell::Cell<u64>"),
not(_Self = "core::cell::Cell<usize>"),
not(_Self = "core::cell::Cell<i8>"),
not(_Self = "core::cell::Cell<i16>"),
not(_Self = "core::cell::Cell<i32>"),
not(_Self = "core::cell::Cell<i64>"),
not(_Self = "core::cell::Cell<isize>"),
not(_Self = "core::cell::Cell<bool>")
),
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock`",
),
on(
_Self = "core::cell::RefCell<T>",
note = "if you want to do aliasing and mutation between multiple threads, use `std::sync::RwLock` instead",
),
message = "`{Self}` cannot be shared between threads safely",
label = "`{Self}` cannot be shared between threads safely"
)]
pub unsafe auto trait Sync {
// FIXME(estebank): once support to add notes in `rustc_on_unimplemented`
// lands in beta, and it has been extended to check whether a closure is
// anywhere in the requirement chain, extend it as such (#48534):
// ```
// on(
// closure,
// note="`{Self}` cannot be shared safely, consider marking the closure `move`"
// ),
// ```
// Empty
}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> !Sync for *const T {}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> !Sync for *mut T {}
/// Zero-sized type used to mark things that "act like" they own a `T`.
///
/// Adding a `PhantomData<T>` field to your type tells the compiler that your
/// type acts as though it stores a value of type `T`, even though it doesn't
/// really. This information is used when computing certain safety properties.
///
/// For a more in-depth explanation of how to use `PhantomData<T>`, please see
/// [the Nomicon](../../nomicon/phantom-data.html).
///
/// # A ghastly note 👻👻👻
///
/// Though they both have scary names, `PhantomData` and 'phantom types' are
/// related, but not identical. A phantom type parameter is simply a type
/// parameter which is never used. In Rust, this often causes the compiler to
/// complain, and the solution is to add a "dummy" use by way of `PhantomData`.
///
/// # Examples
///
/// ## Unused lifetime parameters
///
/// Perhaps the most common use case for `PhantomData` is a struct that has an
/// unused lifetime parameter, typically as part of some unsafe code. For
/// example, here is a struct `Slice` that has two pointers of type `*const T`,
/// presumably pointing into an array somewhere:
///
/// ```compile_fail,E0392
/// struct Slice<'a, T> {
/// start: *const T,
/// end: *const T,
/// }
/// ```
///
/// The intention is that the underlying data is only valid for the
/// lifetime `'a`, so `Slice` should not outlive `'a`. However, this
/// intent is not expressed in the code, since there are no uses of
/// the lifetime `'a` and hence it is not clear what data it applies
/// to. We can correct this by telling the compiler to act *as if* the
/// `Slice` struct contained a reference `&'a T`:
///
/// ```
/// use std::marker::PhantomData;
///
/// # #[allow(dead_code)]
/// struct Slice<'a, T> {
/// start: *const T,
/// end: *const T,
/// phantom: PhantomData<&'a T>,
/// }
/// ```
///
/// This also in turn infers the lifetime bound `T: 'a`, indicating
/// that any references in `T` are valid over the lifetime `'a`.
///
/// When initializing a `Slice` you simply provide the value
/// `PhantomData` for the field `phantom`:
///
/// ```
/// # #![allow(dead_code)]
/// # use std::marker::PhantomData;
/// # struct Slice<'a, T> {
/// # start: *const T,
/// # end: *const T,
/// # phantom: PhantomData<&'a T>,
/// # }
/// fn borrow_vec<T>(vec: &Vec<T>) -> Slice<'_, T> {
/// let ptr = vec.as_ptr();
/// Slice {
/// start: ptr,
/// end: unsafe { ptr.add(vec.len()) },
/// phantom: PhantomData,
/// }
/// }
/// ```
///
/// ## Unused type parameters
///
/// It sometimes happens that you have unused type parameters which
/// indicate what type of data a struct is "tied" to, even though that
/// data is not actually found in the struct itself. Here is an
/// example where this arises with [FFI]. The foreign interface uses
/// handles of type `*mut ()` to refer to Rust values of different
/// types. We track the Rust type using a phantom type parameter on
/// the struct `ExternalResource` which wraps a handle.
///
/// [FFI]: ../../book/ch19-01-unsafe-rust.html#using-extern-functions-to-call-external-code
///
/// ```
/// # #![allow(dead_code)]
/// # trait ResType { }
/// # struct ParamType;
/// # mod foreign_lib {
/// # pub fn new(_: usize) -> *mut () { 42 as *mut () }
/// # pub fn do_stuff(_: *mut (), _: usize) {}
/// # }
/// # fn convert_params(_: ParamType) -> usize { 42 }
/// use std::marker::PhantomData;
/// use std::mem;
///
/// struct ExternalResource<R> {
/// resource_handle: *mut (),
/// resource_type: PhantomData<R>,
/// }
///
/// impl<R: ResType> ExternalResource<R> {
/// fn new() -> Self {
/// let size_of_res = mem::size_of::<R>();
/// Self {
/// resource_handle: foreign_lib::new(size_of_res),
/// resource_type: PhantomData,
/// }
/// }
///
/// fn do_stuff(&self, param: ParamType) {
/// let foreign_params = convert_params(param);
/// foreign_lib::do_stuff(self.resource_handle, foreign_params);
/// }
/// }
/// ```
///
/// ## Ownership and the drop check
///
/// The exact interaction of `PhantomData` with drop check **may change in the future**.
///
/// Currently, adding a field of type `PhantomData<T>` indicates that your type *owns* data of type
/// `T` in very rare circumstances. This in turn has effects on the Rust compiler's [drop check]
/// analysis. For the exact rules, see the [drop check] documentation.
///
/// ## Layout
///
/// For all `T`, the following are guaranteed:
/// * `size_of::<PhantomData<T>>() == 0`
/// * `align_of::<PhantomData<T>>() == 1`
///
/// [drop check]: Drop#drop-check
#[lang = "phantom_data"]
#[stable(feature = "rust1", since = "1.0.0")]
pub struct PhantomData<T: ?Sized>;
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> Hash for PhantomData<T> {
#[inline]
fn hash<H: Hasher>(&self, _: &mut H) {}
}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> cmp::PartialEq for PhantomData<T> {
fn eq(&self, _other: &PhantomData<T>) -> bool {
true
}
}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> cmp::Eq for PhantomData<T> {}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> cmp::PartialOrd for PhantomData<T> {
fn partial_cmp(&self, _other: &PhantomData<T>) -> Option<cmp::Ordering> {
Option::Some(cmp::Ordering::Equal)
}
}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> cmp::Ord for PhantomData<T> {
fn cmp(&self, _other: &PhantomData<T>) -> cmp::Ordering {
cmp::Ordering::Equal
}
}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> Copy for PhantomData<T> {}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> Clone for PhantomData<T> {
fn clone(&self) -> Self {
Self
}
}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T: ?Sized> Default for PhantomData<T> {
fn default() -> Self {
Self
}
}
#[unstable(feature = "structural_match", issue = "31434")]
impl<T: ?Sized> StructuralPartialEq for PhantomData<T> {}
/// Compiler-internal trait used to indicate the type of enum discriminants.
///
/// This trait is automatically implemented for every type and does not add any
/// guarantees to [`mem::Discriminant`]. It is **undefined behavior** to transmute
/// between `DiscriminantKind::Discriminant` and `mem::Discriminant`.
///
/// [`mem::Discriminant`]: crate::mem::Discriminant
#[unstable(
feature = "discriminant_kind",
issue = "none",
reason = "this trait is unlikely to ever be stabilized, use `mem::discriminant` instead"
)]
#[lang = "discriminant_kind"]
#[rustc_deny_explicit_impl(implement_via_object = false)]
pub trait DiscriminantKind {
/// The type of the discriminant, which must satisfy the trait
/// bounds required by `mem::Discriminant`.
#[lang = "discriminant_type"]
type Discriminant: Clone + Copy + Debug + Eq + PartialEq + Hash + Send + Sync + Unpin;
}
/// Used to determine whether a type contains
/// any `UnsafeCell` internally, but not through an indirection.
/// This affects, for example, whether a `static` of that type is
/// placed in read-only static memory or writable static memory.
/// This can be used to declare that a constant with a generic type
/// will not contain interior mutability, and subsequently allow
/// placing the constant behind references.
///
/// # Safety
///
/// This trait is a core part of the language, it is just expressed as a trait in libcore for
/// convenience. Do *not* implement it for other types.
// FIXME: Eventually this trait should become `#[rustc_deny_explicit_impl]`.
// That requires porting the impls below to native internal impls.
#[lang = "freeze"]
#[unstable(feature = "freeze", issue = "121675")]
pub unsafe auto trait Freeze {}
#[unstable(feature = "freeze", issue = "121675")]
impl<T: ?Sized> !Freeze for UnsafeCell<T> {}
marker_impls! {
#[unstable(feature = "freeze", issue = "121675")]
unsafe Freeze for
{T: ?Sized} PhantomData<T>,
{T: ?Sized} *const T,
{T: ?Sized} *mut T,
{T: ?Sized} &T,
{T: ?Sized} &mut T,
}
/// Types that do not require any pinning guarantees.
///
/// For information on what "pinning" is, see the [`pin` module] documentation.
///
/// Implementing the `Unpin` trait for `T` expresses the fact that `T` is pinning-agnostic:
/// it shall not expose nor rely on any pinning guarantees. This, in turn, means that a
/// `Pin`-wrapped pointer to such a type can feature a *fully unrestricted* API.
/// In other words, if `T: Unpin`, a value of type `T` will *not* be bound by the invariants
/// which pinning otherwise offers, even when "pinned" by a [`Pin<Ptr>`] pointing at it.
/// When a value of type `T` is pointed at by a [`Pin<Ptr>`], [`Pin`] will not restrict access
/// to the pointee value like it normally would, thus allowing the user to do anything that they
/// normally could with a non-[`Pin`]-wrapped `Ptr` to that value.
///
/// The idea of this trait is to alleviate the reduced ergonomics of APIs that require the use
/// of [`Pin`] for soundness for some types, but which also want to be used by other types that
/// don't care about pinning. The prime example of such an API is [`Future::poll`]. There are many
/// [`Future`] types that don't care about pinning. These futures can implement `Unpin` and
/// therefore get around the pinning related restrictions in the API, while still allowing the
/// subset of [`Future`]s which *do* require pinning to be implemented soundly.
///
/// For more discussion on the consequences of [`Unpin`] within the wider scope of the pinning
/// system, see the [section about `Unpin`] in the [`pin` module].
///
/// `Unpin` has no consequence at all for non-pinned data. In particular, [`mem::replace`] happily
/// moves `!Unpin` data, which would be immovable when pinned ([`mem::replace`] works for any
/// `&mut T`, not just when `T: Unpin`).
///
/// *However*, you cannot use [`mem::replace`] on `!Unpin` data which is *pinned* by being wrapped
/// inside a [`Pin<Ptr>`] pointing at it. This is because you cannot (safely) use a
/// [`Pin<Ptr>`] to get a `&mut T` to its pointee value, which you would need to call
/// [`mem::replace`], and *that* is what makes this system work.
///
/// So this, for example, can only be done on types implementing `Unpin`:
///
/// ```rust
/// # #![allow(unused_must_use)]
/// use std::mem;
/// use std::pin::Pin;
///
/// let mut string = "this".to_string();
/// let mut pinned_string = Pin::new(&mut string);
///
/// // We need a mutable reference to call `mem::replace`.
/// // We can obtain such a reference by (implicitly) invoking `Pin::deref_mut`,
/// // but that is only possible because `String` implements `Unpin`.
/// mem::replace(&mut *pinned_string, "other".to_string());
/// ```
///
/// This trait is automatically implemented for almost every type. The compiler is free
/// to take the conservative stance of marking types as [`Unpin`] so long as all of the types that
/// compose its fields are also [`Unpin`]. This is because if a type implements [`Unpin`], then it
/// is unsound for that type's implementation to rely on pinning-related guarantees for soundness,
/// *even* when viewed through a "pinning" pointer! It is the responsibility of the implementor of
/// a type that relies upon pinning for soundness to ensure that type is *not* marked as [`Unpin`]
/// by adding [`PhantomPinned`] field. For more details, see the [`pin` module] docs.
///
/// [`mem::replace`]: crate::mem::replace "mem replace"
/// [`Future`]: crate::future::Future "Future"
/// [`Future::poll`]: crate::future::Future::poll "Future poll"
/// [`Pin`]: crate::pin::Pin "Pin"
/// [`Pin<Ptr>`]: crate::pin::Pin "Pin"
/// [`pin` module]: crate::pin "pin module"
/// [section about `Unpin`]: crate::pin#unpin "pin module docs about unpin"
/// [`unsafe`]: ../../std/keyword.unsafe.html "keyword unsafe"
#[stable(feature = "pin", since = "1.33.0")]
#[diagnostic::on_unimplemented(
note = "consider using the `pin!` macro\nconsider using `Box::pin` if you need to access the pinned value outside of the current scope",
message = "`{Self}` cannot be unpinned"
)]
#[lang = "unpin"]
pub auto trait Unpin {}
/// A marker type which does not implement `Unpin`.
///
/// If a type contains a `PhantomPinned`, it will not implement `Unpin` by default.
#[stable(feature = "pin", since = "1.33.0")]
#[derive(Debug, Default, Copy, Clone, Eq, PartialEq, Ord, PartialOrd, Hash)]
pub struct PhantomPinned;
#[stable(feature = "pin", since = "1.33.0")]
impl !Unpin for PhantomPinned {}
marker_impls! {
#[stable(feature = "pin", since = "1.33.0")]
Unpin for
{T: ?Sized} &T,
{T: ?Sized} &mut T,
}
marker_impls! {
#[stable(feature = "pin_raw", since = "1.38.0")]
Unpin for
{T: ?Sized} *const T,
{T: ?Sized} *mut T,
}
/// A marker for types that can be dropped.
///
/// This should be used for `~const` bounds,
/// as non-const bounds will always hold for every type.
#[unstable(feature = "const_trait_impl", issue = "67792")]
#[lang = "destruct"]
#[rustc_on_unimplemented(message = "can't drop `{Self}`", append_const_msg)]
#[rustc_deny_explicit_impl(implement_via_object = false)]
pub trait Destruct {}
/// A marker for tuple types.
///
/// The implementation of this trait is built-in and cannot be implemented
/// for any user type.
#[unstable(feature = "tuple_trait", issue = "none")]
#[lang = "tuple_trait"]
#[diagnostic::on_unimplemented(message = "`{Self}` is not a tuple")]
#[rustc_deny_explicit_impl(implement_via_object = false)]
pub trait Tuple {}
/// A marker for pointer-like types.
///
/// All types that have the same size and alignment as a `usize` or
/// `*const ()` automatically implement this trait.
#[unstable(feature = "pointer_like_trait", issue = "none")]
#[lang = "pointer_like"]
#[diagnostic::on_unimplemented(
message = "`{Self}` needs to have the same ABI as a pointer",
label = "`{Self}` needs to be a pointer-like type"
)]
pub trait PointerLike {}
/// A marker for types which can be used as types of `const` generic parameters.
///
/// These types must have a proper equivalence relation (`Eq`) and it must be automatically
/// derived (`StructuralPartialEq`). There's a hard-coded check in the compiler ensuring
/// that all fields are also `ConstParamTy`, which implies that recursively, all fields
/// are `StructuralPartialEq`.
#[lang = "const_param_ty"]
#[unstable(feature = "unsized_const_params", issue = "95174")]
#[diagnostic::on_unimplemented(message = "`{Self}` can't be used as a const parameter type")]
#[allow(multiple_supertrait_upcastable)]
// We name this differently than the derive macro so that the `adt_const_params` can
// be used independently of `unsized_const_params` without requiring a full path
// to the derive macro every time it is used. This should be renamed on stabilization.
pub trait ConstParamTy_: UnsizedConstParamTy + StructuralPartialEq + Eq {}
/// Derive macro generating an impl of the trait `ConstParamTy`.
#[rustc_builtin_macro]
#[allow_internal_unstable(unsized_const_params)]
#[unstable(feature = "adt_const_params", issue = "95174")]
pub macro ConstParamTy($item:item) {
/* compiler built-in */
}
#[lang = "unsized_const_param_ty"]
#[unstable(feature = "unsized_const_params", issue = "95174")]
#[diagnostic::on_unimplemented(message = "`{Self}` can't be used as a const parameter type")]
/// A marker for types which can be used as types of `const` generic parameters.
///
/// Equivalent to [`ConstParamTy_`] except that this is used by
/// the `unsized_const_params` to allow for fake unstable impls.
pub trait UnsizedConstParamTy: StructuralPartialEq + Eq {}
/// Derive macro generating an impl of the trait `ConstParamTy`.
#[rustc_builtin_macro]
#[allow_internal_unstable(unsized_const_params)]
#[unstable(feature = "unsized_const_params", issue = "95174")]
pub macro UnsizedConstParamTy($item:item) {
/* compiler built-in */
}
// FIXME(adt_const_params): handle `ty::FnDef`/`ty::Closure`
marker_impls! {
#[unstable(feature = "adt_const_params", issue = "95174")]
ConstParamTy_ for
usize, u8, u16, u32, u64, u128,
isize, i8, i16, i32, i64, i128,
bool,
char,
(),
{T: ConstParamTy_, const N: usize} [T; N],
}
marker_impls! {
#[unstable(feature = "unsized_const_params", issue = "95174")]
UnsizedConstParamTy for
usize, u8, u16, u32, u64, u128,
isize, i8, i16, i32, i64, i128,
bool,
char,
(),
{T: UnsizedConstParamTy, const N: usize} [T; N],
str,
{T: UnsizedConstParamTy} [T],
{T: UnsizedConstParamTy + ?Sized} &T,
}
/// A common trait implemented by all function pointers.
#[unstable(
feature = "fn_ptr_trait",
issue = "none",
reason = "internal trait for implementing various traits for all function pointers"
)]
#[lang = "fn_ptr_trait"]
#[rustc_deny_explicit_impl(implement_via_object = false)]
pub trait FnPtr: Copy + Clone {
/// Returns the address of the function pointer.
#[lang = "fn_ptr_addr"]
fn addr(self) -> *const ();
}
/// Derive macro generating impls of traits related to smart pointers.
#[rustc_builtin_macro(SmartPointer, attributes(pointee))]
#[allow_internal_unstable(dispatch_from_dyn, coerce_unsized, unsize)]
#[unstable(feature = "derive_smart_pointer", issue = "123430")]
pub macro SmartPointer($item:item) {
/* compiler built-in */
}
// Support traits and types for the desugaring of const traits and
// `~const` bounds. Not supposed to be used by anything other than
// the compiler.
#[doc(hidden)]
#[unstable(
feature = "effect_types",
issue = "none",
reason = "internal module for implementing effects"
)]
#[allow(missing_debug_implementations)] // these unit structs don't need `Debug` impls.
pub mod effects {
#[lang = "EffectsNoRuntime"]
pub struct NoRuntime;
#[lang = "EffectsMaybe"]
pub struct Maybe;
#[lang = "EffectsRuntime"]
pub struct Runtime;
#[lang = "EffectsCompat"]
pub trait Compat<#[rustc_runtime] const RUNTIME: bool> {}
impl Compat<false> for NoRuntime {}
impl Compat<true> for Runtime {}
impl<#[rustc_runtime] const RUNTIME: bool> Compat<RUNTIME> for Maybe {}
#[lang = "EffectsTyCompat"]
#[marker]
pub trait TyCompat<T: ?Sized> {}
impl<T: ?Sized> TyCompat<T> for T {}
impl<T: ?Sized> TyCompat<Maybe> for T {}
#[lang = "EffectsIntersection"]
pub trait Intersection {
#[lang = "EffectsIntersectionOutput"]
type Output: ?Sized;
}
// FIXME(effects): remove this after next trait solver lands
impl Intersection for () {
type Output = Maybe;
}
}