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// SPDX-License-Identifier: Apache-2.0 OR MIT
//! Library to safely and fallibly initialize pinned `struct`s using in-place constructors.
//!
//! [Pinning][pinning] is Rust's way of ensuring data does not move.
//!
//! It also allows in-place initialization of big `struct`s that would otherwise produce a stack
//! overflow.
//!
//! This library's main use-case is in [Rust-for-Linux]. Although this version can be used
//! standalone.
//!
//! There are cases when you want to in-place initialize a struct. For example when it is very big
//! and moving it from the stack is not an option, because it is bigger than the stack itself.
//! Another reason would be that you need the address of the object to initialize it. This stands
//! in direct conflict with Rust's normal process of first initializing an object and then moving
//! it into it's final memory location. For more information, see
//! <https://rust-for-linux.com/the-safe-pinned-initialization-problem>.
//!
//! This library allows you to do in-place initialization safely.
//!
//! ## Nightly Needed for `alloc` feature
//!
//! This library requires the [`allocator_api` unstable feature] when the `alloc` feature is
//! enabled and thus this feature can only be used with a nightly compiler. When enabling the
//! `alloc` feature, the user will be required to activate `allocator_api` as well.
//!
//! [`allocator_api` unstable feature]: https://doc.rust-lang.org/nightly/unstable-book/library-features/allocator-api.html
//!
//! The feature is enabled by default, thus by default `pin-init` will require a nightly compiler.
//! However, using the crate on stable compilers is possible by disabling `alloc`. In practice this
//! will require the `std` feature, because stable compilers have neither `Box` nor `Arc` in no-std
//! mode.
//!
//! # Overview
//!
//! To initialize a `struct` with an in-place constructor you will need two things:
//! - an in-place constructor,
//! - a memory location that can hold your `struct` (this can be the [stack], an [`Arc<T>`],
//! [`Box<T>`] or any other smart pointer that supports this library).
//!
//! To get an in-place constructor there are generally three options:
//! - directly creating an in-place constructor using the [`pin_init!`] macro,
//! - a custom function/macro returning an in-place constructor provided by someone else,
//! - using the unsafe function [`pin_init_from_closure()`] to manually create an initializer.
//!
//! Aside from pinned initialization, this library also supports in-place construction without
//! pinning, the macros/types/functions are generally named like the pinned variants without the
//! `pin_` prefix.
//!
//! # Examples
//!
//! Throughout the examples we will often make use of the `CMutex` type which can be found in
//! `../examples/mutex.rs`. It is essentially a userland rebuild of the `struct mutex` type from
//! the Linux kernel. It also uses a wait list and a basic spinlock. Importantly the wait list
//! requires it to be pinned to be locked and thus is a prime candidate for using this library.
//!
//! ## Using the [`pin_init!`] macro
//!
//! If you want to use [`PinInit`], then you will have to annotate your `struct` with
//! `#[`[`pin_data`]`]`. It is a macro that uses `#[pin]` as a marker for
//! [structurally pinned fields]. After doing this, you can then create an in-place constructor via
//! [`pin_init!`]. The syntax is almost the same as normal `struct` initializers. The difference is
//! that you need to write `<-` instead of `:` for fields that you want to initialize in-place.
//!
//! ```rust
//! # #![expect(clippy::disallowed_names)]
//! # #![feature(allocator_api)]
//! # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
//! # use core::pin::Pin;
//! use pin_init::{pin_data, pin_init, InPlaceInit};
//!
//! #[pin_data]
//! struct Foo {
//! #[pin]
//! a: CMutex<usize>,
//! b: u32,
//! }
//!
//! let foo = pin_init!(Foo {
//! a <- CMutex::new(42),
//! b: 24,
//! });
//! # let _ = Box::pin_init(foo);
//! ```
//!
//! `foo` now is of the type [`impl PinInit<Foo>`]. We can now use any smart pointer that we like
//! (or just the stack) to actually initialize a `Foo`:
//!
//! ```rust
//! # #![expect(clippy::disallowed_names)]
//! # #![feature(allocator_api)]
//! # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
//! # use core::{alloc::AllocError, pin::Pin};
//! # use pin_init::*;
//! #
//! # #[pin_data]
//! # struct Foo {
//! # #[pin]
//! # a: CMutex<usize>,
//! # b: u32,
//! # }
//! #
//! # let foo = pin_init!(Foo {
//! # a <- CMutex::new(42),
//! # b: 24,
//! # });
//! let foo: Result<Pin<Box<Foo>>, AllocError> = Box::pin_init(foo);
//! ```
//!
//! For more information see the [`pin_init!`] macro.
//!
//! ## Using a custom function/macro that returns an initializer
//!
//! Many types that use this library supply a function/macro that returns an initializer, because
//! the above method only works for types where you can access the fields.
//!
//! ```rust
//! # #![feature(allocator_api)]
//! # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
//! # use pin_init::*;
//! # use std::sync::Arc;
//! # use core::pin::Pin;
//! let mtx: Result<Pin<Arc<CMutex<usize>>>, _> = Arc::pin_init(CMutex::new(42));
//! ```
//!
//! To declare an init macro/function you just return an [`impl PinInit<T, E>`]:
//!
//! ```rust
//! # #![feature(allocator_api)]
//! # use pin_init::*;
//! # #[path = "../examples/error.rs"] mod error; use error::Error;
//! # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
//! #[pin_data]
//! struct DriverData {
//! #[pin]
//! status: CMutex<i32>,
//! buffer: Box<[u8; 1_000_000]>,
//! }
//!
//! impl DriverData {
//! fn new() -> impl PinInit<Self, Error> {
//! try_pin_init!(Self {
//! status <- CMutex::new(0),
//! buffer: Box::init(pin_init::zeroed())?,
//! }? Error)
//! }
//! }
//! ```
//!
//! ## Manual creation of an initializer
//!
//! Often when working with primitives the previous approaches are not sufficient. That is where
//! [`pin_init_from_closure()`] comes in. This `unsafe` function allows you to create a
//! [`impl PinInit<T, E>`] directly from a closure. Of course you have to ensure that the closure
//! actually does the initialization in the correct way. Here are the things to look out for
//! (we are calling the parameter to the closure `slot`):
//! - when the closure returns `Ok(())`, then it has completed the initialization successfully, so
//! `slot` now contains a valid bit pattern for the type `T`,
//! - when the closure returns `Err(e)`, then the caller may deallocate the memory at `slot`, so
//! you need to take care to clean up anything if your initialization fails mid-way,
//! - you may assume that `slot` will stay pinned even after the closure returns until `drop` of
//! `slot` gets called.
//!
//! ```rust
//! # #![feature(extern_types)]
//! use pin_init::{pin_data, pinned_drop, PinInit, PinnedDrop, pin_init_from_closure};
//! use core::{
//! ptr::addr_of_mut,
//! marker::PhantomPinned,
//! cell::UnsafeCell,
//! pin::Pin,
//! mem::MaybeUninit,
//! };
//! mod bindings {
//! #[repr(C)]
//! pub struct foo {
//! /* fields from C ... */
//! }
//! extern "C" {
//! pub fn init_foo(ptr: *mut foo);
//! pub fn destroy_foo(ptr: *mut foo);
//! #[must_use = "you must check the error return code"]
//! pub fn enable_foo(ptr: *mut foo, flags: u32) -> i32;
//! }
//! }
//!
//! /// # Invariants
//! ///
//! /// `foo` is always initialized
//! #[pin_data(PinnedDrop)]
//! pub struct RawFoo {
//! #[pin]
//! _p: PhantomPinned,
//! #[pin]
//! foo: UnsafeCell<MaybeUninit<bindings::foo>>,
//! }
//!
//! impl RawFoo {
//! pub fn new(flags: u32) -> impl PinInit<Self, i32> {
//! // SAFETY:
//! // - when the closure returns `Ok(())`, then it has successfully initialized and
//! // enabled `foo`,
//! // - when it returns `Err(e)`, then it has cleaned up before
//! unsafe {
//! pin_init_from_closure(move |slot: *mut Self| {
//! // `slot` contains uninit memory, avoid creating a reference.
//! let foo = addr_of_mut!((*slot).foo);
//! let foo = UnsafeCell::raw_get(foo).cast::<bindings::foo>();
//!
//! // Initialize the `foo`
//! bindings::init_foo(foo);
//!
//! // Try to enable it.
//! let err = bindings::enable_foo(foo, flags);
//! if err != 0 {
//! // Enabling has failed, first clean up the foo and then return the error.
//! bindings::destroy_foo(foo);
//! Err(err)
//! } else {
//! // All fields of `RawFoo` have been initialized, since `_p` is a ZST.
//! Ok(())
//! }
//! })
//! }
//! }
//! }
//!
//! #[pinned_drop]
//! impl PinnedDrop for RawFoo {
//! fn drop(self: Pin<&mut Self>) {
//! // SAFETY: Since `foo` is initialized, destroying is safe.
//! unsafe { bindings::destroy_foo(self.foo.get().cast::<bindings::foo>()) };
//! }
//! }
//! ```
//!
//! For more information on how to use [`pin_init_from_closure()`], take a look at the uses inside
//! the `kernel` crate. The [`sync`] module is a good starting point.
//!
//! [`sync`]: https://rust.docs.kernel.org/kernel/sync/index.html
//! [pinning]: https://doc.rust-lang.org/std/pin/index.html
//! [structurally pinned fields]:
//! https://doc.rust-lang.org/std/pin/index.html#pinning-is-structural-for-field
//! [stack]: crate::stack_pin_init
#![cfg_attr(
kernel,
doc = "[`Arc<T>`]: https://rust.docs.kernel.org/kernel/sync/struct.Arc.html"
)]
#![cfg_attr(
kernel,
doc = "[`Box<T>`]: https://rust.docs.kernel.org/kernel/alloc/kbox/struct.Box.html"
)]
#![cfg_attr(not(kernel), doc = "[`Arc<T>`]: alloc::alloc::sync::Arc")]
#![cfg_attr(not(kernel), doc = "[`Box<T>`]: alloc::alloc::boxed::Box")]
//! [`impl PinInit<Foo>`]: crate::PinInit
//! [`impl PinInit<T, E>`]: crate::PinInit
//! [`impl Init<T, E>`]: crate::Init
//! [Rust-for-Linux]: https://rust-for-linux.com/
#![cfg_attr(not(RUSTC_LINT_REASONS_IS_STABLE), feature(lint_reasons))]
#![cfg_attr(
all(
any(feature = "alloc", feature = "std"),
not(RUSTC_NEW_UNINIT_IS_STABLE)
),
feature(new_uninit)
)]
#![forbid(missing_docs, unsafe_op_in_unsafe_fn)]
#![cfg_attr(not(feature = "std"), no_std)]
#![cfg_attr(feature = "alloc", feature(allocator_api))]
use core::{
cell::UnsafeCell,
convert::Infallible,
marker::PhantomData,
mem::MaybeUninit,
num::*,
pin::Pin,
ptr::{self, NonNull},
};
#[doc(hidden)]
pub mod __internal;
#[doc(hidden)]
pub mod macros;
#[cfg(any(feature = "std", feature = "alloc"))]
mod alloc;
#[cfg(any(feature = "std", feature = "alloc"))]
pub use alloc::InPlaceInit;
/// Used to specify the pinning information of the fields of a struct.
///
/// This is somewhat similar in purpose as
/// [pin-project-lite](https://crates.io/crates/pin-project-lite).
/// Place this macro on a struct definition and then `#[pin]` in front of the attributes of each
/// field you want to structurally pin.
///
/// This macro enables the use of the [`pin_init!`] macro. When pin-initializing a `struct`,
/// then `#[pin]` directs the type of initializer that is required.
///
/// If your `struct` implements `Drop`, then you need to add `PinnedDrop` as arguments to this
/// macro, and change your `Drop` implementation to `PinnedDrop` annotated with
/// `#[`[`macro@pinned_drop`]`]`, since dropping pinned values requires extra care.
///
/// # Examples
///
/// ```
/// # #![feature(allocator_api)]
/// # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
/// use pin_init::pin_data;
///
/// enum Command {
/// /* ... */
/// }
///
/// #[pin_data]
/// struct DriverData {
/// #[pin]
/// queue: CMutex<Vec<Command>>,
/// buf: Box<[u8; 1024 * 1024]>,
/// }
/// ```
///
/// ```
/// # #![feature(allocator_api)]
/// # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
/// # mod bindings { pub struct info; pub unsafe fn destroy_info(_: *mut info) {} }
/// use core::pin::Pin;
/// use pin_init::{pin_data, pinned_drop, PinnedDrop};
///
/// enum Command {
/// /* ... */
/// }
///
/// #[pin_data(PinnedDrop)]
/// struct DriverData {
/// #[pin]
/// queue: CMutex<Vec<Command>>,
/// buf: Box<[u8; 1024 * 1024]>,
/// raw_info: *mut bindings::info,
/// }
///
/// #[pinned_drop]
/// impl PinnedDrop for DriverData {
/// fn drop(self: Pin<&mut Self>) {
/// unsafe { bindings::destroy_info(self.raw_info) };
/// }
/// }
/// ```
pub use ::pin_init_internal::pin_data;
/// Used to implement `PinnedDrop` safely.
///
/// Only works on structs that are annotated via `#[`[`macro@pin_data`]`]`.
///
/// # Examples
///
/// ```
/// # #![feature(allocator_api)]
/// # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
/// # mod bindings { pub struct info; pub unsafe fn destroy_info(_: *mut info) {} }
/// use core::pin::Pin;
/// use pin_init::{pin_data, pinned_drop, PinnedDrop};
///
/// enum Command {
/// /* ... */
/// }
///
/// #[pin_data(PinnedDrop)]
/// struct DriverData {
/// #[pin]
/// queue: CMutex<Vec<Command>>,
/// buf: Box<[u8; 1024 * 1024]>,
/// raw_info: *mut bindings::info,
/// }
///
/// #[pinned_drop]
/// impl PinnedDrop for DriverData {
/// fn drop(self: Pin<&mut Self>) {
/// unsafe { bindings::destroy_info(self.raw_info) };
/// }
/// }
/// ```
pub use ::pin_init_internal::pinned_drop;
/// Derives the [`Zeroable`] trait for the given struct.
///
/// This can only be used for structs where every field implements the [`Zeroable`] trait.
///
/// # Examples
///
/// ```
/// use pin_init::Zeroable;
///
/// #[derive(Zeroable)]
/// pub struct DriverData {
/// id: i64,
/// buf_ptr: *mut u8,
/// len: usize,
/// }
/// ```
pub use ::pin_init_internal::Zeroable;
/// Initialize and pin a type directly on the stack.
///
/// # Examples
///
/// ```rust
/// # #![expect(clippy::disallowed_names)]
/// # #![feature(allocator_api)]
/// # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
/// # use pin_init::*;
/// # use core::pin::Pin;
/// #[pin_data]
/// struct Foo {
/// #[pin]
/// a: CMutex<usize>,
/// b: Bar,
/// }
///
/// #[pin_data]
/// struct Bar {
/// x: u32,
/// }
///
/// stack_pin_init!(let foo = pin_init!(Foo {
/// a <- CMutex::new(42),
/// b: Bar {
/// x: 64,
/// },
/// }));
/// let foo: Pin<&mut Foo> = foo;
/// println!("a: {}", &*foo.a.lock());
/// ```
///
/// # Syntax
///
/// A normal `let` binding with optional type annotation. The expression is expected to implement
/// [`PinInit`]/[`Init`] with the error type [`Infallible`]. If you want to use a different error
/// type, then use [`stack_try_pin_init!`].
#[macro_export]
macro_rules! stack_pin_init {
(let $var:ident $(: $t:ty)? = $val:expr) => {
let val = $val;
let mut $var = ::core::pin::pin!($crate::__internal::StackInit$(::<$t>)?::uninit());
let mut $var = match $crate::__internal::StackInit::init($var, val) {
Ok(res) => res,
Err(x) => {
let x: ::core::convert::Infallible = x;
match x {}
}
};
};
}
/// Initialize and pin a type directly on the stack.
///
/// # Examples
///
/// ```rust
/// # #![expect(clippy::disallowed_names)]
/// # #![feature(allocator_api)]
/// # #[path = "../examples/error.rs"] mod error; use error::Error;
/// # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
/// # use pin_init::*;
/// #[pin_data]
/// struct Foo {
/// #[pin]
/// a: CMutex<usize>,
/// b: Box<Bar>,
/// }
///
/// struct Bar {
/// x: u32,
/// }
///
/// stack_try_pin_init!(let foo: Foo = try_pin_init!(Foo {
/// a <- CMutex::new(42),
/// b: Box::try_new(Bar {
/// x: 64,
/// })?,
/// }? Error));
/// let foo = foo.unwrap();
/// println!("a: {}", &*foo.a.lock());
/// ```
///
/// ```rust
/// # #![expect(clippy::disallowed_names)]
/// # #![feature(allocator_api)]
/// # #[path = "../examples/error.rs"] mod error; use error::Error;
/// # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
/// # use pin_init::*;
/// #[pin_data]
/// struct Foo {
/// #[pin]
/// a: CMutex<usize>,
/// b: Box<Bar>,
/// }
///
/// struct Bar {
/// x: u32,
/// }
///
/// stack_try_pin_init!(let foo: Foo =? try_pin_init!(Foo {
/// a <- CMutex::new(42),
/// b: Box::try_new(Bar {
/// x: 64,
/// })?,
/// }? Error));
/// println!("a: {}", &*foo.a.lock());
/// # Ok::<_, Error>(())
/// ```
///
/// # Syntax
///
/// A normal `let` binding with optional type annotation. The expression is expected to implement
/// [`PinInit`]/[`Init`]. This macro assigns a result to the given variable, adding a `?` after the
/// `=` will propagate this error.
#[macro_export]
macro_rules! stack_try_pin_init {
(let $var:ident $(: $t:ty)? = $val:expr) => {
let val = $val;
let mut $var = ::core::pin::pin!($crate::__internal::StackInit$(::<$t>)?::uninit());
let mut $var = $crate::__internal::StackInit::init($var, val);
};
(let $var:ident $(: $t:ty)? =? $val:expr) => {
let val = $val;
let mut $var = ::core::pin::pin!($crate::__internal::StackInit$(::<$t>)?::uninit());
let mut $var = $crate::__internal::StackInit::init($var, val)?;
};
}
/// Construct an in-place, pinned initializer for `struct`s.
///
/// This macro defaults the error to [`Infallible`]. If you need a different error, then use
/// [`try_pin_init!`].
///
/// The syntax is almost identical to that of a normal `struct` initializer:
///
/// ```rust
/// # use pin_init::*;
/// # use core::pin::Pin;
/// #[pin_data]
/// struct Foo {
/// a: usize,
/// b: Bar,
/// }
///
/// #[pin_data]
/// struct Bar {
/// x: u32,
/// }
///
/// # fn demo() -> impl PinInit<Foo> {
/// let a = 42;
///
/// let initializer = pin_init!(Foo {
/// a,
/// b: Bar {
/// x: 64,
/// },
/// });
/// # initializer }
/// # Box::pin_init(demo()).unwrap();
/// ```
///
/// Arbitrary Rust expressions can be used to set the value of a variable.
///
/// The fields are initialized in the order that they appear in the initializer. So it is possible
/// to read already initialized fields using raw pointers.
///
/// IMPORTANT: You are not allowed to create references to fields of the struct inside of the
/// initializer.
///
/// # Init-functions
///
/// When working with this library it is often desired to let others construct your types without
/// giving access to all fields. This is where you would normally write a plain function `new` that
/// would return a new instance of your type. With this library that is also possible. However,
/// there are a few extra things to keep in mind.
///
/// To create an initializer function, simply declare it like this:
///
/// ```rust
/// # use pin_init::*;
/// # use core::pin::Pin;
/// # #[pin_data]
/// # struct Foo {
/// # a: usize,
/// # b: Bar,
/// # }
/// # #[pin_data]
/// # struct Bar {
/// # x: u32,
/// # }
/// impl Foo {
/// fn new() -> impl PinInit<Self> {
/// pin_init!(Self {
/// a: 42,
/// b: Bar {
/// x: 64,
/// },
/// })
/// }
/// }
/// ```
///
/// Users of `Foo` can now create it like this:
///
/// ```rust
/// # #![expect(clippy::disallowed_names)]
/// # use pin_init::*;
/// # use core::pin::Pin;
/// # #[pin_data]
/// # struct Foo {
/// # a: usize,
/// # b: Bar,
/// # }
/// # #[pin_data]
/// # struct Bar {
/// # x: u32,
/// # }
/// # impl Foo {
/// # fn new() -> impl PinInit<Self> {
/// # pin_init!(Self {
/// # a: 42,
/// # b: Bar {
/// # x: 64,
/// # },
/// # })
/// # }
/// # }
/// let foo = Box::pin_init(Foo::new());
/// ```
///
/// They can also easily embed it into their own `struct`s:
///
/// ```rust
/// # use pin_init::*;
/// # use core::pin::Pin;
/// # #[pin_data]
/// # struct Foo {
/// # a: usize,
/// # b: Bar,
/// # }
/// # #[pin_data]
/// # struct Bar {
/// # x: u32,
/// # }
/// # impl Foo {
/// # fn new() -> impl PinInit<Self> {
/// # pin_init!(Self {
/// # a: 42,
/// # b: Bar {
/// # x: 64,
/// # },
/// # })
/// # }
/// # }
/// #[pin_data]
/// struct FooContainer {
/// #[pin]
/// foo1: Foo,
/// #[pin]
/// foo2: Foo,
/// other: u32,
/// }
///
/// impl FooContainer {
/// fn new(other: u32) -> impl PinInit<Self> {
/// pin_init!(Self {
/// foo1 <- Foo::new(),
/// foo2 <- Foo::new(),
/// other,
/// })
/// }
/// }
/// ```
///
/// Here we see that when using `pin_init!` with `PinInit`, one needs to write `<-` instead of `:`.
/// This signifies that the given field is initialized in-place. As with `struct` initializers, just
/// writing the field (in this case `other`) without `:` or `<-` means `other: other,`.
///
/// # Syntax
///
/// As already mentioned in the examples above, inside of `pin_init!` a `struct` initializer with
/// the following modifications is expected:
/// - Fields that you want to initialize in-place have to use `<-` instead of `:`.
/// - In front of the initializer you can write `&this in` to have access to a [`NonNull<Self>`]
/// pointer named `this` inside of the initializer.
/// - Using struct update syntax one can place `..Zeroable::zeroed()` at the very end of the
/// struct, this initializes every field with 0 and then runs all initializers specified in the
/// body. This can only be done if [`Zeroable`] is implemented for the struct.
///
/// For instance:
///
/// ```rust
/// # use pin_init::*;
/// # use core::{ptr::addr_of_mut, marker::PhantomPinned};
/// #[pin_data]
/// #[derive(Zeroable)]
/// struct Buf {
/// // `ptr` points into `buf`.
/// ptr: *mut u8,
/// buf: [u8; 64],
/// #[pin]
/// pin: PhantomPinned,
/// }
///
/// let init = pin_init!(&this in Buf {
/// buf: [0; 64],
/// // SAFETY: TODO.
/// ptr: unsafe { addr_of_mut!((*this.as_ptr()).buf).cast() },
/// pin: PhantomPinned,
/// });
/// let init = pin_init!(Buf {
/// buf: [1; 64],
/// ..Zeroable::zeroed()
/// });
/// ```
///
/// [`NonNull<Self>`]: core::ptr::NonNull
// For a detailed example of how this macro works, see the module documentation of the hidden
// module `macros` inside of `macros.rs`.
#[macro_export]
macro_rules! pin_init {
($(&$this:ident in)? $t:ident $(::<$($generics:ty),* $(,)?>)? {
$($fields:tt)*
}) => {
$crate::try_pin_init!($(&$this in)? $t $(::<$($generics),*>)? {
$($fields)*
}? ::core::convert::Infallible)
};
}
/// Construct an in-place, fallible pinned initializer for `struct`s.
///
/// If the initialization can complete without error (or [`Infallible`]), then use [`pin_init!`].
///
/// You can use the `?` operator or use `return Err(err)` inside the initializer to stop
/// initialization and return the error.
///
/// IMPORTANT: if you have `unsafe` code inside of the initializer you have to ensure that when
/// initialization fails, the memory can be safely deallocated without any further modifications.
///
/// The syntax is identical to [`pin_init!`] with the following exception: you must append `? $type`
/// after the `struct` initializer to specify the error type you want to use.
///
/// # Examples
///
/// ```rust
/// # #![feature(allocator_api)]
/// # #[path = "../examples/error.rs"] mod error; use error::Error;
/// use pin_init::{pin_data, try_pin_init, PinInit, InPlaceInit, zeroed};
///
/// #[pin_data]
/// struct BigBuf {
/// big: Box<[u8; 1024 * 1024 * 1024]>,
/// small: [u8; 1024 * 1024],
/// ptr: *mut u8,
/// }
///
/// impl BigBuf {
/// fn new() -> impl PinInit<Self, Error> {
/// try_pin_init!(Self {
/// big: Box::init(zeroed())?,
/// small: [0; 1024 * 1024],
/// ptr: core::ptr::null_mut(),
/// }? Error)
/// }
/// }
/// # let _ = Box::pin_init(BigBuf::new());
/// ```
// For a detailed example of how this macro works, see the module documentation of the hidden
// module `macros` inside of `macros.rs`.
#[macro_export]
macro_rules! try_pin_init {
($(&$this:ident in)? $t:ident $(::<$($generics:ty),* $(,)?>)? {
$($fields:tt)*
}? $err:ty) => {
$crate::__init_internal!(
@this($($this)?),
@typ($t $(::<$($generics),*>)? ),
@fields($($fields)*),
@error($err),
@data(PinData, use_data),
@has_data(HasPinData, __pin_data),
@construct_closure(pin_init_from_closure),
@munch_fields($($fields)*),
)
}
}
/// Construct an in-place initializer for `struct`s.
///
/// This macro defaults the error to [`Infallible`]. If you need a different error, then use
/// [`try_init!`].
///
/// The syntax is identical to [`pin_init!`] and its safety caveats also apply:
/// - `unsafe` code must guarantee either full initialization or return an error and allow
/// deallocation of the memory.
/// - the fields are initialized in the order given in the initializer.
/// - no references to fields are allowed to be created inside of the initializer.
///
/// This initializer is for initializing data in-place that might later be moved. If you want to
/// pin-initialize, use [`pin_init!`].
///
/// # Examples
///
/// ```rust
/// # #![feature(allocator_api)]
/// # #[path = "../examples/error.rs"] mod error; use error::Error;
/// # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
/// # use pin_init::InPlaceInit;
/// use pin_init::{init, Init, zeroed};
///
/// struct BigBuf {
/// small: [u8; 1024 * 1024],
/// }
///
/// impl BigBuf {
/// fn new() -> impl Init<Self> {
/// init!(Self {
/// small <- zeroed(),
/// })
/// }
/// }
/// # let _ = Box::init(BigBuf::new());
/// ```
// For a detailed example of how this macro works, see the module documentation of the hidden
// module `macros` inside of `macros.rs`.
#[macro_export]
macro_rules! init {
($(&$this:ident in)? $t:ident $(::<$($generics:ty),* $(,)?>)? {
$($fields:tt)*
}) => {
$crate::try_init!($(&$this in)? $t $(::<$($generics),*>)? {
$($fields)*
}? ::core::convert::Infallible)
}
}
/// Construct an in-place fallible initializer for `struct`s.
///
/// If the initialization can complete without error (or [`Infallible`]), then use
/// [`init!`].
///
/// The syntax is identical to [`try_pin_init!`]. You need to specify a custom error
/// via `? $type` after the `struct` initializer.
/// The safety caveats from [`try_pin_init!`] also apply:
/// - `unsafe` code must guarantee either full initialization or return an error and allow
/// deallocation of the memory.
/// - the fields are initialized in the order given in the initializer.
/// - no references to fields are allowed to be created inside of the initializer.
///
/// # Examples
///
/// ```rust
/// # #![feature(allocator_api)]
/// # use core::alloc::AllocError;
/// # use pin_init::InPlaceInit;
/// use pin_init::{try_init, Init, zeroed};
///
/// struct BigBuf {
/// big: Box<[u8; 1024 * 1024 * 1024]>,
/// small: [u8; 1024 * 1024],
/// }
///
/// impl BigBuf {
/// fn new() -> impl Init<Self, AllocError> {
/// try_init!(Self {
/// big: Box::init(zeroed())?,
/// small: [0; 1024 * 1024],
/// }? AllocError)
/// }
/// }
/// # let _ = Box::init(BigBuf::new());
/// ```
// For a detailed example of how this macro works, see the module documentation of the hidden
// module `macros` inside of `macros.rs`.
#[macro_export]
macro_rules! try_init {
($(&$this:ident in)? $t:ident $(::<$($generics:ty),* $(,)?>)? {
$($fields:tt)*
}? $err:ty) => {
$crate::__init_internal!(
@this($($this)?),
@typ($t $(::<$($generics),*>)?),
@fields($($fields)*),
@error($err),
@data(InitData, /*no use_data*/),
@has_data(HasInitData, __init_data),
@construct_closure(init_from_closure),
@munch_fields($($fields)*),
)
}
}
/// Asserts that a field on a struct using `#[pin_data]` is marked with `#[pin]` ie. that it is
/// structurally pinned.
///
/// # Example
///
/// This will succeed:
/// ```
/// use pin_init::{pin_data, assert_pinned};
///
/// #[pin_data]
/// struct MyStruct {
/// #[pin]
/// some_field: u64,
/// }
///
/// assert_pinned!(MyStruct, some_field, u64);
/// ```
///
/// This will fail:
/// ```compile_fail
/// use pin_init::{pin_data, assert_pinned};
///
/// #[pin_data]
/// struct MyStruct {
/// some_field: u64,
/// }
///
/// assert_pinned!(MyStruct, some_field, u64);
/// ```
///
/// Some uses of the macro may trigger the `can't use generic parameters from outer item` error. To
/// work around this, you may pass the `inline` parameter to the macro. The `inline` parameter can
/// only be used when the macro is invoked from a function body.
/// ```
/// # use core::pin::Pin;
/// use pin_init::{pin_data, assert_pinned};
///
/// #[pin_data]
/// struct Foo<T> {
/// #[pin]
/// elem: T,
/// }
///
/// impl<T> Foo<T> {
/// fn project(self: Pin<&mut Self>) -> Pin<&mut T> {
/// assert_pinned!(Foo<T>, elem, T, inline);
///
/// // SAFETY: The field is structurally pinned.
/// unsafe { self.map_unchecked_mut(|me| &mut me.elem) }
/// }
/// }
/// ```
#[macro_export]
macro_rules! assert_pinned {
($ty:ty, $field:ident, $field_ty:ty, inline) => {
let _ = move |ptr: *mut $field_ty| {
// SAFETY: This code is unreachable.
let data = unsafe { <$ty as $crate::__internal::HasPinData>::__pin_data() };
let init = $crate::__internal::AlwaysFail::<$field_ty>::new();
// SAFETY: This code is unreachable.
unsafe { data.$field(ptr, init) }.ok();
};
};
($ty:ty, $field:ident, $field_ty:ty) => {
const _: () = {
$crate::assert_pinned!($ty, $field, $field_ty, inline);
};
};
}
/// A pin-initializer for the type `T`.
///
/// To use this initializer, you will need a suitable memory location that can hold a `T`. This can
/// be [`Box<T>`], [`Arc<T>`] or even the stack (see [`stack_pin_init!`]).
///
/// Also see the [module description](self).
///
/// # Safety
///
/// When implementing this trait you will need to take great care. Also there are probably very few
/// cases where a manual implementation is necessary. Use [`pin_init_from_closure`] where possible.
///
/// The [`PinInit::__pinned_init`] function:
/// - returns `Ok(())` if it initialized every field of `slot`,
/// - returns `Err(err)` if it encountered an error and then cleaned `slot`, this means:
/// - `slot` can be deallocated without UB occurring,
/// - `slot` does not need to be dropped,
/// - `slot` is not partially initialized.
/// - while constructing the `T` at `slot` it upholds the pinning invariants of `T`.
///
#[cfg_attr(
kernel,
doc = "[`Arc<T>`]: https://rust.docs.kernel.org/kernel/sync/struct.Arc.html"
)]
#[cfg_attr(
kernel,
doc = "[`Box<T>`]: https://rust.docs.kernel.org/kernel/alloc/kbox/struct.Box.html"
)]
#[cfg_attr(not(kernel), doc = "[`Arc<T>`]: alloc::alloc::sync::Arc")]
#[cfg_attr(not(kernel), doc = "[`Box<T>`]: alloc::alloc::boxed::Box")]
#[must_use = "An initializer must be used in order to create its value."]
pub unsafe trait PinInit<T: ?Sized, E = Infallible>: Sized {
/// Initializes `slot`.
///
/// # Safety
///
/// - `slot` is a valid pointer to uninitialized memory.
/// - the caller does not touch `slot` when `Err` is returned, they are only permitted to
/// deallocate.
/// - `slot` will not move until it is dropped, i.e. it will be pinned.
unsafe fn __pinned_init(self, slot: *mut T) -> Result<(), E>;
/// First initializes the value using `self` then calls the function `f` with the initialized
/// value.
///
/// If `f` returns an error the value is dropped and the initializer will forward the error.
///
/// # Examples
///
/// ```rust
/// # #![feature(allocator_api)]
/// # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
/// # use pin_init::*;
/// let mtx_init = CMutex::new(42);
/// // Make the initializer print the value.
/// let mtx_init = mtx_init.pin_chain(|mtx| {
/// println!("{:?}", mtx.get_data_mut());
/// Ok(())
/// });
/// ```
fn pin_chain<F>(self, f: F) -> ChainPinInit<Self, F, T, E>
where
F: FnOnce(Pin<&mut T>) -> Result<(), E>,
{
ChainPinInit(self, f, PhantomData)
}
}
/// An initializer returned by [`PinInit::pin_chain`].
pub struct ChainPinInit<I, F, T: ?Sized, E>(I, F, __internal::Invariant<(E, T)>);
// SAFETY: The `__pinned_init` function is implemented such that it
// - returns `Ok(())` on successful initialization,
// - returns `Err(err)` on error and in this case `slot` will be dropped.
// - considers `slot` pinned.
unsafe impl<T: ?Sized, E, I, F> PinInit<T, E> for ChainPinInit<I, F, T, E>
where
I: PinInit<T, E>,
F: FnOnce(Pin<&mut T>) -> Result<(), E>,
{
unsafe fn __pinned_init(self, slot: *mut T) -> Result<(), E> {
// SAFETY: All requirements fulfilled since this function is `__pinned_init`.
unsafe { self.0.__pinned_init(slot)? };
// SAFETY: The above call initialized `slot` and we still have unique access.
let val = unsafe { &mut *slot };
// SAFETY: `slot` is considered pinned.
let val = unsafe { Pin::new_unchecked(val) };
// SAFETY: `slot` was initialized above.
(self.1)(val).inspect_err(|_| unsafe { core::ptr::drop_in_place(slot) })
}
}
/// An initializer for `T`.
///
/// To use this initializer, you will need a suitable memory location that can hold a `T`. This can
/// be [`Box<T>`], [`Arc<T>`] or even the stack (see [`stack_pin_init!`]). Because
/// [`PinInit<T, E>`] is a super trait, you can use every function that takes it as well.
///
/// Also see the [module description](self).
///
/// # Safety
///
/// When implementing this trait you will need to take great care. Also there are probably very few
/// cases where a manual implementation is necessary. Use [`init_from_closure`] where possible.
///
/// The [`Init::__init`] function:
/// - returns `Ok(())` if it initialized every field of `slot`,
/// - returns `Err(err)` if it encountered an error and then cleaned `slot`, this means:
/// - `slot` can be deallocated without UB occurring,
/// - `slot` does not need to be dropped,
/// - `slot` is not partially initialized.
/// - while constructing the `T` at `slot` it upholds the pinning invariants of `T`.
///
/// The `__pinned_init` function from the supertrait [`PinInit`] needs to execute the exact same
/// code as `__init`.
///
/// Contrary to its supertype [`PinInit<T, E>`] the caller is allowed to
/// move the pointee after initialization.
///
#[cfg_attr(
kernel,
doc = "[`Arc<T>`]: https://rust.docs.kernel.org/kernel/sync/struct.Arc.html"
)]
#[cfg_attr(
kernel,
doc = "[`Box<T>`]: https://rust.docs.kernel.org/kernel/alloc/kbox/struct.Box.html"
)]
#[cfg_attr(not(kernel), doc = "[`Arc<T>`]: alloc::alloc::sync::Arc")]
#[cfg_attr(not(kernel), doc = "[`Box<T>`]: alloc::alloc::boxed::Box")]
#[must_use = "An initializer must be used in order to create its value."]
pub unsafe trait Init<T: ?Sized, E = Infallible>: PinInit<T, E> {
/// Initializes `slot`.
///
/// # Safety
///
/// - `slot` is a valid pointer to uninitialized memory.
/// - the caller does not touch `slot` when `Err` is returned, they are only permitted to
/// deallocate.
unsafe fn __init(self, slot: *mut T) -> Result<(), E>;
/// First initializes the value using `self` then calls the function `f` with the initialized
/// value.
///
/// If `f` returns an error the value is dropped and the initializer will forward the error.
///
/// # Examples
///
/// ```rust
/// # #![expect(clippy::disallowed_names)]
/// use pin_init::{init, zeroed, Init};
///
/// struct Foo {
/// buf: [u8; 1_000_000],
/// }
///
/// impl Foo {
/// fn setup(&mut self) {
/// println!("Setting up foo");
/// }
/// }
///
/// let foo = init!(Foo {
/// buf <- zeroed()
/// }).chain(|foo| {
/// foo.setup();
/// Ok(())
/// });
/// ```
fn chain<F>(self, f: F) -> ChainInit<Self, F, T, E>
where
F: FnOnce(&mut T) -> Result<(), E>,
{
ChainInit(self, f, PhantomData)
}
}
/// An initializer returned by [`Init::chain`].
pub struct ChainInit<I, F, T: ?Sized, E>(I, F, __internal::Invariant<(E, T)>);
// SAFETY: The `__init` function is implemented such that it
// - returns `Ok(())` on successful initialization,
// - returns `Err(err)` on error and in this case `slot` will be dropped.
unsafe impl<T: ?Sized, E, I, F> Init<T, E> for ChainInit<I, F, T, E>
where
I: Init<T, E>,
F: FnOnce(&mut T) -> Result<(), E>,
{
unsafe fn __init(self, slot: *mut T) -> Result<(), E> {
// SAFETY: All requirements fulfilled since this function is `__init`.
unsafe { self.0.__pinned_init(slot)? };
// SAFETY: The above call initialized `slot` and we still have unique access.
(self.1)(unsafe { &mut *slot }).inspect_err(|_|
// SAFETY: `slot` was initialized above.
unsafe { core::ptr::drop_in_place(slot) })
}
}
// SAFETY: `__pinned_init` behaves exactly the same as `__init`.
unsafe impl<T: ?Sized, E, I, F> PinInit<T, E> for ChainInit<I, F, T, E>
where
I: Init<T, E>,
F: FnOnce(&mut T) -> Result<(), E>,
{
unsafe fn __pinned_init(self, slot: *mut T) -> Result<(), E> {
// SAFETY: `__init` has less strict requirements compared to `__pinned_init`.
unsafe { self.__init(slot) }
}
}
/// Creates a new [`PinInit<T, E>`] from the given closure.
///
/// # Safety
///
/// The closure:
/// - returns `Ok(())` if it initialized every field of `slot`,
/// - returns `Err(err)` if it encountered an error and then cleaned `slot`, this means:
/// - `slot` can be deallocated without UB occurring,
/// - `slot` does not need to be dropped,
/// - `slot` is not partially initialized.
/// - may assume that the `slot` does not move if `T: !Unpin`,
/// - while constructing the `T` at `slot` it upholds the pinning invariants of `T`.
#[inline]
pub const unsafe fn pin_init_from_closure<T: ?Sized, E>(
f: impl FnOnce(*mut T) -> Result<(), E>,
) -> impl PinInit<T, E> {
__internal::InitClosure(f, PhantomData)
}
/// Creates a new [`Init<T, E>`] from the given closure.
///
/// # Safety
///
/// The closure:
/// - returns `Ok(())` if it initialized every field of `slot`,
/// - returns `Err(err)` if it encountered an error and then cleaned `slot`, this means:
/// - `slot` can be deallocated without UB occurring,
/// - `slot` does not need to be dropped,
/// - `slot` is not partially initialized.
/// - the `slot` may move after initialization.
/// - while constructing the `T` at `slot` it upholds the pinning invariants of `T`.
#[inline]
pub const unsafe fn init_from_closure<T: ?Sized, E>(
f: impl FnOnce(*mut T) -> Result<(), E>,
) -> impl Init<T, E> {
__internal::InitClosure(f, PhantomData)
}
/// An initializer that leaves the memory uninitialized.
///
/// The initializer is a no-op. The `slot` memory is not changed.
#[inline]
pub fn uninit<T, E>() -> impl Init<MaybeUninit<T>, E> {
// SAFETY: The memory is allowed to be uninitialized.
unsafe { init_from_closure(|_| Ok(())) }
}
/// Initializes an array by initializing each element via the provided initializer.
///
/// # Examples
///
/// ```rust
/// # use pin_init::*;
/// use pin_init::init_array_from_fn;
/// let array: Box<[usize; 1_000]> = Box::init(init_array_from_fn(|i| i)).unwrap();
/// assert_eq!(array.len(), 1_000);
/// ```
pub fn init_array_from_fn<I, const N: usize, T, E>(
mut make_init: impl FnMut(usize) -> I,
) -> impl Init<[T; N], E>
where
I: Init<T, E>,
{
let init = move |slot: *mut [T; N]| {
let slot = slot.cast::<T>();
for i in 0..N {
let init = make_init(i);
// SAFETY: Since 0 <= `i` < N, it is still in bounds of `[T; N]`.
let ptr = unsafe { slot.add(i) };
// SAFETY: The pointer is derived from `slot` and thus satisfies the `__init`
// requirements.
if let Err(e) = unsafe { init.__init(ptr) } {
// SAFETY: The loop has initialized the elements `slot[0..i]` and since we return
// `Err` below, `slot` will be considered uninitialized memory.
unsafe { ptr::drop_in_place(ptr::slice_from_raw_parts_mut(slot, i)) };
return Err(e);
}
}
Ok(())
};
// SAFETY: The initializer above initializes every element of the array. On failure it drops
// any initialized elements and returns `Err`.
unsafe { init_from_closure(init) }
}
/// Initializes an array by initializing each element via the provided initializer.
///
/// # Examples
///
/// ```rust
/// # #![feature(allocator_api)]
/// # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
/// # use pin_init::*;
/// # use core::pin::Pin;
/// use pin_init::pin_init_array_from_fn;
/// use std::sync::Arc;
/// let array: Pin<Arc<[CMutex<usize>; 1_000]>> =
/// Arc::pin_init(pin_init_array_from_fn(|i| CMutex::new(i))).unwrap();
/// assert_eq!(array.len(), 1_000);
/// ```
pub fn pin_init_array_from_fn<I, const N: usize, T, E>(
mut make_init: impl FnMut(usize) -> I,
) -> impl PinInit<[T; N], E>
where
I: PinInit<T, E>,
{
let init = move |slot: *mut [T; N]| {
let slot = slot.cast::<T>();
for i in 0..N {
let init = make_init(i);
// SAFETY: Since 0 <= `i` < N, it is still in bounds of `[T; N]`.
let ptr = unsafe { slot.add(i) };
// SAFETY: The pointer is derived from `slot` and thus satisfies the `__init`
// requirements.
if let Err(e) = unsafe { init.__pinned_init(ptr) } {
// SAFETY: The loop has initialized the elements `slot[0..i]` and since we return
// `Err` below, `slot` will be considered uninitialized memory.
unsafe { ptr::drop_in_place(ptr::slice_from_raw_parts_mut(slot, i)) };
return Err(e);
}
}
Ok(())
};
// SAFETY: The initializer above initializes every element of the array. On failure it drops
// any initialized elements and returns `Err`.
unsafe { pin_init_from_closure(init) }
}
// SAFETY: Every type can be initialized by-value.
unsafe impl<T, E> Init<T, E> for T {
unsafe fn __init(self, slot: *mut T) -> Result<(), E> {
// SAFETY: TODO.
unsafe { slot.write(self) };
Ok(())
}
}
// SAFETY: Every type can be initialized by-value. `__pinned_init` calls `__init`.
unsafe impl<T, E> PinInit<T, E> for T {
unsafe fn __pinned_init(self, slot: *mut T) -> Result<(), E> {
// SAFETY: TODO.
unsafe { self.__init(slot) }
}
}
/// Smart pointer containing uninitialized memory and that can write a value.
pub trait InPlaceWrite<T> {
/// The type `Self` turns into when the contents are initialized.
type Initialized;
/// Use the given initializer to write a value into `self`.
///
/// Does not drop the current value and considers it as uninitialized memory.
fn write_init<E>(self, init: impl Init<T, E>) -> Result<Self::Initialized, E>;
/// Use the given pin-initializer to write a value into `self`.
///
/// Does not drop the current value and considers it as uninitialized memory.
fn write_pin_init<E>(self, init: impl PinInit<T, E>) -> Result<Pin<Self::Initialized>, E>;
}
/// Trait facilitating pinned destruction.
///
/// Use [`pinned_drop`] to implement this trait safely:
///
/// ```rust
/// # #![feature(allocator_api)]
/// # #[path = "../examples/mutex.rs"] mod mutex; use mutex::*;
/// # use pin_init::*;
/// use core::pin::Pin;
/// #[pin_data(PinnedDrop)]
/// struct Foo {
/// #[pin]
/// mtx: CMutex<usize>,
/// }
///
/// #[pinned_drop]
/// impl PinnedDrop for Foo {
/// fn drop(self: Pin<&mut Self>) {
/// println!("Foo is being dropped!");
/// }
/// }
/// ```
///
/// # Safety
///
/// This trait must be implemented via the [`pinned_drop`] proc-macro attribute on the impl.
pub unsafe trait PinnedDrop: __internal::HasPinData {
/// Executes the pinned destructor of this type.
///
/// While this function is marked safe, it is actually unsafe to call it manually. For this
/// reason it takes an additional parameter. This type can only be constructed by `unsafe` code
/// and thus prevents this function from being called where it should not.
///
/// This extra parameter will be generated by the `#[pinned_drop]` proc-macro attribute
/// automatically.
fn drop(self: Pin<&mut Self>, only_call_from_drop: __internal::OnlyCallFromDrop);
}
/// Marker trait for types that can be initialized by writing just zeroes.
///
/// # Safety
///
/// The bit pattern consisting of only zeroes is a valid bit pattern for this type. In other words,
/// this is not UB:
///
/// ```rust,ignore
/// let val: Self = unsafe { core::mem::zeroed() };
/// ```
pub unsafe trait Zeroable {}
/// Marker trait for types that allow `Option<Self>` to be set to all zeroes in order to write
/// `None` to that location.
///
/// # Safety
///
/// The implementer needs to ensure that `unsafe impl Zeroable for Option<Self> {}` is sound.
pub unsafe trait ZeroableOption {}
// SAFETY: by the safety requirement of `ZeroableOption`, this is valid.
unsafe impl<T: ZeroableOption> Zeroable for Option<T> {}
/// Create a new zeroed T.
///
/// The returned initializer will write `0x00` to every byte of the given `slot`.
#[inline]
pub fn zeroed<T: Zeroable>() -> impl Init<T> {
// SAFETY: Because `T: Zeroable`, all bytes zero is a valid bit pattern for `T`
// and because we write all zeroes, the memory is initialized.
unsafe {
init_from_closure(|slot: *mut T| {
slot.write_bytes(0, 1);
Ok(())
})
}
}
macro_rules! impl_zeroable {
($($({$($generics:tt)*})? $t:ty, )*) => {
// SAFETY: Safety comments written in the macro invocation.
$(unsafe impl$($($generics)*)? Zeroable for $t {})*
};
}
impl_zeroable! {
// SAFETY: All primitives that are allowed to be zero.
bool,
char,
u8, u16, u32, u64, u128, usize,
i8, i16, i32, i64, i128, isize,
f32, f64,
// Note: do not add uninhabited types (such as `!` or `core::convert::Infallible`) to this list;
// creating an instance of an uninhabited type is immediate undefined behavior. For more on
// uninhabited/empty types, consult The Rustonomicon:
// <https://doc.rust-lang.org/stable/nomicon/exotic-sizes.html#empty-types>. The Rust Reference
// also has information on undefined behavior:
// <https://doc.rust-lang.org/stable/reference/behavior-considered-undefined.html>.
//
// SAFETY: These are inhabited ZSTs; there is nothing to zero and a valid value exists.
{<T: ?Sized>} PhantomData<T>, core::marker::PhantomPinned, (),
// SAFETY: Type is allowed to take any value, including all zeros.
{<T>} MaybeUninit<T>,
// SAFETY: `T: Zeroable` and `UnsafeCell` is `repr(transparent)`.
{<T: ?Sized + Zeroable>} UnsafeCell<T>,
// SAFETY: All zeros is equivalent to `None` (option layout optimization guarantee:
// https://doc.rust-lang.org/stable/std/option/index.html#representation).
Option<NonZeroU8>, Option<NonZeroU16>, Option<NonZeroU32>, Option<NonZeroU64>,
Option<NonZeroU128>, Option<NonZeroUsize>,
Option<NonZeroI8>, Option<NonZeroI16>, Option<NonZeroI32>, Option<NonZeroI64>,
Option<NonZeroI128>, Option<NonZeroIsize>,
{<T>} Option<NonNull<T>>,
// SAFETY: `null` pointer is valid.
//
// We cannot use `T: ?Sized`, since the VTABLE pointer part of fat pointers is not allowed to be
// null.
//
// When `Pointee` gets stabilized, we could use
// `T: ?Sized where <T as Pointee>::Metadata: Zeroable`
{<T>} *mut T, {<T>} *const T,
// SAFETY: `null` pointer is valid and the metadata part of these fat pointers is allowed to be
// zero.
{<T>} *mut [T], {<T>} *const [T], *mut str, *const str,
// SAFETY: `T` is `Zeroable`.
{<const N: usize, T: Zeroable>} [T; N], {<T: Zeroable>} Wrapping<T>,
}
macro_rules! impl_tuple_zeroable {
($(,)?) => {};
($first:ident, $($t:ident),* $(,)?) => {
// SAFETY: All elements are zeroable and padding can be zero.
unsafe impl<$first: Zeroable, $($t: Zeroable),*> Zeroable for ($first, $($t),*) {}
impl_tuple_zeroable!($($t),* ,);
}
}
impl_tuple_zeroable!(A, B, C, D, E, F, G, H, I, J);