//! This module provides the macros that actually implement the proc-macros `pin_data` and //! `pinned_drop`. It also contains `__init_internal`, the implementation of the //! `{try_}{pin_}init!` macros. //! //! These macros should never be called directly, since they expect their input to be //! in a certain format which is internal. If used incorrectly, these macros can lead to UB even in //! safe code! Use the public facing macros instead. //! //! This architecture has been chosen because the kernel does not yet have access to `syn` which //! would make matters a lot easier for implementing these as proc-macros. //! //! Since this library and the kernel implementation should diverge as little as possible, the same //! approach has been taken here. //! //! # Macro expansion example //! //! This section is intended for readers trying to understand the macros in this module and the //! `[try_][pin_]init!` macros from `lib.rs`. //! //! We will look at the following example: //! //! ```rust,ignore //! #[pin_data] //! #[repr(C)] //! struct Bar<T> { //! #[pin] //! t: T, //! pub x: usize, //! } //! //! impl<T> Bar<T> { //! fn new(t: T) -> impl PinInit<Self> { //! pin_init!(Self { t, x: 0 }) //! } //! } //! //! #[pin_data(PinnedDrop)] //! struct Foo { //! a: usize, //! #[pin] //! b: Bar<u32>, //! } //! //! #[pinned_drop] //! impl PinnedDrop for Foo { //! fn drop(self: Pin<&mut Self>) { //! println!("{self:p} is getting dropped."); //! } //! } //! //! let a = 42; //! let initializer = pin_init!(Foo { //! a, //! b <- Bar::new(36), //! }); //! ``` //! //! This example includes the most common and important features of the pin-init API. //! //! Below you can find individual section about the different macro invocations. Here are some //! general things we need to take into account when designing macros: //! - use global paths, similarly to file paths, these start with the separator: `::core::panic!()` //! this ensures that the correct item is used, since users could define their own `mod core {}` //! and then their own `panic!` inside to execute arbitrary code inside of our macro. //! - macro `unsafe` hygiene: we need to ensure that we do not expand arbitrary, user-supplied //! expressions inside of an `unsafe` block in the macro, because this would allow users to do //! `unsafe` operations without an associated `unsafe` block. //! //! ## `#[pin_data]` on `Bar` //! //! This macro is used to specify which fields are structurally pinned and which fields are not. It //! is placed on the struct definition and allows `#[pin]` to be placed on the fields. //! //! Here is the definition of `Bar` from our example: //! //! ```rust,ignore //! #[pin_data] //! #[repr(C)] //! struct Bar<T> { //! #[pin] //! t: T, //! pub x: usize, //! } //! ``` //! //! This expands to the following code: //! //! ```rust,ignore //! // Firstly the normal definition of the struct, attributes are preserved: //! #[repr(C)] //! struct Bar<T> { //! t: T, //! pub x: usize, //! } //! // Then an anonymous constant is defined, this is because we do not want any code to access the //! // types that we define inside: //! const _: () = { //! // We define the pin-data carrying struct, it is a ZST and needs to have the same generics, //! // since we need to implement access functions for each field and thus need to know its //! // type. //! struct __ThePinData<T> { //! __phantom: ::core::marker::PhantomData<fn(Bar<T>) -> Bar<T>>, //! } //! // We implement `Copy` for the pin-data struct, since all functions it defines will take //! // `self` by value. //! impl<T> ::core::clone::Clone for __ThePinData<T> { //! fn clone(&self) -> Self { //! *self //! } //! } //! impl<T> ::core::marker::Copy for __ThePinData<T> {} //! // For every field of `Bar`, the pin-data struct will define a function with the same name //! // and accessor (`pub` or `pub(crate)` etc.). This function will take a pointer to the //! // field (`slot`) and a `PinInit` or `Init` depending on the projection kind of the field //! // (if pinning is structural for the field, then `PinInit` otherwise `Init`). //! #[allow(dead_code)] //! impl<T> __ThePinData<T> { //! unsafe fn t<E>( //! self, //! slot: *mut T, //! // Since `t` is `#[pin]`, this is `PinInit`. //! init: impl ::pin_init::PinInit<T, E>, //! ) -> ::core::result::Result<(), E> { //! unsafe { ::pin_init::PinInit::__pinned_init(init, slot) } //! } //! pub unsafe fn x<E>( //! self, //! slot: *mut usize, //! // Since `x` is not `#[pin]`, this is `Init`. //! init: impl ::pin_init::Init<usize, E>, //! ) -> ::core::result::Result<(), E> { //! unsafe { ::pin_init::Init::__init(init, slot) } //! } //! } //! // Implement the internal `HasPinData` trait that associates `Bar` with the pin-data struct //! // that we constructed above. //! unsafe impl<T> ::pin_init::__internal::HasPinData for Bar<T> { //! type PinData = __ThePinData<T>; //! unsafe fn __pin_data() -> Self::PinData { //! __ThePinData { //! __phantom: ::core::marker::PhantomData, //! } //! } //! } //! // Implement the internal `PinData` trait that marks the pin-data struct as a pin-data //! // struct. This is important to ensure that no user can implement a rogue `__pin_data` //! // function without using `unsafe`. //! unsafe impl<T> ::pin_init::__internal::PinData for __ThePinData<T> { //! type Datee = Bar<T>; //! } //! // Now we only want to implement `Unpin` for `Bar` when every structurally pinned field is //! // `Unpin`. In other words, whether `Bar` is `Unpin` only depends on structurally pinned //! // fields (those marked with `#[pin]`). These fields will be listed in this struct, in our //! // case no such fields exist, hence this is almost empty. The two phantomdata fields exist //! // for two reasons: //! // - `__phantom`: every generic must be used, since we cannot really know which generics //! // are used, we declare all and then use everything here once. //! // - `__phantom_pin`: uses the `'__pin` lifetime and ensures that this struct is invariant //! // over it. The lifetime is needed to work around the limitation that trait bounds must //! // not be trivial, e.g. the user has a `#[pin] PhantomPinned` field -- this is //! // unconditionally `!Unpin` and results in an error. The lifetime tricks the compiler //! // into accepting these bounds regardless. //! #[allow(dead_code)] //! struct __Unpin<'__pin, T> { //! __phantom_pin: ::core::marker::PhantomData<fn(&'__pin ()) -> &'__pin ()>, //! __phantom: ::core::marker::PhantomData<fn(Bar<T>) -> Bar<T>>, //! // Our only `#[pin]` field is `t`. //! t: T, //! } //! #[doc(hidden)] //! impl<'__pin, T> ::core::marker::Unpin for Bar<T> //! where //! __Unpin<'__pin, T>: ::core::marker::Unpin, //! {} //! // Now we need to ensure that `Bar` does not implement `Drop`, since that would give users //! // access to `&mut self` inside of `drop` even if the struct was pinned. This could lead to //! // UB with only safe code, so we disallow this by giving a trait implementation error using //! // a direct impl and a blanket implementation. //! trait MustNotImplDrop {} //! // Normally `Drop` bounds do not have the correct semantics, but for this purpose they do //! // (normally people want to know if a type has any kind of drop glue at all, here we want //! // to know if it has any kind of custom drop glue, which is exactly what this bound does). //! #[expect(drop_bounds)] //! impl<T: ::core::ops::Drop> MustNotImplDrop for T {} //! impl<T> MustNotImplDrop for Bar<T> {} //! // Here comes a convenience check, if one implemented `PinnedDrop`, but forgot to add it to //! // `#[pin_data]`, then this will error with the same mechanic as above, this is not needed //! // for safety, but a good sanity check, since no normal code calls `PinnedDrop::drop`. //! #[expect(non_camel_case_types)] //! trait UselessPinnedDropImpl_you_need_to_specify_PinnedDrop {} //! impl< //! T: ::pin_init::PinnedDrop, //! > UselessPinnedDropImpl_you_need_to_specify_PinnedDrop for T {} //! impl<T> UselessPinnedDropImpl_you_need_to_specify_PinnedDrop for Bar<T> {} //! }; //! ``` //! //! ## `pin_init!` in `impl Bar` //! //! This macro creates an pin-initializer for the given struct. It requires that the struct is //! annotated by `#[pin_data]`. //! //! Here is the impl on `Bar` defining the new function: //! //! ```rust,ignore //! impl<T> Bar<T> { //! fn new(t: T) -> impl PinInit<Self> { //! pin_init!(Self { t, x: 0 }) //! } //! } //! ``` //! //! This expands to the following code: //! //! ```rust,ignore //! impl<T> Bar<T> { //! fn new(t: T) -> impl PinInit<Self> { //! { //! // We do not want to allow arbitrary returns, so we declare this type as the `Ok` //! // return type and shadow it later when we insert the arbitrary user code. That way //! // there will be no possibility of returning without `unsafe`. //! struct __InitOk; //! // Get the data about fields from the supplied type. //! // - the function is unsafe, hence the unsafe block //! // - we `use` the `HasPinData` trait in the block, it is only available in that //! // scope. //! let data = unsafe { //! use ::pin_init::__internal::HasPinData; //! Self::__pin_data() //! }; //! // Ensure that `data` really is of type `PinData` and help with type inference: //! let init = ::pin_init::__internal::PinData::make_closure::< //! _, //! __InitOk, //! ::core::convert::Infallible, //! >(data, move |slot| { //! { //! // Shadow the structure so it cannot be used to return early. If a user //! // tries to write `return Ok(__InitOk)`, then they get a type error, //! // since that will refer to this struct instead of the one defined //! // above. //! struct __InitOk; //! // This is the expansion of `t,`, which is syntactic sugar for `t: t,`. //! { //! unsafe { ::core::ptr::write(::core::addr_of_mut!((*slot).t), t) }; //! } //! // Since initialization could fail later (not in this case, since the //! // error type is `Infallible`) we will need to drop this field if there //! // is an error later. This `DropGuard` will drop the field when it gets //! // dropped and has not yet been forgotten. //! let __t_guard = unsafe { //! ::pin_init::__internal::DropGuard::new(::core::addr_of_mut!((*slot).t)) //! }; //! // Expansion of `x: 0,`: //! // Since this can be an arbitrary expression we cannot place it inside //! // of the `unsafe` block, so we bind it here. //! { //! let x = 0; //! unsafe { ::core::ptr::write(::core::addr_of_mut!((*slot).x), x) }; //! } //! // We again create a `DropGuard`. //! let __x_guard = unsafe { //! ::pin_init::__internal::DropGuard::new(::core::addr_of_mut!((*slot).x)) //! }; //! // Since initialization has successfully completed, we can now forget //! // the guards. This is not `mem::forget`, since we only have //! // `&DropGuard`. //! ::core::mem::forget(__x_guard); //! ::core::mem::forget(__t_guard); //! // Here we use the type checker to ensure that every field has been //! // initialized exactly once, since this is `if false` it will never get //! // executed, but still type-checked. //! // Additionally we abuse `slot` to automatically infer the correct type //! // for the struct. This is also another check that every field is //! // accessible from this scope. //! #[allow(unreachable_code, clippy::diverging_sub_expression)] //! let _ = || { //! unsafe { //! ::core::ptr::write( //! slot, //! Self { //! // We only care about typecheck finding every field //! // here, the expression does not matter, just conjure //! // one using `panic!()`: //! t: ::core::panic!(), //! x: ::core::panic!(), //! }, //! ); //! }; //! }; //! } //! // We leave the scope above and gain access to the previously shadowed //! // `__InitOk` that we need to return. //! Ok(__InitOk) //! }); //! // Change the return type from `__InitOk` to `()`. //! let init = move | //! slot, //! | -> ::core::result::Result<(), ::core::convert::Infallible> { //! init(slot).map(|__InitOk| ()) //! }; //! // Construct the initializer. //! let init = unsafe { //! ::pin_init::pin_init_from_closure::< //! _, //! ::core::convert::Infallible, //! >(init) //! }; //! init //! } //! } //! } //! ``` //! //! ## `#[pin_data]` on `Foo` //! //! Since we already took a look at `#[pin_data]` on `Bar`, this section will only explain the //! differences/new things in the expansion of the `Foo` definition: //! //! ```rust,ignore //! #[pin_data(PinnedDrop)] //! struct Foo { //! a: usize, //! #[pin] //! b: Bar<u32>, //! } //! ``` //! //! This expands to the following code: //! //! ```rust,ignore //! struct Foo { //! a: usize, //! b: Bar<u32>, //! } //! const _: () = { //! struct __ThePinData { //! __phantom: ::core::marker::PhantomData<fn(Foo) -> Foo>, //! } //! impl ::core::clone::Clone for __ThePinData { //! fn clone(&self) -> Self { //! *self //! } //! } //! impl ::core::marker::Copy for __ThePinData {} //! #[allow(dead_code)] //! impl __ThePinData { //! unsafe fn b<E>( //! self, //! slot: *mut Bar<u32>, //! init: impl ::pin_init::PinInit<Bar<u32>, E>, //! ) -> ::core::result::Result<(), E> { //! unsafe { ::pin_init::PinInit::__pinned_init(init, slot) } //! } //! unsafe fn a<E>( //! self, //! slot: *mut usize, //! init: impl ::pin_init::Init<usize, E>, //! ) -> ::core::result::Result<(), E> { //! unsafe { ::pin_init::Init::__init(init, slot) } //! } //! } //! unsafe impl ::pin_init::__internal::HasPinData for Foo { //! type PinData = __ThePinData; //! unsafe fn __pin_data() -> Self::PinData { //! __ThePinData { //! __phantom: ::core::marker::PhantomData, //! } //! } //! } //! unsafe impl ::pin_init::__internal::PinData for __ThePinData { //! type Datee = Foo; //! } //! #[allow(dead_code)] //! struct __Unpin<'__pin> { //! __phantom_pin: ::core::marker::PhantomData<fn(&'__pin ()) -> &'__pin ()>, //! __phantom: ::core::marker::PhantomData<fn(Foo) -> Foo>, //! b: Bar<u32>, //! } //! #[doc(hidden)] //! impl<'__pin> ::core::marker::Unpin for Foo //! where //! __Unpin<'__pin>: ::core::marker::Unpin, //! {} //! // Since we specified `PinnedDrop` as the argument to `#[pin_data]`, we expect `Foo` to //! // implement `PinnedDrop`. Thus we do not need to prevent `Drop` implementations like //! // before, instead we implement `Drop` here and delegate to `PinnedDrop`. //! impl ::core::ops::Drop for Foo { //! fn drop(&mut self) { //! // Since we are getting dropped, no one else has a reference to `self` and thus we //! // can assume that we never move. //! let pinned = unsafe { ::core::pin::Pin::new_unchecked(self) }; //! // Create the unsafe token that proves that we are inside of a destructor, this //! // type is only allowed to be created in a destructor. //! let token = unsafe { ::pin_init::__internal::OnlyCallFromDrop::new() }; //! ::pin_init::PinnedDrop::drop(pinned, token); //! } //! } //! }; //! ``` //! //! ## `#[pinned_drop]` on `impl PinnedDrop for Foo` //! //! This macro is used to implement the `PinnedDrop` trait, since that trait is `unsafe` and has an //! extra parameter that should not be used at all. The macro hides that parameter. //! //! Here is the `PinnedDrop` impl for `Foo`: //! //! ```rust,ignore //! #[pinned_drop] //! impl PinnedDrop for Foo { //! fn drop(self: Pin<&mut Self>) { //! println!("{self:p} is getting dropped."); //! } //! } //! ``` //! //! This expands to the following code: //! //! ```rust,ignore //! // `unsafe`, full path and the token parameter are added, everything else stays the same. //! unsafe impl ::pin_init::PinnedDrop for Foo { //! fn drop(self: Pin<&mut Self>, _: ::pin_init::__internal::OnlyCallFromDrop) { //! println!("{self:p} is getting dropped."); //! } //! } //! ``` //! //! ## `pin_init!` on `Foo` //! //! Since we already took a look at `pin_init!` on `Bar`, this section will only show the expansion //! of `pin_init!` on `Foo`: //! //! ```rust,ignore //! let a = 42; //! let initializer = pin_init!(Foo { //! a, //! b <- Bar::new(36), //! }); //! ``` //! //! This expands to the following code: //! //! ```rust,ignore //! let a = 42; //! let initializer = { //! struct __InitOk; //! let data = unsafe { //! use ::pin_init::__internal::HasPinData; //! Foo::__pin_data() //! }; //! let init = ::pin_init::__internal::PinData::make_closure::< //! _, //! __InitOk, //! ::core::convert::Infallible, //! >(data, move |slot| { //! { //! struct __InitOk; //! { //! unsafe { ::core::ptr::write(::core::addr_of_mut!((*slot).a), a) }; //! } //! let __a_guard = unsafe { //! ::pin_init::__internal::DropGuard::new(::core::addr_of_mut!((*slot).a)) //! }; //! let init = Bar::new(36); //! unsafe { data.b(::core::addr_of_mut!((*slot).b), b)? }; //! let __b_guard = unsafe { //! ::pin_init::__internal::DropGuard::new(::core::addr_of_mut!((*slot).b)) //! }; //! ::core::mem::forget(__b_guard); //! ::core::mem::forget(__a_guard); //! #[allow(unreachable_code, clippy::diverging_sub_expression)] //! let _ = || { //! unsafe { //! ::core::ptr::write( //! slot, //! Foo { //! a: ::core::panic!(), //! b: ::core::panic!(), //! }, //! ); //! }; //! }; //! } //! Ok(__InitOk) //! }); //! let init = move | //! slot, //! | -> ::core::result::Result<(), ::core::convert::Infallible> { //! init(slot).map(|__InitOk| ()) //! }; //! let init = unsafe { //! ::pin_init::pin_init_from_closure::<_, ::core::convert::Infallible>(init) //! }; //! init //! }; //! ```
/// Creates a `unsafe impl<...> PinnedDrop for $type` block. /// /// See [`PinnedDrop`] for more information. #[doc(hidden)] #[macro_export]
macro_rules! __pinned_drop {
(
@impl_sig($($impl_sig:tt)*),
@impl_body(
$(#[$($attr:tt)*])* fn drop($($sig:tt)*) {
$($inner:tt)*
}
),
) => { // SAFETY: TODO. unsafe $($impl_sig)* { // Inherit all attributes and the type/ident tokens for the signature.
$(#[$($attr)*])* fn drop($($sig)*, _: $crate::__internal::OnlyCallFromDrop) {
$($inner)*
}
}
}
}
/// This macro first parses the struct definition such that it separates pinned and not pinned /// fields. Afterwards it declares the struct and implement the `PinData` trait safely. #[doc(hidden)] #[macro_export]
macro_rules! __pin_data { // Proc-macro entry point, this is supplied by the proc-macro pre-parsing.
(parse_input:
@args($($pinned_drop:ident)?),
@sig(
$(#[$($struct_attr:tt)*])*
$vis:vis struct $name:ident
$(where $($whr:tt)*)?
),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@decl_generics($($decl_generics:tt)*),
@body({ $($fields:tt)* }),
) => { // We now use token munching to iterate through all of the fields. While doing this we // identify fields marked with `#[pin]`, these fields are the 'pinned fields'. The user // wants these to be structurally pinned. The rest of the fields are the // 'not pinned fields'. Additionally we collect all fields, since we need them in the right // order to declare the struct. // // In this call we also put some explaining comments for the parameters.
$crate::__pin_data!(find_pinned_fields: // Attributes on the struct itself, these will just be propagated to be put onto the // struct definition.
@struct_attrs($(#[$($struct_attr)*])*), // The visibility of the struct.
@vis($vis), // The name of the struct.
@name($name), // The 'impl generics', the generics that will need to be specified on the struct inside // of an `impl<$ty_generics>` block.
@impl_generics($($impl_generics)*), // The 'ty generics', the generics that will need to be specified on the impl blocks.
@ty_generics($($ty_generics)*), // The 'decl generics', the generics that need to be specified on the struct // definition.
@decl_generics($($decl_generics)*), // The where clause of any impl block and the declaration.
@where($($($whr)*)?), // The remaining fields tokens that need to be processed. // We add a `,` at the end to ensure correct parsing.
@fields_munch($($fields)* ,), // The pinned fields.
@pinned(), // The not pinned fields.
@not_pinned(), // All fields.
@fields(), // The accumulator containing all attributes already parsed.
@accum(), // Contains `yes` or `` to indicate if `#[pin]` was found on the current field.
@is_pinned(), // The proc-macro argument, this should be `PinnedDrop` or ``.
@pinned_drop($($pinned_drop)?),
);
};
(find_pinned_fields:
@struct_attrs($($struct_attrs:tt)*),
@vis($vis:vis),
@name($name:ident),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@decl_generics($($decl_generics:tt)*),
@where($($whr:tt)*), // We found a PhantomPinned field, this should generally be pinned!
@fields_munch($field:ident : $($($(::)?core::)?marker::)?PhantomPinned, $($rest:tt)*),
@pinned($($pinned:tt)*),
@not_pinned($($not_pinned:tt)*),
@fields($($fields:tt)*),
@accum($($accum:tt)*), // This field is not pinned.
@is_pinned(),
@pinned_drop($($pinned_drop:ident)?),
) => {
::core::compile_error!(concat!( "The field `",
stringify!($field), "` of type `PhantomPinned` only has an effect, if it has the `#[pin]` attribute.",
));
$crate::__pin_data!(find_pinned_fields:
@struct_attrs($($struct_attrs)*),
@vis($vis),
@name($name),
@impl_generics($($impl_generics)*),
@ty_generics($($ty_generics)*),
@decl_generics($($decl_generics)*),
@where($($whr)*),
@fields_munch($($rest)*),
@pinned($($pinned)* $($accum)* $field: ::core::marker::PhantomPinned,),
@not_pinned($($not_pinned)*),
@fields($($fields)* $($accum)* $field: ::core::marker::PhantomPinned,),
@accum(),
@is_pinned(),
@pinned_drop($($pinned_drop)?),
);
};
(find_pinned_fields:
@struct_attrs($($struct_attrs:tt)*),
@vis($vis:vis),
@name($name:ident),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@decl_generics($($decl_generics:tt)*),
@where($($whr:tt)*), // We reached the field declaration.
@fields_munch($field:ident : $type:ty, $($rest:tt)*),
@pinned($($pinned:tt)*),
@not_pinned($($not_pinned:tt)*),
@fields($($fields:tt)*),
@accum($($accum:tt)*), // This field is pinned.
@is_pinned(yes),
@pinned_drop($($pinned_drop:ident)?),
) => {
$crate::__pin_data!(find_pinned_fields:
@struct_attrs($($struct_attrs)*),
@vis($vis),
@name($name),
@impl_generics($($impl_generics)*),
@ty_generics($($ty_generics)*),
@decl_generics($($decl_generics)*),
@where($($whr)*),
@fields_munch($($rest)*),
@pinned($($pinned)* $($accum)* $field: $type,),
@not_pinned($($not_pinned)*),
@fields($($fields)* $($accum)* $field: $type,),
@accum(),
@is_pinned(),
@pinned_drop($($pinned_drop)?),
);
};
(find_pinned_fields:
@struct_attrs($($struct_attrs:tt)*),
@vis($vis:vis),
@name($name:ident),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@decl_generics($($decl_generics:tt)*),
@where($($whr:tt)*), // We reached the field declaration.
@fields_munch($field:ident : $type:ty, $($rest:tt)*),
@pinned($($pinned:tt)*),
@not_pinned($($not_pinned:tt)*),
@fields($($fields:tt)*),
@accum($($accum:tt)*), // This field is not pinned.
@is_pinned(),
@pinned_drop($($pinned_drop:ident)?),
) => {
$crate::__pin_data!(find_pinned_fields:
@struct_attrs($($struct_attrs)*),
@vis($vis),
@name($name),
@impl_generics($($impl_generics)*),
@ty_generics($($ty_generics)*),
@decl_generics($($decl_generics)*),
@where($($whr)*),
@fields_munch($($rest)*),
@pinned($($pinned)*),
@not_pinned($($not_pinned)* $($accum)* $field: $type,),
@fields($($fields)* $($accum)* $field: $type,),
@accum(),
@is_pinned(),
@pinned_drop($($pinned_drop)?),
);
};
(find_pinned_fields:
@struct_attrs($($struct_attrs:tt)*),
@vis($vis:vis),
@name($name:ident),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@decl_generics($($decl_generics:tt)*),
@where($($whr:tt)*), // We found the `#[pin]` attr.
@fields_munch(#[pin] $($rest:tt)*),
@pinned($($pinned:tt)*),
@not_pinned($($not_pinned:tt)*),
@fields($($fields:tt)*),
@accum($($accum:tt)*),
@is_pinned($($is_pinned:ident)?),
@pinned_drop($($pinned_drop:ident)?),
) => {
$crate::__pin_data!(find_pinned_fields:
@struct_attrs($($struct_attrs)*),
@vis($vis),
@name($name),
@impl_generics($($impl_generics)*),
@ty_generics($($ty_generics)*),
@decl_generics($($decl_generics)*),
@where($($whr)*),
@fields_munch($($rest)*), // We do not include `#[pin]` in the list of attributes, since it is not actually an // attribute that is defined somewhere.
@pinned($($pinned)*),
@not_pinned($($not_pinned)*),
@fields($($fields)*),
@accum($($accum)*), // Set this to `yes`.
@is_pinned(yes),
@pinned_drop($($pinned_drop)?),
);
};
(find_pinned_fields:
@struct_attrs($($struct_attrs:tt)*),
@vis($vis:vis),
@name($name:ident),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@decl_generics($($decl_generics:tt)*),
@where($($whr:tt)*), // We reached the field declaration with visibility, for simplicity we only munch the // visibility and put it into `$accum`.
@fields_munch($fvis:vis $field:ident $($rest:tt)*),
@pinned($($pinned:tt)*),
@not_pinned($($not_pinned:tt)*),
@fields($($fields:tt)*),
@accum($($accum:tt)*),
@is_pinned($($is_pinned:ident)?),
@pinned_drop($($pinned_drop:ident)?),
) => {
$crate::__pin_data!(find_pinned_fields:
@struct_attrs($($struct_attrs)*),
@vis($vis),
@name($name),
@impl_generics($($impl_generics)*),
@ty_generics($($ty_generics)*),
@decl_generics($($decl_generics)*),
@where($($whr)*),
@fields_munch($field $($rest)*),
@pinned($($pinned)*),
@not_pinned($($not_pinned)*),
@fields($($fields)*),
@accum($($accum)* $fvis),
@is_pinned($($is_pinned)?),
@pinned_drop($($pinned_drop)?),
);
};
(find_pinned_fields:
@struct_attrs($($struct_attrs:tt)*),
@vis($vis:vis),
@name($name:ident),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@decl_generics($($decl_generics:tt)*),
@where($($whr:tt)*), // Some other attribute, just put it into `$accum`.
@fields_munch(#[$($attr:tt)*] $($rest:tt)*),
@pinned($($pinned:tt)*),
@not_pinned($($not_pinned:tt)*),
@fields($($fields:tt)*),
@accum($($accum:tt)*),
@is_pinned($($is_pinned:ident)?),
@pinned_drop($($pinned_drop:ident)?),
) => {
$crate::__pin_data!(find_pinned_fields:
@struct_attrs($($struct_attrs)*),
@vis($vis),
@name($name),
@impl_generics($($impl_generics)*),
@ty_generics($($ty_generics)*),
@decl_generics($($decl_generics)*),
@where($($whr)*),
@fields_munch($($rest)*),
@pinned($($pinned)*),
@not_pinned($($not_pinned)*),
@fields($($fields)*),
@accum($($accum)* #[$($attr)*]),
@is_pinned($($is_pinned)?),
@pinned_drop($($pinned_drop)?),
);
};
(find_pinned_fields:
@struct_attrs($($struct_attrs:tt)*),
@vis($vis:vis),
@name($name:ident),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@decl_generics($($decl_generics:tt)*),
@where($($whr:tt)*), // We reached the end of the fields, plus an optional additional comma, since we added one // before and the user is also allowed to put a trailing comma.
@fields_munch($(,)?),
@pinned($($pinned:tt)*),
@not_pinned($($not_pinned:tt)*),
@fields($($fields:tt)*),
@accum(),
@is_pinned(),
@pinned_drop($($pinned_drop:ident)?),
) => { // Declare the struct with all fields in the correct order.
$($struct_attrs)*
$vis struct $name <$($decl_generics)*> where $($whr)*
{
$($fields)*
}
// We put the rest into this const item, because it then will not be accessible to anything // outside. const _: () = { // We declare this struct which will host all of the projection function for our type. // it will be invariant over all generic parameters which are inherited from the // struct.
$vis struct __ThePinData<$($impl_generics)*> where $($whr)*
{
__phantom: ::core::marker::PhantomData< fn($name<$($ty_generics)*>) -> $name<$($ty_generics)*>
>,
}
impl<$($impl_generics)*> ::core::clone::Clone for __ThePinData<$($ty_generics)*> where $($whr)*
{ fn clone(&self) -> Self { *self }
}
impl<$($impl_generics)*> ::core::marker::Copy for __ThePinData<$($ty_generics)*> where $($whr)*
{}
// Make all projection functions.
$crate::__pin_data!(make_pin_data:
@pin_data(__ThePinData),
@impl_generics($($impl_generics)*),
@ty_generics($($ty_generics)*),
@where($($whr)*),
@pinned($($pinned)*),
@not_pinned($($not_pinned)*),
);
// SAFETY: We have added the correct projection functions above to `__ThePinData` and // we also use the least restrictive generics possible. unsafeimpl<$($impl_generics)*>
$crate::__internal::HasPinData for $name<$($ty_generics)*> where $($whr)*
{ type PinData = __ThePinData<$($ty_generics)*>;
// SAFETY: TODO. unsafeimpl<$($impl_generics)*>
$crate::__internal::PinData for __ThePinData<$($ty_generics)*> where $($whr)*
{ type Datee = $name<$($ty_generics)*>;
}
// This struct will be used for the unpin analysis. Since only structurally pinned // fields are relevant whether the struct should implement `Unpin`. #[allow(dead_code)] struct __Unpin <'__pin, $($impl_generics)*> where $($whr)*
{
__phantom_pin: ::core::marker::PhantomData<fn(&'__pin ()) -> &'pan>__pin ()>,
__phantom: ::core::marker::PhantomData< fn($name<$($ty_generics)*>) -> $name<$($ty_generics)*>
>, // Only the pinned fields.
$($pinned)*
}
#[doc(hidden)] impl<'__pin, $($impl_generics)*> ::core::marker::Unpin for $name<$($ty_generics)*> where
__Unpin<'__pin, $($ty_generics)*>: ::core::marker::Unpin,
$($whr)*
{}
// We need to disallow normal `Drop` implementation, the exact behavior depends on // whether `PinnedDrop` was specified as the parameter.
$crate::__pin_data!(drop_prevention:
@name($name),
@impl_generics($($impl_generics)*),
@ty_generics($($ty_generics)*),
@where($($whr)*),
@pinned_drop($($pinned_drop)?),
);
};
}; // When no `PinnedDrop` was specified, then we have to prevent implementing drop.
(drop_prevention:
@name($name:ident),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@where($($whr:tt)*),
@pinned_drop(),
) => { // We prevent this by creating a trait that will be implemented for all types implementing // `Drop`. Additionally we will implement this trait for the struct leading to a conflict, // if it also implements `Drop` trait MustNotImplDrop {} #[expect(drop_bounds)] impl<T: ::core::ops::Drop> MustNotImplDrop for T {} impl<$($impl_generics)*> MustNotImplDrop for $name<$($ty_generics)*> where $($whr)* {} // We also take care to prevent users from writing a useless `PinnedDrop` implementation. // They might implement `PinnedDrop` correctly for the struct, but forget to give // `PinnedDrop` as the parameter to `#[pin_data]`. #[expect(non_camel_case_types)] trait UselessPinnedDropImpl_you_need_to_specify_PinnedDrop {} impl<T: $crate::PinnedDrop>
UselessPinnedDropImpl_you_need_to_specify_PinnedDrop for T {} impl<$($impl_generics)*>
UselessPinnedDropImpl_you_need_to_specify_PinnedDrop for $name<$($ty_generics)*> where $($whr)* {}
}; // When `PinnedDrop` was specified we just implement `Drop` and delegate.
(drop_prevention:
@name($name:ident),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@where($($whr:tt)*),
@pinned_drop(PinnedDrop),
) => { impl<$($impl_generics)*> ::core::ops::Drop for $name<$($ty_generics)*> where $($whr)*
{ fn drop(&mutself) { // SAFETY: Since this is a destructor, `self` will not move after this function // terminates, since it is inaccessible. let pinned = unsafe { ::core::pin::Pin::new_unchecked(self) }; // SAFETY: Since this is a drop function, we can create this token to call the // pinned destructor of this type. let token = unsafe { $crate::__internal::OnlyCallFromDrop::new() };
$crate::PinnedDrop::drop(pinned, token);
}
}
}; // If some other parameter was specified, we emit a readable error.
(drop_prevention:
@name($name:ident),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@where($($whr:tt)*),
@pinned_drop($($rest:tt)*),
) => {
compile_error!( "Wrong parameters to `#[pin_data]`, expected nothing or `PinnedDrop`, got '{}'.",
stringify!($($rest)*),
);
};
(make_pin_data:
@pin_data($pin_data:ident),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@where($($whr:tt)*),
@pinned($($(#[$($p_attr:tt)*])* $pvis:vis $p_field:ident : $p_type:ty),* $(,)?),
@not_pinned($($(#[$($attr:tt)*])* $fvis:vis $field:ident : $type:ty),* $(,)?),
) => { // For every field, we create a projection function according to its projection type. If a // field is structurally pinned, then it must be initialized via `PinInit`, if it is not // structurally pinned, then it can be initialized via `Init`. // // The functions are `unsafe` to prevent accidentally calling them. #[allow(dead_code)] #[expect(clippy::missing_safety_doc)] impl<$($impl_generics)*> $pin_data<$($ty_generics)*> where $($whr)*
{
$(
$(#[$($p_attr)*])*
$pvis unsafefn $p_field<E>( self,
slot: *mut $p_type,
init: impl $crate::PinInit<$p_type, E>,
) -> ::core::result::Result<(), E> { // SAFETY: TODO. unsafe { $crate::PinInit::__pinned_init(init, slot) }
}
)*
$(
$(#[$($attr)*])*
$fvis unsafefn $field<E>( self,
slot: *mut $type,
init: impl $crate::Init<$type, E>,
) -> ::core::result::Result<(), E> { // SAFETY: TODO. unsafe { $crate::Init::__init(init, slot) }
}
)*
}
};
}
/// The internal init macro. Do not call manually! /// /// This is called by the `{try_}{pin_}init!` macros with various inputs. /// /// This macro has multiple internal call configurations, these are always the very first ident: /// - nothing: this is the base case and called by the `{try_}{pin_}init!` macros. /// - `with_update_parsed`: when the `..Zeroable::init_zeroed()` syntax has been handled. /// - `init_slot`: recursively creates the code that initializes all fields in `slot`. /// - `make_initializer`: recursively create the struct initializer that guarantees that every /// field has been initialized exactly once. #[doc(hidden)] #[macro_export]
macro_rules! __init_internal {
(
@this($($this:ident)?),
@typ($t:path),
@fields($($fields:tt)*),
@error($err:ty), // Either `PinData` or `InitData`, `$use_data` should only be present in the `PinData` // case.
@data($data:ident, $($use_data:ident)?), // `HasPinData` or `HasInitData`.
@has_data($has_data:ident, $get_data:ident), // `pin_init_from_closure` or `init_from_closure`.
@construct_closure($construct_closure:ident),
@munch_fields(),
) => {
$crate::__init_internal!(with_update_parsed:
@this($($this)?),
@typ($t),
@fields($($fields)*),
@error($err),
@data($data, $($use_data)?),
@has_data($has_data, $get_data),
@construct_closure($construct_closure),
@init_zeroed(), // Nothing means default behavior.
)
};
(
@this($($this:ident)?),
@typ($t:path),
@fields($($fields:tt)*),
@error($err:ty), // Either `PinData` or `InitData`, `$use_data` should only be present in the `PinData` // case.
@data($data:ident, $($use_data:ident)?), // `HasPinData` or `HasInitData`.
@has_data($has_data:ident, $get_data:ident), // `pin_init_from_closure` or `init_from_closure`.
@construct_closure($construct_closure:ident),
@munch_fields(..Zeroable::init_zeroed()),
) => {
$crate::__init_internal!(with_update_parsed:
@this($($this)?),
@typ($t),
@fields($($fields)*),
@error($err),
@data($data, $($use_data)?),
@has_data($has_data, $get_data),
@construct_closure($construct_closure),
@init_zeroed(()), // `()` means zero all fields not mentioned.
)
};
(
@this($($this:ident)?),
@typ($t:path),
@fields($($fields:tt)*),
@error($err:ty), // Either `PinData` or `InitData`, `$use_data` should only be present in the `PinData` // case.
@data($data:ident, $($use_data:ident)?), // `HasPinData` or `HasInitData`.
@has_data($has_data:ident, $get_data:ident), // `pin_init_from_closure` or `init_from_closure`.
@construct_closure($construct_closure:ident),
@munch_fields($ignore:tt $($rest:tt)*),
) => {
$crate::__init_internal!(
@this($($this)?),
@typ($t),
@fields($($fields)*),
@error($err),
@data($data, $($use_data)?),
@has_data($has_data, $get_data),
@construct_closure($construct_closure),
@munch_fields($($rest)*),
)
};
(with_update_parsed:
@this($($this:ident)?),
@typ($t:path),
@fields($($fields:tt)*),
@error($err:ty), // Either `PinData` or `InitData`, `$use_data` should only be present in the `PinData` // case.
@data($data:ident, $($use_data:ident)?), // `HasPinData` or `HasInitData`.
@has_data($has_data:ident, $get_data:ident), // `pin_init_from_closure` or `init_from_closure`.
@construct_closure($construct_closure:ident),
@init_zeroed($($init_zeroed:expr)?),
) => {{ // We do not want to allow arbitrary returns, so we declare this type as the `Ok` return // type and shadow it later when we insert the arbitrary user code. That way there will be // no possibility of returning without `unsafe`. struct __InitOk; // Get the data about fields from the supplied type. // // SAFETY: TODO. let data = unsafe { use $crate::__internal::$has_data; // Here we abuse `paste!` to retokenize `$t`. Declarative macros have some internal // information that is associated to already parsed fragments, so a path fragment // cannot be used in this position. Doing the retokenization results in valid rust // code.
$crate::macros::paste!($t::$get_data())
}; // Ensure that `data` really is of type `$data` and help with type inference: let init = $crate::__internal::$data::make_closure::<_, __InitOk, $err>(
data, move |slot| {
{ // Shadow the structure so it cannot be used to return early. struct __InitOk; // If `$init_zeroed` is present we should zero the slot now and not emit an // error when fields are missing (since they will be zeroed). We also have to // check that the type actually implements `Zeroable`.
$({ fn assert_zeroable<T: $crate::Zeroable>(_: *mut T) {} // Ensure that the struct is indeed `Zeroable`.
assert_zeroable(slot); // SAFETY: The type implements `Zeroable` by the check above. unsafe { ::core::ptr::write_bytes(slot, 0, 1) };
$init_zeroed // This will be `()` if set.
})? // Create the `this` so it can be referenced by the user inside of the // expressions creating the individual fields.
$(let $this = unsafe { ::core::ptr::NonNull::new_unchecked(slot) };)? // Initialize every field.
$crate::__init_internal!(init_slot($($use_data)?):
@data(data),
@slot(slot),
@guards(),
@munch_fields($($fields)*,),
); // We use unreachable code to ensure that all fields have been mentioned exactly // once, this struct initializer will still be type-checked and complain with a // very natural error message if a field is forgotten/mentioned more than once. #[allow(unreachable_code, clippy::diverging_sub_expression)] let _ = || {
$crate::__init_internal!(make_initializer:
@slot(slot),
@type_name($t),
@munch_fields($($fields)*,),
@acc(),
);
};
}
Ok(__InitOk)
}
); let init = move |slot| -> ::core::result::Result<(), $err> {
init(slot).map(|__InitOk| ())
}; // SAFETY: TODO. let init = unsafe { $crate::$construct_closure::<_, $err>(init) };
init
}};
(init_slot($($use_data:ident)?):
@data($data:ident),
@slot($slot:ident),
@guards($($guards:ident,)*),
@munch_fields($(..Zeroable::init_zeroed())? $(,)?),
) => { // Endpoint of munching, no fields are left. If execution reaches this point, all fields // have been initialized. Therefore we can now dismiss the guards by forgetting them.
$(::core::mem::forget($guards);)*
};
(init_slot($use_data:ident): // `use_data` is present, so we use the `data` to init fields.
@data($data:ident),
@slot($slot:ident),
@guards($($guards:ident,)*), // In-place initialization syntax.
@munch_fields($field:ident <- $val:expr, $($rest:tt)*),
) => { let init = $val; // Call the initializer. // // SAFETY: `slot` is valid, because we are inside of an initializer closure, we // return when an error/panic occurs. // We also use the `data` to require the correct trait (`Init` or `PinInit`) for `$field`. unsafe { $data.$field(::core::ptr::addr_of_mut!((*$slot).$field), init)? }; // Create the drop guard: // // We rely on macro hygiene to make it impossible for users to access this local variable. // We use `paste!` to create new hygiene for `$field`.
$crate::macros::paste! { // SAFETY: We forget the guard later when initialization has succeeded. let [< __ $field _guard >] = unsafe {
$crate::__internal::DropGuard::new(::core::ptr::addr_of_mut!((*$slot).$field))
};
$crate::__init_internal!(init_slot($use_data):
@data($data),
@slot($slot),
@guards([< __ $field _guard >], $($guards,)*),
@munch_fields($($rest)*),
);
}
};
(init_slot(): // No `use_data`, so we use `Init::__init` directly.
@data($data:ident),
@slot($slot:ident),
@guards($($guards:ident,)*), // In-place initialization syntax.
@munch_fields($field:ident <- $val:expr, $($rest:tt)*),
) => { let init = $val; // Call the initializer. // // SAFETY: `slot` is valid, because we are inside of an initializer closure, we // return when an error/panic occurs. unsafe { $crate::Init::__init(init, ::core::ptr::addr_of_mut!((*$slot).$field))? }; // Create the drop guard: // // We rely on macro hygiene to make it impossible for users to access this local variable. // We use `paste!` to create new hygiene for `$field`.
$crate::macros::paste! { // SAFETY: We forget the guard later when initialization has succeeded. let [< __ $field _guard >] = unsafe {
$crate::__internal::DropGuard::new(::core::ptr::addr_of_mut!((*$slot).$field))
};
$crate::__init_internal!(init_slot():
@data($data),
@slot($slot),
@guards([< __ $field _guard >], $($guards,)*),
@munch_fields($($rest)*),
);
}
};
(init_slot($($use_data:ident)?):
@data($data:ident),
@slot($slot:ident),
@guards($($guards:ident,)*), // Init by-value.
@munch_fields($field:ident $(: $val:expr)?, $($rest:tt)*),
) => {
{
$(let $field = $val;)? // Initialize the field. // // SAFETY: The memory at `slot` is uninitialized. unsafe { ::core::ptr::write(::core::ptr::addr_of_mut!((*$slot).$field), $field) };
} // Create the drop guard: // // We rely on macro hygiene to make it impossible for users to access this local variable. // We use `paste!` to create new hygiene for `$field`.
$crate::macros::paste! { // SAFETY: We forget the guard later when initialization has succeeded. let [< __ $field _guard >] = unsafe {
$crate::__internal::DropGuard::new(::core::ptr::addr_of_mut!((*$slot).$field))
};
$crate::__init_internal!(init_slot($($use_data)?):
@data($data),
@slot($slot),
@guards([< __ $field _guard >], $($guards,)*),
@munch_fields($($rest)*),
);
}
};
(make_initializer:
@slot($slot:ident),
@type_name($t:path),
@munch_fields(..Zeroable::init_zeroed() $(,)?),
@acc($($acc:tt)*),
) => { // Endpoint, nothing more to munch, create the initializer. Since the users specified // `..Zeroable::init_zeroed()`, the slot will already have been zeroed and all field that have // not been overwritten are thus zero and initialized. We still check that all fields are // actually accessible by using the struct update syntax ourselves. // We are inside of a closure that is never executed and thus we can abuse `slot` to // get the correct type inference here: #[allow(unused_assignments)] unsafe { letmut zeroed = ::core::mem::zeroed(); // We have to use type inference here to make zeroed have the correct type. This does // not get executed, so it has no effect.
::core::ptr::write($slot, zeroed);
zeroed = ::core::mem::zeroed(); // Here we abuse `paste!` to retokenize `$t`. Declarative macros have some internal // information that is associated to already parsed fragments, so a path fragment // cannot be used in this position. Doing the retokenization results in valid rust // code.
$crate::macros::paste!(
::core::ptr::write($slot, $t {
$($acc)*
..zeroed
});
);
}
};
(make_initializer:
@slot($slot:ident),
@type_name($t:path),
@munch_fields($(,)?),
@acc($($acc:tt)*),
) => { // Endpoint, nothing more to munch, create the initializer. // Since we are in the closure that is never called, this will never get executed. // We abuse `slot` to get the correct type inference here: // // SAFETY: TODO. unsafe { // Here we abuse `paste!` to retokenize `$t`. Declarative macros have some internal // information that is associated to already parsed fragments, so a path fragment // cannot be used in this position. Doing the retokenization results in valid rust // code.
$crate::macros::paste!(
::core::ptr::write($slot, $t {
$($acc)*
});
);
}
};
(make_initializer:
@slot($slot:ident),
@type_name($t:path),
@munch_fields($field:ident <- $val:expr, $($rest:tt)*),
@acc($($acc:tt)*),
) => {
$crate::__init_internal!(make_initializer:
@slot($slot),
@type_name($t),
@munch_fields($($rest)*),
@acc($($acc)* $field: ::core::panic!(),),
);
};
(make_initializer:
@slot($slot:ident),
@type_name($t:path),
@munch_fields($field:ident $(: $val:expr)?, $($rest:tt)*),
@acc($($acc:tt)*),
) => {
$crate::__init_internal!(make_initializer:
@slot($slot),
@type_name($t),
@munch_fields($($rest)*),
@acc($($acc)* $field: ::core::panic!(),),
);
};
}
#[doc(hidden)] #[macro_export]
macro_rules! __derive_zeroable {
(parse_input:
@sig(
$(#[$($struct_attr:tt)*])*
$vis:vis struct $name:ident
$(where $($whr:tt)*)?
),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@body({
$(
$(#[$($field_attr:tt)*])*
$field_vis:vis $field:ident : $field_ty:ty
),* $(,)?
}),
) => { // SAFETY: Every field type implements `Zeroable` and padding bytes may be zero. #[automatically_derived] unsafeimpl<$($impl_generics)*> $crate::Zeroable for $name<$($ty_generics)*> where
$($($whr)*)?
{} const _: () = { fn assert_zeroable<T: ?::core::marker::Sized + $crate::Zeroable>() {} fn ensure_zeroable<$($impl_generics)*>() where $($($whr)*)?
{
$(assert_zeroable::<$field_ty>();)*
}
};
};
(parse_input:
@sig(
$(#[$($struct_attr:tt)*])*
$vis:vis union $name:ident
$(where $($whr:tt)*)?
),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@body({
$(
$(#[$($field_attr:tt)*])*
$field_vis:vis $field:ident : $field_ty:ty
),* $(,)?
}),
) => { // SAFETY: Every field type implements `Zeroable` and padding bytes may be zero. #[automatically_derived] unsafeimpl<$($impl_generics)*> $crate::Zeroable for $name<$($ty_generics)*> where
$($($whr)*)?
{} const _: () = { fn assert_zeroable<T: ?::core::marker::Sized + $crate::Zeroable>() {} fn ensure_zeroable<$($impl_generics)*>() where $($($whr)*)?
{
$(assert_zeroable::<$field_ty>();)*
}
};
};
}
#[doc(hidden)] #[macro_export]
macro_rules! __maybe_derive_zeroable {
(parse_input:
@sig(
$(#[$($struct_attr:tt)*])*
$vis:vis struct $name:ident
$(where $($whr:tt)*)?
),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@body({
$(
$(#[$($field_attr:tt)*])*
$field_vis:vis $field:ident : $field_ty:ty
),* $(,)?
}),
) => { // SAFETY: Every field type implements `Zeroable` and padding bytes may be zero. #[automatically_derived] unsafeimpl<$($impl_generics)*> $crate::Zeroable for $name<$($ty_generics)*> where
$( // the `for<'__dummy>` HRTB makes this not error without the `trivial_bounds` // feature <https://github.com/rust-lang/rust/issues/48214#issuecomment-2557829956>.
$field_ty: for<'__dummy> $crate::Zeroable,
)*
$($($whr)*)?
{}
};
(parse_input:
@sig(
$(#[$($struct_attr:tt)*])*
$vis:vis union $name:ident
$(where $($whr:tt)*)?
),
@impl_generics($($impl_generics:tt)*),
@ty_generics($($ty_generics:tt)*),
@body({
$(
$(#[$($field_attr:tt)*])*
$field_vis:vis $field:ident : $field_ty:ty
),* $(,)?
}),
) => { // SAFETY: Every field type implements `Zeroable` and padding bytes may be zero. #[automatically_derived] unsafeimpl<$($impl_generics)*> $crate::Zeroable for $name<$($ty_generics)*> where
$( // the `for<'__dummy>` HRTB makes this not error without the `trivial_bounds` // feature <https://github.com/rust-lang/rust/issues/48214#issuecomment-2557829956>.
$field_ty: for<'__dummy> $crate::Zeroable,
)*
$($($whr)*)?
{}
};
}
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