vendor/zerocopy-0.7.31/src/macros.rs - toolchain/rustc - Git at Google

 // Copyright 2023 The Fuchsia Authors
 //
 // Licensed under a BSD-style license <LICENSE-BSD>, Apache License, Version 2.0
 // <LICENSE-APACHE or https://www.apache.org/licenses/LICENSE-2.0>, or the MIT
 // license <LICENSE-MIT or https://opensource.org/licenses/MIT>, at your option.
 // This file may not be copied, modified, or distributed except according to
 // those terms.

 /// Documents multiple unsafe blocks with a single safety comment.
 ///
 /// Invoked as:
 ///
 /// ```rust,ignore
 /// safety_comment! {
 ///     // Non-doc comments come first.
 ///     /// SAFETY:
 ///     /// Safety comment starts on its own line.
 ///     macro_1!(args);
 ///     macro_2! { args };
 ///     /// SAFETY:
 ///     /// Subsequent safety comments are allowed but not required.
 ///     macro_3! { args };
 /// }
 /// ```
 ///
 /// The macro invocations are emitted, each decorated with the following
 /// attribute: `#[allow(clippy::undocumented_unsafe_blocks)]`.
 macro_rules! safety_comment {
     (#[doc = r" SAFETY:"] $($(#[$attr:meta])* $macro:ident!$args:tt;)*) => {
         #[allow(clippy::undocumented_unsafe_blocks, unused_attributes)]
         const _: () = { $($(#[$attr])* $macro!$args;)* };
     }
 }

 /// Unsafely implements trait(s) for a type.
 ///
 /// # Safety
 ///
 /// The trait impl must be sound.
 ///
 /// When implementing `TryFromBytes`:
 /// - If no `is_bit_valid` impl is provided, then it must be valid for
 ///   `is_bit_valid` to unconditionally return `true`. In other words, it must
 ///   be the case that any initialized sequence of bytes constitutes a valid
 ///   instance of `$ty`.
 /// - If an `is_bit_valid` impl is provided, then:
 ///   - Regardless of whether the provided closure takes a `Ptr<$repr>` or
 ///     `&$repr` argument, it must be the case that, given `t: *mut $ty` and
 ///     `let r = t as *mut $repr`, `r` refers to an object of equal or lesser
 ///     size than the object referred to by `t`.
 ///   - If the provided closure takes a `&$repr` argument, then given a `Ptr<'a,
 ///     $ty>` which satisfies the preconditions of
 ///     `TryFromBytes::<$ty>::is_bit_valid`, it must be guaranteed that the
 ///     memory referenced by that `Ptr` always contains a valid `$repr`.
 ///   - The alignment of `$repr` is less than or equal to the alignment of
 ///     `$ty`.
 ///   - The impl of `is_bit_valid` must only return `true` for its argument
 ///     `Ptr<$repr>` if the original `Ptr<$ty>` refers to a valid `$ty`.
 macro_rules! unsafe_impl {
     // Implement `$trait` for `$ty` with no bounds.
     ($(#[$attr:meta])* $ty:ty: $trait:ident $(; |$candidate:ident: &$repr:ty| $is_bit_valid:expr)?) => {
         $(#[$attr])*
         unsafe impl $trait for $ty {
             unsafe_impl!(@method $trait $(; |$candidate: &$repr| $is_bit_valid)?);
         }
     };
     // Implement all `$traits` for `$ty` with no bounds.
     ($ty:ty: $($traits:ident),*) => {
         $( unsafe_impl!($ty: $traits); )*
     };
     // This arm is identical to the following one, except it contains a
     // preceding `const`. If we attempt to handle these with a single arm, there
     // is an inherent ambiguity between `const` (the keyword) and `const` (the
     // ident match for `$tyvar:ident`).
     //
     // To explain how this works, consider the following invocation:
     //
     //   unsafe_impl!(const N: usize, T: ?Sized + Copy => Clone for Foo<T>);
     //
     // In this invocation, here are the assignments to meta-variables:
     //
     //   |---------------|------------|
     //   | Meta-variable | Assignment |
     //   |---------------|------------|
     //   | $constname    |  N         |
     //   | $constty      |  usize     |
     //   | $tyvar        |  T         |
     //   | $optbound     |  Sized     |
     //   | $bound        |  Copy      |
     //   | $trait        |  Clone     |
     //   | $ty           |  Foo<T>    |
     //   |---------------|------------|
     //
     // The following arm has the same behavior with the exception of the lack of
     // support for a leading `const` parameter.
     (
         $(#[$attr:meta])*
         const $constname:ident : $constty:ident $(,)?
         $($tyvar:ident $(: $(? $optbound:ident $(+)?)* $($bound:ident $(+)?)* )?),*
         => $trait:ident for $ty:ty $(; |$candidate:ident $(: &$ref_repr:ty)? $(: Ptr<$ptr_repr:ty>)?| $is_bit_valid:expr)?
     ) => {
         unsafe_impl!(
             @inner
             $(#[$attr])*
             @const $constname: $constty,
             $($tyvar $(: $(? $optbound +)* + $($bound +)*)?,)*
             => $trait for $ty $(; |$candidate $(: &$ref_repr)? $(: Ptr<$ptr_repr>)?| $is_bit_valid)?
         );
     };
     (
         $(#[$attr:meta])*
         $($tyvar:ident $(: $(? $optbound:ident $(+)?)* $($bound:ident $(+)?)* )?),*
         => $trait:ident for $ty:ty $(; |$candidate:ident $(: &$ref_repr:ty)? $(: Ptr<$ptr_repr:ty>)?| $is_bit_valid:expr)?
     ) => {
         unsafe_impl!(
             @inner
             $(#[$attr])*
             $($tyvar $(: $(? $optbound +)* + $($bound +)*)?,)*
             => $trait for $ty $(; |$candidate $(: &$ref_repr)? $(: Ptr<$ptr_repr>)?| $is_bit_valid)?
         );
     };
     (
         @inner
         $(#[$attr:meta])*
         $(@const $constname:ident : $constty:ident,)*
         $($tyvar:ident $(: $(? $optbound:ident +)* + $($bound:ident +)* )?,)*
         => $trait:ident for $ty:ty $(; |$candidate:ident $(: &$ref_repr:ty)? $(: Ptr<$ptr_repr:ty>)?| $is_bit_valid:expr)?
     ) => {
         $(#[$attr])*
         unsafe impl<$(const $constname: $constty,)* $($tyvar $(: $(? $optbound +)* $($bound +)*)?),*> $trait for $ty {
             unsafe_impl!(@method $trait $(; |$candidate: $(&$ref_repr)? $(Ptr<$ptr_repr>)?| $is_bit_valid)?);
         }
     };

     (@method TryFromBytes ; |$candidate:ident: &$repr:ty| $is_bit_valid:expr) => {
         #[inline]
         unsafe fn is_bit_valid(candidate: Ptr<'_, Self>) -> bool {
             // SAFETY:
             // - The argument to `cast_unsized` is `|p| p as *mut _` as required
             //   by that method's safety precondition.
             // - The caller has promised that the cast results in an object of
             //   equal or lesser size.
             // - The caller has promised that `$repr`'s alignment is less than
             //   or equal to `Self`'s alignment.
             #[allow(clippy::as_conversions)]
             let candidate = unsafe { candidate.cast_unsized::<$repr, _>(|p| p as *mut _) };
             // SAFETY:
             // - The caller has promised that the referenced memory region will
             //   contain a valid `$repr` for `'a`.
             // - The memory may not be referenced by any mutable references.
             //   This is a precondition of `is_bit_valid`.
             // - The memory may not be mutated even via `UnsafeCell`s. This is a
             //   precondition of `is_bit_valid`.
             // - There must not exist any references to the same memory region
             //   which contain `UnsafeCell`s at byte ranges which are not
             //   identical to the byte ranges at which `T` contains
             //   `UnsafeCell`s. This is a precondition of `is_bit_valid`.
             let $candidate: &$repr = unsafe { candidate.as_ref() };
             $is_bit_valid
         }
     };
     (@method TryFromBytes ; |$candidate:ident: Ptr<$repr:ty>| $is_bit_valid:expr) => {
         #[inline]
         unsafe fn is_bit_valid(candidate: Ptr<'_, Self>) -> bool {
             // SAFETY:
             // - The argument to `cast_unsized` is `|p| p as *mut _` as required
             //   by that method's safety precondition.
             // - The caller has promised that the cast results in an object of
             //   equal or lesser size.
             // - The caller has promised that `$repr`'s alignment is less than
             //   or equal to `Self`'s alignment.
             #[allow(clippy::as_conversions)]
             let $candidate = unsafe { candidate.cast_unsized::<$repr, _>(|p| p as *mut _) };
             $is_bit_valid
         }
     };
     (@method TryFromBytes) => { #[inline(always)] unsafe fn is_bit_valid(_: Ptr<'_, Self>) -> bool { true } };
     (@method $trait:ident) => {
         #[allow(clippy::missing_inline_in_public_items)]
         fn only_derive_is_allowed_to_implement_this_trait() {}
     };
     (@method $trait:ident; |$_candidate:ident $(: &$_ref_repr:ty)? $(: NonNull<$_ptr_repr:ty>)?| $_is_bit_valid:expr) => {
         compile_error!("Can't provide `is_bit_valid` impl for trait other than `TryFromBytes`");
     };
 }

 /// Implements a trait for a type, bounding on each memeber of the power set of
 /// a set of type variables. This is useful for implementing traits for tuples
 /// or `fn` types.
 ///
 /// The last argument is the name of a macro which will be called in every
 /// `impl` block, and is expected to expand to the name of the type for which to
 /// implement the trait.
 ///
 /// For example, the invocation:
 /// ```ignore
 /// unsafe_impl_for_power_set!(A, B => Foo for type!(...))
 /// ```
 /// ...expands to:
 /// ```ignore
 /// unsafe impl       Foo for type!()     { ... }
 /// unsafe impl<B>    Foo for type!(B)    { ... }
 /// unsafe impl<A, B> Foo for type!(A, B) { ... }
 /// ```
 macro_rules! unsafe_impl_for_power_set {
     ($first:ident $(, $rest:ident)* $(-> $ret:ident)? => $trait:ident for $macro:ident!(...)) => {
         unsafe_impl_for_power_set!($($rest),* $(-> $ret)? => $trait for $macro!(...));
         unsafe_impl_for_power_set!(@impl $first $(, $rest)* $(-> $ret)? => $trait for $macro!(...));
     };
     ($(-> $ret:ident)? => $trait:ident for $macro:ident!(...)) => {
         unsafe_impl_for_power_set!(@impl $(-> $ret)? => $trait for $macro!(...));
     };
     (@impl $($vars:ident),* $(-> $ret:ident)? => $trait:ident for $macro:ident!(...)) => {
         unsafe impl<$($vars,)* $($ret)?> $trait for $macro!($($vars),* $(-> $ret)?) {
             #[allow(clippy::missing_inline_in_public_items)]
             fn only_derive_is_allowed_to_implement_this_trait() {}
         }
     };
 }

 /// Expands to an `Option<extern "C" fn>` type with the given argument types and
 /// return type. Designed for use with `unsafe_impl_for_power_set`.
 macro_rules! opt_extern_c_fn {
     ($($args:ident),* -> $ret:ident) => { Option<extern "C" fn($($args),*) -> $ret> };
 }

 /// Expands to a `Option<fn>` type with the given argument types and return
 /// type. Designed for use with `unsafe_impl_for_power_set`.
 macro_rules! opt_fn {
     ($($args:ident),* -> $ret:ident) => { Option<fn($($args),*) -> $ret> };
 }

 /// Implements trait(s) for a type or verifies the given implementation by
 /// referencing an existing (derived) implementation.
 ///
 /// This macro exists so that we can provide zerocopy-derive as an optional
 /// dependency and still get the benefit of using its derives to validate that
 /// our trait impls are sound.
 ///
 /// When compiling without `--cfg 'feature = "derive"` and without `--cfg test`,
 /// `impl_or_verify!` emits the provided trait impl. When compiling with either
 /// of those cfgs, it is expected that the type in question is deriving the
 /// traits instead. In this case, `impl_or_verify!` emits code which validates
 /// that the given trait impl is at least as restrictive as the the impl emitted
 /// by the custom derive. This has the effect of confirming that the impl which
 /// is emitted when the `derive` feature is disabled is actually sound (on the
 /// assumption that the impl emitted by the custom derive is sound).
 ///
 /// The caller is still required to provide a safety comment (e.g. using the
 /// `safety_comment!` macro) . The reason for this restriction is that, while
 /// `impl_or_verify!` can guarantee that the provided impl is sound when it is
 /// compiled with the appropriate cfgs, there is no way to guarantee that it is
 /// ever compiled with those cfgs. In particular, it would be possible to
 /// accidentally place an `impl_or_verify!` call in a context that is only ever
 /// compiled when the `derive` feature is disabled. If that were to happen,
 /// there would be nothing to prevent an unsound trait impl from being emitted.
 /// Requiring a safety comment reduces the likelihood of emitting an unsound
 /// impl in this case, and also provides useful documentation for readers of the
 /// code.
 ///
 /// ## Example
 ///
 /// ```rust,ignore
 /// // Note that these derives are gated by `feature = "derive"`
 /// #[cfg_attr(any(feature = "derive", test), derive(FromZeroes, FromBytes, AsBytes, Unaligned))]
 /// #[repr(transparent)]
 /// struct Wrapper<T>(T);
 ///
 /// safety_comment! {
 ///     /// SAFETY:
 ///     /// `Wrapper<T>` is `repr(transparent)`, so it is sound to implement any
 ///     /// zerocopy trait if `T` implements that trait.
 ///     impl_or_verify!(T: FromZeroes => FromZeroes for Wrapper<T>);
 ///     impl_or_verify!(T: FromBytes => FromBytes for Wrapper<T>);
 ///     impl_or_verify!(T: AsBytes => AsBytes for Wrapper<T>);
 ///     impl_or_verify!(T: Unaligned => Unaligned for Wrapper<T>);
 /// }
 /// ```
 macro_rules! impl_or_verify {
     // The following two match arms follow the same pattern as their
     // counterparts in `unsafe_impl!`; see the documentation on those arms for
     // more details.
     (
         const $constname:ident : $constty:ident $(,)?
         $($tyvar:ident $(: $(? $optbound:ident $(+)?)* $($bound:ident $(+)?)* )?),*
         => $trait:ident for $ty:ty
     ) => {
         impl_or_verify!(@impl { unsafe_impl!(
             const $constname: $constty, $($tyvar $(: $(? $optbound +)* $($bound +)*)?),* => $trait for $ty
         ); });
         impl_or_verify!(@verify $trait, {
             impl<const $constname: $constty, $($tyvar $(: $(? $optbound +)* $($bound +)*)?),*> Subtrait for $ty {}
         });
     };
     (
         $($tyvar:ident $(: $(? $optbound:ident $(+)?)* $($bound:ident $(+)?)* )?),*
         => $trait:ident for $ty:ty
     ) => {
         impl_or_verify!(@impl { unsafe_impl!(
             $($tyvar $(: $(? $optbound +)* $($bound +)*)?),* => $trait for $ty
         ); });
         impl_or_verify!(@verify $trait, {
             impl<$($tyvar $(: $(? $optbound +)* $($bound +)*)?),*> Subtrait for $ty {}
         });
     };
     (
         $($tyvar:ident $(: $(? $optbound:ident $(+)?)* $($bound:ident $(+)?)* )?),*
         => $trait:ident for $ty:ty
     ) => {
         unsafe_impl!(
             @inner
             $($tyvar $(: $(? $optbound +)* + $($bound +)*)?,)*
             => $trait for $ty
         );
     };
     (@impl $impl_block:tt) => {
         #[cfg(not(any(feature = "derive", test)))]
         const _: () = { $impl_block };
     };
     (@verify $trait:ident, $impl_block:tt) => {
         #[cfg(any(feature = "derive", test))]
         const _: () = {
             trait Subtrait: $trait {}
             $impl_block
         };
     };
 }

 /// Implements `KnownLayout` for a sized type.
 macro_rules! impl_known_layout {
     ($(const $constvar:ident : $constty:ty, $tyvar:ident $(: ?$optbound:ident)? => $ty:ty),* $(,)?) => {
         $(impl_known_layout!(@inner const $constvar: $constty, $tyvar $(: ?$optbound)? => $ty);)*
     };
     ($($tyvar:ident $(: ?$optbound:ident)? => $ty:ty),* $(,)?) => {
         $(impl_known_layout!(@inner , $tyvar $(: ?$optbound)? => $ty);)*
     };
     ($($ty:ty),*) => { $(impl_known_layout!(@inner , => $ty);)* };
     (@inner $(const $constvar:ident : $constty:ty)? , $($tyvar:ident $(: ?$optbound:ident)?)? => $ty:ty) => {
         const _: () = {
             use core::ptr::NonNull;

             // SAFETY: Delegates safety to `DstLayout::for_type`.
             unsafe impl<$(const $constvar : $constty,)? $($tyvar $(: ?$optbound)?)?> KnownLayout for $ty {
                 #[allow(clippy::missing_inline_in_public_items)]
                 fn only_derive_is_allowed_to_implement_this_trait() where Self: Sized {}

                 const LAYOUT: DstLayout = DstLayout::for_type::<$ty>();

                 // SAFETY: `.cast` preserves address and provenance.
                 //
                 // TODO(#429): Add documentation to `.cast` that promises that
                 // it preserves provenance.
                 #[inline(always)]
                 fn raw_from_ptr_len(bytes: NonNull<u8>, _elems: usize) -> NonNull<Self> {
                     bytes.cast::<Self>()
                 }
             }
         };
     };
 }

 /// Implements `KnownLayout` for a type in terms of the implementation of
 /// another type with the same representation.
 ///
 /// # Safety
 ///
 /// - `$ty` and `$repr` must have the same:
 ///   - Fixed prefix size
 ///   - Alignment
 ///   - (For DSTs) trailing slice element size
 /// - It must be valid to perform an `as` cast from `*mut $repr` to `*mut $ty`,
 ///   and this operation must preserve referent size (ie, `size_of_val_raw`).
 macro_rules! unsafe_impl_known_layout {
     ($($tyvar:ident: ?Sized + KnownLayout =>)? #[repr($repr:ty)] $ty:ty) => {
         const _: () = {
             use core::ptr::NonNull;

             unsafe impl<$($tyvar: ?Sized + KnownLayout)?> KnownLayout for $ty {
                 #[allow(clippy::missing_inline_in_public_items)]
                 fn only_derive_is_allowed_to_implement_this_trait() {}

                 const LAYOUT: DstLayout = <$repr as KnownLayout>::LAYOUT;

                 // SAFETY: All operations preserve address and provenance.
                 // Caller has promised that the `as` cast preserves size.
                 //
                 // TODO(#429): Add documentation to `NonNull::new_unchecked`
                 // that it preserves provenance.
                 #[inline(always)]
                 #[allow(unused_qualifications)] // for `core::ptr::NonNull`
                 fn raw_from_ptr_len(bytes: NonNull<u8>, elems: usize) -> NonNull<Self> {
                     #[allow(clippy::as_conversions)]
                     let ptr = <$repr>::raw_from_ptr_len(bytes, elems).as_ptr() as *mut Self;
                     // SAFETY: `ptr` was converted from `bytes`, which is non-null.
                     unsafe { NonNull::new_unchecked(ptr) }
                 }
             }
         };
     };
 }

 /// Uses `align_of` to confirm that a type or set of types have alignment 1.
 ///
 /// Note that `align_of<T>` requires `T: Sized`, so this macro doesn't work for
 /// unsized types.
 macro_rules! assert_unaligned {
     ($ty:ty) => {
         // We only compile this assertion under `cfg(test)` to avoid taking an
         // extra non-dev dependency (and making this crate more expensive to
         // compile for our dependents).
         #[cfg(test)]
         static_assertions::const_assert_eq!(core::mem::align_of::<$ty>(), 1);
     };
     ($($ty:ty),*) => {
         $(assert_unaligned!($ty);)*
     };
 }
	// Copyright 2023 The Fuchsia Authors
	//
	// Licensed under a BSD-style license <LICENSE-BSD>, Apache License, Version 2.0
	// <LICENSE-APACHE or https://www.apache.org/licenses/LICENSE-2.0>, or the MIT
	// license <LICENSE-MIT or https://opensource.org/licenses/MIT>, at your option.
	// This file may not be copied, modified, or distributed except according to
	// those terms.

	/// Documents multiple unsafe blocks with a single safety comment.
	///
	/// Invoked as:
	///
	/// ```rust,ignore
	/// safety_comment! {
	/// // Non-doc comments come first.
	/// /// SAFETY:
	/// /// Safety comment starts on its own line.
	/// macro_1!(args);
	/// macro_2! { args };
	/// /// SAFETY:
	/// /// Subsequent safety comments are allowed but not required.
	/// macro_3! { args };
	/// }
	/// ```
	///
	/// The macro invocations are emitted, each decorated with the following
	/// attribute: `#[allow(clippy::undocumented_unsafe_blocks)]`.
	macro_rules! safety_comment {
	(#[doc = r" SAFETY:"] $($(#[$attr:meta])* $macro:ident!$args:tt;)*) => {
	#[allow(clippy::undocumented_unsafe_blocks, unused_attributes)]
	const _: () = { $($(#[$attr])* $macro!$args;)* };
	}
	}

	/// Unsafely implements trait(s) for a type.
	///
	/// # Safety
	///
	/// The trait impl must be sound.
	///
	/// When implementing `TryFromBytes`:
	/// - If no `is_bit_valid` impl is provided, then it must be valid for
	/// `is_bit_valid` to unconditionally return `true`. In other words, it must
	/// be the case that any initialized sequence of bytes constitutes a valid
	/// instance of `$ty`.
	/// - If an `is_bit_valid` impl is provided, then:
	/// - Regardless of whether the provided closure takes a `Ptr<$repr>` or
	/// `&$repr` argument, it must be the case that, given `t: *mut $ty` and
	/// `let r = t as *mut $repr`, `r` refers to an object of equal or lesser
	/// size than the object referred to by `t`.
	/// - If the provided closure takes a `&$repr` argument, then given a `Ptr<'a,
	/// $ty>` which satisfies the preconditions of
	/// `TryFromBytes::<$ty>::is_bit_valid`, it must be guaranteed that the
	/// memory referenced by that `Ptr` always contains a valid `$repr`.
	/// - The alignment of `$repr` is less than or equal to the alignment of
	/// `$ty`.
	/// - The impl of `is_bit_valid` must only return `true` for its argument
	/// `Ptr<$repr>` if the original `Ptr<$ty>` refers to a valid `$ty`.
	macro_rules! unsafe_impl {
	// Implement `$trait` for `$ty` with no bounds.
	($(#[$attr:meta])* $ty:ty: $trait:ident $(; \|$candidate:ident: &$repr:ty\| $is_bit_valid:expr)?) => {
	$(#[$attr])*
	unsafe impl $trait for $ty {
	unsafe_impl!(@method $trait $(; \|$candidate: &$repr\| $is_bit_valid)?);
	}
	};
	// Implement all `$traits` for `$ty` with no bounds.
	($ty:ty: $($traits:ident),*) => {
	$( unsafe_impl!($ty: $traits); )*
	};
	// This arm is identical to the following one, except it contains a
	// preceding `const`. If we attempt to handle these with a single arm, there
	// is an inherent ambiguity between `const` (the keyword) and `const` (the
	// ident match for `$tyvar:ident`).
	//
	// To explain how this works, consider the following invocation:
	//
	// unsafe_impl!(const N: usize, T: ?Sized + Copy => Clone for Foo<T>);
	//
	// In this invocation, here are the assignments to meta-variables:
	//
	// \|---------------\|------------\|
	// \| Meta-variable \| Assignment \|
	// \|---------------\|------------\|
	// \| $constname \| N \|
	// \| $constty \| usize \|
	// \| $tyvar \| T \|
	// \| $optbound \| Sized \|
	// \| $bound \| Copy \|
	// \| $trait \| Clone \|
	// \| $ty \| Foo<T> \|
	// \|---------------\|------------\|
	//
	// The following arm has the same behavior with the exception of the lack of
	// support for a leading `const` parameter.
	(
	$(#[$attr:meta])*
	const $constname:ident : $constty:ident $(,)?
	$($tyvar:ident $(: $(? $optbound:ident $(+)?)* $($bound:ident $(+)?)* )?),*
	=> $trait:ident for $ty:ty $(; \|$candidate:ident $(: &$ref_repr:ty)? $(: Ptr<$ptr_repr:ty>)?\| $is_bit_valid:expr)?
	) => {
	unsafe_impl!(
	@inner
	$(#[$attr])*
	@const $constname: $constty,
	$($tyvar $(: $(? $optbound +)* + $($bound +))?,)
	=> $trait for $ty $(; \|$candidate $(: &$ref_repr)? $(: Ptr<$ptr_repr>)?\| $is_bit_valid)?
	);
	};
	(
	$(#[$attr:meta])*
	$($tyvar:ident $(: $(? $optbound:ident $(+)?)* $($bound:ident $(+)?)* )?),*
	=> $trait:ident for $ty:ty $(; \|$candidate:ident $(: &$ref_repr:ty)? $(: Ptr<$ptr_repr:ty>)?\| $is_bit_valid:expr)?
	) => {
	unsafe_impl!(
	@inner
	$(#[$attr])*
	$($tyvar $(: $(? $optbound +)* + $($bound +))?,)
	=> $trait for $ty $(; \|$candidate $(: &$ref_repr)? $(: Ptr<$ptr_repr>)?\| $is_bit_valid)?
	);
	};
	(
	@inner
	$(#[$attr:meta])*
	$(@const $constname:ident : $constty:ident,)*
	$($tyvar:ident $(: $(? $optbound:ident +)* + $($bound:ident +)* )?,)*
	=> $trait:ident for $ty:ty $(; \|$candidate:ident $(: &$ref_repr:ty)? $(: Ptr<$ptr_repr:ty>)?\| $is_bit_valid:expr)?
	) => {
	$(#[$attr])*
	unsafe impl<$(const $constname: $constty,)* $($tyvar $(: $(? $optbound +)* $($bound +))?),> $trait for $ty {
	unsafe_impl!(@method $trait $(; \|$candidate: $(&$ref_repr)? $(Ptr<$ptr_repr>)?\| $is_bit_valid)?);
	}
	};

	(@method TryFromBytes ; \|$candidate:ident: &$repr:ty\| $is_bit_valid:expr) => {
	#[inline]
	unsafe fn is_bit_valid(candidate: Ptr<'_, Self>) -> bool {
	// SAFETY:
	// - The argument to `cast_unsized` is `\|p\| p as *mut _` as required
	// by that method's safety precondition.
	// - The caller has promised that the cast results in an object of
	// equal or lesser size.
	// - The caller has promised that `$repr`'s alignment is less than
	// or equal to `Self`'s alignment.
	#[allow(clippy::as_conversions)]
	let candidate = unsafe { candidate.cast_unsized::<$repr, _>(\|p\| p as *mut _) };
	// SAFETY:
	// - The caller has promised that the referenced memory region will
	// contain a valid `$repr` for `'a`.
	// - The memory may not be referenced by any mutable references.
	// This is a precondition of `is_bit_valid`.
	// - The memory may not be mutated even via `UnsafeCell`s. This is a
	// precondition of `is_bit_valid`.
	// - There must not exist any references to the same memory region
	// which contain `UnsafeCell`s at byte ranges which are not
	// identical to the byte ranges at which `T` contains
	// `UnsafeCell`s. This is a precondition of `is_bit_valid`.
	let $candidate: &$repr = unsafe { candidate.as_ref() };
	$is_bit_valid
	}
	};
	(@method TryFromBytes ; \|$candidate:ident: Ptr<$repr:ty>\| $is_bit_valid:expr) => {
	#[inline]
	unsafe fn is_bit_valid(candidate: Ptr<'_, Self>) -> bool {
	// SAFETY:
	// - The argument to `cast_unsized` is `\|p\| p as *mut _` as required
	// by that method's safety precondition.
	// - The caller has promised that the cast results in an object of
	// equal or lesser size.
	// - The caller has promised that `$repr`'s alignment is less than
	// or equal to `Self`'s alignment.
	#[allow(clippy::as_conversions)]
	let $candidate = unsafe { candidate.cast_unsized::<$repr, _>(\|p\| p as *mut _) };
	$is_bit_valid
	}
	};
	(@method TryFromBytes) => { #[inline(always)] unsafe fn is_bit_valid(_: Ptr<'_, Self>) -> bool { true } };
	(@method $trait:ident) => {
	#[allow(clippy::missing_inline_in_public_items)]
	fn only_derive_is_allowed_to_implement_this_trait() {}
	};
	(@method $trait:ident; \|$_candidate:ident $(: &$_ref_repr:ty)? $(: NonNull<$_ptr_repr:ty>)?\| $_is_bit_valid:expr) => {
	compile_error!("Can't provide `is_bit_valid` impl for trait other than `TryFromBytes`");
	};
	}

	/// Implements a trait for a type, bounding on each memeber of the power set of
	/// a set of type variables. This is useful for implementing traits for tuples
	/// or `fn` types.
	///
	/// The last argument is the name of a macro which will be called in every
	/// `impl` block, and is expected to expand to the name of the type for which to
	/// implement the trait.
	///
	/// For example, the invocation:
	/// ```ignore
	/// unsafe_impl_for_power_set!(A, B => Foo for type!(...))
	/// ```
	/// ...expands to:
	/// ```ignore
	/// unsafe impl Foo for type!() { ... }
	/// unsafe impl<B> Foo for type!(B) { ... }
	/// unsafe impl<A, B> Foo for type!(A, B) { ... }
	/// ```
	macro_rules! unsafe_impl_for_power_set {
	($first:ident $(, $rest:ident)* $(-> $ret:ident)? => $trait:ident for $macro:ident!(...)) => {
	unsafe_impl_for_power_set!($($rest),* $(-> $ret)? => $trait for $macro!(...));
	unsafe_impl_for_power_set!(@impl $first $(, $rest)* $(-> $ret)? => $trait for $macro!(...));
	};
	($(-> $ret:ident)? => $trait:ident for $macro:ident!(...)) => {
	unsafe_impl_for_power_set!(@impl $(-> $ret)? => $trait for $macro!(...));
	};
	(@impl $($vars:ident),* $(-> $ret:ident)? => $trait:ident for $macro:ident!(...)) => {
	unsafe impl<$($vars,)* $($ret)?> $trait for $macro!($($vars),* $(-> $ret)?) {
	#[allow(clippy::missing_inline_in_public_items)]
	fn only_derive_is_allowed_to_implement_this_trait() {}
	}
	};
	}

	/// Expands to an `Option<extern "C" fn>` type with the given argument types and
	/// return type. Designed for use with `unsafe_impl_for_power_set`.
	macro_rules! opt_extern_c_fn {
	($($args:ident),* -> $ret:ident) => { Option<extern "C" fn($($args),*) -> $ret> };
	}

	/// Expands to a `Option<fn>` type with the given argument types and return
	/// type. Designed for use with `unsafe_impl_for_power_set`.
	macro_rules! opt_fn {
	($($args:ident),* -> $ret:ident) => { Option<fn($($args),*) -> $ret> };
	}

	/// Implements trait(s) for a type or verifies the given implementation by
	/// referencing an existing (derived) implementation.
	///
	/// This macro exists so that we can provide zerocopy-derive as an optional
	/// dependency and still get the benefit of using its derives to validate that
	/// our trait impls are sound.
	///
	/// When compiling without `--cfg 'feature = "derive"` and without `--cfg test`,
	/// `impl_or_verify!` emits the provided trait impl. When compiling with either
	/// of those cfgs, it is expected that the type in question is deriving the
	/// traits instead. In this case, `impl_or_verify!` emits code which validates
	/// that the given trait impl is at least as restrictive as the the impl emitted
	/// by the custom derive. This has the effect of confirming that the impl which
	/// is emitted when the `derive` feature is disabled is actually sound (on the
	/// assumption that the impl emitted by the custom derive is sound).
	///
	/// The caller is still required to provide a safety comment (e.g. using the
	/// `safety_comment!` macro) . The reason for this restriction is that, while
	/// `impl_or_verify!` can guarantee that the provided impl is sound when it is
	/// compiled with the appropriate cfgs, there is no way to guarantee that it is
	/// ever compiled with those cfgs. In particular, it would be possible to
	/// accidentally place an `impl_or_verify!` call in a context that is only ever
	/// compiled when the `derive` feature is disabled. If that were to happen,
	/// there would be nothing to prevent an unsound trait impl from being emitted.
	/// Requiring a safety comment reduces the likelihood of emitting an unsound
	/// impl in this case, and also provides useful documentation for readers of the
	/// code.
	///
	/// ## Example
	///
	/// ```rust,ignore
	/// // Note that these derives are gated by `feature = "derive"`
	/// #[cfg_attr(any(feature = "derive", test), derive(FromZeroes, FromBytes, AsBytes, Unaligned))]
	/// #[repr(transparent)]
	/// struct Wrapper<T>(T);
	///
	/// safety_comment! {
	/// /// SAFETY:
	/// /// `Wrapper<T>` is `repr(transparent)`, so it is sound to implement any
	/// /// zerocopy trait if `T` implements that trait.
	/// impl_or_verify!(T: FromZeroes => FromZeroes for Wrapper<T>);
	/// impl_or_verify!(T: FromBytes => FromBytes for Wrapper<T>);
	/// impl_or_verify!(T: AsBytes => AsBytes for Wrapper<T>);
	/// impl_or_verify!(T: Unaligned => Unaligned for Wrapper<T>);
	/// }
	/// ```
	macro_rules! impl_or_verify {
	// The following two match arms follow the same pattern as their
	// counterparts in `unsafe_impl!`; see the documentation on those arms for
	// more details.
	(
	const $constname:ident : $constty:ident $(,)?
	$($tyvar:ident $(: $(? $optbound:ident $(+)?)* $($bound:ident $(+)?)* )?),*
	=> $trait:ident for $ty:ty
	) => {
	impl_or_verify!(@impl { unsafe_impl!(
	const $constname: $constty, $($tyvar $(: $(? $optbound +)* $($bound +))?), => $trait for $ty
	); });
	impl_or_verify!(@verify $trait, {
	impl<const $constname: $constty, $($tyvar $(: $(? $optbound +)* $($bound +))?),> Subtrait for $ty {}
	});
	};
	(
	$($tyvar:ident $(: $(? $optbound:ident $(+)?)* $($bound:ident $(+)?)* )?),*
	=> $trait:ident for $ty:ty
	) => {
	impl_or_verify!(@impl { unsafe_impl!(
	$($tyvar $(: $(? $optbound +)* $($bound +))?), => $trait for $ty
	); });
	impl_or_verify!(@verify $trait, {
	impl<$($tyvar $(: $(? $optbound +)* $($bound +))?),> Subtrait for $ty {}
	});
	};
	(
	$($tyvar:ident $(: $(? $optbound:ident $(+)?)* $($bound:ident $(+)?)* )?),*
	=> $trait:ident for $ty:ty
	) => {
	unsafe_impl!(
	@inner
	$($tyvar $(: $(? $optbound +)* + $($bound +))?,)
	=> $trait for $ty
	);
	};
	(@impl $impl_block:tt) => {
	#[cfg(not(any(feature = "derive", test)))]
	const _: () = { $impl_block };
	};
	(@verify $trait:ident, $impl_block:tt) => {
	#[cfg(any(feature = "derive", test))]
	const _: () = {
	trait Subtrait: $trait {}
	$impl_block
	};
	};
	}

	/// Implements `KnownLayout` for a sized type.
	macro_rules! impl_known_layout {
	($(const $constvar:ident : $constty:ty, $tyvar:ident $(: ?$optbound:ident)? => $ty:ty),* $(,)?) => {
	$(impl_known_layout!(@inner const $constvar: $constty, $tyvar $(: ?$optbound)? => $ty);)*
	};
	($($tyvar:ident $(: ?$optbound:ident)? => $ty:ty),* $(,)?) => {
	$(impl_known_layout!(@inner , $tyvar $(: ?$optbound)? => $ty);)*
	};
	($($ty:ty),) => { $(impl_known_layout!(@inner , => $ty);) };
	(@inner $(const $constvar:ident : $constty:ty)? , $($tyvar:ident $(: ?$optbound:ident)?)? => $ty:ty) => {
	const _: () = {
	use core::ptr::NonNull;

	// SAFETY: Delegates safety to `DstLayout::for_type`.
	unsafe impl<$(const $constvar : $constty,)? $($tyvar $(: ?$optbound)?)?> KnownLayout for $ty {
	#[allow(clippy::missing_inline_in_public_items)]
	fn only_derive_is_allowed_to_implement_this_trait() where Self: Sized {}

	const LAYOUT: DstLayout = DstLayout::for_type::<$ty>();

	// SAFETY: `.cast` preserves address and provenance.
	//
	// TODO(#429): Add documentation to `.cast` that promises that
	// it preserves provenance.
	#[inline(always)]
	fn raw_from_ptr_len(bytes: NonNull<u8>, _elems: usize) -> NonNull<Self> {
	bytes.cast::<Self>()
	}
	}
	};
	};
	}

	/// Implements `KnownLayout` for a type in terms of the implementation of
	/// another type with the same representation.
	///
	/// # Safety
	///
	/// - `$ty` and `$repr` must have the same:
	/// - Fixed prefix size
	/// - Alignment
	/// - (For DSTs) trailing slice element size
	/// - It must be valid to perform an `as` cast from `mut $repr` to `mut $ty`,
	/// and this operation must preserve referent size (ie, `size_of_val_raw`).
	macro_rules! unsafe_impl_known_layout {
	($($tyvar:ident: ?Sized + KnownLayout =>)? #[repr($repr:ty)] $ty:ty) => {
	const _: () = {
	use core::ptr::NonNull;

	unsafe impl<$($tyvar: ?Sized + KnownLayout)?> KnownLayout for $ty {
	#[allow(clippy::missing_inline_in_public_items)]
	fn only_derive_is_allowed_to_implement_this_trait() {}

	const LAYOUT: DstLayout = <$repr as KnownLayout>::LAYOUT;

	// SAFETY: All operations preserve address and provenance.
	// Caller has promised that the `as` cast preserves size.
	//
	// TODO(#429): Add documentation to `NonNull::new_unchecked`
	// that it preserves provenance.
	#[inline(always)]
	#[allow(unused_qualifications)] // for `core::ptr::NonNull`
	fn raw_from_ptr_len(bytes: NonNull<u8>, elems: usize) -> NonNull<Self> {
	#[allow(clippy::as_conversions)]
	let ptr = <$repr>::raw_from_ptr_len(bytes, elems).as_ptr() as *mut Self;
	// SAFETY: `ptr` was converted from `bytes`, which is non-null.
	unsafe { NonNull::new_unchecked(ptr) }
	}
	}
	};
	};
	}

	/// Uses `align_of` to confirm that a type or set of types have alignment 1.
	///
	/// Note that `align_of<T>` requires `T: Sized`, so this macro doesn't work for
	/// unsized types.
	macro_rules! assert_unaligned {
	($ty:ty) => {
	// We only compile this assertion under `cfg(test)` to avoid taking an
	// extra non-dev dependency (and making this crate more expensive to
	// compile for our dependents).
	#[cfg(test)]
	static_assertions::const_assert_eq!(core::mem::align_of::<$ty>(), 1);
	};
	($($ty:ty),*) => {
	$(assert_unaligned!($ty);)*
	};
	}