rust/kernel/sync/atomic/internal.rs - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0

 //! Atomic internal implementations.
 //!
 //! Provides 1:1 mapping to the C atomic operations.

 use crate::bindings;
 use crate::macros::paste;
 use core::cell::UnsafeCell;

 mod private {
     /// Sealed trait marker to disable customized impls on atomic implementation traits.
     pub trait Sealed {}
 }

 // `i32` and `i64` are only supported atomic implementations.
 impl private::Sealed for i32 {}
 impl private::Sealed for i64 {}

 /// A marker trait for types that implement atomic operations with C side primitives.
 ///
 /// This trait is sealed, and only types that have directly mapping to the C side atomics should
 /// impl this:
 ///
 /// - `i32` maps to `atomic_t`.
 /// - `i64` maps to `atomic64_t`.
 pub trait AtomicImpl: Sized + Send + Copy + private::Sealed {
     /// The type of the delta in arithmetic or logical operations.
     ///
     /// For example, in `atomic_add(ptr, v)`, it's the type of `v`. Usually it's the same type of
     /// [`Self`], but it may be different for the atomic pointer type.
     type Delta;
 }

 // `atomic_t` implements atomic operations on `i32`.
 impl AtomicImpl for i32 {
     type Delta = Self;
 }

 // `atomic64_t` implements atomic operations on `i64`.
 impl AtomicImpl for i64 {
     type Delta = Self;
 }

 /// Atomic representation.
 #[repr(transparent)]
 pub struct AtomicRepr<T: AtomicImpl>(UnsafeCell<T>);

 impl<T: AtomicImpl> AtomicRepr<T> {
     /// Creates a new atomic representation `T`.
     pub const fn new(v: T) -> Self {
         Self(UnsafeCell::new(v))
     }

     /// Returns a pointer to the underlying `T`.
     ///
     /// # Guarantees
     ///
     /// The returned pointer is valid and properly aligned (i.e. aligned to [`align_of::<T>()`]).
     pub const fn as_ptr(&self) -> *mut T {
         // GUARANTEE: `self.0` is an `UnsafeCell<T>`, therefore the pointer returned by `.get()`
         // must be valid and properly aligned.
         self.0.get()
     }
 }

 // This macro generates the function signature with given argument list and return type.
 macro_rules! declare_atomic_method {
     (
         $(#[doc=$doc:expr])*
         $func:ident($($arg:ident : $arg_type:ty),*) $(-> $ret:ty)?
     ) => {
         paste!(
             $(#[doc = $doc])*
             fn [< atomic_ $func >]($($arg: $arg_type,)*) $(-> $ret)?;
         );
     };
     (
         $(#[doc=$doc:expr])*
         $func:ident [$variant:ident $($rest:ident)*]($($arg_sig:tt)*) $(-> $ret:ty)?
     ) => {
         paste!(
             declare_atomic_method!(
                 $(#[doc = $doc])*
                 [< $func _ $variant >]($($arg_sig)*) $(-> $ret)?
             );
         );

         declare_atomic_method!(
             $(#[doc = $doc])*
             $func [$($rest)*]($($arg_sig)*) $(-> $ret)?
         );
     };
     (
         $(#[doc=$doc:expr])*
         $func:ident []($($arg_sig:tt)*) $(-> $ret:ty)?
     ) => {
         declare_atomic_method!(
             $(#[doc = $doc])*
             $func($($arg_sig)*) $(-> $ret)?
         );
     }
 }

 // This macro generates the function implementation with given argument list and return type, and it
 // will replace "call(...)" expression with "$ctype _ $func" to call the real C function.
 macro_rules! impl_atomic_method {
     (
         ($ctype:ident) $func:ident($($arg:ident: $arg_type:ty),*) $(-> $ret:ty)? {
             $unsafe:tt { call($($c_arg:expr),*) }
         }
     ) => {
         paste!(
             #[inline(always)]
             fn [< atomic_ $func >]($($arg: $arg_type,)*) $(-> $ret)? {
                 // TODO: Ideally we want to use the SAFETY comments written at the macro invocation
                 // (e.g. in `declare_and_impl_atomic_methods!()`, however, since SAFETY comments
                 // are just comments, and they are not passed to macros as tokens, therefore we
                 // cannot use them here. One potential improvement is that if we support using
                 // attributes as an alternative for SAFETY comments, then we can use that for macro
                 // generating code.
                 //
                 // SAFETY: specified on macro invocation.
                 $unsafe { bindings::[< $ctype _ $func >]($($c_arg,)*) }
             }
         );
     };
     (
         ($ctype:ident) $func:ident[$variant:ident $($rest:ident)*]($($arg_sig:tt)*) $(-> $ret:ty)? {
             $unsafe:tt { call($($arg:tt)*) }
         }
     ) => {
         paste!(
             impl_atomic_method!(
                 ($ctype) [< $func _ $variant >]($($arg_sig)*) $( -> $ret)? {
                     $unsafe { call($($arg)*) }
             }
             );
         );
         impl_atomic_method!(
             ($ctype) $func [$($rest)*]($($arg_sig)*) $( -> $ret)? {
                 $unsafe { call($($arg)*) }
             }
         );
     };
     (
         ($ctype:ident) $func:ident[]($($arg_sig:tt)*) $( -> $ret:ty)? {
             $unsafe:tt { call($($arg:tt)*) }
         }
     ) => {
         impl_atomic_method!(
             ($ctype) $func($($arg_sig)*) $(-> $ret)? {
                 $unsafe { call($($arg)*) }
             }
         );
     }
 }

 // Delcares $ops trait with methods and implements the trait for `i32` and `i64`.
 macro_rules! declare_and_impl_atomic_methods {
     ($(#[$attr:meta])* $pub:vis trait $ops:ident {
         $(
             $(#[doc=$doc:expr])*
             fn $func:ident [$($variant:ident),*]($($arg_sig:tt)*) $( -> $ret:ty)? {
                 $unsafe:tt { bindings::#call($($arg:tt)*) }
             }
         )*
     }) => {
         $(#[$attr])*
         $pub trait $ops: AtomicImpl {
             $(
                 declare_atomic_method!(
                     $(#[doc=$doc])*
                     $func[$($variant)*]($($arg_sig)*) $(-> $ret)?
                 );
             )*
         }

         impl $ops for i32 {
             $(
                 impl_atomic_method!(
                     (atomic) $func[$($variant)*]($($arg_sig)*) $(-> $ret)? {
                         $unsafe { call($($arg)*) }
                     }
                 );
             )*
         }

         impl $ops for i64 {
             $(
                 impl_atomic_method!(
                     (atomic64) $func[$($variant)*]($($arg_sig)*) $(-> $ret)? {
                         $unsafe { call($($arg)*) }
                     }
                 );
             )*
         }
     }
 }

 declare_and_impl_atomic_methods!(
     /// Basic atomic operations
     pub trait AtomicBasicOps {
         /// Atomic read (load).
         fn read[acquire](a: &AtomicRepr<Self>) -> Self {
             // SAFETY: `a.as_ptr()` is valid and properly aligned.
             unsafe { bindings::#call(a.as_ptr().cast()) }
         }

         /// Atomic set (store).
         fn set[release](a: &AtomicRepr<Self>, v: Self) {
             // SAFETY: `a.as_ptr()` is valid and properly aligned.
             unsafe { bindings::#call(a.as_ptr().cast(), v) }
         }
     }
 );

 declare_and_impl_atomic_methods!(
     /// Exchange and compare-and-exchange atomic operations
     pub trait AtomicExchangeOps {
         /// Atomic exchange.
         ///
         /// Atomically updates `*a` to `v` and returns the old value.
         fn xchg[acquire, release, relaxed](a: &AtomicRepr<Self>, v: Self) -> Self {
             // SAFETY: `a.as_ptr()` is valid and properly aligned.
             unsafe { bindings::#call(a.as_ptr().cast(), v) }
         }

         /// Atomic compare and exchange.
         ///
         /// If `*a` == `*old`, atomically updates `*a` to `new`. Otherwise, `*a` is not
         /// modified, `*old` is updated to the current value of `*a`.
         ///
         /// Return `true` if the update of `*a` occurred, `false` otherwise.
         fn try_cmpxchg[acquire, release, relaxed](
             a: &AtomicRepr<Self>, old: &mut Self, new: Self
         ) -> bool {
             // SAFETY: `a.as_ptr()` is valid and properly aligned. `core::ptr::from_mut(old)`
             // is valid and properly aligned.
             unsafe { bindings::#call(a.as_ptr().cast(), core::ptr::from_mut(old), new) }
         }
     }
 );

 declare_and_impl_atomic_methods!(
     /// Atomic arithmetic operations
     pub trait AtomicArithmeticOps {
         /// Atomic add (wrapping).
         ///
         /// Atomically updates `*a` to `(*a).wrapping_add(v)`.
         fn add[](a: &AtomicRepr<Self>, v: Self::Delta) {
             // SAFETY: `a.as_ptr()` is valid and properly aligned.
             unsafe { bindings::#call(v, a.as_ptr().cast()) }
         }

         /// Atomic fetch and add (wrapping).
         ///
         /// Atomically updates `*a` to `(*a).wrapping_add(v)`, and returns the value of `*a`
         /// before the update.
         fn fetch_add[acquire, release, relaxed](a: &AtomicRepr<Self>, v: Self::Delta) -> Self {
             // SAFETY: `a.as_ptr()` is valid and properly aligned.
             unsafe { bindings::#call(v, a.as_ptr().cast()) }
         }
     }
 );
	// SPDX-License-Identifier: GPL-2.0

	//! Atomic internal implementations.
	//!
	//! Provides 1:1 mapping to the C atomic operations.

	use crate::bindings;
	use crate::macros::paste;
	use core::cell::UnsafeCell;

	mod private {
	/// Sealed trait marker to disable customized impls on atomic implementation traits.
	pub trait Sealed {}
	}

	// `i32` and `i64` are only supported atomic implementations.
	impl private::Sealed for i32 {}
	impl private::Sealed for i64 {}

	/// A marker trait for types that implement atomic operations with C side primitives.
	///
	/// This trait is sealed, and only types that have directly mapping to the C side atomics should
	/// impl this:
	///
	/// - `i32` maps to `atomic_t`.
	/// - `i64` maps to `atomic64_t`.
	pub trait AtomicImpl: Sized + Send + Copy + private::Sealed {
	/// The type of the delta in arithmetic or logical operations.
	///
	/// For example, in `atomic_add(ptr, v)`, it's the type of `v`. Usually it's the same type of
	/// [`Self`], but it may be different for the atomic pointer type.
	type Delta;
	}

	// `atomic_t` implements atomic operations on `i32`.
	impl AtomicImpl for i32 {
	type Delta = Self;
	}

	// `atomic64_t` implements atomic operations on `i64`.
	impl AtomicImpl for i64 {
	type Delta = Self;
	}

	/// Atomic representation.
	#[repr(transparent)]
	pub struct AtomicRepr<T: AtomicImpl>(UnsafeCell<T>);

	impl<T: AtomicImpl> AtomicRepr<T> {
	/// Creates a new atomic representation `T`.
	pub const fn new(v: T) -> Self {
	Self(UnsafeCell::new(v))
	}

	/// Returns a pointer to the underlying `T`.
	///
	/// # Guarantees
	///
	/// The returned pointer is valid and properly aligned (i.e. aligned to [`align_of::<T>()`]).
	pub const fn as_ptr(&self) -> *mut T {
	// GUARANTEE: `self.0` is an `UnsafeCell<T>`, therefore the pointer returned by `.get()`
	// must be valid and properly aligned.
	self.0.get()
	}
	}

	// This macro generates the function signature with given argument list and return type.
	macro_rules! declare_atomic_method {
	(
	$(#[doc=$doc:expr])*
	$func:ident($($arg:ident : $arg_type:ty),*) $(-> $ret:ty)?
	) => {
	paste!(
	$(#[doc = $doc])*
	fn [< atomic_ $func >]($($arg: $arg_type,)*) $(-> $ret)?;
	);
	};
	(
	$(#[doc=$doc:expr])*
	$func:ident [$variant:ident $($rest:ident)]($($arg_sig:tt)) $(-> $ret:ty)?
	) => {
	paste!(
	declare_atomic_method!(
	$(#[doc = $doc])*
	[< $func _ $variant >]($($arg_sig)*) $(-> $ret)?
	);
	);

	declare_atomic_method!(
	$(#[doc = $doc])*
	$func [$($rest)]($($arg_sig)) $(-> $ret)?
	);
	};
	(
	$(#[doc=$doc:expr])*
	$func:ident []($($arg_sig:tt)*) $(-> $ret:ty)?
	) => {
	declare_atomic_method!(
	$(#[doc = $doc])*
	$func($($arg_sig)*) $(-> $ret)?
	);
	}
	}

	// This macro generates the function implementation with given argument list and return type, and it
	// will replace "call(...)" expression with "$ctype _ $func" to call the real C function.
	macro_rules! impl_atomic_method {
	(
	($ctype:ident) $func:ident($($arg:ident: $arg_type:ty),*) $(-> $ret:ty)? {
	$unsafe:tt { call($($c_arg:expr),*) }
	}
	) => {
	paste!(
	#[inline(always)]
	fn [< atomic_ $func >]($($arg: $arg_type,)*) $(-> $ret)? {
	// TODO: Ideally we want to use the SAFETY comments written at the macro invocation
	// (e.g. in `declare_and_impl_atomic_methods!()`, however, since SAFETY comments
	// are just comments, and they are not passed to macros as tokens, therefore we
	// cannot use them here. One potential improvement is that if we support using
	// attributes as an alternative for SAFETY comments, then we can use that for macro
	// generating code.
	//
	// SAFETY: specified on macro invocation.
	$unsafe { bindings::[< $ctype _ $func >]($($c_arg,)*) }
	}
	);
	};
	(
	($ctype:ident) $func:ident[$variant:ident $($rest:ident)]($($arg_sig:tt)) $(-> $ret:ty)? {
	$unsafe:tt { call($($arg:tt)*) }
	}
	) => {
	paste!(
	impl_atomic_method!(
	($ctype) [< $func _ $variant >]($($arg_sig)*) $( -> $ret)? {
	$unsafe { call($($arg)*) }
	}
	);
	);
	impl_atomic_method!(
	($ctype) $func [$($rest)]($($arg_sig)) $( -> $ret)? {
	$unsafe { call($($arg)*) }
	}
	);
	};
	(
	($ctype:ident) $func:ident[]($($arg_sig:tt)*) $( -> $ret:ty)? {
	$unsafe:tt { call($($arg:tt)*) }
	}
	) => {
	impl_atomic_method!(
	($ctype) $func($($arg_sig)*) $(-> $ret)? {
	$unsafe { call($($arg)*) }
	}
	);
	}
	}

	// Delcares $ops trait with methods and implements the trait for `i32` and `i64`.
	macro_rules! declare_and_impl_atomic_methods {
	($(#[$attr:meta])* $pub:vis trait $ops:ident {
	$(
	$(#[doc=$doc:expr])*
	fn $func:ident [$($variant:ident),]($($arg_sig:tt)) $( -> $ret:ty)? {
	$unsafe:tt { bindings::#call($($arg:tt)*) }
	}
	)*
	}) => {
	$(#[$attr])*
	$pub trait $ops: AtomicImpl {
	$(
	declare_atomic_method!(
	$(#[doc=$doc])*
	$func[$($variant)]($($arg_sig)) $(-> $ret)?
	);
	)*
	}

	impl $ops for i32 {
	$(
	impl_atomic_method!(
	(atomic) $func[$($variant)]($($arg_sig)) $(-> $ret)? {
	$unsafe { call($($arg)*) }
	}
	);
	)*
	}

	impl $ops for i64 {
	$(
	impl_atomic_method!(
	(atomic64) $func[$($variant)]($($arg_sig)) $(-> $ret)? {
	$unsafe { call($($arg)*) }
	}
	);
	)*
	}
	}
	}

	declare_and_impl_atomic_methods!(
	/// Basic atomic operations
	pub trait AtomicBasicOps {
	/// Atomic read (load).
	fn read[acquire](a: &AtomicRepr<Self>) -> Self {
	// SAFETY: `a.as_ptr()` is valid and properly aligned.
	unsafe { bindings::#call(a.as_ptr().cast()) }
	}

	/// Atomic set (store).
	fn set[release](a: &AtomicRepr<Self>, v: Self) {
	// SAFETY: `a.as_ptr()` is valid and properly aligned.
	unsafe { bindings::#call(a.as_ptr().cast(), v) }
	}
	}
	);

	declare_and_impl_atomic_methods!(
	/// Exchange and compare-and-exchange atomic operations
	pub trait AtomicExchangeOps {
	/// Atomic exchange.
	///
	/// Atomically updates `*a` to `v` and returns the old value.
	fn xchg[acquire, release, relaxed](a: &AtomicRepr<Self>, v: Self) -> Self {
	// SAFETY: `a.as_ptr()` is valid and properly aligned.
	unsafe { bindings::#call(a.as_ptr().cast(), v) }
	}

	/// Atomic compare and exchange.
	///
	/// If `a` == `old`, atomically updates `a` to `new`. Otherwise, `a` is not
	/// modified, `old` is updated to the current value of `a`.
	///
	/// Return `true` if the update of `*a` occurred, `false` otherwise.
	fn try_cmpxchg[acquire, release, relaxed](
	a: &AtomicRepr<Self>, old: &mut Self, new: Self
	) -> bool {
	// SAFETY: `a.as_ptr()` is valid and properly aligned. `core::ptr::from_mut(old)`
	// is valid and properly aligned.
	unsafe { bindings::#call(a.as_ptr().cast(), core::ptr::from_mut(old), new) }
	}
	}
	);

	declare_and_impl_atomic_methods!(
	/// Atomic arithmetic operations
	pub trait AtomicArithmeticOps {
	/// Atomic add (wrapping).
	///
	/// Atomically updates `a` to `(a).wrapping_add(v)`.
	fn add[](a: &AtomicRepr<Self>, v: Self::Delta) {
	// SAFETY: `a.as_ptr()` is valid and properly aligned.
	unsafe { bindings::#call(v, a.as_ptr().cast()) }
	}

	/// Atomic fetch and add (wrapping).
	///
	/// Atomically updates `a` to `(a).wrapping_add(v)`, and returns the value of `*a`
	/// before the update.
	fn fetch_add[acquire, release, relaxed](a: &AtomicRepr<Self>, v: Self::Delta) -> Self {
	// SAFETY: `a.as_ptr()` is valid and properly aligned.
	unsafe { bindings::#call(v, a.as_ptr().cast()) }
	}
	}
	);