rust/kernel/sync/lock.rs - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0

 //! Generic kernel lock and guard.
 //!
 //! It contains a generic Rust lock and guard that allow for different backends (e.g., mutexes,
 //! spinlocks, raw spinlocks) to be provided with minimal effort.

 use super::LockClassKey;
 use crate::{init::PinInit, pin_init, str::CStr, types::Opaque, types::ScopeGuard};
 use core::{cell::UnsafeCell, marker::PhantomData, marker::PhantomPinned};
 use macros::pin_data;

 pub mod mutex;
 pub mod spinlock;

 /// The "backend" of a lock.
 ///
 /// It is the actual implementation of the lock, without the need to repeat patterns used in all
 /// locks.
 ///
 /// # Safety
 ///
 /// - Implementers must ensure that only one thread/CPU may access the protected data once the lock
 ///   is owned, that is, between calls to [`lock`] and [`unlock`].
 /// - Implementers must also ensure that [`relock`] uses the same locking method as the original
 ///   lock operation.
 ///
 /// [`lock`]: Backend::lock
 /// [`unlock`]: Backend::unlock
 /// [`relock`]: Backend::relock
 pub unsafe trait Backend {
     /// The state required by the lock.
     type State;

     /// The state required to be kept between [`lock`] and [`unlock`].
     ///
     /// [`lock`]: Backend::lock
     /// [`unlock`]: Backend::unlock
     type GuardState;

     /// Initialises the lock.
     ///
     /// # Safety
     ///
     /// `ptr` must be valid for write for the duration of the call, while `name` and `key` must
     /// remain valid for read indefinitely.
     unsafe fn init(
         ptr: *mut Self::State,
         name: *const core::ffi::c_char,
         key: *mut bindings::lock_class_key,
     );

     /// Acquires the lock, making the caller its owner.
     ///
     /// # Safety
     ///
     /// Callers must ensure that [`Backend::init`] has been previously called.
     #[must_use]
     unsafe fn lock(ptr: *mut Self::State) -> Self::GuardState;

     /// Releases the lock, giving up its ownership.
     ///
     /// # Safety
     ///
     /// It must only be called by the current owner of the lock.
     unsafe fn unlock(ptr: *mut Self::State, guard_state: &Self::GuardState);

     /// Reacquires the lock, making the caller its owner.
     ///
     /// # Safety
     ///
     /// Callers must ensure that `guard_state` comes from a previous call to [`Backend::lock`] (or
     /// variant) that has been unlocked with [`Backend::unlock`] and will be relocked now.
     unsafe fn relock(ptr: *mut Self::State, guard_state: &mut Self::GuardState) {
         // SAFETY: The safety requirements ensure that the lock is initialised.
         *guard_state = unsafe { Self::lock(ptr) };
     }
 }

 /// A mutual exclusion primitive.
 ///
 /// Exposes one of the kernel locking primitives. Which one is exposed depends on the lock
 /// [`Backend`] specified as the generic parameter `B`.
 #[pin_data]
 pub struct Lock<T: ?Sized, B: Backend> {
     /// The kernel lock object.
     #[pin]
     state: Opaque<B::State>,

     /// Some locks are known to be self-referential (e.g., mutexes), while others are architecture
     /// or config defined (e.g., spinlocks). So we conservatively require them to be pinned in case
     /// some architecture uses self-references now or in the future.
     #[pin]
     _pin: PhantomPinned,

     /// The data protected by the lock.
     pub(crate) data: UnsafeCell<T>,
 }

 // SAFETY: `Lock` can be transferred across thread boundaries iff the data it protects can.
 unsafe impl<T: ?Sized + Send, B: Backend> Send for Lock<T, B> {}

 // SAFETY: `Lock` serialises the interior mutability it provides, so it is `Sync` as long as the
 // data it protects is `Send`.
 unsafe impl<T: ?Sized + Send, B: Backend> Sync for Lock<T, B> {}

 impl<T, B: Backend> Lock<T, B> {
     /// Constructs a new lock initialiser.
     pub fn new(t: T, name: &'static CStr, key: &'static LockClassKey) -> impl PinInit<Self> {
         pin_init!(Self {
             data: UnsafeCell::new(t),
             _pin: PhantomPinned,
             // SAFETY: `slot` is valid while the closure is called and both `name` and `key` have
             // static lifetimes so they live indefinitely.
             state <- Opaque::ffi_init(|slot| unsafe {
                 B::init(slot, name.as_char_ptr(), key.as_ptr())
             }),
         })
     }
 }

 impl<T: ?Sized, B: Backend> Lock<T, B> {
     /// Acquires the lock and gives the caller access to the data protected by it.
     pub fn lock(&self) -> Guard<'_, T, B> {
         // SAFETY: The constructor of the type calls `init`, so the existence of the object proves
         // that `init` was called.
         let state = unsafe { B::lock(self.state.get()) };
         // SAFETY: The lock was just acquired.
         unsafe { Guard::new(self, state) }
     }
 }

 /// A lock guard.
 ///
 /// Allows mutual exclusion primitives that implement the [`Backend`] trait to automatically unlock
 /// when a guard goes out of scope. It also provides a safe and convenient way to access the data
 /// protected by the lock.
 #[must_use = "the lock unlocks immediately when the guard is unused"]
 pub struct Guard<'a, T: ?Sized, B: Backend> {
     pub(crate) lock: &'a Lock<T, B>,
     pub(crate) state: B::GuardState,
     _not_send: PhantomData<*mut ()>,
 }

 // SAFETY: `Guard` is sync when the data protected by the lock is also sync.
 unsafe impl<T: Sync + ?Sized, B: Backend> Sync for Guard<'_, T, B> {}

 impl<T: ?Sized, B: Backend> Guard<'_, T, B> {
     pub(crate) fn do_unlocked<U>(&mut self, cb: impl FnOnce() -> U) -> U {
         // SAFETY: The caller owns the lock, so it is safe to unlock it.
         unsafe { B::unlock(self.lock.state.get(), &self.state) };

         // SAFETY: The lock was just unlocked above and is being relocked now.
         let _relock =
             ScopeGuard::new(|| unsafe { B::relock(self.lock.state.get(), &mut self.state) });

         cb()
     }
 }

 impl<T: ?Sized, B: Backend> core::ops::Deref for Guard<'_, T, B> {
     type Target = T;

     fn deref(&self) -> &Self::Target {
         // SAFETY: The caller owns the lock, so it is safe to deref the protected data.
         unsafe { &*self.lock.data.get() }
     }
 }

 impl<T: ?Sized, B: Backend> core::ops::DerefMut for Guard<'_, T, B> {
     fn deref_mut(&mut self) -> &mut Self::Target {
         // SAFETY: The caller owns the lock, so it is safe to deref the protected data.
         unsafe { &mut *self.lock.data.get() }
     }
 }

 impl<T: ?Sized, B: Backend> Drop for Guard<'_, T, B> {
     fn drop(&mut self) {
         // SAFETY: The caller owns the lock, so it is safe to unlock it.
         unsafe { B::unlock(self.lock.state.get(), &self.state) };
     }
 }

 impl<'a, T: ?Sized, B: Backend> Guard<'a, T, B> {
     /// Constructs a new immutable lock guard.
     ///
     /// # Safety
     ///
     /// The caller must ensure that it owns the lock.
     pub(crate) unsafe fn new(lock: &'a Lock<T, B>, state: B::GuardState) -> Self {
         Self {
             lock,
             state,
             _not_send: PhantomData,
         }
     }
 }
	// SPDX-License-Identifier: GPL-2.0

	//! Generic kernel lock and guard.
	//!
	//! It contains a generic Rust lock and guard that allow for different backends (e.g., mutexes,
	//! spinlocks, raw spinlocks) to be provided with minimal effort.

	use super::LockClassKey;
	use crate::{init::PinInit, pin_init, str::CStr, types::Opaque, types::ScopeGuard};
	use core::{cell::UnsafeCell, marker::PhantomData, marker::PhantomPinned};
	use macros::pin_data;

	pub mod mutex;
	pub mod spinlock;

	/// The "backend" of a lock.
	///
	/// It is the actual implementation of the lock, without the need to repeat patterns used in all
	/// locks.
	///
	/// # Safety
	///
	/// - Implementers must ensure that only one thread/CPU may access the protected data once the lock
	/// is owned, that is, between calls to [`lock`] and [`unlock`].
	/// - Implementers must also ensure that [`relock`] uses the same locking method as the original
	/// lock operation.
	///
	/// [`lock`]: Backend::lock
	/// [`unlock`]: Backend::unlock
	/// [`relock`]: Backend::relock
	pub unsafe trait Backend {
	/// The state required by the lock.
	type State;

	/// The state required to be kept between [`lock`] and [`unlock`].
	///
	/// [`lock`]: Backend::lock
	/// [`unlock`]: Backend::unlock
	type GuardState;

	/// Initialises the lock.
	///
	/// # Safety
	///
	/// `ptr` must be valid for write for the duration of the call, while `name` and `key` must
	/// remain valid for read indefinitely.
	unsafe fn init(
	ptr: *mut Self::State,
	name: *const core::ffi::c_char,
	key: *mut bindings::lock_class_key,
	);

	/// Acquires the lock, making the caller its owner.
	///
	/// # Safety
	///
	/// Callers must ensure that [`Backend::init`] has been previously called.
	#[must_use]
	unsafe fn lock(ptr: *mut Self::State) -> Self::GuardState;

	/// Releases the lock, giving up its ownership.
	///
	/// # Safety
	///
	/// It must only be called by the current owner of the lock.
	unsafe fn unlock(ptr: *mut Self::State, guard_state: &Self::GuardState);

	/// Reacquires the lock, making the caller its owner.
	///
	/// # Safety
	///
	/// Callers must ensure that `guard_state` comes from a previous call to [`Backend::lock`] (or
	/// variant) that has been unlocked with [`Backend::unlock`] and will be relocked now.
	unsafe fn relock(ptr: *mut Self::State, guard_state: &mut Self::GuardState) {
	// SAFETY: The safety requirements ensure that the lock is initialised.
	*guard_state = unsafe { Self::lock(ptr) };
	}
	}

	/// A mutual exclusion primitive.
	///
	/// Exposes one of the kernel locking primitives. Which one is exposed depends on the lock
	/// [`Backend`] specified as the generic parameter `B`.
	#[pin_data]
	pub struct Lock<T: ?Sized, B: Backend> {
	/// The kernel lock object.
	#[pin]
	state: Opaque<B::State>,

	/// Some locks are known to be self-referential (e.g., mutexes), while others are architecture
	/// or config defined (e.g., spinlocks). So we conservatively require them to be pinned in case
	/// some architecture uses self-references now or in the future.
	#[pin]
	_pin: PhantomPinned,

	/// The data protected by the lock.
	pub(crate) data: UnsafeCell<T>,
	}

	// SAFETY: `Lock` can be transferred across thread boundaries iff the data it protects can.
	unsafe impl<T: ?Sized + Send, B: Backend> Send for Lock<T, B> {}

	// SAFETY: `Lock` serialises the interior mutability it provides, so it is `Sync` as long as the
	// data it protects is `Send`.
	unsafe impl<T: ?Sized + Send, B: Backend> Sync for Lock<T, B> {}

	impl<T, B: Backend> Lock<T, B> {
	/// Constructs a new lock initialiser.
	pub fn new(t: T, name: &'static CStr, key: &'static LockClassKey) -> impl PinInit<Self> {
	pin_init!(Self {
	data: UnsafeCell::new(t),
	_pin: PhantomPinned,
	// SAFETY: `slot` is valid while the closure is called and both `name` and `key` have
	// static lifetimes so they live indefinitely.
	state <- Opaque::ffi_init(\|slot\| unsafe {
	B::init(slot, name.as_char_ptr(), key.as_ptr())
	}),
	})
	}
	}

	impl<T: ?Sized, B: Backend> Lock<T, B> {
	/// Acquires the lock and gives the caller access to the data protected by it.
	pub fn lock(&self) -> Guard<'_, T, B> {
	// SAFETY: The constructor of the type calls `init`, so the existence of the object proves
	// that `init` was called.
	let state = unsafe { B::lock(self.state.get()) };
	// SAFETY: The lock was just acquired.
	unsafe { Guard::new(self, state) }
	}
	}

	/// A lock guard.
	///
	/// Allows mutual exclusion primitives that implement the [`Backend`] trait to automatically unlock
	/// when a guard goes out of scope. It also provides a safe and convenient way to access the data
	/// protected by the lock.
	#[must_use = "the lock unlocks immediately when the guard is unused"]
	pub struct Guard<'a, T: ?Sized, B: Backend> {
	pub(crate) lock: &'a Lock<T, B>,
	pub(crate) state: B::GuardState,
	_not_send: PhantomData<*mut ()>,
	}

	// SAFETY: `Guard` is sync when the data protected by the lock is also sync.
	unsafe impl<T: Sync + ?Sized, B: Backend> Sync for Guard<'_, T, B> {}

	impl<T: ?Sized, B: Backend> Guard<'_, T, B> {
	pub(crate) fn do_unlocked<U>(&mut self, cb: impl FnOnce() -> U) -> U {
	// SAFETY: The caller owns the lock, so it is safe to unlock it.
	unsafe { B::unlock(self.lock.state.get(), &self.state) };

	// SAFETY: The lock was just unlocked above and is being relocked now.
	let _relock =
	ScopeGuard::new(\|\| unsafe { B::relock(self.lock.state.get(), &mut self.state) });

	cb()
	}
	}

	impl<T: ?Sized, B: Backend> core::ops::Deref for Guard<'_, T, B> {
	type Target = T;

	fn deref(&self) -> &Self::Target {
	// SAFETY: The caller owns the lock, so it is safe to deref the protected data.
	unsafe { &*self.lock.data.get() }
	}
	}

	impl<T: ?Sized, B: Backend> core::ops::DerefMut for Guard<'_, T, B> {
	fn deref_mut(&mut self) -> &mut Self::Target {
	// SAFETY: The caller owns the lock, so it is safe to deref the protected data.
	unsafe { &mut *self.lock.data.get() }
	}
	}

	impl<T: ?Sized, B: Backend> Drop for Guard<'_, T, B> {
	fn drop(&mut self) {
	// SAFETY: The caller owns the lock, so it is safe to unlock it.
	unsafe { B::unlock(self.lock.state.get(), &self.state) };
	}
	}

	impl<'a, T: ?Sized, B: Backend> Guard<'a, T, B> {
	/// Constructs a new immutable lock guard.
	///
	/// # Safety
	///
	/// The caller must ensure that it owns the lock.
	pub(crate) unsafe fn new(lock: &'a Lock<T, B>, state: B::GuardState) -> Self {
	Self {
	lock,
	state,
	_not_send: PhantomData,
	}
	}
	}