src/lock.rs - platform/external/rust/crates/futures-channel - Git at Google

 //! A "mutex" which only supports `try_lock`
 //!
 //! As a futures library the eventual call to an event loop should be the only
 //! thing that ever blocks, so this is assisted with a fast user-space
 //! implementation of a lock that can only have a `try_lock` operation.

 use core::cell::UnsafeCell;
 use core::ops::{Deref, DerefMut};
 use core::sync::atomic::Ordering::SeqCst;
 use core::sync::atomic::AtomicBool;

 /// A "mutex" around a value, similar to `std::sync::Mutex<T>`.
 ///
 /// This lock only supports the `try_lock` operation, however, and does not
 /// implement poisoning.
 #[derive(Debug)]
 pub(crate) struct Lock<T> {
     locked: AtomicBool,
     data: UnsafeCell<T>,
 }

 /// Sentinel representing an acquired lock through which the data can be
 /// accessed.
 pub(crate) struct TryLock<'a, T> {
     __ptr: &'a Lock<T>,
 }

 // The `Lock` structure is basically just a `Mutex<T>`, and these two impls are
 // intended to mirror the standard library's corresponding impls for `Mutex<T>`.
 //
 // If a `T` is sendable across threads, so is the lock, and `T` must be sendable
 // across threads to be `Sync` because it allows mutable access from multiple
 // threads.
 unsafe impl<T: Send> Send for Lock<T> {}
 unsafe impl<T: Send> Sync for Lock<T> {}

 impl<T> Lock<T> {
     /// Creates a new lock around the given value.
     pub(crate) fn new(t: T) -> Self {
         Self {
             locked: AtomicBool::new(false),
             data: UnsafeCell::new(t),
         }
     }

     /// Attempts to acquire this lock, returning whether the lock was acquired or
     /// not.
     ///
     /// If `Some` is returned then the data this lock protects can be accessed
     /// through the sentinel. This sentinel allows both mutable and immutable
     /// access.
     ///
     /// If `None` is returned then the lock is already locked, either elsewhere
     /// on this thread or on another thread.
     pub(crate) fn try_lock(&self) -> Option<TryLock<'_, T>> {
         if !self.locked.swap(true, SeqCst) {
             Some(TryLock { __ptr: self })
         } else {
             None
         }
     }
 }

 impl<T> Deref for TryLock<'_, T> {
     type Target = T;
     fn deref(&self) -> &T {
         // The existence of `TryLock` represents that we own the lock, so we
         // can safely access the data here.
         unsafe { &*self.__ptr.data.get() }
     }
 }

 impl<T> DerefMut for TryLock<'_, T> {
     fn deref_mut(&mut self) -> &mut T {
         // The existence of `TryLock` represents that we own the lock, so we
         // can safely access the data here.
         //
         // Additionally, we're the *only* `TryLock` in existence so mutable
         // access should be ok.
         unsafe { &mut *self.__ptr.data.get() }
     }
 }

 impl<T> Drop for TryLock<'_, T> {
     fn drop(&mut self) {
         self.__ptr.locked.store(false, SeqCst);
     }
 }

 #[cfg(test)]
 mod tests {
     use super::Lock;

     #[test]
     fn smoke() {
         let a = Lock::new(1);
         let mut a1 = a.try_lock().unwrap();
         assert!(a.try_lock().is_none());
         assert_eq!(*a1, 1);
         *a1 = 2;
         drop(a1);
         assert_eq!(*a.try_lock().unwrap(), 2);
         assert_eq!(*a.try_lock().unwrap(), 2);
     }
 }
	//! A "mutex" which only supports `try_lock`
	//!
	//! As a futures library the eventual call to an event loop should be the only
	//! thing that ever blocks, so this is assisted with a fast user-space
	//! implementation of a lock that can only have a `try_lock` operation.

	use core::cell::UnsafeCell;
	use core::ops::{Deref, DerefMut};
	use core::sync::atomic::Ordering::SeqCst;
	use core::sync::atomic::AtomicBool;

	/// A "mutex" around a value, similar to `std::sync::Mutex<T>`.
	///
	/// This lock only supports the `try_lock` operation, however, and does not
	/// implement poisoning.
	#[derive(Debug)]
	pub(crate) struct Lock<T> {
	locked: AtomicBool,
	data: UnsafeCell<T>,
	}

	/// Sentinel representing an acquired lock through which the data can be
	/// accessed.
	pub(crate) struct TryLock<'a, T> {
	__ptr: &'a Lock<T>,
	}

	// The `Lock` structure is basically just a `Mutex<T>`, and these two impls are
	// intended to mirror the standard library's corresponding impls for `Mutex<T>`.
	//
	// If a `T` is sendable across threads, so is the lock, and `T` must be sendable
	// across threads to be `Sync` because it allows mutable access from multiple
	// threads.
	unsafe impl<T: Send> Send for Lock<T> {}
	unsafe impl<T: Send> Sync for Lock<T> {}

	impl<T> Lock<T> {
	/// Creates a new lock around the given value.
	pub(crate) fn new(t: T) -> Self {
	Self {
	locked: AtomicBool::new(false),
	data: UnsafeCell::new(t),
	}
	}

	/// Attempts to acquire this lock, returning whether the lock was acquired or
	/// not.
	///
	/// If `Some` is returned then the data this lock protects can be accessed
	/// through the sentinel. This sentinel allows both mutable and immutable
	/// access.
	///
	/// If `None` is returned then the lock is already locked, either elsewhere
	/// on this thread or on another thread.
	pub(crate) fn try_lock(&self) -> Option<TryLock<'_, T>> {
	if !self.locked.swap(true, SeqCst) {
	Some(TryLock { __ptr: self })
	} else {
	None
	}
	}
	}

	impl<T> Deref for TryLock<'_, T> {
	type Target = T;
	fn deref(&self) -> &T {
	// The existence of `TryLock` represents that we own the lock, so we
	// can safely access the data here.
	unsafe { &*self.__ptr.data.get() }
	}
	}

	impl<T> DerefMut for TryLock<'_, T> {
	fn deref_mut(&mut self) -> &mut T {
	// The existence of `TryLock` represents that we own the lock, so we
	// can safely access the data here.
	//
	// Additionally, we're the only `TryLock` in existence so mutable
	// access should be ok.
	unsafe { &mut *self.__ptr.data.get() }
	}
	}

	impl<T> Drop for TryLock<'_, T> {
	fn drop(&mut self) {
	self.__ptr.locked.store(false, SeqCst);
	}
	}

	#[cfg(test)]
	mod tests {
	use super::Lock;

	#[test]
	fn smoke() {
	let a = Lock::new(1);
	let mut a1 = a.try_lock().unwrap();
	assert!(a.try_lock().is_none());
	assert_eq!(*a1, 1);
	*a1 = 2;
	drop(a1);
	assert_eq!(*a.try_lock().unwrap(), 2);
	assert_eq!(*a.try_lock().unwrap(), 2);
	}
	}