library/std/src/sys/vxworks/mutex.rs - third_party/rust - Git at Google

 use crate::cell::UnsafeCell;
 use crate::mem::MaybeUninit;

 pub struct Mutex {
     inner: UnsafeCell<libc::pthread_mutex_t>,
 }

 #[inline]
 pub unsafe fn raw(m: &Mutex) -> *mut libc::pthread_mutex_t {
     m.inner.get()
 }

 unsafe impl Send for Mutex {}
 unsafe impl Sync for Mutex {}

 #[allow(dead_code)] // sys isn't exported yet
 impl Mutex {
     pub const fn new() -> Mutex {
         // Might be moved to a different address, so it is better to avoid
         // initialization of potentially opaque OS data before it landed.
         // Be very careful using this newly constructed `Mutex`, reentrant
         // locking is undefined behavior until `init` is called!
         Mutex { inner: UnsafeCell::new(libc::PTHREAD_MUTEX_INITIALIZER) }
     }
     #[inline]
     pub unsafe fn init(&mut self) {
         // Issue #33770
         //
         // A pthread mutex initialized with PTHREAD_MUTEX_INITIALIZER will have
         // a type of PTHREAD_MUTEX_DEFAULT, which has undefined behavior if you
         // try to re-lock it from the same thread when you already hold a lock.
         //
         // In practice, glibc takes advantage of this undefined behavior to
         // implement hardware lock elision, which uses hardware transactional
         // memory to avoid acquiring the lock. While a transaction is in
         // progress, the lock appears to be unlocked. This isn't a problem for
         // other threads since the transactional memory will abort if a conflict
         // is detected, however no abort is generated if re-locking from the
         // same thread.
         //
         // Since locking the same mutex twice will result in two aliasing &mut
         // references, we instead create the mutex with type
         // PTHREAD_MUTEX_NORMAL which is guaranteed to deadlock if we try to
         // re-lock it from the same thread, thus avoiding undefined behavior.
         let mut attr = MaybeUninit::<libc::pthread_mutexattr_t>::uninit();
         let r = libc::pthread_mutexattr_init(attr.as_mut_ptr());
         debug_assert_eq!(r, 0);
         let r = libc::pthread_mutexattr_settype(attr.as_mut_ptr(), libc::PTHREAD_MUTEX_NORMAL);
         debug_assert_eq!(r, 0);
         let r = libc::pthread_mutex_init(self.inner.get(), attr.as_ptr());
         debug_assert_eq!(r, 0);
         let r = libc::pthread_mutexattr_destroy(attr.as_mut_ptr());
         debug_assert_eq!(r, 0);
     }
     #[inline]
     pub unsafe fn lock(&self) {
         let r = libc::pthread_mutex_lock(self.inner.get());
         debug_assert_eq!(r, 0);
     }
     #[inline]
     pub unsafe fn unlock(&self) {
         let r = libc::pthread_mutex_unlock(self.inner.get());
         debug_assert_eq!(r, 0);
     }
     #[inline]
     pub unsafe fn try_lock(&self) -> bool {
         libc::pthread_mutex_trylock(self.inner.get()) == 0
     }
     #[inline]
     #[cfg(not(target_os = "dragonfly"))]
     pub unsafe fn destroy(&self) {
         let r = libc::pthread_mutex_destroy(self.inner.get());
         debug_assert_eq!(r, 0);
     }
     #[inline]
     #[cfg(target_os = "dragonfly")]
     pub unsafe fn destroy(&self) {
         let r = libc::pthread_mutex_destroy(self.inner.get());
         // On DragonFly pthread_mutex_destroy() returns EINVAL if called on a
         // mutex that was just initialized with libc::PTHREAD_MUTEX_INITIALIZER.
         // Once it is used (locked/unlocked) or pthread_mutex_init() is called,
         // this behaviour no longer occurs.
         debug_assert!(r == 0 || r == libc::EINVAL);
     }
 }

 pub struct ReentrantMutex {
     inner: UnsafeCell<libc::pthread_mutex_t>,
 }

 unsafe impl Send for ReentrantMutex {}
 unsafe impl Sync for ReentrantMutex {}

 impl ReentrantMutex {
     pub const unsafe fn uninitialized() -> ReentrantMutex {
         ReentrantMutex { inner: UnsafeCell::new(libc::PTHREAD_MUTEX_INITIALIZER) }
     }

     pub unsafe fn init(&self) {
         let mut attr = MaybeUninit::<libc::pthread_mutexattr_t>::uninit();
         let result = libc::pthread_mutexattr_init(attr.as_mut_ptr());
         debug_assert_eq!(result, 0);
         let result =
             libc::pthread_mutexattr_settype(attr.as_mut_ptr(), libc::PTHREAD_MUTEX_RECURSIVE);
         debug_assert_eq!(result, 0);
         let result = libc::pthread_mutex_init(self.inner.get(), attr.as_ptr());
         debug_assert_eq!(result, 0);
         let result = libc::pthread_mutexattr_destroy(attr.as_mut_ptr());
         debug_assert_eq!(result, 0);
     }

     pub unsafe fn lock(&self) {
         let result = libc::pthread_mutex_lock(self.inner.get());
         debug_assert_eq!(result, 0);
     }

     #[inline]
     pub unsafe fn try_lock(&self) -> bool {
         libc::pthread_mutex_trylock(self.inner.get()) == 0
     }

     pub unsafe fn unlock(&self) {
         let result = libc::pthread_mutex_unlock(self.inner.get());
         debug_assert_eq!(result, 0);
     }

     pub unsafe fn destroy(&self) {
         let result = libc::pthread_mutex_destroy(self.inner.get());
         debug_assert_eq!(result, 0);
     }
 }
	use crate::cell::UnsafeCell;
	use crate::mem::MaybeUninit;

	pub struct Mutex {
	inner: UnsafeCell<libc::pthread_mutex_t>,
	}

	#[inline]
	pub unsafe fn raw(m: &Mutex) -> *mut libc::pthread_mutex_t {
	m.inner.get()
	}

	unsafe impl Send for Mutex {}
	unsafe impl Sync for Mutex {}

	#[allow(dead_code)] // sys isn't exported yet
	impl Mutex {
	pub const fn new() -> Mutex {
	// Might be moved to a different address, so it is better to avoid
	// initialization of potentially opaque OS data before it landed.
	// Be very careful using this newly constructed `Mutex`, reentrant
	// locking is undefined behavior until `init` is called!
	Mutex { inner: UnsafeCell::new(libc::PTHREAD_MUTEX_INITIALIZER) }
	}
	#[inline]
	pub unsafe fn init(&mut self) {
	// Issue #33770
	//
	// A pthread mutex initialized with PTHREAD_MUTEX_INITIALIZER will have
	// a type of PTHREAD_MUTEX_DEFAULT, which has undefined behavior if you
	// try to re-lock it from the same thread when you already hold a lock.
	//
	// In practice, glibc takes advantage of this undefined behavior to
	// implement hardware lock elision, which uses hardware transactional
	// memory to avoid acquiring the lock. While a transaction is in
	// progress, the lock appears to be unlocked. This isn't a problem for
	// other threads since the transactional memory will abort if a conflict
	// is detected, however no abort is generated if re-locking from the
	// same thread.
	//
	// Since locking the same mutex twice will result in two aliasing &mut
	// references, we instead create the mutex with type
	// PTHREAD_MUTEX_NORMAL which is guaranteed to deadlock if we try to
	// re-lock it from the same thread, thus avoiding undefined behavior.
	let mut attr = MaybeUninit::<libc::pthread_mutexattr_t>::uninit();
	let r = libc::pthread_mutexattr_init(attr.as_mut_ptr());
	debug_assert_eq!(r, 0);
	let r = libc::pthread_mutexattr_settype(attr.as_mut_ptr(), libc::PTHREAD_MUTEX_NORMAL);
	debug_assert_eq!(r, 0);
	let r = libc::pthread_mutex_init(self.inner.get(), attr.as_ptr());
	debug_assert_eq!(r, 0);
	let r = libc::pthread_mutexattr_destroy(attr.as_mut_ptr());
	debug_assert_eq!(r, 0);
	}
	#[inline]
	pub unsafe fn lock(&self) {
	let r = libc::pthread_mutex_lock(self.inner.get());
	debug_assert_eq!(r, 0);
	}
	#[inline]
	pub unsafe fn unlock(&self) {
	let r = libc::pthread_mutex_unlock(self.inner.get());
	debug_assert_eq!(r, 0);
	}
	#[inline]
	pub unsafe fn try_lock(&self) -> bool {
	libc::pthread_mutex_trylock(self.inner.get()) == 0
	}
	#[inline]
	#[cfg(not(target_os = "dragonfly"))]
	pub unsafe fn destroy(&self) {
	let r = libc::pthread_mutex_destroy(self.inner.get());
	debug_assert_eq!(r, 0);
	}
	#[inline]
	#[cfg(target_os = "dragonfly")]
	pub unsafe fn destroy(&self) {
	let r = libc::pthread_mutex_destroy(self.inner.get());
	// On DragonFly pthread_mutex_destroy() returns EINVAL if called on a
	// mutex that was just initialized with libc::PTHREAD_MUTEX_INITIALIZER.
	// Once it is used (locked/unlocked) or pthread_mutex_init() is called,
	// this behaviour no longer occurs.
	debug_assert!(r == 0 \|\| r == libc::EINVAL);
	}
	}

	pub struct ReentrantMutex {
	inner: UnsafeCell<libc::pthread_mutex_t>,
	}

	unsafe impl Send for ReentrantMutex {}
	unsafe impl Sync for ReentrantMutex {}

	impl ReentrantMutex {
	pub const unsafe fn uninitialized() -> ReentrantMutex {
	ReentrantMutex { inner: UnsafeCell::new(libc::PTHREAD_MUTEX_INITIALIZER) }
	}

	pub unsafe fn init(&self) {
	let mut attr = MaybeUninit::<libc::pthread_mutexattr_t>::uninit();
	let result = libc::pthread_mutexattr_init(attr.as_mut_ptr());
	debug_assert_eq!(result, 0);
	let result =
	libc::pthread_mutexattr_settype(attr.as_mut_ptr(), libc::PTHREAD_MUTEX_RECURSIVE);
	debug_assert_eq!(result, 0);
	let result = libc::pthread_mutex_init(self.inner.get(), attr.as_ptr());
	debug_assert_eq!(result, 0);
	let result = libc::pthread_mutexattr_destroy(attr.as_mut_ptr());
	debug_assert_eq!(result, 0);
	}

	pub unsafe fn lock(&self) {
	let result = libc::pthread_mutex_lock(self.inner.get());
	debug_assert_eq!(result, 0);
	}

	#[inline]
	pub unsafe fn try_lock(&self) -> bool {
	libc::pthread_mutex_trylock(self.inner.get()) == 0
	}

	pub unsafe fn unlock(&self) {
	let result = libc::pthread_mutex_unlock(self.inner.get());
	debug_assert_eq!(result, 0);
	}

	pub unsafe fn destroy(&self) {
	let result = libc::pthread_mutex_destroy(self.inner.get());
	debug_assert_eq!(result, 0);
	}
	}