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//! A lock that provides data access to either one writer or many readers. use core::{ cell::UnsafeCell, ops::{Deref, DerefMut}, sync::atomic::{AtomicUsize, Ordering}, marker::PhantomData, fmt, mem, }; use crate::{RelaxStrategy, Spin}; /// A lock that provides data access to either one writer or many readers. /// /// This lock behaves in a similar manner to its namesake `std::sync::RwLock` but uses /// spinning for synchronisation instead. Unlike its namespace, this lock does not /// track lock poisoning. /// /// This type of lock allows a number of readers or at most one writer at any /// point in time. The write portion of this lock typically allows modification /// of the underlying data (exclusive access) and the read portion of this lock /// typically allows for read-only access (shared access). /// /// The type parameter `T` represents the data that this lock protects. It is /// required that `T` satisfies `Send` to be shared across tasks and `Sync` to /// allow concurrent access through readers. The RAII guards returned from the /// locking methods implement `Deref` (and `DerefMut` for the `write` methods) /// to allow access to the contained of the lock. /// /// An [`RwLockUpgradableGuard`](RwLockUpgradableGuard) can be upgraded to a /// writable guard through the [`RwLockUpgradableGuard::upgrade`](RwLockUpgradableGuard::upgrade) /// [`RwLockUpgradableGuard::try_upgrade`](RwLockUpgradableGuard::try_upgrade) functions. /// Writable or upgradeable guards can be downgraded through their respective `downgrade` /// functions. /// /// Based on Facebook's /// [`folly/RWSpinLock.h`](https://github.com/facebook/folly/blob/a0394d84f2d5c3e50ebfd0566f9d3acb52cfab5a/folly/synchronization/RWSpinLock.h). /// This implementation is unfair to writers - if the lock always has readers, then no writers will /// ever get a chance. Using an upgradeable lock guard can *somewhat* alleviate this issue as no /// new readers are allowed when an upgradeable guard is held, but upgradeable guards can be taken /// when there are existing readers. However if the lock is that highly contended and writes are /// crucial then this implementation may be a poor choice. /// /// # Examples /// /// ``` /// use spin; /// /// let lock = spin::RwLock::new(5); /// /// // many reader locks can be held at once /// { /// let r1 = lock.read(); /// let r2 = lock.read(); /// assert_eq!(*r1, 5); /// assert_eq!(*r2, 5); /// } // read locks are dropped at this point /// /// // only one write lock may be held, however /// { /// let mut w = lock.write(); /// *w += 1; /// assert_eq!(*w, 6); /// } // write lock is dropped here /// ``` pub struct RwLock<T: ?Sized, R = Spin> { phantom: PhantomData<R>, lock: AtomicUsize, data: UnsafeCell<T>, } const READER: usize = 1 << 2; const UPGRADED: usize = 1 << 1; const WRITER: usize = 1; /// A guard that provides immutable data access. /// /// When the guard falls out of scope it will decrement the read count, /// potentially releasing the lock. pub struct RwLockReadGuard<'a, T: 'a + ?Sized> { lock: &'a AtomicUsize, data: &'a T, } /// A guard that provides mutable data access. /// /// When the guard falls out of scope it will release the lock. pub struct RwLockWriteGuard<'a, T: 'a + ?Sized, R = Spin> { phantom: PhantomData<R>, inner: &'a RwLock<T, R>, data: &'a mut T, } /// A guard that provides immutable data access but can be upgraded to [`RwLockWriteGuard`]. /// /// No writers or other upgradeable guards can exist while this is in scope. New reader /// creation is prevented (to alleviate writer starvation) but there may be existing readers /// when the lock is acquired. /// /// When the guard falls out of scope it will release the lock. pub struct RwLockUpgradableGuard<'a, T: 'a + ?Sized, R = Spin> { phantom: PhantomData<R>, inner: &'a RwLock<T, R>, data: &'a T, } // Same unsafe impls as `std::sync::RwLock` unsafe impl<T: ?Sized + Send, R> Send for RwLock<T, R> {} unsafe impl<T: ?Sized + Send + Sync, R> Sync for RwLock<T, R> {} impl<T, R> RwLock<T, R> { /// Creates a new spinlock wrapping the supplied data. /// /// May be used statically: /// /// ``` /// use spin; /// /// static RW_LOCK: spin::RwLock<()> = spin::RwLock::new(()); /// /// fn demo() { /// let lock = RW_LOCK.read(); /// // do something with lock /// drop(lock); /// } /// ``` #[inline] pub const fn new(data: T) -> Self { RwLock { phantom: PhantomData, lock: AtomicUsize::new(0), data: UnsafeCell::new(data), } } /// Consumes this `RwLock`, returning the underlying data. #[inline] pub fn into_inner(self) -> T { // We know statically that there are no outstanding references to // `self` so there's no need to lock. let RwLock { data, .. } = self; data.into_inner() } } impl<T: ?Sized, R: RelaxStrategy> RwLock<T, R> { /// Locks this rwlock with shared read access, blocking the current thread /// until it can be acquired. /// /// The calling thread will be blocked until there are no more writers which /// hold the lock. There may be other readers currently inside the lock when /// this method returns. This method does not provide any guarantees with /// respect to the ordering of whether contentious readers or writers will /// acquire the lock first. /// /// Returns an RAII guard which will release this thread's shared access /// once it is dropped. /// /// ``` /// let mylock = spin::RwLock::new(0); /// { /// let mut data = mylock.read(); /// // The lock is now locked and the data can be read /// println!("{}", *data); /// // The lock is dropped /// } /// ``` #[inline] pub fn read(&self) -> RwLockReadGuard<T> { loop { match self.try_read() { Some(guard) => return guard, None => R::relax(), } } } /// Lock this rwlock with exclusive write access, blocking the current /// thread until it can be acquired. /// /// This function will not return while other writers or other readers /// currently have access to the lock. /// /// Returns an RAII guard which will drop the write access of this rwlock /// when dropped. /// /// ``` /// let mylock = spin::RwLock::new(0); /// { /// let mut data = mylock.write(); /// // The lock is now locked and the data can be written /// *data += 1; /// // The lock is dropped /// } /// ``` #[inline] pub fn write(&self) -> RwLockWriteGuard<T, R> { loop { match self.try_write_internal(false) { Some(guard) => return guard, None => R::relax(), } } } /// Obtain a readable lock guard that can later be upgraded to a writable lock guard. /// Upgrades can be done through the [`RwLockUpgradableGuard::upgrade`](RwLockUpgradableGuard::upgrade) method. #[inline] pub fn upgradeable_read(&self) -> RwLockUpgradableGuard<T, R> { loop { match self.try_upgradeable_read() { Some(guard) => return guard, None => R::relax(), } } } } impl<T: ?Sized, R> RwLock<T, R> { /// Attempt to acquire this lock with shared read access. /// /// This function will never block and will return immediately if `read` /// would otherwise succeed. Returns `Some` of an RAII guard which will /// release the shared access of this thread when dropped, or `None` if the /// access could not be granted. This method does not provide any /// guarantees with respect to the ordering of whether contentious readers /// or writers will acquire the lock first. /// /// ``` /// let mylock = spin::RwLock::new(0); /// { /// match mylock.try_read() { /// Some(data) => { /// // The lock is now locked and the data can be read /// println!("{}", *data); /// // The lock is dropped /// }, /// None => (), // no cigar /// }; /// } /// ``` #[inline] pub fn try_read(&self) -> Option<RwLockReadGuard<T>> { let value = self.lock.fetch_add(READER, Ordering::Acquire); // We check the UPGRADED bit here so that new readers are prevented when an UPGRADED lock is held. // This helps reduce writer starvation. if value & (WRITER | UPGRADED) != 0 { // Lock is taken, undo. self.lock.fetch_sub(READER, Ordering::Release); None } else { Some(RwLockReadGuard { lock: &self.lock, data: unsafe { &*self.data.get() }, }) } } /// Return the number of readers that currently hold the lock (including upgradable readers). /// /// # Safety /// /// This function provides no synchronization guarantees and so its result should be considered 'out of date' /// the instant it is called. Do not use it for synchronization purposes. However, it may be useful as a heuristic. pub fn reader_count(&self) -> usize { let state = self.lock.load(Ordering::Relaxed); state / READER + (state & UPGRADED) / UPGRADED } /// Return the number of writers that currently hold the lock. /// /// Because [`RwLock`] guarantees exclusive mutable access, this function may only return either `0` or `1`. /// /// # Safety /// /// This function provides no synchronization guarantees and so its result should be considered 'out of date' /// the instant it is called. Do not use it for synchronization purposes. However, it may be useful as a heuristic. pub fn writer_count(&self) -> usize { (self.lock.load(Ordering::Relaxed) & WRITER) / WRITER } /// Force decrement the reader count. /// /// # Safety /// /// This is *extremely* unsafe if there are outstanding `RwLockReadGuard`s /// live, or if called more times than `read` has been called, but can be /// useful in FFI contexts where the caller doesn't know how to deal with /// RAII. The underlying atomic operation uses `Ordering::Release`. #[inline] pub unsafe fn force_read_decrement(&self) { debug_assert!(self.lock.load(Ordering::Relaxed) & !WRITER > 0); self.lock.fetch_sub(READER, Ordering::Release); } /// Force unlock exclusive write access. /// /// # Safety /// /// This is *extremely* unsafe if there are outstanding `RwLockWriteGuard`s /// live, or if called when there are current readers, but can be useful in /// FFI contexts where the caller doesn't know how to deal with RAII. The /// underlying atomic operation uses `Ordering::Release`. #[inline] pub unsafe fn force_write_unlock(&self) { debug_assert_eq!(self.lock.load(Ordering::Relaxed) & !(WRITER | UPGRADED), 0); self.lock.fetch_and(!(WRITER | UPGRADED), Ordering::Release); } #[inline(always)] fn try_write_internal(&self, strong: bool) -> Option<RwLockWriteGuard<T, R>> { if compare_exchange( &self.lock, 0, WRITER, Ordering::Acquire, Ordering::Relaxed, strong, ) .is_ok() { Some(RwLockWriteGuard { phantom: PhantomData, inner: self, data: unsafe { &mut *self.data.get() }, }) } else { None } } /// Attempt to lock this rwlock with exclusive write access. /// /// This function does not ever block, and it will return `None` if a call /// to `write` would otherwise block. If successful, an RAII guard is /// returned. /// /// ``` /// let mylock = spin::RwLock::new(0); /// { /// match mylock.try_write() { /// Some(mut data) => { /// // The lock is now locked and the data can be written /// *data += 1; /// // The lock is implicitly dropped /// }, /// None => (), // no cigar /// }; /// } /// ``` #[inline] pub fn try_write(&self) -> Option<RwLockWriteGuard<T, R>> { self.try_write_internal(true) } /// Tries to obtain an upgradeable lock guard. #[inline] pub fn try_upgradeable_read(&self) -> Option<RwLockUpgradableGuard<T, R>> { if self.lock.fetch_or(UPGRADED, Ordering::Acquire) & (WRITER | UPGRADED) == 0 { Some(RwLockUpgradableGuard { phantom: PhantomData, inner: self, data: unsafe { &*self.data.get() }, }) } else { // We can't unflip the UPGRADED bit back just yet as there is another upgradeable or write lock. // When they unlock, they will clear the bit. None } } /// Returns a mutable reference to the underlying data. /// /// Since this call borrows the `RwLock` mutably, no actual locking needs to /// take place -- the mutable borrow statically guarantees no locks exist. /// /// # Examples /// /// ``` /// let mut lock = spin::RwLock::new(0); /// *lock.get_mut() = 10; /// assert_eq!(*lock.read(), 10); /// ``` pub fn get_mut(&mut self) -> &mut T { // We know statically that there are no other references to `self`, so // there's no need to lock the inner lock. unsafe { &mut *self.data.get() } } } impl<T: ?Sized + fmt::Debug, R> fmt::Debug for RwLock<T, R> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match self.try_read() { Some(guard) => write!(f, "RwLock {{ data: ") .and_then(|()| (&*guard).fmt(f)) .and_then(|()| write!(f, "}}")), None => write!(f, "RwLock {{ <locked> }}"), } } } impl<T: ?Sized + Default, R> Default for RwLock<T, R> { fn default() -> Self { Self::new(Default::default()) } } impl<T, R> From<T> for RwLock<T, R> { fn from(data: T) -> Self { Self::new(data) } } impl<'rwlock, T: ?Sized> RwLockReadGuard<'rwlock, T> { /// Leak the lock guard, yielding a reference to the underlying data. /// /// Note that this function will permanently lock the original lock for all but reading locks. /// /// ``` /// let mylock = spin::RwLock::new(0); /// /// let data: &i32 = spin::RwLockReadGuard::leak(mylock.read()); /// /// assert_eq!(*data, 0); /// ``` #[inline] pub fn leak(this: Self) -> &'rwlock T { let Self { data, .. } = this; data } } impl<'rwlock, T: ?Sized + fmt::Debug> fmt::Debug for RwLockReadGuard<'rwlock, T> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt::Debug::fmt(&**self, f) } } impl<'rwlock, T: ?Sized + fmt::Display> fmt::Display for RwLockReadGuard<'rwlock, T> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt::Display::fmt(&**self, f) } } impl<'rwlock, T: ?Sized, R: RelaxStrategy> RwLockUpgradableGuard<'rwlock, T, R> { /// Upgrades an upgradeable lock guard to a writable lock guard. /// /// ``` /// let mylock = spin::RwLock::new(0); /// /// let upgradeable = mylock.upgradeable_read(); // Readable, but not yet writable /// let writable = upgradeable.upgrade(); /// ``` #[inline] pub fn upgrade(mut self) -> RwLockWriteGuard<'rwlock, T, R> { loop { self = match self.try_upgrade_internal(false) { Ok(guard) => return guard, Err(e) => e, }; R::relax(); } } } impl<'rwlock, T: ?Sized, R> RwLockUpgradableGuard<'rwlock, T, R> { #[inline(always)] fn try_upgrade_internal(self, strong: bool) -> Result<RwLockWriteGuard<'rwlock, T, R>, Self> { if compare_exchange( &self.inner.lock, UPGRADED, WRITER, Ordering::Acquire, Ordering::Relaxed, strong, ) .is_ok() { let inner = self.inner; // Forget the old guard so its destructor doesn't run (before mutably aliasing data below) mem::forget(self); // Upgrade successful Ok(RwLockWriteGuard { phantom: PhantomData, inner, data: unsafe { &mut *inner.data.get() }, }) } else { Err(self) } } /// Tries to upgrade an upgradeable lock guard to a writable lock guard. /// /// ``` /// let mylock = spin::RwLock::new(0); /// let upgradeable = mylock.upgradeable_read(); // Readable, but not yet writable /// /// match upgradeable.try_upgrade() { /// Ok(writable) => /* upgrade successful - use writable lock guard */ (), /// Err(upgradeable) => /* upgrade unsuccessful */ (), /// }; /// ``` #[inline] pub fn try_upgrade(self) -> Result<RwLockWriteGuard<'rwlock, T, R>, Self> { self.try_upgrade_internal(true) } #[inline] /// Downgrades the upgradeable lock guard to a readable, shared lock guard. Cannot fail and is guaranteed not to spin. /// /// ``` /// let mylock = spin::RwLock::new(1); /// /// let upgradeable = mylock.upgradeable_read(); /// assert!(mylock.try_read().is_none()); /// assert_eq!(*upgradeable, 1); /// /// let readable = upgradeable.downgrade(); // This is guaranteed not to spin /// assert!(mylock.try_read().is_some()); /// assert_eq!(*readable, 1); /// ``` pub fn downgrade(self) -> RwLockReadGuard<'rwlock, T> { // Reserve the read guard for ourselves self.inner.lock.fetch_add(READER, Ordering::Acquire); let inner = self.inner; // Dropping self removes the UPGRADED bit mem::drop(self); RwLockReadGuard { lock: &inner.lock, data: unsafe { &*inner.data.get() }, } } /// Leak the lock guard, yielding a reference to the underlying data. /// /// Note that this function will permanently lock the original lock. /// /// ``` /// let mylock = spin::RwLock::new(0); /// /// let data: &i32 = spin::RwLockUpgradableGuard::leak(mylock.upgradeable_read()); /// /// assert_eq!(*data, 0); /// ``` #[inline] pub fn leak(this: Self) -> &'rwlock T { let Self { data, .. } = this; data } } impl<'rwlock, T: ?Sized + fmt::Debug, R> fmt::Debug for RwLockUpgradableGuard<'rwlock, T, R> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt::Debug::fmt(&**self, f) } } impl<'rwlock, T: ?Sized + fmt::Display, R> fmt::Display for RwLockUpgradableGuard<'rwlock, T, R> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt::Display::fmt(&**self, f) } } impl<'rwlock, T: ?Sized, R> RwLockWriteGuard<'rwlock, T, R> { /// Downgrades the writable lock guard to a readable, shared lock guard. Cannot fail and is guaranteed not to spin. /// /// ``` /// let mylock = spin::RwLock::new(0); /// /// let mut writable = mylock.write(); /// *writable = 1; /// /// let readable = writable.downgrade(); // This is guaranteed not to spin /// # let readable_2 = mylock.try_read().unwrap(); /// assert_eq!(*readable, 1); /// ``` #[inline] pub fn downgrade(self) -> RwLockReadGuard<'rwlock, T> { // Reserve the read guard for ourselves self.inner.lock.fetch_add(READER, Ordering::Acquire); let inner = self.inner; // Dropping self removes the UPGRADED bit mem::drop(self); RwLockReadGuard { lock: &inner.lock, data: unsafe { &*inner.data.get() }, } } /// Downgrades the writable lock guard to an upgradable, shared lock guard. Cannot fail and is guaranteed not to spin. /// /// ``` /// let mylock = spin::RwLock::new(0); /// /// let mut writable = mylock.write(); /// *writable = 1; /// /// let readable = writable.downgrade_to_upgradeable(); // This is guaranteed not to spin /// assert_eq!(*readable, 1); /// ``` #[inline] pub fn downgrade_to_upgradeable(self) -> RwLockUpgradableGuard<'rwlock, T, R> { debug_assert_eq!(self.inner.lock.load(Ordering::Acquire) & (WRITER | UPGRADED), WRITER); // Reserve the read guard for ourselves self.inner.lock.store(UPGRADED, Ordering::Release); let inner = self.inner; // Dropping self removes the UPGRADED bit mem::forget(self); RwLockUpgradableGuard { phantom: PhantomData, inner, data: unsafe { &*inner.data.get() }, } } /// Leak the lock guard, yielding a mutable reference to the underlying data. /// /// Note that this function will permanently lock the original lock. /// /// ``` /// let mylock = spin::RwLock::new(0); /// /// let data: &mut i32 = spin::RwLockWriteGuard::leak(mylock.write()); /// /// *data = 1; /// assert_eq!(*data, 1); /// ``` #[inline] pub fn leak(this: Self) -> &'rwlock mut T { let data = this.data as *mut _; // Keep it in pointer form temporarily to avoid double-aliasing core::mem::forget(this); unsafe { &mut *data } } } impl<'rwlock, T: ?Sized + fmt::Debug, R> fmt::Debug for RwLockWriteGuard<'rwlock, T, R> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt::Debug::fmt(&**self, f) } } impl<'rwlock, T: ?Sized + fmt::Display, R> fmt::Display for RwLockWriteGuard<'rwlock, T, R> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt::Display::fmt(&**self, f) } } impl<'rwlock, T: ?Sized> Deref for RwLockReadGuard<'rwlock, T> { type Target = T; fn deref(&self) -> &T { self.data } } impl<'rwlock, T: ?Sized, R> Deref for RwLockUpgradableGuard<'rwlock, T, R> { type Target = T; fn deref(&self) -> &T { self.data } } impl<'rwlock, T: ?Sized, R> Deref for RwLockWriteGuard<'rwlock, T, R> { type Target = T; fn deref(&self) -> &T { self.data } } impl<'rwlock, T: ?Sized, R> DerefMut for RwLockWriteGuard<'rwlock, T, R> { fn deref_mut(&mut self) -> &mut T { self.data } } impl<'rwlock, T: ?Sized> Drop for RwLockReadGuard<'rwlock, T> { fn drop(&mut self) { debug_assert!(self.lock.load(Ordering::Relaxed) & !(WRITER | UPGRADED) > 0); self.lock.fetch_sub(READER, Ordering::Release); } } impl<'rwlock, T: ?Sized, R> Drop for RwLockUpgradableGuard<'rwlock, T, R> { fn drop(&mut self) { debug_assert_eq!( self.inner.lock.load(Ordering::Relaxed) & (WRITER | UPGRADED), UPGRADED ); self.inner.lock.fetch_sub(UPGRADED, Ordering::AcqRel); } } impl<'rwlock, T: ?Sized, R> Drop for RwLockWriteGuard<'rwlock, T, R> { fn drop(&mut self) { debug_assert_eq!(self.inner.lock.load(Ordering::Relaxed) & WRITER, WRITER); // Writer is responsible for clearing both WRITER and UPGRADED bits. // The UPGRADED bit may be set if an upgradeable lock attempts an upgrade while this lock is held. self.inner.lock.fetch_and(!(WRITER | UPGRADED), Ordering::Release); } } #[inline(always)] fn compare_exchange( atomic: &AtomicUsize, current: usize, new: usize, success: Ordering, failure: Ordering, strong: bool, ) -> Result<usize, usize> { if strong { atomic.compare_exchange(current, new, success, failure) } else { atomic.compare_exchange_weak(current, new, success, failure) } } #[cfg(feature = "lock_api")] unsafe impl<R: RelaxStrategy> lock_api_crate::RawRwLock for RwLock<(), R> { type GuardMarker = lock_api_crate::GuardSend; const INIT: Self = Self::new(()); #[inline(always)] fn lock_exclusive(&self) { // Prevent guard destructor running core::mem::forget(self.write()); } #[inline(always)] fn try_lock_exclusive(&self) -> bool { // Prevent guard destructor running self.try_write().map(|g| core::mem::forget(g)).is_some() } #[inline(always)] unsafe fn unlock_exclusive(&self) { drop(RwLockWriteGuard { inner: self, data: &mut (), phantom: PhantomData, }); } #[inline(always)] fn lock_shared(&self) { // Prevent guard destructor running core::mem::forget(self.read()); } #[inline(always)] fn try_lock_shared(&self) -> bool { // Prevent guard destructor running self.try_read().map(|g| core::mem::forget(g)).is_some() } #[inline(always)] unsafe fn unlock_shared(&self) { drop(RwLockReadGuard { lock: &self.lock, data: &(), }); } #[inline(always)] fn is_locked(&self) -> bool { self.lock.load(Ordering::Relaxed) != 0 } } #[cfg(feature = "lock_api")] unsafe impl<R: RelaxStrategy> lock_api_crate::RawRwLockUpgrade for RwLock<(), R> { #[inline(always)] fn lock_upgradable(&self) { // Prevent guard destructor running core::mem::forget(self.upgradeable_read()); } #[inline(always)] fn try_lock_upgradable(&self) -> bool { // Prevent guard destructor running self.try_upgradeable_read().map(|g| core::mem::forget(g)).is_some() } #[inline(always)] unsafe fn unlock_upgradable(&self) { drop(RwLockUpgradableGuard { inner: self, data: &(), phantom: PhantomData, }); } #[inline(always)] unsafe fn upgrade(&self) { let tmp_guard = RwLockUpgradableGuard { inner: self, data: &(), phantom: PhantomData, }; core::mem::forget(tmp_guard.upgrade()); } #[inline(always)] unsafe fn try_upgrade(&self) -> bool { let tmp_guard = RwLockUpgradableGuard { inner: self, data: &(), phantom: PhantomData, }; tmp_guard.try_upgrade().map(|g| core::mem::forget(g)).is_ok() } } #[cfg(feature = "lock_api")] unsafe impl<R: RelaxStrategy> lock_api_crate::RawRwLockDowngrade for RwLock<(), R> { unsafe fn downgrade(&self) { let tmp_guard = RwLockWriteGuard { inner: self, data: &mut (), phantom: PhantomData, }; core::mem::forget(tmp_guard.downgrade()); } } #[cfg(feature = "lock_api1")] unsafe impl lock_api::RawRwLockUpgradeDowngrade for RwLock<()> { unsafe fn downgrade_upgradable(&self) { let tmp_guard = RwLockUpgradableGuard { inner: self, data: &(), phantom: PhantomData, }; core::mem::forget(tmp_guard.downgrade()); } unsafe fn downgrade_to_upgradable(&self) { let tmp_guard = RwLockWriteGuard { inner: self, data: &mut (), phantom: PhantomData, }; core::mem::forget(tmp_guard.downgrade_to_upgradeable()); } } #[cfg(test)] mod tests { use std::prelude::v1::*; use std::sync::atomic::{AtomicUsize, Ordering}; use std::sync::mpsc::channel; use std::sync::Arc; use std::thread; type RwLock<T> = super::RwLock<T>; #[derive(Eq, PartialEq, Debug)] struct NonCopy(i32); #[test] fn smoke() { let l = RwLock::new(()); drop(l.read()); drop(l.write()); drop((l.read(), l.read())); drop(l.write()); } // TODO: needs RNG //#[test] //fn frob() { // static R: RwLock = RwLock::new(); // const N: usize = 10; // const M: usize = 1000; // // let (tx, rx) = channel::<()>(); // for _ in 0..N { // let tx = tx.clone(); // thread::spawn(move|| { // let mut rng = rand::thread_rng(); // for _ in 0..M { // if rng.gen_weighted_bool(N) { // drop(R.write()); // } else { // drop(R.read()); // } // } // drop(tx); // }); // } // drop(tx); // let _ = rx.recv(); // unsafe { R.destroy(); } //} #[test] fn test_rw_arc() { let arc = Arc::new(RwLock::new(0)); let arc2 = arc.clone(); let (tx, rx) = channel(); thread::spawn(move || { let mut lock = arc2.write(); for _ in 0..10 { let tmp = *lock; *lock = -1; thread::yield_now(); *lock = tmp + 1; } tx.send(()).unwrap(); }); // Readers try to catch the writer in the act let mut children = Vec::new(); for _ in 0..5 { let arc3 = arc.clone(); children.push(thread::spawn(move || { let lock = arc3.read(); assert!(*lock >= 0); })); } // Wait for children to pass their asserts for r in children { assert!(r.join().is_ok()); } // Wait for writer to finish rx.recv().unwrap(); let lock = arc.read(); assert_eq!(*lock, 10); } #[test] fn test_rw_access_in_unwind() { let arc = Arc::new(RwLock::new(1)); let arc2 = arc.clone(); let _ = thread::spawn(move || -> () { struct Unwinder { i: Arc<RwLock<isize>>, } impl Drop for Unwinder { fn drop(&mut self) { let mut lock = self.i.write(); *lock += 1; } } let _u = Unwinder { i: arc2 }; panic!(); }) .join(); let lock = arc.read(); assert_eq!(*lock, 2); } #[test] fn test_rwlock_unsized() { let rw: &RwLock<[i32]> = &RwLock::new([1, 2, 3]); { let b = &mut *rw.write(); b[0] = 4; b[2] = 5; } let comp: &[i32] = &[4, 2, 5]; assert_eq!(&*rw.read(), comp); } #[test] fn test_rwlock_try_write() { use std::mem::drop; let lock = RwLock::new(0isize); let read_guard = lock.read(); let write_result = lock.try_write(); match write_result { None => (), Some(_) => assert!( false, "try_write should not succeed while read_guard is in scope" ), } drop(read_guard); } #[test] fn test_rw_try_read() { let m = RwLock::new(0); ::std::mem::forget(m.write()); assert!(m.try_read().is_none()); } #[test] fn test_into_inner() { let m = RwLock::new(NonCopy(10)); assert_eq!(m.into_inner(), NonCopy(10)); } #[test] fn test_into_inner_drop() { struct Foo(Arc<AtomicUsize>); impl Drop for Foo { fn drop(&mut self) { self.0.fetch_add(1, Ordering::SeqCst); } } let num_drops = Arc::new(AtomicUsize::new(0)); let m = RwLock::new(Foo(num_drops.clone())); assert_eq!(num_drops.load(Ordering::SeqCst), 0); { let _inner = m.into_inner(); assert_eq!(num_drops.load(Ordering::SeqCst), 0); } assert_eq!(num_drops.load(Ordering::SeqCst), 1); } #[test] fn test_force_read_decrement() { let m = RwLock::new(()); ::std::mem::forget(m.read()); ::std::mem::forget(m.read()); ::std::mem::forget(m.read()); assert!(m.try_write().is_none()); unsafe { m.force_read_decrement(); m.force_read_decrement(); } assert!(m.try_write().is_none()); unsafe { m.force_read_decrement(); } assert!(m.try_write().is_some()); } #[test] fn test_force_write_unlock() { let m = RwLock::new(()); ::std::mem::forget(m.write()); assert!(m.try_read().is_none()); unsafe { m.force_write_unlock(); } assert!(m.try_read().is_some()); } #[test] fn test_upgrade_downgrade() { let m = RwLock::new(()); { let _r = m.read(); let upg = m.try_upgradeable_read().unwrap(); assert!(m.try_read().is_none()); assert!(m.try_write().is_none()); assert!(upg.try_upgrade().is_err()); } { let w = m.write(); assert!(m.try_upgradeable_read().is_none()); let _r = w.downgrade(); assert!(m.try_upgradeable_read().is_some()); assert!(m.try_read().is_some()); assert!(m.try_write().is_none()); } { let _u = m.upgradeable_read(); assert!(m.try_upgradeable_read().is_none()); } assert!(m.try_upgradeable_read().unwrap().try_upgrade().is_ok()); } }