// Copyright 2014 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. use prelude::v1::*; use sync::atomic::{AtomicUsize, Ordering, ATOMIC_USIZE_INIT}; use sync::{mutex, MutexGuard, PoisonError}; use sys_common::condvar as sys; use sys_common::mutex as sys_mutex; use sys_common::poison::{self, LockResult}; use sys::time::SteadyTime; use time::Duration; /// A Condition Variable /// /// Condition variables represent the ability to block a thread such that it /// consumes no CPU time while waiting for an event to occur. Condition /// variables are typically associated with a boolean predicate (a condition) /// and a mutex. The predicate is always verified inside of the mutex before /// determining that thread must block. /// /// Functions in this module will block the current **thread** of execution and /// are bindings to system-provided condition variables where possible. Note /// that this module places one additional restriction over the system condition /// variables: each condvar can be used with precisely one mutex at runtime. Any /// attempt to use multiple mutexes on the same condition variable will result /// in a runtime panic. If this is not desired, then the unsafe primitives in /// `sys` do not have this restriction but may result in undefined behavior. /// /// # Examples /// /// ``` /// use std::sync::{Arc, Mutex, Condvar}; /// use std::thread; /// /// let pair = Arc::new((Mutex::new(false), Condvar::new())); /// let pair2 = pair.clone(); /// /// // Inside of our lock, spawn a new thread, and then wait for it to start /// thread::spawn(move|| { /// let &(ref lock, ref cvar) = &*pair2; /// let mut started = lock.lock().unwrap(); /// *started = true; /// cvar.notify_one(); /// }); /// /// // wait for the thread to start up /// let &(ref lock, ref cvar) = &*pair; /// let mut started = lock.lock().unwrap(); /// while !*started { /// started = cvar.wait(started).unwrap(); /// } /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub struct Condvar { inner: Box } /// Statically allocated condition variables. /// /// This structure is identical to `Condvar` except that it is suitable for use /// in static initializers for other structures. /// /// # Examples /// /// ``` /// # #![feature(static_condvar)] /// use std::sync::{StaticCondvar, CONDVAR_INIT}; /// /// static CVAR: StaticCondvar = CONDVAR_INIT; /// ``` #[unstable(feature = "static_condvar", reason = "may be merged with Condvar in the future")] pub struct StaticCondvar { inner: sys::Condvar, mutex: AtomicUsize, } /// Constant initializer for a statically allocated condition variable. #[unstable(feature = "static_condvar", reason = "may be merged with Condvar in the future")] pub const CONDVAR_INIT: StaticCondvar = StaticCondvar { inner: sys::CONDVAR_INIT, mutex: ATOMIC_USIZE_INIT, }; impl Condvar { /// Creates a new condition variable which is ready to be waited on and /// notified. #[stable(feature = "rust1", since = "1.0.0")] pub fn new() -> Condvar { Condvar { inner: box StaticCondvar { inner: unsafe { sys::Condvar::new() }, mutex: AtomicUsize::new(0), } } } /// Blocks the current thread until this condition variable receives a /// notification. /// /// This function will atomically unlock the mutex specified (represented by /// `mutex_guard`) and block the current thread. This means that any calls /// to `notify_*()` which happen logically after the mutex is unlocked are /// candidates to wake this thread up. When this function call returns, the /// lock specified will have been re-acquired. /// /// Note that this function is susceptible to spurious wakeups. Condition /// variables normally have a boolean predicate associated with them, and /// the predicate must always be checked each time this function returns to /// protect against spurious wakeups. /// /// # Failure /// /// This function will return an error if the mutex being waited on is /// poisoned when this thread re-acquires the lock. For more information, /// see information about poisoning on the Mutex type. /// /// # Panics /// /// This function will `panic!()` if it is used with more than one mutex /// over time. Each condition variable is dynamically bound to exactly one /// mutex to ensure defined behavior across platforms. If this functionality /// is not desired, then unsafe primitives in `sys` are provided. #[stable(feature = "rust1", since = "1.0.0")] pub fn wait<'a, T>(&self, guard: MutexGuard<'a, T>) -> LockResult> { unsafe { let me: &'static Condvar = &*(self as *const _); me.inner.wait(guard) } } /// Waits on this condition variable for a notification, timing out after a /// specified duration. /// /// The semantics of this function are equivalent to `wait()` /// except that the thread will be blocked for roughly no longer /// than `ms` milliseconds. This method should not be used for /// precise timing due to anomalies such as preemption or platform /// differences that may not cause the maximum amount of time /// waited to be precisely `ms`. /// /// The returned boolean is `false` only if the timeout is known /// to have elapsed. /// /// Like `wait`, the lock specified will be re-acquired when this function /// returns, regardless of whether the timeout elapsed or not. #[stable(feature = "rust1", since = "1.0.0")] pub fn wait_timeout_ms<'a, T>(&self, guard: MutexGuard<'a, T>, ms: u32) -> LockResult<(MutexGuard<'a, T>, bool)> { unsafe { let me: &'static Condvar = &*(self as *const _); me.inner.wait_timeout_ms(guard, ms) } } /// Waits on this condition variable for a notification, timing out after a /// specified duration. /// /// The semantics of this function are equivalent to `wait()` except that /// the thread will be blocked for roughly no longer than `dur`. This /// method should not be used for precise timing due to anomalies such as /// preemption or platform differences that may not cause the maximum /// amount of time waited to be precisely `dur`. /// /// The returned boolean is `false` only if the timeout is known /// to have elapsed. /// /// Like `wait`, the lock specified will be re-acquired when this function /// returns, regardless of whether the timeout elapsed or not. #[unstable(feature = "wait_timeout", reason = "waiting for Duration")] pub fn wait_timeout<'a, T>(&self, guard: MutexGuard<'a, T>, dur: Duration) -> LockResult<(MutexGuard<'a, T>, bool)> { unsafe { let me: &'static Condvar = &*(self as *const _); me.inner.wait_timeout(guard, dur) } } /// Waits on this condition variable for a notification, timing out after a /// specified duration. /// /// The semantics of this function are equivalent to `wait_timeout` except /// that the implementation will repeatedly wait while the duration has not /// passed and the provided function returns `false`. #[unstable(feature = "wait_timeout_with", reason = "unsure if this API is broadly needed or what form it should take")] pub fn wait_timeout_with<'a, T, F>(&self, guard: MutexGuard<'a, T>, dur: Duration, f: F) -> LockResult<(MutexGuard<'a, T>, bool)> where F: FnMut(LockResult<&mut T>) -> bool { unsafe { let me: &'static Condvar = &*(self as *const _); me.inner.wait_timeout_with(guard, dur, f) } } /// Wakes up one blocked thread on this condvar. /// /// If there is a blocked thread on this condition variable, then it will /// be woken up from its call to `wait` or `wait_timeout`. Calls to /// `notify_one` are not buffered in any way. /// /// To wake up all threads, see `notify_all()`. #[stable(feature = "rust1", since = "1.0.0")] pub fn notify_one(&self) { unsafe { self.inner.inner.notify_one() } } /// Wakes up all blocked threads on this condvar. /// /// This method will ensure that any current waiters on the condition /// variable are awoken. Calls to `notify_all()` are not buffered in any /// way. /// /// To wake up only one thread, see `notify_one()`. #[stable(feature = "rust1", since = "1.0.0")] pub fn notify_all(&self) { unsafe { self.inner.inner.notify_all() } } } #[stable(feature = "rust1", since = "1.0.0")] impl Drop for Condvar { fn drop(&mut self) { unsafe { self.inner.inner.destroy() } } } impl StaticCondvar { /// Blocks the current thread until this condition variable receives a /// notification. /// /// See `Condvar::wait`. #[unstable(feature = "static_condvar", reason = "may be merged with Condvar in the future")] pub fn wait<'a, T>(&'static self, guard: MutexGuard<'a, T>) -> LockResult> { let poisoned = unsafe { let lock = mutex::guard_lock(&guard); self.verify(lock); self.inner.wait(lock); mutex::guard_poison(&guard).get() }; if poisoned { Err(PoisonError::new(guard)) } else { Ok(guard) } } /// Waits on this condition variable for a notification, timing out after a /// specified duration. /// /// See `Condvar::wait_timeout`. #[unstable(feature = "static_condvar", reason = "may be merged with Condvar in the future")] pub fn wait_timeout_ms<'a, T>(&'static self, guard: MutexGuard<'a, T>, ms: u32) -> LockResult<(MutexGuard<'a, T>, bool)> { self.wait_timeout(guard, Duration::from_millis(ms as u64)) } /// Waits on this condition variable for a notification, timing out after a /// specified duration. /// /// See `Condvar::wait_timeout`. #[unstable(feature = "static_condvar", reason = "may be merged with Condvar in the future")] pub fn wait_timeout<'a, T>(&'static self, guard: MutexGuard<'a, T>, timeout: Duration) -> LockResult<(MutexGuard<'a, T>, bool)> { let (poisoned, success) = unsafe { let lock = mutex::guard_lock(&guard); self.verify(lock); let success = self.inner.wait_timeout(lock, timeout); (mutex::guard_poison(&guard).get(), success) }; if poisoned { Err(PoisonError::new((guard, success))) } else { Ok((guard, success)) } } /// Waits on this condition variable for a notification, timing out after a /// specified duration. /// /// The implementation will repeatedly wait while the duration has not /// passed and the function returns `false`. /// /// See `Condvar::wait_timeout_with`. #[unstable(feature = "static_condvar", reason = "may be merged with Condvar in the future")] pub fn wait_timeout_with<'a, T, F>(&'static self, guard: MutexGuard<'a, T>, dur: Duration, mut f: F) -> LockResult<(MutexGuard<'a, T>, bool)> where F: FnMut(LockResult<&mut T>) -> bool { // This could be made more efficient by pushing the implementation into // sys::condvar let start = SteadyTime::now(); let mut guard_result: LockResult> = Ok(guard); while !f(guard_result .as_mut() .map(|g| &mut **g) .map_err(|e| PoisonError::new(&mut **e.get_mut()))) { let now = SteadyTime::now(); let consumed = &now - &start; let guard = guard_result.unwrap_or_else(|e| e.into_inner()); let (new_guard_result, no_timeout) = if consumed > dur { (Ok(guard), false) } else { match self.wait_timeout(guard, dur - consumed) { Ok((new_guard, no_timeout)) => (Ok(new_guard), no_timeout), Err(err) => { let (new_guard, no_timeout) = err.into_inner(); (Err(PoisonError::new(new_guard)), no_timeout) } } }; guard_result = new_guard_result; if !no_timeout { let result = f(guard_result .as_mut() .map(|g| &mut **g) .map_err(|e| PoisonError::new(&mut **e.get_mut()))); return poison::map_result(guard_result, |g| (g, result)); } } poison::map_result(guard_result, |g| (g, true)) } /// Wakes up one blocked thread on this condvar. /// /// See `Condvar::notify_one`. #[unstable(feature = "static_condvar", reason = "may be merged with Condvar in the future")] pub fn notify_one(&'static self) { unsafe { self.inner.notify_one() } } /// Wakes up all blocked threads on this condvar. /// /// See `Condvar::notify_all`. #[unstable(feature = "static_condvar", reason = "may be merged with Condvar in the future")] pub fn notify_all(&'static self) { unsafe { self.inner.notify_all() } } /// Deallocates all resources associated with this static condvar. /// /// This method is unsafe to call as there is no guarantee that there are no /// active users of the condvar, and this also doesn't prevent any future /// users of the condvar. This method is required to be called to not leak /// memory on all platforms. #[unstable(feature = "static_condvar", reason = "may be merged with Condvar in the future")] pub unsafe fn destroy(&'static self) { self.inner.destroy() } fn verify(&self, mutex: &sys_mutex::Mutex) { let addr = mutex as *const _ as usize; match self.mutex.compare_and_swap(0, addr, Ordering::SeqCst) { // If we got out 0, then we have successfully bound the mutex to // this cvar. 0 => {} // If we get out a value that's the same as `addr`, then someone // already beat us to the punch. n if n == addr => {} // Anything else and we're using more than one mutex on this cvar, // which is currently disallowed. _ => panic!("attempted to use a condition variable with two \ mutexes"), } } } #[cfg(test)] mod tests { use prelude::v1::*; use super::{StaticCondvar, CONDVAR_INIT}; use sync::mpsc::channel; use sync::{StaticMutex, MUTEX_INIT, Condvar, Mutex, Arc}; use sync::atomic::{AtomicUsize, ATOMIC_USIZE_INIT, Ordering}; use thread; use time::Duration; use u32; #[test] fn smoke() { let c = Condvar::new(); c.notify_one(); c.notify_all(); } #[test] fn static_smoke() { static C: StaticCondvar = CONDVAR_INIT; C.notify_one(); C.notify_all(); unsafe { C.destroy(); } } #[test] fn notify_one() { static C: StaticCondvar = CONDVAR_INIT; static M: StaticMutex = MUTEX_INIT; let g = M.lock().unwrap(); let _t = thread::spawn(move|| { let _g = M.lock().unwrap(); C.notify_one(); }); let g = C.wait(g).unwrap(); drop(g); unsafe { C.destroy(); M.destroy(); } } #[test] fn notify_all() { const N: usize = 10; let data = Arc::new((Mutex::new(0), Condvar::new())); let (tx, rx) = channel(); for _ in 0..N { let data = data.clone(); let tx = tx.clone(); thread::spawn(move|| { let &(ref lock, ref cond) = &*data; let mut cnt = lock.lock().unwrap(); *cnt += 1; if *cnt == N { tx.send(()).unwrap(); } while *cnt != 0 { cnt = cond.wait(cnt).unwrap(); } tx.send(()).unwrap(); }); } drop(tx); let &(ref lock, ref cond) = &*data; rx.recv().unwrap(); let mut cnt = lock.lock().unwrap(); *cnt = 0; cond.notify_all(); drop(cnt); for _ in 0..N { rx.recv().unwrap(); } } #[test] fn wait_timeout_ms() { static C: StaticCondvar = CONDVAR_INIT; static M: StaticMutex = MUTEX_INIT; let g = M.lock().unwrap(); let (g, _no_timeout) = C.wait_timeout_ms(g, 1).unwrap(); // spurious wakeups mean this isn't necessarily true // assert!(!no_timeout); let _t = thread::spawn(move || { let _g = M.lock().unwrap(); C.notify_one(); }); let (g, no_timeout) = C.wait_timeout_ms(g, u32::MAX).unwrap(); assert!(no_timeout); drop(g); unsafe { C.destroy(); M.destroy(); } } #[test] fn wait_timeout_with() { static C: StaticCondvar = CONDVAR_INIT; static M: StaticMutex = MUTEX_INIT; static S: AtomicUsize = ATOMIC_USIZE_INIT; let g = M.lock().unwrap(); let (g, success) = C.wait_timeout_with(g, Duration::new(0, 1000), |_| { false }).unwrap(); assert!(!success); let (tx, rx) = channel(); let _t = thread::spawn(move || { rx.recv().unwrap(); let g = M.lock().unwrap(); S.store(1, Ordering::SeqCst); C.notify_one(); drop(g); rx.recv().unwrap(); let g = M.lock().unwrap(); S.store(2, Ordering::SeqCst); C.notify_one(); drop(g); rx.recv().unwrap(); let _g = M.lock().unwrap(); S.store(3, Ordering::SeqCst); C.notify_one(); }); let mut state = 0; let day = 24 * 60 * 60; let (_g, success) = C.wait_timeout_with(g, Duration::new(day, 0), |_| { assert_eq!(state, S.load(Ordering::SeqCst)); tx.send(()).unwrap(); state += 1; match state { 1|2 => false, _ => true, } }).unwrap(); assert!(success); } #[test] #[should_panic] fn two_mutexes() { static M1: StaticMutex = MUTEX_INIT; static M2: StaticMutex = MUTEX_INIT; static C: StaticCondvar = CONDVAR_INIT; let mut g = M1.lock().unwrap(); let _t = thread::spawn(move|| { let _g = M1.lock().unwrap(); C.notify_one(); }); g = C.wait(g).unwrap(); drop(g); let _ = C.wait(M2.lock().unwrap()).unwrap(); } }