std::condition_variable_any::wait_for
template< class Lock, class Rep, class Period > std::cv_status wait_for( Lock& lock, |
(1) | (since C++11) |
template< class Lock, class Rep, class Period, class Predicate > bool wait_for( Lock& lock, |
(2) | (since C++11) |
lock
, blocks the current executing thread, and adds it to the list of threads waiting on *this. The thread will be unblocked when notify_all() or notify_one() is executed, or when the relative timeout rel_time
expires. It may also be unblocked spuriously. When unblocked, regardless of the reason, lock
is reacquired and wait_for()
exits. If this function exits via exception, lock
is also reacquired. (until C++14)A steady clock is used to measure the duration. This function may block for longer than timeout_duration
due to scheduling or resource contention delays.
If these functions fail to meet the postcondition (lock is locked by the calling thread), std::terminate is called. For example, this could happen if relocking the mutex throws an exception, | (since C++14) |
Parameters
lock | - | an object of type Lock that meets the BasicLockable requirements, which must be locked by the current thread
|
rel_time | - | an object of type std::chrono::duration representing the maximum time to spend waiting. Note that rel_time must be small enough not to overflow when added to std::chrono::steady_clock::now(). |
pred | - | predicate which returns false if the waiting should be continued. The signature of the predicate function should be equivalent to the following: bool pred(); |
Return value
rel_time
expired, std::cv_status::no_timeout otherwise.pred
still evaluates to false after the rel_time
timeout expired, otherwise true.Exceptions
May throw std::system_error, may also propagate exceptions thrown by lock.lock() or lock.unlock(). |
(until C++14) |
Any exception thrown by clock, time_point, or duration during the execution (clocks, time points, and durations provided by the standard library never throw) |
(since C++14) |
pred
Notes
Even if notified under lock, overload (1) makes no guarantees about the state of the associated predicate when returning due to timeout.
The effects of notify_one()
/notify_all()
and each of the three atomic parts of wait()
/wait_for()
/wait_until()
(unlock+wait, wakeup, and lock) take place in a single total order that can be viewed as modification order of an atomic variable: the order is specific to this individual condition_variable. This makes it impossible for notify_one()
to, for example, be delayed and unblock a thread that started waiting just after the call to notify_one()
was made.
Example
#include <iostream> #include <atomic> #include <condition_variable> #include <thread> #include <chrono> using namespace std::chrono_literals; std::condition_variable_any cv; std::mutex cv_m; int i; void waits(int idx) { std::unique_lock<std::mutex> lk(cv_m); if(cv.wait_for(lk, idx*100ms, []{return i == 1;})) std::cerr << "Thread " << idx << " finished waiting. i == " << i << '\n'; else std::cerr << "Thread " << idx << " timed out. i == " << i << '\n'; } void signals() { std::this_thread::sleep_for(120ms); std::cerr << "Notifying...\n"; cv.notify_all(); std::this_thread::sleep_for(100ms); { std::lock_guard<std::mutex> lk(cv_m); i = 1; } std::cerr << "Notifying again...\n"; cv.notify_all(); } int main() { std::thread t1(waits, 1), t2(waits, 2), t3(waits, 3), t4(signals); t1.join(); t2.join(); t3.join(); t4.join(); }
Output:
Thread 1 timed out. i == 0 Notifying... Thread 2 timed out. i == 0 Notifying again... Thread 3 finished waiting. i == 1
See also
blocks the current thread until the condition variable is woken up (public member function) | |
blocks the current thread until the condition variable is woken up or until specified time point has been reached (public member function) |