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Difference between revisions of "cpp/thread/promise"

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@3@ void specialization, used to communicate stateless events
 
@3@ void specialization, used to communicate stateless events
  
The class template {{tt|std::promise}} provides a facility to store a value or an exception that is later acquired asynchronously via a {{lc|std::future}} object created by the {{tt|std::promise}} object. Note that {{tt|std::promise}} object is meant to be used only once.
+
The class template {{tt|std::promise}} provides a facility to store a value or an exception that is later acquired asynchronously via a {{lc|std::future}} object created by the {{tt|std::promise}} object. Note that the {{tt|std::promise}} object is meant to be used only once.
  
 
Each promise is associated with a ''shared state'', which contains some state information and a ''result'' which may be not yet evaluated, evaluated to a value (possibly void) or evaluated to an exception. A promise may do three things with the shared state:
 
Each promise is associated with a ''shared state'', which contains some state information and a ''result'' which may be not yet evaluated, evaluated to a value (possibly void) or evaluated to an exception. A promise may do three things with the shared state:

Revision as of 00:27, 1 July 2018

 
 
Concurrency support library
Threads
(C++11)
(C++20)
this_thread namespace
(C++11)
(C++11)
(C++11)
Cooperative cancellation
Mutual exclusion
(C++11)
Generic lock management
(C++11)
(C++11)
(C++11)
(C++11)
(C++11)
Condition variables
(C++11)
Semaphores
Latches and Barriers
(C++20)
(C++20)
Futures
promise
(C++11)
(C++11)
(C++11)
(C++11)
Safe Reclamation
(C++26)
Hazard Pointers
Atomic types
(C++11)
(C++20)
Initialization of atomic types
(C++11)(deprecated in C++20)
(C++11)(deprecated in C++20)
Memory ordering
Free functions for atomic operations
Free functions for atomic flags
 
 
Defined in header <future>
template< class R > class promise;
(1) (since C++11)
template< class R > class promise<R&>;
(2) (since C++11)
template<>          class promise<void>;
(3) (since C++11)
1) base template
2) non-void specialization, used to communicate objects between threads
3) void specialization, used to communicate stateless events

The class template std::promise provides a facility to store a value or an exception that is later acquired asynchronously via a std::future object created by the std::promise object. Note that the std::promise object is meant to be used only once.

Each promise is associated with a shared state, which contains some state information and a result which may be not yet evaluated, evaluated to a value (possibly void) or evaluated to an exception. A promise may do three things with the shared state:

  • make ready: the promise stores the result or the exception in the shared state. Marks the state ready and unblocks any thread waiting on a future associated with the shared state.
  • release: the promise gives up its reference to the shared state. If this was the last such reference, the shared state is destroyed. Unless this was a shared state created by std::async which is not yet ready, this operation does not block.
  • abandon: the promise stores the exception of type std::future_error with error code std::future_errc::broken_promise, makes the shared state ready, and then releases it.

The promise is the "push" end of the promise-future communication channel: the operation that stores a value in the shared state synchronizes-with (as defined in std::memory_order) the successful return from any function that is waiting on the shared state (such as std::future::get). Concurrent access to the same shared state may conflict otherwise: for example multiple callers of std::shared_future::get must either all be read-only or provide external synchronization.

Contents

Member functions

constructs the promise object
(public member function) [edit]
destructs the promise object
(public member function) [edit]
assigns the shared state
(public member function) [edit]
swaps two promise objects
(public member function) [edit]
Getting the result
returns a future associated with the promised result
(public member function) [edit]
Setting the result
sets the result to specific value
(public member function) [edit]
sets the result to specific value while delivering the notification only at thread exit
(public member function) [edit]
sets the result to indicate an exception
(public member function) [edit]
sets the result to indicate an exception while delivering the notification only at thread exit
(public member function) [edit]

Non-member functions

specializes the std::swap algorithm
(function template) [edit]

Helper classes

specializes the std::uses_allocator type trait
(class template specialization) [edit]

Example

This example shows how promise<int> can be used as signals between threads.

#include <vector>
#include <thread>
#include <future>
#include <numeric>
#include <iostream>
#include <chrono>
 
void accumulate(std::vector<int>::iterator first,
                std::vector<int>::iterator last,
                std::promise<int> accumulate_promise)
{
    int sum = std::accumulate(first, last, 0);
    accumulate_promise.set_value(sum);  // Notify future
}
 
void do_work(std::promise<void> barrier)
{
    std::this_thread::sleep_for(std::chrono::seconds(1));
    barrier.set_value();
}
 
int main()
{
    // Demonstrate using promise<int> to transmit a result between threads.
    std::vector<int> numbers = { 1, 2, 3, 4, 5, 6 };
    std::promise<int> accumulate_promise;
    std::future<int> accumulate_future = accumulate_promise.get_future();
    std::thread work_thread(accumulate, numbers.begin(), numbers.end(),
                            std::move(accumulate_promise));
    accumulate_future.wait();  // wait for result
    std::cout << "result=" << accumulate_future.get() << '\n';
    work_thread.join();  // wait for thread completion
 
    // Demonstrate using promise<void> to signal state between threads.
    std::promise<void> barrier;
    std::future<void> barrier_future = barrier.get_future();
    std::thread new_work_thread(do_work, std::move(barrier));
    barrier_future.wait();
    new_work_thread.join();
}

Output:

result=21