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One way to get a std::future is through std::async:

int foo()
{
  return 42;
}

...

std::future<int> x = std::async(foo);

In this example, how is the storage for x's asynchronous state allocated, and which thread (if more than one thread is involved) is responsible for performing the allocation? Moreover, does a client of std::async have any control over the allocation?

For context, I see that one of the constructors of std::promise may receive an allocator, but it's not clear to me if it is possible to customize the allocation of the std::future at the level of std::async.

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2 Answers 2

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Just judging from the mere arguments of std::async there seems to be no way to control the allocation of the internal std::promise and it can therefore just use anything, though likely the std::allocator. Though I guess in theory it is unspecified, it is likely the shared state is allocated inside the calling thread. I haven't found any explicit information in the standard about this matter. In the end std::async is a very specialized facility for easy asynchronous invocation, so you don't have to think if there actually is a std::promise anywhere.

For more direct control about the behaviour of an asynchronous call there is also std::packaged_task, which indeed has an allocator argument. But from the mere standard quote it is not perfectly clear if this allocator is just used to allocate storage for the function (since std::packaged_task is kind of a special std::function) or if it is also used to allocate the shared state of the internal std::promise, though it seems likely:

30.6.9.1 [futures.task.members]:

Effects: constructs a new packaged_task object with a shared state and initializes the object’s stored task with std::forward<F>(f). The constructors that take an Allocator argument use it to allocate memory needed to store the internal data structures.

Well, it doesn't even say there is a std::promise underneath (likewise for std::async), it could just be an undefined type connectable to a std::future.

So if it is indeed not specified how std::packaged_task allocates its internal shared state, your best bet might be to implement your own facilities for asynchronous function invocation. Considering that, simply spoken, a std::packaged_task is just a std::function bundled with a std::promise and std::async just starts a std::packaged_task in a new thread (well, except when it doesn't), this shouldn't be too much of a problem.

But indeed this might be an oversight in the specification. Whereas allocation control doesn't really fit to std::async, the explanation of std::packaged_task and its use of allocators might be a bit clearer. But this may also be intentional, so the std::packaged_task is free to use whatever it wants and doesn't even need a std::promise internally.

EDIT: Reading it again, I think the above standard quote indeed says, that the std::packaged_task's shared state is allocated using the provided allocator, since it is part of the "internal data structures", whatever those are (there doesn't need to be an actual std::promise, though). So I think std::packaged_task should be enough for having explicit control of the shared state of an asynchronous task's std::future.

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The memory is allocated by the thread that calls std::async, and you have no control over how it is done. Typically it will be done by some variant of new __internal_state_type, but there is no guarantee; it may use malloc, or an allocator specifically chosen for the purpose.

From 30.6.8p3 [futures.async]:

"Effects: The first function behaves the same as a call to the second function with a policy argument of launch::async | launch::deferred and the same arguments for F and Args. The second function creates a shared state that is associated with the returned future object. ..."

The "first function" is the overload without a launch policy, whilst the second is the overload with a launch policy.

In the case of std::launch::deferred, there is no other thread, so everything must happen on the calling thread. In the case of std::launch::async, 30.6.8p3 goes on to say:

— if policy & launch::async is non-zero — calls INVOKE (DECAY_COPY (std::forward<F>(f)), DECAY_COPY (std::forward<Args>(args))...) (20.8.2, 30.3.1.2) as if in a new thread of execution represented by a thread object with the calls to DECAY_COPY () being evaluated in the thread that called async. ...

I've added the emphasis. Since the copy of the function and arguments has to happen in the calling thread, this essentially requires that the shared state is allocated by the calling thread.

Of course, you could write an implementation that started the new thread, waited for it to allocate the state, and then returned a future that referenced that, but why would you?

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Where is it guaranteed that the calling thread allocates the storage? Ok, it is pretty likely, but I'd still like to see a quote from the standard. –  Christian Rau Oct 11 '12 at 8:10
    
Updated answer with more details. –  Anthony Williams Oct 11 '12 at 9:06
    
Indeed, it seems pretty clear, I overlooked that. But pointing this out in your answer like you do now can't do any harm. Thanks and +1. –  Christian Rau Oct 11 '12 at 9:24
    
@AnthonyWilliams One reason that a user might care about which thread allocated the storage is for locality. If the thread created by std::async executes on a core with faster access to a particular region of memory, then it makes sense to locate the asynchronous state in that region. –  Jared Hoberock Oct 11 '12 at 17:28

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