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If I call std::make_shared<T> (rather than just allocating a shared_ptr<T> explicitly) then I expect the reference count to be allocated in memory alongside the instance of T, for performance reasons. All well and good.

But if I have weak_ptr instances referencing the same object, presumably they will need access to that reference count, to know whether the object still exists.

So, when the last shared_ptr to the instance of T is destroyed, a naive understanding of the system would imply that it cannot deallocate the memory that T is stored in, because weak_ptrs still require access to that count.

It seems like there is a separate weak reference counter and in theory that could be held separately from the instance of T, so that the T can be destroyed and the memory deallocated while weak references still exist. But then we're back to having 2 separate allocations, thwarting the benefits of make_shared.

I assume I am misunderstanding something here. How can the memory allocated for a instance constructed via std::make_shared be freed when weak references exist?

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That's the answer I link to above! It doesn't address the make_shared aspect. –  Kylotan Nov 23 '12 at 21:23
    
What benefits are thwarted by having two allocations? –  Vaughn Cato Nov 23 '12 at 21:25
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Memory fragmentation is one, cache locality is a second (related to the first), speed of allocation is another, speed of deallocaton may be a fourth. –  Kylotan Nov 23 '12 at 21:26
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This answer covers it. –  Joseph Mansfield Nov 23 '12 at 21:28
    
I see, you are talking about the benefit of using shared_ptr<T> p = make_shared<T>() over shared_ptr<T> p(new T). That wasn't clear to me initially. –  Vaughn Cato Nov 23 '12 at 21:42

2 Answers 2

up vote 10 down vote accepted

If you use make_shared and if the implementation uses a single allocation for both the object and the reference counts, then that allocation cannot be freed until all references (both strong and weak) have been released.

However, the object will be destroyed after all strong references have been released (regardless of whether there are still weak references).

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@Kylotan: Not by any definition of "memory leak" that I've ever heard. A memory leak is when memory remains allocated which you no longer have access to, because you've lost all references to it. But if you lose the last weak_ptr, the memory is reclaimed, it is no longer allocated. –  Benjamin Lindley Nov 23 '12 at 21:30
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In theory, a free store could have the ability to accept a "partial return" of memory. Sort of like shrinking reaclloc. In practice? Probably not. –  Yakk Nov 23 '12 at 21:30
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Doesn't this kind of defeat the purpose of weak pointers though. The crux of a weak pointer, compared to a strong pointer, is that the strong pointer delays the release of the object. Keeping a weak pointer to an object is supposed to be very cheap, but if it can make the entire object stick in memory, it's quite expensive. –  David Schwartz Nov 23 '12 at 21:39
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There are two reasons it's not usually as big a deal as people might think. First, for most large objects, their size is not due to their initial allocation but things later attached to them. (For example, in a map, list or vector). These will be freed by the invocation of the object's destructor, so they won't hang around. Second, many weak pointer implementations expect the weak pointer to avoid delaying the destruction of the object indefinitely. So long as the weak pointer itself is destroyed relatively soon after the object goes away, the extra memory usage will be brief. –  David Schwartz Nov 23 '12 at 23:45
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Most importantly of all... you could simply not use make_shared. The point of make_shared (in terms of optimization) is that you're making a choice. You want a single allocation instead of two. That choice has consequences: if you have weak references, then the single allocation won't get cleaned up until all weak references are gone. If you don't want that consequence, then don't use make_shared. –  Nicol Bolas Nov 24 '12 at 0:07

The common implementation is for the ref control block of an std::shared_ptr to contain both a strong and a weak reference count separately. The managed object is destroyed when the strong reference count goes to zero, but the ref control block itself is only released when the weak reference count also reaches zero.

(When you use std::make_shared, the ref control block itself contains enough memory to hold the managed object. This is just a detail.)

In other words, the observable behaviour for the managed object is independent of weak pointers.

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Does that apply when make_shared is used? I was under the impression that the typical implementation (perhaps not mandated by the standard) is to allocate the ref control block and the object itself contiguously. –  Kylotan Nov 23 '12 at 21:58
    
@Kylotan: Yes, those details have no relevance. The managed object will be in-place constructed and destroyed in the larger memory block. –  Kerrek SB Nov 23 '12 at 22:31
    
Maybe I wasn't clear, but I'm not actually interested in the object's behaviour, but the lifetime of the allocated memory it lives in. The answer above implies this is dependent on weak refs in the make_shared case and not dependent on weak refs if I create a shared_ptr explicitly. –  Kylotan Nov 23 '12 at 22:50
    
@Kylotan: The memory lives until all the weak pointers are gone, but the managed object only lives until all the strong references are gone. Is that not clear? I can spell out a code example if you like. –  Kerrek SB Nov 23 '12 at 22:52
    
That's clear - I was just unsure if you were contradicting the other answer or not. –  Kylotan Nov 23 '12 at 22:55

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