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If we assume that std::shared_ptr stores a reference count (which I realize the standard does not require, but I am unaware of any implementations that don't), that reference count has a limited number of bits, and that means there is a maximum number of references that are supported. That leads to two questions:

  • What is this maximum value?
  • What happens if you try to exceed it (e.g., by copying a std::shared_ptr that refers to an object with the maximum reference count)? Note that std::shared_ptr's copy constructor is declared noexcept.

Does the standard shed any light on either of these questions? How about common implementations, e.g., gcc, MSVC, Boost?

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Answer to 2nd question should be "undefined behavior". –  iammilind Sep 13 '12 at 8:19
    
Possible answer to first: Implementation specific. Probably size_t or similar, which will be 32 or 64 bits depending on platform. –  Joachim Pileborg Sep 13 '12 at 8:21
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In practical terms, you will never hit a limit; you will run out of memory long before you overflow a ref counter. Are you actually facing this problem? –  tenfour Sep 13 '12 at 8:21
    
My implementation doesn't use a reference count. –  Simon Richter Sep 13 '12 at 9:51
    
How do you do implement it w/o a reference count? –  Nevin Sep 13 '12 at 14:26

4 Answers 4

up vote 18 down vote accepted

We can get some information from the shared_ptr::use_count() function. §20.7.2.2.5 says:

long use_count() const noexcept;

Returns: the number of shared_ptr objects, *this included, that share ownership with *this, or 0 when *this is empty.

[Note: use_count() is not necessarily efficient.—end note ]

At first sight the long return type seems to answer the first question. However the note seems to imply that shared_ptr is free to use any type of reference counting it wants to, including things like a list of references. If this were the case then theoretically there would be no maximum reference count (although there would certainly be a practical limit).

There is no other reference to limits on the number of references to the same object that I could find.

It's interesting to note that use_count is documented to both not throw and (obviously) to report the count correctly; unless the implementation does use a long member for the count I don't see how both of these can be theoretically guaranteed at all times.

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Nice analysis. Can you find any hints about the underlying reference counting done on the shared state held between promises and futures? –  KnowItAllWannabe Sep 13 '12 at 9:06
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Concerning your last statement, they can't, and the standard has a couple of passages which let the implementation off the hook. In particular, exceeding resource limits is undefined behavior, and the results of converting a different integral type to a long are implementation defined if the value doesn't fit. –  James Kanze Sep 13 '12 at 9:11
    
Visual Studio 2010 does indeed use a long for _Uses and _Weaks in their _Ref_count_base class used by shared_ptr. –  paxos1977 Sep 13 '12 at 16:41
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I wonder why it is long and not unsigned long. It doesn't seem possible at first glance to have a negative number of references. –  Kaz Dragon Sep 18 '12 at 11:12

I'm not sure what the standard suggests, but look at it practically:

The reference count is most likely some sort of std::size_t variable. This variable can hold values up to -1+2^32 in 32-Bit environments and up to -1+2^64 in 64-Bit environments.

Now Image what would have to happen for this variable to reach this value: you would need 2^32 or 2^64 shared_ptr instances. That's a lot. In fact, that's so many that all memory would be exhausted long before you reach this number, since a one shared_ptr is about 8/16 bytes large.

Therefor, you are very unlikely to be able to reach the limit of the reference count if the size of the refcount variable is large enough.

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You went from "most likely not" to "cannot" awfully quickly... –  tenfour Sep 13 '12 at 8:25
    
@tenfour That's right, and here is why: I do not know of an implementation that has a refcount smaller than std::size(). You're right, that doesn't mean it's prohibited by the standard, but in practical terms I think it answers the question. –  fat-lobyte Sep 13 '12 at 8:30
    
If you replace "cannot" with "are extremely unlikely to be able to", then I think everyone would be happy. –  Joris Timmermans Sep 13 '12 at 8:37
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@MadKeithV You're right, I edited the answer. –  fat-lobyte Sep 13 '12 at 8:41
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@fat-lobyte This is all valid for machines with flat addressing, but I've worked on segmented machines with 48 bit addresses and 23 bit size_t. (The processor in question was an 80386. Hardly an exotic.) If the machine has flat addressing, then you can safely say "cannot". If it doesn't, I'm not even sure you can say "extremely unlikely". –  James Kanze Sep 13 '12 at 9:07

The standard doesn't say; as you say, it doesn't even require reference counting. On the other hand, there is (or was) a statement in the standard (or at least in the C standard) that exceeding implementation limits is undefined behavior. So that's almost certainly the official answer.

In practice, I would expect most implementations to maintain the count as a size_t or a ptrdiff_t. On machines with flat addressing, this pretty much means that you cannot create enough references to cause an overflow. (On such machines, a single object could occupy all of the memory, and size_t or ptrdiff_t have the same size as a pointer. Since every reference counted pointer has a distinct address, there can never be more than would fit in a pointer.) On machines with segmented architectures, however, overflow is quite conceivable.

As Jon points out, the standard also requires std::shared_ptr::use_count() to return a long. I'm not sure what the rationale is here: either size_t or ptrdiff_t would make more sense here. But if the implementation uses a different type for the reference count, presumably, the rules for conversion to long would apply: "the value is unchanged if it can be represented in the destination type (and bit-field width); otherwise, the value is implementation-defined." (The C standard makes this somewhat clearer: the "implementation-defined value" can be a signal.)

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You can find out what will happen by instantiating shared pointers using placement new and never deleting them. You can then hit the 32-bit limit easily.

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