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Are the following operations lockfree for std::unique_ptr and/or std::shared_ptr?

  1. Dereferencing, i.e. read(*myPtr) or myPtr->getSomething()
  2. Removing a reference, i.e. with std::move(myUniquePtr) or when a std::shared_ptr goes out of scope.

In my case, I am not concurrently accessing these pointers from multiple threads. I'm just curious if I can use them exclusively on a high-priority, lockfree thread. The objects managed by the pointers were allocated by the main thread prior to the high-priority callbacks and will not be deallocated until the callbacks cease.

Thanks!

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Note that move and going out of scooe are very different. move never changes the reference count. –  Yakk Apr 8 '14 at 4:07
    
@bryanchen those are for multiple threads one variable, which is not what the OP is talking about methinks. –  Yakk Apr 8 '14 at 4:08
    
@Yakk doesn't move remove the reference from a source unique_ptr and add it to a destination unique_ptr? I've seen std::remove_reference in errors related to moving a unique_ptr. –  mxdubois Apr 8 '14 at 4:13
    
@mxdubois sure, bit unique_ptr has no need to ever lock: it has no significant contention. For shared, you can move the reference to the dest without doing a +1 -1 mess... without messimg with the control block comtents of the source at all! The dest admittedly needs a .reset() of non-empty, so there is that. –  Yakk Apr 8 '14 at 4:30

2 Answers 2

up vote 2 down vote accepted

All that the standard says is that for shared_ptr<> (20.7.2.2/4 "Class template shared_ptr"):

Changes in use_count() do not reflect modifications that can introduce data races

It doesn't say that those changes in use_count() have to be lock free. The standard permits a mutex to be used to prevent the data race.

unique_ptr<> has no promises to prevent data races (it's not intended to be thread safe on it's own).

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In practice, however... about the only one with any reason to lock is 'going out of scope'. –  Yakk Apr 8 '14 at 3:58
    
So unique_ptr is not guaranteed to be lockfree? –  mxdubois Apr 8 '14 at 3:59
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@mxdubois: I don't think there's any reason for the unique_ptr implementation to introduce a lock for dereferencing, but I'm not sure the standard forbids it. Similarly for the move operation. –  Michael Burr Apr 8 '14 at 4:07
    
It isn't guaranteed to be lockfree, but there's no reason to use an implementation that synchronises at all. –  R. Martinho Fernandes Apr 8 '14 at 8:40

With a reasonable implementation, you can assume:

std::unique_ptr:

  • All operations on a std::unique_ptr are as lock-free as the corresponding operations on a raw pointer, because there is nothing special regarding concurrency.

std::shared_ptr:

  • All operations, that do not change the reference count, are as lock-free as the corresponding operations on a raw pointer. That includes the operations dereferencing and move construction.
  • std::move is lock-free, because it is only a cast to an rvalue-reference.
  • The destructor of a std::shared_ptr is at least as lock-free as std::atomic<std::size_t> (can be checked with the member function is_lock_free).
  • Move assignment depends on whether the std::shared_ptr on the left side has an associated managed object or not. If there is an associated managed object, it is as lock-free as the destructor. Otherwise it is as lock-free as a move constructor, because the reference count is not changed.
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I'm going to accept Burr's answer because I was mostly looking for what was guaranteed, but thanks for the extra info! –  mxdubois Apr 8 '14 at 20:52

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