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I have a std::vector<...> that is shared in two threads.

Both of them make calls to vec->size();

Can this be a source of race conditions? I'm hoping not since vec->size() is const.

Thanks!

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    FYI: The size() on gcc 4.2 on Mac OS X is implemented as size_type size() const { return size_type(this->_M_impl._M_finish - this->_M_impl._M_start); }.
    – kennytm
    Mar 4, 2010 at 8:16
  • Where did you find this? Enlighten me.
    – anon
    Mar 4, 2010 at 8:17
  • Standard headers are under "/usr/include/c++/*", start from the one you actually include '<vector>' and keep reading the included files until you find what you look for '<bits/stl_vector.h>' is a common header for g++ to store the actual vector implementation (with '<bits/stl_bvector.h>' being the 'bool' specialization, and some other headers used for utility functions) Mar 4, 2010 at 8:34

2 Answers 2

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If you are calling ONLY vec->size() you are safe. But this is somehow difficult to believe. As soon you call any changing method, such as push_back a race can cause to get the wrong size.

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    Not so hard to believe since... I suppose someone can check the vector.size() and if is not empty, then can do a mutex lock/unlock.
    – Vassilis
    Nov 4, 2018 at 16:59
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Probably not. The problem isn't really in vec->size(), it's in all the other functions as well.

Consider this: vector::size() is typically calculated directly from members, e.g. .end - .begin. Now what happens with a push_back on one thread? It affects the size, obviously, via the members. It changes memory. But there is no memory barrier. Other threads on other cores will simply see the old memory. As a result, when they call size(), it will be calculated using the old values.

An obvious exception is when the vector doesn't change size after the creation of the threads. The threads will never have outdated information.

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  • I completely agree with this. When you are writing multi-threaded code you should aim to make your operations atomic. Even if this operation on its own is safe; if you are using mutexs or critical sections for other operations you must use them for this too. If you are worried about performance use a readers writer lock to enable multiple readers to size() but only a singe writer.
    – iain
    Mar 4, 2010 at 12:06
  • Actually size() doesn't access the members. It can't crash and the worse thing that can happen is an outdated result. See my answer. In some cases it's ok to have an outdated value, like for displaying a progress bar representing the size of a container to a user. It's fine because you don't want to iterate on the container anyway and if the value is outdated, it will be correct on the next refresh of the display.
    – Aurelien
    Mar 28, 2013 at 15:42
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    @Aurelien: What you are claiming directly contradicts the first comment from KennyTM, which clearly shows that gcc 4.2 accesses the _M_finish and _M_start members. That can produce a negative size if another thread changes reallocates the vector, and you subtract the old _M_start from the new _M_finish. Cast that negative result back to size_type and you have a value that is nonsensically big. And yes, drawing a progress bar 4 billion pixels wide may cause some troubles.
    – MSalters
    Mar 29, 2013 at 7:46
  • Yes, you are right. I obviously misunderstood that sentence in the documentation: "No contained elements are accessed: concurrently accessing or modifying them is safe." It probably only means that size() is thread-safe against a concurrent modification of the elements already in the container. It doesn't mean that it is thread-safe against modifying the amount of elements. Thanks, I'll remove my answer.
    – Aurelien
    Mar 29, 2013 at 17:47

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