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I've read that std::owner_less performs "owner-based rather than value-based" ordering, that two smart pointers are equivalent if they "point to subobjects of the same object" - what does that exactly mean?

As a test case, I have written the following code:

struct T {};

int main() {
    T* t = new T();

    std::shared_ptr<T> a(t);
    std::shared_ptr<T> b(t);

    std::set<std::shared_ptr<T>> set1;
    set1.insert(a);
    std::cout << set1.size() << std::endl;
    set1.insert(b);
    std::cout << set1.size() << std::endl;

    std::set<std::shared_ptr<T>, std::owner_less<std::shared_ptr<T>>> set2;
    set2.insert(a);
    std::cout << set2.size() << std::endl;
    set2.insert(b);
    std::cout << set2.size() << std::endl;
}

And the output is 1 1 1 2. It seems to me that if std::owner_less performs "owner-based" comparison, shouldn't it consider a and b to be the same, while the default comparator treats them as different? The result of my code seems to be saying just the opposite though.

  • If your intent was that both a and b should share ownership of the object t, then you must create b using the copy constructor of shared_ptr to share ownership with a as in std::shared_ptr<T> b(a). Constructing a shared_ptr from a raw pointer always creates a new owner with a reference count of one. – Julien Villemure-Fréchette Nov 8 '18 at 23:13
  • std::shared_ptr::owner_before provides example similar to what you want IMO. – Jarod42 Nov 8 '18 at 23:28
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std::shared_ptr<T> a(t);
std::shared_ptr<T> b(t);

This is undefined behavior when the shared_ptrs are destroyed; the two shared_ptrs do not know of each other's existence, and each will attempt to delete t.


owner_less can be thought of as "ordering on the address of the (real or metaphorical) control block". Thus, it considers equivalent two shared_ptr (and weak_ptr) if they share ownership or are both empty:

struct T { int x, y; };

std::shared_ptr<T> a(new T{});
std::shared_ptr<T> b = a;

std::shared_ptr<int> c(a, &a->y); // aliasing constructor

std::shared_ptr<T> d(a.get(), [](T*){}); // null deleter to avoid no double delete
std::shared_ptr<T> e(std::shared_ptr<T>(), a.get()); // "non-owning" empty shared_ptr with a non-null stored pointer

a, b, and c are all equivalent according to owner_less because they share ownership. d doesn't share ownership with a (it has its own "control block"), so it's different according to owner_less. Likewise for e, which is empty (owns nothing) but has a non-null stored pointer.

The default comparator simply compares the stored pointer, or get(). It will see a, b, d, and e as all equivalent and c as different (assuming that you converted both sides to shared_ptr<void> so that they are comparable).

  • Thank you for you answer, I actually know those two lines will cause problems but just used it as a way to expose the issue, but I wasn't familiar with aliasing constructors. Could you also explain why the default comparator (I am assuming it is just std::less<std::shared_ptr<T>>?) considers a and b to be the same? – Niko Nov 8 '18 at 23:09
  • I'm not sure if it really is UB in this case because T has a trivial destructor, but in the general case it definitely is. – Daniel H Nov 8 '18 at 23:15
  • 2
    @DanielH You forgot the double free. – T.C. Nov 8 '18 at 23:16
  • @DanielH It is UB because as a and b goes out of scope, delete operator will be called twice on the memory allocated for t. Double delete is always UB. – Julien Villemure-Fréchette Nov 8 '18 at 23:18
  • @JulienVillemure-Fréchette Yeah, you're right. I was just thinking of the destructor, not the deallocation. – Daniel H Nov 9 '18 at 0:04

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