57

What does the C++11 standard say about self move assignment in relation to the standard library? To be more concrete, what, if anything, is guaranteed about what selfAssign does?

template<class T>
std::vector<T> selfAssign(std::vector<T> v) {
  v = std::move(v);
  return v;
}
4
  • 4
    @Mark I don't think this is a duplicate. That question is about writing your own. This question is about what the standard library guarantees. Commented Oct 29, 2012 at 19:02
  • 2
    Note that this does not involve the self-move-assignment of T.
    – Xeo
    Commented Oct 29, 2012 at 19:06
  • @Xeo I removed that line. Thanks for pointing out the error. Commented Oct 29, 2012 at 19:21
  • 2
    voting to reopen as the marked "duplicate" does not cover guarantees on standard containers' move-assignment behaviour, and none of the answers provide Standard references like Howard Hinnant's answer to this thread
    – M.M
    Commented Jul 7, 2014 at 6:59

2 Answers 2

46

17.6.4.9 Function arguments [res.on.arguments]

1 Each of the following applies to all arguments to functions defined in the C++ standard library, unless explicitly stated otherwise.

...

  • If a function argument binds to an rvalue reference parameter, the implementation may assume that this parameter is a unique reference to this argument. [ Note: If the parameter is a generic parameter of the form T&& and an lvalue of type A is bound, the argument binds to an lvalue reference (14.8.2.1) and thus is not covered by the previous sentence. — end note ] [ Note: If a program casts an lvalue to an xvalue while passing that lvalue to a library function (e.g. by calling the function with the argument move(x)), the program is effectively asking that function to treat that lvalue as a temporary. The implementation is free to optimize away aliasing checks which might be needed if the argument was anlvalue. —endnote]

So, the implementation of std::vector<T, A>::operator=(vector&& other) is allowed to assume that other is a prvalue. And if other is a prvalue, self-move-assignment is not possible.

What is likely to happen:

v will be left in a resource-less state (0 capacity). If v already has 0 capacity, then this will be a no-op.

Update

The latest working draft, N4618 has been modified to clearly state that in the MoveAssignable requirements the expression:

t = rv

(where rv is an rvalue), t need only be the equivalent value of rv prior to the assignment if t and rv do not reference the same object. And regardless, rv's state is unspecified after the assignment. There is an additional note for further clarification:

rv must still meet the requirements of the library component that is using it, whether or not t and rv refer to the same object.

6
  • 6
    If I understand your quote correctly, the function selfAssign then invokes undefined behavior because the preconditions of the move assignment operator are not met. My understanding is that std::swap will do self move assignment on the call std::swap(v, v). Does that make it undefined behavior to call std::swap(v, v)? Commented Oct 29, 2012 at 19:11
  • Interesting. This would mean that && implies __restrict for arguments then; I wonder if any compiler takes advantage of this yet. Commented Oct 29, 2012 at 19:25
  • 3
    @MatthieuM.: That's only what the standard says about it's own functions; that's not a general statement about && parameters. You would not be restricted to that in code you write. Commented Oct 29, 2012 at 19:31
  • @BjarkeH.Roune: swap(v, v) is legal and required to work. And it typically does because the self-move-assignment is done with a moved-from value (assuming we're not talking about vector which has a specialized swap which is also required to work with self-swap). In the generic self-swap, you're move assigning from an unspecified value to an unspecified value. So it really doesn't matter what happens as long as it doesn't crash. swap(t, t) requires T to be MoveAssignable. That requirement holds even if T is in a moved-from state. Commented Oct 29, 2012 at 19:38
  • @HowardHinnant I'm not sure I understand your reasoning. I made the topic a question. Commented Oct 29, 2012 at 20:22
5

There is a relevant post by Eric Niebler with multiple links, e.g. to this answer by Howard Hinnant.

The latest С++20 working draft (N4861) is still kind of ambiguous on the matter for my taste. However, there is a recent Library Working Group issue 2839 which adds the following explicit statement at [lib.types.movedfrom]/2:

An object of a type defined in the C++ standard library may be move-assigned (11.4.6 [class.copy.assign]) to itself. Such an assignment places the object in a valid but unspecified state unless otherwise specified.

It was already in the N4885 working draft of C++23.

So, selfAssign is guaranteed to not cause undefined behavior and, as there are no extra guarantees for std::vector, leave v in some valid state.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.