Sign up ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I understand if you wish to pass a vector of MyClass objects and it is a temporary variable, if there is a move constructor defined for MyClass then this will be called, but what happens if you pass a vector of boost::shared_ptr<MyClass> or std::shared_ptr<MyClass>? Does the shared_ptr have a move constructor which then call's MyClass's move constructor?

share|improve this question

3 Answers 3

up vote 3 down vote accepted

if there is a move constructor defined for MyClass then this will be called

Usually not. Moving a vector is usually done my transferring ownership of the managed array, leaving the moved-from vector empty. The objects themselves aren't touched. (I think there may be an exception if the two vectors have incompatible allocators, but that's beyond anything I've ever needed to deal with, so I'm not sure about the details there).

Does the shared_ptr have a move constructor which then call's MyClass's move constructor?

No. Again, it has a move constructor which transfers ownership of the MyClass object to the new pointer, leaving the old pointer empty. The object itself is untouched.

share|improve this answer

Yes, std::shared_ptr<T> has a move constructor, as well as a templated constructor that can move from related shared pointers, but it does not touch the managed object at all. The newly constructed shared pointer shares ownership of the managed object (if there was one), and the moved-from pointer is disengaged ("null").


struct Base {};                // N.B.: No need for a virtual destructor
struct Derived : Base {};

auto p = std::make_shared<Derived>();
std::shared_ptr<Base> q = std::move(p);

share|improve this answer
It has a regular move constructor as well as the template, since templates can't be used as move or copy constructors. –  Mike Seymour Nov 27 '13 at 15:26
@MikeSeymour: Reference? –  Kerrek SB Nov 27 '13 at 15:27
C++11 for shared_ptr. More generally, 12.8/3: "A non-template constructor for class X is a move constructor if..." –  Mike Seymour Nov 27 '13 at 15:28
@MikeSeymour: Thanks. I didn't see it in, but it's right there together with the templated version. –  Kerrek SB Nov 27 '13 at 15:31
Isn't it UB, since Base has no virtual destructor? Why there is no need for it? –  BЈовић Nov 27 '13 at 16:35

If you mean moving std::vector<std::shared_ptr<MyClass>>. Then even the move constructor of std::shared_ptr won't be called. Because the move operation is directly done on std::vectorlevel.

For example, a std::vector<T> may be implemented as a pointer to array of T, and a size member. The move constructor for this can be implemented as:

template <typename T>
class vector {
    /* ... other members */
    vector(vector &&another): _p(another._p), _size(another._size) {
        /* Transfer data ownership */
        another._p = nullptr;
        another._size = 0;

    T *_p;
    size_t _size;

You can see in this process, no data member of type T is touched at all.

EDIT: More specially in C++11 Standard: §23.2.1. General container requirements (4) there is a table contains requirements on implementations of general containers, which contains following requirements:

(X is the type of the elements, u is an identifier declaration, rv is rvalue reference, a is a container of type X)

X u(rv)
X u = rv

C++ Standard: These two (move constructors) should have constant time complexity for all standard containers except std::array.

So it's easy to conclude implementations must use a way like I pointed above for move constructors of std::vector since it cannot invoke move constructors of individual elements or the time complexity will become linear time.

a = rv

C++ Standard: All existing elements of a are either move assigned to or destroyed a shall be equal to the value that rv had before this assignment.

This is for move assign operator. This sentence only states that original elements in a should be "properly handled" (either move-assigned in or destroyed). But this is not a strict requirement. IMHO implementations can choose the best suited way.

I also looked at code in Visual C++ 2013 and this is the snippet I found (vector header, starting from line 836):

/* Directly move, like code above */
void _Assign_rv(_Myt&& _Right, true_type)
{   // move from _Right, stealing its contents
    this->_Myfirst = _Right._Myfirst;
    this->_Mylast = _Right._Mylast;
    this->_Myend = _Right._Myend;

    _Right._Myfirst = pointer();
    _Right._Mylast = pointer();
    _Right._Myend = pointer();

/* Both move assignment operator and move constructor will call this */
void _Assign_rv(_Myt&& _Right, false_type)
{    // move from _Right, possibly moving its contents
    if (get_allocator() == _Right.get_allocator())
        _Assign_rv(_STD forward<_Myt>(_Right), true_type());
        _Construct(_STD make_move_iterator(_Right.begin()),
        _STD make_move_iterator(_Right.end()));

In this code the operation is clear: if both this and right operand have the same allocator, it will directly steal contents without doing anything on individual elements. But if they haven't, then move operations of individual elements will be called. At this time, other answers apply (for std::shared_ptr stuff).

share|improve this answer
I thought each element is moved too? –  user997112 Nov 27 '13 at 15:26
@user997112, I doubt so. –  ʎǝɹɟɟɟǝſ Nov 27 '13 at 15:33

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

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