The standard C++ containers offer only one version of operator[] for containers like vector<T> and deque<T>. It returns a T& (other than for vector<bool>, which I'm going to ignore), which is an lvalue. That means that in code like this,

vector<BigObject> makeVector();       // factory function

auto copyOfObject = makeVector()[0];  // copy BigObject

copyOfObject will be copy constructed. Given that makeVector() returns an rvalue vector, it seems reasonable to expect copyOfObject to be move constructed.

If operator[] for such containers was overloaded for rvalue and lvalue objects, then operator[] for rvalue containers could return an rvalue reference, i.e., an rvalue:

template<typename T>
container {
    T& operator[](int index) &;       // for lvalue objects
    T&& operator[](int index) &&;     // for rvalue objects

In that case, copyOfObject would be move constructed.

Is there a reason this kind of overloading would be a bad idea in general? Is there a reason why it's not done for the standard containers in C++14?

  • I guess it could be undesirable for two reasons, 1) leaving container[0] empty/moved makes repeat access of the same element tricky(unless say, container.at(0) is not overloaded for rvalue), and 2) auto& ref = container[0] will not work everywhere
    – melak47
    Mar 27, 2015 at 22:53
  • Note that we're talking about rvalue containers here. That means that repeat element access is difficult, because the container exists for only the duration of the statement. If you extend its lifetime by binding the container to a named reference (as in your example), the reference is an lvalue, and subsequent accesses through the reference will invoke the lvalue operator[] overload. Mar 27, 2015 at 22:59
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    Well, one obvious possible reason is that it can break existing code. Given vector<int> f(); void g(int &);, g(f()[0]) will suddenly stop working, or, if there's also a void g(const int &);, silently go to a different overload.
    – T.C.
    Mar 27, 2015 at 23:00
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    @T.C.: Valid point, thanks. That's a reasonable answer to the question why the standard containers don't overload operator[] for lvalues and rvalues, but what about new containers where legacy code is not an issue? Is there a problem with the design in general? Mar 27, 2015 at 23:09
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    I don't see a problem with the design in general. After all, class member access uses very similar rules (E1.E2 is an xvalue if E2 names a non-static data member and E1 is an rvalue). std::experimental::optional also uses a similar design, though I can't remember whether the && version for that returns T or T&&.
    – T.C.
    Mar 27, 2015 at 23:14

2 Answers 2


Converting comment into answer:

There's nothing inherently wrong with this approach; class member access follows a similar rule (E1.E2 is an xvalue if E1 is an rvalue and E2 names a non-static data member and is not a reference, see [expr.ref]/4.2), and elements inside a container are logically similar to non-static data members.

A significant problem with doing it for std::vector or other standard containers is that it will likely break some legacy code. Consider:

void foo(int &);
std::vector<int> bar();


That last line will stop compiling if operator[] on an rvalue vector returned an xvalue. Alternatively - and arguably worse - if there is a foo(const int &) overload, it will silently start calling that function instead.

Also, returning a bunch of elements in a container and only using one element is already rather inefficient. It's arguable that code that does this probably doesn't care much about speed anyway, and so the small performance improvement is not worth introducing a potentially breaking change.

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    Do you think your answer also applies to the omission of an rvalue iterator? Jul 5, 2015 at 2:34
  • @NirFriedman rvalue iterator? Special overloads of begin()/end() for rvalues? I don't see how they can be useful.
    – T.C.
    Jul 5, 2015 at 2:38
  • It would be a new type, the way there is an iterator and a const_iterator, you would have rvalue_iterator. They would be useful because they would eliminate the necessity of having separate "move flavored" algorithms. That is, there is std::copy to copy a range, and std::move to move a range, and copy_if, but no move_if. These move flavored algorithms shouldn't exist, it should be handled by the iterators. Jul 5, 2015 at 2:41
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    @NirFriedman We have std::move_iterator for that, though it's arguable that an iterator indiscriminately presenting an rvalue is not necessarily the right way to do it (for instance, using copy_if with a predicate taking its argument by value is correct if inefficient, but if you add a move iterator to the mix everything blows up).
    – T.C.
    Jul 5, 2015 at 2:45
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    @NirFriedman using iter_t = std::conditional_t<std::is_rvalue_reference<decltype(vec)>{}, std::move_iterator<decltype(vec.begin()>, decltype(vec.begin())>; std::copy_if(iter_t{vec.begin()}, iter_t{vec.end()}, out, pred);? Regardless, getting an iterator out of an rvalue is dangerous enough that I don't think it's a good idea to support it beyond what is needed for backwards compatibility.
    – T.C.
    Jul 6, 2015 at 20:37

I think you will leave the container in an invalid state if you move out one of the elements, I would argue the need to allow that state at all. Second, if you ever need that, can't you just call the new object's move constructor like this:

T copyObj = std::move(makeVector()[0]);


Most important point is, again in my opinion, that containers are containers by their nature, so they should not anyhow modify the elements inside them. They just provide a storage, iteration mechanism, etc.

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    Moving is required to leave the source object in a valid state, so the container would not be left in an invalid state. It's true that users can apply std::move themselves, but if that's the only reason for not overloading operator[] for lvalues and rvalues, I consider it a pretty weak motivation. Mar 27, 2015 at 22:44
  • @KnowItAllWannabe, OK I agree, it will be in a valid, but still unspecified state, and all you can do with those elements (which have been moved out from the container), just the actions that do not imply any preconditions. Can you give an example of a reasonable algorithm that you can run on your container after you move out some elements?
    – Arsen Y.M.
    Mar 27, 2015 at 23:19
  • Sure: sort, partition, find_if, etc. For example, you can sort a container of containers by size, even if some of the contained containers have been moved from. Moved-from objects aren't evil or toxic or dangerous, they're just moved from, and for many types, you know what state they're in. For example, moved-fromt shared_ptrs are null. Mar 27, 2015 at 23:25
  • Yes, I understand that (for many types, you know what state they're in), please see my update in the answer, I guess that is the main reason.
    – Arsen Y.M.
    Mar 27, 2015 at 23:38

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