Is there a reason when a function should return a RValue Reference? A technique, or trick, or an idiom or pattern?

MyClass&& func( ... );

I am aware of the danger of returning references in general, but sometimes we do it anyway, don't we? T& T::operator=(T) is just one idiomatic example. But how about T&& func(...)? Is there any general place where we would gain from doing that? Probably different when one writes library or API code, compared to just client code?

5 Answers 5


There are a few occasions when it is appropriate, but they are relatively rare. The case comes up in one example when you want to allow the client to move from a data member. For example:

template <class Iter>
class move_iterator
    Iter i_;
    value_type&& operator*() const {return std::move(*i_);}
  • 5
    An excellent example. The pattern is, you want client code to move something -- allowing him to "steal". Yes, of course.
    – towi
    Apr 24, 2011 at 14:38
  • 4
    In general a moved from object, when used in the std::lib, must meet all of the requirements specified for whatever part of the std::lib it is using. std-defined types must additionally guarantee that their moved from state is valid. Clients can call any function with that object as long as there are no pre-conditions on its value for said function-call. Apr 26, 2011 at 17:07
  • 4
    Finally, in the example above, there are no moved-from objects. std::move doesn't move. It only casts to rvalue. It is up to the client to move (or not) from that rvalue. That client will only access a moved-from value if he dereferences the move_iterator twice, without intervening iterator traversal. Apr 26, 2011 at 17:08
  • 3
    Wouldn't it be safer to use value_type instead of value_type&& as the return type? May 15, 2011 at 12:33
  • 1
    Yes, I think so. However in this case I think the added benefit outweighs the risk. move_iterator is often used in generic code to turn a copying algorithm into a moving one (e.g. a move-version of vector::insert). If you then supply a type with an expensive copy & move to the generic code, you've got an extra copy gratuitously added. I'm thinking array<int, N> for example. When move-inserting a bunch of these into vector, you don't want to accidentally introduce an extra copy. On the risk side, const X& x = *i is pretty rare. I don't think I've ever seen it. May 15, 2011 at 13:39

This follows up on towi's comment. You never want to return references to local variables. But you might have this:

vector<N> operator+(const vector<N>& x1, const vector<N>& x2) { vector<N> x3 = x1; x3 += x2; return x3; }
vector<N>&& operator+(const vector<N>& x1, vector<N>&& x2)    { x2 += x1; return std::move(x2); }
vector<N>&& operator+(vector<N>&& x1, const vector<N>& x2)    { x1 += x2; return std::move(x1); }
vector<N>&& operator+(vector<N>&& x1, vector<N>&& x2)         { x1 += x2; return std::move(x1); }

This should prevent any copies (and possible allocations) in all cases except where both parameters are lvalues.

  • 1
    While it's possible, this is generally frowned upon because this approach has its own issues besides saving temporaries. See stackoverflow.com/questions/6006527
    – sellibitze
    May 25, 2011 at 11:24
  • 2
    Don't those return calls need to use std::move()?
    – wjl
    Jun 10, 2011 at 16:12
  • 1
    @wjl: Good question, but I don't think so. std::move works without using std::move. I think the cast to && does the trick here.
    – Clinton
    Jun 11, 2011 at 6:27
  • 1
    @Clinton there's no cast in your code, you have to return std::move(x2); etc. Or you could write a cast to rvalue reference type, but that's just what move does anyway.
    – M.M
    Mar 30, 2015 at 2:20
  • 1
    The code is only correct if the return value is either unused, or assigned to an object -- but then you may as well have returned by value and taken the arguments by value and let copy elision do its thing.
    – M.M
    Jul 28, 2015 at 0:06

No. Just return the value. Returning references in general is not at all dangerous- it's returning references to local variables which is dangerous. Returning an rvalue reference, however, is pretty worthless in almost all situations (I guess if you were writing std::move or something).

  • 5
    I think during the early design of the C++0x there was a time when it was suggested that things like the move-assign and T&& operator+(const T&,T&&) should return a &&. But that is gone now, in the final draft. That's why I ask.
    – towi
    Apr 24, 2011 at 11:43

You can return by reference if you are sure the referenced object will not go out of scope after the function exits, e.g. it's a global object's reference, or member function returning reference to class fields, etc.

This returning reference rule is just same to both lvalue and rvalue reference. The difference is how you want to use the returned reference. As I can see, returning by rvalue reference is rare. If you have function:

Type&& func();

You won't like such code:

Type&& ref_a = func();

because it effectively defines ref_a as Type& since named rvalue reference is an lvalue, and no actual move will be performed here. It's quite like:

const Type& ref_a = func();

except that the actual ref_a is a non-const lvalue reference.

And it's also not very useful even you directly pass func() to another function which takes a Type&& argument because it's still a named reference inside that function.

void anotherFunc(Type&& t) {
  // t is a named reference

The relationship of func( ) and anotherFunc( ) is more like an "authorization" that func() agrees anotherFunc( ) might take ownership of (or you can say "steal") the returned object from func( ). But this agreement is very loose. A non-const lvalue reference can still be "stolen" by callers. Actually functions are rarely defined to take rvalue reference arguments. The most common case is that "anotherFunc" is a class name and anotherFunc( ) is actually a move constructor.


One more possible case: when you need to unpack a tuple and pass the values to a function.

It could be useful in this case, if you're not sure about copy-elision.

Such an example:

template<typename ... Args>
class store_args{
        std::tuple<Args...> args;

        template<typename Functor, size_t ... Indices>
        decltype(auto) apply_helper(Functor &&f, std::integer_sequence<size_t, Indices...>&&){
            return std::move(f(std::forward<Args>(std::get<Indices>(args))...));

        template<typename Functor>
        auto apply(Functor &&f){
            return apply_helper(std::move(f), std::make_index_sequence<sizeof...(Args)>{});

pretty rare case unless you're writing some form of std::bind or std::thread replacement though.

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