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The definition of xvalue is as follows:

— An xvalue (an “eXpiring” value) also refers to an object, usually near the end of its lifetime (so that its resources may be moved, for example). An xvalue is the result of certain kinds of expressions involving rvalue references (8.3.2). [ Example: The result of calling a function whose return type is an rvalue reference is an xvalue. —end example ]

Will we ever fall into where we practically need to use a function whose return type is an rvalue reference, which is an xvalue?

const int && Foo()
{
    // ...
}

Move semantics take an rvalue reference as a parameter, not a return value. So I don't think that's the case.

share|improve this question
    
what do you mean by "explicit" in the title? – M.M Jan 19 at 10:03
    
@M.M If I write a function that returns an xvalue and I am 'aware of' it, and that's intended by me, I'd say that's explicit even though there is no syntatic keyword to indicate xvalues. – Dean Seo Jan 20 at 0:07
up vote 4 down vote accepted

Returning rvalue references can be of use for functions that already take rvalues as parameters. A simple example:

struct X {
    X() = default;
    X(X&& other) { std::cout << "move ctor\n"; }
    X(X const&) = delete;
    void log(std::string const& s){ std::cout << "log: " << s << "\n"; }
};

void sink(X&& x) { 
    x.log("sink"); 
}

X&& passOn(X&& in) {
    in.log("pass");
    return std::move(in);
}

X moveOn(X&& in) {
    in.log("move");
    return std::move(in);
}

int main() {
    sink(passOn(X()));
    std::cout << "===============================\n";
    sink(moveOn(X()));
}

Live demo →

The second function will call the move constructor to create the returned object, while the first will pass on the reference it already got. This is more useful if we don't return the original reference but instead a reference to a part of the referred object, e.g.

template<class T>
T&& getHead(std::vector<T>&& input) {
    return std::move(input.front());
}
share|improve this answer
    
@Jarod42 Not moving here would call the deleted copy constructor. I am not sure if NRVO would apply at all, since there is no object inside the function. – Arne Mertz Jan 19 at 9:49
    
Useful for perfectly forwarded filter functions. +1! – Yam Marcovic Jan 19 at 11:50

That's exactly what std::move is — the result of std::move execution is an xvalue. Other than that it is hard to tell since in the main returning a reference from the function is a bad thing most of the time. But maybe someone will come up with another clever usage of such a function.

share|improve this answer
    
@DeanSeo, indeed but you can't use rvalue reference in the return type for anything else except casting since returning a reference(no matter what type it is) from the function is wrong except if it is const and const rvalue reference is useless – ixSci Jan 19 at 7:26
    
Sorry for deleteting my previous comment. Btw, 'const rvalue reference that is being returned' is an xvalue. So recursively, returning xvalues is practically useless, you saying? :p – Dean Seo Jan 19 at 7:45
    
@DeanSeo, what I'm saying is that returning a reference to the thing that is created on the stack within a function is incorrect. So I see no usage example when we can use an rvalue reference as the return type except for the case which we have with std::move(we got something from the outside and returned an rvalue ref to it). It doesn't mean there is not such a usage — language features are rediscovered again and again. But for now I heard of nothing in this matter. – ixSci Jan 19 at 7:51

Will we ever fall into where we practically need to use a function whose return type is an rvalue reference, which is an xvalue?

It used in container classes, for instance tuple has a get overload that looks like this:

template< std::size_t I, class... Types >
typename std::tuple_element<I, tuple<Types...> >::type&&
    get( tuple<Types...>&& t );

I assume that std::optional and std::variant in C++17 will both have a similar overloads.

Granted, the only point is to avoid to type std::move in some very specific situations, like:

 auto x = std::get<1>( f() );

Where f returns a tuple by value.

share|improve this answer
    
A great example of how to save even move constructors where they aren't needed (i.e. theoretically it could have just returned the xvalues converted to prvalues, but that would require, unnecessarily, either a move or a copy constructor, which also aren't always available). – Yam Marcovic Jan 19 at 11:48

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