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Following on from a comment I made on this:

passing std::vector to constructor and move semantics Is the std::move necessary in the following code, to ensure that the returned value is a xvalue?

std::vector<string> buildVector()
{
  std::vector<string> local;

  // .... build a vector

  return std::move(local);
}

It is my understanding that this is required. I have often seen this used when returning a std::unique_ptr from a function, however GManNickG made the following comment:

It is my understanding that in a return statement all local variables are automatically xvalues (expiring values) and will be moved, but I'm unsure if that only applies to the returned object itself. So OP should go ahead and put that in there until I'm more confident it shouldn't have to be. :)

Can anyone clarify if the std::move is necessary?

Is the behaviour compiler dependent?

share|improve this question
    
Note you've caused me to since modify my statement. It's only the returned value that gets moved (which may be a local variable), not all local variables in general. (Though that would be nice, it probably breaks on some old code I can't think of, and C++ progression has to maintain backwards compatibility.) – GManNickG Apr 1 '12 at 11:35
up vote 13 down vote accepted

You're guaranteed that local will be returned as an rvalue in this situation. Usually compilers would perform return-value optimization though before this even becomes an issue, and you probably wouldn't see any actual move at all, since the local object would be constructed directly at the call site.

A relevant Note in 6.6.3 ["The return statement"] (2):

A copy or move operation associated with a return statement may be elided or considered as an rvalue for the purpose of overload resolution in selecting a constructor (12.8).

To clarify, this is to say that the returned object can be move-constructed from the local object (even though in practice RVO will skip this step entirely). The normative part of the standard is 12.8 ["Copying and moving class objects"] (31, 32), on copy elision and rvalues (thanks @Mankarse!).


Here's a silly example:

#include <utility>

struct Foo
{
    Foo()            = default;
    Foo(Foo const &) = delete;
    Foo(Foo &&)      = default;
};

Foo f(Foo & x)
{
    Foo y;

    // return x;         // error: use of deleted function ‘Foo::Foo(const Foo&)’
    return std::move(x); // OK
    return std::move(y); // OK
    return y;            // OK (!!)
}

Contrast this with returning an actual rvalue reference:

Foo && g()
{
    Foo y;
    // return y;         // error: cannot bind ‘Foo’ lvalue to ‘Foo&&’
    return std::move(y); // OK type-wise (but undefined behaviour, thanks @GMNG)
}
share|improve this answer
    
+1 (To be clear, the last one has UB and should only be looked at as a type checking example.) – GManNickG Apr 1 '12 at 11:56
    
@GManNickG: True; you don't really return && from anything but forward and move. It's a contrived example. – Kerrek SB Apr 1 '12 at 11:59
    
The normative paragraph guaranteeing this behaviour is [class.copy]/32. – Mankarse Apr 1 '12 at 11:59
    
Thanks for clearingthat up. – mark Apr 1 '12 at 12:20

Altough both, return std::move(local) and return local, do work in sense of that they do compile, their behavior is different. And probably only the latter one was intended.

If you write a function which returns a std::vector<string>, you have to return a std::vector<string> and exactly it. std::move(local) has the typestd::vector<string>&& which is not a std::vector<string> so it has to be converted to it using the move constructor.

The standard says in 6.6.3.2:

The value of the expression is implicitly converted to the return type of the function in which it appears.

That means, return std::move(local) is equalvalent to

std::vector<std::string> converted(std::move(local); // move constructor
return converted; // not yet a copy constructor call (which will be elided anyway)

whereas return local only is

return local; // not yet a copy constructor call (which will be elided anyway)

This spares you one operation.


To give you a short example of what that means:

struct test {
  test() { std::cout << "  construct\n"; }
  test(const test&) { std::cout << "  copy\n"; }
  test(test&&) { std::cout << "  move\n"; }
};

test f1() { test t; return t; }
test f2() { test t; return std::move(t); }

int main()
{
  std::cout << "f1():\n"; test t1 = f1();
  std::cout << "f2():\n"; test t2 = f2();
}

This will output

f1():
  construct
f2():
  construct
  move
share|improve this answer
    
Thanks for your input. – mark Apr 1 '12 at 12:21
    
Note that this is only true in the presence of NVRO/elision. Without elision, f1 will also have to move. – Nicol Bolas Apr 1 '12 at 16:36
    
@NicolBolas: Yes, that's the "not yet a copy constructor call" part written above (well, actually it has to be the move constructor call). However, this affects both, f1 and f2, so even then the f1 has one constructor call less. – ipc Apr 1 '12 at 16:48
    
@ipc: No. In f2, the final returned value is move-constructed directly into the output. So it will still only have 2 constructors: the initial one and the move. – Nicol Bolas Apr 1 '12 at 16:59

I think the answer is no. Though officially only a note, §5/6 summarizes what expressions are/aren't xvalues:

An expression is an xvalue if it is:

  • the result of calling a function, whether implicitly or explicitly, whose return type is an rvalue reference to object type,
  • a cast to an rvalue reference to object type,
  • a class member access expression designating a non-static data member of non-reference type in which the object expression is an xvalue, or
  • a .* pointer-to-member expression in which the first operand is an xvalue and the second operand is a pointer to data member.

In general, the effect of this rule is that named rvalue references are treated as lvalues and unnamed rvalue references to objects are treated as xvalues; rvalue references to functions are treated as lvalues whether named or not.

The first bullet point seems to apply here. Since the function in question returns a value rather than an rvalue reference, the result won't be an xvalue.

share|improve this answer
    
+1 for talking about xvalues, because I was wrong there too. (Not my day I suppose.) Fortunately, what really matters is if the return value can be treated as an rvalue, which it is. But not all xvalues in general like I claimed. – GManNickG Apr 1 '12 at 12:08

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