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I'm having trouble overloading a function to take a value either by const reference or, if it is an rvalue, an rvalue reference. The problem is that my non-const lvalues are binding to the rvalue version of the function. I'm doing this in VC2010.

#include <iostream>
#include <vector>

using namespace std;

template <class T>
void foo(const T& t)
{cout << "void foo(const T&)" << endl;}

template <class T>
void foo(T&& t)
{cout << "void foo(T&&)" << endl;}

int main()
{
    vector<int> x;
    foo(x); // void foo(T&&) ?????
    foo(vector<int>()); // void foo(T&&)
}

The priority seems to be to deduce foo(x) as

foo< vector<int> & >(vector<int>& && t)

instead of

foo< vector<int> >(const vector<int>& t)

I tried replacing the rvalue-reference version with

void foo(typename remove_reference<T>::type&& t)

but this only had the effect of causing everything to resolve to the const-lvalue reference version.

How do I prevent this behaviour? And why is this the default anyway - it seems so dangerous given that rvalue-references are allowed to be modified, this leaves me with an unexpectedly modified local variable.

EDIT: Just added non-template versions of the functions, and they work as expected. Making the function a template changes the overload resolution rules? That is .. really frustrating!

void bar(const vector<int>& t)
{cout << "void bar(const vector<int>&)" << endl;}

void bar(vector<int>&& t)
{cout << "void bar(vector<int>&&)" << endl;}

bar(x); // void bar(const vector<int>&)
bar(vector<int>()); // void bar(vector<int>&&)
share|improve this question
    
What happens when you make x const? What happens when you use x after the other call to foo? –  Daemin Oct 13 '11 at 0:42
    
It is possible to arrange for deduced T&& to bind only to rvalues. See ideone.com/XSBifq . But I wouldn't recommend this. The accepted answer, i.e. don't use overloading like this, is the right approach. –  Aaron McDaid May 10 '13 at 23:52
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2 Answers

up vote 20 down vote accepted

When you have a templated function like this you almost never want to overload. The T&& parameter is a catch anything parameter. And you can use it to get any behavior you want out of one overload.

#include <iostream>
#include <vector>

using namespace std;

template <class T>
void display()
{
    typedef typename remove_reference<T>::type Tr;
    typedef typename remove_cv<Tr>::type Trcv;
    if (is_const<Tr>::value)
        cout << "const ";
    if (is_volatile<Tr>::value)
        cout << "volatile ";
    std::cout << typeid(Trcv).name();
    if (is_lvalue_reference<T>::value)
        std::cout << '&';
    else if (is_rvalue_reference<T>::value)
        std::cout << "&&";
    std::cout << '\n';
}

template <class T>
void foo(T&& t)
{
    display<T>();
}

int main()
{
    vector<int> x;
    vector<int> const cx;
    foo(x); // vector<int>&
    foo(vector<int>()); // vector<int>
    foo(cx);  // const vector<int>&
}
share|improve this answer
    
I see. So, basically, the semantics of && changes between template and non-template functions? && in a non-template function means "move-semantics", && in a template function means "catch-all"? –  Ayjay Oct 13 '11 at 1:22
3  
Yes, you've got it. Although I would have worded it differently: && in a non-template function means "move-semantics", && in a template function means "perfect forwarding" –  Howard Hinnant Oct 13 '11 at 1:55
    
Fair enough, I guess, but that does frustrate me a bit. I can see issues arising out of the lack of unity between semantics. –  Ayjay Oct 13 '11 at 2:23
4  
Fair enough. Me and some other guys (Peter and Dave) were trying to kill two birds with one stone with the introduction of rvalue references: move semantics and perfect forwarding. At the time (2002) we were thinking that a minimal change to the language with little or no backwards incompatibility and accomplish more than one impossible task would be a good thing. But had we been designing with a clean slate, certainly cleaner solutions seem plausible. Certainly if this frustration increases, one should restrict oneself to the C++98/03 subset, and thus this issue will not arise. –  Howard Hinnant Oct 13 '11 at 3:03
1  
<sigh> <off topic> and my sincerest condolences to the family of Dennis Ritchie. –  Howard Hinnant Oct 13 '11 at 3:16
show 1 more comment

In order for T&& to bind to an lvalue reference, T must itself be an lvalue reference type. You can prohibit the template from being instantiated with a reference type T:

template <typename T>
typename std::enable_if<!std::is_reference<T>::value>::type foo(T&& t)
{
    cout << "void foo(T&&)" << endl;
}

enable_if is found in <utility>; is_reference is found in <type_traits>.

The reason that the overload taking T&& is preferred over the overload taking a T const& is that T&& is an exact match (with T = vector<int>&) but T const& requires a qualification conversion (const-qualification must be added).

This only happens with templates. If you have a nontemplate function that takes a std::vector<int>&&, you will only be able to call that function with an rvalue argument. When you have a template that takes a T&&, you should not think of it as "an rvalue reference parameter;" it is a "universal reference parameter" (Scott Meyers used similar language, I believe). It can accept anything.

Allowing a T&& parameter of a function template to bind to any category of argument is what enables perfect forwarding.

share|improve this answer
    
So whenever you templacise a function with an rvalue reference, you need to always remember to manually remove the reference overload? –  Ayjay Oct 13 '11 at 0:45
    
@Ayjay No, usually one template that makes use of perfect forwarding is enough. Since it accepts anything (see Howard's answer) and the value category as well as the cv qualifiers of the argument are preserved, you rarely need another overload. –  Luc Danton Oct 13 '11 at 1:14
    
I have been trying this, and the issue I'm finding is that fighting compile errors is hard. Even though the actual code that would be executed is syntatically correct, some of the other if-conditions have invalid syntax. This is frustrating me, and I may use enable-if to restore the non-template rvalue overload rules so that I can write the functions the same as if they were not templacised. –  Ayjay Oct 13 '11 at 2:40
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