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If you have this function

template<typename T> f(T&);

And then try to call it with, let's say an rvalue like

f(1);

Why isn't T just be deduced to be const int, making the argument a const int& and thus bindable to an rvalue?

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2 Answers

up vote 13 down vote accepted

This is mentioned as a potential solution in the document I linked in the recent C++0x forwarding question.

It would work fairly well, but it breaks existing code. Consider (straight from the document):

template<class A1> void f(A1 & a1)
{
    std::cout << 1 << std::endl;
}

void f(long const &)
{
    std::cout << 2 << std::endl;
}

int main()
{
    f(5);              // prints 2 under the current rules, 1 after the change
    int const n(5);
    f(n);              // 1 in both cases
}

Or

// helper function in a header

template<class T> void something(T & t) // #1
{
    t.something();
}

// source

#include <vector>

void something(bool) // #2
{
}

int main()
{
    std::vector<bool> v(5);

    // resolves to #2 under the current rules, #1 after the change
    something(v[0]);
}

This also fails to forward the value category (lvalue or rvalue), which isn't much of a problem in C++03. But since this fix could only be done during C++0x, we'd effectively shutting ourselves out from rvalue references when forwarding (a bad thing). We should strive for a better solution.

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It is, but only if you declare f to take T const &.

template <typename T> void f(T &);
template <typename T> void g(T const &);

void x() { f(1); }  // error: invalid initialization of non-const reference
void y() { g(1); }  // no error

And if you declare both f(T &) and f(T const &), it'll choose the const-qualified one:

template <typename T> void f(T &);
template <typename T> void f(T const &);

void x() { f(1); } // no error, calls f(T const &)

Now maybe you're saying “in the first example, why does it generate a temporary of type int for the call to f when it could have generated a temporary of type const int and made the code compile?” The best answer I have for you is that that would be inconsistent with the overload resolution behavior when the argument isn't an integer constant.

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Yes, I know about the overloading. I wanted to know why it's even necessary. How would it be inconsistent? –  Puppy Aug 28 '10 at 18:16
    
@DeadMG: 1 has type int. If you declared an int i = 1, then it would choose the non-const approach, because i isn't const. Therefore, for consistency, it does so here too, except that for an rvalue this is an error. –  Matthieu M. Aug 29 '10 at 11:13
    
@Matthieu: 1 is an int rvalue. i is an int lvalue. Since the language insists on treating them differently, then they are different things. Therefore, it's not inconsistent. Infact, it's inconsistent to have a bunch of rules specially for rvalues, and then try to treat them the same here. –  Puppy Aug 29 '10 at 11:28
1  
@DeadMG: I agree that the standard is strange, I personally think that 1 should be of type int const because hey, I can't change it! However it's not how the standard said it was, and therefore it isn't. As for the interdiction to take rvalue by reference I never could like it, it doesn't make sense from the C++ philosophy point of view which happily let's you shoot yourself if you wish to prevent this when it can be so useful (for forwarding, for "sink"-like behavior etc), after all, why couldn't I modify a temporary and be happy with it ? But the standard is law, and thus IS consistent –  Matthieu M. Aug 29 '10 at 11:43
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