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In VS2010 std::forward is defined as such:

template<class _Ty> inline
_Ty&& forward(typename identity<_Ty>::type& _Arg)
{   // forward _Arg, given explicitly specified type parameter
    return ((_Ty&&)_Arg);
}

identity appears to be used solely to disable template argument deduction. What's the point of purposefully disabling it in this case?

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Note that currently std::forward is declared as template<typename T> T&& forward(typename std::remove_reference<T>::type& t); template<typename T> T&& forward(typename std::remove_reference<T>::type&& t); (and both return static_cast<T&&>(t)). MSVC is following a previous version of forward. –  Luc Danton Oct 15 '11 at 19:13
    
Interesting. How is that different from template<typename T> T&& forward(T&& t){ return static_cast<T&&>(t); }? I see the purpose of std::remove_reference in std::move, but not here. –  Dave Oct 15 '11 at 19:32
    
The two overload version works with rvalues and doesn't require std:identity which was in fact dropper altogether from the Standard. –  Luc Danton Oct 15 '11 at 19:37
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3 Answers

Because std::forward(foo) is not useful. The only thing it can do is a no-op, i.e. perfectly-forward its argument and act like an identity function. The alternative would be that it's the same as std::move, but we already have that. In other words, assuming it were possible, in

template<typename T>
void
f(T&& t)
{
    std::forward(t);
}

std::forward(t) is semantically equivalent to t. On the other hand, std::forward<T>(t) is not a no-op in the general case.

So by forbidding std::forward(t) it helps catch programmer errors and we lose nothing since any possible use of std::forward(t) are trivially replaced by t.


I think you'd understand things better if we focus on what exactly std::forward<T>(t) does, rather than what std::forward(t) would do (since it's an uninteresting no-op). Let's try to write a no-op function template that perfectly forwards its argument. Also, for clarity, this template is going to use U as its template parameter. Any use of T will refer to the template parameter of std::forward itself.

template<typename U>
U&&
f(U&& u)
{ return u; }

This naive first attempt isn't quite valid. If we call f(0) then U is deduced as int. This means that the return type if int&& and we can't bind such an rvalue reference from the expression u, which is an lvalue (it's the name of a local variable). If we then attempt:

template<typename U>
U&&
f(U&& u)
{ return std::move(u); }

then int i = 0; f(i); fails. This time, U is deduced as int& (reference collapsing rules guarantees that int& && collapses to int&), hence the return type is int&, and this time we can't bind such an lvalue reference from the expression std::move(u) which is an xvalue.

In the context of a perfect-forwarding function like f, sometimes we want to move, but other times we don't. The rule to know whether we should move depend on U: if it's not an lvalue reference type, it means f was passed an rvalue. If it is an lvalue reference type (U&), it means f was passed an lvalue. So in std::forward<U>(u), U is a necessary parameter to do the right thing. Without it, there's not enough information. This U is not the same type as what T would be deduced (inside std::forward) to in the general case.

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So what does std::forward<T>(t) do differently from std::forward(t)? –  Dani Oct 15 '11 at 19:12
1  
I don't understand why it would be a no-op if it deduced the template argument type instead of me explicitly giving it. Could you elaborate/clarify? –  Dave Oct 15 '11 at 19:14
    
"any possible use of std::forward(t) are trivially replaced by t" I don't think that's true; the former is an r-value, the latter is not. –  avakar Oct 15 '11 at 19:29
2  
@avakar No. Since we're passing a variable to std::forward, T would be deduced to an lvalue reference type and reference collapsing rules would ensure that the return type is that same lvalue reference type, thus the call would be an lvalue. Similarly, std::forward(0) would be an xvalue. Hence, a deducing std::forward would perfectly forward its argument and be a no-op. –  Luc Danton Oct 15 '11 at 19:40
1  
@Dave Right. But t isn't used as an rvalue reference, I'm not sure why you mention that. Do you mean binding to the parameter of std::forward? Do you understand that in template<typename T> void foo(T&&); then T&& may or may not be an rvalue reference? –  Luc Danton Oct 15 '11 at 20:29
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up vote 9 down vote accepted

If you pass an rvalue reference to an object of type X to a template function that takes type T&& as its parameter, template argument deduction deduces T to be X. Therefore, the parameter has type X&&. If the function argument is an lvalue or const lvalue, the compiler deduces its type to be an lvalue reference or const lvalue reference of that type.

If std::forward used template argument deduction:

Since objects with names are lvalues the only time std::forward would correctly cast to T&& would be when the input argument was an unnamed rvalue (like 7 or func()). In the case of perfect forwarding the arg you pass to std::forward is an lvalue because it has a name. std::forward's type would be deduced as an lvalue reference or const lvalue reference. Reference collapsing rules would cause the T&& in static_cast<T&&>(arg) in std::forward to always resolve as an lvalue reference or const lvalue reference.

Example:

template<typename T>
T&& forward_with_deduction(T&& obj)
{
    return static_cast<T&&>(obj);
}

void test(int&){}
void test(const int&){}
void test(int&&){}

template<typename T>
void perfect_forwarder(T&& obj)
{
    test(forward_with_deduction(obj));
}

int main()
{
    int x;
    const int& y(x);
    int&& z = std::move(x);

    test(forward_with_deduction(7));    //  7 is an int&&, correctly calls test(int&&)
    test(forward_with_deduction(z));    //  z is treated as an int&, calls test(int&)

    //  All the below call test(int&) or test(const int&) because in perfect_forwarder 'obj' is treated as
    //  an int& or const int& (because it is named) so T in forward_with_deduction is deduced as int& 
    //  or const int&. The T&& in static_cast<T&&>(obj) then collapses to int& or const int& - which is not what 
    //  we want in the bottom two cases.
    perfect_forwarder(x);           
    perfect_forwarder(y);           
    perfect_forwarder(std::move(x));
    perfect_forwarder(std::move(y));
}
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Great that you got your head wrapped around how and why std::forward works like it does. :) +1 –  Xeo Jan 15 '12 at 3:37
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Edit: The following demonstrates the root of my confusion. Please explain why it calls somefunc#1 instead of somefunc#2.

In ForwardingFunc x is always considered an lvalue on every use:

somefunc(forward(x));

Objects with names are always lvalues.

This is a key safety feature. If you've got a name for it, you don't want to implicitly move from it: it would be too easy to move from it twice:

foo(x);   // no implicit move
bar(x);   // else this would probably not do what you intend

In the call to forward, T deduces as int& because the argument x is an lvalue. So you are calling this specialization:

template<>
int& forward(int& x)
{
    return static_cast<int&>(x);
}

Because T deduces as int& and int& && collapses back down to int&.

Since forward(x) returns an int&, the call to somefunc perfectly matches the #1 overload.

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Ok, so why does changing forward's argument's type to typename std::identity<T>::type change what you described? –  Dave Oct 15 '11 at 23:18
3  
@Dave The argument isn't what's triggering a change. What's different is explicitly passing the template parameter. forward(x) instantiates forward<int&>, whereas the non-deduced call forward<int>(x) instantiates forward<int>. Using typename std::remove_reference<T>::type&& (or using identity) is just here to forbid std::forward(x) in the first place. –  Luc Danton Oct 16 '11 at 2:04
    
@Luc: +1. <stupid rule filler> –  Howard Hinnant Oct 16 '11 at 3:54
    
So when int& is passed to a templated function, T is deduced to be int& but when int&& or int are passed T is deduced to be int? –  Dave Oct 16 '11 at 13:55
    
Only expressions are passed as arguments. Expressions have their type adjusted by removing any reference. The expression can be an lvalue or rvalue. When an lvalue int is passed to a template parameter of the form T&&, T is deduced as int&. When an rvalue int is passed to this same parameter, T is deduced as int. –  Howard Hinnant Oct 16 '11 at 16:06
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