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.

`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`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`std:identity`

which was in fact dropper altogether from the Standard. – Luc Danton Oct 15 '11 at 19:37