This is thanks to the reference collapsing rules. Assume that `U`

is a non-reference type; then:

```
T = U T & = U & T && = U &&
If T = U & , then T & = U & and T && = U & .
T = U && T & = U & T && = U &&
```

Therefore, if your function argument can bind to an lvalue reference of type `U`

, then `T`

must be deduced as `U &`

in order for `T &&`

to become `U &`

, and this is the only choice, since lvalues cannot bind to rvalue references. On the other hand, if your argument is an rvalue of type `U`

, then `T`

is deduced as `U`

so that `T &&`

becomes `U &&`

and your argument can bind.

The key point is that matching reference type is `T &&`

(and not `T`

!). However, since `arg`

itself is a named variable and thus an lvalue, you must use `std::forward<T>(arg)`

to create an *expression* that's identical to the one with which your function was called.

`T -> T`

in the case of rvalues, actually. And I highly recommend watching this video by Scott Meyers on this specific topic. – Xeo Oct 23 '12 at 14:32