In the statement:

```
B(B&& b)
```

The **parameter** `b`

is declared with the type: rvalue reference to `B`

.

In the statement:

```
A(b)
```

The **expression** `b`

is an lvalue of type `B`

.

And lvalue expressions can not bind to rvalue references: specifically the rvalue reference in the statement:

```
A(A&& a)
```

This logic follows cleanly from other parts of the language. Consider this function:

```
void
f(B& b1, B b2, B&& b3)
{
g(b1);
g(b2);
g(b3);
}
```

Even though the parameters of `f`

are all declared with different types, the expressions `b1`

, `b2`

and `b3`

are all lvalue expressions of type `B`

, and thus would all call the same function `g`

, no matter how `g`

is overloaded.

In C++11 it is more important than ever to distinguish between a variable's declaration, and the expression that results from using that variable. And expressions never have reference type. Instead they have a *value category* of precisely one of: lvalue, xvalue, prvalue.

The statement:

```
A(std::move(c))
```

is ok, because `std::move`

returns an rvalue reference. The expression resulting from a function call returning an rvalue reference has value category: xvalue. And together with prvalues, xvalues are considered rvalues. And the rvalue expression of type `C`

:

```
std::move(c)
```

will bind to the rvalue reference parameter in: `A(A&& a)`

.

I find the following diagram (originally invented by Bjarne Stroustrup) very helpful:

```
expression
/ \
glvalue rvalue
/ \ / \
lvalue xvalue prvalue
```