Well, that's the purpose of
reinterpret_cast! As the name suggests, the purpose of that cast is to reinterpret a memory region as a value of another type. For this reason, using
reinterpret_cast you can always cast an lvalue of one type to a reference of another type.
This is described in 5.2.10/10 of the language specification. It also says there that
reinterpret_cast<T&>(x) is the same thing as
The fact that you are casting a pointer in this case is totally and completely unimportant. No, the pointer does not get automatically dereferenced (taking into account the
*reinterpret_cast<T*>(&x) interpretation, one might even say that the opposite is true: the address of that pointer is automatically taken). The pointer in this case serves as just "some variable that occupies some region in memory". The type of that variable makes no difference whatsoever. It can be a
double, a pointer, an
int or any other lvalue. The variable is simply treated as memory region that you reinterpret as another type.
As for the C-style cast - it just gets interpreted as
reinterpret_cast in this context, so the above immediately applies to it.
In your second example you attached reference
c to the memory occupied by pointer variable
pc. When you did
c = 'B', you forcefully wrote the value
'B' into that memory, thus completely destroying the original pointer value (by overwriting one byte of that value). Now the destroyed pointer points to some unpredictable location. Later you tried to dereference that destroyed pointer. What happens in such case is a matter of pure luck. The program might crash, since the pointer is generally non-defererencable. Or you might get lucky and make your pointer to point to some unpredictable yet valid location. In that case you program will output something. No one knows what it will output and there's no meaning in it whatsoever.
One can rewrite your second program into an equivalent program without references
char* pc = new char('A');
char* c = (char *) &pc;
std::cout << *pc << "\n";
*c = 'B';
std::cout << *pc << "\n";
From the practical point of view, on a little-endian platform your code would overwrite the least-significant byte of the pointer. Such a modification will not make the pointer to point too far away from its original location. So, the code is more likely to print something instead of crashing. On a big-endian platform your code would destroy the most-significant byte of the pointer, thus throwing it wildly to point to a totally different location, thus making your program more likely to crash.