Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Originally being the topic of this question, it emerged that the OP just overlooked the dereference. Meanwhile, this answer got me and some others thinking - why is it allowed to cast a pointer to a reference with a C-style cast or reinterpret_cast?

int main() {
    char  c  = 'A';
    char* pc = &c;

    char& c1 = (char&)pc;
    char& c2 = reinterpret_cast<char&>(pc);

The above code compiles without any warning or error (regarding the cast) on Visual Studio while GCC will only give you a warning, as shown here.

My first thought was that the pointer somehow automagically gets dereferenced (I work with MSVC normally, so I didn't get the warning GCC shows), and tried the following:

#include <iostream>

int main() {
    char  c  = 'A';
    char* pc = &c;

    char& c1 = (char&)pc;
    std::cout << *pc << "\n";

    c1 = 'B';
    std::cout << *pc << "\n";

With the very interesting output shown here. So it seems that you are accessing the pointed-to variable, but at the same time, you are not.

Ideas? Explanations? Standard quotes?

share|improve this question

4 Answers 4

up vote 28 down vote accepted

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 *reinterpret_cast<T*>(&x).

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

int main(){
    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.

share|improve this answer
But why? I figured it out after some 15 minutes of poring over the standard, with @litb trying to explain it to me. But disregarding any notion of "purpose", where does it say that this cast is well-formed? –  jalf May 7 '11 at 22:05
@jalf: It says so in 5.2.10/10. Any lvalue can be converted to any other reference type. –  AnT May 7 '11 at 22:09
I did not know about the reinterpret_cast<T&>(x) <==> *reinterpret_cast<T*>(&x) equivalence. Interesting. –  James McNellis May 7 '11 at 22:22
Excellent answer. +1 –  jalf May 8 '11 at 9:33
Well, this concludes it pretty much, thanks for such an exhaustive answer! :) –  Xeo May 8 '11 at 10:56

It took me a while to grok it, but I think I finally got it.

The C++ standard specifies that a cast reinterpret_cast<U&>(t) is equivalent to *reinterpret_cast<U*>(&t).

In our case, U is char, and t is char*.

Expanding those, we see that the following happens:

  • we take the address of the argument to the cast, yielding a value of type char**.
  • we reinterpret_cast this value to char*
  • we dereference the result, yielding a char lvalue.

reinterpret_cast allows you to cast from any pointer type to any other pointer type. And so, a cast from char** to char* is well-formed.

share|improve this answer
Equivalent to *reinterpret_cast<U*>(&t) with the built-in/non-overloaded meaning of & and * operators, as emphasized in 5.2.10/10. boost::addressof takes advantage of that fine distinction. –  usta May 8 '11 at 12:22

Its allowed because C++ allows pretty much anything when you cast.

But as for the behavior:

  • pc is a 4 byte pointer
  • (char)pc tries to interpret the pointer as a byte, in particular the last of the four bytes
  • (char&)pc is the same, but returns a reference to that byte
  • When you first print pc, nothing has happened and you see the letter you stored
  • c = 'B' modifies the last byte of the 4 byte pointer, so it now points to something else
  • When you print again, you are now pointing to a different location which explains your result.

Since the last byte of the pointer is modified the new memory address is nearby, making it unlikely to be in a piece of memory your program isn't allowed to access. That's why you don't get a seg-fault. The actual value obtained is undefined, but is highly likely to be a zero, which explains the blank output when its interpreted as a char.

share|improve this answer
C++ doesn't allow pretty much anything when you cast. Try casting an int to std::string. You can't. –  jalf May 8 '11 at 9:36
@jaff, ok true. But it doesn't restrict you to only casts that make sense. –  Winston Ewert May 8 '11 at 13:59

when you're casting, with a C-style cast or with a reinterpret_cast, you're basically telling the compiler to look the other way ("don't you mind, I know what I'm doing").

C++ allows you to tell the compiler to do that. That doesn't mean it's a good idea...

share|improve this answer
Yes, we already got that from the linked answer. I'm searching for the reason why and how it works, especially the second example. –  Xeo May 7 '11 at 22:02

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.