Having previously been unaware of the existence of std::addressof, why it exists makes sense to me: as a way of taking the an address in the presence of an overloaded operator&. The implementation, however, is slightly more opaque. From gcc 4.7.1:

template<typename _Tp>
inline _Tp*
__addressof(_Tp& __r) _GLIBCXX_NOEXCEPT
  return reinterpret_cast<_Tp*>
(&const_cast<char&>(reinterpret_cast<const volatile char&>(__r)));

The reinterpret_cast<_Tp*> is obvious. The rest of it is dark magic. Can someone break down how this actually works?

  • Casting to char& (or char *) avoids breaking strict aliasing rules, and operator& cannot be overloaded for builtin types such as char. So you end up with a pointer to the base address of _Tp. – Praetorian Apr 24 '13 at 14:53
  • 6
    @Praetorian The aliasing rules aren't an issue here, since you don't dereference the results. The reason char is used is that it cannot have alignment requirements; if you used int, and int had stricter alignment than _Tp, the conversion might change the actual address. – James Kanze Apr 24 '13 at 15:06
  • @JamesKanze Ahh, of course, didn't think about not reading from the cast result. Good thing I posted a comment instead of an answer :) – Praetorian Apr 24 '13 at 15:10
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    @syam Using the results of the conversion (unless it is a character type) is undefined behavior, so the implementation can do anything it wants. On byte addressed machines, reinterpret_cast conversions normally do nothing at the machine code level. On word addressed machines, however, an int* will often be smaller than a char*; conversion of char* to int* will loose data. – James Kanze Apr 24 '13 at 15:21
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    @syam re "anything it wants": there is a requirement that if an address is converted to a type with doesn't have a stricter alignment requirement, and then back to the original type, the resulting pointer will compare equal to the original pointer. But that's really it, in terms of what the standard required. – James Kanze Apr 24 '13 at 15:23
up vote 29 down vote accepted
  • First you have __r which is of type _Tp&
  • It is reinterpret_cast'ed to a char& in order to ensure being able to later take its address without fearing an overloaded operator& in the original type; actually it is cast to const volatile char& because reinterpret_cast can always legally add const and volatile qualifiers even if they are not present, but it can't remove them if they are present (this ensures that whatever qualifiers _Tp had originally, they don't interfere with the cast).
  • This is const_cast'ed to just char&, removing the qualifiers (legally now! const_cast can do what reinterpret_cast couldn't with respect to the qualifiers).
  • The address is taken & (now we have a plain char*)
  • It is reinterpret_cast'ed back to _Tp* (which includes the original const and volatile qualifiers if any).

Edit: since my answer has been accepted, I'll be thorough and add that the choice of char as an intermediate type is due to alignment issues in order to avoid triggering Undefined Behaviour. See @JamesKanze's comments (under the question) for a full explanation. Thanks James for explaining it so clearly.

  • Thanks. With this and the alignment fact brought up in other posts, it all makes a lot more sense now. – Yuushi Apr 24 '13 at 15:06
  • To confirm- no conversion operators can be applied during a reinterpret_cast, right? They can only be applied during a static_cast? – templatetypedef Apr 24 '13 at 17:12
  • @templatetypedef: Yes. static_cast, dynamic_cast and legacy C casts actually perform a conversion when needed, while reinterpret_cast and const_cast only change what type compiler thinks the data is, without ever converting the data itself. – syam Apr 25 '13 at 3:55

It's actually quite simple when you think about it, to get the real adress of an object/function in precense of an overloaded operator& you will need to treat the object as something other than what it really is, some type which cannot have an overloaded operator.. an intrinsic type (such as char).

A char has no alignment and can reside anywhere any other object can, with that said; casting an object to a reference to char is a very good start.

But what about the black magic involved when doing reinterpret_cast<const volatile char&>?

In order to reinterpret the returned pointer from the implementation of addressof we will eventually want to discard qualifiers such as const and volatile (to end up with a plain reference char). These two can be added easily with reinterpret_cast, but asking it to remove them is illegal.

T1 const a; reinterpret_cast<T2&> (a);

/* error: reinterpret_cast from type ‘...’ to type ‘...’ casts away qualifiers */

It's a little bit of a "better safe than sorry" trick.. "Let us add them, just in case, we will remove them later."

Later we cast away the qualifiers (const and volatile) with const_cast<char&> to end up with a plain reference to char, this result is, as the final step, turned back into a pointer to whatever type we passed into our implementation.

A relevant question on this stage is why we didn't skip the use of reinterpret_cast and went directly to the const_cast? this too has a simple answer: const_cast can add/remove qualifiers, but it cannot change the underlying type.

T1 a; const_cast<T2&> (a);

/* error: invalid const_cast from type ‘T1*’ to type ‘T2*’ */

it might not be easy as pie, but it sure tastes good when you get it..

The short version:

operator& can't be overloaded for char. So the type is being cast to a char reference to get what's guaranteed to be the true address.

That conversion is done in two casts because of the restrictions on const_cast and reinterpret_cast.

The longer version:

It's performing three sequential casts.

reinterpret_cast<const volatile char&>

This is effectively casting to a char&. The const and volatile only exist because _Tp may be const or volatile, and reinterpret_cast can add those, but would be unable to remove them.

const_cast<const volatile char&>

Now the const and volatile have been removed. const_cast may do that.

reinterpret_cast<_Tp*> &(result)

Now the address is taken and the type is converted back to a pointer to the original type.

From inside out:

  • First it casts __r type to a const volatile char&: It's casting to a char& just because it's a type that for sure doesn't have an overloaded operator& that does something funky. The const volatile is there because those are restrictions, they can be added but not taken away with reinterpret_cast. _Tp might've already been const and/or volatile, in which case one or both were needed in this cast. If it didn't, the cast just added them needlessly, but it is written for the most restrictive cast.

  • Next, to take away the const volatile you need a const_cast, which leads to the next part... const_cast<char&>.

  • From there they simply take the address and cast it to the type you want, a _Tp*. Note that _Tp might be const and/or volatile, which mean those things could be added back at this point.

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