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.

Consider the following program:

struct ghost
    // ghosts like to pretend that they don't exist
    ghost* operator&() const volatile { return 0; }

int main()
    ghost clyde;
    ghost* clydes_address = &clyde; // darn; that's not clyde's address :'( 

How do I get clyde's address?

I'm looking for a solution that will work equally well for all types of objects. A C++03 solution would be nice, but I'm interested in C++11 solutions too. If possible, let's avoid any implementation-specific behavior.

I am aware of C++11's std::addressof function template, but am not interested in using it here: I'd like to understand how a Standard Library implementor might implement this function template.

share|improve this question
I assume the "punch anyone who overloads operator& in the head" strategy isn't acceptable? –  jalf Jun 27 '11 at 14:49
@jalf: That strategy is acceptable, but now that I've punched said individuals in the head, how do I work around their abominable code? :-) –  James McNellis Jun 27 '11 at 14:54
@jalf Uhm, sometimes you need to overload this operator, and return a proxy object. Though I can’t think of an example just now. –  Konrad Rudolph Jun 27 '11 at 15:06
@Konrad: me either. If you need that, I'd suggest that a better option might be to rethink your design, because overloading that operator just causes too many problems. :) –  jalf Jun 27 '11 at 15:20
CComPtr<> and CComQIPtr<> have an overloaded operator& –  Simon Richter Jun 27 '11 at 23:42

6 Answers 6

up vote 57 down vote accepted

Let us first copy the code from Boost, minus the compiler work around bits:

template<class T>
struct addr_impl_ref
  T & v_;

  inline addr_impl_ref( T & v ): v_( v ) {}
  inline operator T& () const { return v_; }

  addr_impl_ref & operator=(const addr_impl_ref &);

template<class T>
struct addressof_impl
  static inline T * f( T & v, long ) {
    return reinterpret_cast<T*>(
        &const_cast<char&>(reinterpret_cast<const volatile char &>(v)));

  static inline T * f( T * v, int ) { return v; }

template<class T>
T * addressof( T & v ) {
  return addressof_impl<T>::f( addr_impl_ref<T>( v ), 0 );

What happens if we pass a reference to function ?

Note: addressof cannot be used with a pointer to function

In C++ if void func(); is declared, then func is a reference to a function taking no argument and return no result. This reference to a function can be trivially converted into a pointer to function -- from @Konstantin: According to both T & and T * are indistinguishable for functions. The 1st one is an Identity conversion and the 2nd one is Function-to-Pointer conversion both having "Exact Match" rank ( table 9).

The reference to function pass through addr_impl_ref, there is an ambiguity in the overload resolution for the choice of f, which is solved thanks to the dummy argument 0, which is an int first and could be promoted to a long (Integral Promotion).

Thus we simply returns the pointer.

What happens if we pass a type with a conversion operator ?

If the conversion operator yields a T* then we have an ambiguity: for f(T&,long) an Integral Promotion is required for the second argument while for f(T*,int) the conversion operator is called on the first (thanks to @litb)

That's when addr_impl_ref kicks in. The C++ Standard mandates that a conversion sequence may contain at most one user-defined conversion. By wrapping the type in addr_impl_ref and forcing the use of a conversion sequence already, we "disable" any conversion operator that the type comes with.

Thus the f(T&,long) overload is selected (and the Integral Promotion performed).

What happens for any other type ?

Thus the f(T&,long) overload is selected, because there the type does not match the T* parameter.

Note: from the remarks in the file regarding Borland compatibility, arrays do not decay to pointers, but are passed by reference.

What happens in this overload ?

We want to avoid applying operator& to the type, as it may have been overloaded.

The Standard guarantees that reinterpret_cast may be used for this work (see @Matteo Italia's answer: 5.2.10/10).

Boost adds some niceties with const and volatile qualifiers to avoid compiler warnings (and properly use a const_cast to remove them).

  • Cast T& to char const volatile&
  • Stip the const and volatile
  • Apply the & operator to take the address
  • Cast back to a T*

The const/volatile juggling is a bit of black magic, but it does simplify the work (rather than providing 4 overloads). Note that since T is unqualified, if we pass a ghost const&, then T* is ghost const*, thus the qualifiers have not really been lost.

EDIT: the pointer overload is used for pointer to functions, I amended the above explanation somewhat. I still do not understand why it is necessary though.

The following ideone output sums this up, somewhat.

share|improve this answer
"What happens if we pass a pointer ?" part is incorrect. If we pass a pointer to some type U the addressof function the type 'T' is inferred to be 'U*' and addr_impl_ref will have two overloads: 'f(U*&, long)' and 'f(U**,int)', obviously the first one will be selected. –  Konstantin Oznobihin Jun 27 '11 at 16:01
@Konstantin: right, I had thought that the two f overloads where function templates, whereas they are regular member functions of a template class, thanks for pointing it out. (Now I just need to figure out what is the use of the overload, any tip ?) –  Matthieu M. Jun 27 '11 at 16:50
Why would it need to work around types that have a conversion function? Would it not prefer the exact match over invoking any conversion function to T*? EDIT: Now I see. It would, but with the 0 argument it would end up in a criss-cross, so would be ambiguous. –  Johannes Schaub - litb Jun 29 '11 at 20:28
@Johannes: a Chris-Cross? –  James McNellis Jun 30 '11 at 3:20
Yes, I understand. I make joke. :-) –  James McNellis Jul 1 '11 at 1:31

Essentially, you can reinterpret the object as a reference-to-char, take its address (won’t call the overload) and cast the pointer back to a pointer of your type.

The Boost.AddressOf code does exactly that, just taking additional care of volatile and const qualification.

share|improve this answer
I like this explanation better than the selected on as it can be readily understood. –  ArtB Jun 29 '11 at 19:37

The trick behind boost::addressof and the implementation provided by @Luc Danton relies on the magic of the reinterpret_cast; the standard explicitly states at §5.2.10 ¶10 that

An lvalue expression of type T1 can be cast to the type “reference to T2” if an expression of type “pointer to T1” can be explicitly converted to the type “pointer to T2” using a reinterpret_cast. That is, a reference cast reinterpret_cast<T&>(x) has the same effect as the conversion *reinterpret_cast<T*>(&x) with the built-in & and * operators. The result is an lvalue that refers to the same object as the source lvalue, but with a different type.

Now, this allows us to convert an arbitrary object reference to a char & (with a cv qualification if the reference is cv-qualified), because any pointer can be converted to a (possibly cv-qualified) char *. Now that we have a char &, the operator overloading on the object is no longer relevant, and we can obtain the address with the builtin & operator.

The boost implementation adds a few steps to work with cv-qualified objects: the first reinterpret_cast is done to const volatile char &, otherwise a plain char & cast wouldn't work for const and/or volatile references (reinterpret_cast cannot remove const). Then the const and volatile is removed with const_cast, the address is taken with &, and a final reinterpet_cast to the "correct" type is done.

The const_cast is needed to remove the const/volatile that could have been added to non-const/volatile references, but it does not "harm" what was a const/volatile reference in first place, because the final reinterpret_cast will re-add the cv-qualification if it was there in first place (reinterpret_cast cannot remove the const but can add it).

As for the rest of the code in addressof.hpp, it seems that most of it is for workarounds. The static inline T * f( T * v, int ) seems to be needed only for the Borland compiler, but its presence introduces the need for addr_impl_ref, otherwise pointer types would be caught by this second overload.

Edit: the various overloads have a different function, see @Matthieu M. excellent answer.

Well, I'm no longer sure of this either; I should further investigate that code, but now I'm cooking dinner :) , I'll have a look at it later.

share|improve this answer
Matthieu M. explanation regarding passing pointer to addressof is incorrect. Don't spoil your great answer with such edits :) –  Konstantin Oznobihin Jun 27 '11 at 16:04
"good appetit", further investigation shows that the overload is called for reference to functions void func(); boost::addressof(func);. However removing the overload does not prevent gcc 4.3.4 from compiling the code and producing the same output, so I still don't understand why it is necessary to have this overload. –  Matthieu M. Jun 27 '11 at 17:13
@Matthieu: It looks to be a bug in gcc. According to both T & and T * are indistinguishable for functions. The 1st one is an Identity conversion and the 2nd one is Function-to-Pointer conversion both having "Exact Match" rank ( table 9). So it's necessary to have additional argument. –  Konstantin Oznobihin Jun 27 '11 at 18:21
@Matthieu: Just tried it with gcc 4.3.4 (ideone.com/2f34P) and got ambiguity as expected. Did you tried overloaded member functions like in addressof implementation or free function templates? The latter one (like ideone.com/vjCRs) will result in 'T *' overload to be chosen due to temlate argument deduction rules ( –  Konstantin Oznobihin Jun 27 '11 at 18:57
@curiousguy: Why do you think it should? I've referenced specific C++ standard parts prescribing what should compiler do and all compilers I have access to (including but not limited to gcc 4.3.4, comeau-online, VC6.0-VC2010) report ambiguity just as I've described. Could you please elaborate your reasoning regarding this case? –  Konstantin Oznobihin Dec 7 '11 at 12:30

I've seen an implementation of addressof do this:

char* start = &reinterpret_cast<char&>(clyde);
ghost* pointer_to_clyde = reinterpret_cast<ghost*>(start);

Don't ask me how conforming this is!

share|improve this answer
Legal. char* is the listed exception to type aliasing rules. –  Puppy Jun 27 '11 at 15:23
@DeadMG I'm not saying this is not conforming. I'm saying that you should not ask me :) –  Luc Danton Jun 27 '11 at 15:28
+1, here is the demo that how the trick should work: ideone.com/iFHxH –  iammilind Jun 28 '11 at 3:08
@DeadMG There is no aliasing problem here. The question is: is reinterpret_cast<char*> well defined. –  curiousguy Dec 7 '11 at 15:05

Take a look at boost::addressof and its implementation.

share|improve this answer
The Boost code, while interesting, does not explain how its technique works (nor does it explain why two overloads are needed). –  James McNellis Jun 27 '11 at 14:47
do you mean 'static inline T * f( T * v, int )' overload? Looks like it needed for Borland C workaround only. Approach used there is pretty straightforward. The only subtle (nonstandard) thing there is conversion of 'T&' to 'char&'. Although standard, allows cast from 'T*' to 'char*' there seems to be no such requirements for reference casting. Nevertheless, one might expect it to work exactly the same on most compilers. –  Konstantin Oznobihin Jun 27 '11 at 15:10
@Konstantin: the overload is used because for a pointer, addressof returns the pointer itself. It's arguable whether it's what the user wanted or not, but it's how it specified. –  Matthieu M. Jun 27 '11 at 15:28
@Matthieu: are you sure? As far as I can tell, any type (including pointer types) is wrapped inside an addr_impl_ref, so the pointer overload should never be called... –  Matteo Italia Jun 27 '11 at 15:36
Does it really? ideone.com/GpdWt –  Konstantin Oznobihin Jun 27 '11 at 15:37

With C++11, just use std::addressof.

share|improve this answer
As is expressly stated in the question, "I am aware of C++11's std::addressof function template, but am not interested in using it here: I'd like to understand how a Standard Library implementor might implement this function template." –  James McNellis Apr 20 at 20:17

protected by Potatoswatter Jun 2 '13 at 15:30

Thank you for your interest in this question. Because it has attracted low-quality answers, posting an answer now requires 10 reputation on this site.

Would you like to answer one of these unanswered questions instead?

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