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There is a forward C struct declared in an unmodifiable header. I would like to "virtually" add convenience member functions to it. Obviously my first choice would be to extend the struct and add the methods to the derived class. No-can-do, as the struct itself is declared as "forward" in the header, so I get the error "error: invalid use of incomplete type ...". I get a similar error if I try to define a new struct with a single element of the old struct. This sucks.

However, I was thinking that I could do some hackery with reinterpret_cast to get it to work anyway. The way it would go is this:

//defined in header
struct A forward;
void do_something_with_A(A* a, int arg);

//defined in my wrapper
struct B {
  B* wrap(A* a) {return reinterpret_cast<B*>(a); }
  void do_something(int arg) {do_something_with_A(reinterpret_cast<A*>(this),arg); }
}

If I added implicit conversions from type B to type A, I was thinking that this could work out almost as if B was a zero-data inheritor of A. However, this obviously brings up the question: is this undefined in C++? Normally I would think that accessing an element of an illegally casted struct would be undefined; that makes sense. However, I would think that reinterpret_casting from one type to another, passing that pointer around, and then casting back again, without doing anything illegal in between would be fine. I would also think that the way a compiler implements non-virtual struct members would be creating a function

B::do_something(B* b, int arg)

and calling that with the appropriate argument for B. This then reduces to the previous case, which by my dubious logic is okay. So I would think calling .do_something on a struct which is actually a reinterpret_cast A would be okay.

However, this says nothing for what the C++ standard actually says on the matter. Any help with that? Also, if someone has information on how well this will work practically, (i.e. "Every compiler ever made accepts this", or "this only works with a few compilers") that would also be helpful, but slightly less so.

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You can't use static_cast here unless you add relevant conversion in class B, i.e. constructor that takes A*. Anyway, either the A pointer carries no info, which means it's of no value. Or else it carries some info, in which case you're into reinterpret_cast and UB land, perhaps OK for your compiler, perhaps not. –  Cheers and hth. - Alf Aug 24 '11 at 4:37
1  
Also, I believe that in C++ structs with no data members still have a size of 1. –  Chris Lutz Aug 24 '11 at 4:40
    
Sorry, my confusion about reinterpret_cast vs static cast has muddled the issue. I will update the question. –  Jeremy Salwen Aug 24 '11 at 4:40
    
    
If you are writing code which other people are going to use, you don't want to prematurely prevent them from ever optimizing. –  Jeremy Salwen Aug 24 '11 at 6:09

2 Answers 2

up vote 1 down vote accepted

I don't believe this works if you're using static_cast because you cannot static_cast between two completely unrelated class types. To be specific, if you have a pointer of type A* and try to convert it to a pointer of type B*, the static_cast only succeeds if this declaration is valid:

B* ptr(myAPtr);

or if B is non-virtually derived from A (which it isn't). See the ISO spec §5.2.9 for details on the specifics of this. If we consider the above declaration, the only possible conversions that could be applied here in all of §4 are those in §4.10, and of those the only one that might be applicable is conversion from base to derived classes (§4.10/3), but this doesn't apply here because A and B aren't related types.

The only cast you might be able to use here is a reinterpret_cast, and it doesn't look like this will work either. In particular, the behavior of casting across class hierarchies is (§5.2.10/7)

A pointer to an object can be explicitly converted to a pointer to an object of different type.65) Except that converting an rvalue of type “pointer to T1” to the type “pointer to T2” (where T1 and T2 are object types and where the alignment requirements of T2 are no stricter than those of T1) and back to its original type yields the original pointer value, the result of such a pointer conversion is unspecified.

So immediately there's no guarantee that anything is going to work if the two objects have different alignment restrictions, and you cannot ensure that this is true. But suppose that you could. In that case, though, I believe that this will actually work correctly! Here's the reasoning. When you call the member function of the B object, then rule &5.2.2/1) kicks in and says that, since the function is nonvirtual:

[...] The function called in a member function call is normally selected according to the static type of the object expression. [...]

Okay, so we're at least calling the right function. Now, what about the this pointer? Well, according to &5.2.2/4:

[...] If the function is a nonstatic member function, the “this” parameter of the function (9.3.2) shall be initialized with a pointer to the object of the call, converted as if by an explicit type conversion (5.4). [...]

The type conversion done in the last part is the identity conversion from a B* to a B*, since that's the selected type. So you've called the right function with the this pointer set appropriately. Nice! Finally, when you do a reinterpret_cast back to the original type, by the earlier rule, you'll get back the A* object and everything will go as expected.

Of course, this only works if the objects have the same alignment requirements, and this cannot be guaranteed. Consequently, you shouldn't do it!

Hope this helps!

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But it says that alignment requirements(T2)<= alignment requirements(T!) for it to work. If I am not misinterpreting what "alignment requirements means" I would think that an empty struct has no aligment requirements, and thus has less or equally strict alignment requirements than any struct. –  Jeremy Salwen Aug 24 '11 at 4:53
    
But the point where you call do_something on an A* that's been reinterpreted as a B* that's completely unspecified. –  Mark B Aug 24 '11 at 4:59
    
@Mark: yes, certainly. I plan to hide the constructors of B so that B can only be created by a cast from A (unless you purposely do a cast from some other type to B...but hey, I can't control that.) –  Jeremy Salwen Aug 24 '11 at 5:01
1  
@Jeremy Salwen- According to the spec ($3.9/3), alignment restrictions for objects are implementation-dependent. A compliant implementation could, in theory, pick a random number to use as the alignment for each struct, or could force the empty struct to have stricter alignment restrictions than any other type. So you can't necessarily rely on this to work correctly. –  templatetypedef Aug 24 '11 at 17:57

I believe that if you cast A* to B* and then cast it back to A* again, then the standard says you are OK. Those would be reinterpret_casts though not static_casts.

But what exactly is wrong with the normal solution?

class B
{
private:
  A* ptr;
public:
  B(A* p) : ptr(p) {}
  void do_something(int arg) { do_something_with_A(ptr,arg); }
};

Seems to be as efficient as your solution and less mucking about.

share|improve this answer
    
perhaps I should be more explicit: is calling b.do_something(5) allowed when b is really of type A? And the reason I don't want to to follow your suggestion is because it is not as efficient as my solution. It does not allow unique_ptrs to the struct without an additional level of indirection. –  Jeremy Salwen Aug 24 '11 at 4:38
    
OK, understood. But now I'm not sure of the answer. My instinct says it's not OK but would probably work. –  john Aug 24 '11 at 4:41
    
But your requirements seem curious. You are clearly managing the lifetime of the A objects because you want to use unique_ptr but A is an anonymous type, so how are you managing to allocate A objects? –  john Aug 24 '11 at 4:45
    
There are library functions to both allocate and deallocate functions of type A. I wrap them using a custom deallocator and static member functions. –  Jeremy Salwen Aug 24 '11 at 4:55

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