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My program needs to make use of void* in order to transport data or objects in dynamic invocation situation, so that it can reference data of arbitrary types, even primitive types. However, I recently discovered that the process of down-casting these void* in case of classes with multiple base classes fails and even crashes my program after invoking methods on these down casted pointers even if the memory addresses seem to be correct. The crash happens during access to "vtable".

So I have created a small test case, environment is gcc 4.2 on Mac OS X:

class Shape {
public:
    virtual int w() = 0;
    virtual int h() = 0;
};

class Square : public Shape {
public:
    int l;
    int w() {return l;}
    int h() {return l;}
};

class Decorated {
public:
    int padding;
    int w() {return 2*padding;}
    int h() {return 2*padding;}
};

class DecoratedSquare : public Square, public Decorated {
public:
    int w() {return Square::w() + Decorated::w();}
    int h() {return Square::h() + Decorated::h();}
};


#include <iostream>

template <class T> T shape_cast(void *vp) {
//    return dynamic_cast<T>(vp);   // not possible, no pointer to class type
//    return static_cast<T>(vp);
//    return T(vp);
//    return (T)vp;
    return reinterpret_cast<T>(vp);
}

int main(int argc, char *argv[]) {
    DecoratedSquare *ds = new DecoratedSquare;
    ds->l = 20;
    ds->padding = 5;
    void *dsvp = ds;

    std::cout << "Decorated (direct)" << ds->w() << "," << ds->h() << std::endl;

    std::cout << "Shape " << shape_cast<Shape*>(dsvp)->w() << "," << shape_cast<Shape*>(dsvp)->h() << std::endl;
    std::cout << "Square " << shape_cast<Square*>(dsvp)->w() << "," << shape_cast<Square*>(dsvp)->h() << std::endl;
    std::cout << "Decorated (per void*) " << shape_cast<Decorated*>(dsvp)->w() << "," << shape_cast<Decorated*>(dsvp)->h() << std::endl;
    std::cout << "DecoratedSquare " << shape_cast<DecoratedSquare*>(dsvp)->w() << "," << shape_cast<DecoratedSquare*>(dsvp)->h() << std::endl;
}

produces the following output:

Decorated (direct)30,30
Shape 30,30
Square 30,30
Decorated (per void*) 73952,73952
DecoratedSquare 30,30

As you can see, the "Decorated (per void*)" result is completely wrong. It should also be 30,30 like in the first line.

Whatever cast method I use in shape_cast() I will always get the same unexpected results for the Decorated part. Something is completely wrong with these void *.

From my understanding of C++ this should be actually working. Is there any chance to get this to work with the void*? Can this be a bug in gcc?

Thanks

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1  
You can only use reinterpret_cast to cast to void* and then back to the original type. You can NOT cast to void* and then to anything else. –  Loki Astari Mar 4 '10 at 13:54
    
You would be much better off using the decorator pattern than MI, not that that would solve the casting from void* problem. –  quamrana Mar 4 '10 at 14:42

3 Answers 3

up vote 5 down vote accepted

It's not a compiler bug - it's what reinterpret_cast does. The DecoratedSquare object will be laid out in memory something like this:

Square
Decorated
DecoratedSquare specific stuff

Converting a pointer to this to void* will give the address of the start of this data, with no knowledge of what type is there. reinterpret_cast<Decorated*> will take that address and interpret whatever is there as a Decorated - but the actual memory contents are the Square. This is wrong, so you get undefined behaviour.

You should get the correct results if you reinterpret_cast to the correct dynamic type (that is DecoratedSquare), then convert to the base class.

share|improve this answer
    
That explains it but it would mean that without knowledge of the concrete subclass I can not produce code that works on pointers to one of the base classes in a polymorphic way like it would be possible in single inheritance situations, where the caller doesn't need to know the concrete subclass. In other words, it would not be possible to compile a framework and use that later when the concrete subclasses are known? That would means multiple inheritance in C++ is not complete. –  André Pareis Mar 4 '10 at 13:30
2  
MI in C++ is complete, unless you throw away the type information. You can use virtual functions to get polymorphic behaviour without knowing concrete subclasses if you don't cast wildly to wrong types. –  Georg Fritzsche Mar 4 '10 at 13:33
    
To me, as I just don't know the concrete sub type in that part of the framework, it just means I can not use void* there. I have to carry type information somehow using an "any" or the like. Not nice and not what I had expected :( but at least you gave me an good explanation. Thanks everybody –  André Pareis Mar 4 '10 at 13:39
    
@Andre, it isn't a problem of multiple inheritance, it is a problem of casting things to void*. What works is casting a pointer to void* and then back to its original static type (not dynamic like Mike seems to imply). Casting a void* to something else is undefined (well, there are some exceptions) –  AProgrammer Mar 4 '10 at 13:39
1  
You might be able to do what you want with a reinterpret_cast to Shape followed by a dynamic_cast to Decorated. I'm not 100% sure though, so I won't add it to the answer. It may well give undefined behaviour. –  Mike Seymour Mar 4 '10 at 13:39

A static_cast or a dynamic_cast in presence of multiple inheritance may change the representation of the pointer by offsetting it so that it designate the correct address. static_cast determines the correct offset by considering static typing information. dynamic_cast does it by checking the dynamic type. If you go throw void*, you are loosing all static typing information and the possibility to get dynamic typing information, so the reinterpret_cast you are using is assuming that the offset is null, failing some times.

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so does this effectively mean that void* are not feasible in multiple inheritance situations? –  André Pareis Mar 4 '10 at 13:21
1  
It is feasible, as long as you always cast to the actual type of the object, not a base class. –  Mike Seymour Mar 4 '10 at 13:25
    
see my comment on Mike's answer –  André Pareis Mar 4 '10 at 13:33
    
More precisely, you have to cast the void* to the static type the value had before being casted to void*. –  AProgrammer Mar 4 '10 at 13:33

Repeat ten times - the only thing you can safely do with a reinterpret_cast pointer is reinterpret_cast it back to the same pointer type it came from. The same applies with conversions to void*: you must convert back to the original type.

So, if you cast a DecoratedSquare* to void*, you must cast it back to DecoratedSquare*. Not Decorated*, not Square*, not Shape*. Some of them might work on your machine, but this is a combination of good luck and implementation-specific behaviour. It usually works with single-inheritance, because there's no obvious reason to implement object pointers in a way which would stop it working, but this is not guaranteed, and it can't work in general for multiple inheritance.

You say that your code accesses "arbitrary types, including primitive types" via a void*. There's nothing wrong with this - presumably whoever receives the data knows to treat it as a DecoratedSquare* and not as, say, int*.

If whoever receives it only knows to treat it as a base class, such as Decorated*, then whoever converts it to void* should static_cast it to the base class first, then to void*:

void *decorated_vp = static_cast<Decorated*>(ds);

Now when you cast decorated_vp back to Decorated*, you'll get the result of static_cast<Decorated*>(ds), which is what you need.

share|improve this answer
    
Steve thanks for this. I very much sums it up. Indeed, it is always ensured that in the calling part of the framework there is a known base pointer type which is cast to void* and then transported to the receiving end, which knows 2 things: the topmost base class and some subclass where a method is defined. It does not know, however, the concrete subclass. But this seems to be ok now, as the receiving end always reinterpret_casts to the same topmost base class as the sending end did and then does a dynamic_cast or static_cast to the intermediate subclass where it invokes the desired method. –  André Pareis Mar 4 '10 at 14:10
    
+1 for "the only thing you can safely do with a reinterpret_cast pointer is reinterpret_cast it back to the same pointer type it came from." Sums up the situation very well indeed. –  James Johnston Oct 10 '12 at 15:59

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