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In C++, the T q = dynamic_cast<T>(p); construction performs a runtime cast of a pointer p to some other pointer type T that must appear in the inheritance hierarchy of the dynamic type of *p in order to succeed. That is all fine and well.

However, it is also possible to perform dynamic_cast<void*>(p), which will simply return a pointer to the "most derived object" (see 5.2.7::7 in C++11). I understand that this feature probably comes out for free in the implementation of the dynamic cast, but is it useful in practice? After all, its return type is at best void*, so what good is this?

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6  
Just a guess, but couldn't that be used to unambiguously determine object identity? –  Björn Pollex Nov 14 '11 at 15:24
    
@BjörnPollex: But so would p... is there a situation where p1 == p2, but dynamic_cast<void*>(p1) != dynamic_cast<void*>(p2)? –  Kerrek SB Nov 14 '11 at 15:25
7  
Ah, I see what you mean: We could have p1 != p2, but in fact they point the same object. I guess if we had an index keyed on void * that'd make sense. (Though the void pointer itself would no longer be usable.) –  Kerrek SB Nov 14 '11 at 15:27
1  
That's what I meant. –  Björn Pollex Nov 14 '11 at 15:28
2  
@BjörnPollex: You should beef that comment up into an answer -- it sounds like a reasonable idea, surely worth having a post. –  Kerrek SB Nov 14 '11 at 15:41

7 Answers 7

up vote 55 down vote accepted
+150

The dynamic_cast<void*>() can indeed be used to check for identity, even if dealing with multiple inheritance.

Try this code:

#include <iostream>

class B {
public:
    virtual ~B() {}
};

class D1 : public B {
};

class D2 : public B {
};

class DD : public D1, public D2 {
};

namespace {
    bool eq(B* b1, B* b2) {
        return b1 == b2;
    }

    bool eqdc(B* b1, B *b2) {
        return dynamic_cast<void*>(b1) == dynamic_cast<void*>(b2);
    }
};

int
main() {
    DD *dd = new DD();
    D1 *d1 = dynamic_cast<D1*>(dd);
    D2 *d2 = dynamic_cast<D2*>(dd);

    std::cout << "eq: " << eq(d1, d2) << ", eqdc: " << eqdc(d1, d2) << "\n";
    return 0;
}

Output:

eq: 0, eqdc: 1
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I'm awarding the bounty to this question mainly because I feel that none of the other answers added anything profoundly new. That wasn't the original intention, but I didn't want to let the bounty go to waste. If anyone comes up with a new good answer (or edits an existing answer), I'll be happy to start another "reward" bounty! –  Kerrek SB Nov 23 '11 at 17:29

Bear in mind that C++ lets you do things the old C way.

Suppose I have some API in which I'm forced to smuggle an object pointer through the type void*, but where the callback it's eventually passed to will know its dynamic type:

struct BaseClass {
    typedef void(*callback_type)(void*);
    virtual callback_type get_callback(void) = 0;
    virtual ~BaseClass() {}
};

struct ActualType: BaseClass {
    callback_type get_callback(void) { return my_callback; }

    static void my_callback(void *p) {
        ActualType *self = static_cast<ActualType*>(p);
        ...
    }
};

void register_callback(BaseClass *p) {
   // service.register_listener(p->get_callback(), p); // WRONG!
   service.register_listener(p->get_callback(), dynamic_cast<void*>(p));
}

The WRONG! code is wrong because it fails in the presence of multiple inheritance (and isn't guaranteed to work in the absence, either).

Of course, the API isn't very C++-style, and even the "right" code can go wrong if I inherit from ActualType. So I wouldn't claim that this is a brilliant use of dynamic_cast<void*>, but it's a use.

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3  
Well, but my_callback could say dynamic_cast<ActualType*>(static_cast<BaseClass*>(p)), non? In other words, we could use BaseClass* as the basis for the C wrapper. –  Kerrek SB Nov 14 '11 at 16:10
    
@Kerrek: yes, I think you could. For that matter, you could add another virtual function BaseClass::get_this_for_callback, and let each derived class have complete control how to package the pointer. –  Steve Jessop Nov 14 '11 at 16:19
    
@SteveJessop : Just curious, if p is being passed back through a void* in my_callback, why would it matter if p is cast to the most derived type as the second argument of register_listener in the presence of multiple inheritance? I ask because inside of my_callback you're doing a static_cast to an ActualType*, so it does not seem like it really matters if a pointer to the most derived type, or a pointer to the base-class is past to my_callback ... either way it will end up being a pointer to an ActualType object, right? –  Jason Nov 20 '11 at 10:26
    
@Jason: no. With multiple inheritance, and assuming some bases aren't empty, then the address of at least one of the bases is different from the address of the most-derived object. The static cast from void* to ActualType* only results in the right pointer value if the input is the address of an ActualType object, so if BaseClass happens to be the base that's at a different address, then it will go wrong. –  Steve Jessop Nov 20 '11 at 17:44
    
@SteveJessop : Great, thanks for clarifying that :-) –  Jason Nov 20 '11 at 17:55

Casting pointers to void* has its importance since way back in C days. Most suitable place is inside the memory manager of Operating System. It has to store all the pointer and the object of what you create. By storing it in void* they generalize it to store any object on to the memory manager data structure which could be heap/B+Tree or simple arraylist.

For simplicity take example of creating a list of generic items(List contains items of completely different classes). That would be possible only using void*.

standard says that dynamic_cast should return null for illegal type casting and standard also guarantees that any pointer should be able to type cast it to void* and back from it with only exception of function pointers.

Normal application level practical usage is very less for void* typecasting but it is used extensively in low level/embedded systems.

Normally you would want to use reinterpret_cast for low level stuff, like in 8086 it is used to offset pointer of same base to get the address but not restricted to this.

Edit: Standard says that you can convert any pointer to void* even with dynamic_cast<> but it no where states that you can not convert the void* back to the object.

For most usage, its a one way street but there are some unavoidable usage.

It just says that dynamic_cast<> needs type information for converting it back to the requested type.

There are many API's that require you to pass void* to some object eg. java/Jni Code passes the object as void*.
Without type info you cannot do the casting.If you are confident enough that type requested is correct you can ask compiler to do the dynmaic_cast<> with a trick.

Look at this code:

class Base_Class {public : virtual void dummy() { cout<<"Base\n";} };
class Derived_Class: public Base_Class { int a; public: void dummy() { cout<<"Derived\n";} };
class MostDerivedObject : public Derived_Class {int b; public: void dummy() { cout<<"Most\n";} };
class AnotherMostDerivedObject : public Derived_Class {int c; public: void dummy() { cout<<"AnotherMost\n";} };

int main () {
  try {
    Base_Class * ptr_a = new Derived_Class;
    Base_Class * ptr_b = new MostDerivedObject;
    Derived_Class * ptr_c,*ptr_d;

        ptr_c = dynamic_cast< Derived_Class *>(ptr_a);
        ptr_d = dynamic_cast< Derived_Class *>(ptr_b);

        void* testDerived = dynamic_cast<void*>(ptr_c);
        void* testMost = dynamic_cast<void*>(ptr_d);
        Base_Class* tptrDerived = dynamic_cast<Derived_Class*>(static_cast<Base_Class*>(testDerived));
        tptrDerived->dummy();
        Base_Class* tptrMost = dynamic_cast<Derived_Class*>(static_cast<Base_Class*>(testMost));
        tptrMost->dummy();
        //tptrMost = dynamic_cast<AnotherMostDerivedObject*>(static_cast<Base_Class*>(testMost));
        //tptrMost->dummy(); //fails

    } catch (exception& my_ex) {cout << "Exception: " << my_ex.what();}
    system("pause");
  return 0;
}

Please correct me if this is not correct in any way.

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+1 do you have a few links on that, as I am interested in such "low level stuff" –  Sim Nov 17 '11 at 20:33
    
code.google.com/p/c-generic-library This link has code for generic data structure. –  Praveen Nov 18 '11 at 7:30
2  
You can't do a dynamic_cast on a void* according to the C++ standard section 5.2.7/2 ... So using dynamic_cast to recover the type of a void* in a generic data-structure won't work, even if that void* was generated through a dynamic_cast<void*> operation. The pointer the cast is being performed on must be a pointer to a complete class type. –  Jason Nov 20 '11 at 10:08
    
Indeed. I'm afraid this answer is missing the point somewhat. I'm aware of general void pointers. The question, however, is specifically about dynamic_cast on a pointer to a polymorphic class. –  Kerrek SB Nov 20 '11 at 12:35
    
Indeed dynamic_cast<> is one way street but you can get the object back from it if you are sure about the type info of the object. Apart from it there is no portable usage of it with out type info other than comparing the pointers. But it is there as language feature because it is possible to do so, Language can only warrant you about its usage. The same goes with reinterpret_cast<>. –  Praveen Nov 21 '11 at 20:44

it is usefull when we put the storage back to memory pool but we only keep a pointer to the base class. This case we should figure out the original address.

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Hm... can you elaborate on a situation where this would be useful? –  Kerrek SB Nov 22 '11 at 3:10
    
This makes more sense to me now: You can say p->~T(); followed by placement-new via some hinted factory like T::create_inplace(dynamic_cast<void*>(copy_of_p));. –  Kerrek SB Aug 9 '12 at 14:18

Don't do that at home

struct Base {
    virtual ~Base ();
};

struct D : Base {};

Base *create () {
    D *p = new D;
    return p;
}

void *destroy1 (Base *b) {
    void *p = dynamic_cast<void*> (b);
    b->~Base ();
    return p;
}

void destroy2 (void *p) {
    operator delete (p);
}

int i = (destroy2 (destroy1 (create ())), i);

Warning: This will not work if D is defined as:

struct D : Base {
    void* operator new (size_t);
    void operator delete (void*);
};

and there is no way to make it work.

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And you complained about my code being unwise ;-) –  Steve Jessop Nov 23 '11 at 9:32
    
@SteveJessop OK, I have put the big warning message. –  curiousguy Nov 24 '11 at 2:11

This might be one way to provide an Opaque Pointer through an ABI. Opaque Pointers -- and, more generally, Opaque Data Types -- are used to pass objects and other resources around between library code and client code in such a way that the client code can be isolated from the implementation details of the library. There are other ways to accomplish this, to be sure, and maybe some of them would be better for a particular use case.

Windows makes a lot of use of Opaque Pointers in its API. HANDLE is, I believe, generally an opaque pointer to the actual resource you have a HANDLE to, for example. HANDLEs can be Kernel Objects like files, GDI objects, and all sorts of User Objects of various kinds -- all of which must be vastly different in implementation, but all are returned as a HANDLE to the user.

#include <iostream>
#include <string>
#include <iomanip>
using namespace std;


/*** LIBRARY.H ***/
namespace lib
{
    typedef void* MYHANDLE;

    void        ShowObject(MYHANDLE h);
    MYHANDLE    CreateObject();
    void        DestroyObject(MYHANDLE);
};

/*** CLIENT CODE ***/
int main()
{
    for( int i = 0; i < 25; ++i )
    {
        cout << "[" << setw(2) << i << "] :";
        lib::MYHANDLE h = lib::CreateObject();
        lib::ShowObject(h);
        lib::DestroyObject(h);
        cout << "\n";
    }
}

/*** LIBRARY.CPP ***/
namespace impl
{
    class Base { public: virtual ~Base() { cout << "[~Base]"; } };
    class Foo   : public Base { public: virtual ~Foo() { cout << "[~Foo]"; } };
    class Bar   : public Base { public: virtual ~Bar() { cout << "[~Bar]"; } };
};

lib::MYHANDLE lib::CreateObject()
{
    static bool init = false;
    if( !init )
    {
        srand((unsigned)time(0));
        init = true;
    }

    if( rand() % 2 )
        return static_cast<impl::Base*>(new impl::Foo);
    else
        return static_cast<impl::Base*>(new impl::Bar);
}

void lib::DestroyObject(lib::MYHANDLE h)
{
    delete static_cast<impl::Base*>(h);
}

void lib::ShowObject(lib::MYHANDLE h)
{
    impl::Foo* foo = dynamic_cast<impl::Foo*>(static_cast<impl::Base*>(h));
    impl::Bar* bar = dynamic_cast<impl::Bar*>(static_cast<impl::Base*>(h));

    if( foo ) 
        cout << "FOO";
    if( bar )
        cout << "BAR";
}
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Interesting - but are you sure that static_cast<Base*>(dynamic_cast<void*>(pointer_to_base)) is correct? For example, the resulting pointer can no longer be dynamically-cast to to void-pointer, and in fact it's not usable anymore at all. –  Kerrek SB Nov 22 '11 at 18:47
    
dynamic_cast<void*>(new impl::Foo) hug? –  curiousguy Nov 23 '11 at 9:19
    
@KerrekSB I am pretty sure the code has UB. –  curiousguy Nov 23 '11 at 9:20
    
@Kerrek: I am pretty sure the code is correct, and does not exhibit UB. See for example: 5.2.9/10: "An rvalue of type “pointer to cv1 void” can be converted to an rvalue of type “pointer to cv2 T,” where T is an object type and cv2 is the same cv-qualification as, or greater cv-qualification than, cv1. A value of type pointer to object converted to “pointer to cv void” and back to the original pointer type will have its original value." –  John Dibling Nov 23 '11 at 14:56
    
@JohnDibling: I think I managed to cause a crash with that construction, though. Imagine: If you have a Base * p; that points to a derived object x, then static_cast<Base*>(dynamic_cast<void*>(p)) is the same as reinterpret_cast<Base*>(&x), and not static_cast<Base*>(&x). –  Kerrek SB Nov 23 '11 at 15:48

Expanding on @BruceAdi's answer and inspired by this discussion, here's a polymorphic situation which may require pointer adjustment. Suppose we have this factory-type setup:

struct Base { virtual ~Base() = default; /* ... */ };
struct Derived : Base { /* ... */ };

template <typename ...Args>
Base * Factory(Args &&... args)
{
    return ::new Derived(std::forward<Args>(args)...);
}

template <typename ...Args>
Base * InplaceFactory(void * location, Args &&... args)
{
    return ::new (location) Derived(std::forward<Args>(args)...);
}

Now I could say:

Base * p = Factory();

But how would I clean this up manually? I need the actual memory address to call ::operator delete:

p->~Base();              // OK thanks to virtual destructor

// ::operator delete(p); // Error!

::operator delete(dynamic_cast<void*>(p)); // OK

Or I could re-use the memory:

void * addr = dynamic_cast<void*>(p);
p->~Base();
p = InplaceFactory(addr, "some", "arguments");

delete p;  // OK now
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