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I understand that the Diamond shaped inheritance causes ambiguity and it can be avoided by using inheritance through virtual Base Classes, the question is not about it. The question is about sizeof the most derived class in a diamond shaped hierarchy when the classes are polymorphic. Here is a sample code and the sample output:

#include<iostream>

using namespace std;

class Base
{
    public:
        virtual void doSomething(){}  
};

class Derived1:public virtual Base
{
    public:
       virtual void doSomething(){}
};

class Derived2:public virtual Base
{
    public:
       virtual void doSomething(){}
};

class Derived3:public Derived1,public Derived2
{
    public:
       virtual void doSomething(){}
};

int main()
{
    Base obj;
    Derived1 objDerived1;
    Derived2 objDerived2;
    Derived3 objDerived3;

    cout<<"\n Size of Base: "<<sizeof(obj);
    cout<<"\n Size of Derived1: "<<sizeof(objDerived1);
    cout<<"\n Size of Derived2: "<<sizeof(objDerived2);
    cout<<"\n Size of Derived3: "<<sizeof(objDerived3);

    return 0;
}

The output i get is:

 Size of Base: 4
 Size of Derived1: 4
 Size of Derived2: 4
 Size of Derived3: 8

As I understand Base contains a virtual member function and hence,
sizeof Base = size of vptr = 4 on this environment

Similar is the case Derived1 & Derived2 classes.

Here are my questions related to above scenario:
How about size of a Derived3 class object, Does it mean Derived3 class has 2 vptr?
How does the Derived3 class work with these 2 vptr, Any ideas about the mechanism it uses?
The sizeof classes is left as implementation detail of compiler & not defined by the Standard(as the virtual mechanism itself is an implementation detail of compilers)?

share|improve this question
1  
regarding the Standard question. Yes the mechanism of how to implement virtual methods is an implementation details and not specified. Yes the actual result of sizeof is an implementation details too, it notably depends on pointer size, if you were on a 64 bits platform, you would be seeing 8/8/8/16. –  Matthieu M. Mar 31 '11 at 18:12

4 Answers 4

up vote 4 down vote accepted

Yes, Derived3 has two vtable pointers. If you're accessing it by value, it uses the Derived3 version, or picks a function from a parent, or denotes that it's ambiguous if it can't decide.

In the case of a child, it uses the vtable corresponding to the parent 1/2 that's being used polymorphically.

Note that you didn't use virtual inheritance correctly: I believe Derived1 and 2 should inherit virtually from Base. sizeof(Derived3) still seems to be 8, because it still has two possible parents that could be treated as a Derived3. When you cast up to one of the parents the compiler will actually adjust the object pointer to have the correct vtable.

Also I should point out that anything vtable-related is implementation specific because there isn't even any mention of vtables in the standard.

share|improve this answer
    
Thanks, I corrected the typo of the Derived1 & Derived2 virtually inheriting from Base. The O/P is still the same. –  Alok Save Mar 31 '11 at 16:32

A small fix to your code: the virtual is supposed to be in the definition of derived2 and derived 3 in order to work.

http://www.parashift.com/c++-faq-lite/multiple-inheritance.html#faq-25.9

share|improve this answer
    
Thanks I corrected the typo –  Alok Save Mar 31 '11 at 16:39

I think you are wondering about something that is totally implementation specific. You should not assume anything about the size of the classes.

Edit: though being curious is a proven quality ;-)

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Consider a slightly different case:

struct B { virtual void f(); };
struct L : virtual B { virtual void g(); };
struct R : virtual B { virtual void h(); };
struct D : L, R {};

In a typical implementation, L::g will be in the same position (say at index 0) in L's vtable as R:h in R's vtable. Now consider what happens given the following code:

D* pd = new D;
L* pl = pd;
R* pr = pd;
pl->g();
pr->h();

In the last two lines, the compiler will generate code to find the address of the function at the same position in the vtable. So the vtable accessed through pl cannot be the same as the one (or a prefix of the one) accessed through pr. Thus, the complete object needs at least two vptr, to point to two different vtable.

share|improve this answer
    
actually in typical implementation f would probably come before g or h in the virtual table, so that no adjustement is necessary when using L or R polymorphically as a B (that is the layout of the L table will be a superset of the layout of the B table, so that the B view of it conforms to B attempts). –  Matthieu M. Mar 31 '11 at 18:11
    
@Matthieu M. Yes. In a lot of implementations, the vtable will start with one or more special pointers, to type_info information, for example, followed by the virtual functions in the base classes, in order, then the virtual functions of the class which aren't overrides of a base. The fact remains, however, that the vtable for L will have g in the same place as the vtable for R has h, so the same vtable cannot be used for both L and R in D. –  James Kanze Apr 1 '11 at 7:51
    
exact, in a lot of implementations. Building smarter vtables require whole program analysis / link-time optimization. –  Matthieu M. Apr 1 '11 at 12:23
    
Thats a interesting/convincing explanation.Thanks! –  Alok Save Apr 4 '11 at 6:07

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