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My Code:

#include <iostream>

using namespace std;

class A
    virtual void print(void) { cout << "I am base class" << endl; }

class B : public A
    void print(void) { cout << "I am class B" << endl; }

void mainprint(A *a)

int main()
    A a;
    B b;

    B *bp;
    A *ap;

    ap = &b;


    bp = new B();

    mainprint((A *)bp);

    delete bp;

    return 0;


I am base class
I am class B
I am class B
I am class B

I have casted the pointer(bp) to class A inside the function call, but it still calls the derived class print!!!

Can someone shed some light on this for me.

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up vote 6 down vote accepted

I have casted the pointer(bp) to class A inside the function call, but it still calls the base class print!!!

I assume you mean "calls the derived class print", since that's what happened.

That's the whole point of virtual functions; the final override associated with the actual type of the object (i.e. the "dynamic type") is chosen, whatever the type of the reference or pointer used to call the function (i.e. the "static type"). So B::print is chosen, because bp still points to an instance of B.

If you want to force a call to A::print, you could do:


or, if you don't want polymorphic behaviour at all, remove the virtual specification.

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correct, i mean derived class print! – infinitloop Jan 24 '12 at 18:43

You have explicitly requested that behavior by making A::print() a virtual function.

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It's virtual function dispatch (i.e. runtime polymorphism), working as intended.

One way to disable virtual function dispatch is to explicity qualify function name with class name, like this:

void mainprint(A *a) 
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What were you expecting? This is how polymorphism works.

This behavior is expected and correct.



is not casting, but dereferencing.

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i never said (*a) is casting!!! :) – infinitloop Jan 24 '12 at 18:38
@rashid "I have casted the pointer(bp) to class A inside the function call"... – Luchian Grigore Jan 24 '12 at 18:41
i meant mainprint((A *)bp); please correct me if i am confusing something. – infinitloop Jan 24 '12 at 18:45
@rashid oh ok, I must have misunderstood. – Luchian Grigore Jan 24 '12 at 18:46
thats why i said function call, lol – infinitloop Jan 24 '12 at 18:46

I don't get where the problem is... the first one is a print on an actual object of type A, all the others are invocations of print over a B object (directly or via a pointer), so it calls B's print.

Keep in mind that in the function call you are not casting an object of type B to an object of type A (which results in slicing), but you're just casting a pointer to it - the object itself remains intact, and thanks to virtual dispatch even if the static type of the object is A * the correct versions of the virtual functions are invoked.

That's how virtual functions work.

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There is no problem, i am just trying to understand! – infinitloop Jan 24 '12 at 18:39
+1 for establishing the difference between a pointer-to-object & the object itself. – paul23 Jan 24 '12 at 18:47

It is not calling the base-class print, it is calling the derived class print (I am class B) on your last call which is the correct behaviour because pointers and references work with polymorphism.

If you sliced your object then called print it would indeed print the A version. You don't want to be doing that, and fortunately you haven't.

This would be slicing:

B b;
A a(b); 
A a2;
a2 = b;
A& a3 = b;

and you should get:

I am class B I am base class I am base class I am class B

because a and a2 are both objects of type a, even though you have assigned them to b. Slicing is not to be recommended but is a common error.

a3 however is a reference to an object of type A or one of its derivatives but is actually object b of type B and retains the polymorphic behaviour.

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can you please explain slicing of an object? thanks – infinitloop Jan 24 '12 at 18:40

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