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can you explain me why:

int main (int argc, char * const argv[]) {
    Parent* p = new Child();
    return 0;

prints "Child::Method()", and this:

int main (int argc, char * const argv[]) {
    Parent p = *(new Child());
    return 0;

prints "Parent::Method()"?


class Parent {
    void virtual Method() {
    	std::cout << "Parent::Method()";

class Child : public Parent {
    void Method() {
    	std::cout << "Child::Method()";

Thanks, Etam.

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10 Answers 10

up vote 11 down vote accepted

Your second code copies a Child object into a Parent variable. By a process called slicing it loses all information specific to Child (i.e. all private fields partial to Child) and, as a consequence, all virtual method information associated with it.

Also, both your codes leak memory (but I guess you know this).

You can use references, though. E.g.:

Child c;
Parent& p = c;
p.Method(); // Prints "Child::Method"
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I'm sure that slicing is not the cause of the symptoms in this case. – quamrana Aug 26 '09 at 9:10
Any answer to this question must contain the conceptual explanation of how polymorphism applies only to pointers and references, and in the second case 'p' is neither. By talking about slicing you're not providing the 'real' answer. It is a side-effect of what's happening, but doesn't answer the original question. – psychotik Aug 26 '09 at 9:54
I'm with @konrad. The real reason is not because you don't have a pointer or reference. But the real reason is that because the object isn't of type Child. And this is is caused by slicing. – Johannes Schaub - litb Aug 26 '09 at 16:44

In the first case you call the actual object is of Child class:

Parent* p = new Child(); // you new'ed Child class
p->Method(); // and a method of a Child class object is getting called

that's why Child::Method() is called. In the second case you copy the Child class object onto the Parent class object:

Parent p = *(new Child()); // you new'ed Child, then allocated a separate Parent object on stack and copied onto it
p.Method(); // now you have a Parent object and its method is called

and Parent::Method() is called.

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You've commented about what happens, which is what the OP states. Can you explain why it happens? – quamrana Aug 26 '09 at 9:19
That's because the virtual method is called depending on the actual object type, not the pointer type. In the first case the object is of Child class type, in the second one - of Parent class type. – sharptooth Aug 26 '09 at 9:42
@sharptooth: Yes, in the first case there is a virtual method call through a pointer, but in the second case there is no virtual method call, only a direct call to Parent::Method() – quamrana Aug 26 '09 at 9:52
Sure, and Parent::Method() is called. What's the question? – sharptooth Aug 26 '09 at 9:58
@sharptooth: The question is why is Parent::Method() called. I'm sure the answer is that its not a call to a virtual method, but a direct call. – quamrana Aug 26 '09 at 10:01

What happens if you do this?

int main (int argc, char * const argv[]) {
    Parent &p = *(new Child());
    return 0;

That has the same "syntactic" effect (p doesn't require dereferencing to use it), but the semantic effect is now completely different because you're no longer copying part of a Child into a Parent.

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Like the pointer version from the OP, your Parent& is really only a pointer, so no bits of a Child are copied, only its address. The p.Method() call is now polymorphic. – quamrana Aug 26 '09 at 9:09
This is really bad code, though, since it leaks memory that can never be retrieved in a reliable manner (sure, you can call delete &p but that's non-standard code). – Konrad Rudolph Aug 26 '09 at 9:10
@Konrad: Can we leave memory leaks out of this for the moment? – quamrana Aug 26 '09 at 9:16
@Konrad, that's perfectly standard code. Nothing wrong with that - except when Parent overloads operator& and it returns something funky - but i take it that's not the case here. – Johannes Schaub - litb Aug 26 '09 at 16:47
@litb: Just to be clear, I’m taking issue with the usage of new here, which allocates heap space. But since it’s only a temporary, the address is lost and can never be retrieved in a standards compliant manner. How will it be freed? – Konrad Rudolph Aug 26 '09 at 17:28

Virtual behaviour is only available when the virtual function is called via a pointer or a reference. When you say:

Parent p = *(new Child());

you have an actual Parent object, so Parent's method will always be called, no matter what you assign to p.

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@Neil: virtual methods will be called just fine without a pointer or reference. Declare a Child on the stack and it's virtual methods will be called just spiffy. – Michael Kohne Aug 26 '09 at 9:12
A virtual methos will be called, but you won't get virtual behaviour. – anon Aug 26 '09 at 9:36
@Michael: Yes virtual methods will be called but as Neil said (I am just rephrasing), You won't get polymorphic behavior because there won't be a lookup to vtable involved in this case. – Aamir Aug 26 '09 at 9:56

In your second example, slicing occurs: the Child-instance is converted to a Parent-instance, which has no vtable entry for the Child-method. The Child-method is "sliced" off.

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I originally thought it was slicing, but I don't think this is the mechanism. Its simply not a polymorphic call. – quamrana Aug 26 '09 at 9:04
As far as I know, slicing occurs when an instance of a derived class is copied as a base. Usually occurs when not accepting references or pointers as function arguments, but this is basically the same thing. Correct me if I'm wrong though. – jp. Aug 26 '09 at 9:09
@quamrana: It's not a polymorphic call because Parent isn't a derived type. A Child is created via new. A Parent is created on the stack and then set equal to the Child (i.e. the Child is sliced down to a Parent). A method is then called in the Parent. Oh, and the memory from newing the Child has been leaked. – Michael Kohne Aug 26 '09 at 9:10
@Michael: Its not a polymorphic call because pointers (or references) are not involved, and not because of slicing. I'm pretty sure that the v-table would be copied across, but its not used because C++ is sure that the type is a Parent and it doesn't have to go through the v-table for the method call. – quamrana Aug 26 '09 at 9:15

Your first case is simple. An instance of Child is created and asigned to p. So calling p->Method() calls Child::Method().

In the second case, four things happen:

  1. An instance of the Child class, identified by a compiler-assigned temporary variable, is created.
  2. An instance of of the Parent class, identified by the variable p is created.
  3. The copy constructor Parent::Parent(Parent&) is called when p is instantiated to copy the Parent 'slice' of the state of the Child instance to p. Note that if you don't define this copy constructor then the compiler creates it for you.
  4. You call Method() on p, which is an instance of Parent.

Try explicitly defining the copy constructor and you'll see that it is called.

Your possible confusion is probably because the assignments (=) in the two examples do different things. In the first example its simply setting one pointer equal to another, and there is only one object. In the second there are no pointers, so you're assigning (slicing) value. This invokes the copy constructor, and you get two objects (a Child and a Parent). The fact that the compiler is creating an invisible temporary variable doesn't help in understanding whats going on. You might check-out this article on copy constructors.

This is an easy mistake to make if you're used to languages like Java or C# where basically everything is a reference (aka a pointer).

As others have said, polymorphism only works with pointers and references, and these are not used in your second example.

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In the first case, you've got a 'Parent' pointer on a 'Child' object, which is somehow generic, since 'Child' inherits from 'Parent'. Hence the overloaded 'Child' method is called.

In the second case, you make an implicit cast of a 'Child' instance to the type 'Parent', hence you're calling the method on a 'Parent' object.

Hope this helps.

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Polymorphism in C++ is only possible with pointers. The differentiation between the static and the dynamic type (in your first example p is of static type Parent*, but of dynamic type Child*, and this enables C++ to call the derived class' method) does not come into play with non-pointers.

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“Polymorphism in C++ is only possible with pointers.” … and references. Which are not pointers. – Konrad Rudolph Aug 26 '09 at 9:11
Yes, you're right. Let's say "with reference semantics". – Thomas Aug 26 '09 at 11:14

In the first case, the type of the object pointed by pointer p is of 'Child' type. Since child is overriding the virtual method defined in the base class, child's method is called. In the second case, you have copied the child object into a parent object. Here the object slicing occurs and the type of the resultant object is of type 'Parent'. Hence when you call the method, parent's method is called.

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In your first example you call Method through a pointer:


In this case 'p' is a pointer to a Parent, and C++ knows that Parent has a v-table, so it uses that to find the actual method to call, which in this case as you state is Child::Method() because when C++ finds the v-table, it finds the v-table of the 'new' Child instance.

In the second example you call Method on an instance:


In this case 'p' is an instance of Parent and C++ assumes that it knows that the exact type is indeed 'Parent' and so it calls Parent::Method() without going through any v-tables.

I've just checked this with VS2008 and the above is actually what happens and there's no slicing, however, I think that slicing does occur, but you would only see it in the second case if you did:

Parent& q=p;

Then I see: Parent::Method() being printed. q.Method() must be a virtual call, but it can only find the v-table for Parent.

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