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In this piece of code:

using namespace std;

class B
    int b;
    ~B(){ cout <<"B::~B()"<<endl; }//1

class D: public B
  int i,d,e,f;
  ~D() { cout <<"D::~D()"<<endl; }//2

int main(void)
    cout << "sizeB:" << sizeof(B) << " sizeD:"<< sizeof(D) <<endl;
    B *pb = new D[2];

    delete [] pb;

    return 0;

At the beginning, I dont know how delete[] work correctly. Then I notice this:

B* pb = new D[2];
&pb[1] - &pb[0] == sizeof(B);

D* pd = new D[2];
&pb[1] - &pb[0] == sizeof(D);

What did complier do? And why it worked like this?

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Can you clarify your question? It isn't clear what exactly you are asking. –  juanchopanza Jun 17 '13 at 7:47
You're not showing the output; we can hardly explain why it works "like this" when we don't know what "like this" means. –  Angew Jun 17 '13 at 7:47
In the second snippet of code, both variables are called "pd". The second pd will "shadow" the first. What happened there, then, is called a memory leak. The first "pd" is still there, still pointing to an array of 2x D, but you just can't reference it any more. So your second assignment creates a new variable and assigns it a new value. –  kfsone Jun 17 '13 at 7:57
@kfsone no, the second snippet is probably an example. It wouldn't compile otherwise. –  juanchopanza Jun 17 '13 at 8:03
The second snippet had a typo (notice that the second line uses pb, not pd). I have just fixed it. –  Gorpik Jun 17 '13 at 8:21

3 Answers 3

up vote 3 down vote accepted

There is UB here, since you are trying to delete array of type B, that has dynamic type D.

n3376 5.3.4/3:

In the second alternative (delete array) if the dynamic type of the object to be deleted differs from its static type, the behavior is undefined

Also, since you want to work polymorphycally - you should make d-tor of base class virtual.

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UB == Undefined behaviour –  Johan Lundberg Jun 17 '13 at 7:47

It is not at all clear what you are asking, but when you do this:

B* pb = new D[2];

you are dynamically allocating an array of D objects, and you are making a B* point to the first element. Here

D* pd = new D[2];

you are also allocating an array of D objects, and making a D* point to the first element.

All pointer arithmetic you perform on those pointers will be based on the size of B and D respectively. This is not what you want, since the size of B and D need not be the same.

To be clear: you do not have a "base class pointer to derived class object", you have a base class pointer to an array of derived class objects.

It seems to me that what you really want is an array of pointers to B, which you can then point towards B or D objects, i.e. a polymorphic array.

Also note that you need to declare B's destructor as virtual, as has been already pointed out.

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Firstly, pb and pd point to the same address, and because sizeof(B)!=sizeof(D), so pb + sizeof(B) != pd + sizeof(D); but when I use delete[] pb. It calls B's destructor correctly.Should they point to different address and cause error?? –  elinx Jun 17 '13 at 8:54
@elinx you should fix your question, because there is nothing in it which explains why pb and pd point to the same address. –  juanchopanza Jun 17 '13 at 8:58

First of all, you would need the destructor of B to be virtual in order to avoid undefined behaviour (UB) when you try to delete a D object through a B pointer.

But even in this case, you would be the victim of an unfortunate feature of C++, inherited from C. That is: arrays seem to work polymorphically, but they don't.

STL containers protect you against this pitfall. For instance:

std::vector<B> = std::vector<D>(2); // Illegal

But this is not the case with arrays. Your example compiles, but then strange things happen because you really have an array of D, but use it through a B*. Pointer arithmetic fails because the runtime thinks it has an array of B instead of D, and delete[] fails again because the runtime thinks it has to delete an array of B instead of D. Oh, and you could try to insert a B in your array of D when you use it through a B*; this would compile, but fail again miserably at runtime.

In summary: don't try to use containers polymorphically for the reasons you see in your code.

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