Overloading operators in derived class

Question

Must I need to redefine all the overloading operators with derived type if I require to use them in derived class?

The following code compiles fine:

class Point {

public:

    Point(int X = 0, int Y = 0):x(X), y(Y) {}

    virtual ~Point() {}

    Point operator +(Point &rhs) {
        return Point(x + rhs.x, y + rhs.y);
    }

protected:
    int x, y;
};

class Vector : public Point {

public:

    Vector(int X, int Y) : Point(X, Y) {}

    ~Vector() {}

    Vector operator +(Vector &rhs) {
        return Vector(x + rhs.x, y + rhs.y);
    }
};

int main()
{
    Vector v1(1, 2);
    Vector v2(3, 2);

    Vector v3 = v2 + v1;
}

But from what I've read,

C++ Primer 4th Ed. Section 15.5.3.

If a derived class wants to make all the overloaded versions available through its type, then it must either redefine all of them or none of them.

Does the part of the quote "none of them" make any sense here?

Answer 1

What it means is that if Point had more than one operator+(), and you only redefined one of them, then only that one would be accessible in the derived class; the other overloads would be hidden. If you declare no operator+() in the derived class, then all of the parent ones are available; if you declare any in the derived class, then none of the parent ones are available.

Make sense? This case is fine: the parent declares one, and you redefine that one. No problems. If the parent declared two, though, then your child class, which only declares one, would only have access to that one.

Answer 2

Overloading operators in derived class from IBM.

A member function named f in a class A will hide all other members named f in the base classes of A, regardless of return types or arguments. The following example demonstrates this:

struct A {
  void f() { }
};

struct B : A {
  void f(int) { }
};

int main() {
  B obj_B;
  obj_B.f(3);
//  obj_B.f();
}

The compiler would not allow the function call obj_B.f() because the declaration of void B::f(int) has hidden A::f().

To overload, rather than hide, a function of a base class A in a derived class B, you introduce the name of the function into the scope of B with a using declaration. The following example is the same as the previous example except for the using declaration using A::f:

struct A {
  void f() { }
};

struct B : A {
  using A::f;
  void f(int) { }
};

int main() {
  B obj_B;
  obj_B.f(3);
  obj_B.f();
}

So if you do not overload all of them, then only the overloaded functions will be used.

Answer 3

In C++, there is no overloading across scopes derived class scopes are not an exception to this general rule.

There is no overload resolution between Derived and Base class. An example:

class B
{
    public:
    int func1(int i)
    {
        cout<<"B::func1()";
        return i+1;
    }
};



class D : public B
{
    public:
    double func1(double d)
    {
        cout<<"D::func1()";
        return d+1.3;
    }
};

int main ()
{
    D *pd = new D;

    cout << pd->func1(2)  <<endl;
    cout << pd->func1(2.3)<<endl;

    return 0;
}

The output is:

D::func1()3.3
D::func1()3.6

This same rule applies for operator member functions as well, after all they are member functions too!

So in your code example if Point had more than one operator+(), and you redefined the same operator in Derived class then only that derived class operator will be accessible to objects of derived class because that version of the function hides the other Base class versions of operator+().
If you do not redefine the operator+() in the derived class, then none of the parent class versions of the operator+() are hidden and hence accessible through objects of Derived class.

Hence the statement:
If a derived class wants to make all the overloaded versions available through its type, then it must either redefine all of them or none of them.

Also, please note that overloading, overriding and function hiding are three terms that are loosely mis-used interchangeably sometimes but they all have separate meanings.