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My question concerns the combination of public and private inheritance as a tool to separate interface and implementation in a C++ class. In this pattern, the interface base class declares the common functions (class Base0). The common implementation is carried out in a class derived virtually from the interface base (class Impl0 : virtual public Base0). This class contains any common data members. The extension classes are written in two steps. First the extended interface is defined by virtual inheritance from the interface base (class Base1 : virtual public Base0). Second, the extended implementation is carried out by deriving publicly from Base1 (for interface) and privately from Impl0 (for implementation): class Impl1 : public virtual Base1, private Impl0. My questions are the following:

(1) if the functions in the extension class define functions that require common data in Impl0, do I have to replicate that data in `Impl1'?

(2) Is there any way to avoid this replication?

As a minimal example, consider a class hierarchy for implementing the four basic arithmetic functions: add(), substr(), mult() and div(). The basic version, MathOps, contains the add() and subtr() functions. The extended version, MathOps_Extn, contains mult() and div(). The above technique gives the following class hierarchy.

#include<iostream>

using std::cout;
using std::endl;

class MathOps {
public:
  virtual int add(int x) = 0;
  virtual int subtr(int x) = 0;
};

class MathOps_Impl : public virtual MathOps {
private:
  int m_y;
public:
  MathOps_Impl(int y) : m_y(y) {
    cout << "MathOps_Impl initialized with value: " << m_y << endl;
  }

  virtual int add(int x) { return x + m_y;}
  virtual int subtr (int x) { return m_y - x;}
};

class MathOps_Extn  : public virtual MathOps {
  // Extends MathOps by adding mult() and div()                                                                                                                                 
public:
  virtual int mult(int x) = 0;
  virtual int div(int x) = 0;
};

class MathOps_Extn_Impl : public    virtual MathOps_Extn, private MathOps_Impl {
private:
  int m_y; // Have to replicate member data m_y here.                                                                                                                           
public:
  MathOps_Extn_Impl(int y) : MathOps_Impl(y), m_y(y) {
    cout << "MathOps_Extn_Impl initialized with value: " << m_y << endl;
  }

  virtual int mult(int x) {
    return x * m_y;
  }
  virtual int div(int x) {
    int quotient = x == 0? 0 : m_y/x;
    return quotient;
  }
};

int main() {                                                                                                                                           
  MathOps_Extn* B =  new MathOps_Extn_Impl(10);
  cout << "add 20: " << B->add(20) << endl;
  cout << "subtr 20: " << B->subtr(20) << endl;
  cout << "mult 2: " << B->mult(2) << endl;
  cout << "div 5: " << B->div(5) << endl;

Note the replication of m_y in MathOps_Extn_Impl. Is there any way to avoid this replication?

share|improve this question
3  
Who would want to fit arithmetic operations into an hierarchical design? –  K-ballo Jan 17 '13 at 22:27
    
go another step and have a MathOps_Extn_base? Or put m_y in MathOps –  user814628 Jan 17 '13 at 22:29
    
Why won't you use protected? But if you want to have inheritance with private modifier, then yes you have to duplicate it. Putting m_y in interfaces without changing private to protected won't change too much. Edit: about the first question, look how lookup for names works in C++. If you put m_y as protected in Impl0 then you should be able to use it in Impl1. –  Piotr Jaszkowski Jan 17 '13 at 22:37
    
@PiotrJaszkowski Thanks. I came to the same conclusion while reading through other answers on SO (that I didnt come across before posting my question). However, wont making m_y protected allow direct access to it for any (client) class that derives from MathOps_Impl (and hence break encapsulation) ? –  RDK Jan 17 '13 at 22:50
    
@K-ballo I hope you are serious about your question. It is a minimal example to explain my question. –  RDK Jan 17 '13 at 22:55

2 Answers 2

up vote 0 down vote accepted

You can give access to the common data, without breaking encapsulation, via protected member functions in the common implementation class.

Gratuitous example follows :)

#include <cstdio>

class Math
{
public:
    virtual ~Math() {}
    virtual int add(int b) const = 0;
};

class MoreMath : public virtual Math
{
public:
    virtual ~MoreMath() {}
    virtual int subtract(int b) const = 0;
};

class MathImpl : public virtual Math
{
private:
    int m_a;

public:
    MathImpl(int a) : m_a(a) {}
    virtual ~MathImpl() {}
    int add(int b) const { return m_a + b; }

protected:
    int value() const { return m_a; }
};

class MoreMathImpl : public virtual MoreMath, private MathImpl
{
public:
    MoreMathImpl(int a) : MathImpl(a) {}
    int subtract(int b) const { return value() - b; }
};

int main()
{
    MoreMath* one = new MoreMathImpl(1);
    printf("1 + 2 = %d\n", one->add(2));
    printf("1 - 2 = %d\n", one->subtract(2));
    delete one;

    return 0;
}
share|improve this answer
    
Thanks. I have accepted your answer since it avoids protected member data. –  RDK Jan 18 '13 at 17:47

Note the replication of m_y in MathOps_Extn_Impl. Is there any way to avoid this replication?

Yes. Give MathOps_Impl::m_y protected access instead of private.

You're explicitly asking why derived classes can't access private data. That's by design.

share|improve this answer
    
I am aware of the inaccessibility of private base class members. However, please see my comment to PiotrJaszkowski for my unease in using protected. May be protected is the way to go, I just feel that it break encapsulation. –  RDK Jan 17 '13 at 22:52
    
@RDK I agree with your comment that it arguably breaks encapsulation. K-ballo also makes a valid comment that the encapsulation was designed unusually. –  Drew Dormann Jan 18 '13 at 1:26

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