1. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 1Winter Quarter Inheritance and Overloading Lecture 28

2. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 2Winter Quarter Inheritance Objects are often defined in terms of hierarchical classes with a base class and one or more levels of classes that inherit from the classes that are above it in the hierarchy. For instance, graphics objects might be defined as follows:

3. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 3Winter Quarter Inheritance (continued) This hierarchy could, of course, be continued for more levels. Each level inherits the attributes of the above level. Shape is the base class. 2-D and 3-D are derived from Shape and Circle, Square, and Triangle are derived from 2-D. Similarly, Sphere, Cube, and Tetrahedron are derived from 3-D.

4. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 4Winter Quarter Inheritance (continued) class A : base class access specifier B { member access specifier(s):... member data and member function(s);... } Valid access specifiers include public, private, and protected

5. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 5Winter Quarter Public Inheritance public base class (B) public members protected members private members derived class (A) public protected inherited but not accessible class A : public B {// Class A now inherits the members of Class B // with no change in the “access specifier” for }// the inherited members

6. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 6Winter Quarter Protected Inheritance protected base class (B) public members protected members private members derived class (A) protected inherited but not accessible class A : protected B {// Class A now inherits the members of Class B // with public members “promoted” to protected }// but no other changes to the inherited members

7. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 7Winter Quarter Private Inheritance private base class (B) public members protected members private members derived class (A) private inherited but not accessible class A : private B {// Class A now inherits the members of Class B // with public and protected members }// “promoted” to private

8. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 8Winter Quarter Inheritance (continued) class Shape { public: int GetColor ( ) ; protected:// so derived classes can access it int color; }; class Two_D : public Shape { // put members specific to 2D shapes here }; class Three_D : public Shape { // put members specific to 3D shapes here };

9. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 9Winter Quarter Inheritance (continued) class Square : public Two_D { public: float getArea ( ) ; protected: float edge_length; } ; class Cube : public Three_D { public: float getVolume ( ) ; protected: float edge_length; } ;

10. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 10Winter Quarter Inheritance (continued) int main ( ) { Square mySquare; Cube myCube; mySquare.getColor ( ); // Square inherits getColor() mySquare.getArea ( ); myCube.getColor ( ); // Cube inherits getColor() myCube.getVolume ( ); }

11. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 11Winter Quarter Function Overloading C++ supports writing more than one function with the same name but different argument lists. This could include: –different data types –different number of arguments The advantage is that the same apparent function can be called to perform similar but different tasks. The following will show an example of this.

12. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 12Winter Quarter Function Overloading void swap (int *a, int *b) ; void swap (float *c, float *d) ; void swap (char *p, char *q) ; int main ( ) { int a = 4, b = 6 ; float c = 16.7, d = -7.89 ; char p = 'M', q = 'n' ; swap (&a, &b) ; swap (&c, &d) ; swap (&p, &q) ; }

13. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 13Winter Quarter Function Overloading void swap (int *a, int *b) { int temp; temp = *a; *a = *b; *b = temp; } void swap (float *c, float *d) { float temp; temp = *c; *c = *d; *d = temp; } void swap (char *p, char *q) { char temp; temp = *p; *p = *q; *q = temp; }

14. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 14Winter Quarter Function Templates We have discussed overloaded functions as a way to perform similar operations on data of different types. The swap functions were an example. We wrote three functions with the same name but different data types to perform the swap operations. Then we could call swap (&a, &b), for example, and C++ would select which function to use by matching the data type of a and b to one of the functions.

15. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 15Winter Quarter Function Templates Another way to perform this task would be to create a function template definition. With a function template defined, when we call swap (&a, &b), C++ will generate the object code functions for us. The program on the following slides is an example.

16. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 16Winter Quarter Function Templates template void swap (T *a, T *b) { T temp; temp = *a; *a = *b; *b = temp; } T is a “dummy” type that will be filled in by the compiler as needed a and b are of “type” T temp is of “type” T swap is a function template, NOT a function

17. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 17Winter Quarter Function Templates int main ( ) { int a = 5, b = 6; float c = 7.6, d = 9.8; char e = 'M', f = 'Z'; swap (&a, &b);// compiler puts int in for T swap (&c, &d);// compiler puts float in for T swap (&e, &f);// compiler puts char in for T cout << "a=" << a << " and b=" << b << endl; cout << "c=" << c << " and d=" << d << endl; cout << "e=" << e << " and f=” << f << endl; }

18. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 18Winter Quarter Operator Overloading C++ already has a number of types (e.g., int, float, char, etc.) that each have a number of built in operators. For example, a float can be added to another float and stored in yet another float with use of the + and = operators: floatC = floatA + floatB; In this statement, floatB is passed to floatA by way of the + operator. The + operator from floatA then generates another float that is passed to floatC via the = operator. That new float is then stored in floatC by some method outlined in the = function.

19. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 19Winter Quarter Operator Overloading (continued) Operator overloading means that the operators: –Have multiple definitions that are distinguished by the types of their parameters, and –When the operator is used, the C++ compiler uses the types of the operands to determine which definition should be used.

20. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 20Winter Quarter Operator Overloading (continued) A programmer has the ability to re-define or change how the operators (+, -, *, /, =, >, etc.) work on their own classes. Overloading operators usually consists of defining a class member function called operator+ (where + is any operator). Note that operator is a reserved word in C++. If anything usually follows that operator, it is passed to the function. That function acts exactly like any other member function; it has the same scope as other member functions and can return a value just like any other member function.

21. Engineering H192 - Computer Programming The Ohio State University Gateway Engineering Education Coalition Lect 28P. 21Winter Quarter Operator Overloading (continued) Steps for defining an overloaded operator: 1. Name the operator being overloaded. 2.Specify the (new) types of parameters (operands) the operator is to receive. 3.Specify the type of value returned by the operator. 4.Specify what action the operator is to perform.