Interfaces and Polymorphism

1. Interfaces and Polymorphism 9.1 Using Interfaces for Code Reuse 9.1.1 Defining an Interface 9.1.2 implementing an interface 9.2 Converting between Class and Interface Types 9.3 Polymorphism 9.4 Callbacks

2. Assignment • Read Sections 9.1-9.3 and do self check exercises 1-7. • Read Section 9.4 and do self-check exercises 8-10. • Review Exercises: • R9.1 – R9.4, R9.6, R9.8 • Due Tuesday, January 22, 2013 • Programming Exercises: • P9.1, 9.2, and 9.4 (9.5 & 9.6) • Due Friday, February 1, 2013

3. Interface • A Java interface declares a set of methods and their signatures. Unlike a class, it provides no implementation. • To realize (implement) an interface, a class must supply all the methods that the interface requires.

4. A Java interface declares methods that classes are expected to implement. It encapsulates a set of associated behaviors that can be used by classes that are not similar. • Contain no instance fields (cannot construct an object of an interface type) • Interfaces can be implemented by many classes • A class can implement multiple interfaces.

5. <<interface>> Flier fly() Bird Airplane SkiJumper UML Diagram(Unified Modeling Language) A Flier is one that flies. Three dissimilar classes

6. Interface Example public interface Flier { void fly(); } Notice – no public modifier in the method header - Methods defined in an interface are all public by default.

7. Classes realizing Flier public class Bird implements Flier { public void fly() { System.out.println("Using my wings to fly"); } } ================================================================== public class Airplane implements Flier { public void fly() { System.out.println("Using my jet engines to fly"); } } ================================================================== public class SkiJumper implements Flier, Athlete, Comparable { public void fly() { System.out.println("Using skis to take me into the air"); } }

8. Creating an ArrayList of Fliers ArrayList<Flier> airborne = new ArrayList<Flier>(); airborne.add(new SkiJumper(“Jumper”, “One”)); airborne.add(new SkiJumper(“Jumper”, “Two”)); airborne.add(new Airplane());

9. <<interface>> Flier <<interface>> Athlete fly() train() Bird Airplane SkiJumper UML Diagram

10. Another Interface public interface Athlete { void train(double hours); } Used by SkiJumper class

11. Realizing the Interfaces public class SkiJumper implements Flier, Athlete { //Constructor{ } public void fly() { System.out.println("Using skis to take " + myFirstname + " " + myLastName + " into the air."); myNumberOfJumps++; } public void train(double hours) { System.out.println("I am on the slopes " + hours + " hours today."); myHoursTraining +=hours; } // more methods and private instance fields go here

12. public interface Comparable • Method Summary • intcompareTo(Object o) - Used with the String class - Compares this object with the specified object for order (o).  Returns: Neg value if String less than o 0 if String equals o Pos value if String greater than o

13. Example • StringimplementsComparable • We can compare two strings by invoking the String method compareTo. • String makes a promise to "define" what is means to compare two String objects. String s1 = <some string>; String s2 = <some string>; if (s2.compareTo(s1))…….

14. Examples • public class Circle implements Comparable { public int compareTo(Object o) // Circle must define what it means to compare two Circle objects. } • If we want to compare two circles, we must supply the method compareTo.

15. Examples • public class Circle implements Comparable { public int compareTo(Object o) { Circle c = (Circle) o; if (this.equals(c)) return 0; if (this.radius < c.radius) return -1; return 1; } … // we have already defined equals for Circle. What if equals is not defined for Circle? }

16. Examples • public class Student implements Comparable { public int compareTo(Object o) { } … }

17. Examples • public class Student implements Comparable { public intcompareTo(Object o) { Student s = (Student) o; if (this.equals(s)) return 0; if (this.gpa < s.gpa) return -1; return 1; } … }

18. An interface….. • "To be useful, an interface must be realized (implemented) by at least one Java class." – Rick Mercer • A class may implement MANY interfaces.

19. Interfaces • SHOULD NOT GROW! • Classes have "contracts" with an interface. • If the interface changes, all classes that realize the interface are affected! • Interfaces allow for encapsulating similar behaviors between unrelated classes.

20. Interface • Contains constants, method signatures or both. • NO implementations. • No instance variables.

21. Using interfaces • Define a set of methods as an interface. • Classes that realize the interface must support all the methods of the interface. • Create classes that implement those methods. • Compiler verifies that method calls are valid. (if not, the compiler will complain)

22. Interface declarations: • All methods in an interface are public. The methods in the interface are not declared as public because they are public by default. • When implementing the methods of the interface in a class, include the keyword public.

23. Interfaces • Cannot be instantiated. • Flier f = new Flier(); • You can use interface name as a variable type; variable can refer to an object of any class that implements the interface. • Flier b = new Bird(); • Flier s = new SkiJumper(); NO OK OK

24. Using interfaces • Interfaces define types (sets of methods). • A variable of type Flier must refer to an object that implements methods defined by Flier, not necessarily to an instance of Flier. • Actual method invoked is defined by the object’s class, at run-time. (dynamic or late binding)

25. polymorphism… • Late Binding: Behavior can vary depending on the actual type of an object. Occurs at runtime. The method selection takes place when the program runs. • Early Binding (overloading):occurs at compile time. The compiler selects a method from several possible candidates.

26. polymorphism • "In the object-oriented world, polymorphism refers to the ability of different kinds of objects to respond differently to the same commands, provided that the objects belong to classes with a common ancestor." K.N.King The principle that the actual type of the object determines the method to be called is called polymorphism. The term “polymorphism” comes from the Greek words for “many shapes.”

27. Again… • Early binding of methods occurs if the compiler selects a method from several possible candidates as with overloaded methods. • Late binding occurs if the method selection takes place when the program runs.

28. The importance of IS-A • You can convert from a class type to an interface type if the class realizes the interface. String str = "word"; Comparable p = str; // • You need a cast to convert from an interface type to a class type. String str = "word"; Comparable p = str; String t = p; // OK NO

29. The importance of IS-A • You can convert from a class type to an interface type if the class realizes the interface. String str = "word"; Comparable p = str; // • You need a cast to convert from an interface type to a class type. String str = "word"; Comparable p = str; String t = (String)p; // OK OK

30. instanceofoperator EXAMPLE 1 • The instanceof operator tests whether an object belongs to a particular type. What happens? Flier aFlier = new SkiJumper("Joe","Smith"); Flier aFlier2 = new Airplane(); if (aFlier instanceof SkiJumper) System.out.println("That's right."); else System.out.println("NOT");

31. instanceof operator • The instanceof operator tests whether an object belongs to a particular type. What happens? Flier aFlier = new SkiJumper("Joe","Smith"); Flier aFlier2 = new Airplane(); if (aFlier instanceof SkiJumper) System.out.println("That's right."); else System.out.println("NOT"); That's right.

32. instanceof operator EXAMPLE 2 • The instanceof operator tests whether an object belongs to a particular type. What happens? Flier aFlier = new SkiJumper("Joe","Smith"); Flier aFlier2 = new Airplane(); if (aFlier instanceof Flier) System.out.println("That's right."); else System.out.println("NOT");

33. instanceof operator • The instanceof operator tests whether an object belongs to a particular type. Flier aFlier = new SkiJumper("Joe","Smith"); Flier aFlier2 = new Airplane(); if (aFlier instanceof Flier) System.out.println("That's right."); else System.out.println("NOT"); That's right.

34. instanceof operator EXAMPLE 3 • The instanceof operator tests whether an object belongs to a particular type. What happens? Flier aFlier = new SkiJumper("Joe","Smith"); Flier aFlier2 = new Airplane(); if (aFlier2 instanceof Flier) System.out.println("That's right."); else System.out.println("NOT");

35. instanceof operator • The instanceof operator tests whether an object belongs to a particular type. Flier aFlier = new SkiJumper("Joe","Smith"); Flier aFlier2 = new Airplane(); if (aFlier2 instanceof Flier) System.out.println("That's right."); else System.out.println("NOT"); That's right.

36. instanceof operator EXAMPLE 4 • The instanceof operator tests whether an object belongs to a particular type. What happens? Flier aFlier = new SkiJumper("Joe","Smith"); Flier aFlier2 = new Airplane(); if (aFlier2 instanceof SkiJumper) System.out.println("That's right."); else System.out.println("NOT");

37. instanceof operator • The instanceof operator tests whether an object belongs to a particular type. Flier aFlier = new SkiJumper("Joe","Smith"); Flier aFlier2 = new Airplane(); if (aFlier2 instanceof SkiJumper) System.out.println("That's right."); else System.out.println("NOT"); NOT

38. Polymorphism is NOT Overloading. • Method signature • refers to method name and parameters • Overloading means methods have different signatures(different parameters). • Overloading usually occurs in same class. • BankAccount has two constructors. One of the constructors has one double parameter. One of the constructors has no parameters. • The compiler chooses the appropriate method.

39. Polymorphism • The actual type of the object determines which method is to be called. • This is late binding (dynamic binding). • The virtual machine, not the compiler, selects the appropriate method at run time.

40. Suppose C is a class that realizes the interfaces I and J. Which of the following assignments require a cast? C c = …; I i = …; J j = …; • c = i; • j = c; • i = j;

41. Suppose C is a class that realizes the interfaces I and J. Which of the following assignments require a cast? C c = …; I I = …; J j = …; • c = i; • j = c; • i = j;

42. Suppose C is a class that realizes the interfaces I and J. Which of the following assignments will throw an exception? C c = new C(); • I i = c; • J j = (J)i; • C d = (C)i

43. Suppose C is a class that realizes the interfaces I and J. Which of the following assignments will throw an exception? C c = new C(); • I i = c; • J j = (J)i; • C d = (C)I; NONE

44. Consider the following DataSet class.p. 249 //Computes the average of a set of // data values. public class DataSet { public DataSet() { sum = 0; count = 0; maximum = 0; } //Adds a data value to the data // set public void add(double x) { sum = sum + x; if (count == 0 || maximum < x) maximum = x; count++; } //Returns the average of the added data. public double getAverage() { if (count == 0) return 0; else return sum / count; } //Returns the largest of the added data // or 0 if no data has been added public double getMaximum() { return maximum; } private double sum; private double maximum; private int count; }

45. Concerns • Suppose we wanted to find the BankAccount with the highest balance? • Suppose we wanted to find the Coin with the highest value? • Suppose we wanted to find the Student with the highest gpa?

46. Solution: BankAccount solution //Computes the average of a set of // data values. public class DataSet { public DataSet() { sum = 0; count = 0; maximum = 0; } //Adds a data value to the data // set public void add(BankAccount x) { sum = sum + x.getBalance(); if (count == 0 || maximum.getBalance() < x.getBalance()) maximum = x; count++; } //Returns the average of the added data. public double getAverage() { if (count == 0) return 0; else return sum / count; } //Returns the largest of the added data // or 0 if no data has been added public BankAccount getMaximum() { return maximum; } private double sum; private BankAccount maximum; private int count; }

47. Solution: Coin solution //Computes the average of a set of // data values. public class DataSet { public DataSet() { sum = 0; count = 0; maximum = 0; } //Adds a data value to the data // set public void add(Coin x) { sum = sum + x.getValue(); if (count == 0 || maximum.getValue () < x.getValue ()) maximum = x; count++; } //Returns the average of the added data. public double getAverage() { if (count == 0) return 0; else return sum / count; } //Returns the largest of the added data // or 0 if no data has been added public Coin getMaximum() { return maximum; } private double sum; private Coin maximum; private int count; }

48. Solution: Student solution //Computes the average of a set of // data values. public class DataSet { public DataSet() { sum = 0; count = 0; maximum = 0; } //Adds a data value to the data // set public void add(Student x) { sum = sum + x.getGpa(); if (count == 0 || maximum.getGpa () < x.getGpa ()) maximum = x; count++; } //Returns the average of the added data. public double getAverage() { if (count == 0) return 0; else return sum / count; } //Returns the largest of the added data // or 0 if no data has been added public StudentgetMaximum() { return maximum; } private double sum; private Student maximum; private int count; }

49. Hmmmmm… • Clearly the mechanics of analyzing the data is the same in ALL cases but the details of measurement are different. • BankAccount : balance • Coin: value • Student: gpa

50. Suppose we consider the following: public interface Measurable { double getMeasure(); }