1. 1 Final Exam Tues 3/16/10 (2-3:50) (Same classroom) Old Textbook - Chapters 11-16, 18 Focus is on 15, 16 and 18 Final Exam Tues 3/16/10 (2-3:50) (Same classroom) Old Textbook - Chapters 11-16, 18 Focus is on 15, 16 and 18 Multiple choice, True/False and some minimal programming will be required

2. 2 Topics Covered List Structures (Arrays & Linked List) C++ Classes Inheritance Object-Oriented Programming Pointers Dynamic Memory Recursion

3. 3 Array-Based List

4. 4 Linked List ADT

5. 5 Array List vs. Linked List ADT Array List Pre-allocation Required Waste-full if you allocate too much Fatal if you allocate too little Data has to be shifted when an item is inserted or deleted at specified position Linked List Truly dynamic, memory is allocated as needed No shifting when an item is inserted, deleted

6. 6 For the Final Exam You will NOT be asked to write a Linked List. You don’t have to create an array either. Questions related to Link List and Arrays are concept based, (no code writing).

7. 7 Structured Data Type Definition: A structured data type is a type in which each value is a collection of component items. The entire collection has a single name each component can be accessed individually Know what is meant by a structured data type. You do not need to create a struct or use one on the final exam.

8. 8 Accessing struct Members Dot ( period ) is the member selection operator. After the struct type declaration, the various members can be used in your program only when they are preceded by a struct variable name and a dot. EXAMPLES thisAnimal.weight anotherAnimal.country

9. 9 Abstraction Abstraction is the separation of the essential qualities of an object from the details of how it works or is composed It focuses on what, not how It is necessary for managing large, complex software projects

10. 10 Abstract Data Type (ADT) Is a programmer-defined type with a set of values and allowable operations for the type. Some ways to define a new C++ type are: using struct using class

11. 11 ADT Specification Example TYPE TimeType DOMAIN Each TimeType value is a time in hours, minutes, and seconds. OPERATIONS Set the time Print the time Increment by one second Compare 2 times for equality Determine if one time is “less than” another

12. 12 ADT Implementation means Choosing a specific data representation for the abstract data using data types that already exist (built-in or programmer-defined) Called “Data Members” Writing functions (member functions) for each allowable operation

13. 13 Information Hiding Class implementation details are hidden from the client’s view. This is called information hiding. Public functions of a class provide the interface between the client code and the class objects. client code specificationimplementation abstraction barrier

14. 14 Benefits of information hiding Data and details can be concealed from the client of the abstraction. Code can be changed without affecting the client because the specification and interface are unchanged.

15. 15 class TimeType Specification // Specification File( timetype.h ) class TimeType// declares a class data type {// does not allocate memory public : // 5 public function members void Set ( int hours, int mins, int secs ) ; void Increment ( ) ; void Write ( ) const ; bool Equal ( TimeType otherTime ) const ; bool LessThan ( TimeType otherTime ) const ; private :// 3 private data members int hrs ; int mins ; int secs ; } ;

16. 16 Use of C++ data Type class Facilitates re-use of C++ code for an ADT Software that uses the class is called a client Variables of the class type are called class objects or class instances Client code uses public member functions to handle its class objects

17. 17 Using class A class is a programmer-defined type whose components (called class members) can be variables or functions. Class members are private by default. Compiler does not permit client code to access private class members. Class members declared public form the interface between the client and the class. In most classes, the private members contain data, and the public members are functions to manipulate that data.

18. 18 Member functions categorized by task CONSTRUCTOR -- a member function that actually creates a new instance and initialized some or all of its data members ACCESS FUNCTION or OBSERVER -- a member function that can inspect (use but not modify) the data members of a class without changing their values. Such a function is declared with const following the parameter list in both the specification and the implementation files.

19. 19 Client Code Using TimeType #include “timetype.h” // includes specification of the class using namespace std ; int main ( ) { TimeType currentTime ; // declares 2 objects of TimeType TimeType endTime ; bool done = false ; currentTime.Set ( 5, 30, 0 ) ; endTime.Set ( 18, 30, 0 ) ; while ( ! done ) {... currentTime.Increment ( ) ; if ( currentTime.Equal ( endTime ) ) done = true ; } ; } 19

20. 20 class type Declaration The class declaration creates a data type and names the members of the class. It does not allocate memory for any variables of that type! Client code still needs to declare class variables.

21. 21 C++ Data Type class represents an ADT 2 kinds of class members: data members and function members Class members are private by default Data members are generally private Function members are generally declared public Private class members can be accessed only by the class member functions (and friend functions), not by client code.

22. 22 Aggregate class Operations Built-in operations valid on class objects are: Member selection using dot (. ) operator, Assignment to another class variable using ( = ), Pass to a function as argument (by value or by reference), Return as value of a function Other operations can be defined as class member functions

23. 23 2 separate files Generally Used for class Type // Specification File ( timetype.h ) // Specifies the data and function members. class TimeType { public:... private:... } ; // Implementation File ( timetype.cpp ) // Implements the TimeType member functions....

24. 24 Implementation File for TimeType // Implementation File ( timetype.cpp ) // Implements the TimeType member functions. #include “ timetype.h” // also must appear in client code #include... bool TimeType :: Equal (TimeType otherTime ) const // Function value == true, if this time equals otherTime // == false, otherwise { return ( (hrs == otherTime.hrs) && (mins == otherTime.mins) && (secs == otherTime.secs) ) ; }...

25. 25 Scope Resolution Operator ( :: ) C++ programs typically use several class types Different classes can have member functions with the same identifier, like Write( ) Member selection operator is used to determine the class whose member function Write( ) is invoked currentTime.Write( ) ;// class TimeType numberZ.Write( ) ;// class ComplexNumberType In the implementation file, the scope resolution operator is used in the heading before the function member’s name to specify its class void TimeType :: Write ( ) const {... }

26. 26 Class Constructors A class constructor is a member function whose purpose is to initialize the private data members of a class object The name of a constructor is always the name of the class, and there is no return type for the constructor A class may have several constructors with different parameter lists. A constructor with no parameters is the default constructor A constructor is implicitly invoked when a class object is declared--if there are parameters, their values are listed in parentheses in the declaration

27. 27 Specification of TimeType Class Constructors class TimeType// timetype.h { public : // 7 function members void Set ( int hours, int minutes, int seconds ) ; void Increment ( ) ; void Write ( ) const ; bool Equal ( TimeType otherTime ) const ; bool LessThan ( TimeType otherTime ) const ; TimeType ( int initHrs, int initMins, int initSecs ) ; // constructor TimeType ( ) ; // default constructor private :// 3 data members int hrs ; int mins ; int secs ; } ; 27

28. 28 Implementation of TimeType Default Constructor TimeType :: TimeType ( ) // Default Constructor // Postcondition: //hrs == 0 && mins == 0 && secs == 0 { hrs = 0 ; mins = 0 ; secs = 0 ; }

29. 29 Implementation of Another TimeType Class Constructor TimeType :: TimeType ( int initHrs, int initMins, int initSecs ) // Constructor // Precondition: 0 <= initHrs <= 23 && 0 <= initMins <= 59 // 0 <= initSecs <= 59 // Postcondition: //hrs == initHrs && mins == initMins && secs == initSecs { hrs = initHrs ; mins = initMins ; secs = initSecs ; }

30. 30 Separate Compilation and Linking of Files timetype.h client.cpptimetype.cpp client.obj client.exetimetype.obj Compiler Linker #include “timetype.h” implementation file specification file main program

31. 31 For the Final Exam Note: You will be asked to write a simple class, without using dynamic memory. (no Copy Constructor or Destructor writing will be required.) You should know what a copy constructor and a destructor is in concept.

32. 32 Pointers A pointer holds the memory address of another object. Through the pointer we can indirectly manipulate the referenced object. Pointers are useful for Creating linked data structures such as linked lists, management of dynamically allocated objects, and as a function parameter type for passing large objects such as arrays.

33. Pass-by-value CALLING BLOCK FUNCTION CALLED sends a copy of the contents of the actual parameter SO, the actual parameter cannot be changed by the function. 33

34. Pass-by-reference sends the location (memory address) of the actual parameter can change value of actual parameter CALLING BLOCK FUNCTION CALLED 34

35. 35 Obtaining Memory Addresses the address of a non-array variable can be obtained by using the address-of operator & int x; float number; char ch; cout << “Address of x is “ << &x << endl; cout << “Address of number is “ << &number << endl; cout << “Address of ch is “ << &ch << endl;

36. 36 What is a pointer variable? A pointer variable is a variable whose value is the address of a location in memory. to declare a pointer variable, you must specify the type of value that the pointer will point to, for example, int* ptr; // ptr will hold the address of an int char* q; // q will hold the address of a char

37. 37 Using a Pointer Variable int x; x = 12; int* ptr; ptr = &x; NOTE: Because ptr holds the address of x, we say that ptr “points to” x 2000 12 x 3000 2000 ptr

38. 38 2000 12 x 3000 2000 ptr int x; x = 12; int* ptr; ptr = &x; cout << *ptr; NOTE: The value pointed to by ptr is denoted by *ptr Unary operator * is the indirection (deference) operator

39. 39 int x; x = 12; int* ptr; ptr = &x; *ptr = 5; // changes the value // at address ptr to 5 Using the Dereference Operator 2000 12 5 x 3000 2000 ptr

40. 40 char ch; ch = ‘A’; char* q; q = &ch; *q = ‘Z’; char* p; p = q; // now p and q both point to ch Another Example 4000 A Z ch 5000 6000 4000 4000 q p

41. Operator new Syntax new DataType new DataType [IntExpression] If memory is available, in an area called the heap (or free store) new allocates the requested object or array, and returns a pointer to (address of ) the memory allocated. Otherwise, program terminates with error message. The dynamically allocated object exists until the delete operator destroys it. 41

42. 42 3 Kinds of Program Data STATIC DATA: memory allocation exists throughout execution of program AUTOMATIC DATA: automatically created at function entry, resides in activation frame of the function, and is destroyed when returning from function DYNAMIC DATA: explicitly allocated and deallocated during program execution by C++ instructions written by programmer using operators new and delete

43. 43 Dynamically Allocated Data char* ptr; ptr = new char; *ptr = ‘B’; cout << *ptr; NOTE: Dynamic data has no variable name 2000 ptr ‘B’

44. 44 Dynamically Allocated Data char* ptr; ptr = new char; *ptr = ‘B’; cout << *ptr; delete ptr; 2000 ptr NOTE: delete de- allocates the memory pointed to by ptr ?

45. Operator delete returns to the free store memory which was previously allocated at run-time by operator new. The object or array currently pointed to by the pointer is deallocated, and the pointer is considered unassigned. Using Operator delete 45

46. Operator delete Syntax delete Pointer delete [ ] Pointer If the value of the pointer is 0 there is no effect. Otherwise, the object or array currently pointed to by Pointer is deallocated, and the value of Pointer is undefined. The memory is returned to the free store. Square brackets are used with delete to deallocate a dynamically allocated array. 46

47. 47 Dynamic Array Deallocation char *ptr ; ptr = new char[ 5 ]; strcpy( ptr, “Bye” ); ptr[ 1 ] = ‘u’; delete ptr; // deallocates array pointed to by ptr // ptr itself is not deallocated // the value of ptr is undefined. ptr ?

48. 48 int* ptr = new int; *ptr = 3; ptr = new int; // changes value of ptr *ptr = 4; What happens here? 3 ptr 3 ptr 4

49. 49 Inaccessible Object An inaccessible object is an unnamed object that was created by operator new and which a programmer has left without a pointer to it. int* ptr = new int; *ptr = 8; int* ptr2 = new int; *ptr2 = -5; 8 ptr -5 ptr2

50. 50 Making an Object Inaccessible int* ptr = new int; *ptr = 8; int* ptr2 = new int; *ptr2 = -5; ptr = ptr2; // here the 8 becomes inaccessible 8 ptr -5 ptr2 8 ptr -5 ptr2

51. 51 Memory Leak A memory leak is the loss of available memory space that occurs when dynamic data is allocated but never deallocated.

52. 52 int* ptr = new int; *ptr = 8; int* ptr2 = new int; *ptr2 = -5; ptr = ptr2; delete ptr2; // ptr is left dangling ptr2 = NULL; Leaving a Dangling Pointer A pointer that points to dynamic memory that has been de-allocated 8 ptr -5 ptr2 8 ptr NULL ptr2

53. 53 Why is a destructor needed? When a DynArray class variable goes out of scope, the memory space for data members size and pointer arr is deallocated. But the dynamic array that arr points to is not automatically deallocated. A class destructor is used to deallocate the dynamic memory pointed to by the data member.

54. 54 DynArray::~DynArray( ); // Destructor. // POST: Memory for dynamic array deallocated. { delete [ ] arr ; } 54 class DynArray Destructor

55. 55 Shallow Copy vs. Deep Copy a shallow copy copies only the class data members, and does not make a copy of any pointed-to data a deep copy copies not only the class data members, but also makes a separate stored copy of any pointed-to data

56. 56 Initialization of Class Objects C++ defines initialization to mean initialization in a variable declaration passing an object argument by value returning an object as the return value of a function by default, C++ uses shallow copies for these initializations

57. 57 As a result... when a class has a data member pointer to dynamically allocated data, you should write what is called a copy constructor the copy constructor is implicitly called in initialization situations and makes a deep copy of the dynamic data in a different memory location

58. 58 Copy Constructors When there is a copy constructor provided for a class, the copy constructor is used to make copies for pass by value You do not call the copy constructor Like other constructors, it has no return type Because the copy constructor properly defines pass by value for your class, it must use pass by reference in its definition

59. 59 Copy Constructor Copy constructor is a special member function of a class that is implicitly called in these 3 situations: passing object parameters by value initializing an object variable in its declaration returning an object as the return value of a function

60. 60 CONSTRUCTOR COPY CONSTRUCTOR DESTRUCTOR Classes with Data Member Pointers Need

61. 61 For the Final Exam Note: You will not have to write source code using pointers or dynamic memory. Questions related to these topics will be multiple choice or True/False

62. 62 Recursive Function Call A recursive call is a function call in which the called function is the same as the one making the call In other words, recursion occurs when a function calls itself! But we need to avoid making an infinite sequence of function calls (infinite recursion)

63. 63 void message() { cout << “This is a recursive function. \n”; message(); } Recursive Function Example

64. 64 The previous program will eventually crash, because each time a function is called, temporary information is stored on a stack. The stack memory will eventually overflow and cause an error). A recursive function (as with a loop) must have some algorithm to control the number of times it repeats. void message(int times) { if(times > 0) { cout << “This is a recursive function. \n”; message(times-1); } return; } Recursive Function Example

65. 65 Finding a Recursive Solution The idea is for each successive recursive call to bring you one step closer to a situation in which the problem can easily be solved This easily solved situation is called the base case Each recursive algorithm must have at least one base case, as well as a general (recursive) case

66. 66 General format for Many Recursive Functions if (some easily-solved condition) // base case solution statement else // general case recursive function call

67. 67 Example Recursive Function Finding the Sum of the Numbers from 1 to n int Summation ( int n ) { if ( n == 1) // base case return 1 ; else // general case return ( n + Summation ( n - 1 ) ) ; }

68. 68 “Why use recursion?” The previous example could have been written without recursion, by using iteration instead. The iterative solution uses a loop, while the recursive solution uses an if statement. However, for certain problems the recursive solution is the most natural solution. This often occurs when structured variables are used.

69. 69 For the Final Exam Note: You will not have to write source code using recursion. Questions related to this topics will be multiple choice or True/False

70. 70 Final Exam Tues 3/16/10 (2-3:50) (Same classroom) Old Textbook - Chapters 11-16, 18 Focus is on 15, 16 and 18 Final Exam Tues 3/16/10 (2-3:50) (Same classroom) Old Textbook - Chapters 11-16, 18 Focus is on 15, 16 and 18 Multiple choice, True/False and some minimal programming will be required