Review Dr. Yingwu Zhu. Outline ADT concept C++ Class List with class implementation

Review

Dr. Yingwu Zhu

Outline

• ADT concept• C++ Class• List with class implementation

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What is ADT?

• Abstract Data Type• ADT = data items + operations on the data• Implementation of ADT

– Storage/data structures to store the data– Algorithms for the operations, i.e., how to do it

C++ Classes

• Structs vs. Classes

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Structs and Classes Similarities

• Essentially the same syntax• Both are used to model objects with multiple

attributes (characteristics) – represented as data members – also called fields

• Thus, both are used to process non-homogeneous data sets.

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Structs vs. Classes Differences

• No classes in C

• Members public by default

• Can be specified private

• Both structs and classes in C++

• Structs can have members declared private

• Class members are private by default

• Can be specified public

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Advantages in C++ Classes

• C++ classes model objects which have:– Attributes represented as data members– Operations represented as functions (or methods)

• Leads to object oriented programming– Objects are self contained– "I can do it myself" mentality

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Class Declaration

• Syntax

class ClassName{

public: Declarations of public members

private: Declarations of private members

};

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Designing a Class

• Data members normally placed in private: section of a class (information hiding)

• Function members usually in public: section (exported for external use)

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Class Libraries

• Class declarations placed in header file– Given .h extension– Contains data items and prototypes

• Implementation file– Same prefix name as header file– Given .cpp extension

• Programs which use this class library called client/driver programs

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Translating a Library

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Example of User-Defined Time Class

• Now we create a Time class (page 150)– Actions done to Time object, done by the object itself

• Note interface for Time class object, Fig. 4.2– Data members private – inaccessible to users of the class– Information hidingclass Time { private: unsigned myHours, myMinutes; char myAMorPM; public: …};

Nyhoff, ADTs, Data Structures and Problem Solving with C++, Second Edition, © 2005

Pearson Education, Inc. All rights reserved. 0-13-140909-3

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Constructors• Understanding Constructors, p158-159

– Initialize data members– Optional: allocate memory

• Note constructor definition in Time.cpp example (p161)

• SyntaxClassName::ClassName (parameter_list): member_initializer_list{

// body of constructor definition}

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Constructors Time::Time() { myHours = 0; myMinutes = 0; myAMorPM = ‘A’;}

Time::Time(unsigned h, unsigned m, char c) : myHours(h), myMinutes(m), myAMorPM(c) {

}

Data member initialization

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Overloading Functions• Note existence of multiple functions with the

same nameTime(); Time(unsigned initHours, unsigned initMinutes, char initAMPM); – Known as overloading

• Compiler compares numbers and types of arguments of overloaded functions– Checks the "signature" of the functions

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Default Arguments

• Possible to specify default values for constructor arguments Time(unsigned initHours = 12, unsigned initMinutes = 0, char initAMPM = 'A');

• ConsiderTime t1, t2(5), t3(5,30), t4(5,30,'P');

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Copy Operations(p166)

• During initializationTime t = bedTime

• During Assignmentt = midnight;

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Overloading Operators

• Same symbol can be used more than one way• Operator , function: operator ()• Two cases

– If is a function member: a b a.operator (b)

– Otherwise, a b operator (a,b)• Operators: +,-,*,/• Operators: <<, >>

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Redundant Declarations

• Note use of #include "Time.h" in– Time.cpp– Client program

• Causes "redeclaration" errors at compile time• Solution is to use conditional compilation

– Use #ifndef and #define and #endif compiler directives

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Pointers to Class Objects

• Possible to declare pointers to class objectsTime * timePtr = &t;

• Access with timePtr->getMilTime() or (*timePtr).getMilTime()

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The this Pointer

• Every class has a keyword, this– a pointer whose value is the address of the object– Value of *this would be the object itself

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Exercise

• Use what we have learned to Implement a polynomial class in the form of ax+b, coefficients a and b are integers.– Constructor– Overload operator+– Overload operator<<

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Example for class “ax+b”

//poly.h: header file

#include <iostream>

using namespace std;

#ifndef _POLY_H // avoid redundant declarations#define _POLY_Hclass Poly { private: int m_ca; //coefficient a int m_cb; public: Poly(int a, int b) : m_ca(a), m_cb(b) { }; //constructor void display(ostream& out) const; //for operator << overloading Poly operator+(const Poly& po); //overloading +

}; //do not forget to put ; !!!!

ostream& operator<<(ostream& out, const Poly& po); //overloading <<

#endif

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Example: ax+b

//poly.cpp: implementation file#include “poly.h”using namespace std;

void Poly::display(ostream& out) const { out << m_ca << “x + ” << m_cb << endl;}

Poly Poly::operator+(const Poly& po) { Poly c; c.m_ca = this->m_ca + po.m_ca; //what is “this”? Do we need it here? c.m_cb = m_cb + po.m_cb; return c;}

ostream& operator<<(ostream& out, const Poly& po) { po.display(out); return out;}

List with Class Implementation

• List as an ADT• 3 different implementations

– Static array-based– Dynamic array-based– Linked-list based

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Properties of Lists

• Can have a single element• Can have no elements empty!• There can be lists of lists

• We will look at the list as an abstract data type– Homogeneous– Finite length– Sequential elements

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Basic Operations

• Construct an empty list• Determine whether or not empty• Insert an element into the list• Delete an element from the list• Traverse (iterate through) the list to

– Modify– Output– Search for a specific value– Copy or save– Rearrange

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Designing a List Class

• Should contain at least the following function members– Constructor– empty()– insert()– delete()– display()

• Implementation involves– Choosing data structures to store data members– Choosing algorithms to implement function members

Impl. 1: Static Array

• Use a static array to hold list elements• Easy to manipulate arrays for implementing

operations• Natural fit for mapping list elements to array

elements

Design

• What data members?• What operations?

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const int CAPACITY = 1000; //for what purpose? typedef int ElementType; //for what purpose?

class List { private: int size; //# of elements ElementType array[CAPACITY]; public: …};

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Implementing Operations• Constructor

– Static array allocated at compile time. No need to allocate explicitly!

• Empty– Check if size == 0

• Traverse– Use a loop from 0th element to size – 1

• Insert– Shift elements to

right of insertion point

• Delete– Shift elements back

Also adjust size up or

down

Also adjust size up or

down

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List Class with Static Array - Problems

• Stuck with "one size fits all"– Could be wasting space– Could run out of space

• Better to have instantiation of specific list specify what the capacity should be

• Thus we consider creating a List class with dynamically-allocated array

Impl. 2: Using Dynamic Arrays

• Allow List objects to specify varied sizes

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Dynamic-Allocation for List Class

• Now possible to specify different sized listscin >> maxListSize;List aList1(maxListSize);List aList2(500);

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Dynamic-Allocation for List Class

• Changes required in data members– Eliminate const declaration for CAPACITY– Add data member to store capacity specified by client

program– Change array data member to a pointer– Constructor requires considerable change

• Little or no changes required for – empty()– display()– erase()– insert()

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typedef int ElementType;

class List { private: int mySize; //# of elements int myCapacity; ElementType *myArray; public: List (int cap); };

What needs to be changed?

• Constructor• Addition of other functions to deal with

dynamically allocated memory– Destructor– Copy constructor (won’t be discussed here)– Assignment operator (won’t be discussed here)

Constructor

• Two tasks– Data member initialization– Dynamically allocate memory

//constructorList::List(int cap) : mySize(0), myCapacity(cap) { myArray = new int[cap]; //allocate memory assert(myArray != 0); //need #include <cassert>}

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Destructor Needed!• When class object goes out of scope, the pointer

to the dynamically allocated memory is reclaimed automatically

• The dynamically allocated memory is not

• The destructor reclaims dynamically allocated memory

Destructor

• The default destructor needs to be overrided!• De-allocate memory you allocated previously;

otherwise raises memory leak problem!

List::~List() { delete [] myArray;}

Problems

• Array capacity cannot be changed during running time (execution)!

• Insertion & deletion are not efficient!– Involve element shifting

Impl. 3: Using Linked-Lists

• Are able to address the two problems faced by array-based solutions

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Linked List

• Linked list nodes contain– Data part – stores an element of the list– Next part – stores link/pointer to next element

(when no next element, null value)

Basic Operations

• Traversal• Insertion• Deletion

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Traversal

• Initialize a variable ptr to point to first node

• Process data where ptr points

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Traversal (cont.)

• set ptr = ptr->next, process ptr->data

• Continue until ptr == null

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Insertion

• Insertion – To insert 20 after 17– Need address of item before point of insertion

– predptr points to the node containing 17

– Create a new node pointed to by newptr and store 20 in it– Set the next pointer of this new node equal to the next

pointer in its predecessor, thus making it point to its successor.

– Reset the next pointer of its predecessor to point to this new node

20newptr

predptr

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Insertion

• Note: insertion also works at end of list– pointer member of new node set to null

• Insertion at the beginning of the list– predptr must be set to first– pointer member of newptr set to that value– first set to value of newptr

Note: In all cases, no shifting of list elements is required !

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Operations: Deletion

• Delete node containing 22 from list.– Suppose ptr points to the node to be deleted– predptr points to its predecessor (the 17)

• Do a bypass operation: – Set the next pointer in the predecessor to

point to the successor of the node to be deleted– Deallocate the node being deleted.

predptr ptr

To free space

# 1 Lesson in Pointers

• Before operating on an pointer, first check if it is null!

if (ptr) { //do sth. meaningful}

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Linked Lists - Advantages

• Access any item as long as external link to first item maintained

• Insert new item without shifting• Delete existing item without shifting• Can expand/contract as necessary

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Linked Lists - Disadvantages• Overhead of links:

– used only internally, pure overhead• If dynamic, must provide

– destructor– copy constructor (but not here!)

• No longer have direct access to each element of the list– Many sorting algorithms need direct access– Binary search needs direct access

• Access of nth item now less efficient – must go through first element, and then second, and then

third, etc.

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Linked Lists - Disadvantages• List-processing algorithms that require fast access to each

element cannot be done as efficiently with linked lists.• Consider adding an element at the end of the list

Array Linked Lista[size++] = value; Get a new node;

set data part = value

next part = null_value

If list is empty

Set first to point to new node.

Else

Traverse list to find last node

Set next part of last node to point to new node.

This is the inefficient partThis is the inefficient part

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Using C++ Pointers and Classes

• To Implement Nodes class Node{ public:

DataType data; Node * next;};

• Note: The definition of a Node is recursive – (or self-referential)

• It uses the name Node in its definition• The next member is defined as a pointer to a Node

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Working with Nodes

• Declaring pointers Node* ptr; ortypedef Node* NodePointer; NodePointer ptr;

• Allocate and deallocate ptr = new Node; delete ptr;

• Access the data and next part of node(*ptr).data and (*ptr).next

or ptr->data and ptr->next

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Working with Nodes• Note data members

are public

• This class declaration will be placed inside another class declaration for List (private section), p296

class Node{ public: DataType data; Node * next; };

class Node{ public: DataType data; Node * next; };

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typedef int ElementType;class List{ private: class Node { public: ElementType data; Node * next; }; typedef Node * NodePointer; …

Implementing List with Linked-Lists

• data is public inside class Node

• class Node is private inside List

• data is public inside class Node

• class Node is private inside List

Design & Impl.

• Add data members• Add member functions

Class List#ifndef _LIST_H#define _LIST_Htypedef int ElementType; class List { private: class Node { public: ElementType data; Node* next; }; typedef Node* NodePointer; private: NodePointer first; public: List(); ~List(); void insert(ElementType x); void delete(ElementType x);}; #endif

Implementing

• Constructor• Destructor• Operation: insert()• Operation: delete()

Exercises

• Implement Stack and Queue classes with different implementations.

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Stack

• Design and Implement a Stack class• 3 options

– Static array– Dynamic array– Linked list

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Stack.htypedef int DataType;class Stack {

public: Stack(); Stack(const Stack& org); void push(const DataType& v); void pop(); DataType top() const; ~Stack();

private: class Node { public: DataType data; Node* next; Node(DataType v, Node* p) : data(v), next(0) { }

}; typedef Node* NodePtr;

NodePtr myTop;

};

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Queue

• Design and Implement a Queue class• 3 options

– Static array– Dynamic array– Linked list

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Queue.htypedef int DataType;

class Queue {public: //constructor

//… member functions private: class Node { public: DataType data; Node* next; Node(DataType v, Node* p) : data(v), next(0) { }

};

typedef Node* NodePtr; NodePtr myFront, myback;

};