#ifndef ARRAYIMP_H

#define ARRAYIMP_H

#include

#include

using namespace std;

template < class elemType >

class arrayListType {

public:

const arrayListType < elemType > & operator =

(const arrayListType < elemType > & );

//Overloads the assignment operator

bool isEmpty() const;

//Function to determine whether the list is empty

//Postcondition: Returns true if the list is empty;

// otherwise, returns false.

bool isFull() const;

//Function to determine whether the list is full.

//Postcondition: Returns true if the list is full;

// otherwise, returns false.

int listSize() const;

//Function to determine the number of elements in the list

//Postcondition: Returns the value of length.

int maxListSize() const;

//Function to determine the size of the list.

//Postcondition: Returns the value of maxSize.

void print() const;

//Function to output the elements of the list

//Postcondition: Elements of the list are output on the

// standard output device.

bool isItemAtEqual(int location,const elemType & item) const;

//Function to determine whether the item is the same

//as the item in the list at the position specified by

//Postcondition: Returns true if list[location]

// is the same as the item; otherwise,

// returns false.

void insertAt(int location,const elemType & insertItem);

//Function to insert an item in the list at the

//position specified by location. The item to be inserted

//is passed as a parameter to the function.

//Postcondition: Starting at location, the elements of the

// list are shifted down, list[location] = insertItem;,

// and length++;. If the list is full or location is

// out of range, an appropriate message is displayed.

void insertEnd(const elemType & insertItem);

//Function to insert an item at the end of the list.

//The parameter insertItem specifies the item to be inserted.

//Postcondition: list[length] = insertItem; and length++;

// If the list is full, an appropriate message is

// displayed.

void removeAt(int location);

//Function to remove the item from the list at the

//position specified by location

//Postcondition: The list element at list[location] is removed

// and length is decremented by 1. If location is out of

// range, an appropriate message is displayed.

void retrieveAt(int location, elemType & retItem) const;

//Function to retrieve the element from the list at the

//position specified by location.

//Postcondition: retItem = list[location]

// If location is out of range, an appropriate message is

// displayed.

void replaceAt(int location,const elemType & repItem);

//Function to replace the elements in the list at the

//position specified by location. The item to be replaced

//is specified by the parameter repItem.

//Postcondition: list[location] = repItem

// If location is out of range, an appropriate message is

// displayed.

void clearList();

//Function to remove all the elements from the list.

//After this operation, the size of the list is zero.

//Postcondition: length = 0;

int seqSearch(const elemType & item) const;

//Function to search the list for a given item.

//Postcondition: If the item is found, returns the location

// in the array where the item is found; otherwise,

// returns -1.

void insert(const elemType & insertItem);

//Function to insert the item specified by the parameter

//insertItem at the end of the list. However, first the

//list is searched to see whether the item to be inserted

//is already in the list.

//Postcondition: list[length] = insertItem and length++

// If the item is already in the list or the list

// is full, an appropriate message is displayed.

void remove(const elemType & removeItem);

//Function to remove an item from the list. The parameter

//removeItem specifies the item to be removed.

//Postcondition: If removeItem is found in the list,

// it is removed from the list and length is

// decremented by one.

arrayListType(int size = 100);

//constructor

//Creates an array of the size specified by the

//parameter size. The default array size is 100.

//Postcondition: The list points to the array, length = 0,

// and maxSize = size

arrayListType(const arrayListType < elemType > & otherList);

//copy constructor

~arrayListType();

//destructor

//Deallocates the memory occupied by the array.

protected:

elemType * list; //array to hold the list elements

int length; //to store the length of the list

int maxSize; //to store the maximum size of the list

};

template < class elemType >

bool arrayListType < elemType > ::isEmpty() const {

return (length == 0);

}

template < class elemType >

bool arrayListType < elemType > ::isFull() const {

return (length == maxSize);

}

template < class elemType >

int arrayListType < elemType > ::listSize() const {

return length;

}

template < class elemType >

int arrayListType < elemType > ::maxListSize() const {

return maxSize;

}

template < class elemType >

void arrayListType < elemType > ::print() const {

for (int i = 0; i < length; i++)

cout << list[i] << " ";

cout << endl;

}

template < class elemType >

bool arrayListType < elemType > ::isItemAtEqual(int location, const elemType & item) const {

if (location < 0 || location >= length){

cerr << "The position of the item " <<

"is out of range" << endl;

return false;

}

return (list[location] == item);

}

template < class elemType >

void arrayListType < elemType > ::insertAt(int location,

const elemType & insertItem) {

if (location < 0 || location > length)

cerr << "The position of the item to be inserted " <<

"is out of range" << endl;

else if (length >= maxSize) //list is full

cerr << "Cannot insert in a full list" << endl;

else {

for (int i = length; i > location; i--)

list[i] = list[i - 1]; //move the elements down

list[location] = insertItem; //insert the item at the

//specified position

length++; //increment the length

}

} //end insertAt

template < class elemType >

void arrayListType < elemType > ::insertEnd(const elemType & insertItem) {

if (length >= maxSize) //the list is full

cerr<<"Cannot insert in a full list" << endl;

else {

list[length] = insertItem; //insert the item at the end

length++; //increment the length

}

} //end insertEnd

template < class elemType >

void arrayListType < elemType > ::removeAt(int location) {

if (location < 0 || location >= length)

cerr << "The location of the item to be removed " <<

"is out of range" << endl;

else {

for (int i = location; i < length - 1; i++)

list[i] = list[i + 1];

length--;

}

} //end removeAt

template < class elemType >

void arrayListType < elemType > ::retrieveAt(int location, elemType & retItem) const {

if (location < 0 || location >= length)

cerr << "The location of the item to be retrieved is " <<

"out of range." << endl;

else

retItem = list[location];

} //end retrieveAt

template < class elemType >

void arrayListType < elemType > ::replaceAt(int location,

const elemType & repItem)

{

if (location < 0 || location >= length)

cerr << "The location of the item to be replaced is " <<

"out of range." << endl;

else

list[location] = repItem;

} //end replaceAt

template < class elemType >

void arrayListType < elemType > ::clearList() {

length = 0;

} //end clearList

template < class elemType >

arrayListType < elemType > ::arrayListType(int size) {

if (size < 0) {

cerr << "The array size must be positive. Creating " <<

"an array of size 100. " << endl;

maxSize = 100;

} else

maxSize = size;

length = 0;

list = new elemType[maxSize];

assert(list != NULL);

}

template < class elemType >

arrayListType < elemType > ::~arrayListType() {

delete[] list;

}

template < class elemType >

arrayListType < elemType > ::arrayListType(const arrayListType < elemType > & otherList) {

maxSize = otherList.maxSize;

length = otherList.length;

list = new elemType[maxSize]; //create the array

assert(list != NULL); //terminate if unable to allocate

//memory space

for (int j = 0; j < length; j++) //copy otherList

list[j] = otherList.list[j];

} //end copy constructor

template < class elemType >

const arrayListType < elemType > & arrayListType < elemType > ::operator =

(const arrayListType < elemType > & otherList) {

if (this != & otherList) //avoid self-assignment

{

delete[] list;

maxSize = otherList.maxSize;

length = otherList.length;

list = new elemType[maxSize]; //create the array

assert(list != NULL); //if unable to allocate memory

//space, terminate the program

for (int i = 0; i < length; i++)

list[i] = otherList.list[i];

}

return *this;

}

template < class elemType >

int arrayListType < elemType > ::seqSearch(const elemType & item) const {

int loc;

bool found = false;

for (loc = 0; loc < length; loc++)

if (list[loc] == item) {

found = true;

break;

}

if (found)

return loc;

else

return -1;

} //end seqSearch

template < class elemType >

void arrayListType < elemType > ::insert(const elemType & insertItem) {

int loc;

if (length == 0) //list is empty

list[length++] = insertItem; //insert the item and

//increment the length

else if (length == maxSize)

cerr << "Cannot insert in a full list." << endl;

else {

loc = seqSearch(insertItem);

if (loc == -1) //the item to be inserted

//does not exist in the list

list[length++] = insertItem;

else

cerr << "the item to be inserted is already in " <<

"the list. No duplicates are allowed." << endl;

}

} //end insert

template < class elemType >

void arrayListType < elemType > ::remove(const elemType & removeItem) {

int loc;

if (length == 0)

cerr << "Cannot delete from an empty list." << endl;

else {

loc = seqSearch(removeItem);

if (loc != -1)

removeAt(loc);

else

cout << "The item to be deleted is not in the list." <<

endl;

}

} //end remove

#endif // ARRAYIMP_H

#include //Line 1

#include //Line 2

#include

#include "Arrayimp.h" //Line

using namespace std; //Line 4

int main() //Line 5

{

///*

arrayListType L,L1,L2;

L.insertEnd(2);

L.insertEnd(1);

L.insertEnd(3);

L.insertEnd(4);

L.insertEnd(5);

L.insertEnd(3);

L.insertEnd(0);

cout << "List L before L.incrementByConstant(3) contains:" << endl;

L.print();

incrementByConstant(L,3);

cout << "List L after incrementByConstant(L,3) contains:" << endl;

L.print();

L.clearList();

L.insertEnd(2);

L.insertEnd(1);

L.insertEnd(3);

L.insertEnd(4);

L.insertEnd(5);

L.insertEnd(3);

L.insertEnd(0);

cout << "List L before sortEach2(L,\'a\') contains:" << endl;

L.print();

sortEach2(L,'a');

cout << "List L after L.sortEach2(L,\'a\') contains:" << endl;

L.print();

L.clearList();

L.insertEnd(2);

L.insertEnd(1);

L.insertEnd(3);

L.insertEnd(4);

L.insertEnd(5);

L.insertEnd(3);

L.insertEnd(0);

cout << "List L before sortEach2(L,\'d\') contains:" << endl;

L.print();

sortEach2(L,'d');

cout << "List L after sortEach2(L,\'d\') contains:" << endl;

L.print();

L.clearList();

L.insertEnd(2);

L.insertEnd(1);

L.insertEnd(3);

L.insertEnd(4);

L.insertEnd(5);

L.insertEnd(3);

L.insertEnd(0);

cout << "List L before duplicateORremove(L,3) contains:" << endl;

L.print();

duplicateORremove(L,3);

cout << "List L after duplicateORremove(L,3) contains:" << endl;

L.print();

L.clearList();

L.insertEnd(2);

L.insertEnd(1);

L.insertEnd(3);

L.insertEnd(4);

L.insertEnd(5);

L.insertEnd(3);

L.insertEnd(0);

cout << "List L before split(L,3,L1,L2) contains:" << endl;

L.print();

split(L,3,L1,L2);

cout << "List L after split(L,3,L1,L2) contains:" << endl;

L.print();

cout << "List L1 after split(L,3,L1,L2) contains:" << endl;

L1.print();

cout << "List L2 after split(L,3,L1,L2) contains:" << endl;

L2.print();

*/

arrayListType L,L1,L2;

L.insertEnd(2);

L.insertEnd(1);

L.insertEnd(3);

L.insertEnd(4);

L.insertEnd(5);

L.insertEnd(3);

L.insertEnd(0);

cout << "List L before L.incrementByConstant(3) contains:" << endl;

L.print();

///*

L.incrementByConstant(3);

cout << "List L after L.incrementByConstant(3) contains:" << endl;

L.print();

L.clearList();

L.insertEnd(2);

L.insertEnd(1);

L.insertEnd(3);

L.insertEnd(4);

L.insertEnd(5);

L.insertEnd(3);

L.insertEnd(0);

cout << "List L before L.sortEach2(\'a\') contains:" << endl;

L.print();

L.sortEach2('a');

cout << "List L after L.sortEach2(\'a\') contains:" << endl;

L.print();

L.clearList();

L.insertEnd(2);

L.insertEnd(1);

L.insertEnd(3);

L.insertEnd(4);

L.insertEnd(5);

L.insertEnd(3);

L.insertEnd(0);

cout << "List L before L.sortEach2(\'d\') contains:" << endl;

L.print();

L.sortEach2('d');

cout << "List L after L.sortEach2(\'d\') contains:" << endl;

L.print();

L.clearList();

L.insertEnd(2);

L.insertEnd(1);

L.insertEnd(3);

L.insertEnd(4);

L.insertEnd(5);

L.insertEnd(3);

L.insertEnd(0);

cout << "List L before L.duplicateORremove(3) contains:" << endl;

L.print();

L.duplicateORremove(3);

cout << "List L after L.duplicateORremove(3) contains:" << endl;

L.print();

L.clearList();

L.insertEnd(2);

L.insertEnd(1);

L.insertEnd(3);

L.insertEnd(4);

L.insertEnd(5);

L.insertEnd(3);

L.insertEnd(0);

cout << "List L before L.split(3,L1,L2) contains:" << endl;

L.print();

L.split(3,L1,L2);

cout << "List L after L.split(3,L1,L2) contains:" << endl;

L.print();

cout << "List L1 after L.split(3,L1,L2) contains:" << endl;

L1.print();

cout << "List L2 after L.split(3,L1,L2) contains:" << endl;

L2.print();

*/

return 0;

}

Part 2: Starting from the arrayListType.h (attached with the assignment), write the specified member function in Part 1 as non-member functions. Not theta for Part 1, we were calling the member functions using the object L. for this part, this object should be passed by reference to the functions with the other needed function parameters. All functions should be added to the arrayListType.h. After performing the needed modifications to arrayListType.h, you should run the file nonmemberArrayList.cpp (attached with this assignment) without modifying it without any problems and you should get the following output:

List L before L.incrementByConstant(3) contains:

2 1 3 4 5 3 0

List L after incrementByConstant(L,3) contains:

2 1 3 4 5 3 0

List L before sortEach2(L,'a') contains:

2 1 3 4 5 3 0

List L after L.sortEach2(L,'a') contains:

2 1 3 4 5 3 0

List L before sortEach2(L,'d') contains:

2 1 3 4 5 3 0

List L after sortEach2(L,'d') contains:

2 1 3 4 5 3 0

List L before duplicateORremove(L,3) contains:

2 1 3 4 5 3 0

List L after duplicateORremove(L,3) contains:

2 1 3 4 5 3 0

List L before split(L,3,L1,L2) contains:

2 1 3 4 5 3 0

List L after split(L,3,L1,L2) contains:

2 1 3 4 5 3 0

List L1 after split(L,3,L1,L2) contains:

2 1 0

List L2 after split(L,3,L1,L2) contains:

3 4 5 3

m

all of them please. I want to see the implementations in order to practice...

give it a complete answer as possible please. Anything would help.