Circular doubly-linked list Program plan: In a file “ListIterator.java”, create an interface “ListIterator”, Declare the method “next()” that moves the iterator past the next element. Declare the method “hasNext()” that check if there is an element after the iterator position. Declare the method “previous()”. Declare the method “hasPrevious()”. Declare the method “add()” that adds an element before the position of the iterator and moves the iterator past the added element. Declare the method “remove()” that removes the last traversed element. Declare the method “set()” to set the last traversed element to a previous value. In a file “LinkedList.java”, import the package and create a class “LinkedList”, Declare two object variables of type “Node”. Define the constructor to create an empty linked list. Define the method “getFirst()” that returns the first element in the linked list. Define the method “removeFirst()” to remove the first element in the linked list. Define the method “addFirst()” that adds an element to front of the linked list. Define the method “getLast()” that returns an element last in the linked list. Define the method “removeLast()” that removes an element present last in the linked list. Define the method “addLast()” that adds an element to the last in the linked list. Define the method “listIterator()” of type “ListIterator”, that returns an iterator for iterating through the list. Create a class “Node”, Declare the object variable for “Object”, and “Node”. Create a class “LinkedListIterator”, Declare the necessary object variables. Declare the necessary Boolean variables. Define the constructor to create an iterator that points to the front of the linked list. Define the method “next()”, If there is no next element then throws an exception. Set the Boolean values to the Boolean variables. Check if position is null, set the first element to the position. Otherwise, set the next position to the current position. Returns the value at the position. Define the method “hasNext()” that check whether there is an element after the iteration and before the starting of the list. Define the method “add()”, If position is null, Returns the value. Otherwise, Returns the value. Define the method “previous()”, Check if there is any previous element, Throws an exception. Assign the Boolean value to the Boolean variables. Check the condition, Set the null value to the position. Define the method “hasPrevious()”, Returns the Boolean value. Define the method “add()”, If position is null, Call the method “addFirst()”. Set the first to the position. Check the condition, Call the method “addLast()”. Assign the value. Otherwise, Create a new node. Set the value to the new node. Set the next position to the next pointer of new node. Assign the new node value to the previous of the new next node value. Assign the new node value to the next position. Assign the position to the previous of the new node. Assign the new node to the position. Assign the Boolean values to the Boolean variables. Define the method “remove()”, Assign the value returned from the method “lastPosition()” to the position. Check the condition, Call the method “removeFirst()”. Otherwise, check another condition, Call the method “removeLast()”. Otherwise, Assign the value at the next position to the value at the next of the previous position. Assign the value at the previous position to the previous of the next position. Check if there is an element after the next position, Assign the value at the previous position to the current position. Assign the Boolean values to the Boolean variables. Define the method “set()”, Assign the value returned from the method “lastPosition()”. Assign the value. Define the method “lastPosition()” that returns the last node iterated by the iterator if there was not an immediately preceding call to previous or next. In a file “ListTest.java”, create a class “ListTest”, Define the “main()” method. Create “LinkedList” object. Get and print the number of fields in a circular list. Print the expected result. Call the method “addFirst()”. Call the method “addFirst()”. Call the method “addLast()”. Print he value returned from the method “getFirst()”. Print the expected result. Print the value obtained from the method “getLast()”. Print the expected result. Call the method “removeLast()”. Print the result obtained from the method “getLast()”. Print the expected result. Call the method “removeFirst()”. Print the value returned from the method “getFirst()”. Print the expected result. Call the method “addFirst()”. Assign the value returned from the method “listIterator()”. Print the value returned from the method “hasNext()”. Print the expected result. Call the method “next()” Print the value obtained from the method “hasNext()”. Print the expected result. Print the value returned from the method “hasPrevious()”. Print the expected result. Print the value returned from the method “next()”. Print the expected result. Print the value returned from the method “previous()”. Print the expected result.

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Chapter 16, Problem 7PP

Program Plan Intro

Circular doubly-linked list

Program plan:

In a file “ListIterator.java”, create an interface “ListIterator”,

Declare the method “next()” that moves the iterator past the next element.

Declare the method “hasNext()” that check if there is an element after the iterator position.

Declare the method “previous()”.

Declare the method “hasPrevious()”.

Declare the method “add()” that adds an element before the position of the iterator and moves the iterator past the added element.

Declare the method “remove()” that removes the last traversed element.

Declare the method “set()” to set the last traversed element to a previous value.

In a file “LinkedList.java”, import the package and create a class “LinkedList”,

Declare two object variables of type “Node”.

Define the constructor to create an empty linked list.

Define the method “getFirst()” that returns the first element in the linked list.

Define the method “removeFirst()” to remove the first element in the linked list.

Define the method “addFirst()” that adds an element to front of the linked list.

Define the method “getLast()” that returns an element last in the linked list.

Define the method “removeLast()” that removes an element present last in the linked list.

Define the method “addLast()” that adds an element to the last in the linked list.

Define the method “listIterator()” of type “ListIterator”, that returns an iterator for iterating through the list.

Create a class “Node”,

Declare the object variable for “Object”, and “Node”.

Create a class “LinkedListIterator”,

Declare the necessary object variables.

Declare the necessary Boolean variables.

Define the constructor to create an iterator that points to the front of the linked list.

Define the method “next()”,

If there is no next element then throws an exception.

Set the Boolean values to the Boolean variables.

Check if position is null, set the first element to the position.

Otherwise, set the next position to the current position.

Returns the value at the position.

Define the method “hasNext()” that check whether there is an element after the iteration and before the starting of the list.

Define the method “add()”,

If position is null,

Returns the value.

Otherwise,

Returns the value.

Define the method “previous()”,

Check if there is any previous element,

Throws an exception.

Assign the Boolean value to the Boolean variables.

Check the condition,

Set the null value to the position.

Define the method “hasPrevious()”,

Returns the Boolean value.

Define the method “add()”,

If position is null,

Call the method “addFirst()”.

Set the first to the position.

Check the condition,

Call the method “addLast()”.

Assign the value.

Otherwise,

Create a new node.

Set the value to the new node.

Set the next position to the next pointer of new node.

Assign the new node value to the previous of the new next node value.

Assign the new node value to the next position.

Assign the position to the previous of the new node.

Assign the new node to the position.

Assign the Boolean values to the Boolean variables.

Define the method “remove()”,

Assign the value returned from the method “lastPosition()” to the position.

Check the condition,

Call the method “removeFirst()”.

Otherwise, check another condition,

Call the method “removeLast()”.

Otherwise,

Assign the value at the next position to the value at the next of the previous position.

Assign the value at the previous position to the previous of the next position.

Check if there is an element after the next position,

Assign the value at the previous position to the current position.

Assign the Boolean values to the Boolean variables.

Define the method “set()”,

Assign the value returned from the method “lastPosition()”.

Assign the value.

Define the method “lastPosition()” that returns the last node iterated by the iterator if there was not an immediately preceding call to previous or next.

In a file “ListTest.java”, create a class “ListTest”,

Define the “main()” method.

Create “LinkedList” object.

Get and print the number of fields in a circular list.

Print the expected result.

Call the method “addFirst()”.

Call the method “addFirst()”.

Call the method “addLast()”.

Print he value returned from the method “getFirst()”.

Print the expected result.

Print the value obtained from the method “getLast()”.

Print the expected result.

Call the method “removeLast()”.

Print the result obtained from the method “getLast()”.

Print the expected result.

Call the method “removeFirst()”.

Print the value returned from the method “getFirst()”.

Print the expected result.

Call the method “addFirst()”.

Assign the value returned from the method “listIterator()”.

Print the value returned from the method “hasNext()”.

Print the expected result.

Call the method “next()”

Print the value obtained from the method “hasNext()”.

Print the expected result.

Print the value returned from the method “hasPrevious()”.

Print the expected result.

Print the value returned from the method “next()”.

Print the expected result.

Print the value returned from the method “previous()”.

Print the expected result.

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