Computer Science/61b/Homework/hw3/SList.java
< Computer Science | 61b | Homework | hw3(Redirected from CS/61b/Homework/hw3/SList.java)- This page contains computer code. Unlike all articles on the lensowiki, which are released under the GFDL, this code is released under the GPL.
Copyright 2006, 2007 Paul Borokhov. All rights reserved.
This code is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version.
The code is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
/* SList.java */
/**
* The SList class is a singly-linked implementation of the linked list
* abstraction. SLists are mutable data structures, which can grow at either
* end.
*
* @author Kathy Yelick and Jonathan Shewchuk
**/
public class SList {
private SListNode head;
private int size;
/**
* SList() constructs an empty list.
**/
public SList() {
size = 0;
head = null;
}
/**
* isEmpty() indicates whether the list is empty.
* @return true if the list is empty, false otherwise.
**/
public boolean isEmpty() {
return size == 0;
}
/**
* length() returns the length of this list.
* @return the length of this list.
**/
public int length() {
return size;
}
/**
* insertFront() inserts item "obj" at the beginning of this list.
* @param obj the item to be inserted.
**/
public void insertFront(Object obj) {
head = new SListNode(obj, head);
size++;
}
/**
* insertEnd() inserts item "obj" at the end of this list.
* @param obj the item to be inserted.
**/
public void insertEnd(Object obj) {
if (head == null) {
head = new SListNode(obj);
} else {
SListNode node = head;
while (node.next != null) {
node = node.next;
}
node.next = new SListNode(obj);
}
size++;
}
/**
* nth() returns the item at the specified position. If position < 1 or
* position > this.length(), null is returned. Otherwise, the item at
* position "position" is returned. The list does not change.
* @param position the desired position, from 1 to length(), in the list.
* @return the item at the given position in the list.
**/
public Object nth(int position) {
SListNode currentNode;
if ((position < 1) || (head == null)) {
return null;
} else {
currentNode = head;
while (position > 1) {
currentNode = currentNode.next;
if (currentNode == null) {
return null;
}
position--;
}
return currentNode.item;
}
}
/**
* squish() takes this list and, wherever two or more consecutive items are
* equal(), it removes duplicate nodes so that only one consecutive copy
* remains. Hence, no two consecutive items in this list are equal() upon
* completion of the procedure.
*
* After squish() executes, the list may well be shorter than when squish()
* began. No extra items are added to make up for those removed.
*
* For example, if the input list is [ 0 0 0 0 1 1 0 0 0 3 3 3 1 1 0 ], the
* output list is [ 0 1 0 3 1 0 ].
*
* IMPORTANT: Be sure you use the equals() method, and not the "=="
* operator, to compare items.
**/
public void squish() {
if (size != 0) {
tool: for (SListNode node=head; node.next != null; node = node.next) {
while (node.next != null && node.item.equals(node.next.item)) {
if (node.next.next != null) { node.next = node.next.next; }
else { node.next = null; break tool; }
}
} } }
/**
* twin() takes this list and doubles its length by replacing each node
* with two consecutive nodes referencing the same item.
*
* For example, if the input list is [ 3 7 4 2 2 ], the
* output list is [ 3 3 7 7 4 4 2 2 2 2 ].
*
* IMPORTANT: Do not try to make new copies of the items themselves.
* Just copy the references to the items.
**/
public void twin() {
if (size != 0) {
tool: for (SListNode node=head; true; node = node.next.next) {
SListNode dupe = new SListNode(node.item, node.next);
node.next = dupe;
if (dupe.next == null) { break tool; }
}
} }
/**
* toString() converts the list to a String.
* @return a String representation of the list.
**/
public String toString() {
int i;
Object obj;
String result = "[ ";
SListNode cur = head;
while (cur != null) {
obj = cur.item;
result = result + obj.toString() + " ";
cur = cur.next;
}
result = result + "]";
return result;
}
/**
* main() runs test cases on the SList class. Prints summary
* information on basic operations and halts with an error (and a stack
* trace) if any of the tests fail.
**/
public static void main (String[] args) {
testEmpty();
testAfterInsertFront();
testAfterInsertEnd();
}
/**
* testEmpty() tests toString(), isEmpty(), length(), insertFront(), and
* insertEnd() on an empty list. Prints summary information of the tests
* and halts the program if errors are detected.
**/
private static void testEmpty() {
SList lst1 = new SList();
SList lst2 = new SList();
System.out.println();
System.out.println("Here is a list after construction: "
+ lst1.toString());
TestHelper.verify(lst1.toString().equals("[ ]"),
"toString on newly constructed list failed");
System.out.println("isEmpty() should be true. It is: " +
lst1.isEmpty());
TestHelper.verify(lst1.isEmpty() == true,
"isEmpty() on newly constructed list failed");
System.out.println("length() should be 0. It is: " +
lst1.length());
TestHelper.verify(lst1.length() == 0,
"length on newly constructed list failed");
lst1.insertFront(new Integer(3));
System.out.println("Here is a list after insertFront(3) to an empty list: "
+ lst1.toString());
TestHelper.verify(lst1.toString().equals("[ 3 ]"),
"InsertFront on empty list failed");
lst2.insertEnd(new Integer(5));
System.out.println("Here is a list after insertEnd(5) on an empty list: "
+ lst2.toString());
TestHelper.verify(lst2.toString().equals("[ 5 ]"),
"insertEnd on empty list failed");
}
/**
* testAfterInsertFront() tests toString(), isEmpty(), length(),
* insertFront(), and insertEnd() after insertFront(). Prints summary
* information of the tests and halts the program if errors are detected.
**/
private static void testAfterInsertFront() {
SList lst1 = new SList();
lst1.insertFront(new Integer(3));
lst1.insertFront(new Integer(2));
lst1.insertFront(new Integer(1));
System.out.println();
System.out.println("Here is a list after insertFront 3, 2, 1: "
+ lst1.toString());
TestHelper.verify(lst1.toString().equals("[ 1 2 3 ]"),
"InsertFronts on non-empty list failed");
System.out.println("isEmpty() should be false. It is: " +
lst1.isEmpty());
TestHelper.verify(lst1.isEmpty() == false,
"isEmpty() after insertFront failed");
System.out.println("length() should be 3. It is: " +
lst1.length());
TestHelper.verify(lst1.length() == 3,
"length() after insertFront failed");
lst1.insertEnd(new Integer(4));
System.out.println("Here is the same list after insertEnd(4): "
+ lst1.toString());
TestHelper.verify(lst1.toString().equals("[ 1 2 3 4 ]"),
"insertEnd on non-empty list failed");
}
/**
* testAfterInsertEnd() tests toString(), isEmpty(), length(),
* insertFront(), and insertEnd() after insertEnd(). Prints summary
* information of the tests and halts the program if errors are detected.
**/
private static void testAfterInsertEnd() {
SList lst1 = new SList();
lst1.insertEnd(new Integer(6));
lst1.insertEnd(new Integer(7));
System.out.println();
System.out.println("Here is a list after insertEnd 6, 7: "
+ lst1.toString());
System.out.println("isEmpty() should be false. It is: " +
lst1.isEmpty());
TestHelper.verify(lst1.isEmpty() == false,
"isEmpty() after insertEnd failed");
System.out.println("length() should be 2. It is: " +
lst1.length());
TestHelper.verify(lst1.length() == 2,
"length() after insertEndfailed");
lst1.insertFront(new Integer(5));
System.out.println("Here is the same list after insertFront(5): "
+ lst1.toString());
TestHelper.verify(lst1.toString().equals("[ 5 6 7 ]"),
"insertFront after insertEnd failed");
}
}