I have a question for combining two linkedlist. Basically, I want to append one linkedlist to the other linkedlist.
Here is my solution. Is there a more efficient way to do it without looping the first linkedlist? Any suggestion would be appreciated.
static Node connect(LinkedList list1, LinkedList list2) {
Node original = list1.first;
Node previous = null;
Node current = list1.first;
while (current != null) {
previous = current;
current = current.next;
}
previous.next = list2.first;
return original;
}
Use list1.addAll(list2) to append list2 at the end of list1.
For linked lists, linkedList.addAll(otherlist) seems to be a very poor choice.
the java api version of linkedList.addAll begins:
public boolean addAll(int index, Collection<? extends E> c) {
checkPositionIndex(index);
Object[] a = c.toArray();
so even when you have 2 linked lists, the second one gets converted to an array, then re-constituted into individual elements. This is worse than just merging 2 arrays.
I guess this is your own linked list implementation? With only a pointer to next element, the only way to append at the end is to walk all the elements of the first list.
However, you could store a pointer to the last element to make this operation run in constant time (just remember to update the last element of the new list to be the last element of the added list).
The best way is to append the second list to the first list.
1. Create a Node Class.
2. Create New LinkedList Class.
public class LinkedList<T> {
public Node<T> head = null;
public LinkedList() {}
public void addNode(T data){
if(head == null) {
head = new Node<T>(data);
} else {
Node<T> curr = head;
while(curr.getNext() != null) {
curr = curr.getNext();
}
curr.setNext(new Node<T>(data));
}
}
public void appendList(LinkedList<T> linkedList) {
if(linkedList.head == null) {
return;
} else {
Node<T> curr = linkedList.head;
while(curr != null) {
addNode((T) curr.getData());
curr = curr.getNext();
}
}
}
}
3. In the Main function or whereever you want this append to happen, do it like this.
LinkedList<Integer> n = new LinkedListNode().new LinkedList<Integer>();
n.addNode(23);
n.addNode(41);
LinkedList<Integer> n1 = new LinkedListNode().new LinkedList<Integer>();
n1.addNode(50);
n1.addNode(34);
n.appendList(n1);
I like doing this way so that there isn't any need for you to pass both these and loop again in the first LinkedList.
Hope that helps
My Total Code:
NOTE: WITHOUT USING JAVA API
class Node {
Node next;
int data;
Node(int d){
data = d;
next = null;
}
}
public class OddEvenList {
Node head;
public void push(int new_data){
Node new_node = new Node(new_data);
new_node.next = head;
head = new_node;
}
Node reverse(Node head){
Node prev = null;
Node next = null;
Node curr = head;
while(curr != null){
next = curr.next;
curr.next = prev;
prev = curr;
curr = next;
}
head = prev;
return head;
}
Node merge(Node head1, Node head2){
Node curr_odd = head1;
Node curr_even = head2;
Node prev = null;
while(curr_odd != null){
prev = curr_odd;
curr_odd = curr_odd.next;
}
prev.next = curr_even;
return head1;
}
public void print(Node head){
Node tnode = head;
while(tnode != null){
System.out.print(tnode.data + " -> ");
tnode = tnode.next;
}
System.out.println("Null");
}
public static void main(String[] args) {
// TODO Auto-generated method stub
OddEvenList odd = new OddEvenList();
OddEvenList even = new OddEvenList();
OddEvenList merge = new OddEvenList();
odd.push(1);
odd.push(3);
odd.push(5);
odd.push(7);
odd.push(9);
System.out.println("Odd List: ");
odd.print(odd.head);
System.out.println("Even List: ");
even.push(0);
even.push(2);
even.push(4);
even.push(6);
even.push(8);
even.print(even.head);
System.out.println("After Revrse: --------------------");
Node node_odd =odd.reverse(odd.head);
Node node_even = even.reverse(even.head);
System.out.println("Odd List: ");
odd.print(node_odd);
System.out.println("Even List: ");
even.print(node_even);
System.out.println("Meged: --------------");
Node merged = merge.merge(node_odd, node_even);
merge.print(merged);
}
}
Related
I'm studying for an exam, and this is a problem from an old test:
We have a singly linked list with a list head with the following declaration:
class Node {
Object data;
Node next;
Node(Object d,Node n) {
data = d;
next = n;
}
}
Write a method void addLast(Node header, Object x) that adds x at the end of the list.
I know that if I actually had something like:
LinkedList someList = new LinkedList();
I could just add items to the end by doing:
list.addLast(x);
But how can I do it here?
class Node {
Object data;
Node next;
Node(Object d,Node n) {
data = d ;
next = n ;
}
public static Node addLast(Node header, Object x) {
// save the reference to the header so we can return it.
Node ret = header;
// check base case, header is null.
if (header == null) {
return new Node(x, null);
}
// loop until we find the end of the list
while ((header.next != null)) {
header = header.next;
}
// set the new node to the Object x, next will be null.
header.next = new Node(x, null);
return ret;
}
}
You want to navigate through the entire linked list using a loop and checking the "next" value for each node. The last node will be the one whose next value is null. Simply make this node's next value a new node which you create with the input data.
node temp = first; // starts with the first node.
while (temp.next != null)
{
temp = temp.next;
}
temp.next = new Node(header, x);
That's the basic idea. This is of course, pseudo code, but it should be simple enough to implement.
public static Node insertNodeAtTail(Node head,Object data) {
Node node = new Node(data);
node.next = null;
if (head == null){
return node;
}
else{
Node temp = head;
while(temp.next != null){
temp = temp.next;
}
temp.next = node;
return head;
}
}
If you keep track of the tail node, you don't need to loop through every element in the list.
Just update the tail to point to the new node:
AddValueToListEnd(value) {
var node = new Node(value);
if(!this.head) { //if the list is empty, set head and tail to this first node
this.head = node;
this.tail = node;
} else {
this.tail.next = node; //point old tail to new node
}
this.tail = node; //now set the new node as the new tail
}
In plain English:
Create a new node with the given value
If the list is empty, point head and tail to the new node
If the list is not empty, set the old tail.next to be the new node
In either case, update the tail pointer to be the new node
Here is a partial solution to your linked list class, I have left the rest of the implementation to you, and also left the good suggestion to add a tail node as part of the linked list to you as well.
The node file :
public class Node
{
private Object data;
private Node next;
public Node(Object d)
{
data = d ;
next = null;
}
public Object GetItem()
{
return data;
}
public Node GetNext()
{
return next;
}
public void SetNext(Node toAppend)
{
next = toAppend;
}
}
And here is a Linked List file :
public class LL
{
private Node head;
public LL()
{
head = null;
}
public void AddToEnd(String x)
{
Node current = head;
// as you mentioned, this is the base case
if(current == null) {
head = new Node(x);
head.SetNext(null);
}
// you should understand this part thoroughly :
// this is the code that traverses the list.
// the germane thing to see is that when the
// link to the next node is null, we are at the
// end of the list.
else {
while(current.GetNext() != null)
current = current.GetNext();
// add new node at the end
Node toAppend = new Node(x);
current.SetNext(toAppend);
}
}
}
loop to the last element of the linked list which have next pointer to null then modify the next pointer to point to a new node which has the data=object and next pointer = null
Here's a hint, you have a graph of nodes in the linked list, and you always keep a reference to head which is the first node in the linkedList.
next points to the next node in the linkedlist, so when next is null you are at the end of the list.
The addLast() needs some optimisation as the while loop inside addLast() has O(n) complexity. Below is my implementation of LinkedList. Run the code with ll.addLastx(i) once and run it with ll.addLast(i) again , you can see their is a lot of difference in processing time of addLastx() with addLast().
Node.java
package in.datastructure.java.LinkedList;
/**
* Created by abhishek.panda on 07/07/17.
*/
public final class Node {
int data;
Node next;
Node (int data){
this.data = data;
}
public String toString(){
return this.data+"--"+ this.next;
}
}
LinkedList.java
package in.datastructure.java.LinkedList;
import java.util.ArrayList;
import java.util.Date;
public class LinkedList {
Node head;
Node lastx;
/**
* #description To append node at end looping all nodes from head
* #param data
*/
public void addLast(int data){
if(head == null){
head = new Node(data);
return;
}
Node last = head;
while(last.next != null) {
last = last.next;
}
last.next = new Node(data);
}
/**
* #description This keep track on last node and append to it
* #param data
*/
public void addLastx(int data){
if(head == null){
head = new Node(data);
lastx = head;
return;
}
if(lastx.next == null){
lastx.next = new Node(data);
lastx = lastx.next;
}
}
public String toString(){
ArrayList<Integer> arrayList = new ArrayList<Integer>(10);
Node current = head;
while(current.next != null) {
arrayList.add(current.data);
current = current.next;
}
if(current.next == null) {
arrayList.add(current.data);
}
return arrayList.toString();
}
public static void main(String[] args) {
LinkedList ll = new LinkedList();
/**
* #description Checking the code optimization of append code
*/
Date startTime = new Date();
for (int i = 0 ; i < 100000 ; i++){
ll.addLastx(i);
}
Date endTime = new Date();
System.out.println("To total processing time : " + (endTime.getTime()-startTime.getTime()));
System.out.println(ll.toString());
}
}
The above programs might give you NullPointerException. This is an easier way to add an element to the end of linkedList.
public class LinkedList {
Node head;
public static class Node{
int data;
Node next;
Node(int item){
data = item;
next = null;
}
}
public static void main(String args[]){
LinkedList ll = new LinkedList();
ll.head = new Node(1);
Node second = new Node(2);
Node third = new Node(3);
Node fourth = new Node(4);
ll.head.next = second;
second.next = third;
third.next = fourth;
fourth.next = null;
ll.printList();
System.out.println("Add element 100 to the last");
ll.addLast(100);
ll.printList();
}
public void printList(){
Node t = head;
while(n != null){
System.out.println(t.data);
t = t.next;
}
}
public void addLast(int item){
Node new_item = new Node(item);
if(head == null){
head = new_item;
return;
}
new_item.next = null;
Node last = head;
Node temp = null;
while(last != null){
if(last != null)
temp = last;
last = last.next;
}
temp.next = new_item;
return;
}
}
Can someone provide the possible ways to print a Linkedlist in reverse in Java.
A way I understand would be to Recursively reach the end of list, And then start printing from the back and come to front recursively.
Please share the possible ways.
I am using a Node having next and previous.
A Solution I figured is below. But here I need to create a variable each time entering in the recursive loop. That's bad :(
public void reversePrinting(int count){
if(count==0){ //to assign the root node to current only once
current=root;
count++;
}
else{ //moving current node to subsequent nodes
current=current.nextNode;
}
int x= current.data;
if(current.nextNode==null){
System.out.println(x);
return;
}
reversePrinting(count);
System.out.println(x);
}
try this, it is able reverse a linkedlist
public class DoReverse{
private Node head;
private static class Node {
private int value;
private Node next;
Node(int value) {
this.value = value;
}
}
public void addToTheLast(Node node) {
if (head == null) {
head = node;
}
else {
Node temp = head;
while (temp.next != null)
temp = temp.next;
temp.next = node;
}
}
public void printList(Node head) {
Node temp = head;
while (temp != null) {
System.out.format("%d ", temp.value);
temp = temp.next;
}
System.out.println();
}
public static Node reverseList(Node head){
Node prev = null;
Node current = head;
Node next = null;
while(current != null){
next = current.next;
current.next = prev;
prev = current;
current = next;
}
head = prev;
return head;
}
public static void main(String[] args) {
DoReverse list = new DoReverse();
// Creating a linked list
Node head = new Node(5);
list.addToTheLast(head);
list.addToTheLast(new Node(6));
list.addToTheLast(new Node(7));
list.addToTheLast(new Node(1));
list.addToTheLast(new Node(2));
list.addToTheLast(new Node(10));
System.out.println("Before Reversing :");
list.printList(head);
Node reverseHead= list.reverseList(head);
System.out.println("After Reversing :");
list.printList(reverseHead);
}
}
Why not copy the list so that it is reversed:
Reversing a linked list in Java, recursively
And then loop the copy of the list like your normally would?
I was trying to reverse a linked list using recursion. I got the solution, but can't get it to work for below question found on internet.
Reverse a linked list using recursion but function should have void
return type.
I was able to implement the function with return type as Node. Below is my solution.
public static Node recursive(Node start) {
// exit condition
if(start == null || start.next == null)
return start;
Node remainingNode = recursive(start.next);
Node current = remainingNode;
while(current.next != null)
current = current.next;
current.next = start;
start.next = null;
return remainingNode;
}
I cannot imagine if there will be such a solution to this problem.
Any suggestions ?
Tested, it works (assuming you have your own implementation of a linked list with Nodes that know the next node).
public static void reverse(Node previous, Node current) {
//if there is next node...
if (current.next != null) {
//...go forth and pwn
reverse(current, current.next);
}
if (previous == null) {
// this was the start node
current.next= null;
} else {
//reverse
current.next= previous;
}
}
You call it with
reverse(null, startNode);
public void recursiveDisplay(Link current){
if(current== null)
return ;
recursiveDisplay(current.next);
current.display();
}
static StringBuilder reverseStr = new StringBuilder();
public static void main(String args[]) {
String str = "9876543210";
reverse(str, str.length() - 1);
}
public static void reverse(String str, int index) {
if (index < 0) {
System.out.println(reverseStr.toString());
} else {
reverseStr.append(str.charAt(index));
reverse(str, index - 1);
index--;
}
}
This should work
static void reverse(List list, int p) {
if (p == list.size() / 2) {
return;
}
Object o1 = list.get(p);
Object o2 = list.get(list.size() - p - 1);
list.set(p, o2);
list.set(list.size() - p - 1, o1);
reverse(list, p + 1);
}
though to be efficient with LinkedList it should be refactored to use ListIterator
I am not familiar with Java, but here is a C++ version. After reversing the list, the head of list is still preserved, which means that the list can still be accessible from the old list head List* h.
void reverse(List* h) {
if (!h || !h->next) {
return;
}
if (!h->next->next) {
swap(h->value, h->next->value);
return;
}
auto next_of_next = h->next->next;
auto new_head = h->next;
reverse(h->next);
swap(h->value, new_head->value);
next_of_next->next = new_head;
h->next = new_head->next;
new_head->next = nullptr;
}
Try this code instead - it actually works
public static ListElement reverseListConstantStorage(ListElement head) {
return reverse(null,head);
}
private static ListElement reverse(ListElement previous, ListElement current) {
ListElement newHead = null;
if (current.getNext() != null) {
newHead = reverse(current, current.getNext());
} else {//end of the list
newHead=current;
newHead.setNext(previous);
}
current.setNext(previous);
return newHead;
}
public static Node recurse2(Node node){
Node head =null;
if(node.next == null) return node;
Node previous=node, current = node.next;
head = recurse2(node.next);
current.next = previous;
previous.next = null;
return head;
}
While calling the function assign the return value as below:
list.head=recurse2(list.head);
The function below is based on the chosen answer from darijan, all I did is adding 2 lines of code so that it'd fit in the code you guys want to work:
public void reverse(Node previous, Node current) {
//if there is next node...
if (current.next != null) {
//...go forth and pwn
reverse(current, current.next);
}
else this.head = current;/*end of the list <-- This line alone would be the fix
since you will now have the former tail of the Linked List set as the new head*/
if (previous == null) {
// this was the start node
current.next= null;
this.tail = current; /*No need for that one if you're not using a Node in
your class to represent the last Node in the given list*/
} else {
//reverse
current.next= previous;
}
}
Also, I've changed it to a non static function so then the way to use it would be: myLinkedList.reverse(null, myLinkedList.head);
Here is my version - void ReverseWithRecursion(Node currentNode)
- It is method of LinkListDemo Class so head is accessible
Base Case - If Node is null, then do nothing and return.
If Node->Next is null, "Make it head" and return.
Other Case - Reverse the Next of currentNode.
public void ReverseWithRecursion(Node currentNode){
if(currentNode == null) return;
if(currentNode.next == null) {head = currentNode; return;}
Node first = currentNode;
Node rest = currentNode.next;
RevereseWithRecursion(rest);
first.next.next = first;
first.next = null;
}
You Call it like this -
LinkListDemo ll = new LinkListDemo(); // assueme class is available
ll.insert(1); // Assume method is available
ll.insert(2);
ll.insert(3);
ll.ReverseWithRecursion(ll.head);
Given that you have a Node class as below:
public class Node
{
public int data;
public Node next;
public Node(int d) //constructor.
{
data = d;
next = null;
}
}
And a linkedList class where you have declared a head node, so that it can be accessed by the methods that you create inside LinkedList class. The method 'ReverseLinkedList' takes a Node as an argument and reverses the ll.
You may do a dry run of the code by considering 1->2 as the linkedList. Where node = 1, node.next = 2.
public class LinkedList
{
public Node? head; //head of list
public LinkedList()
{
head = null;
}
public void ReverseLinkedList(Node node)
{
if(node==null)
{
return;
}
if(node.next==null)
{
head = node;
return;
}
ReverseLinkedList(node.next); // node.next = rest of the linkedList
node.next.next = node; // consider node as the first part of linkedList
node.next = null;
}
}
The simplest method that I can think of it's:
public static <T> void reverse( LinkedList<T> list )
{
if (list.size() <= 1) {
return;
}
T first = list.removeFirst();
reverse( list);
list.addLast( first );
}
I'm trying to improve my recursion skills (or probably gain them for the first time :)). For it, I've written out a Java code to reverse a singly linked list, which is as follows:
node head, prev; // head is pointing to the start of the linked list
void reverselist(node current) {
if (current.next != null) {
reverselist(current.next);
}
if (current.next == null) {
this.head = current;
prev = current;
}
else {
prev.next = current;
current.next = null;
prev = current;
}
}
This code works fine, but for learning's sake, I want to avoid using global variable (node prev) for operations inside the recursive function. So can this function be re-written to avoid it completely? Any other optimizations are welcome :)
A better implementation should be as below:
public Node reverse(Node current)
{
if (current== null || current.next==null) return current;
Node nextItem = current.next;
current.next = null;
Node reverseRest = reverse(nextItem);
nextItem.next = current;
return reverseRest;
}
public Linkedlist reverseList (LinkedList list) {
Node temp = null;
Node nextNode = list;
while(list != null) {
nextNode = list.next;
list.next = temp;
temp = list;
list = nextNode;
}
return temp;
}
private class LinkedList {
int data;
LinkedList next;
}
I'm studying for an exam, and this is a problem from an old test:
We have a singly linked list with a list head with the following declaration:
class Node {
Object data;
Node next;
Node(Object d,Node n) {
data = d;
next = n;
}
}
Write a method void addLast(Node header, Object x) that adds x at the end of the list.
I know that if I actually had something like:
LinkedList someList = new LinkedList();
I could just add items to the end by doing:
list.addLast(x);
But how can I do it here?
class Node {
Object data;
Node next;
Node(Object d,Node n) {
data = d ;
next = n ;
}
public static Node addLast(Node header, Object x) {
// save the reference to the header so we can return it.
Node ret = header;
// check base case, header is null.
if (header == null) {
return new Node(x, null);
}
// loop until we find the end of the list
while ((header.next != null)) {
header = header.next;
}
// set the new node to the Object x, next will be null.
header.next = new Node(x, null);
return ret;
}
}
You want to navigate through the entire linked list using a loop and checking the "next" value for each node. The last node will be the one whose next value is null. Simply make this node's next value a new node which you create with the input data.
node temp = first; // starts with the first node.
while (temp.next != null)
{
temp = temp.next;
}
temp.next = new Node(header, x);
That's the basic idea. This is of course, pseudo code, but it should be simple enough to implement.
public static Node insertNodeAtTail(Node head,Object data) {
Node node = new Node(data);
node.next = null;
if (head == null){
return node;
}
else{
Node temp = head;
while(temp.next != null){
temp = temp.next;
}
temp.next = node;
return head;
}
}
If you keep track of the tail node, you don't need to loop through every element in the list.
Just update the tail to point to the new node:
AddValueToListEnd(value) {
var node = new Node(value);
if(!this.head) { //if the list is empty, set head and tail to this first node
this.head = node;
this.tail = node;
} else {
this.tail.next = node; //point old tail to new node
}
this.tail = node; //now set the new node as the new tail
}
In plain English:
Create a new node with the given value
If the list is empty, point head and tail to the new node
If the list is not empty, set the old tail.next to be the new node
In either case, update the tail pointer to be the new node
Here is a partial solution to your linked list class, I have left the rest of the implementation to you, and also left the good suggestion to add a tail node as part of the linked list to you as well.
The node file :
public class Node
{
private Object data;
private Node next;
public Node(Object d)
{
data = d ;
next = null;
}
public Object GetItem()
{
return data;
}
public Node GetNext()
{
return next;
}
public void SetNext(Node toAppend)
{
next = toAppend;
}
}
And here is a Linked List file :
public class LL
{
private Node head;
public LL()
{
head = null;
}
public void AddToEnd(String x)
{
Node current = head;
// as you mentioned, this is the base case
if(current == null) {
head = new Node(x);
head.SetNext(null);
}
// you should understand this part thoroughly :
// this is the code that traverses the list.
// the germane thing to see is that when the
// link to the next node is null, we are at the
// end of the list.
else {
while(current.GetNext() != null)
current = current.GetNext();
// add new node at the end
Node toAppend = new Node(x);
current.SetNext(toAppend);
}
}
}
loop to the last element of the linked list which have next pointer to null then modify the next pointer to point to a new node which has the data=object and next pointer = null
Here's a hint, you have a graph of nodes in the linked list, and you always keep a reference to head which is the first node in the linkedList.
next points to the next node in the linkedlist, so when next is null you are at the end of the list.
The addLast() needs some optimisation as the while loop inside addLast() has O(n) complexity. Below is my implementation of LinkedList. Run the code with ll.addLastx(i) once and run it with ll.addLast(i) again , you can see their is a lot of difference in processing time of addLastx() with addLast().
Node.java
package in.datastructure.java.LinkedList;
/**
* Created by abhishek.panda on 07/07/17.
*/
public final class Node {
int data;
Node next;
Node (int data){
this.data = data;
}
public String toString(){
return this.data+"--"+ this.next;
}
}
LinkedList.java
package in.datastructure.java.LinkedList;
import java.util.ArrayList;
import java.util.Date;
public class LinkedList {
Node head;
Node lastx;
/**
* #description To append node at end looping all nodes from head
* #param data
*/
public void addLast(int data){
if(head == null){
head = new Node(data);
return;
}
Node last = head;
while(last.next != null) {
last = last.next;
}
last.next = new Node(data);
}
/**
* #description This keep track on last node and append to it
* #param data
*/
public void addLastx(int data){
if(head == null){
head = new Node(data);
lastx = head;
return;
}
if(lastx.next == null){
lastx.next = new Node(data);
lastx = lastx.next;
}
}
public String toString(){
ArrayList<Integer> arrayList = new ArrayList<Integer>(10);
Node current = head;
while(current.next != null) {
arrayList.add(current.data);
current = current.next;
}
if(current.next == null) {
arrayList.add(current.data);
}
return arrayList.toString();
}
public static void main(String[] args) {
LinkedList ll = new LinkedList();
/**
* #description Checking the code optimization of append code
*/
Date startTime = new Date();
for (int i = 0 ; i < 100000 ; i++){
ll.addLastx(i);
}
Date endTime = new Date();
System.out.println("To total processing time : " + (endTime.getTime()-startTime.getTime()));
System.out.println(ll.toString());
}
}
The above programs might give you NullPointerException. This is an easier way to add an element to the end of linkedList.
public class LinkedList {
Node head;
public static class Node{
int data;
Node next;
Node(int item){
data = item;
next = null;
}
}
public static void main(String args[]){
LinkedList ll = new LinkedList();
ll.head = new Node(1);
Node second = new Node(2);
Node third = new Node(3);
Node fourth = new Node(4);
ll.head.next = second;
second.next = third;
third.next = fourth;
fourth.next = null;
ll.printList();
System.out.println("Add element 100 to the last");
ll.addLast(100);
ll.printList();
}
public void printList(){
Node t = head;
while(n != null){
System.out.println(t.data);
t = t.next;
}
}
public void addLast(int item){
Node new_item = new Node(item);
if(head == null){
head = new_item;
return;
}
new_item.next = null;
Node last = head;
Node temp = null;
while(last != null){
if(last != null)
temp = last;
last = last.next;
}
temp.next = new_item;
return;
}
}