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ReverseEvenNodes.java
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ReverseEvenNodes.java
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package linkedlist;
public class ReverseEvenNodes {
/*
* Given a singly linked list, reverse nodes at even indices:
* Input: 7, 14, 21, 28, 9
* Output: 7, 28, 21, 14, 9
*
* Runtime Complexity:
* Linear, O(n)
*
* Memory Complexity:
* Constant, O(1).
*
*
* Create two lists comprising of nodes at odd and even indices.
* While extracting even nodes, push them at the head of list_even since we need them in reverse order while merging.
* Now that the two lists are in the correct order, it's just a matter of merging their nodes alternately.
* */
public static LinkedList.Node mergeAlternating(LinkedList.Node list1,
LinkedList.Node list2) {
if (list1 == null) {
return list2;
}
if (list2 == null) {
return list1;
}
LinkedList.Node head = list1;
while (list1.next != null &&
list2 != null) {
LinkedList.Node temp = list2;
list2 = list2.next;
temp.next = list1.next;
list1.next = temp;
list1 = temp.next;
}
if (list1.next == null) {
list1.next = list2;
}
return head;
}
public static LinkedList.Node reverseEvenNodes(LinkedList.Node head) {
// Let's extract even nodes from the existing
// list and create a new list consisting of
// even nodes. We will push the even nodes at
// head since we want them to be in reverse order.
LinkedList.Node curr = head;
LinkedList.Node list_even = null;
while (curr != null &&
curr.next != null) {
LinkedList.Node even = curr.next;
curr.next = even.next;
// Push at the head of new list.
even.next = list_even;
list_even = even;
curr = curr.next;
}
// Now, merge the two lists
// Original: 1,2,3,4,5
// Modified original: 1,3,5
// List_even: 4,2
// Merged: 1,4,3,2,5
return mergeAlternating(head, list_even);
}
public static class LinkedList {
private Node head;
public Node head() {
return head;
}
public void printNode(Node node) {
while (node != null) {
System.out.print(node.data + " ");
node = node.next;
}
}
/* Inserts a new Node at end of the list. */
public void push(int new_data) {
Node newNode = new Node(new_data);
if (head == null) {
head = new Node(new_data);
return;
}
newNode.next = null;
Node last = head;
while (last.next != null) {
last = last.next;
}
last.next = newNode;
}
public static class Node {
private Node next;
private Integer data;
public Node(Integer data) {
this.data = data;
}
public Node next() {
return next;
}
public void setNext(Node next) {
this.next = next;
}
public Integer data() {
return data;
}
public void setData(Integer data) {
this.data = data;
}
}
}
public static void main(String[] args) {
LinkedList linkedList1 = new LinkedList();
linkedList1.push(7);
linkedList1.push(14);
linkedList1.push(21);
linkedList1.push(28);
linkedList1.push(9);
System.out.println("List 1: ");
linkedList1.printNode(linkedList1.head);
System.out.println();
LinkedList.Node mergedList = reverseEvenNodes(linkedList1.head);
linkedList1.printNode(mergedList);
}
}