Alternate Odd and Even Nodes in a Singly Linked List
Given a singly linked list, rearrange the list so that even and odd nodes are alternate in the list.
There are two possible forms of this rearrangement. If the first data is odd, then the second node must be even. The third node must be odd and so on. Notice that another arrangement is possible where the first node is even, second odd, third even and so on.
Examples:
Input : 11 -> 20 -> 40 -> 55 -> 77 -> 80 -> NULL Output : 11 -> 20 -> 55 -> 40 -> 77 -> 80 -> NULL 20, 40, 80 occur in even positions and 11, 55, 77 occur in odd positions. Input : 10 -> 1 -> 2 -> 3 -> 5 -> 6 -> 7 -> 8 -> NULL Output : 1 -> 10 -> 3 -> 2 -> 5 -> 6 -> 7 -> 8 -> NULL 1, 3, 5, 7 occur in odd positions and 10, 2, 6, 8 occur at even positions in the list
Method 1 (Simple):
In this method, we create two stacks-Odd and Even. We traverse the list and when we encounter an even node in an odd position we push this node’s address onto Even Stack. If we encounter an odd node in an even position we push this node’s address onto Odd Stack.
After traversing the list, we simply pop the nodes at the top of the two stacks and exchange their data. We keep repeating this step until the stacks become empty.
- Step 1: Create two stacks Odd and Even. These stacks will store the pointers to the nodes in the list
- Step 2: Traverse list from start to end, using the variable current. Repeat following steps 3-4
- Step 3: If current node is even and it occurs at an odd position, push this node’s address to stack Even
- Step 4: If current node is odd and it occurs at an even position, push this node’s address to stack Odd.
[END OF TRAVERSAL]- Step 5: The size of both the stacks will be same. While both the stacks are not empty exchange the nodes at the top of the two stacks, and pop both nodes from their respective stacks.
- Step 6: The List is now rearranged. STOP
Implementation:
C++
// CPP program to rearrange nodes // as alternate odd even nodes in // a Singly Linked List #include <bits/stdc++.h> using namespace std; // Structure node struct Node { int data; struct Node* next; }; // A utility function to print // linked list void printList(struct Node* node) { while (node != NULL) { cout << node->data << " "; node = node->next; } cout << endl; } // Function to create newNode // in a linkedlist Node* newNode(int key) { Node* temp = new Node; temp->data = key; temp->next = NULL; return temp; } // Function to insert at beginning Node* insertBeg(Node* head, int val) { Node* temp = newNode(val); temp->next = head; head = temp; return head; } // Function to rearrange the // odd and even nodes void rearrangeOddEven(Node* head) { stack<Node*> odd; stack<Node*> even; int i = 1; while (head != nullptr) { if (head->data % 2 != 0 && i % 2 == 0) { // Odd Value in Even Position // Add pointer to current node // in odd stack odd.push(head); } else if (head->data % 2 == 0 && i % 2 != 0) { // Even Value in Odd Position // Add pointer to current node // in even stack even.push(head); } head = head->next; i++; } while (!odd.empty() && !even.empty()) { // Swap Data at the top of two stacks swap(odd.top()->data, even.top()->data); odd.pop(); even.pop(); } } // Driver code int main() { Node* head = newNode(8); head = insertBeg(head, 7); head = insertBeg(head, 6); head = insertBeg(head, 5); head = insertBeg(head, 3); head = insertBeg(head, 2); head = insertBeg(head, 1); cout << "Linked List:" << endl; printList(head); rearrangeOddEven(head); cout << "Linked List after " << "Rearranging:" << endl; printList(head); return 0; } |
Java
// Java program to rearrange nodes // as alternate odd even nodes in // a Singly Linked List import java.util.*; class GFG { // class node static class Node { int data; Node next; } // A utility function to print // linked list static void printList(Node node) { while (node != null) { System.out.print(node.data +" "); node = node.next; } System.out.println(); } // Function to create newNode // in a linkedlist static Node newNode(int key) { Node temp = new Node(); temp.data = key; temp.next = null; return temp; } // Function to insert at beginning static Node insertBeg(Node head, int val) { Node temp = newNode(val); temp.next = head; head = temp; return head; } // Function to rearrange the // odd and even nodes static void rearrangeOddEven(Node head) { Stack<Node> odd=new Stack<Node>(); Stack<Node> even=new Stack<Node>(); int i = 1; while (head != null) { if (head.data % 2 != 0 && i % 2 == 0) { // Odd Value in Even Position // Add pointer to current node // in odd stack odd.push(head); } else if (head.data % 2 == 0 && i % 2 != 0) { // Even Value in Odd Position // Add pointer to current node // in even stack even.push(head); } head = head.next; i++; } while (odd.size() > 0 && even.size() > 0) { // Swap Data at the top of two stacks int k=odd.peek().data; odd.peek().data=even.peek().data; even.peek().data=k; odd.pop(); even.pop(); } } // Driver code public static void main(String args[]) { Node head = newNode(8); head = insertBeg(head, 7); head = insertBeg(head, 6); head = insertBeg(head, 5); head = insertBeg(head, 3); head = insertBeg(head, 2); head = insertBeg(head, 1); System.out.println( "Linked List:" ); printList(head); rearrangeOddEven(head); System.out.println( "Linked List after "+ "Rearranging:" ); printList(head); } } // This contributed by Arnab Kundu |
Python
# Python program to rearrange nodes # as alternate odd even nodes in # a Singly Linked List # Link list node class Node: def __init__(self, data): self.data = data self.next = next # A utility function to print # linked list def printList( node): while (node != None) : print(node.data , end=" ") node = node.next print("\n") # Function to create newNode # in a linkedlist def newNode(key): temp = Node(0) temp.data = key temp.next = None return temp # Function to insert at beginning def insertBeg(head, val): temp = newNode(val) temp.next = head head = temp return head # Function to rearrange the # odd and even nodes def rearrangeOddEven( head): odd = [] even = [] i = 1 while (head != None): if (head.data % 2 != 0 and i % 2 == 0): # Odd Value in Even Position # Add pointer to current node # in odd stack odd.append(head) elif (head.data % 2 == 0 and i % 2 != 0): # Even Value in Odd Position # Add pointer to current node # in even stack even.append(head) head = head.next i = i + 1 while (len(odd) != 0 and len(even) != 0) : # Swap Data at the top of two stacks odd[-1].data, even[-1].data = even[-1].data, odd[-1].data odd.pop() even.pop() return head # Driver code head = newNode(8) head = insertBeg(head, 7) head = insertBeg(head, 6) head = insertBeg(head, 5) head = insertBeg(head, 3) head = insertBeg(head, 2) head = insertBeg(head, 1) print( "Linked List:" ) printList(head) rearrangeOddEven(head) print( "Linked List after ", "Rearranging:" ) printList(head) # This code is contributed by Arnab Kundu |
C#
// C# program to rearrange nodes // as alternate odd even nodes in // a Singly Linked List using System; using System.Collections.Generic; class GFG { // class node public class Node { public int data; public Node next; } // A utility function to print // linked list static void printList(Node node) { while (node != null) { Console.Write(node.data +" "); node = node.next; } Console.WriteLine(); } // Function to create newNode // in a linkedlist static Node newNode(int key) { Node temp = new Node(); temp.data = key; temp.next = null; return temp; } // Function to insert at beginning static Node insertBeg(Node head, int val) { Node temp = newNode(val); temp.next = head; head = temp; return head; } // Function to rearrange the // odd and even nodes static void rearrangeOddEven(Node head) { Stack<Node> odd = new Stack<Node>(); Stack<Node> even = new Stack<Node>(); int i = 1; while (head != null) { if (head.data % 2 != 0 && i % 2 == 0) { // Odd Value in Even Position // Add pointer to current node // in odd stack odd.Push(head); } else if (head.data % 2 == 0 && i % 2 != 0) { // Even Value in Odd Position // Add pointer to current node // in even stack even.Push(head); } head = head.next; i++; } while (odd.Count > 0 && even.Count > 0) { // Swap Data at the top of two stacks int k=odd.Peek().data; odd.Peek().data=even.Peek().data; even.Peek().data=k; odd.Pop(); even.Pop(); } } // Driver code public static void Main(String []args) { Node head = newNode(8); head = insertBeg(head, 7); head = insertBeg(head, 6); head = insertBeg(head, 5); head = insertBeg(head, 3); head = insertBeg(head, 2); head = insertBeg(head, 1); Console.WriteLine( "Linked List:" ); printList(head); rearrangeOddEven(head); Console.WriteLine( "Linked List after "+ "Rearranging:" ); printList(head); } } // This code has been contributed by 29AjayKumar |
Javascript
<script> // javascript program to rearrange nodes // as alternate odd even nodes in // a Singly Linked List // class node class Node { constructor() { this.data = 0; this.next = null; } } // A utility function to print // linked list function printList(node) { while (node != null) { document.write(node.data + " "); node = node.next; } document.write(); } // Function to create newNode // in a linkedlist function newNode(key) { var temp = new Node(); temp.data = key; temp.next = null; return temp; } // Function to insert at beginning function insertBeg(head , val) { var temp = newNode(val); temp.next = head; head = temp; return head; } // Function to rearrange the // odd and even nodes function rearrangeOddEven(head) { var odd = []; var even = []; var i = 1; while (head != null) { if (head.data % 2 != 0 && i % 2 == 0) { // Odd Value in Even Position // Add pointer to current node // in odd stack odd.push(head); } else if (head.data % 2 == 0 && i % 2 != 0) { // Even Value in Odd Position // Add pointer to current node // in even stack even.push(head); } head = head.next; i++; } while (odd.length > 0 && even.length > 0) { // Swap Data at the top of two stacks var k = odd[odd.length-1].data; odd[odd.length-1].data = even[even.length-1].data; even[even.length-1].data = k; odd.pop(); even.pop(); } } // Driver code var head = newNode(8); head = insertBeg(head, 7); head = insertBeg(head, 6); head = insertBeg(head, 5); head = insertBeg(head, 3); head = insertBeg(head, 2); head = insertBeg(head, 1); document.write("Linked List:<br/>"); printList(head); rearrangeOddEven(head); document.write("<br/>Linked List after " + "Rearranging:<br/>"); printList(head); // This code contributed by aashish1995 </script> |
Output:
Linked List: 1 2 3 5 6 7 8 Linked List after Rearranging: 1 2 3 6 5 8 7
Time Complexity : O(n)
Auxiliary Space : O(n)
Method 2 (Efficient)
- Segregate odd and even values in the list. After this, all odd values will occur together followed by all even values.
- Split the list into two lists odd and even.
- Merge the even list into odd list
REARRANGE (HEAD)
Step 1: Traverse the list using NODE TEMP.
If TEMP is odd
Add TEMP to the beginning of the List
[END OF IF]
[END OF TRAVERSAL]
Step 2: Set TEMP to 2nd element of LIST.
Step 3: Set PREV_TEMP to 1st element of List
Step 4: Traverse using node TEMP as long as an even
node is not encountered.
PREV_TEMP = TEMP, TEMP = TEMP->NEXT
[END OF TRAVERSAL]
Step 5: Set EVEN to TEMP. Set PREV_TEMP->NEXT to NULL
Step 6: I = HEAD, J = EVEN
Step 7: Repeat while I != NULL and J != NULL
Store next nodes of I and J in K and L
K = I->NEXT, L = J->NEXT
I->NEXT = J, J->NEXT = K, PTR = J
I = K and J = L
[END OF LOOP]
Step 8: if I == NULL
PTR->NEXT = J
[END of IF]
Step 8: Return HEAD.
Step 9: End
Implementation:
C++
// Cpp program to rearrange nodes // as alternate odd even nodes in // a Singly Linked List #include <bits/stdc++.h> using namespace std; // Structure node struct Node { int data; struct Node* next; }; // A utility function to print // linked list void printList(struct Node* node) { while (node != NULL) { cout << node->data << " "; node = node->next; } cout << endl; } // Function to create newNode // in a linkedlist Node* newNode(int key) { Node* temp = new Node; temp->data = key; temp->next = NULL; return temp; } // Function to insert at beginning Node* insertBeg(Node* head, int val) { Node* temp = newNode(val); temp->next = head; head = temp; return head; } // Function to rearrange the // odd and even nodes void rearrange(Node** head) { // Step 1: Segregate even and odd nodes // Step 2: Split odd and even lists // Step 3: Merge even list into odd list Node* even; Node *temp, *prev_temp; Node *i, *j, *k, *l, *ptr; // Step 1: Segregate Odd and Even Nodes temp = (*head)->next; prev_temp = *head; while (temp != nullptr) { // Backup next pointer of temp Node* x = temp->next; // If temp is odd move the node // to beginning of list if (temp->data % 2 != 0) { prev_temp->next = x; temp->next = (*head); (*head) = temp; } else { prev_temp = temp; } // Advance Temp Pointer temp = x; } // Step 2 // Split the List into Odd and even temp = (*head)->next; prev_temp = (*head); while (temp != nullptr && temp->data % 2 != 0) { prev_temp = temp; temp = temp->next; } even = temp; // End the odd List (Make last node null) prev_temp->next = nullptr; // Step 3: // Merge Even List into odd i = *head; j = even; while (j != nullptr && i != nullptr) { // While both lists are not // exhausted Backup next // pointers of i and j k = i->next; l = j->next; i->next = j; j->next = k; // ptr points to the latest node added ptr = j; // Advance i and j pointers i = k; j = l; } if (i == nullptr) { // Odd list exhausts before even, // append remainder of even list to odd. ptr->next = j; } // The case where even list exhausts before // odd list is automatically handled since we // merge the even list into the odd list } // Driver Code int main() { Node* head = newNode(8); head = insertBeg(head, 7); head = insertBeg(head, 6); head = insertBeg(head, 3); head = insertBeg(head, 5); head = insertBeg(head, 1); head = insertBeg(head, 2); head = insertBeg(head, 10); cout << "Linked List:" << endl; printList(head); cout << "Rearranged List" << endl; rearrange(&head); printList(head); } |
Java
// Java program to rearrange nodes // as alternate odd even nodes in // a Singly Linked List class GFG { // Structure node static class Node { int data; Node next; }; // A utility function to print // linked list static void printList(Node node) { while (node != null) { System.out.print(node.data + " "); node = node.next; } System.out.println(); } // Function to create newNode // in a linkedlist static Node newNode(int key) { Node temp = new Node(); temp.data = key; temp.next = null; return temp; } // Function to insert at beginning static Node insertBeg(Node head, int val) { Node temp = newNode(val); temp.next = head; head = temp; return head; } // Function to rearrange the // odd and even nodes static Node rearrange(Node head) { // Step 1: Segregate even and odd nodes // Step 2: Split odd and even lists // Step 3: Merge even list into odd list Node even; Node temp, prev_temp; Node i, j, k, l, ptr=null; // Step 1: Segregate Odd and Even Nodes temp = (head).next; prev_temp = head; while (temp != null) { // Backup next pointer of temp Node x = temp.next; // If temp is odd move the node // to beginning of list if (temp.data % 2 != 0) { prev_temp.next = x; temp.next = (head); (head) = temp; } else { prev_temp = temp; } // Advance Temp Pointer temp = x; } // Step 2 // Split the List into Odd and even temp = (head).next; prev_temp = (head); while (temp != null && temp.data % 2 != 0) { prev_temp = temp; temp = temp.next; } even = temp; // End the odd List (Make last node null) prev_temp.next = null; // Step 3: // Merge Even List into odd i = head; j = even; while (j != null && i != null) { // While both lists are not // exhausted Backup next // pointers of i and j k = i.next; l = j.next; i.next = j; j.next = k; // ptr points to the latest node added ptr = j; // Advance i and j pointers i = k; j = l; } if (i == null) { // Odd list exhausts before even, // append remainder of even list to odd. ptr.next = j; } // The case where even list exhausts before // odd list is automatically handled since we // merge the even list into the odd list return head; } // Driver Code public static void main(String args[]) { Node head = newNode(8); head = insertBeg(head, 7); head = insertBeg(head, 6); head = insertBeg(head, 3); head = insertBeg(head, 5); head = insertBeg(head, 1); head = insertBeg(head, 2); head = insertBeg(head, 10); System.out.println("Linked List:" ); printList(head); System.out.println("Rearranged List" ); head=rearrange(head); printList(head); } } // This code is contributed by Arnab Kundu |
Python3
# Python3 program to rearrange nodes # as alternate odd even nodes in # a Singly Linked List # Structure node class Node : def __init__(self): self.data = 0 self.next = None # A utility function to print # linked list def printList(node) : while (node != None) : print(node.data, end = " ") node = node.next print(" ") # Function to create newNode # in a linkedlist def newNode( key) : temp = Node() temp.data = key temp.next = None return temp # Function to insert at beginning def insertBeg( head, val) : temp = newNode(val) temp.next = head head = temp return head # Function to rearrange the # odd and even nodes def rearrange(head) : # Step 1: Segregate even and odd nodes # Step 2: Split odd and even lists # Step 3: Merge even list into odd list even = None temp = None prev_temp = None i = None j = None k = None l = None ptr = None # Step 1: Segregate Odd and Even Nodes temp = (head).next prev_temp = head while (temp != None) : # Backup next pointer of temp x = temp.next # If temp is odd move the node # to beginning of list if (temp.data % 2 != 0) : prev_temp.next = x temp.next = (head) (head) = temp else: prev_temp = temp # Advance Temp Pointer temp = x # Step 2 # Split the List into Odd and even temp = (head).next prev_temp = (head) while (temp != None and temp.data % 2 != 0) : prev_temp = temp temp = temp.next even = temp # End the odd List (Make last node None) prev_temp.next = None # Step 3: # Merge Even List into odd i = head j = even while (j != None and i != None): # While both lists are not # exhausted Backup next # pointers of i and j k = i.next l = j.next i.next = j j.next = k # ptr points to the latest node added ptr = j # Advance i and j pointers i = k j = l if (i == None): # Odd list exhausts before even, # append remainder of even list to odd. ptr.next = j # The case where even list exhausts before # odd list is automatically handled since we # merge the even list into the odd list return head # Driver Code head = newNode(8) head = insertBeg(head, 7) head = insertBeg(head, 6) head = insertBeg(head, 3) head = insertBeg(head, 5) head = insertBeg(head, 1) head = insertBeg(head, 2) head = insertBeg(head, 10) print("Linked List:" ) printList(head) print("Rearranged List" ) head = rearrange(head) printList(head) # This code is contributed by Arnab Kundu |
C#
// C# program to rearrange nodes // as alternate odd even nodes in // a Singly Linked List using System; class GFG { // Structure node public class Node { public int data; public Node next; }; // A utility function to print // linked list static void printList(Node node) { while (node != null) { Console.Write(node.data + " "); node = node.next; } Console.WriteLine(); } // Function to create newNode // in a linkedlist static Node newNode(int key) { Node temp = new Node(); temp.data = key; temp.next = null; return temp; } // Function to insert at beginning static Node insertBeg(Node head, int val) { Node temp = newNode(val); temp.next = head; head = temp; return head; } // Function to rearrange the // odd and even nodes static Node rearrange(Node head) { // Step 1: Segregate even and odd nodes // Step 2: Split odd and even lists // Step 3: Merge even list into odd list Node even; Node temp, prev_temp; Node i, j, k, l, ptr=null; // Step 1: Segregate Odd and Even Nodes temp = (head).next; prev_temp = head; while (temp != null) { // Backup next pointer of temp Node x = temp.next; // If temp is odd move the node // to beginning of list if (temp.data % 2 != 0) { prev_temp.next = x; temp.next = (head); (head) = temp; } else { prev_temp = temp; } // Advance Temp Pointer temp = x; } // Step 2 // Split the List into Odd and even temp = (head).next; prev_temp = (head); while (temp != null && temp.data % 2 != 0) { prev_temp = temp; temp = temp.next; } even = temp; // End the odd List (Make last node null) prev_temp.next = null; // Step 3: // Merge Even List into odd i = head; j = even; while (j != null && i != null) { // While both lists are not // exhausted Backup next // pointers of i and j k = i.next; l = j.next; i.next = j; j.next = k; // ptr points to the latest node added ptr = j; // Advance i and j pointers i = k; j = l; } if (i == null) { // Odd list exhausts before even, // append remainder of even list to odd. ptr.next = j; } // The case where even list exhausts before // odd list is automatically handled since we // merge the even list into the odd list return head; } // Driver Code public static void Main(String []args) { Node head = newNode(8); head = insertBeg(head, 7); head = insertBeg(head, 6); head = insertBeg(head, 3); head = insertBeg(head, 5); head = insertBeg(head, 1); head = insertBeg(head, 2); head = insertBeg(head, 10); Console.WriteLine("Linked List:" ); printList(head); Console.WriteLine("Rearranged List" ); head=rearrange(head); printList(head); } } // This code is contributed by Rajput-Ji |
Javascript
<script> // JavaScript program to rearrange nodes // as alternate odd even nodes in // a Singly Linked List // Structure node class Node { constructor() { this.data = 0; this.next = null; } } // A utility function to print // linked list function printList(node) { while (node != null) { document.write(node.data + " "); node = node.next; } document.write("<br/>"); } // Function to create newNode // in a linkedlist function newNode(key) { var temp = new Node(); temp.data = key; temp.next = null; return temp; } // Function to insert at beginning function insertBeg(head , val) { var temp = newNode(val); temp.next = head; head = temp; return head; } // Function to rearrange the // odd and even nodes function rearrange(head) { // Step 1: Segregate even and odd nodes // Step 2: Split odd and even lists // Step 3: Merge even list into odd list var even; var temp, prev_temp; var i, j, k, l, ptr = null; // Step 1: Segregate Odd and Even Nodes temp = (head).next; prev_temp = head; while (temp != null) { // Backup next pointer of temp var x = temp.next; // If temp is odd move the node // to beginning of list if (temp.data % 2 != 0) { prev_temp.next = x; temp.next = (head); (head) = temp; } else { prev_temp = temp; } // Advance Temp Pointer temp = x; } // Step 2 // Split the List into Odd and even temp = (head).next; prev_temp = (head); while (temp != null && temp.data % 2 != 0) { prev_temp = temp; temp = temp.next; } even = temp; // End the odd List (Make last node null) prev_temp.next = null; // Step 3: // Merge Even List into odd i = head; j = even; while (j != null && i != null) { // While both lists are not // exhausted Backup next // pointers of i and j k = i.next; l = j.next; i.next = j; j.next = k; // ptr points to the latest node added ptr = j; // Advance i and j pointers i = k; j = l; } if (i == null) { // Odd list exhausts before even, // append remainder of even list to odd. ptr.next = j; } // The case where even list exhausts before // odd list is automatically handled since we // merge the even list into the odd list return head; } // Driver Code var head = newNode(8); head = insertBeg(head, 7); head = insertBeg(head, 6); head = insertBeg(head, 3); head = insertBeg(head, 5); head = insertBeg(head, 1); head = insertBeg(head, 2); head = insertBeg(head, 10); document.write("Linked List:<br/>"); printList(head); document.write("Rearranged List<br/>"); head = rearrange(head); printList(head); // This code contributed by umadevi9616 </script> |
Output:
Linked List: 10 2 1 5 3 6 7 8 Rearranged List 7 10 3 2 5 6 1 8
Time Complexity : O(n)
Auxiliary Space : O(1)
Please Login to comment...