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Sort a linked list of 0s, 1s and 2s

Given a linked list of 0s, 1s and 2s, The task is to sort and print it.

Examples

Input: 1 -> 1 -> 2 -> 0 -> 2 -> 0 -> 1 -> NULL 
Output: 0 -> 0 -> 1 -> 1 -> 1 -> 2 -> 2 -> NULL

Input: 1 -> 1 -> 2 -> 1 -> 0 -> NULL 
Output: 0 -> 1 -> 1 -> 1 -> 2 -> NULL 

Source: Microsoft Interview | Set 1 

Sort Linked List of 0s, 1s and 2s using frequency counting:

Follow the below steps to implement the idea: 

  • Traverse the list and count the number of 0s, 1s, and 2s. Let the counts be n1, n2, and n3 respectively.
  • Traverse the list again, fill the first n1 nodes with 0, then n2 nodes with 1, and finally n3 nodes with 2.

Below image is a dry run of the above approach:

Sort a linked list of 0s, 1s and 2s

Below is the implementation of the above approach.

C++




// C++ Program to sort a linked list 0s, 1s or 2s
#include <bits/stdc++.h>
using namespace std;
 
/* Link list node */
class Node
{
    public:
    int data;
    Node* next;
};
 
// Function to sort a linked list of 0s, 1s and 2s
void sortList(Node *head)
{
    int count[3] = {0, 0, 0}; // Initialize count of '0', '1' and '2' as 0
    Node *ptr = head;
 
    /* count total number of '0', '1' and '2'
    * count[0] will store total number of '0's
    * count[1] will store total number of '1's
    * count[2] will store total number of '2's */
    while (ptr != NULL)
    {
        count[ptr->data] += 1;
        ptr = ptr->next;
    }
 
    int i = 0;
    ptr = head;
 
    /* Let say count[0] = n1, count[1] = n2 and count[2] = n3
    * now start traversing list from head node,
    * 1) fill the list with 0, till n1 > 0
    * 2) fill the list with 1, till n2 > 0
    * 3) fill the list with 2, till n3 > 0 */
    while (ptr != NULL)
    {
        if (count[i] == 0)
            ++i;
        else
        {
            ptr->data = i;
            --count[i];
            ptr = ptr->next;
        }
    }
}
 
/* Function to push a node */
void push (Node** head_ref, int new_data)
{
    /* allocate node */
    Node* new_node = new Node();
 
    /* put in the data */
    new_node->data = new_data;
 
    /* link the old list of the new node */
    new_node->next = (*head_ref);
 
    /* move the head to point to the new node */
    (*head_ref) = new_node;
}
 
/* Function to print linked list */
void printList(Node *node)
{
    while (node != NULL)
    {
        cout << node->data << " ";
        node = node->next;
    }
    cout << endl;
}
 
/* Driver code*/
int main(void)
{
    Node *head = NULL;
    push(&head, 0);
    push(&head, 1);
    push(&head, 0);
    push(&head, 2);
    push(&head, 1);
    push(&head, 1);
    push(&head, 2);
    push(&head, 1);
    push(&head, 2);
 
    cout << "Linked List before Sorting\n";
    printList(head);
 
    sortList(head);
 
    cout << "Linked List after Sorting\n";
    printList(head);
 
    return 0;
}
 
// This code is contributed by rathbhupendra


C




// C Program to sort a linked list 0s, 1s or 2s
#include<stdio.h>
#include<stdlib.h>
 
/* Link list node */
struct Node
{
    int data;
    struct Node* next;
};
 
// Function to sort a linked list of 0s, 1s and 2s
void sortList(struct Node *head)
{
    int count[3] = {0, 0, 0};  // Initialize count of '0', '1' and '2' as 0
    struct Node *ptr = head;
 
    /* count total number of '0', '1' and '2'
     * count[0] will store total number of '0's
     * count[1] will store total number of '1's
     * count[2] will store total number of '2's  */
    while (ptr != NULL)
    {
        count[ptr->data] += 1;
        ptr = ptr->next;
    }
 
    int i = 0;
    ptr = head;
 
    /* Let say count[0] = n1, count[1] = n2 and count[2] = n3
     * now start traversing list from head node,
     * 1) fill the list with 0, till n1 > 0
     * 2) fill the list with 1, till n2 > 0
     * 3) fill the list with 2, till n3 > 0  */
    while (ptr != NULL)
    {
        if (count[i] == 0)
            ++i;
        else
        {
            ptr->data = i;
            --count[i];
            ptr = ptr->next;
        }
    }
}
 
/* Function to push a node */
void push (struct Node** head_ref, int new_data)
{
    /* allocate node */
    struct Node* new_node =
        (struct Node*) malloc(sizeof(struct Node));
 
    /* put in the data  */
    new_node->data  = new_data;
 
    /* link the old list of the new node */
    new_node->next = (*head_ref);
 
    /* move the head to point to the new node */
    (*head_ref)    = new_node;
}
 
/* Function to print linked list */
void printList(struct Node *node)
{
    while (node != NULL)
    {
        printf("%d  ", node->data);
        node = node->next;
    }
    printf("\n");
}
 
/* Driver program to test above function*/
int main(void)
{
    struct Node *head = NULL;
    push(&head, 0);
    push(&head, 1);
    push(&head, 0);
    push(&head, 2);
    push(&head, 1);
    push(&head, 1);
    push(&head, 2);
    push(&head, 1);
    push(&head, 2);
 
    printf("Linked List before Sorting \n");
    printList(head);
 
    sortList(head);
 
    printf("Linked List after Sorting \n");
    printList(head);
 
    return 0;
}


Java




// Java program to sort a linked list of 0, 1 and 2
class LinkedList
{
    Node head;  // head of list
  
    /* Linked list Node*/
    class Node
    {
        int data;
        Node next;
        Node(int d) {data = d; next = null; }
    }
 
    void sortList()
    {
       // initialise count of 0 1 and 2 as 0
       int count[] = {0, 0, 0};
        
       Node ptr = head;
        
       /* count total number of '0', '1' and '2'
        * count[0] will store total number of '0's
        * count[1] will store total number of '1's
        * count[2] will store total number of '2's  */
       while (ptr != null)
       {
            count[ptr.data]++;
            ptr = ptr.next;
       }
 
       int i = 0;
       ptr = head;
 
       /* Let say count[0] = n1, count[1] = n2 and count[2] = n3
        * now start traversing list from head node,
        * 1) fill the list with 0, till n1 > 0
        * 2) fill the list with 1, till n2 > 0
        * 3) fill the list with 2, till n3 > 0  */
        while (ptr != null)
        {
            if (count[i] == 0)
                i++;
            else
            {
               ptr.data= i;
               --count[i];
               ptr = ptr.next;
            }
         }
    }                      
 
                    
    /* Utility functions */
 
    /* Inserts a new Node at front of the list. */
    public void push(int new_data)
    {
        /* 1 & 2: Allocate the Node &
                  Put in the data*/
        Node new_node = new Node(new_data);
  
        /* 3. Make next of new Node as head */
        new_node.next = head;
  
        /* 4. Move the head to point to new Node */
        head = new_node;
    }
 
    /* Function to print linked list */
    void printList()
    {
        Node temp = head;
        while (temp != null)
        {
           System.out.print(temp.data+" ");
           temp = temp.next;
        
        System.out.println();
    }
 
     /* Driver program to test above functions */
    public static void main(String args[])
    {
        LinkedList llist = new LinkedList();
         
        /* Constructed Linked List is 1->2->3->4->5->6->7->
           8->8->9->null */
        llist.push(0);
        llist.push(1);
        llist.push(0);
        llist.push(2);
        llist.push(1);
        llist.push(1);
        llist.push(2);
        llist.push(1);
        llist.push(2);
         
        System.out.println("Linked List before sorting");
        llist.printList();
         
        llist.sortList();
 
        System.out.println("Linked List after sorting");
        llist.printList();
    }
}
/* This code is contributed by Rajat Mishra */


Python3




# Python program to sort a linked list of 0, 1 and 2
class LinkedList(object):
    def __init__(self):
 
         # head of list
         self.head = None
 
    # Linked list Node
    class Node(object):
        def __init__(self, d):
            self.data = d
            self.next = None
 
    def sortList(self):
 
        # initialise count of 0 1 and 2 as 0
        count = [0, 0, 0]
 
        ptr = self.head
 
        # count total number of '0', '1' and '2'
        # * count[0] will store total number of '0's
        # * count[1] will store total number of '1's
        # * count[2] will store total number of '2's 
        while ptr != None:
            count[ptr.data]+=1
            ptr = ptr.next
 
        i = 0
        ptr = self.head
 
        # Let say count[0] = n1, count[1] = n2 and count[2] = n3
        # * now start traversing list from head node,
        # * 1) fill the list with 0, till n1 > 0
        # * 2) fill the list with 1, till n2 > 0
        # * 3) fill the list with 2, till n3 > 0 
        while ptr != None:
            if count[i] == 0:
                i+=1
            else:
                ptr.data = i
                count[i]-=1
                ptr = ptr.next
 
 
    # Utility functions
    # Inserts a new Node at front of the list.
    def push(self, new_data):
 
        # 1 & 2: Allocate the Node &
        # Put in the data
        new_node = self.Node(new_data)
 
        # 3. Make next of new Node as head
        new_node.next = self.head
 
        # 4. Move the head to point to new Node
        self.head = new_node
 
    # Function to print linked list
    def printList(self):
        temp = self.head
        while temp != None:
            print (str(temp.data),end=" ")
            temp = temp.next
        print()
 
# Driver program to test above functions
llist = LinkedList()
llist.push(0)
llist.push(1)
llist.push(0)
llist.push(2)
llist.push(1)
llist.push(1)
llist.push(2)
llist.push(1)
llist.push(2)
 
print ("Linked List before sorting")
llist.printList()
 
llist.sortList()
 
print ("Linked List after sorting")
llist.printList()
 
# This code is contributed by BHAVYA JAIN


C#




// C# program to sort a linked
// list of 0, 1 and 2
using System;
 
public class LinkedList
{
    Node head; // head of list
 
    /* Linked list Node*/
    class Node
    {
        public int data;
        public Node next;
        public Node(int d)
        {
            data = d; next = null;
        }
    }
 
    void sortList()
    {
         
        // initialise count of 0 1 and 2 as 0
        int []count = {0, 0, 0};
         
        Node ptr = head;
         
        /* count total number of '0', '1' and '2'
        * count[0] will store total number of '0's
        * count[1] will store total number of '1's
        * count[2] will store total number of '2's */
        while (ptr != null)
        {
               count[ptr.data]++;
            ptr = ptr.next;
        }
 
        int i = 0;
        ptr = head;
 
        /* Let say count[0] = n1, count[1] = n2 and count[2] = n3
        * now start traversing list from head node,
        * 1) fill the list with 0, till n1 > 0
        * 2) fill the list with 1, till n2 > 0
        * 3) fill the list with 2, till n3 > 0 */
        while (ptr != null)
        {
            if (count[i] == 0)
                i++;
            else
            {
                ptr.data= i;
                --count[i];
                ptr = ptr.next;
            }
        }
    }                    
 
                     
    /* Utility functions */
 
    /* Inserts a new Node at front of the list. */
    public void push(int new_data)
    {
        /* 1 & 2: Allocate the Node &
                Put in the data*/
        Node new_node = new Node(new_data);
 
        /* 3. Make next of new Node as head */
        new_node.next = head;
 
        /* 4. Move the head to point to new Node */
        head = new_node;
    }
 
    /* Function to print linked list */
    void printList()
    {
        Node temp = head;
        while (temp != null)
        {
            Console.Write(temp.data+" ");
            temp = temp.next;
        }
        Console.WriteLine();
    }
 
    /* Driver code */
    public static void Main(String []args)
    {
        LinkedList llist = new LinkedList();
         
        /* Constructed Linked List is 1->2->3->4->
        5->6->7->8->8->9->null */
        llist.push(0);
        llist.push(1);
        llist.push(0);
        llist.push(2);
        llist.push(1);
        llist.push(1);
        llist.push(2);
        llist.push(1);
        llist.push(2);
         
        Console.WriteLine("Linked List before sorting");
        llist.printList();
         
        llist.sortList();
 
        Console.WriteLine("Linked List after sorting");
        llist.printList();
    }
}
 
/* This code is contributed by 29AjayKumar */


Javascript




<script>
 
// Javascript program to sort a
// linked list of 0, 1 and 2
var head; // head of list
 
    /* Linked list Node */
     class Node {
            constructor(val) {
                this.data = val;
                this.next = null;
            }
        }
      
 
    function sortList() {
        // initialise count of 0 1 and 2 as 0
        var count = [ 0, 0, 0 ];
 
var ptr = head;
 
        /*
         count total number of '0', '1' and '2'
          count[0] will store total number of
          '0's count[1] will store total number
          of '1's count[2] will store total
          number of '2's
         */
        while (ptr != null) {
            count[ptr.data]++;
            ptr = ptr.next;
        }
 
        var i = 0;
        ptr = head;
 
        /*
         Let say count[0] = n1, count[1] = n2 and
         count[2] = n3 now start traversing
         list from head node, 1) fill the list
         with 0, till n1 > 0 2) fill the list
         with 1, till n2 > 0 3)
         fill the list with 2, till n3 > 0
         */
        while (ptr != null) {
            if (count[i] == 0)
                i++;
            else {
                ptr.data = i;
                --count[i];
                ptr = ptr.next;
            }
        }
    }
 
    /* Utility functions */
 
    /* Inserts a new Node at front of the list. */
     function push(new_data) {
        /*
         * 1 & 2: Allocate the Node & Put in the data
         */
var new_node = new Node(new_data);
 
        /* 3. Make next of new Node as head */
        new_node.next = head;
 
        /* 4. Move the head to point to new Node */
        head = new_node;
    }
 
    /* Function to print linked list */
    function printList() {
    var temp = head;
        while (temp != null) {
            document.write(temp.data + " ");
            temp = temp.next;
        }
        document.write("<br/>");
    }
 
    /* Driver program to test above functions */
     
        /*
         Constructed Linked List is
         1->2->3->4->5->6->7-> 8->8->9->null
         */
        push(0);
        push(1);
        push(0);
        push(2);
        push(1);
        push(1);
        push(2);
        push(1);
        push(2);
 
        document.write("Linked List before sorting<br/>");
        printList();
 
        sortList();
 
        document.write("Linked List after sorting<br/>");
        printList();
 
// This code is contributed by todaysgaurav
 
</script>


Output

Linked List before Sorting
2 1 2 1 1 2 0 1 0 
Linked List after Sorting
0 0 1 1 1 1 2 2 2 
 

Time Complexity: O(n) where n is the number of nodes in the linked list. 
Auxiliary Space: O(1) 

Sort a linked list of 0s, 1s and 2s by changing links

Using a stable sort algorithm:

C++




//C++ code to implement the above approach
#include <iostream>
 
// Define a structure for a node in a linked list
struct Node {
  int data;
  Node *next;
};
 
// Function to insert a new node at the end of the linked list
void push(Node **head, int data) {
  Node *newNode = new Node();
  newNode->data = data;
  newNode->next = nullptr;
 
  if (*head == nullptr) {
    *head = newNode;
    return;
  }
 
  Node *last = *head;
  while (last->next != nullptr) {
    last = last->next;
  }
 
  last->next = newNode;
}
 
// Function to print the linked list
void printList(Node *head) {
  Node *current = head;
  while (current != nullptr) {
    std::cout << current->data << " ";
    current = current->next;
  }
  std::cout << std::endl;
}
 
// Function to sort the linked list containing 0's, 1's, and 2's
void sortList(Node *head) {
  int count[3] = {0, 0, 0};
 
  // Count the number of 0's, 1's, and 2's in the linked list
  Node *current = head;
  while (current != nullptr) {
    count[current->data]++;
    current = current->next;
  }
 
  // Overwrite the linked list with the sorted elements
  current = head;
  int i = 0;
  while (current != nullptr) {
    if (count[i] == 0) {
      i++;
    } else {
      current->data = i;
      count[i]--;
      current = current->next;
    }
  }
}
 
int main() {
  Node *head = nullptr;
 
  // Insert some elements into the linked list
    push(&head, 0);
    push(&head, 1);
    push(&head, 0);
    push(&head, 2);
    push(&head, 1);
    push(&head, 1);
    push(&head, 2);
    push(&head, 1);
    push(&head, 2);
 
  std::cout << "Linked List before Sorting: "<<std::endl;
  printList(head);
 
  sortList(head);
 
  std::cout << "Linked List after Sorting: "<<std::endl;
  printList(head);
 
  return 0;
}
//This code is contributed by Veerendra Singh Rajpoot


Java




// Java code to implement the above approach
import java.util.*;
 
public class Main {
    // Define a class for a node in a linked list
    static class Node {
        int data;
        Node next;
 
        // Constructor to initialize the node with data
        Node(int data)
        {
            this.data = data;
            this.next = null;
        }
    }
 
    // Function to insert a new node at the end of the
    // linked list
    static Node push(Node head, int data)
    {
        Node newNode = new Node(data);
 
        if (head == null) {
            head = newNode;
            return head;
        }
 
        Node last = head;
        while (last.next != null) {
            last = last.next;
        }
 
        last.next = newNode;
        return head;
    }
 
    // Function to print the linked list
    static void printList(Node head)
    {
        Node current = head;
        while (current != null) {
            System.out.print(current.data + " ");
            current = current.next;
        }
        System.out.println();
    }
 
    // Function to sort the linked list containing 0's, 1's,
    // and 2's
    static void sortList(Node head)
    {
        int[] count = { 0, 0, 0 };
 
        // Count the number of 0's, 1's, and 2's in the
        // linked list
        Node current = head;
        while (current != null) {
            count[current.data]++;
            current = current.next;
        }
 
        // Overwrite the linked list with the sorted
        // elements
        current = head;
        int i = 0;
        while (current != null) {
            if (count[i] == 0) {
                i++;
            }
            else {
                current.data = i;
                count[i]--;
                current = current.next;
            }
        }
    }
 
    public static void main(String[] args)
    {
        Node head = null;
 
        // Insert some elements into the linked list
        head = push(head, 0);
        head = push(head, 1);
        head = push(head, 0);
        head = push(head, 2);
        head = push(head, 1);
        head = push(head, 1);
        head = push(head, 2);
        head = push(head, 1);
        head = push(head, 2);
 
        System.out.println("Linked List before Sorting: ");
        printList(head);
 
        sortList(head);
 
        System.out.println("Linked List after Sorting: ");
        printList(head);
    }
}


Python3




# Define a class for a node in a linked list
class Node:
    def __init__(self, data):
        self.data = data
        self.next = None
 
# Function to insert a new node at the end of the linked list
 
 
def push(head, data):
    new_node = Node(data)
 
    if head is None:
        head = new_node
        return head
 
    last = head
    while last.next is not None:
        last = last.next
 
    last.next = new_node
    return head
 
# Function to print the linked list
 
 
def printList(head):
    current = head
    while current is not None:
        print(current.data, end=' ')
        current = current.next
    print()
 
# Function to sort the linked list containing 0's, 1's, and 2's
 
 
def sortList(head):
    count = [0, 0, 0]
 
    # Count the number of 0's, 1's, and 2's in the linked list
    current = head
    while current is not None:
        count[current.data] += 1
        current = current.next
 
    # Overwrite the linked list with the sorted elements
    current = head
    i = 0
    while current is not None:
        if count[i] == 0:
            i += 1
        else:
            current.data = i
            count[i] -= 1
            current = current.next
 
 
# Main function to test the implementation
if __name__ == '__main__':
    head = None
 
    # Insert some elements into the linked list
    head = push(head, 0)
    head = push(head, 1)
    head = push(head, 0)
    head = push(head, 2)
    head = push(head, 1)
    head = push(head, 1)
    head = push(head, 2)
    head = push(head, 1)
    head = push(head, 2)
 
    print("Linked List before Sorting:")
    printList(head)
 
    sortList(head)
 
    print("Linked List after Sorting:")
    printList(head)


C#




using System;
 
class Gfg{
// Define a structure for a node in a linked list
public class Node {
    public int data;
    public Node next;
}
 
// Function to insert a new node at the end of the linked list
public static void Push(ref Node head, int data) {
    Node newNode = new Node();
    newNode.data = data;
    newNode.next = null;
 
    if (head == null) {
        head = newNode;
        return;
    }
 
    Node last = head;
    while (last.next != null) {
        last = last.next;
    }
 
    last.next = newNode;
}
 
// Function to print the linked list
public static void PrintList(Node head) {
    Node current = head;
    while (current != null) {
        Console.Write(current.data + " ");
        current = current.next;
    }
    Console.WriteLine();
}
 
// Function to sort the linked list containing 0's, 1's, and 2's
public static void SortList(Node head) {
    int[] count = {0, 0, 0};
 
    // Count the number of 0's, 1's, and 2's in the linked list
    Node current = head;
    while (current != null) {
        count[current.data]++;
        current = current.next;
    }
 
    // Overwrite the linked list with the sorted elements
    current = head;
    int i = 0;
    while (current != null) {
        if (count[i] == 0) {
            i++;
        } else {
            current.data = i;
            count[i]--;
            current = current.next;
        }
    }
}
 
public static void Main() {
    Node head = null;
 
    // Insert some elements into the linked list
    Push(ref head, 0);
    Push(ref head, 1);
    Push(ref head, 0);
    Push(ref head, 2);
    Push(ref head, 1);
    Push(ref head, 1);
    Push(ref head, 2);
    Push(ref head, 1);
    Push(ref head, 2);
 
    Console.WriteLine("Linked List before Sorting:");
    PrintList(head);
 
    SortList(head);
 
    Console.WriteLine("Linked List after Sorting:");
    PrintList(head);
}
}


Javascript




// Define a class for a node in a linked list
class Node {
constructor(data) {
this.data = data;
this.next = null;
}
}
 
// Function to insert a new node at the end of the linked list
function push(head, data) {
const new_node = new Node(data);
 
if (head === null) {
head = new_node;
return head;
}
 
let last = head;
while (last.next !== null) {
last = last.next;
}
 
last.next = new_node;
return head;
}
 
// Function to print the linked list
function printList(head) {
let current = head;temp="";
while (current !== null) {
temp = temp + current.data+ ' ';
current = current.next;
}
console.log(temp);
}
 
// Function to sort the linked list containing 0's, 1's, and 2's
function sortList(head) {
const count = [0, 0, 0];
 
// Count the number of 0's, 1's, and 2's in the linked list
let current = head;
while (current !== null) {
count[current.data] += 1;
current = current.next;
}
 
// Overwrite the linked list with the sorted elements
current = head;
let i = 0;
while (current !== null) {
if (count[i] === 0) {
i += 1;
} else {
current.data = i;
count[i] -= 1;
current = current.next;
}
}
}
 
// Main function to test the implementation
let head = null;
 
// Insert some elements into the linked list
head = push(head, 0);
head = push(head, 1);
head = push(head, 0);
head = push(head, 2);
head = push(head, 1);
head = push(head, 1);
head = push(head, 2);
head = push(head, 1);
head = push(head, 2);
 
console.log("Linked List before Sorting:");
printList(head);
 
sortList(head);
 
console.log("Linked List after Sorting:");
printList(head);


Output

Linked List before Sorting: 
0 1 0 2 1 1 2 1 2 
Linked List after Sorting: 
0 0 1 1 1 1 2 2 2 

Explanation of the above approach:

  • The Node structure: This structure is used to define a node in a linked list. It contains an integer data to store the data of the node and a pointer next to the next node in the linked list.
  • The push function: This function is used to insert a new node at the end of the linked list. It takes two parameters: a pointer to the head of the linked list and an integer data to be stored in the new node. The function first creates a new node with the given data and sets its next pointer to nullptr. If the linked list is empty, the function sets the head of the linked list to the new node. Otherwise, it iterates through the linked list to find the last node and inserts the new node after it.
  • The printList function: This function is used to print the linked list. It takes one parameter, a pointer to the head of the linked list, and iterates through the list while printing the data of each node.
  • The sortList function: This function is used to sort the linked list. It takes one parameter, a pointer to the head of the linked list. The function first initializes an array count of size 3 to store the count of 0’s, 1’s, and 2’s in the linked list. It then iterates through the linked list and increments the count of each element as it appears. Finally, it overwrites the linked list with the sorted elements. The function iterates through the linked list again and whenever it encounters a node with a value of 0, it sets its data to 0 and decrements the count of 0’s. Similarly, whenever it encounters a node with a value of 1, it sets its data to 1 and decrements the count of 1’s. And whenever it encounters a node with a value of 2, it sets its data to 2 and decrements the count of 2’s.
  • The main function: This function is the entry point of the program. It first creates an empty linked list and inserts some elements into it. It then calls the sortList function to sort the linked list. Finally, it prints the original and sorted linked lists to verify that the sorting is correct.

Note: This is a simple implementation of the “Using a stable sort algorithm” approach for sorting a linked list containing only 0’s, 1’s, and 2’s. It may not be the most efficient implementation for large linked lists, but it should give you a good understanding of the basic idea

Time complexity: O(n),
The time complexity of this implementation is O(n), where n is the number of elements in the linked list. This is because the program iterates through the linked list twice: once to count the number of 0’s, 1’s, and 2’s, and once to overwrite the linked list with the sorted elements. The count operation takes O(n) time and the overwrite operation takes O(n) time, so the total time complexity is O(n) + O(n) = O(n).

Space complexity: O(1),
The space complexity of this implementation is O(1), because it uses only a constant amount of extra memory to store the count array of size 3. The linked list itself is not used to store any additional information during the sorting, so its space complexity remains the same.

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