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Python Program For Inserting A Node After The N-th Node From The End

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Insert a node x after the nth node from the end in the given singly linked list. It is guaranteed that the list contains the nth node from the end. Also 1 <= n.

Examples: 

Input : list: 1->3->4->5
        n = 4, x = 2
Output : 1->2->3->4->5
4th node from the end is 1 and
insertion has been done after this node.

Input : list: 10->8->3->12->5->18
        n = 2, x = 11
Output : 10->8->3->12->5->11->18

Method 1 (Using length of the list):
Find the length of the linked list, i.e, the number of nodes in the list. Let it be len. Now traverse the list from the 1st node upto the (len-n+1)th node from the beginning and insert the new node after this node. This method requires two traversals of the list. 

Python3




# Python implementation to insert a node after
# the n-th node from the end
 
# Linked List node
class Node:
    def __init__(self, data):
        self.data = data
        self.next = None
 
# function to get a new node
def getNode(data) :
 
    # allocate memory for the node
    newNode = Node(0)
 
    # put in the data
    newNode.data = data
    newNode.next = None
    return newNode
 
# function to insert a node after the
# nth node from the end
def insertAfterNthNode(head, n, x) :
 
    # if list is empty
    if (head == None) :
        return
 
    # get a new node for the value 'x'
    newNode = getNode(x)
    ptr = head
    len = 0
    i = 0
 
    # find length of the list, i.e, the
    # number of nodes in the list
    while (ptr != None) :
     
        len = len + 1
        ptr = ptr.next
     
    # traverse up to the nth node from the end
    ptr = head
    i = 1
    while ( i <= (len - n) ) :
        ptr = ptr.next
        i = i + 1
 
    # insert the 'newNode' by making the
    # necessary adjustment in the links
    newNode.next = ptr.next
    ptr.next = newNode
 
# function to print the list
def printList( head) :
 
    while (head != None):
     
        print(head.data ,end = " ")
        head = head.next
     
# Driver code
 
# Creating list 1->3->4->5
head = getNode(1)
head.next = getNode(3)
head.next.next = getNode(4)
head.next.next.next = getNode(5)
 
n = 4
x = 2
 
print("Original Linked List: ")
printList(head)
 
insertAfterNthNode(head, n, x)
print()
print("Linked List After Insertion: ")
printList(head)
 
# This code is contributed by Arnab Kundu


Output

Original Linked List: 
1 3 4 5 
Linked List After Insertion: 
1 2 3 4 5 

Time Complexity: O(n), where n is the number of nodes in the list.
Auxiliary space: O(1) because using constant space

Method 2 (Single traversal):
This method uses two pointers, one is slow_ptr and the other is fast_ptr. First move the fast_ptr up to the nth node from the beginning. Make the slow_ptr point to the 1st node of the list. Now, simultaneously move both the pointers until fast_ptr points to the last node. At this point the slow_ptr will be pointing to the nth node from the end. Insert the new node after this node. This method requires single traversal of the list.

Python3




# Python3 implementation to insert a
# node after the nth node from the end
  
# Structure of a node
class Node:
     
    def __init__(self, data):
         
        self.data = data
        self.next = None
     
# Function to get a new node
def getNode(data):
     
    # Allocate memory for the node
    newNode = Node(data)
    return newNode
 
# Function to insert a node after the
# nth node from the end
def insertAfterNthNode(head, n, x):
 
    # If list is empty
    if (head == None):
        return
  
    # Get a new node for the value 'x'
    newNode = getNode(x)
  
    # Initializing the slow and fast pointers
    slow_ptr = head
    fast_ptr = head
  
    # Move 'fast_ptr' to point to the nth
    # node from the beginning
    for i in range(1, n):
        fast_ptr = fast_ptr.next
  
    # Iterate until 'fast_ptr' points to the
    # last node
    while (fast_ptr.next != None):
  
        # Move both the pointers to the
        # respective next nodes
        slow_ptr = slow_ptr.next
        fast_ptr = fast_ptr.next
 
    # Insert the 'newNode' by making the
    # necessary adjustment in the links
    newNode.next = slow_ptr.next
    slow_ptr.next = newNode
 
# Function to print the list
def printList(head):
 
    while (head != None):
        print(head.data, end = ' ')
        head = head.next
     
# Driver code
if __name__=='__main__':
     
    # Creating list 1.3.4.5
    head = getNode(1)
    head.next = getNode(3)
    head.next.next = getNode(4)
    head.next.next.next = getNode(5)
 
    n = 4
    x = 2
 
    print("Original Linked List: ", end = '')
    printList(head)
 
    print()
     
    insertAfterNthNode(head, n, x)
 
    print("Linked List After Insertion: ", end = '')
    printList(head)
 
# This code is contributed by rutvik_56


Output

Original Linked List: 1 3 4 5 
Linked List After Insertion: 1 2 3 4 5 

Time Complexity: O(n), where n is the number of nodes in the list.
Auxiliary space: O(1) because using constant space

Please refer complete article on Insert a node after the n-th node from the end for more details!

Using two pointers:

Approach:

In this approach, we use two pointers, one that is n steps ahead of the other. Once the first pointer reaches the end of the list, the second pointer will be at the nth node from the end. We can then insert the new node after this node.

The Node class has two instance variables: data and next. data stores the value of the node, and next stores a reference to the next node in the list.

The LinkedList class has one instance variable: head. head stores a reference to the first node in the list.

The LinkedList class defines a method insert_after_nth_from_end that inserts a new node with the value x after the nth node from the end of the list.

The method first iterates through the list to count the number of nodes. If the count is less than n, the method returns without making any changes to the list. Otherwise, it iterates through the list again to find the nth node from the end.

It then creates a new node with the value x, inserts it after the nth node from the end, and updates the references of the surrounding nodes accordingly.

The LinkedList class also defines a method print_list that prints the values of all the nodes in the list, separated by spaces.

In the example code provided, a linked list is created with four nodes: 1 -> 3 -> 4 -> 5. The insert_after_nth_from_end method is then called with arguments 4 and 2, which means a new node with the value 2 should be inserted after the fourth node from the end of the list.

Python3




class Node:
    def __init__(self, data=None):
        self.data = data
        self.next = None
 
class LinkedList:
    def __init__(self):
        self.head = None
         
    def insert_after_nth_from_end(self, n, x):
        temp = self.head
        count = 0
         
        while temp:
            temp = temp.next
            count += 1
         
        if count < n:
            return
         
        temp = self.head
        for i in range(count-n):
            temp = temp.next
         
        new_node = Node(x)
        new_node.next = temp.next
        temp.next = new_node
         
    def print_list(self):
        temp = self.head
        while temp:
            print(temp.data, end=' ')
            temp = temp.next
        print()
 
llist = LinkedList()
llist.head = Node(1)
second = Node(3)
third = Node(4)
fourth = Node(5)
 
llist.head.next = second
second.next = third
third.next = fourth
 
llist.insert_after_nth_from_end(4, 2)
llist.print_list()


Output

1 2 3 4 5 

Time complexity: O(n)
Auxiliary Space: O(1)



Last Updated : 07 Apr, 2023
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