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Insertion in a Doubly Linked List

Inserting a new node in a doubly linked list is very similar to inserting new node in linked list. There is a little extra work required to maintain the link of the previous node. A node can be inserted in a Doubly Linked List in four ways:

  • At the front of the DLL. 
  • In between two nodes
    • After a given node.
    • Before a given node.
  • At the end of the DLL.

Add a node at the front in a Doubly Linked List:

The new node is always added before the head of the given Linked List. The task can be performed by using the following 5 steps:

  1. Firstly, allocate a new node (say new_node).
  2. Now put the required data in the new node.
  3. Make the next of new_node point to the current head of the doubly linked list.
  4. Make the previous of the current head point to new_node.
  5. Lastly, point head to new_node.

Illustration:

See the below illustration where E is being inserted at the beginning of the doubly linked list.

dll_add_front

Below is the implementation of the 5 steps to insert a node at the front of the linked list:

C




// Given a reference (pointer to pointer) to the head
// of a list and an int, inserts a new node
// on the front of the list.
void push(struct Node** head_ref, int new_data)
{
    // 1. allocate node
    struct Node* new_node
        = (struct Node*)malloc(sizeof(struct Node));
 
    // 2. put in the data
    new_node->data = new_data;
 
    // 3. Make next of new node as head and previous as NULL
    new_node->next = (*head_ref);
    new_node->prev = NULL;
 
    // 4. change prev of head node to new node
    if ((*head_ref) != NULL)
        (*head_ref)->prev = new_node;
 
    // 5. move the head to point to the new node
    (*head_ref) = new_node;
}


C++




// Given a reference (pointer to pointer) to the head
// of a list and an int, inserts a new node
// on the front of the list.
void push(Node** head_ref, int new_data)
{
    // 1. allocate node
    Node* new_node = new Node();
 
    // 2. put in the data
    new_node->data = new_data;
 
    // 3. Make next of new node as head
    // and previous as NULL
    new_node->next = (*head_ref);
    new_node->prev = NULL;
 
    // 4. change prev of head node to new node
    if ((*head_ref) != NULL)
        (*head_ref)->prev = new_node;
 
    // 5. move the head to point to the new node
    (*head_ref) = new_node;
}
 
// This code is contributed by shivanisinghss2110


Java




// Adding a node at the front of the list
public void push(int new_data)
{
    // 1. allocate node
    // 2. put in the data */
    Node new_Node = new Node(new_data);
 
    // 3. Make next of new node as head and previous as NULL
    new_Node.next = head;
    new_Node.prev = null;
 
    // 4. change prev of head node to new node
    if (head != null)
        head.prev = new_Node;
 
    // 5. move the head to point to the new node
    head = new_Node;
}


Python3




# Adding a node at the front of the list
def push(self, new_data):
 
    # 1 & 2: Allocate the Node & Put in the data
    new_node = Node(data=new_data)
 
    # 3. Make next of new node as head and previous as NULL
    new_node.next = self.head
    new_node.prev = None
 
    # 4. change prev of head node to new node
    if self.head is not None:
        self.head.prev = new_node
 
    # 5. move the head to point to the new node
    self.head = new_node
 
# This code is contributed by jatinreaper


C#




// Adding a node at the front of the list
public void push(int new_data)
{
    // 1. allocate node
    // 2. put in the data
    Node new_Node = new Node(new_data);
 
    // 3. Make next of new node as head and previous as NULL
    new_Node.next = head;
    new_Node.prev = null;
 
    // 4. change prev of head node to new node
    if (head != null)
        head.prev = new_Node;
 
    // 5. move the head to point to the new node
    head = new_Node;
}
 
// This code is contributed by aashish1995


Javascript




// Adding a node at the front of the list
function push(new_data)
{
    // 1. allocate node
    // 2. put in the data
    let new_Node = new Node(new_data);
 
    // 3. Make next of new node as head and previous as NULL
    new_Node.next = head;
    new_Node.prev = null;
 
    // 4. change prev of head node to new node
    if (head != null)
        head.prev = new_Node;
 
    // 5. move the head to point to the new node
    head = new_Node;
}
 
// This code is contributed by saurabh_jaiswal.


Time Complexity: O(1)
Auxiliary Space: O(1)

Add a node in between two nodes:

It is further classified into the following two parts:

Add a node after a given node in a Doubly Linked List:

We are given a pointer to a node as prev_node, and the new node is inserted after the given node. This can be done using the following 6 steps:

  1. Firstly create a new node (say new_node).
  2. Now insert the data in the new node.
  3. Point the next of new_node to the next of prev_node.
  4. Point the next of prev_node to new_node.
  5. Point the previous of new_node to prev_node.
  6. Change the pointer of the new node’s previous pointer to new_node.

Illustration:

See the below illustration where ‘E‘ is being inserted after ‘B‘.

dll_add_middle

Below is the implementation of the 7 steps to insert a node after a given node in the linked list:

C




// Given a node as prev_node, insert a new node
// after the given node
void insertAfter(struct Node* prev_node, int new_data)
{
    // Check if the given prev_node is NULL
    if (prev_node == NULL) {
        printf("the given previous node cannot be NULL");
        return;
    }
 
    // 1. allocate new node
    struct Node* new_node
        = (struct Node*)malloc(sizeof(struct Node));
 
    // 2. put in the data
    new_node->data = new_data;
 
    // 3. Make next of new node as next of prev_node
    new_node->next = prev_node->next;
 
    // 4. Make the next of prev_node as new_node
    prev_node->next = new_node;
 
    // 5. Make prev_node as previous of new_node
    new_node->prev = prev_node;
 
    // 6. Change previous of new_node's next node
    if (new_node->next != NULL)
        new_node->next->prev = new_node;
}


C++




// Given a node as prev_node, insert a new node
// after the given node
void insertAfter(Node* prev_node, int new_data)
{
    // Check if the given prev_node is NULL
    if (prev_node == NULL) {
        cout << "the given previous node cannot be NULL";
        return;
    }
 
    // 1. allocate new node
    Node* new_node = new Node();
 
    // 2. put in the data
    new_node->data = new_data;
 
    // 3. Make next of new node as next of prev_node
    new_node->next = prev_node->next;
 
    // 4. Make the next of prev_node as new_node
    prev_node->next = new_node;
 
    // 5. Make prev_node as previous of new_node
    new_node->prev = prev_node;
 
    // 6. Change previous of new_node's next node
    if (new_node->next != NULL)
        new_node->next->prev = new_node;
}
 
// This code is contributed by shivanisinghss2110.


Java




// Given a node as prev_node, insert a new node
// after the given node
public void InsertAfter(Node prev_Node, int new_data)
{
    // Check if the given prev_node is NULL
    if (prev_Node == null) {
        System.out.println(
            "The given previous node cannot be NULL ");
        return;
    }
 
    // 1. allocate node
    // 2. put in the data
    Node new_node = new Node(new_data);
 
    // 3. Make next of new node as next of prev_node
    new_node.next = prev_Node.next;
 
    // 4. Make the next of prev_node as new_node
    prev_Node.next = new_node;
 
    // 5. Make prev_node as previous of new_node
    new_node.prev = prev_Node;
 
    // 6. Change previous of new_node's next node
    if (new_node.next != null)
        new_node.next.prev = new_node;
}


Python3




# Given a node as prev_node, insert
# a new node after the given node
 
 
def insertAfter(self, prev_node, new_data):
 
    # Check if the given prev_node is NULL
    if prev_node is None:
        print("This node doesn't exist in DLL")
        return
 
    # 1. allocate node  &
    # 2. put in the data
    new_node = Node(data=new_data)
 
    # 3. Make next of new node as next of prev_node
    new_node.next = prev_node.next
 
    # 4. Make the next of prev_node as new_node
    prev_node.next = new_node
 
    # 5. Make prev_node as previous of new_node
    new_node.prev = prev_node
 
    # 6. Change previous of new_node's next node
    if new_node.next is not None:
        new_node.next.prev = new_node
 
#  This code is contributed by jatinreaper


C#




// Given a node as prev_node, insert a new node
// after the given node
public void InsertAfter(Node prev_Node, int new_data)
{
    // Check if the given prev_node is NULL
    if (prev_Node == null) {
        Console.WriteLine(
            "The given previous node cannot be NULL ");
        return;
    }
 
    // 1. allocate node
    // 2. put in the data
    Node new_node = new Node(new_data);
 
    // 3. Make next of new node as next of prev_node
    new_node.next = prev_Node.next;
 
    // 4. Make the next of prev_node as new_node
    prev_Node.next = new_node;
 
    // 5. Make prev_node as previous of new_node
    new_node.prev = prev_Node;
 
    // 6. Change previous of new_node's next node
    if (new_node.next != null)
        new_node.next.prev = new_node;
}
 
// This code is contributed by aashish1995


Javascript




<script>
 
function InsertAfter(prev_Node,new_data)
{
        // Check if the given prev_node is NULL
    if (prev_Node == null) {
        document.write("The given previous node cannot be NULL <br>");
        return;
    }
 
    // 1. allocate node
    // 2. put in the data
    let new_node = new Node(new_data);
 
    // 3. Make next of new node as next of prev_node
    new_node.next = prev_Node.next;
 
    // 4. Make the next of prev_node as new_node
    prev_Node.next = new_node;
 
    // 5. Make prev_node as previous of new_node
    new_node.prev = prev_Node;
 
    // 6. Change previous of new_node's next node
    if (new_node.next != null)
        new_node.next.prev = new_node;
}
 
 
// This code is contributed by unknown2108
 
</script>


Time Complexity: O(1)
Auxiliary Space: O(1)

Add a node before a given node in a Doubly Linked List: 

Let the pointer to this given node be next_node. This can be done using the following 6 steps. 

  1. Allocate memory for the new node, let it be called new_node.
  2. Put the data in new_node.
  3. Set the previous pointer of this new_node as the previous node of the next_node.
  4. Set the previous pointer of the next_node as the new_node.
  5. Set the next pointer of this new_node as the next_node.
  6. Now set the previous pointer of new_node.
    • If the previous node of the new_node is not NULL, then set the next pointer of this previous node as new_node.
    • Else, if the prev of new_node is NULL, it will be the new head node.

Illustration:

See the below illustration where ‘B‘ is being inserted before ‘C‘.

Below is the implementation of the above approach.

C




// Given a node as prev_node, insert a new node
// after the given node
void insertBefore(struct Node* next_node, int new_data)
{
    // Check if the given next_node is NULL
    if (next_node == NULL) {
        printf("the given next node cannot be NULL");
        return;
    }
 
    // 1. Allocate new node
    struct Node* new_node
        = (struct Node*)malloc(sizeof(struct Node));
 
    // 2. Put in the data
    new_node->data = new_data;
 
    // 3. Make previous of new node as previous of next_node
    new_node->prev = next_node->prev;
 
    // 4. Make the previous of next_node as new_node
    next_node->prev = new_node;
 
    // 5. Make next_node as next of new_node
    new_node->next = next_node;
 
    // 6. Change next of new_node's previous node
    if (new_node->prev != NULL)
        new_node->prev->next = new_node;
    else
        head = new_node;
}


C++




// Given a node as prev_node, insert a new node
// after the given node
void insertBefore(Node* next_node, int new_data)
{
    // Check if the given next_node is NULL
    if (next_node == NULL) {
        printf("the given next node cannot be NULL");
        return;
    }
 
    // 1. Allocate new node
    Node* new_node = new Node();
 
    // 2. Put in the data
    new_node->data = new_data;
 
    // 3. Make previous of new node as previous of next_node
    new_node->prev = next_node->prev;
 
    // 4. Make the previous of next_node as new_node
    next_node->prev = new_node;
 
    // 5. Make next_node as next of new_node
    new_node->next = next_node;
 
    // 6. Change next of new_node's previous node
    if (new_node->prev != NULL)
        new_node->prev->next = new_node;
    else
        head = new_node;
}


Java




// Given a node as prev_node, insert a new node
// after the given node
public void InsertBefore(Node next_Node, int new_data)
{
    // Check if the given next_node is NULL
    if (next_Node == null) {
        System.out.println(
            "The given next node cannot be NULL ");
        return;
    }
 
    // 1. Allocate node
    // 2. Put in the data
    Node new_node = new Node(new_data);
 
    // 3. Make previous of new node as previous of prev_node
    new_node.prev = next_Node.prev;
 
    // 4. Make the prev of next_node as new_node
    next_Node.prev = new_node;
 
    // 5. Make next_node as next of new_node
    new_node.next = next_Node;
 
    // 6. Change next of new_node's previous node
    if (new_node.prev != null)
        new_node.prev.next = new_node;
    else
        head = new_node;
}


Python3




# Given a node as prev_node, insert
# a new node after the given node
 
 
def insertAfter(self, next_node, new_data):
 
    # Check if the given next_node is NULL
    if next_node is None:
        print("This node doesn't exist in DLL")
        return
 
    # 1. Allocate node  &
    # 2. Put in the data
    new_node = Node(data=new_data)
 
    # 3. Make previous of new node as previous of prev_node
    new_node.prev = next_node.prev
 
    # 4. Make the previous of next_node as new_node
    next_node.prev = new_node
 
    # 5. Make next_node as next of new_node
    new_node.next = next_node
 
    # 6. Change next of new_node's previous node
    if new_node.prev is not None:
        new_node.prev.next = new_node
    else:
        head = new_node
 
#  This code is contributed by jatinreaper


C#




// Given a node as prev_node, insert a new node
// after the given node
public void InsertAfter(Node next_Node, int new_data)
{
    // Check if the given next_node is NULL
    if (next_Node == null) {
        Console.WriteLine(
            "The given next node cannot be NULL ");
        return;
    }
 
    // 1. Allocate node
    // 2. Put in the data
    Node new_node = new Node(new_data);
 
    // 3. Make previous of new node as previous of next_node
    new_node.prev = next_Node.prev;
 
    // 4. Make the previous of next_node as new_node
    next_Node.prev = new_node;
 
    // 5. Make next_node as next of new_node
    new_node.next = next_Node;
 
    // 6. Change next of new_node's previous node
    if (new_node.prev != null)
        new_node.prev.next = new_node;
    else
        head = new_node;
}
 
// This code is contributed by aashish1995


Javascript




<script>
 
function InsertAfter(next_Node,new_data)
{
        // Check if the given next_Node is NULL
    if (next_Node == null) {
        document.write("The given next node cannot be NULL <br>");
        return;
    }
 
    // 1. Allocate node
    // 2. Put in the data
    let new_node = new Node(new_data);
 
    // 3. Make previous of new node as previous of next_node
    new_node.prev = next_Node.prev;
 
    // 4. Make the previous of next_node as new_node
    next_Node.prev = new_node;
 
    // 5. Make next_node as next of new_node
    new_node.next = next_Node;
 
    // 6. Change next of new_node's previous node
    if (new_node.prev != null)
        new_node.prev.next = new_node;
    else
        head = new_node;
}
 
 
// This code is contributed by unknown2108
 
</script>


Time Complexity: O(1)
Auxiliary Space: O(1)

Add a node at the end in a Doubly Linked List:

The new node is always added after the last node of the given Linked List. This can be done using the following 7 steps:

  1. Create a new node (say new_node).
  2. Put the value in the new node.
  3. Make the next pointer of new_node as null.
  4. If the list is empty, make new_node as the head.
  5. Otherwise, travel to the end of the linked list.
  6. Now make the next pointer of last node point to new_node.
  7. Change the previous pointer of new_node to the last node of the list.

Illustration:

See the below illustration where ‘D‘ is inserted at the end of the linked list.

dll_add_end

Below is the implementation of the 7 steps to insert a node at the end of the linked list:

C




// Given a reference (pointer to pointer) to the head
// of a DLL and an int, appends a new node at the end
void append(struct Node** head_ref, int new_data)
{
    // 1. allocate node
    struct Node* new_node
        = (struct Node*)malloc(sizeof(struct Node));
 
    struct Node* last = *head_ref; /* used in step 5*/
 
    // 2. put in the data
    new_node->data = new_data;
 
    // 3. This new node is going to be the last node, so
    // make next of it as NULL
    new_node->next = NULL;
 
    // 4. If the Linked List is empty, then make the new
    // node as head
    if (*head_ref == NULL) {
        new_node->prev = NULL;
        *head_ref = new_node;
        return;
    }
 
    // 5. Else traverse till the last node
    while (last->next != NULL)
        last = last->next;
 
    // 6. Change the next of last node
    last->next = new_node;
 
    // 7. Make last node as previous of new node
    new_node->prev = last;
 
    return;
}


C++




// Given a reference (pointer to pointer) to the head
// of a DLL and an int, appends a new node at the end
void append(Node** head_ref, int new_data)
{
    // 1. allocate node
    Node* new_node = new Node();
 
    Node* last = *head_ref; /* used in step 5*/
 
    // 2. put in the data
    new_node->data = new_data;
 
    // 3. This new node is going to be the last node, so
    // make next of it as NULL
    new_node->next = NULL;
 
    // 4. If the Linked List is empty, then make the new
    // node as head
    if (*head_ref == NULL) {
        new_node->prev = NULL;
        *head_ref = new_node;
        return;
    }
 
    // 5. Else traverse till the last node
    while (last->next != NULL)
        last = last->next;
 
    // 6. Change the next of last node
    last->next = new_node;
 
    // 7. Make last node as previous of new node
    new_node->prev = last;
 
    return;
}
 
// This code is contributed by shivanisinghss2110


Java




// Add a node at the end of the list
void append(int new_data)
{
    // 1. allocate node
    // 2. put in the data
    Node new_node = new Node(new_data);
 
    Node last = head; /* used in step 5*/
 
    // 3. This new node is going to be the last node, so
    // make next of it as NULL
    new_node.next = null;
 
    // 4. If the Linked List is empty, then make the new
    // node as head
    if (head == null) {
        new_node.prev = null;
        head = new_node;
        return;
    }
 
    // 5. Else traverse till the last node
    while (last.next != null)
        last = last.next;
 
    // 6. Change the next of last node
    last.next = new_node;
 
    // 7. Make last node as previous of new node
    new_node.prev = last;
}


Python3




# Add a node at the end of the DLL
def append(self, new_data):
 
    # 1. allocate node
    # 2. put in the data
    new_node = Node(data=new_data)
    last = self.head
 
    # 3. This new node is going to be the
    # last node, so make next of it as NULL
    new_node.next = None
 
    # 4. If the Linked List is empty, then
    #  make the new node as head
    if self.head is None:
        new_node.prev = None
        self.head = new_node
        return
 
    # 5. Else traverse till the last node
    while (last.next is not None):
        last = last.next
 
    # 6. Change the next of last node
    last.next = new_node
    # 7. Make last node as previous of new node */
    new_node.prev = last
 
#  This code is contributed by jatinreaper


C#




// Add a node at the end of the list
void append(int new_data)
{
    // 1. allocate node
    // 2. put in the data
    Node new_node = new Node(new_data);
 
    Node last = head; /* used in step 5*/
 
    // 3. This new node is going
    //  to be the last node, so
    // make next of it as NULL
    new_node.next = null;
 
    // 4. If the Linked List is empty,
    // then make the new node as head
    if (head == null) {
        new_node.prev = null;
        head = new_node;
        return;
    }
 
    // 5. Else traverse till the last node
    while (last.next != null)
        last = last.next;
 
    // 6. Change the next of last node
    last.next = new_node;
 
    // 7. Make last node as previous of new node
    new_node.prev = last;
}
 
// This code is contributed by shivanisinghss2110


Javascript




<script>
// Add a node at the end of the list
function append(new_data)
{
    /* 1. allocate node
     * 2. put in the data */
    var new_node = new Node(new_data);
 
    var last = head; /* used in step 5*/
 
    /* 3. This new node is going to be the last node, so
     * make next of it as NULL*/
    new_node.next = null;
 
    /* 4. If the Linked List is empty, then make the new
     * node as head */
    if (head == null) {
        new_node.prev = null;
        head = new_node;
        return;
    }
 
    /* 5. Else traverse till the last node */
    while (last.next != null)
        last = last.next;
 
    /* 6. Change the next of last node */
    last.next = new_node;
 
    /* 7. Make last node as previous of new node */
    new_node.prev = last;
}
 
// This code is contributed by Rajput-Ji
</script>


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

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