# Why does linked list delete and insert operation have complexity of O(1) ? shouldn't it be of O(n)

It is said that the complexity of the LinkedList remove and the add operation is of `O(1)`. and in case of `ArrayList` it is of `O(n)`.

Calculation for ArrayList of size "M" : if i want to remove the element at Nth position then i can directly go to the Nth position using index in one go (i don't have to traverse till Nth index) and then i can remove the element, till this point the complexity is O(1) then i will have to shift the rest of the elements(M-N shifts) so my complexity will be linear i.e. O(M-N+1). and hence deletion or insertion at the last will give me the best performence( as N ~ M) and deletion or insertion at the start will be worst (as N ~ 1).

Now the LisnkedList of size "M" : as we can not directly reach the Nth element in the LinkedList, to access the Nth element we have to traverse N elements, so the search in the LinkedList is costlier then the ArrayList...but Remove and the add operations are said to be of O(1) in case of LinkedList as, in LinkedList the Shift is not involved, but there is traverse operation involved rigth ? so the complexity should be of order O(n) where Worst performence will be at the tail node and best performence will be at the head node.

Could anyone please explain me why don't we consider the traverse cost while calculating the complexity of LinkedList remove operation ?

So i wants to understand how it works in java.util package. and if i want to implemet the same in C or C++ how would i achieve the O(1) for random deletion and insertion in LinkedList ?

• Possible duplicate of How is LinkedList's add(int, E) of O(1) complexity? Mar 17, 2017 at 5:07
• The O(1) is for insertion or deletion having found the location in the doubly-linked list at which to perform the operation. If that location is neither the head nor tail of the list, and you haven't pointed to it explicitly in some other way, then you have to find it and that part is O(n). Mar 17, 2017 at 5:10

Remove and the add operations are said to be of O(1) in case of `LinkedList` as, in `LinkedList` the shift is not involved, but there is traverse operation involved right?

Adding to either end of a linked list does not require a traversal, as long as you keep a reference to both ends of the list. This is what Java does for its `add` and `addFirst`/`addLast` methods.

Same goes for parameterless `remove` and `removeFirst`/`removeLast` methods - they operate on list ends.

`remove(int)` and `remove(Object)` operations, on the other hand, are not O(1). They requires traversal, so you correctly identified their costs as O(n).

• "Doubly-linked list implementation of the List and Deque interfaces. Implements all optional list operations, and permits all elements (including null)." This line is from oracle java docs docs.oracle.com/javase/7/docs/api/java/util/…. If it is doubly-linked list implementation, then remove(Object) method should take O(1) right?
– Sam
Feb 4, 2019 at 4:21
• @Sam `Remove(Object)` still requires a scan, so it's O(n). See implementation on line 353 here. Feb 4, 2019 at 10:51
• @AndroidDev93 In `remove(n)` it's not the removal that's O(n), it's getting to node `n` that is. Apr 14, 2019 at 7:58
• @dasblinkenlight if you already have access to the node that needs to be removed, why do you need to spend O(n) to get to the node? There is a version of the remove function that takes the Node Object as input. When you have Object, you do not need to spend O(n) to get to the Object. So, the remove function will be O(1). Apr 15, 2019 at 8:32
• You don't have access to node because nodes are kept private to LinkedList and are not given to outside world. If LinkedList.add method returned a Node to you, then yes, you could use that node to delete element in O(1). But that's not the case. LinkedList.remove method is given the object, not the node, and have to traverse the list to find the node containing that object Nov 27, 2019 at 10:06

The complexity of removing is considered that you already have the pointer to the right position of the element you want to remove...

Is not considered the cost you took for finding it

``````Information on this topic is now available on Wikipedia at: Search data structure

+----------------------+----------+------------+----------+--------------+
|                      |  Insert  |   Delete   |  Search  | Space Usage  |
+----------------------+----------+------------+----------+--------------+
| Unsorted array       | O(1)     | O(1)       | O(n)     | O(n)         |
| Value-indexed array  | O(1)     | O(1)       | O(1)     | O(n)         |
| Sorted array         | O(n)     | O(n)       | O(log n) | O(n)         |
| Unsorted linked list | O(1)*    | O(1)*      | O(n)     | O(n)         |
| Sorted linked list   | O(n)*    | O(1)*      | O(n)     | O(n)         |
| Balanced binary tree | O(log n) | O(log n)   | O(log n) | O(n)         |
| Heap                 | O(log n) | O(log n)** | O(n)     | O(n)         |
| Hash table           | O(1)     | O(1)       | O(1)     | O(n)         |
+----------------------+----------+------------+----------+--------------+

* The cost to add or delete an element into a known location in the list (i.e. if you have an iterator to the location) is O(1). If you don't know the location, then you need to traverse the list to the location of deletion/insertion, which takes O(n) time.
** The deletion cost is O(log n) for the minimum or maximum, O(n) for an arbitrary element.
``````

Yes, you are corrrect if you consider two operations (indexing and inserting) in one go. It is not true in this case because when you are inserting a node in the middle of a linked list, the assumption taken is that you are already at the address where you have to insert the node.

The time complexity of accessing the node is O(n) whereas only inserting a node is O(1).

``````newnode->next = head;
``````

Insertion at the tail requires you to keep a pointer to the tail element, add the element at the tail and update the tail pointer.

``````tail->next = newnode;
tail = newnode;
``````

``````temp = head;
delete temp; /* or free(temp); */
``````

All the above are trivial operations and don’t depend upon the number of elements in linked list. Hence, they are O(1)

Deleting the tail element would, however, be a O(n) operation because even though you might have a tail pointer, you would still need the penultimate node that would be setup as the new tail node ( by updating the tail pointer and setting the node’s next member to NULL). For this, you need to traverse through the whole linked list.

``````penultimate_el = find_penultimate_el(head); /* this is O(n) operation */
delete tail; /* or free(tail) */
tail = penultimate_el;
tail->next = NULL;
``````

ArrayList provides resizable-array and stores "references" or "pointers" to actual storage. This array of references has to be recreated if the array is expanded beyond its allocated size. In other words, inserting a node at the beginning would require either all the existing elements to be moved up one, or to re-allocate the whole list if it's beyond it's allocated size. That's why insertion is `O(n)`.

A LinkedList consists of a chain of nodes; each node is separated allocated. And so while inserting, it's not necessary to traverse all the nodes. And that's why it has the complexity `O(1)`. However, if you're inserting at end and you have reference of only first node, then you may have to traverse the entire list and thus complexity in this case will be O(n).

EDIT

If you look at the source code of `java.util.LinkedList` you can find that `LinkedList` always keeps the track of last element

Following are some code snippets from actual `java.util.LinkedList` class.

``````package java.util;

...

extends AbstractSequentialList<E>
implements List<E>, Deque<E>, Cloneable, java.io.Serializable
{
transient int size = 0;

/**
* Pointer to first node.
*/
transient Node<E> first;

/**
* Pointer to last node.
*/
transient Node<E> last;

...
...

/**
* Appends the specified element to the end of this list.
*/
return true;
}

...
...

/**
* Links e as last element.
*/
final Node<E> l = last;
final Node<E> newNode = new Node<>(l, e, null);
last = newNode;
if (l == null)
first = newNode;
else
l.next = newNode;
size++;
modCount++;
}

...
...

}
``````

See particularly the `linkLast()` method. It doesn't traverse the entire list. It just inserts the element at the end of the list and that's why time complexity is `O(1)`.

• Do when i want to insert an element in linkedlist does it already know the address of the node after which it is going to be inserted ? does linkedlist stores the address of each element somewhere ? Please correct me if i am wrong but i think that it only knows the address of the head node and from head node it traverse to the Nth element ? and in that case the complexity to add at the Nth Position in LikedList will be "N" ?? Mar 17, 2017 at 5:38
• @AdityaAgarwal yes you're right. But the fact is the `LinkedList` which comes with `java.util` package keeps the track of last element. And so while inserting, it doesn't have to traverse the entire list. See the edited answer. Mar 17, 2017 at 6:05
• so that means inserting element at the head or tail will be of O(1) but adding the element at the middle at Nth position the complexity will be O(N) as Java.util package have the address of the head an the last(tail) node ? Mar 17, 2017 at 14:10
• @AdityaAgarwal Yes. You can say that. Mar 17, 2017 at 17:14
• Thanks for the response. Do you have any reference to support your last answer ? Appreciate your help. Mar 17, 2017 at 17:17

In array if we see the implementation from C language point of view then it will give us a clear understanding. While we can add and remove elements at constant time in array i.e we don't need to traverse through the entire array Eg: If the array is [1,2,3,4] the 5 can be added directly at Arr[arr.length] postion , similarly we can remove element at constant time ,position to be deleted is Arr[arr.length-1], but let us see a scenario when the array size you have declared is 4 and we want add one more elements then we can clearly see that there is no space for the elements to be added, therefore what we need to do is to make a new array of size lets say double of previous array i.e size 8 , then all the elements of previous array has to be copied here and the new elements is added at 5th position i.e Arr[arr.length] , therefore the insertion time complexity is O(n) as it is directly proportional to number of elements that previous array has.