20

A lot of what I'm reading says that removing an internal element in a doubly linked list (DLL) is O(1); but why is this the case?

I understand why it's O(n) for SLLs; traverse the list O(n) and remove O(1) but don't you still need to traverse the list in a DLL to find the element?

1

4 Answers 4

25

For a doubly linked list, it's constant time to remove an element once you know where it is.

For a singly linked list, it's constant time to remove an element once you know where it and its predecessor are.

Since that link you point to shows a singly linked list removal as O(n) and a doubly linked one as O(1), it's certain that's once you already know where the element is that you want to remove, but not anything else.

In that case, for a doubly linked list, you can just use the prev and next pointers to remove it, giving you O(1). Ignoring the edge cases where you're at the head or tail, that means something like:

corpse->prev->next = corpse->next
corpse->next->prev = corpse->prev
free (corpse)

However, in a singly linked list where you only know the node you want deleted, you can't use corpse->prev to get the one preceding it because there is no prev link.

You have to instead find the previous item by traversing the list from the head, looking for one which has a next of the element you want to remove. That will take O(n), after which it's once again O(1) for the actual removal, such as (again, ignoring the edge cases for simplicity):

lefty = head
while lefty->next != corpse:
    lefty = lefty-> next
lefty->next = corpse->next
free (corpse)

That's why the two complexities are different in that article.


As an aside, there are optimisations in a singly-linked list which can make the deletion O(n) (the deletion being effectively O(1) once you've found the item you want to delete, and the previous item). In code terms, that goes something like:

# Delete a node, returns true if found, otherwise false.

def deleteItem(key):
    # Special cases (empty list and deleting head).

    if head == null: return false
    if head.data == key:
        curr = head
        head = head.next
        free curr
        return true

    # Search non-head part of list (so prev always exists).

    prev = head
    curr = head.next
    while curr != null:
        if curr.data == key:
            # Found it so delete (using prev).

            prev.next = curr.next
            free curr
            return true

        # Advance to next item.

        prev = curr
        curr = curr.next

    # Not found, so fail.

    return false
0
5

As it's stated where your link points to:

The cost for changing an internal element is based on already having a pointer to it, if you need to find the element first, the cost for retrieving the element is also taken.

So, for both DLL and SLL linear search is O(n), and removal via pointer is O(1).

2
  • Wouldn't SLLs be O(n) for removal/deletion since we need to find the predecessor of the item to be removed (and with SLL, we have no "prev", so we would spend n-time to come back to the predecessor)? Or did I misread what you said?
    – gonzofish
    May 9, 2013 at 14:02
  • @gonzofish I think I meant that search and removal are distinct operations themselves, despite the most common usage case is indeed to search for an element and then delete it.
    – vines
    May 12, 2013 at 16:53
4

The complexity of removal in DLL is O(1). It can also be O(1) in SLL if provided pointer to preceding element and not to the element itself.

This complexity is assuming you know where the element is.

I.e. the operation signature is akin to remove_element(list* l, link* e) Searching for the element is O(n) in both cases.

3
  • 1
    That's what I thought but that's not what the link seems to imply though.
    – Matuku
    May 28, 2011 at 12:25
  • 1
    It is exactly. If you are given a pointer to an element in SLL, you have to find the preceding element - an O(n) operation
    – EFraim
    May 28, 2011 at 12:27
  • 1
    @Nik-Lz: Removal operation is usually evaluated separately from search operation. It is often useful when you have some other source for the pointer - and you often do.
    – EFraim
    Aug 29, 2017 at 13:51
4

@Matuku: You are correct.

I humbly disagree with most answers here trying to justify how delete operation for DLL is O(1). It's not.

Let me explain.

Why are we considering the scenario that we 'would' have the pointer to the node that is being deleted? LinkedLists (Singly/Doubly) are traversed linearly, that's their definition. They have pointers only to the head/tail. How can we suddenly have a pointer to some node in between? That defeats the purpose of this data structure. And going by that assumption, if I have a DLL list of say 1 million nodes, then do I also have to maintain 1 million pointers (let's call them access pointers) pointing to each of those nodes so that I can delete them in O(1)? So how would I store those 1 millions access pointers? And how do I know which access pointer points to the correct data/node that I want to delete?

Can we have a real world example where we 'have' the pointer to the data that has to be deleted 100% of the time?

And if you know the exact location/pointer/reference of/to the node to be deleted, why to even use a LinkedList? Just use array! That's what arrays are for - direct access to what you want!

By assuming that you have direct access to any node you want in DLL is going against the whole idea of LinkedList as a conceptual Data Structure. So I agree with OP, he's correct. I will stick with this - Doubly LinkedLists cannot have O(1) for deleting any node. You still need to start either from head or tail, which brings it down to O(n).

" If " we have the pointer to the node to be deleted say X, then of course it's O(1) because we have pointers to the next and prev node we can delete X. But that big if is imaginary, not real.

We cannot play with the definition of the sacred Data Structure called LinkedLists for some weird assumptions we may have from time to time.

2
  • You have real-world examples where you have pointers to the element you want to delete. For instance service requests in device queues in WDK environment. (Windows kernel drivers) When someone requests cancellation on such queue they already know the operation they want to cancel. Hence no traversal is needed - and the distinction is important.
    – EFraim
    Aug 29, 2017 at 13:53
  • Just to elaborate - there are structures where even if you have the pointer to the element the deletion operation is expensive - think array, where you have to reshuffle the elements or, less drastically a balanced tree, where re-balancing might take logarithmic time. There are others, such as lists where the removal operation itself is cheap. And there are algorithms where you want this particular operation to be cheap, knowing that you keep the pointer around.
    – EFraim
    Aug 29, 2017 at 13:58

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.