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I do not quiet understand why deleting at the end of a single linked list goes in O(1) time, as the wikipedia article says.

A single linked list contains out of nodes. A node contains some kind of data, and a reference to the next node. The reference of the last node in the linked list is null.

--------------    --------------           --------------
| data | ref | -> | data | ref | -> ... -> | data | ref |
--------------    --------------           --------------

I indeed can remove the the last node in O(1). But in that case you don't set the reference of the newly last node, the previous one, to null since it still contains the reference to the deleted last node. So I was wondering do they neglect that in the running time analysis? Or is it consired that you don't have to change that since the reference, well, just points to nothing, and such is seen as null?

Because if it would not be neglected I would argue that deleting is O(n). Since you have to iterate over the whole list to get to the newly last node and set its reference also to null. Only in a double linked list it would be really O(1).

-edit- Maybe this point of view gives some more clearence. But I see "deletion of a node" as succesfully deleting the node itself and setting the previous reference to null.

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I see two references to O(1) in that Wikipedia article, but neither of them state that removing the last node in a singly-linked list is an O(1) operation. Presumably, you already hold a pointer to the prior node when attempting the deletion, required for deleting any node except the first. –  Robert Harvey Dec 27 '12 at 1:11

5 Answers 5

up vote 5 down vote accepted

I am not sure I see in the Wikipedia article where it says that it's possible to remove the last entry of a singly-linked list in O(1) time, but that information is incorrect in most cases. Given any individual node in a linked list, it is always possible to remove the node after it in O(1) time by rewiring the list around that new node. Consequently, if you were given a pointer to the penultimate node in a linked list, then you could delete the last element of the list in O(1) time.

However, if you didn't have any extra pointers into the list other than a head pointer, then you could not delete the last element of the list without scanning to the end of the list, which would require Θ(n) time, as you have noted. You are absolutely correct that just deleting the last node without first changing the pointers into it would be a Very Bad Idea, since if you were to do this the existing list would contain a pointer to a deallocated object.

More generally - the cost to do an insertion or deletion in a singly-linked list is O(1), assuming you have a pointer to the node right before the one you want to insert or delete. However, you might have to do extra work (up to Θ(n)) to find that node.

Hope this helps!

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This should be the approved answer. A much better explanation. –  didibus Jun 26 '14 at 18:37

The addition/deletion of ANY node at ANY location is O(1). Code just play with fixed cost (few pointers calculations and malloc/frees) to add/delete the node. This arithmetical cost is fixed for any specific case.

However, the cost to reach(Indexing) the desired node is O(n).

The article is merely listing the addition/deletion in multiple sub-categories(adding in middle, beginning, end) to show that cost for adding in middle differs than adding in beginning/end (But the respective costs are still fixed).

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I'm still not very sure if I understand it correctly. You see deletion as just deleting the node O(1), and not setting the reference of a previous node to null, O(n), "cost to reach the desired node"? I namely see deletion as deleting the node itself and setting the reference of a previous node to null. –  WG- Dec 27 '12 at 1:34
    
I don't see why you approved this answer, it hardly explains much. If I null the node to delete and it's pointer to the next node, I'm left with a broken list. I've arguably split my list in two. How is that proper deletion? Unless it assumes delete to be Delete next node. I need an explanation that goes into the specifics. Indexing is O(n), but if delete requires indexing, it should be part of the use case. That is, if I call a method Delete on a Singly Linked List, I must expect O(n). –  didibus Jun 26 '14 at 18:34

For example, you can have a pointer to the element before last ("second from end") and when deleting: 1. Delete *next of this "second from end" element. 2. Set this "second from end" *next to NULL

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Except that then, if you are keeping a pointer to "second from the end" you now have to go update said pointer. –  James Dec 31 '12 at 9:11

O(1) simply means "constant cost". It does not mean 1 operation. It means "at most C" operations with C being fixed regardless of other parameters changing (such as list size). In fact, in the sometimes confusing world of big-Oh: O(1) == O(22).

By contrast deleting the whole list has O(n) cost, because the cost changes with the size (n) of the list.

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Deleting the whole list is O(1). Emptying the whole list is O(n). –  didibus Jun 26 '14 at 18:38

If you're including the cost of fixing the dangling node, you can still do it in O(1) with the use of sentinel node for the end (also described on that page).

Your "empty" list starts with a single sentinel

Head -> [Sentinel]

Add some stuff

Head -> 1 -> 2 -> 3 -> [Sentinel] 

Now delete the tail (3) by marking the node that was 3 as invalid, and then removing the link to the old sentinel, and freeing the memory for it:

Head -> 1 -> 2 -> 3 -> [Sentinel] 
Head -> 1 -> 2 -> [Sentinel] -> [Sentinel] 
Head -> 1 -> 2 -> [Sentinel]
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I like this. It would make time complexity O(1), while inducing a space trade, though it would keep space complexity O(n). Obviously, like you said, you'd have once in a while a need to do a O(n) operation for cleaning the list, or you could run in memory problems. –  didibus Jun 26 '14 at 18:41

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