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What is the big O notation for this problem? Why? I think it's O(N) because we have one loop here but I'm not sure.

public static void mystery(List<String> list){

    for(int i = 0; i< list.size()-1; i+=2){

        String first = list.remove(i);

        list.add(i + 1, first);


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This looks like a homework. We're not here to solve your homework problems. At least show us that you've tried something. – Luiggi Mendoza Feb 9 '13 at 5:02
Completely impossible to tell, because you're using the List interface rather than a concrete. – Brian Roach Feb 9 '13 at 5:16
Untrue, at least with the built in list implementations. Even a linked list must traverse nodes to get to an index – Kyle Feb 9 '13 at 5:23
@Kyle, List is an interface. You don't know which one is being used. It's not just LinkedList or ArrayList (docs.oracle.com/javase/6/docs/api/java/util/List.html), and the program can implement its own... – thang Feb 9 '13 at 5:48
@thang Exactly why I said 'with built in list implementations'. – Kyle Feb 9 '13 at 5:54

The time complexity is O(n^2).

The loop will execute floor(n/2) times. List.add(int i) and list.remove(int i) are both O(n) on average(see the notes on why below). This results in O(n*n/2) which is O(n^2).

Some notes on built in List implementations

When calling List.add(int i, element) or List.remove(int i) on an ArrayList, elements in the list must be shifted to insert or remove an element(when not at the end of the list) On average the number of shifts necessary is n. Thus the add and remove operations are both O(n).

List.add(int i, element) and List.remove(int i) are also O(n) when called on a LinkedList. This is due to the need to traverse to the given index in order to remove/add an element.

We can do better when we know that adds/remove to a given List will be sequential. A ListIterator, using a LinkedList, can be used to reduce the time complexity to O(n). The add and remove methods are O(1) when invoked on a LinkedLists ListIterator as there's no need to traverse to the given index.

Sample implementation of the askers method using ListIterator

public static void mystery(List<String> list){
    ListIterator<String> iterator = list.listIterator();
    int i = 0;
    while (i < list.size()-1) {
        String first = iterator.next();
        // Remove first
        // Skip an element
        // insert at i+1
share|improve this answer
List.add(int i) and list.remove(int i) are both O(n) on average -- remark that we do not know the run time of remove on average for ArrayList, although it is unclearly stated to be linear by the documentation. However, add on average is constant time (docs.oracle.com/javase/6/docs/api/java/util/ArrayList.html - The add operation runs in amortized constant time). It is conceivable that one can implement an ArrayList in such a way that both add and remove for that specific case yields constant time. How the SDK implements it is not revealed in the documentation. – thang Feb 9 '13 at 6:04
@thang the amortized constant time comment in the docs refers to the add(element) method, not the add(int, element) method(not the end of the list) The underlying array has to be resized hence the amortized comment – Kyle Feb 9 '13 at 6:27
You may be right, but it's actually not stated to be the one add over the other. It is likely that it's just implementing an array without any optimizations, in which case you are right. As I said, it is unclear, and it is conceivable to have an ArrayList implementation where both add and remove in that specific scenario are constant time. It would be an interesting exercise to measure and confirm.... – thang Feb 9 '13 at 6:32
@thang I'm not sure I understand how an arraylist can implement add and remove for any given index in constant time. It's one of the core tradeoffs between an array backed list and a linked list. Give it a look and see what you find though. – Kyle Feb 9 '13 at 6:37
Suppose when you remove, instead of moving elements, it flags that spot as removed. When you add, it finds the closest unused spot and adjusts only up to there. If that optimization were made here, then both add and remove would be constant time in this particular case. There would be sparse adjusters to compensate for indices due to removed elements. It's a stretch of the imagination, but again, without measurement and actual statement in the documentation... well, make no assumptions. – thang Feb 9 '13 at 6:41

It looks like it's O(n^2). It iterates through a list, and for each iteration, it calls list.remove() which also runs in O(n). Therefore the time complexity for this function should be O(n^2).

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list.remove depends on which list implementation it is, for linked list it is O(1) – Oleg Mikheev Feb 9 '13 at 5:13
@Oleg Mikheev. That's only true using an Iterator or at the start and end of a linkedlist – Kyle Feb 9 '13 at 5:20
I wonder if the compiler is smart enough to notice that you are doing sequential item swapping... and optimize list access appropriately. – thang Feb 9 '13 at 5:46
@thang: I highly doubt it. It'd need to be psychic to know whether it could safely muck around like that with a class it's not compiling. – cHao Feb 9 '13 at 10:44

When running this method, it will excute:

remove 0
append 1
remove 1
append 2

Assume List is Array List:

assume all remove elements always at last So: n/2 * (2*n + n) = 3 * n^2 /2 => O(n^2)

assume all remove elements always at top. So: n/2 * (n + n) => O(n^2)

So. because the worst case and best case always O(n^2), so, not only Big-O, but the complexity will be o(n^2).

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Not when its a linked list. It will be O(1) – User 104 Feb 9 '13 at 5:20
@ShivamKalra not really. if all elements remove at last, you still need time trace to the end. – hqt Feb 9 '13 at 5:23
@ShivamKalra: Try removing from a linked list at an index, sans iterator, without counting your way to the entry (read: running in O(N)). – cHao Feb 9 '13 at 5:23
@cHao Right. Only when you've reference of that node then its O(1). – User 104 Feb 9 '13 at 5:27
I think it should be remove 0, append 1, remove 2, append 3, etc. not what is shown there... – thang Feb 9 '13 at 5:45

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