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C#, .NET4.

We have some performance critical code that is causing some problems. It is sort of a modified queue which is in fact being backed by a List. I was wondering how expensive removing an element at index 0 is. Questions that come to mind are:

  • Depending on how List is backed, do any memory allocations/deallocations happen after at RemoveAt() for compensating for the new size of the list? I know, for example, that resizing an array can be expensive (relatively speaking)
  • I always imagined Lists to behave like linked-lists, such that removing an element at the zero position would mean simply having the start-of-list reference adjusted from the previous zero element to what used to be the 1st element (but is now the first element). But, my 'imagination' and reality are not always in line.

I always assumed that RemovedAt was O(1) for Lists. Is that the case?

23

List<T> is backed by a simple array, plus a size field that indicates which portion of the array is actually in use. (to allow for future growth). The array isn't resized unless you add too many elements or call TrimExcess.

Remove is O(n), since it needs to shift the rest of the list down by one.


Instead, you can use a LinkedList<T> (unless you use random access), or write your own list which tracks an empty portion in front.

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    Yes, it is. Most .NET collections besides linked lists are array-based. – Quick Joe Smith May 18 '11 at 23:12
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    @user90070 - Queue<T> is based on a linked list internally, so apart from the fact that you'd be reinventing the wheel using LinkedList<T>, there should be little difference. – Will A May 18 '11 at 23:17
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    @user: LinkedLists has the added benefit of access to the nodes that make up the list. So it's easy to walk through the list in any direction from an inner node. Not as easy with most other collections. – Jeff Mercado May 18 '11 at 23:18
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    @will @user90070 Queue<T> is based on a circular array, not a linked list. Either will work, depending on unmentioned requirements, as the performance characteristics should both be O(1) for the specified operation. All else being equal I'd go for the queue. – Kevin Pullin May 19 '11 at 3:32
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    @VansFannel: Accessing an element at an arbitrary index. – SLaks Nov 27 '17 at 15:22
9

It's O(n). It even says so on MSDN.

This method is an O(n) operation, where n is (Count - index).

  • 1
    ...and .Net Reflector says ` Array.Copy(Me._items, (index + 1), Me._items, index, (Me._size - index))` - so I'll triple vouch for O(n). :) – Will A May 18 '11 at 23:08
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    Does this then imply that removing the last element in the list is O(1) ? – 3Pi Jun 25 '12 at 1:55
  • Not really @3Pi, because you are still doing an Array.Copy operation under the hood. – JwJosefy May 11 '16 at 17:45
  • Not to dwell on the subject but time complexity is a measure of the worst case. Removal is still O(n). Removing the last element just happens to be the best case. – Jeff Mercado May 11 '16 at 18:00
2

From what I can tell, it should be an O(n) operation. Internally it uses Array.Copy (which is an O(n) operation) to copy the elements after 0 back into the list's backing array. From Reflector:

public void RemoveAt(int index) {
    if (index >= this._size) {
        ThrowHelper.ThrowArgumentOutOfRangeException();
    }
    this._size--;
    if (index < this._size) {
        Array.Copy(this._items, index + 1, this._items, index, this._size - index);
    }
    this._items[this._size] = default(T);
    this._version++;
}

So for any valid array index i, it copies all subsequent elements from i + 1 into i.

  • Yup - it's O(n) - I think I'm right in saying that you can't say it's 'very close to' O(n), O(n) + k = O(n), O(n) * 0.9 = O(n) etc. – Will A May 18 '11 at 23:23
  • Yes, you are right since big-o is a worst-case scenario. – Quick Joe Smith May 19 '11 at 2:34

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