I have following task (as part of bigger task):

I need to take an k element from array like data structure and delete it (k is any possible index). Array have O(n) for deleting elements, and List have O(n) for searching element. I would like to do both operations in O(1) time.

Which data structure should I use to meet this requirement?


Deleting element on index(5) will move element from index(6) to index(5).

This particular task is topcoder srm 300 div2 500 points problem. It does not require such sophisticated data structure (simple java methods will do the job since max data is really small), but I am curious how to deal with much bigger problem using c-like thinking about data.

So maybe I am sticked to much to array for this problem? But I will analyze it and edit question later, after work (if you are really curious, you can see task on top coder).

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    Could you clarify whether after deleting element at index 5, does the element at index 6 change indexes so that it now has index 5? Aug 5 '13 at 7:48
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    @Mehrdad: I think it's supposed that the rest part is shifted after deletion, though it needs clarification from OP Aug 5 '13 at 7:49
  • 1
    @H2CO3 see my comment -- OP needs to clarify Aug 5 '13 at 7:50
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    @randomstring No need for further clarification. An array is an array, regardless of what Mehrdad thinks it is. Do we believe Wikipedia?
    – user529758
    Aug 5 '13 at 7:51
  • 3
    Sorted or unsorted array? If the array is unsorted, you can delete in O(1): Instead of moving elements to fill the gap, fill it with the element in the last position and decrement its size by one. Aug 5 '13 at 8:29

I believe what you're asking for is impossible.

However, if you can relax your requirement for indexing to O(log n), then ropes may be able to satisfy it, although I'm not sure if they have a probabilistic or deterministic guarantee (I think it's probabilistic).

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    i agree with impossibility because keys need to be shifted if array-like behavior is needed. O(log(n)) is the best to hope for. Aug 5 '13 at 7:56
  • @BenJackson: You'd need an indexable skip list (I don't know how they work)... normal ones don't support indexing.
    – user541686
    Aug 5 '13 at 7:59
  • O(log n) can be viewed as a constant anyway because memory is bounded so n is too.
    – usr
    Aug 5 '13 at 9:17
  • @usr: It really depends... I don't think that's a safe assumption here. For example, mergesort is O(n log n), which is quite slower than a typical O(n) algorithms... you can't usually ignore O(log n) factors that actually change the amount of work you do.
    – user541686
    Aug 5 '13 at 9:20
  • If all you care about is worst case bounds you can assume log n = 30 in the case of merge sort because it will never be more. If you also care about the actual value of the constant factor you are right.
    – usr
    Aug 5 '13 at 9:28

Given the nature of the "dating" problem as given, it involves continuously choosing and removing the "best" member of a set--a classic priority queue. In fact, you'll need to build two of those (for men and women). You'll either have to build them in O(NlogN) time (a sorted list) for constant O(1) removal, or else build them in linear time (a heap) for O(logN) removal. Overall you get O(NlogN) either way, since you'll be removing all of one queue and most of the other.

So then the question is what structure supports the other part of the task, choosing the "chooser" from the circle and removing him and his choice. Since this too must be done N times, any method that accomplishes the removal in O(logN) time won't increase the overall complexity of your algorithm. You can't get O(1) indexed access with fast deletions given the re-indexing requirement. But you can in fact get O(logN) for both indexed access and deletion with a tree (something like a rope as mentioned). This will give you O(NlogN) overall, which is the best you can do anyway.


There is a solution, that may be satisfying in some cases. You have to use an array and a vector for saving deletions. Every time you delete an element, you put its index in a vector. Every time you read an element of some index, you recalculate its index depending on previous deletions.

Say, you have an array of:

A = [3, 7, 6, 4, 3]

You delete 3-rd element:

A = [3, 7, 6, 4, 3] (no actual deletion)
d = [3]

And then read the 4-th:

i = 4
3 < 4 => i += 1
A[i] = 3

This is not exactly O(1), but yet it does not depend on array length. Only on a number of deleted elements.

  • In the challenge given, every element will be eventually removed, so this is no better than a linear search. Aug 6 '13 at 2:42

The only data-structure that has a small overhead in adding and removing element is an hashtable. The only overhead is the cost of the hash function (and it is considered as O(1), if you take a purely theoretic approach).

But, if you want it to be extremely efficient, you will need to:

  • Have an approximate of the number of elements you will have to get inside your data-structure (and allocate this number once for all at the beginning).
  • Choose an hash function that will avoid collision given the way your keys are distributed (collisions are just breaking the efficiency of hashtables).

If you manage to get everything right, then you should be optimal.

  • Operations are O(1), but you'll have to modify all elements with a larger index (which will take O(n)). Aug 5 '13 at 10:58
  • @Dukeling: Why ? You just insert it at the location noted by the hash. If you have a collision, then you use a linked list (buckets). You will never have to reorder anything... Collision is the only risk where you might loose performance as I said.
    – perror
    Aug 5 '13 at 12:01
  • The lookup is by index. When deleting an index, all indices following that index decreases by one, thus their hash values will also change. Aug 5 '13 at 12:06
  • It just means that you need an iterator on the structure, not that the index have to be contiguous. Or, am I missing something ?
    – perror
    Aug 5 '13 at 12:07
  • No, @perror is correct. A Hashtable is usually represented with a sparse array where each hash modulo the size of the table is the index. However, this also means that changing the "amount of buckets" is going to be very costly, so you'll want a fair estimate on how big a table you need to begin with.
    – kqr
    Aug 5 '13 at 12:16

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