# Heap insert, delete k elements

I have the following problem (I think it's well known/standard) that I am thinking at:

Verify that listing k smallest elements in a binary min-heap is O(k).

I was thinking at traversing the big min-heap in BFS, maintaining a min-heap instead of a simple queue. Initially, the auxiliary min-heap contains the root of my big min-heap. At each step I extract the minimum and I add all its children (maximum 2). The algorithm stops after k extract-mins on the auxiliary min-heap. The size of the auxiliary min-heap is O(k) (for-each min-key extracted I insert its children, maximum 2).

The problem is that extract-min has O(log k) complexity, thus this algorithm has O(k log k) complexity. And I have to find one in O(k).

Do you have any ideas/papers I can use?

Thanks!

-
You are right that 'delete k elements' might not be relevant. I'm not confusing the heap size with the number of smallest elements to extract. I need only to access these k elements, not to remove from the heap. L.E. did you remove your comment? –  Laurențiu Dascălu Oct 31 '10 at 20:29
yes, I deleted my comment since I realized I was confusing things :-) –  Andre Holzner Oct 31 '10 at 20:34

Googling for 'heap selection algorithm', I came across 'Frederickson's heap selection algorithm' which leads to this paper (27 pages...).

-
Well, the indicated algorithm has O(k) complexity for selecting kth element. If I want to select k elements then the cost will be sum of i, with i from 1 to k which is O(k*k). –  Laurențiu Dascălu Nov 1 '10 at 16:34
Once you have the kth smallest element (let's call it x), do a depth first walk of the heap. For each node whose value is <= x, visit both children. Now there are k nodes whose value is <= x (by construction of x) in the worst case, you'll visit both children of each of these nodes even if they're > x. So in the worst case, you'll visit (1 parent + 2 children) * k = 3 * k nodes in the heap (see e.g. 'The Algorithm Design Manual' by S. Skiena, section 4.3.4). I.e. once you know the kth smallest element, finding the smaller k-1 elements can be done in O(k) time. –  Andre Holzner Nov 1 '10 at 20:00

I think I found the solution. At each step, instead of executing extract-min I execute increase-key. I searched for a data structure that has O(1) worst-case time for increase-key, insert-key and get-min, and I found the Brodal queue.

For more information you may look at the Fibonacci heap, because the Brodal queue is based on concepts developed by the Fibonacci heap.

So, at each step I have the following sequence of operations:

1. min = get-min(Auxiliary Heap)

2. let (v1, v2) be the children of min

3. increase-min(Auxiliary Heap, root, v1)

4. insert(Auxiliary heap, v2)

Each of these 4 operations have O(1) worst-case complexity.

-