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We have an n-node binary heap which contains n distinct items (smallest item at the root). For a k<=n, find a O(klogk) time algorithm to select kth smallest element from the heap.

O(klogn) is obvious, but couldn't figure out a O(klogk) one. Maybe we can use a second heap, not sure.

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So if I ask you to find the smallest element (k = 1) it should do that in O(0), that is, instantly? :) –  BlackBear Oct 4 '11 at 16:20
@BlackBear: review the definition of Big-O ;-p –  Steve Jessop Oct 4 '11 at 16:24
Related: stackoverflow.com/questions/4922648/… –  Jim Mischel Oct 4 '11 at 16:59
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2 Answers

up vote 6 down vote accepted

Well, your intuition was right that we need extra data structure to achieve O(klogk) because if we simply perform operations on the original heap, the term logn will remain in the resulting complexity.

Guessing from the targeted complexity O(klogk), I feel like creating and maintaining a heap of size k to help me achieve the goal. As you may be aware, building a heap of size k in top-down fashion takes O(klogk), which really reminds me of our goal.

The following is my try (Not necessarily elegant or efficient) in an attempt to attain O(klogk):

  1. We create a new min heap, initializing its root to be the root of the original heap.

  2. We update the new min heap by deleting the current root and inserting the two children of the current root in the original heap. We repeat this process k times.

  3. The resulting heap will consist of k nodes, the root of which is the kth smallest element in the original heap.

Notes: Nodes in the new heap should store indexes of their corresponding nodes in the original heap, rather than the node values themselves. In each iteration of step 2, we really add a net of one more node into the new heap (one deleted, two inserted), k iterations of which will result in our new heap of size k. During the ith iteration, the node to be deleted is the ith smallest element in the original heap.

Time Complexity: in each iteration, it takes O(3logk) time to delete one element from and insert two into the new heap. After k iterations, it is O(3klogk) = O(klogk)

Hope this solution inspires you a bit.

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This is basically @Kevin 's solution –  amit Oct 5 '11 at 4:26
@amit Oh right, essentially the same idea. Thanks amit. –  Terry Li Oct 5 '11 at 13:22
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Assuming that we're using a minheap, so that a root node is always smaller than its children nodes.

Create a sorted list toVisit, which contains the nodes which we will traverse next. This is initially just the root node.
Create an array smallestNodes. Initially this is empty.
While length of smallestNodes < k:
    Remove the smallest Node from toVisit
    add that node to smallestNodes
    add that node's children to toVisit

When you're done, the kth smallest node is in smallestNodes[k-1].

Depending on the implementation of toVisit, you can get insertion in log(k) time and removal in constant time (since you're only removing the topmost node). That makes O(k*log(k)) total.

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Insertion isn't log(k), but rather log(n), where n is the number of nodes already in the heap. Inserting k nodes will be k*log(n). –  Jim Mischel Oct 4 '11 at 16:56
@JimMischel: no, in toVisit there are no more then 2k nodes at any point [since we add 2 elements for each element we remove, and we do it k times], so the insertion and deletion from toVisit is O(log2k) = O(logk). for each operation on the original list, we just extract the direct children of a specific node, which is O(1). we overall do k times O(logk) ops, which is indeed O(klogk). –  amit Oct 4 '11 at 17:23
though a sorted list is not a good data structure for toVisit, since insertion is O(k) in this list. You will need a heap to actually obtain O(klogk) [skip list/ balanced BST/B+ tree are also valid options, though harder to implement, heap will be enough here]. –  amit Oct 4 '11 at 19:00
@amit: Thank you. I misunderstood the description of the algorithm. –  Jim Mischel Oct 4 '11 at 19:51
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