# Time complexity to get min elements from MAX heap

I was asked in an interview:

What is the best time complexity in getting the min element(s) from a max heap.

I replied as O(1) assuming the heap size is known and the heap is implemented as a binary heap using an array. This way as per my assumption, the min value is at `heapArray[heapSize].

My question is that if this answer is correct. If not what is the correct answer ?

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My question is that if this answer is correct.

No, that's not correct. The only guarantee you have, is that each node contains the maximum element of the subtree below it. In other words, the minimum element can be any leaf in the tree.

If not what is the correct answer?

The correct answer is O(n). In each step you need traverse both left and right sub-trees in order to search for the minimum element. In effect, this means that you need to traverse all elements to find the minimum.

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Btw, this diagram has the property that each left-child is greater than its right-sibling. That's also not a necessary property of a binary heap. – Steve Jessop Jul 25 '12 at 8:01
That's right. Such property still doesn't help in finding the minimum though. – aioobe Jul 25 '12 at 8:10
Couldn't we also just look at the last ceil(n/2) elements of the array. It is still O(n). – Guru Devanla Jul 25 '12 at 16:00
@GuruDevanla It sounds like the question does not specify an implementation. Making assumptions about the implementation would/should not be valid, I would think. – Sahuagin Aug 19 '14 at 0:59

Best complexity is `O(n)`. Sketch proof:

• The minimum element could be absolutely any of the lowest-level nodes (in fact it could even not be at the lowest level, but let's start with these).
• There could be up to `n/2` lowest-level nodes.
• All of them need to be examined, because the one you're looking for might be in the last place you look. Examining all-but-1 of them doesn't tell you whether the last one is the minimum or not.
• Hence `Omega(n)` examinations required.

The bound is tight, since clearly we can do it in `O(n)` by ignoring the fact that our array happens to be a heap.

Moral: it's probably called a heap because (as with the heap of clothes on your bedroom floor) it's easy to get at the top and difficult to get at the rest.

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+1. But I would simply say, "could be any of the leaf nodes". – aioobe Jul 25 '12 at 8:16
@aioobe: that would probably be better, since I'm pretty sure there are guaranteed to be at least `n/2` leaf nodes, which makes the `Omega`-bound more obvious. – Steve Jessop Jul 25 '12 at 9:09
"in fact it could even not be at the lowest level" -- What would be an example where the min element is not at the lowest level? – Mansoor Siddiqui Jul 25 '12 at 20:56
@Mansoor: The max-heap property is that every child is smaller than its parent. Nothing about siblings. So consider a heap with "10" at the root. It has two children "1" and "9". The "9" has two children "8" and "7". Then the smallest value is not at the lowest level (although necessarily it is a leaf node). – Steve Jessop Jul 26 '12 at 8:36
Ah, of course. Thanks for the clarification! :) – Mansoor Siddiqui Jul 26 '12 at 12:34

Min element from Max heap :

1. search at last level = O(n/2)= O(n)

2. replace searched element with last element and decrease heap size by 1 = O(1)

3. Apply Maxheapify on replaced element = O(log n)

Total Time = O(n)+O(1)+O(log n) = O(n)

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