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Given the following problem , I'm not completely sure with my current solution :

Question :

Given a maximum heap with n elements , which is stored in an array A , is it possible to print all the biggest K elements in O(K*log(K)) ?

My answer :

Yes , it is , since searching an element requires O(log(K)) , hence doing that

for K elements would take O(K * log(K)) running time.

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possible duplicate of O(klogk) time algorithm to find kth smallest element from a binary heap. Maybe not a dupe, since the linked question asks for the kth element and not the list of kth largest elements, but the idea is the same. –  amit Jun 26 '12 at 14:39
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5 Answers

up vote 6 down vote accepted

This is possible in a max-heap because you are only printing elements from the tree, not extracting them.

Start by identifying the maximum element, which is located at the root node. Form a pointer to a node and add it to an otherwise empty "maximums" list. Then, for each of the k values, perform the following steps in a loop.

  • Pop the maximal element from the list, taking O(1).
  • Print its value, taking O(1).
  • Insert each of the children of this maximal element to the list. Maintain sort when you insert them, taking O(log(size of list)) time. The maximum size of this list, since we are performing this loop k times, is branch-size*k. Therefore this step takes O(log(k)) time.

In total, then, the run time is O(klog(k)), as desired.

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Will the third step be possible in O(log(k)) time? If the data structure is a linked list, then binary search won't be possible (at least not possible in log(k) time)? If the data structure is an array, then insertion won't be O(1). Please correct me if I missed anything. –  Shubham Goyal Apr 3 '13 at 12:17
    
I feel it would be better to copy the elements to an array first and then sort the array. –  Shubham Goyal Apr 3 '13 at 12:35
    
@ShubhamGoyal The data structure can be a heap itself, which supports O(log k) insert and delete-max. Agreed thought that the individual claims in the answer w.r.t the complexity of operations are impossible to fulfill –  Niklas B. Jun 1 at 11:47
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Searching for an element in a heap of size N is not O(K). First, it does not make sense that the time complexity for finding one element depends on the number of elements you are trying to extract (which is what K represents). Also, there is no such thing as searching in a heap — unless you count the standard look-at-every-element search in O(N).

However, finding the largest element in a heap is O(1) by design (I am obviously assuming that it's a max-heap, so the maximum element is at the top of the heap), and removing the largest element from a heap of size N is O(log(N)) (replace it with a leaf element, and have that leaf percolate back down the heap).

So, extracting K elements from a heap, and returning the heap of non-extracted elements, would take O(K·log(N)) time.

What happens if you extract K elements destructively from the heap ? You can do this by keeping a heap-of-heaps (where the value of a heap is the value of its maximum element). Initially, this heap-of-heaps contains only one element (the original heap). To extract the next maximum element, you extract the top heap, extract its top element (which is the maximum) and then reinsert the two sub-heaps back into the heap-of-heaps.

This grows the heap-of-heaps by one on every removal (remove one, add two), which means it will never hold more than K elements, and so the remove-one-add-two will take O(log(K)). Iterate this, and you get an actual O(K·log(K)) algorithm that does returns the top K elements, but is unable to return the heap of non-extracted elements.

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Please note that I've updated the question - the heap in indeed a maximum heap , however it's given in an array . –  ron Jun 26 '12 at 15:08
    
The fact that it's an array does not change anything. –  Victor Nicollet Jun 26 '12 at 16:26
    
Great ,thanks :) –  ron Jun 26 '12 at 16:30
    
An array is a storage strategy for a heap, but a heap remains a tree regardless of how it is stored. When you remove the top element of a heap, you are left with two sub-heaps which were up until then the two children of that element. In the array case, those two sub-heaps happen to be stored in the same array as the original heap, but that's just an accident - the rules for exploring them remain the same. –  Victor Nicollet Jun 26 '12 at 21:54
    
Right! Of course, thanks for elaborating. –  falstro Jun 27 '12 at 10:22
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You're unfortunately incorrect. Given a max-heap of N elements, you would need O(K*log(N)) to extract the top K entries.

If it's a min-heap, you'll need to sort it completely, giving you O(N*log(N)).

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Indeed, it is too easy, extracting the max element is O(log(N)) where N is the size of the heap. and N≠K.

I will add that searching for a random element is O(N) and not O(Log(N)), but in this case we want to extract the max.

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Please note that I've updated the question . Thanks . –  ron Jun 26 '12 at 14:46
    
@ron My answer is still valid. –  Thomash Jun 26 '12 at 15:11
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It is a simple and elegant algorithm to get first k elements of a max heap in k log(k) time.

steps:-

1.construct another max heap name it auxiliary heap
2.add root element of main heap to auxiliary heap
3.pop out the element from auxiliary heap and add it's 2 children to the heap
4.do step 2 and 3 till k elements have been popped out from auxiliary heap. Add the popped element's children to the auxiliary heap.
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Awesome bey :D.. –  Spandan Nov 23 '13 at 9:24
    
it is the same algorithm that is described in @Victor Nicollet's answer –  J.F. Sebastian Mar 22 at 7:51
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