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Given the following problem:

"Store the largest 5000 numbers from a stream of numbers"

The solution which springs to mind is a binary search tree maintaining a count of the number of nodes in the tree and a reference to the smallest node once the count reaches 5000. When the count reaches 5000, each new number to add can be compared to the smallest item in the tree. If greater, the new number can be added then the smallest removed and the new smallest calculated (which should be very simple already having the previous smallest).

My concern with this solution is that the binary tree is naturally going to get skewed (as I'm only deleting on one side).

Is there a way to solve this problem which won't create a terribly skewed tree?

In case anyone wants it, I've included pseudo-code for my solution so far below:

process(number)
{
  if (count == 5000 && number > smallest.Value)
  {
    addNode( root, number)
    smallest = deleteNodeAndGetNewSmallest ( root, smallest)
  }
}

deleteNodeAndGetNewSmallest( lastSmallest)
{
  if ( lastSmallest has parent)
  {
    if ( lastSmallest has right child)
    {
      smallest = getMin(lastSmallest.right)
      lastSmallest.parent.right = lastSmallest.right
    }
    else
    {
      smallest = lastSmallest.parent
    }
  }
  else 
  {
    smallest = getMin(lastSmallest.right)
    root = lastSmallest.right
  }
  count--
  return smallest
}

getMin( node)
{
  if (node has left)
    return getMin(node.left)
  else
    return node
}

add(number)
{
  //standard implementation of add for BST
  count++
}
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3 Answers 3

up vote 29 down vote accepted

The simplest solution for this is maintaining a min heap of max size 5000.

  • Every time a new number arrives - check if the heap is smaller then 5000, if it is - add it.
  • If it is not - check if the minimum is smaller then the new element, and if it is, pop it out and insert the new element instead.
  • When you are done - you have a heap containing 5000 largest elements.

This solution is O(nlogk) complexity, where n is the number of elements and k is the number of elements you need (5000 in your case).

It can be done also in O(n) using selection algorithm - store all the elements, and then find the 5001th largest element, and return everything bigger then it. But it is harder to implement and for reasonable size input - might not be better. Also, if stream contains duplicates, more processing is needed.

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+1 for selection algorithm. Just want to add: STL C++ has implementation for this. Not sure about Java, though. This method of offline computation, however, need O(n) space complexity. –  nhahtdh May 25 '12 at 9:42
    
Excellent point about selection algorithm. OTOH this demands O(n) memory. –  valdo Jul 14 '12 at 6:48
4  
You can use the selection algorithm to find the top k elements but use only O(k) memory by storing an array of 2k elements. Every time you fill the array, use the selection algorithm to drop off the lowest k. This works out to taking O(n) time regardless of the value of k, since you're doing O(n / k) selection algorithms, each of which takes time O(k). It also only uses O(k) memory. –  templatetypedef Sep 23 '12 at 21:28
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If you are using C++, use STL set.

If you are using Java, use TreeSet.

Their implementations are self-balanced tree, so you don't need to worry about skewed tree.

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front() method will get the smallest number from the set (note that it is called set, but it is a tree inside). The rest are the same as heap. –  nhahtdh May 25 '12 at 10:14
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Use a (minimum) priority queue. Add each incoming item to the queue and when the size reaches 5,000 remove the minimum (top) element every time you add an incoming element. The queue will contain the 5,000 largest elements and when the input stops, just remove the contents. This MinPQ is also called a heap but that is an overloaded term. Insertions and deletions take about log2(N). Where N maxes out at 5,000 this would be just over 12 [log2(4096) = 12] times the number of items you are processing.

An excellent source of info is Algorithms, (4th Edition) by Robert Sedgewick and Kevin Wayne. There is an excellent MOOC on coursera.org that is based on this text.

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