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Some binary-tree structures (such as heaps) can be implemented using an array by setting indices left-to-right, top-to-bottom

           0
      /        \
     1          2
   /   \      /   \
  3     4    5     6
 / \   / \  / \   / \
7   8 9 10 11 12 13 14
       ... etc.

The children and parent of a node at index x can be found easily in O(1):

child-left(x) = 2x+1
child-right(x) = 2x+2
parent(x) = (x-1)/2

But is there a way to find the lowest descendant of x in O(1) (ie. the descendant with highest index)? For instance, in the tree above, the lowest descendant of x=0 would be 14, while for x=1 it would be 10. Note that for x=1, if there were only 10 elements in the tree, it should return 9 instead.

I can assume there will never be more than 232 elements in my array, so 2n can be implemented in O(1) using bit-shifts. Possibly log_2 as well (???)

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As a silly cop-out answer, if you have at most 2^32 elements in the array, you could always just precompute everything and look up the answer in a lookup table in O(1). :-) –  templatetypedef Jul 16 '12 at 17:42
    
Is the binary tree necessarily a perfect binary tree (that is, no missing nodes), or might there be some nodes missing off the bottom level? –  templatetypedef Jul 16 '12 at 17:47
    
@templatetypedef: No, it is not necessarily perfect –  BlueRaja - Danny Pflughoeft Jul 16 '12 at 17:50
    
Why for N=10 the lowest descendant of 1 is 9?? Why not 7? What meaning exactly do you put in the term "lowest" in this case? –  AndreyT Jul 16 '12 at 18:18
    
@AndreyT he describes it as "Descendant with the highest index" in latest edit –  Kevin DiTraglia Jul 16 '12 at 18:20
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1 Answer

up vote 2 down vote accepted

Well, I figured it out. The depth of node x is

depth(x) = log2(x+1)

Similarly, the i-th left-child and i-th right-child of node x can easily be found:

ithLeftChild(x, i) = 2i(x+1) - 1
ithRightChild(x, i) = 2i(x+2) - 2

The index of the left-most child at depth d is ithLeftChild(x, d - depth(x)), and similarly for the right-child.

Let's call the index of the last element n. So, now we can find the depth of n, and we can also find the indicies of leftmostChild and rightmostChild at that depth (which could be larger than the last element, meaning they don't actually exist).

Now we just have three cases:

  • n < leftmostChild. Then our subtree has no elements at that depth, so the highest index must be parent(rightmostChild).
  • leftmostChild <= n <= rightmostChild. Then the highest index is necessarily n.
  • rightmostChild < n. Then rightmostChild must be our highest index.

2i can be implemented in O(1) for reasonable i using bit-shifts; log2(x) can be implemented in O(1) using a 256-byte lookup table. So the overall algorithm is O(1).

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1  
Was about to type this exact solution out and got distracted with work, +1 for figuring it out though. –  Kevin DiTraglia Jul 16 '12 at 19:07
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