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I have an algorithm which operates on a rooted tree. It first recursively computes results for each of the root's child subtrees. It then does some work to combine them. The amount of work at the root is K^2 where K is the number of distinct values among the sizes of the subtrees.

What's the best bound on its runtime complexity? I haven't been able to construct a case in which it does more than linear work in the size of the tree.

  • By "each subtree", do you actually mean each subtree, or just the subtrees rooted at the children? – Sneftel Jun 23 at 14:22
  • Just the child subtrees of the root. I've updated the question, thanks! – snake Jun 23 at 14:23
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This is governed by the Master Theorem of divide and conqour algorithms. For this particular case (me reading between the lines in what you have described) it is mainly determined by how much work it takes on a single node to combine the work compiled for K values in the subtrees. Specifically if it is less than K work, then the cost is dominated by the cost at the lowest level and would be O(K) in total, if the work at a given level is O(K) then the total work becomes O(K log(K)). For work at a level higher than O(K), it is dominated by the work at the higest level. We therefor have that your algorithm as a runtime complexity of O(K^2).

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    It takes Ω(K^2) nodes to make children with K distinct sizes, though – Matt Timmermans Jun 23 at 15:06
  • You need to write it in terms of children instead of distinct children. In such a case the work would likely be closer to O(K^2 log(K)), though I havent run the specific numbers (just assuming they cancel out nicely), so it would be advisable to go through the master theorem with your actual analysis. – Ninetails Jun 23 at 15:28
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    The Master Theorem applies to divide-and-conquer algorithms where sub-problems have equal size, which is not true here. The sub-problem sizes are dictated by the structure of the tree. – snake Jun 23 at 15:58

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