But it involves creating a new set n
times. Is there a way to do it and
only create a new set once?
To the best of my knowledge, no. I'd say what you have a perfectly fine implementation, it runs in O(lg n) -- and its concise too :) Most heap implementations give you O(lg n) for delete min anyway, so what you have is about as good as you can get it.
You might be able to get a little better speed by rolling your balanced tree, and implementing a function to drop a left or right branch for all values greater than a certain value. I don't think an AVL tree or RB tree are appropriate in this context, since you can't really maintain their invariants, but a randomlized tree will give you the results you want.
A treap works awesome for this, because it uses randomization rather than tree invariants to keep itself relatively balanced. Unlike an AVL tree or a RB-tree, you can split a treap on a node without worrying about it being unbalanced. Here's a treap implementation I wrote a few months ago:
I've added a
split function, which will allows you take a tree and return two trees containing all values less than and all values greater than a given value.
split runs in O(lg n) using a single pass through the tree, so you can prune entire branches of your tree in one shot -- provided that you know which value to split on.
But if I want to remove the n maximum
elements... do I just execute the
above n times, or is there a faster
way to do that?
let nthLargest n t = Seq.nth n (Treap.toSeqBack t)
let removeTopN n t =
let largest = nthLargest n t
let smallerValues, wasFound, largerValues = t.Split(largest)
let e = Treap.empty(fun (x : int) (y : int) -> x.CompareTo(y))
let t = [1 .. 100] |> Seq.fold (fun (acc : Treap<_>) x -> acc.Insert(x)) e
let t' = removeTopN 10 t
removeTopN runs in O(n + lg m) time, where n is the index into the tree sequence and m is the number of items in the tree.
I make no guarantees about the accuracy of my code, use at your own peril ;)