# Select the subtrees containing exactly K leaves

I'm given a tree `T` which has `n` nodes and `l` leaves.

I have to select some subtrees which contains exactly `k (<=l)` leaves. If I select node `t`'s ancestors' subtree, we cannot select `t`'s subtree.

For example:

This is the tree `T` which has 13 nodes (7 leaves).

If I want to select `k = 4` leaves, I can select node 4 and 6 (or, node 2 and 5). This is the minimum number of the selection. (we can select node 6, 7, 8, 9 either, but this is not the minimum).

If I want to select `k = 5` leaves, I can select node 3, and this is the minimum number of the selection.

I want to select the minimum numbers of subtrees. I can find only `O(nk^2)` and `O(nk)` algorithm, which uses BFS and dynamic programming. Is there any better solution with selecting this?

Thanks :)

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Could you give a simple example? I haven't been able to understand how you could have a minimum count of subtrees. From what I've got, you always have a fixed number of trees that have k leaves. –  Rubens Nov 18 '12 at 19:00
@Rubens Done. Thanks for giving advice :) –  Love Paper Nov 19 '12 at 7:24
You're welcome! And now your question grew tight enough for interesting solutions ^^ Happens, though, I can't see any better than O(nk). Nice question, anyway! –  Rubens Nov 19 '12 at 10:02

Actually, to know the number of leaves of each subtree you just need to go through each node once so complexity should be `O(nm)` where `m` is the mean number of children of each node, which in most cases evaluates to `O(n)` because `m` is just a constant. To do this, you should:

• Find which nodes of your tree are leaves
• Go up the tree, saving for each node the number of leaves in its subtree

You can do this by starting with leaves and putting parents inside a queue. When you pop a node `n_i` out of the queue, sum the number of leaves contained in each subtree starting from each of `n_i`'s children. Once you're done, mark `n_i` as visited (so you don't visit it multiple times, since it can be added once per children)

This gives something like this:

``````^
|               f (3)              This node last
|              / \
|            /     \
|          /         \
|        /             \
|       d (2)           e (1)      These nodes second
|      /  \            /
|     /    \          /
|    a (1)  b (1)    c (1)         These nodes first
``````

The steps would be:

``````Find leaves `a`, `b` and `c`.
For each leave, add parent to queue   # queue q = (d, d, e)

Pop d                                 # queue q = (d, e)
Count leaves in subtree: d.leaves = a.leaves + b.leaves
Mark d as visited
Add parent to queue                   # queue q = (d, e, f)

Pop d                                 # queue q = (e, f)
d is visited, do nothing

Pop e                                 # queue q = (f)
Count leaves in subtree: e.leaves = c.leaves
Mark d as visited
Add parent to tree                    # queue q = (f, f)

Pop f                                 # queue q = (f)
Count leaves in subtree: f.leaves = d.leaves + e.leaves
Mark d as visited
In your case, you can eliminate nodes in your queue if they have more than `k` leaves, and return each node that you find that haves `k` leaves, which will give an even faster algorithm.