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
Add parent to tree (none)
Pop f # queue q = ()
f is visited, do nothing
```

You can also use a smart data structure that will ignore nodes added twice. Note that you can't use an ordered set because it is very important that you explore "lower" nodes before "higher" nodes.

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.