I'm trying to find a linear-time algorithm using recursion to solve the diameter problem for a rooted k-ary tree implemented with adjacency lists. The diameter of a tree is the maximum distance between any couple of leaves. If I choose a root `r`

(that is, a node whose degree is > 1), it can be shown that the diameter is either the maximum distance between two leaves in the same subtree or the maximum distance between two leaves of a path that go through `r`

. My pseudocode for this problem:

```
Tree-Diameter(T,r)
if degree[r] = 1 then
height[r] = 0
return 0
for each v in Adj[r] do
for i = 1 to degree[r] - 1 do
d_i = Tree-Diameter(T,v)
height[r] = max_{v in Adj[r]} (height[v]
return max(d_i, max_{v in V} (height[v]) + secmax_{v in V} (height[v], 0) + 1)
```

To get linear time, I compute the diameter AND the height of each subtree at the same time. Then, I choose the maximum quantity between the diameters of each subtrees and the the two biggest heights of the tree + 1 (the `secmax`

function chooses between `height[v]`

and `0`

because some subtree can have only a child: in this case, the second biggest height is `0`

). I ask you if this algorithm works fine and if not, what are the problems? I tried to generalize an algorithm that solve the same problem for a binary tree but I don't know if it's a good generalization.

Any help is appreciated! Thanks in advance!