Let's assume that the answer you posted is correct, and that the given file system does indeed store things in a balanced tree. Balancing a tree is a very expensive operation. Keeping a tree "partially" balanced is pretty simple, in that when you allow for a tree to be imbalanced slightly, you only worry about moving things around the point of insertion/deletion. However, when talking about completely balanced trees, when you remove a given node, you may find that suddenly, the children of this node could belong on the complete opposite side of the tree, or a child node on the opposite side has become the root node, and all of it's children need to be rotated up the tree. This requires you to do either a long series of rotations, or to place all the items into an array and re-create the tree.
2 4 6 8
now remove the 7, easy right?
2 4 6
Now remove the 6, still easy, yes...?
Now remove the 8, uh oh
Getting this tree to be the proper balanced form like:
Is quite expensive, compared at least to the other removals we have done, and gets exponentially worse as the depth of our tree increases. We could make this go much(exponentially) faster by removing the 2 and the 4, before removing the 8. Particularly if our tree was more than 3 levels deep.
Without sorting removal is on average a O(K * log_I(N)^2). N representing the number of elements total, and K the number to be removed, I the number of children a given node is permitted, log_I(N) then being the depth, and for each level of depth we increase the number of operations quadratically.
Removal with some ordering help is on average O(K * log_I(N)), though sometimes ordering cannot help you and you are stuck removing something that will require a re-balance. Still, minimizing this is optimal.
Another possible tree ordering scheme:
1 2 3 4
Accomplishing optimal removal under this circumstance would be easier, because we can take advantage of our knowledge of how things are sorted. Under either situation it is possible, and in fact both are identical, under this one the logic is just a little simpler to understand, because the ordering is more human friendly for the given scenario. In either case in-order is defined as "remove the farthest leaf first", in this case it just so happens to be that the farthest leaves are also the smallest numbers, a fact that we could take advantage of to make it even a little more optimal, but this fact is not necessarily true for the file system example presented(though it may be).