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I see structural induction the usual way for proving an algorithm's termination property, but it's not that easy to prove by means of induction on a tree algorithm. Now I am struggling on proving that the pre-order tree traversal algorithm is terminable:

  if node == null then return

How should I prove?

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Hint: induction on the height. – Haile Sep 25 '12 at 15:00
Also, is this homework? – Haile Sep 25 '12 at 15:18
@Haile it's not a homework. actually, my question is based on a graph that may contain cycles. this is a simpler version. – xando Sep 25 '12 at 16:57
up vote 4 down vote accepted

By strong induction on the height of the tree.

Base case

The algorithm terminates on a tree of height 0, since in a tree of height 0 we have the root with no son. visit(node) on the root is a single step, visit on node.left and node.right terminate since they're both NULL.

Inductive Step

Suppose that pre-order traversal terminates on all trees of height 0, 1, 2, .. n, we prove that it terminates on all trees of height n+1. Let's look at it:


terminates since it's a single step.


terminates since if our tree has height n+1 then node.left is a tree of height at most n, and by strong inductive hypothesis pre-order traversal terminates on a tree of height less or equal than n.


the same as node.left.

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Tree doesn't contain cycle. If there were cycles the algorithm will run forever. Hence absence of cycle is a key point to the proof. Other point is left or right are bound by memory constraints to point to null eventually.

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If there are cycles, we have a graph and the algorithm may end by changing the if test to include a verification on whether the node was already visited. – rlinden Sep 25 '12 at 17:23
@rlinden but the set of all graphs is not countable. i am not sure whether the set of all graphs is well-found. if not, we even can not use induction to prove. – xando Sep 25 '12 at 22:13
I don't think that your consideration changes the algorithm, for it applies on a single graph that is represented in memory and, hence, is finite. – rlinden Sep 27 '12 at 13:21

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