First you have to say concretely what you mean by correctness (i.e., the specification against which you want to check your code; see also http://stackoverflow.com/a/16630693/476803 ). Lets assume that correctness here means
Every output of
permute is a permutation of the given string.
Then we have a choice on which natural number to perform induction. For the recursive function
permute, we have the choice between either of
high, or some combination thereof.
When reading the implementation it becomes apparent that there is some prefix of the output string whose elements do not change. Furthermore, the length of this prefix increases during the recursion and thus the remaining suffix, whose length is
high - low, decreases. So lets do induction on
high - low (under the assumption that
low <= high, which is sensible since initially we use
0 for low and the length of some string for
high, and the recursion stops as soon as
low == high). That is, we show
Fact: Every output of
permute(str, low, high) is a permutation of the last
high - low chars of
Base Case: Assume
high - low = 0. Then the statement is vacuously true since it has to hold for the last
0 characters (i.e., for none).
Step Case: Assume that
high - low = n + 1. Furthermore, as induction hypothesis (IH) we may assume that the statement is true for
high - low = n + 1 we have that
high - (low + 1) = n (since
high must be strictly larger than
high - low = n + 1 to hold). Thus, by IH, every output of
permute(str, low+1, high) is a permutation of the last
high - (low + 1) characters of
Now comes the point where we actually have to prove something. Namely that by swapping, in an output generated by
permute(str, low+1, high), the
low-th character of
str with any character after
low (up to
high), we generate a permutation of characters between
high. This step (which I omit here, since I just wanted to demonstrate how you could in principle use induction) concludes the proof.
Finally, by instantiating the above Fact with
high we have that every output of the non-recursive
permute is a permutation of
Note: The above proof only shows that every output is a permutation. However, it might also be interesting to know that in fact all permutations are printed.