# Homework

**Andrew J Bromage
**
ajb@spamcop.net

*Fri, 22 Aug 2003 16:25:30 +1000*

G'day all.
On Fri, Aug 22, 2003 at 03:41:14PM +1000, thomas_bevan@aardvark.net.au wrote:
>* Seeing as its thst time of year again and everyone is posting their
*>* homework, has anyone got any good puzzles to do?
*>* I wouldn't mind having a go at something a bit tricky.
*
OK, here's a tricky problem.
Take a list S. Delete some elements from the list. What you have
left is a subsequence of S. For example, [1,3,2] is a subsequence of
[2,1,2,1,3,2,1,3].
Consider the following list:
[1,2,3,1,2,3,1]
This list contains all permutations of the list [1,2,3] as
subsequences. It is also minimal, in the sense that there is no shorter
subsequence which will do (though there are potentially many minimal
subsequences). We will call such a list a shortest supersequence
over the alphabet [1..3].
The challenge is multi-part. You may answer as many or as few questions
as you want.
1. Write a function sss :: Int -> [Int] where sss n is a shortest
supersequence over the alphabet [1..n]. Make this as efficient
as possible. Prove an upper-bound complexity on your function.
2. Write a function sss_length :: Int -> Int where sss_length n is
the length of a shortest supersequence over the alphabet [1..n].
Make this as efficient as possible. Prove an upper-bound
complexity on your function.
If you can't solve this problem efficiently, write a function
sss_length_bounds :: Int -> (Int,Int) which returns the best
upper and lower bounds that you can.
(Hint: n is a trivial lower bound, n^2 is a trivial upper
bound. A tighter upper bound is n^2-n+1. Prove this as an
exercise.)
3. Write a function sss_count :: Int -> Int where sss_count n is
the number of shortest supersequences over the alphabet [1..n].
Make this as efficient as possible. Prove an upper-bound
complexity on your function.
(Hint: sss_count n must be a multiple of n factorial. Why?)
If you can't solve this problem efficiently, write a function
sss_count_bounds :: Int -> (Int,Int) which returns the best
upper and lower bounds that you can.
Incidentally, I don't have sub-exponential answers to any of these
questions. You did ask for something "a bit tricky".
Cheers,
Andrew Bromage