"the total distance moved by all pegs
should be kept at a minimum"
Unless I'm missing something, this is a non-problem.
Since the order of pegs must be maintained, you can just number the pegs 1, 2, 3, ...
and the final state has to be peg 1 in slot 1, peg 2 in slot 2, etc.
Not being able to jump pegs past each other doesn't matter, each peg has to move a certain distance from it's starting point to its final point. As long as all moves are in the right direction and a peg never has to back up, then the distance each individual peg has to move is a simple constant (it doesn't depend on the order of the moves), and the sum of those distances, your cost function is constant, too.
I don't see any need for dynamic programming or linear programming optimization problem here.
If you introduce a cost for picking up a peg and setting it down, then maybe there's an optimization problem here, but even that might be trivial.
Edit in response to 1800 Information's comment
That is only true if the number of
slots is equal to the number of pegs -
this was not assumed in the problem
statement – 1800 INFORMATION (2 hours
OK, I missed that. Thanks for pointing out what I was missing. I'm still not convinced that this is rocket science, though.
Suppose # pegs > # holes. Compute the final state as above as if you had the extra holes; then pick the N pegs that got moved the furthest and remove them from the problem: those are the ones that don't get moved. Recompute ignoring those pegs.
Suppose # holes > # pegs. The correct final state might or might not have gaps. Compute the final state as above and look for where adjacent pegs got moved towards each other. Those are the points where you can break it into subproblems that can be solved trivially. There's one additional variable when you have holes on both ends of a contiguous subproblem -- where the final contiguous sequence begins.
Yes, it is a little more complicated than I thought at first, but it still seems like a little pencil-and-paper work should show that the solution is a couple of easily understood and coded loops.