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I posted this question over at CodeReview, but I came to realize that it's not so much a Haskell question as it is an algorithm question.

The Haskell code can be found on my github repo but I think the code isn't as important as the general concept.

Basically the program figures out the optimal first set of moves in a game of Kalaha (the Swedish variation). Only the first "turn" is considered, so we assume that you get to start and that anything from the point of the opponent getting to move is not computed.

Kalaha board

The board starts off with empty stores and a equal amount of marbles in each pot.

You start your turn by choosing a non-empty pot on your side, pick all of the marbles up from that pot and then move around the board by dropping one marble when passing a pot. If your last marble lands in the store, you get another turn. If you land in a non-empty, non-store pot, you pick up all of the contents of that pot and continue. Finally, if you land in an empty pot, the turn is passed to the opponent.

So far I've solved this by picking all possible paths and then sorting them according to the amount of marbles in the store by the end. A path would mean to start from one of your pots, do all the necessary pick-up-and-move-around and see if you either land in a store or in an empty pot. If you land in the store you get to continue, and now there are as many new branches as there are non-empty pots on your side.

The problem lies in the fact that if you start with five marbles in the pots, it's already quite a few paths. Jump up to six and ghci runs out of memory.

The reason I can't figure out how to make this less expensive is because I think that each path is necessary during computation. While I'll only need at most three paths (the best ones) out of the thousands (or millions) generated, the rest need to be run through to see if they're actually better than the previous ones.
If one is longer (generally better) then that's good but costly. If it's shorter than any previous path, then program still had to compute that path to find that out.

Is there any way around this, or is computing all the paths necessary by definition?

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For calculating the best single move without trying to look ahead through opponent's moves, it may be possible to employ dynamic programming here: every time you compute the best move from a particular game-state, store the move and the resulting state in a table. There could be many states (up to as many as the number of ways of splitting 30 into 6 bins), but I believe the number of marbles in stores can be disregarded. –  j_random_hacker Jul 12 '12 at 15:26
    
I don't have a proof, but I think that it should be possible to win the game in one turn. A rule that was not mentioned in the text is that you score all of the marbles in the opponent's pits if you run out of playable marbles, so the objective is to run out of marbles in one turn for a perfect game. If moves that end in empty pits are disregarded, the problem will be reduced to exponential complexity instead of NP-difficulty at least. –  dflemstr Jul 12 '12 at 15:47
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I would note that "computing all the paths" does not necessarily imply "running out of memory", if you can garbage collect paths you've already considered. –  Daniel Wagner Jul 12 '12 at 16:25
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Like @DanielWagner said, you should be able to generate the paths in such a way that you only have one path at a time which is considered and then discarded. You do not need all paths in RAM at once. –  Chris Kuklewicz Jul 12 '12 at 16:36
    
One of the classic papers on lazy functional programming is Why Functional Programming Matters, by John Hughes. The key example in that paper is using laziness to structure a program that plays Tic-Tac-Toe, using the alpha-beta heuristic to prune and prioritize the search tree. You are going to need a so-called "static evaluation function" for this, however, which assigns scores to positions to rank them as "better" or "worse" without looking ahead. –  Luis Casillas Jul 12 '12 at 17:29
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2 Answers

Just try them all out in order, recording your sequences of moves as sequences of numbers 1 through 6 (representing the pot that you pick the marbles from), each time replaying the whole sequence from the start. Keep and update just the three winners, plus the very last sequence of moves so you'd know what to try next. If there's no next legal moves, go back one notch.

It's going to be prohibitively slow perhaps, but will use very little memory. You don't store resulting positions, only numbers of pots picked from, and replay the sequence anew each time from the starting position, altering the very last move (instead of 2, next try 3, 4 etc.; if no more legal moves, backtrack one level). Or maybe store positions just for the very last sequence of moves tried, for easier backtracking.

It's a typical space for speed trade-of then.

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I realize now that my question probably should be broken down into space efficiency and computational efficiency. I guess this is a good solution for the space issue. –  linduxed Jul 13 '12 at 12:40
    
@linduxed but consider also this: with this approach, since you retain almost nothing, it is much more easier parallelizable. –  Will Ness Jul 13 '12 at 12:56
    
Possibly, but parallelization is something that is far from my level of knowledge, so I wouldn't be able to implement it. –  linduxed Jul 13 '12 at 13:04
    
@linduxed makes two of us. :) But in theory, it should be simple enough. :) –  Will Ness Jul 13 '12 at 13:10
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You could try parallellizing using this parallel version of map:

parMap :: (a -> b) -> [a] -> Eval [b]
parMap f xs = map f xs `using` parList rseq

Then you will spark off a new thread for each choise in your branch.

if you use as parMap pathFunction kalahaPots as your recursion, it will spark a lot of threads, but it might be faster, you could chunk it but i'm not that good of a parallell haskeller.

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