# Optimizing Scala code snippet

I'm still learning Scala, and I decided to implement an Othello game. I'm using Alpha Beta pruning basing myself on this algorithm to implement the AI component.

However I've realized that my implementation is not very efficient. I start noticing performance issues if I increase the maximum depth of the algorithm to something greater than 5. I realize that the search space is exponential, so I was hoping if you can help me point out ways of optimizing this code.

Here's how I implemented the algorithm:

``````trait MaxMin
case class Max() extends MaxMin
case class Min() extends MaxMin

object AlphaBeta {

type Move = List[State]
type FitnessMove = Tuple2[Int, List[Move]]

def not(p: Player) = p match {
case _: Player2 => Player1()
case _: Player1 => Player2()
}

def max(x: FitnessMove, y: FitnessMove) = if (x._1 >= y._1) x else y
def min(x: FitnessMove, y: FitnessMove) = if (x._1 <= y._1) x else y
def terminal(turn: Int) = if (turn >= 64) true else false

def search(board: Board, player: Player, turn: Int, MAX_DEPTH: Int = 5): Move = {
def alphaBeta(node: Board, depth: Int, alpha: Int, beta: Int,
moveChoice: List[Move], player: Player, p: MaxMin, turn: Int): FitnessMove =
if (depth == 0 || terminal(turn))
(player.evalHeuristic(node, turn), moveChoice)
else
p match {
case _: Max =>
player.getPossibleMoves(node).
takeWhile(_ => beta > alpha). // Pruning
foldLeft((alpha, moveChoice)) { case ((alpha, moveChoice), move) =>
val simulate = player.simulateMove(node, move)
max((alpha, moveChoice),
alphaBeta(simulate, depth-1, alpha, beta,
move :: moveChoice, not(player), Min(), turn+1))
}
case _: Min =>
player.getPossibleMoves(node).
takeWhile(_ => beta > alpha). // Pruning
foldLeft((beta, moveChoice)) { case ((beta, moveChoice), move) =>
val simulate = player.simulateMove(node, move)
(
min((beta, moveChoice),
alphaBeta(simulate, depth-1, alpha, beta,
moveChoice, not(player), Max(), turn+1))._1,
moveChoice
)
}
}
val (_, moveChoice) = alphaBeta(board, MAX_DEPTH, Integer.MIN_VALUE, Integer.MAX_VALUE, List.empty[Move], player, Max(), turn)
}

}
``````

I could probably get better performance if I use while loops and a more "imperative" approach but I prefer to maintain the code immutable. Are there any improvements I could make on the code, or would you approach the whole implementation of the algorithm differently?

Here's the game if you want to check it out. Thanks!

-
Just if you are interested: Some time ago I have written a small console based Othello implementation, without AI: gist.github.com/sschaef/2472666 –  sschaef Mar 17 at 1:04
can you make sure you attach a test so that I can freely refactor your code without breaking its functionalities? –  Edmondo1984 Mar 17 at 2:45
Hi @Edmondo1984 yeah I'll try to add a few tests soon. –  Samuel Heaney Mar 17 at 19:49

I haven't analyzed all of your code, but there was one point above that looked very "suspicious"

``````player.getPossibleMoves(node).
takeWhile
``````

So I thought: OK - if he really gets all the moves here in the list and filters afterwards, this could be very inefficient. This is your implementation which does the actual work with yield

``````  def findPossibleMoves(playerDisk: Int): List[Move] =
groupStatesByMove {
(for {
i <- upperLimit to lowerLimit
j <- leftLimit to rightLimit
if repr(i)(j) == 0
dir <- 1 to 8
disk = getPlayerDisk(i, j, dir)
if disk == playerDisk && findMove(i, j, dir)(playerDisk)
} yield new State(i, j, dir, playerDisk)).toList
}
``````

Now - if you just make the return type an `Iterable` (which should be sufficient for `takeWhile` and most other list-operations except direct access by index - see IterableLike) and if you leave out the `toList`at the end (also in the calling function of `Player`) the output is automatically set to the input type - which is list in this case, as `x to y` yields a list. The trick here is to use a Stream instead - instead of `1 to 8` use `(1 to 8).toStream` instead. The same goes for all other `to` expressions. Then each `State` should only be generated when needed - so: until `takeWhile` returns false.

Here is an example:

``````object TakeTest extends App {
def generate : Iterable[Int] = {
for (j <- (1 to 10).toStream; if (println("generate: " + j) == ()))
yield j
}
println("takeWhile with list:")
generate.toList.takeWhile(_ < 3)
println("takeWhile with Stream/Iterable:")
generate.takeWhile(_ < 3).toList
}
``````

That's the only hint I can give from the code, otherwise I would use - and you should probably make yourself familiar with it: jvisualvm

-
Thanks for the pointers, I was definitely overlooking the part where I generate the a whole collection every time I obtain possible moves. –  Samuel Heaney Mar 17 at 20:57