This question is more a semantic-algorithmic-data-structure question than a F# syntactically question. I have a Minimax algorithm. The minimax algorithm should return the best next move, from a start position. To do this, it calculus all next moves, then the next-next-moves until a determined depth or until there is no more moves. It builds a tree like this:
P / \ a b / \ c d
I have the fallowing data struct to handle the tree:
type TreeOfPosition = | LeafP of Position * int | BranchP of Position * TreeOfPosition list
In the exemple tree above,
a are Branchs and
d are Leafs. The code below is my minimax algorithm:
let evaluateTree ( tree : TreeOfPosition, player : int) = let rec loop minOrmax node = match node with | LeafP(position, 0) -> LeafP(position, evaluateLeaf(position)) | BranchP(position, children) -> minimax.[minOrmax](List.map (loop (1 - minOrmax)) children) loop player tree
This code are returning me a Leaf, for example,
c. When I changed the recursion call to
| BranchP(position, children) -> LeafP(position, getStaticEvalFromNode(minimax.[minOrmax]( List.map (loop (1 - minOrmax)) children)))
And this modification makes the static value of a good leaf go up. I need to return the best second level node. Hope somebody can help! Pedro Dusso
Thanks for all answers guys, they help me a lot. Sorry about didn't specified the things very much. Let's go in parts:
1) I’m matching my LeafP like
LeafP(position, 0) because when I create my tree I set the leafs with a default value of 0 as its static value. As I’m going up my static values, eliminating the leaf and making the (before Branches) leafs with (min or max) static values I thought that this way I would prevent to evaluate a ex-Branch leaf (because it would not have the 0 value).
2) My biggest problem was to get the second level (the next move which has to be played) best position back. I solved it this way:
let evaluateTreeHOF ( tree, player : int) = let rec loop minOrmax node = match node with | LeafP(position, 0) -> LeafP(position, evaluateLeaf(position)) | BranchP(position, children) -> LeafP(position,(children |> List.map (loop (1 - minOrmax)) |> minimax.[minOrmax] |> getStaticEvalFromNode)) match tree with | BranchP(position, children) -> children |> List.map (loop (1 - player)) |> minimax.[player]
Instead of passing the entire tree, I’m passing just the children’s of the start node, and filtering the resulted list (a list of ex-Branches with the static values which went up for be the best for its current level) again. This way I’m getting the node I wanted.
I thought the kvb answers very interesting, but a little complicated to me. The other ones I understudied, but they just give me back the static value – and I could not make them to work for me :(
Thanks a lot for all the answers, all of them inspired me a lot.
Here is my full code: (http://www.inf.ufrgs.br/~pmdusso/works/Functional_Implementation_Minimax_FSharp.htm)