# Java Minimax Alpha-Beta Pruning Recursion Return

I am trying to implement minimax with alpha-beta pruning for a checkers game in Java. My minimax algorithm works perfectly. My code runs with the alpha-beta code in place. Unfortunately, when I play 1000 games vs the standard minimax algorithm, the alpha-beta algorithm always comes out behind by 50 games or so.

Since alpha-beta pruning should not be reducing the quality of the moves, just the time it takes to achieve them, something has to be wrong. However, I have taken out pen and paper and drawn hypothetical leaf node values and used my algorithm to predict whether it will calculate the correct best move, and there doesn't appear to be any logic errors. I used the tree from this video: Alpha-Beta Pruning to trace my algorithm. It logically should make all of the same choices, and therefore be a functioning implementation.

I have also put print statements into the code (they have been removed to reduce the clutter), and values are being returned correctly it appears and pruning does happen. Despite my best efforts I have been unable to find where the logic error lies. This is my third different attempt at implementing this and all of them have had the same issue.

I can't post the full code here, it's much too long, so I have included the methods that are relevant to the error. I'm not certain, but I suspect the problem may likely be in the non-recursive move() method, though I can't find a logical error in it so I'd just be thrashing around in it more, probably making things worse rather than better without having a rhyme or reason.

Is there a trick to recovering multiple integer values from recursive calls in a for loop? It works fine with both my minimax and negamax implementations, but alpha-beta pruning seems to produce some strange results.

``````@Override
public GameState move(GameState state)
{
int alpha = -INFINITY;
int beta = INFINITY;
int bestScore = -Integer.MAX_VALUE;
GameTreeNode gameTreeRoot = new GameTreeNode(state);
GameState bestMove = null;
for(GameTreeNode child: gameTreeRoot.getChildren())
{
if(bestMove == null)
{
bestMove = child.getState();
}
alpha = Math.max(alpha, miniMax(child, plyDepth - 1, alpha, beta));
if(alpha > bestScore)
{
bestMove = child.getState();
bestScore = alpha;
}
}
return bestMove;
}

private int miniMax(GameTreeNode currentNode, int depth, int alpha, int beta)
{
if(depth <= 0 || terminalNode(currentNode.getState()))
{
return getHeuristic(currentNode.getState());
}
if(currentNode.getState().getCurrentPlayer().equals(selfColor))
{
for(GameTreeNode child: currentNode.getChildren())
{
alpha = Math.max(alpha, miniMax(child, depth - 1, alpha, beta));

if(alpha >= beta)
{
return beta;
}
}
return alpha;
}
else
{
for(GameTreeNode child: currentNode.getChildren())
{
beta = Math.min(beta, miniMax(child, depth - 1, alpha, beta));

if(alpha >= beta)
{
return alpha;
}
}
return beta;
}
}
//Checks to see if the node is terminal
private boolean terminalNode(GameState state)
{
if(state.getStatus().equals(win) || state.getStatus().equals(lose) || state.getStatus().equals(draw))
{
return true;
}
else
{
return false;
}
}
``````
-
Checkers has a standard starting position and both minimax and minimax with alpha-beta pruning are deterministic algorithms, so every game should play out identically unless you've introduced randomness somewhere. Perhaps this randomness is producing the divergence in outcomes. –  Kyle Jones Mar 17 '13 at 22:43
Minimax and minimax with alpha-beta are by definintion supposed to produce identical results, only alpha-beta pruning gives you the result somewhat faster, with "somewhat" being determined by how good your move ordering hueristic is. So the way to test your alpha-beta implementation is to run minimax with and without it over a large set of positions and verify that identical results are produced for both versions. –  Kyle Jones Mar 17 '13 at 22:46
@Kyle I realized it's actually because my minimax algorithm returns a random move from among the equal best moves and my alpha-beta pruning algorithm just returns the first best move considered (because of the way alpha is passed my implementation can't find equal moves). At the start a move to the side of the board scores the same at ply 3, but is actually worse, but it's the first one considered by alpha-beta pruning and therefore is returned. So picking a random move from among the best moves is better than just picking the first one in this case. Thanks for the help. –  sage88 Mar 24 '13 at 5:07
@sage88: If you have found the solution to this question, you could answer it by yourself, if you like. –  Christian Ammer Aug 2 '13 at 20:03

I noticed you said you found the problem but shouldnt the minimax alpha beta pruning be

``````if it is MAX's turn to move
for child in children
result = alphaBetaMinimax(child, alpha, beta)
if result > alpha
alpha = result
if node is root
bestMove = operator of child
if alpha >= beta
return alpha
return alpha

if it is MIN's turn to move
for child in children
result = alphaBetaMinimax(child, alpha, beta)
if result < beta
beta = result
if node is root
bestMove = operator of child
if beta <= alpha
return beta
return beta
``````

you wrote:

``````  if alpha >= beta
return beta
return alpha
``````
-
No, you return beta there because it's the cutoff. If alpha exceeds it then you don't want to consider it because the other player would never let you make that move. See the wiki article on alpha beta pruning for more information on this en.wikipedia.org/wiki/Alpha%E2%80%93beta_pruning . And I know this is correct code as it's been run against 40 or so other minimax-esque algorithms and placed 2nd overall. –  sage88 Sep 5 '13 at 15:40

Is there a trick to recovering multiple integer values from recursive calls in a for loop?

Yes, in Java you would need to pass an object into the recursive function call, then modify the contents of that object. After the function returns you will be able to access the modified values.

Eg.

``````class ToBeReturned {
int returnValue1;
int returnValue2;
int returnValue3;
}
``````
-