# Monte Carlo Tree Search: Implementation for Tic-Tac-Toe

Edit: Uploded the full source code if you want to see if you can get the AI to perform better: https://www.dropbox.com/s/ous72hidygbnqv6/MCTS_TTT.rar

Edit: The search space is searched and moves resulting in losses are found. But moves resulting in losses are not visited very often due to the UCT algorithm.

To learn about MCTS (Monte Carlo Tree Search) I've used the algorithm to make an AI for the classic game of tic-tac-toe. I have implemented the algorithm using the following design:

The tree policy is based on UCT and the default policy is to perform random moves until the game ends. What I have observed with my implementation is that the computer sometimes makes errorneous moves because it fails to "see" that a particular move will result in a loss directly.

For instance: Notice how the action 6 (red square) is valued slightly higher than the blue square and therefore the computer marks this spot. I think this is because the game policy is based on random moves and therefore a good chance exist that the human will not put a "2" in the blue box. And if the player does not put a 2 in the blue box, the computer is gaurenteed a win.

My Questions

1) Is this a known issue with MCTS or is it a result of a failed implementation?

2) What could be possible solutions? I'm thinking about confining the moves in the selection phase but I'm not sure :-)

The code for the core MCTS:

``````    //THE EXECUTING FUNCTION
public unsafe byte GetBestMove(Game game, int player, TreeView tv)
{

//Setup root and initial variables
Node root = new Node(null, 0, Opponent(player));
int startPlayer = player;

helper.CopyBytes(root.state, game.board);

//four phases: descent, roll-out, update and growth done iteratively X times
//-----------------------------------------------------------------------------------------------------
for (int iteration = 0; iteration < 1000; iteration++)
{
Node current = Selection(root, game);
int value = Rollout(current, game, startPlayer);
Update(current, value);
}

//Restore game state and return move with highest value
helper.CopyBytes(game.board, root.state);

//Draw tree
DrawTree(tv, root);

//return root.children.Aggregate((i1, i2) => i1.visits > i2.visits ? i1 : i2).action;
return BestChildUCB(root, 0).action;
}

//#1. Select a node if 1: we have more valid feasible moves or 2: it is terminal
public Node Selection(Node current, Game game)
{
while (!game.IsTerminal(current.state))
{
List<byte> validMoves = game.GetValidMoves(current.state);

if (validMoves.Count > current.children.Count)
return Expand(current, game);
else
current = BestChildUCB(current, 1.44);
}

return current;
}

//#1. Helper
public Node BestChildUCB(Node current, double C)
{
Node bestChild = null;
double best = double.NegativeInfinity;

foreach (Node child in current.children)
{
double UCB1 = ((double)child.value / (double)child.visits) + C * Math.Sqrt((2.0 * Math.Log((double)current.visits)) / (double)child.visits);

if (UCB1 > best)
{
bestChild = child;
best = UCB1;
}
}

return bestChild;
}

//#2. Expand a node by creating a new move and returning the node
public Node Expand(Node current, Game game)
{
//Copy current state to the game
helper.CopyBytes(game.board, current.state);

List<byte> validMoves = game.GetValidMoves(current.state);

for (int i = 0; i < validMoves.Count; i++)
{
//We already have evaluated this move
if (current.children.Exists(a => a.action == validMoves[i]))
continue;

int playerActing = Opponent(current.PlayerTookAction);

Node node = new Node(current, validMoves[i], playerActing);

//Do the move in the game and save it to the child node
game.Mark(playerActing, validMoves[i]);
helper.CopyBytes(node.state, game.board);

helper.CopyBytes(game.board, current.state);

return node;
}

throw new Exception("Error");
}

//#3. Roll-out. Simulate a game with a given policy and return the value
public int Rollout(Node current, Game game, int startPlayer)
{
Random r = new Random(1337);
helper.CopyBytes(game.board, current.state);
int player = Opponent(current.PlayerTookAction);

//Do the policy until a winner is found for the first (change?) node added
while (game.GetWinner() == 0)
{
//Random
List<byte> moves = game.GetValidMoves();
byte move = moves[r.Next(0, moves.Count)];
game.Mark(player, move);
player = Opponent(player);
}

if (game.GetWinner() == startPlayer)
return 1;

return 0;
}

//#4. Update
public unsafe void Update(Node current, int value)
{
do
{
current.visits++;
current.value += value;
current = current.parent;
}
while (current != null);
}
``````
-
I do not understand the rationale for adding C * Math.Sqrt((2.0 * Math.Log((double)current.visits)) / (double)child.visits) to your UCB line. What is this term for? What happens if you just remove this part? – phil_20686 May 22 '14 at 10:09
This is coded according to: cameronius.com/cv/mcts-survey-master.pdf (page 9) - BestChild. If I remove it the AI still performs "stupid" moves. – MortenGR May 22 '14 at 10:23
The paper mentions that the algorithm is appropriate "for depth-limited minimax search". In minimax, you apply the same score heuristics for both your moves and opponents. I've never heard of an AI which presumes it's playing against an opponent playing random moves. – Groo May 22 '14 at 11:35
Groo: If I understand it correctly, Monte Carlo Tree Search does not use heutistics (it can be used in games such as go where domain knowledge is hard to specify). In the roll-out phase, a specific policy is used to simulate the game, and this is often (again, if I understand the algorithm correctly), random moves – MortenGR May 22 '14 at 11:41

Ok, I solved the problem by adding the code:

``````        //If this move is terminal and the opponent wins, this means we have
//previously made a move where the opponent can always find a move to win.. not good
if (game.GetWinner() == Opponent(startPlayer))
{
current.parent.value = int.MinValue;
return 0;
}
``````

I think the problem was that the search space was too small. This ensures that even if selection does select a move that is actually terminal, this move is never chosen and resource are used to explore other moves instead :).

Now the AI vs AI always plays tie and the Ai is impossible to beat as human :-)

-

I think your answer shouldn't be marked as accepted. For Tic-Tac-Toe the search space is relatively small and optimal action should be found within a reasonable number of iterations.

It looks like your update function (backpropagation) adds the same amount of reward to nodes at different tree levels. This is not correct, since states current players are different at different tree levels.

I suggest you take a look at backpropagation in the UCT method from this example: http://mcts.ai/code/python.html

You should update node's total reward based on the reward calculated by previous player at specific level (node.playerJustMoved in the example).

-

My very first guess is, that the way your algorithm works, chooses the step which leads most likely to win the match (has most wins in endnodes).

Your example which shows the AI 'failing', is therefore not a 'bug', if I am correct. This way of valueing moves proceeds from enemy random moves. This logic fails, because it's obvious for the player which 1-step is to take to win the match.

Therefore you should erase all nodes which contain a next node with win for the player.

Maybe I am wrong, was just a first guess...

-
Thanks for the reply. So if I understand it correctly, your solution is to erase all moves that could result in a loss (for the player) on the next turn. I've thought about this also, but I would like something with a little more finesse :-) – MortenGR May 22 '14 at 10:13
I am usually not the guy speaking too theoretically, but I will think about it :) It's a very interesting question! – Martin Tausch May 22 '14 at 10:16

So it is possible in any random based heuristic that you simply do not search a representative sample of the game space. E.g. its theoretically possible that you randomly sample exactly the same sequence 100 times, ignoring completely the neighbouring branch which loses. This sets it apart from more typical search algorithms which attempt to find every move.

However, much more likely this is a failed implementation. The game tree of tick tack to is not very large, being about 9! at move one, and shrinking rapidly, so its improbable that the tree search doesn't search every move for a reasonable number of iterations, and hence should find an optimal move.

Without your code, I cannot really provide further comment.

If i was going to guess, i would say that perhaps you are choosing moves based on the largest number of victories, rather than the largest fraction of victories, and hence generally biasing selection towards the moves that were searched most times.

-
Thanks for the reply. I have added the code to the post if you would like to see it. The search space (and thereby moves that could result in loss) are identified in the tree, but they are not visited often because of the UCT algorithm for selection. Using the previous example see this expanded tree: dropbox.com/s/muwew62f7edaszw/ttt2.png. Performing action 3 CAN lead to the human choosing action 2 resulting in 0 value. But it can also lead to action 5,6 or 8 resulting in a lot more value. Notice how action 2 is only visited 10 times. – MortenGR May 22 '14 at 10:18