/**
* alpha_beta.c
* Copyright (C) 2008 Markus Broeker
*/
#include <stdio.h>
#include <stdlib.h>
#include <limits.h>
#define BOARD_SIZE 9
#define EMPTY 32
struct Move {
int target;
int value;
};
typedef struct Move Move;
struct Node {
Move *data;
struct Node *prev;
};
typedef struct Node Node;
Move *bestMove;
Node *stack_end;
char board[BOARD_SIZE] = {
EMPTY, EMPTY, EMPTY,
EMPTY, EMPTY, EMPTY,
EMPTY, EMPTY, EMPTY,
};
int desired_depth = -1;
int estimateFunction ();
int max_alpha_beta (int, int, int);
int min_alpha_beta (int, int, int);
void print (void);
/**
* push: push a move onto the stack
*/
void push (Move * move)
{
Node *actual;
if ((actual = malloc (sizeof (Node))) == NULL) {
perror ("MALLOC");
exit (EXIT_FAILURE);
}
actual->data = move;
actual->prev = stack_end;
stack_end = actual;
}
/**
* undo: revert the last move on the stack
*/
void undo ()
{
Node *actual;
if (stack_end == NULL) {
printf ("Stack underrun\n");
return;
}
board[stack_end->data->target] = EMPTY;
actual = stack_end->prev;
free (stack_end);
stack_end = actual;
}
/**
* validMove returns true(1) when the inspected field is EMPTY
*/
int validMove (int t)
{
if (board[t] == EMPTY)
return 1;
return 0;
}
/**
* Returns a Score of +-50 for 3 in a Row
*/
int estimateFunction ()
{
if (board[0] == 'X' && board[1] == 'X' && board[2] == 'X')
return -50;
if (board[0] == 'O' && board[1] == 'O' && board[2] == 'O')
return 50;
if (board[3] == 'X' && board[4] == 'X' && board[5] == 'X')
return -50;
if (board[3] == 'O' && board[4] == 'O' && board[5] == 'O')
return 50;
if (board[6] == 'X' && board[7] == 'X' && board[8] == 'X')
return -50;
if (board[6] == 'O' && board[7] == 'O' && board[8] == 'O')
return 50;
if (board[0] == 'X' && board[3] == 'X' && board[6] == 'X')
return -50;
if (board[0] == 'O' && board[3] == 'O' && board[6] == 'O')
return 50;
if (board[1] == 'X' && board[4] == 'X' && board[7] == 'X')
return -50;
if (board[1] == 'O' && board[4] == 'O' && board[7] == 'O')
return 50;
if (board[2] == 'X' && board[5] == 'X' && board[8] == 'X')
return -50;
if (board[2] == 'O' && board[5] == 'O' && board[8] == 'O')
return 50;
if (board[0] == 'X' && board[4] == 'X' && board[8] == 'X')
return -50;
if (board[0] == 'O' && board[4] == 'O' && board[8] == 'O')
return 50;
if (board[2] == 'X' && board[4] == 'X' && board[6] == 'X')
return -50;
if (board[2] == 'O' && board[4] == 'O' && board[6] == 'O')
return 50;
return 0;
}
/**
* this function visualizes the board
*/
void print ()
{
int i;
printf (" 1 2 3 \n +---+---+---+\n");
for (i = 0; i < 3; i++) {
printf (" %d | ", i + 1);
printf ("%c", board[3 * i]);
printf (" | ");
printf ("%c", board[3 * i + 1]);
printf (" | ");
printf ("%c", board[3 * i + 2]);
printf (" | \n");
printf (" +---+---+---+\n");
}
if (stack_end->data != NULL)
printf ("Score: %3d\n", stack_end->data->value);
}
/**
* simulates and returns the next possible move for a Player or null, when no more moves are possible.
*/
Move *simulate (int t, int player)
{
Move *move;
while (t < BOARD_SIZE) {
if (!validMove (t)) {
t++;
continue;
}
if ((move = malloc (sizeof (Move))) == NULL) {
perror ("MALLOC");
exit (EXIT_FAILURE);
}
if (player == 0)
board[t] = 'O';
else
board[t] = 'X';
move->target = t;
move->value = estimateFunction ();
push (move);
return move;
}
return NULL;
}
/**
* AlphaBeta-Algorithm: the Maximizer
*/
int max_alpha_beta (int depth, int alpha, int beta)
{
int moveValue;
int t;
Move *move;
if (desired_depth == -1)
desired_depth = depth;
t = 0;
while ((move = simulate (t, 0)) != NULL) {
/*
* particular move from black
*/
t = move->target;
if (depth == 0 || (estimateFunction () * estimateFunction ()) == 2500)
moveValue = move->value;
else /* best next move */
moveValue = min_alpha_beta (depth - 1, alpha, beta);
print ();
undo ();
t++;
if (moveValue >= beta) {
free (move);
return beta;
}
if (moveValue > alpha) {
alpha = moveValue;
if (depth == desired_depth) {
if (bestMove != NULL)
free (bestMove);
bestMove = move;
continue;
}
}
free (move);
}
return alpha;
}
/**
* AlphaBeta-Algorithm: the Minimizer
*/
int min_alpha_beta (int depth, int alpha, int beta)
{
int moveValue;
int t;
Move *move;
t = 0;
while ((move = simulate (t, 1)) != NULL) {
/*
* particular move from white
*/
t = move->target;
if (depth == 0 || (estimateFunction () * estimateFunction ()) == 2500)
moveValue = move->value;
else /* best next move */
moveValue = max_alpha_beta (depth - 1, alpha, beta);
undo ();
free (move);
t++;
if (moveValue <= alpha)
return alpha;
if (moveValue < beta)
beta = moveValue;
}
return beta;
}
/**
* returns true when no more fields are empty
*/
int game_over ()
{
int i;
for (i = 0; i < BOARD_SIZE; i++) {
if (board[i] == EMPTY)
return 0;
}
return 1;
}
int main (int argc, char **argv)
{
Node *actual;
int i, t, value;
int depth;
if (argc == 2)
depth = atoi (argv[1]);
else
depth = 1;
if ((actual = malloc (sizeof (Node))) == NULL) {
perror ("MALLOC");
return EXIT_FAILURE;
}
actual->data = NULL;
actual->prev = NULL;
stack_end = actual;
printf ("\tTic Tac Toe\n");
for (i = 0; i < 5; i++) {
printf ("Enter a number: ");
while (scanf ("%d", &t) < 1) {
printf ("Enter a number: ");
t = getchar ();
}
if (!validMove (--t)) {
i--;
continue;
}
board[t] = 'X';
bestMove = NULL;
value = max_alpha_beta (depth, SHRT_MIN, SHRT_MAX);
if (bestMove == NULL) {
break;
}
board[bestMove->target] = 'O';
free (bestMove);
print ();
if ((estimateFunction () * estimateFunction ()) == 2500) {
free (actual);
return EXIT_SUCCESS;
}
if (game_over ())
break;
}
print ();
free (actual);
return EXIT_SUCCESS;
}