rockbox/apps/plugins/reversi/reversi-game.c

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/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (c) 2006 Alexander Levin
*
* All files in this archive are subject to the GNU General Public License.
* See the file COPYING in the source tree root for full license agreement.
*
* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
/*
* Reversi. Code is heavily based on othello code by Claudio Clemens which is
* copyright (c) 2003-2006 Claudio Clemens <asturio at gmx dot net> and is
* released under the GNU General Public License as published by the Free
* Software Foundation; either version 2, or (at your option) any later version.
*/
#include <stddef.h>
#include "reversi-game.h"
/*
* Constants for directions. The values are chosen so that
* they can be bit combined.
*/
#define DIR_UP 1 /* UP */
#define DIR_DO 2 /* DOWN */
#define DIR_LE 4 /* LEFT */
#define DIR_RI 8 /* RIGHT */
#define DIR_UL 16 /* UP LEFT */
#define DIR_UR 32 /* UP RIGHT */
#define DIR_DL 64 /* DOWN LEFT */
#define DIR_DR 128 /* DOWN RIGHT */
/* Array of directions for easy iteration through all of them */
static int DIRECTIONS[] =
{DIR_UP, DIR_DO, DIR_LE, DIR_RI, DIR_UL, DIR_UR, DIR_DL, DIR_DR};
#define NUM_OF_DIRECTIONS 8
/* Initializes a reversi game */
void reversi_init_game(reversi_board_t *game) {
int r, c;
for (r = 0; r < BOARD_SIZE; r++) {
for (c = 0; c < BOARD_SIZE; c++) {
game->board[r][c] = FREE;
}
}
game->board[3][3] = WHITE;
game->board[4][4] = WHITE;
game->board[3][4] = BLACK;
game->board[4][3] = BLACK;
/* Invalidate the history */
c = sizeof(game->history) / sizeof(game->history[0]);
for (r = 0; r < c; r++) {
game->history[r] = MOVE_INVALID;
}
}
/* Returns the 'flipped' color, e.g. WHITE for BLACK and vice versa */
int reversi_flipped_color(const int color) {
switch (color) {
case WHITE:
return BLACK;
case BLACK:
return WHITE;
default:
return FREE;
}
}
/* Counts and returns the number of occupied cells on the board.
* If white_count and/or black_count is not null, the number of
* white/black stones is placed there. */
int reversi_count_occupied_cells(const reversi_board_t *game,
int *white_count, int *black_count) {
int w_cnt, b_cnt, r, c;
w_cnt = b_cnt = 0;
for (r = 0; r < BOARD_SIZE; r++) {
for (c = 0; c < BOARD_SIZE; c++) {
if (game->board[r][c] == WHITE) {
w_cnt++;
} else if (game->board[r][c] == BLACK) {
b_cnt++;
}
}
}
if (white_count != NULL) {
*white_count = w_cnt;
}
if (black_count != NULL) {
*black_count = b_cnt;
}
return w_cnt + b_cnt;
}
/* Returns the number of free cells on the board */
static int reversi_count_free_cells(const reversi_board_t *game) {
int cnt;
cnt = reversi_count_occupied_cells(game, NULL, NULL);
return BOARD_SIZE*BOARD_SIZE - cnt;
}
/* Checks whether the game is finished. That means that nobody
* can make a move. Note that the implementation is not correct
* as a game may be finished even if there are free cells
*/
bool reversi_game_is_finished(const reversi_board_t *game, int player) {
return (reversi_count_free_cells(game) == 0)
|| (reversi_count_passes(game,player) == 2);
}
/* Returns the total number of moves made so far */
int reversi_count_moves(const reversi_board_t *game) {
int cnt;
cnt = reversi_count_occupied_cells(game, NULL, NULL);
return cnt - INIT_STONES;
}
/* Returns the number of moves made by the specified
* player (WHITE or BLACK) so far
*/
static int reversi_count_player_moves(const reversi_board_t *game,
const int player) {
int moves, cnt, i;
moves = reversi_count_moves(game);
cnt = 0;
for (i = 0; i < moves; i++) {
if (MOVE_PLAYER(game->history[i]) == player) {
cnt++;
}
}
return cnt;
}
/* Returns the number of moves available for the specified player */
int reversi_count_player_available_moves(const reversi_board_t *game,
const int player) {
int cnt = 0, row, col;
for(row=0;row<BOARD_SIZE;row++) {
for(col=0;col<BOARD_SIZE;col++) {
if(reversi_is_valid_move(game, row, col, player)) cnt++;
}
}
return cnt;
}
/* Returns the number of players who HAVE to pass (2 == game is stuck) */
int reversi_count_passes(const reversi_board_t *game, const int player) {
if(reversi_count_player_available_moves(game,player)==0) {
if(reversi_count_player_available_moves(game,
reversi_flipped_color(player))==0) {
return 2;
}
return 1;
}
return 0;
}
/* Returns the number of moves made by WHITE so far */
int reversi_count_white_moves(const reversi_board_t *game) {
return reversi_count_player_moves(game, WHITE);
}
/* Returns the number of moves made by BLACK so far */
int reversi_count_black_moves(const reversi_board_t *game) {
return reversi_count_player_moves(game, BLACK);
}
/* Checks whether the specified position is on the board
* (and not beyond)
*/
static bool reversi_is_position_on_board(const int row, const int col) {
return (row >= 0) && (row < BOARD_SIZE) &&
(col >= 0) && (col < BOARD_SIZE);
}
/* Returns the delta for row to move in the specified direction */
static int reversi_row_delta(const int direction) {
switch (direction) {
case DIR_UP:
case DIR_UL:
case DIR_UR:
return -1;
case DIR_DO:
case DIR_DL:
case DIR_DR:
return 1;
default:
return 0;
}
}
/* Returns the delta for column to move in the specified direction */
static int reversi_column_delta(const int direction) {
switch (direction) {
case DIR_LE:
case DIR_UL:
case DIR_DL:
return -1;
case DIR_RI:
case DIR_UR:
case DIR_DR:
return 1;
default:
return 0;
}
}
/* Checks if some stones would be captured in the specified direction
* if a stone were placed in the specified cell by the specified player.
*
* Returns 0 if no stones would be captured or 'direction' otherwise
*/
static int reversi_is_valid_direction(const reversi_board_t *game,
const int row, const int col, const int player, const int direction) {
int row_delta, col_delta, r, c;
int other_color;
int flip_cnt; /* Number of stones that would be flipped */
row_delta = reversi_row_delta(direction);
col_delta = reversi_column_delta(direction);
other_color = reversi_flipped_color(player);
r = row + row_delta;
c = col + col_delta;
flip_cnt = 0;
while (reversi_is_position_on_board(r, c) &&
(game->board[r][c] == other_color)) {
r += row_delta;
c += col_delta;
flip_cnt++;
}
if ((flip_cnt > 0) && reversi_is_position_on_board(r, c) &&
(game->board[r][c] == player)) {
return direction;
} else {
return 0;
}
}
/* Checks whether the move at the specified position would be valid.
* Params:
* - game: current state of the game
* - row: 0-based row number of the move in question
* - col: 0-based column number of the move in question
* - player: who is about to make the move (WHITE/BLACK)
*
* Checks if the place is empty, the coordinates are legal,
* and some stones can be captured.
*
* Returns 0 if the move is not valid or, otherwise, the or'd
* directions in which stones would be captured.
*/
int reversi_is_valid_move(const reversi_board_t *game,
const int row, const int col, const int player) {
int dirs, i;
dirs = 0;
/* Check if coordinates are legal */
if (!reversi_is_position_on_board(row, col)) {
return dirs;
}
/* Check if the place is free */
if (game->board[row][col] != FREE) {
return dirs;
}
/* Check the directions of capture */
for (i = 0; i < NUM_OF_DIRECTIONS; i++) {
dirs |= reversi_is_valid_direction(game, row, col, player, DIRECTIONS[i]);
}
return dirs;
}
/* Flips the stones in the specified direction after the specified
* player has placed a stone in the specified cell. The move is
* assumed to be valid.
*
* Returns the number of flipped stones in that direction
*/
static int reversi_flip_stones(reversi_board_t *game,
const int row, const int col, const int player, const int direction) {
int row_delta, col_delta, r, c;
int other_color;
int flip_cnt; /* Number of stones flipped */
row_delta = reversi_row_delta(direction);
col_delta = reversi_column_delta(direction);
other_color = reversi_flipped_color(player);
r = row + row_delta;
c = col + col_delta;
flip_cnt = 0;
while (reversi_is_position_on_board(r, c) &&
(game->board[r][c] == other_color)) {
game->board[r][c] = player;
r += row_delta;
c += col_delta;
flip_cnt++;
}
return flip_cnt;
}
/* Tries to make a move (place a stone) at the specified position.
* If the move is valid the board is changed. Otherwise nothing happens.
*
* Params:
* - game: current state of the game
* - row: 0-based row number of the move to make
* - col: 0-based column number of the move to make
* - player: who makes the move (WHITE/BLACK)
*
* Returns the number of flipped (captured) stones (>0) iff the move
* was valid or 0 if the move was not valid. Note that in the case of
* a valid move, the stone itself is not counted.
*/
int reversi_make_move(reversi_board_t *game,
const int row, const int col, const int player) {
int dirs, cnt, i;
dirs = reversi_is_valid_move(game, row, col, player);
if (dirs == 0) {
return 0;
}
/* Place the stone into the cell */
game->board[row][col] = player;
/* Capture stones in all possible directions */
cnt = 0;
for (i = 0; i < NUM_OF_DIRECTIONS; i++) {
if (dirs & DIRECTIONS[i]) {
cnt += reversi_flip_stones(game, row, col, player, DIRECTIONS[i]);
}
}
/* Remember the move */
i = reversi_count_moves(game);
game->history[i-1] = MAKE_MOVE(row, col, player);
return cnt;
}