/* $NetBSD: gomoku.h,v 1.20 2014/03/22 18:58:57 dholland Exp $ */ /* * Copyright (c) 1994 * The Regents of the University of California. All rights reserved. * * This code is derived from software contributed to Berkeley by * Ralph Campbell. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * @(#)gomoku.h 8.2 (Berkeley) 5/3/95 */ #include #include #include /* board dimensions */ #define BSZ 19 #define BSZ1 (BSZ+1) #define BSZ2 (BSZ+2) #define BSZ3 (BSZ+3) #define BSZ4 (BSZ+4) #define BAREA (BSZ2*BSZ1+1) #define TRANSCRIPT_COL 46 /* necessarily == 2*BSZ4 */ /* interactive curses stuff */ #define BGOTO(y,x) move(BSZ - (y), 2 * (x) + 3) /* frame dimensions (based on 5 in a row) */ #define FSZ1 BSZ #define FSZ2 (BSZ-4) #define FAREA (FSZ1*FSZ2 + FSZ2*FSZ2 + FSZ1*FSZ2 + FSZ2*FSZ2) #define MUP (BSZ1) #define MDOWN (-BSZ1) #define MLEFT (-1) #define MRIGHT (1) /* values for s_occ */ #define BLACK 0 #define WHITE 1 #define EMPTY 2 #define BORDER 3 /* return values for makemove() */ #define MOVEOK 0 #define RESIGN 1 #define ILLEGAL 2 #define WIN 3 #define TIE 4 #define SAVE 5 #define A 1 #define B 2 #define C 3 #define D 4 #define E 5 #define F 6 #define G 7 #define H 8 #define J 9 #define K 10 #define L 11 #define M 12 #define N 13 #define O 14 #define P 15 #define Q 16 #define R 17 #define S 18 #define T 19 #define PT(x,y) ((x) + BSZ1 * (y)) /* * A 'frame' is a group of five or six contiguous board locations. * An open ended frame is one with spaces on both ends; otherwise, its closed. * A 'combo' is a group of intersecting frames and consists of two numbers: * 'A' is the number of moves to make the combo non-blockable. * 'B' is the minimum number of moves needed to win once it can't be blocked. * A 'force' is a combo that is one move away from being non-blockable * * Single frame combo values: * board values * 5,0 . . . . . O * 4,1 . . . . . . * 4,0 . . . . X O * 3,1 . . . . X . * 3,0 . . . X X O * 2,1 . . . X X . * 2,0 . . X X X O * 1,1 . . X X X . * 1,0 . X X X X O * 0,1 . X X X X . * 0,0 X X X X X O * * The rule for combining two combos ( ) * with V valid intersection points, is: * A' = A1 + A2 - 2 - V * B' = MIN(A1 + B1 - 1, A2 + B2 - 1) * Each time a frame is added to the combo, the number of moves to complete * the force is the number of moves needed to 'fill' the frame plus one at * the intersection point. The number of moves to win is the number of moves * to complete the best frame minus the last move to complete the force. * Note that it doesn't make sense to combine a <1,x> with anything since * it is already a force. Also, the frames have to be independent so a * single move doesn't affect more than one frame making up the combo. * * Rules for comparing which of two combos ( ) is better: * Both the same color: * = (A1 < A2 || A1 == A2 && B1 <= B2) ? : * We want to complete the force first, then the combo with the * fewest moves to win. * Different colors, is the combo for the player with the next move: * = A2 <= 1 && (A1 > 1 || A2 + B2 < A1 + B1) ? : * We want to block only if we have to (i.e., if they are one move away * from completing a force and we don't have a force that we can * complete which takes fewer or the same number of moves to win). */ #define MAXA 6 #define MAXB 2 #define MAXCOMBO 0x600 union comboval { struct { #if BYTE_ORDER == BIG_ENDIAN u_char a; /* # moves to complete force */ u_char b; /* # moves to win */ #endif #if BYTE_ORDER == LITTLE_ENDIAN u_char b; /* # moves to win */ u_char a; /* # moves to complete force */ #endif } c; u_short s; }; /* * This structure is used to record information about single frames (F) and * combinations of two more frames (C). * For combinations of two or more frames, there is an additional * array of pointers to the frames of the combination which is sorted * by the index into the frames[] array. This is used to prevent duplication * since frame A combined with B is the same as B with A. * struct combostr *c_sort[size c_nframes]; * The leaves of the tree (frames) are numbered 0 (bottom, leftmost) * to c_nframes - 1 (top, right). This is stored in c_frameindex and * c_dir if C_LOOP is set. */ struct combostr { struct combostr *c_next; /* list of combos at the same level */ struct combostr *c_prev; /* list of combos at the same level */ struct combostr *c_link[2]; /* C:previous level or F:NULL */ union comboval c_linkv[2]; /* C:combo value for link[0,1] */ union comboval c_combo; /* C:combo value for this level */ u_short c_vertex; /* C:intersection or F:frame head */ u_char c_nframes; /* number of frames in the combo */ u_char c_dir; /* C:loop frame or F:frame direction */ u_char c_flags; /* C:combo flags */ u_char c_frameindex; /* C:intersection frame index */ u_char c_framecnt[2]; /* number of frames left to attach */ u_char c_emask[2]; /* C:bit mask of completion spots for * link[0] and link[1] */ u_char c_voff[2]; /* C:vertex offset within frame */ }; /* flag values for c_flags */ #define C_OPEN_0 0x01 /* link[0] is an open ended frame */ #define C_OPEN_1 0x02 /* link[1] is an open ended frame */ #define C_LOOP 0x04 /* link[1] intersects previous frame */ #define C_MARK 0x08 /* indicates combo processed */ /* * This structure is used for recording the completion points of * multi frame combos. */ struct elist { struct elist *e_next; /* list of completion points */ struct combostr *e_combo; /* the whole combo */ u_char e_off; /* offset in frame of this empty spot */ u_char e_frameindex; /* intersection frame index */ u_char e_framecnt; /* number of frames left to attach */ u_char e_emask; /* real value of the frame's emask */ union comboval e_fval; /* frame combo value */ }; /* * One spot structure for each location on the board. * A frame consists of the combination for the current spot plus the five spots * 0: right, 1: right & down, 2: down, 3: down & left. */ struct spotstr { short s_occ; /* color of occupant */ short s_wval; /* weighted value */ int s_flags; /* flags for graph walks */ struct combostr *s_frame[4]; /* level 1 combo for frame[dir] */ union comboval s_fval[2][4]; /* combo value for [color][frame] */ union comboval s_combo[2]; /* minimum combo value for BLK & WHT */ u_char s_level[2]; /* number of frames in the min combo */ u_char s_nforce[2]; /* number of <1,x> combos */ struct elist *s_empty; /* level n combo completion spots */ struct elist *s_nempty; /* level n+1 combo completion spots */ int dummy[2]; /* XXX */ }; /* flag values for s_flags */ #define CFLAG 0x000001 /* frame is part of a combo */ #define CFLAGALL 0x00000F /* all frame directions marked */ #define IFLAG 0x000010 /* legal intersection point */ #define IFLAGALL 0x0000F0 /* any intersection points? */ #define FFLAG 0x000100 /* frame is part of a <1,x> combo */ #define FFLAGALL 0x000F00 /* all force frames */ #define MFLAG 0x001000 /* frame has already been seen */ #define MFLAGALL 0x00F000 /* all frames seen */ #define BFLAG 0x010000 /* frame intersects border or dead */ #define BFLAGALL 0x0F0000 /* all frames dead */ /* * This structure is used to store overlap information between frames. */ struct overlap_info { int o_intersect; /* intersection spot */ struct combostr *o_fcombo; /* the connecting combo */ u_char o_link; /* which link to update (0 or 1) */ u_char o_off; /* offset in frame of intersection */ u_char o_frameindex; /* intersection frame index */ }; extern const char *letters; extern const char pdir[]; extern const int dd[4]; extern struct spotstr board[BAREA]; /* info for board */ extern struct combostr frames[FAREA]; /* storage for single frames */ extern struct combostr *sortframes[2]; /* sorted, non-empty frames */ extern u_char overlap[FAREA * FAREA]; /* frame [a][b] overlap */ extern short intersect[FAREA * FAREA]; /* frame [a][b] intersection */ extern int movelog[BSZ * BSZ]; /* history of moves */ extern int movenum; extern int debug; extern int interactive; extern const char *plyr[]; #define ASSERT(x) void bdinit(struct spotstr *); int get_coord(void); int get_key(const char *allowedkeys); int get_line(char *, int); void ask(const char *); void dislog(const char *); void bdump(FILE *); void bdisp(void); void bdisp_init(void); void cursfini(void); void cursinit(void); void bdwho(int); void panic(const char *, ...) __printflike(1, 2) __dead; void debuglog(const char *, ...) __printflike(1, 2); void whatsup(int); const char *stoc(int); int ctos(const char *); int makemove(int, int); int list_eq(struct combostr **, struct combostr **, int); void clearcombo(struct combostr *, int); void markcombo(struct combostr *); int pickmove(int);