bdinit.c revision 1.10
1 1.10 rillig /* $NetBSD: bdinit.c,v 1.10 2022/05/15 22:00:11 rillig Exp $ */ 2 1.3 cgd 3 1.1 tls /* 4 1.1 tls * Copyright (c) 1994 5 1.1 tls * The Regents of the University of California. All rights reserved. 6 1.1 tls * 7 1.1 tls * This code is derived from software contributed to Berkeley by 8 1.1 tls * Ralph Campbell. 9 1.1 tls * 10 1.1 tls * Redistribution and use in source and binary forms, with or without 11 1.1 tls * modification, are permitted provided that the following conditions 12 1.1 tls * are met: 13 1.1 tls * 1. Redistributions of source code must retain the above copyright 14 1.1 tls * notice, this list of conditions and the following disclaimer. 15 1.1 tls * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 tls * notice, this list of conditions and the following disclaimer in the 17 1.1 tls * documentation and/or other materials provided with the distribution. 18 1.5 agc * 3. Neither the name of the University nor the names of its contributors 19 1.1 tls * may be used to endorse or promote products derived from this software 20 1.1 tls * without specific prior written permission. 21 1.1 tls * 22 1.1 tls * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 23 1.1 tls * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 24 1.1 tls * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 25 1.1 tls * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 26 1.1 tls * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 27 1.1 tls * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 28 1.1 tls * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 29 1.1 tls * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 30 1.1 tls * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 31 1.1 tls * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 32 1.1 tls * SUCH DAMAGE. 33 1.1 tls */ 34 1.1 tls 35 1.4 lukem #include <sys/cdefs.h> 36 1.1 tls #ifndef lint 37 1.2 tls #if 0 38 1.2 tls static char sccsid[] = "from: @(#)bdinit.c 8.2 (Berkeley) 5/3/95"; 39 1.2 tls #else 40 1.10 rillig __RCSID("$NetBSD: bdinit.c,v 1.10 2022/05/15 22:00:11 rillig Exp $"); 41 1.2 tls #endif 42 1.1 tls #endif /* not lint */ 43 1.1 tls 44 1.1 tls #include <string.h> 45 1.1 tls #include "gomoku.h" 46 1.1 tls 47 1.8 dholland static void init_overlap(void); 48 1.8 dholland 49 1.4 lukem void 50 1.6 dholland bdinit(struct spotstr *bp) 51 1.1 tls { 52 1.4 lukem int i, j, r; 53 1.4 lukem struct spotstr *sp; 54 1.4 lukem struct combostr *cbp; 55 1.1 tls 56 1.1 tls movenum = 1; 57 1.1 tls 58 1.1 tls /* mark the borders as such */ 59 1.1 tls sp = bp; 60 1.1 tls for (i = BSZ2; --i >= 0; sp++) { 61 1.10 rillig sp->s_occ = BORDER; /* top border */ 62 1.7 dholland sp->s_flags = BFLAGALL; 63 1.1 tls } 64 1.1 tls 65 1.1 tls /* fill entire board with EMPTY spots */ 66 1.1 tls memset(frames, 0, sizeof(frames)); 67 1.1 tls cbp = frames; 68 1.1 tls for (j = 0; ++j < BSZ1; sp++) { /* for each row */ 69 1.1 tls for (i = 0; ++i < BSZ1; sp++) { /* for each column */ 70 1.1 tls sp->s_occ = EMPTY; 71 1.7 dholland sp->s_flags = 0; 72 1.1 tls sp->s_wval = 0; 73 1.1 tls if (j < 5) { 74 1.1 tls /* directions 1, 2, 3 are blocked */ 75 1.7 dholland sp->s_flags |= (BFLAG << 1) | (BFLAG << 2) | 76 1.10 rillig (BFLAG << 3); 77 1.1 tls sp->s_fval[BLACK][1].s = MAXCOMBO; 78 1.1 tls sp->s_fval[BLACK][2].s = MAXCOMBO; 79 1.1 tls sp->s_fval[BLACK][3].s = MAXCOMBO; 80 1.1 tls sp->s_fval[WHITE][1].s = MAXCOMBO; 81 1.1 tls sp->s_fval[WHITE][2].s = MAXCOMBO; 82 1.1 tls sp->s_fval[WHITE][3].s = MAXCOMBO; 83 1.1 tls } else if (j == 5) { 84 1.1 tls /* five spaces, blocked on one side */ 85 1.1 tls sp->s_fval[BLACK][1].s = 0x500; 86 1.1 tls sp->s_fval[BLACK][2].s = 0x500; 87 1.1 tls sp->s_fval[BLACK][3].s = 0x500; 88 1.1 tls sp->s_fval[WHITE][1].s = 0x500; 89 1.1 tls sp->s_fval[WHITE][2].s = 0x500; 90 1.1 tls sp->s_fval[WHITE][3].s = 0x500; 91 1.1 tls } else { 92 1.1 tls /* six spaces, not blocked */ 93 1.1 tls sp->s_fval[BLACK][1].s = 0x401; 94 1.1 tls sp->s_fval[BLACK][2].s = 0x401; 95 1.1 tls sp->s_fval[BLACK][3].s = 0x401; 96 1.1 tls sp->s_fval[WHITE][1].s = 0x401; 97 1.1 tls sp->s_fval[WHITE][2].s = 0x401; 98 1.1 tls sp->s_fval[WHITE][3].s = 0x401; 99 1.1 tls } 100 1.1 tls if (i > (BSZ - 4)) { 101 1.1 tls /* directions 0, 1 are blocked */ 102 1.7 dholland sp->s_flags |= BFLAG | (BFLAG << 1); 103 1.1 tls sp->s_fval[BLACK][0].s = MAXCOMBO; 104 1.1 tls sp->s_fval[BLACK][1].s = MAXCOMBO; 105 1.1 tls sp->s_fval[WHITE][0].s = MAXCOMBO; 106 1.1 tls sp->s_fval[WHITE][1].s = MAXCOMBO; 107 1.1 tls } else if (i == (BSZ - 4)) { 108 1.1 tls sp->s_fval[BLACK][0].s = 0x500; 109 1.1 tls sp->s_fval[WHITE][0].s = 0x500; 110 1.1 tls /* if direction 1 is not blocked */ 111 1.7 dholland if (!(sp->s_flags & (BFLAG << 1))) { 112 1.1 tls sp->s_fval[BLACK][1].s = 0x500; 113 1.1 tls sp->s_fval[WHITE][1].s = 0x500; 114 1.1 tls } 115 1.1 tls } else { 116 1.1 tls sp->s_fval[BLACK][0].s = 0x401; 117 1.1 tls sp->s_fval[WHITE][0].s = 0x401; 118 1.1 tls if (i < 5) { 119 1.1 tls /* direction 3 is blocked */ 120 1.7 dholland sp->s_flags |= (BFLAG << 3); 121 1.1 tls sp->s_fval[BLACK][3].s = MAXCOMBO; 122 1.1 tls sp->s_fval[WHITE][3].s = MAXCOMBO; 123 1.1 tls } else if (i == 5 && 124 1.7 dholland !(sp->s_flags & (BFLAG << 3))) { 125 1.1 tls sp->s_fval[BLACK][3].s = 0x500; 126 1.1 tls sp->s_fval[WHITE][3].s = 0x500; 127 1.1 tls } 128 1.1 tls } 129 1.1 tls /* 130 1.1 tls * Allocate a frame structure for non blocked frames. 131 1.1 tls */ 132 1.1 tls for (r = 4; --r >= 0; ) { 133 1.7 dholland if (sp->s_flags & (BFLAG << r)) 134 1.1 tls continue; 135 1.1 tls cbp->c_combo.s = sp->s_fval[BLACK][r].s; 136 1.1 tls cbp->c_vertex = sp - board; 137 1.1 tls cbp->c_nframes = 1; 138 1.1 tls cbp->c_dir = r; 139 1.1 tls sp->s_frame[r] = cbp; 140 1.1 tls cbp++; 141 1.1 tls } 142 1.1 tls } 143 1.1 tls sp->s_occ = BORDER; /* left & right border */ 144 1.7 dholland sp->s_flags = BFLAGALL; 145 1.1 tls } 146 1.1 tls 147 1.1 tls /* mark the borders as such */ 148 1.1 tls for (i = BSZ1; --i >= 0; sp++) { 149 1.1 tls sp->s_occ = BORDER; /* bottom border */ 150 1.7 dholland sp->s_flags = BFLAGALL; 151 1.1 tls } 152 1.1 tls 153 1.1 tls sortframes[BLACK] = (struct combostr *)0; 154 1.1 tls sortframes[WHITE] = (struct combostr *)0; 155 1.1 tls init_overlap(); 156 1.1 tls } 157 1.1 tls 158 1.1 tls /* 159 1.1 tls * Initialize the overlap array. 160 1.1 tls * Each entry in the array is a bit mask with eight bits corresponding 161 1.1 tls * to whether frame B overlaps frame A (as indexed by overlap[A * FAREA + B]). 162 1.1 tls * The eight bits coorespond to whether A and B are open ended (length 6) or 163 1.1 tls * closed (length 5). 164 1.1 tls * 0 A closed and B closed 165 1.1 tls * 1 A closed and B open 166 1.1 tls * 2 A open and B closed 167 1.1 tls * 3 A open and B open 168 1.1 tls * 4 A closed and B closed and overlaps in more than one spot 169 1.1 tls * 5 A closed and B open and overlaps in more than one spot 170 1.1 tls * 6 A open and B closed and overlaps in more than one spot 171 1.1 tls * 7 A open and B open and overlaps in more than one spot 172 1.1 tls * As pieces are played, it can make frames not overlap if there are no 173 1.1 tls * common open spaces shared between the two frames. 174 1.1 tls */ 175 1.8 dholland static void 176 1.6 dholland init_overlap(void) 177 1.1 tls { 178 1.4 lukem struct spotstr *sp1, *sp2; 179 1.4 lukem struct combostr *cbp; 180 1.9 dholland unsigned frameix; 181 1.4 lukem int i, f, r, n, d1, d2; 182 1.1 tls int mask, bmask, vertex, s; 183 1.1 tls u_char *str; 184 1.1 tls short *ip; 185 1.1 tls 186 1.1 tls memset(overlap, 0, sizeof(overlap)); 187 1.1 tls memset(intersect, 0, sizeof(intersect)); 188 1.1 tls str = &overlap[FAREA * FAREA]; 189 1.1 tls ip = &intersect[FAREA * FAREA]; 190 1.9 dholland for (frameix = FAREA; frameix-- > 0; ) { /* each frame */ 191 1.9 dholland cbp = &frames[frameix]; 192 1.1 tls str -= FAREA; 193 1.1 tls ip -= FAREA; 194 1.1 tls sp1 = &board[vertex = cbp->c_vertex]; 195 1.1 tls d1 = dd[r = cbp->c_dir]; 196 1.1 tls /* 197 1.1 tls * s = 5 if closed, 6 if open. 198 1.1 tls * At this point black & white are the same. 199 1.1 tls */ 200 1.1 tls s = 5 + sp1->s_fval[BLACK][r].c.b; 201 1.1 tls /* for each spot in frame A */ 202 1.1 tls for (i = 0; i < s; i++, sp1 += d1, vertex += d1) { 203 1.1 tls /* the sixth spot in frame A only overlaps if it is open */ 204 1.1 tls mask = (i == 5) ? 0xC : 0xF; 205 1.1 tls /* for each direction */ 206 1.1 tls for (r = 4; --r >= 0; ) { 207 1.1 tls bmask = BFLAG << r; 208 1.1 tls sp2 = sp1; 209 1.1 tls d2 = dd[r]; 210 1.1 tls /* for each frame that intersects at spot sp1 */ 211 1.1 tls for (f = 0; f < 6; f++, sp2 -= d2) { 212 1.1 tls if (sp2->s_occ == BORDER) 213 1.1 tls break; 214 1.7 dholland if (sp2->s_flags & bmask) 215 1.1 tls continue; 216 1.1 tls n = sp2->s_frame[r] - frames; 217 1.1 tls ip[n] = vertex; 218 1.1 tls str[n] |= (f == 5) ? mask & 0xA : mask; 219 1.1 tls if (r == cbp->c_dir) { 220 1.1 tls /* compute the multiple spot overlap values */ 221 1.1 tls switch (i) { 222 1.1 tls case 0: /* sp1 is the first spot in A */ 223 1.1 tls if (f == 4) 224 1.1 tls str[n] |= 0xA0; 225 1.1 tls else if (f != 5) 226 1.1 tls str[n] |= 0xF0; 227 1.1 tls break; 228 1.1 tls case 1: /* sp1 is the second spot in A */ 229 1.1 tls if (f == 5) 230 1.1 tls str[n] |= 0xA0; 231 1.1 tls else 232 1.1 tls str[n] |= 0xF0; 233 1.1 tls break; 234 1.1 tls case 4: /* sp1 is the penultimate spot in A */ 235 1.1 tls if (f == 0) 236 1.1 tls str[n] |= 0xC0; 237 1.1 tls else 238 1.1 tls str[n] |= 0xF0; 239 1.1 tls break; 240 1.1 tls case 5: /* sp1 is the last spot in A */ 241 1.1 tls if (f == 1) 242 1.1 tls str[n] |= 0xC0; 243 1.1 tls else if (f != 0) 244 1.1 tls str[n] |= 0xF0; 245 1.1 tls break; 246 1.1 tls default: 247 1.1 tls str[n] |= 0xF0; 248 1.1 tls } 249 1.1 tls } 250 1.1 tls } 251 1.1 tls } 252 1.1 tls } 253 1.1 tls } 254 1.1 tls } 255
Indexes created Mon Sep 29 21:09:56 GMT 2025