Do not prevent node expansion later when more memory becomes available.
[pachi/derm.git] / patternsp.c
blob9f78a22a7f4538e5a640c560ec0376fbd8bafc56
1 #define DEBUG
2 #include <assert.h>
3 #include <ctype.h>
4 #include <inttypes.h>
5 #include <stdio.h>
6 #include <stdlib.h>
8 #include "board.h"
9 #include "debug.h"
10 #include "pattern.h"
11 #include "patternsp.h"
12 #include "tactics.h"
15 /* Mapping from point sequence to coordinate offsets (to determine
16 * coordinates relative to pattern center). The array is ordered
17 * in the gridcular metric order so that we can go through it
18 * and incrementally match spatial features in nested circles.
19 * Within one circle, coordinates are ordered by rows to keep
20 * good cache behavior. */
21 struct ptcoord ptcoords[MAX_PATTERN_AREA];
23 /* For each radius, starting index in ptcoords[]. */
24 int ptind[MAX_PATTERN_DIST + 2];
26 /* ptcoords[], ptind[] setup */
27 static void __attribute__((constructor))
28 ptcoords_init(void)
30 int i = 0; /* Indexing ptcoords[] */
32 /* First, center point. */
33 ptind[0] = ptind[1] = 0;
34 ptcoords[i].x = ptcoords[i].y = 0; i++;
36 for (int d = 2; d <= MAX_PATTERN_DIST; d++) {
37 ptind[d] = i;
38 /* For each y, examine all integer solutions
39 * of d = |x| + |y| + max(|x|, |y|). */
40 /* TODO: (Stern, 2006) uses a hand-modified
41 * circles that are finer for small d. */
42 for (short y = d / 2; y >= 0; y--) {
43 short x;
44 if (y > d / 3) {
45 /* max(|x|, |y|) = |y|, non-zero x */
46 x = d - y * 2;
47 if (x + y * 2 != d) continue;
48 } else {
49 /* max(|x|, |y|) = |x| */
50 /* Or, max(|x|, |y|) = |y| and x is zero */
51 x = (d - y) / 2;
52 if (x * 2 + y != d) continue;
55 assert((x > y ? x : y) + x + y == d);
57 ptcoords[i].x = x; ptcoords[i].y = y; i++;
58 if (x != 0) { ptcoords[i].x = -x; ptcoords[i].y = y; i++; }
59 if (y != 0) { ptcoords[i].x = x; ptcoords[i].y = -y; i++; }
60 if (x != 0 && y != 0) { ptcoords[i].x = -x; ptcoords[i].y = -y; i++; }
63 ptind[MAX_PATTERN_DIST + 1] = i;
65 #if 0
66 for (int d = 0; d <= MAX_PATTERN_DIST; d++) {
67 fprintf(stderr, "d=%d (%d) ", d, ptind[d]);
68 for (int j = ptind[d]; j < ptind[d + 1]; j++) {
69 fprintf(stderr, "%d,%d ", ptcoords[j].x, ptcoords[j].y);
71 fprintf(stderr, "\n");
73 #endif
77 /* Zobrist hashes used for points in patterns. */
78 hash_t pthashes[PTH__ROTATIONS][MAX_PATTERN_AREA][S_MAX];
80 static void __attribute__((constructor))
81 pthashes_init(void)
83 /* We need fixed hashes for all pattern-relative in
84 * all pattern users! This is a simple way to generate
85 * hopefully good ones. Park-Miller powa. :) */
87 /* We create a virtual board (centered at the sequence start),
88 * plant the hashes there, then pick them up into the sequence
89 * with correct coordinates. It would be possible to generate
90 * the sequence point hashes directly, but the rotations would
91 * make for enormous headaches. */
92 hash_t pthboard[MAX_PATTERN_AREA][4];
93 int pthbc = MAX_PATTERN_AREA / 2; // tengen coord
95 /* The magic numbers are tuned for minimal collisions. */
96 hash_t h = 0x313131;
97 for (int i = 0; i < MAX_PATTERN_AREA; i++) {
98 pthboard[i][S_NONE] = (h = h * 16803 - 7);
99 pthboard[i][S_BLACK] = (h = h * 16805 + 7);
100 pthboard[i][S_WHITE] = (h = h * 16807 + 3);
101 pthboard[i][S_OFFBOARD] = (h = h * 16809 - 3);
104 /* Virtual board with hashes created, now fill
105 * pthashes[] with hashes for points in actual
106 * sequences, also considering various rotations. */
107 #define PTH_VMIRROR 1
108 #define PTH_HMIRROR 2
109 #define PTH_90ROT 4
110 for (int r = 0; r < PTH__ROTATIONS; r++) {
111 for (int i = 0; i < MAX_PATTERN_AREA; i++) {
112 /* Rotate appropriately. */
113 int rx = ptcoords[i].x;
114 int ry = ptcoords[i].y;
115 if (r & PTH_VMIRROR) ry = -ry;
116 if (r & PTH_HMIRROR) rx = -rx;
117 if (r & PTH_90ROT) {
118 int rs = rx; rx = -ry; ry = rs;
120 int bi = pthbc + ry * MAX_PATTERN_DIST + rx;
122 /* Copy info. */
123 pthashes[r][i][S_NONE] = pthboard[bi][S_NONE];
124 pthashes[r][i][S_BLACK] = pthboard[bi][S_BLACK];
125 pthashes[r][i][S_WHITE] = pthboard[bi][S_WHITE];
126 pthashes[r][i][S_OFFBOARD] = pthboard[bi][S_OFFBOARD];
131 inline hash_t
132 spatial_hash(int rotation, struct spatial *s)
134 hash_t h = 0;
135 for (int i = 0; i < ptind[s->dist + 1]; i++) {
136 h ^= pthashes[rotation][i][spatial_point_at(*s, i)];
138 return h & spatial_hash_mask;
141 char *
142 spatial2str(struct spatial *s)
144 static char buf[1024];
145 for (int i = 0; i < ptind[s->dist + 1]; i++) {
146 buf[i] = stone2char(spatial_point_at(*s, i));
148 buf[ptind[s->dist + 1]] = 0;
149 return buf;
152 void
153 spatial_from_board(struct pattern_config *pc, struct spatial *s,
154 struct board *b, struct move *m)
156 assert(pc->spat_min > 0);
158 /* We record all spatial patterns black-to-play; simply
159 * reverse all colors if we are white-to-play. */
160 static enum stone bt_black[4] = { S_NONE, S_BLACK, S_WHITE, S_OFFBOARD };
161 static enum stone bt_white[4] = { S_NONE, S_WHITE, S_BLACK, S_OFFBOARD };
162 enum stone (*bt)[4] = m->color == S_WHITE ? &bt_white : &bt_black;
164 memset(s, 0, sizeof(*s));
165 for (int j = 0; j < ptind[pc->spat_max + 1]; j++) {
166 ptcoords_at(x, y, m->coord, b, j);
167 s->points[j / 4] |= (*bt)[board_atxy(b, x, y)] << ((j % 4) * 2);
169 s->dist = pc->spat_max;
173 /* Spatial dict manipulation. */
175 static int
176 spatial_dict_addc(struct spatial_dict *dict, struct spatial *s)
178 /* Allocate space in 1024 blocks. */
179 #define SPATIALS_ALLOC 1024
180 if (!(dict->nspatials % SPATIALS_ALLOC)) {
181 dict->spatials = realloc(dict->spatials,
182 (dict->nspatials + SPATIALS_ALLOC)
183 * sizeof(*dict->spatials));
185 dict->spatials[dict->nspatials] = *s;
186 return dict->nspatials++;
189 static bool
190 spatial_dict_addh(struct spatial_dict *dict, hash_t hash, int id)
192 if (dict->hash[hash]) {
193 dict->collisions++;
194 /* Give up, not worth the trouble. */
195 return false;
197 dict->hash[hash] = id;
198 return true;
201 /* Spatial dictionary file format:
202 * /^#/ - comments
203 * INDEX RADIUS STONES HASH...
204 * INDEX: index in the spatial table
205 * RADIUS: @d of the pattern
206 * STONES: string of ".XO#" chars
207 * HASH...: space-separated 18bit hash-table indices for the pattern */
209 static void
210 spatial_dict_read(struct spatial_dict *dict, char *buf)
212 /* XXX: We trust the data. Bad data will crash us. */
213 char *bufp = buf;
215 int index, radius;
216 index = strtol(bufp, &bufp, 10);
217 radius = strtol(bufp, &bufp, 10);
218 while (isspace(*bufp)) bufp++;
220 /* Load the stone configuration. */
221 struct spatial s = { .dist = radius };
222 int sl = 0;
223 while (!isspace(*bufp)) {
224 s.points[sl / 4] |= char2stone(*bufp++) << (sl % 4);
225 sl++;
227 while (isspace(*bufp)) bufp++;
229 /* Sanity check. */
230 if (sl != ptind[s.dist + 1]) {
231 fprintf(stderr, "Spatial dictionary: Invalid number of stones (%d != %d) on this line: %s\n",
232 sl, ptind[radius + 1] - 1, buf);
233 exit(EXIT_FAILURE);
236 /* Add to collection. */
237 int id = spatial_dict_addc(dict, &s);
239 /* Add to specified hash places. */
240 while (*bufp) {
241 int hash = strtol(bufp, &bufp, 16);
242 while (isspace(*bufp)) bufp++;
243 spatial_dict_addh(dict, hash & spatial_hash_mask, id);
247 void
248 spatial_write(struct spatial *s, int id, FILE *f)
250 fprintf(f, "%d %d ", id, s->dist);
251 fputs(spatial2str(s), f);
252 for (int r = 0; r < PTH__ROTATIONS; r++)
253 fprintf(f, " %"PRIhash"", spatial_hash(r, s));
254 fputc('\n', f);
257 static void
258 spatial_dict_load(struct spatial_dict *dict, FILE *f)
260 char buf[1024];
261 while (fgets(buf, sizeof(buf), f)) {
262 if (buf[0] == '#') continue;
263 spatial_dict_read(dict, buf);
267 void
268 spatial_dict_writeinfo(struct spatial_dict *dict, FILE *f)
270 /* New file. First, create a comment describing order
271 * of points in the array. This is just for purposes
272 * of external tools, Pachi never interprets it itself. */
273 fprintf(f, "# Pachi spatial patterns dictionary v1.0 maxdist %d\n",
274 MAX_PATTERN_DIST);
275 for (int d = 0; d <= MAX_PATTERN_DIST; d++) {
276 fprintf(f, "# Point order: d=%d ", d);
277 for (int j = ptind[d]; j < ptind[d + 1]; j++) {
278 fprintf(f, "%d,%d ", ptcoords[j].x, ptcoords[j].y);
280 fprintf(f, "\n");
284 const char *spatial_dict_filename = "patterns.spat";
285 struct spatial_dict *
286 spatial_dict_init(bool will_append)
288 FILE *f = fopen(spatial_dict_filename, "r");
289 if (!f && !will_append) {
290 if (DEBUGL(1))
291 fprintf(stderr, "No spatial dictionary, will not match spatial pattern features.\n");
292 return NULL;
295 struct spatial_dict *dict = calloc(1, sizeof(*dict));
296 /* We create a dummy record for index 0 that we will
297 * never reference. This is so that hash value 0 can
298 * represent "no value". */
299 struct spatial dummy = { .dist = 0 };
300 spatial_dict_addc(dict, &dummy);
302 if (f) {
303 spatial_dict_load(dict, f);
304 fclose(f); f = NULL;
305 } else {
306 assert(will_append);
309 return dict;
313 spatial_dict_put(struct spatial_dict *dict, struct spatial *s, hash_t h)
315 int id = spatial_dict_get(dict, s->dist, h);
316 if (id > 0) {
317 /* Check for collisions in append mode. */
318 /* Tough job, we simply try if any other rotation
319 * is also covered by the existing record. */
320 int r; hash_t rhash; int rid;
321 for (r = 1; r < PTH__ROTATIONS; r++) {
322 rhash = spatial_hash(r, s);
323 rid = dict->hash[rhash];
324 if (rid != id)
325 goto collision;
327 /* All rotations match, id is good to go! */
328 return id;
330 collision:
331 if (DEBUGL(1))
332 fprintf(stderr, "Collision %d vs %d (hash %d:%"PRIhash")\n",
333 id, dict->nspatials, r, h);
334 id = 0;
335 /* dict->collisions++; gets done by addh */
338 /* Add new pattern! */
339 id = spatial_dict_addc(dict, s);
340 for (int r = 0; r < PTH__ROTATIONS; r++)
341 spatial_dict_addh(dict, spatial_hash(r, s), id);
342 return id;