7bed19e1 |
1 | /* |
2 | * netslide.c: cross between Net and Sixteen, courtesy of Richard |
3 | * Boulton. |
4 | */ |
5 | |
6 | #include <stdio.h> |
7 | #include <stdlib.h> |
8 | #include <string.h> |
9 | #include <assert.h> |
10 | #include <ctype.h> |
11 | #include <math.h> |
12 | |
13 | #include "puzzles.h" |
14 | #include "tree234.h" |
15 | |
16 | const char *const game_name = "Netslide"; |
e91825f8 |
17 | const char *const game_winhelp_topic = "games.netslide"; |
7bed19e1 |
18 | const int game_can_configure = TRUE; |
19 | |
20 | #define PI 3.141592653589793238462643383279502884197169399 |
21 | |
22 | #define MATMUL(xr,yr,m,x,y) do { \ |
23 | float rx, ry, xx = (x), yy = (y), *mat = (m); \ |
24 | rx = mat[0] * xx + mat[2] * yy; \ |
25 | ry = mat[1] * xx + mat[3] * yy; \ |
26 | (xr) = rx; (yr) = ry; \ |
27 | } while (0) |
28 | |
29 | /* Direction and other bitfields */ |
30 | #define R 0x01 |
31 | #define U 0x02 |
32 | #define L 0x04 |
33 | #define D 0x08 |
34 | #define FLASHING 0x10 |
35 | #define ACTIVE 0x20 |
36 | /* Corner flags go in the barriers array */ |
37 | #define RU 0x10 |
38 | #define UL 0x20 |
39 | #define LD 0x40 |
40 | #define DR 0x80 |
41 | |
42 | /* Get tile at given coordinate */ |
43 | #define T(state, x, y) ( (y) * (state)->width + (x) ) |
44 | |
45 | /* Rotations: Anticlockwise, Clockwise, Flip, general rotate */ |
46 | #define A(x) ( (((x) & 0x07) << 1) | (((x) & 0x08) >> 3) ) |
47 | #define C(x) ( (((x) & 0x0E) >> 1) | (((x) & 0x01) << 3) ) |
48 | #define F(x) ( (((x) & 0x0C) >> 2) | (((x) & 0x03) << 2) ) |
49 | #define ROT(x, n) ( ((n)&3) == 0 ? (x) : \ |
50 | ((n)&3) == 1 ? A(x) : \ |
51 | ((n)&3) == 2 ? F(x) : C(x) ) |
52 | |
53 | /* X and Y displacements */ |
54 | #define X(x) ( (x) == R ? +1 : (x) == L ? -1 : 0 ) |
55 | #define Y(x) ( (x) == D ? +1 : (x) == U ? -1 : 0 ) |
56 | |
57 | /* Bit count */ |
58 | #define COUNT(x) ( (((x) & 0x08) >> 3) + (((x) & 0x04) >> 2) + \ |
59 | (((x) & 0x02) >> 1) + ((x) & 0x01) ) |
60 | |
61 | #define TILE_SIZE 48 |
62 | #define BORDER TILE_SIZE |
63 | #define TILE_BORDER 1 |
64 | #define WINDOW_OFFSET 0 |
65 | |
66 | #define ANIM_TIME 0.13F |
67 | #define FLASH_FRAME 0.07F |
68 | |
69 | enum { |
70 | COL_BACKGROUND, |
71 | COL_FLASHING, |
72 | COL_BORDER, |
73 | COL_WIRE, |
74 | COL_ENDPOINT, |
75 | COL_POWERED, |
76 | COL_BARRIER, |
77 | COL_LOWLIGHT, |
78 | COL_TEXT, |
79 | NCOLOURS |
80 | }; |
81 | |
82 | struct game_params { |
83 | int width; |
84 | int height; |
85 | int wrapping; |
86 | float barrier_probability; |
87 | }; |
88 | |
89 | struct game_state { |
90 | int width, height, cx, cy, wrapping, completed; |
91 | int move_count; |
92 | |
93 | /* position (row or col number, starting at 0) of last move. */ |
94 | int last_move_row, last_move_col; |
95 | |
96 | /* direction of last move: +1 or -1 */ |
97 | int last_move_dir; |
98 | |
99 | unsigned char *tiles; |
100 | unsigned char *barriers; |
101 | }; |
102 | |
103 | #define OFFSET(x2,y2,x1,y1,dir,state) \ |
104 | ( (x2) = ((x1) + (state)->width + X((dir))) % (state)->width, \ |
105 | (y2) = ((y1) + (state)->height + Y((dir))) % (state)->height) |
106 | |
107 | #define index(state, a, x, y) ( a[(y) * (state)->width + (x)] ) |
108 | #define tile(state, x, y) index(state, (state)->tiles, x, y) |
109 | #define barrier(state, x, y) index(state, (state)->barriers, x, y) |
110 | |
111 | struct xyd { |
112 | int x, y, direction; |
113 | }; |
114 | |
115 | static int xyd_cmp(void *av, void *bv) { |
116 | struct xyd *a = (struct xyd *)av; |
117 | struct xyd *b = (struct xyd *)bv; |
118 | if (a->x < b->x) |
119 | return -1; |
120 | if (a->x > b->x) |
121 | return +1; |
122 | if (a->y < b->y) |
123 | return -1; |
124 | if (a->y > b->y) |
125 | return +1; |
126 | if (a->direction < b->direction) |
127 | return -1; |
128 | if (a->direction > b->direction) |
129 | return +1; |
130 | return 0; |
131 | }; |
132 | |
133 | static struct xyd *new_xyd(int x, int y, int direction) |
134 | { |
135 | struct xyd *xyd = snew(struct xyd); |
136 | xyd->x = x; |
137 | xyd->y = y; |
138 | xyd->direction = direction; |
139 | return xyd; |
140 | } |
141 | |
142 | void slide_col(game_state *state, int dir, int col); |
143 | void slide_row(game_state *state, int dir, int row); |
144 | |
145 | /* ---------------------------------------------------------------------- |
146 | * Manage game parameters. |
147 | */ |
148 | game_params *default_params(void) |
149 | { |
150 | game_params *ret = snew(game_params); |
151 | |
152 | ret->width = 3; |
153 | ret->height = 3; |
154 | ret->wrapping = FALSE; |
155 | ret->barrier_probability = 1.0; |
156 | |
157 | return ret; |
158 | } |
159 | |
160 | int game_fetch_preset(int i, char **name, game_params **params) |
161 | { |
162 | game_params *ret; |
163 | char str[80]; |
164 | static const struct { int x, y, wrap, bprob; const char* desc; } values[] = { |
165 | {3, 3, FALSE, 1.0, " easy"}, |
166 | {3, 3, FALSE, 0.0, " medium"}, |
167 | {3, 3, TRUE, 0.0, " hard"}, |
168 | {4, 4, FALSE, 1.0, " easy"}, |
169 | {4, 4, FALSE, 0.0, " medium"}, |
170 | {4, 4, TRUE, 0.0, " hard"}, |
171 | {5, 5, FALSE, 1.0, " easy"}, |
172 | {5, 5, FALSE, 0.0, " medium"}, |
173 | {5, 5, TRUE, 0.0, " hard"}, |
174 | }; |
175 | |
176 | if (i < 0 || i >= lenof(values)) |
177 | return FALSE; |
178 | |
179 | ret = snew(game_params); |
180 | ret->width = values[i].x; |
181 | ret->height = values[i].y; |
182 | ret->wrapping = values[i].wrap; |
183 | ret->barrier_probability = values[i].bprob; |
184 | |
185 | sprintf(str, "%dx%d%s", ret->width, ret->height, |
186 | values[i].desc); |
187 | |
188 | *name = dupstr(str); |
189 | *params = ret; |
190 | return TRUE; |
191 | } |
192 | |
193 | void free_params(game_params *params) |
194 | { |
195 | sfree(params); |
196 | } |
197 | |
198 | game_params *dup_params(game_params *params) |
199 | { |
200 | game_params *ret = snew(game_params); |
201 | *ret = *params; /* structure copy */ |
202 | return ret; |
203 | } |
204 | |
205 | game_params *decode_params(char const *string) |
206 | { |
207 | game_params *ret = default_params(); |
208 | char const *p = string; |
209 | |
210 | ret->wrapping = FALSE; |
211 | ret->barrier_probability = 0.0; |
212 | |
213 | ret->width = atoi(p); |
214 | while (*p && isdigit(*p)) p++; |
215 | if (*p == 'x') { |
216 | p++; |
217 | ret->height = atoi(p); |
218 | while (*p && isdigit(*p)) p++; |
219 | if ( (ret->wrapping = (*p == 'w')) != 0 ) |
220 | p++; |
221 | if (*p == 'b') |
222 | ret->barrier_probability = atof(p+1); |
223 | } else { |
224 | ret->height = ret->width; |
225 | } |
226 | |
227 | return ret; |
228 | } |
229 | |
230 | char *encode_params(game_params *params) |
231 | { |
232 | char ret[400]; |
233 | int len; |
234 | |
235 | len = sprintf(ret, "%dx%d", params->width, params->height); |
236 | if (params->wrapping) |
237 | ret[len++] = 'w'; |
238 | if (params->barrier_probability) |
239 | len += sprintf(ret+len, "b%g", params->barrier_probability); |
240 | assert(len < lenof(ret)); |
241 | ret[len] = '\0'; |
242 | |
243 | return dupstr(ret); |
244 | } |
245 | |
246 | config_item *game_configure(game_params *params) |
247 | { |
248 | config_item *ret; |
249 | char buf[80]; |
250 | |
251 | ret = snewn(5, config_item); |
252 | |
253 | ret[0].name = "Width"; |
254 | ret[0].type = C_STRING; |
255 | sprintf(buf, "%d", params->width); |
256 | ret[0].sval = dupstr(buf); |
257 | ret[0].ival = 0; |
258 | |
259 | ret[1].name = "Height"; |
260 | ret[1].type = C_STRING; |
261 | sprintf(buf, "%d", params->height); |
262 | ret[1].sval = dupstr(buf); |
263 | ret[1].ival = 0; |
264 | |
265 | ret[2].name = "Walls wrap around"; |
266 | ret[2].type = C_BOOLEAN; |
267 | ret[2].sval = NULL; |
268 | ret[2].ival = params->wrapping; |
269 | |
270 | ret[3].name = "Barrier probability"; |
271 | ret[3].type = C_STRING; |
272 | sprintf(buf, "%g", params->barrier_probability); |
273 | ret[3].sval = dupstr(buf); |
274 | ret[3].ival = 0; |
275 | |
276 | ret[4].name = NULL; |
277 | ret[4].type = C_END; |
278 | ret[4].sval = NULL; |
279 | ret[4].ival = 0; |
280 | |
281 | return ret; |
282 | } |
283 | |
284 | game_params *custom_params(config_item *cfg) |
285 | { |
286 | game_params *ret = snew(game_params); |
287 | |
288 | ret->width = atoi(cfg[0].sval); |
289 | ret->height = atoi(cfg[1].sval); |
290 | ret->wrapping = cfg[2].ival; |
291 | ret->barrier_probability = (float)atof(cfg[3].sval); |
292 | |
293 | return ret; |
294 | } |
295 | |
296 | char *validate_params(game_params *params) |
297 | { |
298 | if (params->width <= 1 && params->height <= 1) |
299 | return "Width and height must both be greater than one"; |
300 | if (params->width <= 1) |
301 | return "Width must be greater than one"; |
302 | if (params->height <= 1) |
303 | return "Height must be greater than one"; |
304 | if (params->barrier_probability < 0) |
305 | return "Barrier probability may not be negative"; |
306 | if (params->barrier_probability > 1) |
307 | return "Barrier probability may not be greater than 1"; |
308 | return NULL; |
309 | } |
310 | |
311 | /* ---------------------------------------------------------------------- |
312 | * Randomly select a new game seed. |
313 | */ |
314 | |
315 | char *new_game_seed(game_params *params, random_state *rs) |
316 | { |
317 | /* |
318 | * The full description of a Net game is far too large to |
319 | * encode directly in the seed, so by default we'll have to go |
320 | * for the simple approach of providing a random-number seed. |
321 | * |
322 | * (This does not restrict me from _later on_ inventing a seed |
323 | * string syntax which can never be generated by this code - |
324 | * for example, strings beginning with a letter - allowing me |
325 | * to type in a precise game, and have new_game detect it and |
326 | * understand it and do something completely different.) |
327 | */ |
328 | char buf[40]; |
329 | sprintf(buf, "%lu", random_bits(rs, 32)); |
330 | return dupstr(buf); |
331 | } |
332 | |
333 | char *validate_seed(game_params *params, char *seed) |
334 | { |
335 | /* |
336 | * Since any string at all will suffice to seed the RNG, there |
337 | * is no validation required. |
338 | */ |
339 | return NULL; |
340 | } |
341 | |
342 | /* ---------------------------------------------------------------------- |
343 | * Construct an initial game state, given a seed and parameters. |
344 | */ |
345 | |
346 | game_state *new_game(game_params *params, char *seed) |
347 | { |
348 | random_state *rs; |
349 | game_state *state; |
350 | tree234 *possibilities, *barriers; |
351 | int w, h, x, y, nbarriers; |
352 | |
353 | assert(params->width > 0 && params->height > 0); |
354 | assert(params->width > 1 || params->height > 1); |
355 | |
356 | /* |
357 | * Create a blank game state. |
358 | */ |
359 | state = snew(game_state); |
360 | w = state->width = params->width; |
361 | h = state->height = params->height; |
362 | state->cx = state->width / 2; |
363 | state->cy = state->height / 2; |
364 | state->wrapping = params->wrapping; |
365 | state->completed = 0; |
366 | state->move_count = 0; |
367 | state->last_move_row = -1; |
368 | state->last_move_col = -1; |
369 | state->last_move_dir = 0; |
370 | state->tiles = snewn(state->width * state->height, unsigned char); |
371 | memset(state->tiles, 0, state->width * state->height); |
372 | state->barriers = snewn(state->width * state->height, unsigned char); |
373 | memset(state->barriers, 0, state->width * state->height); |
374 | |
375 | /* |
376 | * Set up border barriers if this is a non-wrapping game. |
377 | */ |
378 | if (!state->wrapping) { |
379 | for (x = 0; x < state->width; x++) { |
380 | barrier(state, x, 0) |= U; |
381 | barrier(state, x, state->height-1) |= D; |
382 | } |
383 | for (y = 0; y < state->height; y++) { |
384 | barrier(state, 0, y) |= L; |
385 | barrier(state, state->width-1, y) |= R; |
386 | } |
387 | } |
388 | |
389 | /* |
390 | * Seed the internal random number generator. |
391 | */ |
392 | rs = random_init(seed, strlen(seed)); |
393 | |
394 | /* |
395 | * Construct the unshuffled grid. |
396 | * |
397 | * To do this, we simply start at the centre point, repeatedly |
398 | * choose a random possibility out of the available ways to |
399 | * extend a used square into an unused one, and do it. After |
400 | * extending the third line out of a square, we remove the |
401 | * fourth from the possibilities list to avoid any full-cross |
402 | * squares (which would make the game too easy because they |
403 | * only have one orientation). |
404 | * |
405 | * The slightly worrying thing is the avoidance of full-cross |
406 | * squares. Can this cause our unsophisticated construction |
407 | * algorithm to paint itself into a corner, by getting into a |
408 | * situation where there are some unreached squares and the |
409 | * only way to reach any of them is to extend a T-piece into a |
410 | * full cross? |
411 | * |
412 | * Answer: no it can't, and here's a proof. |
413 | * |
414 | * Any contiguous group of such unreachable squares must be |
415 | * surrounded on _all_ sides by T-pieces pointing away from the |
416 | * group. (If not, then there is a square which can be extended |
417 | * into one of the `unreachable' ones, and so it wasn't |
418 | * unreachable after all.) In particular, this implies that |
419 | * each contiguous group of unreachable squares must be |
420 | * rectangular in shape (any deviation from that yields a |
421 | * non-T-piece next to an `unreachable' square). |
422 | * |
423 | * So we have a rectangle of unreachable squares, with T-pieces |
424 | * forming a solid border around the rectangle. The corners of |
425 | * that border must be connected (since every tile connects all |
426 | * the lines arriving in it), and therefore the border must |
427 | * form a closed loop around the rectangle. |
428 | * |
429 | * But this can't have happened in the first place, since we |
430 | * _know_ we've avoided creating closed loops! Hence, no such |
431 | * situation can ever arise, and the naive grid construction |
432 | * algorithm will guaranteeably result in a complete grid |
433 | * containing no unreached squares, no full crosses _and_ no |
434 | * closed loops. [] |
435 | */ |
436 | possibilities = newtree234(xyd_cmp); |
437 | |
438 | if (state->cx+1 < state->width) |
439 | add234(possibilities, new_xyd(state->cx, state->cy, R)); |
440 | if (state->cy-1 >= 0) |
441 | add234(possibilities, new_xyd(state->cx, state->cy, U)); |
442 | if (state->cx-1 >= 0) |
443 | add234(possibilities, new_xyd(state->cx, state->cy, L)); |
444 | if (state->cy+1 < state->height) |
445 | add234(possibilities, new_xyd(state->cx, state->cy, D)); |
446 | |
447 | while (count234(possibilities) > 0) { |
448 | int i; |
449 | struct xyd *xyd; |
450 | int x1, y1, d1, x2, y2, d2, d; |
451 | |
452 | /* |
453 | * Extract a randomly chosen possibility from the list. |
454 | */ |
455 | i = random_upto(rs, count234(possibilities)); |
456 | xyd = delpos234(possibilities, i); |
457 | x1 = xyd->x; |
458 | y1 = xyd->y; |
459 | d1 = xyd->direction; |
460 | sfree(xyd); |
461 | |
462 | OFFSET(x2, y2, x1, y1, d1, state); |
463 | d2 = F(d1); |
464 | #ifdef DEBUG |
465 | printf("picked (%d,%d,%c) <-> (%d,%d,%c)\n", |
466 | x1, y1, "0RU3L567D9abcdef"[d1], x2, y2, "0RU3L567D9abcdef"[d2]); |
467 | #endif |
468 | |
469 | /* |
470 | * Make the connection. (We should be moving to an as yet |
471 | * unused tile.) |
472 | */ |
473 | tile(state, x1, y1) |= d1; |
474 | assert(tile(state, x2, y2) == 0); |
475 | tile(state, x2, y2) |= d2; |
476 | |
477 | /* |
478 | * If we have created a T-piece, remove its last |
479 | * possibility. |
480 | */ |
481 | if (COUNT(tile(state, x1, y1)) == 3) { |
482 | struct xyd xyd1, *xydp; |
483 | |
484 | xyd1.x = x1; |
485 | xyd1.y = y1; |
486 | xyd1.direction = 0x0F ^ tile(state, x1, y1); |
487 | |
488 | xydp = find234(possibilities, &xyd1, NULL); |
489 | |
490 | if (xydp) { |
491 | #ifdef DEBUG |
492 | printf("T-piece; removing (%d,%d,%c)\n", |
493 | xydp->x, xydp->y, "0RU3L567D9abcdef"[xydp->direction]); |
494 | #endif |
495 | del234(possibilities, xydp); |
496 | sfree(xydp); |
497 | } |
498 | } |
499 | |
500 | /* |
501 | * Remove all other possibilities that were pointing at the |
502 | * tile we've just moved into. |
503 | */ |
504 | for (d = 1; d < 0x10; d <<= 1) { |
505 | int x3, y3, d3; |
506 | struct xyd xyd1, *xydp; |
507 | |
508 | OFFSET(x3, y3, x2, y2, d, state); |
509 | d3 = F(d); |
510 | |
511 | xyd1.x = x3; |
512 | xyd1.y = y3; |
513 | xyd1.direction = d3; |
514 | |
515 | xydp = find234(possibilities, &xyd1, NULL); |
516 | |
517 | if (xydp) { |
518 | #ifdef DEBUG |
519 | printf("Loop avoidance; removing (%d,%d,%c)\n", |
520 | xydp->x, xydp->y, "0RU3L567D9abcdef"[xydp->direction]); |
521 | #endif |
522 | del234(possibilities, xydp); |
523 | sfree(xydp); |
524 | } |
525 | } |
526 | |
527 | /* |
528 | * Add new possibilities to the list for moving _out_ of |
529 | * the tile we have just moved into. |
530 | */ |
531 | for (d = 1; d < 0x10; d <<= 1) { |
532 | int x3, y3; |
533 | |
534 | if (d == d2) |
535 | continue; /* we've got this one already */ |
536 | |
537 | if (!state->wrapping) { |
538 | if (d == U && y2 == 0) |
539 | continue; |
540 | if (d == D && y2 == state->height-1) |
541 | continue; |
542 | if (d == L && x2 == 0) |
543 | continue; |
544 | if (d == R && x2 == state->width-1) |
545 | continue; |
546 | } |
547 | |
548 | OFFSET(x3, y3, x2, y2, d, state); |
549 | |
550 | if (tile(state, x3, y3)) |
551 | continue; /* this would create a loop */ |
552 | |
553 | #ifdef DEBUG |
554 | printf("New frontier; adding (%d,%d,%c)\n", |
555 | x2, y2, "0RU3L567D9abcdef"[d]); |
556 | #endif |
557 | add234(possibilities, new_xyd(x2, y2, d)); |
558 | } |
559 | } |
560 | /* Having done that, we should have no possibilities remaining. */ |
561 | assert(count234(possibilities) == 0); |
562 | freetree234(possibilities); |
563 | |
564 | /* |
565 | * Now compute a list of the possible barrier locations. |
566 | */ |
567 | barriers = newtree234(xyd_cmp); |
568 | for (y = 0; y < state->height; y++) { |
569 | for (x = 0; x < state->width; x++) { |
570 | |
571 | if (!(tile(state, x, y) & R) && |
572 | (state->wrapping || x < state->width-1)) |
573 | add234(barriers, new_xyd(x, y, R)); |
574 | if (!(tile(state, x, y) & D) && |
575 | (state->wrapping || y < state->height-1)) |
576 | add234(barriers, new_xyd(x, y, D)); |
577 | } |
578 | } |
579 | |
580 | /* |
581 | * Now shuffle the grid. |
582 | * FIXME - this simply does a set of random moves to shuffle the pieces. |
583 | * A better way would be to number all the pieces, generate a placement |
584 | * for all the numbers as for "sixteen", observing parity constraints if |
585 | * neccessary, and then place the pieces according to their numbering. |
586 | * BUT - I'm not sure if this will work, since we disallow movement of |
587 | * the middle row and column. |
588 | */ |
589 | { |
590 | int i; |
591 | int cols = state->width - 1; |
592 | int rows = state->height - 1; |
593 | for (i = 0; i < cols * rows * 2; i++) { |
594 | /* Choose a direction: 0,1,2,3 = up, right, down, left. */ |
595 | int dir = random_upto(rs, 4); |
596 | if (dir % 2 == 0) { |
597 | int col = random_upto(rs, cols); |
598 | if (col >= state->cx) col += 1; |
599 | slide_col(state, 1 - dir, col); |
600 | } else { |
601 | int row = random_upto(rs, rows); |
602 | if (row >= state->cy) row += 1; |
603 | slide_row(state, 2 - dir, row); |
604 | } |
605 | } |
606 | } |
607 | |
608 | /* |
609 | * And now choose barrier locations. (We carefully do this |
610 | * _after_ shuffling, so that changing the barrier rate in the |
611 | * params while keeping the game seed the same will give the |
612 | * same shuffled grid and _only_ change the barrier locations. |
613 | * Also the way we choose barrier locations, by repeatedly |
614 | * choosing one possibility from the list until we have enough, |
615 | * is designed to ensure that raising the barrier rate while |
616 | * keeping the seed the same will provide a superset of the |
617 | * previous barrier set - i.e. if you ask for 10 barriers, and |
618 | * then decide that's still too hard and ask for 20, you'll get |
619 | * the original 10 plus 10 more, rather than getting 20 new |
620 | * ones and the chance of remembering your first 10.) |
621 | */ |
622 | nbarriers = (int)(params->barrier_probability * count234(barriers)); |
623 | assert(nbarriers >= 0 && nbarriers <= count234(barriers)); |
624 | |
625 | while (nbarriers > 0) { |
626 | int i; |
627 | struct xyd *xyd; |
628 | int x1, y1, d1, x2, y2, d2; |
629 | |
630 | /* |
631 | * Extract a randomly chosen barrier from the list. |
632 | */ |
633 | i = random_upto(rs, count234(barriers)); |
634 | xyd = delpos234(barriers, i); |
635 | |
636 | assert(xyd != NULL); |
637 | |
638 | x1 = xyd->x; |
639 | y1 = xyd->y; |
640 | d1 = xyd->direction; |
641 | sfree(xyd); |
642 | |
643 | OFFSET(x2, y2, x1, y1, d1, state); |
644 | d2 = F(d1); |
645 | |
646 | barrier(state, x1, y1) |= d1; |
647 | barrier(state, x2, y2) |= d2; |
648 | |
649 | nbarriers--; |
650 | } |
651 | |
652 | /* |
653 | * Clean up the rest of the barrier list. |
654 | */ |
655 | { |
656 | struct xyd *xyd; |
657 | |
658 | while ( (xyd = delpos234(barriers, 0)) != NULL) |
659 | sfree(xyd); |
660 | |
661 | freetree234(barriers); |
662 | } |
663 | |
664 | /* |
665 | * Set up the barrier corner flags, for drawing barriers |
666 | * prettily when they meet. |
667 | */ |
668 | for (y = 0; y < state->height; y++) { |
669 | for (x = 0; x < state->width; x++) { |
670 | int dir; |
671 | |
672 | for (dir = 1; dir < 0x10; dir <<= 1) { |
673 | int dir2 = A(dir); |
674 | int x1, y1, x2, y2, x3, y3; |
675 | int corner = FALSE; |
676 | |
677 | if (!(barrier(state, x, y) & dir)) |
678 | continue; |
679 | |
680 | if (barrier(state, x, y) & dir2) |
681 | corner = TRUE; |
682 | |
683 | x1 = x + X(dir), y1 = y + Y(dir); |
684 | if (x1 >= 0 && x1 < state->width && |
685 | y1 >= 0 && y1 < state->height && |
686 | (barrier(state, x1, y1) & dir2)) |
687 | corner = TRUE; |
688 | |
689 | x2 = x + X(dir2), y2 = y + Y(dir2); |
690 | if (x2 >= 0 && x2 < state->width && |
691 | y2 >= 0 && y2 < state->height && |
692 | (barrier(state, x2, y2) & dir)) |
693 | corner = TRUE; |
694 | |
695 | if (corner) { |
696 | barrier(state, x, y) |= (dir << 4); |
697 | if (x1 >= 0 && x1 < state->width && |
698 | y1 >= 0 && y1 < state->height) |
699 | barrier(state, x1, y1) |= (A(dir) << 4); |
700 | if (x2 >= 0 && x2 < state->width && |
701 | y2 >= 0 && y2 < state->height) |
702 | barrier(state, x2, y2) |= (C(dir) << 4); |
703 | x3 = x + X(dir) + X(dir2), y3 = y + Y(dir) + Y(dir2); |
704 | if (x3 >= 0 && x3 < state->width && |
705 | y3 >= 0 && y3 < state->height) |
706 | barrier(state, x3, y3) |= (F(dir) << 4); |
707 | } |
708 | } |
709 | } |
710 | } |
711 | |
712 | random_free(rs); |
713 | |
714 | return state; |
715 | } |
716 | |
717 | game_state *dup_game(game_state *state) |
718 | { |
719 | game_state *ret; |
720 | |
721 | ret = snew(game_state); |
722 | ret->width = state->width; |
723 | ret->height = state->height; |
724 | ret->cx = state->cx; |
725 | ret->cy = state->cy; |
726 | ret->wrapping = state->wrapping; |
727 | ret->completed = state->completed; |
728 | ret->move_count = state->move_count; |
729 | ret->last_move_row = state->last_move_row; |
730 | ret->last_move_col = state->last_move_col; |
731 | ret->last_move_dir = state->last_move_dir; |
732 | ret->tiles = snewn(state->width * state->height, unsigned char); |
733 | memcpy(ret->tiles, state->tiles, state->width * state->height); |
734 | ret->barriers = snewn(state->width * state->height, unsigned char); |
735 | memcpy(ret->barriers, state->barriers, state->width * state->height); |
736 | |
737 | return ret; |
738 | } |
739 | |
740 | void free_game(game_state *state) |
741 | { |
742 | sfree(state->tiles); |
743 | sfree(state->barriers); |
744 | sfree(state); |
745 | } |
746 | |
747 | /* ---------------------------------------------------------------------- |
748 | * Utility routine. |
749 | */ |
750 | |
751 | /* |
752 | * Compute which squares are reachable from the centre square, as a |
753 | * quick visual aid to determining how close the game is to |
754 | * completion. This is also a simple way to tell if the game _is_ |
755 | * completed - just call this function and see whether every square |
756 | * is marked active. |
757 | * |
758 | * squares in the moving_row and moving_col are always inactive - this |
759 | * is so that "current" doesn't appear to jump across moving lines. |
760 | */ |
761 | static unsigned char *compute_active(game_state *state, |
762 | int moving_row, int moving_col) |
763 | { |
764 | unsigned char *active; |
765 | tree234 *todo; |
766 | struct xyd *xyd; |
767 | |
768 | active = snewn(state->width * state->height, unsigned char); |
769 | memset(active, 0, state->width * state->height); |
770 | |
771 | /* |
772 | * We only store (x,y) pairs in todo, but it's easier to reuse |
773 | * xyd_cmp and just store direction 0 every time. |
774 | */ |
775 | todo = newtree234(xyd_cmp); |
776 | index(state, active, state->cx, state->cy) = ACTIVE; |
777 | add234(todo, new_xyd(state->cx, state->cy, 0)); |
778 | |
779 | while ( (xyd = delpos234(todo, 0)) != NULL) { |
780 | int x1, y1, d1, x2, y2, d2; |
781 | |
782 | x1 = xyd->x; |
783 | y1 = xyd->y; |
784 | sfree(xyd); |
785 | |
786 | for (d1 = 1; d1 < 0x10; d1 <<= 1) { |
787 | OFFSET(x2, y2, x1, y1, d1, state); |
788 | d2 = F(d1); |
789 | |
790 | /* |
791 | * If the next tile in this direction is connected to |
792 | * us, and there isn't a barrier in the way, and it |
793 | * isn't already marked active, then mark it active and |
794 | * add it to the to-examine list. |
795 | */ |
796 | if ((x2 != moving_col && y2 != moving_row) && |
797 | (tile(state, x1, y1) & d1) && |
798 | (tile(state, x2, y2) & d2) && |
799 | !(barrier(state, x1, y1) & d1) && |
800 | !index(state, active, x2, y2)) { |
801 | index(state, active, x2, y2) = ACTIVE; |
802 | add234(todo, new_xyd(x2, y2, 0)); |
803 | } |
804 | } |
805 | } |
806 | /* Now we expect the todo list to have shrunk to zero size. */ |
807 | assert(count234(todo) == 0); |
808 | freetree234(todo); |
809 | |
810 | return active; |
811 | } |
812 | |
813 | struct game_ui { |
814 | int cur_x, cur_y; |
815 | int cur_visible; |
816 | }; |
817 | |
818 | game_ui *new_ui(game_state *state) |
819 | { |
820 | game_ui *ui = snew(game_ui); |
821 | ui->cur_x = state->width / 2; |
822 | ui->cur_y = state->height / 2; |
823 | ui->cur_visible = FALSE; |
824 | |
825 | return ui; |
826 | } |
827 | |
828 | void free_ui(game_ui *ui) |
829 | { |
830 | sfree(ui); |
831 | } |
832 | |
833 | /* ---------------------------------------------------------------------- |
834 | * Process a move. |
835 | */ |
836 | |
837 | void slide_row(game_state *state, int dir, int row) |
838 | { |
839 | int x = dir > 0 ? -1 : state->width; |
840 | int tx = x + dir; |
841 | int n = state->width - 1; |
842 | unsigned char endtile = state->tiles[T(state, tx, row)]; |
843 | do { |
844 | x = tx; |
845 | tx = (x + dir + state->width) % state->width; |
846 | state->tiles[T(state, x, row)] = state->tiles[T(state, tx, row)]; |
847 | } while (--n > 0); |
848 | state->tiles[T(state, tx, row)] = endtile; |
849 | } |
850 | |
851 | void slide_col(game_state *state, int dir, int col) |
852 | { |
853 | int y = dir > 0 ? -1 : state->height; |
854 | int ty = y + dir; |
855 | int n = state->height - 1; |
856 | unsigned char endtile = state->tiles[T(state, col, ty)]; |
857 | do { |
858 | y = ty; |
859 | ty = (y + dir + state->height) % state->height; |
860 | state->tiles[T(state, col, y)] = state->tiles[T(state, col, ty)]; |
861 | } while (--n > 0); |
862 | state->tiles[T(state, col, ty)] = endtile; |
863 | } |
864 | |
865 | game_state *make_move(game_state *state, game_ui *ui, int x, int y, int button) |
866 | { |
867 | int cx, cy; |
868 | int n, dx, dy; |
869 | game_state *ret; |
870 | |
871 | if (button != LEFT_BUTTON && button != RIGHT_BUTTON) |
872 | return NULL; |
873 | |
874 | cx = (x - (BORDER + WINDOW_OFFSET + TILE_BORDER) + 2*TILE_SIZE) / TILE_SIZE - 2; |
875 | cy = (y - (BORDER + WINDOW_OFFSET + TILE_BORDER) + 2*TILE_SIZE) / TILE_SIZE - 2; |
876 | |
877 | if (cy >= 0 && cy < state->height && cy != state->cy) |
878 | { |
879 | if (cx == -1) dx = +1; |
880 | else if (cx == state->width) dx = -1; |
881 | else return NULL; |
882 | n = state->width; |
883 | dy = 0; |
884 | } |
885 | else if (cx >= 0 && cx < state->width && cx != state->cx) |
886 | { |
887 | if (cy == -1) dy = +1; |
888 | else if (cy == state->height) dy = -1; |
889 | else return NULL; |
890 | n = state->height; |
891 | dx = 0; |
892 | } |
893 | else |
894 | return NULL; |
895 | |
896 | /* reverse direction if right hand button is pressed */ |
897 | if (button == RIGHT_BUTTON) |
898 | { |
899 | dx = -dx; |
900 | dy = -dy; |
901 | } |
902 | |
903 | ret = dup_game(state); |
904 | |
905 | if (dx == 0) slide_col(ret, dy, cx); |
906 | else slide_row(ret, dx, cy); |
907 | |
908 | ret->move_count++; |
909 | ret->last_move_row = dx ? cy : -1; |
910 | ret->last_move_col = dx ? -1 : cx; |
911 | ret->last_move_dir = dx + dy; |
912 | |
913 | /* |
914 | * See if the game has been completed. |
915 | */ |
916 | if (!ret->completed) { |
917 | unsigned char *active = compute_active(ret, -1, -1); |
918 | int x1, y1; |
919 | int complete = TRUE; |
920 | |
921 | for (x1 = 0; x1 < ret->width; x1++) |
922 | for (y1 = 0; y1 < ret->height; y1++) |
923 | if (!index(ret, active, x1, y1)) { |
924 | complete = FALSE; |
925 | goto break_label; /* break out of two loops at once */ |
926 | } |
927 | break_label: |
928 | |
929 | sfree(active); |
930 | |
931 | if (complete) |
932 | ret->completed = ret->move_count; |
933 | } |
934 | |
935 | return ret; |
936 | } |
937 | |
938 | /* ---------------------------------------------------------------------- |
939 | * Routines for drawing the game position on the screen. |
940 | */ |
941 | |
942 | struct game_drawstate { |
943 | int started; |
944 | int width, height; |
945 | unsigned char *visible; |
946 | }; |
947 | |
948 | game_drawstate *game_new_drawstate(game_state *state) |
949 | { |
950 | game_drawstate *ds = snew(game_drawstate); |
951 | |
952 | ds->started = FALSE; |
953 | ds->width = state->width; |
954 | ds->height = state->height; |
955 | ds->visible = snewn(state->width * state->height, unsigned char); |
956 | memset(ds->visible, 0xFF, state->width * state->height); |
957 | |
958 | return ds; |
959 | } |
960 | |
961 | void game_free_drawstate(game_drawstate *ds) |
962 | { |
963 | sfree(ds->visible); |
964 | sfree(ds); |
965 | } |
966 | |
967 | void game_size(game_params *params, int *x, int *y) |
968 | { |
969 | *x = BORDER * 2 + WINDOW_OFFSET * 2 + TILE_SIZE * params->width + TILE_BORDER; |
970 | *y = BORDER * 2 + WINDOW_OFFSET * 2 + TILE_SIZE * params->height + TILE_BORDER; |
971 | } |
972 | |
973 | float *game_colours(frontend *fe, game_state *state, int *ncolours) |
974 | { |
975 | float *ret; |
976 | |
977 | ret = snewn(NCOLOURS * 3, float); |
978 | *ncolours = NCOLOURS; |
979 | |
980 | /* |
981 | * Basic background colour is whatever the front end thinks is |
982 | * a sensible default. |
983 | */ |
984 | frontend_default_colour(fe, &ret[COL_BACKGROUND * 3]); |
985 | |
986 | /* |
987 | * Wires are black. |
988 | */ |
989 | ret[COL_WIRE * 3 + 0] = 0.0F; |
990 | ret[COL_WIRE * 3 + 1] = 0.0F; |
991 | ret[COL_WIRE * 3 + 2] = 0.0F; |
992 | |
993 | /* |
994 | * Powered wires and powered endpoints are cyan. |
995 | */ |
996 | ret[COL_POWERED * 3 + 0] = 0.0F; |
997 | ret[COL_POWERED * 3 + 1] = 1.0F; |
998 | ret[COL_POWERED * 3 + 2] = 1.0F; |
999 | |
1000 | /* |
1001 | * Barriers are red. |
1002 | */ |
1003 | ret[COL_BARRIER * 3 + 0] = 1.0F; |
1004 | ret[COL_BARRIER * 3 + 1] = 0.0F; |
1005 | ret[COL_BARRIER * 3 + 2] = 0.0F; |
1006 | |
1007 | /* |
1008 | * Unpowered endpoints are blue. |
1009 | */ |
1010 | ret[COL_ENDPOINT * 3 + 0] = 0.0F; |
1011 | ret[COL_ENDPOINT * 3 + 1] = 0.0F; |
1012 | ret[COL_ENDPOINT * 3 + 2] = 1.0F; |
1013 | |
1014 | /* |
1015 | * Tile borders are a darker grey than the background. |
1016 | */ |
1017 | ret[COL_BORDER * 3 + 0] = 0.5F * ret[COL_BACKGROUND * 3 + 0]; |
1018 | ret[COL_BORDER * 3 + 1] = 0.5F * ret[COL_BACKGROUND * 3 + 1]; |
1019 | ret[COL_BORDER * 3 + 2] = 0.5F * ret[COL_BACKGROUND * 3 + 2]; |
1020 | |
1021 | /* |
1022 | * Flashing tiles are a grey in between those two. |
1023 | */ |
1024 | ret[COL_FLASHING * 3 + 0] = 0.75F * ret[COL_BACKGROUND * 3 + 0]; |
1025 | ret[COL_FLASHING * 3 + 1] = 0.75F * ret[COL_BACKGROUND * 3 + 1]; |
1026 | ret[COL_FLASHING * 3 + 2] = 0.75F * ret[COL_BACKGROUND * 3 + 2]; |
1027 | |
1028 | ret[COL_LOWLIGHT * 3 + 0] = ret[COL_BACKGROUND * 3 + 0] * 0.8F; |
1029 | ret[COL_LOWLIGHT * 3 + 1] = ret[COL_BACKGROUND * 3 + 1] * 0.8F; |
1030 | ret[COL_LOWLIGHT * 3 + 2] = ret[COL_BACKGROUND * 3 + 2] * 0.8F; |
1031 | ret[COL_TEXT * 3 + 0] = 0.0; |
1032 | ret[COL_TEXT * 3 + 1] = 0.0; |
1033 | ret[COL_TEXT * 3 + 2] = 0.0; |
1034 | |
1035 | return ret; |
1036 | } |
1037 | |
1038 | static void draw_thick_line(frontend *fe, int x1, int y1, int x2, int y2, |
1039 | int colour) |
1040 | { |
1041 | draw_line(fe, x1-1, y1, x2-1, y2, COL_WIRE); |
1042 | draw_line(fe, x1+1, y1, x2+1, y2, COL_WIRE); |
1043 | draw_line(fe, x1, y1-1, x2, y2-1, COL_WIRE); |
1044 | draw_line(fe, x1, y1+1, x2, y2+1, COL_WIRE); |
1045 | draw_line(fe, x1, y1, x2, y2, colour); |
1046 | } |
1047 | |
1048 | static void draw_rect_coords(frontend *fe, int x1, int y1, int x2, int y2, |
1049 | int colour) |
1050 | { |
1051 | int mx = (x1 < x2 ? x1 : x2); |
1052 | int my = (y1 < y2 ? y1 : y2); |
1053 | int dx = (x2 + x1 - 2*mx + 1); |
1054 | int dy = (y2 + y1 - 2*my + 1); |
1055 | |
1056 | draw_rect(fe, mx, my, dx, dy, colour); |
1057 | } |
1058 | |
1059 | static void draw_barrier_corner(frontend *fe, int x, int y, int dir, int phase) |
1060 | { |
1061 | int bx = BORDER + WINDOW_OFFSET + TILE_SIZE * x; |
1062 | int by = BORDER + WINDOW_OFFSET + TILE_SIZE * y; |
1063 | int x1, y1, dx, dy, dir2; |
1064 | |
1065 | dir >>= 4; |
1066 | |
1067 | dir2 = A(dir); |
1068 | dx = X(dir) + X(dir2); |
1069 | dy = Y(dir) + Y(dir2); |
1070 | x1 = (dx > 0 ? TILE_SIZE+TILE_BORDER-1 : 0); |
1071 | y1 = (dy > 0 ? TILE_SIZE+TILE_BORDER-1 : 0); |
1072 | |
1073 | if (phase == 0) { |
1074 | draw_rect_coords(fe, bx+x1, by+y1, |
1075 | bx+x1-TILE_BORDER*dx, by+y1-(TILE_BORDER-1)*dy, |
1076 | COL_WIRE); |
1077 | draw_rect_coords(fe, bx+x1, by+y1, |
1078 | bx+x1-(TILE_BORDER-1)*dx, by+y1-TILE_BORDER*dy, |
1079 | COL_WIRE); |
1080 | } else { |
1081 | draw_rect_coords(fe, bx+x1, by+y1, |
1082 | bx+x1-(TILE_BORDER-1)*dx, by+y1-(TILE_BORDER-1)*dy, |
1083 | COL_BARRIER); |
1084 | } |
1085 | } |
1086 | |
1087 | static void draw_barrier(frontend *fe, int x, int y, int dir, int phase) |
1088 | { |
1089 | int bx = BORDER + WINDOW_OFFSET + TILE_SIZE * x; |
1090 | int by = BORDER + WINDOW_OFFSET + TILE_SIZE * y; |
1091 | int x1, y1, w, h; |
1092 | |
1093 | x1 = (X(dir) > 0 ? TILE_SIZE : X(dir) == 0 ? TILE_BORDER : 0); |
1094 | y1 = (Y(dir) > 0 ? TILE_SIZE : Y(dir) == 0 ? TILE_BORDER : 0); |
1095 | w = (X(dir) ? TILE_BORDER : TILE_SIZE - TILE_BORDER); |
1096 | h = (Y(dir) ? TILE_BORDER : TILE_SIZE - TILE_BORDER); |
1097 | |
1098 | if (phase == 0) { |
1099 | draw_rect(fe, bx+x1-X(dir), by+y1-Y(dir), w, h, COL_WIRE); |
1100 | } else { |
1101 | draw_rect(fe, bx+x1, by+y1, w, h, COL_BARRIER); |
1102 | } |
1103 | } |
1104 | |
1105 | static void draw_tile(frontend *fe, game_state *state, int x, int y, int tile, |
1106 | float xshift, float yshift) |
1107 | { |
1108 | int bx = BORDER + WINDOW_OFFSET + TILE_SIZE * x + (xshift * TILE_SIZE); |
1109 | int by = BORDER + WINDOW_OFFSET + TILE_SIZE * y + (yshift * TILE_SIZE); |
1110 | float cx, cy, ex, ey; |
1111 | int dir, col; |
1112 | |
1113 | /* |
1114 | * When we draw a single tile, we must draw everything up to |
1115 | * and including the borders around the tile. This means that |
1116 | * if the neighbouring tiles have connections to those borders, |
1117 | * we must draw those connections on the borders themselves. |
1118 | * |
1119 | * This would be terribly fiddly if we ever had to draw a tile |
1120 | * while its neighbour was in mid-rotate, because we'd have to |
1121 | * arrange to _know_ that the neighbour was being rotated and |
1122 | * hence had an anomalous effect on the redraw of this tile. |
1123 | * Fortunately, the drawing algorithm avoids ever calling us in |
1124 | * this circumstance: we're either drawing lots of straight |
1125 | * tiles at game start or after a move is complete, or we're |
1126 | * repeatedly drawing only the rotating tile. So no problem. |
1127 | */ |
1128 | |
1129 | /* |
1130 | * So. First blank the tile out completely: draw a big |
1131 | * rectangle in border colour, and a smaller rectangle in |
1132 | * background colour to fill it in. |
1133 | */ |
1134 | draw_rect(fe, bx, by, TILE_SIZE+TILE_BORDER, TILE_SIZE+TILE_BORDER, |
1135 | COL_BORDER); |
1136 | draw_rect(fe, bx+TILE_BORDER, by+TILE_BORDER, |
1137 | TILE_SIZE-TILE_BORDER, TILE_SIZE-TILE_BORDER, |
1138 | tile & FLASHING ? COL_FLASHING : COL_BACKGROUND); |
1139 | |
1140 | /* |
1141 | * Draw the wires. |
1142 | */ |
1143 | cx = cy = TILE_BORDER + (TILE_SIZE-TILE_BORDER) / 2.0F - 0.5F; |
1144 | col = (tile & ACTIVE ? COL_POWERED : COL_WIRE); |
1145 | for (dir = 1; dir < 0x10; dir <<= 1) { |
1146 | if (tile & dir) { |
1147 | ex = (TILE_SIZE - TILE_BORDER - 1.0F) / 2.0F * X(dir); |
1148 | ey = (TILE_SIZE - TILE_BORDER - 1.0F) / 2.0F * Y(dir); |
1149 | draw_thick_line(fe, bx+(int)cx, by+(int)cy, |
1150 | bx+(int)(cx+ex), by+(int)(cy+ey), |
1151 | COL_WIRE); |
1152 | } |
1153 | } |
1154 | for (dir = 1; dir < 0x10; dir <<= 1) { |
1155 | if (tile & dir) { |
1156 | ex = (TILE_SIZE - TILE_BORDER - 1.0F) / 2.0F * X(dir); |
1157 | ey = (TILE_SIZE - TILE_BORDER - 1.0F) / 2.0F * Y(dir); |
1158 | draw_line(fe, bx+(int)cx, by+(int)cy, |
1159 | bx+(int)(cx+ex), by+(int)(cy+ey), col); |
1160 | } |
1161 | } |
1162 | |
1163 | /* |
1164 | * Draw the box in the middle. We do this in blue if the tile |
1165 | * is an unpowered endpoint, in cyan if the tile is a powered |
1166 | * endpoint, in black if the tile is the centrepiece, and |
1167 | * otherwise not at all. |
1168 | */ |
1169 | col = -1; |
1170 | if (x == state->cx && y == state->cy) |
1171 | col = COL_WIRE; |
1172 | else if (COUNT(tile) == 1) { |
1173 | col = (tile & ACTIVE ? COL_POWERED : COL_ENDPOINT); |
1174 | } |
1175 | if (col >= 0) { |
1176 | int i, points[8]; |
1177 | |
1178 | points[0] = +1; points[1] = +1; |
1179 | points[2] = +1; points[3] = -1; |
1180 | points[4] = -1; points[5] = -1; |
1181 | points[6] = -1; points[7] = +1; |
1182 | |
1183 | for (i = 0; i < 8; i += 2) { |
1184 | ex = (TILE_SIZE * 0.24F) * points[i]; |
1185 | ey = (TILE_SIZE * 0.24F) * points[i+1]; |
1186 | points[i] = bx+(int)(cx+ex); |
1187 | points[i+1] = by+(int)(cy+ey); |
1188 | } |
1189 | |
1190 | draw_polygon(fe, points, 4, TRUE, col); |
1191 | draw_polygon(fe, points, 4, FALSE, COL_WIRE); |
1192 | } |
1193 | |
1194 | /* |
1195 | * Draw the points on the border if other tiles are connected |
1196 | * to us. |
1197 | */ |
1198 | for (dir = 1; dir < 0x10; dir <<= 1) { |
1199 | int dx, dy, px, py, lx, ly, vx, vy, ox, oy; |
1200 | |
1201 | dx = X(dir); |
1202 | dy = Y(dir); |
1203 | |
1204 | ox = x + dx; |
1205 | oy = y + dy; |
1206 | |
1207 | if (ox < 0 || ox >= state->width || oy < 0 || oy >= state->height) |
1208 | continue; |
1209 | |
1210 | if (!(tile(state, ox, oy) & F(dir))) |
1211 | continue; |
1212 | |
1213 | px = bx + (int)(dx>0 ? TILE_SIZE + TILE_BORDER - 1 : dx<0 ? 0 : cx); |
1214 | py = by + (int)(dy>0 ? TILE_SIZE + TILE_BORDER - 1 : dy<0 ? 0 : cy); |
1215 | lx = dx * (TILE_BORDER-1); |
1216 | ly = dy * (TILE_BORDER-1); |
1217 | vx = (dy ? 1 : 0); |
1218 | vy = (dx ? 1 : 0); |
1219 | |
1220 | if (xshift == 0.0 && yshift == 0.0 && (tile & dir)) { |
1221 | /* |
1222 | * If we are fully connected to the other tile, we must |
1223 | * draw right across the tile border. (We can use our |
1224 | * own ACTIVE state to determine what colour to do this |
1225 | * in: if we are fully connected to the other tile then |
1226 | * the two ACTIVE states will be the same.) |
1227 | */ |
1228 | draw_rect_coords(fe, px-vx, py-vy, px+lx+vx, py+ly+vy, COL_WIRE); |
1229 | draw_rect_coords(fe, px, py, px+lx, py+ly, |
1230 | (tile & ACTIVE) ? COL_POWERED : COL_WIRE); |
1231 | } else { |
1232 | /* |
1233 | * The other tile extends into our border, but isn't |
1234 | * actually connected to us. Just draw a single black |
1235 | * dot. |
1236 | */ |
1237 | draw_rect_coords(fe, px, py, px, py, COL_WIRE); |
1238 | } |
1239 | } |
1240 | |
1241 | draw_update(fe, bx, by, TILE_SIZE+TILE_BORDER, TILE_SIZE+TILE_BORDER); |
1242 | } |
1243 | |
1244 | static void draw_tile_barriers(frontend *fe, game_state *state, int x, int y) |
1245 | { |
1246 | int phase; |
1247 | int dir; |
1248 | int bx = BORDER + WINDOW_OFFSET + TILE_SIZE * x; |
1249 | int by = BORDER + WINDOW_OFFSET + TILE_SIZE * y; |
1250 | /* |
1251 | * Draw barrier corners, and then barriers. |
1252 | */ |
1253 | for (phase = 0; phase < 2; phase++) { |
1254 | for (dir = 1; dir < 0x10; dir <<= 1) |
1255 | if (barrier(state, x, y) & (dir << 4)) |
1256 | draw_barrier_corner(fe, x, y, dir << 4, phase); |
1257 | for (dir = 1; dir < 0x10; dir <<= 1) |
1258 | if (barrier(state, x, y) & dir) |
1259 | draw_barrier(fe, x, y, dir, phase); |
1260 | } |
1261 | |
1262 | draw_update(fe, bx, by, TILE_SIZE+TILE_BORDER, TILE_SIZE+TILE_BORDER); |
1263 | } |
1264 | |
1265 | static void draw_arrow(frontend *fe, int x, int y, int xdx, int xdy) |
1266 | { |
1267 | int coords[14]; |
1268 | int ydy = -xdx, ydx = xdy; |
1269 | |
1270 | x = x * TILE_SIZE + BORDER + WINDOW_OFFSET; |
1271 | y = y * TILE_SIZE + BORDER + WINDOW_OFFSET; |
1272 | |
1273 | #define POINT(n, xx, yy) ( \ |
1274 | coords[2*(n)+0] = x + (xx)*xdx + (yy)*ydx, \ |
1275 | coords[2*(n)+1] = y + (xx)*xdy + (yy)*ydy) |
1276 | |
1277 | POINT(0, TILE_SIZE / 2, 3 * TILE_SIZE / 4); /* top of arrow */ |
1278 | POINT(1, 3 * TILE_SIZE / 4, TILE_SIZE / 2); /* right corner */ |
1279 | POINT(2, 5 * TILE_SIZE / 8, TILE_SIZE / 2); /* right concave */ |
1280 | POINT(3, 5 * TILE_SIZE / 8, TILE_SIZE / 4); /* bottom right */ |
1281 | POINT(4, 3 * TILE_SIZE / 8, TILE_SIZE / 4); /* bottom left */ |
1282 | POINT(5, 3 * TILE_SIZE / 8, TILE_SIZE / 2); /* left concave */ |
1283 | POINT(6, TILE_SIZE / 4, TILE_SIZE / 2); /* left corner */ |
1284 | |
1285 | draw_polygon(fe, coords, 7, TRUE, COL_LOWLIGHT); |
1286 | draw_polygon(fe, coords, 7, FALSE, COL_TEXT); |
1287 | } |
1288 | |
1289 | void game_redraw(frontend *fe, game_drawstate *ds, game_state *oldstate, |
c822de4a |
1290 | game_state *state, int dir, game_ui *ui, float t, float ft) |
7bed19e1 |
1291 | { |
1292 | int x, y, tx, ty, frame; |
1293 | unsigned char *active; |
1294 | float xshift = 0.0; |
1295 | float yshift = 0.0; |
1296 | |
1297 | /* |
1298 | * Clear the screen and draw the exterior barrier lines if this |
1299 | * is our first call. |
1300 | */ |
1301 | if (!ds->started) { |
1302 | int phase; |
1303 | |
1304 | ds->started = TRUE; |
1305 | |
1306 | draw_rect(fe, 0, 0, |
1307 | BORDER * 2 + WINDOW_OFFSET * 2 + TILE_SIZE * state->width + TILE_BORDER, |
1308 | BORDER * 2 + WINDOW_OFFSET * 2 + TILE_SIZE * state->height + TILE_BORDER, |
1309 | COL_BACKGROUND); |
1310 | draw_update(fe, 0, 0, |
1311 | BORDER * 2 + WINDOW_OFFSET*2 + TILE_SIZE*state->width + TILE_BORDER, |
1312 | BORDER * 2 + WINDOW_OFFSET*2 + TILE_SIZE*state->height + TILE_BORDER); |
1313 | |
1314 | for (phase = 0; phase < 2; phase++) { |
1315 | |
1316 | for (x = 0; x < ds->width; x++) { |
1317 | if (barrier(state, x, 0) & UL) |
1318 | draw_barrier_corner(fe, x, -1, LD, phase); |
1319 | if (barrier(state, x, 0) & RU) |
1320 | draw_barrier_corner(fe, x, -1, DR, phase); |
1321 | if (barrier(state, x, 0) & U) |
1322 | draw_barrier(fe, x, -1, D, phase); |
1323 | if (barrier(state, x, ds->height-1) & DR) |
1324 | draw_barrier_corner(fe, x, ds->height, RU, phase); |
1325 | if (barrier(state, x, ds->height-1) & LD) |
1326 | draw_barrier_corner(fe, x, ds->height, UL, phase); |
1327 | if (barrier(state, x, ds->height-1) & D) |
1328 | draw_barrier(fe, x, ds->height, U, phase); |
1329 | } |
1330 | |
1331 | for (y = 0; y < ds->height; y++) { |
1332 | if (barrier(state, 0, y) & UL) |
1333 | draw_barrier_corner(fe, -1, y, RU, phase); |
1334 | if (barrier(state, 0, y) & LD) |
1335 | draw_barrier_corner(fe, -1, y, DR, phase); |
1336 | if (barrier(state, 0, y) & L) |
1337 | draw_barrier(fe, -1, y, R, phase); |
1338 | if (barrier(state, ds->width-1, y) & RU) |
1339 | draw_barrier_corner(fe, ds->width, y, UL, phase); |
1340 | if (barrier(state, ds->width-1, y) & DR) |
1341 | draw_barrier_corner(fe, ds->width, y, LD, phase); |
1342 | if (barrier(state, ds->width-1, y) & R) |
1343 | draw_barrier(fe, ds->width, y, L, phase); |
1344 | } |
1345 | } |
1346 | |
1347 | /* |
1348 | * Arrows for making moves. |
1349 | */ |
1350 | for (x = 0; x < ds->width; x++) { |
1351 | if (x == state->cx) continue; |
1352 | draw_arrow(fe, x, 0, +1, 0); |
1353 | draw_arrow(fe, x+1, ds->height, -1, 0); |
1354 | } |
1355 | for (y = 0; y < ds->height; y++) { |
1356 | if (y == state->cy) continue; |
1357 | draw_arrow(fe, ds->width, y, 0, +1); |
1358 | draw_arrow(fe, 0, y+1, 0, -1); |
1359 | } |
1360 | } |
1361 | |
1362 | /* Check if this is an undo. If so, we will need to run any animation |
1363 | * backwards. |
1364 | */ |
1365 | if (oldstate && oldstate->move_count > state->move_count) { |
1366 | game_state * tmpstate = state; |
1367 | state = oldstate; |
1368 | oldstate = tmpstate; |
1369 | t = ANIM_TIME - t; |
1370 | } |
1371 | |
1372 | tx = ty = -1; |
1373 | if (oldstate && (t < ANIM_TIME)) { |
1374 | /* |
1375 | * We're animating a slide, of row/column number |
1376 | * state->last_move_pos, in direction |
1377 | * state->last_move_dir |
1378 | */ |
1379 | xshift = state->last_move_row == -1 ? 0.0 : |
1380 | (1 - t / ANIM_TIME) * state->last_move_dir; |
1381 | yshift = state->last_move_col == -1 ? 0.0 : |
1382 | (1 - t / ANIM_TIME) * state->last_move_dir; |
1383 | } |
1384 | |
1385 | frame = -1; |
1386 | if (ft > 0) { |
1387 | /* |
1388 | * We're animating a completion flash. Find which frame |
1389 | * we're at. |
1390 | */ |
1391 | frame = (int)(ft / FLASH_FRAME); |
1392 | } |
1393 | |
1394 | /* |
1395 | * Draw any tile which differs from the way it was last drawn. |
1396 | */ |
1397 | if (xshift != 0.0 || yshift != 0.0) { |
1398 | active = compute_active(state, |
1399 | state->last_move_row, state->last_move_col); |
1400 | } else { |
1401 | active = compute_active(state, -1, -1); |
1402 | } |
1403 | |
1404 | clip(fe, |
1405 | BORDER + WINDOW_OFFSET, BORDER + WINDOW_OFFSET, |
1406 | TILE_SIZE * state->width + TILE_BORDER, |
1407 | TILE_SIZE * state->height + TILE_BORDER); |
1408 | |
1409 | for (x = 0; x < ds->width; x++) |
1410 | for (y = 0; y < ds->height; y++) { |
1411 | unsigned char c = tile(state, x, y) | index(state, active, x, y); |
1412 | |
1413 | /* |
1414 | * In a completion flash, we adjust the FLASHING bit |
1415 | * depending on our distance from the centre point and |
1416 | * the frame number. |
1417 | */ |
1418 | if (frame >= 0) { |
1419 | int xdist, ydist, dist; |
1420 | xdist = (x < state->cx ? state->cx - x : x - state->cx); |
1421 | ydist = (y < state->cy ? state->cy - y : y - state->cy); |
1422 | dist = (xdist > ydist ? xdist : ydist); |
1423 | |
1424 | if (frame >= dist && frame < dist+4) { |
1425 | int flash = (frame - dist) & 1; |
1426 | flash = flash ? FLASHING : 0; |
1427 | c = (c &~ FLASHING) | flash; |
1428 | } |
1429 | } |
1430 | |
1431 | if (index(state, ds->visible, x, y) != c || |
1432 | index(state, ds->visible, x, y) == 0xFF || |
1433 | (x == state->last_move_col || y == state->last_move_row)) |
1434 | { |
1435 | float xs = (y == state->last_move_row ? xshift : 0.0); |
1436 | float ys = (x == state->last_move_col ? yshift : 0.0); |
1437 | |
1438 | draw_tile(fe, state, x, y, c, xs, ys); |
1439 | if (xs < 0 && x == 0) |
1440 | draw_tile(fe, state, state->width, y, c, xs, ys); |
1441 | else if (xs > 0 && x == state->width - 1) |
1442 | draw_tile(fe, state, -1, y, c, xs, ys); |
1443 | else if (ys < 0 && y == 0) |
1444 | draw_tile(fe, state, x, state->height, c, xs, ys); |
1445 | else if (ys > 0 && y == state->height - 1) |
1446 | draw_tile(fe, state, x, -1, c, xs, ys); |
1447 | |
1448 | if (x == state->last_move_col || y == state->last_move_row) |
1449 | index(state, ds->visible, x, y) = 0xFF; |
1450 | else |
1451 | index(state, ds->visible, x, y) = c; |
1452 | } |
1453 | } |
1454 | |
1455 | for (x = 0; x < ds->width; x++) |
1456 | for (y = 0; y < ds->height; y++) |
1457 | draw_tile_barriers(fe, state, x, y); |
1458 | |
1459 | unclip(fe); |
1460 | |
1461 | /* |
1462 | * Update the status bar. |
1463 | */ |
1464 | { |
1465 | char statusbuf[256]; |
1466 | int i, n, a; |
1467 | |
1468 | n = state->width * state->height; |
1469 | for (i = a = 0; i < n; i++) |
1470 | if (active[i]) |
1471 | a++; |
1472 | |
1473 | sprintf(statusbuf, "%sMoves: %d Active: %d/%d", |
1474 | (state->completed ? "COMPLETED! " : ""), |
1475 | (state->completed ? state->completed : state->move_count), |
1476 | a, n); |
1477 | |
1478 | status_bar(fe, statusbuf); |
1479 | } |
1480 | |
1481 | sfree(active); |
1482 | } |
1483 | |
c822de4a |
1484 | float game_anim_length(game_state *oldstate, game_state *newstate, int dir) |
7bed19e1 |
1485 | { |
1486 | return ANIM_TIME; |
1487 | } |
1488 | |
c822de4a |
1489 | float game_flash_length(game_state *oldstate, game_state *newstate, int dir) |
7bed19e1 |
1490 | { |
1491 | /* |
1492 | * If the game has just been completed, we display a completion |
1493 | * flash. |
1494 | */ |
1495 | if (!oldstate->completed && newstate->completed) { |
1496 | int size; |
1497 | size = 0; |
1498 | if (size < newstate->cx+1) |
1499 | size = newstate->cx+1; |
1500 | if (size < newstate->cy+1) |
1501 | size = newstate->cy+1; |
1502 | if (size < newstate->width - newstate->cx) |
1503 | size = newstate->width - newstate->cx; |
1504 | if (size < newstate->height - newstate->cy) |
1505 | size = newstate->height - newstate->cy; |
1506 | return FLASH_FRAME * (size+4); |
1507 | } |
1508 | |
1509 | return 0.0F; |
1510 | } |
1511 | |
1512 | int game_wants_statusbar(void) |
1513 | { |
1514 | return TRUE; |
1515 | } |