]> git.saurik.com Git - wxWidgets.git/blob - demos/life/game.cpp
Fixes to allow compilation with no wchar_t (djgpp probably has a real wchar_t
[wxWidgets.git] / demos / life / game.cpp
1 /////////////////////////////////////////////////////////////////////////////
2 // Name: game.cpp
3 // Purpose: Life! game logic
4 // Author: Guillermo Rodriguez Garcia, <guille@iies.es>
5 // Modified by:
6 // Created: Jan/2000
7 // RCS-ID: $Id$
8 // Copyright: (c) 2000, Guillermo Rodriguez Garcia
9 // Licence: wxWindows licence
10 /////////////////////////////////////////////////////////////////////////////
11
12 // ==========================================================================
13 // headers, declarations, constants
14 // ==========================================================================
15
16 #ifdef __GNUG__
17 #pragma implementation "game.h"
18 #endif
19
20 // For compilers that support precompilation, includes "wx/wx.h".
21 #include "wx/wxprec.h"
22
23 #ifdef __BORLANDC__
24 #pragma hdrstop
25 #endif
26
27 #ifndef WX_PRECOMP
28 #include "wx/wx.h"
29 #endif
30
31 #include "wx/log.h"
32 #include "wx/module.h"
33 #include "game.h"
34
35 #include <string.h> // for memset
36
37
38 #define ARRAYSIZE 1024 // static array for BeginFind & co.
39 #define ALLOCBOXES 16 // number of cellboxes to alloc at once
40 #define MAXDEAD 8 // tics before removing cellbox from list
41
42
43 // ==========================================================================
44 // CellBox
45 // ==========================================================================
46
47 #define HASH(x, y) (((x >> 3) & 0x7f) << 7) + ((y >> 3) & 0x7f)
48
49 #define HASHSIZE 16384 // hash table size (do not change!)
50 #define CELLBOX 8 // cells in a cellbox (do not change!)
51
52
53 class LifeCellBox
54 {
55 public:
56 // members
57 inline bool IsAlive(int dx, int dy) const;
58 inline bool SetCell(int dx, int dy, bool alive);
59
60 // attributes
61 wxInt32 m_x, m_y; // position in universe
62 wxUint32 m_live1, m_live2; // alive cells (1 bit per cell)
63 wxUint32 m_old1, m_old2; // old values for m_live1, 2
64 wxUint32 m_on[8]; // neighbouring info
65 wxUint32 m_dead; // been dead for n generations
66 LifeCellBox *m_up, *m_dn, *m_lf, *m_rt; // neighbour CellBoxes
67 LifeCellBox *m_prev, *m_next; // in linked list
68 LifeCellBox *m_hprev, *m_hnext; // in hash table
69 };
70
71
72 // IsAlive:
73 // Returns whether cell dx, dy in this box is alive
74 //
75 bool LifeCellBox::IsAlive(int dx, int dy) const
76 {
77 if (dy > 3)
78 return (m_live2 & 1 << ((dy - 4) * 8 + dx)) ? true : false ;
79 else
80 return (m_live1 & 1 << ((dy) * 8 + dx)) ? true : false ;
81 }
82
83 // SetCell:
84 // Sets cell dx, dy in this box to 'alive', returns true if
85 // the previous value was different, false if it was the same.
86 //
87 bool LifeCellBox::SetCell(int dx, int dy, bool alive)
88 {
89 if (IsAlive(dx, dy) != alive)
90 {
91 if (dy > 3)
92 m_live2 ^= 1 << ((dy - 4) * 8 + dx);
93 else
94 m_live1 ^= 1 << ((dy) * 8 + dx);
95
96 // reset this here to avoid updating problems
97 m_dead = 0;
98
99 return true;
100 }
101 else
102 return false;
103 }
104
105
106 // ==========================================================================
107 // Life
108 // ==========================================================================
109
110 // --------------------------------------------------------------------------
111 // Ctor and dtor
112 // --------------------------------------------------------------------------
113
114 Life::Life()
115 {
116 // pattern description
117 m_name = wxEmptyString;
118 m_rules = wxEmptyString;
119 m_description = wxEmptyString;
120
121 // pattern data
122 m_numcells = 0;
123 m_boxes = new LifeCellBox *[HASHSIZE];
124 m_head = NULL;
125 m_available = NULL;
126 for (int i = 0; i < HASHSIZE; i++)
127 m_boxes[i] = NULL;
128
129 // state vars for BeginFind & FindMore
130 m_cells = new LifeCell[ARRAYSIZE];
131 m_ncells = 0;
132 m_findmore = false;
133 m_changed = false;
134 }
135
136 Life::~Life()
137 {
138 Clear();
139
140 delete[] m_boxes;
141 delete[] m_cells;
142 }
143
144 // Clear:
145 // Clears the board, freeing all storage.
146 //
147 void Life::Clear()
148 {
149 LifeCellBox *c, *nc;
150
151 // clear the hash table pointers
152 for (int i = 0; i < HASHSIZE; i++)
153 m_boxes[i] = NULL;
154
155 // free used boxes
156 c = m_head;
157 while (c)
158 {
159 nc = c->m_next;
160 delete c;
161 c = nc;
162 }
163 m_head = NULL;
164
165 // free available boxes
166 c = m_available;
167 while (c)
168 {
169 nc = c->m_next;
170 delete c;
171 c = nc;
172 }
173 m_available = NULL;
174
175 // reset state
176 m_name = wxEmptyString;
177 m_rules = wxEmptyString;
178 m_description = wxEmptyString;
179 m_numcells = 0;
180 }
181
182 // --------------------------------------------------------------------------
183 // Test and set individual cells
184 // --------------------------------------------------------------------------
185
186 // IsAlive:
187 // Returns whether cell (x, y) is alive.
188 //
189 bool Life::IsAlive(wxInt32 x, wxInt32 y)
190 {
191 LifeCellBox *c = LinkBox(x, y, false);
192
193 return (c && c->IsAlive( x - c->m_x, y - c->m_y ));
194 }
195
196 // SetCell:
197 // Sets or clears cell (x, y), according to the 'alive' param.
198 //
199 void Life::SetCell(wxInt32 x, wxInt32 y, bool alive)
200 {
201 LifeCellBox *c = LinkBox(x, y);
202 wxUint32 dx = x - c->m_x;
203 wxUint32 dy = y - c->m_y;
204
205 if (c->SetCell(dx, dy, alive))
206 {
207 if (alive)
208 m_numcells++;
209 else
210 m_numcells--;
211 }
212 }
213
214 void Life::SetPattern(const LifePattern& pattern)
215 {
216 wxArrayString data = pattern.m_shape;
217 wxString line;
218 long x = 0,
219 y = 0;
220
221 Clear();
222 for (size_t n = 0; n < data.GetCount(); n++)
223 {
224 line = data[n];
225
226 if ( (line.GetChar(0) != wxT('*')) &&
227 (line.GetChar(0) != wxT('.')) )
228 {
229 // assume that it is a digit or a minus sign
230 line.BeforeFirst(wxT(' ')).ToLong(&x);
231 line.AfterFirst(wxT(' ')).ToLong(&y);
232 }
233 else
234 {
235 // pattern data
236 for (size_t k = 0; k < line.Len(); k++)
237 SetCell(x + k, y, line.GetChar(k) == wxT('*'));
238
239 y++;
240 }
241 }
242
243 m_name = pattern.m_name;
244 m_rules = pattern.m_rules;
245 m_description = pattern.m_description;
246 }
247
248 // --------------------------------------------------------------------------
249 // Cellbox management functions
250 // --------------------------------------------------------------------------
251
252 // CreateBox:
253 // Creates a box in x, y, either taking it from the list
254 // of available boxes, or allocating a new one.
255 //
256 LifeCellBox* Life::CreateBox(wxInt32 x, wxInt32 y, wxUint32 hv)
257 {
258 LifeCellBox *c;
259
260 // if there are no available boxes, alloc a few more
261 if (!m_available)
262 for (int i = 1; i <= ALLOCBOXES; i++)
263 {
264 c = new LifeCellBox();
265
266 if (!c)
267 {
268 // TODO: handle memory errors. Note that right now, if we
269 // couldn't allocate at least one cellbox, we will crash
270 // before leaving CreateBox(). Probably we should try to
271 // allocate some boxes *before* the m_available list goes
272 // empty, so that we have a margin to handle errors
273 // gracefully.
274 wxLogFatalError(_("Out of memory! Aborting..."));
275
276 // NOTREACHED
277 }
278
279 c->m_next = m_available;
280 m_available = c;
281 }
282
283 // take a cellbox from the list of available boxes
284 c = m_available;
285 m_available = c->m_next;
286
287 // reset everything
288 memset((void *) c, 0, sizeof(LifeCellBox));
289 c->m_x = x;
290 c->m_y = y;
291
292 // insert c in the list
293 c->m_next = m_head;
294 m_head = c;
295 if (c->m_next) c->m_next->m_prev = c;
296
297 // insert c in the hash table
298 c->m_hnext = m_boxes[hv];
299 m_boxes[hv] = c;
300 if (c->m_hnext) c->m_hnext->m_hprev = c;
301
302 return c;
303 }
304
305 // LinkBox:
306 // Returns a pointer to the box (x, y); if it didn't exist yet,
307 // it returns NULL or creates a new one, depending on the value
308 // of the 'create' parameter.
309 //
310 LifeCellBox* Life::LinkBox(wxInt32 x, wxInt32 y, bool create)
311 {
312 wxUint32 hv;
313 LifeCellBox *c;
314
315 x &= 0xfffffff8;
316 y &= 0xfffffff8;
317 hv = HASH(x, y);
318
319 // search in the hash table
320 for (c = m_boxes[hv]; c; c = c->m_hnext)
321 if ((c->m_x == x) && (c->m_y == y)) return c;
322
323 // if not found, and (create == true), create a new one
324 return create? CreateBox(x, y, hv) : (LifeCellBox*) NULL;
325 }
326
327 // KillBox:
328 // Removes this box from the list and the hash table and
329 // puts it in the list of available boxes.
330 //
331 void Life::KillBox(LifeCellBox *c)
332 {
333 wxUint32 hv = HASH(c->m_x, c->m_y);
334
335 // remove from the list
336 if (c != m_head)
337 c->m_prev->m_next = c->m_next;
338 else
339 m_head = c->m_next;
340
341 // remove from the hash table
342 if (c != m_boxes[hv])
343 c->m_hprev->m_hnext = c->m_hnext;
344 else
345 m_boxes[hv] = c->m_hnext;
346
347 // update neighbours
348 if (c->m_next) c->m_next->m_prev = c->m_prev;
349 if (c->m_hnext) c->m_hnext->m_hprev = c->m_hprev;
350 if (c->m_up) c->m_up->m_dn = NULL;
351 if (c->m_dn) c->m_dn->m_up = NULL;
352 if (c->m_lf) c->m_lf->m_rt = NULL;
353 if (c->m_rt) c->m_rt->m_lf = NULL;
354
355 // append to the list of available boxes
356 c->m_next = m_available;
357 m_available = c;
358 }
359
360 // --------------------------------------------------------------------------
361 // Navigation
362 // --------------------------------------------------------------------------
363
364 LifeCell Life::FindCenter()
365 {
366 double sx, sy;
367 int n;
368 sx = 0.0;
369 sy = 0.0;
370 n = 0;
371
372 LifeCellBox *c;
373 for (c = m_head; c; c = c->m_next)
374 if (!c->m_dead)
375 {
376 sx += c->m_x;
377 sy += c->m_y;
378 n++;
379 }
380
381 if (n > 0)
382 {
383 sx = (sx / n) + CELLBOX / 2;
384 sy = (sy / n) + CELLBOX / 2;
385 }
386
387 LifeCell cell;
388 cell.i = (wxInt32) sx;
389 cell.j = (wxInt32) sy;
390 return cell;
391 }
392
393 LifeCell Life::FindNorth()
394 {
395 wxInt32 x = 0, y = 0;
396 bool first = true;
397
398 LifeCellBox *c;
399 for (c = m_head; c; c = c->m_next)
400 if (!c->m_dead && ((first) || (c->m_y < y)))
401 {
402 x = c->m_x;
403 y = c->m_y;
404 first = false;
405 }
406
407 LifeCell cell;
408 cell.i = first? 0 : x + CELLBOX / 2;
409 cell.j = first? 0 : y + CELLBOX / 2;
410 return cell;
411 }
412
413 LifeCell Life::FindSouth()
414 {
415 wxInt32 x = 0, y = 0;
416 bool first = true;
417
418 LifeCellBox *c;
419 for (c = m_head; c; c = c->m_next)
420 if (!c->m_dead && ((first) || (c->m_y > y)))
421 {
422 x = c->m_x;
423 y = c->m_y;
424 first = false;
425 }
426
427 LifeCell cell;
428 cell.i = first? 0 : x + CELLBOX / 2;
429 cell.j = first? 0 : y + CELLBOX / 2;
430 return cell;
431 }
432
433 LifeCell Life::FindWest()
434 {
435 wxInt32 x = 0, y = 0;
436 bool first = true;
437
438 LifeCellBox *c;
439 for (c = m_head; c; c = c->m_next)
440 if (!c->m_dead && ((first) || (c->m_x < x)))
441 {
442 x = c->m_x;
443 y = c->m_y;
444 first = false;
445 }
446
447 LifeCell cell;
448 cell.i = first? 0 : x + CELLBOX / 2;
449 cell.j = first? 0 : y + CELLBOX / 2;
450 return cell;
451 }
452
453 LifeCell Life::FindEast()
454 {
455 wxInt32 x = 0, y = 0;
456 bool first = true;
457
458 LifeCellBox *c;
459 for (c = m_head; c; c = c->m_next)
460 if (!c->m_dead && ((first) || (c->m_x > x)))
461 {
462 x = c->m_x;
463 y = c->m_y;
464 first = false;
465 }
466
467 LifeCell cell;
468 cell.i = first? 0 : x + CELLBOX / 2;
469 cell.j = first? 0 : y + CELLBOX / 2;
470 return cell;
471 }
472
473 // --------------------------------------------------------------------------
474 // FindMore & co.
475 // --------------------------------------------------------------------------
476
477 // DoLine:
478 // Post eight cells to the cell arrays - leave out the fourth
479 // argument (or pass 0, the default value) to post alive cells
480 // only, else it will post cells which have changed.
481 //
482 void Life::DoLine(wxInt32 x, wxInt32 y, wxUint32 live, wxUint32 old)
483 {
484 wxUint32 diff = (live ^ old) & 0xff;
485
486 if (!diff) return;
487
488 for (wxInt32 k = 8; k; k--, x++)
489 {
490 if (diff & 0x01)
491 {
492 m_cells[m_ncells].i = x;
493 m_cells[m_ncells].j = y;
494 m_ncells++;
495 }
496 diff >>= 1;
497 }
498 }
499
500 void Life::BeginFind(wxInt32 x0, wxInt32 y0, wxInt32 x1, wxInt32 y1, bool changed)
501 {
502 // TODO: optimize for the case where the maximum number of
503 // cellboxes that fit in the specified viewport is smaller
504 // than the current total of boxes; iterating over the list
505 // should then be faster than searching in the hash table.
506
507 m_x0 = m_x = x0 & 0xfffffff8;
508 m_y0 = m_y = y0 & 0xfffffff8;
509 m_x1 = (x1 + 7) & 0xfffffff8;
510 m_y1 = (y1 + 7) & 0xfffffff8;
511
512 m_findmore = true;
513 m_changed = changed;
514 }
515
516 bool Life::FindMore(LifeCell *cells[], size_t *ncells)
517 {
518 LifeCellBox *c;
519 *cells = m_cells;
520 m_ncells = 0;
521
522 if (m_changed)
523 {
524 for ( ; m_y <= m_y1; m_y += 8, m_x = m_x0)
525 for ( ; m_x <= m_x1; m_x += 8)
526 {
527 if ((c = LinkBox(m_x, m_y, false)) == NULL)
528 continue;
529
530 // check whether there is enough space left in the array
531 if (m_ncells > (ARRAYSIZE - 64))
532 {
533 *ncells = m_ncells;
534 return false;
535 }
536
537 DoLine(m_x, m_y , c->m_live1, c->m_old1 );
538 DoLine(m_x, m_y + 1, c->m_live1 >> 8, c->m_old1 >> 8 );
539 DoLine(m_x, m_y + 2, c->m_live1 >> 16, c->m_old1 >> 16);
540 DoLine(m_x, m_y + 3, c->m_live1 >> 24, c->m_old1 >> 24);
541 DoLine(m_x, m_y + 4, c->m_live2, c->m_old2 );
542 DoLine(m_x, m_y + 5, c->m_live2 >> 8, c->m_old2 >> 8 );
543 DoLine(m_x, m_y + 6, c->m_live2 >> 16, c->m_old2 >> 16);
544 DoLine(m_x, m_y + 7, c->m_live2 >> 24, c->m_old2 >> 24);
545 }
546 }
547 else
548 {
549 for ( ; m_y <= m_y1; m_y += 8, m_x = m_x0)
550 for ( ; m_x <= m_x1; m_x += 8)
551 {
552 if ((c = LinkBox(m_x, m_y, false)) == NULL)
553 continue;
554
555 // check whether there is enough space left in the array
556 if (m_ncells > (ARRAYSIZE - 64))
557 {
558 *ncells = m_ncells;
559 return false;
560 }
561
562 DoLine(m_x, m_y , c->m_live1 );
563 DoLine(m_x, m_y + 1, c->m_live1 >> 8 );
564 DoLine(m_x, m_y + 2, c->m_live1 >> 16);
565 DoLine(m_x, m_y + 3, c->m_live1 >> 24);
566 DoLine(m_x, m_y + 4, c->m_live2 );
567 DoLine(m_x, m_y + 5, c->m_live2 >> 8 );
568 DoLine(m_x, m_y + 6, c->m_live2 >> 16);
569 DoLine(m_x, m_y + 7, c->m_live2 >> 24);
570 }
571 }
572
573 *ncells = m_ncells;
574 m_findmore = false;
575 return true;
576 }
577
578 // --------------------------------------------------------------------------
579 // Evolution engine
580 // --------------------------------------------------------------------------
581
582 extern unsigned char *g_tab;
583 extern int g_tab1[];
584 extern int g_tab2[];
585
586 // NextTic:
587 // Advance one step in evolution :-)
588 //
589 bool Life::NextTic()
590 {
591 LifeCellBox *c, *up, *dn, *lf, *rt;
592 wxUint32 t1, t2, t3, t4;
593 bool changed = false;
594
595 m_numcells = 0;
596
597 // Stage 1:
598 // Compute neighbours of each cell
599 //
600 // WARNING: unrolled loops and lengthy code follows!
601 //
602 c = m_head;
603
604 while (c)
605 {
606 if (! (c->m_live1 || c->m_live2))
607 {
608 c = c->m_next;
609 continue;
610 }
611 up = c->m_up;
612 dn = c->m_dn;
613 lf = c->m_lf;
614 rt = c->m_rt;
615
616 // up
617 t1 = c->m_live1 & 0x000000ff;
618 if (t1)
619 {
620 if (!up)
621 {
622 up = LinkBox(c->m_x, c->m_y - 8);
623 up->m_dn = c;
624 }
625 t2 = g_tab1[t1];
626 up->m_on[7] += t2;
627 c->m_on[1] += t2;
628 c->m_on[0] += g_tab2[t1];
629 }
630
631 // down
632 t1 = (c->m_live2 & 0xff000000) >> 24;
633 if (t1)
634 {
635 if (!dn)
636 {
637 dn = LinkBox(c->m_x, c->m_y + 8);
638 dn->m_up = c;
639 }
640 t2 = g_tab1[t1];
641 dn->m_on[0] += t2;
642 c->m_on[6] += t2;
643 c->m_on[7] += g_tab2[t1];
644 }
645
646 t1 = c->m_live1;
647 t2 = c->m_live2;
648
649 // left
650 if (t1 & 0x01010101)
651 {
652 if (!lf)
653 {
654 lf = LinkBox(c->m_x - 8, c->m_y);
655 lf->m_rt = c;
656 }
657 if (t1 & 0x00000001)
658 {
659 if (!lf->m_up)
660 {
661 lf->m_up = LinkBox(c->m_x - 8, c->m_y - 8);
662 lf->m_up->m_dn = lf;
663 }
664 lf->m_up->m_on[7] += 0x10000000;
665 lf->m_on[0] += 0x10000000;
666 lf->m_on[1] += 0x10000000;
667 }
668 if (t1 & 0x00000100)
669 {
670 lf->m_on[0] += 0x10000000;
671 lf->m_on[1] += 0x10000000;
672 lf->m_on[2] += 0x10000000;
673 }
674 if (t1 & 0x00010000)
675 {
676 lf->m_on[1] += 0x10000000;
677 lf->m_on[2] += 0x10000000;
678 lf->m_on[3] += 0x10000000;
679 }
680 if (t1 & 0x01000000)
681 {
682 lf->m_on[2] += 0x10000000;
683 lf->m_on[3] += 0x10000000;
684 lf->m_on[4] += 0x10000000;
685 }
686 }
687 if (t2 & 0x01010101)
688 {
689 if (!lf)
690 {
691 lf = LinkBox(c->m_x - 8, c->m_y);
692 lf->m_rt = c;
693 }
694 if (t2 & 0x00000001)
695 {
696 lf->m_on[3] += 0x10000000;
697 lf->m_on[4] += 0x10000000;
698 lf->m_on[5] += 0x10000000;
699 }
700 if (t2 & 0x00000100)
701 {
702 lf->m_on[4] += 0x10000000;
703 lf->m_on[5] += 0x10000000;
704 lf->m_on[6] += 0x10000000;
705 }
706 if (t2 & 0x00010000)
707 {
708 lf->m_on[5] += 0x10000000;
709 lf->m_on[6] += 0x10000000;
710 lf->m_on[7] += 0x10000000;
711 }
712 if (t2 & 0x01000000)
713 {
714 if (!lf->m_dn)
715 {
716 lf->m_dn = LinkBox(c->m_x - 8, c->m_y + 8);
717 lf->m_dn->m_up = lf;
718 }
719 lf->m_on[6] += 0x10000000;
720 lf->m_on[7] += 0x10000000;
721 lf->m_dn->m_on[0] += 0x10000000;
722 }
723 }
724
725 // right
726 if (t1 & 0x80808080)
727 {
728 if (!rt)
729 {
730 rt = LinkBox(c->m_x + 8, c->m_y);
731 rt->m_lf = c;
732 }
733 if (t1 & 0x00000080)
734 {
735 if (!rt->m_up)
736 {
737 rt->m_up = LinkBox(c->m_x + 8, c->m_y - 8);
738 rt->m_up->m_dn = rt;
739 }
740 rt->m_up->m_on[7] += 0x00000001;
741 rt->m_on[0] += 0x00000001;
742 rt->m_on[1] += 0x00000001;
743 }
744 if (t1 & 0x00008000)
745 {
746 rt->m_on[0] += 0x00000001;
747 rt->m_on[1] += 0x00000001;
748 rt->m_on[2] += 0x00000001;
749 }
750 if (t1 & 0x00800000)
751 {
752 rt->m_on[1] += 0x00000001;
753 rt->m_on[2] += 0x00000001;
754 rt->m_on[3] += 0x00000001;
755 }
756 if (t1 & 0x80000000)
757 {
758 rt->m_on[2] += 0x00000001;
759 rt->m_on[3] += 0x00000001;
760 rt->m_on[4] += 0x00000001;
761 }
762 }
763 if (t2 & 0x80808080)
764 {
765 if (!rt)
766 {
767 rt = LinkBox(c->m_x + 8, c->m_y);
768 rt->m_lf = c;
769 }
770 if (t2 & 0x00000080)
771 {
772 rt->m_on[3] += 0x00000001;
773 rt->m_on[4] += 0x00000001;
774 rt->m_on[5] += 0x00000001;
775 }
776 if (t2 & 0x00008000)
777 {
778 rt->m_on[4] += 0x00000001;
779 rt->m_on[5] += 0x00000001;
780 rt->m_on[6] += 0x00000001;
781 }
782 if (t2 & 0x00800000)
783 {
784 rt->m_on[5] += 0x00000001;
785 rt->m_on[6] += 0x00000001;
786 rt->m_on[7] += 0x00000001;
787 }
788 if (t2 & 0x80000000)
789 {
790 if (!rt->m_dn)
791 {
792 rt->m_dn = LinkBox(c->m_x + 8, c->m_y + 8);
793 rt->m_dn->m_up = rt;
794 }
795 rt->m_on[6] += 0x00000001;
796 rt->m_on[7] += 0x00000001;
797 rt->m_dn->m_on[0] += 0x00000001;
798 }
799 }
800
801 // inner cells
802 int i;
803 for (i = 1; i <= 3; i++)
804 {
805 t1 = ((c->m_live1) >> (i * 8)) & 0x000000ff;
806 if (t1)
807 {
808 c->m_on[i - 1] += g_tab1[t1];
809 c->m_on[i ] += g_tab2[t1];
810 c->m_on[i + 1] += g_tab1[t1];
811 }
812 }
813 for (i = 0; i <= 2; i++)
814 {
815 t1 = ((c->m_live2) >> (i * 8)) & 0x000000ff;
816 if (t1)
817 {
818 c->m_on[i + 3] += g_tab1[t1];
819 c->m_on[i + 4] += g_tab2[t1];
820 c->m_on[i + 5] += g_tab1[t1];
821 }
822 }
823
824 c->m_up = up;
825 c->m_dn = dn;
826 c->m_lf = lf;
827 c->m_rt = rt;
828 c = c->m_next;
829 }
830
831 // Stage 2:
832 // Stabilize
833 //
834 c = m_head;
835
836 while (c)
837 {
838 t1 = 0;
839 t2 = 0;
840
841 t3 = c->m_live1;
842 c->m_old1 = t3;
843
844 t4 = c->m_on[0];
845 t1 |= g_tab[ ((t4 & 0x0000ffff) << 4 ) + ((t3 ) & 0xf) ];
846 t1 |= g_tab[ ((t4 & 0xffff0000) >> 12) + ((t3 >> 4 ) & 0xf) ] << 4;
847 t4 = c->m_on[1];
848 t1 |= g_tab[ ((t4 & 0x0000ffff) << 4 ) + ((t3 >> 8 ) & 0xf) ] << 8;
849 t1 |= g_tab[ ((t4 & 0xffff0000) >> 12) + ((t3 >> 12) & 0xf) ] << 12;
850 t4 = c->m_on[2];
851 t1 |= g_tab[ ((t4 & 0x0000ffff) << 4 ) + ((t3 >> 16) & 0xf) ] << 16;
852 t1 |= g_tab[ ((t4 & 0xffff0000) >> 12) + ((t3 >> 20) & 0xf) ] << 20;
853 t4 = c->m_on[3];
854 t1 |= g_tab[ ((t4 & 0x0000ffff) << 4 ) + ((t3 >> 24) & 0xf) ] << 24;
855 t1 |= g_tab[ ((t4 & 0xffff0000) >> 12) + ((t3 >> 28) & 0xf) ] << 28;
856
857 t3 = c->m_live2;
858 c->m_old2 = t3;
859
860 t4 = c->m_on[4];
861 t2 |= g_tab[ ((t4 & 0x0000ffff) << 4 ) + ((t3 ) & 0xf) ];
862 t2 |= g_tab[ ((t4 & 0xffff0000) >> 12) + ((t3 >> 4 ) & 0xf) ] << 4;
863 t4 = c->m_on[5];
864 t2 |= g_tab[ ((t4 & 0x0000ffff) << 4 ) + ((t3 >> 8 ) & 0xf) ] << 8;
865 t2 |= g_tab[ ((t4 & 0xffff0000) >> 12) + ((t3 >> 12) & 0xf) ] << 12;
866 t4 = c->m_on[6];
867 t2 |= g_tab[ ((t4 & 0x0000ffff) << 4 ) + ((t3 >> 16) & 0xf) ] << 16;
868 t2 |= g_tab[ ((t4 & 0xffff0000) >> 12) + ((t3 >> 20) & 0xf) ] << 20;
869 t4 = c->m_on[7];
870 t2 |= g_tab[ ((t4 & 0x0000ffff) << 4 ) + ((t3 >> 24) & 0xf) ] << 24;
871 t2 |= g_tab[ ((t4 & 0xffff0000) >> 12) + ((t3 >> 28) & 0xf) ] << 28;
872
873 c->m_on[0] = c->m_on[1] = c->m_on[2] = c->m_on[3] =
874 c->m_on[4] = c->m_on[5] = c->m_on[6] = c->m_on[7] = 0;
875 c->m_live1 = t1;
876 c->m_live2 = t2;
877
878 // count alive cells
879 #if 1
880 wxUint32 t1_, t2_;
881
882 t1_ = (t1 & 0x55555555) + (t1 >> 1 & 0x55555555);
883 t1_ = (t1_ & 0x33333333) + (t1_ >> 2 & 0x33333333);
884
885 t2_ = (t2 & 0x55555555) + (t2 >> 1 & 0x55555555);
886 t2_ = (t2_ & 0x33333333) + (t2_ >> 2 & 0x33333333) + t1_;
887 t2_ = (t2_ & 0x0F0F0F0F) + (t2_ >> 4 & 0x0F0F0F0F);
888 t2_ = (t2_ & 0x00FF00FF) + (t2_ >> 8 & 0x00FF00FF);
889
890 m_numcells += (t2_ & 0xFF) + (t2_ >> 16 & 0xFF);
891 #else
892 // Original, slower code
893 for (int i = 0; i < 32; i++)
894 {
895 if (t1 & (1 << i)) m_numcells++;
896 if (t2 & (1 << i)) m_numcells++;
897 }
898 #endif
899
900 changed |= ((t1 ^ c->m_old1) || (t2 ^ c->m_old2));
901
902 // mark, and discard if necessary, dead boxes
903 if (t1 || t2)
904 {
905 c->m_dead = 0;
906 c = c->m_next;
907 }
908 else
909 {
910 LifeCellBox *aux = c->m_next;
911 if (c->m_dead++ > MAXDEAD)
912 KillBox(c);
913
914 c = aux;
915 }
916 }
917
918 return changed;
919 }
920
921 // ==========================================================================
922 // LifeModule
923 // ==========================================================================
924
925 // A module to pregenerate lookup tables without having to do it
926 // from the application.
927
928 class LifeModule: public wxModule
929 {
930 DECLARE_DYNAMIC_CLASS(LifeModule)
931
932 public:
933 LifeModule() {};
934 bool OnInit();
935 void OnExit();
936 };
937
938 IMPLEMENT_DYNAMIC_CLASS(LifeModule, wxModule)
939
940 bool LifeModule::OnInit()
941 {
942 // see below
943 g_tab = new unsigned char [0xfffff];
944
945 if (!g_tab) return false;
946
947 for (wxUint32 i = 0; i < 0xfffff; i++)
948 {
949 wxUint32 val = i >> 4;
950 wxUint32 old = i & 0x0000f;
951 wxUint32 live = 0;
952
953 for (int j = 0; j < 4; j++)
954 {
955 live >>= 1;
956
957 if (((val & 0xf) == 3) || (((val & 0xf) == 2) && (old & 0x1)))
958 live |= 0x8;
959
960 old >>= 1;
961 val >>= 4;
962 }
963
964 g_tab[i] = (unsigned char) live;
965 }
966
967 return true;
968 }
969
970 void LifeModule::OnExit()
971 {
972 delete [] g_tab;
973 }
974
975
976 // This table converts from number of neighbors (like in on[]) to
977 // bits, for a set of four cells. It takes as index a five-digit
978 // hexadecimal value (0xNNNNB) where Ns hold number of neighbors
979 // for each cell and B holds their previous state.
980 //
981 unsigned char *g_tab;
982
983 // This table converts from bits (like in live1, live2) to number
984 // of neighbors for each cell in the upper or lower row.
985 //
986 int g_tab1[]=
987 {
988 0x00000000,
989 0x00000011,
990 0x00000111,
991 0x00000122,
992 0x00001110,
993 0x00001121,
994 0x00001221,
995 0x00001232,
996 0x00011100,
997 0x00011111,
998 0x00011211,
999 0x00011222,
1000 0x00012210,
1001 0x00012221,
1002 0x00012321,
1003 0x00012332,
1004 0x00111000,
1005 0x00111011,
1006 0x00111111,
1007 0x00111122,
1008 0x00112110,
1009 0x00112121,
1010 0x00112221,
1011 0x00112232,
1012 0x00122100,
1013 0x00122111,
1014 0x00122211,
1015 0x00122222,
1016 0x00123210,
1017 0x00123221,
1018 0x00123321,
1019 0x00123332,
1020 0x01110000,
1021 0x01110011,
1022 0x01110111,
1023 0x01110122,
1024 0x01111110,
1025 0x01111121,
1026 0x01111221,
1027 0x01111232,
1028 0x01121100,
1029 0x01121111,
1030 0x01121211,
1031 0x01121222,
1032 0x01122210,
1033 0x01122221,
1034 0x01122321,
1035 0x01122332,
1036 0x01221000,
1037 0x01221011,
1038 0x01221111,
1039 0x01221122,
1040 0x01222110,
1041 0x01222121,
1042 0x01222221,
1043 0x01222232,
1044 0x01232100,
1045 0x01232111,
1046 0x01232211,
1047 0x01232222,
1048 0x01233210,
1049 0x01233221,
1050 0x01233321,
1051 0x01233332,
1052 0x11100000,
1053 0x11100011,
1054 0x11100111,
1055 0x11100122,
1056 0x11101110,
1057 0x11101121,
1058 0x11101221,
1059 0x11101232,
1060 0x11111100,
1061 0x11111111,
1062 0x11111211,
1063 0x11111222,
1064 0x11112210,
1065 0x11112221,
1066 0x11112321,
1067 0x11112332,
1068 0x11211000,
1069 0x11211011,
1070 0x11211111,
1071 0x11211122,
1072 0x11212110,
1073 0x11212121,
1074 0x11212221,
1075 0x11212232,
1076 0x11222100,
1077 0x11222111,
1078 0x11222211,
1079 0x11222222,
1080 0x11223210,
1081 0x11223221,
1082 0x11223321,
1083 0x11223332,
1084 0x12210000,
1085 0x12210011,
1086 0x12210111,
1087 0x12210122,
1088 0x12211110,
1089 0x12211121,
1090 0x12211221,
1091 0x12211232,
1092 0x12221100,
1093 0x12221111,
1094 0x12221211,
1095 0x12221222,
1096 0x12222210,
1097 0x12222221,
1098 0x12222321,
1099 0x12222332,
1100 0x12321000,
1101 0x12321011,
1102 0x12321111,
1103 0x12321122,
1104 0x12322110,
1105 0x12322121,
1106 0x12322221,
1107 0x12322232,
1108 0x12332100,
1109 0x12332111,
1110 0x12332211,
1111 0x12332222,
1112 0x12333210,
1113 0x12333221,
1114 0x12333321,
1115 0x12333332,
1116 0x11000000,
1117 0x11000011,
1118 0x11000111,
1119 0x11000122,
1120 0x11001110,
1121 0x11001121,
1122 0x11001221,
1123 0x11001232,
1124 0x11011100,
1125 0x11011111,
1126 0x11011211,
1127 0x11011222,
1128 0x11012210,
1129 0x11012221,
1130 0x11012321,
1131 0x11012332,
1132 0x11111000,
1133 0x11111011,
1134 0x11111111,
1135 0x11111122,
1136 0x11112110,
1137 0x11112121,
1138 0x11112221,
1139 0x11112232,
1140 0x11122100,
1141 0x11122111,
1142 0x11122211,
1143 0x11122222,
1144 0x11123210,
1145 0x11123221,
1146 0x11123321,
1147 0x11123332,
1148 0x12110000,
1149 0x12110011,
1150 0x12110111,
1151 0x12110122,
1152 0x12111110,
1153 0x12111121,
1154 0x12111221,
1155 0x12111232,
1156 0x12121100,
1157 0x12121111,
1158 0x12121211,
1159 0x12121222,
1160 0x12122210,
1161 0x12122221,
1162 0x12122321,
1163 0x12122332,
1164 0x12221000,
1165 0x12221011,
1166 0x12221111,
1167 0x12221122,
1168 0x12222110,
1169 0x12222121,
1170 0x12222221,
1171 0x12222232,
1172 0x12232100,
1173 0x12232111,
1174 0x12232211,
1175 0x12232222,
1176 0x12233210,
1177 0x12233221,
1178 0x12233321,
1179 0x12233332,
1180 0x22100000,
1181 0x22100011,
1182 0x22100111,
1183 0x22100122,
1184 0x22101110,
1185 0x22101121,
1186 0x22101221,
1187 0x22101232,
1188 0x22111100,
1189 0x22111111,
1190 0x22111211,
1191 0x22111222,
1192 0x22112210,
1193 0x22112221,
1194 0x22112321,
1195 0x22112332,
1196 0x22211000,
1197 0x22211011,
1198 0x22211111,
1199 0x22211122,
1200 0x22212110,
1201 0x22212121,
1202 0x22212221,
1203 0x22212232,
1204 0x22222100,
1205 0x22222111,
1206 0x22222211,
1207 0x22222222,
1208 0x22223210,
1209 0x22223221,
1210 0x22223321,
1211 0x22223332,
1212 0x23210000,
1213 0x23210011,
1214 0x23210111,
1215 0x23210122,
1216 0x23211110,
1217 0x23211121,
1218 0x23211221,
1219 0x23211232,
1220 0x23221100,
1221 0x23221111,
1222 0x23221211,
1223 0x23221222,
1224 0x23222210,
1225 0x23222221,
1226 0x23222321,
1227 0x23222332,
1228 0x23321000,
1229 0x23321011,
1230 0x23321111,
1231 0x23321122,
1232 0x23322110,
1233 0x23322121,
1234 0x23322221,
1235 0x23322232,
1236 0x23332100,
1237 0x23332111,
1238 0x23332211,
1239 0x23332222,
1240 0x23333210,
1241 0x23333221,
1242 0x23333321,
1243 0x23333332
1244 };
1245
1246 // This table converts from bits (like in live1, live2) to number
1247 // of neighbors for each cell in the same row (excluding ourselves)
1248 //
1249 int g_tab2[]=
1250 {
1251 0x00000000,
1252 0x00000010,
1253 0x00000101,
1254 0x00000111,
1255 0x00001010,
1256 0x00001020,
1257 0x00001111,
1258 0x00001121,
1259 0x00010100,
1260 0x00010110,
1261 0x00010201,
1262 0x00010211,
1263 0x00011110,
1264 0x00011120,
1265 0x00011211,
1266 0x00011221,
1267 0x00101000,
1268 0x00101010,
1269 0x00101101,
1270 0x00101111,
1271 0x00102010,
1272 0x00102020,
1273 0x00102111,
1274 0x00102121,
1275 0x00111100,
1276 0x00111110,
1277 0x00111201,
1278 0x00111211,
1279 0x00112110,
1280 0x00112120,
1281 0x00112211,
1282 0x00112221,
1283 0x01010000,
1284 0x01010010,
1285 0x01010101,
1286 0x01010111,
1287 0x01011010,
1288 0x01011020,
1289 0x01011111,
1290 0x01011121,
1291 0x01020100,
1292 0x01020110,
1293 0x01020201,
1294 0x01020211,
1295 0x01021110,
1296 0x01021120,
1297 0x01021211,
1298 0x01021221,
1299 0x01111000,
1300 0x01111010,
1301 0x01111101,
1302 0x01111111,
1303 0x01112010,
1304 0x01112020,
1305 0x01112111,
1306 0x01112121,
1307 0x01121100,
1308 0x01121110,
1309 0x01121201,
1310 0x01121211,
1311 0x01122110,
1312 0x01122120,
1313 0x01122211,
1314 0x01122221,
1315 0x10100000,
1316 0x10100010,
1317 0x10100101,
1318 0x10100111,
1319 0x10101010,
1320 0x10101020,
1321 0x10101111,
1322 0x10101121,
1323 0x10110100,
1324 0x10110110,
1325 0x10110201,
1326 0x10110211,
1327 0x10111110,
1328 0x10111120,
1329 0x10111211,
1330 0x10111221,
1331 0x10201000,
1332 0x10201010,
1333 0x10201101,
1334 0x10201111,
1335 0x10202010,
1336 0x10202020,
1337 0x10202111,
1338 0x10202121,
1339 0x10211100,
1340 0x10211110,
1341 0x10211201,
1342 0x10211211,
1343 0x10212110,
1344 0x10212120,
1345 0x10212211,
1346 0x10212221,
1347 0x11110000,
1348 0x11110010,
1349 0x11110101,
1350 0x11110111,
1351 0x11111010,
1352 0x11111020,
1353 0x11111111,
1354 0x11111121,
1355 0x11120100,
1356 0x11120110,
1357 0x11120201,
1358 0x11120211,
1359 0x11121110,
1360 0x11121120,
1361 0x11121211,
1362 0x11121221,
1363 0x11211000,
1364 0x11211010,
1365 0x11211101,
1366 0x11211111,
1367 0x11212010,
1368 0x11212020,
1369 0x11212111,
1370 0x11212121,
1371 0x11221100,
1372 0x11221110,
1373 0x11221201,
1374 0x11221211,
1375 0x11222110,
1376 0x11222120,
1377 0x11222211,
1378 0x11222221,
1379 0x01000000,
1380 0x01000010,
1381 0x01000101,
1382 0x01000111,
1383 0x01001010,
1384 0x01001020,
1385 0x01001111,
1386 0x01001121,
1387 0x01010100,
1388 0x01010110,
1389 0x01010201,
1390 0x01010211,
1391 0x01011110,
1392 0x01011120,
1393 0x01011211,
1394 0x01011221,
1395 0x01101000,
1396 0x01101010,
1397 0x01101101,
1398 0x01101111,
1399 0x01102010,
1400 0x01102020,
1401 0x01102111,
1402 0x01102121,
1403 0x01111100,
1404 0x01111110,
1405 0x01111201,
1406 0x01111211,
1407 0x01112110,
1408 0x01112120,
1409 0x01112211,
1410 0x01112221,
1411 0x02010000,
1412 0x02010010,
1413 0x02010101,
1414 0x02010111,
1415 0x02011010,
1416 0x02011020,
1417 0x02011111,
1418 0x02011121,
1419 0x02020100,
1420 0x02020110,
1421 0x02020201,
1422 0x02020211,
1423 0x02021110,
1424 0x02021120,
1425 0x02021211,
1426 0x02021221,
1427 0x02111000,
1428 0x02111010,
1429 0x02111101,
1430 0x02111111,
1431 0x02112010,
1432 0x02112020,
1433 0x02112111,
1434 0x02112121,
1435 0x02121100,
1436 0x02121110,
1437 0x02121201,
1438 0x02121211,
1439 0x02122110,
1440 0x02122120,
1441 0x02122211,
1442 0x02122221,
1443 0x11100000,
1444 0x11100010,
1445 0x11100101,
1446 0x11100111,
1447 0x11101010,
1448 0x11101020,
1449 0x11101111,
1450 0x11101121,
1451 0x11110100,
1452 0x11110110,
1453 0x11110201,
1454 0x11110211,
1455 0x11111110,
1456 0x11111120,
1457 0x11111211,
1458 0x11111221,
1459 0x11201000,
1460 0x11201010,
1461 0x11201101,
1462 0x11201111,
1463 0x11202010,
1464 0x11202020,
1465 0x11202111,
1466 0x11202121,
1467 0x11211100,
1468 0x11211110,
1469 0x11211201,
1470 0x11211211,
1471 0x11212110,
1472 0x11212120,
1473 0x11212211,
1474 0x11212221,
1475 0x12110000,
1476 0x12110010,
1477 0x12110101,
1478 0x12110111,
1479 0x12111010,
1480 0x12111020,
1481 0x12111111,
1482 0x12111121,
1483 0x12120100,
1484 0x12120110,
1485 0x12120201,
1486 0x12120211,
1487 0x12121110,
1488 0x12121120,
1489 0x12121211,
1490 0x12121221,
1491 0x12211000,
1492 0x12211010,
1493 0x12211101,
1494 0x12211111,
1495 0x12212010,
1496 0x12212020,
1497 0x12212111,
1498 0x12212121,
1499 0x12221100,
1500 0x12221110,
1501 0x12221201,
1502 0x12221211,
1503 0x12222110,
1504 0x12222120,
1505 0x12222211,
1506 0x12222221
1507 };