/* -*- Mode: C; tab-width: 4 -*- */ /* demon --- David Griffeath's cellular automata */ #if 0 static const char sccsid[] = "@(#)demon.c 5.00 2000/11/01 xlockmore"; #endif /*- * Copyright (c) 1995 by David Bagley. * * Permission to use, copy, modify, and distribute this software and its * documentation for any purpose and without fee is hereby granted, * provided that the above copyright notice appear in all copies and that * both that copyright notice and this permission notice appear in * supporting documentation. * * This file is provided AS IS with no warranties of any kind. The author * shall have no liability with respect to the infringement of copyrights, * trade secrets or any patents by this file or any part thereof. In no * event will the author be liable for any lost revenue or profits or * other special, indirect and consequential damages. * * Revision History: * 01-Nov-2000: Allocation checks * 10-May-1997: Compatible with xscreensaver * 16-Apr-1997: -neighbors 3, 9 (not sound mathematically), 12, and 8 added * 30-May-1996: Ron Hitchens * Fixed memory management that caused leaks * 14-Apr-1996: -neighbors 6 runtime-time option added * 21-Aug-1995: Coded from A.K. Dewdney's "Computer Recreations", Scientific * American Magazine" Aug 1989 pp 102-105. Also very similar * to hodgepodge machine described in A.K. Dewdney's "Computer * Recreations", Scientific American Magazine" Aug 1988 * pp 104-107. Also used life.c as a guide. */ /*- * A cellular universe of 4 phases debris, droplets, defects, and demons. */ /*- Grid Number of Neighbors ---- ------------------ Square 4 or 8 Hexagon 6 Triangle 3, 9, or 12 */ #ifndef HAVE_JWXYZ # define DO_STIPPLE #endif #ifdef STANDALONE # define MODE_demon # define DEFAULTS "*delay: 50000 \n" \ "*count: 0 \n" \ "*cycles: 1000 \n" \ "*size: -30 \n" \ "*ncolors: 64 \n" \ "*fpsSolid: true \n" \ "*ignoreRotation: True \n" \ # define UNIFORM_COLORS # define release_demon 0 # define reshape_demon 0 # define demon_handle_event 0 # include "xlockmore.h" /* in xscreensaver distribution */ #else /* STANDALONE */ # include "xlock.h" /* in xlockmore distribution */ #endif /* STANDALONE */ #include "automata.h" #ifdef MODE_demon /*- * neighbors of 0 randomizes it between 3, 4, 6, 8, 9, and 12. */ #define DEF_NEIGHBORS "0" /* choose random value */ static int neighbors; static XrmOptionDescRec opts[] = { {"-neighbors", ".demon.neighbors", XrmoptionSepArg, 0} }; static argtype vars[] = { {&neighbors, "neighbors", "Neighbors", DEF_NEIGHBORS, t_Int} }; static OptionStruct desc[] = { {"-neighbors num", "squares 4 or 8, hexagons 6, triangles 3, 9 or 12"} }; ENTRYPOINT ModeSpecOpt demon_opts = {sizeof opts / sizeof opts[0], opts, sizeof vars / sizeof vars[0], vars, desc}; #ifdef USE_MODULES ModStruct demon_description = {"demon", "init_demon", "draw_demon", (char *) NULL, "refresh_demon", "init_demon", "free_demon", &demon_opts, 50000, 0, 1000, -7, 64, 1.0, "", "Shows Griffeath's cellular automata", 0, NULL}; #endif #define DEMONBITS(n,w,h)\ if ((dp->pixmaps[dp->init_bits]=\ XCreatePixmapFromBitmapData(MI_DISPLAY(mi),window,(char *)n,w,h,1,0,1))==None){\ free_demon(mi); return;} else {dp->init_bits++;} #define REDRAWSTEP 2000 /* How many cells to draw per cycle */ #define MINSTATES 2 #define MINGRIDSIZE 5 #define MINSIZE 4 #define NEIGHBORKINDS 6 /* Singly linked list */ typedef struct _CellList { XPoint pt; struct _CellList *next; } CellList; typedef struct { int generation; int xs, ys; int xb, yb; int nrows, ncols; int width, height; int states; int state; int redrawing, redrawpos; int *ncells; CellList **cellList; unsigned char *oldcell, *newcell; int neighbors; int init_bits; GC stippledGC; Pixmap pixmaps[NUMSTIPPLES - 1]; union { XPoint hexagon[6]; XPoint triangle[2][3]; } shape; } demonstruct; static char plots[2][NEIGHBORKINDS] = { {3, 4, 6, 8, 9, 12}, /* Neighborhoods */ {12, 16, 18, 20, 22, 24} /* Number of states */ }; static demonstruct *demons = (demonstruct *) NULL; static void drawcell(ModeInfo * mi, int col, int row, unsigned char state) { demonstruct *dp = &demons[MI_SCREEN(mi)]; GC gc; if (!state) { XSetForeground(MI_DISPLAY(mi), MI_GC(mi), MI_BLACK_PIXEL(mi)); gc = MI_GC(mi); } else if (MI_NPIXELS(mi) >= NUMSTIPPLES) { XSetForeground(MI_DISPLAY(mi), MI_GC(mi), MI_PIXEL(mi, (((int) state - 1) * MI_NPIXELS(mi) / (dp->states - 1)) % MI_NPIXELS(mi))); gc = MI_GC(mi); } else { XGCValues gcv; #ifdef DO_STIPPLE gcv.stipple = dp->pixmaps[(state - 1) % (NUMSTIPPLES - 1)]; #endif /* DO_STIPPLE */ gcv.foreground = MI_WHITE_PIXEL(mi); gcv.background = MI_BLACK_PIXEL(mi); XChangeGC(MI_DISPLAY(mi), dp->stippledGC, GCStipple | GCForeground | GCBackground, &gcv); gc = dp->stippledGC; } if (dp->neighbors == 6) { int ccol = 2 * col + !(row & 1), crow = 2 * row; dp->shape.hexagon[0].x = dp->xb + ccol * dp->xs; dp->shape.hexagon[0].y = dp->yb + crow * dp->ys; if (dp->xs == 1 && dp->ys == 1) XDrawPoint(MI_DISPLAY(mi), MI_WINDOW(mi), gc, dp->shape.hexagon[0].x, dp->shape.hexagon[0].y); else XFillPolygon(MI_DISPLAY(mi), MI_WINDOW(mi), gc, dp->shape.hexagon, 6, Convex, CoordModePrevious); } else if (dp->neighbors == 4 || dp->neighbors == 8) { XFillRectangle(MI_DISPLAY(mi), MI_WINDOW(mi), gc, dp->xb + dp->xs * col, dp->yb + dp->ys * row, dp->xs - (dp->xs > 3), dp->ys - (dp->ys > 3)); } else { /* TRI */ int orient = (col + row) % 2; /* O left 1 right */ dp->shape.triangle[orient][0].x = dp->xb + col * dp->xs; dp->shape.triangle[orient][0].y = dp->yb + row * dp->ys; if (dp->xs <= 3 || dp->ys <= 3) XDrawPoint(MI_DISPLAY(mi), MI_WINDOW(mi), gc, ((orient) ? -1 : 1) + dp->shape.triangle[orient][0].x, dp->shape.triangle[orient][0].y); else { if (orient) dp->shape.triangle[orient][0].x += (dp->xs / 2 - 1); else dp->shape.triangle[orient][0].x -= (dp->xs / 2 - 1); XFillPolygon(MI_DISPLAY(mi), MI_WINDOW(mi), gc, dp->shape.triangle[orient], 3, Convex, CoordModePrevious); } } } static Bool addtolist(ModeInfo * mi, int col, int row, unsigned char state) { demonstruct *dp = &demons[MI_SCREEN(mi)]; CellList *current; current = dp->cellList[state]; if ((dp->cellList[state] = (CellList *) malloc(sizeof (CellList))) == NULL) { return False; } dp->cellList[state]->pt.x = col; dp->cellList[state]->pt.y = row; dp->cellList[state]->next = current; dp->ncells[state]++; return True; } static void free_state(demonstruct * dp, int state) { CellList *current; while (dp->cellList[state]) { current = dp->cellList[state]; dp->cellList[state] = dp->cellList[state]->next; (void) free((void *) current); } dp->cellList[state] = (CellList *) NULL; if (dp->ncells != NULL) dp->ncells[state] = 0; } static void free_list(demonstruct * dp) { int state; for (state = 0; state < dp->states; state++) free_state(dp, state); (void) free((void *) dp->cellList); dp->cellList = (CellList **) NULL; } static void free_struct(demonstruct * dp) { if (dp->cellList != NULL) { free_list(dp); } if (dp->ncells != NULL) { (void) free((void *) dp->ncells); dp->ncells = (int *) NULL; } if (dp->oldcell != NULL) { (void) free((void *) dp->oldcell); dp->oldcell = (unsigned char *) NULL; } if (dp->newcell != NULL) { (void) free((void *) dp->newcell); dp->newcell = (unsigned char *) NULL; } } ENTRYPOINT void free_demon(ModeInfo * mi) { Display *display = MI_DISPLAY(mi); demonstruct *dp = &demons[MI_SCREEN(mi)]; int shade; if (dp->stippledGC != None) { XFreeGC(display, dp->stippledGC); dp->stippledGC = None; } for (shade = 0; shade < dp->init_bits; shade++) { XFreePixmap(display, dp->pixmaps[shade]); } dp->init_bits = 0; free_struct(dp); } static Bool draw_state(ModeInfo * mi, int state) { demonstruct *dp = &demons[MI_SCREEN(mi)]; GC gc; XRectangle *rects; CellList *current; if (!state) { XSetForeground(MI_DISPLAY(mi), MI_GC(mi), MI_BLACK_PIXEL(mi)); gc = MI_GC(mi); } else if (MI_NPIXELS(mi) >= NUMSTIPPLES) { XSetForeground(MI_DISPLAY(mi), MI_GC(mi), MI_PIXEL(mi, (((int) state - 1) * MI_NPIXELS(mi) / (dp->states - 1)) % MI_NPIXELS(mi))); gc = MI_GC(mi); } else { XGCValues gcv; #ifdef DO_STIPPLE gcv.stipple = dp->pixmaps[(state - 1) % (NUMSTIPPLES - 1)]; #endif /* DO_STIPPLE */ gcv.foreground = MI_WHITE_PIXEL(mi); gcv.background = MI_BLACK_PIXEL(mi); XChangeGC(MI_DISPLAY(mi), dp->stippledGC, GCStipple | GCForeground | GCBackground, &gcv); gc = dp->stippledGC; } if (dp->neighbors == 6) { /* Draw right away, slow */ current = dp->cellList[state]; while (current) { int col, row, ccol, crow; col = current->pt.x; row = current->pt.y; ccol = 2 * col + !(row & 1), crow = 2 * row; dp->shape.hexagon[0].x = dp->xb + ccol * dp->xs; dp->shape.hexagon[0].y = dp->yb + crow * dp->ys; if (dp->xs == 1 && dp->ys == 1) XDrawPoint(MI_DISPLAY(mi), MI_WINDOW(mi), gc, dp->shape.hexagon[0].x, dp->shape.hexagon[0].y); else XFillPolygon(MI_DISPLAY(mi), MI_WINDOW(mi), gc, dp->shape.hexagon, 6, Convex, CoordModePrevious); current = current->next; } } else if (dp->neighbors == 4 || dp->neighbors == 8) { /* Take advantage of XDrawRectangles */ int ncells = 0; /* Create Rectangle list from part of the cellList */ if ((rects = (XRectangle *) malloc(dp->ncells[state] * sizeof (XRectangle))) == NULL) { return False; } current = dp->cellList[state]; while (current) { rects[ncells].x = dp->xb + current->pt.x * dp->xs; rects[ncells].y = dp->yb + current->pt.y * dp->ys; rects[ncells].width = dp->xs - (dp->xs > 3); rects[ncells].height = dp->ys - (dp->ys > 3); current = current->next; ncells++; } /* Finally get to draw */ XFillRectangles(MI_DISPLAY(mi), MI_WINDOW(mi), gc, rects, ncells); /* Free up rects list and the appropriate part of the cellList */ (void) free((void *) rects); } else { /* TRI */ current = dp->cellList[state]; while (current) { int col, row, orient; col = current->pt.x; row = current->pt.y; orient = (col + row) % 2; /* O left 1 right */ dp->shape.triangle[orient][0].x = dp->xb + col * dp->xs; dp->shape.triangle[orient][0].y = dp->yb + row * dp->ys; if (dp->xs <= 3 || dp->ys <= 3) XDrawPoint(MI_DISPLAY(mi), MI_WINDOW(mi), gc, ((orient) ? -1 : 1) + dp->shape.triangle[orient][0].x, dp->shape.triangle[orient][0].y); else { if (orient) dp->shape.triangle[orient][0].x += (dp->xs / 2 - 1); else dp->shape.triangle[orient][0].x -= (dp->xs / 2 - 1); XFillPolygon(MI_DISPLAY(mi), MI_WINDOW(mi), gc, dp->shape.triangle[orient], 3, Convex, CoordModePrevious); } current = current->next; } } free_state(dp, state); return True; } static void RandomSoup(ModeInfo * mi) { demonstruct *dp = &demons[MI_SCREEN(mi)]; int row, col, mrow = 0; for (row = 0; row < dp->nrows; ++row) { for (col = 0; col < dp->ncols; ++col) { dp->oldcell[col + mrow] = (unsigned char) LRAND() % ((unsigned char) dp->states); if (!addtolist(mi, col, row, dp->oldcell[col + mrow])) return; /* sparse soup */ } mrow += dp->ncols; } } ENTRYPOINT void init_demon (ModeInfo * mi) { int size = MI_SIZE(mi), nk; demonstruct *dp; MI_INIT (mi, demons); dp = &demons[MI_SCREEN(mi)]; if (MI_WIDTH(mi) < 100 || MI_HEIGHT(mi) < 100) /* tiny window */ size = MIN(MI_WIDTH(mi), MI_HEIGHT(mi)); dp->generation = 0; dp->redrawing = 0; #ifdef DO_STIPPLE if (MI_NPIXELS(mi) < NUMSTIPPLES) { Window window = MI_WINDOW(mi); if (dp->stippledGC == None) { XGCValues gcv; gcv.fill_style = FillOpaqueStippled; if ((dp->stippledGC = XCreateGC(MI_DISPLAY(mi), window, GCFillStyle, &gcv)) == None) { free_demon(mi); return; } } if (dp->init_bits == 0) { int i; for (i = 1; i < NUMSTIPPLES; i++) { DEMONBITS(stipples[i], STIPPLESIZE, STIPPLESIZE); } } } #endif /* DO_STIPPLE */ free_struct(dp); #ifdef HAVE_JWXYZ jwxyz_XSetAntiAliasing (MI_DISPLAY(mi), MI_GC(mi), False); #endif for (nk = 0; nk < NEIGHBORKINDS; nk++) { if (neighbors == plots[0][nk]) { dp->neighbors = plots[0][nk]; break; } if (nk == NEIGHBORKINDS - 1) { nk = NRAND(NEIGHBORKINDS); dp->neighbors = plots[0][nk]; break; } } dp->states = MI_COUNT(mi); if (dp->states < -MINSTATES) dp->states = NRAND(-dp->states - MINSTATES + 1) + MINSTATES; else if (dp->states < MINSTATES) dp->states = plots[1][nk]; if ((dp->cellList = (CellList **) calloc(dp->states, sizeof (CellList *))) == NULL) { free_demon(mi); return; } if ((dp->ncells = (int *) calloc(dp->states, sizeof (int))) == NULL) { free_demon(mi); return; } dp->state = 0; dp->width = MI_WIDTH(mi); dp->height = MI_HEIGHT(mi); if (dp->neighbors == 6) { int nccols, ncrows, i; if (dp->width < 8) dp->width = 8; if (dp->height < 8) dp->height = 8; if (size < -MINSIZE) dp->ys = NRAND(MIN(-size, MAX(MINSIZE, MIN(dp->width, dp->height) / MINGRIDSIZE)) - MINSIZE + 1) + MINSIZE; else if (size < MINSIZE) { if (!size) dp->ys = MAX(MINSIZE, MIN(dp->width, dp->height) / MINGRIDSIZE); else dp->ys = MINSIZE; } else dp->ys = MIN(size, MAX(MINSIZE, MIN(dp->width, dp->height) / MINGRIDSIZE)); dp->xs = dp->ys; nccols = MAX(dp->width / dp->xs - 2, 2); ncrows = MAX(dp->height / dp->ys - 1, 4); dp->ncols = nccols / 2; dp->nrows = 2 * (ncrows / 4); dp->xb = (dp->width - dp->xs * nccols) / 2 + dp->xs / 2; dp->yb = (dp->height - dp->ys * (ncrows / 2) * 2) / 2 + dp->ys - 2; for (i = 0; i < 6; i++) { dp->shape.hexagon[i].x = (dp->xs - 1) * hexagonUnit[i].x; dp->shape.hexagon[i].y = ((dp->ys - 1) * hexagonUnit[i].y / 2) * 4 / 3; } } else if (dp->neighbors == 4 || dp->neighbors == 8) { if (size < -MINSIZE) dp->ys = NRAND(MIN(-size, MAX(MINSIZE, MIN(dp->width, dp->height) / MINGRIDSIZE)) - MINSIZE + 1) + MINSIZE; else if (size < MINSIZE) { if (!size) dp->ys = MAX(MINSIZE, MIN(dp->width, dp->height) / MINGRIDSIZE); else dp->ys = MINSIZE; } else dp->ys = MIN(size, MAX(MINSIZE, MIN(dp->width, dp->height) / MINGRIDSIZE)); dp->xs = dp->ys; dp->ncols = MAX(dp->width / dp->xs, 2); dp->nrows = MAX(dp->height / dp->ys, 2); dp->xb = (dp->width - dp->xs * dp->ncols) / 2; dp->yb = (dp->height - dp->ys * dp->nrows) / 2; } else { /* TRI */ int orient, i; if (dp->width < 2) dp->width = 2; if (dp->height < 2) dp->height = 2; if (size < -MINSIZE) dp->ys = NRAND(MIN(-size, MAX(MINSIZE, MIN(dp->width, dp->height) / MINGRIDSIZE)) - MINSIZE + 1) + MINSIZE; else if (size < MINSIZE) { if (!size) dp->ys = MAX(MINSIZE, MIN(dp->width, dp->height) / MINGRIDSIZE); else dp->ys = MINSIZE; } else dp->ys = MIN(size, MAX(MINSIZE, MIN(dp->width, dp->height) / MINGRIDSIZE)); dp->xs = (int) (1.52 * dp->ys); dp->ncols = (MAX(dp->width / dp->xs - 1, 2) / 2) * 2; dp->nrows = (MAX(dp->height / dp->ys - 1, 2) / 2) * 2; dp->xb = (dp->width - dp->xs * dp->ncols) / 2 + dp->xs / 2; dp->yb = (dp->height - dp->ys * dp->nrows) / 2 + dp->ys / 2; for (orient = 0; orient < 2; orient++) { for (i = 0; i < 3; i++) { dp->shape.triangle[orient][i].x = (dp->xs - 2) * triangleUnit[orient][i].x; dp->shape.triangle[orient][i].y = (dp->ys - 2) * triangleUnit[orient][i].y; } } } MI_CLEARWINDOW(mi); if ((dp->oldcell = (unsigned char *) malloc(dp->ncols * dp->nrows * sizeof (unsigned char))) == NULL) { free_demon(mi); return; } if ((dp->newcell = (unsigned char *) malloc(dp->ncols * dp->nrows * sizeof (unsigned char))) == NULL) { free_demon(mi); return; } RandomSoup(mi); } ENTRYPOINT void draw_demon (ModeInfo * mi) { int i, j, k, l, mj = 0, ml; demonstruct *dp; if (demons == NULL) return; dp = &demons[MI_SCREEN(mi)]; if (dp->cellList == NULL) return; MI_IS_DRAWN(mi) = True; if (dp->state >= dp->states) { (void) memcpy((char *) dp->newcell, (char *) dp->oldcell, dp->ncols * dp->nrows * sizeof (unsigned char)); if (dp->neighbors == 6) { for (j = 0; j < dp->nrows; j++) { for (i = 0; i < dp->ncols; i++) { /* NE */ if (!(j & 1)) k = (i + 1 == dp->ncols) ? 0 : i + 1; else k = i; l = (!j) ? dp->nrows - 1 : j - 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* E */ k = (i + 1 == dp->ncols) ? 0 : i + 1; ml = mj; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* SE */ if (!(j & 1)) k = (i + 1 == dp->ncols) ? 0 : i + 1; else k = i; l = (j + 1 == dp->nrows) ? 0 : j + 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* SW */ if (j & 1) k = (!i) ? dp->ncols - 1 : i - 1; else k = i; l = (j + 1 == dp->nrows) ? 0 : j + 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* W */ k = (!i) ? dp->ncols - 1 : i - 1; ml = mj; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* NW */ if (j & 1) k = (!i) ? dp->ncols - 1 : i - 1; else k = i; l = (!j) ? dp->nrows - 1 : j - 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; } mj += dp->ncols; } } else if (dp->neighbors == 4 || dp->neighbors == 8) { for (j = 0; j < dp->nrows; j++) { for (i = 0; i < dp->ncols; i++) { /* N */ k = i; l = (!j) ? dp->nrows - 1 : j - 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* E */ k = (i + 1 == dp->ncols) ? 0 : i + 1; ml = mj; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* S */ k = i; l = (j + 1 == dp->nrows) ? 0 : j + 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* W */ k = (!i) ? dp->ncols - 1 : i - 1; /*l = j;*/ ml = mj; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; } mj += dp->ncols; } if (dp->neighbors == 8) { mj = 0; for (j = 0; j < dp->nrows; j++) { for (i = 0; i < dp->ncols; i++) { /* NE */ k = (i + 1 == dp->ncols) ? 0 : i + 1; l = (!j) ? dp->nrows - 1 : j - 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* SE */ k = (i + 1 == dp->ncols) ? 0 : i + 1; l = (j + 1 == dp->nrows) ? 0 : j + 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* SW */ k = (!i) ? dp->ncols - 1 : i - 1; l = (j + 1 == dp->nrows) ? 0 : j + 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* NW */ k = (!i) ? dp->ncols - 1 : i - 1; l = (!j) ? dp->nrows - 1 : j - 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; } mj += dp->ncols; } } } else if (dp->neighbors == 3 || dp->neighbors == 9 || dp->neighbors == 12) { for (j = 0; j < dp->nrows; j++) { for (i = 0; i < dp->ncols; i++) { if ((i + j) % 2) { /* right */ /* W */ k = (!i) ? dp->ncols - 1 : i - 1; ml = mj; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; } else { /* left */ /* E */ k = (i + 1 == dp->ncols) ? 0 : i + 1; ml = mj; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; } /* N */ k = i; l = (!j) ? dp->nrows - 1 : j - 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* S */ k = i; l = (j + 1 == dp->nrows) ? 0 : j + 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; } mj += dp->ncols; } if (dp->neighbors == 9 || dp->neighbors == 12) { mj = 0; for (j = 0; j < dp->nrows; j++) { for (i = 0; i < dp->ncols; i++) { /* NN */ k = i; if (!j) l = dp->nrows - 2; else if (!(j - 1)) l = dp->nrows - 1; else l = j - 2; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* SS */ k = i; if (j + 1 == dp->nrows) l = 1; else if (j + 2 == dp->nrows) l = 0; else l = j + 2; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* NW */ k = (!i) ? dp->ncols - 1 : i - 1; l = (!j) ? dp->nrows - 1 : j - 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* NE */ k = (i + 1 == dp->ncols) ? 0 : i + 1; l = (!j) ? dp->nrows - 1 : j - 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* SW */ k = (!i) ? dp->ncols - 1 : i - 1; l = (j + 1 == dp->nrows) ? 0 : j + 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* SE */ k = (i + 1 == dp->ncols) ? 0 : i + 1; l = (j + 1 == dp->nrows) ? 0 : j + 1; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; } mj += dp->ncols; } if (dp->neighbors == 12) { mj = 0; for (j = 0; j < dp->nrows; j++) { for (i = 0; i < dp->ncols; i++) { if ((i + j) % 2) { /* right */ /* NNW */ k = (!i) ? dp->ncols - 1 : i - 1; if (!j) l = dp->nrows - 2; else if (!(j - 1)) l = dp->nrows - 1; else l = j - 2; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* SSW */ k = (!i) ? dp->ncols - 1 : i - 1; if (j + 1 == dp->nrows) l = 1; else if (j + 2 == dp->nrows) l = 0; else l = j + 2; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* EE */ k = (i + 1 == dp->ncols) ? 0 : i + 1; /*l = j;*/ ml = mj; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; } else { /* left */ /* NNE */ k = (i + 1 == dp->ncols) ? 0 : i + 1; if (!j) l = dp->nrows - 2; else if (!(j - 1)) l = dp->nrows - 1; else l = j - 2; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* SSE */ k = (i + 1 == dp->ncols) ? 0 : i + 1; if (j + 1 == dp->nrows) l = 1; else if (j + 2 == dp->nrows) l = 0; else l = j + 2; ml = l * dp->ncols; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; /* WW */ k = (!i) ? dp->ncols - 1 : i - 1; /*l = j;*/ ml = mj; if (dp->oldcell[k + ml] == (int) (dp->oldcell[i + mj] + 1) % dp->states) dp->newcell[i + mj] = dp->oldcell[k + ml]; } } mj += dp->ncols; } } } } mj = 0; for (j = 0; j < dp->nrows; j++) { for (i = 0; i < dp->ncols; i++) if (dp->oldcell[i + mj] != dp->newcell[i + mj]) { dp->oldcell[i + mj] = dp->newcell[i + mj]; if (!addtolist(mi, i, j, dp->oldcell[i + mj])) { free_demon(mi); return; } } mj += dp->ncols; } if (++dp->generation > MI_CYCLES(mi)) init_demon(mi); dp->state = 0; } else { if (dp->ncells[dp->state]) if (!draw_state(mi, dp->state)) { free_demon(mi); return; } dp->state++; } if (dp->redrawing) { for (i = 0; i < REDRAWSTEP; i++) { if (dp->oldcell[dp->redrawpos]) { drawcell(mi, dp->redrawpos % dp->ncols, dp->redrawpos / dp->ncols, dp->oldcell[dp->redrawpos]); } if (++(dp->redrawpos) >= dp->ncols * dp->nrows) { dp->redrawing = 0; break; } } } } #ifndef STANDALONE ENTRYPOINT void refresh_demon (ModeInfo * mi) { demonstruct *dp; if (demons == NULL) return; dp = &demons[MI_SCREEN(mi)]; dp->redrawing = 1; dp->redrawpos = 0; } #endif XSCREENSAVER_MODULE ("Demon", demon) #endif /* MODE_demon */