/* -*- Mode: C; tab-width: 4 -*- */
/* crystal --- polygons moving according to plane group rules */
#if 0
static const char sccsid[] = "@(#)crystal.c 4.12 98/09/10 xlockmore";
#endif
/*-
* Copyright (c) 1997 by Jouk Jansen <joukj@crys.chem.uva.nl>
*
* 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.
*
* The author should like to be notified if changes have been made to the
* routine. Response will only be guaranteed when a VMS version of the
* program is available.
*
* A moving polygon-mode. The polygons obey 2D-planegroup symmetry.
*
* The groupings of the cells fall in 3 categories:
* oblique groups 1 and 2 where the angle gamma ranges from 60 to 120 degrees
* square groups 3 through 11 where the angle gamma is 90 degrees
* hexagonal groups 12 through 17 where the angle gamma is 120 degrees
*
* Revision History:
* 03-Dec-98: Random inversion of y-axis included to simulate hexagonal groups
* with an angle of 60 degrees.
* 10-Sep-98: new colour scheme
* 24-Feb-98: added option centre which turns on/off forcing the centre of
* the screen to be used
* added option maxsize which forces the dimensions to be chasen
* in such ua way that the largest possible part of the screen is
* used
* When only one unit cell is drawn, it is chosen at random
* 18-Feb-98: added support for negative numbers with -nx and -ny meaning
* "random" choice with given maximum
* added +/-grid option. If -cell is specified this option
* determines if one or all unit cells are drawn.
* -batchcount is now a parameter for all the objects on the screen
* instead of the number of "unique" objects
* The maximum size of the objects now scales with the part
* of the screen used.
* fixed "size" problem. Now very small non-vissable objects
* are not allowed
* 13-Feb-98: randomized the unit cell size
* runtime options -/+cell (turn on/off unit cell drawing)
* -nx num (number of translational symmetries in x-direction
* -ny num (idem y-direction but ignored for square and
* hexagonal space groups
* i.e. try xlock -mode crystal -nx 3 -ny 2
* Fullrandom overrules the -/+cell option.
* 05-Feb-98: Revision + bug repairs
* shows unit cell
* use part of the screen for unit cell
* in hexagonal and square groups a&b axis forced to be equal
* cell angle for oblique groups randomly chosen between 60 and 120
* bugs solved: planegroups with cell angles <> 90.0 now work properly
* 19-Sep-97: Added remaining hexagonal groups
* 12-Jun-97: Created
*/
#ifdef STANDALONE
# define DEFAULTS "*delay: 60000 \n" \
"*count: -500 \n" \
"*cycles: 200 \n" \
"*size: -15 \n" \
"*ncolors: 100 \n" \
"*fpsSolid: True \n" \
"*ignoreRotation: True \n" \
# define release_crystal 0
# define reshape_crystal 0
# define crystal_handle_event 0
# include "xlockmore.h" /* in xscreensaver distribution */
#else /* STANDALONE */
# include "xlock.h" /* in xlockmore distribution */
# include "color.h"
#endif /* STANDALONE */
#define DEF_CELL "True" /* Draw unit cell */
#define DEF_GRID "False" /* Draw unit all cell if DEF_CELL is True */
#define DEF_NX "-3" /* number of unit cells in x-direction */
#define DEF_NX1 1 /* number of unit cells in x-direction */
#define DEF_NY "-3" /* number of unit cells in y-direction */
#define DEF_NY1 1 /* number of unit cells in y-direction */
#define DEF_CENTRE "False"
#define DEF_MAXSIZE "False"
#define DEF_CYCLE "True"
#undef NRAND
#define NRAND(n) ( (n) ? (int) (LRAND() % (n)) : 0)
#define min(a,b) ((a) <= (b) ? (a) : (b))
static int nx, ny;
static Bool unit_cell, grid_cell, centre, maxsize, cycle_p;
static XrmOptionDescRec opts[] =
{
{"-nx", "crystal.nx", XrmoptionSepArg, 0},
{"-ny", "crystal.ny", XrmoptionSepArg, 0},
{"-centre", ".crystal.centre", XrmoptionNoArg, "on"},
{"+centre", ".crystal.centre", XrmoptionNoArg, "off"},
{"-maxsize", ".crystal.maxsize", XrmoptionNoArg, "on"},
{"+maxsize", ".crystal.maxsize", XrmoptionNoArg, "off"},
{"-cell", ".crystal.cell", XrmoptionNoArg, "on"},
{"+cell", ".crystal.cell", XrmoptionNoArg, "off"},
{"-grid", ".crystal.grid", XrmoptionNoArg, "on"},
{"+grid", ".crystal.grid", XrmoptionNoArg, "off"},
{"-shift", ".crystal.shift", XrmoptionNoArg, "on"},
{"+shift", ".crystal.shift", XrmoptionNoArg, "off"}
};
static argtype vars[] =
{
{&nx, "nx", "nx", DEF_NX, t_Int},
{&ny, "ny", "ny", DEF_NY, t_Int},
{¢re, "centre", "Centre", DEF_CENTRE, t_Bool},
{&maxsize, "maxsize", "Maxsize", DEF_MAXSIZE, t_Bool},
{&unit_cell, "cell", "Cell", DEF_CELL, t_Bool},
{&grid_cell, "grid", "Grid", DEF_GRID, t_Bool},
{&cycle_p, "shift", "Shift", DEF_CYCLE, t_Bool}
};
static OptionStruct desc[] =
{
{"-nx num", "Number of unit cells in x-direction"},
{"-ny num", "Number of unit cells in y-direction"},
{"-/+centre", "turn on/off centering on screen"},
{"-/+maxsize", "turn on/off use of maximum part of screen"},
{"-/+cell", "turn on/off drawing of unit cell"},
{"-/+grid", "turn on/off drawing of grid of unit cells (if -cell is on)"},
{"-/+shift", "turn on/off colour cycling"}
};
ENTRYPOINT ModeSpecOpt crystal_opts =
{sizeof opts / sizeof opts[0], opts, sizeof vars / sizeof vars[0], vars, desc};
#ifdef USE_MODULES
ModStruct crystal_description =
{"crystal", "init_crystal", "draw_crystal", NULL,
"refresh_crystal", "init_crystal", "free_crystal", &crystal_opts,
60000, -40, 200, -15, 64, 1.0, "",
"Shows polygons in 2D plane groups", 0, NULL};
#endif
#define DEF_NUM_ATOM 10
#define DEF_SIZ_ATOM 10
#define PI_RAD (M_PI / 180.0)
static Bool centro[17] =
{
False,
True,
False,
False,
False,
True,
True,
True,
True,
True,
True,
True,
False,
False,
False,
True,
True
};
static Bool primitive[17] =
{
True,
True,
True,
True,
False,
True,
True,
True,
False,
True,
True,
True,
True,
True,
True,
True,
True
};
static short numops[34] =
{
1, 0,
1, 0,
9, 7,
2, 0,
9, 7,
9, 7,
4, 2,
5, 3,
9, 7,
8, 6,
10, 6,
8, 4,
16, 13,
19, 13,
16, 10,
19, 13,
19, 13
};
static short operation[114] =
{
1, 0, 0, 1, 0, 0,
-1, 0, 0, 1, 0, 1,
-1, 0, 0, 1, 1, 0,
1, 0, 0, 1, 0, 0,
-1, 0, 0, 1, 1, 1,
1, 0, 0, 1, 1, 1,
0, -1, 1, 0, 0, 0,
1, 0, 0, 1, 0, 0,
-1, 0, 0, 1, 0, 0,
0, 1, 1, 0, 0, 0,
-1, 0, -1, 1, 0, 0,
1, -1, 0, -1, 0, 0,
0, 1, 1, 0, 0, 0,
0, -1, 1, -1, 0, 0,
-1, 1, -1, 0, 0, 0,
1, 0, 0, 1, 0, 0,
0, -1, -1, 0, 0, 0,
-1, 1, 0, 1, 0, 0,
1, 0, 1, -1, 0, 0
};
typedef struct {
unsigned long colour;
int x0, y0, velocity[2];
float angle, velocity_a;
int num_point, at_type, size_at;
XPoint xy[5];
} crystalatom;
typedef struct {
Bool painted;
int win_width, win_height, num_atom;
int planegroup, a, b, offset_w, offset_h, nx, ny;
float gamma;
crystalatom *atom;
GC gc;
Bool unit_cell, grid_cell;
Colormap cmap;
XColor *colors;
int ncolors;
Bool cycle_p, mono_p, no_colors;
unsigned long blackpixel, whitepixel, fg, bg;
int direction, invert;
unsigned long grid_pixel;
int inx, iny;
} crystalstruct;
static crystalstruct *crystals = NULL;
static void
trans_coor(XPoint * xyp, XPoint * new_xyp, int num_points,
float gamma)
{
int i;
for (i = 0; i <= num_points; i++) {
new_xyp[i].x = xyp[i].x +
(int) (xyp[i].y * sin((gamma - 90.0) * PI_RAD));
new_xyp[i].y = (int) (xyp[i].y / cos((gamma - 90.0) * PI_RAD));
}
}
static void
trans_coor_back(XPoint * xyp, XPoint * new_xyp,
int num_points, float gamma, int offset_w, int offset_h ,
int winheight , int invert )
{
int i;
for (i = 0; i <= num_points; i++) {
new_xyp[i].y = (int) (xyp[i].y * cos((gamma - 90) * PI_RAD)) +
offset_h;
new_xyp[i].x = xyp[i].x - (int) (xyp[i].y * sin((gamma - 90.0)
* PI_RAD)) + offset_w;
if ( invert ) new_xyp[i].y = winheight - new_xyp[i].y;
}
}
static void
crystal_setupatom(crystalatom * atom0, float gamma)
{
XPoint xy[5];
int x0, y0;
y0 = (int) (atom0->y0 * cos((gamma - 90) * PI_RAD));
x0 = atom0->x0 - (int) (atom0->y0 * sin((gamma - 90.0) * PI_RAD));
switch (atom0->at_type) {
case 0: /* rectangles */
xy[0].x = x0 + (int) (2 * atom0->size_at *
cos(atom0->angle)) +
(int) (atom0->size_at * sin(atom0->angle));
xy[0].y = y0 + (int) (atom0->size_at *
cos(atom0->angle)) -
(int) (2 * atom0->size_at * sin(atom0->angle));
xy[1].x = x0 + (int) (2 * atom0->size_at *
cos(atom0->angle)) -
(int) (atom0->size_at * sin(atom0->angle));
xy[1].y = y0 - (int) (atom0->size_at *
cos(atom0->angle)) -
(int) (2 * atom0->size_at * sin(atom0->angle));
xy[2].x = x0 - (int) (2 * atom0->size_at *
cos(atom0->angle)) -
(int) (atom0->size_at * sin(atom0->angle));
xy[2].y = y0 - (int) (atom0->size_at *
cos(atom0->angle)) +
(int) (2 * atom0->size_at * sin(atom0->angle));
xy[3].x = x0 - (int) (2 * atom0->size_at *
cos(atom0->angle)) +
(int) (atom0->size_at * sin(atom0->angle));
xy[3].y = y0 + (int) (atom0->size_at *
cos(atom0->angle)) +
(int) (2 * atom0->size_at *
sin(atom0->angle));
xy[4].x = xy[0].x;
xy[4].y = xy[0].y;
trans_coor(xy, atom0->xy, 4, gamma);
return;
case 1: /* squares */
xy[0].x = x0 + (int) (1.5 * atom0->size_at *
cos(atom0->angle)) +
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[0].y = y0 + (int) (1.5 * atom0->size_at *
cos(atom0->angle)) -
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[1].x = x0 + (int) (1.5 * atom0->size_at *
cos(atom0->angle)) -
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[1].y = y0 - (int) (1.5 * atom0->size_at *
cos(atom0->angle)) -
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[2].x = x0 - (int) (1.5 * atom0->size_at *
cos(atom0->angle)) -
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[2].y = y0 - (int) (1.5 * atom0->size_at *
cos(atom0->angle)) +
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[3].x = x0 - (int) (1.5 * atom0->size_at *
cos(atom0->angle)) +
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[3].y = y0 + (int) (1.5 * atom0->size_at *
cos(atom0->angle)) +
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[4].x = xy[0].x;
xy[4].y = xy[0].y;
trans_coor(xy, atom0->xy, 4, gamma);
return;
case 2: /* triangles */
xy[0].x = x0 + (int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[0].y = y0 + (int) (1.5 * atom0->size_at *
cos(atom0->angle));
xy[1].x = x0 + (int) (1.5 * atom0->size_at *
cos(atom0->angle)) -
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[1].y = y0 - (int) (1.5 * atom0->size_at *
cos(atom0->angle)) -
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[2].x = x0 - (int) (1.5 * atom0->size_at *
cos(atom0->angle)) -
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[2].y = y0 - (int) (1.5 * atom0->size_at *
cos(atom0->angle)) +
(int) (1.5 * atom0->size_at *
sin(atom0->angle));
xy[3].x = xy[0].x;
xy[3].y = xy[0].y;
trans_coor(xy, atom0->xy, 3, gamma);
return;
}
}
static void
crystal_drawatom(ModeInfo * mi, crystalatom * atom0)
{
crystalstruct *cryst;
Display *display = MI_DISPLAY(mi);
Window window = MI_WINDOW(mi);
int j, k, l, m;
cryst = &crystals[MI_SCREEN(mi)];
for (j = numops[2 * cryst->planegroup + 1];
j < numops[2 * cryst->planegroup]; j++) {
XPoint xy[5], new_xy[5];
XPoint xy_1[5];
int xtrans, ytrans;
xtrans = operation[j * 6] * atom0->x0 + operation[j * 6 + 1] *
atom0->y0 + (int) (operation[j * 6 + 4] * cryst->a /
2.0);
ytrans = operation[j * 6 + 2] * atom0->x0 + operation[j * 6 +
3] * atom0->y0 + (int) (operation[j * 6 + 5] *
cryst->b / 2.0);
if (xtrans < 0) {
if (xtrans < -cryst->a)
xtrans = 2 * cryst->a;
else
xtrans = cryst->a;
} else if (xtrans >= cryst->a)
xtrans = -cryst->a;
else
xtrans = 0;
if (ytrans < 0)
ytrans = cryst->b;
else if (ytrans >= cryst->b)
ytrans = -cryst->b;
else
ytrans = 0;
for (k = 0; k < atom0->num_point; k++) {
xy[k].x = operation[j * 6] * atom0->xy[k].x +
operation[j * 6 + 1] *
atom0->xy[k].y + (int) (operation[j * 6 + 4] *
cryst->a / 2.0) +
xtrans;
xy[k].y = operation[j * 6 + 2] * atom0->xy[k].x +
operation[j * 6 + 3] *
atom0->xy[k].y + (int) (operation[j * 6 + 5] *
cryst->b / 2.0) +
ytrans;
}
xy[atom0->num_point].x = xy[0].x;
xy[atom0->num_point].y = xy[0].y;
for (l = 0; l < cryst->nx; l++) {
for (m = 0; m < cryst->ny; m++) {
for (k = 0; k <= atom0->num_point; k++) {
xy_1[k].x = xy[k].x + l * cryst->a;
xy_1[k].y = xy[k].y + m * cryst->b;
}
trans_coor_back(xy_1, new_xy, atom0->num_point,
cryst->gamma, cryst->offset_w,
cryst->offset_h ,
cryst->win_height,
cryst->invert);
XFillPolygon(display, window, cryst->gc, new_xy,
atom0->num_point, Convex, CoordModeOrigin);
}
}
if (centro[cryst->planegroup] == True) {
for (k = 0; k <= atom0->num_point; k++) {
xy[k].x = cryst->a - xy[k].x;
xy[k].y = cryst->b - xy[k].y;
}
for (l = 0; l < cryst->nx; l++) {
for (m = 0; m < cryst->ny; m++) {
for (k = 0; k <= atom0->num_point; k++) {
xy_1[k].x = xy[k].x + l * cryst->a;
xy_1[k].y = xy[k].y + m * cryst->b;
}
trans_coor_back(xy_1, new_xy, atom0->num_point,
cryst->gamma,
cryst->offset_w,
cryst->offset_h ,
cryst->win_height ,
cryst->invert);
XFillPolygon(display, window, cryst->gc,
new_xy,
atom0->num_point, Convex,
CoordModeOrigin);
}
}
}
if (primitive[cryst->planegroup] == False) {
if (xy[atom0->num_point].x >= (int) (cryst->a / 2.0))
xtrans = (int) (-cryst->a / 2.0);
else
xtrans = (int) (cryst->a / 2.0);
if (xy[atom0->num_point].y >= (int) (cryst->b / 2.0))
ytrans = (int) (-cryst->b / 2.0);
else
ytrans = (int) (cryst->b / 2.0);
for (k = 0; k <= atom0->num_point; k++) {
xy[k].x = xy[k].x + xtrans;
xy[k].y = xy[k].y + ytrans;
}
for (l = 0; l < cryst->nx; l++) {
for (m = 0; m < cryst->ny; m++) {
for (k = 0; k <= atom0->num_point; k++) {
xy_1[k].x = xy[k].x + l * cryst->a;
xy_1[k].y = xy[k].y + m * cryst->b;
}
trans_coor_back(xy_1, new_xy, atom0->num_point,
cryst->gamma,
cryst->offset_w,
cryst->offset_h ,
cryst->win_height,
cryst->invert);
XFillPolygon(display, window, cryst->gc,
new_xy,
atom0->num_point, Convex,
CoordModeOrigin);
}
}
if (centro[cryst->planegroup] == True) {
XPoint xy1[5];
for (k = 0; k <= atom0->num_point; k++) {
xy1[k].x = cryst->a - xy[k].x;
xy1[k].y = cryst->b - xy[k].y;
}
for (l = 0; l < cryst->nx; l++) {
for (m = 0; m < cryst->ny; m++) {
for (k = 0; k <= atom0->num_point; k++) {
xy_1[k].x = xy1[k].x + l * cryst->a;
xy_1[k].y = xy1[k].y + m * cryst->b;
}
trans_coor_back(xy_1, new_xy, atom0->num_point,
cryst->gamma,
cryst->offset_w,
cryst->offset_h ,
cryst->win_height,
cryst->invert);
XFillPolygon(display, window,
cryst->gc,
new_xy, atom0->num_point,
Convex, CoordModeOrigin);
}
}
}
}
}
}
ENTRYPOINT void init_crystal(ModeInfo * mi);
ENTRYPOINT void
draw_crystal(ModeInfo * mi)
{
Display *display = MI_DISPLAY(mi);
Window window = MI_WINDOW(mi);
crystalstruct *cryst = &crystals[MI_SCREEN(mi)];
int i;
#ifdef HAVE_JWXYZ /* Don't second-guess Quartz's double-buffering */
XClearWindow(MI_DISPLAY(mi), MI_WINDOW(mi));
#endif
if (cryst->no_colors) {
init_crystal(mi);
return;
}
/* Moved from init_crystal because you can't draw after MI_CLEARWINDOW in
XScreenSaver. - Dave Odell <dmo2118@gmail.com>
*/
if (cryst->unit_cell
#ifndef HAVE_JWXYZ
&& !cryst->painted
#endif
) {
int y_coor1 , y_coor2;
XSetForeground(display, cryst->gc, cryst->grid_pixel);
if (cryst->grid_cell) {
int inx, iny;
if ( cryst->invert )
y_coor1 = y_coor2 = cryst->win_height - cryst->offset_h;
else
y_coor1 = y_coor2 = cryst->offset_h;
XDrawLine(display, window, cryst->gc, cryst->offset_w,
y_coor1, cryst->offset_w + cryst->nx * cryst->a,
y_coor2);
if ( cryst->invert )
{
y_coor1 = cryst->win_height - cryst->offset_h;
y_coor2 = cryst->win_height - (int) (cryst->ny *
cryst->b *
cos((cryst->gamma - 90) * PI_RAD)) -
cryst->offset_h;
}
else
{
y_coor1 = cryst->offset_h;
y_coor2 = (int) (cryst->ny * cryst->b *
cos((cryst->gamma - 90) * PI_RAD)) +
cryst->offset_h;
}
XDrawLine(display, window, cryst->gc, cryst->offset_w,
y_coor1, (int) (cryst->offset_w - cryst->ny * cryst->b *
sin((cryst->gamma - 90) * PI_RAD)),
y_coor2);
inx = cryst->nx;
for (iny = 1; iny <= cryst->ny; iny++) {
if ( cryst->invert )
{
y_coor1 = cryst->win_height -
(int) (iny * cryst->b * cos((cryst->gamma - 90) *
PI_RAD)) - cryst->offset_h;
y_coor2 = cryst->win_height -
(int) (iny * cryst->b * cos((cryst->gamma - 90) *
PI_RAD)) -
cryst->offset_h;
}
else
{
y_coor1 = (int) (iny * cryst->b * cos((cryst->gamma - 90) *
PI_RAD)) + cryst->offset_h;
y_coor2 = (int) (iny * cryst->b * cos((cryst->gamma - 90) * PI_RAD)) +
cryst->offset_h;
}
XDrawLine(display, window, cryst->gc,
(int) (cryst->offset_w +
inx * cryst->a - (int) (iny * cryst->b *
sin((cryst->gamma - 90) * PI_RAD))),
y_coor1,
(int) (cryst->offset_w - iny * cryst->b *
sin((cryst->gamma - 90) * PI_RAD)),
y_coor2);
}
iny = cryst->ny;
for (inx = 1; inx <= cryst->nx; inx++) {
if ( cryst->invert )
{
y_coor1 =cryst->win_height -
(int) (iny * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) - cryst->offset_h;
y_coor2 =cryst->win_height - cryst->offset_h;
}
else
{
y_coor1 =(int) (iny * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) + cryst->offset_h;
y_coor2 =cryst->offset_h;
}
XDrawLine(display, window, cryst->gc,
(int) (cryst->offset_w +
inx * cryst->a - (int) (iny * cryst->b *
sin((cryst->gamma - 90) * PI_RAD))),
y_coor1,
cryst->offset_w + inx * cryst->a,
y_coor2);
}
} else {
if ( cryst->invert )
{
y_coor1 =cryst->win_height -
(int) (cryst->iny * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) -
cryst->offset_h;
y_coor2 =cryst->win_height -
(int) ( ( cryst->iny + 1 ) * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) -
cryst->offset_h;
}
else
{
y_coor1 =(int) (cryst->iny * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) +
cryst->offset_h;
y_coor2 =(int) (( cryst->iny + 1 ) * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) +
cryst->offset_h;
}
XDrawLine(display, window, cryst->gc,
cryst->offset_w + cryst->inx * cryst->a - (int) (cryst->iny * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor1,
cryst->offset_w + (cryst->inx + 1) * cryst->a - (int) (cryst->iny * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor1);
XDrawLine(display, window, cryst->gc,
cryst->offset_w + cryst->inx * cryst->a - (int) (cryst->iny * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor1,
cryst->offset_w + cryst->inx * cryst->a - (int) ((cryst->iny + 1) * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor2);
XDrawLine(display, window, cryst->gc,
cryst->offset_w + (cryst->inx + 1) * cryst->a - (int) (cryst->iny * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor1,
cryst->offset_w + (cryst->inx + 1) * cryst->a - (int) ((cryst->iny + 1) * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor2);
XDrawLine(display, window, cryst->gc,
cryst->offset_w + cryst->inx * cryst->a - (int) ((cryst->iny + 1) * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor2,
cryst->offset_w + (cryst->inx + 1) * cryst->a - (int) ((cryst->iny + 1) * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor2);
}
}
XSetFunction(display, cryst->gc, GXxor);
/* Rotate colours */
if (cryst->cycle_p) {
rotate_colors(mi->xgwa.screen, cryst->cmap,
cryst->colors, cryst->ncolors,
cryst->direction);
if (!(LRAND() % 1000))
cryst->direction = -cryst->direction;
}
for (i = 0; i < cryst->num_atom; i++) {
crystalatom *atom0;
atom0 = &cryst->atom[i];
if (MI_IS_INSTALL(mi) && MI_NPIXELS(mi) > 2) {
XSetForeground(display, cryst->gc, cryst->colors[atom0->colour].pixel);
} else {
XSetForeground(display, cryst->gc, atom0->colour);
}
#ifndef HAVE_JWXYZ
if(cryst->painted)
crystal_drawatom(mi, atom0);
#endif
atom0->velocity[0] += NRAND(3) - 1;
atom0->velocity[0] = MAX(-20, MIN(20, atom0->velocity[0]));
atom0->velocity[1] += NRAND(3) - 1;
atom0->velocity[1] = MAX(-20, MIN(20, atom0->velocity[1]));
atom0->x0 += atom0->velocity[0];
/*if (cryst->gamma == 90.0) { */
if (atom0->x0 < 0)
atom0->x0 += cryst->a;
else if (atom0->x0 >= cryst->a)
atom0->x0 -= cryst->a;
atom0->y0 += atom0->velocity[1];
if (atom0->y0 < 0)
atom0->y0 += cryst->b;
else if (atom0->y0 >= cryst->b)
atom0->y0 -= cryst->b;
/*} */
atom0->velocity_a += ((float) NRAND(1001) - 500.0) / 2000.0;
atom0->angle += atom0->velocity_a;
crystal_setupatom(atom0, cryst->gamma);
crystal_drawatom(mi, atom0);
}
XSetFunction(display, cryst->gc, GXcopy);
cryst->painted = True;
MI_IS_DRAWN(mi) = True;
}
#ifndef STANDALONE
ENTRYPOINT void
refresh_crystal(ModeInfo * mi)
{
Display *display = MI_DISPLAY(mi);
Window window = MI_WINDOW(mi);
crystalstruct *cryst = &crystals[MI_SCREEN(mi)];
int i;
if (!cryst->painted)
return;
MI_CLEARWINDOW(mi);
XSetFunction(display, cryst->gc, GXxor);
if (cryst->unit_cell) {
int y_coor1 , y_coor2;
if (MI_NPIXELS(mi) > 2)
XSetForeground(display, cryst->gc, MI_PIXEL(mi, NRAND(MI_NPIXELS(mi))));
else
XSetForeground(display, cryst->gc, MI_WHITE_PIXEL(mi));
if (cryst->grid_cell) {
int inx, iny;
if ( cryst->invert )
y_coor1 = y_coor2 = cryst->win_height - cryst->offset_h;
else
y_coor1 = y_coor2 = cryst->offset_h;
XDrawLine(display, window, cryst->gc, cryst->offset_w,
y_coor1, cryst->offset_w + cryst->nx * cryst->a,
y_coor2);
if ( cryst->invert )
{
y_coor1 = cryst->win_height - cryst->offset_h;
y_coor2 = cryst->win_height - (int) (cryst->ny *
cryst->b *
cos((cryst->gamma - 90) * PI_RAD)) -
cryst->offset_h;
}
else
{
y_coor1 = cryst->offset_h;
y_coor2 = (int) (cryst->ny * cryst->b *
cos((cryst->gamma - 90) * PI_RAD)) +
cryst->offset_h;
}
XDrawLine(display, window, cryst->gc, cryst->offset_w,
y_coor1, (int) (cryst->offset_w - cryst->ny * cryst->b *
sin((cryst->gamma - 90) * PI_RAD)),
y_coor2);
inx = cryst->nx;
for (iny = 1; iny <= cryst->ny; iny++) {
if ( cryst->invert )
{
y_coor1 = cryst->win_height -
(int) (iny * cryst->b * cos((cryst->gamma - 90) *
PI_RAD)) - cryst->offset_h;
y_coor2 = cryst->win_height -
(int) (iny * cryst->b * cos((cryst->gamma - 90) *
PI_RAD)) -
cryst->offset_h;
}
else
{
y_coor1 = (int) (iny * cryst->b * cos((cryst->gamma - 90) *
PI_RAD)) + cryst->offset_h;
y_coor2 = (int) (iny * cryst->b * cos((cryst->gamma - 90) * PI_RAD)) +
cryst->offset_h;
}
XDrawLine(display, window, cryst->gc,
(int) (cryst->offset_w +
inx * cryst->a - (int) (iny * cryst->b *
sin((cryst->gamma - 90) * PI_RAD))),
y_coor1,
(int) (cryst->offset_w - iny * cryst->b *
sin((cryst->gamma - 90) * PI_RAD)),
y_coor2);
}
iny = cryst->ny;
for (inx = 1; inx <= cryst->nx; inx++) {
if ( cryst->invert )
{
y_coor1 =cryst->win_height -
(int) (iny * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) - cryst->offset_h;
y_coor2 =cryst->win_height - cryst->offset_h;
}
else
{
y_coor1 =(int) (iny * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) + cryst->offset_h;
y_coor2 =cryst->offset_h;
}
XDrawLine(display, window, cryst->gc,
(int) (cryst->offset_w +
inx * cryst->a - (int) (iny * cryst->b *
sin((cryst->gamma - 90) * PI_RAD))),
y_coor1,
cryst->offset_w + inx * cryst->a,
y_coor2);
}
} else {
int inx, iny;
inx = NRAND(cryst->nx);
iny = NRAND(cryst->ny);
if ( cryst->invert )
{
y_coor1 =cryst->win_height -
(int) (iny * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) -
cryst->offset_h;
y_coor2 =cryst->win_height -
(int) ( ( iny + 1 ) * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) -
cryst->offset_h;
}
else
{
y_coor1 =(int) (iny * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) +
cryst->offset_h;
y_coor2 =(int) (( iny + 1 ) * cryst->b *
cos((cryst->gamma - 90) *
PI_RAD)) +
cryst->offset_h;
}
XDrawLine(display, window, cryst->gc,
cryst->offset_w + inx * cryst->a - (int) (iny * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor1,
cryst->offset_w + (inx + 1) * cryst->a - (int) (iny * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor1);
XDrawLine(display, window, cryst->gc,
cryst->offset_w + inx * cryst->a - (int) (iny * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor1,
cryst->offset_w + inx * cryst->a - (int) ((iny + 1) * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor2);
XDrawLine(display, window, cryst->gc,
cryst->offset_w + (inx + 1) * cryst->a - (int) (iny * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor1,
cryst->offset_w + (inx + 1) * cryst->a - (int) ((iny + 1) * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor2);
XDrawLine(display, window, cryst->gc,
cryst->offset_w + inx * cryst->a - (int) ((iny + 1) * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor2,
cryst->offset_w + (inx + 1) * cryst->a - (int) ((iny + 1) * cryst->b * sin((cryst->gamma - 90) * PI_RAD)),
y_coor2);
}
}
for (i = 0; i < cryst->num_atom; i++) {
crystalatom *atom0;
atom0 = &cryst->atom[i];
if (MI_IS_INSTALL(mi) && MI_NPIXELS(mi) > 2) {
XSetForeground(display, cryst->gc, cryst->colors[atom0->colour].pixel);
} else {
XSetForeground(display, cryst->gc, atom0->colour);
}
crystal_drawatom(mi, atom0);
}
XSetFunction(display, cryst->gc, GXcopy);
}
#endif
ENTRYPOINT void
free_crystal(ModeInfo * mi)
{
Display *display = MI_DISPLAY(mi);
crystalstruct *cryst = &crystals[MI_SCREEN(mi)];
if (MI_IS_INSTALL(mi) && MI_NPIXELS(mi) > 2) {
MI_WHITE_PIXEL(mi) = cryst->whitepixel;
MI_BLACK_PIXEL(mi) = cryst->blackpixel;
#ifndef STANDALONE
MI_FG_PIXEL(mi) = cryst->fg;
MI_BG_PIXEL(mi) = cryst->bg;
#endif
if (cryst->colors && cryst->ncolors && !cryst->no_colors)
free_colors(mi->xgwa.screen, cryst->cmap, cryst->colors,
cryst->ncolors);
if (cryst->colors)
(void) free((void *) cryst->colors);
#if 0 /* #### wrong! -jwz */
XFreeColormap(display, cryst->cmap);
#endif
}
if (cryst->gc != NULL)
XFreeGC(display, cryst->gc);
if (cryst->atom != NULL)
(void) free((void *) cryst->atom);
}
ENTRYPOINT void
init_crystal(ModeInfo * mi)
{
Display *display = MI_DISPLAY(mi);
crystalstruct *cryst;
int i, max_atoms, size_atom, neqv;
int cell_min;
#define MIN_CELL 200
/* initialize */
MI_INIT (mi, crystals);
cryst = &crystals[MI_SCREEN(mi)];
if (!cryst->gc) {
if (MI_IS_INSTALL(mi) && MI_NPIXELS(mi) > 2) {
XColor color;
#ifndef STANDALONE
extern char *background;
extern char *foreground;
cryst->fg = MI_FG_PIXEL(mi);
cryst->bg = MI_BG_PIXEL(mi);
#endif
cryst->blackpixel = MI_BLACK_PIXEL(mi);
cryst->whitepixel = MI_WHITE_PIXEL(mi);
#if 0 /* #### wrong! -jwz */
cryst->cmap = XCreateColormap(display, window,
MI_VISUAL(mi), AllocNone);
XSetWindowColormap(display, window, cryst->cmap);
#else
cryst->cmap = mi->xgwa.colormap;
#endif
(void) XParseColor(display, cryst->cmap, "black", &color);
(void) XAllocColor(display, cryst->cmap, &color);
MI_BLACK_PIXEL(mi) = color.pixel;
(void) XParseColor(display, cryst->cmap, "white", &color);
(void) XAllocColor(display, cryst->cmap, &color);
MI_WHITE_PIXEL(mi) = color.pixel;
#ifndef STANDALONE
(void) XParseColor(display, cryst->cmap, background, &color);
(void) XAllocColor(display, cryst->cmap, &color);
MI_BG_PIXEL(mi) = color.pixel;
(void) XParseColor(display, cryst->cmap, foreground, &color);
(void) XAllocColor(display, cryst->cmap, &color);
MI_FG_PIXEL(mi) = color.pixel;
#endif
cryst->colors = 0;
cryst->ncolors = 0;
}
if ((cryst->gc = XCreateGC(display, MI_WINDOW(mi),
(unsigned long) 0, (XGCValues *) NULL)) == None)
return;
}
/* Clear Display */
MI_CLEARWINDOW(mi);
cryst->painted = False;
XSetFunction(display, cryst->gc, GXxor);
/*Set up crystal data */
cryst->direction = (LRAND() & 1) ? 1 : -1;
if (MI_IS_FULLRANDOM(mi)) {
if (LRAND() & 1)
cryst->unit_cell = True;
else
cryst->unit_cell = False;
} else
cryst->unit_cell = unit_cell;
if (cryst->unit_cell) {
if (MI_IS_FULLRANDOM(mi)) {
if (LRAND() & 1)
cryst->grid_cell = True;
else
cryst->grid_cell = False;
} else
cryst->grid_cell = grid_cell;
}
cryst->win_width = MI_WIDTH(mi);
cryst->win_height = MI_HEIGHT(mi);
cell_min = min(cryst->win_width / 2 + 1, MIN_CELL);
cell_min = min(cell_min, cryst->win_height / 2 + 1);
cryst->planegroup = NRAND(17);
cryst->invert = NRAND(2);
if (MI_IS_VERBOSE(mi))
(void) fprintf(stdout, "Selected plane group no %d\n",
cryst->planegroup + 1);
if (cryst->planegroup > 11)
cryst->gamma = 120.0;
else if (cryst->planegroup < 2)
cryst->gamma = 60.0 + NRAND(60);
else
cryst->gamma = 90.0;
neqv = numops[2 * cryst->planegroup] - numops[2 * cryst->planegroup + 1];
if (centro[cryst->planegroup] == True)
neqv = 2 * neqv;
if (primitive[cryst->planegroup] == False)
neqv = 2 * neqv;
if (nx > 0)
cryst->nx = nx;
else if (nx < 0)
cryst->nx = NRAND(-nx) + 1;
else
cryst->nx = DEF_NX1;
if (cryst->planegroup > 8)
cryst->ny = cryst->nx;
else if (ny > 0)
cryst->ny = ny;
else if (ny < 0)
cryst->ny = NRAND(-ny) + 1;
else
cryst->ny = DEF_NY1;
neqv = neqv * cryst->nx * cryst->ny;
cryst->num_atom = MI_COUNT(mi);
max_atoms = MI_COUNT(mi);
if (cryst->num_atom == 0) {
cryst->num_atom = DEF_NUM_ATOM;
max_atoms = DEF_NUM_ATOM;
} else if (cryst->num_atom < 0) {
max_atoms = -cryst->num_atom;
cryst->num_atom = NRAND(-cryst->num_atom) + 1;
}
if (neqv > 1)
cryst->num_atom = cryst->num_atom / neqv + 1;
if (cryst->atom == NULL)
cryst->atom = (crystalatom *) calloc(max_atoms, sizeof (
crystalatom));
if (maxsize) {
if (cryst->planegroup < 13) {
cryst->gamma = 90.0;
cryst->offset_w = 0;
cryst->offset_h = 0;
if (cryst->planegroup < 10) {
cryst->b = cryst->win_height;
cryst->a = cryst->win_width;
} else {
cryst->b = min(cryst->win_height, cryst->win_width);
cryst->a = cryst->b;
}
} else {
cryst->gamma = 120.0;
cryst->a = (int) (cryst->win_width * 2.0 / 3.0);
cryst->b = cryst->a;
cryst->offset_h = (int) (cryst->b * 0.25 *
cos((cryst->gamma - 90) * PI_RAD));
cryst->offset_w = (int) (cryst->b * 0.5);
}
} else {
int max_repeat = 10;
cryst->offset_w = -1;
while (max_repeat-- &&
(cryst->offset_w < 4 || (int) (cryst->offset_w - cryst->b *
sin((cryst->gamma - 90) * PI_RAD)) < 4)
) {
cryst->b = NRAND((int) (cryst->win_height / (cos((cryst->gamma - 90) *
PI_RAD))) - cell_min) + cell_min;
if (cryst->planegroup > 8)
cryst->a = cryst->b;
else
cryst->a = NRAND(cryst->win_width - cell_min) + cell_min;
cryst->offset_w = (int) ((cryst->win_width - (cryst->a - cryst->b *
sin((cryst->gamma - 90) *
PI_RAD))) / 2.0);
}
cryst->offset_h = (int) ((cryst->win_height - cryst->b * cos((
cryst->gamma - 90) * PI_RAD)) / 2.0);
if (!centre) {
if (cryst->offset_h > 0)
cryst->offset_h = NRAND(2 * cryst->offset_h);
cryst->offset_w = (int) (cryst->win_width - cryst->a -
cryst->b *
fabs(sin((cryst->gamma - 90) * PI_RAD)));
if (cryst->gamma > 90.0) {
if (cryst->offset_w > 0)
cryst->offset_w = NRAND(cryst->offset_w) +
(int) (cryst->b * sin((cryst->gamma - 90) * PI_RAD));
else
cryst->offset_w = (int) (cryst->b * sin((cryst->gamma - 90) *
PI_RAD));
} else if (cryst->offset_w > 0)
cryst->offset_w = NRAND(cryst->offset_w);
else
cryst->offset_w = 0;
}
}
size_atom = min((int) ((float) (cryst->a) / 40.) + 1,
(int) ((float) (cryst->b) / 40.) + 1);
if (MI_SIZE(mi) < size_atom) {
if (MI_SIZE(mi) < -size_atom)
size_atom = -size_atom;
else
size_atom = MI_SIZE(mi);
}
cryst->a = cryst->a / cryst->nx;
cryst->b = cryst->b / cryst->ny;
if (MI_IS_INSTALL(mi) && MI_NPIXELS(mi) > 2) {
/* Set up colour map */
if (cryst->colors && cryst->ncolors && !cryst->no_colors)
free_colors(mi->xgwa.screen, cryst->cmap,
cryst->colors, cryst->ncolors);
if (cryst->colors)
(void) free((void *) cryst->colors);
cryst->colors = 0;
cryst->ncolors = MI_NCOLORS(mi);
if (cryst->ncolors < 2)
cryst->ncolors = 2;
if (cryst->ncolors <= 2)
cryst->mono_p = True;
else
cryst->mono_p = False;
if (cryst->mono_p)
cryst->colors = 0;
else
cryst->colors = (XColor *) malloc(sizeof (*cryst->colors) * (cryst->ncolors + 1));
cryst->cycle_p = has_writable_cells(mi->xgwa.screen, MI_VISUAL(mi));
if (cryst->cycle_p) {
if (MI_IS_FULLRANDOM(mi)) {
if (!NRAND(8))
cryst->cycle_p = False;
else
cryst->cycle_p = True;
} else {
cryst->cycle_p = cycle_p;
}
}
if (!cryst->mono_p) {
if (!(LRAND() % 10))
make_random_colormap(mi->xgwa.screen, MI_VISUAL(mi),
cryst->cmap, cryst->colors,
&cryst->ncolors,
True, True, &cryst->cycle_p, True);
else if (!(LRAND() % 2))
make_uniform_colormap(mi->xgwa.screen, MI_VISUAL(mi),
cryst->cmap, cryst->colors,
&cryst->ncolors, True,
&cryst->cycle_p, True);
else
make_smooth_colormap(mi->xgwa.screen, MI_VISUAL(mi),
cryst->cmap, cryst->colors,
&cryst->ncolors,
True, &cryst->cycle_p, True);
}
#if 0 /* #### wrong! -jwz */
XInstallColormap(display, cryst->cmap);
#endif
if (cryst->ncolors < 2) {
cryst->ncolors = 2;
cryst->no_colors = True;
} else
cryst->no_colors = False;
if (cryst->ncolors <= 2)
cryst->mono_p = True;
if (cryst->mono_p)
cryst->cycle_p = False;
}
for (i = 0; i < cryst->num_atom; i++) {
crystalatom *atom0;
atom0 = &cryst->atom[i];
if (MI_IS_INSTALL(mi) && MI_NPIXELS(mi) > 2) {
if (cryst->ncolors > 2)
atom0->colour = NRAND(cryst->ncolors - 2) + 2;
else
atom0->colour = 1; /* Just in case */
} else {
if (MI_NPIXELS(mi) > 2)
atom0->colour = MI_PIXEL(mi, NRAND(MI_NPIXELS(mi)));
else
atom0->colour = 1; /*Xor'red so WHITE may not be appropriate */
}
atom0->x0 = NRAND(cryst->a);
atom0->y0 = NRAND(cryst->b);
atom0->velocity[0] = NRAND(7) - 3;
atom0->velocity[1] = NRAND(7) - 3;
atom0->velocity_a = (NRAND(7) - 3) * PI_RAD;
atom0->angle = NRAND(90) * PI_RAD;
atom0->at_type = NRAND(3);
if (size_atom == 0)
atom0->size_at = DEF_SIZ_ATOM;
else if (size_atom > 0)
atom0->size_at = size_atom;
else
atom0->size_at = NRAND(-size_atom) + 1;
atom0->size_at++;
if (atom0->at_type == 2)
atom0->num_point = 3;
else
atom0->num_point = 4;
crystal_setupatom(atom0, cryst->gamma);
}
XSetFunction(display, cryst->gc, GXcopy);
if (MI_NPIXELS(mi) > 2)
cryst->grid_pixel = MI_PIXEL(mi, NRAND(MI_NPIXELS(mi)));
else
cryst->grid_pixel = MI_WHITE_PIXEL(mi);
cryst->inx = NRAND(cryst->nx);
cryst->iny = NRAND(cryst->ny);
}
XSCREENSAVER_MODULE ("Crystal", crystal)