void calcnormals(Gobject *o, int mallocnormals){
int aktpoly = -1,
edges,i1,i2,i3,
normanz = 0,
aktnorm = 0;
vec norm;
double erg;
while ((edges = o->polygons[++aktpoly])!=0){
normanz++;
aktpoly+=edges+2;
}
/* printf("Calcnormals.Normanzahl:%i\n",normanz);*/
if (mallocnormals)
o->na=malloc(sizeof(vec)*normanz);
aktpoly=0;
for (aktnorm=0;aktnorm<normanz;aktnorm++){
i1=o->polygons[aktpoly+3];
i2=o->polygons[aktpoly+4];
i3=o->polygons[aktpoly+5];
veq(norm,vnorm(vp(vdiff(o->va[i2],o->va[i1]),vdiff(o->va[i3],o->va[i1]))));
if (o->type==V3DPOLYHEDRON){
erg=sp(vdiff(o->va[i1],o->posmc),norm);vreset();
if (erg<0) veq(norm,sm(-1,norm));
if (erg==0){printf("Fehler in calcnormals: Normale nicht definiert\n"); }
}
/* pv(norm);*/
veq(o->na[aktnorm],norm);
o->polygons[aktpoly+1]=aktnorm;
aktpoly+=o->polygons[aktpoly]+3;
}
}
/* apply the constraints with SHAKE and RATTTLE */
static void constrain(int itmax, double tol)
{
int i, it;
double vl, dev, maxdev, dot;
double dx0[N][D], dx[D], dv[D];
for ( i = 1; i < N; i++ ) {
vdiff(dx0[i], x[i], x[0]);
}
/* SHAKE */
for ( it = 0; it < itmax; it++ ) {
maxdev = 0;
for ( i = 1; i < N; i++ ) {
/* constraint the distance between atoms 0 and i */
vdiff(dx, x[i], x[0]);
dev = vsqr(dx) - 1;
if ( dev > maxdev ) maxdev = dev;
dot = vdot(dx, dx0[i]);
if ( dot < 0.2 ) { /* really bad */
dot = 0.2;
}
dev = dev / (2 * dot);
vsinc(x[i], dx0[i], -dev * 0.5);
vsinc(x[0], dx0[i], dev * 0.5);
}
if ( maxdev < tol ) break;
}
/* RATTLE */
for ( it = 0; it < itmax; it++ ) {
maxdev = 0;
for ( i = 1; i < N; i++ ) {
/* annihilate the parallel velocity */
vdiff(dx, x[i], x[0]);
vdiff(dv, v[i], v[0]);
/* the relative velocity should be perpendicular
* to dr, if not, subtract the nonperpendicular one */
vl = vdot(dv, dx);
/* because the reference length is 1.0
* we do not have to divide it */
vsinc(v[i], dx, -vl * 0.5);
vsinc(v[0], dx, +vl * 0.5);
dev = fabs(vl);
if ( dev > maxdev ) {
maxdev = dev;
}
}
if ( maxdev < tol ) break;
}
}
void flaeche_3d(int c,vecp rp, vecp v1p,vecp v2p,int n1, int n2){
int i,j;
vec r,r2,v1,v2;
veq(r,mc2wc(rp));
veq(v1,sm(1.0/n1,vdiff(mc2wc(vsum(rp,v1p)),r)));
veq(v2,sm(1.0/n2,vdiff(mc2wc(vsum(rp,v2p)),r)));
/* veq(v1,mc2wcnorm(v1p)));
veq(v2,sm(1.0/n2,mc2wcnorm(v2p)));*/
veq(r2,vsum(r,sm(0.5,vsum(v1,v2))));
for (i=0;i<n1;i++)
for (j=0;j<n2;j++)
einfache_flaeche_wc_3d(c,
vsum(r2,vsum(sm(1.0*i,v1),sm(1.0*j,v2))),
vsum(r,vsum(sm(1.0*i,v1),sm(1.0*j,v2))),
vsum(r,vsum(sm(1.0*(i+1),v1),sm(1.0*j,v2))),
vsum(r,vsum(sm(1.0*(i+1),v1),sm(1.0*(j+1),v2))),
vsum(r,vsum(sm(1.0*i,v1),sm(1.0*(j+1),v2))));
}
/* bond energy 1/2 k (r - r0)^2 */
static double potbond(double *a, double *b,
double r0, double kr, double *fa, double *fb)
{
double dx[D], r, dr, amp;
r = vnorm( vdiff(dx, a, b) );
dr = r - r0;
amp = kr * dr / r;
vsinc(fa, dx, -amp);
vsinc(fb, dx, amp);
return 0.5 * kr * dr * dr;
}
void contour3d(Contour* c){
int i,j,*k;
vecp v;
matp m;
if (c->initialized==0){
c->tva=malloc((c->vaakt+1)*sizeof(vec));
c->na=malloc((c->polakt+1)*sizeof(vec));
c->sp=malloc((c->polakt+1)*sizeof(vec));
c->points=malloc((c->polakt+1)*sizeof(DPoint));
c->Garray=malloc((c->polakt+1)*sizeof(Gobject));
for (i=0;i<=c->polakt;i++) {
c->Garray[i].na=c->na;
c->Garray[i].tva=c->tva;
c->Garray[i].poswc=(vecp) &c->sp[i]; /* compiler distinguishes between
vec* and vecp */
c->Garray[i].points=c->points;
c->Garray[i].polygons=&c->pol[i*6];
c->Garray[i].drawstruct=drawtrianglelight;
j=c->pol[i*6];
veq(c->na[i],vnorm(vp(vdiff(c->va[j+4],c->va[j+3]),vdiff(c->va[j+5],c->va[j+3]))));
}
c->initialized=1;
}
/* Transformation, die jedes Mal durchlaufen wird. */
meq(c->mc2wcmn,getmc2wcmn());
meq(c->mc2wcm,getmc2wcm());
veq(c->mc2wcv,getmc2wcv());
m=c->mc2wcm;
v=c->mc2wcv;
for (i=0;i<=c->vaakt;i++) {
veq(c->tva[i],vsum(matvecmul(m,c->va[i]),v));
wc2dc(&c->points[i].x,&c->points[i].y,c->tva[i]);
}
for (i=0;i<=c->polakt;i++){ /* Schwerpunkt in Weltkoordinaten */
k=&c->pol[i*6+3];
veq(c->sp[i],sm(0.33333,
vsum(vsum(c->tva[*k],c->tva[*(k+1)]),c->tva[*(k+2)])));
insertGobject(&c->Garray[i]);
}
}
void KDTree::n_nearest(std::vector<float>& qv, int nn, KDTreeResultVector& result) {
SearchRecord sr(qv, *this, result);
std::vector<float> vdiff(dim, 0.0);
result.clear();
sr.centeridx = -1;
sr.correltime = 0;
sr.nn = nn;
root->search(sr);
if (sort_results) sort(result.begin(), result.end());
}
void KDTree::r_nearest(std::vector<float>& qv, float r2, KDTreeResultVector& result) {
// search for all within a ball of a certain radius
SearchRecord sr(qv, *this, result);
std::vector<float> vdiff(dim, 0.0);
result.clear();
sr.centeridx = -1;
sr.correltime = 0;
sr.nn = 0;
sr.ballsize = r2;
root->search(sr);
if (sort_results) sort(result.begin(), result.end());
}
void
DoFlares(GLfloat from[3], GLfloat at[3], GLfloat light[3], GLfloat near_clip)
{
GLfloat view_dir[3], tmp[3], light_dir[3], position[3], dx[3], dy[3],
center[3], axis[3], sx[3], sy[3], dot, global_scale = 1.5;
GLuint bound_to = 0;
int i;
/* view_dir = normalize(at-from) */
vdiff(view_dir, at, from);
vnorm(view_dir);
/* center = from + near_clip * view_dir */
vscale(tmp, view_dir, near_clip);
vadd(center, from, tmp);
/* light_dir = normalize(light-from) */
vdiff(light_dir, light, from);
vnorm(light_dir);
/* light = from + dot(light,view_dir)*near_clip*light_dir */
dot = vdot(light_dir, view_dir);
vscale(tmp, light_dir, near_clip / dot);
vadd(light, from, light_dir);
/* axis = light - center */
vdiff(axis, light, center);
vcopy(dx, axis);
/* dx = normalize(axis) */
vnorm(dx);
/* dy = cross(dx,view_dir) */
vcross(dy, dx, view_dir);
glDisable(GL_DEPTH_TEST);
glDisable(GL_DITHER);
glEnable(GL_BLEND);
glBlendFunc(GL_ONE, GL_ONE);
for (i = 0; i < num_flares; i++) {
vscale(sx, dx, flare[i].scale * global_scale);
vscale(sy, dy, flare[i].scale * global_scale);
glColor3fv(flare[i].color);
/* Note logic below to eliminate duplicate texture binds. */
if (flare[i].type < 0) {
if (bound_to)
glEnd();
glBindTexture(GL_TEXTURE_2D, shineTex[shine_tic]);
bound_to = shineTex[shine_tic];
shine_tic = (shine_tic + 1) % 10;
glBegin(GL_QUADS);
} else {
if (bound_to != flareTex[flare[i].type]) {
glEnd();
glBindTexture(GL_TEXTURE_2D, flareTex[flare[i].type]);
bound_to = flareTex[flare[i].type];
glBegin(GL_QUADS);
}
}
/* position = center + flare[i].loc * axis */
vscale(tmp, axis, flare[i].loc);
vadd(position, center, tmp);
glTexCoord2f(0.0, 0.0);
vadd(tmp, position, sx);
vadd(tmp, tmp, sy);
glVertex3fv(tmp);
glTexCoord2f(1.0, 0.0);
vdiff(tmp, position, sx);
vadd(tmp, tmp, sy);
glVertex3fv(tmp);
glTexCoord2f(1.0, 1.0);
vdiff(tmp, position, sx);
vdiff(tmp, tmp, sy);
glVertex3fv(tmp);
glTexCoord2f(0.0, 1.0);
vadd(tmp, position, sx);
vdiff(tmp, tmp, sy);
glVertex3fv(tmp);
}
glEnd();
}
