Trisurf Monte Carlo simulator
Samo Penic
2014-02-11 23d807748be58e5178c04304d9cc788bf122eb12
src/energy.c
@@ -23,29 +23,29 @@
inline ts_bool energy_vertex(ts_vertex *vtx){
//    ts_vertex *vtx=&vlist->vertex[n]-1; // Caution! 0 Indexed value!
//    ts_triangle *tristar=vtx->tristar-1;
    ts_vertex_data *data=vtx->data;
    //ts_vertex_data *data=vtx->data;
    ts_uint jj;
    ts_uint jjp,jjm;
    ts_vertex *j,*jp, *jm;
    ts_triangle *jt;
    ts_double s=0,xh=0,yh=0,zh=0,txn=0,tyn=0,tzn=0;
    ts_double s=0.0,xh=0.0,yh=0.0,zh=0.0,txn=0.0,tyn=0.0,tzn=0.0;
    ts_double x1,x2,x3,ctp,ctm,tot,xlen;
    ts_double h,ht;
    for(jj=1; jj<=data->neigh_no;jj++){
    for(jj=1; jj<=vtx->neigh_no;jj++){
        jjp=jj+1;
        if(jjp>data->neigh_no) jjp=1;
        if(jjp>vtx->neigh_no) jjp=1;
        jjm=jj-1;
        if(jjm<1) jjm=data->neigh_no;
        j=data->neigh[jj-1];
        jp=data->neigh[jjp-1];
        jm=data->neigh[jjm-1];
        if(jjm<1) jjm=vtx->neigh_no;
        j=vtx->neigh[jj-1];
        jp=vtx->neigh[jjp-1];
        jm=vtx->neigh[jjm-1];
//        printf("tristar_no=%u, neigh_no=%u, jj=%u\n",data->tristar_no,data->neigh_no,jj);
        jt=data->tristar[jj-1];
        jt=vtx->tristar[jj-1];
        x1=vtx_distance_sq(vtx,jp); //shouldn't be zero!
        x2=vtx_distance_sq(j,jp); // shouldn't be zero!
        x3=(j->data->x-jp->data->x)*(data->x-jp->data->x)+
           (j->data->y-jp->data->y)*(data->y-jp->data->y)+
           (j->data->z-jp->data->z)*(data->z-jp->data->z);
        x3=(j->x-jp->x)*(vtx->x-jp->x)+
           (j->y-jp->y)*(vtx->y-jp->y)+
           (j->z-jp->z)*(vtx->z-jp->z);
        
#ifdef TS_DOUBLE_DOUBLE
        ctp=x3/sqrt(x1*x2-x3*x3);
@@ -58,9 +58,9 @@
#endif
        x1=vtx_distance_sq(vtx,jm);
        x2=vtx_distance_sq(j,jm);
        x3=(j->data->x-jm->data->x)*(data->x-jm->data->x)+
           (j->data->y-jm->data->y)*(data->y-jm->data->y)+
           (j->data->z-jm->data->z)*(data->z-jm->data->z);
        x3=(j->x-jm->x)*(vtx->x-jm->x)+
           (j->y-jm->y)*(vtx->y-jm->y)+
           (j->z-jm->z)*(vtx->z-jm->z);
#ifdef TS_DOUBLE_DOUBLE
        ctm=x3/sqrt(x1*x2-x3*x3);
#endif
@@ -72,23 +72,25 @@
#endif
        tot=ctp+ctm;
        tot=0.5*tot;
        xlen=vtx_distance_sq(j,vtx);
/*
#ifdef  TS_DOUBLE_DOUBLE 
        data->bond[jj-1]->data->bond_length=sqrt(xlen);
        vtx->bond[jj-1]->bond_length=sqrt(xlen);
#endif
#ifdef  TS_DOUBLE_FLOAT
        data->bond[jj-1]->data->bond_length=sqrtf(xlen);
        vtx->bond[jj-1]->bond_length=sqrtf(xlen);
#endif
#ifdef  TS_DOUBLE_LONGDOUBLE 
        data->bond[jj-1]->data->bond_length=sqrtl(xlen);
        vtx->bond[jj-1]->bond_length=sqrtl(xlen);
#endif
        data->bond[jj-1]->data->bond_length_dual=tot*data->bond[jj-1]->data->bond_length;
        vtx->bond[jj-1]->bond_length_dual=tot*vtx->bond[jj-1]->bond_length;
*/
        s+=tot*xlen;
        xh+=tot*(j->data->x - data->x);
        yh+=tot*(j->data->y - data->y);
        zh+=tot*(j->data->z - data->z);
        xh+=tot*(j->x - vtx->x);
        yh+=tot*(j->y - vtx->y);
        zh+=tot*(j->z - vtx->z);
        txn+=jt->xnorm;
        tyn+=jt->ynorm;
        tzn+=jt->znorm;
@@ -99,29 +101,29 @@
    s=s/4.0; 
#ifdef TS_DOUBLE_DOUBLE
    if(ht>=0.0) {
        data->curvature=sqrt(h);
        vtx->curvature=sqrt(h);
    } else {
        data->curvature=-sqrt(h);
        vtx->curvature=-sqrt(h);
    }
#endif
#ifdef TS_DOUBLE_FLOAT
    if(ht>=0.0) {
        data->curvature=sqrtf(h);
        vtx->curvature=sqrtf(h);
    } else {
        data->curvature=-sqrtf(h);
        vtx->curvature=-sqrtf(h);
    }
#endif
#ifdef TS_DOUBLE_LONGDOUBLE
    if(ht>=0.0) {
        data->curvature=sqrtl(h);
        vtx->curvature=sqrtl(h);
    } else {
        data->curvature=-sqrtl(h);
        vtx->curvature=-sqrtl(h);
    }
#endif
// What is vtx->data->c?????????????? Here it is 0!
// What is vtx->c?????????????? Here it is 0!
// c is forced curvature energy for each vertex. Should be set to zero for
// norman circumstances.
    data->energy=0.5*s*(data->curvature/s-data->c)*(data->curvature/s-data->c);
// normal circumstances.
    vtx->energy=0.5*s*(vtx->curvature/s-vtx->c)*(vtx->curvature/s-vtx->c);
    return TS_SUCCESS;
}