| | |
| | | //END MONTE CARLOOOOOOO |
| | | return TS_SUCCESS; |
| | | } |
| | | |
| | | |
| | | |
| | | |
| | | ts_bool single_filament_vertex_move(ts_vesicle *vesicle,ts_poly *poly,ts_vertex *vtx,ts_double *rn){ |
| | | ts_uint i; |
| | | ts_bool retval; |
| | | ts_uint cellidx; |
| | | // ts_double delta_energy; |
| | | ts_double costheta,sintheta,phi,r; |
| | | ts_double dist[2]; |
| | | //This will hold all the information of vtx and its neighbours |
| | | ts_vertex backupvtx; |
| | | ts_bond backupbond[2]; |
| | | memcpy((void *)&backupvtx,(void *)vtx,sizeof(ts_vertex)); |
| | | |
| | | //random move in a sphere with radius stepsize: |
| | | r=vesicle->stepsize*rn[0]; |
| | | phi=rn[1]*2*M_PI; |
| | | costheta=2*rn[2]-1; |
| | | sintheta=sqrt(1-pow(costheta,2)); |
| | | vtx->x=vtx->x+r*sintheta*cos(phi); |
| | | vtx->y=vtx->y+r*sintheta*sin(phi); |
| | | vtx->z=vtx->z+r*costheta; |
| | | |
| | | |
| | | //distance with neighbours check |
| | | for(i=0;i<vtx->bond_no;i++){ |
| | | dist[i]=vtx_distance_sq(vtx->bond[i]->vtx1,vtx->bond[i]->vtx2); |
| | | if(dist[i]<1.0 || dist[i]>vesicle->dmax) { |
| | | vtx=memcpy((void *)vtx,(void *)&backupvtx,sizeof(ts_vertex)); |
| | | return TS_FAIL; |
| | | } |
| | | } |
| | | |
| | | |
| | | //self avoidance check with distant vertices |
| | | cellidx=vertex_self_avoidance(vesicle, vtx); |
| | | //check occupation number |
| | | retval=cell_occupation_number_and_internal_proximity(vesicle->clist,cellidx,vtx); |
| | | |
| | | if(retval==TS_FAIL){ |
| | | vtx=memcpy((void *)vtx,(void *)&backupvtx,sizeof(ts_vertex)); |
| | | return TS_FAIL; |
| | | } |
| | | |
| | | //backup bonds |
| | | for(i=0;i<vtx->bond_no;i++){ |
| | | memcpy(&backupbond[i],vtx->bond[i], sizeof(ts_bond)); |
| | | vtx->bond[i]->bond_length=sqrt(dist[i]); |
| | | bond_vector(vtx->bond[i]); |
| | | |
| | | } |
| | | |
| | | //if all the tests are successful, then energy for vtx and neighbours is calculated |
| | | // delta_energy=0; |
| | | /* for(i=0;i<vtx->neigh_no;i++){ |
| | | // memcpy((void *)&backupbond[i],(void *)vtx->bond[i],sizeof(ts_bond)); |
| | | xp = vtx->neigh[i] |
| | | vtx->bond[i]->bond_length=sqrt(vtx_distance_sq(vtx->bond[i]->vtx1,vtx->bond[i]->vtx2)); |
| | | bond_energy(vtx->bond[i],poly); |
| | | delta_energy+= vtx->bond[i]->energy - backupbond[i].energy; |
| | | } |
| | | |
| | | if(vtx==poly->vlist->vtx[0]){ |
| | | delta_energy+= |
| | | (pow(sqrt(vtx_distance_sq(vtx, poly->grafted_vtx)-1),2)- |
| | | pow(sqrt(vtx_distance_sq(&backupvtx, poly->grafted_vtx)-1),2)) *poly->k; |
| | | |
| | | } |
| | | |
| | | |
| | | if(delta_energy>=0){ |
| | | #ifdef TS_DOUBLE_DOUBLE |
| | | if(exp(-delta_energy)< drand48() ) |
| | | #endif |
| | | #ifdef TS_DOUBLE_FLOAT |
| | | if(expf(-delta_energy)< (ts_float)drand48()) |
| | | #endif |
| | | #ifdef TS_DOUBLE_LONGDOUBLE |
| | | if(expl(-delta_energy)< (ts_ldouble)drand48()) |
| | | #endif |
| | | { |
| | | //not accepted, reverting changes |
| | | vtx=memcpy((void *)vtx,(void *)&backupvtx,sizeof(ts_vertex)); |
| | | for(i=0;i<vtx->bond_no;i++){ |
| | | vtx->bond[i]=memcpy((void *)vtx->bond[i],(void *)&backupbond[i],sizeof(ts_bond)); |
| | | } |
| | | |
| | | return TS_FAIL; |
| | | } |
| | | } |
| | | |
| | | */ |
| | | // oldcellidx=vertex_self_avoidance(vesicle, &backupvtx[0]); |
| | | if(vtx->cell!=vesicle->clist->cell[cellidx]){ |
| | | retval=cell_add_vertex(vesicle->clist->cell[cellidx],vtx); |
| | | // if(retval==TS_SUCCESS) cell_remove_vertex(vesicle->clist->cell[oldcellidx],vtx); |
| | | if(retval==TS_SUCCESS) cell_remove_vertex(backupvtx.cell,vtx); |
| | | } |
| | | // if(oldcellidx); |
| | | //END MONTE CARLOOOOOOO |
| | | return TS_SUCCESS; |
| | | } |