Trisurf Monte Carlo simulator
blame | history | patch | commit | commitdiff | ignore whitespace
Samo Penic
2019-02-11 36bc6d58f7f1b83ae07c00ce7f42755bedbcff18 
 src/poly.c


@@ -7,6 +7,7 @@


#include<math.h>


#include"energy.h"


#include"cell.h"


#include"frame.h"


ts_bool poly_assign_filament_xi(ts_vesicle *vesicle, ts_tape *tape){


   ts_uint i;




@@ -47,49 +48,20 @@


   poly->blist->bond[i]->bond_length=sqrt(vtx_distance_sq(poly->blist->bond[i]->vtx1,poly->blist->bond[i]->vtx2));


   bond_energy(poly->blist->bond[i],poly);


   }




   vertex_list_assign_id(poly->vlist,TS_ID_FILAMENT);


   return poly;


}






ts_poly_list *init_poly_list(ts_uint n_poly, ts_uint n_mono, ts_vertex_list *vlist, ts_vesicle *vesicle){


   ts_poly_list *poly_list=(ts_poly_list *)calloc(1,sizeof(ts_poly_list));


   poly_list->poly   = (ts_poly **)calloc(n_poly,sizeof(ts_poly *));


   ts_uint i=0,j=0,k; //idx;


   ts_uint gvtxi;


   ts_double xnorm,ynorm,znorm,normlength;


   ts_double dphi,dh;




   // Grafting polymers:


   if (vlist!=NULL){


      if (n_poly > vlist->n){fatal("Number of polymers larger than numbero f vertices on a vesicle.",310);}


	


      while(i<n_poly){


         gvtxi = rand() % vlist->n;


         if (vlist->vtx[gvtxi]->grafted_poly == NULL){


         poly_list->poly[i] = init_poly(n_mono, vlist->vtx[gvtxi]);


         i++;


         }


      }


   }


   else


   {


      for(i=0;i<n_poly;i++){


         poly_list->poly[i] = init_poly(n_mono, NULL);


      }


   }




   poly_list->n = n_poly;




   if (vlist!=NULL){


ts_bool poly_initial_distribution(ts_poly_list *poly_list, ts_int i, ts_vesicle *vesicle){


   /* Make straight grafted poylmers normal to membrane (polymer brush). Dist. between poly vertices put to 1*/


      ts_double xnorm,ynorm,znorm,normlength;


      ts_int intpoly=vesicle->tape->internal_poly;


      ts_int cellidx;


      ts_double posX,posY,posZ,prevPosX,prevPosY,prevPosZ, phi,theta;


      ts_double posX,posY,posZ,prevPosX,prevPosY,prevPosZ, phi,costheta,sintheta;


      ts_bool retval;


      ts_int l;


      for (i=0;i<poly_list->n;i++){


	


      ts_int j,k,l,m;


         xnorm=0.0;


         ynorm=0.0;


         znorm=0.0;


@@ -105,104 +77,123 @@


         xnorm=xnorm/normlength;


         ynorm=ynorm/normlength;


         znorm=znorm/normlength;




         //prepare starting position for building the polymeres


         prevPosX=poly_list->poly[i]->grafted_vtx->x;


         prevPosY=poly_list->poly[i]->grafted_vtx->y;


         prevPosZ=poly_list->poly[i]->grafted_vtx->z;


         for (j=0;j<poly_list->poly[i]->vlist->n;j++){


            //if(j==0){


               posX=prevPosX+xnorm*(vesicle->clist->dmin_interspecies);


               posY=prevPosY+ynorm*(vesicle->clist->dmin_interspecies);


               posZ=prevPosZ+znorm*(vesicle->clist->dmin_interspecies);


            //}else{


            //   posX=prevPosX+xnorm;


            //   posY=prevPosY+ynorm;


            //   posZ=prevPosZ+znorm;


            //}


            //trying to go towards normal


            posX=prevPosX+(ts_double)xnorm;


            posY=prevPosY+(ts_double)ynorm;


            posZ=prevPosZ+(ts_double)znorm;


            k=0;


            l=0;


            while(1){


               poly_list->poly[i]->vlist->vtx[j]->x = posX;


               poly_list->poly[i]->vlist->vtx[j]->y = posY;


               poly_list->poly[i]->vlist->vtx[j]->z = posZ;


               cellidx=vertex_self_avoidance(vesicle, poly_list->poly[i]->vlist->vtx[j]);


               //distance from neighbors


               //retval=TS_SUCCESS;


               /*for(k=0;k<poly_list->poly[i]->vlist->vtx[j]->neigh_no;k++){


                  dist=vtx_distance_sq(poly_list->poly[i]->vlist->vtx[j],poly_list->poly[i]->vlist->vtx[j]->neigh[k]);


                  if(dist<1.0 || dist>vesicle->dmax){


                     retval=TS_FAIL;


                     printf("dist_fail! %e\n", dist);


                  }


               }*/


               //if(retval!=TS_FAIL){


                  //check occupation number


                  retval=cell_occupation_number_and_internal_proximity(vesicle->clist,cellidx,poly_list->poly[i]->vlist->vtx[j]);


               //}


               retval=cell_occupation_number_and_internal_proximity(vesicle->clist,cellidx,poly_list->poly[i]->vlist->vtx[j]);


               if(retval==TS_SUCCESS){


                  retval=cell_add_vertex(vesicle->clist->cell[cellidx],poly_list->poly[i]->vlist->vtx[j]);


                  break;


               }


               else{


            //      printf("%d %d Cannot put the vesicle here. Finding another position\n",i,j);


                  theta=drand48()*M_PI-M_PI/2;


                  phi=drand48()*2*M_PI;


                  posX=prevPosX+sin(phi)*cos(theta);


                  posY=prevPosY+sin(phi)*sin(theta);


                  posZ=prevPosZ+cos(theta);


                  //randomly change the normal.


               }


               k++;


               if(k>1000){


                  //lets choose another grafting vertex;


                  while(1){


                     gvtxi = rand() % vesicle->vlist->n;


                     if (vesicle->vlist->vtx[gvtxi]->grafted_poly == NULL){


                        ts_fprintf(stdout,"Found new potential grafting vertex %d for poly %d\n",gvtxi,i);


                        poly_list->poly[i]->grafted_vtx->grafted_poly=NULL;


                        poly_list->poly[i]->grafted_vtx = vesicle->vlist->vtx[gvtxi];


                        vesicle->vlist->vtx[gvtxi]->grafted_poly = poly_list->poly[i];


                        l++;


                        k=0;


               //   printf("%d %d Cannot put the vertex here. Finding another position\n",i,j);


                  //randomly change the direction.


                  m=0;


                  //we must move first vertex into the vesicle if the normal is in or out of the vesicle if the normal is out


                  do{


                     costheta=2.0*drand48()-1.0;


                     sintheta=sqrt(1-pow(costheta,2));


                     phi=drand48()*2.0*M_PI;


                     if(j==0){


                  //for special cases, when we are on the edge of bipyramid  the distance od dmin_interspecies is not enough


                        posX=prevPosX+vesicle->dmax*sintheta*cos(phi);


                        posY=prevPosY+vesicle->dmax*sintheta*sin(phi);


                        posZ=prevPosZ+vesicle->dmax*costheta;










         xnorm=0.0;


         ynorm=0.0;


         znorm=0.0;


         int o;


         for (o=0;o<poly_list->poly[i]->grafted_vtx->tristar_no;o++){


            xnorm-=poly_list->poly[i]->grafted_vtx->tristar[o]->xnorm;


            ynorm-=poly_list->poly[i]->grafted_vtx->tristar[o]->ynorm;


            znorm-=poly_list->poly[i]->grafted_vtx->tristar[o]->znorm;	


         }


         normlength=sqrt(xnorm*xnorm+ynorm*ynorm+znorm*znorm);


         if(intpoly && i%2){


            normlength=-normlength;


         }


         xnorm=xnorm/normlength;


         ynorm=ynorm/normlength;


         znorm=znorm/normlength;




         //prepare starting position for building the polymeres


         posX=poly_list->poly[i]->grafted_vtx->x+xnorm;


         posY=poly_list->poly[i]->grafted_vtx->y+ynorm;


         posZ=poly_list->poly[i]->grafted_vtx->z+znorm;


			












                     } else {


                        posX=prevPosX+vesicle->clist->dmin_interspecies*sintheta*cos(phi);


                        posY=prevPosY+vesicle->clist->dmin_interspecies*sintheta*sin(phi);


                        posZ=prevPosZ+vesicle->clist->dmin_interspecies*costheta;


                     }


                     m++;


                     if(m>1000) {


                        k=9999; //break also ot of the outer loop


                        printf("was here\n");


                        break;


                     }


                  }


                  if(l>1000)


                     fatal("Cannot make internal polymeres. No space inside the vesicle?",1001);


                  while((xnorm*(poly_list->poly[i]->grafted_vtx->x-posX)+ynorm*(poly_list->poly[i]->grafted_vtx->y-posY)+znorm*(poly_list->poly[i]->grafted_vtx->z-posZ))>0.0 && j==0);


               }


               k++;


               if(k>1000){


                  //undo changes to the cell


                  for(l=0;l<j;l++){


                     cellidx=vertex_self_avoidance(vesicle, poly_list->poly[i]->vlist->vtx[l]);


                     cell_remove_vertex(vesicle->clist->cell[cellidx],poly_list->poly[i]->vlist->vtx[l]);


                  }


                  return TS_FAIL;


               }


            }


            prevPosX=posX;


            prevPosY=posY;


            prevPosZ=posZ;


         }


   printf("did it\n");


   return TS_SUCCESS;




}






ts_poly_list *init_poly_list(ts_uint n_poly, ts_uint n_mono, ts_vertex_list *vlist, ts_vesicle *vesicle){


   ts_poly_list *poly_list=(ts_poly_list *)calloc(1,sizeof(ts_poly_list));


   poly_list->poly   = (ts_poly **)calloc(n_poly,sizeof(ts_poly *));


   ts_uint i=0,j=0; //idx;


   ts_uint gvtxi;


   ts_bool retval;


   ts_double dphi,dh;


   cell_occupation(vesicle); //needed for evading the membrane


   // Grafting polymers:


   int tries=0;


   if (vlist!=NULL){


      if (n_poly > vlist->n){fatal("Number of polymers larger than numbero f vertices on a vesicle.",310);}


      while(i<n_poly){


         gvtxi = rand() % vlist->n;


         if (vlist->vtx[gvtxi]->grafted_poly == NULL){


            poly_list->poly[i] = init_poly(n_mono, vlist->vtx[gvtxi]);


            retval=poly_initial_distribution(poly_list, i, vesicle);


            if(retval==TS_FAIL){


               ts_fprintf(stdout,"Found new potential grafting vertex %d for poly %d\n",gvtxi,i);


               poly_free(poly_list->poly[i]);


               tries++;


            }


            else {


               tries=0;


               i++;


            }


            if(tries>5000){


               fatal("Cannot find space for inner polymeres",1001);


            }


         }


      }


   }


   else


   {


      for(i=0;i<n_poly;i++){


         poly_list->poly[i] = init_poly(n_mono, NULL);


      }


   }




   poly_list->n = n_poly;




   if (vlist!=NULL){


   }


   else


   {


@@ -244,16 +235,16 @@


      }


   }


*/




	


   return poly_list;


}






ts_bool poly_free(ts_poly *poly){




   if (poly->grafted_vtx!=NULL){


      poly->grafted_vtx->grafted_poly=NULL;


   }


//   if (poly->grafted_vtx!=NULL){


//      poly->grafted_vtx->grafted_poly=NULL;


//   }


   vtx_list_free(poly->vlist);


   bond_list_free(poly->blist);


   free(poly);


@@ -263,8 +254,9 @@




ts_bool poly_list_free(ts_poly_list *poly_list){


   ts_uint i;




   //fprintf(stderr,"no. of polys=%d\n", poly_list->n);


   for(i=0;i<poly_list->n;i++){


   //   fprintf(stderr,"%d poly address in mem=%ld\n",i+1,(long)&(poly_list->poly[i]));


      poly_free(poly_list->poly[i]);


   }


   free(poly_list->poly);