trisurf-ng.git - Gitblit

			@@ -8,6 +8,7 @@
			#include "energy.h"
			#include "timestep.h"
			#include "cell.h"
			#include "bondflip.h"
			//#include "io.h"
			#include<stdio.h>

			@@ -27,7 +28,7 @@
			ts_vertex *it=bond->vtx1;
			ts_vertex *k=bond->vtx2;
			ts_uint nei,neip,neim;
			ts_uint i,j;
			ts_uint i; //j;
			ts_double oldenergy, delta_energy;
			// ts_triangle lm=NULL,lp=NULL, lp1=NULL, lp2=NULL, lm1=NULL, lm2=NULL;

			@@ -39,7 +40,7 @@
			fatal("In bondflip, number of neighbours of k or it is less than 3!",999);
			}


			nei=0;
			for(i=0;i<it->neigh_no;i++){ // Finds the nn of it, that is k
			if(it->neigh[i]==k){
			nei=i;
			@@ -68,7 +69,7 @@
			}
			// fprintf(stderr,"Membrane didn't wrap too much.. Continue.\n");
			/* if bond would be too long, return... */
			if(vertex_distance_sq(km,kp) > vesicle->dmax ) return TS_FAIL;
			if(vtx_distance_sq(km,kp) > vesicle->dmax ) return TS_FAIL;
			// fprintf(stderr,"Bond will not be too long.. Continue.\n");

			/* we make a bond flip. this is different than in original fortran */
			@@ -78,46 +79,59 @@
			oldenergy+=kp->xk* kp->energy;
			oldenergy+=km->xk* km->energy;
			oldenergy+=it->xk* it->energy;
			// for(i=0;i<k->neigh_no;i++) oldenergy+=k->neigh[i]->xk*k->neigh[i]->energy;
			// for(i=0;i<kp->neigh_no;i++) oldenergy+=kp->neigh[i]->xk*kp->neigh[i]->energy;
			// for(i=0;i<km->neigh_no;i++) oldenergy+=km->neigh[i]->xk*km->neigh[i]->energy;
			// for(i=0;i<it->neigh_no;i++) oldenergy+=it->neigh[i]->xk*it->neigh[i]->energy;
			//Neigbours don't change its energy.
			/*
			fprintf(stderr,"*** Naslov k=%d\n",k);
			fprintf(stderr,"*** Naslov it=%d\n",it);
			fprintf(stderr,"*** Naslov km=%d\n",km);
			fprintf(stderr,"*** Naslov kp=%d\n",kp);
			fprintf(stderr,"*** Naslov k=%ld\n",(long)k);
			fprintf(stderr,"*** Naslov it=%ld\n",(long)it);
			fprintf(stderr,"*** Naslov km=%ld\n",(long)km);
			fprintf(stderr,"*** Naslov kp=%ld\n",(long)kp);

			for(i=0;i<k->neigh_no;i++)
			fprintf(stderr,"k sosed=%d\n",k->neigh[i]);
			fprintf(stderr,"k sosed=%ld\n",(long)k->neigh[i]);
			for(i=0;i<it->neigh_no;i++)
			fprintf(stderr,"it sosed=%d\n",it->neigh[i]);
			fprintf(stderr,"it sosed=%ld\n",(long)it->neigh[i]);

			for(i=0;i<km->neigh_no;i++)
			fprintf(stderr,"km sosed=%d\n",km->neigh[i]);
			fprintf(stderr,"km sosed=%ld\n",(long)km->neigh[i]);
			for(i=0;i<kp->neigh_no;i++)
			fprintf(stderr,"kp sosed=%d\n",kp->neigh[i]);
			fprintf(stderr,"kp sosed=%ld\n",(long)kp->neigh[i]);


			*/
			// fprintf(stderr,"I WAS HERE! Before bondflip!\n");
			// fprintf(stderr,"I WAS HERE! Before bondflip!\n");
			ts_flip_bond(k,it,km,kp, bond);
			// fprintf(stderr,"I WAS HERE! Bondflip successful!\n");
			// fprintf(stderr,"I WAS HERE! Bondflip successful!\n");

			/* Calculating the new energy */
			delta_energy=0;
			for(i=0;i<k->neigh_no;i++) energy_vertex(k->neigh[i]);
			for(i=0;i<kp->neigh_no;i++) energy_vertex(kp->neigh[i]);
			for(i=0;i<km->neigh_no;i++) energy_vertex(km->neigh[i]);
			for(i=0;i<it->neigh_no;i++) energy_vertex(it->neigh[i]);
			/* ts_double dbg_energy=0.0;
			for(i=0;i<k->neigh_no;i++) {
			dbg_energy=k->neigh[i]->energy;
			energy_vertex(k->neigh[i]);
			if(abs(dbg_energy-k->neigh[i]->energy)>1e-100) fatal("Energy changes!",1);
			}
			for(i=0;i<kp->neigh_no;i++) {
			dbg_energy=kp->neigh[i]->energy;
			energy_vertex(kp->neigh[i]);
			if(abs(dbg_energy-kp->neigh[i]->energy)>1e-100) fatal("Energy changes!",1);
			}
			for(i=0;i<km->neigh_no;i++){
			dbg_energy=km->neigh[i]->energy;
			energy_vertex(km->neigh[i]);
			if(abs(dbg_energy-km->neigh[i]->energy)>1e-100) fatal("Energy changes!",1);
			}

			for(i=0;i<it->neigh_no;i++){
			dbg_energy=it->neigh[i]->energy;
			energy_vertex(it->neigh[i]);
			if(abs(dbg_energy-it->neigh[i]->energy)>1e-100) fatal("Energy changes!",1);
			}
			*/
			delta_energy+=k->xk* k->energy;
			delta_energy+=kp->xk* kp->energy;
			delta_energy+=km->xk* km->energy;
			delta_energy+=it->xk* it->energy;
			// for(i=0;i<k->neigh_no;i++) delta_energy+=k->neigh[i]->xk*k->neigh[i]->energy;
			// for(i=0;i<kp->neigh_no;i++) delta_energy+=kp->neigh[i]->xk*kp->neigh[i]->energy;
			// for(i=0;i<km->neigh_no;i++) delta_energy+=km->neigh[i]->xk*km->neigh[i]->energy;
			// for(i=0;i<it->neigh_no;i++) delta_energy+=it->neigh[i]->xk*it->neigh[i]->energy;
			//Neigbours don't change its energy.
			delta_energy-=oldenergy;
			// fprintf(stderr,"I WAS HERE! Got energy!\n");
			/* MONTE CARLO */
			@@ -174,7 +188,7 @@
			ts_bond *bond){

			ts_triangle lm=NULL,lp=NULL, lp1=NULL, lm2=NULL;
			ts_uint i,j, lmidx, lpidx;
			ts_uint i,j; //lmidx, lpidx;
			if(k==NULL \|\| it==NULL \|\| km==NULL \|\| kp==NULL){
			fatal("ts_flip_bond: You called me with invalid pointers to vertices",999);
			}
			@@ -232,26 +246,24 @@
			*/
			if(lm2==NULL \|\| lp1==NULL) fatal("ts_flip_bond: Cannot find triangles lm2 and lp1!",999);


			//fprintf(stderr,"1. step: lm, lm2, lp1 and lp found!\n");

			/*
			//DEBUG TESTING
			fprintf(stderr,"--- Naslov lm=%d",lm);
			fprintf(stderr,"1. step: lm, lm2, lp1 and lp found!\n");
			fprintf(stderr,"--- Naslov lm=%ld",(long)lm);


			fprintf(stderr," vtxs(%d, %d, %d)\n",lm->vertex[0],lm->vertex[1], lm->vertex[2]);
			fprintf(stderr,"--- Naslov lp=%d",lp);
			fprintf(stderr," vtxs(%d, %d, %d)\n",lp->vertex[0],lp->vertex[1], lp->vertex[2]);
			fprintf(stderr,"--- Naslov lm2=%d",lm2);
			fprintf(stderr," vtxs(%d, %d, %d)\n",lm2->vertex[0],lm2->vertex[1], lm2->vertex[2]);
			fprintf(stderr,"--- Naslov lp1=%d",lp1);
			fprintf(stderr," vtxs(%d, %d, %d)\n",lp1->vertex[0],lp1->vertex[1], lp1->vertex[2]);
			fprintf(stderr," vtxs(%ld, %ld, %ld)\n",(long)lm->vertex[0],(long)lm->vertex[1], (long)lm->vertex[2]);
			fprintf(stderr,"--- Naslov lp=%ld",(long)lp);
			fprintf(stderr," vtxs(%ld, %ld, %ld)\n",(long)lp->vertex[0],(long)lp->vertex[1], (long)lp->vertex[2]);
			fprintf(stderr,"--- Naslov lm2=%ld",(long)lm2);
			fprintf(stderr," vtxs(%ld, %ld, %ld)\n",(long)lm2->vertex[0],(long)lm2->vertex[1], (long)lm2->vertex[2]);
			fprintf(stderr,"--- Naslov lp1=%ld",(long)lp1);
			fprintf(stderr," vtxs(%ld, %ld, %ld)\n",(long)lp1->vertex[0],(long)lp1->vertex[1], (long)lp1->vertex[2]);

			for(i=0;i<lm->neigh_no;i++)
			fprintf(stderr,"lm sosed=%d\n",lm->neigh[i]);
			fprintf(stderr,"lm sosed=%ld\n",(long)lm->neigh[i]);
			for(i=0;i<lp->neigh_no;i++)
			fprintf(stderr,"lp sosed=%d\n",lp->neigh[i]);
			fprintf(stderr,"lp sosed=%ld\n",(long)lp->neigh[i]);
			// END DEBUG TESTING
			*/
			/*
			@@ -276,14 +288,17 @@
			// * normals are recalculated here
			triangle_normal_vector(lp);
			triangle_normal_vector(lm);
			//fprintf(stderr,"2a. step: triangle normals recalculated\n");
			// 3. step. Correct neighbours in vertex_list


			vertex_remove_neighbour(k,it);
			vertex_remove_neighbour(it,k);
			vtx_remove_neighbour(k,it);
			// vtx_remove_neighbour(it,k);
			//fprintf(stderr,"3. step (PROGRESS): removed k and it neighbours\n");

			//Tukaj pa nastopi tezava... Kam dodati soseda?
			vertex_insert_neighbour(km,kp,k);
			vertex_insert_neighbour(kp,km,it);
			vtx_insert_neighbour(km,kp,k);
			vtx_insert_neighbour(kp,km,it);
			// vertex_add_neighbour(km,kp); //pazi na vrstni red.
			// vertex_add_neighbour(kp,km);
			//fprintf(stderr,"3. step: vertex neighbours corrected\n");
			@@ -300,7 +315,7 @@
			// 5. step. Correct neighbouring triangles

			triangle_remove_neighbour(lp,lp1);
			// fprintf(stderr,".\n");
			// fprintf(stderr,".\n");
			triangle_remove_neighbour(lp1,lp);
			// fprintf(stderr,".\n");
			triangle_remove_neighbour(lm,lm2);
			@@ -318,8 +333,8 @@
			// 6. step. Correct tristar for vertices km, kp, k and it
			vertex_add_tristar(km,lp); // Preveri vrstni red!
			vertex_add_tristar(kp,lm);
			vertex_remove_tristar(it,lm);
			vertex_remove_tristar(k,lp);
			vtx_remove_tristar(it,lm);
			vtx_remove_tristar(k,lp);
			//fprintf(stderr,"6. step: tristar corrected\n");

			/*