trisurf-ng.git - Gitblit

Samo Penic

2018-12-11 0dd5baa7166ab9abd7ef2d6b374e72beab03ef2a

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7f6076	1	/* vim: set ts=4 sts=4 sw=4 noet : */
7958e9	2	#include<stdlib.h>
SP	3	#include<math.h>
	4	#include<stdio.h>
	5	#include "general.h"
	6	#include "vertex.h"
	7	#include "bond.h"
	8	#include "vesicle.h"
	9	#include "vertex.h"
	10	#include "triangle.h"
	11	#include "initial_distribution.h"
f74313	12	#include "energy.h"
1ab449	13	#include "poly.h"
8a6614	14	#include "io.h"
dc77e8	15	#include "sh.h"
459ff9	16	#include "shcomplex.h"
7958e9	17
SP	18	ts_vesicle *initial_distribution_dipyramid(ts_uint nshell, ts_uint ncmax1, ts_uint ncmax2, ts_uint ncmax3, ts_double stepsize){
1ab449	19	ts_fprintf(stdout,"Starting initial_distribution on vesicle with %u shells!...\n",nshell);
7958e9	20	ts_bool retval;
1ab449	21	ts_uint no_vertices=5nshellnshell+2;
SP	22	ts_vesicle *vesicle=init_vesicle(no_vertices,ncmax1,ncmax2,ncmax3,stepsize);
	23	vesicle->nshell=nshell;
	24	//retval = vtx_set_global_values(vesicle);
	25	retval = pentagonal_dipyramid_vertex_distribution(vesicle->vlist);
	26	retval = init_vertex_neighbours(vesicle->vlist);
	27	vesicle->vlist = init_sort_neighbours(vesicle->blist,vesicle->vlist);
b01cc1	28	// retval = init_vesicle_bonds(vesicle); // bonds are created in sort_neigh
1ab449	29	retval = init_triangles(vesicle);
SP	30	retval = init_triangle_neighbours(vesicle);
	31	retval = init_common_vertex_triangle_neighbours(vesicle);
	32	retval = init_normal_vectors(vesicle->tlist);
	33	retval = mean_curvature_and_energy(vesicle);
	34	ts_fprintf(stdout,"initial_distribution finished!\n");
41a035	35	if(retval);
7958e9	36	return vesicle;
SP	37	}
	38
	39
1ab449	40
SP	41	ts_vesicle create_vesicle_from_tape(ts_tape tape){
	42	ts_vesicle *vesicle;
bcf455	43
1ab449	44	vesicle=initial_distribution_dipyramid(tape->nshell,tape->ncxmax,tape->ncymax,tape->nczmax,tape->stepsize);
698ae1	45	vesicle->tape=tape;
SP	46	set_vesicle_values_from_tape(vesicle);
def8b5	47	initial_population_with_c0(vesicle,tape);
698ae1	48	return vesicle;
SP	49	}
	50
	51	ts_bool set_vesicle_values_from_tape(ts_vesicle *vesicle){
58230a	52	// Nucleus:
698ae1	53	ts_vertex *vtx;
SP	54	ts_tape *tape=vesicle->tape;
fe24d2	55	vesicle->R_nucleus=tape->R_nucleus*tape->R_nucleus;
37791b	56	vesicle->R_nucleusX=tape->R_nucleusX*tape->R_nucleusX;
SP	57	vesicle->R_nucleusY=tape->R_nucleusY*tape->R_nucleusY;
	58	vesicle->R_nucleusZ=tape->R_nucleusZ*tape->R_nucleusZ;
fe24d2	59	vesicle->clist->dmin_interspecies = tape->dmin_interspecies*tape->dmin_interspecies;
bcf455	60
58230a	61	//Initialize grafted polymers (brush):
624f81	62	vesicle->poly_list=init_poly_list(tape->npoly,tape->nmono, vesicle->vlist, vesicle);
1ab449	63	vesicle->spring_constant=tape->kspring;
SP	64	poly_assign_spring_const(vesicle);
bcf455	65
58230a	66	//Initialize filaments (polymers inside the vesicle):
M	67	vesicle->filament_list=init_poly_list(tape->nfil,tape->nfono, NULL, vesicle);
bcf455	68	poly_assign_filament_xi(vesicle,tape);
58230a	69
bcf455	70	ts_uint i,j;
M	71	for(i=0;i<vesicle->filament_list->n;i++){
	72	for(j=0;j<vesicle->filament_list->poly[i]->blist->n;j++){
	73	bond_vector(vesicle->filament_list->poly[i]->blist->bond[j]);
	74	vesicle->filament_list->poly[i]->blist->bond[j]->bond_length = sqrt(vtx_distance_sq(vesicle->filament_list->poly[i]->blist->bond[j]->vtx1,vesicle->filament_list->poly[i]->blist->bond[j]->vtx2));
	75	}
58230a	76	}
bcf455	77
M	78	for(i=0;i<vesicle->filament_list->n;i++){
	79	for(j=0;j<vesicle->filament_list->poly[i]->vlist->n;j++){
	80	vtx = vesicle->filament_list->poly[i]->vlist->vtx[j];
	81	if(vtx->bond_no == 2){
	82	vtx->energy = -(vtx->bond[0]->xvtx->bond[1]->x + vtx->bond[0]->yvtx->bond[1]->y + vtx->bond[0]->z*vtx->bond[1]->z)/vtx->bond[0]->bond_length/vtx->bond[1]->bond_length;
	83	}
	84	}
58230a	85	}
bcf455	86
ea1cce	87	for(i=0;i<vesicle->filament_list->n;i++){
M	88	vertex_list_assign_id(vesicle->filament_list->poly[i]->vlist,TS_ID_FILAMENT);
	89	}
bcf455	90
58230a	91	// vesicle->spring_constant=tape->kspring;
M	92	// poly_assign_spring_const(vesicle);
	93
1ab449	94
SP	95	vesicle->nshell=tape->nshell;
	96	vesicle->dmax=tape->dmaxtape->dmax; / dmax^2 in the vesicle dmax variable */
	97	vesicle->bending_rigidity=tape->xk0;
	98	vtx_set_global_values(vesicle); /* make xk0 default value for every vertex */
f4d6ca	99	// ts_fprintf(stdout, "Tape setting: xk0=%e\n",tape->xk0);
1ab449	100	vesicle->stepsize=tape->stepsize;
SP	101	vesicle->clist->ncmax[0]=tape->ncxmax;
	102	vesicle->clist->ncmax[1]=tape->ncymax;
	103	vesicle->clist->ncmax[2]=tape->nczmax;
90882f	104	vesicle->clist->max_occupancy=16; /* hard coded max occupancy? */
1ab449	105
SP	106	vesicle->pressure= tape->pressure;
	107	vesicle->pswitch=tape->pswitch;
632960	108	if(tape->shc>0){
459ff9	109	vesicle->sphHarmonics=complex_sph_init(vesicle->vlist,tape->shc);
632960	110	}
SP	111	else {
	112	vesicle->sphHarmonics=NULL;
	113	}
e5858f	114
def8b5	115
698ae1	116	return TS_SUCCESS;
1ab449	117
SP	118	}
	119
	120
def8b5	121	ts_bool initial_population_with_c0(ts_vesicle vesicle, ts_tape tape){
SP	122	int rndvtx,i,j;
e5858f	123	if(tape->number_of_vertices_with_c0>0){
073d28	124	// ts_fprintf(stderr,"Setting values for spontaneous curvature as defined in tape\n");
eb9583	125	j=0;
e5858f	126	for(i=0;i<tape->number_of_vertices_with_c0;i++){
SP	127	rndvtx=rand() % vesicle->vlist->n;
eb9583	128	if(fabs(vesicle->vlist->vtx[rndvtx]->c-tape->c0)<1e-15){
SP	129	j++;
	130	i--;
	131	if(j>10*vesicle->vlist->n){
	132	fatal("cannot populate vesicle with vertices with spontaneous curvature. Too many spontaneous curvature vertices?",100);
	133	}
	134	continue;
	135	}
e5858f	136	vesicle->vlist->vtx[rndvtx]->c=tape->c0;
SP	137	}
	138	mean_curvature_and_energy(vesicle);
	139	if(fabs(tape->w)>1e-16){ //if nonzero energy
073d28	140	// ts_fprintf(stderr,"Setting attraction between vertices with spontaneous curvature\n");
e5858f	141	sweep_attraction_bond_energy(vesicle);
SP	142	}
	143	}
def8b5	144	return TS_SUCCESS;
1ab449	145	}
SP	146
	147
7958e9	148	ts_bool pentagonal_dipyramid_vertex_distribution(ts_vertex_list *vlist){
SP	149	/* Some often used relations */
	150	const ts_double s1= sin(2.0*M_PI/5.0);
	151	const ts_double s2= sin(4.0*M_PI/5.0);
	152	const ts_double c1= cos(2.0*M_PI/5.0);
	153	const ts_double c2= cos(4.0*M_PI/5.0);
	154
	155	/* Calculates projection lenght of an edge bond to pentagram plane */
fab2ad	156	const ts_double xl0=DEF_A0/(2.0*sin(M_PI/5.0));
7958e9	157	#ifdef TS_DOUBLE_DOUBLE
fab2ad	158	const ts_double z0=sqrt(pow(DEF_A0,2)-pow(xl0,2));
7958e9	159	#endif
SP	160	#ifdef TS_DOUBLE_FLOAT
fab2ad	161	const ts_double z0=sqrtf(powf(DEF_A0,2)-powf(xl0,2));
7958e9	162	#endif
SP	163	#ifdef TS_DOUBLE_LONGDOUBLE
fab2ad	164	const ts_double z0=sqrtl(powl(DEF_A0,2)-powl(xl0,2));
7958e9	165	#endif
SP	166	// const z0=sqrt(A0A0 -xl0xl0); /* I could use pow function but if pow is used make a check on the float type. If float then powf, if long double use powl */
	167
	168	/placeholder for the pointer to vertex datastructure list... DIRTY: actual pointer points towards invalid address, one position before actual beginning of the list... This is to solve the difference between 1 based indexing in original program in fortran and 0 based indexing in C. All algorithms remain unchanged because of this!/
	169	ts_vertex **vtx=vlist->vtx -1 ;
	170
	171
	172	ts_uint nshell=(ts_uint)( sqrt((ts_double)(vlist->n-2)/5));
	173	// printf("nshell=%u\n",nshell);
	174	ts_uint i,n0; // some for loop prereq
	175	ts_int j,k;
	176	ts_double dx,dy; // end loop prereq
	177
	178	/* topmost vertex */
8f6a69	179	vtx[1]->x=0.0;
SP	180	vtx[1]->y=0.0;
	181	vtx[1]->z=z0*(ts_double)nshell;
7958e9	182
SP	183	/* starting from to in circular order on pentagrams */
	184	for(i=1;i<=nshell;i++){
	185	n0=2+5i(i-1)/2; //-1 would be for the reason that C index starts from 0
8f6a69	186	vtx[n0]->x=0.0;
SP	187	vtx[n0]->y=(ts_double)i*xl0;
	188	vtx[n0+i]->x=vtx[n0]->y*s1;
	189	vtx[n0+i]->y=vtx[n0]->y*c1;
	190	vtx[n0+2i]->x=vtx[n0]->ys2;
	191	vtx[n0+2i]->y=vtx[n0]->yc2;
	192	vtx[n0+3i]->x=-vtx[n0+2i]->x;
	193	vtx[n0+3i]->y=vtx[n0+2i]->y;
	194	vtx[n0+4*i]->x=-vtx[n0+i]->x;
	195	vtx[n0+4*i]->y=vtx[n0+i]->y;
7958e9	196	}
SP	197
	198	/* vertexes on the faces of the dipyramid */
	199	for(i=1;i<=nshell;i++){
	200	n0=2+5i(i-1)/2; // -1 would be because of C!
	201	for(j=1;j<=i-1;j++){
8f6a69	202	dx=(vtx[n0]->x-vtx[n0+4*i]->x)/(ts_double)i;
SP	203	dy=(vtx[n0]->y-vtx[n0+4*i]->y)/(ts_double)i;
	204	vtx[n0+4i+j]->x=(ts_double)jdx+vtx[n0+4*i]->x;
	205	vtx[n0+4i+j]->y=(ts_double)jdy+vtx[n0+4*i]->y;
7958e9	206	}
SP	207	for(k=0;k<=3;k++){ // I would be worried about zero starting of for
8f6a69	208	dx=(vtx[n0+(k+1)i]->x - vtx[n0+ki]->x)/(ts_double) i;
SP	209	dy=(vtx[n0+(k+1)i]->y - vtx[n0+ki]->y)/(ts_double) i;
7958e9	210	for(j=1; j<=i-1;j++){
8f6a69	211	vtx[n0+ki+j]->x= (ts_double)jdx+vtx[n0+k*i]->x;
SP	212	vtx[n0+ki+j]->y= (ts_double)jdy+vtx[n0+k*i]->y;
7958e9	213	}
SP	214	}
	215	}
	216
	217	for(i=1;i<=nshell;i++){
	218	n0= 2+ 5i(i-1)/2;
	219	for(j=0;j<=5*i-1;j++){
8f6a69	220	vtx[n0+j]->z= z0*(ts_double)(nshell-i); // I would be worried about zero starting of for
7958e9	221	}
SP	222	}
	223
	224	/* for botom part of dipyramide we calculate the positions of vertices */
	225	for(i=2+5nshell(nshell+1)/2;i<=vlist->n;i++){
8f6a69	226	vtx[i]->x=vtx[vlist->n - i +1]->x;
SP	227	vtx[i]->y=vtx[vlist->n - i +1]->y;
	228	vtx[i]->z=-vtx[vlist->n - i +1]->z;
7958e9	229	}
SP	230
	231	for(i=1;i<=vlist->n;i++){
	232	for(j=1;j<=vlist->n;j++){
	233	if(i!=j && vtx_distance_sq(vtx[i],vtx[j])<0.001){
	234	printf("Vertices %u and %u are the same!\n",i,j);
	235	}
	236	}
	237	}
	238	return TS_SUCCESS;
	239	}
	240
	241
	242
	243	ts_bool init_vertex_neighbours(ts_vertex_list *vlist){
	244	ts_vertex **vtx=vlist->vtx -1; // take a look at dipyramid function for comment.
	245	const ts_double eps=0.001; //TODO: find out if you can use EPS from math.h
	246	ts_uint i,j;
	247	ts_double dist2; // Square of distance of neighbours
	248	/this is not required if we zero all data in vertex structure at initialization /
	249	/if we force zeroing at initialization this for loop can safely be deleted /
	250	//for(i=1;i<=vlist->n;i++){
	251	// vtx[i].neigh_no=0;
	252	//}
	253	for(i=1;i<=vlist->n;i++){
	254	for(j=1;j<=vlist->n;j++){
	255	dist2=vtx_distance_sq(vtx[i],vtx[j]);
fab2ad	256	if( (dist2>eps) && (dist2<(DEF_A0*DEF_A0+eps))){
7958e9	257	//if it is close enough, but not too much close (solves problem of comparing when i==j)
SP	258	vtx_add_neighbour(vtx[i],vtx[j]);
	259	}
	260	}
	261	// printf ("vertex %u ima %u sosedov!\n",i,vtx[i]->data->neigh_no);
	262	}
	263
	264	return TS_SUCCESS;
	265	}
	266
b01cc1	267	// TODO: with new datastructure can be rewritten. Partially it is done, but it is complicated.
SP	268	ts_vertex_list init_sort_neighbours(ts_bond_list blist,ts_vertex_list *vlist){
7958e9	269	ts_vertex **vtx=vlist->vtx -1; // take a look at dipyramid function for comment.
SP	270	ts_uint i,l,j,jj,jjj,k=0;
	271	ts_double eps=0.001; // Take a look if EPS from math.h can be used
	272
	273	/lets initialize memory for temporary vertex_list. Should we write a function instead /
b01cc1	274	ts_vertex_list *tvlist=vertex_list_copy(vlist);
7958e9	275	ts_vertex *tvtx=tvlist->vtx -1; / again to compensate for 0-indexing */
SP	276
	277	ts_double dist2; // Square of distance of neighbours
	278	ts_double direct; // Something, dont know what, but could be normal of some kind
	279	for(i=1;i<=vlist->n;i++){
	280	k++; // WHY i IS NOT GOOD??
8f6a69	281	vtx_add_cneighbour(blist,tvtx[k], tvtx[vtx[i]->neigh[0]->idx+1]); //always add 1st
7958e9	282	jjj=1;
SP	283	jj=1;
8f6a69	284	for(l=2;l<=vtx[i]->neigh_no;l++){
SP	285	for(j=2;j<=vtx[i]->neigh_no;j++){
	286	dist2=vtx_distance_sq(vtx[i]->neigh[j-1],vtx[i]->neigh[jj-1]);
	287	direct=vtx_direct(vtx[i],vtx[i]->neigh[j-1],vtx[i]->neigh[jj-1]);
	288	// TODO: check if fabs can be used with all floating point types!!
fab2ad	289	if( (fabs(dist2-DEF_A0*DEF_A0)<=eps) && (direct>0.0) && (j!=jjj) ){
8f6a69	290	vtx_add_cneighbour(blist,tvtx[k],tvtx[vtx[i]->neigh[j-1]->idx+1]);
7958e9	291	jjj=jj;
SP	292	jj=j;
	293	break;
	294	}
	295	}
	296	}
	297	}
b01cc1	298	/* We use the temporary vertex for our main vertices and we abandon main
SP	299	* vertices, because their neighbours are not correctly ordered */
	300	// tvtx=vlist->vtx;
	301	// vlist->vtx=tvtx;
	302	// tvlist->vtx=vtx;
	303	vtx_list_free(vlist);
	304	/* Let's make a check if the number of bonds is correct */
	305	if((blist->n)!=3*(tvlist->n-2)){
	306	ts_fprintf(stderr,"Number of bonds is %u should be %u!\n", blist->n, 3*(tvlist->n-2));
	307	fatal("Number of bonds is not 3*(no_vertex-2).",4);
7958e9	308	}
SP	309
b01cc1	310	return tvlist;
7958e9	311	}
SP	312
	313
	314	ts_bool init_vesicle_bonds(ts_vesicle *vesicle){
	315	ts_vertex_list *vlist=vesicle->vlist;
	316	ts_bond_list *blist=vesicle->blist;
	317	ts_vertex **vtx=vesicle->vlist->vtx - 1; // Because of 0 indexing
	318	/* lets make correct clockwise ordering of in nearest neighbour list */
	319	ts_uint i,j,k;
	320	for(i=1;i<=vlist->n;i++){
	321	for(j=i+1;j<=vlist->n;j++){
8f6a69	322	for(k=0;k<vtx[i]->neigh_no;k++){ // has changed 0 to < instead of 1 and <=
SP	323	if(vtx[i]->neigh[k]==vtx[j]){ //if addresses matches it is the same
7958e9	324	bond_add(blist,vtx[i],vtx[j]);
SP	325	break;
	326	}
	327	}
	328	}
	329	}
	330	/* Let's make a check if the number of bonds is correct */
	331	if((blist->n)!=3*(vlist->n-2)){
	332	ts_fprintf(stderr,"Number of bonds is %u should be %u!\n", blist->n, 3*(vlist->n-2));
	333	fatal("Number of bonds is not 3*(no_vertex-2).",4);
	334	}
	335	return TS_SUCCESS;
	336	}
	337
	338
	339
	340	ts_bool init_triangles(ts_vesicle *vesicle){
	341	ts_uint i,j,jj,k;
	342	ts_vertex **vtx=vesicle->vlist->vtx -1; // difference between 0 indexing and 1 indexing
	343	ts_triangle_list *tlist=vesicle->tlist;
	344	ts_double dist, direct;
	345	ts_double eps=0.001; // can we use EPS from math.h?
	346	k=0;
	347	for(i=1;i<=vesicle->vlist->n;i++){
8f6a69	348	for(j=1;j<=vtx[i]->neigh_no;j++){
SP	349	for(jj=1;jj<=vtx[i]->neigh_no;jj++){
7958e9	350	// ts_fprintf(stderr,"%u: (%u,%u) neigh_no=%u ",i,j,jj,vtx[i].neigh_no);
SP	351	// ts_fprintf(stderr,"%e, %e",vtx[i].neigh[j-1]->x,vtx[i].neigh[jj-1]->x);
8f6a69	352	dist=vtx_distance_sq(vtx[i]->neigh[j-1],vtx[i]->neigh[jj-1]);
SP	353	direct=vtx_direct(vtx[i],vtx[i]->neigh[j-1],vtx[i]->neigh[jj-1]);
	354	// TODO: same as above
fab2ad	355	if(fabs(dist-DEF_A0*DEF_A0)<=eps && direct < 0.0 && vtx[i]->neigh[j-1]->idx+1 > i && vtx[i]->neigh[jj-1]->idx+1 >i){
8f6a69	356	triangle_add(tlist,vtx[i],vtx[i]->neigh[j-1],vtx[i]->neigh[jj-1]);
7958e9	357	}
SP	358	}
	359	}
	360	}
	361	/* We check if all triangles have 3 vertices and if the number of triangles
	362	* matches the theoretical value.
	363	*/
	364	for(i=0;i<tlist->n;i++){
	365	k=0;
	366	for(j=0;j<3;j++){
41a035	367	if(tlist->tria[i]->vertex[j]!=NULL)
7958e9	368	k++;
SP	369	}
	370	if(k!=3){
8f6a69	371	fatal("Some triangles have less than 3 vertices..",4);
7958e9	372	}
SP	373	}
	374	if(tlist->n!=2*(vesicle->vlist->n -2)){
	375	ts_fprintf(stderr,"The number of triangles is %u but should be %u!\n",tlist->n,2*(vesicle->vlist->n -2));
	376	fatal("The number of triangles doesn't match 2*(no_vertex -2).",4);
	377	}
	378	return TS_SUCCESS;
	379	}
	380
	381
	382
	383	ts_bool init_triangle_neighbours(ts_vesicle *vesicle){
	384	ts_uint i,j,nobo;
	385	ts_vertex i1,i2,i3,j1,j2,j3;
	386	// ts_vertex **vtx=vesicle->vlist->vtx -1; // difference between 0 indexing and 1 indexing
	387	ts_triangle_list *tlist=vesicle->tlist;
	388	ts_triangle **tria=tlist->tria -1;
	389	nobo=0;
	390	for(i=1;i<=tlist->n;i++){
41a035	391	i1=tria[i]->vertex[0];
SP	392	i2=tria[i]->vertex[1];
	393	i3=tria[i]->vertex[2];
7958e9	394	for(j=1;j<=tlist->n;j++){
SP	395	if(j==i) continue;
41a035	396	j1=tria[j]->vertex[0];
SP	397	j2=tria[j]->vertex[1];
	398	j3=tria[j]->vertex[2];
7958e9	399	if((i1==j1 && i3==j2) \|\| (i1==j2 && i3==j3) \|\| (i1==j3 && i3==j1)){
SP	400	triangle_add_neighbour(tria[i],tria[j]);
	401	nobo++;
	402	}
	403	}
	404	}
	405	for(i=1;i<=tlist->n;i++){
41a035	406	i1=tria[i]->vertex[0];
SP	407	i2=tria[i]->vertex[1];
	408	i3=tria[i]->vertex[2];
7958e9	409	for(j=1;j<=tlist->n;j++){
SP	410	if(j==i) continue;
41a035	411	j1=tria[j]->vertex[0];
SP	412	j2=tria[j]->vertex[1];
	413	j3=tria[j]->vertex[2];
7958e9	414	if((i1==j1 && i2==j3) \|\| (i1==j3 && i2==j2) \|\| (i1==j2 && i2==j1)){
SP	415	triangle_add_neighbour(tria[i],tria[j]);
	416	nobo++;
	417	}
	418	}
	419	}
	420	for(i=1;i<=tlist->n;i++){
41a035	421	i1=tria[i]->vertex[0];
SP	422	i2=tria[i]->vertex[1];
	423	i3=tria[i]->vertex[2];
7958e9	424	for(j=1;j<=tlist->n;j++){
SP	425	if(j==i) continue;
41a035	426	j1=tria[j]->vertex[0];
SP	427	j2=tria[j]->vertex[1];
	428	j3=tria[j]->vertex[2];
7958e9	429	if((i2==j1 && i3==j3) \|\| (i2==j3 && i3==j2) \|\| (i2==j2 && i3==j1)){
SP	430	triangle_add_neighbour(tria[i],tria[j]);
	431	nobo++;
	432	}
	433	}
	434	}
	435	if(nobo != vesicle->blist->n*2) {
	436	ts_fprintf(stderr,"Number of triangles= %u, number of bonds= %u\n",nobo/2, vesicle->blist->n);
	437	fatal("Number of triangle neighbour pairs differs from double the number of bonds!",4);
	438	}
	439	return TS_SUCCESS;
	440	}
	441
	442
	443	ts_bool init_common_vertex_triangle_neighbours(ts_vesicle *vesicle){
	444	ts_uint i,j,jp,k;
	445	ts_vertex k1,k2,k3,k4,*k5;
	446	ts_vertex **vtx=vesicle->vlist->vtx -1; // difference between 0 indexing and 1 indexing
	447	ts_triangle_list *tlist=vesicle->tlist;
	448	ts_triangle **tria=tlist->tria -1;
	449
	450	for(i=1;i<=vesicle->vlist->n;i++){
8f6a69	451	for(j=1;j<=vtx[i]->neigh_no;j++){
SP	452	k1=vtx[i]->neigh[j-1];
7958e9	453	jp=j+1;
8f6a69	454	if(j == vtx[i]->neigh_no) jp=1;
SP	455	k2=vtx[i]->neigh[jp-1];
7958e9	456	for(k=1;k<=tlist->n;k++){ // VERY NON-OPTIMAL!!! too many loops (vlist.n * vtx.neigh * tlist.n )!
41a035	457	k3=tria[k]->vertex[0];
SP	458	k4=tria[k]->vertex[1];
	459	k5=tria[k]->vertex[2];
7958e9	460	// ts_fprintf(stderr,"%u %u: k=(%u %u %u)\n",k1,k2,k3,k4,k5);
SP	461	if((vtx[i]==k3 && k1==k4 && k2==k5) \|\|
	462	(vtx[i]==k4 && k1==k5 && k2==k3) \|\|
	463	(vtx[i]==k5 && k1==k3 && k2==k4)){
b01cc1	464
SP	465	//TODO: probably something wrong with neighbour distribution.
	466	// if(vtx[i]==k3 \|\| vtx[i]==k4 \|\| vtx[i]==k5){
dac2e5	467	// if(i==6) ts_fprintf(stdout, "Vtx[%u] > Added to tristar!\n",i);
7958e9	468	vertex_add_tristar(vtx[i],tria[k]);
SP	469	}
	470	}
	471	}
	472	/* ts_fprintf(stderr,"TRISTAR for %u (%u):",i-1,vtx[i].tristar_no);
	473	for(j=0;j<vtx[i].tristar_no;j++){
	474	ts_fprintf(stderr," %u,",vtx[i].tristar[j]->idx);
	475	}
	476	ts_fprintf(stderr,"\n"); */
	477	}
	478	return TS_SUCCESS;
	479	}
	480
	481
	482	ts_bool init_normal_vectors(ts_triangle_list *tlist){
	483	/* Normals point INSIDE vesicle */
	484	ts_uint k;
	485	ts_triangle **tria=tlist->tria -1; //for 0 indexing
	486	for(k=1;k<=tlist->n;k++){
	487	triangle_normal_vector(tria[k]);
	488	}
	489	return TS_SUCCESS;
	490	}