trisurf-ng.git - Gitblit

			@@ -1,9 +1,26 @@
			/* vim: set ts=4 sts=4 sw=4 noet : */
			#include<stdlib.h>
			#include<stdio.h>
			#include "general.h"
			#include "triangle.h"
			#include<math.h>

			/** @brief Prepares the list for triangles.
			* @returns pointer to empty data structure for maintaining triangle list.
			*
			* Create empty list for holding the information on triangles. Triangles are
			* added later on with triangle_add().
			* Returns pointer to the tlist datastructure it has created. This pointer must
			* be assigned to some variable or it will be lost.
			*
			*
			* Example of usage:
			* ts_triangle_list *tlist;
			* tlist=triangle_data_free();
			*
			* Initalized data structure for holding the information on triangles.
			*
			*/
			ts_triangle_list *init_triangle_list(){
			ts_triangle_list tlist=(ts_triangle_list )malloc(sizeof(ts_triangle_list));
			tlist->n = 0;
			@@ -11,7 +28,30 @@
			return tlist;
			}


			/** @brief Add the triangle to the triangle list and create necessary data
			* structures.
			* @param *tlist is a pointer to triangle list where triangle should be created
			* @param vtx1, vtx2, *vtx3 are the three vertices defining the triangle
			* @returns pointer to the newly created triangle on success and NULL if
			* triangle could not be created. It breaks program execution if memory
			* allocation of triangle list can't be done.
			*
			* Add the triangle ts_triangle to the ts_triangle_list.
			* The triangle list is resized, the ts_triangle is allocated and
			* triangle data is zeroed. Returned pointer to newly
			* created triangle doesn't need assigning, since it is
			* referenced by triangle list.
			*
			* WARNING: Function can be accelerated a bit by removing the NULL checks.
			* However the time gained by removal doesn't justify the time spent by
			* debugging stupid NULL pointers.
			*
			* Example of usage:
			* triangle_add(tlist, vlist->vtx[1], vlist->vtx[2], vlist->vtx[3]);
			*
			* Creates a triangle with given vertices and puts it into the list.
			*
			*/
			ts_triangle triangle_add(ts_triangle_list tlist, ts_vertex vtx1, ts_vertex vtx2, ts_vertex *vtx3){
			if(vtx1==NULL \|\| vtx2==NULL \|\| vtx3==NULL){
			return NULL;
			@@ -22,90 +62,167 @@

			tlist->tria[tlist->n-1]=(ts_triangle *)calloc(1,sizeof(ts_triangle));
			if(tlist->tria[tlist->n-1]==NULL) fatal("Cannot reallocate memory for additional ts_triangle.",5);
			tlist->tria[tlist->n-1]->data=(ts_triangle_data *)calloc(1,sizeof(ts_triangle_data));

			//NOW insert vertices!
			tlist->tria[tlist->n - 1]->idx=tlist->n-1;
			tlist->tria[tlist->n - 1]->data->vertex[0]=vtx1;
			tlist->tria[tlist->n - 1]->data->vertex[1]=vtx2;
			tlist->tria[tlist->n - 1]->data->vertex[2]=vtx3;
			tlist->tria[tlist->n - 1]->vertex[0]=vtx1;
			tlist->tria[tlist->n - 1]->vertex[1]=vtx2;
			tlist->tria[tlist->n - 1]->vertex[2]=vtx3;
			return tlist->tria[tlist->n-1];
			}

			/** @brief Add the neigbour to triangles.
			* @param *tria is a first triangle.
			* @param *ntria is a second triangle.
			* @returns TS_SUCCES on sucessful adition to the list, TS_FAIL if triangles
			* are NULL and breaks execution FATALY if memory allocation error occurs.
			*
			* Add the neigbour to the list of neighbouring triangles. The
			* neighbouring triangles are those, who share two vertices and corresponding
			* bond. Function resizes
			* the list and adds the pointer to neighbour. It receives two arguments of
			* ts_triangle type. It then adds second triangle to the list of first
			* triangle, but not the opposite. Upon
			* success it returns TS_SUCCESS, upon detecting NULL pointers
			* returns TS_FAIL and it FATALY ends when the data structure
			* cannot be resized.
			*
			*
			* WARNING: Function can be accelerated a bit by removing the NULL checks.
			* However the time gained by removal doesn't justify the time spent by
			* debugging stupid NULL pointers.
			*
			* Example of usage:
			* triangle_add_neighbour(tlist->tria[3], tlist->tria[4]);
			*
			* Triangle 4 is a neighbour of triangle 3, but (strangely) not the
			* oposite. The function should be called again with the changed order of
			* triangles to make neighbourship mutual.
			*
			*/

			ts_bool triangle_add_neighbour(ts_triangle tria, ts_triangle ntria){
			if(tria==NULL \|\| ntria==NULL) return TS_FAIL;
			/*TODO: check if the neighbour already exists! Now there is no such check
			* because of the performance issue. */
			tria->data->neigh_no++;
			tria->data->neigh=realloc(tria->data->neigh,tria->data->neigh_nosizeof(ts_triangle ));
			if(tria->data->neigh == NULL)
			tria->neigh_no++;
			tria->neigh=realloc(tria->neigh,tria->neigh_nosizeof(ts_triangle ));
			if(tria->neigh == NULL)
			fatal("Reallocation of memory failed during insertion of triangle neighbour in triangle_add_neighbour",3);
			tria->data->neigh[tria->data->neigh_no-1]=ntria;

			/* we repeat the procedure for the neighbour */
			ntria->data->neigh_no++;
			ntria->data->neigh=realloc(ntria->data->neigh,ntria->data->neigh_nosizeof(ts_triangle ));
			if(ntria->data->neigh == NULL)
			fatal("Reallocation of memory failed during insertion of triangle neighbour in triangle_add_neighbour",3);
			ntria->data->neigh[ntria->data->neigh_no-1]=tria;
			tria->neigh[tria->neigh_no-1]=ntria;
			return TS_SUCCESS;
			}


			/** @brief Remove the neigbours from triangle.
			* @param *tria is a first triangle.
			* @param *ntria is neighbouring triangle.
			* @returns TS_SUCCESS on successful removal, TS_FAIL if triangles are not
			* neighbours and it breaks program execution FATALY if memory allocation
			* problem occurs.
			*
			* Removes the neigbour from the list of neighbouring triangles. The
			* neighbouring triangles are those, who share two vertices and corresponding
			* bond. Function resizes
			* the list and deletes the pointer to neighbour. It receives two arguments of
			* ts_triangle type. It then mutually removes triangles from eachouther
			* neighbour list. Upon
			* success it returns TS_SUCCESS, upon failure to find the triangle in the
			* neighbour list returns TS_FAIL. It FATALY breaks program execution when the datastructure
			* cannot be resized due to memory constrain problems.
			*
			* WARNING: The function doesn't check whether the pointer is NULL or invalid. It is the
			* job of programmer to make sure the pointer is valid.
			*
			* WARNING: Function is slow. Do not use it often!
			*
			* Example of usage:
			* triangle_remove_neighbour(tlist->tria[3], tlist->tria[4]);
			*
			* Triangles 3 and 4 are not neighbours anymore.
			*
			*/
			ts_bool triangle_remove_neighbour(ts_triangle tria, ts_triangle ntria){
			ts_uint i,j=0;
			if(tria==NULL \|\| ntria==NULL) return TS_FAIL;

			for(i=0;i<tria->data->neigh_no;i++){
			if(tria->data->neigh[i]!=ntria){
			tria->data->neigh[j]=tria->data->neigh[i];
			for(i=0;i<tria->neigh_no;i++){
			if(tria->neigh[i]!=ntria){
			tria->neigh[j]=tria->neigh[i];
			j++;
			}
			}
			if(j==i) {
			return TS_FAIL;
			//fatal("In triangle_remove_neighbour: Specified neighbour does not exist for given triangle",3);
			}
			tria->data->neigh_no--;
			tria->data->neigh=(ts_triangle *)realloc(tria->data->neigh,tria->data->neigh_nosizeof(ts_triangle *));
			if(tria->data->neigh == NULL){
			tria->neigh_no--;
			tria->neigh=(ts_triangle *)realloc(tria->neigh,tria->neigh_nosizeof(ts_triangle *));
			if(tria->neigh == NULL){
			fprintf(stderr,"Ooops: tria->neigh_no=%d\n",tria->neigh_no);
			fatal("Reallocation of memory failed during removal of vertex neighbour in triangle_remove_neighbour",100);
			}
			/* we repeat the procedure for neighbour */
			for(i=0;i<ntria->data->neigh_no;i++){
			if(ntria->data->neigh[i]!=tria){
			ntria->data->neigh[j]=ntria->data->neigh[i];
			j=0;
			for(i=0;i<ntria->neigh_no;i++){
			if(ntria->neigh[i]!=tria){
			ntria->neigh[j]=ntria->neigh[i];
			j++;
			}
			}
			if(j==i) {
			return TS_FAIL;
			//fatal("In triangle_remove_neighbour: Specified neighbour does not exist for given triangle",3);
			}
			ntria->data->neigh_no--;
			ntria->data->neigh=(ts_triangle *)realloc(ntria->data->neigh,ntria->data->neigh_nosizeof(ts_triangle *));
			if(ntria->data->neigh == NULL){
			ntria->neigh_no--;
			ntria->neigh=(ts_triangle *)realloc(ntria->neigh,ntria->neigh_nosizeof(ts_triangle *));
			if(ntria->neigh == NULL){
			fprintf(stderr,"Ooops: ntria->neigh_no=%d\n",ntria->neigh_no);
			fatal("Reallocation of memory failed during removal of vertex neighbour in triangle_remove_neighbour",100);
			}
			return TS_SUCCESS;
			}


			/** @brief Calculates normal vector of the triangle, its corresponding area and volume.
			* @param *tria is a triangle pointer for which normal, area and volume is
			* to be calculated.
			* @returns TS_SUCCESS on success. (always)
			*
			* Calculate normal vector of the triangle (xnorm, ynorm and znorm) and stores
			* information. At the same time
			* triangle area is determined, since we already have the normal and volume of
			* triangular pyramid with given triangle as a base and vesicle centroid as a
			* tip.
			*
			* Function receives one argument of type ts_triangle. It should be corectly
			* initialized. The
			* result is stored in triangle->xnorm, triangle->ynorm, triangle->znorm.
			* Area and volume are stored into triangle->area and triangle->volume.
			* Returns TS_SUCCESS on completion.
			*
			* NOTE: Function uses math.h library. Function pow implementation is selected
			* accordind to the used TS_DOUBLE_* definition set in general.h, so it should
			* be compatible with any type of floating point precision.
			*
			* Example of usage:
			* triangle_normal_vector(tlist->tria[3]);
			*
			* Computes normals and stores information into tlist->tria[3]->xnorm,
			* tlist->tria[3]->ynorm, tlist->tria[3]->znorm tlist->tria[3]->area and
			* tlist->tria[3]->volume.
			*
			*/
			ts_bool triangle_normal_vector(ts_triangle *tria){
			ts_double x21,x31,y21,y31,z21,z31,xden;
			x21=tria->data->vertex[1]->data->x - tria->data->vertex[0]->data->x;
			x31=tria->data->vertex[2]->data->x - tria->data->vertex[0]->data->x;
			y21=tria->data->vertex[1]->data->y - tria->data->vertex[0]->data->y;
			y31=tria->data->vertex[2]->data->y - tria->data->vertex[0]->data->y;
			z21=tria->data->vertex[1]->data->z - tria->data->vertex[0]->data->z;
			z31=tria->data->vertex[2]->data->z - tria->data->vertex[0]->data->z;
			x21=tria->vertex[1]->x - tria->vertex[0]->x;
			x31=tria->vertex[2]->x - tria->vertex[0]->x;
			y21=tria->vertex[1]->y - tria->vertex[0]->y;
			y31=tria->vertex[2]->y - tria->vertex[0]->y;
			z21=tria->vertex[1]->z - tria->vertex[0]->z;
			z31=tria->vertex[2]->z - tria->vertex[0]->z;

			tria->data->xnorm=y21z31 - z21y31;
			tria->data->ynorm=z21x31 - x21z31;
			tria->data->znorm=x21y31 - y21x31;
			xden=tria->data->xnorm*tria->data->xnorm +
			tria->data->ynorm*tria->data->ynorm +
			tria->data->znorm*tria->data->znorm;
			tria->xnorm=y21z31 - z21y31;
			tria->ynorm=z21x31 - x21z31;
			tria->znorm=x21y31 - y21x31;
			xden=tria->xnorm*tria->xnorm +
			tria->ynorm*tria->ynorm +
			tria->znorm*tria->znorm;
			#ifdef TS_DOUBLE_DOUBLE
			xden=sqrt(xden);
			#endif
			@@ -115,23 +232,53 @@
			#ifdef TS_DOUBLE_LONGDOUBLE
			xden=sqrtl(xden);
			#endif
			tria->data->xnorm=tria->data->xnorm/xden;
			tria->data->ynorm=tria->data->ynorm/xden;
			tria->data->znorm=tria->data->znorm/xden;
			tria->xnorm=tria->xnorm/xden;
			tria->ynorm=tria->ynorm/xden;
			tria->znorm=tria->znorm/xden;

			/* Here it is an excellent point to recalculate volume of the triangle and
			* store it into datastructure. Volume is required at least by constant volume
			* calculation of vertex move and bondflip and spherical harmonics. */
			tria->volume=(tria->vertex[0]->x+ tria->vertex[1]->x + tria->vertex[2]->x) * tria->xnorm +
			(tria->vertex[0]->y+ tria->vertex[1]->y + tria->vertex[2]->y) * tria->ynorm +
			(tria->vertex[0]->z+ tria->vertex[1]->z + tria->vertex[2]->z) * tria->znorm;
			tria->volume=-xden*tria->volume/18.0;
			/* Also, area can be calculated in each triangle */
			tria->area=xden/2;


			return TS_SUCCESS;
			}


			ts_bool triangle_data_free(ts_triangle_data *data){
			if(data->neigh!=NULL) free(data->neigh);
			free(data);
			return TS_SUCCESS;
			}

			/** @brief Frees the memory allocated for data structure of triangle list
			* @param *tlist is a pointer to datastructure triangle list to be freed.
			* @returns TS_SUCCESS on success (always).
			*
			* Function frees the memory of ts_triangle_list previously allocated. It
			* accepts one argument, the address of data structure. It destroys all
			* ts_triangle's in the list with underlying data (by calling
			* triangle_data_free()), and the list itself.
			*
			* Should be used eveytime the deletion of triangle list (created by
			* init_triangle_list() and altered by add_triangle() or remove_triangle()) is desired.
			*
			* WARNING: The function doesn't check whether the pointer is NULL or invalid. It is the
			* job of programmer to make sure the pointer is valid.
			*
			* WARNING: Careful when destroying triangle lists. There could be pointers to
			* that information remaining in structures like vertex_data. This pointers
			* will be rendered invalid by this operation and should not be used anymore.
			*
			* Example of usage:
			* triangle_list_free(tlist);
			*
			* Clears all the information on triangles.
			*
			*/
			ts_bool triangle_list_free(ts_triangle_list *tlist){
			ts_uint i;
			for(i=0;i<tlist->n;i++){
			triangle_data_free(tlist->tria[i]->data);
			if(tlist->tria[i]->neigh!=NULL) free(tlist->tria[i]->neigh);
			free(tlist->tria[i]);
			}
			free(tlist->tria);