trisurf-ng.git - Gitblit

			@@ -1,3 +1,4 @@
			/* vim: set ts=4 sts=4 sw=4 noet : */
			#include <stdio.h>
			#include <string.h>
			#include <stdlib.h>
			@@ -9,11 +10,17 @@
			#include <zlib.h>
			#include "vesicle.h"
			#include "vertex.h"
			ts_bool parseDump(char *dumpfname) {
			xmlDocPtr doc;
			xmlNodePtr cur;
			ts_vesicle *vesicle;
			#include "triangle.h"
			#include "bond.h"
			#include "energy.h"
			#include "poly.h"
			#include "initial_distribution.h"
			#include "io.h"

			ts_vesicle parseDump(char dumpfname) {
			xmlDocPtr doc;
			xmlNodePtr cur, cur1,cur2;
			ts_vesicle *vesicle=NULL;
			doc = xmlParseFile(dumpfname);

			if (doc == NULL ) {
			@@ -32,22 +39,68 @@

			cur = cur->xmlChildrenNode;
			while (cur != NULL) {

			if ((!xmlStrcmp(cur->name, (const xmlChar *)"tape"))){
			setGlobalTapeTXTfromTapeTag(doc, cur);
			}

			if ((!xmlStrcmp(cur->name, (const xmlChar *)"trisurf"))){
			vesicle=parseTrisurfTag(doc, cur);
			}

			// START Point Position data & Bonds
			if ((!xmlStrcmp(cur->name, (const xmlChar *)"UnstructuredGrid"))){
			cur1 = cur->xmlChildrenNode;
			while(cur1!=NULL){
			if ((!xmlStrcmp(cur1->name, (const xmlChar *)"Piece"))){
			cur2=cur1->xmlChildrenNode;
			while(cur2!=NULL){
			if ((!xmlStrcmp(cur2->name, (const xmlChar *)"Points"))){
			//fprintf(stderr,"Found point data\n");
			if(vesicle!=NULL)
			parseXMLVertexPosition(vesicle, doc, cur2);
			}
			if ((!xmlStrcmp(cur2->name, (const xmlChar *)"Cells"))){
			//fprintf(stderr,"Found cell(Bonds) data\n");
			if(vesicle!=NULL)
			parseXMLBonds(vesicle, doc, cur2);
			}
			cur2=cur2->next;
			}
			}
			cur1 = cur1->next;
			}
			}
			// END Point Position data & Bonds
			cur = cur->next;
			}

			xmlFreeDoc(doc);
			fprintf(stderr,"Restoration completed\n");
			exit(0);
			vesicle_free(vesicle);

			// vesicle->poly_list=init_poly_list(0, 0, vesicle->vlist, vesicle);

			init_normal_vectors(vesicle->tlist);
			mean_curvature_and_energy(vesicle);

			/* TODO: filaments */

			ts_fprintf(stdout,"Restoration completed\n");
			// write_vertex_xml_file(vesicle,999);
			// vesicle_free(vesicle);
			// exit(0);
			return vesicle;
			}

			ts_bool setGlobalTapeTXTfromTapeTag(xmlDocPtr doc, xmlNodePtr cur){
			xmlChar *tape = xmlNodeListGetString(doc, cur->xmlChildrenNode, 1);
			strcpy(tapetxt,(char *)tape);
			xmlFree(tape);
			return TS_SUCCESS;
			}


			/* this is a parser of additional data in xml */
			ts_vesicle *parseTrisurfTag(xmlDocPtr doc, xmlNodePtr cur){
			fprintf(stderr,"Parsing trisurf tag\n");
			//fprintf(stderr,"Parsing trisurf tag\n");
			xmlNodePtr child;

			#ifdef COMPRESS
			@@ -77,39 +130,56 @@
			inflateInit(&infstream);
			inflate(&infstream, Z_NO_FLUSH);
			inflateEnd(&infstream);
			fprintf(stderr,"%lu\n",cLen);
			//fprintf(stderr,"%lu\n",cLen);
			subtree[infstream.total_out]='\0'; //zero terminate string
			fprintf(stderr,"%s\n",subtree);
			//fprintf(stderr,"%s\n",subtree);

			free(subtree);
			#endif
			/parse xml subtree /
			xmlChar nvtx, npoly, *nfono;
			xmlChar nvtx, npoly, *nmono;
			nvtx = xmlGetProp(cur, (xmlChar *)"nvtx");
			npoly=xmlGetProp(cur, (xmlChar *)"npoly");
			nfono=xmlGetProp(cur, (xmlChar *)"nfono");
			fprintf(stderr,"nvtx=%u\n",atoi((char *)nvtx));
			ts_vesicle vesicle=init_vesicle(atoi((char )nvtx),10,10,10,0.1);
			nmono=xmlGetProp(cur, (xmlChar *)"nmono");
			ts_tape *tape=parsetapebuffer(tapetxt);
			//fprintf(stderr,"nvtx=%u\n",atoi((char *)nvtx));
			//TODO: check if nvtx is in agreement with nshell from tape
			ts_vesicle vesicle=init_vesicle(atoi((char )nvtx),tape->ncxmax,tape->ncymax,tape->nczmax,tape->stepsize);
			//vesicle->poly_list=init_poly_list(atoi((char )npoly),atoi((char )nmono), vesicle->vlist, vesicle);
			xmlFree(nvtx);
			xmlFree(npoly);
			xmlFree(nfono);
			xmlFree(nmono);

			child = cur->xmlChildrenNode;
			while (child != NULL) {
			if ((!xmlStrcmp(child->name, (const xmlChar *)"vtxn"))){
			parseTrisurfVtxn(vesicle->vlist, doc, child);
			}

			if ((!xmlStrcmp(child->name, (const xmlChar *)"tria"))){
			parseTrisurfTria(vesicle, doc, child);
			}
			if ((!xmlStrcmp(child->name, (const xmlChar *)"trianeigh"))){
			parseTrisurfTriaNeigh(vesicle, doc, child);
			}
			if ((!xmlStrcmp(child->name, (const xmlChar *)"tristar"))){
			parseTrisurfTristar(vesicle, doc, child);
			}

			child = child->next;
			}


			vesicle->tape=tape;
			set_vesicle_values_from_tape(vesicle);

			return vesicle;
			}

			ts_bool parseTrisurfVtxn(ts_vertex_list vlist, xmlDocPtr doc, xmlNodePtr cur){


			/* Low level tags parsers */

			ts_bool parseTrisurfVtxn(ts_vertex_list *vlist, xmlDocPtr doc, xmlNodePtr cur){

			xmlChar *chari;
			xmlChar *neighs;
			@@ -136,3 +206,159 @@
			return TS_SUCCESS;
			}

			ts_bool parseTrisurfTria(ts_vesicle *vesicle, xmlDocPtr doc, xmlNodePtr cur){
			xmlChar *triangles;
			char *tria;
			char *vtx[3];

			ts_uint i,j;
			triangles = xmlNodeListGetString(doc, cur->xmlChildrenNode, 1);
			tria=(char *)triangles;
			vtx[0]=strtok(tria," ");
			for(i=1;i<3;i++) vtx[i]=strtok(NULL," ");
			j=0;
			while(vtx[2]!=NULL){
			triangle_add(vesicle->tlist, vesicle->vlist->vtx[atoi(vtx[0])],vesicle->vlist->vtx[atoi(vtx[1])],vesicle->vlist->vtx[atoi(vtx[2])]);
			for(i=0;i<3;i++) vtx[i]=strtok(NULL," ");
			j++;
			}
			//fprintf(stderr,"Parsing triangles %s j=%d\n",triangles,j);

			xmlFree(triangles);
			return TS_SUCCESS;
			}


			ts_bool parseTrisurfTriaNeigh(ts_vesicle *vesicle, xmlDocPtr doc, xmlNodePtr cur){
			xmlChar *triangles;
			char *tria;
			char *ntria[3];
			ts_uint i,j;
			triangles = xmlNodeListGetString(doc, cur->xmlChildrenNode, 1);
			tria=(char *)triangles;
			ntria[0]=strtok(tria," ");
			for(i=1;i<3;i++) ntria[i]=strtok(NULL," ");
			j=0;
			while(ntria[2]!=NULL){
			triangle_add_neighbour(vesicle->tlist->tria[j],vesicle->tlist->tria[atoi(ntria[0])]);
			triangle_add_neighbour(vesicle->tlist->tria[j],vesicle->tlist->tria[atoi(ntria[1])]);
			triangle_add_neighbour(vesicle->tlist->tria[j],vesicle->tlist->tria[atoi(ntria[2])]);
			j++;
			for(i=0;i<3;i++) ntria[i]=strtok(NULL," ");
			}
			//fprintf(stderr,"Parsing triangle neighbors j=%d\n",j);

			xmlFree(triangles);
			return TS_SUCCESS;
			}


			ts_bool parseTrisurfTristar(ts_vesicle *vesicle, xmlDocPtr doc, xmlNodePtr cur){

			xmlChar *chari;
			xmlChar *tristar;
			char *t;
			char *token;
			ts_uint neighi;
			ts_uint i;
			chari = xmlGetProp(cur, (xmlChar *)"idx");
			i=atoi((char *)chari);
			xmlFree(chari);
			ts_vertex *vtx=vesicle->vlist->vtx[i];
			tristar = xmlNodeListGetString(doc, cur->xmlChildrenNode, 1);
			// fprintf(stderr,"Found tristar for vtx %u that seems to have index %u with tristar=%s\n",i,vtx->idx,tristar);

			t=(char *)tristar;
			token=strtok(t," ");
			while(token!=NULL){
			neighi=atoi(token);
			//fprintf(stderr,"%u", neighi);
			vertex_add_tristar(vtx,vesicle->tlist->tria[neighi]);
			token=strtok(NULL," ");
			}
			xmlFree(tristar);
			return TS_SUCCESS;
			}


			/* this is a parser of vertex positions and bonds from main xml data */
			ts_bool parseXMLVertexPosition(ts_vesicle *vesicle,xmlDocPtr doc, xmlNodePtr cur){
			xmlNodePtr child = cur->xmlChildrenNode;
			xmlChar *points;
			char *pts;
			int i, idx, polyidx, monoidx;
			char *token[3];
			while (child != NULL) {
			if ((!xmlStrcmp(child->name, (const xmlChar *)"DataArray"))){
			points = xmlNodeListGetString(doc, child->xmlChildrenNode, 1);
			pts=(char *)points;
			token[0]=strtok(pts," ");
			token[1]=strtok(NULL," ");
			token[2]=strtok(NULL,"\n");
			idx=0;
			while(token[0]!=NULL){
			if(idx<vesicle->vlist->n){
			vesicle->vlist->vtx[idx]->x=atof(token[0]);
			vesicle->vlist->vtx[idx]->y=atof(token[1]);
			vesicle->vlist->vtx[idx]->z=atof(token[2]);
			} else {
			polyidx=(idx-vesicle->vlist->n)/vesicle->tape->nmono;
			monoidx=(idx-vesicle->vlist->n)%vesicle->tape->nmono;
			vesicle->poly_list->poly[polyidx]->vlist->vtx[monoidx]->x=atof(token[0]);
			vesicle->poly_list->poly[polyidx]->vlist->vtx[monoidx]->y=atof(token[1]);
			vesicle->poly_list->poly[polyidx]->vlist->vtx[monoidx]->z=atof(token[2]);
			}
			for(i=0;i<2;i++) token[i]=strtok(NULL," ");
			token[2]=strtok(NULL,"\n");
			idx++;
			}
			xmlFree(points);
			}
			child=child->next;
			}
			//fprintf(stderr,"Vertices position j=%d\n",idx);

			return TS_SUCCESS;
			}
			ts_bool parseXMLBonds(ts_vesicle *vesicle,xmlDocPtr doc, xmlNodePtr cur){
			xmlNodePtr child = cur->xmlChildrenNode;
			xmlChar bonds, conname;
			char *b;
			int idx, polyidx;
			char *token[2];
			while (child != NULL) {
			conname=xmlGetProp(child, (xmlChar *)"Name");
			if ((!xmlStrcmp(child->name, (const xmlChar )"DataArray")) && !xmlStrcmp(conname, (const xmlChar )"connectivity") ){
			bonds = xmlNodeListGetString(doc, child->xmlChildrenNode, 1);
			b=(char *)bonds;
			token[0]=strtok(b," ");
			token[1]=strtok(NULL,"\n");
			idx=0;
			while(token[0]!=NULL){
			if(idx<3*(vesicle->vlist->n-2)){
			bond_add(vesicle->blist, vesicle->vlist->vtx[atoi(token[0])], vesicle->vlist->vtx[atoi(token[1])]);
			}
			else {
			//find grafted vtx
			if((vesicle->tape->nmono-1)==(idx-3*(vesicle->vlist->n-2))%(vesicle->tape->nmono)){
			polyidx=(idx-3*(vesicle->vlist->n-2))/(vesicle->tape->nmono);
			//fprintf(stderr,"poly=%d, vertex=%d\n",polyidx,atoi(token[0]));
			vesicle->poly_list->poly[polyidx]->grafted_vtx=vesicle->vlist->vtx[atoi(token[0])];
			vesicle->vlist->vtx[atoi(token[0])]->grafted_poly=vesicle->poly_list->poly[polyidx];
			}
			}
			token[0]=strtok(NULL," ");
			token[1]=strtok(NULL,"\n");
			idx++;
			}
			xmlFree(bonds);
			}
			xmlFree(conname);
			child=child->next;
			}
			//fprintf(stderr,"Bond data j=%d\n",idx);
			return TS_SUCCESS;
			}