void wendy_GIO_ROP::save_mata_ass(string arDsoPath,string dpCachePath,GU_Detail *gdp ) { //get arnold dso path g_particle_mataAss assROP; ofstream fout; string getCacheDP=dpCachePath; stringstream ss(getCacheDP); string sub_str; vector <string> sp_strPath; sp_strPath.clear(); while(getline(ss,sub_str,'.')) { sp_strPath.push_back(sub_str); } string newAssPathName = sp_strPath[0]+"."+sp_strPath[1]+string(".ass"); fout.open(newAssPathName); assROP.setGioCachePath(getCacheDP); // set Link GIO CACHE for (GA_AttributeDict::iterator it = gdp->getAttributeDict(GA_ATTRIB_POINT).begin(GA_SCOPE_PUBLIC); !it.atEnd(); ++it) { GA_Attribute *attrib = it.attrib(); string attName( attrib->getName() ); assROP.inserExtraMataInfo(attName); } //set ass bbox UT_BoundingBox BBOX; gdp->getBBox(&BBOX); BBOX.expandBounds(2,2,2); float min_x=BBOX.xmin(); float min_y=BBOX.xmin(); float min_z=BBOX.xmin(); float max_x=BBOX.xmax(); float max_y=BBOX.ymax(); float max_z=BBOX.zmax(); assROP.setBBOX(min_x,min_y,min_z,max_x,max_y,max_z); assROP.setDsoPath(arDsoPath); assROP.save(fout); fout.close(); }
int main(int argc, char *argv[]) { logger.setLogLevel(Logging::Debug); struct args a; setArgs(a, argc, argv); GU_Detail gdp; bool binary = false; bool bbox = false; if( a.b ) binary = true; // convert all files in directory from hsff to geo or bgeo if (a.cd || a.c) { logger.debug("Found argument -cd or -c, trying to convert files in a directory."); std::vector<std::string> filesToConvert; if( a.cd ) { logger.debug("Found argument -cd trying to convert files in a directory."); std::string info("Directory: "); info += a.cdDir; logger.debug(info); if( binary ) logger.debug("Exporting binary bgeo files"); else logger.debug("Exporting ascii geo files"); //dirname.harden(argv[1]); // what does this mean, harden??? fs::path p(a.cdDir); getHsffFiles(p, filesToConvert, binary); }else{ logger.debug("Found argument -c trying to convert exactly one file."); //filename = UT_String(args.argp('c')); std::string info("Filename."); info += a.cFile; logger.debug(info); filesToConvert.push_back(a.cFile); } // export geo loop for( uint fId = 0; fId < filesToConvert.size(); fId++) { Hsff inFile(filesToConvert[fId]); if(!inFile.good) { logger.error(std::string("Error: problems reading file ") + filesToConvert[fId]); //cerr << "Error: problems reading file " << filesToConvert[fId] << "\n"; inFile.close(); continue; } logger.debug(std::string("Converting file ") + filesToConvert[fId]); //cout << "Converting " << filesToConvert[fId] << "\n"; inFile.doBinary = binary; unsigned int geoType = inFile.readGeoType(); switch(geoType) { case PARTICLE: //cout << "Detected particle file.\n"; createParticleGeo(inFile); break; case FLUID: //cout << "Detected fluid file.\n"; createFluidGeo(inFile); break; case MESH: //cout << "Detected mesh file.\n"; createMeshGeo(inFile); break; case CURVE: //cout << "Detected curve file.\n"; createCurveGeo(inFile); break; case NURBS: //cout << "Detected nurbs file.\n"; createNurbsGeo(inFile); break; } inFile.close(); } return 0; } // get bbox from 1st argument if (a.bbox) { std::string info("Getting BBox of "); info += a.bboxfile; logger.debug(info); if( !isValid(fs::path(a.bboxfile))) { logger.error("Could not read file."); return 1; } UT_BoundingBox bbox; getBBox(a.bboxfile, bbox); cout << "BBox: " << bbox.xmin() << " " << bbox.ymin() << " " << bbox.zmin() << " " << bbox.xmax() << " " << bbox.ymax() << " " << bbox.zmax() << "\n"; } if (a.ptc) { std::string info("Getting pointcloud of "); info += a.ptcfile; logger.debug(info); std::string outFile = pystring::replace(a.ptcfile, ".geo", ".hsffp"); // add a 'p' to show that it is a point cloud file from this tool if( pystring::endswith(a.ptcfile, "bgeo")) outFile = pystring::replace(a.ptcfile, ".bgeo", ".hsffp"); // add a 'p' to show that it is a point cloud file from this tool UT_BoundingBox bbox; readPtc(a.ptcfile, outFile, a.ptcdv, bbox); cout << "BBox: " << bbox.xmin() << " " << bbox.ymin() << " " << bbox.zmin() << " " << bbox.xmax() << " " << bbox.ymax() << " " << bbox.zmax() << "\n"; } //cout << "numargs: " << args.argc() << "\n"; // if (args.argc() == 3) //{ // UT_String dobin; // // dobin.harden(argv[2]); // if(dobin.isInteger()) // { // if( dobin.toInt() == 0) // binary = true; // else // binary = false; // } //} //if(binary) // cout << "Writing from source dir " << dirname << " as binary\n"; //else // cout << "Writing from source dir " << dirname << " as ascii\n"; return 0; }
void SOP_Scallop::SaveDivMap(float time) { OP_Context context(time); bool clip = (lockInputs(context) < UT_ERROR_ABORT); UT_BoundingBox bbox; if(clip) { const GU_Detail* input = inputGeo(0,context); if(input != NULL) { //UT_Matrix4 bm; int res = input->getBBox(&bbox); if(res == 0) clip = false; } else clip = false; unlockInputs(); }; if(!clip) return; UT_String file; STR_PARM(file,"mappath", 11, 0, time); float& now=time; ////////////////////////////////////////////////////////////////////////// Daemon::now=now; Daemon::bias = evalFloat("bias",0,now); int cnt = evalInt("daemons", 0, now); Daemon* daemons=new Daemon[cnt]; float weights = 0; int totd=0; float maxR = 0; for(int i=1;i<=cnt;i++) { bool skip = (evalIntInst("enabled#",&i,0,now)==0); if(skip) continue; Daemon& d = daemons[totd]; UT_String path = ""; evalStringInst("obj#", &i, path, 0, now); if(path == "") continue; SOP_Node* node = getSOPNode(path); OBJ_Node* obj = dynamic_cast<OBJ_Node*>(node->getParent()); if(obj == NULL) continue; obj->getWorldTransform(d.xform,context); d.weight = evalFloatInst("weight#",&i,0,now); d.c[0] = evalFloatInst("color#",&i,0,now); d.c[1] = evalFloatInst("color#",&i,1,now); d.c[2] = evalFloatInst("color#",&i,2,now); int mth = evalIntInst("model#",&i,0,now); switch(mth) { case 1: d.method = Methods::Spherical; break; case 2: d.method = Methods::Polar; break; case 3: d.method = Methods::Swirl; break; case 4: d.method = Methods::Trigonometric; break; case 5: { UT_String script; evalStringInst("vexcode#", &i, script, 0, now); d.SetupCVEX(script); break; }; case 0: default: d.method = Methods::Linear; }; d.power = evalFloatInst("power#",&i,0,now); d.radius = evalFloatInst("radius#",&i,0,now); d.parameter = evalFloatInst("parameter#",&i,0,now); if(d.radius > maxR) maxR = d.radius; weights+=d.weight; totd++; }; if(totd == 0) { delete [] daemons; return; }; float base = 0.0; for(int i=0;i<totd;i++) { Daemon& d = daemons[i]; d.range[0]=base; d.range[1] = base+d.weight/weights; base=d.range[1]; }; ////////////////////////////////////////////////////////////////////////// int total = evalInt("count",0,now); int degr = evalInt("degr",0,now); total >>= degr; GU_Detail det; UT_Vector3 current(0,0,0); float C[3] = { 0,0,0 }; float R=1.0f; float param=0.0f; srand(0); bool medial = (evalInt("mapmedial",0,now)!=0); int mapdiv = evalInt("mapdiv",0,now); //BoundBox Box; OctreeBox O(mapdiv); //if(medial) //{ O.bbox=bbox; //} //else //{ // BoundBox::limit = evalInt("nodecount", 0, now); // BoundBox::medial = (evalInt("mapmedial",0,now)!=0); // float boxb[6]; // memcpy(boxb,bbox.minvec().vec,12); // memcpy(boxb+3,bbox.maxvec().vec,12); // Box.Organize(boxb); //}; for(int i=-50;i<total;i++) { bool ok = false; float w = double(rand())/double(RAND_MAX); for(int j=0;j<totd;j++) { ok = daemons[j].Transform(w,current,C,R,param); if(ok) break; }; if(i<0) continue; //if(medial) //{ float P[4] = { current.x(), current.y(), current.z(), R }; O.Insert(P); //} //else //{ // Box.CheckPoint(current.vec); //} }; delete [] daemons; ////////////////////////////////////////////////////////////////////////// int ita[3] = {-1,-1,-1}; //if(medial) //{ int count = 0; OctreeBox::at = det.addPrimAttrib("count",4,GB_ATTRIB_INT,&count); det.addVariableName("count","COUNT"); float radius = 0.0f; OctreeBox::rt = det.addAttrib("radius",4,GB_ATTRIB_FLOAT,&radius); det.addVariableName("radius","RADIUS"); OctreeBox::it = det.addPrimAttrib("mask",12,GB_ATTRIB_INT,ita); det.addVariableName("mask","MASK"); float box[6] = {bbox.xmin(),bbox.xmax(),bbox.ymin(),bbox.ymax(),bbox.zmin(),bbox.zmax()}; det.addAttrib("bbox",24,GB_ATTRIB_FLOAT,box); O.maxlevel = 0x01<<mapdiv; O.parentbbox = bbox; O.Build(det); //} //else Box.Build(det); det.save(file.buffer(),1,NULL); // ...SAVE ATLAS { UT_String atlas =file; atlas+=".atlas"; FILE* fa = fopen(atlas.buffer(),"wb"); GEO_PrimList& pl = det.primitives(); int cnt = pl.entries(); fwrite(&cnt,sizeof(int),1,fa); float bb[6] = { bbox.xmin(), bbox.xmax(), bbox.ymin(), bbox.ymax(), bbox.zmin(), bbox.zmax() }; fwrite(bb,sizeof(float),6,fa); fwrite(&(O.maxlevel),sizeof(int),1,fa); fwrite(&(O.maxlevel),sizeof(int),1,fa); fwrite(&(O.maxlevel),sizeof(int),1,fa); for(int i=0;i<cnt;i++) { const GEO_PrimVolume* v = dynamic_cast<const GEO_PrimVolume*>(pl[i]); UT_BoundingBox b; v->getBBox(&b); float _bb[6] = { b.xmin(), b.xmax(), b.ymin(), b.ymax(), b.zmin(), b.zmax() }; fwrite(_bb,sizeof(float),6,fa); // MASK fwrite(v->castAttribData<int>(OctreeBox::it),sizeof(int),3,fa); } fclose(fa); } };