#include "UserData.h" #include "parse.h" void freeUserData(UserData data){ if(data!=NULL){ if(data->trmix!=NULL){ delete data->trmix; printf("Transport Deleted!\n"); } if(data->gas!=NULL){ delete data->gas; printf("Gas Deleted!\n"); } if(data->adaptiveGrid){ if(data->grid->xOld!=NULL){ delete[] data->grid->xOld; printf("old grid array Deleted!\n"); } if(data->grid->x!=NULL){ delete[] data->grid->x; printf("current grid array Deleted!\n"); } if(data->grid!=NULL){ free(data->grid); printf("grid object Freed!\n"); } } else{ if(data->uniformGrid!=NULL){ delete[] data->uniformGrid; printf("uniformGrid deleted!\n"); } } if(data->innerMassFractions!=NULL){ delete[] data->innerMassFractions; printf("innerMassFractions array Deleted!\n"); } if(data->output!=NULL){ fclose(data->output); printf("Output File Cleared from Memory!\n"); } if(data->gridOutput!=NULL){ fclose(data->gridOutput); printf("Grid Output File Cleared from Memory!\n"); } //if(data->ratesOutput!=NULL){ // fclose(data->ratesOutput); // printf("Rates Output File Cleared from Memory!\n"); //} if(data->globalOutput!=NULL){ fclose(data->globalOutput); printf("Global Output File Cleared from Memory!\n"); } } free(data); /* Free the user data */ printf("\n\n"); } UserData allocateUserData(FILE *input){ UserData data; data = (UserData) malloc(sizeof *data); if(!data){ printf("Allocation Failed!\n"); return(NULL); } setSaneDefaults(data); int ier; ier=parseNumber(input, "basePts" , MAXBUFLEN, &data->npts); if(ier==-1 || data->npts<=0){ printf("Enter non-zero basePts!\n"); return(NULL); } ier=parseNumber(input, "domainLength", MAXBUFLEN, &data->domainLength); if(ier==-1 || data->domainLength<=0.0e0){ printf("domainLength error!\n"); return(NULL); } ier=parseNumber(input, "constantPressure" , MAXBUFLEN, &data->constantPressure); if(ier==-1 || (data->constantPressure!=0 && data->constantPressure!=1)){ printf("constantPressure error!\n"); return(NULL); } ier=parseNumber(input, "problemType" , MAXBUFLEN, &data->problemType); if(ier==-1 || (data->problemType!=0 && data->problemType!=1 && data->problemType!=2 && data->problemType!=3)){ printf("include valid problemType!\n"); printf("0: premixed combustion with NO equilibrated ignition kernel\n"); printf("1: premixed combustion WITH equilibrated ignition kernel\n"); printf("2: arbitrary initial conditions\n"); printf("3: Restart\n"); return(NULL); } ier=parseNumber(input, "dPdt" , MAXBUFLEN, &data->dPdt); ier=parseNumber (input, "reflectProblem" , MAXBUFLEN, &data->reflectProblem); if(data->reflectProblem!=0 && data->reflectProblem!=1){ printf("Invalid entry for reflectProblem! Can be only 1 or 0.\n"); return(NULL); } ier=parseNumber(input, "mdot" , MAXBUFLEN, &data->mdot); ier=parseNumber(input, "initialTemperature", MAXBUFLEN, &data->initialTemperature); if(ier==-1 || data->initialTemperature<=0.0e0){ printf("Enter positive initialTemperature in K!\n"); return(NULL); } ier=parseNumber(input, "initialPressure", MAXBUFLEN, &data->initialPressure); if(ier==-1 || data->initialTemperature<=0.0e0){ printf("Enter positive initialPressure in atm!\n"); return(NULL); } ier=parseNumber (input, "metric" , MAXBUFLEN, &data->metric); if(data->metric!=0 && data->metric!=1 && data->metric!=2){ printf("Invalid entry for metric!\n"); printf("0: Cartesian\n"); printf("1: Cylindrical\n"); printf("2: Spherical\n"); return(NULL); } ier=parseNumber(input, "QDot", MAXBUFLEN, &data->maxQDot); if(ier==-1 && data->problemType==0){ printf("Need to specify QDot for problemType 0!\n"); return(NULL); } ier=parseNumber(input, "kernelSize", MAXBUFLEN, &data->kernelSize); if(ier==-1 && data->problemType==0){ printf("Need to specify kernelSize for problemType 0!\n"); return(NULL); } ier=parseNumber(input, "ignTime", MAXBUFLEN, &data->ignTime); if(ier==-1 && data->problemType==0){ printf("Need to specify ignTime for problemType 0!\n"); return(NULL); } ier=parseNumber(input, "mixingWidth", MAXBUFLEN, &data->mixingWidth); if(ier==-1){ printf("Need to specify mixingWidth!\n"); return(NULL); } ier=parseNumber(input, "shift", MAXBUFLEN, &data->shift); ier=parseNumber(input, "firstRadius", MAXBUFLEN, &data->firstRadius); ier=parseNumber(input, "wallTemperature", MAXBUFLEN, &data->wallTemperature); ier=parseNumber (input, "dirichletInner" , MAXBUFLEN, &data->dirichletInner); if(data->dirichletInner!=0 && data->dirichletInner!=1){ printf("dirichletInner can either be 0 or 1!\n"); return(NULL); } ier=parseNumber (input, "dirichletOuter" , MAXBUFLEN, &data->dirichletOuter); if(data->dirichletOuter!=0 && data->dirichletOuter!=1){ printf("dirichletOuter can either be 0 or 1!\n"); return(NULL); } ier=parseNumber (input, "adaptiveGrid" , MAXBUFLEN, &data->adaptiveGrid); if(ier==-1 || (data->adaptiveGrid!=0 && data->adaptiveGrid!=1)){ printf("specify adaptiveGrid as 0 or 1!\n"); return(NULL); } ier=parseNumber (input, "moveGrid" , MAXBUFLEN, &data->moveGrid); if(ier==-1 || (data->moveGrid!=0 && data->moveGrid!=1)){ printf("specify moveGrid as 0 or 1!\n"); return(NULL); } ier=parseNumber (input, "isotherm" , MAXBUFLEN, &data->isotherm); if(ier==-1){ printf("specify temperature of isotherm!\n"); return(NULL); } ier=parseNumber(input, "gridOffset", MAXBUFLEN, &data->gridOffset); ier=parseNumber (input, "nSaves" , MAXBUFLEN, &data->nSaves); if(data->nSaves<0 ){ printf("nSaves must be greater than 0!\n"); return(NULL); } ier=parseNumber (input, "writeRates" , MAXBUFLEN, &data->writeRates); if(data->writeRates!=0 && data->writeRates!=1){ printf("writeRates must either be 0 or 1!\n"); return(NULL); } ier=parseNumber (input, "writeEveryRegrid", MAXBUFLEN, &data->writeEveryRegrid); if(data->writeEveryRegrid!=0 && data->writeEveryRegrid!=1){ printf("writeEveryRegrid must either be 0 or 1!\n"); return(NULL); } ier=parseNumber (input, "writeDeltaT", MAXBUFLEN, &data->writeDeltaT); ier=parseNumber (input, "setConstraints" , MAXBUFLEN, &data->setConstraints); if(data->setConstraints!=0 && data->setConstraints!=1){ printf("setConstraints must either be 0 or 1!\n"); return(NULL); } ier=parseNumber (input, "suppressAlg" , MAXBUFLEN, &data->suppressAlg); if(data->setConstraints!=0 && data->suppressAlg!=1){ printf("suppressAlg must either be 0 or 1!\n"); return(NULL); } ier=parseNumber (input, "dryRun" , MAXBUFLEN, &data->dryRun); if(data->dryRun!=0 && data->dryRun!=1){ printf("dryRun must either be 0 or 1!\n"); return(NULL); } ier=parseNumber (input, "finalTime" , MAXBUFLEN, &data->finalTime); ier=parseNumber (input, "relativeTolerance" , MAXBUFLEN, &data->relativeTolerance); ier=parseNumber (input, "radiusTolerance" , MAXBUFLEN, &data->radiusTolerance); ier=parseNumber (input, "temperatureTolerance", MAXBUFLEN, &data->temperatureTolerance); ier=parseNumber (input, "pressureTolerance", MAXBUFLEN, &data->pressureTolerance); ier=parseNumber (input, "massFractionTolerance", MAXBUFLEN, &data->massFractionTolerance); ier=parseNumber (input, "bathGasTolerance", MAXBUFLEN, &data->bathGasTolerance); char chem[MAXBUFLEN],mix[MAXBUFLEN],tran[MAXBUFLEN]; ier=parseNumber(input, "chemistryFile" , MAXBUFLEN, chem); if(ier==-1){ printf("Enter chemistryFile!\n"); return(NULL); }else{ try{ data->gas = new Cantera::IdealGasMix(chem); data->nsp=data->gas->nSpecies(); //assign no: of species } catch (Cantera::CanteraError& err) { printf("Error:\n"); printf("%s\n",err.what()); return(NULL); } } ier=parseNumber(input, "transportModel", MAXBUFLEN, tran); if(ier==-1){ printf("Enter transportModel!\n"); return(NULL); }else{ try{ data->trmix = Cantera::newTransportMgr(tran, data->gas); }catch (Cantera::CanteraError& err) { printf("Error:\n"); printf("%s\n",err.what()); return(NULL); } } ier=parseNumber(input, "mixtureComposition", MAXBUFLEN, mix); if(ier==-1){ printf("Enter mixtureComposition!\n"); return(NULL); }else{ if(data->gas!=NULL){ try{ data->gas->setState_TPX(data->initialTemperature, data->initialPressure*Cantera::OneAtm, mix); }catch (Cantera::CanteraError& err) { printf("Error:\n"); printf("%s\n",err.what()); return(NULL); } } } ier=parseNumber (input, "nThreads" , MAXBUFLEN, &data->nThreads); if(data->nThreads<0 ){ printf("nThreads must be greater than 0!\n"); return(NULL); } data->nr=0; //data->np=data->nr+1; data->nt=data->nr+1; data->ny=data->nt+1; data->np=data->ny+data->nsp; data->nvar=data->nsp+3; //assign no: of variables (R,T,P,nsp species) if(!data->adaptiveGrid){ data->uniformGrid = new double [data->npts]; data->neq=data->nvar*data->npts; } else{ data->grid=(UserGrid) malloc(sizeof *data->grid); ier=getGridSettings(input,data->grid); if(ier==-1)return(NULL); ier=initializeGrid(data->grid); if(ier==-1)return(NULL); ier=reGrid(data->grid, data->grid->position); if(ier==-1)return(NULL); data->npts=data->grid->nPts; data->neq=data->nvar*data->npts; } data->output=fopen("output.dat","w"); data->globalOutput=fopen("globalOutput.dat","w"); data->gridOutput=fopen("grid.dat","w"); //data->ratesOutput=fopen("rates.dat","w"); data->innerMassFractions = new double [data->nsp]; return(data); } void setSaneDefaults(UserData data){ data->domainLength=1.0e-02; data->constantPressure=1; data->problemType=1; data->dPdt=0.0e0; data->reflectProblem=0; data->mdot=0.0; data->initialTemperature=300.0; data->initialPressure=1.0; data->metric=0; data->ignTime=1e-09; data->maxQDot=0.0e0; data->maxTemperature=300.0e0; data->mixingWidth=1e-04; data->shift=3.0e-03; data->firstRadius=1e-04; data->wallTemperature=298.0e0; data->dirichletInner=0; data->dirichletOuter=0; data->adaptiveGrid=0; data->moveGrid=0; data->gridOffset=0.0e0; data->isotherm=1000.0; data->nSaves=30; data->writeRates=0; data->writeEveryRegrid=0; data->writeDeltaT=1e-04; data->relativeTolerance=1e-06; data->radiusTolerance=1e-08; data->temperatureTolerance=1e-06; data->pressureTolerance=1e-06; data->massFractionTolerance=1e-09; data->bathGasTolerance=1e-06; data->finalTime=1e-02; data->tNow=0.0e0; data->setConstraints=0; data->suppressAlg=1; data->regrid=0; data->gridDirection=1; data->dryRun=0; data->nThreads=1; data->flamePosition[0]=0.0e0; data->flamePosition[1]=0.0e0; data->flameTime[0]=0.0e0; data->flameTime[1]=0.0e0; data->nTimeSteps=0; }