int main( int argc, char* argv[] )
{
  using Teuchos::rcp;
  using Teuchos::RCP;
  using Teuchos::OSTab;
  using MoochoPack::MoochoSolver;
  using MoochoPack::MoochoThyraSolver;
  using Teuchos::CommandLineProcessor;

  Teuchos::GlobalMPISession mpiSession(&argc, &argv);

  Teuchos::Time timer("");
  
  bool dummySuccess = true;

  Teuchos::RCP<Teuchos::FancyOStream>
    out = Teuchos::VerboseObjectBase::getDefaultOStream();

  try {
 
    //
    // A) Create the solver objects that will insert their command-line
    // options
    //

    MoochoThyraSolver solver;

    //
    // B) Get options from the command line
    //

    int localDim = 4;
    double pt = 0.0;
    double p0 = 0.1;
    double scale = 0.1;

    CommandLineProcessor clp;
    clp.throwExceptions(false);
    clp.addOutputSetupOptions(true);

    clp.setOption("local-dim", &localDim);
    clp.setOption("pt", &pt);
    clp.setOption("p0", &p0);
    clp.setOption("scale", &scale);

    solver.setupCLP(&clp);

    CommandLineProcessor::EParseCommandLineReturn
      parse_return = clp.parse(argc,argv,&std::cerr);

    if( parse_return != CommandLineProcessor::PARSE_SUCCESSFUL )
      return parse_return;

    solver.readParameters( out.get() );

    Teuchos::RCP<Epetra_Comm> comm = Teuchos::null;

#ifdef HAVE_MPI
    MPI_Comm mpiComm = MPI_COMM_WORLD;
    comm = Teuchos::rcp(new Epetra_MpiComm(mpiComm));
#else
    comm = Teuchos::rcp(new Epetra_SerialComm());
#endif
 
    //
    // C) Create the Thyra::ModelEvaluator object
    //
 
    *out << "\nCreate EpetraExt::DiagonalQuadraticResponseOnlyModelEvaluator object ...\n";
 
    Teuchos::RCP<EpetraExt::DiagonalQuadraticResponseOnlyModelEvaluator>
      epetraModel = EpetraExt::diagonalQuadraticResponseOnlyModelEvaluator(
        comm, localDim, pt, p0, scale);
      
    *out << "\nCreate the Thyra::EpetraModelEvaluator wrapper object ...\n";
    
    Teuchos::RCP<Thyra::EpetraModelEvaluator>
      epetraThyraModel(new Thyra::EpetraModelEvaluator()); // Sets default options!
    epetraThyraModel->initialize(epetraModel, Teuchos::null);
    
    //
    // D) Solve the NLP
    //
    
    // Set the model
    solver.setModel(epetraThyraModel);
    
    // Read the initial guess if one exists
    solver.readInitialGuess(out.get());
    
    // Solve the NLP
    const MoochoSolver::ESolutionStatus	solution_status = solver.solve();
    
    // Write the solution to file
    solver.writeFinalSolution(out.get());
    
    // Write the final parameters to file
    solver.writeParamsFile();
    
    //
    // E) Return the solution status (0 if successful)
    //
    
    if(solution_status == MoochoSolver::SOLVE_RETURN_SOLVED)
      *out << "\nEnd Result: TEST PASSED\n";
    else
      *out << "\nEnd Result: TEST FAILED\n";
    
    return solution_status;
    
  }
  TEUCHOS_STANDARD_CATCH_STATEMENTS(true, *out, dummySuccess)
    
  return MoochoSolver::SOLVE_RETURN_EXCEPTION;

}
コード例 #2
0
int main( int argc, char* argv[] )
{
  using Teuchos::CommandLineProcessor;
  typedef AbstractLinAlgPack::value_type  Scalar;
  using MoochoPack::MoochoSolver;
  using MoochoPack::MoochoThyraSolver;

  bool dummySuccess = true;

  Teuchos::GlobalMPISession mpiSession(&argc,&argv);

  Teuchos::RCP<Teuchos::FancyOStream>
    out = Teuchos::VerboseObjectBase::getDefaultOStream();

  try {

    Stratimikos::DefaultLinearSolverBuilder lowsfCreator;
    MoochoThyraSolver                     solver;
  
    //
    // Get options from the command line
    //
    
    Scalar       xt0         = 1.0;
    Scalar       xt1         = 1.0;
    Scalar       pt0         = 2.0;
    Scalar       pt1         = 0.0;
    Scalar       d           = 10.0;
    Scalar       x00         = 1.0;
    Scalar       x01         = 1.0;
    Scalar       p00         = 2.0;
    Scalar       p01         = 0.0;
    Scalar       pL0         = -1e+50;
    Scalar       pL1         = -1e+50;
    Scalar       pU0         = +1e+50;
    Scalar       pU1         = +1e+50;

    Scalar       xL0         = -1e+50;
    Scalar       xL1         = -1e+50;
    Scalar       xU0         = +1e+50;
    Scalar       xU1         = +1e+50;

    bool supportDerivs = true;

    std::string extraXmlFile = "";

    CommandLineProcessor  clp(false); // Don't throw exceptions

    lowsfCreator.setupCLP(&clp);
    solver.setupCLP(&clp);

    clp.setOption( "xt0", &xt0 );
    clp.setOption( "xt1", &xt1 );
    clp.setOption( "pt0", &pt0 );
    clp.setOption( "pt1", &pt1 );
    clp.setOption( "d", &d );
    clp.setOption( "x00", &x00 );
    clp.setOption( "x01", &x01 );
    clp.setOption( "p00", &p00 );
    clp.setOption( "p01", &p01 );
    clp.setOption( "pL0", &pL0 );
    clp.setOption( "pL1", &pL1 );
    clp.setOption( "pU0", &pU0 );
    clp.setOption( "pU1", &pU1 );
    clp.setOption( "xL0", &xL0 );
    clp.setOption( "xL1", &xL1 );
    clp.setOption( "xU0", &xU0 );
    clp.setOption( "xU1", &xU1 );
    clp.setOption( "support-derivs", "no-support-derivs", &supportDerivs );
    clp.setOption("extra-xml-file",&extraXmlFile,"File with extra XML text that will modify the initial XML read in");
 
    std::string line("");
    if(extraXmlFile.length()) {
      std::ifstream myfile(extraXmlFile.c_str());
      if (myfile.is_open())
      {
        getline (myfile,line);
        solver.extraParamsXmlStringOption(line);
        std::cout << line << "\n";
        myfile.close();
      }
    }

    CommandLineProcessor::EParseCommandLineReturn
      parse_return = clp.parse(argc,argv,&std::cerr);

    if( parse_return != CommandLineProcessor::PARSE_SUCCESSFUL )
      return parse_return;

    lowsfCreator.readParameters(out.get());
    solver.readParameters(out.get());

    //
    // Create the NLP
    //
    
    // Create the EpetraExt::ModelEvaluator object

    Teuchos::RCP<EpetraModelEval4DOpt>
      epetraModel = Teuchos::rcp(new EpetraModelEval4DOpt(xt0,xt1,pt0,pt1,d,x00,x01,p00,p01));
    epetraModel->setSupportDerivs(supportDerivs);
    epetraModel->set_p_bounds(pL0,pL1,pU0,pU1);
    epetraModel->set_x_bounds(xL0,xL1,xU0,xU1);

    // Create the Thyra::EpetraModelEvaluator object

    Teuchos::RCP<Thyra::LinearOpWithSolveFactoryBase<double> >
      lowsFactory = lowsfCreator.createLinearSolveStrategy("");

    Teuchos::RCP<Thyra::EpetraModelEvaluator>
      epetraThyraModel = Teuchos::rcp(new Thyra::EpetraModelEvaluator());
    
    epetraThyraModel->initialize(epetraModel,lowsFactory);
    
    //
    // Solve the NLP
    //
    
    // Set the model
    solver.setModel(epetraThyraModel);

    // Read the initial guess if one exists
    solver.readInitialGuess(out.get());

    // Solve the NLP
    const MoochoSolver::ESolutionStatus	solution_status = solver.solve();

    // Write the final solution if requested
    solver.writeFinalSolution(out.get());

    // Write the parameters that where read
    lowsfCreator.writeParamsFile(*lowsFactory);
    solver.writeParamsFile();
    
    //
    // Return the solution status (0 if sucessfull)
    //

    return solution_status;

  }
  TEUCHOS_STANDARD_CATCH_STATEMENTS(true,*out,dummySuccess)

  return MoochoSolver::SOLVE_RETURN_EXCEPTION;

}
コード例 #3
0
int main( int argc, char* argv[] )
{
  using Teuchos::rcp;
  using Teuchos::RCP;
  using Teuchos::OSTab;
  using MoochoPack::MoochoSolver;
  using MoochoPack::MoochoThyraSolver;
  using Teuchos::CommandLineProcessor;

  Teuchos::GlobalMPISession mpiSession(&argc,&argv);

  const int numProcs = mpiSession.getNProc();

  Teuchos::Time timer("");
  
  bool dummySuccess = true;

  Teuchos::RCP<Teuchos::FancyOStream>
    out = Teuchos::VerboseObjectBase::getDefaultOStream();

  try {
  
    // Create the solver object
    GLpApp::AdvDiffReactOptModelCreator     advDiffReacModelCreator;
    Stratimikos::DefaultLinearSolverBuilder   lowsfCreator;
    MoochoThyraSolver                       solver;

    //
    // Get options from the command line
    //

    std::string         matchingVecFile     = "";

    bool                showMoochoThyraParams = false;
    bool                showMoochoThyraParamsWithDoc = true;
    bool                showMoochoThyraParamsXML = false;

    CommandLineProcessor  clp;
    clp.throwExceptions(false);
    clp.addOutputSetupOptions(true);

    advDiffReacModelCreator.setupCLP(&clp);
    lowsfCreator.setupCLP(&clp);
    solver.setupCLP(&clp);

    clp.setOption(
      "q-vec-file", &matchingVecFile
      ,"Base file name to read the objective state matching "
      "vector q (i.e. ||x-q||_M in the objective)."
      );
    
    clp.setOption(
      "only-print-moocho-thyra-solver-params", "no-print-moocho-thyra-solver-params"
      ,&showMoochoThyraParams
      ,"Only print the parameters accepted by MoochoPack::MoochoThyraSolver and stop."
      );
    clp.setOption(
      "show-doc", "hide-doc", &showMoochoThyraParamsWithDoc
      ,"Show MoochoPack::MocohoThyraSolver parameters with documentation or not."
      );
    clp.setOption(
      "xml-format", "readable-format", &showMoochoThyraParamsXML
      ,"Show MoochoPack::MoochoThyraSolver parameters in XML or human-readable format."
      );

    CommandLineProcessor::EParseCommandLineReturn
      parse_return = clp.parse(argc,argv,&std::cerr);

    if( parse_return != CommandLineProcessor::PARSE_SUCCESSFUL )
      return parse_return;

    lowsfCreator.readParameters( !showMoochoThyraParams ? out.get() : NULL );
    solver.readParameters( !showMoochoThyraParams ? out.get() : NULL );

    if(showMoochoThyraParams) {
      typedef Teuchos::ParameterList::PrintOptions PLPrintOptions;
      if(showMoochoThyraParamsXML)
        Teuchos::writeParameterListToXmlOStream(
          *solver.getValidParameters()
          ,*out
          );
      else
        solver.getValidParameters()->print(
          *out,PLPrintOptions().indent(2).showTypes(true).showDoc(showMoochoThyraParamsWithDoc)
          );
      return 0;
    }

    //
    // Setup the output streams
    //
    
    Teuchos::RCP<Teuchos::FancyOStream>
      journalOut = Teuchos::rcp(
        new Teuchos::FancyOStream(
          solver.getSolver().generate_output_file("MoochoJournal")
          ,"  "
          )
        );
    journalOut->copyAllOutputOptions(*out);

    *out
      << "\n***"
      << "\n*** NLPThyraEpetraAdvDiffReactOptMain, Global numProcs = "<<numProcs
      << "\n***\n";

#ifdef HAVE_MPI
    MPI_Comm mpiComm = MPI_COMM_WORLD;
#endif

    Teuchos::RCP<Epetra_Comm> comm = Teuchos::null;
#ifdef HAVE_MPI
    comm = Teuchos::rcp(new Epetra_MpiComm(mpiComm));
#else
    comm = Teuchos::rcp(new Epetra_SerialComm());
#endif
    
    //
    // Create the Thyra::ModelEvaluator object
    //
    
    *out << "\nCreate the GLpApp::AdvDiffReactOptModel wrapper object ...\n";
    
    Teuchos::RCP<GLpApp::AdvDiffReactOptModel>
      epetraModel = advDiffReacModelCreator.createModel(comm);
    epetraModel->setOStream(journalOut);

    *out << "\nCreate the Thyra::LinearOpWithSolveFactory object ...\n";

    Teuchos::RCP<Thyra::LinearOpWithSolveFactoryBase<Scalar> >
      lowsFactory = lowsfCreator.createLinearSolveStrategy("");
    // ToDo: Set the output stream before calling above!
    ///lowsFactory = lowsfCreator.createLOWSF(OSTab(journalOut).get());
    
    *out << "\nCreate the Thyra::EpetraModelEvaluator wrapper object ...\n";
    
    Teuchos::RCP<Thyra::EpetraModelEvaluator>
      epetraThyraModel = rcp(new Thyra::EpetraModelEvaluator()); // Sets default options!
    epetraThyraModel->setOStream(journalOut);
    epetraThyraModel->initialize(epetraModel,lowsFactory);

    *out
      << "\nnx = " << epetraThyraModel->get_x_space()->dim()
      << "\nnp = " << epetraThyraModel->get_p_space(0)->dim() << "\n";

    if(matchingVecFile != "") {
      *out << "\nReading the matching vector \'q\' from the file(s) with base name \""<<matchingVecFile<<"\" ...\n";
      Thyra::DefaultSpmdMultiVectorFileIO<Scalar> fileIO;
      epetraModel->set_q(
        Thyra::get_Epetra_Vector(
          *epetraModel->get_x_map()
          ,readVectorFromFile(fileIO,matchingVecFile,*epetraThyraModel->get_x_space())
          )
        );
    }

    //
    // Solve the NLP
    //

    // Set the journal file
    solver.getSolver().set_journal_out(journalOut);
    
    // Set the model
    solver.setModel(epetraThyraModel);

    // Read the initial guess if one exists
    solver.readInitialGuess(out.get());

    // Solve the NLP
    const MoochoSolver::ESolutionStatus	solution_status = solver.solve();

    // Write the solution to file
    solver.writeFinalSolution(out.get());
    
    // Write the final parameters to file
    lowsfCreator.writeParamsFile(*lowsFactory);
    solver.writeParamsFile();
    
    //
    // Return the solution status (0 if successful)
    //

    if(solution_status == MoochoSolver::SOLVE_RETURN_SOLVED)
      *out << "\nEnd Result: TEST PASSED\n";
    else
      *out << "\nEnd Result: TEST FAILED\n";
    
    return solution_status;

  }
  TEUCHOS_STANDARD_CATCH_STATEMENTS(true, *out, dummySuccess)

  return MoochoSolver::SOLVE_RETURN_EXCEPTION;

}