コード例 #1
0
int main(int argc, char *argv[]) {
#include "MueLu_UseShortNames.hpp"

  Teuchos::oblackholestream blackhole;
  Teuchos::GlobalMPISession mpiSession(&argc,&argv,&blackhole);
  RCP<const Teuchos::Comm<int> > comm = Teuchos::DefaultComm<int>::getComm();

  /**********************************************************************************/
  /* SET TEST PARAMETERS                                                            */
  /**********************************************************************************/
  // Note: use --help to list available options.
  Teuchos::CommandLineProcessor clp(false);

  // Default is Laplace1D with nx = 8748.
  // It's a nice size for 1D and perfect aggregation. (6561=3^8)
  //Nice size for 1D and perfect aggregation on small numbers of processors. (8748=4*3^7)
  Galeri::Xpetra::Parameters<GO> matrixParameters(clp, 8748); // manage parameters of the test case
  Xpetra::Parameters xpetraParameters(clp);             // manage parameters of xpetra

  // custom parameters
  LO maxLevels = 1;
  LO its=2;
  std::string coarseSolver="amesos2";
  clp.setOption("maxLevels",&maxLevels,"maximum number of levels allowed");
  clp.setOption("its",&its,"number of multigrid cycles");
  clp.setOption("coarseSolver",&coarseSolver,"amesos2 or ifpack2 (Tpetra specific. Ignored for Epetra)");

  switch (clp.parse(argc,argv)) {
  case Teuchos::CommandLineProcessor::PARSE_HELP_PRINTED:        return EXIT_SUCCESS; break;
  case Teuchos::CommandLineProcessor::PARSE_ERROR:
  case Teuchos::CommandLineProcessor::PARSE_UNRECOGNIZED_OPTION: return EXIT_FAILURE; break;
  case Teuchos::CommandLineProcessor::PARSE_SUCCESSFUL:                               break;
  }

  matrixParameters.check();
  xpetraParameters.check();
  // TODO: check custom parameters

  if (comm->getRank() == 0) {
    matrixParameters.print();
    xpetraParameters.print();
    // TODO: print custom parameters
  }


#ifdef FOR_PARALLEL_DEBUGGING
  //Utils::BreakForDebugger(*comm);

  LO mypid = comm->getRank();

  if (mypid  == 0) std::cout << "Host and Process Ids for tasks" << std::endl;
  for (LO i = 0; i <comm->getSize(); i++) {
    if (i == mypid ) {
      char buf[80];
      char hostname[80];
      gethostname(hostname, sizeof(hostname));
      LO pid = getpid();
      sprintf(buf, "Host: %s\tMPI rank: %d,\tPID: %d\n\tattach %d\n\tcontinue\n",
              hostname, mypid, pid, pid);
      printf("%s\n",buf);
      fflush(stdout);
      sleep(1);
    }
  }

  if (mypid == 0) {
    printf( "** Enter a character to continue > "); fflush(stdout);
    char go = ' ';
    scanf("%c",&go);
  }
  comm->barrier();
#endif

  /**********************************************************************************/
  /* CREATE INITIAL MATRIX                                                          */
  /**********************************************************************************/
  const RCP<const Map> map = MapFactory::Build(xpetraParameters.GetLib(), matrixParameters.GetNumGlobalElements(), 0, comm);
  RCP<Galeri::Xpetra::Problem<Map,CrsMatrixWrap,MultiVector> > Pr =
      Galeri::Xpetra::BuildProblem<SC, LO, GO, Map, CrsMatrixWrap, MultiVector>(matrixParameters.GetMatrixType(), map, matrixParameters.GetParameterList()); //TODO: Matrix vs. CrsMatrixWrap
  RCP<Matrix> Op = Pr->BuildMatrix();
  /**********************************************************************************/
  /*                                                                                */
  /**********************************************************************************/

  // dump matrix to file
  //std::string fileName = "Amat.mm";
  //Utils::Write(fileName,Op);

  RCP<MultiVector> nullSpace = MultiVectorFactory::Build(map,1);
  nullSpace->putScalar( (SC) 1.0);
  Teuchos::Array<Teuchos::ScalarTraits<SC>::magnitudeType> norms(1);
  nullSpace->norm1(norms);
  if (comm->getRank() == 0)
    std::cout << "||NS|| = " << norms[0] << std::endl;

  RCP<MueLu::Hierarchy<SC,LO,GO,NO,LMO> > H = rcp( new Hierarchy() );
  H->setDefaultVerbLevel(Teuchos::VERB_HIGH);
  RCP<MueLu::Level> Finest = rcp( new MueLu::Level() );
  Finest->setDefaultVerbLevel(Teuchos::VERB_HIGH);

  Finest->Set("A",Op);
  Finest->Set("Nullspace",nullSpace);
  Finest->Request("Nullspace"); //FIXME putting this in to avoid error until Merge needs business
                                //FIXME is implemented

  Finest->Set("NullSpace",nullSpace);
  H->SetLevel(Finest);

  RCP<CoupledAggregationFactory> CoupledAggFact = rcp(new CoupledAggregationFactory());
  CoupledAggFact->SetMinNodesPerAggregate(3);
  CoupledAggFact->SetMaxNeighAlreadySelected(0);
  CoupledAggFact->SetOrdering("natural");
  CoupledAggFact->SetPhase3AggCreation(0.5);

  RCP<TentativePFactory> TentPFact = rcp(new TentativePFactory(CoupledAggFact));

  RCP<SaPFactory>       Pfact = rcp( new SaPFactory(TentPFact) );
  //Pfact->SetDampingFactor(0.);
  RCP<Factory>         Rfact = rcp( new TransPFactory() );
  RCP<GenericPRFactory> PRfact = rcp( new GenericPRFactory(Pfact,Rfact));
  RCP<RAPFactory>       Acfact = rcp( new RAPFactory() );

  RCP<SmootherPrototype> smooProto;
  Teuchos::ParameterList ifpackList;
  ifpackList.set("relaxation: sweeps", (LO) 1);
  ifpackList.set("relaxation: damping factor", (SC) 1.0);
  /*
  ifpackList.set("type", "Chebyshev");
  ifpackList.set("chebyshev: degree", (int) 1);
  ifpackList.set("chebyshev: max eigenvalue", (double) 2.0);
  ifpackList.set("chebyshev: min eigenvalue", (double) 1.0);
  ifpackList.set("chebyshev: zero starting solution", false);
  */
  if (xpetraParameters.GetLib() == Xpetra::UseEpetra) {
#if defined(HAVE_MUELU_EPETRA) && defined(HAVE_MUELU_IFPACK)
    ifpackList.set("relaxation: type", "symmetric Gauss-Seidel");
    smooProto = rcp( new IfpackSmoother("point relaxation stand-alone",ifpackList) );
#endif
  } else if (xpetraParameters.GetLib() == Xpetra::UseTpetra) {
#if defined(HAVE_MUELU_TPETRA) && defined(HAVE_MUELU_IFPACK2)
    ifpackList.set("relaxation: type", "Symmetric Gauss-Seidel");
    smooProto = rcp( new Ifpack2Smoother("RELAXATION",ifpackList) );
#endif
  }
  if (smooProto == Teuchos::null) {
    throw(MueLu::Exceptions::RuntimeError("main: smoother error"));
  }

  RCP<SmootherFactory> SmooFact = rcp( new SmootherFactory(smooProto) );
  Acfact->setVerbLevel(Teuchos::VERB_HIGH);

  Teuchos::ParameterList status;
  status = H->FullPopulate(PRfact,Acfact,SmooFact,0,maxLevels);
  //RCP<MueLu::Level> coarseLevel = H.GetLevel(1);
  //RCP<Matrix> P = coarseLevel->template Get< RCP<Matrix> >("P");
  //fileName = "Pfinal.mm";
  //Utils::Write(fileName,P);
  if (comm->getRank() == 0) {
    std::cout  << "======================\n Multigrid statistics \n======================" << std::endl;
    status.print(std::cout,Teuchos::ParameterList::PrintOptions().indent(2));
  }

  //FIXME we should be able to just call smoother->SetNIts(50) ... but right now an exception gets thrown

  RCP<SmootherPrototype> coarseProto;
  if (xpetraParameters.GetLib() == Xpetra::UseEpetra) {
#if defined(HAVE_MUELU_EPETRA) && defined(HAVE_MUELU_AMESOS)
    if (comm->getRank() == 0) std::cout << "CoarseGrid: AMESOS" << std::endl;
    Teuchos::ParameterList amesosList;
    amesosList.set("PrintTiming",true);
    coarseProto = rcp( new AmesosSmoother("Amesos_Klu",amesosList) );
    //#elif
#endif
  } else if (xpetraParameters.GetLib() == Xpetra::UseTpetra) {
    if (coarseSolver=="amesos2") {
#if defined(HAVE_MUELU_TPETRA) && defined(HAVE_MUELU_AMESOS2)
      if (comm->getRank() == 0) std::cout << "CoarseGrid: AMESOS2" << std::endl;
      Teuchos::ParameterList paramList; //unused
      coarseProto = rcp( new Amesos2Smoother("Superlu", paramList) );
#else
      std::cout  << "AMESOS2 not available (try --coarseSolver=ifpack2)" << std::endl;
      return EXIT_FAILURE;
#endif // HAVE_MUELU_TPETRA && HAVE_MUELU_AMESOS2
    } else if(coarseSolver=="ifpack2") {
#if defined(HAVE_MUELU_TPETRA) && defined(HAVE_MUELU_IFPACK2)
        if (comm->getRank() == 0) std::cout << "CoarseGrid: IFPACK2" << std::endl;
        Teuchos::ParameterList ifpack2List;
        ifpack2List.set("fact: ilut level-of-fill",99); // TODO ??
        ifpack2List.set("fact: drop tolerance", 0);
        ifpack2List.set("fact: absolute threshold", 0);
        ifpack2List.set("fact: relative threshold", 0);
        coarseProto = rcp( new Ifpack2Smoother("ILUT",ifpack2List) );
#else
        std::cout  << "IFPACK2 not available (try --coarseSolver=amesos2)" << std::endl;
        return EXIT_FAILURE;
#endif
    } else {
      std::cout  << "Unknow coarse grid solver (try  --coarseSolver=ifpack2 or --coarseSolver=amesos2)" << std::endl;
      return EXIT_FAILURE;
    }

  }
  if (coarseProto == Teuchos::null) {
    throw(MueLu::Exceptions::RuntimeError("main: coarse smoother error"));
  }

  SmootherFactory coarseSolveFact(coarseProto);
  H->SetCoarsestSolver(coarseSolveFact,MueLu::PRE);

  // Define RHS
  RCP<MultiVector> X = MultiVectorFactory::Build(map,1);
  RCP<MultiVector> RHS = MultiVectorFactory::Build(map,1);

  X->setSeed(846930886);
  X->randomize();
  X->norm2(norms);
  if (comm->getRank() == 0)
    std::cout << "||X_true|| = " << std::setiosflags(std::ios::fixed) << std::setprecision(10) << norms[0] << std::endl;

  Op->apply(*X,*RHS,Teuchos::NO_TRANS,(SC)1.0,(SC)0.0);

  // Use AMG directly as an iterative method
  {
    X->putScalar( (SC) 0.0);

    H->PrintResidualHistory(true);
    H->Iterate(*RHS,*X,its);

    X->norm2(norms);
    if (comm->getRank() == 0)
      std::cout << "||X_" << std::setprecision(2) << its << "|| = " << std::setiosflags(std::ios::fixed) << std::setprecision(10) << norms[0] << std::endl;
  }

  return EXIT_SUCCESS;

}
コード例 #2
0
int main(int argc, char *argv[]) {
#include "MueLu_UseShortNames.hpp"

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

  bool success = false;
  bool verbose = true;
  try {
    Teuchos::RCP<const Teuchos::Comm<int> > comm = Teuchos::DefaultComm<int>::getComm();

    /**********************************************************************************/
    /* SET TEST PARAMETERS                                                            */
    /**********************************************************************************/
    /**********************************************************************************/
    /* SET TEST PARAMETERS                                                            */
    /**********************************************************************************/
    // Note: use --help to list available options.
    Teuchos::CommandLineProcessor clp(false);

    // Default is Laplace1D with nx = 8748.
    // It's a nice size for 1D and perfect aggregation. (6561=3^8)
    //Nice size for 1D and perfect aggregation on small numbers of processors. (8748=4*3^7)
    Galeri::Xpetra::Parameters<GO> matrixParameters(clp, 8748); // manage parameters of the test case
    Xpetra::Parameters xpetraParameters(clp);             // manage parameters of xpetra

    // custom parameters
    int pauseForDebugger=0;
    //std::string aggOrdering = "natural";
    int minPerAgg=2; //was 3 in simple
    int maxNbrAlreadySelected=0;
    int printTimings=0;

    //clp.setOption("aggOrdering",&aggOrdering,"aggregation ordering strategy (natural,graph)");
    clp.setOption("debug",&pauseForDebugger,"pause to attach debugger");
    clp.setOption("maxNbrSel",&maxNbrAlreadySelected,"maximum # of nbrs allowed to be in other aggregates");
    clp.setOption("minPerAgg",&minPerAgg,"minimum #DOFs per aggregate");
    clp.setOption("timings",&printTimings,"print timings to screen");

    switch (clp.parse(argc,argv)) {
      case Teuchos::CommandLineProcessor::PARSE_HELP_PRINTED:        return EXIT_SUCCESS; break;
      case Teuchos::CommandLineProcessor::PARSE_ERROR:
      case Teuchos::CommandLineProcessor::PARSE_UNRECOGNIZED_OPTION: return EXIT_FAILURE; break;
      case Teuchos::CommandLineProcessor::PARSE_SUCCESSFUL:                               break;
    }

    Teuchos::RCP<Teuchos::TimeMonitor> globalTimeMonitor = Teuchos::rcp (new Teuchos::TimeMonitor(*Teuchos::TimeMonitor::getNewTimer("Timings: Global Time")));

    if (pauseForDebugger) {
      Utilities::PauseForDebugger();
    }

    matrixParameters.check();
    xpetraParameters.check();
    Xpetra::UnderlyingLib lib = xpetraParameters.GetLib();

    if (comm->getRank() == 0) {
      std::cout << xpetraParameters << matrixParameters;
    }

    /**********************************************************************************/
    /* CREATE INITIAL MATRIX                                                          */
    /**********************************************************************************/
    Teuchos::RCP<const Map> map;
    Teuchos::RCP<Matrix> A;

    {
      Teuchos::TimeMonitor tm(*Teuchos::TimeMonitor::getNewTimer("Timings: Matrix Build"));

      map = MapFactory::Build(lib, matrixParameters.GetNumGlobalElements(), 0, comm);
      Teuchos::RCP<Galeri::Xpetra::Problem<Map,CrsMatrixWrap,MultiVector> > Pr =
        Galeri::Xpetra::BuildProblem<SC,LO,GO,Map,CrsMatrixWrap,MultiVector>(matrixParameters.GetMatrixType(), map, matrixParameters.GetParameterList()); //TODO: Matrix vs. CrsMatrixWrap
      A = Pr->BuildMatrix();

    }
    /**********************************************************************************/
    /*                                                                                */
    /**********************************************************************************/


    Teuchos::RCP<Hierarchy> hierarchy = Teuchos::rcp(new Hierarchy(A));
    hierarchy->SetDefaultVerbLevel(MueLu::toMueLuVerbLevel(Teuchos::VERB_EXTREME));
    hierarchy->SetMaxCoarseSize(100);

    ///////////////////////////////////////////////////////////

    Teuchos::RCP<MueLu::Level> Finest = hierarchy->GetLevel();  // get finest level

    Finest->Set("A",A);

    Teuchos::RCP<AmalgamationFactory> amalgFact = Teuchos::rcp(new AmalgamationFactory());
    Teuchos::RCP<CoalesceDropFactory> dropFact = Teuchos::rcp(new CoalesceDropFactory());
    dropFact->SetFactory("UnAmalgamationInfo", amalgFact);

    // aggregation factory
    Teuchos::RCP<UncoupledAggregationFactory> UnCoupledAggFact = Teuchos::rcp(new UncoupledAggregationFactory(/*dropFact*/));
    UnCoupledAggFact->SetFactory("Graph", dropFact);
    UnCoupledAggFact->SetFactory("DofsPerNode", dropFact);
    //UnCoupledAggFact->SetFactory("Graph", dropFact); // UnCoupledAggFact not changed to new factory handling
    //UnCoupledAggFact->SetMinNodesPerAggregate(minPerAgg);
    //UnCoupledAggFact->SetMaxNeighAlreadySelected(maxNbrAlreadySelected);
    //UnCoupledAggFact->SetOrdering(MueLu::AggOptions::GRAPH);
    UnCoupledAggFact->SetParameter("aggregation: max selected neighbors", Teuchos::ParameterEntry(maxNbrAlreadySelected));
    UnCoupledAggFact->SetParameter("aggregation: min agg size",           Teuchos::ParameterEntry(minPerAgg));
    UnCoupledAggFact->SetParameter("aggregation: ordering",               Teuchos::ParameterEntry(std::string("graph")));

    Finest->Request("Graph",dropFact.get());
    Finest->Request("DofsPerNode",dropFact.get());
    Finest->Request("UnAmalgamationInfo",amalgFact.get());
    UnCoupledAggFact->Build(*Finest);

    // Timer final summaries
    globalTimeMonitor = Teuchos::null; // stop this timer before summary

    if (printTimings)
      Teuchos::TimeMonitor::summarize();

    success = true;
  }
  TEUCHOS_STANDARD_CATCH_STATEMENTS(verbose, std::cerr, success);

  return ( success ? EXIT_SUCCESS : EXIT_FAILURE );
}
コード例 #3
0
int main(int argc, char *argv[]) {
#include "MueLu_UseShortNames.hpp"

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

  bool success = true;
  bool verbose = true;
  try {
    Teuchos::RCP<const Teuchos::Comm<int> > comm = Teuchos::DefaultComm<int>::getComm();

    /**********************************************************************************/
    /* SET TEST PARAMETERS                                                            */
    /**********************************************************************************/
    // Note: use --help to list available options.
    Teuchos::CommandLineProcessor clp(false);

    // Default is Laplace1D with nx = 8748.
    // It's a nice size for 1D and perfect aggregation. (6561=3^8)
    //Nice size for 1D and perfect aggregation on small numbers of processors. (8748=4*3^7)
    Galeri::Xpetra::Parameters<GO> matrixParameters(clp, 8748); // manage parameters of the test case
    Xpetra::Parameters xpetraParameters(clp);             // manage parameters of xpetra

    // custom parameters
    int pauseForDebugger=0;
    //std::string aggOrdering = "natural";
    int minPerAgg=2; //was 3 in simple
    int maxNbrAlreadySelected=0;
    int printTimings=0;
    std::string xmlFile="parameters.xml";

    //clp.setOption("aggOrdering",&aggOrdering,"aggregation ordering strategy (natural,graph)");
    clp.setOption("debug",&pauseForDebugger,"pause to attach debugger");
    clp.setOption("maxNbrSel",&maxNbrAlreadySelected,"maximum # of nbrs allowed to be in other aggregates");
    clp.setOption("minPerAgg",&minPerAgg,"minimum #DOFs per aggregate");
    clp.setOption("timings",&printTimings,"print timings to screen");
    clp.setOption("xmlFile",&xmlFile,"file name containing MueLu multigrid parameters in XML format");

    switch (clp.parse(argc,argv)) {
      case Teuchos::CommandLineProcessor::PARSE_HELP_PRINTED:        return EXIT_SUCCESS; break;
      case Teuchos::CommandLineProcessor::PARSE_ERROR:
      case Teuchos::CommandLineProcessor::PARSE_UNRECOGNIZED_OPTION: return EXIT_FAILURE; break;
      case Teuchos::CommandLineProcessor::PARSE_SUCCESSFUL:                               break;
    }

    Teuchos::RCP<Teuchos::TimeMonitor> globalTimeMonitor = Teuchos::rcp (new Teuchos::TimeMonitor(*Teuchos::TimeMonitor::getNewTimer("Timings: Global Time")));

    if (pauseForDebugger) {
      Utilities::PauseForDebugger();
    }

    matrixParameters.check();
    xpetraParameters.check();
    Xpetra::UnderlyingLib lib = xpetraParameters.GetLib();

    if (comm->getRank() == 0) {
      std::cout << xpetraParameters << matrixParameters;
    }

    /**********************************************************************************/
    /* CREATE INITIAL MATRIX                                                          */
    /**********************************************************************************/
    Teuchos::RCP<const Map> map;
    Teuchos::RCP<Matrix> A;

    {
      Teuchos::TimeMonitor tm(*Teuchos::TimeMonitor::getNewTimer("Timings: Matrix Build"));

      map = MapFactory::Build(lib, matrixParameters.GetNumGlobalElements(), 0, comm);
      Teuchos::RCP<Galeri::Xpetra::Problem<Map,CrsMatrixWrap,MultiVector> > Pr =
        Galeri::Xpetra::BuildProblem<SC,LO,GO,Map,CrsMatrixWrap,MultiVector>(matrixParameters.GetMatrixType(), map, matrixParameters.GetParameterList()); //TODO: Matrix vs. CrsMatrixWrap
      A = Pr->BuildMatrix();

    }
    /**********************************************************************************/
    /*                                                                                */
    /**********************************************************************************/
    Teuchos::ParameterList paramList;
    Teuchos::updateParametersFromXmlFileAndBroadcast(xmlFile, Teuchos::Ptr<Teuchos::ParameterList>(&paramList), *comm);

    // create parameter list interpreter
    Teuchos::RCP<HierarchyManager> mueluFactory = Teuchos::rcp(new ParameterListInterpreter(paramList));

    Teuchos::RCP<Hierarchy> H = mueluFactory->CreateHierarchy();

    H->GetLevel(0)->Set< Teuchos::RCP<Matrix> >("A", A);

    Teuchos::RCP<MultiVector> nullspace = MultiVectorFactory::Build(A->getRowMap(), 1);
    nullspace->putScalar(1.0);
    H->GetLevel(0)->Set("Nullspace", nullspace);

    // set minimal information about number of layers for semicoarsening...
    // This information can also be provided as a user parameter in the xml file using the
    // parameter: "semicoarsen: num layers"
    H->GetLevel(0)->Set("NumZLayers",matrixParameters.GetParameterList().get<GO>("nz"));


    mueluFactory->SetupHierarchy(*H);

    for (int l=0; l<H->GetNumLevels(); l++) {
      Teuchos::RCP<MueLu::Level> level = H->GetLevel(l);
      if(level->IsAvailable("A", MueLu::NoFactory::get()) == false) { success = false; H->GetLevel(l)->print(std::cout, MueLu::Debug);}
      if(level->IsAvailable("P", MueLu::NoFactory::get()) == false && l>0) { success = false; H->GetLevel(l)->print(std::cout, MueLu::Debug);}
      if(level->IsAvailable("R", MueLu::NoFactory::get()) == false && l>0) { success = false; H->GetLevel(l)->print(std::cout, MueLu::Debug);}
      if(level->IsAvailable("PreSmoother",  MueLu::NoFactory::get()) == false) { success = false; H->GetLevel(l)->print(std::cout, MueLu::Debug);}
      if(level->IsAvailable("PostSmoother", MueLu::NoFactory::get()) == false && l<H->GetNumLevels()-1) { success = false; H->GetLevel(l)->print(std::cout, MueLu::Debug);}
      if(level->IsAvailable("NumZLayers",   MueLu::NoFactory::get()) == true && l>0) {  success = false; H->GetLevel(l)->print(std::cout, MueLu::Debug);}
      H->GetLevel(l)->print(std::cout, MueLu::Debug);
    }
    ///////////////////////////////////////////////////////////

    // =========================================================================
    // System solution (Ax = b)
    // =========================================================================
    comm->barrier();
    typedef Teuchos::ScalarTraits<SC> STS;
    SC zero = STS::zero(), one = STS::one();

    Teuchos::RCP<Vector> X = VectorFactory::Build(A->getRowMap());
    Teuchos::RCP<Vector> B = VectorFactory::Build(A->getRowMap());

    {
      // we set seed for reproducibility
      Utilities::SetRandomSeed(*comm);
      X->randomize();
      A->apply(*X, *B, Teuchos::NO_TRANS, one, zero);

      Teuchos::Array<STS::magnitudeType> norms(1);
      B->norm2(norms);
      B->scale(one/norms[0]);
      X->putScalar(zero);
    }

    comm->barrier();

    H->IsPreconditioner(false);
    H->Iterate(*B, *X, 20);

    // Timer final summaries
    globalTimeMonitor = Teuchos::null; // stop this timer before summary

    if (printTimings)
      Teuchos::TimeMonitor::summarize();
  }
  TEUCHOS_STANDARD_CATCH_STATEMENTS(verbose, std::cerr, success);

  return ( success ? EXIT_SUCCESS : EXIT_FAILURE );
}