int Piro::Thyra::PerformMoochoAnalysis( ::Thyra::ModelEvaluatorDefaultBase<double>& piroModel, Teuchos::ParameterList& moochoParams, RCP< ::Thyra::VectorBase<double> >& p) { #ifdef Piro_ENABLE_MOOCHO MoochoPack::MoochoThyraSolver solver; // Set the model and parameter list solver.setModel(rcp(&piroModel,false)); solver.setParameterList(rcp(&moochoParams,false)); // Solve the NLP const MoochoPack::MoochoSolver::ESolutionStatus solution_status = solver.solve(); // Extract the final solution p = ::Thyra::createMember(piroModel.get_p_space(0)); RCP<const ::Thyra::VectorBase<double> > p_final = solver.getFinalPoint().get_p(0); ::Thyra::copy(*p_final, p.ptr()); return (int) solution_status; #else RCP<Teuchos::FancyOStream> out = Teuchos::VerboseObjectBase::getDefaultOStream(); *out << "ERROR: Trilinos/Piro was not configured to include MOOCHO analysis." << endl; return 0; // should not fail tests #endif }
int Piro::PerformDakotaAnalysis( Thyra::ModelEvaluatorDefaultBase<double>& piroModel, Teuchos::ParameterList& dakotaParams, RCP< Thyra::VectorBase<double> >& p) { #ifdef HAVE_PIRO_TRIKOTA dakotaParams.validateParameters(*Piro::getValidPiroAnalysisDakotaParameters(),0); using std::string; string dakotaIn = dakotaParams.get("Input File","dakota.in"); string dakotaOut = dakotaParams.get("Output File","dakota.out"); string dakotaErr = dakotaParams.get("Error File","dakota.err"); string dakotaRes = dakotaParams.get("Restart File","dakota_restart.out"); string dakotaRestartIn; if (dakotaParams.isParameter("Restart File To Read")) dakotaRestartIn = dakotaParams.get<string>("Restart File To Read"); int dakotaRestartEvals= dakotaParams.get("Restart Evals To Read", 0); int p_index = dakotaParams.get("Parameter Vector Index", 0); int g_index = dakotaParams.get("Response Vector Index", 0); TriKota::Driver dakota(dakotaIn, dakotaOut, dakotaErr, dakotaRes, dakotaRestartIn, dakotaRestartEvals); RCP<TriKota::ThyraDirectApplicInterface> trikota_interface = rcp(new TriKota::ThyraDirectApplicInterface (dakota.getProblemDescDB(), rcp(&piroModel,false), p_index, g_index), false); dakota.run(trikota_interface.get()); Dakota::RealVector finalValues; if (dakota.rankZero()) finalValues = dakota.getFinalSolution().all_continuous_variables(); // Copy Dakota parameters into Thyra p = Thyra::createMember(piroModel.get_p_space(p_index)); { Thyra::DetachedVectorView<double> global_p(p); for (int i = 0; i < finalValues.length(); ++i) global_p[i] = finalValues[i]; } return 0; #else RCP<Teuchos::FancyOStream> out = Teuchos::VerboseObjectBase::getDefaultOStream(); *out << "ERROR: Trilinos/Piro was not configured to include Dakota analysis." << "\nYou must enable TriKota." << endl; return 0; // should not fail tests #endif }
int Piro::Thyra::PerformOptiPackAnalysis( ::Thyra::ModelEvaluatorDefaultBase<double>& piroModel, Teuchos::ParameterList& optipackParams, Teuchos::ParameterList& globipackParams, RCP< ::Thyra::VectorBase<double> >& p) { RCP<Teuchos::FancyOStream> out = Teuchos::VerboseObjectBase::getDefaultOStream(); #ifdef Piro_ENABLE_OptiPack // First, Linesearch stuff const RCP<GlobiPack::BrentsLineSearch<double> > linesearch = GlobiPack::brentsLineSearch<double>(); const RCP<ParameterList> lsPL = rcp(&globipackParams, false); linesearch->setParameterList(lsPL); // Temporary Debug *out << "\nCurrent LineSearch parameters" << endl; lsPL->print(*out); // Second, Optimization stuff p = ::Thyra::createMember(piroModel.get_p_space(0)); RCP<const ::Thyra::VectorBase<double> > p_init = piroModel.getNominalValues().get_p(0); ::Thyra::copy(*p_init, p.ptr()); const RCP<OptiPack::NonlinearCG<double> > cgSolver = OptiPack::nonlinearCG<double>(rcp(&piroModel,false), 0, 0, linesearch); const RCP<ParameterList> pl = rcp(&optipackParams,false); cgSolver->setParameterList(pl); // Temporary Debug Info *out << "\nCurrent nonlinearCG parameter list" << endl; pl->print(*out); // Solve the prob double g_opt; // optimal value of the response int numIters; // number of iteration taken const OptiPack::NonlinearCGUtils::ESolveReturn solveResult = cgSolver->doSolve( p.ptr(), outArg(g_opt), null, null, null, outArg(numIters) ); return (int) solveResult; #else *out << "ERROR: Trilinos/Piro was not configured to include OptiPack analysis." << endl; return 0; // should not fail tests #endif }
int Piro::Thyra::PerformDakotaAnalysis( ::Thyra::ModelEvaluatorDefaultBase<double>& piroModel, Teuchos::ParameterList& dakotaParams, RCP< ::Thyra::VectorBase<double> >& p) { #ifdef Piro_ENABLE_TriKota string dakotaIn = dakotaParams.get("Input File","dakota.in"); string dakotaOut= dakotaParams.get("Output File","dakota.out"); string dakotaErr= dakotaParams.get("Error File","dakota.err"); string dakotaRes= dakotaParams.get("Restart File","dakota_restart.out"); TriKota::Driver dakota(dakotaIn.c_str(), dakotaOut.c_str(), dakotaErr.c_str(), dakotaRes.c_str()); RCP<TriKota::ThyraDirectApplicInterface> trikota_interface = rcp(new TriKota::ThyraDirectApplicInterface (dakota.getProblemDescDB(), rcp(&piroModel,false)), false); dakota.run(trikota_interface.get()); Dakota::RealVector finalValues = dakota.getFinalSolution().all_continuous_variables(); // Copy Dakota parameters into Thyra p = ::Thyra::createMember(piroModel.get_p_space(0)); { ::Thyra::DetachedVectorView<double> global_p(p); for (int i = 0; i < finalValues.length(); ++i) global_p[i] = finalValues[i]; } return 0; #else RCP<Teuchos::FancyOStream> out = Teuchos::VerboseObjectBase::getDefaultOStream(); *out << "ERROR: Trilinos/Piro was not configured to include Dakota analysis." << "\nYou must enable TriKota." << endl; return 0; // should not fail tests #endif }
int Piro::PerformROLAnalysis( Thyra::ModelEvaluatorDefaultBase<double>& piroModel, Teuchos::ParameterList& rolParams, RCP< Thyra::VectorBase<double> >& p) { #ifdef HAVE_PIRO_ROL using std::string; RCP<Teuchos::FancyOStream> out = Teuchos::VerboseObjectBase::getDefaultOStream(); int g_index = rolParams.get<int>("Response Vector Index", 0); int p_index = rolParams.get<int>("Parameter Vector Index", 0); p = Thyra::createMember(piroModel.get_p_space(p_index)); RCP<const Thyra::VectorBase<double> > p_init = piroModel.getNominalValues().get_p(p_index); Thyra::copy(*p_init, p.ptr()); ROL::ThyraVector<double> rol_p(p); ROL::ThyraME_Objective<double> obj(piroModel, g_index, p_index); bool print = rolParams.get<bool>("Print Output", false); int seed = rolParams.get<int>("Seed For Thyra Randomize", 42); //! set initial guess (or use the one provided by the Model Evaluator) std::string init_guess_type = rolParams.get<string>("Parameter Initial Guess Type", "From Model Evaluator"); if(init_guess_type == "Uniform Vector") rol_p.putScalar(rolParams.get<double>("Uniform Parameter Guess", 1.0)); else if(init_guess_type == "Random Vector") { Teuchos::Array<double> minmax(2); minmax[0] = -1; minmax[1] = 1; minmax = rolParams.get<Teuchos::Array<double> >("Min And Max Of Random Parameter Guess", minmax); ::Thyra::randomize<double>( minmax[0], minmax[1], rol_p.getVector().ptr()); } else if(init_guess_type != "From Model Evaluator") { TEUCHOS_TEST_FOR_EXCEPTION(true, Teuchos::Exceptions::InvalidParameter, std::endl << "Error in Piro::PerformROLAnalysis: " << "Parameter Initial Guess Type \"" << init_guess_type << "\" is not Known.\nValid options are: \"Parameter Scalar Guess\", \"Uniform Vector\" and \"Random Vector\""<<std::endl); } //! test thyra implementation of ROL vector if(rolParams.get<bool>("Test Vector", false)) { Teuchos::RCP<Thyra::VectorBase<double> > rand_vec_x = p->clone_v(); Teuchos::RCP<Thyra::VectorBase<double> > rand_vec_y = p->clone_v(); Teuchos::RCP<Thyra::VectorBase<double> > rand_vec_z = p->clone_v(); ::Thyra::seed_randomize<double>( seed ); int num_tests = rolParams.get<int>("Number Of Vector Tests", 1); for(int i=0; i< num_tests; i++) { *out << "\nROL performing vector test " << i+1 << " of " << num_tests << std::endl; ::Thyra::randomize<double>( -1.0, 1.0, rand_vec_x.ptr()); ::Thyra::randomize<double>( -1.0, 1.0, rand_vec_y.ptr()); ::Thyra::randomize<double>( -1.0, 1.0, rand_vec_z.ptr()); ROL::ThyraVector<double> rol_x(rand_vec_x); ROL::ThyraVector<double> rol_y(rand_vec_y); ROL::ThyraVector<double> rol_z(rand_vec_z); rol_x.checkVector(rol_y, rol_z,print, *out); } } //! check correctness of Gradient prvided by Model Evaluator if(rolParams.get<bool>("Check Gradient", false)) { Teuchos::RCP<Thyra::VectorBase<double> > rand_vec = p->clone_v(); ::Thyra::seed_randomize<double>( seed ); int num_checks = rolParams.get<int>("Number Of Gradient Checks", 1); double norm_p = rol_p.norm(); for(int i=0; i< num_checks; i++) { *out << "\nROL performing gradient check " << i+1 << " of " << num_checks << ", at parameter initial guess" << std::endl; ::Thyra::randomize<double>( -1.0, 1.0, rand_vec.ptr()); ROL::ThyraVector<double> rol_direction(rand_vec); double norm_d = rol_direction.norm(); if(norm_d*norm_p > 0.0) rol_direction.scale(norm_p/norm_d); obj.checkGradient(rol_p, rol_direction, print, *out); } } // Define Step Teuchos::RCP<ROL::LineSearchStep<double> > step = Teuchos::rcp(new ROL::LineSearchStep<double>(rolParams.sublist("ROL Options"))); *out << "\nROL options:" << std::endl; rolParams.sublist("ROL Options").print(*out); *out << std::endl; // Define Status Test double gtol = rolParams.get("Gradient Tolerance", 1e-5); // norm of gradient tolerance double stol = rolParams.get("Step Tolerance", 1e-5); // norm of step tolerance int maxit = rolParams.get("Max Iterations", 100); // maximum number of iterations Teuchos::RCP<ROL::StatusTest<double> > status = Teuchos::rcp(new ROL::StatusTest<double>(gtol, stol, maxit)); // Define Algorithm ROL::Algorithm<double> algo(step,status,print); // Run Algorithm std::vector<std::string> output; if(rolParams.get<bool>("Bound Constrained", false)) { double eps_bound = rolParams.get<double>("epsilon bound", 1e-6); Teuchos::RCP<const Thyra::VectorBase<double> > p_lo = piroModel.getLowerBounds().get_p(p_index); Teuchos::RCP<const Thyra::VectorBase<double> > p_up = piroModel.getUpperBounds().get_p(p_index); TEUCHOS_TEST_FOR_EXCEPTION((p_lo == Teuchos::null) || (p_up == Teuchos::null), Teuchos::Exceptions::InvalidParameter, std::endl << "Error in Piro::PerformROLAnalysis: " << "Lower and/or Upper bounds pointers are null, cannot perform bound constrained optimization"<<std::endl); ROL::Thyra_BoundConstraint<double> boundConstraint(p_lo->clone_v(), p_up->clone_v(), eps_bound); output = algo.run(rol_p, obj, boundConstraint, print, *out); } else output = algo.run(rol_p, obj, print, *out); for ( unsigned i = 0; i < output.size(); i++ ) { *out << output[i]; } return 0; #else RCP<Teuchos::FancyOStream> out = Teuchos::VerboseObjectBase::getDefaultOStream(); *out << "ERROR: Trilinos/Piro was not configured to include ROL analysis." << "\nYou must enable ROL." << endl; return 0; // should not fail tests #endif }