// ***************************************************************** // ***************************************************************** bool LOCA::Epetra::ModelEvaluatorInterface:: computeShiftedMatrix(double alpha, double beta, const Epetra_Vector& x, Epetra_Operator& A) { // Create inargs EpetraExt::ModelEvaluator::InArgs inargs = model_->createInArgs(); inargs.set_x(Teuchos::rcp(&x, false)); if (inargs.supports(EpetraExt::ModelEvaluator::IN_ARG_alpha)) inargs.set_alpha(-beta); // alpha and beta are switched between LOCA and Thyra if (inargs.supports(EpetraExt::ModelEvaluator::IN_ARG_beta)) inargs.set_beta(alpha); alpha_prev = -beta; beta_prev = alpha; // prec must know alpha and beta inargs.set_p(0, Teuchos::rcp(¶m_vec, false)); if (inargs.supports(EpetraExt::ModelEvaluator::IN_ARG_x_dot)) { // Create x_dot, filled with zeros if (x_dot == NULL) x_dot = new Epetra_Vector(x.Map()); inargs.set_x_dot(Teuchos::rcp(x_dot, false)); } // Create outargs EpetraExt::ModelEvaluator::OutArgs outargs = model_->createOutArgs(); EpetraExt::ModelEvaluator::Evaluation<Epetra_Vector> eval_f; outargs.set_f(eval_f); outargs.set_W(Teuchos::rcp(&A, false)); model_->evalModel(inargs, outargs); return true; }
// ***************************************************************** // ***************************************************************** bool LOCA::Epetra::ModelEvaluatorInterface:: computeJacobian(const Epetra_Vector& x, Epetra_Operator& Jac) { // Create inargs EpetraExt::ModelEvaluator::InArgs inargs = model_->createInArgs(); inargs.set_x(Teuchos::rcp(&x, false)); if (inargs.supports(EpetraExt::ModelEvaluator::IN_ARG_alpha)) inargs.set_alpha(0.0); if (inargs.supports(EpetraExt::ModelEvaluator::IN_ARG_beta)) inargs.set_beta(1.0); alpha_prev = 0.0; beta_prev = 1.0; // prec must know alpha and beta inargs.set_p(0, Teuchos::rcp(¶m_vec, false)); if (inargs.supports(EpetraExt::ModelEvaluator::IN_ARG_x_dot)) { // Create x_dot, filled with zeros if (x_dot == NULL) x_dot = new Epetra_Vector(x.Map()); inargs.set_x_dot(Teuchos::rcp(x_dot, false)); } // Create outargs EpetraExt::ModelEvaluator::OutArgs outargs = model_->createOutArgs(); EpetraExt::ModelEvaluator::Evaluation<Epetra_Vector> eval_f; outargs.set_f(eval_f); outargs.set_W(Teuchos::rcp(&Jac, false)); model_->evalModel(inargs, outargs); return true; }
// ***************************************************************** // ***************************************************************** bool NOX::Epetra::ModelEvaluatorInterface:: computeJacobian(const Epetra_Vector& x, Epetra_Operator& Jaco) { EpetraExt::ModelEvaluator::OutArgs outargs = model_->createOutArgs(); inargs_.set_x( Teuchos::rcp(&x, false) ); outargs.set_W( Teuchos::rcp(&Jaco, false) ); model_->evalModel(inargs_, outargs); inargs_.set_x(Teuchos::null); return true; }
int main(int argc, char *argv[]) { int status=0; // 0 = pass, failures are incremented // Initialize MPI and timer int Proc=0; #ifdef HAVE_MPI MPI_Init(&argc,&argv); double total_time = -MPI_Wtime(); (void) MPI_Comm_rank(MPI_COMM_WORLD, &Proc); MPI_Comm appComm = MPI_COMM_WORLD; #else int appComm=0; #endif using Teuchos::RCP; using Teuchos::rcp; // Command-line argument for input file //char* defaultfile="input_1.xml"; try { RCP<EpetraExt::ModelEvaluator> Model = rcp(new MockModelEval_A(appComm)); // Set input arguments to evalModel call EpetraExt::ModelEvaluator::InArgs inArgs = Model->createInArgs(); RCP<Epetra_Vector> x = rcp(new Epetra_Vector(*(Model->get_x_init()))); inArgs.set_x(x); int num_p = inArgs.Np(); // Number of *vectors* of parameters RCP<Epetra_Vector> p1; if (num_p > 0) { p1 = rcp(new Epetra_Vector(*(Model->get_p_init(0)))); inArgs.set_p(0,p1); } int numParams = p1->MyLength(); // Number of parameters in p1 vector // Set output arguments to evalModel call EpetraExt::ModelEvaluator::OutArgs outArgs = Model->createOutArgs(); RCP<Epetra_Vector> f = rcp(new Epetra_Vector(x->Map())); outArgs.set_f(f); int num_g = outArgs.Ng(); // Number of *vectors* of responses RCP<Epetra_Vector> g1; if (num_g > 0) { g1 = rcp(new Epetra_Vector(*(Model->get_g_map(0)))); outArgs.set_g(0,g1); } RCP<Epetra_Operator> W_op = Model->create_W(); outArgs.set_W(W_op); RCP<Epetra_MultiVector> dfdp = rcp(new Epetra_MultiVector( *(Model->get_x_map()), numParams)); outArgs.set_DfDp(0, dfdp); RCP<Epetra_MultiVector> dgdp = rcp(new Epetra_MultiVector(g1->Map(), numParams)); outArgs.set_DgDp(0, 0, dgdp); RCP<Epetra_MultiVector> dgdx = rcp(new Epetra_MultiVector(x->Map(), g1->MyLength())); outArgs.set_DgDx(0, dgdx); // Now, evaluate the model! Model->evalModel(inArgs, outArgs); // Print out everything if (Proc == 0) cout << "Finished Model Evaluation: Printing everything {Exact in brackets}" << "\n-----------------------------------------------------------------" << std::setprecision(9) << endl; x->Print(cout << "\nSolution vector! {3,3,3,3}\n"); if (num_p>0) p1->Print(cout << "\nParameters! {1,1}\n"); f->Print(cout << "\nResidual! {8,5,0,-7}\n"); if (num_g>0) g1->Print(cout << "\nResponses! {2}\n"); RCP<Epetra_CrsMatrix> W = Teuchos::rcp_dynamic_cast<Epetra_CrsMatrix>(W_op, true); W->Print(cout << "\nJacobian! {6 on diags}\n"); dfdp->Print(cout << "\nDfDp sensitivity MultiVector! {-1,0,0,0}{0,-4,-6,-8}\n"); dgdp->Print(cout << "\nDgDp response sensitivity MultiVector!{2,2}\n"); dgdx->Print(cout << "\nDgDx^T response gradient MultiVector! {-2,-2,-2,-2}\n"); if (Proc == 0) cout << "\n-----------------------------------------------------------------\n"; } catch (std::exception& e) { cout << e.what() << endl; status = 10; } catch (string& s) { cout << s << endl; status = 20; } catch (char *s) { cout << s << endl; status = 30; } catch (...) { cout << "Caught unknown exception!" << endl; status = 40; } #ifdef HAVE_MPI total_time += MPI_Wtime(); MPI_Barrier(MPI_COMM_WORLD); if (Proc==0) cout << "\n\nTOTAL TIME " << total_time << endl; MPI_Finalize() ; #endif if (Proc==0) { if (status==0) cout << "TEST PASSED" << endl; else cout << "TEST Failed" << endl; } return status; }
void EpetraExt::MultiPointModelEvaluator::evalModel( const InArgs& inArgs, const OutArgs& outArgs ) const { EpetraExt::ModelEvaluator::InArgs underlyingInArgs = underlyingME->createInArgs(); EpetraExt::ModelEvaluator::OutArgs underlyingOutArgs = underlyingME->createOutArgs(); //temp code for multipoint param q vec /* Teuchos::RefCountPtr<Epetra_Vector> q = Teuchos::rcp(new Epetra_Vector(*(underlyingME->get_p_map(1)))); */ // Parse InArgs Teuchos::RefCountPtr<const Epetra_Vector> p_in = inArgs.get_p(0); if (p_in.get()) underlyingInArgs.set_p(0, p_in); Teuchos::RefCountPtr<const Epetra_Vector> x_in = inArgs.get_x(); block_x->Epetra_Vector::operator=(*x_in); //copy into block vector // Parse OutArgs Teuchos::RefCountPtr<Epetra_Vector> f_out = outArgs.get_f(); Teuchos::RefCountPtr<Epetra_Operator> W_out = outArgs.get_W(); Teuchos::RefCountPtr<EpetraExt::BlockCrsMatrix> W_block = Teuchos::rcp_dynamic_cast<EpetraExt::BlockCrsMatrix>(W_out); Teuchos::RefCountPtr<Epetra_Vector> g_out; if (underlyingNg) g_out = outArgs.get_g(0); if (g_out.get()) g_out->PutScalar(0.0); EpetraExt::ModelEvaluator::Derivative DfDp_out = outArgs.get_DfDp(0); EpetraExt::ModelEvaluator::Derivative DgDx_out; EpetraExt::ModelEvaluator::Derivative DgDp_out; if (underlyingNg) { DgDx_out = outArgs.get_DgDx(0); DgDp_out = outArgs.get_DgDp(0,0); if (!DgDx_out.isEmpty()) DgDx_out.getMultiVector()->PutScalar(0.0); if (!DgDp_out.isEmpty()) DgDp_out.getMultiVector()->PutScalar(0.0); } // For mathcingProblems, g is needed to calc DgDx DgDp, so ask for // g even if it isn't requested. bool need_g = g_out.get(); if (matchingProblem) if ( !DgDx_out.isEmpty() || !DgDp_out.isEmpty() ) need_g = true; // Begin loop over Points (steps) owned on this proc for (int i=0; i < timeStepsOnTimeDomain; i++) { // Set MultiPoint parameter vector underlyingInArgs.set_p(1, (*q_vec)[i]); // Set InArgs if(longlong) { #ifndef EPETRA_NO_64BIT_GLOBAL_INDICES block_x->ExtractBlockValues(*split_x, (*rowIndex_LL)[i]); #endif } else { #ifndef EPETRA_NO_32BIT_GLOBAL_INDICES block_x->ExtractBlockValues(*split_x, (*rowIndex_int)[i]); #endif } underlyingInArgs.set_x(split_x); // Set OutArgs if (f_out.get()) underlyingOutArgs.set_f(split_f); if (need_g) underlyingOutArgs.set_g(0, split_g); if (W_out.get()) underlyingOutArgs.set_W(split_W); if (!DfDp_out.isEmpty()) underlyingOutArgs.set_DfDp(0, *deriv_DfDp); if (!DgDx_out.isEmpty()) underlyingOutArgs.set_DgDx(0, *deriv_DgDx); if (!DgDp_out.isEmpty()) underlyingOutArgs.set_DgDp(0, 0, *deriv_DgDp); //********Eval Model ********/ underlyingME->evalModel(underlyingInArgs, underlyingOutArgs); //********Eval Model ********/ // If matchingProblem, modify all g-related quantitites G = 0.5*(g-g*)^2 / g*^2 if (matchingProblem) { if (need_g) { double diff = (*split_g)[0] - (*(*matching_vec)[i])[0]; double nrmlz = fabs((*(*matching_vec)[i])[0]) + 1.0e-6; (*split_g)[0] = 0.5 * diff * diff/(nrmlz*nrmlz); if (!DgDx_out.isEmpty()) split_DgDx->Scale(diff/(nrmlz*nrmlz)); if (!DgDp_out.isEmpty()) split_DgDp->Scale(diff/(nrmlz*nrmlz)); } } // Repackage block components into global block matrx/vector/multivector if(longlong) { #ifndef EPETRA_NO_64BIT_GLOBAL_INDICES if (f_out.get()) block_f->LoadBlockValues(*split_f, (*rowIndex_LL)[i]); if (W_out.get()) W_block->LoadBlock(*split_W, i, 0); // note: split_DfDp points inside deriv_DfDp if (!DfDp_out.isEmpty()) block_DfDp->LoadBlockValues(*split_DfDp, (*rowIndex_LL)[i]); if (!DgDx_out.isEmpty()) block_DgDx->LoadBlockValues(*split_DgDx, (*rowIndex_LL)[i]); #endif } else { #ifndef EPETRA_NO_32BIT_GLOBAL_INDICES if (f_out.get()) block_f->LoadBlockValues(*split_f, (*rowIndex_int)[i]); if (W_out.get()) W_block->LoadBlock(*split_W, i, 0); // note: split_DfDp points inside deriv_DfDp if (!DfDp_out.isEmpty()) block_DfDp->LoadBlockValues(*split_DfDp, (*rowIndex_int)[i]); if (!DgDx_out.isEmpty()) block_DgDx->LoadBlockValues(*split_DgDx, (*rowIndex_int)[i]); #endif } // Assemble multiple steps on this domain into g and dgdp(0) vectors if (g_out.get()) g_out->Update(1.0, *split_g, 1.0); if (!DgDp_out.isEmpty()) DgDp_out.getMultiVector()->Update(1.0, *split_DgDp, 1.0); } // End loop over multiPoint steps on this domain/cluster //Copy block vectors into *_out vectors of same size if (f_out.get()) f_out->operator=(*block_f); if (!DfDp_out.isEmpty()) DfDp_out.getMultiVector()->operator=(*block_DfDp); if (!DgDx_out.isEmpty()) DgDx_out.getMultiVector()->operator=(*block_DgDx); //Sum together obj fn contributions from differnt Domains (clusters). if (numTimeDomains > 1) { double factorToZeroOutCopies = 0.0; if (globalComm->SubDomainComm().MyPID()==0) factorToZeroOutCopies = 1.0; if (g_out.get()) { (*g_out).Scale(factorToZeroOutCopies); double* vPtr = &((*g_out)[0]); Epetra_Vector tmp = *(g_out.get()); globalComm->SumAll( &(tmp[0]), vPtr, num_g0); } if (!DgDp_out.isEmpty()) { DgDp_out.getMultiVector()->Scale(factorToZeroOutCopies); double* mvPtr = (*DgDp_out.getMultiVector())[0]; Epetra_MultiVector tmp = *(DgDp_out.getMultiVector()); globalComm->SumAll(tmp[0], mvPtr, num_dg0dp0); } } }