Thyra::ModelEvaluatorBase::OutArgs<Scalar> Piro::VelocityVerletSolver<Scalar>::createOutArgsImpl() const { Thyra::ModelEvaluatorBase::OutArgsSetup<Scalar> outArgs; outArgs.setModelEvalDescription(this->description()); // One additional response slot for the solution vector outArgs.set_Np_Ng(num_p, num_g + 1); const Thyra::ModelEvaluatorBase::OutArgs<Scalar> modelOutArgs = model->createOutArgs(); if (num_p > 0) { // Only one parameter supported const int l = 0; // Computing the DxDp sensitivity for a transient problem currently requires the evaluation of // the mutilivector-based, Jacobian-oriented DfDp derivatives of the underlying transient model. const Thyra::ModelEvaluatorBase::DerivativeSupport model_dfdp_support = modelOutArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_DfDp, l); if (!model_dfdp_support.supports(Thyra::ModelEvaluatorBase::DERIV_MV_JACOBIAN_FORM)) { // Ok to return early since only one parameter supported return outArgs; } // Solution sensitivity outArgs.setSupports( Thyra::ModelEvaluatorBase::OUT_ARG_DgDp, num_g, l, Thyra::ModelEvaluatorBase::DERIV_MV_JACOBIAN_FORM); if (num_g > 0) { // Only one response supported const int j = 0; const Thyra::ModelEvaluatorBase::DerivativeSupport model_dgdx_support = modelOutArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_DgDx, j); if (!model_dgdx_support.none()) { const Thyra::ModelEvaluatorBase::DerivativeSupport model_dgdp_support = modelOutArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_DgDp, j, l); // Response sensitivity Thyra::ModelEvaluatorBase::DerivativeSupport dgdp_support; if (model_dgdp_support.supports(Thyra::ModelEvaluatorBase::DERIV_MV_JACOBIAN_FORM)) { dgdp_support.plus(Thyra::ModelEvaluatorBase::DERIV_MV_JACOBIAN_FORM); } if (model_dgdp_support.supports(Thyra::ModelEvaluatorBase::DERIV_LINEAR_OP)) { dgdp_support.plus(Thyra::ModelEvaluatorBase::DERIV_LINEAR_OP); } outArgs.setSupports( Thyra::ModelEvaluatorBase::OUT_ARG_DgDp, j, l, dgdp_support); } } } return outArgs; }
void Piro::SteadyStateSolver<Scalar>::evalConvergedModel( const Thyra::ModelEvaluatorBase::InArgs<Scalar>& modelInArgs, const Thyra::ModelEvaluatorBase::OutArgs<Scalar>& outArgs) const { using Teuchos::RCP; using Teuchos::rcp; // Solution at convergence is the response at index num_g_ { const RCP<Thyra::VectorBase<Scalar> > gx_out = outArgs.get_g(num_g_); if (Teuchos::nonnull(gx_out)) { Thyra::copy(*modelInArgs.get_x(), gx_out.ptr()); } } // Setup output for final evalution of underlying model Thyra::ModelEvaluatorBase::OutArgs<Scalar> modelOutArgs = model_->createOutArgs(); { // Responses for (int j = 0; j < num_g_; ++j) { const RCP<Thyra::VectorBase<Scalar> > g_out = outArgs.get_g(j); // Forward to underlying model modelOutArgs.set_g(j, g_out); } // Jacobian { bool jacobianRequired = false; for (int j = 0; j <= num_g_; ++j) { for (int l = 0; l < num_p_; ++l) { const Thyra::ModelEvaluatorBase::DerivativeSupport dgdp_support = outArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_DgDp, j, l); if (!dgdp_support.none()) { const Thyra::ModelEvaluatorBase::Derivative<Scalar> dgdp_deriv = outArgs.get_DgDp(j, l); if (!dgdp_deriv.isEmpty()) { jacobianRequired = true; } } } } if (jacobianRequired) { const RCP<Thyra::LinearOpWithSolveBase<Scalar> > jacobian = model_->create_W(); modelOutArgs.set_W(jacobian); } } // DfDp derivatives for (int l = 0; l < num_p_; ++l) { Thyra::ModelEvaluatorBase::DerivativeSupport dfdp_request; for (int j = 0; j <= num_g_; ++j) { const Thyra::ModelEvaluatorBase::DerivativeSupport dgdp_support = outArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_DgDp, j, l); if (!dgdp_support.none()) { const Thyra::ModelEvaluatorBase::Derivative<Scalar> dgdp_deriv = outArgs.get_DgDp(j, l); if (Teuchos::nonnull(dgdp_deriv.getLinearOp())) { dfdp_request.plus(Thyra::ModelEvaluatorBase::DERIV_LINEAR_OP); } else if (Teuchos::nonnull(dgdp_deriv.getMultiVector())) { dfdp_request.plus(Thyra::ModelEvaluatorBase::DERIV_MV_JACOBIAN_FORM); } } } if (!dfdp_request.none()) { Thyra::ModelEvaluatorBase::Derivative<Scalar> dfdp_deriv; if (dfdp_request.supports(Thyra::ModelEvaluatorBase::DERIV_MV_JACOBIAN_FORM)) { dfdp_deriv = Thyra::create_DfDp_mv(*model_, l, Thyra::ModelEvaluatorBase::DERIV_MV_JACOBIAN_FORM); } else if (dfdp_request.supports(Thyra::ModelEvaluatorBase::DERIV_LINEAR_OP)) { dfdp_deriv = model_->create_DfDp_op(l); } modelOutArgs.set_DfDp(l, dfdp_deriv); } } // DgDx derivatives for (int j = 0; j < num_g_; ++j) { Thyra::ModelEvaluatorBase::DerivativeSupport dgdx_request; for (int l = 0; l < num_p_; ++l) { const Thyra::ModelEvaluatorBase::DerivativeSupport dgdp_support = outArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_DgDp, j, l); if (!dgdp_support.none()) { const Thyra::ModelEvaluatorBase::Derivative<Scalar> dgdp_deriv = outArgs.get_DgDp(j, l); if (!dgdp_deriv.isEmpty()) { const bool dgdp_mvGrad_required = Teuchos::nonnull(dgdp_deriv.getMultiVector()) && dgdp_deriv.getMultiVectorOrientation() == Thyra::ModelEvaluatorBase::DERIV_MV_GRADIENT_FORM; if (dgdp_mvGrad_required) { dgdx_request.plus(Thyra::ModelEvaluatorBase::DERIV_MV_GRADIENT_FORM); } else { dgdx_request.plus(Thyra::ModelEvaluatorBase::DERIV_LINEAR_OP); } } } } if (!dgdx_request.none()) { Thyra::ModelEvaluatorBase::Derivative<Scalar> dgdx_deriv; if (dgdx_request.supports(Thyra::ModelEvaluatorBase::DERIV_MV_GRADIENT_FORM)) { dgdx_deriv = Thyra::create_DgDx_mv(*model_, j, Thyra::ModelEvaluatorBase::DERIV_MV_GRADIENT_FORM); } else if (dgdx_request.supports(Thyra::ModelEvaluatorBase::DERIV_LINEAR_OP)) { dgdx_deriv = model_->create_DgDx_op(j); } modelOutArgs.set_DgDx(j, dgdx_deriv); } } // DgDp derivatives for (int l = 0; l < num_p_; ++l) { for (int j = 0; j < num_g_; ++j) { const Thyra::ModelEvaluatorBase::DerivativeSupport dgdp_support = outArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_DgDp, j, l); if (!dgdp_support.none()) { const Thyra::ModelEvaluatorBase::Derivative<Scalar> dgdp_deriv = outArgs.get_DgDp(j, l); Thyra::ModelEvaluatorBase::Derivative<Scalar> model_dgdp_deriv; const RCP<Thyra::LinearOpBase<Scalar> > dgdp_op = dgdp_deriv.getLinearOp(); if (Teuchos::nonnull(dgdp_op)) { model_dgdp_deriv = model_->create_DgDp_op(j, l); } else { model_dgdp_deriv = dgdp_deriv; } if (!model_dgdp_deriv.isEmpty()) { modelOutArgs.set_DgDp(j, l, model_dgdp_deriv); } } } } } // Evaluate underlying model model_->evalModel(modelInArgs, modelOutArgs); // Assemble user-requested sensitivities if (modelOutArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_W)) { const RCP<Thyra::LinearOpWithSolveBase<Scalar> > jacobian = modelOutArgs.get_W(); if (Teuchos::nonnull(jacobian)) { for (int l = 0; l < num_p_; ++l) { const Thyra::ModelEvaluatorBase::DerivativeSupport dfdp_support = modelOutArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_DfDp, l); if (!dfdp_support.none()) { const Thyra::ModelEvaluatorBase::Derivative<Scalar> dfdp_deriv = modelOutArgs.get_DfDp(l); const RCP<Thyra::MultiVectorBase<Scalar> > dfdp_mv = dfdp_deriv.getMultiVector(); RCP<Thyra::LinearOpBase<Scalar> > dfdp_op = dfdp_deriv.getLinearOp(); if (Teuchos::is_null(dfdp_op)) { dfdp_op = dfdp_mv; } const Thyra::ModelEvaluatorBase::Derivative<Scalar> dxdp_deriv = outArgs.get_DgDp(num_g_, l); const RCP<Thyra::LinearOpBase<Scalar> > dxdp_op = dxdp_deriv.getLinearOp(); const RCP<Thyra::MultiVectorBase<Scalar> > dxdp_mv = dxdp_deriv.getMultiVector(); RCP<const Thyra::LinearOpBase<Scalar> > minus_dxdp_op; RCP<Thyra::MultiVectorBase<Scalar> > minus_dxdp_mv; if (Teuchos::nonnull(dfdp_mv)) { if (Teuchos::nonnull(dxdp_mv)) { minus_dxdp_mv = dxdp_mv; // Use user-provided object as temporary } else { minus_dxdp_mv = Thyra::createMembers(model_->get_x_space(), model_->get_p_space(l)); minus_dxdp_op = minus_dxdp_mv; } } if (Teuchos::is_null(minus_dxdp_op)) { const RCP<const Thyra::LinearOpBase<Scalar> > dfdx_inv_op = Thyra::inverse<Scalar>(jacobian); minus_dxdp_op = Thyra::multiply<Scalar>(dfdx_inv_op, dfdp_op); } if (Teuchos::nonnull(minus_dxdp_mv)) { Thyra::assign(minus_dxdp_mv.ptr(), Teuchos::ScalarTraits<Scalar>::zero()); const Thyra::SolveCriteria<Scalar> defaultSolveCriteria; const Thyra::SolveStatus<Scalar> solveStatus = Thyra::solve( *jacobian, Thyra::NOTRANS, *dfdp_mv, minus_dxdp_mv.ptr(), Teuchos::ptr(&defaultSolveCriteria)); TEUCHOS_TEST_FOR_EXCEPTION( solveStatus.solveStatus == Thyra::SOLVE_STATUS_UNCONVERGED, std::runtime_error, "Jacobian solver failed to converge"); } // Solution sensitivities if (Teuchos::nonnull(dxdp_mv)) { minus_dxdp_mv = Teuchos::null; // Invalidates temporary Thyra::scale(-Teuchos::ScalarTraits<Scalar>::one(), dxdp_mv.ptr()); } else if (Teuchos::nonnull(dxdp_op)) { const RCP<Thyra::DefaultMultipliedLinearOp<Scalar> > dxdp_op_downcasted = Teuchos::rcp_dynamic_cast<Thyra::DefaultMultipliedLinearOp<Scalar> >(dxdp_op); TEUCHOS_TEST_FOR_EXCEPTION( Teuchos::is_null(dxdp_op_downcasted), std::invalid_argument, "Illegal operator for DgDp(" << "j = " << num_g_ << ", " << "index l = " << l << ")\n"); const RCP<const Thyra::LinearOpBase<Scalar> > minus_id_op = Thyra::scale<Scalar>(-Teuchos::ScalarTraits<Scalar>::one(), Thyra::identity(dfdp_op->domain())); dxdp_op_downcasted->initialize(Teuchos::tuple(minus_dxdp_op, minus_id_op)); } // Response sensitivities for (int j = 0; j < num_g_; ++j) { const Thyra::ModelEvaluatorBase::DerivativeSupport dgdp_support = outArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_DgDp, j, l); if (!dgdp_support.none()) { const Thyra::ModelEvaluatorBase::Derivative<Scalar> dgdp_deriv = outArgs.get_DgDp(j, l); if (!dgdp_deriv.isEmpty()) { const Thyra::ModelEvaluatorBase::Derivative<Scalar> dgdx_deriv = modelOutArgs.get_DgDx(j); const RCP<const Thyra::MultiVectorBase<Scalar> > dgdx_mv = dgdx_deriv.getMultiVector(); RCP<const Thyra::LinearOpBase<Scalar> > dgdx_op = dgdx_deriv.getLinearOp(); if (Teuchos::is_null(dgdx_op)) { dgdx_op = Thyra::adjoint<Scalar>(dgdx_mv); } const RCP<Thyra::LinearOpBase<Scalar> > dgdp_op = dgdp_deriv.getLinearOp(); if (Teuchos::nonnull(dgdp_op)) { const RCP<Thyra::DefaultAddedLinearOp<Scalar> > dgdp_op_downcasted = Teuchos::rcp_dynamic_cast<Thyra::DefaultAddedLinearOp<Scalar> >(dgdp_op); TEUCHOS_TEST_FOR_EXCEPTION( Teuchos::is_null(dgdp_op_downcasted), std::invalid_argument, "Illegal operator for DgDp(" << "j = " << j << ", " << "index l = " << l << ")\n"); dgdp_op_downcasted->uninitialize(); const RCP<const Thyra::LinearOpBase<Scalar> > implicit_dgdp_op = Thyra::multiply<Scalar>( Thyra::scale<Scalar>(-Teuchos::ScalarTraits<Scalar>::one(), dgdx_op), minus_dxdp_op); const RCP<const Thyra::LinearOpBase<Scalar> > model_dgdp_op = modelOutArgs.get_DgDp(j, l).getLinearOp(); Teuchos::Array<RCP<const Thyra::LinearOpBase<Scalar> > > op_args(2); op_args[0] = model_dgdp_op; op_args[1] = implicit_dgdp_op; dgdp_op_downcasted->initialize(op_args); } const RCP<Thyra::MultiVectorBase<Scalar> > dgdp_mv = dgdp_deriv.getMultiVector(); if (Teuchos::nonnull(dgdp_mv)) { if (dgdp_deriv.getMultiVectorOrientation() == Thyra::ModelEvaluatorBase::DERIV_MV_GRADIENT_FORM) { if (Teuchos::nonnull(dxdp_mv)) { Thyra::apply( *dxdp_mv, Thyra::TRANS, *dgdx_mv, dgdp_mv.ptr(), Teuchos::ScalarTraits<Scalar>::one(), Teuchos::ScalarTraits<Scalar>::one()); } else { Thyra::apply( *minus_dxdp_mv, Thyra::TRANS, *dgdx_mv, dgdp_mv.ptr(), -Teuchos::ScalarTraits<Scalar>::one(), Teuchos::ScalarTraits<Scalar>::one()); } } else { if (Teuchos::nonnull(dxdp_mv)) { Thyra::apply( *dgdx_op, Thyra::NOTRANS, *dxdp_mv, dgdp_mv.ptr(), Teuchos::ScalarTraits<Scalar>::one(), Teuchos::ScalarTraits<Scalar>::one()); } else { Thyra::apply( *dgdx_op, Thyra::NOTRANS, *minus_dxdp_mv, dgdp_mv.ptr(), -Teuchos::ScalarTraits<Scalar>::one(), Teuchos::ScalarTraits<Scalar>::one()); } } } } } } } } } } }
void Piro::RythmosSolver<Scalar>::evalModelImpl( #endif const Thyra::ModelEvaluatorBase::InArgs<Scalar>& inArgs, const Thyra::ModelEvaluatorBase::OutArgs<Scalar>& outArgs) const { using Teuchos::RCP; using Teuchos::rcp; // TODO: Support more than 1 parameter and 1 response const int j = 0; const int l = 0; // Parse InArgs RCP<const Thyra::VectorBase<Scalar> > p_in; if (num_p > 0) { p_in = inArgs.get_p(l); } RCP<const Thyra::VectorBase<Scalar> > p_in2; //JF add for multipoint if (num_p > 1) { p_in2 = inArgs.get_p(l+1); } // Parse OutArgs RCP<Thyra::VectorBase<Scalar> > g_out; if (num_g > 0) { g_out = outArgs.get_g(j); } const RCP<Thyra::VectorBase<Scalar> > gx_out = outArgs.get_g(num_g); Thyra::ModelEvaluatorBase::InArgs<Scalar> state_ic = model->getNominalValues(); // Set initial time in ME if needed if(t_initial > 0.0 && state_ic.supports(Thyra::ModelEvaluatorBase::IN_ARG_t)) state_ic.set_t(t_initial); if (Teuchos::nonnull(initialConditionModel)) { // The initial condition depends on the parameter // It is found by querying the auxiliary model evaluator as the last response const RCP<Thyra::VectorBase<Scalar> > initialState = Thyra::createMember(model->get_x_space()); { Thyra::ModelEvaluatorBase::InArgs<Scalar> initCondInArgs = initialConditionModel->createInArgs(); if (num_p > 0) { initCondInArgs.set_p(l, inArgs.get_p(l)); } Thyra::ModelEvaluatorBase::OutArgs<Scalar> initCondOutArgs = initialConditionModel->createOutArgs(); initCondOutArgs.set_g(initCondOutArgs.Ng() - 1, initialState); initialConditionModel->evalModel(initCondInArgs, initCondOutArgs); } state_ic.set_x(initialState); } // Set paramters p_in as part of initial conditions if (num_p > 0) { if (Teuchos::nonnull(p_in)) { state_ic.set_p(l, p_in); } } if (num_p > 1) { //JF added for multipoint if (Teuchos::nonnull(p_in2)) { state_ic.set_p(l+1, p_in2); } } *out << "\nstate_ic:\n" << Teuchos::describe(state_ic, solnVerbLevel); //JF may need a version of the following for multipoint, i.e. num_p>1, l+1, if we want sensitivities RCP<Thyra::MultiVectorBase<Scalar> > dgxdp_out; Thyra::ModelEvaluatorBase::Derivative<Scalar> dgdp_deriv_out; if (num_p > 0) { const Thyra::ModelEvaluatorBase::DerivativeSupport dgxdp_support = outArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_DgDp, num_g, l); if (dgxdp_support.supports(Thyra::ModelEvaluatorBase::DERIV_MV_JACOBIAN_FORM)) { const Thyra::ModelEvaluatorBase::Derivative<Scalar> dgxdp_deriv = outArgs.get_DgDp(num_g, l); dgxdp_out = dgxdp_deriv.getMultiVector(); } if (num_g > 0) { const Thyra::ModelEvaluatorBase::DerivativeSupport dgdp_support = outArgs.supports(Thyra::ModelEvaluatorBase::OUT_ARG_DgDp, j, l); if (!dgdp_support.none()) { dgdp_deriv_out = outArgs.get_DgDp(j, l); } } } const bool requestedSensitivities = Teuchos::nonnull(dgxdp_out) || !dgdp_deriv_out.isEmpty(); RCP<const Thyra::VectorBase<Scalar> > finalSolution; if (!requestedSensitivities) { // *out << "\nE) Solve the forward problem ...\n"; // fwdStateStepper->setInitialCondition(state_ic); fwdStateIntegrator->setStepper(fwdStateStepper, t_final, true); *out << "T final : " << t_final << " \n"; Teuchos::Array<RCP<const Thyra::VectorBase<Scalar> > > x_final_array; fwdStateIntegrator->getFwdPoints( Teuchos::tuple<Scalar>(t_final), &x_final_array, NULL, NULL); finalSolution = x_final_array[0]; if (Teuchos::VERB_MEDIUM <= solnVerbLevel) { std::cout << "Final Solution\n" << *finalSolution << std::endl; } } else { // Computing sensitivities // *out << "\nE) Solve the forward problem with Sensitivities...\n"; // RCP<Rythmos::ForwardSensitivityStepper<Scalar> > stateAndSensStepper = Rythmos::forwardSensitivityStepper<Scalar>(); stateAndSensStepper->initializeSyncedSteppers( model, l, model->getNominalValues(), fwdStateStepper, fwdTimeStepSolver); // // Set the initial condition for the state and forward sensitivities // const RCP<Thyra::VectorBase<Scalar> > s_bar_init = Thyra::createMember(stateAndSensStepper->getFwdSensModel()->get_x_space()); const RCP<Thyra::VectorBase<Scalar> > s_bar_dot_init = Thyra::createMember(stateAndSensStepper->getFwdSensModel()->get_x_space()); if (Teuchos::is_null(initialConditionModel)) { // The initial condition is assumed to be independent from the parameters // Therefore, the initial condition for the sensitivity is zero Thyra::assign(s_bar_init.ptr(), Teuchos::ScalarTraits<Scalar>::zero()); } else { // Use initialConditionModel to compute initial condition for sensitivity Thyra::ModelEvaluatorBase::InArgs<Scalar> initCondInArgs = initialConditionModel->createInArgs(); initCondInArgs.set_p(l, inArgs.get_p(l)); Thyra::ModelEvaluatorBase::OutArgs<Scalar> initCondOutArgs = initialConditionModel->createOutArgs(); typedef Thyra::DefaultMultiVectorProductVector<Scalar> DMVPV; const RCP<DMVPV> s_bar_init_downcasted = Teuchos::rcp_dynamic_cast<DMVPV>(s_bar_init); const Thyra::ModelEvaluatorBase::Derivative<Scalar> initCond_deriv( s_bar_init_downcasted->getNonconstMultiVector(), Thyra::ModelEvaluatorBase::DERIV_MV_JACOBIAN_FORM); initCondOutArgs.set_DgDp(initCondOutArgs.Ng() - 1, l, initCond_deriv); initialConditionModel->evalModel(initCondInArgs, initCondOutArgs); } Thyra::assign(s_bar_dot_init.ptr(), Teuchos::ScalarTraits<Scalar>::zero()); RCP<const Rythmos::StateAndForwardSensitivityModelEvaluator<Scalar> > stateAndSensModel = stateAndSensStepper->getStateAndFwdSensModel(); Thyra::ModelEvaluatorBase::InArgs<Scalar> state_and_sens_ic = stateAndSensStepper->getModel()->createInArgs(); // Copy time, parameters etc. state_and_sens_ic.setArgs(state_ic); // Set initial condition for x_bar = [ x; s_bar ] state_and_sens_ic.set_x(stateAndSensModel->create_x_bar_vec(state_ic.get_x(), s_bar_init)); // Set initial condition for x_bar_dot = [ x_dot; s_bar_dot ] state_and_sens_ic.set_x_dot(stateAndSensModel->create_x_bar_vec(state_ic.get_x_dot(), s_bar_dot_init)); stateAndSensStepper->setInitialCondition(state_and_sens_ic); // // Use a StepperAsModelEvaluator to integrate the state+sens // const RCP<Rythmos::StepperAsModelEvaluator<Scalar> > stateAndSensIntegratorAsModel = Rythmos::stepperAsModelEvaluator( Teuchos::rcp_implicit_cast<Rythmos::StepperBase<Scalar> >(stateAndSensStepper), Teuchos::rcp_implicit_cast<Rythmos::IntegratorBase<Scalar> >(fwdStateIntegrator), state_and_sens_ic); // StepperAsModelEvaluator outputs the solution as its last response const int stateAndSensModelStateResponseIndex = stateAndSensIntegratorAsModel->Ng() - 1; *out << "\nUse the StepperAsModelEvaluator to integrate state + sens x_bar(p,t_final) ... \n"; Teuchos::OSTab tab(out); // Solution sensitivity in column-oriented (Jacobian) MultiVector form RCP<const Thyra::MultiVectorBase<Scalar> > dxdp; const RCP<Thyra::VectorBase<Scalar> > x_bar_final = Thyra::createMember(stateAndSensIntegratorAsModel->get_g_space(stateAndSensModelStateResponseIndex)); // Extract pieces of x_bar_final to prepare output { const RCP<const Thyra::ProductVectorBase<Scalar> > x_bar_final_downcasted = Thyra::productVectorBase<Scalar>(x_bar_final); // Solution const int solutionBlockIndex = 0; finalSolution = x_bar_final_downcasted->getVectorBlock(solutionBlockIndex); // Sensitivity const int sensitivityBlockIndex = 1; const RCP<const Thyra::VectorBase<Scalar> > s_bar_final = x_bar_final_downcasted->getVectorBlock(sensitivityBlockIndex); { typedef Thyra::DefaultMultiVectorProductVector<Scalar> DMVPV; const RCP<const DMVPV> s_bar_final_downcasted = Teuchos::rcp_dynamic_cast<const DMVPV>(s_bar_final); dxdp = s_bar_final_downcasted->getMultiVector(); } } Thyra::eval_g( *stateAndSensIntegratorAsModel, l, *state_ic.get_p(l), t_final, stateAndSensModelStateResponseIndex, x_bar_final.get() ); *out << "\nx_bar_final = x_bar(p,t_final) evaluated using " << "stateAndSensIntegratorAsModel:\n" << Teuchos::describe(*x_bar_final,solnVerbLevel); if (Teuchos::nonnull(dgxdp_out)) { Thyra::assign(dgxdp_out.ptr(), *dxdp); } if (!dgdp_deriv_out.isEmpty()) { RCP<Thyra::DefaultAddedLinearOp<Scalar> > dgdp_op_out; { const RCP<Thyra::LinearOpBase<Scalar> > dgdp_op = dgdp_deriv_out.getLinearOp(); if (Teuchos::nonnull(dgdp_op)) { dgdp_op_out = Teuchos::rcp_dynamic_cast<Thyra::DefaultAddedLinearOp<Scalar> >(dgdp_op); dgdp_op_out.assert_not_null(); } } Thyra::ModelEvaluatorBase::InArgs<Scalar> modelInArgs = model->createInArgs(); { modelInArgs.set_x(finalSolution); if (num_p > 0) { modelInArgs.set_p(l, p_in); } } // require dgdx, dgdp from model Thyra::ModelEvaluatorBase::OutArgs<Scalar> modelOutArgs = model->createOutArgs(); { const Thyra::ModelEvaluatorBase::Derivative<Scalar> dgdx_deriv(model->create_DgDx_op(j)); modelOutArgs.set_DgDx(j, dgdx_deriv); Thyra::ModelEvaluatorBase::Derivative<Scalar> dgdp_deriv; if (Teuchos::nonnull(dgdp_op_out)) { dgdp_deriv = model->create_DgDp_op(j, l); } else { dgdp_deriv = dgdp_deriv_out; } modelOutArgs.set_DgDp(j, l, dgdp_deriv); } model->evalModel(modelInArgs, modelOutArgs); const RCP<const Thyra::LinearOpBase<Scalar> > dgdx = modelOutArgs.get_DgDx(j).getLinearOp(); // dgdp_out = dgdp + <dgdx, dxdp> if (Teuchos::nonnull(dgdp_op_out)) { Teuchos::Array<RCP<const Thyra::LinearOpBase<Scalar> > > op_args(2); { op_args[0] = modelOutArgs.get_DgDp(j, l).getLinearOp(); op_args[1] = Thyra::multiply<Scalar>(dgdx, dxdp); } dgdp_op_out->initialize(op_args); } else { const RCP<Thyra::MultiVectorBase<Scalar> > dgdp_mv_out = dgdp_deriv_out.getMultiVector(); Thyra::apply( *dgdx, Thyra::NOTRANS, *dxdp, dgdp_mv_out.ptr(), Teuchos::ScalarTraits<Scalar>::one(), Teuchos::ScalarTraits<Scalar>::one()); } } } *out << "\nF) Check the solution to the forward problem ...\n"; // As post-processing step, calculate responses at final solution { Thyra::ModelEvaluatorBase::InArgs<Scalar> modelInArgs = model->createInArgs(); { modelInArgs.set_x(finalSolution); if (num_p > 0) { modelInArgs.set_p(l, p_in); } if (num_p > 1) { //JF added for multipoint modelInArgs.set_p(l+1, p_in2); } //Set time to be final time at which the solve occurs (< t_final in the case we don't make it to t_final). modelInArgs.set_t(fwdStateStepper->getTimeRange().lower()); } Thyra::ModelEvaluatorBase::OutArgs<Scalar> modelOutArgs = model->createOutArgs(); if (Teuchos::nonnull(g_out)) { Thyra::put_scalar(Teuchos::ScalarTraits<Scalar>::zero(), g_out.ptr()); modelOutArgs.set_g(j, g_out); } model->evalModel(modelInArgs, modelOutArgs); } // Return the final solution as an additional g-vector, if requested if (Teuchos::nonnull(gx_out)) { Thyra::copy(*finalSolution, gx_out.ptr()); } }