void DiscreteBoundaryOperator<ValueType>::applyImpl( const Thyra::EOpTransp M_trans, const Thyra::MultiVectorBase<ValueType> &X_in, const Teuchos::Ptr<Thyra::MultiVectorBase<ValueType>> &Y_inout, const ValueType alpha, const ValueType beta) const { typedef Thyra::Ordinal Ordinal; // Note: the name is VERY misleading: these asserts don't disappear in // release runs, and in case of failure throw exceptions rather than // abort. TEUCHOS_ASSERT(this->opSupported(M_trans)); TEUCHOS_ASSERT(X_in.range()->isCompatible(*this->domain())); TEUCHOS_ASSERT(Y_inout->range()->isCompatible(*this->range())); TEUCHOS_ASSERT(Y_inout->domain()->isCompatible(*X_in.domain())); const Ordinal colCount = X_in.domain()->dim(); // Loop over the input columns for (Ordinal col = 0; col < colCount; ++col) { // Get access the the elements of X_in's and Y_inout's column #col Thyra::ConstDetachedSpmdVectorView<ValueType> xVec(X_in.col(col)); Thyra::DetachedSpmdVectorView<ValueType> yVec(Y_inout->col(col)); const Teuchos::ArrayRCP<const ValueType> xArray(xVec.sv().values()); const Teuchos::ArrayRCP<ValueType> yArray(yVec.sv().values()); // Wrap the Trilinos array in an Armadillo vector. const_cast is used // because it's more natural to have a const arma::Col<ValueType> array // than an arma::Col<const ValueType> one. const arma::Col<ValueType> xCol(const_cast<ValueType *>(xArray.get()), xArray.size(), false /* copy_aux_mem */); arma::Col<ValueType> yCol(yArray.get(), yArray.size(), false); applyBuiltInImpl(static_cast<TranspositionMode>(M_trans), xCol, yCol, alpha, beta); } }
NOX::Thyra::MultiVector:: MultiVector(const ::Thyra::MultiVectorBase<double>& source) : thyraMultiVec(source.clone_mv()), noxThyraVectors(thyraMultiVec->domain()->dim()) { }
void ExampleTridiagSerialLinearOp<Scalar>::applyImpl( const Thyra::EOpTransp M_trans, const Thyra::MultiVectorBase<Scalar> &X_in, const Teuchos::Ptr<Thyra::MultiVectorBase<Scalar> > &Y_inout, const Scalar alpha, const Scalar beta ) const { typedef Teuchos::ScalarTraits<Scalar> ST; typedef Thyra::Ordinal Ordinal; const Ordinal dim = space_->dim(); // Loop over the input columns const Ordinal m = X_in.domain()->dim(); for (Ordinal col_j = 0; col_j < m; ++col_j) { // Get access the the elements of column j Thyra::ConstDetachedVectorView<Scalar> x_vec(X_in.col(col_j)); Thyra::DetachedVectorView<Scalar> y_vec(Y_inout->col(col_j)); const Teuchos::ArrayRCP<const Scalar> x = x_vec.sv().values(); const Teuchos::ArrayRCP<Scalar> y = y_vec.sv().values(); // Perform y = beta*y (being careful to set y=0 if beta=0 in case y is // uninitialized on input!) if( beta == ST::zero() ) { for( Ordinal k = 0; k < dim; ++k ) y[k] = ST::zero(); } else if( beta != ST::one() ) { for( Ordinal k = 0; k < dim; ++k ) y[k] *= beta; } // Perform y = alpha*op(M)*x Ordinal k = 0; if( M_trans == Thyra::NOTRANS ) { y[k] += alpha * ( diag_[k]*x[k] + upper_[k]*x[k+1] ); // First row for( k = 1; k < dim - 1; ++k ) // Middle rows y[k] += alpha * ( lower_[k-1]*x[k-1] + diag_[k]*x[k] + upper_[k]*x[k+1] ); y[k] += alpha * ( lower_[k-1]*x[k-1] + diag_[k]*x[k] ); // Last row } else if( M_trans == Thyra::CONJ ) { y[k] += alpha * ( ST::conjugate(diag_[k])*x[k] + ST::conjugate(upper_[k])*x[k+1] ); for( k = 1; k < dim - 1; ++k ) y[k] += alpha * ( ST::conjugate(lower_[k-1])*x[k-1] + ST::conjugate(diag_[k])*x[k] + ST::conjugate(upper_[k])*x[k+1] ); y[k] += alpha * ( ST::conjugate(lower_[k-1])*x[k-1] + ST::conjugate(diag_[k])*x[k] ); } else if( M_trans == Thyra::TRANS ) { y[k] += alpha * ( diag_[k]*x[k] + lower_[k]*x[k+1] ); for( k = 1; k < dim - 1; ++k ) y[k] += alpha * ( upper_[k-1]*x[k-1] + diag_[k]*x[k] + lower_[k]*x[k+1] ); y[k] += alpha * ( upper_[k-1]*x[k-1] + diag_[k]*x[k] ); } else if( M_trans == Thyra::CONJTRANS ) { y[k] += alpha * ( ST::conjugate(diag_[k])*x[k] + ST::conjugate(lower_[k])*x[k+1] ); for( k = 1; k < dim - 1; ++k ) y[k] += alpha * ( ST::conjugate(upper_[k-1])*x[k-1] + ST::conjugate(diag_[k])*x[k] + ST::conjugate(lower_[k])*x[k+1] ); y[k] += alpha * ( ST::conjugate(upper_[k-1])*x[k-1] + ST::conjugate(diag_[k])*x[k] ); } else { TEUCHOS_TEST_FOR_EXCEPT(true); // Throw exception if we get here! } } }
void MatrixFreeJacobianOperator<Scalar>::applyImpl(const ::Thyra::EOpTransp M_trans, const ::Thyra::MultiVectorBase< Scalar > &thyra_mv_y, const Teuchos::Ptr< ::Thyra::MultiVectorBase< Scalar > > &thyra_mv_u, const Scalar alpha, const Scalar beta) const { TEUCHOS_ASSERT(setup_called_); // Use a directional derivative to approximate u = Jy /* * delta = scalar perturbation * x = solution vector used to evaluate f * f = function evaluation (RHS) * y = vector that J is applied to * * f(x + delta * y) - f(x) * u = Jy = ----------------------- * delta */ TEUCHOS_ASSERT(thyra_mv_y.domain()->dim() == 1); TEUCHOS_ASSERT(thyra_mv_u->domain()->dim() == 1); const Teuchos::RCP<const ::Thyra::VectorBase<Scalar> > y_ptr = thyra_mv_y.col(0); const Teuchos::RCP< ::Thyra::VectorBase<Scalar> > u_ptr = thyra_mv_u->col(0); const ::Thyra::VectorBase<Scalar>& y = *y_ptr; ::Thyra::VectorBase<Scalar>& u = *u_ptr; typename Teuchos::ScalarTraits<Scalar>::magnitudeType norm_2_x = ::Thyra::norm(*x_base_); typename Teuchos::ScalarTraits<Scalar>::magnitudeType norm_2_y = ::Thyra::norm(y); // Make sure the y-norm is not zero, otherwise we can get an inf perturbation from divide by zero if (norm_2_y == 0.0) { norm_2_y = 1.0; ::Thyra::assign(Teuchos::ptrFromRef(u),0.0); return; } if (perturbation_type_ == SalingerLOCA) { delta_ = lambda_ * (lambda_ + norm_2_x / norm_2_y); } else if (perturbation_type_ == KelleySalingerPawlowski) { Scalar inner_prod_x_y = ::Thyra::inner(*x_base_,y); if (inner_prod_x_y==Teuchos::ScalarTraits<Scalar>::zero()) inner_prod_x_y = 1.0e-12; delta_ = lambda_ * (1.0e-12 / lambda_ + std::fabs(inner_prod_x_y) / (norm_2_y * norm_2_y) ) * inner_prod_x_y / std::fabs(inner_prod_x_y); } else if (perturbation_type_ == KnollKeyes) { delta_ = lambda_ * ::Thyra::norm_1(*x_base_) / (Teuchos::as<double>(x_base_->space()->dim()) * norm_2_y) + lambda_; } else { delta_ = user_defined_delta_; } // perturbed solution: x_p = delta * y + x_0 ::Thyra::V_StVpV(x_perturb_.ptr(),delta_,y,*x_base_); if (is_null(in_args_)) { in_args_ = Teuchos::rcp(new ::Thyra::ModelEvaluatorBase::InArgs<Scalar>(model_->createInArgs())); in_args_->setArgs(model_->getNominalValues()); } in_args_->set_x(x_perturb_); if (is_null(out_args_)) out_args_ = Teuchos::rcp(new ::Thyra::ModelEvaluatorBase::OutArgs<Scalar>(model_->createOutArgs())); out_args_->set_f(f_perturb_); // f_p = f(delta * y + x) model_->evalModel(*in_args_,*out_args_); // to be safe, remove arguments in_args_->set_x(Teuchos::null); out_args_->set_f(Teuchos::null); Scalar inv_delta = Teuchos::ScalarTraits<Scalar>::one() / delta_; if ( difference_type_ == Centered ) { // perturbed solution: x_p = -delta * y + x_0 ::Thyra::V_StVpV(x_perturb_.ptr(),-delta_,y,*x_base_); out_args_->set_f(f2_perturb_); // f_p2 = f(-delta * y + x) model_->evalModel(*in_args_,*out_args_); // to be safe, remove arguments in_args_->set_x(Teuchos::null); out_args_->set_f(Teuchos::null); ::Thyra::V_StVpStV(ptrFromRef(u),inv_delta,*f_perturb_,-inv_delta,*f2_perturb_); } else { ::Thyra::V_StVpStV(ptrFromRef(u),inv_delta,*f_perturb_,-inv_delta,*f_base_); } }
void Piro::MatrixFreeLinearOp<Scalar>::applyImpl( const Thyra::EOpTransp M_trans, const Thyra::MultiVectorBase<Scalar> &X, const Teuchos::Ptr<Thyra::MultiVectorBase<Scalar> > &Y, const Scalar alpha, const Scalar beta) const { using Teuchos::RCP; using Teuchos::Ptr; TEUCHOS_TEST_FOR_EXCEPTION( !this->opSupported(M_trans), Thyra::Exceptions::OpNotSupported, this->description() << " does not support operation " << Thyra::toString(M_trans)); TEUCHOS_TEST_FOR_EXCEPTION( !X.range()->isCompatible(*this->domain()), Thyra::Exceptions::IncompatibleVectorSpaces, "Domain of " << this->description() << ": " << this->domain()->description() << " is not compatible with column space of " << X.description() << ": " << X.range()->description()); TEUCHOS_TEST_FOR_EXCEPTION( !Y->range()->isCompatible(*this->range()), Thyra::Exceptions::IncompatibleVectorSpaces, "Range of " << this->description() << ": " << this->range()->description() << " is not compatible with column space of " << Y->description() << ": " << Y->range()->description()); TEUCHOS_TEST_FOR_EXCEPTION( !Y->domain()->isCompatible(*X.domain()), Thyra::Exceptions::IncompatibleVectorSpaces, "Row space of " << Y->description() << ": " << Y->domain()->description() << " is not compatible with row space of " << X.description() << ": " << X.domain()->description()); TEUCHOS_TEST_FOR_EXCEPTION( &X == Y.get(), std::logic_error, "X and Y arguments are both aliases of " << X.description()); if (alpha == Teuchos::ScalarTraits<Scalar>::zero()) { // Y <- beta * Y Thyra::Vt_S(Y, beta); return; } typedef typename Teuchos::ScalarTraits<Scalar>::magnitudeType ScalarMagnitude; RCP<const Thyra::VectorBase<Scalar> > x_dot_base; if (basePoint_.supports(Thyra::ModelEvaluatorBase::IN_ARG_x_dot)) x_dot_base = basePoint_.get_x_dot(); RCP<const Thyra::VectorBase<Scalar> > x_base = basePoint_.get_x(); if (Teuchos::is_null(x_base)) { x_base = model_->getNominalValues().get_x(); } x_base.assert_not_null(); const ScalarMagnitude norm_x_base = Thyra::norm_2(*x_base); // Number of columns common to both vectors X and Y // (X and Y have compatible row spaces) const Thyra::Ordinal colCount = X.domain()->dim(); for (Teuchos::Ordinal j = Teuchos::Ordinal(); j < colCount; ++j) { const RCP<const Thyra::VectorBase<Scalar> > X_vec = X.col(j); const RCP<Thyra::VectorBase<Scalar> > Y_vec = Y->col(j); const ScalarMagnitude norm_dx = Thyra::norm_2(*X_vec); if (norm_dx == Teuchos::ScalarTraits<ScalarMagnitude>::zero()) { if (beta == Teuchos::ScalarTraits<Scalar>::zero()) { // Y_vec <- 0 Thyra::put_scalar(Teuchos::ScalarTraits<ScalarMagnitude>::zero(), Y_vec.ptr()); } else { // Y_vec <- beta * Y_vec Thyra::scale(beta, Y_vec.ptr()); } } else { // Scalar perturbation const ScalarMagnitude relative_pert_ratio = static_cast<ScalarMagnitude>(lambda_); const ScalarMagnitude eta = (relative_pert_ratio * ((norm_x_base / norm_dx) + relative_pert_ratio)); // Compute perturbed residual // Dynamic: f_pert <- f(x_dot_base + eta * (W_alpha * X), x_base + eta * (W_beta * X)) // Static: f_pert <- f(x_base + eta * X) const RCP<Thyra::VectorBase<Scalar> > f_pert = Thyra::createMember(this->range()); { Thyra::ModelEvaluatorBase::InArgs<Scalar> pertInArgs = model_->createInArgs(); { pertInArgs.setArgs(basePoint_); const bool isDynamic = Teuchos::nonnull(x_dot_base); if (isDynamic) { const RCP<Thyra::VectorBase<Scalar> > x_dot_pert = Thyra::createMember(this->domain()); const Scalar W_alpha = pertInArgs.get_alpha(); Thyra::V_VpStV<Scalar>(x_dot_pert.ptr(), *x_dot_base, W_alpha * eta, *X_vec); pertInArgs.set_x_dot(x_dot_pert); } const RCP<Thyra::VectorBase<Scalar> > x_pert = Thyra::createMember(this->domain()); const Scalar W_beta = isDynamic ? pertInArgs.get_beta() : Teuchos::ScalarTraits<Scalar>::one(); Thyra::V_VpStV<Scalar>(x_pert.ptr(), *x_base, W_beta * eta, *X_vec); pertInArgs.set_x(x_pert); } Thyra::ModelEvaluatorBase::OutArgs<Scalar> pertOutArgs = model_->createOutArgs(); { pertOutArgs.set_f(f_pert); } model_->evalModel(pertInArgs, pertOutArgs); } // Y <- alpha * (1/eta) * (f_pert - f_base) + beta * Y const Scalar alpha_over_eta = alpha / eta; if (beta == Teuchos::ScalarTraits<Scalar>::zero()) { // Y <- alpha * (1/eta) * (f_pert - f_base) Thyra::V_StVpStV<Scalar>(Y_vec.ptr(), alpha_over_eta, *f_pert, -alpha_over_eta, *f_base_); } else { // Aliasing f_pert and alpha_op_X (f_pert == alpha_op_X) const RCP<Thyra::VectorBase<Scalar> > alpha_op_X = f_pert; // alpha_op_X <- alpha * (1/eta) * (f_pert - f_base) Thyra::Vp_StV(alpha_op_X.ptr(), -Teuchos::ScalarTraits<Scalar>::one(), *f_base_); const Scalar alpha_over_eta = alpha / eta; Thyra::Vt_S(alpha_op_X.ptr(), alpha_over_eta); // Y <- alpha_op_X + beta * Y Thyra::Vp_V<Scalar>(Y_vec.ptr(), *alpha_op_X, beta); } } } }