/** * \file * \copyright * Copyright (c) 2012-2021, OpenGeoSys Community (http://www.opengeosys.org) * Distributed under a Modified BSD License. * See accompanying file LICENSE.txt or * http://www.opengeosys.org/project/license * */ #include "VectorMatrixAssembler.h" #include #include // for std::reference_wrapper. #include "NumLib/DOF/DOFTableUtil.h" #include "MathLib/LinAlg/Eigen/EigenMapTools.h" #include "LocalAssemblerInterface.h" #include "CoupledSolutionsForStaggeredScheme.h" #include "Process.h" namespace ProcessLib { VectorMatrixAssembler::VectorMatrixAssembler( std::unique_ptr&& jacobian_assembler) : _jacobian_assembler(std::move(jacobian_assembler)) { } void VectorMatrixAssembler::preAssemble( const std::size_t mesh_item_id, LocalAssemblerInterface& local_assembler, const NumLib::LocalToGlobalIndexMap& dof_table, const double t, double const dt, const GlobalVector& x) { auto const indices = NumLib::getIndices(mesh_item_id, dof_table); auto const local_x = x.get(indices); local_assembler.preAssemble(t, dt, local_x); } void VectorMatrixAssembler::assemble( const std::size_t mesh_item_id, LocalAssemblerInterface& local_assembler, std::vector> const& dof_tables, const double t, double const dt, std::vector const& x, std::vector const& xdot, int const process_id, GlobalMatrix& M, GlobalMatrix& K, GlobalVector& b) { std::vector> indices_of_processes; indices_of_processes.reserve(dof_tables.size()); transform(cbegin(dof_tables), cend(dof_tables), back_inserter(indices_of_processes), [&](auto const& dof_table) { return NumLib::getIndices(mesh_item_id, dof_table); }); auto const& indices = indices_of_processes[process_id]; _local_M_data.clear(); _local_K_data.clear(); _local_b_data.clear(); std::size_t const number_of_processes = x.size(); // Monolithic scheme if (number_of_processes == 1) { auto const local_x = x[process_id]->get(indices); auto const local_xdot = xdot[process_id]->get(indices); local_assembler.assemble(t, dt, local_x, local_xdot, _local_M_data, _local_K_data, _local_b_data); } else // Staggered scheme { auto local_coupled_xs = getCoupledLocalSolutions(x, indices_of_processes); auto const local_x = MathLib::toVector(local_coupled_xs); auto local_coupled_xdots = getCoupledLocalSolutions(xdot, indices_of_processes); auto const local_xdot = MathLib::toVector(local_coupled_xdots); local_assembler.assembleForStaggeredScheme( t, dt, local_x, local_xdot, process_id, _local_M_data, _local_K_data, _local_b_data); } auto const num_r_c = indices.size(); auto const r_c_indices = NumLib::LocalToGlobalIndexMap::RowColumnIndices(indices, indices); if (!_local_M_data.empty()) { auto const local_M = MathLib::toMatrix(_local_M_data, num_r_c, num_r_c); M.add(r_c_indices, local_M); } if (!_local_K_data.empty()) { auto const local_K = MathLib::toMatrix(_local_K_data, num_r_c, num_r_c); K.add(r_c_indices, local_K); } if (!_local_b_data.empty()) { assert(_local_b_data.size() == num_r_c); b.add(indices, _local_b_data); } } void VectorMatrixAssembler::assembleWithJacobian( std::size_t const mesh_item_id, LocalAssemblerInterface& local_assembler, std::vector> const& dof_tables, const double t, double const dt, std::vector const& x, std::vector const& xdot, const double dxdot_dx, const double dx_dx, int const process_id, GlobalMatrix& M, GlobalMatrix& K, GlobalVector& b, GlobalMatrix& Jac) { std::vector> indices_of_processes; indices_of_processes.reserve(dof_tables.size()); transform(cbegin(dof_tables), cend(dof_tables), back_inserter(indices_of_processes), [&](auto const& dof_table) { return NumLib::getIndices(mesh_item_id, dof_table); }); auto const& indices = indices_of_processes[process_id]; _local_M_data.clear(); _local_K_data.clear(); _local_b_data.clear(); _local_Jac_data.clear(); std::size_t const number_of_processes = x.size(); // Monolithic scheme if (number_of_processes == 1) { auto const local_x = x[process_id]->get(indices); auto const local_xdot = xdot[process_id]->get(indices); _jacobian_assembler->assembleWithJacobian( local_assembler, t, dt, local_x, local_xdot, dxdot_dx, dx_dx, _local_M_data, _local_K_data, _local_b_data, _local_Jac_data); } else // Staggered scheme { auto local_coupled_xs = getCoupledLocalSolutions(x, indices_of_processes); auto const local_x = MathLib::toVector(local_coupled_xs); auto local_coupled_xdots = getCoupledLocalSolutions(xdot, indices_of_processes); auto const local_xdot = MathLib::toVector(local_coupled_xdots); _jacobian_assembler->assembleWithJacobianForStaggeredScheme( local_assembler, t, dt, local_x, local_xdot, dxdot_dx, dx_dx, process_id, _local_M_data, _local_K_data, _local_b_data, _local_Jac_data); } auto const num_r_c = indices.size(); auto const r_c_indices = NumLib::LocalToGlobalIndexMap::RowColumnIndices(indices, indices); if (!_local_M_data.empty()) { auto const local_M = MathLib::toMatrix(_local_M_data, num_r_c, num_r_c); M.add(r_c_indices, local_M); } if (!_local_K_data.empty()) { auto const local_K = MathLib::toMatrix(_local_K_data, num_r_c, num_r_c); K.add(r_c_indices, local_K); } if (!_local_b_data.empty()) { assert(_local_b_data.size() == num_r_c); b.add(indices, _local_b_data); } if (!_local_Jac_data.empty()) { auto const local_Jac = MathLib::toMatrix(_local_Jac_data, num_r_c, num_r_c); Jac.add(r_c_indices, local_Jac); } else { OGS_FATAL( "No Jacobian has been assembled! This might be due to programming " "errors in the local assembler of the current process."); } } } // namespace ProcessLib