OGS: ProcessLib/ComponentTransport/ComponentTransportFEM.h Source File

#pragma once


#include <numeric>

#include <vector>


#include "ChemistryLib/ChemicalSolverInterface.h"

#include "ComponentTransportProcessData.h"

#include "MaterialLib/MPL/MaterialSpatialDistributionMap.h"

#include "MaterialLib/MPL/Medium.h"

#include "MaterialLib/MPL/Property.h"

#include "MaterialLib/MPL/Utils/FormEigenTensor.h"

#include "MathLib/LinAlg/Eigen/EigenMapTools.h"

#include "NumLib/DOF/DOFTableUtil.h"

#include "NumLib/Extrapolation/ExtrapolatableElement.h"

#include "NumLib/Fem/FiniteElement/TemplateIsoparametric.h"

#include "NumLib/Fem/InitShapeMatrices.h"

#include "NumLib/Fem/Integration/GenericIntegrationMethod.h"

#include "NumLib/Fem/ShapeMatrixPolicy.h"

#include "NumLib/Function/Interpolation.h"

#include "NumLib/NumericalStability/AdvectionMatrixAssembler.h"

#include "NumLib/NumericalStability/HydrodynamicDispersion.h"

#include "ParameterLib/Parameter.h"

#include "ProcessLib/LocalAssemblerInterface.h"

#include "ProcessLib/ProcessVariable.h"


namespace ProcessLib

{

namespace ComponentTransport

{

template <typename NodalRowVectorType, typename GlobalDimNodalMatrixType>

struct IntegrationPointData final

{

    IntegrationPointData(NodalRowVectorType const& N_,

                         GlobalDimNodalMatrixType const& dNdx_,

                         double const& integration_weight_)

        : N(N_), dNdx(dNdx_), integration_weight(integration_weight_)

    {

    }


    void pushBackState() { porosity_prev = porosity; }

    NodalRowVectorType const N;

    GlobalDimNodalMatrixType const dNdx;

    double const integration_weight;


    // -1 indicates that no chemical reaction takes place in the element to

    // which the integration point belongs.

    GlobalIndexType chemical_system_id = -1;


    double porosity = std::numeric_limits<double>::quiet_NaN();

    double porosity_prev = std::numeric_limits<double>::quiet_NaN();

    EIGEN_MAKE_ALIGNED_OPERATOR_NEW;

};


class ComponentTransportLocalAssemblerInterface

    : public ProcessLib::LocalAssemblerInterface,

      public NumLib::ExtrapolatableElement

{

public:

    ComponentTransportLocalAssemblerInterface() = default;


    virtual void setChemicalSystemID(std::size_t const /*mesh_item_id*/) = 0;


    void initializeChemicalSystem(

        std::size_t const mesh_item_id,

        std::vector<NumLib::LocalToGlobalIndexMap const*> const& dof_tables,

        std::vector<GlobalVector*> const& x, double const t)

    {

        std::vector<double> local_x_vec;


        auto const n_processes = x.size();

        for (std::size_t process_id = 0; process_id < n_processes; ++process_id)

        {

            auto const indices =

                NumLib::getIndices(mesh_item_id, *dof_tables[process_id]);

            assert(!indices.empty());

            auto const local_solution = x[process_id]->get(indices);

            local_x_vec.insert(std::end(local_x_vec),

                               std::begin(local_solution),

                               std::end(local_solution));

        }

        auto const local_x = MathLib::toVector(local_x_vec);


        initializeChemicalSystemConcrete(local_x, t);

    }


    void setChemicalSystem(

        std::size_t const mesh_item_id,

        std::vector<NumLib::LocalToGlobalIndexMap const*> const& dof_tables,

        std::vector<GlobalVector*> const& x, double const t, double const dt)

    {

        std::vector<double> local_x_vec;


        auto const n_processes = x.size();

        for (std::size_t process_id = 0; process_id < n_processes; ++process_id)

        {

            auto const indices =

                NumLib::getIndices(mesh_item_id, *dof_tables[process_id]);

            assert(!indices.empty());

            auto const local_solution = x[process_id]->get(indices);

            local_x_vec.insert(std::end(local_x_vec),

                               std::begin(local_solution),

                               std::end(local_solution));

        }

        auto const local_x = MathLib::toVector(local_x_vec);


        setChemicalSystemConcrete(local_x, t, dt);

    }


    void assembleReactionEquation(

        std::size_t const mesh_item_id,

        std::vector<NumLib::LocalToGlobalIndexMap const*> const& dof_tables,

        std::vector<GlobalVector*> const& x, double const t, double const dt,

        GlobalMatrix& M, GlobalMatrix& K, GlobalVector& b, int const process_id)

    {

        std::vector<double> local_x_vec;


        auto const n_processes = x.size();

        for (std::size_t pcs_id = 0; pcs_id < n_processes; ++pcs_id)

        {

            auto const indices =

                NumLib::getIndices(mesh_item_id, *dof_tables[pcs_id]);

            assert(!indices.empty());

            auto const local_solution = x[pcs_id]->get(indices);

            local_x_vec.insert(std::end(local_x_vec),

                               std::begin(local_solution),

                               std::end(local_solution));

        }

        auto const local_x = MathLib::toVector(local_x_vec);


        auto const indices =

            NumLib::getIndices(mesh_item_id, *dof_tables[process_id]);

        auto const num_r_c = indices.size();


        std::vector<double> local_M_data;

        local_M_data.reserve(num_r_c * num_r_c);

        std::vector<double> local_K_data;

        local_K_data.reserve(num_r_c * num_r_c);

        std::vector<double> local_b_data;

        local_b_data.reserve(num_r_c);


        assembleReactionEquationConcrete(t, dt, local_x, local_M_data,

                                         local_K_data, local_b_data,

                                         process_id);


        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())

        {

            b.add(indices, local_b_data);

        }

    }


    virtual void postSpeciationCalculation(std::size_t const ele_id,

                                           double const t, double const dt) = 0;


    virtual void computeReactionRelatedSecondaryVariable(

        std::size_t const ele_id) = 0;


    virtual std::vector<double> const& getIntPtDarcyVelocity(

        const double t,

        std::vector<GlobalVector*> const& x,

        std::vector<NumLib::LocalToGlobalIndexMap const*> const& dof_table,

        std::vector<double>& cache) const = 0;


    virtual std::vector<double> const& getIntPtMolarFlux(

        const double t,

        std::vector<GlobalVector*> const& x,

        std::vector<NumLib::LocalToGlobalIndexMap const*> const& dof_table,

        std::vector<double>& cache) const = 0;


private:

    virtual void initializeChemicalSystemConcrete(

        Eigen::VectorXd const& /*local_x*/, double const /*t*/) = 0;


    virtual void setChemicalSystemConcrete(Eigen::VectorXd const& /*local_x*/,

                                           double const /*t*/,

                                           double const /*dt*/) = 0;


    virtual void assembleReactionEquationConcrete(

        double const t, double const dt, Eigen::VectorXd const& local_x,

        std::vector<double>& local_M_data, std::vector<double>& local_K_data,

        std::vector<double>& local_b_data, int const transport_process_id) = 0;

};


template <typename ShapeFunction, int GlobalDim>

class LocalAssemblerData : public ComponentTransportLocalAssemblerInterface

{

    // When monolithic scheme is adopted, nodal pressure and nodal concentration

    // are accessed by vector index.

    static const int pressure_index = 0;

    static const int first_concentration_index = ShapeFunction::NPOINTS;


    static const int pressure_size = ShapeFunction::NPOINTS;

    static const int concentration_size =

        ShapeFunction::NPOINTS;  // per component


    using ShapeMatricesType = ShapeMatrixPolicyType<ShapeFunction, GlobalDim>;

    using ShapeMatrices = typename ShapeMatricesType::ShapeMatrices;


    using LocalBlockMatrixType =

        typename ShapeMatricesType::template MatrixType<pressure_size,

                                                        pressure_size>;

    using LocalSegmentVectorType =

        typename ShapeMatricesType::template VectorType<pressure_size>;


    using LocalMatrixType =

        Eigen::Matrix<double, Eigen::Dynamic, Eigen::Dynamic, Eigen::RowMajor>;

    using LocalVectorType = Eigen::Matrix<double, Eigen::Dynamic, 1>;


    using NodalVectorType = typename ShapeMatricesType::NodalVectorType;

    using NodalRowVectorType = typename ShapeMatricesType::NodalRowVectorType;


    using GlobalDimVectorType = typename ShapeMatricesType::GlobalDimVectorType;

    using GlobalDimNodalMatrixType =

        typename ShapeMatricesType::GlobalDimNodalMatrixType;

    using GlobalDimMatrixType = typename ShapeMatricesType::GlobalDimMatrixType;


public:

    LocalAssemblerData(

        MeshLib::Element const& element,

        std::size_t const local_matrix_size,

        NumLib::GenericIntegrationMethod const& integration_method,

        bool is_axially_symmetric,

        ComponentTransportProcessData const& process_data,

        std::vector<std::reference_wrapper<ProcessVariable>> const&

            transport_process_variables)

        : _element(element),

          _process_data(process_data),

          _integration_method(integration_method),

          _transport_process_variables(transport_process_variables)

    {

        (void)local_matrix_size;


        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();

        _ip_data.reserve(n_integration_points);


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());


        double const aperture_size = _process_data.aperture_size(0.0, pos)[0];


        auto const shape_matrices =

            NumLib::initShapeMatrices<ShapeFunction, ShapeMatricesType,

                                      GlobalDim>(element, is_axially_symmetric,

                                                 _integration_method);

        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());

        for (unsigned ip = 0; ip < n_integration_points; ip++)

        {

            _ip_data.emplace_back(

                shape_matrices[ip].N, shape_matrices[ip].dNdx,

                _integration_method.getWeightedPoint(ip).getWeight() *

                    shape_matrices[ip].integralMeasure *

                    shape_matrices[ip].detJ * aperture_size);


            pos.setIntegrationPoint(ip);


            _ip_data[ip].porosity =

                medium[MaterialPropertyLib::PropertyType::porosity]

                    .template initialValue<double>(

                        pos, std::numeric_limits<double>::quiet_NaN() /*t*/);


            _ip_data[ip].pushBackState();

        }

    }


    void setChemicalSystemID(std::size_t const /*mesh_item_id*/) override

    {

        assert(_process_data.chemical_solver_interface);

        // chemical system index map

        auto& chemical_system_index_map =

            _process_data.chemical_solver_interface->chemical_system_index_map;


        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();

        for (unsigned ip = 0; ip < n_integration_points; ip++)

        {

            _ip_data[ip].chemical_system_id =

                chemical_system_index_map.empty()

                    ? 0

                    : chemical_system_index_map.back() + 1;

            chemical_system_index_map.push_back(

                _ip_data[ip].chemical_system_id);

        }

    }


    void initializeChemicalSystemConcrete(Eigen::VectorXd const& local_x,

                                          double const t) override

    {

        assert(_process_data.chemical_solver_interface);


        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());


        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();

        for (unsigned ip = 0; ip < n_integration_points; ip++)

        {

            auto& ip_data = _ip_data[ip];

            auto const& N = ip_data.N;

            auto const& chemical_system_id = ip_data.chemical_system_id;


            auto const n_component = _transport_process_variables.size();

            std::vector<double> C_int_pt(n_component);

            for (unsigned component_id = 0; component_id < n_component;

                 ++component_id)

            {

                auto const concentration_index =

                    first_concentration_index +

                    component_id * concentration_size;

                auto const local_C =

                    local_x.template segment<concentration_size>(

                        concentration_index);


                NumLib::shapeFunctionInterpolate(local_C, N,

                                                 C_int_pt[component_id]);

            }


            _process_data.chemical_solver_interface

                ->initializeChemicalSystemConcrete(C_int_pt, chemical_system_id,

                                                   medium, pos, t);

        }

    }


    void setChemicalSystemConcrete(Eigen::VectorXd const& local_x,

                                   double const t, double dt) override

    {

        assert(_process_data.chemical_solver_interface);


        auto const& medium =

            _process_data.media_map.getMedium(_element.getID());


        MaterialPropertyLib::VariableArray vars;

        MaterialPropertyLib::VariableArray vars_prev;


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());


        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();

        for (unsigned ip = 0; ip < n_integration_points; ip++)

        {

            auto& ip_data = _ip_data[ip];

            auto const& N = ip_data.N;

            auto& porosity = ip_data.porosity;

            auto const& porosity_prev = ip_data.porosity_prev;

            auto const& chemical_system_id = ip_data.chemical_system_id;


            auto const n_component = _transport_process_variables.size();

            std::vector<double> C_int_pt(n_component);

            for (unsigned component_id = 0; component_id < n_component;

                 ++component_id)

            {

                auto const concentration_index =

                    first_concentration_index +

                    component_id * concentration_size;

                auto const local_C =

                    local_x.template segment<concentration_size>(

                        concentration_index);


                NumLib::shapeFunctionInterpolate(local_C, N,

                                                 C_int_pt[component_id]);

            }


            {

                vars_prev.porosity = porosity_prev;


                porosity =

                    _process_data.chemically_induced_porosity_change

                        ? porosity_prev

                        : medium

                              ->property(

                                  MaterialPropertyLib::PropertyType::porosity)

                              .template value<double>(vars, vars_prev, pos, t,

                                                      dt);


                vars.porosity = porosity;

            }


            _process_data.chemical_solver_interface->setChemicalSystemConcrete(

                C_int_pt, chemical_system_id, medium, vars, pos, t, dt);

        }

    }


    void postSpeciationCalculation(std::size_t const ele_id, double const t,

                                   double const dt) override

    {

        if (!_process_data.chemically_induced_porosity_change)

        {

            return;

        }


        auto const& medium = *_process_data.media_map.getMedium(ele_id);


        ParameterLib::SpatialPosition pos;

        pos.setElementID(ele_id);


        for (auto& ip_data : _ip_data)

        {

            ip_data.porosity = ip_data.porosity_prev;


            _process_data.chemical_solver_interface

                ->updateVolumeFractionPostReaction(ip_data.chemical_system_id,

                                                   medium, pos,

                                                   ip_data.porosity, t, dt);


            _process_data.chemical_solver_interface->updatePorosityPostReaction(

                ip_data.chemical_system_id, medium, ip_data.porosity);

        }

    }


    void assemble(double const t, double const dt,

                  std::vector<double> const& local_x,

                  std::vector<double> const& /*local_x_prev*/,

                  std::vector<double>& local_M_data,

                  std::vector<double>& local_K_data,

                  std::vector<double>& local_b_data) override

    {

        auto const local_matrix_size = local_x.size();

        // Nodal DOFs include pressure

        int const num_nodal_dof = 1 + _transport_process_variables.size();

        // This assertion is valid only if all nodal d.o.f. use the same shape

        // matrices.

        assert(local_matrix_size == ShapeFunction::NPOINTS * num_nodal_dof);


        auto local_M = MathLib::createZeroedMatrix<LocalMatrixType>(

            local_M_data, local_matrix_size, local_matrix_size);

        auto local_K = MathLib::createZeroedMatrix<LocalMatrixType>(

            local_K_data, local_matrix_size, local_matrix_size);

        auto local_b = MathLib::createZeroedVector<LocalVectorType>(

            local_b_data, local_matrix_size);


        // Get block matrices

        auto Kpp = local_K.template block<pressure_size, pressure_size>(

            pressure_index, pressure_index);

        auto Mpp = local_M.template block<pressure_size, pressure_size>(

            pressure_index, pressure_index);

        auto Bp = local_b.template segment<pressure_size>(pressure_index);


        auto local_p = Eigen::Map<const NodalVectorType>(

            &local_x[pressure_index], pressure_size);


        auto const& b =

            _process_data

                .projected_specific_body_force_vectors[_element.getID()];


        auto const number_of_components = num_nodal_dof - 1;

        for (int component_id = 0; component_id < number_of_components;

             ++component_id)

        {

            /*  Partitioned assembler matrix

             *  |  pp | pc1 | pc2 | pc3 |

             *  |-----|-----|-----|-----|

             *  | c1p | c1c1|  0  |  0  |

             *  |-----|-----|-----|-----|

             *  | c2p |  0  | c2c2|  0  |

             *  |-----|-----|-----|-----|

             *  | c3p |  0  |  0  | c3c3|

             */

            auto concentration_index =

                pressure_size + component_id * concentration_size;


            auto KCC =

                local_K.template block<concentration_size, concentration_size>(

                    concentration_index, concentration_index);

            auto MCC =

                local_M.template block<concentration_size, concentration_size>(

                    concentration_index, concentration_index);

            auto MCp =

                local_M.template block<concentration_size, pressure_size>(

                    concentration_index, pressure_index);

            auto MpC =

                local_M.template block<pressure_size, concentration_size>(

                    pressure_index, concentration_index);


            auto local_C = Eigen::Map<const NodalVectorType>(

                &local_x[concentration_index], concentration_size);


            assembleBlockMatrices(b, component_id, t, dt, local_C, local_p, KCC,

                                  MCC, MCp, MpC, Kpp, Mpp, Bp);


            if (_process_data.chemical_solver_interface)

            {

                auto const stoichiometric_matrix =

                    _process_data.chemical_solver_interface

                        ->getStoichiometricMatrix();


                assert(stoichiometric_matrix);


                for (Eigen::SparseMatrix<double>::InnerIterator it(

                         *stoichiometric_matrix, component_id);

                     it;

                     ++it)

                {

                    auto const stoichiometric_coefficient = it.value();

                    auto const coupled_component_id = it.row();

                    auto const kinetic_prefactor =

                        _process_data.chemical_solver_interface

                            ->getKineticPrefactor(coupled_component_id);


                    auto const concentration_index =

                        pressure_size + component_id * concentration_size;

                    auto const coupled_concentration_index =

                        pressure_size +

                        coupled_component_id * concentration_size;

                    auto KCmCn = local_K.template block<concentration_size,

                                                        concentration_size>(

                        concentration_index, coupled_concentration_index);


                    // account for the coupling between components

                    assembleKCmCn(component_id, t, dt, KCmCn,

                                  stoichiometric_coefficient,

                                  kinetic_prefactor);

                }

            }

        }

    }


    void assembleBlockMatrices(

        GlobalDimVectorType const& b, int const component_id, double const t,

        double const dt,

        Eigen::Ref<const NodalVectorType> const& C_nodal_values,

        Eigen::Ref<const NodalVectorType> const& p_nodal_values,

        Eigen::Ref<LocalBlockMatrixType> KCC,

        Eigen::Ref<LocalBlockMatrixType> MCC,

        Eigen::Ref<LocalBlockMatrixType> MCp,

        Eigen::Ref<LocalBlockMatrixType> MpC,

        Eigen::Ref<LocalBlockMatrixType> Kpp,

        Eigen::Ref<LocalBlockMatrixType> Mpp,

        Eigen::Ref<LocalSegmentVectorType> Bp)

    {

        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());


        MaterialPropertyLib::VariableArray vars;


        // Get material properties

        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());

        // Select the only valid for component transport liquid phase.

        auto const& phase = medium.phase("AqueousLiquid");


        // Assume that the component name is the same as the process variable

        // name. Components are shifted by one because the first one is always

        // pressure.

        auto const& component = phase.component(

            _transport_process_variables[component_id].get().getName());


        LocalBlockMatrixType KCC_Laplacian =

            LocalBlockMatrixType::Zero(concentration_size, concentration_size);


        std::vector<GlobalDimVectorType> ip_flux_vector;

        double average_velocity_norm = 0.0;

        if (!_process_data.non_advective_form)

        {

            ip_flux_vector.reserve(n_integration_points);

        }


        for (unsigned ip(0); ip < n_integration_points; ++ip)

        {

            pos.setIntegrationPoint(ip);


            auto& ip_data = _ip_data[ip];

            auto const& N = ip_data.N;

            auto const& dNdx = ip_data.dNdx;

            auto const& w = ip_data.integration_weight;

            auto& porosity = ip_data.porosity;


            double C_int_pt = 0.0;

            double p_int_pt = 0.0;


            NumLib::shapeFunctionInterpolate(C_nodal_values, N, C_int_pt);

            NumLib::shapeFunctionInterpolate(p_nodal_values, N, p_int_pt);


            vars.concentration = C_int_pt;

            vars.phase_pressure = p_int_pt;


            // update according to a particular porosity model

            porosity = medium[MaterialPropertyLib::PropertyType::porosity]

                           .template value<double>(vars, pos, t, dt);

            vars.porosity = porosity;


            auto const& retardation_factor =

                component[MaterialPropertyLib::PropertyType::retardation_factor]

                    .template value<double>(vars, pos, t, dt);


            auto const& solute_dispersivity_transverse = medium.template value<

                double>(

                MaterialPropertyLib::PropertyType::transversal_dispersivity);


            auto const& solute_dispersivity_longitudinal =

                medium.template value<double>(

                    MaterialPropertyLib::PropertyType::

                        longitudinal_dispersivity);


            // Use the fluid density model to compute the density

            // TODO (renchao): concentration of which component as the argument

            // for calculation of fluid density

            auto const density =

                phase[MaterialPropertyLib::PropertyType::density]

                    .template value<double>(vars, pos, t, dt);


            auto const decay_rate =

                component[MaterialPropertyLib::PropertyType::decay_rate]

                    .template value<double>(vars, pos, t, dt);


            auto const& pore_diffusion_coefficient =

                MaterialPropertyLib::formEigenTensor<GlobalDim>(

                    component[MaterialPropertyLib::PropertyType::pore_diffusion]

                        .value(vars, pos, t, dt));


            auto const& K = MaterialPropertyLib::formEigenTensor<GlobalDim>(

                medium[MaterialPropertyLib::PropertyType::permeability].value(

                    vars, pos, t, dt));


            // Use the viscosity model to compute the viscosity

            auto const mu = phase[MaterialPropertyLib::PropertyType::viscosity]

                                .template value<double>(vars, pos, t, dt);


            GlobalDimMatrixType const K_over_mu = K / mu;

            GlobalDimVectorType const velocity =

                _process_data.has_gravity

                    ? GlobalDimVectorType(-K_over_mu *

                                          (dNdx * p_nodal_values - density * b))

                    : GlobalDimVectorType(-K_over_mu * dNdx * p_nodal_values);


            const double drho_dp =

                phase[MaterialPropertyLib::PropertyType::density]

                    .template dValue<double>(

                        vars, MaterialPropertyLib::Variable::phase_pressure,

                        pos, t, dt);


            const double drho_dC =

                phase[MaterialPropertyLib::PropertyType::density]

                    .template dValue<double>(

                        vars, MaterialPropertyLib::Variable::concentration, pos,

                        t, dt);


            GlobalDimMatrixType const hydrodynamic_dispersion =

                NumLib::computeHydrodynamicDispersion(

                    _process_data.stabilizer, _element.getID(),

                    pore_diffusion_coefficient, velocity, porosity,

                    solute_dispersivity_transverse,

                    solute_dispersivity_longitudinal);


            const double R_times_phi(retardation_factor * porosity);

            GlobalDimVectorType const mass_density_flow = velocity * density;

            auto const N_t_N = (N.transpose() * N).eval();


            if (_process_data.non_advective_form)

            {

                MCp.noalias() += N_t_N * (C_int_pt * R_times_phi * drho_dp * w);

                MCC.noalias() += N_t_N * (C_int_pt * R_times_phi * drho_dC * w);

                KCC.noalias() -= dNdx.transpose() * mass_density_flow * N * w;

            }

            else

            {

                ip_flux_vector.emplace_back(mass_density_flow);

                average_velocity_norm += velocity.norm();

            }

            MCC.noalias() += N_t_N * (R_times_phi * density * w);

            KCC.noalias() += N_t_N * (decay_rate * R_times_phi * density * w);

            KCC_Laplacian.noalias() +=

                dNdx.transpose() * hydrodynamic_dispersion * dNdx * density * w;


            MpC.noalias() += N_t_N * (porosity * drho_dC * w);


            // Calculate Mpp, Kpp, and bp in the first loop over components

            if (component_id == 0)

            {

                Mpp.noalias() += N_t_N * (porosity * drho_dp * w);

                Kpp.noalias() +=

                    dNdx.transpose() * K_over_mu * dNdx * (density * w);


                if (_process_data.has_gravity)

                {

                    Bp.noalias() += dNdx.transpose() * K_over_mu * b *

                                    (density * density * w);

                }

            }

        }


        if (!_process_data.non_advective_form)

        {

            NumLib::assembleAdvectionMatrix(

                _process_data.stabilizer,

                _ip_data,

                ip_flux_vector,

                average_velocity_norm /

                    static_cast<double>(n_integration_points),

                KCC_Laplacian);

        }


        KCC.noalias() += KCC_Laplacian;

    }


    void assembleKCmCn(int const component_id, double const t, double const dt,

                       Eigen::Ref<LocalBlockMatrixType> KCmCn,

                       double const stoichiometric_coefficient,

                       double const kinetic_prefactor)

    {

        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());


        MaterialPropertyLib::VariableArray vars;


        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());

        auto const& phase = medium.phase("AqueousLiquid");

        auto const& component = phase.component(

            _transport_process_variables[component_id].get().getName());


        for (unsigned ip(0); ip < n_integration_points; ++ip)

        {

            auto& ip_data = _ip_data[ip];

            auto const& N = ip_data.N;

            auto const& w = ip_data.integration_weight;

            auto& porosity = ip_data.porosity;


            auto const retardation_factor =

                component[MaterialPropertyLib::PropertyType::retardation_factor]

                    .template value<double>(vars, pos, t, dt);


            porosity = medium[MaterialPropertyLib::PropertyType::porosity]

                           .template value<double>(vars, pos, t, dt);


            auto const density =

                phase[MaterialPropertyLib::PropertyType::density]

                    .template value<double>(vars, pos, t, dt);


            KCmCn.noalias() -= w * N.transpose() * stoichiometric_coefficient *

                               kinetic_prefactor * retardation_factor *

                               porosity * density * N;

        }

    }


    void assembleForStaggeredScheme(double const t, double const dt,

                                    Eigen::VectorXd const& local_x,

                                    Eigen::VectorXd const& local_x_prev,

                                    int const process_id,

                                    std::vector<double>& local_M_data,

                                    std::vector<double>& local_K_data,

                                    std::vector<double>& local_b_data) override

    {

        if (process_id == _process_data.hydraulic_process_id)

        {

            assembleHydraulicEquation(t, dt, local_x, local_x_prev,

                                      local_M_data, local_K_data, local_b_data);

        }

        else

        {

            // Go for assembling in an order of transport process id.

            assembleComponentTransportEquation(t, dt, local_x, local_x_prev,

                                               local_M_data, local_K_data,

                                               local_b_data, process_id);

        }

    }


    void assembleHydraulicEquation(double const t,

                                   double const dt,

                                   Eigen::VectorXd const& local_x,

                                   Eigen::VectorXd const& local_x_prev,

                                   std::vector<double>& local_M_data,

                                   std::vector<double>& local_K_data,

                                   std::vector<double>& local_b_data)

    {

        auto const local_p =

            local_x.template segment<pressure_size>(pressure_index);

        auto const local_C = local_x.template segment<concentration_size>(

            first_concentration_index);

        auto const local_C_prev =

            local_x_prev.segment<concentration_size>(first_concentration_index);


        auto local_M = MathLib::createZeroedMatrix<LocalBlockMatrixType>(

            local_M_data, pressure_size, pressure_size);

        auto local_K = MathLib::createZeroedMatrix<LocalBlockMatrixType>(

            local_K_data, pressure_size, pressure_size);

        auto local_b = MathLib::createZeroedVector<LocalSegmentVectorType>(

            local_b_data, pressure_size);


        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());


        auto const& b =

            _process_data

                .projected_specific_body_force_vectors[_element.getID()];


        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());

        auto const& phase = medium.phase("AqueousLiquid");


        MaterialPropertyLib::VariableArray vars;

        MaterialPropertyLib::VariableArray vars_prev;


        for (unsigned ip(0); ip < n_integration_points; ++ip)

        {

            pos.setIntegrationPoint(ip);


            auto& ip_data = _ip_data[ip];

            auto const& N = ip_data.N;

            auto const& dNdx = ip_data.dNdx;

            auto const& w = ip_data.integration_weight;

            auto& porosity = ip_data.porosity;

            auto const& porosity_prev = ip_data.porosity_prev;


            double C_int_pt = 0.0;

            double p_int_pt = 0.0;


            NumLib::shapeFunctionInterpolate(local_C, N, C_int_pt);

            NumLib::shapeFunctionInterpolate(local_p, N, p_int_pt);


            vars.concentration = C_int_pt;

            vars.phase_pressure = p_int_pt;


            //  porosity

            {

                vars_prev.porosity = porosity_prev;


                porosity =

                    _process_data.chemically_induced_porosity_change

                        ? porosity_prev

                        : medium[MaterialPropertyLib::PropertyType::porosity]

                              .template value<double>(vars, vars_prev, pos, t,

                                                      dt);


                vars.porosity = porosity;

            }


            // Use the fluid density model to compute the density

            // TODO: Concentration of which component as one of arguments for

            // calculation of fluid density

            auto const density =

                phase[MaterialPropertyLib::PropertyType::density]

                    .template value<double>(vars, pos, t, dt);


            auto const& K = MaterialPropertyLib::formEigenTensor<GlobalDim>(

                medium[MaterialPropertyLib::PropertyType::permeability].value(

                    vars, pos, t, dt));


            // Use the viscosity model to compute the viscosity

            auto const mu = phase[MaterialPropertyLib::PropertyType::viscosity]

                                .template value<double>(vars, pos, t, dt);


            GlobalDimMatrixType const K_over_mu = K / mu;


            const double drho_dp =

                phase[MaterialPropertyLib::PropertyType::density]

                    .template dValue<double>(

                        vars, MaterialPropertyLib::Variable::phase_pressure,

                        pos, t, dt);

            const double drho_dC =

                phase[MaterialPropertyLib::PropertyType::density]

                    .template dValue<double>(

                        vars, MaterialPropertyLib::Variable::concentration, pos,

                        t, dt);


            // matrix assembly

            local_M.noalias() += w * N.transpose() * porosity * drho_dp * N;

            local_K.noalias() +=

                w * dNdx.transpose() * density * K_over_mu * dNdx;


            if (_process_data.has_gravity)

            {

                local_b.noalias() +=

                    w * density * density * dNdx.transpose() * K_over_mu * b;

            }


            // coupling term

            {

                double const C_dot = (C_int_pt - N.dot(local_C_prev)) / dt;


                local_b.noalias() -=

                    w * N.transpose() * porosity * drho_dC * C_dot;

            }

        }

    }


    void assembleComponentTransportEquation(

        double const t, double const dt, Eigen::VectorXd const& local_x,

        Eigen::VectorXd const& local_x_prev, std::vector<double>& local_M_data,

        std::vector<double>& local_K_data,

        std::vector<double>& /*local_b_data*/, int const transport_process_id)

    {

        auto const local_p =

            local_x.template segment<pressure_size>(pressure_index);

        auto const local_C = local_x.template segment<concentration_size>(

            first_concentration_index +

            (transport_process_id - 1) * concentration_size);

        auto const local_p_prev =

            local_x_prev.segment<pressure_size>(pressure_index);


        NodalVectorType local_T;

        if (_process_data.temperature)

        {

            local_T =

                _process_data.temperature->getNodalValuesOnElement(_element, t);

        }


        auto local_M = MathLib::createZeroedMatrix<LocalBlockMatrixType>(

            local_M_data, concentration_size, concentration_size);

        auto local_K = MathLib::createZeroedMatrix<LocalBlockMatrixType>(

            local_K_data, concentration_size, concentration_size);


        LocalBlockMatrixType KCC_Laplacian =

            LocalBlockMatrixType::Zero(concentration_size, concentration_size);


        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();


        std::vector<GlobalDimVectorType> ip_flux_vector;

        double average_velocity_norm = 0.0;

        if (!_process_data.non_advective_form)

        {

            ip_flux_vector.reserve(n_integration_points);

        }


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());


        auto const& b =

            _process_data

                .projected_specific_body_force_vectors[_element.getID()];


        MaterialPropertyLib::VariableArray vars;

        MaterialPropertyLib::VariableArray vars_prev;


        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());

        auto const& phase = medium.phase("AqueousLiquid");

        // Hydraulic process id is 0 and thus transport process id starts

        // from 1.

        auto const component_id = transport_process_id - 1;

        auto const& component = phase.component(

            _transport_process_variables[component_id].get().getName());


        for (unsigned ip(0); ip < n_integration_points; ++ip)

        {

            pos.setIntegrationPoint(ip);


            auto& ip_data = _ip_data[ip];

            auto const& N = ip_data.N;

            auto const& dNdx = ip_data.dNdx;

            auto const& w = ip_data.integration_weight;

            auto& porosity = ip_data.porosity;

            auto const& porosity_prev = ip_data.porosity_prev;


            double C_int_pt = 0.0;

            double p_int_pt = 0.0;


            NumLib::shapeFunctionInterpolate(local_C, N, C_int_pt);

            NumLib::shapeFunctionInterpolate(local_p, N, p_int_pt);


            vars.concentration = C_int_pt;

            vars.phase_pressure = p_int_pt;


            if (_process_data.temperature)

            {

                vars.temperature = N.dot(local_T);

            }


            // porosity

            {

                vars_prev.porosity = porosity_prev;


                porosity =

                    _process_data.chemically_induced_porosity_change

                        ? porosity_prev

                        : medium[MaterialPropertyLib::PropertyType::porosity]

                              .template value<double>(vars, vars_prev, pos, t,

                                                      dt);


                vars.porosity = porosity;

            }


            auto const& retardation_factor =

                component[MaterialPropertyLib::PropertyType::retardation_factor]

                    .template value<double>(vars, pos, t, dt);


            auto const& solute_dispersivity_transverse = medium.template value<

                double>(

                MaterialPropertyLib::PropertyType::transversal_dispersivity);

            auto const& solute_dispersivity_longitudinal =

                medium.template value<double>(

                    MaterialPropertyLib::PropertyType::

                        longitudinal_dispersivity);


            // Use the fluid density model to compute the density

            auto const density =

                phase[MaterialPropertyLib::PropertyType::density]

                    .template value<double>(vars, pos, t, dt);

            auto const decay_rate =

                component[MaterialPropertyLib::PropertyType::decay_rate]

                    .template value<double>(vars, pos, t, dt);


            auto const& pore_diffusion_coefficient =

                MaterialPropertyLib::formEigenTensor<GlobalDim>(

                    component[MaterialPropertyLib::PropertyType::pore_diffusion]

                        .value(vars, pos, t, dt));


            auto const& K = MaterialPropertyLib::formEigenTensor<GlobalDim>(

                medium[MaterialPropertyLib::PropertyType::permeability].value(

                    vars, pos, t, dt));

            // Use the viscosity model to compute the viscosity

            auto const mu = phase[MaterialPropertyLib::PropertyType::viscosity]

                                .template value<double>(vars, pos, t, dt);


            GlobalDimMatrixType const K_over_mu = K / mu;

            GlobalDimVectorType const velocity =

                _process_data.has_gravity

                    ? GlobalDimVectorType(-K_over_mu *

                                          (dNdx * local_p - density * b))

                    : GlobalDimVectorType(-K_over_mu * dNdx * local_p);


            GlobalDimMatrixType const hydrodynamic_dispersion =

                NumLib::computeHydrodynamicDispersion(

                    _process_data.stabilizer, _element.getID(),

                    pore_diffusion_coefficient, velocity, porosity,

                    solute_dispersivity_transverse,

                    solute_dispersivity_longitudinal);


            double const R_times_phi = retardation_factor * porosity;

            auto const N_t_N = (N.transpose() * N).eval();


            if (_process_data.non_advective_form)

            {

                const double drho_dC =

                    phase[MaterialPropertyLib::PropertyType::density]

                        .template dValue<double>(

                            vars, MaterialPropertyLib::Variable::concentration,

                            pos, t, dt);

                local_M.noalias() +=

                    N_t_N * (R_times_phi * C_int_pt * drho_dC * w);

            }


            local_M.noalias() += N_t_N * (R_times_phi * density * w);


            // coupling term

            if (_process_data.non_advective_form)

            {

                double const p_dot = (p_int_pt - N.dot(local_p_prev)) / dt;


                const double drho_dp =

                    phase[MaterialPropertyLib::PropertyType::density]

                        .template dValue<double>(

                            vars, MaterialPropertyLib::Variable::phase_pressure,

                            pos, t, dt);


                local_K.noalias() +=

                    N_t_N * ((R_times_phi * drho_dp * p_dot) * w) -

                    dNdx.transpose() * velocity * N * (density * w);

            }

            else

            {

                ip_flux_vector.emplace_back(velocity * density);

                average_velocity_norm += velocity.norm();

            }

            local_K.noalias() +=

                N_t_N * (decay_rate * R_times_phi * density * w);


            KCC_Laplacian.noalias() += dNdx.transpose() *

                                       hydrodynamic_dispersion * dNdx *

                                       (density * w);

        }


        if (!_process_data.non_advective_form)

        {

            NumLib::assembleAdvectionMatrix(

                _process_data.stabilizer,

                _ip_data,

                ip_flux_vector,

                average_velocity_norm /

                    static_cast<double>(n_integration_points),

                KCC_Laplacian);

        }

        local_K.noalias() += KCC_Laplacian;

    }


    void assembleWithJacobianForStaggeredScheme(

        double const t, double const dt, Eigen::VectorXd const& local_x,

        Eigen::VectorXd const& local_x_prev, int const process_id,

        std::vector<double>& /*local_M_data*/,

        std::vector<double>& /*local_K_data*/,

        std::vector<double>& local_b_data,

        std::vector<double>& local_Jac_data) override

    {

        if (process_id == _process_data.hydraulic_process_id)

        {

            assembleWithJacobianHydraulicEquation(t, dt, local_x, local_x_prev,

                                                  local_b_data, local_Jac_data);

        }

        else

        {

            int const component_id = process_id - 1;

            assembleWithJacobianComponentTransportEquation(

                t, dt, local_x, local_x_prev, local_b_data, local_Jac_data,

                component_id);

        }

    }


    void assembleWithJacobianHydraulicEquation(

        double const t, double const dt, Eigen::VectorXd const& local_x,

        Eigen::VectorXd const& local_x_prev, std::vector<double>& local_b_data,

        std::vector<double>& local_Jac_data)

    {

        auto const p = local_x.template segment<pressure_size>(pressure_index);

        auto const c = local_x.template segment<concentration_size>(

            first_concentration_index);


        auto const p_prev = local_x_prev.segment<pressure_size>(pressure_index);

        auto const c_prev =

            local_x_prev.segment<concentration_size>(first_concentration_index);


        auto local_Jac = MathLib::createZeroedMatrix<LocalBlockMatrixType>(

            local_Jac_data, pressure_size, pressure_size);

        auto local_rhs = MathLib::createZeroedVector<LocalSegmentVectorType>(

            local_b_data, pressure_size);


        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());

        auto const& b =

            _process_data

                .projected_specific_body_force_vectors[_element.getID()];


        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());

        auto const& phase = medium.phase("AqueousLiquid");


        MaterialPropertyLib::VariableArray vars;

        MaterialPropertyLib::VariableArray vars_prev;


        for (unsigned ip(0); ip < n_integration_points; ++ip)

        {

            pos.setIntegrationPoint(ip);


            auto& ip_data = _ip_data[ip];

            auto const& N = ip_data.N;

            auto const& dNdx = ip_data.dNdx;

            auto const& w = ip_data.integration_weight;

            auto& phi = ip_data.porosity;

            auto const& phi_prev = ip_data.porosity_prev;


            double const p_ip = N.dot(p);

            double const c_ip = N.dot(c);


            double const cdot_ip = (c_ip - N.dot(c_prev)) / dt;


            vars.phase_pressure = p_ip;

            vars.concentration = c_ip;


            //  porosity

            {

                vars_prev.porosity = phi_prev;


                phi = _process_data.chemically_induced_porosity_change

                          ? phi_prev

                          : medium[MaterialPropertyLib::PropertyType::porosity]

                                .template value<double>(vars, vars_prev, pos, t,

                                                        dt);


                vars.porosity = phi;

            }


            auto const rho = phase[MaterialPropertyLib::PropertyType::density]

                                 .template value<double>(vars, pos, t, dt);


            auto const k = MaterialPropertyLib::formEigenTensor<GlobalDim>(

                medium[MaterialPropertyLib::PropertyType::permeability].value(

                    vars, pos, t, dt));


            auto const mu = phase[MaterialPropertyLib::PropertyType::viscosity]

                                .template value<double>(vars, pos, t, dt);


            auto const drho_dp =

                phase[MaterialPropertyLib::PropertyType::density]

                    .template dValue<double>(

                        vars, MaterialPropertyLib::Variable::phase_pressure,

                        pos, t, dt);

            auto const drho_dc =

                phase[MaterialPropertyLib::PropertyType::density]

                    .template dValue<double>(

                        vars, MaterialPropertyLib::Variable::concentration, pos,

                        t, dt);


            // matrix assembly

            local_Jac.noalias() += w * N.transpose() * phi * drho_dp / dt * N +

                                   w * dNdx.transpose() * rho * k / mu * dNdx;


            local_rhs.noalias() -=

                w * N.transpose() * phi *

                    (drho_dp * N * p_prev + drho_dc * cdot_ip) +

                w * rho * dNdx.transpose() * k / mu * dNdx * p;


            if (_process_data.has_gravity)

            {

                local_rhs.noalias() +=

                    w * rho * dNdx.transpose() * k / mu * rho * b;

            }

        }

    }


    void assembleWithJacobianComponentTransportEquation(

        double const t, double const dt, Eigen::VectorXd const& local_x,

        Eigen::VectorXd const& local_x_prev, std::vector<double>& local_b_data,

        std::vector<double>& local_Jac_data, int const component_id)

    {

        auto const concentration_index =

            first_concentration_index + component_id * concentration_size;


        auto const p = local_x.template segment<pressure_size>(pressure_index);

        auto const c =

            local_x.template segment<concentration_size>(concentration_index);

        auto const c_prev =

            local_x_prev.segment<concentration_size>(concentration_index);


        NodalVectorType T;

        if (_process_data.temperature)

        {

            T = _process_data.temperature->getNodalValuesOnElement(_element, t);

        }


        auto local_Jac = MathLib::createZeroedMatrix<LocalBlockMatrixType>(

            local_Jac_data, concentration_size, concentration_size);

        auto local_rhs = MathLib::createZeroedVector<LocalSegmentVectorType>(

            local_b_data, concentration_size);


        LocalBlockMatrixType KCC_Laplacian =

            LocalBlockMatrixType::Zero(concentration_size, concentration_size);


        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();


        std::vector<GlobalDimVectorType> ip_flux_vector;

        double average_velocity_norm = 0.0;

        ip_flux_vector.reserve(n_integration_points);


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());


        auto const& b =

            _process_data

                .projected_specific_body_force_vectors[_element.getID()];


        MaterialPropertyLib::VariableArray vars;

        MaterialPropertyLib::VariableArray vars_prev;


        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());

        auto const& phase = medium.phase("AqueousLiquid");

        auto const& component = phase.component(

            _transport_process_variables[component_id].get().getName());


        for (unsigned ip(0); ip < n_integration_points; ++ip)

        {

            pos.setIntegrationPoint(ip);


            auto& ip_data = _ip_data[ip];

            auto const& N = ip_data.N;

            auto const& dNdx = ip_data.dNdx;

            auto const& w = ip_data.integration_weight;

            auto& phi = ip_data.porosity;

            auto const& phi_prev = ip_data.porosity_prev;


            double const p_ip = N.dot(p);

            double const c_ip = N.dot(c);


            vars.phase_pressure = p_ip;

            vars.concentration = c_ip;


            if (_process_data.temperature)

            {

                vars.temperature = N.dot(T);

            }


            // porosity

            {

                vars_prev.porosity = phi_prev;


                phi = _process_data.chemically_induced_porosity_change

                          ? phi_prev

                          : medium[MaterialPropertyLib::PropertyType::porosity]

                                .template value<double>(vars, vars_prev, pos, t,

                                                        dt);


                vars.porosity = phi;

            }


            auto const R =

                component[MaterialPropertyLib::PropertyType::retardation_factor]

                    .template value<double>(vars, pos, t, dt);


            auto const alpha_T = medium.template value<double>(

                MaterialPropertyLib::PropertyType::transversal_dispersivity);

            auto const alpha_L = medium.template value<double>(

                MaterialPropertyLib::PropertyType::longitudinal_dispersivity);


            auto const rho = phase[MaterialPropertyLib::PropertyType::density]

                                 .template value<double>(vars, pos, t, dt);

            // first-order decay constant

            auto const alpha =

                component[MaterialPropertyLib::PropertyType::decay_rate]

                    .template value<double>(vars, pos, t, dt);


            auto const Dp = MaterialPropertyLib::formEigenTensor<GlobalDim>(

                component[MaterialPropertyLib::PropertyType::pore_diffusion]

                    .value(vars, pos, t, dt));


            auto const k = MaterialPropertyLib::formEigenTensor<GlobalDim>(

                medium[MaterialPropertyLib::PropertyType::permeability].value(

                    vars, pos, t, dt));

            auto const mu = phase[MaterialPropertyLib::PropertyType::viscosity]

                                .template value<double>(vars, pos, t, dt);

            // Darcy flux

            GlobalDimVectorType const q =

                _process_data.has_gravity

                    ? GlobalDimVectorType(-k / mu * (dNdx * p - rho * b))

                    : GlobalDimVectorType(-k / mu * dNdx * p);


            GlobalDimMatrixType const D = NumLib::computeHydrodynamicDispersion(

                _process_data.stabilizer, _element.getID(), Dp, q, phi, alpha_T,

                alpha_L);


            // matrix assembly

            local_Jac.noalias() +=

                w * rho * N.transpose() * phi * R * (alpha + 1 / dt) * N;


            KCC_Laplacian.noalias() += w * rho * dNdx.transpose() * D * dNdx;


            auto const cdot = (c - c_prev) / dt;

            local_rhs.noalias() -=

                w * rho * N.transpose() * phi * R * N * (cdot + alpha * c);


            ip_flux_vector.emplace_back(q * rho);

            average_velocity_norm += q.norm();

        }


        NumLib::assembleAdvectionMatrix(

            _process_data.stabilizer, _ip_data, ip_flux_vector,

            average_velocity_norm / static_cast<double>(n_integration_points),

            KCC_Laplacian);


        local_rhs.noalias() -= KCC_Laplacian * c;


        local_Jac.noalias() += KCC_Laplacian;

    }


    void assembleReactionEquationConcrete(

        double const t, double const dt, Eigen::VectorXd const& local_x,

        std::vector<double>& local_M_data, std::vector<double>& local_K_data,

        std::vector<double>& local_b_data,

        int const transport_process_id) override

    {

        auto const local_C = local_x.template segment<concentration_size>(

            first_concentration_index +

            (transport_process_id - 1) * concentration_size);


        auto local_M = MathLib::createZeroedMatrix<LocalBlockMatrixType>(

            local_M_data, concentration_size, concentration_size);

        auto local_K = MathLib::createZeroedMatrix<LocalBlockMatrixType>(

            local_K_data, concentration_size, concentration_size);

        auto local_b = MathLib::createZeroedVector<LocalVectorType>(

            local_b_data, concentration_size);


        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());


        MaterialPropertyLib::VariableArray vars;

        MaterialPropertyLib::VariableArray vars_prev;


        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());

        auto const component_id = transport_process_id - 1;

        for (unsigned ip(0); ip < n_integration_points; ++ip)

        {

            pos.setIntegrationPoint(ip);


            auto& ip_data = _ip_data[ip];

            auto const& N = ip_data.N;

            auto const w = ip_data.integration_weight;

            auto& porosity = ip_data.porosity;

            auto const& porosity_prev = ip_data.porosity_prev;

            auto const chemical_system_id = ip_data.chemical_system_id;


            double C_int_pt = 0.0;

            NumLib::shapeFunctionInterpolate(local_C, N, C_int_pt);


            vars.concentration = C_int_pt;


            auto const porosity_dot = (porosity - porosity_prev) / dt;


            // porosity

            {

                vars_prev.porosity = porosity_prev;


                porosity =

                    _process_data.chemically_induced_porosity_change

                        ? porosity_prev

                        : medium[MaterialPropertyLib::PropertyType::porosity]

                              .template value<double>(vars, vars_prev, pos, t,

                                                      dt);

            }


            local_M.noalias() += w * N.transpose() * porosity * N;


            local_K.noalias() += w * N.transpose() * porosity_dot * N;


            if (chemical_system_id == -1)

            {

                continue;

            }


            auto const C_post_int_pt =

                _process_data.chemical_solver_interface->getConcentration(

                    component_id, chemical_system_id);


            local_b.noalias() +=

                w * N.transpose() * porosity * (C_post_int_pt - C_int_pt) / dt;

        }

    }


    std::vector<double> const& getIntPtDarcyVelocity(

        const double t,

        std::vector<GlobalVector*> const& x,

        std::vector<NumLib::LocalToGlobalIndexMap const*> const& dof_table,

        std::vector<double>& cache) const override

    {

        assert(x.size() == dof_table.size());


        auto const n_processes = x.size();

        std::vector<std::vector<double>> local_x;

        local_x.reserve(n_processes);


        for (std::size_t process_id = 0; process_id < n_processes; ++process_id)

        {

            auto const indices =

                NumLib::getIndices(_element.getID(), *dof_table[process_id]);

            assert(!indices.empty());

            local_x.push_back(x[process_id]->get(indices));

        }


        // only one process, must be monolithic.

        if (n_processes == 1)

        {

            auto const local_p = Eigen::Map<const NodalVectorType>(

                &local_x[0][pressure_index], pressure_size);

            auto const local_C = Eigen::Map<const NodalVectorType>(

                &local_x[0][first_concentration_index], concentration_size);

            return calculateIntPtDarcyVelocity(t, local_p, local_C, cache);

        }


        // multiple processes, must be staggered.

        {

            constexpr int pressure_process_id = 0;

            constexpr int concentration_process_id = 1;

            auto const local_p = Eigen::Map<const NodalVectorType>(

                &local_x[pressure_process_id][0], pressure_size);

            auto const local_C = Eigen::Map<const NodalVectorType>(

                &local_x[concentration_process_id][0], concentration_size);

            return calculateIntPtDarcyVelocity(t, local_p, local_C, cache);

        }

    }


    std::vector<double> const& calculateIntPtDarcyVelocity(

        const double t,

        Eigen::Ref<const NodalVectorType> const& p_nodal_values,

        Eigen::Ref<const NodalVectorType> const& C_nodal_values,

        std::vector<double>& cache) const

    {

        auto const n_integration_points =

            _integration_method.getNumberOfPoints();


        cache.clear();

        auto cache_mat = MathLib::createZeroedMatrix<

            Eigen::Matrix<double, GlobalDim, Eigen::Dynamic, Eigen::RowMajor>>(

            cache, GlobalDim, n_integration_points);


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());


        auto const& b =

            _process_data

                .projected_specific_body_force_vectors[_element.getID()];


        MaterialPropertyLib::VariableArray vars;


        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());

        auto const& phase = medium.phase("AqueousLiquid");


        for (unsigned ip = 0; ip < n_integration_points; ++ip)

        {

            auto const& ip_data = _ip_data[ip];

            auto const& N = ip_data.N;

            auto const& dNdx = ip_data.dNdx;

            auto const& porosity = ip_data.porosity;


            pos.setIntegrationPoint(ip);


            double C_int_pt = 0.0;

            double p_int_pt = 0.0;


            NumLib::shapeFunctionInterpolate(C_nodal_values, N, C_int_pt);

            NumLib::shapeFunctionInterpolate(p_nodal_values, N, p_int_pt);


            vars.concentration = C_int_pt;

            vars.phase_pressure = p_int_pt;

            vars.porosity = porosity;


            // TODO (naumov) Temporary value not used by current material

            // models. Need extension of secondary variables interface.

            double const dt = std::numeric_limits<double>::quiet_NaN();

            auto const& K = MaterialPropertyLib::formEigenTensor<GlobalDim>(

                medium[MaterialPropertyLib::PropertyType::permeability].value(

                    vars, pos, t, dt));

            auto const mu = phase[MaterialPropertyLib::PropertyType::viscosity]

                                .template value<double>(vars, pos, t, dt);

            GlobalDimMatrixType const K_over_mu = K / mu;


            cache_mat.col(ip).noalias() = -K_over_mu * dNdx * p_nodal_values;

            if (_process_data.has_gravity)

            {

                auto const rho_w =

                    phase[MaterialPropertyLib::PropertyType::density]

                        .template value<double>(vars, pos, t, dt);

                // here it is assumed that the vector b is directed 'downwards'

                cache_mat.col(ip).noalias() += K_over_mu * rho_w * b;

            }

        }


        return cache;

    }


    Eigen::Map<const Eigen::RowVectorXd> getShapeMatrix(

        const unsigned integration_point) const override

    {

        auto const& N = _ip_data[integration_point].N;


        // assumes N is stored contiguously in memory

        return Eigen::Map<const Eigen::RowVectorXd>(N.data(), N.size());

    }


    Eigen::Vector3d getFlux(MathLib::Point3d const& pnt_local_coords,

                            double const t,

                            std::vector<double> const& local_x) const override

    {

        auto const local_p = Eigen::Map<const NodalVectorType>(

            &local_x[pressure_index], pressure_size);

        auto const local_C = Eigen::Map<const NodalVectorType>(

            &local_x[first_concentration_index], concentration_size);


        // Eval shape matrices at given point

        // Note: Axial symmetry is set to false here, because we only need dNdx

        // here, which is not affected by axial symmetry.

        auto const shape_matrices =

            NumLib::computeShapeMatrices<ShapeFunction, ShapeMatricesType,

                                         GlobalDim>(

                _element, false /*is_axially_symmetric*/,

                std::array{pnt_local_coords})[0];


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());

        auto const& b =

            _process_data

                .projected_specific_body_force_vectors[_element.getID()];


        MaterialPropertyLib::VariableArray vars;


        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());

        auto const& phase = medium.phase("AqueousLiquid");


        // local_x contains the local concentration and pressure values

        double c_int_pt;

        NumLib::shapeFunctionInterpolate(local_C, shape_matrices.N, c_int_pt);

        vars.concentration = c_int_pt;


        double p_int_pt;

        NumLib::shapeFunctionInterpolate(local_p, shape_matrices.N, p_int_pt);

        vars.phase_pressure = p_int_pt;


        // TODO (naumov) Temporary value not used by current material models.

        // Need extension of secondary variables interface.

        double const dt = std::numeric_limits<double>::quiet_NaN();

        auto const K = MaterialPropertyLib::formEigenTensor<GlobalDim>(

            medium[MaterialPropertyLib::PropertyType::permeability].value(

                vars, pos, t, dt));


        auto const mu = phase[MaterialPropertyLib::PropertyType::viscosity]

                            .template value<double>(vars, pos, t, dt);

        GlobalDimMatrixType const K_over_mu = K / mu;


        GlobalDimVectorType q = -K_over_mu * shape_matrices.dNdx * local_p;

        auto const rho_w = phase[MaterialPropertyLib::PropertyType::density]

                               .template value<double>(vars, pos, t, dt);

        if (_process_data.has_gravity)

        {

            q += K_over_mu * rho_w * b;

        }

        Eigen::Vector3d flux(0.0, 0.0, 0.0);

        flux.head<GlobalDim>() = rho_w * q;

        return flux;

    }


    void computeSecondaryVariableConcrete(

        double const t,

        double const /*dt*/,

        Eigen::VectorXd const& local_x,

        Eigen::VectorXd const& /*local_x_prev*/) override

    {

        auto const local_p =

            local_x.template segment<pressure_size>(pressure_index);

        auto const local_C = local_x.template segment<concentration_size>(

            first_concentration_index);


        std::vector<double> ele_velocity;

        calculateIntPtDarcyVelocity(t, local_p, local_C, ele_velocity);


        auto const n_integration_points =

            _integration_method.getNumberOfPoints();

        auto const ele_velocity_mat =

            MathLib::toMatrix(ele_velocity, GlobalDim, n_integration_points);


        auto const ele_id = _element.getID();

        Eigen::Map<LocalVectorType>(

            &(*_process_data.mesh_prop_velocity)[ele_id * GlobalDim],

            GlobalDim) =

            ele_velocity_mat.rowwise().sum() / n_integration_points;

    }


    void computeReactionRelatedSecondaryVariable(

        std::size_t const ele_id) override

    {

        auto const n_integration_points =

            _integration_method.getNumberOfPoints();


        if (_process_data.chemically_induced_porosity_change)

        {

            auto const& medium = *_process_data.media_map.getMedium(ele_id);


            for (auto& ip_data : _ip_data)

            {

                ip_data.porosity = ip_data.porosity_prev;


                _process_data.chemical_solver_interface

                    ->updatePorosityPostReaction(ip_data.chemical_system_id,

                                                 medium, ip_data.porosity);

            }


            (*_process_data.mesh_prop_porosity)[ele_id] =

                std::accumulate(_ip_data.begin(), _ip_data.end(), 0.,

                                [](double const s, auto const& ip)

                                { return s + ip.porosity; }) /

                n_integration_points;

        }


        std::vector<GlobalIndexType> chemical_system_indices;

        chemical_system_indices.reserve(n_integration_points);

        std::transform(_ip_data.begin(), _ip_data.end(),

                       std::back_inserter(chemical_system_indices),

                       [](auto const& ip_data)

                       { return ip_data.chemical_system_id; });


        _process_data.chemical_solver_interface->computeSecondaryVariable(

            ele_id, chemical_system_indices);

    }


    std::vector<double> const& getIntPtMolarFlux(

        const double t,

        std::vector<GlobalVector*> const& x,

        std::vector<NumLib::LocalToGlobalIndexMap const*> const& dof_tables,

        std::vector<double>& cache) const override

    {

        std::vector<double> local_x_vec;


        auto const n_processes = x.size();

        for (std::size_t process_id = 0; process_id < n_processes; ++process_id)

        {

            auto const indices =

                NumLib::getIndices(_element.getID(), *dof_tables[process_id]);

            assert(!indices.empty());

            auto const local_solution = x[process_id]->get(indices);

            local_x_vec.insert(std::end(local_x_vec),

                               std::begin(local_solution),

                               std::end(local_solution));

        }

        auto const local_x = MathLib::toVector(local_x_vec);


        auto const p = local_x.template segment<pressure_size>(pressure_index);

        auto const c = local_x.template segment<concentration_size>(

            first_concentration_index);


        auto const n_integration_points =

            _integration_method.getNumberOfPoints();


        cache.clear();

        auto cache_mat = MathLib::createZeroedMatrix<

            Eigen::Matrix<double, GlobalDim, Eigen::Dynamic, Eigen::RowMajor>>(

            cache, GlobalDim, n_integration_points);


        ParameterLib::SpatialPosition pos;

        pos.setElementID(_element.getID());


        auto const& b =

            _process_data

                .projected_specific_body_force_vectors[_element.getID()];


        MaterialPropertyLib::VariableArray vars;


        auto const& medium =

            *_process_data.media_map.getMedium(_element.getID());

        auto const& phase = medium.phase("AqueousLiquid");


        int const component_id = 0;

        auto const& component = phase.component(

            _transport_process_variables[component_id].get().getName());


        for (unsigned ip = 0; ip < n_integration_points; ++ip)

        {

            auto const& ip_data = _ip_data[ip];

            auto const& N = ip_data.N;

            auto const& dNdx = ip_data.dNdx;

            auto const& phi = ip_data.porosity;


            pos.setIntegrationPoint(ip);


            double const p_ip = N.dot(p);

            double const c_ip = N.dot(c);


            vars.concentration = c_ip;

            vars.phase_pressure = p_ip;

            vars.porosity = phi;


            double const dt = std::numeric_limits<double>::quiet_NaN();


            auto const& k = MaterialPropertyLib::formEigenTensor<GlobalDim>(

                medium[MaterialPropertyLib::PropertyType::permeability].value(

                    vars, pos, t, dt));

            auto const mu = phase[MaterialPropertyLib::PropertyType::viscosity]

                                .template value<double>(vars, pos, t, dt);

            auto const rho = phase[MaterialPropertyLib::PropertyType::density]

                                 .template value<double>(vars, pos, t, dt);


            // Darcy flux

            GlobalDimVectorType const q =

                _process_data.has_gravity

                    ? GlobalDimVectorType(-k / mu * (dNdx * p - rho * b))

                    : GlobalDimVectorType(-k / mu * dNdx * p);


            auto const alpha_T = medium.template value<double>(

                MaterialPropertyLib::PropertyType::transversal_dispersivity);

            auto const alpha_L = medium.template value<double>(

                MaterialPropertyLib::PropertyType::longitudinal_dispersivity);

            auto const Dp = MaterialPropertyLib::formEigenTensor<GlobalDim>(

                component[MaterialPropertyLib::PropertyType::pore_diffusion]

                    .value(vars, pos, t, dt));


            // Hydrodynamic dispersion

            GlobalDimMatrixType const D = NumLib::computeHydrodynamicDispersion(

                _process_data.stabilizer, _element.getID(), Dp, q, phi, alpha_T,

                alpha_L);


            cache_mat.col(ip).noalias() = q * c_ip - phi * D * dNdx * c;

        }


        return cache;

    }


    void postTimestepConcrete(Eigen::VectorXd const& /*local_x*/,

                              Eigen::VectorXd const& /*local_x_prev*/,

                              double const /*t*/, double const /*dt*/,

                              bool const /*use_monolithic_scheme*/,

                              int const /*process_id*/) override

    {

        unsigned const n_integration_points =

            _integration_method.getNumberOfPoints();


        for (unsigned ip = 0; ip < n_integration_points; ip++)

        {

            _ip_data[ip].pushBackState();

        }

    }


private:

    MeshLib::Element const& _element;

    ComponentTransportProcessData const& _process_data;


    NumLib::GenericIntegrationMethod const& _integration_method;

    std::vector<std::reference_wrapper<ProcessVariable>> const

        _transport_process_variables;


    std::vector<

        IntegrationPointData<NodalRowVectorType, GlobalDimNodalMatrixType>,

        Eigen::aligned_allocator<

            IntegrationPointData<NodalRowVectorType, GlobalDimNodalMatrixType>>>

        _ip_data;

};


}  // namespace ComponentTransport

}  // namespace ProcessLib

AdvectionMatrixAssembler.h

ChemicalSolverInterface.h

ComponentTransportProcessData.h

DOFTableUtil.h

EigenMapTools.h

ExtrapolatableElement.h

FormEigenTensor.h

GenericIntegrationMethod.h

GlobalIndexType
GlobalMatrix::IndexType GlobalIndexType
Definition: GlobalMatrixVectorTypes.h:51

HydrodynamicDispersion.h

InitShapeMatrices.h

Interpolation.h

LocalAssemblerInterface.h

Property.h

MaterialSpatialDistributionMap.h

Medium.h

Parameter.h

ProcessVariable.h

ShapeMatrixPolicy.h

getName
std::string getName(std::string const &line)
Returns the name/title from the "Zone"-description.
Definition: TecPlotTools.cpp:63

TemplateIsoparametric.h

ChemistryLib::ChemicalSolverInterface::updatePorosityPostReaction
virtual void updatePorosityPostReaction(GlobalIndexType const &, MaterialPropertyLib::Medium const &, double &)
Definition: ChemicalSolverInterface.h:104

ChemistryLib::ChemicalSolverInterface::getKineticPrefactor
virtual double getKineticPrefactor(std::size_t reaction_id) const
Definition: ChemicalSolverInterface.h:90

ChemistryLib::ChemicalSolverInterface::computeSecondaryVariable
virtual void computeSecondaryVariable(std::size_t const, std::vector< GlobalIndexType > const &)
Definition: ChemicalSolverInterface.h:111

ChemistryLib::ChemicalSolverInterface::setChemicalSystemConcrete
virtual void setChemicalSystemConcrete(std::vector< double > const &, GlobalIndexType const &, MaterialPropertyLib::Medium const *, MaterialPropertyLib::VariableArray const &, ParameterLib::SpatialPosition const &, double const, double const)
Definition: ChemicalSolverInterface.h:57

ChemistryLib::ChemicalSolverInterface::updateVolumeFractionPostReaction
virtual void updateVolumeFractionPostReaction(GlobalIndexType const &, MaterialPropertyLib::Medium const &, ParameterLib::SpatialPosition const &, double const, double const, double const)
Definition: ChemicalSolverInterface.h:96

ChemistryLib::ChemicalSolverInterface::chemical_system_index_map
std::vector< GlobalIndexType > chemical_system_index_map
Definition: ChemicalSolverInterface.h:120

ChemistryLib::ChemicalSolverInterface::getStoichiometricMatrix
virtual Eigen::SparseMatrix< double > const * getStoichiometricMatrix() const
Definition: ChemicalSolverInterface.h:85

ChemistryLib::ChemicalSolverInterface::getConcentration
virtual double getConcentration(int const, GlobalIndexType const) const
Definition: ChemicalSolverInterface.h:73

ChemistryLib::ChemicalSolverInterface::initializeChemicalSystemConcrete
virtual void initializeChemicalSystemConcrete(std::vector< double > const &, GlobalIndexType const &, MaterialPropertyLib::Medium const &, ParameterLib::SpatialPosition const &, double const)
Definition: ChemicalSolverInterface.h:49

MaterialPropertyLib::MaterialSpatialDistributionMap::getMedium
Medium * getMedium(std::size_t element_id)
Definition: MaterialSpatialDistributionMap.cpp:18

MaterialPropertyLib::Medium::phase
Phase const & phase(std::size_t index) const
Definition: Medium.cpp:33

MaterialPropertyLib::Phase::component
Component const & component(std::size_t const &index) const
Definition: Phase.cpp:33

MaterialPropertyLib::VariableArray
Definition: VariableType.h:96

MaterialPropertyLib::VariableArray::porosity
double porosity
Definition: VariableType.h:187

MaterialPropertyLib::VariableArray::temperature
double temperature
Definition: VariableType.h:193

MaterialPropertyLib::VariableArray::concentration
double concentration
Definition: VariableType.h:164

MaterialPropertyLib::VariableArray::phase_pressure
double phase_pressure
Definition: VariableType.h:186

MathLib::EigenMatrix
Definition: EigenMatrix.h:28

MathLib::EigenMatrix::add
int add(IndexType row, IndexType col, double val)
Definition: EigenMatrix.h:86

MathLib::EigenVector
Global vector based on Eigen vector.
Definition: EigenVector.h:25

MathLib::EigenVector::add
void add(IndexType rowId, double v)
add entry
Definition: EigenVector.h:76

MathLib::Point3d
Definition: Point3d.h:27

MathLib::WeightedPoint::getWeight
double getWeight() const
Definition: WeightedPoint.h:80

MeshLib::Element
Definition: Element.h:34

MeshLib::Element::getID
virtual std::size_t getID() const final
Returns the ID of the element.
Definition: Element.h:89

NumLib::ExtrapolatableElement
Definition: ExtrapolatableElement.h:24

NumLib::GenericIntegrationMethod
Definition: GenericIntegrationMethod.h:24

NumLib::GenericIntegrationMethod::getWeightedPoint
MathLib::WeightedPoint const & getWeightedPoint(unsigned const igp) const
Definition: GenericIntegrationMethod.h:36

NumLib::GenericIntegrationMethod::getNumberOfPoints
unsigned getNumberOfPoints() const
Definition: GenericIntegrationMethod.h:34

NumLib::LocalToGlobalIndexMap::RowColumnIndices
MathLib::RowColumnIndices< GlobalIndexType > RowColumnIndices
Definition: LocalToGlobalIndexMap.h:51

ParameterLib::SpatialPosition
Definition: SpatialPosition.h:27

ParameterLib::SpatialPosition::setElementID
void setElementID(std::size_t element_id)
Definition: SpatialPosition.h:59

ParameterLib::SpatialPosition::setIntegrationPoint
void setIntegrationPoint(unsigned integration_point)
Definition: SpatialPosition.h:65

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface
Definition: ComponentTransportFEM.h:67

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::getIntPtDarcyVelocity
virtual std::vector< double > const & getIntPtDarcyVelocity(const double t, std::vector< GlobalVector * > const &x, std::vector< NumLib::LocalToGlobalIndexMap const * > const &dof_table, std::vector< double > &cache) const =0

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::getIntPtMolarFlux
virtual std::vector< double > const & getIntPtMolarFlux(const double t, std::vector< GlobalVector * > const &x, std::vector< NumLib::LocalToGlobalIndexMap const * > const &dof_table, std::vector< double > &cache) const =0

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::setChemicalSystemConcrete
virtual void setChemicalSystemConcrete(Eigen::VectorXd const &, double const, double const)=0

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::postSpeciationCalculation
virtual void postSpeciationCalculation(std::size_t const ele_id, double const t, double const dt)=0

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::computeReactionRelatedSecondaryVariable
virtual void computeReactionRelatedSecondaryVariable(std::size_t const ele_id)=0

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::setChemicalSystemID
virtual void setChemicalSystemID(std::size_t const)=0

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::initializeChemicalSystem
void initializeChemicalSystem(std::size_t const mesh_item_id, std::vector< NumLib::LocalToGlobalIndexMap const * > const &dof_tables, std::vector< GlobalVector * > const &x, double const t)
Definition: ComponentTransportFEM.h:73

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::setChemicalSystem
void setChemicalSystem(std::size_t const mesh_item_id, std::vector< NumLib::LocalToGlobalIndexMap const * > const &dof_tables, std::vector< GlobalVector * > const &x, double const t, double const dt)
Definition: ComponentTransportFEM.h:96

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::assembleReactionEquationConcrete
virtual void assembleReactionEquationConcrete(double const t, double const dt, Eigen::VectorXd const &local_x, std::vector< double > &local_M_data, std::vector< double > &local_K_data, std::vector< double > &local_b_data, int const transport_process_id)=0

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::assembleReactionEquation
void assembleReactionEquation(std::size_t const mesh_item_id, std::vector< NumLib::LocalToGlobalIndexMap const * > const &dof_tables, std::vector< GlobalVector * > const &x, double const t, double const dt, GlobalMatrix &M, GlobalMatrix &K, GlobalVector &b, int const process_id)
Definition: ComponentTransportFEM.h:119

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::initializeChemicalSystemConcrete
virtual void initializeChemicalSystemConcrete(Eigen::VectorXd const &, double const)=0

ProcessLib::ComponentTransport::ComponentTransportLocalAssemblerInterface::ComponentTransportLocalAssemblerInterface
ComponentTransportLocalAssemblerInterface()=default

ProcessLib::ComponentTransport::LocalAssemblerData
Definition: ComponentTransportFEM.h:209

ProcessLib::ComponentTransport::LocalAssemblerData::GlobalDimVectorType
typename ShapeMatricesType::GlobalDimVectorType GlobalDimVectorType
Definition: ComponentTransportFEM.h:235

ProcessLib::ComponentTransport::LocalAssemblerData::assembleForStaggeredScheme
void assembleForStaggeredScheme(double const t, double const dt, Eigen::VectorXd const &local_x, Eigen::VectorXd const &local_x_prev, int const process_id, std::vector< double > &local_M_data, std::vector< double > &local_K_data, std::vector< double > &local_b_data) override
Definition: ComponentTransportFEM.h:769

ProcessLib::ComponentTransport::LocalAssemblerData::ShapeMatrices
typename ShapeMatricesType::ShapeMatrices ShapeMatrices
Definition: ComponentTransportFEM.h:220

ProcessLib::ComponentTransport::LocalAssemblerData::_element
MeshLib::Element const  & _element
Definition: ComponentTransportFEM.h:1824

ProcessLib::ComponentTransport::LocalAssemblerData::LocalMatrixType
Eigen::Matrix< double, Eigen::Dynamic, Eigen::Dynamic, Eigen::RowMajor > LocalMatrixType
Definition: ComponentTransportFEM.h:229

ProcessLib::ComponentTransport::LocalAssemblerData::assembleWithJacobianHydraulicEquation
void assembleWithJacobianHydraulicEquation(double const t, double const dt, Eigen::VectorXd const &local_x, Eigen::VectorXd const &local_x_prev, std::vector< double > &local_b_data, std::vector< double > &local_Jac_data)
Definition: ComponentTransportFEM.h:1135

ProcessLib::ComponentTransport::LocalAssemblerData::first_concentration_index
static const int first_concentration_index
Definition: ComponentTransportFEM.h:213

ProcessLib::ComponentTransport::LocalAssemblerData::postTimestepConcrete
void postTimestepConcrete(Eigen::VectorXd const &, Eigen::VectorXd const &, double const, double const, bool const, int const) override
Definition: ComponentTransportFEM.h:1808

ProcessLib::ComponentTransport::LocalAssemblerData::postSpeciationCalculation
void postSpeciationCalculation(std::size_t const ele_id, double const t, double const dt) override
Definition: ComponentTransportFEM.h:411

ProcessLib::ComponentTransport::LocalAssemblerData::_integration_method
NumLib::GenericIntegrationMethod const  & _integration_method
Definition: ComponentTransportFEM.h:1827

ProcessLib::ComponentTransport::LocalAssemblerData::initializeChemicalSystemConcrete
void initializeChemicalSystemConcrete(Eigen::VectorXd const &local_x, double const t) override
Definition: ComponentTransportFEM.h:310

ProcessLib::ComponentTransport::LocalAssemblerData::computeReactionRelatedSecondaryVariable
void computeReactionRelatedSecondaryVariable(std::size_t const ele_id) override
Definition: ComponentTransportFEM.h:1670

ProcessLib::ComponentTransport::LocalAssemblerData::GlobalDimNodalMatrixType
typename ShapeMatricesType::GlobalDimNodalMatrixType GlobalDimNodalMatrixType
Definition: ComponentTransportFEM.h:237

ProcessLib::ComponentTransport::LocalAssemblerData::getIntPtMolarFlux
std::vector< double > const & getIntPtMolarFlux(const double t, std::vector< GlobalVector * > const &x, std::vector< NumLib::LocalToGlobalIndexMap const * > const &dof_tables, std::vector< double > &cache) const override
Definition: ComponentTransportFEM.h:1707

ProcessLib::ComponentTransport::LocalAssemblerData::calculateIntPtDarcyVelocity
std::vector< double > const & calculateIntPtDarcyVelocity(const double t, Eigen::Ref< const NodalVectorType > const &p_nodal_values, Eigen::Ref< const NodalVectorType > const &C_nodal_values, std::vector< double > &cache) const
Definition: ComponentTransportFEM.h:1503

ProcessLib::ComponentTransport::LocalAssemblerData::assembleBlockMatrices
void assembleBlockMatrices(GlobalDimVectorType const &b, int const component_id, double const t, double const dt, Eigen::Ref< const NodalVectorType > const &C_nodal_values, Eigen::Ref< const NodalVectorType > const &p_nodal_values, Eigen::Ref< LocalBlockMatrixType > KCC, Eigen::Ref< LocalBlockMatrixType > MCC, Eigen::Ref< LocalBlockMatrixType > MCp, Eigen::Ref< LocalBlockMatrixType > MpC, Eigen::Ref< LocalBlockMatrixType > Kpp, Eigen::Ref< LocalBlockMatrixType > Mpp, Eigen::Ref< LocalSegmentVectorType > Bp)
Definition: ComponentTransportFEM.h:545

ProcessLib::ComponentTransport::LocalAssemblerData::GlobalDimMatrixType
typename ShapeMatricesType::GlobalDimMatrixType GlobalDimMatrixType
Definition: ComponentTransportFEM.h:238

ProcessLib::ComponentTransport::LocalAssemblerData::assembleWithJacobianForStaggeredScheme
void assembleWithJacobianForStaggeredScheme(double const t, double const dt, Eigen::VectorXd const &local_x, Eigen::VectorXd const &local_x_prev, int const process_id, std::vector< double > &, std::vector< double > &, std::vector< double > &local_b_data, std::vector< double > &local_Jac_data) override
Definition: ComponentTransportFEM.h:1113

ProcessLib::ComponentTransport::LocalAssemblerData::_process_data
ComponentTransportProcessData const  & _process_data
Definition: ComponentTransportFEM.h:1825

ProcessLib::ComponentTransport::LocalAssemblerData::getShapeMatrix
Eigen::Map< const Eigen::RowVectorXd > getShapeMatrix(const unsigned integration_point) const override
Provides the shape matrix at the given integration point.
Definition: ComponentTransportFEM.h:1573

ProcessLib::ComponentTransport::LocalAssemblerData::ShapeMatricesType
ShapeMatrixPolicyType< ShapeFunction, GlobalDim > ShapeMatricesType
Definition: ComponentTransportFEM.h:219

ProcessLib::ComponentTransport::LocalAssemblerData::computeSecondaryVariableConcrete
void computeSecondaryVariableConcrete(double const t, double const, Eigen::VectorXd const &local_x, Eigen::VectorXd const &) override
Definition: ComponentTransportFEM.h:1644

ProcessLib::ComponentTransport::LocalAssemblerData::_transport_process_variables
std::vector< std::reference_wrapper< ProcessVariable > > const _transport_process_variables
Definition: ComponentTransportFEM.h:1829

ProcessLib::ComponentTransport::LocalAssemblerData::assembleHydraulicEquation
void assembleHydraulicEquation(double const t, double const dt, Eigen::VectorXd const &local_x, Eigen::VectorXd const &local_x_prev, std::vector< double > &local_M_data, std::vector< double > &local_K_data, std::vector< double > &local_b_data)
Definition: ComponentTransportFEM.h:791

ProcessLib::ComponentTransport::LocalAssemblerData::NodalRowVectorType
typename ShapeMatricesType::NodalRowVectorType NodalRowVectorType
Definition: ComponentTransportFEM.h:233

ProcessLib::ComponentTransport::LocalAssemblerData::getIntPtDarcyVelocity
std::vector< double > const & getIntPtDarcyVelocity(const double t, std::vector< GlobalVector * > const &x, std::vector< NumLib::LocalToGlobalIndexMap const * > const &dof_table, std::vector< double > &cache) const override
Definition: ComponentTransportFEM.h:1461

ProcessLib::ComponentTransport::LocalAssemblerData::_ip_data
std::vector< IntegrationPointData< NodalRowVectorType, GlobalDimNodalMatrixType >, Eigen::aligned_allocator< IntegrationPointData< NodalRowVectorType, GlobalDimNodalMatrixType > > > _ip_data
Definition: ComponentTransportFEM.h:1835

ProcessLib::ComponentTransport::LocalAssemblerData::concentration_size
static const int concentration_size
Definition: ComponentTransportFEM.h:216

ProcessLib::ComponentTransport::LocalAssemblerData::LocalBlockMatrixType
typename ShapeMatricesType::template MatrixType< pressure_size, pressure_size > LocalBlockMatrixType
Definition: ComponentTransportFEM.h:224

ProcessLib::ComponentTransport::LocalAssemblerData::LocalSegmentVectorType
typename ShapeMatricesType::template VectorType< pressure_size > LocalSegmentVectorType
Definition: ComponentTransportFEM.h:226

ProcessLib::ComponentTransport::LocalAssemblerData::assembleComponentTransportEquation
void assembleComponentTransportEquation(double const t, double const dt, Eigen::VectorXd const &local_x, Eigen::VectorXd const &local_x_prev, std::vector< double > &local_M_data, std::vector< double > &local_K_data, std::vector< double > &, int const transport_process_id)
Definition: ComponentTransportFEM.h:913

ProcessLib::ComponentTransport::LocalAssemblerData::getFlux
Eigen::Vector3d getFlux(MathLib::Point3d const &pnt_local_coords, double const t, std::vector< double > const &local_x) const override
Definition: ComponentTransportFEM.h:1582

ProcessLib::ComponentTransport::LocalAssemblerData::assemble
void assemble(double const t, double const dt, std::vector< double > const &local_x, std::vector< double > const &, std::vector< double > &local_M_data, std::vector< double > &local_K_data, std::vector< double > &local_b_data) override
Definition: ComponentTransportFEM.h:438

ProcessLib::ComponentTransport::LocalAssemblerData::assembleWithJacobianComponentTransportEquation
void assembleWithJacobianComponentTransportEquation(double const t, double const dt, Eigen::VectorXd const &local_x, Eigen::VectorXd const &local_x_prev, std::vector< double > &local_b_data, std::vector< double > &local_Jac_data, int const component_id)
Definition: ComponentTransportFEM.h:1239

ProcessLib::ComponentTransport::LocalAssemblerData::LocalVectorType
Eigen::Matrix< double, Eigen::Dynamic, 1 > LocalVectorType
Definition: ComponentTransportFEM.h:230

ProcessLib::ComponentTransport::LocalAssemblerData::pressure_size
static const int pressure_size
Definition: ComponentTransportFEM.h:215

ProcessLib::ComponentTransport::LocalAssemblerData::assembleReactionEquationConcrete
void assembleReactionEquationConcrete(double const t, double const dt, Eigen::VectorXd const &local_x, std::vector< double > &local_M_data, std::vector< double > &local_K_data, std::vector< double > &local_b_data, int const transport_process_id) override
Definition: ComponentTransportFEM.h:1384

ProcessLib::ComponentTransport::LocalAssemblerData::LocalAssemblerData
LocalAssemblerData(MeshLib::Element const &element, std::size_t const local_matrix_size, NumLib::GenericIntegrationMethod const &integration_method, bool is_axially_symmetric, ComponentTransportProcessData const &process_data, std::vector< std::reference_wrapper< ProcessVariable > > const &transport_process_variables)
Definition: ComponentTransportFEM.h:241

ProcessLib::ComponentTransport::LocalAssemblerData::assembleKCmCn
void assembleKCmCn(int const component_id, double const t, double const dt, Eigen::Ref< LocalBlockMatrixType > KCmCn, double const stoichiometric_coefficient, double const kinetic_prefactor)
Definition: ComponentTransportFEM.h:726

ProcessLib::ComponentTransport::LocalAssemblerData::pressure_index
static const int pressure_index
Definition: ComponentTransportFEM.h:212

ProcessLib::ComponentTransport::LocalAssemblerData::setChemicalSystemConcrete
void setChemicalSystemConcrete(Eigen::VectorXd const &local_x, double const t, double dt) override
Definition: ComponentTransportFEM.h:351

ProcessLib::ComponentTransport::LocalAssemblerData::setChemicalSystemID
void setChemicalSystemID(std::size_t const) override
Definition: ComponentTransportFEM.h:290

ProcessLib::ComponentTransport::LocalAssemblerData::NodalVectorType
typename ShapeMatricesType::NodalVectorType NodalVectorType
Definition: ComponentTransportFEM.h:232

ProcessLib::LocalAssemblerInterface
Definition: LocalAssemblerInterface.h:32

MaterialPropertyLib::Variable::concentration
@ concentration

MaterialPropertyLib::Variable::phase_pressure
@ phase_pressure

MaterialPropertyLib::PropertyType
PropertyType
Definition: PropertyType.h:33

MaterialPropertyLib::density
@ density
Definition: PropertyType.h:48

MaterialPropertyLib::viscosity
@ viscosity
Definition: PropertyType.h:112

MaterialPropertyLib::porosity
@ porosity
Definition: PropertyType.h:75

MaterialPropertyLib::permeability
@ permeability
Definition: PropertyType.h:68

MaterialPropertyLib::longitudinal_dispersivity
@ longitudinal_dispersivity
used to compute the hydrodynamic dispersion tensor.
Definition: PropertyType.h:60

MaterialPropertyLib::transversal_dispersivity
@ transversal_dispersivity
used to compute the hydrodynamic dispersion tensor.
Definition: PropertyType.h:110

MaterialPropertyLib::decay_rate
@ decay_rate
Definition: PropertyType.h:47

MaterialPropertyLib::retardation_factor
@ retardation_factor
specify retardation factor used in component transport process.
Definition: PropertyType.h:84

MaterialPropertyLib::pore_diffusion
@ pore_diffusion
Definition: PropertyType.h:73

MathLib::toVector
Eigen::Map< const Vector > toVector(std::vector< double > const &data, Eigen::VectorXd::Index size)
Creates an Eigen mapped vector from the given data vector.
Definition: EigenMapTools.h:167

MathLib::createZeroedMatrix
Eigen::Map< Matrix > createZeroedMatrix(std::vector< double > &data, Eigen::MatrixXd::Index rows, Eigen::MatrixXd::Index cols)
Definition: EigenMapTools.h:32

MathLib::toMatrix
Eigen::Map< const Matrix > toMatrix(std::vector< double > const &data, Eigen::MatrixXd::Index rows, Eigen::MatrixXd::Index cols)
Definition: EigenMapTools.h:72

NumLib::detail::assembleAdvectionMatrix
void assembleAdvectionMatrix(IPData const &ip_data_vector, std::vector< FluxVectorType > const &ip_flux_vector, Eigen::MatrixBase< Derived > &laplacian_matrix)
Definition: AdvectionMatrixAssembler.h:24

NumLib::detail::shapeFunctionInterpolate
void shapeFunctionInterpolate(const NodalValues &, const ShapeMatrix &)
Definition: Interpolation.h:27

NumLib::getIndices
std::vector< GlobalIndexType > getIndices(std::size_t const mesh_item_id, NumLib::LocalToGlobalIndexMap const &dof_table)
Definition: DOFTableUtil.cpp:124

NumLib::initShapeMatrices
std::vector< typename ShapeMatricesType::ShapeMatrices, Eigen::aligned_allocator< typename ShapeMatricesType::ShapeMatrices > > initShapeMatrices(MeshLib::Element const &e, bool const is_axially_symmetric, IntegrationMethod const &integration_method)
Definition: InitShapeMatrices.h:53

NumLib::computeShapeMatrices
std::vector< typename ShapeMatricesType::ShapeMatrices, Eigen::aligned_allocator< typename ShapeMatricesType::ShapeMatrices > > computeShapeMatrices(MeshLib::Element const &e, bool const is_axially_symmetric, PointContainer const &points)
Definition: InitShapeMatrices.h:25

NumLib::computeHydrodynamicDispersion
Eigen::MatrixXd computeHydrodynamicDispersion(NumericalStabilization const &stabilizer, std::size_t const element_id, Eigen::MatrixXd const &pore_diffusion_coefficient, Eigen::VectorXd const &velocity, double const porosity, double const solute_dispersivity_transverse, double const solute_dispersivity_longitudinal)
Definition: HydrodynamicDispersion.h:71

ProcessLib
Definition: ProjectData.h:51

EigenFixedShapeMatrixPolicy
Definition: ShapeMatrixPolicy.h:73

EigenFixedShapeMatrixPolicy::ShapeMatrices
NumLib::ShapeMatrices< NodalRowVectorType, DimNodalMatrixType, DimMatrixType, GlobalDimNodalMatrixType > ShapeMatrices
Definition: ShapeMatrixPolicy.h:89

EigenFixedShapeMatrixPolicy::GlobalDimNodalMatrixType
MatrixType< GlobalDim, ShapeFunction::NPOINTS > GlobalDimNodalMatrixType
Definition: ShapeMatrixPolicy.h:83

EigenFixedShapeMatrixPolicy::GlobalDimMatrixType
MatrixType< GlobalDim, GlobalDim > GlobalDimMatrixType
Definition: ShapeMatrixPolicy.h:84

EigenFixedShapeMatrixPolicy::GlobalDimVectorType
VectorType< GlobalDim > GlobalDimVectorType
Definition: ShapeMatrixPolicy.h:85

EigenFixedShapeMatrixPolicy::NodalVectorType
VectorType< ShapeFunction::NPOINTS > NodalVectorType
Definition: ShapeMatrixPolicy.h:76

EigenFixedShapeMatrixPolicy::NodalRowVectorType
RowVectorType< ShapeFunction::NPOINTS > NodalRowVectorType
Definition: ShapeMatrixPolicy.h:78

ParameterLib::Parameter::getNodalValuesOnElement
virtual Eigen::Matrix< T, Eigen::Dynamic, Eigen::Dynamic > getNodalValuesOnElement(MeshLib::Element const &element, double const t) const
Returns a matrix of values for all nodes of the given element.
Definition: Parameter.h:164

ProcessLib::ComponentTransport::ComponentTransportProcessData
Definition: ComponentTransportProcessData.h:40

ProcessLib::ComponentTransport::ComponentTransportProcessData::stabilizer
NumLib::NumericalStabilization stabilizer
Definition: ComponentTransportProcessData.h:73

ProcessLib::ComponentTransport::ComponentTransportProcessData::projected_specific_body_force_vectors
std::vector< Eigen::VectorXd > const projected_specific_body_force_vectors
Projected specific body force vector: R * R^T * b.
Definition: ComponentTransportProcessData.h:76

ProcessLib::ComponentTransport::ComponentTransportProcessData::media_map
MaterialPropertyLib::MaterialSpatialDistributionMap media_map
Definition: ComponentTransportProcessData.h:41

ProcessLib::ComponentTransport::ComponentTransportProcessData::chemical_solver_interface
ChemistryLib::ChemicalSolverInterface *const chemical_solver_interface
Definition: ComponentTransportProcessData.h:70

ProcessLib::ComponentTransport::ComponentTransportProcessData::hydraulic_process_id
static const int hydraulic_process_id
Definition: ComponentTransportProcessData.h:85

ProcessLib::ComponentTransport::ComponentTransportProcessData::aperture_size
ParameterLib::Parameter< double > const  & aperture_size
Definition: ComponentTransportProcessData.h:82

ProcessLib::ComponentTransport::ComponentTransportProcessData::mesh_prop_velocity
MeshLib::PropertyVector< double > * mesh_prop_velocity
Definition: ComponentTransportProcessData.h:93

ProcessLib::ComponentTransport::ComponentTransportProcessData::non_advective_form
bool const non_advective_form
Definition: ComponentTransportProcessData.h:43

ProcessLib::ComponentTransport::ComponentTransportProcessData::has_gravity
bool const has_gravity
Definition: ComponentTransportProcessData.h:42

ProcessLib::ComponentTransport::ComponentTransportProcessData::temperature
ParameterLib::Parameter< double > const  *const temperature
Definition: ComponentTransportProcessData.h:46

ProcessLib::ComponentTransport::ComponentTransportProcessData::chemically_induced_porosity_change
bool const chemically_induced_porosity_change
Definition: ComponentTransportProcessData.h:69

ProcessLib::ComponentTransport::ComponentTransportProcessData::mesh_prop_porosity
MeshLib::PropertyVector< double > * mesh_prop_porosity
Definition: ComponentTransportProcessData.h:94

ProcessLib::ComponentTransport::IntegrationPointData
Definition: ComponentTransportFEM.h:42

ProcessLib::ComponentTransport::IntegrationPointData::porosity
double porosity
Definition: ComponentTransportFEM.h:59

ProcessLib::ComponentTransport::IntegrationPointData::pushBackState
void pushBackState()
Definition: ComponentTransportFEM.h:50

ProcessLib::ComponentTransport::IntegrationPointData::dNdx
GlobalDimNodalMatrixType const dNdx
Definition: ComponentTransportFEM.h:52

ProcessLib::ComponentTransport::IntegrationPointData::chemical_system_id
GlobalIndexType chemical_system_id
Definition: ComponentTransportFEM.h:57

ProcessLib::ComponentTransport::IntegrationPointData::EIGEN_MAKE_ALIGNED_OPERATOR_NEW
EIGEN_MAKE_ALIGNED_OPERATOR_NEW
Definition: ComponentTransportFEM.h:61

ProcessLib::ComponentTransport::IntegrationPointData::N
NodalRowVectorType const N
Definition: ComponentTransportFEM.h:51

ProcessLib::ComponentTransport::IntegrationPointData::porosity_prev
double porosity_prev
Definition: ComponentTransportFEM.h:60

ProcessLib::ComponentTransport::IntegrationPointData::IntegrationPointData
IntegrationPointData(NodalRowVectorType const &N_, GlobalDimNodalMatrixType const &dNdx_, double const &integration_weight_)
Definition: ComponentTransportFEM.h:43

ProcessLib::ComponentTransport::IntegrationPointData::integration_weight
double const integration_weight
Definition: ComponentTransportFEM.h:53