master-6aae17/doxygen/transport__dg_8cc_source.html

 /*!
 *
  * Copyright (C) 2015 Technical University of Liberec.  All rights reserved.
 *
 * This program is free software; you can redistribute it and/or modify it under
 * the terms of the GNU General Public License version 3 as published by the
 * Free Software Foundation. (http://www.gnu.org/licenses/gpl-3.0.en.html)
 *
 * This program is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
 * FOR A PARTICULAR PURPOSE.  See the GNU General Public License for more details.
 *
 *
 * @file    transport_dg.cc
 * @brief   Discontinuous Galerkin method for equation of transport with dispersion.
 * @author  Jan Stebel
 */

 #include "system/sys_profiler.hh"
 #include "transport/transport_dg.hh"

 #include "io/output_time.hh"
 #include "quadrature/quadrature_lib.hh"
 #include "fem/mapping_p1.hh"
 #include "fem/fe_values.hh"
 #include "fem/fe_p.hh"
 #include "fem/fe_rt.hh"
 #include "fem/dh_cell_accessor.hh"
 #include "fields/field_fe.hh"
 #include "fields/fe_value_handler.hh"
 #include "la/linsys_PETSC.hh"
 #include "flow/mh_dofhandler.hh"
 #include "transport/advection_diffusion_model.hh"
 #include "transport/concentration_model.hh"
 #include "transport/heat_model.hh"
 #include "coupling/balance.hh"

 #include "fields/multi_field.hh"
 #include "fields/generic_field.hh"
 #include "input/factory.hh"
 #include "fields/equation_output.hh"
 #include "mesh/long_idx.hh"
 #include "mesh/accessors.hh"

 FLOW123D_FORCE_LINK_IN_CHILD(concentrationTransportModel);
 FLOW123D_FORCE_LINK_IN_CHILD(heatModel);


 using namespace Input::Type;

 template<class Model>
 const Selection & TransportDG<Model>::get_dg_variant_selection_input_type() {
     return Selection("DG_variant", "Type of penalty term.")
         .add_value(non_symmetric, "non-symmetric", "non-symmetric weighted interior penalty DG method")
         .add_value(incomplete,    "incomplete",    "incomplete weighted interior penalty DG method")
         .add_value(symmetric,     "symmetric",     "symmetric weighted interior penalty DG method")
         .close();
 }

 /*
 *  Should be removed
 template<class Model>
 const Selection & TransportDG<Model>::EqData::get_output_selection() {
     return Model::ModelEqData::get_output_selection_input_type(
             "DG",
             "Implicit in time Discontinuous Galerkin solver")
         .copy_values(EqData().make_output_field_selection("").close())
         ConvectionTransport::EqData().output_fields
                                     .make_output_field_selection(
                                         "ConvectionTransport_output_fields",
                                         "Selection of output fields for Convection Solute Transport model.")
                                     .close()),
         .close();
 }
 */

 template<class Model>
 const Record & TransportDG<Model>::get_input_type() {
     std::string equation_name = std::string(Model::ModelEqData::name()) + "_DG";
     return Model::get_input_type("DG", "Discontinuous Galerkin (DG) solver")
         .declare_key("solver", LinSys_PETSC::get_input_type(), Default("{}"),
                 "Solver for the linear system.")
         .declare_key("input_fields", Array(
                 TransportDG<Model>::EqData()
                     .make_field_descriptor_type(equation_name)),
                 IT::Default::obligatory(),
                 "Input fields of the equation.")
         .declare_key("dg_variant", TransportDG<Model>::get_dg_variant_selection_input_type(), Default("\"non-symmetric\""),
                 "Variant of the interior penalty discontinuous Galerkin method.")
         .declare_key("dg_order", Integer(0,3), Default("1"),
                 "Polynomial order for the finite element in DG method (order 0 is suitable if there is no diffusion/dispersion).")
         .declare_key("output",
                 EqData().output_fields.make_output_type(equation_name, ""),
                 IT::Default("{ \"fields\": [ " + Model::ModelEqData::default_output_field() + "] }"),
                 "Specification of output fields and output times.")
         .close();
 }

 template<class Model>
 const int TransportDG<Model>::registrar =
         Input::register_class< TransportDG<Model>, Mesh &, const Input::Record>(std::string(Model::ModelEqData::name()) + "_DG") +
         TransportDG<Model>::get_input_type().size();


 FEObjects::FEObjects(Mesh *mesh_, unsigned int fe_order)
 {
     unsigned int q_order;

     q_order = 2*fe_order;
     fe0_ = new FE_P_disc<0>(fe_order);
     fe1_ = new FE_P_disc<1>(fe_order);
     fe2_ = new FE_P_disc<2>(fe_order);
     fe3_ = new FE_P_disc<3>(fe_order);

     fe_rt1_ = new FE_RT0<1>;
     fe_rt2_ = new FE_RT0<2>;
     fe_rt3_ = new FE_RT0<3>;

     q0_ = new QGauss<0>(q_order);
     q1_ = new QGauss<1>(q_order);
     q2_ = new QGauss<2>(q_order);
     q3_ = new QGauss<3>(q_order);

     map1_ = new MappingP1<1,3>;
     map2_ = new MappingP1<2,3>;
     map3_ = new MappingP1<3,3>;

     ds_ = std::make_shared<EqualOrderDiscreteSpace>(mesh_, fe0_, fe1_, fe2_, fe3_);
     dh_ = std::make_shared<DOFHandlerMultiDim>(*mesh_);

     dh_->distribute_dofs(ds_);
 }


 FEObjects::~FEObjects()
 {
     delete fe0_;
     delete fe1_;
     delete fe2_;
     delete fe3_;
     delete fe_rt1_;
     delete fe_rt2_;
     delete fe_rt3_;
     delete q0_;
     delete q1_;
     delete q2_;
     delete q3_;
     delete map1_;
     delete map2_;
     delete map3_;
 }

 template<> FiniteElement<0> *FEObjects::fe<0>() { return fe0_; }
 template<> FiniteElement<1> *FEObjects::fe<1>() { return fe1_; }
 template<> FiniteElement<2> *FEObjects::fe<2>() { return fe2_; }
 template<> FiniteElement<3> *FEObjects::fe<3>() { return fe3_; }

 template<> FiniteElement<0> *FEObjects::fe_rt<0>() { return 0; }
 template<> FiniteElement<1> *FEObjects::fe_rt<1>() { return fe_rt1_; }
 template<> FiniteElement<2> *FEObjects::fe_rt<2>() { return fe_rt2_; }
 template<> FiniteElement<3> *FEObjects::fe_rt<3>() { return fe_rt3_; }

 template<> Quadrature<0> *FEObjects::q<0>() { return q0_; }
 template<> Quadrature<1> *FEObjects::q<1>() { return q1_; }
 template<> Quadrature<2> *FEObjects::q<2>() { return q2_; }
 template<> Quadrature<3> *FEObjects::q<3>() { return q3_; }

 template<> MappingP1<1,3> *FEObjects::mapping<1>() { return map1_; }
 template<> MappingP1<2,3> *FEObjects::mapping<2>() { return map2_; }
 template<> MappingP1<3,3> *FEObjects::mapping<3>() { return map3_; }

 std::shared_ptr<DOFHandlerMultiDim> FEObjects::dh() { return dh_; }


 template<class Model>
 TransportDG<Model>::EqData::EqData() : Model::ModelEqData()
 {
     *this+=fracture_sigma
             .name("fracture_sigma")
             .description(
             "Coefficient of diffusive transfer through fractures (for each substance).")
             .units( UnitSI::dimensionless() )
             .input_default("1.0")
             .flags_add(FieldFlag::in_main_matrix);

     *this+=dg_penalty
             .name("dg_penalty")
             .description(
             "Penalty parameter influencing the discontinuity of the solution (for each substance). "
             "Its default value 1 is sufficient in most cases. Higher value diminishes the inter-element jumps.")
             .units( UnitSI::dimensionless() )
             .input_default("1.0")
             .flags_add(FieldFlag::in_rhs & FieldFlag::in_main_matrix);

     *this += region_id.name("region_id")
                 .units( UnitSI::dimensionless())
                 .flags(FieldFlag::equation_external_output)
                 .description("Region ids.");

     *this += subdomain.name("subdomain")
       .units( UnitSI::dimensionless() )
       .flags(FieldFlag::equation_external_output)
       .description("Subdomain ids of the domain decomposition.");


     // add all input fields to the output list
     output_fields += *this;

 }

 template<class Model>
 TransportDG<Model>::TransportDG(Mesh & init_mesh, const Input::Record in_rec)
         : Model(init_mesh, in_rec),
           input_rec(in_rec),
           allocation_done(false)
 {
     // Can not use name() + "constructor" here, since START_TIMER only accepts const char *
     // due to constexpr optimization.
     START_TIMER(Model::ModelEqData::name());
     // Check that Model is derived from AdvectionDiffusionModel.
     static_assert(std::is_base_of<AdvectionDiffusionModel, Model>::value, "");

     this->eq_data_ = &data_;


     // Set up physical parameters.
     data_.set_mesh(init_mesh);
     data_.region_id = GenericField<3>::region_id(*Model::mesh_);
     data_.subdomain = GenericField<3>::subdomain(*Model::mesh_);


     // DG variant and order
     dg_variant = in_rec.val<DGVariant>("dg_variant");
     dg_order = in_rec.val<unsigned int>("dg_order");

     Model::init_from_input(in_rec);

     // create finite element structures and distribute DOFs
     feo = new FEObjects(Model::mesh_, dg_order);
     //DebugOut().fmt("TDG: solution size {}\n", feo->dh()->n_global_dofs());

 }


 template<class Model>
 void TransportDG<Model>::initialize()
 {
     data_.set_components(Model::substances_.names());
     data_.set_input_list( input_rec.val<Input::Array>("input_fields"), *(Model::time_) );

     // DG stabilization parameters on boundary edges
     gamma.resize(Model::n_substances());
     for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
         gamma[sbi].resize(Model::mesh_->boundary_.size());

     // Resize coefficient arrays
     int qsize = max(feo->q<0>()->size(), max(feo->q<1>()->size(), max(feo->q<2>()->size(), feo->q<3>()->size())));
     int max_edg_sides = max(Model::mesh_->max_edge_sides(1), max(Model::mesh_->max_edge_sides(2), Model::mesh_->max_edge_sides(3)));
     mm_coef.resize(qsize);
     ret_coef.resize(Model::n_substances());
     ret_sources.resize(Model::n_substances());
     ret_sources_prev.resize(Model::n_substances());
     ad_coef.resize(Model::n_substances());
     dif_coef.resize(Model::n_substances());
     for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
     {
         ret_coef[sbi].resize(qsize);
         ad_coef[sbi].resize(qsize);
         dif_coef[sbi].resize(qsize);
     }
     ad_coef_edg.resize(max_edg_sides);
     dif_coef_edg.resize(max_edg_sides);
     for (int sd=0; sd<max_edg_sides; sd++)
     {
         ad_coef_edg[sd].resize(Model::n_substances());
         dif_coef_edg[sd].resize(Model::n_substances());
         for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
         {
             ad_coef_edg[sd][sbi].resize(qsize);
             dif_coef_edg[sd][sbi].resize(qsize);
         }
     }

     output_vec.resize(Model::n_substances());
     data_.output_field.set_components(Model::substances_.names());
     data_.output_field.set_mesh(*Model::mesh_);
     data_.output_type(OutputTime::CORNER_DATA);

     data_.output_field.setup_components();
     for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
     {
         // create shared pointer to a FieldFE, pass FE data and push this FieldFE to output_field on all regions
         std::shared_ptr<FieldFE<3, FieldValue<3>::Scalar> > output_field_ptr(new FieldFE<3, FieldValue<3>::Scalar>);
         output_vec[sbi] = output_field_ptr->set_fe_data(feo->dh());
         data_.output_field[sbi].set_field(Model::mesh_->region_db().get_region_set("ALL"), output_field_ptr, 0);
     }

     // set time marks for writing the output
     data_.output_fields.initialize(Model::output_stream_, Model::mesh_, input_rec.val<Input::Record>("output"), this->time());

     // equation default PETSc solver options
     std::string petsc_default_opts;
     if (feo->dh()->distr()->np() == 1)
       petsc_default_opts = "-ksp_type bcgs -pc_type ilu -pc_factor_levels 2 -ksp_diagonal_scale_fix -pc_factor_fill 6.0";
     else
       petsc_default_opts = "-ksp_type bcgs -ksp_diagonal_scale_fix -pc_type asm -pc_asm_overlap 4 -sub_pc_type ilu -sub_pc_factor_levels 3 -sub_pc_factor_fill 6.0";

     // allocate matrix and vector structures
     ls    = new LinSys*[Model::n_substances()];
     ls_dt = new LinSys*[Model::n_substances()];
     solution_elem_ = new double*[Model::n_substances()];

     stiffness_matrix.resize(Model::n_substances(), nullptr);
     mass_matrix.resize(Model::n_substances(), nullptr);
     rhs.resize(Model::n_substances(), nullptr);
     mass_vec.resize(Model::n_substances(), nullptr);
     ret_vec.resize(Model::n_substances(), nullptr);

     for (unsigned int sbi = 0; sbi < Model::n_substances(); sbi++) {
         ls[sbi] = new LinSys_PETSC(feo->dh()->distr().get(), petsc_default_opts);
         ( (LinSys_PETSC *)ls[sbi] )->set_from_input( input_rec.val<Input::Record>("solver") );
         ls[sbi]->set_solution(output_vec[sbi].petsc_vec());

         ls_dt[sbi] = new LinSys_PETSC(feo->dh()->distr().get(), petsc_default_opts);
         ( (LinSys_PETSC *)ls_dt[sbi] )->set_from_input( input_rec.val<Input::Record>("solver") );
         solution_elem_[sbi] = new double[Model::mesh_->get_el_ds()->lsize()];

         VecDuplicate(ls[sbi]->get_solution(), &ret_vec[sbi]);
     }


     // initialization of balance object
     Model::balance_->allocate(feo->dh()->distr()->lsize(),
             max(feo->fe<1>()->n_dofs(), max(feo->fe<2>()->n_dofs(), feo->fe<3>()->n_dofs())));

 }


 template<class Model>
 TransportDG<Model>::~TransportDG()
 {
     delete Model::time_;

     if (gamma.size() > 0) {
         // initialize called

         for (unsigned int i=0; i<Model::n_substances(); i++)
         {
             delete ls[i];
             delete[] solution_elem_[i];
             delete ls_dt[i];

             if (stiffness_matrix[i])
                 chkerr(MatDestroy(&stiffness_matrix[i]));
             if (mass_matrix[i])
                 chkerr(MatDestroy(&mass_matrix[i]));
             if (rhs[i])
                 chkerr(VecDestroy(&rhs[i]));
             if (mass_vec[i])
                 chkerr(VecDestroy(&mass_vec[i]));
             if (ret_vec[i])
                 chkerr(VecDestroy(&ret_vec[i]));
         }
         delete[] ls;
         delete[] solution_elem_;
         delete[] ls_dt;
         //delete[] stiffness_matrix;
         //delete[] mass_matrix;
         //delete[] rhs;
         //delete[] mass_vec;
         //delete[] ret_vec;
         delete feo;

     }

 }


 template<class Model>
 void TransportDG<Model>::zero_time_step()
 {
     START_TIMER(Model::ModelEqData::name());
     data_.mark_input_times( *(Model::time_) );
     data_.set_time(Model::time_->step(), LimitSide::left);
     std::stringstream ss; // print warning message with table of uninitialized fields
     if ( FieldCommon::print_message_table(ss, "transport DG") ) {
         WarningOut() << ss.str();
     }


     // set initial conditions
     set_initial_condition();
     for (unsigned int sbi = 0; sbi < Model::n_substances(); sbi++)
         ( (LinSys_PETSC *)ls[sbi] )->set_initial_guess_nonzero();

     // check first time assembly - needs preallocation
     if (!allocation_done) preallocate();

     // after preallocation we assemble the matrices and vectors required for mass balance
     for (unsigned int sbi=0; sbi<Model::n_substances(); ++sbi)
     {
         Model::balance_->calculate_instant(Model::subst_idx[sbi], ls[sbi]->get_solution());

         // add sources due to sorption
         ret_sources_prev[sbi] = 0;
     }

     output_data();
 }


 template<class Model>
 void TransportDG<Model>::preallocate()
 {
     // preallocate system matrix
     for (unsigned int i=0; i<Model::n_substances(); i++)
     {
         // preallocate system matrix
         ls[i]->start_allocation();
         stiffness_matrix[i] = NULL;
         rhs[i] = NULL;

         // preallocate mass matrix
         ls_dt[i]->start_allocation();
         mass_matrix[i] = NULL;
         VecZeroEntries(ret_vec[i]);
     }
     assemble_stiffness_matrix();
     assemble_mass_matrix();
     set_sources();
     set_boundary_conditions();
     for (unsigned int i=0; i<Model::n_substances(); i++)
     {
       VecAssemblyBegin(ret_vec[i]);
       VecAssemblyEnd(ret_vec[i]);
     }

     allocation_done = true;
 }


 template<class Model>
 void TransportDG<Model>::update_solution()
 {
     START_TIMER("DG-ONE STEP");

     Model::time_->next_time();
     Model::time_->view("TDG");

     START_TIMER("data reinit");
     data_.set_time(Model::time_->step(), LimitSide::left);
     END_TIMER("data reinit");

     // assemble mass matrix
     if (mass_matrix[0] == NULL || data_.subset(FieldFlag::in_time_term).changed() )
     {
         for (unsigned int i=0; i<Model::n_substances(); i++)
         {
             ls_dt[i]->start_add_assembly();
             ls_dt[i]->mat_zero_entries();
             VecZeroEntries(ret_vec[i]);
         }
         assemble_mass_matrix();
         for (unsigned int i=0; i<Model::n_substances(); i++)
         {
             ls_dt[i]->finish_assembly();
             VecAssemblyBegin(ret_vec[i]);
             VecAssemblyEnd(ret_vec[i]);
             // construct mass_vec for initial time
             if (mass_matrix[i] == NULL)
             {
                 VecDuplicate(ls[i]->get_solution(), &mass_vec[i]);
                 MatMult(*(ls_dt[i]->get_matrix()), ls[i]->get_solution(), mass_vec[i]);
                 MatConvert(*( ls_dt[i]->get_matrix() ), MATSAME, MAT_INITIAL_MATRIX, &mass_matrix[i]);
             }
             else
                 MatCopy(*( ls_dt[i]->get_matrix() ), mass_matrix[i], DIFFERENT_NONZERO_PATTERN);
         }
     }

     // assemble stiffness matrix
     if (stiffness_matrix[0] == NULL
             || data_.subset(FieldFlag::in_main_matrix).changed()
             || Model::flux_changed)
     {
         // new fluxes can change the location of Neumann boundary,
         // thus stiffness matrix must be reassembled
         for (unsigned int i=0; i<Model::n_substances(); i++)
         {
             ls[i]->start_add_assembly();
             ls[i]->mat_zero_entries();
         }
         assemble_stiffness_matrix();
         for (unsigned int i=0; i<Model::n_substances(); i++)
         {
             ls[i]->finish_assembly();

             if (stiffness_matrix[i] == NULL)
                 MatConvert(*( ls[i]->get_matrix() ), MATSAME, MAT_INITIAL_MATRIX, &stiffness_matrix[i]);
             else
                 MatCopy(*( ls[i]->get_matrix() ), stiffness_matrix[i], DIFFERENT_NONZERO_PATTERN);
         }
     }

     // assemble right hand side (due to sources and boundary conditions)
     if (rhs[0] == NULL
             || data_.subset(FieldFlag::in_rhs).changed()
             || Model::flux_changed)
     {
         for (unsigned int i=0; i<Model::n_substances(); i++)
         {
             ls[i]->start_add_assembly();
             ls[i]->rhs_zero_entries();
         }
         set_sources();
         set_boundary_conditions();
         for (unsigned int i=0; i<Model::n_substances(); i++)
         {
             ls[i]->finish_assembly();

             if (rhs[i] == nullptr) VecDuplicate(*( ls[i]->get_rhs() ), &rhs[i]);
             VecCopy(*( ls[i]->get_rhs() ), rhs[i]);
         }
     }

     Model::flux_changed = false;


     /* Apply backward Euler time integration.
     *
     * Denoting A the stiffness matrix and M the mass matrix, the algebraic system at the k-th time level reads
     *
     *   (1/dt M + A)u^k = f + 1/dt M.u^{k-1}
     *
     * Hence we modify at each time level the right hand side:
     *
     *   f^k = f + 1/dt M u^{k-1},
     *
     * where f stands for the term stemming from the force and boundary conditions.
     * Accordingly, we set
     *
     *   A^k = A + 1/dt M.
     *
     */
     Mat m;
     START_TIMER("solve");
     for (unsigned int i=0; i<Model::n_substances(); i++)
     {
         MatConvert(stiffness_matrix[i], MATSAME, MAT_INITIAL_MATRIX, &m);
         MatAXPY(m, 1./Model::time_->dt(), mass_matrix[i], SUBSET_NONZERO_PATTERN);
         ls[i]->set_matrix(m, DIFFERENT_NONZERO_PATTERN);
         Vec w;
         VecDuplicate(rhs[i], &w);
         VecWAXPY(w, 1./Model::time_->dt(), mass_vec[i], rhs[i]);
         ls[i]->set_rhs(w);

         VecDestroy(&w);
         chkerr(MatDestroy(&m));

         ls[i]->solve();

         // update mass_vec due to possible changes in mass matrix
         MatMult(*(ls_dt[i]->get_matrix()), ls[i]->get_solution(), mass_vec[i]);
     }
     END_TIMER("solve");

     calculate_cumulative_balance();

     END_TIMER("DG-ONE STEP");
 }


 template<class Model>
 void TransportDG<Model>::calculate_concentration_matrix()
 {
     // calculate element averages of solution
     unsigned int i_cell=0;
     for (auto cell : feo->dh()->own_range() )
     {

         unsigned int n_dofs;
         switch (cell.dim())
         {
         case 1:
             n_dofs = feo->fe<1>()->n_dofs();
             break;
         case 2:
             n_dofs = feo->fe<2>()->n_dofs();
             break;
         case 3:
             n_dofs = feo->fe<3>()->n_dofs();
             break;
         }

         std::vector<LongIdx> dof_indices(n_dofs);
         cell.get_dof_indices(dof_indices);

         for (unsigned int sbi=0; sbi<Model::n_substances(); ++sbi)
         {
             solution_elem_[sbi][i_cell] = 0;

             for (unsigned int j=0; j<n_dofs; ++j)
                 solution_elem_[sbi][i_cell] += ls[sbi]->get_solution_array()[dof_indices[j]-feo->dh()->distr()->begin()];

             solution_elem_[sbi][i_cell] = max(solution_elem_[sbi][i_cell]/n_dofs, 0.);
         }
         ++i_cell;
     }
 }


 template<class Model>
 void TransportDG<Model>::output_data()
 {
     //if (!Model::time_->is_current( Model::time_->marks().type_output() )) return;


     START_TIMER("DG-OUTPUT");

     // gather the solution from all processors
     data_.output_fields.set_time( this->time().step(), LimitSide::left);
     //if (data_.output_fields.is_field_output_time(data_.output_field, this->time().step()) )
     data_.output_fields.output(this->time().step());

     Model::output_data();

     START_TIMER("TOS-balance");
     for (unsigned int sbi=0; sbi<Model::n_substances(); ++sbi)
       Model::balance_->calculate_instant(Model::subst_idx[sbi], ls[sbi]->get_solution());
     Model::balance_->output();
     END_TIMER("TOS-balance");

     END_TIMER("DG-OUTPUT");
 }


 template<class Model>
 void TransportDG<Model>::calculate_cumulative_balance()
 {
     if (Model::balance_->cumulative())
     {
         for (unsigned int sbi=0; sbi<Model::n_substances(); ++sbi)
         {
             Model::balance_->calculate_cumulative(Model::subst_idx[sbi], ls[sbi]->get_solution());

             // update source increment due to retardation
             VecDot(ret_vec[sbi], ls[sbi]->get_solution(), &ret_sources[sbi]);

             Model::balance_->add_cumulative_source(Model::subst_idx[sbi], (ret_sources[sbi]-ret_sources_prev[sbi])/Model::time_->dt());
             ret_sources_prev[sbi] = ret_sources[sbi];
         }
     }
 }


 template<class Model>
 void TransportDG<Model>::assemble_mass_matrix()
 {
   START_TIMER("assemble_mass");
     Model::balance_->start_mass_assembly(Model::subst_idx);
     assemble_mass_matrix<1>();
     assemble_mass_matrix<2>();
     assemble_mass_matrix<3>();
     Model::balance_->finish_mass_assembly(Model::subst_idx);
   END_TIMER("assemble_mass");
 }


 template<class Model> template<unsigned int dim>
 void TransportDG<Model>::assemble_mass_matrix()
 {
     FEValues<dim,3> fe_values(*feo->mapping<dim>(), *feo->q<dim>(), *feo->fe<dim>(), update_values | update_JxW_values | update_quadrature_points);
     const unsigned int ndofs = feo->fe<dim>()->n_dofs(), qsize = feo->q<dim>()->size();
     vector<LongIdx> dof_indices(ndofs);
     PetscScalar local_mass_matrix[ndofs*ndofs], local_retardation_balance_vector[ndofs];
     vector<PetscScalar> local_mass_balance_vector(ndofs);

     // assemble integral over elements
     for (auto cell : feo->dh()->own_range() )
     {
         if (cell.dim() != dim) continue;
         ElementAccessor<3> elm = cell.elm();

         fe_values.reinit(elm);
         cell.get_dof_indices(dof_indices);

         Model::compute_mass_matrix_coefficient(fe_values.point_list(), elm, mm_coef);
         Model::compute_retardation_coefficient(fe_values.point_list(), elm, ret_coef);

         for (unsigned int sbi=0; sbi<Model::n_substances(); ++sbi)
         {
             // assemble the local mass matrix
             for (unsigned int i=0; i<ndofs; i++)
             {
                 for (unsigned int j=0; j<ndofs; j++)
                 {
                     local_mass_matrix[i*ndofs+j] = 0;
                     for (unsigned int k=0; k<qsize; k++)
                         local_mass_matrix[i*ndofs+j] += (mm_coef[k]+ret_coef[sbi][k])*fe_values.shape_value(j,k)*fe_values.shape_value(i,k)*fe_values.JxW(k);
                 }
             }

             for (unsigned int i=0; i<ndofs; i++)
             {
                     local_mass_balance_vector[i] = 0;
                     local_retardation_balance_vector[i] = 0;
                     for (unsigned int k=0; k<qsize; k++)
                     {
                         local_mass_balance_vector[i] += mm_coef[k]*fe_values.shape_value(i,k)*fe_values.JxW(k);
                         local_retardation_balance_vector[i] -= ret_coef[sbi][k]*fe_values.shape_value(i,k)*fe_values.JxW(k);
                     }
             }

             Model::balance_->add_mass_matrix_values(Model::subst_idx[sbi], elm.region().bulk_idx(), dof_indices, local_mass_balance_vector);
             ls_dt[sbi]->mat_set_values(ndofs, &(dof_indices[0]), ndofs, &(dof_indices[0]), local_mass_matrix);
             VecSetValues(ret_vec[sbi], ndofs, &(dof_indices[0]), local_retardation_balance_vector, ADD_VALUES);
         }
     }
 }


 template<class Model>
 void TransportDG<Model>::assemble_stiffness_matrix()
 {
   START_TIMER("assemble_stiffness");
   START_TIMER("assemble_volume_integrals");
     assemble_volume_integrals<1>();
     assemble_volume_integrals<2>();
     assemble_volume_integrals<3>();
   END_TIMER("assemble_volume_integrals");

   START_TIMER("assemble_fluxes_boundary");
     assemble_fluxes_boundary<1>();
     assemble_fluxes_boundary<2>();
     assemble_fluxes_boundary<3>();
   END_TIMER("assemble_fluxes_boundary");

   START_TIMER("assemble_fluxes_elem_elem");
     assemble_fluxes_element_element<1>();
     assemble_fluxes_element_element<2>();
     assemble_fluxes_element_element<3>();
   END_TIMER("assemble_fluxes_elem_elem");

   START_TIMER("assemble_fluxes_elem_side");
     assemble_fluxes_element_side<1>();
     assemble_fluxes_element_side<2>();
     assemble_fluxes_element_side<3>();
   END_TIMER("assemble_fluxes_elem_side");
   END_TIMER("assemble_stiffness");
 }


 template<class Model>
 template<unsigned int dim>
 void TransportDG<Model>::assemble_volume_integrals()
 {
     FEValues<dim,3> fv_rt(*feo->mapping<dim>(), *feo->q<dim>(), *feo->fe_rt<dim>(),
             update_values | update_gradients);
     FEValues<dim,3> fe_values(*feo->mapping<dim>(), *feo->q<dim>(), *feo->fe<dim>(),
             update_values | update_gradients | update_JxW_values | update_quadrature_points);
     const unsigned int ndofs = feo->fe<dim>()->n_dofs(), qsize = feo->q<dim>()->size();
     std::vector<LongIdx> dof_indices(ndofs);
     vector<arma::vec3> velocity(qsize);
     vector<vector<double> > sources_sigma(Model::n_substances(), std::vector<double>(qsize));
     PetscScalar local_matrix[ndofs*ndofs];

     // assemble integral over elements
     for (auto cell : feo->dh()->local_range() )
     {
         if (!cell.is_own()) continue;
         if (cell.dim() != dim) continue;
         ElementAccessor<3> elm = cell.elm();

         fe_values.reinit(elm);
         fv_rt.reinit(elm);
         cell.get_dof_indices(dof_indices);

         calculate_velocity(elm, velocity, fv_rt);
         Model::compute_advection_diffusion_coefficients(fe_values.point_list(), velocity, elm, ad_coef, dif_coef);
         Model::compute_sources_sigma(fe_values.point_list(), elm, sources_sigma);

         // assemble the local stiffness matrix
         for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
         {
             for (unsigned int i=0; i<ndofs; i++)
                 for (unsigned int j=0; j<ndofs; j++)
                     local_matrix[i*ndofs+j] = 0;

             for (unsigned int k=0; k<qsize; k++)
             {
                 for (unsigned int i=0; i<ndofs; i++)
                 {
                     arma::vec3 Kt_grad_i = dif_coef[sbi][k].t()*fe_values.shape_grad(i,k);
                     double ad_dot_grad_i = arma::dot(ad_coef[sbi][k], fe_values.shape_grad(i,k));

                     for (unsigned int j=0; j<ndofs; j++)
                         local_matrix[i*ndofs+j] += (arma::dot(Kt_grad_i, fe_values.shape_grad(j,k))
                                                   -fe_values.shape_value(j,k)*ad_dot_grad_i
                                                   +sources_sigma[sbi][k]*fe_values.shape_value(j,k)*fe_values.shape_value(i,k))*fe_values.JxW(k);
                 }
             }
             ls[sbi]->mat_set_values(ndofs, &(dof_indices[0]), ndofs, &(dof_indices[0]), local_matrix);
         }
     }
 }


 template<class Model>
 void TransportDG<Model>::set_sources()
 {
   START_TIMER("assemble_sources");
     Model::balance_->start_source_assembly(Model::subst_idx);
     set_sources<1>();
     set_sources<2>();
     set_sources<3>();
     Model::balance_->finish_source_assembly(Model::subst_idx);
   END_TIMER("assemble_sources");
 }

 template<class Model>
 template<unsigned int dim>
 void TransportDG<Model>::set_sources()
 {
     FEValues<dim,3> fe_values(*feo->mapping<dim>(), *feo->q<dim>(), *feo->fe<dim>(),
             update_values | update_JxW_values | update_quadrature_points);
     const unsigned int ndofs = feo->fe<dim>()->n_dofs(), qsize = feo->q<dim>()->size();
     vector<std::vector<double> > sources_conc(Model::n_substances(), std::vector<double>(qsize)),
             sources_density(Model::n_substances(), std::vector<double>(qsize)),
             sources_sigma(Model::n_substances(), std::vector<double>(qsize));
     vector<LongIdx> dof_indices(ndofs);
     vector<LongIdx> loc_dof_indices(ndofs);
     PetscScalar local_rhs[ndofs];
     vector<PetscScalar> local_source_balance_vector(ndofs), local_source_balance_rhs(ndofs);
     double source;

     // assemble integral over elements
     for (auto cell : feo->dh()->own_range() )
     {
         if (cell.dim() != dim) continue;
         ElementAccessor<3> elm = cell.elm();

         fe_values.reinit(elm);
         cell.get_dof_indices(dof_indices);
         cell.get_loc_dof_indices(loc_dof_indices);

         Model::compute_source_coefficients(fe_values.point_list(), elm, sources_conc, sources_density, sources_sigma);

         // assemble the local stiffness matrix
         for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
         {
             fill_n(local_rhs, ndofs, 0);
             local_source_balance_vector.assign(ndofs, 0);
             local_source_balance_rhs.assign(ndofs, 0);

             // compute sources
             for (unsigned int k=0; k<qsize; k++)
             {
                 source = (sources_density[sbi][k] + sources_conc[sbi][k]*sources_sigma[sbi][k])*fe_values.JxW(k);

                 for (unsigned int i=0; i<ndofs; i++)
                     local_rhs[i] += source*fe_values.shape_value(i,k);
             }
             ls[sbi]->rhs_set_values(ndofs, &(dof_indices[0]), local_rhs);

             for (unsigned int i=0; i<ndofs; i++)
             {
                 for (unsigned int k=0; k<qsize; k++)
                     local_source_balance_vector[i] -= sources_sigma[sbi][k]*fe_values.shape_value(i,k)*fe_values.JxW(k);

                 local_source_balance_rhs[i] += local_rhs[i];
             }
             Model::balance_->add_source_values(Model::subst_idx[sbi], elm.region().bulk_idx(), loc_dof_indices,
                                                local_source_balance_vector, local_source_balance_rhs);
         }
     }
 }


 // return the ratio of longest and shortest edge
 double elem_anisotropy(ElementAccessor<3> e)
 {
     double h_max = 0, h_min = numeric_limits<double>::infinity();
     for (unsigned int i=0; i<e->n_nodes(); i++)
         for (unsigned int j=i+1; j<e->n_nodes(); j++)
         {
             h_max = max(h_max, e.node(i)->distance(*e.node(j)));
             h_min = min(h_min, e.node(i)->distance(*e.node(j)));
         }
     return h_max/h_min;
 }


 template<class Model>
 template<unsigned int dim>
 void TransportDG<Model>::assemble_fluxes_element_element()
 {
     vector<FESideValues<dim,3>*> fe_values;
     FESideValues<dim,3> fsv_rt(*feo->mapping<dim>(), *feo->q<dim-1>(), *feo->fe_rt<dim>(),
             update_values);
     const unsigned int ndofs = feo->fe<dim>()->n_dofs(), qsize = feo->q<dim-1>()->size(),
             n_max_sides = ad_coef_edg.size();
     vector< vector<LongIdx> > side_dof_indices;
     PetscScalar local_matrix[ndofs*ndofs];
     vector<vector<arma::vec3> > side_velocity(n_max_sides);
     vector<vector<double> > dg_penalty(n_max_sides);
     double gamma_l, omega[2], transport_flux, delta[2], delta_sum;
     double aniso1, aniso2;

     for (unsigned int sid=0; sid<n_max_sides; sid++) // Optimize: SWAP LOOPS
     {
         side_dof_indices.push_back( vector<LongIdx>(ndofs) );
         fe_values.push_back(new FESideValues<dim,3>(*feo->mapping<dim>(), *feo->q<dim-1>(), *feo->fe<dim>(),
                 update_values | update_gradients | update_side_JxW_values | update_normal_vectors | update_quadrature_points));
     }

     // assemble integral over sides
     int sid, s1, s2;
     for ( DHCellAccessor dh_cell : feo->dh()->local_range() ) {
         if (dh_cell.dim() != dim) continue;
         for( DHCellSide cell_side : dh_cell.side_range() )
         {
             if (cell_side.n_edge_sides() < 2) continue;
             bool unique_edge = (cell_side.edge_sides().begin()->side()->element().idx() != dh_cell.elm_idx());
             if ( unique_edge ) continue;
             sid=0;
             for( DHCellSide edge_side : cell_side.edge_sides() )
             {
                 auto dh_edge_cell = feo->dh()->cell_accessor_from_element( edge_side.side()->elem_idx() );
                 ElementAccessor<3> cell = dh_edge_cell.elm();
                 dh_edge_cell.get_dof_indices(side_dof_indices[sid]);
                 fe_values[sid]->reinit(cell, edge_side.side()->side_idx());
                 fsv_rt.reinit(cell, edge_side.side()->side_idx());
                 calculate_velocity(cell, side_velocity[sid], fsv_rt);
                 Model::compute_advection_diffusion_coefficients(fe_values[sid]->point_list(), side_velocity[sid], cell, ad_coef_edg[sid], dif_coef_edg[sid]);
                 dg_penalty[sid].resize(Model::n_substances());
                 for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
                     dg_penalty[sid][sbi] = data_.dg_penalty[sbi].value(cell.centre(), cell);
                 ++sid;
             }
             arma::vec3 normal_vector = fe_values[0]->normal_vector(0);

             // fluxes and penalty
             for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
             {
                 vector<double> fluxes(cell_side.n_edge_sides());
                 double pflux = 0, nflux = 0; // calculate the total in- and out-flux through the edge
                 sid=0;
                 for( DHCellSide edge_side : cell_side.edge_sides() )
                 {
                     fluxes[sid] = 0;
                     for (unsigned int k=0; k<qsize; k++)
                         fluxes[sid] += arma::dot(ad_coef_edg[sid][sbi][k], fe_values[sid]->normal_vector(k))*fe_values[sid]->JxW(k);
                     fluxes[sid] /= edge_side.side()->measure();
                     if (fluxes[sid] > 0)
                         pflux += fluxes[sid];
                     else
                         nflux += fluxes[sid];
                     ++sid;
                 }

                 s1=0;
                 for( DHCellSide edge_side1 : cell_side.edge_sides() )
                 {
                     s2=-1; // need increment at begin of loop (see conditionally 'continue' directions)
                     for( DHCellSide edge_side2 : cell_side.edge_sides() )
                     {
                         s2++;
                         if (s2<=s1) continue;
                         ASSERT(edge_side1.side()->valid()).error("Invalid side of edge.");

                         arma::vec3 nv = fe_values[s1]->normal_vector(0);

                         // set up the parameters for DG method
                         // calculate the flux from edge_side1 to edge_side2
                         if (fluxes[s2] > 0 && fluxes[s1] < 0)
                             transport_flux = fluxes[s1]*fabs(fluxes[s2]/pflux);
                         else if (fluxes[s2] < 0 && fluxes[s1] > 0)
                             transport_flux = fluxes[s1]*fabs(fluxes[s2]/nflux);
                         else
                             transport_flux = 0;

                         gamma_l = 0.5*fabs(transport_flux);

                         delta[0] = 0;
                         delta[1] = 0;
                         for (unsigned int k=0; k<qsize; k++)
                         {
                             delta[0] += dot(dif_coef_edg[s1][sbi][k]*normal_vector,normal_vector);
                             delta[1] += dot(dif_coef_edg[s2][sbi][k]*normal_vector,normal_vector);
                         }
                         delta[0] /= qsize;
                         delta[1] /= qsize;

                         delta_sum = delta[0] + delta[1];

 //                        if (delta_sum > numeric_limits<double>::epsilon())
                         if (fabs(delta_sum) > 0)
                         {
                             omega[0] = delta[1]/delta_sum;
                             omega[1] = delta[0]/delta_sum;
                             double local_alpha = max(dg_penalty[s1][sbi], dg_penalty[s2][sbi]);
                             double h = edge_side1.side()->diameter();
                             aniso1 = elem_anisotropy(edge_side1.side()->element());
                             aniso2 = elem_anisotropy(edge_side2.side()->element());
                             gamma_l += local_alpha/h*aniso1*aniso2*(delta[0]*delta[1]/delta_sum);
                         }
                         else
                             for (int i=0; i<2; i++) omega[i] = 0;
                         // end of set up the parameters for DG method

                         int sd[2]; bool is_side_own[2];
                         sd[0] = s1; is_side_own[0] = edge_side1.cell().is_own();
                         sd[1] = s2; is_side_own[1] = edge_side2.cell().is_own();

 #define AVERAGE(i,k,side_id)  (fe_values[sd[side_id]]->shape_value(i,k)*0.5)
 #define WAVERAGE(i,k,side_id) (arma::dot(dif_coef_edg[sd[side_id]][sbi][k]*fe_values[sd[side_id]]->shape_grad(i,k),nv)*omega[side_id])
 #define JUMP(i,k,side_id)     ((side_id==0?1:-1)*fe_values[sd[side_id]]->shape_value(i,k))

                         // For selected pair of elements:
                         for (int n=0; n<2; n++)
                         {
                             if (!is_side_own[n]) continue;

                             for (int m=0; m<2; m++)
                             {
                                 for (unsigned int i=0; i<fe_values[sd[n]]->n_dofs(); i++)
                                     for (unsigned int j=0; j<fe_values[sd[m]]->n_dofs(); j++)
                                         local_matrix[i*fe_values[sd[m]]->n_dofs()+j] = 0;

                                 for (unsigned int k=0; k<qsize; k++)
                                 {
                                     double flux_times_JxW = transport_flux*fe_values[0]->JxW(k);
                                     double gamma_times_JxW = gamma_l*fe_values[0]->JxW(k);

                                     for (unsigned int i=0; i<fe_values[sd[n]]->n_dofs(); i++)
                                     {
                                         double flux_JxW_jump_i = flux_times_JxW*JUMP(i,k,n);
                                         double gamma_JxW_jump_i = gamma_times_JxW*JUMP(i,k,n);
                                         double JxW_jump_i = fe_values[0]->JxW(k)*JUMP(i,k,n);
                                         double JxW_var_wavg_i = fe_values[0]->JxW(k)*WAVERAGE(i,k,n)*dg_variant;

                                         for (unsigned int j=0; j<fe_values[sd[m]]->n_dofs(); j++)
                                         {
                                             int index = i*fe_values[sd[m]]->n_dofs()+j;

                                             // flux due to transport (applied on interior edges) (average times jump)
                                             local_matrix[index] += flux_JxW_jump_i*AVERAGE(j,k,m);

                                             // penalty enforcing continuity across edges (applied on interior and Dirichlet edges) (jump times jump)
                                             local_matrix[index] += gamma_JxW_jump_i*JUMP(j,k,m);

                                             // terms due to diffusion
                                             local_matrix[index] -= WAVERAGE(j,k,m)*JxW_jump_i;
                                             local_matrix[index] -= JUMP(j,k,m)*JxW_var_wavg_i;
                                         }
                                     }
                                 }
                                 ls[sbi]->mat_set_values(fe_values[sd[n]]->n_dofs(), &(side_dof_indices[sd[n]][0]), fe_values[sd[m]]->n_dofs(), &(side_dof_indices[sd[m]][0]), local_matrix);
                             }
                         }
 #undef AVERAGE
 #undef WAVERAGE
 #undef JUMP
                     }
                 s1++;
                 }
             }
         }
     }

     for (unsigned int i=0; i<n_max_sides; i++)
     {
         delete fe_values[i];
     }
 }


 template<class Model>
 template<unsigned int dim>
 void TransportDG<Model>::assemble_fluxes_boundary()
 {
     FESideValues<dim,3> fe_values_side(*feo->mapping<dim>(), *feo->q<dim-1>(), *feo->fe<dim>(),
             update_values | update_gradients | update_side_JxW_values | update_normal_vectors | update_quadrature_points);
     FESideValues<dim,3> fsv_rt(*feo->mapping<dim>(), *feo->q<dim-1>(), *feo->fe_rt<dim>(),
             update_values);
     const unsigned int ndofs = feo->fe<dim>()->n_dofs(), qsize = feo->q<dim-1>()->size();
     std::vector<LongIdx> side_dof_indices(ndofs);
     PetscScalar local_matrix[ndofs*ndofs];
     vector<arma::vec3> side_velocity;
     vector<double> robin_sigma(qsize);
     vector<double> csection(qsize);
     double gamma_l;

     // assemble boundary integral
     for (auto cell : feo->dh()->local_range() )
     {
         if (!cell.is_own()) continue;
         for( DHCellSide cell_side : cell.side_range() )
         {
             const Side *side = cell_side.side();
             if (side->edge()->n_sides > 1) continue;
             // check spatial dimension
             if (side->dim() != dim-1) continue;
             // skip edges lying not on the boundary
             if (side->cond() == NULL) continue;

             ElementAccessor<3> elm_acc = cell.elm();
             cell.get_dof_indices(side_dof_indices);
             fe_values_side.reinit(elm_acc, side->side_idx());
             fsv_rt.reinit(elm_acc, side->side_idx());

             calculate_velocity(elm_acc, side_velocity, fsv_rt);
             Model::compute_advection_diffusion_coefficients(fe_values_side.point_list(), side_velocity, elm_acc, ad_coef, dif_coef);
             arma::uvec bc_type;
             Model::get_bc_type(side->cond()->element_accessor(), bc_type);
             data_.cross_section.value_list(fe_values_side.point_list(), elm_acc, csection);

             for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
             {
                 for (unsigned int i=0; i<ndofs; i++)
                     for (unsigned int j=0; j<ndofs; j++)
                         local_matrix[i*ndofs+j] = 0;

                 // On Neumann boundaries we have only term from integrating by parts the advective term,
                 // on Dirichlet boundaries we additionally apply the penalty which enforces the prescribed value.
                 double side_flux = 0;
                 for (unsigned int k=0; k<qsize; k++)
                     side_flux += arma::dot(ad_coef[sbi][k], fe_values_side.normal_vector(k))*fe_values_side.JxW(k);
                 double transport_flux = side_flux/side->measure();

                 if (bc_type[sbi] == AdvectionDiffusionModel::abc_dirichlet)
                 {
                     // set up the parameters for DG method
                     set_DG_parameters_boundary(side, qsize, dif_coef[sbi], transport_flux, fe_values_side.normal_vector(0), data_.dg_penalty[sbi].value(elm_acc.centre(), elm_acc), gamma_l);
                     gamma[sbi][side->cond_idx()] = gamma_l;
                     transport_flux += gamma_l;
                 }

                 // fluxes and penalty
                 for (unsigned int k=0; k<qsize; k++)
                 {
                     double flux_times_JxW;
                     if (bc_type[sbi] == AdvectionDiffusionModel::abc_total_flux)
                     {
                         Model::get_flux_bc_sigma(sbi, fe_values_side.point_list(), side->cond()->element_accessor(), robin_sigma);
                         flux_times_JxW = csection[k]*robin_sigma[k]*fe_values_side.JxW(k);
                     }
                     else if (bc_type[sbi] == AdvectionDiffusionModel::abc_diffusive_flux)
                     {
                         Model::get_flux_bc_sigma(sbi, fe_values_side.point_list(), side->cond()->element_accessor(), robin_sigma);
                         flux_times_JxW = (transport_flux + csection[k]*robin_sigma[k])*fe_values_side.JxW(k);
                     }
                     else if (bc_type[sbi] == AdvectionDiffusionModel::abc_inflow && side_flux < 0)
                         flux_times_JxW = 0;
                     else
                         flux_times_JxW = transport_flux*fe_values_side.JxW(k);

                     for (unsigned int i=0; i<ndofs; i++)
                     {
                         for (unsigned int j=0; j<ndofs; j++)
                         {
                             // flux due to advection and penalty
                             local_matrix[i*ndofs+j] += flux_times_JxW*fe_values_side.shape_value(i,k)*fe_values_side.shape_value(j,k);

                             // flux due to diffusion (only on dirichlet and inflow boundary)
                             if (bc_type[sbi] == AdvectionDiffusionModel::abc_dirichlet)
                                 local_matrix[i*ndofs+j] -= (arma::dot(dif_coef[sbi][k]*fe_values_side.shape_grad(j,k),fe_values_side.normal_vector(k))*fe_values_side.shape_value(i,k)
                                         + arma::dot(dif_coef[sbi][k]*fe_values_side.shape_grad(i,k),fe_values_side.normal_vector(k))*fe_values_side.shape_value(j,k)*dg_variant
                                         )*fe_values_side.JxW(k);
                         }
                     }
                 }

                 ls[sbi]->mat_set_values(ndofs, &(side_dof_indices[0]), ndofs, &(side_dof_indices[0]), local_matrix);
             }
         }
     }
 }


 template<class Model>
 template<unsigned int dim>
 void TransportDG<Model>::assemble_fluxes_element_side()
 {

     if (dim == 1) return;
     FEValues<dim-1,3> fe_values_vb(*feo->mapping<dim-1>(), *feo->q<dim-1>(), *feo->fe<dim-1>(),
             update_values | update_gradients | update_JxW_values | update_quadrature_points);
     FESideValues<dim,3> fe_values_side(*feo->mapping<dim>(), *feo->q<dim-1>(), *feo->fe<dim>(),
             update_values | update_gradients | update_side_JxW_values | update_normal_vectors | update_quadrature_points);
     FESideValues<dim,3> fsv_rt(*feo->mapping<dim>(), *feo->q<dim-1>(), *feo->fe_rt<dim>(),
             update_values);
     FEValues<dim-1,3> fv_rt(*feo->mapping<dim-1>(), *feo->q<dim-1>(), *feo->fe_rt<dim-1>(),
             update_values);

     vector<FEValuesSpaceBase<3>*> fv_sb(2);
     const unsigned int ndofs = feo->fe<dim>()->n_dofs();    // number of local dofs
     const unsigned int qsize = feo->q<dim-1>()->size();     // number of quadrature points
     int side_dof_indices[2*ndofs];
     vector<LongIdx> indices(ndofs);
     unsigned int n_dofs[2], n_indices;
     vector<arma::vec3> velocity_higher, velocity_lower;
     vector<double> frac_sigma(qsize);
     vector<double> csection_lower(qsize), csection_higher(qsize);
     PetscScalar local_matrix[4*ndofs*ndofs];
     double comm_flux[2][2];

     // index 0 = element with lower dimension,
     // index 1 = side of element with higher dimension
     fv_sb[0] = &fe_values_vb;
     fv_sb[1] = &fe_values_side;

     // assemble integral over sides
     for (DHCellAccessor cell_lower_dim : feo->dh()->local_range() )
         for( DHCellSide neighb_side : cell_lower_dim.neighb_sides() )
         {
             // skip neighbours of different dimension
             if (cell_lower_dim.elm().dim() != dim-1) continue;

             ElementAccessor<3> elm_lower_dim = cell_lower_dim.elm();
             n_indices = cell_lower_dim.get_dof_indices(indices);
             for(unsigned int i=0; i<n_indices; ++i) {
                 side_dof_indices[i] = indices[i];
             }
             fe_values_vb.reinit(elm_lower_dim);
             n_dofs[0] = fv_sb[0]->n_dofs();

             DHCellAccessor cell_higher_dim = feo->dh()->cell_accessor_from_element( neighb_side.side()->element().idx() );
             ElementAccessor<3> elm_higher_dim = cell_higher_dim.elm();
             n_indices = cell_higher_dim.get_dof_indices(indices);
             for(unsigned int i=0; i<n_indices; ++i) {
                 side_dof_indices[i+n_dofs[0]] = indices[i];
             }
             fe_values_side.reinit(elm_higher_dim, neighb_side.side()->side_idx());
             n_dofs[1] = fv_sb[1]->n_dofs();

             // Testing element if they belong to local partition.
             bool own_element_id[2];
             own_element_id[0] = cell_lower_dim.is_own();
             own_element_id[1] = cell_higher_dim.is_own();

             fsv_rt.reinit(elm_higher_dim, neighb_side.side()->side_idx());
             fv_rt.reinit(elm_lower_dim);
             calculate_velocity(elm_higher_dim, velocity_higher, fsv_rt);
             calculate_velocity(elm_lower_dim, velocity_lower, fv_rt);
             Model::compute_advection_diffusion_coefficients(fe_values_vb.point_list(), velocity_lower, elm_lower_dim, ad_coef_edg[0], dif_coef_edg[0]);
             Model::compute_advection_diffusion_coefficients(fe_values_vb.point_list(), velocity_higher, elm_higher_dim, ad_coef_edg[1], dif_coef_edg[1]);
             data_.cross_section.value_list(fe_values_vb.point_list(), elm_lower_dim, csection_lower);
             data_.cross_section.value_list(fe_values_vb.point_list(), elm_higher_dim, csection_higher);

             for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++) // Optimize: SWAP LOOPS
             {
                 for (unsigned int i=0; i<n_dofs[0]+n_dofs[1]; i++)
                     for (unsigned int j=0; j<n_dofs[0]+n_dofs[1]; j++)
                         local_matrix[i*(n_dofs[0]+n_dofs[1])+j] = 0;

                 data_.fracture_sigma[sbi].value_list(fe_values_vb.point_list(), elm_lower_dim, frac_sigma);

                 // set transmission conditions
                 for (unsigned int k=0; k<qsize; k++)
                 {
                     /* The communication flux has two parts:
                     * - "diffusive" term containing sigma
                     * - "advective" term representing usual upwind
                     *
                     * The calculation differs from the reference manual, since ad_coef and dif_coef have different meaning
                     * than b and A in the manual.
                     * In calculation of sigma there appears one more csection_lower in the denominator.
                     */
                     double sigma = frac_sigma[k]*arma::dot(dif_coef_edg[0][sbi][k]*fe_values_side.normal_vector(k),fe_values_side.normal_vector(k))*
                             2*csection_higher[k]*csection_higher[k]/(csection_lower[k]*csection_lower[k]);

                     double transport_flux = arma::dot(ad_coef_edg[1][sbi][k], fe_values_side.normal_vector(k));

                     comm_flux[0][0] =  (sigma-min(0.,transport_flux))*fv_sb[0]->JxW(k);
                     comm_flux[0][1] = -(sigma-min(0.,transport_flux))*fv_sb[0]->JxW(k);
                     comm_flux[1][0] = -(sigma+max(0.,transport_flux))*fv_sb[0]->JxW(k);
                     comm_flux[1][1] =  (sigma+max(0.,transport_flux))*fv_sb[0]->JxW(k);

                     for (int n=0; n<2; n++)
                     {
                         if (!own_element_id[n]) continue;

                         for (unsigned int i=0; i<n_dofs[n]; i++)
                             for (int m=0; m<2; m++)
                                 for (unsigned int j=0; j<n_dofs[m]; j++)
                                     local_matrix[(i+n*n_dofs[0])*(n_dofs[0]+n_dofs[1]) + m*n_dofs[0] + j] +=
                                             comm_flux[m][n]*fv_sb[m]->shape_value(j,k)*fv_sb[n]->shape_value(i,k);
                     }
                 }
                 ls[sbi]->mat_set_values(n_dofs[0]+n_dofs[1], side_dof_indices, n_dofs[0]+n_dofs[1], side_dof_indices, local_matrix);
             }
         }

 }


 template<class Model>
 void TransportDG<Model>::set_boundary_conditions()
 {
   START_TIMER("assemble_bc");
     Model::balance_->start_flux_assembly(Model::subst_idx);
     set_boundary_conditions<1>();
     set_boundary_conditions<2>();
     set_boundary_conditions<3>();
     Model::balance_->finish_flux_assembly(Model::subst_idx);
   END_TIMER("assemble_bc");
 }


 template<class Model>
 template<unsigned int dim>
 void TransportDG<Model>::set_boundary_conditions()
 {
     FESideValues<dim,3> fe_values_side(*feo->mapping<dim>(), *feo->q<dim-1>(), *feo->fe<dim>(),
             update_values | update_gradients | update_normal_vectors | update_side_JxW_values | update_quadrature_points);
     FESideValues<dim,3> fsv_rt(*feo->mapping<dim>(), *feo->q<dim-1>(), *feo->fe_rt<dim>(),
                 update_values);
     const unsigned int ndofs = feo->fe<dim>()->n_dofs(), qsize = feo->q<dim-1>()->size();
     vector<LongIdx> side_dof_indices(ndofs);
     unsigned int loc_b=0;
     double local_rhs[ndofs];
     vector<PetscScalar> local_flux_balance_vector(ndofs);
     PetscScalar local_flux_balance_rhs;
     vector<double> bc_values(qsize);
     vector<double> bc_fluxes(qsize),
             bc_sigma(qsize),
             bc_ref_values(qsize);
     vector<double> csection(qsize);
     vector<arma::vec3> velocity;

     for (auto cell : feo->dh()->own_range() )
     {
         if (cell.elm()->boundary_idx_ == nullptr) continue;

         for (unsigned int si=0; si<cell.elm()->n_sides(); si++)
         {
             const Edge *edg = cell.elm().side(si)->edge();
             if (edg->n_sides > 1) continue;
             // skip edges lying not on the boundary
             if (edg->side(0)->cond() == NULL) continue;

             if (edg->side(0)->dim() != dim-1)
             {
                 if (edg->side(0)->cond() != nullptr) ++loc_b;
                 continue;
             }

             SideIter side = edg->side(0);
             ElementAccessor<3> elm = Model::mesh_->element_accessor( side->element().idx() );
             ElementAccessor<3> ele_acc = side->cond()->element_accessor();

             arma::uvec bc_type;
             Model::get_bc_type(ele_acc, bc_type);

             fe_values_side.reinit(elm, side->side_idx());
             fsv_rt.reinit(elm, side->side_idx());
             calculate_velocity(elm, velocity, fsv_rt);

             Model::compute_advection_diffusion_coefficients(fe_values_side.point_list(), velocity, side->element(), ad_coef, dif_coef);
             data_.cross_section.value_list(fe_values_side.point_list(), side->element(), csection);

             auto dh_cell = feo->dh()->cell_accessor_from_element( side->element().idx() );
             dh_cell.get_dof_indices(side_dof_indices);

             for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
             {
                 fill_n(local_rhs, ndofs, 0);
                 local_flux_balance_vector.assign(ndofs, 0);
                 local_flux_balance_rhs = 0;

                 // The b.c. data are fetched for all possible b.c. types since we allow
                 // different bc_type for each substance.
                 data_.bc_dirichlet_value[sbi].value_list(fe_values_side.point_list(), ele_acc, bc_values);

                 double side_flux = 0;
                 for (unsigned int k=0; k<qsize; k++)
                     side_flux += arma::dot(ad_coef[sbi][k], fe_values_side.normal_vector(k))*fe_values_side.JxW(k);
                 double transport_flux = side_flux/side->measure();

                 if (bc_type[sbi] == AdvectionDiffusionModel::abc_inflow && side_flux < 0)
                 {
                     for (unsigned int k=0; k<qsize; k++)
                     {
                         double bc_term = -transport_flux*bc_values[k]*fe_values_side.JxW(k);
                         for (unsigned int i=0; i<ndofs; i++)
                             local_rhs[i] += bc_term*fe_values_side.shape_value(i,k);
                     }
                     for (unsigned int i=0; i<ndofs; i++)
                         local_flux_balance_rhs -= local_rhs[i];
                 }
                 else if (bc_type[sbi] == AdvectionDiffusionModel::abc_dirichlet)
                 {
                     for (unsigned int k=0; k<qsize; k++)
                     {
                         double bc_term = gamma[sbi][side->cond_idx()]*bc_values[k]*fe_values_side.JxW(k);
                         arma::vec3 bc_grad = -bc_values[k]*fe_values_side.JxW(k)*dg_variant*(arma::trans(dif_coef[sbi][k])*fe_values_side.normal_vector(k));
                         for (unsigned int i=0; i<ndofs; i++)
                             local_rhs[i] += bc_term*fe_values_side.shape_value(i,k)
                                     + arma::dot(bc_grad,fe_values_side.shape_grad(i,k));
                     }
                     for (unsigned int k=0; k<qsize; k++)
                     {
                         for (unsigned int i=0; i<ndofs; i++)
                         {
                             local_flux_balance_vector[i] += (arma::dot(ad_coef[sbi][k], fe_values_side.normal_vector(k))*fe_values_side.shape_value(i,k)
                                     - arma::dot(dif_coef[sbi][k]*fe_values_side.shape_grad(i,k),fe_values_side.normal_vector(k))
                                     + gamma[sbi][side->cond_idx()]*fe_values_side.shape_value(i,k))*fe_values_side.JxW(k);
                         }
                     }
                     if (Model::time_->tlevel() > 0)
                         for (unsigned int i=0; i<ndofs; i++)
                             local_flux_balance_rhs -= local_rhs[i];
                 }
                 else if (bc_type[sbi] == AdvectionDiffusionModel::abc_total_flux)
                 {
                     Model::get_flux_bc_data(sbi, fe_values_side.point_list(), ele_acc, bc_fluxes, bc_sigma, bc_ref_values);
                     for (unsigned int k=0; k<qsize; k++)
                     {
                         double bc_term = csection[k]*(bc_sigma[k]*bc_ref_values[k]+bc_fluxes[k])*fe_values_side.JxW(k);
                         for (unsigned int i=0; i<ndofs; i++)
                             local_rhs[i] += bc_term*fe_values_side.shape_value(i,k);
                     }

                     for (unsigned int i=0; i<ndofs; i++)
                     {
                         for (unsigned int k=0; k<qsize; k++)
                             local_flux_balance_vector[i] += csection[k]*bc_sigma[k]*fe_values_side.JxW(k)*fe_values_side.shape_value(i,k);
                         local_flux_balance_rhs -= local_rhs[i];
                     }
                 }
                 else if (bc_type[sbi] == AdvectionDiffusionModel::abc_diffusive_flux)
                 {
                     Model::get_flux_bc_data(sbi, fe_values_side.point_list(), ele_acc, bc_fluxes, bc_sigma, bc_ref_values);
                     for (unsigned int k=0; k<qsize; k++)
                     {
                         double bc_term = csection[k]*(bc_sigma[k]*bc_ref_values[k]+bc_fluxes[k])*fe_values_side.JxW(k);
                         for (unsigned int i=0; i<ndofs; i++)
                             local_rhs[i] += bc_term*fe_values_side.shape_value(i,k);
                     }

                     for (unsigned int i=0; i<ndofs; i++)
                     {
                         for (unsigned int k=0; k<qsize; k++)
                             local_flux_balance_vector[i] += csection[k]*(arma::dot(ad_coef[sbi][k], fe_values_side.normal_vector(k)) + bc_sigma[k])*fe_values_side.JxW(k)*fe_values_side.shape_value(i,k);
                         local_flux_balance_rhs -= local_rhs[i];
                     }
                 }
                 else if (bc_type[sbi] == AdvectionDiffusionModel::abc_inflow && side_flux >= 0)
                 {
                     for (unsigned int k=0; k<qsize; k++)
                     {
                         for (unsigned int i=0; i<ndofs; i++)
                             local_flux_balance_vector[i] += arma::dot(ad_coef[sbi][k], fe_values_side.normal_vector(k))*fe_values_side.JxW(k)*fe_values_side.shape_value(i,k);
                     }
                 }
                 ls[sbi]->rhs_set_values(ndofs, &(side_dof_indices[0]), local_rhs);

                 Model::balance_->add_flux_matrix_values(Model::subst_idx[sbi], loc_b, side_dof_indices, local_flux_balance_vector);
                 Model::balance_->add_flux_vec_value(Model::subst_idx[sbi], loc_b, local_flux_balance_rhs);
             }
             ++loc_b;
         }
     }
 }


 template<class Model>
 template<unsigned int dim>
 void TransportDG<Model>::calculate_velocity(const ElementAccessor<3> &cell,
                                             vector<arma::vec3> &velocity,
                                             FEValuesBase<dim,3> &fv)
 {
     OLD_ASSERT(cell->dim() == dim, "Element dimension mismatch!");

     velocity.resize(fv.n_points());

     for (unsigned int k=0; k<fv.n_points(); k++)
     {
         velocity[k].zeros();
         for (unsigned int sid=0; sid<cell->n_sides(); sid++)
           for (unsigned int c=0; c<3; ++c)
             velocity[k][c] += fv.shape_value_component(sid,k,c) * Model::mh_dh->side_flux( *(cell.side(sid)) );
     }
 }


 template<class Model>
 void TransportDG<Model>::set_DG_parameters_boundary(const Side *side,
             const int K_size,
             const vector<arma::mat33> &K,
             const double flux,
             const arma::vec3 &normal_vector,
             const double alpha,
             double &gamma)
 {
     double delta = 0, h = 0;

     // calculate the side diameter
     if (side->dim() == 0)
     {
         h = 1;
     }
     else
     {
         for (unsigned int i=0; i<side->n_nodes(); i++)
             for (unsigned int j=i+1; j<side->n_nodes(); j++)
                 h = max(h, side->node(i)->distance( *side->node(j).node() ));
     }

     // delta is set to the average value of Kn.n on the side
     for (int k=0; k<K_size; k++)
         delta += dot(K[k]*normal_vector,normal_vector);
     delta /= K_size;

     gamma = 0.5*fabs(flux) + alpha/h*delta*elem_anisotropy(side->element());
 }


 template<class Model>
 void TransportDG<Model>::set_initial_condition()
 {
     START_TIMER("set_init_cond");
     for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
         ls[sbi]->start_allocation();
     prepare_initial_condition<1>();
     prepare_initial_condition<2>();
     prepare_initial_condition<3>();

     for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
         ls[sbi]->start_add_assembly();
     prepare_initial_condition<1>();
     prepare_initial_condition<2>();
     prepare_initial_condition<3>();

     for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
     {
         ls[sbi]->finish_assembly();
         ls[sbi]->solve();
     }
     END_TIMER("set_init_cond");
 }

 template<class Model>
 template<unsigned int dim>
 void TransportDG<Model>::prepare_initial_condition()
 {
     FEValues<dim,3> fe_values(*feo->mapping<dim>(), *feo->q<dim>(), *feo->fe<dim>(),
             update_values | update_JxW_values | update_quadrature_points);
     const unsigned int ndofs = feo->fe<dim>()->n_dofs(), qsize = feo->q<dim>()->size();
     std::vector<LongIdx> dof_indices(ndofs);
     double matrix[ndofs*ndofs], rhs[ndofs];
     std::vector<std::vector<double> > init_values(Model::n_substances());

     for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++) // Optimize: SWAP LOOPS
         init_values[sbi].resize(qsize);

     for (auto cell : feo->dh()->own_range() )
     {
         if (cell.dim() != dim) continue;
         ElementAccessor<3> elem = cell.elm();

         cell.get_dof_indices(dof_indices);
         fe_values.reinit(elem);

         Model::compute_init_cond(fe_values.point_list(), elem, init_values);

         for (unsigned int sbi=0; sbi<Model::n_substances(); sbi++)
         {
             for (unsigned int i=0; i<ndofs; i++)
             {
                 rhs[i] = 0;
                 for (unsigned int j=0; j<ndofs; j++)
                     matrix[i*ndofs+j] = 0;
             }

             for (unsigned int k=0; k<qsize; k++)
             {
                 double rhs_term = init_values[sbi][k]*fe_values.JxW(k);

                 for (unsigned int i=0; i<ndofs; i++)
                 {
                     for (unsigned int j=0; j<ndofs; j++)
                         matrix[i*ndofs+j] += fe_values.shape_value(i,k)*fe_values.shape_value(j,k)*fe_values.JxW(k);

                     rhs[i] += fe_values.shape_value(i,k)*rhs_term;
                 }
             }
             ls[sbi]->set_values(ndofs, &(dof_indices[0]), ndofs, &(dof_indices[0]), matrix, rhs);
         }
     }
 }


 template<class Model>
 void TransportDG<Model>::get_par_info(LongIdx * &el_4_loc, Distribution * &el_ds)
 {
     el_4_loc = Model::mesh_->get_el_4_loc();
     el_ds = Model::mesh_->get_el_ds();
 }


 template<class Model>
 void TransportDG<Model>::update_after_reactions(bool solution_changed)
 {
     if (solution_changed)
     {
         unsigned int i_cell=0;
         for (auto cell : feo->dh()->own_range() )
         {

             unsigned int n_dofs;
             switch (cell.dim())
             {
             case 1:
                 n_dofs = feo->fe<1>()->n_dofs();
                 break;
             case 2:
                 n_dofs = feo->fe<2>()->n_dofs();
                 break;
             case 3:
                 n_dofs = feo->fe<3>()->n_dofs();
                 break;
             }

             std::vector<LongIdx> dof_indices(n_dofs);
             cell.get_dof_indices(dof_indices);

             for (unsigned int sbi=0; sbi<Model::n_substances(); ++sbi)
             {
                 double old_average = 0;
                 for (unsigned int j=0; j<n_dofs; ++j)
                     old_average += ls[sbi]->get_solution_array()[dof_indices[j]-feo->dh()->distr()->begin()];
                 old_average /= n_dofs;

                 for (unsigned int j=0; j<n_dofs; ++j)
                     ls[sbi]->get_solution_array()[dof_indices[j]-feo->dh()->distr()->begin()] += solution_elem_[sbi][i_cell] - old_average;
             }
             ++i_cell;
         }
     }
     // update mass_vec for the case that mass matrix changes in next time step
     for (unsigned int sbi=0; sbi<Model::n_substances(); ++sbi)
         MatMult(*(ls_dt[sbi]->get_matrix()), ls[sbi]->get_solution(), mass_vec[sbi]);
 }

 template<class Model>
 LongIdx *TransportDG<Model>::get_row_4_el()
 {
     return Model::mesh_->get_row_4_el();
 }


 template class TransportDG<ConcentrationTransportModel>;
 template class TransportDG<HeatTransferModel>;


EquationBase::time
TimeGovernor & time()
Definition: equation.hh:148

Side
Definition: sides.h:39

LongIdx
int LongIdx
Define type that represents indices of large arrays (elements, nodes, dofs etc.)
Definition: long_idx.hh:22

Side::edge
const Edge * edge() const
Definition: side_impl.hh:66

TransportDG::input_rec
Input::Record input_rec
Record with input specification.
Definition: transport_dg.hh:464

mapping_p1.hh
Class MappingP1 implements the affine transformation of the unit cell onto the actual cell...

update_values
Shape function values.
Definition: update_flags.hh:87

EquationBase::eq_data_
FieldSet * eq_data_
Definition: equation.hh:232

GenericField::subdomain
static auto subdomain(Mesh &mesh) -> IndexField
Definition: generic_field.impl.hh:57

mh_dofhandler.hh

TransportDG::assemble_fluxes_element_element
void assemble_fluxes_element_element()
Assembles the fluxes between elements of the same dimension.
Definition: transport_dg.cc:906

TransportDG::set_sources
void set_sources()
Assembles the right hand side due to volume sources.
Definition: transport_dg.cc:818

FEObjects::fe
FiniteElement< dim > * fe()

TransportDG::set_boundary_conditions
void set_boundary_conditions()
Assembles the r.h.s. components corresponding to the Dirichlet boundary conditions.
Definition: transport_dg.cc:1314

TransportDG::get_par_info
void get_par_info(LongIdx *&el_4_loc, Distribution *&el_ds)
Definition: transport_dg.cc:1616

Element::n_nodes
unsigned int n_nodes() const
Definition: elements.h:129

update_side_JxW_values
Transformed quadrature weight for cell sides.
Definition: update_flags.hh:153

TransportDG::mm_coef
vector< double > mm_coef
Mass matrix coefficients.
Definition: transport_dg.hh:474

arma::vec3
Definition: doxy_dummy_defs.hh:17

Input::Array
Accessor to input data conforming to declared Array.
Definition: accessors.hh:567

TransportDG::assemble_fluxes_element_side
void assemble_fluxes_element_side()
Assembles the fluxes between elements of different dimensions.
Definition: transport_dg.cc:1194

FieldFlag::in_main_matrix
static constexpr Mask in_main_matrix
A field is part of main "stiffness matrix" of the equation.
Definition: field_flag.hh:49

FESideValues::reinit
void reinit(ElementAccessor< 3 > &cell, unsigned int sid)
Update cell-dependent data (gradients, Jacobians etc.)
Definition: fe_values.cc:610

linsys_PETSC.hh
Solver based on the original PETSc solver using MPIAIJ matrix and succesive Schur complement construc...

Side::side_idx
unsigned int side_idx() const
Definition: side_impl.hh:82

TransportDG::calculate_concentration_matrix
void calculate_concentration_matrix()
Definition: transport_dg.cc:578

TransportDG
Transport with dispersion implemented using discontinuous Galerkin method.
Definition: transport_dg.hh:159

Input::Type::Default
Class Input::Type::Default specifies default value of keys of a Input::Type::Record.
Definition: type_record.hh:61

FieldCommon::flags_add
FieldCommon & flags_add(FieldFlag::Flags::Mask mask)
Definition: field_common.hh:187

Node::distance
double distance(const Node &n2) const
Definition: nodes.hh:85

LinSys_PETSC::set_from_input
void set_from_input(const Input::Record in_rec) override
Definition: linsys_PETSC.cc:454

accessors.hh

LinSys_PETSC
Definition: linsys_PETSC.hh:43

LinSys::start_add_assembly
virtual void start_add_assembly()
Definition: linsys.hh:341

TransportDG::assemble_mass_matrix
void assemble_mass_matrix()
Assembles the mass matrix.
Definition: transport_dg.cc:663

EquationOutput::output
void output(TimeStep step)
Definition: equation_output.cc:187

Side::cond
Boundary * cond() const
Definition: side_impl.hh:71

LinSys::mat_zero_entries
virtual PetscErrorCode mat_zero_entries()
Definition: linsys.hh:264

TransportDG::output_vec
vector< VectorMPI > output_vec
Array for storing the output solution data.
Definition: transport_dg.hh:461

LinSys::rhs_set_values
virtual void rhs_set_values(int nrow, int *rows, double *vals)=0

TransportDG::update_solution
void update_solution() override
Computes the solution in one time instant.
Definition: transport_dg.cc:447

ElementAccessor< 3 >

Input::Type::Default::obligatory
static Default obligatory()
The factory function to make an empty default value which is obligatory.
Definition: type_record.hh:110

TransportDG::dg_variant
int dg_variant
DG variant ((non-)symmetric/incomplete.
Definition: transport_dg.hh:415

fe_value_handler.hh

AdvectionDiffusionModel::abc_total_flux
Definition: advection_diffusion_model.hh:42

TransportDG::prepare_initial_condition
void prepare_initial_condition()
Assembles the auxiliary linear system to calculate the initial solution as L^2-projection of the pres...
Definition: transport_dg.cc:1566

Mesh
Definition: mesh.h:76

generic_field.hh
Fields computed from the mesh data.

LinSys::start_allocation
virtual void start_allocation()
Definition: linsys.hh:333

FEObjects::~FEObjects
~FEObjects()
Definition: transport_dg.cc:138

TransportDG::set_initial_condition
void set_initial_condition()
Sets the initial condition.
Definition: transport_dg.cc:1541

DHCellAccessor
Cell accessor allow iterate over DOF handler cells.
Definition: dh_cell_accessor.hh:40

fe_values.hh
Class FEValues calculates finite element data on the actual cells such as shape function values...

chkerr
void chkerr(unsigned int ierr)
Replacement of new/delete operator in the spirit of xmalloc.
Definition: system.hh:147

Distribution
Definition: distribution.hh:50

LinSys::finish_assembly
virtual void finish_assembly()=0

Edge::n_sides
int n_sides
Definition: edges.h:36

TransportDG::ad_coef
vector< vector< arma::vec3 > > ad_coef
Advection coefficients.
Definition: transport_dg.hh:480

Edge
Definition: edges.h:26

ElementAccessor::side
SideIter side(const unsigned int loc_index)
Definition: accessors.hh:137

ASSERT
#define ASSERT(expr)
Allow use shorter versions of macro names if these names is not used with external library...
Definition: asserts.hh:346

AVERAGE
#define AVERAGE(i, k, side_id)

FEObjects::dh
std::shared_ptr< DOFHandlerMultiDim > dh()
Definition: transport_dg.cc:175

TransportDG::assemble_stiffness_matrix
void assemble_stiffness_matrix()
Assembles the stiffness matrix.
Definition: transport_dg.cc:731

std::vector< LongIdx >

AdvectionDiffusionModel::abc_dirichlet
Definition: advection_diffusion_model.hh:41

TransportDG::dif_coef_edg
vector< vector< vector< arma::mat33 > > > dif_coef_edg
Diffusion coefficients on edges.
Definition: transport_dg.hh:486

concentration_model.hh
Discontinuous Galerkin method for equation of transport with dispersion.

Input::Type::Integer
Class for declaration of the integral input data.
Definition: type_base.hh:490

TransportDG::get_solution
const Vec & get_solution(unsigned int sbi)
Definition: transport_dg.hh:234

DHCellAccessor::is_own
bool is_own() const
Return true if accessor represents own element (false for ghost element)
Definition: dh_cell_accessor.hh:123

FieldCommon::units
FieldCommon & units(const UnitSI &units)
Set basic units of the field.
Definition: field_common.hh:142

Side::element
ElementAccessor< 3 > element() const
Definition: side_impl.hh:53

TransportDG::ret_sources_prev
vector< double > ret_sources_prev
Definition: transport_dg.hh:478

TransportDG::EqData::dg_penalty
MultiField< 3, FieldValue< 3 >::Scalar > dg_penalty
Penalty enforcing inter-element continuity of solution (for each substance).
Definition: transport_dg.hh:169

TransportDG::get_dg_variant_selection_input_type
static const Input::Type::Selection & get_dg_variant_selection_input_type()
Input type for the DG variant selection.
Definition: transport_dg.cc:53

FEValuesBase::n_points
unsigned int n_points()
Returns the number of quadrature points.
Definition: fe_values.hh:407

Input::Type::Array
Class for declaration of inputs sequences.
Definition: type_base.hh:346

TransportDG::EqData::output_fields
EquationOutput output_fields
Definition: transport_dg.hh:173

TransportDG::mass_matrix
std::vector< Mat > mass_matrix
The mass matrix.
Definition: transport_dg.hh:434

Quadrature< 0 >

TransportDG::calculate_cumulative_balance
void calculate_cumulative_balance()
Definition: transport_dg.cc:644

TransportDG::assemble_fluxes_boundary
void assemble_fluxes_boundary()
Assembles the fluxes on the boundary.
Definition: transport_dg.cc:1091

value
static constexpr bool value
Definition: json.hpp:87

QGauss
Symmetric Gauss-Legendre quadrature formulae on simplices.
Definition: quadrature_lib.hh:33

TransportDG::set_DG_parameters_boundary
void set_DG_parameters_boundary(const Side *side, const int K_size, const std::vector< arma::mat33 > &K, const double flux, const arma::vec3 &normal_vector, const double alpha, double &gamma)
Calculates the dispersivity (diffusivity) tensor from the velocity field.
Definition: transport_dg.cc:1506

WAVERAGE
#define WAVERAGE(i, k, side_id)

sys_profiler.hh

TransportDG::TransportDG
TransportDG(Mesh &init_mesh, const Input::Record in_rec)
Constructor.
Definition: transport_dg.cc:215

TransportDG::ret_coef
vector< vector< double > > ret_coef
Retardation coefficient due to sorption.
Definition: transport_dg.hh:476

ElementAccessor::centre
arma::vec::fixed< spacedim > centre() const
Computes the barycenter.
Definition: accessors.hh:285

FEValuesBase::shape_grad
arma::vec::fixed< spacedim > shape_grad(const unsigned int function_no, const unsigned int point_no) override
Return the gradient of the function_no-th shape function at the point_no-th quadrature point...
Definition: fe_values.cc:237

Element::dim
unsigned int dim() const
Definition: elements.h:124

FEObjects
Definition: transport_dg.hh:72

OLD_ASSERT
#define OLD_ASSERT(...)
Definition: global_defs.h:131

TransportDG::get_row_4_el
LongIdx * get_row_4_el()
Definition: transport_dg.cc:1668

TransportDG::initialize
void initialize() override
Definition: transport_dg.cc:249

TransportDG::ad_coef_edg
vector< vector< vector< arma::vec3 > > > ad_coef_edg
Advection coefficients on edges.
Definition: transport_dg.hh:484

FE_P_disc< 0 >

update_quadrature_points
Transformed quadrature points.
Definition: update_flags.hh:102

TransportDG::EqData
Definition: transport_dg.hh:163

equation_output.hh

DHCellAccessor::elm
const ElementAccessor< 3 > elm() const
Return ElementAccessor to element of loc_ele_idx_.
Definition: dh_cell_accessor.hh:68

TransportDG::output_data
void output_data()
Postprocesses the solution and writes to output file.
Definition: transport_dg.cc:619

LinSys::set_rhs
virtual PetscErrorCode set_rhs(Vec &rhs)
Definition: linsys.hh:255

TransportDG::EqData::fracture_sigma
MultiField< 3, FieldValue< 3 >::Scalar > fracture_sigma
Transition parameter for diffusive transfer on fractures (for each substance).
Definition: transport_dg.hh:168

TransportDG::preallocate
void preallocate()
Definition: transport_dg.cc:416

Side::dim
unsigned int dim() const
Definition: side_impl.hh:38

Input::Type
Definition: balance.hh:36

TransportDG::dif_coef
vector< vector< arma::mat33 > > dif_coef
Diffusion coefficients.
Definition: transport_dg.hh:482

TransportDG::feo
FEObjects * feo
Finite element objects.
Definition: transport_dg.hh:409

SideIter
Definition: sides.h:132

FieldFlag::in_time_term
static constexpr Mask in_time_term
A field is part of time term of the equation.
Definition: field_flag.hh:47

DHCellSide::edge_sides
RangeConvert< DHEdgeSide, DHCellSide > edge_sides() const
Returns range of all sides looped over common Edge.
Definition: dh_cell_accessor.hh:410

FieldCommon::input_default
FieldCommon & input_default(const string &input_default)
Definition: field_common.hh:129

LinSys::get_solution
const Vec & get_solution()
Definition: linsys.hh:282

FEValuesBase::JxW
double JxW(const unsigned int point_no) override
Return the product of Jacobian determinant and the quadrature weight at given quadrature point...
Definition: fe_values.hh:336

FE_RT0
Raviart-Thomas element of order 0.
Definition: fe_rt.hh:60

fe_p.hh
Definitions of basic Lagrangean finite elements with polynomial shape functions.

FieldFlag::equation_external_output
static constexpr Mask equation_external_output
Match an output field, that can be also copy of other field.
Definition: field_flag.hh:58

TransportDG::EqData::subdomain
Field< 3, FieldValue< 3 >::Scalar > subdomain
Definition: transport_dg.hh:171

Input::Record
Accessor to the data with type Type::Record.
Definition: accessors.hh:292

Input::Record::val
const Ret val(const string &key) const
Definition: accessors_impl.hh:31

Element::n_sides
unsigned int n_sides() const
Definition: elements.h:135

GenericField::region_id
static auto region_id(Mesh &mesh) -> IndexField
Definition: generic_field.impl.hh:38

START_TIMER
#define START_TIMER(tag)
Starts a timer with specified tag.
Definition: sys_profiler.hh:117

TransportDG::rhs
std::vector< Vec > rhs
Vector of right hand side.
Definition: transport_dg.hh:428

EquationBase::mesh_
Mesh * mesh_
Definition: equation.hh:223

Input::Type::Selection::add_value
Selection & add_value(const int value, const std::string &key, const std::string &description="", TypeBase::attribute_map attributes=TypeBase::attribute_map())
Adds one new value with name given by key to the Selection.
Definition: type_selection.cc:50

Input::Type::Record::declare_key
Record & declare_key(const string &key, std::shared_ptr< TypeBase > type, const Default &default_value, const string &description, TypeBase::attribute_map key_attributes=TypeBase::attribute_map())
Declares a new key of the Record.
Definition: type_record.cc:501

balance.hh

TransportDG::EqData::region_id
Field< 3, FieldValue< 3 >::Scalar > region_id
Definition: transport_dg.hh:170

TransportDG::EqData::EqData
EqData()
Definition: transport_dg.cc:179

elem_anisotropy
double elem_anisotropy(ElementAccessor< 3 > e)
Definition: transport_dg.cc:890

TransportDG::dg_order
unsigned int dg_order
Polynomial order of finite elements.
Definition: transport_dg.hh:418

FieldFlag::in_rhs
static constexpr Mask in_rhs
A field is part of the right hand side of the equation.
Definition: field_flag.hh:51

MappingP1< 1, 3 >

update_gradients
Shape function gradients.
Definition: update_flags.hh:95

AdvectionDiffusionModel::abc_inflow
Definition: advection_diffusion_model.hh:40

FLOW123D_FORCE_LINK_IN_CHILD
FLOW123D_FORCE_LINK_IN_CHILD(concentrationTransportModel)

Side::node
NodeAccessor< 3 > node(unsigned int i) const
Definition: side_impl.hh:47

output_time.hh

Side::measure
double measure() const
Calculate metrics of the side.
Definition: sides.cc:30

FEValuesBase::normal_vector
arma::vec::fixed< spacedim > normal_vector(unsigned int point_no) override
Returns the normal vector to a side at given quadrature point.
Definition: fe_values.hh:368

OutputTime::CORNER_DATA
Definition: output_time.hh:106

ElementAccessor::region
Region region() const
Definition: accessors.hh:95

update_normal_vectors
Normal vectors.
Definition: update_flags.hh:124

LinSys::rhs_zero_entries
virtual PetscErrorCode rhs_zero_entries()
Definition: linsys.hh:273

LinSys::set_solution
void set_solution(Vec sol_vec)
Definition: linsys.hh:290

transport_dg.hh
Discontinuous Galerkin method for equation of transport with dispersion.

TransportDG::solution_elem_
double ** solution_elem_
Element averages of solution (the array is passed to reactions in operator splitting).
Definition: transport_dg.hh:449

TransportDG::stiffness_matrix
std::vector< Mat > stiffness_matrix
The stiffness matrix.
Definition: transport_dg.hh:431

AdvectionDiffusionModel::abc_diffusive_flux
Definition: advection_diffusion_model.hh:43

FieldCommon::description
FieldCommon & description(const string &description)
Definition: field_common.hh:117

LinSys::set_values
void set_values(int nrow, int *rows, int ncol, int *cols, PetscScalar *mat_vals, PetscScalar *rhs_vals)
Set values in the system matrix and values in the right-hand side vector on corresponding rows...
Definition: linsys.hh:386

TransportDG::data_
EqData data_
Field data for model parameters.
Definition: transport_dg.hh:400

TransportDG::allocation_done
bool allocation_done
Indicates whether matrices have been preallocated.
Definition: transport_dg.hh:497

multi_field.hh

Side::cond_idx
unsigned int cond_idx() const
Definition: side_impl.hh:76

TransportDG::gamma
std::vector< std::vector< double > > gamma
Penalty parameters.
Definition: transport_dg.hh:412

TransportDG::get_input_type
static const Input::Type::Record & get_input_type()
Declare input record type for the equation TransportDG.
Definition: transport_dg.cc:79

EquationOutput::initialize
void initialize(std::shared_ptr< OutputTime > stream, Mesh *mesh, Input::Record in_rec, const TimeGovernor &tg)
Definition: equation_output.cc:109

dh_cell_accessor.hh

advection_diffusion_model.hh
Discontinuous Galerkin method for equation of transport with dispersion.

Input::Type::Selection::close
const Selection & close() const
Close the Selection, no more values can be added.
Definition: type_selection.cc:65

long_idx.hh

FEValuesBase::shape_value
double shape_value(const unsigned int function_no, const unsigned int point_no) override
Return the value of the function_no-th shape function at the point_no-th quadrature point...
Definition: fe_values.cc:228

TransportDG::update_after_reactions
void update_after_reactions(bool solution_changed)
Definition: transport_dg.cc:1624

FEObjects::mapping
MappingP1< dim, 3 > * mapping()

TransportDG::ret_vec
std::vector< Vec > ret_vec
Auxiliary vectors for calculation of sources in balance due to retardation (e.g. sorption).
Definition: transport_dg.hh:440

FEValuesBase::shape_value_component
double shape_value_component(const unsigned int function_no, const unsigned int point_no, const unsigned int comp) const
Return the value of the function_no-th shape function at the point_no-th quadrature point...
Definition: fe_values.cc:246

TransportDG::ret_sources
vector< double > ret_sources
Temporary values of increments due to retardation (e.g. sorption)
Definition: transport_dg.hh:478

FieldSet::set_time
bool set_time(const TimeStep &time, LimitSide limit_side)
Definition: field_set.cc:157

RegionIdx::bulk_idx
unsigned int bulk_idx() const
Returns index of the region in the bulk set.
Definition: region.hh:91

LinSys
Definition: la_linsys_new.hh:169

quadrature_lib.hh
Definitions of particular quadrature rules on simplices.

WarningOut
#define WarningOut()
Macro defining &#39;warning&#39; record of log.
Definition: logger.hh:246

FieldCommon::name
FieldCommon & name(const string &name)
Definition: field_common.hh:110

LinSys::solve
virtual SolveInfo solve()=0

FEValues< dim, 3 >

END_TIMER
#define END_TIMER(tag)
Ends a timer with specified tag.
Definition: sys_profiler.hh:151

heat_model.hh
Discontinuous Galerkin method for equation of transport with dispersion.

TransportDG::calculate_velocity
void calculate_velocity(const ElementAccessor< 3 > &cell, std::vector< arma::vec3 > &velocity, FEValuesBase< dim, 3 > &fv)
Calculates the velocity field on a given dim dimensional cell.
Definition: transport_dg.cc:1486

FEValuesBase::point_list
vector< arma::vec::fixed< spacedim > > & point_list()
Return coordinates of all quadrature points in the actual cell system.
Definition: fe_values.hh:357

FEObjects::q
Quadrature< dim > * q()

TransportDG::DGVariant
DGVariant
Definition: transport_dg.hh:179

LinSys_PETSC::get_input_type
static const Input::Type::Record & get_input_type()
Definition: linsys_PETSC.cc:32

LinSys::set_matrix
virtual PetscErrorCode set_matrix(Mat &matrix, MatStructure str)
Definition: linsys.hh:246

TransportDG::mass_vec
std::vector< Vec > mass_vec
Mass from previous time instant (necessary when coefficients of mass matrix change in time)...
Definition: transport_dg.hh:437

Input::Type::Record
Record type proxy class.
Definition: type_record.hh:182

LimitSide::left

TransportDG::assemble_volume_integrals
void assemble_volume_integrals()
Assembles the volume integrals into the stiffness matrix.
Definition: transport_dg.cc:764

LinSys::mat_set_values
virtual void mat_set_values(int nrow, int *rows, int ncol, int *cols, double *vals)=0

FieldCommon::flags
FieldCommon & flags(FieldFlag::Flags::Mask mask)
Definition: field_common.hh:181

FiniteElement< 0 >

FEValuesBase
Base class for FEValues and FESideValues.
Definition: fe_values.hh:37

field_fe.hh

UnitSI::dimensionless
static UnitSI & dimensionless()
Returns dimensionless unit.
Definition: unit_si.cc:55

FieldCommon::print_message_table
static bool print_message_table(ostream &stream, std::string equation_name)
Definition: field_common.cc:96

TransportDG::~TransportDG
~TransportDG()
Destructor.
Definition: transport_dg.cc:343

ElementAccessor::idx
unsigned int idx() const
Return local idx of element in boundary / bulk part of element vector.
Definition: accessors.hh:111

TransportDG::ls
LinSys ** ls
Linear algebra system for the transport equation.
Definition: transport_dg.hh:443

DHCellAccessor::get_dof_indices
unsigned int get_dof_indices(std::vector< int > &indices) const
Fill vector of the global indices of dofs associated to the cell.
Definition: dh_cell_accessor.hh:77

FEObjects::fe_rt
FiniteElement< dim > * fe_rt()

Edge::side
SideIter side(const unsigned int i) const
Definition: edges.h:31

TransportDG::ls_dt
LinSys ** ls_dt
Linear algebra system for the time derivative (actually it is used only for handling the matrix struc...
Definition: transport_dg.hh:446

JUMP
#define JUMP(i, k, side_id)

Input::Type::Selection
Template for classes storing finite set of named values.
Definition: type_selection.hh:65

fe_rt.hh
Definitions of Raviart-Thomas finite elements.

DHCellSide
Side accessor allows to iterate over sides of DOF handler cell.
Definition: dh_cell_accessor.hh:156

FieldValue_
Definition: field_values.hh:247

Boundary::element_accessor
ElementAccessor< 3 > element_accessor()
Definition: boundaries.cc:48

factory.hh

TransportDG::zero_time_step
void zero_time_step() override
Initialize solution in the zero time.
Definition: transport_dg.cc:383

FEObjects::FEObjects
FEObjects(Mesh *mesh_, unsigned int fe_order)
Definition: transport_dg.cc:108

FieldFE
Definition: field.hh:56

FEValues::reinit
void reinit(ElementAccessor< 3 > &cell)
Update cell-dependent data (gradients, Jacobians etc.)
Definition: fe_values.cc:539

Side::n_nodes
unsigned int n_nodes() const
Definition: side_impl.hh:34

update_JxW_values
Transformed quadrature weights.
Definition: update_flags.hh:114

FESideValues
Calculates finite element data on a side.
Definition: fe_values.hh:582

ElementAccessor::node
const Node * node(unsigned int ni) const
Definition: accessors.hh:145