C++ (Cpp) space_e Beispiele

Beispiel #1

int main(int argc, char* argv[])
{
    // Load the mesh.
    Mesh mesh;
    H2DReader mloader;
    mloader.load("channel.mesh", &mesh);

    // Perform initial mesh refinements.
    for (int i = 0; i < INIT_REF_NUM; i++) mesh.refine_all_elements(2);
    //mesh.refine_towards_boundary(BDY_SOLID_WALL_BOTTOM, 2);

    // Initialize boundary condition types and spaces with default shapesets.
    L2Space space_rho(&mesh, P_INIT);
    L2Space space_rho_v_x(&mesh, P_INIT);
    L2Space space_rho_v_y(&mesh, P_INIT);
    L2Space space_e(&mesh, P_INIT);
    int ndof = Space::get_num_dofs(Hermes::vector<Space*>(&space_rho, &space_rho_v_x, &space_rho_v_y, &space_e));
    info("ndof: %d", ndof);

    // Initialize solutions, set initial conditions.
    InitialSolutionEulerDensity prev_rho(&mesh, RHO_EXT);
    InitialSolutionEulerDensityVelX prev_rho_v_x(&mesh, RHO_EXT * V1_EXT);
    InitialSolutionEulerDensityVelY prev_rho_v_y(&mesh, RHO_EXT * V2_EXT);
    InitialSolutionEulerDensityEnergy prev_e(&mesh, QuantityCalculator::calc_energy(RHO_EXT, RHO_EXT * V1_EXT, RHO_EXT * V2_EXT, P_EXT, KAPPA));

    // Numerical flux.
    StegerWarmingNumericalFlux num_flux(KAPPA);

    // Initialize weak formulation.
    EulerEquationsWeakFormExplicitMultiComponentSemiImplicit wf(&num_flux, KAPPA, RHO_EXT, V1_EXT, V2_EXT, P_EXT, BDY_SOLID_WALL_BOTTOM, BDY_SOLID_WALL_TOP,
            BDY_INLET, BDY_OUTLET, &prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e);

    // Initialize the FE problem.
    bool is_linear = true;
    DiscreteProblem dp(&wf, Hermes::vector<Space*>(&space_rho, &space_rho_v_x, &space_rho_v_y, &space_e), is_linear);

    // If the FE problem is in fact a FV problem.
    //if(P_INIT == 0) dp.set_fvm();

    // Filters for visualization of Mach number, pressure and entropy.
    MachNumberFilter Mach_number(Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e), KAPPA);
    PressureFilter pressure(Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e), KAPPA);
    EntropyFilter entropy(Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e), KAPPA, RHO_EXT, P_EXT);

    ScalarView pressure_view("Pressure", new WinGeom(0, 0, 600, 300));
    ScalarView Mach_number_view("Mach number", new WinGeom(700, 0, 600, 300));
    ScalarView entropy_production_view("Entropy estimate", new WinGeom(0, 400, 600, 300));


    ScalarView s1("1", new WinGeom(0, 0, 600, 300));
    ScalarView s2("2", new WinGeom(700, 0, 600, 300));
    ScalarView s3("3", new WinGeom(0, 400, 600, 300));
    ScalarView s4("4", new WinGeom(700, 400, 600, 300));


    // Set up the solver, matrix, and rhs according to the solver selection.
    SparseMatrix* matrix = create_matrix(matrix_solver);
    Vector* rhs = create_vector(matrix_solver);
    Solver* solver = create_linear_solver(matrix_solver, matrix, rhs);

    // Set up CFL calculation class.
    CFLCalculation CFL(CFL_NUMBER, KAPPA);

    int iteration = 0;
    double t = 0;
    for(t = 0.0; t < 3.0; t += time_step) {
        info("---- Time step %d, time %3.5f.", iteration++, t);

        // Set the current time step.
        wf.set_time_step(time_step);

        bool rhs_only = (iteration == 1 ? false : true);
        // Assemble stiffness matrix and rhs or just rhs.
        if (rhs_only == false) {
            info("Assembling the stiffness matrix and right-hand side vector.");
            dp.assemble(matrix, rhs);
        }

        else {
            info("Assembling the right-hand side vector (only).");
            dp.assemble(NULL, rhs);
        }

        // Solve the matrix problem.
        info("Solving the matrix problem.");
        scalar* solution_vector = NULL;
        if(solver->solve()) {
            solution_vector = solver->get_solution();
            Solution::vector_to_solutions(solution_vector, Hermes::vector<Space *>(&space_rho, &space_rho_v_x,
                                          &space_rho_v_y, &space_e), Hermes::vector<Solution *>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
        }
        else
            error ("Matrix solver failed.\n");

        if(SHOCK_CAPTURING) {
            DiscontinuityDetector discontinuity_detector(Hermes::vector<Space *>(&space_rho, &space_rho_v_x,
                    &space_rho_v_y, &space_e), Hermes::vector<Solution *>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));

            std::set<int> discontinuous_elements = discontinuity_detector.get_discontinuous_element_ids(DISCONTINUITY_DETECTOR_PARAM);

            FluxLimiter flux_limiter(solution_vector, Hermes::vector<Space *>(&space_rho, &space_rho_v_x,
                                     &space_rho_v_y, &space_e), Hermes::vector<Solution *>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));

            flux_limiter.limit_according_to_detector(discontinuous_elements);
        }

        if((iteration - 1) % CFL_CALC_FREQ == 0)
            CFL.calculate(Hermes::vector<Solution *>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e), &mesh, time_step);

        // Visualization.
        /*
        Mach_number.reinit();
        pressure.reinit();
        entropy.reinit();
        pressure_view.show(&pressure);
        entropy_production_view.show(&entropy);
        Mach_number_view.show(&Mach_number);
        */

        s1.show(&prev_rho);
        s2.show(&prev_rho_v_x);
        s3.show(&prev_rho_v_y);
        s4.show(&prev_e);

        View::wait();

    }

    pressure_view.close();
    entropy_production_view.close();
    Mach_number_view.close();


    s1.close();
    s2.close();
    s3.close();
    s4.close();


    return 0;
}

Beispiel #2

Datei: main.cpp Projekt: sriharifez/hermes

int main(int argc, char* argv[])
{
  // Load the mesh.
  Mesh mesh;
  H2DReader mloader;
  mloader.load("GAMM-channel.mesh", &mesh);

  // Perform initial mesh refinements.
  for (int i = 0; i < INIT_REF_NUM; i++) mesh.refine_all_elements();
  mesh.refine_towards_boundary(1, 1);
  mesh.refine_element(1053);
  mesh.refine_element(1054);
  mesh.refine_element(1087);
  mesh.refine_element(1088);
  mesh.refine_element(1117);
  mesh.refine_element(1118);
  mesh.refine_element(1151);
  mesh.refine_element(1152);

  // Enter boundary markers.  
  BCTypes bc_types;
  bc_types.add_bc_neumann(Hermes::Tuple<int>(BDY_SOLID_WALL, BDY_INLET_OUTLET));

  // Create L2 spaces with default shapesets.
  L2Space space_rho(&mesh, &bc_types, P_INIT);
  L2Space space_rho_v_x(&mesh, &bc_types, P_INIT);
  L2Space space_rho_v_y(&mesh, &bc_types, P_INIT);
  L2Space space_e(&mesh, &bc_types, P_INIT);

  // Initialize solutions, set initial conditions.
  Solution sln_rho, sln_rho_v_x, sln_rho_v_y, sln_e, prev_rho, prev_rho_v_x, prev_rho_v_y, prev_e;
  sln_rho.set_exact(&mesh, ic_density);
  sln_rho_v_x.set_exact(&mesh, ic_density_vel_x);
  sln_rho_v_y.set_exact(&mesh, ic_density_vel_y);
  sln_e.set_exact(&mesh, ic_energy);
  prev_rho.set_exact(&mesh, ic_density);
  prev_rho_v_x.set_exact(&mesh, ic_density_vel_x);
  prev_rho_v_y.set_exact(&mesh, ic_density_vel_y);
  prev_e.set_exact(&mesh, ic_energy);

  // Initialize weak formulation.
  WeakForm wf(4);

  // Bilinear forms coming from time discretization by explicit Euler's method.
  wf.add_matrix_form(0, 0, callback(bilinear_form_0_0_time));
  wf.add_matrix_form(1, 1, callback(bilinear_form_1_1_time));
  wf.add_matrix_form(2, 2, callback(bilinear_form_2_2_time));
  wf.add_matrix_form(3, 3, callback(bilinear_form_3_3_time));

  // Volumetric linear forms.
  // Linear forms coming from the linearization by taking the Eulerian fluxes' Jacobian matrices 
  // from the previous time step.
  // First flux.
  // Unnecessary for FVM.
  if(P_INIT.order_h > 0 || P_INIT.order_v > 0) {
    wf.add_vector_form(0, callback(linear_form_0_1), HERMES_ANY, Hermes::Tuple<MeshFunction*>(&prev_rho_v_x));
    
    wf.add_vector_form(1, callback(linear_form_1_0_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_1_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_2_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_3_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(2, callback(linear_form_2_0_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_1_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_2_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_3_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_0_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_1_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_2_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_3_first_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    // Second flux.
    
    wf.add_vector_form(0, callback(linear_form_0_2), HERMES_ANY, Hermes::Tuple<MeshFunction*>(&prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_0_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_1_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_2_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_3_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(2, callback(linear_form_2_0_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_1_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_2_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_3_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_0_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_1_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_2_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_3_second_flux), HERMES_ANY, 
                       Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  }

  // Volumetric linear forms coming from the time discretization.
#ifdef HERMES_USE_VECTOR_VALUED_FORMS
  wf.add_vector_form(0, linear_form_vector, linear_form_order, HERMES_ANY, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form(1, linear_form_vector, linear_form_order, HERMES_ANY, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form(2, linear_form_vector, linear_form_order, HERMES_ANY, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form(3, linear_form_vector, linear_form_order, HERMES_ANY, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
#else
  wf.add_vector_form(0, linear_form, linear_form_order, HERMES_ANY, &prev_rho);
  wf.add_vector_form(1, linear_form, linear_form_order, HERMES_ANY, &prev_rho_v_x);
  wf.add_vector_form(2, linear_form, linear_form_order, HERMES_ANY, &prev_rho_v_y);
  wf.add_vector_form(3, linear_form, linear_form_order, HERMES_ANY, &prev_e);
#endif

  // Surface linear forms - inner edges coming from the DG formulation.
#ifdef HERMES_USE_VECTOR_VALUED_FORMS
  wf.add_vector_form_surf(0, linear_form_interface_vector, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, linear_form_interface_vector, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, linear_form_interface_vector, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, linear_form_interface_vector, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
#else
  wf.add_vector_form_surf(0, linear_form_interface_0, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, linear_form_interface_1, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, linear_form_interface_2, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, linear_form_interface_3, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
#endif

  // Surface linear forms - inlet / outlet edges.
#ifdef HERMES_USE_VECTOR_VALUED_FORMS
  wf.add_vector_form_surf(0, bdy_flux_inlet_outlet_comp_vector, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, bdy_flux_inlet_outlet_comp_vector, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, bdy_flux_inlet_outlet_comp_vector, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, bdy_flux_inlet_outlet_comp_vector, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
#else
  wf.add_vector_form_surf(0, bdy_flux_inlet_outlet_comp_0, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, bdy_flux_inlet_outlet_comp_1, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, bdy_flux_inlet_outlet_comp_2, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, bdy_flux_inlet_outlet_comp_3, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
#endif
  
  // Surface linear forms - Solid wall edges.
#ifdef HERMES_USE_VECTOR_VALUED_FORMS
  wf.add_vector_form_surf(0, bdy_flux_solid_wall_comp_vector, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, bdy_flux_solid_wall_comp_vector, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, bdy_flux_solid_wall_comp_vector, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, bdy_flux_solid_wall_comp_vector, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
#else
  wf.add_vector_form_surf(0, bdy_flux_solid_wall_comp_0, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, bdy_flux_solid_wall_comp_1, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, bdy_flux_solid_wall_comp_2, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, bdy_flux_solid_wall_comp_3, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::Tuple<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
#endif

  // Initialize the FE problem.
  bool is_linear = true;
  
  DiscreteProblem dp(&wf, Hermes::Tuple<Space*>(&space_rho, &space_rho_v_x, &space_rho_v_y, &space_e), is_linear);
  
  // If the FE problem is in fact a FV problem.
  if(P_INIT.order_h == 0 && P_INIT.order_v == 0)
    dp.set_fvm();
#ifdef HERMES_USE_VECTOR_VALUED_FORMS
  dp.use_vector_valued_forms();
#endif

  // Filters for visualization of pressure and the two components of velocity.
  SimpleFilter pressure(calc_pressure_func, Hermes::Tuple<MeshFunction*>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));
  SimpleFilter u(calc_u_func, Hermes::Tuple<MeshFunction*>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));
  SimpleFilter w(calc_w_func, Hermes::Tuple<MeshFunction*>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));
  SimpleFilter Mach_number(calc_Mach_func, Hermes::Tuple<MeshFunction*>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));
  SimpleFilter entropy_estimate(calc_entropy_estimate_func, Hermes::Tuple<MeshFunction*>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));

  ScalarView pressure_view("Pressure", new WinGeom(0, 0, 600, 300));
  ScalarView Mach_number_view("Mach number", new WinGeom(700, 0, 600, 300));
  ScalarView entropy_production_view("Entropy estimate", new WinGeom(0, 400, 600, 300));
  VectorView vview("Velocity", new WinGeom(700, 400, 600, 300));

  // Iteration number.
  int iteration = 0;
  
  // Set up the solver, matrix, and rhs according to the solver selection.
  SparseMatrix* matrix = create_matrix(matrix_solver);
  Vector* rhs = create_vector(matrix_solver);
  Solver* solver = create_linear_solver(matrix_solver, matrix, rhs);

  // Output of the approximate time derivative.
  std::ofstream time_der_out("time_der");

  for(t = 0.0; t < 10; t += TAU)
  {
    info("---- Time step %d, time %3.5f.", iteration, t);

    iteration++;

    bool rhs_only = (iteration == 1 ? false : true);
    // Assemble stiffness matrix and rhs or just rhs.
    if (rhs_only == false) info("Assembling the stiffness matrix and right-hand side vector.");
    else info("Assembling the right-hand side vector (only).");
    dp.assemble(matrix, rhs, rhs_only);

        
    // Solve the matrix problem.
    info("Solving the matrix problem.");
    if(solver->solve())
      Solution::vector_to_solutions(solver->get_solution(), Hermes::Tuple<Space *>(&space_rho, &space_rho_v_x, 
      &space_rho_v_y, &space_e), Hermes::Tuple<Solution *>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));
    else
    error ("Matrix solver failed.\n");

    // Approximate the time derivative of the solution.
    if(CALC_TIME_DER) {
      Adapt *adapt_for_time_der_calc = new Adapt(Hermes::Tuple<Space *>(&space_rho, &space_rho_v_x, &space_rho_v_y, &space_e));
      bool solutions_for_adapt = false;
      double difference = iteration == 1 ? 0 : 
        adapt_for_time_der_calc->calc_err_est(Hermes::Tuple<Solution *>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e), 
					      Hermes::Tuple<Solution *>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e), 
                                              (Hermes::Tuple<double>*) NULL, solutions_for_adapt, 
                                              HERMES_TOTAL_ERROR_ABS | HERMES_ELEMENT_ERROR_ABS) / TAU;
      delete adapt_for_time_der_calc;

      // Info about the approximate time derivative.
      if(iteration > 1)
      {
        info("Approximate the norm time derivative : %g.", difference);
        time_der_out << iteration << '\t' << difference << std::endl;
      }
    }

    // Determine the time step according to the CFL condition.
    // Only mean values on an element of each solution component are taken into account.
    double *solution_vector = solver->get_solution();
    double min_condition = 0;
    Element *e;
    for (int _id = 0, _max = mesh.get_max_element_id(); _id < _max; _id++) \
          if (((e) = mesh.get_element_fast(_id))->used) \
            if ((e)->active)
    {
      AsmList al;
      space_rho.get_element_assembly_list(e, &al);
      double rho = solution_vector[al.dof[0]];
      space_rho_v_x.get_element_assembly_list(e, &al);
      double v1 = solution_vector[al.dof[0]] / rho;
      space_rho_v_y.get_element_assembly_list(e, &al);
      double v2 = solution_vector[al.dof[0]] / rho;
      space_e.get_element_assembly_list(e, &al);
      double energy = solution_vector[al.dof[0]];
      
      double condition = e->get_area() / (std::sqrt(v1*v1 + v2*v2) + calc_sound_speed(rho, rho*v1, rho*v2, energy));
      
      if(condition < min_condition || min_condition == 0.)
        min_condition = condition;
    }
    if(TAU > min_condition)
      TAU = min_condition;
    if(TAU < min_condition * 0.9)
      TAU = min_condition;

    // Copy the solutions into the previous time level ones.
    prev_rho.copy(&sln_rho);
    prev_rho_v_x.copy(&sln_rho_v_x);
    prev_rho_v_y.copy(&sln_rho_v_y);
    prev_e.copy(&sln_e);

    // Visualization.
    pressure.reinit();
    u.reinit();
    w.reinit();
    Mach_number.reinit();
    entropy_estimate.reinit();
    pressure_view.show(&pressure);
    entropy_production_view.show(&entropy_estimate);
    Mach_number_view.show(&Mach_number);
    vview.show(&u, &w);

    // If used, we need to clean the vector valued form caches.
#ifdef HERMES_USE_VECTOR_VALUED_FORMS
    DiscreteProblem::empty_form_caches();
#endif
  }
  
  time_der_out.close();
  return 0;
}

Beispiel #3

Datei: main.cpp Projekt: Zhonghua/hermes-dev

int main(int argc, char* argv[])
{
  // Load the mesh.
  Mesh basemesh;
  H2DReader mloader;
  mloader.load("GAMM-channel.mesh", &basemesh);

  // Initialize the meshes.
  Mesh mesh_flow, mesh_concentration;
  mesh_flow.copy(&basemesh);
  mesh_concentration.copy(&basemesh);

  for(unsigned int i = 0; i < INIT_REF_NUM_CONCENTRATION; i++)
    mesh_concentration.refine_all_elements();

  mesh_concentration.refine_towards_boundary(BDY_DIRICHLET_CONCENTRATION, INIT_REF_NUM_CONCENTRATION_BDY);
  mesh_flow.refine_towards_boundary(BDY_DIRICHLET_CONCENTRATION, INIT_REF_NUM_CONCENTRATION_BDY);

  for(unsigned int i = 0; i < INIT_REF_NUM_FLOW; i++)
    mesh_flow.refine_all_elements();

  // Initialize boundary condition types and spaces with default shapesets.
  // For the concentration.
  EssentialBCs bcs_concentration;
  
  bcs_concentration.add_boundary_condition(new ConcentrationTimedepEssentialBC(BDY_DIRICHLET_CONCENTRATION, CONCENTRATION_EXT, CONCENTRATION_EXT_STARTUP_TIME));
  bcs_concentration.add_boundary_condition(new ConcentrationTimedepEssentialBC(BDY_SOLID_WALL_TOP, 0.0, CONCENTRATION_EXT_STARTUP_TIME));
  
  L2Space space_rho(&mesh_flow, P_INIT_FLOW);
  L2Space space_rho_v_x(&mesh_flow, P_INIT_FLOW);
  L2Space space_rho_v_y(&mesh_flow, P_INIT_FLOW);
  L2Space space_e(&mesh_flow, P_INIT_FLOW);
  // Space for concentration.
  H1Space space_c(&mesh_concentration, &bcs_concentration, P_INIT_CONCENTRATION);

  int ndof = Space::get_num_dofs(Hermes::vector<Space*>(&space_rho, &space_rho_v_x, &space_rho_v_y, &space_e, &space_c));
  info("ndof: %d", ndof);

  // Initialize solutions, set initial conditions.
  InitialSolutionEulerDensity prev_rho(&mesh_flow, RHO_EXT);
  InitialSolutionEulerDensityVelX prev_rho_v_x(&mesh_flow, RHO_EXT * V1_EXT);
  InitialSolutionEulerDensityVelY prev_rho_v_y(&mesh_flow, RHO_EXT * V2_EXT);
  InitialSolutionEulerDensityEnergy prev_e(&mesh_flow, QuantityCalculator::calc_energy(RHO_EXT, RHO_EXT * V1_EXT, RHO_EXT * V2_EXT, P_EXT, KAPPA));
  InitialSolutionConcentration prev_c(&mesh_concentration, 0.0);

  // Numerical flux.
  OsherSolomonNumericalFlux num_flux(KAPPA);

  // Initialize weak formulation.
  EulerEquationsWeakFormSemiImplicitCoupled wf(&num_flux, KAPPA, RHO_EXT, V1_EXT, V2_EXT, P_EXT, BDY_SOLID_WALL_BOTTOM,
    BDY_SOLID_WALL_TOP, BDY_INLET, BDY_OUTLET, BDY_NATURAL_CONCENTRATION, &prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e, &prev_c, EPSILON, (P_INIT_FLOW == 0));
  
  wf.set_time_step(time_step);

  // Initialize the FE problem.
  DiscreteProblem dp(&wf, Hermes::vector<Space*>(&space_rho, &space_rho_v_x, &space_rho_v_y, &space_e, &space_c));

  // If the FE problem is in fact a FV problem.
  //if(P_INIT == 0) dp.set_fvm();  

  // Filters for visualization of Mach number, pressure and entropy.
  MachNumberFilter Mach_number(Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e), KAPPA);
  PressureFilter pressure(Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e), KAPPA);
  EntropyFilter entropy(Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e), KAPPA, RHO_EXT, P_EXT);

  /*
  ScalarView pressure_view("Pressure", new WinGeom(0, 0, 600, 300));
  ScalarView Mach_number_view("Mach number", new WinGeom(700, 0, 600, 300));
  ScalarView entropy_production_view("Entropy estimate", new WinGeom(0, 400, 600, 300));
  ScalarView s5("Concentration", new WinGeom(700, 400, 600, 300));
  */
  
  ScalarView s1("1", new WinGeom(0, 0, 600, 300));
  ScalarView s2("2", new WinGeom(700, 0, 600, 300));
  ScalarView s3("3", new WinGeom(0, 400, 600, 300));
  ScalarView s4("4", new WinGeom(700, 400, 600, 300));
  ScalarView s5("Concentration", new WinGeom(350, 200, 600, 300));

  // Set up the solver, matrix, and rhs according to the solver selection.
  SparseMatrix* matrix = create_matrix(matrix_solver);
  Vector* rhs = create_vector(matrix_solver);
  Solver* solver = create_linear_solver(matrix_solver, matrix, rhs);

  // Set up CFL calculation class.
  CFLCalculation CFL(CFL_NUMBER, KAPPA);

  // Set up Advection-Diffusion-Equation stability calculation class.
  ADEStabilityCalculation ADES(ADVECTION_STABILITY_CONSTANT, DIFFUSION_STABILITY_CONSTANT, EPSILON);

  int iteration = 0; double t = 0;
  for(t = 0.0; t < 100.0; t += time_step) {
    info("---- Time step %d, time %3.5f.", iteration++, t);

    // Set the current time step.
    wf.set_time_step(time_step);
    Space::update_essential_bc_values(&space_c, t);

    // Assemble stiffness matrix and rhs.
    info("Assembling the stiffness matrix and right-hand side vector.");
    dp.assemble(matrix, rhs);

    // Solve the matrix problem.
    info("Solving the matrix problem.");
    scalar* solution_vector = NULL;
    if(solver->solve()) {
      solution_vector = solver->get_solution();
      Solution::vector_to_solutions(solution_vector, Hermes::vector<Space *>(&space_rho, &space_rho_v_x, 
      &space_rho_v_y, &space_e, &space_c), Hermes::vector<Solution *>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e, &prev_c));
    }
    else
    error ("Matrix solver failed.\n");

    if(SHOCK_CAPTURING) {
      DiscontinuityDetector discontinuity_detector(Hermes::vector<Space *>(&space_rho, &space_rho_v_x, 
        &space_rho_v_y, &space_e), Hermes::vector<Solution *>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));

      std::set<int> discontinuous_elements = discontinuity_detector.get_discontinuous_element_ids(DISCONTINUITY_DETECTOR_PARAM);

      FluxLimiter flux_limiter(solution_vector, Hermes::vector<Space *>(&space_rho, &space_rho_v_x, 
        &space_rho_v_y, &space_e), Hermes::vector<Solution *>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));

      flux_limiter.limit_according_to_detector(discontinuous_elements);
    }

    util_time_step = time_step;

    CFL.calculate_semi_implicit(Hermes::vector<Solution *>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e), &mesh_flow, util_time_step);

    time_step = util_time_step;

    ADES.calculate(Hermes::vector<Solution *>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y), &mesh_concentration, util_time_step);

    if(util_time_step < time_step)
      time_step = util_time_step;

    // Visualization.
    if((iteration - 1) % EVERY_NTH_STEP == 0) {
      // Hermes visualization.
      if(HERMES_VISUALIZATION) {
        /*
        Mach_number.reinit();
        pressure.reinit();
        entropy.reinit();
        pressure_view.show(&pressure);
        entropy_production_view.show(&entropy);
        Mach_number_view.show(&Mach_number);
        s5.show(&prev_c);
        */
        s1.show(&prev_rho);
        s2.show(&prev_rho_v_x);
        s3.show(&prev_rho_v_y);
        s4.show(&prev_e);
        s5.show(&prev_c);
        /*
        s1.save_numbered_screenshot("density%i.bmp", iteration, true);
        s2.save_numbered_screenshot("density_v_x%i.bmp", iteration, true);
        s3.save_numbered_screenshot("density_v_y%i.bmp", iteration, true);
        s4.save_numbered_screenshot("energy%i.bmp", iteration, true);
        s5.save_numbered_screenshot("concentration%i.bmp", iteration, true);
        */
        //s5.wait_for_close();
        
      }
      // Output solution in VTK format.
      if(VTK_VISUALIZATION) {
        pressure.reinit();
        Mach_number.reinit();
        Linearizer lin;
        char filename[40];
        sprintf(filename, "pressure-%i.vtk", iteration - 1);
        lin.save_solution_vtk(&pressure, filename, "Pressure", false);
        sprintf(filename, "pressure-3D-%i.vtk", iteration - 1);
        lin.save_solution_vtk(&pressure, filename, "Pressure", true);
        sprintf(filename, "Mach number-%i.vtk", iteration - 1);
        lin.save_solution_vtk(&Mach_number, filename, "MachNumber", false);
        sprintf(filename, "Mach number-3D-%i.vtk", iteration - 1);
        lin.save_solution_vtk(&Mach_number, filename, "MachNumber", true);
        sprintf(filename, "Concentration-%i.vtk", iteration - 1);
        lin.save_solution_vtk(&prev_c, filename, "Concentration", true);
        sprintf(filename, "Concentration-3D-%i.vtk", iteration - 1);
        lin.save_solution_vtk(&prev_c, filename, "Concentration", true);
 
      }
    }
  }
  
  /*
  pressure_view.close();
  entropy_production_view.close();
  Mach_number_view.close();
  s5.close();
  */
  
  s1.close();
  s2.close();
  s3.close();
  s4.close();
  s5.close();

  return 0;
}

Beispiel #4

Datei: main.cpp Projekt: alieed/hermes

int main(int argc, char* argv[])
{
  // Provide a possibility to change INITIAL_CONCENTRATION_STATE through an argument.
  if(argc > 1)
    INITIAL_CONCENTRATION_STATE = atoi(argv[1]);

  if(argc > 2)
    INIT_REF_NUM_FLOW = atoi(argv[2]);

  if(argc > 3)
    INIT_REF_NUM_CONCENTRATION = atoi(argv[3]);

  // Load the mesh.
  Mesh basemesh;
  H2DReader mloader;
  if(INITIAL_CONCENTRATION_STATE == 0)
    mloader.load("GAMM-channel-4-bnds.mesh", &basemesh);
  else
    mloader.load("channel-4-bnds.mesh", &basemesh);


  // Initialize the meshes.
  Mesh mesh_flow, mesh_concentration;
  mesh_flow.copy(&basemesh);
  mesh_concentration.copy(&basemesh);

  for(unsigned int i = 0; i < INIT_REF_NUM_CONCENTRATION; i++)
    mesh_concentration.refine_all_elements();

  for(unsigned int i = 0; i < INIT_REF_NUM_FLOW; i++)
    mesh_flow.refine_all_elements();

  // Initialize boundary condition types and spaces with default shapesets.
  BCTypes bc_types_euler;
  bc_types_euler.add_bc_neumann(Hermes::vector<int>(BDY_SOLID_WALL_TOP, BDY_SOLID_WALL_BOTTOM, BDY_INLET, BDY_OUTLET));

  BCTypes bc_types_concentration;
  BCValues bc_values_concentration;

  switch(INITIAL_CONCENTRATION_STATE) {
  case 0:
    bc_types_concentration.add_bc_neumann(Hermes::vector<int>(BDY_INLET, BDY_OUTLET, BDY_SOLID_WALL_TOP));
    bc_types_concentration.add_bc_dirichlet(Hermes::vector<int>(BDY_SOLID_WALL_BOTTOM));
    bc_values_concentration.add_const(Hermes::vector<int>(BDY_SOLID_WALL_BOTTOM), CONCENTRATION_EXT);
    break;
  case 1:
    bc_types_concentration.add_bc_neumann(Hermes::vector<int>(BDY_INLET, BDY_OUTLET, BDY_SOLID_WALL_TOP));
    bc_types_concentration.add_bc_dirichlet(Hermes::vector<int>(BDY_SOLID_WALL_BOTTOM));
    bc_values_concentration.add_const(Hermes::vector<int>(BDY_SOLID_WALL_BOTTOM), CONCENTRATION_EXT);
    break;
  case 2:
    bc_types_concentration.add_bc_neumann(Hermes::vector<int>(BDY_SOLID_WALL_BOTTOM, BDY_OUTLET, BDY_SOLID_WALL_TOP));
    bc_types_concentration.add_bc_dirichlet(Hermes::vector<int>(BDY_INLET));
    bc_values_concentration.add_const(Hermes::vector<int>(BDY_INLET), CONCENTRATION_EXT);
    break;
  }

  L2Space space_rho(&mesh_flow, &bc_types_euler, P_INIT_FLOW);
  L2Space space_rho_v_x(&mesh_flow, &bc_types_euler, P_INIT_FLOW);
  L2Space space_rho_v_y(&mesh_flow, &bc_types_euler, P_INIT_FLOW);
  L2Space space_e(&mesh_flow, &bc_types_euler, P_INIT_FLOW);
  // Space for concentration.
  H1Space space_c(&mesh_concentration, &bc_types_concentration, &bc_values_concentration, P_INIT_CONCENTRATION);

  // Initialize solutions, set initial conditions.
  Solution sln_rho, sln_rho_v_x, sln_rho_v_y, sln_e, sln_c, prev_rho, prev_rho_v_x, prev_rho_v_y, prev_e, prev_c;
  sln_rho.set_exact(&mesh_flow, ic_density);
  sln_rho_v_x.set_exact(&mesh_flow, ic_density_vel_x);
  sln_rho_v_y.set_exact(&mesh_flow, ic_density_vel_y);
  sln_e.set_exact(&mesh_flow, ic_energy);
  sln_c.set_exact(&mesh_concentration, ic_concentration);
  prev_rho.set_exact(&mesh_flow, ic_density);
  prev_rho_v_x.set_exact(&mesh_flow, ic_density_vel_x);
  prev_rho_v_y.set_exact(&mesh_flow, ic_density_vel_y);
  prev_e.set_exact(&mesh_flow, ic_energy);
  prev_c.set_exact(&mesh_concentration, ic_concentration);

  // Initialize weak formulation.
  WeakForm wf(5);

  // Bilinear forms coming from time discretization by explicit Euler's method.
  wf.add_matrix_form(0, 0, callback(bilinear_form_time));
  wf.add_matrix_form(1, 1, callback(bilinear_form_time));
  wf.add_matrix_form(2, 2, callback(bilinear_form_time));
  wf.add_matrix_form(3, 3, callback(bilinear_form_time));
  wf.add_matrix_form(4, 4, callback(bilinear_form_time));

  // Volumetric linear forms.
  // Linear forms coming from the linearization by taking the Eulerian fluxes' Jacobian matrices 
  // from the previous time step.
  // Unnecessary for FVM.
  if(P_INIT_FLOW.order_h > 0 || P_INIT_FLOW.order_v > 0) {
    // First flux.
    wf.add_vector_form(0, callback(linear_form_0_1), HERMES_ANY, Hermes::vector<MeshFunction*>(&prev_rho_v_x));
    
    wf.add_vector_form(1, callback(linear_form_1_0_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_1_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_2_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_3_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(2, callback(linear_form_2_0_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_1_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_2_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_3_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_0_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_1_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_2_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_3_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    // Second flux.
    wf.add_vector_form(0, callback(linear_form_0_2), HERMES_ANY, Hermes::vector<MeshFunction*>(&prev_rho_v_y));
    
    wf.add_vector_form(1, callback(linear_form_1_0_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_1_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_2_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_3_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(2, callback(linear_form_2_0_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_1_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_2_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_3_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_0_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_1_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_2_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_3_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  }

  // Volumetric linear forms coming from the time discretization.
  wf.add_vector_form(0, linear_form_time, linear_form_order, HERMES_ANY, &prev_rho);
  wf.add_vector_form(1, linear_form_time, linear_form_order, HERMES_ANY, &prev_rho_v_x);
  wf.add_vector_form(2, linear_form_time, linear_form_order, HERMES_ANY, &prev_rho_v_y);
  wf.add_vector_form(3, linear_form_time, linear_form_order, HERMES_ANY, &prev_e);
  wf.add_vector_form(4, callback(linear_form_time_concentration), HERMES_ANY, &prev_c);

  // Surface linear forms - inner edges coming from the DG formulation.
  wf.add_vector_form_surf(0, linear_form_interface_0, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, linear_form_interface_1, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, linear_form_interface_2, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, linear_form_interface_3, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));


  // Surface linear forms - inlet / outlet edges.
  wf.add_vector_form_surf(0, bdy_flux_inlet_outlet_comp_0, linear_form_order, BDY_INLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, bdy_flux_inlet_outlet_comp_1, linear_form_order, BDY_INLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, bdy_flux_inlet_outlet_comp_2, linear_form_order, BDY_INLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, bdy_flux_inlet_outlet_comp_3, linear_form_order, BDY_INLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  
  wf.add_vector_form_surf(0, bdy_flux_inlet_outlet_comp_0, linear_form_order, BDY_OUTLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, bdy_flux_inlet_outlet_comp_1, linear_form_order, BDY_OUTLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, bdy_flux_inlet_outlet_comp_2, linear_form_order, BDY_OUTLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, bdy_flux_inlet_outlet_comp_3, linear_form_order, BDY_OUTLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  
  // Surface linear forms - Solid wall edges.
  wf.add_vector_form_surf(0, bdy_flux_solid_wall_comp_0, linear_form_order, BDY_SOLID_WALL_TOP, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, bdy_flux_solid_wall_comp_1, linear_form_order, BDY_SOLID_WALL_TOP, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, bdy_flux_solid_wall_comp_2, linear_form_order, BDY_SOLID_WALL_TOP, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, bdy_flux_solid_wall_comp_3, linear_form_order, BDY_SOLID_WALL_TOP, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));

  wf.add_vector_form_surf(0, bdy_flux_solid_wall_comp_0, linear_form_order, BDY_SOLID_WALL_BOTTOM, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, bdy_flux_solid_wall_comp_1, linear_form_order, BDY_SOLID_WALL_BOTTOM, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, bdy_flux_solid_wall_comp_2, linear_form_order, BDY_SOLID_WALL_BOTTOM, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, bdy_flux_solid_wall_comp_3, linear_form_order, BDY_SOLID_WALL_BOTTOM, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));

  // Forms for concentration.
  wf.add_vector_form(4, callback(linear_form_concentration_grad_grad), HERMES_ANY, &prev_c);
  
  wf.add_vector_form(4, callback(linear_form_concentration_convective), HERMES_ANY, 
                          Hermes::vector<MeshFunction*>(&prev_c, &prev_rho, &prev_rho_v_x, &prev_rho_v_y));

  wf.add_vector_form_surf(4, callback(linear_form_concentration_inlet_outlet), BDY_INLET, 
                          Hermes::vector<MeshFunction*>(&prev_c, &prev_rho, &prev_rho_v_x, &prev_rho_v_y));

  wf.add_vector_form_surf(4, callback(linear_form_concentration_inlet_outlet), BDY_OUTLET, 
                          Hermes::vector<MeshFunction*>(&prev_c, &prev_rho, &prev_rho_v_x, &prev_rho_v_y));

  wf.add_vector_form_surf(4, callback(linear_form_concentration_inner_edges), H2D_DG_INNER_EDGE, 
                          Hermes::vector<MeshFunction*>(&prev_c, &prev_rho, &prev_rho_v_x, &prev_rho_v_y));

  // Initialize the FE problem.
  bool is_linear = true;
  
  DiscreteProblem dp(&wf, Hermes::vector<Space*>(&space_rho, &space_rho_v_x, &space_rho_v_y, &space_e, &space_c), is_linear);
  
  // Filters for visualization of pressure and the two components of velocity.
  /*
  SimpleFilter pressure(calc_pressure_func, Hermes::vector<MeshFunction*>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));
  SimpleFilter u(calc_u_func, Hermes::vector<MeshFunction*>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));
  SimpleFilter w(calc_w_func, Hermes::vector<MeshFunction*>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));
  SimpleFilter Mach_number(calc_Mach_func, Hermes::vector<MeshFunction*>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));
  SimpleFilter entropy_estimate(calc_entropy_estimate_func, Hermes::vector<MeshFunction*>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));

  ScalarView pressure_view("Pressure", new WinGeom(0, 0, 600, 300));
  ScalarView Mach_number_view("Mach number", new WinGeom(700, 0, 600, 300));
  ScalarView entropy_production_view("Entropy estimate", new WinGeom(0, 400, 600, 300));
  VectorView vview("Velocity", new WinGeom(700, 400, 600, 300));
  */

  ScalarView s1("w0", new WinGeom(0, 0, 600, 300));
  ScalarView s2("w1", new WinGeom(700, 0, 600, 300));
  ScalarView s3("w2", new WinGeom(0, 400, 600, 300));
  ScalarView s4("w3", new WinGeom(700, 400, 600, 300));
  ScalarView s5("Concentration", new WinGeom(350, 200, 600, 300));
  
  // Iteration number.
  int iteration = 0;
  
  // Set up the solver, matrix, and rhs according to the solver selection.
  SparseMatrix* matrix = create_matrix(matrix_solver);
  Vector* rhs = create_vector(matrix_solver);
  Solver* solver = create_linear_solver(matrix_solver, matrix, rhs);

  // Output of the approximate time derivative.
  std::ofstream time_der_out("time_der");

  for(t = 0.0; t < 3.0; t += TAU) {
    info("---- Time step %d, time %3.5f.", iteration++, t);

    bool rhs_only = (iteration == 1 ? false : true);
    // Assemble stiffness matrix and rhs or just rhs.
    if (rhs_only == false) info("Assembling the stiffness matrix and right-hand side vector.");
    else info("Assembling the right-hand side vector (only).");
    dp.assemble(matrix, rhs, rhs_only);
        
    // Solve the matrix problem.
    info("Solving the matrix problem.");
    if(solver->solve())
      Solution::vector_to_solutions(solver->get_solution(), Hermes::vector<Space *>(&space_rho, &space_rho_v_x, 
      &space_rho_v_y, &space_e, &space_c), Hermes::vector<Solution *>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e, &sln_c));
    else
    error ("Matrix solver failed.\n");

    // Copy the solutions into the previous time level ones.
    prev_rho.copy(&sln_rho);
    prev_rho_v_x.copy(&sln_rho_v_x);
    prev_rho_v_y.copy(&sln_rho_v_y);
    prev_e.copy(&sln_e);
    prev_c.copy(&sln_c);

    // Visualization.
    /*
    pressure.reinit();
    u.reinit();
    w.reinit();
    Mach_number.reinit();
    entropy_estimate.reinit();
    pressure_view.show(&pressure);
    entropy_production_view.show(&entropy_estimate);
    Mach_number_view.show(&Mach_number);
    vview.show(&u, &w);
    */

    // Visualization.
    if((iteration - 1) % EVERY_NTH_STEP == 0) {
      // Hermes visualization.
      if(HERMES_VISUALIZATION) {
        s1.show(&prev_rho);
        s2.show(&prev_rho_v_x);
        s3.show(&prev_rho_v_y);
        s4.show(&prev_e);
        s5.show(&prev_c);
      }
      // Output solution in VTK format.
      if(VTK_OUTPUT) {
        Linearizer lin;
        char filename[40];
        sprintf(filename, "w0-%i.vtk", iteration - 1);
        lin.save_solution_vtk(&prev_rho, filename, "w0", false);
        sprintf(filename, "w1-%i.vtk", iteration - 1);
        lin.save_solution_vtk(&prev_rho_v_x, filename, "w1", false);
        sprintf(filename, "w2-%i.vtk", iteration - 1);
        lin.save_solution_vtk(&prev_rho_v_y, filename, "w2", false);
        sprintf(filename, "w3-%i.vtk", iteration - 1);
        lin.save_solution_vtk(&prev_e, filename, "w3", false);
        sprintf(filename, "concentration-%i.vtk", iteration - 1);
        lin.save_solution_vtk(&prev_c, filename, "concentration", false);
      }
    }


  }
  
  s1.close();
  s2.close();
  s3.close();
  s4.close();
  s5.close();
  time_der_out.close();
  return 0;
}

Beispiel #5

Datei: main.cpp Projekt: alieed/hermes

int main(int argc, char* argv[])
{
  /* So far the DG assembling is very slow for higher order polynomials,
      so only constant functions are used here.
  if(argc < 3)
    error("Too few arguments in example-euler-gamm-explicit");

  Ord2 P_INIT= Ord2(atoi(argv[1]), atoi(argv[2]));
  */

  Ord2 P_INIT= Ord2(0, 0);

  // Load the mesh.
  Mesh mesh;
  H2DReader mloader;
  mloader.load("GAMM-channel.mesh", &mesh);

  // Perform initial mesh refinements.
  for (int i = 0; i < INIT_REF_NUM; i++) mesh.refine_all_elements();
  mesh.refine_towards_boundary(1, 1);
  mesh.refine_element_id(1053);
  mesh.refine_element_id(1054);
  mesh.refine_element_id(1087);
  mesh.refine_element_id(1088);
  mesh.refine_element_id(1117);
  mesh.refine_element_id(1118);
  mesh.refine_element_id(1151);
  mesh.refine_element_id(1152);

  // Enter boundary markers.  
  BCTypes bc_types;
  bc_types.add_bc_neumann(Hermes::vector<int>(BDY_SOLID_WALL, BDY_INLET_OUTLET));

  // Create L2 spaces with default shapesets.
  L2Space space_rho(&mesh, &bc_types, P_INIT);
  L2Space space_rho_v_x(&mesh, &bc_types, P_INIT);
  L2Space space_rho_v_y(&mesh, &bc_types, P_INIT);
  L2Space space_e(&mesh, &bc_types, P_INIT);

  // Initialize solutions, set initial conditions.
  Solution sln_rho, sln_rho_v_x, sln_rho_v_y, sln_e, prev_rho, prev_rho_v_x, prev_rho_v_y, prev_e;
  sln_rho.set_exact(&mesh, ic_density);
  sln_rho_v_x.set_exact(&mesh, ic_density_vel_x);
  sln_rho_v_y.set_exact(&mesh, ic_density_vel_y);
  sln_e.set_exact(&mesh, ic_energy);
  prev_rho.set_exact(&mesh, ic_density);
  prev_rho_v_x.set_exact(&mesh, ic_density_vel_x);
  prev_rho_v_y.set_exact(&mesh, ic_density_vel_y);
  prev_e.set_exact(&mesh, ic_energy);

  // Initialize weak formulation.
  WeakForm wf(4);

  // Bilinear forms coming from time discretization by explicit Euler's method.
  wf.add_matrix_form(0, 0, callback(bilinear_form_0_0_time));
  wf.add_matrix_form(1, 1, callback(bilinear_form_1_1_time));
  wf.add_matrix_form(2, 2, callback(bilinear_form_2_2_time));
  wf.add_matrix_form(3, 3, callback(bilinear_form_3_3_time));

  // Volumetric linear forms.
  // Linear forms coming from the linearization by taking the Eulerian fluxes' Jacobian matrices 
  // from the previous time step.
  // Unnecessary for FVM.
  if(P_INIT.order_h > 0 || P_INIT.order_v > 0) {
    // First flux.
    wf.add_vector_form(0, callback(linear_form_0_1), HERMES_ANY, Hermes::vector<MeshFunction*>(&prev_rho_v_x));
    
    wf.add_vector_form(1, callback(linear_form_1_0_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_1_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_2_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_3_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(2, callback(linear_form_2_0_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_1_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_2_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_3_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_0_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_1_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_2_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_3_first_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    // Second flux.
    
    wf.add_vector_form(0, callback(linear_form_0_2), HERMES_ANY, Hermes::vector<MeshFunction*>(&prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_0_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_1_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_2_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(1, callback(linear_form_1_3_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(2, callback(linear_form_2_0_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_1_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_2_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y));
    wf.add_vector_form(2, callback(linear_form_2_3_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_0_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_1_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_2_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
    wf.add_vector_form(3, callback(linear_form_3_3_second_flux), HERMES_ANY, 
                       Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  }

  // Volumetric linear forms coming from the time discretization.
  wf.add_vector_form(0, linear_form, linear_form_order, HERMES_ANY, &prev_rho);
  wf.add_vector_form(1, linear_form, linear_form_order, HERMES_ANY, &prev_rho_v_x);
  wf.add_vector_form(2, linear_form, linear_form_order, HERMES_ANY, &prev_rho_v_y);
  wf.add_vector_form(3, linear_form, linear_form_order, HERMES_ANY, &prev_e);

  // Surface linear forms - inner edges coming from the DG formulation.
  wf.add_vector_form_surf(0, linear_form_interface_0, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, linear_form_interface_1, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, linear_form_interface_2, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, linear_form_interface_3, linear_form_order, H2D_DG_INNER_EDGE, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));

  // Surface linear forms - inlet / outlet edges.
  wf.add_vector_form_surf(0, bdy_flux_inlet_outlet_comp_0, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, bdy_flux_inlet_outlet_comp_1, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, bdy_flux_inlet_outlet_comp_2, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, bdy_flux_inlet_outlet_comp_3, linear_form_order, BDY_INLET_OUTLET, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));

  
  // Surface linear forms - Solid wall edges.
  wf.add_vector_form_surf(0, bdy_flux_solid_wall_comp_0, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(1, bdy_flux_solid_wall_comp_1, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(2, bdy_flux_solid_wall_comp_2, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));
  wf.add_vector_form_surf(3, bdy_flux_solid_wall_comp_3, linear_form_order, BDY_SOLID_WALL, 
                          Hermes::vector<MeshFunction*>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e));


  // Initialize the FE problem.
  bool is_linear = true;
  
  DiscreteProblem dp(&wf, Hermes::vector<Space*>(&space_rho, &space_rho_v_x, &space_rho_v_y, &space_e), is_linear);
  
  // If the FE problem is in fact a FV problem.
  if(P_INIT.order_h == 0 && P_INIT.order_v == 0)
    dp.set_fvm();

  // Iteration number.
  int iteration = 0;
  
  // Set up the solver, matrix, and rhs according to the solver selection.
  SparseMatrix* matrix = create_matrix(matrix_solver);
  Vector* rhs = create_vector(matrix_solver);
  Solver* solver = create_linear_solver(matrix_solver, matrix, rhs);

  // For testing purposes.
  double l2_norms[5][4];
  for(unsigned int i = 0; i < 5; i++)
    for(unsigned int j = 0; j < 4; j++)
      l2_norms[i][j] = 0.0;
  double point_values[5][3];
  for(unsigned int i = 0; i < 5; i++)
    for(unsigned int j = 0; j < 3; j++)
      point_values[i][j] = 0.0;
  // Calculate the special point where we will evaluate the solution.
  double x = 0.75;
  double y = sqrt((double)(1.-x*x)) + 0.001;

  for(unsigned int time_step = 0; time_step < 5; time_step++)
  {
    iteration++;

    bool rhs_only = (iteration == 1 ? false : true);
    // Assemble stiffness matrix and rhs or just rhs.
    if (rhs_only == false) info("Assembling the stiffness matrix and right-hand side vector.");
    else info("Assembling the right-hand side vector (only).");
    dp.assemble(matrix, rhs, rhs_only);

        
    // Solve the matrix problem.
    info("Solving the matrix problem.");
    if(solver->solve())
      Solution::vector_to_solutions(solver->get_solution(), Hermes::vector<Space *>(&space_rho, &space_rho_v_x, 
      &space_rho_v_y, &space_e), Hermes::vector<Solution *>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e));
    else
    error ("Matrix solver failed.\n");

    // Approximate the time derivative of the solution.
    if(CALC_TIME_DER) {
      Adapt *adapt_for_time_der_calc = new Adapt(Hermes::vector<Space *>(&space_rho, &space_rho_v_x, &space_rho_v_y, &space_e));
      bool solutions_for_adapt = false;
      double difference = iteration == 1 ? 0 : 
        adapt_for_time_der_calc->calc_err_est(Hermes::vector<Solution *>(&prev_rho, &prev_rho_v_x, &prev_rho_v_y, &prev_e), 
					      Hermes::vector<Solution *>(&sln_rho, &sln_rho_v_x, &sln_rho_v_y, &sln_e), 
                                              (Hermes::vector<double>*) NULL, solutions_for_adapt, 
                                              HERMES_TOTAL_ERROR_ABS | HERMES_ELEMENT_ERROR_ABS) / TAU;
      delete adapt_for_time_der_calc;
    }

    // Determine the time step according to the CFL condition.
    // Only mean values on an element of each solution component are taken into account.
    double *solution_vector = solver->get_solution();
    double min_condition = 0;
    Element *e;
    for (int _id = 0, _max = mesh.get_max_element_id(); _id < _max; _id++) \
          if (((e) = mesh.get_element_fast(_id))->used) \
            if ((e)->active) {
              AsmList al;
              space_rho.get_element_assembly_list(e, &al);
              double rho = solution_vector[al.dof[0]];
              space_rho_v_x.get_element_assembly_list(e, &al);
              double v1 = solution_vector[al.dof[0]] / rho;
              space_rho_v_y.get_element_assembly_list(e, &al);
              double v2 = solution_vector[al.dof[0]] / rho;
              space_e.get_element_assembly_list(e, &al);
              double energy = solution_vector[al.dof[0]];
              double condition = e->get_area() / (std::sqrt(v1*v1 + v2*v2) + calc_sound_speed(rho, rho*v1, rho*v2, energy));
              if(condition < min_condition || min_condition == 0.)
                min_condition = condition;
            }
    if(TAU > min_condition)
      TAU = min_condition;
    if(TAU < min_condition * 0.9)
      TAU = min_condition;

    // Storing the testing values.
    for(unsigned int j = 0; j < 4; j++)
      for(unsigned int k = j*space_rho.get_num_dofs(); k < (j+1)*space_rho.get_num_dofs(); k++)
        l2_norms[time_step][j] += solver->get_solution()[k];    

    point_values[time_step][0] = sln_rho_v_x.get_pt_value(0.5, 0.001);
    point_values[time_step][1] = sln_rho_v_x.get_pt_value(x, y);
    point_values[time_step][2] = sln_rho_v_x.get_pt_value(1.5, 0.001);

    // Copy the solutions into the previous time level ones.
    prev_rho.copy(&sln_rho);
    prev_rho_v_x.copy(&sln_rho_v_x);
    prev_rho_v_y.copy(&sln_rho_v_y);
    prev_e.copy(&sln_e);
  }
  bool okay = true;
  switch(P_INIT.order_h* 10 + P_INIT.order_v) {
  case 0:
    if(std::abs(l2_norms[0][0] - 888.0) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[0][1] - 1110) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[0][2]) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[0][3] - 6243.75) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[1][0] - 887.99997637865545) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[1][1] - 1109.9997956458228) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[1][2] - 3.1927018090871903e-008) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[1][3] - 6243.7496921971369) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[2][0] - 887.99993429457072) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[2][1] - 1109.9994322038613) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[2][2] + 5.3556469633245445e-008) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[2][3] - 6243.7491437826511) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[3][0] - 887.99987376550200) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[3][1] - 1109.9989102977672) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[3][2] + 3.6958140470412712e-007) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[3][3] - 6243.7483549661320) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[4][0] - 887.99979481320088) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[4][1] - 1109.9982305630808) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[4][2] + 1.0303296924184822e-006) > 1E-8)
      okay = false;
    if(std::abs(l2_norms[4][3] - 6243.7473260085462) > 1E-8)
      okay = false;

    // points
    if(std::abs(point_values[0][0] - 1.25) > 1E-8)
      okay = false;
    if(std::abs(point_values[0][1] - 1.25) > 1E-8)
      okay = false;
    if(std::abs(point_values[0][2] - 1.2459744738974898) > 1E-8)
      okay = false;
    if(std::abs(point_values[1][0] - 1.2499951035194972) > 1E-8)
      okay = false;
    if(std::abs(point_values[1][1] - 1.25) > 1E-8)
      okay = false;
    if(std::abs(point_values[1][2] - 1.2428402692519325) > 1E-8)
      okay = false;
    if(std::abs(point_values[2][0] - 1.2499864002215795) > 1E-8)
      okay = false;
    if(std::abs(point_values[2][1] - 1.25) > 1E-8)
      okay = false;
    if(std::abs(point_values[2][2] - 1.2397180160697001) > 1E-8)
      okay = false;
    if(std::abs(point_values[3][0] - 1.2499739085927257) > 1E-8)
      okay = false;
    if(std::abs(point_values[3][1] - 1.25) > 1E-8)
      okay = false;
    if(std::abs(point_values[3][2] - 1.2366079101139087) > 1E-8)
      okay = false;
    if(std::abs(point_values[4][0] - 1.2499576472516911) > 1E-8)
      okay = false;
    if(std::abs(point_values[4][1] - 1.25) > 1E-8)
      okay = false;
    if(std::abs(point_values[4][2] - 1.2335101392959738) > 1E-8)
      okay = false;
    break;
  }

  if (okay) {      // ndofs was 908 at the time this test was created
    printf("Success!\n");
    return ERR_SUCCESS;
  }
  else {
    printf("Failure!\n");
    return ERR_FAILURE;
  } 
}