// MFEM Example 4 - Parallel Version // // Compile with: make ex4p // // Sample runs: mpirun -np 4 ex4p -m ../data/square-disc.mesh // mpirun -np 4 ex4p -m ../data/star.mesh // mpirun -np 4 ex4p -m ../data/beam-tet.mesh // mpirun -np 4 ex4p -m ../data/beam-hex.mesh // mpirun -np 4 ex4p -m ../data/beam-hex.mesh -o 2 -pa // mpirun -np 4 ex4p -m ../data/escher.mesh -o 2 -sc // mpirun -np 4 ex4p -m ../data/fichera.mesh -o 2 -hb // mpirun -np 4 ex4p -m ../data/fichera-q2.vtk // mpirun -np 4 ex4p -m ../data/fichera-q3.mesh -o 2 -sc // mpirun -np 4 ex4p -m ../data/square-disc-nurbs.mesh -o 3 // mpirun -np 4 ex4p -m ../data/beam-hex-nurbs.mesh -o 3 // mpirun -np 4 ex4p -m ../data/periodic-square.mesh -no-bc // mpirun -np 4 ex4p -m ../data/periodic-cube.mesh -no-bc // mpirun -np 4 ex4p -m ../data/amr-quad.mesh // mpirun -np 3 ex4p -m ../data/amr-quad.mesh -o 2 -hb // mpirun -np 4 ex4p -m ../data/amr-hex.mesh -o 2 -sc // mpirun -np 4 ex4p -m ../data/amr-hex.mesh -o 2 -hb // mpirun -np 4 ex4p -m ../data/ref-prism.mesh -o 1 // mpirun -np 4 ex4p -m ../data/octahedron.mesh -o 1 // mpirun -np 4 ex4p -m ../data/star-surf.mesh -o 3 -hb // // Device sample runs: // mpirun -np 4 ex4p -m ../data/star.mesh -pa -d cuda // mpirun -np 4 ex4p -m ../data/star.mesh -pa -d raja-cuda // mpirun -np 4 ex4p -m ../data/star.mesh -pa -d raja-omp // mpirun -np 4 ex4p -m ../data/beam-hex.mesh -pa -d cuda // // Description: This example code solves a simple 2D/3D H(div) diffusion // problem corresponding to the second order definite equation // -grad(alpha div F) + beta F = f with boundary condition F dot n // = . Here, we use a given exact solution F // and compute the corresponding r.h.s. f. We discretize with // Raviart-Thomas finite elements. // // The example demonstrates the use of H(div) finite element // spaces with the grad-div and H(div) vector finite element mass // bilinear form, as well as the computation of discretization // error when the exact solution is known. Bilinear form // hybridization and static condensation are also illustrated. // // We recommend viewing examples 1-3 before viewing this example. #include "mfem.hpp" #include #include using namespace std; using namespace mfem; // Exact solution, F, and r.h.s., f. See below for implementation. void F_exact(const Vector &, Vector &); void f_exact(const Vector &, Vector &); double freq = 1.0, kappa; int main(int argc, char *argv[]) { // 1. Initialize MPI and HYPRE. Mpi::Init(argc, argv); int num_procs = Mpi::WorldSize(); int myid = Mpi::WorldRank(); Hypre::Init(); // 2. Parse command-line options. const char *mesh_file = "../data/star.mesh"; int order = 1; bool set_bc = true; bool static_cond = false; bool hybridization = false; bool pa = false; const char *device_config = "cpu"; bool visualization = 1; OptionsParser args(argc, argv); args.AddOption(&mesh_file, "-m", "--mesh", "Mesh file to use."); args.AddOption(&order, "-o", "--order", "Finite element order (polynomial degree)."); args.AddOption(&set_bc, "-bc", "--impose-bc", "-no-bc", "--dont-impose-bc", "Impose or not essential boundary conditions."); args.AddOption(&freq, "-f", "--frequency", "Set the frequency for the exact" " solution."); args.AddOption(&static_cond, "-sc", "--static-condensation", "-no-sc", "--no-static-condensation", "Enable static condensation."); args.AddOption(&hybridization, "-hb", "--hybridization", "-no-hb", "--no-hybridization", "Enable hybridization."); args.AddOption(&pa, "-pa", "--partial-assembly", "-no-pa", "--no-partial-assembly", "Enable Partial Assembly."); args.AddOption(&device_config, "-d", "--device", "Device configuration string, see Device::Configure()."); args.AddOption(&visualization, "-vis", "--visualization", "-no-vis", "--no-visualization", "Enable or disable GLVis visualization."); args.Parse(); if (!args.Good()) { if (myid == 0) { args.PrintUsage(cout); } return 1; } if (myid == 0) { args.PrintOptions(cout); } kappa = freq * M_PI; // 3. Enable hardware devices such as GPUs, and programming models such as // CUDA, OCCA, RAJA and OpenMP based on command line options. Device device(device_config); if (myid == 0) { device.Print(); } // 4. Read the (serial) mesh from the given mesh file on all processors. We // can handle triangular, quadrilateral, tetrahedral, hexahedral, surface // and volume, as well as periodic meshes with the same code. Mesh *mesh = new Mesh(mesh_file, 1, 1); int dim = mesh->Dimension(); int sdim = mesh->SpaceDimension(); // 5. Refine the serial mesh on all processors to increase the resolution. In // this example we do 'ref_levels' of uniform refinement. We choose // 'ref_levels' to be the largest number that gives a final mesh with no // more than 1,000 elements. { int ref_levels = (int)floor(log(1000./mesh->GetNE())/log(2.)/dim); for (int l = 0; l < ref_levels; l++) { mesh->UniformRefinement(); } } // 6. Define a parallel mesh by a partitioning of the serial mesh. Refine // this mesh further in parallel to increase the resolution. Once the // parallel mesh is defined, the serial mesh can be deleted. ParMesh *pmesh = new ParMesh(MPI_COMM_WORLD, *mesh); delete mesh; { int par_ref_levels = 2; for (int l = 0; l < par_ref_levels; l++) { pmesh->UniformRefinement(); } } // 7. Define a parallel finite element space on the parallel mesh. Here we // use the Raviart-Thomas finite elements of the specified order. FiniteElementCollection *fec = new RT_FECollection(order-1, dim); ParFiniteElementSpace *fespace = new ParFiniteElementSpace(pmesh, fec); HYPRE_BigInt size = fespace->GlobalTrueVSize(); if (myid == 0) { cout << "Number of finite element unknowns: " << size << endl; } // 8. Determine the list of true (i.e. parallel conforming) essential // boundary dofs. In this example, the boundary conditions are defined // by marking all the boundary attributes from the mesh as essential // (Dirichlet) and converting them to a list of true dofs. Array ess_tdof_list; if (pmesh->bdr_attributes.Size()) { Array ess_bdr(pmesh->bdr_attributes.Max()); ess_bdr = set_bc ? 1 : 0; fespace->GetEssentialTrueDofs(ess_bdr, ess_tdof_list); } // 9. Set up the parallel linear form b(.) which corresponds to the // right-hand side of the FEM linear system, which in this case is // (f,phi_i) where f is given by the function f_exact and phi_i are the // basis functions in the finite element fespace. VectorFunctionCoefficient f(sdim, f_exact); ParLinearForm *b = new ParLinearForm(fespace); b->AddDomainIntegrator(new VectorFEDomainLFIntegrator(f)); b->Assemble(); // 10. Define the solution vector x as a parallel finite element grid function // corresponding to fespace. Initialize x by projecting the exact // solution. Note that only values from the boundary faces will be used // when eliminating the non-homogeneous boundary condition to modify the // r.h.s. vector b. ParGridFunction x(fespace); VectorFunctionCoefficient F(sdim, F_exact); x.ProjectCoefficient(F); // 11. Set up the parallel bilinear form corresponding to the H(div) // diffusion operator grad alpha div + beta I, by adding the div-div and // the mass domain integrators. Coefficient *alpha = new ConstantCoefficient(1.0); Coefficient *beta = new ConstantCoefficient(1.0); ParBilinearForm *a = new ParBilinearForm(fespace); if (pa) { a->SetAssemblyLevel(AssemblyLevel::PARTIAL); } a->AddDomainIntegrator(new DivDivIntegrator(*alpha)); a->AddDomainIntegrator(new VectorFEMassIntegrator(*beta)); // 12. Assemble the parallel bilinear form and the corresponding linear // system, applying any necessary transformations such as: parallel // assembly, eliminating boundary conditions, applying conforming // constraints for non-conforming AMR, static condensation, // hybridization, etc. FiniteElementCollection *hfec = NULL; ParFiniteElementSpace *hfes = NULL; if (static_cond) { a->EnableStaticCondensation(); } else if (hybridization) { hfec = new DG_Interface_FECollection(order-1, dim); hfes = new ParFiniteElementSpace(pmesh, hfec); a->EnableHybridization(hfes, new NormalTraceJumpIntegrator(), ess_tdof_list); } a->Assemble(); OperatorPtr A; Vector B, X; a->FormLinearSystem(ess_tdof_list, x, *b, A, X, B); if (myid == 0 && !pa) { cout << "Size of linear system: " << A.As()->GetGlobalNumRows() << endl; } // 13. Define and apply a parallel PCG solver for A X = B with the 2D AMS or // the 3D ADS preconditioners from hypre. If using hybridization, the // system is preconditioned with hypre's BoomerAMG. In the partial // assembly case, use Jacobi preconditioning. Solver *prec = NULL; CGSolver *pcg = new CGSolver(MPI_COMM_WORLD); pcg->SetOperator(*A); pcg->SetRelTol(1e-12); pcg->SetMaxIter(2000); pcg->SetPrintLevel(1); if (hybridization) { prec = new HypreBoomerAMG(*A.As()); } else if (pa) { prec = new OperatorJacobiSmoother(*a, ess_tdof_list); } else { ParFiniteElementSpace *prec_fespace = (a->StaticCondensationIsEnabled() ? a->SCParFESpace() : fespace); if (dim == 2) { prec = new HypreAMS(*A.As(), prec_fespace); } else { prec = new HypreADS(*A.As(), prec_fespace); } } pcg->SetPreconditioner(*prec); pcg->Mult(B, X); // 14. Recover the parallel grid function corresponding to X. This is the // local finite element solution on each processor. a->RecoverFEMSolution(X, *b, x); // 15. Compute and print the L^2 norm of the error. { double error = x.ComputeL2Error(F); if (myid == 0) { cout << "\n|| F_h - F ||_{L^2} = " << error << '\n' << endl; } } // 16. Save the refined mesh and the solution in parallel. This output can // be viewed later using GLVis: "glvis -np -m mesh -g sol". { ostringstream mesh_name, sol_name; mesh_name << "mesh." << setfill('0') << setw(6) << myid; sol_name << "sol." << setfill('0') << setw(6) << myid; ofstream mesh_ofs(mesh_name.str().c_str()); mesh_ofs.precision(8); pmesh->Print(mesh_ofs); ofstream sol_ofs(sol_name.str().c_str()); sol_ofs.precision(8); x.Save(sol_ofs); } // 17. Send the solution by socket to a GLVis server. if (visualization) { char vishost[] = "localhost"; int visport = 19916; socketstream sol_sock(vishost, visport); sol_sock << "parallel " << num_procs << " " << myid << "\n"; sol_sock.precision(8); sol_sock << "solution\n" << *pmesh << x << flush; } // 18. Free the used memory. delete pcg; delete prec; delete hfes; delete hfec; delete a; delete alpha; delete beta; delete b; delete fespace; delete fec; delete pmesh; return 0; } // The exact solution (for non-surface meshes) void F_exact(const Vector &p, Vector &F) { int dim = p.Size(); double x = p(0); double y = p(1); // double z = (dim == 3) ? p(2) : 0.0; // Uncomment if F is changed to depend on z F(0) = cos(kappa*x)*sin(kappa*y); F(1) = cos(kappa*y)*sin(kappa*x); if (dim == 3) { F(2) = 0.0; } } // The right hand side void f_exact(const Vector &p, Vector &f) { int dim = p.Size(); double x = p(0); double y = p(1); // double z = (dim == 3) ? p(2) : 0.0; // Uncomment if f is changed to depend on z double temp = 1 + 2*kappa*kappa; f(0) = temp*cos(kappa*x)*sin(kappa*y); f(1) = temp*cos(kappa*y)*sin(kappa*x); if (dim == 3) { f(2) = 0; } }