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ex14.cpp
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ex14.cpp
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// MFEM Example 14
//
// Compile with: make ex14
//
// Sample runs: ex14 -m ../data/inline-quad.mesh -o 0
// ex14 -m ../data/star.mesh -r 4 -o 2
// ex14 -m ../data/star-mixed.mesh -r 4 -o 2
// ex14 -m ../data/star-mixed.mesh -r 2 -o 2 -k 0 -e 1
// ex14 -m ../data/escher.mesh -s 1
// ex14 -m ../data/fichera.mesh -s 1 -k 1
// ex14 -m ../data/fichera-mixed.mesh -s 1 -k 1
// ex14 -m ../data/square-disc-p2.vtk -r 3 -o 2
// ex14 -m ../data/square-disc-p3.mesh -r 2 -o 3
// ex14 -m ../data/square-disc-nurbs.mesh -o 1
// ex14 -m ../data/disc-nurbs.mesh -r 3 -o 2 -s 1 -k 0
// ex14 -m ../data/pipe-nurbs.mesh -o 1
// ex14 -m ../data/inline-segment.mesh -r 5
// ex14 -m ../data/amr-quad.mesh -r 3
// ex14 -m ../data/amr-hex.mesh
// ex14 -m ../data/fichera-amr.mesh
// ex14 -pa -r 1 -o 3
// ex14 -pa -r 1 -o 3 -m ../data/fichera.mesh
//
// Device sample runs:
// ex14 -pa -r 2 -d cuda -o 3
// ex14 -pa -r 2 -d cuda -o 3 -m ../data/fichera.mesh
//
// Description: This example code demonstrates the use of MFEM to define a
// discontinuous Galerkin (DG) finite element discretization of
// the Laplace problem -Delta u = 1 with homogeneous Dirichlet
// boundary conditions. Finite element spaces of any order,
// including zero on regular grids, are supported. The example
// highlights the use of discontinuous spaces and DG-specific face
// integrators.
//
// We recommend viewing examples 1 and 9 before viewing this
// example.
#include "mfem.hpp"
#include <fstream>
#include <iostream>
using namespace std;
using namespace mfem;
int main(int argc, char *argv[])
{
// 1. Parse command-line options.
const char *mesh_file = "../data/star.mesh";
int ref_levels = -1;
int order = 1;
real_t sigma = -1.0;
real_t kappa = -1.0;
real_t eta = 0.0;
bool pa = false;
bool visualization = 1;
const char *device_config = "cpu";
OptionsParser args(argc, argv);
args.AddOption(&mesh_file, "-m", "--mesh",
"Mesh file to use.");
args.AddOption(&ref_levels, "-r", "--refine",
"Number of times to refine the mesh uniformly, -1 for auto.");
args.AddOption(&order, "-o", "--order",
"Finite element order (polynomial degree) >= 0.");
args.AddOption(&sigma, "-s", "--sigma",
"One of the three DG penalty parameters, typically +1/-1."
" See the documentation of class DGDiffusionIntegrator.");
args.AddOption(&kappa, "-k", "--kappa",
"One of the three DG penalty parameters, should be positive."
" Negative values are replaced with (order+1)^2.");
args.AddOption(&eta, "-e", "--eta", "BR2 penalty parameter.");
args.AddOption(&pa, "-pa", "--partial-assembly", "-no-pa",
"--no-partial-assembly", "Enable Partial Assembly.");
args.AddOption(&visualization, "-vis", "--visualization", "-no-vis",
"--no-visualization",
"Enable or disable GLVis visualization.");
args.AddOption(&device_config, "-d", "--device",
"Device configuration string, see Device::Configure().");
args.Parse();
if (!args.Good())
{
args.PrintUsage(cout);
return 1;
}
if (kappa < 0)
{
kappa = (order+1)*(order+1);
}
args.PrintOptions(cout);
// 2. 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);
device.Print();
// 3. Read the mesh from the given mesh file. We can handle triangular,
// quadrilateral, tetrahedral and hexahedral meshes with the same code.
// NURBS meshes are projected to second order meshes.
Mesh mesh(mesh_file);
const int dim = mesh.Dimension();
// 4. Refine the mesh to increase the resolution. In this example we do
// 'ref_levels' of uniform refinement. By default, or if ref_levels < 0,
// we choose it to be the largest number that gives a final mesh with no
// more than 50,000 elements.
{
if (ref_levels < 0)
{
ref_levels = (int)floor(log(50000./mesh.GetNE())/log(2.)/dim);
}
for (int l = 0; l < ref_levels; l++)
{
mesh.UniformRefinement();
}
}
if (mesh.NURBSext)
{
mesh.SetCurvature(max(order, 1));
}
// 5. Define a finite element space on the mesh. Here we use discontinuous
// finite elements of the specified order >= 0.
const auto bt = pa ? BasisType::GaussLobatto : BasisType::GaussLegendre;
DG_FECollection fec(order, dim, bt);
FiniteElementSpace fespace(&mesh, &fec);
cout << "Number of unknowns: " << fespace.GetVSize() << endl;
// 6. Set up the linear form b(.) which corresponds to the right-hand side of
// the FEM linear system.
LinearForm b(&fespace);
ConstantCoefficient one(1.0);
ConstantCoefficient zero(0.0);
b.AddDomainIntegrator(new DomainLFIntegrator(one));
b.AddBdrFaceIntegrator(
new DGDirichletLFIntegrator(zero, one, sigma, kappa));
b.Assemble();
// 7. Define the solution vector x as a finite element grid function
// corresponding to fespace. Initialize x with initial guess of zero.
GridFunction x(&fespace);
x = 0.0;
// 8. Set up the bilinear form a(.,.) on the finite element space
// corresponding to the Laplacian operator -Delta, by adding the Diffusion
// domain integrator and the interior and boundary DG face integrators.
// Note that boundary conditions are imposed weakly in the form, so there
// is no need for dof elimination. After assembly and finalizing we
// extract the corresponding sparse matrix A.
BilinearForm a(&fespace);
a.AddDomainIntegrator(new DiffusionIntegrator(one));
a.AddInteriorFaceIntegrator(new DGDiffusionIntegrator(one, sigma, kappa));
a.AddBdrFaceIntegrator(new DGDiffusionIntegrator(one, sigma, kappa));
if (eta > 0)
{
MFEM_VERIFY(!pa, "BR2 not yet compatible with partial assembly.");
a.AddInteriorFaceIntegrator(new DGDiffusionBR2Integrator(fespace, eta));
a.AddBdrFaceIntegrator(new DGDiffusionBR2Integrator(fespace, eta));
}
if (pa) { a.SetAssemblyLevel(AssemblyLevel::PARTIAL); }
a.Assemble();
a.Finalize();
// 9. Define a simple symmetric Gauss-Seidel preconditioner and use it to
// solve the system Ax=b with PCG in the symmetric case, and GMRES in the
// non-symmetric one. (Note that tolerances are squared: 1e-12 corresponds
// to a relative tolerance of 1e-6).
//
// If MFEM was compiled with SuiteSparse, use UMFPACK to solve the system.
if (pa)
{
MFEM_VERIFY(sigma == -1.0,
"The case of PA with sigma != -1 is not yet supported.");
CG(a, b, x, 1, 500, 1e-12, 0.0);
}
else
{
const SparseMatrix &A = a.SpMat();
#ifndef MFEM_USE_SUITESPARSE
GSSmoother M(A);
if (sigma == -1.0)
{
PCG(A, M, b, x, 1, 500, 1e-12, 0.0);
}
else
{
GMRES(A, M, b, x, 1, 500, 10, 1e-12, 0.0);
}
#else
UMFPackSolver umf_solver;
umf_solver.Control[UMFPACK_ORDERING] = UMFPACK_ORDERING_METIS;
umf_solver.SetOperator(A);
umf_solver.Mult(b, x);
#endif
}
// 10. Save the refined mesh and the solution. This output can be viewed
// later using GLVis: "glvis -m refined.mesh -g sol.gf".
ofstream mesh_ofs("refined.mesh");
mesh_ofs.precision(8);
mesh.Print(mesh_ofs);
ofstream sol_ofs("sol.gf");
sol_ofs.precision(8);
x.Save(sol_ofs);
// 11. Send the solution by socket to a GLVis server.
if (visualization)
{
char vishost[] = "localhost";
int visport = 19916;
socketstream sol_sock(vishost, visport);
sol_sock.precision(8);
sol_sock << "solution\n" << mesh << x << flush;
}
return 0;
}