void assign_permeability(RI& r, int nc, double k)
{
typedef typename RI::SharedPermTensor Tensor;
for (int c = 0; c < nc; ++c) {
Tensor K = r.permeabilityModifiable(c);
for (int i = 0; i < dim; ++i) {
K(i,i) = k;
}
}
}
int main(int argc, char** argv)
{
typedef Dune::GridInterfaceEuler<CpGrid> GI;
typedef GI ::CellIterator CI;
typedef CI ::FaceIterator FI;
typedef Dune::BasicBoundaryConditions<true, false> BCs;
typedef Dune::ReservoirPropertyCapillary<3> RI;
typedef Dune::IncompFlowSolverHybrid<GI, RI, BCs,
Dune::MimeticIPEvaluator> FlowSolver;
Opm::parameter::ParameterGroup param(argc, argv);
CpGrid grid;
grid.init(param);
//grid.setUniqueBoundaryIds(true);
GridInterfaceEuler<CpGrid> g(grid);
typedef Dune::FlowBC BC;
BCs flow_bc(7);
#define BCDIR 4
#if BCDIR == 1
flow_bc.flowCond(1) = BC(BC::Dirichlet, 1.0*Opm::unit::barsa);
flow_bc.flowCond(2) = BC(BC::Dirichlet, 0.0*Opm::unit::barsa);
#elif BCDIR == 2
flow_bc.flowCond(3) = BC(BC::Dirichlet, 1.0*Opm::unit::barsa);
flow_bc.flowCond(4) = BC(BC::Dirichlet, 0.0*Opm::unit::barsa);
#elif BCDIR == 3
flow_bc.flowCond(5) = BC(BC::Dirichlet, 1.0*Opm::unit::barsa);
flow_bc.flowCond(6) = BC(BC::Dirichlet, 0.0*Opm::unit::barsa);
#elif BCDIR == 4
flow_bc.flowCond(5) = BC(BC::Dirichlet, 1.0*Opm::unit::barsa);
#endif
RI r;
r.init(g.numberOfCells());
std::vector<double> permdata;
fill_perm(permdata);
ASSERT (int(permdata.size()) == 3 * 60 * 220 * 85);
Dune::SharedFortranMatrix Perm(60 * 220 * 85, 3, &permdata[0]);
const int imin = param.get<int>("imin");
const int jmin = param.get<int>("jmin");
const int kmin = param.get<int>("kmin");
for (int c = 0; c < g.numberOfCells(); ++c) {
boost::array<int,3> ijk;
grid.getIJK(c, ijk);
ijk[0] += imin; ijk[1] += jmin; ijk[2] += kmin;
const int gc = ijk[0] + 60*(ijk[1] + 220*ijk[2]);
RI::SharedPermTensor K = r.permeabilityModifiable(c);
K(0,0) = 0*0.1*Opm::unit::darcy + 1*Perm(gc,0);
K(1,1) = 0*0.1*Opm::unit::darcy + 1*Perm(gc,1);
K(2,2) = 0*0.1*Opm::unit::darcy + 1*Perm(gc,2);
}
#if 1
CI::Vector gravity;
gravity[0] = gravity[1] = gravity[2] = 0.0;
#if 1
gravity[2] = Opm::unit::gravity;
gravity[2] = 10; //Opm::unit::gravity;
#endif
#endif
FlowSolver solver;
solver.init(g, r, gravity, flow_bc);
#if 1
std::vector<double> src(g.numberOfCells(), 0.0);
std::vector<double> sat(g.numberOfCells(), 0.0);
#if 0
const int nx = param.get<int>("nx");
const int ny = param.get<int>("ny");
const int nz = param.get<int>("nz");
const int
i = 0 + nz*(nx/2 + nx*ny/2 ),
p1 = 0 + nz*(0 + nx*0 ),
p2 = 0 + nz*((nx-1) + nx*0 ),
p3 = 0 + nz*(0 + nx*(ny-1)),
p4 = 0 + nz*((nx-1) + nx*(ny-1));
const double bbl = 0.159 * unit::cubic(unit::meter);
const double irate = 1.0e4 * bbl / unit::day;
for (int z = 0; z < nz; ++z) {
src[i + z] = irate / nz;
src[p1 + z] = -(irate / nz) / 4;
src[p2 + z] = -(irate / nz) / 4;
src[p3 + z] = -(irate / nz) / 4;
src[p4 + z] = -(irate / nz) / 4;
}
#endif
solver.solve(r, sat, flow_bc, src, 5.0e-8, 3);
#endif
#if 1
std::vector<GI::Vector> cell_velocity;
estimateCellVelocity(cell_velocity, g, solver.getSolution());
// Dune's vtk writer wants multi-component data to be flattened.
std::vector<double> cell_velocity_flat(&*cell_velocity.front().begin(),
&*cell_velocity.back().end());
std::vector<double> cell_pressure;
getCellPressure(cell_pressure, g, solver.getSolution());
Dune::VTKWriter<CpGrid::LeafGridView> vtkwriter(grid.leafView());
vtkwriter.addCellData(cell_velocity_flat, "velocity", 3);
vtkwriter.addCellData(cell_pressure, "pressure");
vtkwriter.write("spe10_test_output", Dune::VTKOptions::ascii);
#endif
return 0;
}
