Example #1
0
    inline void setupGridAndProps(const Opm::parameter::ParameterGroup& param,
				  CpGrid& grid,
				  ResProp<3>& res_prop)
    {
	// Initialize grid and reservoir properties.
	// Parts copied from CpGrid::init().
	std::string fileformat = param.getDefault<std::string>("fileformat", "cartesian");
	if (fileformat == "sintef_legacy") {
	    std::string grid_prefix = param.get<std::string>("grid_prefix");
	    grid.readSintefLegacyFormat(grid_prefix);
	    MESSAGE("Warning: We do not yet read legacy reservoir properties. Using defaults.");
	    res_prop.init(grid.size(0));
	} else if (fileformat == "eclipse") {
	    Opm::EclipseGridParser parser(param.get<std::string>("filename"));
	    double z_tolerance = param.getDefault<double>("z_tolerance", 0.0);
	    bool periodic_extension = param.getDefault<bool>("periodic_extension", false);
	    bool turn_normals = param.getDefault<bool>("turn_normals", false);
	    grid.processEclipseFormat(parser, z_tolerance, periodic_extension, turn_normals);
            double perm_threshold_md = param.getDefault("perm_threshold_md", 0.0);
	    double perm_threshold = Opm::unit::convert::from(perm_threshold_md, Opm::prefix::milli*Opm::unit::darcy);
	    std::string rock_list = param.getDefault<std::string>("rock_list", "no_list");
	    std::string* rl_ptr = (rock_list == "no_list") ? 0 : &rock_list;
            bool use_j = param.getDefault("use_jfunction_scaling", useJ<ResProp<3> >());
            double sigma = 1.0;
            double theta = 0.0;
            if (use_j) {
                sigma = param.getDefault("sigma", sigma);
                theta = param.getDefault("theta", theta);
            }
            if (param.has("viscosity1") || param.has("viscosity2")) {
                double v1 = param.getDefault("viscosity1", 0.001);
                double v2 = param.getDefault("viscosity2", 0.003);
                res_prop.setViscosities(v1, v2);
            }
	    res_prop.init(parser, grid.globalCell(), perm_threshold, rl_ptr,
                          use_j, sigma, theta);
	} else if (fileformat == "cartesian") {
	    array<int, 3> dims = {{ param.getDefault<int>("nx", 1),
				    param.getDefault<int>("ny", 1),
				    param.getDefault<int>("nz", 1) }};
	    array<double, 3> cellsz = {{ param.getDefault<double>("dx", 1.0),
					 param.getDefault<double>("dy", 1.0),
					 param.getDefault<double>("dz", 1.0) }};
	    grid.createCartesian(dims, cellsz);
	    double default_poro = param.getDefault("default_poro", 0.2);
	    double default_perm_md = param.getDefault("default_perm_md", 100.0);
	    double default_perm = Opm::unit::convert::from(default_perm_md, Opm::prefix::milli*Opm::unit::darcy);
	    MESSAGE("Warning: For generated cartesian grids, we use uniform reservoir properties.");
	    res_prop.init(grid.size(0), default_poro, default_perm);
	} else {
	    THROW("Unknown file format string: " << fileformat);
	}
	if (param.getDefault("use_unique_boundary_ids", false)) {
	    grid.setUniqueBoundaryIds(true);
	}
    }
CombinedGridWellGraph::CombinedGridWellGraph(const CpGrid& grid,
                                             const Opm::EclipseStateConstPtr eclipseState,
                                             const double* transmissibilities,
                                             bool pretendEmptyGrid)
    : grid_(grid), eclipseState_(eclipseState), transmissibilities_(transmissibilities)
{
    if ( pretendEmptyGrid )
    {
        // wellsGraph not needed
        return;
    }
    wellsGraph_.resize(grid.numCells());
    const auto& cpgdim = grid.logicalCartesianSize();
    // create compressed lookup from cartesian.
    std::vector<Opm::WellConstPtr> wells  = eclipseState->getSchedule()->getWells();
    std::vector<int> cartesian_to_compressed(cpgdim[0]*cpgdim[1]*cpgdim[2], -1);
    int last_time_step = eclipseState->getSchedule()->getTimeMap()->size()-1;
    for( int i=0; i < grid.numCells(); ++i )
    {
        cartesian_to_compressed[grid.globalCell()[i]] = i;
    }
    // We assume that we know all the wells.
    for (auto wellIter= wells.begin(); wellIter != wells.end(); ++wellIter) {
        Opm::WellConstPtr well = (*wellIter);
        std::set<int> well_indices;
        Opm::CompletionSetConstPtr completionSet = well->getCompletions(last_time_step);
        for (size_t c=0; c<completionSet->size(); c++) {
            Opm::CompletionConstPtr completion = completionSet->get(c);
            int i = completion->getI();
            int j = completion->getJ();
            int k = completion->getK();
            int cart_grid_idx = i + cpgdim[0]*(j + cpgdim[1]*k);
            int compressed_idx = cartesian_to_compressed[cart_grid_idx];
            if ( compressed_idx >= 0 ) // Ignore completions in inactive cells.
            {
                well_indices.insert(compressed_idx);
            }
        }
        addCompletionSetToGraph(well_indices);
    }
}
Example #3
0
    inline void setupGridAndPropsEclipse(const Opm::EclipseGridParser& parser,
                                         double z_tolerance,
                                         bool periodic_extension,
                                         bool turn_normals,
                                         bool clip_z,
                                         bool unique_bids,
                                         double perm_threshold,
                                         const std::string& rock_list,
                                         bool use_jfunction_scaling,
                                         double sigma,
                                         double theta,
                                         CpGrid& grid,
                                         ResProp<3>& res_prop)
    {
        grid.processEclipseFormat(parser, z_tolerance, periodic_extension, turn_normals, clip_z);
        const std::string* rl_ptr = (rock_list == "no_list") ? 0 : &rock_list;
        res_prop.init(parser, grid.globalCell(), perm_threshold, rl_ptr, use_jfunction_scaling, sigma, theta);
	if (unique_bids) {
	    grid.setUniqueBoundaryIds(true);
	}
    }
CombinedGridWellGraph::CombinedGridWellGraph(const CpGrid& grid,
                                             const Opm::EclipseState* eclipseState,
                                             const double* transmissibilities,
                                             bool pretendEmptyGrid)
    : grid_(grid), transmissibilities_(transmissibilities)
{
    if ( pretendEmptyGrid )
    {
        // wellsGraph not needed
        return;
    }
    wellsGraph_.resize(grid.numCells());
    const auto& cpgdim = grid.logicalCartesianSize();
    // create compressed lookup from cartesian.
    std::vector<int> cartesian_to_compressed(cpgdim[0]*cpgdim[1]*cpgdim[2], -1);

    for( int i=0; i < grid.numCells(); ++i )
    {
        cartesian_to_compressed[grid.globalCell()[i]] = i;
    }
    well_indices_.init(*eclipseState, cpgdim, cartesian_to_compressed);
    std::vector<int>().swap(cartesian_to_compressed); // free memory.
    addCompletionSetToGraph();
}
Example #5
0
int main(int argc, char** argv)
try
{
    Dune::MPIHelper::instance(argc,argv); // Dummy if no MPI.

    CpGrid grid;

    if (argc != 2) {
        std::cout << "Usage: grdecl2vtu filename.grdecl" << std::endl;
        exit(1);
    }

    const char* eclipsefilename = argv[1];
#if HAVE_OPM_PARSER
    Opm::ParseContext parseContext;
    Opm::Parser parser;
    auto deck = parser.parseFile(eclipsefilename, parseContext);

    // Get logical cartesian grid dimensions.
    std::array<size_t, 3> dims;
    if (deck.hasKeyword("SPECGRID")) {
        const auto& specgridRecord = deck.getKeyword("SPECGRID").getRecord(0);
        dims[0] = specgridRecord.getItem("NX").get< int >(0);
        dims[1] = specgridRecord.getItem("NY").get< int >(0);
        dims[2] = specgridRecord.getItem("NZ").get< int >(0);
    } else if (deck.hasKeyword("DIMENS")) {
        const auto& dimensRecord = deck.getKeyword("DIMENS").getRecord(0);
        dims[0] = dimensRecord.getItem("NX").get< int >(0);
        dims[1] = dimensRecord.getItem("NY").get< int >(0);
        dims[2] = dimensRecord.getItem("NZ").get< int >(0);
    } else {
        OPM_THROW(std::runtime_error, "Found neither SPECGRID nor DIMENS in file. At least one is needed.");
    }

    {
        const int* actnum = deck.hasKeyword("ACTNUM") ? deck.getKeyword("ACTNUM").getIntData().data() : nullptr;
        Opm::EclipseGrid ecl_grid(deck , actnum);
        grid.processEclipseFormat(ecl_grid, false);
    }
#endif

    VTKWriter<CpGrid::LeafGridView> vtkwriter(grid.leafGridView());

#if HAVE_OPM_PARSER
    const std::vector<int>& global_cell = grid.globalCell();

    std::vector<double> poros;
    condWriteDoubleField(poros, "PORO", deck, global_cell, dims, vtkwriter);

    std::vector<double> permxs;
    condWriteDoubleField(permxs, "PERMX", deck, global_cell, dims, vtkwriter);
    std::vector<double> permys;
    condWriteDoubleField(permys, "PERMY", deck, global_cell, dims, vtkwriter);

    std::vector<double> permzs;
    condWriteDoubleField(permzs, "PERMZ", deck, global_cell, dims, vtkwriter);

    std::vector<double> actnums;
    condWriteIntegerField(actnums, "ACTNUM", deck, global_cell, dims, vtkwriter);

    std::vector<double> satnums;
    condWriteIntegerField(satnums, "SATNUM", deck, global_cell, dims, vtkwriter);

    std::vector<double> regnums;
    condWriteIntegerField(regnums, "REGNUM", deck, global_cell, dims, vtkwriter);

    std::vector<double> swats;
    condWriteDoubleField(swats, "SWAT", deck, global_cell, dims, vtkwriter);
#endif // #if HAVE_OPM_PARSER

    std::string fname(eclipsefilename);
    std::string fnamebase = fname.substr(0, fname.find_last_of('.'));
    std::cout << "Writing to filename " << fnamebase << ".vtu" << std::endl;
    vtkwriter.write(fnamebase, VTK::ascii);
}
catch (const std::exception &e) {
    std::cerr << "Program threw an exception: " << e.what() << "\n";
    throw;
}