Esempio n. 1
0
void Config::set(PMap &a, const PMap &b, bool merge) {
	if(!merge) {
		a.clear();
		a = b;
		return;
	}
	for(PMap::const_iterator i = b.begin(); i != b.end(); ++i) {
		a.insert(*i);
	}
}
Esempio n. 2
0
bool Config::loadSetting(const std::string &line, const std::string &name, PMap &var) const {
	size_t i = isSetting(line, name, "=");
	if(i != std::string::npos) {
		size_t j = line.find(':', i);
		if(j == std::string::npos) { return false; }
		var.clear();
		var.insert(PMap::value_type(
			trim(line.substr(i, j - i)),
			trim(line.substr(j + 1))
		));
		return true;
	}
	i = isSetting(line, name, "+=");
	if(i != std::string::npos) {
		size_t j = line.find(':', i);
		if(j == std::string::npos) { return false; }
		var.insert(PMap::value_type(
			trim(line.substr(i, j - i)),
			trim(line.substr(j + 1))
		));
		return true;
	}
	i = isSetting(line, name, "-=");
	if(i != std::string::npos) {
		size_t j = line.find(':', i);
		if(j == std::string::npos) { return false; }
		PMap::iterator a = var.find(PMap::value_type(
			trim(line.substr(i, j - i)),
			trim(line.substr(j + 1))
		));
		if(a != var.end()) {
			var.erase(a);
		}
		return true;
	}
	return false;
}
Esempio n. 3
0
void writeVtkData(const UnstructuredGrid& grid,
                  const DataMap& data,
                  std::ostream& os)
{
    if (grid.dimensions != 3) {
        OPM_THROW(std::runtime_error, "Vtk output for 3d grids only");
    }
    os.precision(12);
    os << "<?xml version=\"1.0\"?>\n";
    PMap pm;
    pm["type"] = "UnstructuredGrid";
    Tag vtkfiletag("VTKFile", pm, os);
    Tag ugtag("UnstructuredGrid", os);
    int num_pts = grid.number_of_nodes;
    int num_cells = grid.number_of_cells;
    pm.clear();
    pm["NumberOfPoints"] = boost::lexical_cast<std::string>(num_pts);
    pm["NumberOfCells"] = boost::lexical_cast<std::string>(num_cells);
    Tag piecetag("Piece", pm, os);
    {
        Tag pointstag("Points", os);
        pm.clear();
        pm["type"] = "Float64";
        pm["Name"] = "Coordinates";
        pm["NumberOfComponents"] = "3";
        pm["format"] = "ascii";
        Tag datag("DataArray", pm, os);
        for (int i = 0; i < num_pts; ++i) {
            Tag::indent(os);
            os << grid.node_coordinates[3*i + 0] << ' '
               << grid.node_coordinates[3*i + 1] << ' '
               << grid.node_coordinates[3*i + 2] << '\n';
        }
    }
    {
        Tag cellstag("Cells", os);
        pm.clear();
        pm["type"] = "Int32";
        pm["NumberOfComponents"] = "1";
        pm["format"] = "ascii";
        std::vector<int> cell_numpts;
        cell_numpts.reserve(num_cells);
        {
            pm["Name"] = "connectivity";
            Tag t("DataArray", pm, os);
            int hf = 0;
            for (int c = 0; c < num_cells; ++c) {
                std::set<int> cell_pts;
                for (; hf < grid.cell_facepos[c+1]; ++hf) {
                    int f = grid.cell_faces[hf];
                    const int* fnbeg = grid.face_nodes + grid.face_nodepos[f];
                    const int* fnend = grid.face_nodes + grid.face_nodepos[f+1];
                    cell_pts.insert(fnbeg, fnend);
                }
                cell_numpts.push_back(cell_pts.size());
                Tag::indent(os);
                std::copy(cell_pts.begin(), cell_pts.end(),
                          std::ostream_iterator<int>(os, " "));
                os << '\n';
            }
        }
        {
            pm["Name"] = "offsets";
            Tag t("DataArray", pm, os);
            int offset = 0;
            const int num_per_line = 10;
            for (int c = 0; c < num_cells; ++c) {
                if (c % num_per_line == 0) {
                    Tag::indent(os);
                }
                offset += cell_numpts[c];
                os << offset << ' ';
                if (c % num_per_line == num_per_line - 1
                        || c == num_cells - 1) {
                    os << '\n';
                }
            }
        }
        std::vector<int> cell_foffsets;
        cell_foffsets.reserve(num_cells);
        {
            pm["Name"] = "faces";
            Tag t("DataArray", pm, os);
            const int* fp = grid.cell_facepos;
            int offset = 0;
            for (int c = 0; c < num_cells; ++c) {
                Tag::indent(os);
                os << fp[c+1] - fp[c] << '\n';
                ++offset;
                for (int hf = fp[c]; hf < fp[c+1]; ++hf) {
                    int f = grid.cell_faces[hf];
                    const int* np = grid.face_nodepos;
                    int f_num_pts = np[f+1] - np[f];
                    Tag::indent(os);
                    os << f_num_pts << ' ';
                    ++offset;
                    std::copy(grid.face_nodes + np[f],
                              grid.face_nodes + np[f+1],
                              std::ostream_iterator<int>(os, " "));
                    os << '\n';
                    offset += f_num_pts;
                }
                cell_foffsets.push_back(offset);
            }
        }
        {
            pm["Name"] = "faceoffsets";
            Tag t("DataArray", pm, os);
            const int num_per_line = 10;
            for (int c = 0; c < num_cells; ++c) {
                if (c % num_per_line == 0) {
                    Tag::indent(os);
                }
                os << cell_foffsets[c] << ' ';
                if (c % num_per_line == num_per_line - 1
                        || c == num_cells - 1) {
                    os << '\n';
                }
            }
        }
        {
            pm["type"] = "UInt8";
            pm["Name"] = "types";
            Tag t("DataArray", pm, os);
            const int num_per_line = 10;
            for (int c = 0; c < num_cells; ++c) {
                if (c % num_per_line == 0) {
                    Tag::indent(os);
                }
                os << "42 ";
                if (c % num_per_line == num_per_line - 1
                        || c == num_cells - 1) {
                    os << '\n';
                }
            }
        }
    }
    {
        pm.clear();
        if (data.find("saturation") != data.end()) {
            pm["Scalars"] = "saturation";
        } else if (data.find("pressure") != data.end()) {
            pm["Scalars"] = "pressure";
        }
        Tag celldatatag("CellData", pm, os);
        pm.clear();
        pm["NumberOfComponents"] = "1";
        pm["format"] = "ascii";
        pm["type"] = "Float64";
        for (DataMap::const_iterator dit = data.begin(); dit != data.end(); ++dit) {
            pm["Name"] = dit->first;
            const std::vector<double>& field = *(dit->second);
            const int num_comps = field.size()/grid.number_of_cells;
            pm["NumberOfComponents"] = boost::lexical_cast<std::string>(num_comps);
            Tag ptag("DataArray", pm, os);
            const int num_per_line = num_comps == 1 ? 5 : num_comps;
            for (int item = 0; item < num_cells*num_comps; ++item) {
                if (item % num_per_line == 0) {
                    Tag::indent(os);
                }
                double value = field[item];
                if (std::fabs(value) < std::numeric_limits<double>::min()) {
                    // Avoiding denormal numbers to work around
                    // bug in Paraview.
                    value = 0.0;
                }
                os << value << ' ';
                if (item % num_per_line == num_per_line - 1
                        || item == num_cells - 1) {
                    os << '\n';
                }
            }
        }
    }
}