/// \brief Get a vector of pressure thresholds from either EclipseState
/// or maxDp (for defaulted values) for all Non-neighbour connections (NNCs).
/// \param[in] nnc The NNCs,
/// \param[in] eclipseState Processed eclipse state, EQLNUM is accessed from it.
/// \param[in] maxDp The maximum gravity corrected pressure differences between
/// the equilibration regions.
/// \return A vector of pressure thresholds, one
/// for each NNC in the grid. A value
/// of zero means no threshold for that
/// particular connection. An empty vector is
/// returned if there is no THPRES
/// feature used in the deck.
std::vector<double> thresholdPressuresNNC(EclipseStateConstPtr eclipseState,
const NNC& nnc,
const std::map<std::pair<int, int>, double>& maxDp)
{
const SimulationConfig& simulationConfig = eclipseState->getSimulationConfig();
std::vector<double> thpres_vals;
if (simulationConfig.hasThresholdPressure()) {
std::shared_ptr<const ThresholdPressure> thresholdPressure = simulationConfig.getThresholdPressure();
const auto& eqlnum = eclipseState->get3DProperties().getIntGridProperty("EQLNUM");
const auto& eqlnumData = eqlnum.getData();
// Set values for each NNC
thpres_vals.resize(nnc.numNNC(), 0.0);
for (size_t i = 0 ; i < nnc.numNNC(); ++i) {
const int gc1 = nnc.nncdata()[i].cell1;
const int gc2 = nnc.nncdata()[i].cell2;
const int eq1 = eqlnumData[gc1];
const int eq2 = eqlnumData[gc2];
if (thresholdPressure->hasRegionBarrier(eq1,eq2)) {
if (thresholdPressure->hasThresholdPressure(eq1,eq2)) {
thpres_vals[i] = thresholdPressure->getThresholdPressure(eq1,eq2);
} else {
// set the threshold pressure for NNC of PVT regions where the third item
// has been defaulted to the maximum pressure potential difference between
// these regions
const auto barrierId = std::make_pair(eq1, eq2);
thpres_vals[i] = maxDp.at(barrierId);
}
}
}
}
return thpres_vals;
}
void restoreSOLUTION(const std::string& restart_filename,
int reportstep,
bool unified,
EclipseStateConstPtr eclipseState,
int numcells,
const PhaseUsage& phaseUsage,
SimulatorState& simulator_state)
{
const char* filename = restart_filename.c_str();
ecl_file_type* file_type = ecl_file_open(filename, 0);
if (file_type) {
bool block_selected = unified ? ecl_file_select_rstblock_report_step(file_type , reportstep) : true;
if (block_selected) {
restorePressureData(file_type, eclipseState, numcells, simulator_state);
restoreTemperatureData(file_type, eclipseState, numcells, simulator_state);
restoreSaturation(file_type, phaseUsage, numcells, simulator_state);
BlackoilState* blackoilState = dynamic_cast<BlackoilState*>(&simulator_state);
if (blackoilState) {
SimulationConfigConstPtr sim_config = eclipseState->getSimulationConfig();
restoreRSandRV(file_type, sim_config, numcells, blackoilState);
}
} else {
std::string error_str = "Restart file " + restart_filename + " does not contain data for report step " + std::to_string(reportstep) + "!\n";
throw std::runtime_error(error_str);
}
ecl_file_close(file_type);
} else {
std::string error_str = "Restart file " + restart_filename + " not found!\n";
throw std::runtime_error(error_str);
}
}
std::vector<double> thresholdPressures(const DeckConstPtr& /* deck */,
EclipseStateConstPtr eclipseState,
const Grid& grid,
const std::map<std::pair<int, int>, double>& maxDp)
{
const SimulationConfig& simulationConfig = eclipseState->getSimulationConfig();
std::vector<double> thpres_vals;
if (simulationConfig.hasThresholdPressure()) {
std::shared_ptr<const ThresholdPressure> thresholdPressure = simulationConfig.getThresholdPressure();
const auto& eqlnum = eclipseState->get3DProperties().getIntGridProperty("EQLNUM");
const auto& eqlnumData = eqlnum.getData();
// Set threshold pressure values for each cell face.
const int num_faces = UgGridHelpers::numFaces(grid);
const auto& fc = UgGridHelpers::faceCells(grid);
const int* gc = UgGridHelpers::globalCell(grid);
thpres_vals.resize(num_faces, 0.0);
for (int face = 0; face < num_faces; ++face) {
const int c1 = fc(face, 0);
const int c2 = fc(face, 1);
if (c1 < 0 || c2 < 0) {
// Boundary face, skip it.
continue;
}
const int gc1 = (gc == 0) ? c1 : gc[c1];
const int gc2 = (gc == 0) ? c2 : gc[c2];
const int eq1 = eqlnumData[gc1];
const int eq2 = eqlnumData[gc2];
if (thresholdPressure->hasRegionBarrier(eq1,eq2)) {
if (thresholdPressure->hasThresholdPressure(eq1,eq2)) {
thpres_vals[face] = thresholdPressure->getThresholdPressure(eq1,eq2);
}
else {
// set the threshold pressure for faces of PVT regions where the third item
// has been defaulted to the maximum pressure potential difference between
// these regions
const auto barrierId = std::make_pair(std::min(eq1, eq2), std::max(eq1, eq2));
if (maxDp.count(barrierId) > 0)
thpres_vals[face] = maxDp.at(barrierId);
else
thpres_vals[face] = 0.0;
}
}
}
}
return thpres_vals;
}
