// -*- mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- // vi: set et ts=4 sw=4 sts=4: /* This file is part of the Open Porous Media project (OPM). OPM is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 2 of the License, or (at your option) any later version. OPM is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with OPM. If not, see . Consult the COPYING file in the top-level source directory of this module for the precise wording of the license and the list of copyright holders. */ #ifndef EWOMS_ECL_GENERIC_THRESHOLD_PRESSURE_IMPL_HH #define EWOMS_ECL_GENERIC_THRESHOLD_PRESSURE_IMPL_HH #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace Opm { template EclGenericThresholdPressure:: EclGenericThresholdPressure(const CartesianIndexMapper& cartMapper, const GridView& gridView, const ElementMapper& elementMapper, const EclipseState& eclState) : cartMapper_(cartMapper) , gridView_(gridView) , elementMapper_(elementMapper) , lookUpData_(gridView) , lookUpCartesianData_(gridView, cartMapper_) , eclState_(eclState) { } template Scalar EclGenericThresholdPressure:: thresholdPressure(int elem1Idx, int elem2Idx) const { if (!enableThresholdPressure_) return 0.0; // threshold pressure accross faults if (!thpresftValues_.empty()) { int fault1Idx = lookUpCartesianData_(elem1Idx, cartElemFaultIdx_); int fault2Idx = lookUpCartesianData_(elem2Idx, cartElemFaultIdx_); if (fault1Idx != -1 && fault1Idx == fault2Idx) // inside a fault there's no threshold pressure, even accross EQUIL // regions. return 0.0; if (fault1Idx != fault2Idx) { // TODO: which value if a cell is part of multiple faults? we take // the maximum here. Scalar val1 = (fault1Idx >= 0) ? thpresftValues_[fault1Idx] : 0.0; Scalar val2 = (fault2Idx >= 0) ? thpresftValues_[fault2Idx] : 0.0; return std::max(val1, val2); } } // threshold pressure accross EQUIL regions auto equilRegion1Idx = elemEquilRegion_[elem1Idx]; auto equilRegion2Idx = elemEquilRegion_[elem2Idx]; if (equilRegion1Idx == equilRegion2Idx) return 0.0; return thpres_[equilRegion1Idx*numEquilRegions_ + equilRegion2Idx]; } template void EclGenericThresholdPressure:: finishInit() { const auto& simConfig = eclState_.getSimulationConfig(); enableThresholdPressure_ = simConfig.useThresholdPressure(); if (!enableThresholdPressure_) return; numEquilRegions_ = eclState_.getTableManager().getEqldims().getNumEquilRegions(); const decltype(numEquilRegions_) maxRegions = std::numeric_limits>::max(); if (numEquilRegions_ > maxRegions) { // make sure that the index of an equilibration region can be stored // in the vector OPM_THROW(std::invalid_argument, (fmt::format("The maximum number of supported " "equilibration regions by OPM flow is {}, but " "{} are used!", maxRegions, numEquilRegions_))); } if (numEquilRegions_ > 2048) { // warn about performance OpmLog::warning(fmt::format("Number of equilibration regions is {}, which is " "rather large. Note, that this might " "have a negative impact on performance " "and memory consumption.", numEquilRegions_)); } // internalize the data specified using the EQLNUM keyword elemEquilRegion_ = lookUpData_.template assignFieldPropsIntOnLeaf(eclState_.fieldProps(), "EQLNUM", true); /* If this is a restart run the ThresholdPressure object will be active, but it will *not* be properly initialized with numerical values. The values must instead come from the THPRES vector in the restart file. */ if (simConfig.getThresholdPressure().restart()) return; // allocate the array which specifies the threshold pressures thpres_.resize(numEquilRegions_*numEquilRegions_, 0.0); thpresDefault_.resize(numEquilRegions_*numEquilRegions_, 0.0); } template void EclGenericThresholdPressure:: applyExplicitThresholdPressures_() { const SimulationConfig& simConfig = eclState_.getSimulationConfig(); const auto& thpres = simConfig.getThresholdPressure(); // set the threshold pressures for all EQUIL region boundaries which have a // intersection in the grid for (const auto& elem : elements(gridView_, Dune::Partitions::interior)) { for (const auto& intersection : intersections(gridView_, elem)) { if (intersection.boundary()) continue; // ignore boundary intersections for now (TODO?) else if (!intersection.neighbor()) //processor boundary but not domain boundary continue; const auto& inside = intersection.inside(); const auto& outside = intersection.outside(); auto equilRegionInside = elemEquilRegion_[elementMapper_.index(inside)]; auto equilRegionOutside = elemEquilRegion_[elementMapper_.index(outside)]; if (thpres.hasRegionBarrier(equilRegionInside + 1, equilRegionOutside + 1)) { Scalar pth = 0.0; if (thpres.hasThresholdPressure(equilRegionInside + 1, equilRegionOutside + 1)) { // threshold pressure explicitly specified pth = thpres.getThresholdPressure(equilRegionInside + 1, equilRegionOutside + 1); } else { // take the threshold pressure from the initial condition unsigned offset = equilRegionInside*numEquilRegions_ + equilRegionOutside; pth = thpresDefault_[offset]; } unsigned offset1 = equilRegionInside*numEquilRegions_ + equilRegionOutside; unsigned offset2 = equilRegionOutside*numEquilRegions_ + equilRegionInside; thpres_[offset1] = pth; thpres_[offset2] = pth; } } } // apply threshold pressures across faults if (thpres.ftSize() > 0) configureThpresft_(); } template void EclGenericThresholdPressure:: configureThpresft_() { // retrieve the faults collection. const FaultCollection& faults = eclState_.getFaults(); const SimulationConfig& simConfig = eclState_.getSimulationConfig(); const auto& thpres = simConfig.getThresholdPressure(); // extract the multipliers int numFaults = faults.size(); int numCartesianElem = eclState_.getInputGrid().getCartesianSize(); thpresftValues_.resize(numFaults, -1.0); cartElemFaultIdx_.resize(numCartesianElem, -1); for (std::size_t faultIdx = 0; faultIdx < faults.size(); faultIdx++) { auto& fault = faults.getFault(faultIdx); thpresftValues_[faultIdx] = thpres.getThresholdPressureFault(faultIdx); for (const FaultFace& face : fault) // "face" is a misnomer because the object describes a set of cell // indices, but we go with the conventions of the parser here... for (std::size_t cartElemIdx : face) cartElemFaultIdx_[cartElemIdx] = faultIdx; } } template std::vector EclGenericThresholdPressure:: getRestartVector() const { if (!enableThresholdPressure_) return {}; std::vector result(numEquilRegions_ * numEquilRegions_, 0.0); const auto& simConfig = eclState_.getSimulationConfig(); const auto& thpres = simConfig.getThresholdPressure(); std::size_t idx = 0; for (unsigned j = 1; j <= numEquilRegions_; ++j) { for (unsigned i = 1; i <= numEquilRegions_; ++i, ++idx) { if (thpres.hasRegionBarrier(i, j)) { if (thpres.hasThresholdPressure(i, j)) { result[idx] = thpres.getThresholdPressure(i, j); } else { result[idx] = this->thpresDefault_[idx]; } } } } return result; } template void EclGenericThresholdPressure:: logPressures() { if (!enableThresholdPressure_) return; auto lineFormat = [this](unsigned i, unsigned j, double val) { const auto& units = eclState_.getUnits(); return fmt::format("{:4}{:>6}{:23}{:>6}{:24}{:>11.07}{:7}{}\n", " ", i, " ", j, " ", units.from_si(UnitSystem::measure::pressure, val), " ", units.name(UnitSystem::measure::pressure)); }; auto lineFormatS = [](auto s1, auto s2, auto s3) { return fmt::format("{:4}{:^16}{:13}{:^9}{:21}{:^18}\n", " ", s1, " ", s2, " ", s3); }; std::string str = "\nLIST OF ALL NON-ZERO THRESHOLD PRESSURES\n" "----------------------------------------\n" "\n"; str += lineFormatS("FLOW FROM REGION", "TO REGION", "THRESHOLD PRESSURE"); str += lineFormatS(std::string(16, '-'), std::string(9, '-'), std::string(18, '-')); const auto& simConfig = eclState_.getSimulationConfig(); const auto& thpres = simConfig.getThresholdPressure(); for (unsigned i = 1; i <= numEquilRegions_; ++i) { for (unsigned j = (thpres.irreversible() ? 1 : i); j <= numEquilRegions_; ++j) { if (thpres.hasRegionBarrier(i, j)) { if (thpres.hasThresholdPressure(i, j)) { str += lineFormat(i, j, thpres.getThresholdPressure(j, i)); } else { std::size_t idx = (j - 1) * numEquilRegions_ + (i - 1); str += lineFormat(i, j, this->thpresDefault_[idx]); } } } } str += lineFormatS(std::string(16, '-'), std::string(9, '-'), std::string(18, '-')); OpmLog::note(str); } } // namespace Opm #endif