/* Copyright 2012 SINTEF ICT, Applied Mathematics. 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 3 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 . */ #include "config.h" #include #include #include #include #include #include #include #include #include #include #include namespace Opm { typedef SaturationPropsFromDeck::MaterialLawManager::MaterialLaw MaterialLaw; // ----------- Methods of SaturationPropsFromDeck --------- /// Default constructor. SaturationPropsFromDeck::SaturationPropsFromDeck() { } /// Initialize from deck. void SaturationPropsFromDeck::init(const PhaseUsage &phaseUsage, std::shared_ptr materialLawManager) { phaseUsage_ = phaseUsage; materialLawManager_ = materialLawManager; } /// \return P, the number of phases. int SaturationPropsFromDeck::numPhases() const { return phaseUsage_.num_phases; } /// Relative permeability. /// \param[in] n Number of data points. /// \param[in] s Array of nP saturation values. /// \param[in] cells Array of n cell indices to be associated with the s values. /// \param[out] kr Array of nP relperm values, array must be valid before calling. /// \param[out] dkrds If non-null: array of nP^2 relperm derivative values, /// array must be valid before calling. /// The P^2 derivative matrix is /// m_{ij} = \frac{dkr_i}{ds^j}, /// and is output in Fortran order (m_00 m_10 m_20 m01 ...) void SaturationPropsFromDeck::relperm(const int n, const double* s, const int* cells, double* kr, double* dkrds) const { assert(cells != 0); const int np = numPhases(); if (dkrds) { ExplicitArraysSatDerivativesFluidState fluidState(phaseUsage_); fluidState.setSaturationArray(s); typedef ExplicitArraysSatDerivativesFluidState::Evaluation Evaluation; Evaluation relativePerms[BlackoilPhases::MaxNumPhases]; for (int i = 0; i < n; ++i) { fluidState.setIndex(i); const auto& params = materialLawManager_->materialLawParams(cells[i]); MaterialLaw::relativePermeabilities(relativePerms, params, fluidState); // copy the values calculated using opm-material to the target arrays for (int krPhaseIdx = 0; krPhaseIdx < np; ++krPhaseIdx) { kr[np*i + krPhaseIdx] = relativePerms[krPhaseIdx].value; for (int satPhaseIdx = 0; satPhaseIdx < np; ++satPhaseIdx) dkrds[np*np*i + satPhaseIdx*np + krPhaseIdx] = relativePerms[krPhaseIdx].derivatives[satPhaseIdx]; } } } else { ExplicitArraysFluidState fluidState(phaseUsage_); fluidState.setSaturationArray(s); double relativePerms[BlackoilPhases::MaxNumPhases]; for (int i = 0; i < n; ++i) { fluidState.setIndex(i); const auto& params = materialLawManager_->materialLawParams(cells[i]); MaterialLaw::relativePermeabilities(relativePerms, params, fluidState); // copy the values calculated using opm-material to the target arrays for (int krPhaseIdx = 0; krPhaseIdx < np; ++krPhaseIdx) { kr[np*i + krPhaseIdx] = relativePerms[krPhaseIdx]; } } } } /// Capillary pressure. /// \param[in] n Number of data points. /// \param[in] s Array of nP saturation values. /// \param[in] cells Array of n cell indices to be associated with the s values. /// \param[out] pc Array of nP capillary pressure values, array must be valid before calling. /// \param[out] dpcds If non-null: array of nP^2 derivative values, /// array must be valid before calling. /// The P^2 derivative matrix is /// m_{ij} = \frac{dpc_i}{ds^j}, /// and is output in Fortran order (m_00 m_10 m_20 m01 ...) void SaturationPropsFromDeck::capPress(const int n, const double* s, const int* cells, double* pc, double* dpcds) const { assert(cells != 0); const int np = numPhases(); if (dpcds) { ExplicitArraysSatDerivativesFluidState fluidState(phaseUsage_); typedef ExplicitArraysSatDerivativesFluidState::Evaluation Evaluation; fluidState.setSaturationArray(s); Evaluation capillaryPressures[BlackoilPhases::MaxNumPhases]; for (int i = 0; i < n; ++i) { fluidState.setIndex(i); const auto& params = materialLawManager_->materialLawParams(cells[i]); MaterialLaw::capillaryPressures(capillaryPressures, params, fluidState); // copy the values calculated using opm-material to the target arrays for (int pcPhaseIdx = 0; pcPhaseIdx < np; ++pcPhaseIdx) { double sign = (pcPhaseIdx == BlackoilPhases::Aqua)? -1.0 : 1.0; pc[np*i + pcPhaseIdx] = sign*capillaryPressures[pcPhaseIdx].value; for (int satPhaseIdx = 0; satPhaseIdx < np; ++satPhaseIdx) dpcds[np*np*i + satPhaseIdx*np + pcPhaseIdx] = sign*capillaryPressures[pcPhaseIdx].derivatives[satPhaseIdx]; } } } else { ExplicitArraysFluidState fluidState(phaseUsage_); fluidState.setSaturationArray(s); double capillaryPressures[BlackoilPhases::MaxNumPhases]; for (int i = 0; i < n; ++i) { fluidState.setIndex(i); const auto& params = materialLawManager_->materialLawParams(cells[i]); MaterialLaw::capillaryPressures(capillaryPressures, params, fluidState); // copy the values calculated using opm-material to the target arrays for (int pcPhaseIdx = 0; pcPhaseIdx < np; ++pcPhaseIdx) { double sign = (pcPhaseIdx == BlackoilPhases::Aqua)? -1.0 : 1.0; pc[np*i + pcPhaseIdx] = sign*capillaryPressures[pcPhaseIdx]; } } } } /// Obtain the range of allowable saturation values. /// \param[in] n Number of data points. /// \param[in] cells Array of n cell indices. /// \param[out] smin Array of nP minimum s values, array must be valid before calling. /// \param[out] smax Array of nP maximum s values, array must be valid before calling. void SaturationPropsFromDeck::satRange(const int n, const int* cells, double* smin, double* smax) const { int wpos = phaseUsage_.phase_pos[BlackoilPhases::Aqua]; int gpos = phaseUsage_.phase_pos[BlackoilPhases::Vapour]; int opos = phaseUsage_.phase_pos[BlackoilPhases::Liquid]; const int np = numPhases(); for (int i = 0; i < n; ++i) { const auto& scaledDrainageInfo = materialLawManager_->oilWaterScaledEpsInfoDrainage(cells[i]); if (phaseUsage_.phase_used[BlackoilPhases::Aqua]) { smin[np*i + wpos] = scaledDrainageInfo.Swl; smax[np*i + wpos] = scaledDrainageInfo.Swu; } if (phaseUsage_.phase_used[BlackoilPhases::Vapour]) { smin[np*i + gpos] = scaledDrainageInfo.Sgl; smax[np*i + gpos] = scaledDrainageInfo.Sgu; } if (phaseUsage_.phase_used[BlackoilPhases::Liquid]) { smin[np*i + opos] = 1.0; smax[np*i + opos] = 1.0; if (phaseUsage_.phase_used[BlackoilPhases::Aqua]) { smin[np*i + opos] -= smax[np*i + wpos]; smax[np*i + opos] -= smin[np*i + wpos]; } if (phaseUsage_.phase_used[BlackoilPhases::Vapour]) { smin[np*i + opos] -= smax[np*i + gpos]; smax[np*i + opos] -= smin[np*i + gpos]; } smin[np*i + opos] = std::max(0.0, smin[np*i + opos]); } } } /// Update saturation state for the hysteresis tracking /// \param[in] n Number of data points. /// \param[in] s Array of nP saturation values. void SaturationPropsFromDeck::updateSatHyst(const int n, const int* cells, const double* s) { assert(cells != 0); if (materialLawManager_->enableHysteresis()) { ExplicitArraysFluidState fluidState(phaseUsage_); fluidState.setSaturationArray(s); for (int i = 0; i < n; ++i) { fluidState.setIndex(i); materialLawManager_->updateHysteresis(fluidState, cells[i]); } } } /// Update capillary pressure scaling according to pressure diff. and initial water saturation. /// \param[in] cell Cell index. /// \param[in] pcow P_oil - P_water. /// \param[in/out] swat Water saturation. / Possibly modified Water saturation. void SaturationPropsFromDeck::swatInitScaling(const int cell, const double pcow, double& swat) { swat = materialLawManager_->applySwatinit(cell, pcow, swat); } } // namespace Opm