mirror of
https://github.com/OPM/opm-simulators.git
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1fbe8e3b6d
As it turns out initializing the Geology on a distributed grid result in wrong values for e.g. saturation. Therefore with this commit we resort to initializing the global geology and distribute it using communication.
410 lines
18 KiB
C++
410 lines
18 KiB
C++
/*
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Copyright 2013 SINTEF ICT, Applied Mathematics.
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This file is part of the Open Porous Media project (OPM).
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OPM is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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OPM is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with OPM. If not, see <http://www.gnu.org/licenses/>.
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*/
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#ifndef OPM_GEOPROPS_HEADER_INCLUDED
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#define OPM_GEOPROPS_HEADER_INCLUDED
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#include <opm/core/grid.h>
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#include <opm/autodiff/GridHelpers.hpp>
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#include <opm/core/utility/ErrorMacros.hpp>
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//#include <opm/core/pressure/tpfa/trans_tpfa.h>
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#include <opm/core/pressure/tpfa/TransTpfa.hpp>
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#include <opm/parser/eclipse/EclipseState/EclipseState.hpp>
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#include <opm/parser/eclipse/EclipseState/Grid/EclipseGrid.hpp>
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#include <opm/core/utility/platform_dependent/disable_warnings.h>
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#include <Eigen/Eigen>
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#ifdef HAVE_DUNE_CORNERPOINT
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#include <dune/common/version.hh>
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#include <dune/grid/CpGrid.hpp>
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#include <dune/grid/common/mcmgmapper.hh>
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#endif
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#include <opm/core/utility/platform_dependent/reenable_warnings.h>
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#include <cstddef>
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namespace Opm
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{
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/// Class containing static geological properties that are
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/// derived from grid and petrophysical properties:
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/// - pore volume
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/// - transmissibilities
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/// - gravity potentials
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class DerivedGeology
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{
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public:
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typedef Eigen::ArrayXd Vector;
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/// Construct contained derived geological properties
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/// from grid and property information.
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template <class Props, class Grid>
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DerivedGeology(const Grid& grid,
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const Props& props ,
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Opm::EclipseStateConstPtr eclState,
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const bool use_local_perm,
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const double* grav = 0
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)
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: pvol_ (Opm::AutoDiffGrid::numCells(grid))
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, trans_(Opm::AutoDiffGrid::numFaces(grid))
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, gpot_ (Vector::Zero(Opm::AutoDiffGrid::cell2Faces(grid).noEntries(), 1))
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, z_(Opm::AutoDiffGrid::numCells(grid))
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{
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int numCells = AutoDiffGrid::numCells(grid);
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int numFaces = AutoDiffGrid::numFaces(grid);
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const int *cartDims = AutoDiffGrid::cartDims(grid);
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int numCartesianCells =
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cartDims[0]
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* cartDims[1]
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* cartDims[2];
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// get the pore volume multipliers from the EclipseState
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std::vector<double> multpv(numCartesianCells, 1.0);
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if (eclState->hasDoubleGridProperty("MULTPV")) {
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multpv = eclState->getDoubleGridProperty("MULTPV")->getData();
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}
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// get the net-to-gross cell thickness from the EclipseState
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std::vector<double> ntg(numCartesianCells, 1.0);
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if (eclState->hasDoubleGridProperty("NTG")) {
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ntg = eclState->getDoubleGridProperty("NTG")->getData();
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}
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// get grid from parser.
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// Get original grid cell volume.
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EclipseGridConstPtr eclgrid = eclState->getEclipseGrid();
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// Pore volume.
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// New keywords MINPVF will add some PV due to OPM cpgrid process algorithm.
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// But the default behavior is to get the comparable pore volume with ECLIPSE.
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for (int cellIdx = 0; cellIdx < numCells; ++cellIdx) {
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int cartesianCellIdx = AutoDiffGrid::globalCell(grid)[cellIdx];
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pvol_[cellIdx] =
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props.porosity()[cellIdx]
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* multpv[cartesianCellIdx]
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* ntg[cartesianCellIdx];
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if (eclgrid->getMinpvMode() == MinpvMode::ModeEnum::OpmFIL) {
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pvol_[cellIdx] *= AutoDiffGrid::cellVolume(grid, cellIdx);
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} else {
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pvol_[cellIdx] *= eclgrid->getCellVolume(cartesianCellIdx);
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}
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}
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// Use volume weighted arithmetic average of the NTG values for
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// the cells effected by the current OPM cpgrid process algorithm
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// for MINPV. Note that the change does not effect the pore volume calculations
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// as the pore volume is currently defaulted to be comparable to ECLIPSE, but
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// only the transmissibility calculations.
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minPvFillProps_(grid, eclState,ntg);
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// Transmissibility
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Vector htrans(AutoDiffGrid::numCellFaces(grid));
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Grid* ug = const_cast<Grid*>(& grid);
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if (! use_local_perm) {
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tpfa_htrans_compute(ug, props.permeability(), htrans.data());
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}
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else {
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tpfa_loc_trans_compute_(grid,props.permeability(),htrans);
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}
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std::vector<double> mult;
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multiplyHalfIntersections_(grid, eclState, ntg, htrans, mult);
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// combine the half-face transmissibilites into the final face
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// transmissibilites.
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tpfa_trans_compute(ug, htrans.data(), trans_.data());
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// multiply the face transmissibilities with their appropriate
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// transmissibility multipliers
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for (int faceIdx = 0; faceIdx < numFaces; faceIdx++) {
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trans_[faceIdx] *= mult[faceIdx];
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}
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// Compute z coordinates
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for (int c = 0; c<numCells; ++c){
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z_[c] = Opm::UgGridHelpers::cellCentroidCoordinate(grid, c, 2);
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}
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// Gravity potential
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std::fill(gravity_, gravity_ + 3, 0.0);
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if (grav != 0) {
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const typename Vector::Index nd = AutoDiffGrid::dimensions(grid);
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typedef typename AutoDiffGrid::ADCell2FacesTraits<Grid>::Type Cell2Faces;
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Cell2Faces c2f=AutoDiffGrid::cell2Faces(grid);
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std::size_t i = 0;
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for (typename Vector::Index c = 0; c < numCells; ++c) {
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const double* const cc = AutoDiffGrid::cellCentroid(grid, c);
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typename Cell2Faces::row_type faces=c2f[c];
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typedef typename Cell2Faces::row_type::iterator Iter;
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for (Iter f=faces.begin(), end=faces.end(); f!=end; ++f, ++i) {
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auto fc = AutoDiffGrid::faceCentroid(grid, *f);
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for (typename Vector::Index d = 0; d < nd; ++d) {
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gpot_[i] += grav[d] * (fc[d] - cc[d]);
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}
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}
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}
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std::copy(grav, grav + nd, gravity_);
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}
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}
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const Vector& poreVolume() const { return pvol_ ;}
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const Vector& transmissibility() const { return trans_ ;}
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const Vector& gravityPotential() const { return gpot_ ;}
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const Vector& z() const { return z_ ;}
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const double* gravity() const { return gravity_;}
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Vector& poreVolume() { return pvol_ ;}
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Vector& transmissibility() { return trans_ ;}
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private:
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template <class Grid>
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void multiplyHalfIntersections_(const Grid &grid,
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Opm::EclipseStateConstPtr eclState,
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const std::vector<double> &ntg,
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Vector &halfIntersectTransmissibility,
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std::vector<double> &intersectionTransMult);
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template <class Grid>
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void tpfa_loc_trans_compute_(const Grid &grid,
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const double* perm,
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Vector &hTrans);
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template <class Grid>
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void minPvFillProps_(const Grid &grid,
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Opm::EclipseStateConstPtr eclState,
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std::vector<double> &ntg);
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Vector pvol_ ;
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Vector trans_;
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Vector gpot_ ;
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Vector z_;
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double gravity_[3]; // Size 3 even if grid is 2-dim.
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};
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template <class GridType>
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inline void DerivedGeology::minPvFillProps_(const GridType &grid,
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Opm::EclipseStateConstPtr eclState,
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std::vector<double> &ntg)
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{
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int numCells = Opm::AutoDiffGrid::numCells(grid);
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const int* global_cell = Opm::UgGridHelpers::globalCell(grid);
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const int* cartdims = Opm::UgGridHelpers::cartDims(grid);
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EclipseGridConstPtr eclgrid = eclState->getEclipseGrid();
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std::vector<double> porv = eclState->getDoubleGridProperty("PORV")->getData();
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for (int cellIdx = 0; cellIdx < numCells; ++cellIdx) {
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const int nx = cartdims[0];
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const int ny = cartdims[1];
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const int cartesianCellIdx = global_cell[cellIdx];
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const double cellVolume = eclgrid->getCellVolume(cartesianCellIdx);
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ntg[cartesianCellIdx] *= cellVolume;
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double totalCellVolume = cellVolume;
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// Average properties as long as there exist cells above
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// that has pore volume less than the MINPV threshold
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int cartesianCellIdxAbove = cartesianCellIdx - nx*ny;
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while ( cartesianCellIdxAbove >= 0 &&
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porv[cartesianCellIdxAbove] > 0 &&
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porv[cartesianCellIdxAbove] < eclgrid->getMinpvValue() ) {
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// Volume weighted arithmetic average of NTG
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const double cellAboveVolume = eclgrid->getCellVolume(cartesianCellIdxAbove);
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totalCellVolume += cellAboveVolume;
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ntg[cartesianCellIdx] += ntg[cartesianCellIdxAbove]*cellAboveVolume;
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cartesianCellIdxAbove -= nx*ny;
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}
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ntg[cartesianCellIdx] /= totalCellVolume;
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}
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}
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template <class GridType>
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inline void DerivedGeology::multiplyHalfIntersections_(const GridType &grid,
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Opm::EclipseStateConstPtr eclState,
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const std::vector<double> &ntg,
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Vector &halfIntersectTransmissibility,
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std::vector<double> &intersectionTransMult)
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{
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int numCells = Opm::AutoDiffGrid::numCells(grid);
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int numIntersections = Opm::AutoDiffGrid::numFaces(grid);
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intersectionTransMult.resize(numIntersections);
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std::fill(intersectionTransMult.begin(), intersectionTransMult.end(), 1.0);
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std::shared_ptr<const Opm::TransMult> multipliers = eclState->getTransMult();
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auto cell2Faces = Opm::UgGridHelpers::cell2Faces(grid);
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auto faceCells = Opm::AutoDiffGrid::faceCells(grid);
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const int* global_cell = Opm::UgGridHelpers::globalCell(grid);
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int cellFaceIdx = 0;
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for (int cellIdx = 0; cellIdx < numCells; ++cellIdx) {
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// loop over all logically-Cartesian faces of the current cell
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auto cellFacesRange = cell2Faces[cellIdx];
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for(auto cellFaceIter = cellFacesRange.begin(), cellFaceEnd = cellFacesRange.end();
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cellFaceIter != cellFaceEnd; ++cellFaceIter, ++cellFaceIdx)
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{
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// the index of the current cell in arrays for the logically-Cartesian grid
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int cartesianCellIdx = global_cell[cellIdx];
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// The index of the face in the compressed grid
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int faceIdx = *cellFaceIter;
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// the logically-Cartesian direction of the face
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int faceTag = Opm::UgGridHelpers::faceTag(grid, cellFaceIter);
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// Translate the C face tag into the enum used by opm-parser's TransMult class
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Opm::FaceDir::DirEnum faceDirection;
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if (faceTag == 0) // left
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faceDirection = Opm::FaceDir::XMinus;
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else if (faceTag == 1) // right
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faceDirection = Opm::FaceDir::XPlus;
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else if (faceTag == 2) // back
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faceDirection = Opm::FaceDir::YMinus;
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else if (faceTag == 3) // front
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faceDirection = Opm::FaceDir::YPlus;
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else if (faceTag == 4) // bottom
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faceDirection = Opm::FaceDir::ZMinus;
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else if (faceTag == 5) // top
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faceDirection = Opm::FaceDir::ZPlus;
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else
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OPM_THROW(std::logic_error, "Unhandled face direction: " << faceTag);
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// Account for NTG in horizontal one-sided transmissibilities
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switch (faceDirection) {
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case Opm::FaceDir::XMinus:
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case Opm::FaceDir::XPlus:
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case Opm::FaceDir::YMinus:
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case Opm::FaceDir::YPlus:
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halfIntersectTransmissibility[cellFaceIdx] *= ntg[cartesianCellIdx];
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break;
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default:
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// do nothing for the top and bottom faces
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break;
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}
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// Multiplier contribution on this face for MULT[XYZ] logical cartesian multipliers
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intersectionTransMult[faceIdx] *=
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multipliers->getMultiplier(cartesianCellIdx, faceDirection);
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// Multiplier contribution on this fase for region multipliers
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const int cellIdxInside = faceCells(faceIdx, 0);
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const int cellIdxOutside = faceCells(faceIdx, 1);
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// Do not apply region multipliers in the case of boundary connections
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if (cellIdxInside < 0 || cellIdxOutside < 0) {
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continue;
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}
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const int cartesianCellIdxInside = global_cell[cellIdxInside];
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const int cartesianCellIdxOutside = global_cell[cellIdxOutside];
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// Only apply the region multipliers from the inside
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if (cartesianCellIdx == cartesianCellIdxInside) {
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intersectionTransMult[faceIdx] *= multipliers->getRegionMultiplier(cartesianCellIdxInside,cartesianCellIdxOutside,faceDirection);
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}
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}
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}
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}
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template <class GridType>
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inline void DerivedGeology::tpfa_loc_trans_compute_(const GridType& grid,
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const double* perm,
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Vector& hTrans){
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// Using Local coordinate system for the transmissibility calculations
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// hTrans(cellFaceIdx) = K(cellNo,j) * sum( C(:,i) .* N(:,j), 2) / sum(C.*C, 2)
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// where K is a diagonal permeability tensor, C is the distance from cell centroid
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// to face centroid and N is the normal vector pointing outwards with norm equal to the face area.
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// Off-diagonal permeability values are ignored without warning
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int numCells = AutoDiffGrid::numCells(grid);
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int cellFaceIdx = 0;
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auto cell2Faces = Opm::UgGridHelpers::cell2Faces(grid);
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auto faceCells = Opm::UgGridHelpers::faceCells(grid);
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for (int cellIdx = 0; cellIdx < numCells; ++cellIdx) {
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// loop over all logically-Cartesian faces of the current cell
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auto cellFacesRange = cell2Faces[cellIdx];
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for(auto cellFaceIter = cellFacesRange.begin(), cellFaceEnd = cellFacesRange.end();
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cellFaceIter != cellFaceEnd; ++cellFaceIter, ++cellFaceIdx)
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{
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// The index of the face in the compressed grid
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const int faceIdx = *cellFaceIter;
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// the logically-Cartesian direction of the face
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const int faceTag = Opm::UgGridHelpers::faceTag(grid, cellFaceIter);
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// d = 0: XPERM d = 4: YPERM d = 8: ZPERM ignores off-diagonal permeability values.
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const int d = std::floor(faceTag/2) * 4;
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// compute the half transmissibility
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double dist = 0.0;
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double cn = 0.0;
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double sgn = 2.0 * (faceCells(faceIdx, 0) == cellIdx) - 1;
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const int dim = Opm::UgGridHelpers::dimensions(grid);
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for (int indx = 0; indx < dim; ++indx) {
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const double Ci = Opm::UgGridHelpers::faceCentroid(grid, faceIdx)[indx] -
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Opm::UgGridHelpers::cellCentroidCoordinate(grid, cellIdx, indx);
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dist += Ci*Ci;
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cn += sgn * Ci * Opm::UgGridHelpers::faceNormal(grid, faceIdx)[indx];
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}
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if (cn < 0){
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switch (d) {
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case 0:
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OPM_MESSAGE("Warning: negative X-transmissibility value in cell: " << cellIdx << " replace by absolute value") ;
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break;
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case 4:
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OPM_MESSAGE("Warning: negative Y-transmissibility value in cell: " << cellIdx << " replace by absolute value") ;
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break;
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case 8:
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OPM_MESSAGE("Warning: negative Z-transmissibility value in cell: " << cellIdx << " replace by absolute value") ;
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break;
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default:
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OPM_THROW(std::logic_error, "Inconsistency in the faceTag in cell: " << cellIdx);
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}
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cn = -cn;
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}
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hTrans[cellFaceIdx] = perm[cellIdx*dim*dim + d] * cn / dist;
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}
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}
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}
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}
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#endif // OPM_GEOPROPS_HEADER_INCLUDED
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