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202 lines
6.9 KiB
C++
202 lines
6.9 KiB
C++
/*
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Copyright 2014 SINTEF ICT, Applied Mathematics.
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Copyright 2015 Dr. Blatt - HPC-Simulation-Software & Services
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Copyright 2015 NTNU
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Copyright 2015 Statoil AS
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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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#include <config.h>
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#include <opm/autodiff/DuneMatrix.hpp>
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#include <opm/autodiff/NewtonIterationBlackoilCPR.hpp>
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#include <opm/autodiff/NewtonIterationUtilities.hpp>
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#include <opm/autodiff/AutoDiffHelpers.hpp>
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#include <opm/parser/eclipse/Units/Units.hpp>
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#include <opm/common/Exceptions.hpp>
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#include <opm/core/linalg/ParallelIstlInformation.hpp>
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#include <opm/common/utility/platform_dependent/disable_warnings.h>
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#if HAVE_UMFPACK
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#include <Eigen/UmfPackSupport>
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#else
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#include <Eigen/SparseLU>
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#endif
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#include <opm/common/utility/platform_dependent/reenable_warnings.h>
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namespace Opm
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{
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typedef AutoDiffBlock<double> ADB;
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typedef ADB::V V;
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typedef ADB::M M;
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/// Construct a system solver.
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NewtonIterationBlackoilCPR::NewtonIterationBlackoilCPR(const ParameterGroup& param,
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const boost::any& parallelInformation_arg)
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: cpr_param_( param ),
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iterations_( 0 ),
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parallelInformation_(parallelInformation_arg),
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newton_use_gmres_( param.getDefault("newton_use_gmres", false ) ),
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linear_solver_reduction_( param.getDefault("linear_solver_reduction", 1e-2 ) ),
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linear_solver_maxiter_( param.getDefault("linear_solver_maxiter", 50 ) ),
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linear_solver_restart_( param.getDefault("linear_solver_restart", 40 ) ),
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linear_solver_verbosity_( param.getDefault("linear_solver_verbosity", 0 )),
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linear_solver_ignoreconvergencefailure_(param.getDefault("linear_solver_ignoreconvergencefailure", false))
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{
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}
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/// Solve the linear system Ax = b, with A being the
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/// combined derivative matrix of the residual and b
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/// being the residual itself.
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/// \param[in] residual residual object containing A and b.
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/// \return the solution x
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NewtonIterationBlackoilCPR::SolutionVector
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NewtonIterationBlackoilCPR::computeNewtonIncrement(const LinearisedBlackoilResidual& residual) const
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{
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// Build the vector of equations.
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const int np = residual.material_balance_eq.size();
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std::vector<ADB> eqs;
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eqs.reserve(np + 2);
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for (int phase = 0; phase < np; ++phase) {
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eqs.push_back(residual.material_balance_eq[phase]);
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}
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// check if wells are present
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const bool hasWells = residual.well_flux_eq.size() > 0 ;
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std::vector<ADB> elim_eqs;
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if( hasWells )
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{
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eqs.push_back(residual.well_flux_eq);
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eqs.push_back(residual.well_eq);
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// Eliminate the well-related unknowns, and corresponding equations.
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elim_eqs.reserve(2);
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elim_eqs.push_back(eqs[np]);
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eqs = eliminateVariable(eqs, np); // Eliminate well flux unknowns.
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elim_eqs.push_back(eqs[np]);
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eqs = eliminateVariable(eqs, np); // Eliminate well bhp unknowns.
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assert(int(eqs.size()) == np);
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}
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// Scale material balance equations.
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for (int phase = 0; phase < np; ++phase) {
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eqs[phase] = eqs[phase] * residual.matbalscale[phase];
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}
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// Add material balance equations (or other manipulations) to
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// form pressure equation in top left of full system.
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Eigen::SparseMatrix<double, Eigen::RowMajor> A;
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V b;
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formEllipticSystem(np, eqs, A, b);
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// Scale pressure equation.
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const double pscale = 200*unit::barsa;
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const int nc = residual.material_balance_eq[0].size();
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A.topRows(nc) *= pscale;
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b.topRows(nc) *= pscale;
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// Solve reduced system.
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SolutionVector dx(SolutionVector::Zero(b.size()));
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// Create ISTL matrix.
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DuneMatrix istlA( A );
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// Create ISTL matrix for elliptic part.
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DuneMatrix istlAe( A.topLeftCorner(nc, nc) );
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// Right hand side.
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Vector istlb(istlA.N());
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std::copy_n(b.data(), istlb.size(), istlb.begin());
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// System solution
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Vector x(istlA.M());
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x = 0.0;
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Dune::InverseOperatorResult result;
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#if HAVE_MPI
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if(parallelInformation_.type()==typeid(ParallelISTLInformation))
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{
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typedef Dune::OwnerOverlapCopyCommunication<int,int> Comm;
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const ParallelISTLInformation& info =
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boost::any_cast<const ParallelISTLInformation&>( parallelInformation_);
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Comm istlComm(info.communicator());
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Comm istlAeComm(info.communicator());
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info.copyValuesTo(istlAeComm.indexSet(), istlAeComm.remoteIndices());
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info.copyValuesTo(istlComm.indexSet(), istlComm.remoteIndices(),
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istlAe.N(), istlA.N()/istlAe.N());
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// Construct operator, scalar product and vectors needed.
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typedef Dune::OverlappingSchwarzOperator<Mat,Vector,Vector,Comm> Operator;
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Operator opA(istlA, istlComm);
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constructPreconditionerAndSolve<Dune::SolverCategory::overlapping>(opA, istlAe, x, istlb, istlComm, istlAeComm, result);
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}
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else
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#endif
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{
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// Construct operator, scalar product and vectors needed.
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typedef Dune::MatrixAdapter<Mat,Vector,Vector> Operator;
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Operator opA(istlA);
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Dune::Amg::SequentialInformation info;
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constructPreconditionerAndSolve(opA, istlAe, x, istlb, info, info, result);
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}
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// store number of iterations
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iterations_ = result.iterations;
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// Check for failure of linear solver.
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if (!result.converged && !linear_solver_ignoreconvergencefailure_) {
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OPM_THROW(LinearSolverProblem, "Convergence failure for linear solver.");
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}
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// Copy solver output to dx.
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std::copy(x.begin(), x.end(), dx.data());
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if ( hasWells ) {
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// Compute full solution using the eliminated equations.
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// Recovery in inverse order of elimination.
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dx = recoverVariable(elim_eqs[1], dx, np);
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dx = recoverVariable(elim_eqs[0], dx, np);
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}
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return dx;
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}
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const boost::any& NewtonIterationBlackoilCPR::parallelInformation() const
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{
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return parallelInformation_;
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}
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} // namespace Opm
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