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794 lines
35 KiB
C++
794 lines
35 KiB
C++
/*
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Copyright 2012 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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#include "config.h"
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#include <opm/core/grid/CellQuadrature.hpp>
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#include <opm/core/grid/FaceQuadrature.hpp>
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#include <opm/core/tof/TofDiscGalReorder.hpp>
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#include <opm/core/tof/DGBasis.hpp>
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#include <opm/core/grid.h>
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#include <opm/core/utility/ErrorMacros.hpp>
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#include <opm/core/utility/SparseTable.hpp>
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#include <opm/core/utility/VelocityInterpolation.hpp>
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#include <opm/core/utility/parameters/ParameterGroup.hpp>
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#include <opm/core/linalg/blas_lapack.h>
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#include <algorithm>
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#include <cmath>
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#include <numeric>
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#include <iostream>
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namespace Opm
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{
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/// Construct solver.
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TofDiscGalReorder::TofDiscGalReorder(const UnstructuredGrid& grid,
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const parameter::ParameterGroup& param)
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: grid_(grid),
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use_cvi_(false),
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use_limiter_(false),
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limiter_relative_flux_threshold_(1e-3),
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limiter_method_(MinUpwindAverage),
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limiter_usage_(DuringComputations),
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coord_(grid.dimensions),
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velocity_(grid.dimensions),
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gauss_seidel_tol_(1e-3)
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{
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const int dg_degree = param.getDefault("dg_degree", 0);
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const bool use_tensorial_basis = param.getDefault("use_tensorial_basis", false);
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if (use_tensorial_basis) {
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basis_func_.reset(new DGBasisMultilin(grid_, dg_degree));
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} else {
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basis_func_.reset(new DGBasisBoundedTotalDegree(grid_, dg_degree));
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}
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use_cvi_ = param.getDefault("use_cvi", use_cvi_);
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use_limiter_ = param.getDefault("use_limiter", use_limiter_);
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if (use_limiter_) {
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limiter_relative_flux_threshold_ = param.getDefault("limiter_relative_flux_threshold",
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limiter_relative_flux_threshold_);
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const std::string limiter_method_str = param.getDefault<std::string>("limiter_method", "MinUpwindAverage");
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if (limiter_method_str == "MinUpwindFace") {
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limiter_method_ = MinUpwindFace;
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} else if (limiter_method_str == "MinUpwindAverage") {
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limiter_method_ = MinUpwindAverage;
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} else {
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OPM_THROW(std::runtime_error, "Unknown limiter method: " << limiter_method_str);
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}
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const std::string limiter_usage_str = param.getDefault<std::string>("limiter_usage", "DuringComputations");
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if (limiter_usage_str == "DuringComputations") {
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limiter_usage_ = DuringComputations;
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} else if (limiter_usage_str == "AsPostProcess") {
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limiter_usage_ = AsPostProcess;
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} else if (limiter_usage_str == "AsSimultaneousPostProcess") {
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limiter_usage_ = AsSimultaneousPostProcess;
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} else {
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OPM_THROW(std::runtime_error, "Unknown limiter usage spec: " << limiter_usage_str);
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}
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}
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// A note about the use_cvi_ member variable:
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// In principle, we should not need it, since the choice of velocity
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// interpolation is made below, but we may need to use higher order
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// quadrature to exploit CVI, so we store the choice.
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// An alternative would be to add a virtual method isConstant() to
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// the VelocityInterpolationInterface.
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if (use_cvi_) {
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velocity_interpolation_.reset(new VelocityInterpolationECVI(grid_));
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} else {
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velocity_interpolation_.reset(new VelocityInterpolationConstant(grid_));
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}
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}
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/// Solve for time-of-flight.
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void TofDiscGalReorder::solveTof(const double* darcyflux,
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const double* porevolume,
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const double* source,
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std::vector<double>& tof_coeff)
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{
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darcyflux_ = darcyflux;
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porevolume_ = porevolume;
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source_ = source;
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#ifndef NDEBUG
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// Sanity check for sources.
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const double cum_src = std::accumulate(source, source + grid_.number_of_cells, 0.0);
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if (std::fabs(cum_src) > *std::max_element(source, source + grid_.number_of_cells)*1e-2) {
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// OPM_THROW(std::runtime_error, "Sources do not sum to zero: " << cum_src);
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OPM_MESSAGE("Warning: sources do not sum to zero: " << cum_src);
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}
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#endif
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const int num_basis = basis_func_->numBasisFunc();
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tof_coeff.resize(num_basis*grid_.number_of_cells);
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std::fill(tof_coeff.begin(), tof_coeff.end(), 0.0);
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tof_coeff_ = &tof_coeff[0];
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rhs_.resize(num_basis);
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jac_.resize(num_basis*num_basis);
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orig_jac_.resize(num_basis*num_basis);
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basis_.resize(num_basis);
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basis_nb_.resize(num_basis);
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grad_basis_.resize(num_basis*grid_.dimensions);
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velocity_interpolation_->setupFluxes(darcyflux);
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num_tracers_ = 0;
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num_multicell_ = 0;
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max_size_multicell_ = 0;
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max_iter_multicell_ = 0;
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num_singlesolves_ = 0;
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reorderAndTransport(grid_, darcyflux);
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switch (limiter_usage_) {
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case AsPostProcess:
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applyLimiterAsPostProcess();
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break;
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case AsSimultaneousPostProcess:
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applyLimiterAsSimultaneousPostProcess();
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break;
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case DuringComputations:
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// Do nothing.
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break;
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default:
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OPM_THROW(std::runtime_error, "Unknown limiter usage choice: " << limiter_usage_);
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}
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if (num_multicell_ > 0) {
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std::cout << num_multicell_ << " multicell blocks with max size "
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<< max_size_multicell_ << " cells in upto "
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<< max_iter_multicell_ << " iterations." << std::endl;
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std::cout << "Average solves per cell (for all cells) was "
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<< double(num_singlesolves_)/double(grid_.number_of_cells) << std::endl;
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}
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}
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/// Solve for time-of-flight and a number of tracers.
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/// \param[in] darcyflux Array of signed face fluxes.
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/// \param[in] porevolume Array of pore volumes.
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/// \param[in] source Source term. Sign convention is:
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/// (+) inflow flux,
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/// (-) outflow flux.
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/// \param[in] tracerheads Table containing one row per tracer, and each
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/// row contains the source cells for that tracer.
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/// \param[out] tof_coeff Array of time-of-flight solution coefficients.
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/// The values are ordered by cell, meaning that
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/// the K coefficients corresponding to the first
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/// cell comes before the K coefficients corresponding
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/// to the second cell etc.
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/// K depends on degree and grid dimension.
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/// \param[out] tracer_coeff Array of tracer solution coefficients. N*K per cell,
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/// where N is equal to tracerheads.size(). All K coefs
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/// for a tracer are consecutive, and all tracers' coefs
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/// for a cell come before those for the next cell.
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void TofDiscGalReorder::solveTofTracer(const double* darcyflux,
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const double* porevolume,
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const double* source,
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const SparseTable<int>& tracerheads,
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std::vector<double>& tof_coeff,
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std::vector<double>& tracer_coeff)
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{
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darcyflux_ = darcyflux;
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porevolume_ = porevolume;
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source_ = source;
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#ifndef NDEBUG
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// Sanity check for sources.
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const double cum_src = std::accumulate(source, source + grid_.number_of_cells, 0.0);
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if (std::fabs(cum_src) > *std::max_element(source, source + grid_.number_of_cells)*1e-2) {
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// OPM_THROW(std::runtime_error, "Sources do not sum to zero: " << cum_src);
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OPM_MESSAGE("Warning: sources do not sum to zero: " << cum_src);
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}
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#endif
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const int num_basis = basis_func_->numBasisFunc();
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num_tracers_ = tracerheads.size();
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tof_coeff.resize(num_basis*grid_.number_of_cells);
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std::fill(tof_coeff.begin(), tof_coeff.end(), 0.0);
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tof_coeff_ = &tof_coeff[0];
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rhs_.resize(num_basis*(num_tracers_ + 1));
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jac_.resize(num_basis*num_basis);
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orig_jac_.resize(num_basis*num_basis);
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basis_.resize(num_basis);
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basis_nb_.resize(num_basis);
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grad_basis_.resize(num_basis*grid_.dimensions);
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velocity_interpolation_->setupFluxes(darcyflux);
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// Set up tracer
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tracer_coeff.resize(grid_.number_of_cells*num_tracers_*num_basis);
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std::fill(tracer_coeff.begin(), tracer_coeff.end(), 0.0);
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if (num_tracers_ > 0) {
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tracerhead_by_cell_.clear();
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tracerhead_by_cell_.resize(grid_.number_of_cells, NoTracerHead);
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}
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for (int tr = 0; tr < num_tracers_; ++tr) {
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for (int i = 0; i < tracerheads[tr].size(); ++i) {
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const int cell = tracerheads[tr][i];
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basis_func_->addConstant(1.0, &tracer_coeff[cell*num_tracers_*num_basis + tr*num_basis]);
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tracer_coeff[cell*num_tracers_ + tr] = 1.0;
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tracerhead_by_cell_[cell] = tr;
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}
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}
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tracer_coeff_ = &tracer_coeff[0];
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num_multicell_ = 0;
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max_size_multicell_ = 0;
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max_iter_multicell_ = 0;
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num_singlesolves_ = 0;
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reorderAndTransport(grid_, darcyflux);
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switch (limiter_usage_) {
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case AsPostProcess:
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applyLimiterAsPostProcess();
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break;
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case AsSimultaneousPostProcess:
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applyLimiterAsSimultaneousPostProcess();
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break;
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case DuringComputations:
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// Do nothing.
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break;
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default:
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OPM_THROW(std::runtime_error, "Unknown limiter usage choice: " << limiter_usage_);
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}
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if (num_multicell_ > 0) {
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std::cout << num_multicell_ << " multicell blocks with max size "
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<< max_size_multicell_ << " cells in upto "
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<< max_iter_multicell_ << " iterations." << std::endl;
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std::cout << "Average solves per cell (for all cells) was "
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<< double(num_singlesolves_)/double(grid_.number_of_cells) << std::endl;
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}
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}
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void TofDiscGalReorder::solveSingleCell(const int cell)
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{
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// Residual:
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// For each cell K, basis function b_j (spanning V_h),
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// writing the solution u_h|K = \sum_i c_i b_i
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// Res = - \int_K \sum_i c_i b_i v(x) \cdot \grad b_j dx
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// + \int_{\partial K} F(u_h, u_h^{ext}, v(x) \cdot n) b_j ds
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// - \int_K \phi b_j
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// This is linear in c_i, so we do not need any nonlinear iterations.
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// We assemble the jacobian and the right-hand side. The residual is
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// equal to Res = Jac*c - rhs, and we compute rhs directly.
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//
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// For tracers, the equation is the same, except for the last
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// term being zero (the one with \phi).
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//
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// The rhs_ vector contains a (Fortran ordering) matrix of all
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// right-hand-sides, first for tof and then (optionally) for
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// all tracers.
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const int dim = grid_.dimensions;
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const int num_basis = basis_func_->numBasisFunc();
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++num_singlesolves_;
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std::fill(rhs_.begin(), rhs_.end(), 0.0);
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std::fill(jac_.begin(), jac_.end(), 0.0);
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// Compute cell residual contribution.
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{
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const int deg_needed = basis_func_->degree();
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CellQuadrature quad(grid_, cell, deg_needed);
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for (int quad_pt = 0; quad_pt < quad.numQuadPts(); ++quad_pt) {
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// Integral of: b_i \phi
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quad.quadPtCoord(quad_pt, &coord_[0]);
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basis_func_->eval(cell, &coord_[0], &basis_[0]);
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const double w = quad.quadPtWeight(quad_pt);
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for (int j = 0; j < num_basis; ++j) {
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// Only adding to the tof rhs.
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rhs_[j] += w * basis_[j] * porevolume_[cell] / grid_.cell_volumes[cell];
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}
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}
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}
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// Compute upstream residual contribution.
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for (int hface = grid_.cell_facepos[cell]; hface < grid_.cell_facepos[cell+1]; ++hface) {
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const int face = grid_.cell_faces[hface];
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double flux = 0.0;
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int upstream_cell = -1;
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if (cell == grid_.face_cells[2*face]) {
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flux = darcyflux_[face];
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upstream_cell = grid_.face_cells[2*face+1];
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} else {
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flux = -darcyflux_[face];
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upstream_cell = grid_.face_cells[2*face];
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}
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if (flux >= 0.0) {
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// This is an outflow boundary.
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continue;
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}
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if (upstream_cell < 0) {
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// This is an outer boundary. Assumed tof = 0 on inflow, so no contribution.
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// For tracers, a cell with inflow should be marked as a tracer head cell,
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// and not be modified.
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continue;
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}
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// Do quadrature over the face to compute
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// \int_{\partial K} u_h^{ext} (v(x) \cdot n) b_j ds
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// (where u_h^{ext} is the upstream unknown (tof)).
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// Quadrature degree set to 2*D, since u_h^{ext} varies
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// with degree D, and b_j too. We assume that the normal
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// velocity is constant (this assumption may have to go
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// for higher order than DG1).
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const double normal_velocity = flux / grid_.face_areas[face];
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const int deg_needed = 2*basis_func_->degree();
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FaceQuadrature quad(grid_, face, deg_needed);
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for (int quad_pt = 0; quad_pt < quad.numQuadPts(); ++quad_pt) {
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quad.quadPtCoord(quad_pt, &coord_[0]);
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basis_func_->eval(cell, &coord_[0], &basis_[0]);
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basis_func_->eval(upstream_cell, &coord_[0], &basis_nb_[0]);
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const double w = quad.quadPtWeight(quad_pt);
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// Modify tof rhs
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const double tof_upstream = std::inner_product(basis_nb_.begin(), basis_nb_.end(),
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tof_coeff_ + num_basis*upstream_cell, 0.0);
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for (int j = 0; j < num_basis; ++j) {
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rhs_[j] -= w * tof_upstream * normal_velocity * basis_[j];
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}
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// Modify tracer rhs
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if (num_tracers_ && tracerhead_by_cell_[cell] == NoTracerHead) {
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for (int tr = 0; tr < num_tracers_; ++tr) {
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const double* up_tr_co = tracer_coeff_ + num_tracers_*num_basis*upstream_cell + num_basis*tr;
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const double tracer_up = std::inner_product(basis_nb_.begin(), basis_nb_.end(), up_tr_co, 0.0);
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for (int j = 0; j < num_basis; ++j) {
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rhs_[num_basis*(tr + 1) + j] -= w * tracer_up * normal_velocity * basis_[j];
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}
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}
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}
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}
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}
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// Compute cell jacobian contribution. We use Fortran ordering
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// for jac_, i.e. rows cycling fastest.
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{
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// Even with ECVI velocity interpolation, degree of precision 1
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// is sufficient for optimal convergence order for DG1 when we
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// use linear (total degree 1) basis functions.
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// With bi(tri)-linear basis functions, it still seems sufficient
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// for convergence order 2, but the solution looks much better and
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// has significantly lower error with degree of precision 2.
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// For now, we err on the side of caution, and use 2*degree, even
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// though this is wasteful for the pure linear basis functions.
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// const int deg_needed = 2*basis_func_->degree() - 1;
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const int deg_needed = 2*basis_func_->degree();
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CellQuadrature quad(grid_, cell, deg_needed);
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for (int quad_pt = 0; quad_pt < quad.numQuadPts(); ++quad_pt) {
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// b_i (v \cdot \grad b_j)
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quad.quadPtCoord(quad_pt, &coord_[0]);
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basis_func_->eval(cell, &coord_[0], &basis_[0]);
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basis_func_->evalGrad(cell, &coord_[0], &grad_basis_[0]);
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velocity_interpolation_->interpolate(cell, &coord_[0], &velocity_[0]);
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const double w = quad.quadPtWeight(quad_pt);
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for (int j = 0; j < num_basis; ++j) {
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for (int i = 0; i < num_basis; ++i) {
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for (int dd = 0; dd < dim; ++dd) {
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jac_[j*num_basis + i] -= w * basis_[j] * grad_basis_[dim*i + dd] * velocity_[dd];
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}
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}
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}
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}
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}
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// Compute downstream jacobian contribution from faces.
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for (int hface = grid_.cell_facepos[cell]; hface < grid_.cell_facepos[cell+1]; ++hface) {
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const int face = grid_.cell_faces[hface];
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double flux = 0.0;
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if (cell == grid_.face_cells[2*face]) {
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flux = darcyflux_[face];
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} else {
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flux = -darcyflux_[face];
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}
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if (flux <= 0.0) {
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// This is an inflow boundary.
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continue;
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}
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// Do quadrature over the face to compute
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// \int_{\partial K} b_i (v(x) \cdot n) b_j ds
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const double normal_velocity = flux / grid_.face_areas[face];
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FaceQuadrature quad(grid_, face, 2*basis_func_->degree());
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for (int quad_pt = 0; quad_pt < quad.numQuadPts(); ++quad_pt) {
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// u^ext flux B (B = {b_j})
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quad.quadPtCoord(quad_pt, &coord_[0]);
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basis_func_->eval(cell, &coord_[0], &basis_[0]);
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const double w = quad.quadPtWeight(quad_pt);
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for (int j = 0; j < num_basis; ++j) {
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for (int i = 0; i < num_basis; ++i) {
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jac_[j*num_basis + i] += w * basis_[i] * normal_velocity * basis_[j];
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}
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}
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}
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}
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// Compute downstream jacobian contribution from sink terms.
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// Contribution from inflow sources would be
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// similar to the contribution from upstream faces, but
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// it is zero since we let all external inflow be associated
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// with a zero tof.
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if (source_[cell] < 0.0) {
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// A sink.
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const double flux = -source_[cell]; // Sign convention for flux: outflux > 0.
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const double flux_density = flux / grid_.cell_volumes[cell];
|
|
// Do quadrature over the cell to compute
|
|
// \int_{K} b_i flux b_j dx
|
|
CellQuadrature quad(grid_, cell, 2*basis_func_->degree());
|
|
for (int quad_pt = 0; quad_pt < quad.numQuadPts(); ++quad_pt) {
|
|
quad.quadPtCoord(quad_pt, &coord_[0]);
|
|
basis_func_->eval(cell, &coord_[0], &basis_[0]);
|
|
const double w = quad.quadPtWeight(quad_pt);
|
|
for (int j = 0; j < num_basis; ++j) {
|
|
for (int i = 0; i < num_basis; ++i) {
|
|
jac_[j*num_basis + i] += w * basis_[i] * flux_density * basis_[j];
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
// Solve linear equation.
|
|
MAT_SIZE_T n = num_basis;
|
|
int num_tracer_to_compute = num_tracers_;
|
|
if (num_tracers_) {
|
|
if (tracerhead_by_cell_[cell] != NoTracerHead) {
|
|
num_tracer_to_compute = 0;
|
|
}
|
|
}
|
|
MAT_SIZE_T nrhs = 1 + num_tracer_to_compute;
|
|
MAT_SIZE_T lda = num_basis;
|
|
std::vector<MAT_SIZE_T> piv(num_basis);
|
|
MAT_SIZE_T ldb = num_basis;
|
|
MAT_SIZE_T info = 0;
|
|
orig_jac_ = jac_;
|
|
orig_rhs_ = rhs_;
|
|
dgesv_(&n, &nrhs, &jac_[0], &lda, &piv[0], &rhs_[0], &ldb, &info);
|
|
if (info != 0) {
|
|
// Print the local matrix and rhs.
|
|
std::cerr << "Failed solving single-cell system Ax = b in cell " << cell
|
|
<< " with A = \n";
|
|
for (int row = 0; row < n; ++row) {
|
|
for (int col = 0; col < n; ++col) {
|
|
std::cerr << " " << orig_jac_[row + n*col];
|
|
}
|
|
std::cerr << '\n';
|
|
}
|
|
std::cerr << "and b = \n";
|
|
for (int row = 0; row < n; ++row) {
|
|
std::cerr << " " << orig_rhs_[row] << '\n';
|
|
}
|
|
OPM_THROW(std::runtime_error, "Lapack error: " << info << " encountered in cell " << cell);
|
|
}
|
|
|
|
// The solution ends up in rhs_, so we must copy it.
|
|
std::copy(rhs_.begin(), rhs_.begin() + num_basis, tof_coeff_ + num_basis*cell);
|
|
if (num_tracers_ && tracerhead_by_cell_[cell] == NoTracerHead) {
|
|
std::copy(rhs_.begin() + num_basis, rhs_.end(), tracer_coeff_ + num_tracers_*num_basis*cell);
|
|
}
|
|
|
|
// Apply limiter.
|
|
if (basis_func_->degree() > 0 && use_limiter_ && limiter_usage_ == DuringComputations) {
|
|
#ifdef EXTRA_VERBOSE
|
|
std::cout << "Cell: " << cell << " ";
|
|
std::cout << "v = ";
|
|
for (int dd = 0; dd < dim; ++dd) {
|
|
std::cout << velocity_[dd] << ' ';
|
|
}
|
|
std::cout << " grad tau = ";
|
|
for (int dd = 0; dd < dim; ++dd) {
|
|
std::cout << tof_coeff_[num_basis*cell + dd + 1] << ' ';
|
|
}
|
|
const double prod = std::inner_product(velocity_.begin(), velocity_.end(),
|
|
tof_coeff_ + num_basis*cell + 1, 0.0);
|
|
const double vv = std::inner_product(velocity_.begin(), velocity_.end(),
|
|
velocity_.begin(), 0.0);
|
|
const double gg = std::inner_product(tof_coeff_ + num_basis*cell + 1,
|
|
tof_coeff_ + num_basis*cell + num_basis,
|
|
tof_coeff_ + num_basis*cell + 1, 0.0);
|
|
std::cout << " prod = " << std::inner_product(velocity_.begin(), velocity_.end(),
|
|
tof_coeff_ + num_basis*cell + 1, 0.0);
|
|
std::cout << " normalized = " << prod/std::sqrt(vv*gg);
|
|
std::cout << " angle = " << std::acos(prod/std::sqrt(vv*gg))*360.0/(2.0*M_PI);
|
|
std::cout << std::endl;
|
|
#endif
|
|
applyLimiter(cell, tof_coeff_);
|
|
if (num_tracers_ && tracerhead_by_cell_[cell] == NoTracerHead) {
|
|
for (int tr = 0; tr < num_tracers_; ++tr) {
|
|
applyTracerLimiter(cell, tracer_coeff_ + cell*num_tracers_*num_basis + tr*num_basis);
|
|
}
|
|
}
|
|
}
|
|
|
|
// Ensure that tracer averages sum to 1.
|
|
if (num_tracers_ && tracerhead_by_cell_[cell] == NoTracerHead) {
|
|
std::vector<double> tr_aver(num_tracers_);
|
|
double tr_sum = 0.0;
|
|
for (int tr = 0; tr < num_tracers_; ++tr) {
|
|
const double* local_basis = tracer_coeff_ + cell*num_tracers_*num_basis + tr*num_basis;
|
|
tr_aver[tr] = basis_func_->functionAverage(local_basis);
|
|
tr_sum += tr_aver[tr];
|
|
}
|
|
if (tr_sum == 0.0) {
|
|
std::cout << "Tracer sum is zero in cell " << cell << std::endl;
|
|
} else {
|
|
for (int tr = 0; tr < num_tracers_; ++tr) {
|
|
const double increment = tr_aver[tr]/tr_sum - tr_aver[tr];
|
|
double* local_basis = tracer_coeff_ + cell*num_tracers_*num_basis + tr*num_basis;
|
|
basis_func_->addConstant(increment, local_basis);
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
|
|
|
|
|
|
void TofDiscGalReorder::solveMultiCell(const int num_cells, const int* cells)
|
|
{
|
|
++num_multicell_;
|
|
max_size_multicell_ = std::max(max_size_multicell_, num_cells);
|
|
// std::cout << "Multiblock solve with " << num_cells << " cells." << std::endl;
|
|
|
|
// Using a Gauss-Seidel approach.
|
|
const int nb = basis_func_->numBasisFunc();
|
|
double max_delta = 1e100;
|
|
int num_iter = 0;
|
|
while (max_delta > gauss_seidel_tol_) {
|
|
max_delta = 0.0;
|
|
++num_iter;
|
|
for (int ci = 0; ci < num_cells; ++ci) {
|
|
const int cell = cells[ci];
|
|
const double tof_before = basis_func_->functionAverage(&tof_coeff_[nb*cell]);
|
|
solveSingleCell(cell);
|
|
const double tof_after = basis_func_->functionAverage(&tof_coeff_[nb*cell]);
|
|
max_delta = std::max(max_delta, std::fabs(tof_after - tof_before));
|
|
}
|
|
// std::cout << "Max delta = " << max_delta << std::endl;
|
|
}
|
|
max_iter_multicell_ = std::max(max_iter_multicell_, num_iter);
|
|
}
|
|
|
|
|
|
|
|
|
|
void TofDiscGalReorder::applyLimiter(const int cell, double* tof)
|
|
{
|
|
switch (limiter_method_) {
|
|
case MinUpwindFace:
|
|
applyMinUpwindLimiter(cell, true, tof);
|
|
break;
|
|
case MinUpwindAverage:
|
|
applyMinUpwindLimiter(cell, false, tof);
|
|
break;
|
|
default:
|
|
OPM_THROW(std::runtime_error, "Limiter type not implemented: " << limiter_method_);
|
|
}
|
|
}
|
|
|
|
|
|
|
|
|
|
void TofDiscGalReorder::applyMinUpwindLimiter(const int cell, const bool face_min, double* tof)
|
|
{
|
|
if (basis_func_->degree() != 1) {
|
|
OPM_THROW(std::runtime_error, "This limiter only makes sense for our DG1 implementation.");
|
|
}
|
|
|
|
// Limiter principles:
|
|
// 1. Let M be either:
|
|
// - the minimum TOF value of all upstream faces,
|
|
// evaluated in the upstream cells
|
|
// (chosen if face_min is true).
|
|
// or:
|
|
// - the minimum average TOF value of all upstream cells
|
|
// (chosen if face_min is false).
|
|
// Then the value at all points in this cell shall be at
|
|
// least M. Upstream faces whose flux does not exceed the
|
|
// relative flux threshold are not considered for this
|
|
// minimum.
|
|
// 2. The TOF shall not be below zero in any point.
|
|
|
|
// Find minimum tof on upstream faces/cells and for this cell.
|
|
const int num_basis = basis_func_->numBasisFunc();
|
|
double min_upstream_tof = 1e100;
|
|
double min_here_tof = 1e100;
|
|
int num_upstream_faces = 0;
|
|
const double total_flux = totalFlux(cell);
|
|
for (int hface = grid_.cell_facepos[cell]; hface < grid_.cell_facepos[cell+1]; ++hface) {
|
|
const int face = grid_.cell_faces[hface];
|
|
double flux = 0.0;
|
|
int upstream_cell = -1;
|
|
if (cell == grid_.face_cells[2*face]) {
|
|
flux = darcyflux_[face];
|
|
upstream_cell = grid_.face_cells[2*face+1];
|
|
} else {
|
|
flux = -darcyflux_[face];
|
|
upstream_cell = grid_.face_cells[2*face];
|
|
}
|
|
const bool upstream = (flux < -total_flux*limiter_relative_flux_threshold_);
|
|
const bool interior = (upstream_cell >= 0);
|
|
|
|
// Find minimum tof in this cell and upstream.
|
|
// The meaning of minimum upstream tof depends on method.
|
|
min_here_tof = std::min(min_here_tof, minCornerVal(cell, face));
|
|
if (upstream) {
|
|
++num_upstream_faces;
|
|
double upstream_tof = 0.0;
|
|
if (interior) {
|
|
if (face_min) {
|
|
upstream_tof = minCornerVal(upstream_cell, face);
|
|
} else {
|
|
upstream_tof = basis_func_->functionAverage(tof_coeff_ + num_basis*upstream_cell);
|
|
}
|
|
}
|
|
min_upstream_tof = std::min(min_upstream_tof, upstream_tof);
|
|
}
|
|
}
|
|
|
|
// Compute slope multiplier (limiter).
|
|
if (num_upstream_faces == 0) {
|
|
min_upstream_tof = 0.0;
|
|
min_here_tof = 0.0;
|
|
}
|
|
if (min_upstream_tof < 0.0) {
|
|
min_upstream_tof = 0.0;
|
|
}
|
|
const double tof_c = basis_func_->functionAverage(tof_coeff_ + num_basis*cell);
|
|
double limiter = (tof_c - min_upstream_tof)/(tof_c - min_here_tof);
|
|
if (tof_c < min_upstream_tof) {
|
|
// Handle by setting a flat solution.
|
|
// std::cout << "Trouble in cell " << cell << std::endl;
|
|
limiter = 0.0;
|
|
basis_func_->addConstant(min_upstream_tof - tof_c, tof + num_basis*cell);
|
|
}
|
|
assert(limiter >= 0.0);
|
|
|
|
// Actually do the limiting (if applicable).
|
|
if (limiter < 1.0) {
|
|
// std::cout << "Applying limiter in cell " << cell << ", limiter = " << limiter << std::endl;
|
|
basis_func_->multiplyGradient(limiter, tof + num_basis*cell);
|
|
} else {
|
|
// std::cout << "Not applying limiter in cell " << cell << "!" << std::endl;
|
|
}
|
|
}
|
|
|
|
|
|
|
|
|
|
|
|
|
|
void TofDiscGalReorder::applyLimiterAsPostProcess()
|
|
{
|
|
// Apply the limiter sequentially to all cells.
|
|
// This means that a cell's limiting behaviour may be affected by
|
|
// any limiting applied to its upstream cells.
|
|
const std::vector<int>& seq = ReorderSolverInterface::sequence();
|
|
const int nc = seq.size();
|
|
assert(nc == grid_.number_of_cells);
|
|
for (int i = 0; i < nc; ++i) {
|
|
const int cell = seq[i];
|
|
applyLimiter(cell, tof_coeff_);
|
|
}
|
|
}
|
|
|
|
|
|
|
|
|
|
void TofDiscGalReorder::applyLimiterAsSimultaneousPostProcess()
|
|
{
|
|
// Apply the limiter simultaneously to all cells.
|
|
// This means that each cell is limited independently from all other cells,
|
|
// we write the resulting dofs to a new array instead of writing to tof_coeff_.
|
|
// Afterwards we copy the results back to tof_coeff_.
|
|
const int num_basis = basis_func_->numBasisFunc();
|
|
std::vector<double> tof_coeffs_new(tof_coeff_, tof_coeff_ + num_basis*grid_.number_of_cells);
|
|
for (int c = 0; c < grid_.number_of_cells; ++c) {
|
|
applyLimiter(c, &tof_coeffs_new[0]);
|
|
}
|
|
std::copy(tof_coeffs_new.begin(), tof_coeffs_new.end(), tof_coeff_);
|
|
}
|
|
|
|
|
|
|
|
|
|
double TofDiscGalReorder::totalFlux(const int cell) const
|
|
{
|
|
// Find total upstream/downstream fluxes.
|
|
double upstream_flux = 0.0;
|
|
double downstream_flux = 0.0;
|
|
for (int hface = grid_.cell_facepos[cell]; hface < grid_.cell_facepos[cell+1]; ++hface) {
|
|
const int face = grid_.cell_faces[hface];
|
|
double flux = 0.0;
|
|
if (cell == grid_.face_cells[2*face]) {
|
|
flux = darcyflux_[face];
|
|
} else {
|
|
flux = -darcyflux_[face];
|
|
}
|
|
if (flux < 0.0) {
|
|
upstream_flux += flux;
|
|
} else {
|
|
downstream_flux += flux;
|
|
}
|
|
}
|
|
// In the presence of sources, significant fluxes may be missing from the computed fluxes,
|
|
// setting the total flux to the (positive) maximum avoids this: since source is either
|
|
// inflow or outflow, not both, either upstream_flux or downstream_flux must be correct.
|
|
return std::max(-upstream_flux, downstream_flux);
|
|
}
|
|
|
|
|
|
|
|
|
|
double TofDiscGalReorder::minCornerVal(const int cell, const int face) const
|
|
{
|
|
// Evaluate the solution in all corners.
|
|
const int dim = grid_.dimensions;
|
|
const int num_basis = basis_func_->numBasisFunc();
|
|
double min_cornerval = 1e100;
|
|
for (int fnode = grid_.face_nodepos[face]; fnode < grid_.face_nodepos[face+1]; ++fnode) {
|
|
const double* nc = grid_.node_coordinates + dim*grid_.face_nodes[fnode];
|
|
basis_func_->eval(cell, nc, &basis_[0]);
|
|
const double tof_corner = std::inner_product(basis_.begin(), basis_.end(),
|
|
tof_coeff_ + num_basis*cell, 0.0);
|
|
min_cornerval = std::min(min_cornerval, tof_corner);
|
|
}
|
|
return min_cornerval;
|
|
}
|
|
|
|
|
|
|
|
void TofDiscGalReorder::applyTracerLimiter(const int cell, double* local_coeff)
|
|
{
|
|
// Evaluate the solution in all corners of all faces. Extract max and min.
|
|
const int dim = grid_.dimensions;
|
|
const int num_basis = basis_func_->numBasisFunc();
|
|
double min_cornerval = 1e100;
|
|
double max_cornerval = -1e100;
|
|
for (int hface = grid_.cell_facepos[cell]; hface < grid_.cell_facepos[cell+1]; ++hface) {
|
|
const int face = grid_.cell_faces[hface];
|
|
for (int fnode = grid_.face_nodepos[face]; fnode < grid_.face_nodepos[face+1]; ++fnode) {
|
|
const double* nc = grid_.node_coordinates + dim*grid_.face_nodes[fnode];
|
|
basis_func_->eval(cell, nc, &basis_[0]);
|
|
const double tracer_corner = std::inner_product(basis_.begin(), basis_.end(),
|
|
local_coeff, 0.0);
|
|
min_cornerval = std::min(min_cornerval, tracer_corner);
|
|
max_cornerval = std::max(min_cornerval, tracer_corner);
|
|
}
|
|
}
|
|
const double average = basis_func_->functionAverage(local_coeff);
|
|
if (average < 0.0 || average > 1.0) {
|
|
// Adjust average. Flatten gradient.
|
|
std::fill(local_coeff, local_coeff + num_basis, 0.0);
|
|
if (average > 1.0) {
|
|
basis_func_->addConstant(1.0, local_coeff);
|
|
}
|
|
} else {
|
|
// Possibly adjust gradient.
|
|
double factor = 1.0;
|
|
if (min_cornerval < 0.0) {
|
|
factor = average/(average - min_cornerval);
|
|
}
|
|
if (max_cornerval > 1.0) {
|
|
factor = std::min(factor, (1.0 - average)/(max_cornerval - average));
|
|
}
|
|
if (factor != 1.0) {
|
|
basis_func_->multiplyGradient(factor, local_coeff);
|
|
}
|
|
}
|
|
}
|
|
|
|
|
|
|
|
|
|
} // namespace Opm
|