libopm-simulators/html/SolverAdapter_8hpp_source.html

/*

  Copyright 2022-2023 SINTEF AS


  This file is part of the Open Porous Media project (OPM).


  OPM is free software: you can redistribute it and/or modify

  it under the terms of the GNU General Public License as published by

  the Free Software Foundation, either version 3 of the License, or

  (at your option) any later version.


  OPM is distributed in the hope that it will be useful,

  but WITHOUT ANY WARRANTY; without even the implied warranty of

  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the

  GNU General Public License for more details.


  You should have received a copy of the GNU General Public License

  along with OPM.  If not, see <http://www.gnu.org/licenses/>.

*/

#ifndef OPM_SOLVERADAPTER_HPP

#define OPM_SOLVERADAPTER_HPP


#include <dune/istl/bcrsmatrix.hh>

#include <dune/istl/operators.hh>

#include <dune/istl/paamg/pinfo.hh>

#include <dune/istl/schwarz.hh>

#include <dune/istl/solver.hh>


#include <opm/common/ErrorMacros.hpp>


#include <opm/simulators/linalg/gpuistl/GpuBlockPreconditioner.hpp>

#include <opm/simulators/linalg/gpuistl/GpuSparseMatrixWrapper.hpp>

#include <opm/simulators/linalg/gpuistl/GpuVector.hpp>

#include <opm/simulators/linalg/gpuistl/PreconditionerAdapter.hpp>

#include <opm/simulators/linalg/gpuistl/detail/has_function.hpp>


#if HAVE_MPI

#include <opm/simulators/linalg/gpuistl/GpuOwnerOverlapCopy.hpp>

#endif


#include <memory>


namespace Opm::gpuistl

{

template <class Operator, template <class> class UnderlyingSolver, class X>


class SolverAdapter : public Dune::IterativeSolver<X, X>

{

public:

    using typename Dune::IterativeSolver<X, X>::domain_type;

    using typename Dune::IterativeSolver<X, X>::range_type;

    using typename Dune::IterativeSolver<X, X>::field_type;

    using typename Dune::IterativeSolver<X, X>::real_type;

    using typename Dune::IterativeSolver<X, X>::scalar_real_type;

    static constexpr auto block_size = domain_type::block_type::dimension;

    using XGPU = Opm::gpuistl::GpuVector<real_type>;


    template<class Comm>


    SolverAdapter(Operator& op,

                  Dune::ScalarProduct<X>& sp,

                  std::shared_ptr<Dune::Preconditioner<X, X>> prec,

                  scalar_real_type reduction,

                  int maxit,

                  int verbose,

                  const Comm& comm)

        : Dune::IterativeSolver<X, X>(op, sp, *prec, reduction, maxit, verbose)

        , m_opOnCPUWithMatrix(op)

        , m_matrix(GpuSparseMatrixWrapper<real_type>::fromMatrix(op.getmat()))

        , m_underlyingSolver(constructSolver(prec, reduction, maxit, verbose, comm))

    {

        OPM_ERROR_IF(

            detail::is_a_well_operator<Operator>::value,

            "Currently we only support operators of type MatrixAdapter in the CUDA/HIP solver. "

            "Use --matrix-add-well-contributions=true. "

            "Using WellModelMatrixAdapter with SolverAdapter is not well-defined so it will not work well, or at all.");

    }


    virtual void apply(X& x, X& b, double reduction, Dune::InverseOperatorResult& res) override

    {

        // TODO: Can we do this without reimplementing the other function?

        // TODO: [perf] Do we need to update the matrix every time? Probably yes

        m_matrix.updateNonzeroValues(m_opOnCPUWithMatrix.getmat(), true);


        if (!m_inputBuffer) {

            m_inputBuffer.reset(new XGPU(b.dim()));

            m_outputBuffer.reset(new XGPU(x.dim()));

        }


        m_inputBuffer->copyFromHost(b);

        // TODO: [perf] do we need to copy x here?

        m_outputBuffer->copyFromHost(x);


        m_underlyingSolver.apply(*m_outputBuffer, *m_inputBuffer, reduction, res);


        // TODO: [perf] do we need to copy b here?

        m_inputBuffer->copyToHost(b);

        m_outputBuffer->copyToHost(x);

    }

    virtual void apply(X& x, X& b, Dune::InverseOperatorResult& res) override

    {

        // TODO: [perf] Do we need to update the matrix every time? Probably yes

        m_matrix.updateNonzeroValues(m_opOnCPUWithMatrix.getmat(), true);


        if (!m_inputBuffer) {

            m_inputBuffer.reset(new XGPU(b.dim()));

            m_outputBuffer.reset(new XGPU(x.dim()));

        }


        m_inputBuffer->copyFromHost(b);

        // TODO: [perf] do we need to copy x here?

        m_outputBuffer->copyFromHost(x);


        m_underlyingSolver.apply(*m_outputBuffer, *m_inputBuffer, res);


        // TODO: [perf] do we need to copy b here?

        m_inputBuffer->copyToHost(b);

        m_outputBuffer->copyToHost(x);

    }


private:

    Operator& m_opOnCPUWithMatrix;

    GpuSparseMatrixWrapper<real_type> m_matrix;


    UnderlyingSolver<XGPU> m_underlyingSolver;


    // TODO: Use a std::forward

    // This is the MPI parallel case (general communication object)

#if HAVE_MPI

    template <class Comm>

    UnderlyingSolver<XGPU> constructSolver(std::shared_ptr<Dune::Preconditioner<X, X>> prec,

                                           scalar_real_type reduction,

                                           int maxit,

                                           int verbose,

                                           const Comm& communication)

    {

        // TODO: See the below TODO over the definition of precHolder in the other overload of constructSolver

        // TODO: We are currently double wrapping preconditioners in the preconditioner factory to be extra

        //       compatible with CPU. Probably a cleaner way eventually would be to do more modifications to the

        //       flexible solver to accomodate the pure GPU better.

        auto precAsHolder = std::dynamic_pointer_cast<PreconditionerHolder<X, X>>(prec);

        if (!precAsHolder) {

            OPM_THROW(std::invalid_argument,

                      "The preconditioner needs to be a CUDA preconditioner (eg. GPUDILU) wrapped in a "

                      "Opm::gpuistl::PreconditionerAdapter wrapped in a "

                      "Opm::gpuistl::GpuBlockPreconditioner. If you are unsure what this means, set "

                      "preconditioner to 'gpudilu'");

        }


        auto preconditionerAdapter = precAsHolder->getUnderlyingPreconditioner();

        auto preconditionerAdapterAsHolder

            = std::dynamic_pointer_cast<PreconditionerHolder<XGPU, XGPU>>(preconditionerAdapter);

        if (!preconditionerAdapterAsHolder) {

            OPM_THROW(std::invalid_argument,

                      "The preconditioner needs to be a CUDA preconditioner (eg. GPUDILU) wrapped in a "

                      "Opm::gpuistl::PreconditionerAdapter wrapped in a "

                      "Opm::gpuistl::GpuBlockPreconditioner. If you are unsure what this means, set "

                      "preconditioner to 'gpudilu'");

        }

        // We need to get the underlying preconditioner:

        auto preconditionerReallyOnGPU = preconditionerAdapterAsHolder->getUnderlyingPreconditioner();


        using CudaCommunication = GpuOwnerOverlapCopy<real_type, Comm>;

        using SchwarzOperator

            = Dune::OverlappingSchwarzOperator<GpuSparseMatrixWrapper<real_type>, XGPU, XGPU, CudaCommunication>;

        auto cudaCommunication = makeGpuOwnerOverlapCopy<real_type, block_size, Comm>(communication);


        auto mpiPreconditioner = std::make_shared<GpuBlockPreconditioner<XGPU, XGPU, CudaCommunication>>(

            preconditionerReallyOnGPU, cudaCommunication);


        auto scalarProduct = std::make_shared<Dune::ParallelScalarProduct<XGPU, CudaCommunication>>(

            cudaCommunication, m_opOnCPUWithMatrix.category());


        // NOTE: Ownership of cudaCommunication is handled by mpiPreconditioner. However, just to make sure we

        //       remember this, we add this check. So remember that we hold one count in this scope, and one in the

        //       GpuBlockPreconditioner instance. We accommodate for the fact that it could be passed around in

        //       GpuBlockPreconditioner, hence we do not test for != 2

        OPM_ERROR_IF(cudaCommunication.use_count() < 2, "Internal error. Shared pointer not owned properly.");

        auto overlappingCudaOperator = std::make_shared<SchwarzOperator>(m_matrix, *cudaCommunication);


        return UnderlyingSolver<XGPU>(

            overlappingCudaOperator, scalarProduct, mpiPreconditioner, reduction, maxit, verbose);

    }

#endif


    // This is the serial case (specific overload for Dune::Amg::SequentialInformation)

    UnderlyingSolver<XGPU> constructSolver(std::shared_ptr<Dune::Preconditioner<X, X>> prec,

                                           scalar_real_type reduction,

                                           int maxit,

                                           int verbose,

                                           [[maybe_unused]] const Dune::Amg::SequentialInformation& communication)

    {

        // Dune::Amg::SequentialInformation is the serial case

        return constructSolver(prec, reduction, maxit, verbose);

    }


    // TODO: Use a std::forward

    UnderlyingSolver<XGPU> constructSolver(std::shared_ptr<Dune::Preconditioner<X, X>> prec,

                                           scalar_real_type reduction,

                                           int maxit,

                                           int verbose)

    {

        // TODO: Fix the reliance on casting here. This is a code smell to a certain degree, and assumes

        //       a certain setup beforehand. The only reason we do it this way is to minimize edits to the

        //       flexible solver. We could design it differently, but keep this for the time being until

        //       we figure out how we want to GPU-ify the rest of the system.

        auto precAsHolder = std::dynamic_pointer_cast<PreconditionerHolder<XGPU, XGPU>>(prec);

        if (!precAsHolder) {

            OPM_THROW(std::invalid_argument,

                      "The preconditioner needs to be a CUDA preconditioner wrapped in a "

                      "Opm::gpuistl::PreconditionerHolder (eg. GPUDILU).");

        }

        auto preconditionerOnGPU = precAsHolder->getUnderlyingPreconditioner();


        auto matrixOperator = std::make_shared<Dune::MatrixAdapter<GpuSparseMatrixWrapper<real_type>, XGPU, XGPU>>(m_matrix);

        auto scalarProduct = std::make_shared<Dune::SeqScalarProduct<XGPU>>();

        return UnderlyingSolver<XGPU>(matrixOperator, scalarProduct, preconditionerOnGPU, reduction, maxit, verbose);

    }


    std::unique_ptr<XGPU> m_inputBuffer;

    std::unique_ptr<XGPU> m_outputBuffer;

};


} // namespace Opm::gpuistl


#endif

Opm::gpuistl::GpuSparseMatrixWrapper
The GpuSparseMatrixWrapper Checks CUDA/HIP version and dispatches a version either using the old or t...
Definition GpuSparseMatrixWrapper.hpp:61

Opm::gpuistl::GpuSparseMatrixWrapper::updateNonzeroValues
void updateNonzeroValues(const MatrixType &matrix, bool copyNonZeroElementsDirectly=false)
updateNonzeroValues updates the non-zero values by using the non-zero values of the supplied matrix
Definition GpuSparseMatrixWrapper.hpp:374

Opm::gpuistl::GpuVector
Definition gpu_type_detection.hpp:30

Opm::gpuistl::SolverAdapter::SolverAdapter
SolverAdapter(Operator &op, Dune::ScalarProduct< X > &sp, std::shared_ptr< Dune::Preconditioner< X, X > > prec, scalar_real_type reduction, int maxit, int verbose, const Comm &comm)
constructor
Definition SolverAdapter.hpp:75