ginkgo-hpc/html/fcg_8hpp_source.html

// SPDX-FileCopyrightText: 2017 - 2025 The Ginkgo authors

//

// SPDX-License-Identifier: BSD-3-Clause


#ifndef GKO_PUBLIC_CORE_SOLVER_FCG_HPP_

#define GKO_PUBLIC_CORE_SOLVER_FCG_HPP_


#include <vector>


#include <ginkgo/core/base/array.hpp>

#include <ginkgo/core/base/exception_helpers.hpp>

#include <ginkgo/core/base/lin_op.hpp>

#include <ginkgo/core/base/math.hpp>

#include <ginkgo/core/base/types.hpp>

#include <ginkgo/core/config/config.hpp>

#include <ginkgo/core/config/registry.hpp>

#include <ginkgo/core/log/logger.hpp>

#include <ginkgo/core/matrix/dense.hpp>

#include <ginkgo/core/matrix/identity.hpp>

#include <ginkgo/core/solver/solver_base.hpp>

#include <ginkgo/core/stop/combined.hpp>

#include <ginkgo/core/stop/criterion.hpp>


namespace gko {

namespace solver {


template <typename ValueType = default_precision>


class Fcg

    : public EnableLinOp<Fcg<ValueType>>,

      public EnablePreconditionedIterativeSolver<ValueType, Fcg<ValueType>>,

      public Transposable {

    friend class EnableLinOp<Fcg>;

    friend class EnablePolymorphicObject<Fcg, LinOp>;

    GKO_ASSERT_SUPPORTED_VALUE_TYPE;


public:

    using value_type = ValueType;

    using transposed_type = Fcg<ValueType>;


    std::unique_ptr<LinOp> transpose() const override;


    std::unique_ptr<LinOp> conj_transpose() const override;


    bool apply_uses_initial_guess() const override { return true; }


    class Factory;


    struct parameters_type

        : enable_preconditioned_iterative_solver_factory_parameters<

              parameters_type, Factory> {};


    GKO_ENABLE_LIN_OP_FACTORY(Fcg, parameters, Factory);

    GKO_ENABLE_BUILD_METHOD(Factory);


    static parameters_type parse(const config::pnode& config,

                                 const config::registry& context,

                                 const config::type_descriptor& td_for_child =

                                     config::make_type_descriptor<ValueType>());


protected:

    void apply_impl(const LinOp* b, LinOp* x) const override;


    template <typename VectorType>

    void apply_dense_impl(const VectorType* b, VectorType* x) const;


    void apply_impl(const LinOp* alpha, const LinOp* b, const LinOp* beta,

                    LinOp* x) const override;


    explicit Fcg(std::shared_ptr<const Executor> exec)

        : EnableLinOp<Fcg>(std::move(exec))

    {}


    explicit Fcg(const Factory* factory,

                 std::shared_ptr<const LinOp> system_matrix)

        : EnableLinOp<Fcg>(factory->get_executor(),

                           gko::transpose(system_matrix->get_size())),

          EnablePreconditionedIterativeSolver<ValueType, Fcg<ValueType>>{

              std::move(system_matrix), factory->get_parameters()},

          parameters_{factory->get_parameters()}

    {}

};


template <typename ValueType>


struct workspace_traits<Fcg<ValueType>> {

    using Solver = Fcg<ValueType>;

    // number of vectors used by this workspace

    static int num_vectors(const Solver&);

    // number of arrays used by this workspace

    static int num_arrays(const Solver&);

    // array containing the num_vectors names for the workspace vectors

    static std::vector<std::string> op_names(const Solver&);

    // array containing the num_arrays names for the workspace vectors

    static std::vector<std::string> array_names(const Solver&);

    // array containing all varying scalar vectors (independent of problem size)

    static std::vector<int> scalars(const Solver&);

    // array containing all varying vectors (dependent on problem size)

    static std::vector<int> vectors(const Solver&);


    // residual vector

    constexpr static int r = 0;

    // preconditioned residual vector

    constexpr static int z = 1;

    // p vector

    constexpr static int p = 2;

    // q vector

    constexpr static int q = 3;

    // t vector

    constexpr static int t = 4;

    // beta scalar

    constexpr static int beta = 5;

    // previous rho scalar

    constexpr static int prev_rho = 6;

    // current rho scalar

    constexpr static int rho = 7;

    // current rho_t scalar

    constexpr static int rho_t = 8;

    // constant 1.0 scalar

    constexpr static int one = 9;

    // constant -1.0 scalar

    constexpr static int minus_one = 10;


    // stopping status array

    constexpr static int stop = 0;

    // reduction tmp array

    constexpr static int tmp = 1;

};


}  // namespace solver

}  // namespace gko


#endif  // GKO_PUBLIC_CORE_SOLVER_FCG_HPP_

gko::EnableLinOp
The EnableLinOp mixin can be used to provide sensible default implementations of the majority of the ...
Definition lin_op.hpp:879

gko::EnablePolymorphicObject
This mixin inherits from (a subclass of) PolymorphicObject and provides a base implementation of a ne...
Definition polymorphic_object.hpp:668

gko::LinOp
Definition lin_op.hpp:117

gko::Transposable
Linear operators which support transposition should implement the Transposable interface.
Definition lin_op.hpp:433

gko::config::pnode
pnode describes a tree of properties.
Definition property_tree.hpp:28

gko::config::registry
This class stores additional context for creating Ginkgo objects from configuration files.
Definition registry.hpp:167

gko::config::type_descriptor
This class describes the value and index types to be used when building a Ginkgo type from a configur...
Definition type_descriptor.hpp:39

gko::solver::EnablePreconditionedIterativeSolver
A LinOp implementing this interface stores a system matrix and stopping criterion factory.
Definition solver_base.hpp:802

gko::solver::Factory
Definition ir.hpp:184

gko::solver::Fcg
FCG or the flexible conjugate gradient method is an iterative type Krylov subspace method which is su...
Definition fcg.hpp:55

gko::solver::Fcg::transpose
std::unique_ptr< LinOp > transpose() const override
Returns a LinOp representing the transpose of the Transposable object.

gko::solver::Fcg::conj_transpose
std::unique_ptr< LinOp > conj_transpose() const override
Returns a LinOp representing the conjugate transpose of the Transposable object.

gko::solver::Fcg::parse
static parameters_type parse(const config::pnode &config, const config::registry &context, const config::type_descriptor &td_for_child=config::make_type_descriptor< ValueType >())
Create the parameters from the property_tree.

gko::solver::Fcg::apply_uses_initial_guess
bool apply_uses_initial_guess() const override
Return true as iterative solvers use the data in x as an initial guess.
Definition fcg.hpp:73

GKO_ENABLE_BUILD_METHOD
#define GKO_ENABLE_BUILD_METHOD(_factory_name)
Defines a build method for the factory, simplifying its construction by removing the repetitive typin...
Definition abstract_factory.hpp:394

GKO_ENABLE_LIN_OP_FACTORY
#define GKO_ENABLE_LIN_OP_FACTORY(_lin_op, _parameters_name, _factory_name)
This macro will generate a default implementation of a LinOpFactory for the LinOp subclass it is defi...
Definition lin_op.hpp:1017

gko::solver
The ginkgo Solve namespace.
Definition bicg.hpp:28

gko
The Ginkgo namespace.
Definition abstract_factory.hpp:20

gko::transpose
batch_dim< 2, DimensionType > transpose(const batch_dim< 2, DimensionType > &input)
Returns a batch_dim object with its dimensions swapped for batched operators.
Definition batch_dim.hpp:119

std
STL namespace.

gko::solver::Fcg::parameters_type
Definition fcg.hpp:79

gko::solver::enable_preconditioned_iterative_solver_factory_parameters
Definition solver_base.hpp:855

gko::solver::workspace_traits
Traits class providing information on the type and location of workspace vectors inside a solver.
Definition solver_base.hpp:238