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#ifndef ROCALUTION_KRYLOV_IDR_HPP_
#define ROCALUTION_KRYLOV_IDR_HPP_

#include "../solver.hpp"
#include "rocalution/export.hpp"

#include <vector>

namespace rocalution
{

    /** \ingroup solver_module
  * \class IDR
  * \brief Induced Dimension Reduction Method
  * \details
  * The Induced Dimension Reduction method is a Krylov subspace method for solving
  * sparse (non) symmetric linear systems \f$Ax=b\f$. IDR(s) generates residuals in a
  * sequence of nested subspaces.
  * \cite IDR1
  * \cite IDR2
  *
  * The dimension of the shadow space can be set by SetShadowSpace(). The default size
  * of the shadow space is 4.
  *
  * \tparam OperatorType - can be LocalMatrix, GlobalMatrix or LocalStencil
  * \tparam VectorType - can be LocalVector or GlobalVector
  * \tparam ValueType - can be float, double, std::complex<float> or std::complex<double>
  */
    template <class OperatorType, class VectorType, typename ValueType>
    class IDR : public IterativeLinearSolver<OperatorType, VectorType, ValueType>
    {
    public:
        ROCALUTION_EXPORT
        IDR();
        ROCALUTION_EXPORT
        virtual ~IDR();

        ROCALUTION_EXPORT
        virtual void Print(void) const;

        ROCALUTION_EXPORT
        virtual void Build(void);
        ROCALUTION_EXPORT
        virtual void ReBuildNumeric(void);
        ROCALUTION_EXPORT
        virtual void Clear(void);

        /** \brief Set the size of the Shadow Space */
        ROCALUTION_EXPORT
        void SetShadowSpace(int s);
        /** \brief Set random seed for ONB creation (seed must be greater than 0) */
        ROCALUTION_EXPORT
        void SetRandomSeed(unsigned long long seed);

    protected:
        virtual void SolveNonPrecond_(const VectorType& rhs, VectorType* x);
        virtual void SolvePrecond_(const VectorType& rhs, VectorType* x);

        virtual void PrintStart_(void) const;
        virtual void PrintEnd_(void) const;

        virtual void MoveToHostLocalData_(void);
        virtual void MoveToAcceleratorLocalData_(void);

    private:
        int                s_;
        unsigned long long seed_;

        ValueType kappa_;

        ValueType* c_;
        ValueType* f_;
        ValueType* M_;

        VectorType r_;
        VectorType v_;
        VectorType t_;

        VectorType** G_;
        VectorType** U_;
        VectorType** P_;
    };

} // namespace rocalution

#endif // ROCALUTION_KRYLOV_IDR_HPP_