doc/examples/matrixfree_cg.cpp - eigen - Git at Google

 #include <iostream>
 #include <Eigen/Core>
 #include <Eigen/Dense>
 #include <Eigen/IterativeLinearSolvers>
 #include <unsupported/Eigen/IterativeSolvers>

 class MatrixReplacement;
 using Eigen::SparseMatrix;

 namespace Eigen {
 namespace internal {
   // MatrixReplacement looks-like a SparseMatrix, so let's inherits its traits:
   template<>
   struct traits<MatrixReplacement> :  public Eigen::internal::traits<Eigen::SparseMatrix<double> >
   {};
 }
 }

 // Example of a matrix-free wrapper from a user type to Eigen's compatible type
 // For the sake of simplicity, this example simply wrap a Eigen::SparseMatrix.
 class MatrixReplacement : public Eigen::EigenBase<MatrixReplacement> {
 public:
   // Required typedefs, constants, and method:
   typedef double Scalar;
   typedef double RealScalar;
   typedef int StorageIndex;
   enum {
     ColsAtCompileTime = Eigen::Dynamic,
     MaxColsAtCompileTime = Eigen::Dynamic,
     IsRowMajor = false
   };

   Index rows() const { return mp_mat->rows(); }
   Index cols() const { return mp_mat->cols(); }

   template<typename Rhs>
   Eigen::Product<MatrixReplacement,Rhs,Eigen::AliasFreeProduct> operator*(const Eigen::MatrixBase<Rhs>& x) const {
     return Eigen::Product<MatrixReplacement,Rhs,Eigen::AliasFreeProduct>(*this, x.derived());
   }

   // Custom API:
   MatrixReplacement() : mp_mat(0) {}

   void attachMyMatrix(const SparseMatrix<double> &mat) {
     mp_mat = &mat;
   }
   const SparseMatrix<double> my_matrix() const { return *mp_mat; }

 private:
   const SparseMatrix<double> *mp_mat;
 };


 // Implementation of MatrixReplacement * Eigen::DenseVector though a specialization of internal::generic_product_impl:
 namespace Eigen {
 namespace internal {

   template<typename Rhs>
   struct generic_product_impl<MatrixReplacement, Rhs, SparseShape, DenseShape, GemvProduct> // GEMV stands for matrix-vector
   : generic_product_impl_base<MatrixReplacement,Rhs,generic_product_impl<MatrixReplacement,Rhs> >
   {
     typedef typename Product<MatrixReplacement,Rhs>::Scalar Scalar;

     template<typename Dest>
     static void scaleAndAddTo(Dest& dst, const MatrixReplacement& lhs, const Rhs& rhs, const Scalar& alpha)
     {
       // This method should implement "dst += alpha * lhs * rhs" inplace,
       // however, for iterative solvers, alpha is always equal to 1, so let's not bother about it.
       assert(alpha==Scalar(1) && "scaling is not implemented");
       EIGEN_ONLY_USED_FOR_DEBUG(alpha);

       // Here we could simply call dst.noalias() += lhs.my_matrix() * rhs,
       // but let's do something fancier (and less efficient):
       for(Index i=0; i<lhs.cols(); ++i)
         dst += rhs(i) * lhs.my_matrix().col(i);
     }
   };

 }
 }

 int main()
 {
   int n = 10;
   Eigen::SparseMatrix<double> S = Eigen::MatrixXd::Random(n,n).sparseView(0.5,1);
   S = S.transpose()*S;

   MatrixReplacement A;
   A.attachMyMatrix(S);

   Eigen::VectorXd b(n), x;
   b.setRandom();

   // Solve Ax = b using various iterative solver with matrix-free version:
   {
     Eigen::ConjugateGradient<MatrixReplacement, Eigen::Lower|Eigen::Upper, Eigen::IdentityPreconditioner> cg;
     cg.compute(A);
     x = cg.solve(b);
     std::cout << "CG:       #iterations: " << cg.iterations() << ", estimated error: " << cg.error() << std::endl;
   }

   {
     Eigen::BiCGSTAB<MatrixReplacement, Eigen::IdentityPreconditioner> bicg;
     bicg.compute(A);
     x = bicg.solve(b);
     std::cout << "BiCGSTAB: #iterations: " << bicg.iterations() << ", estimated error: " << bicg.error() << std::endl;
   }

   {
     Eigen::GMRES<MatrixReplacement, Eigen::IdentityPreconditioner> gmres;
     gmres.compute(A);
     x = gmres.solve(b);
     std::cout << "GMRES:    #iterations: " << gmres.iterations() << ", estimated error: " << gmres.error() << std::endl;
   }

   {
     Eigen::DGMRES<MatrixReplacement, Eigen::IdentityPreconditioner> gmres;
     gmres.compute(A);
     x = gmres.solve(b);
     std::cout << "DGMRES:   #iterations: " << gmres.iterations() << ", estimated error: " << gmres.error() << std::endl;
   }

   {
     Eigen::MINRES<MatrixReplacement, Eigen::Lower|Eigen::Upper, Eigen::IdentityPreconditioner> minres;
     minres.compute(A);
     x = minres.solve(b);
     std::cout << "MINRES:   #iterations: " << minres.iterations() << ", estimated error: " << minres.error() << std::endl;
   }
 }
	#include <iostream>
	#include <Eigen/Core>
	#include <Eigen/Dense>
	#include <Eigen/IterativeLinearSolvers>
	#include <unsupported/Eigen/IterativeSolvers>

	class MatrixReplacement;
	using Eigen::SparseMatrix;

	namespace Eigen {
	namespace internal {
	// MatrixReplacement looks-like a SparseMatrix, so let's inherits its traits:
	template<>
	struct traits<MatrixReplacement> : public Eigen::internal::traits<Eigen::SparseMatrix<double> >
	{};
	}
	}

	// Example of a matrix-free wrapper from a user type to Eigen's compatible type
	// For the sake of simplicity, this example simply wrap a Eigen::SparseMatrix.
	class MatrixReplacement : public Eigen::EigenBase<MatrixReplacement> {
	public:
	// Required typedefs, constants, and method:
	typedef double Scalar;
	typedef double RealScalar;
	typedef int StorageIndex;
	enum {
	ColsAtCompileTime = Eigen::Dynamic,
	MaxColsAtCompileTime = Eigen::Dynamic,
	IsRowMajor = false
	};

	Index rows() const { return mp_mat->rows(); }
	Index cols() const { return mp_mat->cols(); }

	template<typename Rhs>
	Eigen::Product<MatrixReplacement,Rhs,Eigen::AliasFreeProduct> operator*(const Eigen::MatrixBase<Rhs>& x) const {
	return Eigen::Product<MatrixReplacement,Rhs,Eigen::AliasFreeProduct>(*this, x.derived());
	}

	// Custom API:
	MatrixReplacement() : mp_mat(0) {}

	void attachMyMatrix(const SparseMatrix<double> &mat) {
	mp_mat = &mat;
	}
	const SparseMatrix<double> my_matrix() const { return *mp_mat; }

	private:
	const SparseMatrix<double> *mp_mat;
	};


	// Implementation of MatrixReplacement * Eigen::DenseVector though a specialization of internal::generic_product_impl:
	namespace Eigen {
	namespace internal {

	template<typename Rhs>
	struct generic_product_impl<MatrixReplacement, Rhs, SparseShape, DenseShape, GemvProduct> // GEMV stands for matrix-vector
	: generic_product_impl_base<MatrixReplacement,Rhs,generic_product_impl<MatrixReplacement,Rhs> >
	{
	typedef typename Product<MatrixReplacement,Rhs>::Scalar Scalar;

	template<typename Dest>
	static void scaleAndAddTo(Dest& dst, const MatrixReplacement& lhs, const Rhs& rhs, const Scalar& alpha)
	{
	// This method should implement "dst += alpha * lhs * rhs" inplace,
	// however, for iterative solvers, alpha is always equal to 1, so let's not bother about it.
	assert(alpha==Scalar(1) && "scaling is not implemented");
	EIGEN_ONLY_USED_FOR_DEBUG(alpha);

	// Here we could simply call dst.noalias() += lhs.my_matrix() * rhs,
	// but let's do something fancier (and less efficient):
	for(Index i=0; i<lhs.cols(); ++i)
	dst += rhs(i) * lhs.my_matrix().col(i);
	}
	};

	}
	}

	int main()
	{
	int n = 10;
	Eigen::SparseMatrix<double> S = Eigen::MatrixXd::Random(n,n).sparseView(0.5,1);
	S = S.transpose()*S;

	MatrixReplacement A;
	A.attachMyMatrix(S);

	Eigen::VectorXd b(n), x;
	b.setRandom();

	// Solve Ax = b using various iterative solver with matrix-free version:
	{
	Eigen::ConjugateGradient<MatrixReplacement, Eigen::Lower\|Eigen::Upper, Eigen::IdentityPreconditioner> cg;
	cg.compute(A);
	x = cg.solve(b);
	std::cout << "CG: #iterations: " << cg.iterations() << ", estimated error: " << cg.error() << std::endl;
	}

	{
	Eigen::BiCGSTAB<MatrixReplacement, Eigen::IdentityPreconditioner> bicg;
	bicg.compute(A);
	x = bicg.solve(b);
	std::cout << "BiCGSTAB: #iterations: " << bicg.iterations() << ", estimated error: " << bicg.error() << std::endl;
	}

	{
	Eigen::GMRES<MatrixReplacement, Eigen::IdentityPreconditioner> gmres;
	gmres.compute(A);
	x = gmres.solve(b);
	std::cout << "GMRES: #iterations: " << gmres.iterations() << ", estimated error: " << gmres.error() << std::endl;
	}

	{
	Eigen::DGMRES<MatrixReplacement, Eigen::IdentityPreconditioner> gmres;
	gmres.compute(A);
	x = gmres.solve(b);
	std::cout << "DGMRES: #iterations: " << gmres.iterations() << ", estimated error: " << gmres.error() << std::endl;
	}

	{
	Eigen::MINRES<MatrixReplacement, Eigen::Lower\|Eigen::Upper, Eigen::IdentityPreconditioner> minres;
	minres.compute(A);
	x = minres.solve(b);
	std::cout << "MINRES: #iterations: " << minres.iterations() << ", estimated error: " << minres.error() << std::endl;
	}
	}