Eigen/src/IterativeLinearSolvers/BiCGSTAB.h - eigen/fuchsia - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2011-2014 Gael Guennebaud <gael.guennebaud@inria.fr>
 // Copyright (C) 2012 Désiré Nuentsa-Wakam <desire.nuentsa_wakam@inria.fr>
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #ifndef EIGEN_BICGSTAB_H
 #define EIGEN_BICGSTAB_H

 namespace Eigen {

 namespace internal {

 /** \internal Low-level bi conjugate gradient stabilized algorithm
   * \param mat The matrix A
   * \param rhs The right hand side vector b
   * \param x On input and initial solution, on output the computed solution.
   * \param precond A preconditioner being able to efficiently solve for an
   *                approximation of Ax=b (regardless of b)
   * \param iters On input the max number of iteration, on output the number of performed iterations.
   * \param tol_error On input the tolerance error, on output an estimation of the relative error.
   * \return false in the case of numerical issue, for example a break down of BiCGSTAB.
   */
 template<typename MatrixType, typename Rhs, typename Dest, typename Preconditioner>
 bool bicgstab(const MatrixType& mat, const Rhs& rhs, Dest& x,
               const Preconditioner& precond, Index& iters,
               typename Dest::RealScalar& tol_error)
 {
   using std::sqrt;
   using std::abs;
   typedef typename Dest::RealScalar RealScalar;
   typedef typename Dest::Scalar Scalar;
   typedef Matrix<Scalar,Dynamic,1> VectorType;
   RealScalar tol = tol_error;
   Index maxIters = iters;

   Index n = mat.cols();
   VectorType r  = rhs - mat * x;
   VectorType r0 = r;

   RealScalar r0_sqnorm = r0.squaredNorm();
   RealScalar rhs_sqnorm = rhs.squaredNorm();
   if(rhs_sqnorm == 0)
   {
     x.setZero();
     return true;
   }
   Scalar rho    = 1;
   Scalar alpha  = 1;
   Scalar w      = 1;

   VectorType v = VectorType::Zero(n), p = VectorType::Zero(n);
   VectorType y(n),  z(n);
   VectorType kt(n), ks(n);

   VectorType s(n), t(n);

   RealScalar tol2 = tol*tol*rhs_sqnorm;
   RealScalar eps2 = NumTraits<Scalar>::epsilon()*NumTraits<Scalar>::epsilon();
   Index i = 0;
   Index restarts = 0;

   while ( r.squaredNorm() > tol2 && i<maxIters )
   {
     Scalar rho_old = rho;

     rho = r0.dot(r);
     if (abs(rho) < eps2*r0_sqnorm)
     {
       // The new residual vector became too orthogonal to the arbitrarily chosen direction r0
       // Let's restart with a new r0:
       r  = rhs - mat * x;
       r0 = r;
       rho = r0_sqnorm = r.squaredNorm();
       if(restarts++ == 0)
         i = 0;
     }
     Scalar beta = (rho/rho_old) * (alpha / w);
     p = r + beta * (p - w * v);

     y = precond.solve(p);

     v.noalias() = mat * y;

     alpha = rho / r0.dot(v);
     s = r - alpha * v;

     z = precond.solve(s);
     t.noalias() = mat * z;

     RealScalar tmp = t.squaredNorm();
     if(tmp>RealScalar(0))
       w = t.dot(s) / tmp;
     else
       w = Scalar(0);
     x += alpha * y + w * z;
     r = s - w * t;
     ++i;
   }
   tol_error = sqrt(r.squaredNorm()/rhs_sqnorm);
   iters = i;
   return true;
 }

 }

 template< typename _MatrixType,
           typename _Preconditioner = DiagonalPreconditioner<typename _MatrixType::Scalar> >
 class BiCGSTAB;

 namespace internal {

 template< typename _MatrixType, typename _Preconditioner>
 struct traits<BiCGSTAB<_MatrixType,_Preconditioner> >
 {
   typedef _MatrixType MatrixType;
   typedef _Preconditioner Preconditioner;
 };

 }

 /** \ingroup IterativeLinearSolvers_Module
   * \brief A bi conjugate gradient stabilized solver for sparse square problems
   *
   * This class allows to solve for A.x = b sparse linear problems using a bi conjugate gradient
   * stabilized algorithm. The vectors x and b can be either dense or sparse.
   *
   * \tparam _MatrixType the type of the sparse matrix A, can be a dense or a sparse matrix.
   * \tparam _Preconditioner the type of the preconditioner. Default is DiagonalPreconditioner
   *
   * \implsparsesolverconcept
   *
   * The maximal number of iterations and tolerance value can be controlled via the setMaxIterations()
   * and setTolerance() methods. The defaults are the size of the problem for the maximal number of iterations
   * and NumTraits<Scalar>::epsilon() for the tolerance.
   *
   * The tolerance corresponds to the relative residual error: |Ax-b|/|b|
   *
   * \b Performance: when using sparse matrices, best performance is achied for a row-major sparse matrix format.
   * Moreover, in this case multi-threading can be exploited if the user code is compiled with OpenMP enabled.
   * See \ref TopicMultiThreading for details.
   *
   * This class can be used as the direct solver classes. Here is a typical usage example:
   * \include BiCGSTAB_simple.cpp
   *
   * By default the iterations start with x=0 as an initial guess of the solution.
   * One can control the start using the solveWithGuess() method.
   *
   * BiCGSTAB can also be used in a matrix-free context, see the following \link MatrixfreeSolverExample example \endlink.
   *
   * \sa class SimplicialCholesky, DiagonalPreconditioner, IdentityPreconditioner
   */
 template< typename _MatrixType, typename _Preconditioner>
 class BiCGSTAB : public IterativeSolverBase<BiCGSTAB<_MatrixType,_Preconditioner> >
 {
   typedef IterativeSolverBase<BiCGSTAB> Base;
   using Base::matrix;
   using Base::m_error;
   using Base::m_iterations;
   using Base::m_info;
   using Base::m_isInitialized;
 public:
   typedef _MatrixType MatrixType;
   typedef typename MatrixType::Scalar Scalar;
   typedef typename MatrixType::RealScalar RealScalar;
   typedef _Preconditioner Preconditioner;

 public:

   /** Default constructor. */
   BiCGSTAB() : Base() {}

   /** Initialize the solver with matrix \a A for further \c Ax=b solving.
     *
     * This constructor is a shortcut for the default constructor followed
     * by a call to compute().
     *
     * \warning this class stores a reference to the matrix A as well as some
     * precomputed values that depend on it. Therefore, if \a A is changed
     * this class becomes invalid. Call compute() to update it with the new
     * matrix A, or modify a copy of A.
     */
   template<typename MatrixDerived>
   explicit BiCGSTAB(const EigenBase<MatrixDerived>& A) : Base(A.derived()) {}

   ~BiCGSTAB() {}

   /** \internal */
   template<typename Rhs,typename Dest>
   void _solve_with_guess_impl(const Rhs& b, Dest& x) const
   {
     bool failed = false;
     for(Index j=0; j<b.cols(); ++j)
     {
       m_iterations = Base::maxIterations();
       m_error = Base::m_tolerance;

       typename Dest::ColXpr xj(x,j);
       if(!internal::bicgstab(matrix(), b.col(j), xj, Base::m_preconditioner, m_iterations, m_error))
         failed = true;
     }
     m_info = failed ? NumericalIssue
            : m_error <= Base::m_tolerance ? Success
            : NoConvergence;
     m_isInitialized = true;
   }

   /** \internal */
   using Base::_solve_impl;
   template<typename Rhs,typename Dest>
   void _solve_impl(const MatrixBase<Rhs>& b, Dest& x) const
   {
     x.resize(this->rows(),b.cols());
     x.setZero();
     _solve_with_guess_impl(b,x);
   }

 protected:

 };

 } // end namespace Eigen

 #endif // EIGEN_BICGSTAB_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2011-2014 Gael Guennebaud <gael.guennebaud@inria.fr>
	// Copyright (C) 2012 Désiré Nuentsa-Wakam <desire.nuentsa_wakam@inria.fr>
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#ifndef EIGEN_BICGSTAB_H
	#define EIGEN_BICGSTAB_H

	namespace Eigen {

	namespace internal {

	/** \internal Low-level bi conjugate gradient stabilized algorithm
	* \param mat The matrix A
	* \param rhs The right hand side vector b
	* \param x On input and initial solution, on output the computed solution.
	* \param precond A preconditioner being able to efficiently solve for an
	* approximation of Ax=b (regardless of b)
	* \param iters On input the max number of iteration, on output the number of performed iterations.
	* \param tol_error On input the tolerance error, on output an estimation of the relative error.
	* \return false in the case of numerical issue, for example a break down of BiCGSTAB.
	*/
	template<typename MatrixType, typename Rhs, typename Dest, typename Preconditioner>
	bool bicgstab(const MatrixType& mat, const Rhs& rhs, Dest& x,
	const Preconditioner& precond, Index& iters,
	typename Dest::RealScalar& tol_error)
	{
	using std::sqrt;
	using std::abs;
	typedef typename Dest::RealScalar RealScalar;
	typedef typename Dest::Scalar Scalar;
	typedef Matrix<Scalar,Dynamic,1> VectorType;
	RealScalar tol = tol_error;
	Index maxIters = iters;

	Index n = mat.cols();
	VectorType r = rhs - mat * x;
	VectorType r0 = r;

	RealScalar r0_sqnorm = r0.squaredNorm();
	RealScalar rhs_sqnorm = rhs.squaredNorm();
	if(rhs_sqnorm == 0)
	{
	x.setZero();
	return true;
	}
	Scalar rho = 1;
	Scalar alpha = 1;
	Scalar w = 1;

	VectorType v = VectorType::Zero(n), p = VectorType::Zero(n);
	VectorType y(n), z(n);
	VectorType kt(n), ks(n);

	VectorType s(n), t(n);

	RealScalar tol2 = toltolrhs_sqnorm;
	RealScalar eps2 = NumTraits<Scalar>::epsilon()*NumTraits<Scalar>::epsilon();
	Index i = 0;
	Index restarts = 0;

	while ( r.squaredNorm() > tol2 && i<maxIters )
	{
	Scalar rho_old = rho;

	rho = r0.dot(r);
	if (abs(rho) < eps2*r0_sqnorm)
	{
	// The new residual vector became too orthogonal to the arbitrarily chosen direction r0
	// Let's restart with a new r0:
	r = rhs - mat * x;
	r0 = r;
	rho = r0_sqnorm = r.squaredNorm();
	if(restarts++ == 0)
	i = 0;
	}
	Scalar beta = (rho/rho_old) * (alpha / w);
	p = r + beta * (p - w * v);

	y = precond.solve(p);

	v.noalias() = mat * y;

	alpha = rho / r0.dot(v);
	s = r - alpha * v;

	z = precond.solve(s);
	t.noalias() = mat * z;

	RealScalar tmp = t.squaredNorm();
	if(tmp>RealScalar(0))
	w = t.dot(s) / tmp;
	else
	w = Scalar(0);
	x += alpha * y + w * z;
	r = s - w * t;
	++i;
	}
	tol_error = sqrt(r.squaredNorm()/rhs_sqnorm);
	iters = i;
	return true;
	}

	}

	template< typename _MatrixType,
	typename _Preconditioner = DiagonalPreconditioner<typename _MatrixType::Scalar> >
	class BiCGSTAB;

	namespace internal {

	template< typename _MatrixType, typename _Preconditioner>
	struct traits<BiCGSTAB<_MatrixType,_Preconditioner> >
	{
	typedef _MatrixType MatrixType;
	typedef _Preconditioner Preconditioner;
	};

	}

	/** \ingroup IterativeLinearSolvers_Module
	* \brief A bi conjugate gradient stabilized solver for sparse square problems
	*
	* This class allows to solve for A.x = b sparse linear problems using a bi conjugate gradient
	* stabilized algorithm. The vectors x and b can be either dense or sparse.
	*
	* \tparam _MatrixType the type of the sparse matrix A, can be a dense or a sparse matrix.
	* \tparam _Preconditioner the type of the preconditioner. Default is DiagonalPreconditioner
	*
	* \implsparsesolverconcept
	*
	* The maximal number of iterations and tolerance value can be controlled via the setMaxIterations()
	* and setTolerance() methods. The defaults are the size of the problem for the maximal number of iterations
	* and NumTraits<Scalar>::epsilon() for the tolerance.
	*
	* The tolerance corresponds to the relative residual error: \|Ax-b\|/\|b\|
	*
	* \b Performance: when using sparse matrices, best performance is achied for a row-major sparse matrix format.
	* Moreover, in this case multi-threading can be exploited if the user code is compiled with OpenMP enabled.
	* See \ref TopicMultiThreading for details.
	*
	* This class can be used as the direct solver classes. Here is a typical usage example:
	* \include BiCGSTAB_simple.cpp
	*
	* By default the iterations start with x=0 as an initial guess of the solution.
	* One can control the start using the solveWithGuess() method.
	*
	* BiCGSTAB can also be used in a matrix-free context, see the following \link MatrixfreeSolverExample example \endlink.
	*
	* \sa class SimplicialCholesky, DiagonalPreconditioner, IdentityPreconditioner
	*/
	template< typename _MatrixType, typename _Preconditioner>
	class BiCGSTAB : public IterativeSolverBase<BiCGSTAB<_MatrixType,_Preconditioner> >
	{
	typedef IterativeSolverBase<BiCGSTAB> Base;
	using Base::matrix;
	using Base::m_error;
	using Base::m_iterations;
	using Base::m_info;
	using Base::m_isInitialized;
	public:
	typedef _MatrixType MatrixType;
	typedef typename MatrixType::Scalar Scalar;
	typedef typename MatrixType::RealScalar RealScalar;
	typedef _Preconditioner Preconditioner;

	public:

	/** Default constructor. */
	BiCGSTAB() : Base() {}

	/** Initialize the solver with matrix \a A for further \c Ax=b solving.
	*
	* This constructor is a shortcut for the default constructor followed
	* by a call to compute().
	*
	* \warning this class stores a reference to the matrix A as well as some
	* precomputed values that depend on it. Therefore, if \a A is changed
	* this class becomes invalid. Call compute() to update it with the new
	* matrix A, or modify a copy of A.
	*/
	template<typename MatrixDerived>
	explicit BiCGSTAB(const EigenBase<MatrixDerived>& A) : Base(A.derived()) {}

	~BiCGSTAB() {}

	/** \internal */
	template<typename Rhs,typename Dest>
	void _solve_with_guess_impl(const Rhs& b, Dest& x) const
	{
	bool failed = false;
	for(Index j=0; j<b.cols(); ++j)
	{
	m_iterations = Base::maxIterations();
	m_error = Base::m_tolerance;

	typename Dest::ColXpr xj(x,j);
	if(!internal::bicgstab(matrix(), b.col(j), xj, Base::m_preconditioner, m_iterations, m_error))
	failed = true;
	}
	m_info = failed ? NumericalIssue
	: m_error <= Base::m_tolerance ? Success
	: NoConvergence;
	m_isInitialized = true;
	}

	/** \internal */
	using Base::_solve_impl;
	template<typename Rhs,typename Dest>
	void _solve_impl(const MatrixBase<Rhs>& b, Dest& x) const
	{
	x.resize(this->rows(),b.cols());
	x.setZero();
	_solve_with_guess_impl(b,x);
	}

	protected:

	};

	} // end namespace Eigen

	#endif // EIGEN_BICGSTAB_H