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synced 2026-04-10 11:34:33 +08:00
Add a CG-based solver for rectangular least-square problems (bug #975).
This commit is contained in:
@@ -17,9 +17,9 @@ namespace Eigen {
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*
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* This class allows to approximately solve for A.x = b problems assuming A is a diagonal matrix.
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* In other words, this preconditioner neglects all off diagonal entries and, in Eigen's language, solves for:
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* \code
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* A.diagonal().asDiagonal() . x = b
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* \endcode
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\code
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A.diagonal().asDiagonal() . x = b
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\endcode
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*
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* \tparam _Scalar the type of the scalar.
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*
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@@ -28,6 +28,7 @@ namespace Eigen {
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*
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* \note A variant that has yet to be implemented would attempt to preserve the norm of each column.
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*
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* \sa class LeastSquareDiagonalPreconditioner, class ConjugateGradient
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*/
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template <typename _Scalar>
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class DiagonalPreconditioner
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@@ -100,6 +101,69 @@ class DiagonalPreconditioner
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bool m_isInitialized;
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};
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/** \ingroup IterativeLinearSolvers_Module
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* \brief Jacobi preconditioner for LSCG
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*
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* This class allows to approximately solve for A' A x = A' b problems assuming A' A is a diagonal matrix.
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* In other words, this preconditioner neglects all off diagonal entries and, in Eigen's language, solves for:
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\code
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(A.adjoint() * A).diagonal().asDiagonal() * x = b
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\endcode
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*
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* \tparam _Scalar the type of the scalar.
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*
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* The diagonal entries are pre-inverted and stored into a dense vector.
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*
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* \sa class LSCG, class DiagonalPreconditioner
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*/
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template <typename _Scalar>
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class LeastSquareDiagonalPreconditioner : public DiagonalPreconditioner<_Scalar>
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{
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typedef _Scalar Scalar;
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typedef typename NumTraits<Scalar>::Real RealScalar;
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typedef DiagonalPreconditioner<_Scalar> Base;
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using Base::m_invdiag;
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public:
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LeastSquareDiagonalPreconditioner() : Base() {}
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template<typename MatType>
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explicit LeastSquareDiagonalPreconditioner(const MatType& mat) : Base()
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{
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compute(mat);
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}
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template<typename MatType>
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LeastSquareDiagonalPreconditioner& analyzePattern(const MatType& )
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{
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return *this;
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}
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template<typename MatType>
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LeastSquareDiagonalPreconditioner& factorize(const MatType& mat)
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{
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// Compute the inverse squared-norm of each column of mat
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m_invdiag.resize(mat.cols());
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for(Index j=0; j<mat.outerSize(); ++j)
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{
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RealScalar sum = mat.innerVector(j).squaredNorm();
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if(sum>0)
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m_invdiag(j) = RealScalar(1)/sum;
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else
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m_invdiag(j) = RealScalar(1);
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}
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Base::m_isInitialized = true;
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return *this;
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}
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template<typename MatType>
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LeastSquareDiagonalPreconditioner& compute(const MatType& mat)
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{
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return factorize(mat);
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}
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protected:
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};
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/** \ingroup IterativeLinearSolvers_Module
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* \brief A naive preconditioner which approximates any matrix as the identity matrix
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@@ -60,29 +60,29 @@ void conjugate_gradient(const MatrixType& mat, const Rhs& rhs, Dest& x,
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}
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VectorType p(n);
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p = precond.solve(residual); //initial search direction
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p = precond.solve(residual); // initial search direction
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VectorType z(n), tmp(n);
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RealScalar absNew = numext::real(residual.dot(p)); // the square of the absolute value of r scaled by invM
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Index i = 0;
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while(i < maxIters)
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{
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tmp.noalias() = mat * p; // the bottleneck of the algorithm
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tmp.noalias() = mat * p; // the bottleneck of the algorithm
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Scalar alpha = absNew / p.dot(tmp); // the amount we travel on dir
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x += alpha * p; // update solution
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residual -= alpha * tmp; // update residue
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Scalar alpha = absNew / p.dot(tmp); // the amount we travel on dir
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x += alpha * p; // update solution
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residual -= alpha * tmp; // update residual
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residualNorm2 = residual.squaredNorm();
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if(residualNorm2 < threshold)
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break;
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z = precond.solve(residual); // approximately solve for "A z = residual"
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z = precond.solve(residual); // approximately solve for "A z = residual"
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RealScalar absOld = absNew;
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absNew = numext::real(residual.dot(z)); // update the absolute value of r
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RealScalar beta = absNew / absOld; // calculate the Gram-Schmidt value used to create the new search direction
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p = z + beta * p; // update search direction
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RealScalar beta = absNew / absOld; // calculate the Gram-Schmidt value used to create the new search direction
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p = z + beta * p; // update search direction
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i++;
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}
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tol_error = sqrt(residualNorm2 / rhsNorm2);
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@@ -122,24 +122,24 @@ struct traits<ConjugateGradient<_MatrixType,_UpLo,_Preconditioner> >
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* and NumTraits<Scalar>::epsilon() for the tolerance.
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*
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* This class can be used as the direct solver classes. Here is a typical usage example:
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* \code
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* int n = 10000;
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* VectorXd x(n), b(n);
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* SparseMatrix<double> A(n,n);
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* // fill A and b
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* ConjugateGradient<SparseMatrix<double> > cg;
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* cg.compute(A);
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* x = cg.solve(b);
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* std::cout << "#iterations: " << cg.iterations() << std::endl;
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* std::cout << "estimated error: " << cg.error() << std::endl;
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* // update b, and solve again
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* x = cg.solve(b);
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* \endcode
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\code
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int n = 10000;
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VectorXd x(n), b(n);
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SparseMatrix<double> A(n,n);
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// fill A and b
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ConjugateGradient<SparseMatrix<double> > cg;
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cg.compute(A);
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x = cg.solve(b);
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std::cout << "#iterations: " << cg.iterations() << std::endl;
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std::cout << "estimated error: " << cg.error() << std::endl;
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// update b, and solve again
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x = cg.solve(b);
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\endcode
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*
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* By default the iterations start with x=0 as an initial guess of the solution.
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* One can control the start using the solveWithGuess() method.
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*
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* \sa class SimplicialCholesky, DiagonalPreconditioner, IdentityPreconditioner
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* \sa class LSCG, class SimplicialCholesky, DiagonalPreconditioner, IdentityPreconditioner
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*/
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template< typename _MatrixType, int _UpLo, typename _Preconditioner>
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class ConjugateGradient : public IterativeSolverBase<ConjugateGradient<_MatrixType,_UpLo,_Preconditioner> >
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213
Eigen/src/IterativeLinearSolvers/LeastSquareConjugateGradient.h
Normal file
213
Eigen/src/IterativeLinearSolvers/LeastSquareConjugateGradient.h
Normal file
@@ -0,0 +1,213 @@
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// This file is part of Eigen, a lightweight C++ template library
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// for linear algebra.
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//
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// Copyright (C) 2015 Gael Guennebaud <gael.guennebaud@inria.fr>
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//
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// This Source Code Form is subject to the terms of the Mozilla
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// Public License v. 2.0. If a copy of the MPL was not distributed
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// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.
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#ifndef EIGEN_LEAST_SQUARE_CONJUGATE_GRADIENT_H
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#define EIGEN_LEAST_SQUARE_CONJUGATE_GRADIENT_H
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namespace Eigen {
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namespace internal {
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/** \internal Low-level conjugate gradient algorithm for least-square problems
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* \param mat The matrix A
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* \param rhs The right hand side vector b
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* \param x On input and initial solution, on output the computed solution.
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* \param precond A preconditioner being able to efficiently solve for an
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* approximation of A'Ax=b (regardless of b)
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* \param iters On input the max number of iteration, on output the number of performed iterations.
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* \param tol_error On input the tolerance error, on output an estimation of the relative error.
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*/
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template<typename MatrixType, typename Rhs, typename Dest, typename Preconditioner>
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EIGEN_DONT_INLINE
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void least_square_conjugate_gradient(const MatrixType& mat, const Rhs& rhs, Dest& x,
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const Preconditioner& precond, Index& iters,
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typename Dest::RealScalar& tol_error)
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{
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using std::sqrt;
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using std::abs;
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typedef typename Dest::RealScalar RealScalar;
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typedef typename Dest::Scalar Scalar;
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typedef Matrix<Scalar,Dynamic,1> VectorType;
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RealScalar tol = tol_error;
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Index maxIters = iters;
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Index m = mat.rows(), n = mat.cols();
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VectorType residual = rhs - mat * x;
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VectorType normal_residual = mat.adjoint() * residual;
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RealScalar rhsNorm2 = (mat.adjoint()*rhs).squaredNorm();
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if(rhsNorm2 == 0)
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{
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x.setZero();
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iters = 0;
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tol_error = 0;
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return;
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}
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RealScalar threshold = tol*tol*rhsNorm2;
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RealScalar residualNorm2 = normal_residual.squaredNorm();
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if (residualNorm2 < threshold)
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{
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iters = 0;
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tol_error = sqrt(residualNorm2 / rhsNorm2);
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return;
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}
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VectorType p(n);
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p = precond.solve(normal_residual); // initial search direction
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VectorType z(n), tmp(m);
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RealScalar absNew = numext::real(normal_residual.dot(p)); // the square of the absolute value of r scaled by invM
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Index i = 0;
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while(i < maxIters)
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{
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tmp.noalias() = mat * p;
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Scalar alpha = absNew / tmp.squaredNorm(); // the amount we travel on dir
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x += alpha * p; // update solution
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residual -= alpha * tmp; // update residual
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normal_residual = mat.adjoint() * residual; // update residual of the normal equation
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residualNorm2 = normal_residual.squaredNorm();
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if(residualNorm2 < threshold)
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break;
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z = precond.solve(normal_residual); // approximately solve for "A'A z = normal_residual"
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RealScalar absOld = absNew;
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absNew = numext::real(normal_residual.dot(z)); // update the absolute value of r
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RealScalar beta = absNew / absOld; // calculate the Gram-Schmidt value used to create the new search direction
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p = z + beta * p; // update search direction
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i++;
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}
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tol_error = sqrt(residualNorm2 / rhsNorm2);
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iters = i;
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}
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}
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template< typename _MatrixType,
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typename _Preconditioner = LeastSquareDiagonalPreconditioner<typename _MatrixType::Scalar> >
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class LSCG;
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namespace internal {
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template< typename _MatrixType, typename _Preconditioner>
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struct traits<LSCG<_MatrixType,_Preconditioner> >
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{
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typedef _MatrixType MatrixType;
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typedef _Preconditioner Preconditioner;
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};
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}
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/** \ingroup IterativeLinearSolvers_Module
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* \brief A conjugate gradient solver for sparse (or dense) least-square problems
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*
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* This class allows to solve for A x = b linear problems using an iterative conjugate gradient algorithm.
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* The matrix A can be non symmetric and rectangular, but the matrix A' A should be positive-definite to guaranty stability.
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* Otherwise, the SparseLU or SparseQR classes might be preferable.
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* The matrix A and the vectors x and b can be either dense or sparse.
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*
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* \tparam _MatrixType the type of the matrix A, can be a dense or a sparse matrix.
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* \tparam _Preconditioner the type of the preconditioner. Default is LeastSquareDiagonalPreconditioner
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*
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* The maximal number of iterations and tolerance value can be controlled via the setMaxIterations()
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* and setTolerance() methods. The defaults are the size of the problem for the maximal number of iterations
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* and NumTraits<Scalar>::epsilon() for the tolerance.
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*
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* This class can be used as the direct solver classes. Here is a typical usage example:
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\code
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int m=1000000, n = 10000;
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VectorXd x(n), b(m);
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SparseMatrix<double> A(m,n);
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// fill A and b
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LSCG<SparseMatrix<double> > lscg;
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lscg.compute(A);
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x = lscg.solve(b);
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std::cout << "#iterations: " << lscg.iterations() << std::endl;
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std::cout << "estimated error: " << lscg.error() << std::endl;
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// update b, and solve again
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x = lscg.solve(b);
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\endcode
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*
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* By default the iterations start with x=0 as an initial guess of the solution.
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* One can control the start using the solveWithGuess() method.
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*
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* \sa class ConjugateGradient, SparseLU, SparseQR
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*/
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template< typename _MatrixType, typename _Preconditioner>
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class LSCG : public IterativeSolverBase<LSCG<_MatrixType,_Preconditioner> >
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{
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typedef IterativeSolverBase<LSCG> Base;
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using Base::mp_matrix;
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using Base::m_error;
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using Base::m_iterations;
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using Base::m_info;
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using Base::m_isInitialized;
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public:
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typedef _MatrixType MatrixType;
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typedef typename MatrixType::Scalar Scalar;
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typedef typename MatrixType::RealScalar RealScalar;
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typedef _Preconditioner Preconditioner;
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public:
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/** Default constructor. */
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LSCG() : Base() {}
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/** Initialize the solver with matrix \a A for further \c Ax=b solving.
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*
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* This constructor is a shortcut for the default constructor followed
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* by a call to compute().
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*
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* \warning this class stores a reference to the matrix A as well as some
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* precomputed values that depend on it. Therefore, if \a A is changed
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* this class becomes invalid. Call compute() to update it with the new
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* matrix A, or modify a copy of A.
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*/
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explicit LSCG(const MatrixType& A) : Base(A) {}
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~LSCG() {}
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/** \internal */
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template<typename Rhs,typename Dest>
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void _solve_with_guess_impl(const Rhs& b, Dest& x) const
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{
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m_iterations = Base::maxIterations();
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m_error = Base::m_tolerance;
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for(Index j=0; j<b.cols(); ++j)
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{
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m_iterations = Base::maxIterations();
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m_error = Base::m_tolerance;
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typename Dest::ColXpr xj(x,j);
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internal::least_square_conjugate_gradient(mp_matrix, b.col(j), xj, Base::m_preconditioner, m_iterations, m_error);
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}
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m_isInitialized = true;
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m_info = m_error <= Base::m_tolerance ? Success : NoConvergence;
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}
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/** \internal */
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using Base::_solve_impl;
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template<typename Rhs,typename Dest>
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void _solve_impl(const MatrixBase<Rhs>& b, Dest& x) const
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{
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x.setZero();
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_solve_with_guess_impl(b.derived(),x);
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}
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};
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} // end namespace Eigen
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#endif // EIGEN_LEAST_SQUARE_CONJUGATE_GRADIENT_H
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