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MINRES, bug #715: add support for zero rhs, and remove square test.
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giacomo po
parent
dead9085c0
commit
3e42b775ea
@ -37,22 +37,31 @@ namespace Eigen {
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typedef typename Dest::Scalar Scalar;
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typedef Matrix<Scalar,Dynamic,1> VectorType;
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// Check for zero rhs
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const RealScalar rhsNorm2(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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// initialize
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const int maxIters(iters); // initialize maxIters to iters
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const int N(mat.cols()); // the size of the matrix
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const RealScalar rhsNorm2(rhs.squaredNorm());
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const RealScalar threshold2(tol_error*tol_error*rhsNorm2); // convergence threshold (compared to residualNorm2)
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// Initialize preconditioned Lanczos
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// VectorType v_old(N); // will be initialized inside loop
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VectorType v_old(N); // will be initialized inside loop
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VectorType v( VectorType::Zero(N) ); //initialize v
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VectorType v_new(rhs-mat*x); //initialize v_new
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RealScalar residualNorm2(v_new.squaredNorm());
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// VectorType w(N); // will be initialized inside loop
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VectorType w(N); // will be initialized inside loop
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VectorType w_new(precond.solve(v_new)); // initialize w_new
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// RealScalar beta; // will be initialized inside loop
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RealScalar beta_new2(v_new.dot(w_new));
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eigen_assert(beta_new2 >= 0 && "PRECONDITIONER IS NOT POSITIVE DEFINITE");
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eigen_assert(beta_new2 >= 0.0 && "PRECONDITIONER IS NOT POSITIVE DEFINITE");
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RealScalar beta_new(sqrt(beta_new2));
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const RealScalar beta_one(beta_new);
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v_new /= beta_new;
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@ -62,14 +71,14 @@ namespace Eigen {
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RealScalar c_old(1.0);
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RealScalar s(0.0); // the sine of the Givens rotation
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RealScalar s_old(0.0); // the sine of the Givens rotation
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// VectorType p_oold(N); // will be initialized in loop
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VectorType p_oold(N); // will be initialized in loop
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VectorType p_old(VectorType::Zero(N)); // initialize p_old=0
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VectorType p(p_old); // initialize p=0
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RealScalar eta(1.0);
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iters = 0; // reset iters
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while ( iters < maxIters ){
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while ( iters < maxIters )
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{
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// Preconditioned Lanczos
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/* Note that there are 4 variants on the Lanczos algorithm. These are
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* described in Paige, C. C. (1972). Computational variants of
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@ -81,17 +90,17 @@ namespace Eigen {
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* A. Greenbaum, Iterative Methods for Solving Linear Systems, SIAM (1987).
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*/
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const RealScalar beta(beta_new);
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// v_old = v; // update: at first time step, this makes v_old = 0 so value of beta doesn't matter
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const VectorType v_old(v); // NOT SURE IF CREATING v_old EVERY ITERATION IS EFFICIENT
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v_old = v; // update: at first time step, this makes v_old = 0 so value of beta doesn't matter
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// const VectorType v_old(v); // NOT SURE IF CREATING v_old EVERY ITERATION IS EFFICIENT
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v = v_new; // update
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// w = w_new; // update
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const VectorType w(w_new); // NOT SURE IF CREATING w EVERY ITERATION IS EFFICIENT
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w = w_new; // update
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// const VectorType w(w_new); // NOT SURE IF CREATING w EVERY ITERATION IS EFFICIENT
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v_new.noalias() = mat*w - beta*v_old; // compute v_new
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const RealScalar alpha = v_new.dot(w);
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v_new -= alpha*v; // overwrite v_new
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w_new = precond.solve(v_new); // overwrite w_new
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beta_new2 = v_new.dot(w_new); // compute beta_new
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eigen_assert(beta_new2 >= 0 && "PRECONDITIONER IS NOT POSITIVE DEFINITE");
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eigen_assert(beta_new2 >= 0.0 && "PRECONDITIONER IS NOT POSITIVE DEFINITE");
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beta_new = sqrt(beta_new2); // compute beta_new
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v_new /= beta_new; // overwrite v_new for next iteration
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w_new /= beta_new; // overwrite w_new for next iteration
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@ -107,28 +116,34 @@ namespace Eigen {
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s=beta_new/r1; // new sine
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// Update solution
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// p_oold = p_old;
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const VectorType p_oold(p_old); // NOT SURE IF CREATING p_oold EVERY ITERATION IS EFFICIENT
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p_oold = p_old;
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// const VectorType p_oold(p_old); // NOT SURE IF CREATING p_oold EVERY ITERATION IS EFFICIENT
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p_old = p;
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p.noalias()=(w-r2*p_old-r3*p_oold) /r1; // IS NOALIAS REQUIRED?
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x += beta_one*c*eta*p;
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/* Update the squared residual. Note that this is the estimated residual.
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The real residual |Ax-b|^2 may be slightly larger */
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residualNorm2 *= s*s;
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if ( residualNorm2 < threshold2){
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if ( residualNorm2 < threshold2)
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{
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break;
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}
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eta=-s*eta; // update eta
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iters++; // increment iteration number (for output purposes)
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}
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tol_error = std::sqrt(residualNorm2 / rhsNorm2); // return error. Note that this is the estimated error. The real error |Ax-b|/|b| may be slightly larger
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/* Compute error. Note that this is the estimated error. The real
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error |Ax-b|/|b| may be slightly larger */
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tol_error = std::sqrt(residualNorm2 / rhsNorm2);
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}
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}
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template< typename _MatrixType, int _UpLo=Lower,
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typename _Preconditioner = IdentityPreconditioner>
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// typename _Preconditioner = IdentityPreconditioner<typename _MatrixType::Scalar> > // preconditioner must be positive definite
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class MINRES;
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namespace internal {
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@ -1,8 +1,8 @@
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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) 2011 Gael Guennebaud <g.gael@free.fr>
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// Copyright (C) 2012 Giacomo Po <gpo@ucla.edu>
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// Copyright (C) 2011 Gael Guennebaud <g.gael@free.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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@ -14,19 +14,29 @@
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template<typename T> void test_minres_T()
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{
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MINRES<SparseMatrix<T>, Lower, DiagonalPreconditioner<T> > minres_colmajor_diag;
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MINRES<SparseMatrix<T>, Lower, IdentityPreconditioner > minres_colmajor_I;
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// MINRES<SparseMatrix<T>, Lower, IncompleteLUT<T> > minres_colmajor_ilut;
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//minres<SparseMatrix<T>, SSORPreconditioner<T> > minres_colmajor_ssor;
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// Identity preconditioner
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MINRES<SparseMatrix<T>, Lower, IdentityPreconditioner > minres_colmajor_lower_I;
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MINRES<SparseMatrix<T>, Upper, IdentityPreconditioner > minres_colmajor_upper_I;
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// Diagonal preconditioner
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MINRES<SparseMatrix<T>, Lower, DiagonalPreconditioner<T> > minres_colmajor_lower_diag;
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MINRES<SparseMatrix<T>, Upper, DiagonalPreconditioner<T> > minres_colmajor_upper_diag;
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// call tests for SPD matrix
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CALL_SUBTEST( check_sparse_spd_solving(minres_colmajor_lower_I) );
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CALL_SUBTEST( check_sparse_spd_solving(minres_colmajor_upper_I) );
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CALL_SUBTEST( check_sparse_spd_solving(minres_colmajor_lower_diag) );
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CALL_SUBTEST( check_sparse_spd_solving(minres_colmajor_upper_diag) );
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// TO DO: symmetric semi-definite matrix
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// TO DO: symmetric indefinite matrix
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CALL_SUBTEST( check_sparse_square_solving(minres_colmajor_diag) );
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CALL_SUBTEST( check_sparse_spd_solving(minres_colmajor_I) );
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// CALL_SUBTEST( check_sparse_square_solving(minres_colmajor_ilut) );
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//CALL_SUBTEST( check_sparse_square_solving(minres_colmajor_ssor) );
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}
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void test_minres()
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{
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CALL_SUBTEST_1(test_minres_T<double>());
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// CALL_SUBTEST_2(test_minres_T<std::complex<double> >());
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// CALL_SUBTEST_2(test_minres_T<std::compex<double> >());
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}
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