| /* | |
| Copyright (c) 2011, Intel Corporation. All rights reserved. | |
| Copyright (C) 2011-2016 Gael Guennebaud <gael.guennebaud@inria.fr> | |
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| are permitted provided that the following conditions are met: | |
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| ******************************************************************************** | |
| * Content : Documentation on the use of BLAS/LAPACK libraries through Eigen | |
| ******************************************************************************** | |
| */ | |
| namespace Eigen { | |
| /** \page TopicUsingBlasLapack Using BLAS/LAPACK from %Eigen | |
| Since %Eigen version 3.3 and later, any F77 compatible BLAS or LAPACK libraries can be used as backends for dense matrix products and dense matrix decompositions. | |
| For instance, one can use <a href="http://eigen.tuxfamily.org/Counter/redirect_to_mkl.php">Intel® MKL</a>, Apple's Accelerate framework on OSX, <a href="http://www.openblas.net/">OpenBLAS</a>, <a href="http://www.netlib.org/lapack">Netlib LAPACK</a>, etc. | |
| Do not miss this \link TopicUsingIntelMKL page \endlink for further discussions on the specific use of Intel® MKL (also includes VML, PARDISO, etc.) | |
| In order to use an external BLAS and/or LAPACK library, you must link you own application to the respective libraries and their dependencies. | |
| For LAPACK, you must also link to the standard <a href="http://www.netlib.org/lapack/lapacke.html">Lapacke</a> library, which is used as a convenient think layer between %Eigen's C++ code and LAPACK F77 interface. Then you must activate their usage by defining one or multiple of the following macros (\b before including any %Eigen's header): | |
| \note For Mac users, in order to use the lapack version shipped with the Accelerate framework, you also need the lapacke library. | |
| Using <a href="https://www.macports.org/">MacPorts</a>, this is as easy as: | |
| \code | |
| sudo port install lapack | |
| \endcode | |
| and then use the following link flags: \c -framework \c Accelerate \c /opt/local/lib/lapack/liblapacke.dylib | |
| <table class="manual"> | |
| <tr><td>\c EIGEN_USE_BLAS </td><td>Enables the use of external BLAS level 2 and 3 routines (compatible with any F77 BLAS interface)</td></tr> | |
| <tr class="alt"><td>\c EIGEN_USE_LAPACKE </td><td>Enables the use of external Lapack routines via the <a href="http://www.netlib.org/lapack/lapacke.html">Lapacke</a> C interface to Lapack (compatible with any F77 LAPACK interface)</td></tr> | |
| <tr><td>\c EIGEN_USE_LAPACKE_STRICT </td><td>Same as \c EIGEN_USE_LAPACKE but algorithms of lower numerical robustness are disabled. \n This currently concerns only JacobiSVD which otherwise would be replaced by \c gesvd that is less robust than Jacobi rotations.</td></tr> | |
| </table> | |
| When doing so, a number of %Eigen's algorithms are silently substituted with calls to BLAS or LAPACK routines. | |
| These substitutions apply only for \b Dynamic \b or \b large enough objects with one of the following four standard scalar types: \c float, \c double, \c complex<float>, and \c complex<double>. | |
| Operations on other scalar types or mixing reals and complexes will continue to use the built-in algorithms. | |
| The breadth of %Eigen functionality that can be substituted is listed in the table below. | |
| <table class="manual"> | |
| <tr><th>Functional domain</th><th>Code example</th><th>BLAS/LAPACK routines</th></tr> | |
| <tr><td>Matrix-matrix operations \n \c EIGEN_USE_BLAS </td><td>\code | |
| m1*m2.transpose(); | |
| m1.selfadjointView<Lower>()*m2; | |
| m1*m2.triangularView<Upper>(); | |
| m1.selfadjointView<Lower>().rankUpdate(m2,1.0); | |
| \endcode</td><td>\code | |
| ?gemm | |
| ?symm/?hemm | |
| ?trmm | |
| dsyrk/ssyrk | |
| \endcode</td></tr> | |
| <tr class="alt"><td>Matrix-vector operations \n \c EIGEN_USE_BLAS </td><td>\code | |
| m1.adjoint()*b; | |
| m1.selfadjointView<Lower>()*b; | |
| m1.triangularView<Upper>()*b; | |
| \endcode</td><td>\code | |
| ?gemv | |
| ?symv/?hemv | |
| ?trmv | |
| \endcode</td></tr> | |
| <tr><td>LU decomposition \n \c EIGEN_USE_LAPACKE \n \c EIGEN_USE_LAPACKE_STRICT </td><td>\code | |
| v1 = m1.lu().solve(v2); | |
| \endcode</td><td>\code | |
| ?getrf | |
| \endcode</td></tr> | |
| <tr class="alt"><td>Cholesky decomposition \n \c EIGEN_USE_LAPACKE \n \c EIGEN_USE_LAPACKE_STRICT </td><td>\code | |
| v1 = m2.selfadjointView<Upper>().llt().solve(v2); | |
| \endcode</td><td>\code | |
| ?potrf | |
| \endcode</td></tr> | |
| <tr><td>QR decomposition \n \c EIGEN_USE_LAPACKE \n \c EIGEN_USE_LAPACKE_STRICT </td><td>\code | |
| m1.householderQr(); | |
| m1.colPivHouseholderQr(); | |
| \endcode</td><td>\code | |
| ?geqrf | |
| ?geqp3 | |
| \endcode</td></tr> | |
| <tr class="alt"><td>Singular value decomposition \n \c EIGEN_USE_LAPACKE </td><td>\code | |
| JacobiSVD<MatrixXd> svd; | |
| svd.compute(m1, ComputeThinV); | |
| \endcode</td><td>\code | |
| ?gesvd | |
| \endcode</td></tr> | |
| <tr><td>Eigen-value decompositions \n \c EIGEN_USE_LAPACKE \n \c EIGEN_USE_LAPACKE_STRICT </td><td>\code | |
| EigenSolver<MatrixXd> es(m1); | |
| ComplexEigenSolver<MatrixXcd> ces(m1); | |
| SelfAdjointEigenSolver<MatrixXd> saes(m1+m1.transpose()); | |
| GeneralizedSelfAdjointEigenSolver<MatrixXd> | |
| gsaes(m1+m1.transpose(),m2+m2.transpose()); | |
| \endcode</td><td>\code | |
| ?gees | |
| ?gees | |
| ?syev/?heev | |
| ?syev/?heev, | |
| ?potrf | |
| \endcode</td></tr> | |
| <tr class="alt"><td>Schur decomposition \n \c EIGEN_USE_LAPACKE \n \c EIGEN_USE_LAPACKE_STRICT </td><td>\code | |
| RealSchur<MatrixXd> schurR(m1); | |
| ComplexSchur<MatrixXcd> schurC(m1); | |
| \endcode</td><td>\code | |
| ?gees | |
| \endcode</td></tr> | |
| </table> | |
| In the examples, m1 and m2 are dense matrices and v1 and v2 are dense vectors. | |
| */ | |
| } | |