genhermv.c

来自「math library from gnu」· C语言代码 · 共 204 行

204 行

/* eigen/genhermv.c *  * Copyright (C) 2007 Patrick Alken *  * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or (at * your option) any later version. *  * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU * General Public License for more details. *  * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */#include <stdlib.h>#include <config.h>#include <gsl/gsl_eigen.h>#include <gsl/gsl_linalg.h>#include <gsl/gsl_math.h>#include <gsl/gsl_blas.h>#include <gsl/gsl_vector.h>#include <gsl/gsl_matrix.h>#include <gsl/gsl_complex.h>#include <gsl/gsl_complex_math.h>/* * This module computes the eigenvalues and eigenvectors of a complex * generalized hermitian-definite eigensystem A x = \lambda B x, where * A and B are hermitian, and B is positive-definite. */static void genhermv_normalize_eigenvectors(gsl_matrix_complex *evec);/*gsl_eigen_genhermv_alloc()Allocate a workspace for solving the generalized hermitian-definiteeigenvalue problem. The size of this workspace is O(5n).Inputs: n - size of matricesReturn: pointer to workspace*/gsl_eigen_genhermv_workspace *gsl_eigen_genhermv_alloc(const size_t n){  gsl_eigen_genhermv_workspace *w;  if (n == 0)    {      GSL_ERROR_NULL ("matrix dimension must be positive integer",                      GSL_EINVAL);    }  w = (gsl_eigen_genhermv_workspace *) calloc (1, sizeof (gsl_eigen_genhermv_workspace));  if (w == 0)    {      GSL_ERROR_NULL ("failed to allocate space for workspace", GSL_ENOMEM);    }  w->size = n;  w->hermv_workspace_p = gsl_eigen_hermv_alloc(n);  if (!w->hermv_workspace_p)    {      gsl_eigen_genhermv_free(w);      GSL_ERROR_NULL("failed to allocate space for hermv workspace", GSL_ENOMEM);    }  return (w);} /* gsl_eigen_genhermv_alloc() *//*gsl_eigen_genhermv_free()  Free workspace w*/voidgsl_eigen_genhermv_free (gsl_eigen_genhermv_workspace * w){  if (w->hermv_workspace_p)    gsl_eigen_hermv_free(w->hermv_workspace_p);  free(w);} /* gsl_eigen_genhermv_free() *//*gsl_eigen_genhermv()Solve the generalized hermitian-definite eigenvalue problemA x = \lambda B xfor the eigenvalues \lambda and eigenvectors x.Inputs: A    - complex hermitian matrix        B    - complex hermitian and positive definite matrix        eval - where to store eigenvalues        evec - where to store eigenvectors        w    - workspaceReturn: success or error*/intgsl_eigen_genhermv (gsl_matrix_complex * A, gsl_matrix_complex * B,                    gsl_vector * eval, gsl_matrix_complex * evec,                    gsl_eigen_genhermv_workspace * w){  const size_t N = A->size1;  /* check matrix and vector sizes */  if (N != A->size2)    {      GSL_ERROR ("matrix must be square to compute eigenvalues", GSL_ENOTSQR);    }  else if ((N != B->size1) || (N != B->size2))    {      GSL_ERROR ("B matrix dimensions must match A", GSL_EBADLEN);    }  else if (eval->size != N)    {      GSL_ERROR ("eigenvalue vector must match matrix size", GSL_EBADLEN);    }  else if (evec->size1 != evec->size2)    {      GSL_ERROR ("eigenvector matrix must be square", GSL_ENOTSQR);    }  else if (evec->size1 != N)    {      GSL_ERROR ("eigenvector matrix has wrong size", GSL_EBADLEN);    }  else if (w->size != N)    {      GSL_ERROR ("matrix size does not match workspace", GSL_EBADLEN);    }  else    {      int s;      /* compute Cholesky factorization of B */      s = gsl_linalg_complex_cholesky_decomp(B);      if (s != GSL_SUCCESS)        return s; /* B is not positive definite */      /* transform to standard hermitian eigenvalue problem */      gsl_eigen_genherm_standardize(A, B);      /* compute eigenvalues and eigenvectors */      s = gsl_eigen_hermv(A, eval, evec, w->hermv_workspace_p);      if (s != GSL_SUCCESS)        return s;      /* backtransform eigenvectors: evec -> L^{-H} evec */      gsl_blas_ztrsm(CblasLeft,                     CblasLower,                     CblasConjTrans,                     CblasNonUnit,                     GSL_COMPLEX_ONE,                     B,                     evec);      /* the blas call destroyed the normalization - renormalize */      genhermv_normalize_eigenvectors(evec);      return GSL_SUCCESS;    }} /* gsl_eigen_genhermv() *//******************************************** *           INTERNAL ROUTINES              * ********************************************//*genhermv_normalize_eigenvectors()  Normalize eigenvectors so that their Euclidean norm is 1Inputs: evec - eigenvectors*/static voidgenhermv_normalize_eigenvectors(gsl_matrix_complex *evec){  const size_t N = evec->size1;  size_t i;     /* looping */  for (i = 0; i < N; ++i)    {      gsl_vector_complex_view vi = gsl_matrix_complex_column(evec, i);      double scale = 1.0 / gsl_blas_dznrm2(&vi.vector);      gsl_blas_zdscal(scale, &vi.vector);    }} /* genhermv_normalize_eigenvectors() */

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