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eigenvalues_bi.c
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eigenvalues_bi.c
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/***********************************************************************
* Copyright (C) 2002,2003,2004,2005,2006,2007,2008 Carsten Urbach
*
* This file is part of tmLQCD.
*
* tmLQCD 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.
*
* tmLQCD 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 tmLQCD. If not, see <http://www.gnu.org/licenses/>.
*
* Here we compute the nr_of_eigenvalues lowest eigenvalues
* of (gamma5*D)^2. Therefore we use the arnoldi routines.
*
* The computed eigenvalues are stored in g_eigenvalues
* and the computed eigenvectors in g_ev
*
* inout:
* nr_of_eigenvalues: input: Number of eigenvalues to compute
* output: Number of computed eigenvalues
* input:
* crylov_space_dimension: Dimension of crylov space dimension
* to be used in the arnoldi routines
*
* Autor: Thomas Chiarappa
* Thomas.Chiarappa@mib.infn.it
*
*******************************************************************************/
#ifdef HAVE_CONFIG_H
# include<config.h>
#endif
#include <stdlib.h>
#include <stdio.h>
#include <math.h>
#ifdef MPI
# include <mpi.h>
#endif
#include "global.h"
#include "su3.h"
#include "linalg_eo.h"
#include "start.h"
#include "tm_operators.h"
#include "solver/solver.h"
#include "solver/jdher_bi.h"
#include "eigenvalues_bi.h"
#include "Nondegenerate_Matrix.h"
double eigenvalues_bi(int * nr_of_eigenvalues,
const int max_iterations, const double precision,
const int maxmin) {
static bispinor * eigenvectors_bi_ = NULL;
static int allocated = 0;
static bispinor *eigenvectors_bi = NULL;
static double * eigenvls_bi = NULL;
/**********************
* For Jacobi-Davidson
**********************/
int verbosity = g_debug_level, converged = 0, blocksize = 1, blockwise = 0;
int solver_it_max = 200, j_max, j_min;
double decay_min = 1.7, decay_max = 1.5, prec,
threshold_min = 1.e-3, threshold_max = 5.e-2,
startvalue, threshold, decay, returnvalue;
int v0dim = 0;
/**********************
* General variables
**********************/
int returncode=0;
char * filename = NULL;
filename = calloc(200, sizeof(char));
/* strcpy(filename,optarg);*/
if(maxmin == JD_MINIMAL) {
startvalue = 0.;
threshold = threshold_min;
decay = decay_min;
solver_it_max = 200;
}
else {
startvalue = 50.;
threshold = threshold_max;
decay = decay_max;
solver_it_max = 50;
}
if(g_proc_id == g_stdio_proc) {
printf("Number of %s eigenvalues to compute = %d\n",
maxmin ? "maximal" : "minimal",(*nr_of_eigenvalues));
printf("Using Jacobi-Davidson method! \n");
}
if((*nr_of_eigenvalues) < 8){
j_max = 15;
j_min = 8;
}
else{
j_max = 2*(*nr_of_eigenvalues);
j_min = *nr_of_eigenvalues;
}
if(precision < 1.e-14){
prec = 1.e-14;
}
else{
prec = precision;
}
if(allocated == 0) {
allocated = 1;
#if (defined SSE || defined SSE2 || defined SSE3)
eigenvectors_bi_ = calloc((VOLUME)/2*(*nr_of_eigenvalues)+1, sizeof(bispinor));
eigenvectors_bi = (bispinor *)(((unsigned long int)(eigenvectors_bi_)+ALIGN_BASE)&~ALIGN_BASE);
#else
eigenvectors_bi_= calloc((VOLUME)/2*(*nr_of_eigenvalues), sizeof(bispinor));
eigenvectors_bi = eigenvectors_bi_;
#endif
eigenvls_bi = (double*)malloc((*nr_of_eigenvalues)*sizeof(double));
}
/* compute eigenvalues */
if((g_proc_id==0) && (g_debug_level > 4)) {
printf(" Values of mu = %e mubar = %e eps = %e precision = %e \n \n", g_mu, g_mubar, g_epsbar, precision);
}
/* here n and lda are equal, because Q_Qdagger_ND_BI does an internal */
/* conversion to non _bi fields which are subject to xchange_fields */
/* so _bi fields do not need boundary */
jdher_bi((VOLUME)/2*sizeof(bispinor)/sizeof(_Complex double), (VOLUME)/2*sizeof(bispinor)/sizeof(_Complex double),
startvalue, prec,
(*nr_of_eigenvalues), j_max, j_min,
max_iterations, blocksize, blockwise, v0dim, (_Complex double*) eigenvectors_bi,
BICGSTAB, solver_it_max,
threshold, decay, verbosity,
&converged, (_Complex double*) eigenvectors_bi, eigenvls_bi,
&returncode, maxmin, 1,
&Q_Qdagger_ND_BI);
*nr_of_eigenvalues = converged;
returnvalue = eigenvls_bi[0];
return(returnvalue);
}