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detratio_monomial.c
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detratio_monomial.c
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/***********************************************************************
*
* Copyright (C) 1008 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/>.
***********************************************************************/
#ifdef HAVE_CONFIG_H
# include<config.h>
#endif
#include <stdlib.h>
#include <stdio.h>
#include <math.h>
#include <time.h>
#include "global.h"
#include "su3.h"
#include "su3adj.h"
#include "su3spinor.h"
#include "ranlxd.h"
#include "start.h"
#include "linalg_eo.h"
#include "linsolve.h"
#include "deriv_Sb.h"
#include "deriv_Sb_D_psi.h"
#include "gamma.h"
#include "tm_operators.h"
#include "hybrid_update.h"
#include "Hopping_Matrix.h"
#include "solver/chrono_guess.h"
#include "solver/bicgstab_complex.h"
#include "solver/solver.h"
#include "read_input.h"
#include "smearing/stout.h"
#include "clover_leaf.h"
#include "monomial.h"
#include "boundary.h"
#include "detratio_monomial.h"
extern int ITER_MAX_BCG;
extern int ITER_MAX_CG;
/* think about chronological solver ! */
void detratio_derivative(const int no, hamiltonian_field_t * const hf) {
int saveiter = ITER_MAX_BCG;
monomial * mnl = &monomial_list[no];
mnl->forcefactor = 1.;
if(mnl->even_odd_flag) {
/*
* this is being run in case there is even/odd preconditioning
*/
/*********************************************************************
*
* This term is det((Q^2 + \mu_1^2)/(Q^2 + \mu_2^2))
* mu1 and mu2 are set according to the monomial
*
*********************************************************************/
/* First term coming from the second field */
/* Multiply with W_+ */
g_mu = mnl->mu2;
boundary(mnl->kappa2);
if(mnl->solver != CG) {
fprintf(stderr, "Bicgstab currently not implemented, using CG instead! (detratio_monomial.c)\n");
}
Qtm_plus_psi(g_spinor_field[DUM_DERI+2], mnl->pf);
g_mu = mnl->mu;
boundary(mnl->kappa);
/* Invert Q_{+} Q_{-} */
/* X_W -> DUM_DERI+1 */
chrono_guess(g_spinor_field[DUM_DERI+1], g_spinor_field[DUM_DERI+2], mnl->csg_field,
mnl->csg_index_array, mnl->csg_N, mnl->csg_n, VOLUME/2, &Qtm_pm_psi);
mnl->iter1 += cg_her(g_spinor_field[DUM_DERI+1], g_spinor_field[DUM_DERI+2], mnl->maxiter,
mnl->forceprec, g_relative_precision_flag, VOLUME/2, &Qtm_pm_psi);
chrono_add_solution(g_spinor_field[DUM_DERI+1], mnl->csg_field, mnl->csg_index_array,
mnl->csg_N, &mnl->csg_n, VOLUME/2);
/* Y_W -> DUM_DERI */
Qtm_minus_psi(g_spinor_field[DUM_DERI], g_spinor_field[DUM_DERI+1]);
/* apply Hopping Matrix M_{eo} */
/* to get the even sites of X */
H_eo_tm_inv_psi(g_spinor_field[DUM_DERI+2], g_spinor_field[DUM_DERI+1], EO, -1.);
/* \delta Q sandwitched by Y_o^\dagger and X_e */
deriv_Sb(OE, g_spinor_field[DUM_DERI], g_spinor_field[DUM_DERI+2], hf, mnl->forcefactor);
/* to get the even sites of Y */
H_eo_tm_inv_psi(g_spinor_field[DUM_DERI+3], g_spinor_field[DUM_DERI], EO, +1);
/* \delta Q sandwitched by Y_e^\dagger and X_o */
deriv_Sb(EO, g_spinor_field[DUM_DERI+3], g_spinor_field[DUM_DERI+1], hf, mnl->forcefactor);
g_mu = mnl->mu2;
boundary(mnl->kappa2);
/* Second term coming from the second field */
/* The sign is opposite!! */
mul_r(g_spinor_field[DUM_DERI], -1., mnl->pf, VOLUME/2);
/* apply Hopping Matrix M_{eo} */
/* to get the even sites of X */
H_eo_tm_inv_psi(g_spinor_field[DUM_DERI+2], g_spinor_field[DUM_DERI+1], EO, -1.);
/* \delta Q sandwitched by Y_o^\dagger and X_e */
deriv_Sb(OE, g_spinor_field[DUM_DERI], g_spinor_field[DUM_DERI+2], hf, mnl->forcefactor);
/* to get the even sites of Y */
H_eo_tm_inv_psi(g_spinor_field[DUM_DERI+3], g_spinor_field[DUM_DERI], EO, +1);
/* \delta Q sandwitched by Y_e^\dagger and X_o */
deriv_Sb(EO, g_spinor_field[DUM_DERI+3], g_spinor_field[DUM_DERI+1], hf, mnl->forcefactor);
}
else { /* no even/odd preconditioning */
/*********************************************************************
*
* This term is det((Q^2 + \mu_1^2)/(Q^2 + \mu_2^2))
* mu1 and mu2 are set according to the monomial
*
*********************************************************************/
/* First term coming from the second field */
/* Multiply with W_+ */
g_mu = mnl->mu2;
boundary(mnl->kappa2);
Q_plus_psi(g_spinor_field[DUM_DERI+2], mnl->pf);
g_mu = mnl->mu;
boundary(mnl->kappa);
if(mnl->solver == CG) {
/* If CG is used anyhow */
/* gamma5(g_spinor_field[DUM_DERI+1], g_spinor_field[DUM_DERI+2], VOLUME/2); */
/* Invert Q_{+} Q_{-} */
/* X_W -> DUM_DERI+1 */
chrono_guess(g_spinor_field[DUM_DERI+1], g_spinor_field[DUM_DERI+2], mnl->csg_field,
mnl->csg_index_array, mnl->csg_N, mnl->csg_n, VOLUME/2, &Q_pm_psi);
mnl->iter1 += cg_her(g_spinor_field[DUM_DERI+1], g_spinor_field[DUM_DERI+2],
mnl->maxiter, mnl->forceprec, g_relative_precision_flag,
VOLUME, &Q_pm_psi);
chrono_add_solution(g_spinor_field[DUM_DERI+1], mnl->csg_field, mnl->csg_index_array,
mnl->csg_N, &mnl->csg_n, VOLUME/2);
/* Y_W -> DUM_DERI */
Q_minus_psi(g_spinor_field[DUM_DERI], g_spinor_field[DUM_DERI+1]);
}
else {
/* Invert first Q_+ */
/* Y_o -> DUM_DERI */
chrono_guess(g_spinor_field[DUM_DERI], g_spinor_field[DUM_DERI+2], mnl->csg_field, mnl->csg_index_array,
mnl->csg_N, mnl->csg_n, VOLUME/2, &Q_plus_psi);
gamma5(g_spinor_field[DUM_DERI], g_spinor_field[DUM_DERI], VOLUME);
mnl->iter1 += bicgstab_complex(g_spinor_field[DUM_DERI], g_spinor_field[DUM_DERI+2],
mnl->maxiter, mnl->forceprec, g_relative_precision_flag,
VOLUME, Q_plus_psi);
chrono_add_solution(g_spinor_field[DUM_DERI], mnl->csg_field, mnl->csg_index_array,
mnl->csg_N, &mnl->csg_n, VOLUME/2);
/* Now Q_- */
/* X_o -> DUM_DERI+1 */
g_mu = -g_mu;
chrono_guess(g_spinor_field[DUM_DERI+1], g_spinor_field[DUM_DERI], mnl->csg_field2,
mnl->csg_index_array2, mnl->csg_N2, mnl->csg_n2, VOLUME/2, &Q_minus_psi);
gamma5(g_spinor_field[DUM_DERI+1], g_spinor_field[DUM_DERI+1], VOLUME);
mnl->iter1 += bicgstab_complex(g_spinor_field[DUM_DERI+1],g_spinor_field[DUM_DERI],
mnl->maxiter, mnl->forceprec, g_relative_precision_flag,
VOLUME, Q_minus_psi);
chrono_add_solution(g_spinor_field[DUM_DERI+1], mnl->csg_field2, mnl->csg_index_array2,
mnl->csg_N2, &mnl->csg_n2, VOLUME/2);
g_mu = -g_mu;
}
/* \delta Q sandwitched by Y^\dagger and X */
deriv_Sb_D_psi(g_spinor_field[DUM_DERI], g_spinor_field[DUM_DERI+1], hf, mnl->forcefactor);
g_mu = mnl->mu2;
boundary(mnl->kappa2);
/* Second term coming from the second field */
/* The sign is opposite!! */
mul_r(g_spinor_field[DUM_DERI], -1., mnl->pf, VOLUME);
/* \delta Q sandwitched by Y^\dagger and X */
deriv_Sb_D_psi(g_spinor_field[DUM_DERI], g_spinor_field[DUM_DERI+1], hf, mnl->forcefactor);
}
g_mu = g_mu1;
boundary(g_kappa);
ITER_MAX_BCG = saveiter;
return;
}
void detratio_heatbath(const int id, hamiltonian_field_t * const hf) {
int saveiter = ITER_MAX_BCG;
monomial * mnl = &monomial_list[id];
g_mu = mnl->mu;
boundary(mnl->kappa);
mnl->csg_n = 0;
mnl->csg_n2 = 0;
mnl->iter0 = 0;
mnl->iter1 = 0;
if(mnl->even_odd_flag) {
random_spinor_field(g_spinor_field[4], VOLUME/2, mnl->rngrepro);
mnl->energy0 = square_norm(g_spinor_field[4], VOLUME/2, 1);
Qtm_plus_psi(g_spinor_field[3], g_spinor_field[4]);
g_mu = mnl->mu2;
boundary(mnl->kappa2);
zero_spinor_field(mnl->pf,VOLUME/2);
if(mnl->solver == CG) ITER_MAX_BCG = 0;
ITER_MAX_CG = mnl->maxiter;
mnl->iter0 += bicg(mnl->pf, g_spinor_field[3], mnl->accprec, g_relative_precision_flag);
chrono_add_solution(mnl->pf, mnl->csg_field, mnl->csg_index_array,
mnl->csg_N, &mnl->csg_n, VOLUME/2);
if(mnl->solver != CG) {
chrono_add_solution(mnl->pf, mnl->csg_field2, mnl->csg_index_array2,
mnl->csg_N2, &mnl->csg_n2, VOLUME/2);
}
}
else {
random_spinor_field(g_spinor_field[4], VOLUME, mnl->rngrepro);
mnl->energy0 = square_norm(g_spinor_field[4], VOLUME, 1);
Q_plus_psi(g_spinor_field[3], g_spinor_field[4]);
g_mu = mnl->mu2;
boundary(mnl->kappa2);
zero_spinor_field(mnl->pf,VOLUME);
mnl->iter0 += bicgstab_complex(mnl->pf, g_spinor_field[3], mnl->maxiter, mnl->accprec,
g_relative_precision_flag, VOLUME, Q_plus_psi);
chrono_add_solution(mnl->pf, mnl->csg_field, mnl->csg_index_array,
mnl->csg_N, &mnl->csg_n, VOLUME/2);
if(mnl->solver != CG) {
chrono_add_solution(mnl->pf, mnl->csg_field2, mnl->csg_index_array2,
mnl->csg_N2, &mnl->csg_n2, VOLUME/2);
}
}
if(g_proc_id == 0 && g_debug_level > 3) {
printf("called detratio_heatbath for id %d %d energy %f\n", id, mnl->even_odd_flag, mnl->energy0);
}
g_mu = g_mu1;
boundary(g_kappa);
ITER_MAX_BCG = saveiter;
return;
}
double detratio_acc(const int id, hamiltonian_field_t * const hf) {
monomial * mnl = &monomial_list[id];
int saveiter = ITER_MAX_BCG;
int save_sloppy = g_sloppy_precision_flag;
g_mu = mnl->mu2;
boundary(mnl->kappa2);
if(even_odd_flag) {
Qtm_plus_psi(g_spinor_field[DUM_DERI+5], mnl->pf);
g_mu = mnl->mu;
boundary(mnl->kappa);
if(mnl->solver == CG) ITER_MAX_BCG = 0;
ITER_MAX_CG = mnl->maxiter;
chrono_guess(g_spinor_field[3], g_spinor_field[DUM_DERI+5], mnl->csg_field, mnl->csg_index_array,
mnl->csg_N, mnl->csg_n, VOLUME/2, &Qtm_plus_psi);
g_sloppy_precision_flag = 0;
mnl->iter0 += bicg(g_spinor_field[3], g_spinor_field[DUM_DERI+5], mnl->accprec, g_relative_precision_flag);
g_sloppy_precision_flag = save_sloppy;
/* ITER_MAX_BCG = *saveiter_max; */
/* Compute the energy contr. from second field */
mnl->energy1 = square_norm(g_spinor_field[3], VOLUME/2, 1);
}
else {
Q_plus_psi(g_spinor_field[DUM_DERI+5], mnl->pf);
g_mu = mnl->mu;
boundary(mnl->kappa);
chrono_guess(g_spinor_field[3], g_spinor_field[DUM_DERI+5], mnl->csg_field, mnl->csg_index_array,
mnl->csg_N, mnl->csg_n, VOLUME/2, &Q_plus_psi);
mnl->iter0 += bicgstab_complex(g_spinor_field[3], g_spinor_field[DUM_DERI+5],
mnl->maxiter, mnl->accprec, g_relative_precision_flag,
VOLUME, Q_plus_psi);
/* ITER_MAX_BCG = *saveiter_max; */
/* Compute the energy contr. from second field */
mnl->energy1 = square_norm(g_spinor_field[3], VOLUME, 1);
}
g_mu = g_mu1;
boundary(g_kappa);
ITER_MAX_BCG = saveiter;
if(g_proc_id == 0 && g_debug_level > 3) {
printf("called detratio_acc for id %d %d dH = %1.4e\n",
id, mnl->even_odd_flag, mnl->energy1 - mnl->energy0);
}
return(mnl->energy1 - mnl->energy0);
}