-/* -*- mode: c; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4; c-file-style: "stroustrup"; -*-
+/*
+ * This file is part of the GROMACS molecular simulation package.
*
- *
- * This source code is part of
- *
- * G R O M A C S
- *
- * GROningen MAchine for Chemical Simulations
- *
- * VERSION 3.2.0
- * Written by David van der Spoel, Erik Lindahl, Berk Hess, and others.
* Copyright (c) 1991-2000, University of Groningen, The Netherlands.
- * Copyright (c) 2001-2004, The GROMACS development team,
- * check out http://www.gromacs.org for more information.
-
- * 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 2
+ * Copyright (c) 2001-2004, The GROMACS development team.
+ * Copyright (c) 2013,2014, by the GROMACS development team, led by
+ * Mark Abraham, David van der Spoel, Berk Hess, and Erik Lindahl,
+ * and including many others, as listed in the AUTHORS file in the
+ * top-level source directory and at http://www.gromacs.org.
+ *
+ * GROMACS is free software; you can redistribute it and/or
+ * modify it under the terms of the GNU Lesser General Public License
+ * as published by the Free Software Foundation; either version 2.1
* of the License, or (at your option) any later version.
- *
- * If you want to redistribute modifications, please consider that
- * scientific software is very special. Version control is crucial -
- * bugs must be traceable. We will be happy to consider code for
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+ * in the README & COPYING files - if they are missing, get the
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+ *
* To help us fund GROMACS development, we humbly ask that you cite
- * the papers on the package - you can find them in the top README file.
- *
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- *
- * And Hey:
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+ * the research papers on the package. Check out http://www.gromacs.org.
*/
-#ifdef HAVE_CONFIG_H
-#include <config.h>
-#endif
-
-#include "typedefs.h"
-#include "smalloc.h"
-#include "vec.h"
-#include "nrjac.h"
-#include "network.h"
-#include "orires.h"
-#include "do_fit.h"
-#include "main.h"
-#include "copyrite.h"
-#include "pbc.h"
-#include "mtop_util.h"
-
-void init_orires(FILE *fplog,const gmx_mtop_t *mtop,
+#include "gmxpre.h"
+
+#include "gromacs/legacyheaders/orires.h"
+
+#include "gromacs/legacyheaders/copyrite.h"
+#include "gromacs/legacyheaders/main.h"
+#include "gromacs/legacyheaders/network.h"
+#include "gromacs/legacyheaders/typedefs.h"
+#include "gromacs/legacyheaders/types/commrec.h"
+#include "gromacs/linearalgebra/nrjac.h"
+#include "gromacs/math/do_fit.h"
+#include "gromacs/math/vec.h"
+#include "gromacs/pbcutil/ishift.h"
+#include "gromacs/pbcutil/mshift.h"
+#include "gromacs/pbcutil/pbc.h"
+#include "gromacs/topology/mtop_util.h"
+#include "gromacs/utility/fatalerror.h"
+#include "gromacs/utility/smalloc.h"
+
+void init_orires(FILE *fplog, const gmx_mtop_t *mtop,
rvec xref[],
const t_inputrec *ir,
- const gmx_multisim_t *ms,t_oriresdata *od,
+ const t_commrec *cr, t_oriresdata *od,
t_state *state)
{
- int i,j,d,ex,nmol,nr,*nr_ex;
- double mtot;
- rvec com;
- gmx_mtop_ilistloop_t iloop;
- t_ilist *il;
+ int i, j, d, ex, nmol, *nr_ex;
+ double mtot;
+ rvec com;
+ gmx_mtop_ilistloop_t iloop;
+ t_ilist *il;
gmx_mtop_atomloop_all_t aloop;
- t_atom *atom;
-
- od->fc = ir->orires_fc;
- od->nex = 0;
- od->S = NULL;
+ t_atom *atom;
+ const gmx_multisim_t *ms;
- od->M=NULL;
- od->eig=NULL;
- od->v=NULL;
+ od->nr = gmx_mtop_ftype_count(mtop, F_ORIRES);
+ if (0 == od->nr)
+ {
+ /* Not doing orientation restraints */
+ return;
+ }
- od->nr = gmx_mtop_ftype_count(mtop,F_ORIRES);
- if (od->nr == 0)
+ if (DOMAINDECOMP(cr))
{
+ gmx_fatal(FARGS, "Orientation restraints do not work with more than one domain (ie. MPI rank).");
+ }
+ /* Orientation restraints */
+ if (!MASTER(cr))
+ {
+ /* Nothing to do */
return;
}
-
+ ms = cr->ms;
+
+ od->fc = ir->orires_fc;
+ od->nex = 0;
+ od->S = NULL;
+ od->M = NULL;
+ od->eig = NULL;
+ od->v = NULL;
+
nr_ex = NULL;
-
+
iloop = gmx_mtop_ilistloop_init(mtop);
- while (gmx_mtop_ilistloop_next(iloop,&il,&nmol))
+ while (gmx_mtop_ilistloop_next(iloop, &il, &nmol))
{
- for(i=0; i<il[F_ORIRES].nr; i+=3)
+ for (i = 0; i < il[F_ORIRES].nr; i += 3)
{
ex = mtop->ffparams.iparams[il[F_ORIRES].iatoms[i]].orires.ex;
if (ex >= od->nex)
{
- srenew(nr_ex,ex+1);
- for(j=od->nex; j<ex+1; j++)
+ srenew(nr_ex, ex+1);
+ for (j = od->nex; j < ex+1; j++)
{
nr_ex[j] = 0;
- }
+ }
od->nex = ex+1;
}
nr_ex[ex]++;
}
}
- snew(od->S,od->nex);
+ snew(od->S, od->nex);
/* When not doing time averaging, the instaneous and time averaged data
* are indentical and the pointers can point to the same memory.
*/
- snew(od->Dinsl,od->nr);
+ snew(od->Dinsl, od->nr);
if (ms)
{
- snew(od->Dins,od->nr);
+ snew(od->Dins, od->nr);
}
else
{
if (ir->orires_tau == 0)
{
- od->Dtav = od->Dins;
- od->edt = 0.0;
- od->edt_1= 1.0;
+ od->Dtav = od->Dins;
+ od->edt = 0.0;
+ od->edt_1 = 1.0;
}
else
{
- snew(od->Dtav,od->nr);
- od->edt = exp(-ir->delta_t/ir->orires_tau);
- od->edt_1= 1.0 - od->edt;
+ snew(od->Dtav, od->nr);
+ od->edt = exp(-ir->delta_t/ir->orires_tau);
+ od->edt_1 = 1.0 - od->edt;
/* Extend the state with the orires history */
- state->flags |= (1<<estORIRE_INITF);
+ state->flags |= (1<<estORIRE_INITF);
state->hist.orire_initf = 1;
- state->flags |= (1<<estORIRE_DTAV);
+ state->flags |= (1<<estORIRE_DTAV);
state->hist.norire_Dtav = od->nr*5;
- snew(state->hist.orire_Dtav,state->hist.norire_Dtav);
+ snew(state->hist.orire_Dtav, state->hist.norire_Dtav);
}
- snew(od->oinsl,od->nr);
+ snew(od->oinsl, od->nr);
if (ms)
{
- snew(od->oins,od->nr);
+ snew(od->oins, od->nr);
}
else
{
od->oins = od->oinsl;
}
- if (ir->orires_tau == 0) {
+ if (ir->orires_tau == 0)
+ {
od->otav = od->oins;
}
else
{
- snew(od->otav,od->nr);
+ snew(od->otav, od->nr);
}
- snew(od->tmp,od->nex);
- snew(od->TMP,od->nex);
- for(ex=0; ex<od->nex; ex++)
+ snew(od->tmp, od->nex);
+ snew(od->TMP, od->nex);
+ for (ex = 0; ex < od->nex; ex++)
{
- snew(od->TMP[ex],5);
- for(i=0; i<5; i++)
+ snew(od->TMP[ex], 5);
+ for (i = 0; i < 5; i++)
{
- snew(od->TMP[ex][i],5);
+ snew(od->TMP[ex][i], 5);
}
}
-
+
od->nref = 0;
- for(i=0; i<mtop->natoms; i++)
+ for (i = 0; i < mtop->natoms; i++)
{
- if (ggrpnr(&mtop->groups,egcORFIT,i) == 0)
+ if (ggrpnr(&mtop->groups, egcORFIT, i) == 0)
{
od->nref++;
}
}
- snew(od->mref,od->nref);
- snew(od->xref,od->nref);
- snew(od->xtmp,od->nref);
-
- snew(od->eig,od->nex*12);
-
+ snew(od->mref, od->nref);
+ snew(od->xref, od->nref);
+ snew(od->xtmp, od->nref);
+
+ snew(od->eig, od->nex*12);
+
/* Determine the reference structure on the master node.
* Copy it to the other nodes after checking multi compatibility,
* so we are sure the subsystems match before copying.
*/
clear_rvec(com);
- mtot = 0.0;
- j = 0;
+ mtot = 0.0;
+ j = 0;
aloop = gmx_mtop_atomloop_all_init(mtop);
- while(gmx_mtop_atomloop_all_next(aloop,&i,&atom))
+ while (gmx_mtop_atomloop_all_next(aloop, &i, &atom))
{
if (mtop->groups.grpnr[egcORFIT] == NULL ||
mtop->groups.grpnr[egcORFIT][i] == 0)
{
/* Not correct for free-energy with changing masses */
od->mref[j] = atom->m;
- if (ms==NULL || MASTERSIM(ms))
+ if (ms == NULL || MASTERSIM(ms))
{
- copy_rvec(xref[i],od->xref[j]);
- for(d=0; d<DIM; d++)
+ copy_rvec(xref[i], od->xref[j]);
+ for (d = 0; d < DIM; d++)
{
com[d] += od->mref[j]*xref[i][d];
}
j++;
}
}
- svmul(1.0/mtot,com,com);
- if (ms==NULL || MASTERSIM(ms))
+ svmul(1.0/mtot, com, com);
+ if (ms == NULL || MASTERSIM(ms))
{
- for(j=0; j<od->nref; j++)
+ for (j = 0; j < od->nref; j++)
{
- rvec_dec(od->xref[j],com);
+ rvec_dec(od->xref[j], com);
}
}
-
- fprintf(fplog,"Found %d orientation experiments\n",od->nex);
- for(i=0; i<od->nex; i++)
+
+ fprintf(fplog, "Found %d orientation experiments\n", od->nex);
+ for (i = 0; i < od->nex; i++)
{
- fprintf(fplog," experiment %d has %d restraints\n",i+1,nr_ex[i]);
+ fprintf(fplog, " experiment %d has %d restraints\n", i+1, nr_ex[i]);
}
-
+
sfree(nr_ex);
-
- fprintf(fplog," the fit group consists of %d atoms and has total mass %g\n",
- od->nref,mtot);
-
+
+ fprintf(fplog, " the fit group consists of %d atoms and has total mass %g\n",
+ od->nref, mtot);
+
if (ms)
{
- fprintf(fplog," the orientation restraints are ensemble averaged over %d systems\n",ms->nsim);
-
- check_multi_int(fplog,ms,od->nr,
- "the number of orientation restraints");
- check_multi_int(fplog,ms,od->nref,
- "the number of fit atoms for orientation restraining");
- check_multi_int(fplog,ms,ir->nsteps,"nsteps");
+ fprintf(fplog, " the orientation restraints are ensemble averaged over %d systems\n", ms->nsim);
+
+ check_multi_int(fplog, ms, od->nr,
+ "the number of orientation restraints",
+ FALSE);
+ check_multi_int(fplog, ms, od->nref,
+ "the number of fit atoms for orientation restraining",
+ FALSE);
+ check_multi_int(fplog, ms, ir->nsteps, "nsteps", FALSE);
/* Copy the reference coordinates from the master to the other nodes */
- gmx_sum_sim(DIM*od->nref,od->xref[0],ms);
+ gmx_sum_sim(DIM*od->nref, od->xref[0], ms);
}
-
- please_cite(fplog,"Hess2003");
+
+ please_cite(fplog, "Hess2003");
}
void diagonalize_orires_tensors(t_oriresdata *od)
{
- int ex,i,j,nrot,ord[DIM],t;
- matrix S,TMP;
-
+ int ex, i, j, nrot, ord[DIM], t;
+ matrix S, TMP;
+
if (od->M == NULL)
{
- snew(od->M,DIM);
- for(i=0; i<DIM; i++)
+ snew(od->M, DIM);
+ for (i = 0; i < DIM; i++)
{
- snew(od->M[i],DIM);
+ snew(od->M[i], DIM);
}
- snew(od->eig_diag,DIM);
- snew(od->v,DIM);
- for(i=0; i<DIM; i++)
+ snew(od->eig_diag, DIM);
+ snew(od->v, DIM);
+ for (i = 0; i < DIM; i++)
{
- snew(od->v[i],DIM);
+ snew(od->v[i], DIM);
}
}
- for(ex=0; ex<od->nex; ex++)
+ for (ex = 0; ex < od->nex; ex++)
{
/* Rotate the S tensor back to the reference frame */
- mmul(od->R,od->S[ex],TMP);
- mtmul(TMP,od->R,S);
- for(i=0; i<DIM; i++)
+ mmul(od->R, od->S[ex], TMP);
+ mtmul(TMP, od->R, S);
+ for (i = 0; i < DIM; i++)
{
- for(j=0; j<DIM; j++)
+ for (j = 0; j < DIM; j++)
{
od->M[i][j] = S[i][j];
}
}
-
- jacobi(od->M,DIM,od->eig_diag,od->v,&nrot);
-
- for(i=0; i<DIM; i++)
+
+ jacobi(od->M, DIM, od->eig_diag, od->v, &nrot);
+
+ for (i = 0; i < DIM; i++)
{
ord[i] = i;
}
- for(i=0; i<DIM; i++)
+ for (i = 0; i < DIM; i++)
{
- for(j=i+1; j<DIM; j++)
+ for (j = i+1; j < DIM; j++)
{
if (sqr(od->eig_diag[ord[j]]) > sqr(od->eig_diag[ord[i]]))
{
- t = ord[i];
+ t = ord[i];
ord[i] = ord[j];
ord[j] = t;
}
}
}
-
- for(i=0; i<DIM; i++)
+
+ for (i = 0; i < DIM; i++)
{
od->eig[ex*12 + i] = od->eig_diag[ord[i]];
}
- for(i=0; i<DIM; i++)
+ for (i = 0; i < DIM; i++)
{
- for(j=0; j<DIM; j++)
+ for (j = 0; j < DIM; j++)
{
od->eig[ex*12 + 3 + 3*i + j] = od->v[j][ord[i]];
}
}
}
-void print_orires_log(FILE *log,t_oriresdata *od)
+void print_orires_log(FILE *log, t_oriresdata *od)
{
- int ex,i;
- real *eig;
-
+ int ex, i;
+ real *eig;
+
diagonalize_orires_tensors(od);
-
- for(ex=0; ex<od->nex; ex++)
+
+ for (ex = 0; ex < od->nex; ex++)
{
eig = od->eig + ex*12;
- fprintf(log," Orientation experiment %d:\n",ex+1);
- fprintf(log," order parameter: %g\n",eig[0]);
- for(i=0; i<DIM; i++)
+ fprintf(log, " Orientation experiment %d:\n", ex+1);
+ fprintf(log, " order parameter: %g\n", eig[0]);
+ for (i = 0; i < DIM; i++)
{
- fprintf(log," eig: %6.3f %6.3f %6.3f %6.3f\n",
+ fprintf(log, " eig: %6.3f %6.3f %6.3f %6.3f\n",
(eig[0] != 0) ? eig[i]/eig[0] : eig[i],
eig[DIM+i*DIM+XX],
eig[DIM+i*DIM+YY],
eig[DIM+i*DIM+ZZ]);
}
- fprintf(log,"\n");
+ fprintf(log, "\n");
}
}
real calc_orires_dev(const gmx_multisim_t *ms,
- int nfa,const t_iatom forceatoms[],const t_iparams ip[],
- const t_mdatoms *md,const rvec x[],const t_pbc *pbc,
- t_fcdata *fcd,history_t *hist)
+ int nfa, const t_iatom forceatoms[], const t_iparams ip[],
+ const t_mdatoms *md, const rvec x[], const t_pbc *pbc,
+ t_fcdata *fcd, history_t *hist)
{
- int fa,d,i,j,type,ex,nref;
- real edt,edt_1,invn,pfac,r2,invr,corrfac,weight,wsv2,sw,dev;
- tensor *S,R,TMP;
- rvec5 *Dinsl,*Dins,*Dtav,*rhs;
- real *mref,***T;
- double mtot;
- rvec *xref,*xtmp,com,r_unrot,r;
- t_oriresdata *od;
+ int fa, d, i, j, type, ex, nref;
+ real edt, edt_1, invn, pfac, r2, invr, corrfac, weight, wsv2, sw, dev;
+ tensor *S, R, TMP;
+ rvec5 *Dinsl, *Dins, *Dtav, *rhs;
+ real *mref, ***T;
+ double mtot;
+ rvec *xref, *xtmp, com, r_unrot, r;
+ t_oriresdata *od;
gmx_bool bTAV;
- const real two_thr=2.0/3.0;
-
+ const real two_thr = 2.0/3.0;
+
od = &(fcd->orires);
if (od->nr == 0)
{
/* This means that this is not the master node */
- gmx_fatal(FARGS,"Orientation restraints are only supported on the master node, use less processors");
- }
-
- bTAV = (od->edt != 0);
- edt = od->edt;
- edt_1= od->edt_1;
- S = od->S;
- Dinsl= od->Dinsl;
- Dins = od->Dins;
- Dtav = od->Dtav;
- T = od->TMP;
- rhs = od->tmp;
- nref = od->nref;
- mref = od->mref;
- xref = od->xref;
- xtmp = od->xtmp;
-
+ gmx_fatal(FARGS, "Orientation restraints are only supported on the master rank, use fewer ranks");
+ }
+
+ bTAV = (od->edt != 0);
+ edt = od->edt;
+ edt_1 = od->edt_1;
+ S = od->S;
+ Dinsl = od->Dinsl;
+ Dins = od->Dins;
+ Dtav = od->Dtav;
+ T = od->TMP;
+ rhs = od->tmp;
+ nref = od->nref;
+ mref = od->mref;
+ xref = od->xref;
+ xtmp = od->xtmp;
+
if (bTAV)
{
od->exp_min_t_tau = hist->orire_initf*edt;
-
+
/* Correction factor to correct for the lack of history
* at short times.
*/
{
invn = 1.0;
}
-
+
clear_rvec(com);
mtot = 0;
- j=0;
- for(i=0; i<md->nr; i++)
+ j = 0;
+ for (i = 0; i < md->nr; i++)
{
if (md->cORF[i] == 0)
{
- copy_rvec(x[i],xtmp[j]);
+ copy_rvec(x[i], xtmp[j]);
mref[j] = md->massT[i];
- for(d=0; d<DIM; d++)
+ for (d = 0; d < DIM; d++)
{
com[d] += mref[j]*xref[j][d];
}
j++;
}
}
- svmul(1.0/mtot,com,com);
- for(j=0; j<nref; j++)
+ svmul(1.0/mtot, com, com);
+ for (j = 0; j < nref; j++)
{
- rvec_dec(xtmp[j],com);
+ rvec_dec(xtmp[j], com);
}
/* Calculate the rotation matrix to rotate x to the reference orientation */
- calc_fit_R(DIM,nref,mref,xref,xtmp,R);
- copy_mat(R,od->R);
-
+ calc_fit_R(DIM, nref, mref, xref, xtmp, R);
+ copy_mat(R, od->R);
+
d = 0;
- for(fa=0; fa<nfa; fa+=3)
+ for (fa = 0; fa < nfa; fa += 3)
{
type = forceatoms[fa];
if (pbc)
{
- pbc_dx_aiuc(pbc,x[forceatoms[fa+1]],x[forceatoms[fa+2]],r_unrot);
+ pbc_dx_aiuc(pbc, x[forceatoms[fa+1]], x[forceatoms[fa+2]], r_unrot);
}
else
{
- rvec_sub(x[forceatoms[fa+1]],x[forceatoms[fa+2]],r_unrot);
+ rvec_sub(x[forceatoms[fa+1]], x[forceatoms[fa+2]], r_unrot);
}
- mvmul(R,r_unrot,r);
+ mvmul(R, r_unrot, r);
r2 = norm2(r);
invr = gmx_invsqrt(r2);
/* Calculate the prefactor for the D tensor, this includes the factor 3! */
pfac = ip[type].orires.c*invr*invr*3;
- for(i=0; i<ip[type].orires.power; i++)
+ for (i = 0; i < ip[type].orires.power; i++)
{
pfac *= invr;
}
Dinsl[d][2] = pfac*(2*r[0]*r[2]);
Dinsl[d][3] = pfac*(2*r[1]*r[1] + r[0]*r[0] - r2);
Dinsl[d][4] = pfac*(2*r[1]*r[2]);
-
+
if (ms)
{
- for(i=0; i<5; i++)
+ for (i = 0; i < 5; i++)
{
Dins[d][i] = Dinsl[d][i]*invn;
}
d++;
}
-
+
if (ms)
{
- gmx_sum_sim(5*od->nr,Dins[0],ms);
+ gmx_sum_sim(5*od->nr, Dins[0], ms);
}
-
+
/* Calculate the order tensor S for each experiment via optimization */
- for(ex=0; ex<od->nex; ex++)
+ for (ex = 0; ex < od->nex; ex++)
{
- for(i=0; i<5; i++)
+ for (i = 0; i < 5; i++)
{
rhs[ex][i] = 0;
- for(j=0; j<=i; j++)
+ for (j = 0; j <= i; j++)
{
T[ex][i][j] = 0;
}
}
}
d = 0;
- for(fa=0; fa<nfa; fa+=3)
+ for (fa = 0; fa < nfa; fa += 3)
{
if (bTAV)
{
* Thus the results stay correct when this routine
* is called multiple times.
*/
- for(i=0; i<5; i++)
+ for (i = 0; i < 5; i++)
{
Dtav[d][i] = edt*hist->orire_Dtav[d*5+i] + edt_1*Dins[d][i];
}
}
-
+
type = forceatoms[fa];
ex = ip[type].orires.ex;
weight = ip[type].orires.kfac;
/* Calculate the vector rhs and half the matrix T for the 5 equations */
- for(i=0; i<5; i++) {
+ for (i = 0; i < 5; i++)
+ {
rhs[ex][i] += Dtav[d][i]*ip[type].orires.obs*weight;
- for(j=0; j<=i; j++)
+ for (j = 0; j <= i; j++)
{
T[ex][i][j] += Dtav[d][i]*Dtav[d][j]*weight;
}
d++;
}
/* Now we have all the data we can calculate S */
- for(ex=0; ex<od->nex; ex++)
+ for (ex = 0; ex < od->nex; ex++)
{
/* Correct corrfac and copy one half of T to the other half */
- for(i=0; i<5; i++)
+ for (i = 0; i < 5; i++)
{
rhs[ex][i] *= corrfac;
T[ex][i][i] *= sqr(corrfac);
- for(j=0; j<i; j++)
+ for (j = 0; j < i; j++)
{
T[ex][i][j] *= sqr(corrfac);
T[ex][j][i] = T[ex][i][j];
}
}
- m_inv_gen(T[ex],5,T[ex]);
+ m_inv_gen(T[ex], 5, T[ex]);
/* Calculate the orientation tensor S for this experiment */
S[ex][0][0] = 0;
S[ex][0][1] = 0;
S[ex][0][2] = 0;
S[ex][1][1] = 0;
S[ex][1][2] = 0;
- for(i=0; i<5; i++)
+ for (i = 0; i < 5; i++)
{
S[ex][0][0] += 1.5*T[ex][0][i]*rhs[ex][i];
S[ex][0][1] += 1.5*T[ex][1][i]*rhs[ex][i];
S[ex][2][1] = S[ex][1][2];
S[ex][2][2] = -S[ex][0][0] - S[ex][1][1];
}
-
+
wsv2 = 0;
sw = 0;
-
+
d = 0;
- for(fa=0; fa<nfa; fa+=3)
+ for (fa = 0; fa < nfa; fa += 3)
{
type = forceatoms[fa];
- ex = ip[type].orires.ex;
-
+ ex = ip[type].orires.ex;
+
od->otav[d] = two_thr*
corrfac*(S[ex][0][0]*Dtav[d][0] + S[ex][0][1]*Dtav[d][1] +
S[ex][0][2]*Dtav[d][2] + S[ex][1][1]*Dtav[d][3] +
S[ex][0][2]*Dinsl[d][2] + S[ex][1][1]*Dinsl[d][3] +
S[ex][1][2]*Dinsl[d][4]);
}
-
+
dev = od->otav[d] - ip[type].orires.obs;
-
+
wsv2 += ip[type].orires.kfac*sqr(dev);
sw += ip[type].orires.kfac;
-
+
d++;
}
od->rmsdev = sqrt(wsv2/sw);
-
+
/* Rotate the S matrices back, so we get the correct grad(tr(S D)) */
- for(ex=0; ex<od->nex; ex++)
+ for (ex = 0; ex < od->nex; ex++)
{
- tmmul(R,S[ex],TMP);
- mmul(TMP,R,S[ex]);
+ tmmul(R, S[ex], TMP);
+ mmul(TMP, R, S[ex]);
}
-
+
return od->rmsdev;
-
+
/* Approx. 120*nfa/3 flops */
}
-real orires(int nfa,const t_iatom forceatoms[],const t_iparams ip[],
- const rvec x[],rvec f[],rvec fshift[],
- const t_pbc *pbc,const t_graph *g,
- real lambda,real *dvdlambda,
- const t_mdatoms *md,t_fcdata *fcd,
- int *global_atom_index)
+real orires(int nfa, const t_iatom forceatoms[], const t_iparams ip[],
+ const rvec x[], rvec f[], rvec fshift[],
+ const t_pbc *pbc, const t_graph *g,
+ real gmx_unused lambda, real gmx_unused *dvdlambda,
+ const t_mdatoms gmx_unused *md, t_fcdata *fcd,
+ int gmx_unused *global_atom_index)
{
- atom_id ai,aj;
- int fa,d,i,type,ex,power,ki=CENTRAL;
- ivec dt;
- real r2,invr,invr2,fc,smooth_fc,dev,devins,pfac;
- rvec r,Sr,fij;
- real vtot;
+ atom_id ai, aj;
+ int fa, d, i, type, ex, power, ki = CENTRAL;
+ ivec dt;
+ real r2, invr, invr2, fc, smooth_fc, dev, devins, pfac;
+ rvec r, Sr, fij;
+ real vtot;
const t_oriresdata *od;
- gmx_bool bTAV;
-
+ gmx_bool bTAV;
+
vtot = 0;
- od = &(fcd->orires);
-
+ od = &(fcd->orires);
+
if (od->fc != 0)
{
bTAV = (od->edt != 0);
/* Smoothly switch on the restraining when time averaging is used */
smooth_fc *= (1.0 - od->exp_min_t_tau);
}
-
+
d = 0;
- for(fa=0; fa<nfa; fa+=3)
+ for (fa = 0; fa < nfa; fa += 3)
{
type = forceatoms[fa];
ai = forceatoms[fa+1];
aj = forceatoms[fa+2];
if (pbc)
{
- ki = pbc_dx_aiuc(pbc,x[ai],x[aj],r);
+ ki = pbc_dx_aiuc(pbc, x[ai], x[aj], r);
}
else
{
- rvec_sub(x[ai],x[aj],r);
+ rvec_sub(x[ai], x[aj], r);
}
r2 = norm2(r);
invr = gmx_invsqrt(r2);
power = ip[type].orires.power;
fc = smooth_fc*ip[type].orires.kfac;
dev = od->otav[d] - ip[type].orires.obs;
-
+
/* NOTE:
* there is no real potential when time averaging is applied
*/
vtot += 0.5*fc*sqr(dev);
-
+
if (bTAV)
{
/* Calculate the force as the sqrt of tav times instantaneous */
}
}
}
-
+
pfac = fc*ip[type].orires.c*invr2;
- for(i=0; i<power; i++)
+ for (i = 0; i < power; i++)
{
pfac *= invr;
}
- mvmul(od->S[ex],r,Sr);
- for(i=0; i<DIM; i++)
+ mvmul(od->S[ex], r, Sr);
+ for (i = 0; i < DIM; i++)
{
fij[i] =
- -pfac*dev*(4*Sr[i] - 2*(2+power)*invr2*iprod(Sr,r)*r[i]);
+ -pfac*dev*(4*Sr[i] - 2*(2+power)*invr2*iprod(Sr, r)*r[i]);
}
-
+
if (g)
{
- ivec_sub(SHIFT_IVEC(g,ai),SHIFT_IVEC(g,aj),dt);
- ki=IVEC2IS(dt);
+ ivec_sub(SHIFT_IVEC(g, ai), SHIFT_IVEC(g, aj), dt);
+ ki = IVEC2IS(dt);
}
-
- for(i=0; i<DIM; i++)
+
+ for (i = 0; i < DIM; i++)
{
f[ai][i] += fij[i];
f[aj][i] -= fij[i];
d++;
}
}
-
+
return vtot;
-
+
/* Approx. 80*nfa/3 flops */
}
-void update_orires_history(t_fcdata *fcd,history_t *hist)
+void update_orires_history(t_fcdata *fcd, history_t *hist)
{
t_oriresdata *od;
- int pair,i;
-
+ int pair, i;
+
od = &(fcd->orires);
if (od->edt != 0)
{
* in calc_orires_dev.
*/
hist->orire_initf = od->exp_min_t_tau;
- for(pair=0; pair<od->nr; pair++)
+ for (pair = 0; pair < od->nr; pair++)
{
- for(i=0; i<5; i++)
+ for (i = 0; i < 5; i++)
{
hist->orire_Dtav[pair*5+i] = od->Dtav[pair][i];
}