/*
- *
- * 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.
+ * This file is part of the GROMACS molecular simulation package.
+ *
* 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
- * inclusion in the official distribution, but derived work must not
- * be called official GROMACS. Details are found in the README & COPYING
- * files - if they are missing, get the official version at www.gromacs.org.
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+ * consider that scientific software is very special. Version
+ * control is crucial - bugs must be traceable. We will be happy to
+ * consider code for inclusion in the official distribution, but
+ * derived work must not be called official GROMACS. Details are found
+ * in the README & COPYING files - if they are missing, get the
+ * official version at http://www.gromacs.org.
+ *
* 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:
- * GROningen Mixture of Alchemy and Childrens' Stories
+ * the research papers on the package. Check out http://www.gromacs.org.
*/
-#ifdef HAVE_CONFIG_H
-#include <config.h>
-#endif
+#include "gmxpre.h"
#include <stdio.h>
#include <math.h>
-#include "maths.h"
-#include "typedefs.h"
-#include "vec.h"
-#include "coulomb.h"
-#include "smalloc.h"
-#include "physics.h"
-#include "txtdump.h"
-#include "futil.h"
-#include "names.h"
-#include "writeps.h"
-#include "macros.h"
-
-real calc_ewaldcoeff(real rc,real dtol)
+#include "gromacs/math/utilities.h"
+#include "gromacs/legacyheaders/typedefs.h"
+#include "gromacs/legacyheaders/types/commrec.h"
+#include "gromacs/math/vec.h"
+#include "gromacs/legacyheaders/coulomb.h"
+#include "gromacs/utility/smalloc.h"
+#include "gromacs/math/units.h"
+#include "gromacs/legacyheaders/txtdump.h"
+#include "gromacs/utility/futil.h"
+#include "gromacs/legacyheaders/names.h"
+#include "gromacs/legacyheaders/macros.h"
+
+real calc_ewaldcoeff_q(real rc, real dtol)
{
- real x=5,low,high;
- int n,i=0;
-
-
- do {
- i++;
- x*=2;
- } while (gmx_erfc(x*rc) > dtol);
-
- n=i+60; /* search tolerance is 2^-60 */
- low=0;
- high=x;
- for(i=0;i<n;i++) {
- x=(low+high)/2;
- if (gmx_erfc(x*rc) > dtol)
- low=x;
- else
- high=x;
- }
- return x;
-}
+ real x = 5, low, high;
+ int n, i = 0;
+
+ do
+ {
+ i++;
+ x *= 2;
+ }
+ while (gmx_erfc(x*rc) > dtol);
+ n = i+60; /* search tolerance is 2^-60 */
+ low = 0;
+ high = x;
+ for (i = 0; i < n; i++)
+ {
+ x = (low+high)/2;
+ if (gmx_erfc(x*rc) > dtol)
+ {
+ low = x;
+ }
+ else
+ {
+ high = x;
+ }
+ }
+ return x;
+}
-real ewald_LRcorrection(FILE *fplog,
- int start,int end,
- t_commrec *cr,int thread,t_forcerec *fr,
- real *chargeA,real *chargeB,
- gmx_bool calc_excl_corr,
- t_blocka *excl,rvec x[],
- matrix box,rvec mu_tot[],
- int ewald_geometry,real epsilon_surface,
- rvec *f,tensor vir,
- real lambda,real *dvdlambda)
+static real ewald_function_lj(real x, real rc)
{
- int i,i1,i2,j,k,m,iv,jv,q;
- atom_id *AA;
- double q2sumA,q2sumB,Vexcl,dvdl_excl; /* Necessary for precision */
- real one_4pi_eps;
- real v,vc,qiA,qiB,dr,dr2,rinv,fscal,enercorr;
- real Vself[2],Vdipole[2],rinv2,ewc=fr->ewaldcoeff,ewcdr;
- rvec df,dx,mutot[2],dipcorrA,dipcorrB;
- tensor dxdf;
- real vol = box[XX][XX]*box[YY][YY]*box[ZZ][ZZ];
- real L1,dipole_coeff,qqA,qqB,qqL,vr0;
- /*#define TABLES*/
-#ifdef TABLES
- real tabscale=fr->tabscale;
- real eps,eps2,VV,FF,F,Y,Geps,Heps2,Fp,fijC,r1t;
- real *VFtab=fr->coulvdwtab;
- int n0,n1,nnn;
+ real xrc, xrc2, xrc4, factor;
+ xrc = x*rc;
+ xrc2 = xrc*xrc;
+ xrc4 = xrc2*xrc2;
+#ifdef GMX_DOUBLE
+ factor = exp(-xrc2)*(1 + xrc2 + xrc4/2.0);
#else
- double isp=0.564189583547756;
+ factor = expf(-xrc2)*(1 + xrc2 + xrc4/2.0);
#endif
- gmx_bool bFreeEnergy = (chargeB != NULL);
- gmx_bool bMolPBC = fr->bMolPBC;
-
- one_4pi_eps = ONE_4PI_EPS0/fr->epsilon_r;
- vr0 = ewc*2/sqrt(M_PI);
-
- AA = excl->a;
- Vexcl = 0;
- dvdl_excl = 0;
- q2sumA = 0;
- q2sumB = 0;
- Vdipole[0] = 0;
- Vdipole[1] = 0;
- L1 = 1.0-lambda;
-
- /* Note that we have to transform back to gromacs units, since
- * mu_tot contains the dipole in debye units (for output).
- */
- for(i=0; (i<DIM); i++) {
- mutot[0][i] = mu_tot[0][i]*DEBYE2ENM;
- mutot[1][i] = mu_tot[1][i]*DEBYE2ENM;
- dipcorrA[i] = 0;
- dipcorrB[i] = 0;
- }
- dipole_coeff=0;
- switch (ewald_geometry) {
- case eewg3D:
- if (epsilon_surface != 0) {
- dipole_coeff =
- 2*M_PI*ONE_4PI_EPS0/((2*epsilon_surface + fr->epsilon_r)*vol);
- for(i=0; (i<DIM); i++) {
- dipcorrA[i] = 2*dipole_coeff*mutot[0][i];
- dipcorrB[i] = 2*dipole_coeff*mutot[1][i];
- }
+
+ return factor;
+}
+
+real calc_ewaldcoeff_lj(real rc, real dtol)
+{
+ real x = 5, low, high;
+ int n, i = 0;
+
+ do
+ {
+ i++;
+ x *= 2.0;
}
- break;
- case eewg3DC:
- dipole_coeff = 2*M_PI*one_4pi_eps/vol;
- dipcorrA[ZZ] = 2*dipole_coeff*mutot[0][ZZ];
- dipcorrB[ZZ] = 2*dipole_coeff*mutot[1][ZZ];
- break;
- default:
- gmx_incons("Unsupported Ewald geometry");
- break;
- }
- if (debug) {
- fprintf(debug,"dipcorr = %8.3f %8.3f %8.3f\n",
- dipcorrA[XX],dipcorrA[YY],dipcorrA[ZZ]);
- fprintf(debug,"mutot = %8.3f %8.3f %8.3f\n",
- mutot[0][XX],mutot[0][YY],mutot[0][ZZ]);
- }
-
- clear_mat(dxdf);
- if ((calc_excl_corr || dipole_coeff != 0) && !bFreeEnergy) {
- for(i=start; (i<end); i++) {
- /* Initiate local variables (for this i-particle) to 0 */
- qiA = chargeA[i]*one_4pi_eps;
-
- if (calc_excl_corr)
- {
- i1 = excl->index[i];
- i2 = excl->index[i+1];
-
- /* Loop over excluded neighbours */
- for(j=i1; (j<i2); j++) {
- k = AA[j];
- /*
- * First we must test whether k <> i, and then, because the
- * exclusions are all listed twice i->k and k->i we must select
- * just one of the two.
- * As a minor optimization we only compute forces when the charges
- * are non-zero.
- */
- if (k > i) {
- qqA = qiA*chargeA[k];
- if (qqA != 0.0) {
- rvec_sub(x[i],x[k],dx);
- if (bMolPBC) {
- /* Cheap pbc_dx, assume excluded pairs are at short distance. */
- for(m=DIM-1; (m>=0); m--) {
- if (dx[m] > 0.5*box[m][m])
- rvec_dec(dx,box[m]);
- else if (dx[m] < -0.5*box[m][m])
- rvec_inc(dx,box[m]);
- }
- }
- dr2 = norm2(dx);
- /* Distance between two excluded particles may be zero in the
- * case of shells
- */
- if (dr2 != 0) {
- rinv = gmx_invsqrt(dr2);
- rinv2 = rinv*rinv;
- dr = 1.0/rinv;
-#ifdef TABLES
- r1t = tabscale*dr;
- n0 = r1t;
- assert(n0 >= 3);
- n1 = 12*n0;
- eps = r1t-n0;
- eps2 = eps*eps;
- nnn = n1;
- Y = VFtab[nnn];
- F = VFtab[nnn+1];
- Geps = eps*VFtab[nnn+2];
- Heps2 = eps2*VFtab[nnn+3];
- Fp = F+Geps+Heps2;
- VV = Y+eps*Fp;
- FF = Fp+Geps+2.0*Heps2;
- vc = qqA*(rinv-VV);
- fijC = qqA*FF;
- Vexcl += vc;
-
- fscal = vc*rinv2+fijC*tabscale*rinv;
- /* End of tabulated interaction part */
-#else
-
- /* This is the code you would want instead if not using
- * tables:
- */
- ewcdr = ewc*dr;
- vc = qqA*gmx_erf(ewcdr)*rinv;
- Vexcl += vc;
+ while (ewald_function_lj(x, rc) > dtol);
+
+ n = i + 60; /* search tolerance is 2^-60 */
+ low = 0;
+ high = x;
+ for (i = 0; i < n; ++i)
+ {
+ x = (low + high) / 2.0;
+ if (ewald_function_lj(x, rc) > dtol)
+ {
+ low = x;
+ }
+ else
+ {
+ high = x;
+ }
+ }
+ return x;
+}
+
+void ewald_LRcorrection(int start, int end,
+ t_commrec *cr, int thread, t_forcerec *fr,
+ real *chargeA, real *chargeB,
+ real *C6A, real *C6B,
+ real *sigmaA, real *sigmaB,
+ real *sigma3A, real *sigma3B,
+ gmx_bool calc_excl_corr,
+ t_blocka *excl, rvec x[],
+ matrix box, rvec mu_tot[],
+ int ewald_geometry, real epsilon_surface,
+ rvec *f, tensor vir_q, tensor vir_lj,
+ real *Vcorr_q, real *Vcorr_lj,
+ real lambda_q, real lambda_lj,
+ real *dvdlambda_q, real *dvdlambda_lj)
+{
+ int i, i1, i2, j, k, m, iv, jv, q;
+ atom_id *AA;
+ double Vexcl_q, dvdl_excl_q, dvdl_excl_lj; /* Necessary for precision */
+ double Vexcl_lj;
+ real one_4pi_eps;
+ real v, vc, qiA, qiB, dr2, rinv, enercorr;
+ real Vself_q[2], Vself_lj[2], Vdipole[2], rinv2, ewc_q = fr->ewaldcoeff_q, ewcdr;
+ real ewc_lj = fr->ewaldcoeff_lj, ewc_lj2 = ewc_lj * ewc_lj;
+ real c6Ai = 0, c6Bi = 0, c6A = 0, c6B = 0, ewcdr2, ewcdr4, c6L = 0, rinv6;
+ rvec df, dx, mutot[2], dipcorrA, dipcorrB;
+ tensor dxdf_q, dxdf_lj;
+ real vol = box[XX][XX]*box[YY][YY]*box[ZZ][ZZ];
+ real L1_q, L1_lj, dipole_coeff, qqA, qqB, qqL, vr0_q, vr0_lj = 0;
+ gmx_bool bFreeEnergy = (chargeB != NULL);
+ gmx_bool bMolPBC = fr->bMolPBC;
+ gmx_bool bDoingLBRule = (fr->ljpme_combination_rule == eljpmeLB);
+
+ /* This routine can be made faster by using tables instead of analytical interactions
+ * However, that requires a thorough verification that they are correct in all cases.
+ */
+
+ one_4pi_eps = ONE_4PI_EPS0/fr->epsilon_r;
+ vr0_q = ewc_q*M_2_SQRTPI;
+ if (EVDW_PME(fr->vdwtype))
+ {
+ vr0_lj = -pow(ewc_lj, 6)/6.0;
+ }
+
+ AA = excl->a;
+ Vexcl_q = 0;
+ Vexcl_lj = 0;
+ dvdl_excl_q = 0;
+ dvdl_excl_lj = 0;
+ Vdipole[0] = 0;
+ Vdipole[1] = 0;
+ L1_q = 1.0-lambda_q;
+ L1_lj = 1.0-lambda_lj;
+ /* Note that we have to transform back to gromacs units, since
+ * mu_tot contains the dipole in debye units (for output).
+ */
+ for (i = 0; (i < DIM); i++)
+ {
+ mutot[0][i] = mu_tot[0][i]*DEBYE2ENM;
+ mutot[1][i] = mu_tot[1][i]*DEBYE2ENM;
+ dipcorrA[i] = 0;
+ dipcorrB[i] = 0;
+ }
+ dipole_coeff = 0;
+ switch (ewald_geometry)
+ {
+ case eewg3D:
+ if (epsilon_surface != 0)
+ {
+ dipole_coeff =
+ 2*M_PI*ONE_4PI_EPS0/((2*epsilon_surface + fr->epsilon_r)*vol);
+ for (i = 0; (i < DIM); i++)
+ {
+ dipcorrA[i] = 2*dipole_coeff*mutot[0][i];
+ dipcorrB[i] = 2*dipole_coeff*mutot[1][i];
+ }
+ }
+ break;
+ case eewg3DC:
+ dipole_coeff = 2*M_PI*one_4pi_eps/vol;
+ dipcorrA[ZZ] = 2*dipole_coeff*mutot[0][ZZ];
+ dipcorrB[ZZ] = 2*dipole_coeff*mutot[1][ZZ];
+ break;
+ default:
+ gmx_incons("Unsupported Ewald geometry");
+ break;
+ }
+ if (debug)
+ {
+ fprintf(debug, "dipcorr = %8.3f %8.3f %8.3f\n",
+ dipcorrA[XX], dipcorrA[YY], dipcorrA[ZZ]);
+ fprintf(debug, "mutot = %8.3f %8.3f %8.3f\n",
+ mutot[0][XX], mutot[0][YY], mutot[0][ZZ]);
+ }
+ clear_mat(dxdf_q);
+ if (EVDW_PME(fr->vdwtype))
+ {
+ clear_mat(dxdf_lj);
+ }
+ if ((calc_excl_corr || dipole_coeff != 0) && !bFreeEnergy)
+ {
+ for (i = start; (i < end); i++)
+ {
+ /* Initiate local variables (for this i-particle) to 0 */
+ qiA = chargeA[i]*one_4pi_eps;
+ if (EVDW_PME(fr->vdwtype))
+ {
+ c6Ai = C6A[i];
+ if (bDoingLBRule)
+ {
+ c6Ai *= sigma3A[i];
+ }
+ }
+ if (calc_excl_corr)
+ {
+ i1 = excl->index[i];
+ i2 = excl->index[i+1];
+
+ /* Loop over excluded neighbours */
+ for (j = i1; (j < i2); j++)
+ {
+ k = AA[j];
+ /*
+ * First we must test whether k <> i, and then,
+ * because the exclusions are all listed twice i->k
+ * and k->i we must select just one of the two. As
+ * a minor optimization we only compute forces when
+ * the charges are non-zero.
+ */
+ if (k > i)
+ {
+ qqA = qiA*chargeA[k];
+ if (EVDW_PME(fr->vdwtype))
+ {
+ c6A = c6Ai * C6A[k];
+ if (bDoingLBRule)
+ {
+ c6A *= pow(0.5*(sigmaA[i]+sigmaA[k]), 6)*sigma3A[k];
+ }
+ }
+ if (qqA != 0.0 || c6A != 0.0)
+ {
+ real fscal;
+
+ fscal = 0;
+ rvec_sub(x[i], x[k], dx);
+ if (bMolPBC)
+ {
+ /* Cheap pbc_dx, assume excluded pairs are at short distance. */
+ for (m = DIM-1; (m >= 0); m--)
+ {
+ if (dx[m] > 0.5*box[m][m])
+ {
+ rvec_dec(dx, box[m]);
+ }
+ else if (dx[m] < -0.5*box[m][m])
+ {
+ rvec_inc(dx, box[m]);
+ }
+ }
+ }
+ dr2 = norm2(dx);
+ /* Distance between two excluded particles
+ * may be zero in the case of shells
+ */
+ if (dr2 != 0)
+ {
+ rinv = gmx_invsqrt(dr2);
+ rinv2 = rinv*rinv;
+ if (qqA != 0.0)
+ {
+ real dr;
+
+ dr = 1.0/rinv;
+ ewcdr = ewc_q*dr;
+ vc = qqA*gmx_erf(ewcdr)*rinv;
+ Vexcl_q += vc;
#ifdef GMX_DOUBLE
- /* Relative accuracy at R_ERF_R_INACC of 3e-10 */
-#define R_ERF_R_INACC 0.006
+ /* Relative accuracy at R_ERF_R_INACC of 3e-10 */
+#define R_ERF_R_INACC 0.006
#else
- /* Relative accuracy at R_ERF_R_INACC of 2e-5 */
-#define R_ERF_R_INACC 0.1
-#endif
- if (ewcdr > R_ERF_R_INACC) {
- fscal = rinv2*(vc - 2.0*qqA*ewc*isp*exp(-ewcdr*ewcdr));
- } else {
- /* Use a fourth order series expansion for small ewcdr */
- fscal = ewc*ewc*qqA*vr0*(2.0/3.0 - 0.4*ewcdr*ewcdr);
- }
+ /* Relative accuracy at R_ERF_R_INACC of 2e-5 */
+#define R_ERF_R_INACC 0.1
#endif
- /* The force vector is obtained by multiplication with the
- * distance vector
- */
- svmul(fscal,dx,df);
- rvec_inc(f[k],df);
- rvec_dec(f[i],df);
- for(iv=0; (iv<DIM); iv++)
- for(jv=0; (jv<DIM); jv++)
- dxdf[iv][jv] += dx[iv]*df[jv];
- } else {
- Vexcl += qqA*vr0;
- }
- }
- }
- }
- }
- /* Dipole correction on force */
- if (dipole_coeff != 0) {
- for(j=0; (j<DIM); j++)
- f[i][j] -= dipcorrA[j]*chargeA[i];
- }
+ /* fscal is the scalar force pre-multiplied by rinv,
+ * to normalise the relative position vector dx */
+ if (ewcdr > R_ERF_R_INACC)
+ {
+ fscal = rinv2*(vc - qqA*ewc_q*M_2_SQRTPI*exp(-ewcdr*ewcdr));
+ }
+ else
+ {
+ /* Use a fourth order series expansion for small ewcdr */
+ fscal = ewc_q*ewc_q*qqA*vr0_q*(2.0/3.0 - 0.4*ewcdr*ewcdr);
+ }
+
+ /* The force vector is obtained by multiplication with
+ * the relative position vector
+ */
+ svmul(fscal, dx, df);
+ rvec_inc(f[k], df);
+ rvec_dec(f[i], df);
+ for (iv = 0; (iv < DIM); iv++)
+ {
+ for (jv = 0; (jv < DIM); jv++)
+ {
+ dxdf_q[iv][jv] += dx[iv]*df[jv];
+ }
+ }
+ }
+
+ if (c6A != 0.0)
+ {
+ rinv6 = rinv2*rinv2*rinv2;
+ ewcdr2 = ewc_lj2*dr2;
+ ewcdr4 = ewcdr2*ewcdr2;
+ /* We get the excluded long-range contribution from -C6*(1-g(r))
+ * g(r) is also defined in the manual under LJ-PME
+ */
+ vc = -c6A*rinv6*(1.0 - exp(-ewcdr2)*(1 + ewcdr2 + 0.5*ewcdr4));
+ Vexcl_lj += vc;
+ /* The force is the derivative of the potential vc.
+ * fscal is the scalar force pre-multiplied by rinv,
+ * to normalise the relative position vector dx */
+ fscal = 6.0*vc*rinv2 + c6A*rinv6*exp(-ewcdr2)*ewc_lj2*ewcdr4;
+
+ /* The force vector is obtained by multiplication with
+ * the relative position vector
+ */
+ svmul(fscal, dx, df);
+ rvec_inc(f[k], df);
+ rvec_dec(f[i], df);
+ for (iv = 0; (iv < DIM); iv++)
+ {
+ for (jv = 0; (jv < DIM); jv++)
+ {
+ dxdf_lj[iv][jv] += dx[iv]*df[jv];
+ }
+ }
+ }
+ }
+ else
+ {
+ Vexcl_q += qqA*vr0_q;
+ Vexcl_lj += c6A*vr0_lj;
+ }
+ }
+ }
+ }
+ }
+ /* Dipole correction on force */
+ if (dipole_coeff != 0)
+ {
+ for (j = 0; (j < DIM); j++)
+ {
+ f[i][j] -= dipcorrA[j]*chargeA[i];
+ }
+ }
+ }
+ }
+ else if (calc_excl_corr || dipole_coeff != 0)
+ {
+ for (i = start; (i < end); i++)
+ {
+ /* Initiate local variables (for this i-particle) to 0 */
+ qiA = chargeA[i]*one_4pi_eps;
+ qiB = chargeB[i]*one_4pi_eps;
+ if (EVDW_PME(fr->vdwtype))
+ {
+ c6Ai = C6A[i];
+ c6Bi = C6B[i];
+ if (bDoingLBRule)
+ {
+ c6Ai *= sigma3A[i];
+ c6Bi *= sigma3B[i];
+ }
+ }
+ if (calc_excl_corr)
+ {
+ i1 = excl->index[i];
+ i2 = excl->index[i+1];
+
+ /* Loop over excluded neighbours */
+ for (j = i1; (j < i2); j++)
+ {
+ k = AA[j];
+ if (k > i)
+ {
+ qqA = qiA*chargeA[k];
+ qqB = qiB*chargeB[k];
+ if (EVDW_PME(fr->vdwtype))
+ {
+ c6A = c6Ai*C6A[k];
+ c6B = c6Bi*C6B[k];
+ if (bDoingLBRule)
+ {
+ c6A *= pow(0.5*(sigmaA[i]+sigmaA[k]), 6)*sigma3A[k];
+ c6B *= pow(0.5*(sigmaB[i]+sigmaB[k]), 6)*sigma3B[k];
+ }
+ }
+ if (qqA != 0.0 || qqB != 0.0 || c6A != 0.0 || c6B != 0.0)
+ {
+ real fscal;
+
+ fscal = 0;
+ qqL = L1_q*qqA + lambda_q*qqB;
+ if (EVDW_PME(fr->vdwtype))
+ {
+ c6L = L1_lj*c6A + lambda_lj*c6B;
+ }
+ rvec_sub(x[i], x[k], dx);
+ if (bMolPBC)
+ {
+ /* Cheap pbc_dx, assume excluded pairs are at short distance. */
+ for (m = DIM-1; (m >= 0); m--)
+ {
+ if (dx[m] > 0.5*box[m][m])
+ {
+ rvec_dec(dx, box[m]);
+ }
+ else if (dx[m] < -0.5*box[m][m])
+ {
+ rvec_inc(dx, box[m]);
+ }
+ }
+ }
+ dr2 = norm2(dx);
+ if (dr2 != 0)
+ {
+ rinv = gmx_invsqrt(dr2);
+ rinv2 = rinv*rinv;
+ if (qqA != 0.0 || qqB != 0.0)
+ {
+ real dr;
+
+ dr = 1.0/rinv;
+ v = gmx_erf(ewc_q*dr)*rinv;
+ vc = qqL*v;
+ Vexcl_q += vc;
+ /* fscal is the scalar force pre-multiplied by rinv,
+ * to normalise the relative position vector dx */
+ fscal = rinv2*(vc-qqL*ewc_q*M_2_SQRTPI*exp(-ewc_q*ewc_q*dr2));
+ dvdl_excl_q += (qqB - qqA)*v;
+
+ /* The force vector is obtained by multiplication with
+ * the relative position vector
+ */
+ svmul(fscal, dx, df);
+ rvec_inc(f[k], df);
+ rvec_dec(f[i], df);
+ for (iv = 0; (iv < DIM); iv++)
+ {
+ for (jv = 0; (jv < DIM); jv++)
+ {
+ dxdf_q[iv][jv] += dx[iv]*df[jv];
+ }
+ }
+ }
+
+ if ((c6A != 0.0 || c6B != 0.0) && EVDW_PME(fr->vdwtype))
+ {
+ rinv6 = rinv2*rinv2*rinv2;
+ ewcdr2 = ewc_lj2*dr2;
+ ewcdr4 = ewcdr2*ewcdr2;
+ v = -rinv6*(1.0 - exp(-ewcdr2)*(1 + ewcdr2 + 0.5*ewcdr4));
+ vc = c6L*v;
+ Vexcl_lj += vc;
+ /* fscal is the scalar force pre-multiplied by rinv,
+ * to normalise the relative position vector dx */
+ fscal = 6.0*vc*rinv2 + c6L*rinv6*exp(-ewcdr2)*ewc_lj2*ewcdr4;
+ dvdl_excl_lj += (c6B - c6A)*v;
+
+ /* The force vector is obtained by multiplication with
+ * the relative position vector
+ */
+ svmul(fscal, dx, df);
+ rvec_inc(f[k], df);
+ rvec_dec(f[i], df);
+ for (iv = 0; (iv < DIM); iv++)
+ {
+ for (jv = 0; (jv < DIM); jv++)
+ {
+ dxdf_lj[iv][jv] += dx[iv]*df[jv];
+ }
+ }
+ }
+ }
+ else
+ {
+ Vexcl_q += qqL*vr0_q;
+ dvdl_excl_q += (qqB - qqA)*vr0_q;
+ Vexcl_lj += c6L*vr0_lj;
+ dvdl_excl_lj += (c6B - c6A)*vr0_lj;
+ }
+ }
+ }
+ }
+ }
+ /* Dipole correction on force */
+ if (dipole_coeff != 0)
+ {
+ for (j = 0; (j < DIM); j++)
+ {
+ f[i][j] -= L1_q*dipcorrA[j]*chargeA[i]
+ + lambda_q*dipcorrB[j]*chargeB[i];
+ }
+ }
+ }
}
- } else if (calc_excl_corr || dipole_coeff != 0) {
- for(i=start; (i<end); i++) {
- /* Initiate local variables (for this i-particle) to 0 */
- qiA = chargeA[i]*one_4pi_eps;
- qiB = chargeB[i]*one_4pi_eps;
-
- if (calc_excl_corr)
- {
- i1 = excl->index[i];
- i2 = excl->index[i+1];
-
- /* Loop over excluded neighbours */
- for(j=i1; (j<i2); j++) {
- k = AA[j];
- if (k > i) {
- qqA = qiA*chargeA[k];
- qqB = qiB*chargeB[k];
- if (qqA != 0.0 || qqB != 0.0) {
- qqL = L1*qqA + lambda*qqB;
- rvec_sub(x[i],x[k],dx);
- if (bMolPBC) {
- /* Cheap pbc_dx, assume excluded pairs are at short distance. */
- for(m=DIM-1; (m>=0); m--) {
- if (dx[m] > 0.5*box[m][m])
- rvec_dec(dx,box[m]);
- else if (dx[m] < -0.5*box[m][m])
- rvec_inc(dx,box[m]);
- }
- }
- dr2 = norm2(dx);
- if (dr2 != 0) {
- rinv = gmx_invsqrt(dr2);
- rinv2 = rinv*rinv;
- dr = 1.0/rinv;
- v = gmx_erf(ewc*dr)*rinv;
- vc = qqL*v;
- Vexcl += vc;
- fscal = rinv2*(vc-2.0*qqL*ewc*isp*exp(-ewc*ewc*dr2));
- svmul(fscal,dx,df);
- rvec_inc(f[k],df);
- rvec_dec(f[i],df);
- for(iv=0; (iv<DIM); iv++)
- for(jv=0; (jv<DIM); jv++)
- dxdf[iv][jv] += dx[iv]*df[jv];
- dvdl_excl += (qqB - qqA)*v;
- } else {
- Vexcl += qqL*vr0;
- dvdl_excl += (qqB - qqA)*vr0;
- }
- }
- }
- }
- }
- /* Dipole correction on force */
- if (dipole_coeff != 0) {
- for(j=0; (j<DIM); j++)
- f[i][j] -= L1*dipcorrA[j]*chargeA[i]
- + lambda*dipcorrB[j]*chargeB[i];
- }
+ for (iv = 0; (iv < DIM); iv++)
+ {
+ for (jv = 0; (jv < DIM); jv++)
+ {
+ vir_q[iv][jv] += 0.5*dxdf_q[iv][jv];
+ vir_lj[iv][jv] += 0.5*dxdf_lj[iv][jv];
+ }
}
- }
- for(iv=0; (iv<DIM); iv++)
- for(jv=0; (jv<DIM); jv++)
- vir[iv][jv] += 0.5*dxdf[iv][jv];
-
-
- Vself[0] = 0;
- Vself[1] = 0;
- /* Global corrections only on master process */
- if (MASTER(cr) && thread == 0) {
- for(q=0; q<(bFreeEnergy ? 2 : 1); q++) {
- if (calc_excl_corr) {
- /* Self-energy correction */
- Vself[q] = ewc*one_4pi_eps*fr->q2sum[q]/sqrt(M_PI);
- }
-
- /* Apply surface dipole correction:
- * correction = dipole_coeff * (dipole)^2
- */
- if (dipole_coeff != 0) {
- if (ewald_geometry == eewg3D)
- Vdipole[q] = dipole_coeff*iprod(mutot[q],mutot[q]);
- else if (ewald_geometry == eewg3DC)
- Vdipole[q] = dipole_coeff*mutot[q][ZZ]*mutot[q][ZZ];
- }
+
+ Vself_q[0] = 0;
+ Vself_q[1] = 0;
+ Vself_lj[0] = 0;
+ Vself_lj[1] = 0;
+
+ /* Global corrections only on master process */
+ if (MASTER(cr) && thread == 0)
+ {
+ for (q = 0; q < (bFreeEnergy ? 2 : 1); q++)
+ {
+ if (calc_excl_corr)
+ {
+ /* Self-energy correction */
+ Vself_q[q] = ewc_q*one_4pi_eps*fr->q2sum[q]*M_1_SQRTPI;
+ if (EVDW_PME(fr->vdwtype))
+ {
+ Vself_lj[q] = fr->c6sum[q]*0.5*vr0_lj;
+ }
+ }
+
+ /* Apply surface dipole correction:
+ * correction = dipole_coeff * (dipole)^2
+ */
+ if (dipole_coeff != 0)
+ {
+ if (ewald_geometry == eewg3D)
+ {
+ Vdipole[q] = dipole_coeff*iprod(mutot[q], mutot[q]);
+ }
+ else if (ewald_geometry == eewg3DC)
+ {
+ Vdipole[q] = dipole_coeff*mutot[q][ZZ]*mutot[q][ZZ];
+ }
+ }
+ }
}
- }
-
- if (!bFreeEnergy) {
- enercorr = Vdipole[0] - Vself[0] - Vexcl;
- } else {
- enercorr = L1*(Vdipole[0] - Vself[0])
- + lambda*(Vdipole[1] - Vself[1])
- - Vexcl;
- *dvdlambda += Vdipole[1] - Vself[1]
- - (Vdipole[0] - Vself[0]) - dvdl_excl;
- }
-
- if (debug) {
- fprintf(debug,"Long Range corrections for Ewald interactions:\n");
- fprintf(debug,"start=%d,natoms=%d\n",start,end-start);
- fprintf(debug,"q2sum = %g, Vself=%g\n",
- L1*q2sumA+lambda*q2sumB,L1*Vself[0]+lambda*Vself[1]);
- fprintf(debug,"Long Range correction: Vexcl=%g\n",Vexcl);
- if (MASTER(cr) && thread == 0) {
- if (epsilon_surface > 0 || ewald_geometry == eewg3DC) {
- fprintf(debug,"Total dipole correction: Vdipole=%g\n",
- L1*Vdipole[0]+lambda*Vdipole[1]);
- }
+ if (!bFreeEnergy)
+ {
+ *Vcorr_q = Vdipole[0] - Vself_q[0] - Vexcl_q;
+ if (EVDW_PME(fr->vdwtype))
+ {
+ *Vcorr_lj = -Vself_lj[0] - Vexcl_lj;
+ }
+ }
+ else
+ {
+ *Vcorr_q = L1_q*(Vdipole[0] - Vself_q[0])
+ + lambda_q*(Vdipole[1] - Vself_q[1])
+ - Vexcl_q;
+ *dvdlambda_q += Vdipole[1] - Vself_q[1]
+ - (Vdipole[0] - Vself_q[0]) - dvdl_excl_q;
+ if (EVDW_PME(fr->vdwtype))
+ {
+ *Vcorr_lj = -(L1_lj*Vself_lj[0] + lambda_lj*Vself_lj[1]) - Vexcl_lj;
+ *dvdlambda_lj += -Vself_lj[1] + Vself_lj[0] - dvdl_excl_lj;
+ }
+ }
+
+ if (debug)
+ {
+ fprintf(debug, "Long Range corrections for Ewald interactions:\n");
+ fprintf(debug, "start=%d,natoms=%d\n", start, end-start);
+ fprintf(debug, "q2sum = %g, Vself_q=%g c6sum = %g, Vself_lj=%g\n",
+ L1_q*fr->q2sum[0]+lambda_q*fr->q2sum[1], L1_q*Vself_q[0]+lambda_q*Vself_q[1], L1_lj*fr->c6sum[0]+lambda_lj*fr->c6sum[1], L1_lj*Vself_lj[0]+lambda_lj*Vself_lj[1]);
+ fprintf(debug, "Electrostatic Long Range correction: Vexcl=%g\n", Vexcl_q);
+ fprintf(debug, "Lennard-Jones Long Range correction: Vexcl=%g\n", Vexcl_lj);
+ if (MASTER(cr) && thread == 0)
+ {
+ if (epsilon_surface > 0 || ewald_geometry == eewg3DC)
+ {
+ fprintf(debug, "Total dipole correction: Vdipole=%g\n",
+ L1_q*Vdipole[0]+lambda_q*Vdipole[1]);
+ }
+ }
}
- }
-
- /* Return the correction to the energy */
- return enercorr;
}
-real ewald_charge_correction(t_commrec *cr,t_forcerec *fr,real lambda,
+real ewald_charge_correction(t_commrec *cr, t_forcerec *fr, real lambda,
matrix box,
- real *dvdlambda,tensor vir)
+ real *dvdlambda, tensor vir)
{
- real vol,fac,qs2A,qs2B,vc,enercorr;
+ real vol, fac, qs2A, qs2B, vc, enercorr;
int d;
if (MASTER(cr))
/* Apply charge correction */
vol = box[XX][XX]*box[YY][YY]*box[ZZ][ZZ];
- fac = M_PI*ONE_4PI_EPS0/(fr->epsilon_r*2.0*vol*vol*sqr(fr->ewaldcoeff));
+ fac = M_PI*ONE_4PI_EPS0/(fr->epsilon_r*2.0*vol*vol*sqr(fr->ewaldcoeff_q));
- qs2A = fr->qsum[0]*fr->qsum[0];
- qs2B = fr->qsum[1]*fr->qsum[1];
+ qs2A = fr->qsum[0]*fr->qsum[0];
+ qs2B = fr->qsum[1]*fr->qsum[1];
vc = (qs2A*(1 - lambda) + qs2B*lambda)*fac;
- enercorr = -vol*vc;
+ enercorr = -vol*vc;
- *dvdlambda += -vol*(qs2B - qs2A)*fac;
+ *dvdlambda += -vol*(qs2B - qs2A)*fac;
- for(d=0; d<DIM; d++)
- {
- vir[d][d] += vc;
- }
+ for (d = 0; d < DIM; d++)
+ {
+ vir[d][d] += vc;
+ }
if (debug)
- {
- fprintf(debug,"Total charge correction: Vcharge=%g\n",enercorr);
+ {
+ fprintf(debug, "Total charge correction: Vcharge=%g\n", enercorr);
}
}
else