Page Menu
Home
c4science
Search
Configure Global Search
Log In
Files
F90774561
dihedral_charmmfsh.cpp
No One
Temporary
Actions
Download File
Edit File
Delete File
View Transforms
Subscribe
Mute Notifications
Award Token
Subscribers
None
File Metadata
Details
File Info
Storage
Attached
Created
Mon, Nov 4, 15:26
Size
14 KB
Mime Type
text/x-c
Expires
Wed, Nov 6, 15:26 (1 d, 23 h)
Engine
blob
Format
Raw Data
Handle
22132594
Attached To
rLAMMPS lammps
dihedral_charmmfsh.cpp
View Options
/* ----------------------------------------------------------------------
LAMMPS - Large-scale Atomic/Molecular Massively Parallel Simulator
http://lammps.sandia.gov, Sandia National Laboratories
Steve Plimpton, sjplimp@sandia.gov
Copyright (2003) Sandia Corporation. Under the terms of Contract
DE-AC04-94AL85000 with Sandia Corporation, the U.S. Government retains
certain rights in this software. This software is distributed under
the GNU General Public License.
See the README file in the top-level LAMMPS directory.
------------------------------------------------------------------------- */
/* ----------------------------------------------------------------------
Contributing author: Paul Crozier (SNL)
The force-shifted sections were provided by Robert Meissner
and Lucio Colombi Ciacchi of Bremen University, Bremen, Germany,
with additional assistance from Robert A. Latour, Clemson University
------------------------------------------------------------------------- */
#include <mpi.h>
#include <math.h>
#include <stdlib.h>
#include "dihedral_charmmfsh.h"
#include "atom.h"
#include "comm.h"
#include "neighbor.h"
#include "domain.h"
#include "force.h"
#include "pair.h"
#include "update.h"
#include "math_const.h"
#include "memory.h"
#include "error.h"
using namespace LAMMPS_NS;
using namespace MathConst;
#define TOLERANCE 0.05
/* ---------------------------------------------------------------------- */
DihedralCharmmfsh::DihedralCharmmfsh(LAMMPS *lmp) : Dihedral(lmp)
{
weightflag = 0;
writedata = 1;
}
/* ---------------------------------------------------------------------- */
DihedralCharmmfsh::~DihedralCharmmfsh()
{
if (allocated && !copymode) {
memory->destroy(setflag);
memory->destroy(k);
memory->destroy(multiplicity);
memory->destroy(shift);
memory->destroy(cos_shift);
memory->destroy(sin_shift);
memory->destroy(weight);
}
}
/* ---------------------------------------------------------------------- */
void DihedralCharmmfsh::compute(int eflag, int vflag)
{
int i1,i2,i3,i4,i,m,n,type;
double vb1x,vb1y,vb1z,vb2x,vb2y,vb2z,vb3x,vb3y,vb3z,vb2xm,vb2ym,vb2zm;
double edihedral,f1[3],f2[3],f3[3],f4[3];
double ax,ay,az,bx,by,bz,rasq,rbsq,rgsq,rg,rginv,ra2inv,rb2inv,rabinv;
double df,df1,ddf1,fg,hg,fga,hgb,gaa,gbb;
double dtfx,dtfy,dtfz,dtgx,dtgy,dtgz,dthx,dthy,dthz;
double c,s,p,sx2,sy2,sz2;
int itype,jtype;
double delx,dely,delz,rsq,r2inv,r6inv,r;
double forcecoul,forcelj,fpair,ecoul,evdwl;
edihedral = evdwl = ecoul = 0.0;
if (eflag || vflag) ev_setup(eflag,vflag);
else evflag = 0;
// insure pair->ev_tally() will use 1-4 virial contribution
if (weightflag && vflag_global == 2)
force->pair->vflag_either = force->pair->vflag_global = 1;
double **x = atom->x;
double **f = atom->f;
double *q = atom->q;
int *atomtype = atom->type;
int **dihedrallist = neighbor->dihedrallist;
int ndihedrallist = neighbor->ndihedrallist;
int nlocal = atom->nlocal;
int newton_bond = force->newton_bond;
double qqrd2e = force->qqrd2e;
for (n = 0; n < ndihedrallist; n++) {
i1 = dihedrallist[n][0];
i2 = dihedrallist[n][1];
i3 = dihedrallist[n][2];
i4 = dihedrallist[n][3];
type = dihedrallist[n][4];
// 1st bond
vb1x = x[i1][0] - x[i2][0];
vb1y = x[i1][1] - x[i2][1];
vb1z = x[i1][2] - x[i2][2];
// 2nd bond
vb2x = x[i3][0] - x[i2][0];
vb2y = x[i3][1] - x[i2][1];
vb2z = x[i3][2] - x[i2][2];
vb2xm = -vb2x;
vb2ym = -vb2y;
vb2zm = -vb2z;
// 3rd bond
vb3x = x[i4][0] - x[i3][0];
vb3y = x[i4][1] - x[i3][1];
vb3z = x[i4][2] - x[i3][2];
ax = vb1y*vb2zm - vb1z*vb2ym;
ay = vb1z*vb2xm - vb1x*vb2zm;
az = vb1x*vb2ym - vb1y*vb2xm;
bx = vb3y*vb2zm - vb3z*vb2ym;
by = vb3z*vb2xm - vb3x*vb2zm;
bz = vb3x*vb2ym - vb3y*vb2xm;
rasq = ax*ax + ay*ay + az*az;
rbsq = bx*bx + by*by + bz*bz;
rgsq = vb2xm*vb2xm + vb2ym*vb2ym + vb2zm*vb2zm;
rg = sqrt(rgsq);
rginv = ra2inv = rb2inv = 0.0;
if (rg > 0) rginv = 1.0/rg;
if (rasq > 0) ra2inv = 1.0/rasq;
if (rbsq > 0) rb2inv = 1.0/rbsq;
rabinv = sqrt(ra2inv*rb2inv);
c = (ax*bx + ay*by + az*bz)*rabinv;
s = rg*rabinv*(ax*vb3x + ay*vb3y + az*vb3z);
// error check
if (c > 1.0 + TOLERANCE || c < (-1.0 - TOLERANCE)) {
int me;
MPI_Comm_rank(world,&me);
if (screen) {
char str[128];
sprintf(str,"Dihedral problem: %d " BIGINT_FORMAT " "
TAGINT_FORMAT " " TAGINT_FORMAT " "
TAGINT_FORMAT " " TAGINT_FORMAT,
me,update->ntimestep,
atom->tag[i1],atom->tag[i2],atom->tag[i3],atom->tag[i4]);
error->warning(FLERR,str,0);
fprintf(screen," 1st atom: %d %g %g %g\n",
me,x[i1][0],x[i1][1],x[i1][2]);
fprintf(screen," 2nd atom: %d %g %g %g\n",
me,x[i2][0],x[i2][1],x[i2][2]);
fprintf(screen," 3rd atom: %d %g %g %g\n",
me,x[i3][0],x[i3][1],x[i3][2]);
fprintf(screen," 4th atom: %d %g %g %g\n",
me,x[i4][0],x[i4][1],x[i4][2]);
}
}
if (c > 1.0) c = 1.0;
if (c < -1.0) c = -1.0;
m = multiplicity[type];
p = 1.0;
ddf1 = df1 = 0.0;
for (i = 0; i < m; i++) {
ddf1 = p*c - df1*s;
df1 = p*s + df1*c;
p = ddf1;
}
p = p*cos_shift[type] + df1*sin_shift[type];
df1 = df1*cos_shift[type] - ddf1*sin_shift[type];
df1 *= -m;
p += 1.0;
if (m == 0) {
p = 1.0 + cos_shift[type];
df1 = 0.0;
}
if (eflag) edihedral = k[type] * p;
fg = vb1x*vb2xm + vb1y*vb2ym + vb1z*vb2zm;
hg = vb3x*vb2xm + vb3y*vb2ym + vb3z*vb2zm;
fga = fg*ra2inv*rginv;
hgb = hg*rb2inv*rginv;
gaa = -ra2inv*rg;
gbb = rb2inv*rg;
dtfx = gaa*ax;
dtfy = gaa*ay;
dtfz = gaa*az;
dtgx = fga*ax - hgb*bx;
dtgy = fga*ay - hgb*by;
dtgz = fga*az - hgb*bz;
dthx = gbb*bx;
dthy = gbb*by;
dthz = gbb*bz;
df = -k[type] * df1;
sx2 = df*dtgx;
sy2 = df*dtgy;
sz2 = df*dtgz;
f1[0] = df*dtfx;
f1[1] = df*dtfy;
f1[2] = df*dtfz;
f2[0] = sx2 - f1[0];
f2[1] = sy2 - f1[1];
f2[2] = sz2 - f1[2];
f4[0] = df*dthx;
f4[1] = df*dthy;
f4[2] = df*dthz;
f3[0] = -sx2 - f4[0];
f3[1] = -sy2 - f4[1];
f3[2] = -sz2 - f4[2];
// apply force to each of 4 atoms
if (newton_bond || i1 < nlocal) {
f[i1][0] += f1[0];
f[i1][1] += f1[1];
f[i1][2] += f1[2];
}
if (newton_bond || i2 < nlocal) {
f[i2][0] += f2[0];
f[i2][1] += f2[1];
f[i2][2] += f2[2];
}
if (newton_bond || i3 < nlocal) {
f[i3][0] += f3[0];
f[i3][1] += f3[1];
f[i3][2] += f3[2];
}
if (newton_bond || i4 < nlocal) {
f[i4][0] += f4[0];
f[i4][1] += f4[1];
f[i4][2] += f4[2];
}
if (evflag)
ev_tally(i1,i2,i3,i4,nlocal,newton_bond,edihedral,f1,f3,f4,
vb1x,vb1y,vb1z,vb2x,vb2y,vb2z,vb3x,vb3y,vb3z);
// 1-4 LJ and Coulomb interactions
// tally energy/virial in pair, using newton_bond as newton flag
if (weight[type] > 0.0) {
itype = atomtype[i1];
jtype = atomtype[i4];
delx = x[i1][0] - x[i4][0];
dely = x[i1][1] - x[i4][1];
delz = x[i1][2] - x[i4][2];
rsq = delx*delx + dely*dely + delz*delz;
r2inv = 1.0/rsq;
r6inv = r2inv*r2inv*r2inv;
// modifying coul and LJ force and energies to apply
// force_shift and force_switch as in CHARMM pairwise
// LJ interactions between 1-4 atoms should usually be
// for r < cut_inner, so switching not applied
r = sqrt(rsq);
if (implicit) forcecoul = qqrd2e * q[i1]*q[i4]*r2inv;
else if (dihedflag) forcecoul = qqrd2e * q[i1]*q[i4]*sqrt(r2inv);
else forcecoul = qqrd2e * q[i1]*q[i4]*(sqrt(r2inv) -
r*cut_coulinv14*cut_coulinv14);
forcelj = r6inv * (lj14_1[itype][jtype]*r6inv - lj14_2[itype][jtype]);
fpair = weight[type] * (forcelj+forcecoul)*r2inv;
if (eflag) {
if (dihedflag) ecoul = weight[type] * forcecoul;
else ecoul = weight[type] * qqrd2e * q[i1]*q[i4] *
(sqrt(r2inv) + r*cut_coulinv14*cut_coulinv14 -
2.0*cut_coulinv14);
evdwl14_12 = r6inv*lj14_3[itype][jtype]*r6inv -
lj14_3[itype][jtype]*cut_lj_inner6inv*cut_lj6inv;
evdwl14_6 = -lj14_4[itype][jtype]*r6inv +
lj14_4[itype][jtype]*cut_lj_inner3inv*cut_lj3inv;
evdwl = evdwl14_12 + evdwl14_6;
evdwl *= weight[type];
}
if (newton_bond || i1 < nlocal) {
f[i1][0] += delx*fpair;
f[i1][1] += dely*fpair;
f[i1][2] += delz*fpair;
}
if (newton_bond || i4 < nlocal) {
f[i4][0] -= delx*fpair;
f[i4][1] -= dely*fpair;
f[i4][2] -= delz*fpair;
}
if (evflag) force->pair->ev_tally(i1,i4,nlocal,newton_bond,
evdwl,ecoul,fpair,delx,dely,delz);
}
}
}
/* ---------------------------------------------------------------------- */
void DihedralCharmmfsh::allocate()
{
allocated = 1;
int n = atom->ndihedraltypes;
memory->create(k,n+1,"dihedral:k");
memory->create(multiplicity,n+1,"dihedral:k");
memory->create(shift,n+1,"dihedral:shift");
memory->create(cos_shift,n+1,"dihedral:cos_shift");
memory->create(sin_shift,n+1,"dihedral:sin_shift");
memory->create(weight,n+1,"dihedral:weight");
memory->create(setflag,n+1,"dihedral:setflag");
for (int i = 1; i <= n; i++) setflag[i] = 0;
}
/* ----------------------------------------------------------------------
set coeffs for one type
------------------------------------------------------------------------- */
void DihedralCharmmfsh::coeff(int narg, char **arg)
{
if (narg != 5) error->all(FLERR,"Incorrect args for dihedral coefficients");
if (!allocated) allocate();
int ilo,ihi;
force->bounds(FLERR,arg[0],atom->ndihedraltypes,ilo,ihi);
// require integer values of shift for backwards compatibility
// arbitrary phase angle shift could be allowed, but would break
// backwards compatibility and is probably not needed
double k_one = force->numeric(FLERR,arg[1]);
int multiplicity_one = force->inumeric(FLERR,arg[2]);
int shift_one = force->inumeric(FLERR,arg[3]);
double weight_one = force->numeric(FLERR,arg[4]);
if (multiplicity_one < 0)
error->all(FLERR,"Incorrect multiplicity arg for dihedral coefficients");
if (weight_one < 0.0 || weight_one > 1.0)
error->all(FLERR,"Incorrect weight arg for dihedral coefficients");
if (weight_one > 0.0) weightflag=1;
int count = 0;
for (int i = ilo; i <= ihi; i++) {
k[i] = k_one;
shift[i] = shift_one;
cos_shift[i] = cos(MY_PI*shift_one/180.0);
sin_shift[i] = sin(MY_PI*shift_one/180.0);
multiplicity[i] = multiplicity_one;
weight[i] = weight_one;
setflag[i] = 1;
count++;
}
if (count == 0) error->all(FLERR,"Incorrect args for dihedral coefficients");
}
/* ----------------------------------------------------------------------
error check and initialize all values needed for force computation
------------------------------------------------------------------------- */
void DihedralCharmmfsh::init_style()
{
// insure use of CHARMM pair_style if any weight factors are non-zero
// set local ptrs to LJ 14 arrays setup by Pair
if (weightflag) {
int itmp;
if (force->pair == NULL)
error->all(FLERR,"Dihedral charmmfsh is incompatible with Pair style");
lj14_1 = (double **) force->pair->extract("lj14_1",itmp);
lj14_2 = (double **) force->pair->extract("lj14_2",itmp);
lj14_3 = (double **) force->pair->extract("lj14_3",itmp);
lj14_4 = (double **) force->pair->extract("lj14_4",itmp);
int *ptr = (int *) force->pair->extract("implicit",itmp);
if (!lj14_1 || !lj14_2 || !lj14_3 || !lj14_4 || !ptr)
error->all(FLERR,"Dihedral charmmfsh is incompatible with Pair style");
implicit = *ptr;
}
// constants for applying force switch (LJ) and force_shift (coul)
// to 1/4 dihedral atoms to match CHARMM pairwise interactions
int itmp;
int *p_dihedflag = (int *) force->pair->extract("dihedflag",itmp);
double *p_cutljinner = (double *) force->pair->extract("cut_lj_inner",itmp);
double *p_cutlj = (double *) force->pair->extract("cut_lj",itmp);
double *p_cutcoul = (double *) force->pair->extract("cut_coul",itmp);
if (p_cutcoul == NULL || p_cutljinner == NULL ||
p_cutlj == NULL || p_dihedflag == NULL)
error->all(FLERR,"Dihedral charmmfsh is incompatible with Pair style");
dihedflag = *p_dihedflag;
cut_coul14 = *p_cutcoul;
cut_lj_inner14 = *p_cutljinner;
cut_lj14 = *p_cutlj;
cut_coulinv14 = 1/cut_coul14;
cut_lj_inner3inv = (1/cut_lj_inner14) * (1/cut_lj_inner14) *
(1/cut_lj_inner14);
cut_lj_inner6inv = cut_lj_inner3inv * cut_lj_inner3inv;
cut_lj3inv = (1/cut_lj14) * (1/cut_lj14) * (1/cut_lj14);
cut_lj6inv = cut_lj3inv * cut_lj3inv;
}
/* ----------------------------------------------------------------------
proc 0 writes out coeffs to restart file
------------------------------------------------------------------------- */
void DihedralCharmmfsh::write_restart(FILE *fp)
{
fwrite(&k[1],sizeof(double),atom->ndihedraltypes,fp);
fwrite(&multiplicity[1],sizeof(int),atom->ndihedraltypes,fp);
fwrite(&shift[1],sizeof(int),atom->ndihedraltypes,fp);
fwrite(&weight[1],sizeof(double),atom->ndihedraltypes,fp);
fwrite(&weightflag,sizeof(int),1,fp);
}
/* ----------------------------------------------------------------------
proc 0 reads coeffs from restart file, bcasts them
------------------------------------------------------------------------- */
void DihedralCharmmfsh::read_restart(FILE *fp)
{
allocate();
if (comm->me == 0) {
fread(&k[1],sizeof(double),atom->ndihedraltypes,fp);
fread(&multiplicity[1],sizeof(int),atom->ndihedraltypes,fp);
fread(&shift[1],sizeof(int),atom->ndihedraltypes,fp);
fread(&weight[1],sizeof(double),atom->ndihedraltypes,fp);
fread(&weightflag,sizeof(int),1,fp);
}
MPI_Bcast(&k[1],atom->ndihedraltypes,MPI_DOUBLE,0,world);
MPI_Bcast(&multiplicity[1],atom->ndihedraltypes,MPI_INT,0,world);
MPI_Bcast(&shift[1],atom->ndihedraltypes,MPI_INT,0,world);
MPI_Bcast(&weight[1],atom->ndihedraltypes,MPI_DOUBLE,0,world);
MPI_Bcast(&weightflag,1,MPI_INT,0,world);
for (int i = 1; i <= atom->ndihedraltypes; i++) {
setflag[i] = 1;
cos_shift[i] = cos(MY_PI*shift[i]/180.0);
sin_shift[i] = sin(MY_PI*shift[i]/180.0);
}
}
/* ----------------------------------------------------------------------
proc 0 writes to data file
------------------------------------------------------------------------- */
void DihedralCharmmfsh::write_data(FILE *fp)
{
for (int i = 1; i <= atom->ndihedraltypes; i++)
fprintf(fp,"%d %g %d %d %g\n",i,k[i],multiplicity[i],shift[i],weight[i]);
}
Event Timeline
Log In to Comment