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rLAMMPS lammps
pair_lubricate.cpp
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/* ----------------------------------------------------------------------
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 authors: Randy Schunk (SNL)
Amit Kumar and Michael Bybee (UIUC)
------------------------------------------------------------------------- */
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "pair_lubricate.h"
#include "atom.h"
#include "atom_vec.h"
#include "comm.h"
#include "force.h"
#include "neighbor.h"
#include "neigh_list.h"
#include "neigh_request.h"
#include "domain.h"
#include "modify.h"
#include "fix.h"
#include "fix_deform.h"
#include "fix_wall.h"
#include "input.h"
#include "variable.h"
#include "random_mars.h"
#include "math_const.h"
#include "memory.h"
#include "error.h"
using namespace LAMMPS_NS;
using namespace MathConst;
// same as fix_deform.cpp
enum{NO_REMAP,X_REMAP,V_REMAP};
// same as fix_wall.cpp
enum{EDGE,CONSTANT,VARIABLE};
/* ---------------------------------------------------------------------- */
PairLubricate::PairLubricate(LAMMPS *lmp) : Pair(lmp)
{
single_enable = 0;
// set comm size needed by this Pair
comm_forward = 6;
}
/* ---------------------------------------------------------------------- */
PairLubricate::~PairLubricate()
{
if (allocated) {
memory->destroy(setflag);
memory->destroy(cutsq);
memory->destroy(cut);
memory->destroy(cut_inner);
}
}
/* ---------------------------------------------------------------------- */
void PairLubricate::compute(int eflag, int vflag)
{
int i,j,ii,jj,inum,jnum,itype,jtype;
double xtmp,ytmp,ztmp,delx,dely,delz,fx,fy,fz,tx,ty,tz;
double rsq,r,h_sep,radi;
double vr1,vr2,vr3,vnnr,vn1,vn2,vn3;
double vt1,vt2,vt3,wt1,wt2,wt3,wdotn;
double vRS0;
double vi[3],vj[3],wi[3],wj[3],xl[3];
double a_sq,a_sh,a_pu;
int *ilist,*jlist,*numneigh,**firstneigh;
double lamda[3],vstream[3];
double vxmu2f = force->vxmu2f;
if (eflag || vflag) ev_setup(eflag,vflag);
else evflag = vflag_fdotr = 0;
double **x = atom->x;
double **v = atom->v;
double **f = atom->f;
double **omega = atom->omega;
double **torque = atom->torque;
double *radius = atom->radius;
int *type = atom->type;
int nlocal = atom->nlocal;
int newton_pair = force->newton_pair;
inum = list->inum;
ilist = list->ilist;
numneigh = list->numneigh;
firstneigh = list->firstneigh;
// subtract streaming component of velocity, omega, angmom
// assume fluid streaming velocity = box deformation rate
// vstream = (ux,uy,uz)
// ux = h_rate[0]*x + h_rate[5]*y + h_rate[4]*z
// uy = h_rate[1]*y + h_rate[3]*z
// uz = h_rate[2]*z
// omega_new = omega - curl(vstream)/2
// angmom_new = angmom - I*curl(vstream)/2
// Ef = (grad(vstream) + (grad(vstream))^T) / 2
if (shearing) {
double *h_rate = domain->h_rate;
double *h_ratelo = domain->h_ratelo;
for (ii = 0; ii < inum; ii++) {
i = ilist[ii];
itype = type[i];
radi = radius[i];
domain->x2lamda(x[i],lamda);
vstream[0] = h_rate[0]*lamda[0] + h_rate[5]*lamda[1] +
h_rate[4]*lamda[2] + h_ratelo[0];
vstream[1] = h_rate[1]*lamda[1] + h_rate[3]*lamda[2] + h_ratelo[1];
vstream[2] = h_rate[2]*lamda[2] + h_ratelo[2];
v[i][0] -= vstream[0];
v[i][1] -= vstream[1];
v[i][2] -= vstream[2];
omega[i][0] += 0.5*h_rate[3];
omega[i][1] -= 0.5*h_rate[4];
omega[i][2] += 0.5*h_rate[5];
}
// set Ef from h_rate in strain units
Ef[0][0] = h_rate[0]/domain->xprd;
Ef[1][1] = h_rate[1]/domain->yprd;
Ef[2][2] = h_rate[2]/domain->zprd;
Ef[0][1] = Ef[1][0] = 0.5 * h_rate[5]/domain->yprd;
Ef[0][2] = Ef[2][0] = 0.5 * h_rate[4]/domain->zprd;
Ef[1][2] = Ef[2][1] = 0.5 * h_rate[3]/domain->zprd;
// copy updated velocity/omega/angmom to the ghost particles
// no need to do this if not shearing since comm->ghost_velocity is set
comm->forward_comm_pair(this);
}
// This section of code adjusts R0/RT0/RS0 if necessary due to changes
// in the volume fraction as a result of fix deform or moving walls
double dims[3], wallcoord;
if (flagVF) // Flag for volume fraction corrections
if (flagdeform || flagwall == 2){ // Possible changes in volume fraction
if (flagdeform && !flagwall)
for (j = 0; j < 3; j++)
dims[j] = domain->prd[j];
else if (flagwall == 2 || (flagdeform && flagwall == 1)){
double wallhi[3], walllo[3];
for (int j = 0; j < 3; j++){
wallhi[j] = domain->prd[j];
walllo[j] = 0;
}
for (int m = 0; m < wallfix->nwall; m++){
int dim = wallfix->wallwhich[m] / 2;
int side = wallfix->wallwhich[m] % 2;
if (wallfix->xstyle[m] == VARIABLE){
wallcoord = input->variable->compute_equal(wallfix->xindex[m]);
}
else wallcoord = wallfix->coord0[m];
if (side == 0) walllo[dim] = wallcoord;
else wallhi[dim] = wallcoord;
}
for (int j = 0; j < 3; j++)
dims[j] = wallhi[j] - walllo[j];
}
double vol_T = dims[0]*dims[1]*dims[2];
double vol_f = vol_P/vol_T;
if (flaglog == 0) {
R0 = 6*MY_PI*mu*rad*(1.0 + 2.16*vol_f);
RT0 = 8*MY_PI*mu*pow(rad,3.0);
RS0 = 20.0/3.0*MY_PI*mu*pow(rad,3.0)*
(1.0 + 3.33*vol_f + 2.80*vol_f*vol_f);
} else {
R0 = 6*MY_PI*mu*rad*(1.0 + 2.725*vol_f - 6.583*vol_f*vol_f);
RT0 = 8*MY_PI*mu*pow(rad,3.0)*(1.0 + 0.749*vol_f - 2.469*vol_f*vol_f);
RS0 = 20.0/3.0*MY_PI*mu*pow(rad,3.0)*
(1.0 + 3.64*vol_f - 6.95*vol_f*vol_f);
}
}
// end of R0 adjustment code
for (ii = 0; ii < inum; ii++) {
i = ilist[ii];
xtmp = x[i][0];
ytmp = x[i][1];
ztmp = x[i][2];
itype = type[i];
radi = radius[i];
jlist = firstneigh[i];
jnum = numneigh[i];
// angular velocity
wi[0] = omega[i][0];
wi[1] = omega[i][1];
wi[2] = omega[i][2];
// FLD contribution to force and torque due to isotropic terms
// FLD contribution to stress from isotropic RS0
if (flagfld) {
f[i][0] -= vxmu2f*R0*v[i][0];
f[i][1] -= vxmu2f*R0*v[i][1];
f[i][2] -= vxmu2f*R0*v[i][2];
torque[i][0] -= vxmu2f*RT0*wi[0];
torque[i][1] -= vxmu2f*RT0*wi[1];
torque[i][2] -= vxmu2f*RT0*wi[2];
if (shearing && vflag_either) {
vRS0 = -vxmu2f * RS0;
v_tally_tensor(i,i,nlocal,newton_pair,
vRS0*Ef[0][0],vRS0*Ef[1][1],vRS0*Ef[2][2],
vRS0*Ef[0][1],vRS0*Ef[0][2],vRS0*Ef[1][2]);
}
}
if (!flagHI) continue;
for (jj = 0; jj < jnum; jj++) {
j = jlist[jj];
j &= NEIGHMASK;
delx = xtmp - x[j][0];
dely = ytmp - x[j][1];
delz = ztmp - x[j][2];
rsq = delx*delx + dely*dely + delz*delz;
jtype = type[j];
if (rsq < cutsq[itype][jtype]) {
r = sqrt(rsq);
// angular momentum = I*omega = 2/5 * M*R^2 * omega
wj[0] = omega[j][0];
wj[1] = omega[j][1];
wj[2] = omega[j][2];
// xl = point of closest approach on particle i from its center
xl[0] = -delx/r*radi;
xl[1] = -dely/r*radi;
xl[2] = -delz/r*radi;
// velocity at the point of closest approach on both particles
// v = v + omega_cross_xl - Ef.xl
// particle i
vi[0] = v[i][0] + (wi[1]*xl[2] - wi[2]*xl[1])
- (Ef[0][0]*xl[0] + Ef[0][1]*xl[1] + Ef[0][2]*xl[2]);
vi[1] = v[i][1] + (wi[2]*xl[0] - wi[0]*xl[2])
- (Ef[1][0]*xl[0] + Ef[1][1]*xl[1] + Ef[1][2]*xl[2]);
vi[2] = v[i][2] + (wi[0]*xl[1] - wi[1]*xl[0])
- (Ef[2][0]*xl[0] + Ef[2][1]*xl[1] + Ef[2][2]*xl[2]);
// particle j
vj[0] = v[j][0] - (wj[1]*xl[2] - wj[2]*xl[1])
+ (Ef[0][0]*xl[0] + Ef[0][1]*xl[1] + Ef[0][2]*xl[2]);
vj[1] = v[j][1] - (wj[2]*xl[0] - wj[0]*xl[2])
+ (Ef[1][0]*xl[0] + Ef[1][1]*xl[1] + Ef[1][2]*xl[2]);
vj[2] = v[j][2] - (wj[0]*xl[1] - wj[1]*xl[0])
+ (Ef[2][0]*xl[0] + Ef[2][1]*xl[1] + Ef[2][2]*xl[2]);
// scalar resistances XA and YA
h_sep = r - 2.0*radi;
// if less than the minimum gap use the minimum gap instead
if (r < cut_inner[itype][jtype])
h_sep = cut_inner[itype][jtype] - 2.0*radi;
// scale h_sep by radi
h_sep = h_sep/radi;
// scalar resistances
if (flaglog) {
a_sq = 6.0*MY_PI*mu*radi*(1.0/4.0/h_sep + 9.0/40.0*log(1.0/h_sep));
a_sh = 6.0*MY_PI*mu*radi*(1.0/6.0*log(1.0/h_sep));
a_pu = 8.0*MY_PI*mu*pow(radi,3.0)*(3.0/160.0*log(1.0/h_sep));
} else
a_sq = 6.0*MY_PI*mu*radi*(1.0/4.0/h_sep);
// relative velocity at the point of closest approach
// includes fluid velocity
vr1 = vi[0] - vj[0];
vr2 = vi[1] - vj[1];
vr3 = vi[2] - vj[2];
// normal component (vr.n)n
vnnr = (vr1*delx + vr2*dely + vr3*delz)/r;
vn1 = vnnr*delx/r;
vn2 = vnnr*dely/r;
vn3 = vnnr*delz/r;
// tangential component vr - (vr.n)n
vt1 = vr1 - vn1;
vt2 = vr2 - vn2;
vt3 = vr3 - vn3;
// force due to squeeze type motion
fx = a_sq*vn1;
fy = a_sq*vn2;
fz = a_sq*vn3;
// force due to all shear kind of motions
if (flaglog) {
fx = fx + a_sh*vt1;
fy = fy + a_sh*vt2;
fz = fz + a_sh*vt3;
}
// scale forces for appropriate units
fx *= vxmu2f;
fy *= vxmu2f;
fz *= vxmu2f;
// add to total force
f[i][0] -= fx;
f[i][1] -= fy;
f[i][2] -= fz;
if (newton_pair || j < nlocal) {
f[j][0] += fx;
f[j][1] += fy;
f[j][2] += fz;
}
// torque due to this force
if (flaglog) {
tx = xl[1]*fz - xl[2]*fy;
ty = xl[2]*fx - xl[0]*fz;
tz = xl[0]*fy - xl[1]*fx;
torque[i][0] -= vxmu2f*tx;
torque[i][1] -= vxmu2f*ty;
torque[i][2] -= vxmu2f*tz;
if (newton_pair || j < nlocal) {
torque[j][0] -= vxmu2f*tx;
torque[j][1] -= vxmu2f*ty;
torque[j][2] -= vxmu2f*tz;
}
// torque due to a_pu
wdotn = ((wi[0]-wj[0])*delx + (wi[1]-wj[1])*dely +
(wi[2]-wj[2])*delz)/r;
wt1 = (wi[0]-wj[0]) - wdotn*delx/r;
wt2 = (wi[1]-wj[1]) - wdotn*dely/r;
wt3 = (wi[2]-wj[2]) - wdotn*delz/r;
tx = a_pu*wt1;
ty = a_pu*wt2;
tz = a_pu*wt3;
torque[i][0] -= vxmu2f*tx;
torque[i][1] -= vxmu2f*ty;
torque[i][2] -= vxmu2f*tz;
if (newton_pair || j < nlocal) {
torque[j][0] += vxmu2f*tx;
torque[j][1] += vxmu2f*ty;
torque[j][2] += vxmu2f*tz;
}
}
if (evflag) ev_tally_xyz(i,j,nlocal,newton_pair,
0.0,0.0,-fx,-fy,-fz,delx,dely,delz);
}
}
}
// restore streaming component of velocity, omega, angmom
if (shearing) {
double *h_rate = domain->h_rate;
double *h_ratelo = domain->h_ratelo;
for (ii = 0; ii < inum; ii++) {
i = ilist[ii];
itype = type[i];
radi = radius[i];
domain->x2lamda(x[i],lamda);
vstream[0] = h_rate[0]*lamda[0] + h_rate[5]*lamda[1] +
h_rate[4]*lamda[2] + h_ratelo[0];
vstream[1] = h_rate[1]*lamda[1] + h_rate[3]*lamda[2] + h_ratelo[1];
vstream[2] = h_rate[2]*lamda[2] + h_ratelo[2];
v[i][0] += vstream[0];
v[i][1] += vstream[1];
v[i][2] += vstream[2];
omega[i][0] -= 0.5*h_rate[3];
omega[i][1] += 0.5*h_rate[4];
omega[i][2] -= 0.5*h_rate[5];
}
}
if (vflag_fdotr) virial_fdotr_compute();
}
/* ----------------------------------------------------------------------
allocate all arrays
------------------------------------------------------------------------- */
void PairLubricate::allocate()
{
allocated = 1;
int n = atom->ntypes;
memory->create(setflag,n+1,n+1,"pair:setflag");
for (int i = 1; i <= n; i++)
for (int j = i; j <= n; j++)
setflag[i][j] = 0;
memory->create(cutsq,n+1,n+1,"pair:cutsq");
memory->create(cut,n+1,n+1,"pair:cut");
memory->create(cut_inner,n+1,n+1,"pair:cut_inner");
}
/* ----------------------------------------------------------------------
global settings
------------------------------------------------------------------------- */
void PairLubricate::settings(int narg, char **arg)
{
if (narg != 5 && narg != 7) error->all(FLERR,"Illegal pair_style command");
mu = force->numeric(FLERR,arg[0]);
flaglog = force->inumeric(FLERR,arg[1]);
flagfld = force->inumeric(FLERR,arg[2]);
cut_inner_global = force->numeric(FLERR,arg[3]);
cut_global = force->numeric(FLERR,arg[4]);
flagHI = flagVF = 1;
if (narg == 7) {
flagHI = force->inumeric(FLERR,arg[5]);
flagVF = force->inumeric(FLERR,arg[6]);
}
if (flaglog == 1 && flagHI == 0) {
error->warning(FLERR,"Cannot include log terms without 1/r terms; "
"setting flagHI to 1");
flagHI = 1;
}
// reset cutoffs that have been explicitly set
if (allocated) {
for (int i = 1; i <= atom->ntypes; i++)
for (int j = i; j <= atom->ntypes; j++)
if (setflag[i][j]) {
cut_inner[i][j] = cut_inner_global;
cut[i][j] = cut_global;
}
}
}
/* ----------------------------------------------------------------------
set coeffs for one or more type pairs
------------------------------------------------------------------------- */
void PairLubricate::coeff(int narg, char **arg)
{
if (narg != 2 && narg != 4)
error->all(FLERR,"Incorrect args for pair coefficients");
if (!allocated) allocate();
int ilo,ihi,jlo,jhi;
force->bounds(FLERR,arg[0],atom->ntypes,ilo,ihi);
force->bounds(FLERR,arg[1],atom->ntypes,jlo,jhi);
double cut_inner_one = cut_inner_global;
double cut_one = cut_global;
if (narg == 4) {
cut_inner_one = force->numeric(FLERR,arg[2]);
cut_one = force->numeric(FLERR,arg[3]);
}
int count = 0;
for (int i = ilo; i <= ihi; i++) {
for (int j = MAX(jlo,i); j <= jhi; j++) {
cut_inner[i][j] = cut_inner_one;
cut[i][j] = cut_one;
setflag[i][j] = 1;
count++;
}
}
if (count == 0) error->all(FLERR,"Incorrect args for pair coefficients");
}
/* ----------------------------------------------------------------------
init specific to this pair style
------------------------------------------------------------------------- */
void PairLubricate::init_style()
{
if (!atom->sphere_flag)
error->all(FLERR,"Pair lubricate requires atom style sphere");
if (comm->ghost_velocity == 0)
error->all(FLERR,"Pair lubricate requires ghost atoms store velocity");
neighbor->request(this,instance_me);
// require that atom radii are identical within each type
// require monodisperse system with same radii for all types
double radtype;
for (int i = 1; i <= atom->ntypes; i++) {
if (!atom->radius_consistency(i,radtype))
error->all(FLERR,"Pair lubricate requires monodisperse particles");
if (i > 1 && radtype != rad)
error->all(FLERR,"Pair lubricate requires monodisperse particles");
rad = radtype;
}
// check for fix deform, if exists it must use "remap v"
// If box will change volume, set appropriate flag so that volume
// and v.f. corrections are re-calculated at every step.
//
// If available volume is different from box volume
// due to walls, set volume appropriately; if walls will
// move, set appropriate flag so that volume and v.f. corrections
// are re-calculated at every step.
shearing = flagdeform = flagwall = 0;
for (int i = 0; i < modify->nfix; i++){
if (strcmp(modify->fix[i]->style,"deform") == 0) {
shearing = flagdeform = 1;
if (((FixDeform *) modify->fix[i])->remapflag != V_REMAP)
error->all(FLERR,"Using pair lubricate with inconsistent "
"fix deform remap option");
}
if (strstr(modify->fix[i]->style,"wall") != NULL) {
if (flagwall)
error->all(FLERR,
"Cannot use multiple fix wall commands with pair lubricate");
flagwall = 1; // Walls exist
wallfix = (FixWall *) modify->fix[i];
if (wallfix->xflag) flagwall = 2; // Moving walls exist
}
}
// set the isotropic constants that depend on the volume fraction
// vol_T = total volume
double vol_T;
double wallcoord;
if (!flagwall) vol_T = domain->xprd*domain->yprd*domain->zprd;
else {
double wallhi[3], walllo[3];
for (int j = 0; j < 3; j++){
wallhi[j] = domain->prd[j];
walllo[j] = 0;
}
for (int m = 0; m < wallfix->nwall; m++){
int dim = wallfix->wallwhich[m] / 2;
int side = wallfix->wallwhich[m] % 2;
if (wallfix->xstyle[m] == VARIABLE){
wallfix->xindex[m] = input->variable->find(wallfix->xstr[m]);
//Since fix->wall->init happens after pair->init_style
wallcoord = input->variable->compute_equal(wallfix->xindex[m]);
}
else wallcoord = wallfix->coord0[m];
if (side == 0) walllo[dim] = wallcoord;
else wallhi[dim] = wallcoord;
}
vol_T = (wallhi[0] - walllo[0]) * (wallhi[1] - walllo[1]) *
(wallhi[2] - walllo[2]);
}
// vol_P = volume of particles, assuming monodispersity
// vol_f = volume fraction
vol_P = atom->natoms*(4.0/3.0)*MY_PI*pow(rad,3.0);
double vol_f = vol_P/vol_T;
if (!flagVF) vol_f = 0;
// set isotropic constants for FLD
if (flaglog == 0) {
R0 = 6*MY_PI*mu*rad*(1.0 + 2.16*vol_f);
RT0 = 8*MY_PI*mu*pow(rad,3.0);
RS0 = 20.0/3.0*MY_PI*mu*pow(rad,3.0)*(1.0 + 3.33*vol_f + 2.80*vol_f*vol_f);
} else {
R0 = 6*MY_PI*mu*rad*(1.0 + 2.725*vol_f - 6.583*vol_f*vol_f);
RT0 = 8*MY_PI*mu*pow(rad,3.0)*(1.0 + 0.749*vol_f - 2.469*vol_f*vol_f);
RS0 = 20.0/3.0*MY_PI*mu*pow(rad,3.0)*(1.0 + 3.64*vol_f - 6.95*vol_f*vol_f);
}
// set Ef = 0 since used whether shearing or not
Ef[0][0] = Ef[0][1] = Ef[0][2] = 0.0;
Ef[1][0] = Ef[1][1] = Ef[1][2] = 0.0;
Ef[2][0] = Ef[2][1] = Ef[2][2] = 0.0;
}
/* ----------------------------------------------------------------------
init for one type pair i,j and corresponding j,i
------------------------------------------------------------------------- */
double PairLubricate::init_one(int i, int j)
{
if (setflag[i][j] == 0) {
cut_inner[i][j] = mix_distance(cut_inner[i][i],cut_inner[j][j]);
cut[i][j] = mix_distance(cut[i][i],cut[j][j]);
}
cut_inner[j][i] = cut_inner[i][j];
return cut[i][j];
}
/* ----------------------------------------------------------------------
proc 0 writes to restart file
------------------------------------------------------------------------- */
void PairLubricate::write_restart(FILE *fp)
{
write_restart_settings(fp);
int i,j;
for (i = 1; i <= atom->ntypes; i++)
for (j = i; j <= atom->ntypes; j++) {
fwrite(&setflag[i][j],sizeof(int),1,fp);
if (setflag[i][j]) {
fwrite(&cut_inner[i][j],sizeof(double),1,fp);
fwrite(&cut[i][j],sizeof(double),1,fp);
}
}
}
/* ----------------------------------------------------------------------
proc 0 reads from restart file, bcasts
------------------------------------------------------------------------- */
void PairLubricate::read_restart(FILE *fp)
{
read_restart_settings(fp);
allocate();
int i,j;
int me = comm->me;
for (i = 1; i <= atom->ntypes; i++)
for (j = i; j <= atom->ntypes; j++) {
if (me == 0) fread(&setflag[i][j],sizeof(int),1,fp);
MPI_Bcast(&setflag[i][j],1,MPI_INT,0,world);
if (setflag[i][j]) {
if (me == 0) {
fread(&cut_inner[i][j],sizeof(double),1,fp);
fread(&cut[i][j],sizeof(double),1,fp);
}
MPI_Bcast(&cut_inner[i][j],1,MPI_DOUBLE,0,world);
MPI_Bcast(&cut[i][j],1,MPI_DOUBLE,0,world);
}
}
}
/* ----------------------------------------------------------------------
proc 0 writes to restart file
------------------------------------------------------------------------- */
void PairLubricate::write_restart_settings(FILE *fp)
{
fwrite(&mu,sizeof(double),1,fp);
fwrite(&flaglog,sizeof(int),1,fp);
fwrite(&flagfld,sizeof(int),1,fp);
fwrite(&cut_inner_global,sizeof(double),1,fp);
fwrite(&cut_global,sizeof(double),1,fp);
fwrite(&offset_flag,sizeof(int),1,fp);
fwrite(&mix_flag,sizeof(int),1,fp);
fwrite(&flagHI,sizeof(int),1,fp);
fwrite(&flagVF,sizeof(int),1,fp);
}
/* ----------------------------------------------------------------------
proc 0 reads from restart file, bcasts
------------------------------------------------------------------------- */
void PairLubricate::read_restart_settings(FILE *fp)
{
int me = comm->me;
if (me == 0) {
fread(&mu,sizeof(double),1,fp);
fread(&flaglog,sizeof(int),1,fp);
fread(&flagfld,sizeof(int),1,fp);
fread(&cut_inner_global,sizeof(double),1,fp);
fread(&cut_global,sizeof(double),1,fp);
fread(&offset_flag,sizeof(int),1,fp);
fread(&mix_flag,sizeof(int),1,fp);
fread(&flagHI,sizeof(int),1,fp);
fread(&flagVF,sizeof(int),1,fp);
}
MPI_Bcast(&mu,1,MPI_DOUBLE,0,world);
MPI_Bcast(&flaglog,1,MPI_INT,0,world);
MPI_Bcast(&flagfld,1,MPI_INT,0,world);
MPI_Bcast(&cut_inner_global,1,MPI_DOUBLE,0,world);
MPI_Bcast(&cut_global,1,MPI_DOUBLE,0,world);
MPI_Bcast(&offset_flag,1,MPI_INT,0,world);
MPI_Bcast(&mix_flag,1,MPI_INT,0,world);
MPI_Bcast(&flagHI,1,MPI_INT,0,world);
MPI_Bcast(&flagVF,1,MPI_INT,0,world);
}
/* ---------------------------------------------------------------------- */
int PairLubricate::pack_forward_comm(int n, int *list, double *buf,
int pbc_flag, int *pbc)
{
int i,j,m;
double **v = atom->v;
double **omega = atom->omega;
m = 0;
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = v[j][0];
buf[m++] = v[j][1];
buf[m++] = v[j][2];
buf[m++] = omega[j][0];
buf[m++] = omega[j][1];
buf[m++] = omega[j][2];
}
return m;
}
/* ---------------------------------------------------------------------- */
void PairLubricate::unpack_forward_comm(int n, int first, double *buf)
{
int i,m,last;
double **v = atom->v;
double **omega = atom->omega;
m = 0;
last = first + n;
for (i = first; i < last; i++) {
v[i][0] = buf[m++];
v[i][1] = buf[m++];
v[i][2] = buf[m++];
omega[i][0] = buf[m++];
omega[i][1] = buf[m++];
omega[i][2] = buf[m++];
}
}
/* ----------------------------------------------------------------------
check if name is recognized, return integer index for that name
if name not recognized, return -1
if type pair setting, return -2 if no type pairs are set
------------------------------------------------------------------------- */
int PairLubricate::pre_adapt(char *name, int ilo, int ihi, int jlo, int jhi)
{
if (strcmp(name,"mu") == 0) return 0;
return -1;
}
/* ----------------------------------------------------------------------
adapt parameter indexed by which
change all pair variables affected by the reset parameter
if type pair setting, set I-J and J-I coeffs
------------------------------------------------------------------------- */
void PairLubricate::adapt(int which, int ilo, int ihi, int jlo, int jhi,
double value)
{
mu = value;
}
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