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atom_vec_wavepacket.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 author: Ilya Valuev (JIHT, Moscow, Russia)
------------------------------------------------------------------------- */
#include "math.h"
#include "stdlib.h"
#include "atom_vec_wavepacket.h"
#include "atom.h"
#include "comm.h"
#include "domain.h"
#include "modify.h"
#include "force.h"
#include "fix.h"
#include "memory.h"
#include "error.h"
using namespace LAMMPS_NS;
#define DELTA 10000
/* ---------------------------------------------------------------------- */
AtomVecWavepacket::AtomVecWavepacket(LAMMPS *lmp, int narg, char **arg) :
AtomVec(lmp, narg, arg)
{
comm_x_only = comm_f_only = 0;
mass_type = 1;
molecular = 0;
size_forward = 4; // coords[3]+radius[1]
size_reverse = 10; // force[3]+erforce[1]+ervelforce[1]+vforce[3]+csforce[2]
size_border = 10; // coords[3]+tag[1]+type[1]+mask[1]+q[1]+spin[1]+eradius[1]+etag[1]
size_velocity = 6; // +velocities[3]+ ervel[1]+cs[2]
size_data_atom = 11; // for input file: 1-tag 2-type 3-q 4-spin 5-eradius 6-etag 7-cs_re 8-cs_im 9-x 10-y 11-z
size_data_vel = 5; // for input file: vx vy vz ervel <??>
xcol_data = 9; // starting column for x data
atom->wavepacket_flag = 1;
atom->electron_flag = 1; // compatible with eff
atom->q_flag = atom->spin_flag = atom->eradius_flag =
atom->ervel_flag = atom->erforce_flag = 1;
atom->cs_flag = atom->csforce_flag = atom->vforce_flag = atom->ervelforce_flag = atom->etag_flag = 1;
}
/* ----------------------------------------------------------------------
grow atom-electron arrays
n = 0 grows arrays by DELTA
n > 0 allocates arrays to size n
------------------------------------------------------------------------- */
void AtomVecWavepacket::grow(int n)
{
if (n == 0) nmax += DELTA;
else nmax = n;
atom->nmax = nmax;
tag = memory->grow(atom->tag,nmax,"atom:tag");
type = memory->grow(atom->type,nmax,"atom:type");
mask = memory->grow(atom->mask,nmax,"atom:mask");
image = memory->grow(atom->image,nmax,"atom:image");
x = memory->grow(atom->x,nmax,3,"atom:x");
v = memory->grow(atom->v,nmax,3,"atom:v");
f = memory->grow(atom->f,nmax*comm->nthreads,3,"atom:f");
q = memory->grow(atom->q,nmax,"atom:q");
spin = memory->grow(atom->spin,nmax,"atom:spin");
eradius = memory->grow(atom->eradius,nmax,"atom:eradius");
ervel = memory->grow(atom->ervel,nmax,"atom:ervel");
erforce = memory->grow(atom->erforce,nmax*comm->nthreads,"atom:erforce");
cs = memory->grow(atom->cs,2*nmax,"atom:cs");
csforce = memory->grow(atom->csforce,2*nmax,"atom:csforce");
vforce = memory->grow(atom->vforce,3*nmax,"atom:vforce");
ervelforce = memory->grow(atom->ervelforce,nmax,"atom:ervelforce");
etag = memory->grow(atom->etag,nmax,"atom:etag");
if (atom->nextra_grow)
for (int iextra = 0; iextra < atom->nextra_grow; iextra++)
modify->fix[atom->extra_grow[iextra]]->grow_arrays(nmax);
}
/* ----------------------------------------------------------------------
reset local array ptrs
------------------------------------------------------------------------- */
void AtomVecWavepacket::grow_reset()
{
tag = atom->tag; type = atom->type;
mask = atom->mask; image = atom->image;
x = atom->x; v = atom->v; f = atom->f;
q = atom->q;
eradius = atom->eradius; ervel = atom->ervel; erforce = atom->erforce;
cs = atom->cs;
csforce = atom->csforce;
vforce = atom->vforce;
ervelforce = atom->ervelforce;
etag = atom->etag;
}
/* ----------------------------------------------------------------------
copy atom I info to atom J
------------------------------------------------------------------------- */
void AtomVecWavepacket::copy(int i, int j, int delflag)
{
tag[j] = tag[i];
type[j] = type[i];
mask[j] = mask[i];
image[j] = image[i];
x[j][0] = x[i][0];
x[j][1] = x[i][1];
x[j][2] = x[i][2];
v[j][0] = v[i][0];
v[j][1] = v[i][1];
v[j][2] = v[i][2];
q[j] = q[i];
spin[j] = spin[i];
eradius[j] = eradius[i];
ervel[j] = ervel[i];
cs[2*j] = cs[2*i];
cs[2*j+1] = cs[2*i+1];
etag[j] = etag[i];
if (atom->nextra_grow)
for (int iextra = 0; iextra < atom->nextra_grow; iextra++)
modify->fix[atom->extra_grow[iextra]]->copy_arrays(i,j);
}
/* ---------------------------------------------------------------------- */
// this will be used as partial pack for unsplit Hartree packets (v, ervel not regarded as separate variables)
int AtomVecWavepacket::pack_comm(int n, int *list, double *buf,
int pbc_flag, int *pbc)
{
int i,j,m;
double dx,dy,dz;
m = 0;
if (pbc_flag == 0) {
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = x[j][0];
buf[m++] = x[j][1];
buf[m++] = x[j][2];
buf[m++] = eradius[j];
}
} else {
if (domain->triclinic == 0) {
dx = pbc[0]*domain->xprd;
dy = pbc[1]*domain->yprd;
dz = pbc[2]*domain->zprd;
} else {
dx = pbc[0]*domain->xprd + pbc[5]*domain->xy + pbc[4]*domain->xz;
dy = pbc[1]*domain->yprd + pbc[3]*domain->yz;
dz = pbc[2]*domain->zprd;
}
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = x[j][0] + dx;
buf[m++] = x[j][1] + dy;
buf[m++] = x[j][2] + dz;
buf[m++] = eradius[j];
}
}
return m;
}
/* ---------------------------------------------------------------------- */
// this is a complete pack of all 'position' variables of AWPMD
int AtomVecWavepacket::pack_comm_vel(int n, int *list, double *buf,
int pbc_flag, int *pbc)
{
int i,j,m;
double dx,dy,dz,dvx,dvy,dvz;
m = 0;
if (pbc_flag == 0) {
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = x[j][0];
buf[m++] = x[j][1];
buf[m++] = x[j][2];
buf[m++] = eradius[j];
buf[m++] = v[j][0];
buf[m++] = v[j][1];
buf[m++] = v[j][2];
buf[m++] = ervel[j];
buf[m++] = cs[2*j];
buf[m++] = cs[2*j+1];
}
} else {
if (domain->triclinic == 0) {
dx = pbc[0]*domain->xprd;
dy = pbc[1]*domain->yprd;
dz = pbc[2]*domain->zprd;
} else {
dx = pbc[0]*domain->xprd + pbc[5]*domain->xy + pbc[4]*domain->xz;
dy = pbc[1]*domain->yprd + pbc[3]*domain->yz;
dz = pbc[2]*domain->zprd;
}
if (!deform_vremap) {
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = x[j][0] + dx;
buf[m++] = x[j][1] + dy;
buf[m++] = x[j][2] + dz;
buf[m++] = eradius[j];
buf[m++] = v[j][0];
buf[m++] = v[j][1];
buf[m++] = v[j][2];
buf[m++] = ervel[j];
buf[m++] = cs[2*j];
buf[m++] = cs[2*j+1];
}
} else {
dvx = pbc[0]*h_rate[0] + pbc[5]*h_rate[5] + pbc[4]*h_rate[4];
dvy = pbc[1]*h_rate[1] + pbc[3]*h_rate[3];
dvz = pbc[2]*h_rate[2];
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = x[j][0] + dx;
buf[m++] = x[j][1] + dy;
buf[m++] = x[j][2] + dz;
buf[m++] = eradius[j];
if (mask[i] & deform_groupbit) {
buf[m++] = v[j][0] + dvx;
buf[m++] = v[j][1] + dvy;
buf[m++] = v[j][2] + dvz;
} else {
buf[m++] = v[j][0];
buf[m++] = v[j][1];
buf[m++] = v[j][2];
}
buf[m++] = ervel[j];
buf[m++] = cs[2*j];
buf[m++] = cs[2*j+1];
}
}
}
return m;
}
/* ---------------------------------------------------------------------- */
int AtomVecWavepacket::pack_comm_hybrid(int n, int *list, double *buf)
{
int i,j,m;
m = 0;
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = eradius[j];
buf[m++] = ervel[j];
buf[m++] = cs[2*j];
buf[m++] = cs[2*j+1];
}
return m;
}
/* ---------------------------------------------------------------------- */
void AtomVecWavepacket::unpack_comm(int n, int first, double *buf)
{
int i,m,last;
m = 0;
last = first + n;
for (i = first; i < last; i++) {
x[i][0] = buf[m++];
x[i][1] = buf[m++];
x[i][2] = buf[m++];
eradius[i] = buf[m++];
}
}
/* ---------------------------------------------------------------------- */
void AtomVecWavepacket::unpack_comm_vel(int n, int first, double *buf)
{
int i,m,last;
m = 0;
last = first + n;
for (i = first; i < last; i++) {
x[i][0] = buf[m++];
x[i][1] = buf[m++];
x[i][2] = buf[m++];
eradius[i] = buf[m++];
v[i][0] = buf[m++];
v[i][1] = buf[m++];
v[i][2] = buf[m++];
ervel[i] = buf[m++];
cs[2*i] = buf[m++];
cs[2*i+1] = buf[m++];
}
}
/* ---------------------------------------------------------------------- */
int AtomVecWavepacket::unpack_comm_hybrid(int n, int first, double *buf)
{
int i,m,last;
m = 0;
last = first + n;
for (i = first; i < last; i++){
eradius[i] = buf[m++];
ervel[i] = buf[m++];
cs[2*i] = buf[m++];
cs[2*i+1] = buf[m++];
}
return m;
}
/* ---------------------------------------------------------------------- */
int AtomVecWavepacket::pack_reverse(int n, int first, double *buf)
{
int i,m,last;
m = 0;
last = first + n;
for (i = first; i < last; i++) { //10
buf[m++] = f[i][0];
buf[m++] = f[i][1];
buf[m++] = f[i][2];
buf[m++] = erforce[i];
buf[m++] = ervelforce[i];
buf[m++] = vforce[3*i];
buf[m++] = vforce[3*i+1];
buf[m++] = vforce[3*i+2];
buf[m++] = csforce[2*i];
buf[m++] = csforce[2*i+1];
}
return m;
}
/* ---------------------------------------------------------------------- */
int AtomVecWavepacket::pack_reverse_hybrid(int n, int first, double *buf)
{
int i,m,last;
m = 0;
last = first + n;
for (i = first; i < last; i++){
buf[m++] = erforce[i];
buf[m++] = ervelforce[i];
buf[m++] = vforce[3*i];
buf[m++] = vforce[3*i+1];
buf[m++] = vforce[3*i+2];
buf[m++] = csforce[2*i];
buf[m++] = csforce[2*i+1];
}
return m;
}
/* ---------------------------------------------------------------------- */
void AtomVecWavepacket::unpack_reverse(int n, int *list, double *buf)
{
int i,j,m;
m = 0;
for (i = 0; i < n; i++) {
j = list[i];
f[j][0] += buf[m++];
f[j][1] += buf[m++];
f[j][2] += buf[m++];
erforce[j] += buf[m++];
ervelforce[j] += buf[m++];
vforce[3*j] += buf[m++];
vforce[3*j+1] += buf[m++];
vforce[3*j+2] += buf[m++];
csforce[2*j] += buf[m++];
csforce[2*j+1] += buf[m++];
}
}
/* ---------------------------------------------------------------------- */
int AtomVecWavepacket::unpack_reverse_hybrid(int n, int *list, double *buf)
{
int i,j,m;
m = 0;
for (i = 0; i < n; i++) {
j = list[i];
erforce[j] += buf[m++];
ervelforce[j] += buf[m++];
vforce[3*j] += buf[m++];
vforce[3*j+1] += buf[m++];
vforce[3*j+2] += buf[m++];
csforce[2*j] += buf[m++];
csforce[2*j+1] += buf[m++];
}
return m;
}
/* ---------------------------------------------------------------------- */
// will be used for Hartree unsplit version (the etag is added however)
int AtomVecWavepacket::pack_border(int n, int *list, double *buf,
int pbc_flag, int *pbc)
{
int i,j,m;
double dx,dy,dz;
m = 0;
if (pbc_flag == 0) {
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = x[j][0];
buf[m++] = x[j][1];
buf[m++] = x[j][2];
buf[m++] = tag[j];
buf[m++] = type[j];
buf[m++] = mask[j];
buf[m++] = q[j];
buf[m++] = spin[j];
buf[m++] = eradius[j];
buf[m++] = etag[j];
}
} else {
if (domain->triclinic == 0) {
dx = pbc[0]*domain->xprd;
dy = pbc[1]*domain->yprd;
dz = pbc[2]*domain->zprd;
} else {
dx = pbc[0];
dy = pbc[1];
dz = pbc[2];
}
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = x[j][0] + dx;
buf[m++] = x[j][1] + dy;
buf[m++] = x[j][2] + dz;
buf[m++] = tag[j];
buf[m++] = type[j];
buf[m++] = mask[j];
buf[m++] = q[j];
buf[m++] = spin[j];
buf[m++] = eradius[j];
buf[m++] = etag[j];
}
}
return m;
}
/* ---------------------------------------------------------------------- */
int AtomVecWavepacket::pack_border_vel(int n, int *list, double *buf,
int pbc_flag, int *pbc)
{
int i,j,m;
double dx,dy,dz,dvx,dvy,dvz;
m = 0;
if (pbc_flag == 0) {
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = x[j][0];
buf[m++] = x[j][1];
buf[m++] = x[j][2];
buf[m++] = tag[j];
buf[m++] = type[j];
buf[m++] = mask[j];
buf[m++] = q[j];
buf[m++] = spin[j];
buf[m++] = eradius[j];
buf[m++] = etag[j];
buf[m++] = v[j][0];
buf[m++] = v[j][1];
buf[m++] = v[j][2];
buf[m++] = ervel[j];
buf[m++] = cs[2*j];
buf[m++] = cs[2*j+1];
}
} else {
if (domain->triclinic == 0) {
dx = pbc[0]*domain->xprd;
dy = pbc[1]*domain->yprd;
dz = pbc[2]*domain->zprd;
} else {
dx = pbc[0];
dy = pbc[1];
dz = pbc[2];
}
if (domain->triclinic == 0) {
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = x[j][0] + dx;
buf[m++] = x[j][1] + dy;
buf[m++] = x[j][2] + dz;
buf[m++] = tag[j];
buf[m++] = type[j];
buf[m++] = mask[j];
buf[m++] = q[j];
buf[m++] = spin[j];
buf[m++] = eradius[j];
buf[m++] = etag[j];
buf[m++] = v[j][0];
buf[m++] = v[j][1];
buf[m++] = v[j][2];
buf[m++] = ervel[j];
buf[m++] = cs[2*j];
buf[m++] = cs[2*j+1];
}
} else {
dvx = pbc[0]*h_rate[0] + pbc[5]*h_rate[5] + pbc[4]*h_rate[4];
dvy = pbc[1]*h_rate[1] + pbc[3]*h_rate[3];
dvz = pbc[2]*h_rate[2];
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = x[j][0] + dx;
buf[m++] = x[j][1] + dy;
buf[m++] = x[j][2] + dz;
buf[m++] = tag[j];
buf[m++] = type[j];
buf[m++] = mask[j];
buf[m++] = q[j];
buf[m++] = spin[j];
buf[m++] = eradius[j];
buf[m++] = etag[j];
if (mask[i] & deform_groupbit) {
buf[m++] = v[j][0] + dvx;
buf[m++] = v[j][1] + dvy;
buf[m++] = v[j][2] + dvz;
} else {
buf[m++] = v[j][0];
buf[m++] = v[j][1];
buf[m++] = v[j][2];
}
buf[m++] = ervel[j];
buf[m++] = cs[2*j];
buf[m++] = cs[2*j+1];
}
}
}
return m;
}
/* ---------------------------------------------------------------------- */
int AtomVecWavepacket::pack_border_hybrid(int n, int *list, double *buf)
{
int i,j,m;
m = 0;
for (i = 0; i < n; i++) {
j = list[i];
buf[m++] = q[j];
buf[m++] = spin[j];
buf[m++] = eradius[j];
buf[m++] = etag[j];
buf[m++] = ervel[j];
buf[m++] = cs[2*j];
buf[m++] = cs[2*j+1];
}
return m;
}
/* ---------------------------------------------------------------------- */
void AtomVecWavepacket::unpack_border(int n, int first, double *buf)
{
int i,m,last;
m = 0;
last = first + n;
for (i = first; i < last; i++) {
if (i == nmax) grow(0);
x[i][0] = buf[m++];
x[i][1] = buf[m++];
x[i][2] = buf[m++];
tag[i] = static_cast<int> (buf[m++]);
type[i] = static_cast<int> (buf[m++]);
mask[i] = static_cast<int> (buf[m++]);
q[i] = buf[m++];
spin[i] = static_cast<int> (buf[m++]);
eradius[i] = buf[m++];
etag[i] = (int)buf[m++];
}
}
/* ---------------------------------------------------------------------- */
void AtomVecWavepacket::unpack_border_vel(int n, int first, double *buf)
{
int i,m,last;
m = 0;
last = first + n;
for (i = first; i < last; i++) {
if (i == nmax) grow(0);
x[i][0] = buf[m++];
x[i][1] = buf[m++];
x[i][2] = buf[m++];
tag[i] = static_cast<int> (buf[m++]);
type[i] = static_cast<int> (buf[m++]);
mask[i] = static_cast<int> (buf[m++]);
q[i] = buf[m++];
spin[i] = static_cast<int> (buf[m++]);
eradius[i] = buf[m++];
etag[i] = (int)buf[m++];
v[i][0] = buf[m++];
v[i][1] = buf[m++];
v[i][2] = buf[m++];
ervel[i] = buf[m++];
cs[2*i] = buf[m++];
cs[2*i+1] = buf[m++];
}
}
/* ---------------------------------------------------------------------- */
int AtomVecWavepacket::unpack_border_hybrid(int n, int first, double *buf)
{
int i,m,last;
m = 0;
last = first + n;
for (i = first; i < last; i++) {
q[i] = buf[m++];
spin[i] = static_cast<int> (buf[m++]);
eradius[i] = buf[m++];
etag[i] = (int)buf[m++];
ervel[i] = buf[m++];
cs[2*i] = buf[m++];
cs[2*i+1] = buf[m++];
}
return m;
}
/* ----------------------------------------------------------------------
pack data for atom I for sending to another proc
xyz must be 1st 3 values, so comm::exchange() can test on them
------------------------------------------------------------------------- */
int AtomVecWavepacket::pack_exchange(int i, double *buf)
{
int m = 1;
buf[m++] = x[i][0];
buf[m++] = x[i][1];
buf[m++] = x[i][2];
buf[m++] = v[i][0];
buf[m++] = v[i][1];
buf[m++] = v[i][2];
buf[m++] = tag[i];
buf[m++] = type[i];
buf[m++] = mask[i];
buf[m++] = image[i];
buf[m++] = q[i];
buf[m++] = spin[i];
buf[m++] = eradius[i];
buf[m++] = ervel[i];
buf[m++] = etag[i];
buf[m++] = cs[2*i];
buf[m++] = cs[2*i+1];
if (atom->nextra_grow)
for (int iextra = 0; iextra < atom->nextra_grow; iextra++)
m += modify->fix[atom->extra_grow[iextra]]->pack_exchange(i,&buf[m]);
buf[0] = m;
return m;
}
/* ---------------------------------------------------------------------- */
int AtomVecWavepacket::unpack_exchange(double *buf)
{
int nlocal = atom->nlocal;
if (nlocal == nmax) grow(0);
int m = 1;
x[nlocal][0] = buf[m++];
x[nlocal][1] = buf[m++];
x[nlocal][2] = buf[m++];
v[nlocal][0] = buf[m++];
v[nlocal][1] = buf[m++];
v[nlocal][2] = buf[m++];
tag[nlocal] = static_cast<int> (buf[m++]);
type[nlocal] = static_cast<int> (buf[m++]);
mask[nlocal] = static_cast<int> (buf[m++]);
image[nlocal] = static_cast<int> (buf[m++]);
q[nlocal] = buf[m++];
spin[nlocal] = static_cast<int> (buf[m++]);
eradius[nlocal] = buf[m++];
ervel[nlocal] = buf[m++];
etag[nlocal] = buf[m++];
cs[2*nlocal] = buf[m++];
cs[2*nlocal+1] = buf[m++];
if (atom->nextra_grow)
for (int iextra = 0; iextra < atom->nextra_grow; iextra++)
m += modify->fix[atom->extra_grow[iextra]]->
unpack_exchange(nlocal,&buf[m]);
atom->nlocal++;
return m;
}
/* ----------------------------------------------------------------------
size of restart data for all atoms owned by this proc
include extra data stored by fixes
------------------------------------------------------------------------- */
int AtomVecWavepacket::size_restart()
{
int i;
int nlocal = atom->nlocal;
int n = 18 * nlocal; // Associated with pack_restart
if (atom->nextra_restart)
for (int iextra = 0; iextra < atom->nextra_restart; iextra++)
for (i = 0; i < nlocal; i++)
n += modify->fix[atom->extra_restart[iextra]]->size_restart(i);
return n;
}
/* ----------------------------------------------------------------------
pack atom I's data for restart file including extra quantities
xyz must be 1st 3 values, so that read_restart can test on them
molecular types may be negative, but write as positive
------------------------------------------------------------------------- */
int AtomVecWavepacket::pack_restart(int i, double *buf)
{
int m = 1;
buf[m++] = x[i][0];
buf[m++] = x[i][1];
buf[m++] = x[i][2];
buf[m++] = tag[i];
buf[m++] = type[i];
buf[m++] = mask[i];
buf[m++] = image[i];
buf[m++] = v[i][0];
buf[m++] = v[i][1];
buf[m++] = v[i][2];
buf[m++] = q[i];
buf[m++] = spin[i];
buf[m++] = eradius[i];
buf[m++] = ervel[i];
buf[m++] = etag[i];
buf[m++] = cs[2*i];
buf[m++] = cs[2*i+1];
if (atom->nextra_restart)
for (int iextra = 0; iextra < atom->nextra_restart; iextra++)
m += modify->fix[atom->extra_restart[iextra]]->pack_restart(i,&buf[m]);
buf[0] = m;
return m;
}
/* ----------------------------------------------------------------------
unpack data for one atom from restart file including extra quantities
------------------------------------------------------------------------- */
int AtomVecWavepacket::unpack_restart(double *buf)
{
int nlocal = atom->nlocal;
if (nlocal == nmax) {
grow(0);
if (atom->nextra_store)
memory->grow(atom->extra,nmax,atom->nextra_store,"atom:extra");
}
int m = 1;
x[nlocal][0] = buf[m++];
x[nlocal][1] = buf[m++];
x[nlocal][2] = buf[m++];
tag[nlocal] = static_cast<int> (buf[m++]);
type[nlocal] = static_cast<int> (buf[m++]);
mask[nlocal] = static_cast<int> (buf[m++]);
image[nlocal] = static_cast<int> (buf[m++]);
v[nlocal][0] = buf[m++];
v[nlocal][1] = buf[m++];
v[nlocal][2] = buf[m++];
q[nlocal] = buf[m++];
spin[nlocal] = static_cast<int> (buf[m++]);
eradius[nlocal] = buf[m++];
ervel[nlocal] = buf[m++];
etag[nlocal] = buf[m++];
cs[2*nlocal] = buf[m++];
cs[2*nlocal+1] = buf[m++];
double **extra = atom->extra;
if (atom->nextra_store) {
int size = static_cast<int> (buf[0]) - m;
for (int i = 0; i < size; i++) extra[nlocal][i] = buf[m++];
}
atom->nlocal++;
return m;
}
/* ----------------------------------------------------------------------
create one atom of itype at coord
set other values to defaults
AWPMD: creates a proton
------------------------------------------------------------------------- */
void AtomVecWavepacket::create_atom(int itype, double *coord)
{
int nlocal = atom->nlocal;
if (nlocal == nmax) grow(0);
tag[nlocal] = 0;
type[nlocal] = itype;
x[nlocal][0] = coord[0];
x[nlocal][1] = coord[1];
x[nlocal][2] = coord[2];
mask[nlocal] = 1;
image[nlocal] = (512 << 20) | (512 << 10) | 512;
v[nlocal][0] = 0.0;
v[nlocal][1] = 0.0;
v[nlocal][2] = 0.0;
q[nlocal] = 1.;
spin[nlocal] = 0.;
eradius[nlocal] = 0.0;
ervel[nlocal] = 0.0;
etag[nlocal]= 0.;
cs[2*nlocal] = 0.;
cs[2*nlocal+1] = 0.;
atom->nlocal++;
}
/* ----------------------------------------------------------------------
unpack one line from Atoms section of data file
initialize other atom quantities
AWPMD: 0-tag 1-type 2-q 3-spin 4-eradius 5-etag 6-cs_re 7-cs_im
------------------------------------------------------------------------- */
void AtomVecWavepacket::data_atom(double *coord, int imagetmp, char **values)
{
int nlocal = atom->nlocal;
if (nlocal == nmax) grow(0);
tag[nlocal] = atoi(values[0]);
if (tag[nlocal] <= 0)
error->one(FLERR,"Invalid atom ID in Atoms section of data file (ID tag must be >0)");
type[nlocal] = atoi(values[1]);
if (type[nlocal] <= 0 || type[nlocal] > atom->ntypes)
error->one(FLERR,"Invalid atom type in Atoms section of data file");
q[nlocal] = atof(values[2]);
spin[nlocal] = atoi(values[3]);
eradius[nlocal] = atof(values[4]);
if (eradius[nlocal] < 0.0)
error->one(FLERR,"Invalid eradius in Atoms section of data file");
etag[nlocal] = atoi(values[5]);
cs[2*nlocal] = atoi(values[6]);
cs[2*nlocal+1] = atof(values[7]);
x[nlocal][0] = coord[0];
x[nlocal][1] = coord[1];
x[nlocal][2] = coord[2];
image[nlocal] = imagetmp;
mask[nlocal] = 1;
v[nlocal][0] = 0.0;
v[nlocal][1] = 0.0;
v[nlocal][2] = 0.0;
ervel[nlocal] = 0.0;
atom->nlocal++;
}
/* ----------------------------------------------------------------------
unpack hybrid quantities from one line in Atoms section of data file
initialize other atom quantities for this sub-style
------------------------------------------------------------------------- */
int AtomVecWavepacket::data_atom_hybrid(int nlocal, char **values)
{
q[nlocal] = atof(values[0]);
spin[nlocal] = atoi(values[1]);
eradius[nlocal] = atof(values[2]);
if (eradius[nlocal] < 0.0)
error->one(FLERR,"Invalid eradius in Atoms section of data file");
etag[nlocal] = atoi(values[3]);
cs[2*nlocal] = atoi(values[4]);
cs[2*nlocal+1] = atof(values[5]);
v[nlocal][0] = 0.0;
v[nlocal][1] = 0.0;
v[nlocal][2] = 0.0;
ervel[nlocal] = 0.0;
return 3;
}
/* ----------------------------------------------------------------------
unpack one line from Velocities section of data file
------------------------------------------------------------------------- */
void AtomVecWavepacket::data_vel(int m, char **values)
{
v[m][0] = atof(values[0]);
v[m][1] = atof(values[1]);
v[m][2] = atof(values[2]);
ervel[m] = atof(values[3]);
}
/* ----------------------------------------------------------------------
unpack hybrid quantities from one line in Velocities section of data file
------------------------------------------------------------------------- */
int AtomVecWavepacket::data_vel_hybrid(int m, char **values)
{
ervel[m] = atof(values[0]);
return 1;
}
/* ----------------------------------------------------------------------
return # of bytes of allocated memory
------------------------------------------------------------------------- */
bigint AtomVecWavepacket::memory_usage()
{
bigint bytes = 0;
if (atom->memcheck("tag")) bytes += memory->usage(tag,nmax);
if (atom->memcheck("type")) bytes += memory->usage(type,nmax);
if (atom->memcheck("mask")) bytes += memory->usage(mask,nmax);
if (atom->memcheck("image")) bytes += memory->usage(image,nmax);
if (atom->memcheck("x")) bytes += memory->usage(x,nmax,3);
if (atom->memcheck("v")) bytes += memory->usage(v,nmax,3);
if (atom->memcheck("f")) bytes += memory->usage(f,nmax*comm->nthreads,3);
if (atom->memcheck("q")) bytes += memory->usage(q,nmax);
if (atom->memcheck("spin")) bytes += memory->usage(spin,nmax);
if (atom->memcheck("eradius")) bytes += memory->usage(eradius,nmax);
if (atom->memcheck("ervel")) bytes += memory->usage(ervel,nmax);
if (atom->memcheck("erforce")) bytes += memory->usage(erforce,nmax*comm->nthreads);
if (atom->memcheck("ervelforce")) bytes += memory->usage(ervelforce,nmax);
if (atom->memcheck("cs")) bytes += memory->usage(cs,2*nmax);
if (atom->memcheck("csforce")) bytes += memory->usage(csforce,2*nmax);
if (atom->memcheck("vforce")) bytes += memory->usage(vforce,3*nmax);
if (atom->memcheck("etag")) bytes += memory->usage(etag,nmax);
return bytes;
}

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