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ewald.cpp
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rLAMMPS lammps
ewald.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: Roy Pollock (LLNL), Paul Crozier (SNL)
------------------------------------------------------------------------- */
#include "mpi.h"
#include "stdlib.h"
#include "stdio.h"
#include "string.h"
#include "math.h"
#include "ewald.h"
#include "atom.h"
#include "comm.h"
#include "force.h"
#include "pair.h"
#include "domain.h"
#include "memory.h"
#include "error.h"
using
namespace
LAMMPS_NS
;
#define SMALL 0.00001
#define MIN(a,b) ((a) < (b) ? (a) : (b))
#define MAX(a,b) ((a) > (b) ? (a) : (b))
/* ---------------------------------------------------------------------- */
Ewald
::
Ewald
(
LAMMPS
*
lmp
,
int
narg
,
char
**
arg
)
:
KSpace
(
lmp
,
narg
,
arg
)
{
if
(
narg
!=
1
)
error
->
all
(
"Illegal kspace_style ewald command"
);
precision
=
atof
(
arg
[
0
]);
PI
=
4.0
*
atan
(
1.0
);
kmax
=
0
;
kxvecs
=
kyvecs
=
kzvecs
=
NULL
;
ug
=
NULL
;
eg
=
vg
=
NULL
;
sfacrl
=
sfacim
=
sfacrl_all
=
sfacim_all
=
NULL
;
nmax
=
0
;
ek
=
NULL
;
cs
=
sn
=
NULL
;
kcount
=
0
;
}
/* ----------------------------------------------------------------------
free all memory
------------------------------------------------------------------------- */
Ewald
::~
Ewald
()
{
deallocate
();
memory
->
destroy_2d_double_array
(
ek
);
memory
->
destroy_3d_double_array
(
cs
,
-
kmax_created
);
memory
->
destroy_3d_double_array
(
sn
,
-
kmax_created
);
}
/* ---------------------------------------------------------------------- */
void
Ewald
::
init
()
{
if
(
comm
->
me
==
0
)
{
if
(
screen
)
fprintf
(
screen
,
"Ewald initialization ...
\n
"
);
if
(
logfile
)
fprintf
(
logfile
,
"Ewald initialization ...
\n
"
);
}
// error check
if
(
domain
->
triclinic
)
error
->
all
(
"Cannot use Ewald with triclinic box"
);
if
(
domain
->
dimension
==
2
)
error
->
all
(
"Cannot use Ewald with 2d simulation"
);
if
(
!
atom
->
q_flag
)
error
->
all
(
"Kspace style requires atom attribute q"
);
if
(
slabflag
==
0
&&
domain
->
nonperiodic
>
0
)
error
->
all
(
"Cannot use nonperiodic boundaries with Ewald"
);
if
(
slabflag
==
1
)
{
if
(
domain
->
xperiodic
!=
1
||
domain
->
yperiodic
!=
1
||
domain
->
boundary
[
2
][
0
]
!=
1
||
domain
->
boundary
[
2
][
1
]
!=
1
)
error
->
all
(
"Incorrect boundaries with slab Ewald"
);
}
// extract short-range Coulombic cutoff from pair style
qqrd2e
=
force
->
qqrd2e
;
scale
=
1.0
;
if
(
force
->
pair
==
NULL
)
error
->
all
(
"KSpace style is incompatible with Pair style"
);
int
itmp
;
double
*
p_cutoff
=
(
double
*
)
force
->
pair
->
extract
(
"cut_coul"
,
itmp
);
if
(
p_cutoff
==
NULL
)
error
->
all
(
"KSpace style is incompatible with Pair style"
);
double
cutoff
=
*
p_cutoff
;
qsum
=
qsqsum
=
0.0
;
for
(
int
i
=
0
;
i
<
atom
->
nlocal
;
i
++
)
{
qsum
+=
atom
->
q
[
i
];
qsqsum
+=
atom
->
q
[
i
]
*
atom
->
q
[
i
];
}
double
tmp
;
MPI_Allreduce
(
&
qsum
,
&
tmp
,
1
,
MPI_DOUBLE
,
MPI_SUM
,
world
);
qsum
=
tmp
;
MPI_Allreduce
(
&
qsqsum
,
&
tmp
,
1
,
MPI_DOUBLE
,
MPI_SUM
,
world
);
qsqsum
=
tmp
;
if
(
qsqsum
==
0.0
)
error
->
all
(
"Cannot use kspace solver on system with no charge"
);
if
(
fabs
(
qsum
)
>
SMALL
&&
comm
->
me
==
0
)
{
char
str
[
128
];
sprintf
(
str
,
"System is not charge neutral, net charge = %g"
,
qsum
);
error
->
warning
(
str
);
}
// setup K-space resolution
if
(
!
gewaldflag
)
g_ewald
=
(
1.35
-
0.15
*
log
(
precision
))
/
cutoff
;
gsqmx
=
-
4.0
*
g_ewald
*
g_ewald
*
log
(
precision
);
if
(
comm
->
me
==
0
)
{
if
(
screen
)
fprintf
(
screen
,
" G vector = %g
\n
"
,
g_ewald
);
if
(
logfile
)
fprintf
(
logfile
,
" G vector = %g
\n
"
,
g_ewald
);
}
// setup Ewald coefficients so can print stats
setup
();
if
(
comm
->
me
==
0
)
{
if
(
screen
)
fprintf
(
screen
,
" vectors: actual 1d max = %d %d %d
\n
"
,
kcount
,
kmax
,
kmax3d
);
if
(
logfile
)
fprintf
(
logfile
,
" vectors: actual 1d max = %d %d %d
\n
"
,
kcount
,
kmax
,
kmax3d
);
}
}
/* ----------------------------------------------------------------------
adjust Ewald coeffs, called initially and whenever volume has changed
------------------------------------------------------------------------- */
void
Ewald
::
setup
()
{
// volume-dependent factors
double
xprd
=
domain
->
xprd
;
double
yprd
=
domain
->
yprd
;
double
zprd
=
domain
->
zprd
;
// adjustment of z dimension for 2d slab Ewald
// 3d Ewald just uses zprd since slab_volfactor = 1.0
double
zprd_slab
=
zprd
*
slab_volfactor
;
volume
=
xprd
*
yprd
*
zprd_slab
;
unitk
[
0
]
=
2.0
*
PI
/
xprd
;
unitk
[
1
]
=
2.0
*
PI
/
yprd
;
unitk
[
2
]
=
2.0
*
PI
/
zprd_slab
;
// determine kmax
// function of current box size, precision, G_ewald (short-range cutoff)
int
nkxmx
=
static_cast
<
int
>
((
g_ewald
*
xprd
/
PI
)
*
sqrt
(
-
log
(
precision
)));
int
nkymx
=
static_cast
<
int
>
((
g_ewald
*
yprd
/
PI
)
*
sqrt
(
-
log
(
precision
)));
int
nkzmx
=
static_cast
<
int
>
((
g_ewald
*
zprd_slab
/
PI
)
*
sqrt
(
-
log
(
precision
)));
int
kmax_old
=
kmax
;
kmax
=
MAX
(
nkxmx
,
nkymx
);
kmax
=
MAX
(
kmax
,
nkzmx
);
kmax3d
=
4
*
kmax
*
kmax
*
kmax
+
6
*
kmax
*
kmax
+
3
*
kmax
;
// if size has grown, reallocate k-dependent and nlocal-dependent arrays
if
(
kmax
>
kmax_old
)
{
deallocate
();
allocate
();
memory
->
destroy_2d_double_array
(
ek
);
memory
->
destroy_3d_double_array
(
cs
,
-
kmax_created
);
memory
->
destroy_3d_double_array
(
sn
,
-
kmax_created
);
nmax
=
atom
->
nmax
;
ek
=
memory
->
create_2d_double_array
(
nmax
,
3
,
"ewald:ek"
);
cs
=
memory
->
create_3d_double_array
(
-
kmax
,
kmax
,
3
,
nmax
,
"ewald:cs"
);
sn
=
memory
->
create_3d_double_array
(
-
kmax
,
kmax
,
3
,
nmax
,
"ewald:sn"
);
kmax_created
=
kmax
;
}
// pre-compute Ewald coefficients
coeffs
();
}
/* ----------------------------------------------------------------------
compute the Ewald long-range force, energy, virial
------------------------------------------------------------------------- */
void
Ewald
::
compute
(
int
eflag
,
int
vflag
)
{
int
i
,
k
,
n
;
energy
=
0.0
;
if
(
vflag
)
for
(
n
=
0
;
n
<
6
;
n
++
)
virial
[
n
]
=
0.0
;
// extend size of per-atom arrays if necessary
if
(
atom
->
nlocal
>
nmax
)
{
memory
->
destroy_2d_double_array
(
ek
);
memory
->
destroy_3d_double_array
(
cs
,
-
kmax_created
);
memory
->
destroy_3d_double_array
(
sn
,
-
kmax_created
);
nmax
=
atom
->
nmax
;
ek
=
memory
->
create_2d_double_array
(
nmax
,
3
,
"ewald:ek"
);
cs
=
memory
->
create_3d_double_array
(
-
kmax
,
kmax
,
3
,
nmax
,
"ewald:cs"
);
sn
=
memory
->
create_3d_double_array
(
-
kmax
,
kmax
,
3
,
nmax
,
"ewald:sn"
);
kmax_created
=
kmax
;
}
// partial structure factors on each processor
// total structure factor by summing over procs
eik_dot_r
();
MPI_Allreduce
(
sfacrl
,
sfacrl_all
,
kcount
,
MPI_DOUBLE
,
MPI_SUM
,
world
);
MPI_Allreduce
(
sfacim
,
sfacim_all
,
kcount
,
MPI_DOUBLE
,
MPI_SUM
,
world
);
// K-space portion of electric field
// double loop over K-vectors and local atoms
double
**
f
=
atom
->
f
;
double
*
q
=
atom
->
q
;
int
nlocal
=
atom
->
nlocal
;
int
kx
,
ky
,
kz
;
double
cypz
,
sypz
,
exprl
,
expim
,
partial
;
for
(
i
=
0
;
i
<
nlocal
;
i
++
)
{
ek
[
i
][
0
]
=
0.0
;
ek
[
i
][
1
]
=
0.0
;
ek
[
i
][
2
]
=
0.0
;
}
for
(
k
=
0
;
k
<
kcount
;
k
++
)
{
kx
=
kxvecs
[
k
];
ky
=
kyvecs
[
k
];
kz
=
kzvecs
[
k
];
for
(
i
=
0
;
i
<
nlocal
;
i
++
)
{
cypz
=
cs
[
ky
][
1
][
i
]
*
cs
[
kz
][
2
][
i
]
-
sn
[
ky
][
1
][
i
]
*
sn
[
kz
][
2
][
i
];
sypz
=
sn
[
ky
][
1
][
i
]
*
cs
[
kz
][
2
][
i
]
+
cs
[
ky
][
1
][
i
]
*
sn
[
kz
][
2
][
i
];
exprl
=
cs
[
kx
][
0
][
i
]
*
cypz
-
sn
[
kx
][
0
][
i
]
*
sypz
;
expim
=
sn
[
kx
][
0
][
i
]
*
cypz
+
cs
[
kx
][
0
][
i
]
*
sypz
;
partial
=
expim
*
sfacrl_all
[
k
]
-
exprl
*
sfacim_all
[
k
];
ek
[
i
][
0
]
+=
partial
*
eg
[
k
][
0
];
ek
[
i
][
1
]
+=
partial
*
eg
[
k
][
1
];
ek
[
i
][
2
]
+=
partial
*
eg
[
k
][
2
];
}
}
// convert E-field to force
for
(
i
=
0
;
i
<
nlocal
;
i
++
)
{
f
[
i
][
0
]
+=
qqrd2e
*
scale
*
q
[
i
]
*
ek
[
i
][
0
];
f
[
i
][
1
]
+=
qqrd2e
*
scale
*
q
[
i
]
*
ek
[
i
][
1
];
f
[
i
][
2
]
+=
qqrd2e
*
scale
*
q
[
i
]
*
ek
[
i
][
2
];
}
// energy if requested
if
(
eflag
)
{
for
(
k
=
0
;
k
<
kcount
;
k
++
)
energy
+=
ug
[
k
]
*
(
sfacrl_all
[
k
]
*
sfacrl_all
[
k
]
+
sfacim_all
[
k
]
*
sfacim_all
[
k
]);
PI
=
4.0
*
atan
(
1.0
);
energy
-=
g_ewald
*
qsqsum
/
1.772453851
+
0.5
*
PI
*
qsum
*
qsum
/
(
g_ewald
*
g_ewald
*
volume
);
energy
*=
qqrd2e
*
scale
;
}
// virial if requested
if
(
vflag
)
{
double
uk
;
for
(
k
=
0
;
k
<
kcount
;
k
++
)
{
uk
=
ug
[
k
]
*
(
sfacrl_all
[
k
]
*
sfacrl_all
[
k
]
+
sfacim_all
[
k
]
*
sfacim_all
[
k
]);
for
(
n
=
0
;
n
<
6
;
n
++
)
virial
[
n
]
+=
uk
*
vg
[
k
][
n
];
}
for
(
n
=
0
;
n
<
6
;
n
++
)
virial
[
n
]
*=
qqrd2e
*
scale
;
}
if
(
slabflag
)
slabcorr
(
eflag
);
}
/* ---------------------------------------------------------------------- */
void
Ewald
::
eik_dot_r
()
{
int
i
,
k
,
l
,
m
,
n
,
ic
;
double
cstr1
,
sstr1
,
cstr2
,
sstr2
,
cstr3
,
sstr3
,
cstr4
,
sstr4
;
double
sqk
,
clpm
,
slpm
;
double
**
x
=
atom
->
x
;
double
*
q
=
atom
->
q
;
int
nlocal
=
atom
->
nlocal
;
n
=
0
;
// (k,0,0), (0,l,0), (0,0,m)
for
(
ic
=
0
;
ic
<
3
;
ic
++
)
{
sqk
=
unitk
[
ic
]
*
unitk
[
ic
];
if
(
sqk
<=
gsqmx
)
{
cstr1
=
0.0
;
sstr1
=
0.0
;
for
(
i
=
0
;
i
<
nlocal
;
i
++
)
{
cs
[
0
][
ic
][
i
]
=
1.0
;
sn
[
0
][
ic
][
i
]
=
0.0
;
cs
[
1
][
ic
][
i
]
=
cos
(
unitk
[
ic
]
*
x
[
i
][
ic
]);
sn
[
1
][
ic
][
i
]
=
sin
(
unitk
[
ic
]
*
x
[
i
][
ic
]);
cs
[
-
1
][
ic
][
i
]
=
cs
[
1
][
ic
][
i
];
sn
[
-
1
][
ic
][
i
]
=
-
sn
[
1
][
ic
][
i
];
cstr1
+=
q
[
i
]
*
cs
[
1
][
ic
][
i
];
sstr1
+=
q
[
i
]
*
sn
[
1
][
ic
][
i
];
}
sfacrl
[
n
]
=
cstr1
;
sfacim
[
n
++
]
=
sstr1
;
}
}
for
(
m
=
2
;
m
<=
kmax
;
m
++
)
{
for
(
ic
=
0
;
ic
<
3
;
ic
++
)
{
sqk
=
m
*
unitk
[
ic
]
*
m
*
unitk
[
ic
];
if
(
sqk
<=
gsqmx
)
{
cstr1
=
0.0
;
sstr1
=
0.0
;
for
(
i
=
0
;
i
<
nlocal
;
i
++
)
{
cs
[
m
][
ic
][
i
]
=
cs
[
m
-
1
][
ic
][
i
]
*
cs
[
1
][
ic
][
i
]
-
sn
[
m
-
1
][
ic
][
i
]
*
sn
[
1
][
ic
][
i
];
sn
[
m
][
ic
][
i
]
=
sn
[
m
-
1
][
ic
][
i
]
*
cs
[
1
][
ic
][
i
]
+
cs
[
m
-
1
][
ic
][
i
]
*
sn
[
1
][
ic
][
i
];
cs
[
-
m
][
ic
][
i
]
=
cs
[
m
][
ic
][
i
];
sn
[
-
m
][
ic
][
i
]
=
-
sn
[
m
][
ic
][
i
];
cstr1
+=
q
[
i
]
*
cs
[
m
][
ic
][
i
];
sstr1
+=
q
[
i
]
*
sn
[
m
][
ic
][
i
];
}
sfacrl
[
n
]
=
cstr1
;
sfacim
[
n
++
]
=
sstr1
;
}
}
}
// 1 = (k,l,0), 2 = (k,-l,0)
for
(
k
=
1
;
k
<=
kmax
;
k
++
)
{
for
(
l
=
1
;
l
<=
kmax
;
l
++
)
{
sqk
=
(
k
*
unitk
[
0
]
*
k
*
unitk
[
0
])
+
(
l
*
unitk
[
1
]
*
l
*
unitk
[
1
]);
if
(
sqk
<=
gsqmx
)
{
cstr1
=
0.0
;
sstr1
=
0.0
;
cstr2
=
0.0
;
sstr2
=
0.0
;
for
(
i
=
0
;
i
<
nlocal
;
i
++
)
{
cstr1
+=
q
[
i
]
*
(
cs
[
k
][
0
][
i
]
*
cs
[
l
][
1
][
i
]
-
sn
[
k
][
0
][
i
]
*
sn
[
l
][
1
][
i
]);
sstr1
+=
q
[
i
]
*
(
sn
[
k
][
0
][
i
]
*
cs
[
l
][
1
][
i
]
+
cs
[
k
][
0
][
i
]
*
sn
[
l
][
1
][
i
]);
cstr2
+=
q
[
i
]
*
(
cs
[
k
][
0
][
i
]
*
cs
[
l
][
1
][
i
]
+
sn
[
k
][
0
][
i
]
*
sn
[
l
][
1
][
i
]);
sstr2
+=
q
[
i
]
*
(
sn
[
k
][
0
][
i
]
*
cs
[
l
][
1
][
i
]
-
cs
[
k
][
0
][
i
]
*
sn
[
l
][
1
][
i
]);
}
sfacrl
[
n
]
=
cstr1
;
sfacim
[
n
++
]
=
sstr1
;
sfacrl
[
n
]
=
cstr2
;
sfacim
[
n
++
]
=
sstr2
;
}
}
}
// 1 = (0,l,m), 2 = (0,l,-m)
for
(
l
=
1
;
l
<=
kmax
;
l
++
)
{
for
(
m
=
1
;
m
<=
kmax
;
m
++
)
{
sqk
=
(
l
*
unitk
[
1
]
*
l
*
unitk
[
1
])
+
(
m
*
unitk
[
2
]
*
m
*
unitk
[
2
]);
if
(
sqk
<=
gsqmx
)
{
cstr1
=
0.0
;
sstr1
=
0.0
;
cstr2
=
0.0
;
sstr2
=
0.0
;
for
(
i
=
0
;
i
<
nlocal
;
i
++
)
{
cstr1
+=
q
[
i
]
*
(
cs
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
-
sn
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
]);
sstr1
+=
q
[
i
]
*
(
sn
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
+
cs
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
]);
cstr2
+=
q
[
i
]
*
(
cs
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
+
sn
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
]);
sstr2
+=
q
[
i
]
*
(
sn
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
-
cs
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
]);
}
sfacrl
[
n
]
=
cstr1
;
sfacim
[
n
++
]
=
sstr1
;
sfacrl
[
n
]
=
cstr2
;
sfacim
[
n
++
]
=
sstr2
;
}
}
}
// 1 = (k,0,m), 2 = (k,0,-m)
for
(
k
=
1
;
k
<=
kmax
;
k
++
)
{
for
(
m
=
1
;
m
<=
kmax
;
m
++
)
{
sqk
=
(
k
*
unitk
[
0
]
*
k
*
unitk
[
0
])
+
(
m
*
unitk
[
2
]
*
m
*
unitk
[
2
]);
if
(
sqk
<=
gsqmx
)
{
cstr1
=
0.0
;
sstr1
=
0.0
;
cstr2
=
0.0
;
sstr2
=
0.0
;
for
(
i
=
0
;
i
<
nlocal
;
i
++
)
{
cstr1
+=
q
[
i
]
*
(
cs
[
k
][
0
][
i
]
*
cs
[
m
][
2
][
i
]
-
sn
[
k
][
0
][
i
]
*
sn
[
m
][
2
][
i
]);
sstr1
+=
q
[
i
]
*
(
sn
[
k
][
0
][
i
]
*
cs
[
m
][
2
][
i
]
+
cs
[
k
][
0
][
i
]
*
sn
[
m
][
2
][
i
]);
cstr2
+=
q
[
i
]
*
(
cs
[
k
][
0
][
i
]
*
cs
[
m
][
2
][
i
]
+
sn
[
k
][
0
][
i
]
*
sn
[
m
][
2
][
i
]);
sstr2
+=
q
[
i
]
*
(
sn
[
k
][
0
][
i
]
*
cs
[
m
][
2
][
i
]
-
cs
[
k
][
0
][
i
]
*
sn
[
m
][
2
][
i
]);
}
sfacrl
[
n
]
=
cstr1
;
sfacim
[
n
++
]
=
sstr1
;
sfacrl
[
n
]
=
cstr2
;
sfacim
[
n
++
]
=
sstr2
;
}
}
}
// 1 = (k,l,m), 2 = (k,-l,m), 3 = (k,l,-m), 4 = (k,-l,-m)
for
(
k
=
1
;
k
<=
kmax
;
k
++
)
{
for
(
l
=
1
;
l
<=
kmax
;
l
++
)
{
for
(
m
=
1
;
m
<=
kmax
;
m
++
)
{
sqk
=
(
k
*
unitk
[
0
]
*
k
*
unitk
[
0
])
+
(
l
*
unitk
[
1
]
*
l
*
unitk
[
1
])
+
(
m
*
unitk
[
2
]
*
m
*
unitk
[
2
]);
if
(
sqk
<=
gsqmx
)
{
cstr1
=
0.0
;
sstr1
=
0.0
;
cstr2
=
0.0
;
sstr2
=
0.0
;
cstr3
=
0.0
;
sstr3
=
0.0
;
cstr4
=
0.0
;
sstr4
=
0.0
;
for
(
i
=
0
;
i
<
nlocal
;
i
++
)
{
clpm
=
cs
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
-
sn
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
];
slpm
=
sn
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
+
cs
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
];
cstr1
+=
q
[
i
]
*
(
cs
[
k
][
0
][
i
]
*
clpm
-
sn
[
k
][
0
][
i
]
*
slpm
);
sstr1
+=
q
[
i
]
*
(
sn
[
k
][
0
][
i
]
*
clpm
+
cs
[
k
][
0
][
i
]
*
slpm
);
clpm
=
cs
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
+
sn
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
];
slpm
=
-
sn
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
+
cs
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
];
cstr2
+=
q
[
i
]
*
(
cs
[
k
][
0
][
i
]
*
clpm
-
sn
[
k
][
0
][
i
]
*
slpm
);
sstr2
+=
q
[
i
]
*
(
sn
[
k
][
0
][
i
]
*
clpm
+
cs
[
k
][
0
][
i
]
*
slpm
);
clpm
=
cs
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
+
sn
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
];
slpm
=
sn
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
-
cs
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
];
cstr3
+=
q
[
i
]
*
(
cs
[
k
][
0
][
i
]
*
clpm
-
sn
[
k
][
0
][
i
]
*
slpm
);
sstr3
+=
q
[
i
]
*
(
sn
[
k
][
0
][
i
]
*
clpm
+
cs
[
k
][
0
][
i
]
*
slpm
);
clpm
=
cs
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
-
sn
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
];
slpm
=
-
sn
[
l
][
1
][
i
]
*
cs
[
m
][
2
][
i
]
-
cs
[
l
][
1
][
i
]
*
sn
[
m
][
2
][
i
];
cstr4
+=
q
[
i
]
*
(
cs
[
k
][
0
][
i
]
*
clpm
-
sn
[
k
][
0
][
i
]
*
slpm
);
sstr4
+=
q
[
i
]
*
(
sn
[
k
][
0
][
i
]
*
clpm
+
cs
[
k
][
0
][
i
]
*
slpm
);
}
sfacrl
[
n
]
=
cstr1
;
sfacim
[
n
++
]
=
sstr1
;
sfacrl
[
n
]
=
cstr2
;
sfacim
[
n
++
]
=
sstr2
;
sfacrl
[
n
]
=
cstr3
;
sfacim
[
n
++
]
=
sstr3
;
sfacrl
[
n
]
=
cstr4
;
sfacim
[
n
++
]
=
sstr4
;
}
}
}
}
}
/* ----------------------------------------------------------------------
pre-compute coefficients for each Ewald K-vector
------------------------------------------------------------------------- */
void
Ewald
::
coeffs
()
{
int
k
,
l
,
m
;
double
sqk
,
vterm
;
double
unitkx
=
unitk
[
0
];
double
unitky
=
unitk
[
1
];
double
unitkz
=
unitk
[
2
];
double
g_ewald_sq_inv
=
1.0
/
(
g_ewald
*
g_ewald
);
double
preu
=
4.0
*
PI
/
volume
;
kcount
=
0
;
// (k,0,0), (0,l,0), (0,0,m)
for
(
m
=
1
;
m
<=
kmax
;
m
++
)
{
sqk
=
(
m
*
unitkx
)
*
(
m
*
unitkx
);
if
(
sqk
<=
gsqmx
)
{
kxvecs
[
kcount
]
=
m
;
kyvecs
[
kcount
]
=
0
;
kzvecs
[
kcount
]
=
0
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
2.0
*
unitkx
*
m
*
ug
[
kcount
];
eg
[
kcount
][
1
]
=
0.0
;
eg
[
kcount
][
2
]
=
0.0
;
vterm
=
-
2.0
*
(
1.0
/
sqk
+
0.25
*
g_ewald_sq_inv
);
vg
[
kcount
][
0
]
=
1.0
+
vterm
*
(
unitkx
*
m
)
*
(
unitkx
*
m
);
vg
[
kcount
][
1
]
=
1.0
;
vg
[
kcount
][
2
]
=
1.0
;
vg
[
kcount
][
3
]
=
0.0
;
vg
[
kcount
][
4
]
=
0.0
;
vg
[
kcount
][
5
]
=
0.0
;
kcount
++
;
}
sqk
=
(
m
*
unitky
)
*
(
m
*
unitky
);
if
(
sqk
<=
gsqmx
)
{
kxvecs
[
kcount
]
=
0
;
kyvecs
[
kcount
]
=
m
;
kzvecs
[
kcount
]
=
0
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
0.0
;
eg
[
kcount
][
1
]
=
2.0
*
unitky
*
m
*
ug
[
kcount
];
eg
[
kcount
][
2
]
=
0.0
;
vterm
=
-
2.0
*
(
1.0
/
sqk
+
0.25
*
g_ewald_sq_inv
);
vg
[
kcount
][
0
]
=
1.0
;
vg
[
kcount
][
1
]
=
1.0
+
vterm
*
(
unitky
*
m
)
*
(
unitky
*
m
);
vg
[
kcount
][
2
]
=
1.0
;
vg
[
kcount
][
3
]
=
0.0
;
vg
[
kcount
][
4
]
=
0.0
;
vg
[
kcount
][
5
]
=
0.0
;
kcount
++
;
}
sqk
=
(
m
*
unitkz
)
*
(
m
*
unitkz
);
if
(
sqk
<=
gsqmx
)
{
kxvecs
[
kcount
]
=
0
;
kyvecs
[
kcount
]
=
0
;
kzvecs
[
kcount
]
=
m
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
0.0
;
eg
[
kcount
][
1
]
=
0.0
;
eg
[
kcount
][
2
]
=
2.0
*
unitkz
*
m
*
ug
[
kcount
];
vterm
=
-
2.0
*
(
1.0
/
sqk
+
0.25
*
g_ewald_sq_inv
);
vg
[
kcount
][
0
]
=
1.0
;
vg
[
kcount
][
1
]
=
1.0
;
vg
[
kcount
][
2
]
=
1.0
+
vterm
*
(
unitkz
*
m
)
*
(
unitkz
*
m
);
vg
[
kcount
][
3
]
=
0.0
;
vg
[
kcount
][
4
]
=
0.0
;
vg
[
kcount
][
5
]
=
0.0
;
kcount
++
;
}
}
// 1 = (k,l,0), 2 = (k,-l,0)
for
(
k
=
1
;
k
<=
kmax
;
k
++
)
{
for
(
l
=
1
;
l
<=
kmax
;
l
++
)
{
sqk
=
(
unitkx
*
k
)
*
(
unitkx
*
k
)
+
(
unitky
*
l
)
*
(
unitky
*
l
);
if
(
sqk
<=
gsqmx
)
{
kxvecs
[
kcount
]
=
k
;
kyvecs
[
kcount
]
=
l
;
kzvecs
[
kcount
]
=
0
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
2.0
*
unitkx
*
k
*
ug
[
kcount
];
eg
[
kcount
][
1
]
=
2.0
*
unitky
*
l
*
ug
[
kcount
];
eg
[
kcount
][
2
]
=
0.0
;
vterm
=
-
2.0
*
(
1.0
/
sqk
+
0.25
*
g_ewald_sq_inv
);
vg
[
kcount
][
0
]
=
1.0
+
vterm
*
(
unitkx
*
k
)
*
(
unitkx
*
k
);
vg
[
kcount
][
1
]
=
1.0
+
vterm
*
(
unitky
*
l
)
*
(
unitky
*
l
);
vg
[
kcount
][
2
]
=
1.0
;
vg
[
kcount
][
3
]
=
vterm
*
unitkx
*
k
*
unitky
*
l
;
vg
[
kcount
][
4
]
=
0.0
;
vg
[
kcount
][
5
]
=
0.0
;
kcount
++
;
kxvecs
[
kcount
]
=
k
;
kyvecs
[
kcount
]
=
-
l
;
kzvecs
[
kcount
]
=
0
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
2.0
*
unitkx
*
k
*
ug
[
kcount
];
eg
[
kcount
][
1
]
=
-
2.0
*
unitky
*
l
*
ug
[
kcount
];
eg
[
kcount
][
2
]
=
0.0
;
vg
[
kcount
][
0
]
=
1.0
+
vterm
*
(
unitkx
*
k
)
*
(
unitkx
*
k
);
vg
[
kcount
][
1
]
=
1.0
+
vterm
*
(
unitky
*
l
)
*
(
unitky
*
l
);
vg
[
kcount
][
2
]
=
1.0
;
vg
[
kcount
][
3
]
=
-
vterm
*
unitkx
*
k
*
unitky
*
l
;
vg
[
kcount
][
4
]
=
0.0
;
vg
[
kcount
][
5
]
=
0.0
;
kcount
++
;;
}
}
}
// 1 = (0,l,m), 2 = (0,l,-m)
for
(
l
=
1
;
l
<=
kmax
;
l
++
)
{
for
(
m
=
1
;
m
<=
kmax
;
m
++
)
{
sqk
=
(
unitky
*
l
)
*
(
unitky
*
l
)
+
(
unitkz
*
m
)
*
(
unitkz
*
m
);
if
(
sqk
<=
gsqmx
)
{
kxvecs
[
kcount
]
=
0
;
kyvecs
[
kcount
]
=
l
;
kzvecs
[
kcount
]
=
m
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
0.0
;
eg
[
kcount
][
1
]
=
2.0
*
unitky
*
l
*
ug
[
kcount
];
eg
[
kcount
][
2
]
=
2.0
*
unitkz
*
m
*
ug
[
kcount
];
vterm
=
-
2.0
*
(
1.0
/
sqk
+
0.25
*
g_ewald_sq_inv
);
vg
[
kcount
][
0
]
=
1.0
;
vg
[
kcount
][
1
]
=
1.0
+
vterm
*
(
unitky
*
l
)
*
(
unitky
*
l
);
vg
[
kcount
][
2
]
=
1.0
+
vterm
*
(
unitkz
*
m
)
*
(
unitkz
*
m
);
vg
[
kcount
][
3
]
=
0.0
;
vg
[
kcount
][
4
]
=
0.0
;
vg
[
kcount
][
5
]
=
vterm
*
unitky
*
l
*
unitkz
*
m
;
kcount
++
;
kxvecs
[
kcount
]
=
0
;
kyvecs
[
kcount
]
=
l
;
kzvecs
[
kcount
]
=
-
m
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
0.0
;
eg
[
kcount
][
1
]
=
2.0
*
unitky
*
l
*
ug
[
kcount
];
eg
[
kcount
][
2
]
=
-
2.0
*
unitkz
*
m
*
ug
[
kcount
];
vg
[
kcount
][
0
]
=
1.0
;
vg
[
kcount
][
1
]
=
1.0
+
vterm
*
(
unitky
*
l
)
*
(
unitky
*
l
);
vg
[
kcount
][
2
]
=
1.0
+
vterm
*
(
unitkz
*
m
)
*
(
unitkz
*
m
);
vg
[
kcount
][
3
]
=
0.0
;
vg
[
kcount
][
4
]
=
0.0
;
vg
[
kcount
][
5
]
=
-
vterm
*
unitky
*
l
*
unitkz
*
m
;
kcount
++
;
}
}
}
// 1 = (k,0,m), 2 = (k,0,-m)
for
(
k
=
1
;
k
<=
kmax
;
k
++
)
{
for
(
m
=
1
;
m
<=
kmax
;
m
++
)
{
sqk
=
(
unitkx
*
k
)
*
(
unitkx
*
k
)
+
(
unitkz
*
m
)
*
(
unitkz
*
m
);
if
(
sqk
<=
gsqmx
)
{
kxvecs
[
kcount
]
=
k
;
kyvecs
[
kcount
]
=
0
;
kzvecs
[
kcount
]
=
m
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
2.0
*
unitkx
*
k
*
ug
[
kcount
];
eg
[
kcount
][
1
]
=
0.0
;
eg
[
kcount
][
2
]
=
2.0
*
unitkz
*
m
*
ug
[
kcount
];
vterm
=
-
2.0
*
(
1.0
/
sqk
+
0.25
*
g_ewald_sq_inv
);
vg
[
kcount
][
0
]
=
1.0
+
vterm
*
(
unitkx
*
k
)
*
(
unitkx
*
k
);
vg
[
kcount
][
1
]
=
1.0
;
vg
[
kcount
][
2
]
=
1.0
+
vterm
*
(
unitkz
*
m
)
*
(
unitkz
*
m
);
vg
[
kcount
][
3
]
=
0.0
;
vg
[
kcount
][
4
]
=
vterm
*
unitkx
*
k
*
unitkz
*
m
;
vg
[
kcount
][
5
]
=
0.0
;
kcount
++
;
kxvecs
[
kcount
]
=
k
;
kyvecs
[
kcount
]
=
0
;
kzvecs
[
kcount
]
=
-
m
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
2.0
*
unitkx
*
k
*
ug
[
kcount
];
eg
[
kcount
][
1
]
=
0.0
;
eg
[
kcount
][
2
]
=
-
2.0
*
unitkz
*
m
*
ug
[
kcount
];
vg
[
kcount
][
0
]
=
1.0
+
vterm
*
(
unitkx
*
k
)
*
(
unitkx
*
k
);
vg
[
kcount
][
1
]
=
1.0
;
vg
[
kcount
][
2
]
=
1.0
+
vterm
*
(
unitkz
*
m
)
*
(
unitkz
*
m
);
vg
[
kcount
][
3
]
=
0.0
;
vg
[
kcount
][
4
]
=
-
vterm
*
unitkx
*
k
*
unitkz
*
m
;
vg
[
kcount
][
5
]
=
0.0
;
kcount
++
;
}
}
}
// 1 = (k,l,m), 2 = (k,-l,m), 3 = (k,l,-m), 4 = (k,-l,-m)
for
(
k
=
1
;
k
<=
kmax
;
k
++
)
{
for
(
l
=
1
;
l
<=
kmax
;
l
++
)
{
for
(
m
=
1
;
m
<=
kmax
;
m
++
)
{
sqk
=
(
unitkx
*
k
)
*
(
unitkx
*
k
)
+
(
unitky
*
l
)
*
(
unitky
*
l
)
+
(
unitkz
*
m
)
*
(
unitkz
*
m
);
if
(
sqk
<=
gsqmx
)
{
kxvecs
[
kcount
]
=
k
;
kyvecs
[
kcount
]
=
l
;
kzvecs
[
kcount
]
=
m
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
2.0
*
unitkx
*
k
*
ug
[
kcount
];
eg
[
kcount
][
1
]
=
2.0
*
unitky
*
l
*
ug
[
kcount
];
eg
[
kcount
][
2
]
=
2.0
*
unitkz
*
m
*
ug
[
kcount
];
vterm
=
-
2.0
*
(
1.0
/
sqk
+
0.25
*
g_ewald_sq_inv
);
vg
[
kcount
][
0
]
=
1.0
+
vterm
*
(
unitkx
*
k
)
*
(
unitkx
*
k
);
vg
[
kcount
][
1
]
=
1.0
+
vterm
*
(
unitky
*
l
)
*
(
unitky
*
l
);
vg
[
kcount
][
2
]
=
1.0
+
vterm
*
(
unitkz
*
m
)
*
(
unitkz
*
m
);
vg
[
kcount
][
3
]
=
vterm
*
unitkx
*
k
*
unitky
*
l
;
vg
[
kcount
][
4
]
=
vterm
*
unitkx
*
k
*
unitkz
*
m
;
vg
[
kcount
][
5
]
=
vterm
*
unitky
*
l
*
unitkz
*
m
;
kcount
++
;
kxvecs
[
kcount
]
=
k
;
kyvecs
[
kcount
]
=
-
l
;
kzvecs
[
kcount
]
=
m
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
2.0
*
unitkx
*
k
*
ug
[
kcount
];
eg
[
kcount
][
1
]
=
-
2.0
*
unitky
*
l
*
ug
[
kcount
];
eg
[
kcount
][
2
]
=
2.0
*
unitkz
*
m
*
ug
[
kcount
];
vg
[
kcount
][
0
]
=
1.0
+
vterm
*
(
unitkx
*
k
)
*
(
unitkx
*
k
);
vg
[
kcount
][
1
]
=
1.0
+
vterm
*
(
unitky
*
l
)
*
(
unitky
*
l
);
vg
[
kcount
][
2
]
=
1.0
+
vterm
*
(
unitkz
*
m
)
*
(
unitkz
*
m
);
vg
[
kcount
][
3
]
=
-
vterm
*
unitkx
*
k
*
unitky
*
l
;
vg
[
kcount
][
4
]
=
vterm
*
unitkx
*
k
*
unitkz
*
m
;
vg
[
kcount
][
5
]
=
-
vterm
*
unitky
*
l
*
unitkz
*
m
;
kcount
++
;
kxvecs
[
kcount
]
=
k
;
kyvecs
[
kcount
]
=
l
;
kzvecs
[
kcount
]
=
-
m
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
2.0
*
unitkx
*
k
*
ug
[
kcount
];
eg
[
kcount
][
1
]
=
2.0
*
unitky
*
l
*
ug
[
kcount
];
eg
[
kcount
][
2
]
=
-
2.0
*
unitkz
*
m
*
ug
[
kcount
];
vg
[
kcount
][
0
]
=
1.0
+
vterm
*
(
unitkx
*
k
)
*
(
unitkx
*
k
);
vg
[
kcount
][
1
]
=
1.0
+
vterm
*
(
unitky
*
l
)
*
(
unitky
*
l
);
vg
[
kcount
][
2
]
=
1.0
+
vterm
*
(
unitkz
*
m
)
*
(
unitkz
*
m
);
vg
[
kcount
][
3
]
=
vterm
*
unitkx
*
k
*
unitky
*
l
;
vg
[
kcount
][
4
]
=
-
vterm
*
unitkx
*
k
*
unitkz
*
m
;
vg
[
kcount
][
5
]
=
-
vterm
*
unitky
*
l
*
unitkz
*
m
;
kcount
++
;
kxvecs
[
kcount
]
=
k
;
kyvecs
[
kcount
]
=
-
l
;
kzvecs
[
kcount
]
=
-
m
;
ug
[
kcount
]
=
preu
*
exp
(
-
0.25
*
sqk
*
g_ewald_sq_inv
)
/
sqk
;
eg
[
kcount
][
0
]
=
2.0
*
unitkx
*
k
*
ug
[
kcount
];
eg
[
kcount
][
1
]
=
-
2.0
*
unitky
*
l
*
ug
[
kcount
];
eg
[
kcount
][
2
]
=
-
2.0
*
unitkz
*
m
*
ug
[
kcount
];
vg
[
kcount
][
0
]
=
1.0
+
vterm
*
(
unitkx
*
k
)
*
(
unitkx
*
k
);
vg
[
kcount
][
1
]
=
1.0
+
vterm
*
(
unitky
*
l
)
*
(
unitky
*
l
);
vg
[
kcount
][
2
]
=
1.0
+
vterm
*
(
unitkz
*
m
)
*
(
unitkz
*
m
);
vg
[
kcount
][
3
]
=
-
vterm
*
unitkx
*
k
*
unitky
*
l
;
vg
[
kcount
][
4
]
=
-
vterm
*
unitkx
*
k
*
unitkz
*
m
;
vg
[
kcount
][
5
]
=
vterm
*
unitky
*
l
*
unitkz
*
m
;
kcount
++
;;
}
}
}
}
}
/* ----------------------------------------------------------------------
allocate memory that depends on # of K-vectors
------------------------------------------------------------------------- */
void
Ewald
::
allocate
()
{
kxvecs
=
new
int
[
kmax3d
];
kyvecs
=
new
int
[
kmax3d
];
kzvecs
=
new
int
[
kmax3d
];
ug
=
new
double
[
kmax3d
];
eg
=
memory
->
create_2d_double_array
(
kmax3d
,
3
,
"ewald:eg"
);
vg
=
memory
->
create_2d_double_array
(
kmax3d
,
6
,
"ewald:vg"
);
sfacrl
=
new
double
[
kmax3d
];
sfacim
=
new
double
[
kmax3d
];
sfacrl_all
=
new
double
[
kmax3d
];
sfacim_all
=
new
double
[
kmax3d
];
}
/* ----------------------------------------------------------------------
deallocate memory that depends on # of K-vectors
------------------------------------------------------------------------- */
void
Ewald
::
deallocate
()
{
delete
[]
kxvecs
;
delete
[]
kyvecs
;
delete
[]
kzvecs
;
delete
[]
ug
;
memory
->
destroy_2d_double_array
(
eg
);
memory
->
destroy_2d_double_array
(
vg
);
delete
[]
sfacrl
;
delete
[]
sfacim
;
delete
[]
sfacrl_all
;
delete
[]
sfacim_all
;
}
/* ----------------------------------------------------------------------
Slab-geometry correction term to dampen inter-slab interactions between
periodically repeating slabs. Yields good approximation to 2-D Ewald if
adequate empty space is left between repeating slabs (J. Chem. Phys.
111, 3155). Slabs defined here to be parallel to the xy plane.
------------------------------------------------------------------------- */
void
Ewald
::
slabcorr
(
int
eflag
)
{
// compute local contribution to global dipole moment
double
*
q
=
atom
->
q
;
double
**
x
=
atom
->
x
;
int
nlocal
=
atom
->
nlocal
;
double
dipole
=
0.0
;
for
(
int
i
=
0
;
i
<
nlocal
;
i
++
)
dipole
+=
q
[
i
]
*
x
[
i
][
2
];
// sum local contributions to get global dipole moment
double
dipole_all
;
MPI_Allreduce
(
&
dipole
,
&
dipole_all
,
1
,
MPI_DOUBLE
,
MPI_SUM
,
world
);
// compute corrections
double
e_slabcorr
=
2.0
*
PI
*
dipole_all
*
dipole_all
/
volume
;
if
(
eflag
)
energy
+=
qqrd2e
*
scale
*
e_slabcorr
;
// add on force corrections
double
ffact
=
-
4.0
*
PI
*
dipole_all
/
volume
;
double
**
f
=
atom
->
f
;
for
(
int
i
=
0
;
i
<
nlocal
;
i
++
)
f
[
i
][
2
]
+=
qqrd2e
*
scale
*
q
[
i
]
*
ffact
;
}
/* ----------------------------------------------------------------------
memory usage of local arrays
------------------------------------------------------------------------- */
double
Ewald
::
memory_usage
()
{
double
bytes
=
3
*
kmax3d
*
sizeof
(
int
);
bytes
+=
(
1
+
3
+
6
)
*
kmax3d
*
sizeof
(
double
);
bytes
+=
4
*
kmax3d
*
sizeof
(
double
);
bytes
+=
nmax
*
3
*
sizeof
(
double
);
bytes
+=
2
*
(
2
*
kmax
+
1
)
*
3
*
nmax
*
sizeof
(
double
);
return
bytes
;
}
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