Page Menu
Home
c4science
Search
Configure Global Search
Log In
Files
F74642373
pair_lj_cut_coul_long_cs.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
Sun, Jul 28, 21:49
Size
17 KB
Mime Type
text/x-c
Expires
Tue, Jul 30, 21:49 (1 d, 23 h)
Engine
blob
Format
Raw Data
Handle
19242227
Attached To
rLAMMPS lammps
pair_lj_cut_coul_long_cs.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: Hendrik Heenen (hendrik.heenen@mytum.de)
------------------------------------------------------------------------- */
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "pair_lj_cut_coul_long_cs.h"
#include "atom.h"
#include "comm.h"
#include "force.h"
#include "kspace.h"
#include "update.h"
#include "integrate.h"
#include "respa.h"
#include "neighbor.h"
#include "neigh_list.h"
#include "neigh_request.h"
#include "math_const.h"
#include "memory.h"
#include "error.h"
using
namespace
LAMMPS_NS
;
using
namespace
MathConst
;
#define EWALD_F 1.12837917
#define EWALD_P 9.95473818e-1
#define B0 -0.1335096380159268
#define B1 -2.57839507e-1
#define B2 -1.37203639e-1
#define B3 -8.88822059e-3
#define B4 -5.80844129e-3
#define B5 1.14652755e-1
#define EPSILON 1.0e-20
#define EPS_EWALD 1.0e-6
#define EPS_EWALD_SQR 1.0e-12
/* ---------------------------------------------------------------------- */
PairLJCutCoulLongCS
::
PairLJCutCoulLongCS
(
LAMMPS
*
lmp
)
:
PairLJCutCoulLong
(
lmp
)
{
ewaldflag
=
pppmflag
=
1
;
respa_enable
=
1
;
writedata
=
1
;
ftable
=
NULL
;
qdist
=
0.0
;
}
/* ---------------------------------------------------------------------- */
void
PairLJCutCoulLongCS
::
compute
(
int
eflag
,
int
vflag
)
{
int
i
,
ii
,
j
,
jj
,
inum
,
jnum
,
itype
,
jtype
,
itable
;
double
qtmp
,
xtmp
,
ytmp
,
ztmp
,
delx
,
dely
,
delz
,
evdwl
,
ecoul
,
fpair
;
double
fraction
,
table
;
double
r
,
r2inv
,
r6inv
,
forcecoul
,
forcelj
,
factor_coul
,
factor_lj
;
double
grij
,
expm2
,
prefactor
,
t
,
erfc
,
u
;
int
*
ilist
,
*
jlist
,
*
numneigh
,
**
firstneigh
;
double
rsq
;
evdwl
=
ecoul
=
0.0
;
if
(
eflag
||
vflag
)
ev_setup
(
eflag
,
vflag
);
else
evflag
=
vflag_fdotr
=
0
;
double
**
x
=
atom
->
x
;
double
**
f
=
atom
->
f
;
double
*
q
=
atom
->
q
;
int
*
type
=
atom
->
type
;
int
nlocal
=
atom
->
nlocal
;
double
*
special_coul
=
force
->
special_coul
;
double
*
special_lj
=
force
->
special_lj
;
int
newton_pair
=
force
->
newton_pair
;
double
qqrd2e
=
force
->
qqrd2e
;
inum
=
list
->
inum
;
ilist
=
list
->
ilist
;
numneigh
=
list
->
numneigh
;
firstneigh
=
list
->
firstneigh
;
// loop over neighbors of my atoms
for
(
ii
=
0
;
ii
<
inum
;
ii
++
)
{
i
=
ilist
[
ii
];
qtmp
=
q
[
i
];
xtmp
=
x
[
i
][
0
];
ytmp
=
x
[
i
][
1
];
ztmp
=
x
[
i
][
2
];
itype
=
type
[
i
];
jlist
=
firstneigh
[
i
];
jnum
=
numneigh
[
i
];
for
(
jj
=
0
;
jj
<
jnum
;
jj
++
)
{
j
=
jlist
[
jj
];
factor_lj
=
special_lj
[
sbmask
(
j
)];
factor_coul
=
special_coul
[
sbmask
(
j
)];
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
])
{
rsq
+=
EPSILON
;
// Add Epsilon for case: r = 0; Interaction must be removed by special bond;
r2inv
=
1.0
/
rsq
;
if
(
rsq
<
cut_coulsq
)
{
if
(
!
ncoultablebits
||
rsq
<=
tabinnersq
)
{
r
=
sqrt
(
rsq
);
prefactor
=
qqrd2e
*
qtmp
*
q
[
j
];
if
(
factor_coul
<
1.0
)
{
// When bonded parts are being calculated a minimal distance (EPS_EWALD)
// has to be added to the prefactor and erfc in order to make the
// used approximation functions for the Ewald correction valid
grij
=
g_ewald
*
(
r
+
EPS_EWALD
);
expm2
=
exp
(
-
grij
*
grij
);
t
=
1.0
/
(
1.0
+
EWALD_P
*
grij
);
u
=
1.0
-
t
;
erfc
=
t
*
(
1.
+
u
*
(
B0
+
u
*
(
B1
+
u
*
(
B2
+
u
*
(
B3
+
u
*
(
B4
+
u
*
B5
))))))
*
expm2
;
prefactor
/=
(
r
+
EPS_EWALD
);
forcecoul
=
prefactor
*
(
erfc
+
EWALD_F
*
grij
*
expm2
-
(
1.0
-
factor_coul
));
// Additionally r2inv needs to be accordingly modified since the later
// scaling of the overall force shall be consistent
r2inv
=
1.0
/
(
rsq
+
EPS_EWALD_SQR
);
}
else
{
grij
=
g_ewald
*
r
;
expm2
=
exp
(
-
grij
*
grij
);
t
=
1.0
/
(
1.0
+
EWALD_P
*
grij
);
u
=
1.0
-
t
;
erfc
=
t
*
(
1.
+
u
*
(
B0
+
u
*
(
B1
+
u
*
(
B2
+
u
*
(
B3
+
u
*
(
B4
+
u
*
B5
))))))
*
expm2
;
prefactor
/=
r
;
forcecoul
=
prefactor
*
(
erfc
+
EWALD_F
*
grij
*
expm2
);
}
}
else
{
union_int_float_t
rsq_lookup
;
rsq_lookup
.
f
=
rsq
;
itable
=
rsq_lookup
.
i
&
ncoulmask
;
itable
>>=
ncoulshiftbits
;
fraction
=
(
rsq_lookup
.
f
-
rtable
[
itable
])
*
drtable
[
itable
];
table
=
ftable
[
itable
]
+
fraction
*
dftable
[
itable
];
forcecoul
=
qtmp
*
q
[
j
]
*
table
;
if
(
factor_coul
<
1.0
)
{
table
=
ctable
[
itable
]
+
fraction
*
dctable
[
itable
];
prefactor
=
qtmp
*
q
[
j
]
*
table
;
forcecoul
-=
(
1.0
-
factor_coul
)
*
prefactor
;
}
}
}
else
forcecoul
=
0.0
;
if
(
rsq
<
cut_ljsq
[
itype
][
jtype
])
{
r6inv
=
r2inv
*
r2inv
*
r2inv
;
forcelj
=
r6inv
*
(
lj1
[
itype
][
jtype
]
*
r6inv
-
lj2
[
itype
][
jtype
]);
}
else
forcelj
=
0.0
;
fpair
=
(
forcecoul
+
factor_lj
*
forcelj
)
*
r2inv
;
f
[
i
][
0
]
+=
delx
*
fpair
;
f
[
i
][
1
]
+=
dely
*
fpair
;
f
[
i
][
2
]
+=
delz
*
fpair
;
if
(
newton_pair
||
j
<
nlocal
)
{
f
[
j
][
0
]
-=
delx
*
fpair
;
f
[
j
][
1
]
-=
dely
*
fpair
;
f
[
j
][
2
]
-=
delz
*
fpair
;
}
if
(
eflag
)
{
if
(
rsq
<
cut_coulsq
)
{
if
(
!
ncoultablebits
||
rsq
<=
tabinnersq
)
ecoul
=
prefactor
*
erfc
;
else
{
table
=
etable
[
itable
]
+
fraction
*
detable
[
itable
];
ecoul
=
qtmp
*
q
[
j
]
*
table
;
}
if
(
factor_coul
<
1.0
)
ecoul
-=
(
1.0
-
factor_coul
)
*
prefactor
;
}
else
ecoul
=
0.0
;
if
(
rsq
<
cut_ljsq
[
itype
][
jtype
])
{
evdwl
=
r6inv
*
(
lj3
[
itype
][
jtype
]
*
r6inv
-
lj4
[
itype
][
jtype
])
-
offset
[
itype
][
jtype
];
evdwl
*=
factor_lj
;
}
else
evdwl
=
0.0
;
}
if
(
evflag
)
ev_tally
(
i
,
j
,
nlocal
,
newton_pair
,
evdwl
,
ecoul
,
fpair
,
delx
,
dely
,
delz
);
}
}
}
if
(
vflag_fdotr
)
virial_fdotr_compute
();
}
/* ---------------------------------------------------------------------- */
void
PairLJCutCoulLongCS
::
compute_inner
()
{
int
i
,
j
,
ii
,
jj
,
inum
,
jnum
,
itype
,
jtype
;
double
qtmp
,
xtmp
,
ytmp
,
ztmp
,
delx
,
dely
,
delz
,
fpair
;
double
rsq
,
r2inv
,
r6inv
,
forcecoul
,
forcelj
,
factor_coul
,
factor_lj
;
double
rsw
;
int
*
ilist
,
*
jlist
,
*
numneigh
,
**
firstneigh
;
double
**
x
=
atom
->
x
;
double
**
f
=
atom
->
f
;
double
*
q
=
atom
->
q
;
int
*
type
=
atom
->
type
;
int
nlocal
=
atom
->
nlocal
;
double
*
special_coul
=
force
->
special_coul
;
double
*
special_lj
=
force
->
special_lj
;
int
newton_pair
=
force
->
newton_pair
;
double
qqrd2e
=
force
->
qqrd2e
;
inum
=
listinner
->
inum
;
ilist
=
listinner
->
ilist
;
numneigh
=
listinner
->
numneigh
;
firstneigh
=
listinner
->
firstneigh
;
double
cut_out_on
=
cut_respa
[
0
];
double
cut_out_off
=
cut_respa
[
1
];
double
cut_out_diff
=
cut_out_off
-
cut_out_on
;
double
cut_out_on_sq
=
cut_out_on
*
cut_out_on
;
double
cut_out_off_sq
=
cut_out_off
*
cut_out_off
;
// loop over neighbors of my atoms
for
(
ii
=
0
;
ii
<
inum
;
ii
++
)
{
i
=
ilist
[
ii
];
qtmp
=
q
[
i
];
xtmp
=
x
[
i
][
0
];
ytmp
=
x
[
i
][
1
];
ztmp
=
x
[
i
][
2
];
itype
=
type
[
i
];
jlist
=
firstneigh
[
i
];
jnum
=
numneigh
[
i
];
for
(
jj
=
0
;
jj
<
jnum
;
jj
++
)
{
j
=
jlist
[
jj
];
factor_lj
=
special_lj
[
sbmask
(
j
)];
factor_coul
=
special_coul
[
sbmask
(
j
)];
j
&=
NEIGHMASK
;
delx
=
xtmp
-
x
[
j
][
0
];
dely
=
ytmp
-
x
[
j
][
1
];
delz
=
ztmp
-
x
[
j
][
2
];
rsq
=
delx
*
delx
+
dely
*
dely
+
delz
*
delz
;
if
(
rsq
<
cut_out_off_sq
)
{
rsq
+=
EPSILON
;
// Add Epsilon for case: r = 0; Interaction must be removed by special bond;
r2inv
=
1.0
/
rsq
;
forcecoul
=
qqrd2e
*
qtmp
*
q
[
j
]
*
sqrt
(
r2inv
);
if
(
factor_coul
<
1.0
)
forcecoul
-=
(
1.0
-
factor_coul
)
*
forcecoul
;
jtype
=
type
[
j
];
if
(
rsq
<
cut_ljsq
[
itype
][
jtype
])
{
r6inv
=
r2inv
*
r2inv
*
r2inv
;
forcelj
=
r6inv
*
(
lj1
[
itype
][
jtype
]
*
r6inv
-
lj2
[
itype
][
jtype
]);
}
else
forcelj
=
0.0
;
fpair
=
(
forcecoul
+
factor_lj
*
forcelj
)
*
r2inv
;
if
(
rsq
>
cut_out_on_sq
)
{
rsw
=
(
sqrt
(
rsq
)
-
cut_out_on
)
/
cut_out_diff
;
fpair
*=
1.0
+
rsw
*
rsw
*
(
2.0
*
rsw
-
3.0
);
}
f
[
i
][
0
]
+=
delx
*
fpair
;
f
[
i
][
1
]
+=
dely
*
fpair
;
f
[
i
][
2
]
+=
delz
*
fpair
;
if
(
newton_pair
||
j
<
nlocal
)
{
f
[
j
][
0
]
-=
delx
*
fpair
;
f
[
j
][
1
]
-=
dely
*
fpair
;
f
[
j
][
2
]
-=
delz
*
fpair
;
}
}
}
}
}
/* ---------------------------------------------------------------------- */
void
PairLJCutCoulLongCS
::
compute_middle
()
{
int
i
,
j
,
ii
,
jj
,
inum
,
jnum
,
itype
,
jtype
;
double
qtmp
,
xtmp
,
ytmp
,
ztmp
,
delx
,
dely
,
delz
,
fpair
;
double
rsq
,
r2inv
,
r6inv
,
forcecoul
,
forcelj
,
factor_coul
,
factor_lj
;
double
rsw
;
int
*
ilist
,
*
jlist
,
*
numneigh
,
**
firstneigh
;
double
**
x
=
atom
->
x
;
double
**
f
=
atom
->
f
;
double
*
q
=
atom
->
q
;
int
*
type
=
atom
->
type
;
int
nlocal
=
atom
->
nlocal
;
double
*
special_coul
=
force
->
special_coul
;
double
*
special_lj
=
force
->
special_lj
;
int
newton_pair
=
force
->
newton_pair
;
double
qqrd2e
=
force
->
qqrd2e
;
inum
=
listmiddle
->
inum
;
ilist
=
listmiddle
->
ilist
;
numneigh
=
listmiddle
->
numneigh
;
firstneigh
=
listmiddle
->
firstneigh
;
double
cut_in_off
=
cut_respa
[
0
];
double
cut_in_on
=
cut_respa
[
1
];
double
cut_out_on
=
cut_respa
[
2
];
double
cut_out_off
=
cut_respa
[
3
];
double
cut_in_diff
=
cut_in_on
-
cut_in_off
;
double
cut_out_diff
=
cut_out_off
-
cut_out_on
;
double
cut_in_off_sq
=
cut_in_off
*
cut_in_off
;
double
cut_in_on_sq
=
cut_in_on
*
cut_in_on
;
double
cut_out_on_sq
=
cut_out_on
*
cut_out_on
;
double
cut_out_off_sq
=
cut_out_off
*
cut_out_off
;
// loop over neighbors of my atoms
for
(
ii
=
0
;
ii
<
inum
;
ii
++
)
{
i
=
ilist
[
ii
];
qtmp
=
q
[
i
];
xtmp
=
x
[
i
][
0
];
ytmp
=
x
[
i
][
1
];
ztmp
=
x
[
i
][
2
];
itype
=
type
[
i
];
jlist
=
firstneigh
[
i
];
jnum
=
numneigh
[
i
];
for
(
jj
=
0
;
jj
<
jnum
;
jj
++
)
{
j
=
jlist
[
jj
];
factor_lj
=
special_lj
[
sbmask
(
j
)];
factor_coul
=
special_coul
[
sbmask
(
j
)];
j
&=
NEIGHMASK
;
delx
=
xtmp
-
x
[
j
][
0
];
dely
=
ytmp
-
x
[
j
][
1
];
delz
=
ztmp
-
x
[
j
][
2
];
rsq
=
delx
*
delx
+
dely
*
dely
+
delz
*
delz
;
if
(
rsq
<
cut_out_off_sq
&&
rsq
>
cut_in_off_sq
)
{
r2inv
=
1.0
/
rsq
;
forcecoul
=
qqrd2e
*
qtmp
*
q
[
j
]
*
sqrt
(
r2inv
);
if
(
factor_coul
<
1.0
)
forcecoul
-=
(
1.0
-
factor_coul
)
*
forcecoul
;
jtype
=
type
[
j
];
if
(
rsq
<
cut_ljsq
[
itype
][
jtype
])
{
r6inv
=
r2inv
*
r2inv
*
r2inv
;
forcelj
=
r6inv
*
(
lj1
[
itype
][
jtype
]
*
r6inv
-
lj2
[
itype
][
jtype
]);
}
else
forcelj
=
0.0
;
fpair
=
(
forcecoul
+
factor_lj
*
forcelj
)
*
r2inv
;
if
(
rsq
<
cut_in_on_sq
)
{
rsw
=
(
sqrt
(
rsq
)
-
cut_in_off
)
/
cut_in_diff
;
fpair
*=
rsw
*
rsw
*
(
3.0
-
2.0
*
rsw
);
}
if
(
rsq
>
cut_out_on_sq
)
{
rsw
=
(
sqrt
(
rsq
)
-
cut_out_on
)
/
cut_out_diff
;
fpair
*=
1.0
+
rsw
*
rsw
*
(
2.0
*
rsw
-
3.0
);
}
f
[
i
][
0
]
+=
delx
*
fpair
;
f
[
i
][
1
]
+=
dely
*
fpair
;
f
[
i
][
2
]
+=
delz
*
fpair
;
if
(
newton_pair
||
j
<
nlocal
)
{
f
[
j
][
0
]
-=
delx
*
fpair
;
f
[
j
][
1
]
-=
dely
*
fpair
;
f
[
j
][
2
]
-=
delz
*
fpair
;
}
}
}
}
}
/* ---------------------------------------------------------------------- */
void
PairLJCutCoulLongCS
::
compute_outer
(
int
eflag
,
int
vflag
)
{
int
i
,
j
,
ii
,
jj
,
inum
,
jnum
,
itype
,
jtype
,
itable
;
double
qtmp
,
xtmp
,
ytmp
,
ztmp
,
delx
,
dely
,
delz
,
evdwl
,
ecoul
,
fpair
;
double
fraction
,
table
;
double
r
,
r2inv
,
r6inv
,
forcecoul
,
forcelj
,
factor_coul
,
factor_lj
;
double
grij
,
expm2
,
prefactor
,
t
,
erfc
,
u
;
double
rsw
;
int
*
ilist
,
*
jlist
,
*
numneigh
,
**
firstneigh
;
double
rsq
;
evdwl
=
ecoul
=
0.0
;
if
(
eflag
||
vflag
)
ev_setup
(
eflag
,
vflag
);
else
evflag
=
0
;
double
**
x
=
atom
->
x
;
double
**
f
=
atom
->
f
;
double
*
q
=
atom
->
q
;
int
*
type
=
atom
->
type
;
int
nlocal
=
atom
->
nlocal
;
double
*
special_coul
=
force
->
special_coul
;
double
*
special_lj
=
force
->
special_lj
;
int
newton_pair
=
force
->
newton_pair
;
double
qqrd2e
=
force
->
qqrd2e
;
inum
=
listouter
->
inum
;
ilist
=
listouter
->
ilist
;
numneigh
=
listouter
->
numneigh
;
firstneigh
=
listouter
->
firstneigh
;
double
cut_in_off
=
cut_respa
[
2
];
double
cut_in_on
=
cut_respa
[
3
];
double
cut_in_diff
=
cut_in_on
-
cut_in_off
;
double
cut_in_off_sq
=
cut_in_off
*
cut_in_off
;
double
cut_in_on_sq
=
cut_in_on
*
cut_in_on
;
// loop over neighbors of my atoms
for
(
ii
=
0
;
ii
<
inum
;
ii
++
)
{
i
=
ilist
[
ii
];
qtmp
=
q
[
i
];
xtmp
=
x
[
i
][
0
];
ytmp
=
x
[
i
][
1
];
ztmp
=
x
[
i
][
2
];
itype
=
type
[
i
];
jlist
=
firstneigh
[
i
];
jnum
=
numneigh
[
i
];
for
(
jj
=
0
;
jj
<
jnum
;
jj
++
)
{
j
=
jlist
[
jj
];
factor_lj
=
special_lj
[
sbmask
(
j
)];
factor_coul
=
special_coul
[
sbmask
(
j
)];
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
])
{
rsq
+=
EPSILON
;
// Add Epsilon for case: r = 0; Interaction must be removed by special bond;
r2inv
=
1.0
/
rsq
;
if
(
rsq
<
cut_coulsq
)
{
if
(
!
ncoultablebits
||
rsq
<=
tabinnersq
)
{
r
=
sqrt
(
rsq
);
grij
=
g_ewald
*
r
;
expm2
=
exp
(
-
grij
*
grij
);
t
=
1.0
/
(
1.0
+
EWALD_P
*
grij
);
u
=
1.
-
t
;
erfc
=
t
*
(
1.
+
u
*
(
B0
+
u
*
(
B1
+
u
*
(
B2
+
u
*
(
B3
+
u
*
(
B4
+
u
*
B5
))))))
*
expm2
;
//erfc = t * (A1+t*(A2+t*(A3+t*(A4+t*A5)))) * expm2;
prefactor
=
qqrd2e
*
qtmp
*
q
[
j
]
/
r
;
forcecoul
=
prefactor
*
(
erfc
+
EWALD_F
*
grij
*
expm2
-
1.0
);
if
(
rsq
>
cut_in_off_sq
)
{
if
(
rsq
<
cut_in_on_sq
)
{
rsw
=
(
r
-
cut_in_off
)
/
cut_in_diff
;
forcecoul
+=
prefactor
*
rsw
*
rsw
*
(
3.0
-
2.0
*
rsw
);
if
(
factor_coul
<
1.0
)
forcecoul
-=
(
1.0
-
factor_coul
)
*
prefactor
*
rsw
*
rsw
*
(
3.0
-
2.0
*
rsw
);
}
else
{
forcecoul
+=
prefactor
;
if
(
factor_coul
<
1.0
)
forcecoul
-=
(
1.0
-
factor_coul
)
*
prefactor
;
}
}
}
else
{
union_int_float_t
rsq_lookup
;
rsq_lookup
.
f
=
rsq
;
itable
=
rsq_lookup
.
i
&
ncoulmask
;
itable
>>=
ncoulshiftbits
;
fraction
=
(
rsq_lookup
.
f
-
rtable
[
itable
])
*
drtable
[
itable
];
table
=
ftable
[
itable
]
+
fraction
*
dftable
[
itable
];
forcecoul
=
qtmp
*
q
[
j
]
*
table
;
if
(
factor_coul
<
1.0
)
{
table
=
ctable
[
itable
]
+
fraction
*
dctable
[
itable
];
prefactor
=
qtmp
*
q
[
j
]
*
table
;
forcecoul
-=
(
1.0
-
factor_coul
)
*
prefactor
;
}
}
}
else
forcecoul
=
0.0
;
if
(
rsq
<
cut_ljsq
[
itype
][
jtype
]
&&
rsq
>
cut_in_off_sq
)
{
r6inv
=
r2inv
*
r2inv
*
r2inv
;
forcelj
=
r6inv
*
(
lj1
[
itype
][
jtype
]
*
r6inv
-
lj2
[
itype
][
jtype
]);
if
(
rsq
<
cut_in_on_sq
)
{
rsw
=
(
sqrt
(
rsq
)
-
cut_in_off
)
/
cut_in_diff
;
forcelj
*=
rsw
*
rsw
*
(
3.0
-
2.0
*
rsw
);
}
}
else
forcelj
=
0.0
;
fpair
=
(
forcecoul
+
forcelj
)
*
r2inv
;
f
[
i
][
0
]
+=
delx
*
fpair
;
f
[
i
][
1
]
+=
dely
*
fpair
;
f
[
i
][
2
]
+=
delz
*
fpair
;
if
(
newton_pair
||
j
<
nlocal
)
{
f
[
j
][
0
]
-=
delx
*
fpair
;
f
[
j
][
1
]
-=
dely
*
fpair
;
f
[
j
][
2
]
-=
delz
*
fpair
;
}
if
(
eflag
)
{
if
(
rsq
<
cut_coulsq
)
{
if
(
!
ncoultablebits
||
rsq
<=
tabinnersq
)
{
ecoul
=
prefactor
*
erfc
;
if
(
factor_coul
<
1.0
)
ecoul
-=
(
1.0
-
factor_coul
)
*
prefactor
;
}
else
{
table
=
etable
[
itable
]
+
fraction
*
detable
[
itable
];
ecoul
=
qtmp
*
q
[
j
]
*
table
;
if
(
factor_coul
<
1.0
)
{
table
=
ptable
[
itable
]
+
fraction
*
dptable
[
itable
];
prefactor
=
qtmp
*
q
[
j
]
*
table
;
ecoul
-=
(
1.0
-
factor_coul
)
*
prefactor
;
}
}
}
else
ecoul
=
0.0
;
if
(
rsq
<
cut_ljsq
[
itype
][
jtype
])
{
r6inv
=
r2inv
*
r2inv
*
r2inv
;
evdwl
=
r6inv
*
(
lj3
[
itype
][
jtype
]
*
r6inv
-
lj4
[
itype
][
jtype
])
-
offset
[
itype
][
jtype
];
evdwl
*=
factor_lj
;
}
else
evdwl
=
0.0
;
}
if
(
vflag
)
{
if
(
rsq
<
cut_coulsq
)
{
if
(
!
ncoultablebits
||
rsq
<=
tabinnersq
)
{
forcecoul
=
prefactor
*
(
erfc
+
EWALD_F
*
grij
*
expm2
);
if
(
factor_coul
<
1.0
)
forcecoul
-=
(
1.0
-
factor_coul
)
*
prefactor
;
}
else
{
table
=
vtable
[
itable
]
+
fraction
*
dvtable
[
itable
];
forcecoul
=
qtmp
*
q
[
j
]
*
table
;
if
(
factor_coul
<
1.0
)
{
table
=
ptable
[
itable
]
+
fraction
*
dptable
[
itable
];
prefactor
=
qtmp
*
q
[
j
]
*
table
;
forcecoul
-=
(
1.0
-
factor_coul
)
*
prefactor
;
}
}
}
else
forcecoul
=
0.0
;
if
(
rsq
<=
cut_in_off_sq
)
{
r6inv
=
r2inv
*
r2inv
*
r2inv
;
forcelj
=
r6inv
*
(
lj1
[
itype
][
jtype
]
*
r6inv
-
lj2
[
itype
][
jtype
]);
}
else
if
(
rsq
<=
cut_in_on_sq
)
{
r6inv
=
r2inv
*
r2inv
*
r2inv
;
forcelj
=
r6inv
*
(
lj1
[
itype
][
jtype
]
*
r6inv
-
lj2
[
itype
][
jtype
]);
}
fpair
=
(
forcecoul
+
factor_lj
*
forcelj
)
*
r2inv
;
}
if
(
evflag
)
ev_tally
(
i
,
j
,
nlocal
,
newton_pair
,
evdwl
,
ecoul
,
fpair
,
delx
,
dely
,
delz
);
}
}
}
}
Event Timeline
Log In to Comment