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rLAMMPS lammps
dihedral_class2.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: Eric Simon (Cray)
------------------------------------------------------------------------- */
#include "math.h"
#include "stdlib.h"
#include "dihedral_class2.h"
#include "atom.h"
#include "neighbor.h"
#include "update.h"
#include "domain.h"
#include "comm.h"
#include "force.h"
#include "memory.h"
#include "error.h"
using
namespace
LAMMPS_NS
;
#define MIN(A,B) ((A) < (B)) ? (A) : (B)
#define MAX(A,B) ((A) > (B)) ? (A) : (B)
#define TOLERANCE 0.05
#define SMALL 0.0000001
/* ---------------------------------------------------------------------- */
DihedralClass2
::
DihedralClass2
(
LAMMPS
*
lmp
)
:
Dihedral
(
lmp
)
{
PI
=
4.0
*
atan
(
1.0
);
}
/* ---------------------------------------------------------------------- */
DihedralClass2
::~
DihedralClass2
()
{
if
(
allocated
)
{
memory
->
sfree
(
setflag
);
memory
->
sfree
(
setflag_d
);
memory
->
sfree
(
setflag_mbt
);
memory
->
sfree
(
setflag_ebt
);
memory
->
sfree
(
setflag_at
);
memory
->
sfree
(
setflag_aat
);
memory
->
sfree
(
setflag_bb13t
);
memory
->
sfree
(
k1
);
memory
->
sfree
(
k2
);
memory
->
sfree
(
k3
);
memory
->
sfree
(
phi1
);
memory
->
sfree
(
phi2
);
memory
->
sfree
(
phi3
);
memory
->
sfree
(
mbt_f1
);
memory
->
sfree
(
mbt_f2
);
memory
->
sfree
(
mbt_f3
);
memory
->
sfree
(
mbt_r0
);
memory
->
sfree
(
ebt_f1_1
);
memory
->
sfree
(
ebt_f2_1
);
memory
->
sfree
(
ebt_f3_1
);
memory
->
sfree
(
ebt_r0_1
);
memory
->
sfree
(
ebt_f1_2
);
memory
->
sfree
(
ebt_f2_2
);
memory
->
sfree
(
ebt_f3_2
);
memory
->
sfree
(
ebt_r0_2
);
memory
->
sfree
(
at_f1_1
);
memory
->
sfree
(
at_f2_1
);
memory
->
sfree
(
at_f3_1
);
memory
->
sfree
(
at_theta0_1
);
memory
->
sfree
(
at_f1_2
);
memory
->
sfree
(
at_f2_2
);
memory
->
sfree
(
at_f3_2
);
memory
->
sfree
(
at_theta0_2
);
memory
->
sfree
(
aat_k
);
memory
->
sfree
(
aat_theta0_1
);
memory
->
sfree
(
aat_theta0_2
);
memory
->
sfree
(
bb13t_k
);
memory
->
sfree
(
bb13t_r10
);
memory
->
sfree
(
bb13t_r30
);
}
}
/* ---------------------------------------------------------------------- */
void
DihedralClass2
::
compute
(
int
eflag
,
int
vflag
)
{
int
i1
,
i2
,
i3
,
i4
,
i
,
j
,
k
,
n
,
type
;
double
vb1x
,
vb1y
,
vb1z
,
vb2x
,
vb2y
,
vb2z
,
vb3x
,
vb3y
,
vb3z
,
vb2xm
,
vb2ym
,
vb2zm
;
double
edihedral
;
double
r1mag2
,
r1
,
r2mag2
,
r2
,
r3mag2
,
r3
;
double
sb1
,
rb1
,
sb2
,
rb2
,
sb3
,
rb3
,
c0
,
r12c1
;
double
r12c2
,
costh12
,
costh13
,
costh23
,
sc1
,
sc2
,
s1
,
s2
,
c
;
double
cosphi
,
phi
,
sinphi
,
a11
,
a22
,
a33
,
a12
,
a13
,
a23
,
sx1
,
sx2
;
double
sx12
,
sy1
,
sy2
,
sy12
,
sz1
,
sz2
,
sz12
,
dphi1
,
dphi2
,
dphi3
;
double
de_dihedral
,
t1
,
t2
,
t3
,
t4
,
cos2phi
,
cos3phi
,
bt1
,
bt2
;
double
bt3
,
sumbte
,
db
,
sumbtf
,
at1
,
at2
,
at3
,
da
,
da1
,
da2
,
r1_0
;
double
r3_0
,
dr1
,
dr2
,
tk1
,
tk2
,
s12
,
sin2
;
double
dcosphidr
[
4
][
3
],
dphidr
[
4
][
3
],
dbonddr
[
3
][
4
][
3
],
dthetadr
[
2
][
4
][
3
];
double
fabcd
[
4
][
3
];
edihedral
=
0.0
;
if
(
eflag
||
vflag
)
ev_setup
(
eflag
,
vflag
);
else
evflag
=
0
;
double
**
x
=
atom
->
x
;
double
**
f
=
atom
->
f
;
int
**
dihedrallist
=
neighbor
->
dihedrallist
;
int
ndihedrallist
=
neighbor
->
ndihedrallist
;
int
nlocal
=
atom
->
nlocal
;
int
newton_bond
=
force
->
newton_bond
;
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
];
domain
->
minimum_image
(
vb1x
,
vb1y
,
vb1z
);
// 2nd bond
vb2x
=
x
[
i3
][
0
]
-
x
[
i2
][
0
];
vb2y
=
x
[
i3
][
1
]
-
x
[
i2
][
1
];
vb2z
=
x
[
i3
][
2
]
-
x
[
i2
][
2
];
domain
->
minimum_image
(
vb2x
,
vb2y
,
vb2z
);
vb2xm
=
-
vb2x
;
vb2ym
=
-
vb2y
;
vb2zm
=
-
vb2z
;
domain
->
minimum_image
(
vb2xm
,
vb2ym
,
vb2zm
);
// 3rd bond
vb3x
=
x
[
i4
][
0
]
-
x
[
i3
][
0
];
vb3y
=
x
[
i4
][
1
]
-
x
[
i3
][
1
];
vb3z
=
x
[
i4
][
2
]
-
x
[
i3
][
2
];
domain
->
minimum_image
(
vb3x
,
vb3y
,
vb3z
);
// distances
r1mag2
=
vb1x
*
vb1x
+
vb1y
*
vb1y
+
vb1z
*
vb1z
;
r1
=
sqrt
(
r1mag2
);
r2mag2
=
vb2x
*
vb2x
+
vb2y
*
vb2y
+
vb2z
*
vb2z
;
r2
=
sqrt
(
r2mag2
);
r3mag2
=
vb3x
*
vb3x
+
vb3y
*
vb3y
+
vb3z
*
vb3z
;
r3
=
sqrt
(
r3mag2
);
sb1
=
1.0
/
r1mag2
;
rb1
=
1.0
/
r1
;
sb2
=
1.0
/
r2mag2
;
rb2
=
1.0
/
r2
;
sb3
=
1.0
/
r3mag2
;
rb3
=
1.0
/
r3
;
c0
=
(
vb1x
*
vb3x
+
vb1y
*
vb3y
+
vb1z
*
vb3z
)
*
rb1
*
rb3
;
// angles
r12c1
=
rb1
*
rb2
;
r12c2
=
rb2
*
rb3
;
costh12
=
(
vb1x
*
vb2x
+
vb1y
*
vb2y
+
vb1z
*
vb2z
)
*
r12c1
;
costh13
=
c0
;
costh23
=
(
vb2xm
*
vb3x
+
vb2ym
*
vb3y
+
vb2zm
*
vb3z
)
*
r12c2
;
// cos and sin of 2 angles and final c
sin2
=
MAX
(
1.0
-
costh12
*
costh12
,
0.0
);
sc1
=
sqrt
(
sin2
);
if
(
sc1
<
SMALL
)
sc1
=
SMALL
;
sc1
=
1.0
/
sc1
;
sin2
=
MAX
(
1.0
-
costh23
*
costh23
,
0.0
);
sc2
=
sqrt
(
sin2
);
if
(
sc2
<
SMALL
)
sc2
=
SMALL
;
sc2
=
1.0
/
sc2
;
s1
=
sc1
*
sc1
;
s2
=
sc2
*
sc2
;
s12
=
sc1
*
sc2
;
c
=
(
c0
+
costh12
*
costh23
)
*
s12
;
// 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 %d %d %d %d %d
\n
"
,
me
,
update
->
ntimestep
,
atom
->
tag
[
i1
],
atom
->
tag
[
i2
],
atom
->
tag
[
i3
],
atom
->
tag
[
i4
]);
error
->
warning
(
str
);
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
;
cosphi
=
c
;
phi
=
acos
(
c
);
sinphi
=
sqrt
(
1.0
-
c
*
c
);
sinphi
=
MAX
(
sinphi
,
SMALL
);
a11
=
-
c
*
sb1
*
s1
;
a22
=
sb2
*
(
2.0
*
costh13
*
s12
-
c
*
(
s1
+
s2
));
a33
=
-
c
*
sb3
*
s2
;
a12
=
r12c1
*
(
costh12
*
c
*
s1
+
costh23
*
s12
);
a13
=
rb1
*
rb3
*
s12
;
a23
=
r12c2
*
(
-
costh23
*
c
*
s2
-
costh12
*
s12
);
sx1
=
a11
*
vb1x
+
a12
*
vb2x
+
a13
*
vb3x
;
sx2
=
a12
*
vb1x
+
a22
*
vb2x
+
a23
*
vb3x
;
sx12
=
a13
*
vb1x
+
a23
*
vb2x
+
a33
*
vb3x
;
sy1
=
a11
*
vb1y
+
a12
*
vb2y
+
a13
*
vb3y
;
sy2
=
a12
*
vb1y
+
a22
*
vb2y
+
a23
*
vb3y
;
sy12
=
a13
*
vb1y
+
a23
*
vb2y
+
a33
*
vb3y
;
sz1
=
a11
*
vb1z
+
a12
*
vb2z
+
a13
*
vb3z
;
sz2
=
a12
*
vb1z
+
a22
*
vb2z
+
a23
*
vb3z
;
sz12
=
a13
*
vb1z
+
a23
*
vb2z
+
a33
*
vb3z
;
// set up d(cos(phi))/d(r) and dphi/dr arrays
dcosphidr
[
0
][
0
]
=
-
sx1
;
dcosphidr
[
0
][
1
]
=
-
sy1
;
dcosphidr
[
0
][
2
]
=
-
sz1
;
dcosphidr
[
1
][
0
]
=
sx2
+
sx1
;
dcosphidr
[
1
][
1
]
=
sy2
+
sy1
;
dcosphidr
[
1
][
2
]
=
sz2
+
sz1
;
dcosphidr
[
2
][
0
]
=
sx12
-
sx2
;
dcosphidr
[
2
][
1
]
=
sy12
-
sy2
;
dcosphidr
[
2
][
2
]
=
sz12
-
sz2
;
dcosphidr
[
3
][
0
]
=
-
sx12
;
dcosphidr
[
3
][
1
]
=
-
sy12
;
dcosphidr
[
3
][
2
]
=
-
sz12
;
for
(
i
=
0
;
i
<
4
;
i
++
)
for
(
j
=
0
;
j
<
3
;
j
++
)
dphidr
[
i
][
j
]
=
-
dcosphidr
[
i
][
j
]
/
sinphi
;
// energy
dphi1
=
phi
-
phi1
[
type
];
dphi2
=
2.0
*
phi
-
phi2
[
type
];
dphi3
=
3.0
*
phi
-
phi3
[
type
];
if
(
eflag
)
edihedral
=
k1
[
type
]
*
(
1.0
-
cos
(
dphi1
))
+
k2
[
type
]
*
(
1.0
-
cos
(
dphi2
))
+
k3
[
type
]
*
(
1.0
-
cos
(
dphi3
));
de_dihedral
=
k1
[
type
]
*
sin
(
dphi1
)
+
2.0
*
k2
[
type
]
*
sin
(
dphi2
)
+
3.0
*
k3
[
type
]
*
sin
(
dphi3
);
// torsion forces on all 4 atoms
for
(
i
=
0
;
i
<
4
;
i
++
)
for
(
j
=
0
;
j
<
3
;
j
++
)
fabcd
[
i
][
j
]
=
de_dihedral
*
dphidr
[
i
][
j
];
// set up d(bond)/d(r) array
// dbonddr(i,j,k) = bond i, atom j, coordinate k
for
(
i
=
0
;
i
<
3
;
i
++
)
for
(
j
=
0
;
j
<
4
;
j
++
)
for
(
k
=
0
;
k
<
3
;
k
++
)
dbonddr
[
i
][
j
][
k
]
=
0.0
;
// bond1
dbonddr
[
0
][
0
][
0
]
=
vb1x
/
r1
;
dbonddr
[
0
][
0
][
1
]
=
vb1y
/
r1
;
dbonddr
[
0
][
0
][
2
]
=
vb1z
/
r1
;
dbonddr
[
0
][
1
][
0
]
=
-
vb1x
/
r1
;
dbonddr
[
0
][
1
][
1
]
=
-
vb1y
/
r1
;
dbonddr
[
0
][
1
][
2
]
=
-
vb1z
/
r1
;
// bond2
dbonddr
[
1
][
1
][
0
]
=
vb2x
/
r2
;
dbonddr
[
1
][
1
][
1
]
=
vb2y
/
r2
;
dbonddr
[
1
][
1
][
2
]
=
vb2z
/
r2
;
dbonddr
[
1
][
2
][
0
]
=
-
vb2x
/
r2
;
dbonddr
[
1
][
2
][
1
]
=
-
vb2y
/
r2
;
dbonddr
[
1
][
2
][
2
]
=
-
vb2z
/
r2
;
// bond3
dbonddr
[
2
][
2
][
0
]
=
vb3x
/
r3
;
dbonddr
[
2
][
2
][
1
]
=
vb3y
/
r3
;
dbonddr
[
2
][
2
][
2
]
=
vb3z
/
r3
;
dbonddr
[
2
][
3
][
0
]
=
-
vb3x
/
r3
;
dbonddr
[
2
][
3
][
1
]
=
-
vb3y
/
r3
;
dbonddr
[
2
][
3
][
2
]
=
-
vb3z
/
r3
;
// set up d(theta)/d(r) array
// dthetadr(i,j,k) = angle i, atom j, coordinate k
for
(
i
=
0
;
i
<
2
;
i
++
)
for
(
j
=
0
;
j
<
4
;
j
++
)
for
(
k
=
0
;
k
<
3
;
k
++
)
dthetadr
[
i
][
j
][
k
]
=
0.0
;
t1
=
costh12
/
r1mag2
;
t2
=
costh23
/
r2mag2
;
t3
=
costh12
/
r2mag2
;
t4
=
costh23
/
r3mag2
;
// angle12
dthetadr
[
0
][
0
][
0
]
=
sc1
*
((
t1
*
vb1x
)
-
(
vb2x
*
r12c1
));
dthetadr
[
0
][
0
][
1
]
=
sc1
*
((
t1
*
vb1y
)
-
(
vb2y
*
r12c1
));
dthetadr
[
0
][
0
][
2
]
=
sc1
*
((
t1
*
vb1z
)
-
(
vb2z
*
r12c1
));
dthetadr
[
0
][
1
][
0
]
=
sc1
*
((
-
t1
*
vb1x
)
+
(
vb2x
*
r12c1
)
+
(
-
t3
*
vb2x
)
+
(
vb1x
*
r12c1
));
dthetadr
[
0
][
1
][
1
]
=
sc1
*
((
-
t1
*
vb1y
)
+
(
vb2y
*
r12c1
)
+
(
-
t3
*
vb2y
)
+
(
vb1y
*
r12c1
));
dthetadr
[
0
][
1
][
2
]
=
sc1
*
((
-
t1
*
vb1z
)
+
(
vb2z
*
r12c1
)
+
(
-
t3
*
vb2z
)
+
(
vb1z
*
r12c1
));
dthetadr
[
0
][
2
][
0
]
=
sc1
*
((
t3
*
vb2x
)
-
(
vb1x
*
r12c1
));
dthetadr
[
0
][
2
][
1
]
=
sc1
*
((
t3
*
vb2y
)
-
(
vb1y
*
r12c1
));
dthetadr
[
0
][
2
][
2
]
=
sc1
*
((
t3
*
vb2z
)
-
(
vb1z
*
r12c1
));
// angle23
dthetadr
[
1
][
1
][
0
]
=
sc2
*
((
t2
*
vb2x
)
+
(
vb3x
*
r12c2
));
dthetadr
[
1
][
1
][
1
]
=
sc2
*
((
t2
*
vb2y
)
+
(
vb3y
*
r12c2
));
dthetadr
[
1
][
1
][
2
]
=
sc2
*
((
t2
*
vb2z
)
+
(
vb3z
*
r12c2
));
dthetadr
[
1
][
2
][
0
]
=
sc2
*
((
-
t2
*
vb2x
)
-
(
vb3x
*
r12c2
)
+
(
t4
*
vb3x
)
+
(
vb2x
*
r12c2
));
dthetadr
[
1
][
2
][
1
]
=
sc2
*
((
-
t2
*
vb2y
)
-
(
vb3y
*
r12c2
)
+
(
t4
*
vb3y
)
+
(
vb2y
*
r12c2
));
dthetadr
[
1
][
2
][
2
]
=
sc2
*
((
-
t2
*
vb2z
)
-
(
vb3z
*
r12c2
)
+
(
t4
*
vb3z
)
+
(
vb2z
*
r12c2
));
dthetadr
[
1
][
3
][
0
]
=
-
sc2
*
((
t4
*
vb3x
)
+
(
vb2x
*
r12c2
));
dthetadr
[
1
][
3
][
1
]
=
-
sc2
*
((
t4
*
vb3y
)
+
(
vb2y
*
r12c2
));
dthetadr
[
1
][
3
][
2
]
=
-
sc2
*
((
t4
*
vb3z
)
+
(
vb2z
*
r12c2
));
// mid-bond/torsion coupling
// energy on bond2 (middle bond)
cos2phi
=
cos
(
2.0
*
phi
);
cos3phi
=
cos
(
3.0
*
phi
);
bt1
=
mbt_f1
[
type
]
*
cosphi
;
bt2
=
mbt_f2
[
type
]
*
cos2phi
;
bt3
=
mbt_f3
[
type
]
*
cos3phi
;
sumbte
=
bt1
+
bt2
+
bt3
;
db
=
r2
-
mbt_r0
[
type
];
if
(
eflag
)
edihedral
+=
db
*
sumbte
;
// force on bond2
bt1
=
-
mbt_f1
[
type
]
*
sinphi
;
bt2
=
-
2.0
*
mbt_f2
[
type
]
*
sin
(
2.0
*
phi
);
bt3
=
-
3.0
*
mbt_f3
[
type
]
*
sin
(
3.0
*
phi
);
sumbtf
=
bt1
+
bt2
+
bt3
;
for
(
i
=
0
;
i
<
4
;
i
++
)
for
(
j
=
0
;
j
<
3
;
j
++
)
fabcd
[
i
][
j
]
+=
db
*
sumbtf
*
dphidr
[
i
][
j
]
+
sumbte
*
dbonddr
[
1
][
i
][
j
];
// end-bond/torsion coupling
// energy on bond1 (first bond)
bt1
=
ebt_f1_1
[
type
]
*
cosphi
;
bt2
=
ebt_f2_1
[
type
]
*
cos2phi
;
bt3
=
ebt_f3_1
[
type
]
*
cos3phi
;
sumbte
=
bt1
+
bt2
+
bt3
;
db
=
r1
-
ebt_r0_1
[
type
];
if
(
eflag
)
edihedral
+=
db
*
(
bt1
+
bt2
+
bt3
);
// force on bond1
bt1
=
ebt_f1_1
[
type
]
*
sinphi
;
bt2
=
2.0
*
ebt_f2_1
[
type
]
*
sin
(
2.0
*
phi
);
bt3
=
3.0
*
ebt_f3_1
[
type
]
*
sin
(
3.0
*
phi
);
sumbtf
=
bt1
+
bt2
+
bt3
;
for
(
i
=
0
;
i
<
4
;
i
++
)
for
(
j
=
0
;
j
<
3
;
j
++
)
fabcd
[
i
][
j
]
-=
db
*
sumbtf
*
dphidr
[
i
][
j
]
+
sumbte
*
dbonddr
[
0
][
i
][
j
];
// end-bond/torsion coupling
// energy on bond3 (last bond)
bt1
=
ebt_f1_2
[
type
]
*
cosphi
;
bt2
=
ebt_f2_2
[
type
]
*
cos2phi
;
bt3
=
ebt_f3_2
[
type
]
*
cos3phi
;
sumbte
=
bt1
+
bt2
+
bt3
;
db
=
r3
-
ebt_r0_2
[
type
];
if
(
eflag
)
edihedral
+=
db
*
(
bt1
+
bt2
+
bt3
);
// force on bond3
bt1
=
-
ebt_f1_2
[
type
]
*
sinphi
;
bt2
=
-
2.0
*
ebt_f2_2
[
type
]
*
sin
(
2.0
*
phi
);
bt3
=
-
3.0
*
ebt_f3_2
[
type
]
*
sin
(
3.0
*
phi
);
sumbtf
=
bt1
+
bt2
+
bt3
;
for
(
i
=
0
;
i
<
4
;
i
++
)
for
(
j
=
0
;
j
<
3
;
j
++
)
fabcd
[
i
][
j
]
+=
db
*
sumbtf
*
dphidr
[
i
][
j
]
+
sumbte
*
dbonddr
[
2
][
i
][
j
];
// angle/torsion coupling
// energy on angle1
at1
=
at_f1_1
[
type
]
*
cosphi
;
at2
=
at_f2_1
[
type
]
*
cos2phi
;
at3
=
at_f3_1
[
type
]
*
cos3phi
;
sumbte
=
at1
+
at2
+
at3
;
da
=
acos
(
costh12
)
-
at_theta0_1
[
type
];
if
(
eflag
)
edihedral
+=
da
*
(
at1
+
at2
+
at3
);
// force on angle1
bt1
=
at_f1_1
[
type
]
*
sinphi
;
bt2
=
2.0
*
at_f2_1
[
type
]
*
sin
(
2.0
*
phi
);
bt3
=
3.0
*
at_f3_1
[
type
]
*
sin
(
3.0
*
phi
);
sumbtf
=
bt1
+
bt2
+
bt3
;
for
(
i
=
0
;
i
<
4
;
i
++
)
for
(
j
=
0
;
j
<
3
;
j
++
)
fabcd
[
i
][
j
]
-=
da
*
sumbtf
*
dphidr
[
i
][
j
]
+
sumbte
*
dthetadr
[
0
][
i
][
j
];
// energy on angle2
at1
=
at_f1_2
[
type
]
*
cosphi
;
at2
=
at_f2_2
[
type
]
*
cos2phi
;
at3
=
at_f3_2
[
type
]
*
cos3phi
;
sumbte
=
at1
+
at2
+
at3
;
da
=
acos
(
costh23
)
-
at_theta0_2
[
type
];
if
(
eflag
)
edihedral
+=
da
*
(
at1
+
at2
+
at3
);
// force on angle2
bt1
=
-
at_f1_2
[
type
]
*
sinphi
;
bt2
=
-
2.0
*
at_f2_2
[
type
]
*
sin
(
2.0
*
phi
);
bt3
=
-
3.0
*
at_f3_2
[
type
]
*
sin
(
3.0
*
phi
);
sumbtf
=
bt1
+
bt2
+
bt3
;
for
(
i
=
0
;
i
<
4
;
i
++
)
for
(
j
=
0
;
j
<
3
;
j
++
)
fabcd
[
i
][
j
]
+=
da
*
sumbtf
*
dphidr
[
i
][
j
]
+
sumbte
*
dthetadr
[
1
][
i
][
j
];
// angle/angle/torsion coupling
da1
=
acos
(
costh12
)
-
aat_theta0_1
[
type
];
da2
=
acos
(
costh23
)
-
aat_theta0_2
[
type
];
if
(
eflag
)
edihedral
+=
aat_k
[
type
]
*
da1
*
da2
*
cosphi
;
for
(
i
=
0
;
i
<
4
;
i
++
)
for
(
j
=
0
;
j
<
3
;
j
++
)
fabcd
[
i
][
j
]
-=
aat_k
[
type
]
*
(
cosphi
*
(
da2
*
dthetadr
[
0
][
i
][
j
]
-
da1
*
dthetadr
[
1
][
i
][
j
])
+
sinphi
*
da1
*
da2
*
dphidr
[
i
][
j
]);
// bond1/bond3 coupling
if
(
fabs
(
bb13t_k
[
type
])
>
SMALL
)
{
r1_0
=
bb13t_r10
[
type
];
r3_0
=
bb13t_r30
[
type
];
dr1
=
r1
-
r1_0
;
dr2
=
r3
-
r3_0
;
tk1
=
-
bb13t_k
[
type
]
*
dr1
/
r3
;
tk2
=
-
bb13t_k
[
type
]
*
dr2
/
r1
;
if
(
eflag
)
edihedral
+=
bb13t_k
[
type
]
*
dr1
*
dr2
;
fabcd
[
0
][
0
]
+=
tk2
*
vb1x
;
fabcd
[
0
][
1
]
+=
tk2
*
vb1y
;
fabcd
[
0
][
2
]
+=
tk2
*
vb1z
;
fabcd
[
1
][
0
]
-=
tk2
*
vb1x
;
fabcd
[
1
][
1
]
-=
tk2
*
vb1y
;
fabcd
[
1
][
2
]
-=
tk2
*
vb1z
;
fabcd
[
2
][
0
]
-=
tk1
*
vb3x
;
fabcd
[
2
][
1
]
-=
tk1
*
vb3y
;
fabcd
[
2
][
2
]
-=
tk1
*
vb3z
;
fabcd
[
3
][
0
]
+=
tk1
*
vb3x
;
fabcd
[
3
][
1
]
+=
tk1
*
vb3y
;
fabcd
[
3
][
2
]
+=
tk1
*
vb3z
;
}
// apply force to each of 4 atoms
if
(
newton_bond
||
i1
<
nlocal
)
{
f
[
i1
][
0
]
+=
fabcd
[
0
][
0
];
f
[
i1
][
1
]
+=
fabcd
[
0
][
1
];
f
[
i1
][
2
]
+=
fabcd
[
0
][
2
];
}
if
(
newton_bond
||
i2
<
nlocal
)
{
f
[
i2
][
0
]
+=
fabcd
[
1
][
0
];
f
[
i2
][
1
]
+=
fabcd
[
1
][
1
];
f
[
i2
][
2
]
+=
fabcd
[
1
][
2
];
}
if
(
newton_bond
||
i3
<
nlocal
)
{
f
[
i3
][
0
]
+=
fabcd
[
2
][
0
];
f
[
i3
][
1
]
+=
fabcd
[
2
][
1
];
f
[
i3
][
2
]
+=
fabcd
[
2
][
2
];
}
if
(
newton_bond
||
i4
<
nlocal
)
{
f
[
i4
][
0
]
+=
fabcd
[
3
][
0
];
f
[
i4
][
1
]
+=
fabcd
[
3
][
1
];
f
[
i4
][
2
]
+=
fabcd
[
3
][
2
];
}
if
(
evflag
)
ev_tally
(
i1
,
i2
,
i3
,
i4
,
nlocal
,
newton_bond
,
edihedral
,
fabcd
[
0
],
fabcd
[
2
],
fabcd
[
3
],
vb1x
,
vb1y
,
vb1z
,
vb2x
,
vb2y
,
vb2z
,
vb3x
,
vb3y
,
vb3z
);
}
}
/* ---------------------------------------------------------------------- */
void
DihedralClass2
::
allocate
()
{
allocated
=
1
;
int
n
=
atom
->
ndihedraltypes
;
k1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:k1"
);
k2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:k2"
);
k3
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:k3"
);
phi1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:phi1"
);
phi2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:phi2"
);
phi3
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:phi3"
);
mbt_f1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:mbt_f1"
);
mbt_f2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:mbt_f2"
);
mbt_f3
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:mbt_f3"
);
mbt_r0
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:mbt_r0"
);
ebt_f1_1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:ebt_f1_1"
);
ebt_f2_1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:ebt_f2_1"
);
ebt_f3_1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:ebt_f3_1"
);
ebt_r0_1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:ebt_r0_1"
);
ebt_f1_2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:ebt_f1_2"
);
ebt_f2_2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:ebt_f2_2"
);
ebt_f3_2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:ebt_f3_2"
);
ebt_r0_2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:ebt_r0_2"
);
at_f1_1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:at_f1_1"
);
at_f2_1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:at_f2_1"
);
at_f3_1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:at_f3_1"
);
at_theta0_1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:at_theta0_1"
);
at_f1_2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:at_f1_2"
);
at_f2_2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:at_f2_2"
);
at_f3_2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:at_f3_2"
);
at_theta0_2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:at_theta0_2"
);
aat_k
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:aat_k"
);
aat_theta0_1
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:aat_theta0_1"
);
aat_theta0_2
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:aat_theta0_2"
);
bb13t_k
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:bb13t_k"
);
bb13t_r10
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:bb13t_r10"
);
bb13t_r30
=
(
double
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
double
),
"dihedral:bb13t_r30"
);
setflag
=
(
int
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
int
),
"dihedral:setflag"
);
setflag_d
=
(
int
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
int
),
"dihedral:setflag_d"
);
setflag_mbt
=
(
int
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
int
),
"dihedral:setflag_mbt"
);
setflag_ebt
=
(
int
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
int
),
"dihedral:setflag_ebt"
);
setflag_at
=
(
int
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
int
),
"dihedral:setflag_at"
);
setflag_aat
=
(
int
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
int
),
"dihedral:setflag_aat"
);
setflag_bb13t
=
(
int
*
)
memory
->
smalloc
((
n
+
1
)
*
sizeof
(
int
),
"dihedral:setflag_bb13t"
);
for
(
int
i
=
1
;
i
<=
n
;
i
++
)
setflag
[
i
]
=
setflag_d
[
i
]
=
setflag_mbt
[
i
]
=
setflag_ebt
[
i
]
=
setflag_at
[
i
]
=
setflag_aat
[
i
]
=
setflag_bb13t
[
i
]
=
0
;
}
/* ----------------------------------------------------------------------
set coeffs for one or more types
which = 0 -> Dihedral coeffs
which = 1 -> MiddleBondTorsion coeffs
which = 2 -> EndBondTorsion coeffs
which = 3 -> AngleTorsion coeffs
which = 4 -> AngleAngleTorsion coeffs
which = 5 -> BondBond13Torsion coeffs
------------------------------------------------------------------------- */
void
DihedralClass2
::
coeff
(
int
which
,
int
narg
,
char
**
arg
)
{
if
(
which
<
0
||
which
>
5
)
error
->
all
(
"Invalid coeffs for this dihedral style"
);
if
(
!
allocated
)
allocate
();
int
ilo
,
ihi
;
force
->
bounds
(
arg
[
0
],
atom
->
ndihedraltypes
,
ilo
,
ihi
);
int
count
=
0
;
if
(
which
==
0
)
{
if
(
narg
!=
7
)
error
->
all
(
"Incorrect args for dihedral coefficients"
);
double
k1_one
=
atof
(
arg
[
1
]);
double
phi1_one
=
atof
(
arg
[
2
]);
double
k2_one
=
atof
(
arg
[
3
]);
double
phi2_one
=
atof
(
arg
[
4
]);
double
k3_one
=
atof
(
arg
[
5
]);
double
phi3_one
=
atof
(
arg
[
6
]);
// convert phi's from degrees to radians
for
(
int
i
=
ilo
;
i
<=
ihi
;
i
++
)
{
k1
[
i
]
=
k1_one
;
phi1
[
i
]
=
phi1_one
/
180.0
*
PI
;
k2
[
i
]
=
k2_one
;
phi2
[
i
]
=
phi2_one
/
180.0
*
PI
;
k3
[
i
]
=
k3_one
;
phi3
[
i
]
=
phi3_one
/
180.0
*
PI
;
setflag_d
[
i
]
=
1
;
count
++
;
}
}
if
(
which
==
1
)
{
if
(
narg
!=
5
)
error
->
all
(
"Incorrect args for dihedral coefficients"
);
double
f1_one
=
atof
(
arg
[
1
]);
double
f2_one
=
atof
(
arg
[
2
]);
double
f3_one
=
atof
(
arg
[
3
]);
double
r0_one
=
atof
(
arg
[
4
]);
for
(
int
i
=
ilo
;
i
<=
ihi
;
i
++
)
{
mbt_f1
[
i
]
=
f1_one
;
mbt_f2
[
i
]
=
f2_one
;
mbt_f3
[
i
]
=
f3_one
;
mbt_r0
[
i
]
=
r0_one
;
setflag_mbt
[
i
]
=
1
;
count
++
;
}
}
if
(
which
==
2
)
{
if
(
narg
!=
9
)
error
->
all
(
"Incorrect args for dihedral coefficients"
);
double
f1_1_one
=
atof
(
arg
[
1
]);
double
f2_1_one
=
atof
(
arg
[
2
]);
double
f3_1_one
=
atof
(
arg
[
3
]);
double
f1_2_one
=
atof
(
arg
[
4
]);
double
f2_2_one
=
atof
(
arg
[
5
]);
double
f3_2_one
=
atof
(
arg
[
6
]);
double
r0_1_one
=
atof
(
arg
[
7
]);
double
r0_2_one
=
atof
(
arg
[
8
]);
for
(
int
i
=
ilo
;
i
<=
ihi
;
i
++
)
{
ebt_f1_1
[
i
]
=
f1_1_one
;
ebt_f2_1
[
i
]
=
f2_1_one
;
ebt_f3_1
[
i
]
=
f3_1_one
;
ebt_f1_2
[
i
]
=
f1_2_one
;
ebt_f2_2
[
i
]
=
f2_2_one
;
ebt_f3_2
[
i
]
=
f3_2_one
;
ebt_r0_1
[
i
]
=
r0_1_one
;
ebt_r0_2
[
i
]
=
r0_2_one
;
setflag_ebt
[
i
]
=
1
;
count
++
;
}
}
if
(
which
==
3
)
{
if
(
narg
!=
9
)
error
->
all
(
"Incorrect args for dihedral coefficients"
);
double
f1_1_one
=
atof
(
arg
[
1
]);
double
f2_1_one
=
atof
(
arg
[
2
]);
double
f3_1_one
=
atof
(
arg
[
3
]);
double
f1_2_one
=
atof
(
arg
[
4
]);
double
f2_2_one
=
atof
(
arg
[
5
]);
double
f3_2_one
=
atof
(
arg
[
6
]);
double
theta0_1_one
=
atof
(
arg
[
7
]);
double
theta0_2_one
=
atof
(
arg
[
8
]);
// convert theta0's from degrees to radians
for
(
int
i
=
ilo
;
i
<=
ihi
;
i
++
)
{
at_f1_1
[
i
]
=
f1_1_one
;
at_f2_1
[
i
]
=
f2_1_one
;
at_f3_1
[
i
]
=
f3_1_one
;
at_f1_2
[
i
]
=
f1_2_one
;
at_f2_2
[
i
]
=
f2_2_one
;
at_f3_2
[
i
]
=
f3_2_one
;
at_theta0_1
[
i
]
=
theta0_1_one
/
180.0
*
PI
;
at_theta0_2
[
i
]
=
theta0_2_one
/
180.0
*
PI
;
setflag_at
[
i
]
=
1
;
count
++
;
}
}
if
(
which
==
4
)
{
if
(
narg
!=
4
)
error
->
all
(
"Incorrect args for dihedral coefficients"
);
double
k_one
=
atof
(
arg
[
1
]);
double
theta0_1_one
=
atof
(
arg
[
2
]);
double
theta0_2_one
=
atof
(
arg
[
3
]);
// convert theta0's from degrees to radians
for
(
int
i
=
ilo
;
i
<=
ihi
;
i
++
)
{
aat_k
[
i
]
=
k_one
;
aat_theta0_1
[
i
]
=
theta0_1_one
/
180.0
*
PI
;
aat_theta0_2
[
i
]
=
theta0_2_one
/
180.0
*
PI
;
setflag_aat
[
i
]
=
1
;
count
++
;
}
}
if
(
which
==
5
)
{
if
(
narg
!=
4
)
error
->
all
(
"Incorrect args for dihedral coefficients"
);
double
k_one
=
atof
(
arg
[
1
]);
double
r10_one
=
atof
(
arg
[
2
]);
double
r30_one
=
atof
(
arg
[
3
]);
for
(
int
i
=
ilo
;
i
<=
ihi
;
i
++
)
{
bb13t_k
[
i
]
=
k_one
;
bb13t_r10
[
i
]
=
r10_one
;
bb13t_r30
[
i
]
=
r30_one
;
setflag_bb13t
[
i
]
=
1
;
count
++
;
}
}
if
(
count
==
0
)
error
->
all
(
"Incorrect args for dihedral coefficients"
);
for
(
int
i
=
ilo
;
i
<=
ihi
;
i
++
)
if
(
setflag_d
[
i
]
==
1
&&
setflag_mbt
[
i
]
==
1
&&
setflag_ebt
[
i
]
==
1
&&
setflag_at
[
i
]
==
1
&&
setflag_aat
[
i
]
==
1
&&
setflag_bb13t
[
i
]
==
1
)
setflag
[
i
]
=
1
;
}
/* ----------------------------------------------------------------------
proc 0 writes out coeffs to restart file
------------------------------------------------------------------------- */
void
DihedralClass2
::
write_restart
(
FILE
*
fp
)
{
fwrite
(
&
k1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
k2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
k3
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
phi1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
phi2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
phi3
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
mbt_f1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
mbt_f2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
mbt_f3
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
mbt_r0
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
ebt_f1_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
ebt_f2_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
ebt_f3_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
ebt_r0_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
ebt_f1_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
ebt_f2_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
ebt_f3_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
ebt_r0_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
at_f1_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
at_f2_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
at_f3_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
at_theta0_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
at_f1_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
at_f2_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
at_f3_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
at_theta0_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
aat_k
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
aat_theta0_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
aat_theta0_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
bb13t_k
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
bb13t_r10
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fwrite
(
&
bb13t_r30
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
}
/* ----------------------------------------------------------------------
proc 0 reads coeffs from restart file, bcasts them
------------------------------------------------------------------------- */
void
DihedralClass2
::
read_restart
(
FILE
*
fp
)
{
allocate
();
if
(
comm
->
me
==
0
)
{
fread
(
&
k1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
k2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
k3
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
phi1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
phi2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
phi3
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
mbt_f1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
mbt_f2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
mbt_f3
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
mbt_r0
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
ebt_f1_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
ebt_f2_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
ebt_f3_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
ebt_r0_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
ebt_f1_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
ebt_f2_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
ebt_f3_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
ebt_r0_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
at_f1_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
at_f2_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
at_f3_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
at_theta0_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
at_f1_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
at_f2_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
at_f3_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
at_theta0_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
aat_k
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
aat_theta0_1
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
aat_theta0_2
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
bb13t_k
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
bb13t_r10
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
fread
(
&
bb13t_r30
[
1
],
sizeof
(
double
),
atom
->
ndihedraltypes
,
fp
);
}
MPI_Bcast
(
&
k1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
k2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
k3
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
phi1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
phi2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
phi3
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
mbt_f1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
mbt_f2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
mbt_f3
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
mbt_r0
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
ebt_f1_1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
ebt_f2_1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
ebt_f3_1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
ebt_r0_1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
ebt_f1_2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
ebt_f2_2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
ebt_f3_2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
ebt_r0_2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
at_f1_1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
at_f2_1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
at_f3_1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
at_theta0_1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
at_f1_2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
at_f2_2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
at_f3_2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
at_theta0_2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
aat_k
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
aat_theta0_1
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
aat_theta0_2
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
bb13t_k
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
bb13t_r10
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
bb13t_r30
[
1
],
atom
->
ndihedraltypes
,
MPI_DOUBLE
,
0
,
world
);
for
(
int
i
=
1
;
i
<=
atom
->
ndihedraltypes
;
i
++
)
setflag
[
i
]
=
1
;
}
Event Timeline
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