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atom_vec_full_kokkos.cpp
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rLAMMPS lammps
atom_vec_full_kokkos.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.
------------------------------------------------------------------------- */
#include <stdlib.h>
#include "atom_vec_full_kokkos.h"
#include "atom_kokkos.h"
#include "comm_kokkos.h"
#include "domain.h"
#include "modify.h"
#include "fix.h"
#include "atom_masks.h"
#include "memory.h"
#include "error.h"
using
namespace
LAMMPS_NS
;
#define DELTA 10000
/* ---------------------------------------------------------------------- */
AtomVecFullKokkos
::
AtomVecFullKokkos
(
LAMMPS
*
lmp
)
:
AtomVecKokkos
(
lmp
)
{
molecular
=
1
;
bonds_allow
=
angles_allow
=
dihedrals_allow
=
impropers_allow
=
1
;
mass_type
=
1
;
comm_x_only
=
comm_f_only
=
1
;
size_forward
=
3
;
size_reverse
=
3
;
size_border
=
8
;
size_velocity
=
3
;
size_data_atom
=
7
;
size_data_vel
=
4
;
xcol_data
=
5
;
atom
->
molecule_flag
=
atom
->
q_flag
=
1
;
k_count
=
DAT
::
tdual_int_1d
(
"atom::k_count"
,
1
);
atomKK
=
(
AtomKokkos
*
)
atom
;
commKK
=
(
CommKokkos
*
)
comm
;
}
/* ----------------------------------------------------------------------
grow atom arrays
n = 0 grows arrays by DELTA
n > 0 allocates arrays to size n
------------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
grow
(
int
n
)
{
if
(
n
==
0
)
nmax
+=
DELTA
;
else
nmax
=
n
;
atomKK
->
nmax
=
nmax
;
if
(
nmax
<
0
||
nmax
>
MAXSMALLINT
)
error
->
one
(
FLERR
,
"Per-processor system is too big"
);
sync
(
Device
,
ALL_MASK
);
modified
(
Device
,
ALL_MASK
);
memory
->
grow_kokkos
(
atomKK
->
k_tag
,
atomKK
->
tag
,
nmax
,
"atom:tag"
);
memory
->
grow_kokkos
(
atomKK
->
k_type
,
atomKK
->
type
,
nmax
,
"atom:type"
);
memory
->
grow_kokkos
(
atomKK
->
k_mask
,
atomKK
->
mask
,
nmax
,
"atom:mask"
);
memory
->
grow_kokkos
(
atomKK
->
k_image
,
atomKK
->
image
,
nmax
,
"atom:image"
);
memory
->
grow_kokkos
(
atomKK
->
k_x
,
atomKK
->
x
,
nmax
,
3
,
"atom:x"
);
memory
->
grow_kokkos
(
atomKK
->
k_v
,
atomKK
->
v
,
nmax
,
3
,
"atom:v"
);
memory
->
grow_kokkos
(
atomKK
->
k_f
,
atomKK
->
f
,
nmax
,
3
,
"atom:f"
);
memory
->
grow_kokkos
(
atomKK
->
k_q
,
atomKK
->
q
,
nmax
,
"atom:q"
);
memory
->
grow_kokkos
(
atomKK
->
k_molecule
,
atomKK
->
molecule
,
nmax
,
"atom:molecule"
);
memory
->
grow_kokkos
(
atomKK
->
k_nspecial
,
atomKK
->
nspecial
,
nmax
,
3
,
"atom:nspecial"
);
memory
->
grow_kokkos
(
atomKK
->
k_special
,
atomKK
->
special
,
nmax
,
atomKK
->
maxspecial
,
"atom:special"
);
memory
->
grow_kokkos
(
atomKK
->
k_num_bond
,
atomKK
->
num_bond
,
nmax
,
"atom:num_bond"
);
memory
->
grow_kokkos
(
atomKK
->
k_bond_type
,
atomKK
->
bond_type
,
nmax
,
atomKK
->
bond_per_atom
,
"atom:bond_type"
);
memory
->
grow_kokkos
(
atomKK
->
k_bond_atom
,
atomKK
->
bond_atom
,
nmax
,
atomKK
->
bond_per_atom
,
"atom:bond_atom"
);
memory
->
grow_kokkos
(
atomKK
->
k_num_angle
,
atomKK
->
num_angle
,
nmax
,
"atom:num_angle"
);
memory
->
grow_kokkos
(
atomKK
->
k_angle_type
,
atomKK
->
angle_type
,
nmax
,
atomKK
->
angle_per_atom
,
"atom:angle_type"
);
memory
->
grow_kokkos
(
atomKK
->
k_angle_atom1
,
atomKK
->
angle_atom1
,
nmax
,
atomKK
->
angle_per_atom
,
"atom:angle_atom1"
);
memory
->
grow_kokkos
(
atomKK
->
k_angle_atom2
,
atomKK
->
angle_atom2
,
nmax
,
atomKK
->
angle_per_atom
,
"atom:angle_atom2"
);
memory
->
grow_kokkos
(
atomKK
->
k_angle_atom3
,
atomKK
->
angle_atom3
,
nmax
,
atomKK
->
angle_per_atom
,
"atom:angle_atom3"
);
memory
->
grow_kokkos
(
atomKK
->
k_num_dihedral
,
atomKK
->
num_dihedral
,
nmax
,
"atom:num_dihedral"
);
memory
->
grow_kokkos
(
atomKK
->
k_dihedral_type
,
atomKK
->
dihedral_type
,
nmax
,
atomKK
->
dihedral_per_atom
,
"atom:dihedral_type"
);
memory
->
grow_kokkos
(
atomKK
->
k_dihedral_atom1
,
atomKK
->
dihedral_atom1
,
nmax
,
atomKK
->
dihedral_per_atom
,
"atom:dihedral_atom1"
);
memory
->
grow_kokkos
(
atomKK
->
k_dihedral_atom2
,
atomKK
->
dihedral_atom2
,
nmax
,
atomKK
->
dihedral_per_atom
,
"atom:dihedral_atom2"
);
memory
->
grow_kokkos
(
atomKK
->
k_dihedral_atom3
,
atomKK
->
dihedral_atom3
,
nmax
,
atomKK
->
dihedral_per_atom
,
"atom:dihedral_atom3"
);
memory
->
grow_kokkos
(
atomKK
->
k_dihedral_atom4
,
atomKK
->
dihedral_atom4
,
nmax
,
atomKK
->
dihedral_per_atom
,
"atom:dihedral_atom4"
);
memory
->
grow_kokkos
(
atomKK
->
k_num_improper
,
atomKK
->
num_improper
,
nmax
,
"atom:num_improper"
);
memory
->
grow_kokkos
(
atomKK
->
k_improper_type
,
atomKK
->
improper_type
,
nmax
,
atomKK
->
improper_per_atom
,
"atom:improper_type"
);
memory
->
grow_kokkos
(
atomKK
->
k_improper_atom1
,
atomKK
->
improper_atom1
,
nmax
,
atomKK
->
improper_per_atom
,
"atom:improper_atom1"
);
memory
->
grow_kokkos
(
atomKK
->
k_improper_atom2
,
atomKK
->
improper_atom2
,
nmax
,
atomKK
->
improper_per_atom
,
"atom:improper_atom2"
);
memory
->
grow_kokkos
(
atomKK
->
k_improper_atom3
,
atomKK
->
improper_atom3
,
nmax
,
atomKK
->
improper_per_atom
,
"atom:improper_atom3"
);
memory
->
grow_kokkos
(
atomKK
->
k_improper_atom4
,
atomKK
->
improper_atom4
,
nmax
,
atomKK
->
improper_per_atom
,
"atom:improper_atom4"
);
grow_reset
();
sync
(
Host
,
ALL_MASK
);
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
AtomVecFullKokkos
::
grow_reset
()
{
tag
=
atomKK
->
tag
;
d_tag
=
atomKK
->
k_tag
.
d_view
;
h_tag
=
atomKK
->
k_tag
.
h_view
;
type
=
atomKK
->
type
;
d_type
=
atomKK
->
k_type
.
d_view
;
h_type
=
atomKK
->
k_type
.
h_view
;
mask
=
atomKK
->
mask
;
d_mask
=
atomKK
->
k_mask
.
d_view
;
h_mask
=
atomKK
->
k_mask
.
h_view
;
image
=
atomKK
->
image
;
d_image
=
atomKK
->
k_image
.
d_view
;
h_image
=
atomKK
->
k_image
.
h_view
;
x
=
atomKK
->
x
;
d_x
=
atomKK
->
k_x
.
d_view
;
h_x
=
atomKK
->
k_x
.
h_view
;
v
=
atomKK
->
v
;
d_v
=
atomKK
->
k_v
.
d_view
;
h_v
=
atomKK
->
k_v
.
h_view
;
f
=
atomKK
->
f
;
d_f
=
atomKK
->
k_f
.
d_view
;
h_f
=
atomKK
->
k_f
.
h_view
;
q
=
atomKK
->
q
;
d_q
=
atomKK
->
k_q
.
d_view
;
h_q
=
atomKK
->
k_q
.
h_view
;
molecule
=
atomKK
->
molecule
;
d_molecule
=
atomKK
->
k_molecule
.
d_view
;
h_molecule
=
atomKK
->
k_molecule
.
h_view
;
nspecial
=
atomKK
->
nspecial
;
d_nspecial
=
atomKK
->
k_nspecial
.
d_view
;
h_nspecial
=
atomKK
->
k_nspecial
.
h_view
;
special
=
atomKK
->
special
;
d_special
=
atomKK
->
k_special
.
d_view
;
h_special
=
atomKK
->
k_special
.
h_view
;
num_bond
=
atomKK
->
num_bond
;
d_num_bond
=
atomKK
->
k_num_bond
.
d_view
;
h_num_bond
=
atomKK
->
k_num_bond
.
h_view
;
bond_type
=
atomKK
->
bond_type
;
d_bond_type
=
atomKK
->
k_bond_type
.
d_view
;
h_bond_type
=
atomKK
->
k_bond_type
.
h_view
;
bond_atom
=
atomKK
->
bond_atom
;
d_bond_atom
=
atomKK
->
k_bond_atom
.
d_view
;
h_bond_atom
=
atomKK
->
k_bond_atom
.
h_view
;
num_angle
=
atomKK
->
num_angle
;
d_num_angle
=
atomKK
->
k_num_angle
.
d_view
;
h_num_angle
=
atomKK
->
k_num_angle
.
h_view
;
angle_type
=
atomKK
->
angle_type
;
d_angle_type
=
atomKK
->
k_angle_type
.
d_view
;
h_angle_type
=
atomKK
->
k_angle_type
.
h_view
;
angle_atom1
=
atomKK
->
angle_atom1
;
d_angle_atom1
=
atomKK
->
k_angle_atom1
.
d_view
;
h_angle_atom1
=
atomKK
->
k_angle_atom1
.
h_view
;
angle_atom2
=
atomKK
->
angle_atom2
;
d_angle_atom2
=
atomKK
->
k_angle_atom2
.
d_view
;
h_angle_atom2
=
atomKK
->
k_angle_atom2
.
h_view
;
angle_atom3
=
atomKK
->
angle_atom3
;
d_angle_atom3
=
atomKK
->
k_angle_atom3
.
d_view
;
h_angle_atom3
=
atomKK
->
k_angle_atom3
.
h_view
;
num_dihedral
=
atomKK
->
num_dihedral
;
d_num_dihedral
=
atomKK
->
k_num_dihedral
.
d_view
;
h_num_dihedral
=
atomKK
->
k_num_dihedral
.
h_view
;
dihedral_type
=
atomKK
->
dihedral_type
;
d_dihedral_type
=
atomKK
->
k_dihedral_type
.
d_view
;
h_dihedral_type
=
atomKK
->
k_dihedral_type
.
h_view
;
dihedral_atom1
=
atomKK
->
dihedral_atom1
;
d_dihedral_atom1
=
atomKK
->
k_dihedral_atom1
.
d_view
;
h_dihedral_atom1
=
atomKK
->
k_dihedral_atom1
.
h_view
;
dihedral_atom2
=
atomKK
->
dihedral_atom2
;
d_dihedral_atom2
=
atomKK
->
k_dihedral_atom2
.
d_view
;
h_dihedral_atom2
=
atomKK
->
k_dihedral_atom2
.
h_view
;
dihedral_atom3
=
atomKK
->
dihedral_atom3
;
d_dihedral_atom3
=
atomKK
->
k_dihedral_atom3
.
d_view
;
h_dihedral_atom3
=
atomKK
->
k_dihedral_atom3
.
h_view
;
dihedral_atom4
=
atomKK
->
dihedral_atom4
;
d_dihedral_atom4
=
atomKK
->
k_dihedral_atom4
.
d_view
;
h_dihedral_atom4
=
atomKK
->
k_dihedral_atom4
.
h_view
;
num_improper
=
atomKK
->
num_improper
;
d_num_improper
=
atomKK
->
k_num_improper
.
d_view
;
h_num_improper
=
atomKK
->
k_num_improper
.
h_view
;
improper_type
=
atomKK
->
improper_type
;
d_improper_type
=
atomKK
->
k_improper_type
.
d_view
;
h_improper_type
=
atomKK
->
k_improper_type
.
h_view
;
improper_atom1
=
atomKK
->
improper_atom1
;
d_improper_atom1
=
atomKK
->
k_improper_atom1
.
d_view
;
h_improper_atom1
=
atomKK
->
k_improper_atom1
.
h_view
;
improper_atom2
=
atomKK
->
improper_atom2
;
d_improper_atom2
=
atomKK
->
k_improper_atom2
.
d_view
;
h_improper_atom2
=
atomKK
->
k_improper_atom2
.
h_view
;
improper_atom3
=
atomKK
->
improper_atom3
;
d_improper_atom3
=
atomKK
->
k_improper_atom3
.
d_view
;
h_improper_atom3
=
atomKK
->
k_improper_atom3
.
h_view
;
improper_atom4
=
atomKK
->
improper_atom4
;
d_improper_atom4
=
atomKK
->
k_improper_atom4
.
d_view
;
h_improper_atom4
=
atomKK
->
k_improper_atom4
.
h_view
;
}
/* ----------------------------------------------------------------------
copy atom I info to atom J
------------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
copy
(
int
i
,
int
j
,
int
delflag
)
{
int
k
;
h_tag
[
j
]
=
h_tag
[
i
];
h_type
[
j
]
=
h_type
[
i
];
mask
[
j
]
=
mask
[
i
];
h_image
[
j
]
=
h_image
[
i
];
h_x
(
j
,
0
)
=
h_x
(
i
,
0
);
h_x
(
j
,
1
)
=
h_x
(
i
,
1
);
h_x
(
j
,
2
)
=
h_x
(
i
,
2
);
h_v
(
j
,
0
)
=
h_v
(
i
,
0
);
h_v
(
j
,
1
)
=
h_v
(
i
,
1
);
h_v
(
j
,
2
)
=
h_v
(
i
,
2
);
h_q
[
j
]
=
h_q
[
i
];
h_molecule
(
j
)
=
h_molecule
(
i
);
h_num_bond
(
j
)
=
h_num_bond
(
i
);
for
(
k
=
0
;
k
<
h_num_bond
(
j
);
k
++
)
{
h_bond_type
(
j
,
k
)
=
h_bond_type
(
i
,
k
);
h_bond_atom
(
j
,
k
)
=
h_bond_atom
(
i
,
k
);
}
h_nspecial
(
j
,
0
)
=
h_nspecial
(
i
,
0
);
h_nspecial
(
j
,
1
)
=
h_nspecial
(
i
,
1
);
h_nspecial
(
j
,
2
)
=
h_nspecial
(
i
,
2
);
for
(
k
=
0
;
k
<
h_nspecial
(
j
,
2
);
k
++
)
h_special
(
j
,
k
)
=
h_special
(
i
,
k
);
h_num_angle
(
j
)
=
h_num_angle
(
i
);
for
(
k
=
0
;
k
<
h_num_angle
(
j
);
k
++
)
{
h_angle_type
(
j
,
k
)
=
h_angle_type
(
i
,
k
);
h_angle_atom1
(
j
,
k
)
=
h_angle_atom1
(
i
,
k
);
h_angle_atom2
(
j
,
k
)
=
h_angle_atom2
(
i
,
k
);
h_angle_atom3
(
j
,
k
)
=
h_angle_atom3
(
i
,
k
);
}
h_num_dihedral
(
j
)
=
h_num_dihedral
(
i
);
for
(
k
=
0
;
k
<
h_num_dihedral
(
j
);
k
++
)
{
h_dihedral_type
(
j
,
k
)
=
h_dihedral_type
(
i
,
k
);
h_dihedral_atom1
(
j
,
k
)
=
h_dihedral_atom1
(
i
,
k
);
h_dihedral_atom2
(
j
,
k
)
=
h_dihedral_atom2
(
i
,
k
);
h_dihedral_atom3
(
j
,
k
)
=
h_dihedral_atom3
(
i
,
k
);
h_dihedral_atom4
(
j
,
k
)
=
h_dihedral_atom4
(
i
,
k
);
}
h_num_improper
(
j
)
=
h_num_improper
(
i
);
for
(
k
=
0
;
k
<
h_num_improper
(
j
);
k
++
)
{
h_improper_type
(
j
,
k
)
=
h_improper_type
(
i
,
k
);
h_improper_atom1
(
j
,
k
)
=
h_improper_atom1
(
i
,
k
);
h_improper_atom2
(
j
,
k
)
=
h_improper_atom2
(
i
,
k
);
h_improper_atom3
(
j
,
k
)
=
h_improper_atom3
(
i
,
k
);
h_improper_atom4
(
j
,
k
)
=
h_improper_atom4
(
i
,
k
);
}
if
(
atom
->
nextra_grow
)
for
(
int
iextra
=
0
;
iextra
<
atom
->
nextra_grow
;
iextra
++
)
modify
->
fix
[
atom
->
extra_grow
[
iextra
]]
->
copy_arrays
(
i
,
j
,
delflag
);
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
,
int
PBC_FLAG
,
int
TRICLINIC
>
struct
AtomVecFullKokkos_PackComm
{
typedef
DeviceType
device_type
;
typename
ArrayTypes
<
DeviceType
>::
t_x_array_randomread
_x
;
typename
ArrayTypes
<
DeviceType
>::
t_xfloat_2d_um
_buf
;
typename
ArrayTypes
<
DeviceType
>::
t_int_2d_const
_list
;
const
int
_iswap
;
X_FLOAT
_xprd
,
_yprd
,
_zprd
,
_xy
,
_xz
,
_yz
;
X_FLOAT
_pbc
[
6
];
AtomVecFullKokkos_PackComm
(
const
typename
DAT
::
tdual_x_array
&
x
,
const
typename
DAT
::
tdual_xfloat_2d
&
buf
,
const
typename
DAT
::
tdual_int_2d
&
list
,
const
int
&
iswap
,
const
X_FLOAT
&
xprd
,
const
X_FLOAT
&
yprd
,
const
X_FLOAT
&
zprd
,
const
X_FLOAT
&
xy
,
const
X_FLOAT
&
xz
,
const
X_FLOAT
&
yz
,
const
int
*
const
pbc
)
:
_x
(
x
.
view
<
DeviceType
>
()),
_list
(
list
.
view
<
DeviceType
>
()),
_iswap
(
iswap
),
_xprd
(
xprd
),
_yprd
(
yprd
),
_zprd
(
zprd
),
_xy
(
xy
),
_xz
(
xz
),
_yz
(
yz
)
{
const
size_t
maxsend
=
(
buf
.
view
<
DeviceType
>
().
dimension_0
()
*
buf
.
view
<
DeviceType
>
().
dimension_1
())
/
3
;
const
size_t
elements
=
3
;
buffer_view
<
DeviceType
>
(
_buf
,
buf
,
maxsend
,
elements
);
_pbc
[
0
]
=
pbc
[
0
];
_pbc
[
1
]
=
pbc
[
1
];
_pbc
[
2
]
=
pbc
[
2
];
_pbc
[
3
]
=
pbc
[
3
];
_pbc
[
4
]
=
pbc
[
4
];
_pbc
[
5
]
=
pbc
[
5
];
};
KOKKOS_INLINE_FUNCTION
void
operator
()
(
const
int
&
i
)
const
{
const
int
j
=
_list
(
_iswap
,
i
);
if
(
PBC_FLAG
==
0
)
{
_buf
(
i
,
0
)
=
_x
(
j
,
0
);
_buf
(
i
,
1
)
=
_x
(
j
,
1
);
_buf
(
i
,
2
)
=
_x
(
j
,
2
);
}
else
{
if
(
TRICLINIC
==
0
)
{
_buf
(
i
,
0
)
=
_x
(
j
,
0
)
+
_pbc
[
0
]
*
_xprd
;
_buf
(
i
,
1
)
=
_x
(
j
,
1
)
+
_pbc
[
1
]
*
_yprd
;
_buf
(
i
,
2
)
=
_x
(
j
,
2
)
+
_pbc
[
2
]
*
_zprd
;
}
else
{
_buf
(
i
,
0
)
=
_x
(
j
,
0
)
+
_pbc
[
0
]
*
_xprd
+
_pbc
[
5
]
*
_xy
+
_pbc
[
4
]
*
_xz
;
_buf
(
i
,
1
)
=
_x
(
j
,
1
)
+
_pbc
[
1
]
*
_yprd
+
_pbc
[
3
]
*
_yz
;
_buf
(
i
,
2
)
=
_x
(
j
,
2
)
+
_pbc
[
2
]
*
_zprd
;
}
}
}
};
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
pack_comm_kokkos
(
const
int
&
n
,
const
DAT
::
tdual_int_2d
&
list
,
const
int
&
iswap
,
const
DAT
::
tdual_xfloat_2d
&
buf
,
const
int
&
pbc_flag
,
const
int
*
const
pbc
)
{
// Check whether to always run forward communication on the host
// Choose correct forward PackComm kernel
if
(
commKK
->
forward_comm_on_host
)
{
sync
(
Host
,
X_MASK
);
if
(
pbc_flag
)
{
if
(
domain
->
triclinic
)
{
struct
AtomVecFullKokkos_PackComm
<
LMPHostType
,
1
,
1
>
f
(
atomKK
->
k_x
,
buf
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
else
{
struct
AtomVecFullKokkos_PackComm
<
LMPHostType
,
1
,
0
>
f
(
atomKK
->
k_x
,
buf
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
}
else
{
if
(
domain
->
triclinic
)
{
struct
AtomVecFullKokkos_PackComm
<
LMPHostType
,
0
,
1
>
f
(
atomKK
->
k_x
,
buf
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
else
{
struct
AtomVecFullKokkos_PackComm
<
LMPHostType
,
0
,
0
>
f
(
atomKK
->
k_x
,
buf
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
}
LMPHostType
::
fence
();
}
else
{
sync
(
Device
,
X_MASK
);
if
(
pbc_flag
)
{
if
(
domain
->
triclinic
)
{
struct
AtomVecFullKokkos_PackComm
<
LMPDeviceType
,
1
,
1
>
f
(
atomKK
->
k_x
,
buf
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
else
{
struct
AtomVecFullKokkos_PackComm
<
LMPDeviceType
,
1
,
0
>
f
(
atomKK
->
k_x
,
buf
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
}
else
{
if
(
domain
->
triclinic
)
{
struct
AtomVecFullKokkos_PackComm
<
LMPDeviceType
,
0
,
1
>
f
(
atomKK
->
k_x
,
buf
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
else
{
struct
AtomVecFullKokkos_PackComm
<
LMPDeviceType
,
0
,
0
>
f
(
atomKK
->
k_x
,
buf
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
}
LMPDeviceType
::
fence
();
}
return
n
*
size_forward
;
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
,
int
PBC_FLAG
,
int
TRICLINIC
>
struct
AtomVecFullKokkos_PackCommSelf
{
typedef
DeviceType
device_type
;
typename
ArrayTypes
<
DeviceType
>::
t_x_array_randomread
_x
;
typename
ArrayTypes
<
DeviceType
>::
t_x_array
_xw
;
int
_nfirst
;
typename
ArrayTypes
<
DeviceType
>::
t_int_2d_const
_list
;
const
int
_iswap
;
X_FLOAT
_xprd
,
_yprd
,
_zprd
,
_xy
,
_xz
,
_yz
;
X_FLOAT
_pbc
[
6
];
AtomVecFullKokkos_PackCommSelf
(
const
typename
DAT
::
tdual_x_array
&
x
,
const
int
&
nfirst
,
const
typename
DAT
::
tdual_int_2d
&
list
,
const
int
&
iswap
,
const
X_FLOAT
&
xprd
,
const
X_FLOAT
&
yprd
,
const
X_FLOAT
&
zprd
,
const
X_FLOAT
&
xy
,
const
X_FLOAT
&
xz
,
const
X_FLOAT
&
yz
,
const
int
*
const
pbc
)
:
_x
(
x
.
view
<
DeviceType
>
()),
_xw
(
x
.
view
<
DeviceType
>
()),
_nfirst
(
nfirst
),
_list
(
list
.
view
<
DeviceType
>
()),
_iswap
(
iswap
),
_xprd
(
xprd
),
_yprd
(
yprd
),
_zprd
(
zprd
),
_xy
(
xy
),
_xz
(
xz
),
_yz
(
yz
)
{
_pbc
[
0
]
=
pbc
[
0
];
_pbc
[
1
]
=
pbc
[
1
];
_pbc
[
2
]
=
pbc
[
2
];
_pbc
[
3
]
=
pbc
[
3
];
_pbc
[
4
]
=
pbc
[
4
];
_pbc
[
5
]
=
pbc
[
5
];
};
KOKKOS_INLINE_FUNCTION
void
operator
()
(
const
int
&
i
)
const
{
const
int
j
=
_list
(
_iswap
,
i
);
if
(
PBC_FLAG
==
0
)
{
_xw
(
i
+
_nfirst
,
0
)
=
_x
(
j
,
0
);
_xw
(
i
+
_nfirst
,
1
)
=
_x
(
j
,
1
);
_xw
(
i
+
_nfirst
,
2
)
=
_x
(
j
,
2
);
}
else
{
if
(
TRICLINIC
==
0
)
{
_xw
(
i
+
_nfirst
,
0
)
=
_x
(
j
,
0
)
+
_pbc
[
0
]
*
_xprd
;
_xw
(
i
+
_nfirst
,
1
)
=
_x
(
j
,
1
)
+
_pbc
[
1
]
*
_yprd
;
_xw
(
i
+
_nfirst
,
2
)
=
_x
(
j
,
2
)
+
_pbc
[
2
]
*
_zprd
;
}
else
{
_xw
(
i
+
_nfirst
,
0
)
=
_x
(
j
,
0
)
+
_pbc
[
0
]
*
_xprd
+
_pbc
[
5
]
*
_xy
+
_pbc
[
4
]
*
_xz
;
_xw
(
i
+
_nfirst
,
1
)
=
_x
(
j
,
1
)
+
_pbc
[
1
]
*
_yprd
+
_pbc
[
3
]
*
_yz
;
_xw
(
i
+
_nfirst
,
2
)
=
_x
(
j
,
2
)
+
_pbc
[
2
]
*
_zprd
;
}
}
}
};
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
pack_comm_self
(
const
int
&
n
,
const
DAT
::
tdual_int_2d
&
list
,
const
int
&
iswap
,
const
int
nfirst
,
const
int
&
pbc_flag
,
const
int
*
const
pbc
)
{
if
(
commKK
->
forward_comm_on_host
)
{
sync
(
Host
,
X_MASK
);
modified
(
Host
,
X_MASK
);
if
(
pbc_flag
)
{
if
(
domain
->
triclinic
)
{
struct
AtomVecFullKokkos_PackCommSelf
<
LMPHostType
,
1
,
1
>
f
(
atomKK
->
k_x
,
nfirst
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
else
{
struct
AtomVecFullKokkos_PackCommSelf
<
LMPHostType
,
1
,
0
>
f
(
atomKK
->
k_x
,
nfirst
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
}
else
{
if
(
domain
->
triclinic
)
{
struct
AtomVecFullKokkos_PackCommSelf
<
LMPHostType
,
0
,
1
>
f
(
atomKK
->
k_x
,
nfirst
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
else
{
struct
AtomVecFullKokkos_PackCommSelf
<
LMPHostType
,
0
,
0
>
f
(
atomKK
->
k_x
,
nfirst
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
}
LMPHostType
::
fence
();
}
else
{
sync
(
Device
,
X_MASK
);
modified
(
Device
,
X_MASK
);
if
(
pbc_flag
)
{
if
(
domain
->
triclinic
)
{
struct
AtomVecFullKokkos_PackCommSelf
<
LMPDeviceType
,
1
,
1
>
f
(
atomKK
->
k_x
,
nfirst
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
else
{
struct
AtomVecFullKokkos_PackCommSelf
<
LMPDeviceType
,
1
,
0
>
f
(
atomKK
->
k_x
,
nfirst
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
}
else
{
if
(
domain
->
triclinic
)
{
struct
AtomVecFullKokkos_PackCommSelf
<
LMPDeviceType
,
0
,
1
>
f
(
atomKK
->
k_x
,
nfirst
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
else
{
struct
AtomVecFullKokkos_PackCommSelf
<
LMPDeviceType
,
0
,
0
>
f
(
atomKK
->
k_x
,
nfirst
,
list
,
iswap
,
domain
->
xprd
,
domain
->
yprd
,
domain
->
zprd
,
domain
->
xy
,
domain
->
xz
,
domain
->
yz
,
pbc
);
Kokkos
::
parallel_for
(
n
,
f
);
}
}
LMPDeviceType
::
fence
();
}
return
n
*
3
;
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
struct
AtomVecFullKokkos_UnpackComm
{
typedef
DeviceType
device_type
;
typename
ArrayTypes
<
DeviceType
>::
t_x_array
_x
;
typename
ArrayTypes
<
DeviceType
>::
t_xfloat_2d_const
_buf
;
int
_first
;
AtomVecFullKokkos_UnpackComm
(
const
typename
DAT
::
tdual_x_array
&
x
,
const
typename
DAT
::
tdual_xfloat_2d
&
buf
,
const
int
&
first
)
:
_x
(
x
.
view
<
DeviceType
>
()),
_buf
(
buf
.
view
<
DeviceType
>
()),
_first
(
first
)
{};
KOKKOS_INLINE_FUNCTION
void
operator
()
(
const
int
&
i
)
const
{
_x
(
i
+
_first
,
0
)
=
_buf
(
i
,
0
);
_x
(
i
+
_first
,
1
)
=
_buf
(
i
,
1
);
_x
(
i
+
_first
,
2
)
=
_buf
(
i
,
2
);
}
};
/* ---------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
unpack_comm_kokkos
(
const
int
&
n
,
const
int
&
first
,
const
DAT
::
tdual_xfloat_2d
&
buf
)
{
if
(
commKK
->
forward_comm_on_host
)
{
sync
(
Host
,
X_MASK
);
modified
(
Host
,
X_MASK
);
struct
AtomVecFullKokkos_UnpackComm
<
LMPHostType
>
f
(
atomKK
->
k_x
,
buf
,
first
);
Kokkos
::
parallel_for
(
n
,
f
);
LMPDeviceType
::
fence
();
}
else
{
sync
(
Device
,
X_MASK
);
modified
(
Device
,
X_MASK
);
struct
AtomVecFullKokkos_UnpackComm
<
LMPDeviceType
>
f
(
atomKK
->
k_x
,
buf
,
first
);
Kokkos
::
parallel_for
(
n
,
f
);
LMPDeviceType
::
fence
();
}
}
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
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
++
]
=
h_x
(
j
,
0
);
buf
[
m
++
]
=
h_x
(
j
,
1
);
buf
[
m
++
]
=
h_x
(
j
,
2
);
}
}
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
++
]
=
h_x
(
j
,
0
)
+
dx
;
buf
[
m
++
]
=
h_x
(
j
,
1
)
+
dy
;
buf
[
m
++
]
=
h_x
(
j
,
2
)
+
dz
;
}
}
return
m
;
}
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
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
++
]
=
h_x
(
j
,
0
);
buf
[
m
++
]
=
h_x
(
j
,
1
);
buf
[
m
++
]
=
h_x
(
j
,
2
);
buf
[
m
++
]
=
h_v
(
j
,
0
);
buf
[
m
++
]
=
h_v
(
j
,
1
);
buf
[
m
++
]
=
h_v
(
j
,
2
);
}
}
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
++
]
=
h_x
(
j
,
0
)
+
dx
;
buf
[
m
++
]
=
h_x
(
j
,
1
)
+
dy
;
buf
[
m
++
]
=
h_x
(
j
,
2
)
+
dz
;
buf
[
m
++
]
=
h_v
(
j
,
0
);
buf
[
m
++
]
=
h_v
(
j
,
1
);
buf
[
m
++
]
=
h_v
(
j
,
2
);
}
}
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
++
]
=
h_x
(
j
,
0
)
+
dx
;
buf
[
m
++
]
=
h_x
(
j
,
1
)
+
dy
;
buf
[
m
++
]
=
h_x
(
j
,
2
)
+
dz
;
if
(
mask
[
i
]
&
deform_groupbit
)
{
buf
[
m
++
]
=
h_v
(
j
,
0
)
+
dvx
;
buf
[
m
++
]
=
h_v
(
j
,
1
)
+
dvy
;
buf
[
m
++
]
=
h_v
(
j
,
2
)
+
dvz
;
}
else
{
buf
[
m
++
]
=
h_v
(
j
,
0
);
buf
[
m
++
]
=
h_v
(
j
,
1
);
buf
[
m
++
]
=
h_v
(
j
,
2
);
}
}
}
}
return
m
;
}
/* ---------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
unpack_comm
(
int
n
,
int
first
,
double
*
buf
)
{
int
i
,
m
,
last
;
m
=
0
;
last
=
first
+
n
;
for
(
i
=
first
;
i
<
last
;
i
++
)
{
h_x
(
i
,
0
)
=
buf
[
m
++
];
h_x
(
i
,
1
)
=
buf
[
m
++
];
h_x
(
i
,
2
)
=
buf
[
m
++
];
}
}
/* ---------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
unpack_comm_vel
(
int
n
,
int
first
,
double
*
buf
)
{
int
i
,
m
,
last
;
m
=
0
;
last
=
first
+
n
;
for
(
i
=
first
;
i
<
last
;
i
++
)
{
h_x
(
i
,
0
)
=
buf
[
m
++
];
h_x
(
i
,
1
)
=
buf
[
m
++
];
h_x
(
i
,
2
)
=
buf
[
m
++
];
h_v
(
i
,
0
)
=
buf
[
m
++
];
h_v
(
i
,
1
)
=
buf
[
m
++
];
h_v
(
i
,
2
)
=
buf
[
m
++
];
}
}
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
pack_reverse
(
int
n
,
int
first
,
double
*
buf
)
{
if
(
n
>
0
)
sync
(
Host
,
F_MASK
);
int
m
=
0
;
const
int
last
=
first
+
n
;
for
(
int
i
=
first
;
i
<
last
;
i
++
)
{
buf
[
m
++
]
=
h_f
(
i
,
0
);
buf
[
m
++
]
=
h_f
(
i
,
1
);
buf
[
m
++
]
=
h_f
(
i
,
2
);
}
return
m
;
}
/* ---------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
unpack_reverse
(
int
n
,
int
*
list
,
double
*
buf
)
{
if
(
n
>
0
)
modified
(
Host
,
F_MASK
);
int
m
=
0
;
for
(
int
i
=
0
;
i
<
n
;
i
++
)
{
const
int
j
=
list
[
i
];
h_f
(
j
,
0
)
+=
buf
[
m
++
];
h_f
(
j
,
1
)
+=
buf
[
m
++
];
h_f
(
j
,
2
)
+=
buf
[
m
++
];
}
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
,
int
PBC_FLAG
>
struct
AtomVecFullKokkos_PackBorder
{
union
ubuf
{
double
d
;
int64_t
i
;
KOKKOS_INLINE_FUNCTION
ubuf
(
double
arg
)
:
d
(
arg
)
{}
KOKKOS_INLINE_FUNCTION
ubuf
(
int64_t
arg
)
:
i
(
arg
)
{}
KOKKOS_INLINE_FUNCTION
ubuf
(
int
arg
)
:
i
(
arg
)
{}
};
typedef
DeviceType
device_type
;
typedef
ArrayTypes
<
DeviceType
>
AT
;
typename
AT
::
t_xfloat_2d
_buf
;
const
typename
AT
::
t_int_2d_const
_list
;
const
int
_iswap
;
const
typename
AT
::
t_x_array_randomread
_x
;
const
typename
AT
::
t_tagint_1d
_tag
;
const
typename
AT
::
t_int_1d
_type
;
const
typename
AT
::
t_int_1d
_mask
;
const
typename
AT
::
t_float_1d
_q
;
const
typename
AT
::
t_tagint_1d
_molecule
;
X_FLOAT
_dx
,
_dy
,
_dz
;
AtomVecFullKokkos_PackBorder
(
const
typename
AT
::
t_xfloat_2d
&
buf
,
const
typename
AT
::
t_int_2d_const
&
list
,
const
int
&
iswap
,
const
typename
AT
::
t_x_array
&
x
,
const
typename
AT
::
t_tagint_1d
&
tag
,
const
typename
AT
::
t_int_1d
&
type
,
const
typename
AT
::
t_int_1d
&
mask
,
const
typename
AT
::
t_float_1d
&
q
,
const
typename
AT
::
t_tagint_1d
&
molecule
,
const
X_FLOAT
&
dx
,
const
X_FLOAT
&
dy
,
const
X_FLOAT
&
dz
)
:
_buf
(
buf
),
_list
(
list
),
_iswap
(
iswap
),
_x
(
x
),
_tag
(
tag
),
_type
(
type
),
_mask
(
mask
),
_q
(
q
),
_molecule
(
molecule
),
_dx
(
dx
),
_dy
(
dy
),
_dz
(
dz
)
{}
KOKKOS_INLINE_FUNCTION
void
operator
()
(
const
int
&
i
)
const
{
const
int
j
=
_list
(
_iswap
,
i
);
if
(
PBC_FLAG
==
0
)
{
_buf
(
i
,
0
)
=
_x
(
j
,
0
);
_buf
(
i
,
1
)
=
_x
(
j
,
1
);
_buf
(
i
,
2
)
=
_x
(
j
,
2
);
_buf
(
i
,
3
)
=
ubuf
(
_tag
(
j
)).
d
;
_buf
(
i
,
4
)
=
ubuf
(
_type
(
j
)).
d
;
_buf
(
i
,
5
)
=
ubuf
(
_mask
(
j
)).
d
;
_buf
(
i
,
6
)
=
_q
(
j
);
_buf
(
i
,
7
)
=
ubuf
(
_molecule
(
j
)).
d
;
}
else
{
_buf
(
i
,
0
)
=
_x
(
j
,
0
)
+
_dx
;
_buf
(
i
,
1
)
=
_x
(
j
,
1
)
+
_dy
;
_buf
(
i
,
2
)
=
_x
(
j
,
2
)
+
_dz
;
_buf
(
i
,
3
)
=
ubuf
(
_tag
(
j
)).
d
;
_buf
(
i
,
4
)
=
ubuf
(
_type
(
j
)).
d
;
_buf
(
i
,
5
)
=
ubuf
(
_mask
(
j
)).
d
;
_buf
(
i
,
6
)
=
_q
(
j
);
_buf
(
i
,
7
)
=
ubuf
(
_molecule
(
j
)).
d
;
}
}
};
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
pack_border_kokkos
(
int
n
,
DAT
::
tdual_int_2d
k_sendlist
,
DAT
::
tdual_xfloat_2d
buf
,
int
iswap
,
int
pbc_flag
,
int
*
pbc
,
ExecutionSpace
space
)
{
X_FLOAT
dx
,
dy
,
dz
;
if
(
pbc_flag
!=
0
)
{
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
(
space
==
Host
)
{
AtomVecFullKokkos_PackBorder
<
LMPHostType
,
1
>
f
(
buf
.
view
<
LMPHostType
>
(),
k_sendlist
.
view
<
LMPHostType
>
(),
iswap
,
h_x
,
h_tag
,
h_type
,
h_mask
,
h_q
,
h_molecule
,
dx
,
dy
,
dz
);
Kokkos
::
parallel_for
(
n
,
f
);
LMPHostType
::
fence
();
}
else
{
AtomVecFullKokkos_PackBorder
<
LMPDeviceType
,
1
>
f
(
buf
.
view
<
LMPDeviceType
>
(),
k_sendlist
.
view
<
LMPDeviceType
>
(),
iswap
,
d_x
,
d_tag
,
d_type
,
d_mask
,
d_q
,
d_molecule
,
dx
,
dy
,
dz
);
Kokkos
::
parallel_for
(
n
,
f
);
LMPDeviceType
::
fence
();
}
}
else
{
dx
=
dy
=
dz
=
0
;
if
(
space
==
Host
)
{
AtomVecFullKokkos_PackBorder
<
LMPHostType
,
0
>
f
(
buf
.
view
<
LMPHostType
>
(),
k_sendlist
.
view
<
LMPHostType
>
(),
iswap
,
h_x
,
h_tag
,
h_type
,
h_mask
,
h_q
,
h_molecule
,
dx
,
dy
,
dz
);
Kokkos
::
parallel_for
(
n
,
f
);
LMPHostType
::
fence
();
}
else
{
AtomVecFullKokkos_PackBorder
<
LMPDeviceType
,
0
>
f
(
buf
.
view
<
LMPDeviceType
>
(),
k_sendlist
.
view
<
LMPDeviceType
>
(),
iswap
,
d_x
,
d_tag
,
d_type
,
d_mask
,
d_q
,
d_molecule
,
dx
,
dy
,
dz
);
Kokkos
::
parallel_for
(
n
,
f
);
LMPDeviceType
::
fence
();
}
}
return
n
*
size_border
;
}
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
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
++
]
=
h_x
(
j
,
0
);
buf
[
m
++
]
=
h_x
(
j
,
1
);
buf
[
m
++
]
=
h_x
(
j
,
2
);
buf
[
m
++
]
=
ubuf
(
h_tag
(
j
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_type
(
j
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_mask
(
j
)).
d
;
buf
[
m
++
]
=
h_q
(
j
);
buf
[
m
++
]
=
ubuf
(
h_molecule
(
j
)).
d
;
}
}
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
++
]
=
h_x
(
j
,
0
)
+
dx
;
buf
[
m
++
]
=
h_x
(
j
,
1
)
+
dy
;
buf
[
m
++
]
=
h_x
(
j
,
2
)
+
dz
;
buf
[
m
++
]
=
ubuf
(
h_tag
(
j
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_type
(
j
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_mask
(
j
)).
d
;
buf
[
m
++
]
=
h_q
(
j
);
buf
[
m
++
]
=
ubuf
(
h_molecule
(
j
)).
d
;
}
}
if
(
atom
->
nextra_border
)
for
(
int
iextra
=
0
;
iextra
<
atom
->
nextra_border
;
iextra
++
)
m
+=
modify
->
fix
[
atom
->
extra_border
[
iextra
]]
->
pack_border
(
n
,
list
,
&
buf
[
m
]);
return
m
;
}
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
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
++
]
=
h_x
(
j
,
0
);
buf
[
m
++
]
=
h_x
(
j
,
1
);
buf
[
m
++
]
=
h_x
(
j
,
2
);
buf
[
m
++
]
=
ubuf
(
h_tag
(
j
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_type
(
j
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_mask
(
j
)).
d
;
buf
[
m
++
]
=
h_q
(
j
);
buf
[
m
++
]
=
ubuf
(
h_molecule
(
j
)).
d
;
buf
[
m
++
]
=
h_v
(
j
,
0
);
buf
[
m
++
]
=
h_v
(
j
,
1
);
buf
[
m
++
]
=
h_v
(
j
,
2
);
}
}
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
(
!
deform_vremap
)
{
for
(
i
=
0
;
i
<
n
;
i
++
)
{
j
=
list
[
i
];
buf
[
m
++
]
=
h_x
(
j
,
0
)
+
dx
;
buf
[
m
++
]
=
h_x
(
j
,
1
)
+
dy
;
buf
[
m
++
]
=
h_x
(
j
,
2
)
+
dz
;
buf
[
m
++
]
=
ubuf
(
h_tag
(
j
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_type
(
j
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_mask
(
j
)).
d
;
buf
[
m
++
]
=
h_q
(
j
);
buf
[
m
++
]
=
ubuf
(
h_molecule
(
j
)).
d
;
buf
[
m
++
]
=
h_v
(
j
,
0
);
buf
[
m
++
]
=
h_v
(
j
,
1
);
buf
[
m
++
]
=
h_v
(
j
,
2
);
}
}
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
++
]
=
h_x
(
j
,
0
)
+
dx
;
buf
[
m
++
]
=
h_x
(
j
,
1
)
+
dy
;
buf
[
m
++
]
=
h_x
(
j
,
2
)
+
dz
;
buf
[
m
++
]
=
ubuf
(
h_tag
(
j
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_type
(
j
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_mask
(
j
)).
d
;
buf
[
m
++
]
=
h_q
(
j
);
buf
[
m
++
]
=
ubuf
(
h_molecule
(
j
)).
d
;
if
(
mask
[
i
]
&
deform_groupbit
)
{
buf
[
m
++
]
=
h_v
(
j
,
0
)
+
dvx
;
buf
[
m
++
]
=
h_v
(
j
,
1
)
+
dvy
;
buf
[
m
++
]
=
h_v
(
j
,
2
)
+
dvz
;
}
else
{
buf
[
m
++
]
=
h_v
(
j
,
0
);
buf
[
m
++
]
=
h_v
(
j
,
1
);
buf
[
m
++
]
=
h_v
(
j
,
2
);
}
}
}
}
if
(
atom
->
nextra_border
)
for
(
int
iextra
=
0
;
iextra
<
atom
->
nextra_border
;
iextra
++
)
m
+=
modify
->
fix
[
atom
->
extra_border
[
iextra
]]
->
pack_border
(
n
,
list
,
&
buf
[
m
]);
return
m
;
}
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
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
++
]
=
h_q
(
j
);
buf
[
m
++
]
=
ubuf
(
h_molecule
(
j
)).
d
;
}
return
m
;
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
struct
AtomVecFullKokkos_UnpackBorder
{
union
ubuf
{
double
d
;
int64_t
i
;
KOKKOS_INLINE_FUNCTION
ubuf
(
double
arg
)
:
d
(
arg
)
{}
KOKKOS_INLINE_FUNCTION
ubuf
(
int64_t
arg
)
:
i
(
arg
)
{}
KOKKOS_INLINE_FUNCTION
ubuf
(
int
arg
)
:
i
(
arg
)
{}
};
typedef
DeviceType
device_type
;
typedef
ArrayTypes
<
DeviceType
>
AT
;
const
typename
AT
::
t_xfloat_2d_const
_buf
;
typename
AT
::
t_x_array
_x
;
typename
AT
::
t_tagint_1d
_tag
;
typename
AT
::
t_int_1d
_type
;
typename
AT
::
t_int_1d
_mask
;
typename
AT
::
t_float_1d
_q
;
typename
AT
::
t_tagint_1d
_molecule
;
int
_first
;
AtomVecFullKokkos_UnpackBorder
(
const
typename
AT
::
t_xfloat_2d_const
&
buf
,
typename
AT
::
t_x_array
&
x
,
typename
AT
::
t_tagint_1d
&
tag
,
typename
AT
::
t_int_1d
&
type
,
typename
AT
::
t_int_1d
&
mask
,
typename
AT
::
t_float_1d
&
q
,
typename
AT
::
t_tagint_1d
&
molecule
,
const
int
&
first
)
:
_buf
(
buf
),
_x
(
x
),
_tag
(
tag
),
_type
(
type
),
_mask
(
mask
),
_q
(
q
),
_molecule
(
molecule
),
_first
(
first
){
};
KOKKOS_INLINE_FUNCTION
void
operator
()
(
const
int
&
i
)
const
{
_x
(
i
+
_first
,
0
)
=
_buf
(
i
,
0
);
_x
(
i
+
_first
,
1
)
=
_buf
(
i
,
1
);
_x
(
i
+
_first
,
2
)
=
_buf
(
i
,
2
);
_tag
(
i
+
_first
)
=
(
tagint
)
ubuf
(
_buf
(
i
,
3
)).
i
;
_type
(
i
+
_first
)
=
(
int
)
ubuf
(
_buf
(
i
,
4
)).
i
;
_mask
(
i
+
_first
)
=
(
int
)
ubuf
(
_buf
(
i
,
5
)).
i
;
_q
(
i
+
_first
)
=
_buf
(
i
,
6
);
_molecule
(
i
+
_first
)
=
(
tagint
)
ubuf
(
_buf
(
i
,
7
)).
i
;
}
};
/* ---------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
unpack_border_kokkos
(
const
int
&
n
,
const
int
&
first
,
const
DAT
::
tdual_xfloat_2d
&
buf
,
ExecutionSpace
space
)
{
modified
(
space
,
X_MASK
|
TAG_MASK
|
TYPE_MASK
|
MASK_MASK
|
Q_MASK
|
MOLECULE_MASK
);
while
(
first
+
n
>=
nmax
)
grow
(
0
);
modified
(
space
,
X_MASK
|
TAG_MASK
|
TYPE_MASK
|
MASK_MASK
|
Q_MASK
|
MOLECULE_MASK
);
if
(
space
==
Host
)
{
struct
AtomVecFullKokkos_UnpackBorder
<
LMPHostType
>
f
(
buf
.
view
<
LMPHostType
>
(),
h_x
,
h_tag
,
h_type
,
h_mask
,
h_q
,
h_molecule
,
first
);
Kokkos
::
parallel_for
(
n
,
f
);
LMPHostType
::
fence
();
}
else
{
struct
AtomVecFullKokkos_UnpackBorder
<
LMPDeviceType
>
f
(
buf
.
view
<
LMPDeviceType
>
(),
d_x
,
d_tag
,
d_type
,
d_mask
,
d_q
,
d_molecule
,
first
);
Kokkos
::
parallel_for
(
n
,
f
);
LMPDeviceType
::
fence
();
}
}
/* ---------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
unpack_border
(
int
n
,
int
first
,
double
*
buf
)
{
int
i
,
m
,
last
;
m
=
0
;
last
=
first
+
n
;
if
(
n
>
0
)
modified
(
Host
,
X_MASK
|
TAG_MASK
|
TYPE_MASK
|
MASK_MASK
|
Q_MASK
|
MOLECULE_MASK
);
for
(
i
=
first
;
i
<
last
;
i
++
)
{
if
(
i
==
nmax
)
grow
(
0
);
h_x
(
i
,
0
)
=
buf
[
m
++
];
h_x
(
i
,
1
)
=
buf
[
m
++
];
h_x
(
i
,
2
)
=
buf
[
m
++
];
h_tag
(
i
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_type
(
i
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_mask
(
i
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_q
(
i
)
=
buf
[
m
++
];
h_molecule
(
i
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
}
if
(
atom
->
nextra_border
)
for
(
int
iextra
=
0
;
iextra
<
atom
->
nextra_border
;
iextra
++
)
m
+=
modify
->
fix
[
atom
->
extra_border
[
iextra
]]
->
unpack_border
(
n
,
first
,
&
buf
[
m
]);
}
/* ---------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
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
);
modified
(
Host
,
X_MASK
|
TAG_MASK
|
TYPE_MASK
|
MASK_MASK
|
Q_MASK
|
MOLECULE_MASK
);
h_x
(
i
,
0
)
=
buf
[
m
++
];
h_x
(
i
,
1
)
=
buf
[
m
++
];
h_x
(
i
,
2
)
=
buf
[
m
++
];
h_tag
(
i
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_type
(
i
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_mask
(
i
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_q
(
i
)
=
buf
[
m
++
];
h_molecule
(
i
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_v
(
i
,
0
)
=
buf
[
m
++
];
h_v
(
i
,
1
)
=
buf
[
m
++
];
h_v
(
i
,
2
)
=
buf
[
m
++
];
}
if
(
atom
->
nextra_border
)
for
(
int
iextra
=
0
;
iextra
<
atom
->
nextra_border
;
iextra
++
)
m
+=
modify
->
fix
[
atom
->
extra_border
[
iextra
]]
->
unpack_border
(
n
,
first
,
&
buf
[
m
]);
}
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
unpack_border_hybrid
(
int
n
,
int
first
,
double
*
buf
)
{
int
i
,
m
,
last
;
m
=
0
;
last
=
first
+
n
;
for
(
i
=
first
;
i
<
last
;
i
++
)
{
h_q
(
i
)
=
buf
[
m
++
];
h_molecule
(
i
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
}
return
m
;
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
struct
AtomVecFullKokkos_PackExchangeFunctor
{
union
ubuf
{
double
d
;
int64_t
i
;
KOKKOS_INLINE_FUNCTION
ubuf
(
double
arg
)
:
d
(
arg
)
{}
KOKKOS_INLINE_FUNCTION
ubuf
(
int64_t
arg
)
:
i
(
arg
)
{}
KOKKOS_INLINE_FUNCTION
ubuf
(
int
arg
)
:
i
(
arg
)
{}
};
typedef
DeviceType
device_type
;
typedef
ArrayTypes
<
DeviceType
>
AT
;
typename
AT
::
t_x_array_randomread
_x
;
typename
AT
::
t_v_array_randomread
_v
;
typename
AT
::
t_tagint_1d_randomread
_tag
;
typename
AT
::
t_int_1d_randomread
_type
;
typename
AT
::
t_int_1d_randomread
_mask
;
typename
AT
::
t_imageint_1d_randomread
_image
;
typename
AT
::
t_float_1d_randomread
_q
;
typename
AT
::
t_tagint_1d_randomread
_molecule
;
typename
AT
::
t_int_2d_randomread
_nspecial
;
typename
AT
::
t_tagint_2d_randomread
_special
;
typename
AT
::
t_int_1d_randomread
_num_bond
;
typename
AT
::
t_int_2d_randomread
_bond_type
;
typename
AT
::
t_tagint_2d_randomread
_bond_atom
;
typename
AT
::
t_int_1d_randomread
_num_angle
;
typename
AT
::
t_int_2d_randomread
_angle_type
;
typename
AT
::
t_tagint_2d_randomread
_angle_atom1
,
_angle_atom2
,
_angle_atom3
;
typename
AT
::
t_int_1d_randomread
_num_dihedral
;
typename
AT
::
t_int_2d_randomread
_dihedral_type
;
typename
AT
::
t_tagint_2d_randomread
_dihedral_atom1
,
_dihedral_atom2
,
_dihedral_atom3
,
_dihedral_atom4
;
typename
AT
::
t_int_1d_randomread
_num_improper
;
typename
AT
::
t_int_2d_randomread
_improper_type
;
typename
AT
::
t_tagint_2d_randomread
_improper_atom1
,
_improper_atom2
,
_improper_atom3
,
_improper_atom4
;
typename
AT
::
t_x_array
_xw
;
typename
AT
::
t_v_array
_vw
;
typename
AT
::
t_tagint_1d
_tagw
;
typename
AT
::
t_int_1d
_typew
;
typename
AT
::
t_int_1d
_maskw
;
typename
AT
::
t_imageint_1d
_imagew
;
typename
AT
::
t_float_1d
_qw
;
typename
AT
::
t_tagint_1d
_moleculew
;
typename
AT
::
t_int_2d
_nspecialw
;
typename
AT
::
t_tagint_2d
_specialw
;
typename
AT
::
t_int_1d
_num_bondw
;
typename
AT
::
t_int_2d
_bond_typew
;
typename
AT
::
t_tagint_2d
_bond_atomw
;
typename
AT
::
t_int_1d
_num_anglew
;
typename
AT
::
t_int_2d
_angle_typew
;
typename
AT
::
t_tagint_2d
_angle_atom1w
,
_angle_atom2w
,
_angle_atom3w
;
typename
AT
::
t_int_1d
_num_dihedralw
;
typename
AT
::
t_int_2d
_dihedral_typew
;
typename
AT
::
t_tagint_2d
_dihedral_atom1w
,
_dihedral_atom2w
,
_dihedral_atom3w
,
_dihedral_atom4w
;
typename
AT
::
t_int_1d
_num_improperw
;
typename
AT
::
t_int_2d
_improper_typew
;
typename
AT
::
t_tagint_2d
_improper_atom1w
,
_improper_atom2w
,
_improper_atom3w
,
_improper_atom4w
;
typename
AT
::
t_xfloat_2d_um
_buf
;
typename
AT
::
t_int_1d_const
_sendlist
;
typename
AT
::
t_int_1d_const
_copylist
;
int
_nlocal
,
_dim
;
X_FLOAT
_lo
,
_hi
;
size_t
elements
;
AtomVecFullKokkos_PackExchangeFunctor
(
const
AtomKokkos
*
atom
,
const
typename
AT
::
tdual_xfloat_2d
buf
,
typename
AT
::
tdual_int_1d
sendlist
,
typename
AT
::
tdual_int_1d
copylist
,
int
nlocal
,
int
dim
,
X_FLOAT
lo
,
X_FLOAT
hi
)
:
_x
(
atom
->
k_x
.
view
<
DeviceType
>
()),
_v
(
atom
->
k_v
.
view
<
DeviceType
>
()),
_tag
(
atom
->
k_tag
.
view
<
DeviceType
>
()),
_type
(
atom
->
k_type
.
view
<
DeviceType
>
()),
_mask
(
atom
->
k_mask
.
view
<
DeviceType
>
()),
_image
(
atom
->
k_image
.
view
<
DeviceType
>
()),
_q
(
atom
->
k_q
.
view
<
DeviceType
>
()),
_molecule
(
atom
->
k_molecule
.
view
<
DeviceType
>
()),
_nspecial
(
atom
->
k_nspecial
.
view
<
DeviceType
>
()),
_special
(
atom
->
k_special
.
view
<
DeviceType
>
()),
_num_bond
(
atom
->
k_num_bond
.
view
<
DeviceType
>
()),
_bond_type
(
atom
->
k_bond_type
.
view
<
DeviceType
>
()),
_bond_atom
(
atom
->
k_bond_atom
.
view
<
DeviceType
>
()),
_num_angle
(
atom
->
k_num_angle
.
view
<
DeviceType
>
()),
_angle_type
(
atom
->
k_angle_type
.
view
<
DeviceType
>
()),
_angle_atom1
(
atom
->
k_angle_atom1
.
view
<
DeviceType
>
()),
_angle_atom2
(
atom
->
k_angle_atom2
.
view
<
DeviceType
>
()),
_angle_atom3
(
atom
->
k_angle_atom3
.
view
<
DeviceType
>
()),
_num_dihedral
(
atom
->
k_num_dihedral
.
view
<
DeviceType
>
()),
_dihedral_type
(
atom
->
k_dihedral_type
.
view
<
DeviceType
>
()),
_dihedral_atom1
(
atom
->
k_dihedral_atom1
.
view
<
DeviceType
>
()),
_dihedral_atom2
(
atom
->
k_dihedral_atom2
.
view
<
DeviceType
>
()),
_dihedral_atom3
(
atom
->
k_dihedral_atom3
.
view
<
DeviceType
>
()),
_dihedral_atom4
(
atom
->
k_dihedral_atom4
.
view
<
DeviceType
>
()),
_num_improper
(
atom
->
k_num_improper
.
view
<
DeviceType
>
()),
_improper_type
(
atom
->
k_improper_type
.
view
<
DeviceType
>
()),
_improper_atom1
(
atom
->
k_improper_atom1
.
view
<
DeviceType
>
()),
_improper_atom2
(
atom
->
k_improper_atom2
.
view
<
DeviceType
>
()),
_improper_atom3
(
atom
->
k_improper_atom3
.
view
<
DeviceType
>
()),
_improper_atom4
(
atom
->
k_improper_atom4
.
view
<
DeviceType
>
()),
_xw
(
atom
->
k_x
.
view
<
DeviceType
>
()),
_vw
(
atom
->
k_v
.
view
<
DeviceType
>
()),
_tagw
(
atom
->
k_tag
.
view
<
DeviceType
>
()),
_typew
(
atom
->
k_type
.
view
<
DeviceType
>
()),
_maskw
(
atom
->
k_mask
.
view
<
DeviceType
>
()),
_imagew
(
atom
->
k_image
.
view
<
DeviceType
>
()),
_qw
(
atom
->
k_q
.
view
<
DeviceType
>
()),
_moleculew
(
atom
->
k_molecule
.
view
<
DeviceType
>
()),
_nspecialw
(
atom
->
k_nspecial
.
view
<
DeviceType
>
()),
_specialw
(
atom
->
k_special
.
view
<
DeviceType
>
()),
_num_bondw
(
atom
->
k_num_bond
.
view
<
DeviceType
>
()),
_bond_typew
(
atom
->
k_bond_type
.
view
<
DeviceType
>
()),
_bond_atomw
(
atom
->
k_bond_atom
.
view
<
DeviceType
>
()),
_num_anglew
(
atom
->
k_num_angle
.
view
<
DeviceType
>
()),
_angle_typew
(
atom
->
k_angle_type
.
view
<
DeviceType
>
()),
_angle_atom1w
(
atom
->
k_angle_atom1
.
view
<
DeviceType
>
()),
_angle_atom2w
(
atom
->
k_angle_atom2
.
view
<
DeviceType
>
()),
_angle_atom3w
(
atom
->
k_angle_atom3
.
view
<
DeviceType
>
()),
_num_dihedralw
(
atom
->
k_num_dihedral
.
view
<
DeviceType
>
()),
_dihedral_typew
(
atom
->
k_dihedral_type
.
view
<
DeviceType
>
()),
_dihedral_atom1w
(
atom
->
k_dihedral_atom1
.
view
<
DeviceType
>
()),
_dihedral_atom2w
(
atom
->
k_dihedral_atom2
.
view
<
DeviceType
>
()),
_dihedral_atom3w
(
atom
->
k_dihedral_atom3
.
view
<
DeviceType
>
()),
_dihedral_atom4w
(
atom
->
k_dihedral_atom4
.
view
<
DeviceType
>
()),
_num_improperw
(
atom
->
k_num_improper
.
view
<
DeviceType
>
()),
_improper_typew
(
atom
->
k_improper_type
.
view
<
DeviceType
>
()),
_improper_atom1w
(
atom
->
k_improper_atom1
.
view
<
DeviceType
>
()),
_improper_atom2w
(
atom
->
k_improper_atom2
.
view
<
DeviceType
>
()),
_improper_atom3w
(
atom
->
k_improper_atom3
.
view
<
DeviceType
>
()),
_improper_atom4w
(
atom
->
k_improper_atom4
.
view
<
DeviceType
>
()),
_sendlist
(
sendlist
.
template
view
<
DeviceType
>
()),
_copylist
(
copylist
.
template
view
<
DeviceType
>
()),
_nlocal
(
nlocal
),
_dim
(
dim
),
_lo
(
lo
),
_hi
(
hi
){
// 3 comp of x, 3 comp of v, 1 tag, 1 type, 1 mask, 1 image, 1 molecule, 3 nspecial,
// maxspecial special, 1 num_bond, bond_per_atom bond_type, bond_per_atom bond_atom,
// 1 num_angle, angle_per_atom angle_type, angle_per_atom angle_atom1, angle_atom2,
// and angle_atom3
// 1 num_dihedral, dihedral_per_atom dihedral_type, 4*dihedral_per_atom
// 1 num_improper, 5*improper_per_atom
// 1 charge
// 1 to store buffer length
elements
=
20
+
atom
->
maxspecial
+
2
*
atom
->
bond_per_atom
+
4
*
atom
->
angle_per_atom
+
5
*
atom
->
dihedral_per_atom
+
5
*
atom
->
improper_per_atom
;
const
int
maxsendlist
=
(
buf
.
template
view
<
DeviceType
>
().
dimension_0
()
*
buf
.
template
view
<
DeviceType
>
().
dimension_1
())
/
elements
;
buffer_view
<
DeviceType
>
(
_buf
,
buf
,
maxsendlist
,
elements
);
}
KOKKOS_INLINE_FUNCTION
void
operator
()
(
const
int
&
mysend
)
const
{
int
k
;
const
int
i
=
_sendlist
(
mysend
);
_buf
(
mysend
,
0
)
=
elements
;
int
m
=
1
;
_buf
(
mysend
,
m
++
)
=
_x
(
i
,
0
);
_buf
(
mysend
,
m
++
)
=
_x
(
i
,
1
);
_buf
(
mysend
,
m
++
)
=
_x
(
i
,
2
);
_buf
(
mysend
,
m
++
)
=
_v
(
i
,
0
);
_buf
(
mysend
,
m
++
)
=
_v
(
i
,
1
);
_buf
(
mysend
,
m
++
)
=
_v
(
i
,
2
);
_buf
(
mysend
,
m
++
)
=
ubuf
(
_tag
(
i
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_type
(
i
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_mask
(
i
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_image
(
i
)).
d
;
_buf
(
mysend
,
m
++
)
=
_q
(
i
);
_buf
(
mysend
,
m
++
)
=
ubuf
(
_molecule
(
i
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_num_bond
(
i
)).
d
;
for
(
k
=
0
;
k
<
_num_bond
(
i
);
k
++
)
{
_buf
(
mysend
,
m
++
)
=
ubuf
(
_bond_type
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_bond_atom
(
i
,
k
)).
d
;
}
_buf
(
mysend
,
m
++
)
=
ubuf
(
_num_angle
(
i
)).
d
;
for
(
k
=
0
;
k
<
_num_angle
(
i
);
k
++
)
{
_buf
(
mysend
,
m
++
)
=
ubuf
(
_angle_type
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_angle_atom1
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_angle_atom2
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_angle_atom3
(
i
,
k
)).
d
;
}
_buf
(
mysend
,
m
++
)
=
ubuf
(
_num_dihedral
(
i
)).
d
;
for
(
k
=
0
;
k
<
_num_dihedral
(
i
);
k
++
)
{
_buf
(
mysend
,
m
++
)
=
ubuf
(
_dihedral_type
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_dihedral_atom1
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_dihedral_atom2
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_dihedral_atom3
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_dihedral_atom4
(
i
,
k
)).
d
;
}
_buf
(
mysend
,
m
++
)
=
ubuf
(
_num_improper
(
i
)).
d
;
for
(
k
=
0
;
k
<
_num_improper
(
i
);
k
++
)
{
_buf
(
mysend
,
m
++
)
=
ubuf
(
_improper_type
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_improper_atom1
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_improper_atom2
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_improper_atom3
(
i
,
k
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_improper_atom4
(
i
,
k
)).
d
;
}
_buf
(
mysend
,
m
++
)
=
ubuf
(
_nspecial
(
i
,
0
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_nspecial
(
i
,
1
)).
d
;
_buf
(
mysend
,
m
++
)
=
ubuf
(
_nspecial
(
i
,
2
)).
d
;
for
(
k
=
0
;
k
<
_nspecial
(
i
,
2
);
k
++
)
_buf
(
mysend
,
m
++
)
=
ubuf
(
_special
(
i
,
k
)).
d
;
const
int
j
=
_copylist
(
mysend
);
if
(
j
>-
1
)
{
_xw
(
i
,
0
)
=
_x
(
j
,
0
);
_xw
(
i
,
1
)
=
_x
(
j
,
1
);
_xw
(
i
,
2
)
=
_x
(
j
,
2
);
_vw
(
i
,
0
)
=
_v
(
j
,
0
);
_vw
(
i
,
1
)
=
_v
(
j
,
1
);
_vw
(
i
,
2
)
=
_v
(
j
,
2
);
_tagw
(
i
)
=
_tag
(
j
);
_typew
(
i
)
=
_type
(
j
);
_maskw
(
i
)
=
_mask
(
j
);
_imagew
(
i
)
=
_image
(
j
);
_qw
(
i
)
=
_q
(
j
);
_moleculew
(
i
)
=
_molecule
(
j
);
_num_bondw
(
i
)
=
_num_bond
(
j
);
for
(
k
=
0
;
k
<
_num_bond
(
j
);
k
++
)
{
_bond_typew
(
i
,
k
)
=
_bond_type
(
j
,
k
);
_bond_atomw
(
i
,
k
)
=
_bond_atom
(
j
,
k
);
}
_num_anglew
(
i
)
=
_num_angle
(
j
);
for
(
k
=
0
;
k
<
_num_angle
(
j
);
k
++
)
{
_angle_typew
(
i
,
k
)
=
_angle_type
(
j
,
k
);
_angle_atom1w
(
i
,
k
)
=
_angle_atom1
(
j
,
k
);
_angle_atom2w
(
i
,
k
)
=
_angle_atom2
(
j
,
k
);
_angle_atom3w
(
i
,
k
)
=
_angle_atom3
(
j
,
k
);
}
_num_dihedralw
(
i
)
=
_num_dihedral
(
j
);
for
(
k
=
0
;
k
<
_num_dihedral
(
j
);
k
++
)
{
_dihedral_typew
(
i
,
k
)
=
_dihedral_type
(
j
,
k
);
_dihedral_atom1w
(
i
,
k
)
=
_dihedral_atom1
(
j
,
k
);
_dihedral_atom2w
(
i
,
k
)
=
_dihedral_atom2
(
j
,
k
);
_dihedral_atom3w
(
i
,
k
)
=
_dihedral_atom3
(
j
,
k
);
_dihedral_atom4w
(
i
,
k
)
=
_dihedral_atom4
(
j
,
k
);
}
_num_improperw
(
i
)
=
_num_improper
(
j
);
for
(
k
=
0
;
k
<
_num_improper
(
j
);
k
++
)
{
_improper_typew
(
i
,
k
)
=
_improper_type
(
j
,
k
);
_improper_atom1w
(
i
,
k
)
=
_improper_atom1
(
j
,
k
);
_improper_atom2w
(
i
,
k
)
=
_improper_atom2
(
j
,
k
);
_improper_atom3w
(
i
,
k
)
=
_improper_atom3
(
j
,
k
);
_improper_atom4w
(
i
,
k
)
=
_improper_atom4
(
j
,
k
);
}
_nspecialw
(
i
,
0
)
=
_nspecial
(
j
,
0
);
_nspecialw
(
i
,
1
)
=
_nspecial
(
j
,
1
);
_nspecialw
(
i
,
2
)
=
_nspecial
(
j
,
2
);
for
(
k
=
0
;
k
<
_nspecial
(
j
,
2
);
k
++
)
_specialw
(
i
,
k
)
=
_special
(
j
,
k
);
}
}
};
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
pack_exchange_kokkos
(
const
int
&
nsend
,
DAT
::
tdual_xfloat_2d
&
k_buf
,
DAT
::
tdual_int_1d
k_sendlist
,
DAT
::
tdual_int_1d
k_copylist
,
ExecutionSpace
space
,
int
dim
,
X_FLOAT
lo
,
X_FLOAT
hi
)
{
const
int
elements
=
20
+
atom
->
maxspecial
+
2
*
atom
->
bond_per_atom
+
4
*
atom
->
angle_per_atom
+
5
*
atom
->
dihedral_per_atom
+
5
*
atom
->
improper_per_atom
;
if
(
nsend
>
(
int
)
(
k_buf
.
view
<
LMPHostType
>
().
dimension_0
()
*
k_buf
.
view
<
LMPHostType
>
().
dimension_1
())
/
elements
)
{
int
newsize
=
nsend
*
elements
/
k_buf
.
view
<
LMPHostType
>
().
dimension_1
()
+
1
;
k_buf
.
resize
(
newsize
,
k_buf
.
view
<
LMPHostType
>
().
dimension_1
());
}
if
(
space
==
Host
)
{
AtomVecFullKokkos_PackExchangeFunctor
<
LMPHostType
>
f
(
atomKK
,
k_buf
,
k_sendlist
,
k_copylist
,
atom
->
nlocal
,
dim
,
lo
,
hi
);
Kokkos
::
parallel_for
(
nsend
,
f
);
LMPHostType
::
fence
();
return
nsend
*
elements
;
}
else
{
AtomVecFullKokkos_PackExchangeFunctor
<
LMPDeviceType
>
f
(
atomKK
,
k_buf
,
k_sendlist
,
k_copylist
,
atom
->
nlocal
,
dim
,
lo
,
hi
);
Kokkos
::
parallel_for
(
nsend
,
f
);
LMPDeviceType
::
fence
();
return
nsend
*
elements
;
}
}
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
pack_exchange
(
int
i
,
double
*
buf
)
{
int
k
;
int
m
=
1
;
buf
[
m
++
]
=
h_x
(
i
,
0
);
buf
[
m
++
]
=
h_x
(
i
,
1
);
buf
[
m
++
]
=
h_x
(
i
,
2
);
buf
[
m
++
]
=
h_v
(
i
,
0
);
buf
[
m
++
]
=
h_v
(
i
,
1
);
buf
[
m
++
]
=
h_v
(
i
,
2
);
buf
[
m
++
]
=
ubuf
(
h_tag
(
i
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_type
(
i
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_mask
(
i
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_image
(
i
)).
d
;
buf
[
m
++
]
=
h_q
(
i
);
buf
[
m
++
]
=
ubuf
(
h_molecule
(
i
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_num_bond
(
i
)).
d
;
for
(
k
=
0
;
k
<
h_num_bond
(
i
);
k
++
)
{
buf
[
m
++
]
=
ubuf
(
h_bond_type
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_bond_atom
(
i
,
k
)).
d
;
}
buf
[
m
++
]
=
ubuf
(
h_num_angle
(
i
)).
d
;
for
(
k
=
0
;
k
<
h_num_angle
(
i
);
k
++
)
{
buf
[
m
++
]
=
ubuf
(
h_angle_type
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_angle_atom1
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_angle_atom2
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_angle_atom3
(
i
,
k
)).
d
;
}
buf
[
m
++
]
=
ubuf
(
h_num_dihedral
(
i
)).
d
;
for
(
k
=
0
;
k
<
h_num_dihedral
(
i
);
k
++
)
{
buf
[
m
++
]
=
ubuf
(
h_dihedral_type
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_dihedral_atom1
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_dihedral_atom2
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_dihedral_atom3
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_dihedral_atom4
(
i
,
k
)).
d
;
}
buf
[
m
++
]
=
ubuf
(
h_num_improper
(
i
)).
d
;
for
(
k
=
0
;
k
<
h_num_improper
(
i
);
k
++
)
{
buf
[
m
++
]
=
ubuf
(
h_improper_type
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_improper_atom1
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_improper_atom2
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_improper_atom3
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_improper_atom4
(
i
,
k
)).
d
;
}
buf
[
m
++
]
=
ubuf
(
h_nspecial
(
i
,
0
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_nspecial
(
i
,
1
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_nspecial
(
i
,
2
)).
d
;
for
(
k
=
0
;
k
<
h_nspecial
(
i
,
2
);
k
++
)
buf
[
m
++
]
=
ubuf
(
h_special
(
i
,
k
)).
d
;
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
;
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
struct
AtomVecFullKokkos_UnpackExchangeFunctor
{
union
ubuf
{
double
d
;
int64_t
i
;
KOKKOS_INLINE_FUNCTION
ubuf
(
double
arg
)
:
d
(
arg
)
{}
KOKKOS_INLINE_FUNCTION
ubuf
(
int64_t
arg
)
:
i
(
arg
)
{}
KOKKOS_INLINE_FUNCTION
ubuf
(
int
arg
)
:
i
(
arg
)
{}
};
typedef
DeviceType
device_type
;
typedef
ArrayTypes
<
DeviceType
>
AT
;
typename
AT
::
t_x_array
_x
;
typename
AT
::
t_v_array
_v
;
typename
AT
::
t_tagint_1d
_tag
;
typename
AT
::
t_int_1d
_type
;
typename
AT
::
t_int_1d
_mask
;
typename
AT
::
t_imageint_1d
_image
;
typename
AT
::
t_float_1d
_q
;
typename
AT
::
t_tagint_1d
_molecule
;
typename
AT
::
t_int_2d
_nspecial
;
typename
AT
::
t_tagint_2d
_special
;
typename
AT
::
t_int_1d
_num_bond
;
typename
AT
::
t_int_2d
_bond_type
;
typename
AT
::
t_tagint_2d
_bond_atom
;
typename
AT
::
t_int_1d
_num_angle
;
typename
AT
::
t_int_2d
_angle_type
;
typename
AT
::
t_tagint_2d
_angle_atom1
,
_angle_atom2
,
_angle_atom3
;
typename
AT
::
t_int_1d
_num_dihedral
;
typename
AT
::
t_int_2d
_dihedral_type
;
typename
AT
::
t_tagint_2d
_dihedral_atom1
,
_dihedral_atom2
,
_dihedral_atom3
,
_dihedral_atom4
;
typename
AT
::
t_int_1d
_num_improper
;
typename
AT
::
t_int_2d
_improper_type
;
typename
AT
::
t_tagint_2d
_improper_atom1
,
_improper_atom2
,
_improper_atom3
,
_improper_atom4
;
typename
AT
::
t_xfloat_2d_um
_buf
;
typename
AT
::
t_int_1d
_nlocal
;
int
_dim
;
X_FLOAT
_lo
,
_hi
;
size_t
elements
;
AtomVecFullKokkos_UnpackExchangeFunctor
(
const
AtomKokkos
*
atom
,
const
typename
AT
::
tdual_xfloat_2d
buf
,
typename
AT
::
tdual_int_1d
nlocal
,
int
dim
,
X_FLOAT
lo
,
X_FLOAT
hi
)
:
_x
(
atom
->
k_x
.
view
<
DeviceType
>
()),
_v
(
atom
->
k_v
.
view
<
DeviceType
>
()),
_tag
(
atom
->
k_tag
.
view
<
DeviceType
>
()),
_type
(
atom
->
k_type
.
view
<
DeviceType
>
()),
_mask
(
atom
->
k_mask
.
view
<
DeviceType
>
()),
_image
(
atom
->
k_image
.
view
<
DeviceType
>
()),
_q
(
atom
->
k_q
.
view
<
DeviceType
>
()),
_molecule
(
atom
->
k_molecule
.
view
<
DeviceType
>
()),
_nspecial
(
atom
->
k_nspecial
.
view
<
DeviceType
>
()),
_special
(
atom
->
k_special
.
view
<
DeviceType
>
()),
_num_bond
(
atom
->
k_num_bond
.
view
<
DeviceType
>
()),
_bond_type
(
atom
->
k_bond_type
.
view
<
DeviceType
>
()),
_bond_atom
(
atom
->
k_bond_atom
.
view
<
DeviceType
>
()),
_num_angle
(
atom
->
k_num_angle
.
view
<
DeviceType
>
()),
_angle_type
(
atom
->
k_angle_type
.
view
<
DeviceType
>
()),
_angle_atom1
(
atom
->
k_angle_atom1
.
view
<
DeviceType
>
()),
_angle_atom2
(
atom
->
k_angle_atom2
.
view
<
DeviceType
>
()),
_angle_atom3
(
atom
->
k_angle_atom3
.
view
<
DeviceType
>
()),
_num_dihedral
(
atom
->
k_num_dihedral
.
view
<
DeviceType
>
()),
_dihedral_type
(
atom
->
k_dihedral_type
.
view
<
DeviceType
>
()),
_dihedral_atom1
(
atom
->
k_dihedral_atom1
.
view
<
DeviceType
>
()),
_dihedral_atom2
(
atom
->
k_dihedral_atom2
.
view
<
DeviceType
>
()),
_dihedral_atom3
(
atom
->
k_dihedral_atom3
.
view
<
DeviceType
>
()),
_dihedral_atom4
(
atom
->
k_dihedral_atom4
.
view
<
DeviceType
>
()),
_num_improper
(
atom
->
k_num_improper
.
view
<
DeviceType
>
()),
_improper_type
(
atom
->
k_improper_type
.
view
<
DeviceType
>
()),
_improper_atom1
(
atom
->
k_improper_atom1
.
view
<
DeviceType
>
()),
_improper_atom2
(
atom
->
k_improper_atom2
.
view
<
DeviceType
>
()),
_improper_atom3
(
atom
->
k_improper_atom3
.
view
<
DeviceType
>
()),
_improper_atom4
(
atom
->
k_improper_atom4
.
view
<
DeviceType
>
()),
_nlocal
(
nlocal
.
template
view
<
DeviceType
>
()),
_dim
(
dim
),
_lo
(
lo
),
_hi
(
hi
){
elements
=
20
+
atom
->
maxspecial
+
2
*
atom
->
bond_per_atom
+
4
*
atom
->
angle_per_atom
+
5
*
atom
->
dihedral_per_atom
+
5
*
atom
->
improper_per_atom
;
const
int
maxsendlist
=
(
buf
.
template
view
<
DeviceType
>
().
dimension_0
()
*
buf
.
template
view
<
DeviceType
>
().
dimension_1
())
/
elements
;
buffer_view
<
DeviceType
>
(
_buf
,
buf
,
maxsendlist
,
elements
);
}
KOKKOS_INLINE_FUNCTION
void
operator
()
(
const
int
&
myrecv
)
const
{
X_FLOAT
x
=
_buf
(
myrecv
,
_dim
+
1
);
if
(
x
>=
_lo
&&
x
<
_hi
)
{
int
i
=
Kokkos
::
atomic_fetch_add
(
&
_nlocal
(
0
),
1
);
int
m
=
1
;
_x
(
i
,
0
)
=
_buf
(
myrecv
,
m
++
);
_x
(
i
,
1
)
=
_buf
(
myrecv
,
m
++
);
_x
(
i
,
2
)
=
_buf
(
myrecv
,
m
++
);
_v
(
i
,
0
)
=
_buf
(
myrecv
,
m
++
);
_v
(
i
,
1
)
=
_buf
(
myrecv
,
m
++
);
_v
(
i
,
2
)
=
_buf
(
myrecv
,
m
++
);
_tag
(
i
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_type
(
i
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_mask
(
i
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_image
(
i
)
=
(
imageint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_q
(
i
)
=
_buf
(
myrecv
,
m
++
);
_molecule
(
i
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_num_bond
(
i
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
int
k
;
for
(
k
=
0
;
k
<
_num_bond
(
i
);
k
++
)
{
_bond_type
(
i
,
k
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_bond_atom
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
}
_num_angle
(
i
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
for
(
k
=
0
;
k
<
_num_angle
(
i
);
k
++
)
{
_angle_type
(
i
,
k
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_angle_atom1
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_angle_atom2
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_angle_atom3
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
}
_num_dihedral
(
i
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
for
(
k
=
0
;
k
<
_num_dihedral
(
i
);
k
++
)
{
_dihedral_type
(
i
,
k
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_dihedral_atom1
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_dihedral_atom2
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_dihedral_atom3
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_dihedral_atom4
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
}
_num_improper
(
i
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
for
(
k
=
0
;
k
<
_num_improper
(
i
);
k
++
)
{
_improper_type
(
i
,
k
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_improper_atom1
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_improper_atom2
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_improper_atom3
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_improper_atom4
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
}
_nspecial
(
i
,
0
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_nspecial
(
i
,
1
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
_nspecial
(
i
,
2
)
=
(
int
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
for
(
k
=
0
;
k
<
_nspecial
(
i
,
2
);
k
++
)
_special
(
i
,
k
)
=
(
tagint
)
ubuf
(
_buf
(
myrecv
,
m
++
)).
i
;
}
}
};
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
unpack_exchange_kokkos
(
DAT
::
tdual_xfloat_2d
&
k_buf
,
int
nrecv
,
int
nlocal
,
int
dim
,
X_FLOAT
lo
,
X_FLOAT
hi
,
ExecutionSpace
space
)
{
const
size_t
elements
=
20
+
atom
->
maxspecial
+
2
*
atom
->
bond_per_atom
+
4
*
atom
->
angle_per_atom
+
5
*
atom
->
dihedral_per_atom
+
5
*
atom
->
improper_per_atom
;
if
(
space
==
Host
)
{
k_count
.
h_view
(
0
)
=
nlocal
;
AtomVecFullKokkos_UnpackExchangeFunctor
<
LMPHostType
>
f
(
atomKK
,
k_buf
,
k_count
,
dim
,
lo
,
hi
);
Kokkos
::
parallel_for
(
nrecv
/
elements
,
f
);
LMPHostType
::
fence
();
return
k_count
.
h_view
(
0
);
}
else
{
k_count
.
h_view
(
0
)
=
nlocal
;
k_count
.
modify
<
LMPHostType
>
();
k_count
.
sync
<
LMPDeviceType
>
();
AtomVecFullKokkos_UnpackExchangeFunctor
<
LMPDeviceType
>
f
(
atomKK
,
k_buf
,
k_count
,
dim
,
lo
,
hi
);
Kokkos
::
parallel_for
(
nrecv
/
elements
,
f
);
LMPDeviceType
::
fence
();
k_count
.
modify
<
LMPDeviceType
>
();
k_count
.
sync
<
LMPHostType
>
();
return
k_count
.
h_view
(
0
);
}
}
/* ---------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
unpack_exchange
(
double
*
buf
)
{
int
nlocal
=
atom
->
nlocal
;
if
(
nlocal
==
nmax
)
grow
(
0
);
modified
(
Host
,
X_MASK
|
V_MASK
|
TAG_MASK
|
TYPE_MASK
|
MASK_MASK
|
IMAGE_MASK
|
Q_MASK
|
MOLECULE_MASK
|
BOND_MASK
|
ANGLE_MASK
|
DIHEDRAL_MASK
|
IMPROPER_MASK
|
SPECIAL_MASK
);
int
k
;
int
m
=
1
;
h_x
(
nlocal
,
0
)
=
buf
[
m
++
];
h_x
(
nlocal
,
1
)
=
buf
[
m
++
];
h_x
(
nlocal
,
2
)
=
buf
[
m
++
];
h_v
(
nlocal
,
0
)
=
buf
[
m
++
];
h_v
(
nlocal
,
1
)
=
buf
[
m
++
];
h_v
(
nlocal
,
2
)
=
buf
[
m
++
];
h_tag
(
nlocal
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_type
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_mask
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_image
(
nlocal
)
=
(
imageint
)
ubuf
(
buf
[
m
++
]).
i
;
h_q
(
nlocal
)
=
buf
[
m
++
];
h_molecule
(
nlocal
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_num_bond
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
for
(
k
=
0
;
k
<
h_num_bond
(
nlocal
);
k
++
)
{
h_bond_type
(
nlocal
,
k
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_bond_atom
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
}
h_num_angle
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
for
(
k
=
0
;
k
<
h_num_angle
(
nlocal
);
k
++
)
{
h_angle_type
(
nlocal
,
k
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_angle_atom1
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_angle_atom2
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_angle_atom3
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
}
h_num_dihedral
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
for
(
k
=
0
;
k
<
h_num_dihedral
(
nlocal
);
k
++
)
{
h_dihedral_type
(
nlocal
,
k
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_dihedral_atom1
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_dihedral_atom2
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_dihedral_atom3
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_dihedral_atom4
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
}
h_num_improper
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
for
(
k
=
0
;
k
<
h_num_improper
(
nlocal
);
k
++
)
{
h_improper_type
(
nlocal
,
k
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_improper_atom1
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_improper_atom2
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_improper_atom3
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_improper_atom4
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
}
h_nspecial
(
nlocal
,
0
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_nspecial
(
nlocal
,
1
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_nspecial
(
nlocal
,
2
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
for
(
k
=
0
;
k
<
h_nspecial
(
nlocal
,
2
);
k
++
)
h_special
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
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
AtomVecFullKokkos
::
size_restart
()
{
int
i
;
int
nlocal
=
atom
->
nlocal
;
int
n
=
0
;
for
(
i
=
0
;
i
<
nlocal
;
i
++
)
n
+=
17
+
2
*
num_bond
[
i
]
+
4
*
num_angle
[
i
]
+
5
*
num_dihedral
[
i
]
+
5
*
num_improper
[
i
];
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
AtomVecFullKokkos
::
pack_restart
(
int
i
,
double
*
buf
)
{
sync
(
Host
,
X_MASK
|
V_MASK
|
TAG_MASK
|
TYPE_MASK
|
MASK_MASK
|
IMAGE_MASK
|
Q_MASK
|
MOLECULE_MASK
|
BOND_MASK
|
ANGLE_MASK
|
DIHEDRAL_MASK
|
IMPROPER_MASK
|
SPECIAL_MASK
);
int
m
=
1
;
buf
[
m
++
]
=
h_x
(
i
,
0
);
buf
[
m
++
]
=
h_x
(
i
,
1
);
buf
[
m
++
]
=
h_x
(
i
,
2
);
buf
[
m
++
]
=
ubuf
(
h_tag
(
i
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_type
(
i
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_mask
(
i
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_image
(
i
)).
d
;
buf
[
m
++
]
=
h_v
(
i
,
0
);
buf
[
m
++
]
=
h_v
(
i
,
1
);
buf
[
m
++
]
=
h_v
(
i
,
2
);
buf
[
m
++
]
=
h_q
(
i
);
buf
[
m
++
]
=
ubuf
(
h_molecule
(
i
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_num_bond
(
i
)).
d
;
for
(
int
k
=
0
;
k
<
h_num_bond
(
i
);
k
++
)
{
buf
[
m
++
]
=
ubuf
(
MAX
(
h_bond_type
(
i
,
k
),
-
h_bond_type
(
i
,
k
))).
d
;
buf
[
m
++
]
=
ubuf
(
h_bond_atom
(
i
,
k
)).
d
;
}
buf
[
m
++
]
=
ubuf
(
h_num_angle
(
i
)).
d
;
for
(
int
k
=
0
;
k
<
h_num_angle
(
i
);
k
++
)
{
buf
[
m
++
]
=
ubuf
(
MAX
(
h_angle_type
(
i
,
k
),
-
h_angle_type
(
i
,
k
))).
d
;
buf
[
m
++
]
=
ubuf
(
h_angle_atom1
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_angle_atom2
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_angle_atom3
(
i
,
k
)).
d
;
}
buf
[
m
++
]
=
ubuf
(
h_num_dihedral
(
i
)).
d
;
for
(
int
k
=
0
;
k
<
h_num_dihedral
(
i
);
k
++
)
{
buf
[
m
++
]
=
ubuf
(
MAX
(
h_dihedral_type
(
i
,
k
),
-
h_dihedral_type
(
i
,
k
))).
d
;
buf
[
m
++
]
=
ubuf
(
h_dihedral_atom1
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_dihedral_atom2
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_dihedral_atom3
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_dihedral_atom4
(
i
,
k
)).
d
;
}
buf
[
m
++
]
=
ubuf
(
h_num_improper
(
i
)).
d
;
for
(
int
k
=
0
;
k
<
h_num_improper
(
i
);
k
++
)
{
buf
[
m
++
]
=
ubuf
(
MAX
(
h_improper_type
(
i
,
k
),
-
h_improper_type
(
i
,
k
))).
d
;
buf
[
m
++
]
=
ubuf
(
h_improper_atom1
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_improper_atom2
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_improper_atom3
(
i
,
k
)).
d
;
buf
[
m
++
]
=
ubuf
(
h_improper_atom4
(
i
,
k
)).
d
;
}
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
AtomVecFullKokkos
::
unpack_restart
(
double
*
buf
)
{
int
k
;
int
nlocal
=
atom
->
nlocal
;
if
(
nlocal
==
nmax
)
{
grow
(
0
);
if
(
atom
->
nextra_store
)
memory
->
grow
(
atom
->
extra
,
nmax
,
atom
->
nextra_store
,
"atom:extra"
);
}
modified
(
Host
,
X_MASK
|
V_MASK
|
TAG_MASK
|
TYPE_MASK
|
MASK_MASK
|
IMAGE_MASK
|
Q_MASK
|
MOLECULE_MASK
|
BOND_MASK
|
ANGLE_MASK
|
DIHEDRAL_MASK
|
IMPROPER_MASK
|
SPECIAL_MASK
);
int
m
=
1
;
h_x
(
nlocal
,
0
)
=
buf
[
m
++
];
h_x
(
nlocal
,
1
)
=
buf
[
m
++
];
h_x
(
nlocal
,
2
)
=
buf
[
m
++
];
h_tag
(
nlocal
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_type
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_mask
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_image
(
nlocal
)
=
(
imageint
)
ubuf
(
buf
[
m
++
]).
i
;
h_v
(
nlocal
,
0
)
=
buf
[
m
++
];
h_v
(
nlocal
,
1
)
=
buf
[
m
++
];
h_v
(
nlocal
,
2
)
=
buf
[
m
++
];
h_q
(
nlocal
)
=
buf
[
m
++
];
h_molecule
(
nlocal
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_num_bond
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
for
(
k
=
0
;
k
<
h_num_bond
(
nlocal
);
k
++
)
{
h_bond_type
(
nlocal
,
k
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_bond_atom
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
}
h_num_angle
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
for
(
k
=
0
;
k
<
h_num_angle
(
nlocal
);
k
++
)
{
h_angle_type
(
nlocal
,
k
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_angle_atom1
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_angle_atom2
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_angle_atom3
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
}
h_num_dihedral
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
for
(
k
=
0
;
k
<
h_num_dihedral
(
nlocal
);
k
++
)
{
h_dihedral_type
(
nlocal
,
k
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_dihedral_atom1
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_dihedral_atom2
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_dihedral_atom3
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_dihedral_atom4
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
}
h_num_improper
(
nlocal
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
for
(
k
=
0
;
k
<
h_num_improper
(
nlocal
);
k
++
)
{
h_improper_type
(
nlocal
,
k
)
=
(
int
)
ubuf
(
buf
[
m
++
]).
i
;
h_improper_atom1
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_improper_atom2
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_improper_atom3
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
h_improper_atom4
(
nlocal
,
k
)
=
(
tagint
)
ubuf
(
buf
[
m
++
]).
i
;
}
h_nspecial
(
nlocal
,
0
)
=
h_nspecial
(
nlocal
,
1
)
=
h_nspecial
(
nlocal
,
2
)
=
0
;
double
**
extra
=
atom
->
extra
;
if
(
atom
->
nextra_store
)
{
int
size
=
static_cast
<
int
>
(
ubuf
(
buf
[
m
++
]).
i
)
-
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
------------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
create_atom
(
int
itype
,
double
*
coord
)
{
int
nlocal
=
atom
->
nlocal
;
if
(
nlocal
==
nmax
)
{
atomKK
->
modified
(
Host
,
ALL_MASK
);
grow
(
0
);
}
atomKK
->
modified
(
Host
,
ALL_MASK
);
tag
[
nlocal
]
=
0
;
type
[
nlocal
]
=
itype
;
h_x
(
nlocal
,
0
)
=
coord
[
0
];
h_x
(
nlocal
,
1
)
=
coord
[
1
];
h_x
(
nlocal
,
2
)
=
coord
[
2
];
h_mask
(
nlocal
)
=
1
;
h_image
(
nlocal
)
=
((
imageint
)
IMGMAX
<<
IMG2BITS
)
|
((
imageint
)
IMGMAX
<<
IMGBITS
)
|
IMGMAX
;
h_v
(
nlocal
,
0
)
=
0.0
;
h_v
(
nlocal
,
1
)
=
0.0
;
h_v
(
nlocal
,
2
)
=
0.0
;
h_q
(
nlocal
)
=
0.0
;
h_molecule
(
nlocal
)
=
0
;
h_num_bond
(
nlocal
)
=
0
;
h_num_angle
(
nlocal
)
=
0
;
h_num_dihedral
(
nlocal
)
=
0
;
h_num_improper
(
nlocal
)
=
0
;
h_nspecial
(
nlocal
,
0
)
=
h_nspecial
(
nlocal
,
1
)
=
h_nspecial
(
nlocal
,
2
)
=
0
;
atom
->
nlocal
++
;
}
/* ----------------------------------------------------------------------
unpack one line from Atoms section of data file
initialize other atom quantities
------------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
data_atom
(
double
*
coord
,
imageint
imagetmp
,
char
**
values
)
{
int
nlocal
=
atom
->
nlocal
;
if
(
nlocal
==
nmax
)
grow
(
0
);
atomKK
->
modified
(
Host
,
ALL_MASK
);
h_tag
(
nlocal
)
=
atoi
(
values
[
0
]);
h_molecule
(
nlocal
)
=
atoi
(
values
[
1
]);
h_type
(
nlocal
)
=
atoi
(
values
[
2
]);
if
(
h_type
(
nlocal
)
<=
0
||
h_type
(
nlocal
)
>
atom
->
ntypes
)
error
->
one
(
FLERR
,
"Invalid atom type in Atoms section of data file"
);
h_q
(
nlocal
)
=
atof
(
values
[
3
]);
h_x
(
nlocal
,
0
)
=
coord
[
0
];
h_x
(
nlocal
,
1
)
=
coord
[
1
];
h_x
(
nlocal
,
2
)
=
coord
[
2
];
h_image
(
nlocal
)
=
imagetmp
;
h_mask
(
nlocal
)
=
1
;
h_v
(
nlocal
,
0
)
=
0.0
;
h_v
(
nlocal
,
1
)
=
0.0
;
h_v
(
nlocal
,
2
)
=
0.0
;
h_num_bond
(
nlocal
)
=
0
;
h_num_angle
(
nlocal
)
=
0
;
h_num_dihedral
(
nlocal
)
=
0
;
h_num_improper
(
nlocal
)
=
0
;
atom
->
nlocal
++
;
}
/* ----------------------------------------------------------------------
unpack hybrid quantities from one line in Atoms section of data file
initialize other atom quantities for this sub-style
------------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
data_atom_hybrid
(
int
nlocal
,
char
**
values
)
{
h_molecule
(
nlocal
)
=
atoi
(
values
[
0
]);
h_q
(
nlocal
)
=
atof
(
values
[
1
]);
h_num_bond
(
nlocal
)
=
0
;
h_num_angle
(
nlocal
)
=
0
;
h_num_dihedral
(
nlocal
)
=
0
;
h_num_improper
(
nlocal
)
=
0
;
return
2
;
}
/* ----------------------------------------------------------------------
pack atom info for data file including 3 image flags
------------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
pack_data
(
double
**
buf
)
{
int
nlocal
=
atom
->
nlocal
;
for
(
int
i
=
0
;
i
<
nlocal
;
i
++
)
{
buf
[
i
][
0
]
=
h_tag
(
i
);
buf
[
i
][
1
]
=
h_molecule
(
i
);
buf
[
i
][
2
]
=
h_type
(
i
);
buf
[
i
][
3
]
=
h_q
(
i
);
buf
[
i
][
4
]
=
h_x
(
i
,
0
);
buf
[
i
][
5
]
=
h_x
(
i
,
1
);
buf
[
i
][
6
]
=
h_x
(
i
,
2
);
buf
[
i
][
7
]
=
(
h_image
[
i
]
&
IMGMASK
)
-
IMGMAX
;
buf
[
i
][
8
]
=
(
h_image
[
i
]
>>
IMGBITS
&
IMGMASK
)
-
IMGMAX
;
buf
[
i
][
9
]
=
(
h_image
[
i
]
>>
IMG2BITS
)
-
IMGMAX
;
}
}
/* ----------------------------------------------------------------------
pack hybrid atom info for data file
------------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
pack_data_hybrid
(
int
i
,
double
*
buf
)
{
buf
[
0
]
=
h_molecule
(
i
);
buf
[
1
]
=
h_q
(
i
);
return
2
;
}
/* ----------------------------------------------------------------------
write atom info to data file including 3 image flags
------------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
write_data
(
FILE
*
fp
,
int
n
,
double
**
buf
)
{
for
(
int
i
=
0
;
i
<
n
;
i
++
)
fprintf
(
fp
,
"%d %d %d %-1.16e %-1.16e %-1.16e %-1.16e %d %d %d
\n
"
,
(
int
)
buf
[
i
][
0
],(
int
)
buf
[
i
][
1
],
(
int
)
buf
[
i
][
2
],
buf
[
i
][
3
],
buf
[
i
][
4
],
buf
[
i
][
5
],
buf
[
i
][
6
],
(
int
)
buf
[
i
][
7
],(
int
)
buf
[
i
][
8
],(
int
)
buf
[
i
][
9
]);
}
/* ----------------------------------------------------------------------
write hybrid atom info to data file
------------------------------------------------------------------------- */
int
AtomVecFullKokkos
::
write_data_hybrid
(
FILE
*
fp
,
double
*
buf
)
{
fprintf
(
fp
,
" "
TAGINT_FORMAT
" %-1.16e"
,(
tagint
)
ubuf
(
buf
[
0
]).
i
,
buf
[
1
]);
return
2
;
}
/* ----------------------------------------------------------------------
return # of bytes of allocated memory
------------------------------------------------------------------------- */
bigint
AtomVecFullKokkos
::
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
*
commKK
->
nthreads
,
3
);
if
(
atom
->
memcheck
(
"q"
))
bytes
+=
memory
->
usage
(
q
,
nmax
);
if
(
atom
->
memcheck
(
"molecule"
))
bytes
+=
memory
->
usage
(
molecule
,
nmax
);
if
(
atom
->
memcheck
(
"nspecial"
))
bytes
+=
memory
->
usage
(
nspecial
,
nmax
,
3
);
if
(
atom
->
memcheck
(
"special"
))
bytes
+=
memory
->
usage
(
special
,
nmax
,
atom
->
maxspecial
);
if
(
atom
->
memcheck
(
"num_bond"
))
bytes
+=
memory
->
usage
(
num_bond
,
nmax
);
if
(
atom
->
memcheck
(
"bond_type"
))
bytes
+=
memory
->
usage
(
bond_type
,
nmax
,
atom
->
bond_per_atom
);
if
(
atom
->
memcheck
(
"bond_atom"
))
bytes
+=
memory
->
usage
(
bond_atom
,
nmax
,
atom
->
bond_per_atom
);
if
(
atom
->
memcheck
(
"num_angle"
))
bytes
+=
memory
->
usage
(
num_angle
,
nmax
);
if
(
atom
->
memcheck
(
"angle_type"
))
bytes
+=
memory
->
usage
(
angle_type
,
nmax
,
atom
->
angle_per_atom
);
if
(
atom
->
memcheck
(
"angle_atom1"
))
bytes
+=
memory
->
usage
(
angle_atom1
,
nmax
,
atom
->
angle_per_atom
);
if
(
atom
->
memcheck
(
"angle_atom2"
))
bytes
+=
memory
->
usage
(
angle_atom2
,
nmax
,
atom
->
angle_per_atom
);
if
(
atom
->
memcheck
(
"angle_atom3"
))
bytes
+=
memory
->
usage
(
angle_atom3
,
nmax
,
atom
->
angle_per_atom
);
if
(
atom
->
memcheck
(
"num_dihedral"
))
bytes
+=
memory
->
usage
(
num_dihedral
,
nmax
);
if
(
atom
->
memcheck
(
"dihedral_type"
))
bytes
+=
memory
->
usage
(
dihedral_type
,
nmax
,
atom
->
dihedral_per_atom
);
if
(
atom
->
memcheck
(
"dihedral_atom1"
))
bytes
+=
memory
->
usage
(
dihedral_atom1
,
nmax
,
atom
->
dihedral_per_atom
);
if
(
atom
->
memcheck
(
"dihedral_atom2"
))
bytes
+=
memory
->
usage
(
dihedral_atom2
,
nmax
,
atom
->
dihedral_per_atom
);
if
(
atom
->
memcheck
(
"dihedral_atom3"
))
bytes
+=
memory
->
usage
(
dihedral_atom3
,
nmax
,
atom
->
dihedral_per_atom
);
if
(
atom
->
memcheck
(
"dihedral_atom4"
))
bytes
+=
memory
->
usage
(
dihedral_atom4
,
nmax
,
atom
->
dihedral_per_atom
);
if
(
atom
->
memcheck
(
"num_improper"
))
bytes
+=
memory
->
usage
(
num_improper
,
nmax
);
if
(
atom
->
memcheck
(
"improper_type"
))
bytes
+=
memory
->
usage
(
improper_type
,
nmax
,
atom
->
improper_per_atom
);
if
(
atom
->
memcheck
(
"improper_atom1"
))
bytes
+=
memory
->
usage
(
improper_atom1
,
nmax
,
atom
->
improper_per_atom
);
if
(
atom
->
memcheck
(
"improper_atom2"
))
bytes
+=
memory
->
usage
(
improper_atom2
,
nmax
,
atom
->
improper_per_atom
);
if
(
atom
->
memcheck
(
"improper_atom3"
))
bytes
+=
memory
->
usage
(
improper_atom3
,
nmax
,
atom
->
improper_per_atom
);
if
(
atom
->
memcheck
(
"improper_atom4"
))
bytes
+=
memory
->
usage
(
improper_atom4
,
nmax
,
atom
->
improper_per_atom
);
return
bytes
;
}
/* ---------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
sync
(
ExecutionSpace
space
,
unsigned
int
mask
)
{
if
(
space
==
Device
)
{
if
(
mask
&
X_MASK
)
atomKK
->
k_x
.
sync
<
LMPDeviceType
>
();
if
(
mask
&
V_MASK
)
atomKK
->
k_v
.
sync
<
LMPDeviceType
>
();
if
(
mask
&
F_MASK
)
atomKK
->
k_f
.
sync
<
LMPDeviceType
>
();
if
(
mask
&
TAG_MASK
)
atomKK
->
k_tag
.
sync
<
LMPDeviceType
>
();
if
(
mask
&
TYPE_MASK
)
atomKK
->
k_type
.
sync
<
LMPDeviceType
>
();
if
(
mask
&
MASK_MASK
)
atomKK
->
k_mask
.
sync
<
LMPDeviceType
>
();
if
(
mask
&
IMAGE_MASK
)
atomKK
->
k_image
.
sync
<
LMPDeviceType
>
();
if
(
mask
&
Q_MASK
)
atomKK
->
k_q
.
sync
<
LMPDeviceType
>
();
if
(
mask
&
MOLECULE_MASK
)
atomKK
->
k_molecule
.
sync
<
LMPDeviceType
>
();
if
(
mask
&
SPECIAL_MASK
)
{
atomKK
->
k_nspecial
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_special
.
sync
<
LMPDeviceType
>
();
}
if
(
mask
&
BOND_MASK
)
{
atomKK
->
k_num_bond
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_bond_type
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_bond_atom
.
sync
<
LMPDeviceType
>
();
}
if
(
mask
&
ANGLE_MASK
)
{
atomKK
->
k_num_angle
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_angle_type
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_angle_atom1
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_angle_atom2
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_angle_atom3
.
sync
<
LMPDeviceType
>
();
}
if
(
mask
&
DIHEDRAL_MASK
)
{
atomKK
->
k_num_dihedral
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_dihedral_type
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_dihedral_atom1
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_dihedral_atom2
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_dihedral_atom3
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_dihedral_atom4
.
sync
<
LMPDeviceType
>
();
}
if
(
mask
&
IMPROPER_MASK
)
{
atomKK
->
k_num_improper
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_improper_type
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_improper_atom1
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_improper_atom2
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_improper_atom3
.
sync
<
LMPDeviceType
>
();
atomKK
->
k_improper_atom4
.
sync
<
LMPDeviceType
>
();
}
}
else
{
if
(
mask
&
X_MASK
)
atomKK
->
k_x
.
sync
<
LMPHostType
>
();
if
(
mask
&
V_MASK
)
atomKK
->
k_v
.
sync
<
LMPHostType
>
();
if
(
mask
&
F_MASK
)
atomKK
->
k_f
.
sync
<
LMPHostType
>
();
if
(
mask
&
TAG_MASK
)
atomKK
->
k_tag
.
sync
<
LMPHostType
>
();
if
(
mask
&
TYPE_MASK
)
atomKK
->
k_type
.
sync
<
LMPHostType
>
();
if
(
mask
&
MASK_MASK
)
atomKK
->
k_mask
.
sync
<
LMPHostType
>
();
if
(
mask
&
IMAGE_MASK
)
atomKK
->
k_image
.
sync
<
LMPHostType
>
();
if
(
mask
&
Q_MASK
)
atomKK
->
k_q
.
sync
<
LMPHostType
>
();
if
(
mask
&
MOLECULE_MASK
)
atomKK
->
k_molecule
.
sync
<
LMPHostType
>
();
if
(
mask
&
SPECIAL_MASK
)
{
atomKK
->
k_nspecial
.
sync
<
LMPHostType
>
();
atomKK
->
k_special
.
sync
<
LMPHostType
>
();
}
if
(
mask
&
BOND_MASK
)
{
atomKK
->
k_num_bond
.
sync
<
LMPHostType
>
();
atomKK
->
k_bond_type
.
sync
<
LMPHostType
>
();
atomKK
->
k_bond_atom
.
sync
<
LMPHostType
>
();
}
if
(
mask
&
ANGLE_MASK
)
{
atomKK
->
k_num_angle
.
sync
<
LMPHostType
>
();
atomKK
->
k_angle_type
.
sync
<
LMPHostType
>
();
atomKK
->
k_angle_atom1
.
sync
<
LMPHostType
>
();
atomKK
->
k_angle_atom2
.
sync
<
LMPHostType
>
();
atomKK
->
k_angle_atom3
.
sync
<
LMPHostType
>
();
}
if
(
mask
&
DIHEDRAL_MASK
)
{
atomKK
->
k_num_dihedral
.
sync
<
LMPHostType
>
();
atomKK
->
k_dihedral_type
.
sync
<
LMPHostType
>
();
atomKK
->
k_dihedral_atom1
.
sync
<
LMPHostType
>
();
atomKK
->
k_dihedral_atom2
.
sync
<
LMPHostType
>
();
atomKK
->
k_dihedral_atom3
.
sync
<
LMPHostType
>
();
atomKK
->
k_dihedral_atom4
.
sync
<
LMPHostType
>
();
}
if
(
mask
&
IMPROPER_MASK
)
{
atomKK
->
k_num_improper
.
sync
<
LMPHostType
>
();
atomKK
->
k_improper_type
.
sync
<
LMPHostType
>
();
atomKK
->
k_improper_atom1
.
sync
<
LMPHostType
>
();
atomKK
->
k_improper_atom2
.
sync
<
LMPHostType
>
();
atomKK
->
k_improper_atom3
.
sync
<
LMPHostType
>
();
atomKK
->
k_improper_atom4
.
sync
<
LMPHostType
>
();
}
}
}
/* ---------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
sync_overlapping_device
(
ExecutionSpace
space
,
unsigned
int
mask
)
{
if
(
space
==
Device
)
{
if
((
mask
&
X_MASK
)
&&
atomKK
->
k_x
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_x_array
>
(
atomKK
->
k_x
,
space
);
if
((
mask
&
V_MASK
)
&&
atomKK
->
k_v
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_v_array
>
(
atomKK
->
k_v
,
space
);
if
((
mask
&
F_MASK
)
&&
atomKK
->
k_f
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_f_array
>
(
atomKK
->
k_f
,
space
);
if
((
mask
&
TAG_MASK
)
&&
atomKK
->
k_tag
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_1d
>
(
atomKK
->
k_tag
,
space
);
if
((
mask
&
TYPE_MASK
)
&&
atomKK
->
k_type
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_type
,
space
);
if
((
mask
&
MASK_MASK
)
&&
atomKK
->
k_mask
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_mask
,
space
);
if
((
mask
&
IMAGE_MASK
)
&&
atomKK
->
k_image
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_imageint_1d
>
(
atomKK
->
k_image
,
space
);
if
((
mask
&
Q_MASK
)
&&
atomKK
->
k_q
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_float_1d
>
(
atomKK
->
k_q
,
space
);
if
((
mask
&
MOLECULE_MASK
)
&&
atomKK
->
k_molecule
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_1d
>
(
atomKK
->
k_molecule
,
space
);
if
(
mask
&
SPECIAL_MASK
)
{
if
(
atomKK
->
k_nspecial
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_int_2d
>
(
atomKK
->
k_nspecial
,
space
);
if
(
atomKK
->
k_special
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_special
,
space
);
}
if
(
mask
&
BOND_MASK
)
{
if
(
atomKK
->
k_num_bond
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_num_bond
,
space
);
if
(
atomKK
->
k_bond_type
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_int_2d
>
(
atomKK
->
k_bond_type
,
space
);
if
(
atomKK
->
k_bond_atom
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_bond_atom
,
space
);
}
if
(
mask
&
ANGLE_MASK
)
{
if
(
atomKK
->
k_num_angle
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_num_angle
,
space
);
if
(
atomKK
->
k_angle_type
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_int_2d
>
(
atomKK
->
k_angle_type
,
space
);
if
(
atomKK
->
k_angle_atom1
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_angle_atom1
,
space
);
if
(
atomKK
->
k_angle_atom2
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_angle_atom2
,
space
);
if
(
atomKK
->
k_angle_atom3
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_angle_atom3
,
space
);
}
if
(
mask
&
DIHEDRAL_MASK
)
{
if
(
atomKK
->
k_num_dihedral
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_num_dihedral
,
space
);
if
(
atomKK
->
k_dihedral_type
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_int_2d
>
(
atomKK
->
k_dihedral_type
,
space
);
if
(
atomKK
->
k_dihedral_atom1
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_dihedral_atom1
,
space
);
if
(
atomKK
->
k_dihedral_atom2
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_dihedral_atom2
,
space
);
if
(
atomKK
->
k_dihedral_atom3
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_dihedral_atom3
,
space
);
}
if
(
mask
&
IMPROPER_MASK
)
{
if
(
atomKK
->
k_num_improper
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_num_improper
,
space
);
if
(
atomKK
->
k_improper_type
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_int_2d
>
(
atomKK
->
k_improper_type
,
space
);
if
(
atomKK
->
k_improper_atom1
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_improper_atom1
,
space
);
if
(
atomKK
->
k_improper_atom2
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_improper_atom2
,
space
);
if
(
atomKK
->
k_improper_atom3
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_improper_atom3
,
space
);
if
(
atomKK
->
k_improper_atom4
.
need_sync
<
LMPDeviceType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_improper_atom4
,
space
);
}
}
else
{
if
((
mask
&
X_MASK
)
&&
atomKK
->
k_x
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_x_array
>
(
atomKK
->
k_x
,
space
);
if
((
mask
&
V_MASK
)
&&
atomKK
->
k_v
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_v_array
>
(
atomKK
->
k_v
,
space
);
if
((
mask
&
F_MASK
)
&&
atomKK
->
k_f
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_f_array
>
(
atomKK
->
k_f
,
space
);
if
((
mask
&
TAG_MASK
)
&&
atomKK
->
k_tag
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_1d
>
(
atomKK
->
k_tag
,
space
);
if
((
mask
&
TYPE_MASK
)
&&
atomKK
->
k_type
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_type
,
space
);
if
((
mask
&
MASK_MASK
)
&&
atomKK
->
k_mask
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_mask
,
space
);
if
((
mask
&
IMAGE_MASK
)
&&
atomKK
->
k_image
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_imageint_1d
>
(
atomKK
->
k_image
,
space
);
if
((
mask
&
Q_MASK
)
&&
atomKK
->
k_q
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_float_1d
>
(
atomKK
->
k_q
,
space
);
if
((
mask
&
MOLECULE_MASK
)
&&
atomKK
->
k_molecule
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_1d
>
(
atomKK
->
k_molecule
,
space
);
if
(
mask
&
SPECIAL_MASK
)
{
if
(
atomKK
->
k_nspecial
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_int_2d
>
(
atomKK
->
k_nspecial
,
space
);
if
(
atomKK
->
k_special
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_special
,
space
);
}
if
(
mask
&
BOND_MASK
)
{
if
(
atomKK
->
k_num_bond
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_num_bond
,
space
);
if
(
atomKK
->
k_bond_type
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_int_2d
>
(
atomKK
->
k_bond_type
,
space
);
if
(
atomKK
->
k_bond_atom
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_bond_atom
,
space
);
}
if
(
mask
&
ANGLE_MASK
)
{
if
(
atomKK
->
k_num_angle
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_num_angle
,
space
);
if
(
atomKK
->
k_angle_type
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_int_2d
>
(
atomKK
->
k_angle_type
,
space
);
if
(
atomKK
->
k_angle_atom1
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_angle_atom1
,
space
);
if
(
atomKK
->
k_angle_atom2
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_angle_atom2
,
space
);
if
(
atomKK
->
k_angle_atom3
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_angle_atom3
,
space
);
}
if
(
mask
&
DIHEDRAL_MASK
)
{
if
(
atomKK
->
k_num_dihedral
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_num_dihedral
,
space
);
if
(
atomKK
->
k_dihedral_type
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_int_2d
>
(
atomKK
->
k_dihedral_type
,
space
);
if
(
atomKK
->
k_dihedral_atom1
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_dihedral_atom1
,
space
);
if
(
atomKK
->
k_dihedral_atom2
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_dihedral_atom2
,
space
);
if
(
atomKK
->
k_dihedral_atom3
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_dihedral_atom3
,
space
);
if
(
atomKK
->
k_dihedral_atom4
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_dihedral_atom4
,
space
);
}
if
(
mask
&
IMPROPER_MASK
)
{
if
(
atomKK
->
k_num_improper
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_int_1d
>
(
atomKK
->
k_num_improper
,
space
);
if
(
atomKK
->
k_improper_type
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_int_2d
>
(
atomKK
->
k_improper_type
,
space
);
if
(
atomKK
->
k_improper_atom1
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_improper_atom1
,
space
);
if
(
atomKK
->
k_improper_atom2
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_improper_atom2
,
space
);
if
(
atomKK
->
k_improper_atom3
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_improper_atom3
,
space
);
if
(
atomKK
->
k_improper_atom4
.
need_sync
<
LMPHostType
>
())
perform_async_copy
<
DAT
::
tdual_tagint_2d
>
(
atomKK
->
k_improper_atom4
,
space
);
}
}
}
/* ---------------------------------------------------------------------- */
void
AtomVecFullKokkos
::
modified
(
ExecutionSpace
space
,
unsigned
int
mask
)
{
if
(
space
==
Device
)
{
if
(
mask
&
X_MASK
)
atomKK
->
k_x
.
modify
<
LMPDeviceType
>
();
if
(
mask
&
V_MASK
)
atomKK
->
k_v
.
modify
<
LMPDeviceType
>
();
if
(
mask
&
F_MASK
)
atomKK
->
k_f
.
modify
<
LMPDeviceType
>
();
if
(
mask
&
TAG_MASK
)
atomKK
->
k_tag
.
modify
<
LMPDeviceType
>
();
if
(
mask
&
TYPE_MASK
)
atomKK
->
k_type
.
modify
<
LMPDeviceType
>
();
if
(
mask
&
MASK_MASK
)
atomKK
->
k_mask
.
modify
<
LMPDeviceType
>
();
if
(
mask
&
IMAGE_MASK
)
atomKK
->
k_image
.
modify
<
LMPDeviceType
>
();
if
(
mask
&
Q_MASK
)
atomKK
->
k_q
.
modify
<
LMPDeviceType
>
();
if
(
mask
&
MOLECULE_MASK
)
atomKK
->
k_molecule
.
modify
<
LMPDeviceType
>
();
if
(
mask
&
SPECIAL_MASK
)
{
atomKK
->
k_nspecial
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_special
.
modify
<
LMPDeviceType
>
();
}
if
(
mask
&
BOND_MASK
)
{
atomKK
->
k_num_bond
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_bond_type
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_bond_atom
.
modify
<
LMPDeviceType
>
();
}
if
(
mask
&
ANGLE_MASK
)
{
atomKK
->
k_num_angle
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_angle_type
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_angle_atom1
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_angle_atom2
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_angle_atom3
.
modify
<
LMPDeviceType
>
();
}
if
(
mask
&
DIHEDRAL_MASK
)
{
atomKK
->
k_num_dihedral
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_dihedral_type
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_dihedral_atom1
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_dihedral_atom2
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_dihedral_atom3
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_dihedral_atom4
.
modify
<
LMPDeviceType
>
();
}
if
(
mask
&
IMPROPER_MASK
)
{
atomKK
->
k_num_improper
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_improper_type
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_improper_atom1
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_improper_atom2
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_improper_atom3
.
modify
<
LMPDeviceType
>
();
atomKK
->
k_improper_atom4
.
modify
<
LMPDeviceType
>
();
}
}
else
{
if
(
mask
&
X_MASK
)
atomKK
->
k_x
.
modify
<
LMPHostType
>
();
if
(
mask
&
V_MASK
)
atomKK
->
k_v
.
modify
<
LMPHostType
>
();
if
(
mask
&
F_MASK
)
atomKK
->
k_f
.
modify
<
LMPHostType
>
();
if
(
mask
&
TAG_MASK
)
atomKK
->
k_tag
.
modify
<
LMPHostType
>
();
if
(
mask
&
TYPE_MASK
)
atomKK
->
k_type
.
modify
<
LMPHostType
>
();
if
(
mask
&
MASK_MASK
)
atomKK
->
k_mask
.
modify
<
LMPHostType
>
();
if
(
mask
&
IMAGE_MASK
)
atomKK
->
k_image
.
modify
<
LMPHostType
>
();
if
(
mask
&
Q_MASK
)
atomKK
->
k_q
.
modify
<
LMPHostType
>
();
if
(
mask
&
MOLECULE_MASK
)
atomKK
->
k_molecule
.
modify
<
LMPHostType
>
();
if
(
mask
&
SPECIAL_MASK
)
{
atomKK
->
k_nspecial
.
modify
<
LMPHostType
>
();
atomKK
->
k_special
.
modify
<
LMPHostType
>
();
}
if
(
mask
&
BOND_MASK
)
{
atomKK
->
k_num_bond
.
modify
<
LMPHostType
>
();
atomKK
->
k_bond_type
.
modify
<
LMPHostType
>
();
atomKK
->
k_bond_atom
.
modify
<
LMPHostType
>
();
}
if
(
mask
&
ANGLE_MASK
)
{
atomKK
->
k_num_angle
.
modify
<
LMPHostType
>
();
atomKK
->
k_angle_type
.
modify
<
LMPHostType
>
();
atomKK
->
k_angle_atom1
.
modify
<
LMPHostType
>
();
atomKK
->
k_angle_atom2
.
modify
<
LMPHostType
>
();
atomKK
->
k_angle_atom3
.
modify
<
LMPHostType
>
();
}
if
(
mask
&
DIHEDRAL_MASK
)
{
atomKK
->
k_num_dihedral
.
modify
<
LMPHostType
>
();
atomKK
->
k_dihedral_type
.
modify
<
LMPHostType
>
();
atomKK
->
k_dihedral_atom1
.
modify
<
LMPHostType
>
();
atomKK
->
k_dihedral_atom2
.
modify
<
LMPHostType
>
();
atomKK
->
k_dihedral_atom3
.
modify
<
LMPHostType
>
();
atomKK
->
k_dihedral_atom4
.
modify
<
LMPHostType
>
();
}
if
(
mask
&
IMPROPER_MASK
)
{
atomKK
->
k_num_improper
.
modify
<
LMPHostType
>
();
atomKK
->
k_improper_type
.
modify
<
LMPHostType
>
();
atomKK
->
k_improper_atom1
.
modify
<
LMPHostType
>
();
atomKK
->
k_improper_atom2
.
modify
<
LMPHostType
>
();
atomKK
->
k_improper_atom3
.
modify
<
LMPHostType
>
();
atomKK
->
k_improper_atom4
.
modify
<
LMPHostType
>
();
}
}
}
Event Timeline
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