Page Menu
Home
c4science
Search
Configure Global Search
Log In
Files
F91005287
pair_eam_alloy_kokkos.cpp
No One
Temporary
Actions
Download File
Edit File
Delete File
View Transforms
Subscribe
Mute Notifications
Award Token
Subscribers
None
File Metadata
Details
File Info
Storage
Attached
Created
Wed, Nov 6, 20:47
Size
37 KB
Mime Type
text/x-c
Expires
Fri, Nov 8, 20:47 (2 d)
Engine
blob
Format
Raw Data
Handle
22178056
Attached To
rLAMMPS lammps
pair_eam_alloy_kokkos.cpp
View Options
/* ----------------------------------------------------------------------
LAMMPS - Large-scale Atomic/Molecular Massively Parallel Simulator
http://lammps.sandia.gov, Sandia National Laboratories
Steve Plimpton, sjplimp@sandia.gov
Copyright (2003) Sandia Corporation. Under the terms of Contract
DE-AC04-94AL85000 with Sandia Corporation, the U.S. Government retains
certain rights in this software. This software is distributed under
the GNU General Public License.
See the README file in the top-level LAMMPS directory.
------------------------------------------------------------------------- */
/* ----------------------------------------------------------------------
Contributing authors: Stan Moore (SNL)
------------------------------------------------------------------------- */
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "kokkos.h"
#include "pair_kokkos.h"
#include "pair_eam_alloy_kokkos.h"
#include "atom_kokkos.h"
#include "force.h"
#include "comm.h"
#include "neighbor.h"
#include "neigh_list_kokkos.h"
#include "neigh_request.h"
#include "memory.h"
#include "error.h"
#include "atom_masks.h"
using
namespace
LAMMPS_NS
;
#define MAXLINE 1024
// Cannot use virtual inheritance on the GPU, so must duplicate code
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
PairEAMAlloyKokkos
<
DeviceType
>::
PairEAMAlloyKokkos
(
LAMMPS
*
lmp
)
:
PairEAM
(
lmp
)
{
respa_enable
=
0
;
one_coeff
=
1
;
manybody_flag
=
1
;
atomKK
=
(
AtomKokkos
*
)
atom
;
execution_space
=
ExecutionSpaceFromDevice
<
DeviceType
>::
space
;
datamask_read
=
X_MASK
|
F_MASK
|
TYPE_MASK
|
ENERGY_MASK
|
VIRIAL_MASK
;
datamask_modify
=
F_MASK
|
ENERGY_MASK
|
VIRIAL_MASK
;
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
PairEAMAlloyKokkos
<
DeviceType
>::~
PairEAMAlloyKokkos
()
{
if
(
!
copymode
)
{
memory
->
destroy_kokkos
(
k_eatom
,
eatom
);
memory
->
destroy_kokkos
(
k_vatom
,
vatom
);
}
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
void
PairEAMAlloyKokkos
<
DeviceType
>::
compute
(
int
eflag_in
,
int
vflag_in
)
{
eflag
=
eflag_in
;
vflag
=
vflag_in
;
if
(
neighflag
==
FULL
)
no_virial_fdotr_compute
=
1
;
if
(
eflag
||
vflag
)
ev_setup
(
eflag
,
vflag
);
else
evflag
=
vflag_fdotr
=
0
;
// reallocate per-atom arrays if necessary
if
(
eflag_atom
)
{
memory
->
destroy_kokkos
(
k_eatom
,
eatom
);
memory
->
create_kokkos
(
k_eatom
,
eatom
,
maxeatom
,
"pair:eatom"
);
d_eatom
=
k_eatom
.
d_view
;
}
if
(
vflag_atom
)
{
memory
->
destroy_kokkos
(
k_vatom
,
vatom
);
memory
->
create_kokkos
(
k_vatom
,
vatom
,
maxvatom
,
6
,
"pair:vatom"
);
d_vatom
=
k_vatom
.
d_view
;
}
atomKK
->
sync
(
execution_space
,
datamask_read
);
if
(
eflag
||
vflag
)
atomKK
->
modified
(
execution_space
,
datamask_modify
);
else
atomKK
->
modified
(
execution_space
,
F_MASK
);
// grow energy and fp arrays if necessary
// need to be atom->nmax in length
if
(
atom
->
nmax
>
nmax
)
{
nmax
=
atom
->
nmax
;
k_rho
=
DAT
::
tdual_ffloat_1d
(
"pair:rho"
,
nmax
);
k_fp
=
DAT
::
tdual_ffloat_1d
(
"pair:fp"
,
nmax
);
d_rho
=
k_rho
.
d_view
;
d_fp
=
k_fp
.
d_view
;
h_rho
=
k_rho
.
h_view
;
h_fp
=
k_fp
.
h_view
;
}
x
=
atomKK
->
k_x
.
view
<
DeviceType
>
();
f
=
atomKK
->
k_f
.
view
<
DeviceType
>
();
v_rho
=
k_rho
.
view
<
DeviceType
>
();
type
=
atomKK
->
k_type
.
view
<
DeviceType
>
();
tag
=
atomKK
->
k_tag
.
view
<
DeviceType
>
();
nlocal
=
atom
->
nlocal
;
nall
=
atom
->
nlocal
+
atom
->
nghost
;
newton_pair
=
force
->
newton_pair
;
NeighListKokkos
<
DeviceType
>*
k_list
=
static_cast
<
NeighListKokkos
<
DeviceType
>*>
(
list
);
d_numneigh
=
k_list
->
d_numneigh
;
d_neighbors
=
k_list
->
d_neighbors
;
d_ilist
=
k_list
->
d_ilist
;
int
inum
=
list
->
inum
;
// Call cleanup_copy which sets allocations NULL which are destructed by the PairStyle
k_list
->
clean_copy
();
copymode
=
1
;
// zero out density
if
(
newton_pair
)
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyInitialize
>
(
0
,
nall
),
*
this
);
else
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyInitialize
>
(
0
,
nlocal
),
*
this
);
DeviceType
::
fence
();
// loop over neighbors of my atoms
EV_FLOAT
ev
;
// compute kernel A
if
(
neighflag
==
HALF
||
neighflag
==
HALFTHREAD
)
{
if
(
neighflag
==
HALF
)
{
if
(
newton_pair
)
{
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelA
<
HALF
,
1
>
>
(
0
,
inum
),
*
this
);
}
else
{
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelA
<
HALF
,
0
>
>
(
0
,
inum
),
*
this
);
}
}
else
if
(
neighflag
==
HALFTHREAD
)
{
if
(
newton_pair
)
{
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelA
<
HALFTHREAD
,
1
>
>
(
0
,
inum
),
*
this
);
}
else
{
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelA
<
HALFTHREAD
,
0
>
>
(
0
,
inum
),
*
this
);
}
}
DeviceType
::
fence
();
// communicate and sum densities (on the host)
if
(
newton_pair
)
{
k_rho
.
template
modify
<
DeviceType
>
();
k_rho
.
template
sync
<
LMPHostType
>
();
comm
->
reverse_comm_pair
(
this
);
k_rho
.
template
modify
<
LMPHostType
>
();
k_rho
.
template
sync
<
DeviceType
>
();
}
// compute kernel B
if
(
eflag
)
Kokkos
::
parallel_reduce
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelB
<
1
>
>
(
0
,
inum
),
*
this
,
ev
);
else
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelB
<
0
>
>
(
0
,
inum
),
*
this
);
DeviceType
::
fence
();
}
else
if
(
neighflag
==
FULL
)
{
// compute kernel AB
if
(
eflag
)
Kokkos
::
parallel_reduce
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelAB
<
1
>
>
(
0
,
inum
),
*
this
,
ev
);
else
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelAB
<
0
>
>
(
0
,
inum
),
*
this
);
DeviceType
::
fence
();
}
if
(
eflag
)
{
eng_vdwl
+=
ev
.
evdwl
;
ev
.
evdwl
=
0.0
;
}
// communicate derivative of embedding function (on the device)
comm
->
forward_comm_pair
(
this
);
// compute kernel C
if
(
evflag
)
{
if
(
neighflag
==
HALF
)
{
if
(
newton_pair
)
{
Kokkos
::
parallel_reduce
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
HALF
,
1
,
1
>
>
(
0
,
inum
),
*
this
,
ev
);
}
else
{
Kokkos
::
parallel_reduce
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
HALF
,
0
,
1
>
>
(
0
,
inum
),
*
this
,
ev
);
}
}
else
if
(
neighflag
==
HALFTHREAD
)
{
if
(
newton_pair
)
{
Kokkos
::
parallel_reduce
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
HALFTHREAD
,
1
,
1
>
>
(
0
,
inum
),
*
this
,
ev
);
}
else
{
Kokkos
::
parallel_reduce
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
HALFTHREAD
,
0
,
1
>
>
(
0
,
inum
),
*
this
,
ev
);
}
}
else
if
(
neighflag
==
FULL
)
{
if
(
newton_pair
)
{
Kokkos
::
parallel_reduce
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
FULL
,
1
,
1
>
>
(
0
,
inum
),
*
this
,
ev
);
}
else
{
Kokkos
::
parallel_reduce
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
FULL
,
0
,
1
>
>
(
0
,
inum
),
*
this
,
ev
);
}
}
}
else
{
if
(
neighflag
==
HALF
)
{
if
(
newton_pair
)
{
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
HALF
,
1
,
0
>
>
(
0
,
inum
),
*
this
);
}
else
{
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
HALF
,
0
,
0
>
>
(
0
,
inum
),
*
this
);
}
}
else
if
(
neighflag
==
HALFTHREAD
)
{
if
(
newton_pair
)
{
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
HALFTHREAD
,
1
,
0
>
>
(
0
,
inum
),
*
this
);
}
else
{
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
HALFTHREAD
,
0
,
0
>
>
(
0
,
inum
),
*
this
);
}
}
else
if
(
neighflag
==
FULL
)
{
if
(
newton_pair
)
{
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
FULL
,
1
,
0
>
>
(
0
,
inum
),
*
this
);
}
else
{
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
DeviceType
,
TagPairEAMAlloyKernelC
<
FULL
,
0
,
0
>
>
(
0
,
inum
),
*
this
);
}
}
}
DeviceType
::
fence
();
if
(
eflag_global
)
eng_vdwl
+=
ev
.
evdwl
;
if
(
vflag_global
)
{
virial
[
0
]
+=
ev
.
v
[
0
];
virial
[
1
]
+=
ev
.
v
[
1
];
virial
[
2
]
+=
ev
.
v
[
2
];
virial
[
3
]
+=
ev
.
v
[
3
];
virial
[
4
]
+=
ev
.
v
[
4
];
virial
[
5
]
+=
ev
.
v
[
5
];
}
if
(
vflag_fdotr
)
pair_virial_fdotr_compute
(
this
);
if
(
eflag_atom
)
{
k_eatom
.
template
modify
<
DeviceType
>
();
k_eatom
.
template
sync
<
LMPHostType
>
();
}
if
(
vflag_atom
)
{
k_vatom
.
template
modify
<
DeviceType
>
();
k_vatom
.
template
sync
<
LMPHostType
>
();
}
copymode
=
0
;
}
/* ----------------------------------------------------------------------
init specific to this pair style
------------------------------------------------------------------------- */
template
<
class
DeviceType
>
void
PairEAMAlloyKokkos
<
DeviceType
>::
init_style
()
{
// convert read-in file(s) to arrays and spline them
PairEAM
::
init_style
();
// irequest = neigh request made by parent class
neighflag
=
lmp
->
kokkos
->
neighflag
;
int
irequest
=
neighbor
->
nrequest
-
1
;
neighbor
->
requests
[
irequest
]
->
kokkos_host
=
Kokkos
::
Impl
::
is_same
<
DeviceType
,
LMPHostType
>::
value
&&
!
Kokkos
::
Impl
::
is_same
<
DeviceType
,
LMPDeviceType
>::
value
;
neighbor
->
requests
[
irequest
]
->
kokkos_device
=
Kokkos
::
Impl
::
is_same
<
DeviceType
,
LMPDeviceType
>::
value
;
if
(
neighflag
==
FULL
)
{
neighbor
->
requests
[
irequest
]
->
full
=
1
;
neighbor
->
requests
[
irequest
]
->
half
=
0
;
neighbor
->
requests
[
irequest
]
->
full_cluster
=
0
;
}
else
if
(
neighflag
==
HALF
||
neighflag
==
HALFTHREAD
)
{
neighbor
->
requests
[
irequest
]
->
full
=
0
;
neighbor
->
requests
[
irequest
]
->
half
=
1
;
neighbor
->
requests
[
irequest
]
->
full_cluster
=
0
;
}
else
{
error
->
all
(
FLERR
,
"Cannot use chosen neighbor list style with pair eam/kk/alloy"
);
}
}
template
<
class
DeviceType
>
void
PairEAMAlloyKokkos
<
DeviceType
>::
file2array
()
{
file2array_alloy
();
int
i
,
j
;
int
n
=
atom
->
ntypes
;
DAT
::
tdual_int_1d
k_type2frho
=
DAT
::
tdual_int_1d
(
"pair:type2frho"
,
n
+
1
);
DAT
::
tdual_int_2d
k_type2rhor
=
DAT
::
tdual_int_2d
(
"pair:type2rhor"
,
n
+
1
,
n
+
1
);
DAT
::
tdual_int_2d
k_type2z2r
=
DAT
::
tdual_int_2d
(
"pair:type2z2r"
,
n
+
1
,
n
+
1
);
HAT
::
t_int_1d
h_type2frho
=
k_type2frho
.
h_view
;
HAT
::
t_int_2d
h_type2rhor
=
k_type2rhor
.
h_view
;
HAT
::
t_int_2d
h_type2z2r
=
k_type2z2r
.
h_view
;
for
(
i
=
1
;
i
<=
n
;
i
++
)
{
h_type2frho
[
i
]
=
type2frho
[
i
];
for
(
j
=
1
;
j
<=
n
;
j
++
)
{
h_type2rhor
(
i
,
j
)
=
type2rhor
[
i
][
j
];
h_type2z2r
(
i
,
j
)
=
type2z2r
[
i
][
j
];
}
}
k_type2frho
.
template
modify
<
LMPHostType
>
();
k_type2frho
.
template
sync
<
DeviceType
>
();
k_type2rhor
.
template
modify
<
LMPHostType
>
();
k_type2rhor
.
template
sync
<
DeviceType
>
();
k_type2z2r
.
template
modify
<
LMPHostType
>
();
k_type2z2r
.
template
sync
<
DeviceType
>
();
d_type2frho
=
k_type2frho
.
d_view
;
d_type2rhor
=
k_type2rhor
.
d_view
;
d_type2z2r
=
k_type2z2r
.
d_view
;
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
void
PairEAMAlloyKokkos
<
DeviceType
>::
array2spline
()
{
rdr
=
1.0
/
dr
;
rdrho
=
1.0
/
drho
;
tdual_ffloat_2d_n7
k_frho_spline
=
tdual_ffloat_2d_n7
(
"pair:frho"
,
nfrho
,
nrho
+
1
);
tdual_ffloat_2d_n7
k_rhor_spline
=
tdual_ffloat_2d_n7
(
"pair:rhor"
,
nrhor
,
nr
+
1
);
tdual_ffloat_2d_n7
k_z2r_spline
=
tdual_ffloat_2d_n7
(
"pair:z2r"
,
nz2r
,
nr
+
1
);
t_host_ffloat_2d_n7
h_frho_spline
=
k_frho_spline
.
h_view
;
t_host_ffloat_2d_n7
h_rhor_spline
=
k_rhor_spline
.
h_view
;
t_host_ffloat_2d_n7
h_z2r_spline
=
k_z2r_spline
.
h_view
;
for
(
int
i
=
0
;
i
<
nfrho
;
i
++
)
interpolate
(
nrho
,
drho
,
frho
[
i
],
h_frho_spline
,
i
);
k_frho_spline
.
template
modify
<
LMPHostType
>
();
k_frho_spline
.
template
sync
<
DeviceType
>
();
for
(
int
i
=
0
;
i
<
nrhor
;
i
++
)
interpolate
(
nr
,
dr
,
rhor
[
i
],
h_rhor_spline
,
i
);
k_rhor_spline
.
template
modify
<
LMPHostType
>
();
k_rhor_spline
.
template
sync
<
DeviceType
>
();
for
(
int
i
=
0
;
i
<
nz2r
;
i
++
)
interpolate
(
nr
,
dr
,
z2r
[
i
],
h_z2r_spline
,
i
);
k_z2r_spline
.
template
modify
<
LMPHostType
>
();
k_z2r_spline
.
template
sync
<
DeviceType
>
();
d_frho_spline
=
k_frho_spline
.
d_view
;
d_rhor_spline
=
k_rhor_spline
.
d_view
;
d_z2r_spline
=
k_z2r_spline
.
d_view
;
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
void
PairEAMAlloyKokkos
<
DeviceType
>::
interpolate
(
int
n
,
double
delta
,
double
*
f
,
t_host_ffloat_2d_n7
h_spline
,
int
i
)
{
for
(
int
m
=
1
;
m
<=
n
;
m
++
)
h_spline
(
i
,
m
,
6
)
=
f
[
m
];
h_spline
(
i
,
1
,
5
)
=
h_spline
(
i
,
2
,
6
)
-
h_spline
(
i
,
1
,
6
);
h_spline
(
i
,
2
,
5
)
=
0.5
*
(
h_spline
(
i
,
3
,
6
)
-
h_spline
(
i
,
1
,
6
));
h_spline
(
i
,
n
-
1
,
5
)
=
0.5
*
(
h_spline
(
i
,
n
,
6
)
-
h_spline
(
i
,
n
-
2
,
6
));
h_spline
(
i
,
n
,
5
)
=
h_spline
(
i
,
n
,
6
)
-
h_spline
(
i
,
n
-
1
,
6
);
for
(
int
m
=
3
;
m
<=
n
-
2
;
m
++
)
h_spline
(
i
,
m
,
5
)
=
((
h_spline
(
i
,
m
-
2
,
6
)
-
h_spline
(
i
,
m
+
2
,
6
))
+
8.0
*
(
h_spline
(
i
,
m
+
1
,
6
)
-
h_spline
(
i
,
m
-
1
,
6
)))
/
12.0
;
for
(
int
m
=
1
;
m
<=
n
-
1
;
m
++
)
{
h_spline
(
i
,
m
,
4
)
=
3.0
*
(
h_spline
(
i
,
m
+
1
,
6
)
-
h_spline
(
i
,
m
,
6
))
-
2.0
*
h_spline
(
i
,
m
,
5
)
-
h_spline
(
i
,
m
+
1
,
5
);
h_spline
(
i
,
m
,
3
)
=
h_spline
(
i
,
m
,
5
)
+
h_spline
(
i
,
m
+
1
,
5
)
-
2.0
*
(
h_spline
(
i
,
m
+
1
,
6
)
-
h_spline
(
i
,
m
,
6
));
}
h_spline
(
i
,
n
,
4
)
=
0.0
;
h_spline
(
i
,
n
,
3
)
=
0.0
;
for
(
int
m
=
1
;
m
<=
n
;
m
++
)
{
h_spline
(
i
,
m
,
2
)
=
h_spline
(
i
,
m
,
5
)
/
delta
;
h_spline
(
i
,
m
,
1
)
=
2.0
*
h_spline
(
i
,
m
,
4
)
/
delta
;
h_spline
(
i
,
m
,
0
)
=
3.0
*
h_spline
(
i
,
m
,
3
)
/
delta
;
}
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
int
PairEAMAlloyKokkos
<
DeviceType
>::
pack_forward_comm_kokkos
(
int
n
,
DAT
::
tdual_int_2d
k_sendlist
,
int
iswap_in
,
DAT
::
tdual_xfloat_1d
&
buf
,
int
pbc_flag
,
int
*
pbc
)
{
d_sendlist
=
k_sendlist
.
view
<
DeviceType
>
();
iswap
=
iswap_in
;
v_buf
=
buf
.
view
<
DeviceType
>
();
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
LMPDeviceType
,
TagPairEAMAlloyPackForwardComm
>
(
0
,
n
),
*
this
);
DeviceType
::
fence
();
return
n
;
}
template
<
class
DeviceType
>
KOKKOS_INLINE_FUNCTION
void
PairEAMAlloyKokkos
<
DeviceType
>::
operator
()(
TagPairEAMAlloyPackForwardComm
,
const
int
&
i
)
const
{
int
j
=
d_sendlist
(
iswap
,
i
);
v_buf
[
i
]
=
d_fp
[
j
];
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
void
PairEAMAlloyKokkos
<
DeviceType
>::
unpack_forward_comm_kokkos
(
int
n
,
int
first_in
,
DAT
::
tdual_xfloat_1d
&
buf
)
{
first
=
first_in
;
v_buf
=
buf
.
view
<
DeviceType
>
();
Kokkos
::
parallel_for
(
Kokkos
::
RangePolicy
<
LMPDeviceType
,
TagPairEAMAlloyUnpackForwardComm
>
(
0
,
n
),
*
this
);
DeviceType
::
fence
();
}
template
<
class
DeviceType
>
KOKKOS_INLINE_FUNCTION
void
PairEAMAlloyKokkos
<
DeviceType
>::
operator
()(
TagPairEAMAlloyUnpackForwardComm
,
const
int
&
i
)
const
{
d_fp
[
i
+
first
]
=
v_buf
[
i
];
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
int
PairEAMAlloyKokkos
<
DeviceType
>::
pack_forward_comm
(
int
n
,
int
*
list
,
double
*
buf
,
int
pbc_flag
,
int
*
pbc
)
{
int
i
,
j
;
for
(
i
=
0
;
i
<
n
;
i
++
)
{
j
=
list
[
i
];
buf
[
i
]
=
h_fp
[
j
];
}
return
n
;
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
void
PairEAMAlloyKokkos
<
DeviceType
>::
unpack_forward_comm
(
int
n
,
int
first
,
double
*
buf
)
{
for
(
int
i
=
0
;
i
<
n
;
i
++
)
{
h_fp
[
i
+
first
]
=
buf
[
i
];
}
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
int
PairEAMAlloyKokkos
<
DeviceType
>::
pack_reverse_comm
(
int
n
,
int
first
,
double
*
buf
)
{
int
i
,
m
,
last
;
m
=
0
;
last
=
first
+
n
;
for
(
i
=
first
;
i
<
last
;
i
++
)
buf
[
m
++
]
=
h_rho
[
i
];
return
m
;
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
void
PairEAMAlloyKokkos
<
DeviceType
>::
unpack_reverse_comm
(
int
n
,
int
*
list
,
double
*
buf
)
{
int
i
,
j
,
m
;
m
=
0
;
for
(
i
=
0
;
i
<
n
;
i
++
)
{
j
=
list
[
i
];
h_rho
[
j
]
+=
buf
[
m
++
];
}
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
KOKKOS_INLINE_FUNCTION
void
PairEAMAlloyKokkos
<
DeviceType
>::
operator
()(
TagPairEAMAlloyInitialize
,
const
int
&
i
)
const
{
d_rho
[
i
]
=
0.0
;
}
/* ---------------------------------------------------------------------- */
////Specialisation for Neighborlist types Half, HalfThread, Full
template
<
class
DeviceType
>
template
<
int
NEIGHFLAG
,
int
NEWTON_PAIR
>
KOKKOS_INLINE_FUNCTION
void
PairEAMAlloyKokkos
<
DeviceType
>::
operator
()(
TagPairEAMAlloyKernelA
<
NEIGHFLAG
,
NEWTON_PAIR
>
,
const
int
&
ii
)
const
{
// rho = density at each atom
// loop over neighbors of my atoms
// The rho array is atomic for Half/Thread neighbor style
Kokkos
::
View
<
F_FLOAT
*
,
typename
DAT
::
t_f_array
::
array_layout
,
DeviceType
,
Kokkos
::
MemoryTraits
<
AtomicF
<
NEIGHFLAG
>::
value
>
>
rho
=
v_rho
;
const
int
i
=
d_ilist
[
ii
];
const
X_FLOAT
xtmp
=
x
(
i
,
0
);
const
X_FLOAT
ytmp
=
x
(
i
,
1
);
const
X_FLOAT
ztmp
=
x
(
i
,
2
);
const
int
itype
=
type
(
i
);
//const AtomNeighborsConst d_neighbors_i = k_list.get_neighbors_const(i);
const
int
jnum
=
d_numneigh
[
i
];
F_FLOAT
rhotmp
=
0.0
;
for
(
int
jj
=
0
;
jj
<
jnum
;
jj
++
)
{
//int j = d_neighbors_i[jj];
int
j
=
d_neighbors
(
i
,
jj
);
j
&=
NEIGHMASK
;
const
X_FLOAT
delx
=
xtmp
-
x
(
j
,
0
);
const
X_FLOAT
dely
=
ytmp
-
x
(
j
,
1
);
const
X_FLOAT
delz
=
ztmp
-
x
(
j
,
2
);
const
int
jtype
=
type
(
j
);
const
F_FLOAT
rsq
=
delx
*
delx
+
dely
*
dely
+
delz
*
delz
;
if
(
rsq
<
cutforcesq
)
{
F_FLOAT
p
=
sqrt
(
rsq
)
*
rdr
+
1.0
;
int
m
=
static_cast
<
int
>
(
p
);
m
=
MIN
(
m
,
nr
-
1
);
p
-=
m
;
p
=
MIN
(
p
,
1.0
);
const
int
d_type2rhor_ji
=
d_type2rhor
(
jtype
,
itype
);
rhotmp
+=
((
d_rhor_spline
(
d_type2rhor_ji
,
m
,
3
)
*
p
+
d_rhor_spline
(
d_type2rhor_ji
,
m
,
4
))
*
p
+
d_rhor_spline
(
d_type2rhor_ji
,
m
,
5
))
*
p
+
d_rhor_spline
(
d_type2rhor_ji
,
m
,
6
);
if
(
NEWTON_PAIR
||
j
<
nlocal
)
{
const
int
d_type2rhor_ij
=
d_type2rhor
(
itype
,
jtype
);
rho
[
j
]
+=
((
d_rhor_spline
(
d_type2rhor_ij
,
m
,
3
)
*
p
+
d_rhor_spline
(
d_type2rhor_ij
,
m
,
4
))
*
p
+
d_rhor_spline
(
d_type2rhor_ij
,
m
,
5
))
*
p
+
d_rhor_spline
(
d_type2rhor_ij
,
m
,
6
);
}
}
}
rho
[
i
]
+=
rhotmp
;
}
/* ---------------------------------------------------------------------- */
////Specialisation for Neighborlist types Half, HalfThread, Full
template
<
class
DeviceType
>
template
<
int
EFLAG
>
KOKKOS_INLINE_FUNCTION
void
PairEAMAlloyKokkos
<
DeviceType
>::
operator
()(
TagPairEAMAlloyKernelB
<
EFLAG
>
,
const
int
&
ii
,
EV_FLOAT
&
ev
)
const
{
// fp = derivative of embedding energy at each atom
// phi = embedding energy at each atom
// if rho > rhomax (e.g. due to close approach of two atoms),
// will exceed table, so add linear term to conserve energy
const
int
i
=
d_ilist
[
ii
];
const
int
itype
=
type
(
i
);
F_FLOAT
p
=
d_rho
[
i
]
*
rdrho
+
1.0
;
int
m
=
static_cast
<
int
>
(
p
);
m
=
MAX
(
1
,
MIN
(
m
,
nrho
-
1
));
p
-=
m
;
p
=
MIN
(
p
,
1.0
);
const
int
d_type2frho_i
=
d_type2frho
[
itype
];
d_fp
[
i
]
=
(
d_frho_spline
(
d_type2frho_i
,
m
,
0
)
*
p
+
d_frho_spline
(
d_type2frho_i
,
m
,
1
))
*
p
+
d_frho_spline
(
d_type2frho_i
,
m
,
2
);
if
(
EFLAG
)
{
F_FLOAT
phi
=
((
d_frho_spline
(
d_type2frho_i
,
m
,
3
)
*
p
+
d_frho_spline
(
d_type2frho_i
,
m
,
4
))
*
p
+
d_frho_spline
(
d_type2frho_i
,
m
,
5
))
*
p
+
d_frho_spline
(
d_type2frho_i
,
m
,
6
);
if
(
d_rho
[
i
]
>
rhomax
)
phi
+=
d_fp
[
i
]
*
(
d_rho
[
i
]
-
rhomax
);
if
(
eflag_global
)
ev
.
evdwl
+=
phi
;
if
(
eflag_atom
)
d_eatom
[
i
]
+=
phi
;
}
}
template
<
class
DeviceType
>
template
<
int
EFLAG
>
KOKKOS_INLINE_FUNCTION
void
PairEAMAlloyKokkos
<
DeviceType
>::
operator
()(
TagPairEAMAlloyKernelB
<
EFLAG
>
,
const
int
&
ii
)
const
{
EV_FLOAT
ev
;
this
->
template
operator
()
<
EFLAG
>
(
TagPairEAMAlloyKernelB
<
EFLAG
>
(),
ii
,
ev
);
}
/* ---------------------------------------------------------------------- */
////Specialisation for Neighborlist types Half, HalfThread, Full
template
<
class
DeviceType
>
template
<
int
EFLAG
>
KOKKOS_INLINE_FUNCTION
void
PairEAMAlloyKokkos
<
DeviceType
>::
operator
()(
TagPairEAMAlloyKernelAB
<
EFLAG
>
,
const
int
&
ii
,
EV_FLOAT
&
ev
)
const
{
// rho = density at each atom
// loop over neighbors of my atoms
const
int
i
=
d_ilist
[
ii
];
const
X_FLOAT
xtmp
=
x
(
i
,
0
);
const
X_FLOAT
ytmp
=
x
(
i
,
1
);
const
X_FLOAT
ztmp
=
x
(
i
,
2
);
const
int
itype
=
type
(
i
);
//const AtomNeighborsConst d_neighbors_i = k_list.get_neighbors_const(i);
const
int
jnum
=
d_numneigh
[
i
];
F_FLOAT
rhotmp
=
0.0
;
for
(
int
jj
=
0
;
jj
<
jnum
;
jj
++
)
{
//int j = d_neighbors_i[jj];
int
j
=
d_neighbors
(
i
,
jj
);
j
&=
NEIGHMASK
;
const
X_FLOAT
delx
=
xtmp
-
x
(
j
,
0
);
const
X_FLOAT
dely
=
ytmp
-
x
(
j
,
1
);
const
X_FLOAT
delz
=
ztmp
-
x
(
j
,
2
);
const
int
jtype
=
type
(
j
);
const
F_FLOAT
rsq
=
delx
*
delx
+
dely
*
dely
+
delz
*
delz
;
if
(
rsq
<
cutforcesq
)
{
F_FLOAT
p
=
sqrt
(
rsq
)
*
rdr
+
1.0
;
int
m
=
static_cast
<
int
>
(
p
);
m
=
MIN
(
m
,
nr
-
1
);
p
-=
m
;
p
=
MIN
(
p
,
1.0
);
const
int
d_type2rhor_ji
=
d_type2rhor
(
jtype
,
itype
);
rhotmp
+=
((
d_rhor_spline
(
d_type2rhor_ji
,
m
,
3
)
*
p
+
d_rhor_spline
(
d_type2rhor_ji
,
m
,
4
))
*
p
+
d_rhor_spline
(
d_type2rhor_ji
,
m
,
5
))
*
p
+
d_rhor_spline
(
d_type2rhor_ji
,
m
,
6
);
}
}
d_rho
[
i
]
+=
rhotmp
;
// fp = derivative of embedding energy at each atom
// phi = embedding energy at each atom
// if rho > rhomax (e.g. due to close approach of two atoms),
// will exceed table, so add linear term to conserve energy
F_FLOAT
p
=
d_rho
[
i
]
*
rdrho
+
1.0
;
int
m
=
static_cast
<
int
>
(
p
);
m
=
MAX
(
1
,
MIN
(
m
,
nrho
-
1
));
p
-=
m
;
p
=
MIN
(
p
,
1.0
);
const
int
d_type2frho_i
=
d_type2frho
[
itype
];
d_fp
[
i
]
=
(
d_frho_spline
(
d_type2frho_i
,
m
,
0
)
*
p
+
d_frho_spline
(
d_type2frho_i
,
m
,
1
))
*
p
+
d_frho_spline
(
d_type2frho_i
,
m
,
2
);
if
(
EFLAG
)
{
F_FLOAT
phi
=
((
d_frho_spline
(
d_type2frho_i
,
m
,
3
)
*
p
+
d_frho_spline
(
d_type2frho_i
,
m
,
4
))
*
p
+
d_frho_spline
(
d_type2frho_i
,
m
,
5
))
*
p
+
d_frho_spline
(
d_type2frho_i
,
m
,
6
);
if
(
d_rho
[
i
]
>
rhomax
)
phi
+=
d_fp
[
i
]
*
(
d_rho
[
i
]
-
rhomax
);
if
(
eflag_global
)
ev
.
evdwl
+=
phi
;
if
(
eflag_atom
)
d_eatom
[
i
]
+=
phi
;
}
}
template
<
class
DeviceType
>
template
<
int
EFLAG
>
KOKKOS_INLINE_FUNCTION
void
PairEAMAlloyKokkos
<
DeviceType
>::
operator
()(
TagPairEAMAlloyKernelAB
<
EFLAG
>
,
const
int
&
ii
)
const
{
EV_FLOAT
ev
;
this
->
template
operator
()
<
EFLAG
>
(
TagPairEAMAlloyKernelAB
<
EFLAG
>
(),
ii
,
ev
);
}
/* ---------------------------------------------------------------------- */
////Specialisation for Neighborlist types Half, HalfThread, Full
template
<
class
DeviceType
>
template
<
int
NEIGHFLAG
,
int
NEWTON_PAIR
,
int
EVFLAG
>
KOKKOS_INLINE_FUNCTION
void
PairEAMAlloyKokkos
<
DeviceType
>::
operator
()(
TagPairEAMAlloyKernelC
<
NEIGHFLAG
,
NEWTON_PAIR
,
EVFLAG
>
,
const
int
&
ii
,
EV_FLOAT
&
ev
)
const
{
// The f array is atomic for Half/Thread neighbor style
Kokkos
::
View
<
F_FLOAT
*
[
3
],
typename
DAT
::
t_f_array
::
array_layout
,
DeviceType
,
Kokkos
::
MemoryTraits
<
AtomicF
<
NEIGHFLAG
>::
value
>
>
a_f
=
f
;
const
int
i
=
d_ilist
[
ii
];
const
X_FLOAT
xtmp
=
x
(
i
,
0
);
const
X_FLOAT
ytmp
=
x
(
i
,
1
);
const
X_FLOAT
ztmp
=
x
(
i
,
2
);
const
int
itype
=
type
(
i
);
//const AtomNeighborsConst d_neighbors_i = k_list.get_neighbors_const(i);
const
int
jnum
=
d_numneigh
[
i
];
F_FLOAT
fxtmp
=
0.0
;
F_FLOAT
fytmp
=
0.0
;
F_FLOAT
fztmp
=
0.0
;
for
(
int
jj
=
0
;
jj
<
jnum
;
jj
++
)
{
//int j = d_neighbors_i[jj];
int
j
=
d_neighbors
(
i
,
jj
);
j
&=
NEIGHMASK
;
const
X_FLOAT
delx
=
xtmp
-
x
(
j
,
0
);
const
X_FLOAT
dely
=
ytmp
-
x
(
j
,
1
);
const
X_FLOAT
delz
=
ztmp
-
x
(
j
,
2
);
const
int
jtype
=
type
(
j
);
const
F_FLOAT
rsq
=
delx
*
delx
+
dely
*
dely
+
delz
*
delz
;
if
(
rsq
<
cutforcesq
)
{
const
F_FLOAT
r
=
sqrt
(
rsq
);
F_FLOAT
p
=
r
*
rdr
+
1.0
;
int
m
=
static_cast
<
int
>
(
p
);
m
=
MIN
(
m
,
nr
-
1
);
p
-=
m
;
p
=
MIN
(
p
,
1.0
);
// rhoip = derivative of (density at atom j due to atom i)
// rhojp = derivative of (density at atom i due to atom j)
// phi = pair potential energy
// phip = phi'
// z2 = phi * r
// z2p = (phi * r)' = (phi' r) + phi
// psip needs both fp[i] and fp[j] terms since r_ij appears in two
// terms of embed eng: Fi(sum rho_ij) and Fj(sum rho_ji)
// hence embed' = Fi(sum rho_ij) rhojp + Fj(sum rho_ji) rhoip
const
int
d_type2rhor_ij
=
d_type2rhor
(
itype
,
jtype
);
const
F_FLOAT
rhoip
=
(
d_rhor_spline
(
d_type2rhor_ij
,
m
,
0
)
*
p
+
d_rhor_spline
(
d_type2rhor_ij
,
m
,
1
))
*
p
+
d_rhor_spline
(
d_type2rhor_ij
,
m
,
2
);
const
int
d_type2rhor_ji
=
d_type2rhor
(
jtype
,
itype
);
const
F_FLOAT
rhojp
=
(
d_rhor_spline
(
d_type2rhor_ji
,
m
,
0
)
*
p
+
d_rhor_spline
(
d_type2rhor_ji
,
m
,
1
))
*
p
+
d_rhor_spline
(
d_type2rhor_ji
,
m
,
2
);
const
int
d_type2z2r_ij
=
d_type2z2r
(
itype
,
jtype
);
const
F_FLOAT
z2p
=
(
d_z2r_spline
(
d_type2z2r_ij
,
m
,
0
)
*
p
+
d_z2r_spline
(
d_type2z2r_ij
,
m
,
1
))
*
p
+
d_z2r_spline
(
d_type2z2r_ij
,
m
,
2
);
const
F_FLOAT
z2
=
((
d_z2r_spline
(
d_type2z2r_ij
,
m
,
3
)
*
p
+
d_z2r_spline
(
d_type2z2r_ij
,
m
,
4
))
*
p
+
d_z2r_spline
(
d_type2z2r_ij
,
m
,
5
))
*
p
+
d_z2r_spline
(
d_type2z2r_ij
,
m
,
6
);
const
F_FLOAT
recip
=
1.0
/
r
;
const
F_FLOAT
phi
=
z2
*
recip
;
const
F_FLOAT
phip
=
z2p
*
recip
-
phi
*
recip
;
const
F_FLOAT
psip
=
d_fp
[
i
]
*
rhojp
+
d_fp
[
j
]
*
rhoip
+
phip
;
const
F_FLOAT
fpair
=
-
psip
*
recip
;
fxtmp
+=
delx
*
fpair
;
fytmp
+=
dely
*
fpair
;
fztmp
+=
delz
*
fpair
;
if
((
NEIGHFLAG
==
HALF
||
NEIGHFLAG
==
HALFTHREAD
)
&&
(
NEWTON_PAIR
||
j
<
nlocal
))
{
a_f
(
j
,
0
)
-=
delx
*
fpair
;
a_f
(
j
,
1
)
-=
dely
*
fpair
;
a_f
(
j
,
2
)
-=
delz
*
fpair
;
}
if
(
EVFLAG
)
{
if
(
eflag
)
{
ev
.
evdwl
+=
(((
NEIGHFLAG
==
HALF
||
NEIGHFLAG
==
HALFTHREAD
)
&&
(
NEWTON_PAIR
||
(
j
<
nlocal
)))
?
1.0
:
0.5
)
*
phi
;
}
if
(
vflag_either
||
eflag_atom
)
this
->
template
ev_tally
<
NEIGHFLAG
,
NEWTON_PAIR
>
(
ev
,
i
,
j
,
phi
,
fpair
,
delx
,
dely
,
delz
);
}
}
}
a_f
(
i
,
0
)
+=
fxtmp
;
a_f
(
i
,
1
)
+=
fytmp
;
a_f
(
i
,
2
)
+=
fztmp
;
}
template
<
class
DeviceType
>
template
<
int
NEIGHFLAG
,
int
NEWTON_PAIR
,
int
EVFLAG
>
KOKKOS_INLINE_FUNCTION
void
PairEAMAlloyKokkos
<
DeviceType
>::
operator
()(
TagPairEAMAlloyKernelC
<
NEIGHFLAG
,
NEWTON_PAIR
,
EVFLAG
>
,
const
int
&
ii
)
const
{
EV_FLOAT
ev
;
this
->
template
operator
()
<
NEIGHFLAG
,
NEWTON_PAIR
,
EVFLAG
>
(
TagPairEAMAlloyKernelC
<
NEIGHFLAG
,
NEWTON_PAIR
,
EVFLAG
>
(),
ii
,
ev
);
}
/* ---------------------------------------------------------------------- */
template
<
class
DeviceType
>
template
<
int
NEIGHFLAG
,
int
NEWTON_PAIR
>
KOKKOS_INLINE_FUNCTION
void
PairEAMAlloyKokkos
<
DeviceType
>::
ev_tally
(
EV_FLOAT
&
ev
,
const
int
&
i
,
const
int
&
j
,
const
F_FLOAT
&
epair
,
const
F_FLOAT
&
fpair
,
const
F_FLOAT
&
delx
,
const
F_FLOAT
&
dely
,
const
F_FLOAT
&
delz
)
const
{
const
int
EFLAG
=
eflag
;
const
int
VFLAG
=
vflag_either
;
// The eatom and vatom arrays are atomic for Half/Thread neighbor style
Kokkos
::
View
<
E_FLOAT
*
,
typename
DAT
::
t_efloat_1d
::
array_layout
,
DeviceType
,
Kokkos
::
MemoryTraits
<
AtomicF
<
NEIGHFLAG
>::
value
>
>
v_eatom
=
k_eatom
.
view
<
DeviceType
>
();
Kokkos
::
View
<
F_FLOAT
*
[
6
],
typename
DAT
::
t_virial_array
::
array_layout
,
DeviceType
,
Kokkos
::
MemoryTraits
<
AtomicF
<
NEIGHFLAG
>::
value
>
>
v_vatom
=
k_vatom
.
view
<
DeviceType
>
();
if
(
EFLAG
)
{
if
(
eflag_atom
)
{
const
E_FLOAT
epairhalf
=
0.5
*
epair
;
if
(
NEIGHFLAG
!=
FULL
)
{
if
(
NEWTON_PAIR
||
i
<
nlocal
)
v_eatom
[
i
]
+=
epairhalf
;
if
(
NEWTON_PAIR
||
j
<
nlocal
)
v_eatom
[
j
]
+=
epairhalf
;
}
else
{
v_eatom
[
i
]
+=
epairhalf
;
}
}
}
if
(
VFLAG
)
{
const
E_FLOAT
v0
=
delx
*
delx
*
fpair
;
const
E_FLOAT
v1
=
dely
*
dely
*
fpair
;
const
E_FLOAT
v2
=
delz
*
delz
*
fpair
;
const
E_FLOAT
v3
=
delx
*
dely
*
fpair
;
const
E_FLOAT
v4
=
delx
*
delz
*
fpair
;
const
E_FLOAT
v5
=
dely
*
delz
*
fpair
;
if
(
vflag_global
)
{
if
(
NEIGHFLAG
!=
FULL
)
{
if
(
NEWTON_PAIR
||
i
<
nlocal
)
{
ev
.
v
[
0
]
+=
0.5
*
v0
;
ev
.
v
[
1
]
+=
0.5
*
v1
;
ev
.
v
[
2
]
+=
0.5
*
v2
;
ev
.
v
[
3
]
+=
0.5
*
v3
;
ev
.
v
[
4
]
+=
0.5
*
v4
;
ev
.
v
[
5
]
+=
0.5
*
v5
;
}
if
(
NEWTON_PAIR
||
j
<
nlocal
)
{
ev
.
v
[
0
]
+=
0.5
*
v0
;
ev
.
v
[
1
]
+=
0.5
*
v1
;
ev
.
v
[
2
]
+=
0.5
*
v2
;
ev
.
v
[
3
]
+=
0.5
*
v3
;
ev
.
v
[
4
]
+=
0.5
*
v4
;
ev
.
v
[
5
]
+=
0.5
*
v5
;
}
}
else
{
ev
.
v
[
0
]
+=
0.5
*
v0
;
ev
.
v
[
1
]
+=
0.5
*
v1
;
ev
.
v
[
2
]
+=
0.5
*
v2
;
ev
.
v
[
3
]
+=
0.5
*
v3
;
ev
.
v
[
4
]
+=
0.5
*
v4
;
ev
.
v
[
5
]
+=
0.5
*
v5
;
}
}
if
(
vflag_atom
)
{
if
(
NEIGHFLAG
!=
FULL
)
{
if
(
NEWTON_PAIR
||
i
<
nlocal
)
{
v_vatom
(
i
,
0
)
+=
0.5
*
v0
;
v_vatom
(
i
,
1
)
+=
0.5
*
v1
;
v_vatom
(
i
,
2
)
+=
0.5
*
v2
;
v_vatom
(
i
,
3
)
+=
0.5
*
v3
;
v_vatom
(
i
,
4
)
+=
0.5
*
v4
;
v_vatom
(
i
,
5
)
+=
0.5
*
v5
;
}
if
(
NEWTON_PAIR
||
j
<
nlocal
)
{
v_vatom
(
j
,
0
)
+=
0.5
*
v0
;
v_vatom
(
j
,
1
)
+=
0.5
*
v1
;
v_vatom
(
j
,
2
)
+=
0.5
*
v2
;
v_vatom
(
j
,
3
)
+=
0.5
*
v3
;
v_vatom
(
j
,
4
)
+=
0.5
*
v4
;
v_vatom
(
j
,
5
)
+=
0.5
*
v5
;
}
}
else
{
v_vatom
(
i
,
0
)
+=
0.5
*
v0
;
v_vatom
(
i
,
1
)
+=
0.5
*
v1
;
v_vatom
(
i
,
2
)
+=
0.5
*
v2
;
v_vatom
(
i
,
3
)
+=
0.5
*
v3
;
v_vatom
(
i
,
4
)
+=
0.5
*
v4
;
v_vatom
(
i
,
5
)
+=
0.5
*
v5
;
}
}
}
}
/* ---------------------------------------------------------------------- */
// Duplicate PairEAMAlloy functions
/* ----------------------------------------------------------------------
set coeffs for one or more type pairs
read DYNAMO setfl file
------------------------------------------------------------------------- */
template
<
class
DeviceType
>
void
PairEAMAlloyKokkos
<
DeviceType
>::
coeff
(
int
narg
,
char
**
arg
)
{
int
i
,
j
;
if
(
!
allocated
)
allocate
();
if
(
narg
!=
3
+
atom
->
ntypes
)
error
->
all
(
FLERR
,
"Incorrect args for pair coefficients"
);
// insure I,J args are * *
if
(
strcmp
(
arg
[
0
],
"*"
)
!=
0
||
strcmp
(
arg
[
1
],
"*"
)
!=
0
)
error
->
all
(
FLERR
,
"Incorrect args for pair coefficients"
);
// read EAM setfl file
if
(
setfl
)
{
for
(
i
=
0
;
i
<
setfl
->
nelements
;
i
++
)
delete
[]
setfl
->
elements
[
i
];
delete
[]
setfl
->
elements
;
delete
[]
setfl
->
mass
;
memory
->
destroy
(
setfl
->
frho
);
memory
->
destroy
(
setfl
->
rhor
);
memory
->
destroy
(
setfl
->
z2r
);
delete
setfl
;
}
setfl
=
new
Setfl
();
read_file
(
arg
[
2
]);
// read args that map atom types to elements in potential file
// map[i] = which element the Ith atom type is, -1 if NULL
for
(
i
=
3
;
i
<
narg
;
i
++
)
{
if
(
strcmp
(
arg
[
i
],
"NULL"
)
==
0
)
{
map
[
i
-
2
]
=
-
1
;
continue
;
}
for
(
j
=
0
;
j
<
setfl
->
nelements
;
j
++
)
if
(
strcmp
(
arg
[
i
],
setfl
->
elements
[
j
])
==
0
)
break
;
if
(
j
<
setfl
->
nelements
)
map
[
i
-
2
]
=
j
;
else
error
->
all
(
FLERR
,
"No matching element in EAM potential file"
);
}
// clear setflag since coeff() called once with I,J = * *
int
n
=
atom
->
ntypes
;
for
(
i
=
1
;
i
<=
n
;
i
++
)
for
(
j
=
i
;
j
<=
n
;
j
++
)
setflag
[
i
][
j
]
=
0
;
// set setflag i,j for type pairs where both are mapped to elements
// set mass of atom type if i = j
int
count
=
0
;
for
(
i
=
1
;
i
<=
n
;
i
++
)
{
for
(
j
=
i
;
j
<=
n
;
j
++
)
{
if
(
map
[
i
]
>=
0
&&
map
[
j
]
>=
0
)
{
setflag
[
i
][
j
]
=
1
;
if
(
i
==
j
)
atom
->
set_mass
(
i
,
setfl
->
mass
[
map
[
i
]]);
count
++
;
}
}
}
if
(
count
==
0
)
error
->
all
(
FLERR
,
"Incorrect args for pair coefficients"
);
}
/* ----------------------------------------------------------------------
read a multi-element DYNAMO setfl file
------------------------------------------------------------------------- */
template
<
class
DeviceType
>
void
PairEAMAlloyKokkos
<
DeviceType
>::
read_file
(
char
*
filename
)
{
Setfl
*
file
=
setfl
;
// open potential file
int
me
=
comm
->
me
;
FILE
*
fptr
;
char
line
[
MAXLINE
];
if
(
me
==
0
)
{
fptr
=
force
->
open_potential
(
filename
);
if
(
fptr
==
NULL
)
{
char
str
[
128
];
sprintf
(
str
,
"Cannot open EAM potential file %s"
,
filename
);
error
->
one
(
FLERR
,
str
);
}
}
// read and broadcast header
// extract element names from nelements line
int
n
;
if
(
me
==
0
)
{
fgets
(
line
,
MAXLINE
,
fptr
);
fgets
(
line
,
MAXLINE
,
fptr
);
fgets
(
line
,
MAXLINE
,
fptr
);
fgets
(
line
,
MAXLINE
,
fptr
);
n
=
strlen
(
line
)
+
1
;
}
MPI_Bcast
(
&
n
,
1
,
MPI_INT
,
0
,
world
);
MPI_Bcast
(
line
,
n
,
MPI_CHAR
,
0
,
world
);
sscanf
(
line
,
"%d"
,
&
file
->
nelements
);
int
nwords
=
atom
->
count_words
(
line
);
if
(
nwords
!=
file
->
nelements
+
1
)
error
->
all
(
FLERR
,
"Incorrect element names in EAM potential file"
);
char
**
words
=
new
char
*
[
file
->
nelements
+
1
];
nwords
=
0
;
strtok
(
line
,
"
\t\n\r\f
"
);
while
((
words
[
nwords
++
]
=
strtok
(
NULL
,
"
\t\n\r\f
"
)))
continue
;
file
->
elements
=
new
char
*
[
file
->
nelements
];
for
(
int
i
=
0
;
i
<
file
->
nelements
;
i
++
)
{
n
=
strlen
(
words
[
i
])
+
1
;
file
->
elements
[
i
]
=
new
char
[
n
];
strcpy
(
file
->
elements
[
i
],
words
[
i
]);
}
delete
[]
words
;
if
(
me
==
0
)
{
fgets
(
line
,
MAXLINE
,
fptr
);
sscanf
(
line
,
"%d %lg %d %lg %lg"
,
&
file
->
nrho
,
&
file
->
drho
,
&
file
->
nr
,
&
file
->
dr
,
&
file
->
cut
);
}
MPI_Bcast
(
&
file
->
nrho
,
1
,
MPI_INT
,
0
,
world
);
MPI_Bcast
(
&
file
->
drho
,
1
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
file
->
nr
,
1
,
MPI_INT
,
0
,
world
);
MPI_Bcast
(
&
file
->
dr
,
1
,
MPI_DOUBLE
,
0
,
world
);
MPI_Bcast
(
&
file
->
cut
,
1
,
MPI_DOUBLE
,
0
,
world
);
file
->
mass
=
new
double
[
file
->
nelements
];
memory
->
create
(
file
->
frho
,
file
->
nelements
,
file
->
nrho
+
1
,
"pair:frho"
);
memory
->
create
(
file
->
rhor
,
file
->
nelements
,
file
->
nr
+
1
,
"pair:rhor"
);
memory
->
create
(
file
->
z2r
,
file
->
nelements
,
file
->
nelements
,
file
->
nr
+
1
,
"pair:z2r"
);
int
i
,
j
,
tmp
;
for
(
i
=
0
;
i
<
file
->
nelements
;
i
++
)
{
if
(
me
==
0
)
{
fgets
(
line
,
MAXLINE
,
fptr
);
sscanf
(
line
,
"%d %lg"
,
&
tmp
,
&
file
->
mass
[
i
]);
}
MPI_Bcast
(
&
file
->
mass
[
i
],
1
,
MPI_DOUBLE
,
0
,
world
);
if
(
me
==
0
)
grab
(
fptr
,
file
->
nrho
,
&
file
->
frho
[
i
][
1
]);
MPI_Bcast
(
&
file
->
frho
[
i
][
1
],
file
->
nrho
,
MPI_DOUBLE
,
0
,
world
);
if
(
me
==
0
)
grab
(
fptr
,
file
->
nr
,
&
file
->
rhor
[
i
][
1
]);
MPI_Bcast
(
&
file
->
rhor
[
i
][
1
],
file
->
nr
,
MPI_DOUBLE
,
0
,
world
);
}
for
(
i
=
0
;
i
<
file
->
nelements
;
i
++
)
for
(
j
=
0
;
j
<=
i
;
j
++
)
{
if
(
me
==
0
)
grab
(
fptr
,
file
->
nr
,
&
file
->
z2r
[
i
][
j
][
1
]);
MPI_Bcast
(
&
file
->
z2r
[
i
][
j
][
1
],
file
->
nr
,
MPI_DOUBLE
,
0
,
world
);
}
// close the potential file
if
(
me
==
0
)
fclose
(
fptr
);
}
/* ----------------------------------------------------------------------
copy read-in setfl potential to standard array format
------------------------------------------------------------------------- */
template
<
class
DeviceType
>
void
PairEAMAlloyKokkos
<
DeviceType
>::
file2array_alloy
()
{
int
i
,
j
,
m
,
n
;
int
ntypes
=
atom
->
ntypes
;
// set function params directly from setfl file
nrho
=
setfl
->
nrho
;
nr
=
setfl
->
nr
;
drho
=
setfl
->
drho
;
dr
=
setfl
->
dr
;
rhomax
=
(
nrho
-
1
)
*
drho
;
// ------------------------------------------------------------------
// setup frho arrays
// ------------------------------------------------------------------
// allocate frho arrays
// nfrho = # of setfl elements + 1 for zero array
nfrho
=
setfl
->
nelements
+
1
;
memory
->
destroy
(
frho
);
memory
->
create
(
frho
,
nfrho
,
nrho
+
1
,
"pair:frho"
);
// copy each element's frho to global frho
for
(
i
=
0
;
i
<
setfl
->
nelements
;
i
++
)
for
(
m
=
1
;
m
<=
nrho
;
m
++
)
frho
[
i
][
m
]
=
setfl
->
frho
[
i
][
m
];
// add extra frho of zeroes for non-EAM types to point to (pair hybrid)
// this is necessary b/c fp is still computed for non-EAM atoms
for
(
m
=
1
;
m
<=
nrho
;
m
++
)
frho
[
nfrho
-
1
][
m
]
=
0.0
;
// type2frho[i] = which frho array (0 to nfrho-1) each atom type maps to
// if atom type doesn't point to element (non-EAM atom in pair hybrid)
// then map it to last frho array of zeroes
for
(
i
=
1
;
i
<=
ntypes
;
i
++
)
if
(
map
[
i
]
>=
0
)
type2frho
[
i
]
=
map
[
i
];
else
type2frho
[
i
]
=
nfrho
-
1
;
// ------------------------------------------------------------------
// setup rhor arrays
// ------------------------------------------------------------------
// allocate rhor arrays
// nrhor = # of setfl elements
nrhor
=
setfl
->
nelements
;
memory
->
destroy
(
rhor
);
memory
->
create
(
rhor
,
nrhor
,
nr
+
1
,
"pair:rhor"
);
// copy each element's rhor to global rhor
for
(
i
=
0
;
i
<
setfl
->
nelements
;
i
++
)
for
(
m
=
1
;
m
<=
nr
;
m
++
)
rhor
[
i
][
m
]
=
setfl
->
rhor
[
i
][
m
];
// type2rhor[i][j] = which rhor array (0 to nrhor-1) each type pair maps to
// for setfl files, I,J mapping only depends on I
// OK if map = -1 (non-EAM atom in pair hybrid) b/c type2rhor not used
for
(
i
=
1
;
i
<=
ntypes
;
i
++
)
for
(
j
=
1
;
j
<=
ntypes
;
j
++
)
type2rhor
[
i
][
j
]
=
map
[
i
];
// ------------------------------------------------------------------
// setup z2r arrays
// ------------------------------------------------------------------
// allocate z2r arrays
// nz2r = N*(N+1)/2 where N = # of setfl elements
nz2r
=
setfl
->
nelements
*
(
setfl
->
nelements
+
1
)
/
2
;
memory
->
destroy
(
z2r
);
memory
->
create
(
z2r
,
nz2r
,
nr
+
1
,
"pair:z2r"
);
// copy each element pair z2r to global z2r, only for I >= J
n
=
0
;
for
(
i
=
0
;
i
<
setfl
->
nelements
;
i
++
)
for
(
j
=
0
;
j
<=
i
;
j
++
)
{
for
(
m
=
1
;
m
<=
nr
;
m
++
)
z2r
[
n
][
m
]
=
setfl
->
z2r
[
i
][
j
][
m
];
n
++
;
}
// type2z2r[i][j] = which z2r array (0 to nz2r-1) each type pair maps to
// set of z2r arrays only fill lower triangular Nelement matrix
// value = n = sum over rows of lower-triangular matrix until reach irow,icol
// swap indices when irow < icol to stay lower triangular
// if map = -1 (non-EAM atom in pair hybrid):
// type2z2r is not used by non-opt
// but set type2z2r to 0 since accessed by opt
int
irow
,
icol
;
for
(
i
=
1
;
i
<=
ntypes
;
i
++
)
{
for
(
j
=
1
;
j
<=
ntypes
;
j
++
)
{
irow
=
map
[
i
];
icol
=
map
[
j
];
if
(
irow
==
-
1
||
icol
==
-
1
)
{
type2z2r
[
i
][
j
]
=
0
;
continue
;
}
if
(
irow
<
icol
)
{
irow
=
map
[
j
];
icol
=
map
[
i
];
}
n
=
0
;
for
(
m
=
0
;
m
<
irow
;
m
++
)
n
+=
m
+
1
;
n
+=
icol
;
type2z2r
[
i
][
j
]
=
n
;
}
}
}
/* ---------------------------------------------------------------------- */
namespace
LAMMPS_NS
{
template
class
PairEAMAlloyKokkos
<
LMPDeviceType
>
;
#ifdef KOKKOS_HAVE_CUDA
template
class
PairEAMAlloyKokkos
<
LMPHostType
>
;
#endif
}
Event Timeline
Log In to Comment