Page Menu
Home
c4science
Search
Configure Global Search
Log In
Files
F90172826
rcb.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, Oct 30, 03:48
Size
42 KB
Mime Type
text/x-c
Expires
Fri, Nov 1, 03:48 (2 d)
Engine
blob
Format
Raw Data
Handle
22001352
Attached To
rLAMMPS lammps
rcb.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.
------------------------------------------------------------------------- */
#include <mpi.h>
#include <string.h>
#include "rcb.h"
#include "irregular.h"
#include "memory.h"
#include "error.h"
using
namespace
LAMMPS_NS
;
#define MYHUGE 1.0e30
#define TINY 1.0e-6
#define DELTA 16384
// prototypes for non-class functions
void
box_merge
(
void
*
,
void
*
,
int
*
,
MPI_Datatype
*
);
void
median_merge
(
void
*
,
void
*
,
int
*
,
MPI_Datatype
*
);
// NOTE: if want to have reuse flag, need to sum Tree across procs
/* ---------------------------------------------------------------------- */
RCB
::
RCB
(
LAMMPS
*
lmp
)
:
Pointers
(
lmp
)
{
MPI_Comm_rank
(
world
,
&
me
);
MPI_Comm_size
(
world
,
&
nprocs
);
ndot
=
maxdot
=
0
;
dots
=
NULL
;
nlist
=
maxlist
=
0
;
dotlist
=
dotmark
=
dotmark_select
=
NULL
;
maxbuf
=
0
;
buf
=
NULL
;
maxrecv
=
maxsend
=
0
;
recvproc
=
recvindex
=
sendproc
=
sendindex
=
NULL
;
tree
=
NULL
;
irregular
=
NULL
;
// create MPI data and function types for box and median AllReduce ops
MPI_Type_contiguous
(
6
,
MPI_DOUBLE
,
&
box_type
);
MPI_Type_commit
(
&
box_type
);
MPI_Type_contiguous
(
sizeof
(
Median
),
MPI_CHAR
,
&
med_type
);
MPI_Type_commit
(
&
med_type
);
MPI_Op_create
(
box_merge
,
1
,
&
box_op
);
MPI_Op_create
(
median_merge
,
1
,
&
med_op
);
reuse
=
0
;
}
/* ---------------------------------------------------------------------- */
RCB
::~
RCB
()
{
memory
->
sfree
(
dots
);
memory
->
destroy
(
dotlist
);
memory
->
destroy
(
dotmark
);
memory
->
destroy
(
dotmark_select
);
memory
->
sfree
(
buf
);
memory
->
destroy
(
recvproc
);
memory
->
destroy
(
recvindex
);
memory
->
destroy
(
sendproc
);
memory
->
destroy
(
sendindex
);
memory
->
sfree
(
tree
);
delete
irregular
;
MPI_Type_free
(
&
med_type
);
MPI_Type_free
(
&
box_type
);
MPI_Op_free
(
&
box_op
);
MPI_Op_free
(
&
med_op
);
}
/* ----------------------------------------------------------------------
perform RCB balancing of N particles at coords X in bounding box LO/HI
NEW version: each RCB cut is tested in all dimensions
dimeension that produces 2 boxes with largest min size is selected
this is to prevent very narrow boxes from being produced
if wt = NULL, ignore per-particle weights
if wt defined, per-particle weights > 0.0
dimension = 2 or 3
as documented in rcb.h:
sets noriginal,nfinal,nkeep,recvproc,recvindex,lo,hi
all proc particles will be inside or on surface of 3-d box
defined by final lo/hi
// NOTE: worry about re-use of data structs for fix balance?
------------------------------------------------------------------------- */
void
RCB
::
compute
(
int
dimension
,
int
n
,
double
**
x
,
double
*
wt
,
double
*
bboxlo
,
double
*
bboxhi
)
{
int
i
,
j
,
k
;
int
keep
,
outgoing
,
incoming
,
incoming2
;
int
dim
,
markactive
;
int
indexlo
,
indexhi
;
int
first_iteration
,
breakflag
;
double
wttot
,
wtlo
,
wthi
,
wtsum
,
wtok
,
wtupto
,
wtmax
;
double
targetlo
,
targethi
;
double
valuemin
,
valuemax
,
valuehalf
,
valuehalf_select
,
smaller
;
double
tolerance
;
MPI_Comm
comm
,
comm_half
;
MPI_Request
request
,
request2
;
Median
med
,
medme
;
// create list of my Dots
ndot
=
nkeep
=
noriginal
=
n
;
if
(
ndot
>
maxdot
)
{
maxdot
=
ndot
;
memory
->
sfree
(
dots
);
dots
=
(
Dot
*
)
memory
->
smalloc
(
ndot
*
sizeof
(
Dot
),
"RCB:dots"
);
}
for
(
i
=
0
;
i
<
ndot
;
i
++
)
{
dots
[
i
].
x
[
0
]
=
x
[
i
][
0
];
dots
[
i
].
x
[
1
]
=
x
[
i
][
1
];
dots
[
i
].
x
[
2
]
=
x
[
i
][
2
];
dots
[
i
].
proc
=
me
;
dots
[
i
].
index
=
i
;
}
if
(
wt
)
for
(
i
=
0
;
i
<
ndot
;
i
++
)
dots
[
i
].
wt
=
wt
[
i
];
else
for
(
i
=
0
;
i
<
ndot
;
i
++
)
dots
[
i
].
wt
=
1.0
;
// initial bounding box = simulation box
// includes periodic or shrink-wrapped boundaries
lo
=
bbox
.
lo
;
hi
=
bbox
.
hi
;
lo
[
0
]
=
bboxlo
[
0
];
lo
[
1
]
=
bboxlo
[
1
];
lo
[
2
]
=
bboxlo
[
2
];
hi
[
0
]
=
bboxhi
[
0
];
hi
[
1
]
=
bboxhi
[
1
];
hi
[
2
]
=
bboxhi
[
2
];
cut
=
0.0
;
cutdim
=
-
1
;
// initialize counters
counters
[
0
]
=
0
;
counters
[
1
]
=
0
;
counters
[
2
]
=
0
;
counters
[
3
]
=
ndot
;
counters
[
4
]
=
maxdot
;
counters
[
5
]
=
0
;
counters
[
6
]
=
0
;
// create communicator for use in recursion
MPI_Comm_dup
(
world
,
&
comm
);
// recurse until partition is a single proc = me
// proclower,procupper = lower,upper procs in partition
// procmid = 1st proc in upper half of partition
int
procpartner
,
procpartner2
;
int
procmid
;
int
proclower
=
0
;
int
procupper
=
nprocs
-
1
;
while
(
proclower
!=
procupper
)
{
// if odd # of procs, lower partition gets extra one
procmid
=
proclower
+
(
procupper
-
proclower
)
/
2
+
1
;
// determine communication partner(s)
// readnumber = # of proc partners to read from
if
(
me
<
procmid
)
procpartner
=
me
+
(
procmid
-
proclower
);
else
procpartner
=
me
-
(
procmid
-
proclower
);
int
readnumber
=
1
;
if
(
procpartner
>
procupper
)
{
readnumber
=
0
;
procpartner
--
;
}
if
(
me
==
procupper
&&
procpartner
!=
procmid
-
1
)
{
readnumber
=
2
;
procpartner2
=
procpartner
+
1
;
}
// wttot = summed weight of entire partition
// search tolerance = largest single weight (plus epsilon)
// targetlo = desired weight in lower half of partition
// targethi = desired weight in upper half of partition
wtmax
=
wtsum
=
0.0
;
if
(
wt
)
{
for
(
i
=
0
;
i
<
ndot
;
i
++
)
{
wtsum
+=
dots
[
i
].
wt
;
if
(
dots
[
i
].
wt
>
wtmax
)
wtmax
=
dots
[
i
].
wt
;
}
}
else
{
for
(
i
=
0
;
i
<
ndot
;
i
++
)
wtsum
+=
dots
[
i
].
wt
;
wtmax
=
1.0
;
}
MPI_Allreduce
(
&
wtsum
,
&
wttot
,
1
,
MPI_DOUBLE
,
MPI_SUM
,
comm
);
if
(
wt
)
MPI_Allreduce
(
&
wtmax
,
&
tolerance
,
1
,
MPI_DOUBLE
,
MPI_MAX
,
comm
);
else
tolerance
=
1.0
;
tolerance
*=
1.0
+
TINY
;
targetlo
=
wttot
*
(
procmid
-
proclower
)
/
(
procupper
+
1
-
proclower
);
targethi
=
wttot
-
targetlo
;
// attempt a cut in each dimension
// each cut produces 2 boxes, each with a reduced box length in that dim
// smaller = the smaller of the 2 reduced box lengths in that dimension
// choose to cut in dimension which produces largest smaller value
// this should induce final proc sub-boxes to be as cube-ish as possible
// dim_select = selected cut dimension
// valuehalf_select = valuehalf in that dimension
// dotmark_select = dot markings in that dimension
int
dim_select
=
-
1
;
double
largest
=
0.0
;
for
(
dim
=
0
;
dim
<
dimension
;
dim
++
)
{
// create active list and mark array for dots
// initialize active list to all dots
if
(
ndot
>
maxlist
)
{
memory
->
destroy
(
dotlist
);
memory
->
destroy
(
dotmark
);
memory
->
destroy
(
dotmark_select
);
maxlist
=
maxdot
;
memory
->
create
(
dotlist
,
maxlist
,
"RCB:dotlist"
);
memory
->
create
(
dotmark
,
maxlist
,
"RCB:dotmark"
);
memory
->
create
(
dotmark_select
,
maxlist
,
"RCB:dotmark_select"
);
}
nlist
=
ndot
;
for
(
i
=
0
;
i
<
nlist
;
i
++
)
dotlist
[
i
]
=
i
;
// median iteration
// zoom in on bisector until correct # of dots in each half of partition
// as each iteration of median-loop begins, require:
// all non-active dots are marked with 0/1 in dotmark
// valuemin <= every active dot <= valuemax
// wtlo, wthi = total wt of non-active dots
// when leave median-loop, require only:
// valuehalf = correct cut position
// all dots <= valuehalf are marked with 0 in dotmark
// all dots >= valuehalf are marked with 1 in dotmark
// markactive = which side of cut is active = 0/1
// indexlo,indexhi = indices of dot closest to median
wtlo
=
wthi
=
0.0
;
valuemin
=
lo
[
dim
];
valuemax
=
hi
[
dim
];
first_iteration
=
1
;
indexlo
=
indexhi
=
0
;
while
(
1
)
{
// choose bisector value
// use old value on 1st iteration if old cut dimension is the same
// on 2nd option: could push valuehalf towards geometric center
// with "1.0-factor" to force overshoot
if
(
first_iteration
&&
reuse
&&
dim
==
tree
[
procmid
].
dim
)
{
counters
[
5
]
++
;
valuehalf
=
tree
[
procmid
].
cut
;
if
(
valuehalf
<
valuemin
||
valuehalf
>
valuemax
)
valuehalf
=
0.5
*
(
valuemin
+
valuemax
);
}
else
if
(
wt
)
valuehalf
=
valuemin
+
(
targetlo
-
wtlo
)
/
(
wttot
-
wtlo
-
wthi
)
*
(
valuemax
-
valuemin
);
else
valuehalf
=
0.5
*
(
valuemin
+
valuemax
);
first_iteration
=
0
;
// initialize local median data structure
medme
.
totallo
=
medme
.
totalhi
=
0.0
;
medme
.
valuelo
=
-
MYHUGE
;
medme
.
valuehi
=
MYHUGE
;
medme
.
wtlo
=
medme
.
wthi
=
0.0
;
medme
.
countlo
=
medme
.
counthi
=
0
;
medme
.
proclo
=
medme
.
prochi
=
me
;
// mark all active dots on one side or other of bisector
// also set all fields in median data struct
// save indices of closest dots on either side
for
(
j
=
0
;
j
<
nlist
;
j
++
)
{
i
=
dotlist
[
j
];
if
(
dots
[
i
].
x
[
dim
]
<=
valuehalf
)
{
// in lower part
medme
.
totallo
+=
dots
[
i
].
wt
;
dotmark
[
i
]
=
0
;
if
(
dots
[
i
].
x
[
dim
]
>
medme
.
valuelo
)
{
// my closest dot
medme
.
valuelo
=
dots
[
i
].
x
[
dim
];
medme
.
wtlo
=
dots
[
i
].
wt
;
medme
.
countlo
=
1
;
indexlo
=
i
;
}
else
if
(
dots
[
i
].
x
[
dim
]
==
medme
.
valuelo
)
{
// tied for closest
medme
.
wtlo
+=
dots
[
i
].
wt
;
medme
.
countlo
++
;
}
}
else
{
// in upper part
medme
.
totalhi
+=
dots
[
i
].
wt
;
dotmark
[
i
]
=
1
;
if
(
dots
[
i
].
x
[
dim
]
<
medme
.
valuehi
)
{
// my closest dot
medme
.
valuehi
=
dots
[
i
].
x
[
dim
];
medme
.
wthi
=
dots
[
i
].
wt
;
medme
.
counthi
=
1
;
indexhi
=
i
;
}
else
if
(
dots
[
i
].
x
[
dim
]
==
medme
.
valuehi
)
{
// tied for closest
medme
.
wthi
+=
dots
[
i
].
wt
;
medme
.
counthi
++
;
}
}
}
// combine median data struct across current subset of procs
counters
[
0
]
++
;
MPI_Allreduce
(
&
medme
,
&
med
,
1
,
med_type
,
med_op
,
comm
);
// test median guess for convergence
// move additional dots that are next to cut across it
if
(
wtlo
+
med
.
totallo
<
targetlo
)
{
// lower half TOO SMALL
wtlo
+=
med
.
totallo
;
valuehalf
=
med
.
valuehi
;
if
(
med
.
counthi
==
1
)
{
// only one dot to move
if
(
wtlo
+
med
.
wthi
<
targetlo
)
{
// move it, keep iterating
if
(
me
==
med
.
prochi
)
dotmark
[
indexhi
]
=
0
;
}
else
{
// only move if beneficial
if
(
wtlo
+
med
.
wthi
-
targetlo
<
targetlo
-
wtlo
)
if
(
me
==
med
.
prochi
)
dotmark
[
indexhi
]
=
0
;
break
;
// all done
}
}
else
{
// multiple dots to move
breakflag
=
0
;
wtok
=
0.0
;
if
(
medme
.
valuehi
==
med
.
valuehi
)
wtok
=
medme
.
wthi
;
if
(
wtlo
+
med
.
wthi
>=
targetlo
)
{
// all done
MPI_Scan
(
&
wtok
,
&
wtupto
,
1
,
MPI_DOUBLE
,
MPI_SUM
,
comm
);
wtmax
=
targetlo
-
wtlo
;
if
(
wtupto
>
wtmax
)
wtok
=
wtok
-
(
wtupto
-
wtmax
);
breakflag
=
1
;
}
// wtok = most I can move
for
(
j
=
0
,
wtsum
=
0.0
;
j
<
nlist
&&
wtsum
<
wtok
;
j
++
)
{
i
=
dotlist
[
j
];
if
(
dots
[
i
].
x
[
dim
]
==
med
.
valuehi
)
{
// only move if better
if
(
wtsum
+
dots
[
i
].
wt
-
wtok
<
wtok
-
wtsum
)
dotmark
[
i
]
=
0
;
wtsum
+=
dots
[
i
].
wt
;
}
}
if
(
breakflag
)
break
;
// done if moved enough
}
wtlo
+=
med
.
wthi
;
if
(
targetlo
-
wtlo
<=
tolerance
)
break
;
// close enough
valuemin
=
med
.
valuehi
;
// iterate again
markactive
=
1
;
}
else
if
(
wthi
+
med
.
totalhi
<
targethi
)
{
// upper half TOO SMALL
wthi
+=
med
.
totalhi
;
valuehalf
=
med
.
valuelo
;
if
(
med
.
countlo
==
1
)
{
// only one dot to move
if
(
wthi
+
med
.
wtlo
<
targethi
)
{
// move it, keep iterating
if
(
me
==
med
.
proclo
)
dotmark
[
indexlo
]
=
1
;
}
else
{
// only move if beneficial
if
(
wthi
+
med
.
wtlo
-
targethi
<
targethi
-
wthi
)
if
(
me
==
med
.
proclo
)
dotmark
[
indexlo
]
=
1
;
break
;
// all done
}
}
else
{
// multiple dots to move
breakflag
=
0
;
wtok
=
0.0
;
if
(
medme
.
valuelo
==
med
.
valuelo
)
wtok
=
medme
.
wtlo
;
if
(
wthi
+
med
.
wtlo
>=
targethi
)
{
// all done
MPI_Scan
(
&
wtok
,
&
wtupto
,
1
,
MPI_DOUBLE
,
MPI_SUM
,
comm
);
wtmax
=
targethi
-
wthi
;
if
(
wtupto
>
wtmax
)
wtok
=
wtok
-
(
wtupto
-
wtmax
);
breakflag
=
1
;
}
// wtok = most I can move
for
(
j
=
0
,
wtsum
=
0.0
;
j
<
nlist
&&
wtsum
<
wtok
;
j
++
)
{
i
=
dotlist
[
j
];
if
(
dots
[
i
].
x
[
dim
]
==
med
.
valuelo
)
{
// only move if better
if
(
wtsum
+
dots
[
i
].
wt
-
wtok
<
wtok
-
wtsum
)
dotmark
[
i
]
=
1
;
wtsum
+=
dots
[
i
].
wt
;
}
}
if
(
breakflag
)
break
;
// done if moved enough
}
wthi
+=
med
.
wtlo
;
if
(
targethi
-
wthi
<=
tolerance
)
break
;
// close enough
valuemax
=
med
.
valuelo
;
// iterate again
markactive
=
0
;
}
else
// Goldilocks result: both partitions just right
break
;
// shrink the active list
k
=
0
;
for
(
j
=
0
;
j
<
nlist
;
j
++
)
{
i
=
dotlist
[
j
];
if
(
dotmark
[
i
]
==
markactive
)
dotlist
[
k
++
]
=
i
;
}
nlist
=
k
;
}
// cut produces 2 sub-boxes with reduced size in dim
// compare smaller of the 2 sizes to previous dims
// keep dim that has the largest smaller
smaller
=
MIN
(
valuehalf
-
lo
[
dim
],
hi
[
dim
]
-
valuehalf
);
if
(
smaller
>
largest
)
{
largest
=
smaller
;
dim_select
=
dim
;
valuehalf_select
=
valuehalf
;
memcpy
(
dotmark_select
,
dotmark
,
ndot
*
sizeof
(
int
));
}
}
// copy results for best dim cut into dim,valuehalf,dotmark
dim
=
dim_select
;
valuehalf
=
valuehalf_select
;
memcpy
(
dotmark
,
dotmark_select
,
ndot
*
sizeof
(
int
));
// found median
// store cut info only if I am procmid
if
(
me
==
procmid
)
{
cut
=
valuehalf
;
cutdim
=
dim
;
}
// use cut to shrink my RCB bounding box
if
(
me
<
procmid
)
hi
[
dim
]
=
valuehalf
;
else
lo
[
dim
]
=
valuehalf
;
// outgoing = number of dots to ship to partner
// nkeep = number of dots that have never migrated
markactive
=
(
me
<
procpartner
);
for
(
i
=
0
,
keep
=
0
,
outgoing
=
0
;
i
<
ndot
;
i
++
)
if
(
dotmark
[
i
]
==
markactive
)
outgoing
++
;
else
if
(
i
<
nkeep
)
keep
++
;
nkeep
=
keep
;
// alert partner how many dots I'll send, read how many I'll recv
MPI_Send
(
&
outgoing
,
1
,
MPI_INT
,
procpartner
,
0
,
world
);
incoming
=
0
;
if
(
readnumber
)
{
MPI_Recv
(
&
incoming
,
1
,
MPI_INT
,
procpartner
,
0
,
world
,
MPI_STATUS_IGNORE
);
if
(
readnumber
==
2
)
{
MPI_Recv
(
&
incoming2
,
1
,
MPI_INT
,
procpartner2
,
0
,
world
,
MPI_STATUS_IGNORE
);
incoming
+=
incoming2
;
}
}
// check if need to alloc more space
int
ndotnew
=
ndot
-
outgoing
+
incoming
;
if
(
ndotnew
>
maxdot
)
{
while
(
maxdot
<
ndotnew
)
maxdot
+=
DELTA
;
dots
=
(
Dot
*
)
memory
->
srealloc
(
dots
,
maxdot
*
sizeof
(
Dot
),
"RCB::dots"
);
counters
[
6
]
++
;
}
counters
[
1
]
+=
outgoing
;
counters
[
2
]
+=
incoming
;
if
(
ndotnew
>
counters
[
3
])
counters
[
3
]
=
ndotnew
;
if
(
maxdot
>
counters
[
4
])
counters
[
4
]
=
maxdot
;
// malloc comm send buffer
if
(
outgoing
>
maxbuf
)
{
memory
->
sfree
(
buf
);
maxbuf
=
outgoing
;
buf
=
(
Dot
*
)
memory
->
smalloc
(
maxbuf
*
sizeof
(
Dot
),
"RCB:buf"
);
}
// fill buffer with dots that are marked for sending
// pack down the unmarked ones
keep
=
outgoing
=
0
;
for
(
i
=
0
;
i
<
ndot
;
i
++
)
{
if
(
dotmark
[
i
]
==
markactive
)
memcpy
(
&
buf
[
outgoing
++
],
&
dots
[
i
],
sizeof
(
Dot
));
else
memcpy
(
&
dots
[
keep
++
],
&
dots
[
i
],
sizeof
(
Dot
));
}
// post receives for dots
if
(
readnumber
>
0
)
{
MPI_Irecv
(
&
dots
[
keep
],
incoming
*
sizeof
(
Dot
),
MPI_CHAR
,
procpartner
,
1
,
world
,
&
request
);
if
(
readnumber
==
2
)
{
keep
+=
incoming
-
incoming2
;
MPI_Irecv
(
&
dots
[
keep
],
incoming2
*
sizeof
(
Dot
),
MPI_CHAR
,
procpartner2
,
1
,
world
,
&
request2
);
}
}
// handshake before sending dots to insure recvs have been posted
if
(
readnumber
>
0
)
{
MPI_Send
(
NULL
,
0
,
MPI_INT
,
procpartner
,
0
,
world
);
if
(
readnumber
==
2
)
MPI_Send
(
NULL
,
0
,
MPI_INT
,
procpartner2
,
0
,
world
);
}
MPI_Recv
(
NULL
,
0
,
MPI_INT
,
procpartner
,
0
,
world
,
MPI_STATUS_IGNORE
);
// send dots to partner
MPI_Rsend
(
buf
,
outgoing
*
sizeof
(
Dot
),
MPI_CHAR
,
procpartner
,
1
,
world
);
// wait until all dots are received
if
(
readnumber
>
0
)
{
MPI_Wait
(
&
request
,
MPI_STATUS_IGNORE
);
if
(
readnumber
==
2
)
MPI_Wait
(
&
request2
,
MPI_STATUS_IGNORE
);
}
ndot
=
ndotnew
;
// cut partition in half, create new communicators of 1/2 size
int
split
;
if
(
me
<
procmid
)
{
procupper
=
procmid
-
1
;
split
=
0
;
}
else
{
proclower
=
procmid
;
split
=
1
;
}
MPI_Comm_split
(
comm
,
split
,
me
,
&
comm_half
);
MPI_Comm_free
(
&
comm
);
comm
=
comm_half
;
}
// clean up
MPI_Comm_free
(
&
comm
);
// set public variables with results of rebalance
nfinal
=
ndot
;
if
(
nfinal
>
maxrecv
)
{
memory
->
destroy
(
recvproc
);
memory
->
destroy
(
recvindex
);
maxrecv
=
nfinal
;
memory
->
create
(
recvproc
,
maxrecv
,
"RCB:recvproc"
);
memory
->
create
(
recvindex
,
maxrecv
,
"RCB:recvindex"
);
}
for
(
i
=
0
;
i
<
nfinal
;
i
++
)
{
recvproc
[
i
]
=
dots
[
i
].
proc
;
recvindex
[
i
]
=
dots
[
i
].
index
;
}
}
/* ----------------------------------------------------------------------
perform RCB balancing of N particles at coords X in bounding box LO/HI
OLD version: each RCB cut is made in longest dimension of sub-box
if wt = NULL, ignore per-particle weights
if wt defined, per-particle weights > 0.0
dimension = 2 or 3
as documented in rcb.h:
sets noriginal,nfinal,nkeep,recvproc,recvindex,lo,hi
all proc particles will be inside or on surface of 3-d box
defined by final lo/hi
// NOTE: worry about re-use of data structs for fix balance?
------------------------------------------------------------------------- */
void
RCB
::
compute_old
(
int
dimension
,
int
n
,
double
**
x
,
double
*
wt
,
double
*
bboxlo
,
double
*
bboxhi
)
{
int
i
,
j
,
k
;
int
keep
,
outgoing
,
incoming
,
incoming2
;
int
dim
,
markactive
;
int
indexlo
,
indexhi
;
int
first_iteration
,
breakflag
;
double
wttot
,
wtlo
,
wthi
,
wtsum
,
wtok
,
wtupto
,
wtmax
;
double
targetlo
,
targethi
;
double
valuemin
,
valuemax
,
valuehalf
;
double
tolerance
;
MPI_Comm
comm
,
comm_half
;
MPI_Request
request
,
request2
;
Median
med
,
medme
;
// create list of my Dots
ndot
=
nkeep
=
noriginal
=
n
;
if
(
ndot
>
maxdot
)
{
maxdot
=
ndot
;
memory
->
sfree
(
dots
);
dots
=
(
Dot
*
)
memory
->
smalloc
(
ndot
*
sizeof
(
Dot
),
"RCB:dots"
);
}
for
(
i
=
0
;
i
<
ndot
;
i
++
)
{
dots
[
i
].
x
[
0
]
=
x
[
i
][
0
];
dots
[
i
].
x
[
1
]
=
x
[
i
][
1
];
dots
[
i
].
x
[
2
]
=
x
[
i
][
2
];
dots
[
i
].
proc
=
me
;
dots
[
i
].
index
=
i
;
}
if
(
wt
)
for
(
i
=
0
;
i
<
ndot
;
i
++
)
dots
[
i
].
wt
=
wt
[
i
];
else
for
(
i
=
0
;
i
<
ndot
;
i
++
)
dots
[
i
].
wt
=
1.0
;
// initial bounding box = simulation box
// includes periodic or shrink-wrapped boundaries
lo
=
bbox
.
lo
;
hi
=
bbox
.
hi
;
lo
[
0
]
=
bboxlo
[
0
];
lo
[
1
]
=
bboxlo
[
1
];
lo
[
2
]
=
bboxlo
[
2
];
hi
[
0
]
=
bboxhi
[
0
];
hi
[
1
]
=
bboxhi
[
1
];
hi
[
2
]
=
bboxhi
[
2
];
cut
=
0.0
;
cutdim
=
-
1
;
// initialize counters
counters
[
0
]
=
0
;
counters
[
1
]
=
0
;
counters
[
2
]
=
0
;
counters
[
3
]
=
ndot
;
counters
[
4
]
=
maxdot
;
counters
[
5
]
=
0
;
counters
[
6
]
=
0
;
// create communicator for use in recursion
MPI_Comm_dup
(
world
,
&
comm
);
// recurse until partition is a single proc = me
// proclower,procupper = lower,upper procs in partition
// procmid = 1st proc in upper half of partition
int
procpartner
,
procpartner2
;
int
procmid
;
int
proclower
=
0
;
int
procupper
=
nprocs
-
1
;
while
(
proclower
!=
procupper
)
{
// if odd # of procs, lower partition gets extra one
procmid
=
proclower
+
(
procupper
-
proclower
)
/
2
+
1
;
// determine communication partner(s)
// readnumber = # of proc partners to read from
if
(
me
<
procmid
)
procpartner
=
me
+
(
procmid
-
proclower
);
else
procpartner
=
me
-
(
procmid
-
proclower
);
int
readnumber
=
1
;
if
(
procpartner
>
procupper
)
{
readnumber
=
0
;
procpartner
--
;
}
if
(
me
==
procupper
&&
procpartner
!=
procmid
-
1
)
{
readnumber
=
2
;
procpartner2
=
procpartner
+
1
;
}
// wttot = summed weight of entire partition
// search tolerance = largest single weight (plus epsilon)
// targetlo = desired weight in lower half of partition
// targethi = desired weight in upper half of partition
wtmax
=
wtsum
=
0.0
;
if
(
wt
)
{
for
(
i
=
0
;
i
<
ndot
;
i
++
)
{
wtsum
+=
dots
[
i
].
wt
;
if
(
dots
[
i
].
wt
>
wtmax
)
wtmax
=
dots
[
i
].
wt
;
}
}
else
{
for
(
i
=
0
;
i
<
ndot
;
i
++
)
wtsum
+=
dots
[
i
].
wt
;
wtmax
=
1.0
;
}
MPI_Allreduce
(
&
wtsum
,
&
wttot
,
1
,
MPI_DOUBLE
,
MPI_SUM
,
comm
);
if
(
wt
)
MPI_Allreduce
(
&
wtmax
,
&
tolerance
,
1
,
MPI_DOUBLE
,
MPI_MAX
,
comm
);
else
tolerance
=
1.0
;
tolerance
*=
1.0
+
TINY
;
targetlo
=
wttot
*
(
procmid
-
proclower
)
/
(
procupper
+
1
-
proclower
);
targethi
=
wttot
-
targetlo
;
// dim = dimension to bisect on
// do not allow choice of z dimension for 2d system
dim
=
0
;
if
(
hi
[
1
]
-
lo
[
1
]
>
hi
[
0
]
-
lo
[
0
])
dim
=
1
;
if
(
dimension
==
3
)
{
if
(
dim
==
0
&&
hi
[
2
]
-
lo
[
2
]
>
hi
[
0
]
-
lo
[
0
])
dim
=
2
;
if
(
dim
==
1
&&
hi
[
2
]
-
lo
[
2
]
>
hi
[
1
]
-
lo
[
1
])
dim
=
2
;
}
// create active list and mark array for dots
// initialize active list to all dots
if
(
ndot
>
maxlist
)
{
memory
->
destroy
(
dotlist
);
memory
->
destroy
(
dotmark
);
maxlist
=
maxdot
;
memory
->
create
(
dotlist
,
maxlist
,
"RCB:dotlist"
);
memory
->
create
(
dotmark
,
maxlist
,
"RCB:dotmark"
);
}
nlist
=
ndot
;
for
(
i
=
0
;
i
<
nlist
;
i
++
)
dotlist
[
i
]
=
i
;
// median iteration
// zoom in on bisector until correct # of dots in each half of partition
// as each iteration of median-loop begins, require:
// all non-active dots are marked with 0/1 in dotmark
// valuemin <= every active dot <= valuemax
// wtlo, wthi = total wt of non-active dots
// when leave median-loop, require only:
// valuehalf = correct cut position
// all dots <= valuehalf are marked with 0 in dotmark
// all dots >= valuehalf are marked with 1 in dotmark
// markactive = which side of cut is active = 0/1
// indexlo,indexhi = indices of dot closest to median
wtlo
=
wthi
=
0.0
;
valuemin
=
lo
[
dim
];
valuemax
=
hi
[
dim
];
first_iteration
=
1
;
indexlo
=
indexhi
=
0
;
while
(
1
)
{
// choose bisector value
// use old value on 1st iteration if old cut dimension is the same
// on 2nd option: could push valuehalf towards geometric center
// with "1.0-factor" to force overshoot
if
(
first_iteration
&&
reuse
&&
dim
==
tree
[
procmid
].
dim
)
{
counters
[
5
]
++
;
valuehalf
=
tree
[
procmid
].
cut
;
if
(
valuehalf
<
valuemin
||
valuehalf
>
valuemax
)
valuehalf
=
0.5
*
(
valuemin
+
valuemax
);
}
else
if
(
wt
)
valuehalf
=
valuemin
+
(
targetlo
-
wtlo
)
/
(
wttot
-
wtlo
-
wthi
)
*
(
valuemax
-
valuemin
);
else
valuehalf
=
0.5
*
(
valuemin
+
valuemax
);
first_iteration
=
0
;
// initialize local median data structure
medme
.
totallo
=
medme
.
totalhi
=
0.0
;
medme
.
valuelo
=
-
MYHUGE
;
medme
.
valuehi
=
MYHUGE
;
medme
.
wtlo
=
medme
.
wthi
=
0.0
;
medme
.
countlo
=
medme
.
counthi
=
0
;
medme
.
proclo
=
medme
.
prochi
=
me
;
// mark all active dots on one side or other of bisector
// also set all fields in median data struct
// save indices of closest dots on either side
for
(
j
=
0
;
j
<
nlist
;
j
++
)
{
i
=
dotlist
[
j
];
if
(
dots
[
i
].
x
[
dim
]
<=
valuehalf
)
{
// in lower part
medme
.
totallo
+=
dots
[
i
].
wt
;
dotmark
[
i
]
=
0
;
if
(
dots
[
i
].
x
[
dim
]
>
medme
.
valuelo
)
{
// my closest dot
medme
.
valuelo
=
dots
[
i
].
x
[
dim
];
medme
.
wtlo
=
dots
[
i
].
wt
;
medme
.
countlo
=
1
;
indexlo
=
i
;
}
else
if
(
dots
[
i
].
x
[
dim
]
==
medme
.
valuelo
)
{
// tied for closest
medme
.
wtlo
+=
dots
[
i
].
wt
;
medme
.
countlo
++
;
}
}
else
{
// in upper part
medme
.
totalhi
+=
dots
[
i
].
wt
;
dotmark
[
i
]
=
1
;
if
(
dots
[
i
].
x
[
dim
]
<
medme
.
valuehi
)
{
// my closest dot
medme
.
valuehi
=
dots
[
i
].
x
[
dim
];
medme
.
wthi
=
dots
[
i
].
wt
;
medme
.
counthi
=
1
;
indexhi
=
i
;
}
else
if
(
dots
[
i
].
x
[
dim
]
==
medme
.
valuehi
)
{
// tied for closest
medme
.
wthi
+=
dots
[
i
].
wt
;
medme
.
counthi
++
;
}
}
}
// combine median data struct across current subset of procs
counters
[
0
]
++
;
MPI_Allreduce
(
&
medme
,
&
med
,
1
,
med_type
,
med_op
,
comm
);
// test median guess for convergence
// move additional dots that are next to cut across it
if
(
wtlo
+
med
.
totallo
<
targetlo
)
{
// lower half TOO SMALL
wtlo
+=
med
.
totallo
;
valuehalf
=
med
.
valuehi
;
if
(
med
.
counthi
==
1
)
{
// only one dot to move
if
(
wtlo
+
med
.
wthi
<
targetlo
)
{
// move it, keep iterating
if
(
me
==
med
.
prochi
)
dotmark
[
indexhi
]
=
0
;
}
else
{
// only move if beneficial
if
(
wtlo
+
med
.
wthi
-
targetlo
<
targetlo
-
wtlo
)
if
(
me
==
med
.
prochi
)
dotmark
[
indexhi
]
=
0
;
break
;
// all done
}
}
else
{
// multiple dots to move
breakflag
=
0
;
wtok
=
0.0
;
if
(
medme
.
valuehi
==
med
.
valuehi
)
wtok
=
medme
.
wthi
;
if
(
wtlo
+
med
.
wthi
>=
targetlo
)
{
// all done
MPI_Scan
(
&
wtok
,
&
wtupto
,
1
,
MPI_DOUBLE
,
MPI_SUM
,
comm
);
wtmax
=
targetlo
-
wtlo
;
if
(
wtupto
>
wtmax
)
wtok
=
wtok
-
(
wtupto
-
wtmax
);
breakflag
=
1
;
}
// wtok = most I can move
for
(
j
=
0
,
wtsum
=
0.0
;
j
<
nlist
&&
wtsum
<
wtok
;
j
++
)
{
i
=
dotlist
[
j
];
if
(
dots
[
i
].
x
[
dim
]
==
med
.
valuehi
)
{
// only move if better
if
(
wtsum
+
dots
[
i
].
wt
-
wtok
<
wtok
-
wtsum
)
dotmark
[
i
]
=
0
;
wtsum
+=
dots
[
i
].
wt
;
}
}
if
(
breakflag
)
break
;
// done if moved enough
}
wtlo
+=
med
.
wthi
;
if
(
targetlo
-
wtlo
<=
tolerance
)
break
;
// close enough
valuemin
=
med
.
valuehi
;
// iterate again
markactive
=
1
;
}
else
if
(
wthi
+
med
.
totalhi
<
targethi
)
{
// upper half TOO SMALL
wthi
+=
med
.
totalhi
;
valuehalf
=
med
.
valuelo
;
if
(
med
.
countlo
==
1
)
{
// only one dot to move
if
(
wthi
+
med
.
wtlo
<
targethi
)
{
// move it, keep iterating
if
(
me
==
med
.
proclo
)
dotmark
[
indexlo
]
=
1
;
}
else
{
// only move if beneficial
if
(
wthi
+
med
.
wtlo
-
targethi
<
targethi
-
wthi
)
if
(
me
==
med
.
proclo
)
dotmark
[
indexlo
]
=
1
;
break
;
// all done
}
}
else
{
// multiple dots to move
breakflag
=
0
;
wtok
=
0.0
;
if
(
medme
.
valuelo
==
med
.
valuelo
)
wtok
=
medme
.
wtlo
;
if
(
wthi
+
med
.
wtlo
>=
targethi
)
{
// all done
MPI_Scan
(
&
wtok
,
&
wtupto
,
1
,
MPI_DOUBLE
,
MPI_SUM
,
comm
);
wtmax
=
targethi
-
wthi
;
if
(
wtupto
>
wtmax
)
wtok
=
wtok
-
(
wtupto
-
wtmax
);
breakflag
=
1
;
}
// wtok = most I can move
for
(
j
=
0
,
wtsum
=
0.0
;
j
<
nlist
&&
wtsum
<
wtok
;
j
++
)
{
i
=
dotlist
[
j
];
if
(
dots
[
i
].
x
[
dim
]
==
med
.
valuelo
)
{
// only move if better
if
(
wtsum
+
dots
[
i
].
wt
-
wtok
<
wtok
-
wtsum
)
dotmark
[
i
]
=
1
;
wtsum
+=
dots
[
i
].
wt
;
}
}
if
(
breakflag
)
break
;
// done if moved enough
}
wthi
+=
med
.
wtlo
;
if
(
targethi
-
wthi
<=
tolerance
)
break
;
// close enough
valuemax
=
med
.
valuelo
;
// iterate again
markactive
=
0
;
}
else
// Goldilocks result: both partitions just right
break
;
// shrink the active list
k
=
0
;
for
(
j
=
0
;
j
<
nlist
;
j
++
)
{
i
=
dotlist
[
j
];
if
(
dotmark
[
i
]
==
markactive
)
dotlist
[
k
++
]
=
i
;
}
nlist
=
k
;
}
// found median
// store cut info only if I am procmid
if
(
me
==
procmid
)
{
cut
=
valuehalf
;
cutdim
=
dim
;
}
// use cut to shrink my RCB bounding box
if
(
me
<
procmid
)
hi
[
dim
]
=
valuehalf
;
else
lo
[
dim
]
=
valuehalf
;
// outgoing = number of dots to ship to partner
// nkeep = number of dots that have never migrated
markactive
=
(
me
<
procpartner
);
for
(
i
=
0
,
keep
=
0
,
outgoing
=
0
;
i
<
ndot
;
i
++
)
if
(
dotmark
[
i
]
==
markactive
)
outgoing
++
;
else
if
(
i
<
nkeep
)
keep
++
;
nkeep
=
keep
;
// alert partner how many dots I'll send, read how many I'll recv
MPI_Send
(
&
outgoing
,
1
,
MPI_INT
,
procpartner
,
0
,
world
);
incoming
=
0
;
if
(
readnumber
)
{
MPI_Recv
(
&
incoming
,
1
,
MPI_INT
,
procpartner
,
0
,
world
,
MPI_STATUS_IGNORE
);
if
(
readnumber
==
2
)
{
MPI_Recv
(
&
incoming2
,
1
,
MPI_INT
,
procpartner2
,
0
,
world
,
MPI_STATUS_IGNORE
);
incoming
+=
incoming2
;
}
}
// check if need to alloc more space
int
ndotnew
=
ndot
-
outgoing
+
incoming
;
if
(
ndotnew
>
maxdot
)
{
while
(
maxdot
<
ndotnew
)
maxdot
+=
DELTA
;
dots
=
(
Dot
*
)
memory
->
srealloc
(
dots
,
maxdot
*
sizeof
(
Dot
),
"RCB::dots"
);
counters
[
6
]
++
;
}
counters
[
1
]
+=
outgoing
;
counters
[
2
]
+=
incoming
;
if
(
ndotnew
>
counters
[
3
])
counters
[
3
]
=
ndotnew
;
if
(
maxdot
>
counters
[
4
])
counters
[
4
]
=
maxdot
;
// malloc comm send buffer
if
(
outgoing
>
maxbuf
)
{
memory
->
sfree
(
buf
);
maxbuf
=
outgoing
;
buf
=
(
Dot
*
)
memory
->
smalloc
(
maxbuf
*
sizeof
(
Dot
),
"RCB:buf"
);
}
// fill buffer with dots that are marked for sending
// pack down the unmarked ones
keep
=
outgoing
=
0
;
for
(
i
=
0
;
i
<
ndot
;
i
++
)
{
if
(
dotmark
[
i
]
==
markactive
)
memcpy
(
&
buf
[
outgoing
++
],
&
dots
[
i
],
sizeof
(
Dot
));
else
memcpy
(
&
dots
[
keep
++
],
&
dots
[
i
],
sizeof
(
Dot
));
}
// post receives for dots
if
(
readnumber
>
0
)
{
MPI_Irecv
(
&
dots
[
keep
],
incoming
*
sizeof
(
Dot
),
MPI_CHAR
,
procpartner
,
1
,
world
,
&
request
);
if
(
readnumber
==
2
)
{
keep
+=
incoming
-
incoming2
;
MPI_Irecv
(
&
dots
[
keep
],
incoming2
*
sizeof
(
Dot
),
MPI_CHAR
,
procpartner2
,
1
,
world
,
&
request2
);
}
}
// handshake before sending dots to insure recvs have been posted
if
(
readnumber
>
0
)
{
MPI_Send
(
NULL
,
0
,
MPI_INT
,
procpartner
,
0
,
world
);
if
(
readnumber
==
2
)
MPI_Send
(
NULL
,
0
,
MPI_INT
,
procpartner2
,
0
,
world
);
}
MPI_Recv
(
NULL
,
0
,
MPI_INT
,
procpartner
,
0
,
world
,
MPI_STATUS_IGNORE
);
// send dots to partner
MPI_Rsend
(
buf
,
outgoing
*
sizeof
(
Dot
),
MPI_CHAR
,
procpartner
,
1
,
world
);
// wait until all dots are received
if
(
readnumber
>
0
)
{
MPI_Wait
(
&
request
,
MPI_STATUS_IGNORE
);
if
(
readnumber
==
2
)
MPI_Wait
(
&
request2
,
MPI_STATUS_IGNORE
);
}
ndot
=
ndotnew
;
// cut partition in half, create new communicators of 1/2 size
int
split
;
if
(
me
<
procmid
)
{
procupper
=
procmid
-
1
;
split
=
0
;
}
else
{
proclower
=
procmid
;
split
=
1
;
}
MPI_Comm_split
(
comm
,
split
,
me
,
&
comm_half
);
MPI_Comm_free
(
&
comm
);
comm
=
comm_half
;
}
// clean up
MPI_Comm_free
(
&
comm
);
// set public variables with results of rebalance
nfinal
=
ndot
;
if
(
nfinal
>
maxrecv
)
{
memory
->
destroy
(
recvproc
);
memory
->
destroy
(
recvindex
);
maxrecv
=
nfinal
;
memory
->
create
(
recvproc
,
maxrecv
,
"RCB:recvproc"
);
memory
->
create
(
recvindex
,
maxrecv
,
"RCB:recvindex"
);
}
for
(
i
=
0
;
i
<
nfinal
;
i
++
)
{
recvproc
[
i
]
=
dots
[
i
].
proc
;
recvindex
[
i
]
=
dots
[
i
].
index
;
}
}
/* ----------------------------------------------------------------------
custom MPI reduce operation
merge of each component of an RCB bounding box
------------------------------------------------------------------------- */
void
box_merge
(
void
*
in
,
void
*
inout
,
int
*
len
,
MPI_Datatype
*
dptr
)
{
RCB
::
BBox
*
box1
=
(
RCB
::
BBox
*
)
in
;
RCB
::
BBox
*
box2
=
(
RCB
::
BBox
*
)
inout
;
for
(
int
i
=
0
;
i
<
3
;
i
++
)
{
if
(
box1
->
lo
[
i
]
<
box2
->
lo
[
i
])
box2
->
lo
[
i
]
=
box1
->
lo
[
i
];
if
(
box1
->
hi
[
i
]
>
box2
->
hi
[
i
])
box2
->
hi
[
i
]
=
box1
->
hi
[
i
];
}
}
/* ----------------------------------------------------------------------
custom MPI reduce operation
merge median data structure
on input:
in,inout->totallo, totalhi = weight in both partitions on this proc
valuelo, valuehi = pos of nearest dot(s) to cut on this proc
wtlo, wthi = total wt of dot(s) at that pos on this proc
countlo, counthi = # of dot(s) nearest to cut on this proc
proclo, prochi = not used
on exit:
inout-> totallo, totalhi = total # of active dots in both partitions
valuelo, valuehi = pos of nearest dot(s) to cut
wtlo, wthi = total wt of dot(s) at that position
countlo, counthi = total # of dot(s) nearest to cut
proclo, prochi = one unique proc who owns a nearest dot
all procs must get same proclo,prochi
------------------------------------------------------------------------- */
void
median_merge
(
void
*
in
,
void
*
inout
,
int
*
len
,
MPI_Datatype
*
dptr
)
{
RCB
::
Median
*
med1
=
(
RCB
::
Median
*
)
in
;
RCB
::
Median
*
med2
=
(
RCB
::
Median
*
)
inout
;
med2
->
totallo
+=
med1
->
totallo
;
if
(
med1
->
valuelo
>
med2
->
valuelo
)
{
med2
->
valuelo
=
med1
->
valuelo
;
med2
->
wtlo
=
med1
->
wtlo
;
med2
->
countlo
=
med1
->
countlo
;
med2
->
proclo
=
med1
->
proclo
;
}
else
if
(
med1
->
valuelo
==
med2
->
valuelo
)
{
med2
->
wtlo
+=
med1
->
wtlo
;
med2
->
countlo
+=
med1
->
countlo
;
if
(
med1
->
proclo
<
med2
->
proclo
)
med2
->
proclo
=
med1
->
proclo
;
}
med2
->
totalhi
+=
med1
->
totalhi
;
if
(
med1
->
valuehi
<
med2
->
valuehi
)
{
med2
->
valuehi
=
med1
->
valuehi
;
med2
->
wthi
=
med1
->
wthi
;
med2
->
counthi
=
med1
->
counthi
;
med2
->
prochi
=
med1
->
prochi
;
}
else
if
(
med1
->
valuehi
==
med2
->
valuehi
)
{
med2
->
wthi
+=
med1
->
wthi
;
med2
->
counthi
+=
med1
->
counthi
;
if
(
med1
->
prochi
<
med2
->
prochi
)
med2
->
prochi
=
med1
->
prochi
;
}
}
/* ----------------------------------------------------------------------
invert the RCB rebalance result to convert receive info into send info
sortflag = flag for sorting order of received messages by proc ID
------------------------------------------------------------------------- */
void
RCB
::
invert
(
int
sortflag
)
{
// only create Irregular if not previously created
// allows Irregular to persist for multiple RCB calls by fix balance
if
(
!
irregular
)
irregular
=
new
Irregular
(
lmp
);
// nsend = # of dots to request from other procs
int
nsend
=
nfinal
-
nkeep
;
int
*
proclist
;
memory
->
create
(
proclist
,
nsend
,
"RCB:proclist"
);
Invert
*
sinvert
=
(
Invert
*
)
memory
->
smalloc
(
nsend
*
sizeof
(
Invert
),
"RCB:sinvert"
);
int
m
=
0
;
for
(
int
i
=
nkeep
;
i
<
nfinal
;
i
++
)
{
proclist
[
m
]
=
recvproc
[
i
];
sinvert
[
m
].
rindex
=
recvindex
[
i
];
sinvert
[
m
].
sproc
=
me
;
sinvert
[
m
].
sindex
=
i
;
m
++
;
}
// perform inversion via irregular comm
// nrecv = # of my dots to send to other procs
int
nrecv
=
irregular
->
create_data
(
nsend
,
proclist
,
sortflag
);
Invert
*
rinvert
=
(
Invert
*
)
memory
->
smalloc
(
nrecv
*
sizeof
(
Invert
),
"RCB:rinvert"
);
irregular
->
exchange_data
((
char
*
)
sinvert
,
sizeof
(
Invert
),(
char
*
)
rinvert
);
irregular
->
destroy_data
();
// set public variables from requests to send my dots
if
(
noriginal
>
maxsend
)
{
memory
->
destroy
(
sendproc
);
memory
->
destroy
(
sendindex
);
maxsend
=
noriginal
;
memory
->
create
(
sendproc
,
maxsend
,
"RCB:sendproc"
);
memory
->
create
(
sendindex
,
maxsend
,
"RCB:sendindex"
);
}
for
(
int
i
=
0
;
i
<
nkeep
;
i
++
)
{
sendproc
[
recvindex
[
i
]]
=
me
;
sendindex
[
recvindex
[
i
]]
=
i
;
}
for
(
int
i
=
0
;
i
<
nrecv
;
i
++
)
{
m
=
rinvert
[
i
].
rindex
;
sendproc
[
m
]
=
rinvert
[
i
].
sproc
;
sendindex
[
m
]
=
rinvert
[
i
].
sindex
;
}
// clean-up
memory
->
destroy
(
proclist
);
memory
->
destroy
(
sinvert
);
memory
->
destroy
(
rinvert
);
}
/* ----------------------------------------------------------------------
memory use of Irregular
------------------------------------------------------------------------- */
bigint
RCB
::
memory_usage
()
{
bigint
bytes
=
0
;
if
(
irregular
)
bytes
+=
irregular
->
memory_usage
();
return
bytes
;
}
// -----------------------------------------------------------------------
// DEBUG methods
// -----------------------------------------------------------------------
/*
// consistency checks on RCB results
void RCB::check()
{
int i,iflag,total1,total2;
double weight,wtmax,wtmin,wtone,tolerance;
// check that total # of dots remained the same
MPI_Allreduce(&ndotorig,&total1,1,MPI_INT,MPI_SUM,world);
MPI_Allreduce(&ndot,&total2,1,MPI_INT,MPI_SUM,world);
if (total1 != total2) {
if (me == 0)
printf("ERROR: Points before RCB = %d, Points after RCB = %d\n",
total1,total2);
}
// check that result is load-balanced within log2(P)*max-wt
weight = wtone = 0.0;
for (i = 0; i < ndot; i++) {
weight += dots[i].wt;
if (dots[i].wt > wtone) wtone = dots[i].wt;
}
MPI_Allreduce(&weight,&wtmin,1,MPI_DOUBLE,MPI_MIN,world);
MPI_Allreduce(&weight,&wtmax,1,MPI_DOUBLE,MPI_MAX,world);
MPI_Allreduce(&wtone,&tolerance,1,MPI_DOUBLE,MPI_MAX,world);
// i = smallest power-of-2 >= nprocs
// tolerance = largest-single-weight*log2(nprocs)
for (i = 0; (nprocs >> i) != 0; i++);
tolerance = tolerance * i * (1.0 + TINY);
if (wtmax - wtmin > tolerance) {
if (me == 0)
printf("ERROR: Load-imbalance > tolerance of %g\n",tolerance);
MPI_Barrier(world);
if (weight == wtmin) printf(" Proc %d has weight = %g\n",me,weight);
if (weight == wtmax) printf(" Proc %d has weight = %g\n",me,weight);
}
MPI_Barrier(world);
// check that final set of points is inside RCB box of each proc
iflag = 0;
for (i = 0; i < ndot; i++) {
if (dots[i].x[0] < lo[0] || dots[i].x[0] > hi[0] ||
dots[i].x[1] < lo[1] || dots[i].x[1] > hi[1] ||
dots[i].x[2] < lo[2] || dots[i].x[2] > hi[2])
iflag++;
}
if (iflag > 0)
printf("ERROR: %d points are out-of-box on proc %d\n",iflag,me);
}
// stats for RCB decomposition
void RCB::stats(int flag)
{
int i,iflag,sum,min,max;
double ave,rsum,rmin,rmax;
double weight,wttot,wtmin,wtmax;
if (me == 0) printf("RCB Statistics:\n");
// distribution info
for (i = 0, weight = 0.0; i < ndot; i++) weight += dots[i].wt;
MPI_Allreduce(&weight,&wttot,1,MPI_DOUBLE,MPI_SUM,world);
MPI_Allreduce(&weight,&wtmin,1,MPI_DOUBLE,MPI_MIN,world);
MPI_Allreduce(&weight,&wtmax,1,MPI_DOUBLE,MPI_MAX,world);
if (me == 0) {
printf(" Total weight of dots = %g\n",wttot);
printf(" Weight on each proc: ave = %g, max = %g, min = %g\n",
wttot/nprocs,wtmax,wtmin);
}
if (flag) {
MPI_Barrier(world);
printf(" Proc %d has weight = %g\n",me,weight);
}
for (i = 0, weight = 0.0; i < ndot; i++)
if (dots[i].wt > weight) weight = dots[i].wt;
MPI_Allreduce(&weight,&wtmax,1,MPI_DOUBLE,MPI_MAX,world);
if (me == 0) printf(" Maximum weight of single dot = %g\n",wtmax);
if (flag) {
MPI_Barrier(world);
printf(" Proc %d max weight = %g\n",me,weight);
}
// counter info
MPI_Allreduce(&counters[0],&sum,1,MPI_INT,MPI_SUM,world);
MPI_Allreduce(&counters[0],&min,1,MPI_INT,MPI_MIN,world);
MPI_Allreduce(&counters[0],&max,1,MPI_INT,MPI_MAX,world);
ave = ((double) sum)/nprocs;
if (me == 0)
printf(" Median iter: ave = %g, min = %d, max = %d\n",ave,min,max);
if (flag) {
MPI_Barrier(world);
printf(" Proc %d median count = %d\n",me,counters[0]);
}
MPI_Allreduce(&counters[1],&sum,1,MPI_INT,MPI_SUM,world);
MPI_Allreduce(&counters[1],&min,1,MPI_INT,MPI_MIN,world);
MPI_Allreduce(&counters[1],&max,1,MPI_INT,MPI_MAX,world);
ave = ((double) sum)/nprocs;
if (me == 0)
printf(" Send count: ave = %g, min = %d, max = %d\n",ave,min,max);
if (flag) {
MPI_Barrier(world);
printf(" Proc %d send count = %d\n",me,counters[1]);
}
MPI_Allreduce(&counters[2],&sum,1,MPI_INT,MPI_SUM,world);
MPI_Allreduce(&counters[2],&min,1,MPI_INT,MPI_MIN,world);
MPI_Allreduce(&counters[2],&max,1,MPI_INT,MPI_MAX,world);
ave = ((double) sum)/nprocs;
if (me == 0)
printf(" Recv count: ave = %g, min = %d, max = %d\n",ave,min,max);
if (flag) {
MPI_Barrier(world);
printf(" Proc %d recv count = %d\n",me,counters[2]);
}
MPI_Allreduce(&counters[3],&sum,1,MPI_INT,MPI_SUM,world);
MPI_Allreduce(&counters[3],&min,1,MPI_INT,MPI_MIN,world);
MPI_Allreduce(&counters[3],&max,1,MPI_INT,MPI_MAX,world);
ave = ((double) sum)/nprocs;
if (me == 0)
printf(" Max dots: ave = %g, min = %d, max = %d\n",ave,min,max);
if (flag) {
MPI_Barrier(world);
printf(" Proc %d max dots = %d\n",me,counters[3]);
}
MPI_Allreduce(&counters[4],&sum,1,MPI_INT,MPI_SUM,world);
MPI_Allreduce(&counters[4],&min,1,MPI_INT,MPI_MIN,world);
MPI_Allreduce(&counters[4],&max,1,MPI_INT,MPI_MAX,world);
ave = ((double) sum)/nprocs;
if (me == 0)
printf(" Max memory: ave = %g, min = %d, max = %d\n",ave,min,max);
if (flag) {
MPI_Barrier(world);
printf(" Proc %d max memory = %d\n",me,counters[4]);
}
if (reuse) {
MPI_Allreduce(&counters[5],&sum,1,MPI_INT,MPI_SUM,world);
MPI_Allreduce(&counters[5],&min,1,MPI_INT,MPI_MIN,world);
MPI_Allreduce(&counters[5],&max,1,MPI_INT,MPI_MAX,world);
ave = ((double) sum)/nprocs;
if (me == 0)
printf(" # of Reuse: ave = %g, min = %d, max = %d\n",ave,min,max);
if (flag) {
MPI_Barrier(world);
printf(" Proc %d # of Reuse = %d\n",me,counters[5]);
}
}
MPI_Allreduce(&counters[6],&sum,1,MPI_INT,MPI_SUM,world);
MPI_Allreduce(&counters[6],&min,1,MPI_INT,MPI_MIN,world);
MPI_Allreduce(&counters[6],&max,1,MPI_INT,MPI_MAX,world);
ave = ((double) sum)/nprocs;
if (me == 0)
printf(" # of OverAlloc: ave = %g, min = %d, max = %d\n",ave,min,max);
if (flag) {
MPI_Barrier(world);
printf(" Proc %d # of OverAlloc = %d\n",me,counters[6]);
}
// RCB boxes for each proc
if (flag) {
if (me == 0) printf(" RCB sub-domain boxes:\n");
for (i = 0; i < 3; i++) {
MPI_Barrier(world);
if (me == 0) printf(" Dimension %d\n",i+1);
MPI_Barrier(world);
printf(" Proc = %d: Box = %g %g\n",me,lo[i],hi[i]);
}
}
}
*/
Event Timeline
Log In to Comment