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openmpi/ompi/mca/coll/tuned/coll_tuned_allgatherv.c
Jeff Squyres e7ecd56bd2 This commit represents a bunch of work on a Mercurial side branch. As 
such, the commit message back to the master SVN repository is fairly
long.

= ORTE Job-Level Output Messages =

Add two new interfaces that should be used for all new code throughout
the ORTE and OMPI layers (we already make the search-and-replace on
the existing ORTE / OMPI layers):

 * orte_output(): (and corresponding friends ORTE_OUTPUT,
   orte_output_verbose, etc.)  This function sends the output directly
   to the HNP for processing as part of a job-specific output
   channel.  It supports all the same outputs as opal_output()
   (syslog, file, stdout, stderr), but for stdout/stderr, the output
   is sent to the HNP for processing and output.  More on this below.
 * orte_show_help(): This function is a drop-in-replacement for
   opal_show_help(), with two differences in functionality:
   1. the rendered text help message output is sent to the HNP for
      display (rather than outputting directly into the process' stderr
      stream)
   1. the HNP detects duplicate help messages and does not display them
      (so that you don't see the same error message N times, once from
      each of your N MPI processes); instead, it counts "new" instances
      of the help message and displays a message every ~5 seconds when
      there are new ones ("I got X new copies of the help message...")

opal_show_help and opal_output still exist, but they only output in
the current process.  The intent for the new orte_* functions is that
they can apply job-level intelligence to the output.  As such, we
recommend that all new ORTE and OMPI code use the new orte_*
functions, not thei opal_* functions.

=== New code ===

For ORTE and OMPI programmers, here's what you need to do differently
in new code:

 * Do not include opal/util/show_help.h or opal/util/output.h.
   Instead, include orte/util/output.h (this one header file has
   declarations for both the orte_output() series of functions and
   orte_show_help()).
 * Effectively s/opal_output/orte_output/gi throughout your code.
   Note that orte_output_open() takes a slightly different argument
   list (as a way to pass data to the filtering stream -- see below),
   so you if explicitly call opal_output_open(), you'll need to
   slightly adapt to the new signature of orte_output_open().
 * Literally s/opal_show_help/orte_show_help/.  The function signature
   is identical.

=== Notes ===

 * orte_output'ing to stream 0 will do similar to what
   opal_output'ing did, so leaving a hard-coded "0" as the first
   argument is safe.
 * For systems that do not use ORTE's RML or the HNP, the effect of
   orte_output_* and orte_show_help will be identical to their opal
   counterparts (the additional information passed to
   orte_output_open() will be lost!).  Indeed, the orte_* functions
   simply become trivial wrappers to their opal_* counterparts.  Note
   that we have not tested this; the code is simple but it is quite
   possible that we mucked something up.

= Filter Framework =

Messages sent view the new orte_* functions described above and
messages output via the IOF on the HNP will now optionally be passed
through a new "filter" framework before being output to
stdout/stderr.  The "filter" OPAL MCA framework is intended to allow
preprocessing to messages before they are sent to their final
destinations.  The first component that was written in the filter
framework was to create an XML stream, segregating all the messages
into different XML tags, etc.  This will allow 3rd party tools to read
the stdout/stderr from the HNP and be able to know exactly what each
text message is (e.g., a help message, another OMPI infrastructure
message, stdout from the user process, stderr from the user process,
etc.).

Filtering is not active by default.  Filter components must be
specifically requested, such as:

{{{
$ mpirun --mca filter xml ...
}}}

There can only be one filter component active.

= New MCA Parameters =

The new functionality described above introduces two new MCA
parameters:

 * '''orte_base_help_aggregate''': Defaults to 1 (true), meaning that
   help messages will be aggregated, as described above.  If set to 0,
   all help messages will be displayed, even if they are duplicates
   (i.e., the original behavior).
 * '''orte_base_show_output_recursions''': An MCA parameter to help
   debug one of the known issues, described below.  It is likely that
   this MCA parameter will disappear before v1.3 final.

= Known Issues =

 * The XML filter component is not complete.  The current output from
   this component is preliminary and not real XML.  A bit more work
   needs to be done to configure.m4 search for an appropriate XML
   library/link it in/use it at run time.
 * There are possible recursion loops in the orte_output() and
   orte_show_help() functions -- e.g., if RML send calls orte_output()
   or orte_show_help().  We have some ideas how to fix these, but
   figured that it was ok to commit before feature freeze with known
   issues.  The code currently contains sub-optimal workarounds so
   that this will not be a problem, but it would be good to actually
   solve the problem rather than have hackish workarounds before v1.3 final.

This commit was SVN r18434.
2008-05-13 20:00:55 +00:00

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/*
* Copyright (c) 2004-2005 The Trustees of Indiana University and Indiana
* University Research and Technology
* Corporation. All rights reserved.
* Copyright (c) 2004-2007 The University of Tennessee and The University
* of Tennessee Research Foundation. All rights
* reserved.
* Copyright (c) 2004-2005 High Performance Computing Center Stuttgart,
* University of Stuttgart. All rights reserved.
* Copyright (c) 2004-2005 The Regents of the University of California.
* All rights reserved.
* $COPYRIGHT$
*
* Additional copyrights may follow
*
* $HEADER$
*/
#include "ompi_config.h"
#include "mpi.h"
#include "ompi/constants.h"
#include "ompi/datatype/datatype.h"
#include "ompi/communicator/communicator.h"
#include "ompi/mca/coll/coll.h"
#include "ompi/mca/coll/base/coll_tags.h"
#include "ompi/mca/pml/pml.h"
#include "ompi/op/op.h"
#include "coll_tuned.h"
#include "coll_tuned_topo.h"
#include "coll_tuned_util.h"
/*
* ompi_coll_tuned_allgatherv_intra_bruck
*
* Function: allgather using O(log(N)) steps.
* Accepts: Same arguments as MPI_Allgather
* Returns: MPI_SUCCESS or error code
*
* Description: Variation to All-to-all algorithm described by Bruck et al.in
* "Efficient Algorithms for All-to-all Communications
* in Multiport Message-Passing Systems"
* Note: Unlike in case of allgather implementation, we relay on
* indexed datatype to select buffers appropriately.
* The only additional memory requirement is for creation of
* temporary datatypes.
* Example on 7 nodes (memory lay out need not be in-order)
* Initial set up:
* # 0 1 2 3 4 5 6
* [0] [ ] [ ] [ ] [ ] [ ] [ ]
* [ ] [1] [ ] [ ] [ ] [ ] [ ]
* [ ] [ ] [2] [ ] [ ] [ ] [ ]
* [ ] [ ] [ ] [3] [ ] [ ] [ ]
* [ ] [ ] [ ] [ ] [4] [ ] [ ]
* [ ] [ ] [ ] [ ] [ ] [5] [ ]
* [ ] [ ] [ ] [ ] [ ] [ ] [6]
* Step 0: send message to (rank - 2^0), receive message from (rank + 2^0)
* # 0 1 2 3 4 5 6
* [0] [ ] [ ] [ ] [ ] [ ] [0]
* [1] [1] [ ] [ ] [ ] [ ] [ ]
* [ ] [2] [2] [ ] [ ] [ ] [ ]
* [ ] [ ] [3] [3] [ ] [ ] [ ]
* [ ] [ ] [ ] [4] [4] [ ] [ ]
* [ ] [ ] [ ] [ ] [5] [5] [ ]
* [ ] [ ] [ ] [ ] [ ] [6] [6]
* Step 1: send message to (rank - 2^1), receive message from (rank + 2^1).
* message contains all blocks from (rank) .. (rank + 2^2) with
* wrap around.
* # 0 1 2 3 4 5 6
* [0] [ ] [ ] [ ] [0] [0] [0]
* [1] [1] [ ] [ ] [ ] [1] [1]
* [2] [2] [2] [ ] [ ] [ ] [2]
* [3] [3] [3] [3] [ ] [ ] [ ]
* [ ] [4] [4] [4] [4] [ ] [ ]
* [ ] [ ] [5] [5] [5] [5] [ ]
* [ ] [ ] [ ] [6] [6] [6] [6]
* Step 2: send message to (rank - 2^2), receive message from (rank + 2^2).
* message size is "all remaining blocks"
* # 0 1 2 3 4 5 6
* [0] [0] [0] [0] [0] [0] [0]
* [1] [1] [1] [1] [1] [1] [1]
* [2] [2] [2] [2] [2] [2] [2]
* [3] [3] [3] [3] [3] [3] [3]
* [4] [4] [4] [4] [4] [4] [4]
* [5] [5] [5] [5] [5] [5] [5]
* [6] [6] [6] [6] [6] [6] [6]
*/
int ompi_coll_tuned_allgatherv_intra_bruck(void *sbuf, int scount,
struct ompi_datatype_t *sdtype,
void *rbuf, int *rcounts,
int *rdispls,
struct ompi_datatype_t *rdtype,
struct ompi_communicator_t *comm,
struct mca_coll_base_module_1_1_0_t *module)
{
int line = -1, err = 0;
int rank, size;
int sendto, recvfrom, distance, blockcount, i;
int *new_rcounts = NULL, *new_rdispls = NULL;
int *new_scounts = NULL, *new_sdispls = NULL;
ptrdiff_t slb, rlb, sext, rext;
char *tmpsend = NULL, *tmprecv = NULL;
struct ompi_datatype_t *new_rdtype, *new_sdtype;
size = ompi_comm_size(comm);
rank = ompi_comm_rank(comm);
ORTE_OUTPUT((ompi_coll_tuned_stream,
"coll:tuned:allgather_intra_bruck rank %d", rank));
err = ompi_ddt_get_extent (sdtype, &slb, &sext);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
err = ompi_ddt_get_extent (rdtype, &rlb, &rext);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
/* Initialization step:
- if send buffer is not MPI_IN_PLACE, copy send buffer to block rank of
the receive buffer.
*/
tmprecv = (char*) rbuf + rdispls[rank] * rext;
if (MPI_IN_PLACE != sbuf) {
tmpsend = (char*) sbuf;
err = ompi_ddt_sndrcv(tmpsend, scount, sdtype,
tmprecv, rcounts[rank], rdtype);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
}
/* Communication step:
At every step i, rank r:
- doubles the distance
- sends message with blockcount blocks, (rbuf[rank] .. rbuf[rank + 2^i])
to rank (r - distance)
- receives message of blockcount blocks,
(rbuf[r + distance] ... rbuf[(r+distance) + 2^i]) from
rank (r + distance)
- blockcount doubles until the last step when only the remaining data is
exchanged.
*/
blockcount = 1;
tmpsend = (char*) rbuf;
new_rcounts = (int*) calloc(size, sizeof(int));
if (NULL == new_rcounts) { err = -1; line = __LINE__; goto err_hndl; }
new_rdispls = (int*) calloc(size, sizeof(int));
if (NULL == new_rdispls) { err = -1; line = __LINE__; goto err_hndl; }
new_scounts = (int*) calloc(size, sizeof(int));
if (NULL == new_scounts) { err = -1; line = __LINE__; goto err_hndl; }
new_sdispls = (int*) calloc(size, sizeof(int));
if (NULL == new_sdispls) { err = -1; line = __LINE__; goto err_hndl; }
for (distance = 1; distance < size; distance<<=1) {
recvfrom = (rank + distance) % size;
sendto = (rank - distance + size) % size;
if (distance <= (size >> 1)) {
blockcount = distance;
} else {
blockcount = size - distance;
}
/* create send and receive datatypes */
for (i = 0; i < blockcount; i++) {
const int tmp_srank = (rank + i) % size;
const int tmp_rrank = (recvfrom + i) % size;
new_scounts[i] = rcounts[tmp_srank];
new_sdispls[i] = rdispls[tmp_srank];
new_rcounts[i] = rcounts[tmp_rrank];
new_rdispls[i] = rdispls[tmp_rrank];
}
err = ompi_ddt_create_indexed(blockcount, new_scounts, new_sdispls,
rdtype, &new_sdtype);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
err = ompi_ddt_create_indexed(blockcount, new_rcounts, new_rdispls,
rdtype, &new_rdtype);
err = ompi_ddt_commit(&new_sdtype);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
err = ompi_ddt_commit(&new_rdtype);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
/* Sendreceive */
err = ompi_coll_tuned_sendrecv(rbuf, 1, new_sdtype, sendto,
MCA_COLL_BASE_TAG_ALLGATHERV,
rbuf, 1, new_rdtype, recvfrom,
MCA_COLL_BASE_TAG_ALLGATHERV,
comm, MPI_STATUS_IGNORE, rank);
ompi_ddt_destroy(&new_sdtype);
ompi_ddt_destroy(&new_rdtype);
}
free(new_rcounts);
free(new_rdispls);
free(new_scounts);
free(new_sdispls);
return OMPI_SUCCESS;
err_hndl:
if( NULL != new_rcounts ) free(new_rcounts);
if( NULL != new_rdispls ) free(new_rdispls);
if( NULL != new_scounts ) free(new_scounts);
if( NULL != new_sdispls ) free(new_sdispls);
ORTE_OUTPUT((ompi_coll_tuned_stream, "%s:%4d\tError occurred %d, rank %2d",
__FILE__, line, err, rank));
return err;
}
/*
* ompi_coll_tuned_allgatherv_intra_ring
*
* Function: allgatherv using O(N) steps.
* Accepts: Same arguments as MPI_Allgatherv
* Returns: MPI_SUCCESS or error code
*
* Description: Ring algorithm for all gather.
* At every step i, rank r receives message from rank (r - 1)
* containing data from rank (r - i - 1) and sends message to rank
* (r + 1) containing data from rank (r - i), with wrap arounds.
* Memory requirements:
* No additional memory requirements.
*
*/
int ompi_coll_tuned_allgatherv_intra_ring(void *sbuf, int scount,
struct ompi_datatype_t *sdtype,
void* rbuf, int *rcounts, int *rdisps,
struct ompi_datatype_t *rdtype,
struct ompi_communicator_t *comm,
struct mca_coll_base_module_1_1_0_t *module)
{
int line = -1;
int rank, size;
int sendto, recvfrom, i, recvdatafrom, senddatafrom;
int err = 0;
ptrdiff_t slb, rlb, sext, rext;
char *tmpsend = NULL, *tmprecv = NULL;
size = ompi_comm_size(comm);
rank = ompi_comm_rank(comm);
ORTE_OUTPUT((ompi_coll_tuned_stream,
"coll:tuned:allgatherv_intra_ring rank %d", rank));
err = ompi_ddt_get_extent (sdtype, &slb, &sext);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
err = ompi_ddt_get_extent (rdtype, &rlb, &rext);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
/* Initialization step:
- if send buffer is not MPI_IN_PLACE, copy send buffer to
the appropriate block of receive buffer
*/
tmprecv = (char*) rbuf + rdisps[rank] * rext;
if (MPI_IN_PLACE != sbuf) {
tmpsend = (char*) sbuf;
err = ompi_ddt_sndrcv(tmpsend, scount, sdtype,
tmprecv, rcounts[rank], rdtype);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
}
/* Communication step:
At every step i: 0 .. (P-1), rank r:
- receives message from [(r - 1 + size) % size] containing data from rank
[(r - i - 1 + size) % size]
- sends message to rank [(r + 1) % size] containing data from rank
[(r - i + size) % size]
- sends message which starts at begining of rbuf and has size
*/
sendto = (rank + 1) % size;
recvfrom = (rank - 1 + size) % size;
for (i = 0; i < size - 1; i++) {
recvdatafrom = (rank - i - 1 + size) % size;
senddatafrom = (rank - i + size) % size;
tmprecv = (char*)rbuf + rdisps[recvdatafrom] * rext;
tmpsend = (char*)rbuf + rdisps[senddatafrom] * rext;
/* Sendreceive */
err = ompi_coll_tuned_sendrecv(tmpsend, rcounts[senddatafrom], rdtype,
sendto, MCA_COLL_BASE_TAG_ALLGATHERV,
tmprecv, rcounts[recvdatafrom], rdtype,
recvfrom, MCA_COLL_BASE_TAG_ALLGATHERV,
comm, MPI_STATUS_IGNORE, rank);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
}
return OMPI_SUCCESS;
err_hndl:
ORTE_OUTPUT((ompi_coll_tuned_stream, "%s:%4d\tError occurred %d, rank %2d",
__FILE__, line, err, rank));
return err;
}
/*
* ompi_coll_tuned_allgatherv_intra_neighborexchange
*
* Function: allgatherv using N/2 steps (O(N))
* Accepts: Same arguments as MPI_Allgatherv
* Returns: MPI_SUCCESS or error code
*
* Description: Neighbor Exchange algorithm for allgather adapted for
* allgatherv.
* Described by Chen et.al. in
* "Performance Evaluation of Allgather Algorithms on
* Terascale Linux Cluster with Fast Ethernet",
* Proceedings of the Eighth International Conference on
* High-Performance Computing inn Asia-Pacific Region
* (HPCASIA'05), 2005
*
* Rank r exchanges message with one of its neighbors and
* forwards the data further in the next step.
*
* No additional memory requirements.
*
* Limitations: Algorithm works only on even number of processes.
* For odd number of processes we switch to ring algorithm.
*
* Example on 6 nodes:
* Initial state
* # 0 1 2 3 4 5
* [0] [ ] [ ] [ ] [ ] [ ]
* [ ] [1] [ ] [ ] [ ] [ ]
* [ ] [ ] [2] [ ] [ ] [ ]
* [ ] [ ] [ ] [3] [ ] [ ]
* [ ] [ ] [ ] [ ] [4] [ ]
* [ ] [ ] [ ] [ ] [ ] [5]
* Step 0:
* # 0 1 2 3 4 5
* [0] [0] [ ] [ ] [ ] [ ]
* [1] [1] [ ] [ ] [ ] [ ]
* [ ] [ ] [2] [2] [ ] [ ]
* [ ] [ ] [3] [3] [ ] [ ]
* [ ] [ ] [ ] [ ] [4] [4]
* [ ] [ ] [ ] [ ] [5] [5]
* Step 1:
* # 0 1 2 3 4 5
* [0] [0] [0] [ ] [ ] [0]
* [1] [1] [1] [ ] [ ] [1]
* [ ] [2] [2] [2] [2] [ ]
* [ ] [3] [3] [3] [3] [ ]
* [4] [ ] [ ] [4] [4] [4]
* [5] [ ] [ ] [5] [5] [5]
* Step 2:
* # 0 1 2 3 4 5
* [0] [0] [0] [0] [0] [0]
* [1] [1] [1] [1] [1] [1]
* [2] [2] [2] [2] [2] [2]
* [3] [3] [3] [3] [3] [3]
* [4] [4] [4] [4] [4] [4]
* [5] [5] [5] [5] [5] [5]
*/
int
ompi_coll_tuned_allgatherv_intra_neighborexchange(void *sbuf, int scount,
struct ompi_datatype_t *sdtype,
void* rbuf, int *rcounts, int *rdispls,
struct ompi_datatype_t *rdtype,
struct ompi_communicator_t *comm,
struct mca_coll_base_module_1_1_0_t *module)
{
int line = -1;
int rank, size;
int neighbor[2], offset_at_step[2], recv_data_from[2], send_data_from;
int new_scounts[2], new_sdispls[2], new_rcounts[2], new_rdispls[2];
int i, even_rank;
int err = 0;
ptrdiff_t slb, rlb, sext, rext;
char *tmpsend = NULL, *tmprecv = NULL;
struct ompi_datatype_t *new_rdtype, *new_sdtype;
size = ompi_comm_size(comm);
rank = ompi_comm_rank(comm);
if (size % 2) {
ORTE_OUTPUT((ompi_coll_tuned_stream,
"coll:tuned:allgatherv_intra_neighborexchange WARNING: odd size %d, switching to ring algorithm",
size));
return ompi_coll_tuned_allgatherv_intra_ring(sbuf, scount, sdtype,
rbuf, rcounts,
rdispls, rdtype,
comm, module);
}
ORTE_OUTPUT((ompi_coll_tuned_stream,
"coll:tuned:allgatherv_intra_neighborexchange rank %d", rank));
err = ompi_ddt_get_extent (sdtype, &slb, &sext);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
err = ompi_ddt_get_extent (rdtype, &rlb, &rext);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
/* Initialization step:
- if send buffer is not MPI_IN_PLACE, copy send buffer to
the appropriate block of receive buffer
*/
tmprecv = (char*) rbuf + rdispls[rank] * rext;
if (MPI_IN_PLACE != sbuf) {
tmpsend = (char*) sbuf;
err = ompi_ddt_sndrcv(tmpsend, scount, sdtype,
tmprecv, rcounts[rank], rdtype);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
}
/* Determine neighbors, order in which blocks will arrive, etc. */
even_rank = !(rank % 2);
if (even_rank) {
neighbor[0] = (rank + 1) % size;
neighbor[1] = (rank - 1 + size) % size;
recv_data_from[0] = rank;
recv_data_from[1] = rank;
offset_at_step[0] = (+2);
offset_at_step[1] = (-2);
} else {
neighbor[0] = (rank - 1 + size) % size;
neighbor[1] = (rank + 1) % size;
recv_data_from[0] = neighbor[0];
recv_data_from[1] = neighbor[0];
offset_at_step[0] = (-2);
offset_at_step[1] = (+2);
}
/* Communication loop:
- First step is special: exchange a single block with neighbor[0].
- Rest of the steps:
update recv_data_from according to offset, and
exchange two blocks with appropriate neighbor.
the send location becomes previous receve location.
Note, we need to create indexed datatype to send and receive these
blocks properly.
*/
tmprecv = (char*)rbuf + rdispls[neighbor[0]] * rext;
tmpsend = (char*)rbuf + rdispls[rank] * rext;
err = ompi_coll_tuned_sendrecv(tmpsend, rcounts[rank], rdtype,
neighbor[0], MCA_COLL_BASE_TAG_ALLGATHERV,
tmprecv, rcounts[neighbor[0]], rdtype,
neighbor[0], MCA_COLL_BASE_TAG_ALLGATHERV,
comm, MPI_STATUS_IGNORE, rank);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
/* Determine initial sending counts and displacements*/
if (even_rank) {
send_data_from = rank;
} else {
send_data_from = recv_data_from[0];
}
for (i = 1; i < (size / 2); i++) {
const int i_parity = i % 2;
recv_data_from[i_parity] =
(recv_data_from[i_parity] + offset_at_step[i_parity] + size) % size;
/* Create new indexed types for sending and receiving.
We are sending data from ranks (send_data_from) and (send_data_from+1)
We are receiving data from ranks (recv_data_from[i_parity]) and
(recv_data_from[i_parity]+1).
*/
new_scounts[0] = rcounts[send_data_from];
new_scounts[1] = rcounts[(send_data_from + 1)];
new_sdispls[0] = rdispls[send_data_from];
new_sdispls[1] = rdispls[(send_data_from + 1)];
err = ompi_ddt_create_indexed(2, new_scounts, new_sdispls, rdtype,
&new_sdtype);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
err = ompi_ddt_commit(&new_sdtype);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
new_rcounts[0] = rcounts[recv_data_from[i_parity]];
new_rcounts[1] = rcounts[(recv_data_from[i_parity] + 1)];
new_rdispls[0] = rdispls[recv_data_from[i_parity]];
new_rdispls[1] = rdispls[(recv_data_from[i_parity] + 1)];
err = ompi_ddt_create_indexed(2, new_rcounts, new_rdispls, rdtype,
&new_rdtype);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
err = ompi_ddt_commit(&new_rdtype);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
tmprecv = (char*)rbuf;
tmpsend = (char*)rbuf;
/* Sendreceive */
err = ompi_coll_tuned_sendrecv(tmpsend, 1, new_sdtype, neighbor[i_parity],
MCA_COLL_BASE_TAG_ALLGATHERV,
tmprecv, 1, new_rdtype, neighbor[i_parity],
MCA_COLL_BASE_TAG_ALLGATHERV,
comm, MPI_STATUS_IGNORE, rank);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
send_data_from = recv_data_from[i_parity];
ompi_ddt_destroy(&new_sdtype);
ompi_ddt_destroy(&new_rdtype);
}
return OMPI_SUCCESS;
err_hndl:
ORTE_OUTPUT((ompi_coll_tuned_stream, "%s:%4d\tError occurred %d, rank %2d",
__FILE__, line, err, rank));
return err;
}
int ompi_coll_tuned_allgatherv_intra_two_procs(void *sbuf, int scount,
struct ompi_datatype_t *sdtype,
void* rbuf, int *rcounts,
int *rdispls,
struct ompi_datatype_t *rdtype,
struct ompi_communicator_t *comm,
struct mca_coll_base_module_1_1_0_t *module)
{
int line = -1, err = 0;
int rank;
int remote;
char *tmpsend = NULL, *tmprecv = NULL;
ptrdiff_t sext, rext, lb;
rank = ompi_comm_rank(comm);
ORTE_OUTPUT((ompi_coll_tuned_stream,
"ompi_coll_tuned_allgatherv_intra_two_procs rank %d", rank));
err = ompi_ddt_get_extent (sdtype, &lb, &sext);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
err = ompi_ddt_get_extent (rdtype, &lb, &rext);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
/* Exchange data:
- compute source and destinations
- send receive data
*/
remote = rank ^ 0x1;
tmpsend = (char*)sbuf;
if (MPI_IN_PLACE == sbuf) {
tmpsend = (char*)rbuf + rdispls[rank] * rext;
scount = rcounts[rank];
sdtype = rdtype;
}
tmprecv = (char*)rbuf + rdispls[remote] * rext;
err = ompi_coll_tuned_sendrecv(tmpsend, scount, sdtype, remote,
MCA_COLL_BASE_TAG_ALLGATHERV,
tmprecv, rcounts[remote], rdtype, remote,
MCA_COLL_BASE_TAG_ALLGATHERV,
comm, MPI_STATUS_IGNORE, rank);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
/* Place your data in correct location if necessary */
if (MPI_IN_PLACE != sbuf) {
err = ompi_ddt_sndrcv((char*)sbuf, scount, sdtype,
(char*)rbuf + rdispls[rank] * rext,
rcounts[rank], rdtype);
if (MPI_SUCCESS != err) { line = __LINE__; goto err_hndl; }
}
return MPI_SUCCESS;
err_hndl:
ORTE_OUTPUT((ompi_coll_tuned_stream, "%s:%4d\tError occurred %d, rank %2d",
__FILE__, line, err, rank));
return err;
}
/*
* Linear functions are copied from the BASIC coll module
* they do not segment the message and are simple implementations
* but for some small number of nodes and/or small data sizes they
* are just as fast as tuned/tree based segmenting operations
* and as such may be selected by the decision functions
* These are copied into this module due to the way we select modules
* in V1. i.e. in V2 we will handle this differently and so will not
* have to duplicate code.
* JPG following the examples from other coll_tuned implementations. Dec06.
*/
/* copied function (with appropriate renaming) starts here */
/*
* allgatherv_intra_basic
*
* Function: - allgatherv using other MPI collectives:
* gatherv + bcast (from basic module).
* Accepts: - same as MPI_Allgatherv()
* Returns: - MPI_SUCCESS or error code
*/
int
ompi_coll_tuned_allgatherv_intra_basic_default(void *sbuf, int scount,
struct ompi_datatype_t *sdtype,
void *rbuf, int *rcounts,
int *disps,
struct ompi_datatype_t *rdtype,
struct ompi_communicator_t *comm,
struct mca_coll_base_module_1_1_0_t *module)
{
int i, size, rank ;
int err;
MPI_Aint extent;
MPI_Aint lb;
char *send_buf = NULL;
struct ompi_datatype_t *newtype, *send_type;
size = ompi_comm_size(comm);
rank = ompi_comm_rank(comm);
/*
* We don't have a root process defined. Arbitrarily assign root
* to process with rank 0 (OMPI convention)
*/
ORTE_OUTPUT((ompi_coll_tuned_stream,
"ompi_coll_tuned_allgatherv_intra_basic_default rank %d",
rank));
if (MPI_IN_PLACE == sbuf) {
ompi_ddt_get_extent(rdtype, &lb, &extent);
send_type = rdtype;
send_buf = (char*)rbuf;
for (i = 0; i < rank; ++i) {
send_buf += (rcounts[i] * extent);
}
} else {
send_buf = (char*)sbuf;
send_type = sdtype;
}
err = comm->c_coll.coll_gatherv(send_buf,
rcounts[rank], send_type,rbuf,
rcounts, disps, rdtype, 0,
comm, module);
if (MPI_SUCCESS != err) {
return err;
}
/*
* we now have all the data in the root's rbuf. Need to
* broadcast the data out to the other processes
*
* Need to define a datatype that captures the different vectors
* from each process. MPI_TYPE_INDEXED with params
* size,rcount,displs,rdtype,newtype
* should do the trick.
* Use underlying ddt functions to create, and commit the
* new datatype on each process, then broadcast and destroy the
* datatype.
*/
err = ompi_ddt_create_indexed(size,rcounts,disps,rdtype,&newtype);
if (MPI_SUCCESS != err) {
return err;
}
err = ompi_ddt_commit(&newtype);
if(MPI_SUCCESS != err) {
return err;
}
comm->c_coll.coll_bcast(rbuf, 1, newtype, 0, comm, module);
ompi_ddt_destroy (&newtype);
return MPI_SUCCESS;
}
/* copied function (with appropriate renaming) ends here */
/* The following are used by dynamic and forced rules */
/* publish details of each algorithm and if its forced/fixed/locked in */
/* as you add methods/algorithms you must update this and the query/map
routines */
/* this routine is called by the component only */
/* this makes sure that the mca parameters are set to their initial values
and perms */
/* module does not call this they call the forced_getvalues routine instead */
int
ompi_coll_tuned_allgatherv_intra_check_forced_init(coll_tuned_force_algorithm_mca_param_indices_t *mca_param_indices)
{
int max_alg = 5, requested_alg;
ompi_coll_tuned_forced_max_algorithms[ALLGATHERV] = max_alg;
mca_base_param_reg_int (&mca_coll_tuned_component.super.collm_version,
"allgatherv_algorithm_count",
"Number of allgather algorithms available",
false, true, max_alg, NULL);
mca_param_indices->algorithm_param_index
= mca_base_param_reg_int(&mca_coll_tuned_component.super.collm_version,
"allgatherv_algorithm",
"Which allgather algorithm is used. Can be locked down to choice of: 0 ignore, 1 default (gatherv + bcast), 2 bruck, 3 ring, 4 neighbor exchange, 5: two proc only.",
false, false, 0, NULL);
mca_base_param_lookup_int(mca_param_indices->algorithm_param_index,
&(requested_alg));
if( requested_alg > max_alg ) {
if( 0 == ompi_comm_rank( MPI_COMM_WORLD ) ) {
orte_output( 0, "Allgather algorithm #%d is not available (range [0..%d]). Switching back to ignore(0)\n",
requested_alg, max_alg );
}
mca_base_param_set_int( mca_param_indices->algorithm_param_index, 0);
}
mca_param_indices->segsize_param_index
= mca_base_param_reg_int(&mca_coll_tuned_component.super.collm_version,
"allgatherv_algorithm_segmentsize",
"Segment size in bytes used by default for allgather algorithms. Only has meaning if algorithm is forced and supports segmenting. 0 bytes means no segmentation. Currently, available algorithms do not support segmentation.",
false, false, 0, NULL);
mca_param_indices->tree_fanout_param_index
= mca_base_param_reg_int(&mca_coll_tuned_component.super.collm_version,
"allgatherv_algorithm_tree_fanout",
"Fanout for n-tree used for allgather algorithms. Only has meaning if algorithm is forced and supports n-tree topo based operation. Currently, available algorithms do not support n-tree topologies.",
false, false,
ompi_coll_tuned_init_tree_fanout, /* get system wide default */
NULL);
mca_param_indices->chain_fanout_param_index
= mca_base_param_reg_int(&mca_coll_tuned_component.super.collm_version,
"allgatherv_algorithm_chain_fanout",
"Fanout for chains used for allgather algorithms. Only has meaning if algorithm is forced and supports chain topo based operation. Currently, available algorithms do not support chain topologies.",
false, false,
ompi_coll_tuned_init_chain_fanout, /* get system wide default */
NULL);
return (MPI_SUCCESS);
}
int ompi_coll_tuned_allgatherv_intra_do_forced(void *sbuf, int scount,
struct ompi_datatype_t *sdtype,
void *rbuf, int *rcounts,
int *rdispls,
struct ompi_datatype_t *rdtype,
struct ompi_communicator_t *comm,
struct mca_coll_base_module_1_1_0_t *module)
{
mca_coll_tuned_module_t *tuned_module = (mca_coll_tuned_module_t*) module;
mca_coll_tuned_comm_t *data = tuned_module->tuned_data;
ORTE_OUTPUT((ompi_coll_tuned_stream,
"coll:tuned:allgatherv_intra_do_forced selected algorithm %d",
data->user_forced[ALLGATHERV].algorithm));
switch (data->user_forced[ALLGATHERV].algorithm) {
case (0):
return ompi_coll_tuned_allgatherv_intra_dec_fixed (sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
case (1):
return ompi_coll_tuned_allgatherv_intra_basic_default (sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
case (2):
return ompi_coll_tuned_allgatherv_intra_bruck (sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
case (3):
return ompi_coll_tuned_allgatherv_intra_ring (sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
case (4):
return ompi_coll_tuned_allgatherv_intra_neighborexchange (sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
case (5):
return ompi_coll_tuned_allgatherv_intra_two_procs (sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
default:
ORTE_OUTPUT((ompi_coll_tuned_stream,
"coll:tuned:allgatherv_intra_do_forced attempt to select algorithm %d when only 0-%d is valid?",
data->user_forced[ALLGATHERV].algorithm,
ompi_coll_tuned_forced_max_algorithms[ALLGATHERV]));
return (MPI_ERR_ARG);
} /* switch */
}
int ompi_coll_tuned_allgatherv_intra_do_this(void *sbuf, int scount,
struct ompi_datatype_t *sdtype,
void *rbuf, int *rcounts,
int *rdispls,
struct ompi_datatype_t *rdtype,
struct ompi_communicator_t *comm,
struct mca_coll_base_module_1_1_0_t *module,
int algorithm, int faninout,
int segsize)
{
ORTE_OUTPUT((ompi_coll_tuned_stream,
"coll:tuned:allgatherv_intra_do_this selected algorithm %d topo faninout %d segsize %d",
algorithm, faninout, segsize));
switch (algorithm) {
case (0):
return ompi_coll_tuned_allgatherv_intra_dec_fixed(sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
case (1):
return ompi_coll_tuned_allgatherv_intra_basic_default(sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
case (2):
return ompi_coll_tuned_allgatherv_intra_bruck(sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
case (3):
return ompi_coll_tuned_allgatherv_intra_ring(sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
case (4):
return ompi_coll_tuned_allgatherv_intra_neighborexchange(sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
case (5):
return ompi_coll_tuned_allgatherv_intra_two_procs (sbuf, scount, sdtype,
rbuf, rcounts, rdispls, rdtype,
comm, module);
default:
ORTE_OUTPUT((ompi_coll_tuned_stream,
"coll:tuned:allgatherv_intra_do_this attempt to select algorithm %d when only 0-%d is valid?",
algorithm,
ompi_coll_tuned_forced_max_algorithms[ALLGATHERV]));
return (MPI_ERR_ARG);
} /* switch */
}
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