482d84b6e5
The expected sequence of events for processing info during object creation
is that if there's an incoming info arg, it is opal_info_dup()ed into the obj
at obj->s_info first. Then interested components register callbacks for
keys they want to know about using opal_infosubscribe_infosubscribe().
Inside info_subscribe_subscribe() the specified callback() is called with
whatever matching k/v is in the object's info, or with the default. The
return string from the callback goes into the new k/v stored in info, and
the input k/v is saved as __IN_<key>/<val>. It's saved the same way
whether the input came from info or whether it was a default. A null return
from the callback indicates an ignored key/val, and no k/v is stored for
it, but an __IN_<key>/<val> is still kept so we still have access to the
original.
At MPI_*_set_info() time, opal_infosubscribe_change_info() is used. That
function calls the registered callbacks for each item in the provided info.
If the callback returns non-null, the info is updated with that k/v, or if
the callback returns null, that key is deleted from info. An __IN_<key>/<val>
is saved either way, and overwrites any previously saved value.
When MPI_*_get_info() is called, opal_info_dup_mpistandard() is used, which
allows relatively easy changes in interpretation of the standard, by looking
at both the <key>/<val> and __IN_<key>/<val> in info. Right now it does
1. includes system extras, eg k/v defaults not expliclty set by the user
2. omits ignored keys
3. shows input values, not callback modifications, eg not the internal values
Currently the callbacks are doing things like
return some_condition ? "true" : "false"
that is, returning static strings that are not to be freed. If the return
strings start becoming more dynamic in the future I don't see how unallocated
strings could support that, so I'd propose a change for the future that
the callback()s registered with info_subscribe_subscribe() do a strdup on
their return, and we change the callers of callback() to free the strings
it returns (there are only two callers).
Rough outline of the smaller changes spread over the less central files:
comm.c
initialize comm->super.s_info to NULL
copy into comm->super.s_info in comm creation calls that provide info
OBJ_RELEASE comm->super.s_info at free time
comm_init.c
initialize comm->super.s_info to NULL
file.c
copy into file->super.s_info if file creation provides info
OBJ_RELEASE file->super.s_info at free time
win.c
copy into win->super.s_info if win creation provides info
OBJ_RELEASE win->super.s_info at free time
comm_get_info.c
file_get_info.c
win_get_info.c
change_info() if there's no info attached (shouldn't happen if callbacks
are registered)
copy the info for the user
The other category of change is generally addressing compiler warnings where
ompi_info_t and opal_info_t were being used a little too interchangably. An
ompi_info_t* contains an opal_info_t*, at &(ompi_info->super)
Also this commit updates the copyrights.
Signed-off-by: Mark Allen <markalle@us.ibm.com>
371 строка
12 KiB
C
371 строка
12 KiB
C
/* -*- Mode: C; c-basic-offset:4 ; indent-tabs-mode:nil -*- */
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/*
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* Copyright (c) 2004-2005 The Trustees of Indiana University and Indiana
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* University Research and Technology
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* Corporation. All rights reserved.
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* Copyright (c) 2004-2017 The University of Tennessee and The University
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* of Tennessee Research Foundation. All rights
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* reserved.
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* Copyright (c) 2004-2005 High Performance Computing Center Stuttgart,
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* University of Stuttgart. All rights reserved.
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* Copyright (c) 2004-2005 The Regents of the University of California.
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* All rights reserved.
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* Copyright (c) 2007-2015 Cisco Systems, Inc. All rights reserved.
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* Copyright (c) 2009 Sun Microsystems, Inc. All rights reserved.
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* Copyright (c) 2012-2015 Los Alamos National Security, LLC. All rights
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* reserved.
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* Copyright (c) 2015 Research Organization for Information Science
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* and Technology (RIST). All rights reserved.
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* Copyright (c) 2016-2017 IBM Corporation. All rights reserved.
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* $COPYRIGHT$
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*
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* Additional copyrights may follow
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*
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* $HEADER$
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*/
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#include "ompi_config.h"
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#include "ompi/constants.h"
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#include <string.h>
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#include <errno.h>
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#include <stdlib.h>
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#ifdef HAVE_UNISTD_H
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#include <unistd.h>
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#endif
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#include <limits.h>
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#include <ctype.h>
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#ifdef HAVE_SYS_UTSNAME_H
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#include <sys/utsname.h>
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#endif
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#include <assert.h>
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#include "opal/util/argv.h"
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#include "opal/util/opal_getcwd.h"
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#include "opal/util/output.h"
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#include "opal/util/strncpy.h"
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#include "opal/util/info.h"
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#include "ompi/info/info.h"
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#include "ompi/runtime/mpiruntime.h"
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#include "ompi/runtime/params.h"
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/*
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* Global variables
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*/
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ompi_predefined_info_t ompi_mpi_info_null = {{{{{0}}}}};
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ompi_predefined_info_t *ompi_mpi_info_null_addr = &ompi_mpi_info_null;
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ompi_predefined_info_t ompi_mpi_info_env = {{{{{0}}}}};
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/*
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* Local functions
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*/
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static void info_constructor(ompi_info_t *info);
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static void info_destructor(ompi_info_t *info);
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/*
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* ompi_info_t classes
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*/
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OBJ_CLASS_INSTANCE(ompi_info_t,
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opal_info_t,
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info_constructor,
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info_destructor);
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/*
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* The global fortran <-> C translation table
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*/
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opal_pointer_array_t ompi_info_f_to_c_table = {{0}};
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/*
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* This function is called during ompi_init and initializes the
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* fortran to C translation table. It also fills in the values
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* for the MPI_INFO_GET_ENV object
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*/
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int ompi_mpiinfo_init(void)
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{
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char val[OPAL_MAXHOSTNAMELEN];
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char *cptr;
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/* initialize table */
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OBJ_CONSTRUCT(&ompi_info_f_to_c_table, opal_pointer_array_t);
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if( OPAL_SUCCESS != opal_pointer_array_init(&ompi_info_f_to_c_table, 0,
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OMPI_FORTRAN_HANDLE_MAX, 16) ) {
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return OMPI_ERROR;
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}
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/* Create MPI_INFO_NULL */
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OBJ_CONSTRUCT(&ompi_mpi_info_null.info, ompi_info_t);
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assert(ompi_mpi_info_null.info.i_f_to_c_index == 0);
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/* Create MPI_INFO_ENV */
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OBJ_CONSTRUCT(&ompi_mpi_info_env.info, ompi_info_t);
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assert(ompi_mpi_info_env.info.i_f_to_c_index == 1);
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/* fill the env info object */
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/* command for this app_context */
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if (NULL != (cptr = getenv("OMPI_COMMAND"))) {
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opal_info_set(&ompi_mpi_info_env.info.super, "command", cptr);
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}
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/* space-separated list of argv for this command */
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if (NULL != (cptr = getenv("OMPI_ARGV"))) {
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opal_info_set(&ompi_mpi_info_env.info.super, "argv", cptr);
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}
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/* max procs for the entire job */
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if (NULL != (cptr = getenv("OMPI_MCA_orte_ess_num_procs"))) {
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opal_info_set(&ompi_mpi_info_env.info.super, "maxprocs", cptr);
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/* Open MPI does not support the "soft" option, so set it to maxprocs */
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opal_info_set(&ompi_mpi_info_env.info.super, "soft", cptr);
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}
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/* local host name */
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gethostname(val, sizeof(val));
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opal_info_set(&ompi_mpi_info_env.info.super, "host", val);
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/* architecture name */
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if (NULL != (cptr = getenv("OMPI_MCA_orte_cpu_type"))) {
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opal_info_set(&ompi_mpi_info_env.info.super, "arch", cptr);
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}
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#ifdef HAVE_SYS_UTSNAME_H
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else {
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struct utsname sysname;
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uname(&sysname);
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cptr = sysname.machine;
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opal_info_set(&ompi_mpi_info_env.info.super, "arch", cptr);
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}
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#endif
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/* initial working dir of this process - only set when
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* run by mpiexec as we otherwise have no reliable way
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* of determining the value
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*/
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if (NULL != (cptr = getenv("OMPI_MCA_initial_wdir"))) {
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opal_info_set(&ompi_mpi_info_env.info.super, "wdir", cptr);
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}
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/* provide the REQUESTED thread level - may be different
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* than the ACTUAL thread level you get.
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* ugly, but have to do a switch to find the string representation */
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switch (ompi_mpi_thread_requested) {
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case MPI_THREAD_SINGLE:
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opal_info_set(&ompi_mpi_info_env.info.super, "thread_level", "MPI_THREAD_SINGLE");
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break;
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case MPI_THREAD_FUNNELED:
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opal_info_set(&ompi_mpi_info_env.info.super, "thread_level", "MPI_THREAD_FUNNELED");
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break;
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case MPI_THREAD_SERIALIZED:
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opal_info_set(&ompi_mpi_info_env.info.super, "thread_level", "MPI_THREAD_SERIALIZED");
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break;
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case MPI_THREAD_MULTIPLE:
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opal_info_set(&ompi_mpi_info_env.info.super, "thread_level", "MPI_THREAD_MULTIPLE");
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break;
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default:
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/* do nothing - don't know the value */
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break;
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}
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/**** now some OMPI-specific values that other MPIs may not provide ****/
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/* the number of app_contexts in this job */
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if (NULL != (cptr = getenv("OMPI_NUM_APP_CTX"))) {
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opal_info_set(&ompi_mpi_info_env.info.super, "ompi_num_apps", cptr);
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}
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/* space-separated list of first MPI rank of each app_context */
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if (NULL != (cptr = getenv("OMPI_FIRST_RANKS"))) {
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opal_info_set(&ompi_mpi_info_env.info.super, "ompi_first_rank", cptr);
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}
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/* space-separated list of num procs for each app_context */
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if (NULL != (cptr = getenv("OMPI_APP_CTX_NUM_PROCS"))) {
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opal_info_set(&ompi_mpi_info_env.info.super, "ompi_np", cptr);
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}
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/* location of the directory containing any prepositioned files
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* the user may have requested
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*/
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if (NULL != (cptr = getenv("OMPI_FILE_LOCATION"))) {
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opal_info_set(&ompi_mpi_info_env.info.super, "ompi_positioned_file_dir", cptr);
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}
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/* All done */
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return OMPI_SUCCESS;
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}
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// Generally ompi_info_t processing is handled by opal_info_t now.
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// But to avoid compiler warnings and to avoid having to constantly
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// change code to mpiinfo->super to make MPI code use the opal_info_t
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// it's convenient to have ompi_info_t wrappers for some of the opal_info_t
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// related calls:
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int ompi_info_dup (ompi_info_t *info, ompi_info_t **newinfo) {
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return opal_info_dup (&(info->super), (opal_info_t **)newinfo);
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}
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int ompi_info_dup_mpistandard (ompi_info_t *info, ompi_info_t **newinfo) {
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return opal_info_dup_mpistandard (&(info->super), (opal_info_t **)newinfo);
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}
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int ompi_info_set (ompi_info_t *info, const char *key, const char *value) {
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return opal_info_set (&(info->super), key, value);
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}
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int ompi_info_set_value_enum (ompi_info_t *info, const char *key, int value,
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mca_base_var_enum_t *var_enum)
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{
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return opal_info_set_value_enum (&(info->super), key, value, var_enum);
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}
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int ompi_info_get (ompi_info_t *info, const char *key, int valuelen,
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char *value, int *flag)
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{
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return opal_info_get (&(info->super), key, valuelen, value, flag);
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}
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int ompi_info_get_value_enum (ompi_info_t *info, const char *key, int *value,
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int default_value, mca_base_var_enum_t *var_enum,
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int *flag)
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{
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return opal_info_get_value_enum (&(info->super), key, value,
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default_value, var_enum, flag);
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}
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int ompi_info_get_bool(ompi_info_t *info, char *key, bool *value, int *flag) {
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return opal_info_get_bool(&(info->super), key, value, flag);
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}
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int ompi_info_delete (ompi_info_t *info, const char *key) {
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return opal_info_delete (&(info->super), key);
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}
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int ompi_info_get_valuelen (ompi_info_t *info, const char *key, int *valuelen,
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int *flag)
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{
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return opal_info_get_valuelen (&(info->super), key, valuelen, flag);
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}
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int ompi_info_get_nthkey (ompi_info_t *info, int n, char *key) {
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return opal_info_get_nthkey (&(info->super), n, key);
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}
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int ompi_info_get_nkeys(ompi_info_t *info, int *nkeys)
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{
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return opal_info_get_nkeys (&(info->super), nkeys);
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}
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/*
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* Shut down MPI_Info handling
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*/
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int ompi_mpiinfo_finalize(void)
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{
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size_t i, max;
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ompi_info_t *info;
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opal_list_item_t *item;
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opal_info_entry_t *entry;
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bool found = false;
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/* Go through the f2c table and see if anything is left. Free them
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all. */
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max = opal_pointer_array_get_size(&ompi_info_f_to_c_table);
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for (i = 2; i < max; ++i) {
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info = (ompi_info_t *)opal_pointer_array_get_item(&ompi_info_f_to_c_table, i);
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/* If the info was freed but still exists because the user
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told us to never free handles, then do an OBJ_RELEASE it
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and all is well. Then get the value again and see if it's
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actually been freed. */
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if (NULL != info && ompi_debug_no_free_handles && info->i_freed) {
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OBJ_RELEASE(info);
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info = (ompi_info_t *)opal_pointer_array_get_item(&ompi_info_f_to_c_table, i);
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}
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/* If it still exists here and was never freed, then it's an
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orphan */
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if (NULL != info) {
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/* If the user wanted warnings about MPI object leaks, print out
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a message */
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if (!info->i_freed && ompi_debug_show_handle_leaks) {
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if (ompi_debug_show_handle_leaks) {
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opal_output(0, "WARNING: MPI_Info still allocated at MPI_FINALIZE");
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for (item = opal_list_get_first(&info->super.super);
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opal_list_get_end(&(info->super.super)) != item;
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item = opal_list_get_next(item)) {
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entry = (opal_info_entry_t *) item;
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opal_output(0, "WARNING: key=\"%s\", value=\"%s\"",
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entry->ie_key,
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NULL != entry->ie_value ? entry->ie_value : "(null)");
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found = true;
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}
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}
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OBJ_RELEASE(info);
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}
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/* Don't bother setting each element back down to NULL; it
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would just take a lot of thread locks / unlocks and
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since we're destroying everything, it isn't worth it */
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if (!found && ompi_debug_show_handle_leaks) {
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opal_output(0, "WARNING: (no keys)");
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}
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}
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}
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/* All done -- destroy the table */
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OBJ_DESTRUCT(&ompi_info_f_to_c_table);
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return OPAL_SUCCESS;
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}
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/*
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* This function is invoked when OBJ_NEW() is called. Here, we add this
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* info pointer to the table and then store its index as the handle
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*/
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static void info_constructor(ompi_info_t *info)
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{
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info->i_f_to_c_index = opal_pointer_array_add(&ompi_info_f_to_c_table,
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info);
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info->i_freed = false;
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/*
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* If the user doesn't want us to ever free it, then add an extra
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* RETAIN here
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*/
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if (ompi_debug_no_free_handles) {
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OBJ_RETAIN(&(info->super));
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}
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}
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/*
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* * This function is called during OBJ_DESTRUCT of "info". When this
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* * done, we need to remove the entry from the opal fortran to C
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* * translation table
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* */
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static void info_destructor(ompi_info_t *info)
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{
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/* reset the &ompi_info_f_to_c_table entry - make sure that the
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entry is in the table */
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if (MPI_UNDEFINED != info->i_f_to_c_index &&
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NULL != opal_pointer_array_get_item(&ompi_info_f_to_c_table,
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info->i_f_to_c_index)){
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opal_pointer_array_set_item(&ompi_info_f_to_c_table,
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info->i_f_to_c_index, NULL);
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}
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}
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/*
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* Free an info handle and all of its keys and values.
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*/
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int ompi_info_free (ompi_info_t **info)
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{
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(*info)->i_freed = true;
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OBJ_RELEASE(*info);
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*info = MPI_INFO_NULL;
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return MPI_SUCCESS;
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}
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