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openmpi/orte/mca/ess/singleton/ess_singleton_module.c
Ralph Castain a200e4f865 As per the RFC, bring in the ORTE async progress code and the rewrite of OOB: 
*** THIS RFC INCLUDES A MINOR CHANGE TO THE MPI-RTE INTERFACE ***

Note: during the course of this work, it was necessary to completely separate the MPI and RTE progress engines. There were multiple places in the MPI layer where ORTE_WAIT_FOR_COMPLETION was being used. A new OMPI_WAIT_FOR_COMPLETION macro was created (defined in ompi/mca/rte/rte.h) that simply cycles across opal_progress until the provided flag becomes false. Places where the MPI layer blocked waiting for RTE to complete an event have been modified to use this macro.

***************************************************************************************

I am reissuing this RFC because of the time that has passed since its original release. Since its initial release and review, I have debugged it further to ensure it fully supports tests like loop_spawn. It therefore seems ready for merge back to the trunk. Given its prior review, I have set the timeout for one week.

The code is in  https://bitbucket.org/rhc/ompi-oob2


WHAT:    Rewrite of ORTE OOB

WHY:       Support asynchronous progress and a host of other features

WHEN:    Wed, August 21

SYNOPSIS:
The current OOB has served us well, but a number of limitations have been identified over the years. Specifically:

* it is only progressed when called via opal_progress, which can lead to hangs or recursive calls into libevent (which is not supported by that code)

* we've had issues when multiple NICs are available as the code doesn't "shift" messages between transports - thus, all nodes had to be available via the same TCP interface.

* the OOB "unloads" incoming opal_buffer_t objects during the transmission, thus preventing use of OBJ_RETAIN in the code when repeatedly sending the same message to multiple recipients

* there is no failover mechanism across NICs - if the selected NIC (or its attached switch) fails, we are forced to abort

* only one transport (i.e., component) can be "active"


The revised OOB resolves these problems:

* async progress is used for all application processes, with the progress thread blocking in the event library

* each available TCP NIC is supported by its own TCP module. The ability to asynchronously progress each module independently is provided, but not enabled by default (a runtime MCA parameter turns it "on")

* multi-address TCP NICs (e.g., a NIC with both an IPv4 and IPv6 address, or with virtual interfaces) are supported - reachability is determined by comparing the contact info for a peer against all addresses within the range covered by the address/mask pairs for the NIC.

* a message that arrives on one TCP NIC is automatically shifted to whatever NIC that is connected to the next "hop" if that peer cannot be reached by the incoming NIC. If no TCP module will reach the peer, then the OOB attempts to send the message via all other available components - if none can reach the peer, then an "error" is reported back to the RML, which then calls the errmgr for instructions.

* opal_buffer_t now conforms to standard object rules re OBJ_RETAIN as we no longer "unload" the incoming object

* NIC failure is reported to the TCP component, which then tries to resend the message across any other available TCP NIC. If that doesn't work, then the message is given back to the OOB base to try using other components. If all that fails, then the error is reported to the RML, which reports to the errmgr for instructions

* obviously from the above, multiple OOB components (e.g., TCP and UD) can be active in parallel

* the matching code has been moved to the RML (and out of the OOB/TCP component) so it is independent of transport

* routing is done by the individual OOB modules (as opposed to the RML). Thus, both routed and non-routed transports can simultaneously be active

* all blocking send/recv APIs have been removed. Everything operates asynchronously.


KNOWN LIMITATIONS:

* although provision is made for component failover as described above, the code for doing so has not been fully implemented yet. At the moment, if all connections for a given peer fail, the errmgr is notified of a "lost connection", which by default results in termination of the job if it was a lifeline

* the IPv6 code is present and compiles, but is not complete. Since the current IPv6 support in the OOB doesn't work anyway, I don't consider this a blocker

* routing is performed at the individual module level, yet the active routed component is selected on a global basis. We probably should update that to reflect that different transports may need/choose to route in different ways

* obviously, not every error path has been tested nor necessarily covered

* determining abnormal termination is more challenging than in the old code as we now potentially have multiple ways of connecting to a process. Ideally, we would declare "connection failed" when *all* transports can no longer reach the process, but that requires some additional (possibly complex) code. For now, the code replicates the old behavior only somewhat modified - i.e., if a module sees its connection fail, it checks to see if it is a lifeline. If so, it notifies the errmgr that the lifeline is lost - otherwise, it notifies the errmgr that a non-lifeline connection was lost.

* reachability is determined solely on the basis of a shared subnet address/mask - more sophisticated algorithms (e.g., the one used in the tcp btl) are required to handle routing via gateways

* the RML needs to assign sequence numbers to each message on a per-peer basis. The receiving RML will then deliver messages in order, thus preventing out-of-order messaging in the case where messages travel across different transports or a message needs to be redirected/resent due to failure of a NIC

This commit was SVN r29058.
2013-08-22 16:37:40 +00:00

476 строки
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C
Исходник Ответственный История

/*
* Copyright (c) 2004-2005 The Trustees of Indiana University and Indiana
* University Research and Technology
* Corporation. All rights reserved.
* Copyright (c) 2004-2011 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 (c) 2010 Oracle and/or its affiliates. All rights reserved.
* Copyright (c) 2011 Cisco Systems, Inc. All rights reserved.
* $COPYRIGHT$
*
* Additional copyrights may follow
*
* $HEADER$
*
*/
#include "orte_config.h"
#include "orte/constants.h"
#ifdef HAVE_STRING_H
#include <string.h>
#endif
#ifdef HAVE_SYS_TYPES_H
#include <sys/types.h>
#endif
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#include <signal.h>
#include <errno.h>
#include "opal/hash_string.h"
#include "opal/util/argv.h"
#include "opal/util/path.h"
#include "opal/mca/installdirs/installdirs.h"
#include "orte/util/show_help.h"
#include "orte/util/proc_info.h"
#include "orte/mca/errmgr/errmgr.h"
#include "orte/mca/routed/routed.h"
#include "orte/util/name_fns.h"
#include "orte/runtime/orte_globals.h"
#include "orte/util/nidmap.h"
#include "orte/mca/ess/ess.h"
#include "orte/mca/ess/base/base.h"
#include "orte/mca/ess/singleton/ess_singleton.h"
static int fork_hnp(void);
static void set_handler_default(int sig)
{
struct sigaction act;
act.sa_handler = SIG_DFL;
act.sa_flags = 0;
sigemptyset(&act.sa_mask);
sigaction(sig, &act, (struct sigaction *)0);
}
static int rte_init(void);
static int rte_finalize(void);
extern char *orte_ess_singleton_server_uri;
orte_ess_base_module_t orte_ess_singleton_module = {
rte_init,
rte_finalize,
orte_ess_base_app_abort,
NULL /* ft_event */
};
static int rte_init(void)
{
int rc;
char *param;
uint16_t jobfam;
uint32_t hash32;
uint32_t bias;
/* run the prolog */
if (ORTE_SUCCESS != (rc = orte_ess_base_std_prolog())) {
ORTE_ERROR_LOG(rc);
return rc;
}
if (NULL != orte_ess_singleton_server_uri) {
/* we are going to connect to a server HNP */
if (0 == strncmp(orte_ess_singleton_server_uri, "file", strlen("file")) ||
0 == strncmp(orte_ess_singleton_server_uri, "FILE", strlen("FILE"))) {
char input[1024], *filename;
FILE *fp;
/* it is a file - get the filename */
filename = strchr(orte_ess_singleton_server_uri, ':');
if (NULL == filename) {
/* filename is not correctly formatted */
orte_show_help("help-orterun.txt", "orterun:ompi-server-filename-bad", true,
"singleton", orte_ess_singleton_server_uri);
return ORTE_ERROR;
}
++filename; /* space past the : */
if (0 >= strlen(filename)) {
/* they forgot to give us the name! */
orte_show_help("help-orterun.txt", "orterun:ompi-server-filename-missing", true,
"singleton", orte_ess_singleton_server_uri);
return ORTE_ERROR;
}
/* open the file and extract the uri */
fp = fopen(filename, "r");
if (NULL == fp) { /* can't find or read file! */
orte_show_help("help-orterun.txt", "orterun:ompi-server-filename-access", true,
"singleton", orte_ess_singleton_server_uri);
return ORTE_ERROR;
}
if (NULL == fgets(input, 1024, fp)) {
/* something malformed about file */
fclose(fp);
orte_show_help("help-orterun.txt", "orterun:ompi-server-file-bad", true,
"singleton", orte_ess_singleton_server_uri, "singleton");
return ORTE_ERROR;
}
fclose(fp);
input[strlen(input)-1] = '\0'; /* remove newline */
orte_process_info.my_hnp_uri = strdup(input);
} else {
orte_process_info.my_hnp_uri = strdup(orte_ess_singleton_server_uri);
}
/* save the daemon uri - we will process it later */
orte_process_info.my_daemon_uri = strdup(orte_process_info.my_hnp_uri);
/* indicate we are a singleton so orte_init knows what to do */
orte_process_info.proc_type |= ORTE_PROC_SINGLETON;
/* for convenience, push the pubsub version of this param into the environ */
asprintf(&param,"OMPI_MCA_pubsub_orte_server=%s",orte_process_info.my_hnp_uri);
putenv(param);
/* now define my own name */
/* hash the nodename */
OPAL_HASH_STR(orte_process_info.nodename, hash32);
bias = (uint32_t)orte_process_info.pid;
OPAL_OUTPUT_VERBOSE((5, orte_ess_base_framework.framework_output,
"ess:singleton: initial bias %ld nodename hash %lu",
(long)bias, (unsigned long)hash32));
/* fold in the bias */
hash32 = hash32 ^ bias;
/* now compress to 16-bits */
jobfam = (uint16_t)(((0x0000ffff & (0xffff0000 & hash32) >> 16)) ^ (0x0000ffff & hash32));
OPAL_OUTPUT_VERBOSE((5, orte_ess_base_framework.framework_output,
"ess:singleton:: final jobfam %lu",
(unsigned long)jobfam));
/* set the name */
ORTE_PROC_MY_NAME->jobid = 0xffff0000 & ((uint32_t)jobfam << 16);
ORTE_PROC_MY_NAME->vpid = 0;
} else {
/*
* If we are the selected module, then we must be a singleton
* as it means that no other method for discovering a name
* could be found. In this case, we need to start a daemon that
* can support our operation. We must do this for two reasons:
*
* (1) if we try to play the role of the HNP, then any child processes
* we might start via comm_spawn will rely on us for all ORTE-level
* support. However, we can only progress those requests when the
* the application calls into the OMPI/ORTE library! Thus, if this
* singleton just does computation, the other processes will "hang"
* in any calls into the ORTE layer that communicate with the HNP -
* and most calls on application procs *do*.
*
* (2) daemons are used to communicate messages for administrative
* purposes in a broadcast-like manner. Thus, daemons are expected
* to be able to interpret specific commands. Our application process
* doesn't have any idea how to handle those commands, thus causing
* the entire ORTE administrative system to break down.
*
* For those reasons, we choose to fork/exec a daemon at this time
* and then reconnect ourselves to it. We could just "fork" and declare
* the child to be a daemon, but that would require we place *all* of the
* daemon command processing code in the ORTE library, do some strange
* mojo in a few places, etc. This doesn't seem worth it, so we'll just
* do the old fork/exec here
*/
if (ORTE_SUCCESS != (rc= fork_hnp())) {
/* if this didn't work, then we cannot support operation any further.
* Abort the system and tell orte_init to exit
*/
ORTE_ERROR_LOG(rc);
return rc;
}
}
orte_process_info.num_procs = 1;
if (orte_process_info.max_procs < orte_process_info.num_procs) {
orte_process_info.max_procs = orte_process_info.num_procs;
}
/* NOTE: do not wireup our io - let the fork'd orted serve
* as our io handler. This prevents issues with the event
* library wrt pty's and stdin
*/
/* use the std app init to complete the procedure */
if (ORTE_SUCCESS != (rc = orte_ess_base_app_setup())) {
ORTE_ERROR_LOG(rc);
return rc;
}
/* if one was provided, build my nidmap */
if (ORTE_SUCCESS != (rc = orte_util_nidmap_init(orte_process_info.sync_buf))) {
ORTE_ERROR_LOG(rc);
return rc;
}
/* set the collective ids */
orte_process_info.peer_modex = 0;
orte_process_info.peer_init_barrier = 1;
orte_process_info.peer_fini_barrier = 2;
/* set some envars */
putenv("OMPI_NUM_APP_CTX=1");
putenv("OMPI_FIRST_RANKS=0");
putenv("OMPI_APP_CTX_NUM_PROCS=1");
putenv("OMPI_MCA_orte_ess_num_procs=1");
return ORTE_SUCCESS;
}
static int rte_finalize(void)
{
int ret;
/* deconstruct my nidmap and jobmap arrays */
orte_util_nidmap_finalize();
/* use the default procedure to finish */
if (ORTE_SUCCESS != (ret = orte_ess_base_app_finalize())) {
ORTE_ERROR_LOG(ret);
}
return ret;
}
#define ORTE_URI_MSG_LGTH 256
static int fork_hnp(void)
{
int p[2], death_pipe[2];
char *cmd;
char **argv = NULL;
int argc;
char *param;
sigset_t sigs;
int buffer_length, num_chars_read, chunk;
char *orted_uri;
int rc;
/* A pipe is used to communicate between the parent and child to
indicate whether the exec ultimately succeeded or failed. The
child sets the pipe to be close-on-exec; the child only ever
writes anything to the pipe if there is an error (e.g.,
executable not found, exec() fails, etc.). The parent does a
blocking read on the pipe; if the pipe closed with no data,
then the exec() succeeded. If the parent reads something from
the pipe, then the child was letting us know that it failed.
*/
if (pipe(p) < 0) {
ORTE_ERROR_LOG(ORTE_ERR_SYS_LIMITS_PIPES);
return ORTE_ERR_SYS_LIMITS_PIPES;
}
/* we also have to give the HNP a pipe it can watch to know when
* we terminated. Since the HNP is going to be a child of us, it
* can't just use waitpid to see when we leave - so it will watch
* the pipe instead
*/
if (pipe(death_pipe) < 0) {
ORTE_ERROR_LOG(ORTE_ERR_SYS_LIMITS_PIPES);
return ORTE_ERR_SYS_LIMITS_PIPES;
}
/* find the orted binary using the install_dirs support - this also
* checks to ensure that we can see this executable and it *is* executable by us
*/
cmd = opal_path_access("orted", opal_install_dirs.bindir, X_OK);
if (NULL == cmd) {
/* guess we couldn't do it - best to abort */
ORTE_ERROR_LOG(ORTE_ERR_FILE_NOT_EXECUTABLE);
close(p[0]);
close(p[1]);
return ORTE_ERR_FILE_NOT_EXECUTABLE;
}
/* okay, setup an appropriate argv */
opal_argv_append(&argc, &argv, "orted");
/* tell the daemon it is to be the HNP */
opal_argv_append(&argc, &argv, "--hnp");
/* tell the daemon to get out of our process group */
opal_argv_append(&argc, &argv, "--set-sid");
/* tell the daemon to report back its uri so we can connect to it */
opal_argv_append(&argc, &argv, "--report-uri");
asprintf(&param, "%d", p[1]);
opal_argv_append(&argc, &argv, param);
free(param);
/* give the daemon a pipe it can watch to tell when we have died */
opal_argv_append(&argc, &argv, "--singleton-died-pipe");
asprintf(&param, "%d", death_pipe[0]);
opal_argv_append(&argc, &argv, param);
free(param);
/* add any debug flags */
if (orte_debug_flag) {
opal_argv_append(&argc, &argv, "--debug");
}
if (orte_debug_daemons_flag) {
opal_argv_append(&argc, &argv, "--debug-daemons");
}
if (orte_debug_daemons_file_flag) {
if (!orte_debug_daemons_flag) {
opal_argv_append(&argc, &argv, "--debug-daemons");
}
opal_argv_append(&argc, &argv, "--debug-daemons-file");
}
/* indicate that it must use the novm state machine */
opal_argv_append(&argc, &argv, "-mca");
opal_argv_append(&argc, &argv, "state_novm_select");
opal_argv_append(&argc, &argv, "1");
/* Fork off the child */
orte_process_info.hnp_pid = fork();
if(orte_process_info.hnp_pid < 0) {
ORTE_ERROR_LOG(ORTE_ERR_SYS_LIMITS_CHILDREN);
close(p[0]);
close(p[1]);
close(death_pipe[0]);
close(death_pipe[1]);
free(cmd);
opal_argv_free(argv);
return ORTE_ERR_SYS_LIMITS_CHILDREN;
}
if (orte_process_info.hnp_pid == 0) {
close(p[0]);
close(death_pipe[1]);
/* I am the child - exec me */
/* Set signal handlers back to the default. Do this close
to the execve() because the event library may (and likely
will) reset them. If we don't do this, the event
library may have left some set that, at least on some
OS's, don't get reset via fork() or exec(). Hence, the
orted could be unkillable (for example). */
set_handler_default(SIGTERM);
set_handler_default(SIGINT);
set_handler_default(SIGHUP);
set_handler_default(SIGPIPE);
set_handler_default(SIGCHLD);
/* Unblock all signals, for many of the same reasons that
we set the default handlers, above. This is noticable
on Linux where the event library blocks SIGTERM, but we
don't want that blocked by the orted (or, more
specifically, we don't want it to be blocked by the
orted and then inherited by the ORTE processes that it
forks, making them unkillable by SIGTERM). */
sigprocmask(0, 0, &sigs);
sigprocmask(SIG_UNBLOCK, &sigs, 0);
execv(cmd, argv);
/* if I get here, the execv failed! */
orte_show_help("help-ess-base.txt", "ess-base:execv-error",
true, cmd, strerror(errno));
exit(1);
} else {
/* I am the parent - wait to hear something back and
* report results
*/
close(p[1]); /* parent closes the write - orted will write its contact info to it*/
close(death_pipe[0]); /* parent closes the death_pipe's read */
opal_argv_free(argv);
/* setup the buffer to read the name + uri */
buffer_length = ORTE_URI_MSG_LGTH;
chunk = ORTE_URI_MSG_LGTH-1;
num_chars_read = 0;
orted_uri = (char*)malloc(buffer_length);
while (chunk == (rc = read(p[0], &orted_uri[num_chars_read], chunk))) {
/* we read an entire buffer - better get more */
num_chars_read += chunk;
buffer_length += ORTE_URI_MSG_LGTH;
orted_uri = realloc((void*)orted_uri, buffer_length);
}
num_chars_read += rc;
if (num_chars_read <= 0) {
/* we didn't get anything back - this is bad */
ORTE_ERROR_LOG(ORTE_ERR_HNP_COULD_NOT_START);
free(orted_uri);
return ORTE_ERR_HNP_COULD_NOT_START;
}
if (']' != orted_uri[strlen(orted_uri)-1]) {
ORTE_ERROR_LOG(ORTE_ERR_COMM_FAILURE);
free(orted_uri);
return ORTE_ERR_COMM_FAILURE;
}
orted_uri[strlen(orted_uri)-1] = '\0';
/* parse the sysinfo from the returned info */
if (NULL == (param = strrchr(orted_uri, '['))) {
ORTE_ERROR_LOG(ORTE_ERR_COMM_FAILURE);
free(orted_uri);
return ORTE_ERR_COMM_FAILURE;
}
param[-1] = '\0'; /* terminate the string */
if (ORTE_SUCCESS != (rc = orte_util_convert_string_to_sysinfo(&orte_local_cpu_type,
&orte_local_cpu_model, ++param))) {
ORTE_ERROR_LOG(rc);
free(orted_uri);
return rc;
}
/* parse the name from the returned info */
if (NULL == (param = strrchr(orted_uri, '['))) {
ORTE_ERROR_LOG(ORTE_ERR_COMM_FAILURE);
free(orted_uri);
return ORTE_ERR_COMM_FAILURE;
}
*param = '\0'; /* terminate the string */
param++;
if (ORTE_SUCCESS != (rc = orte_util_convert_string_to_process_name(ORTE_PROC_MY_NAME, param))) {
ORTE_ERROR_LOG(rc);
free(orted_uri);
return rc;
}
/* save the daemon uri - we will process it later */
orte_process_info.my_daemon_uri = strdup(orted_uri);
/* likewise, since this is also the HNP, set that uri too */
orte_process_info.my_hnp_uri = strdup(orted_uri);
/* indicate we are a singleton so orte_init knows what to do */
orte_process_info.proc_type |= ORTE_PROC_SINGLETON;
/* all done - report success */
free(orted_uri);
return ORTE_SUCCESS;
}
}
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