/*
This file is provided under a dual BSD/GPLv2 license. When using or
redistributing this file, you may do so under either license.
GPL LICENSE SUMMARY
Copyright(c) 2015 Intel Corporation.
This program is free software; you can redistribute it and/or modify
it under the terms of version 2 of the GNU General Public License as
published by the Free Software Foundation.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
Contact Information:
Intel Corporation, www.intel.com
BSD LICENSE
Copyright(c) 2015 Intel Corporation.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions
are met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in
the documentation and/or other materials provided with the
distribution.
* Neither the name of Intel Corporation nor the names of its
contributors may be used to endorse or promote products derived
from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/* Copyright (c) 2003-2014 Intel Corporation. All rights reserved. */
#include "psm_user.h"
#include "psm_mq_internal.h"
int psmi_ep_device_is_enabled(const psm2_ep_t ep, int devid);
#if _HFI_DEBUGGING
PSMI_ALWAYS_INLINE(
char *psmi_getdevice(int type))
{
switch (type) {
case PTL_DEVID_IPS:
return "ips";
case PTL_DEVID_AMSH:
return "amsh";
case PTL_DEVID_SELF:
return "self";
default:
return "ips";
}
}
#endif
psm2_error_t
__psm2_ep_connect(psm2_ep_t ep, int num_of_epid, psm2_epid_t const *array_of_epid,
int const *array_of_epid_mask, /* can be NULL */
psm2_error_t *array_of_errors, psm2_epaddr_t *array_of_epaddr,
int64_t timeout)
{
psm2_error_t err = PSM2_OK;
ptl_ctl_t *ptlctl;
ptl_t *ptl;
int i, j, dup_idx;
int num_toconnect = 0;
int *epid_mask = NULL;
int *epid_mask_isdupof = NULL;
uint64_t t_start = get_cycles();
uint64_t t_left;
union psmi_envvar_val timeout_intval;
PSM2_LOG_MSG("entering");
PSMI_ERR_UNLESS_INITIALIZED(ep);
/*
* Normally we would lock here, but instead each implemented ptl component
* does its own locking. This is mostly because the ptl components are
* ahead of the PSM2 interface in that they can disconnect their peers.
*/
if (ep == NULL || array_of_epaddr == NULL || array_of_epid == NULL ||
num_of_epid < 1) {
err = psmi_handle_error(ep, PSM2_PARAM_ERR,
"Invalid psm2_ep_connect parameters");
goto fail_nolock;
}
PSMI_LOCK(ep->mq->progress_lock);
/* We need two of these masks to detect duplicates */
err = PSM2_NO_MEMORY;
epid_mask =
(int *)psmi_malloc(ep, UNDEFINED, sizeof(int) * num_of_epid);
if (epid_mask == NULL)
goto fail;
epid_mask_isdupof =
(int *)psmi_malloc(ep, UNDEFINED, sizeof(int) * num_of_epid);
if (epid_mask_isdupof == NULL)
goto fail;
err = PSM2_OK;
/* Eventually handle timeouts across all connects. */
for (j = 0; j < num_of_epid; j++) {
if (array_of_epid_mask != NULL && !array_of_epid_mask[j])
epid_mask[j] = 0;
else {
epid_mask[j] = 1;
array_of_errors[j] = PSM2_EPID_UNKNOWN;
array_of_epaddr[j] = NULL;
if (psmi_epid_version(array_of_epid[j]) >
PSMI_EPID_VERSION) {
psmi_handle_error(PSMI_EP_NORETURN, PSM2_INTERNAL_ERR,
" Unknown version of EPID - %"PRIu64" \n"
"Please upgrade PSM2 or set PSM2_ADDR_FMT=1 in the environment to force EPID version 1 \n",
psmi_epid_version(array_of_epid[j]));
}
num_toconnect++;
}
epid_mask_isdupof[j] = -1;
}
psmi_getenv("PSM2_CONNECT_TIMEOUT",
"End-point connection timeout over-ride. 0 for no time-out.",
PSMI_ENVVAR_LEVEL_USER, PSMI_ENVVAR_TYPE_UINT,
(union psmi_envvar_val)0, &timeout_intval);
if (getenv("PSM2_CONNECT_TIMEOUT")) {
timeout = timeout_intval.e_uint * SEC_ULL;
} else if (timeout > 0) {
/* The timeout parameter provides the minimum timeout. A heuristic
* is used to scale up the timeout linearly with the number of
* endpoints, and we allow one second per 100 endpoints. */
timeout = max(timeout, (num_toconnect * SEC_ULL) / 100);
}
if (timeout > 0 && timeout < PSMI_MIN_EP_CONNECT_TIMEOUT)
timeout = PSMI_MIN_EP_CONNECT_TIMEOUT;
_HFI_PRDBG("Connect to %d endpoints with time-out of %.2f secs\n",
num_toconnect, (double)timeout / 1e9);
/* Look for duplicates in input array */
for (i = 0; i < num_of_epid; i++) {
for (j = i + 1; j < num_of_epid; j++) {
if (array_of_epid[i] == array_of_epid[j] &&
epid_mask[i] && epid_mask[j]) {
epid_mask[j] = 0; /* don't connect more than once */
epid_mask_isdupof[j] = i;
}
}
}
for (i = 0; i < PTL_MAX_INIT; i++) {
if (ep->devid_enabled[i] == -1)
continue;
/* Set up the right connect ptrs */
switch (ep->devid_enabled[i]) {
case PTL_DEVID_IPS:
ptlctl = &ep->ptl_ips;
ptl = ep->ptl_ips.ptl;
break;
case PTL_DEVID_AMSH:
ptlctl = &ep->ptl_amsh;
ptl = ep->ptl_amsh.ptl;
break;
case PTL_DEVID_SELF:
ptlctl = &ep->ptl_self;
ptl = ep->ptl_self.ptl;
break;
default:
ptlctl = &ep->ptl_ips; /*no-unused */
ptl = ep->ptl_ips.ptl; /*no-unused */
psmi_handle_error(PSMI_EP_NORETURN, PSM2_INTERNAL_ERR,
"Unknown/unhandled PTL id %d\n",
ep->devid_enabled[i]);
break;
}
t_left = psmi_cycles_left(t_start, timeout);
if (_HFI_VDBG_ON) {
_HFI_VDBG_ALWAYS
("Trying to connect with device %s\n",
psmi_getdevice(ep->devid_enabled[i]));
}
if ((err = ptlctl->ep_connect(ptl, num_of_epid, array_of_epid,
epid_mask, array_of_errors,
array_of_epaddr,
cycles_to_nanosecs(t_left)))) {
if (_HFI_PRDBG_ON) {
_HFI_PRDBG_ALWAYS
("Connect failure in device %s err=%d\n",
psmi_getdevice(ep->devid_enabled[i]), err);
}
goto connect_fail;
}
/* Now process what's been connected */
for (j = 0; j < num_of_epid; j++) {
dup_idx = epid_mask_isdupof[j];
if (!epid_mask[j] && dup_idx == -1)
continue;
if (dup_idx != -1) { /* dup */
array_of_epaddr[j] = array_of_epaddr[dup_idx];
array_of_errors[j] = array_of_errors[dup_idx];
epid_mask_isdupof[j] = -1;
}
if (array_of_errors[j] == PSM2_OK) {
epid_mask[j] = 0; /* don't try on next ptl */
ep->connections++;
}
}
}
for (i = 0; i < num_of_epid; i++) {
ptl_ctl_t *c = NULL;
if (array_of_epid_mask != NULL && !array_of_epid_mask[i])
continue;
/* If we see unreachable here, that means some PTLs were not enabled */
if (array_of_errors[i] == PSM2_EPID_UNREACHABLE) {
err = PSM2_EPID_UNREACHABLE;
break;
}
psmi_assert_always(array_of_epaddr[i] != NULL);
c = array_of_epaddr[i]->ptlctl;
psmi_assert_always(c != NULL);
_HFI_VDBG("%-20s DEVICE %s (%p)\n",
psmi_epaddr_get_name(array_of_epid[i]),
c == &ep->ptl_ips ? "hfi" :
(c == &ep->ptl_amsh ? "amsh" : "self"),
(void *)array_of_epaddr[i]->ptlctl->ptl);
}
if (err == PSM2_OK)
for (i=0; i<num_of_epid; i++)
array_of_errors[i] = PSM2_OK;
connect_fail:
/* If the error is a timeout (at worse) and the client is OPA MPI,
* just return timeout to let OPA MPI handle the hostnames that
* timed out */
if (err != PSM2_OK) {
char errbuf[PSM2_ERRSTRING_MAXLEN];
size_t len;
int j = 0;
if (err == PSM2_EPID_UNREACHABLE) {
char *deverr = "of an incorrect setting";
char *eperr = "";
char *devname = NULL;
if (!psmi_ep_device_is_enabled(ep, PTL_DEVID_AMSH)) {
deverr =
"there is no shared memory PSM2 device (shm)";
eperr = " shared memory";
} else
if (!psmi_ep_device_is_enabled(ep, PTL_DEVID_IPS)) {
deverr =
"there is no OPA PSM2 device (hfi)";
eperr = " OPA";
}
len = snprintf(errbuf, sizeof(errbuf) - 1,
"Some%s endpoints could not be connected because %s "
"in the currently enabled PSM2_DEVICES (",
eperr, deverr);
for (i = 0; i < PTL_MAX_INIT && len < sizeof(errbuf) - 1;
i++) {
switch (ep->devid_enabled[i]) {
case PTL_DEVID_IPS:
devname = "hfi";
break;
case PTL_DEVID_AMSH:
devname = "shm";
break;
case PTL_DEVID_SELF:
default:
devname = "self";
break;
}
len +=
snprintf(errbuf + len,
sizeof(errbuf) - len - 1, "%s,",
devname);
}
if (len < sizeof(errbuf) - 1 && devname != NULL)
/* parsed something, remove trailing comma */
errbuf[len - 1] = ')';
} else
len = snprintf(errbuf, sizeof(errbuf) - 1,
"%s", err == PSM2_TIMEOUT ?
"Detected connection timeout" :
psm2_error_get_string(err));
/* first pass, look for all nodes with the error */
for (i = 0; i < num_of_epid && len < sizeof(errbuf) - 1; i++) {
if (array_of_epid_mask != NULL
&& !array_of_epid_mask[i])
continue;
if (array_of_errors[i] == PSM2_OK)
continue;
if (array_of_errors[i] == PSM2_EPID_UNREACHABLE &&
err != PSM2_EPID_UNREACHABLE)
continue;
if (err == array_of_errors[i]) {
len +=
snprintf(errbuf + len,
sizeof(errbuf) - len - 1, "%c %s",
j == 0 ? ':' : ',',
psmi_epaddr_get_hostname
(array_of_epid[i]));
j++;
}
}
errbuf[sizeof(errbuf) - 1] = '\0';
err = psmi_handle_error(ep, err, "%s", errbuf);
}
fail:
PSMI_UNLOCK(ep->mq->progress_lock);
fail_nolock:
if (epid_mask != NULL)
psmi_free(epid_mask);
if (epid_mask_isdupof != NULL)
psmi_free(epid_mask_isdupof);
PSM2_LOG_MSG("leaving");
return err;
}
PSMI_API_DECL(psm2_ep_connect)
psm2_error_t __psm2_ep_disconnect(psm2_ep_t ep, int num_of_epaddr,
psm2_epaddr_t *array_of_epaddr,
const int *array_of_epaddr_mask,
psm2_error_t *array_of_errors,
int64_t timeout)
{
return psm2_ep_disconnect2(ep, num_of_epaddr, array_of_epaddr,
array_of_epaddr_mask, array_of_errors,
PSM2_EP_DISCONNECT_GRACEFUL, timeout);
}
PSMI_API_DECL(psm2_ep_disconnect)
psm2_error_t __psm2_ep_disconnect2(psm2_ep_t ep, int num_of_epaddr,
psm2_epaddr_t *array_of_epaddr,
const int *array_of_epaddr_mask,
psm2_error_t *array_of_errors,
int mode, int64_t timeout)
{
psm2_error_t err = PSM2_OK;
ptl_ctl_t *ptlctl;
ptl_t *ptl;
int i, j, dup_idx;
int num_todisconnect = 0;
int *epaddr_mask = NULL;
int *epaddr_mask_isdupof = NULL;
uint64_t t_start = get_cycles();
uint64_t t_left;
union psmi_envvar_val timeout_intval;
PSM2_LOG_MSG("entering");
PSMI_ERR_UNLESS_INITIALIZED(ep);
/*
* Normally we would lock here, but instead each implemented ptl component
* does its own locking. This is mostly because the ptl components are
* ahead of the PSM2 interface in that they can disconnect their peers.
*/
if (ep == NULL || array_of_epaddr == NULL ||
num_of_epaddr < 1) {
err = psmi_handle_error(ep, PSM2_PARAM_ERR,
"Invalid psm2_ep_disconnect parameters");
goto fail_nolock;
}
PSMI_LOCK(ep->mq->progress_lock);
/* We need two of these masks to detect duplicates */
err = PSM2_NO_MEMORY;
epaddr_mask =
(int *)psmi_malloc(ep, UNDEFINED, sizeof(int) * num_of_epaddr);
if (epaddr_mask == NULL)
goto fail;
epaddr_mask_isdupof =
(int *)psmi_malloc(ep, UNDEFINED, sizeof(int) * num_of_epaddr);
if (epaddr_mask_isdupof == NULL)
goto fail;
err = PSM2_OK;
/* Eventually handle timeouts across all connects. */
for (j = 0; j < num_of_epaddr; j++) {
if (array_of_epaddr_mask != NULL && !array_of_epaddr_mask[j])
epaddr_mask[j] = 0;
else {
epaddr_mask[j] = 1;
array_of_errors[j] = PSM2_EPID_UNKNOWN;
num_todisconnect++;
}
epaddr_mask_isdupof[j] = -1;
}
psmi_getenv("PSM2_DISCONNECT_TIMEOUT",
"End-point disconnection timeout over-ride. 0 for no time-out.",
PSMI_ENVVAR_LEVEL_USER, PSMI_ENVVAR_TYPE_UINT,
(union psmi_envvar_val)0, &timeout_intval);
if (getenv("PSM2_DISCONNECT_TIMEOUT")) {
timeout = timeout_intval.e_uint * SEC_ULL;
} else if (timeout > 0) {
/* The timeout parameter provides the minimum timeout. A heuristic
* is used to scale up the timeout linearly with the number of
* endpoints, and we allow one second per 100 endpoints. */
timeout = max(timeout, (num_todisconnect * SEC_ULL) / 100);
}
if (timeout > 0 && timeout < PSMI_MIN_EP_CONNECT_TIMEOUT)
timeout = PSMI_MIN_EP_CONNECT_TIMEOUT;
_HFI_PRDBG("Disconnect %d endpoints with time-out of %.2f secs\n",
num_todisconnect, (double)timeout / 1e9);
/* Look for duplicates in input array */
for (i = 0; i < num_of_epaddr; i++) {
for (j = i + 1; j < num_of_epaddr; j++) {
if (array_of_epaddr[i] == array_of_epaddr[j] &&
epaddr_mask[i] && epaddr_mask[j]) {
epaddr_mask[j] = 0; /* don't disconnect more than once */
epaddr_mask_isdupof[j] = i;
}
}
}
for (i = 0; i < PTL_MAX_INIT; i++) {
if (ep->devid_enabled[i] == -1)
continue;
/* Set up the right connect ptrs */
switch (ep->devid_enabled[i]) {
case PTL_DEVID_IPS:
ptlctl = &ep->ptl_ips;
ptl = ep->ptl_ips.ptl;
break;
case PTL_DEVID_AMSH:
ptlctl = &ep->ptl_amsh;
ptl = ep->ptl_amsh.ptl;
break;
case PTL_DEVID_SELF:
ptlctl = &ep->ptl_self;
ptl = ep->ptl_self.ptl;
break;
default:
ptlctl = &ep->ptl_ips; /*no-unused */
ptl = ep->ptl_ips.ptl; /*no-unused */
psmi_handle_error(PSMI_EP_NORETURN, PSM2_INTERNAL_ERR,
"Unknown/unhandled PTL id %d\n",
ep->devid_enabled[i]);
break;
}
t_left = psmi_cycles_left(t_start, timeout);
if (_HFI_VDBG_ON) {
_HFI_VDBG_ALWAYS
("Trying to disconnect with device %s\n",
psmi_getdevice(ep->devid_enabled[i]));
}
if ((err = ptlctl->ep_disconnect(ptl, (mode == PSM2_EP_DISCONNECT_FORCE),
num_of_epaddr, array_of_epaddr,
epaddr_mask, array_of_errors,
cycles_to_nanosecs(t_left)))) {
if (_HFI_PRDBG_ON) {
_HFI_PRDBG_ALWAYS
("Disconnect failure in device %s err=%d\n",
psmi_getdevice(ep->devid_enabled[i]), err);
}
goto disconnect_fail;
}
/* Now process what's been disconnected */
for (j = 0; j < num_of_epaddr; j++) {
dup_idx = epaddr_mask_isdupof[j];
if (!epaddr_mask[j] && dup_idx == -1)
continue;
if (dup_idx != -1) { /* dup */
array_of_errors[j] = array_of_errors[dup_idx];
epaddr_mask_isdupof[j] = -1;
}
if (array_of_errors[j] == PSM2_OK) {
epaddr_mask[j] = 0; /* don't try on next ptl */
array_of_epaddr[j] = NULL;
ep->connections--;
}
}
}
for (i = 0; i < num_of_epaddr; i++) {
if (array_of_epaddr_mask != NULL && !array_of_epaddr_mask[i])
continue;
/* If we see unreachable here, that means some PTLs were not enabled */
if (array_of_errors[i] == PSM2_EPID_UNREACHABLE) {
err = PSM2_EPID_UNREACHABLE;
break;
}
}
disconnect_fail:
/* If the error is a timeout (at worse) and the client is OPA MPI,
* just return timeout to let OPA MPI handle the hostnames that
* timed out */
if (err != PSM2_OK) {
char errbuf[PSM2_ERRSTRING_MAXLEN];
size_t len;
int j = 0;
if (err == PSM2_EPID_UNREACHABLE) {
char *deverr = "of an incorrect setting";
char *eperr = "";
char *devname = NULL;
if (!psmi_ep_device_is_enabled(ep, PTL_DEVID_AMSH)) {
deverr =
"there is no shared memory PSM2 device (shm)";
eperr = " shared memory";
} else
if (!psmi_ep_device_is_enabled(ep, PTL_DEVID_IPS)) {
deverr =
"there is no OPA PSM2 device (hfi)";
eperr = " OPA";
}
len = snprintf(errbuf, sizeof(errbuf) - 1,
"Some%s endpoints could not be disconnected because %s "
"in the currently enabled PSM2_DEVICES (",
eperr, deverr);
for (i = 0; i < PTL_MAX_INIT && len < sizeof(errbuf) - 1; i++) {
switch (ep->devid_enabled[i]) {
case PTL_DEVID_IPS:
devname = "hfi";
break;
case PTL_DEVID_AMSH:
devname = "shm";
break;
case PTL_DEVID_SELF:
default:
devname = "self";
break;
}
len +=
snprintf(errbuf + len,
sizeof(errbuf) - len - 1, "%s,",
devname);
}
if (len < sizeof(errbuf) - 1 && devname != NULL)
/* parsed something, remove trailing comma */
errbuf[len - 1] = ')';
} else
len = snprintf(errbuf, sizeof(errbuf) - 1,
"%s", err == PSM2_TIMEOUT ?
"Detected disconnect timeout" :
psm2_error_get_string(err));
/* first pass, look for all nodes with the error */
for (i = 0; i < num_of_epaddr && len < sizeof(errbuf) - 1; i++) {
if (array_of_epaddr_mask != NULL
&& !array_of_epaddr_mask[i])
continue;
if (array_of_errors[i] == PSM2_OK)
continue;
if (array_of_errors[i] == PSM2_EPID_UNREACHABLE &&
err != PSM2_EPID_UNREACHABLE)
continue;
if (err == array_of_errors[i]) {
len +=
snprintf(errbuf + len,
sizeof(errbuf) - len - 1, "%c %s",
j == 0 ? ':' : ',',
psmi_epaddr_get_hostname
(array_of_epaddr[i]->epid));
j++;
}
}
errbuf[sizeof(errbuf) - 1] = '\0';
err = psmi_handle_error(ep, err, "%s", errbuf);
}
fail:
PSMI_UNLOCK(ep->mq->progress_lock);
fail_nolock:
if (epaddr_mask != NULL)
psmi_free(epaddr_mask);
if (epaddr_mask_isdupof != NULL)
psmi_free(epaddr_mask_isdupof);
PSM2_LOG_MSG("leaving");
return err;
}
PSMI_API_DECL(psm2_ep_disconnect2)