/*
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) 2003-2015 Intel Corporation. All rights reserved. */
#include "psm_user.h"
#include "psm2_hal.h"
#include "psm_mq_internal.h"
#include "ptl_ips/ips_proto_header.h"
#ifdef PSM_CUDA
#include "psm_gdrcpy.h"
#endif
#if 0
/* Not exposed in public psm, but may extend parts of PSM 2.1 to support
* this feature before 2.3 */
psm_mq_unexpected_callback_fn_t
psmi_mq_register_unexpected_callback(psm2_mq_t mq,
psm_mq_unexpected_callback_fn_t fn)
{
psm_mq_unexpected_callback_fn_t old_fn = mq->unexpected_callback;
mq->unexpected_callback = fn;
return old_fn;
}
#endif
void psmi_mq_handle_rts_complete(psm2_mq_req_t req)
{
psm2_mq_t mq = req->mq;
/* Stats on rendez-vous messages */
psmi_mq_stats_rts_account(req);
req->state = MQ_STATE_COMPLETE;
ips_barrier();
if(!psmi_is_req_internal(req))
mq_qq_append(&mq->completed_q, req);
_HFI_VDBG("RTS complete, req=%p, recv_msglen = %d\n",
req, req->req_data.recv_msglen);
return;
}
static void
psmi_mq_req_copy(psm2_mq_req_t req,
uint32_t offset, const void *buf, uint32_t nbytes)
{
/* recv_msglen may be changed by unexpected receive req_data.buf. */
uint32_t msglen_this, end;
uint8_t *msgptr = (uint8_t *) req->req_data.buf + offset;
/* out of receiving range. */
if (offset >= req->req_data.recv_msglen) {
req->send_msgoff += nbytes;
return;
}
end = offset + nbytes;
if (end > req->req_data.recv_msglen) {
msglen_this = req->req_data.recv_msglen - offset;
end = req->req_data.recv_msglen;
} else {
msglen_this = nbytes;
}
psmi_mq_mtucpy(msgptr, buf, msglen_this);
if (req->recv_msgoff < end) {
req->recv_msgoff = end;
}
req->send_msgoff += nbytes;
return;
}
int
psmi_mq_handle_data(psm2_mq_t mq, psm2_mq_req_t req,
uint32_t offset, const void *buf, uint32_t nbytes)
{
psmi_assert(req != NULL);
int rc;
if (req->state == MQ_STATE_MATCHED)
rc = MQ_RET_MATCH_OK;
else {
psmi_assert(req->state == MQ_STATE_UNEXP);
rc = MQ_RET_UNEXP_OK;
}
psmi_mq_req_copy(req, offset, buf, nbytes);
/*
* the reason to use >= is because send_msgoff
* may be DW pad included.
*/
if (req->send_msgoff >= req->req_data.send_msglen) {
if (req->type & MQE_TYPE_EAGER_QUEUE) {
STAILQ_REMOVE(&mq->eager_q, req, psm2_mq_req, nextq);
}
if (req->state == MQ_STATE_MATCHED) {
req->state = MQ_STATE_COMPLETE;
ips_barrier();
mq_qq_append(&mq->completed_q, req);
} else { /* MQ_STATE_UNEXP */
req->state = MQ_STATE_COMPLETE;
}
}
return rc;
}
static
void mq_add_to_unexpected_hashes(psm2_mq_t mq, psm2_mq_req_t req)
{
int table;
mq_qq_append(&mq->unexpected_q, req);
req->q[PSM2_ANYTAG_ANYSRC] = &mq->unexpected_q;
mq->unexpected_list_len++;
if_pt (mq->nohash_fastpath) {
if_pf (mq->unexpected_list_len >= HASH_THRESHOLD)
psmi_mq_fastpath_disable(mq);
return;
}
for (table = PSM2_TAG_SRC; table < PSM2_ANYTAG_ANYSRC; table++)
mq_qq_append_which(mq->unexpected_htab,
table, mq->hashvals[table], req);
mq->unexpected_hash_len++;
}
psm2_mq_req_t
mq_list_scan(struct mqq *q, psm2_epaddr_t src, psm2_mq_tag_t *tag, int which, uint64_t *time_threshold)
{
psm2_mq_req_t *curp, cur;
for (curp = &q->first;
((cur = *curp) != NULL) && (cur->timestamp < *time_threshold);
curp = &cur->next[which]) {
if ((cur->req_data.peer == PSM2_MQ_ANY_ADDR || src == cur->req_data.peer) &&
!((tag->tag[0] ^ cur->req_data.tag.tag[0]) & cur->req_data.tagsel.tag[0]) &&
!((tag->tag[1] ^ cur->req_data.tag.tag[1]) & cur->req_data.tagsel.tag[1]) &&
!((tag->tag[2] ^ cur->req_data.tag.tag[2]) & cur->req_data.tagsel.tag[2])) {
*time_threshold = cur->timestamp;
return cur;
}
}
return NULL;
}
psm2_mq_req_t
mq_req_match(psm2_mq_t mq, psm2_epaddr_t src, psm2_mq_tag_t *tag, int remove)
{
psm2_mq_req_t match[4];
int table;
uint64_t best_ts = -1;
if (mq->nohash_fastpath) {
table = PSM2_ANYTAG_ANYSRC;
match[table] =
mq_list_scan(&mq->expected_q,
src, tag, PSM2_ANYTAG_ANYSRC, &best_ts);
if (match[table] && remove) {
mq->expected_list_len--;
mq_qq_remove_which(match[table], table);
}
return match[table];
}
mq->hashvals[PSM2_TAG_SRC] = hash_64(*(uint64_t *) tag->tag) % NUM_HASH_BUCKETS;
mq->hashvals[PSM2_TAG_ANYSRC] = hash_32(tag->tag[0]) % NUM_HASH_BUCKETS;
mq->hashvals[PSM2_ANYTAG_SRC] = hash_32(tag->tag[1]) % NUM_HASH_BUCKETS;
for (table = PSM2_TAG_SRC; table < PSM2_ANYTAG_ANYSRC; table++)
match[table] =
mq_list_scan(&mq->expected_htab[table][mq->hashvals[table]],
src, tag, table, &best_ts);
table = PSM2_ANYTAG_ANYSRC;
match[table] = mq_list_scan(&mq->expected_q, src, tag, table, &best_ts);
table = min_timestamp_4(match);
if (table == -1)
return NULL;
if (remove) {
if_pt (table == PSM2_ANYTAG_ANYSRC)
mq->expected_list_len--;
else
mq->expected_hash_len--;
mq_qq_remove_which(match[table], table);
psmi_mq_fastpath_try_reenable(mq);
}
return match[table];
}
/*
* This handles the rendezvous MPI envelopes, the packet might have the whole
* message payload, or zero payload.
*/
int
psmi_mq_handle_rts(psm2_mq_t mq, psm2_epaddr_t src, psm2_mq_tag_t *tag,
uint32_t send_msglen, const void *payload, uint32_t paylen,
int msgorder, mq_rts_callback_fn_t cb, psm2_mq_req_t *req_o)
{
psm2_mq_req_t req;
uint32_t msglen;
int rc;
PSMI_LOCK_ASSERT(mq->progress_lock);
if (msgorder && (req = mq_req_match(mq, src, tag, 1))) {
/* we have a match, no need to callback */
msglen = mq_set_msglen(req, req->req_data.buf_len, send_msglen);
/* reset send_msglen because sender only sends this many */
req->req_data.send_msglen = msglen;
req->state = MQ_STATE_MATCHED;
req->req_data.peer = src;
req->req_data.tag = *tag;
if (paylen > msglen) paylen = msglen;
if (paylen) {
psmi_mq_mtucpy(req->req_data.buf, payload, paylen);
}
req->recv_msgoff = req->send_msgoff = paylen;
*req_o = req; /* yes match */
PSM2_LOG_EPM(OPCODE_LONG_RTS,PSM2_LOG_RX,src->epid,mq->ep->epid,
"req->rts_reqidx_peer: %d",req->rts_reqidx_peer);
rc = MQ_RET_MATCH_OK;
} else if (msgorder > 1) {
/* There is NO request match, and this is the first time
* to try to process this packet, we leave the packet in
* hardware queue for retry in hope there is a request
* match next time, this is for performance
* consideration.
*/
rc = MQ_RET_UNEXP_NO_RESOURCES;
} else { /* No match, keep track of callback */
req = psmi_mq_req_alloc(mq, MQE_TYPE_RECV);
psmi_assert(req != NULL);
/* We don't know recv_msglen yet but we set it here for
* mq_iprobe */
req->req_data.send_msglen = req->req_data.recv_msglen = send_msglen;
PSM2_LOG_EPM_COND(req->req_data.send_msglen > mq->hfi_thresh_rv,
OPCODE_LONG_RTS,PSM2_LOG_RX,src->epid,mq->ep->epid,
"req->rts_reqidx_peer: %d",req->rts_reqidx_peer);
req->state = MQ_STATE_UNEXP_RV;
req->req_data.peer = src;
req->req_data.tag = *tag;
req->rts_callback = cb;
if (paylen > send_msglen) paylen = send_msglen;
if (paylen) {
req->req_data.buf = psmi_mq_sysbuf_alloc(mq, paylen);
psmi_assert(paylen == 0 || req->req_data.buf != NULL);
mq->stats.rx_sysbuf_num++;
mq->stats.rx_sysbuf_bytes += paylen;
psmi_mq_mtucpy(req->req_data.buf, payload, paylen);
}
req->recv_msgoff = req->send_msgoff = paylen;
if (msgorder) {
mq_add_to_unexpected_hashes(mq, req);
}
/* caller will handle out of order case */
*req_o = req; /* no match, will callback */
rc = MQ_RET_UNEXP_OK;
}
#ifdef PSM_DEBUG
if (req)
_HFI_VDBG("match=%s (req=%p) src=%s mqtag=%08x.%08x.%08x recvlen=%d "
"sendlen=%d errcode=%d\n",
rc == MQ_RET_MATCH_OK ? "YES" : "NO", req,
psmi_epaddr_get_name(src->epid),
req->req_data.tag.tag[0], req->req_data.tag.tag[1], req->req_data.tag.tag[2],
req->req_data.recv_msglen, req->req_data.send_msglen, req->req_data.error_code);
else
_HFI_VDBG("match=%s (req=%p) src=%s\n",
rc == MQ_RET_MATCH_OK ? "YES" : "NO", req,
psmi_epaddr_get_name(src->epid));
#endif /* #ifdef PSM_DEBUG */
return rc;
}
/*
* This handles the regular (i.e. non-rendezvous MPI envelopes)
*/
int
psmi_mq_handle_envelope(psm2_mq_t mq, psm2_epaddr_t src, psm2_mq_tag_t *tag,
uint32_t send_msglen, uint32_t offset,
const void *payload, uint32_t paylen, int msgorder,
uint32_t opcode, psm2_mq_req_t *req_o)
{
psm2_mq_req_t req;
uint32_t msglen;
psmi_mtucpy_fn_t psmi_mtucpy_fn;
if (msgorder && (req = mq_req_match(mq, src, tag, 1))) {
/* we have a match */
void *user_buffer = req->req_data.buf;
psmi_assert(MQE_TYPE_IS_RECV(req->type));
req->req_data.peer = src;
req->req_data.tag = *tag;
msglen = mq_set_msglen(req, req->req_data.buf_len, send_msglen);
_HFI_VDBG("match=YES (req=%p) opcode=%x src=%s mqtag=%x.%x.%x"
" msglen=%d paylen=%d\n", req, opcode,
psmi_epaddr_get_name(src->epid),
tag->tag[0], tag->tag[1], tag->tag[2], msglen,
paylen);
switch (opcode) {
case MQ_MSG_TINY:
/* mq_copy_tiny() can handle zero byte */
#ifdef PSM_CUDA
if (PSMI_USE_GDR_COPY(req, msglen)) {
user_buffer = gdr_convert_gpu_to_host_addr(GDR_FD,
(unsigned long)req->req_data.buf,
msglen, 1, src->proto);
}
#endif
mq_copy_tiny((uint32_t *) user_buffer, (uint32_t *) payload, msglen);
req->state = MQ_STATE_COMPLETE;
ips_barrier();
mq_qq_append(&mq->completed_q, req);
break;
case MQ_MSG_SHORT: /* message fits in 1 payload */
psmi_mtucpy_fn = psmi_mq_mtucpy;
#ifdef PSM_CUDA
if (PSMI_USE_GDR_COPY(req, msglen)) {
user_buffer = gdr_convert_gpu_to_host_addr(GDR_FD,
(unsigned long)req->req_data.buf,
msglen, 1, src->proto);
psmi_mtucpy_fn = psmi_mq_mtucpy_host_mem;
}
#endif
if (msglen <= paylen) {
psmi_mtucpy_fn(user_buffer, payload, msglen);
} else {
psmi_assert((msglen & ~0x3) == paylen);
psmi_mtucpy_fn(user_buffer, payload, paylen);
/*
* there are nonDW bytes attached in header,
* copy after the DW payload.
*/
mq_copy_tiny((uint32_t *)(user_buffer+paylen),
(uint32_t *)&offset, msglen & 0x3);
}
req->state = MQ_STATE_COMPLETE;
ips_barrier();
mq_qq_append(&mq->completed_q, req);
break;
case MQ_MSG_EAGER:
req->state = MQ_STATE_MATCHED;
req->type |= MQE_TYPE_EAGER_QUEUE;
req->send_msgoff = req->recv_msgoff = 0;
STAILQ_INSERT_TAIL(&mq->eager_q, req, nextq);
_HFI_VDBG("exp MSG_EAGER of length %d bytes pay=%d\n",
msglen, paylen);
#ifdef PSM_CUDA
if (PSMI_USE_GDR_COPY(req, req->req_data.send_msglen)) {
req->req_data.buf = gdr_convert_gpu_to_host_addr(GDR_FD,
(unsigned long)req->user_gpu_buffer,
req->req_data.send_msglen, 1, src->proto);
}
#endif
if (paylen > 0)
psmi_mq_handle_data(mq, req, offset, payload,
paylen);
break;
default:
psmi_handle_error(PSMI_EP_NORETURN, PSM2_INTERNAL_ERR,
"Internal error, unknown packet 0x%x",
opcode);
}
mq->stats.rx_user_bytes += msglen;
mq->stats.rx_user_num++;
*req_o = req; /* yes match */
return MQ_RET_MATCH_OK;
}
/* unexpected message or out of order message. */
#if 0
/*
* Keep a callback here in case we want to fit some other high-level
* protocols over MQ (i.e. shmem). These protocols would bypass the
* normal message handling and go to higher-level message handlers.
*/
if (msgorder && mq->unexpected_callback) {
mq->unexpected_callback(mq, opcode, epaddr, req_data.tag, send_msglen,
payload, paylen);
*req_o = NULL;
return MQ_RET_UNEXP_OK;
}
#endif
if (msgorder > 1) {
/* There is NO request match, and this is the first time
* to try to process this packet, we leave the packet in
* hardware queue for retry in hope there is a request
* match nex time, this is for performance
* consideration.
*/
return MQ_RET_UNEXP_NO_RESOURCES;
}
req = psmi_mq_req_alloc(mq, MQE_TYPE_RECV);
psmi_assert(req != NULL);
req->req_data.peer = src;
req->req_data.tag = *tag;
req->recv_msgoff = 0;
req->req_data.recv_msglen = req->req_data.send_msglen = req->req_data.buf_len = msglen =
send_msglen;
_HFI_VDBG("match=NO (req=%p) opcode=%x src=%s mqtag=%08x.%08x.%08x"
" send_msglen=%d\n", req, opcode,
psmi_epaddr_get_name(src->epid),
tag->tag[0], tag->tag[1], tag->tag[2], send_msglen);
switch (opcode) {
case MQ_MSG_TINY:
if (msglen > 0) {
req->req_data.buf = psmi_mq_sysbuf_alloc(mq, msglen);
psmi_assert(msglen == 0 || req->req_data.buf != NULL);
mq->stats.rx_sysbuf_num++;
mq->stats.rx_sysbuf_bytes += paylen;
mq_copy_tiny((uint32_t *) req->req_data.buf,
(uint32_t *) payload, msglen);
} else
req->req_data.buf = NULL;
req->state = MQ_STATE_COMPLETE;
break;
case MQ_MSG_SHORT:
req->req_data.buf = psmi_mq_sysbuf_alloc(mq, msglen);
psmi_assert(msglen == 0 || req->req_data.buf != NULL);
mq->stats.rx_sysbuf_num++;
mq->stats.rx_sysbuf_bytes += paylen;
if (msglen <= paylen) {
psmi_mq_mtucpy(req->req_data.buf, payload, msglen);
} else {
psmi_assert((msglen & ~0x3) == paylen);
psmi_mq_mtucpy(req->req_data.buf, payload, paylen);
/*
* there are nonDW bytes attached in header,
* copy after the DW payload.
*/
mq_copy_tiny((uint32_t *)(req->req_data.buf+paylen),
(uint32_t *)&offset, msglen & 0x3);
}
req->state = MQ_STATE_COMPLETE;
break;
case MQ_MSG_EAGER:
req->send_msgoff = 0;
req->req_data.buf = psmi_mq_sysbuf_alloc(mq, msglen);
psmi_assert(msglen == 0 || req->req_data.buf != NULL);
mq->stats.rx_sysbuf_num++;
mq->stats.rx_sysbuf_bytes += paylen;
req->state = MQ_STATE_UNEXP;
req->type |= MQE_TYPE_EAGER_QUEUE;
STAILQ_INSERT_TAIL(&mq->eager_q, req, nextq);
_HFI_VDBG("unexp MSG_EAGER of length %d bytes pay=%d\n",
msglen, paylen);
if (paylen > 0)
psmi_mq_handle_data(mq, req, offset, payload, paylen);
break;
default:
psmi_handle_error(PSMI_EP_NORETURN, PSM2_INTERNAL_ERR,
"Internal error, unknown packet 0x%x",
opcode);
}
mq->stats.rx_sys_bytes += msglen;
mq->stats.rx_sys_num++;
if (msgorder) {
mq_add_to_unexpected_hashes(mq, req);
}
/* caller will handle out of order case */
*req_o = req; /* no match, will callback */
return MQ_RET_UNEXP_OK;
}
int psmi_mq_handle_outoforder(psm2_mq_t mq, psm2_mq_req_t ureq)
{
psm2_mq_req_t ereq;
uint32_t msglen;
ereq = mq_req_match(mq, ureq->req_data.peer, &ureq->req_data.tag, 1);
if (ereq == NULL) {
mq_add_to_unexpected_hashes(mq, ureq);
return 0;
}
psmi_assert(MQE_TYPE_IS_RECV(ereq->type));
ereq->req_data.peer = ureq->req_data.peer;
ereq->req_data.tag = ureq->req_data.tag;
msglen = mq_set_msglen(ereq, ereq->req_data.buf_len, ureq->req_data.send_msglen);
switch (ureq->state) {
case MQ_STATE_COMPLETE:
if (ureq->req_data.buf != NULL) { /* 0-byte don't alloc a sysreq_data.buf */
psmi_mq_mtucpy(ereq->req_data.buf, (const void *)ureq->req_data.buf,
msglen);
psmi_mq_sysbuf_free(mq, ureq->req_data.buf);
}
ereq->state = MQ_STATE_COMPLETE;
ips_barrier();
mq_qq_append(&mq->completed_q, ereq);
break;
case MQ_STATE_UNEXP: /* not done yet */
ereq->state = MQ_STATE_MATCHED;
ereq->msg_seqnum = ureq->msg_seqnum;
ereq->ptl_req_ptr = ureq->ptl_req_ptr;
ereq->send_msgoff = ureq->send_msgoff;
ereq->recv_msgoff = min(ureq->recv_msgoff, msglen);
if (ereq->recv_msgoff) {
psmi_mq_mtucpy(ereq->req_data.buf,
(const void *)ureq->req_data.buf,
ereq->recv_msgoff);
}
psmi_mq_sysbuf_free(mq, ureq->req_data.buf);
ereq->type = ureq->type;
STAILQ_INSERT_AFTER(&mq->eager_q, ureq, ereq, nextq);
STAILQ_REMOVE(&mq->eager_q, ureq, psm2_mq_req, nextq);
break;
case MQ_STATE_UNEXP_RV: /* rendez-vous ... */
ereq->state = MQ_STATE_MATCHED;
ereq->rts_peer = ureq->rts_peer;
ereq->rts_sbuf = ureq->rts_sbuf;
ereq->send_msgoff = ureq->send_msgoff;
ereq->recv_msgoff = min(ureq->recv_msgoff, msglen);
if (ereq->recv_msgoff) {
psmi_mq_mtucpy(ereq->req_data.buf,
(const void *)ureq->req_data.buf,
ereq->recv_msgoff);
}
if (ereq->send_msgoff) {
psmi_mq_sysbuf_free(mq, ureq->req_data.buf);
}
ereq->rts_callback = ureq->rts_callback;
ereq->rts_reqidx_peer = ureq->rts_reqidx_peer;
ereq->type = ureq->type;
ereq->rts_callback(ereq, 0);
break;
default:
fprintf(stderr, "Unexpected state %d in req %p\n", ureq->state,
ureq);
fprintf(stderr, "type=%d, mq=%p, tag=%08x.%08x.%08x\n",
ureq->type, ureq->mq, ureq->req_data.tag.tag[0],
ureq->req_data.tag.tag[1], ureq->req_data.tag.tag[2]);
abort();
}
psmi_mq_req_free(ureq);
return 0;
}