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openmpi/opal/mca/btl/openib/btl_openib_endpoint.h
Nathan Hjelm b308afa8fd btl/openib: remove derived btl segment type
The derived segment type (btl_openib_segment_t) was intended to store
the registration info needed for put and get. In BTL 3.0 this is no
longer required. I intended to remove this type as part of
open-mpi/ompi@74f1af4548 .

Signed-off-by: Nathan Hjelm <hjelmn@lanl.gov>
2015-03-10 14:41:15 -06:00

729 строки
25 KiB
C++

/* -*- Mode: C; c-basic-offset:4 ; indent-tabs-mode:nil -*- */
/*
* Copyright (c) 2004-2005 The Trustees of Indiana University and Indiana
* University Research and Technology
* Corporation. All rights reserved.
* Copyright (c) 2004-2013 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) 2007-2009 Cisco Systems, Inc. All rights reserved.
* Copyright (c) 2006-2015 Los Alamos National Security, LLC. All rights
* reserved.
* Copyright (c) 2006-2007 Voltaire All rights reserved.
* Copyright (c) 2007-2009 Mellanox Technologies. All rights reserved.
* Copyright (c) 2010-2012 Oracle and/or its affiliates. All rights reserved.
* Copyright (c) 2014 Bull SAS. All rights reserved.
* Copyright (c) 2015 Research Organization for Information Science
* and Technology (RIST). All rights reserved.
* Copyright (c) 2015 NVIDIA Corporation. All rights reserved.
* $COPYRIGHT$
*
* Additional copyrights may follow
*
* $HEADER$
*/
#ifndef MCA_BTL_IB_ENDPOINT_H
#define MCA_BTL_IB_ENDPOINT_H
#include <errno.h>
#include <string.h>
#include "opal/class/opal_list.h"
#include "opal/mca/event/event.h"
#include "opal/util/output.h"
#include "opal/mca/btl/btl.h"
#include "opal/mca/btl/base/btl_base_error.h"
#include "btl_openib.h"
#include "btl_openib_frag.h"
#include "btl_openib_eager_rdma.h"
#include "connect/base.h"
#define QP_TX_BATCH_COUNT 64
#define QP_TX_BATCH_COUNT 64
BEGIN_C_DECLS
struct mca_btl_openib_frag_t;
struct mca_btl_openib_proc_modex_t;
/**
* State of IB endpoint connection.
*/
typedef enum {
/* Defines the state in which this BTL instance
* has started the process of connection */
MCA_BTL_IB_CONNECTING,
/* Waiting for ack from endpoint */
MCA_BTL_IB_CONNECT_ACK,
/*Waiting for final connection ACK from endpoint */
MCA_BTL_IB_WAITING_ACK,
/* Connected ... both sender & receiver have
* buffers associated with this connection */
MCA_BTL_IB_CONNECTED,
/* Connection is closed, there are no resources
* associated with this */
MCA_BTL_IB_CLOSED,
/* Maximum number of retries have been used.
* Report failure on send to upper layer */
MCA_BTL_IB_FAILED
} mca_btl_openib_endpoint_state_t;
typedef struct mca_btl_openib_rem_qp_info_t {
uint32_t rem_qp_num;
/* Remote QP number */
uint32_t rem_psn;
/* Remote processes port sequence number */
} mca_btl_openib_rem_qp_info_t;
typedef struct mca_btl_openib_rem_srq_info_t {
/* Remote SRQ number */
uint32_t rem_srq_num;
} mca_btl_openib_rem_srq_info_t;
typedef struct mca_btl_openib_rem_info_t {
/* Local identifier of the remote process */
uint16_t rem_lid;
/* subnet id of remote process */
uint64_t rem_subnet_id;
/* MTU of remote process */
uint32_t rem_mtu;
/* index of remote endpoint in endpoint array */
uint32_t rem_index;
/* Remote QPs */
mca_btl_openib_rem_qp_info_t *rem_qps;
/* Remote xrc_srq info, used only with XRC connections */
mca_btl_openib_rem_srq_info_t *rem_srqs;
/* Vendor id of remote HCA */
uint32_t rem_vendor_id;
/* Vendor part id of remote HCA */
uint32_t rem_vendor_part_id;
/* Transport type of remote port */
mca_btl_openib_transport_type_t rem_transport_type;
} mca_btl_openib_rem_info_t;
/**
* Agggregates all per peer qp info for an endpoint
*/
typedef struct mca_btl_openib_endpoint_pp_qp_t {
int32_t sd_credits; /**< this rank's view of the credits
* available for sending:
* this is the credits granted by the
* remote peer which has some relation to the
* number of receive buffers posted remotely
*/
int32_t rd_posted; /**< number of descriptors posted to the nic*/
int32_t rd_credits; /**< number of credits to return to peer */
int32_t cm_received; /**< Credit messages received */
int32_t cm_return; /**< how may credits to return */
int32_t cm_sent; /**< Outstanding number of credit messages */
} mca_btl_openib_endpoint_pp_qp_t;
/**
* Aggregates all srq qp info for an endpoint
*/
typedef struct mca_btl_openib_endpoint_srq_qp_t {
int32_t dummy;
} mca_btl_openib_endpoint_srq_qp_t;
typedef struct mca_btl_openib_qp_t {
struct ibv_qp *lcl_qp;
uint32_t lcl_psn;
int32_t sd_wqe; /**< number of available send wqe entries */
int32_t sd_wqe_inflight;
int wqe_count;
int users;
opal_mutex_t lock;
} mca_btl_openib_qp_t;
typedef struct mca_btl_openib_endpoint_qp_t {
mca_btl_openib_qp_t *qp;
opal_list_t no_credits_pending_frags[2]; /**< put fragment here if there is no credits
available */
opal_list_t no_wqe_pending_frags[2]; /**< put fragments here if there is no wqe
available */
int32_t rd_credit_send_lock; /**< Lock credit send fragment */
mca_btl_openib_send_control_frag_t *credit_frag;
size_t ib_inline_max; /**< max size of inline send*/
union {
mca_btl_openib_endpoint_srq_qp_t srq_qp;
mca_btl_openib_endpoint_pp_qp_t pp_qp;
} u;
} mca_btl_openib_endpoint_qp_t;
/**
* An abstraction that represents a connection to a endpoint process.
* An instance of mca_btl_base_endpoint_t is associated w/ each process
* and BTL pair at startup. However, connections to the endpoint
* are established dynamically on an as-needed basis:
*/
struct mca_btl_base_endpoint_t {
opal_list_item_t super;
/** BTL module that created this connection */
struct mca_btl_openib_module_t* endpoint_btl;
/** proc structure corresponding to endpoint */
struct mca_btl_openib_proc_t* endpoint_proc;
/** local CPC to connect to this endpoint */
opal_btl_openib_connect_base_module_t *endpoint_local_cpc;
/** hook for local CPC to hang endpoint-specific data */
void *endpoint_local_cpc_data;
/** If endpoint_local_cpc->cbm_uses_cts is true and this endpoint
is iWARP, then endpoint_initiator must be true on the side
that actually initiates the QP, false on the other side. This
bool is used to know which way to send the first CTS
message. */
bool endpoint_initiator;
/** pointer to remote proc's CPC data (essentially its CPC modex
message) */
opal_btl_openib_connect_base_module_data_t *endpoint_remote_cpc_data;
/** current state of the connection */
mca_btl_openib_endpoint_state_t endpoint_state;
/** number of connection retries attempted */
size_t endpoint_retries;
/** timestamp of when the first connection was attempted */
double endpoint_tstamp;
/** lock for concurrent access to endpoint state */
opal_mutex_t endpoint_lock;
/** list of pending frags due to lazy connection establishment
for this endpotint */
opal_list_t pending_lazy_frags;
mca_btl_openib_endpoint_qp_t *qps;
#if OPAL_HAVE_CONNECTX_XRC_DOMAINS
struct ibv_qp *xrc_recv_qp;
#else
uint32_t xrc_recv_qp_num; /* in xrc we will use it as recv qp */
#endif
uint32_t xrc_recv_psn;
/** list of pending rget ops */
opal_list_t pending_get_frags;
/** list of pending rput ops */
opal_list_t pending_put_frags;
/** number of available get tokens */
int32_t get_tokens;
/** subnet id of this endpoint*/
uint64_t subnet_id;
/** used only for xrc; pointer to struct that keeps remote port
info */
struct ib_address_t *ib_addr;
/** number of eager received */
int32_t eager_recv_count;
/** info about remote RDMA buffer */
mca_btl_openib_eager_rdma_remote_t eager_rdma_remote;
/** info about local RDMA buffer */
mca_btl_openib_eager_rdma_local_t eager_rdma_local;
/** index of the endpoint in endpoints array */
int32_t index;
/** does the endpoint require network byte ordering? */
bool nbo;
/** use eager rdma for this peer? */
bool use_eager_rdma;
/** information about the remote port */
mca_btl_openib_rem_info_t rem_info;
/** Frag for initial wireup CTS protocol; will be NULL if CPC
indicates that it does not want to use CTS */
mca_btl_openib_recv_frag_t endpoint_cts_frag;
/** Memory registration info for the CTS frag */
struct ibv_mr *endpoint_cts_mr;
/** Whether we've posted receives on this EP or not (only used in
CTS protocol) */
bool endpoint_posted_recvs;
/** Whether we've received the CTS from the peer or not (only used
in CTS protocol) */
bool endpoint_cts_received;
/** Whether we've send out CTS to the peer or not (only used in
CTS protocol) */
bool endpoint_cts_sent;
};
typedef struct mca_btl_base_endpoint_t mca_btl_base_endpoint_t;
typedef mca_btl_base_endpoint_t mca_btl_openib_endpoint_t;
OBJ_CLASS_DECLARATION(mca_btl_openib_endpoint_t);
static inline int32_t qp_get_wqe(mca_btl_openib_endpoint_t *ep, const int qp)
{
return OPAL_THREAD_ADD32(&ep->qps[qp].qp->sd_wqe, -1);
}
static inline int32_t qp_put_wqe(mca_btl_openib_endpoint_t *ep, const int qp)
{
return OPAL_THREAD_ADD32(&ep->qps[qp].qp->sd_wqe, 1);
}
static inline int32_t qp_inc_inflight_wqe(mca_btl_openib_endpoint_t *ep, const int qp, mca_btl_openib_com_frag_t *frag)
{
frag->n_wqes_inflight = 0;
return OPAL_THREAD_ADD32(&ep->qps[qp].qp->sd_wqe_inflight, 1);
}
static inline void qp_inflight_wqe_to_frag(mca_btl_openib_endpoint_t *ep, const int qp, mca_btl_openib_com_frag_t *frag)
{
frag->n_wqes_inflight = ep->qps[qp].qp->sd_wqe_inflight;
ep->qps[qp].qp->sd_wqe_inflight = 0;
}
static inline int qp_frag_to_wqe(mca_btl_openib_endpoint_t *ep, const int qp, mca_btl_openib_com_frag_t *frag)
{
int n;
n = frag->n_wqes_inflight;
OPAL_THREAD_ADD32(&ep->qps[qp].qp->sd_wqe, n);
frag->n_wqes_inflight = 0;
return n;
}
static inline int qp_need_signal(mca_btl_openib_endpoint_t *ep, const int qp, size_t size, int rdma)
{
/* note that size here is payload only */
if (ep->qps[qp].qp->sd_wqe <= 0 ||
size + sizeof(mca_btl_openib_header_t) + (rdma ? sizeof(mca_btl_openib_footer_t) : 0) > ep->qps[qp].ib_inline_max ||
(!BTL_OPENIB_QP_TYPE_PP(qp) && ep->endpoint_btl->qps[qp].u.srq_qp.sd_credits <= 0)) {
ep->qps[qp].qp->wqe_count = QP_TX_BATCH_COUNT;
return 1;
}
if (0 < --ep->qps[qp].qp->wqe_count) {
return 0;
}
ep->qps[qp].qp->wqe_count = QP_TX_BATCH_COUNT;
return 1;
}
static inline void qp_reset_signal_count(mca_btl_openib_endpoint_t *ep, const int qp)
{
ep->qps[qp].qp->wqe_count = QP_TX_BATCH_COUNT;
}
int mca_btl_openib_endpoint_send(mca_btl_base_endpoint_t*,
mca_btl_openib_send_frag_t*);
int mca_btl_openib_endpoint_post_send(mca_btl_openib_endpoint_t*,
mca_btl_openib_send_frag_t*);
void mca_btl_openib_endpoint_send_credits(mca_btl_base_endpoint_t*, const int);
void mca_btl_openib_endpoint_connect_eager_rdma(mca_btl_openib_endpoint_t*);
int mca_btl_openib_endpoint_post_recvs(mca_btl_openib_endpoint_t*);
void mca_btl_openib_endpoint_send_cts(mca_btl_openib_endpoint_t *endpoint);
void mca_btl_openib_endpoint_cpc_complete(mca_btl_openib_endpoint_t*);
void mca_btl_openib_endpoint_connected(mca_btl_openib_endpoint_t*);
void mca_btl_openib_endpoint_init(mca_btl_openib_module_t*,
mca_btl_base_endpoint_t*,
opal_btl_openib_connect_base_module_t *local_cpc,
struct mca_btl_openib_proc_modex_t *remote_proc_info,
opal_btl_openib_connect_base_module_data_t *remote_cpc_data);
/*
* Invoke an error on the btl associated with an endpoint. If we
* don't have an endpoint, then just use the first one on the
* component list of BTLs.
*/
void *mca_btl_openib_endpoint_invoke_error(void *endpoint);
static inline int post_recvs(mca_btl_base_endpoint_t *ep, const int qp,
const int num_post)
{
int i, rc;
struct ibv_recv_wr *bad_wr, *wr_list = NULL, *wr = NULL;
mca_btl_openib_module_t *openib_btl = ep->endpoint_btl;
if(0 == num_post)
return OPAL_SUCCESS;
for(i = 0; i < num_post; i++) {
opal_free_list_item_t* item;
item = opal_free_list_wait (&openib_btl->device->qps[qp].recv_free);
to_base_frag(item)->base.order = qp;
to_com_frag(item)->endpoint = ep;
if(NULL == wr)
wr = wr_list = &to_recv_frag(item)->rd_desc;
else
wr = wr->next = &to_recv_frag(item)->rd_desc;
OPAL_OUTPUT((-1, "Posting recv (QP num %d): WR ID %p, SG addr %p, len %d, lkey %d",
ep->qps[qp].qp->lcl_qp->qp_num,
(void*) ((uintptr_t*)wr->wr_id),
(void*)((uintptr_t*) wr->sg_list[0].addr),
wr->sg_list[0].length,
wr->sg_list[0].lkey));
}
wr->next = NULL;
rc = ibv_post_recv(ep->qps[qp].qp->lcl_qp, wr_list, &bad_wr);
if (0 == rc)
return OPAL_SUCCESS;
BTL_ERROR(("error %d posting receive on qp %d", rc, qp));
return OPAL_ERROR;
}
static inline int mca_btl_openib_endpoint_post_rr_nolock(
mca_btl_base_endpoint_t *ep, const int qp)
{
int rd_rsv = mca_btl_openib_component.qp_infos[qp].u.pp_qp.rd_rsv;
int rd_num = mca_btl_openib_component.qp_infos[qp].rd_num;
int rd_low = mca_btl_openib_component.qp_infos[qp].rd_low;
int cqp = mca_btl_openib_component.credits_qp, rc;
int cm_received = 0, num_post = 0;
assert(BTL_OPENIB_QP_TYPE_PP(qp));
if(ep->qps[qp].u.pp_qp.rd_posted <= rd_low)
num_post = rd_num - ep->qps[qp].u.pp_qp.rd_posted;
assert(num_post >= 0);
if(ep->qps[qp].u.pp_qp.cm_received >= (rd_rsv >> 2))
cm_received = ep->qps[qp].u.pp_qp.cm_received;
if((rc = post_recvs(ep, qp, num_post)) != OPAL_SUCCESS) {
return rc;
}
OPAL_THREAD_ADD32(&ep->qps[qp].u.pp_qp.rd_posted, num_post);
OPAL_THREAD_ADD32(&ep->qps[qp].u.pp_qp.rd_credits, num_post);
/* post buffers for credit management on credit management qp */
if((rc = post_recvs(ep, cqp, cm_received)) != OPAL_SUCCESS) {
return rc;
}
OPAL_THREAD_ADD32(&ep->qps[qp].u.pp_qp.cm_return, cm_received);
OPAL_THREAD_ADD32(&ep->qps[qp].u.pp_qp.cm_received, -cm_received);
assert(ep->qps[qp].u.pp_qp.rd_credits <= rd_num &&
ep->qps[qp].u.pp_qp.rd_credits >= 0);
return OPAL_SUCCESS;
}
static inline int mca_btl_openib_endpoint_post_rr(
mca_btl_base_endpoint_t *ep, const int qp)
{
int ret;
OPAL_THREAD_LOCK(&ep->endpoint_lock);
ret = mca_btl_openib_endpoint_post_rr_nolock(ep, qp);
OPAL_THREAD_UNLOCK(&ep->endpoint_lock);
return ret;
}
#define BTL_OPENIB_CREDITS_SEND_TRYLOCK(E, Q) \
OPAL_ATOMIC_CMPSET_32(&(E)->qps[(Q)].rd_credit_send_lock, 0, 1)
#define BTL_OPENIB_CREDITS_SEND_UNLOCK(E, Q) \
OPAL_ATOMIC_CMPSET_32(&(E)->qps[(Q)].rd_credit_send_lock, 1, 0)
#define BTL_OPENIB_GET_CREDITS(FROM, TO) \
do { \
TO = FROM; \
} while(0 == OPAL_ATOMIC_CMPSET_32(&FROM, TO, 0))
static inline bool check_eager_rdma_credits(const mca_btl_openib_endpoint_t *ep)
{
return (ep->eager_rdma_local.credits > ep->eager_rdma_local.rd_win) ? true :
false;
}
static inline bool
check_send_credits(const mca_btl_openib_endpoint_t *ep, const int qp)
{
if(!BTL_OPENIB_QP_TYPE_PP(qp))
return false;
return (ep->qps[qp].u.pp_qp.rd_credits >=
mca_btl_openib_component.qp_infos[qp].u.pp_qp.rd_win) ? true : false;
}
static inline void send_credits(mca_btl_openib_endpoint_t *ep, int qp)
{
if(BTL_OPENIB_QP_TYPE_PP(qp)) {
if(check_send_credits(ep, qp))
goto try_send;
} else {
qp = mca_btl_openib_component.credits_qp;
}
if(!check_eager_rdma_credits(ep))
return;
try_send:
if(BTL_OPENIB_CREDITS_SEND_TRYLOCK(ep, qp))
mca_btl_openib_endpoint_send_credits(ep, qp);
}
static inline int check_endpoint_state(mca_btl_openib_endpoint_t *ep,
mca_btl_base_descriptor_t *des, opal_list_t *pending_list)
{
int rc = OPAL_ERR_RESOURCE_BUSY;
switch(ep->endpoint_state) {
case MCA_BTL_IB_CLOSED:
rc = ep->endpoint_local_cpc->cbm_start_connect(ep->endpoint_local_cpc, ep);
if (OPAL_SUCCESS == rc) {
rc = OPAL_ERR_RESOURCE_BUSY;
}
/*
* As long as we expect a message from the peer (in order
* to setup the connection) let the event engine pool the
* OOB events. Note: we increment it once peer active
* connection.
*/
opal_progress_event_users_increment();
/* fall through */
default:
opal_list_append(pending_list, (opal_list_item_t *)des);
break;
case MCA_BTL_IB_FAILED:
rc = OPAL_ERR_UNREACH;
break;
case MCA_BTL_IB_CONNECTED:
rc = OPAL_SUCCESS;
break;
}
return rc;
}
static inline __opal_attribute_always_inline__ int
ib_send_flags(uint32_t size, mca_btl_openib_endpoint_qp_t *qp, int do_signal)
{
if (do_signal) {
return IBV_SEND_SIGNALED |
((size <= qp->ib_inline_max) ? IBV_SEND_INLINE : 0);
} else {
return ((size <= qp->ib_inline_max) ? IBV_SEND_INLINE : 0);
}
}
static inline int
acquire_eager_rdma_send_credit(mca_btl_openib_endpoint_t *endpoint)
{
if(OPAL_THREAD_ADD32(&endpoint->eager_rdma_remote.tokens, -1) < 0) {
OPAL_THREAD_ADD32(&endpoint->eager_rdma_remote.tokens, 1);
return OPAL_ERR_OUT_OF_RESOURCE;
}
return OPAL_SUCCESS;
}
static inline int post_send(mca_btl_openib_endpoint_t *ep,
mca_btl_openib_send_frag_t *frag, const bool rdma, int do_signal)
{
mca_btl_openib_module_t *openib_btl = ep->endpoint_btl;
mca_btl_base_segment_t *seg = &to_base_frag(frag)->segment;
struct ibv_sge *sg = &to_com_frag(frag)->sg_entry;
struct ibv_send_wr *sr_desc = &to_out_frag(frag)->sr_desc;
struct ibv_send_wr *bad_wr;
int qp = to_base_frag(frag)->base.order;
sg->length = seg->seg_len + sizeof(mca_btl_openib_header_t) +
(rdma ? sizeof(mca_btl_openib_footer_t) : 0) + frag->coalesced_length;
sr_desc->send_flags = ib_send_flags(sg->length, &(ep->qps[qp]), do_signal);
if(ep->nbo)
BTL_OPENIB_HEADER_HTON(*frag->hdr);
if(rdma) {
int32_t head;
mca_btl_openib_footer_t* ftr =
(mca_btl_openib_footer_t*)(((char*)frag->hdr) + sg->length +
BTL_OPENIB_FTR_PADDING(sg->length) - sizeof(mca_btl_openib_footer_t));
sr_desc->opcode = IBV_WR_RDMA_WRITE;
MCA_BTL_OPENIB_RDMA_FRAG_SET_SIZE(ftr, sg->length);
MCA_BTL_OPENIB_RDMA_MAKE_LOCAL(ftr);
#if OPAL_ENABLE_DEBUG
do {
ftr->seq = ep->eager_rdma_remote.seq;
} while (!OPAL_ATOMIC_CMPSET_32((int32_t*) &ep->eager_rdma_remote.seq,
(int32_t) ftr->seq,
(int32_t) (ftr->seq+1)));
#endif
if(ep->nbo)
BTL_OPENIB_FOOTER_HTON(*ftr);
sr_desc->wr.rdma.rkey = ep->eager_rdma_remote.rkey;
MCA_BTL_OPENIB_RDMA_MOVE_INDEX(ep->eager_rdma_remote.head, head);
#if BTL_OPENIB_FAILOVER_ENABLED
/* frag->ftr is unused on the sending fragment, so use it
* to indicate it is an eager fragment. A non-zero value
* indicates it is eager, and the value indicates the
* location in the eager RDMA array that it lives. */
frag->ftr = (mca_btl_openib_footer_t*)(long)(1 + head);
#endif
sr_desc->wr.rdma.remote_addr =
ep->eager_rdma_remote.base.lval +
head * openib_btl->eager_rdma_frag_size +
sizeof(mca_btl_openib_header_t) +
mca_btl_openib_component.eager_limit +
sizeof(mca_btl_openib_footer_t);
sr_desc->wr.rdma.remote_addr -= sg->length + BTL_OPENIB_FTR_PADDING(sg->length);
} else {
if(BTL_OPENIB_QP_TYPE_PP(qp)) {
sr_desc->opcode = IBV_WR_SEND;
} else {
sr_desc->opcode = IBV_WR_SEND_WITH_IMM;
#if !defined(WORDS_BIGENDIAN) && OPAL_ENABLE_HETEROGENEOUS_SUPPORT
sr_desc->imm_data = htonl(ep->rem_info.rem_index);
#else
sr_desc->imm_data = ep->rem_info.rem_index;
#endif
}
}
#if HAVE_XRC
#if OPAL_HAVE_CONNECTX_XRC_DOMAINS
if(BTL_OPENIB_QP_TYPE_XRC(qp))
sr_desc->qp_type.xrc.remote_srqn = ep->rem_info.rem_srqs[qp].rem_srq_num;
#else
if(BTL_OPENIB_QP_TYPE_XRC(qp))
sr_desc->xrc_remote_srq_num = ep->rem_info.rem_srqs[qp].rem_srq_num;
#endif
#endif
assert(sg->addr == (uint64_t)(uintptr_t)frag->hdr);
if (sr_desc->send_flags & IBV_SEND_SIGNALED) {
qp_inflight_wqe_to_frag(ep, qp, to_com_frag(frag));
} else {
qp_inc_inflight_wqe(ep, qp, to_com_frag(frag));
}
return ibv_post_send(ep->qps[qp].qp->lcl_qp, sr_desc, &bad_wr);
}
/* called with the endpoint lock held */
static inline int mca_btl_openib_endpoint_credit_acquire (struct mca_btl_base_endpoint_t *endpoint, int qp,
int prio, size_t size, bool *do_rdma,
mca_btl_openib_send_frag_t *frag, bool queue_frag)
{
mca_btl_openib_module_t *openib_btl = endpoint->endpoint_btl;
mca_btl_openib_header_t *hdr = frag->hdr;
size_t eager_limit;
int32_t cm_return;
eager_limit = mca_btl_openib_component.eager_limit +
sizeof(mca_btl_openib_header_coalesced_t) +
sizeof(mca_btl_openib_control_header_t);
if (!(prio && size < eager_limit && acquire_eager_rdma_send_credit(endpoint) == OPAL_SUCCESS)) {
*do_rdma = false;
prio = !prio;
if (BTL_OPENIB_QP_TYPE_PP(qp)) {
if (OPAL_THREAD_ADD32(&endpoint->qps[qp].u.pp_qp.sd_credits, -1) < 0) {
OPAL_THREAD_ADD32(&endpoint->qps[qp].u.pp_qp.sd_credits, 1);
if (queue_frag) {
opal_list_append(&endpoint->qps[qp].no_credits_pending_frags[prio],
(opal_list_item_t *)frag);
}
return OPAL_ERR_OUT_OF_RESOURCE;
}
} else {
if(OPAL_THREAD_ADD32(&openib_btl->qps[qp].u.srq_qp.sd_credits, -1) < 0) {
OPAL_THREAD_ADD32(&openib_btl->qps[qp].u.srq_qp.sd_credits, 1);
if (queue_frag) {
OPAL_THREAD_LOCK(&openib_btl->ib_lock);
opal_list_append(&openib_btl->qps[qp].u.srq_qp.pending_frags[prio],
(opal_list_item_t *)frag);
OPAL_THREAD_UNLOCK(&openib_btl->ib_lock);
}
return OPAL_ERR_OUT_OF_RESOURCE;
}
}
} else {
/* High priority frag. Try to send over eager RDMA */
*do_rdma = true;
}
/* Set all credits */
BTL_OPENIB_GET_CREDITS(endpoint->eager_rdma_local.credits, hdr->credits);
if (hdr->credits) {
hdr->credits |= BTL_OPENIB_RDMA_CREDITS_FLAG;
}
if (!*do_rdma) {
if (BTL_OPENIB_QP_TYPE_PP(qp) && 0 == hdr->credits) {
BTL_OPENIB_GET_CREDITS(endpoint->qps[qp].u.pp_qp.rd_credits, hdr->credits);
}
} else {
hdr->credits |= (qp << 11);
}
BTL_OPENIB_GET_CREDITS(endpoint->qps[qp].u.pp_qp.cm_return, cm_return);
/* cm_seen is only 8 bytes, but cm_return is 32 bytes */
if(cm_return > 255) {
hdr->cm_seen = 255;
cm_return -= 255;
OPAL_THREAD_ADD32(&endpoint->qps[qp].u.pp_qp.cm_return, cm_return);
} else {
hdr->cm_seen = cm_return;
}
return OPAL_SUCCESS;
}
/* called with the endpoint lock held. */
static inline void mca_btl_openib_endpoint_credit_release (struct mca_btl_base_endpoint_t *endpoint, int qp,
bool do_rdma, mca_btl_openib_send_frag_t *frag)
{
mca_btl_openib_header_t *hdr = frag->hdr;
if (BTL_OPENIB_IS_RDMA_CREDITS(hdr->credits)) {
OPAL_THREAD_ADD32(&endpoint->eager_rdma_local.credits, BTL_OPENIB_CREDITS(hdr->credits));
}
if (do_rdma) {
OPAL_THREAD_ADD32(&endpoint->eager_rdma_remote.tokens, 1);
} else {
if(BTL_OPENIB_QP_TYPE_PP(qp)) {
OPAL_THREAD_ADD32 (&endpoint->qps[qp].u.pp_qp.rd_credits, hdr->credits);
OPAL_THREAD_ADD32(&endpoint->qps[qp].u.pp_qp.sd_credits, 1);
} else if BTL_OPENIB_QP_TYPE_SRQ(qp){
mca_btl_openib_module_t *openib_btl = endpoint->endpoint_btl;
OPAL_THREAD_ADD32(&openib_btl->qps[qp].u.srq_qp.sd_credits, 1);
}
}
}
END_C_DECLS
#endif