d/numam-spdk
1
0
Fork 0
Code Issues Pull Requests Projects Releases Wiki Activity
d1024c4bc6
numam-spdk/lib/nvmf/rdma.c
Alexey Marchuk 9cea323284 nvmf/rdma: Move definitions of rxe vendor IDs to common rdma.h 
These definitions will be used in the next patch to check if
device is rxe

Signed-off-by: Alexey Marchuk <alexeymar@mellanox.com>
Change-Id: Icc073344103991ff24fc3bb88a1ceb9867de6f6a
Reviewed-on: https://review.spdk.io/gerrit/c/spdk/spdk/+/10727
Community-CI: Broadcom CI <spdk-ci.pdl@broadcom.com>
Community-CI: Mellanox Build Bot
Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
Reviewed-by: Jim Harris <james.r.harris@intel.com>
Reviewed-by: Tomasz Zawadzki <tomasz.zawadzki@intel.com>
2021-12-23 08:44:40 +00:00

4259 lines
133 KiB
C
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/*-
* BSD LICENSE
*
* Copyright (c) Intel Corporation. All rights reserved.
* Copyright (c) 2019-2021 Mellanox Technologies LTD. All rights reserved.
* Copyright (c) 2021 NVIDIA CORPORATION & AFFILIATES. All rights reserved.
*
* 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.
*/
#include "spdk/stdinc.h"
#include "spdk/config.h"
#include "spdk/thread.h"
#include "spdk/likely.h"
#include "spdk/nvmf_transport.h"
#include "spdk/string.h"
#include "spdk/trace.h"
#include "spdk/util.h"
#include "spdk_internal/assert.h"
#include "spdk/log.h"
#include "spdk_internal/rdma.h"
#include "nvmf_internal.h"
#include "spdk_internal/trace_defs.h"
struct spdk_nvme_rdma_hooks g_nvmf_hooks = {};
const struct spdk_nvmf_transport_ops spdk_nvmf_transport_rdma;
/*
RDMA Connection Resource Defaults
*/
#define NVMF_DEFAULT_TX_SGE SPDK_NVMF_MAX_SGL_ENTRIES
#define NVMF_DEFAULT_RSP_SGE 1
#define NVMF_DEFAULT_RX_SGE 2
/* The RDMA completion queue size */
#define DEFAULT_NVMF_RDMA_CQ_SIZE 4096
#define MAX_WR_PER_QP(queue_depth) (queue_depth * 3 + 2)
static int g_spdk_nvmf_ibv_query_mask =
IBV_QP_STATE |
IBV_QP_PKEY_INDEX |
IBV_QP_PORT |
IBV_QP_ACCESS_FLAGS |
IBV_QP_AV |
IBV_QP_PATH_MTU |
IBV_QP_DEST_QPN |
IBV_QP_RQ_PSN |
IBV_QP_MAX_DEST_RD_ATOMIC |
IBV_QP_MIN_RNR_TIMER |
IBV_QP_SQ_PSN |
IBV_QP_TIMEOUT |
IBV_QP_RETRY_CNT |
IBV_QP_RNR_RETRY |
IBV_QP_MAX_QP_RD_ATOMIC;
enum spdk_nvmf_rdma_request_state {
/* The request is not currently in use */
RDMA_REQUEST_STATE_FREE = 0,
/* Initial state when request first received */
RDMA_REQUEST_STATE_NEW,
/* The request is queued until a data buffer is available. */
RDMA_REQUEST_STATE_NEED_BUFFER,
/* The request is waiting on RDMA queue depth availability
* to transfer data from the host to the controller.
*/
RDMA_REQUEST_STATE_DATA_TRANSFER_TO_CONTROLLER_PENDING,
/* The request is currently transferring data from the host to the controller. */
RDMA_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER,
/* The request is ready to execute at the block device */
RDMA_REQUEST_STATE_READY_TO_EXECUTE,
/* The request is currently executing at the block device */
RDMA_REQUEST_STATE_EXECUTING,
/* The request finished executing at the block device */
RDMA_REQUEST_STATE_EXECUTED,
/* The request is waiting on RDMA queue depth availability
* to transfer data from the controller to the host.
*/
RDMA_REQUEST_STATE_DATA_TRANSFER_TO_HOST_PENDING,
/* The request is ready to send a completion */
RDMA_REQUEST_STATE_READY_TO_COMPLETE,
/* The request is currently transferring data from the controller to the host. */
RDMA_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST,
/* The request currently has an outstanding completion without an
* associated data transfer.
*/
RDMA_REQUEST_STATE_COMPLETING,
/* The request completed and can be marked free. */
RDMA_REQUEST_STATE_COMPLETED,
/* Terminator */
RDMA_REQUEST_NUM_STATES,
};
SPDK_TRACE_REGISTER_FN(nvmf_trace, "nvmf_rdma", TRACE_GROUP_NVMF_RDMA)
{
spdk_trace_register_object(OBJECT_NVMF_RDMA_IO, 'r');
spdk_trace_register_description("RDMA_REQ_NEW", TRACE_RDMA_REQUEST_STATE_NEW,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 1,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_REQ_NEED_BUFFER", TRACE_RDMA_REQUEST_STATE_NEED_BUFFER,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 0,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_REQ_TX_PENDING_C2H",
TRACE_RDMA_REQUEST_STATE_DATA_TRANSFER_TO_HOST_PENDING,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 0,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_REQ_TX_PENDING_H2C",
TRACE_RDMA_REQUEST_STATE_DATA_TRANSFER_TO_CONTROLLER_PENDING,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 0,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_REQ_TX_H2C",
TRACE_RDMA_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 0,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_REQ_RDY_TO_EXECUTE",
TRACE_RDMA_REQUEST_STATE_READY_TO_EXECUTE,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 0,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_REQ_EXECUTING",
TRACE_RDMA_REQUEST_STATE_EXECUTING,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 0,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_REQ_EXECUTED",
TRACE_RDMA_REQUEST_STATE_EXECUTED,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 0,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_REQ_RDY_TO_COMPL",
TRACE_RDMA_REQUEST_STATE_READY_TO_COMPLETE,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 0,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_REQ_COMPLETING_C2H",
TRACE_RDMA_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 0,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_REQ_COMPLETING",
TRACE_RDMA_REQUEST_STATE_COMPLETING,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 0,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_REQ_COMPLETED",
TRACE_RDMA_REQUEST_STATE_COMPLETED,
OWNER_NONE, OBJECT_NVMF_RDMA_IO, 0,
SPDK_TRACE_ARG_TYPE_PTR, "qpair");
spdk_trace_register_description("RDMA_QP_CREATE", TRACE_RDMA_QP_CREATE,
OWNER_NONE, OBJECT_NONE, 0,
SPDK_TRACE_ARG_TYPE_INT, "");
spdk_trace_register_description("RDMA_IBV_ASYNC_EVENT", TRACE_RDMA_IBV_ASYNC_EVENT,
OWNER_NONE, OBJECT_NONE, 0,
SPDK_TRACE_ARG_TYPE_INT, "type");
spdk_trace_register_description("RDMA_CM_ASYNC_EVENT", TRACE_RDMA_CM_ASYNC_EVENT,
OWNER_NONE, OBJECT_NONE, 0,
SPDK_TRACE_ARG_TYPE_INT, "type");
spdk_trace_register_description("RDMA_QP_STATE_CHANGE", TRACE_RDMA_QP_STATE_CHANGE,
OWNER_NONE, OBJECT_NONE, 0,
SPDK_TRACE_ARG_TYPE_PTR, "state");
spdk_trace_register_description("RDMA_QP_DISCONNECT", TRACE_RDMA_QP_DISCONNECT,
OWNER_NONE, OBJECT_NONE, 0,
SPDK_TRACE_ARG_TYPE_INT, "");
spdk_trace_register_description("RDMA_QP_DESTROY", TRACE_RDMA_QP_DESTROY,
OWNER_NONE, OBJECT_NONE, 0,
SPDK_TRACE_ARG_TYPE_INT, "");
}
enum spdk_nvmf_rdma_wr_type {
RDMA_WR_TYPE_RECV,
RDMA_WR_TYPE_SEND,
RDMA_WR_TYPE_DATA,
};
struct spdk_nvmf_rdma_wr {
enum spdk_nvmf_rdma_wr_type type;
};
/* This structure holds commands as they are received off the wire.
* It must be dynamically paired with a full request object
* (spdk_nvmf_rdma_request) to service a request. It is separate
* from the request because RDMA does not appear to order
* completions, so occasionally we'll get a new incoming
* command when there aren't any free request objects.
*/
struct spdk_nvmf_rdma_recv {
struct ibv_recv_wr wr;
struct ibv_sge sgl[NVMF_DEFAULT_RX_SGE];
struct spdk_nvmf_rdma_qpair *qpair;
/* In-capsule data buffer */
uint8_t *buf;
struct spdk_nvmf_rdma_wr rdma_wr;
uint64_t receive_tsc;
STAILQ_ENTRY(spdk_nvmf_rdma_recv) link;
};
struct spdk_nvmf_rdma_request_data {
struct spdk_nvmf_rdma_wr rdma_wr;
struct ibv_send_wr wr;
struct ibv_sge sgl[SPDK_NVMF_MAX_SGL_ENTRIES];
};
struct spdk_nvmf_rdma_request {
struct spdk_nvmf_request req;
enum spdk_nvmf_rdma_request_state state;
/* Data offset in req.iov */
uint32_t offset;
struct spdk_nvmf_rdma_recv *recv;
struct {
struct spdk_nvmf_rdma_wr rdma_wr;
struct ibv_send_wr wr;
struct ibv_sge sgl[NVMF_DEFAULT_RSP_SGE];
} rsp;
struct spdk_nvmf_rdma_request_data data;
uint32_t iovpos;
uint32_t num_outstanding_data_wr;
uint64_t receive_tsc;
STAILQ_ENTRY(spdk_nvmf_rdma_request) state_link;
};
struct spdk_nvmf_rdma_resource_opts {
struct spdk_nvmf_rdma_qpair *qpair;
/* qp points either to an ibv_qp object or an ibv_srq object depending on the value of shared. */
void *qp;
struct ibv_pd *pd;
uint32_t max_queue_depth;
uint32_t in_capsule_data_size;
bool shared;
};
struct spdk_nvmf_rdma_resources {
/* Array of size "max_queue_depth" containing RDMA requests. */
struct spdk_nvmf_rdma_request *reqs;
/* Array of size "max_queue_depth" containing RDMA recvs. */
struct spdk_nvmf_rdma_recv *recvs;
/* Array of size "max_queue_depth" containing 64 byte capsules
* used for receive.
*/
union nvmf_h2c_msg *cmds;
struct ibv_mr *cmds_mr;
/* Array of size "max_queue_depth" containing 16 byte completions
* to be sent back to the user.
*/
union nvmf_c2h_msg *cpls;
struct ibv_mr *cpls_mr;
/* Array of size "max_queue_depth * InCapsuleDataSize" containing
* buffers to be used for in capsule data.
*/
void *bufs;
struct ibv_mr *bufs_mr;
/* Receives that are waiting for a request object */
STAILQ_HEAD(, spdk_nvmf_rdma_recv) incoming_queue;
/* Queue to track free requests */
STAILQ_HEAD(, spdk_nvmf_rdma_request) free_queue;
};
typedef void (*spdk_nvmf_rdma_qpair_ibv_event)(struct spdk_nvmf_rdma_qpair *rqpair);
struct spdk_nvmf_rdma_ibv_event_ctx {
struct spdk_nvmf_rdma_qpair *rqpair;
spdk_nvmf_rdma_qpair_ibv_event cb_fn;
/* Link to other ibv events associated with this qpair */
STAILQ_ENTRY(spdk_nvmf_rdma_ibv_event_ctx) link;
};
struct spdk_nvmf_rdma_qpair {
struct spdk_nvmf_qpair qpair;
struct spdk_nvmf_rdma_device *device;
struct spdk_nvmf_rdma_poller *poller;
struct spdk_rdma_qp *rdma_qp;
struct rdma_cm_id *cm_id;
struct spdk_rdma_srq *srq;
struct rdma_cm_id *listen_id;
/* The maximum number of I/O outstanding on this connection at one time */
uint16_t max_queue_depth;
/* The maximum number of active RDMA READ and ATOMIC operations at one time */
uint16_t max_read_depth;
/* The maximum number of RDMA SEND operations at one time */
uint32_t max_send_depth;
/* The current number of outstanding WRs from this qpair's
* recv queue. Should not exceed device->attr.max_queue_depth.
*/
uint16_t current_recv_depth;
/* The current number of active RDMA READ operations */
uint16_t current_read_depth;
/* The current number of posted WRs from this qpair's
* send queue. Should not exceed max_send_depth.
*/
uint32_t current_send_depth;
/* The maximum number of SGEs per WR on the send queue */
uint32_t max_send_sge;
/* The maximum number of SGEs per WR on the recv queue */
uint32_t max_recv_sge;
struct spdk_nvmf_rdma_resources *resources;
STAILQ_HEAD(, spdk_nvmf_rdma_request) pending_rdma_read_queue;
STAILQ_HEAD(, spdk_nvmf_rdma_request) pending_rdma_write_queue;
/* Number of requests not in the free state */
uint32_t qd;
TAILQ_ENTRY(spdk_nvmf_rdma_qpair) link;
STAILQ_ENTRY(spdk_nvmf_rdma_qpair) recv_link;
STAILQ_ENTRY(spdk_nvmf_rdma_qpair) send_link;
/* IBV queue pair attributes: they are used to manage
* qp state and recover from errors.
*/
enum ibv_qp_state ibv_state;
/*
* io_channel which is used to destroy qpair when it is removed from poll group
*/
struct spdk_io_channel *destruct_channel;
/* List of ibv async events */
STAILQ_HEAD(, spdk_nvmf_rdma_ibv_event_ctx) ibv_events;
/* Lets us know that we have received the last_wqe event. */
bool last_wqe_reached;
/* Indicate that nvmf_rdma_close_qpair is called */
bool to_close;
};
struct spdk_nvmf_rdma_poller_stat {
uint64_t completions;
uint64_t polls;
uint64_t idle_polls;
uint64_t requests;
uint64_t request_latency;
uint64_t pending_free_request;
uint64_t pending_rdma_read;
uint64_t pending_rdma_write;
struct spdk_rdma_qp_stats qp_stats;
};
struct spdk_nvmf_rdma_poller {
struct spdk_nvmf_rdma_device *device;
struct spdk_nvmf_rdma_poll_group *group;
int num_cqe;
int required_num_wr;
struct ibv_cq *cq;
/* The maximum number of I/O outstanding on the shared receive queue at one time */
uint16_t max_srq_depth;
/* Shared receive queue */
struct spdk_rdma_srq *srq;
struct spdk_nvmf_rdma_resources *resources;
struct spdk_nvmf_rdma_poller_stat stat;
TAILQ_HEAD(, spdk_nvmf_rdma_qpair) qpairs;
STAILQ_HEAD(, spdk_nvmf_rdma_qpair) qpairs_pending_recv;
STAILQ_HEAD(, spdk_nvmf_rdma_qpair) qpairs_pending_send;
TAILQ_ENTRY(spdk_nvmf_rdma_poller) link;
};
struct spdk_nvmf_rdma_poll_group_stat {
uint64_t pending_data_buffer;
};
struct spdk_nvmf_rdma_poll_group {
struct spdk_nvmf_transport_poll_group group;
struct spdk_nvmf_rdma_poll_group_stat stat;
TAILQ_HEAD(, spdk_nvmf_rdma_poller) pollers;
TAILQ_ENTRY(spdk_nvmf_rdma_poll_group) link;
};
struct spdk_nvmf_rdma_conn_sched {
struct spdk_nvmf_rdma_poll_group *next_admin_pg;
struct spdk_nvmf_rdma_poll_group *next_io_pg;
};
/* Assuming rdma_cm uses just one protection domain per ibv_context. */
struct spdk_nvmf_rdma_device {
struct ibv_device_attr attr;
struct ibv_context *context;
struct spdk_rdma_mem_map *map;
struct ibv_pd *pd;
int num_srq;
TAILQ_ENTRY(spdk_nvmf_rdma_device) link;
};
struct spdk_nvmf_rdma_port {
const struct spdk_nvme_transport_id *trid;
struct rdma_cm_id *id;
struct spdk_nvmf_rdma_device *device;
TAILQ_ENTRY(spdk_nvmf_rdma_port) link;
};
struct rdma_transport_opts {
int num_cqe;
uint32_t max_srq_depth;
bool no_srq;
bool no_wr_batching;
int acceptor_backlog;
};
struct spdk_nvmf_rdma_transport {
struct spdk_nvmf_transport transport;
struct rdma_transport_opts rdma_opts;
struct spdk_nvmf_rdma_conn_sched conn_sched;
struct rdma_event_channel *event_channel;
struct spdk_mempool *data_wr_pool;
struct spdk_poller *accept_poller;
pthread_mutex_t lock;
/* fields used to poll RDMA/IB events */
nfds_t npoll_fds;
struct pollfd *poll_fds;
TAILQ_HEAD(, spdk_nvmf_rdma_device) devices;
TAILQ_HEAD(, spdk_nvmf_rdma_port) ports;
TAILQ_HEAD(, spdk_nvmf_rdma_poll_group) poll_groups;
};
static const struct spdk_json_object_decoder rdma_transport_opts_decoder[] = {
{
"num_cqe", offsetof(struct rdma_transport_opts, num_cqe),
spdk_json_decode_int32, true
},
{
"max_srq_depth", offsetof(struct rdma_transport_opts, max_srq_depth),
spdk_json_decode_uint32, true
},
{
"no_srq", offsetof(struct rdma_transport_opts, no_srq),
spdk_json_decode_bool, true
},
{
"no_wr_batching", offsetof(struct rdma_transport_opts, no_wr_batching),
spdk_json_decode_bool, true
},
{
"acceptor_backlog", offsetof(struct rdma_transport_opts, acceptor_backlog),
spdk_json_decode_int32, true
},
};
static bool
nvmf_rdma_request_process(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_request *rdma_req);
static void
_poller_submit_sends(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_poller *rpoller);
static void
_poller_submit_recvs(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_poller *rpoller);
static inline int
nvmf_rdma_check_ibv_state(enum ibv_qp_state state)
{
switch (state) {
case IBV_QPS_RESET:
case IBV_QPS_INIT:
case IBV_QPS_RTR:
case IBV_QPS_RTS:
case IBV_QPS_SQD:
case IBV_QPS_SQE:
case IBV_QPS_ERR:
return 0;
default:
return -1;
}
}
static inline enum spdk_nvme_media_error_status_code
nvmf_rdma_dif_error_to_compl_status(uint8_t err_type) {
enum spdk_nvme_media_error_status_code result;
switch (err_type)
{
case SPDK_DIF_REFTAG_ERROR:
result = SPDK_NVME_SC_REFERENCE_TAG_CHECK_ERROR;
break;
case SPDK_DIF_APPTAG_ERROR:
result = SPDK_NVME_SC_APPLICATION_TAG_CHECK_ERROR;
break;
case SPDK_DIF_GUARD_ERROR:
result = SPDK_NVME_SC_GUARD_CHECK_ERROR;
break;
default:
SPDK_UNREACHABLE();
}
return result;
}
static enum ibv_qp_state
nvmf_rdma_update_ibv_state(struct spdk_nvmf_rdma_qpair *rqpair) {
enum ibv_qp_state old_state, new_state;
struct ibv_qp_attr qp_attr;
struct ibv_qp_init_attr init_attr;
int rc;
old_state = rqpair->ibv_state;
rc = ibv_query_qp(rqpair->rdma_qp->qp, &qp_attr,
g_spdk_nvmf_ibv_query_mask, &init_attr);
if (rc)
{
SPDK_ERRLOG("Failed to get updated RDMA queue pair state!\n");
return IBV_QPS_ERR + 1;
}
new_state = qp_attr.qp_state;
rqpair->ibv_state = new_state;
qp_attr.ah_attr.port_num = qp_attr.port_num;
rc = nvmf_rdma_check_ibv_state(new_state);
if (rc)
{
SPDK_ERRLOG("QP#%d: bad state updated: %u, maybe hardware issue\n", rqpair->qpair.qid, new_state);
/*
* IBV_QPS_UNKNOWN undefined if lib version smaller than libibverbs-1.1.8
* IBV_QPS_UNKNOWN is the enum element after IBV_QPS_ERR
*/
return IBV_QPS_ERR + 1;
}
if (old_state != new_state)
{
spdk_trace_record(TRACE_RDMA_QP_STATE_CHANGE, 0, 0, (uintptr_t)rqpair, new_state);
}
return new_state;
}
static void
nvmf_rdma_request_free_data(struct spdk_nvmf_rdma_request *rdma_req,
struct spdk_nvmf_rdma_transport *rtransport)
{
struct spdk_nvmf_rdma_request_data *data_wr;
struct ibv_send_wr *next_send_wr;
uint64_t req_wrid;
rdma_req->num_outstanding_data_wr = 0;
data_wr = &rdma_req->data;
req_wrid = data_wr->wr.wr_id;
while (data_wr && data_wr->wr.wr_id == req_wrid) {
memset(data_wr->sgl, 0, sizeof(data_wr->wr.sg_list[0]) * data_wr->wr.num_sge);
data_wr->wr.num_sge = 0;
next_send_wr = data_wr->wr.next;
if (data_wr != &rdma_req->data) {
spdk_mempool_put(rtransport->data_wr_pool, data_wr);
}
data_wr = (!next_send_wr || next_send_wr == &rdma_req->rsp.wr) ? NULL :
SPDK_CONTAINEROF(next_send_wr, struct spdk_nvmf_rdma_request_data, wr);
}
}
static void
nvmf_rdma_dump_request(struct spdk_nvmf_rdma_request *req)
{
SPDK_ERRLOG("\t\tRequest Data From Pool: %d\n", req->req.data_from_pool);
if (req->req.cmd) {
SPDK_ERRLOG("\t\tRequest opcode: %d\n", req->req.cmd->nvmf_cmd.opcode);
}
if (req->recv) {
SPDK_ERRLOG("\t\tRequest recv wr_id%lu\n", req->recv->wr.wr_id);
}
}
static void
nvmf_rdma_dump_qpair_contents(struct spdk_nvmf_rdma_qpair *rqpair)
{
int i;
SPDK_ERRLOG("Dumping contents of queue pair (QID %d)\n", rqpair->qpair.qid);
for (i = 0; i < rqpair->max_queue_depth; i++) {
if (rqpair->resources->reqs[i].state != RDMA_REQUEST_STATE_FREE) {
nvmf_rdma_dump_request(&rqpair->resources->reqs[i]);
}
}
}
static void
nvmf_rdma_resources_destroy(struct spdk_nvmf_rdma_resources *resources)
{
if (resources->cmds_mr) {
ibv_dereg_mr(resources->cmds_mr);
}
if (resources->cpls_mr) {
ibv_dereg_mr(resources->cpls_mr);
}
if (resources->bufs_mr) {
ibv_dereg_mr(resources->bufs_mr);
}
spdk_free(resources->cmds);
spdk_free(resources->cpls);
spdk_free(resources->bufs);
free(resources->reqs);
free(resources->recvs);
free(resources);
}
static struct spdk_nvmf_rdma_resources *
nvmf_rdma_resources_create(struct spdk_nvmf_rdma_resource_opts *opts)
{
struct spdk_nvmf_rdma_resources *resources;
struct spdk_nvmf_rdma_request *rdma_req;
struct spdk_nvmf_rdma_recv *rdma_recv;
struct spdk_rdma_qp *qp = NULL;
struct spdk_rdma_srq *srq = NULL;
struct ibv_recv_wr *bad_wr = NULL;
uint32_t i;
int rc = 0;
resources = calloc(1, sizeof(struct spdk_nvmf_rdma_resources));
if (!resources) {
SPDK_ERRLOG("Unable to allocate resources for receive queue.\n");
return NULL;
}
resources->reqs = calloc(opts->max_queue_depth, sizeof(*resources->reqs));
resources->recvs = calloc(opts->max_queue_depth, sizeof(*resources->recvs));
resources->cmds = spdk_zmalloc(opts->max_queue_depth * sizeof(*resources->cmds),
0x1000, NULL, SPDK_ENV_LCORE_ID_ANY, SPDK_MALLOC_DMA);
resources->cpls = spdk_zmalloc(opts->max_queue_depth * sizeof(*resources->cpls),
0x1000, NULL, SPDK_ENV_LCORE_ID_ANY, SPDK_MALLOC_DMA);
if (opts->in_capsule_data_size > 0) {
resources->bufs = spdk_zmalloc(opts->max_queue_depth * opts->in_capsule_data_size,
0x1000, NULL, SPDK_ENV_LCORE_ID_ANY,
SPDK_MALLOC_DMA);
}
if (!resources->reqs || !resources->recvs || !resources->cmds ||
!resources->cpls || (opts->in_capsule_data_size && !resources->bufs)) {
SPDK_ERRLOG("Unable to allocate sufficient memory for RDMA queue.\n");
goto cleanup;
}
resources->cmds_mr = ibv_reg_mr(opts->pd, resources->cmds,
opts->max_queue_depth * sizeof(*resources->cmds),
IBV_ACCESS_LOCAL_WRITE);
resources->cpls_mr = ibv_reg_mr(opts->pd, resources->cpls,
opts->max_queue_depth * sizeof(*resources->cpls),
0);
if (opts->in_capsule_data_size) {
resources->bufs_mr = ibv_reg_mr(opts->pd, resources->bufs,
opts->max_queue_depth *
opts->in_capsule_data_size,
IBV_ACCESS_LOCAL_WRITE | IBV_ACCESS_REMOTE_WRITE);
}
if (!resources->cmds_mr || !resources->cpls_mr ||
(opts->in_capsule_data_size &&
!resources->bufs_mr)) {
goto cleanup;
}
SPDK_DEBUGLOG(rdma, "Command Array: %p Length: %lx LKey: %x\n",
resources->cmds, opts->max_queue_depth * sizeof(*resources->cmds),
resources->cmds_mr->lkey);
SPDK_DEBUGLOG(rdma, "Completion Array: %p Length: %lx LKey: %x\n",
resources->cpls, opts->max_queue_depth * sizeof(*resources->cpls),
resources->cpls_mr->lkey);
if (resources->bufs && resources->bufs_mr) {
SPDK_DEBUGLOG(rdma, "In Capsule Data Array: %p Length: %x LKey: %x\n",
resources->bufs, opts->max_queue_depth *
opts->in_capsule_data_size, resources->bufs_mr->lkey);
}
/* Initialize queues */
STAILQ_INIT(&resources->incoming_queue);
STAILQ_INIT(&resources->free_queue);
if (opts->shared) {
srq = (struct spdk_rdma_srq *)opts->qp;
} else {
qp = (struct spdk_rdma_qp *)opts->qp;
}
for (i = 0; i < opts->max_queue_depth; i++) {
rdma_recv = &resources->recvs[i];
rdma_recv->qpair = opts->qpair;
/* Set up memory to receive commands */
if (resources->bufs) {
rdma_recv->buf = (void *)((uintptr_t)resources->bufs + (i *
opts->in_capsule_data_size));
}
rdma_recv->rdma_wr.type = RDMA_WR_TYPE_RECV;
rdma_recv->sgl[0].addr = (uintptr_t)&resources->cmds[i];
rdma_recv->sgl[0].length = sizeof(resources->cmds[i]);
rdma_recv->sgl[0].lkey = resources->cmds_mr->lkey;
rdma_recv->wr.num_sge = 1;
if (rdma_recv->buf && resources->bufs_mr) {
rdma_recv->sgl[1].addr = (uintptr_t)rdma_recv->buf;
rdma_recv->sgl[1].length = opts->in_capsule_data_size;
rdma_recv->sgl[1].lkey = resources->bufs_mr->lkey;
rdma_recv->wr.num_sge++;
}
rdma_recv->wr.wr_id = (uintptr_t)&rdma_recv->rdma_wr;
rdma_recv->wr.sg_list = rdma_recv->sgl;
if (srq) {
spdk_rdma_srq_queue_recv_wrs(srq, &rdma_recv->wr);
} else {
spdk_rdma_qp_queue_recv_wrs(qp, &rdma_recv->wr);
}
}
for (i = 0; i < opts->max_queue_depth; i++) {
rdma_req = &resources->reqs[i];
if (opts->qpair != NULL) {
rdma_req->req.qpair = &opts->qpair->qpair;
} else {
rdma_req->req.qpair = NULL;
}
rdma_req->req.cmd = NULL;
/* Set up memory to send responses */
rdma_req->req.rsp = &resources->cpls[i];
rdma_req->rsp.sgl[0].addr = (uintptr_t)&resources->cpls[i];
rdma_req->rsp.sgl[0].length = sizeof(resources->cpls[i]);
rdma_req->rsp.sgl[0].lkey = resources->cpls_mr->lkey;
rdma_req->rsp.rdma_wr.type = RDMA_WR_TYPE_SEND;
rdma_req->rsp.wr.wr_id = (uintptr_t)&rdma_req->rsp.rdma_wr;
rdma_req->rsp.wr.next = NULL;
rdma_req->rsp.wr.opcode = IBV_WR_SEND;
rdma_req->rsp.wr.send_flags = IBV_SEND_SIGNALED;
rdma_req->rsp.wr.sg_list = rdma_req->rsp.sgl;
rdma_req->rsp.wr.num_sge = SPDK_COUNTOF(rdma_req->rsp.sgl);
/* Set up memory for data buffers */
rdma_req->data.rdma_wr.type = RDMA_WR_TYPE_DATA;
rdma_req->data.wr.wr_id = (uintptr_t)&rdma_req->data.rdma_wr;
rdma_req->data.wr.next = NULL;
rdma_req->data.wr.send_flags = IBV_SEND_SIGNALED;
rdma_req->data.wr.sg_list = rdma_req->data.sgl;
rdma_req->data.wr.num_sge = SPDK_COUNTOF(rdma_req->data.sgl);
/* Initialize request state to FREE */
rdma_req->state = RDMA_REQUEST_STATE_FREE;
STAILQ_INSERT_TAIL(&resources->free_queue, rdma_req, state_link);
}
if (srq) {
rc = spdk_rdma_srq_flush_recv_wrs(srq, &bad_wr);
} else {
rc = spdk_rdma_qp_flush_recv_wrs(qp, &bad_wr);
}
if (rc) {
goto cleanup;
}
return resources;
cleanup:
nvmf_rdma_resources_destroy(resources);
return NULL;
}
static void
nvmf_rdma_qpair_clean_ibv_events(struct spdk_nvmf_rdma_qpair *rqpair)
{
struct spdk_nvmf_rdma_ibv_event_ctx *ctx, *tctx;
STAILQ_FOREACH_SAFE(ctx, &rqpair->ibv_events, link, tctx) {
ctx->rqpair = NULL;
/* Memory allocated for ctx is freed in nvmf_rdma_qpair_process_ibv_event */
STAILQ_REMOVE(&rqpair->ibv_events, ctx, spdk_nvmf_rdma_ibv_event_ctx, link);
}
}
static void
nvmf_rdma_qpair_destroy(struct spdk_nvmf_rdma_qpair *rqpair)
{
struct spdk_nvmf_rdma_recv *rdma_recv, *recv_tmp;
struct ibv_recv_wr *bad_recv_wr = NULL;
int rc;
spdk_trace_record(TRACE_RDMA_QP_DESTROY, 0, 0, (uintptr_t)rqpair);
if (rqpair->qd != 0) {
struct spdk_nvmf_qpair *qpair = &rqpair->qpair;
struct spdk_nvmf_rdma_transport *rtransport = SPDK_CONTAINEROF(qpair->transport,
struct spdk_nvmf_rdma_transport, transport);
struct spdk_nvmf_rdma_request *req;
uint32_t i, max_req_count = 0;
SPDK_WARNLOG("Destroying qpair when queue depth is %d\n", rqpair->qd);
if (rqpair->srq == NULL) {
nvmf_rdma_dump_qpair_contents(rqpair);
max_req_count = rqpair->max_queue_depth;
} else if (rqpair->poller && rqpair->resources) {
max_req_count = rqpair->poller->max_srq_depth;
}
SPDK_DEBUGLOG(rdma, "Release incomplete requests\n");
for (i = 0; i < max_req_count; i++) {
req = &rqpair->resources->reqs[i];
if (req->req.qpair == qpair && req->state != RDMA_REQUEST_STATE_FREE) {
/* nvmf_rdma_request_process checks qpair ibv and internal state
* and completes a request */
nvmf_rdma_request_process(rtransport, req);
}
}
assert(rqpair->qd == 0);
}
if (rqpair->poller) {
TAILQ_REMOVE(&rqpair->poller->qpairs, rqpair, link);
if (rqpair->srq != NULL && rqpair->resources != NULL) {
/* Drop all received but unprocessed commands for this queue and return them to SRQ */
STAILQ_FOREACH_SAFE(rdma_recv, &rqpair->resources->incoming_queue, link, recv_tmp) {
if (rqpair == rdma_recv->qpair) {
STAILQ_REMOVE(&rqpair->resources->incoming_queue, rdma_recv, spdk_nvmf_rdma_recv, link);
spdk_rdma_srq_queue_recv_wrs(rqpair->srq, &rdma_recv->wr);
rc = spdk_rdma_srq_flush_recv_wrs(rqpair->srq, &bad_recv_wr);
if (rc) {
SPDK_ERRLOG("Unable to re-post rx descriptor\n");
}
}
}
}
}
if (rqpair->cm_id) {
if (rqpair->rdma_qp != NULL) {
spdk_rdma_qp_destroy(rqpair->rdma_qp);
rqpair->rdma_qp = NULL;
}
rdma_destroy_id(rqpair->cm_id);
if (rqpair->poller != NULL && rqpair->srq == NULL) {
rqpair->poller->required_num_wr -= MAX_WR_PER_QP(rqpair->max_queue_depth);
}
}
if (rqpair->srq == NULL && rqpair->resources != NULL) {
nvmf_rdma_resources_destroy(rqpair->resources);
}
nvmf_rdma_qpair_clean_ibv_events(rqpair);
if (rqpair->destruct_channel) {
spdk_put_io_channel(rqpair->destruct_channel);
rqpair->destruct_channel = NULL;
}
free(rqpair);
}
static int
nvmf_rdma_resize_cq(struct spdk_nvmf_rdma_qpair *rqpair, struct spdk_nvmf_rdma_device *device)
{
struct spdk_nvmf_rdma_poller *rpoller;
int rc, num_cqe, required_num_wr;
/* Enlarge CQ size dynamically */
rpoller = rqpair->poller;
required_num_wr = rpoller->required_num_wr + MAX_WR_PER_QP(rqpair->max_queue_depth);
num_cqe = rpoller->num_cqe;
if (num_cqe < required_num_wr) {
num_cqe = spdk_max(num_cqe * 2, required_num_wr);
num_cqe = spdk_min(num_cqe, device->attr.max_cqe);
}
if (rpoller->num_cqe != num_cqe) {
if (device->context->device->transport_type == IBV_TRANSPORT_IWARP) {
SPDK_ERRLOG("iWARP doesn't support CQ resize. Current capacity %u, required %u\n"
"Using CQ of insufficient size may lead to CQ overrun\n", rpoller->num_cqe, num_cqe);
return -1;
}
if (required_num_wr > device->attr.max_cqe) {
SPDK_ERRLOG("RDMA CQE requirement (%d) exceeds device max_cqe limitation (%d)\n",
required_num_wr, device->attr.max_cqe);
return -1;
}
SPDK_DEBUGLOG(rdma, "Resize RDMA CQ from %d to %d\n", rpoller->num_cqe, num_cqe);
rc = ibv_resize_cq(rpoller->cq, num_cqe);
if (rc) {
SPDK_ERRLOG("RDMA CQ resize failed: errno %d: %s\n", errno, spdk_strerror(errno));
return -1;
}
rpoller->num_cqe = num_cqe;
}
rpoller->required_num_wr = required_num_wr;
return 0;
}
static int
nvmf_rdma_qpair_initialize(struct spdk_nvmf_qpair *qpair)
{
struct spdk_nvmf_rdma_qpair *rqpair;
struct spdk_nvmf_rdma_transport *rtransport;
struct spdk_nvmf_transport *transport;
struct spdk_nvmf_rdma_resource_opts opts;
struct spdk_nvmf_rdma_device *device;
struct spdk_rdma_qp_init_attr qp_init_attr = {};
rqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_rdma_qpair, qpair);
device = rqpair->device;
qp_init_attr.qp_context = rqpair;
qp_init_attr.pd = device->pd;
qp_init_attr.send_cq = rqpair->poller->cq;
qp_init_attr.recv_cq = rqpair->poller->cq;
if (rqpair->srq) {
qp_init_attr.srq = rqpair->srq->srq;
} else {
qp_init_attr.cap.max_recv_wr = rqpair->max_queue_depth;
}
/* SEND, READ, and WRITE operations */
qp_init_attr.cap.max_send_wr = (uint32_t)rqpair->max_queue_depth * 2;
qp_init_attr.cap.max_send_sge = spdk_min((uint32_t)device->attr.max_sge, NVMF_DEFAULT_TX_SGE);
qp_init_attr.cap.max_recv_sge = spdk_min((uint32_t)device->attr.max_sge, NVMF_DEFAULT_RX_SGE);
qp_init_attr.stats = &rqpair->poller->stat.qp_stats;
if (rqpair->srq == NULL && nvmf_rdma_resize_cq(rqpair, device) < 0) {
SPDK_ERRLOG("Failed to resize the completion queue. Cannot initialize qpair.\n");
goto error;
}
rqpair->rdma_qp = spdk_rdma_qp_create(rqpair->cm_id, &qp_init_attr);
if (!rqpair->rdma_qp) {
goto error;
}
rqpair->max_send_depth = spdk_min((uint32_t)(rqpair->max_queue_depth * 2),
qp_init_attr.cap.max_send_wr);
rqpair->max_send_sge = spdk_min(NVMF_DEFAULT_TX_SGE, qp_init_attr.cap.max_send_sge);
rqpair->max_recv_sge = spdk_min(NVMF_DEFAULT_RX_SGE, qp_init_attr.cap.max_recv_sge);
spdk_trace_record(TRACE_RDMA_QP_CREATE, 0, 0, (uintptr_t)rqpair);
SPDK_DEBUGLOG(rdma, "New RDMA Connection: %p\n", qpair);
if (rqpair->poller->srq == NULL) {
rtransport = SPDK_CONTAINEROF(qpair->transport, struct spdk_nvmf_rdma_transport, transport);
transport = &rtransport->transport;
opts.qp = rqpair->rdma_qp;
opts.pd = rqpair->cm_id->pd;
opts.qpair = rqpair;
opts.shared = false;
opts.max_queue_depth = rqpair->max_queue_depth;
opts.in_capsule_data_size = transport->opts.in_capsule_data_size;
rqpair->resources = nvmf_rdma_resources_create(&opts);
if (!rqpair->resources) {
SPDK_ERRLOG("Unable to allocate resources for receive queue.\n");
rdma_destroy_qp(rqpair->cm_id);
goto error;
}
} else {
rqpair->resources = rqpair->poller->resources;
}
rqpair->current_recv_depth = 0;
STAILQ_INIT(&rqpair->pending_rdma_read_queue);
STAILQ_INIT(&rqpair->pending_rdma_write_queue);
return 0;
error:
rdma_destroy_id(rqpair->cm_id);
rqpair->cm_id = NULL;
return -1;
}
/* Append the given recv wr structure to the resource structs outstanding recvs list. */
/* This function accepts either a single wr or the first wr in a linked list. */
static void
nvmf_rdma_qpair_queue_recv_wrs(struct spdk_nvmf_rdma_qpair *rqpair, struct ibv_recv_wr *first)
{
struct spdk_nvmf_rdma_transport *rtransport = SPDK_CONTAINEROF(rqpair->qpair.transport,
struct spdk_nvmf_rdma_transport, transport);
if (rqpair->srq != NULL) {
spdk_rdma_srq_queue_recv_wrs(rqpair->srq, first);
} else {
if (spdk_rdma_qp_queue_recv_wrs(rqpair->rdma_qp, first)) {
STAILQ_INSERT_TAIL(&rqpair->poller->qpairs_pending_recv, rqpair, recv_link);
}
}
if (rtransport->rdma_opts.no_wr_batching) {
_poller_submit_recvs(rtransport, rqpair->poller);
}
}
static int
request_transfer_in(struct spdk_nvmf_request *req)
{
struct spdk_nvmf_rdma_request *rdma_req;
struct spdk_nvmf_qpair *qpair;
struct spdk_nvmf_rdma_qpair *rqpair;
struct spdk_nvmf_rdma_transport *rtransport;
qpair = req->qpair;
rdma_req = SPDK_CONTAINEROF(req, struct spdk_nvmf_rdma_request, req);
rqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_rdma_qpair, qpair);
rtransport = SPDK_CONTAINEROF(rqpair->qpair.transport,
struct spdk_nvmf_rdma_transport, transport);
assert(req->xfer == SPDK_NVME_DATA_HOST_TO_CONTROLLER);
assert(rdma_req != NULL);
if (spdk_rdma_qp_queue_send_wrs(rqpair->rdma_qp, &rdma_req->data.wr)) {
STAILQ_INSERT_TAIL(&rqpair->poller->qpairs_pending_send, rqpair, send_link);
}
if (rtransport->rdma_opts.no_wr_batching) {
_poller_submit_sends(rtransport, rqpair->poller);
}
rqpair->current_read_depth += rdma_req->num_outstanding_data_wr;
rqpair->current_send_depth += rdma_req->num_outstanding_data_wr;
return 0;
}
static int
request_transfer_out(struct spdk_nvmf_request *req, int *data_posted)
{
int num_outstanding_data_wr = 0;
struct spdk_nvmf_rdma_request *rdma_req;
struct spdk_nvmf_qpair *qpair;
struct spdk_nvmf_rdma_qpair *rqpair;
struct spdk_nvme_cpl *rsp;
struct ibv_send_wr *first = NULL;
struct spdk_nvmf_rdma_transport *rtransport;
*data_posted = 0;
qpair = req->qpair;
rsp = &req->rsp->nvme_cpl;
rdma_req = SPDK_CONTAINEROF(req, struct spdk_nvmf_rdma_request, req);
rqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_rdma_qpair, qpair);
rtransport = SPDK_CONTAINEROF(rqpair->qpair.transport,
struct spdk_nvmf_rdma_transport, transport);
/* Advance our sq_head pointer */
if (qpair->sq_head == qpair->sq_head_max) {
qpair->sq_head = 0;
} else {
qpair->sq_head++;
}
rsp->sqhd = qpair->sq_head;
/* queue the capsule for the recv buffer */
assert(rdma_req->recv != NULL);
nvmf_rdma_qpair_queue_recv_wrs(rqpair, &rdma_req->recv->wr);
rdma_req->recv = NULL;
assert(rqpair->current_recv_depth > 0);
rqpair->current_recv_depth--;
/* Build the response which consists of optional
* RDMA WRITEs to transfer data, plus an RDMA SEND
* containing the response.
*/
first = &rdma_req->rsp.wr;
if (rsp->status.sc != SPDK_NVME_SC_SUCCESS) {
/* On failure, data was not read from the controller. So clear the
* number of outstanding data WRs to zero.
*/
rdma_req->num_outstanding_data_wr = 0;
} else if (req->xfer == SPDK_NVME_DATA_CONTROLLER_TO_HOST) {
first = &rdma_req->data.wr;
*data_posted = 1;
num_outstanding_data_wr = rdma_req->num_outstanding_data_wr;
}
if (spdk_rdma_qp_queue_send_wrs(rqpair->rdma_qp, first)) {
STAILQ_INSERT_TAIL(&rqpair->poller->qpairs_pending_send, rqpair, send_link);
}
if (rtransport->rdma_opts.no_wr_batching) {
_poller_submit_sends(rtransport, rqpair->poller);
}
/* +1 for the rsp wr */
rqpair->current_send_depth += num_outstanding_data_wr + 1;
return 0;
}
static int
nvmf_rdma_event_accept(struct rdma_cm_id *id, struct spdk_nvmf_rdma_qpair *rqpair)
{
struct spdk_nvmf_rdma_accept_private_data accept_data;
struct rdma_conn_param ctrlr_event_data = {};
int rc;
accept_data.recfmt = 0;
accept_data.crqsize = rqpair->max_queue_depth;
ctrlr_event_data.private_data = &accept_data;
ctrlr_event_data.private_data_len = sizeof(accept_data);
if (id->ps == RDMA_PS_TCP) {
ctrlr_event_data.responder_resources = 0; /* We accept 0 reads from the host */
ctrlr_event_data.initiator_depth = rqpair->max_read_depth;
}
/* Configure infinite retries for the initiator side qpair.
* When using a shared receive queue on the target side,
* we need to pass this value to the initiator to prevent the
* initiator side NIC from completing SEND requests back to the
* initiator with status rnr_retry_count_exceeded. */
if (rqpair->srq != NULL) {
ctrlr_event_data.rnr_retry_count = 0x7;
}
/* When qpair is created without use of rdma cm API, an additional
* information must be provided to initiator in the connection response:
* whether qpair is using SRQ and its qp_num
* Fields below are ignored by rdma cm if qpair has been
* created using rdma cm API. */
ctrlr_event_data.srq = rqpair->srq ? 1 : 0;
ctrlr_event_data.qp_num = rqpair->rdma_qp->qp->qp_num;
rc = spdk_rdma_qp_accept(rqpair->rdma_qp, &ctrlr_event_data);
if (rc) {
SPDK_ERRLOG("Error %d on spdk_rdma_qp_accept\n", errno);
} else {
SPDK_DEBUGLOG(rdma, "Sent back the accept\n");
}
return rc;
}
static void
nvmf_rdma_event_reject(struct rdma_cm_id *id, enum spdk_nvmf_rdma_transport_error error)
{
struct spdk_nvmf_rdma_reject_private_data rej_data;
rej_data.recfmt = 0;
rej_data.sts = error;
rdma_reject(id, &rej_data, sizeof(rej_data));
}
static int
nvmf_rdma_connect(struct spdk_nvmf_transport *transport, struct rdma_cm_event *event)
{
struct spdk_nvmf_rdma_transport *rtransport;
struct spdk_nvmf_rdma_qpair *rqpair = NULL;
struct spdk_nvmf_rdma_port *port;
struct rdma_conn_param *rdma_param = NULL;
const struct spdk_nvmf_rdma_request_private_data *private_data = NULL;
uint16_t max_queue_depth;
uint16_t max_read_depth;
rtransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_rdma_transport, transport);
assert(event->id != NULL); /* Impossible. Can't even reject the connection. */
assert(event->id->verbs != NULL); /* Impossible. No way to handle this. */
rdma_param = &event->param.conn;
if (rdma_param->private_data == NULL ||
rdma_param->private_data_len < sizeof(struct spdk_nvmf_rdma_request_private_data)) {
SPDK_ERRLOG("connect request: no private data provided\n");
nvmf_rdma_event_reject(event->id, SPDK_NVMF_RDMA_ERROR_INVALID_PRIVATE_DATA_LENGTH);
return -1;
}
private_data = rdma_param->private_data;
if (private_data->recfmt != 0) {
SPDK_ERRLOG("Received RDMA private data with RECFMT != 0\n");
nvmf_rdma_event_reject(event->id, SPDK_NVMF_RDMA_ERROR_INVALID_RECFMT);
return -1;
}
SPDK_DEBUGLOG(rdma, "Connect Recv on fabric intf name %s, dev_name %s\n",
event->id->verbs->device->name, event->id->verbs->device->dev_name);
port = event->listen_id->context;
SPDK_DEBUGLOG(rdma, "Listen Id was %p with verbs %p. ListenAddr: %p\n",
event->listen_id, event->listen_id->verbs, port);
/* Figure out the supported queue depth. This is a multi-step process
* that takes into account hardware maximums, host provided values,
* and our target's internal memory limits */
SPDK_DEBUGLOG(rdma, "Calculating Queue Depth\n");
/* Start with the maximum queue depth allowed by the target */
max_queue_depth = rtransport->transport.opts.max_queue_depth;
max_read_depth = rtransport->transport.opts.max_queue_depth;
SPDK_DEBUGLOG(rdma, "Target Max Queue Depth: %d\n",
rtransport->transport.opts.max_queue_depth);
/* Next check the local NIC's hardware limitations */
SPDK_DEBUGLOG(rdma,
"Local NIC Max Send/Recv Queue Depth: %d Max Read/Write Queue Depth: %d\n",
port->device->attr.max_qp_wr, port->device->attr.max_qp_rd_atom);
max_queue_depth = spdk_min(max_queue_depth, port->device->attr.max_qp_wr);
max_read_depth = spdk_min(max_read_depth, port->device->attr.max_qp_init_rd_atom);
/* Next check the remote NIC's hardware limitations */
SPDK_DEBUGLOG(rdma,
"Host (Initiator) NIC Max Incoming RDMA R/W operations: %d Max Outgoing RDMA R/W operations: %d\n",
rdma_param->initiator_depth, rdma_param->responder_resources);
if (rdma_param->initiator_depth > 0) {
max_read_depth = spdk_min(max_read_depth, rdma_param->initiator_depth);
}
/* Finally check for the host software requested values, which are
* optional. */
if (rdma_param->private_data != NULL &&
rdma_param->private_data_len >= sizeof(struct spdk_nvmf_rdma_request_private_data)) {
SPDK_DEBUGLOG(rdma, "Host Receive Queue Size: %d\n", private_data->hrqsize);
SPDK_DEBUGLOG(rdma, "Host Send Queue Size: %d\n", private_data->hsqsize);
max_queue_depth = spdk_min(max_queue_depth, private_data->hrqsize);
max_queue_depth = spdk_min(max_queue_depth, private_data->hsqsize + 1);
}
SPDK_DEBUGLOG(rdma, "Final Negotiated Queue Depth: %d R/W Depth: %d\n",
max_queue_depth, max_read_depth);
rqpair = calloc(1, sizeof(struct spdk_nvmf_rdma_qpair));
if (rqpair == NULL) {
SPDK_ERRLOG("Could not allocate new connection.\n");
nvmf_rdma_event_reject(event->id, SPDK_NVMF_RDMA_ERROR_NO_RESOURCES);
return -1;
}
rqpair->device = port->device;
rqpair->max_queue_depth = max_queue_depth;
rqpair->max_read_depth = max_read_depth;
rqpair->cm_id = event->id;
rqpair->listen_id = event->listen_id;
rqpair->qpair.transport = transport;
STAILQ_INIT(&rqpair->ibv_events);
/* use qid from the private data to determine the qpair type
qid will be set to the appropriate value when the controller is created */
rqpair->qpair.qid = private_data->qid;
event->id->context = &rqpair->qpair;
spdk_nvmf_tgt_new_qpair(transport->tgt, &rqpair->qpair);
return 0;
}
static inline void
nvmf_rdma_setup_wr(struct ibv_send_wr *wr, struct ibv_send_wr *next,
enum spdk_nvme_data_transfer xfer)
{
if (xfer == SPDK_NVME_DATA_CONTROLLER_TO_HOST) {
wr->opcode = IBV_WR_RDMA_WRITE;
wr->send_flags = 0;
wr->next = next;
} else if (xfer == SPDK_NVME_DATA_HOST_TO_CONTROLLER) {
wr->opcode = IBV_WR_RDMA_READ;
wr->send_flags = IBV_SEND_SIGNALED;
wr->next = NULL;
} else {
assert(0);
}
}
static int
nvmf_request_alloc_wrs(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_request *rdma_req,
uint32_t num_sgl_descriptors)
{
struct spdk_nvmf_rdma_request_data *work_requests[SPDK_NVMF_MAX_SGL_ENTRIES];
struct spdk_nvmf_rdma_request_data *current_data_wr;
uint32_t i;
if (num_sgl_descriptors > SPDK_NVMF_MAX_SGL_ENTRIES) {
SPDK_ERRLOG("Requested too much entries (%u), the limit is %u\n",
num_sgl_descriptors, SPDK_NVMF_MAX_SGL_ENTRIES);
return -EINVAL;
}
if (spdk_mempool_get_bulk(rtransport->data_wr_pool, (void **)work_requests, num_sgl_descriptors)) {
return -ENOMEM;
}
current_data_wr = &rdma_req->data;
for (i = 0; i < num_sgl_descriptors; i++) {
nvmf_rdma_setup_wr(&current_data_wr->wr, &work_requests[i]->wr, rdma_req->req.xfer);
current_data_wr->wr.next = &work_requests[i]->wr;
current_data_wr = work_requests[i];
current_data_wr->wr.sg_list = current_data_wr->sgl;
current_data_wr->wr.wr_id = rdma_req->data.wr.wr_id;
}
nvmf_rdma_setup_wr(&current_data_wr->wr, &rdma_req->rsp.wr, rdma_req->req.xfer);
return 0;
}
static inline void
nvmf_rdma_setup_request(struct spdk_nvmf_rdma_request *rdma_req)
{
struct ibv_send_wr *wr = &rdma_req->data.wr;
struct spdk_nvme_sgl_descriptor *sgl = &rdma_req->req.cmd->nvme_cmd.dptr.sgl1;
wr->wr.rdma.rkey = sgl->keyed.key;
wr->wr.rdma.remote_addr = sgl->address;
nvmf_rdma_setup_wr(wr, &rdma_req->rsp.wr, rdma_req->req.xfer);
}
static inline void
nvmf_rdma_update_remote_addr(struct spdk_nvmf_rdma_request *rdma_req, uint32_t num_wrs)
{
struct ibv_send_wr *wr = &rdma_req->data.wr;
struct spdk_nvme_sgl_descriptor *sgl = &rdma_req->req.cmd->nvme_cmd.dptr.sgl1;
uint32_t i;
int j;
uint64_t remote_addr_offset = 0;
for (i = 0; i < num_wrs; ++i) {
wr->wr.rdma.rkey = sgl->keyed.key;
wr->wr.rdma.remote_addr = sgl->address + remote_addr_offset;
for (j = 0; j < wr->num_sge; ++j) {
remote_addr_offset += wr->sg_list[j].length;
}
wr = wr->next;
}
}
static int
nvmf_rdma_fill_wr_sgl(struct spdk_nvmf_rdma_poll_group *rgroup,
struct spdk_nvmf_rdma_device *device,
struct spdk_nvmf_rdma_request *rdma_req,
struct ibv_send_wr *wr,
uint32_t total_length,
uint32_t num_extra_wrs)
{
struct spdk_rdma_memory_translation mem_translation;
struct spdk_dif_ctx *dif_ctx = NULL;
struct ibv_sge *sg_ele;
struct iovec *iov;
uint32_t remaining_data_block = 0;
uint32_t lkey, remaining;
int rc;
if (spdk_unlikely(rdma_req->req.dif_enabled)) {
dif_ctx = &rdma_req->req.dif.dif_ctx;
remaining_data_block = dif_ctx->block_size - dif_ctx->md_size;
}
wr->num_sge = 0;
while (total_length && (num_extra_wrs || wr->num_sge < SPDK_NVMF_MAX_SGL_ENTRIES)) {
iov = &rdma_req->req.iov[rdma_req->iovpos];
rc = spdk_rdma_get_translation(device->map, iov->iov_base, iov->iov_len, &mem_translation);
if (spdk_unlikely(rc)) {
return false;
}
lkey = spdk_rdma_memory_translation_get_lkey(&mem_translation);
sg_ele = &wr->sg_list[wr->num_sge];
remaining = spdk_min((uint32_t)iov->iov_len - rdma_req->offset, total_length);
if (spdk_likely(!dif_ctx)) {
sg_ele->lkey = lkey;
sg_ele->addr = (uintptr_t)iov->iov_base + rdma_req->offset;
sg_ele->length = remaining;
SPDK_DEBUGLOG(rdma, "sge[%d] %p addr 0x%"PRIx64", len %u\n", wr->num_sge, sg_ele, sg_ele->addr,
sg_ele->length);
rdma_req->offset += sg_ele->length;
total_length -= sg_ele->length;
wr->num_sge++;
if (rdma_req->offset == iov->iov_len) {
rdma_req->offset = 0;
rdma_req->iovpos++;
}
} else {
uint32_t data_block_size = dif_ctx->block_size - dif_ctx->md_size;
uint32_t md_size = dif_ctx->md_size;
uint32_t sge_len;
while (remaining) {
if (wr->num_sge >= SPDK_NVMF_MAX_SGL_ENTRIES) {
if (num_extra_wrs > 0 && wr->next) {
wr = wr->next;
wr->num_sge = 0;
sg_ele = &wr->sg_list[wr->num_sge];
num_extra_wrs--;
} else {
break;
}
}
sg_ele->lkey = lkey;
sg_ele->addr = (uintptr_t)((char *)iov->iov_base + rdma_req->offset);
sge_len = spdk_min(remaining, remaining_data_block);
sg_ele->length = sge_len;
SPDK_DEBUGLOG(rdma, "sge[%d] %p addr 0x%"PRIx64", len %u\n", wr->num_sge, sg_ele, sg_ele->addr,
sg_ele->length);
remaining -= sge_len;
remaining_data_block -= sge_len;
rdma_req->offset += sge_len;
total_length -= sge_len;
sg_ele++;
wr->num_sge++;
if (remaining_data_block == 0) {
/* skip metadata */
rdma_req->offset += md_size;
total_length -= md_size;
/* Metadata that do not fit this IO buffer will be included in the next IO buffer */
remaining -= spdk_min(remaining, md_size);
remaining_data_block = data_block_size;
}
if (remaining == 0) {
/* By subtracting the size of the last IOV from the offset, we ensure that we skip
the remaining metadata bits at the beginning of the next buffer */
rdma_req->offset -= spdk_min(iov->iov_len, rdma_req->offset);
rdma_req->iovpos++;
}
}
}
}
if (total_length) {
SPDK_ERRLOG("Not enough SG entries to hold data buffer\n");
return -EINVAL;
}
return 0;
}
static inline uint32_t
nvmf_rdma_calc_num_wrs(uint32_t length, uint32_t io_unit_size, uint32_t block_size)
{
/* estimate the number of SG entries and WRs needed to process the request */
uint32_t num_sge = 0;
uint32_t i;
uint32_t num_buffers = SPDK_CEIL_DIV(length, io_unit_size);
for (i = 0; i < num_buffers && length > 0; i++) {
uint32_t buffer_len = spdk_min(length, io_unit_size);
uint32_t num_sge_in_block = SPDK_CEIL_DIV(buffer_len, block_size);
if (num_sge_in_block * block_size > buffer_len) {
++num_sge_in_block;
}
num_sge += num_sge_in_block;
length -= buffer_len;
}
return SPDK_CEIL_DIV(num_sge, SPDK_NVMF_MAX_SGL_ENTRIES);
}
static int
nvmf_rdma_request_fill_iovs(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_device *device,
struct spdk_nvmf_rdma_request *rdma_req,
uint32_t length)
{
struct spdk_nvmf_rdma_qpair *rqpair;
struct spdk_nvmf_rdma_poll_group *rgroup;
struct spdk_nvmf_request *req = &rdma_req->req;
struct ibv_send_wr *wr = &rdma_req->data.wr;
int rc;
uint32_t num_wrs = 1;
rqpair = SPDK_CONTAINEROF(req->qpair, struct spdk_nvmf_rdma_qpair, qpair);
rgroup = rqpair->poller->group;
/* rdma wr specifics */
nvmf_rdma_setup_request(rdma_req);
rc = spdk_nvmf_request_get_buffers(req, &rgroup->group, &rtransport->transport,
length);
if (rc != 0) {
return rc;
}
assert(req->iovcnt <= rqpair->max_send_sge);
rdma_req->iovpos = 0;
if (spdk_unlikely(req->dif_enabled)) {
num_wrs = nvmf_rdma_calc_num_wrs(length, rtransport->transport.opts.io_unit_size,
req->dif.dif_ctx.block_size);
if (num_wrs > 1) {
rc = nvmf_request_alloc_wrs(rtransport, rdma_req, num_wrs - 1);
if (rc != 0) {
goto err_exit;
}
}
}
rc = nvmf_rdma_fill_wr_sgl(rgroup, device, rdma_req, wr, length, num_wrs - 1);
if (spdk_unlikely(rc != 0)) {
goto err_exit;
}
if (spdk_unlikely(num_wrs > 1)) {
nvmf_rdma_update_remote_addr(rdma_req, num_wrs);
}
/* set the number of outstanding data WRs for this request. */
rdma_req->num_outstanding_data_wr = num_wrs;
return rc;
err_exit:
spdk_nvmf_request_free_buffers(req, &rgroup->group, &rtransport->transport);
nvmf_rdma_request_free_data(rdma_req, rtransport);
req->iovcnt = 0;
return rc;
}
static int
nvmf_rdma_request_fill_iovs_multi_sgl(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_device *device,
struct spdk_nvmf_rdma_request *rdma_req)
{
struct spdk_nvmf_rdma_qpair *rqpair;
struct spdk_nvmf_rdma_poll_group *rgroup;
struct ibv_send_wr *current_wr;
struct spdk_nvmf_request *req = &rdma_req->req;
struct spdk_nvme_sgl_descriptor *inline_segment, *desc;
uint32_t num_sgl_descriptors;
uint32_t lengths[SPDK_NVMF_MAX_SGL_ENTRIES], total_length = 0;
uint32_t i;
int rc;
rqpair = SPDK_CONTAINEROF(rdma_req->req.qpair, struct spdk_nvmf_rdma_qpair, qpair);
rgroup = rqpair->poller->group;
inline_segment = &req->cmd->nvme_cmd.dptr.sgl1;
assert(inline_segment->generic.type == SPDK_NVME_SGL_TYPE_LAST_SEGMENT);
assert(inline_segment->unkeyed.subtype == SPDK_NVME_SGL_SUBTYPE_OFFSET);
num_sgl_descriptors = inline_segment->unkeyed.length / sizeof(struct spdk_nvme_sgl_descriptor);
assert(num_sgl_descriptors <= SPDK_NVMF_MAX_SGL_ENTRIES);
desc = (struct spdk_nvme_sgl_descriptor *)rdma_req->recv->buf + inline_segment->address;
for (i = 0; i < num_sgl_descriptors; i++) {
if (spdk_likely(!req->dif_enabled)) {
lengths[i] = desc->keyed.length;
} else {
req->dif.orig_length += desc->keyed.length;
lengths[i] = spdk_dif_get_length_with_md(desc->keyed.length, &req->dif.dif_ctx);
req->dif.elba_length += lengths[i];
}
total_length += lengths[i];
desc++;
}
if (total_length > rtransport->transport.opts.max_io_size) {
SPDK_ERRLOG("Multi SGL length 0x%x exceeds max io size 0x%x\n",
total_length, rtransport->transport.opts.max_io_size);
req->rsp->nvme_cpl.status.sc = SPDK_NVME_SC_DATA_SGL_LENGTH_INVALID;
return -EINVAL;
}
if (nvmf_request_alloc_wrs(rtransport, rdma_req, num_sgl_descriptors - 1) != 0) {
return -ENOMEM;
}
rc = spdk_nvmf_request_get_buffers(req, &rgroup->group, &rtransport->transport, total_length);
if (rc != 0) {
nvmf_rdma_request_free_data(rdma_req, rtransport);
return rc;
}
/* The first WR must always be the embedded data WR. This is how we unwind them later. */
current_wr = &rdma_req->data.wr;
assert(current_wr != NULL);
req->length = 0;
rdma_req->iovpos = 0;
desc = (struct spdk_nvme_sgl_descriptor *)rdma_req->recv->buf + inline_segment->address;
for (i = 0; i < num_sgl_descriptors; i++) {
/* The descriptors must be keyed data block descriptors with an address, not an offset. */
if (spdk_unlikely(desc->generic.type != SPDK_NVME_SGL_TYPE_KEYED_DATA_BLOCK ||
desc->keyed.subtype != SPDK_NVME_SGL_SUBTYPE_ADDRESS)) {
rc = -EINVAL;
goto err_exit;
}
rc = nvmf_rdma_fill_wr_sgl(rgroup, device, rdma_req, current_wr, lengths[i], 0);
if (rc != 0) {
rc = -ENOMEM;
goto err_exit;
}
req->length += desc->keyed.length;
current_wr->wr.rdma.rkey = desc->keyed.key;
current_wr->wr.rdma.remote_addr = desc->address;
current_wr = current_wr->next;
desc++;
}
#ifdef SPDK_CONFIG_RDMA_SEND_WITH_INVAL
/* Go back to the last descriptor in the list. */
desc--;
if ((device->attr.device_cap_flags & IBV_DEVICE_MEM_MGT_EXTENSIONS) != 0) {
if (desc->keyed.subtype == SPDK_NVME_SGL_SUBTYPE_INVALIDATE_KEY) {
rdma_req->rsp.wr.opcode = IBV_WR_SEND_WITH_INV;
rdma_req->rsp.wr.imm_data = desc->keyed.key;
}
}
#endif
rdma_req->num_outstanding_data_wr = num_sgl_descriptors;
return 0;
err_exit:
spdk_nvmf_request_free_buffers(req, &rgroup->group, &rtransport->transport);
nvmf_rdma_request_free_data(rdma_req, rtransport);
return rc;
}
static int
nvmf_rdma_request_parse_sgl(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_device *device,
struct spdk_nvmf_rdma_request *rdma_req)
{
struct spdk_nvmf_request *req = &rdma_req->req;
struct spdk_nvme_cpl *rsp;
struct spdk_nvme_sgl_descriptor *sgl;
int rc;
uint32_t length;
rsp = &req->rsp->nvme_cpl;
sgl = &req->cmd->nvme_cmd.dptr.sgl1;
if (sgl->generic.type == SPDK_NVME_SGL_TYPE_KEYED_DATA_BLOCK &&
(sgl->keyed.subtype == SPDK_NVME_SGL_SUBTYPE_ADDRESS ||
sgl->keyed.subtype == SPDK_NVME_SGL_SUBTYPE_INVALIDATE_KEY)) {
length = sgl->keyed.length;
if (length > rtransport->transport.opts.max_io_size) {
SPDK_ERRLOG("SGL length 0x%x exceeds max io size 0x%x\n",
length, rtransport->transport.opts.max_io_size);
rsp->status.sc = SPDK_NVME_SC_DATA_SGL_LENGTH_INVALID;
return -1;
}
#ifdef SPDK_CONFIG_RDMA_SEND_WITH_INVAL
if ((device->attr.device_cap_flags & IBV_DEVICE_MEM_MGT_EXTENSIONS) != 0) {
if (sgl->keyed.subtype == SPDK_NVME_SGL_SUBTYPE_INVALIDATE_KEY) {
rdma_req->rsp.wr.opcode = IBV_WR_SEND_WITH_INV;
rdma_req->rsp.wr.imm_data = sgl->keyed.key;
}
}
#endif
/* fill request length and populate iovs */
req->length = length;
if (spdk_unlikely(req->dif_enabled)) {
req->dif.orig_length = length;
length = spdk_dif_get_length_with_md(length, &req->dif.dif_ctx);
req->dif.elba_length = length;
}
rc = nvmf_rdma_request_fill_iovs(rtransport, device, rdma_req, length);
if (spdk_unlikely(rc < 0)) {
if (rc == -EINVAL) {
SPDK_ERRLOG("SGL length exceeds the max I/O size\n");
rsp->status.sc = SPDK_NVME_SC_DATA_SGL_LENGTH_INVALID;
return -1;
}
/* No available buffers. Queue this request up. */
SPDK_DEBUGLOG(rdma, "No available large data buffers. Queueing request %p\n", rdma_req);
return 0;
}
/* backward compatible */
req->data = req->iov[0].iov_base;
SPDK_DEBUGLOG(rdma, "Request %p took %d buffer/s from central pool\n", rdma_req,
req->iovcnt);
return 0;
} else if (sgl->generic.type == SPDK_NVME_SGL_TYPE_DATA_BLOCK &&
sgl->unkeyed.subtype == SPDK_NVME_SGL_SUBTYPE_OFFSET) {
uint64_t offset = sgl->address;
uint32_t max_len = rtransport->transport.opts.in_capsule_data_size;
SPDK_DEBUGLOG(nvmf, "In-capsule data: offset 0x%" PRIx64 ", length 0x%x\n",
offset, sgl->unkeyed.length);
if (offset > max_len) {
SPDK_ERRLOG("In-capsule offset 0x%" PRIx64 " exceeds capsule length 0x%x\n",
offset, max_len);
rsp->status.sc = SPDK_NVME_SC_INVALID_SGL_OFFSET;
return -1;
}
max_len -= (uint32_t)offset;
if (sgl->unkeyed.length > max_len) {
SPDK_ERRLOG("In-capsule data length 0x%x exceeds capsule length 0x%x\n",
sgl->unkeyed.length, max_len);
rsp->status.sc = SPDK_NVME_SC_DATA_SGL_LENGTH_INVALID;
return -1;
}
rdma_req->num_outstanding_data_wr = 0;
req->data = rdma_req->recv->buf + offset;
req->data_from_pool = false;
req->length = sgl->unkeyed.length;
req->iov[0].iov_base = req->data;
req->iov[0].iov_len = req->length;
req->iovcnt = 1;
return 0;
} else if (sgl->generic.type == SPDK_NVME_SGL_TYPE_LAST_SEGMENT &&
sgl->unkeyed.subtype == SPDK_NVME_SGL_SUBTYPE_OFFSET) {
rc = nvmf_rdma_request_fill_iovs_multi_sgl(rtransport, device, rdma_req);
if (rc == -ENOMEM) {
SPDK_DEBUGLOG(rdma, "No available large data buffers. Queueing request %p\n", rdma_req);
return 0;
} else if (rc == -EINVAL) {
SPDK_ERRLOG("Multi SGL element request length exceeds the max I/O size\n");
rsp->status.sc = SPDK_NVME_SC_DATA_SGL_LENGTH_INVALID;
return -1;
}
/* backward compatible */
req->data = req->iov[0].iov_base;
SPDK_DEBUGLOG(rdma, "Request %p took %d buffer/s from central pool\n", rdma_req,
req->iovcnt);
return 0;
}
SPDK_ERRLOG("Invalid NVMf I/O Command SGL: Type 0x%x, Subtype 0x%x\n",
sgl->generic.type, sgl->generic.subtype);
rsp->status.sc = SPDK_NVME_SC_SGL_DESCRIPTOR_TYPE_INVALID;
return -1;
}
static void
_nvmf_rdma_request_free(struct spdk_nvmf_rdma_request *rdma_req,
struct spdk_nvmf_rdma_transport *rtransport)
{
struct spdk_nvmf_rdma_qpair *rqpair;
struct spdk_nvmf_rdma_poll_group *rgroup;
rqpair = SPDK_CONTAINEROF(rdma_req->req.qpair, struct spdk_nvmf_rdma_qpair, qpair);
if (rdma_req->req.data_from_pool) {
rgroup = rqpair->poller->group;
spdk_nvmf_request_free_buffers(&rdma_req->req, &rgroup->group, &rtransport->transport);
}
nvmf_rdma_request_free_data(rdma_req, rtransport);
rdma_req->req.length = 0;
rdma_req->req.iovcnt = 0;
rdma_req->req.data = NULL;
rdma_req->rsp.wr.next = NULL;
rdma_req->data.wr.next = NULL;
rdma_req->offset = 0;
memset(&rdma_req->req.dif, 0, sizeof(rdma_req->req.dif));
rqpair->qd--;
STAILQ_INSERT_HEAD(&rqpair->resources->free_queue, rdma_req, state_link);
rdma_req->state = RDMA_REQUEST_STATE_FREE;
}
bool
nvmf_rdma_request_process(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_request *rdma_req)
{
struct spdk_nvmf_rdma_qpair *rqpair;
struct spdk_nvmf_rdma_device *device;
struct spdk_nvmf_rdma_poll_group *rgroup;
struct spdk_nvme_cpl *rsp = &rdma_req->req.rsp->nvme_cpl;
int rc;
struct spdk_nvmf_rdma_recv *rdma_recv;
enum spdk_nvmf_rdma_request_state prev_state;
bool progress = false;
int data_posted;
uint32_t num_blocks;
rqpair = SPDK_CONTAINEROF(rdma_req->req.qpair, struct spdk_nvmf_rdma_qpair, qpair);
device = rqpair->device;
rgroup = rqpair->poller->group;
assert(rdma_req->state != RDMA_REQUEST_STATE_FREE);
/* If the queue pair is in an error state, force the request to the completed state
* to release resources. */
if (rqpair->ibv_state == IBV_QPS_ERR || rqpair->qpair.state != SPDK_NVMF_QPAIR_ACTIVE) {
if (rdma_req->state == RDMA_REQUEST_STATE_NEED_BUFFER) {
STAILQ_REMOVE(&rgroup->group.pending_buf_queue, &rdma_req->req, spdk_nvmf_request, buf_link);
} else if (rdma_req->state == RDMA_REQUEST_STATE_DATA_TRANSFER_TO_CONTROLLER_PENDING) {
STAILQ_REMOVE(&rqpair->pending_rdma_read_queue, rdma_req, spdk_nvmf_rdma_request, state_link);
} else if (rdma_req->state == RDMA_REQUEST_STATE_DATA_TRANSFER_TO_HOST_PENDING) {
STAILQ_REMOVE(&rqpair->pending_rdma_write_queue, rdma_req, spdk_nvmf_rdma_request, state_link);
}
rdma_req->state = RDMA_REQUEST_STATE_COMPLETED;
}
/* The loop here is to allow for several back-to-back state changes. */
do {
prev_state = rdma_req->state;
SPDK_DEBUGLOG(rdma, "Request %p entering state %d\n", rdma_req, prev_state);
switch (rdma_req->state) {
case RDMA_REQUEST_STATE_FREE:
/* Some external code must kick a request into RDMA_REQUEST_STATE_NEW
* to escape this state. */
break;
case RDMA_REQUEST_STATE_NEW:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_NEW, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
rdma_recv = rdma_req->recv;
/* The first element of the SGL is the NVMe command */
rdma_req->req.cmd = (union nvmf_h2c_msg *)rdma_recv->sgl[0].addr;
memset(rdma_req->req.rsp, 0, sizeof(*rdma_req->req.rsp));
if (rqpair->ibv_state == IBV_QPS_ERR || rqpair->qpair.state != SPDK_NVMF_QPAIR_ACTIVE) {
rdma_req->state = RDMA_REQUEST_STATE_COMPLETED;
break;
}
if (spdk_unlikely(spdk_nvmf_request_get_dif_ctx(&rdma_req->req, &rdma_req->req.dif.dif_ctx))) {
rdma_req->req.dif_enabled = true;
}
#ifdef SPDK_CONFIG_RDMA_SEND_WITH_INVAL
rdma_req->rsp.wr.opcode = IBV_WR_SEND;
rdma_req->rsp.wr.imm_data = 0;
#endif
/* The next state transition depends on the data transfer needs of this request. */
rdma_req->req.xfer = spdk_nvmf_req_get_xfer(&rdma_req->req);
if (spdk_unlikely(rdma_req->req.xfer == SPDK_NVME_DATA_BIDIRECTIONAL)) {
rsp->status.sct = SPDK_NVME_SCT_GENERIC;
rsp->status.sc = SPDK_NVME_SC_INVALID_OPCODE;
rdma_req->state = RDMA_REQUEST_STATE_READY_TO_COMPLETE;
SPDK_DEBUGLOG(rdma, "Request %p: invalid xfer type (BIDIRECTIONAL)\n", rdma_req);
break;
}
/* If no data to transfer, ready to execute. */
if (rdma_req->req.xfer == SPDK_NVME_DATA_NONE) {
rdma_req->state = RDMA_REQUEST_STATE_READY_TO_EXECUTE;
break;
}
rdma_req->state = RDMA_REQUEST_STATE_NEED_BUFFER;
STAILQ_INSERT_TAIL(&rgroup->group.pending_buf_queue, &rdma_req->req, buf_link);
break;
case RDMA_REQUEST_STATE_NEED_BUFFER:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_NEED_BUFFER, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
assert(rdma_req->req.xfer != SPDK_NVME_DATA_NONE);
if (&rdma_req->req != STAILQ_FIRST(&rgroup->group.pending_buf_queue)) {
/* This request needs to wait in line to obtain a buffer */
break;
}
/* Try to get a data buffer */
rc = nvmf_rdma_request_parse_sgl(rtransport, device, rdma_req);
if (rc < 0) {
STAILQ_REMOVE_HEAD(&rgroup->group.pending_buf_queue, buf_link);
rdma_req->state = RDMA_REQUEST_STATE_READY_TO_COMPLETE;
break;
}
if (!rdma_req->req.data) {
/* No buffers available. */
rgroup->stat.pending_data_buffer++;
break;
}
STAILQ_REMOVE_HEAD(&rgroup->group.pending_buf_queue, buf_link);
/* If data is transferring from host to controller and the data didn't
* arrive using in capsule data, we need to do a transfer from the host.
*/
if (rdma_req->req.xfer == SPDK_NVME_DATA_HOST_TO_CONTROLLER &&
rdma_req->req.data_from_pool) {
STAILQ_INSERT_TAIL(&rqpair->pending_rdma_read_queue, rdma_req, state_link);
rdma_req->state = RDMA_REQUEST_STATE_DATA_TRANSFER_TO_CONTROLLER_PENDING;
break;
}
rdma_req->state = RDMA_REQUEST_STATE_READY_TO_EXECUTE;
break;
case RDMA_REQUEST_STATE_DATA_TRANSFER_TO_CONTROLLER_PENDING:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_DATA_TRANSFER_TO_CONTROLLER_PENDING, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
if (rdma_req != STAILQ_FIRST(&rqpair->pending_rdma_read_queue)) {
/* This request needs to wait in line to perform RDMA */
break;
}
if (rqpair->current_send_depth + rdma_req->num_outstanding_data_wr > rqpair->max_send_depth
|| rqpair->current_read_depth + rdma_req->num_outstanding_data_wr > rqpair->max_read_depth) {
/* We can only have so many WRs outstanding. we have to wait until some finish. */
rqpair->poller->stat.pending_rdma_read++;
break;
}
/* We have already verified that this request is the head of the queue. */
STAILQ_REMOVE_HEAD(&rqpair->pending_rdma_read_queue, state_link);
rc = request_transfer_in(&rdma_req->req);
if (!rc) {
rdma_req->state = RDMA_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER;
} else {
rsp->status.sc = SPDK_NVME_SC_INTERNAL_DEVICE_ERROR;
rdma_req->state = RDMA_REQUEST_STATE_READY_TO_COMPLETE;
}
break;
case RDMA_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
/* Some external code must kick a request into RDMA_REQUEST_STATE_READY_TO_EXECUTE
* to escape this state. */
break;
case RDMA_REQUEST_STATE_READY_TO_EXECUTE:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_READY_TO_EXECUTE, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
if (spdk_unlikely(rdma_req->req.dif_enabled)) {
if (rdma_req->req.xfer == SPDK_NVME_DATA_HOST_TO_CONTROLLER) {
/* generate DIF for write operation */
num_blocks = SPDK_CEIL_DIV(rdma_req->req.dif.elba_length, rdma_req->req.dif.dif_ctx.block_size);
assert(num_blocks > 0);
rc = spdk_dif_generate(rdma_req->req.iov, rdma_req->req.iovcnt,
num_blocks, &rdma_req->req.dif.dif_ctx);
if (rc != 0) {
SPDK_ERRLOG("DIF generation failed\n");
rdma_req->state = RDMA_REQUEST_STATE_COMPLETED;
spdk_nvmf_qpair_disconnect(&rqpair->qpair, NULL, NULL);
break;
}
}
assert(rdma_req->req.dif.elba_length >= rdma_req->req.length);
/* set extended length before IO operation */
rdma_req->req.length = rdma_req->req.dif.elba_length;
}
rdma_req->state = RDMA_REQUEST_STATE_EXECUTING;
spdk_nvmf_request_exec(&rdma_req->req);
break;
case RDMA_REQUEST_STATE_EXECUTING:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_EXECUTING, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
/* Some external code must kick a request into RDMA_REQUEST_STATE_EXECUTED
* to escape this state. */
break;
case RDMA_REQUEST_STATE_EXECUTED:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_EXECUTED, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
if (rsp->status.sc == SPDK_NVME_SC_SUCCESS &&
rdma_req->req.xfer == SPDK_NVME_DATA_CONTROLLER_TO_HOST) {
STAILQ_INSERT_TAIL(&rqpair->pending_rdma_write_queue, rdma_req, state_link);
rdma_req->state = RDMA_REQUEST_STATE_DATA_TRANSFER_TO_HOST_PENDING;
} else {
rdma_req->state = RDMA_REQUEST_STATE_READY_TO_COMPLETE;
}
if (spdk_unlikely(rdma_req->req.dif_enabled)) {
/* restore the original length */
rdma_req->req.length = rdma_req->req.dif.orig_length;
if (rdma_req->req.xfer == SPDK_NVME_DATA_CONTROLLER_TO_HOST) {
struct spdk_dif_error error_blk;
num_blocks = SPDK_CEIL_DIV(rdma_req->req.dif.elba_length, rdma_req->req.dif.dif_ctx.block_size);
rc = spdk_dif_verify(rdma_req->req.iov, rdma_req->req.iovcnt, num_blocks,
&rdma_req->req.dif.dif_ctx, &error_blk);
if (rc) {
struct spdk_nvme_cpl *rsp = &rdma_req->req.rsp->nvme_cpl;
SPDK_ERRLOG("DIF error detected. type=%d, offset=%" PRIu32 "\n", error_blk.err_type,
error_blk.err_offset);
rsp->status.sct = SPDK_NVME_SCT_MEDIA_ERROR;
rsp->status.sc = nvmf_rdma_dif_error_to_compl_status(error_blk.err_type);
rdma_req->state = RDMA_REQUEST_STATE_READY_TO_COMPLETE;
STAILQ_REMOVE(&rqpair->pending_rdma_write_queue, rdma_req, spdk_nvmf_rdma_request, state_link);
}
}
}
break;
case RDMA_REQUEST_STATE_DATA_TRANSFER_TO_HOST_PENDING:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_DATA_TRANSFER_TO_HOST_PENDING, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
if (rdma_req != STAILQ_FIRST(&rqpair->pending_rdma_write_queue)) {
/* This request needs to wait in line to perform RDMA */
break;
}
if ((rqpair->current_send_depth + rdma_req->num_outstanding_data_wr + 1) >
rqpair->max_send_depth) {
/* We can only have so many WRs outstanding. we have to wait until some finish.
* +1 since each request has an additional wr in the resp. */
rqpair->poller->stat.pending_rdma_write++;
break;
}
/* We have already verified that this request is the head of the queue. */
STAILQ_REMOVE_HEAD(&rqpair->pending_rdma_write_queue, state_link);
/* The data transfer will be kicked off from
* RDMA_REQUEST_STATE_READY_TO_COMPLETE state.
*/
rdma_req->state = RDMA_REQUEST_STATE_READY_TO_COMPLETE;
break;
case RDMA_REQUEST_STATE_READY_TO_COMPLETE:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_READY_TO_COMPLETE, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
rc = request_transfer_out(&rdma_req->req, &data_posted);
assert(rc == 0); /* No good way to handle this currently */
if (rc) {
rdma_req->state = RDMA_REQUEST_STATE_COMPLETED;
} else {
rdma_req->state = data_posted ? RDMA_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST :
RDMA_REQUEST_STATE_COMPLETING;
}
break;
case RDMA_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
/* Some external code must kick a request into RDMA_REQUEST_STATE_COMPLETED
* to escape this state. */
break;
case RDMA_REQUEST_STATE_COMPLETING:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_COMPLETING, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
/* Some external code must kick a request into RDMA_REQUEST_STATE_COMPLETED
* to escape this state. */
break;
case RDMA_REQUEST_STATE_COMPLETED:
spdk_trace_record(TRACE_RDMA_REQUEST_STATE_COMPLETED, 0, 0,
(uintptr_t)rdma_req, (uintptr_t)rqpair);
rqpair->poller->stat.request_latency += spdk_get_ticks() - rdma_req->receive_tsc;
_nvmf_rdma_request_free(rdma_req, rtransport);
break;
case RDMA_REQUEST_NUM_STATES:
default:
assert(0);
break;
}
if (rdma_req->state != prev_state) {
progress = true;
}
} while (rdma_req->state != prev_state);
return progress;
}
/* Public API callbacks begin here */
#define SPDK_NVMF_RDMA_DEFAULT_MAX_QUEUE_DEPTH 128
#define SPDK_NVMF_RDMA_DEFAULT_AQ_DEPTH 128
#define SPDK_NVMF_RDMA_DEFAULT_SRQ_DEPTH 4096
#define SPDK_NVMF_RDMA_DEFAULT_MAX_QPAIRS_PER_CTRLR 128
#define SPDK_NVMF_RDMA_DEFAULT_IN_CAPSULE_DATA_SIZE 4096
#define SPDK_NVMF_RDMA_DEFAULT_MAX_IO_SIZE 131072
#define SPDK_NVMF_RDMA_MIN_IO_BUFFER_SIZE (SPDK_NVMF_RDMA_DEFAULT_MAX_IO_SIZE / SPDK_NVMF_MAX_SGL_ENTRIES)
#define SPDK_NVMF_RDMA_DEFAULT_NUM_SHARED_BUFFERS 4095
#define SPDK_NVMF_RDMA_DEFAULT_BUFFER_CACHE_SIZE 32
#define SPDK_NVMF_RDMA_DEFAULT_NO_SRQ false
#define SPDK_NVMF_RDMA_DIF_INSERT_OR_STRIP false
#define SPDK_NVMF_RDMA_ACCEPTOR_BACKLOG 100
#define SPDK_NVMF_RDMA_DEFAULT_ABORT_TIMEOUT_SEC 1
#define SPDK_NVMF_RDMA_DEFAULT_NO_WR_BATCHING false
static void
nvmf_rdma_opts_init(struct spdk_nvmf_transport_opts *opts)
{
opts->max_queue_depth = SPDK_NVMF_RDMA_DEFAULT_MAX_QUEUE_DEPTH;
opts->max_qpairs_per_ctrlr = SPDK_NVMF_RDMA_DEFAULT_MAX_QPAIRS_PER_CTRLR;
opts->in_capsule_data_size = SPDK_NVMF_RDMA_DEFAULT_IN_CAPSULE_DATA_SIZE;
opts->max_io_size = SPDK_NVMF_RDMA_DEFAULT_MAX_IO_SIZE;
opts->io_unit_size = SPDK_NVMF_RDMA_MIN_IO_BUFFER_SIZE;
opts->max_aq_depth = SPDK_NVMF_RDMA_DEFAULT_AQ_DEPTH;
opts->num_shared_buffers = SPDK_NVMF_RDMA_DEFAULT_NUM_SHARED_BUFFERS;
opts->buf_cache_size = SPDK_NVMF_RDMA_DEFAULT_BUFFER_CACHE_SIZE;
opts->dif_insert_or_strip = SPDK_NVMF_RDMA_DIF_INSERT_OR_STRIP;
opts->abort_timeout_sec = SPDK_NVMF_RDMA_DEFAULT_ABORT_TIMEOUT_SEC;
opts->transport_specific = NULL;
}
static int nvmf_rdma_destroy(struct spdk_nvmf_transport *transport,
spdk_nvmf_transport_destroy_done_cb cb_fn, void *cb_arg);
static inline bool
nvmf_rdma_is_rxe_device(struct spdk_nvmf_rdma_device *device)
{
return device->attr.vendor_id == SPDK_RDMA_RXE_VENDOR_ID_OLD ||
device->attr.vendor_id == SPDK_RDMA_RXE_VENDOR_ID_NEW;
}
static int
nvmf_rdma_accept(void *ctx);
static struct spdk_nvmf_transport *
nvmf_rdma_create(struct spdk_nvmf_transport_opts *opts)
{
int rc;
struct spdk_nvmf_rdma_transport *rtransport;
struct spdk_nvmf_rdma_device *device, *tmp;
struct ibv_context **contexts;
uint32_t i;
int flag;
uint32_t sge_count;
uint32_t min_shared_buffers;
int max_device_sge = SPDK_NVMF_MAX_SGL_ENTRIES;
pthread_mutexattr_t attr;
rtransport = calloc(1, sizeof(*rtransport));
if (!rtransport) {
return NULL;
}
if (pthread_mutexattr_init(&attr)) {
SPDK_ERRLOG("pthread_mutexattr_init() failed\n");
free(rtransport);
return NULL;
}
if (pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_RECURSIVE)) {
SPDK_ERRLOG("pthread_mutexattr_settype() failed\n");
pthread_mutexattr_destroy(&attr);
free(rtransport);
return NULL;
}
if (pthread_mutex_init(&rtransport->lock, &attr)) {
SPDK_ERRLOG("pthread_mutex_init() failed\n");
pthread_mutexattr_destroy(&attr);
free(rtransport);
return NULL;
}
pthread_mutexattr_destroy(&attr);
TAILQ_INIT(&rtransport->devices);
TAILQ_INIT(&rtransport->ports);
TAILQ_INIT(&rtransport->poll_groups);
rtransport->transport.ops = &spdk_nvmf_transport_rdma;
rtransport->rdma_opts.num_cqe = DEFAULT_NVMF_RDMA_CQ_SIZE;
rtransport->rdma_opts.max_srq_depth = SPDK_NVMF_RDMA_DEFAULT_SRQ_DEPTH;
rtransport->rdma_opts.no_srq = SPDK_NVMF_RDMA_DEFAULT_NO_SRQ;
rtransport->rdma_opts.acceptor_backlog = SPDK_NVMF_RDMA_ACCEPTOR_BACKLOG;
rtransport->rdma_opts.no_wr_batching = SPDK_NVMF_RDMA_DEFAULT_NO_WR_BATCHING;
if (opts->transport_specific != NULL &&
spdk_json_decode_object_relaxed(opts->transport_specific, rdma_transport_opts_decoder,
SPDK_COUNTOF(rdma_transport_opts_decoder),
&rtransport->rdma_opts)) {
SPDK_ERRLOG("spdk_json_decode_object_relaxed failed\n");
nvmf_rdma_destroy(&rtransport->transport, NULL, NULL);
return NULL;
}
SPDK_INFOLOG(rdma, "*** RDMA Transport Init ***\n"
" Transport opts: max_ioq_depth=%d, max_io_size=%d,\n"
" max_io_qpairs_per_ctrlr=%d, io_unit_size=%d,\n"
" in_capsule_data_size=%d, max_aq_depth=%d,\n"
" num_shared_buffers=%d, num_cqe=%d, max_srq_depth=%d, no_srq=%d,"
" acceptor_backlog=%d, no_wr_batching=%d abort_timeout_sec=%d\n",
opts->max_queue_depth,
opts->max_io_size,
opts->max_qpairs_per_ctrlr - 1,
opts->io_unit_size,
opts->in_capsule_data_size,
opts->max_aq_depth,
opts->num_shared_buffers,
rtransport->rdma_opts.num_cqe,
rtransport->rdma_opts.max_srq_depth,
rtransport->rdma_opts.no_srq,
rtransport->rdma_opts.acceptor_backlog,
rtransport->rdma_opts.no_wr_batching,
opts->abort_timeout_sec);
/* I/O unit size cannot be larger than max I/O size */
if (opts->io_unit_size > opts->max_io_size) {
opts->io_unit_size = opts->max_io_size;
}
if (rtransport->rdma_opts.acceptor_backlog <= 0) {
SPDK_ERRLOG("The acceptor backlog cannot be less than 1, setting to the default value of (%d).\n",
SPDK_NVMF_RDMA_ACCEPTOR_BACKLOG);
rtransport->rdma_opts.acceptor_backlog = SPDK_NVMF_RDMA_ACCEPTOR_BACKLOG;
}
if (opts->num_shared_buffers < (SPDK_NVMF_MAX_SGL_ENTRIES * 2)) {
SPDK_ERRLOG("The number of shared data buffers (%d) is less than"
"the minimum number required to guarantee that forward progress can be made (%d)\n",
opts->num_shared_buffers, (SPDK_NVMF_MAX_SGL_ENTRIES * 2));
nvmf_rdma_destroy(&rtransport->transport, NULL, NULL);
return NULL;
}
min_shared_buffers = spdk_env_get_core_count() * opts->buf_cache_size;
if (min_shared_buffers > opts->num_shared_buffers) {
SPDK_ERRLOG("There are not enough buffers to satisfy"
"per-poll group caches for each thread. (%" PRIu32 ")"
"supplied. (%" PRIu32 ") required\n", opts->num_shared_buffers, min_shared_buffers);
SPDK_ERRLOG("Please specify a larger number of shared buffers\n");
nvmf_rdma_destroy(&rtransport->transport, NULL, NULL);
return NULL;
}
sge_count = opts->max_io_size / opts->io_unit_size;
if (sge_count > NVMF_DEFAULT_TX_SGE) {
SPDK_ERRLOG("Unsupported IO Unit size specified, %d bytes\n", opts->io_unit_size);
nvmf_rdma_destroy(&rtransport->transport, NULL, NULL);
return NULL;
}
rtransport->event_channel = rdma_create_event_channel();
if (rtransport->event_channel == NULL) {
SPDK_ERRLOG("rdma_create_event_channel() failed, %s\n", spdk_strerror(errno));
nvmf_rdma_destroy(&rtransport->transport, NULL, NULL);
return NULL;
}
flag = fcntl(rtransport->event_channel->fd, F_GETFL);
if (fcntl(rtransport->event_channel->fd, F_SETFL, flag | O_NONBLOCK) < 0) {
SPDK_ERRLOG("fcntl can't set nonblocking mode for socket, fd: %d (%s)\n",
rtransport->event_channel->fd, spdk_strerror(errno));
nvmf_rdma_destroy(&rtransport->transport, NULL, NULL);
return NULL;
}
rtransport->data_wr_pool = spdk_mempool_create("spdk_nvmf_rdma_wr_data",
opts->max_queue_depth * SPDK_NVMF_MAX_SGL_ENTRIES,
sizeof(struct spdk_nvmf_rdma_request_data),
SPDK_MEMPOOL_DEFAULT_CACHE_SIZE,
SPDK_ENV_SOCKET_ID_ANY);
if (!rtransport->data_wr_pool) {
SPDK_ERRLOG("Unable to allocate work request pool for poll group\n");
nvmf_rdma_destroy(&rtransport->transport, NULL, NULL);
return NULL;
}
contexts = rdma_get_devices(NULL);
if (contexts == NULL) {
SPDK_ERRLOG("rdma_get_devices() failed: %s (%d)\n", spdk_strerror(errno), errno);
nvmf_rdma_destroy(&rtransport->transport, NULL, NULL);
return NULL;
}
i = 0;
rc = 0;
while (contexts[i] != NULL) {
device = calloc(1, sizeof(*device));
if (!device) {
SPDK_ERRLOG("Unable to allocate memory for RDMA devices.\n");
rc = -ENOMEM;
break;
}
device->context = contexts[i];
rc = ibv_query_device(device->context, &device->attr);
if (rc < 0) {
SPDK_ERRLOG("Failed to query RDMA device attributes.\n");
free(device);
break;
}
max_device_sge = spdk_min(max_device_sge, device->attr.max_sge);
#ifdef SPDK_CONFIG_RDMA_SEND_WITH_INVAL
if ((device->attr.device_cap_flags & IBV_DEVICE_MEM_MGT_EXTENSIONS) == 0) {
SPDK_WARNLOG("The libibverbs on this system supports SEND_WITH_INVALIDATE,");
SPDK_WARNLOG("but the device with vendor ID %u does not.\n", device->attr.vendor_id);
}
/**
* The vendor ID is assigned by the IEEE and an ID of 0 implies Soft-RoCE.
* The Soft-RoCE RXE driver does not currently support send with invalidate,
* but incorrectly reports that it does. There are changes making their way
* through the kernel now that will enable this feature. When they are merged,
* we can conditionally enable this feature.
*
* TODO: enable this for versions of the kernel rxe driver that support it.
*/
if (nvmf_rdma_is_rxe_device(device)) {
device->attr.device_cap_flags &= ~(IBV_DEVICE_MEM_MGT_EXTENSIONS);
}
#endif
/* set up device context async ev fd as NON_BLOCKING */
flag = fcntl(device->context->async_fd, F_GETFL);
rc = fcntl(device->context->async_fd, F_SETFL, flag | O_NONBLOCK);
if (rc < 0) {
SPDK_ERRLOG("Failed to set context async fd to NONBLOCK.\n");
free(device);
break;
}
TAILQ_INSERT_TAIL(&rtransport->devices, device, link);
i++;
if (g_nvmf_hooks.get_ibv_pd) {
device->pd = g_nvmf_hooks.get_ibv_pd(NULL, device->context);
} else {
device->pd = ibv_alloc_pd(device->context);
}
if (!device->pd) {
SPDK_ERRLOG("Unable to allocate protection domain.\n");
rc = -ENOMEM;
break;
}
assert(device->map == NULL);
device->map = spdk_rdma_create_mem_map(device->pd, &g_nvmf_hooks, SPDK_RDMA_MEMORY_MAP_ROLE_TARGET);
if (!device->map) {
SPDK_ERRLOG("Unable to allocate memory map for listen address\n");
rc = -ENOMEM;
break;
}
assert(device->map != NULL);
assert(device->pd != NULL);
}
rdma_free_devices(contexts);
if (opts->io_unit_size * max_device_sge < opts->max_io_size) {
/* divide and round up. */
opts->io_unit_size = (opts->max_io_size + max_device_sge - 1) / max_device_sge;
/* round up to the nearest 4k. */
opts->io_unit_size = (opts->io_unit_size + NVMF_DATA_BUFFER_ALIGNMENT - 1) & ~NVMF_DATA_BUFFER_MASK;
opts->io_unit_size = spdk_max(opts->io_unit_size, SPDK_NVMF_RDMA_MIN_IO_BUFFER_SIZE);
SPDK_NOTICELOG("Adjusting the io unit size to fit the device's maximum I/O size. New I/O unit size %u\n",
opts->io_unit_size);
}
if (rc < 0) {
nvmf_rdma_destroy(&rtransport->transport, NULL, NULL);
return NULL;
}
/* Set up poll descriptor array to monitor events from RDMA and IB
* in a single poll syscall
*/
rtransport->npoll_fds = i + 1;
i = 0;
rtransport->poll_fds = calloc(rtransport->npoll_fds, sizeof(struct pollfd));
if (rtransport->poll_fds == NULL) {
SPDK_ERRLOG("poll_fds allocation failed\n");
nvmf_rdma_destroy(&rtransport->transport, NULL, NULL);
return NULL;
}
rtransport->poll_fds[i].fd = rtransport->event_channel->fd;
rtransport->poll_fds[i++].events = POLLIN;
TAILQ_FOREACH_SAFE(device, &rtransport->devices, link, tmp) {
rtransport->poll_fds[i].fd = device->context->async_fd;
rtransport->poll_fds[i++].events = POLLIN;
}
rtransport->accept_poller = SPDK_POLLER_REGISTER(nvmf_rdma_accept, &rtransport->transport,
rtransport->transport.opts.acceptor_poll_rate);
if (!rtransport->accept_poller) {
nvmf_rdma_destroy(&rtransport->transport, NULL, NULL);
return NULL;
}
return &rtransport->transport;
}
static void
nvmf_rdma_dump_opts(struct spdk_nvmf_transport *transport, struct spdk_json_write_ctx *w)
{
struct spdk_nvmf_rdma_transport *rtransport;
assert(w != NULL);
rtransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_rdma_transport, transport);
spdk_json_write_named_uint32(w, "max_srq_depth", rtransport->rdma_opts.max_srq_depth);
spdk_json_write_named_bool(w, "no_srq", rtransport->rdma_opts.no_srq);
if (rtransport->rdma_opts.no_srq == true) {
spdk_json_write_named_int32(w, "num_cqe", rtransport->rdma_opts.num_cqe);
}
spdk_json_write_named_int32(w, "acceptor_backlog", rtransport->rdma_opts.acceptor_backlog);
spdk_json_write_named_bool(w, "no_wr_batching", rtransport->rdma_opts.no_wr_batching);
}
static int
nvmf_rdma_destroy(struct spdk_nvmf_transport *transport,
spdk_nvmf_transport_destroy_done_cb cb_fn, void *cb_arg)
{
struct spdk_nvmf_rdma_transport *rtransport;
struct spdk_nvmf_rdma_port *port, *port_tmp;
struct spdk_nvmf_rdma_device *device, *device_tmp;
rtransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_rdma_transport, transport);
TAILQ_FOREACH_SAFE(port, &rtransport->ports, link, port_tmp) {
TAILQ_REMOVE(&rtransport->ports, port, link);
rdma_destroy_id(port->id);
free(port);
}
if (rtransport->poll_fds != NULL) {
free(rtransport->poll_fds);
}
if (rtransport->event_channel != NULL) {
rdma_destroy_event_channel(rtransport->event_channel);
}
TAILQ_FOREACH_SAFE(device, &rtransport->devices, link, device_tmp) {
TAILQ_REMOVE(&rtransport->devices, device, link);
spdk_rdma_free_mem_map(&device->map);
if (device->pd) {
if (!g_nvmf_hooks.get_ibv_pd) {
ibv_dealloc_pd(device->pd);
}
}
free(device);
}
if (rtransport->data_wr_pool != NULL) {
if (spdk_mempool_count(rtransport->data_wr_pool) !=
(transport->opts.max_queue_depth * SPDK_NVMF_MAX_SGL_ENTRIES)) {
SPDK_ERRLOG("transport wr pool count is %zu but should be %u\n",
spdk_mempool_count(rtransport->data_wr_pool),
transport->opts.max_queue_depth * SPDK_NVMF_MAX_SGL_ENTRIES);
}
}
spdk_mempool_free(rtransport->data_wr_pool);
spdk_poller_unregister(&rtransport->accept_poller);
pthread_mutex_destroy(&rtransport->lock);
free(rtransport);
if (cb_fn) {
cb_fn(cb_arg);
}
return 0;
}
static int
nvmf_rdma_trid_from_cm_id(struct rdma_cm_id *id,
struct spdk_nvme_transport_id *trid,
bool peer);
static int
nvmf_rdma_listen(struct spdk_nvmf_transport *transport, const struct spdk_nvme_transport_id *trid,
struct spdk_nvmf_listen_opts *listen_opts)
{
struct spdk_nvmf_rdma_transport *rtransport;
struct spdk_nvmf_rdma_device *device;
struct spdk_nvmf_rdma_port *port;
struct addrinfo *res;
struct addrinfo hints;
int family;
int rc;
if (!strlen(trid->trsvcid)) {
SPDK_ERRLOG("Service id is required\n");
return -EINVAL;
}
rtransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_rdma_transport, transport);
assert(rtransport->event_channel != NULL);
pthread_mutex_lock(&rtransport->lock);
port = calloc(1, sizeof(*port));
if (!port) {
SPDK_ERRLOG("Port allocation failed\n");
pthread_mutex_unlock(&rtransport->lock);
return -ENOMEM;
}
port->trid = trid;
switch (trid->adrfam) {
case SPDK_NVMF_ADRFAM_IPV4:
family = AF_INET;
break;
case SPDK_NVMF_ADRFAM_IPV6:
family = AF_INET6;
break;
default:
SPDK_ERRLOG("Unhandled ADRFAM %d\n", trid->adrfam);
free(port);
pthread_mutex_unlock(&rtransport->lock);
return -EINVAL;
}
memset(&hints, 0, sizeof(hints));
hints.ai_family = family;
hints.ai_flags = AI_NUMERICSERV;
hints.ai_socktype = SOCK_STREAM;
hints.ai_protocol = 0;
rc = getaddrinfo(trid->traddr, trid->trsvcid, &hints, &res);
if (rc) {
SPDK_ERRLOG("getaddrinfo failed: %s (%d)\n", gai_strerror(rc), rc);
free(port);
pthread_mutex_unlock(&rtransport->lock);
return -EINVAL;
}
rc = rdma_create_id(rtransport->event_channel, &port->id, port, RDMA_PS_TCP);
if (rc < 0) {
SPDK_ERRLOG("rdma_create_id() failed\n");
freeaddrinfo(res);
free(port);
pthread_mutex_unlock(&rtransport->lock);
return rc;
}
rc = rdma_bind_addr(port->id, res->ai_addr);
freeaddrinfo(res);
if (rc < 0) {
SPDK_ERRLOG("rdma_bind_addr() failed\n");
rdma_destroy_id(port->id);
free(port);
pthread_mutex_unlock(&rtransport->lock);
return rc;
}
if (!port->id->verbs) {
SPDK_ERRLOG("ibv_context is null\n");
rdma_destroy_id(port->id);
free(port);
pthread_mutex_unlock(&rtransport->lock);
return -1;
}
rc = rdma_listen(port->id, rtransport->rdma_opts.acceptor_backlog);
if (rc < 0) {
SPDK_ERRLOG("rdma_listen() failed\n");
rdma_destroy_id(port->id);
free(port);
pthread_mutex_unlock(&rtransport->lock);
return rc;
}
TAILQ_FOREACH(device, &rtransport->devices, link) {
if (device->context == port->id->verbs) {
port->device = device;
break;
}
}
if (!port->device) {
SPDK_ERRLOG("Accepted a connection with verbs %p, but unable to find a corresponding device.\n",
port->id->verbs);
rdma_destroy_id(port->id);
free(port);
pthread_mutex_unlock(&rtransport->lock);
return -EINVAL;
}
SPDK_NOTICELOG("*** NVMe/RDMA Target Listening on %s port %s ***\n",
trid->traddr, trid->trsvcid);
TAILQ_INSERT_TAIL(&rtransport->ports, port, link);
pthread_mutex_unlock(&rtransport->lock);
return 0;
}
static void
nvmf_rdma_stop_listen(struct spdk_nvmf_transport *transport,
const struct spdk_nvme_transport_id *trid)
{
struct spdk_nvmf_rdma_transport *rtransport;
struct spdk_nvmf_rdma_port *port, *tmp;
rtransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_rdma_transport, transport);
pthread_mutex_lock(&rtransport->lock);
TAILQ_FOREACH_SAFE(port, &rtransport->ports, link, tmp) {
if (spdk_nvme_transport_id_compare(port->trid, trid) == 0) {
TAILQ_REMOVE(&rtransport->ports, port, link);
rdma_destroy_id(port->id);
free(port);
break;
}
}
pthread_mutex_unlock(&rtransport->lock);
}
static void
nvmf_rdma_qpair_process_pending(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_qpair *rqpair, bool drain)
{
struct spdk_nvmf_request *req, *tmp;
struct spdk_nvmf_rdma_request *rdma_req, *req_tmp;
struct spdk_nvmf_rdma_resources *resources;
/* We process I/O in the data transfer pending queue at the highest priority. RDMA reads first */
STAILQ_FOREACH_SAFE(rdma_req, &rqpair->pending_rdma_read_queue, state_link, req_tmp) {
if (nvmf_rdma_request_process(rtransport, rdma_req) == false && drain == false) {
break;
}
}
/* Then RDMA writes since reads have stronger restrictions than writes */
STAILQ_FOREACH_SAFE(rdma_req, &rqpair->pending_rdma_write_queue, state_link, req_tmp) {
if (nvmf_rdma_request_process(rtransport, rdma_req) == false && drain == false) {
break;
}
}
/* Then we handle request waiting on memory buffers. */
STAILQ_FOREACH_SAFE(req, &rqpair->poller->group->group.pending_buf_queue, buf_link, tmp) {
rdma_req = SPDK_CONTAINEROF(req, struct spdk_nvmf_rdma_request, req);
if (nvmf_rdma_request_process(rtransport, rdma_req) == false && drain == false) {
break;
}
}
resources = rqpair->resources;
while (!STAILQ_EMPTY(&resources->free_queue) && !STAILQ_EMPTY(&resources->incoming_queue)) {
rdma_req = STAILQ_FIRST(&resources->free_queue);
STAILQ_REMOVE_HEAD(&resources->free_queue, state_link);
rdma_req->recv = STAILQ_FIRST(&resources->incoming_queue);
STAILQ_REMOVE_HEAD(&resources->incoming_queue, link);
if (rqpair->srq != NULL) {
rdma_req->req.qpair = &rdma_req->recv->qpair->qpair;
rdma_req->recv->qpair->qd++;
} else {
rqpair->qd++;
}
rdma_req->receive_tsc = rdma_req->recv->receive_tsc;
rdma_req->state = RDMA_REQUEST_STATE_NEW;
if (nvmf_rdma_request_process(rtransport, rdma_req) == false) {
break;
}
}
if (!STAILQ_EMPTY(&resources->incoming_queue) && STAILQ_EMPTY(&resources->free_queue)) {
rqpair->poller->stat.pending_free_request++;
}
}
static inline bool
nvmf_rdma_can_ignore_last_wqe_reached(struct spdk_nvmf_rdma_device *device)
{
/* iWARP transport and SoftRoCE driver don't support LAST_WQE_REACHED ibv async event */
return nvmf_rdma_is_rxe_device(device) ||
device->context->device->transport_type == IBV_TRANSPORT_IWARP;
}
static void
nvmf_rdma_destroy_drained_qpair(struct spdk_nvmf_rdma_qpair *rqpair)
{
struct spdk_nvmf_rdma_transport *rtransport = SPDK_CONTAINEROF(rqpair->qpair.transport,
struct spdk_nvmf_rdma_transport, transport);
nvmf_rdma_qpair_process_pending(rtransport, rqpair, true);
/* nvmr_rdma_close_qpair is not called */
if (!rqpair->to_close) {
return;
}
/* In non SRQ path, we will reach rqpair->max_queue_depth. In SRQ path, we will get the last_wqe event. */
if (rqpair->current_send_depth != 0) {
return;
}
if (rqpair->srq == NULL && rqpair->current_recv_depth != rqpair->max_queue_depth) {
return;
}
if (rqpair->srq != NULL && rqpair->last_wqe_reached == false &&
!nvmf_rdma_can_ignore_last_wqe_reached(rqpair->device)) {
return;
}
assert(rqpair->qpair.state == SPDK_NVMF_QPAIR_ERROR);
nvmf_rdma_qpair_destroy(rqpair);
}
static int
nvmf_rdma_disconnect(struct rdma_cm_event *evt)
{
struct spdk_nvmf_qpair *qpair;
struct spdk_nvmf_rdma_qpair *rqpair;
if (evt->id == NULL) {
SPDK_ERRLOG("disconnect request: missing cm_id\n");
return -1;
}
qpair = evt->id->context;
if (qpair == NULL) {
SPDK_ERRLOG("disconnect request: no active connection\n");
return -1;
}
rqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_rdma_qpair, qpair);
spdk_trace_record(TRACE_RDMA_QP_DISCONNECT, 0, 0, (uintptr_t)rqpair);
spdk_nvmf_qpair_disconnect(&rqpair->qpair, NULL, NULL);
return 0;
}
#ifdef DEBUG
static const char *CM_EVENT_STR[] = {
"RDMA_CM_EVENT_ADDR_RESOLVED",
"RDMA_CM_EVENT_ADDR_ERROR",
"RDMA_CM_EVENT_ROUTE_RESOLVED",
"RDMA_CM_EVENT_ROUTE_ERROR",
"RDMA_CM_EVENT_CONNECT_REQUEST",
"RDMA_CM_EVENT_CONNECT_RESPONSE",
"RDMA_CM_EVENT_CONNECT_ERROR",
"RDMA_CM_EVENT_UNREACHABLE",
"RDMA_CM_EVENT_REJECTED",
"RDMA_CM_EVENT_ESTABLISHED",
"RDMA_CM_EVENT_DISCONNECTED",
"RDMA_CM_EVENT_DEVICE_REMOVAL",
"RDMA_CM_EVENT_MULTICAST_JOIN",
"RDMA_CM_EVENT_MULTICAST_ERROR",
"RDMA_CM_EVENT_ADDR_CHANGE",
"RDMA_CM_EVENT_TIMEWAIT_EXIT"
};
#endif /* DEBUG */
static void
nvmf_rdma_disconnect_qpairs_on_port(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_port *port)
{
struct spdk_nvmf_rdma_poll_group *rgroup;
struct spdk_nvmf_rdma_poller *rpoller;
struct spdk_nvmf_rdma_qpair *rqpair;
TAILQ_FOREACH(rgroup, &rtransport->poll_groups, link) {
TAILQ_FOREACH(rpoller, &rgroup->pollers, link) {
TAILQ_FOREACH(rqpair, &rpoller->qpairs, link) {
if (rqpair->listen_id == port->id) {
spdk_nvmf_qpair_disconnect(&rqpair->qpair, NULL, NULL);
}
}
}
}
}
static bool
nvmf_rdma_handle_cm_event_addr_change(struct spdk_nvmf_transport *transport,
struct rdma_cm_event *event)
{
const struct spdk_nvme_transport_id *trid;
struct spdk_nvmf_rdma_port *port;
struct spdk_nvmf_rdma_transport *rtransport;
bool event_acked = false;
rtransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_rdma_transport, transport);
TAILQ_FOREACH(port, &rtransport->ports, link) {
if (port->id == event->id) {
SPDK_ERRLOG("ADDR_CHANGE: IP %s:%s migrated\n", port->trid->traddr, port->trid->trsvcid);
rdma_ack_cm_event(event);
event_acked = true;
trid = port->trid;
break;
}
}
if (event_acked) {
nvmf_rdma_disconnect_qpairs_on_port(rtransport, port);
nvmf_rdma_stop_listen(transport, trid);
nvmf_rdma_listen(transport, trid, NULL);
}
return event_acked;
}
static void
nvmf_rdma_handle_cm_event_port_removal(struct spdk_nvmf_transport *transport,
struct rdma_cm_event *event)
{
struct spdk_nvmf_rdma_port *port;
struct spdk_nvmf_rdma_transport *rtransport;
port = event->id->context;
rtransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_rdma_transport, transport);
SPDK_NOTICELOG("Port %s:%s is being removed\n", port->trid->traddr, port->trid->trsvcid);
nvmf_rdma_disconnect_qpairs_on_port(rtransport, port);
rdma_ack_cm_event(event);
while (spdk_nvmf_transport_stop_listen(transport, port->trid) == 0) {
;
}
}
static void
nvmf_process_cm_event(struct spdk_nvmf_transport *transport)
{
struct spdk_nvmf_rdma_transport *rtransport;
struct rdma_cm_event *event;
int rc;
bool event_acked;
rtransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_rdma_transport, transport);
if (rtransport->event_channel == NULL) {
return;
}
while (1) {
event_acked = false;
rc = rdma_get_cm_event(rtransport->event_channel, &event);
if (rc) {
if (errno != EAGAIN && errno != EWOULDBLOCK) {
SPDK_ERRLOG("Acceptor Event Error: %s\n", spdk_strerror(errno));
}
break;
}
SPDK_DEBUGLOG(rdma, "Acceptor Event: %s\n", CM_EVENT_STR[event->event]);
spdk_trace_record(TRACE_RDMA_CM_ASYNC_EVENT, 0, 0, 0, event->event);
switch (event->event) {
case RDMA_CM_EVENT_ADDR_RESOLVED:
case RDMA_CM_EVENT_ADDR_ERROR:
case RDMA_CM_EVENT_ROUTE_RESOLVED:
case RDMA_CM_EVENT_ROUTE_ERROR:
/* No action required. The target never attempts to resolve routes. */
break;
case RDMA_CM_EVENT_CONNECT_REQUEST:
rc = nvmf_rdma_connect(transport, event);
if (rc < 0) {
SPDK_ERRLOG("Unable to process connect event. rc: %d\n", rc);
break;
}
break;
case RDMA_CM_EVENT_CONNECT_RESPONSE:
/* The target never initiates a new connection. So this will not occur. */
break;
case RDMA_CM_EVENT_CONNECT_ERROR:
/* Can this happen? The docs say it can, but not sure what causes it. */
break;
case RDMA_CM_EVENT_UNREACHABLE:
case RDMA_CM_EVENT_REJECTED:
/* These only occur on the client side. */
break;
case RDMA_CM_EVENT_ESTABLISHED:
/* TODO: Should we be waiting for this event anywhere? */
break;
case RDMA_CM_EVENT_DISCONNECTED:
rc = nvmf_rdma_disconnect(event);
if (rc < 0) {
SPDK_ERRLOG("Unable to process disconnect event. rc: %d\n", rc);
break;
}
break;
case RDMA_CM_EVENT_DEVICE_REMOVAL:
/* In case of device removal, kernel IB part triggers IBV_EVENT_DEVICE_FATAL
* which triggers RDMA_CM_EVENT_DEVICE_REMOVAL on all cma_ids.
* Once these events are sent to SPDK, we should release all IB resources and
* don't make attempts to call any ibv_query/modify/create functions. We can only call
* ibv_destroy* functions to release user space memory allocated by IB. All kernel
* resources are already cleaned. */
if (event->id->qp) {
/* If rdma_cm event has a valid `qp` pointer then the event refers to the
* corresponding qpair. Otherwise the event refers to a listening device */
rc = nvmf_rdma_disconnect(event);
if (rc < 0) {
SPDK_ERRLOG("Unable to process disconnect event. rc: %d\n", rc);
break;
}
} else {
nvmf_rdma_handle_cm_event_port_removal(transport, event);
event_acked = true;
}
break;
case RDMA_CM_EVENT_MULTICAST_JOIN:
case RDMA_CM_EVENT_MULTICAST_ERROR:
/* Multicast is not used */
break;
case RDMA_CM_EVENT_ADDR_CHANGE:
event_acked = nvmf_rdma_handle_cm_event_addr_change(transport, event);
break;
case RDMA_CM_EVENT_TIMEWAIT_EXIT:
/* For now, do nothing. The target never re-uses queue pairs. */
break;
default:
SPDK_ERRLOG("Unexpected Acceptor Event [%d]\n", event->event);
break;
}
if (!event_acked) {
rdma_ack_cm_event(event);
}
}
}
static void
nvmf_rdma_handle_last_wqe_reached(struct spdk_nvmf_rdma_qpair *rqpair)
{
rqpair->last_wqe_reached = true;
nvmf_rdma_destroy_drained_qpair(rqpair);
}
static void
nvmf_rdma_qpair_process_ibv_event(void *ctx)
{
struct spdk_nvmf_rdma_ibv_event_ctx *event_ctx = ctx;
if (event_ctx->rqpair) {
STAILQ_REMOVE(&event_ctx->rqpair->ibv_events, event_ctx, spdk_nvmf_rdma_ibv_event_ctx, link);
if (event_ctx->cb_fn) {
event_ctx->cb_fn(event_ctx->rqpair);
}
}
free(event_ctx);
}
static int
nvmf_rdma_send_qpair_async_event(struct spdk_nvmf_rdma_qpair *rqpair,
spdk_nvmf_rdma_qpair_ibv_event fn)
{
struct spdk_nvmf_rdma_ibv_event_ctx *ctx;
struct spdk_thread *thr = NULL;
int rc;
if (rqpair->qpair.group) {
thr = rqpair->qpair.group->thread;
} else if (rqpair->destruct_channel) {
thr = spdk_io_channel_get_thread(rqpair->destruct_channel);
}
if (!thr) {
SPDK_DEBUGLOG(rdma, "rqpair %p has no thread\n", rqpair);
return -EINVAL;
}
ctx = calloc(1, sizeof(*ctx));
if (!ctx) {
return -ENOMEM;
}
ctx->rqpair = rqpair;
ctx->cb_fn = fn;
STAILQ_INSERT_TAIL(&rqpair->ibv_events, ctx, link);
rc = spdk_thread_send_msg(thr, nvmf_rdma_qpair_process_ibv_event, ctx);
if (rc) {
STAILQ_REMOVE(&rqpair->ibv_events, ctx, spdk_nvmf_rdma_ibv_event_ctx, link);
free(ctx);
}
return rc;
}
static int
nvmf_process_ib_event(struct spdk_nvmf_rdma_device *device)
{
int rc;
struct spdk_nvmf_rdma_qpair *rqpair = NULL;
struct ibv_async_event event;
rc = ibv_get_async_event(device->context, &event);
if (rc) {
/* In non-blocking mode -1 means there are no events available */
return rc;
}
switch (event.event_type) {
case IBV_EVENT_QP_FATAL:
rqpair = event.element.qp->qp_context;
SPDK_ERRLOG("Fatal event received for rqpair %p\n", rqpair);
spdk_trace_record(TRACE_RDMA_IBV_ASYNC_EVENT, 0, 0,
(uintptr_t)rqpair, event.event_type);
nvmf_rdma_update_ibv_state(rqpair);
spdk_nvmf_qpair_disconnect(&rqpair->qpair, NULL, NULL);
break;
case IBV_EVENT_QP_LAST_WQE_REACHED:
/* This event only occurs for shared receive queues. */
rqpair = event.element.qp->qp_context;
SPDK_DEBUGLOG(rdma, "Last WQE reached event received for rqpair %p\n", rqpair);
rc = nvmf_rdma_send_qpair_async_event(rqpair, nvmf_rdma_handle_last_wqe_reached);
if (rc) {
SPDK_WARNLOG("Failed to send LAST_WQE_REACHED event. rqpair %p, err %d\n", rqpair, rc);
rqpair->last_wqe_reached = true;
}
break;
case IBV_EVENT_SQ_DRAINED:
/* This event occurs frequently in both error and non-error states.
* Check if the qpair is in an error state before sending a message. */
rqpair = event.element.qp->qp_context;
SPDK_DEBUGLOG(rdma, "Last sq drained event received for rqpair %p\n", rqpair);
spdk_trace_record(TRACE_RDMA_IBV_ASYNC_EVENT, 0, 0,
(uintptr_t)rqpair, event.event_type);
if (nvmf_rdma_update_ibv_state(rqpair) == IBV_QPS_ERR) {
spdk_nvmf_qpair_disconnect(&rqpair->qpair, NULL, NULL);
}
break;
case IBV_EVENT_QP_REQ_ERR:
case IBV_EVENT_QP_ACCESS_ERR:
case IBV_EVENT_COMM_EST:
case IBV_EVENT_PATH_MIG:
case IBV_EVENT_PATH_MIG_ERR:
SPDK_NOTICELOG("Async event: %s\n",
ibv_event_type_str(event.event_type));
rqpair = event.element.qp->qp_context;
spdk_trace_record(TRACE_RDMA_IBV_ASYNC_EVENT, 0, 0,
(uintptr_t)rqpair, event.event_type);
nvmf_rdma_update_ibv_state(rqpair);
break;
case IBV_EVENT_CQ_ERR:
case IBV_EVENT_DEVICE_FATAL:
case IBV_EVENT_PORT_ACTIVE:
case IBV_EVENT_PORT_ERR:
case IBV_EVENT_LID_CHANGE:
case IBV_EVENT_PKEY_CHANGE:
case IBV_EVENT_SM_CHANGE:
case IBV_EVENT_SRQ_ERR:
case IBV_EVENT_SRQ_LIMIT_REACHED:
case IBV_EVENT_CLIENT_REREGISTER:
case IBV_EVENT_GID_CHANGE:
default:
SPDK_NOTICELOG("Async event: %s\n",
ibv_event_type_str(event.event_type));
spdk_trace_record(TRACE_RDMA_IBV_ASYNC_EVENT, 0, 0, 0, event.event_type);
break;
}
ibv_ack_async_event(&event);
return 0;
}
static void
nvmf_process_ib_events(struct spdk_nvmf_rdma_device *device, uint32_t max_events)
{
int rc = 0;
uint32_t i = 0;
for (i = 0; i < max_events; i++) {
rc = nvmf_process_ib_event(device);
if (rc) {
break;
}
}
SPDK_DEBUGLOG(rdma, "Device %s: %u events processed\n", device->context->device->name, i);
}
static int
nvmf_rdma_accept(void *ctx)
{
int nfds, i = 0;
struct spdk_nvmf_transport *transport = ctx;
struct spdk_nvmf_rdma_transport *rtransport;
struct spdk_nvmf_rdma_device *device, *tmp;
uint32_t count;
rtransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_rdma_transport, transport);
count = nfds = poll(rtransport->poll_fds, rtransport->npoll_fds, 0);
if (nfds <= 0) {
return SPDK_POLLER_IDLE;
}
/* The first poll descriptor is RDMA CM event */
if (rtransport->poll_fds[i++].revents & POLLIN) {
nvmf_process_cm_event(transport);
nfds--;
}
if (nfds == 0) {
return SPDK_POLLER_BUSY;
}
/* Second and subsequent poll descriptors are IB async events */
TAILQ_FOREACH_SAFE(device, &rtransport->devices, link, tmp) {
if (rtransport->poll_fds[i++].revents & POLLIN) {
nvmf_process_ib_events(device, 32);
nfds--;
}
}
/* check all flagged fd's have been served */
assert(nfds == 0);
return count > 0 ? SPDK_POLLER_BUSY : SPDK_POLLER_IDLE;
}
static void
nvmf_rdma_cdata_init(struct spdk_nvmf_transport *transport, struct spdk_nvmf_subsystem *subsystem,
struct spdk_nvmf_ctrlr_data *cdata)
{
cdata->nvmf_specific.msdbd = SPDK_NVMF_MAX_SGL_ENTRIES;
/* Disable in-capsule data transfer for RDMA controller when dif_insert_or_strip is enabled
since in-capsule data only works with NVME drives that support SGL memory layout */
if (transport->opts.dif_insert_or_strip) {
cdata->nvmf_specific.ioccsz = sizeof(struct spdk_nvme_cmd) / 16;
}
if (cdata->nvmf_specific.ioccsz > ((sizeof(struct spdk_nvme_cmd) + 0x1000) / 16)) {
SPDK_WARNLOG("RDMA is configured to support up to 16 SGL entries while in capsule"
" data is greater than 4KiB.\n");
SPDK_WARNLOG("When used in conjunction with the NVMe-oF initiator from the Linux "
"kernel between versions 5.4 and 5.12 data corruption may occur for "
"writes that are not a multiple of 4KiB in size.\n");
}
}
static void
nvmf_rdma_discover(struct spdk_nvmf_transport *transport,
struct spdk_nvme_transport_id *trid,
struct spdk_nvmf_discovery_log_page_entry *entry)
{
entry->trtype = SPDK_NVMF_TRTYPE_RDMA;
entry->adrfam = trid->adrfam;
entry->treq.secure_channel = SPDK_NVMF_TREQ_SECURE_CHANNEL_NOT_REQUIRED;
spdk_strcpy_pad(entry->trsvcid, trid->trsvcid, sizeof(entry->trsvcid), ' ');
spdk_strcpy_pad(entry->traddr, trid->traddr, sizeof(entry->traddr), ' ');
entry->tsas.rdma.rdma_qptype = SPDK_NVMF_RDMA_QPTYPE_RELIABLE_CONNECTED;
entry->tsas.rdma.rdma_prtype = SPDK_NVMF_RDMA_PRTYPE_NONE;
entry->tsas.rdma.rdma_cms = SPDK_NVMF_RDMA_CMS_RDMA_CM;
}
static void
nvmf_rdma_poll_group_destroy(struct spdk_nvmf_transport_poll_group *group);
static struct spdk_nvmf_transport_poll_group *
nvmf_rdma_poll_group_create(struct spdk_nvmf_transport *transport)
{
struct spdk_nvmf_rdma_transport *rtransport;
struct spdk_nvmf_rdma_poll_group *rgroup;
struct spdk_nvmf_rdma_poller *poller;
struct spdk_nvmf_rdma_device *device;
struct spdk_rdma_srq_init_attr srq_init_attr;
struct spdk_nvmf_rdma_resource_opts opts;
int num_cqe;
rtransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_rdma_transport, transport);
rgroup = calloc(1, sizeof(*rgroup));
if (!rgroup) {
return NULL;
}
TAILQ_INIT(&rgroup->pollers);
pthread_mutex_lock(&rtransport->lock);
TAILQ_FOREACH(device, &rtransport->devices, link) {
poller = calloc(1, sizeof(*poller));
if (!poller) {
SPDK_ERRLOG("Unable to allocate memory for new RDMA poller\n");
nvmf_rdma_poll_group_destroy(&rgroup->group);
pthread_mutex_unlock(&rtransport->lock);
return NULL;
}
poller->device = device;
poller->group = rgroup;
TAILQ_INIT(&poller->qpairs);
STAILQ_INIT(&poller->qpairs_pending_send);
STAILQ_INIT(&poller->qpairs_pending_recv);
TAILQ_INSERT_TAIL(&rgroup->pollers, poller, link);
if (rtransport->rdma_opts.no_srq == false && device->num_srq < device->attr.max_srq) {
if ((int)rtransport->rdma_opts.max_srq_depth > device->attr.max_srq_wr) {
SPDK_WARNLOG("Requested SRQ depth %u, max supported by dev %s is %d\n",
rtransport->rdma_opts.max_srq_depth, device->context->device->name, device->attr.max_srq_wr);
}
poller->max_srq_depth = spdk_min((int)rtransport->rdma_opts.max_srq_depth, device->attr.max_srq_wr);
device->num_srq++;
memset(&srq_init_attr, 0, sizeof(srq_init_attr));
srq_init_attr.pd = device->pd;
srq_init_attr.stats = &poller->stat.qp_stats.recv;
srq_init_attr.srq_init_attr.attr.max_wr = poller->max_srq_depth;
srq_init_attr.srq_init_attr.attr.max_sge = spdk_min(device->attr.max_sge, NVMF_DEFAULT_RX_SGE);
poller->srq = spdk_rdma_srq_create(&srq_init_attr);
if (!poller->srq) {
SPDK_ERRLOG("Unable to create shared receive queue, errno %d\n", errno);
nvmf_rdma_poll_group_destroy(&rgroup->group);
pthread_mutex_unlock(&rtransport->lock);
return NULL;
}
opts.qp = poller->srq;
opts.pd = device->pd;
opts.qpair = NULL;
opts.shared = true;
opts.max_queue_depth = poller->max_srq_depth;
opts.in_capsule_data_size = transport->opts.in_capsule_data_size;
poller->resources = nvmf_rdma_resources_create(&opts);
if (!poller->resources) {
SPDK_ERRLOG("Unable to allocate resources for shared receive queue.\n");
nvmf_rdma_poll_group_destroy(&rgroup->group);
pthread_mutex_unlock(&rtransport->lock);
return NULL;
}
}
/*
* When using an srq, we can limit the completion queue at startup.
* The following formula represents the calculation:
* num_cqe = num_recv + num_data_wr + num_send_wr.
* where num_recv=num_data_wr=and num_send_wr=poller->max_srq_depth
*/
if (poller->srq) {
num_cqe = poller->max_srq_depth * 3;
} else {
num_cqe = rtransport->rdma_opts.num_cqe;
}
poller->cq = ibv_create_cq(device->context, num_cqe, poller, NULL, 0);
if (!poller->cq) {
SPDK_ERRLOG("Unable to create completion queue\n");
nvmf_rdma_poll_group_destroy(&rgroup->group);
pthread_mutex_unlock(&rtransport->lock);
return NULL;
}
poller->num_cqe = num_cqe;
}
TAILQ_INSERT_TAIL(&rtransport->poll_groups, rgroup, link);
if (rtransport->conn_sched.next_admin_pg == NULL) {
rtransport->conn_sched.next_admin_pg = rgroup;
rtransport->conn_sched.next_io_pg = rgroup;
}
pthread_mutex_unlock(&rtransport->lock);
return &rgroup->group;
}
static struct spdk_nvmf_transport_poll_group *
nvmf_rdma_get_optimal_poll_group(struct spdk_nvmf_qpair *qpair)
{
struct spdk_nvmf_rdma_transport *rtransport;
struct spdk_nvmf_rdma_poll_group **pg;
struct spdk_nvmf_transport_poll_group *result;
rtransport = SPDK_CONTAINEROF(qpair->transport, struct spdk_nvmf_rdma_transport, transport);
pthread_mutex_lock(&rtransport->lock);
if (TAILQ_EMPTY(&rtransport->poll_groups)) {
pthread_mutex_unlock(&rtransport->lock);
return NULL;
}
if (qpair->qid == 0) {
pg = &rtransport->conn_sched.next_admin_pg;
} else {
pg = &rtransport->conn_sched.next_io_pg;
}
assert(*pg != NULL);
result = &(*pg)->group;
*pg = TAILQ_NEXT(*pg, link);
if (*pg == NULL) {
*pg = TAILQ_FIRST(&rtransport->poll_groups);
}
pthread_mutex_unlock(&rtransport->lock);
return result;
}
static void
nvmf_rdma_poll_group_destroy(struct spdk_nvmf_transport_poll_group *group)
{
struct spdk_nvmf_rdma_poll_group *rgroup, *next_rgroup;
struct spdk_nvmf_rdma_poller *poller, *tmp;
struct spdk_nvmf_rdma_qpair *qpair, *tmp_qpair;
struct spdk_nvmf_rdma_transport *rtransport;
rgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_rdma_poll_group, group);
if (!rgroup) {
return;
}
TAILQ_FOREACH_SAFE(poller, &rgroup->pollers, link, tmp) {
TAILQ_REMOVE(&rgroup->pollers, poller, link);
TAILQ_FOREACH_SAFE(qpair, &poller->qpairs, link, tmp_qpair) {
nvmf_rdma_qpair_destroy(qpair);
}
if (poller->srq) {
if (poller->resources) {
nvmf_rdma_resources_destroy(poller->resources);
}
spdk_rdma_srq_destroy(poller->srq);
SPDK_DEBUGLOG(rdma, "Destroyed RDMA shared queue %p\n", poller->srq);
}
if (poller->cq) {
ibv_destroy_cq(poller->cq);
}
free(poller);
}
if (rgroup->group.transport == NULL) {
/* Transport can be NULL when nvmf_rdma_poll_group_create()
* calls this function directly in a failure path. */
free(rgroup);
return;
}
rtransport = SPDK_CONTAINEROF(rgroup->group.transport, struct spdk_nvmf_rdma_transport, transport);
pthread_mutex_lock(&rtransport->lock);
next_rgroup = TAILQ_NEXT(rgroup, link);
TAILQ_REMOVE(&rtransport->poll_groups, rgroup, link);
if (next_rgroup == NULL) {
next_rgroup = TAILQ_FIRST(&rtransport->poll_groups);
}
if (rtransport->conn_sched.next_admin_pg == rgroup) {
rtransport->conn_sched.next_admin_pg = next_rgroup;
}
if (rtransport->conn_sched.next_io_pg == rgroup) {
rtransport->conn_sched.next_io_pg = next_rgroup;
}
pthread_mutex_unlock(&rtransport->lock);
free(rgroup);
}
static void
nvmf_rdma_qpair_reject_connection(struct spdk_nvmf_rdma_qpair *rqpair)
{
if (rqpair->cm_id != NULL) {
nvmf_rdma_event_reject(rqpair->cm_id, SPDK_NVMF_RDMA_ERROR_NO_RESOURCES);
}
}
static int
nvmf_rdma_poll_group_add(struct spdk_nvmf_transport_poll_group *group,
struct spdk_nvmf_qpair *qpair)
{
struct spdk_nvmf_rdma_poll_group *rgroup;
struct spdk_nvmf_rdma_qpair *rqpair;
struct spdk_nvmf_rdma_device *device;
struct spdk_nvmf_rdma_poller *poller;
int rc;
rgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_rdma_poll_group, group);
rqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_rdma_qpair, qpair);
device = rqpair->device;
TAILQ_FOREACH(poller, &rgroup->pollers, link) {
if (poller->device == device) {
break;
}
}
if (!poller) {
SPDK_ERRLOG("No poller found for device.\n");
return -1;
}
TAILQ_INSERT_TAIL(&poller->qpairs, rqpair, link);
rqpair->poller = poller;
rqpair->srq = rqpair->poller->srq;
rc = nvmf_rdma_qpair_initialize(qpair);
if (rc < 0) {
SPDK_ERRLOG("Failed to initialize nvmf_rdma_qpair with qpair=%p\n", qpair);
return -1;
}
rc = nvmf_rdma_event_accept(rqpair->cm_id, rqpair);
if (rc) {
/* Try to reject, but we probably can't */
nvmf_rdma_qpair_reject_connection(rqpair);
return -1;
}
nvmf_rdma_update_ibv_state(rqpair);
return 0;
}
static int
nvmf_rdma_poll_group_remove(struct spdk_nvmf_transport_poll_group *group,
struct spdk_nvmf_qpair *qpair)
{
struct spdk_nvmf_rdma_qpair *rqpair;
rqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_rdma_qpair, qpair);
assert(group->transport->tgt != NULL);
rqpair->destruct_channel = spdk_get_io_channel(group->transport->tgt);
if (!rqpair->destruct_channel) {
SPDK_WARNLOG("failed to get io_channel, qpair %p\n", qpair);
return 0;
}
/* Sanity check that we get io_channel on the correct thread */
if (qpair->group) {
assert(qpair->group->thread == spdk_io_channel_get_thread(rqpair->destruct_channel));
}
return 0;
}
static int
nvmf_rdma_request_free(struct spdk_nvmf_request *req)
{
struct spdk_nvmf_rdma_request *rdma_req = SPDK_CONTAINEROF(req, struct spdk_nvmf_rdma_request, req);
struct spdk_nvmf_rdma_transport *rtransport = SPDK_CONTAINEROF(req->qpair->transport,
struct spdk_nvmf_rdma_transport, transport);
struct spdk_nvmf_rdma_qpair *rqpair = SPDK_CONTAINEROF(rdma_req->req.qpair,
struct spdk_nvmf_rdma_qpair, qpair);
/*
* AER requests are freed when a qpair is destroyed. The recv corresponding to that request
* needs to be returned to the shared receive queue or the poll group will eventually be
* starved of RECV structures.
*/
if (rqpair->srq && rdma_req->recv) {
int rc;
struct ibv_recv_wr *bad_recv_wr;
spdk_rdma_srq_queue_recv_wrs(rqpair->srq, &rdma_req->recv->wr);
rc = spdk_rdma_srq_flush_recv_wrs(rqpair->srq, &bad_recv_wr);
if (rc) {
SPDK_ERRLOG("Unable to re-post rx descriptor\n");
}
}
_nvmf_rdma_request_free(rdma_req, rtransport);
return 0;
}
static int
nvmf_rdma_request_complete(struct spdk_nvmf_request *req)
{
struct spdk_nvmf_rdma_transport *rtransport = SPDK_CONTAINEROF(req->qpair->transport,
struct spdk_nvmf_rdma_transport, transport);
struct spdk_nvmf_rdma_request *rdma_req = SPDK_CONTAINEROF(req,
struct spdk_nvmf_rdma_request, req);
struct spdk_nvmf_rdma_qpair *rqpair = SPDK_CONTAINEROF(rdma_req->req.qpair,
struct spdk_nvmf_rdma_qpair, qpair);
if (rqpair->ibv_state != IBV_QPS_ERR) {
/* The connection is alive, so process the request as normal */
rdma_req->state = RDMA_REQUEST_STATE_EXECUTED;
} else {
/* The connection is dead. Move the request directly to the completed state. */
rdma_req->state = RDMA_REQUEST_STATE_COMPLETED;
}
nvmf_rdma_request_process(rtransport, rdma_req);
return 0;
}
static void
nvmf_rdma_close_qpair(struct spdk_nvmf_qpair *qpair,
spdk_nvmf_transport_qpair_fini_cb cb_fn, void *cb_arg)
{
struct spdk_nvmf_rdma_qpair *rqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_rdma_qpair, qpair);
rqpair->to_close = true;
/* This happens only when the qpair is disconnected before
* it is added to the poll group. Since there is no poll group,
* the RDMA qp has not been initialized yet and the RDMA CM
* event has not yet been acknowledged, so we need to reject it.
*/
if (rqpair->qpair.state == SPDK_NVMF_QPAIR_UNINITIALIZED) {
nvmf_rdma_qpair_reject_connection(rqpair);
nvmf_rdma_qpair_destroy(rqpair);
return;
}
if (rqpair->rdma_qp) {
spdk_rdma_qp_disconnect(rqpair->rdma_qp);
}
nvmf_rdma_destroy_drained_qpair(rqpair);
if (cb_fn) {
cb_fn(cb_arg);
}
}
static struct spdk_nvmf_rdma_qpair *
get_rdma_qpair_from_wc(struct spdk_nvmf_rdma_poller *rpoller, struct ibv_wc *wc)
{
struct spdk_nvmf_rdma_qpair *rqpair;
/* @todo: improve QP search */
TAILQ_FOREACH(rqpair, &rpoller->qpairs, link) {
if (wc->qp_num == rqpair->rdma_qp->qp->qp_num) {
return rqpair;
}
}
SPDK_ERRLOG("Didn't find QP with qp_num %u\n", wc->qp_num);
return NULL;
}
#ifdef DEBUG
static int
nvmf_rdma_req_is_completing(struct spdk_nvmf_rdma_request *rdma_req)
{
return rdma_req->state == RDMA_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST ||
rdma_req->state == RDMA_REQUEST_STATE_COMPLETING;
}
#endif
static void
_poller_reset_failed_recvs(struct spdk_nvmf_rdma_poller *rpoller, struct ibv_recv_wr *bad_recv_wr,
int rc)
{
struct spdk_nvmf_rdma_recv *rdma_recv;
struct spdk_nvmf_rdma_wr *bad_rdma_wr;
SPDK_ERRLOG("Failed to post a recv for the poller %p with errno %d\n", rpoller, -rc);
while (bad_recv_wr != NULL) {
bad_rdma_wr = (struct spdk_nvmf_rdma_wr *)bad_recv_wr->wr_id;
rdma_recv = SPDK_CONTAINEROF(bad_rdma_wr, struct spdk_nvmf_rdma_recv, rdma_wr);
rdma_recv->qpair->current_recv_depth++;
bad_recv_wr = bad_recv_wr->next;
SPDK_ERRLOG("Failed to post a recv for the qpair %p with errno %d\n", rdma_recv->qpair, -rc);
spdk_nvmf_qpair_disconnect(&rdma_recv->qpair->qpair, NULL, NULL);
}
}
static void
_qp_reset_failed_recvs(struct spdk_nvmf_rdma_qpair *rqpair, struct ibv_recv_wr *bad_recv_wr, int rc)
{
SPDK_ERRLOG("Failed to post a recv for the qpair %p with errno %d\n", rqpair, -rc);
while (bad_recv_wr != NULL) {
bad_recv_wr = bad_recv_wr->next;
rqpair->current_recv_depth++;
}
spdk_nvmf_qpair_disconnect(&rqpair->qpair, NULL, NULL);
}
static void
_poller_submit_recvs(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_poller *rpoller)
{
struct spdk_nvmf_rdma_qpair *rqpair;
struct ibv_recv_wr *bad_recv_wr;
int rc;
if (rpoller->srq) {
rc = spdk_rdma_srq_flush_recv_wrs(rpoller->srq, &bad_recv_wr);
if (rc) {
_poller_reset_failed_recvs(rpoller, bad_recv_wr, rc);
}
} else {
while (!STAILQ_EMPTY(&rpoller->qpairs_pending_recv)) {
rqpair = STAILQ_FIRST(&rpoller->qpairs_pending_recv);
rc = spdk_rdma_qp_flush_recv_wrs(rqpair->rdma_qp, &bad_recv_wr);
if (rc) {
_qp_reset_failed_recvs(rqpair, bad_recv_wr, rc);
}
STAILQ_REMOVE_HEAD(&rpoller->qpairs_pending_recv, recv_link);
}
}
}
static void
_qp_reset_failed_sends(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_qpair *rqpair, struct ibv_send_wr *bad_wr, int rc)
{
struct spdk_nvmf_rdma_wr *bad_rdma_wr;
struct spdk_nvmf_rdma_request *prev_rdma_req = NULL, *cur_rdma_req = NULL;
SPDK_ERRLOG("Failed to post a send for the qpair %p with errno %d\n", rqpair, -rc);
for (; bad_wr != NULL; bad_wr = bad_wr->next) {
bad_rdma_wr = (struct spdk_nvmf_rdma_wr *)bad_wr->wr_id;
assert(rqpair->current_send_depth > 0);
rqpair->current_send_depth--;
switch (bad_rdma_wr->type) {
case RDMA_WR_TYPE_DATA:
cur_rdma_req = SPDK_CONTAINEROF(bad_rdma_wr, struct spdk_nvmf_rdma_request, data.rdma_wr);
if (bad_wr->opcode == IBV_WR_RDMA_READ) {
assert(rqpair->current_read_depth > 0);
rqpair->current_read_depth--;
}
break;
case RDMA_WR_TYPE_SEND:
cur_rdma_req = SPDK_CONTAINEROF(bad_rdma_wr, struct spdk_nvmf_rdma_request, rsp.rdma_wr);
break;
default:
SPDK_ERRLOG("Found a RECV in the list of pending SEND requests for qpair %p\n", rqpair);
prev_rdma_req = cur_rdma_req;
continue;
}
if (prev_rdma_req == cur_rdma_req) {
/* this request was handled by an earlier wr. i.e. we were performing an nvme read. */
/* We only have to check against prev_wr since each requests wrs are contiguous in this list. */
continue;
}
switch (cur_rdma_req->state) {
case RDMA_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER:
cur_rdma_req->req.rsp->nvme_cpl.status.sc = SPDK_NVME_SC_INTERNAL_DEVICE_ERROR;
cur_rdma_req->state = RDMA_REQUEST_STATE_READY_TO_COMPLETE;
break;
case RDMA_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST:
case RDMA_REQUEST_STATE_COMPLETING:
cur_rdma_req->state = RDMA_REQUEST_STATE_COMPLETED;
break;
default:
SPDK_ERRLOG("Found a request in a bad state %d when draining pending SEND requests for qpair %p\n",
cur_rdma_req->state, rqpair);
continue;
}
nvmf_rdma_request_process(rtransport, cur_rdma_req);
prev_rdma_req = cur_rdma_req;
}
if (rqpair->qpair.state == SPDK_NVMF_QPAIR_ACTIVE) {
/* Disconnect the connection. */
spdk_nvmf_qpair_disconnect(&rqpair->qpair, NULL, NULL);
}
}
static void
_poller_submit_sends(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_poller *rpoller)
{
struct spdk_nvmf_rdma_qpair *rqpair;
struct ibv_send_wr *bad_wr = NULL;
int rc;
while (!STAILQ_EMPTY(&rpoller->qpairs_pending_send)) {
rqpair = STAILQ_FIRST(&rpoller->qpairs_pending_send);
rc = spdk_rdma_qp_flush_send_wrs(rqpair->rdma_qp, &bad_wr);
/* bad wr always points to the first wr that failed. */
if (rc) {
_qp_reset_failed_sends(rtransport, rqpair, bad_wr, rc);
}
STAILQ_REMOVE_HEAD(&rpoller->qpairs_pending_send, send_link);
}
}
static const char *
nvmf_rdma_wr_type_str(enum spdk_nvmf_rdma_wr_type wr_type)
{
switch (wr_type) {
case RDMA_WR_TYPE_RECV:
return "RECV";
case RDMA_WR_TYPE_SEND:
return "SEND";
case RDMA_WR_TYPE_DATA:
return "DATA";
default:
SPDK_ERRLOG("Unknown WR type %d\n", wr_type);
SPDK_UNREACHABLE();
}
}
static inline void
nvmf_rdma_log_wc_status(struct spdk_nvmf_rdma_qpair *rqpair, struct ibv_wc *wc)
{
enum spdk_nvmf_rdma_wr_type wr_type = ((struct spdk_nvmf_rdma_wr *)wc->wr_id)->type;
if (wc->status == IBV_WC_WR_FLUSH_ERR) {
/* If qpair is in ERR state, we will receive completions for all posted and not completed
* Work Requests with IBV_WC_WR_FLUSH_ERR status. Don't log an error in that case */
SPDK_DEBUGLOG(rdma,
"Error on CQ %p, (qp state %d ibv_state %d) request 0x%lu, type %s, status: (%d): %s\n",
rqpair->poller->cq, rqpair->qpair.state, rqpair->ibv_state, wc->wr_id,
nvmf_rdma_wr_type_str(wr_type), wc->status, ibv_wc_status_str(wc->status));
} else {
SPDK_ERRLOG("Error on CQ %p, (qp state %d ibv_state %d) request 0x%lu, type %s, status: (%d): %s\n",
rqpair->poller->cq, rqpair->qpair.state, rqpair->ibv_state, wc->wr_id,
nvmf_rdma_wr_type_str(wr_type), wc->status, ibv_wc_status_str(wc->status));
}
}
static int
nvmf_rdma_poller_poll(struct spdk_nvmf_rdma_transport *rtransport,
struct spdk_nvmf_rdma_poller *rpoller)
{
struct ibv_wc wc[32];
struct spdk_nvmf_rdma_wr *rdma_wr;
struct spdk_nvmf_rdma_request *rdma_req;
struct spdk_nvmf_rdma_recv *rdma_recv;
struct spdk_nvmf_rdma_qpair *rqpair;
int reaped, i;
int count = 0;
bool error = false;
uint64_t poll_tsc = spdk_get_ticks();
/* Poll for completing operations. */
reaped = ibv_poll_cq(rpoller->cq, 32, wc);
if (reaped < 0) {
SPDK_ERRLOG("Error polling CQ! (%d): %s\n",
errno, spdk_strerror(errno));
return -1;
} else if (reaped == 0) {
rpoller->stat.idle_polls++;
}
rpoller->stat.polls++;
rpoller->stat.completions += reaped;
for (i = 0; i < reaped; i++) {
rdma_wr = (struct spdk_nvmf_rdma_wr *)wc[i].wr_id;
switch (rdma_wr->type) {
case RDMA_WR_TYPE_SEND:
rdma_req = SPDK_CONTAINEROF(rdma_wr, struct spdk_nvmf_rdma_request, rsp.rdma_wr);
rqpair = SPDK_CONTAINEROF(rdma_req->req.qpair, struct spdk_nvmf_rdma_qpair, qpair);
if (!wc[i].status) {
count++;
assert(wc[i].opcode == IBV_WC_SEND);
assert(nvmf_rdma_req_is_completing(rdma_req));
}
rdma_req->state = RDMA_REQUEST_STATE_COMPLETED;
/* RDMA_WRITE operation completed. +1 since it was chained with rsp WR */
rqpair->current_send_depth -= rdma_req->num_outstanding_data_wr + 1;
rdma_req->num_outstanding_data_wr = 0;
nvmf_rdma_request_process(rtransport, rdma_req);
break;
case RDMA_WR_TYPE_RECV:
/* rdma_recv->qpair will be invalid if using an SRQ. In that case we have to get the qpair from the wc. */
rdma_recv = SPDK_CONTAINEROF(rdma_wr, struct spdk_nvmf_rdma_recv, rdma_wr);
if (rpoller->srq != NULL) {
rdma_recv->qpair = get_rdma_qpair_from_wc(rpoller, &wc[i]);
/* It is possible that there are still some completions for destroyed QP
* associated with SRQ. We just ignore these late completions and re-post
* receive WRs back to SRQ.
*/
if (spdk_unlikely(NULL == rdma_recv->qpair)) {
struct ibv_recv_wr *bad_wr;
int rc;
rdma_recv->wr.next = NULL;
spdk_rdma_srq_queue_recv_wrs(rpoller->srq, &rdma_recv->wr);
rc = spdk_rdma_srq_flush_recv_wrs(rpoller->srq, &bad_wr);
if (rc) {
SPDK_ERRLOG("Failed to re-post recv WR to SRQ, err %d\n", rc);
}
continue;
}
}
rqpair = rdma_recv->qpair;
assert(rqpair != NULL);
if (!wc[i].status) {
assert(wc[i].opcode == IBV_WC_RECV);
if (rqpair->current_recv_depth >= rqpair->max_queue_depth) {
spdk_nvmf_qpair_disconnect(&rqpair->qpair, NULL, NULL);
break;
}
}
rdma_recv->wr.next = NULL;
rqpair->current_recv_depth++;
rdma_recv->receive_tsc = poll_tsc;
rpoller->stat.requests++;
STAILQ_INSERT_TAIL(&rqpair->resources->incoming_queue, rdma_recv, link);
break;
case RDMA_WR_TYPE_DATA:
rdma_req = SPDK_CONTAINEROF(rdma_wr, struct spdk_nvmf_rdma_request, data.rdma_wr);
rqpair = SPDK_CONTAINEROF(rdma_req->req.qpair, struct spdk_nvmf_rdma_qpair, qpair);
assert(rdma_req->num_outstanding_data_wr > 0);
rqpair->current_send_depth--;
rdma_req->num_outstanding_data_wr--;
if (!wc[i].status) {
assert(wc[i].opcode == IBV_WC_RDMA_READ);
rqpair->current_read_depth--;
/* wait for all outstanding reads associated with the same rdma_req to complete before proceeding. */
if (rdma_req->num_outstanding_data_wr == 0) {
rdma_req->state = RDMA_REQUEST_STATE_READY_TO_EXECUTE;
nvmf_rdma_request_process(rtransport, rdma_req);
}
} else {
/* If the data transfer fails still force the queue into the error state,
* if we were performing an RDMA_READ, we need to force the request into a
* completed state since it wasn't linked to a send. However, in the RDMA_WRITE
* case, we should wait for the SEND to complete. */
if (rdma_req->data.wr.opcode == IBV_WR_RDMA_READ) {
rqpair->current_read_depth--;
if (rdma_req->num_outstanding_data_wr == 0) {
rdma_req->state = RDMA_REQUEST_STATE_COMPLETED;
}
}
}
break;
default:
SPDK_ERRLOG("Received an unknown opcode on the CQ: %d\n", wc[i].opcode);
continue;
}
/* Handle error conditions */
if (wc[i].status) {
nvmf_rdma_update_ibv_state(rqpair);
nvmf_rdma_log_wc_status(rqpair, &wc[i]);
error = true;
if (rqpair->qpair.state == SPDK_NVMF_QPAIR_ACTIVE) {
/* Disconnect the connection. */
spdk_nvmf_qpair_disconnect(&rqpair->qpair, NULL, NULL);
} else {
nvmf_rdma_destroy_drained_qpair(rqpair);
}
continue;
}
nvmf_rdma_qpair_process_pending(rtransport, rqpair, false);
if (rqpair->qpair.state != SPDK_NVMF_QPAIR_ACTIVE) {
nvmf_rdma_destroy_drained_qpair(rqpair);
}
}
if (error == true) {
return -1;
}
/* submit outstanding work requests. */
_poller_submit_recvs(rtransport, rpoller);
_poller_submit_sends(rtransport, rpoller);
return count;
}
static int
nvmf_rdma_poll_group_poll(struct spdk_nvmf_transport_poll_group *group)
{
struct spdk_nvmf_rdma_transport *rtransport;
struct spdk_nvmf_rdma_poll_group *rgroup;
struct spdk_nvmf_rdma_poller *rpoller;
int count, rc;
rtransport = SPDK_CONTAINEROF(group->transport, struct spdk_nvmf_rdma_transport, transport);
rgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_rdma_poll_group, group);
count = 0;
TAILQ_FOREACH(rpoller, &rgroup->pollers, link) {
rc = nvmf_rdma_poller_poll(rtransport, rpoller);
if (rc < 0) {
return rc;
}
count += rc;
}
return count;
}
static int
nvmf_rdma_trid_from_cm_id(struct rdma_cm_id *id,
struct spdk_nvme_transport_id *trid,
bool peer)
{
struct sockaddr *saddr;
uint16_t port;
spdk_nvme_trid_populate_transport(trid, SPDK_NVME_TRANSPORT_RDMA);
if (peer) {
saddr = rdma_get_peer_addr(id);
} else {
saddr = rdma_get_local_addr(id);
}
switch (saddr->sa_family) {
case AF_INET: {
struct sockaddr_in *saddr_in = (struct sockaddr_in *)saddr;
trid->adrfam = SPDK_NVMF_ADRFAM_IPV4;
inet_ntop(AF_INET, &saddr_in->sin_addr,
trid->traddr, sizeof(trid->traddr));
if (peer) {
port = ntohs(rdma_get_dst_port(id));
} else {
port = ntohs(rdma_get_src_port(id));
}
snprintf(trid->trsvcid, sizeof(trid->trsvcid), "%u", port);
break;
}
case AF_INET6: {
struct sockaddr_in6 *saddr_in = (struct sockaddr_in6 *)saddr;
trid->adrfam = SPDK_NVMF_ADRFAM_IPV6;
inet_ntop(AF_INET6, &saddr_in->sin6_addr,
trid->traddr, sizeof(trid->traddr));
if (peer) {
port = ntohs(rdma_get_dst_port(id));
} else {
port = ntohs(rdma_get_src_port(id));
}
snprintf(trid->trsvcid, sizeof(trid->trsvcid), "%u", port);
break;
}
default:
return -1;
}
return 0;
}
static int
nvmf_rdma_qpair_get_peer_trid(struct spdk_nvmf_qpair *qpair,
struct spdk_nvme_transport_id *trid)
{
struct spdk_nvmf_rdma_qpair *rqpair;
rqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_rdma_qpair, qpair);
return nvmf_rdma_trid_from_cm_id(rqpair->cm_id, trid, true);
}
static int
nvmf_rdma_qpair_get_local_trid(struct spdk_nvmf_qpair *qpair,
struct spdk_nvme_transport_id *trid)
{
struct spdk_nvmf_rdma_qpair *rqpair;
rqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_rdma_qpair, qpair);
return nvmf_rdma_trid_from_cm_id(rqpair->cm_id, trid, false);
}
static int
nvmf_rdma_qpair_get_listen_trid(struct spdk_nvmf_qpair *qpair,
struct spdk_nvme_transport_id *trid)
{
struct spdk_nvmf_rdma_qpair *rqpair;
rqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_rdma_qpair, qpair);
return nvmf_rdma_trid_from_cm_id(rqpair->listen_id, trid, false);
}
void
spdk_nvmf_rdma_init_hooks(struct spdk_nvme_rdma_hooks *hooks)
{
g_nvmf_hooks = *hooks;
}
static void
nvmf_rdma_request_set_abort_status(struct spdk_nvmf_request *req,
struct spdk_nvmf_rdma_request *rdma_req_to_abort)
{
rdma_req_to_abort->req.rsp->nvme_cpl.status.sct = SPDK_NVME_SCT_GENERIC;
rdma_req_to_abort->req.rsp->nvme_cpl.status.sc = SPDK_NVME_SC_ABORTED_BY_REQUEST;
rdma_req_to_abort->state = RDMA_REQUEST_STATE_READY_TO_COMPLETE;
req->rsp->nvme_cpl.cdw0 &= ~1U; /* Command was successfully aborted. */
}
static int
_nvmf_rdma_qpair_abort_request(void *ctx)
{
struct spdk_nvmf_request *req = ctx;
struct spdk_nvmf_rdma_request *rdma_req_to_abort = SPDK_CONTAINEROF(
req->req_to_abort, struct spdk_nvmf_rdma_request, req);
struct spdk_nvmf_rdma_qpair *rqpair = SPDK_CONTAINEROF(req->req_to_abort->qpair,
struct spdk_nvmf_rdma_qpair, qpair);
int rc;
spdk_poller_unregister(&req->poller);
switch (rdma_req_to_abort->state) {
case RDMA_REQUEST_STATE_EXECUTING:
rc = nvmf_ctrlr_abort_request(req);
if (rc == SPDK_NVMF_REQUEST_EXEC_STATUS_ASYNCHRONOUS) {
return SPDK_POLLER_BUSY;
}
break;
case RDMA_REQUEST_STATE_NEED_BUFFER:
STAILQ_REMOVE(&rqpair->poller->group->group.pending_buf_queue,
&rdma_req_to_abort->req, spdk_nvmf_request, buf_link);
nvmf_rdma_request_set_abort_status(req, rdma_req_to_abort);
break;
case RDMA_REQUEST_STATE_DATA_TRANSFER_TO_CONTROLLER_PENDING:
STAILQ_REMOVE(&rqpair->pending_rdma_read_queue, rdma_req_to_abort,
spdk_nvmf_rdma_request, state_link);
nvmf_rdma_request_set_abort_status(req, rdma_req_to_abort);
break;
case RDMA_REQUEST_STATE_DATA_TRANSFER_TO_HOST_PENDING:
STAILQ_REMOVE(&rqpair->pending_rdma_write_queue, rdma_req_to_abort,
spdk_nvmf_rdma_request, state_link);
nvmf_rdma_request_set_abort_status(req, rdma_req_to_abort);
break;
case RDMA_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER:
if (spdk_get_ticks() < req->timeout_tsc) {
req->poller = SPDK_POLLER_REGISTER(_nvmf_rdma_qpair_abort_request, req, 0);
return SPDK_POLLER_BUSY;
}
break;
default:
break;
}
spdk_nvmf_request_complete(req);
return SPDK_POLLER_BUSY;
}
static void
nvmf_rdma_qpair_abort_request(struct spdk_nvmf_qpair *qpair,
struct spdk_nvmf_request *req)
{
struct spdk_nvmf_rdma_qpair *rqpair;
struct spdk_nvmf_rdma_transport *rtransport;
struct spdk_nvmf_transport *transport;
uint16_t cid;
uint32_t i, max_req_count;
struct spdk_nvmf_rdma_request *rdma_req_to_abort = NULL, *rdma_req;
rqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_rdma_qpair, qpair);
rtransport = SPDK_CONTAINEROF(qpair->transport, struct spdk_nvmf_rdma_transport, transport);
transport = &rtransport->transport;
cid = req->cmd->nvme_cmd.cdw10_bits.abort.cid;
max_req_count = rqpair->srq == NULL ? rqpair->max_queue_depth : rqpair->poller->max_srq_depth;
for (i = 0; i < max_req_count; i++) {
rdma_req = &rqpair->resources->reqs[i];
/* When SRQ == NULL, rqpair has its own requests and req.qpair pointer always points to the qpair
* When SRQ != NULL all rqpairs share common requests and qpair pointer is assigned when we start to
* process a request. So in both cases all requests which are not in FREE state have valid qpair ptr */
if (rdma_req->state != RDMA_REQUEST_STATE_FREE && rdma_req->req.cmd->nvme_cmd.cid == cid &&
rdma_req->req.qpair == qpair) {
rdma_req_to_abort = rdma_req;
break;
}
}
if (rdma_req_to_abort == NULL) {
spdk_nvmf_request_complete(req);
return;
}
req->req_to_abort = &rdma_req_to_abort->req;
req->timeout_tsc = spdk_get_ticks() +
transport->opts.abort_timeout_sec * spdk_get_ticks_hz();
req->poller = NULL;
_nvmf_rdma_qpair_abort_request(req);
}
static void
nvmf_rdma_poll_group_dump_stat(struct spdk_nvmf_transport_poll_group *group,
struct spdk_json_write_ctx *w)
{
struct spdk_nvmf_rdma_poll_group *rgroup;
struct spdk_nvmf_rdma_poller *rpoller;
assert(w != NULL);
rgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_rdma_poll_group, group);
spdk_json_write_named_uint64(w, "pending_data_buffer", rgroup->stat.pending_data_buffer);
spdk_json_write_named_array_begin(w, "devices");
TAILQ_FOREACH(rpoller, &rgroup->pollers, link) {
spdk_json_write_object_begin(w);
spdk_json_write_named_string(w, "name",
ibv_get_device_name(rpoller->device->context->device));
spdk_json_write_named_uint64(w, "polls",
rpoller->stat.polls);
spdk_json_write_named_uint64(w, "idle_polls",
rpoller->stat.idle_polls);
spdk_json_write_named_uint64(w, "completions",
rpoller->stat.completions);
spdk_json_write_named_uint64(w, "requests",
rpoller->stat.requests);
spdk_json_write_named_uint64(w, "request_latency",
rpoller->stat.request_latency);
spdk_json_write_named_uint64(w, "pending_free_request",
rpoller->stat.pending_free_request);
spdk_json_write_named_uint64(w, "pending_rdma_read",
rpoller->stat.pending_rdma_read);
spdk_json_write_named_uint64(w, "pending_rdma_write",
rpoller->stat.pending_rdma_write);
spdk_json_write_named_uint64(w, "total_send_wrs",
rpoller->stat.qp_stats.send.num_submitted_wrs);
spdk_json_write_named_uint64(w, "send_doorbell_updates",
rpoller->stat.qp_stats.send.doorbell_updates);
spdk_json_write_named_uint64(w, "total_recv_wrs",
rpoller->stat.qp_stats.recv.num_submitted_wrs);
spdk_json_write_named_uint64(w, "recv_doorbell_updates",
rpoller->stat.qp_stats.recv.doorbell_updates);
spdk_json_write_object_end(w);
}
spdk_json_write_array_end(w);
}
const struct spdk_nvmf_transport_ops spdk_nvmf_transport_rdma = {
.name = "RDMA",
.type = SPDK_NVME_TRANSPORT_RDMA,
.opts_init = nvmf_rdma_opts_init,
.create = nvmf_rdma_create,
.dump_opts = nvmf_rdma_dump_opts,
.destroy = nvmf_rdma_destroy,
.listen = nvmf_rdma_listen,
.stop_listen = nvmf_rdma_stop_listen,
.cdata_init = nvmf_rdma_cdata_init,
.listener_discover = nvmf_rdma_discover,
.poll_group_create = nvmf_rdma_poll_group_create,
.get_optimal_poll_group = nvmf_rdma_get_optimal_poll_group,
.poll_group_destroy = nvmf_rdma_poll_group_destroy,
.poll_group_add = nvmf_rdma_poll_group_add,
.poll_group_remove = nvmf_rdma_poll_group_remove,
.poll_group_poll = nvmf_rdma_poll_group_poll,
.req_free = nvmf_rdma_request_free,
.req_complete = nvmf_rdma_request_complete,
.qpair_fini = nvmf_rdma_close_qpair,
.qpair_get_peer_trid = nvmf_rdma_qpair_get_peer_trid,
.qpair_get_local_trid = nvmf_rdma_qpair_get_local_trid,
.qpair_get_listen_trid = nvmf_rdma_qpair_get_listen_trid,
.qpair_abort_request = nvmf_rdma_qpair_abort_request,
.poll_group_dump_stat = nvmf_rdma_poll_group_dump_stat,
};
SPDK_NVMF_TRANSPORT_REGISTER(rdma, &spdk_nvmf_transport_rdma);
SPDK_LOG_REGISTER_COMPONENT(rdma)
Reference in New Issue View Git Blame Copy Permalink