numam-spdk/lib/nvmf/tcp.c

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/*-
* BSD LICENSE
*
* Copyright (c) Intel Corporation.
* 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/crc32.h"
#include "spdk/endian.h"
#include "spdk/assert.h"
#include "spdk/thread.h"
#include "spdk/nvmf.h"
#include "spdk/nvmf_spec.h"
#include "spdk/sock.h"
#include "spdk/string.h"
#include "spdk/trace.h"
#include "spdk/util.h"
#include "nvmf_internal.h"
#include "transport.h"
#include "spdk_internal/log.h"
#include "spdk_internal/nvme_tcp.h"
#define NVMF_TCP_MAX_ACCEPT_SOCK_ONE_TIME 16
#define NVMF_TCP_PDU_MAX_H2C_DATA_SIZE 131072
#define NVMF_TCP_PDU_MAX_C2H_DATA_SIZE 131072
#define NVMF_TCP_QPAIR_MAX_C2H_PDU_NUM 64 /* Maximal c2h_data pdu number for ecah tqpair */
/* spdk nvmf related structure */
enum spdk_nvmf_tcp_req_state {
/* The request is not currently in use */
TCP_REQUEST_STATE_FREE = 0,
/* Initial state when request first received */
TCP_REQUEST_STATE_NEW,
/* The request is queued until a data buffer is available. */
TCP_REQUEST_STATE_NEED_BUFFER,
/* The request is currently transferring data from the host to the controller. */
TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER,
/* The request is ready to execute at the block device */
TCP_REQUEST_STATE_READY_TO_EXECUTE,
/* The request is currently executing at the block device */
TCP_REQUEST_STATE_EXECUTING,
/* The request finished executing at the block device */
TCP_REQUEST_STATE_EXECUTED,
/* The request is ready to send a completion */
TCP_REQUEST_STATE_READY_TO_COMPLETE,
/* The request is currently transferring final pdus from the controller to the host. */
TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST,
/* The request completed and can be marked free. */
TCP_REQUEST_STATE_COMPLETED,
/* Terminator */
TCP_REQUEST_NUM_STATES,
};
static const char *spdk_nvmf_tcp_term_req_fes_str[] = {
"Invalid PDU Header Field",
"PDU Sequence Error",
"Header Digiest Error",
"Data Transfer Out of Range",
"R2T Limit Exceeded",
"Unsupported parameter",
};
#define OBJECT_NVMF_TCP_IO 0x80
#define TRACE_GROUP_NVMF_TCP 0x5
#define TRACE_TCP_REQUEST_STATE_NEW SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0x0)
#define TRACE_TCP_REQUEST_STATE_NEED_BUFFER SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0x1)
nvmf/tcp: Support single r2t usage According to the TP 8000 spec in Page 26: Maximum Number of Outstanding R2T (MAXR2T): Specifies the maximum number of outstanding R2T PDUs for a command at any point in time on the connection. Note that by the spec, the target may only support single r2t (which is the minimum possible), it doesn't have to use multiple r2ts even if the initiator supports that. So remove the maxr2t and pending_r2t variable in the tcp qpair structure. In the original design, we think that maxr2t is the maximal active r2t numbers for each connection. So if the initiator sends out maxr2t=16, it means that all the commands of a qpair can use such number of R2T pdus. So we need to wait for the available R2Ts for the request when the maxr2t reaches the maximal value. But it is the wrong understanding of the spec. In fact, each command has its own number of maximal r2t numbers, then we do not need to use the wait method for R2T method anymore. So we remove the state TCP_REQUEST_STATE_DATA_PENDING_FOR_R2T. Futhermore, we adjust the related SPDK_TPOINT_ID definition. In current patch, the target will support one active R2T for each write NVMe command. Thus, we remove the function spdk_nvmf_tcp_handle_queued_r2t_req. Reported-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Ziye Yang <ziye.yang@intel.com> Change-Id: I7547b8facbc39139b4584637ccc51ba8b33ca285 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/455763 Reviewed-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com> Reviewed-by: Or Gerlitz <gerlitz.or@gmail.com> Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
2019-05-27 12:45:58 +00:00
#define TRACE_TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0x2)
#define TRACE_TCP_REQUEST_STATE_READY_TO_EXECUTE SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0x3)
#define TRACE_TCP_REQUEST_STATE_EXECUTING SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0x4)
#define TRACE_TCP_REQUEST_STATE_EXECUTED SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0x5)
#define TRACE_TCP_REQUEST_STATE_READY_TO_COMPLETE SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0x6)
#define TRACE_TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0x7)
#define TRACE_TCP_REQUEST_STATE_COMPLETED SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0x8)
#define TRACE_TCP_FLUSH_WRITEBUF_START SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0x9)
#define TRACE_TCP_FLUSH_WRITEBUF_DONE SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0xA)
#define TRACE_TCP_READ_FROM_SOCKET_DONE SPDK_TPOINT_ID(TRACE_GROUP_NVMF_TCP, 0xB)
SPDK_TRACE_REGISTER_FN(nvmf_tcp_trace, "nvmf_tcp", TRACE_GROUP_NVMF_TCP)
{
spdk_trace_register_object(OBJECT_NVMF_TCP_IO, 'r');
spdk_trace_register_description("TCP_REQ_NEW",
TRACE_TCP_REQUEST_STATE_NEW,
OWNER_NONE, OBJECT_NVMF_TCP_IO, 1, 1, "");
spdk_trace_register_description("TCP_REQ_NEED_BUFFER",
TRACE_TCP_REQUEST_STATE_NEED_BUFFER,
OWNER_NONE, OBJECT_NVMF_TCP_IO, 0, 1, "");
spdk_trace_register_description("TCP_REQ_TX_H_TO_C",
TRACE_TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER,
OWNER_NONE, OBJECT_NVMF_TCP_IO, 0, 1, "");
spdk_trace_register_description("TCP_REQ_RDY_TO_EXECUTE",
TRACE_TCP_REQUEST_STATE_READY_TO_EXECUTE,
OWNER_NONE, OBJECT_NVMF_TCP_IO, 0, 1, "");
spdk_trace_register_description("TCP_REQ_EXECUTING",
TRACE_TCP_REQUEST_STATE_EXECUTING,
OWNER_NONE, OBJECT_NVMF_TCP_IO, 0, 1, "");
spdk_trace_register_description("TCP_REQ_EXECUTED",
TRACE_TCP_REQUEST_STATE_EXECUTED,
OWNER_NONE, OBJECT_NVMF_TCP_IO, 0, 1, "");
spdk_trace_register_description("TCP_REQ_RDY_TO_COMPLETE",
TRACE_TCP_REQUEST_STATE_READY_TO_COMPLETE,
OWNER_NONE, OBJECT_NVMF_TCP_IO, 0, 1, "");
spdk_trace_register_description("TCP_REQ_TRANSFER_C2H",
TRACE_TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST,
OWNER_NONE, OBJECT_NVMF_TCP_IO, 0, 1, "");
spdk_trace_register_description("TCP_REQ_COMPLETED",
TRACE_TCP_REQUEST_STATE_COMPLETED,
OWNER_NONE, OBJECT_NVMF_TCP_IO, 0, 1, "");
spdk_trace_register_description("TCP_WRITE_START",
TRACE_TCP_FLUSH_WRITEBUF_START,
OWNER_NONE, OBJECT_NONE, 0, 0, "");
spdk_trace_register_description("TCP_WRITE_DONE",
TRACE_TCP_FLUSH_WRITEBUF_DONE,
OWNER_NONE, OBJECT_NONE, 0, 0, "");
spdk_trace_register_description("TCP_READ_DONE",
TRACE_TCP_READ_FROM_SOCKET_DONE,
OWNER_NONE, OBJECT_NONE, 0, 0, "");
}
struct spdk_nvmf_tcp_req {
struct spdk_nvmf_request req;
struct spdk_nvme_cpl rsp;
struct spdk_nvme_cmd cmd;
/* In-capsule data buffer */
uint8_t *buf;
bool data_from_pool;
void *buffers[SPDK_NVMF_MAX_SGL_ENTRIES];
/* transfer_tag */
uint16_t ttag;
/*
* next_expected_r2t_offset is used when we receive the h2c_data PDU.
*/
uint32_t next_expected_r2t_offset;
uint32_t r2tl_remain;
/*
* c2h_data_offset is used when we send the c2h_data PDU.
*/
uint32_t c2h_data_offset;
uint32_t c2h_data_pdu_num;
enum spdk_nvmf_tcp_req_state state;
bool has_incapsule_data;
TAILQ_ENTRY(spdk_nvmf_tcp_req) link;
TAILQ_ENTRY(spdk_nvmf_tcp_req) state_link;
};
struct spdk_nvmf_tcp_qpair {
struct spdk_nvmf_qpair qpair;
struct spdk_nvmf_tcp_poll_group *group;
struct spdk_nvmf_tcp_port *port;
struct spdk_sock *sock;
struct spdk_poller *flush_poller;
enum nvme_tcp_pdu_recv_state recv_state;
enum nvme_tcp_qpair_state state;
struct nvme_tcp_pdu pdu_in_progress;
TAILQ_HEAD(, nvme_tcp_pdu) send_queue;
TAILQ_HEAD(, nvme_tcp_pdu) free_queue;
struct nvme_tcp_pdu *pdu;
struct nvme_tcp_pdu *pdu_pool;
uint16_t free_pdu_num;
/* Queues to track the requests in all states */
TAILQ_HEAD(, spdk_nvmf_tcp_req) state_queue[TCP_REQUEST_NUM_STATES];
/* Number of requests in each state */
int32_t state_cntr[TCP_REQUEST_NUM_STATES];
TAILQ_HEAD(, spdk_nvmf_tcp_req) queued_c2h_data_tcp_req;
uint8_t cpda;
/* Array of size "max_queue_depth * InCapsuleDataSize" containing
* buffers to be used for in capsule data.
*/
void *buf;
void *bufs;
struct spdk_nvmf_tcp_req *req;
struct spdk_nvmf_tcp_req *reqs;
bool host_hdgst_enable;
bool host_ddgst_enable;
/* The maximum number of I/O outstanding on this connection at one time */
uint16_t max_queue_depth;
/** Specifies the maximum number of PDU-Data bytes per H2C Data Transfer PDU */
uint32_t maxh2cdata;
uint32_t c2h_data_pdu_cnt;
/* IP address */
char initiator_addr[SPDK_NVMF_TRADDR_MAX_LEN];
char target_addr[SPDK_NVMF_TRADDR_MAX_LEN];
/* IP port */
uint16_t initiator_port;
uint16_t target_port;
/* Timer used to destroy qpair after detecting transport error issue if initiator does
* not close the connection.
*/
struct spdk_poller *timeout_poller;
TAILQ_ENTRY(spdk_nvmf_tcp_qpair) link;
};
struct spdk_nvmf_tcp_poll_group {
struct spdk_nvmf_transport_poll_group group;
struct spdk_sock_group *sock_group;
/* Requests that are waiting to obtain a data buffer */
TAILQ_HEAD(, spdk_nvmf_tcp_req) pending_data_buf_queue;
TAILQ_HEAD(, spdk_nvmf_tcp_qpair) qpairs;
};
struct spdk_nvmf_tcp_port {
struct spdk_nvme_transport_id trid;
struct spdk_sock *listen_sock;
uint32_t ref;
TAILQ_ENTRY(spdk_nvmf_tcp_port) link;
};
struct spdk_nvmf_tcp_transport {
struct spdk_nvmf_transport transport;
pthread_mutex_t lock;
TAILQ_HEAD(, spdk_nvmf_tcp_port) ports;
};
static void spdk_nvmf_tcp_qpair_process_pending(struct spdk_nvmf_tcp_transport *ttransport,
struct spdk_nvmf_tcp_qpair *tqpair);
static bool spdk_nvmf_tcp_req_process(struct spdk_nvmf_tcp_transport *ttransport,
struct spdk_nvmf_tcp_req *tcp_req);
static void spdk_nvmf_tcp_handle_pending_c2h_data_queue(struct spdk_nvmf_tcp_qpair *tqpair);
static void
spdk_nvmf_tcp_req_set_state(struct spdk_nvmf_tcp_req *tcp_req,
enum spdk_nvmf_tcp_req_state state)
{
struct spdk_nvmf_qpair *qpair;
struct spdk_nvmf_tcp_qpair *tqpair;
qpair = tcp_req->req.qpair;
tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
TAILQ_REMOVE(&tqpair->state_queue[tcp_req->state], tcp_req, state_link);
tqpair->state_cntr[tcp_req->state]--;
assert(tqpair->state_cntr[tcp_req->state] >= 0);
TAILQ_INSERT_TAIL(&tqpair->state_queue[state], tcp_req, state_link);
tqpair->state_cntr[state]++;
tcp_req->state = state;
}
static struct nvme_tcp_pdu *
spdk_nvmf_tcp_pdu_get(struct spdk_nvmf_tcp_qpair *tqpair)
{
struct nvme_tcp_pdu *pdu;
pdu = TAILQ_FIRST(&tqpair->free_queue);
if (!pdu) {
SPDK_ERRLOG("Unable to get PDU for tqpair=%p\n", tqpair);
abort();
return NULL;
}
tqpair->free_pdu_num--;
TAILQ_REMOVE(&tqpair->free_queue, pdu, tailq);
memset(pdu, 0, sizeof(*pdu));
pdu->ref = 1;
return pdu;
}
static void
spdk_nvmf_tcp_pdu_put(struct spdk_nvmf_tcp_qpair *tqpair, struct nvme_tcp_pdu *pdu)
{
if (!pdu) {
return;
}
assert(pdu->ref > 0);
pdu->ref--;
if (pdu->ref == 0) {
tqpair->free_pdu_num++;
TAILQ_INSERT_HEAD(&tqpair->free_queue, pdu, tailq);
}
}
static struct spdk_nvmf_tcp_req *
spdk_nvmf_tcp_req_get(struct spdk_nvmf_tcp_qpair *tqpair)
{
struct spdk_nvmf_tcp_req *tcp_req;
tcp_req = TAILQ_FIRST(&tqpair->state_queue[TCP_REQUEST_STATE_FREE]);
if (!tcp_req) {
SPDK_ERRLOG("Cannot allocate tcp_req on tqpair=%p\n", tqpair);
return NULL;
}
memset(&tcp_req->cmd, 0, sizeof(tcp_req->cmd));
memset(&tcp_req->rsp, 0, sizeof(tcp_req->rsp));
tcp_req->next_expected_r2t_offset = 0;
tcp_req->r2tl_remain = 0;
tcp_req->c2h_data_offset = 0;
tcp_req->has_incapsule_data = false;
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_NEW);
return tcp_req;
}
static void
nvmf_tcp_request_free(struct spdk_nvmf_tcp_req *tcp_req)
{
struct spdk_nvmf_tcp_transport *ttransport;
if (!tcp_req) {
return;
}
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "tcp_req=%p will be freed\n", tcp_req);
ttransport = SPDK_CONTAINEROF(tcp_req->req.qpair->transport,
struct spdk_nvmf_tcp_transport, transport);
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_COMPLETED);
spdk_nvmf_tcp_req_process(ttransport, tcp_req);
}
static int
spdk_nvmf_tcp_req_free(struct spdk_nvmf_request *req)
{
struct spdk_nvmf_tcp_req *tcp_req = SPDK_CONTAINEROF(req, struct spdk_nvmf_tcp_req, req);
nvmf_tcp_request_free(tcp_req);
return 0;
}
static void
spdk_nvmf_tcp_drain_state_queue(struct spdk_nvmf_tcp_qpair *tqpair,
enum spdk_nvmf_tcp_req_state state)
{
struct spdk_nvmf_tcp_req *tcp_req, *req_tmp;
TAILQ_FOREACH_SAFE(tcp_req, &tqpair->state_queue[state], state_link, req_tmp) {
nvmf_tcp_request_free(tcp_req);
}
}
static void
spdk_nvmf_tcp_cleanup_all_states(struct spdk_nvmf_tcp_qpair *tqpair)
{
struct spdk_nvmf_tcp_req *tcp_req, *req_tmp;
struct nvme_tcp_pdu *pdu, *tmp_pdu;
/* Free the pdus in the send_queue */
TAILQ_FOREACH_SAFE(pdu, &tqpair->send_queue, tailq, tmp_pdu) {
TAILQ_REMOVE(&tqpair->send_queue, pdu, tailq);
/* Also check the pdu type, we need to calculte the c2h_data_pdu_cnt later */
if (pdu->hdr.common.pdu_type == SPDK_NVME_TCP_PDU_TYPE_C2H_DATA) {
assert(tqpair->c2h_data_pdu_cnt > 0);
tqpair->c2h_data_pdu_cnt--;
}
spdk_nvmf_tcp_pdu_put(tqpair, pdu);
}
TAILQ_FOREACH_SAFE(tcp_req, &tqpair->queued_c2h_data_tcp_req, link, req_tmp) {
TAILQ_REMOVE(&tqpair->queued_c2h_data_tcp_req, tcp_req, link);
}
spdk_nvmf_tcp_drain_state_queue(tqpair, TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST);
spdk_nvmf_tcp_drain_state_queue(tqpair, TCP_REQUEST_STATE_NEW);
/* Wipe the requests waiting for buffer from the global list */
TAILQ_FOREACH_SAFE(tcp_req, &tqpair->state_queue[TCP_REQUEST_STATE_NEED_BUFFER], state_link,
req_tmp) {
TAILQ_REMOVE(&tqpair->group->pending_data_buf_queue, tcp_req, link);
}
spdk_nvmf_tcp_drain_state_queue(tqpair, TCP_REQUEST_STATE_NEED_BUFFER);
spdk_nvmf_tcp_drain_state_queue(tqpair, TCP_REQUEST_STATE_EXECUTING);
spdk_nvmf_tcp_drain_state_queue(tqpair, TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER);
}
static void
nvmf_tcp_dump_qpair_req_contents(struct spdk_nvmf_tcp_qpair *tqpair)
{
int i;
struct spdk_nvmf_tcp_req *tcp_req;
SPDK_ERRLOG("Dumping contents of queue pair (QID %d)\n", tqpair->qpair.qid);
for (i = 1; i < TCP_REQUEST_NUM_STATES; i++) {
SPDK_ERRLOG("\tNum of requests in state[%d] = %d\n", i, tqpair->state_cntr[i]);
TAILQ_FOREACH(tcp_req, &tqpair->state_queue[i], state_link) {
SPDK_ERRLOG("\t\tRequest Data From Pool: %d\n", tcp_req->data_from_pool);
SPDK_ERRLOG("\t\tRequest opcode: %d\n", tcp_req->req.cmd->nvmf_cmd.opcode);
}
}
}
static void
spdk_nvmf_tcp_qpair_destroy(struct spdk_nvmf_tcp_qpair *tqpair)
{
int err = 0;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "enter\n");
spdk_poller_unregister(&tqpair->flush_poller);
spdk_sock_close(&tqpair->sock);
spdk_nvmf_tcp_cleanup_all_states(tqpair);
if (tqpair->free_pdu_num != (tqpair->max_queue_depth + NVMF_TCP_QPAIR_MAX_C2H_PDU_NUM)) {
SPDK_ERRLOG("tqpair(%p) free pdu pool num is %u but should be %u\n", tqpair,
tqpair->free_pdu_num,
(tqpair->max_queue_depth + NVMF_TCP_QPAIR_MAX_C2H_PDU_NUM));
err++;
}
if (tqpair->state_cntr[TCP_REQUEST_STATE_FREE] != tqpair->max_queue_depth) {
SPDK_ERRLOG("tqpair(%p) free tcp request num is %u but should be %u\n", tqpair,
tqpair->state_cntr[TCP_REQUEST_STATE_FREE],
tqpair->max_queue_depth);
err++;
}
if (tqpair->c2h_data_pdu_cnt != 0) {
SPDK_ERRLOG("tqpair(%p) free c2h_data_pdu cnt is %u but should be 0\n", tqpair,
tqpair->c2h_data_pdu_cnt);
err++;
}
if (err > 0) {
nvmf_tcp_dump_qpair_req_contents(tqpair);
}
free(tqpair->pdu);
free(tqpair->pdu_pool);
free(tqpair->req);
free(tqpair->reqs);
spdk_dma_free(tqpair->buf);
spdk_dma_free(tqpair->bufs);
free(tqpair);
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Leave\n");
}
static int
spdk_nvmf_tcp_destroy(struct spdk_nvmf_transport *transport)
{
struct spdk_nvmf_tcp_transport *ttransport;
assert(transport != NULL);
ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
pthread_mutex_destroy(&ttransport->lock);
free(ttransport);
return 0;
}
static struct spdk_nvmf_transport *
spdk_nvmf_tcp_create(struct spdk_nvmf_transport_opts *opts)
{
struct spdk_nvmf_tcp_transport *ttransport;
uint32_t sge_count;
uint32_t min_shared_buffers;
ttransport = calloc(1, sizeof(*ttransport));
if (!ttransport) {
return NULL;
}
TAILQ_INIT(&ttransport->ports);
ttransport->transport.ops = &spdk_nvmf_transport_tcp;
SPDK_NOTICELOG("*** TCP Transport Init ***\n");
SPDK_INFOLOG(SPDK_LOG_NVMF_TCP, "*** TCP Transport Init ***\n"
" Transport opts: max_ioq_depth=%d, max_io_size=%d,\n"
" max_qpairs_per_ctrlr=%d, io_unit_size=%d,\n"
" in_capsule_data_size=%d, max_aq_depth=%d\n"
" num_shared_buffers=%d, c2h_success=%d\n",
opts->max_queue_depth,
opts->max_io_size,
opts->max_qpairs_per_ctrlr,
opts->io_unit_size,
opts->in_capsule_data_size,
opts->max_aq_depth,
opts->num_shared_buffers,
opts->c2h_success);
/* 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;
}
sge_count = opts->max_io_size / opts->io_unit_size;
if (sge_count > SPDK_NVMF_MAX_SGL_ENTRIES) {
SPDK_ERRLOG("Unsupported IO Unit size specified, %d bytes\n", opts->io_unit_size);
free(ttransport);
return NULL;
}
min_shared_buffers = spdk_thread_get_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");
spdk_nvmf_tcp_destroy(&ttransport->transport);
return NULL;
}
pthread_mutex_init(&ttransport->lock, NULL);
return &ttransport->transport;
}
static int
_spdk_nvmf_tcp_trsvcid_to_int(const char *trsvcid)
{
unsigned long long ull;
char *end = NULL;
ull = strtoull(trsvcid, &end, 10);
if (end == NULL || end == trsvcid || *end != '\0') {
return -1;
}
/* Valid TCP/IP port numbers are in [0, 65535] */
if (ull > 65535) {
return -1;
}
return (int)ull;
}
/**
* Canonicalize a listen address trid.
*/
static int
_spdk_nvmf_tcp_canon_listen_trid(struct spdk_nvme_transport_id *canon_trid,
const struct spdk_nvme_transport_id *trid)
{
int trsvcid_int;
trsvcid_int = _spdk_nvmf_tcp_trsvcid_to_int(trid->trsvcid);
if (trsvcid_int < 0) {
return -EINVAL;
}
memset(canon_trid, 0, sizeof(*canon_trid));
canon_trid->trtype = SPDK_NVME_TRANSPORT_TCP;
canon_trid->adrfam = trid->adrfam;
snprintf(canon_trid->traddr, sizeof(canon_trid->traddr), "%s", trid->traddr);
snprintf(canon_trid->trsvcid, sizeof(canon_trid->trsvcid), "%d", trsvcid_int);
return 0;
}
/**
* Find an existing listening port.
*
* Caller must hold ttransport->lock.
*/
static struct spdk_nvmf_tcp_port *
_spdk_nvmf_tcp_find_port(struct spdk_nvmf_tcp_transport *ttransport,
const struct spdk_nvme_transport_id *trid)
{
struct spdk_nvme_transport_id canon_trid;
struct spdk_nvmf_tcp_port *port;
if (_spdk_nvmf_tcp_canon_listen_trid(&canon_trid, trid) != 0) {
return NULL;
}
TAILQ_FOREACH(port, &ttransport->ports, link) {
if (spdk_nvme_transport_id_compare(&canon_trid, &port->trid) == 0) {
return port;
}
}
return NULL;
}
static int
spdk_nvmf_tcp_listen(struct spdk_nvmf_transport *transport,
const struct spdk_nvme_transport_id *trid)
{
struct spdk_nvmf_tcp_transport *ttransport;
struct spdk_nvmf_tcp_port *port;
int trsvcid_int;
uint8_t adrfam;
ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
trsvcid_int = _spdk_nvmf_tcp_trsvcid_to_int(trid->trsvcid);
if (trsvcid_int < 0) {
SPDK_ERRLOG("Invalid trsvcid '%s'\n", trid->trsvcid);
return -EINVAL;
}
pthread_mutex_lock(&ttransport->lock);
port = _spdk_nvmf_tcp_find_port(ttransport, trid);
if (port) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Already listening on %s port %s\n",
trid->traddr, trid->trsvcid);
port->ref++;
pthread_mutex_unlock(&ttransport->lock);
return 0;
}
port = calloc(1, sizeof(*port));
if (!port) {
SPDK_ERRLOG("Port allocation failed\n");
free(port);
pthread_mutex_unlock(&ttransport->lock);
return -ENOMEM;
}
port->ref = 1;
if (_spdk_nvmf_tcp_canon_listen_trid(&port->trid, trid) != 0) {
SPDK_ERRLOG("Invalid traddr %s / trsvcid %s\n",
trid->traddr, trid->trsvcid);
free(port);
pthread_mutex_unlock(&ttransport->lock);
return -ENOMEM;
}
port->listen_sock = spdk_sock_listen(trid->traddr, trsvcid_int);
if (port->listen_sock == NULL) {
SPDK_ERRLOG("spdk_sock_listen(%s, %d) failed: %s (%d)\n",
trid->traddr, trsvcid_int,
spdk_strerror(errno), errno);
free(port);
pthread_mutex_unlock(&ttransport->lock);
return -errno;
}
if (spdk_sock_is_ipv4(port->listen_sock)) {
adrfam = SPDK_NVMF_ADRFAM_IPV4;
} else if (spdk_sock_is_ipv6(port->listen_sock)) {
adrfam = SPDK_NVMF_ADRFAM_IPV6;
} else {
SPDK_ERRLOG("Unhandled socket type\n");
adrfam = 0;
}
if (adrfam != trid->adrfam) {
SPDK_ERRLOG("Socket address family mismatch\n");
spdk_sock_close(&port->listen_sock);
free(port);
pthread_mutex_unlock(&ttransport->lock);
return -EINVAL;
}
SPDK_NOTICELOG("*** NVMe/TCP Target Listening on %s port %d ***\n",
trid->traddr, trsvcid_int);
TAILQ_INSERT_TAIL(&ttransport->ports, port, link);
pthread_mutex_unlock(&ttransport->lock);
return 0;
}
static int
spdk_nvmf_tcp_stop_listen(struct spdk_nvmf_transport *transport,
const struct spdk_nvme_transport_id *trid)
{
struct spdk_nvmf_tcp_transport *ttransport;
struct spdk_nvmf_tcp_port *port;
int rc;
ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Removing listen address %s port %s\n",
trid->traddr, trid->trsvcid);
pthread_mutex_lock(&ttransport->lock);
port = _spdk_nvmf_tcp_find_port(ttransport, trid);
if (port) {
assert(port->ref > 0);
port->ref--;
if (port->ref == 0) {
TAILQ_REMOVE(&ttransport->ports, port, link);
spdk_sock_close(&port->listen_sock);
free(port);
}
rc = 0;
} else {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Port not found\n");
rc = -ENOENT;
}
pthread_mutex_unlock(&ttransport->lock);
return rc;
}
static int
spdk_nvmf_tcp_qpair_flush_pdus_internal(struct spdk_nvmf_tcp_qpair *tqpair)
{
const int array_size = 32;
struct iovec iovs[array_size];
int iovcnt = 0;
int bytes = 0;
int total_length = 0;
uint32_t mapped_length;
struct nvme_tcp_pdu *pdu;
int pdu_length;
TAILQ_HEAD(, nvme_tcp_pdu) completed_pdus_list;
struct spdk_nvmf_tcp_transport *ttransport;
pdu = TAILQ_FIRST(&tqpair->send_queue);
if (pdu == NULL) {
return 0;
}
/*
* Build up a list of iovecs for the first few PDUs in the
* tqpair 's send_queue.
*/
while (pdu != NULL && ((array_size - iovcnt) >= 3)) {
iovcnt += nvme_tcp_build_iovs(&iovs[iovcnt],
array_size - iovcnt,
pdu,
tqpair->host_hdgst_enable,
tqpair->host_ddgst_enable,
&mapped_length);
total_length += mapped_length;
pdu = TAILQ_NEXT(pdu, tailq);
}
spdk_trace_record(TRACE_TCP_FLUSH_WRITEBUF_START, 0, total_length, 0, iovcnt);
bytes = spdk_sock_writev(tqpair->sock, iovs, iovcnt);
if (bytes == -1) {
if (errno == EWOULDBLOCK || errno == EAGAIN) {
return 1;
} else {
SPDK_ERRLOG("spdk_sock_writev() failed, errno %d: %s\n",
errno, spdk_strerror(errno));
return -1;
}
}
spdk_trace_record(TRACE_TCP_FLUSH_WRITEBUF_DONE, 0, bytes, 0, 0);
pdu = TAILQ_FIRST(&tqpair->send_queue);
/*
* Free any PDUs that were fully written. If a PDU was only
* partially written, update its writev_offset so that next
* time only the unwritten portion will be sent to writev().
*/
TAILQ_INIT(&completed_pdus_list);
while (bytes > 0) {
pdu_length = pdu->hdr.common.plen - pdu->writev_offset;
if (bytes >= pdu_length) {
bytes -= pdu_length;
TAILQ_REMOVE(&tqpair->send_queue, pdu, tailq);
TAILQ_INSERT_TAIL(&completed_pdus_list, pdu, tailq);
pdu = TAILQ_FIRST(&tqpair->send_queue);
} else {
pdu->writev_offset += bytes;
bytes = 0;
}
}
while (!TAILQ_EMPTY(&completed_pdus_list)) {
pdu = TAILQ_FIRST(&completed_pdus_list);
TAILQ_REMOVE(&completed_pdus_list, pdu, tailq);
assert(pdu->cb_fn != NULL);
pdu->cb_fn(pdu->cb_arg);
spdk_nvmf_tcp_pdu_put(tqpair, pdu);
}
ttransport = SPDK_CONTAINEROF(tqpair->qpair.transport, struct spdk_nvmf_tcp_transport, transport);
spdk_nvmf_tcp_qpair_process_pending(ttransport, tqpair);
return TAILQ_EMPTY(&tqpair->send_queue) ? 0 : 1;
}
static int
spdk_nvmf_tcp_qpair_flush_pdus(void *_tqpair)
{
struct spdk_nvmf_tcp_qpair *tqpair = _tqpair;
int rc;
if (tqpair->state == NVME_TCP_QPAIR_STATE_RUNNING) {
rc = spdk_nvmf_tcp_qpair_flush_pdus_internal(tqpair);
if (rc == 0 && tqpair->flush_poller != NULL) {
spdk_poller_unregister(&tqpair->flush_poller);
} else if (rc == 1 && tqpair->flush_poller == NULL) {
tqpair->flush_poller = spdk_poller_register(spdk_nvmf_tcp_qpair_flush_pdus,
tqpair, 50);
}
} else {
/*
* If the tqpair state is not RUNNING, then
* keep trying to flush PDUs until our list is
* empty - to make sure all data is sent before
* closing the connection.
*/
do {
rc = spdk_nvmf_tcp_qpair_flush_pdus_internal(tqpair);
} while (rc == 1);
}
if (rc < 0 && tqpair->state < NVME_TCP_QPAIR_STATE_EXITING) {
/*
* If the poller has already started destruction of the tqpair,
* i.e. the socket read failed, then the connection state may already
* be EXITED. We don't want to set it back to EXITING in that case.
*/
tqpair->state = NVME_TCP_QPAIR_STATE_EXITING;
}
return -1;
}
static void
spdk_nvmf_tcp_qpair_write_pdu(struct spdk_nvmf_tcp_qpair *tqpair,
struct nvme_tcp_pdu *pdu,
nvme_tcp_qpair_xfer_complete_cb cb_fn,
void *cb_arg)
{
int enable_digest;
int hlen;
uint32_t crc32c;
hlen = pdu->hdr.common.hlen;
enable_digest = 1;
if (pdu->hdr.common.pdu_type == SPDK_NVME_TCP_PDU_TYPE_IC_RESP ||
pdu->hdr.common.pdu_type == SPDK_NVME_TCP_PDU_TYPE_C2H_TERM_REQ) {
/* this PDU should be sent without digest */
enable_digest = 0;
}
/* Header Digest */
if (enable_digest && tqpair->host_hdgst_enable) {
crc32c = nvme_tcp_pdu_calc_header_digest(pdu);
MAKE_DIGEST_WORD((uint8_t *)pdu->hdr.raw + hlen, crc32c);
}
/* Data Digest */
if (pdu->data_len > 0 && enable_digest && tqpair->host_ddgst_enable) {
crc32c = nvme_tcp_pdu_calc_data_digest(pdu);
MAKE_DIGEST_WORD(pdu->data_digest, crc32c);
}
pdu->cb_fn = cb_fn;
pdu->cb_arg = cb_arg;
TAILQ_INSERT_TAIL(&tqpair->send_queue, pdu, tailq);
spdk_nvmf_tcp_qpair_flush_pdus(tqpair);
}
static int
spdk_nvmf_tcp_qpair_init_mem_resource(struct spdk_nvmf_tcp_qpair *tqpair, uint16_t size)
{
int i;
struct spdk_nvmf_tcp_req *tcp_req;
struct spdk_nvmf_transport *transport = tqpair->qpair.transport;
struct spdk_nvmf_tcp_transport *ttransport;
ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
if (!tqpair->qpair.sq_head_max) {
tqpair->req = calloc(1, sizeof(*tqpair->req));
if (!tqpair->req) {
SPDK_ERRLOG("Unable to allocate req on tqpair=%p.\n", tqpair);
return -1;
}
if (transport->opts.in_capsule_data_size) {
tqpair->buf = spdk_dma_zmalloc(ttransport->transport.opts.in_capsule_data_size, 0x1000, NULL);
if (!tqpair->buf) {
SPDK_ERRLOG("Unable to allocate buf on tqpair=%p.\n", tqpair);
return -1;
}
}
tcp_req = tqpair->req;
tcp_req->ttag = 0;
tcp_req->req.qpair = &tqpair->qpair;
/* Set up memory to receive commands */
if (tqpair->buf) {
tcp_req->buf = tqpair->buf;
}
/* Set the cmdn and rsp */
tcp_req->req.rsp = (union nvmf_c2h_msg *)&tcp_req->rsp;
tcp_req->req.cmd = (union nvmf_h2c_msg *)&tcp_req->cmd;
/* Initialize request state to FREE */
tcp_req->state = TCP_REQUEST_STATE_FREE;
TAILQ_INSERT_TAIL(&tqpair->state_queue[tcp_req->state], tcp_req, state_link);
tqpair->pdu = calloc(NVMF_TCP_QPAIR_MAX_C2H_PDU_NUM + 1, sizeof(*tqpair->pdu));
if (!tqpair->pdu) {
SPDK_ERRLOG("Unable to allocate pdu on tqpair=%p.\n", tqpair);
return -1;
}
for (i = 0; i < 1 + NVMF_TCP_QPAIR_MAX_C2H_PDU_NUM; i++) {
TAILQ_INSERT_TAIL(&tqpair->free_queue, &tqpair->pdu[i], tailq);
}
} else {
tqpair->reqs = calloc(size, sizeof(*tqpair->reqs));
if (!tqpair->reqs) {
SPDK_ERRLOG("Unable to allocate reqs on tqpair=%p\n", tqpair);
return -1;
}
if (transport->opts.in_capsule_data_size) {
tqpair->bufs = spdk_dma_zmalloc(size * transport->opts.in_capsule_data_size,
0x1000, NULL);
if (!tqpair->bufs) {
SPDK_ERRLOG("Unable to allocate bufs on tqpair=%p.\n", tqpair);
return -1;
}
}
for (i = 0; i < size; i++) {
struct spdk_nvmf_tcp_req *tcp_req = &tqpair->reqs[i];
tcp_req->ttag = i + 1;
tcp_req->req.qpair = &tqpair->qpair;
/* Set up memory to receive commands */
if (tqpair->bufs) {
tcp_req->buf = (void *)((uintptr_t)tqpair->bufs + (i * transport->opts.in_capsule_data_size));
}
/* Set the cmdn and rsp */
tcp_req->req.rsp = (union nvmf_c2h_msg *)&tcp_req->rsp;
tcp_req->req.cmd = (union nvmf_h2c_msg *)&tcp_req->cmd;
/* Initialize request state to FREE */
tcp_req->state = TCP_REQUEST_STATE_FREE;
TAILQ_INSERT_TAIL(&tqpair->state_queue[tcp_req->state], tcp_req, state_link);
}
tqpair->pdu_pool = calloc(size, sizeof(*tqpair->pdu_pool));
if (!tqpair->pdu_pool) {
SPDK_ERRLOG("Unable to allocate pdu pool on tqpair =%p.\n", tqpair);
return -1;
}
for (i = 0; i < size; i++) {
TAILQ_INSERT_TAIL(&tqpair->free_queue, &tqpair->pdu_pool[i], tailq);
}
}
return 0;
}
static int
spdk_nvmf_tcp_qpair_init(struct spdk_nvmf_qpair *qpair)
{
struct spdk_nvmf_tcp_qpair *tqpair;
int i;
tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "New TCP Connection: %p\n", qpair);
TAILQ_INIT(&tqpair->send_queue);
TAILQ_INIT(&tqpair->free_queue);
TAILQ_INIT(&tqpair->queued_c2h_data_tcp_req);
/* Initialise request state queues of the qpair */
for (i = TCP_REQUEST_STATE_FREE; i < TCP_REQUEST_NUM_STATES; i++) {
TAILQ_INIT(&tqpair->state_queue[i]);
}
tqpair->host_hdgst_enable = true;
tqpair->host_ddgst_enable = true;
return 0;
}
static int
spdk_nvmf_tcp_qpair_sock_init(struct spdk_nvmf_tcp_qpair *tqpair)
{
int rc;
int buf_size;
/* set recv buffer size */
buf_size = 2 * 1024 * 1024;
rc = spdk_sock_set_recvbuf(tqpair->sock, buf_size);
if (rc != 0) {
SPDK_ERRLOG("spdk_sock_set_recvbuf failed\n");
return rc;
}
/* set send buffer size */
rc = spdk_sock_set_sendbuf(tqpair->sock, buf_size);
if (rc != 0) {
SPDK_ERRLOG("spdk_sock_set_sendbuf failed\n");
return rc;
}
/* set low water mark */
rc = spdk_sock_set_recvlowat(tqpair->sock, sizeof(struct spdk_nvme_tcp_c2h_data_hdr));
if (rc != 0) {
SPDK_ERRLOG("spdk_sock_set_recvlowat() failed\n");
return rc;
}
return 0;
}
static void
_spdk_nvmf_tcp_handle_connect(struct spdk_nvmf_transport *transport,
struct spdk_nvmf_tcp_port *port,
struct spdk_sock *sock, new_qpair_fn cb_fn)
{
struct spdk_nvmf_tcp_qpair *tqpair;
int rc;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "New connection accepted on %s port %s\n",
port->trid.traddr, port->trid.trsvcid);
tqpair = calloc(1, sizeof(struct spdk_nvmf_tcp_qpair));
if (tqpair == NULL) {
SPDK_ERRLOG("Could not allocate new connection.\n");
spdk_sock_close(&sock);
return;
}
tqpair->sock = sock;
tqpair->max_queue_depth = 1;
tqpair->free_pdu_num = tqpair->max_queue_depth + NVMF_TCP_QPAIR_MAX_C2H_PDU_NUM;
tqpair->state_cntr[TCP_REQUEST_STATE_FREE] = tqpair->max_queue_depth;
tqpair->port = port;
tqpair->qpair.transport = transport;
rc = spdk_sock_getaddr(tqpair->sock, tqpair->target_addr,
sizeof(tqpair->target_addr), &tqpair->target_port,
tqpair->initiator_addr, sizeof(tqpair->initiator_addr),
&tqpair->initiator_port);
if (rc < 0) {
SPDK_ERRLOG("spdk_sock_getaddr() failed of tqpair=%p\n", tqpair);
spdk_nvmf_tcp_qpair_destroy(tqpair);
return;
}
cb_fn(&tqpair->qpair);
}
static void
spdk_nvmf_tcp_port_accept(struct spdk_nvmf_transport *transport, struct spdk_nvmf_tcp_port *port,
new_qpair_fn cb_fn)
{
struct spdk_sock *sock;
int i;
for (i = 0; i < NVMF_TCP_MAX_ACCEPT_SOCK_ONE_TIME; i++) {
sock = spdk_sock_accept(port->listen_sock);
if (sock) {
_spdk_nvmf_tcp_handle_connect(transport, port, sock, cb_fn);
}
}
}
static void
spdk_nvmf_tcp_accept(struct spdk_nvmf_transport *transport, new_qpair_fn cb_fn)
{
struct spdk_nvmf_tcp_transport *ttransport;
struct spdk_nvmf_tcp_port *port;
ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
TAILQ_FOREACH(port, &ttransport->ports, link) {
spdk_nvmf_tcp_port_accept(transport, port, cb_fn);
}
}
static void
spdk_nvmf_tcp_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_TCP;
entry->adrfam = trid->adrfam;
entry->treq.secure_channel = SPDK_NVMF_TREQ_SECURE_CHANNEL_NOT_SPECIFIED;
spdk_strcpy_pad(entry->trsvcid, trid->trsvcid, sizeof(entry->trsvcid), ' ');
spdk_strcpy_pad(entry->traddr, trid->traddr, sizeof(entry->traddr), ' ');
entry->tsas.tcp.sectype = SPDK_NVME_TCP_SECURITY_NONE;
}
static struct spdk_nvmf_transport_poll_group *
spdk_nvmf_tcp_poll_group_create(struct spdk_nvmf_transport *transport)
{
struct spdk_nvmf_tcp_poll_group *tgroup;
tgroup = calloc(1, sizeof(*tgroup));
if (!tgroup) {
return NULL;
}
tgroup->sock_group = spdk_sock_group_create(NULL);
if (!tgroup->sock_group) {
goto cleanup;
}
TAILQ_INIT(&tgroup->qpairs);
TAILQ_INIT(&tgroup->pending_data_buf_queue);
return &tgroup->group;
cleanup:
free(tgroup);
return NULL;
}
static void
spdk_nvmf_tcp_poll_group_destroy(struct spdk_nvmf_transport_poll_group *group)
{
struct spdk_nvmf_tcp_poll_group *tgroup;
tgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_tcp_poll_group, group);
spdk_sock_group_close(&tgroup->sock_group);
if (!TAILQ_EMPTY(&tgroup->pending_data_buf_queue)) {
SPDK_ERRLOG("Pending I/O list wasn't empty on poll group destruction\n");
}
free(tgroup);
}
static void
spdk_nvmf_tcp_qpair_set_recv_state(struct spdk_nvmf_tcp_qpair *tqpair,
enum nvme_tcp_pdu_recv_state state)
{
if (tqpair->recv_state == state) {
SPDK_ERRLOG("The recv state of tqpair=%p is same with the state(%d) to be set\n",
tqpair, state);
return;
}
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "tqpair(%p) recv state=%d\n", tqpair, state);
tqpair->recv_state = state;
switch (state) {
case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_CH:
case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PSH:
case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PAYLOAD:
break;
case NVME_TCP_PDU_RECV_STATE_ERROR:
case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY:
memset(&tqpair->pdu_in_progress, 0, sizeof(tqpair->pdu_in_progress));
break;
default:
SPDK_ERRLOG("The state(%d) is invalid\n", state);
abort();
break;
}
}
static int
spdk_nvmf_tcp_qpair_handle_timeout(void *ctx)
{
struct spdk_nvmf_tcp_qpair *tqpair = ctx;
assert(tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_ERROR);
SPDK_ERRLOG("No pdu coming for tqpair=%p within %d seconds\n", tqpair,
SPDK_NVME_TCP_QPAIR_EXIT_TIMEOUT);
tqpair->state = NVME_TCP_QPAIR_STATE_EXITED;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "will disconect the tqpair=%p\n", tqpair);
spdk_poller_unregister(&tqpair->timeout_poller);
spdk_nvmf_qpair_disconnect(&tqpair->qpair, NULL, NULL);
return 0;
}
static void
spdk_nvmf_tcp_send_c2h_term_req_complete(void *cb_arg)
{
struct spdk_nvmf_tcp_qpair *tqpair = (struct spdk_nvmf_tcp_qpair *)cb_arg;
if (!tqpair->timeout_poller) {
tqpair->timeout_poller = spdk_poller_register(spdk_nvmf_tcp_qpair_handle_timeout, tqpair,
SPDK_NVME_TCP_QPAIR_EXIT_TIMEOUT * 1000000);
}
}
static void
spdk_nvmf_tcp_send_c2h_term_req(struct spdk_nvmf_tcp_qpair *tqpair, struct nvme_tcp_pdu *pdu,
enum spdk_nvme_tcp_term_req_fes fes, uint32_t error_offset)
{
struct nvme_tcp_pdu *rsp_pdu;
struct spdk_nvme_tcp_term_req_hdr *c2h_term_req;
uint32_t c2h_term_req_hdr_len = sizeof(*c2h_term_req);
uint32_t copy_len;
rsp_pdu = spdk_nvmf_tcp_pdu_get(tqpair);
if (!rsp_pdu) {
tqpair->state = NVME_TCP_QPAIR_STATE_EXITING;
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_ERROR);
return;
}
c2h_term_req = &rsp_pdu->hdr.term_req;
c2h_term_req->common.pdu_type = SPDK_NVME_TCP_PDU_TYPE_C2H_TERM_REQ;
c2h_term_req->common.hlen = c2h_term_req_hdr_len;
if ((fes == SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD) ||
(fes == SPDK_NVME_TCP_TERM_REQ_FES_INVALID_DATA_UNSUPPORTED_PARAMETER)) {
DSET32(&c2h_term_req->fei, error_offset);
}
copy_len = pdu->hdr.common.hlen;
if (copy_len > SPDK_NVME_TCP_TERM_REQ_ERROR_DATA_MAX_SIZE) {
copy_len = SPDK_NVME_TCP_TERM_REQ_ERROR_DATA_MAX_SIZE;
}
/* Copy the error info into the buffer */
memcpy((uint8_t *)rsp_pdu->hdr.raw + c2h_term_req_hdr_len, pdu->hdr.raw, copy_len);
nvme_tcp_pdu_set_data(rsp_pdu, (uint8_t *)rsp_pdu->hdr.raw + c2h_term_req_hdr_len, copy_len);
/* Contain the header of the wrong received pdu */
c2h_term_req->common.plen = c2h_term_req->common.hlen + copy_len;
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_ERROR);
spdk_nvmf_tcp_qpair_write_pdu(tqpair, rsp_pdu, spdk_nvmf_tcp_send_c2h_term_req_complete, tqpair);
}
static void
spdk_nvmf_tcp_capsule_cmd_hdr_handle(struct spdk_nvmf_tcp_transport *ttransport,
struct spdk_nvmf_tcp_qpair *tqpair,
struct nvme_tcp_pdu *pdu)
{
struct spdk_nvmf_tcp_req *tcp_req;
tcp_req = spdk_nvmf_tcp_req_get(tqpair);
if (!tcp_req) {
SPDK_ERRLOG("Cannot allocate tcp_req\n");
tqpair->state = NVME_TCP_QPAIR_STATE_EXITING;
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_ERROR);
return;
}
pdu->ctx = tcp_req;
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_NEW);
spdk_nvmf_tcp_req_process(ttransport, tcp_req);
return;
}
static void
spdk_nvmf_tcp_capsule_cmd_payload_handle(struct spdk_nvmf_tcp_transport *ttransport,
struct spdk_nvmf_tcp_qpair *tqpair,
struct nvme_tcp_pdu *pdu)
{
struct spdk_nvmf_tcp_req *tcp_req;
struct spdk_nvme_tcp_cmd *capsule_cmd;
uint32_t error_offset = 0;
enum spdk_nvme_tcp_term_req_fes fes;
capsule_cmd = &pdu->hdr.capsule_cmd;
tcp_req = pdu->ctx;
assert(tcp_req != NULL);
if (capsule_cmd->common.pdo > SPDK_NVME_TCP_PDU_PDO_MAX_OFFSET) {
SPDK_ERRLOG("Expected ICReq capsule_cmd pdu offset <= %d, got %c\n",
SPDK_NVME_TCP_PDU_PDO_MAX_OFFSET, capsule_cmd->common.pdo);
fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
error_offset = offsetof(struct spdk_nvme_tcp_common_pdu_hdr, pdo);
goto err;
}
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY);
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_EXECUTE);
spdk_nvmf_tcp_req_process(ttransport, tcp_req);
return;
err:
spdk_nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
}
static void
spdk_nvmf_tcp_h2c_data_hdr_handle(struct spdk_nvmf_tcp_transport *ttransport,
struct spdk_nvmf_tcp_qpair *tqpair,
struct nvme_tcp_pdu *pdu)
{
struct spdk_nvmf_tcp_req *tcp_req;
uint32_t error_offset = 0;
enum spdk_nvme_tcp_term_req_fes fes = 0;
struct spdk_nvme_tcp_h2c_data_hdr *h2c_data;
bool ttag_offset_error = false;
h2c_data = &pdu->hdr.h2c_data;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "tqpair=%p, r2t_info: datao=%u, datal=%u, cccid=%u, ttag=%u\n",
tqpair, h2c_data->datao, h2c_data->datal, h2c_data->cccid, h2c_data->ttag);
/* According to the information in the pdu to find the req */
TAILQ_FOREACH(tcp_req, &tqpair->state_queue[TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER],
state_link) {
if ((tcp_req->req.cmd->nvme_cmd.cid == h2c_data->cccid) && (tcp_req->ttag == h2c_data->ttag)) {
break;
}
if (!ttag_offset_error && (tcp_req->req.cmd->nvme_cmd.cid == h2c_data->cccid)) {
ttag_offset_error = true;
}
}
if (!tcp_req) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "tcp_req is not found for tqpair=%p\n", tqpair);
fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_DATA_UNSUPPORTED_PARAMETER;
if (!ttag_offset_error) {
error_offset = offsetof(struct spdk_nvme_tcp_h2c_data_hdr, cccid);
} else {
error_offset = offsetof(struct spdk_nvme_tcp_h2c_data_hdr, ttag);
}
goto err;
}
if (tcp_req->next_expected_r2t_offset != h2c_data->datao) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP,
"tcp_req(%p), tqpair=%p, expected_r2t_offset=%u, but data offset =%u\n",
tcp_req, tqpair, tcp_req->next_expected_r2t_offset, h2c_data->datao);
fes = SPDK_NVME_TCP_TERM_REQ_FES_DATA_TRANSFER_OUT_OF_RANGE;
goto err;
}
if (h2c_data->datal > tqpair->maxh2cdata) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "tcp_req(%p), tqpair=%p, datao=%u execeeds maxh2cdata size=%u\n",
tcp_req, tqpair, h2c_data->datao, tqpair->maxh2cdata);
fes = SPDK_NVME_TCP_TERM_REQ_FES_DATA_TRANSFER_OUT_OF_RANGE;
goto err;
}
if ((h2c_data->datao + h2c_data->datal) > tcp_req->req.length) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP,
"tcp_req(%p), tqpair=%p, (datao=%u + datal=%u) execeeds requested length=%u\n",
tcp_req, tqpair, h2c_data->datao, h2c_data->datal, tcp_req->req.length);
fes = SPDK_NVME_TCP_TERM_REQ_FES_R2T_LIMIT_EXCEEDED;
goto err;
}
pdu->ctx = tcp_req;
nvme_tcp_pdu_set_data_buf(pdu, tcp_req->req.iov, tcp_req->req.iovcnt,
h2c_data->datao, h2c_data->datal);
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PAYLOAD);
return;
err:
spdk_nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
}
static void
spdk_nvmf_tcp_pdu_cmd_complete(void *cb_arg)
{
struct spdk_nvmf_tcp_req *tcp_req = cb_arg;
nvmf_tcp_request_free(tcp_req);
}
static void
spdk_nvmf_tcp_send_capsule_resp_pdu(struct spdk_nvmf_tcp_req *tcp_req,
struct spdk_nvmf_tcp_qpair *tqpair)
{
struct nvme_tcp_pdu *rsp_pdu;
struct spdk_nvme_tcp_rsp *capsule_resp;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "enter, tqpair=%p\n", tqpair);
rsp_pdu = spdk_nvmf_tcp_pdu_get(tqpair);
if (!rsp_pdu) {
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_ERROR);
tqpair->state = NVME_TCP_QPAIR_STATE_EXITING;
return;
}
capsule_resp = &rsp_pdu->hdr.capsule_resp;
capsule_resp->common.pdu_type = SPDK_NVME_TCP_PDU_TYPE_CAPSULE_RESP;
capsule_resp->common.plen = capsule_resp->common.hlen = sizeof(*capsule_resp);
capsule_resp->rccqe = tcp_req->req.rsp->nvme_cpl;
if (tqpair->host_hdgst_enable) {
capsule_resp->common.flags |= SPDK_NVME_TCP_CH_FLAGS_HDGSTF;
capsule_resp->common.plen += SPDK_NVME_TCP_DIGEST_LEN;
}
spdk_nvmf_tcp_qpair_write_pdu(tqpair, rsp_pdu, spdk_nvmf_tcp_pdu_cmd_complete, tcp_req);
}
static void
spdk_nvmf_tcp_pdu_c2h_data_complete(void *cb_arg)
{
struct spdk_nvmf_tcp_req *tcp_req = cb_arg;
struct spdk_nvmf_tcp_qpair *tqpair = SPDK_CONTAINEROF(tcp_req->req.qpair,
struct spdk_nvmf_tcp_qpair, qpair);
assert(tqpair != NULL);
assert(tcp_req->c2h_data_pdu_num > 0);
tcp_req->c2h_data_pdu_num--;
if (!tcp_req->c2h_data_pdu_num) {
if (tqpair->qpair.transport->opts.c2h_success) {
nvmf_tcp_request_free(tcp_req);
} else {
spdk_nvmf_tcp_send_capsule_resp_pdu(tcp_req, tqpair);
}
}
tqpair->c2h_data_pdu_cnt--;
spdk_nvmf_tcp_handle_pending_c2h_data_queue(tqpair);
}
static void
spdk_nvmf_tcp_send_r2t_pdu(struct spdk_nvmf_tcp_qpair *tqpair,
struct spdk_nvmf_tcp_req *tcp_req)
{
struct nvme_tcp_pdu *rsp_pdu;
struct spdk_nvme_tcp_r2t_hdr *r2t;
rsp_pdu = spdk_nvmf_tcp_pdu_get(tqpair);
if (!rsp_pdu) {
tqpair->state = NVME_TCP_QPAIR_STATE_EXITING;
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_ERROR);
return;
}
r2t = &rsp_pdu->hdr.r2t;
r2t->common.pdu_type = SPDK_NVME_TCP_PDU_TYPE_R2T;
r2t->common.plen = r2t->common.hlen = sizeof(*r2t);
if (tqpair->host_hdgst_enable) {
r2t->common.flags |= SPDK_NVME_TCP_CH_FLAGS_HDGSTF;
r2t->common.plen += SPDK_NVME_TCP_DIGEST_LEN;
}
r2t->cccid = tcp_req->req.cmd->nvme_cmd.cid;
r2t->ttag = tcp_req->ttag;
r2t->r2to = tcp_req->next_expected_r2t_offset;
r2t->r2tl = spdk_min(tcp_req->req.length - tcp_req->next_expected_r2t_offset, tqpair->maxh2cdata);
tcp_req->r2tl_remain = r2t->r2tl;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP,
"tcp_req(%p) on tqpair(%p), r2t_info: cccid=%u, ttag=%u, r2to=%u, r2tl=%u\n",
tcp_req, tqpair, r2t->cccid, r2t->ttag, r2t->r2to, r2t->r2tl);
spdk_nvmf_tcp_qpair_write_pdu(tqpair, rsp_pdu, spdk_nvmf_tcp_pdu_cmd_complete, NULL);
}
static void
spdk_nvmf_tcp_h2c_data_payload_handle(struct spdk_nvmf_tcp_transport *ttransport,
struct spdk_nvmf_tcp_qpair *tqpair,
struct nvme_tcp_pdu *pdu)
{
struct spdk_nvmf_tcp_req *tcp_req;
tcp_req = pdu->ctx;
assert(tcp_req != NULL);
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "enter\n");
tcp_req->next_expected_r2t_offset += pdu->data_len;
tcp_req->r2tl_remain -= pdu->data_len;
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY);
if (!tcp_req->r2tl_remain) {
if (tcp_req->next_expected_r2t_offset == tcp_req->req.length) {
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_EXECUTE);
spdk_nvmf_tcp_req_process(ttransport, tcp_req);
} else {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Send r2t pdu for tcp_req=%p on tqpair=%p\n", tcp_req, tqpair);
spdk_nvmf_tcp_send_r2t_pdu(tqpair, tcp_req);
}
}
}
static void
spdk_nvmf_tcp_h2c_term_req_dump(struct spdk_nvme_tcp_term_req_hdr *h2c_term_req)
{
SPDK_ERRLOG("Error info of pdu(%p): %s\n", h2c_term_req,
spdk_nvmf_tcp_term_req_fes_str[h2c_term_req->fes]);
if ((h2c_term_req->fes == SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD) ||
(h2c_term_req->fes == SPDK_NVME_TCP_TERM_REQ_FES_INVALID_DATA_UNSUPPORTED_PARAMETER)) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "The offset from the start of the PDU header is %u\n",
DGET32(h2c_term_req->fei));
}
}
static void
spdk_nvmf_tcp_h2c_term_req_hdr_handle(struct spdk_nvmf_tcp_qpair *tqpair,
struct nvme_tcp_pdu *pdu)
{
struct spdk_nvme_tcp_term_req_hdr *h2c_term_req = &pdu->hdr.term_req;
uint32_t error_offset = 0;
enum spdk_nvme_tcp_term_req_fes fes;
if (h2c_term_req->fes > SPDK_NVME_TCP_TERM_REQ_FES_INVALID_DATA_UNSUPPORTED_PARAMETER) {
SPDK_ERRLOG("Fatal Error Stauts(FES) is unknown for h2c_term_req pdu=%p\n", pdu);
fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
error_offset = offsetof(struct spdk_nvme_tcp_term_req_hdr, fes);
goto end;
}
/* set the data buffer */
nvme_tcp_pdu_set_data(pdu, (uint8_t *)pdu->hdr.raw + h2c_term_req->common.hlen,
h2c_term_req->common.plen - h2c_term_req->common.hlen);
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PAYLOAD);
return;
end:
spdk_nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
return;
}
static void
spdk_nvmf_tcp_h2c_term_req_payload_handle(struct spdk_nvmf_tcp_qpair *tqpair,
struct nvme_tcp_pdu *pdu)
{
struct spdk_nvme_tcp_term_req_hdr *h2c_term_req = &pdu->hdr.term_req;
spdk_nvmf_tcp_h2c_term_req_dump(h2c_term_req);
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_ERROR);
return;
}
static void
spdk_nvmf_tcp_pdu_payload_handle(struct spdk_nvmf_tcp_qpair *tqpair)
{
int rc = 0;
struct nvme_tcp_pdu *pdu;
uint32_t crc32c, error_offset = 0;
enum spdk_nvme_tcp_term_req_fes fes;
struct spdk_nvmf_tcp_transport *ttransport;
assert(tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PAYLOAD);
pdu = &tqpair->pdu_in_progress;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "enter\n");
/* check data digest if need */
if (pdu->ddgst_enable) {
crc32c = nvme_tcp_pdu_calc_data_digest(pdu);
rc = MATCH_DIGEST_WORD(pdu->data_digest, crc32c);
if (rc == 0) {
SPDK_ERRLOG("Data digest error on tqpair=(%p) with pdu=%p\n", tqpair, pdu);
fes = SPDK_NVME_TCP_TERM_REQ_FES_HDGST_ERROR;
spdk_nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
return;
}
}
ttransport = SPDK_CONTAINEROF(tqpair->qpair.transport, struct spdk_nvmf_tcp_transport, transport);
switch (pdu->hdr.common.pdu_type) {
case SPDK_NVME_TCP_PDU_TYPE_CAPSULE_CMD:
spdk_nvmf_tcp_capsule_cmd_payload_handle(ttransport, tqpair, pdu);
break;
case SPDK_NVME_TCP_PDU_TYPE_H2C_DATA:
spdk_nvmf_tcp_h2c_data_payload_handle(ttransport, tqpair, pdu);
break;
case SPDK_NVME_TCP_PDU_TYPE_H2C_TERM_REQ:
spdk_nvmf_tcp_h2c_term_req_payload_handle(tqpair, pdu);
break;
default:
/* The code should not go to here */
SPDK_ERRLOG("The code should not go to here\n");
break;
}
}
static void
spdk_nvmf_tcp_send_icresp_complete(void *cb_arg)
{
struct spdk_nvmf_tcp_qpair *tqpair = cb_arg;
tqpair->state = NVME_TCP_QPAIR_STATE_RUNNING;
}
static void
spdk_nvmf_tcp_icreq_handle(struct spdk_nvmf_tcp_transport *ttransport,
struct spdk_nvmf_tcp_qpair *tqpair,
struct nvme_tcp_pdu *pdu)
{
struct spdk_nvme_tcp_ic_req *ic_req = &pdu->hdr.ic_req;
struct nvme_tcp_pdu *rsp_pdu;
struct spdk_nvme_tcp_ic_resp *ic_resp;
uint32_t error_offset = 0;
enum spdk_nvme_tcp_term_req_fes fes;
/* Only PFV 0 is defined currently */
if (ic_req->pfv != 0) {
SPDK_ERRLOG("Expected ICReq PFV %u, got %u\n", 0u, ic_req->pfv);
fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
error_offset = offsetof(struct spdk_nvme_tcp_ic_req, pfv);
goto end;
}
/* MAXR2T is 0's based */
nvmf/tcp: Support single r2t usage According to the TP 8000 spec in Page 26: Maximum Number of Outstanding R2T (MAXR2T): Specifies the maximum number of outstanding R2T PDUs for a command at any point in time on the connection. Note that by the spec, the target may only support single r2t (which is the minimum possible), it doesn't have to use multiple r2ts even if the initiator supports that. So remove the maxr2t and pending_r2t variable in the tcp qpair structure. In the original design, we think that maxr2t is the maximal active r2t numbers for each connection. So if the initiator sends out maxr2t=16, it means that all the commands of a qpair can use such number of R2T pdus. So we need to wait for the available R2Ts for the request when the maxr2t reaches the maximal value. But it is the wrong understanding of the spec. In fact, each command has its own number of maximal r2t numbers, then we do not need to use the wait method for R2T method anymore. So we remove the state TCP_REQUEST_STATE_DATA_PENDING_FOR_R2T. Futhermore, we adjust the related SPDK_TPOINT_ID definition. In current patch, the target will support one active R2T for each write NVMe command. Thus, we remove the function spdk_nvmf_tcp_handle_queued_r2t_req. Reported-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Ziye Yang <ziye.yang@intel.com> Change-Id: I7547b8facbc39139b4584637ccc51ba8b33ca285 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/455763 Reviewed-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com> Reviewed-by: Or Gerlitz <gerlitz.or@gmail.com> Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
2019-05-27 12:45:58 +00:00
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "maxr2t =%u\n", (ic_req->maxr2t + 1u));
tqpair->host_hdgst_enable = ic_req->dgst.bits.hdgst_enable ? true : false;
tqpair->host_ddgst_enable = ic_req->dgst.bits.ddgst_enable ? true : false;
tqpair->cpda = spdk_min(ic_req->hpda, SPDK_NVME_TCP_CPDA_MAX);
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "cpda of tqpair=(%p) is : %u\n", tqpair, tqpair->cpda);
rsp_pdu = spdk_nvmf_tcp_pdu_get(tqpair);
if (!rsp_pdu) {
tqpair->state = NVME_TCP_QPAIR_STATE_EXITING;
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_ERROR);
return;
}
ic_resp = &rsp_pdu->hdr.ic_resp;
ic_resp->common.pdu_type = SPDK_NVME_TCP_PDU_TYPE_IC_RESP;
ic_resp->common.hlen = ic_resp->common.plen = sizeof(*ic_resp);
ic_resp->pfv = 0;
ic_resp->cpda = tqpair->cpda;
tqpair->maxh2cdata = spdk_min(NVMF_TCP_PDU_MAX_H2C_DATA_SIZE,
ttransport->transport.opts.io_unit_size);
ic_resp->maxh2cdata = tqpair->maxh2cdata;
ic_resp->dgst.bits.hdgst_enable = tqpair->host_hdgst_enable ? 1 : 0;
ic_resp->dgst.bits.ddgst_enable = tqpair->host_ddgst_enable ? 1 : 0;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "host_hdgst_enable: %u\n", tqpair->host_hdgst_enable);
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "host_ddgst_enable: %u\n", tqpair->host_ddgst_enable);
spdk_nvmf_tcp_qpair_write_pdu(tqpair, rsp_pdu, spdk_nvmf_tcp_send_icresp_complete, tqpair);
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY);
return;
end:
spdk_nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
return;
}
static void
spdk_nvmf_tcp_pdu_psh_handle(struct spdk_nvmf_tcp_qpair *tqpair)
{
struct nvme_tcp_pdu *pdu;
int rc;
uint32_t crc32c, error_offset = 0;
enum spdk_nvme_tcp_term_req_fes fes;
struct spdk_nvmf_tcp_transport *ttransport;
assert(tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PSH);
pdu = &tqpair->pdu_in_progress;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "pdu type of tqpair(%p) is %d\n", tqpair,
pdu->hdr.common.pdu_type);
/* check header digest if needed */
if (pdu->has_hdgst) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Compare the header of pdu=%p on tqpair=%p\n", pdu, tqpair);
crc32c = nvme_tcp_pdu_calc_header_digest(pdu);
rc = MATCH_DIGEST_WORD((uint8_t *)pdu->hdr.raw + pdu->hdr.common.hlen, crc32c);
if (rc == 0) {
SPDK_ERRLOG("Header digest error on tqpair=(%p) with pdu=%p\n", tqpair, pdu);
fes = SPDK_NVME_TCP_TERM_REQ_FES_HDGST_ERROR;
spdk_nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
return;
}
}
ttransport = SPDK_CONTAINEROF(tqpair->qpair.transport, struct spdk_nvmf_tcp_transport, transport);
switch (pdu->hdr.common.pdu_type) {
case SPDK_NVME_TCP_PDU_TYPE_IC_REQ:
spdk_nvmf_tcp_icreq_handle(ttransport, tqpair, pdu);
break;
case SPDK_NVME_TCP_PDU_TYPE_CAPSULE_CMD:
spdk_nvmf_tcp_capsule_cmd_hdr_handle(ttransport, tqpair, pdu);
break;
case SPDK_NVME_TCP_PDU_TYPE_H2C_DATA:
spdk_nvmf_tcp_h2c_data_hdr_handle(ttransport, tqpair, pdu);
break;
case SPDK_NVME_TCP_PDU_TYPE_H2C_TERM_REQ:
spdk_nvmf_tcp_h2c_term_req_hdr_handle(tqpair, pdu);
break;
default:
SPDK_ERRLOG("Unexpected PDU type 0x%02x\n", tqpair->pdu_in_progress.hdr.common.pdu_type);
fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
error_offset = 1;
spdk_nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
break;
}
}
static void
spdk_nvmf_tcp_pdu_ch_handle(struct spdk_nvmf_tcp_qpair *tqpair)
{
struct nvme_tcp_pdu *pdu;
uint32_t error_offset = 0;
enum spdk_nvme_tcp_term_req_fes fes;
uint8_t expected_hlen, pdo;
bool plen_error = false, pdo_error = false;
assert(tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_CH);
pdu = &tqpair->pdu_in_progress;
if (pdu->hdr.common.pdu_type == SPDK_NVME_TCP_PDU_TYPE_IC_REQ) {
if (tqpair->state != NVME_TCP_QPAIR_STATE_INVALID) {
SPDK_ERRLOG("Already received ICreq PDU, and reject this pdu=%p\n", pdu);
fes = SPDK_NVME_TCP_TERM_REQ_FES_PDU_SEQUENCE_ERROR;
goto err;
}
expected_hlen = sizeof(struct spdk_nvme_tcp_ic_req);
if (pdu->hdr.common.plen != expected_hlen) {
plen_error = true;
}
} else {
if (tqpair->state != NVME_TCP_QPAIR_STATE_RUNNING) {
SPDK_ERRLOG("The TCP/IP connection is not negotitated\n");
fes = SPDK_NVME_TCP_TERM_REQ_FES_PDU_SEQUENCE_ERROR;
goto err;
}
switch (pdu->hdr.common.pdu_type) {
case SPDK_NVME_TCP_PDU_TYPE_CAPSULE_CMD:
expected_hlen = sizeof(struct spdk_nvme_tcp_cmd);
pdo = pdu->hdr.common.pdo;
if ((tqpair->cpda != 0) && (pdo != ((tqpair->cpda + 1) << 2))) {
pdo_error = true;
break;
}
if (pdu->hdr.common.plen < expected_hlen) {
plen_error = true;
}
break;
case SPDK_NVME_TCP_PDU_TYPE_H2C_DATA:
expected_hlen = sizeof(struct spdk_nvme_tcp_h2c_data_hdr);
pdo = pdu->hdr.common.pdo;
if ((tqpair->cpda != 0) && (pdo != ((tqpair->cpda + 1) << 2))) {
pdo_error = true;
break;
}
if (pdu->hdr.common.plen < expected_hlen) {
plen_error = true;
}
break;
case SPDK_NVME_TCP_PDU_TYPE_H2C_TERM_REQ:
expected_hlen = sizeof(struct spdk_nvme_tcp_term_req_hdr);
if ((pdu->hdr.common.plen <= expected_hlen) ||
(pdu->hdr.common.plen > SPDK_NVME_TCP_TERM_REQ_PDU_MAX_SIZE)) {
plen_error = true;
}
break;
default:
SPDK_ERRLOG("Unexpected PDU type 0x%02x\n", pdu->hdr.common.pdu_type);
fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
error_offset = offsetof(struct spdk_nvme_tcp_common_pdu_hdr, pdu_type);
goto err;
}
}
if (pdu->hdr.common.hlen != expected_hlen) {
SPDK_ERRLOG("PDU type=0x%02x, Expected ICReq header length %u, got %u on tqpair=%p\n",
pdu->hdr.common.pdu_type,
expected_hlen, pdu->hdr.common.hlen, tqpair);
fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
error_offset = offsetof(struct spdk_nvme_tcp_common_pdu_hdr, hlen);
goto err;
} else if (pdo_error) {
fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
error_offset = offsetof(struct spdk_nvme_tcp_common_pdu_hdr, pdo);
} else if (plen_error) {
fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
error_offset = offsetof(struct spdk_nvme_tcp_common_pdu_hdr, plen);
goto err;
} else {
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PSH);
return;
}
err:
spdk_nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
}
nvmf/tcp: Add a maximal PDU loop number In our previous code, we will handle all the PDU until there is no incoming data from the network if we can continue the loop. However this is not quite fair when we handling multiple connections in a polling group. And this change is setting a maximal NVME/TCP PDU we can handle for each conneciton, it can improve the performance. After some tuing, 32 should be a good loop number. Our iSCSI target uses 16. The following shows some performance data: Configuration: 1 Command used in the initiator side: ./examples/nvme/perf/perf -r 'trtype:TCP adrfam:IPv4 traddr:192.168.4.11 trsvcid:4420' -q 128 -o 4096 -w randrw -M 50 -t 10 2 target side, export 4 malloc bdev in a same subsystem Result: Before patch: Starting thread on core 0 ======================================================== Latency(us) Device Information : IOPS MiB/s Average min max TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51554.20 201.38 2483.07 462.31 4158.45 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51533.00 201.30 2484.12 508.06 4464.07 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51630.20 201.68 2479.30 481.19 4120.83 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51700.70 201.96 2475.85 442.61 4018.67 ======================================================== Total : 206418.10 806.32 2480.58 442.61 4464.07 After patch: Starting thread on core 0 ======================================================== Latency(us) Device Information : IOPS MiB/s Average min max TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57445.30 224.40 2228.46 450.03 4231.23 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57529.50 224.72 2225.17 676.07 4251.76 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57524.80 224.71 2225.29 627.08 4193.28 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57476.50 224.52 2227.17 663.14 4205.12 ======================================================== Total : 229976.10 898.34 2226.52 450.03 4251.76 Signed-off-by: Ziye Yang <ziye.yang@intel.com> Change-Id: I86b7af1b669169eee2225de2d28c2cc313e7d905 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/459572 Tested-by: SPDK CI Jenkins <sys_sgci@intel.com> Reviewed-by: Changpeng Liu <changpeng.liu@intel.com> Reviewed-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com>
2019-06-14 08:48:37 +00:00
#define MAX_NVME_TCP_PDU_LOOP_COUNT 32
static int
spdk_nvmf_tcp_sock_process(struct spdk_nvmf_tcp_qpair *tqpair)
{
int rc = 0;
struct nvme_tcp_pdu *pdu;
enum nvme_tcp_pdu_recv_state prev_state;
nvmf/tcp: Add a maximal PDU loop number In our previous code, we will handle all the PDU until there is no incoming data from the network if we can continue the loop. However this is not quite fair when we handling multiple connections in a polling group. And this change is setting a maximal NVME/TCP PDU we can handle for each conneciton, it can improve the performance. After some tuing, 32 should be a good loop number. Our iSCSI target uses 16. The following shows some performance data: Configuration: 1 Command used in the initiator side: ./examples/nvme/perf/perf -r 'trtype:TCP adrfam:IPv4 traddr:192.168.4.11 trsvcid:4420' -q 128 -o 4096 -w randrw -M 50 -t 10 2 target side, export 4 malloc bdev in a same subsystem Result: Before patch: Starting thread on core 0 ======================================================== Latency(us) Device Information : IOPS MiB/s Average min max TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51554.20 201.38 2483.07 462.31 4158.45 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51533.00 201.30 2484.12 508.06 4464.07 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51630.20 201.68 2479.30 481.19 4120.83 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51700.70 201.96 2475.85 442.61 4018.67 ======================================================== Total : 206418.10 806.32 2480.58 442.61 4464.07 After patch: Starting thread on core 0 ======================================================== Latency(us) Device Information : IOPS MiB/s Average min max TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57445.30 224.40 2228.46 450.03 4231.23 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57529.50 224.72 2225.17 676.07 4251.76 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57524.80 224.71 2225.29 627.08 4193.28 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57476.50 224.52 2227.17 663.14 4205.12 ======================================================== Total : 229976.10 898.34 2226.52 450.03 4251.76 Signed-off-by: Ziye Yang <ziye.yang@intel.com> Change-Id: I86b7af1b669169eee2225de2d28c2cc313e7d905 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/459572 Tested-by: SPDK CI Jenkins <sys_sgci@intel.com> Reviewed-by: Changpeng Liu <changpeng.liu@intel.com> Reviewed-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com>
2019-06-14 08:48:37 +00:00
uint32_t data_len, current_pdu_num = 0;
uint8_t psh_len, pdo, hlen;
int8_t padding_len;
/* The loop here is to allow for several back-to-back state changes. */
do {
prev_state = tqpair->recv_state;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "tqpair(%p) recv pdu entering state %d\n", tqpair, prev_state);
switch (tqpair->recv_state) {
/* Wait for the common header */
case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY:
case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_CH:
pdu = &tqpair->pdu_in_progress;
rc = nvme_tcp_read_data(tqpair->sock,
sizeof(struct spdk_nvme_tcp_common_pdu_hdr) - pdu->ch_valid_bytes,
(void *)&pdu->hdr.common + pdu->ch_valid_bytes);
if (rc < 0) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "will disconnect tqpair=%p\n", tqpair);
return NVME_TCP_PDU_FATAL;
} else if (rc > 0) {
pdu->ch_valid_bytes += rc;
spdk_trace_record(TRACE_TCP_READ_FROM_SOCKET_DONE, 0, rc, 0, 0);
if (spdk_likely(tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY)) {
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_CH);
}
}
if (pdu->ch_valid_bytes < sizeof(struct spdk_nvme_tcp_common_pdu_hdr)) {
return NVME_TCP_PDU_IN_PROGRESS;
}
/* The command header of this PDU has now been read from the socket. */
spdk_nvmf_tcp_pdu_ch_handle(tqpair);
break;
/* Wait for the pdu specific header */
case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PSH:
pdu = &tqpair->pdu_in_progress;
psh_len = hlen = pdu->hdr.common.hlen;
/* Only capsule_cmd and h2c_data has header digest */
if (((pdu->hdr.common.pdu_type == SPDK_NVME_TCP_PDU_TYPE_CAPSULE_CMD) ||
(pdu->hdr.common.pdu_type == SPDK_NVME_TCP_PDU_TYPE_H2C_DATA)) &&
tqpair->host_hdgst_enable) {
pdu->has_hdgst = true;
psh_len += SPDK_NVME_TCP_DIGEST_LEN;
if (pdu->hdr.common.plen > psh_len) {
pdo = pdu->hdr.common.pdo;
padding_len = pdo - psh_len;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "padding length is =%d for pdu=%p on tqpair=%p\n", padding_len,
pdu, tqpair);
if (padding_len > 0) {
psh_len = pdo;
}
}
}
psh_len -= sizeof(struct spdk_nvme_tcp_common_pdu_hdr);
/* The following will read psh + hdgest (if possbile) + padding (if posssible) */
if (pdu->psh_valid_bytes < psh_len) {
rc = nvme_tcp_read_data(tqpair->sock,
psh_len - pdu->psh_valid_bytes,
(void *)&pdu->hdr.raw + sizeof(struct spdk_nvme_tcp_common_pdu_hdr) + pdu->psh_valid_bytes);
if (rc < 0) {
return NVME_TCP_PDU_FATAL;
} else if (rc > 0) {
spdk_trace_record(TRACE_TCP_READ_FROM_SOCKET_DONE,
0, rc, 0, 0);
pdu->psh_valid_bytes += rc;
}
if (pdu->psh_valid_bytes < psh_len) {
return NVME_TCP_PDU_IN_PROGRESS;
}
}
/* All header(ch, psh, head digist) of this PDU has now been read from the socket. */
spdk_nvmf_tcp_pdu_psh_handle(tqpair);
nvmf/tcp: Add a maximal PDU loop number In our previous code, we will handle all the PDU until there is no incoming data from the network if we can continue the loop. However this is not quite fair when we handling multiple connections in a polling group. And this change is setting a maximal NVME/TCP PDU we can handle for each conneciton, it can improve the performance. After some tuing, 32 should be a good loop number. Our iSCSI target uses 16. The following shows some performance data: Configuration: 1 Command used in the initiator side: ./examples/nvme/perf/perf -r 'trtype:TCP adrfam:IPv4 traddr:192.168.4.11 trsvcid:4420' -q 128 -o 4096 -w randrw -M 50 -t 10 2 target side, export 4 malloc bdev in a same subsystem Result: Before patch: Starting thread on core 0 ======================================================== Latency(us) Device Information : IOPS MiB/s Average min max TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51554.20 201.38 2483.07 462.31 4158.45 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51533.00 201.30 2484.12 508.06 4464.07 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51630.20 201.68 2479.30 481.19 4120.83 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51700.70 201.96 2475.85 442.61 4018.67 ======================================================== Total : 206418.10 806.32 2480.58 442.61 4464.07 After patch: Starting thread on core 0 ======================================================== Latency(us) Device Information : IOPS MiB/s Average min max TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57445.30 224.40 2228.46 450.03 4231.23 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57529.50 224.72 2225.17 676.07 4251.76 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57524.80 224.71 2225.29 627.08 4193.28 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57476.50 224.52 2227.17 663.14 4205.12 ======================================================== Total : 229976.10 898.34 2226.52 450.03 4251.76 Signed-off-by: Ziye Yang <ziye.yang@intel.com> Change-Id: I86b7af1b669169eee2225de2d28c2cc313e7d905 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/459572 Tested-by: SPDK CI Jenkins <sys_sgci@intel.com> Reviewed-by: Changpeng Liu <changpeng.liu@intel.com> Reviewed-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com>
2019-06-14 08:48:37 +00:00
if (tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY) {
current_pdu_num++;
}
break;
case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PAYLOAD:
pdu = &tqpair->pdu_in_progress;
/* check whether the data is valid, if not we just return */
if (!pdu->data_len) {
return NVME_TCP_PDU_IN_PROGRESS;
}
data_len = pdu->data_len;
/* data digest */
if (spdk_unlikely((pdu->hdr.common.pdu_type != SPDK_NVME_TCP_PDU_TYPE_H2C_TERM_REQ) &&
tqpair->host_ddgst_enable)) {
data_len += SPDK_NVME_TCP_DIGEST_LEN;
pdu->ddgst_enable = true;
}
rc = nvme_tcp_read_payload_data(tqpair->sock, pdu);
if (rc < 0) {
return NVME_TCP_PDU_IN_PROGRESS;
}
pdu->readv_offset += rc;
if (pdu->readv_offset < data_len) {
return NVME_TCP_PDU_IN_PROGRESS;
}
/* All of this PDU has now been read from the socket. */
spdk_nvmf_tcp_pdu_payload_handle(tqpair);
nvmf/tcp: Add a maximal PDU loop number In our previous code, we will handle all the PDU until there is no incoming data from the network if we can continue the loop. However this is not quite fair when we handling multiple connections in a polling group. And this change is setting a maximal NVME/TCP PDU we can handle for each conneciton, it can improve the performance. After some tuing, 32 should be a good loop number. Our iSCSI target uses 16. The following shows some performance data: Configuration: 1 Command used in the initiator side: ./examples/nvme/perf/perf -r 'trtype:TCP adrfam:IPv4 traddr:192.168.4.11 trsvcid:4420' -q 128 -o 4096 -w randrw -M 50 -t 10 2 target side, export 4 malloc bdev in a same subsystem Result: Before patch: Starting thread on core 0 ======================================================== Latency(us) Device Information : IOPS MiB/s Average min max TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51554.20 201.38 2483.07 462.31 4158.45 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51533.00 201.30 2484.12 508.06 4464.07 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51630.20 201.68 2479.30 481.19 4120.83 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51700.70 201.96 2475.85 442.61 4018.67 ======================================================== Total : 206418.10 806.32 2480.58 442.61 4464.07 After patch: Starting thread on core 0 ======================================================== Latency(us) Device Information : IOPS MiB/s Average min max TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57445.30 224.40 2228.46 450.03 4231.23 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57529.50 224.72 2225.17 676.07 4251.76 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57524.80 224.71 2225.29 627.08 4193.28 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57476.50 224.52 2227.17 663.14 4205.12 ======================================================== Total : 229976.10 898.34 2226.52 450.03 4251.76 Signed-off-by: Ziye Yang <ziye.yang@intel.com> Change-Id: I86b7af1b669169eee2225de2d28c2cc313e7d905 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/459572 Tested-by: SPDK CI Jenkins <sys_sgci@intel.com> Reviewed-by: Changpeng Liu <changpeng.liu@intel.com> Reviewed-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com>
2019-06-14 08:48:37 +00:00
current_pdu_num++;
break;
case NVME_TCP_PDU_RECV_STATE_ERROR:
pdu = &tqpair->pdu_in_progress;
/* Check whether the connection is closed. Each time, we only read 1 byte every time */
rc = nvme_tcp_read_data(tqpair->sock, 1, (void *)&pdu->hdr.common);
if (rc < 0) {
return NVME_TCP_PDU_FATAL;
}
break;
default:
assert(0);
SPDK_ERRLOG("code should not come to here");
break;
}
nvmf/tcp: Add a maximal PDU loop number In our previous code, we will handle all the PDU until there is no incoming data from the network if we can continue the loop. However this is not quite fair when we handling multiple connections in a polling group. And this change is setting a maximal NVME/TCP PDU we can handle for each conneciton, it can improve the performance. After some tuing, 32 should be a good loop number. Our iSCSI target uses 16. The following shows some performance data: Configuration: 1 Command used in the initiator side: ./examples/nvme/perf/perf -r 'trtype:TCP adrfam:IPv4 traddr:192.168.4.11 trsvcid:4420' -q 128 -o 4096 -w randrw -M 50 -t 10 2 target side, export 4 malloc bdev in a same subsystem Result: Before patch: Starting thread on core 0 ======================================================== Latency(us) Device Information : IOPS MiB/s Average min max TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51554.20 201.38 2483.07 462.31 4158.45 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51533.00 201.30 2484.12 508.06 4464.07 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51630.20 201.68 2479.30 481.19 4120.83 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 51700.70 201.96 2475.85 442.61 4018.67 ======================================================== Total : 206418.10 806.32 2480.58 442.61 4464.07 After patch: Starting thread on core 0 ======================================================== Latency(us) Device Information : IOPS MiB/s Average min max TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57445.30 224.40 2228.46 450.03 4231.23 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57529.50 224.72 2225.17 676.07 4251.76 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57524.80 224.71 2225.29 627.08 4193.28 TCP (addr:192.168.4.11 subnqn:nqn.2016-06.io.spdk:cnode1) from core 0: 57476.50 224.52 2227.17 663.14 4205.12 ======================================================== Total : 229976.10 898.34 2226.52 450.03 4251.76 Signed-off-by: Ziye Yang <ziye.yang@intel.com> Change-Id: I86b7af1b669169eee2225de2d28c2cc313e7d905 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/459572 Tested-by: SPDK CI Jenkins <sys_sgci@intel.com> Reviewed-by: Changpeng Liu <changpeng.liu@intel.com> Reviewed-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com>
2019-06-14 08:48:37 +00:00
} while ((tqpair->recv_state != prev_state) && (current_pdu_num < MAX_NVME_TCP_PDU_LOOP_COUNT));
return rc;
}
static enum spdk_nvme_data_transfer
spdk_nvmf_tcp_req_get_xfer(struct spdk_nvmf_tcp_req *tcp_req) {
enum spdk_nvme_data_transfer xfer;
struct spdk_nvme_cmd *cmd = &tcp_req->req.cmd->nvme_cmd;
struct spdk_nvme_sgl_descriptor *sgl = &cmd->dptr.sgl1;
/* Figure out data transfer direction */
if (cmd->opc == SPDK_NVME_OPC_FABRIC)
{
xfer = spdk_nvme_opc_get_data_transfer(tcp_req->req.cmd->nvmf_cmd.fctype);
} else
{
xfer = spdk_nvme_opc_get_data_transfer(cmd->opc);
/* Some admin commands are special cases */
if ((tcp_req->req.qpair->qid == 0) &&
((cmd->opc == SPDK_NVME_OPC_GET_FEATURES) ||
(cmd->opc == SPDK_NVME_OPC_SET_FEATURES))) {
switch (cmd->cdw10 & 0xff) {
case SPDK_NVME_FEAT_LBA_RANGE_TYPE:
case SPDK_NVME_FEAT_AUTONOMOUS_POWER_STATE_TRANSITION:
case SPDK_NVME_FEAT_HOST_IDENTIFIER:
break;
default:
xfer = SPDK_NVME_DATA_NONE;
}
}
}
if (xfer == SPDK_NVME_DATA_NONE)
{
return xfer;
}
/* Even for commands that may transfer data, they could have specified 0 length.
* We want those to show up with xfer SPDK_NVME_DATA_NONE.
*/
switch (sgl->generic.type)
{
case SPDK_NVME_SGL_TYPE_DATA_BLOCK:
case SPDK_NVME_SGL_TYPE_BIT_BUCKET:
case SPDK_NVME_SGL_TYPE_SEGMENT:
case SPDK_NVME_SGL_TYPE_LAST_SEGMENT:
case SPDK_NVME_SGL_TYPE_TRANSPORT_DATA_BLOCK:
if (sgl->unkeyed.length == 0) {
xfer = SPDK_NVME_DATA_NONE;
}
break;
case SPDK_NVME_SGL_TYPE_KEYED_DATA_BLOCK:
if (sgl->keyed.length == 0) {
xfer = SPDK_NVME_DATA_NONE;
}
break;
}
return xfer;
}
static void
spdk_nvmf_tcp_request_free_buffers(struct spdk_nvmf_tcp_req *tcp_req,
struct spdk_nvmf_transport_poll_group *group, struct spdk_nvmf_transport *transport)
{
for (uint32_t i = 0; i < tcp_req->req.iovcnt; i++) {
assert(tcp_req->buffers[i] != NULL);
if (group->buf_cache_count < group->buf_cache_size) {
STAILQ_INSERT_HEAD(&group->buf_cache,
(struct spdk_nvmf_transport_pg_cache_buf *)tcp_req->buffers[i], link);
group->buf_cache_count++;
} else {
spdk_mempool_put(transport->data_buf_pool, tcp_req->buffers[i]);
}
tcp_req->req.iov[i].iov_base = NULL;
tcp_req->buffers[i] = NULL;
tcp_req->req.iov[i].iov_len = 0;
}
tcp_req->data_from_pool = false;
}
static int
spdk_nvmf_tcp_req_fill_iovs(struct spdk_nvmf_tcp_transport *ttransport,
struct spdk_nvmf_tcp_req *tcp_req)
{
void *buf = NULL;
uint32_t length = tcp_req->req.length;
uint32_t i = 0;
struct spdk_nvmf_tcp_qpair *tqpair;
struct spdk_nvmf_transport_poll_group *group;
tqpair = SPDK_CONTAINEROF(tcp_req->req.qpair, struct spdk_nvmf_tcp_qpair, qpair);
group = &tqpair->group->group;
tcp_req->req.iovcnt = 0;
while (length) {
if (!(STAILQ_EMPTY(&group->buf_cache))) {
group->buf_cache_count--;
buf = STAILQ_FIRST(&group->buf_cache);
STAILQ_REMOVE_HEAD(&group->buf_cache, link);
} else {
buf = spdk_mempool_get(ttransport->transport.data_buf_pool);
if (!buf) {
goto nomem;
}
}
tcp_req->req.iov[i].iov_base = (void *)((uintptr_t)(buf + NVMF_DATA_BUFFER_MASK) &
~NVMF_DATA_BUFFER_MASK);
tcp_req->req.iov[i].iov_len = spdk_min(length, ttransport->transport.opts.io_unit_size);
tcp_req->req.iovcnt++;
tcp_req->buffers[i] = buf;
length -= tcp_req->req.iov[i].iov_len;
i++;
}
assert(tcp_req->req.iovcnt <= SPDK_NVMF_MAX_SGL_ENTRIES);
tcp_req->data_from_pool = true;
return 0;
nomem:
spdk_nvmf_tcp_request_free_buffers(tcp_req, group, &ttransport->transport);
tcp_req->req.iovcnt = 0;
return -ENOMEM;
}
static int
spdk_nvmf_tcp_req_parse_sgl(struct spdk_nvmf_tcp_transport *ttransport,
struct spdk_nvmf_tcp_req *tcp_req)
{
struct spdk_nvme_cmd *cmd;
struct spdk_nvme_cpl *rsp;
struct spdk_nvme_sgl_descriptor *sgl;
cmd = &tcp_req->req.cmd->nvme_cmd;
rsp = &tcp_req->req.rsp->nvme_cpl;
sgl = &cmd->dptr.sgl1;
if (sgl->generic.type == SPDK_NVME_SGL_TYPE_TRANSPORT_DATA_BLOCK &&
sgl->unkeyed.subtype == SPDK_NVME_SGL_SUBTYPE_TRANSPORT) {
if (sgl->unkeyed.length > ttransport->transport.opts.max_io_size) {
SPDK_ERRLOG("SGL length 0x%x exceeds max io size 0x%x\n",
sgl->unkeyed.length, ttransport->transport.opts.max_io_size);
rsp->status.sc = SPDK_NVME_SC_DATA_SGL_LENGTH_INVALID;
return -1;
}
/* fill request length and populate iovs */
tcp_req->req.length = sgl->unkeyed.length;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Data requested length= 0x%x\n",
sgl->unkeyed.length);
if (spdk_nvmf_tcp_req_fill_iovs(ttransport, tcp_req) < 0) {
/* No available buffers. Queue this request up. */
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "No available large data buffers. Queueing request %p\n", tcp_req);
return 0;
}
/* backward compatible */
tcp_req->req.data = tcp_req->req.iov[0].iov_base;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Request %p took %d buffer/s from central pool, and data=%p\n",
tcp_req,
tcp_req->req.iovcnt, tcp_req->req.data);
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 = ttransport->transport.opts.in_capsule_data_size;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "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;
}
tcp_req->req.data = tcp_req->buf + offset;
tcp_req->data_from_pool = false;
tcp_req->req.length = sgl->unkeyed.length;
tcp_req->req.iov[0].iov_base = tcp_req->req.data;
tcp_req->req.iov[0].iov_len = tcp_req->req.length;
tcp_req->req.iovcnt = 1;
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
spdk_nvmf_tcp_send_c2h_data(struct spdk_nvmf_tcp_qpair *tqpair,
struct spdk_nvmf_tcp_req *tcp_req)
{
struct nvme_tcp_pdu *rsp_pdu;
struct spdk_nvme_tcp_c2h_data_hdr *c2h_data;
uint32_t plen, pdo, alignment;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "enter\n");
rsp_pdu = spdk_nvmf_tcp_pdu_get(tqpair);
assert(rsp_pdu != NULL);
c2h_data = &rsp_pdu->hdr.c2h_data;
c2h_data->common.pdu_type = SPDK_NVME_TCP_PDU_TYPE_C2H_DATA;
plen = c2h_data->common.hlen = sizeof(*c2h_data);
if (tqpair->host_hdgst_enable) {
plen += SPDK_NVME_TCP_DIGEST_LEN;
c2h_data->common.flags |= SPDK_NVME_TCP_CH_FLAGS_HDGSTF;
}
/* set the psh */
c2h_data->cccid = tcp_req->req.cmd->nvme_cmd.cid;
c2h_data->datal = spdk_min(NVMF_TCP_PDU_MAX_C2H_DATA_SIZE,
tcp_req->req.length - tcp_req->c2h_data_offset);
c2h_data->datao = tcp_req->c2h_data_offset;
/* set the padding */
rsp_pdu->padding_len = 0;
pdo = plen;
if (tqpair->cpda) {
alignment = (tqpair->cpda + 1) << 2;
if (alignment > plen) {
rsp_pdu->padding_len = alignment - plen;
pdo = plen = alignment;
}
}
c2h_data->common.pdo = pdo;
plen += c2h_data->datal;
if (tqpair->host_ddgst_enable) {
c2h_data->common.flags |= SPDK_NVME_TCP_CH_FLAGS_DDGSTF;
plen += SPDK_NVME_TCP_DIGEST_LEN;
}
c2h_data->common.plen = plen;
nvme_tcp_pdu_set_data_buf(rsp_pdu, tcp_req->req.iov, tcp_req->req.iovcnt,
c2h_data->datao, c2h_data->datal);
tcp_req->c2h_data_offset += c2h_data->datal;
if (tcp_req->c2h_data_offset == tcp_req->req.length) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Last pdu for tcp_req=%p on tqpair=%p\n", tcp_req, tqpair);
c2h_data->common.flags |= SPDK_NVME_TCP_C2H_DATA_FLAGS_LAST_PDU;
if (tqpair->qpair.transport->opts.c2h_success) {
c2h_data->common.flags |= SPDK_NVME_TCP_C2H_DATA_FLAGS_SUCCESS;
}
TAILQ_REMOVE(&tqpair->queued_c2h_data_tcp_req, tcp_req, link);
}
tqpair->c2h_data_pdu_cnt += 1;
spdk_nvmf_tcp_qpair_write_pdu(tqpair, rsp_pdu, spdk_nvmf_tcp_pdu_c2h_data_complete, tcp_req);
}
static int
spdk_nvmf_tcp_calc_c2h_data_pdu_num(struct spdk_nvmf_tcp_req *tcp_req)
{
return (tcp_req->req.length + NVMF_TCP_PDU_MAX_C2H_DATA_SIZE - 1) /
NVMF_TCP_PDU_MAX_C2H_DATA_SIZE;
}
static void
spdk_nvmf_tcp_handle_pending_c2h_data_queue(struct spdk_nvmf_tcp_qpair *tqpair)
{
struct spdk_nvmf_tcp_req *tcp_req;
while (!TAILQ_EMPTY(&tqpair->queued_c2h_data_tcp_req) &&
(tqpair->c2h_data_pdu_cnt < NVMF_TCP_QPAIR_MAX_C2H_PDU_NUM)) {
tcp_req = TAILQ_FIRST(&tqpair->queued_c2h_data_tcp_req);
spdk_nvmf_tcp_send_c2h_data(tqpair, tcp_req);
}
}
static void
spdk_nvmf_tcp_queue_c2h_data(struct spdk_nvmf_tcp_req *tcp_req,
struct spdk_nvmf_tcp_qpair *tqpair)
{
tcp_req->c2h_data_pdu_num = spdk_nvmf_tcp_calc_c2h_data_pdu_num(tcp_req);
assert(tcp_req->c2h_data_pdu_num < NVMF_TCP_QPAIR_MAX_C2H_PDU_NUM);
TAILQ_INSERT_TAIL(&tqpair->queued_c2h_data_tcp_req, tcp_req, link);
spdk_nvmf_tcp_handle_pending_c2h_data_queue(tqpair);
}
static int
request_transfer_out(struct spdk_nvmf_request *req)
{
struct spdk_nvmf_tcp_req *tcp_req;
struct spdk_nvmf_qpair *qpair;
struct spdk_nvmf_tcp_qpair *tqpair;
struct spdk_nvme_cpl *rsp;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "enter\n");
qpair = req->qpair;
rsp = &req->rsp->nvme_cpl;
tcp_req = SPDK_CONTAINEROF(req, struct spdk_nvmf_tcp_req, req);
/* 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;
tqpair = SPDK_CONTAINEROF(tcp_req->req.qpair, struct spdk_nvmf_tcp_qpair, qpair);
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST);
if (rsp->status.sc == SPDK_NVME_SC_SUCCESS &&
req->xfer == SPDK_NVME_DATA_CONTROLLER_TO_HOST) {
spdk_nvmf_tcp_queue_c2h_data(tcp_req, tqpair);
} else {
spdk_nvmf_tcp_send_capsule_resp_pdu(tcp_req, tqpair);
}
return 0;
}
static void
spdk_nvmf_tcp_pdu_set_buf_from_req(struct spdk_nvmf_tcp_qpair *tqpair,
struct spdk_nvmf_tcp_req *tcp_req)
{
struct nvme_tcp_pdu *pdu;
if (tcp_req->data_from_pool) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Will send r2t for tcp_req(%p) on tqpair=%p\n", tcp_req, tqpair);
tcp_req->next_expected_r2t_offset = 0;
nvmf/tcp: Support single r2t usage According to the TP 8000 spec in Page 26: Maximum Number of Outstanding R2T (MAXR2T): Specifies the maximum number of outstanding R2T PDUs for a command at any point in time on the connection. Note that by the spec, the target may only support single r2t (which is the minimum possible), it doesn't have to use multiple r2ts even if the initiator supports that. So remove the maxr2t and pending_r2t variable in the tcp qpair structure. In the original design, we think that maxr2t is the maximal active r2t numbers for each connection. So if the initiator sends out maxr2t=16, it means that all the commands of a qpair can use such number of R2T pdus. So we need to wait for the available R2Ts for the request when the maxr2t reaches the maximal value. But it is the wrong understanding of the spec. In fact, each command has its own number of maximal r2t numbers, then we do not need to use the wait method for R2T method anymore. So we remove the state TCP_REQUEST_STATE_DATA_PENDING_FOR_R2T. Futhermore, we adjust the related SPDK_TPOINT_ID definition. In current patch, the target will support one active R2T for each write NVMe command. Thus, we remove the function spdk_nvmf_tcp_handle_queued_r2t_req. Reported-by: Or Gerlitz <ogerlitz@mellanox.com> Signed-off-by: Ziye Yang <ziye.yang@intel.com> Change-Id: I7547b8facbc39139b4584637ccc51ba8b33ca285 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/455763 Reviewed-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com> Reviewed-by: Or Gerlitz <gerlitz.or@gmail.com> Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
2019-05-27 12:45:58 +00:00
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER);
spdk_nvmf_tcp_send_r2t_pdu(tqpair, tcp_req);
} else {
pdu = &tqpair->pdu_in_progress;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Not need to send r2t for tcp_req(%p) on tqpair=%p\n", tcp_req,
tqpair);
/* No need to send r2t, contained in the capsuled data */
nvme_tcp_pdu_set_data_buf(pdu, tcp_req->req.iov, tcp_req->req.iovcnt,
0, tcp_req->req.length);
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PAYLOAD);
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER);
}
}
static void
spdk_nvmf_tcp_set_incapsule_data(struct spdk_nvmf_tcp_qpair *tqpair,
struct spdk_nvmf_tcp_req *tcp_req)
{
struct nvme_tcp_pdu *pdu;
uint32_t plen = 0;
pdu = &tqpair->pdu_in_progress;
plen = pdu->hdr.common.hlen;
if (tqpair->host_hdgst_enable) {
plen += SPDK_NVME_TCP_DIGEST_LEN;
}
if (pdu->hdr.common.plen != plen) {
tcp_req->has_incapsule_data = true;
}
}
static bool
spdk_nvmf_tcp_req_process(struct spdk_nvmf_tcp_transport *ttransport,
struct spdk_nvmf_tcp_req *tcp_req)
{
struct spdk_nvmf_tcp_qpair *tqpair;
struct spdk_nvme_cpl *rsp = &tcp_req->req.rsp->nvme_cpl;
int rc;
enum spdk_nvmf_tcp_req_state prev_state;
bool progress = false;
struct spdk_nvmf_transport_poll_group *group;
tqpair = SPDK_CONTAINEROF(tcp_req->req.qpair, struct spdk_nvmf_tcp_qpair, qpair);
group = &tqpair->group->group;
assert(tcp_req->state != TCP_REQUEST_STATE_FREE);
/* The loop here is to allow for several back-to-back state changes. */
do {
prev_state = tcp_req->state;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "Request %p entering state %d on tqpair=%p\n", tcp_req, prev_state,
tqpair);
switch (tcp_req->state) {
case TCP_REQUEST_STATE_FREE:
/* Some external code must kick a request into TCP_REQUEST_STATE_NEW
* to escape this state. */
break;
case TCP_REQUEST_STATE_NEW:
spdk_trace_record(TRACE_TCP_REQUEST_STATE_NEW, 0, 0, (uintptr_t)tcp_req, 0);
/* copy the cmd from the receive pdu */
tcp_req->cmd = tqpair->pdu_in_progress.hdr.capsule_cmd.ccsqe;
/* The next state transition depends on the data transfer needs of this request. */
tcp_req->req.xfer = spdk_nvmf_tcp_req_get_xfer(tcp_req);
/* If no data to transfer, ready to execute. */
if (tcp_req->req.xfer == SPDK_NVME_DATA_NONE) {
/* Reset the tqpair receving pdu state */
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY);
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_EXECUTE);
break;
}
spdk_nvmf_tcp_set_incapsule_data(tqpair, tcp_req);
if (!tcp_req->has_incapsule_data) {
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY);
}
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_NEED_BUFFER);
TAILQ_INSERT_TAIL(&tqpair->group->pending_data_buf_queue, tcp_req, link);
break;
case TCP_REQUEST_STATE_NEED_BUFFER:
spdk_trace_record(TRACE_TCP_REQUEST_STATE_NEED_BUFFER, 0, 0, (uintptr_t)tcp_req, 0);
assert(tcp_req->req.xfer != SPDK_NVME_DATA_NONE);
if (!tcp_req->has_incapsule_data &&
(tcp_req != TAILQ_FIRST(&tqpair->group->pending_data_buf_queue))) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP,
"Not the first element to wait for the buf for tcp_req(%p) on tqpair=%p\n",
tcp_req, tqpair);
/* This request needs to wait in line to obtain a buffer */
break;
}
/* Try to get a data buffer */
rc = spdk_nvmf_tcp_req_parse_sgl(ttransport, tcp_req);
if (rc < 0) {
TAILQ_REMOVE(&tqpair->group->pending_data_buf_queue, tcp_req, link);
rsp->status.sc = SPDK_NVME_SC_INTERNAL_DEVICE_ERROR;
/* Reset the tqpair receving pdu state */
spdk_nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_ERROR);
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_COMPLETE);
break;
}
if (!tcp_req->req.data) {
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "No buffer allocated for tcp_req(%p) on tqpair(%p\n)",
tcp_req, tqpair);
/* No buffers available. */
break;
}
TAILQ_REMOVE(&tqpair->group->pending_data_buf_queue, tcp_req, link);
/* If data is transferring from host to controller, we need to do a transfer from the host. */
if (tcp_req->req.xfer == SPDK_NVME_DATA_HOST_TO_CONTROLLER) {
spdk_nvmf_tcp_pdu_set_buf_from_req(tqpair, tcp_req);
break;
}
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_EXECUTE);
break;
case TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER:
spdk_trace_record(TRACE_TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER, 0, 0,
(uintptr_t)tcp_req, 0);
/* Some external code must kick a request into TCP_REQUEST_STATE_READY_TO_EXECUTE
* to escape this state. */
break;
case TCP_REQUEST_STATE_READY_TO_EXECUTE:
spdk_trace_record(TRACE_TCP_REQUEST_STATE_READY_TO_EXECUTE, 0, 0, (uintptr_t)tcp_req, 0);
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_EXECUTING);
spdk_nvmf_request_exec(&tcp_req->req);
break;
case TCP_REQUEST_STATE_EXECUTING:
spdk_trace_record(TRACE_TCP_REQUEST_STATE_EXECUTING, 0, 0, (uintptr_t)tcp_req, 0);
/* Some external code must kick a request into TCP_REQUEST_STATE_EXECUTED
* to escape this state. */
break;
case TCP_REQUEST_STATE_EXECUTED:
spdk_trace_record(TRACE_TCP_REQUEST_STATE_EXECUTED, 0, 0, (uintptr_t)tcp_req, 0);
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_COMPLETE);
break;
case TCP_REQUEST_STATE_READY_TO_COMPLETE:
spdk_trace_record(TRACE_TCP_REQUEST_STATE_READY_TO_COMPLETE, 0, 0, (uintptr_t)tcp_req, 0);
rc = request_transfer_out(&tcp_req->req);
assert(rc == 0); /* No good way to handle this currently */
break;
case TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST:
spdk_trace_record(TRACE_TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST, 0, 0,
(uintptr_t)tcp_req,
0);
/* Some external code must kick a request into TCP_REQUEST_STATE_COMPLETED
* to escape this state. */
break;
case TCP_REQUEST_STATE_COMPLETED:
spdk_trace_record(TRACE_TCP_REQUEST_STATE_COMPLETED, 0, 0, (uintptr_t)tcp_req, 0);
if (tcp_req->data_from_pool) {
spdk_nvmf_tcp_request_free_buffers(tcp_req, group, &ttransport->transport);
}
tcp_req->req.length = 0;
tcp_req->req.iovcnt = 0;
tcp_req->req.data = NULL;
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_FREE);
break;
case TCP_REQUEST_NUM_STATES:
default:
assert(0);
break;
}
if (tcp_req->state != prev_state) {
progress = true;
}
} while (tcp_req->state != prev_state);
return progress;
}
static void
spdk_nvmf_tcp_qpair_process_pending(struct spdk_nvmf_tcp_transport *ttransport,
struct spdk_nvmf_tcp_qpair *tqpair)
{
struct spdk_nvmf_tcp_req *tcp_req, *req_tmp;
/* Tqpair is not in a good state, so return it */
if (spdk_unlikely(tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_ERROR)) {
return;
}
TAILQ_FOREACH_SAFE(tcp_req, &tqpair->group->pending_data_buf_queue, link, req_tmp) {
if (spdk_nvmf_tcp_req_process(ttransport, tcp_req) == false) {
break;
}
}
}
static void
spdk_nvmf_tcp_sock_cb(void *arg, struct spdk_sock_group *group, struct spdk_sock *sock)
{
struct spdk_nvmf_tcp_qpair *tqpair = arg;
struct spdk_nvmf_tcp_transport *ttransport;
int rc;
assert(tqpair != NULL);
ttransport = SPDK_CONTAINEROF(tqpair->qpair.transport, struct spdk_nvmf_tcp_transport, transport);
spdk_nvmf_tcp_qpair_process_pending(ttransport, tqpair);
rc = spdk_nvmf_tcp_sock_process(tqpair);
/* check the following two factors:
* rc: The socket is closed
* State of tqpair: The tqpair is in EXITING state due to internal error
*/
if ((rc < 0) || (tqpair->state == NVME_TCP_QPAIR_STATE_EXITING)) {
tqpair->state = NVME_TCP_QPAIR_STATE_EXITED;
spdk_nvmf_tcp_qpair_flush_pdus(tqpair);
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "will disconect the tqpair=%p\n", tqpair);
spdk_poller_unregister(&tqpair->timeout_poller);
spdk_nvmf_qpair_disconnect(&tqpair->qpair, NULL, NULL);
}
}
static int
spdk_nvmf_tcp_poll_group_add(struct spdk_nvmf_transport_poll_group *group,
struct spdk_nvmf_qpair *qpair)
{
struct spdk_nvmf_tcp_poll_group *tgroup;
struct spdk_nvmf_tcp_qpair *tqpair;
int rc;
tgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_tcp_poll_group, group);
tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
rc = spdk_sock_group_add_sock(tgroup->sock_group, tqpair->sock,
spdk_nvmf_tcp_sock_cb, tqpair);
if (rc != 0) {
SPDK_ERRLOG("Could not add sock to sock_group: %s (%d)\n",
spdk_strerror(errno), errno);
spdk_nvmf_tcp_qpair_destroy(tqpair);
return -1;
}
rc = spdk_nvmf_tcp_qpair_sock_init(tqpair);
if (rc != 0) {
SPDK_ERRLOG("Cannot set sock opt for tqpair=%p\n", tqpair);
spdk_nvmf_tcp_qpair_destroy(tqpair);
return -1;
}
rc = spdk_nvmf_tcp_qpair_init(&tqpair->qpair);
if (rc < 0) {
SPDK_ERRLOG("Cannot init tqpair=%p\n", tqpair);
spdk_nvmf_tcp_qpair_destroy(tqpair);
return -1;
}
rc = spdk_nvmf_tcp_qpair_init_mem_resource(tqpair, 1);
if (rc < 0) {
SPDK_ERRLOG("Cannot init memory resource info for tqpair=%p\n", tqpair);
spdk_nvmf_tcp_qpair_destroy(tqpair);
return -1;
}
tqpair->group = tgroup;
tqpair->state = NVME_TCP_QPAIR_STATE_INVALID;
TAILQ_INSERT_TAIL(&tgroup->qpairs, tqpair, link);
return 0;
}
static int
spdk_nvmf_tcp_poll_group_remove(struct spdk_nvmf_transport_poll_group *group,
struct spdk_nvmf_qpair *qpair)
{
struct spdk_nvmf_tcp_poll_group *tgroup;
struct spdk_nvmf_tcp_qpair *tqpair;
int rc;
tgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_tcp_poll_group, group);
tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
assert(tqpair->group == tgroup);
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "remove tqpair=%p from the tgroup=%p\n", tqpair, tgroup);
TAILQ_REMOVE(&tgroup->qpairs, tqpair, link);
rc = spdk_sock_group_remove_sock(tgroup->sock_group, tqpair->sock);
if (rc != 0) {
SPDK_ERRLOG("Could not remove sock from sock_group: %s (%d)\n",
spdk_strerror(errno), errno);
}
return rc;
}
static int
spdk_nvmf_tcp_req_complete(struct spdk_nvmf_request *req)
{
struct spdk_nvmf_tcp_transport *ttransport;
struct spdk_nvmf_tcp_req *tcp_req;
ttransport = SPDK_CONTAINEROF(req->qpair->transport, struct spdk_nvmf_tcp_transport, transport);
tcp_req = SPDK_CONTAINEROF(req, struct spdk_nvmf_tcp_req, req);
spdk_nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_EXECUTED);
spdk_nvmf_tcp_req_process(ttransport, tcp_req);
return 0;
}
static void
spdk_nvmf_tcp_close_qpair(struct spdk_nvmf_qpair *qpair)
{
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "enter\n");
spdk_nvmf_tcp_qpair_destroy(SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair));
}
static int
spdk_nvmf_tcp_poll_group_poll(struct spdk_nvmf_transport_poll_group *group)
{
struct spdk_nvmf_tcp_poll_group *tgroup;
int rc;
tgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_tcp_poll_group, group);
if (spdk_unlikely(TAILQ_EMPTY(&tgroup->qpairs))) {
return 0;
}
rc = spdk_sock_group_poll(tgroup->sock_group);
if (rc < 0) {
SPDK_ERRLOG("Failed to poll sock_group=%p\n", tgroup->sock_group);
return rc;
}
return 0;
}
static int
spdk_nvmf_tcp_qpair_get_trid(struct spdk_nvmf_qpair *qpair,
struct spdk_nvme_transport_id *trid, bool peer)
{
struct spdk_nvmf_tcp_qpair *tqpair;
uint16_t port;
tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
trid->trtype = SPDK_NVME_TRANSPORT_TCP;
if (peer) {
snprintf(trid->traddr, sizeof(trid->traddr), "%s", tqpair->initiator_addr);
port = tqpair->initiator_port;
} else {
snprintf(trid->traddr, sizeof(trid->traddr), "%s", tqpair->target_addr);
port = tqpair->target_port;
}
if (spdk_sock_is_ipv4(tqpair->sock)) {
trid->adrfam = SPDK_NVMF_ADRFAM_IPV4;
} else if (spdk_sock_is_ipv4(tqpair->sock)) {
trid->adrfam = SPDK_NVMF_ADRFAM_IPV6;
} else {
return -1;
}
snprintf(trid->trsvcid, sizeof(trid->trsvcid), "%d", port);
return 0;
}
static int
spdk_nvmf_tcp_qpair_get_local_trid(struct spdk_nvmf_qpair *qpair,
struct spdk_nvme_transport_id *trid)
{
return spdk_nvmf_tcp_qpair_get_trid(qpair, trid, 0);
}
static int
spdk_nvmf_tcp_qpair_get_peer_trid(struct spdk_nvmf_qpair *qpair,
struct spdk_nvme_transport_id *trid)
{
return spdk_nvmf_tcp_qpair_get_trid(qpair, trid, 1);
}
static int
spdk_nvmf_tcp_qpair_get_listen_trid(struct spdk_nvmf_qpair *qpair,
struct spdk_nvme_transport_id *trid)
{
return spdk_nvmf_tcp_qpair_get_trid(qpair, trid, 0);
}
static int
spdk_nvmf_tcp_qpair_set_sq_size(struct spdk_nvmf_qpair *qpair)
{
struct spdk_nvmf_tcp_qpair *tqpair;
int rc;
tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
rc = spdk_nvmf_tcp_qpair_init_mem_resource(tqpair, tqpair->qpair.sq_head_max);
if (!rc) {
tqpair->max_queue_depth += tqpair->qpair.sq_head_max;
tqpair->free_pdu_num += tqpair->qpair.sq_head_max;
tqpair->state_cntr[TCP_REQUEST_STATE_FREE] += tqpair->qpair.sq_head_max;
SPDK_DEBUGLOG(SPDK_LOG_NVMF_TCP, "The queue depth=%u for tqpair=%p\n",
tqpair->max_queue_depth, tqpair);
}
return rc;
}
#define SPDK_NVMF_TCP_DEFAULT_MAX_QUEUE_DEPTH 128
#define SPDK_NVMF_TCP_DEFAULT_AQ_DEPTH 128
#define SPDK_NVMF_TCP_DEFAULT_MAX_QPAIRS_PER_CTRLR 128
#define SPDK_NVMF_TCP_DEFAULT_IN_CAPSULE_DATA_SIZE 4096
#define SPDK_NVMF_TCP_DEFAULT_MAX_IO_SIZE 131072
#define SPDK_NVMF_TCP_DEFAULT_IO_UNIT_SIZE 131072
#define SPDK_NVMF_TCP_DEFAULT_NUM_SHARED_BUFFERS 511
#define SPDK_NVMF_TCP_DEFAULT_BUFFER_CACHE_SIZE 32
#define SPDK_NVMF_TCP_DEFAULT_SUCCESS_OPTIMIZATION true
static void
spdk_nvmf_tcp_opts_init(struct spdk_nvmf_transport_opts *opts)
{
opts->max_queue_depth = SPDK_NVMF_TCP_DEFAULT_MAX_QUEUE_DEPTH;
opts->max_qpairs_per_ctrlr = SPDK_NVMF_TCP_DEFAULT_MAX_QPAIRS_PER_CTRLR;
opts->in_capsule_data_size = SPDK_NVMF_TCP_DEFAULT_IN_CAPSULE_DATA_SIZE;
opts->max_io_size = SPDK_NVMF_TCP_DEFAULT_MAX_IO_SIZE;
opts->io_unit_size = SPDK_NVMF_TCP_DEFAULT_IO_UNIT_SIZE;
opts->max_aq_depth = SPDK_NVMF_TCP_DEFAULT_AQ_DEPTH;
opts->num_shared_buffers = SPDK_NVMF_TCP_DEFAULT_NUM_SHARED_BUFFERS;
opts->buf_cache_size = SPDK_NVMF_TCP_DEFAULT_BUFFER_CACHE_SIZE;
opts->c2h_success = SPDK_NVMF_TCP_DEFAULT_SUCCESS_OPTIMIZATION;
}
const struct spdk_nvmf_transport_ops spdk_nvmf_transport_tcp = {
.type = SPDK_NVME_TRANSPORT_TCP,
.opts_init = spdk_nvmf_tcp_opts_init,
.create = spdk_nvmf_tcp_create,
.destroy = spdk_nvmf_tcp_destroy,
.listen = spdk_nvmf_tcp_listen,
.stop_listen = spdk_nvmf_tcp_stop_listen,
.accept = spdk_nvmf_tcp_accept,
.listener_discover = spdk_nvmf_tcp_discover,
.poll_group_create = spdk_nvmf_tcp_poll_group_create,
.poll_group_destroy = spdk_nvmf_tcp_poll_group_destroy,
.poll_group_add = spdk_nvmf_tcp_poll_group_add,
.poll_group_remove = spdk_nvmf_tcp_poll_group_remove,
.poll_group_poll = spdk_nvmf_tcp_poll_group_poll,
.req_free = spdk_nvmf_tcp_req_free,
.req_complete = spdk_nvmf_tcp_req_complete,
.qpair_fini = spdk_nvmf_tcp_close_qpair,
.qpair_get_local_trid = spdk_nvmf_tcp_qpair_get_local_trid,
.qpair_get_peer_trid = spdk_nvmf_tcp_qpair_get_peer_trid,
.qpair_get_listen_trid = spdk_nvmf_tcp_qpair_get_listen_trid,
.qpair_set_sqsize = spdk_nvmf_tcp_qpair_set_sq_size,
};
SPDK_LOG_REGISTER_COMPONENT("nvmf_tcp", SPDK_LOG_NVMF_TCP)