LCOV - code coverage report
Current view: top level - lib/nvmf - tcp.c (source / functions) Hit Total Coverage
Test: ut_cov_unit.info Lines: 696 1996 34.9 %
Date: 2024-12-04 15:00:27 Functions: 45 105 42.9 %

          Line data    Source code
       1             : /*   SPDX-License-Identifier: BSD-3-Clause
       2             :  *   Copyright (C) 2018 Intel Corporation. All rights reserved.
       3             :  *   Copyright (c) 2019, 2020 Mellanox Technologies LTD. All rights reserved.
       4             :  *   Copyright (c) 2022-2024 NVIDIA CORPORATION & AFFILIATES. All rights reserved.
       5             :  */
       6             : 
       7             : #include "spdk/accel.h"
       8             : #include "spdk/stdinc.h"
       9             : #include "spdk/crc32.h"
      10             : #include "spdk/endian.h"
      11             : #include "spdk/assert.h"
      12             : #include "spdk/thread.h"
      13             : #include "spdk/nvmf_transport.h"
      14             : #include "spdk/string.h"
      15             : #include "spdk/trace.h"
      16             : #include "spdk/util.h"
      17             : #include "spdk/log.h"
      18             : #include "spdk/keyring.h"
      19             : 
      20             : #include "spdk_internal/assert.h"
      21             : #include "spdk_internal/nvme_tcp.h"
      22             : #include "spdk_internal/sock.h"
      23             : 
      24             : #include "nvmf_internal.h"
      25             : #include "transport.h"
      26             : 
      27             : #include "spdk_internal/trace_defs.h"
      28             : 
      29             : #define NVMF_TCP_MAX_ACCEPT_SOCK_ONE_TIME 16
      30             : #define SPDK_NVMF_TCP_DEFAULT_MAX_SOCK_PRIORITY 16
      31             : #define SPDK_NVMF_TCP_DEFAULT_SOCK_PRIORITY 0
      32             : #define SPDK_NVMF_TCP_DEFAULT_CONTROL_MSG_NUM 32
      33             : #define SPDK_NVMF_TCP_DEFAULT_SUCCESS_OPTIMIZATION true
      34             : 
      35             : #define SPDK_NVMF_TCP_MIN_IO_QUEUE_DEPTH 2
      36             : #define SPDK_NVMF_TCP_MAX_IO_QUEUE_DEPTH 65535
      37             : #define SPDK_NVMF_TCP_MIN_ADMIN_QUEUE_DEPTH 2
      38             : #define SPDK_NVMF_TCP_MAX_ADMIN_QUEUE_DEPTH 4096
      39             : 
      40             : #define SPDK_NVMF_TCP_DEFAULT_MAX_IO_QUEUE_DEPTH 128
      41             : #define SPDK_NVMF_TCP_DEFAULT_MAX_ADMIN_QUEUE_DEPTH 128
      42             : #define SPDK_NVMF_TCP_DEFAULT_MAX_QPAIRS_PER_CTRLR 128
      43             : #define SPDK_NVMF_TCP_DEFAULT_IN_CAPSULE_DATA_SIZE 4096
      44             : #define SPDK_NVMF_TCP_DEFAULT_MAX_IO_SIZE 131072
      45             : #define SPDK_NVMF_TCP_DEFAULT_IO_UNIT_SIZE 131072
      46             : #define SPDK_NVMF_TCP_DEFAULT_NUM_SHARED_BUFFERS 511
      47             : #define SPDK_NVMF_TCP_DEFAULT_BUFFER_CACHE_SIZE UINT32_MAX
      48             : #define SPDK_NVMF_TCP_DEFAULT_DIF_INSERT_OR_STRIP false
      49             : #define SPDK_NVMF_TCP_DEFAULT_ABORT_TIMEOUT_SEC 1
      50             : 
      51             : const struct spdk_nvmf_transport_ops spdk_nvmf_transport_tcp;
      52             : static bool g_tls_log = false;
      53             : 
      54             : /* spdk nvmf related structure */
      55             : enum spdk_nvmf_tcp_req_state {
      56             : 
      57             :         /* The request is not currently in use */
      58             :         TCP_REQUEST_STATE_FREE = 0,
      59             : 
      60             :         /* Initial state when request first received */
      61             :         TCP_REQUEST_STATE_NEW = 1,
      62             : 
      63             :         /* The request is queued until a data buffer is available. */
      64             :         TCP_REQUEST_STATE_NEED_BUFFER = 2,
      65             : 
      66             :         /* The request has the data buffer available */
      67             :         TCP_REQUEST_STATE_HAVE_BUFFER = 3,
      68             : 
      69             :         /* The request is waiting for zcopy_start to finish */
      70             :         TCP_REQUEST_STATE_AWAITING_ZCOPY_START = 4,
      71             : 
      72             :         /* The request has received a zero-copy buffer */
      73             :         TCP_REQUEST_STATE_ZCOPY_START_COMPLETED = 5,
      74             : 
      75             :         /* The request is currently transferring data from the host to the controller. */
      76             :         TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER = 6,
      77             : 
      78             :         /* The request is waiting for the R2T send acknowledgement. */
      79             :         TCP_REQUEST_STATE_AWAITING_R2T_ACK = 7,
      80             : 
      81             :         /* The request is ready to execute at the block device */
      82             :         TCP_REQUEST_STATE_READY_TO_EXECUTE = 8,
      83             : 
      84             :         /* The request is currently executing at the block device */
      85             :         TCP_REQUEST_STATE_EXECUTING = 9,
      86             : 
      87             :         /* The request is waiting for zcopy buffers to be committed */
      88             :         TCP_REQUEST_STATE_AWAITING_ZCOPY_COMMIT = 10,
      89             : 
      90             :         /* The request finished executing at the block device */
      91             :         TCP_REQUEST_STATE_EXECUTED = 11,
      92             : 
      93             :         /* The request is ready to send a completion */
      94             :         TCP_REQUEST_STATE_READY_TO_COMPLETE = 12,
      95             : 
      96             :         /* The request is currently transferring final pdus from the controller to the host. */
      97             :         TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST = 13,
      98             : 
      99             :         /* The request is waiting for zcopy buffers to be released (without committing) */
     100             :         TCP_REQUEST_STATE_AWAITING_ZCOPY_RELEASE = 14,
     101             : 
     102             :         /* The request completed and can be marked free. */
     103             :         TCP_REQUEST_STATE_COMPLETED = 15,
     104             : 
     105             :         /* Terminator */
     106             :         TCP_REQUEST_NUM_STATES,
     107             : };
     108             : 
     109             : enum nvmf_tcp_qpair_state {
     110             :         NVMF_TCP_QPAIR_STATE_INVALID = 0,
     111             :         NVMF_TCP_QPAIR_STATE_INITIALIZING = 1,
     112             :         NVMF_TCP_QPAIR_STATE_RUNNING = 2,
     113             :         NVMF_TCP_QPAIR_STATE_EXITING = 3,
     114             :         NVMF_TCP_QPAIR_STATE_EXITED = 4,
     115             : };
     116             : 
     117             : static const char *spdk_nvmf_tcp_term_req_fes_str[] = {
     118             :         "Invalid PDU Header Field",
     119             :         "PDU Sequence Error",
     120             :         "Header Digiest Error",
     121             :         "Data Transfer Out of Range",
     122             :         "R2T Limit Exceeded",
     123             :         "Unsupported parameter",
     124             : };
     125             : 
     126             : static void
     127           0 : nvmf_tcp_trace(void)
     128             : {
     129           0 :         spdk_trace_register_owner_type(OWNER_TYPE_NVMF_TCP, 't');
     130           0 :         spdk_trace_register_object(OBJECT_NVMF_TCP_IO, 'r');
     131           0 :         spdk_trace_register_description("TCP_REQ_NEW",
     132             :                                         TRACE_TCP_REQUEST_STATE_NEW,
     133             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 1,
     134             :                                         SPDK_TRACE_ARG_TYPE_INT, "qd");
     135           0 :         spdk_trace_register_description("TCP_REQ_NEED_BUFFER",
     136             :                                         TRACE_TCP_REQUEST_STATE_NEED_BUFFER,
     137             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     138             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     139           0 :         spdk_trace_register_description("TCP_REQ_HAVE_BUFFER",
     140             :                                         TRACE_TCP_REQUEST_STATE_HAVE_BUFFER,
     141             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     142             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     143           0 :         spdk_trace_register_description("TCP_REQ_WAIT_ZCPY_START",
     144             :                                         TRACE_TCP_REQUEST_STATE_AWAIT_ZCOPY_START,
     145             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     146             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     147           0 :         spdk_trace_register_description("TCP_REQ_ZCPY_START_CPL",
     148             :                                         TRACE_TCP_REQUEST_STATE_ZCOPY_START_COMPLETED,
     149             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     150             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     151           0 :         spdk_trace_register_description("TCP_REQ_TX_H_TO_C",
     152             :                                         TRACE_TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER,
     153             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     154             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     155           0 :         spdk_trace_register_description("TCP_REQ_RDY_TO_EXECUTE",
     156             :                                         TRACE_TCP_REQUEST_STATE_READY_TO_EXECUTE,
     157             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     158             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     159           0 :         spdk_trace_register_description("TCP_REQ_EXECUTING",
     160             :                                         TRACE_TCP_REQUEST_STATE_EXECUTING,
     161             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     162             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     163           0 :         spdk_trace_register_description("TCP_REQ_WAIT_ZCPY_CMT",
     164             :                                         TRACE_TCP_REQUEST_STATE_AWAIT_ZCOPY_COMMIT,
     165             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     166             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     167           0 :         spdk_trace_register_description("TCP_REQ_EXECUTED",
     168             :                                         TRACE_TCP_REQUEST_STATE_EXECUTED,
     169             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     170             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     171           0 :         spdk_trace_register_description("TCP_REQ_RDY_TO_COMPLETE",
     172             :                                         TRACE_TCP_REQUEST_STATE_READY_TO_COMPLETE,
     173             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     174             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     175           0 :         spdk_trace_register_description("TCP_REQ_TRANSFER_C2H",
     176             :                                         TRACE_TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST,
     177             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     178             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     179           0 :         spdk_trace_register_description("TCP_REQ_AWAIT_ZCPY_RLS",
     180             :                                         TRACE_TCP_REQUEST_STATE_AWAIT_ZCOPY_RELEASE,
     181             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     182             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     183           0 :         spdk_trace_register_description("TCP_REQ_COMPLETED",
     184             :                                         TRACE_TCP_REQUEST_STATE_COMPLETED,
     185             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     186             :                                         SPDK_TRACE_ARG_TYPE_INT, "qd");
     187           0 :         spdk_trace_register_description("TCP_READ_DONE",
     188             :                                         TRACE_TCP_READ_FROM_SOCKET_DONE,
     189             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NONE, 0,
     190             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     191           0 :         spdk_trace_register_description("TCP_REQ_AWAIT_R2T_ACK",
     192             :                                         TRACE_TCP_REQUEST_STATE_AWAIT_R2T_ACK,
     193             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NVMF_TCP_IO, 0,
     194             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     195             : 
     196           0 :         spdk_trace_register_description("TCP_QP_CREATE", TRACE_TCP_QP_CREATE,
     197             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NONE, 0,
     198             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     199           0 :         spdk_trace_register_description("TCP_QP_SOCK_INIT", TRACE_TCP_QP_SOCK_INIT,
     200             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NONE, 0,
     201             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     202           0 :         spdk_trace_register_description("TCP_QP_STATE_CHANGE", TRACE_TCP_QP_STATE_CHANGE,
     203             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NONE, 0,
     204             :                                         SPDK_TRACE_ARG_TYPE_INT, "state");
     205           0 :         spdk_trace_register_description("TCP_QP_DISCONNECT", TRACE_TCP_QP_DISCONNECT,
     206             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NONE, 0,
     207             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     208           0 :         spdk_trace_register_description("TCP_QP_DESTROY", TRACE_TCP_QP_DESTROY,
     209             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NONE, 0,
     210             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     211           0 :         spdk_trace_register_description("TCP_QP_ABORT_REQ", TRACE_TCP_QP_ABORT_REQ,
     212             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NONE, 0,
     213             :                                         SPDK_TRACE_ARG_TYPE_INT, "");
     214           0 :         spdk_trace_register_description("TCP_QP_RCV_STATE_CHANGE", TRACE_TCP_QP_RCV_STATE_CHANGE,
     215             :                                         OWNER_TYPE_NVMF_TCP, OBJECT_NONE, 0,
     216             :                                         SPDK_TRACE_ARG_TYPE_INT, "state");
     217             : 
     218           0 :         spdk_trace_tpoint_register_relation(TRACE_BDEV_IO_START, OBJECT_NVMF_TCP_IO, 1);
     219           0 :         spdk_trace_tpoint_register_relation(TRACE_BDEV_IO_DONE, OBJECT_NVMF_TCP_IO, 0);
     220           0 :         spdk_trace_tpoint_register_relation(TRACE_SOCK_REQ_QUEUE, OBJECT_NVMF_TCP_IO, 0);
     221           0 :         spdk_trace_tpoint_register_relation(TRACE_SOCK_REQ_PEND, OBJECT_NVMF_TCP_IO, 0);
     222           0 :         spdk_trace_tpoint_register_relation(TRACE_SOCK_REQ_COMPLETE, OBJECT_NVMF_TCP_IO, 0);
     223           0 : }
     224           1 : SPDK_TRACE_REGISTER_FN(nvmf_tcp_trace, "nvmf_tcp", TRACE_GROUP_NVMF_TCP)
     225             : 
     226             : struct spdk_nvmf_tcp_req  {
     227             :         struct spdk_nvmf_request                req;
     228             :         struct spdk_nvme_cpl                    rsp;
     229             :         struct spdk_nvme_cmd                    cmd;
     230             : 
     231             :         /* A PDU that can be used for sending responses. This is
     232             :          * not the incoming PDU! */
     233             :         struct nvme_tcp_pdu                     *pdu;
     234             : 
     235             :         /* In-capsule data buffer */
     236             :         uint8_t                                 *buf;
     237             : 
     238             :         struct spdk_nvmf_tcp_req                *fused_pair;
     239             : 
     240             :         /*
     241             :          * The PDU for a request may be used multiple times in serial over
     242             :          * the request's lifetime. For example, first to send an R2T, then
     243             :          * to send a completion. To catch mistakes where the PDU is used
     244             :          * twice at the same time, add a debug flag here for init/fini.
     245             :          */
     246             :         bool                                    pdu_in_use;
     247             :         bool                                    has_in_capsule_data;
     248             :         bool                                    fused_failed;
     249             : 
     250             :         /* transfer_tag */
     251             :         uint16_t                                ttag;
     252             : 
     253             :         enum spdk_nvmf_tcp_req_state            state;
     254             : 
     255             :         /*
     256             :          * h2c_offset is used when we receive the h2c_data PDU.
     257             :          */
     258             :         uint32_t                                h2c_offset;
     259             : 
     260             :         STAILQ_ENTRY(spdk_nvmf_tcp_req)         link;
     261             :         TAILQ_ENTRY(spdk_nvmf_tcp_req)          state_link;
     262             :         STAILQ_ENTRY(spdk_nvmf_tcp_req)         control_msg_link;
     263             : };
     264             : 
     265             : struct spdk_nvmf_tcp_qpair {
     266             :         struct spdk_nvmf_qpair                  qpair;
     267             :         struct spdk_nvmf_tcp_poll_group         *group;
     268             :         struct spdk_sock                        *sock;
     269             : 
     270             :         enum nvme_tcp_pdu_recv_state            recv_state;
     271             :         enum nvmf_tcp_qpair_state               state;
     272             : 
     273             :         /* PDU being actively received */
     274             :         struct nvme_tcp_pdu                     *pdu_in_progress;
     275             : 
     276             :         struct spdk_nvmf_tcp_req                *fused_first;
     277             : 
     278             :         /* Queues to track the requests in all states */
     279             :         TAILQ_HEAD(, spdk_nvmf_tcp_req)         tcp_req_working_queue;
     280             :         TAILQ_HEAD(, spdk_nvmf_tcp_req)         tcp_req_free_queue;
     281             :         SLIST_HEAD(, nvme_tcp_pdu)              tcp_pdu_free_queue;
     282             :         /* Number of working pdus */
     283             :         uint32_t                                tcp_pdu_working_count;
     284             : 
     285             :         /* Number of requests in each state */
     286             :         uint32_t                                state_cntr[TCP_REQUEST_NUM_STATES];
     287             : 
     288             :         uint8_t                                 cpda;
     289             : 
     290             :         bool                                    host_hdgst_enable;
     291             :         bool                                    host_ddgst_enable;
     292             : 
     293             :         bool                                    await_req_msg_pending;
     294             : 
     295             :         /* This is a spare PDU used for sending special management
     296             :          * operations. Primarily, this is used for the initial
     297             :          * connection response and c2h termination request. */
     298             :         struct nvme_tcp_pdu                     *mgmt_pdu;
     299             : 
     300             :         /* Arrays of in-capsule buffers, requests, and pdus.
     301             :          * Each array is 'resource_count' number of elements */
     302             :         void                                    *bufs;
     303             :         struct spdk_nvmf_tcp_req                *reqs;
     304             :         struct nvme_tcp_pdu                     *pdus;
     305             :         uint32_t                                resource_count;
     306             :         uint32_t                                recv_buf_size;
     307             : 
     308             :         struct spdk_nvmf_tcp_port               *port;
     309             : 
     310             :         /* IP address */
     311             :         char                                    initiator_addr[SPDK_NVMF_TRADDR_MAX_LEN];
     312             :         char                                    target_addr[SPDK_NVMF_TRADDR_MAX_LEN];
     313             : 
     314             :         /* IP port */
     315             :         uint16_t                                initiator_port;
     316             :         uint16_t                                target_port;
     317             : 
     318             :         /* Wait until the host terminates the connection (e.g. after sending C2HTermReq) */
     319             :         bool                                    wait_terminate;
     320             : 
     321             :         /* Timer used to destroy qpair after detecting transport error issue if initiator does
     322             :          *  not close the connection.
     323             :          */
     324             :         struct spdk_poller                      *timeout_poller;
     325             : 
     326             :         spdk_nvmf_transport_qpair_fini_cb       fini_cb_fn;
     327             :         void                                    *fini_cb_arg;
     328             : 
     329             :         TAILQ_ENTRY(spdk_nvmf_tcp_qpair)        link;
     330             :         bool                                    pending_flush;
     331             : };
     332             : 
     333             : struct spdk_nvmf_tcp_control_msg {
     334             :         STAILQ_ENTRY(spdk_nvmf_tcp_control_msg) link;
     335             : };
     336             : 
     337             : struct spdk_nvmf_tcp_control_msg_list {
     338             :         void *msg_buf;
     339             :         STAILQ_HEAD(, spdk_nvmf_tcp_control_msg) free_msgs;
     340             :         STAILQ_HEAD(, spdk_nvmf_tcp_req) waiting_for_msg_reqs;
     341             : };
     342             : 
     343             : struct spdk_nvmf_tcp_poll_group {
     344             :         struct spdk_nvmf_transport_poll_group   group;
     345             :         struct spdk_sock_group                  *sock_group;
     346             : 
     347             :         TAILQ_HEAD(, spdk_nvmf_tcp_qpair)       qpairs;
     348             : 
     349             :         struct spdk_io_channel                  *accel_channel;
     350             :         struct spdk_nvmf_tcp_control_msg_list   *control_msg_list;
     351             : 
     352             :         TAILQ_ENTRY(spdk_nvmf_tcp_poll_group)   link;
     353             : };
     354             : 
     355             : struct spdk_nvmf_tcp_port {
     356             :         const struct spdk_nvme_transport_id     *trid;
     357             :         struct spdk_sock                        *listen_sock;
     358             :         struct spdk_nvmf_transport              *transport;
     359             :         TAILQ_ENTRY(spdk_nvmf_tcp_port)         link;
     360             : };
     361             : 
     362             : struct tcp_transport_opts {
     363             :         bool            c2h_success;
     364             :         uint16_t        control_msg_num;
     365             :         uint32_t        sock_priority;
     366             : };
     367             : 
     368             : struct tcp_psk_entry {
     369             :         char                            hostnqn[SPDK_NVMF_NQN_MAX_LEN + 1];
     370             :         char                            subnqn[SPDK_NVMF_NQN_MAX_LEN + 1];
     371             :         char                            pskid[NVMF_PSK_IDENTITY_LEN];
     372             :         uint8_t                         psk[SPDK_TLS_PSK_MAX_LEN];
     373             :         struct spdk_key                 *key;
     374             :         uint32_t                        psk_size;
     375             :         enum nvme_tcp_cipher_suite      tls_cipher_suite;
     376             :         TAILQ_ENTRY(tcp_psk_entry)      link;
     377             : };
     378             : 
     379             : struct spdk_nvmf_tcp_transport {
     380             :         struct spdk_nvmf_transport              transport;
     381             :         struct tcp_transport_opts               tcp_opts;
     382             :         uint32_t                                ack_timeout;
     383             : 
     384             :         struct spdk_nvmf_tcp_poll_group         *next_pg;
     385             : 
     386             :         struct spdk_poller                      *accept_poller;
     387             :         struct spdk_sock_group                  *listen_sock_group;
     388             : 
     389             :         TAILQ_HEAD(, spdk_nvmf_tcp_port)        ports;
     390             :         TAILQ_HEAD(, spdk_nvmf_tcp_poll_group)  poll_groups;
     391             : 
     392             :         TAILQ_HEAD(, tcp_psk_entry)             psks;
     393             : };
     394             : 
     395             : static const struct spdk_json_object_decoder tcp_transport_opts_decoder[] = {
     396             :         {
     397             :                 "c2h_success", offsetof(struct tcp_transport_opts, c2h_success),
     398             :                 spdk_json_decode_bool, true
     399             :         },
     400             :         {
     401             :                 "control_msg_num", offsetof(struct tcp_transport_opts, control_msg_num),
     402             :                 spdk_json_decode_uint16, true
     403             :         },
     404             :         {
     405             :                 "sock_priority", offsetof(struct tcp_transport_opts, sock_priority),
     406             :                 spdk_json_decode_uint32, true
     407             :         },
     408             : };
     409             : 
     410             : static bool nvmf_tcp_req_process(struct spdk_nvmf_tcp_transport *ttransport,
     411             :                                  struct spdk_nvmf_tcp_req *tcp_req);
     412             : static void nvmf_tcp_poll_group_destroy(struct spdk_nvmf_transport_poll_group *group);
     413             : 
     414             : static void _nvmf_tcp_send_c2h_data(struct spdk_nvmf_tcp_qpair *tqpair,
     415             :                                     struct spdk_nvmf_tcp_req *tcp_req);
     416             : static void nvmf_tcp_qpair_process(struct spdk_nvmf_tcp_qpair *tqpair);
     417             : 
     418             : static inline void
     419          10 : nvmf_tcp_req_set_state(struct spdk_nvmf_tcp_req *tcp_req,
     420             :                        enum spdk_nvmf_tcp_req_state state)
     421             : {
     422             :         struct spdk_nvmf_qpair *qpair;
     423             :         struct spdk_nvmf_tcp_qpair *tqpair;
     424             : 
     425          10 :         qpair = tcp_req->req.qpair;
     426          10 :         tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
     427             : 
     428          10 :         assert(tqpair->state_cntr[tcp_req->state] > 0);
     429          10 :         tqpair->state_cntr[tcp_req->state]--;
     430          10 :         tqpair->state_cntr[state]++;
     431             : 
     432          10 :         tcp_req->state = state;
     433          10 : }
     434             : 
     435             : static inline struct nvme_tcp_pdu *
     436           7 : nvmf_tcp_req_pdu_init(struct spdk_nvmf_tcp_req *tcp_req)
     437             : {
     438           7 :         assert(tcp_req->pdu_in_use == false);
     439             : 
     440           7 :         memset(tcp_req->pdu, 0, sizeof(*tcp_req->pdu));
     441           7 :         tcp_req->pdu->qpair = SPDK_CONTAINEROF(tcp_req->req.qpair, struct spdk_nvmf_tcp_qpair, qpair);
     442             : 
     443           7 :         return tcp_req->pdu;
     444             : }
     445             : 
     446             : static struct spdk_nvmf_tcp_req *
     447           1 : nvmf_tcp_req_get(struct spdk_nvmf_tcp_qpair *tqpair)
     448             : {
     449             :         struct spdk_nvmf_tcp_req *tcp_req;
     450             : 
     451           1 :         tcp_req = TAILQ_FIRST(&tqpair->tcp_req_free_queue);
     452           1 :         if (spdk_unlikely(!tcp_req)) {
     453           0 :                 return NULL;
     454             :         }
     455             : 
     456           1 :         memset(&tcp_req->rsp, 0, sizeof(tcp_req->rsp));
     457           1 :         tcp_req->h2c_offset = 0;
     458           1 :         tcp_req->has_in_capsule_data = false;
     459           1 :         tcp_req->req.dif_enabled = false;
     460           1 :         tcp_req->req.zcopy_phase = NVMF_ZCOPY_PHASE_NONE;
     461             : 
     462           1 :         TAILQ_REMOVE(&tqpair->tcp_req_free_queue, tcp_req, state_link);
     463           1 :         TAILQ_INSERT_TAIL(&tqpair->tcp_req_working_queue, tcp_req, state_link);
     464           1 :         tqpair->qpair.queue_depth++;
     465           1 :         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_NEW);
     466           1 :         return tcp_req;
     467           1 : }
     468             : 
     469             : static void
     470           0 : handle_await_req(void *arg)
     471             : {
     472           0 :         struct spdk_nvmf_tcp_qpair *tqpair = arg;
     473             : 
     474           0 :         tqpair->await_req_msg_pending = false;
     475           0 :         if (tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_REQ) {
     476           0 :                 nvmf_tcp_qpair_process(tqpair);
     477           0 :         }
     478           0 : }
     479             : 
     480             : static inline void
     481           0 : nvmf_tcp_req_put(struct spdk_nvmf_tcp_qpair *tqpair, struct spdk_nvmf_tcp_req *tcp_req)
     482             : {
     483           0 :         assert(!tcp_req->pdu_in_use);
     484             : 
     485           0 :         TAILQ_REMOVE(&tqpair->tcp_req_working_queue, tcp_req, state_link);
     486           0 :         TAILQ_INSERT_TAIL(&tqpair->tcp_req_free_queue, tcp_req, state_link);
     487           0 :         tqpair->qpair.queue_depth--;
     488           0 :         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_FREE);
     489           0 :         if (tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_REQ &&
     490           0 :             !tqpair->await_req_msg_pending) {
     491           0 :                 tqpair->await_req_msg_pending = true;
     492           0 :                 spdk_thread_send_msg(spdk_get_thread(), handle_await_req, tqpair);
     493           0 :         }
     494           0 : }
     495             : 
     496             : static void
     497           1 : nvmf_tcp_req_get_buffers_done(struct spdk_nvmf_request *req)
     498             : {
     499             :         struct spdk_nvmf_tcp_req *tcp_req;
     500             :         struct spdk_nvmf_transport *transport;
     501             :         struct spdk_nvmf_tcp_transport *ttransport;
     502             : 
     503           1 :         tcp_req = SPDK_CONTAINEROF(req, struct spdk_nvmf_tcp_req, req);
     504           1 :         transport = req->qpair->transport;
     505           1 :         ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
     506             : 
     507           1 :         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_HAVE_BUFFER);
     508           1 :         nvmf_tcp_req_process(ttransport, tcp_req);
     509           1 : }
     510             : 
     511             : static void
     512           0 : nvmf_tcp_request_free(void *cb_arg)
     513             : {
     514             :         struct spdk_nvmf_tcp_transport *ttransport;
     515           0 :         struct spdk_nvmf_tcp_req *tcp_req = cb_arg;
     516             : 
     517           0 :         assert(tcp_req != NULL);
     518             : 
     519           0 :         SPDK_DEBUGLOG(nvmf_tcp, "tcp_req=%p will be freed\n", tcp_req);
     520           0 :         ttransport = SPDK_CONTAINEROF(tcp_req->req.qpair->transport,
     521             :                                       struct spdk_nvmf_tcp_transport, transport);
     522           0 :         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_COMPLETED);
     523           0 :         nvmf_tcp_req_process(ttransport, tcp_req);
     524           0 : }
     525             : 
     526             : static int
     527           0 : nvmf_tcp_req_free(struct spdk_nvmf_request *req)
     528             : {
     529           0 :         struct spdk_nvmf_tcp_req *tcp_req = SPDK_CONTAINEROF(req, struct spdk_nvmf_tcp_req, req);
     530             : 
     531           0 :         nvmf_tcp_request_free(tcp_req);
     532             : 
     533           0 :         return 0;
     534             : }
     535             : 
     536             : static void
     537           6 : nvmf_tcp_drain_state_queue(struct spdk_nvmf_tcp_qpair *tqpair,
     538             :                            enum spdk_nvmf_tcp_req_state state)
     539             : {
     540             :         struct spdk_nvmf_tcp_req *tcp_req, *req_tmp;
     541             : 
     542           6 :         assert(state != TCP_REQUEST_STATE_FREE);
     543           6 :         TAILQ_FOREACH_SAFE(tcp_req, &tqpair->tcp_req_working_queue, state_link, req_tmp) {
     544           0 :                 if (state == tcp_req->state) {
     545           0 :                         nvmf_tcp_request_free(tcp_req);
     546           0 :                 }
     547           0 :         }
     548           6 : }
     549             : 
     550             : static inline void
     551           0 : nvmf_tcp_request_get_buffers_abort(struct spdk_nvmf_tcp_req *tcp_req)
     552             : {
     553             :         /* Request can wait either for the iobuf or control_msg */
     554           0 :         struct spdk_nvmf_poll_group *group = tcp_req->req.qpair->group;
     555           0 :         struct spdk_nvmf_transport *transport = tcp_req->req.qpair->transport;
     556           0 :         struct spdk_nvmf_transport_poll_group *tgroup = nvmf_get_transport_poll_group(group, transport);
     557           0 :         struct spdk_nvmf_tcp_poll_group *tcp_group = SPDK_CONTAINEROF(tgroup,
     558             :                         struct spdk_nvmf_tcp_poll_group, group);
     559             :         struct spdk_nvmf_tcp_req *tmp_req, *abort_req;
     560             : 
     561           0 :         assert(tcp_req->state == TCP_REQUEST_STATE_NEED_BUFFER);
     562             : 
     563           0 :         STAILQ_FOREACH_SAFE(abort_req, &tcp_group->control_msg_list->waiting_for_msg_reqs, control_msg_link,
     564             :                             tmp_req) {
     565           0 :                 if (abort_req == tcp_req) {
     566           0 :                         STAILQ_REMOVE(&tcp_group->control_msg_list->waiting_for_msg_reqs, abort_req, spdk_nvmf_tcp_req,
     567             :                                       control_msg_link);
     568           0 :                         return;
     569             :                 }
     570           0 :         }
     571             : 
     572           0 :         if (!nvmf_request_get_buffers_abort(&tcp_req->req)) {
     573           0 :                 SPDK_ERRLOG("Failed to abort tcp_req=%p\n", tcp_req);
     574           0 :                 assert(0 && "Should never happen");
     575             :         }
     576           0 : }
     577             : 
     578             : static void
     579           1 : nvmf_tcp_cleanup_all_states(struct spdk_nvmf_tcp_qpair *tqpair)
     580             : {
     581             :         struct spdk_nvmf_tcp_req *tcp_req, *req_tmp;
     582             : 
     583           1 :         nvmf_tcp_drain_state_queue(tqpair, TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST);
     584           1 :         nvmf_tcp_drain_state_queue(tqpair, TCP_REQUEST_STATE_NEW);
     585             : 
     586             :         /* Wipe the requests waiting for buffer from the waiting list */
     587           1 :         TAILQ_FOREACH_SAFE(tcp_req, &tqpair->tcp_req_working_queue, state_link, req_tmp) {
     588           0 :                 if (tcp_req->state == TCP_REQUEST_STATE_NEED_BUFFER) {
     589           0 :                         nvmf_tcp_request_get_buffers_abort(tcp_req);
     590           0 :                 }
     591           0 :         }
     592             : 
     593           1 :         nvmf_tcp_drain_state_queue(tqpair, TCP_REQUEST_STATE_NEED_BUFFER);
     594           1 :         nvmf_tcp_drain_state_queue(tqpair, TCP_REQUEST_STATE_EXECUTING);
     595           1 :         nvmf_tcp_drain_state_queue(tqpair, TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER);
     596           1 :         nvmf_tcp_drain_state_queue(tqpair, TCP_REQUEST_STATE_AWAITING_R2T_ACK);
     597           1 : }
     598             : 
     599             : static void
     600           0 : nvmf_tcp_dump_qpair_req_contents(struct spdk_nvmf_tcp_qpair *tqpair)
     601             : {
     602             :         int i;
     603             :         struct spdk_nvmf_tcp_req *tcp_req;
     604             : 
     605           0 :         SPDK_ERRLOG("Dumping contents of queue pair (QID %d)\n", tqpair->qpair.qid);
     606           0 :         for (i = 1; i < TCP_REQUEST_NUM_STATES; i++) {
     607           0 :                 SPDK_ERRLOG("\tNum of requests in state[%d] = %u\n", i, tqpair->state_cntr[i]);
     608           0 :                 TAILQ_FOREACH(tcp_req, &tqpair->tcp_req_working_queue, state_link) {
     609           0 :                         if ((int)tcp_req->state == i) {
     610           0 :                                 SPDK_ERRLOG("\t\tRequest Data From Pool: %d\n", tcp_req->req.data_from_pool);
     611           0 :                                 SPDK_ERRLOG("\t\tRequest opcode: %d\n", tcp_req->req.cmd->nvmf_cmd.opcode);
     612           0 :                         }
     613           0 :                 }
     614           0 :         }
     615           0 : }
     616             : 
     617             : static void
     618           1 : _nvmf_tcp_qpair_destroy(void *_tqpair)
     619             : {
     620           1 :         struct spdk_nvmf_tcp_qpair *tqpair = _tqpair;
     621           1 :         spdk_nvmf_transport_qpair_fini_cb cb_fn = tqpair->fini_cb_fn;
     622           1 :         void *cb_arg = tqpair->fini_cb_arg;
     623           1 :         int err = 0;
     624             : 
     625           1 :         spdk_trace_record(TRACE_TCP_QP_DESTROY, tqpair->qpair.trace_id, 0, 0);
     626             : 
     627           1 :         SPDK_DEBUGLOG(nvmf_tcp, "enter\n");
     628             : 
     629           1 :         err = spdk_sock_close(&tqpair->sock);
     630           1 :         assert(err == 0);
     631           1 :         nvmf_tcp_cleanup_all_states(tqpair);
     632             : 
     633           1 :         if (tqpair->state_cntr[TCP_REQUEST_STATE_FREE] != tqpair->resource_count) {
     634           0 :                 SPDK_ERRLOG("tqpair(%p) free tcp request num is %u but should be %u\n", tqpair,
     635             :                             tqpair->state_cntr[TCP_REQUEST_STATE_FREE],
     636             :                             tqpair->resource_count);
     637           0 :                 err++;
     638           0 :         }
     639             : 
     640           1 :         if (err > 0) {
     641           0 :                 nvmf_tcp_dump_qpair_req_contents(tqpair);
     642           0 :         }
     643             : 
     644             :         /* The timeout poller might still be registered here if we close the qpair before host
     645             :          * terminates the connection.
     646             :          */
     647           1 :         spdk_poller_unregister(&tqpair->timeout_poller);
     648           1 :         spdk_dma_free(tqpair->pdus);
     649           1 :         free(tqpair->reqs);
     650           1 :         spdk_free(tqpair->bufs);
     651           1 :         spdk_trace_unregister_owner(tqpair->qpair.trace_id);
     652           1 :         free(tqpair);
     653             : 
     654           1 :         if (cb_fn != NULL) {
     655           0 :                 cb_fn(cb_arg);
     656           0 :         }
     657             : 
     658           1 :         SPDK_DEBUGLOG(nvmf_tcp, "Leave\n");
     659           1 : }
     660             : 
     661             : static void
     662           1 : nvmf_tcp_qpair_destroy(struct spdk_nvmf_tcp_qpair *tqpair)
     663             : {
     664             :         /* Delay the destruction to make sure it isn't performed from the context of a sock
     665             :          * callback.  Otherwise, spdk_sock_close() might not abort pending requests, causing their
     666             :          * completions to be executed after the qpair is freed.  (Note: this fixed issue #2471.)
     667             :          */
     668           1 :         spdk_thread_send_msg(spdk_get_thread(), _nvmf_tcp_qpair_destroy, tqpair);
     669           1 : }
     670             : 
     671             : static void
     672           0 : nvmf_tcp_dump_opts(struct spdk_nvmf_transport *transport, struct spdk_json_write_ctx *w)
     673             : {
     674             :         struct spdk_nvmf_tcp_transport  *ttransport;
     675           0 :         assert(w != NULL);
     676             : 
     677           0 :         ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
     678           0 :         spdk_json_write_named_bool(w, "c2h_success", ttransport->tcp_opts.c2h_success);
     679           0 :         spdk_json_write_named_uint32(w, "sock_priority", ttransport->tcp_opts.sock_priority);
     680           0 : }
     681             : 
     682             : static void
     683           1 : nvmf_tcp_free_psk_entry(struct tcp_psk_entry *entry)
     684             : {
     685           1 :         if (entry == NULL) {
     686           0 :                 return;
     687             :         }
     688             : 
     689           1 :         spdk_memset_s(entry->psk, sizeof(entry->psk), 0, sizeof(entry->psk));
     690           1 :         spdk_keyring_put_key(entry->key);
     691           1 :         free(entry);
     692           1 : }
     693             : 
     694             : static int
     695           5 : nvmf_tcp_destroy(struct spdk_nvmf_transport *transport,
     696             :                  spdk_nvmf_transport_destroy_done_cb cb_fn, void *cb_arg)
     697             : {
     698             :         struct spdk_nvmf_tcp_transport  *ttransport;
     699             :         struct tcp_psk_entry *entry, *tmp;
     700             : 
     701           5 :         assert(transport != NULL);
     702           5 :         ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
     703             : 
     704           5 :         TAILQ_FOREACH_SAFE(entry, &ttransport->psks, link, tmp) {
     705           0 :                 TAILQ_REMOVE(&ttransport->psks, entry, link);
     706           0 :                 nvmf_tcp_free_psk_entry(entry);
     707           0 :         }
     708             : 
     709           5 :         spdk_poller_unregister(&ttransport->accept_poller);
     710           5 :         spdk_sock_group_unregister_interrupt(ttransport->listen_sock_group);
     711           5 :         spdk_sock_group_close(&ttransport->listen_sock_group);
     712           5 :         free(ttransport);
     713             : 
     714           5 :         if (cb_fn) {
     715           0 :                 cb_fn(cb_arg);
     716           0 :         }
     717           5 :         return 0;
     718             : }
     719             : 
     720             : static int nvmf_tcp_accept(void *ctx);
     721             : 
     722             : static void nvmf_tcp_accept_cb(void *ctx, struct spdk_sock_group *group, struct spdk_sock *sock);
     723             : 
     724             : static struct spdk_nvmf_transport *
     725           6 : nvmf_tcp_create(struct spdk_nvmf_transport_opts *opts)
     726             : {
     727             :         struct spdk_nvmf_tcp_transport *ttransport;
     728             :         uint32_t sge_count;
     729             :         uint32_t min_shared_buffers;
     730             :         int rc;
     731             :         uint64_t period;
     732             : 
     733           6 :         ttransport = calloc(1, sizeof(*ttransport));
     734           6 :         if (!ttransport) {
     735           0 :                 return NULL;
     736             :         }
     737             : 
     738           6 :         TAILQ_INIT(&ttransport->ports);
     739           6 :         TAILQ_INIT(&ttransport->poll_groups);
     740           6 :         TAILQ_INIT(&ttransport->psks);
     741             : 
     742           6 :         ttransport->transport.ops = &spdk_nvmf_transport_tcp;
     743             : 
     744           6 :         ttransport->tcp_opts.c2h_success = SPDK_NVMF_TCP_DEFAULT_SUCCESS_OPTIMIZATION;
     745           6 :         ttransport->tcp_opts.sock_priority = SPDK_NVMF_TCP_DEFAULT_SOCK_PRIORITY;
     746           6 :         ttransport->tcp_opts.control_msg_num = SPDK_NVMF_TCP_DEFAULT_CONTROL_MSG_NUM;
     747           6 :         if (opts->transport_specific != NULL &&
     748           0 :             spdk_json_decode_object_relaxed(opts->transport_specific, tcp_transport_opts_decoder,
     749             :                                             SPDK_COUNTOF(tcp_transport_opts_decoder),
     750           0 :                                             &ttransport->tcp_opts)) {
     751           0 :                 SPDK_ERRLOG("spdk_json_decode_object_relaxed failed\n");
     752           0 :                 free(ttransport);
     753           0 :                 return NULL;
     754             :         }
     755             : 
     756           6 :         SPDK_NOTICELOG("*** TCP Transport Init ***\n");
     757             : 
     758           6 :         SPDK_INFOLOG(nvmf_tcp, "*** TCP Transport Init ***\n"
     759             :                      "  Transport opts:  max_ioq_depth=%d, max_io_size=%d,\n"
     760             :                      "  max_io_qpairs_per_ctrlr=%d, io_unit_size=%d,\n"
     761             :                      "  in_capsule_data_size=%d, max_aq_depth=%d\n"
     762             :                      "  num_shared_buffers=%d, c2h_success=%d,\n"
     763             :                      "  dif_insert_or_strip=%d, sock_priority=%d\n"
     764             :                      "  abort_timeout_sec=%d, control_msg_num=%hu\n"
     765             :                      "  ack_timeout=%d\n",
     766             :                      opts->max_queue_depth,
     767             :                      opts->max_io_size,
     768             :                      opts->max_qpairs_per_ctrlr - 1,
     769             :                      opts->io_unit_size,
     770             :                      opts->in_capsule_data_size,
     771             :                      opts->max_aq_depth,
     772             :                      opts->num_shared_buffers,
     773             :                      ttransport->tcp_opts.c2h_success,
     774             :                      opts->dif_insert_or_strip,
     775             :                      ttransport->tcp_opts.sock_priority,
     776             :                      opts->abort_timeout_sec,
     777             :                      ttransport->tcp_opts.control_msg_num,
     778             :                      opts->ack_timeout);
     779             : 
     780           6 :         if (ttransport->tcp_opts.sock_priority > SPDK_NVMF_TCP_DEFAULT_MAX_SOCK_PRIORITY) {
     781           0 :                 SPDK_ERRLOG("Unsupported socket_priority=%d, the current range is: 0 to %d\n"
     782             :                             "you can use man 7 socket to view the range of priority under SO_PRIORITY item\n",
     783             :                             ttransport->tcp_opts.sock_priority, SPDK_NVMF_TCP_DEFAULT_MAX_SOCK_PRIORITY);
     784           0 :                 free(ttransport);
     785           0 :                 return NULL;
     786             :         }
     787             : 
     788           6 :         if (ttransport->tcp_opts.control_msg_num == 0 &&
     789           0 :             opts->in_capsule_data_size < SPDK_NVME_TCP_IN_CAPSULE_DATA_MAX_SIZE) {
     790           0 :                 SPDK_WARNLOG("TCP param control_msg_num can't be 0 if ICD is less than %u bytes. Using default value %u\n",
     791             :                              SPDK_NVME_TCP_IN_CAPSULE_DATA_MAX_SIZE, SPDK_NVMF_TCP_DEFAULT_CONTROL_MSG_NUM);
     792           0 :                 ttransport->tcp_opts.control_msg_num = SPDK_NVMF_TCP_DEFAULT_CONTROL_MSG_NUM;
     793           0 :         }
     794             : 
     795             :         /* I/O unit size cannot be larger than max I/O size */
     796           6 :         if (opts->io_unit_size > opts->max_io_size) {
     797           1 :                 SPDK_WARNLOG("TCP param io_unit_size %u can't be larger than max_io_size %u. Using max_io_size as io_unit_size\n",
     798             :                              opts->io_unit_size, opts->max_io_size);
     799           1 :                 opts->io_unit_size = opts->max_io_size;
     800           1 :         }
     801             : 
     802             :         /* In capsule data size cannot be larger than max I/O size */
     803           6 :         if (opts->in_capsule_data_size > opts->max_io_size) {
     804           0 :                 SPDK_WARNLOG("TCP param ICD size %u can't be larger than max_io_size %u. Using max_io_size as ICD size\n",
     805             :                              opts->io_unit_size, opts->max_io_size);
     806           0 :                 opts->in_capsule_data_size = opts->max_io_size;
     807           0 :         }
     808             : 
     809             :         /* max IO queue depth cannot be smaller than 2 or larger than 65535.
     810             :          * We will not check SPDK_NVMF_TCP_MAX_IO_QUEUE_DEPTH, because max_queue_depth is 16bits and always not larger than 64k. */
     811           6 :         if (opts->max_queue_depth < SPDK_NVMF_TCP_MIN_IO_QUEUE_DEPTH) {
     812           0 :                 SPDK_WARNLOG("TCP param max_queue_depth %u can't be smaller than %u or larger than %u. Using default value %u\n",
     813             :                              opts->max_queue_depth, SPDK_NVMF_TCP_MIN_IO_QUEUE_DEPTH,
     814             :                              SPDK_NVMF_TCP_MAX_IO_QUEUE_DEPTH, SPDK_NVMF_TCP_DEFAULT_MAX_IO_QUEUE_DEPTH);
     815           0 :                 opts->max_queue_depth = SPDK_NVMF_TCP_DEFAULT_MAX_IO_QUEUE_DEPTH;
     816           0 :         }
     817             : 
     818             :         /* max admin queue depth cannot be smaller than 2 or larger than 4096 */
     819           6 :         if (opts->max_aq_depth < SPDK_NVMF_TCP_MIN_ADMIN_QUEUE_DEPTH ||
     820           6 :             opts->max_aq_depth > SPDK_NVMF_TCP_MAX_ADMIN_QUEUE_DEPTH) {
     821           0 :                 SPDK_WARNLOG("TCP param max_aq_depth %u can't be smaller than %u or larger than %u. Using default value %u\n",
     822             :                              opts->max_aq_depth, SPDK_NVMF_TCP_MIN_ADMIN_QUEUE_DEPTH,
     823             :                              SPDK_NVMF_TCP_MAX_ADMIN_QUEUE_DEPTH, SPDK_NVMF_TCP_DEFAULT_MAX_ADMIN_QUEUE_DEPTH);
     824           0 :                 opts->max_aq_depth = SPDK_NVMF_TCP_DEFAULT_MAX_ADMIN_QUEUE_DEPTH;
     825           0 :         }
     826             : 
     827           6 :         sge_count = opts->max_io_size / opts->io_unit_size;
     828           6 :         if (sge_count > SPDK_NVMF_MAX_SGL_ENTRIES) {
     829           1 :                 SPDK_ERRLOG("Unsupported IO Unit size specified, %d bytes\n", opts->io_unit_size);
     830           1 :                 free(ttransport);
     831           1 :                 return NULL;
     832             :         }
     833             : 
     834             :         /* If buf_cache_size == UINT32_MAX, we will dynamically pick a cache size later that we know will fit. */
     835           5 :         if (opts->buf_cache_size < UINT32_MAX) {
     836           5 :                 min_shared_buffers = spdk_env_get_core_count() * opts->buf_cache_size;
     837           5 :                 if (min_shared_buffers > opts->num_shared_buffers) {
     838           0 :                         SPDK_ERRLOG("There are not enough buffers to satisfy "
     839             :                                     "per-poll group caches for each thread. (%" PRIu32 ") "
     840             :                                     "supplied. (%" PRIu32 ") required\n", opts->num_shared_buffers, min_shared_buffers);
     841           0 :                         SPDK_ERRLOG("Please specify a larger number of shared buffers\n");
     842           0 :                         free(ttransport);
     843           0 :                         return NULL;
     844             :                 }
     845           5 :         }
     846             : 
     847           5 :         period = spdk_interrupt_mode_is_enabled() ? 0 : opts->acceptor_poll_rate;
     848           5 :         ttransport->accept_poller = SPDK_POLLER_REGISTER(nvmf_tcp_accept, &ttransport->transport, period);
     849           5 :         if (!ttransport->accept_poller) {
     850           0 :                 free(ttransport);
     851           0 :                 return NULL;
     852             :         }
     853             : 
     854           5 :         spdk_poller_register_interrupt(ttransport->accept_poller, NULL, NULL);
     855             : 
     856           5 :         ttransport->listen_sock_group = spdk_sock_group_create(NULL);
     857           5 :         if (ttransport->listen_sock_group == NULL) {
     858           0 :                 SPDK_ERRLOG("Failed to create socket group for listen sockets\n");
     859           0 :                 spdk_poller_unregister(&ttransport->accept_poller);
     860           0 :                 free(ttransport);
     861           0 :                 return NULL;
     862             :         }
     863             : 
     864           5 :         if (spdk_interrupt_mode_is_enabled()) {
     865           0 :                 rc = SPDK_SOCK_GROUP_REGISTER_INTERRUPT(ttransport->listen_sock_group,
     866             :                                                         SPDK_INTERRUPT_EVENT_IN | SPDK_INTERRUPT_EVENT_OUT, nvmf_tcp_accept, &ttransport->transport);
     867           0 :                 if (rc != 0) {
     868           0 :                         SPDK_ERRLOG("Failed to register interrupt for listen socker sock group\n");
     869           0 :                         spdk_sock_group_close(&ttransport->listen_sock_group);
     870           0 :                         spdk_poller_unregister(&ttransport->accept_poller);
     871           0 :                         free(ttransport);
     872           0 :                         return NULL;
     873             :                 }
     874           0 :         }
     875             : 
     876           5 :         return &ttransport->transport;
     877           6 : }
     878             : 
     879             : static int
     880           0 : nvmf_tcp_trsvcid_to_int(const char *trsvcid)
     881             : {
     882             :         unsigned long long ull;
     883           0 :         char *end = NULL;
     884             : 
     885           0 :         ull = strtoull(trsvcid, &end, 10);
     886           0 :         if (end == NULL || end == trsvcid || *end != '\0') {
     887           0 :                 return -1;
     888             :         }
     889             : 
     890             :         /* Valid TCP/IP port numbers are in [1, 65535] */
     891           0 :         if (ull == 0 || ull > 65535) {
     892           0 :                 return -1;
     893             :         }
     894             : 
     895           0 :         return (int)ull;
     896           0 : }
     897             : 
     898             : /**
     899             :  * Canonicalize a listen address trid.
     900             :  */
     901             : static int
     902           0 : nvmf_tcp_canon_listen_trid(struct spdk_nvme_transport_id *canon_trid,
     903             :                            const struct spdk_nvme_transport_id *trid)
     904             : {
     905             :         int trsvcid_int;
     906             : 
     907           0 :         trsvcid_int = nvmf_tcp_trsvcid_to_int(trid->trsvcid);
     908           0 :         if (trsvcid_int < 0) {
     909           0 :                 return -EINVAL;
     910             :         }
     911             : 
     912           0 :         memset(canon_trid, 0, sizeof(*canon_trid));
     913           0 :         spdk_nvme_trid_populate_transport(canon_trid, SPDK_NVME_TRANSPORT_TCP);
     914           0 :         canon_trid->adrfam = trid->adrfam;
     915           0 :         snprintf(canon_trid->traddr, sizeof(canon_trid->traddr), "%s", trid->traddr);
     916           0 :         snprintf(canon_trid->trsvcid, sizeof(canon_trid->trsvcid), "%d", trsvcid_int);
     917             : 
     918           0 :         return 0;
     919           0 : }
     920             : 
     921             : /**
     922             :  * Find an existing listening port.
     923             :  */
     924             : static struct spdk_nvmf_tcp_port *
     925           0 : nvmf_tcp_find_port(struct spdk_nvmf_tcp_transport *ttransport,
     926             :                    const struct spdk_nvme_transport_id *trid)
     927             : {
     928             :         struct spdk_nvme_transport_id canon_trid;
     929             :         struct spdk_nvmf_tcp_port *port;
     930             : 
     931           0 :         if (nvmf_tcp_canon_listen_trid(&canon_trid, trid) != 0) {
     932           0 :                 return NULL;
     933             :         }
     934             : 
     935           0 :         TAILQ_FOREACH(port, &ttransport->ports, link) {
     936           0 :                 if (spdk_nvme_transport_id_compare(&canon_trid, port->trid) == 0) {
     937           0 :                         return port;
     938             :                 }
     939           0 :         }
     940             : 
     941           0 :         return NULL;
     942           0 : }
     943             : 
     944             : static int
     945           0 : tcp_sock_get_key(uint8_t *out, int out_len, const char **cipher, const char *pskid,
     946             :                  void *get_key_ctx)
     947             : {
     948             :         struct tcp_psk_entry *entry;
     949           0 :         struct spdk_nvmf_tcp_transport *ttransport = get_key_ctx;
     950             :         size_t psk_len;
     951             :         int rc;
     952             : 
     953           0 :         TAILQ_FOREACH(entry, &ttransport->psks, link) {
     954           0 :                 if (strcmp(pskid, entry->pskid) != 0) {
     955           0 :                         continue;
     956             :                 }
     957             : 
     958           0 :                 psk_len = entry->psk_size;
     959           0 :                 if ((size_t)out_len < psk_len) {
     960           0 :                         SPDK_ERRLOG("Out buffer of size: %" PRIu32 " cannot fit PSK of len: %lu\n",
     961             :                                     out_len, psk_len);
     962           0 :                         return -ENOBUFS;
     963             :                 }
     964             : 
     965             :                 /* Convert PSK to the TLS PSK format. */
     966           0 :                 rc = nvme_tcp_derive_tls_psk(entry->psk, psk_len, pskid, out, out_len,
     967           0 :                                              entry->tls_cipher_suite);
     968           0 :                 if (rc < 0) {
     969           0 :                         SPDK_ERRLOG("Could not generate TLS PSK\n");
     970           0 :                 }
     971             : 
     972           0 :                 switch (entry->tls_cipher_suite) {
     973             :                 case NVME_TCP_CIPHER_AES_128_GCM_SHA256:
     974           0 :                         *cipher = "TLS_AES_128_GCM_SHA256";
     975           0 :                         break;
     976             :                 case NVME_TCP_CIPHER_AES_256_GCM_SHA384:
     977           0 :                         *cipher = "TLS_AES_256_GCM_SHA384";
     978           0 :                         break;
     979             :                 default:
     980           0 :                         *cipher = NULL;
     981           0 :                         return -ENOTSUP;
     982             :                 }
     983             : 
     984           0 :                 return rc;
     985             :         }
     986             : 
     987           0 :         SPDK_ERRLOG("Could not find PSK for identity: %s\n", pskid);
     988             : 
     989           0 :         return -EINVAL;
     990           0 : }
     991             : 
     992             : static int
     993           0 : nvmf_tcp_listen(struct spdk_nvmf_transport *transport, const struct spdk_nvme_transport_id *trid,
     994             :                 struct spdk_nvmf_listen_opts *listen_opts)
     995             : {
     996             :         struct spdk_nvmf_tcp_transport *ttransport;
     997             :         struct spdk_nvmf_tcp_port *port;
     998             :         int trsvcid_int;
     999             :         uint8_t adrfam;
    1000             :         const char *sock_impl_name;
    1001             :         struct spdk_sock_impl_opts impl_opts;
    1002           0 :         size_t impl_opts_size = sizeof(impl_opts);
    1003             :         struct spdk_sock_opts opts;
    1004             :         int rc;
    1005             : 
    1006           0 :         if (!strlen(trid->trsvcid)) {
    1007           0 :                 SPDK_ERRLOG("Service id is required\n");
    1008           0 :                 return -EINVAL;
    1009             :         }
    1010             : 
    1011           0 :         ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
    1012             : 
    1013           0 :         trsvcid_int = nvmf_tcp_trsvcid_to_int(trid->trsvcid);
    1014           0 :         if (trsvcid_int < 0) {
    1015           0 :                 SPDK_ERRLOG("Invalid trsvcid '%s'\n", trid->trsvcid);
    1016           0 :                 return -EINVAL;
    1017             :         }
    1018             : 
    1019           0 :         port = calloc(1, sizeof(*port));
    1020           0 :         if (!port) {
    1021           0 :                 SPDK_ERRLOG("Port allocation failed\n");
    1022           0 :                 return -ENOMEM;
    1023             :         }
    1024             : 
    1025           0 :         port->trid = trid;
    1026             : 
    1027           0 :         sock_impl_name = NULL;
    1028             : 
    1029           0 :         opts.opts_size = sizeof(opts);
    1030           0 :         spdk_sock_get_default_opts(&opts);
    1031           0 :         opts.priority = ttransport->tcp_opts.sock_priority;
    1032           0 :         opts.ack_timeout = transport->opts.ack_timeout;
    1033           0 :         if (listen_opts->secure_channel) {
    1034           0 :                 if (listen_opts->sock_impl &&
    1035           0 :                     strncmp("ssl", listen_opts->sock_impl, strlen(listen_opts->sock_impl))) {
    1036           0 :                         SPDK_ERRLOG("Enabling secure_channel while specifying a sock_impl different from 'ssl' is unsupported");
    1037           0 :                         free(port);
    1038           0 :                         return -EINVAL;
    1039             :                 }
    1040           0 :                 listen_opts->sock_impl = "ssl";
    1041           0 :         }
    1042             : 
    1043           0 :         if (listen_opts->sock_impl) {
    1044           0 :                 sock_impl_name = listen_opts->sock_impl;
    1045           0 :                 spdk_sock_impl_get_opts(sock_impl_name, &impl_opts, &impl_opts_size);
    1046             : 
    1047           0 :                 if (!strncmp("ssl", sock_impl_name, strlen(sock_impl_name))) {
    1048           0 :                         if (!g_tls_log) {
    1049           0 :                                 SPDK_NOTICELOG("TLS support is considered experimental\n");
    1050           0 :                                 g_tls_log = true;
    1051           0 :                         }
    1052           0 :                         impl_opts.tls_version = SPDK_TLS_VERSION_1_3;
    1053           0 :                         impl_opts.get_key = tcp_sock_get_key;
    1054           0 :                         impl_opts.get_key_ctx = ttransport;
    1055           0 :                         impl_opts.tls_cipher_suites = "TLS_AES_256_GCM_SHA384:TLS_AES_128_GCM_SHA256";
    1056           0 :                 }
    1057             : 
    1058           0 :                 opts.impl_opts = &impl_opts;
    1059           0 :                 opts.impl_opts_size = sizeof(impl_opts);
    1060           0 :         }
    1061             : 
    1062           0 :         port->listen_sock = spdk_sock_listen_ext(trid->traddr, trsvcid_int,
    1063           0 :                             sock_impl_name, &opts);
    1064           0 :         if (port->listen_sock == NULL) {
    1065           0 :                 SPDK_ERRLOG("spdk_sock_listen(%s, %d) failed: %s (%d)\n",
    1066             :                             trid->traddr, trsvcid_int,
    1067             :                             spdk_strerror(errno), errno);
    1068           0 :                 free(port);
    1069           0 :                 return -errno;
    1070             :         }
    1071             : 
    1072           0 :         if (spdk_sock_is_ipv4(port->listen_sock)) {
    1073           0 :                 adrfam = SPDK_NVMF_ADRFAM_IPV4;
    1074           0 :         } else if (spdk_sock_is_ipv6(port->listen_sock)) {
    1075           0 :                 adrfam = SPDK_NVMF_ADRFAM_IPV6;
    1076           0 :         } else {
    1077           0 :                 SPDK_ERRLOG("Unhandled socket type\n");
    1078           0 :                 adrfam = 0;
    1079             :         }
    1080             : 
    1081           0 :         if (adrfam != trid->adrfam) {
    1082           0 :                 SPDK_ERRLOG("Socket address family mismatch\n");
    1083           0 :                 spdk_sock_close(&port->listen_sock);
    1084           0 :                 free(port);
    1085           0 :                 return -EINVAL;
    1086             :         }
    1087             : 
    1088           0 :         rc = spdk_sock_group_add_sock(ttransport->listen_sock_group, port->listen_sock, nvmf_tcp_accept_cb,
    1089           0 :                                       port);
    1090           0 :         if (rc < 0) {
    1091           0 :                 SPDK_ERRLOG("Failed to add socket to the listen socket group\n");
    1092           0 :                 spdk_sock_close(&port->listen_sock);
    1093           0 :                 free(port);
    1094           0 :                 return -errno;
    1095             :         }
    1096             : 
    1097           0 :         port->transport = transport;
    1098             : 
    1099           0 :         SPDK_NOTICELOG("*** NVMe/TCP Target Listening on %s port %s ***\n",
    1100             :                        trid->traddr, trid->trsvcid);
    1101             : 
    1102           0 :         TAILQ_INSERT_TAIL(&ttransport->ports, port, link);
    1103           0 :         return 0;
    1104           0 : }
    1105             : 
    1106             : static void
    1107           0 : nvmf_tcp_stop_listen(struct spdk_nvmf_transport *transport,
    1108             :                      const struct spdk_nvme_transport_id *trid)
    1109             : {
    1110             :         struct spdk_nvmf_tcp_transport *ttransport;
    1111             :         struct spdk_nvmf_tcp_port *port;
    1112             : 
    1113           0 :         ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
    1114             : 
    1115           0 :         SPDK_DEBUGLOG(nvmf_tcp, "Removing listen address %s port %s\n",
    1116             :                       trid->traddr, trid->trsvcid);
    1117             : 
    1118           0 :         port = nvmf_tcp_find_port(ttransport, trid);
    1119           0 :         if (port) {
    1120           0 :                 spdk_sock_group_remove_sock(ttransport->listen_sock_group, port->listen_sock);
    1121           0 :                 TAILQ_REMOVE(&ttransport->ports, port, link);
    1122           0 :                 spdk_sock_close(&port->listen_sock);
    1123           0 :                 free(port);
    1124           0 :         }
    1125           0 : }
    1126             : 
    1127             : static void nvmf_tcp_qpair_set_recv_state(struct spdk_nvmf_tcp_qpair *tqpair,
    1128             :                 enum nvme_tcp_pdu_recv_state state);
    1129             : 
    1130             : static void
    1131           1 : nvmf_tcp_qpair_set_state(struct spdk_nvmf_tcp_qpair *tqpair, enum nvmf_tcp_qpair_state state)
    1132             : {
    1133           1 :         tqpair->state = state;
    1134           1 :         spdk_trace_record(TRACE_TCP_QP_STATE_CHANGE, tqpair->qpair.trace_id, 0, 0,
    1135             :                           (uint64_t)tqpair->state);
    1136           1 : }
    1137             : 
    1138             : static void
    1139           0 : nvmf_tcp_qpair_disconnect(struct spdk_nvmf_tcp_qpair *tqpair)
    1140             : {
    1141           0 :         SPDK_DEBUGLOG(nvmf_tcp, "Disconnecting qpair %p\n", tqpair);
    1142             : 
    1143           0 :         spdk_trace_record(TRACE_TCP_QP_DISCONNECT, tqpair->qpair.trace_id, 0, 0);
    1144             : 
    1145           0 :         if (tqpair->state <= NVMF_TCP_QPAIR_STATE_RUNNING) {
    1146           0 :                 nvmf_tcp_qpair_set_state(tqpair, NVMF_TCP_QPAIR_STATE_EXITING);
    1147           0 :                 assert(tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_ERROR);
    1148           0 :                 spdk_poller_unregister(&tqpair->timeout_poller);
    1149             : 
    1150             :                 /* This will end up calling nvmf_tcp_close_qpair */
    1151           0 :                 spdk_nvmf_qpair_disconnect(&tqpair->qpair);
    1152           0 :         }
    1153           0 : }
    1154             : 
    1155             : static void
    1156          16 : _mgmt_pdu_write_done(void *_tqpair, int err)
    1157             : {
    1158          16 :         struct spdk_nvmf_tcp_qpair *tqpair = _tqpair;
    1159          16 :         struct nvme_tcp_pdu *pdu = tqpair->mgmt_pdu;
    1160             : 
    1161          16 :         if (spdk_unlikely(err != 0)) {
    1162          16 :                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_QUIESCING);
    1163          16 :                 return;
    1164             :         }
    1165             : 
    1166           0 :         assert(pdu->cb_fn != NULL);
    1167           0 :         pdu->cb_fn(pdu->cb_arg);
    1168          16 : }
    1169             : 
    1170             : static void
    1171           0 : _req_pdu_write_done(void *req, int err)
    1172             : {
    1173           0 :         struct spdk_nvmf_tcp_req *tcp_req = req;
    1174           0 :         struct nvme_tcp_pdu *pdu = tcp_req->pdu;
    1175           0 :         struct spdk_nvmf_tcp_qpair *tqpair = pdu->qpair;
    1176             : 
    1177           0 :         assert(tcp_req->pdu_in_use);
    1178           0 :         tcp_req->pdu_in_use = false;
    1179             : 
    1180             :         /* If the request is in a completed state, we're waiting for write completion to free it */
    1181           0 :         if (spdk_unlikely(tcp_req->state == TCP_REQUEST_STATE_COMPLETED)) {
    1182           0 :                 nvmf_tcp_request_free(tcp_req);
    1183           0 :                 return;
    1184             :         }
    1185             : 
    1186           0 :         if (spdk_unlikely(err != 0)) {
    1187           0 :                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_QUIESCING);
    1188           0 :                 return;
    1189             :         }
    1190             : 
    1191           0 :         assert(pdu->cb_fn != NULL);
    1192           0 :         pdu->cb_fn(pdu->cb_arg);
    1193           0 : }
    1194             : 
    1195             : static void
    1196          16 : _pdu_write_done(struct nvme_tcp_pdu *pdu, int err)
    1197             : {
    1198          16 :         pdu->sock_req.cb_fn(pdu->sock_req.cb_arg, err);
    1199          16 : }
    1200             : 
    1201             : static void
    1202           0 : tcp_sock_flush_cb(void *arg)
    1203             : {
    1204           0 :         struct spdk_nvmf_tcp_qpair *tqpair = arg;
    1205           0 :         int rc = spdk_sock_flush(tqpair->sock);
    1206             : 
    1207           0 :         if (rc < 0 && errno == EAGAIN) {
    1208           0 :                 spdk_thread_send_msg(spdk_get_thread(), tcp_sock_flush_cb, tqpair);
    1209           0 :                 return;
    1210             :         }
    1211             : 
    1212           0 :         tqpair->pending_flush = false;
    1213           0 :         if (rc < 0) {
    1214           0 :                 SPDK_ERRLOG("Could not write to socket: rc=%d, errno=%d\n", rc, errno);
    1215           0 :         }
    1216           0 : }
    1217             : 
    1218             : static void
    1219          23 : _tcp_write_pdu(struct nvme_tcp_pdu *pdu)
    1220             : {
    1221             :         int rc;
    1222             :         uint32_t mapped_length;
    1223          23 :         struct spdk_nvmf_tcp_qpair *tqpair = pdu->qpair;
    1224             : 
    1225          46 :         pdu->sock_req.iovcnt = nvme_tcp_build_iovs(pdu->iov, SPDK_COUNTOF(pdu->iov), pdu,
    1226          23 :                                tqpair->host_hdgst_enable, tqpair->host_ddgst_enable, &mapped_length);
    1227          23 :         spdk_sock_writev_async(tqpair->sock, &pdu->sock_req);
    1228             : 
    1229          23 :         if (pdu->hdr.common.pdu_type == SPDK_NVME_TCP_PDU_TYPE_IC_RESP ||
    1230          22 :             pdu->hdr.common.pdu_type == SPDK_NVME_TCP_PDU_TYPE_C2H_TERM_REQ) {
    1231             :                 /* Try to force the send immediately. */
    1232          16 :                 rc = spdk_sock_flush(tqpair->sock);
    1233          16 :                 if (rc > 0 && (uint32_t)rc == mapped_length) {
    1234           0 :                         _pdu_write_done(pdu, 0);
    1235           0 :                 } else {
    1236          16 :                         SPDK_ERRLOG("Could not write %s to socket: rc=%d, errno=%d\n",
    1237             :                                     pdu->hdr.common.pdu_type == SPDK_NVME_TCP_PDU_TYPE_IC_RESP ?
    1238             :                                     "IC_RESP" : "TERM_REQ", rc, errno);
    1239          16 :                         _pdu_write_done(pdu, rc >= 0 ? -EAGAIN : -errno);
    1240             :                 }
    1241          23 :         } else if (spdk_interrupt_mode_is_enabled()) {
    1242             :                 /* Async writes must be flushed */
    1243           0 :                 if (!tqpair->pending_flush) {
    1244           0 :                         tqpair->pending_flush = true;
    1245           0 :                         spdk_thread_send_msg(spdk_get_thread(), tcp_sock_flush_cb, tqpair);
    1246           0 :                 }
    1247           0 :         }
    1248          23 : }
    1249             : 
    1250             : static void
    1251           0 : data_crc32_accel_done(void *cb_arg, int status)
    1252             : {
    1253           0 :         struct nvme_tcp_pdu *pdu = cb_arg;
    1254             : 
    1255           0 :         if (spdk_unlikely(status)) {
    1256           0 :                 SPDK_ERRLOG("Failed to compute the data digest for pdu =%p\n", pdu);
    1257           0 :                 _pdu_write_done(pdu, status);
    1258           0 :                 return;
    1259             :         }
    1260             : 
    1261           0 :         pdu->data_digest_crc32 ^= SPDK_CRC32C_XOR;
    1262           0 :         MAKE_DIGEST_WORD(pdu->data_digest, pdu->data_digest_crc32);
    1263             : 
    1264           0 :         _tcp_write_pdu(pdu);
    1265           0 : }
    1266             : 
    1267             : static void
    1268          23 : pdu_data_crc32_compute(struct nvme_tcp_pdu *pdu)
    1269             : {
    1270          23 :         struct spdk_nvmf_tcp_qpair *tqpair = pdu->qpair;
    1271          23 :         int rc = 0;
    1272             : 
    1273             :         /* Data Digest */
    1274          23 :         if (pdu->data_len > 0 && g_nvme_tcp_ddgst[pdu->hdr.common.pdu_type] && tqpair->host_ddgst_enable) {
    1275             :                 /* Only support this limitated case for the first step */
    1276           0 :                 if (spdk_likely(!pdu->dif_ctx && (pdu->data_len % SPDK_NVME_TCP_DIGEST_ALIGNMENT == 0)
    1277             :                                 && tqpair->group)) {
    1278           0 :                         rc = spdk_accel_submit_crc32cv(tqpair->group->accel_channel, &pdu->data_digest_crc32, pdu->data_iov,
    1279           0 :                                                        pdu->data_iovcnt, 0, data_crc32_accel_done, pdu);
    1280           0 :                         if (spdk_likely(rc == 0)) {
    1281           0 :                                 return;
    1282             :                         }
    1283           0 :                 } else {
    1284           0 :                         pdu->data_digest_crc32 = nvme_tcp_pdu_calc_data_digest(pdu);
    1285             :                 }
    1286           0 :                 data_crc32_accel_done(pdu, rc);
    1287           0 :         } else {
    1288          23 :                 _tcp_write_pdu(pdu);
    1289             :         }
    1290          23 : }
    1291             : 
    1292             : static void
    1293          23 : nvmf_tcp_qpair_write_pdu(struct spdk_nvmf_tcp_qpair *tqpair,
    1294             :                          struct nvme_tcp_pdu *pdu,
    1295             :                          nvme_tcp_qpair_xfer_complete_cb cb_fn,
    1296             :                          void *cb_arg)
    1297             : {
    1298             :         int hlen;
    1299             :         uint32_t crc32c;
    1300             : 
    1301          23 :         assert(tqpair->pdu_in_progress != pdu);
    1302             : 
    1303          23 :         hlen = pdu->hdr.common.hlen;
    1304          23 :         pdu->cb_fn = cb_fn;
    1305          23 :         pdu->cb_arg = cb_arg;
    1306             : 
    1307          23 :         pdu->iov[0].iov_base = &pdu->hdr.raw;
    1308          23 :         pdu->iov[0].iov_len = hlen;
    1309             : 
    1310             :         /* Header Digest */
    1311          23 :         if (g_nvme_tcp_hdgst[pdu->hdr.common.pdu_type] && tqpair->host_hdgst_enable) {
    1312           1 :                 crc32c = nvme_tcp_pdu_calc_header_digest(pdu);
    1313           1 :                 MAKE_DIGEST_WORD((uint8_t *)pdu->hdr.raw + hlen, crc32c);
    1314           1 :         }
    1315             : 
    1316             :         /* Data Digest */
    1317          23 :         pdu_data_crc32_compute(pdu);
    1318          23 : }
    1319             : 
    1320             : static void
    1321          16 : nvmf_tcp_qpair_write_mgmt_pdu(struct spdk_nvmf_tcp_qpair *tqpair,
    1322             :                               nvme_tcp_qpair_xfer_complete_cb cb_fn,
    1323             :                               void *cb_arg)
    1324             : {
    1325          16 :         struct nvme_tcp_pdu *pdu = tqpair->mgmt_pdu;
    1326             : 
    1327          16 :         pdu->sock_req.cb_fn = _mgmt_pdu_write_done;
    1328          16 :         pdu->sock_req.cb_arg = tqpair;
    1329             : 
    1330          16 :         nvmf_tcp_qpair_write_pdu(tqpair, pdu, cb_fn, cb_arg);
    1331          16 : }
    1332             : 
    1333             : static void
    1334           7 : nvmf_tcp_qpair_write_req_pdu(struct spdk_nvmf_tcp_qpair *tqpair,
    1335             :                              struct spdk_nvmf_tcp_req *tcp_req,
    1336             :                              nvme_tcp_qpair_xfer_complete_cb cb_fn,
    1337             :                              void *cb_arg)
    1338             : {
    1339           7 :         struct nvme_tcp_pdu *pdu = tcp_req->pdu;
    1340             : 
    1341           7 :         pdu->sock_req.cb_fn = _req_pdu_write_done;
    1342           7 :         pdu->sock_req.cb_arg = tcp_req;
    1343             : 
    1344           7 :         assert(!tcp_req->pdu_in_use);
    1345           7 :         tcp_req->pdu_in_use = true;
    1346             : 
    1347           7 :         nvmf_tcp_qpair_write_pdu(tqpair, pdu, cb_fn, cb_arg);
    1348           7 : }
    1349             : 
    1350             : static int
    1351           1 : nvmf_tcp_qpair_init_mem_resource(struct spdk_nvmf_tcp_qpair *tqpair)
    1352             : {
    1353             :         uint32_t i;
    1354             :         struct spdk_nvmf_transport_opts *opts;
    1355             :         uint32_t in_capsule_data_size;
    1356             : 
    1357           1 :         opts = &tqpair->qpair.transport->opts;
    1358             : 
    1359           1 :         in_capsule_data_size = opts->in_capsule_data_size;
    1360           1 :         if (opts->dif_insert_or_strip) {
    1361           0 :                 in_capsule_data_size = SPDK_BDEV_BUF_SIZE_WITH_MD(in_capsule_data_size);
    1362           0 :         }
    1363             : 
    1364           1 :         tqpair->resource_count = opts->max_queue_depth;
    1365             : 
    1366           1 :         tqpair->reqs = calloc(tqpair->resource_count, sizeof(*tqpair->reqs));
    1367           1 :         if (!tqpair->reqs) {
    1368           0 :                 SPDK_ERRLOG("Unable to allocate reqs on tqpair=%p\n", tqpair);
    1369           0 :                 return -1;
    1370             :         }
    1371             : 
    1372           1 :         if (in_capsule_data_size) {
    1373           1 :                 tqpair->bufs = spdk_zmalloc(tqpair->resource_count * in_capsule_data_size, 0x1000,
    1374             :                                             NULL, SPDK_ENV_LCORE_ID_ANY,
    1375             :                                             SPDK_MALLOC_DMA);
    1376           1 :                 if (!tqpair->bufs) {
    1377           0 :                         SPDK_ERRLOG("Unable to allocate bufs on tqpair=%p.\n", tqpair);
    1378           0 :                         return -1;
    1379             :                 }
    1380           1 :         }
    1381             :         /* prepare memory space for receiving pdus and tcp_req */
    1382             :         /* Add additional 1 member, which will be used for mgmt_pdu owned by the tqpair */
    1383           1 :         tqpair->pdus = spdk_dma_zmalloc((2 * tqpair->resource_count + 1) * sizeof(*tqpair->pdus), 0x1000,
    1384             :                                         NULL);
    1385           1 :         if (!tqpair->pdus) {
    1386           0 :                 SPDK_ERRLOG("Unable to allocate pdu pool on tqpair =%p.\n", tqpair);
    1387           0 :                 return -1;
    1388             :         }
    1389             : 
    1390         129 :         for (i = 0; i < tqpair->resource_count; i++) {
    1391         128 :                 struct spdk_nvmf_tcp_req *tcp_req = &tqpair->reqs[i];
    1392             : 
    1393         128 :                 tcp_req->ttag = i + 1;
    1394         128 :                 tcp_req->req.qpair = &tqpair->qpair;
    1395             : 
    1396         128 :                 tcp_req->pdu = &tqpair->pdus[i];
    1397         128 :                 tcp_req->pdu->qpair = tqpair;
    1398             : 
    1399             :                 /* Set up memory to receive commands */
    1400         128 :                 if (tqpair->bufs) {
    1401         128 :                         tcp_req->buf = (void *)((uintptr_t)tqpair->bufs + (i * in_capsule_data_size));
    1402         128 :                 }
    1403             : 
    1404             :                 /* Set the cmdn and rsp */
    1405         128 :                 tcp_req->req.rsp = (union nvmf_c2h_msg *)&tcp_req->rsp;
    1406         128 :                 tcp_req->req.cmd = (union nvmf_h2c_msg *)&tcp_req->cmd;
    1407             : 
    1408         128 :                 tcp_req->req.stripped_data = NULL;
    1409             : 
    1410             :                 /* Initialize request state to FREE */
    1411         128 :                 tcp_req->state = TCP_REQUEST_STATE_FREE;
    1412         128 :                 TAILQ_INSERT_TAIL(&tqpair->tcp_req_free_queue, tcp_req, state_link);
    1413         128 :                 tqpair->state_cntr[TCP_REQUEST_STATE_FREE]++;
    1414         128 :         }
    1415             : 
    1416         129 :         for (; i < 2 * tqpair->resource_count; i++) {
    1417         128 :                 struct nvme_tcp_pdu *pdu = &tqpair->pdus[i];
    1418             : 
    1419         128 :                 pdu->qpair = tqpair;
    1420         128 :                 SLIST_INSERT_HEAD(&tqpair->tcp_pdu_free_queue, pdu, slist);
    1421         128 :         }
    1422             : 
    1423           1 :         tqpair->mgmt_pdu = &tqpair->pdus[i];
    1424           1 :         tqpair->mgmt_pdu->qpair = tqpair;
    1425           1 :         tqpair->pdu_in_progress = SLIST_FIRST(&tqpair->tcp_pdu_free_queue);
    1426           1 :         SLIST_REMOVE_HEAD(&tqpair->tcp_pdu_free_queue, slist);
    1427           1 :         tqpair->tcp_pdu_working_count = 1;
    1428             : 
    1429           2 :         tqpair->recv_buf_size = (in_capsule_data_size + sizeof(struct spdk_nvme_tcp_cmd) + 2 *
    1430           1 :                                  SPDK_NVME_TCP_DIGEST_LEN) * SPDK_NVMF_TCP_RECV_BUF_SIZE_FACTOR;
    1431             : 
    1432           1 :         return 0;
    1433           1 : }
    1434             : 
    1435             : static int
    1436           1 : nvmf_tcp_qpair_init(struct spdk_nvmf_qpair *qpair)
    1437             : {
    1438             :         struct spdk_nvmf_tcp_qpair *tqpair;
    1439             : 
    1440           1 :         tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
    1441             : 
    1442           1 :         SPDK_DEBUGLOG(nvmf_tcp, "New TCP Connection: %p\n", qpair);
    1443             : 
    1444           1 :         spdk_trace_record(TRACE_TCP_QP_CREATE, tqpair->qpair.trace_id, 0, 0);
    1445             : 
    1446             :         /* Initialise request state queues of the qpair */
    1447           1 :         TAILQ_INIT(&tqpair->tcp_req_free_queue);
    1448           1 :         TAILQ_INIT(&tqpair->tcp_req_working_queue);
    1449           1 :         SLIST_INIT(&tqpair->tcp_pdu_free_queue);
    1450           1 :         tqpair->qpair.queue_depth = 0;
    1451             : 
    1452           1 :         tqpair->host_hdgst_enable = true;
    1453           1 :         tqpair->host_ddgst_enable = true;
    1454             : 
    1455           1 :         return 0;
    1456             : }
    1457             : 
    1458             : static int
    1459           0 : nvmf_tcp_qpair_sock_init(struct spdk_nvmf_tcp_qpair *tqpair)
    1460             : {
    1461             :         char saddr[32], caddr[32];
    1462             :         uint16_t sport, cport;
    1463             :         char owner[256];
    1464             :         int rc;
    1465             : 
    1466           0 :         rc = spdk_sock_getaddr(tqpair->sock, saddr, sizeof(saddr), &sport,
    1467           0 :                                caddr, sizeof(caddr), &cport);
    1468           0 :         if (rc != 0) {
    1469           0 :                 SPDK_ERRLOG("spdk_sock_getaddr() failed\n");
    1470           0 :                 return rc;
    1471             :         }
    1472           0 :         snprintf(owner, sizeof(owner), "%s:%d", caddr, cport);
    1473           0 :         tqpair->qpair.trace_id = spdk_trace_register_owner(OWNER_TYPE_NVMF_TCP, owner);
    1474           0 :         spdk_trace_record(TRACE_TCP_QP_SOCK_INIT, tqpair->qpair.trace_id, 0, 0);
    1475             : 
    1476             :         /* set low water mark */
    1477           0 :         rc = spdk_sock_set_recvlowat(tqpair->sock, 1);
    1478           0 :         if (rc != 0) {
    1479           0 :                 SPDK_ERRLOG("spdk_sock_set_recvlowat() failed\n");
    1480           0 :                 return rc;
    1481             :         }
    1482             : 
    1483           0 :         return 0;
    1484           0 : }
    1485             : 
    1486             : static void
    1487           0 : nvmf_tcp_handle_connect(struct spdk_nvmf_tcp_port *port, struct spdk_sock *sock)
    1488             : {
    1489             :         struct spdk_nvmf_tcp_qpair *tqpair;
    1490             :         int rc;
    1491             : 
    1492           0 :         SPDK_DEBUGLOG(nvmf_tcp, "New connection accepted on %s port %s\n",
    1493             :                       port->trid->traddr, port->trid->trsvcid);
    1494             : 
    1495           0 :         tqpair = calloc(1, sizeof(struct spdk_nvmf_tcp_qpair));
    1496           0 :         if (tqpair == NULL) {
    1497           0 :                 SPDK_ERRLOG("Could not allocate new connection.\n");
    1498           0 :                 spdk_sock_close(&sock);
    1499           0 :                 return;
    1500             :         }
    1501             : 
    1502           0 :         tqpair->sock = sock;
    1503           0 :         tqpair->state_cntr[TCP_REQUEST_STATE_FREE] = 0;
    1504           0 :         tqpair->port = port;
    1505           0 :         tqpair->qpair.transport = port->transport;
    1506           0 :         tqpair->qpair.numa.id_valid = 1;
    1507           0 :         tqpair->qpair.numa.id = spdk_sock_get_numa_id(sock);
    1508             : 
    1509           0 :         rc = spdk_sock_getaddr(tqpair->sock, tqpair->target_addr,
    1510           0 :                                sizeof(tqpair->target_addr), &tqpair->target_port,
    1511           0 :                                tqpair->initiator_addr, sizeof(tqpair->initiator_addr),
    1512           0 :                                &tqpair->initiator_port);
    1513           0 :         if (rc < 0) {
    1514           0 :                 SPDK_ERRLOG("spdk_sock_getaddr() failed of tqpair=%p\n", tqpair);
    1515           0 :                 nvmf_tcp_qpair_destroy(tqpair);
    1516           0 :                 return;
    1517             :         }
    1518             : 
    1519           0 :         spdk_nvmf_tgt_new_qpair(port->transport->tgt, &tqpair->qpair);
    1520           0 : }
    1521             : 
    1522             : static uint32_t
    1523           0 : nvmf_tcp_port_accept(struct spdk_nvmf_tcp_port *port)
    1524             : {
    1525             :         struct spdk_sock *sock;
    1526           0 :         uint32_t count = 0;
    1527             :         int i;
    1528             : 
    1529           0 :         for (i = 0; i < NVMF_TCP_MAX_ACCEPT_SOCK_ONE_TIME; i++) {
    1530           0 :                 sock = spdk_sock_accept(port->listen_sock);
    1531           0 :                 if (sock == NULL) {
    1532           0 :                         break;
    1533             :                 }
    1534           0 :                 count++;
    1535           0 :                 nvmf_tcp_handle_connect(port, sock);
    1536           0 :         }
    1537             : 
    1538           0 :         return count;
    1539             : }
    1540             : 
    1541             : static int
    1542           0 : nvmf_tcp_accept(void *ctx)
    1543             : {
    1544           0 :         struct spdk_nvmf_transport *transport = ctx;
    1545             :         struct spdk_nvmf_tcp_transport *ttransport;
    1546             :         int count;
    1547             : 
    1548           0 :         ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
    1549             : 
    1550           0 :         count = spdk_sock_group_poll(ttransport->listen_sock_group);
    1551           0 :         if (count < 0) {
    1552           0 :                 SPDK_ERRLOG("Fail in TCP listen socket group poll\n");
    1553           0 :         }
    1554             : 
    1555           0 :         return count != 0 ? SPDK_POLLER_BUSY : SPDK_POLLER_IDLE;
    1556             : }
    1557             : 
    1558             : static void
    1559           0 : nvmf_tcp_accept_cb(void *ctx, struct spdk_sock_group *group, struct spdk_sock *sock)
    1560             : {
    1561           0 :         struct spdk_nvmf_tcp_port *port = ctx;
    1562             : 
    1563           0 :         nvmf_tcp_port_accept(port);
    1564           0 : }
    1565             : 
    1566             : static void
    1567           0 : nvmf_tcp_discover(struct spdk_nvmf_transport *transport,
    1568             :                   struct spdk_nvme_transport_id *trid,
    1569             :                   struct spdk_nvmf_discovery_log_page_entry *entry)
    1570             : {
    1571             :         struct spdk_nvmf_tcp_port *port;
    1572             :         struct spdk_nvmf_tcp_transport *ttransport;
    1573             : 
    1574           0 :         entry->trtype = SPDK_NVMF_TRTYPE_TCP;
    1575           0 :         entry->adrfam = trid->adrfam;
    1576             : 
    1577           0 :         spdk_strcpy_pad(entry->trsvcid, trid->trsvcid, sizeof(entry->trsvcid), ' ');
    1578           0 :         spdk_strcpy_pad(entry->traddr, trid->traddr, sizeof(entry->traddr), ' ');
    1579             : 
    1580           0 :         ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
    1581           0 :         port = nvmf_tcp_find_port(ttransport, trid);
    1582             : 
    1583           0 :         assert(port != NULL);
    1584             : 
    1585           0 :         if (strcmp(spdk_sock_get_impl_name(port->listen_sock), "ssl") == 0) {
    1586           0 :                 entry->treq.secure_channel = SPDK_NVMF_TREQ_SECURE_CHANNEL_REQUIRED;
    1587           0 :                 entry->tsas.tcp.sectype = SPDK_NVME_TCP_SECURITY_TLS_1_3;
    1588           0 :         } else {
    1589           0 :                 entry->treq.secure_channel = SPDK_NVMF_TREQ_SECURE_CHANNEL_NOT_REQUIRED;
    1590           0 :                 entry->tsas.tcp.sectype = SPDK_NVME_TCP_SECURITY_NONE;
    1591             :         }
    1592           0 : }
    1593             : 
    1594             : static struct spdk_nvmf_tcp_control_msg_list *
    1595           1 : nvmf_tcp_control_msg_list_create(uint16_t num_messages)
    1596             : {
    1597             :         struct spdk_nvmf_tcp_control_msg_list *list;
    1598             :         struct spdk_nvmf_tcp_control_msg *msg;
    1599             :         uint16_t i;
    1600             : 
    1601           1 :         list = calloc(1, sizeof(*list));
    1602           1 :         if (!list) {
    1603           0 :                 SPDK_ERRLOG("Failed to allocate memory for list structure\n");
    1604           0 :                 return NULL;
    1605             :         }
    1606             : 
    1607           1 :         list->msg_buf = spdk_zmalloc(num_messages * SPDK_NVME_TCP_IN_CAPSULE_DATA_MAX_SIZE,
    1608             :                                      NVMF_DATA_BUFFER_ALIGNMENT, NULL, SPDK_ENV_NUMA_ID_ANY, SPDK_MALLOC_DMA);
    1609           1 :         if (!list->msg_buf) {
    1610           0 :                 SPDK_ERRLOG("Failed to allocate memory for control message buffers\n");
    1611           0 :                 free(list);
    1612           0 :                 return NULL;
    1613             :         }
    1614             : 
    1615           1 :         STAILQ_INIT(&list->free_msgs);
    1616           1 :         STAILQ_INIT(&list->waiting_for_msg_reqs);
    1617             : 
    1618          33 :         for (i = 0; i < num_messages; i++) {
    1619          32 :                 msg = (struct spdk_nvmf_tcp_control_msg *)((char *)list->msg_buf + i *
    1620             :                                 SPDK_NVME_TCP_IN_CAPSULE_DATA_MAX_SIZE);
    1621          32 :                 STAILQ_INSERT_TAIL(&list->free_msgs, msg, link);
    1622          32 :         }
    1623             : 
    1624           1 :         return list;
    1625           1 : }
    1626             : 
    1627             : static void
    1628           1 : nvmf_tcp_control_msg_list_free(struct spdk_nvmf_tcp_control_msg_list *list)
    1629             : {
    1630           1 :         if (!list) {
    1631           0 :                 return;
    1632             :         }
    1633             : 
    1634           1 :         spdk_free(list->msg_buf);
    1635           1 :         free(list);
    1636           1 : }
    1637             : 
    1638             : static int nvmf_tcp_poll_group_poll(struct spdk_nvmf_transport_poll_group *group);
    1639             : 
    1640             : static int
    1641           0 : nvmf_tcp_poll_group_intr(void *ctx)
    1642             : {
    1643           0 :         struct spdk_nvmf_transport_poll_group *group = ctx;
    1644           0 :         int ret = 0;
    1645             : 
    1646           0 :         ret = nvmf_tcp_poll_group_poll(group);
    1647             : 
    1648           0 :         return ret != 0 ? SPDK_POLLER_BUSY : SPDK_POLLER_IDLE;
    1649             : }
    1650             : 
    1651             : static struct spdk_nvmf_transport_poll_group *
    1652           1 : nvmf_tcp_poll_group_create(struct spdk_nvmf_transport *transport,
    1653             :                            struct spdk_nvmf_poll_group *group)
    1654             : {
    1655             :         struct spdk_nvmf_tcp_transport  *ttransport;
    1656             :         struct spdk_nvmf_tcp_poll_group *tgroup;
    1657             :         int rc;
    1658             : 
    1659           1 :         tgroup = calloc(1, sizeof(*tgroup));
    1660           1 :         if (!tgroup) {
    1661           0 :                 return NULL;
    1662             :         }
    1663             : 
    1664           1 :         tgroup->sock_group = spdk_sock_group_create(&tgroup->group);
    1665           1 :         if (!tgroup->sock_group) {
    1666           0 :                 goto cleanup;
    1667             :         }
    1668             : 
    1669           1 :         TAILQ_INIT(&tgroup->qpairs);
    1670             : 
    1671           1 :         ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
    1672             : 
    1673           1 :         if (transport->opts.in_capsule_data_size < SPDK_NVME_TCP_IN_CAPSULE_DATA_MAX_SIZE) {
    1674           1 :                 SPDK_DEBUGLOG(nvmf_tcp, "ICD %u is less than min required for admin/fabric commands (%u). "
    1675             :                               "Creating control messages list\n", transport->opts.in_capsule_data_size,
    1676             :                               SPDK_NVME_TCP_IN_CAPSULE_DATA_MAX_SIZE);
    1677           1 :                 tgroup->control_msg_list = nvmf_tcp_control_msg_list_create(ttransport->tcp_opts.control_msg_num);
    1678           1 :                 if (!tgroup->control_msg_list) {
    1679           0 :                         goto cleanup;
    1680             :                 }
    1681           1 :         }
    1682             : 
    1683           1 :         tgroup->accel_channel = spdk_accel_get_io_channel();
    1684           1 :         if (spdk_unlikely(!tgroup->accel_channel)) {
    1685           0 :                 SPDK_ERRLOG("Cannot create accel_channel for tgroup=%p\n", tgroup);
    1686           0 :                 goto cleanup;
    1687             :         }
    1688             : 
    1689           1 :         TAILQ_INSERT_TAIL(&ttransport->poll_groups, tgroup, link);
    1690           1 :         if (ttransport->next_pg == NULL) {
    1691           1 :                 ttransport->next_pg = tgroup;
    1692           1 :         }
    1693             : 
    1694           1 :         if (spdk_interrupt_mode_is_enabled()) {
    1695           0 :                 rc = SPDK_SOCK_GROUP_REGISTER_INTERRUPT(tgroup->sock_group,
    1696             :                                                         SPDK_INTERRUPT_EVENT_IN | SPDK_INTERRUPT_EVENT_OUT, nvmf_tcp_poll_group_intr, &tgroup->group);
    1697           0 :                 if (rc != 0) {
    1698           0 :                         SPDK_ERRLOG("Failed to register interrupt for sock group\n");
    1699           0 :                         goto cleanup;
    1700             :                 }
    1701           0 :         }
    1702             : 
    1703           1 :         return &tgroup->group;
    1704             : 
    1705             : cleanup:
    1706           0 :         nvmf_tcp_poll_group_destroy(&tgroup->group);
    1707           0 :         return NULL;
    1708           1 : }
    1709             : 
    1710             : static struct spdk_nvmf_transport_poll_group *
    1711           0 : nvmf_tcp_get_optimal_poll_group(struct spdk_nvmf_qpair *qpair)
    1712             : {
    1713             :         struct spdk_nvmf_tcp_transport *ttransport;
    1714             :         struct spdk_nvmf_tcp_poll_group **pg;
    1715             :         struct spdk_nvmf_tcp_qpair *tqpair;
    1716           0 :         struct spdk_sock_group *group = NULL, *hint = NULL;
    1717             :         int rc;
    1718             : 
    1719           0 :         ttransport = SPDK_CONTAINEROF(qpair->transport, struct spdk_nvmf_tcp_transport, transport);
    1720             : 
    1721           0 :         if (TAILQ_EMPTY(&ttransport->poll_groups)) {
    1722           0 :                 return NULL;
    1723             :         }
    1724             : 
    1725           0 :         pg = &ttransport->next_pg;
    1726           0 :         assert(*pg != NULL);
    1727           0 :         hint = (*pg)->sock_group;
    1728             : 
    1729           0 :         tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
    1730           0 :         rc = spdk_sock_get_optimal_sock_group(tqpair->sock, &group, hint);
    1731           0 :         if (rc != 0) {
    1732           0 :                 return NULL;
    1733           0 :         } else if (group != NULL) {
    1734             :                 /* Optimal poll group was found */
    1735           0 :                 return spdk_sock_group_get_ctx(group);
    1736             :         }
    1737             : 
    1738             :         /* The hint was used for optimal poll group, advance next_pg. */
    1739           0 :         *pg = TAILQ_NEXT(*pg, link);
    1740           0 :         if (*pg == NULL) {
    1741           0 :                 *pg = TAILQ_FIRST(&ttransport->poll_groups);
    1742           0 :         }
    1743             : 
    1744           0 :         return spdk_sock_group_get_ctx(hint);
    1745           0 : }
    1746             : 
    1747             : static void
    1748           1 : nvmf_tcp_poll_group_destroy(struct spdk_nvmf_transport_poll_group *group)
    1749             : {
    1750             :         struct spdk_nvmf_tcp_poll_group *tgroup, *next_tgroup;
    1751             :         struct spdk_nvmf_tcp_transport *ttransport;
    1752             : 
    1753           1 :         tgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_tcp_poll_group, group);
    1754           1 :         spdk_sock_group_unregister_interrupt(tgroup->sock_group);
    1755           1 :         spdk_sock_group_close(&tgroup->sock_group);
    1756           1 :         if (tgroup->control_msg_list) {
    1757           1 :                 nvmf_tcp_control_msg_list_free(tgroup->control_msg_list);
    1758           1 :         }
    1759             : 
    1760           1 :         if (tgroup->accel_channel) {
    1761           1 :                 spdk_put_io_channel(tgroup->accel_channel);
    1762           1 :         }
    1763             : 
    1764           1 :         if (tgroup->group.transport == NULL) {
    1765             :                 /* Transport can be NULL when nvmf_tcp_poll_group_create()
    1766             :                  * calls this function directly in a failure path. */
    1767           0 :                 free(tgroup);
    1768           0 :                 return;
    1769             :         }
    1770             : 
    1771           1 :         ttransport = SPDK_CONTAINEROF(tgroup->group.transport, struct spdk_nvmf_tcp_transport, transport);
    1772             : 
    1773           1 :         next_tgroup = TAILQ_NEXT(tgroup, link);
    1774           1 :         TAILQ_REMOVE(&ttransport->poll_groups, tgroup, link);
    1775           1 :         if (next_tgroup == NULL) {
    1776           1 :                 next_tgroup = TAILQ_FIRST(&ttransport->poll_groups);
    1777           1 :         }
    1778           1 :         if (ttransport->next_pg == tgroup) {
    1779           1 :                 ttransport->next_pg = next_tgroup;
    1780           1 :         }
    1781             : 
    1782           1 :         free(tgroup);
    1783           1 : }
    1784             : 
    1785             : static void
    1786          37 : nvmf_tcp_qpair_set_recv_state(struct spdk_nvmf_tcp_qpair *tqpair,
    1787             :                               enum nvme_tcp_pdu_recv_state state)
    1788             : {
    1789          37 :         if (tqpair->recv_state == state) {
    1790          19 :                 SPDK_ERRLOG("The recv state of tqpair=%p is same with the state(%d) to be set\n",
    1791             :                             tqpair, state);
    1792          19 :                 return;
    1793             :         }
    1794             : 
    1795          18 :         if (spdk_unlikely(state == NVME_TCP_PDU_RECV_STATE_QUIESCING)) {
    1796          13 :                 if (tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_CH && tqpair->pdu_in_progress) {
    1797          10 :                         SLIST_INSERT_HEAD(&tqpair->tcp_pdu_free_queue, tqpair->pdu_in_progress, slist);
    1798          10 :                         tqpair->tcp_pdu_working_count--;
    1799          10 :                 }
    1800          13 :         }
    1801             : 
    1802          18 :         if (spdk_unlikely(state == NVME_TCP_PDU_RECV_STATE_ERROR)) {
    1803           0 :                 assert(tqpair->tcp_pdu_working_count == 0);
    1804           0 :         }
    1805             : 
    1806          18 :         SPDK_DEBUGLOG(nvmf_tcp, "tqpair(%p) recv state=%d\n", tqpair, state);
    1807          18 :         tqpair->recv_state = state;
    1808             : 
    1809          18 :         spdk_trace_record(TRACE_TCP_QP_RCV_STATE_CHANGE, tqpair->qpair.trace_id, 0, 0,
    1810             :                           (uint64_t)tqpair->recv_state);
    1811          37 : }
    1812             : 
    1813             : static int
    1814           0 : nvmf_tcp_qpair_handle_timeout(void *ctx)
    1815             : {
    1816           0 :         struct spdk_nvmf_tcp_qpair *tqpair = ctx;
    1817             : 
    1818           0 :         assert(tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_ERROR);
    1819             : 
    1820           0 :         SPDK_ERRLOG("No pdu coming for tqpair=%p within %d seconds\n", tqpair,
    1821             :                     SPDK_NVME_TCP_QPAIR_EXIT_TIMEOUT);
    1822             : 
    1823           0 :         nvmf_tcp_qpair_disconnect(tqpair);
    1824           0 :         return SPDK_POLLER_BUSY;
    1825             : }
    1826             : 
    1827             : static void
    1828           0 : nvmf_tcp_send_c2h_term_req_complete(void *cb_arg)
    1829             : {
    1830           0 :         struct spdk_nvmf_tcp_qpair *tqpair = (struct spdk_nvmf_tcp_qpair *)cb_arg;
    1831             : 
    1832           0 :         if (!tqpair->timeout_poller) {
    1833           0 :                 tqpair->timeout_poller = SPDK_POLLER_REGISTER(nvmf_tcp_qpair_handle_timeout, tqpair,
    1834             :                                          SPDK_NVME_TCP_QPAIR_EXIT_TIMEOUT * 1000000);
    1835           0 :         }
    1836           0 : }
    1837             : 
    1838             : static void
    1839          15 : nvmf_tcp_send_c2h_term_req(struct spdk_nvmf_tcp_qpair *tqpair, struct nvme_tcp_pdu *pdu,
    1840             :                            enum spdk_nvme_tcp_term_req_fes fes, uint32_t error_offset)
    1841             : {
    1842             :         struct nvme_tcp_pdu *rsp_pdu;
    1843             :         struct spdk_nvme_tcp_term_req_hdr *c2h_term_req;
    1844          15 :         uint32_t c2h_term_req_hdr_len = sizeof(*c2h_term_req);
    1845             :         uint32_t copy_len;
    1846             : 
    1847          15 :         rsp_pdu = tqpair->mgmt_pdu;
    1848             : 
    1849          15 :         c2h_term_req = &rsp_pdu->hdr.term_req;
    1850          15 :         c2h_term_req->common.pdu_type = SPDK_NVME_TCP_PDU_TYPE_C2H_TERM_REQ;
    1851          15 :         c2h_term_req->common.hlen = c2h_term_req_hdr_len;
    1852          15 :         c2h_term_req->fes = fes;
    1853             : 
    1854          15 :         if ((fes == SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD) ||
    1855           3 :             (fes == SPDK_NVME_TCP_TERM_REQ_FES_INVALID_DATA_UNSUPPORTED_PARAMETER)) {
    1856          12 :                 DSET32(&c2h_term_req->fei, error_offset);
    1857          12 :         }
    1858             : 
    1859          15 :         copy_len = spdk_min(pdu->hdr.common.hlen, SPDK_NVME_TCP_TERM_REQ_ERROR_DATA_MAX_SIZE);
    1860             : 
    1861             :         /* Copy the error info into the buffer */
    1862          15 :         memcpy((uint8_t *)rsp_pdu->hdr.raw + c2h_term_req_hdr_len, pdu->hdr.raw, copy_len);
    1863          15 :         nvme_tcp_pdu_set_data(rsp_pdu, (uint8_t *)rsp_pdu->hdr.raw + c2h_term_req_hdr_len, copy_len);
    1864             : 
    1865             :         /* Contain the header of the wrong received pdu */
    1866          15 :         c2h_term_req->common.plen = c2h_term_req->common.hlen + copy_len;
    1867          15 :         tqpair->wait_terminate = true;
    1868          15 :         nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_QUIESCING);
    1869          15 :         nvmf_tcp_qpair_write_mgmt_pdu(tqpair, nvmf_tcp_send_c2h_term_req_complete, tqpair);
    1870          15 : }
    1871             : 
    1872             : static void
    1873           1 : nvmf_tcp_capsule_cmd_hdr_handle(struct spdk_nvmf_tcp_transport *ttransport,
    1874             :                                 struct spdk_nvmf_tcp_qpair *tqpair,
    1875             :                                 struct nvme_tcp_pdu *pdu)
    1876             : {
    1877             :         struct spdk_nvmf_tcp_req *tcp_req;
    1878             : 
    1879           1 :         assert(pdu->psh_valid_bytes == pdu->psh_len);
    1880           1 :         assert(pdu->hdr.common.pdu_type == SPDK_NVME_TCP_PDU_TYPE_CAPSULE_CMD);
    1881             : 
    1882           1 :         tcp_req = nvmf_tcp_req_get(tqpair);
    1883           1 :         if (!tcp_req) {
    1884             :                 /* Directly return and make the allocation retry again.  This can happen if we're
    1885             :                  * using asynchronous writes to send the response to the host or when releasing
    1886             :                  * zero-copy buffers after a response has been sent.  In both cases, the host might
    1887             :                  * receive the response before we've finished processing the request and is free to
    1888             :                  * send another one.
    1889             :                  */
    1890           0 :                 if (tqpair->state_cntr[TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST] > 0 ||
    1891           0 :                     tqpair->state_cntr[TCP_REQUEST_STATE_AWAITING_ZCOPY_RELEASE] > 0) {
    1892           0 :                         return;
    1893             :                 }
    1894             : 
    1895             :                 /* The host sent more commands than the maximum queue depth. */
    1896           0 :                 SPDK_ERRLOG("Cannot allocate tcp_req on tqpair=%p\n", tqpair);
    1897           0 :                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_QUIESCING);
    1898           0 :                 return;
    1899             :         }
    1900             : 
    1901           1 :         pdu->req = tcp_req;
    1902           1 :         assert(tcp_req->state == TCP_REQUEST_STATE_NEW);
    1903           1 :         nvmf_tcp_req_process(ttransport, tcp_req);
    1904           1 : }
    1905             : 
    1906             : static void
    1907           0 : nvmf_tcp_capsule_cmd_payload_handle(struct spdk_nvmf_tcp_transport *ttransport,
    1908             :                                     struct spdk_nvmf_tcp_qpair *tqpair,
    1909             :                                     struct nvme_tcp_pdu *pdu)
    1910             : {
    1911             :         struct spdk_nvmf_tcp_req *tcp_req;
    1912             :         struct spdk_nvme_tcp_cmd *capsule_cmd;
    1913           0 :         uint32_t error_offset = 0;
    1914             :         enum spdk_nvme_tcp_term_req_fes fes;
    1915             :         struct spdk_nvme_cpl *rsp;
    1916             : 
    1917           0 :         capsule_cmd = &pdu->hdr.capsule_cmd;
    1918           0 :         tcp_req = pdu->req;
    1919           0 :         assert(tcp_req != NULL);
    1920             : 
    1921             :         /* Zero-copy requests don't support ICD */
    1922           0 :         assert(!spdk_nvmf_request_using_zcopy(&tcp_req->req));
    1923             : 
    1924           0 :         if (capsule_cmd->common.pdo > SPDK_NVME_TCP_PDU_PDO_MAX_OFFSET) {
    1925           0 :                 SPDK_ERRLOG("Expected ICReq capsule_cmd pdu offset <= %d, got %c\n",
    1926             :                             SPDK_NVME_TCP_PDU_PDO_MAX_OFFSET, capsule_cmd->common.pdo);
    1927           0 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
    1928           0 :                 error_offset = offsetof(struct spdk_nvme_tcp_common_pdu_hdr, pdo);
    1929           0 :                 goto err;
    1930             :         }
    1931             : 
    1932           0 :         rsp = &tcp_req->req.rsp->nvme_cpl;
    1933           0 :         if (spdk_unlikely(rsp->status.sc == SPDK_NVME_SC_COMMAND_TRANSIENT_TRANSPORT_ERROR)) {
    1934           0 :                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_COMPLETE);
    1935           0 :         } else {
    1936           0 :                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_EXECUTE);
    1937             :         }
    1938             : 
    1939           0 :         nvmf_tcp_req_process(ttransport, tcp_req);
    1940             : 
    1941           0 :         return;
    1942             : err:
    1943           0 :         nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
    1944           0 : }
    1945             : 
    1946             : static void
    1947           1 : nvmf_tcp_h2c_data_hdr_handle(struct spdk_nvmf_tcp_transport *ttransport,
    1948             :                              struct spdk_nvmf_tcp_qpair *tqpair,
    1949             :                              struct nvme_tcp_pdu *pdu)
    1950             : {
    1951             :         struct spdk_nvmf_tcp_req *tcp_req;
    1952           1 :         uint32_t error_offset = 0;
    1953           1 :         enum spdk_nvme_tcp_term_req_fes fes = 0;
    1954             :         struct spdk_nvme_tcp_h2c_data_hdr *h2c_data;
    1955             : 
    1956           1 :         h2c_data = &pdu->hdr.h2c_data;
    1957             : 
    1958           1 :         SPDK_DEBUGLOG(nvmf_tcp, "tqpair=%p, r2t_info: datao=%u, datal=%u, cccid=%u, ttag=%u\n",
    1959             :                       tqpair, h2c_data->datao, h2c_data->datal, h2c_data->cccid, h2c_data->ttag);
    1960             : 
    1961           1 :         if (h2c_data->ttag > tqpair->resource_count) {
    1962           0 :                 SPDK_DEBUGLOG(nvmf_tcp, "ttag %u is larger than allowed %u.\n", h2c_data->ttag,
    1963             :                               tqpair->resource_count);
    1964           0 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_PDU_SEQUENCE_ERROR;
    1965           0 :                 error_offset = offsetof(struct spdk_nvme_tcp_h2c_data_hdr, ttag);
    1966           0 :                 goto err;
    1967             :         }
    1968             : 
    1969           1 :         tcp_req = &tqpair->reqs[h2c_data->ttag - 1];
    1970             : 
    1971           1 :         if (spdk_unlikely(tcp_req->state != TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER &&
    1972             :                           tcp_req->state != TCP_REQUEST_STATE_AWAITING_R2T_ACK)) {
    1973           0 :                 SPDK_DEBUGLOG(nvmf_tcp, "tcp_req(%p), tqpair=%p, has error state in %d\n", tcp_req, tqpair,
    1974             :                               tcp_req->state);
    1975           0 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
    1976           0 :                 error_offset = offsetof(struct spdk_nvme_tcp_h2c_data_hdr, ttag);
    1977           0 :                 goto err;
    1978             :         }
    1979             : 
    1980           1 :         if (spdk_unlikely(tcp_req->req.cmd->nvme_cmd.cid != h2c_data->cccid)) {
    1981           0 :                 SPDK_DEBUGLOG(nvmf_tcp, "tcp_req(%p), tqpair=%p, expected %u but %u for cccid.\n", tcp_req, tqpair,
    1982             :                               tcp_req->req.cmd->nvme_cmd.cid, h2c_data->cccid);
    1983           0 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_PDU_SEQUENCE_ERROR;
    1984           0 :                 error_offset = offsetof(struct spdk_nvme_tcp_h2c_data_hdr, cccid);
    1985           0 :                 goto err;
    1986             :         }
    1987             : 
    1988           1 :         if (tcp_req->h2c_offset != h2c_data->datao) {
    1989           0 :                 SPDK_DEBUGLOG(nvmf_tcp,
    1990             :                               "tcp_req(%p), tqpair=%p, expected data offset %u, but data offset is %u\n",
    1991             :                               tcp_req, tqpair, tcp_req->h2c_offset, h2c_data->datao);
    1992           0 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_DATA_TRANSFER_OUT_OF_RANGE;
    1993           0 :                 goto err;
    1994             :         }
    1995             : 
    1996           1 :         if ((h2c_data->datao + h2c_data->datal) > tcp_req->req.length) {
    1997           0 :                 SPDK_DEBUGLOG(nvmf_tcp,
    1998             :                               "tcp_req(%p), tqpair=%p,  (datao=%u + datal=%u) exceeds requested length=%u\n",
    1999             :                               tcp_req, tqpair, h2c_data->datao, h2c_data->datal, tcp_req->req.length);
    2000           0 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_DATA_TRANSFER_OUT_OF_RANGE;
    2001           0 :                 goto err;
    2002             :         }
    2003             : 
    2004           1 :         pdu->req = tcp_req;
    2005             : 
    2006           1 :         if (spdk_unlikely(tcp_req->req.dif_enabled)) {
    2007           0 :                 pdu->dif_ctx = &tcp_req->req.dif.dif_ctx;
    2008           0 :         }
    2009             : 
    2010           2 :         nvme_tcp_pdu_set_data_buf(pdu, tcp_req->req.iov, tcp_req->req.iovcnt,
    2011           1 :                                   h2c_data->datao, h2c_data->datal);
    2012           1 :         nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PAYLOAD);
    2013           1 :         return;
    2014             : 
    2015             : err:
    2016           0 :         nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
    2017           1 : }
    2018             : 
    2019             : static void
    2020           3 : nvmf_tcp_send_capsule_resp_pdu(struct spdk_nvmf_tcp_req *tcp_req,
    2021             :                                struct spdk_nvmf_tcp_qpair *tqpair)
    2022             : {
    2023             :         struct nvme_tcp_pdu *rsp_pdu;
    2024             :         struct spdk_nvme_tcp_rsp *capsule_resp;
    2025             : 
    2026           3 :         SPDK_DEBUGLOG(nvmf_tcp, "enter, tqpair=%p\n", tqpair);
    2027             : 
    2028           3 :         rsp_pdu = nvmf_tcp_req_pdu_init(tcp_req);
    2029           3 :         assert(rsp_pdu != NULL);
    2030             : 
    2031           3 :         capsule_resp = &rsp_pdu->hdr.capsule_resp;
    2032           3 :         capsule_resp->common.pdu_type = SPDK_NVME_TCP_PDU_TYPE_CAPSULE_RESP;
    2033           3 :         capsule_resp->common.plen = capsule_resp->common.hlen = sizeof(*capsule_resp);
    2034           3 :         capsule_resp->rccqe = tcp_req->req.rsp->nvme_cpl;
    2035           3 :         if (tqpair->host_hdgst_enable) {
    2036           1 :                 capsule_resp->common.flags |= SPDK_NVME_TCP_CH_FLAGS_HDGSTF;
    2037           1 :                 capsule_resp->common.plen += SPDK_NVME_TCP_DIGEST_LEN;
    2038           1 :         }
    2039             : 
    2040           3 :         nvmf_tcp_qpair_write_req_pdu(tqpair, tcp_req, nvmf_tcp_request_free, tcp_req);
    2041           3 : }
    2042             : 
    2043             : static void
    2044           0 : nvmf_tcp_pdu_c2h_data_complete(void *cb_arg)
    2045             : {
    2046           0 :         struct spdk_nvmf_tcp_req *tcp_req = cb_arg;
    2047           0 :         struct spdk_nvmf_tcp_qpair *tqpair = SPDK_CONTAINEROF(tcp_req->req.qpair,
    2048             :                                              struct spdk_nvmf_tcp_qpair, qpair);
    2049             : 
    2050           0 :         assert(tqpair != NULL);
    2051             : 
    2052           0 :         if (spdk_unlikely(tcp_req->pdu->rw_offset < tcp_req->req.length)) {
    2053           0 :                 SPDK_DEBUGLOG(nvmf_tcp, "sending another C2H part, offset %u length %u\n", tcp_req->pdu->rw_offset,
    2054             :                               tcp_req->req.length);
    2055           0 :                 _nvmf_tcp_send_c2h_data(tqpair, tcp_req);
    2056           0 :                 return;
    2057             :         }
    2058             : 
    2059           0 :         if (tcp_req->pdu->hdr.c2h_data.common.flags & SPDK_NVME_TCP_C2H_DATA_FLAGS_SUCCESS) {
    2060           0 :                 nvmf_tcp_request_free(tcp_req);
    2061           0 :         } else {
    2062           0 :                 nvmf_tcp_send_capsule_resp_pdu(tcp_req, tqpair);
    2063             :         }
    2064           0 : }
    2065             : 
    2066             : static void
    2067           0 : nvmf_tcp_r2t_complete(void *cb_arg)
    2068             : {
    2069           0 :         struct spdk_nvmf_tcp_req *tcp_req = cb_arg;
    2070             :         struct spdk_nvmf_tcp_transport *ttransport;
    2071             : 
    2072           0 :         ttransport = SPDK_CONTAINEROF(tcp_req->req.qpair->transport,
    2073             :                                       struct spdk_nvmf_tcp_transport, transport);
    2074             : 
    2075           0 :         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER);
    2076             : 
    2077           0 :         if (tcp_req->h2c_offset == tcp_req->req.length) {
    2078           0 :                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_EXECUTE);
    2079           0 :                 nvmf_tcp_req_process(ttransport, tcp_req);
    2080           0 :         }
    2081           0 : }
    2082             : 
    2083             : static void
    2084           0 : nvmf_tcp_send_r2t_pdu(struct spdk_nvmf_tcp_qpair *tqpair,
    2085             :                       struct spdk_nvmf_tcp_req *tcp_req)
    2086             : {
    2087             :         struct nvme_tcp_pdu *rsp_pdu;
    2088             :         struct spdk_nvme_tcp_r2t_hdr *r2t;
    2089             : 
    2090           0 :         rsp_pdu = nvmf_tcp_req_pdu_init(tcp_req);
    2091           0 :         assert(rsp_pdu != NULL);
    2092             : 
    2093           0 :         r2t = &rsp_pdu->hdr.r2t;
    2094           0 :         r2t->common.pdu_type = SPDK_NVME_TCP_PDU_TYPE_R2T;
    2095           0 :         r2t->common.plen = r2t->common.hlen = sizeof(*r2t);
    2096             : 
    2097           0 :         if (tqpair->host_hdgst_enable) {
    2098           0 :                 r2t->common.flags |= SPDK_NVME_TCP_CH_FLAGS_HDGSTF;
    2099           0 :                 r2t->common.plen += SPDK_NVME_TCP_DIGEST_LEN;
    2100           0 :         }
    2101             : 
    2102           0 :         r2t->cccid = tcp_req->req.cmd->nvme_cmd.cid;
    2103           0 :         r2t->ttag = tcp_req->ttag;
    2104           0 :         r2t->r2to = tcp_req->h2c_offset;
    2105           0 :         r2t->r2tl = tcp_req->req.length;
    2106             : 
    2107           0 :         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_AWAITING_R2T_ACK);
    2108             : 
    2109           0 :         SPDK_DEBUGLOG(nvmf_tcp,
    2110             :                       "tcp_req(%p) on tqpair(%p), r2t_info: cccid=%u, ttag=%u, r2to=%u, r2tl=%u\n",
    2111             :                       tcp_req, tqpair, r2t->cccid, r2t->ttag, r2t->r2to, r2t->r2tl);
    2112           0 :         nvmf_tcp_qpair_write_req_pdu(tqpair, tcp_req, nvmf_tcp_r2t_complete, tcp_req);
    2113           0 : }
    2114             : 
    2115             : static void
    2116           0 : nvmf_tcp_h2c_data_payload_handle(struct spdk_nvmf_tcp_transport *ttransport,
    2117             :                                  struct spdk_nvmf_tcp_qpair *tqpair,
    2118             :                                  struct nvme_tcp_pdu *pdu)
    2119             : {
    2120             :         struct spdk_nvmf_tcp_req *tcp_req;
    2121             :         struct spdk_nvme_cpl *rsp;
    2122             : 
    2123           0 :         tcp_req = pdu->req;
    2124           0 :         assert(tcp_req != NULL);
    2125             : 
    2126           0 :         SPDK_DEBUGLOG(nvmf_tcp, "enter\n");
    2127             : 
    2128           0 :         tcp_req->h2c_offset += pdu->data_len;
    2129             : 
    2130             :         /* Wait for all of the data to arrive AND for the initial R2T PDU send to be
    2131             :          * acknowledged before moving on. */
    2132           0 :         if (tcp_req->h2c_offset == tcp_req->req.length &&
    2133           0 :             tcp_req->state == TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER) {
    2134             :                 /* After receiving all the h2c data, we need to check whether there is
    2135             :                  * transient transport error */
    2136           0 :                 rsp = &tcp_req->req.rsp->nvme_cpl;
    2137           0 :                 if (spdk_unlikely(rsp->status.sc == SPDK_NVME_SC_COMMAND_TRANSIENT_TRANSPORT_ERROR)) {
    2138           0 :                         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_COMPLETE);
    2139           0 :                 } else {
    2140           0 :                         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_EXECUTE);
    2141             :                 }
    2142           0 :                 nvmf_tcp_req_process(ttransport, tcp_req);
    2143           0 :         }
    2144           0 : }
    2145             : 
    2146             : static void
    2147           0 : nvmf_tcp_h2c_term_req_dump(struct spdk_nvme_tcp_term_req_hdr *h2c_term_req)
    2148             : {
    2149           0 :         SPDK_ERRLOG("Error info of pdu(%p): %s\n", h2c_term_req,
    2150             :                     spdk_nvmf_tcp_term_req_fes_str[h2c_term_req->fes]);
    2151           0 :         if ((h2c_term_req->fes == SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD) ||
    2152           0 :             (h2c_term_req->fes == SPDK_NVME_TCP_TERM_REQ_FES_INVALID_DATA_UNSUPPORTED_PARAMETER)) {
    2153           0 :                 SPDK_DEBUGLOG(nvmf_tcp, "The offset from the start of the PDU header is %u\n",
    2154             :                               DGET32(h2c_term_req->fei));
    2155           0 :         }
    2156           0 : }
    2157             : 
    2158             : static void
    2159           0 : nvmf_tcp_h2c_term_req_hdr_handle(struct spdk_nvmf_tcp_qpair *tqpair,
    2160             :                                  struct nvme_tcp_pdu *pdu)
    2161             : {
    2162           0 :         struct spdk_nvme_tcp_term_req_hdr *h2c_term_req = &pdu->hdr.term_req;
    2163           0 :         uint32_t error_offset = 0;
    2164             :         enum spdk_nvme_tcp_term_req_fes fes;
    2165             : 
    2166           0 :         if (h2c_term_req->fes > SPDK_NVME_TCP_TERM_REQ_FES_INVALID_DATA_UNSUPPORTED_PARAMETER) {
    2167           0 :                 SPDK_ERRLOG("Fatal Error Status(FES) is unknown for h2c_term_req pdu=%p\n", pdu);
    2168           0 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
    2169           0 :                 error_offset = offsetof(struct spdk_nvme_tcp_term_req_hdr, fes);
    2170           0 :                 goto end;
    2171             :         }
    2172             : 
    2173             :         /* set the data buffer */
    2174           0 :         nvme_tcp_pdu_set_data(pdu, (uint8_t *)pdu->hdr.raw + h2c_term_req->common.hlen,
    2175           0 :                               h2c_term_req->common.plen - h2c_term_req->common.hlen);
    2176           0 :         nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PAYLOAD);
    2177           0 :         return;
    2178             : end:
    2179           0 :         nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
    2180           0 : }
    2181             : 
    2182             : static void
    2183           0 : nvmf_tcp_h2c_term_req_payload_handle(struct spdk_nvmf_tcp_qpair *tqpair,
    2184             :                                      struct nvme_tcp_pdu *pdu)
    2185             : {
    2186           0 :         struct spdk_nvme_tcp_term_req_hdr *h2c_term_req = &pdu->hdr.term_req;
    2187             : 
    2188           0 :         nvmf_tcp_h2c_term_req_dump(h2c_term_req);
    2189           0 :         nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_QUIESCING);
    2190           0 : }
    2191             : 
    2192             : static void
    2193           0 : _nvmf_tcp_pdu_payload_handle(struct spdk_nvmf_tcp_qpair *tqpair, struct nvme_tcp_pdu *pdu)
    2194             : {
    2195           0 :         struct spdk_nvmf_tcp_transport *ttransport = SPDK_CONTAINEROF(tqpair->qpair.transport,
    2196             :                         struct spdk_nvmf_tcp_transport, transport);
    2197             : 
    2198           0 :         switch (pdu->hdr.common.pdu_type) {
    2199             :         case SPDK_NVME_TCP_PDU_TYPE_CAPSULE_CMD:
    2200           0 :                 nvmf_tcp_capsule_cmd_payload_handle(ttransport, tqpair, pdu);
    2201           0 :                 break;
    2202             :         case SPDK_NVME_TCP_PDU_TYPE_H2C_DATA:
    2203           0 :                 nvmf_tcp_h2c_data_payload_handle(ttransport, tqpair, pdu);
    2204           0 :                 break;
    2205             : 
    2206             :         case SPDK_NVME_TCP_PDU_TYPE_H2C_TERM_REQ:
    2207           0 :                 nvmf_tcp_h2c_term_req_payload_handle(tqpair, pdu);
    2208           0 :                 break;
    2209             : 
    2210             :         default:
    2211             :                 /* The code should not go to here */
    2212           0 :                 SPDK_ERRLOG("ERROR pdu type %d\n", pdu->hdr.common.pdu_type);
    2213           0 :                 break;
    2214             :         }
    2215           0 :         SLIST_INSERT_HEAD(&tqpair->tcp_pdu_free_queue, pdu, slist);
    2216           0 :         tqpair->tcp_pdu_working_count--;
    2217           0 : }
    2218             : 
    2219             : static inline void
    2220           1 : nvmf_tcp_req_set_cpl(struct spdk_nvmf_tcp_req *treq, int sct, int sc)
    2221             : {
    2222           1 :         treq->req.rsp->nvme_cpl.status.sct = sct;
    2223           1 :         treq->req.rsp->nvme_cpl.status.sc = sc;
    2224           1 :         treq->req.rsp->nvme_cpl.cid = treq->req.cmd->nvme_cmd.cid;
    2225           1 : }
    2226             : 
    2227             : static void
    2228           0 : data_crc32_calc_done(void *cb_arg, int status)
    2229             : {
    2230           0 :         struct nvme_tcp_pdu *pdu = cb_arg;
    2231           0 :         struct spdk_nvmf_tcp_qpair *tqpair = pdu->qpair;
    2232             : 
    2233             :         /* async crc32 calculation is failed and use direct calculation to check */
    2234           0 :         if (spdk_unlikely(status)) {
    2235           0 :                 SPDK_ERRLOG("Data digest on tqpair=(%p) with pdu=%p failed to be calculated asynchronously\n",
    2236             :                             tqpair, pdu);
    2237           0 :                 pdu->data_digest_crc32 = nvme_tcp_pdu_calc_data_digest(pdu);
    2238           0 :         }
    2239           0 :         pdu->data_digest_crc32 ^= SPDK_CRC32C_XOR;
    2240           0 :         if (!MATCH_DIGEST_WORD(pdu->data_digest, pdu->data_digest_crc32)) {
    2241           0 :                 SPDK_ERRLOG("Data digest error on tqpair=(%p) with pdu=%p\n", tqpair, pdu);
    2242           0 :                 assert(pdu->req != NULL);
    2243           0 :                 nvmf_tcp_req_set_cpl(pdu->req, SPDK_NVME_SCT_GENERIC,
    2244             :                                      SPDK_NVME_SC_COMMAND_TRANSIENT_TRANSPORT_ERROR);
    2245           0 :         }
    2246           0 :         _nvmf_tcp_pdu_payload_handle(tqpair, pdu);
    2247           0 : }
    2248             : 
    2249             : static void
    2250           0 : nvmf_tcp_pdu_payload_handle(struct spdk_nvmf_tcp_qpair *tqpair, struct nvme_tcp_pdu *pdu)
    2251             : {
    2252           0 :         int rc = 0;
    2253           0 :         assert(tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PAYLOAD);
    2254           0 :         tqpair->pdu_in_progress = NULL;
    2255           0 :         nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY);
    2256           0 :         SPDK_DEBUGLOG(nvmf_tcp, "enter\n");
    2257             :         /* check data digest if need */
    2258           0 :         if (pdu->ddgst_enable) {
    2259           0 :                 if (tqpair->qpair.qid != 0 && !pdu->dif_ctx && tqpair->group &&
    2260           0 :                     (pdu->data_len % SPDK_NVME_TCP_DIGEST_ALIGNMENT == 0)) {
    2261           0 :                         rc = spdk_accel_submit_crc32cv(tqpair->group->accel_channel, &pdu->data_digest_crc32, pdu->data_iov,
    2262           0 :                                                        pdu->data_iovcnt, 0, data_crc32_calc_done, pdu);
    2263           0 :                         if (spdk_likely(rc == 0)) {
    2264           0 :                                 return;
    2265             :                         }
    2266           0 :                 } else {
    2267           0 :                         pdu->data_digest_crc32 = nvme_tcp_pdu_calc_data_digest(pdu);
    2268             :                 }
    2269           0 :                 data_crc32_calc_done(pdu, rc);
    2270           0 :         } else {
    2271           0 :                 _nvmf_tcp_pdu_payload_handle(tqpair, pdu);
    2272             :         }
    2273           0 : }
    2274             : 
    2275             : static void
    2276           0 : nvmf_tcp_send_icresp_complete(void *cb_arg)
    2277             : {
    2278           0 :         struct spdk_nvmf_tcp_qpair *tqpair = cb_arg;
    2279             : 
    2280           0 :         nvmf_tcp_qpair_set_state(tqpair, NVMF_TCP_QPAIR_STATE_RUNNING);
    2281           0 : }
    2282             : 
    2283             : static void
    2284           3 : nvmf_tcp_icreq_handle(struct spdk_nvmf_tcp_transport *ttransport,
    2285             :                       struct spdk_nvmf_tcp_qpair *tqpair,
    2286             :                       struct nvme_tcp_pdu *pdu)
    2287             : {
    2288           3 :         struct spdk_nvme_tcp_ic_req *ic_req = &pdu->hdr.ic_req;
    2289             :         struct nvme_tcp_pdu *rsp_pdu;
    2290             :         struct spdk_nvme_tcp_ic_resp *ic_resp;
    2291           3 :         uint32_t error_offset = 0;
    2292             :         enum spdk_nvme_tcp_term_req_fes fes;
    2293             : 
    2294             :         /* Only PFV 0 is defined currently */
    2295           3 :         if (ic_req->pfv != 0) {
    2296           2 :                 SPDK_ERRLOG("Expected ICReq PFV %u, got %u\n", 0u, ic_req->pfv);
    2297           2 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
    2298           2 :                 error_offset = offsetof(struct spdk_nvme_tcp_ic_req, pfv);
    2299           2 :                 goto end;
    2300             :         }
    2301             : 
    2302             :         /* This value is 0’s based value in units of dwords should not be larger than SPDK_NVME_TCP_HPDA_MAX */
    2303           1 :         if (ic_req->hpda > SPDK_NVME_TCP_HPDA_MAX) {
    2304           0 :                 SPDK_ERRLOG("ICReq HPDA out of range 0 to 31, got %u\n", ic_req->hpda);
    2305           0 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
    2306           0 :                 error_offset = offsetof(struct spdk_nvme_tcp_ic_req, hpda);
    2307           0 :                 goto end;
    2308             :         }
    2309             : 
    2310             :         /* MAXR2T is 0's based */
    2311           1 :         SPDK_DEBUGLOG(nvmf_tcp, "maxr2t =%u\n", (ic_req->maxr2t + 1u));
    2312             : 
    2313           1 :         tqpair->host_hdgst_enable = ic_req->dgst.bits.hdgst_enable ? true : false;
    2314           1 :         if (!tqpair->host_hdgst_enable) {
    2315           1 :                 tqpair->recv_buf_size -= SPDK_NVME_TCP_DIGEST_LEN * SPDK_NVMF_TCP_RECV_BUF_SIZE_FACTOR;
    2316           1 :         }
    2317             : 
    2318           1 :         tqpair->host_ddgst_enable = ic_req->dgst.bits.ddgst_enable ? true : false;
    2319           1 :         if (!tqpair->host_ddgst_enable) {
    2320           1 :                 tqpair->recv_buf_size -= SPDK_NVME_TCP_DIGEST_LEN * SPDK_NVMF_TCP_RECV_BUF_SIZE_FACTOR;
    2321           1 :         }
    2322             : 
    2323           1 :         tqpair->recv_buf_size = spdk_max(tqpair->recv_buf_size, MIN_SOCK_PIPE_SIZE);
    2324             :         /* Now that we know whether digests are enabled, properly size the receive buffer */
    2325           1 :         if (spdk_sock_set_recvbuf(tqpair->sock, tqpair->recv_buf_size) < 0) {
    2326           0 :                 SPDK_WARNLOG("Unable to allocate enough memory for receive buffer on tqpair=%p with size=%d\n",
    2327             :                              tqpair,
    2328             :                              tqpair->recv_buf_size);
    2329             :                 /* Not fatal. */
    2330           0 :         }
    2331             : 
    2332           1 :         tqpair->cpda = spdk_min(ic_req->hpda, SPDK_NVME_TCP_CPDA_MAX);
    2333           1 :         SPDK_DEBUGLOG(nvmf_tcp, "cpda of tqpair=(%p) is : %u\n", tqpair, tqpair->cpda);
    2334             : 
    2335           1 :         rsp_pdu = tqpair->mgmt_pdu;
    2336             : 
    2337           1 :         ic_resp = &rsp_pdu->hdr.ic_resp;
    2338           1 :         ic_resp->common.pdu_type = SPDK_NVME_TCP_PDU_TYPE_IC_RESP;
    2339           1 :         ic_resp->common.hlen = ic_resp->common.plen =  sizeof(*ic_resp);
    2340           1 :         ic_resp->pfv = 0;
    2341           1 :         ic_resp->cpda = tqpair->cpda;
    2342           1 :         ic_resp->maxh2cdata = ttransport->transport.opts.max_io_size;
    2343           1 :         ic_resp->dgst.bits.hdgst_enable = tqpair->host_hdgst_enable ? 1 : 0;
    2344           1 :         ic_resp->dgst.bits.ddgst_enable = tqpair->host_ddgst_enable ? 1 : 0;
    2345             : 
    2346           1 :         SPDK_DEBUGLOG(nvmf_tcp, "host_hdgst_enable: %u\n", tqpair->host_hdgst_enable);
    2347           1 :         SPDK_DEBUGLOG(nvmf_tcp, "host_ddgst_enable: %u\n", tqpair->host_ddgst_enable);
    2348             : 
    2349           1 :         nvmf_tcp_qpair_set_state(tqpair, NVMF_TCP_QPAIR_STATE_INITIALIZING);
    2350           1 :         nvmf_tcp_qpair_write_mgmt_pdu(tqpair, nvmf_tcp_send_icresp_complete, tqpair);
    2351           1 :         nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY);
    2352           1 :         return;
    2353             : end:
    2354           2 :         nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
    2355           3 : }
    2356             : 
    2357             : static void
    2358           0 : nvmf_tcp_pdu_psh_handle(struct spdk_nvmf_tcp_qpair *tqpair,
    2359             :                         struct spdk_nvmf_tcp_transport *ttransport)
    2360             : {
    2361             :         struct nvme_tcp_pdu *pdu;
    2362             :         int rc;
    2363           0 :         uint32_t crc32c, error_offset = 0;
    2364             :         enum spdk_nvme_tcp_term_req_fes fes;
    2365             : 
    2366           0 :         assert(tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PSH);
    2367           0 :         pdu = tqpair->pdu_in_progress;
    2368             : 
    2369           0 :         SPDK_DEBUGLOG(nvmf_tcp, "pdu type of tqpair(%p) is %d\n", tqpair,
    2370             :                       pdu->hdr.common.pdu_type);
    2371             :         /* check header digest if needed */
    2372           0 :         if (pdu->has_hdgst) {
    2373           0 :                 SPDK_DEBUGLOG(nvmf_tcp, "Compare the header of pdu=%p on tqpair=%p\n", pdu, tqpair);
    2374           0 :                 crc32c = nvme_tcp_pdu_calc_header_digest(pdu);
    2375           0 :                 rc = MATCH_DIGEST_WORD((uint8_t *)pdu->hdr.raw + pdu->hdr.common.hlen, crc32c);
    2376           0 :                 if (rc == 0) {
    2377           0 :                         SPDK_ERRLOG("Header digest error on tqpair=(%p) with pdu=%p\n", tqpair, pdu);
    2378           0 :                         fes = SPDK_NVME_TCP_TERM_REQ_FES_HDGST_ERROR;
    2379           0 :                         nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
    2380           0 :                         return;
    2381             : 
    2382             :                 }
    2383           0 :         }
    2384             : 
    2385           0 :         switch (pdu->hdr.common.pdu_type) {
    2386             :         case SPDK_NVME_TCP_PDU_TYPE_IC_REQ:
    2387           0 :                 nvmf_tcp_icreq_handle(ttransport, tqpair, pdu);
    2388           0 :                 break;
    2389             :         case SPDK_NVME_TCP_PDU_TYPE_CAPSULE_CMD:
    2390           0 :                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_REQ);
    2391           0 :                 break;
    2392             :         case SPDK_NVME_TCP_PDU_TYPE_H2C_DATA:
    2393           0 :                 nvmf_tcp_h2c_data_hdr_handle(ttransport, tqpair, pdu);
    2394           0 :                 break;
    2395             : 
    2396             :         case SPDK_NVME_TCP_PDU_TYPE_H2C_TERM_REQ:
    2397           0 :                 nvmf_tcp_h2c_term_req_hdr_handle(tqpair, pdu);
    2398           0 :                 break;
    2399             : 
    2400             :         default:
    2401           0 :                 SPDK_ERRLOG("Unexpected PDU type 0x%02x\n", tqpair->pdu_in_progress->hdr.common.pdu_type);
    2402           0 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
    2403           0 :                 error_offset = 1;
    2404           0 :                 nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
    2405           0 :                 break;
    2406             :         }
    2407           0 : }
    2408             : 
    2409             : static void
    2410          11 : nvmf_tcp_pdu_ch_handle(struct spdk_nvmf_tcp_qpair *tqpair)
    2411             : {
    2412             :         struct nvme_tcp_pdu *pdu;
    2413          11 :         uint32_t error_offset = 0;
    2414             :         enum spdk_nvme_tcp_term_req_fes fes;
    2415             :         uint8_t expected_hlen, pdo;
    2416          11 :         bool plen_error = false, pdo_error = false;
    2417             : 
    2418          11 :         assert(tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_CH);
    2419          11 :         pdu = tqpair->pdu_in_progress;
    2420          11 :         assert(pdu);
    2421          11 :         if (pdu->hdr.common.pdu_type == SPDK_NVME_TCP_PDU_TYPE_IC_REQ) {
    2422           4 :                 if (tqpair->state != NVMF_TCP_QPAIR_STATE_INVALID) {
    2423           1 :                         SPDK_ERRLOG("Already received ICreq PDU, and reject this pdu=%p\n", pdu);
    2424           1 :                         fes = SPDK_NVME_TCP_TERM_REQ_FES_PDU_SEQUENCE_ERROR;
    2425           1 :                         goto err;
    2426             :                 }
    2427           3 :                 expected_hlen = sizeof(struct spdk_nvme_tcp_ic_req);
    2428           3 :                 if (pdu->hdr.common.plen != expected_hlen) {
    2429           1 :                         plen_error = true;
    2430           1 :                 }
    2431           3 :         } else {
    2432           7 :                 if (tqpair->state != NVMF_TCP_QPAIR_STATE_RUNNING) {
    2433           1 :                         SPDK_ERRLOG("The TCP/IP connection is not negotiated\n");
    2434           1 :                         fes = SPDK_NVME_TCP_TERM_REQ_FES_PDU_SEQUENCE_ERROR;
    2435           1 :                         goto err;
    2436             :                 }
    2437             : 
    2438           6 :                 switch (pdu->hdr.common.pdu_type) {
    2439             :                 case SPDK_NVME_TCP_PDU_TYPE_CAPSULE_CMD:
    2440           2 :                         expected_hlen = sizeof(struct spdk_nvme_tcp_cmd);
    2441           2 :                         pdo = pdu->hdr.common.pdo;
    2442           2 :                         if ((tqpair->cpda != 0) && (pdo % ((tqpair->cpda + 1) << 2) != 0)) {
    2443           1 :                                 pdo_error = true;
    2444           1 :                                 break;
    2445             :                         }
    2446             : 
    2447           1 :                         if (pdu->hdr.common.plen < expected_hlen) {
    2448           1 :                                 plen_error = true;
    2449           1 :                         }
    2450           1 :                         break;
    2451             :                 case SPDK_NVME_TCP_PDU_TYPE_H2C_DATA:
    2452           2 :                         expected_hlen = sizeof(struct spdk_nvme_tcp_h2c_data_hdr);
    2453           2 :                         pdo = pdu->hdr.common.pdo;
    2454           2 :                         if ((tqpair->cpda != 0) && (pdo % ((tqpair->cpda + 1) << 2) != 0)) {
    2455           1 :                                 pdo_error = true;
    2456           1 :                                 break;
    2457             :                         }
    2458           1 :                         if (pdu->hdr.common.plen < expected_hlen) {
    2459           1 :                                 plen_error = true;
    2460           1 :                         }
    2461           1 :                         break;
    2462             : 
    2463             :                 case SPDK_NVME_TCP_PDU_TYPE_H2C_TERM_REQ:
    2464           1 :                         expected_hlen = sizeof(struct spdk_nvme_tcp_term_req_hdr);
    2465           1 :                         if ((pdu->hdr.common.plen <= expected_hlen) ||
    2466           0 :                             (pdu->hdr.common.plen > SPDK_NVME_TCP_TERM_REQ_PDU_MAX_SIZE)) {
    2467           1 :                                 plen_error = true;
    2468           1 :                         }
    2469           1 :                         break;
    2470             : 
    2471             :                 default:
    2472           1 :                         SPDK_ERRLOG("Unexpected PDU type 0x%02x\n", pdu->hdr.common.pdu_type);
    2473           1 :                         fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
    2474           1 :                         error_offset = offsetof(struct spdk_nvme_tcp_common_pdu_hdr, pdu_type);
    2475           1 :                         goto err;
    2476             :                 }
    2477             :         }
    2478             : 
    2479          10 :         if (pdu->hdr.common.hlen != expected_hlen) {
    2480           1 :                 SPDK_ERRLOG("PDU type=0x%02x, Expected ICReq header length %u, got %u on tqpair=%p\n",
    2481             :                             pdu->hdr.common.pdu_type,
    2482             :                             expected_hlen, pdu->hdr.common.hlen, tqpair);
    2483           1 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
    2484           1 :                 error_offset = offsetof(struct spdk_nvme_tcp_common_pdu_hdr, hlen);
    2485           1 :                 goto err;
    2486           7 :         } else if (pdo_error) {
    2487           2 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
    2488           2 :                 error_offset = offsetof(struct spdk_nvme_tcp_common_pdu_hdr, pdo);
    2489           7 :         } else if (plen_error) {
    2490           4 :                 fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
    2491           4 :                 error_offset = offsetof(struct spdk_nvme_tcp_common_pdu_hdr, plen);
    2492           4 :                 goto err;
    2493             :         } else {
    2494           1 :                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PSH);
    2495           1 :                 nvme_tcp_pdu_calc_psh_len(tqpair->pdu_in_progress, tqpair->host_hdgst_enable);
    2496           1 :                 return;
    2497             :         }
    2498             : err:
    2499          10 :         nvmf_tcp_send_c2h_term_req(tqpair, pdu, fes, error_offset);
    2500          11 : }
    2501             : 
    2502             : static int
    2503           0 : nvmf_tcp_sock_process(struct spdk_nvmf_tcp_qpair *tqpair)
    2504             : {
    2505           0 :         int rc = 0;
    2506             :         struct nvme_tcp_pdu *pdu;
    2507             :         enum nvme_tcp_pdu_recv_state prev_state;
    2508             :         uint32_t data_len;
    2509           0 :         struct spdk_nvmf_tcp_transport *ttransport = SPDK_CONTAINEROF(tqpair->qpair.transport,
    2510             :                         struct spdk_nvmf_tcp_transport, transport);
    2511             : 
    2512             :         /* The loop here is to allow for several back-to-back state changes. */
    2513           0 :         do {
    2514           0 :                 prev_state = tqpair->recv_state;
    2515           0 :                 SPDK_DEBUGLOG(nvmf_tcp, "tqpair(%p) recv pdu entering state %d\n", tqpair, prev_state);
    2516             : 
    2517           0 :                 pdu = tqpair->pdu_in_progress;
    2518           0 :                 assert(pdu != NULL ||
    2519             :                        tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY ||
    2520             :                        tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_QUIESCING ||
    2521             :                        tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_ERROR);
    2522             : 
    2523           0 :                 switch (tqpair->recv_state) {
    2524             :                 /* Wait for the common header  */
    2525             :                 case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY:
    2526           0 :                         if (!pdu) {
    2527           0 :                                 pdu = SLIST_FIRST(&tqpair->tcp_pdu_free_queue);
    2528           0 :                                 if (spdk_unlikely(!pdu)) {
    2529           0 :                                         return NVME_TCP_PDU_IN_PROGRESS;
    2530             :                                 }
    2531           0 :                                 SLIST_REMOVE_HEAD(&tqpair->tcp_pdu_free_queue, slist);
    2532           0 :                                 tqpair->pdu_in_progress = pdu;
    2533           0 :                                 tqpair->tcp_pdu_working_count++;
    2534           0 :                         }
    2535           0 :                         memset(pdu, 0, offsetof(struct nvme_tcp_pdu, qpair));
    2536           0 :                         nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_CH);
    2537             :                 /* FALLTHROUGH */
    2538             :                 case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_CH:
    2539           0 :                         if (spdk_unlikely(tqpair->state == NVMF_TCP_QPAIR_STATE_INITIALIZING)) {
    2540           0 :                                 return rc;
    2541             :                         }
    2542             : 
    2543           0 :                         rc = nvme_tcp_read_data(tqpair->sock,
    2544           0 :                                                 sizeof(struct spdk_nvme_tcp_common_pdu_hdr) - pdu->ch_valid_bytes,
    2545           0 :                                                 (void *)&pdu->hdr.common + pdu->ch_valid_bytes);
    2546           0 :                         if (rc < 0) {
    2547           0 :                                 SPDK_DEBUGLOG(nvmf_tcp, "will disconnect tqpair=%p\n", tqpair);
    2548           0 :                                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_QUIESCING);
    2549           0 :                                 break;
    2550           0 :                         } else if (rc > 0) {
    2551           0 :                                 pdu->ch_valid_bytes += rc;
    2552           0 :                                 spdk_trace_record(TRACE_TCP_READ_FROM_SOCKET_DONE, tqpair->qpair.trace_id, rc, 0);
    2553           0 :                         }
    2554             : 
    2555           0 :                         if (pdu->ch_valid_bytes < sizeof(struct spdk_nvme_tcp_common_pdu_hdr)) {
    2556           0 :                                 return NVME_TCP_PDU_IN_PROGRESS;
    2557             :                         }
    2558             : 
    2559             :                         /* The command header of this PDU has now been read from the socket. */
    2560           0 :                         nvmf_tcp_pdu_ch_handle(tqpair);
    2561           0 :                         break;
    2562             :                 /* Wait for the pdu specific header  */
    2563             :                 case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PSH:
    2564           0 :                         rc = nvme_tcp_read_data(tqpair->sock,
    2565           0 :                                                 pdu->psh_len - pdu->psh_valid_bytes,
    2566           0 :                                                 (void *)&pdu->hdr.raw + sizeof(struct spdk_nvme_tcp_common_pdu_hdr) + pdu->psh_valid_bytes);
    2567           0 :                         if (rc < 0) {
    2568           0 :                                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_QUIESCING);
    2569           0 :                                 break;
    2570           0 :                         } else if (rc > 0) {
    2571           0 :                                 spdk_trace_record(TRACE_TCP_READ_FROM_SOCKET_DONE, tqpair->qpair.trace_id, rc, 0);
    2572           0 :                                 pdu->psh_valid_bytes += rc;
    2573           0 :                         }
    2574             : 
    2575           0 :                         if (pdu->psh_valid_bytes < pdu->psh_len) {
    2576           0 :                                 return NVME_TCP_PDU_IN_PROGRESS;
    2577             :                         }
    2578             : 
    2579             :                         /* All header(ch, psh, head digits) of this PDU has now been read from the socket. */
    2580           0 :                         nvmf_tcp_pdu_psh_handle(tqpair, ttransport);
    2581           0 :                         break;
    2582             :                 /* Wait for the req slot */
    2583             :                 case NVME_TCP_PDU_RECV_STATE_AWAIT_REQ:
    2584           0 :                         nvmf_tcp_capsule_cmd_hdr_handle(ttransport, tqpair, pdu);
    2585           0 :                         break;
    2586             :                 /* Wait for the request processing loop to acquire a buffer for the PDU */
    2587             :                 case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_BUF:
    2588           0 :                         break;
    2589             :                 case NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PAYLOAD:
    2590             :                         /* check whether the data is valid, if not we just return */
    2591           0 :                         if (!pdu->data_len) {
    2592           0 :                                 return NVME_TCP_PDU_IN_PROGRESS;
    2593             :                         }
    2594             : 
    2595           0 :                         data_len = pdu->data_len;
    2596             :                         /* data digest */
    2597           0 :                         if (spdk_unlikely((pdu->hdr.common.pdu_type != SPDK_NVME_TCP_PDU_TYPE_H2C_TERM_REQ) &&
    2598             :                                           tqpair->host_ddgst_enable)) {
    2599           0 :                                 data_len += SPDK_NVME_TCP_DIGEST_LEN;
    2600           0 :                                 pdu->ddgst_enable = true;
    2601           0 :                         }
    2602             : 
    2603           0 :                         rc = nvme_tcp_read_payload_data(tqpair->sock, pdu);
    2604           0 :                         if (rc < 0) {
    2605           0 :                                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_QUIESCING);
    2606           0 :                                 break;
    2607             :                         }
    2608           0 :                         pdu->rw_offset += rc;
    2609             : 
    2610           0 :                         if (pdu->rw_offset < data_len) {
    2611           0 :                                 return NVME_TCP_PDU_IN_PROGRESS;
    2612             :                         }
    2613             : 
    2614             :                         /* Generate and insert DIF to whole data block received if DIF is enabled */
    2615           0 :                         if (spdk_unlikely(pdu->dif_ctx != NULL) &&
    2616           0 :                             spdk_dif_generate_stream(pdu->data_iov, pdu->data_iovcnt, 0, data_len,
    2617           0 :                                                      pdu->dif_ctx) != 0) {
    2618           0 :                                 SPDK_ERRLOG("DIF generate failed\n");
    2619           0 :                                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_QUIESCING);
    2620           0 :                                 break;
    2621             :                         }
    2622             : 
    2623             :                         /* All of this PDU has now been read from the socket. */
    2624           0 :                         nvmf_tcp_pdu_payload_handle(tqpair, pdu);
    2625           0 :                         break;
    2626             :                 case NVME_TCP_PDU_RECV_STATE_QUIESCING:
    2627           0 :                         if (tqpair->tcp_pdu_working_count != 0) {
    2628           0 :                                 return NVME_TCP_PDU_IN_PROGRESS;
    2629             :                         }
    2630           0 :                         nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_ERROR);
    2631           0 :                         break;
    2632             :                 case NVME_TCP_PDU_RECV_STATE_ERROR:
    2633           0 :                         if (spdk_sock_is_connected(tqpair->sock) && tqpair->wait_terminate) {
    2634           0 :                                 return NVME_TCP_PDU_IN_PROGRESS;
    2635             :                         }
    2636           0 :                         return NVME_TCP_PDU_FATAL;
    2637             :                 default:
    2638           0 :                         SPDK_ERRLOG("The state(%d) is invalid\n", tqpair->recv_state);
    2639           0 :                         abort();
    2640             :                         break;
    2641             :                 }
    2642           0 :         } while (tqpair->recv_state != prev_state);
    2643             : 
    2644           0 :         return rc;
    2645           0 : }
    2646             : 
    2647             : static inline void *
    2648           0 : nvmf_tcp_control_msg_get(struct spdk_nvmf_tcp_control_msg_list *list,
    2649             :                          struct spdk_nvmf_tcp_req *tcp_req)
    2650             : {
    2651             :         struct spdk_nvmf_tcp_control_msg *msg;
    2652             : 
    2653           0 :         assert(list);
    2654             : 
    2655           0 :         msg = STAILQ_FIRST(&list->free_msgs);
    2656           0 :         if (!msg) {
    2657           0 :                 SPDK_DEBUGLOG(nvmf_tcp, "Out of control messages\n");
    2658           0 :                 STAILQ_INSERT_TAIL(&list->waiting_for_msg_reqs, tcp_req, control_msg_link);
    2659           0 :                 return NULL;
    2660             :         }
    2661           0 :         STAILQ_REMOVE_HEAD(&list->free_msgs, link);
    2662           0 :         return msg;
    2663           0 : }
    2664             : 
    2665             : static inline void
    2666           0 : nvmf_tcp_control_msg_put(struct spdk_nvmf_tcp_control_msg_list *list, void *_msg)
    2667             : {
    2668           0 :         struct spdk_nvmf_tcp_control_msg *msg = _msg;
    2669             :         struct spdk_nvmf_tcp_req *tcp_req;
    2670             :         struct spdk_nvmf_tcp_transport *ttransport;
    2671             : 
    2672           0 :         assert(list);
    2673           0 :         STAILQ_INSERT_HEAD(&list->free_msgs, msg, link);
    2674           0 :         if (!STAILQ_EMPTY(&list->waiting_for_msg_reqs)) {
    2675           0 :                 tcp_req = STAILQ_FIRST(&list->waiting_for_msg_reqs);
    2676           0 :                 STAILQ_REMOVE_HEAD(&list->waiting_for_msg_reqs, control_msg_link);
    2677           0 :                 ttransport = SPDK_CONTAINEROF(tcp_req->req.qpair->transport,
    2678             :                                               struct spdk_nvmf_tcp_transport, transport);
    2679           0 :                 nvmf_tcp_req_process(ttransport, tcp_req);
    2680           0 :         }
    2681           0 : }
    2682             : 
    2683             : static void
    2684           3 : nvmf_tcp_req_parse_sgl(struct spdk_nvmf_tcp_req *tcp_req,
    2685             :                        struct spdk_nvmf_transport *transport,
    2686             :                        struct spdk_nvmf_transport_poll_group *group)
    2687             : {
    2688           3 :         struct spdk_nvmf_request                *req = &tcp_req->req;
    2689             :         struct spdk_nvme_cmd                    *cmd;
    2690             :         struct spdk_nvme_sgl_descriptor         *sgl;
    2691             :         struct spdk_nvmf_tcp_poll_group         *tgroup;
    2692             :         enum spdk_nvme_tcp_term_req_fes         fes;
    2693             :         struct nvme_tcp_pdu                     *pdu;
    2694             :         struct spdk_nvmf_tcp_qpair              *tqpair;
    2695           3 :         uint32_t                                length, error_offset = 0;
    2696             : 
    2697           3 :         cmd = &req->cmd->nvme_cmd;
    2698           3 :         sgl = &cmd->dptr.sgl1;
    2699             : 
    2700           3 :         if (sgl->generic.type == SPDK_NVME_SGL_TYPE_TRANSPORT_DATA_BLOCK &&
    2701           3 :             sgl->unkeyed.subtype == SPDK_NVME_SGL_SUBTYPE_TRANSPORT) {
    2702             :                 /* get request length from sgl */
    2703           3 :                 length = sgl->unkeyed.length;
    2704           3 :                 if (spdk_unlikely(length > transport->opts.max_io_size)) {
    2705           1 :                         SPDK_ERRLOG("SGL length 0x%x exceeds max io size 0x%x\n",
    2706             :                                     length, transport->opts.max_io_size);
    2707           1 :                         fes = SPDK_NVME_TCP_TERM_REQ_FES_DATA_TRANSFER_LIMIT_EXCEEDED;
    2708           1 :                         goto fatal_err;
    2709             :                 }
    2710             : 
    2711             :                 /* fill request length and populate iovs */
    2712           2 :                 req->length = length;
    2713             : 
    2714           2 :                 SPDK_DEBUGLOG(nvmf_tcp, "Data requested length= 0x%x\n", length);
    2715             : 
    2716           2 :                 if (spdk_unlikely(req->dif_enabled)) {
    2717           0 :                         req->dif.orig_length = length;
    2718           0 :                         length = spdk_dif_get_length_with_md(length, &req->dif.dif_ctx);
    2719           0 :                         req->dif.elba_length = length;
    2720           0 :                 }
    2721             : 
    2722           2 :                 if (nvmf_ctrlr_use_zcopy(req)) {
    2723           0 :                         SPDK_DEBUGLOG(nvmf_tcp, "Using zero-copy to execute request %p\n", tcp_req);
    2724           0 :                         req->data_from_pool = false;
    2725           0 :                         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_HAVE_BUFFER);
    2726           0 :                         return;
    2727             :                 }
    2728             : 
    2729           2 :                 if (spdk_nvmf_request_get_buffers(req, group, transport, length)) {
    2730             :                         /* No available buffers. Queue this request up. */
    2731           1 :                         SPDK_DEBUGLOG(nvmf_tcp, "No available large data buffers. Queueing request %p\n",
    2732             :                                       tcp_req);
    2733           1 :                         return;
    2734             :                 }
    2735             : 
    2736           1 :                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_HAVE_BUFFER);
    2737           1 :                 SPDK_DEBUGLOG(nvmf_tcp, "Request %p took %d buffer/s from central pool, and data=%p\n",
    2738             :                               tcp_req, req->iovcnt, req->iov[0].iov_base);
    2739             : 
    2740           1 :                 return;
    2741           0 :         } else if (sgl->generic.type == SPDK_NVME_SGL_TYPE_DATA_BLOCK &&
    2742           0 :                    sgl->unkeyed.subtype == SPDK_NVME_SGL_SUBTYPE_OFFSET) {
    2743           0 :                 uint64_t offset = sgl->address;
    2744           0 :                 uint32_t max_len = transport->opts.in_capsule_data_size;
    2745             : 
    2746           0 :                 assert(tcp_req->has_in_capsule_data);
    2747             :                 /* Capsule Cmd with In-capsule Data should get data length from pdu header */
    2748           0 :                 tqpair = tcp_req->pdu->qpair;
    2749             :                 /* receiving pdu is not same with the pdu in tcp_req */
    2750           0 :                 pdu = tqpair->pdu_in_progress;
    2751           0 :                 length = pdu->hdr.common.plen - pdu->psh_len - sizeof(struct spdk_nvme_tcp_common_pdu_hdr);
    2752           0 :                 if (tqpair->host_ddgst_enable) {
    2753           0 :                         length -= SPDK_NVME_TCP_DIGEST_LEN;
    2754           0 :                 }
    2755             :                 /* This error is not defined in NVMe/TCP spec, take this error as fatal error */
    2756           0 :                 if (spdk_unlikely(length != sgl->unkeyed.length)) {
    2757           0 :                         SPDK_ERRLOG("In-Capsule Data length 0x%x is not equal to SGL data length 0x%x\n",
    2758             :                                     length, sgl->unkeyed.length);
    2759           0 :                         fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_HEADER_FIELD;
    2760           0 :                         error_offset = offsetof(struct spdk_nvme_tcp_common_pdu_hdr, plen);
    2761           0 :                         goto fatal_err;
    2762             :                 }
    2763             : 
    2764           0 :                 SPDK_DEBUGLOG(nvmf_tcp, "In-capsule data: offset 0x%" PRIx64 ", length 0x%x\n",
    2765             :                               offset, length);
    2766             : 
    2767             :                 /* The NVMe/TCP transport does not use ICDOFF to control the in-capsule data offset. ICDOFF should be '0' */
    2768           0 :                 if (spdk_unlikely(offset != 0)) {
    2769             :                         /* Not defined fatal error in NVMe/TCP spec, handle this error as a fatal error */
    2770           0 :                         SPDK_ERRLOG("In-capsule offset 0x%" PRIx64 " should be ZERO in NVMe/TCP\n", offset);
    2771           0 :                         fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_DATA_UNSUPPORTED_PARAMETER;
    2772           0 :                         error_offset = offsetof(struct spdk_nvme_tcp_cmd, ccsqe.dptr.sgl1.address);
    2773           0 :                         goto fatal_err;
    2774             :                 }
    2775             : 
    2776           0 :                 if (spdk_unlikely(length > max_len)) {
    2777             :                         /* According to the SPEC we should support ICD up to 8192 bytes for admin and fabric commands */
    2778           0 :                         if (length <= SPDK_NVME_TCP_IN_CAPSULE_DATA_MAX_SIZE &&
    2779           0 :                             (cmd->opc == SPDK_NVME_OPC_FABRIC || req->qpair->qid == 0)) {
    2780             : 
    2781             :                                 /* Get a buffer from dedicated list */
    2782           0 :                                 SPDK_DEBUGLOG(nvmf_tcp, "Getting a buffer from control msg list\n");
    2783           0 :                                 tgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_tcp_poll_group, group);
    2784           0 :                                 assert(tgroup->control_msg_list);
    2785           0 :                                 req->iov[0].iov_base = nvmf_tcp_control_msg_get(tgroup->control_msg_list, tcp_req);
    2786           0 :                                 if (!req->iov[0].iov_base) {
    2787             :                                         /* No available buffers. Queue this request up. */
    2788           0 :                                         SPDK_DEBUGLOG(nvmf_tcp, "No available ICD buffers. Queueing request %p\n", tcp_req);
    2789           0 :                                         nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_BUF);
    2790           0 :                                         return;
    2791             :                                 }
    2792           0 :                         } else {
    2793           0 :                                 SPDK_ERRLOG("In-capsule data length 0x%x exceeds capsule length 0x%x\n",
    2794             :                                             length, max_len);
    2795           0 :                                 fes = SPDK_NVME_TCP_TERM_REQ_FES_DATA_TRANSFER_LIMIT_EXCEEDED;
    2796           0 :                                 goto fatal_err;
    2797             :                         }
    2798           0 :                 } else {
    2799           0 :                         req->iov[0].iov_base = tcp_req->buf;
    2800             :                 }
    2801             : 
    2802           0 :                 req->length = length;
    2803           0 :                 req->data_from_pool = false;
    2804             : 
    2805           0 :                 if (spdk_unlikely(req->dif_enabled)) {
    2806           0 :                         length = spdk_dif_get_length_with_md(length, &req->dif.dif_ctx);
    2807           0 :                         req->dif.elba_length = length;
    2808           0 :                 }
    2809             : 
    2810           0 :                 req->iov[0].iov_len = length;
    2811           0 :                 req->iovcnt = 1;
    2812           0 :                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_HAVE_BUFFER);
    2813             : 
    2814           0 :                 return;
    2815             :         }
    2816             :         /* If we want to handle the problem here, then we can't skip the following data segment.
    2817             :          * Because this function runs before reading data part, now handle all errors as fatal errors. */
    2818           0 :         SPDK_ERRLOG("Invalid NVMf I/O Command SGL:  Type 0x%x, Subtype 0x%x\n",
    2819             :                     sgl->generic.type, sgl->generic.subtype);
    2820           0 :         fes = SPDK_NVME_TCP_TERM_REQ_FES_INVALID_DATA_UNSUPPORTED_PARAMETER;
    2821           0 :         error_offset = offsetof(struct spdk_nvme_tcp_cmd, ccsqe.dptr.sgl1.generic);
    2822             : fatal_err:
    2823           1 :         nvmf_tcp_send_c2h_term_req(tcp_req->pdu->qpair, tcp_req->pdu, fes, error_offset);
    2824           3 : }
    2825             : 
    2826             : static inline enum spdk_nvme_media_error_status_code
    2827           0 : nvmf_tcp_dif_error_to_compl_status(uint8_t err_type) {
    2828             :         enum spdk_nvme_media_error_status_code result;
    2829             : 
    2830           0 :         switch (err_type)
    2831             :         {
    2832             :         case SPDK_DIF_REFTAG_ERROR:
    2833           0 :                 result = SPDK_NVME_SC_REFERENCE_TAG_CHECK_ERROR;
    2834           0 :                 break;
    2835             :         case SPDK_DIF_APPTAG_ERROR:
    2836           0 :                 result = SPDK_NVME_SC_APPLICATION_TAG_CHECK_ERROR;
    2837           0 :                 break;
    2838             :         case SPDK_DIF_GUARD_ERROR:
    2839           0 :                 result = SPDK_NVME_SC_GUARD_CHECK_ERROR;
    2840           0 :                 break;
    2841             :         default:
    2842           0 :                 SPDK_UNREACHABLE();
    2843             :                 break;
    2844             :         }
    2845             : 
    2846           0 :         return result;
    2847             : }
    2848             : 
    2849             : static void
    2850           4 : _nvmf_tcp_send_c2h_data(struct spdk_nvmf_tcp_qpair *tqpair,
    2851             :                         struct spdk_nvmf_tcp_req *tcp_req)
    2852             : {
    2853           4 :         struct spdk_nvmf_tcp_transport *ttransport = SPDK_CONTAINEROF(
    2854             :                                 tqpair->qpair.transport, struct spdk_nvmf_tcp_transport, transport);
    2855             :         struct nvme_tcp_pdu *rsp_pdu;
    2856             :         struct spdk_nvme_tcp_c2h_data_hdr *c2h_data;
    2857             :         uint32_t plen, pdo, alignment;
    2858             :         int rc;
    2859             : 
    2860           4 :         SPDK_DEBUGLOG(nvmf_tcp, "enter\n");
    2861             : 
    2862           4 :         rsp_pdu = tcp_req->pdu;
    2863           4 :         assert(rsp_pdu != NULL);
    2864             : 
    2865           4 :         c2h_data = &rsp_pdu->hdr.c2h_data;
    2866           4 :         c2h_data->common.pdu_type = SPDK_NVME_TCP_PDU_TYPE_C2H_DATA;
    2867           4 :         plen = c2h_data->common.hlen = sizeof(*c2h_data);
    2868             : 
    2869           4 :         if (tqpair->host_hdgst_enable) {
    2870           0 :                 plen += SPDK_NVME_TCP_DIGEST_LEN;
    2871           0 :                 c2h_data->common.flags |= SPDK_NVME_TCP_CH_FLAGS_HDGSTF;
    2872           0 :         }
    2873             : 
    2874             :         /* set the psh */
    2875           4 :         c2h_data->cccid = tcp_req->req.cmd->nvme_cmd.cid;
    2876           4 :         c2h_data->datal = tcp_req->req.length - tcp_req->pdu->rw_offset;
    2877           4 :         c2h_data->datao = tcp_req->pdu->rw_offset;
    2878             : 
    2879             :         /* set the padding */
    2880           4 :         rsp_pdu->padding_len = 0;
    2881           4 :         pdo = plen;
    2882           4 :         if (tqpair->cpda) {
    2883           0 :                 alignment = (tqpair->cpda + 1) << 2;
    2884           0 :                 if (plen % alignment != 0) {
    2885           0 :                         pdo = (plen + alignment) / alignment * alignment;
    2886           0 :                         rsp_pdu->padding_len = pdo - plen;
    2887           0 :                         plen = pdo;
    2888           0 :                 }
    2889           0 :         }
    2890             : 
    2891           4 :         c2h_data->common.pdo = pdo;
    2892           4 :         plen += c2h_data->datal;
    2893           4 :         if (tqpair->host_ddgst_enable) {
    2894           0 :                 c2h_data->common.flags |= SPDK_NVME_TCP_CH_FLAGS_DDGSTF;
    2895           0 :                 plen += SPDK_NVME_TCP_DIGEST_LEN;
    2896           0 :         }
    2897             : 
    2898           4 :         c2h_data->common.plen = plen;
    2899             : 
    2900           4 :         if (spdk_unlikely(tcp_req->req.dif_enabled)) {
    2901           0 :                 rsp_pdu->dif_ctx = &tcp_req->req.dif.dif_ctx;
    2902           0 :         }
    2903             : 
    2904           8 :         nvme_tcp_pdu_set_data_buf(rsp_pdu, tcp_req->req.iov, tcp_req->req.iovcnt,
    2905           4 :                                   c2h_data->datao, c2h_data->datal);
    2906             : 
    2907             : 
    2908           4 :         c2h_data->common.flags |= SPDK_NVME_TCP_C2H_DATA_FLAGS_LAST_PDU;
    2909             :         /* Need to send the capsule response if response is not all 0 */
    2910           5 :         if (ttransport->tcp_opts.c2h_success &&
    2911           2 :             tcp_req->rsp.cdw0 == 0 && tcp_req->rsp.cdw1 == 0) {
    2912           1 :                 c2h_data->common.flags |= SPDK_NVME_TCP_C2H_DATA_FLAGS_SUCCESS;
    2913           1 :         }
    2914             : 
    2915           4 :         if (spdk_unlikely(tcp_req->req.dif_enabled)) {
    2916           0 :                 struct spdk_nvme_cpl *rsp = &tcp_req->req.rsp->nvme_cpl;
    2917           0 :                 struct spdk_dif_error err_blk = {};
    2918           0 :                 uint32_t mapped_length = 0;
    2919           0 :                 uint32_t available_iovs = SPDK_COUNTOF(rsp_pdu->iov);
    2920           0 :                 uint32_t ddgst_len = 0;
    2921             : 
    2922           0 :                 if (tqpair->host_ddgst_enable) {
    2923             :                         /* Data digest consumes additional iov entry */
    2924           0 :                         available_iovs--;
    2925             :                         /* plen needs to be updated since nvme_tcp_build_iovs compares expected and actual plen */
    2926           0 :                         ddgst_len = SPDK_NVME_TCP_DIGEST_LEN;
    2927           0 :                         c2h_data->common.plen -= ddgst_len;
    2928           0 :                 }
    2929             :                 /* Temp call to estimate if data can be described by limited number of iovs.
    2930             :                  * iov vector will be rebuilt in nvmf_tcp_qpair_write_pdu */
    2931           0 :                 nvme_tcp_build_iovs(rsp_pdu->iov, available_iovs, rsp_pdu, tqpair->host_hdgst_enable,
    2932             :                                     false, &mapped_length);
    2933             : 
    2934           0 :                 if (mapped_length != c2h_data->common.plen) {
    2935           0 :                         c2h_data->datal = mapped_length - (c2h_data->common.plen - c2h_data->datal);
    2936           0 :                         SPDK_DEBUGLOG(nvmf_tcp,
    2937             :                                       "Part C2H, data_len %u (of %u), PDU len %u, updated PDU len %u, offset %u\n",
    2938             :                                       c2h_data->datal, tcp_req->req.length, c2h_data->common.plen, mapped_length, rsp_pdu->rw_offset);
    2939           0 :                         c2h_data->common.plen = mapped_length;
    2940             : 
    2941             :                         /* Rebuild pdu->data_iov since data length is changed */
    2942           0 :                         nvme_tcp_pdu_set_data_buf(rsp_pdu, tcp_req->req.iov, tcp_req->req.iovcnt, c2h_data->datao,
    2943           0 :                                                   c2h_data->datal);
    2944             : 
    2945           0 :                         c2h_data->common.flags &= ~(SPDK_NVME_TCP_C2H_DATA_FLAGS_LAST_PDU |
    2946             :                                                     SPDK_NVME_TCP_C2H_DATA_FLAGS_SUCCESS);
    2947           0 :                 }
    2948             : 
    2949           0 :                 c2h_data->common.plen += ddgst_len;
    2950             : 
    2951           0 :                 assert(rsp_pdu->rw_offset <= tcp_req->req.length);
    2952             : 
    2953           0 :                 rc = spdk_dif_verify_stream(rsp_pdu->data_iov, rsp_pdu->data_iovcnt,
    2954           0 :                                             0, rsp_pdu->data_len, rsp_pdu->dif_ctx, &err_blk);
    2955           0 :                 if (rc != 0) {
    2956           0 :                         SPDK_ERRLOG("DIF error detected. type=%d, offset=%" PRIu32 "\n",
    2957             :                                     err_blk.err_type, err_blk.err_offset);
    2958           0 :                         rsp->status.sct = SPDK_NVME_SCT_MEDIA_ERROR;
    2959           0 :                         rsp->status.sc = nvmf_tcp_dif_error_to_compl_status(err_blk.err_type);
    2960           0 :                         nvmf_tcp_send_capsule_resp_pdu(tcp_req, tqpair);
    2961           0 :                         return;
    2962             :                 }
    2963           0 :         }
    2964             : 
    2965           4 :         rsp_pdu->rw_offset += c2h_data->datal;
    2966           4 :         nvmf_tcp_qpair_write_req_pdu(tqpair, tcp_req, nvmf_tcp_pdu_c2h_data_complete, tcp_req);
    2967           4 : }
    2968             : 
    2969             : static void
    2970           4 : nvmf_tcp_send_c2h_data(struct spdk_nvmf_tcp_qpair *tqpair,
    2971             :                        struct spdk_nvmf_tcp_req *tcp_req)
    2972             : {
    2973           4 :         nvmf_tcp_req_pdu_init(tcp_req);
    2974           4 :         _nvmf_tcp_send_c2h_data(tqpair, tcp_req);
    2975           4 : }
    2976             : 
    2977             : static int
    2978           1 : request_transfer_out(struct spdk_nvmf_request *req)
    2979             : {
    2980             :         struct spdk_nvmf_tcp_req        *tcp_req;
    2981             :         struct spdk_nvmf_qpair          *qpair;
    2982             :         struct spdk_nvmf_tcp_qpair      *tqpair;
    2983             :         struct spdk_nvme_cpl            *rsp;
    2984             : 
    2985           1 :         SPDK_DEBUGLOG(nvmf_tcp, "enter\n");
    2986             : 
    2987           1 :         qpair = req->qpair;
    2988           1 :         rsp = &req->rsp->nvme_cpl;
    2989           1 :         tcp_req = SPDK_CONTAINEROF(req, struct spdk_nvmf_tcp_req, req);
    2990             : 
    2991             :         /* Advance our sq_head pointer */
    2992           1 :         if (qpair->sq_head == qpair->sq_head_max) {
    2993           1 :                 qpair->sq_head = 0;
    2994           1 :         } else {
    2995           0 :                 qpair->sq_head++;
    2996             :         }
    2997           1 :         rsp->sqhd = qpair->sq_head;
    2998             : 
    2999           1 :         tqpair = SPDK_CONTAINEROF(tcp_req->req.qpair, struct spdk_nvmf_tcp_qpair, qpair);
    3000           1 :         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST);
    3001           1 :         if (rsp->status.sc == SPDK_NVME_SC_SUCCESS && req->xfer == SPDK_NVME_DATA_CONTROLLER_TO_HOST) {
    3002           0 :                 nvmf_tcp_send_c2h_data(tqpair, tcp_req);
    3003           0 :         } else {
    3004           1 :                 nvmf_tcp_send_capsule_resp_pdu(tcp_req, tqpair);
    3005             :         }
    3006             : 
    3007           1 :         return 0;
    3008             : }
    3009             : 
    3010             : static void
    3011           4 : nvmf_tcp_check_fused_ordering(struct spdk_nvmf_tcp_transport *ttransport,
    3012             :                               struct spdk_nvmf_tcp_qpair *tqpair,
    3013             :                               struct spdk_nvmf_tcp_req *tcp_req)
    3014             : {
    3015             :         enum spdk_nvme_cmd_fuse last, next;
    3016             : 
    3017           4 :         last = tqpair->fused_first ? tqpair->fused_first->cmd.fuse : SPDK_NVME_CMD_FUSE_NONE;
    3018           4 :         next = tcp_req->cmd.fuse;
    3019             : 
    3020           4 :         assert(last != SPDK_NVME_CMD_FUSE_SECOND);
    3021             : 
    3022           4 :         if (spdk_likely(last == SPDK_NVME_CMD_FUSE_NONE && next == SPDK_NVME_CMD_FUSE_NONE)) {
    3023           4 :                 return;
    3024             :         }
    3025             : 
    3026           0 :         if (last == SPDK_NVME_CMD_FUSE_FIRST) {
    3027           0 :                 if (next == SPDK_NVME_CMD_FUSE_SECOND) {
    3028             :                         /* This is a valid pair of fused commands.  Point them at each other
    3029             :                          * so they can be submitted consecutively once ready to be executed.
    3030             :                          */
    3031           0 :                         tqpair->fused_first->fused_pair = tcp_req;
    3032           0 :                         tcp_req->fused_pair = tqpair->fused_first;
    3033           0 :                         tqpair->fused_first = NULL;
    3034           0 :                         return;
    3035             :                 } else {
    3036             :                         /* Mark the last req as failed since it wasn't followed by a SECOND. */
    3037           0 :                         tqpair->fused_first->fused_failed = true;
    3038             : 
    3039             :                         /*
    3040             :                          * If the last req is in READY_TO_EXECUTE state, then call
    3041             :                          * nvmf_tcp_req_process(), otherwise nothing else will kick it.
    3042             :                          */
    3043           0 :                         if (tqpair->fused_first->state == TCP_REQUEST_STATE_READY_TO_EXECUTE) {
    3044           0 :                                 nvmf_tcp_req_process(ttransport, tqpair->fused_first);
    3045           0 :                         }
    3046             : 
    3047           0 :                         tqpair->fused_first = NULL;
    3048             :                 }
    3049           0 :         }
    3050             : 
    3051           0 :         if (next == SPDK_NVME_CMD_FUSE_FIRST) {
    3052             :                 /* Set tqpair->fused_first here so that we know to check that the next request
    3053             :                  * is a SECOND (and to fail this one if it isn't).
    3054             :                  */
    3055           0 :                 tqpair->fused_first = tcp_req;
    3056           0 :         } else if (next == SPDK_NVME_CMD_FUSE_SECOND) {
    3057             :                 /* Mark this req failed since it is a SECOND and the last one was not a FIRST. */
    3058           0 :                 tcp_req->fused_failed = true;
    3059           0 :         }
    3060           4 : }
    3061             : 
    3062             : static bool
    3063           5 : nvmf_tcp_req_process(struct spdk_nvmf_tcp_transport *ttransport,
    3064             :                      struct spdk_nvmf_tcp_req *tcp_req)
    3065             : {
    3066             :         struct spdk_nvmf_tcp_qpair              *tqpair;
    3067             :         uint32_t                                plen;
    3068             :         struct nvme_tcp_pdu                     *pdu;
    3069             :         enum spdk_nvmf_tcp_req_state            prev_state;
    3070           5 :         bool                                    progress = false;
    3071           5 :         struct spdk_nvmf_transport              *transport = &ttransport->transport;
    3072             :         struct spdk_nvmf_transport_poll_group   *group;
    3073             :         struct spdk_nvmf_tcp_poll_group         *tgroup;
    3074             : 
    3075           5 :         tqpair = SPDK_CONTAINEROF(tcp_req->req.qpair, struct spdk_nvmf_tcp_qpair, qpair);
    3076           5 :         group = &tqpair->group->group;
    3077           5 :         assert(tcp_req->state != TCP_REQUEST_STATE_FREE);
    3078             : 
    3079             :         /* If the qpair is not active, we need to abort the outstanding requests. */
    3080           5 :         if (!spdk_nvmf_qpair_is_active(&tqpair->qpair)) {
    3081           0 :                 if (tcp_req->state == TCP_REQUEST_STATE_NEED_BUFFER) {
    3082           0 :                         nvmf_tcp_request_get_buffers_abort(tcp_req);
    3083           0 :                 }
    3084           0 :                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_COMPLETED);
    3085           0 :         }
    3086             : 
    3087             :         /* The loop here is to allow for several back-to-back state changes. */
    3088           5 :         do {
    3089          13 :                 prev_state = tcp_req->state;
    3090             : 
    3091          13 :                 SPDK_DEBUGLOG(nvmf_tcp, "Request %p entering state %d on tqpair=%p\n", tcp_req, prev_state,
    3092             :                               tqpair);
    3093             : 
    3094          13 :                 switch (tcp_req->state) {
    3095             :                 case TCP_REQUEST_STATE_FREE:
    3096             :                         /* Some external code must kick a request into TCP_REQUEST_STATE_NEW
    3097             :                          * to escape this state. */
    3098           0 :                         break;
    3099             :                 case TCP_REQUEST_STATE_NEW:
    3100           4 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_NEW, tqpair->qpair.trace_id, 0, (uintptr_t)tcp_req,
    3101             :                                           tqpair->qpair.queue_depth);
    3102             : 
    3103             :                         /* copy the cmd from the receive pdu */
    3104           4 :                         tcp_req->cmd = tqpair->pdu_in_progress->hdr.capsule_cmd.ccsqe;
    3105             : 
    3106           4 :                         if (spdk_unlikely(spdk_nvmf_request_get_dif_ctx(&tcp_req->req, &tcp_req->req.dif.dif_ctx))) {
    3107           0 :                                 tcp_req->req.dif_enabled = true;
    3108           0 :                                 tqpair->pdu_in_progress->dif_ctx = &tcp_req->req.dif.dif_ctx;
    3109           0 :                         }
    3110             : 
    3111           4 :                         nvmf_tcp_check_fused_ordering(ttransport, tqpair, tcp_req);
    3112             : 
    3113             :                         /* The next state transition depends on the data transfer needs of this request. */
    3114           4 :                         tcp_req->req.xfer = spdk_nvmf_req_get_xfer(&tcp_req->req);
    3115             : 
    3116           4 :                         if (spdk_unlikely(tcp_req->req.xfer == SPDK_NVME_DATA_BIDIRECTIONAL)) {
    3117           1 :                                 nvmf_tcp_req_set_cpl(tcp_req, SPDK_NVME_SCT_GENERIC, SPDK_NVME_SC_INVALID_OPCODE);
    3118           1 :                                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY);
    3119           1 :                                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_COMPLETE);
    3120           1 :                                 SPDK_DEBUGLOG(nvmf_tcp, "Request %p: invalid xfer type (BIDIRECTIONAL)\n", tcp_req);
    3121           1 :                                 break;
    3122             :                         }
    3123             : 
    3124             :                         /* If no data to transfer, ready to execute. */
    3125           3 :                         if (tcp_req->req.xfer == SPDK_NVME_DATA_NONE) {
    3126             :                                 /* Reset the tqpair receiving pdu state */
    3127           0 :                                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY);
    3128           0 :                                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_EXECUTE);
    3129           0 :                                 break;
    3130             :                         }
    3131             : 
    3132           3 :                         pdu = tqpair->pdu_in_progress;
    3133           3 :                         plen = pdu->hdr.common.hlen;
    3134           3 :                         if (tqpair->host_hdgst_enable) {
    3135           0 :                                 plen += SPDK_NVME_TCP_DIGEST_LEN;
    3136           0 :                         }
    3137           3 :                         if (pdu->hdr.common.plen != plen) {
    3138           3 :                                 tcp_req->has_in_capsule_data = true;
    3139           3 :                         } else {
    3140             :                                 /* Data is transmitted by C2H PDUs */
    3141           0 :                                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_READY);
    3142             :                         }
    3143             : 
    3144           3 :                         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_NEED_BUFFER);
    3145           3 :                         break;
    3146             :                 case TCP_REQUEST_STATE_NEED_BUFFER:
    3147           3 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_NEED_BUFFER, tqpair->qpair.trace_id, 0,
    3148             :                                           (uintptr_t)tcp_req);
    3149             : 
    3150           3 :                         assert(tcp_req->req.xfer != SPDK_NVME_DATA_NONE);
    3151             : 
    3152             :                         /* Try to get a data buffer */
    3153           3 :                         nvmf_tcp_req_parse_sgl(tcp_req, transport, group);
    3154           3 :                         break;
    3155             :                 case TCP_REQUEST_STATE_HAVE_BUFFER:
    3156           2 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_HAVE_BUFFER, tqpair->qpair.trace_id, 0,
    3157             :                                           (uintptr_t)tcp_req);
    3158             :                         /* Get a zcopy buffer if the request can be serviced through zcopy */
    3159           2 :                         if (spdk_nvmf_request_using_zcopy(&tcp_req->req)) {
    3160           0 :                                 if (spdk_unlikely(tcp_req->req.dif_enabled)) {
    3161           0 :                                         assert(tcp_req->req.dif.elba_length >= tcp_req->req.length);
    3162           0 :                                         tcp_req->req.length = tcp_req->req.dif.elba_length;
    3163           0 :                                 }
    3164             : 
    3165           0 :                                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_AWAITING_ZCOPY_START);
    3166           0 :                                 spdk_nvmf_request_zcopy_start(&tcp_req->req);
    3167           0 :                                 break;
    3168             :                         }
    3169             : 
    3170           2 :                         assert(tcp_req->req.iovcnt > 0);
    3171             : 
    3172             :                         /* If data is transferring from host to controller, we need to do a transfer from the host. */
    3173           2 :                         if (tcp_req->req.xfer == SPDK_NVME_DATA_HOST_TO_CONTROLLER) {
    3174           2 :                                 if (tcp_req->req.data_from_pool) {
    3175           0 :                                         SPDK_DEBUGLOG(nvmf_tcp, "Sending R2T for tcp_req(%p) on tqpair=%p\n", tcp_req, tqpair);
    3176           0 :                                         nvmf_tcp_send_r2t_pdu(tqpair, tcp_req);
    3177           0 :                                 } else {
    3178             :                                         struct nvme_tcp_pdu *pdu;
    3179             : 
    3180           2 :                                         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER);
    3181             : 
    3182           2 :                                         pdu = tqpair->pdu_in_progress;
    3183           2 :                                         SPDK_DEBUGLOG(nvmf_tcp, "Not need to send r2t for tcp_req(%p) on tqpair=%p\n", tcp_req,
    3184             :                                                       tqpair);
    3185             :                                         /* No need to send r2t, contained in the capsuled data */
    3186           4 :                                         nvme_tcp_pdu_set_data_buf(pdu, tcp_req->req.iov, tcp_req->req.iovcnt,
    3187           2 :                                                                   0, tcp_req->req.length);
    3188           2 :                                         nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_AWAIT_PDU_PAYLOAD);
    3189             :                                 }
    3190           2 :                                 break;
    3191             :                         }
    3192             : 
    3193           0 :                         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_EXECUTE);
    3194           0 :                         break;
    3195             :                 case TCP_REQUEST_STATE_AWAITING_ZCOPY_START:
    3196           0 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_AWAIT_ZCOPY_START, tqpair->qpair.trace_id, 0,
    3197             :                                           (uintptr_t)tcp_req);
    3198             :                         /* Some external code must kick a request into  TCP_REQUEST_STATE_ZCOPY_START_COMPLETED
    3199             :                          * to escape this state. */
    3200           0 :                         break;
    3201             :                 case TCP_REQUEST_STATE_ZCOPY_START_COMPLETED:
    3202           0 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_ZCOPY_START_COMPLETED, tqpair->qpair.trace_id, 0,
    3203             :                                           (uintptr_t)tcp_req);
    3204           0 :                         if (spdk_unlikely(spdk_nvme_cpl_is_error(&tcp_req->req.rsp->nvme_cpl))) {
    3205           0 :                                 SPDK_DEBUGLOG(nvmf_tcp, "Zero-copy start failed for tcp_req(%p) on tqpair=%p\n",
    3206             :                                               tcp_req, tqpair);
    3207           0 :                                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_COMPLETE);
    3208           0 :                                 break;
    3209             :                         }
    3210           0 :                         if (tcp_req->req.xfer == SPDK_NVME_DATA_HOST_TO_CONTROLLER) {
    3211           0 :                                 SPDK_DEBUGLOG(nvmf_tcp, "Sending R2T for tcp_req(%p) on tqpair=%p\n", tcp_req, tqpair);
    3212           0 :                                 nvmf_tcp_send_r2t_pdu(tqpair, tcp_req);
    3213           0 :                         } else {
    3214           0 :                                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_EXECUTED);
    3215             :                         }
    3216           0 :                         break;
    3217             :                 case TCP_REQUEST_STATE_AWAITING_R2T_ACK:
    3218           0 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_AWAIT_R2T_ACK, tqpair->qpair.trace_id, 0,
    3219             :                                           (uintptr_t)tcp_req);
    3220             :                         /* The R2T completion or the h2c data incoming will kick it out of this state. */
    3221           0 :                         break;
    3222             :                 case TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER:
    3223             : 
    3224           2 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER, tqpair->qpair.trace_id,
    3225             :                                           0, (uintptr_t)tcp_req);
    3226             :                         /* Some external code must kick a request into TCP_REQUEST_STATE_READY_TO_EXECUTE
    3227             :                          * to escape this state. */
    3228           2 :                         break;
    3229             :                 case TCP_REQUEST_STATE_READY_TO_EXECUTE:
    3230           0 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_READY_TO_EXECUTE, tqpair->qpair.trace_id, 0,
    3231             :                                           (uintptr_t)tcp_req);
    3232             : 
    3233           0 :                         if (spdk_unlikely(tcp_req->req.dif_enabled)) {
    3234           0 :                                 assert(tcp_req->req.dif.elba_length >= tcp_req->req.length);
    3235           0 :                                 tcp_req->req.length = tcp_req->req.dif.elba_length;
    3236           0 :                         }
    3237             : 
    3238           0 :                         if (tcp_req->cmd.fuse != SPDK_NVME_CMD_FUSE_NONE) {
    3239           0 :                                 if (tcp_req->fused_failed) {
    3240             :                                         /* This request failed FUSED semantics.  Fail it immediately, without
    3241             :                                          * even sending it to the target layer.
    3242             :                                          */
    3243           0 :                                         nvmf_tcp_req_set_cpl(tcp_req, SPDK_NVME_SCT_GENERIC, SPDK_NVME_SC_ABORTED_MISSING_FUSED);
    3244           0 :                                         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_COMPLETE);
    3245           0 :                                         break;
    3246             :                                 }
    3247             : 
    3248           0 :                                 if (tcp_req->fused_pair == NULL ||
    3249           0 :                                     tcp_req->fused_pair->state != TCP_REQUEST_STATE_READY_TO_EXECUTE) {
    3250             :                                         /* This request is ready to execute, but either we don't know yet if it's
    3251             :                                          * valid - i.e. this is a FIRST but we haven't received the next request yet),
    3252             :                                          * or the other request of this fused pair isn't ready to execute. So
    3253             :                                          * break here and this request will get processed later either when the
    3254             :                                          * other request is ready or we find that this request isn't valid.
    3255             :                                          */
    3256           0 :                                         break;
    3257             :                                 }
    3258           0 :                         }
    3259             : 
    3260           0 :                         if (!spdk_nvmf_request_using_zcopy(&tcp_req->req)) {
    3261           0 :                                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_EXECUTING);
    3262             :                                 /* If we get to this point, and this request is a fused command, we know that
    3263             :                                  * it is part of a valid sequence (FIRST followed by a SECOND) and that both
    3264             :                                  * requests are READY_TO_EXECUTE.  So call spdk_nvmf_request_exec() both on this
    3265             :                                  * request, and the other request of the fused pair, in the correct order.
    3266             :                                  * Also clear the ->fused_pair pointers on both requests, since after this point
    3267             :                                  * we no longer need to maintain the relationship between these two requests.
    3268             :                                  */
    3269           0 :                                 if (tcp_req->cmd.fuse == SPDK_NVME_CMD_FUSE_SECOND) {
    3270           0 :                                         assert(tcp_req->fused_pair != NULL);
    3271           0 :                                         assert(tcp_req->fused_pair->fused_pair == tcp_req);
    3272           0 :                                         nvmf_tcp_req_set_state(tcp_req->fused_pair, TCP_REQUEST_STATE_EXECUTING);
    3273           0 :                                         spdk_nvmf_request_exec(&tcp_req->fused_pair->req);
    3274           0 :                                         tcp_req->fused_pair->fused_pair = NULL;
    3275           0 :                                         tcp_req->fused_pair = NULL;
    3276           0 :                                 }
    3277           0 :                                 spdk_nvmf_request_exec(&tcp_req->req);
    3278           0 :                                 if (tcp_req->cmd.fuse == SPDK_NVME_CMD_FUSE_FIRST) {
    3279           0 :                                         assert(tcp_req->fused_pair != NULL);
    3280           0 :                                         assert(tcp_req->fused_pair->fused_pair == tcp_req);
    3281           0 :                                         nvmf_tcp_req_set_state(tcp_req->fused_pair, TCP_REQUEST_STATE_EXECUTING);
    3282           0 :                                         spdk_nvmf_request_exec(&tcp_req->fused_pair->req);
    3283           0 :                                         tcp_req->fused_pair->fused_pair = NULL;
    3284           0 :                                         tcp_req->fused_pair = NULL;
    3285           0 :                                 }
    3286           0 :                         } else {
    3287             :                                 /* For zero-copy, only requests with data coming from host to the
    3288             :                                  * controller can end up here. */
    3289           0 :                                 assert(tcp_req->req.xfer == SPDK_NVME_DATA_HOST_TO_CONTROLLER);
    3290           0 :                                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_AWAITING_ZCOPY_COMMIT);
    3291           0 :                                 spdk_nvmf_request_zcopy_end(&tcp_req->req, true);
    3292             :                         }
    3293             : 
    3294           0 :                         break;
    3295             :                 case TCP_REQUEST_STATE_EXECUTING:
    3296           0 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_EXECUTING, tqpair->qpair.trace_id, 0, (uintptr_t)tcp_req);
    3297             :                         /* Some external code must kick a request into TCP_REQUEST_STATE_EXECUTED
    3298             :                          * to escape this state. */
    3299           0 :                         break;
    3300             :                 case TCP_REQUEST_STATE_AWAITING_ZCOPY_COMMIT:
    3301           0 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_AWAIT_ZCOPY_COMMIT, tqpair->qpair.trace_id, 0,
    3302             :                                           (uintptr_t)tcp_req);
    3303             :                         /* Some external code must kick a request into TCP_REQUEST_STATE_EXECUTED
    3304             :                          * to escape this state. */
    3305           0 :                         break;
    3306             :                 case TCP_REQUEST_STATE_EXECUTED:
    3307           0 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_EXECUTED, tqpair->qpair.trace_id, 0, (uintptr_t)tcp_req);
    3308             : 
    3309           0 :                         if (spdk_unlikely(tcp_req->req.dif_enabled)) {
    3310           0 :                                 tcp_req->req.length = tcp_req->req.dif.orig_length;
    3311           0 :                         }
    3312             : 
    3313           0 :                         nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_READY_TO_COMPLETE);
    3314           0 :                         break;
    3315             :                 case TCP_REQUEST_STATE_READY_TO_COMPLETE:
    3316           1 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_READY_TO_COMPLETE, tqpair->qpair.trace_id, 0,
    3317             :                                           (uintptr_t)tcp_req);
    3318           1 :                         if (request_transfer_out(&tcp_req->req) != 0) {
    3319           0 :                                 assert(0); /* No good way to handle this currently */
    3320             :                         }
    3321           1 :                         break;
    3322             :                 case TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST:
    3323           1 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_TRANSFERRING_CONTROLLER_TO_HOST, tqpair->qpair.trace_id,
    3324             :                                           0, (uintptr_t)tcp_req);
    3325             :                         /* Some external code must kick a request into TCP_REQUEST_STATE_COMPLETED
    3326             :                          * to escape this state. */
    3327           1 :                         break;
    3328             :                 case TCP_REQUEST_STATE_AWAITING_ZCOPY_RELEASE:
    3329           0 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_AWAIT_ZCOPY_RELEASE, tqpair->qpair.trace_id, 0,
    3330             :                                           (uintptr_t)tcp_req);
    3331             :                         /* Some external code must kick a request into TCP_REQUEST_STATE_COMPLETED
    3332             :                          * to escape this state. */
    3333           0 :                         break;
    3334             :                 case TCP_REQUEST_STATE_COMPLETED:
    3335           0 :                         spdk_trace_record(TRACE_TCP_REQUEST_STATE_COMPLETED, tqpair->qpair.trace_id, 0, (uintptr_t)tcp_req,
    3336             :                                           tqpair->qpair.queue_depth);
    3337             :                         /* If there's an outstanding PDU sent to the host, the request is completed
    3338             :                          * due to the qpair being disconnected.  We must delay the completion until
    3339             :                          * that write is done to avoid freeing the request twice. */
    3340           0 :                         if (spdk_unlikely(tcp_req->pdu_in_use)) {
    3341           0 :                                 SPDK_DEBUGLOG(nvmf_tcp, "Delaying completion due to outstanding "
    3342             :                                               "write on req=%p\n", tcp_req);
    3343             :                                 /* This can only happen for zcopy requests */
    3344           0 :                                 assert(spdk_nvmf_request_using_zcopy(&tcp_req->req));
    3345           0 :                                 assert(!spdk_nvmf_qpair_is_active(&tqpair->qpair));
    3346           0 :                                 break;
    3347             :                         }
    3348             : 
    3349           0 :                         if (tcp_req->req.data_from_pool) {
    3350           0 :                                 spdk_nvmf_request_free_buffers(&tcp_req->req, group, transport);
    3351           0 :                         } else if (spdk_unlikely(tcp_req->has_in_capsule_data &&
    3352             :                                                  (tcp_req->cmd.opc == SPDK_NVME_OPC_FABRIC ||
    3353             :                                                   tqpair->qpair.qid == 0) && tcp_req->req.length > transport->opts.in_capsule_data_size)) {
    3354           0 :                                 tgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_tcp_poll_group, group);
    3355           0 :                                 assert(tgroup->control_msg_list);
    3356           0 :                                 SPDK_DEBUGLOG(nvmf_tcp, "Put buf to control msg list\n");
    3357           0 :                                 nvmf_tcp_control_msg_put(tgroup->control_msg_list,
    3358           0 :                                                          tcp_req->req.iov[0].iov_base);
    3359           0 :                         } else if (tcp_req->req.zcopy_bdev_io != NULL) {
    3360             :                                 /* If the request has an unreleased zcopy bdev_io, it's either a
    3361             :                                  * read, a failed write, or the qpair is being disconnected */
    3362           0 :                                 assert(spdk_nvmf_request_using_zcopy(&tcp_req->req));
    3363           0 :                                 assert(tcp_req->req.xfer == SPDK_NVME_DATA_CONTROLLER_TO_HOST ||
    3364             :                                        spdk_nvme_cpl_is_error(&tcp_req->req.rsp->nvme_cpl) ||
    3365             :                                        !spdk_nvmf_qpair_is_active(&tqpair->qpair));
    3366           0 :                                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_AWAITING_ZCOPY_RELEASE);
    3367           0 :                                 spdk_nvmf_request_zcopy_end(&tcp_req->req, false);
    3368           0 :                                 break;
    3369             :                         }
    3370           0 :                         tcp_req->req.length = 0;
    3371           0 :                         tcp_req->req.iovcnt = 0;
    3372           0 :                         tcp_req->fused_failed = false;
    3373           0 :                         if (tcp_req->fused_pair) {
    3374             :                                 /* This req was part of a valid fused pair, but failed before it got to
    3375             :                                  * READ_TO_EXECUTE state.  This means we need to fail the other request
    3376             :                                  * in the pair, because it is no longer part of a valid pair.  If the pair
    3377             :                                  * already reached READY_TO_EXECUTE state, we need to kick it.
    3378             :                                  */
    3379           0 :                                 tcp_req->fused_pair->fused_failed = true;
    3380           0 :                                 if (tcp_req->fused_pair->state == TCP_REQUEST_STATE_READY_TO_EXECUTE) {
    3381           0 :                                         nvmf_tcp_req_process(ttransport, tcp_req->fused_pair);
    3382           0 :                                 }
    3383           0 :                                 tcp_req->fused_pair = NULL;
    3384           0 :                         }
    3385             : 
    3386           0 :                         nvmf_tcp_req_put(tqpair, tcp_req);
    3387           0 :                         break;
    3388           0 :                 case TCP_REQUEST_NUM_STATES:
    3389             :                 default:
    3390           0 :                         assert(0);
    3391             :                         break;
    3392             :                 }
    3393             : 
    3394          13 :                 if (tcp_req->state != prev_state) {
    3395           8 :                         progress = true;
    3396           8 :                 }
    3397          13 :         } while (tcp_req->state != prev_state);
    3398             : 
    3399           5 :         return progress;
    3400             : }
    3401             : 
    3402             : static void
    3403           0 : nvmf_tcp_qpair_process(struct spdk_nvmf_tcp_qpair *tqpair)
    3404             : {
    3405             :         int rc;
    3406             : 
    3407           0 :         assert(tqpair != NULL);
    3408           0 :         rc = nvmf_tcp_sock_process(tqpair);
    3409             : 
    3410             :         /* If there was a new socket error, disconnect */
    3411           0 :         if (rc < 0) {
    3412           0 :                 nvmf_tcp_qpair_disconnect(tqpair);
    3413           0 :         }
    3414           0 : }
    3415             : 
    3416             : static void
    3417           0 : nvmf_tcp_sock_cb(void *arg, struct spdk_sock_group *group, struct spdk_sock *sock)
    3418             : {
    3419           0 :         struct spdk_nvmf_tcp_qpair *tqpair = arg;
    3420             : 
    3421           0 :         nvmf_tcp_qpair_process(tqpair);
    3422           0 : }
    3423             : 
    3424             : static int
    3425           0 : nvmf_tcp_poll_group_add(struct spdk_nvmf_transport_poll_group *group,
    3426             :                         struct spdk_nvmf_qpair *qpair)
    3427             : {
    3428             :         struct spdk_nvmf_tcp_poll_group *tgroup;
    3429             :         struct spdk_nvmf_tcp_qpair      *tqpair;
    3430             :         int                             rc;
    3431             : 
    3432           0 :         tgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_tcp_poll_group, group);
    3433           0 :         tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
    3434             : 
    3435           0 :         rc =  nvmf_tcp_qpair_sock_init(tqpair);
    3436           0 :         if (rc != 0) {
    3437           0 :                 SPDK_ERRLOG("Cannot set sock opt for tqpair=%p\n", tqpair);
    3438           0 :                 return -1;
    3439             :         }
    3440             : 
    3441           0 :         rc = nvmf_tcp_qpair_init(&tqpair->qpair);
    3442           0 :         if (rc < 0) {
    3443           0 :                 SPDK_ERRLOG("Cannot init tqpair=%p\n", tqpair);
    3444           0 :                 return -1;
    3445             :         }
    3446             : 
    3447           0 :         rc = nvmf_tcp_qpair_init_mem_resource(tqpair);
    3448           0 :         if (rc < 0) {
    3449           0 :                 SPDK_ERRLOG("Cannot init memory resource info for tqpair=%p\n", tqpair);
    3450           0 :                 return -1;
    3451             :         }
    3452             : 
    3453           0 :         rc = spdk_sock_group_add_sock(tgroup->sock_group, tqpair->sock,
    3454           0 :                                       nvmf_tcp_sock_cb, tqpair);
    3455           0 :         if (rc != 0) {
    3456           0 :                 SPDK_ERRLOG("Could not add sock to sock_group: %s (%d)\n",
    3457             :                             spdk_strerror(errno), errno);
    3458           0 :                 return -1;
    3459             :         }
    3460             : 
    3461           0 :         tqpair->group = tgroup;
    3462           0 :         nvmf_tcp_qpair_set_state(tqpair, NVMF_TCP_QPAIR_STATE_INVALID);
    3463           0 :         TAILQ_INSERT_TAIL(&tgroup->qpairs, tqpair, link);
    3464             : 
    3465           0 :         return 0;
    3466           0 : }
    3467             : 
    3468             : static int
    3469           0 : nvmf_tcp_poll_group_remove(struct spdk_nvmf_transport_poll_group *group,
    3470             :                            struct spdk_nvmf_qpair *qpair)
    3471             : {
    3472             :         struct spdk_nvmf_tcp_poll_group *tgroup;
    3473             :         struct spdk_nvmf_tcp_qpair              *tqpair;
    3474             :         int                             rc;
    3475             : 
    3476           0 :         tgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_tcp_poll_group, group);
    3477           0 :         tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
    3478             : 
    3479           0 :         assert(tqpair->group == tgroup);
    3480             : 
    3481           0 :         SPDK_DEBUGLOG(nvmf_tcp, "remove tqpair=%p from the tgroup=%p\n", tqpair, tgroup);
    3482           0 :         if (tqpair->recv_state == NVME_TCP_PDU_RECV_STATE_AWAIT_REQ) {
    3483             :                 /* Change the state to move the qpair from the await_req list to the main list
    3484             :                  * and prevent adding it again later by nvmf_tcp_qpair_set_recv_state() */
    3485           0 :                 nvmf_tcp_qpair_set_recv_state(tqpair, NVME_TCP_PDU_RECV_STATE_QUIESCING);
    3486           0 :         }
    3487           0 :         TAILQ_REMOVE(&tgroup->qpairs, tqpair, link);
    3488             : 
    3489             :         /* Try to force out any pending writes */
    3490           0 :         spdk_sock_flush(tqpair->sock);
    3491             : 
    3492           0 :         rc = spdk_sock_group_remove_sock(tgroup->sock_group, tqpair->sock);
    3493           0 :         if (rc != 0) {
    3494           0 :                 SPDK_ERRLOG("Could not remove sock from sock_group: %s (%d)\n",
    3495             :                             spdk_strerror(errno), errno);
    3496           0 :         }
    3497             : 
    3498           0 :         return rc;
    3499             : }
    3500             : 
    3501             : static int
    3502           0 : nvmf_tcp_req_complete(struct spdk_nvmf_request *req)
    3503             : {
    3504             :         struct spdk_nvmf_tcp_transport *ttransport;
    3505             :         struct spdk_nvmf_tcp_req *tcp_req;
    3506             : 
    3507           0 :         ttransport = SPDK_CONTAINEROF(req->qpair->transport, struct spdk_nvmf_tcp_transport, transport);
    3508           0 :         tcp_req = SPDK_CONTAINEROF(req, struct spdk_nvmf_tcp_req, req);
    3509             : 
    3510           0 :         switch (tcp_req->state) {
    3511             :         case TCP_REQUEST_STATE_EXECUTING:
    3512             :         case TCP_REQUEST_STATE_AWAITING_ZCOPY_COMMIT:
    3513           0 :                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_EXECUTED);
    3514           0 :                 break;
    3515             :         case TCP_REQUEST_STATE_AWAITING_ZCOPY_START:
    3516           0 :                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_ZCOPY_START_COMPLETED);
    3517           0 :                 break;
    3518             :         case TCP_REQUEST_STATE_AWAITING_ZCOPY_RELEASE:
    3519           0 :                 nvmf_tcp_req_set_state(tcp_req, TCP_REQUEST_STATE_COMPLETED);
    3520           0 :                 break;
    3521             :         default:
    3522           0 :                 SPDK_ERRLOG("Unexpected request state %d (cntlid:%d, qid:%d)\n",
    3523             :                             tcp_req->state, req->qpair->ctrlr->cntlid, req->qpair->qid);
    3524           0 :                 assert(0 && "Unexpected request state");
    3525             :                 break;
    3526             :         }
    3527             : 
    3528           0 :         nvmf_tcp_req_process(ttransport, tcp_req);
    3529             : 
    3530           0 :         return 0;
    3531             : }
    3532             : 
    3533             : static void
    3534           0 : nvmf_tcp_close_qpair(struct spdk_nvmf_qpair *qpair,
    3535             :                      spdk_nvmf_transport_qpair_fini_cb cb_fn, void *cb_arg)
    3536             : {
    3537             :         struct spdk_nvmf_tcp_qpair *tqpair;
    3538             : 
    3539           0 :         SPDK_DEBUGLOG(nvmf_tcp, "Qpair: %p\n", qpair);
    3540             : 
    3541           0 :         tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
    3542             : 
    3543           0 :         assert(tqpair->fini_cb_fn == NULL);
    3544           0 :         tqpair->fini_cb_fn = cb_fn;
    3545           0 :         tqpair->fini_cb_arg = cb_arg;
    3546             : 
    3547           0 :         nvmf_tcp_qpair_set_state(tqpair, NVMF_TCP_QPAIR_STATE_EXITED);
    3548           0 :         nvmf_tcp_qpair_destroy(tqpair);
    3549           0 : }
    3550             : 
    3551             : static int
    3552           0 : nvmf_tcp_poll_group_poll(struct spdk_nvmf_transport_poll_group *group)
    3553             : {
    3554             :         struct spdk_nvmf_tcp_poll_group *tgroup;
    3555             :         int num_events;
    3556             : 
    3557           0 :         tgroup = SPDK_CONTAINEROF(group, struct spdk_nvmf_tcp_poll_group, group);
    3558             : 
    3559           0 :         if (spdk_unlikely(TAILQ_EMPTY(&tgroup->qpairs))) {
    3560           0 :                 return 0;
    3561             :         }
    3562             : 
    3563           0 :         num_events = spdk_sock_group_poll(tgroup->sock_group);
    3564           0 :         if (spdk_unlikely(num_events < 0)) {
    3565           0 :                 SPDK_ERRLOG("Failed to poll sock_group=%p\n", tgroup->sock_group);
    3566           0 :         }
    3567             : 
    3568           0 :         return num_events;
    3569           0 : }
    3570             : 
    3571             : static int
    3572           0 : nvmf_tcp_qpair_get_trid(struct spdk_nvmf_qpair *qpair,
    3573             :                         struct spdk_nvme_transport_id *trid, bool peer)
    3574             : {
    3575             :         struct spdk_nvmf_tcp_qpair     *tqpair;
    3576             :         uint16_t                        port;
    3577             : 
    3578           0 :         tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
    3579           0 :         spdk_nvme_trid_populate_transport(trid, SPDK_NVME_TRANSPORT_TCP);
    3580             : 
    3581           0 :         if (peer) {
    3582           0 :                 snprintf(trid->traddr, sizeof(trid->traddr), "%s", tqpair->initiator_addr);
    3583           0 :                 port = tqpair->initiator_port;
    3584           0 :         } else {
    3585           0 :                 snprintf(trid->traddr, sizeof(trid->traddr), "%s", tqpair->target_addr);
    3586           0 :                 port = tqpair->target_port;
    3587             :         }
    3588             : 
    3589           0 :         if (spdk_sock_is_ipv4(tqpair->sock)) {
    3590           0 :                 trid->adrfam = SPDK_NVMF_ADRFAM_IPV4;
    3591           0 :         } else if (spdk_sock_is_ipv6(tqpair->sock)) {
    3592           0 :                 trid->adrfam = SPDK_NVMF_ADRFAM_IPV6;
    3593           0 :         } else {
    3594           0 :                 return -1;
    3595             :         }
    3596             : 
    3597           0 :         snprintf(trid->trsvcid, sizeof(trid->trsvcid), "%d", port);
    3598           0 :         return 0;
    3599           0 : }
    3600             : 
    3601             : static int
    3602           0 : nvmf_tcp_qpair_get_local_trid(struct spdk_nvmf_qpair *qpair,
    3603             :                               struct spdk_nvme_transport_id *trid)
    3604             : {
    3605           0 :         return nvmf_tcp_qpair_get_trid(qpair, trid, 0);
    3606             : }
    3607             : 
    3608             : static int
    3609           0 : nvmf_tcp_qpair_get_peer_trid(struct spdk_nvmf_qpair *qpair,
    3610             :                              struct spdk_nvme_transport_id *trid)
    3611             : {
    3612           0 :         return nvmf_tcp_qpair_get_trid(qpair, trid, 1);
    3613             : }
    3614             : 
    3615             : static int
    3616           0 : nvmf_tcp_qpair_get_listen_trid(struct spdk_nvmf_qpair *qpair,
    3617             :                                struct spdk_nvme_transport_id *trid)
    3618             : {
    3619           0 :         return nvmf_tcp_qpair_get_trid(qpair, trid, 0);
    3620             : }
    3621             : 
    3622             : static void
    3623           0 : nvmf_tcp_req_set_abort_status(struct spdk_nvmf_request *req,
    3624             :                               struct spdk_nvmf_tcp_req *tcp_req_to_abort)
    3625             : {
    3626           0 :         nvmf_tcp_req_set_cpl(tcp_req_to_abort, SPDK_NVME_SCT_GENERIC, SPDK_NVME_SC_ABORTED_BY_REQUEST);
    3627           0 :         nvmf_tcp_req_set_state(tcp_req_to_abort, TCP_REQUEST_STATE_READY_TO_COMPLETE);
    3628             : 
    3629           0 :         req->rsp->nvme_cpl.cdw0 &= ~1U; /* Command was successfully aborted. */
    3630           0 : }
    3631             : 
    3632             : static int
    3633           0 : _nvmf_tcp_qpair_abort_request(void *ctx)
    3634             : {
    3635           0 :         struct spdk_nvmf_request *req = ctx;
    3636           0 :         struct spdk_nvmf_tcp_req *tcp_req_to_abort = SPDK_CONTAINEROF(req->req_to_abort,
    3637             :                         struct spdk_nvmf_tcp_req, req);
    3638           0 :         struct spdk_nvmf_tcp_qpair *tqpair = SPDK_CONTAINEROF(req->req_to_abort->qpair,
    3639             :                                              struct spdk_nvmf_tcp_qpair, qpair);
    3640           0 :         struct spdk_nvmf_tcp_transport *ttransport = SPDK_CONTAINEROF(tqpair->qpair.transport,
    3641             :                         struct spdk_nvmf_tcp_transport, transport);
    3642             :         int rc;
    3643             : 
    3644           0 :         spdk_poller_unregister(&req->poller);
    3645             : 
    3646           0 :         switch (tcp_req_to_abort->state) {
    3647             :         case TCP_REQUEST_STATE_EXECUTING:
    3648             :         case TCP_REQUEST_STATE_AWAITING_ZCOPY_START:
    3649             :         case TCP_REQUEST_STATE_AWAITING_ZCOPY_COMMIT:
    3650           0 :                 rc = nvmf_ctrlr_abort_request(req);
    3651           0 :                 if (rc == SPDK_NVMF_REQUEST_EXEC_STATUS_ASYNCHRONOUS) {
    3652           0 :                         return SPDK_POLLER_BUSY;
    3653             :                 }
    3654           0 :                 break;
    3655             : 
    3656             :         case TCP_REQUEST_STATE_NEED_BUFFER:
    3657           0 :                 nvmf_tcp_request_get_buffers_abort(tcp_req_to_abort);
    3658           0 :                 nvmf_tcp_req_set_abort_status(req, tcp_req_to_abort);
    3659           0 :                 nvmf_tcp_req_process(ttransport, tcp_req_to_abort);
    3660           0 :                 break;
    3661             : 
    3662             :         case TCP_REQUEST_STATE_AWAITING_R2T_ACK:
    3663             :         case TCP_REQUEST_STATE_TRANSFERRING_HOST_TO_CONTROLLER:
    3664           0 :                 if (spdk_get_ticks() < req->timeout_tsc) {
    3665           0 :                         req->poller = SPDK_POLLER_REGISTER(_nvmf_tcp_qpair_abort_request, req, 0);
    3666           0 :                         return SPDK_POLLER_BUSY;
    3667             :                 }
    3668           0 :                 break;
    3669             : 
    3670             :         default:
    3671             :                 /* Requests in other states are either un-abortable (e.g.
    3672             :                  * TRANSFERRING_CONTROLLER_TO_HOST) or should never end up here, as they're
    3673             :                  * immediately transitioned to other states in nvmf_tcp_req_process() (e.g.
    3674             :                  * READY_TO_EXECUTE).  But it is fine to end up here, as we'll simply complete the
    3675             :                  * abort request with the bit0 of dword0 set (command not aborted).
    3676             :                  */
    3677           0 :                 break;
    3678             :         }
    3679             : 
    3680           0 :         spdk_nvmf_request_complete(req);
    3681           0 :         return SPDK_POLLER_BUSY;
    3682           0 : }
    3683             : 
    3684             : static void
    3685           0 : nvmf_tcp_qpair_abort_request(struct spdk_nvmf_qpair *qpair,
    3686             :                              struct spdk_nvmf_request *req)
    3687             : {
    3688             :         struct spdk_nvmf_tcp_qpair *tqpair;
    3689             :         struct spdk_nvmf_tcp_transport *ttransport;
    3690             :         struct spdk_nvmf_transport *transport;
    3691             :         uint16_t cid;
    3692             :         uint32_t i;
    3693           0 :         struct spdk_nvmf_tcp_req *tcp_req_to_abort = NULL;
    3694             : 
    3695           0 :         tqpair = SPDK_CONTAINEROF(qpair, struct spdk_nvmf_tcp_qpair, qpair);
    3696           0 :         ttransport = SPDK_CONTAINEROF(qpair->transport, struct spdk_nvmf_tcp_transport, transport);
    3697           0 :         transport = &ttransport->transport;
    3698             : 
    3699           0 :         cid = req->cmd->nvme_cmd.cdw10_bits.abort.cid;
    3700             : 
    3701           0 :         for (i = 0; i < tqpair->resource_count; i++) {
    3702           0 :                 if (tqpair->reqs[i].state != TCP_REQUEST_STATE_FREE &&
    3703           0 :                     tqpair->reqs[i].req.cmd->nvme_cmd.cid == cid) {
    3704           0 :                         tcp_req_to_abort = &tqpair->reqs[i];
    3705           0 :                         break;
    3706             :                 }
    3707           0 :         }
    3708             : 
    3709           0 :         spdk_trace_record(TRACE_TCP_QP_ABORT_REQ, tqpair->qpair.trace_id, 0, (uintptr_t)req);
    3710             : 
    3711           0 :         if (tcp_req_to_abort == NULL) {
    3712           0 :                 spdk_nvmf_request_complete(req);
    3713           0 :                 return;
    3714             :         }
    3715             : 
    3716           0 :         req->req_to_abort = &tcp_req_to_abort->req;
    3717           0 :         req->timeout_tsc = spdk_get_ticks() +
    3718           0 :                            transport->opts.abort_timeout_sec * spdk_get_ticks_hz();
    3719           0 :         req->poller = NULL;
    3720             : 
    3721           0 :         _nvmf_tcp_qpair_abort_request(req);
    3722           0 : }
    3723             : 
    3724             : struct tcp_subsystem_add_host_opts {
    3725             :         char *psk;
    3726             : };
    3727             : 
    3728             : static const struct spdk_json_object_decoder tcp_subsystem_add_host_opts_decoder[] = {
    3729             :         {"psk", offsetof(struct tcp_subsystem_add_host_opts, psk), spdk_json_decode_string, true},
    3730             : };
    3731             : 
    3732             : static int
    3733           1 : nvmf_tcp_subsystem_add_host(struct spdk_nvmf_transport *transport,
    3734             :                             const struct spdk_nvmf_subsystem *subsystem,
    3735             :                             const char *hostnqn,
    3736             :                             const struct spdk_json_val *transport_specific)
    3737             : {
    3738             :         struct tcp_subsystem_add_host_opts opts;
    3739             :         struct spdk_nvmf_tcp_transport *ttransport;
    3740           1 :         struct tcp_psk_entry *tmp, *entry = NULL;
    3741           1 :         uint8_t psk_configured[SPDK_TLS_PSK_MAX_LEN] = {};
    3742           1 :         char psk_interchange[SPDK_TLS_PSK_MAX_LEN + 1] = {};
    3743             :         uint8_t tls_cipher_suite;
    3744           1 :         int rc = 0;
    3745             :         uint8_t psk_retained_hash;
    3746             :         uint64_t psk_configured_size;
    3747             : 
    3748           1 :         if (transport_specific == NULL) {
    3749           0 :                 return 0;
    3750             :         }
    3751             : 
    3752           1 :         assert(transport != NULL);
    3753           1 :         assert(subsystem != NULL);
    3754             : 
    3755           1 :         memset(&opts, 0, sizeof(opts));
    3756             : 
    3757             :         /* Decode PSK (either name of a key or file path) */
    3758           1 :         if (spdk_json_decode_object_relaxed(transport_specific, tcp_subsystem_add_host_opts_decoder,
    3759             :                                             SPDK_COUNTOF(tcp_subsystem_add_host_opts_decoder), &opts)) {
    3760           0 :                 SPDK_ERRLOG("spdk_json_decode_object failed\n");
    3761           0 :                 return -EINVAL;
    3762             :         }
    3763             : 
    3764           1 :         if (opts.psk == NULL) {
    3765           0 :                 return 0;
    3766             :         }
    3767             : 
    3768           1 :         entry = calloc(1, sizeof(struct tcp_psk_entry));
    3769           1 :         if (entry == NULL) {
    3770           0 :                 SPDK_ERRLOG("Unable to allocate memory for PSK entry!\n");
    3771           0 :                 rc = -ENOMEM;
    3772           0 :                 goto end;
    3773             :         }
    3774             : 
    3775           1 :         entry->key = spdk_keyring_get_key(opts.psk);
    3776           1 :         if (entry->key == NULL) {
    3777           0 :                 SPDK_ERRLOG("Key '%s' does not exist\n", opts.psk);
    3778           0 :                 rc = -EINVAL;
    3779           0 :                 goto end;
    3780             :         }
    3781             : 
    3782           1 :         rc = spdk_key_get_key(entry->key, psk_interchange, SPDK_TLS_PSK_MAX_LEN);
    3783           1 :         if (rc < 0) {
    3784           0 :                 SPDK_ERRLOG("Failed to retrieve PSK '%s'\n", opts.psk);
    3785           0 :                 rc = -EINVAL;
    3786           0 :                 goto end;
    3787             :         }
    3788             : 
    3789             :         /* Parse PSK interchange to get length of base64 encoded data.
    3790             :          * This is then used to decide which cipher suite should be used
    3791             :          * to generate PSK identity and TLS PSK later on. */
    3792           1 :         rc = nvme_tcp_parse_interchange_psk(psk_interchange, psk_configured, sizeof(psk_configured),
    3793             :                                             &psk_configured_size, &psk_retained_hash);
    3794           1 :         if (rc < 0) {
    3795           0 :                 SPDK_ERRLOG("Failed to parse PSK interchange!\n");
    3796           0 :                 goto end;
    3797             :         }
    3798             : 
    3799             :         /* The Base64 string encodes the configured PSK (32 or 48 bytes binary).
    3800             :          * This check also ensures that psk_configured_size is smaller than
    3801             :          * psk_retained buffer size. */
    3802           1 :         if (psk_configured_size == SHA256_DIGEST_LENGTH) {
    3803           1 :                 tls_cipher_suite = NVME_TCP_CIPHER_AES_128_GCM_SHA256;
    3804           1 :         } else if (psk_configured_size == SHA384_DIGEST_LENGTH) {
    3805           0 :                 tls_cipher_suite = NVME_TCP_CIPHER_AES_256_GCM_SHA384;
    3806           0 :         } else {
    3807           0 :                 SPDK_ERRLOG("Unrecognized cipher suite!\n");
    3808           0 :                 rc = -EINVAL;
    3809           0 :                 goto end;
    3810             :         }
    3811             : 
    3812           1 :         ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
    3813             :         /* Generate PSK identity. */
    3814           2 :         rc = nvme_tcp_generate_psk_identity(entry->pskid, sizeof(entry->pskid), hostnqn,
    3815           1 :                                             subsystem->subnqn, tls_cipher_suite);
    3816           1 :         if (rc) {
    3817           0 :                 rc = -EINVAL;
    3818           0 :                 goto end;
    3819             :         }
    3820             :         /* Check if PSK identity entry already exists. */
    3821           1 :         TAILQ_FOREACH(tmp, &ttransport->psks, link) {
    3822           0 :                 if (strncmp(tmp->pskid, entry->pskid, NVMF_PSK_IDENTITY_LEN) == 0) {
    3823           0 :                         SPDK_ERRLOG("Given PSK identity: %s entry already exists!\n", entry->pskid);
    3824           0 :                         rc = -EEXIST;
    3825           0 :                         goto end;
    3826             :                 }
    3827           0 :         }
    3828             : 
    3829           1 :         if (snprintf(entry->hostnqn, sizeof(entry->hostnqn), "%s", hostnqn) < 0) {
    3830           0 :                 SPDK_ERRLOG("Could not write hostnqn string!\n");
    3831           0 :                 rc = -EINVAL;
    3832           0 :                 goto end;
    3833             :         }
    3834           1 :         if (snprintf(entry->subnqn, sizeof(entry->subnqn), "%s", subsystem->subnqn) < 0) {
    3835           0 :                 SPDK_ERRLOG("Could not write subnqn string!\n");
    3836           0 :                 rc = -EINVAL;
    3837           0 :                 goto end;
    3838             :         }
    3839             : 
    3840           1 :         entry->tls_cipher_suite = tls_cipher_suite;
    3841             : 
    3842             :         /* No hash indicates that Configured PSK must be used as Retained PSK. */
    3843           1 :         if (psk_retained_hash == NVME_TCP_HASH_ALGORITHM_NONE) {
    3844             :                 /* Psk configured is either 32 or 48 bytes long. */
    3845           0 :                 memcpy(entry->psk, psk_configured, psk_configured_size);
    3846           0 :                 entry->psk_size = psk_configured_size;
    3847           0 :         } else {
    3848             :                 /* Derive retained PSK. */
    3849           2 :                 rc = nvme_tcp_derive_retained_psk(psk_configured, psk_configured_size, hostnqn, entry->psk,
    3850           1 :                                                   SPDK_TLS_PSK_MAX_LEN, psk_retained_hash);
    3851           1 :                 if (rc < 0) {
    3852           0 :                         SPDK_ERRLOG("Unable to derive retained PSK!\n");
    3853           0 :                         goto end;
    3854             :                 }
    3855           1 :                 entry->psk_size = rc;
    3856             :         }
    3857             : 
    3858           1 :         TAILQ_INSERT_TAIL(&ttransport->psks, entry, link);
    3859           1 :         rc = 0;
    3860             : 
    3861             : end:
    3862           1 :         spdk_memset_s(psk_configured, sizeof(psk_configured), 0, sizeof(psk_configured));
    3863           1 :         spdk_memset_s(psk_interchange, sizeof(psk_interchange), 0, sizeof(psk_interchange));
    3864             : 
    3865           1 :         free(opts.psk);
    3866           1 :         if (rc != 0) {
    3867           0 :                 nvmf_tcp_free_psk_entry(entry);
    3868           0 :         }
    3869             : 
    3870           1 :         return rc;
    3871           1 : }
    3872             : 
    3873             : static void
    3874           1 : nvmf_tcp_subsystem_remove_host(struct spdk_nvmf_transport *transport,
    3875             :                                const struct spdk_nvmf_subsystem *subsystem,
    3876             :                                const char *hostnqn)
    3877             : {
    3878             :         struct spdk_nvmf_tcp_transport *ttransport;
    3879             :         struct tcp_psk_entry *entry, *tmp;
    3880             : 
    3881           1 :         assert(transport != NULL);
    3882           1 :         assert(subsystem != NULL);
    3883             : 
    3884           1 :         ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
    3885           1 :         TAILQ_FOREACH_SAFE(entry, &ttransport->psks, link, tmp) {
    3886           1 :                 if ((strncmp(entry->hostnqn, hostnqn, SPDK_NVMF_NQN_MAX_LEN)) == 0 &&
    3887           1 :                     (strncmp(entry->subnqn, subsystem->subnqn, SPDK_NVMF_NQN_MAX_LEN)) == 0) {
    3888           1 :                         TAILQ_REMOVE(&ttransport->psks, entry, link);
    3889           1 :                         nvmf_tcp_free_psk_entry(entry);
    3890           1 :                         break;
    3891             :                 }
    3892           0 :         }
    3893           1 : }
    3894             : 
    3895             : static void
    3896           0 : nvmf_tcp_subsystem_dump_host(struct spdk_nvmf_transport *transport,
    3897             :                              const struct spdk_nvmf_subsystem *subsystem, const char *hostnqn,
    3898             :                              struct spdk_json_write_ctx *w)
    3899             : {
    3900             :         struct spdk_nvmf_tcp_transport *ttransport;
    3901             :         struct tcp_psk_entry *entry;
    3902             : 
    3903           0 :         assert(transport != NULL);
    3904           0 :         assert(subsystem != NULL);
    3905             : 
    3906           0 :         ttransport = SPDK_CONTAINEROF(transport, struct spdk_nvmf_tcp_transport, transport);
    3907           0 :         TAILQ_FOREACH(entry, &ttransport->psks, link) {
    3908           0 :                 if ((strncmp(entry->hostnqn, hostnqn, SPDK_NVMF_NQN_MAX_LEN)) == 0 &&
    3909           0 :                     (strncmp(entry->subnqn, subsystem->subnqn, SPDK_NVMF_NQN_MAX_LEN)) == 0) {
    3910           0 :                         spdk_json_write_named_string(w, "psk",  spdk_key_get_name(entry->key));
    3911           0 :                         break;
    3912             :                 }
    3913           0 :         }
    3914           0 : }
    3915             : 
    3916             : static void
    3917           1 : nvmf_tcp_opts_init(struct spdk_nvmf_transport_opts *opts)
    3918             : {
    3919           1 :         opts->max_queue_depth =              SPDK_NVMF_TCP_DEFAULT_MAX_IO_QUEUE_DEPTH;
    3920           1 :         opts->max_qpairs_per_ctrlr = SPDK_NVMF_TCP_DEFAULT_MAX_QPAIRS_PER_CTRLR;
    3921           1 :         opts->in_capsule_data_size = SPDK_NVMF_TCP_DEFAULT_IN_CAPSULE_DATA_SIZE;
    3922           1 :         opts->max_io_size =          SPDK_NVMF_TCP_DEFAULT_MAX_IO_SIZE;
    3923           1 :         opts->io_unit_size =         SPDK_NVMF_TCP_DEFAULT_IO_UNIT_SIZE;
    3924           1 :         opts->max_aq_depth =         SPDK_NVMF_TCP_DEFAULT_MAX_ADMIN_QUEUE_DEPTH;
    3925           1 :         opts->num_shared_buffers =   SPDK_NVMF_TCP_DEFAULT_NUM_SHARED_BUFFERS;
    3926           1 :         opts->buf_cache_size =               SPDK_NVMF_TCP_DEFAULT_BUFFER_CACHE_SIZE;
    3927           1 :         opts->dif_insert_or_strip =  SPDK_NVMF_TCP_DEFAULT_DIF_INSERT_OR_STRIP;
    3928           1 :         opts->abort_timeout_sec =    SPDK_NVMF_TCP_DEFAULT_ABORT_TIMEOUT_SEC;
    3929           1 :         opts->transport_specific =      NULL;
    3930           1 : }
    3931             : 
    3932             : const struct spdk_nvmf_transport_ops spdk_nvmf_transport_tcp = {
    3933             :         .name = "TCP",
    3934             :         .type = SPDK_NVME_TRANSPORT_TCP,
    3935             :         .opts_init = nvmf_tcp_opts_init,
    3936             :         .create = nvmf_tcp_create,
    3937             :         .dump_opts = nvmf_tcp_dump_opts,
    3938             :         .destroy = nvmf_tcp_destroy,
    3939             : 
    3940             :         .listen = nvmf_tcp_listen,
    3941             :         .stop_listen = nvmf_tcp_stop_listen,
    3942             : 
    3943             :         .listener_discover = nvmf_tcp_discover,
    3944             : 
    3945             :         .poll_group_create = nvmf_tcp_poll_group_create,
    3946             :         .get_optimal_poll_group = nvmf_tcp_get_optimal_poll_group,
    3947             :         .poll_group_destroy = nvmf_tcp_poll_group_destroy,
    3948             :         .poll_group_add = nvmf_tcp_poll_group_add,
    3949             :         .poll_group_remove = nvmf_tcp_poll_group_remove,
    3950             :         .poll_group_poll = nvmf_tcp_poll_group_poll,
    3951             : 
    3952             :         .req_free = nvmf_tcp_req_free,
    3953             :         .req_complete = nvmf_tcp_req_complete,
    3954             :         .req_get_buffers_done = nvmf_tcp_req_get_buffers_done,
    3955             : 
    3956             :         .qpair_fini = nvmf_tcp_close_qpair,
    3957             :         .qpair_get_local_trid = nvmf_tcp_qpair_get_local_trid,
    3958             :         .qpair_get_peer_trid = nvmf_tcp_qpair_get_peer_trid,
    3959             :         .qpair_get_listen_trid = nvmf_tcp_qpair_get_listen_trid,
    3960             :         .qpair_abort_request = nvmf_tcp_qpair_abort_request,
    3961             :         .subsystem_add_host = nvmf_tcp_subsystem_add_host,
    3962             :         .subsystem_remove_host = nvmf_tcp_subsystem_remove_host,
    3963             :         .subsystem_dump_host = nvmf_tcp_subsystem_dump_host,
    3964             : };
    3965             : 
    3966           1 : SPDK_NVMF_TRANSPORT_REGISTER(tcp, &spdk_nvmf_transport_tcp);
    3967           1 : SPDK_LOG_REGISTER_COMPONENT(nvmf_tcp)

Generated by: LCOV version 1.15