// SPDX-License-Identifier: GPL-2.0 or BSD-3-Clause /* Authors: Bernard Metzler */ /* Fredy Neeser */ /* Greg Joyce */ /* Copyright (c) 2008-2019, IBM Corporation */ /* Copyright (c) 2017, Open Grid Computing, Inc. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "siw.h" #include "siw_cm.h" /* * Set to any combination of * MPA_V2_RDMA_NO_RTR, MPA_V2_RDMA_READ_RTR, MPA_V2_RDMA_WRITE_RTR */ static __be16 rtr_type = MPA_V2_RDMA_READ_RTR | MPA_V2_RDMA_WRITE_RTR; static const bool relaxed_ird_negotiation = true; static void siw_cm_llp_state_change(struct sock *s); static void siw_cm_llp_data_ready(struct sock *s); static void siw_cm_llp_write_space(struct sock *s); static void siw_cm_llp_error_report(struct sock *s); static int siw_cm_upcall(struct siw_cep *cep, enum iw_cm_event_type reason, int status); static void siw_sk_assign_cm_upcalls(struct sock *sk) { write_lock_bh(&sk->sk_callback_lock); sk->sk_state_change = siw_cm_llp_state_change; sk->sk_data_ready = siw_cm_llp_data_ready; sk->sk_write_space = siw_cm_llp_write_space; sk->sk_error_report = siw_cm_llp_error_report; write_unlock_bh(&sk->sk_callback_lock); } static void siw_sk_save_upcalls(struct sock *sk) { struct siw_cep *cep = sk_to_cep(sk); write_lock_bh(&sk->sk_callback_lock); cep->sk_state_change = sk->sk_state_change; cep->sk_data_ready = sk->sk_data_ready; cep->sk_write_space = sk->sk_write_space; cep->sk_error_report = sk->sk_error_report; write_unlock_bh(&sk->sk_callback_lock); } static void siw_sk_restore_upcalls(struct sock *sk, struct siw_cep *cep) { sk->sk_state_change = cep->sk_state_change; sk->sk_data_ready = cep->sk_data_ready; sk->sk_write_space = cep->sk_write_space; sk->sk_error_report = cep->sk_error_report; sk->sk_user_data = NULL; } static void siw_qp_socket_assoc(struct siw_cep *cep, struct siw_qp *qp) { struct socket *s = cep->sock; struct sock *sk = s->sk; write_lock_bh(&sk->sk_callback_lock); qp->attrs.sk = s; sk->sk_data_ready = siw_qp_llp_data_ready; sk->sk_write_space = siw_qp_llp_write_space; write_unlock_bh(&sk->sk_callback_lock); } static void siw_socket_disassoc(struct socket *s) { struct sock *sk = s->sk; struct siw_cep *cep; if (sk) { write_lock_bh(&sk->sk_callback_lock); cep = sk_to_cep(sk); if (cep) { siw_sk_restore_upcalls(sk, cep); siw_cep_put(cep); } else { pr_warn("siw: cannot restore sk callbacks: no ep\n"); } write_unlock_bh(&sk->sk_callback_lock); } else { pr_warn("siw: cannot restore sk callbacks: no sk\n"); } } static void siw_rtr_data_ready(struct sock *sk) { struct siw_cep *cep; struct siw_qp *qp = NULL; read_descriptor_t rd_desc; read_lock(&sk->sk_callback_lock); cep = sk_to_cep(sk); if (!cep) { WARN(1, "No connection endpoint\n"); goto out; } qp = sk_to_qp(sk); memset(&rd_desc, 0, sizeof(rd_desc)); rd_desc.arg.data = qp; rd_desc.count = 1; tcp_read_sock(sk, &rd_desc, siw_tcp_rx_data); /* * Check if first frame was successfully processed. * Signal connection full establishment if yes. * Failed data processing would have already scheduled * connection drop. */ if (!qp->rx_stream.rx_suspend) siw_cm_upcall(cep, IW_CM_EVENT_ESTABLISHED, 0); out: read_unlock(&sk->sk_callback_lock); if (qp) siw_qp_socket_assoc(cep, qp); } static void siw_sk_assign_rtr_upcalls(struct siw_cep *cep) { struct sock *sk = cep->sock->sk; write_lock_bh(&sk->sk_callback_lock); sk->sk_data_ready = siw_rtr_data_ready; sk->sk_write_space = siw_qp_llp_write_space; write_unlock_bh(&sk->sk_callback_lock); } static void siw_cep_socket_assoc(struct siw_cep *cep, struct socket *s) { cep->sock = s; siw_cep_get(cep); s->sk->sk_user_data = cep; siw_sk_save_upcalls(s->sk); siw_sk_assign_cm_upcalls(s->sk); } static struct siw_cep *siw_cep_alloc(struct siw_device *sdev) { struct siw_cep *cep = kzalloc(sizeof(*cep), GFP_KERNEL); unsigned long flags; if (!cep) return NULL; INIT_LIST_HEAD(&cep->listenq); INIT_LIST_HEAD(&cep->devq); INIT_LIST_HEAD(&cep->work_freelist); kref_init(&cep->ref); cep->state = SIW_EPSTATE_IDLE; init_waitqueue_head(&cep->waitq); spin_lock_init(&cep->lock); cep->sdev = sdev; cep->enhanced_rdma_conn_est = false; spin_lock_irqsave(&sdev->lock, flags); list_add_tail(&cep->devq, &sdev->cep_list); spin_unlock_irqrestore(&sdev->lock, flags); siw_dbg_cep(cep, "new endpoint\n"); return cep; } static void siw_cm_free_work(struct siw_cep *cep) { struct list_head *w, *tmp; struct siw_cm_work *work; list_for_each_safe(w, tmp, &cep->work_freelist) { work = list_entry(w, struct siw_cm_work, list); list_del(&work->list); kfree(work); } } static void siw_cancel_mpatimer(struct siw_cep *cep) { spin_lock_bh(&cep->lock); if (cep->mpa_timer) { if (cancel_delayed_work(&cep->mpa_timer->work)) { siw_cep_put(cep); kfree(cep->mpa_timer); /* not needed again */ } cep->mpa_timer = NULL; } spin_unlock_bh(&cep->lock); } static void siw_put_work(struct siw_cm_work *work) { INIT_LIST_HEAD(&work->list); spin_lock_bh(&work->cep->lock); list_add(&work->list, &work->cep->work_freelist); spin_unlock_bh(&work->cep->lock); } static void siw_cep_set_inuse(struct siw_cep *cep) { unsigned long flags; retry: spin_lock_irqsave(&cep->lock, flags); if (cep->in_use) { spin_unlock_irqrestore(&cep->lock, flags); wait_event_interruptible(cep->waitq, !cep->in_use); if (signal_pending(current)) flush_signals(current); goto retry; } else { cep->in_use = 1; spin_unlock_irqrestore(&cep->lock, flags); } } static void siw_cep_set_free(struct siw_cep *cep) { unsigned long flags; spin_lock_irqsave(&cep->lock, flags); cep->in_use = 0; spin_unlock_irqrestore(&cep->lock, flags); wake_up(&cep->waitq); } static void __siw_cep_dealloc(struct kref *ref) { struct siw_cep *cep = container_of(ref, struct siw_cep, ref); struct siw_device *sdev = cep->sdev; unsigned long flags; WARN_ON(cep->listen_cep); /* kfree(NULL) is safe */ kfree(cep->mpa.pdata); spin_lock_bh(&cep->lock); if (!list_empty(&cep->work_freelist)) siw_cm_free_work(cep); spin_unlock_bh(&cep->lock); spin_lock_irqsave(&sdev->lock, flags); list_del(&cep->devq); spin_unlock_irqrestore(&sdev->lock, flags); siw_dbg_cep(cep, "free endpoint\n"); kfree(cep); } static struct siw_cm_work *siw_get_work(struct siw_cep *cep) { struct siw_cm_work *work = NULL; spin_lock_bh(&cep->lock); if (!list_empty(&cep->work_freelist)) { work = list_entry(cep->work_freelist.next, struct siw_cm_work, list); list_del_init(&work->list); } spin_unlock_bh(&cep->lock); return work; } static int siw_cm_alloc_work(struct siw_cep *cep, int num) { struct siw_cm_work *work; while (num--) { work = kmalloc(sizeof(*work), GFP_KERNEL); if (!work) { if (!(list_empty(&cep->work_freelist))) siw_cm_free_work(cep); return -ENOMEM; } work->cep = cep; INIT_LIST_HEAD(&work->list); list_add(&work->list, &cep->work_freelist); } return 0; } /* * siw_cm_upcall() * * Upcall to IWCM to inform about async connection events */ static int siw_cm_upcall(struct siw_cep *cep, enum iw_cm_event_type reason, int status) { struct iw_cm_event event; struct iw_cm_id *id; memset(&event, 0, sizeof(event)); event.status = status; event.event = reason; if (reason == IW_CM_EVENT_CONNECT_REQUEST) { event.provider_data = cep; id = cep->listen_cep->cm_id; } else { id = cep->cm_id; } /* Signal IRD and ORD */ if (reason == IW_CM_EVENT_ESTABLISHED || reason == IW_CM_EVENT_CONNECT_REPLY) { /* Signal negotiated IRD/ORD values we will use */ event.ird = cep->ird; event.ord = cep->ord; } else if (reason == IW_CM_EVENT_CONNECT_REQUEST) { event.ird = cep->ord; event.ord = cep->ird; } /* Signal private data and address information */ if (reason == IW_CM_EVENT_CONNECT_REQUEST || reason == IW_CM_EVENT_CONNECT_REPLY) { u16 pd_len = be16_to_cpu(cep->mpa.hdr.params.pd_len); if (pd_len) { /* * hand over MPA private data */ event.private_data_len = pd_len; event.private_data = cep->mpa.pdata; /* Hide MPA V2 IRD/ORD control */ if (cep->enhanced_rdma_conn_est) { event.private_data_len -= sizeof(struct mpa_v2_data); event.private_data += sizeof(struct mpa_v2_data); } } getname_local(cep->sock, &event.local_addr); getname_peer(cep->sock, &event.remote_addr); } siw_dbg_cep(cep, "[QP %u]: reason=%d, status=%d\n", cep->qp ? qp_id(cep->qp) : UINT_MAX, reason, status); return id->event_handler(id, &event); } /* * siw_qp_cm_drop() * * Drops established LLP connection if present and not already * scheduled for dropping. Called from user context, SQ workqueue * or receive IRQ. Caller signals if socket can be immediately * closed (basically, if not in IRQ). */ void siw_qp_cm_drop(struct siw_qp *qp, int schedule) { struct siw_cep *cep = qp->cep; qp->rx_stream.rx_suspend = 1; qp->tx_ctx.tx_suspend = 1; if (!qp->cep) return; if (schedule) { siw_cm_queue_work(cep, SIW_CM_WORK_CLOSE_LLP); } else { siw_cep_set_inuse(cep); if (cep->state == SIW_EPSTATE_CLOSED) { siw_dbg_cep(cep, "already closed\n"); goto out; } siw_dbg_cep(cep, "immediate close, state %d\n", cep->state); if (qp->term_info.valid) siw_send_terminate(qp); if (cep->cm_id) { switch (cep->state) { case SIW_EPSTATE_AWAIT_MPAREP: siw_cm_upcall(cep, IW_CM_EVENT_CONNECT_REPLY, -EINVAL); break; case SIW_EPSTATE_RDMA_MODE: siw_cm_upcall(cep, IW_CM_EVENT_CLOSE, 0); break; case SIW_EPSTATE_IDLE: case SIW_EPSTATE_LISTENING: case SIW_EPSTATE_CONNECTING: case SIW_EPSTATE_AWAIT_MPAREQ: case SIW_EPSTATE_RECVD_MPAREQ: case SIW_EPSTATE_CLOSED: default: break; } cep->cm_id->rem_ref(cep->cm_id); cep->cm_id = NULL; siw_cep_put(cep); } cep->state = SIW_EPSTATE_CLOSED; if (cep->sock) { siw_socket_disassoc(cep->sock); /* * Immediately close socket */ sock_release(cep->sock); cep->sock = NULL; } if (cep->qp) { cep->qp = NULL; siw_qp_put(qp); } out: siw_cep_set_free(cep); } } void siw_cep_put(struct siw_cep *cep) { WARN_ON(kref_read(&cep->ref) < 1); kref_put(&cep->ref, __siw_cep_dealloc); } void siw_cep_get(struct siw_cep *cep) { kref_get(&cep->ref); } /* * Expects params->pd_len in host byte order */ static int siw_send_mpareqrep(struct siw_cep *cep, const void *pdata, u8 pd_len) { struct socket *s = cep->sock; struct mpa_rr *rr = &cep->mpa.hdr; struct kvec iov[3]; struct msghdr msg; int rv; int iovec_num = 0; int mpa_len; memset(&msg, 0, sizeof(msg)); iov[iovec_num].iov_base = rr; iov[iovec_num].iov_len = sizeof(*rr); mpa_len = sizeof(*rr); if (cep->enhanced_rdma_conn_est) { iovec_num++; iov[iovec_num].iov_base = &cep->mpa.v2_ctrl; iov[iovec_num].iov_len = sizeof(cep->mpa.v2_ctrl); mpa_len += sizeof(cep->mpa.v2_ctrl); } if (pd_len) { iovec_num++; iov[iovec_num].iov_base = (char *)pdata; iov[iovec_num].iov_len = pd_len; mpa_len += pd_len; } if (cep->enhanced_rdma_conn_est) pd_len += sizeof(cep->mpa.v2_ctrl); rr->params.pd_len = cpu_to_be16(pd_len); rv = kernel_sendmsg(s, &msg, iov, iovec_num + 1, mpa_len); return rv < 0 ? rv : 0; } /* * Receive MPA Request/Reply header. * * Returns 0 if complete MPA Request/Reply header including * eventual private data was received. Returns -EAGAIN if * header was partially received or negative error code otherwise. * * Context: May be called in process context only */ static int siw_recv_mpa_rr(struct siw_cep *cep) { struct mpa_rr *hdr = &cep->mpa.hdr; struct socket *s = cep->sock; u16 pd_len; int rcvd, to_rcv; if (cep->mpa.bytes_rcvd < sizeof(struct mpa_rr)) { rcvd = ksock_recv(s, (char *)hdr + cep->mpa.bytes_rcvd, sizeof(struct mpa_rr) - cep->mpa.bytes_rcvd, 0); if (rcvd <= 0) return -ECONNABORTED; cep->mpa.bytes_rcvd += rcvd; if (cep->mpa.bytes_rcvd < sizeof(struct mpa_rr)) return -EAGAIN; if (be16_to_cpu(hdr->params.pd_len) > MPA_MAX_PRIVDATA) return -EPROTO; } pd_len = be16_to_cpu(hdr->params.pd_len); /* * At least the MPA Request/Reply header (frame not including * private data) has been received. * Receive (or continue receiving) any private data. */ to_rcv = pd_len - (cep->mpa.bytes_rcvd - sizeof(struct mpa_rr)); if (!to_rcv) { /* * We must have hdr->params.pd_len == 0 and thus received a * complete MPA Request/Reply frame. * Check against peer protocol violation. */ u32 word; rcvd = ksock_recv(s, (char *)&word, sizeof(word), MSG_DONTWAIT); if (rcvd == -EAGAIN) return 0; if (rcvd == 0) { siw_dbg_cep(cep, "peer EOF\n"); return -EPIPE; } if (rcvd < 0) { siw_dbg_cep(cep, "error: %d\n", rcvd); return rcvd; } siw_dbg_cep(cep, "peer sent extra data: %d\n", rcvd); return -EPROTO; } /* * At this point, we must have hdr->params.pd_len != 0. * A private data buffer gets allocated if hdr->params.pd_len != 0. */ if (!cep->mpa.pdata) { cep->mpa.pdata = kmalloc(pd_len + 4, GFP_KERNEL); if (!cep->mpa.pdata) return -ENOMEM; } rcvd = ksock_recv( s, cep->mpa.pdata + cep->mpa.bytes_rcvd - sizeof(struct mpa_rr), to_rcv + 4, MSG_DONTWAIT); if (rcvd < 0) return rcvd; if (rcvd > to_rcv) return -EPROTO; cep->mpa.bytes_rcvd += rcvd; if (to_rcv == rcvd) { siw_dbg_cep(cep, "%d bytes private data received\n", pd_len); return 0; } return -EAGAIN; } /* * siw_proc_mpareq() * * Read MPA Request from socket and signal new connection to IWCM * if success. Caller must hold lock on corresponding listening CEP. */ static int siw_proc_mpareq(struct siw_cep *cep) { struct mpa_rr *req; int version, rv; u16 pd_len; rv = siw_recv_mpa_rr(cep); if (rv) return rv; req = &cep->mpa.hdr; version = __mpa_rr_revision(req->params.bits); pd_len = be16_to_cpu(req->params.pd_len); if (version > MPA_REVISION_2) /* allow for 0, 1, and 2 only */ return -EPROTO; if (memcmp(req->key, MPA_KEY_REQ, 16)) return -EPROTO; /* Prepare for sending MPA reply */ memcpy(req->key, MPA_KEY_REP, 16); if (version == MPA_REVISION_2 && (req->params.bits & MPA_RR_FLAG_ENHANCED)) { /* * MPA version 2 must signal IRD/ORD values and P2P mode * in private data if header flag MPA_RR_FLAG_ENHANCED * is set. */ if (pd_len < sizeof(struct mpa_v2_data)) goto reject_conn; cep->enhanced_rdma_conn_est = true; } /* MPA Markers: currently not supported. Marker TX to be added. */ if (req->params.bits & MPA_RR_FLAG_MARKERS) goto reject_conn; if (req->params.bits & MPA_RR_FLAG_CRC) { /* * RFC 5044, page 27: CRC MUST be used if peer requests it. * siw specific: 'mpa_crc_strict' parameter to reject * connection with CRC if local CRC off enforced by * 'mpa_crc_strict' module parameter. */ if (!mpa_crc_required && mpa_crc_strict) goto reject_conn; /* Enable CRC if requested by module parameter */ if (mpa_crc_required) req->params.bits |= MPA_RR_FLAG_CRC; } if (cep->enhanced_rdma_conn_est) { struct mpa_v2_data *v2 = (struct mpa_v2_data *)cep->mpa.pdata; /* * Peer requested ORD becomes requested local IRD, * peer requested IRD becomes requested local ORD. * IRD and ORD get limited by global maximum values. */ cep->ord = ntohs(v2->ird) & MPA_IRD_ORD_MASK; cep->ord = min(cep->ord, SIW_MAX_ORD_QP); cep->ird = ntohs(v2->ord) & MPA_IRD_ORD_MASK; cep->ird = min(cep->ird, SIW_MAX_IRD_QP); /* May get overwritten by locally negotiated values */ cep->mpa.v2_ctrl.ird = htons(cep->ird); cep->mpa.v2_ctrl.ord = htons(cep->ord); /* * Support for peer sent zero length Write or Read to * let local side enter RTS. Writes are preferred. * Sends would require pre-posting a Receive and are * not supported. * Propose zero length Write if none of Read and Write * is indicated. */ if (v2->ird & MPA_V2_PEER_TO_PEER) { cep->mpa.v2_ctrl.ird |= MPA_V2_PEER_TO_PEER; if (v2->ord & MPA_V2_RDMA_WRITE_RTR) cep->mpa.v2_ctrl.ord |= MPA_V2_RDMA_WRITE_RTR; else if (v2->ord & MPA_V2_RDMA_READ_RTR) cep->mpa.v2_ctrl.ord |= MPA_V2_RDMA_READ_RTR; else cep->mpa.v2_ctrl.ord |= MPA_V2_RDMA_WRITE_RTR; } } cep->state = SIW_EPSTATE_RECVD_MPAREQ; /* Keep reference until IWCM accepts/rejects */ siw_cep_get(cep); rv = siw_cm_upcall(cep, IW_CM_EVENT_CONNECT_REQUEST, 0); if (rv) siw_cep_put(cep); return rv; reject_conn: siw_dbg_cep(cep, "reject: crc %d:%d:%d, m %d:%d\n", req->params.bits & MPA_RR_FLAG_CRC ? 1 : 0, mpa_crc_required, mpa_crc_strict, req->params.bits & MPA_RR_FLAG_MARKERS ? 1 : 0, 0); req->params.bits &= ~MPA_RR_FLAG_MARKERS; req->params.bits |= MPA_RR_FLAG_REJECT; if (!mpa_crc_required && mpa_crc_strict) req->params.bits &= ~MPA_RR_FLAG_CRC; if (pd_len) kfree(cep->mpa.pdata); cep->mpa.pdata = NULL; siw_send_mpareqrep(cep, NULL, 0); return -EOPNOTSUPP; } static int siw_proc_mpareply(struct siw_cep *cep) { struct siw_qp_attrs qp_attrs; enum siw_qp_attr_mask qp_attr_mask; struct siw_qp *qp = cep->qp; struct mpa_rr *rep; int rv; u16 rep_ord; u16 rep_ird; bool ird_insufficient = false; enum mpa_v2_ctrl mpa_p2p_mode = MPA_V2_RDMA_NO_RTR; rv = siw_recv_mpa_rr(cep); if (rv != -EAGAIN) siw_cancel_mpatimer(cep); if (rv) goto out_err; rep = &cep->mpa.hdr; if (__mpa_rr_revision(rep->params.bits) > MPA_REVISION_2) { /* allow for 0, 1, and 2 only */ rv = -EPROTO; goto out_err; } if (memcmp(rep->key, MPA_KEY_REP, 16)) { siw_init_terminate(qp, TERM_ERROR_LAYER_LLP, LLP_ETYPE_MPA, LLP_ECODE_INVALID_REQ_RESP, 0); siw_send_terminate(qp); rv = -EPROTO; goto out_err; } if (rep->params.bits & MPA_RR_FLAG_REJECT) { siw_dbg_cep(cep, "got mpa reject\n"); siw_cm_upcall(cep, IW_CM_EVENT_CONNECT_REPLY, -ECONNRESET); return -ECONNRESET; } if (try_gso && rep->params.bits & MPA_RR_FLAG_GSO_EXP) { siw_dbg_cep(cep, "peer allows GSO on TX\n"); qp->tx_ctx.gso_seg_limit = 0; } if ((rep->params.bits & MPA_RR_FLAG_MARKERS) || (mpa_crc_required && !(rep->params.bits & MPA_RR_FLAG_CRC)) || (mpa_crc_strict && !mpa_crc_required && (rep->params.bits & MPA_RR_FLAG_CRC))) { siw_dbg_cep(cep, "reply unsupp: crc %d:%d:%d, m %d:%d\n", rep->params.bits & MPA_RR_FLAG_CRC ? 1 : 0, mpa_crc_required, mpa_crc_strict, rep->params.bits & MPA_RR_FLAG_MARKERS ? 1 : 0, 0); siw_cm_upcall(cep, IW_CM_EVENT_CONNECT_REPLY, -ECONNREFUSED); return -EINVAL; } if (cep->enhanced_rdma_conn_est) { struct mpa_v2_data *v2; if (__mpa_rr_revision(rep->params.bits) < MPA_REVISION_2 || !(rep->params.bits & MPA_RR_FLAG_ENHANCED)) { /* * Protocol failure: The responder MUST reply with * MPA version 2 and MUST set MPA_RR_FLAG_ENHANCED. */ siw_dbg_cep(cep, "mpa reply error: vers %d, enhcd %d\n", __mpa_rr_revision(rep->params.bits), rep->params.bits & MPA_RR_FLAG_ENHANCED ? 1 : 0); siw_cm_upcall(cep, IW_CM_EVENT_CONNECT_REPLY, -ECONNRESET); return -EINVAL; } v2 = (struct mpa_v2_data *)cep->mpa.pdata; rep_ird = ntohs(v2->ird) & MPA_IRD_ORD_MASK; rep_ord = ntohs(v2->ord) & MPA_IRD_ORD_MASK; if (cep->ird < rep_ord && (relaxed_ird_negotiation == false || rep_ord > cep->sdev->attrs.max_ird)) { siw_dbg_cep(cep, "ird %d, rep_ord %d, max_ord %d\n", cep->ird, rep_ord, cep->sdev->attrs.max_ord); ird_insufficient = true; } if (cep->ord > rep_ird && relaxed_ird_negotiation == false) { siw_dbg_cep(cep, "ord %d, rep_ird %d\n", cep->ord, rep_ird); ird_insufficient = true; } /* * Always report negotiated peer values to user, * even if IRD/ORD negotiation failed */ cep->ird = rep_ord; cep->ord = rep_ird; if (ird_insufficient) { /* * If the initiator IRD is insuffient for the * responder ORD, send a TERM. */ siw_init_terminate(qp, TERM_ERROR_LAYER_LLP, LLP_ETYPE_MPA, LLP_ECODE_INSUFFICIENT_IRD, 0); siw_send_terminate(qp); rv = -ENOMEM; goto out_err; } if (cep->mpa.v2_ctrl_req.ird & MPA_V2_PEER_TO_PEER) mpa_p2p_mode = cep->mpa.v2_ctrl_req.ord & (MPA_V2_RDMA_WRITE_RTR | MPA_V2_RDMA_READ_RTR); /* * Check if we requested P2P mode, and if peer agrees */ if (mpa_p2p_mode != MPA_V2_RDMA_NO_RTR) { if ((mpa_p2p_mode & v2->ord) == 0) { /* * We requested RTR mode(s), but the peer * did not pick any mode we support. */ siw_dbg_cep(cep, "rtr mode: req %2x, got %2x\n", mpa_p2p_mode, v2->ord & (MPA_V2_RDMA_WRITE_RTR | MPA_V2_RDMA_READ_RTR)); siw_init_terminate(qp, TERM_ERROR_LAYER_LLP, LLP_ETYPE_MPA, LLP_ECODE_NO_MATCHING_RTR, 0); siw_send_terminate(qp); rv = -EPROTO; goto out_err; } mpa_p2p_mode = v2->ord & (MPA_V2_RDMA_WRITE_RTR | MPA_V2_RDMA_READ_RTR); } } memset(&qp_attrs, 0, sizeof(qp_attrs)); if (rep->params.bits & MPA_RR_FLAG_CRC) qp_attrs.flags = SIW_MPA_CRC; qp_attrs.irq_size = cep->ird; qp_attrs.orq_size = cep->ord; qp_attrs.sk = cep->sock; qp_attrs.state = SIW_QP_STATE_RTS; qp_attr_mask = SIW_QP_ATTR_STATE | SIW_QP_ATTR_LLP_HANDLE | SIW_QP_ATTR_ORD | SIW_QP_ATTR_IRD | SIW_QP_ATTR_MPA; /* Move socket RX/TX under QP control */ down_write(&qp->state_lock); if (qp->attrs.state > SIW_QP_STATE_RTR) { rv = -EINVAL; up_write(&qp->state_lock); goto out_err; } rv = siw_qp_modify(qp, &qp_attrs, qp_attr_mask); siw_qp_socket_assoc(cep, qp); up_write(&qp->state_lock); /* Send extra RDMA frame to trigger peer RTS if negotiated */ if (mpa_p2p_mode != MPA_V2_RDMA_NO_RTR) { rv = siw_qp_mpa_rts(qp, mpa_p2p_mode); if (rv) goto out_err; } if (!rv) { rv = siw_cm_upcall(cep, IW_CM_EVENT_CONNECT_REPLY, 0); if (!rv) cep->state = SIW_EPSTATE_RDMA_MODE; return 0; } out_err: siw_cm_upcall(cep, IW_CM_EVENT_CONNECT_REPLY, -EINVAL); return rv; } /* * siw_accept_newconn - accept an incoming pending connection * */ static void siw_accept_newconn(struct siw_cep *cep) { struct socket *s = cep->sock; struct socket *new_s = NULL; struct siw_cep *new_cep = NULL; int rv = 0; /* debug only. should disappear */ if (cep->state != SIW_EPSTATE_LISTENING) goto error; new_cep = siw_cep_alloc(cep->sdev); if (!new_cep) goto error; /* * 4: Allocate a sufficient number of work elements * to allow concurrent handling of local + peer close * events, MPA header processing + MPA timeout. */ if (siw_cm_alloc_work(new_cep, 4) != 0) goto error; /* * Copy saved socket callbacks from listening CEP * and assign new socket with new CEP */ new_cep->sk_state_change = cep->sk_state_change; new_cep->sk_data_ready = cep->sk_data_ready; new_cep->sk_write_space = cep->sk_write_space; new_cep->sk_error_report = cep->sk_error_report; rv = kernel_accept(s, &new_s, O_NONBLOCK); if (rv != 0) { /* * Connection already aborted by peer..? */ siw_dbg_cep(cep, "kernel_accept() error: %d\n", rv); goto error; } new_cep->sock = new_s; siw_cep_get(new_cep); new_s->sk->sk_user_data = new_cep; if (siw_tcp_nagle == false) { int val = 1; rv = kernel_setsockopt(new_s, SOL_TCP, TCP_NODELAY, (char *)&val, sizeof(val)); if (rv) { siw_dbg_cep(cep, "setsockopt NODELAY error: %d\n", rv); goto error; } } new_cep->state = SIW_EPSTATE_AWAIT_MPAREQ; rv = siw_cm_queue_work(new_cep, SIW_CM_WORK_MPATIMEOUT); if (rv) goto error; /* * See siw_proc_mpareq() etc. for the use of new_cep->listen_cep. */ new_cep->listen_cep = cep; siw_cep_get(cep); if (atomic_read(&new_s->sk->sk_rmem_alloc)) { /* * MPA REQ already queued */ siw_dbg_cep(cep, "immediate mpa request\n"); siw_cep_set_inuse(new_cep); rv = siw_proc_mpareq(new_cep); siw_cep_set_free(new_cep); if (rv != -EAGAIN) { siw_cep_put(cep); new_cep->listen_cep = NULL; if (rv) goto error; } } return; error: if (new_cep) siw_cep_put(new_cep); if (new_s) { siw_socket_disassoc(new_s); sock_release(new_s); new_cep->sock = NULL; } siw_dbg_cep(cep, "error %d\n", rv); } static void siw_cm_work_handler(struct work_struct *w) { struct siw_cm_work *work; struct siw_cep *cep; int release_cep = 0, rv = 0; work = container_of(w, struct siw_cm_work, work.work); cep = work->cep; siw_dbg_cep(cep, "[QP %u]: work type: %d, state %d\n", cep->qp ? qp_id(cep->qp) : UINT_MAX, work->type, cep->state); siw_cep_set_inuse(cep); switch (work->type) { case SIW_CM_WORK_ACCEPT: siw_accept_newconn(cep); break; case SIW_CM_WORK_READ_MPAHDR: if (cep->state == SIW_EPSTATE_AWAIT_MPAREQ) { if (cep->listen_cep) { siw_cep_set_inuse(cep->listen_cep); if (cep->listen_cep->state == SIW_EPSTATE_LISTENING) rv = siw_proc_mpareq(cep); else rv = -EFAULT; siw_cep_set_free(cep->listen_cep); if (rv != -EAGAIN) { siw_cep_put(cep->listen_cep); cep->listen_cep = NULL; if (rv) siw_cep_put(cep); } } } else if (cep->state == SIW_EPSTATE_AWAIT_MPAREP) { rv = siw_proc_mpareply(cep); } else { /* * CEP already moved out of MPA handshake. * any connection management already done. * silently ignore the mpa packet. */ if (cep->state == SIW_EPSTATE_RDMA_MODE) { cep->sock->sk->sk_data_ready(cep->sock->sk); siw_dbg_cep(cep, "already in RDMA mode"); } else { siw_dbg_cep(cep, "out of state: %d\n", cep->state); } } if (rv && rv != EAGAIN) release_cep = 1; break; case SIW_CM_WORK_CLOSE_LLP: /* * QP scheduled LLP close */ if (cep->qp && cep->qp->term_info.valid) siw_send_terminate(cep->qp); if (cep->cm_id) siw_cm_upcall(cep, IW_CM_EVENT_CLOSE, 0); release_cep = 1; break; case SIW_CM_WORK_PEER_CLOSE: if (cep->cm_id) { if (cep->state == SIW_EPSTATE_AWAIT_MPAREP) { /* * MPA reply not received, but connection drop */ siw_cm_upcall(cep, IW_CM_EVENT_CONNECT_REPLY, -ECONNRESET); } else if (cep->state == SIW_EPSTATE_RDMA_MODE) { /* * NOTE: IW_CM_EVENT_DISCONNECT is given just * to transition IWCM into CLOSING. */ siw_cm_upcall(cep, IW_CM_EVENT_DISCONNECT, 0); siw_cm_upcall(cep, IW_CM_EVENT_CLOSE, 0); } /* * for other states there is no connection * known to the IWCM. */ } else { if (cep->state == SIW_EPSTATE_RECVD_MPAREQ) { /* * Wait for the ulp/CM to call accept/reject */ siw_dbg_cep(cep, "mpa req recvd, wait for ULP\n"); } else if (cep->state == SIW_EPSTATE_AWAIT_MPAREQ) { /* * Socket close before MPA request received. */ siw_dbg_cep(cep, "no mpareq: drop listener\n"); siw_cep_put(cep->listen_cep); cep->listen_cep = NULL; } } release_cep = 1; break; case SIW_CM_WORK_MPATIMEOUT: cep->mpa_timer = NULL; if (cep->state == SIW_EPSTATE_AWAIT_MPAREP) { /* * MPA request timed out: * Hide any partially received private data and signal * timeout */ cep->mpa.hdr.params.pd_len = 0; if (cep->cm_id) siw_cm_upcall(cep, IW_CM_EVENT_CONNECT_REPLY, -ETIMEDOUT); release_cep = 1; } else if (cep->state == SIW_EPSTATE_AWAIT_MPAREQ) { /* * No MPA request received after peer TCP stream setup. */ if (cep->listen_cep) { siw_cep_put(cep->listen_cep); cep->listen_cep = NULL; } release_cep = 1; } break; default: WARN(1, "Undefined CM work type: %d\n", work->type); } if (release_cep) { siw_dbg_cep(cep, "release: timer=%s, QP[%u]\n", cep->mpa_timer ? "y" : "n", cep->qp ? qp_id(cep->qp) : UINT_MAX); siw_cancel_mpatimer(cep); cep->state = SIW_EPSTATE_CLOSED; if (cep->qp) { struct siw_qp *qp = cep->qp; /* * Serialize a potential race with application * closing the QP and calling siw_qp_cm_drop() */ siw_qp_get(qp); siw_cep_set_free(cep); siw_qp_llp_close(qp); siw_qp_put(qp); siw_cep_set_inuse(cep); cep->qp = NULL; siw_qp_put(qp); } if (cep->sock) { siw_socket_disassoc(cep->sock); sock_release(cep->sock); cep->sock = NULL; } if (cep->cm_id) { cep->cm_id->rem_ref(cep->cm_id); cep->cm_id = NULL; siw_cep_put(cep); } } siw_cep_set_free(cep); siw_put_work(work); siw_cep_put(cep); } static struct workqueue_struct *siw_cm_wq; int siw_cm_queue_work(struct siw_cep *cep, enum siw_work_type type) { struct siw_cm_work *work = siw_get_work(cep); unsigned long delay = 0; if (!work) { siw_dbg_cep(cep, "failed with no work available\n"); return -ENOMEM; } work->type = type; work->cep = cep; siw_cep_get(cep); INIT_DELAYED_WORK(&work->work, siw_cm_work_handler); if (type == SIW_CM_WORK_MPATIMEOUT) { cep->mpa_timer = work; if (cep->state == SIW_EPSTATE_AWAIT_MPAREP) delay = MPAREQ_TIMEOUT; else delay = MPAREP_TIMEOUT; } siw_dbg_cep(cep, "[QP %u]: work type: %d, timeout %lu\n", cep->qp ? qp_id(cep->qp) : -1, type, delay); queue_delayed_work(siw_cm_wq, &work->work, delay); return 0; } static void siw_cm_llp_data_ready(struct sock *sk) { struct siw_cep *cep; read_lock(&sk->sk_callback_lock); cep = sk_to_cep(sk); if (!cep) goto out; siw_dbg_cep(cep, "state: %d\n", cep->state); switch (cep->state) { case SIW_EPSTATE_RDMA_MODE: /* fall through */ case SIW_EPSTATE_LISTENING: break; case SIW_EPSTATE_AWAIT_MPAREQ: /* fall through */ case SIW_EPSTATE_AWAIT_MPAREP: siw_cm_queue_work(cep, SIW_CM_WORK_READ_MPAHDR); break; default: siw_dbg_cep(cep, "unexpected data, state %d\n", cep->state); break; } out: read_unlock(&sk->sk_callback_lock); } static void siw_cm_llp_write_space(struct sock *sk) { struct siw_cep *cep = sk_to_cep(sk); if (cep) siw_dbg_cep(cep, "state: %d\n", cep->state); } static void siw_cm_llp_error_report(struct sock *sk) { struct siw_cep *cep = sk_to_cep(sk); if (cep) { siw_dbg_cep(cep, "error %d, socket state: %d, cep state: %d\n", sk->sk_err, sk->sk_state, cep->state); cep->sk_error_report(sk); } } static void siw_cm_llp_state_change(struct sock *sk) { struct siw_cep *cep; void (*orig_state_change)(struct sock *s); read_lock(&sk->sk_callback_lock); cep = sk_to_cep(sk); if (!cep) { /* endpoint already disassociated */ read_unlock(&sk->sk_callback_lock); return; } orig_state_change = cep->sk_state_change; siw_dbg_cep(cep, "state: %d\n", cep->state); switch (sk->sk_state) { case TCP_ESTABLISHED: /* * handle accepting socket as special case where only * new connection is possible */ siw_cm_queue_work(cep, SIW_CM_WORK_ACCEPT); break; case TCP_CLOSE: case TCP_CLOSE_WAIT: if (cep->qp) cep->qp->tx_ctx.tx_suspend = 1; siw_cm_queue_work(cep, SIW_CM_WORK_PEER_CLOSE); break; default: siw_dbg_cep(cep, "unexpected socket state %d\n", sk->sk_state); } read_unlock(&sk->sk_callback_lock); orig_state_change(sk); } static int kernel_bindconnect(struct socket *s, struct sockaddr *laddr, struct sockaddr *raddr) { int rv, flags = 0, s_val = 1; size_t size = laddr->sa_family == AF_INET ? sizeof(struct sockaddr_in) : sizeof(struct sockaddr_in6); /* * Make address available again asap. */ rv = kernel_setsockopt(s, SOL_SOCKET, SO_REUSEADDR, (char *)&s_val, sizeof(s_val)); if (rv < 0) return rv; rv = s->ops->bind(s, laddr, size); if (rv < 0) return rv; rv = s->ops->connect(s, raddr, size, flags); return rv < 0 ? rv : 0; } int siw_connect(struct iw_cm_id *id, struct iw_cm_conn_param *params) { struct siw_device *sdev = to_siw_dev(id->device); struct siw_qp *qp; struct siw_cep *cep = NULL; struct socket *s = NULL; struct sockaddr *laddr = (struct sockaddr *)&id->local_addr, *raddr = (struct sockaddr *)&id->remote_addr; bool p2p_mode = peer_to_peer, v4 = true; u16 pd_len = params->private_data_len; int version = mpa_version, rv; if (pd_len > MPA_MAX_PRIVDATA) return -EINVAL; if (params->ird > sdev->attrs.max_ird || params->ord > sdev->attrs.max_ord) return -ENOMEM; if (laddr->sa_family == AF_INET6) v4 = false; else if (laddr->sa_family != AF_INET) return -EAFNOSUPPORT; /* * Respect any iwarp port mapping: Use mapped remote address * if valid. Local address must not be mapped, since siw * uses kernel TCP stack. */ if ((v4 && to_sockaddr_in(id->remote_addr).sin_port != 0) || to_sockaddr_in6(id->remote_addr).sin6_port != 0) raddr = (struct sockaddr *)&id->m_remote_addr; qp = siw_qp_id2obj(sdev, params->qpn); if (!qp) { WARN(1, "[QP %u] does not exist\n", params->qpn); rv = -EINVAL; goto error; } siw_dbg_qp(qp, "pd_len %d, laddr %pISp, raddr %pISp\n", pd_len, laddr, raddr); rv = sock_create(v4 ? AF_INET : AF_INET6, SOCK_STREAM, IPPROTO_TCP, &s); if (rv < 0) goto error; /* * NOTE: For simplification, connect() is called in blocking * mode. Might be reconsidered for async connection setup at * TCP level. */ rv = kernel_bindconnect(s, laddr, raddr); if (rv != 0) { siw_dbg_qp(qp, "kernel_bindconnect: error %d\n", rv); goto error; } if (siw_tcp_nagle == false) { int val = 1; rv = kernel_setsockopt(s, SOL_TCP, TCP_NODELAY, (char *)&val, sizeof(val)); if (rv) { siw_dbg_qp(qp, "setsockopt NODELAY error: %d\n", rv); goto error; } } cep = siw_cep_alloc(sdev); if (!cep) { rv = -ENOMEM; goto error; } siw_cep_set_inuse(cep); /* Associate QP with CEP */ siw_cep_get(cep); qp->cep = cep; /* siw_qp_get(qp) already done by QP lookup */ cep->qp = qp; id->add_ref(id); cep->cm_id = id; /* * 4: Allocate a sufficient number of work elements * to allow concurrent handling of local + peer close * events, MPA header processing + MPA timeout. */ rv = siw_cm_alloc_work(cep, 4); if (rv != 0) { rv = -ENOMEM; goto error; } cep->ird = params->ird; cep->ord = params->ord; if (p2p_mode && cep->ord == 0) cep->ord = 1; cep->state = SIW_EPSTATE_CONNECTING; /* * Associate CEP with socket */ siw_cep_socket_assoc(cep, s); cep->state = SIW_EPSTATE_AWAIT_MPAREP; /* * Set MPA Request bits: CRC if required, no MPA Markers, * MPA Rev. according to module parameter 'mpa_version', Key 'Request'. */ cep->mpa.hdr.params.bits = 0; if (version > MPA_REVISION_2) { pr_warn("Setting MPA version to %u\n", MPA_REVISION_2); version = MPA_REVISION_2; /* Adjust also module parameter */ mpa_version = MPA_REVISION_2; } __mpa_rr_set_revision(&cep->mpa.hdr.params.bits, version); if (try_gso) cep->mpa.hdr.params.bits |= MPA_RR_FLAG_GSO_EXP; if (mpa_crc_required) cep->mpa.hdr.params.bits |= MPA_RR_FLAG_CRC; /* * If MPA version == 2: * o Include ORD and IRD. * o Indicate peer-to-peer mode, if required by module * parameter 'peer_to_peer'. */ if (version == MPA_REVISION_2) { cep->enhanced_rdma_conn_est = true; cep->mpa.hdr.params.bits |= MPA_RR_FLAG_ENHANCED; cep->mpa.v2_ctrl.ird = htons(cep->ird); cep->mpa.v2_ctrl.ord = htons(cep->ord); if (p2p_mode) { cep->mpa.v2_ctrl.ird |= MPA_V2_PEER_TO_PEER; cep->mpa.v2_ctrl.ord |= rtr_type; } /* Remember own P2P mode requested */ cep->mpa.v2_ctrl_req.ird = cep->mpa.v2_ctrl.ird; cep->mpa.v2_ctrl_req.ord = cep->mpa.v2_ctrl.ord; } memcpy(cep->mpa.hdr.key, MPA_KEY_REQ, 16); rv = siw_send_mpareqrep(cep, params->private_data, pd_len); /* * Reset private data. */ cep->mpa.hdr.params.pd_len = 0; if (rv >= 0) { rv = siw_cm_queue_work(cep, SIW_CM_WORK_MPATIMEOUT); if (!rv) { siw_dbg_cep(cep, "[QP %u]: exit\n", qp_id(qp)); siw_cep_set_free(cep); return 0; } } error: siw_dbg(id->device, "failed: %d\n", rv); if (cep) { siw_socket_disassoc(s); sock_release(s); cep->sock = NULL; cep->qp = NULL; cep->cm_id = NULL; id->rem_ref(id); siw_cep_put(cep); qp->cep = NULL; siw_cep_put(cep); cep->state = SIW_EPSTATE_CLOSED; siw_cep_set_free(cep); siw_cep_put(cep); } else if (s) { sock_release(s); } if (qp) siw_qp_put(qp); return rv; } /* * siw_accept - Let SoftiWARP accept an RDMA connection request * * @id: New connection management id to be used for accepted * connection request * @params: Connection parameters provided by ULP for accepting connection * * Transition QP to RTS state, associate new CM id @id with accepted CEP * and get prepared for TCP input by installing socket callbacks. * Then send MPA Reply and generate the "connection established" event. * Socket callbacks must be installed before sending MPA Reply, because * the latter may cause a first RDMA message to arrive from the RDMA Initiator * side very quickly, at which time the socket callbacks must be ready. */ int siw_accept(struct iw_cm_id *id, struct iw_cm_conn_param *params) { struct siw_device *sdev = to_siw_dev(id->device); struct siw_cep *cep = (struct siw_cep *)id->provider_data; struct siw_qp *qp; struct siw_qp_attrs qp_attrs; int rv, max_priv_data = MPA_MAX_PRIVDATA; bool wait_for_peer_rts = false; siw_cep_set_inuse(cep); siw_cep_put(cep); /* Free lingering inbound private data */ if (cep->mpa.hdr.params.pd_len) { cep->mpa.hdr.params.pd_len = 0; kfree(cep->mpa.pdata); cep->mpa.pdata = NULL; } siw_cancel_mpatimer(cep); if (cep->state != SIW_EPSTATE_RECVD_MPAREQ) { siw_dbg_cep(cep, "out of state\n"); siw_cep_set_free(cep); siw_cep_put(cep); return -ECONNRESET; } qp = siw_qp_id2obj(sdev, params->qpn); if (!qp) { WARN(1, "[QP %d] does not exist\n", params->qpn); siw_cep_set_free(cep); siw_cep_put(cep); return -EINVAL; } down_write(&qp->state_lock); if (qp->attrs.state > SIW_QP_STATE_RTR) { rv = -EINVAL; up_write(&qp->state_lock); goto error; } siw_dbg_cep(cep, "[QP %d]\n", params->qpn); if (try_gso && cep->mpa.hdr.params.bits & MPA_RR_FLAG_GSO_EXP) { siw_dbg_cep(cep, "peer allows GSO on TX\n"); qp->tx_ctx.gso_seg_limit = 0; } if (params->ord > sdev->attrs.max_ord || params->ird > sdev->attrs.max_ird) { siw_dbg_cep( cep, "[QP %u]: ord %d (max %d), ird %d (max %d)\n", qp_id(qp), params->ord, sdev->attrs.max_ord, params->ird, sdev->attrs.max_ird); rv = -EINVAL; up_write(&qp->state_lock); goto error; } if (cep->enhanced_rdma_conn_est) max_priv_data -= sizeof(struct mpa_v2_data); if (params->private_data_len > max_priv_data) { siw_dbg_cep( cep, "[QP %u]: private data length: %d (max %d)\n", qp_id(qp), params->private_data_len, max_priv_data); rv = -EINVAL; up_write(&qp->state_lock); goto error; } if (cep->enhanced_rdma_conn_est) { if (params->ord > cep->ord) { if (relaxed_ird_negotiation) { params->ord = cep->ord; } else { cep->ird = params->ird; cep->ord = params->ord; rv = -EINVAL; up_write(&qp->state_lock); goto error; } } if (params->ird < cep->ird) { if (relaxed_ird_negotiation && cep->ird <= sdev->attrs.max_ird) params->ird = cep->ird; else { rv = -ENOMEM; up_write(&qp->state_lock); goto error; } } if (cep->mpa.v2_ctrl.ord & (MPA_V2_RDMA_WRITE_RTR | MPA_V2_RDMA_READ_RTR)) wait_for_peer_rts = true; /* * Signal back negotiated IRD and ORD values */ cep->mpa.v2_ctrl.ord = htons(params->ord & MPA_IRD_ORD_MASK) | (cep->mpa.v2_ctrl.ord & ~MPA_V2_MASK_IRD_ORD); cep->mpa.v2_ctrl.ird = htons(params->ird & MPA_IRD_ORD_MASK) | (cep->mpa.v2_ctrl.ird & ~MPA_V2_MASK_IRD_ORD); } cep->ird = params->ird; cep->ord = params->ord; cep->cm_id = id; id->add_ref(id); memset(&qp_attrs, 0, sizeof(qp_attrs)); qp_attrs.orq_size = cep->ord; qp_attrs.irq_size = cep->ird; qp_attrs.sk = cep->sock; if (cep->mpa.hdr.params.bits & MPA_RR_FLAG_CRC) qp_attrs.flags = SIW_MPA_CRC; qp_attrs.state = SIW_QP_STATE_RTS; siw_dbg_cep(cep, "[QP%u]: moving to rts\n", qp_id(qp)); /* Associate QP with CEP */ siw_cep_get(cep); qp->cep = cep; /* siw_qp_get(qp) already done by QP lookup */ cep->qp = qp; cep->state = SIW_EPSTATE_RDMA_MODE; /* Move socket RX/TX under QP control */ rv = siw_qp_modify(qp, &qp_attrs, SIW_QP_ATTR_STATE | SIW_QP_ATTR_LLP_HANDLE | SIW_QP_ATTR_ORD | SIW_QP_ATTR_IRD | SIW_QP_ATTR_MPA); up_write(&qp->state_lock); if (rv) goto error; siw_dbg_cep(cep, "[QP %u]: send mpa reply, %d byte pdata\n", qp_id(qp), params->private_data_len); rv = siw_send_mpareqrep(cep, params->private_data, params->private_data_len); if (rv != 0) goto error; if (wait_for_peer_rts) { siw_sk_assign_rtr_upcalls(cep); } else { siw_qp_socket_assoc(cep, qp); rv = siw_cm_upcall(cep, IW_CM_EVENT_ESTABLISHED, 0); if (rv) goto error; } siw_cep_set_free(cep); return 0; error: siw_socket_disassoc(cep->sock); sock_release(cep->sock); cep->sock = NULL; cep->state = SIW_EPSTATE_CLOSED; if (cep->cm_id) { cep->cm_id->rem_ref(id); cep->cm_id = NULL; } if (qp->cep) { siw_cep_put(cep); qp->cep = NULL; } cep->qp = NULL; siw_qp_put(qp); siw_cep_set_free(cep); siw_cep_put(cep); return rv; } /* * siw_reject() * * Local connection reject case. Send private data back to peer, * close connection and dereference connection id. */ int siw_reject(struct iw_cm_id *id, const void *pdata, u8 pd_len) { struct siw_cep *cep = (struct siw_cep *)id->provider_data; siw_cep_set_inuse(cep); siw_cep_put(cep); siw_cancel_mpatimer(cep); if (cep->state != SIW_EPSTATE_RECVD_MPAREQ) { siw_dbg_cep(cep, "out of state\n"); siw_cep_set_free(cep); siw_cep_put(cep); /* put last reference */ return -ECONNRESET; } siw_dbg_cep(cep, "cep->state %d, pd_len %d\n", cep->state, pd_len); if (__mpa_rr_revision(cep->mpa.hdr.params.bits) >= MPA_REVISION_1) { cep->mpa.hdr.params.bits |= MPA_RR_FLAG_REJECT; /* reject */ siw_send_mpareqrep(cep, pdata, pd_len); } siw_socket_disassoc(cep->sock); sock_release(cep->sock); cep->sock = NULL; cep->state = SIW_EPSTATE_CLOSED; siw_cep_set_free(cep); siw_cep_put(cep); return 0; } static int siw_listen_address(struct iw_cm_id *id, int backlog, struct sockaddr *laddr, int addr_family) { struct socket *s; struct siw_cep *cep = NULL; struct siw_device *sdev = to_siw_dev(id->device); int rv = 0, s_val; rv = sock_create(addr_family, SOCK_STREAM, IPPROTO_TCP, &s); if (rv < 0) return rv; /* * Allow binding local port when still in TIME_WAIT from last close. */ s_val = 1; rv = kernel_setsockopt(s, SOL_SOCKET, SO_REUSEADDR, (char *)&s_val, sizeof(s_val)); if (rv) { siw_dbg(id->device, "setsockopt error: %d\n", rv); goto error; } rv = s->ops->bind(s, laddr, addr_family == AF_INET ? sizeof(struct sockaddr_in) : sizeof(struct sockaddr_in6)); if (rv) { siw_dbg(id->device, "socket bind error: %d\n", rv); goto error; } cep = siw_cep_alloc(sdev); if (!cep) { rv = -ENOMEM; goto error; } siw_cep_socket_assoc(cep, s); rv = siw_cm_alloc_work(cep, backlog); if (rv) { siw_dbg(id->device, "alloc_work error %d, backlog %d\n", rv, backlog); goto error; } rv = s->ops->listen(s, backlog); if (rv) { siw_dbg(id->device, "listen error %d\n", rv); goto error; } cep->cm_id = id; id->add_ref(id); /* * In case of a wildcard rdma_listen on a multi-homed device, * a listener's IWCM id is associated with more than one listening CEP. * * We currently use id->provider_data in three different ways: * * o For a listener's IWCM id, id->provider_data points to * the list_head of the list of listening CEPs. * Uses: siw_create_listen(), siw_destroy_listen() * * o For each accepted passive-side IWCM id, id->provider_data * points to the CEP itself. This is a consequence of * - siw_cm_upcall() setting event.provider_data = cep and * - the IWCM's cm_conn_req_handler() setting provider_data of the * new passive-side IWCM id equal to event.provider_data * Uses: siw_accept(), siw_reject() * * o For an active-side IWCM id, id->provider_data is not used at all. * */ if (!id->provider_data) { id->provider_data = kmalloc(sizeof(struct list_head), GFP_KERNEL); if (!id->provider_data) { rv = -ENOMEM; goto error; } INIT_LIST_HEAD((struct list_head *)id->provider_data); } list_add_tail(&cep->listenq, (struct list_head *)id->provider_data); cep->state = SIW_EPSTATE_LISTENING; siw_dbg(id->device, "Listen at laddr %pISp\n", laddr); return 0; error: siw_dbg(id->device, "failed: %d\n", rv); if (cep) { siw_cep_set_inuse(cep); if (cep->cm_id) { cep->cm_id->rem_ref(cep->cm_id); cep->cm_id = NULL; } cep->sock = NULL; siw_socket_disassoc(s); cep->state = SIW_EPSTATE_CLOSED; siw_cep_set_free(cep); siw_cep_put(cep); } sock_release(s); return rv; } static void siw_drop_listeners(struct iw_cm_id *id) { struct list_head *p, *tmp; /* * In case of a wildcard rdma_listen on a multi-homed device, * a listener's IWCM id is associated with more than one listening CEP. */ list_for_each_safe(p, tmp, (struct list_head *)id->provider_data) { struct siw_cep *cep = list_entry(p, struct siw_cep, listenq); list_del(p); siw_dbg_cep(cep, "drop cep, state %d\n", cep->state); siw_cep_set_inuse(cep); if (cep->cm_id) { cep->cm_id->rem_ref(cep->cm_id); cep->cm_id = NULL; } if (cep->sock) { siw_socket_disassoc(cep->sock); sock_release(cep->sock); cep->sock = NULL; } cep->state = SIW_EPSTATE_CLOSED; siw_cep_set_free(cep); siw_cep_put(cep); } } /* * siw_create_listen - Create resources for a listener's IWCM ID @id * * Listens on the socket address id->local_addr. * * If the listener's @id provides a specific local IP address, at most one * listening socket is created and associated with @id. * * If the listener's @id provides the wildcard (zero) local IP address, * a separate listen is performed for each local IP address of the device * by creating a listening socket and binding to that local IP address. * */ int siw_create_listen(struct iw_cm_id *id, int backlog) { struct net_device *dev = to_siw_dev(id->device)->netdev; int rv = 0, listeners = 0; siw_dbg(id->device, "backlog %d\n", backlog); /* * For each attached address of the interface, create a * listening socket, if id->local_addr is the wildcard * IP address or matches the IP address. */ if (id->local_addr.ss_family == AF_INET) { struct in_device *in_dev = in_dev_get(dev); struct sockaddr_in s_laddr; const struct in_ifaddr *ifa; if (!in_dev) { rv = -ENODEV; goto out; } memcpy(&s_laddr, &id->local_addr, sizeof(s_laddr)); siw_dbg(id->device, "laddr %pISp\n", &s_laddr); rtnl_lock(); in_dev_for_each_ifa_rtnl(ifa, in_dev) { if (ipv4_is_zeronet(s_laddr.sin_addr.s_addr) || s_laddr.sin_addr.s_addr == ifa->ifa_address) { s_laddr.sin_addr.s_addr = ifa->ifa_address; rv = siw_listen_address(id, backlog, (struct sockaddr *)&s_laddr, AF_INET); if (!rv) listeners++; } } rtnl_unlock(); in_dev_put(in_dev); } else if (id->local_addr.ss_family == AF_INET6) { struct inet6_dev *in6_dev = in6_dev_get(dev); struct inet6_ifaddr *ifp; struct sockaddr_in6 *s_laddr = &to_sockaddr_in6(id->local_addr); if (!in6_dev) { rv = -ENODEV; goto out; } siw_dbg(id->device, "laddr %pISp\n", &s_laddr); rtnl_lock(); list_for_each_entry(ifp, &in6_dev->addr_list, if_list) { if (ifp->flags & (IFA_F_TENTATIVE | IFA_F_DEPRECATED)) continue; if (ipv6_addr_any(&s_laddr->sin6_addr) || ipv6_addr_equal(&s_laddr->sin6_addr, &ifp->addr)) { struct sockaddr_in6 bind_addr = { .sin6_family = AF_INET6, .sin6_port = s_laddr->sin6_port, .sin6_flowinfo = 0, .sin6_addr = ifp->addr, .sin6_scope_id = dev->ifindex }; rv = siw_listen_address(id, backlog, (struct sockaddr *)&bind_addr, AF_INET6); if (!rv) listeners++; } } rtnl_unlock(); in6_dev_put(in6_dev); } else { rv = -EAFNOSUPPORT; } out: if (listeners) rv = 0; else if (!rv) rv = -EINVAL; siw_dbg(id->device, "%s\n", rv ? "FAIL" : "OK"); return rv; } int siw_destroy_listen(struct iw_cm_id *id) { if (!id->provider_data) { siw_dbg(id->device, "no cep(s)\n"); return 0; } siw_drop_listeners(id); kfree(id->provider_data); id->provider_data = NULL; return 0; } int siw_cm_init(void) { /* * create_single_workqueue for strict ordering */ siw_cm_wq = create_singlethread_workqueue("siw_cm_wq"); if (!siw_cm_wq) return -ENOMEM; return 0; } void siw_cm_exit(void) { if (siw_cm_wq) { flush_workqueue(siw_cm_wq); destroy_workqueue(siw_cm_wq); } }