// SPDX-License-Identifier: GPL-2.0 or Linux-OpenIB /* Copyright (c) 2015 - 2021 Intel Corporation */ #include "main.h" static struct irdma_rsrc_limits rsrc_limits_table[] = { [0] = { .qplimit = SZ_128, }, [1] = { .qplimit = SZ_1K, }, [2] = { .qplimit = SZ_2K, }, [3] = { .qplimit = SZ_4K, }, [4] = { .qplimit = SZ_16K, }, [5] = { .qplimit = SZ_64K, }, [6] = { .qplimit = SZ_128K, }, [7] = { .qplimit = SZ_256K, }, }; /* types of hmc objects */ static enum irdma_hmc_rsrc_type iw_hmc_obj_types[] = { IRDMA_HMC_IW_QP, IRDMA_HMC_IW_CQ, IRDMA_HMC_IW_HTE, IRDMA_HMC_IW_ARP, IRDMA_HMC_IW_APBVT_ENTRY, IRDMA_HMC_IW_MR, IRDMA_HMC_IW_XF, IRDMA_HMC_IW_XFFL, IRDMA_HMC_IW_Q1, IRDMA_HMC_IW_Q1FL, IRDMA_HMC_IW_PBLE, IRDMA_HMC_IW_TIMER, IRDMA_HMC_IW_FSIMC, IRDMA_HMC_IW_FSIAV, IRDMA_HMC_IW_RRF, IRDMA_HMC_IW_RRFFL, IRDMA_HMC_IW_HDR, IRDMA_HMC_IW_MD, IRDMA_HMC_IW_OOISC, IRDMA_HMC_IW_OOISCFFL, }; /** * irdma_iwarp_ce_handler - handle iwarp completions * @iwcq: iwarp cq receiving event */ static void irdma_iwarp_ce_handler(struct irdma_sc_cq *iwcq) { struct irdma_cq *cq = iwcq->back_cq; if (!cq->user_mode) atomic_set(&cq->armed, 0); if (cq->ibcq.comp_handler) cq->ibcq.comp_handler(&cq->ibcq, cq->ibcq.cq_context); } /** * irdma_puda_ce_handler - handle puda completion events * @rf: RDMA PCI function * @cq: puda completion q for event */ static void irdma_puda_ce_handler(struct irdma_pci_f *rf, struct irdma_sc_cq *cq) { struct irdma_sc_dev *dev = &rf->sc_dev; u32 compl_error; int status; do { status = irdma_puda_poll_cmpl(dev, cq, &compl_error); if (status == -ENOENT) break; if (status) { ibdev_dbg(to_ibdev(dev), "ERR: puda status = %d\n", status); break; } if (compl_error) { ibdev_dbg(to_ibdev(dev), "ERR: puda compl_err =0x%x\n", compl_error); break; } } while (1); irdma_sc_ccq_arm(cq); } /** * irdma_process_ceq - handle ceq for completions * @rf: RDMA PCI function * @ceq: ceq having cq for completion */ static void irdma_process_ceq(struct irdma_pci_f *rf, struct irdma_ceq *ceq) { struct irdma_sc_dev *dev = &rf->sc_dev; struct irdma_sc_ceq *sc_ceq; struct irdma_sc_cq *cq; unsigned long flags; sc_ceq = &ceq->sc_ceq; do { spin_lock_irqsave(&ceq->ce_lock, flags); cq = irdma_sc_process_ceq(dev, sc_ceq); if (!cq) { spin_unlock_irqrestore(&ceq->ce_lock, flags); break; } if (cq->cq_type == IRDMA_CQ_TYPE_IWARP) irdma_iwarp_ce_handler(cq); spin_unlock_irqrestore(&ceq->ce_lock, flags); if (cq->cq_type == IRDMA_CQ_TYPE_CQP) queue_work(rf->cqp_cmpl_wq, &rf->cqp_cmpl_work); else if (cq->cq_type == IRDMA_CQ_TYPE_ILQ || cq->cq_type == IRDMA_CQ_TYPE_IEQ) irdma_puda_ce_handler(rf, cq); } while (1); } static void irdma_set_flush_fields(struct irdma_sc_qp *qp, struct irdma_aeqe_info *info) { qp->sq_flush_code = info->sq; qp->rq_flush_code = info->rq; qp->event_type = IRDMA_QP_EVENT_CATASTROPHIC; switch (info->ae_id) { case IRDMA_AE_AMP_BOUNDS_VIOLATION: case IRDMA_AE_AMP_INVALID_STAG: case IRDMA_AE_AMP_RIGHTS_VIOLATION: case IRDMA_AE_AMP_UNALLOCATED_STAG: case IRDMA_AE_AMP_BAD_PD: case IRDMA_AE_AMP_BAD_QP: case IRDMA_AE_AMP_BAD_STAG_KEY: case IRDMA_AE_AMP_BAD_STAG_INDEX: case IRDMA_AE_AMP_TO_WRAP: case IRDMA_AE_PRIV_OPERATION_DENIED: qp->flush_code = FLUSH_PROT_ERR; qp->event_type = IRDMA_QP_EVENT_ACCESS_ERR; break; case IRDMA_AE_UDA_XMIT_BAD_PD: case IRDMA_AE_WQE_UNEXPECTED_OPCODE: qp->flush_code = FLUSH_LOC_QP_OP_ERR; qp->event_type = IRDMA_QP_EVENT_CATASTROPHIC; break; case IRDMA_AE_UDA_XMIT_DGRAM_TOO_LONG: case IRDMA_AE_UDA_XMIT_DGRAM_TOO_SHORT: case IRDMA_AE_UDA_L4LEN_INVALID: case IRDMA_AE_DDP_UBE_INVALID_MO: case IRDMA_AE_DDP_UBE_DDP_MESSAGE_TOO_LONG_FOR_AVAILABLE_BUFFER: qp->flush_code = FLUSH_LOC_LEN_ERR; qp->event_type = IRDMA_QP_EVENT_CATASTROPHIC; break; case IRDMA_AE_AMP_INVALIDATE_NO_REMOTE_ACCESS_RIGHTS: case IRDMA_AE_IB_REMOTE_ACCESS_ERROR: qp->flush_code = FLUSH_REM_ACCESS_ERR; qp->event_type = IRDMA_QP_EVENT_ACCESS_ERR; break; case IRDMA_AE_LLP_SEGMENT_TOO_SMALL: case IRDMA_AE_LLP_RECEIVED_MPA_CRC_ERROR: case IRDMA_AE_ROCE_RSP_LENGTH_ERROR: case IRDMA_AE_IB_REMOTE_OP_ERROR: qp->flush_code = FLUSH_REM_OP_ERR; qp->event_type = IRDMA_QP_EVENT_CATASTROPHIC; break; case IRDMA_AE_LCE_QP_CATASTROPHIC: qp->flush_code = FLUSH_FATAL_ERR; qp->event_type = IRDMA_QP_EVENT_CATASTROPHIC; break; case IRDMA_AE_IB_RREQ_AND_Q1_FULL: qp->flush_code = FLUSH_GENERAL_ERR; break; case IRDMA_AE_LLP_TOO_MANY_RETRIES: qp->flush_code = FLUSH_RETRY_EXC_ERR; qp->event_type = IRDMA_QP_EVENT_CATASTROPHIC; break; case IRDMA_AE_AMP_MWBIND_INVALID_RIGHTS: case IRDMA_AE_AMP_MWBIND_BIND_DISABLED: case IRDMA_AE_AMP_MWBIND_INVALID_BOUNDS: case IRDMA_AE_AMP_MWBIND_VALID_STAG: qp->flush_code = FLUSH_MW_BIND_ERR; qp->event_type = IRDMA_QP_EVENT_ACCESS_ERR; break; case IRDMA_AE_IB_INVALID_REQUEST: qp->flush_code = FLUSH_REM_INV_REQ_ERR; qp->event_type = IRDMA_QP_EVENT_REQ_ERR; break; default: qp->flush_code = FLUSH_GENERAL_ERR; qp->event_type = IRDMA_QP_EVENT_CATASTROPHIC; break; } } /** * irdma_process_aeq - handle aeq events * @rf: RDMA PCI function */ static void irdma_process_aeq(struct irdma_pci_f *rf) { struct irdma_sc_dev *dev = &rf->sc_dev; struct irdma_aeq *aeq = &rf->aeq; struct irdma_sc_aeq *sc_aeq = &aeq->sc_aeq; struct irdma_aeqe_info aeinfo; struct irdma_aeqe_info *info = &aeinfo; int ret; struct irdma_qp *iwqp = NULL; struct irdma_cq *iwcq = NULL; struct irdma_sc_qp *qp = NULL; struct irdma_qp_host_ctx_info *ctx_info = NULL; struct irdma_device *iwdev = rf->iwdev; unsigned long flags; u32 aeqcnt = 0; if (!sc_aeq->size) return; do { memset(info, 0, sizeof(*info)); ret = irdma_sc_get_next_aeqe(sc_aeq, info); if (ret) break; aeqcnt++; ibdev_dbg(&iwdev->ibdev, "AEQ: ae_id = 0x%x bool qp=%d qp_id = %d tcp_state=%d iwarp_state=%d ae_src=%d\n", info->ae_id, info->qp, info->qp_cq_id, info->tcp_state, info->iwarp_state, info->ae_src); if (info->qp) { spin_lock_irqsave(&rf->qptable_lock, flags); iwqp = rf->qp_table[info->qp_cq_id]; if (!iwqp) { spin_unlock_irqrestore(&rf->qptable_lock, flags); if (info->ae_id == IRDMA_AE_QP_SUSPEND_COMPLETE) { atomic_dec(&iwdev->vsi.qp_suspend_reqs); wake_up(&iwdev->suspend_wq); continue; } ibdev_dbg(&iwdev->ibdev, "AEQ: qp_id %d is already freed\n", info->qp_cq_id); continue; } irdma_qp_add_ref(&iwqp->ibqp); spin_unlock_irqrestore(&rf->qptable_lock, flags); qp = &iwqp->sc_qp; spin_lock_irqsave(&iwqp->lock, flags); iwqp->hw_tcp_state = info->tcp_state; iwqp->hw_iwarp_state = info->iwarp_state; if (info->ae_id != IRDMA_AE_QP_SUSPEND_COMPLETE) iwqp->last_aeq = info->ae_id; spin_unlock_irqrestore(&iwqp->lock, flags); ctx_info = &iwqp->ctx_info; } else { if (info->ae_id != IRDMA_AE_CQ_OPERATION_ERROR) continue; } switch (info->ae_id) { struct irdma_cm_node *cm_node; case IRDMA_AE_LLP_CONNECTION_ESTABLISHED: cm_node = iwqp->cm_node; if (cm_node->accept_pend) { atomic_dec(&cm_node->listener->pend_accepts_cnt); cm_node->accept_pend = 0; } iwqp->rts_ae_rcvd = 1; wake_up_interruptible(&iwqp->waitq); break; case IRDMA_AE_LLP_FIN_RECEIVED: case IRDMA_AE_RDMAP_ROE_BAD_LLP_CLOSE: if (qp->term_flags) break; if (atomic_inc_return(&iwqp->close_timer_started) == 1) { iwqp->hw_tcp_state = IRDMA_TCP_STATE_CLOSE_WAIT; if (iwqp->hw_tcp_state == IRDMA_TCP_STATE_CLOSE_WAIT && iwqp->ibqp_state == IB_QPS_RTS) { irdma_next_iw_state(iwqp, IRDMA_QP_STATE_CLOSING, 0, 0, 0); irdma_cm_disconn(iwqp); } irdma_schedule_cm_timer(iwqp->cm_node, (struct irdma_puda_buf *)iwqp, IRDMA_TIMER_TYPE_CLOSE, 1, 0); } break; case IRDMA_AE_LLP_CLOSE_COMPLETE: if (qp->term_flags) irdma_terminate_done(qp, 0); else irdma_cm_disconn(iwqp); break; case IRDMA_AE_BAD_CLOSE: case IRDMA_AE_RESET_SENT: irdma_next_iw_state(iwqp, IRDMA_QP_STATE_ERROR, 1, 0, 0); irdma_cm_disconn(iwqp); break; case IRDMA_AE_LLP_CONNECTION_RESET: if (atomic_read(&iwqp->close_timer_started)) break; irdma_cm_disconn(iwqp); break; case IRDMA_AE_QP_SUSPEND_COMPLETE: if (iwqp->iwdev->vsi.tc_change_pending) { if (!atomic_dec_return(&qp->vsi->qp_suspend_reqs)) wake_up(&iwqp->iwdev->suspend_wq); } if (iwqp->suspend_pending) { iwqp->suspend_pending = false; wake_up(&iwqp->iwdev->suspend_wq); } break; case IRDMA_AE_TERMINATE_SENT: irdma_terminate_send_fin(qp); break; case IRDMA_AE_LLP_TERMINATE_RECEIVED: irdma_terminate_received(qp, info); break; case IRDMA_AE_CQ_OPERATION_ERROR: ibdev_err(&iwdev->ibdev, "Processing an iWARP related AE for CQ misc = 0x%04X\n", info->ae_id); spin_lock_irqsave(&rf->cqtable_lock, flags); iwcq = rf->cq_table[info->qp_cq_id]; if (!iwcq) { spin_unlock_irqrestore(&rf->cqtable_lock, flags); ibdev_dbg(to_ibdev(dev), "cq_id %d is already freed\n", info->qp_cq_id); continue; } irdma_cq_add_ref(&iwcq->ibcq); spin_unlock_irqrestore(&rf->cqtable_lock, flags); if (iwcq->ibcq.event_handler) { struct ib_event ibevent; ibevent.device = iwcq->ibcq.device; ibevent.event = IB_EVENT_CQ_ERR; ibevent.element.cq = &iwcq->ibcq; iwcq->ibcq.event_handler(&ibevent, iwcq->ibcq.cq_context); } irdma_cq_rem_ref(&iwcq->ibcq); break; case IRDMA_AE_RESET_NOT_SENT: case IRDMA_AE_LLP_DOUBT_REACHABILITY: case IRDMA_AE_RESOURCE_EXHAUSTION: break; case IRDMA_AE_PRIV_OPERATION_DENIED: case IRDMA_AE_STAG_ZERO_INVALID: case IRDMA_AE_IB_RREQ_AND_Q1_FULL: case IRDMA_AE_DDP_UBE_INVALID_DDP_VERSION: case IRDMA_AE_DDP_UBE_INVALID_MO: case IRDMA_AE_DDP_UBE_INVALID_QN: case IRDMA_AE_DDP_NO_L_BIT: case IRDMA_AE_RDMAP_ROE_INVALID_RDMAP_VERSION: case IRDMA_AE_RDMAP_ROE_UNEXPECTED_OPCODE: case IRDMA_AE_ROE_INVALID_RDMA_READ_REQUEST: case IRDMA_AE_ROE_INVALID_RDMA_WRITE_OR_READ_RESP: case IRDMA_AE_INVALID_ARP_ENTRY: case IRDMA_AE_INVALID_TCP_OPTION_RCVD: case IRDMA_AE_STALE_ARP_ENTRY: case IRDMA_AE_LLP_RECEIVED_MPA_CRC_ERROR: case IRDMA_AE_LLP_SEGMENT_TOO_SMALL: case IRDMA_AE_LLP_SYN_RECEIVED: case IRDMA_AE_LLP_TOO_MANY_RETRIES: case IRDMA_AE_LCE_QP_CATASTROPHIC: case IRDMA_AE_LCE_FUNCTION_CATASTROPHIC: case IRDMA_AE_LLP_TOO_MANY_RNRS: case IRDMA_AE_LCE_CQ_CATASTROPHIC: case IRDMA_AE_UDA_XMIT_DGRAM_TOO_LONG: default: ibdev_err(&iwdev->ibdev, "abnormal ae_id = 0x%x bool qp=%d qp_id = %d, ae_src=%d\n", info->ae_id, info->qp, info->qp_cq_id, info->ae_src); if (rdma_protocol_roce(&iwdev->ibdev, 1)) { ctx_info->roce_info->err_rq_idx_valid = info->rq; if (info->rq) { ctx_info->roce_info->err_rq_idx = info->wqe_idx; irdma_sc_qp_setctx_roce(&iwqp->sc_qp, iwqp->host_ctx.va, ctx_info); } irdma_set_flush_fields(qp, info); irdma_cm_disconn(iwqp); break; } ctx_info->iwarp_info->err_rq_idx_valid = info->rq; if (info->rq) { ctx_info->iwarp_info->err_rq_idx = info->wqe_idx; ctx_info->tcp_info_valid = false; ctx_info->iwarp_info_valid = true; irdma_sc_qp_setctx(&iwqp->sc_qp, iwqp->host_ctx.va, ctx_info); } if (iwqp->hw_iwarp_state != IRDMA_QP_STATE_RTS && iwqp->hw_iwarp_state != IRDMA_QP_STATE_TERMINATE) { irdma_next_iw_state(iwqp, IRDMA_QP_STATE_ERROR, 1, 0, 0); irdma_cm_disconn(iwqp); } else { irdma_terminate_connection(qp, info); } break; } if (info->qp) irdma_qp_rem_ref(&iwqp->ibqp); } while (1); if (aeqcnt) irdma_sc_repost_aeq_entries(dev, aeqcnt); } /** * irdma_ena_intr - set up device interrupts * @dev: hardware control device structure * @msix_id: id of the interrupt to be enabled */ static void irdma_ena_intr(struct irdma_sc_dev *dev, u32 msix_id) { dev->irq_ops->irdma_en_irq(dev, msix_id); } /** * irdma_dpc - tasklet for aeq and ceq 0 * @t: tasklet_struct ptr */ static void irdma_dpc(struct tasklet_struct *t) { struct irdma_pci_f *rf = from_tasklet(rf, t, dpc_tasklet); if (rf->msix_shared) irdma_process_ceq(rf, rf->ceqlist); irdma_process_aeq(rf); irdma_ena_intr(&rf->sc_dev, rf->iw_msixtbl[0].idx); } /** * irdma_ceq_dpc - dpc handler for CEQ * @t: tasklet_struct ptr */ static void irdma_ceq_dpc(struct tasklet_struct *t) { struct irdma_ceq *iwceq = from_tasklet(iwceq, t, dpc_tasklet); struct irdma_pci_f *rf = iwceq->rf; irdma_process_ceq(rf, iwceq); irdma_ena_intr(&rf->sc_dev, iwceq->msix_idx); } /** * irdma_save_msix_info - copy msix vector information to iwarp device * @rf: RDMA PCI function * * Allocate iwdev msix table and copy the msix info to the table * Return 0 if successful, otherwise return error */ static int irdma_save_msix_info(struct irdma_pci_f *rf) { struct irdma_qvlist_info *iw_qvlist; struct irdma_qv_info *iw_qvinfo; struct msix_entry *pmsix; u32 ceq_idx; u32 i; size_t size; if (!rf->msix_count) return -EINVAL; size = sizeof(struct irdma_msix_vector) * rf->msix_count; size += struct_size(iw_qvlist, qv_info, rf->msix_count); rf->iw_msixtbl = kzalloc(size, GFP_KERNEL); if (!rf->iw_msixtbl) return -ENOMEM; rf->iw_qvlist = (struct irdma_qvlist_info *) (&rf->iw_msixtbl[rf->msix_count]); iw_qvlist = rf->iw_qvlist; iw_qvinfo = iw_qvlist->qv_info; iw_qvlist->num_vectors = rf->msix_count; if (rf->msix_count <= num_online_cpus()) rf->msix_shared = true; else if (rf->msix_count > num_online_cpus() + 1) rf->msix_count = num_online_cpus() + 1; pmsix = rf->msix_entries; for (i = 0, ceq_idx = 0; i < rf->msix_count; i++, iw_qvinfo++) { rf->iw_msixtbl[i].idx = pmsix->entry; rf->iw_msixtbl[i].irq = pmsix->vector; rf->iw_msixtbl[i].cpu_affinity = ceq_idx; if (!i) { iw_qvinfo->aeq_idx = 0; if (rf->msix_shared) iw_qvinfo->ceq_idx = ceq_idx++; else iw_qvinfo->ceq_idx = IRDMA_Q_INVALID_IDX; } else { iw_qvinfo->aeq_idx = IRDMA_Q_INVALID_IDX; iw_qvinfo->ceq_idx = ceq_idx++; } iw_qvinfo->itr_idx = 3; iw_qvinfo->v_idx = rf->iw_msixtbl[i].idx; pmsix++; } return 0; } /** * irdma_irq_handler - interrupt handler for aeq and ceq0 * @irq: Interrupt request number * @data: RDMA PCI function */ static irqreturn_t irdma_irq_handler(int irq, void *data) { struct irdma_pci_f *rf = data; tasklet_schedule(&rf->dpc_tasklet); return IRQ_HANDLED; } /** * irdma_ceq_handler - interrupt handler for ceq * @irq: interrupt request number * @data: ceq pointer */ static irqreturn_t irdma_ceq_handler(int irq, void *data) { struct irdma_ceq *iwceq = data; if (iwceq->irq != irq) ibdev_err(to_ibdev(&iwceq->rf->sc_dev), "expected irq = %d received irq = %d\n", iwceq->irq, irq); tasklet_schedule(&iwceq->dpc_tasklet); return IRQ_HANDLED; } /** * irdma_destroy_irq - destroy device interrupts * @rf: RDMA PCI function * @msix_vec: msix vector to disable irq * @dev_id: parameter to pass to free_irq (used during irq setup) * * The function is called when destroying aeq/ceq */ static void irdma_destroy_irq(struct irdma_pci_f *rf, struct irdma_msix_vector *msix_vec, void *dev_id) { struct irdma_sc_dev *dev = &rf->sc_dev; dev->irq_ops->irdma_dis_irq(dev, msix_vec->idx); irq_update_affinity_hint(msix_vec->irq, NULL); free_irq(msix_vec->irq, dev_id); if (rf == dev_id) { tasklet_kill(&rf->dpc_tasklet); } else { struct irdma_ceq *iwceq = (struct irdma_ceq *)dev_id; tasklet_kill(&iwceq->dpc_tasklet); } } /** * irdma_destroy_cqp - destroy control qp * @rf: RDMA PCI function * * Issue destroy cqp request and * free the resources associated with the cqp */ static void irdma_destroy_cqp(struct irdma_pci_f *rf) { struct irdma_sc_dev *dev = &rf->sc_dev; struct irdma_cqp *cqp = &rf->cqp; int status = 0; status = irdma_sc_cqp_destroy(dev->cqp); if (status) ibdev_dbg(to_ibdev(dev), "ERR: Destroy CQP failed %d\n", status); irdma_cleanup_pending_cqp_op(rf); dma_free_coherent(dev->hw->device, cqp->sq.size, cqp->sq.va, cqp->sq.pa); cqp->sq.va = NULL; kfree(cqp->scratch_array); cqp->scratch_array = NULL; kfree(cqp->cqp_requests); cqp->cqp_requests = NULL; } static void irdma_destroy_virt_aeq(struct irdma_pci_f *rf) { struct irdma_aeq *aeq = &rf->aeq; u32 pg_cnt = DIV_ROUND_UP(aeq->mem.size, PAGE_SIZE); dma_addr_t *pg_arr = (dma_addr_t *)aeq->palloc.level1.addr; irdma_unmap_vm_page_list(&rf->hw, pg_arr, pg_cnt); irdma_free_pble(rf->pble_rsrc, &aeq->palloc); vfree(aeq->mem.va); } /** * irdma_destroy_aeq - destroy aeq * @rf: RDMA PCI function * * Issue a destroy aeq request and * free the resources associated with the aeq * The function is called during driver unload */ static void irdma_destroy_aeq(struct irdma_pci_f *rf) { struct irdma_sc_dev *dev = &rf->sc_dev; struct irdma_aeq *aeq = &rf->aeq; int status = -EBUSY; if (!rf->msix_shared) { rf->sc_dev.irq_ops->irdma_cfg_aeq(&rf->sc_dev, rf->iw_msixtbl->idx, false); irdma_destroy_irq(rf, rf->iw_msixtbl, rf); } if (rf->reset) goto exit; aeq->sc_aeq.size = 0; status = irdma_cqp_aeq_cmd(dev, &aeq->sc_aeq, IRDMA_OP_AEQ_DESTROY); if (status) ibdev_dbg(to_ibdev(dev), "ERR: Destroy AEQ failed %d\n", status); exit: if (aeq->virtual_map) { irdma_destroy_virt_aeq(rf); } else { dma_free_coherent(dev->hw->device, aeq->mem.size, aeq->mem.va, aeq->mem.pa); aeq->mem.va = NULL; } } /** * irdma_destroy_ceq - destroy ceq * @rf: RDMA PCI function * @iwceq: ceq to be destroyed * * Issue a destroy ceq request and * free the resources associated with the ceq */ static void irdma_destroy_ceq(struct irdma_pci_f *rf, struct irdma_ceq *iwceq) { struct irdma_sc_dev *dev = &rf->sc_dev; int status; if (rf->reset) goto exit; status = irdma_sc_ceq_destroy(&iwceq->sc_ceq, 0, 1); if (status) { ibdev_dbg(to_ibdev(dev), "ERR: CEQ destroy command failed %d\n", status); goto exit; } status = irdma_sc_cceq_destroy_done(&iwceq->sc_ceq); if (status) ibdev_dbg(to_ibdev(dev), "ERR: CEQ destroy completion failed %d\n", status); exit: dma_free_coherent(dev->hw->device, iwceq->mem.size, iwceq->mem.va, iwceq->mem.pa); iwceq->mem.va = NULL; } /** * irdma_del_ceq_0 - destroy ceq 0 * @rf: RDMA PCI function * * Disable the ceq 0 interrupt and destroy the ceq 0 */ static void irdma_del_ceq_0(struct irdma_pci_f *rf) { struct irdma_ceq *iwceq = rf->ceqlist; struct irdma_msix_vector *msix_vec; if (rf->msix_shared) { msix_vec = &rf->iw_msixtbl[0]; rf->sc_dev.irq_ops->irdma_cfg_ceq(&rf->sc_dev, msix_vec->ceq_id, msix_vec->idx, false); irdma_destroy_irq(rf, msix_vec, rf); } else { msix_vec = &rf->iw_msixtbl[1]; irdma_destroy_irq(rf, msix_vec, iwceq); } irdma_destroy_ceq(rf, iwceq); rf->sc_dev.ceq_valid = false; rf->ceqs_count = 0; } /** * irdma_del_ceqs - destroy all ceq's except CEQ 0 * @rf: RDMA PCI function * * Go through all of the device ceq's, except 0, and for each * ceq disable the ceq interrupt and destroy the ceq */ static void irdma_del_ceqs(struct irdma_pci_f *rf) { struct irdma_ceq *iwceq = &rf->ceqlist[1]; struct irdma_msix_vector *msix_vec; u32 i = 0; if (rf->msix_shared) msix_vec = &rf->iw_msixtbl[1]; else msix_vec = &rf->iw_msixtbl[2]; for (i = 1; i < rf->ceqs_count; i++, msix_vec++, iwceq++) { rf->sc_dev.irq_ops->irdma_cfg_ceq(&rf->sc_dev, msix_vec->ceq_id, msix_vec->idx, false); irdma_destroy_irq(rf, msix_vec, iwceq); irdma_cqp_ceq_cmd(&rf->sc_dev, &iwceq->sc_ceq, IRDMA_OP_CEQ_DESTROY); dma_free_coherent(rf->sc_dev.hw->device, iwceq->mem.size, iwceq->mem.va, iwceq->mem.pa); iwceq->mem.va = NULL; } rf->ceqs_count = 1; } /** * irdma_destroy_ccq - destroy control cq * @rf: RDMA PCI function * * Issue destroy ccq request and * free the resources associated with the ccq */ static void irdma_destroy_ccq(struct irdma_pci_f *rf) { struct irdma_sc_dev *dev = &rf->sc_dev; struct irdma_ccq *ccq = &rf->ccq; int status = 0; if (rf->cqp_cmpl_wq) destroy_workqueue(rf->cqp_cmpl_wq); if (!rf->reset) status = irdma_sc_ccq_destroy(dev->ccq, 0, true); if (status) ibdev_dbg(to_ibdev(dev), "ERR: CCQ destroy failed %d\n", status); dma_free_coherent(dev->hw->device, ccq->mem_cq.size, ccq->mem_cq.va, ccq->mem_cq.pa); ccq->mem_cq.va = NULL; } /** * irdma_close_hmc_objects_type - delete hmc objects of a given type * @dev: iwarp device * @obj_type: the hmc object type to be deleted * @hmc_info: host memory info struct * @privileged: permission to close HMC objects * @reset: true if called before reset */ static void irdma_close_hmc_objects_type(struct irdma_sc_dev *dev, enum irdma_hmc_rsrc_type obj_type, struct irdma_hmc_info *hmc_info, bool privileged, bool reset) { struct irdma_hmc_del_obj_info info = {}; info.hmc_info = hmc_info; info.rsrc_type = obj_type; info.count = hmc_info->hmc_obj[obj_type].cnt; info.privileged = privileged; if (irdma_sc_del_hmc_obj(dev, &info, reset)) ibdev_dbg(to_ibdev(dev), "ERR: del HMC obj of type %d failed\n", obj_type); } /** * irdma_del_hmc_objects - remove all device hmc objects * @dev: iwarp device * @hmc_info: hmc_info to free * @privileged: permission to delete HMC objects * @reset: true if called before reset * @vers: hardware version */ static void irdma_del_hmc_objects(struct irdma_sc_dev *dev, struct irdma_hmc_info *hmc_info, bool privileged, bool reset, enum irdma_vers vers) { unsigned int i; for (i = 0; i < IW_HMC_OBJ_TYPE_NUM; i++) { if (dev->hmc_info->hmc_obj[iw_hmc_obj_types[i]].cnt) irdma_close_hmc_objects_type(dev, iw_hmc_obj_types[i], hmc_info, privileged, reset); if (vers == IRDMA_GEN_1 && i == IRDMA_HMC_IW_TIMER) break; } } /** * irdma_create_hmc_obj_type - create hmc object of a given type * @dev: hardware control device structure * @info: information for the hmc object to create */ static int irdma_create_hmc_obj_type(struct irdma_sc_dev *dev, struct irdma_hmc_create_obj_info *info) { return irdma_sc_create_hmc_obj(dev, info); } /** * irdma_create_hmc_objs - create all hmc objects for the device * @rf: RDMA PCI function * @privileged: permission to create HMC objects * @vers: HW version * * Create the device hmc objects and allocate hmc pages * Return 0 if successful, otherwise clean up and return error */ static int irdma_create_hmc_objs(struct irdma_pci_f *rf, bool privileged, enum irdma_vers vers) { struct irdma_sc_dev *dev = &rf->sc_dev; struct irdma_hmc_create_obj_info info = {}; int i, status = 0; info.hmc_info = dev->hmc_info; info.privileged = privileged; info.entry_type = rf->sd_type; for (i = 0; i < IW_HMC_OBJ_TYPE_NUM; i++) { if (iw_hmc_obj_types[i] == IRDMA_HMC_IW_PBLE) continue; if (dev->hmc_info->hmc_obj[iw_hmc_obj_types[i]].cnt) { info.rsrc_type = iw_hmc_obj_types[i]; info.count = dev->hmc_info->hmc_obj[info.rsrc_type].cnt; info.add_sd_cnt = 0; status = irdma_create_hmc_obj_type(dev, &info); if (status) { ibdev_dbg(to_ibdev(dev), "ERR: create obj type %d status = %d\n", iw_hmc_obj_types[i], status); break; } } if (vers == IRDMA_GEN_1 && i == IRDMA_HMC_IW_TIMER) break; } if (!status) return irdma_sc_static_hmc_pages_allocated(dev->cqp, 0, dev->hmc_fn_id, true, true); while (i) { i--; /* destroy the hmc objects of a given type */ if (dev->hmc_info->hmc_obj[iw_hmc_obj_types[i]].cnt) irdma_close_hmc_objects_type(dev, iw_hmc_obj_types[i], dev->hmc_info, privileged, false); } return status; } /** * irdma_obj_aligned_mem - get aligned memory from device allocated memory * @rf: RDMA PCI function * @memptr: points to the memory addresses * @size: size of memory needed * @mask: mask for the aligned memory * * Get aligned memory of the requested size and * update the memptr to point to the new aligned memory * Return 0 if successful, otherwise return no memory error */ static int irdma_obj_aligned_mem(struct irdma_pci_f *rf, struct irdma_dma_mem *memptr, u32 size, u32 mask) { unsigned long va, newva; unsigned long extra; va = (unsigned long)rf->obj_next.va; newva = va; if (mask) newva = ALIGN(va, (unsigned long)mask + 1ULL); extra = newva - va; memptr->va = (u8 *)va + extra; memptr->pa = rf->obj_next.pa + extra; memptr->size = size; if (((u8 *)memptr->va + size) > ((u8 *)rf->obj_mem.va + rf->obj_mem.size)) return -ENOMEM; rf->obj_next.va = (u8 *)memptr->va + size; rf->obj_next.pa = memptr->pa + size; return 0; } /** * irdma_create_cqp - create control qp * @rf: RDMA PCI function * * Return 0, if the cqp and all the resources associated with it * are successfully created, otherwise return error */ static int irdma_create_cqp(struct irdma_pci_f *rf) { u32 sqsize = IRDMA_CQP_SW_SQSIZE_2048; struct irdma_dma_mem mem; struct irdma_sc_dev *dev = &rf->sc_dev; struct irdma_cqp_init_info cqp_init_info = {}; struct irdma_cqp *cqp = &rf->cqp; u16 maj_err, min_err; int i, status; cqp->cqp_requests = kcalloc(sqsize, sizeof(*cqp->cqp_requests), GFP_KERNEL); if (!cqp->cqp_requests) return -ENOMEM; cqp->scratch_array = kcalloc(sqsize, sizeof(*cqp->scratch_array), GFP_KERNEL); if (!cqp->scratch_array) { status = -ENOMEM; goto err_scratch; } dev->cqp = &cqp->sc_cqp; dev->cqp->dev = dev; cqp->sq.size = ALIGN(sizeof(struct irdma_cqp_sq_wqe) * sqsize, IRDMA_CQP_ALIGNMENT); cqp->sq.va = dma_alloc_coherent(dev->hw->device, cqp->sq.size, &cqp->sq.pa, GFP_KERNEL); if (!cqp->sq.va) { status = -ENOMEM; goto err_sq; } status = irdma_obj_aligned_mem(rf, &mem, sizeof(struct irdma_cqp_ctx), IRDMA_HOST_CTX_ALIGNMENT_M); if (status) goto err_ctx; dev->cqp->host_ctx_pa = mem.pa; dev->cqp->host_ctx = mem.va; /* populate the cqp init info */ cqp_init_info.dev = dev; cqp_init_info.sq_size = sqsize; cqp_init_info.sq = cqp->sq.va; cqp_init_info.sq_pa = cqp->sq.pa; cqp_init_info.host_ctx_pa = mem.pa; cqp_init_info.host_ctx = mem.va; cqp_init_info.hmc_profile = rf->rsrc_profile; cqp_init_info.scratch_array = cqp->scratch_array; cqp_init_info.protocol_used = rf->protocol_used; switch (rf->rdma_ver) { case IRDMA_GEN_1: cqp_init_info.hw_maj_ver = IRDMA_CQPHC_HW_MAJVER_GEN_1; break; case IRDMA_GEN_2: cqp_init_info.hw_maj_ver = IRDMA_CQPHC_HW_MAJVER_GEN_2; break; } status = irdma_sc_cqp_init(dev->cqp, &cqp_init_info); if (status) { ibdev_dbg(to_ibdev(dev), "ERR: cqp init status %d\n", status); goto err_ctx; } spin_lock_init(&cqp->req_lock); spin_lock_init(&cqp->compl_lock); status = irdma_sc_cqp_create(dev->cqp, &maj_err, &min_err); if (status) { ibdev_dbg(to_ibdev(dev), "ERR: cqp create failed - status %d maj_err %d min_err %d\n", status, maj_err, min_err); goto err_ctx; } INIT_LIST_HEAD(&cqp->cqp_avail_reqs); INIT_LIST_HEAD(&cqp->cqp_pending_reqs); /* init the waitqueue of the cqp_requests and add them to the list */ for (i = 0; i < sqsize; i++) { init_waitqueue_head(&cqp->cqp_requests[i].waitq); list_add_tail(&cqp->cqp_requests[i].list, &cqp->cqp_avail_reqs); } init_waitqueue_head(&cqp->remove_wq); return 0; err_ctx: dma_free_coherent(dev->hw->device, cqp->sq.size, cqp->sq.va, cqp->sq.pa); cqp->sq.va = NULL; err_sq: kfree(cqp->scratch_array); cqp->scratch_array = NULL; err_scratch: kfree(cqp->cqp_requests); cqp->cqp_requests = NULL; return status; } /** * irdma_create_ccq - create control cq * @rf: RDMA PCI function * * Return 0, if the ccq and the resources associated with it * are successfully created, otherwise return error */ static int irdma_create_ccq(struct irdma_pci_f *rf) { struct irdma_sc_dev *dev = &rf->sc_dev; struct irdma_ccq_init_info info = {}; struct irdma_ccq *ccq = &rf->ccq; int status; dev->ccq = &ccq->sc_cq; dev->ccq->dev = dev; info.dev = dev; ccq->shadow_area.size = sizeof(struct irdma_cq_shadow_area); ccq->mem_cq.size = ALIGN(sizeof(struct irdma_cqe) * IW_CCQ_SIZE, IRDMA_CQ0_ALIGNMENT); ccq->mem_cq.va = dma_alloc_coherent(dev->hw->device, ccq->mem_cq.size, &ccq->mem_cq.pa, GFP_KERNEL); if (!ccq->mem_cq.va) return -ENOMEM; status = irdma_obj_aligned_mem(rf, &ccq->shadow_area, ccq->shadow_area.size, IRDMA_SHADOWAREA_M); if (status) goto exit; ccq->sc_cq.back_cq = ccq; /* populate the ccq init info */ info.cq_base = ccq->mem_cq.va; info.cq_pa = ccq->mem_cq.pa; info.num_elem = IW_CCQ_SIZE; info.shadow_area = ccq->shadow_area.va; info.shadow_area_pa = ccq->shadow_area.pa; info.ceqe_mask = false; info.ceq_id_valid = true; info.shadow_read_threshold = 16; info.vsi = &rf->default_vsi; status = irdma_sc_ccq_init(dev->ccq, &info); if (!status) status = irdma_sc_ccq_create(dev->ccq, 0, true, true); exit: if (status) { dma_free_coherent(dev->hw->device, ccq->mem_cq.size, ccq->mem_cq.va, ccq->mem_cq.pa); ccq->mem_cq.va = NULL; } return status; } /** * irdma_alloc_set_mac - set up a mac address table entry * @iwdev: irdma device * * Allocate a mac ip entry and add it to the hw table Return 0 * if successful, otherwise return error */ static int irdma_alloc_set_mac(struct irdma_device *iwdev) { int status; status = irdma_alloc_local_mac_entry(iwdev->rf, &iwdev->mac_ip_table_idx); if (!status) { status = irdma_add_local_mac_entry(iwdev->rf, (const u8 *)iwdev->netdev->dev_addr, (u8)iwdev->mac_ip_table_idx); if (status) irdma_del_local_mac_entry(iwdev->rf, (u8)iwdev->mac_ip_table_idx); } return status; } /** * irdma_cfg_ceq_vector - set up the msix interrupt vector for * ceq * @rf: RDMA PCI function * @iwceq: ceq associated with the vector * @ceq_id: the id number of the iwceq * @msix_vec: interrupt vector information * * Allocate interrupt resources and enable irq handling * Return 0 if successful, otherwise return error */ static int irdma_cfg_ceq_vector(struct irdma_pci_f *rf, struct irdma_ceq *iwceq, u32 ceq_id, struct irdma_msix_vector *msix_vec) { int status; if (rf->msix_shared && !ceq_id) { snprintf(msix_vec->name, sizeof(msix_vec->name) - 1, "irdma-%s-AEQCEQ-0", dev_name(&rf->pcidev->dev)); tasklet_setup(&rf->dpc_tasklet, irdma_dpc); status = request_irq(msix_vec->irq, irdma_irq_handler, 0, msix_vec->name, rf); } else { snprintf(msix_vec->name, sizeof(msix_vec->name) - 1, "irdma-%s-CEQ-%d", dev_name(&rf->pcidev->dev), ceq_id); tasklet_setup(&iwceq->dpc_tasklet, irdma_ceq_dpc); status = request_irq(msix_vec->irq, irdma_ceq_handler, 0, msix_vec->name, iwceq); } cpumask_clear(&msix_vec->mask); cpumask_set_cpu(msix_vec->cpu_affinity, &msix_vec->mask); irq_update_affinity_hint(msix_vec->irq, &msix_vec->mask); if (status) { ibdev_dbg(&rf->iwdev->ibdev, "ERR: ceq irq config fail\n"); return status; } msix_vec->ceq_id = ceq_id; rf->sc_dev.irq_ops->irdma_cfg_ceq(&rf->sc_dev, ceq_id, msix_vec->idx, true); return 0; } /** * irdma_cfg_aeq_vector - set up the msix vector for aeq * @rf: RDMA PCI function * * Allocate interrupt resources and enable irq handling * Return 0 if successful, otherwise return error */ static int irdma_cfg_aeq_vector(struct irdma_pci_f *rf) { struct irdma_msix_vector *msix_vec = rf->iw_msixtbl; u32 ret = 0; if (!rf->msix_shared) { snprintf(msix_vec->name, sizeof(msix_vec->name) - 1, "irdma-%s-AEQ", dev_name(&rf->pcidev->dev)); tasklet_setup(&rf->dpc_tasklet, irdma_dpc); ret = request_irq(msix_vec->irq, irdma_irq_handler, 0, msix_vec->name, rf); } if (ret) { ibdev_dbg(&rf->iwdev->ibdev, "ERR: aeq irq config fail\n"); return -EINVAL; } rf->sc_dev.irq_ops->irdma_cfg_aeq(&rf->sc_dev, msix_vec->idx, true); return 0; } /** * irdma_create_ceq - create completion event queue * @rf: RDMA PCI function * @iwceq: pointer to the ceq resources to be created * @ceq_id: the id number of the iwceq * @vsi: SC vsi struct * * Return 0, if the ceq and the resources associated with it * are successfully created, otherwise return error */ static int irdma_create_ceq(struct irdma_pci_f *rf, struct irdma_ceq *iwceq, u32 ceq_id, struct irdma_sc_vsi *vsi) { int status; struct irdma_ceq_init_info info = {}; struct irdma_sc_dev *dev = &rf->sc_dev; u32 ceq_size; info.ceq_id = ceq_id; iwceq->rf = rf; ceq_size = min(rf->sc_dev.hmc_info->hmc_obj[IRDMA_HMC_IW_CQ].cnt, dev->hw_attrs.max_hw_ceq_size); iwceq->mem.size = ALIGN(sizeof(struct irdma_ceqe) * ceq_size, IRDMA_CEQ_ALIGNMENT); iwceq->mem.va = dma_alloc_coherent(dev->hw->device, iwceq->mem.size, &iwceq->mem.pa, GFP_KERNEL); if (!iwceq->mem.va) return -ENOMEM; info.ceq_id = ceq_id; info.ceqe_base = iwceq->mem.va; info.ceqe_pa = iwceq->mem.pa; info.elem_cnt = ceq_size; iwceq->sc_ceq.ceq_id = ceq_id; info.dev = dev; info.vsi = vsi; status = irdma_sc_ceq_init(&iwceq->sc_ceq, &info); if (!status) { if (dev->ceq_valid) status = irdma_cqp_ceq_cmd(&rf->sc_dev, &iwceq->sc_ceq, IRDMA_OP_CEQ_CREATE); else status = irdma_sc_cceq_create(&iwceq->sc_ceq, 0); } if (status) { dma_free_coherent(dev->hw->device, iwceq->mem.size, iwceq->mem.va, iwceq->mem.pa); iwceq->mem.va = NULL; } return status; } /** * irdma_setup_ceq_0 - create CEQ 0 and it's interrupt resource * @rf: RDMA PCI function * * Allocate a list for all device completion event queues * Create the ceq 0 and configure it's msix interrupt vector * Return 0, if successfully set up, otherwise return error */ static int irdma_setup_ceq_0(struct irdma_pci_f *rf) { struct irdma_ceq *iwceq; struct irdma_msix_vector *msix_vec; u32 i; int status = 0; u32 num_ceqs; num_ceqs = min(rf->msix_count, rf->sc_dev.hmc_fpm_misc.max_ceqs); rf->ceqlist = kcalloc(num_ceqs, sizeof(*rf->ceqlist), GFP_KERNEL); if (!rf->ceqlist) { status = -ENOMEM; goto exit; } iwceq = &rf->ceqlist[0]; status = irdma_create_ceq(rf, iwceq, 0, &rf->default_vsi); if (status) { ibdev_dbg(&rf->iwdev->ibdev, "ERR: create ceq status = %d\n", status); goto exit; } spin_lock_init(&iwceq->ce_lock); i = rf->msix_shared ? 0 : 1; msix_vec = &rf->iw_msixtbl[i]; iwceq->irq = msix_vec->irq; iwceq->msix_idx = msix_vec->idx; status = irdma_cfg_ceq_vector(rf, iwceq, 0, msix_vec); if (status) { irdma_destroy_ceq(rf, iwceq); goto exit; } irdma_ena_intr(&rf->sc_dev, msix_vec->idx); rf->ceqs_count++; exit: if (status && !rf->ceqs_count) { kfree(rf->ceqlist); rf->ceqlist = NULL; return status; } rf->sc_dev.ceq_valid = true; return 0; } /** * irdma_setup_ceqs - manage the device ceq's and their interrupt resources * @rf: RDMA PCI function * @vsi: VSI structure for this CEQ * * Allocate a list for all device completion event queues * Create the ceq's and configure their msix interrupt vectors * Return 0, if ceqs are successfully set up, otherwise return error */ static int irdma_setup_ceqs(struct irdma_pci_f *rf, struct irdma_sc_vsi *vsi) { u32 i; u32 ceq_id; struct irdma_ceq *iwceq; struct irdma_msix_vector *msix_vec; int status; u32 num_ceqs; num_ceqs = min(rf->msix_count, rf->sc_dev.hmc_fpm_misc.max_ceqs); i = (rf->msix_shared) ? 1 : 2; for (ceq_id = 1; i < num_ceqs; i++, ceq_id++) { iwceq = &rf->ceqlist[ceq_id]; status = irdma_create_ceq(rf, iwceq, ceq_id, vsi); if (status) { ibdev_dbg(&rf->iwdev->ibdev, "ERR: create ceq status = %d\n", status); goto del_ceqs; } spin_lock_init(&iwceq->ce_lock); msix_vec = &rf->iw_msixtbl[i]; iwceq->irq = msix_vec->irq; iwceq->msix_idx = msix_vec->idx; status = irdma_cfg_ceq_vector(rf, iwceq, ceq_id, msix_vec); if (status) { irdma_destroy_ceq(rf, iwceq); goto del_ceqs; } irdma_ena_intr(&rf->sc_dev, msix_vec->idx); rf->ceqs_count++; } return 0; del_ceqs: irdma_del_ceqs(rf); return status; } static int irdma_create_virt_aeq(struct irdma_pci_f *rf, u32 size) { struct irdma_aeq *aeq = &rf->aeq; dma_addr_t *pg_arr; u32 pg_cnt; int status; if (rf->rdma_ver < IRDMA_GEN_2) return -EOPNOTSUPP; aeq->mem.size = sizeof(struct irdma_sc_aeqe) * size; aeq->mem.va = vzalloc(aeq->mem.size); if (!aeq->mem.va) return -ENOMEM; pg_cnt = DIV_ROUND_UP(aeq->mem.size, PAGE_SIZE); status = irdma_get_pble(rf->pble_rsrc, &aeq->palloc, pg_cnt, true); if (status) { vfree(aeq->mem.va); return status; } pg_arr = (dma_addr_t *)aeq->palloc.level1.addr; status = irdma_map_vm_page_list(&rf->hw, aeq->mem.va, pg_arr, pg_cnt); if (status) { irdma_free_pble(rf->pble_rsrc, &aeq->palloc); vfree(aeq->mem.va); return status; } return 0; } /** * irdma_create_aeq - create async event queue * @rf: RDMA PCI function * * Return 0, if the aeq and the resources associated with it * are successfully created, otherwise return error */ static int irdma_create_aeq(struct irdma_pci_f *rf) { struct irdma_aeq_init_info info = {}; struct irdma_sc_dev *dev = &rf->sc_dev; struct irdma_aeq *aeq = &rf->aeq; struct irdma_hmc_info *hmc_info = rf->sc_dev.hmc_info; u32 aeq_size; u8 multiplier = (rf->protocol_used == IRDMA_IWARP_PROTOCOL_ONLY) ? 2 : 1; int status; aeq_size = multiplier * hmc_info->hmc_obj[IRDMA_HMC_IW_QP].cnt + hmc_info->hmc_obj[IRDMA_HMC_IW_CQ].cnt; aeq_size = min(aeq_size, dev->hw_attrs.max_hw_aeq_size); aeq->mem.size = ALIGN(sizeof(struct irdma_sc_aeqe) * aeq_size, IRDMA_AEQ_ALIGNMENT); aeq->mem.va = dma_alloc_coherent(dev->hw->device, aeq->mem.size, &aeq->mem.pa, GFP_KERNEL | __GFP_NOWARN); if (aeq->mem.va) goto skip_virt_aeq; /* physically mapped aeq failed. setup virtual aeq */ status = irdma_create_virt_aeq(rf, aeq_size); if (status) return status; info.virtual_map = true; aeq->virtual_map = info.virtual_map; info.pbl_chunk_size = 1; info.first_pm_pbl_idx = aeq->palloc.level1.idx; skip_virt_aeq: info.aeqe_base = aeq->mem.va; info.aeq_elem_pa = aeq->mem.pa; info.elem_cnt = aeq_size; info.dev = dev; info.msix_idx = rf->iw_msixtbl->idx; status = irdma_sc_aeq_init(&aeq->sc_aeq, &info); if (status) goto err; status = irdma_cqp_aeq_cmd(dev, &aeq->sc_aeq, IRDMA_OP_AEQ_CREATE); if (status) goto err; return 0; err: if (aeq->virtual_map) { irdma_destroy_virt_aeq(rf); } else { dma_free_coherent(dev->hw->device, aeq->mem.size, aeq->mem.va, aeq->mem.pa); aeq->mem.va = NULL; } return status; } /** * irdma_setup_aeq - set up the device aeq * @rf: RDMA PCI function * * Create the aeq and configure its msix interrupt vector * Return 0 if successful, otherwise return error */ static int irdma_setup_aeq(struct irdma_pci_f *rf) { struct irdma_sc_dev *dev = &rf->sc_dev; int status; status = irdma_create_aeq(rf); if (status) return status; status = irdma_cfg_aeq_vector(rf); if (status) { irdma_destroy_aeq(rf); return status; } if (!rf->msix_shared) irdma_ena_intr(dev, rf->iw_msixtbl[0].idx); return 0; } /** * irdma_initialize_ilq - create iwarp local queue for cm * @iwdev: irdma device * * Return 0 if successful, otherwise return error */ static int irdma_initialize_ilq(struct irdma_device *iwdev) { struct irdma_puda_rsrc_info info = {}; int status; info.type = IRDMA_PUDA_RSRC_TYPE_ILQ; info.cq_id = 1; info.qp_id = 1; info.count = 1; info.pd_id = 1; info.abi_ver = IRDMA_ABI_VER; info.sq_size = min(iwdev->rf->max_qp / 2, (u32)32768); info.rq_size = info.sq_size; info.buf_size = 1024; info.tx_buf_cnt = 2 * info.sq_size; info.receive = irdma_receive_ilq; info.xmit_complete = irdma_free_sqbuf; status = irdma_puda_create_rsrc(&iwdev->vsi, &info); if (status) ibdev_dbg(&iwdev->ibdev, "ERR: ilq create fail\n"); return status; } /** * irdma_initialize_ieq - create iwarp exception queue * @iwdev: irdma device * * Return 0 if successful, otherwise return error */ static int irdma_initialize_ieq(struct irdma_device *iwdev) { struct irdma_puda_rsrc_info info = {}; int status; info.type = IRDMA_PUDA_RSRC_TYPE_IEQ; info.cq_id = 2; info.qp_id = iwdev->vsi.exception_lan_q; info.count = 1; info.pd_id = 2; info.abi_ver = IRDMA_ABI_VER; info.sq_size = min(iwdev->rf->max_qp / 2, (u32)32768); info.rq_size = info.sq_size; info.buf_size = iwdev->vsi.mtu + IRDMA_IPV4_PAD; info.tx_buf_cnt = 4096; status = irdma_puda_create_rsrc(&iwdev->vsi, &info); if (status) ibdev_dbg(&iwdev->ibdev, "ERR: ieq create fail\n"); return status; } /** * irdma_reinitialize_ieq - destroy and re-create ieq * @vsi: VSI structure */ void irdma_reinitialize_ieq(struct irdma_sc_vsi *vsi) { struct irdma_device *iwdev = vsi->back_vsi; struct irdma_pci_f *rf = iwdev->rf; irdma_puda_dele_rsrc(vsi, IRDMA_PUDA_RSRC_TYPE_IEQ, false); if (irdma_initialize_ieq(iwdev)) { iwdev->rf->reset = true; rf->gen_ops.request_reset(rf); } } /** * irdma_hmc_setup - create hmc objects for the device * @rf: RDMA PCI function * * Set up the device private memory space for the number and size of * the hmc objects and create the objects * Return 0 if successful, otherwise return error */ static int irdma_hmc_setup(struct irdma_pci_f *rf) { int status; u32 qpcnt; qpcnt = rsrc_limits_table[rf->limits_sel].qplimit; rf->sd_type = IRDMA_SD_TYPE_DIRECT; status = irdma_cfg_fpm_val(&rf->sc_dev, qpcnt); if (status) return status; status = irdma_create_hmc_objs(rf, true, rf->rdma_ver); return status; } /** * irdma_del_init_mem - deallocate memory resources * @rf: RDMA PCI function */ static void irdma_del_init_mem(struct irdma_pci_f *rf) { struct irdma_sc_dev *dev = &rf->sc_dev; kfree(dev->hmc_info->sd_table.sd_entry); dev->hmc_info->sd_table.sd_entry = NULL; vfree(rf->mem_rsrc); rf->mem_rsrc = NULL; dma_free_coherent(rf->hw.device, rf->obj_mem.size, rf->obj_mem.va, rf->obj_mem.pa); rf->obj_mem.va = NULL; if (rf->rdma_ver != IRDMA_GEN_1) { bitmap_free(rf->allocated_ws_nodes); rf->allocated_ws_nodes = NULL; } kfree(rf->ceqlist); rf->ceqlist = NULL; kfree(rf->iw_msixtbl); rf->iw_msixtbl = NULL; kfree(rf->hmc_info_mem); rf->hmc_info_mem = NULL; } /** * irdma_initialize_dev - initialize device * @rf: RDMA PCI function * * Allocate memory for the hmc objects and initialize iwdev * Return 0 if successful, otherwise clean up the resources * and return error */ static int irdma_initialize_dev(struct irdma_pci_f *rf) { int status; struct irdma_sc_dev *dev = &rf->sc_dev; struct irdma_device_init_info info = {}; struct irdma_dma_mem mem; u32 size; size = sizeof(struct irdma_hmc_pble_rsrc) + sizeof(struct irdma_hmc_info) + (sizeof(struct irdma_hmc_obj_info) * IRDMA_HMC_IW_MAX); rf->hmc_info_mem = kzalloc(size, GFP_KERNEL); if (!rf->hmc_info_mem) return -ENOMEM; rf->pble_rsrc = (struct irdma_hmc_pble_rsrc *)rf->hmc_info_mem; dev->hmc_info = &rf->hw.hmc; dev->hmc_info->hmc_obj = (struct irdma_hmc_obj_info *) (rf->pble_rsrc + 1); status = irdma_obj_aligned_mem(rf, &mem, IRDMA_QUERY_FPM_BUF_SIZE, IRDMA_FPM_QUERY_BUF_ALIGNMENT_M); if (status) goto error; info.fpm_query_buf_pa = mem.pa; info.fpm_query_buf = mem.va; status = irdma_obj_aligned_mem(rf, &mem, IRDMA_COMMIT_FPM_BUF_SIZE, IRDMA_FPM_COMMIT_BUF_ALIGNMENT_M); if (status) goto error; info.fpm_commit_buf_pa = mem.pa; info.fpm_commit_buf = mem.va; info.bar0 = rf->hw.hw_addr; info.hmc_fn_id = rf->pf_id; info.hw = &rf->hw; status = irdma_sc_dev_init(rf->rdma_ver, &rf->sc_dev, &info); if (status) goto error; return status; error: kfree(rf->hmc_info_mem); rf->hmc_info_mem = NULL; return status; } /** * irdma_rt_deinit_hw - clean up the irdma device resources * @iwdev: irdma device * * remove the mac ip entry and ipv4/ipv6 addresses, destroy the * device queues and free the pble and the hmc objects */ void irdma_rt_deinit_hw(struct irdma_device *iwdev) { ibdev_dbg(&iwdev->ibdev, "INIT: state = %d\n", iwdev->init_state); switch (iwdev->init_state) { case IP_ADDR_REGISTERED: if (iwdev->rf->sc_dev.hw_attrs.uk_attrs.hw_rev == IRDMA_GEN_1) irdma_del_local_mac_entry(iwdev->rf, (u8)iwdev->mac_ip_table_idx); fallthrough; case AEQ_CREATED: case PBLE_CHUNK_MEM: case CEQS_CREATED: case IEQ_CREATED: if (!iwdev->roce_mode) irdma_puda_dele_rsrc(&iwdev->vsi, IRDMA_PUDA_RSRC_TYPE_IEQ, iwdev->rf->reset); fallthrough; case ILQ_CREATED: if (!iwdev->roce_mode) irdma_puda_dele_rsrc(&iwdev->vsi, IRDMA_PUDA_RSRC_TYPE_ILQ, iwdev->rf->reset); break; default: ibdev_warn(&iwdev->ibdev, "bad init_state = %d\n", iwdev->init_state); break; } irdma_cleanup_cm_core(&iwdev->cm_core); if (iwdev->vsi.pestat) { irdma_vsi_stats_free(&iwdev->vsi); kfree(iwdev->vsi.pestat); } if (iwdev->cleanup_wq) destroy_workqueue(iwdev->cleanup_wq); } static int irdma_setup_init_state(struct irdma_pci_f *rf) { int status; status = irdma_save_msix_info(rf); if (status) return status; rf->hw.device = &rf->pcidev->dev; rf->obj_mem.size = ALIGN(8192, IRDMA_HW_PAGE_SIZE); rf->obj_mem.va = dma_alloc_coherent(rf->hw.device, rf->obj_mem.size, &rf->obj_mem.pa, GFP_KERNEL); if (!rf->obj_mem.va) { status = -ENOMEM; goto clean_msixtbl; } rf->obj_next = rf->obj_mem; status = irdma_initialize_dev(rf); if (status) goto clean_obj_mem; return 0; clean_obj_mem: dma_free_coherent(rf->hw.device, rf->obj_mem.size, rf->obj_mem.va, rf->obj_mem.pa); rf->obj_mem.va = NULL; clean_msixtbl: kfree(rf->iw_msixtbl); rf->iw_msixtbl = NULL; return status; } /** * irdma_get_used_rsrc - determine resources used internally * @iwdev: irdma device * * Called at the end of open to get all internal allocations */ static void irdma_get_used_rsrc(struct irdma_device *iwdev) { iwdev->rf->used_pds = find_first_zero_bit(iwdev->rf->allocated_pds, iwdev->rf->max_pd); iwdev->rf->used_qps = find_first_zero_bit(iwdev->rf->allocated_qps, iwdev->rf->max_qp); iwdev->rf->used_cqs = find_first_zero_bit(iwdev->rf->allocated_cqs, iwdev->rf->max_cq); iwdev->rf->used_mrs = find_first_zero_bit(iwdev->rf->allocated_mrs, iwdev->rf->max_mr); } void irdma_ctrl_deinit_hw(struct irdma_pci_f *rf) { enum init_completion_state state = rf->init_state; rf->init_state = INVALID_STATE; if (rf->rsrc_created) { irdma_destroy_aeq(rf); irdma_destroy_pble_prm(rf->pble_rsrc); irdma_del_ceqs(rf); rf->rsrc_created = false; } switch (state) { case CEQ0_CREATED: irdma_del_ceq_0(rf); fallthrough; case CCQ_CREATED: irdma_destroy_ccq(rf); fallthrough; case HW_RSRC_INITIALIZED: case HMC_OBJS_CREATED: irdma_del_hmc_objects(&rf->sc_dev, rf->sc_dev.hmc_info, true, rf->reset, rf->rdma_ver); fallthrough; case CQP_CREATED: irdma_destroy_cqp(rf); fallthrough; case INITIAL_STATE: irdma_del_init_mem(rf); break; case INVALID_STATE: default: ibdev_warn(&rf->iwdev->ibdev, "bad init_state = %d\n", rf->init_state); break; } } /** * irdma_rt_init_hw - Initializes runtime portion of HW * @iwdev: irdma device * @l2params: qos, tc, mtu info from netdev driver * * Create device queues ILQ, IEQ, CEQs and PBLEs. Setup irdma * device resource objects. */ int irdma_rt_init_hw(struct irdma_device *iwdev, struct irdma_l2params *l2params) { struct irdma_pci_f *rf = iwdev->rf; struct irdma_sc_dev *dev = &rf->sc_dev; struct irdma_vsi_init_info vsi_info = {}; struct irdma_vsi_stats_info stats_info = {}; int status; vsi_info.dev = dev; vsi_info.back_vsi = iwdev; vsi_info.params = l2params; vsi_info.pf_data_vsi_num = iwdev->vsi_num; vsi_info.register_qset = rf->gen_ops.register_qset; vsi_info.unregister_qset = rf->gen_ops.unregister_qset; vsi_info.exception_lan_q = 2; irdma_sc_vsi_init(&iwdev->vsi, &vsi_info); status = irdma_setup_cm_core(iwdev, rf->rdma_ver); if (status) return status; stats_info.pestat = kzalloc(sizeof(*stats_info.pestat), GFP_KERNEL); if (!stats_info.pestat) { irdma_cleanup_cm_core(&iwdev->cm_core); return -ENOMEM; } stats_info.fcn_id = dev->hmc_fn_id; status = irdma_vsi_stats_init(&iwdev->vsi, &stats_info); if (status) { irdma_cleanup_cm_core(&iwdev->cm_core); kfree(stats_info.pestat); return status; } do { if (!iwdev->roce_mode) { status = irdma_initialize_ilq(iwdev); if (status) break; iwdev->init_state = ILQ_CREATED; status = irdma_initialize_ieq(iwdev); if (status) break; iwdev->init_state = IEQ_CREATED; } if (!rf->rsrc_created) { status = irdma_setup_ceqs(rf, &iwdev->vsi); if (status) break; iwdev->init_state = CEQS_CREATED; status = irdma_hmc_init_pble(&rf->sc_dev, rf->pble_rsrc); if (status) { irdma_del_ceqs(rf); break; } iwdev->init_state = PBLE_CHUNK_MEM; status = irdma_setup_aeq(rf); if (status) { irdma_destroy_pble_prm(rf->pble_rsrc); irdma_del_ceqs(rf); break; } iwdev->init_state = AEQ_CREATED; rf->rsrc_created = true; } if (iwdev->rf->sc_dev.hw_attrs.uk_attrs.hw_rev == IRDMA_GEN_1) irdma_alloc_set_mac(iwdev); irdma_add_ip(iwdev); iwdev->init_state = IP_ADDR_REGISTERED; /* handles asynch cleanup tasks - disconnect CM , free qp, * free cq bufs */ iwdev->cleanup_wq = alloc_workqueue("irdma-cleanup-wq", WQ_UNBOUND, WQ_UNBOUND_MAX_ACTIVE); if (!iwdev->cleanup_wq) return -ENOMEM; irdma_get_used_rsrc(iwdev); init_waitqueue_head(&iwdev->suspend_wq); return 0; } while (0); dev_err(&rf->pcidev->dev, "HW runtime init FAIL status = %d last cmpl = %d\n", status, iwdev->init_state); irdma_rt_deinit_hw(iwdev); return status; } /** * irdma_ctrl_init_hw - Initializes control portion of HW * @rf: RDMA PCI function * * Create admin queues, HMC obejcts and RF resource objects */ int irdma_ctrl_init_hw(struct irdma_pci_f *rf) { struct irdma_sc_dev *dev = &rf->sc_dev; int status; do { status = irdma_setup_init_state(rf); if (status) break; rf->init_state = INITIAL_STATE; status = irdma_create_cqp(rf); if (status) break; rf->init_state = CQP_CREATED; status = irdma_hmc_setup(rf); if (status) break; rf->init_state = HMC_OBJS_CREATED; status = irdma_initialize_hw_rsrc(rf); if (status) break; rf->init_state = HW_RSRC_INITIALIZED; status = irdma_create_ccq(rf); if (status) break; rf->init_state = CCQ_CREATED; dev->feature_info[IRDMA_FEATURE_FW_INFO] = IRDMA_FW_VER_DEFAULT; if (rf->rdma_ver != IRDMA_GEN_1) { status = irdma_get_rdma_features(dev); if (status) break; } status = irdma_setup_ceq_0(rf); if (status) break; rf->init_state = CEQ0_CREATED; /* Handles processing of CQP completions */ rf->cqp_cmpl_wq = alloc_ordered_workqueue("cqp_cmpl_wq", WQ_HIGHPRI); if (!rf->cqp_cmpl_wq) { status = -ENOMEM; break; } INIT_WORK(&rf->cqp_cmpl_work, cqp_compl_worker); irdma_sc_ccq_arm(dev->ccq); return 0; } while (0); dev_err(&rf->pcidev->dev, "IRDMA hardware initialization FAILED init_state=%d status=%d\n", rf->init_state, status); irdma_ctrl_deinit_hw(rf); return status; } /** * irdma_set_hw_rsrc - set hw memory resources. * @rf: RDMA PCI function */ static void irdma_set_hw_rsrc(struct irdma_pci_f *rf) { rf->allocated_qps = (void *)(rf->mem_rsrc + (sizeof(struct irdma_arp_entry) * rf->arp_table_size)); rf->allocated_cqs = &rf->allocated_qps[BITS_TO_LONGS(rf->max_qp)]; rf->allocated_mrs = &rf->allocated_cqs[BITS_TO_LONGS(rf->max_cq)]; rf->allocated_pds = &rf->allocated_mrs[BITS_TO_LONGS(rf->max_mr)]; rf->allocated_ahs = &rf->allocated_pds[BITS_TO_LONGS(rf->max_pd)]; rf->allocated_mcgs = &rf->allocated_ahs[BITS_TO_LONGS(rf->max_ah)]; rf->allocated_arps = &rf->allocated_mcgs[BITS_TO_LONGS(rf->max_mcg)]; rf->qp_table = (struct irdma_qp **) (&rf->allocated_arps[BITS_TO_LONGS(rf->arp_table_size)]); rf->cq_table = (struct irdma_cq **)(&rf->qp_table[rf->max_qp]); spin_lock_init(&rf->rsrc_lock); spin_lock_init(&rf->arp_lock); spin_lock_init(&rf->qptable_lock); spin_lock_init(&rf->cqtable_lock); spin_lock_init(&rf->qh_list_lock); } /** * irdma_calc_mem_rsrc_size - calculate memory resources size. * @rf: RDMA PCI function */ static u32 irdma_calc_mem_rsrc_size(struct irdma_pci_f *rf) { u32 rsrc_size; rsrc_size = sizeof(struct irdma_arp_entry) * rf->arp_table_size; rsrc_size += sizeof(unsigned long) * BITS_TO_LONGS(rf->max_qp); rsrc_size += sizeof(unsigned long) * BITS_TO_LONGS(rf->max_mr); rsrc_size += sizeof(unsigned long) * BITS_TO_LONGS(rf->max_cq); rsrc_size += sizeof(unsigned long) * BITS_TO_LONGS(rf->max_pd); rsrc_size += sizeof(unsigned long) * BITS_TO_LONGS(rf->arp_table_size); rsrc_size += sizeof(unsigned long) * BITS_TO_LONGS(rf->max_ah); rsrc_size += sizeof(unsigned long) * BITS_TO_LONGS(rf->max_mcg); rsrc_size += sizeof(struct irdma_qp **) * rf->max_qp; rsrc_size += sizeof(struct irdma_cq **) * rf->max_cq; return rsrc_size; } /** * irdma_initialize_hw_rsrc - initialize hw resource tracking array * @rf: RDMA PCI function */ u32 irdma_initialize_hw_rsrc(struct irdma_pci_f *rf) { u32 rsrc_size; u32 mrdrvbits; u32 ret; if (rf->rdma_ver != IRDMA_GEN_1) { rf->allocated_ws_nodes = bitmap_zalloc(IRDMA_MAX_WS_NODES, GFP_KERNEL); if (!rf->allocated_ws_nodes) return -ENOMEM; set_bit(0, rf->allocated_ws_nodes); rf->max_ws_node_id = IRDMA_MAX_WS_NODES; } rf->max_cqe = rf->sc_dev.hw_attrs.uk_attrs.max_hw_cq_size; rf->max_qp = rf->sc_dev.hmc_info->hmc_obj[IRDMA_HMC_IW_QP].cnt; rf->max_mr = rf->sc_dev.hmc_info->hmc_obj[IRDMA_HMC_IW_MR].cnt; rf->max_cq = rf->sc_dev.hmc_info->hmc_obj[IRDMA_HMC_IW_CQ].cnt; rf->max_pd = rf->sc_dev.hw_attrs.max_hw_pds; rf->arp_table_size = rf->sc_dev.hmc_info->hmc_obj[IRDMA_HMC_IW_ARP].cnt; rf->max_ah = rf->sc_dev.hmc_info->hmc_obj[IRDMA_HMC_IW_FSIAV].cnt; rf->max_mcg = rf->max_qp; rsrc_size = irdma_calc_mem_rsrc_size(rf); rf->mem_rsrc = vzalloc(rsrc_size); if (!rf->mem_rsrc) { ret = -ENOMEM; goto mem_rsrc_vzalloc_fail; } rf->arp_table = (struct irdma_arp_entry *)rf->mem_rsrc; irdma_set_hw_rsrc(rf); set_bit(0, rf->allocated_mrs); set_bit(0, rf->allocated_qps); set_bit(0, rf->allocated_cqs); set_bit(0, rf->allocated_pds); set_bit(0, rf->allocated_arps); set_bit(0, rf->allocated_ahs); set_bit(0, rf->allocated_mcgs); set_bit(2, rf->allocated_qps); /* qp 2 IEQ */ set_bit(1, rf->allocated_qps); /* qp 1 ILQ */ set_bit(1, rf->allocated_cqs); set_bit(1, rf->allocated_pds); set_bit(2, rf->allocated_cqs); set_bit(2, rf->allocated_pds); INIT_LIST_HEAD(&rf->mc_qht_list.list); /* stag index mask has a minimum of 14 bits */ mrdrvbits = 24 - max(get_count_order(rf->max_mr), 14); rf->mr_stagmask = ~(((1 << mrdrvbits) - 1) << (32 - mrdrvbits)); return 0; mem_rsrc_vzalloc_fail: bitmap_free(rf->allocated_ws_nodes); rf->allocated_ws_nodes = NULL; return ret; } /** * irdma_cqp_ce_handler - handle cqp completions * @rf: RDMA PCI function * @cq: cq for cqp completions */ void irdma_cqp_ce_handler(struct irdma_pci_f *rf, struct irdma_sc_cq *cq) { struct irdma_cqp_request *cqp_request; struct irdma_sc_dev *dev = &rf->sc_dev; u32 cqe_count = 0; struct irdma_ccq_cqe_info info; unsigned long flags; int ret; do { memset(&info, 0, sizeof(info)); spin_lock_irqsave(&rf->cqp.compl_lock, flags); ret = irdma_sc_ccq_get_cqe_info(cq, &info); spin_unlock_irqrestore(&rf->cqp.compl_lock, flags); if (ret) break; cqp_request = (struct irdma_cqp_request *) (unsigned long)info.scratch; if (info.error && irdma_cqp_crit_err(dev, cqp_request->info.cqp_cmd, info.maj_err_code, info.min_err_code)) ibdev_err(&rf->iwdev->ibdev, "cqp opcode = 0x%x maj_err_code = 0x%x min_err_code = 0x%x\n", info.op_code, info.maj_err_code, info.min_err_code); if (cqp_request) { cqp_request->compl_info.maj_err_code = info.maj_err_code; cqp_request->compl_info.min_err_code = info.min_err_code; cqp_request->compl_info.op_ret_val = info.op_ret_val; cqp_request->compl_info.error = info.error; if (cqp_request->waiting) { WRITE_ONCE(cqp_request->request_done, true); wake_up(&cqp_request->waitq); irdma_put_cqp_request(&rf->cqp, cqp_request); } else { if (cqp_request->callback_fcn) cqp_request->callback_fcn(cqp_request); irdma_put_cqp_request(&rf->cqp, cqp_request); } } cqe_count++; } while (1); if (cqe_count) { irdma_process_bh(dev); irdma_sc_ccq_arm(cq); } } /** * cqp_compl_worker - Handle cqp completions * @work: Pointer to work structure */ void cqp_compl_worker(struct work_struct *work) { struct irdma_pci_f *rf = container_of(work, struct irdma_pci_f, cqp_cmpl_work); struct irdma_sc_cq *cq = &rf->ccq.sc_cq; irdma_cqp_ce_handler(rf, cq); } /** * irdma_lookup_apbvt_entry - lookup hash table for an existing apbvt entry corresponding to port * @cm_core: cm's core * @port: port to identify apbvt entry */ static struct irdma_apbvt_entry *irdma_lookup_apbvt_entry(struct irdma_cm_core *cm_core, u16 port) { struct irdma_apbvt_entry *entry; hash_for_each_possible(cm_core->apbvt_hash_tbl, entry, hlist, port) { if (entry->port == port) { entry->use_cnt++; return entry; } } return NULL; } /** * irdma_next_iw_state - modify qp state * @iwqp: iwarp qp to modify * @state: next state for qp * @del_hash: del hash * @term: term message * @termlen: length of term message */ void irdma_next_iw_state(struct irdma_qp *iwqp, u8 state, u8 del_hash, u8 term, u8 termlen) { struct irdma_modify_qp_info info = {}; info.next_iwarp_state = state; info.remove_hash_idx = del_hash; info.cq_num_valid = true; info.arp_cache_idx_valid = true; info.dont_send_term = true; info.dont_send_fin = true; info.termlen = termlen; if (term & IRDMAQP_TERM_SEND_TERM_ONLY) info.dont_send_term = false; if (term & IRDMAQP_TERM_SEND_FIN_ONLY) info.dont_send_fin = false; if (iwqp->sc_qp.term_flags && state == IRDMA_QP_STATE_ERROR) info.reset_tcp_conn = true; iwqp->hw_iwarp_state = state; irdma_hw_modify_qp(iwqp->iwdev, iwqp, &info, 0); iwqp->iwarp_state = info.next_iwarp_state; } /** * irdma_del_local_mac_entry - remove a mac entry from the hw * table * @rf: RDMA PCI function * @idx: the index of the mac ip address to delete */ void irdma_del_local_mac_entry(struct irdma_pci_f *rf, u16 idx) { struct irdma_cqp *iwcqp = &rf->cqp; struct irdma_cqp_request *cqp_request; struct cqp_cmds_info *cqp_info; cqp_request = irdma_alloc_and_get_cqp_request(iwcqp, true); if (!cqp_request) return; cqp_info = &cqp_request->info; cqp_info->cqp_cmd = IRDMA_OP_DELETE_LOCAL_MAC_ENTRY; cqp_info->post_sq = 1; cqp_info->in.u.del_local_mac_entry.cqp = &iwcqp->sc_cqp; cqp_info->in.u.del_local_mac_entry.scratch = (uintptr_t)cqp_request; cqp_info->in.u.del_local_mac_entry.entry_idx = idx; cqp_info->in.u.del_local_mac_entry.ignore_ref_count = 0; irdma_handle_cqp_op(rf, cqp_request); irdma_put_cqp_request(iwcqp, cqp_request); } /** * irdma_add_local_mac_entry - add a mac ip address entry to the * hw table * @rf: RDMA PCI function * @mac_addr: pointer to mac address * @idx: the index of the mac ip address to add */ int irdma_add_local_mac_entry(struct irdma_pci_f *rf, const u8 *mac_addr, u16 idx) { struct irdma_local_mac_entry_info *info; struct irdma_cqp *iwcqp = &rf->cqp; struct irdma_cqp_request *cqp_request; struct cqp_cmds_info *cqp_info; int status; cqp_request = irdma_alloc_and_get_cqp_request(iwcqp, true); if (!cqp_request) return -ENOMEM; cqp_info = &cqp_request->info; cqp_info->post_sq = 1; info = &cqp_info->in.u.add_local_mac_entry.info; ether_addr_copy(info->mac_addr, mac_addr); info->entry_idx = idx; cqp_info->in.u.add_local_mac_entry.scratch = (uintptr_t)cqp_request; cqp_info->cqp_cmd = IRDMA_OP_ADD_LOCAL_MAC_ENTRY; cqp_info->in.u.add_local_mac_entry.cqp = &iwcqp->sc_cqp; cqp_info->in.u.add_local_mac_entry.scratch = (uintptr_t)cqp_request; status = irdma_handle_cqp_op(rf, cqp_request); irdma_put_cqp_request(iwcqp, cqp_request); return status; } /** * irdma_alloc_local_mac_entry - allocate a mac entry * @rf: RDMA PCI function * @mac_tbl_idx: the index of the new mac address * * Allocate a mac address entry and update the mac_tbl_idx * to hold the index of the newly created mac address * Return 0 if successful, otherwise return error */ int irdma_alloc_local_mac_entry(struct irdma_pci_f *rf, u16 *mac_tbl_idx) { struct irdma_cqp *iwcqp = &rf->cqp; struct irdma_cqp_request *cqp_request; struct cqp_cmds_info *cqp_info; int status = 0; cqp_request = irdma_alloc_and_get_cqp_request(iwcqp, true); if (!cqp_request) return -ENOMEM; cqp_info = &cqp_request->info; cqp_info->cqp_cmd = IRDMA_OP_ALLOC_LOCAL_MAC_ENTRY; cqp_info->post_sq = 1; cqp_info->in.u.alloc_local_mac_entry.cqp = &iwcqp->sc_cqp; cqp_info->in.u.alloc_local_mac_entry.scratch = (uintptr_t)cqp_request; status = irdma_handle_cqp_op(rf, cqp_request); if (!status) *mac_tbl_idx = (u16)cqp_request->compl_info.op_ret_val; irdma_put_cqp_request(iwcqp, cqp_request); return status; } /** * irdma_cqp_manage_apbvt_cmd - send cqp command manage apbvt * @iwdev: irdma device * @accel_local_port: port for apbvt * @add_port: add ordelete port */ static int irdma_cqp_manage_apbvt_cmd(struct irdma_device *iwdev, u16 accel_local_port, bool add_port) { struct irdma_apbvt_info *info; struct irdma_cqp_request *cqp_request; struct cqp_cmds_info *cqp_info; int status; cqp_request = irdma_alloc_and_get_cqp_request(&iwdev->rf->cqp, add_port); if (!cqp_request) return -ENOMEM; cqp_info = &cqp_request->info; info = &cqp_info->in.u.manage_apbvt_entry.info; memset(info, 0, sizeof(*info)); info->add = add_port; info->port = accel_local_port; cqp_info->cqp_cmd = IRDMA_OP_MANAGE_APBVT_ENTRY; cqp_info->post_sq = 1; cqp_info->in.u.manage_apbvt_entry.cqp = &iwdev->rf->cqp.sc_cqp; cqp_info->in.u.manage_apbvt_entry.scratch = (uintptr_t)cqp_request; ibdev_dbg(&iwdev->ibdev, "DEV: %s: port=0x%04x\n", (!add_port) ? "DELETE" : "ADD", accel_local_port); status = irdma_handle_cqp_op(iwdev->rf, cqp_request); irdma_put_cqp_request(&iwdev->rf->cqp, cqp_request); return status; } /** * irdma_add_apbvt - add tcp port to HW apbvt table * @iwdev: irdma device * @port: port for apbvt */ struct irdma_apbvt_entry *irdma_add_apbvt(struct irdma_device *iwdev, u16 port) { struct irdma_cm_core *cm_core = &iwdev->cm_core; struct irdma_apbvt_entry *entry; unsigned long flags; spin_lock_irqsave(&cm_core->apbvt_lock, flags); entry = irdma_lookup_apbvt_entry(cm_core, port); if (entry) { spin_unlock_irqrestore(&cm_core->apbvt_lock, flags); return entry; } entry = kzalloc(sizeof(*entry), GFP_ATOMIC); if (!entry) { spin_unlock_irqrestore(&cm_core->apbvt_lock, flags); return NULL; } entry->port = port; entry->use_cnt = 1; hash_add(cm_core->apbvt_hash_tbl, &entry->hlist, entry->port); spin_unlock_irqrestore(&cm_core->apbvt_lock, flags); if (irdma_cqp_manage_apbvt_cmd(iwdev, port, true)) { kfree(entry); return NULL; } return entry; } /** * irdma_del_apbvt - delete tcp port from HW apbvt table * @iwdev: irdma device * @entry: apbvt entry object */ void irdma_del_apbvt(struct irdma_device *iwdev, struct irdma_apbvt_entry *entry) { struct irdma_cm_core *cm_core = &iwdev->cm_core; unsigned long flags; spin_lock_irqsave(&cm_core->apbvt_lock, flags); if (--entry->use_cnt) { spin_unlock_irqrestore(&cm_core->apbvt_lock, flags); return; } hash_del(&entry->hlist); /* apbvt_lock is held across CQP delete APBVT OP (non-waiting) to * protect against race where add APBVT CQP can race ahead of the delete * APBVT for same port. */ irdma_cqp_manage_apbvt_cmd(iwdev, entry->port, false); kfree(entry); spin_unlock_irqrestore(&cm_core->apbvt_lock, flags); } /** * irdma_manage_arp_cache - manage hw arp cache * @rf: RDMA PCI function * @mac_addr: mac address ptr * @ip_addr: ip addr for arp cache * @ipv4: flag inicating IPv4 * @action: add, delete or modify */ void irdma_manage_arp_cache(struct irdma_pci_f *rf, const unsigned char *mac_addr, u32 *ip_addr, bool ipv4, u32 action) { struct irdma_add_arp_cache_entry_info *info; struct irdma_cqp_request *cqp_request; struct cqp_cmds_info *cqp_info; int arp_index; arp_index = irdma_arp_table(rf, ip_addr, ipv4, mac_addr, action); if (arp_index == -1) return; cqp_request = irdma_alloc_and_get_cqp_request(&rf->cqp, false); if (!cqp_request) return; cqp_info = &cqp_request->info; if (action == IRDMA_ARP_ADD) { cqp_info->cqp_cmd = IRDMA_OP_ADD_ARP_CACHE_ENTRY; info = &cqp_info->in.u.add_arp_cache_entry.info; memset(info, 0, sizeof(*info)); info->arp_index = (u16)arp_index; info->permanent = true; ether_addr_copy(info->mac_addr, mac_addr); cqp_info->in.u.add_arp_cache_entry.scratch = (uintptr_t)cqp_request; cqp_info->in.u.add_arp_cache_entry.cqp = &rf->cqp.sc_cqp; } else { cqp_info->cqp_cmd = IRDMA_OP_DELETE_ARP_CACHE_ENTRY; cqp_info->in.u.del_arp_cache_entry.scratch = (uintptr_t)cqp_request; cqp_info->in.u.del_arp_cache_entry.cqp = &rf->cqp.sc_cqp; cqp_info->in.u.del_arp_cache_entry.arp_index = arp_index; } cqp_info->post_sq = 1; irdma_handle_cqp_op(rf, cqp_request); irdma_put_cqp_request(&rf->cqp, cqp_request); } /** * irdma_send_syn_cqp_callback - do syn/ack after qhash * @cqp_request: qhash cqp completion */ static void irdma_send_syn_cqp_callback(struct irdma_cqp_request *cqp_request) { struct irdma_cm_node *cm_node = cqp_request->param; irdma_send_syn(cm_node, 1); irdma_rem_ref_cm_node(cm_node); } /** * irdma_manage_qhash - add or modify qhash * @iwdev: irdma device * @cminfo: cm info for qhash * @etype: type (syn or quad) * @mtype: type of qhash * @cmnode: cmnode associated with connection * @wait: wait for completion */ int irdma_manage_qhash(struct irdma_device *iwdev, struct irdma_cm_info *cminfo, enum irdma_quad_entry_type etype, enum irdma_quad_hash_manage_type mtype, void *cmnode, bool wait) { struct irdma_qhash_table_info *info; struct irdma_cqp *iwcqp = &iwdev->rf->cqp; struct irdma_cqp_request *cqp_request; struct cqp_cmds_info *cqp_info; struct irdma_cm_node *cm_node = cmnode; int status; cqp_request = irdma_alloc_and_get_cqp_request(iwcqp, wait); if (!cqp_request) return -ENOMEM; cqp_info = &cqp_request->info; info = &cqp_info->in.u.manage_qhash_table_entry.info; memset(info, 0, sizeof(*info)); info->vsi = &iwdev->vsi; info->manage = mtype; info->entry_type = etype; if (cminfo->vlan_id < VLAN_N_VID) { info->vlan_valid = true; info->vlan_id = cminfo->vlan_id; } else { info->vlan_valid = false; } info->ipv4_valid = cminfo->ipv4; info->user_pri = cminfo->user_pri; ether_addr_copy(info->mac_addr, iwdev->netdev->dev_addr); info->qp_num = cminfo->qh_qpid; info->dest_port = cminfo->loc_port; info->dest_ip[0] = cminfo->loc_addr[0]; info->dest_ip[1] = cminfo->loc_addr[1]; info->dest_ip[2] = cminfo->loc_addr[2]; info->dest_ip[3] = cminfo->loc_addr[3]; if (etype == IRDMA_QHASH_TYPE_TCP_ESTABLISHED || etype == IRDMA_QHASH_TYPE_UDP_UNICAST || etype == IRDMA_QHASH_TYPE_UDP_MCAST || etype == IRDMA_QHASH_TYPE_ROCE_MCAST || etype == IRDMA_QHASH_TYPE_ROCEV2_HW) { info->src_port = cminfo->rem_port; info->src_ip[0] = cminfo->rem_addr[0]; info->src_ip[1] = cminfo->rem_addr[1]; info->src_ip[2] = cminfo->rem_addr[2]; info->src_ip[3] = cminfo->rem_addr[3]; } if (cmnode) { cqp_request->callback_fcn = irdma_send_syn_cqp_callback; cqp_request->param = cmnode; if (!wait) refcount_inc(&cm_node->refcnt); } if (info->ipv4_valid) ibdev_dbg(&iwdev->ibdev, "CM: %s caller: %pS loc_port=0x%04x rem_port=0x%04x loc_addr=%pI4 rem_addr=%pI4 mac=%pM, vlan_id=%d cm_node=%p\n", (!mtype) ? "DELETE" : "ADD", __builtin_return_address(0), info->dest_port, info->src_port, info->dest_ip, info->src_ip, info->mac_addr, cminfo->vlan_id, cmnode ? cmnode : NULL); else ibdev_dbg(&iwdev->ibdev, "CM: %s caller: %pS loc_port=0x%04x rem_port=0x%04x loc_addr=%pI6 rem_addr=%pI6 mac=%pM, vlan_id=%d cm_node=%p\n", (!mtype) ? "DELETE" : "ADD", __builtin_return_address(0), info->dest_port, info->src_port, info->dest_ip, info->src_ip, info->mac_addr, cminfo->vlan_id, cmnode ? cmnode : NULL); cqp_info->in.u.manage_qhash_table_entry.cqp = &iwdev->rf->cqp.sc_cqp; cqp_info->in.u.manage_qhash_table_entry.scratch = (uintptr_t)cqp_request; cqp_info->cqp_cmd = IRDMA_OP_MANAGE_QHASH_TABLE_ENTRY; cqp_info->post_sq = 1; status = irdma_handle_cqp_op(iwdev->rf, cqp_request); if (status && cm_node && !wait) irdma_rem_ref_cm_node(cm_node); irdma_put_cqp_request(iwcqp, cqp_request); return status; } /** * irdma_hw_flush_wqes_callback - Check return code after flush * @cqp_request: qhash cqp completion */ static void irdma_hw_flush_wqes_callback(struct irdma_cqp_request *cqp_request) { struct irdma_qp_flush_info *hw_info; struct irdma_sc_qp *qp; struct irdma_qp *iwqp; struct cqp_cmds_info *cqp_info; cqp_info = &cqp_request->info; hw_info = &cqp_info->in.u.qp_flush_wqes.info; qp = cqp_info->in.u.qp_flush_wqes.qp; iwqp = qp->qp_uk.back_qp; if (cqp_request->compl_info.maj_err_code) return; if (hw_info->rq && (cqp_request->compl_info.min_err_code == IRDMA_CQP_COMPL_SQ_WQE_FLUSHED || cqp_request->compl_info.min_err_code == 0)) { /* RQ WQE flush was requested but did not happen */ qp->qp_uk.rq_flush_complete = true; } if (hw_info->sq && (cqp_request->compl_info.min_err_code == IRDMA_CQP_COMPL_RQ_WQE_FLUSHED || cqp_request->compl_info.min_err_code == 0)) { if (IRDMA_RING_MORE_WORK(qp->qp_uk.sq_ring)) { ibdev_err(&iwqp->iwdev->ibdev, "Flush QP[%d] failed, SQ has more work", qp->qp_uk.qp_id); irdma_ib_qp_event(iwqp, IRDMA_QP_EVENT_CATASTROPHIC); } qp->qp_uk.sq_flush_complete = true; } } /** * irdma_hw_flush_wqes - flush qp's wqe * @rf: RDMA PCI function * @qp: hardware control qp * @info: info for flush * @wait: flag wait for completion */ int irdma_hw_flush_wqes(struct irdma_pci_f *rf, struct irdma_sc_qp *qp, struct irdma_qp_flush_info *info, bool wait) { int status; struct irdma_qp_flush_info *hw_info; struct irdma_cqp_request *cqp_request; struct cqp_cmds_info *cqp_info; struct irdma_qp *iwqp = qp->qp_uk.back_qp; cqp_request = irdma_alloc_and_get_cqp_request(&rf->cqp, wait); if (!cqp_request) return -ENOMEM; cqp_info = &cqp_request->info; if (!wait) cqp_request->callback_fcn = irdma_hw_flush_wqes_callback; hw_info = &cqp_request->info.in.u.qp_flush_wqes.info; memcpy(hw_info, info, sizeof(*hw_info)); cqp_info->cqp_cmd = IRDMA_OP_QP_FLUSH_WQES; cqp_info->post_sq = 1; cqp_info->in.u.qp_flush_wqes.qp = qp; cqp_info->in.u.qp_flush_wqes.scratch = (uintptr_t)cqp_request; status = irdma_handle_cqp_op(rf, cqp_request); if (status) { qp->qp_uk.sq_flush_complete = true; qp->qp_uk.rq_flush_complete = true; irdma_put_cqp_request(&rf->cqp, cqp_request); return status; } if (!wait || cqp_request->compl_info.maj_err_code) goto put_cqp; if (info->rq) { if (cqp_request->compl_info.min_err_code == IRDMA_CQP_COMPL_SQ_WQE_FLUSHED || cqp_request->compl_info.min_err_code == 0) { /* RQ WQE flush was requested but did not happen */ qp->qp_uk.rq_flush_complete = true; } } if (info->sq) { if (cqp_request->compl_info.min_err_code == IRDMA_CQP_COMPL_RQ_WQE_FLUSHED || cqp_request->compl_info.min_err_code == 0) { /* * Handling case where WQE is posted to empty SQ when * flush has not completed */ if (IRDMA_RING_MORE_WORK(qp->qp_uk.sq_ring)) { struct irdma_cqp_request *new_req; if (!qp->qp_uk.sq_flush_complete) goto put_cqp; qp->qp_uk.sq_flush_complete = false; qp->flush_sq = false; info->rq = false; info->sq = true; new_req = irdma_alloc_and_get_cqp_request(&rf->cqp, true); if (!new_req) { status = -ENOMEM; goto put_cqp; } cqp_info = &new_req->info; hw_info = &new_req->info.in.u.qp_flush_wqes.info; memcpy(hw_info, info, sizeof(*hw_info)); cqp_info->cqp_cmd = IRDMA_OP_QP_FLUSH_WQES; cqp_info->post_sq = 1; cqp_info->in.u.qp_flush_wqes.qp = qp; cqp_info->in.u.qp_flush_wqes.scratch = (uintptr_t)new_req; status = irdma_handle_cqp_op(rf, new_req); if (new_req->compl_info.maj_err_code || new_req->compl_info.min_err_code != IRDMA_CQP_COMPL_SQ_WQE_FLUSHED || status) { ibdev_err(&iwqp->iwdev->ibdev, "fatal QP event: SQ in error but not flushed, qp: %d", iwqp->ibqp.qp_num); qp->qp_uk.sq_flush_complete = false; irdma_ib_qp_event(iwqp, IRDMA_QP_EVENT_CATASTROPHIC); } irdma_put_cqp_request(&rf->cqp, new_req); } else { /* SQ WQE flush was requested but did not happen */ qp->qp_uk.sq_flush_complete = true; } } else { if (!IRDMA_RING_MORE_WORK(qp->qp_uk.sq_ring)) qp->qp_uk.sq_flush_complete = true; } } ibdev_dbg(&rf->iwdev->ibdev, "VERBS: qp_id=%d qp_type=%d qpstate=%d ibqpstate=%d last_aeq=%d hw_iw_state=%d maj_err_code=%d min_err_code=%d\n", iwqp->ibqp.qp_num, rf->protocol_used, iwqp->iwarp_state, iwqp->ibqp_state, iwqp->last_aeq, iwqp->hw_iwarp_state, cqp_request->compl_info.maj_err_code, cqp_request->compl_info.min_err_code); put_cqp: irdma_put_cqp_request(&rf->cqp, cqp_request); return status; } /** * irdma_gen_ae - generate AE * @rf: RDMA PCI function * @qp: qp associated with AE * @info: info for ae * @wait: wait for completion */ void irdma_gen_ae(struct irdma_pci_f *rf, struct irdma_sc_qp *qp, struct irdma_gen_ae_info *info, bool wait) { struct irdma_gen_ae_info *ae_info; struct irdma_cqp_request *cqp_request; struct cqp_cmds_info *cqp_info; cqp_request = irdma_alloc_and_get_cqp_request(&rf->cqp, wait); if (!cqp_request) return; cqp_info = &cqp_request->info; ae_info = &cqp_request->info.in.u.gen_ae.info; memcpy(ae_info, info, sizeof(*ae_info)); cqp_info->cqp_cmd = IRDMA_OP_GEN_AE; cqp_info->post_sq = 1; cqp_info->in.u.gen_ae.qp = qp; cqp_info->in.u.gen_ae.scratch = (uintptr_t)cqp_request; irdma_handle_cqp_op(rf, cqp_request); irdma_put_cqp_request(&rf->cqp, cqp_request); } void irdma_flush_wqes(struct irdma_qp *iwqp, u32 flush_mask) { struct irdma_qp_flush_info info = {}; struct irdma_pci_f *rf = iwqp->iwdev->rf; u8 flush_code = iwqp->sc_qp.flush_code; if (!(flush_mask & IRDMA_FLUSH_SQ) && !(flush_mask & IRDMA_FLUSH_RQ)) return; /* Set flush info fields*/ info.sq = flush_mask & IRDMA_FLUSH_SQ; info.rq = flush_mask & IRDMA_FLUSH_RQ; /* Generate userflush errors in CQE */ info.sq_major_code = IRDMA_FLUSH_MAJOR_ERR; info.sq_minor_code = FLUSH_GENERAL_ERR; info.rq_major_code = IRDMA_FLUSH_MAJOR_ERR; info.rq_minor_code = FLUSH_GENERAL_ERR; info.userflushcode = true; if (flush_mask & IRDMA_REFLUSH) { if (info.sq) iwqp->sc_qp.flush_sq = false; if (info.rq) iwqp->sc_qp.flush_rq = false; } else { if (flush_code) { if (info.sq && iwqp->sc_qp.sq_flush_code) info.sq_minor_code = flush_code; if (info.rq && iwqp->sc_qp.rq_flush_code) info.rq_minor_code = flush_code; } if (!iwqp->user_mode) queue_delayed_work(iwqp->iwdev->cleanup_wq, &iwqp->dwork_flush, msecs_to_jiffies(IRDMA_FLUSH_DELAY_MS)); } /* Issue flush */ (void)irdma_hw_flush_wqes(rf, &iwqp->sc_qp, &info, flush_mask & IRDMA_FLUSH_WAIT); iwqp->flush_issued = true; }