/********************************************************************** * Author: Cavium, Inc. * * Contact: support@cavium.com * Please include "LiquidIO" in the subject. * * Copyright (c) 2003-2016 Cavium, Inc. * * This file is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License, Version 2, as * published by the Free Software Foundation. * * This file is distributed in the hope that it will be useful, but * AS-IS and WITHOUT ANY WARRANTY; without even the implied warranty * of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE, TITLE, or * NONINFRINGEMENT. See the GNU General Public License for more details. ***********************************************************************/ #include #include #include "liquidio_common.h" #include "octeon_droq.h" #include "octeon_iq.h" #include "response_manager.h" #include "octeon_device.h" #include "octeon_nic.h" #include "octeon_main.h" #include "octeon_network.h" /* OOM task polling interval */ #define LIO_OOM_POLL_INTERVAL_MS 250 #define OCTNIC_MAX_SG MAX_SKB_FRAGS /** * \brief Callback for getting interface configuration * @param status status of request * @param buf pointer to resp structure */ void lio_if_cfg_callback(struct octeon_device *oct, u32 status __attribute__((unused)), void *buf) { struct octeon_soft_command *sc = (struct octeon_soft_command *)buf; struct liquidio_if_cfg_context *ctx; struct liquidio_if_cfg_resp *resp; resp = (struct liquidio_if_cfg_resp *)sc->virtrptr; ctx = (struct liquidio_if_cfg_context *)sc->ctxptr; oct = lio_get_device(ctx->octeon_id); if (resp->status) dev_err(&oct->pci_dev->dev, "nic if cfg instruction failed. Status: %llx\n", CVM_CAST64(resp->status)); WRITE_ONCE(ctx->cond, 1); snprintf(oct->fw_info.liquidio_firmware_version, 32, "%s", resp->cfg_info.liquidio_firmware_version); /* This barrier is required to be sure that the response has been * written fully before waking up the handler */ wmb(); wake_up_interruptible(&ctx->wc); } /** * \brief Delete gather lists * @param lio per-network private data */ void lio_delete_glists(struct lio *lio) { struct octnic_gather *g; int i; kfree(lio->glist_lock); lio->glist_lock = NULL; if (!lio->glist) return; for (i = 0; i < lio->oct_dev->num_iqs; i++) { do { g = (struct octnic_gather *) lio_list_delete_head(&lio->glist[i]); kfree(g); } while (g); if (lio->glists_virt_base && lio->glists_virt_base[i] && lio->glists_dma_base && lio->glists_dma_base[i]) { lio_dma_free(lio->oct_dev, lio->glist_entry_size * lio->tx_qsize, lio->glists_virt_base[i], lio->glists_dma_base[i]); } } kfree(lio->glists_virt_base); lio->glists_virt_base = NULL; kfree(lio->glists_dma_base); lio->glists_dma_base = NULL; kfree(lio->glist); lio->glist = NULL; } /** * \brief Setup gather lists * @param lio per-network private data */ int lio_setup_glists(struct octeon_device *oct, struct lio *lio, int num_iqs) { struct octnic_gather *g; int i, j; lio->glist_lock = kcalloc(num_iqs, sizeof(*lio->glist_lock), GFP_KERNEL); if (!lio->glist_lock) return -ENOMEM; lio->glist = kcalloc(num_iqs, sizeof(*lio->glist), GFP_KERNEL); if (!lio->glist) { kfree(lio->glist_lock); lio->glist_lock = NULL; return -ENOMEM; } lio->glist_entry_size = ROUNDUP8((ROUNDUP4(OCTNIC_MAX_SG) >> 2) * OCT_SG_ENTRY_SIZE); /* allocate memory to store virtual and dma base address of * per glist consistent memory */ lio->glists_virt_base = kcalloc(num_iqs, sizeof(*lio->glists_virt_base), GFP_KERNEL); lio->glists_dma_base = kcalloc(num_iqs, sizeof(*lio->glists_dma_base), GFP_KERNEL); if (!lio->glists_virt_base || !lio->glists_dma_base) { lio_delete_glists(lio); return -ENOMEM; } for (i = 0; i < num_iqs; i++) { int numa_node = dev_to_node(&oct->pci_dev->dev); spin_lock_init(&lio->glist_lock[i]); INIT_LIST_HEAD(&lio->glist[i]); lio->glists_virt_base[i] = lio_dma_alloc(oct, lio->glist_entry_size * lio->tx_qsize, &lio->glists_dma_base[i]); if (!lio->glists_virt_base[i]) { lio_delete_glists(lio); return -ENOMEM; } for (j = 0; j < lio->tx_qsize; j++) { g = kzalloc_node(sizeof(*g), GFP_KERNEL, numa_node); if (!g) g = kzalloc(sizeof(*g), GFP_KERNEL); if (!g) break; g->sg = lio->glists_virt_base[i] + (j * lio->glist_entry_size); g->sg_dma_ptr = lio->glists_dma_base[i] + (j * lio->glist_entry_size); list_add_tail(&g->list, &lio->glist[i]); } if (j != lio->tx_qsize) { lio_delete_glists(lio); return -ENOMEM; } } return 0; } int liquidio_set_feature(struct net_device *netdev, int cmd, u16 param1) { struct lio *lio = GET_LIO(netdev); struct octeon_device *oct = lio->oct_dev; struct octnic_ctrl_pkt nctrl; int ret = 0; memset(&nctrl, 0, sizeof(struct octnic_ctrl_pkt)); nctrl.ncmd.u64 = 0; nctrl.ncmd.s.cmd = cmd; nctrl.ncmd.s.param1 = param1; nctrl.iq_no = lio->linfo.txpciq[0].s.q_no; nctrl.wait_time = 100; nctrl.netpndev = (u64)netdev; nctrl.cb_fn = liquidio_link_ctrl_cmd_completion; ret = octnet_send_nic_ctrl_pkt(lio->oct_dev, &nctrl); if (ret < 0) { dev_err(&oct->pci_dev->dev, "Feature change failed in core (ret: 0x%x)\n", ret); } return ret; } void octeon_report_tx_completion_to_bql(void *txq, unsigned int pkts_compl, unsigned int bytes_compl) { struct netdev_queue *netdev_queue = txq; netdev_tx_completed_queue(netdev_queue, pkts_compl, bytes_compl); } void octeon_update_tx_completion_counters(void *buf, int reqtype, unsigned int *pkts_compl, unsigned int *bytes_compl) { struct octnet_buf_free_info *finfo; struct sk_buff *skb = NULL; struct octeon_soft_command *sc; switch (reqtype) { case REQTYPE_NORESP_NET: case REQTYPE_NORESP_NET_SG: finfo = buf; skb = finfo->skb; break; case REQTYPE_RESP_NET_SG: case REQTYPE_RESP_NET: sc = buf; skb = sc->callback_arg; break; default: return; } (*pkts_compl)++; *bytes_compl += skb->len; } int octeon_report_sent_bytes_to_bql(void *buf, int reqtype) { struct octnet_buf_free_info *finfo; struct sk_buff *skb; struct octeon_soft_command *sc; struct netdev_queue *txq; switch (reqtype) { case REQTYPE_NORESP_NET: case REQTYPE_NORESP_NET_SG: finfo = buf; skb = finfo->skb; break; case REQTYPE_RESP_NET_SG: case REQTYPE_RESP_NET: sc = buf; skb = sc->callback_arg; break; default: return 0; } txq = netdev_get_tx_queue(skb->dev, skb_get_queue_mapping(skb)); netdev_tx_sent_queue(txq, skb->len); return netif_xmit_stopped(txq); } void liquidio_link_ctrl_cmd_completion(void *nctrl_ptr) { struct octnic_ctrl_pkt *nctrl = (struct octnic_ctrl_pkt *)nctrl_ptr; struct net_device *netdev = (struct net_device *)nctrl->netpndev; struct lio *lio = GET_LIO(netdev); struct octeon_device *oct = lio->oct_dev; u8 *mac; if (nctrl->completion && nctrl->response_code) { /* Signal whoever is interested that the response code from the * firmware has arrived. */ WRITE_ONCE(*nctrl->response_code, nctrl->status); complete(nctrl->completion); } if (nctrl->status) return; switch (nctrl->ncmd.s.cmd) { case OCTNET_CMD_CHANGE_DEVFLAGS: case OCTNET_CMD_SET_MULTI_LIST: case OCTNET_CMD_SET_UC_LIST: break; case OCTNET_CMD_CHANGE_MACADDR: mac = ((u8 *)&nctrl->udd[0]) + 2; if (nctrl->ncmd.s.param1) { /* vfidx is 0 based, but vf_num (param1) is 1 based */ int vfidx = nctrl->ncmd.s.param1 - 1; bool mac_is_admin_assigned = nctrl->ncmd.s.param2; if (mac_is_admin_assigned) netif_info(lio, probe, lio->netdev, "MAC Address %pM is configured for VF %d\n", mac, vfidx); } else { netif_info(lio, probe, lio->netdev, " MACAddr changed to %pM\n", mac); } break; case OCTNET_CMD_GPIO_ACCESS: netif_info(lio, probe, lio->netdev, "LED Flashing visual identification\n"); break; case OCTNET_CMD_ID_ACTIVE: netif_info(lio, probe, lio->netdev, "LED Flashing visual identification\n"); break; case OCTNET_CMD_LRO_ENABLE: dev_info(&oct->pci_dev->dev, "%s LRO Enabled\n", netdev->name); break; case OCTNET_CMD_LRO_DISABLE: dev_info(&oct->pci_dev->dev, "%s LRO Disabled\n", netdev->name); break; case OCTNET_CMD_VERBOSE_ENABLE: dev_info(&oct->pci_dev->dev, "%s Firmware debug enabled\n", netdev->name); break; case OCTNET_CMD_VERBOSE_DISABLE: dev_info(&oct->pci_dev->dev, "%s Firmware debug disabled\n", netdev->name); break; case OCTNET_CMD_VLAN_FILTER_CTL: if (nctrl->ncmd.s.param1) dev_info(&oct->pci_dev->dev, "%s VLAN filter enabled\n", netdev->name); else dev_info(&oct->pci_dev->dev, "%s VLAN filter disabled\n", netdev->name); break; case OCTNET_CMD_ADD_VLAN_FILTER: dev_info(&oct->pci_dev->dev, "%s VLAN filter %d added\n", netdev->name, nctrl->ncmd.s.param1); break; case OCTNET_CMD_DEL_VLAN_FILTER: dev_info(&oct->pci_dev->dev, "%s VLAN filter %d removed\n", netdev->name, nctrl->ncmd.s.param1); break; case OCTNET_CMD_SET_SETTINGS: dev_info(&oct->pci_dev->dev, "%s settings changed\n", netdev->name); break; /* Case to handle "OCTNET_CMD_TNL_RX_CSUM_CTL" * Command passed by NIC driver */ case OCTNET_CMD_TNL_RX_CSUM_CTL: if (nctrl->ncmd.s.param1 == OCTNET_CMD_RXCSUM_ENABLE) { netif_info(lio, probe, lio->netdev, "RX Checksum Offload Enabled\n"); } else if (nctrl->ncmd.s.param1 == OCTNET_CMD_RXCSUM_DISABLE) { netif_info(lio, probe, lio->netdev, "RX Checksum Offload Disabled\n"); } break; /* Case to handle "OCTNET_CMD_TNL_TX_CSUM_CTL" * Command passed by NIC driver */ case OCTNET_CMD_TNL_TX_CSUM_CTL: if (nctrl->ncmd.s.param1 == OCTNET_CMD_TXCSUM_ENABLE) { netif_info(lio, probe, lio->netdev, "TX Checksum Offload Enabled\n"); } else if (nctrl->ncmd.s.param1 == OCTNET_CMD_TXCSUM_DISABLE) { netif_info(lio, probe, lio->netdev, "TX Checksum Offload Disabled\n"); } break; /* Case to handle "OCTNET_CMD_VXLAN_PORT_CONFIG" * Command passed by NIC driver */ case OCTNET_CMD_VXLAN_PORT_CONFIG: if (nctrl->ncmd.s.more == OCTNET_CMD_VXLAN_PORT_ADD) { netif_info(lio, probe, lio->netdev, "VxLAN Destination UDP PORT:%d ADDED\n", nctrl->ncmd.s.param1); } else if (nctrl->ncmd.s.more == OCTNET_CMD_VXLAN_PORT_DEL) { netif_info(lio, probe, lio->netdev, "VxLAN Destination UDP PORT:%d DELETED\n", nctrl->ncmd.s.param1); } break; case OCTNET_CMD_SET_FLOW_CTL: netif_info(lio, probe, lio->netdev, "Set RX/TX flow control parameters\n"); break; case OCTNET_CMD_QUEUE_COUNT_CTL: netif_info(lio, probe, lio->netdev, "Queue count updated to %d\n", nctrl->ncmd.s.param1); break; default: dev_err(&oct->pci_dev->dev, "%s Unknown cmd %d\n", __func__, nctrl->ncmd.s.cmd); } } void octeon_pf_changed_vf_macaddr(struct octeon_device *oct, u8 *mac) { bool macaddr_changed = false; struct net_device *netdev; struct lio *lio; rtnl_lock(); netdev = oct->props[0].netdev; lio = GET_LIO(netdev); lio->linfo.macaddr_is_admin_asgnd = true; if (!ether_addr_equal(netdev->dev_addr, mac)) { macaddr_changed = true; ether_addr_copy(netdev->dev_addr, mac); ether_addr_copy(((u8 *)&lio->linfo.hw_addr) + 2, mac); call_netdevice_notifiers(NETDEV_CHANGEADDR, netdev); } rtnl_unlock(); if (macaddr_changed) dev_info(&oct->pci_dev->dev, "PF changed VF's MAC address to %pM\n", mac); /* no need to notify the firmware of the macaddr change because * the PF did that already */ } static void octnet_poll_check_rxq_oom_status(struct work_struct *work) { struct cavium_wk *wk = (struct cavium_wk *)work; struct lio *lio = (struct lio *)wk->ctxptr; struct octeon_device *oct = lio->oct_dev; struct octeon_droq *droq; int q, q_no = 0; if (ifstate_check(lio, LIO_IFSTATE_RUNNING)) { for (q = 0; q < lio->linfo.num_rxpciq; q++) { q_no = lio->linfo.rxpciq[q].s.q_no; droq = oct->droq[q_no]; if (!droq) continue; octeon_droq_check_oom(droq); } } queue_delayed_work(lio->rxq_status_wq.wq, &lio->rxq_status_wq.wk.work, msecs_to_jiffies(LIO_OOM_POLL_INTERVAL_MS)); } int setup_rx_oom_poll_fn(struct net_device *netdev) { struct lio *lio = GET_LIO(netdev); struct octeon_device *oct = lio->oct_dev; lio->rxq_status_wq.wq = alloc_workqueue("rxq-oom-status", WQ_MEM_RECLAIM, 0); if (!lio->rxq_status_wq.wq) { dev_err(&oct->pci_dev->dev, "unable to create cavium rxq oom status wq\n"); return -ENOMEM; } INIT_DELAYED_WORK(&lio->rxq_status_wq.wk.work, octnet_poll_check_rxq_oom_status); lio->rxq_status_wq.wk.ctxptr = lio; queue_delayed_work(lio->rxq_status_wq.wq, &lio->rxq_status_wq.wk.work, msecs_to_jiffies(LIO_OOM_POLL_INTERVAL_MS)); return 0; } void cleanup_rx_oom_poll_fn(struct net_device *netdev) { struct lio *lio = GET_LIO(netdev); if (lio->rxq_status_wq.wq) { cancel_delayed_work_sync(&lio->rxq_status_wq.wk.work); flush_workqueue(lio->rxq_status_wq.wq); destroy_workqueue(lio->rxq_status_wq.wq); } } /* Runs in interrupt context. */ static void lio_update_txq_status(struct octeon_device *oct, int iq_num) { struct octeon_instr_queue *iq = oct->instr_queue[iq_num]; struct net_device *netdev; struct lio *lio; netdev = oct->props[iq->ifidx].netdev; /* This is needed because the first IQ does not have * a netdev associated with it. */ if (!netdev) return; lio = GET_LIO(netdev); if (__netif_subqueue_stopped(netdev, iq->q_index) && lio->linfo.link.s.link_up && (!octnet_iq_is_full(oct, iq_num))) { netif_wake_subqueue(netdev, iq->q_index); INCR_INSTRQUEUE_PKT_COUNT(lio->oct_dev, iq_num, tx_restart, 1); } } /** * \brief Setup output queue * @param oct octeon device * @param q_no which queue * @param num_descs how many descriptors * @param desc_size size of each descriptor * @param app_ctx application context */ static int octeon_setup_droq(struct octeon_device *oct, int q_no, int num_descs, int desc_size, void *app_ctx) { int ret_val; dev_dbg(&oct->pci_dev->dev, "Creating Droq: %d\n", q_no); /* droq creation and local register settings. */ ret_val = octeon_create_droq(oct, q_no, num_descs, desc_size, app_ctx); if (ret_val < 0) return ret_val; if (ret_val == 1) { dev_dbg(&oct->pci_dev->dev, "Using default droq %d\n", q_no); return 0; } /* Enable the droq queues */ octeon_set_droq_pkt_op(oct, q_no, 1); /* Send Credit for Octeon Output queues. Credits are always * sent after the output queue is enabled. */ writel(oct->droq[q_no]->max_count, oct->droq[q_no]->pkts_credit_reg); return ret_val; } /** Routine to push packets arriving on Octeon interface upto network layer. * @param oct_id - octeon device id. * @param skbuff - skbuff struct to be passed to network layer. * @param len - size of total data received. * @param rh - Control header associated with the packet * @param param - additional control data with the packet * @param arg - farg registered in droq_ops */ static void liquidio_push_packet(u32 octeon_id __attribute__((unused)), void *skbuff, u32 len, union octeon_rh *rh, void *param, void *arg) { struct net_device *netdev = (struct net_device *)arg; struct octeon_droq *droq = container_of(param, struct octeon_droq, napi); struct sk_buff *skb = (struct sk_buff *)skbuff; struct skb_shared_hwtstamps *shhwtstamps; struct napi_struct *napi = param; u16 vtag = 0; u32 r_dh_off; u64 ns; if (netdev) { struct lio *lio = GET_LIO(netdev); struct octeon_device *oct = lio->oct_dev; /* Do not proceed if the interface is not in RUNNING state. */ if (!ifstate_check(lio, LIO_IFSTATE_RUNNING)) { recv_buffer_free(skb); droq->stats.rx_dropped++; return; } skb->dev = netdev; skb_record_rx_queue(skb, droq->q_no); if (likely(len > MIN_SKB_SIZE)) { struct octeon_skb_page_info *pg_info; unsigned char *va; pg_info = ((struct octeon_skb_page_info *)(skb->cb)); if (pg_info->page) { /* For Paged allocation use the frags */ va = page_address(pg_info->page) + pg_info->page_offset; memcpy(skb->data, va, MIN_SKB_SIZE); skb_put(skb, MIN_SKB_SIZE); skb_add_rx_frag(skb, skb_shinfo(skb)->nr_frags, pg_info->page, pg_info->page_offset + MIN_SKB_SIZE, len - MIN_SKB_SIZE, LIO_RXBUFFER_SZ); } } else { struct octeon_skb_page_info *pg_info = ((struct octeon_skb_page_info *)(skb->cb)); skb_copy_to_linear_data(skb, page_address(pg_info->page) + pg_info->page_offset, len); skb_put(skb, len); put_page(pg_info->page); } r_dh_off = (rh->r_dh.len - 1) * BYTES_PER_DHLEN_UNIT; if (oct->ptp_enable) { if (rh->r_dh.has_hwtstamp) { /* timestamp is included from the hardware at * the beginning of the packet. */ if (ifstate_check (lio, LIO_IFSTATE_RX_TIMESTAMP_ENABLED)) { /* Nanoseconds are in the first 64-bits * of the packet. */ memcpy(&ns, (skb->data + r_dh_off), sizeof(ns)); r_dh_off -= BYTES_PER_DHLEN_UNIT; shhwtstamps = skb_hwtstamps(skb); shhwtstamps->hwtstamp = ns_to_ktime(ns + lio->ptp_adjust); } } } if (rh->r_dh.has_hash) { __be32 *hash_be = (__be32 *)(skb->data + r_dh_off); u32 hash = be32_to_cpu(*hash_be); skb_set_hash(skb, hash, PKT_HASH_TYPE_L4); r_dh_off -= BYTES_PER_DHLEN_UNIT; } skb_pull(skb, rh->r_dh.len * BYTES_PER_DHLEN_UNIT); skb->protocol = eth_type_trans(skb, skb->dev); if ((netdev->features & NETIF_F_RXCSUM) && (((rh->r_dh.encap_on) && (rh->r_dh.csum_verified & CNNIC_TUN_CSUM_VERIFIED)) || (!(rh->r_dh.encap_on) && (rh->r_dh.csum_verified & CNNIC_CSUM_VERIFIED)))) /* checksum has already been verified */ skb->ip_summed = CHECKSUM_UNNECESSARY; else skb->ip_summed = CHECKSUM_NONE; /* Setting Encapsulation field on basis of status received * from the firmware */ if (rh->r_dh.encap_on) { skb->encapsulation = 1; skb->csum_level = 1; droq->stats.rx_vxlan++; } /* inbound VLAN tag */ if ((netdev->features & NETIF_F_HW_VLAN_CTAG_RX) && rh->r_dh.vlan) { u16 priority = rh->r_dh.priority; u16 vid = rh->r_dh.vlan; vtag = (priority << VLAN_PRIO_SHIFT) | vid; __vlan_hwaccel_put_tag(skb, htons(ETH_P_8021Q), vtag); } napi_gro_receive(napi, skb); droq->stats.rx_bytes_received += len - rh->r_dh.len * BYTES_PER_DHLEN_UNIT; droq->stats.rx_pkts_received++; } else { recv_buffer_free(skb); } } /** * \brief wrapper for calling napi_schedule * @param param parameters to pass to napi_schedule * * Used when scheduling on different CPUs */ static void napi_schedule_wrapper(void *param) { struct napi_struct *napi = param; napi_schedule(napi); } /** * \brief callback when receive interrupt occurs and we are in NAPI mode * @param arg pointer to octeon output queue */ static void liquidio_napi_drv_callback(void *arg) { struct octeon_device *oct; struct octeon_droq *droq = arg; int this_cpu = smp_processor_id(); oct = droq->oct_dev; if (OCTEON_CN23XX_PF(oct) || OCTEON_CN23XX_VF(oct) || droq->cpu_id == this_cpu) { napi_schedule_irqoff(&droq->napi); } else { call_single_data_t *csd = &droq->csd; csd->func = napi_schedule_wrapper; csd->info = &droq->napi; csd->flags = 0; smp_call_function_single_async(droq->cpu_id, csd); } } /** * \brief Entry point for NAPI polling * @param napi NAPI structure * @param budget maximum number of items to process */ static int liquidio_napi_poll(struct napi_struct *napi, int budget) { struct octeon_instr_queue *iq; struct octeon_device *oct; struct octeon_droq *droq; int tx_done = 0, iq_no; int work_done; droq = container_of(napi, struct octeon_droq, napi); oct = droq->oct_dev; iq_no = droq->q_no; /* Handle Droq descriptors */ work_done = octeon_droq_process_poll_pkts(oct, droq, budget); /* Flush the instruction queue */ iq = oct->instr_queue[iq_no]; if (iq) { /* TODO: move this check to inside octeon_flush_iq, * once check_db_timeout is removed */ if (atomic_read(&iq->instr_pending)) /* Process iq buffers with in the budget limits */ tx_done = octeon_flush_iq(oct, iq, budget); else tx_done = 1; /* Update iq read-index rather than waiting for next interrupt. * Return back if tx_done is false. */ /* sub-queue status update */ lio_update_txq_status(oct, iq_no); } else { dev_err(&oct->pci_dev->dev, "%s: iq (%d) num invalid\n", __func__, iq_no); } #define MAX_REG_CNT 2000000U /* force enable interrupt if reg cnts are high to avoid wraparound */ if ((work_done < budget && tx_done) || (iq && iq->pkt_in_done >= MAX_REG_CNT) || (droq->pkt_count >= MAX_REG_CNT)) { tx_done = 1; napi_complete_done(napi, work_done); octeon_enable_irq(droq->oct_dev, droq->q_no); return 0; } return (!tx_done) ? (budget) : (work_done); } /** * \brief Setup input and output queues * @param octeon_dev octeon device * @param ifidx Interface index * * Note: Queues are with respect to the octeon device. Thus * an input queue is for egress packets, and output queues * are for ingress packets. */ int liquidio_setup_io_queues(struct octeon_device *octeon_dev, int ifidx, u32 num_iqs, u32 num_oqs) { struct octeon_droq_ops droq_ops; struct net_device *netdev; struct octeon_droq *droq; struct napi_struct *napi; int cpu_id_modulus; int num_tx_descs; struct lio *lio; int retval = 0; int q, q_no; int cpu_id; netdev = octeon_dev->props[ifidx].netdev; lio = GET_LIO(netdev); memset(&droq_ops, 0, sizeof(struct octeon_droq_ops)); droq_ops.fptr = liquidio_push_packet; droq_ops.farg = netdev; droq_ops.poll_mode = 1; droq_ops.napi_fn = liquidio_napi_drv_callback; cpu_id = 0; cpu_id_modulus = num_present_cpus(); /* set up DROQs. */ for (q = 0; q < num_oqs; q++) { q_no = lio->linfo.rxpciq[q].s.q_no; dev_dbg(&octeon_dev->pci_dev->dev, "%s index:%d linfo.rxpciq.s.q_no:%d\n", __func__, q, q_no); retval = octeon_setup_droq( octeon_dev, q_no, CFG_GET_NUM_RX_DESCS_NIC_IF(octeon_get_conf(octeon_dev), lio->ifidx), CFG_GET_NUM_RX_BUF_SIZE_NIC_IF(octeon_get_conf(octeon_dev), lio->ifidx), NULL); if (retval) { dev_err(&octeon_dev->pci_dev->dev, "%s : Runtime DROQ(RxQ) creation failed.\n", __func__); return 1; } droq = octeon_dev->droq[q_no]; napi = &droq->napi; dev_dbg(&octeon_dev->pci_dev->dev, "netif_napi_add netdev:%llx oct:%llx\n", (u64)netdev, (u64)octeon_dev); netif_napi_add(netdev, napi, liquidio_napi_poll, 64); /* designate a CPU for this droq */ droq->cpu_id = cpu_id; cpu_id++; if (cpu_id >= cpu_id_modulus) cpu_id = 0; octeon_register_droq_ops(octeon_dev, q_no, &droq_ops); } if (OCTEON_CN23XX_PF(octeon_dev) || OCTEON_CN23XX_VF(octeon_dev)) { /* 23XX PF/VF can send/recv control messages (via the first * PF/VF-owned droq) from the firmware even if the ethX * interface is down, so that's why poll_mode must be off * for the first droq. */ octeon_dev->droq[0]->ops.poll_mode = 0; } /* set up IQs. */ for (q = 0; q < num_iqs; q++) { num_tx_descs = CFG_GET_NUM_TX_DESCS_NIC_IF( octeon_get_conf(octeon_dev), lio->ifidx); retval = octeon_setup_iq(octeon_dev, ifidx, q, lio->linfo.txpciq[q], num_tx_descs, netdev_get_tx_queue(netdev, q)); if (retval) { dev_err(&octeon_dev->pci_dev->dev, " %s : Runtime IQ(TxQ) creation failed.\n", __func__); return 1; } /* XPS */ if (!OCTEON_CN23XX_VF(octeon_dev) && octeon_dev->msix_on && octeon_dev->ioq_vector) { struct octeon_ioq_vector *ioq_vector; ioq_vector = &octeon_dev->ioq_vector[q]; netif_set_xps_queue(netdev, &ioq_vector->affinity_mask, ioq_vector->iq_index); } } return 0; } static int liquidio_schedule_msix_droq_pkt_handler(struct octeon_droq *droq, u64 ret) { struct octeon_device *oct = droq->oct_dev; struct octeon_device_priv *oct_priv = (struct octeon_device_priv *)oct->priv; if (droq->ops.poll_mode) { droq->ops.napi_fn(droq); } else { if (ret & MSIX_PO_INT) { if (OCTEON_CN23XX_VF(oct)) dev_err(&oct->pci_dev->dev, "should not come here should not get rx when poll mode = 0 for vf\n"); tasklet_schedule(&oct_priv->droq_tasklet); return 1; } /* this will be flushed periodically by check iq db */ if (ret & MSIX_PI_INT) return 0; } return 0; } irqreturn_t liquidio_msix_intr_handler(int irq __attribute__((unused)), void *dev) { struct octeon_ioq_vector *ioq_vector = (struct octeon_ioq_vector *)dev; struct octeon_device *oct = ioq_vector->oct_dev; struct octeon_droq *droq = oct->droq[ioq_vector->droq_index]; u64 ret; ret = oct->fn_list.msix_interrupt_handler(ioq_vector); if (ret & MSIX_PO_INT || ret & MSIX_PI_INT) liquidio_schedule_msix_droq_pkt_handler(droq, ret); return IRQ_HANDLED; } /** * \brief Droq packet processor sceduler * @param oct octeon device */ static void liquidio_schedule_droq_pkt_handlers(struct octeon_device *oct) { struct octeon_device_priv *oct_priv = (struct octeon_device_priv *)oct->priv; struct octeon_droq *droq; u64 oq_no; if (oct->int_status & OCT_DEV_INTR_PKT_DATA) { for (oq_no = 0; oq_no < MAX_OCTEON_OUTPUT_QUEUES(oct); oq_no++) { if (!(oct->droq_intr & BIT_ULL(oq_no))) continue; droq = oct->droq[oq_no]; if (droq->ops.poll_mode) { droq->ops.napi_fn(droq); oct_priv->napi_mask |= BIT_ULL(oq_no); } else { tasklet_schedule(&oct_priv->droq_tasklet); } } } } /** * \brief Interrupt handler for octeon * @param irq unused * @param dev octeon device */ static irqreturn_t liquidio_legacy_intr_handler(int irq __attribute__((unused)), void *dev) { struct octeon_device *oct = (struct octeon_device *)dev; irqreturn_t ret; /* Disable our interrupts for the duration of ISR */ oct->fn_list.disable_interrupt(oct, OCTEON_ALL_INTR); ret = oct->fn_list.process_interrupt_regs(oct); if (ret == IRQ_HANDLED) liquidio_schedule_droq_pkt_handlers(oct); /* Re-enable our interrupts */ if (!(atomic_read(&oct->status) == OCT_DEV_IN_RESET)) oct->fn_list.enable_interrupt(oct, OCTEON_ALL_INTR); return ret; } /** * \brief Setup interrupt for octeon device * @param oct octeon device * * Enable interrupt in Octeon device as given in the PCI interrupt mask. */ int octeon_setup_interrupt(struct octeon_device *oct, u32 num_ioqs) { struct msix_entry *msix_entries; char *queue_irq_names = NULL; int i, num_interrupts = 0; int num_alloc_ioq_vectors; char *aux_irq_name = NULL; int num_ioq_vectors; int irqret, err; if (oct->msix_on) { oct->num_msix_irqs = num_ioqs; if (OCTEON_CN23XX_PF(oct)) { num_interrupts = MAX_IOQ_INTERRUPTS_PER_PF + 1; /* one non ioq interrupt for handling * sli_mac_pf_int_sum */ oct->num_msix_irqs += 1; } else if (OCTEON_CN23XX_VF(oct)) { num_interrupts = MAX_IOQ_INTERRUPTS_PER_VF; } /* allocate storage for the names assigned to each irq */ oct->irq_name_storage = kcalloc(num_interrupts, INTRNAMSIZ, GFP_KERNEL); if (!oct->irq_name_storage) { dev_err(&oct->pci_dev->dev, "Irq name storage alloc failed...\n"); return -ENOMEM; } queue_irq_names = oct->irq_name_storage; if (OCTEON_CN23XX_PF(oct)) aux_irq_name = &queue_irq_names [IRQ_NAME_OFF(MAX_IOQ_INTERRUPTS_PER_PF)]; oct->msix_entries = kcalloc(oct->num_msix_irqs, sizeof(struct msix_entry), GFP_KERNEL); if (!oct->msix_entries) { dev_err(&oct->pci_dev->dev, "Memory Alloc failed...\n"); kfree(oct->irq_name_storage); oct->irq_name_storage = NULL; return -ENOMEM; } msix_entries = (struct msix_entry *)oct->msix_entries; /*Assumption is that pf msix vectors start from pf srn to pf to * trs and not from 0. if not change this code */ if (OCTEON_CN23XX_PF(oct)) { for (i = 0; i < oct->num_msix_irqs - 1; i++) msix_entries[i].entry = oct->sriov_info.pf_srn + i; msix_entries[oct->num_msix_irqs - 1].entry = oct->sriov_info.trs; } else if (OCTEON_CN23XX_VF(oct)) { for (i = 0; i < oct->num_msix_irqs; i++) msix_entries[i].entry = i; } num_alloc_ioq_vectors = pci_enable_msix_range( oct->pci_dev, msix_entries, oct->num_msix_irqs, oct->num_msix_irqs); if (num_alloc_ioq_vectors < 0) { dev_err(&oct->pci_dev->dev, "unable to Allocate MSI-X interrupts\n"); kfree(oct->msix_entries); oct->msix_entries = NULL; kfree(oct->irq_name_storage); oct->irq_name_storage = NULL; return num_alloc_ioq_vectors; } dev_dbg(&oct->pci_dev->dev, "OCTEON: Enough MSI-X interrupts are allocated...\n"); num_ioq_vectors = oct->num_msix_irqs; /** For PF, there is one non-ioq interrupt handler */ if (OCTEON_CN23XX_PF(oct)) { num_ioq_vectors -= 1; snprintf(aux_irq_name, INTRNAMSIZ, "LiquidIO%u-pf%u-aux", oct->octeon_id, oct->pf_num); irqret = request_irq( msix_entries[num_ioq_vectors].vector, liquidio_legacy_intr_handler, 0, aux_irq_name, oct); if (irqret) { dev_err(&oct->pci_dev->dev, "Request_irq failed for MSIX interrupt Error: %d\n", irqret); pci_disable_msix(oct->pci_dev); kfree(oct->msix_entries); kfree(oct->irq_name_storage); oct->irq_name_storage = NULL; oct->msix_entries = NULL; return irqret; } } for (i = 0 ; i < num_ioq_vectors ; i++) { if (OCTEON_CN23XX_PF(oct)) snprintf(&queue_irq_names[IRQ_NAME_OFF(i)], INTRNAMSIZ, "LiquidIO%u-pf%u-rxtx-%u", oct->octeon_id, oct->pf_num, i); if (OCTEON_CN23XX_VF(oct)) snprintf(&queue_irq_names[IRQ_NAME_OFF(i)], INTRNAMSIZ, "LiquidIO%u-vf%u-rxtx-%u", oct->octeon_id, oct->vf_num, i); irqret = request_irq(msix_entries[i].vector, liquidio_msix_intr_handler, 0, &queue_irq_names[IRQ_NAME_OFF(i)], &oct->ioq_vector[i]); if (irqret) { dev_err(&oct->pci_dev->dev, "Request_irq failed for MSIX interrupt Error: %d\n", irqret); /** Freeing the non-ioq irq vector here . */ free_irq(msix_entries[num_ioq_vectors].vector, oct); while (i) { i--; /** clearing affinity mask. */ irq_set_affinity_hint( msix_entries[i].vector, NULL); free_irq(msix_entries[i].vector, &oct->ioq_vector[i]); } pci_disable_msix(oct->pci_dev); kfree(oct->msix_entries); kfree(oct->irq_name_storage); oct->irq_name_storage = NULL; oct->msix_entries = NULL; return irqret; } oct->ioq_vector[i].vector = msix_entries[i].vector; /* assign the cpu mask for this msix interrupt vector */ irq_set_affinity_hint(msix_entries[i].vector, &oct->ioq_vector[i].affinity_mask ); } dev_dbg(&oct->pci_dev->dev, "OCTEON[%d]: MSI-X enabled\n", oct->octeon_id); } else { err = pci_enable_msi(oct->pci_dev); if (err) dev_warn(&oct->pci_dev->dev, "Reverting to legacy interrupts. Error: %d\n", err); else oct->flags |= LIO_FLAG_MSI_ENABLED; /* allocate storage for the names assigned to the irq */ oct->irq_name_storage = kcalloc(1, INTRNAMSIZ, GFP_KERNEL); if (!oct->irq_name_storage) return -ENOMEM; queue_irq_names = oct->irq_name_storage; if (OCTEON_CN23XX_PF(oct)) snprintf(&queue_irq_names[IRQ_NAME_OFF(0)], INTRNAMSIZ, "LiquidIO%u-pf%u-rxtx-%u", oct->octeon_id, oct->pf_num, 0); if (OCTEON_CN23XX_VF(oct)) snprintf(&queue_irq_names[IRQ_NAME_OFF(0)], INTRNAMSIZ, "LiquidIO%u-vf%u-rxtx-%u", oct->octeon_id, oct->vf_num, 0); irqret = request_irq(oct->pci_dev->irq, liquidio_legacy_intr_handler, IRQF_SHARED, &queue_irq_names[IRQ_NAME_OFF(0)], oct); if (irqret) { if (oct->flags & LIO_FLAG_MSI_ENABLED) pci_disable_msi(oct->pci_dev); dev_err(&oct->pci_dev->dev, "Request IRQ failed with code: %d\n", irqret); kfree(oct->irq_name_storage); oct->irq_name_storage = NULL; return irqret; } } return 0; } static void liquidio_change_mtu_completion(struct octeon_device *oct, u32 status, void *buf) { struct octeon_soft_command *sc = (struct octeon_soft_command *)buf; struct liquidio_if_cfg_context *ctx; ctx = (struct liquidio_if_cfg_context *)sc->ctxptr; if (status) { dev_err(&oct->pci_dev->dev, "MTU change failed. Status: %llx\n", CVM_CAST64(status)); WRITE_ONCE(ctx->cond, LIO_CHANGE_MTU_FAIL); } else { WRITE_ONCE(ctx->cond, LIO_CHANGE_MTU_SUCCESS); } /* This barrier is required to be sure that the response has been * written fully before waking up the handler */ wmb(); wake_up_interruptible(&ctx->wc); } /** * \brief Net device change_mtu * @param netdev network device */ int liquidio_change_mtu(struct net_device *netdev, int new_mtu) { struct lio *lio = GET_LIO(netdev); struct octeon_device *oct = lio->oct_dev; struct liquidio_if_cfg_context *ctx; struct octeon_soft_command *sc; union octnet_cmd *ncmd; int ctx_size; int ret = 0; ctx_size = sizeof(struct liquidio_if_cfg_context); sc = (struct octeon_soft_command *) octeon_alloc_soft_command(oct, OCTNET_CMD_SIZE, 16, ctx_size); ncmd = (union octnet_cmd *)sc->virtdptr; ctx = (struct liquidio_if_cfg_context *)sc->ctxptr; WRITE_ONCE(ctx->cond, 0); ctx->octeon_id = lio_get_device_id(oct); init_waitqueue_head(&ctx->wc); ncmd->u64 = 0; ncmd->s.cmd = OCTNET_CMD_CHANGE_MTU; ncmd->s.param1 = new_mtu; octeon_swap_8B_data((u64 *)ncmd, (OCTNET_CMD_SIZE >> 3)); sc->iq_no = lio->linfo.txpciq[0].s.q_no; octeon_prepare_soft_command(oct, sc, OPCODE_NIC, OPCODE_NIC_CMD, 0, 0, 0); sc->callback = liquidio_change_mtu_completion; sc->callback_arg = sc; sc->wait_time = 100; ret = octeon_send_soft_command(oct, sc); if (ret == IQ_SEND_FAILED) { netif_info(lio, rx_err, lio->netdev, "Failed to change MTU\n"); return -EINVAL; } /* Sleep on a wait queue till the cond flag indicates that the * response arrived or timed-out. */ if (sleep_cond(&ctx->wc, &ctx->cond) == -EINTR || ctx->cond == LIO_CHANGE_MTU_FAIL) { octeon_free_soft_command(oct, sc); return -EINVAL; } netdev->mtu = new_mtu; lio->mtu = new_mtu; octeon_free_soft_command(oct, sc); return 0; } int lio_wait_for_clean_oq(struct octeon_device *oct) { int retry = 100, pending_pkts = 0; int idx; do { pending_pkts = 0; for (idx = 0; idx < MAX_OCTEON_OUTPUT_QUEUES(oct); idx++) { if (!(oct->io_qmask.oq & BIT_ULL(idx))) continue; pending_pkts += atomic_read(&oct->droq[idx]->pkts_pending); } if (pending_pkts > 0) schedule_timeout_uninterruptible(1); } while (retry-- && pending_pkts); return pending_pkts; } static void octnet_nic_stats_callback(struct octeon_device *oct_dev, u32 status, void *ptr) { struct octeon_soft_command *sc = (struct octeon_soft_command *)ptr; struct oct_nic_stats_resp *resp = (struct oct_nic_stats_resp *)sc->virtrptr; struct oct_nic_stats_ctrl *ctrl = (struct oct_nic_stats_ctrl *)sc->ctxptr; struct nic_rx_stats *rsp_rstats = &resp->stats.fromwire; struct nic_tx_stats *rsp_tstats = &resp->stats.fromhost; struct nic_rx_stats *rstats = &oct_dev->link_stats.fromwire; struct nic_tx_stats *tstats = &oct_dev->link_stats.fromhost; if (status != OCTEON_REQUEST_TIMEOUT && !resp->status) { octeon_swap_8B_data((u64 *)&resp->stats, (sizeof(struct oct_link_stats)) >> 3); /* RX link-level stats */ rstats->total_rcvd = rsp_rstats->total_rcvd; rstats->bytes_rcvd = rsp_rstats->bytes_rcvd; rstats->total_bcst = rsp_rstats->total_bcst; rstats->total_mcst = rsp_rstats->total_mcst; rstats->runts = rsp_rstats->runts; rstats->ctl_rcvd = rsp_rstats->ctl_rcvd; /* Accounts for over/under-run of buffers */ rstats->fifo_err = rsp_rstats->fifo_err; rstats->dmac_drop = rsp_rstats->dmac_drop; rstats->fcs_err = rsp_rstats->fcs_err; rstats->jabber_err = rsp_rstats->jabber_err; rstats->l2_err = rsp_rstats->l2_err; rstats->frame_err = rsp_rstats->frame_err; rstats->red_drops = rsp_rstats->red_drops; /* RX firmware stats */ rstats->fw_total_rcvd = rsp_rstats->fw_total_rcvd; rstats->fw_total_fwd = rsp_rstats->fw_total_fwd; rstats->fw_total_mcast = rsp_rstats->fw_total_mcast; rstats->fw_total_bcast = rsp_rstats->fw_total_bcast; rstats->fw_err_pko = rsp_rstats->fw_err_pko; rstats->fw_err_link = rsp_rstats->fw_err_link; rstats->fw_err_drop = rsp_rstats->fw_err_drop; rstats->fw_rx_vxlan = rsp_rstats->fw_rx_vxlan; rstats->fw_rx_vxlan_err = rsp_rstats->fw_rx_vxlan_err; /* Number of packets that are LROed */ rstats->fw_lro_pkts = rsp_rstats->fw_lro_pkts; /* Number of octets that are LROed */ rstats->fw_lro_octs = rsp_rstats->fw_lro_octs; /* Number of LRO packets formed */ rstats->fw_total_lro = rsp_rstats->fw_total_lro; /* Number of times lRO of packet aborted */ rstats->fw_lro_aborts = rsp_rstats->fw_lro_aborts; rstats->fw_lro_aborts_port = rsp_rstats->fw_lro_aborts_port; rstats->fw_lro_aborts_seq = rsp_rstats->fw_lro_aborts_seq; rstats->fw_lro_aborts_tsval = rsp_rstats->fw_lro_aborts_tsval; rstats->fw_lro_aborts_timer = rsp_rstats->fw_lro_aborts_timer; /* intrmod: packet forward rate */ rstats->fwd_rate = rsp_rstats->fwd_rate; /* TX link-level stats */ tstats->total_pkts_sent = rsp_tstats->total_pkts_sent; tstats->total_bytes_sent = rsp_tstats->total_bytes_sent; tstats->mcast_pkts_sent = rsp_tstats->mcast_pkts_sent; tstats->bcast_pkts_sent = rsp_tstats->bcast_pkts_sent; tstats->ctl_sent = rsp_tstats->ctl_sent; /* Packets sent after one collision*/ tstats->one_collision_sent = rsp_tstats->one_collision_sent; /* Packets sent after multiple collision*/ tstats->multi_collision_sent = rsp_tstats->multi_collision_sent; /* Packets not sent due to max collisions */ tstats->max_collision_fail = rsp_tstats->max_collision_fail; /* Packets not sent due to max deferrals */ tstats->max_deferral_fail = rsp_tstats->max_deferral_fail; /* Accounts for over/under-run of buffers */ tstats->fifo_err = rsp_tstats->fifo_err; tstats->runts = rsp_tstats->runts; /* Total number of collisions detected */ tstats->total_collisions = rsp_tstats->total_collisions; /* firmware stats */ tstats->fw_total_sent = rsp_tstats->fw_total_sent; tstats->fw_total_fwd = rsp_tstats->fw_total_fwd; tstats->fw_total_mcast_sent = rsp_tstats->fw_total_mcast_sent; tstats->fw_total_bcast_sent = rsp_tstats->fw_total_bcast_sent; tstats->fw_err_pko = rsp_tstats->fw_err_pko; tstats->fw_err_pki = rsp_tstats->fw_err_pki; tstats->fw_err_link = rsp_tstats->fw_err_link; tstats->fw_err_drop = rsp_tstats->fw_err_drop; tstats->fw_tso = rsp_tstats->fw_tso; tstats->fw_tso_fwd = rsp_tstats->fw_tso_fwd; tstats->fw_err_tso = rsp_tstats->fw_err_tso; tstats->fw_tx_vxlan = rsp_tstats->fw_tx_vxlan; resp->status = 1; } else { resp->status = -1; } complete(&ctrl->complete); } int octnet_get_link_stats(struct net_device *netdev) { struct lio *lio = GET_LIO(netdev); struct octeon_device *oct_dev = lio->oct_dev; struct octeon_soft_command *sc; struct oct_nic_stats_ctrl *ctrl; struct oct_nic_stats_resp *resp; int retval; /* Alloc soft command */ sc = (struct octeon_soft_command *) octeon_alloc_soft_command(oct_dev, 0, sizeof(struct oct_nic_stats_resp), sizeof(struct octnic_ctrl_pkt)); if (!sc) return -ENOMEM; resp = (struct oct_nic_stats_resp *)sc->virtrptr; memset(resp, 0, sizeof(struct oct_nic_stats_resp)); ctrl = (struct oct_nic_stats_ctrl *)sc->ctxptr; memset(ctrl, 0, sizeof(struct oct_nic_stats_ctrl)); ctrl->netdev = netdev; init_completion(&ctrl->complete); sc->iq_no = lio->linfo.txpciq[0].s.q_no; octeon_prepare_soft_command(oct_dev, sc, OPCODE_NIC, OPCODE_NIC_PORT_STATS, 0, 0, 0); sc->callback = octnet_nic_stats_callback; sc->callback_arg = sc; sc->wait_time = 500; /*in milli seconds*/ retval = octeon_send_soft_command(oct_dev, sc); if (retval == IQ_SEND_FAILED) { octeon_free_soft_command(oct_dev, sc); return -EINVAL; } wait_for_completion_timeout(&ctrl->complete, msecs_to_jiffies(1000)); if (resp->status != 1) { octeon_free_soft_command(oct_dev, sc); return -EINVAL; } octeon_free_soft_command(oct_dev, sc); return 0; } static void liquidio_nic_seapi_ctl_callback(struct octeon_device *oct, u32 status, void *buf) { struct liquidio_nic_seapi_ctl_context *ctx; struct octeon_soft_command *sc = buf; ctx = sc->ctxptr; oct = lio_get_device(ctx->octeon_id); if (status) { dev_err(&oct->pci_dev->dev, "%s: instruction failed. Status: %llx\n", __func__, CVM_CAST64(status)); } ctx->status = status; complete(&ctx->complete); } int liquidio_set_speed(struct lio *lio, int speed) { struct liquidio_nic_seapi_ctl_context *ctx; struct octeon_device *oct = lio->oct_dev; struct oct_nic_seapi_resp *resp; struct octeon_soft_command *sc; union octnet_cmd *ncmd; u32 ctx_size; int retval; u32 var; if (oct->speed_setting == speed) return 0; if (!OCTEON_CN23XX_PF(oct)) { dev_err(&oct->pci_dev->dev, "%s: SET SPEED only for PF\n", __func__); return -EOPNOTSUPP; } ctx_size = sizeof(struct liquidio_nic_seapi_ctl_context); sc = octeon_alloc_soft_command(oct, OCTNET_CMD_SIZE, sizeof(struct oct_nic_seapi_resp), ctx_size); if (!sc) return -ENOMEM; ncmd = sc->virtdptr; ctx = sc->ctxptr; resp = sc->virtrptr; memset(resp, 0, sizeof(struct oct_nic_seapi_resp)); ctx->octeon_id = lio_get_device_id(oct); ctx->status = 0; init_completion(&ctx->complete); ncmd->u64 = 0; ncmd->s.cmd = SEAPI_CMD_SPEED_SET; ncmd->s.param1 = speed; octeon_swap_8B_data((u64 *)ncmd, (OCTNET_CMD_SIZE >> 3)); sc->iq_no = lio->linfo.txpciq[0].s.q_no; octeon_prepare_soft_command(oct, sc, OPCODE_NIC, OPCODE_NIC_UBOOT_CTL, 0, 0, 0); sc->callback = liquidio_nic_seapi_ctl_callback; sc->callback_arg = sc; sc->wait_time = 5000; retval = octeon_send_soft_command(oct, sc); if (retval == IQ_SEND_FAILED) { dev_info(&oct->pci_dev->dev, "Failed to send soft command\n"); retval = -EBUSY; } else { /* Wait for response or timeout */ if (wait_for_completion_timeout(&ctx->complete, msecs_to_jiffies(10000)) == 0) { dev_err(&oct->pci_dev->dev, "%s: sc timeout\n", __func__); octeon_free_soft_command(oct, sc); return -EINTR; } retval = resp->status; if (retval) { dev_err(&oct->pci_dev->dev, "%s failed, retval=%d\n", __func__, retval); octeon_free_soft_command(oct, sc); return -EIO; } var = be32_to_cpu((__force __be32)resp->speed); if (var != speed) { dev_err(&oct->pci_dev->dev, "%s: setting failed speed= %x, expect %x\n", __func__, var, speed); } oct->speed_setting = var; } octeon_free_soft_command(oct, sc); return retval; } int liquidio_get_speed(struct lio *lio) { struct liquidio_nic_seapi_ctl_context *ctx; struct octeon_device *oct = lio->oct_dev; struct oct_nic_seapi_resp *resp; struct octeon_soft_command *sc; union octnet_cmd *ncmd; u32 ctx_size; int retval; ctx_size = sizeof(struct liquidio_nic_seapi_ctl_context); sc = octeon_alloc_soft_command(oct, OCTNET_CMD_SIZE, sizeof(struct oct_nic_seapi_resp), ctx_size); if (!sc) return -ENOMEM; ncmd = sc->virtdptr; ctx = sc->ctxptr; resp = sc->virtrptr; memset(resp, 0, sizeof(struct oct_nic_seapi_resp)); ctx->octeon_id = lio_get_device_id(oct); ctx->status = 0; init_completion(&ctx->complete); ncmd->u64 = 0; ncmd->s.cmd = SEAPI_CMD_SPEED_GET; octeon_swap_8B_data((u64 *)ncmd, (OCTNET_CMD_SIZE >> 3)); sc->iq_no = lio->linfo.txpciq[0].s.q_no; octeon_prepare_soft_command(oct, sc, OPCODE_NIC, OPCODE_NIC_UBOOT_CTL, 0, 0, 0); sc->callback = liquidio_nic_seapi_ctl_callback; sc->callback_arg = sc; sc->wait_time = 5000; retval = octeon_send_soft_command(oct, sc); if (retval == IQ_SEND_FAILED) { dev_info(&oct->pci_dev->dev, "Failed to send soft command\n"); oct->no_speed_setting = 1; oct->speed_setting = 25; retval = -EBUSY; } else { if (wait_for_completion_timeout(&ctx->complete, msecs_to_jiffies(10000)) == 0) { dev_err(&oct->pci_dev->dev, "%s: sc timeout\n", __func__); oct->speed_setting = 25; oct->no_speed_setting = 1; octeon_free_soft_command(oct, sc); return -EINTR; } retval = resp->status; if (retval) { dev_err(&oct->pci_dev->dev, "%s failed retval=%d\n", __func__, retval); oct->no_speed_setting = 1; oct->speed_setting = 25; octeon_free_soft_command(oct, sc); retval = -EIO; } else { u32 var; var = be32_to_cpu((__force __be32)resp->speed); oct->speed_setting = var; if (var == 0xffff) { oct->no_speed_setting = 1; /* unable to access boot variables * get the default value based on the NIC type */ oct->speed_setting = 25; } } } octeon_free_soft_command(oct, sc); return retval; }