// SPDX-License-Identifier: GPL-2.0+ #include "lan966x_main.h" static int lan966x_fdma_channel_active(struct lan966x *lan966x) { return lan_rd(lan966x, FDMA_CH_ACTIVE); } static struct page *lan966x_fdma_rx_alloc_page(struct lan966x_rx *rx, struct lan966x_db *db) { struct lan966x *lan966x = rx->lan966x; dma_addr_t dma_addr; struct page *page; page = dev_alloc_pages(rx->page_order); if (unlikely(!page)) return NULL; dma_addr = dma_map_page(lan966x->dev, page, 0, PAGE_SIZE << rx->page_order, DMA_FROM_DEVICE); if (unlikely(dma_mapping_error(lan966x->dev, dma_addr))) goto free_page; db->dataptr = dma_addr; return page; free_page: __free_pages(page, rx->page_order); return NULL; } static void lan966x_fdma_rx_free_pages(struct lan966x_rx *rx) { struct lan966x *lan966x = rx->lan966x; struct lan966x_rx_dcb *dcb; struct lan966x_db *db; int i, j; for (i = 0; i < FDMA_DCB_MAX; ++i) { dcb = &rx->dcbs[i]; for (j = 0; j < FDMA_RX_DCB_MAX_DBS; ++j) { db = &dcb->db[j]; dma_unmap_single(lan966x->dev, (dma_addr_t)db->dataptr, PAGE_SIZE << rx->page_order, DMA_FROM_DEVICE); __free_pages(rx->page[i][j], rx->page_order); } } } static void lan966x_fdma_rx_add_dcb(struct lan966x_rx *rx, struct lan966x_rx_dcb *dcb, u64 nextptr) { struct lan966x_db *db; int i; for (i = 0; i < FDMA_RX_DCB_MAX_DBS; ++i) { db = &dcb->db[i]; db->status = FDMA_DCB_STATUS_INTR; } dcb->nextptr = FDMA_DCB_INVALID_DATA; dcb->info = FDMA_DCB_INFO_DATAL(PAGE_SIZE << rx->page_order); rx->last_entry->nextptr = nextptr; rx->last_entry = dcb; } static int lan966x_fdma_rx_alloc(struct lan966x_rx *rx) { struct lan966x *lan966x = rx->lan966x; struct lan966x_rx_dcb *dcb; struct lan966x_db *db; struct page *page; int i, j; int size; /* calculate how many pages are needed to allocate the dcbs */ size = sizeof(struct lan966x_rx_dcb) * FDMA_DCB_MAX; size = ALIGN(size, PAGE_SIZE); rx->dcbs = dma_alloc_coherent(lan966x->dev, size, &rx->dma, GFP_KERNEL); if (!rx->dcbs) return -ENOMEM; rx->last_entry = rx->dcbs; rx->db_index = 0; rx->dcb_index = 0; /* Now for each dcb allocate the dbs */ for (i = 0; i < FDMA_DCB_MAX; ++i) { dcb = &rx->dcbs[i]; dcb->info = 0; /* For each db allocate a page and map it to the DB dataptr. */ for (j = 0; j < FDMA_RX_DCB_MAX_DBS; ++j) { db = &dcb->db[j]; page = lan966x_fdma_rx_alloc_page(rx, db); if (!page) return -ENOMEM; db->status = 0; rx->page[i][j] = page; } lan966x_fdma_rx_add_dcb(rx, dcb, rx->dma + sizeof(*dcb) * i); } return 0; } static void lan966x_fdma_rx_free(struct lan966x_rx *rx) { struct lan966x *lan966x = rx->lan966x; u32 size; /* Now it is possible to do the cleanup of dcb */ size = sizeof(struct lan966x_tx_dcb) * FDMA_DCB_MAX; size = ALIGN(size, PAGE_SIZE); dma_free_coherent(lan966x->dev, size, rx->dcbs, rx->dma); } static void lan966x_fdma_rx_start(struct lan966x_rx *rx) { struct lan966x *lan966x = rx->lan966x; u32 mask; /* When activating a channel, first is required to write the first DCB * address and then to activate it */ lan_wr(lower_32_bits((u64)rx->dma), lan966x, FDMA_DCB_LLP(rx->channel_id)); lan_wr(upper_32_bits((u64)rx->dma), lan966x, FDMA_DCB_LLP1(rx->channel_id)); lan_wr(FDMA_CH_CFG_CH_DCB_DB_CNT_SET(FDMA_RX_DCB_MAX_DBS) | FDMA_CH_CFG_CH_INTR_DB_EOF_ONLY_SET(1) | FDMA_CH_CFG_CH_INJ_PORT_SET(0) | FDMA_CH_CFG_CH_MEM_SET(1), lan966x, FDMA_CH_CFG(rx->channel_id)); /* Start fdma */ lan_rmw(FDMA_PORT_CTRL_XTR_STOP_SET(0), FDMA_PORT_CTRL_XTR_STOP, lan966x, FDMA_PORT_CTRL(0)); /* Enable interrupts */ mask = lan_rd(lan966x, FDMA_INTR_DB_ENA); mask = FDMA_INTR_DB_ENA_INTR_DB_ENA_GET(mask); mask |= BIT(rx->channel_id); lan_rmw(FDMA_INTR_DB_ENA_INTR_DB_ENA_SET(mask), FDMA_INTR_DB_ENA_INTR_DB_ENA, lan966x, FDMA_INTR_DB_ENA); /* Activate the channel */ lan_rmw(FDMA_CH_ACTIVATE_CH_ACTIVATE_SET(BIT(rx->channel_id)), FDMA_CH_ACTIVATE_CH_ACTIVATE, lan966x, FDMA_CH_ACTIVATE); } static void lan966x_fdma_rx_disable(struct lan966x_rx *rx) { struct lan966x *lan966x = rx->lan966x; u32 val; /* Disable the channel */ lan_rmw(FDMA_CH_DISABLE_CH_DISABLE_SET(BIT(rx->channel_id)), FDMA_CH_DISABLE_CH_DISABLE, lan966x, FDMA_CH_DISABLE); readx_poll_timeout_atomic(lan966x_fdma_channel_active, lan966x, val, !(val & BIT(rx->channel_id)), READL_SLEEP_US, READL_TIMEOUT_US); lan_rmw(FDMA_CH_DB_DISCARD_DB_DISCARD_SET(BIT(rx->channel_id)), FDMA_CH_DB_DISCARD_DB_DISCARD, lan966x, FDMA_CH_DB_DISCARD); } static void lan966x_fdma_rx_reload(struct lan966x_rx *rx) { struct lan966x *lan966x = rx->lan966x; lan_rmw(FDMA_CH_RELOAD_CH_RELOAD_SET(BIT(rx->channel_id)), FDMA_CH_RELOAD_CH_RELOAD, lan966x, FDMA_CH_RELOAD); } static void lan966x_fdma_tx_add_dcb(struct lan966x_tx *tx, struct lan966x_tx_dcb *dcb) { dcb->nextptr = FDMA_DCB_INVALID_DATA; dcb->info = 0; } static int lan966x_fdma_tx_alloc(struct lan966x_tx *tx) { struct lan966x *lan966x = tx->lan966x; struct lan966x_tx_dcb *dcb; struct lan966x_db *db; int size; int i, j; tx->dcbs_buf = kcalloc(FDMA_DCB_MAX, sizeof(struct lan966x_tx_dcb_buf), GFP_KERNEL); if (!tx->dcbs_buf) return -ENOMEM; /* calculate how many pages are needed to allocate the dcbs */ size = sizeof(struct lan966x_tx_dcb) * FDMA_DCB_MAX; size = ALIGN(size, PAGE_SIZE); tx->dcbs = dma_alloc_coherent(lan966x->dev, size, &tx->dma, GFP_KERNEL); if (!tx->dcbs) goto out; /* Now for each dcb allocate the db */ for (i = 0; i < FDMA_DCB_MAX; ++i) { dcb = &tx->dcbs[i]; for (j = 0; j < FDMA_TX_DCB_MAX_DBS; ++j) { db = &dcb->db[j]; db->dataptr = 0; db->status = 0; } lan966x_fdma_tx_add_dcb(tx, dcb); } return 0; out: kfree(tx->dcbs_buf); return -ENOMEM; } static void lan966x_fdma_tx_free(struct lan966x_tx *tx) { struct lan966x *lan966x = tx->lan966x; int size; kfree(tx->dcbs_buf); size = sizeof(struct lan966x_tx_dcb) * FDMA_DCB_MAX; size = ALIGN(size, PAGE_SIZE); dma_free_coherent(lan966x->dev, size, tx->dcbs, tx->dma); } static void lan966x_fdma_tx_activate(struct lan966x_tx *tx) { struct lan966x *lan966x = tx->lan966x; u32 mask; /* When activating a channel, first is required to write the first DCB * address and then to activate it */ lan_wr(lower_32_bits((u64)tx->dma), lan966x, FDMA_DCB_LLP(tx->channel_id)); lan_wr(upper_32_bits((u64)tx->dma), lan966x, FDMA_DCB_LLP1(tx->channel_id)); lan_wr(FDMA_CH_CFG_CH_DCB_DB_CNT_SET(FDMA_TX_DCB_MAX_DBS) | FDMA_CH_CFG_CH_INTR_DB_EOF_ONLY_SET(1) | FDMA_CH_CFG_CH_INJ_PORT_SET(0) | FDMA_CH_CFG_CH_MEM_SET(1), lan966x, FDMA_CH_CFG(tx->channel_id)); /* Start fdma */ lan_rmw(FDMA_PORT_CTRL_INJ_STOP_SET(0), FDMA_PORT_CTRL_INJ_STOP, lan966x, FDMA_PORT_CTRL(0)); /* Enable interrupts */ mask = lan_rd(lan966x, FDMA_INTR_DB_ENA); mask = FDMA_INTR_DB_ENA_INTR_DB_ENA_GET(mask); mask |= BIT(tx->channel_id); lan_rmw(FDMA_INTR_DB_ENA_INTR_DB_ENA_SET(mask), FDMA_INTR_DB_ENA_INTR_DB_ENA, lan966x, FDMA_INTR_DB_ENA); /* Activate the channel */ lan_rmw(FDMA_CH_ACTIVATE_CH_ACTIVATE_SET(BIT(tx->channel_id)), FDMA_CH_ACTIVATE_CH_ACTIVATE, lan966x, FDMA_CH_ACTIVATE); } static void lan966x_fdma_tx_disable(struct lan966x_tx *tx) { struct lan966x *lan966x = tx->lan966x; u32 val; /* Disable the channel */ lan_rmw(FDMA_CH_DISABLE_CH_DISABLE_SET(BIT(tx->channel_id)), FDMA_CH_DISABLE_CH_DISABLE, lan966x, FDMA_CH_DISABLE); readx_poll_timeout_atomic(lan966x_fdma_channel_active, lan966x, val, !(val & BIT(tx->channel_id)), READL_SLEEP_US, READL_TIMEOUT_US); lan_rmw(FDMA_CH_DB_DISCARD_DB_DISCARD_SET(BIT(tx->channel_id)), FDMA_CH_DB_DISCARD_DB_DISCARD, lan966x, FDMA_CH_DB_DISCARD); tx->activated = false; tx->last_in_use = -1; } static void lan966x_fdma_tx_reload(struct lan966x_tx *tx) { struct lan966x *lan966x = tx->lan966x; /* Write the registers to reload the channel */ lan_rmw(FDMA_CH_RELOAD_CH_RELOAD_SET(BIT(tx->channel_id)), FDMA_CH_RELOAD_CH_RELOAD, lan966x, FDMA_CH_RELOAD); } static void lan966x_fdma_wakeup_netdev(struct lan966x *lan966x) { struct lan966x_port *port; int i; for (i = 0; i < lan966x->num_phys_ports; ++i) { port = lan966x->ports[i]; if (!port) continue; if (netif_queue_stopped(port->dev)) netif_wake_queue(port->dev); } } static void lan966x_fdma_stop_netdev(struct lan966x *lan966x) { struct lan966x_port *port; int i; for (i = 0; i < lan966x->num_phys_ports; ++i) { port = lan966x->ports[i]; if (!port) continue; netif_stop_queue(port->dev); } } static void lan966x_fdma_tx_clear_buf(struct lan966x *lan966x, int weight) { struct lan966x_tx *tx = &lan966x->tx; struct lan966x_tx_dcb_buf *dcb_buf; struct lan966x_db *db; unsigned long flags; bool clear = false; int i; spin_lock_irqsave(&lan966x->tx_lock, flags); for (i = 0; i < FDMA_DCB_MAX; ++i) { dcb_buf = &tx->dcbs_buf[i]; if (!dcb_buf->used) continue; db = &tx->dcbs[i].db[0]; if (!(db->status & FDMA_DCB_STATUS_DONE)) continue; dcb_buf->dev->stats.tx_packets++; dcb_buf->dev->stats.tx_bytes += dcb_buf->skb->len; dcb_buf->used = false; dma_unmap_single(lan966x->dev, dcb_buf->dma_addr, dcb_buf->skb->len, DMA_TO_DEVICE); if (!dcb_buf->ptp) dev_kfree_skb_any(dcb_buf->skb); clear = true; } if (clear) lan966x_fdma_wakeup_netdev(lan966x); spin_unlock_irqrestore(&lan966x->tx_lock, flags); } static bool lan966x_fdma_rx_more_frames(struct lan966x_rx *rx) { struct lan966x_db *db; /* Check if there is any data */ db = &rx->dcbs[rx->dcb_index].db[rx->db_index]; if (unlikely(!(db->status & FDMA_DCB_STATUS_DONE))) return false; return true; } static struct sk_buff *lan966x_fdma_rx_get_frame(struct lan966x_rx *rx) { struct lan966x *lan966x = rx->lan966x; u64 src_port, timestamp; struct lan966x_db *db; struct sk_buff *skb; struct page *page; /* Get the received frame and unmap it */ db = &rx->dcbs[rx->dcb_index].db[rx->db_index]; page = rx->page[rx->dcb_index][rx->db_index]; dma_sync_single_for_cpu(lan966x->dev, (dma_addr_t)db->dataptr, FDMA_DCB_STATUS_BLOCKL(db->status), DMA_FROM_DEVICE); skb = build_skb(page_address(page), PAGE_SIZE << rx->page_order); if (unlikely(!skb)) goto unmap_page; skb_put(skb, FDMA_DCB_STATUS_BLOCKL(db->status)); lan966x_ifh_get_src_port(skb->data, &src_port); lan966x_ifh_get_timestamp(skb->data, ×tamp); if (WARN_ON(src_port >= lan966x->num_phys_ports)) goto free_skb; dma_unmap_single_attrs(lan966x->dev, (dma_addr_t)db->dataptr, PAGE_SIZE << rx->page_order, DMA_FROM_DEVICE, DMA_ATTR_SKIP_CPU_SYNC); skb->dev = lan966x->ports[src_port]->dev; skb_pull(skb, IFH_LEN * sizeof(u32)); if (likely(!(skb->dev->features & NETIF_F_RXFCS))) skb_trim(skb, skb->len - ETH_FCS_LEN); lan966x_ptp_rxtstamp(lan966x, skb, timestamp); skb->protocol = eth_type_trans(skb, skb->dev); if (lan966x->bridge_mask & BIT(src_port)) { skb->offload_fwd_mark = 1; skb_reset_network_header(skb); if (!lan966x_hw_offload(lan966x, src_port, skb)) skb->offload_fwd_mark = 0; } skb->dev->stats.rx_bytes += skb->len; skb->dev->stats.rx_packets++; return skb; free_skb: kfree_skb(skb); unmap_page: dma_unmap_single_attrs(lan966x->dev, (dma_addr_t)db->dataptr, PAGE_SIZE << rx->page_order, DMA_FROM_DEVICE, DMA_ATTR_SKIP_CPU_SYNC); __free_pages(page, rx->page_order); return NULL; } static int lan966x_fdma_napi_poll(struct napi_struct *napi, int weight) { struct lan966x *lan966x = container_of(napi, struct lan966x, napi); struct lan966x_rx *rx = &lan966x->rx; int dcb_reload = rx->dcb_index; struct lan966x_rx_dcb *old_dcb; struct lan966x_db *db; struct sk_buff *skb; struct page *page; int counter = 0; u64 nextptr; lan966x_fdma_tx_clear_buf(lan966x, weight); /* Get all received skb */ while (counter < weight) { if (!lan966x_fdma_rx_more_frames(rx)) break; skb = lan966x_fdma_rx_get_frame(rx); rx->page[rx->dcb_index][rx->db_index] = NULL; rx->dcb_index++; rx->dcb_index &= FDMA_DCB_MAX - 1; if (!skb) break; napi_gro_receive(&lan966x->napi, skb); counter++; } /* Allocate new pages and map them */ while (dcb_reload != rx->dcb_index) { db = &rx->dcbs[dcb_reload].db[rx->db_index]; page = lan966x_fdma_rx_alloc_page(rx, db); if (unlikely(!page)) break; rx->page[dcb_reload][rx->db_index] = page; old_dcb = &rx->dcbs[dcb_reload]; dcb_reload++; dcb_reload &= FDMA_DCB_MAX - 1; nextptr = rx->dma + ((unsigned long)old_dcb - (unsigned long)rx->dcbs); lan966x_fdma_rx_add_dcb(rx, old_dcb, nextptr); lan966x_fdma_rx_reload(rx); } if (counter < weight && napi_complete_done(napi, counter)) lan_wr(0xff, lan966x, FDMA_INTR_DB_ENA); return counter; } irqreturn_t lan966x_fdma_irq_handler(int irq, void *args) { struct lan966x *lan966x = args; u32 db, err, err_type; db = lan_rd(lan966x, FDMA_INTR_DB); err = lan_rd(lan966x, FDMA_INTR_ERR); if (db) { lan_wr(0, lan966x, FDMA_INTR_DB_ENA); lan_wr(db, lan966x, FDMA_INTR_DB); napi_schedule(&lan966x->napi); } if (err) { err_type = lan_rd(lan966x, FDMA_ERRORS); WARN(1, "Unexpected error: %d, error_type: %d\n", err, err_type); lan_wr(err, lan966x, FDMA_INTR_ERR); lan_wr(err_type, lan966x, FDMA_ERRORS); } return IRQ_HANDLED; } static int lan966x_fdma_get_next_dcb(struct lan966x_tx *tx) { struct lan966x_tx_dcb_buf *dcb_buf; int i; for (i = 0; i < FDMA_DCB_MAX; ++i) { dcb_buf = &tx->dcbs_buf[i]; if (!dcb_buf->used && i != tx->last_in_use) return i; } return -1; } int lan966x_fdma_xmit(struct sk_buff *skb, __be32 *ifh, struct net_device *dev) { struct lan966x_port *port = netdev_priv(dev); struct lan966x *lan966x = port->lan966x; struct lan966x_tx_dcb_buf *next_dcb_buf; struct lan966x_tx_dcb *next_dcb, *dcb; struct lan966x_tx *tx = &lan966x->tx; struct lan966x_db *next_db; int needed_headroom; int needed_tailroom; dma_addr_t dma_addr; int next_to_use; int err; /* Get next index */ next_to_use = lan966x_fdma_get_next_dcb(tx); if (next_to_use < 0) { netif_stop_queue(dev); return NETDEV_TX_BUSY; } if (skb_put_padto(skb, ETH_ZLEN)) { dev->stats.tx_dropped++; return NETDEV_TX_OK; } /* skb processing */ needed_headroom = max_t(int, IFH_LEN * sizeof(u32) - skb_headroom(skb), 0); needed_tailroom = max_t(int, ETH_FCS_LEN - skb_tailroom(skb), 0); if (needed_headroom || needed_tailroom || skb_header_cloned(skb)) { err = pskb_expand_head(skb, needed_headroom, needed_tailroom, GFP_ATOMIC); if (unlikely(err)) { dev->stats.tx_dropped++; err = NETDEV_TX_OK; goto release; } } skb_tx_timestamp(skb); skb_push(skb, IFH_LEN * sizeof(u32)); memcpy(skb->data, ifh, IFH_LEN * sizeof(u32)); skb_put(skb, 4); dma_addr = dma_map_single(lan966x->dev, skb->data, skb->len, DMA_TO_DEVICE); if (dma_mapping_error(lan966x->dev, dma_addr)) { dev->stats.tx_dropped++; err = NETDEV_TX_OK; goto release; } /* Setup next dcb */ next_dcb = &tx->dcbs[next_to_use]; next_dcb->nextptr = FDMA_DCB_INVALID_DATA; next_db = &next_dcb->db[0]; next_db->dataptr = dma_addr; next_db->status = FDMA_DCB_STATUS_SOF | FDMA_DCB_STATUS_EOF | FDMA_DCB_STATUS_INTR | FDMA_DCB_STATUS_BLOCKO(0) | FDMA_DCB_STATUS_BLOCKL(skb->len); /* Fill up the buffer */ next_dcb_buf = &tx->dcbs_buf[next_to_use]; next_dcb_buf->skb = skb; next_dcb_buf->dma_addr = dma_addr; next_dcb_buf->used = true; next_dcb_buf->ptp = false; next_dcb_buf->dev = dev; if (skb_shinfo(skb)->tx_flags & SKBTX_HW_TSTAMP && LAN966X_SKB_CB(skb)->rew_op == IFH_REW_OP_TWO_STEP_PTP) next_dcb_buf->ptp = true; if (likely(lan966x->tx.activated)) { /* Connect current dcb to the next db */ dcb = &tx->dcbs[tx->last_in_use]; dcb->nextptr = tx->dma + (next_to_use * sizeof(struct lan966x_tx_dcb)); lan966x_fdma_tx_reload(tx); } else { /* Because it is first time, then just activate */ lan966x->tx.activated = true; lan966x_fdma_tx_activate(tx); } /* Move to next dcb because this last in use */ tx->last_in_use = next_to_use; return NETDEV_TX_OK; release: if (skb_shinfo(skb)->tx_flags & SKBTX_HW_TSTAMP && LAN966X_SKB_CB(skb)->rew_op == IFH_REW_OP_TWO_STEP_PTP) lan966x_ptp_txtstamp_release(port, skb); dev_kfree_skb_any(skb); return err; } static int lan966x_fdma_get_max_mtu(struct lan966x *lan966x) { int max_mtu = 0; int i; for (i = 0; i < lan966x->num_phys_ports; ++i) { struct lan966x_port *port; int mtu; port = lan966x->ports[i]; if (!port) continue; mtu = lan_rd(lan966x, DEV_MAC_MAXLEN_CFG(port->chip_port)); if (mtu > max_mtu) max_mtu = mtu; } return max_mtu; } static int lan966x_qsys_sw_status(struct lan966x *lan966x) { return lan_rd(lan966x, QSYS_SW_STATUS(CPU_PORT)); } static int lan966x_fdma_reload(struct lan966x *lan966x, int new_mtu) { dma_addr_t rx_dma; void *rx_dcbs; u32 size; int err; /* Store these for later to free them */ rx_dma = lan966x->rx.dma; rx_dcbs = lan966x->rx.dcbs; napi_synchronize(&lan966x->napi); napi_disable(&lan966x->napi); lan966x_fdma_stop_netdev(lan966x); lan966x_fdma_rx_disable(&lan966x->rx); lan966x_fdma_rx_free_pages(&lan966x->rx); lan966x->rx.page_order = round_up(new_mtu, PAGE_SIZE) / PAGE_SIZE - 1; err = lan966x_fdma_rx_alloc(&lan966x->rx); if (err) goto restore; lan966x_fdma_rx_start(&lan966x->rx); size = sizeof(struct lan966x_rx_dcb) * FDMA_DCB_MAX; size = ALIGN(size, PAGE_SIZE); dma_free_coherent(lan966x->dev, size, rx_dcbs, rx_dma); lan966x_fdma_wakeup_netdev(lan966x); napi_enable(&lan966x->napi); return err; restore: lan966x->rx.dma = rx_dma; lan966x->rx.dcbs = rx_dcbs; lan966x_fdma_rx_start(&lan966x->rx); return err; } int lan966x_fdma_change_mtu(struct lan966x *lan966x) { int max_mtu; int err; u32 val; max_mtu = lan966x_fdma_get_max_mtu(lan966x); max_mtu += IFH_LEN * sizeof(u32); max_mtu += SKB_DATA_ALIGN(sizeof(struct skb_shared_info)); max_mtu += VLAN_HLEN * 2; if (round_up(max_mtu, PAGE_SIZE) / PAGE_SIZE - 1 == lan966x->rx.page_order) return 0; /* Disable the CPU port */ lan_rmw(QSYS_SW_PORT_MODE_PORT_ENA_SET(0), QSYS_SW_PORT_MODE_PORT_ENA, lan966x, QSYS_SW_PORT_MODE(CPU_PORT)); /* Flush the CPU queues */ readx_poll_timeout(lan966x_qsys_sw_status, lan966x, val, !(QSYS_SW_STATUS_EQ_AVAIL_GET(val)), READL_SLEEP_US, READL_TIMEOUT_US); /* Add a sleep in case there are frames between the queues and the CPU * port */ usleep_range(1000, 2000); err = lan966x_fdma_reload(lan966x, max_mtu); /* Enable back the CPU port */ lan_rmw(QSYS_SW_PORT_MODE_PORT_ENA_SET(1), QSYS_SW_PORT_MODE_PORT_ENA, lan966x, QSYS_SW_PORT_MODE(CPU_PORT)); return err; } void lan966x_fdma_netdev_init(struct lan966x *lan966x, struct net_device *dev) { if (lan966x->fdma_ndev) return; lan966x->fdma_ndev = dev; netif_napi_add(dev, &lan966x->napi, lan966x_fdma_napi_poll); napi_enable(&lan966x->napi); } void lan966x_fdma_netdev_deinit(struct lan966x *lan966x, struct net_device *dev) { if (lan966x->fdma_ndev == dev) { netif_napi_del(&lan966x->napi); lan966x->fdma_ndev = NULL; } } int lan966x_fdma_init(struct lan966x *lan966x) { int err; if (!lan966x->fdma) return 0; lan966x->rx.lan966x = lan966x; lan966x->rx.channel_id = FDMA_XTR_CHANNEL; lan966x->tx.lan966x = lan966x; lan966x->tx.channel_id = FDMA_INJ_CHANNEL; lan966x->tx.last_in_use = -1; err = lan966x_fdma_rx_alloc(&lan966x->rx); if (err) return err; err = lan966x_fdma_tx_alloc(&lan966x->tx); if (err) { lan966x_fdma_rx_free(&lan966x->rx); return err; } lan966x_fdma_rx_start(&lan966x->rx); return 0; } void lan966x_fdma_deinit(struct lan966x *lan966x) { if (!lan966x->fdma) return; lan966x_fdma_rx_disable(&lan966x->rx); lan966x_fdma_tx_disable(&lan966x->tx); napi_synchronize(&lan966x->napi); napi_disable(&lan966x->napi); lan966x_fdma_rx_free_pages(&lan966x->rx); lan966x_fdma_rx_free(&lan966x->rx); lan966x_fdma_tx_free(&lan966x->tx); }