1 /* QLogic qede NIC Driver
2 * Copyright (c) 2015 QLogic Corporation
4 * This software is available under the terms of the GNU General Public License
5 * (GPL) Version 2, available from the file COPYING in the main directory of
9 #include <linux/module.h>
10 #include <linux/pci.h>
11 #include <linux/version.h>
12 #include <linux/device.h>
13 #include <linux/netdevice.h>
14 #include <linux/etherdevice.h>
15 #include <linux/skbuff.h>
16 #include <linux/errno.h>
17 #include <linux/list.h>
18 #include <linux/string.h>
19 #include <linux/dma-mapping.h>
20 #include <linux/interrupt.h>
21 #include <asm/byteorder.h>
22 #include <asm/param.h>
24 #include <linux/netdev_features.h>
25 #include <linux/udp.h>
26 #include <linux/tcp.h>
27 #include <net/vxlan.h>
31 #include <linux/if_ether.h>
32 #include <linux/if_vlan.h>
33 #include <linux/pkt_sched.h>
34 #include <linux/ethtool.h>
36 #include <linux/random.h>
37 #include <net/ip6_checksum.h>
38 #include <linux/bitops.h>
42 static const char version[] = "QLogic QL4xxx 40G/100G Ethernet Driver qede "
43 DRV_MODULE_VERSION "\n";
45 MODULE_DESCRIPTION("QLogic 40G/100G Ethernet Driver");
46 MODULE_LICENSE("GPL");
47 MODULE_VERSION(DRV_MODULE_VERSION);
50 module_param(debug, uint, 0);
51 MODULE_PARM_DESC(debug, " Default debug msglevel");
53 static const struct qed_eth_ops *qed_ops;
55 #define CHIP_NUM_57980S_40 0x1634
56 #define CHIP_NUM_57980S_10 0x1635
57 #define CHIP_NUM_57980S_MF 0x1636
58 #define CHIP_NUM_57980S_100 0x1644
59 #define CHIP_NUM_57980S_50 0x1654
60 #define CHIP_NUM_57980S_25 0x1656
62 #ifndef PCI_DEVICE_ID_NX2_57980E
63 #define PCI_DEVICE_ID_57980S_40 CHIP_NUM_57980S_40
64 #define PCI_DEVICE_ID_57980S_10 CHIP_NUM_57980S_10
65 #define PCI_DEVICE_ID_57980S_MF CHIP_NUM_57980S_MF
66 #define PCI_DEVICE_ID_57980S_100 CHIP_NUM_57980S_100
67 #define PCI_DEVICE_ID_57980S_50 CHIP_NUM_57980S_50
68 #define PCI_DEVICE_ID_57980S_25 CHIP_NUM_57980S_25
71 static const struct pci_device_id qede_pci_tbl[] = {
72 { PCI_VDEVICE(QLOGIC, PCI_DEVICE_ID_57980S_40), 0 },
73 { PCI_VDEVICE(QLOGIC, PCI_DEVICE_ID_57980S_10), 0 },
74 { PCI_VDEVICE(QLOGIC, PCI_DEVICE_ID_57980S_MF), 0 },
75 { PCI_VDEVICE(QLOGIC, PCI_DEVICE_ID_57980S_100), 0 },
76 { PCI_VDEVICE(QLOGIC, PCI_DEVICE_ID_57980S_50), 0 },
77 { PCI_VDEVICE(QLOGIC, PCI_DEVICE_ID_57980S_25), 0 },
81 MODULE_DEVICE_TABLE(pci, qede_pci_tbl);
83 static int qede_probe(struct pci_dev *pdev, const struct pci_device_id *id);
85 #define TX_TIMEOUT (5 * HZ)
87 static void qede_remove(struct pci_dev *pdev);
88 static int qede_alloc_rx_buffer(struct qede_dev *edev,
89 struct qede_rx_queue *rxq);
90 static void qede_link_update(void *dev, struct qed_link_output *link);
92 static struct pci_driver qede_pci_driver = {
94 .id_table = qede_pci_tbl,
96 .remove = qede_remove,
99 static struct qed_eth_cb_ops qede_ll_ops = {
101 .link_update = qede_link_update,
105 static int qede_netdev_event(struct notifier_block *this, unsigned long event,
108 struct net_device *ndev = netdev_notifier_info_to_dev(ptr);
109 struct ethtool_drvinfo drvinfo;
110 struct qede_dev *edev;
112 /* Currently only support name change */
113 if (event != NETDEV_CHANGENAME)
116 /* Check whether this is a qede device */
117 if (!ndev || !ndev->ethtool_ops || !ndev->ethtool_ops->get_drvinfo)
120 memset(&drvinfo, 0, sizeof(drvinfo));
121 ndev->ethtool_ops->get_drvinfo(ndev, &drvinfo);
122 if (strcmp(drvinfo.driver, "qede"))
124 edev = netdev_priv(ndev);
126 /* Notify qed of the name change */
127 if (!edev->ops || !edev->ops->common)
129 edev->ops->common->set_id(edev->cdev, edev->ndev->name,
136 static struct notifier_block qede_netdev_notifier = {
137 .notifier_call = qede_netdev_event,
141 int __init qede_init(void)
146 pr_notice("qede_init: %s\n", version);
148 qed_ver = qed_get_protocol_version(QED_PROTOCOL_ETH);
149 if (qed_ver != QEDE_ETH_INTERFACE_VERSION) {
150 pr_notice("Version mismatch [%08x != %08x]\n",
152 QEDE_ETH_INTERFACE_VERSION);
156 qed_ops = qed_get_eth_ops(QEDE_ETH_INTERFACE_VERSION);
158 pr_notice("Failed to get qed ethtool operations\n");
162 /* Must register notifier before pci ops, since we might miss
163 * interface rename after pci probe and netdev registeration.
165 ret = register_netdevice_notifier(&qede_netdev_notifier);
167 pr_notice("Failed to register netdevice_notifier\n");
172 ret = pci_register_driver(&qede_pci_driver);
174 pr_notice("Failed to register driver\n");
175 unregister_netdevice_notifier(&qede_netdev_notifier);
183 static void __exit qede_cleanup(void)
185 pr_notice("qede_cleanup called\n");
187 unregister_netdevice_notifier(&qede_netdev_notifier);
188 pci_unregister_driver(&qede_pci_driver);
192 module_init(qede_init);
193 module_exit(qede_cleanup);
195 /* -------------------------------------------------------------------------
197 * -------------------------------------------------------------------------
200 /* Unmap the data and free skb */
201 static int qede_free_tx_pkt(struct qede_dev *edev,
202 struct qede_tx_queue *txq,
205 u16 idx = txq->sw_tx_cons & NUM_TX_BDS_MAX;
206 struct sk_buff *skb = txq->sw_tx_ring[idx].skb;
207 struct eth_tx_1st_bd *first_bd;
208 struct eth_tx_bd *tx_data_bd;
209 int bds_consumed = 0;
211 bool data_split = txq->sw_tx_ring[idx].flags & QEDE_TSO_SPLIT_BD;
212 int i, split_bd_len = 0;
214 if (unlikely(!skb)) {
216 "skb is null for txq idx=%d txq->sw_tx_cons=%d txq->sw_tx_prod=%d\n",
217 idx, txq->sw_tx_cons, txq->sw_tx_prod);
223 first_bd = (struct eth_tx_1st_bd *)qed_chain_consume(&txq->tx_pbl);
227 nbds = first_bd->data.nbds;
230 struct eth_tx_bd *split = (struct eth_tx_bd *)
231 qed_chain_consume(&txq->tx_pbl);
232 split_bd_len = BD_UNMAP_LEN(split);
235 dma_unmap_page(&edev->pdev->dev, BD_UNMAP_ADDR(first_bd),
236 BD_UNMAP_LEN(first_bd) + split_bd_len, DMA_TO_DEVICE);
238 /* Unmap the data of the skb frags */
239 for (i = 0; i < skb_shinfo(skb)->nr_frags; i++, bds_consumed++) {
240 tx_data_bd = (struct eth_tx_bd *)
241 qed_chain_consume(&txq->tx_pbl);
242 dma_unmap_page(&edev->pdev->dev, BD_UNMAP_ADDR(tx_data_bd),
243 BD_UNMAP_LEN(tx_data_bd), DMA_TO_DEVICE);
246 while (bds_consumed++ < nbds)
247 qed_chain_consume(&txq->tx_pbl);
250 dev_kfree_skb_any(skb);
251 txq->sw_tx_ring[idx].skb = NULL;
252 txq->sw_tx_ring[idx].flags = 0;
257 /* Unmap the data and free skb when mapping failed during start_xmit */
258 static void qede_free_failed_tx_pkt(struct qede_dev *edev,
259 struct qede_tx_queue *txq,
260 struct eth_tx_1st_bd *first_bd,
264 u16 idx = txq->sw_tx_prod & NUM_TX_BDS_MAX;
265 struct sk_buff *skb = txq->sw_tx_ring[idx].skb;
266 struct eth_tx_bd *tx_data_bd;
267 int i, split_bd_len = 0;
269 /* Return prod to its position before this skb was handled */
270 qed_chain_set_prod(&txq->tx_pbl,
271 le16_to_cpu(txq->tx_db.data.bd_prod),
274 first_bd = (struct eth_tx_1st_bd *)qed_chain_produce(&txq->tx_pbl);
277 struct eth_tx_bd *split = (struct eth_tx_bd *)
278 qed_chain_produce(&txq->tx_pbl);
279 split_bd_len = BD_UNMAP_LEN(split);
283 dma_unmap_page(&edev->pdev->dev, BD_UNMAP_ADDR(first_bd),
284 BD_UNMAP_LEN(first_bd) + split_bd_len, DMA_TO_DEVICE);
286 /* Unmap the data of the skb frags */
287 for (i = 0; i < nbd; i++) {
288 tx_data_bd = (struct eth_tx_bd *)
289 qed_chain_produce(&txq->tx_pbl);
290 if (tx_data_bd->nbytes)
291 dma_unmap_page(&edev->pdev->dev,
292 BD_UNMAP_ADDR(tx_data_bd),
293 BD_UNMAP_LEN(tx_data_bd), DMA_TO_DEVICE);
296 /* Return again prod to its position before this skb was handled */
297 qed_chain_set_prod(&txq->tx_pbl,
298 le16_to_cpu(txq->tx_db.data.bd_prod),
302 dev_kfree_skb_any(skb);
303 txq->sw_tx_ring[idx].skb = NULL;
304 txq->sw_tx_ring[idx].flags = 0;
307 static u32 qede_xmit_type(struct qede_dev *edev,
311 u32 rc = XMIT_L4_CSUM;
314 if (skb->ip_summed != CHECKSUM_PARTIAL)
317 l3_proto = vlan_get_protocol(skb);
318 if (l3_proto == htons(ETH_P_IPV6) &&
319 (ipv6_hdr(skb)->nexthdr == NEXTHDR_IPV6))
328 static void qede_set_params_for_ipv6_ext(struct sk_buff *skb,
329 struct eth_tx_2nd_bd *second_bd,
330 struct eth_tx_3rd_bd *third_bd)
333 u16 bd2_bits = 0, bd2_bits2 = 0;
335 bd2_bits2 |= (1 << ETH_TX_DATA_2ND_BD_IPV6_EXT_SHIFT);
337 bd2_bits |= ((((u8 *)skb_transport_header(skb) - skb->data) >> 1) &
338 ETH_TX_DATA_2ND_BD_L4_HDR_START_OFFSET_W_MASK)
339 << ETH_TX_DATA_2ND_BD_L4_HDR_START_OFFSET_W_SHIFT;
341 bd2_bits2 |= (ETH_L4_PSEUDO_CSUM_CORRECT_LENGTH <<
342 ETH_TX_DATA_2ND_BD_L4_PSEUDO_CSUM_MODE_SHIFT);
344 if (vlan_get_protocol(skb) == htons(ETH_P_IPV6))
345 l4_proto = ipv6_hdr(skb)->nexthdr;
347 l4_proto = ip_hdr(skb)->protocol;
349 if (l4_proto == IPPROTO_UDP)
350 bd2_bits2 |= 1 << ETH_TX_DATA_2ND_BD_L4_UDP_SHIFT;
353 third_bd->data.bitfields |=
354 ((tcp_hdrlen(skb) / 4) &
355 ETH_TX_DATA_3RD_BD_TCP_HDR_LEN_DW_MASK) <<
356 ETH_TX_DATA_3RD_BD_TCP_HDR_LEN_DW_SHIFT;
359 second_bd->data.bitfields = cpu_to_le16(bd2_bits);
360 second_bd->data.bitfields2 = cpu_to_le16(bd2_bits2);
363 static int map_frag_to_bd(struct qede_dev *edev,
365 struct eth_tx_bd *bd)
369 /* Map skb non-linear frag data for DMA */
370 mapping = skb_frag_dma_map(&edev->pdev->dev, frag, 0,
373 if (unlikely(dma_mapping_error(&edev->pdev->dev, mapping))) {
374 DP_NOTICE(edev, "Unable to map frag - dropping packet\n");
378 /* Setup the data pointer of the frag data */
379 BD_SET_UNMAP_ADDR_LEN(bd, mapping, skb_frag_size(frag));
384 /* Main transmit function */
386 netdev_tx_t qede_start_xmit(struct sk_buff *skb,
387 struct net_device *ndev)
389 struct qede_dev *edev = netdev_priv(ndev);
390 struct netdev_queue *netdev_txq;
391 struct qede_tx_queue *txq;
392 struct eth_tx_1st_bd *first_bd;
393 struct eth_tx_2nd_bd *second_bd = NULL;
394 struct eth_tx_3rd_bd *third_bd = NULL;
395 struct eth_tx_bd *tx_data_bd = NULL;
399 int rc, frag_idx = 0, ipv6_ext = 0;
405 /* Get tx-queue context and netdev index */
406 txq_index = skb_get_queue_mapping(skb);
407 WARN_ON(txq_index >= QEDE_TSS_CNT(edev));
408 txq = QEDE_TX_QUEUE(edev, txq_index);
409 netdev_txq = netdev_get_tx_queue(ndev, txq_index);
411 /* Current code doesn't support SKB linearization, since the max number
412 * of skb frags can be passed in the FW HSI.
414 BUILD_BUG_ON(MAX_SKB_FRAGS > ETH_TX_MAX_BDS_PER_NON_LSO_PACKET);
416 WARN_ON(qed_chain_get_elem_left(&txq->tx_pbl) <
417 (MAX_SKB_FRAGS + 1));
419 xmit_type = qede_xmit_type(edev, skb, &ipv6_ext);
421 /* Fill the entry in the SW ring and the BDs in the FW ring */
422 idx = txq->sw_tx_prod & NUM_TX_BDS_MAX;
423 txq->sw_tx_ring[idx].skb = skb;
424 first_bd = (struct eth_tx_1st_bd *)
425 qed_chain_produce(&txq->tx_pbl);
426 memset(first_bd, 0, sizeof(*first_bd));
427 first_bd->data.bd_flags.bitfields =
428 1 << ETH_TX_1ST_BD_FLAGS_START_BD_SHIFT;
430 /* Map skb linear data for DMA and set in the first BD */
431 mapping = dma_map_single(&edev->pdev->dev, skb->data,
432 skb_headlen(skb), DMA_TO_DEVICE);
433 if (unlikely(dma_mapping_error(&edev->pdev->dev, mapping))) {
434 DP_NOTICE(edev, "SKB mapping failed\n");
435 qede_free_failed_tx_pkt(edev, txq, first_bd, 0, false);
439 BD_SET_UNMAP_ADDR_LEN(first_bd, mapping, skb_headlen(skb));
441 /* In case there is IPv6 with extension headers or LSO we need 2nd and
444 if (unlikely((xmit_type & XMIT_LSO) | ipv6_ext)) {
445 second_bd = (struct eth_tx_2nd_bd *)
446 qed_chain_produce(&txq->tx_pbl);
447 memset(second_bd, 0, sizeof(*second_bd));
450 third_bd = (struct eth_tx_3rd_bd *)
451 qed_chain_produce(&txq->tx_pbl);
452 memset(third_bd, 0, sizeof(*third_bd));
455 /* We need to fill in additional data in second_bd... */
456 tx_data_bd = (struct eth_tx_bd *)second_bd;
459 if (skb_vlan_tag_present(skb)) {
460 first_bd->data.vlan = cpu_to_le16(skb_vlan_tag_get(skb));
461 first_bd->data.bd_flags.bitfields |=
462 1 << ETH_TX_1ST_BD_FLAGS_VLAN_INSERTION_SHIFT;
465 /* Fill the parsing flags & params according to the requested offload */
466 if (xmit_type & XMIT_L4_CSUM) {
467 /* We don't re-calculate IP checksum as it is already done by
470 first_bd->data.bd_flags.bitfields |=
471 1 << ETH_TX_1ST_BD_FLAGS_L4_CSUM_SHIFT;
473 /* If the packet is IPv6 with extension header, indicate that
474 * to FW and pass few params, since the device cracker doesn't
475 * support parsing IPv6 with extension header/s.
477 if (unlikely(ipv6_ext))
478 qede_set_params_for_ipv6_ext(skb, second_bd, third_bd);
481 if (xmit_type & XMIT_LSO) {
482 first_bd->data.bd_flags.bitfields |=
483 (1 << ETH_TX_1ST_BD_FLAGS_LSO_SHIFT);
484 third_bd->data.lso_mss =
485 cpu_to_le16(skb_shinfo(skb)->gso_size);
487 first_bd->data.bd_flags.bitfields |=
488 1 << ETH_TX_1ST_BD_FLAGS_IP_CSUM_SHIFT;
489 hlen = skb_transport_header(skb) +
490 tcp_hdrlen(skb) - skb->data;
492 /* @@@TBD - if will not be removed need to check */
493 third_bd->data.bitfields |=
494 (1 << ETH_TX_DATA_3RD_BD_HDR_NBD_SHIFT);
496 /* Make life easier for FW guys who can't deal with header and
497 * data on same BD. If we need to split, use the second bd...
499 if (unlikely(skb_headlen(skb) > hlen)) {
500 DP_VERBOSE(edev, NETIF_MSG_TX_QUEUED,
501 "TSO split header size is %d (%x:%x)\n",
502 first_bd->nbytes, first_bd->addr.hi,
505 mapping = HILO_U64(le32_to_cpu(first_bd->addr.hi),
506 le32_to_cpu(first_bd->addr.lo)) +
509 BD_SET_UNMAP_ADDR_LEN(tx_data_bd, mapping,
510 le16_to_cpu(first_bd->nbytes) -
513 /* this marks the BD as one that has no
516 txq->sw_tx_ring[idx].flags |= QEDE_TSO_SPLIT_BD;
518 first_bd->nbytes = cpu_to_le16(hlen);
520 tx_data_bd = (struct eth_tx_bd *)third_bd;
525 /* Handle fragmented skb */
526 /* special handle for frags inside 2nd and 3rd bds.. */
527 while (tx_data_bd && frag_idx < skb_shinfo(skb)->nr_frags) {
528 rc = map_frag_to_bd(edev,
529 &skb_shinfo(skb)->frags[frag_idx],
532 qede_free_failed_tx_pkt(edev, txq, first_bd, nbd,
537 if (tx_data_bd == (struct eth_tx_bd *)second_bd)
538 tx_data_bd = (struct eth_tx_bd *)third_bd;
545 /* map last frags into 4th, 5th .... */
546 for (; frag_idx < skb_shinfo(skb)->nr_frags; frag_idx++, nbd++) {
547 tx_data_bd = (struct eth_tx_bd *)
548 qed_chain_produce(&txq->tx_pbl);
550 memset(tx_data_bd, 0, sizeof(*tx_data_bd));
552 rc = map_frag_to_bd(edev,
553 &skb_shinfo(skb)->frags[frag_idx],
556 qede_free_failed_tx_pkt(edev, txq, first_bd, nbd,
562 /* update the first BD with the actual num BDs */
563 first_bd->data.nbds = nbd;
565 netdev_tx_sent_queue(netdev_txq, skb->len);
567 skb_tx_timestamp(skb);
569 /* Advance packet producer only before sending the packet since mapping
574 /* 'next page' entries are counted in the producer value */
575 txq->tx_db.data.bd_prod =
576 cpu_to_le16(qed_chain_get_prod_idx(&txq->tx_pbl));
578 /* wmb makes sure that the BDs data is updated before updating the
579 * producer, otherwise FW may read old data from the BDs.
583 writel(txq->tx_db.raw, txq->doorbell_addr);
585 /* mmiowb is needed to synchronize doorbell writes from more than one
586 * processor. It guarantees that the write arrives to the device before
587 * the queue lock is released and another start_xmit is called (possibly
588 * on another CPU). Without this barrier, the next doorbell can bypass
589 * this doorbell. This is applicable to IA64/Altix systems.
593 if (unlikely(qed_chain_get_elem_left(&txq->tx_pbl)
594 < (MAX_SKB_FRAGS + 1))) {
595 netif_tx_stop_queue(netdev_txq);
596 DP_VERBOSE(edev, NETIF_MSG_TX_QUEUED,
597 "Stop queue was called\n");
598 /* paired memory barrier is in qede_tx_int(), we have to keep
599 * ordering of set_bit() in netif_tx_stop_queue() and read of
604 if (qed_chain_get_elem_left(&txq->tx_pbl)
605 >= (MAX_SKB_FRAGS + 1) &&
606 (edev->state == QEDE_STATE_OPEN)) {
607 netif_tx_wake_queue(netdev_txq);
608 DP_VERBOSE(edev, NETIF_MSG_TX_QUEUED,
609 "Wake queue was called\n");
616 static int qede_txq_has_work(struct qede_tx_queue *txq)
620 /* Tell compiler that consumer and producer can change */
622 hw_bd_cons = le16_to_cpu(*txq->hw_cons_ptr);
623 if (qed_chain_get_cons_idx(&txq->tx_pbl) == hw_bd_cons + 1)
626 return hw_bd_cons != qed_chain_get_cons_idx(&txq->tx_pbl);
629 static int qede_tx_int(struct qede_dev *edev,
630 struct qede_tx_queue *txq)
632 struct netdev_queue *netdev_txq;
634 unsigned int pkts_compl = 0, bytes_compl = 0;
637 netdev_txq = netdev_get_tx_queue(edev->ndev, txq->index);
639 hw_bd_cons = le16_to_cpu(*txq->hw_cons_ptr);
642 while (hw_bd_cons != qed_chain_get_cons_idx(&txq->tx_pbl)) {
645 rc = qede_free_tx_pkt(edev, txq, &len);
647 DP_NOTICE(edev, "hw_bd_cons = %d, chain_cons=%d\n",
649 qed_chain_get_cons_idx(&txq->tx_pbl));
658 netdev_tx_completed_queue(netdev_txq, pkts_compl, bytes_compl);
660 /* Need to make the tx_bd_cons update visible to start_xmit()
661 * before checking for netif_tx_queue_stopped(). Without the
662 * memory barrier, there is a small possibility that
663 * start_xmit() will miss it and cause the queue to be stopped
665 * On the other hand we need an rmb() here to ensure the proper
666 * ordering of bit testing in the following
667 * netif_tx_queue_stopped(txq) call.
671 if (unlikely(netif_tx_queue_stopped(netdev_txq))) {
672 /* Taking tx_lock is needed to prevent reenabling the queue
673 * while it's empty. This could have happen if rx_action() gets
674 * suspended in qede_tx_int() after the condition before
675 * netif_tx_wake_queue(), while tx_action (qede_start_xmit()):
677 * stops the queue->sees fresh tx_bd_cons->releases the queue->
678 * sends some packets consuming the whole queue again->
682 __netif_tx_lock(netdev_txq, smp_processor_id());
684 if ((netif_tx_queue_stopped(netdev_txq)) &&
685 (edev->state == QEDE_STATE_OPEN) &&
686 (qed_chain_get_elem_left(&txq->tx_pbl)
687 >= (MAX_SKB_FRAGS + 1))) {
688 netif_tx_wake_queue(netdev_txq);
689 DP_VERBOSE(edev, NETIF_MSG_TX_DONE,
690 "Wake queue was called\n");
693 __netif_tx_unlock(netdev_txq);
699 static bool qede_has_rx_work(struct qede_rx_queue *rxq)
701 u16 hw_comp_cons, sw_comp_cons;
703 /* Tell compiler that status block fields can change */
706 hw_comp_cons = le16_to_cpu(*rxq->hw_cons_ptr);
707 sw_comp_cons = qed_chain_get_cons_idx(&rxq->rx_comp_ring);
709 return hw_comp_cons != sw_comp_cons;
712 static bool qede_has_tx_work(struct qede_fastpath *fp)
716 for (tc = 0; tc < fp->edev->num_tc; tc++)
717 if (qede_txq_has_work(&fp->txqs[tc]))
722 /* This function copies the Rx buffer from the CONS position to the PROD
723 * position, since we failed to allocate a new Rx buffer.
725 static void qede_reuse_rx_data(struct qede_rx_queue *rxq)
727 struct eth_rx_bd *rx_bd_cons = qed_chain_consume(&rxq->rx_bd_ring);
728 struct eth_rx_bd *rx_bd_prod = qed_chain_produce(&rxq->rx_bd_ring);
729 struct sw_rx_data *sw_rx_data_cons =
730 &rxq->sw_rx_ring[rxq->sw_rx_cons & NUM_RX_BDS_MAX];
731 struct sw_rx_data *sw_rx_data_prod =
732 &rxq->sw_rx_ring[rxq->sw_rx_prod & NUM_RX_BDS_MAX];
734 dma_unmap_addr_set(sw_rx_data_prod, mapping,
735 dma_unmap_addr(sw_rx_data_cons, mapping));
737 sw_rx_data_prod->data = sw_rx_data_cons->data;
738 memcpy(rx_bd_prod, rx_bd_cons, sizeof(struct eth_rx_bd));
744 static inline void qede_update_rx_prod(struct qede_dev *edev,
745 struct qede_rx_queue *rxq)
747 u16 bd_prod = qed_chain_get_prod_idx(&rxq->rx_bd_ring);
748 u16 cqe_prod = qed_chain_get_prod_idx(&rxq->rx_comp_ring);
749 struct eth_rx_prod_data rx_prods = {0};
751 /* Update producers */
752 rx_prods.bd_prod = cpu_to_le16(bd_prod);
753 rx_prods.cqe_prod = cpu_to_le16(cqe_prod);
755 /* Make sure that the BD and SGE data is updated before updating the
756 * producers since FW might read the BD/SGE right after the producer
761 internal_ram_wr(rxq->hw_rxq_prod_addr, sizeof(rx_prods),
764 /* mmiowb is needed to synchronize doorbell writes from more than one
765 * processor. It guarantees that the write arrives to the device before
766 * the napi lock is released and another qede_poll is called (possibly
767 * on another CPU). Without this barrier, the next doorbell can bypass
768 * this doorbell. This is applicable to IA64/Altix systems.
773 static u32 qede_get_rxhash(struct qede_dev *edev,
776 enum pkt_hash_types *rxhash_type)
778 enum rss_hash_type htype;
780 htype = GET_FIELD(bitfields, ETH_FAST_PATH_RX_REG_CQE_RSS_HASH_TYPE);
782 if ((edev->ndev->features & NETIF_F_RXHASH) && htype) {
783 *rxhash_type = ((htype == RSS_HASH_TYPE_IPV4) ||
784 (htype == RSS_HASH_TYPE_IPV6)) ?
785 PKT_HASH_TYPE_L3 : PKT_HASH_TYPE_L4;
786 return le32_to_cpu(rss_hash);
788 *rxhash_type = PKT_HASH_TYPE_NONE;
792 static void qede_set_skb_csum(struct sk_buff *skb, u8 csum_flag)
794 skb_checksum_none_assert(skb);
796 if (csum_flag & QEDE_CSUM_UNNECESSARY)
797 skb->ip_summed = CHECKSUM_UNNECESSARY;
800 static inline void qede_skb_receive(struct qede_dev *edev,
801 struct qede_fastpath *fp,
806 __vlan_hwaccel_put_tag(skb, htons(ETH_P_8021Q),
809 napi_gro_receive(&fp->napi, skb);
812 static u8 qede_check_csum(u16 flag)
817 if ((PARSING_AND_ERR_FLAGS_L4CHKSMWASCALCULATED_MASK <<
818 PARSING_AND_ERR_FLAGS_L4CHKSMWASCALCULATED_SHIFT) & flag) {
819 csum_flag |= PARSING_AND_ERR_FLAGS_L4CHKSMERROR_MASK <<
820 PARSING_AND_ERR_FLAGS_L4CHKSMERROR_SHIFT;
821 csum = QEDE_CSUM_UNNECESSARY;
824 csum_flag |= PARSING_AND_ERR_FLAGS_IPHDRERROR_MASK <<
825 PARSING_AND_ERR_FLAGS_IPHDRERROR_SHIFT;
827 if (csum_flag & flag)
828 return QEDE_CSUM_ERROR;
833 static int qede_rx_int(struct qede_fastpath *fp, int budget)
835 struct qede_dev *edev = fp->edev;
836 struct qede_rx_queue *rxq = fp->rxq;
838 u16 hw_comp_cons, sw_comp_cons, sw_rx_index, parse_flag;
842 hw_comp_cons = le16_to_cpu(*rxq->hw_cons_ptr);
843 sw_comp_cons = qed_chain_get_cons_idx(&rxq->rx_comp_ring);
845 /* Memory barrier to prevent the CPU from doing speculative reads of CQE
846 * / BD in the while-loop before reading hw_comp_cons. If the CQE is
847 * read before it is written by FW, then FW writes CQE and SB, and then
848 * the CPU reads the hw_comp_cons, it will use an old CQE.
852 /* Loop to complete all indicated BDs */
853 while (sw_comp_cons != hw_comp_cons) {
854 struct eth_fast_path_rx_reg_cqe *fp_cqe;
855 enum pkt_hash_types rxhash_type;
856 enum eth_rx_cqe_type cqe_type;
857 struct sw_rx_data *sw_rx_data;
858 union eth_rx_cqe *cqe;
864 /* Get the CQE from the completion ring */
865 cqe = (union eth_rx_cqe *)
866 qed_chain_consume(&rxq->rx_comp_ring);
867 cqe_type = cqe->fast_path_regular.type;
869 if (unlikely(cqe_type == ETH_RX_CQE_TYPE_SLOW_PATH)) {
870 edev->ops->eth_cqe_completion(
871 edev->cdev, fp->rss_id,
872 (struct eth_slow_path_rx_cqe *)cqe);
876 /* Get the data from the SW ring */
877 sw_rx_index = rxq->sw_rx_cons & NUM_RX_BDS_MAX;
878 sw_rx_data = &rxq->sw_rx_ring[sw_rx_index];
879 data = sw_rx_data->data;
881 fp_cqe = &cqe->fast_path_regular;
882 len = le16_to_cpu(fp_cqe->pkt_len);
883 pad = fp_cqe->placement_offset;
885 /* For every Rx BD consumed, we allocate a new BD so the BD ring
886 * is always with a fixed size. If allocation fails, we take the
887 * consumed BD and return it to the ring in the PROD position.
888 * The packet that was received on that BD will be dropped (and
889 * not passed to the upper stack).
891 if (likely(qede_alloc_rx_buffer(edev, rxq) == 0)) {
892 dma_unmap_single(&edev->pdev->dev,
893 dma_unmap_addr(sw_rx_data, mapping),
894 rxq->rx_buf_size, DMA_FROM_DEVICE);
896 /* If this is an error packet then drop it */
898 le16_to_cpu(cqe->fast_path_regular.pars_flags.flags);
899 csum_flag = qede_check_csum(parse_flag);
900 if (csum_flag == QEDE_CSUM_ERROR) {
902 "CQE in CONS = %u has error, flags = %x, dropping incoming packet\n",
903 sw_comp_cons, parse_flag);
909 skb = build_skb(data, 0);
911 if (unlikely(!skb)) {
913 "Build_skb failed, dropping incoming packet\n");
915 rxq->rx_alloc_errors++;
919 skb_reserve(skb, pad);
923 "New buffer allocation failed, dropping incoming packet and reusing its buffer\n");
924 qede_reuse_rx_data(rxq);
925 rxq->rx_alloc_errors++;
929 sw_rx_data->data = NULL;
933 skb->protocol = eth_type_trans(skb, edev->ndev);
935 rx_hash = qede_get_rxhash(edev, fp_cqe->bitfields,
939 skb_set_hash(skb, rx_hash, rxhash_type);
941 qede_set_skb_csum(skb, csum_flag);
943 skb_record_rx_queue(skb, fp->rss_id);
945 qede_skb_receive(edev, fp, skb, le16_to_cpu(fp_cqe->vlan_tag));
947 qed_chain_consume(&rxq->rx_bd_ring);
953 next_cqe: /* don't consume bd rx buffer */
954 qed_chain_recycle_consumed(&rxq->rx_comp_ring);
955 sw_comp_cons = qed_chain_get_cons_idx(&rxq->rx_comp_ring);
956 /* CR TPA - revisit how to handle budget in TPA perhaps
959 if (rx_pkt == budget)
961 } /* repeat while sw_comp_cons != hw_comp_cons... */
963 /* Update producers */
964 qede_update_rx_prod(edev, rxq);
969 static int qede_poll(struct napi_struct *napi, int budget)
972 struct qede_fastpath *fp = container_of(napi, struct qede_fastpath,
974 struct qede_dev *edev = fp->edev;
979 for (tc = 0; tc < edev->num_tc; tc++)
980 if (qede_txq_has_work(&fp->txqs[tc]))
981 qede_tx_int(edev, &fp->txqs[tc]);
983 if (qede_has_rx_work(fp->rxq)) {
984 work_done += qede_rx_int(fp, budget - work_done);
986 /* must not complete if we consumed full budget */
987 if (work_done >= budget)
991 /* Fall out from the NAPI loop if needed */
992 if (!(qede_has_rx_work(fp->rxq) || qede_has_tx_work(fp))) {
993 qed_sb_update_sb_idx(fp->sb_info);
994 /* *_has_*_work() reads the status block,
995 * thus we need to ensure that status block indices
996 * have been actually read (qed_sb_update_sb_idx)
997 * prior to this check (*_has_*_work) so that
998 * we won't write the "newer" value of the status block
999 * to HW (if there was a DMA right after
1000 * qede_has_rx_work and if there is no rmb, the memory
1001 * reading (qed_sb_update_sb_idx) may be postponed
1002 * to right before *_ack_sb). In this case there
1003 * will never be another interrupt until there is
1004 * another update of the status block, while there
1005 * is still unhandled work.
1009 if (!(qede_has_rx_work(fp->rxq) ||
1010 qede_has_tx_work(fp))) {
1011 napi_complete(napi);
1012 /* Update and reenable interrupts */
1013 qed_sb_ack(fp->sb_info, IGU_INT_ENABLE,
1023 static irqreturn_t qede_msix_fp_int(int irq, void *fp_cookie)
1025 struct qede_fastpath *fp = fp_cookie;
1027 qed_sb_ack(fp->sb_info, IGU_INT_DISABLE, 0 /*do not update*/);
1029 napi_schedule_irqoff(&fp->napi);
1033 /* -------------------------------------------------------------------------
1035 * -------------------------------------------------------------------------
1038 static int qede_open(struct net_device *ndev);
1039 static int qede_close(struct net_device *ndev);
1040 static int qede_set_mac_addr(struct net_device *ndev, void *p);
1041 static void qede_set_rx_mode(struct net_device *ndev);
1042 static void qede_config_rx_mode(struct net_device *ndev);
1044 static int qede_set_ucast_rx_mac(struct qede_dev *edev,
1045 enum qed_filter_xcast_params_type opcode,
1046 unsigned char mac[ETH_ALEN])
1048 struct qed_filter_params filter_cmd;
1050 memset(&filter_cmd, 0, sizeof(filter_cmd));
1051 filter_cmd.type = QED_FILTER_TYPE_UCAST;
1052 filter_cmd.filter.ucast.type = opcode;
1053 filter_cmd.filter.ucast.mac_valid = 1;
1054 ether_addr_copy(filter_cmd.filter.ucast.mac, mac);
1056 return edev->ops->filter_config(edev->cdev, &filter_cmd);
1059 void qede_fill_by_demand_stats(struct qede_dev *edev)
1061 struct qed_eth_stats stats;
1063 edev->ops->get_vport_stats(edev->cdev, &stats);
1064 edev->stats.no_buff_discards = stats.no_buff_discards;
1065 edev->stats.rx_ucast_bytes = stats.rx_ucast_bytes;
1066 edev->stats.rx_mcast_bytes = stats.rx_mcast_bytes;
1067 edev->stats.rx_bcast_bytes = stats.rx_bcast_bytes;
1068 edev->stats.rx_ucast_pkts = stats.rx_ucast_pkts;
1069 edev->stats.rx_mcast_pkts = stats.rx_mcast_pkts;
1070 edev->stats.rx_bcast_pkts = stats.rx_bcast_pkts;
1071 edev->stats.mftag_filter_discards = stats.mftag_filter_discards;
1072 edev->stats.mac_filter_discards = stats.mac_filter_discards;
1074 edev->stats.tx_ucast_bytes = stats.tx_ucast_bytes;
1075 edev->stats.tx_mcast_bytes = stats.tx_mcast_bytes;
1076 edev->stats.tx_bcast_bytes = stats.tx_bcast_bytes;
1077 edev->stats.tx_ucast_pkts = stats.tx_ucast_pkts;
1078 edev->stats.tx_mcast_pkts = stats.tx_mcast_pkts;
1079 edev->stats.tx_bcast_pkts = stats.tx_bcast_pkts;
1080 edev->stats.tx_err_drop_pkts = stats.tx_err_drop_pkts;
1081 edev->stats.coalesced_pkts = stats.tpa_coalesced_pkts;
1082 edev->stats.coalesced_events = stats.tpa_coalesced_events;
1083 edev->stats.coalesced_aborts_num = stats.tpa_aborts_num;
1084 edev->stats.non_coalesced_pkts = stats.tpa_not_coalesced_pkts;
1085 edev->stats.coalesced_bytes = stats.tpa_coalesced_bytes;
1087 edev->stats.rx_64_byte_packets = stats.rx_64_byte_packets;
1088 edev->stats.rx_127_byte_packets = stats.rx_127_byte_packets;
1089 edev->stats.rx_255_byte_packets = stats.rx_255_byte_packets;
1090 edev->stats.rx_511_byte_packets = stats.rx_511_byte_packets;
1091 edev->stats.rx_1023_byte_packets = stats.rx_1023_byte_packets;
1092 edev->stats.rx_1518_byte_packets = stats.rx_1518_byte_packets;
1093 edev->stats.rx_1522_byte_packets = stats.rx_1522_byte_packets;
1094 edev->stats.rx_2047_byte_packets = stats.rx_2047_byte_packets;
1095 edev->stats.rx_4095_byte_packets = stats.rx_4095_byte_packets;
1096 edev->stats.rx_9216_byte_packets = stats.rx_9216_byte_packets;
1097 edev->stats.rx_16383_byte_packets = stats.rx_16383_byte_packets;
1098 edev->stats.rx_crc_errors = stats.rx_crc_errors;
1099 edev->stats.rx_mac_crtl_frames = stats.rx_mac_crtl_frames;
1100 edev->stats.rx_pause_frames = stats.rx_pause_frames;
1101 edev->stats.rx_pfc_frames = stats.rx_pfc_frames;
1102 edev->stats.rx_align_errors = stats.rx_align_errors;
1103 edev->stats.rx_carrier_errors = stats.rx_carrier_errors;
1104 edev->stats.rx_oversize_packets = stats.rx_oversize_packets;
1105 edev->stats.rx_jabbers = stats.rx_jabbers;
1106 edev->stats.rx_undersize_packets = stats.rx_undersize_packets;
1107 edev->stats.rx_fragments = stats.rx_fragments;
1108 edev->stats.tx_64_byte_packets = stats.tx_64_byte_packets;
1109 edev->stats.tx_65_to_127_byte_packets = stats.tx_65_to_127_byte_packets;
1110 edev->stats.tx_128_to_255_byte_packets =
1111 stats.tx_128_to_255_byte_packets;
1112 edev->stats.tx_256_to_511_byte_packets =
1113 stats.tx_256_to_511_byte_packets;
1114 edev->stats.tx_512_to_1023_byte_packets =
1115 stats.tx_512_to_1023_byte_packets;
1116 edev->stats.tx_1024_to_1518_byte_packets =
1117 stats.tx_1024_to_1518_byte_packets;
1118 edev->stats.tx_1519_to_2047_byte_packets =
1119 stats.tx_1519_to_2047_byte_packets;
1120 edev->stats.tx_2048_to_4095_byte_packets =
1121 stats.tx_2048_to_4095_byte_packets;
1122 edev->stats.tx_4096_to_9216_byte_packets =
1123 stats.tx_4096_to_9216_byte_packets;
1124 edev->stats.tx_9217_to_16383_byte_packets =
1125 stats.tx_9217_to_16383_byte_packets;
1126 edev->stats.tx_pause_frames = stats.tx_pause_frames;
1127 edev->stats.tx_pfc_frames = stats.tx_pfc_frames;
1128 edev->stats.tx_lpi_entry_count = stats.tx_lpi_entry_count;
1129 edev->stats.tx_total_collisions = stats.tx_total_collisions;
1130 edev->stats.brb_truncates = stats.brb_truncates;
1131 edev->stats.brb_discards = stats.brb_discards;
1132 edev->stats.tx_mac_ctrl_frames = stats.tx_mac_ctrl_frames;
1135 static struct rtnl_link_stats64 *qede_get_stats64(
1136 struct net_device *dev,
1137 struct rtnl_link_stats64 *stats)
1139 struct qede_dev *edev = netdev_priv(dev);
1141 qede_fill_by_demand_stats(edev);
1143 stats->rx_packets = edev->stats.rx_ucast_pkts +
1144 edev->stats.rx_mcast_pkts +
1145 edev->stats.rx_bcast_pkts;
1146 stats->tx_packets = edev->stats.tx_ucast_pkts +
1147 edev->stats.tx_mcast_pkts +
1148 edev->stats.tx_bcast_pkts;
1150 stats->rx_bytes = edev->stats.rx_ucast_bytes +
1151 edev->stats.rx_mcast_bytes +
1152 edev->stats.rx_bcast_bytes;
1154 stats->tx_bytes = edev->stats.tx_ucast_bytes +
1155 edev->stats.tx_mcast_bytes +
1156 edev->stats.tx_bcast_bytes;
1158 stats->tx_errors = edev->stats.tx_err_drop_pkts;
1159 stats->multicast = edev->stats.rx_mcast_pkts +
1160 edev->stats.rx_bcast_pkts;
1162 stats->rx_fifo_errors = edev->stats.no_buff_discards;
1164 stats->collisions = edev->stats.tx_total_collisions;
1165 stats->rx_crc_errors = edev->stats.rx_crc_errors;
1166 stats->rx_frame_errors = edev->stats.rx_align_errors;
1171 static const struct net_device_ops qede_netdev_ops = {
1172 .ndo_open = qede_open,
1173 .ndo_stop = qede_close,
1174 .ndo_start_xmit = qede_start_xmit,
1175 .ndo_set_rx_mode = qede_set_rx_mode,
1176 .ndo_set_mac_address = qede_set_mac_addr,
1177 .ndo_validate_addr = eth_validate_addr,
1178 .ndo_change_mtu = qede_change_mtu,
1179 .ndo_get_stats64 = qede_get_stats64,
1182 /* -------------------------------------------------------------------------
1183 * START OF PROBE / REMOVE
1184 * -------------------------------------------------------------------------
1187 static struct qede_dev *qede_alloc_etherdev(struct qed_dev *cdev,
1188 struct pci_dev *pdev,
1189 struct qed_dev_eth_info *info,
1193 struct net_device *ndev;
1194 struct qede_dev *edev;
1196 ndev = alloc_etherdev_mqs(sizeof(*edev),
1200 pr_err("etherdev allocation failed\n");
1204 edev = netdev_priv(ndev);
1208 edev->dp_module = dp_module;
1209 edev->dp_level = dp_level;
1210 edev->ops = qed_ops;
1211 edev->q_num_rx_buffers = NUM_RX_BDS_DEF;
1212 edev->q_num_tx_buffers = NUM_TX_BDS_DEF;
1214 DP_INFO(edev, "Allocated netdev with 64 tx queues and 64 rx queues\n");
1216 SET_NETDEV_DEV(ndev, &pdev->dev);
1218 memset(&edev->stats, 0, sizeof(edev->stats));
1219 memcpy(&edev->dev_info, info, sizeof(*info));
1221 edev->num_tc = edev->dev_info.num_tc;
1226 static void qede_init_ndev(struct qede_dev *edev)
1228 struct net_device *ndev = edev->ndev;
1229 struct pci_dev *pdev = edev->pdev;
1232 pci_set_drvdata(pdev, ndev);
1234 ndev->mem_start = edev->dev_info.common.pci_mem_start;
1235 ndev->base_addr = ndev->mem_start;
1236 ndev->mem_end = edev->dev_info.common.pci_mem_end;
1237 ndev->irq = edev->dev_info.common.pci_irq;
1239 ndev->watchdog_timeo = TX_TIMEOUT;
1241 ndev->netdev_ops = &qede_netdev_ops;
1243 qede_set_ethtool_ops(ndev);
1245 /* user-changeble features */
1246 hw_features = NETIF_F_GRO | NETIF_F_SG |
1247 NETIF_F_IP_CSUM | NETIF_F_IPV6_CSUM |
1248 NETIF_F_TSO | NETIF_F_TSO6;
1250 ndev->vlan_features = hw_features | NETIF_F_RXHASH | NETIF_F_RXCSUM |
1252 ndev->features = hw_features | NETIF_F_RXHASH | NETIF_F_RXCSUM |
1253 NETIF_F_HW_VLAN_CTAG_RX | NETIF_F_HIGHDMA |
1254 NETIF_F_HW_VLAN_CTAG_TX;
1256 ndev->hw_features = hw_features;
1258 /* Set network device HW mac */
1259 ether_addr_copy(edev->ndev->dev_addr, edev->dev_info.common.hw_mac);
1262 /* This function converts from 32b param to two params of level and module
1263 * Input 32b decoding:
1264 * b31 - enable all NOTICE prints. NOTICE prints are for deviation from the
1265 * 'happy' flow, e.g. memory allocation failed.
1266 * b30 - enable all INFO prints. INFO prints are for major steps in the flow
1267 * and provide important parameters.
1268 * b29-b0 - per-module bitmap, where each bit enables VERBOSE prints of that
1269 * module. VERBOSE prints are for tracking the specific flow in low level.
1271 * Notice that the level should be that of the lowest required logs.
1273 void qede_config_debug(uint debug, u32 *p_dp_module, u8 *p_dp_level)
1275 *p_dp_level = QED_LEVEL_NOTICE;
1278 if (debug & QED_LOG_VERBOSE_MASK) {
1279 *p_dp_level = QED_LEVEL_VERBOSE;
1280 *p_dp_module = (debug & 0x3FFFFFFF);
1281 } else if (debug & QED_LOG_INFO_MASK) {
1282 *p_dp_level = QED_LEVEL_INFO;
1283 } else if (debug & QED_LOG_NOTICE_MASK) {
1284 *p_dp_level = QED_LEVEL_NOTICE;
1288 static void qede_free_fp_array(struct qede_dev *edev)
1290 if (edev->fp_array) {
1291 struct qede_fastpath *fp;
1295 fp = &edev->fp_array[i];
1301 kfree(edev->fp_array);
1306 static int qede_alloc_fp_array(struct qede_dev *edev)
1308 struct qede_fastpath *fp;
1311 edev->fp_array = kcalloc(QEDE_RSS_CNT(edev),
1312 sizeof(*edev->fp_array), GFP_KERNEL);
1313 if (!edev->fp_array) {
1314 DP_NOTICE(edev, "fp array allocation failed\n");
1319 fp = &edev->fp_array[i];
1321 fp->sb_info = kcalloc(1, sizeof(*fp->sb_info), GFP_KERNEL);
1323 DP_NOTICE(edev, "sb info struct allocation failed\n");
1327 fp->rxq = kcalloc(1, sizeof(*fp->rxq), GFP_KERNEL);
1329 DP_NOTICE(edev, "RXQ struct allocation failed\n");
1333 fp->txqs = kcalloc(edev->num_tc, sizeof(*fp->txqs), GFP_KERNEL);
1335 DP_NOTICE(edev, "TXQ array allocation failed\n");
1342 qede_free_fp_array(edev);
1346 static void qede_sp_task(struct work_struct *work)
1348 struct qede_dev *edev = container_of(work, struct qede_dev,
1350 mutex_lock(&edev->qede_lock);
1352 if (edev->state == QEDE_STATE_OPEN) {
1353 if (test_and_clear_bit(QEDE_SP_RX_MODE, &edev->sp_flags))
1354 qede_config_rx_mode(edev->ndev);
1357 mutex_unlock(&edev->qede_lock);
1360 static void qede_update_pf_params(struct qed_dev *cdev)
1362 struct qed_pf_params pf_params;
1365 memset(&pf_params, 0, sizeof(struct qed_pf_params));
1366 pf_params.eth_pf_params.num_cons = 32;
1367 qed_ops->common->update_pf_params(cdev, &pf_params);
1370 enum qede_probe_mode {
1374 static int __qede_probe(struct pci_dev *pdev, u32 dp_module, u8 dp_level,
1375 enum qede_probe_mode mode)
1377 struct qed_slowpath_params params;
1378 struct qed_dev_eth_info dev_info;
1379 struct qede_dev *edev;
1380 struct qed_dev *cdev;
1383 if (unlikely(dp_level & QED_LEVEL_INFO))
1384 pr_notice("Starting qede probe\n");
1386 cdev = qed_ops->common->probe(pdev, QED_PROTOCOL_ETH,
1387 dp_module, dp_level);
1393 qede_update_pf_params(cdev);
1395 /* Start the Slowpath-process */
1396 memset(¶ms, 0, sizeof(struct qed_slowpath_params));
1397 params.int_mode = QED_INT_MODE_MSIX;
1398 params.drv_major = QEDE_MAJOR_VERSION;
1399 params.drv_minor = QEDE_MINOR_VERSION;
1400 params.drv_rev = QEDE_REVISION_VERSION;
1401 params.drv_eng = QEDE_ENGINEERING_VERSION;
1402 strlcpy(params.name, "qede LAN", QED_DRV_VER_STR_SIZE);
1403 rc = qed_ops->common->slowpath_start(cdev, ¶ms);
1405 pr_notice("Cannot start slowpath\n");
1409 /* Learn information crucial for qede to progress */
1410 rc = qed_ops->fill_dev_info(cdev, &dev_info);
1414 edev = qede_alloc_etherdev(cdev, pdev, &dev_info, dp_module,
1421 qede_init_ndev(edev);
1423 rc = register_netdev(edev->ndev);
1425 DP_NOTICE(edev, "Cannot register net-device\n");
1429 edev->ops->common->set_id(cdev, edev->ndev->name, DRV_MODULE_VERSION);
1431 edev->ops->register_ops(cdev, &qede_ll_ops, edev);
1433 INIT_DELAYED_WORK(&edev->sp_task, qede_sp_task);
1434 mutex_init(&edev->qede_lock);
1436 DP_INFO(edev, "Ending successfully qede probe\n");
1441 free_netdev(edev->ndev);
1443 qed_ops->common->slowpath_stop(cdev);
1445 qed_ops->common->remove(cdev);
1450 static int qede_probe(struct pci_dev *pdev, const struct pci_device_id *id)
1455 qede_config_debug(debug, &dp_module, &dp_level);
1457 return __qede_probe(pdev, dp_module, dp_level,
1461 enum qede_remove_mode {
1465 static void __qede_remove(struct pci_dev *pdev, enum qede_remove_mode mode)
1467 struct net_device *ndev = pci_get_drvdata(pdev);
1468 struct qede_dev *edev = netdev_priv(ndev);
1469 struct qed_dev *cdev = edev->cdev;
1471 DP_INFO(edev, "Starting qede_remove\n");
1473 cancel_delayed_work_sync(&edev->sp_task);
1474 unregister_netdev(ndev);
1476 edev->ops->common->set_power_state(cdev, PCI_D0);
1478 pci_set_drvdata(pdev, NULL);
1482 /* Use global ops since we've freed edev */
1483 qed_ops->common->slowpath_stop(cdev);
1484 qed_ops->common->remove(cdev);
1486 pr_notice("Ending successfully qede_remove\n");
1489 static void qede_remove(struct pci_dev *pdev)
1491 __qede_remove(pdev, QEDE_REMOVE_NORMAL);
1494 /* -------------------------------------------------------------------------
1495 * START OF LOAD / UNLOAD
1496 * -------------------------------------------------------------------------
1499 static int qede_set_num_queues(struct qede_dev *edev)
1504 /* Setup queues according to possible resources*/
1505 rss_num = netif_get_num_default_rss_queues() *
1506 edev->dev_info.common.num_hwfns;
1508 rss_num = min_t(u16, QEDE_MAX_RSS_CNT(edev), rss_num);
1510 rc = edev->ops->common->set_fp_int(edev->cdev, rss_num);
1512 /* Managed to request interrupts for our queues */
1514 DP_INFO(edev, "Managed %d [of %d] RSS queues\n",
1515 QEDE_RSS_CNT(edev), rss_num);
1521 static void qede_free_mem_sb(struct qede_dev *edev,
1522 struct qed_sb_info *sb_info)
1524 if (sb_info->sb_virt)
1525 dma_free_coherent(&edev->pdev->dev, sizeof(*sb_info->sb_virt),
1526 (void *)sb_info->sb_virt, sb_info->sb_phys);
1529 /* This function allocates fast-path status block memory */
1530 static int qede_alloc_mem_sb(struct qede_dev *edev,
1531 struct qed_sb_info *sb_info,
1534 struct status_block *sb_virt;
1538 sb_virt = dma_alloc_coherent(&edev->pdev->dev,
1540 &sb_phys, GFP_KERNEL);
1542 DP_ERR(edev, "Status block allocation failed\n");
1546 rc = edev->ops->common->sb_init(edev->cdev, sb_info,
1547 sb_virt, sb_phys, sb_id,
1548 QED_SB_TYPE_L2_QUEUE);
1550 DP_ERR(edev, "Status block initialization failed\n");
1551 dma_free_coherent(&edev->pdev->dev, sizeof(*sb_virt),
1559 static void qede_free_rx_buffers(struct qede_dev *edev,
1560 struct qede_rx_queue *rxq)
1564 for (i = rxq->sw_rx_cons; i != rxq->sw_rx_prod; i++) {
1565 struct sw_rx_data *rx_buf;
1568 rx_buf = &rxq->sw_rx_ring[i & NUM_RX_BDS_MAX];
1569 data = rx_buf->data;
1571 dma_unmap_single(&edev->pdev->dev,
1572 dma_unmap_addr(rx_buf, mapping),
1573 rxq->rx_buf_size, DMA_FROM_DEVICE);
1575 rx_buf->data = NULL;
1580 static void qede_free_mem_rxq(struct qede_dev *edev,
1581 struct qede_rx_queue *rxq)
1583 /* Free rx buffers */
1584 qede_free_rx_buffers(edev, rxq);
1586 /* Free the parallel SW ring */
1587 kfree(rxq->sw_rx_ring);
1589 /* Free the real RQ ring used by FW */
1590 edev->ops->common->chain_free(edev->cdev, &rxq->rx_bd_ring);
1591 edev->ops->common->chain_free(edev->cdev, &rxq->rx_comp_ring);
1594 static int qede_alloc_rx_buffer(struct qede_dev *edev,
1595 struct qede_rx_queue *rxq)
1597 struct sw_rx_data *sw_rx_data;
1598 struct eth_rx_bd *rx_bd;
1603 rx_buf_size = rxq->rx_buf_size;
1605 data = kmalloc(rx_buf_size, GFP_ATOMIC);
1606 if (unlikely(!data)) {
1607 DP_NOTICE(edev, "Failed to allocate Rx data\n");
1611 mapping = dma_map_single(&edev->pdev->dev, data,
1612 rx_buf_size, DMA_FROM_DEVICE);
1613 if (unlikely(dma_mapping_error(&edev->pdev->dev, mapping))) {
1615 DP_NOTICE(edev, "Failed to map Rx buffer\n");
1619 sw_rx_data = &rxq->sw_rx_ring[rxq->sw_rx_prod & NUM_RX_BDS_MAX];
1620 sw_rx_data->data = data;
1622 dma_unmap_addr_set(sw_rx_data, mapping, mapping);
1624 /* Advance PROD and get BD pointer */
1625 rx_bd = (struct eth_rx_bd *)qed_chain_produce(&rxq->rx_bd_ring);
1627 rx_bd->addr.hi = cpu_to_le32(upper_32_bits(mapping));
1628 rx_bd->addr.lo = cpu_to_le32(lower_32_bits(mapping));
1635 /* This function allocates all memory needed per Rx queue */
1636 static int qede_alloc_mem_rxq(struct qede_dev *edev,
1637 struct qede_rx_queue *rxq)
1639 int i, rc, size, num_allocated;
1641 rxq->num_rx_buffers = edev->q_num_rx_buffers;
1643 rxq->rx_buf_size = NET_IP_ALIGN +
1646 QEDE_FW_RX_ALIGN_END;
1648 /* Allocate the parallel driver ring for Rx buffers */
1649 size = sizeof(*rxq->sw_rx_ring) * NUM_RX_BDS_MAX;
1650 rxq->sw_rx_ring = kzalloc(size, GFP_KERNEL);
1651 if (!rxq->sw_rx_ring) {
1652 DP_ERR(edev, "Rx buffers ring allocation failed\n");
1656 /* Allocate FW Rx ring */
1657 rc = edev->ops->common->chain_alloc(edev->cdev,
1658 QED_CHAIN_USE_TO_CONSUME_PRODUCE,
1659 QED_CHAIN_MODE_NEXT_PTR,
1661 sizeof(struct eth_rx_bd),
1667 /* Allocate FW completion ring */
1668 rc = edev->ops->common->chain_alloc(edev->cdev,
1669 QED_CHAIN_USE_TO_CONSUME,
1672 sizeof(union eth_rx_cqe),
1673 &rxq->rx_comp_ring);
1677 /* Allocate buffers for the Rx ring */
1678 for (i = 0; i < rxq->num_rx_buffers; i++) {
1679 rc = qede_alloc_rx_buffer(edev, rxq);
1684 if (!num_allocated) {
1685 DP_ERR(edev, "Rx buffers allocation failed\n");
1687 } else if (num_allocated < rxq->num_rx_buffers) {
1689 "Allocated less buffers than desired (%d allocated)\n",
1696 qede_free_mem_rxq(edev, rxq);
1700 static void qede_free_mem_txq(struct qede_dev *edev,
1701 struct qede_tx_queue *txq)
1703 /* Free the parallel SW ring */
1704 kfree(txq->sw_tx_ring);
1706 /* Free the real RQ ring used by FW */
1707 edev->ops->common->chain_free(edev->cdev, &txq->tx_pbl);
1710 /* This function allocates all memory needed per Tx queue */
1711 static int qede_alloc_mem_txq(struct qede_dev *edev,
1712 struct qede_tx_queue *txq)
1715 union eth_tx_bd_types *p_virt;
1717 txq->num_tx_buffers = edev->q_num_tx_buffers;
1719 /* Allocate the parallel driver ring for Tx buffers */
1720 size = sizeof(*txq->sw_tx_ring) * NUM_TX_BDS_MAX;
1721 txq->sw_tx_ring = kzalloc(size, GFP_KERNEL);
1722 if (!txq->sw_tx_ring) {
1723 DP_NOTICE(edev, "Tx buffers ring allocation failed\n");
1727 rc = edev->ops->common->chain_alloc(edev->cdev,
1728 QED_CHAIN_USE_TO_CONSUME_PRODUCE,
1739 qede_free_mem_txq(edev, txq);
1743 /* This function frees all memory of a single fp */
1744 static void qede_free_mem_fp(struct qede_dev *edev,
1745 struct qede_fastpath *fp)
1749 qede_free_mem_sb(edev, fp->sb_info);
1751 qede_free_mem_rxq(edev, fp->rxq);
1753 for (tc = 0; tc < edev->num_tc; tc++)
1754 qede_free_mem_txq(edev, &fp->txqs[tc]);
1757 /* This function allocates all memory needed for a single fp (i.e. an entity
1758 * which contains status block, one rx queue and multiple per-TC tx queues.
1760 static int qede_alloc_mem_fp(struct qede_dev *edev,
1761 struct qede_fastpath *fp)
1765 rc = qede_alloc_mem_sb(edev, fp->sb_info, fp->rss_id);
1769 rc = qede_alloc_mem_rxq(edev, fp->rxq);
1773 for (tc = 0; tc < edev->num_tc; tc++) {
1774 rc = qede_alloc_mem_txq(edev, &fp->txqs[tc]);
1782 qede_free_mem_fp(edev, fp);
1786 static void qede_free_mem_load(struct qede_dev *edev)
1791 struct qede_fastpath *fp = &edev->fp_array[i];
1793 qede_free_mem_fp(edev, fp);
1797 /* This function allocates all qede memory at NIC load. */
1798 static int qede_alloc_mem_load(struct qede_dev *edev)
1802 for (rss_id = 0; rss_id < QEDE_RSS_CNT(edev); rss_id++) {
1803 struct qede_fastpath *fp = &edev->fp_array[rss_id];
1805 rc = qede_alloc_mem_fp(edev, fp);
1810 if (rss_id != QEDE_RSS_CNT(edev)) {
1811 /* Failed allocating memory for all the queues */
1814 "Failed to allocate memory for the leading queue\n");
1818 "Failed to allocate memory for all of RSS queues\n Desired: %d queues, allocated: %d queues\n",
1819 QEDE_RSS_CNT(edev), rss_id);
1821 edev->num_rss = rss_id;
1827 /* This function inits fp content and resets the SB, RXQ and TXQ structures */
1828 static void qede_init_fp(struct qede_dev *edev)
1830 int rss_id, txq_index, tc;
1831 struct qede_fastpath *fp;
1833 for_each_rss(rss_id) {
1834 fp = &edev->fp_array[rss_id];
1837 fp->rss_id = rss_id;
1839 memset((void *)&fp->napi, 0, sizeof(fp->napi));
1841 memset((void *)fp->sb_info, 0, sizeof(*fp->sb_info));
1843 memset((void *)fp->rxq, 0, sizeof(*fp->rxq));
1844 fp->rxq->rxq_id = rss_id;
1846 memset((void *)fp->txqs, 0, (edev->num_tc * sizeof(*fp->txqs)));
1847 for (tc = 0; tc < edev->num_tc; tc++) {
1848 txq_index = tc * QEDE_RSS_CNT(edev) + rss_id;
1849 fp->txqs[tc].index = txq_index;
1852 snprintf(fp->name, sizeof(fp->name), "%s-fp-%d",
1853 edev->ndev->name, rss_id);
1857 static int qede_set_real_num_queues(struct qede_dev *edev)
1861 rc = netif_set_real_num_tx_queues(edev->ndev, QEDE_TSS_CNT(edev));
1863 DP_NOTICE(edev, "Failed to set real number of Tx queues\n");
1866 rc = netif_set_real_num_rx_queues(edev->ndev, QEDE_RSS_CNT(edev));
1868 DP_NOTICE(edev, "Failed to set real number of Rx queues\n");
1875 static void qede_napi_disable_remove(struct qede_dev *edev)
1880 napi_disable(&edev->fp_array[i].napi);
1882 netif_napi_del(&edev->fp_array[i].napi);
1886 static void qede_napi_add_enable(struct qede_dev *edev)
1890 /* Add NAPI objects */
1892 netif_napi_add(edev->ndev, &edev->fp_array[i].napi,
1893 qede_poll, NAPI_POLL_WEIGHT);
1894 napi_enable(&edev->fp_array[i].napi);
1898 static void qede_sync_free_irqs(struct qede_dev *edev)
1902 for (i = 0; i < edev->int_info.used_cnt; i++) {
1903 if (edev->int_info.msix_cnt) {
1904 synchronize_irq(edev->int_info.msix[i].vector);
1905 free_irq(edev->int_info.msix[i].vector,
1906 &edev->fp_array[i]);
1908 edev->ops->common->simd_handler_clean(edev->cdev, i);
1912 edev->int_info.used_cnt = 0;
1915 static int qede_req_msix_irqs(struct qede_dev *edev)
1919 /* Sanitize number of interrupts == number of prepared RSS queues */
1920 if (QEDE_RSS_CNT(edev) > edev->int_info.msix_cnt) {
1922 "Interrupt mismatch: %d RSS queues > %d MSI-x vectors\n",
1923 QEDE_RSS_CNT(edev), edev->int_info.msix_cnt);
1927 for (i = 0; i < QEDE_RSS_CNT(edev); i++) {
1928 rc = request_irq(edev->int_info.msix[i].vector,
1929 qede_msix_fp_int, 0, edev->fp_array[i].name,
1930 &edev->fp_array[i]);
1932 DP_ERR(edev, "Request fp %d irq failed\n", i);
1933 qede_sync_free_irqs(edev);
1936 DP_VERBOSE(edev, NETIF_MSG_INTR,
1937 "Requested fp irq for %s [entry %d]. Cookie is at %p\n",
1938 edev->fp_array[i].name, i,
1939 &edev->fp_array[i]);
1940 edev->int_info.used_cnt++;
1946 static void qede_simd_fp_handler(void *cookie)
1948 struct qede_fastpath *fp = (struct qede_fastpath *)cookie;
1950 napi_schedule_irqoff(&fp->napi);
1953 static int qede_setup_irqs(struct qede_dev *edev)
1957 /* Learn Interrupt configuration */
1958 rc = edev->ops->common->get_fp_int(edev->cdev, &edev->int_info);
1962 if (edev->int_info.msix_cnt) {
1963 rc = qede_req_msix_irqs(edev);
1966 edev->ndev->irq = edev->int_info.msix[0].vector;
1968 const struct qed_common_ops *ops;
1970 /* qed should learn receive the RSS ids and callbacks */
1971 ops = edev->ops->common;
1972 for (i = 0; i < QEDE_RSS_CNT(edev); i++)
1973 ops->simd_handler_config(edev->cdev,
1974 &edev->fp_array[i], i,
1975 qede_simd_fp_handler);
1976 edev->int_info.used_cnt = QEDE_RSS_CNT(edev);
1981 static int qede_drain_txq(struct qede_dev *edev,
1982 struct qede_tx_queue *txq,
1987 while (txq->sw_tx_cons != txq->sw_tx_prod) {
1991 "Tx queue[%d] is stuck, requesting MCP to drain\n",
1993 rc = edev->ops->common->drain(edev->cdev);
1996 return qede_drain_txq(edev, txq, false);
1999 "Timeout waiting for tx queue[%d]: PROD=%d, CONS=%d\n",
2000 txq->index, txq->sw_tx_prod,
2005 usleep_range(1000, 2000);
2009 /* FW finished processing, wait for HW to transmit all tx packets */
2010 usleep_range(1000, 2000);
2015 static int qede_stop_queues(struct qede_dev *edev)
2017 struct qed_update_vport_params vport_update_params;
2018 struct qed_dev *cdev = edev->cdev;
2021 /* Disable the vport */
2022 memset(&vport_update_params, 0, sizeof(vport_update_params));
2023 vport_update_params.vport_id = 0;
2024 vport_update_params.update_vport_active_flg = 1;
2025 vport_update_params.vport_active_flg = 0;
2026 vport_update_params.update_rss_flg = 0;
2028 rc = edev->ops->vport_update(cdev, &vport_update_params);
2030 DP_ERR(edev, "Failed to update vport\n");
2034 /* Flush Tx queues. If needed, request drain from MCP */
2036 struct qede_fastpath *fp = &edev->fp_array[i];
2038 for (tc = 0; tc < edev->num_tc; tc++) {
2039 struct qede_tx_queue *txq = &fp->txqs[tc];
2041 rc = qede_drain_txq(edev, txq, true);
2047 /* Stop all Queues in reverse order*/
2048 for (i = QEDE_RSS_CNT(edev) - 1; i >= 0; i--) {
2049 struct qed_stop_rxq_params rx_params;
2051 /* Stop the Tx Queue(s)*/
2052 for (tc = 0; tc < edev->num_tc; tc++) {
2053 struct qed_stop_txq_params tx_params;
2055 tx_params.rss_id = i;
2056 tx_params.tx_queue_id = tc * QEDE_RSS_CNT(edev) + i;
2057 rc = edev->ops->q_tx_stop(cdev, &tx_params);
2059 DP_ERR(edev, "Failed to stop TXQ #%d\n",
2060 tx_params.tx_queue_id);
2065 /* Stop the Rx Queue*/
2066 memset(&rx_params, 0, sizeof(rx_params));
2067 rx_params.rss_id = i;
2068 rx_params.rx_queue_id = i;
2070 rc = edev->ops->q_rx_stop(cdev, &rx_params);
2072 DP_ERR(edev, "Failed to stop RXQ #%d\n", i);
2077 /* Stop the vport */
2078 rc = edev->ops->vport_stop(cdev, 0);
2080 DP_ERR(edev, "Failed to stop VPORT\n");
2085 static int qede_start_queues(struct qede_dev *edev)
2088 int vport_id = 0, drop_ttl0_flg = 1, vlan_removal_en = 1;
2089 struct qed_dev *cdev = edev->cdev;
2090 struct qed_update_vport_rss_params *rss_params = &edev->rss_params;
2091 struct qed_update_vport_params vport_update_params;
2092 struct qed_queue_start_common_params q_params;
2094 if (!edev->num_rss) {
2096 "Cannot update V-VPORT as active as there are no Rx queues\n");
2100 rc = edev->ops->vport_start(cdev, vport_id,
2106 DP_ERR(edev, "Start V-PORT failed %d\n", rc);
2110 DP_VERBOSE(edev, NETIF_MSG_IFUP,
2111 "Start vport ramrod passed, vport_id = %d, MTU = %d, vlan_removal_en = %d\n",
2112 vport_id, edev->ndev->mtu + 0xe, vlan_removal_en);
2115 struct qede_fastpath *fp = &edev->fp_array[i];
2116 dma_addr_t phys_table = fp->rxq->rx_comp_ring.pbl.p_phys_table;
2118 memset(&q_params, 0, sizeof(q_params));
2119 q_params.rss_id = i;
2120 q_params.queue_id = i;
2121 q_params.vport_id = 0;
2122 q_params.sb = fp->sb_info->igu_sb_id;
2123 q_params.sb_idx = RX_PI;
2125 rc = edev->ops->q_rx_start(cdev, &q_params,
2126 fp->rxq->rx_buf_size,
2127 fp->rxq->rx_bd_ring.p_phys_addr,
2129 fp->rxq->rx_comp_ring.page_cnt,
2130 &fp->rxq->hw_rxq_prod_addr);
2132 DP_ERR(edev, "Start RXQ #%d failed %d\n", i, rc);
2136 fp->rxq->hw_cons_ptr = &fp->sb_info->sb_virt->pi_array[RX_PI];
2138 qede_update_rx_prod(edev, fp->rxq);
2140 for (tc = 0; tc < edev->num_tc; tc++) {
2141 struct qede_tx_queue *txq = &fp->txqs[tc];
2142 int txq_index = tc * QEDE_RSS_CNT(edev) + i;
2144 memset(&q_params, 0, sizeof(q_params));
2145 q_params.rss_id = i;
2146 q_params.queue_id = txq_index;
2147 q_params.vport_id = 0;
2148 q_params.sb = fp->sb_info->igu_sb_id;
2149 q_params.sb_idx = TX_PI(tc);
2151 rc = edev->ops->q_tx_start(cdev, &q_params,
2152 txq->tx_pbl.pbl.p_phys_table,
2153 txq->tx_pbl.page_cnt,
2154 &txq->doorbell_addr);
2156 DP_ERR(edev, "Start TXQ #%d failed %d\n",
2162 &fp->sb_info->sb_virt->pi_array[TX_PI(tc)];
2163 SET_FIELD(txq->tx_db.data.params,
2164 ETH_DB_DATA_DEST, DB_DEST_XCM);
2165 SET_FIELD(txq->tx_db.data.params, ETH_DB_DATA_AGG_CMD,
2167 SET_FIELD(txq->tx_db.data.params,
2168 ETH_DB_DATA_AGG_VAL_SEL,
2169 DQ_XCM_ETH_TX_BD_PROD_CMD);
2171 txq->tx_db.data.agg_flags = DQ_XCM_ETH_DQ_CF_CMD;
2175 /* Prepare and send the vport enable */
2176 memset(&vport_update_params, 0, sizeof(vport_update_params));
2177 vport_update_params.vport_id = vport_id;
2178 vport_update_params.update_vport_active_flg = 1;
2179 vport_update_params.vport_active_flg = 1;
2181 /* Fill struct with RSS params */
2182 if (QEDE_RSS_CNT(edev) > 1) {
2183 vport_update_params.update_rss_flg = 1;
2184 for (i = 0; i < 128; i++)
2185 rss_params->rss_ind_table[i] =
2186 ethtool_rxfh_indir_default(i, QEDE_RSS_CNT(edev));
2187 netdev_rss_key_fill(rss_params->rss_key,
2188 sizeof(rss_params->rss_key));
2190 memset(rss_params, 0, sizeof(*rss_params));
2192 memcpy(&vport_update_params.rss_params, rss_params,
2193 sizeof(*rss_params));
2195 rc = edev->ops->vport_update(cdev, &vport_update_params);
2197 DP_ERR(edev, "Update V-PORT failed %d\n", rc);
2204 static int qede_set_mcast_rx_mac(struct qede_dev *edev,
2205 enum qed_filter_xcast_params_type opcode,
2206 unsigned char *mac, int num_macs)
2208 struct qed_filter_params filter_cmd;
2211 memset(&filter_cmd, 0, sizeof(filter_cmd));
2212 filter_cmd.type = QED_FILTER_TYPE_MCAST;
2213 filter_cmd.filter.mcast.type = opcode;
2214 filter_cmd.filter.mcast.num = num_macs;
2216 for (i = 0; i < num_macs; i++, mac += ETH_ALEN)
2217 ether_addr_copy(filter_cmd.filter.mcast.mac[i], mac);
2219 return edev->ops->filter_config(edev->cdev, &filter_cmd);
2222 enum qede_unload_mode {
2226 static void qede_unload(struct qede_dev *edev, enum qede_unload_mode mode)
2228 struct qed_link_params link_params;
2231 DP_INFO(edev, "Starting qede unload\n");
2233 mutex_lock(&edev->qede_lock);
2234 edev->state = QEDE_STATE_CLOSED;
2237 netif_tx_disable(edev->ndev);
2238 netif_carrier_off(edev->ndev);
2240 /* Reset the link */
2241 memset(&link_params, 0, sizeof(link_params));
2242 link_params.link_up = false;
2243 edev->ops->common->set_link(edev->cdev, &link_params);
2244 rc = qede_stop_queues(edev);
2246 qede_sync_free_irqs(edev);
2250 DP_INFO(edev, "Stopped Queues\n");
2252 edev->ops->fastpath_stop(edev->cdev);
2254 /* Release the interrupts */
2255 qede_sync_free_irqs(edev);
2256 edev->ops->common->set_fp_int(edev->cdev, 0);
2258 qede_napi_disable_remove(edev);
2260 qede_free_mem_load(edev);
2261 qede_free_fp_array(edev);
2264 mutex_unlock(&edev->qede_lock);
2265 DP_INFO(edev, "Ending qede unload\n");
2268 enum qede_load_mode {
2272 static int qede_load(struct qede_dev *edev, enum qede_load_mode mode)
2274 struct qed_link_params link_params;
2275 struct qed_link_output link_output;
2278 DP_INFO(edev, "Starting qede load\n");
2280 rc = qede_set_num_queues(edev);
2284 rc = qede_alloc_fp_array(edev);
2290 rc = qede_alloc_mem_load(edev);
2293 DP_INFO(edev, "Allocated %d RSS queues on %d TC/s\n",
2294 QEDE_RSS_CNT(edev), edev->num_tc);
2296 rc = qede_set_real_num_queues(edev);
2300 qede_napi_add_enable(edev);
2301 DP_INFO(edev, "Napi added and enabled\n");
2303 rc = qede_setup_irqs(edev);
2306 DP_INFO(edev, "Setup IRQs succeeded\n");
2308 rc = qede_start_queues(edev);
2311 DP_INFO(edev, "Start VPORT, RXQ and TXQ succeeded\n");
2313 /* Add primary mac and set Rx filters */
2314 ether_addr_copy(edev->primary_mac, edev->ndev->dev_addr);
2316 mutex_lock(&edev->qede_lock);
2317 edev->state = QEDE_STATE_OPEN;
2318 mutex_unlock(&edev->qede_lock);
2320 /* Ask for link-up using current configuration */
2321 memset(&link_params, 0, sizeof(link_params));
2322 link_params.link_up = true;
2323 edev->ops->common->set_link(edev->cdev, &link_params);
2325 /* Query whether link is already-up */
2326 memset(&link_output, 0, sizeof(link_output));
2327 edev->ops->common->get_link(edev->cdev, &link_output);
2328 qede_link_update(edev, &link_output);
2330 DP_INFO(edev, "Ending successfully qede load\n");
2335 qede_sync_free_irqs(edev);
2336 memset(&edev->int_info.msix_cnt, 0, sizeof(struct qed_int_info));
2338 qede_napi_disable_remove(edev);
2340 qede_free_mem_load(edev);
2342 edev->ops->common->set_fp_int(edev->cdev, 0);
2343 qede_free_fp_array(edev);
2349 void qede_reload(struct qede_dev *edev,
2350 void (*func)(struct qede_dev *, union qede_reload_args *),
2351 union qede_reload_args *args)
2353 qede_unload(edev, QEDE_UNLOAD_NORMAL);
2354 /* Call function handler to update parameters
2355 * needed for function load.
2360 qede_load(edev, QEDE_LOAD_NORMAL);
2362 mutex_lock(&edev->qede_lock);
2363 qede_config_rx_mode(edev->ndev);
2364 mutex_unlock(&edev->qede_lock);
2367 /* called with rtnl_lock */
2368 static int qede_open(struct net_device *ndev)
2370 struct qede_dev *edev = netdev_priv(ndev);
2372 netif_carrier_off(ndev);
2374 edev->ops->common->set_power_state(edev->cdev, PCI_D0);
2376 return qede_load(edev, QEDE_LOAD_NORMAL);
2379 static int qede_close(struct net_device *ndev)
2381 struct qede_dev *edev = netdev_priv(ndev);
2383 qede_unload(edev, QEDE_UNLOAD_NORMAL);
2388 static void qede_link_update(void *dev, struct qed_link_output *link)
2390 struct qede_dev *edev = dev;
2392 if (!netif_running(edev->ndev)) {
2393 DP_VERBOSE(edev, NETIF_MSG_LINK, "Interface is not running\n");
2397 if (link->link_up) {
2398 DP_NOTICE(edev, "Link is up\n");
2399 netif_tx_start_all_queues(edev->ndev);
2400 netif_carrier_on(edev->ndev);
2402 DP_NOTICE(edev, "Link is down\n");
2403 netif_tx_disable(edev->ndev);
2404 netif_carrier_off(edev->ndev);
2408 static int qede_set_mac_addr(struct net_device *ndev, void *p)
2410 struct qede_dev *edev = netdev_priv(ndev);
2411 struct sockaddr *addr = p;
2414 ASSERT_RTNL(); /* @@@TBD To be removed */
2416 DP_INFO(edev, "Set_mac_addr called\n");
2418 if (!is_valid_ether_addr(addr->sa_data)) {
2419 DP_NOTICE(edev, "The MAC address is not valid\n");
2423 ether_addr_copy(ndev->dev_addr, addr->sa_data);
2425 if (!netif_running(ndev)) {
2426 DP_NOTICE(edev, "The device is currently down\n");
2430 /* Remove the previous primary mac */
2431 rc = qede_set_ucast_rx_mac(edev, QED_FILTER_XCAST_TYPE_DEL,
2436 /* Add MAC filter according to the new unicast HW MAC address */
2437 ether_addr_copy(edev->primary_mac, ndev->dev_addr);
2438 return qede_set_ucast_rx_mac(edev, QED_FILTER_XCAST_TYPE_ADD,
2443 qede_configure_mcast_filtering(struct net_device *ndev,
2444 enum qed_filter_rx_mode_type *accept_flags)
2446 struct qede_dev *edev = netdev_priv(ndev);
2447 unsigned char *mc_macs, *temp;
2448 struct netdev_hw_addr *ha;
2449 int rc = 0, mc_count;
2452 size = 64 * ETH_ALEN;
2454 mc_macs = kzalloc(size, GFP_KERNEL);
2457 "Failed to allocate memory for multicast MACs\n");
2464 /* Remove all previously configured MAC filters */
2465 rc = qede_set_mcast_rx_mac(edev, QED_FILTER_XCAST_TYPE_DEL,
2470 netif_addr_lock_bh(ndev);
2472 mc_count = netdev_mc_count(ndev);
2473 if (mc_count < 64) {
2474 netdev_for_each_mc_addr(ha, ndev) {
2475 ether_addr_copy(temp, ha->addr);
2480 netif_addr_unlock_bh(ndev);
2482 /* Check for all multicast @@@TBD resource allocation */
2483 if ((ndev->flags & IFF_ALLMULTI) ||
2485 if (*accept_flags == QED_FILTER_RX_MODE_TYPE_REGULAR)
2486 *accept_flags = QED_FILTER_RX_MODE_TYPE_MULTI_PROMISC;
2488 /* Add all multicast MAC filters */
2489 rc = qede_set_mcast_rx_mac(edev, QED_FILTER_XCAST_TYPE_ADD,
2498 static void qede_set_rx_mode(struct net_device *ndev)
2500 struct qede_dev *edev = netdev_priv(ndev);
2502 DP_INFO(edev, "qede_set_rx_mode called\n");
2504 if (edev->state != QEDE_STATE_OPEN) {
2506 "qede_set_rx_mode called while interface is down\n");
2508 set_bit(QEDE_SP_RX_MODE, &edev->sp_flags);
2509 schedule_delayed_work(&edev->sp_task, 0);
2513 /* Must be called with qede_lock held */
2514 static void qede_config_rx_mode(struct net_device *ndev)
2516 enum qed_filter_rx_mode_type accept_flags = QED_FILTER_TYPE_UCAST;
2517 struct qede_dev *edev = netdev_priv(ndev);
2518 struct qed_filter_params rx_mode;
2519 unsigned char *uc_macs, *temp;
2520 struct netdev_hw_addr *ha;
2524 netif_addr_lock_bh(ndev);
2526 uc_count = netdev_uc_count(ndev);
2527 size = uc_count * ETH_ALEN;
2529 uc_macs = kzalloc(size, GFP_ATOMIC);
2531 DP_NOTICE(edev, "Failed to allocate memory for unicast MACs\n");
2532 netif_addr_unlock_bh(ndev);
2537 netdev_for_each_uc_addr(ha, ndev) {
2538 ether_addr_copy(temp, ha->addr);
2542 netif_addr_unlock_bh(ndev);
2544 /* Configure the struct for the Rx mode */
2545 memset(&rx_mode, 0, sizeof(struct qed_filter_params));
2546 rx_mode.type = QED_FILTER_TYPE_RX_MODE;
2548 /* Remove all previous unicast secondary macs and multicast macs
2549 * (configrue / leave the primary mac)
2551 rc = qede_set_ucast_rx_mac(edev, QED_FILTER_XCAST_TYPE_REPLACE,
2556 /* Check for promiscuous */
2557 if ((ndev->flags & IFF_PROMISC) ||
2558 (uc_count > 15)) { /* @@@TBD resource allocation - 1 */
2559 accept_flags = QED_FILTER_RX_MODE_TYPE_PROMISC;
2561 /* Add MAC filters according to the unicast secondary macs */
2565 for (i = 0; i < uc_count; i++) {
2566 rc = qede_set_ucast_rx_mac(edev,
2567 QED_FILTER_XCAST_TYPE_ADD,
2575 rc = qede_configure_mcast_filtering(ndev, &accept_flags);
2580 rx_mode.filter.accept_flags = accept_flags;
2581 edev->ops->filter_config(edev->cdev, &rx_mode);
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