tsnep_main.c 68 KB

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  1. // SPDX-License-Identifier: GPL-2.0
  2. /* Copyright (C) 2021 Gerhard Engleder <gerhard@engleder-embedded.com> */
  3. /* TSN endpoint Ethernet MAC driver
  4. *
  5. * The TSN endpoint Ethernet MAC is a FPGA based network device for real-time
  6. * communication. It is designed for endpoints within TSN (Time Sensitive
  7. * Networking) networks; e.g., for PLCs in the industrial automation case.
  8. *
  9. * It supports multiple TX/RX queue pairs. The first TX/RX queue pair is used
  10. * by the driver.
  11. *
  12. * More information can be found here:
  13. * - www.embedded-experts.at/tsn
  14. * - www.engleder-embedded.com
  15. */
  16. #include "tsnep.h"
  17. #include "tsnep_hw.h"
  18. #include <linux/module.h>
  19. #include <linux/of.h>
  20. #include <linux/of_net.h>
  21. #include <linux/of_mdio.h>
  22. #include <linux/interrupt.h>
  23. #include <linux/etherdevice.h>
  24. #include <linux/phy.h>
  25. #include <linux/iopoll.h>
  26. #include <linux/bpf.h>
  27. #include <linux/bpf_trace.h>
  28. #include <net/page_pool/helpers.h>
  29. #include <net/xdp_sock_drv.h>
  30. #define TSNEP_RX_OFFSET (max(NET_SKB_PAD, XDP_PACKET_HEADROOM) + NET_IP_ALIGN)
  31. #define TSNEP_HEADROOM ALIGN(TSNEP_RX_OFFSET, 4)
  32. #define TSNEP_MAX_RX_BUF_SIZE (PAGE_SIZE - TSNEP_HEADROOM - \
  33. SKB_DATA_ALIGN(sizeof(struct skb_shared_info)))
  34. /* XSK buffer shall store at least Q-in-Q frame */
  35. #define TSNEP_XSK_RX_BUF_SIZE (ALIGN(TSNEP_RX_INLINE_METADATA_SIZE + \
  36. ETH_FRAME_LEN + ETH_FCS_LEN + \
  37. VLAN_HLEN * 2, 4))
  38. #ifdef CONFIG_ARCH_DMA_ADDR_T_64BIT
  39. #define DMA_ADDR_HIGH(dma_addr) ((u32)(((dma_addr) >> 32) & 0xFFFFFFFF))
  40. #else
  41. #define DMA_ADDR_HIGH(dma_addr) ((u32)(0))
  42. #endif
  43. #define DMA_ADDR_LOW(dma_addr) ((u32)((dma_addr) & 0xFFFFFFFF))
  44. #define TSNEP_COALESCE_USECS_DEFAULT 64
  45. #define TSNEP_COALESCE_USECS_MAX ((ECM_INT_DELAY_MASK >> ECM_INT_DELAY_SHIFT) * \
  46. ECM_INT_DELAY_BASE_US + ECM_INT_DELAY_BASE_US - 1)
  47. /* mapping type */
  48. #define TSNEP_TX_TYPE_MAP BIT(0)
  49. #define TSNEP_TX_TYPE_MAP_PAGE BIT(1)
  50. #define TSNEP_TX_TYPE_INLINE BIT(2)
  51. /* buffer type */
  52. #define TSNEP_TX_TYPE_SKB BIT(8)
  53. #define TSNEP_TX_TYPE_SKB_MAP (TSNEP_TX_TYPE_SKB | TSNEP_TX_TYPE_MAP)
  54. #define TSNEP_TX_TYPE_SKB_INLINE (TSNEP_TX_TYPE_SKB | TSNEP_TX_TYPE_INLINE)
  55. #define TSNEP_TX_TYPE_SKB_FRAG BIT(9)
  56. #define TSNEP_TX_TYPE_SKB_FRAG_MAP_PAGE (TSNEP_TX_TYPE_SKB_FRAG | TSNEP_TX_TYPE_MAP_PAGE)
  57. #define TSNEP_TX_TYPE_SKB_FRAG_INLINE (TSNEP_TX_TYPE_SKB_FRAG | TSNEP_TX_TYPE_INLINE)
  58. #define TSNEP_TX_TYPE_XDP_TX BIT(10)
  59. #define TSNEP_TX_TYPE_XDP_NDO BIT(11)
  60. #define TSNEP_TX_TYPE_XDP_NDO_MAP_PAGE (TSNEP_TX_TYPE_XDP_NDO | TSNEP_TX_TYPE_MAP_PAGE)
  61. #define TSNEP_TX_TYPE_XDP (TSNEP_TX_TYPE_XDP_TX | TSNEP_TX_TYPE_XDP_NDO)
  62. #define TSNEP_TX_TYPE_XSK BIT(12)
  63. #define TSNEP_TX_TYPE_TSTAMP BIT(13)
  64. #define TSNEP_TX_TYPE_SKB_TSTAMP (TSNEP_TX_TYPE_SKB | TSNEP_TX_TYPE_TSTAMP)
  65. #define TSNEP_XDP_TX BIT(0)
  66. #define TSNEP_XDP_REDIRECT BIT(1)
  67. static void tsnep_enable_irq(struct tsnep_adapter *adapter, u32 mask)
  68. {
  69. iowrite32(mask, adapter->addr + ECM_INT_ENABLE);
  70. }
  71. static void tsnep_disable_irq(struct tsnep_adapter *adapter, u32 mask)
  72. {
  73. mask |= ECM_INT_DISABLE;
  74. iowrite32(mask, adapter->addr + ECM_INT_ENABLE);
  75. }
  76. static irqreturn_t tsnep_irq(int irq, void *arg)
  77. {
  78. struct tsnep_adapter *adapter = arg;
  79. u32 active = ioread32(adapter->addr + ECM_INT_ACTIVE);
  80. /* acknowledge interrupt */
  81. if (active != 0)
  82. iowrite32(active, adapter->addr + ECM_INT_ACKNOWLEDGE);
  83. /* handle link interrupt */
  84. if ((active & ECM_INT_LINK) != 0)
  85. phy_mac_interrupt(adapter->netdev->phydev);
  86. /* handle TX/RX queue 0 interrupt */
  87. if ((active & adapter->queue[0].irq_mask) != 0) {
  88. if (napi_schedule_prep(&adapter->queue[0].napi)) {
  89. tsnep_disable_irq(adapter, adapter->queue[0].irq_mask);
  90. /* schedule after masking to avoid races */
  91. __napi_schedule(&adapter->queue[0].napi);
  92. }
  93. }
  94. return IRQ_HANDLED;
  95. }
  96. static irqreturn_t tsnep_irq_txrx(int irq, void *arg)
  97. {
  98. struct tsnep_queue *queue = arg;
  99. /* handle TX/RX queue interrupt */
  100. if (napi_schedule_prep(&queue->napi)) {
  101. tsnep_disable_irq(queue->adapter, queue->irq_mask);
  102. /* schedule after masking to avoid races */
  103. __napi_schedule(&queue->napi);
  104. }
  105. return IRQ_HANDLED;
  106. }
  107. int tsnep_set_irq_coalesce(struct tsnep_queue *queue, u32 usecs)
  108. {
  109. if (usecs > TSNEP_COALESCE_USECS_MAX)
  110. return -ERANGE;
  111. usecs /= ECM_INT_DELAY_BASE_US;
  112. usecs <<= ECM_INT_DELAY_SHIFT;
  113. usecs &= ECM_INT_DELAY_MASK;
  114. queue->irq_delay &= ~ECM_INT_DELAY_MASK;
  115. queue->irq_delay |= usecs;
  116. iowrite8(queue->irq_delay, queue->irq_delay_addr);
  117. return 0;
  118. }
  119. u32 tsnep_get_irq_coalesce(struct tsnep_queue *queue)
  120. {
  121. u32 usecs;
  122. usecs = (queue->irq_delay & ECM_INT_DELAY_MASK);
  123. usecs >>= ECM_INT_DELAY_SHIFT;
  124. usecs *= ECM_INT_DELAY_BASE_US;
  125. return usecs;
  126. }
  127. static int tsnep_mdiobus_read(struct mii_bus *bus, int addr, int regnum)
  128. {
  129. struct tsnep_adapter *adapter = bus->priv;
  130. u32 md;
  131. int retval;
  132. md = ECM_MD_READ;
  133. if (!adapter->suppress_preamble)
  134. md |= ECM_MD_PREAMBLE;
  135. md |= (regnum << ECM_MD_ADDR_SHIFT) & ECM_MD_ADDR_MASK;
  136. md |= (addr << ECM_MD_PHY_ADDR_SHIFT) & ECM_MD_PHY_ADDR_MASK;
  137. iowrite32(md, adapter->addr + ECM_MD_CONTROL);
  138. retval = readl_poll_timeout_atomic(adapter->addr + ECM_MD_STATUS, md,
  139. !(md & ECM_MD_BUSY), 16, 1000);
  140. if (retval != 0)
  141. return retval;
  142. return (md & ECM_MD_DATA_MASK) >> ECM_MD_DATA_SHIFT;
  143. }
  144. static int tsnep_mdiobus_write(struct mii_bus *bus, int addr, int regnum,
  145. u16 val)
  146. {
  147. struct tsnep_adapter *adapter = bus->priv;
  148. u32 md;
  149. int retval;
  150. md = ECM_MD_WRITE;
  151. if (!adapter->suppress_preamble)
  152. md |= ECM_MD_PREAMBLE;
  153. md |= (regnum << ECM_MD_ADDR_SHIFT) & ECM_MD_ADDR_MASK;
  154. md |= (addr << ECM_MD_PHY_ADDR_SHIFT) & ECM_MD_PHY_ADDR_MASK;
  155. md |= ((u32)val << ECM_MD_DATA_SHIFT) & ECM_MD_DATA_MASK;
  156. iowrite32(md, adapter->addr + ECM_MD_CONTROL);
  157. retval = readl_poll_timeout_atomic(adapter->addr + ECM_MD_STATUS, md,
  158. !(md & ECM_MD_BUSY), 16, 1000);
  159. if (retval != 0)
  160. return retval;
  161. return 0;
  162. }
  163. static void tsnep_set_link_mode(struct tsnep_adapter *adapter)
  164. {
  165. u32 mode;
  166. switch (adapter->phydev->speed) {
  167. case SPEED_100:
  168. mode = ECM_LINK_MODE_100;
  169. break;
  170. case SPEED_1000:
  171. mode = ECM_LINK_MODE_1000;
  172. break;
  173. default:
  174. mode = ECM_LINK_MODE_OFF;
  175. break;
  176. }
  177. iowrite32(mode, adapter->addr + ECM_STATUS);
  178. }
  179. static void tsnep_phy_link_status_change(struct net_device *netdev)
  180. {
  181. struct tsnep_adapter *adapter = netdev_priv(netdev);
  182. struct phy_device *phydev = netdev->phydev;
  183. if (phydev->link)
  184. tsnep_set_link_mode(adapter);
  185. phy_print_status(netdev->phydev);
  186. }
  187. static int tsnep_phy_loopback(struct tsnep_adapter *adapter, bool enable)
  188. {
  189. int speed;
  190. if (enable) {
  191. if (adapter->phydev->autoneg == AUTONEG_DISABLE &&
  192. adapter->phydev->speed == SPEED_100)
  193. speed = SPEED_100;
  194. else
  195. speed = SPEED_1000;
  196. } else {
  197. speed = 0;
  198. }
  199. return phy_loopback(adapter->phydev, enable, speed);
  200. }
  201. static int tsnep_phy_open(struct tsnep_adapter *adapter)
  202. {
  203. struct phy_device *phydev;
  204. struct ethtool_keee ethtool_keee;
  205. int retval;
  206. retval = phy_connect_direct(adapter->netdev, adapter->phydev,
  207. tsnep_phy_link_status_change,
  208. adapter->phy_mode);
  209. if (retval)
  210. return retval;
  211. phydev = adapter->netdev->phydev;
  212. /* MAC supports only 100Mbps|1000Mbps full duplex
  213. * SPE (Single Pair Ethernet) is also an option but not implemented yet
  214. */
  215. phy_remove_link_mode(phydev, ETHTOOL_LINK_MODE_10baseT_Half_BIT);
  216. phy_remove_link_mode(phydev, ETHTOOL_LINK_MODE_10baseT_Full_BIT);
  217. phy_remove_link_mode(phydev, ETHTOOL_LINK_MODE_100baseT_Half_BIT);
  218. phy_remove_link_mode(phydev, ETHTOOL_LINK_MODE_1000baseT_Half_BIT);
  219. /* disable EEE autoneg, EEE not supported by TSNEP */
  220. memset(&ethtool_keee, 0, sizeof(ethtool_keee));
  221. phy_ethtool_set_eee(adapter->phydev, &ethtool_keee);
  222. adapter->phydev->irq = PHY_MAC_INTERRUPT;
  223. phy_start(adapter->phydev);
  224. return 0;
  225. }
  226. static void tsnep_phy_close(struct tsnep_adapter *adapter)
  227. {
  228. phy_stop(adapter->netdev->phydev);
  229. phy_disconnect(adapter->netdev->phydev);
  230. }
  231. static void tsnep_tx_ring_cleanup(struct tsnep_tx *tx)
  232. {
  233. struct device *dmadev = tx->adapter->dmadev;
  234. int i;
  235. memset(tx->entry, 0, sizeof(tx->entry));
  236. for (i = 0; i < TSNEP_RING_PAGE_COUNT; i++) {
  237. if (tx->page[i]) {
  238. dma_free_coherent(dmadev, PAGE_SIZE, tx->page[i],
  239. tx->page_dma[i]);
  240. tx->page[i] = NULL;
  241. tx->page_dma[i] = 0;
  242. }
  243. }
  244. }
  245. static int tsnep_tx_ring_create(struct tsnep_tx *tx)
  246. {
  247. struct device *dmadev = tx->adapter->dmadev;
  248. struct tsnep_tx_entry *entry;
  249. struct tsnep_tx_entry *next_entry;
  250. int i, j;
  251. int retval;
  252. for (i = 0; i < TSNEP_RING_PAGE_COUNT; i++) {
  253. tx->page[i] =
  254. dma_alloc_coherent(dmadev, PAGE_SIZE, &tx->page_dma[i],
  255. GFP_KERNEL);
  256. if (!tx->page[i]) {
  257. retval = -ENOMEM;
  258. goto alloc_failed;
  259. }
  260. for (j = 0; j < TSNEP_RING_ENTRIES_PER_PAGE; j++) {
  261. entry = &tx->entry[TSNEP_RING_ENTRIES_PER_PAGE * i + j];
  262. entry->desc_wb = (struct tsnep_tx_desc_wb *)
  263. (((u8 *)tx->page[i]) + TSNEP_DESC_SIZE * j);
  264. entry->desc = (struct tsnep_tx_desc *)
  265. (((u8 *)entry->desc_wb) + TSNEP_DESC_OFFSET);
  266. entry->desc_dma = tx->page_dma[i] + TSNEP_DESC_SIZE * j;
  267. entry->owner_user_flag = false;
  268. }
  269. }
  270. for (i = 0; i < TSNEP_RING_SIZE; i++) {
  271. entry = &tx->entry[i];
  272. next_entry = &tx->entry[(i + 1) & TSNEP_RING_MASK];
  273. entry->desc->next = __cpu_to_le64(next_entry->desc_dma);
  274. }
  275. return 0;
  276. alloc_failed:
  277. tsnep_tx_ring_cleanup(tx);
  278. return retval;
  279. }
  280. static void tsnep_tx_init(struct tsnep_tx *tx)
  281. {
  282. dma_addr_t dma;
  283. dma = tx->entry[0].desc_dma | TSNEP_RESET_OWNER_COUNTER;
  284. iowrite32(DMA_ADDR_LOW(dma), tx->addr + TSNEP_TX_DESC_ADDR_LOW);
  285. iowrite32(DMA_ADDR_HIGH(dma), tx->addr + TSNEP_TX_DESC_ADDR_HIGH);
  286. tx->write = 0;
  287. tx->read = 0;
  288. tx->owner_counter = 1;
  289. tx->increment_owner_counter = TSNEP_RING_SIZE - 1;
  290. }
  291. static void tsnep_tx_enable(struct tsnep_tx *tx)
  292. {
  293. struct netdev_queue *nq;
  294. nq = netdev_get_tx_queue(tx->adapter->netdev, tx->queue_index);
  295. __netif_tx_lock_bh(nq);
  296. netif_tx_wake_queue(nq);
  297. __netif_tx_unlock_bh(nq);
  298. }
  299. static void tsnep_tx_disable(struct tsnep_tx *tx, struct napi_struct *napi)
  300. {
  301. struct netdev_queue *nq;
  302. u32 val;
  303. nq = netdev_get_tx_queue(tx->adapter->netdev, tx->queue_index);
  304. __netif_tx_lock_bh(nq);
  305. netif_tx_stop_queue(nq);
  306. __netif_tx_unlock_bh(nq);
  307. /* wait until TX is done in hardware */
  308. readx_poll_timeout(ioread32, tx->addr + TSNEP_CONTROL, val,
  309. ((val & TSNEP_CONTROL_TX_ENABLE) == 0), 10000,
  310. 1000000);
  311. /* wait until TX is also done in software */
  312. while (READ_ONCE(tx->read) != tx->write) {
  313. napi_schedule(napi);
  314. napi_synchronize(napi);
  315. }
  316. }
  317. static void tsnep_tx_activate(struct tsnep_tx *tx, int index, int length,
  318. bool last)
  319. {
  320. struct tsnep_tx_entry *entry = &tx->entry[index];
  321. entry->properties = 0;
  322. /* xdpf and zc are union with skb */
  323. if (entry->skb) {
  324. entry->properties = length & TSNEP_DESC_LENGTH_MASK;
  325. entry->properties |= TSNEP_DESC_INTERRUPT_FLAG;
  326. if ((entry->type & TSNEP_TX_TYPE_SKB_TSTAMP) == TSNEP_TX_TYPE_SKB_TSTAMP)
  327. entry->properties |= TSNEP_DESC_EXTENDED_WRITEBACK_FLAG;
  328. /* toggle user flag to prevent false acknowledge
  329. *
  330. * Only the first fragment is acknowledged. For all other
  331. * fragments no acknowledge is done and the last written owner
  332. * counter stays in the writeback descriptor. Therefore, it is
  333. * possible that the last written owner counter is identical to
  334. * the new incremented owner counter and a false acknowledge is
  335. * detected before the real acknowledge has been done by
  336. * hardware.
  337. *
  338. * The user flag is used to prevent this situation. The user
  339. * flag is copied to the writeback descriptor by the hardware
  340. * and is used as additional acknowledge data. By toggeling the
  341. * user flag only for the first fragment (which is
  342. * acknowledged), it is guaranteed that the last acknowledge
  343. * done for this descriptor has used a different user flag and
  344. * cannot be detected as false acknowledge.
  345. */
  346. entry->owner_user_flag = !entry->owner_user_flag;
  347. }
  348. if (last)
  349. entry->properties |= TSNEP_TX_DESC_LAST_FRAGMENT_FLAG;
  350. if (index == tx->increment_owner_counter) {
  351. tx->owner_counter++;
  352. if (tx->owner_counter == 4)
  353. tx->owner_counter = 1;
  354. tx->increment_owner_counter--;
  355. if (tx->increment_owner_counter < 0)
  356. tx->increment_owner_counter = TSNEP_RING_SIZE - 1;
  357. }
  358. entry->properties |=
  359. (tx->owner_counter << TSNEP_DESC_OWNER_COUNTER_SHIFT) &
  360. TSNEP_DESC_OWNER_COUNTER_MASK;
  361. if (entry->owner_user_flag)
  362. entry->properties |= TSNEP_TX_DESC_OWNER_USER_FLAG;
  363. entry->desc->more_properties =
  364. __cpu_to_le32(entry->len & TSNEP_DESC_LENGTH_MASK);
  365. if (entry->type & TSNEP_TX_TYPE_INLINE)
  366. entry->properties |= TSNEP_TX_DESC_DATA_AFTER_DESC_FLAG;
  367. /* descriptor properties shall be written last, because valid data is
  368. * signaled there
  369. */
  370. dma_wmb();
  371. entry->desc->properties = __cpu_to_le32(entry->properties);
  372. }
  373. static int tsnep_tx_desc_available(struct tsnep_tx *tx)
  374. {
  375. if (tx->read <= tx->write)
  376. return TSNEP_RING_SIZE - tx->write + tx->read - 1;
  377. else
  378. return tx->read - tx->write - 1;
  379. }
  380. static int tsnep_tx_map_frag(skb_frag_t *frag, struct tsnep_tx_entry *entry,
  381. struct device *dmadev, dma_addr_t *dma)
  382. {
  383. unsigned int len;
  384. int mapped;
  385. len = skb_frag_size(frag);
  386. if (likely(len > TSNEP_DESC_SIZE_DATA_AFTER_INLINE)) {
  387. *dma = skb_frag_dma_map(dmadev, frag, 0, len, DMA_TO_DEVICE);
  388. if (dma_mapping_error(dmadev, *dma))
  389. return -ENOMEM;
  390. entry->type = TSNEP_TX_TYPE_SKB_FRAG_MAP_PAGE;
  391. mapped = 1;
  392. } else {
  393. void *fragdata = skb_frag_address_safe(frag);
  394. if (likely(fragdata)) {
  395. memcpy(&entry->desc->tx, fragdata, len);
  396. } else {
  397. struct page *page = skb_frag_page(frag);
  398. fragdata = kmap_local_page(page);
  399. memcpy(&entry->desc->tx, fragdata + skb_frag_off(frag),
  400. len);
  401. kunmap_local(fragdata);
  402. }
  403. entry->type = TSNEP_TX_TYPE_SKB_FRAG_INLINE;
  404. mapped = 0;
  405. }
  406. return mapped;
  407. }
  408. static int tsnep_tx_map(struct sk_buff *skb, struct tsnep_tx *tx, int count,
  409. bool do_tstamp)
  410. {
  411. struct device *dmadev = tx->adapter->dmadev;
  412. struct tsnep_tx_entry *entry;
  413. unsigned int len;
  414. int map_len = 0;
  415. dma_addr_t dma;
  416. int i, mapped;
  417. for (i = 0; i < count; i++) {
  418. entry = &tx->entry[(tx->write + i) & TSNEP_RING_MASK];
  419. if (!i) {
  420. len = skb_headlen(skb);
  421. if (likely(len > TSNEP_DESC_SIZE_DATA_AFTER_INLINE)) {
  422. dma = dma_map_single(dmadev, skb->data, len,
  423. DMA_TO_DEVICE);
  424. if (dma_mapping_error(dmadev, dma))
  425. return -ENOMEM;
  426. entry->type = TSNEP_TX_TYPE_SKB_MAP;
  427. mapped = 1;
  428. } else {
  429. memcpy(&entry->desc->tx, skb->data, len);
  430. entry->type = TSNEP_TX_TYPE_SKB_INLINE;
  431. mapped = 0;
  432. }
  433. if (do_tstamp)
  434. entry->type |= TSNEP_TX_TYPE_TSTAMP;
  435. } else {
  436. skb_frag_t *frag = &skb_shinfo(skb)->frags[i - 1];
  437. len = skb_frag_size(frag);
  438. mapped = tsnep_tx_map_frag(frag, entry, dmadev, &dma);
  439. if (mapped < 0)
  440. return mapped;
  441. }
  442. entry->len = len;
  443. if (likely(mapped)) {
  444. dma_unmap_addr_set(entry, dma, dma);
  445. entry->desc->tx = __cpu_to_le64(dma);
  446. }
  447. map_len += len;
  448. }
  449. return map_len;
  450. }
  451. static int tsnep_tx_unmap(struct tsnep_tx *tx, int index, int count)
  452. {
  453. struct device *dmadev = tx->adapter->dmadev;
  454. struct tsnep_tx_entry *entry;
  455. int map_len = 0;
  456. int i;
  457. for (i = 0; i < count; i++) {
  458. entry = &tx->entry[(index + i) & TSNEP_RING_MASK];
  459. if (entry->len) {
  460. if (entry->type & TSNEP_TX_TYPE_MAP)
  461. dma_unmap_single(dmadev,
  462. dma_unmap_addr(entry, dma),
  463. dma_unmap_len(entry, len),
  464. DMA_TO_DEVICE);
  465. else if (entry->type & TSNEP_TX_TYPE_MAP_PAGE)
  466. dma_unmap_page(dmadev,
  467. dma_unmap_addr(entry, dma),
  468. dma_unmap_len(entry, len),
  469. DMA_TO_DEVICE);
  470. map_len += entry->len;
  471. entry->len = 0;
  472. }
  473. }
  474. return map_len;
  475. }
  476. static netdev_tx_t tsnep_xmit_frame_ring(struct sk_buff *skb,
  477. struct tsnep_tx *tx)
  478. {
  479. struct tsnep_tx_entry *entry;
  480. bool do_tstamp = false;
  481. int count = 1;
  482. int length;
  483. int retval;
  484. int i;
  485. if (skb_shinfo(skb)->nr_frags > 0)
  486. count += skb_shinfo(skb)->nr_frags;
  487. if (tsnep_tx_desc_available(tx) < count) {
  488. /* ring full, shall not happen because queue is stopped if full
  489. * below
  490. */
  491. netif_stop_subqueue(tx->adapter->netdev, tx->queue_index);
  492. return NETDEV_TX_BUSY;
  493. }
  494. entry = &tx->entry[tx->write];
  495. entry->skb = skb;
  496. if (unlikely(skb_shinfo(skb)->tx_flags & SKBTX_HW_TSTAMP) &&
  497. tx->adapter->hwtstamp_config.tx_type == HWTSTAMP_TX_ON) {
  498. skb_shinfo(skb)->tx_flags |= SKBTX_IN_PROGRESS;
  499. do_tstamp = true;
  500. }
  501. retval = tsnep_tx_map(skb, tx, count, do_tstamp);
  502. if (retval < 0) {
  503. tsnep_tx_unmap(tx, tx->write, count);
  504. dev_kfree_skb_any(entry->skb);
  505. entry->skb = NULL;
  506. tx->dropped++;
  507. return NETDEV_TX_OK;
  508. }
  509. length = retval;
  510. for (i = 0; i < count; i++)
  511. tsnep_tx_activate(tx, (tx->write + i) & TSNEP_RING_MASK, length,
  512. i == count - 1);
  513. tx->write = (tx->write + count) & TSNEP_RING_MASK;
  514. skb_tx_timestamp(skb);
  515. /* descriptor properties shall be valid before hardware is notified */
  516. dma_wmb();
  517. iowrite32(TSNEP_CONTROL_TX_ENABLE, tx->addr + TSNEP_CONTROL);
  518. if (tsnep_tx_desc_available(tx) < (MAX_SKB_FRAGS + 1)) {
  519. /* ring can get full with next frame */
  520. netif_stop_subqueue(tx->adapter->netdev, tx->queue_index);
  521. }
  522. return NETDEV_TX_OK;
  523. }
  524. static int tsnep_xdp_tx_map(struct xdp_frame *xdpf, struct tsnep_tx *tx,
  525. struct skb_shared_info *shinfo, int count, u32 type)
  526. {
  527. struct device *dmadev = tx->adapter->dmadev;
  528. struct tsnep_tx_entry *entry;
  529. struct page *page;
  530. skb_frag_t *frag;
  531. unsigned int len;
  532. int map_len = 0;
  533. dma_addr_t dma;
  534. void *data;
  535. int i;
  536. frag = NULL;
  537. len = xdpf->len;
  538. for (i = 0; i < count; i++) {
  539. entry = &tx->entry[(tx->write + i) & TSNEP_RING_MASK];
  540. if (type & TSNEP_TX_TYPE_XDP_NDO) {
  541. data = unlikely(frag) ? skb_frag_address(frag) :
  542. xdpf->data;
  543. dma = dma_map_single(dmadev, data, len, DMA_TO_DEVICE);
  544. if (dma_mapping_error(dmadev, dma))
  545. return -ENOMEM;
  546. entry->type = TSNEP_TX_TYPE_XDP_NDO_MAP_PAGE;
  547. } else {
  548. page = unlikely(frag) ? skb_frag_page(frag) :
  549. virt_to_page(xdpf->data);
  550. dma = page_pool_get_dma_addr(page);
  551. if (unlikely(frag))
  552. dma += skb_frag_off(frag);
  553. else
  554. dma += sizeof(*xdpf) + xdpf->headroom;
  555. dma_sync_single_for_device(dmadev, dma, len,
  556. DMA_BIDIRECTIONAL);
  557. entry->type = TSNEP_TX_TYPE_XDP_TX;
  558. }
  559. entry->len = len;
  560. dma_unmap_addr_set(entry, dma, dma);
  561. entry->desc->tx = __cpu_to_le64(dma);
  562. map_len += len;
  563. if (i + 1 < count) {
  564. frag = &shinfo->frags[i];
  565. len = skb_frag_size(frag);
  566. }
  567. }
  568. return map_len;
  569. }
  570. /* This function requires __netif_tx_lock is held by the caller. */
  571. static bool tsnep_xdp_xmit_frame_ring(struct xdp_frame *xdpf,
  572. struct tsnep_tx *tx, u32 type)
  573. {
  574. struct skb_shared_info *shinfo = xdp_get_shared_info_from_frame(xdpf);
  575. struct tsnep_tx_entry *entry;
  576. int count, length, retval, i;
  577. count = 1;
  578. if (unlikely(xdp_frame_has_frags(xdpf)))
  579. count += shinfo->nr_frags;
  580. /* ensure that TX ring is not filled up by XDP, always MAX_SKB_FRAGS
  581. * will be available for normal TX path and queue is stopped there if
  582. * necessary
  583. */
  584. if (tsnep_tx_desc_available(tx) < (MAX_SKB_FRAGS + 1 + count))
  585. return false;
  586. entry = &tx->entry[tx->write];
  587. entry->xdpf = xdpf;
  588. retval = tsnep_xdp_tx_map(xdpf, tx, shinfo, count, type);
  589. if (retval < 0) {
  590. tsnep_tx_unmap(tx, tx->write, count);
  591. entry->xdpf = NULL;
  592. tx->dropped++;
  593. return false;
  594. }
  595. length = retval;
  596. for (i = 0; i < count; i++)
  597. tsnep_tx_activate(tx, (tx->write + i) & TSNEP_RING_MASK, length,
  598. i == count - 1);
  599. tx->write = (tx->write + count) & TSNEP_RING_MASK;
  600. /* descriptor properties shall be valid before hardware is notified */
  601. dma_wmb();
  602. return true;
  603. }
  604. static void tsnep_xdp_xmit_flush(struct tsnep_tx *tx)
  605. {
  606. iowrite32(TSNEP_CONTROL_TX_ENABLE, tx->addr + TSNEP_CONTROL);
  607. }
  608. static bool tsnep_xdp_xmit_back(struct tsnep_adapter *adapter,
  609. struct xdp_buff *xdp,
  610. struct netdev_queue *tx_nq, struct tsnep_tx *tx,
  611. bool zc)
  612. {
  613. struct xdp_frame *xdpf = xdp_convert_buff_to_frame(xdp);
  614. bool xmit;
  615. u32 type;
  616. if (unlikely(!xdpf))
  617. return false;
  618. /* no page pool for zero copy */
  619. if (zc)
  620. type = TSNEP_TX_TYPE_XDP_NDO;
  621. else
  622. type = TSNEP_TX_TYPE_XDP_TX;
  623. __netif_tx_lock(tx_nq, smp_processor_id());
  624. xmit = tsnep_xdp_xmit_frame_ring(xdpf, tx, type);
  625. /* Avoid transmit queue timeout since we share it with the slow path */
  626. if (xmit)
  627. txq_trans_cond_update(tx_nq);
  628. __netif_tx_unlock(tx_nq);
  629. return xmit;
  630. }
  631. static int tsnep_xdp_tx_map_zc(struct xdp_desc *xdpd, struct tsnep_tx *tx)
  632. {
  633. struct tsnep_tx_entry *entry;
  634. dma_addr_t dma;
  635. entry = &tx->entry[tx->write];
  636. entry->zc = true;
  637. dma = xsk_buff_raw_get_dma(tx->xsk_pool, xdpd->addr);
  638. xsk_buff_raw_dma_sync_for_device(tx->xsk_pool, dma, xdpd->len);
  639. entry->type = TSNEP_TX_TYPE_XSK;
  640. entry->len = xdpd->len;
  641. entry->desc->tx = __cpu_to_le64(dma);
  642. return xdpd->len;
  643. }
  644. static void tsnep_xdp_xmit_frame_ring_zc(struct xdp_desc *xdpd,
  645. struct tsnep_tx *tx)
  646. {
  647. int length;
  648. length = tsnep_xdp_tx_map_zc(xdpd, tx);
  649. tsnep_tx_activate(tx, tx->write, length, true);
  650. tx->write = (tx->write + 1) & TSNEP_RING_MASK;
  651. }
  652. static void tsnep_xdp_xmit_zc(struct tsnep_tx *tx)
  653. {
  654. int desc_available = tsnep_tx_desc_available(tx);
  655. struct xdp_desc *descs = tx->xsk_pool->tx_descs;
  656. int batch, i;
  657. /* ensure that TX ring is not filled up by XDP, always MAX_SKB_FRAGS
  658. * will be available for normal TX path and queue is stopped there if
  659. * necessary
  660. */
  661. if (desc_available <= (MAX_SKB_FRAGS + 1))
  662. return;
  663. desc_available -= MAX_SKB_FRAGS + 1;
  664. batch = xsk_tx_peek_release_desc_batch(tx->xsk_pool, desc_available);
  665. for (i = 0; i < batch; i++)
  666. tsnep_xdp_xmit_frame_ring_zc(&descs[i], tx);
  667. if (batch) {
  668. /* descriptor properties shall be valid before hardware is
  669. * notified
  670. */
  671. dma_wmb();
  672. tsnep_xdp_xmit_flush(tx);
  673. }
  674. }
  675. static bool tsnep_tx_poll(struct tsnep_tx *tx, int napi_budget)
  676. {
  677. struct tsnep_tx_entry *entry;
  678. struct netdev_queue *nq;
  679. int xsk_frames = 0;
  680. int budget = 128;
  681. int length;
  682. int count;
  683. nq = netdev_get_tx_queue(tx->adapter->netdev, tx->queue_index);
  684. __netif_tx_lock(nq, smp_processor_id());
  685. do {
  686. if (tx->read == tx->write)
  687. break;
  688. entry = &tx->entry[tx->read];
  689. if ((__le32_to_cpu(entry->desc_wb->properties) &
  690. TSNEP_TX_DESC_OWNER_MASK) !=
  691. (entry->properties & TSNEP_TX_DESC_OWNER_MASK))
  692. break;
  693. /* descriptor properties shall be read first, because valid data
  694. * is signaled there
  695. */
  696. dma_rmb();
  697. count = 1;
  698. if ((entry->type & TSNEP_TX_TYPE_SKB) &&
  699. skb_shinfo(entry->skb)->nr_frags > 0)
  700. count += skb_shinfo(entry->skb)->nr_frags;
  701. else if ((entry->type & TSNEP_TX_TYPE_XDP) &&
  702. xdp_frame_has_frags(entry->xdpf))
  703. count += xdp_get_shared_info_from_frame(entry->xdpf)->nr_frags;
  704. length = tsnep_tx_unmap(tx, tx->read, count);
  705. if (((entry->type & TSNEP_TX_TYPE_SKB_TSTAMP) == TSNEP_TX_TYPE_SKB_TSTAMP) &&
  706. (__le32_to_cpu(entry->desc_wb->properties) &
  707. TSNEP_DESC_EXTENDED_WRITEBACK_FLAG)) {
  708. struct skb_shared_hwtstamps hwtstamps;
  709. u64 timestamp;
  710. if (entry->skb->sk &&
  711. READ_ONCE(entry->skb->sk->sk_tsflags) & SOF_TIMESTAMPING_BIND_PHC)
  712. timestamp =
  713. __le64_to_cpu(entry->desc_wb->counter);
  714. else
  715. timestamp =
  716. __le64_to_cpu(entry->desc_wb->timestamp);
  717. memset(&hwtstamps, 0, sizeof(hwtstamps));
  718. hwtstamps.hwtstamp = ns_to_ktime(timestamp);
  719. skb_tstamp_tx(entry->skb, &hwtstamps);
  720. }
  721. if (entry->type & TSNEP_TX_TYPE_SKB)
  722. napi_consume_skb(entry->skb, napi_budget);
  723. else if (entry->type & TSNEP_TX_TYPE_XDP)
  724. xdp_return_frame_rx_napi(entry->xdpf);
  725. else
  726. xsk_frames++;
  727. /* xdpf and zc are union with skb */
  728. entry->skb = NULL;
  729. tx->read = (tx->read + count) & TSNEP_RING_MASK;
  730. tx->packets++;
  731. tx->bytes += length + ETH_FCS_LEN;
  732. budget--;
  733. } while (likely(budget));
  734. if (tx->xsk_pool) {
  735. if (xsk_frames)
  736. xsk_tx_completed(tx->xsk_pool, xsk_frames);
  737. if (xsk_uses_need_wakeup(tx->xsk_pool))
  738. xsk_set_tx_need_wakeup(tx->xsk_pool);
  739. tsnep_xdp_xmit_zc(tx);
  740. }
  741. if ((tsnep_tx_desc_available(tx) >= ((MAX_SKB_FRAGS + 1) * 2)) &&
  742. netif_tx_queue_stopped(nq)) {
  743. netif_tx_wake_queue(nq);
  744. }
  745. __netif_tx_unlock(nq);
  746. return budget != 0;
  747. }
  748. static bool tsnep_tx_pending(struct tsnep_tx *tx)
  749. {
  750. struct tsnep_tx_entry *entry;
  751. struct netdev_queue *nq;
  752. bool pending = false;
  753. nq = netdev_get_tx_queue(tx->adapter->netdev, tx->queue_index);
  754. __netif_tx_lock(nq, smp_processor_id());
  755. if (tx->read != tx->write) {
  756. entry = &tx->entry[tx->read];
  757. if ((__le32_to_cpu(entry->desc_wb->properties) &
  758. TSNEP_TX_DESC_OWNER_MASK) ==
  759. (entry->properties & TSNEP_TX_DESC_OWNER_MASK))
  760. pending = true;
  761. }
  762. __netif_tx_unlock(nq);
  763. return pending;
  764. }
  765. static int tsnep_tx_open(struct tsnep_tx *tx)
  766. {
  767. int retval;
  768. retval = tsnep_tx_ring_create(tx);
  769. if (retval)
  770. return retval;
  771. tsnep_tx_init(tx);
  772. return 0;
  773. }
  774. static void tsnep_tx_close(struct tsnep_tx *tx)
  775. {
  776. tsnep_tx_ring_cleanup(tx);
  777. }
  778. static void tsnep_rx_ring_cleanup(struct tsnep_rx *rx)
  779. {
  780. struct device *dmadev = rx->adapter->dmadev;
  781. struct tsnep_rx_entry *entry;
  782. int i;
  783. for (i = 0; i < TSNEP_RING_SIZE; i++) {
  784. entry = &rx->entry[i];
  785. if (!rx->xsk_pool && entry->page)
  786. page_pool_put_full_page(rx->page_pool, entry->page,
  787. false);
  788. if (rx->xsk_pool && entry->xdp)
  789. xsk_buff_free(entry->xdp);
  790. /* xdp is union with page */
  791. entry->page = NULL;
  792. }
  793. if (rx->page_pool)
  794. page_pool_destroy(rx->page_pool);
  795. memset(rx->entry, 0, sizeof(rx->entry));
  796. for (i = 0; i < TSNEP_RING_PAGE_COUNT; i++) {
  797. if (rx->page[i]) {
  798. dma_free_coherent(dmadev, PAGE_SIZE, rx->page[i],
  799. rx->page_dma[i]);
  800. rx->page[i] = NULL;
  801. rx->page_dma[i] = 0;
  802. }
  803. }
  804. }
  805. static int tsnep_rx_ring_create(struct tsnep_rx *rx)
  806. {
  807. struct device *dmadev = rx->adapter->dmadev;
  808. struct tsnep_rx_entry *entry;
  809. struct page_pool_params pp_params = { 0 };
  810. struct tsnep_rx_entry *next_entry;
  811. int i, j;
  812. int retval;
  813. for (i = 0; i < TSNEP_RING_PAGE_COUNT; i++) {
  814. rx->page[i] =
  815. dma_alloc_coherent(dmadev, PAGE_SIZE, &rx->page_dma[i],
  816. GFP_KERNEL);
  817. if (!rx->page[i]) {
  818. retval = -ENOMEM;
  819. goto failed;
  820. }
  821. for (j = 0; j < TSNEP_RING_ENTRIES_PER_PAGE; j++) {
  822. entry = &rx->entry[TSNEP_RING_ENTRIES_PER_PAGE * i + j];
  823. entry->desc_wb = (struct tsnep_rx_desc_wb *)
  824. (((u8 *)rx->page[i]) + TSNEP_DESC_SIZE * j);
  825. entry->desc = (struct tsnep_rx_desc *)
  826. (((u8 *)entry->desc_wb) + TSNEP_DESC_OFFSET);
  827. entry->desc_dma = rx->page_dma[i] + TSNEP_DESC_SIZE * j;
  828. }
  829. }
  830. pp_params.flags = PP_FLAG_DMA_MAP | PP_FLAG_DMA_SYNC_DEV;
  831. pp_params.order = 0;
  832. pp_params.pool_size = TSNEP_RING_SIZE;
  833. pp_params.nid = dev_to_node(dmadev);
  834. pp_params.dev = dmadev;
  835. pp_params.dma_dir = DMA_BIDIRECTIONAL;
  836. pp_params.max_len = TSNEP_MAX_RX_BUF_SIZE;
  837. pp_params.offset = TSNEP_RX_OFFSET;
  838. rx->page_pool = page_pool_create(&pp_params);
  839. if (IS_ERR(rx->page_pool)) {
  840. retval = PTR_ERR(rx->page_pool);
  841. rx->page_pool = NULL;
  842. goto failed;
  843. }
  844. for (i = 0; i < TSNEP_RING_SIZE; i++) {
  845. entry = &rx->entry[i];
  846. next_entry = &rx->entry[(i + 1) & TSNEP_RING_MASK];
  847. entry->desc->next = __cpu_to_le64(next_entry->desc_dma);
  848. }
  849. return 0;
  850. failed:
  851. tsnep_rx_ring_cleanup(rx);
  852. return retval;
  853. }
  854. static void tsnep_rx_init(struct tsnep_rx *rx)
  855. {
  856. dma_addr_t dma;
  857. dma = rx->entry[0].desc_dma | TSNEP_RESET_OWNER_COUNTER;
  858. iowrite32(DMA_ADDR_LOW(dma), rx->addr + TSNEP_RX_DESC_ADDR_LOW);
  859. iowrite32(DMA_ADDR_HIGH(dma), rx->addr + TSNEP_RX_DESC_ADDR_HIGH);
  860. rx->write = 0;
  861. rx->read = 0;
  862. rx->owner_counter = 1;
  863. rx->increment_owner_counter = TSNEP_RING_SIZE - 1;
  864. }
  865. static void tsnep_rx_enable(struct tsnep_rx *rx)
  866. {
  867. /* descriptor properties shall be valid before hardware is notified */
  868. dma_wmb();
  869. iowrite32(TSNEP_CONTROL_RX_ENABLE, rx->addr + TSNEP_CONTROL);
  870. }
  871. static void tsnep_rx_disable(struct tsnep_rx *rx)
  872. {
  873. u32 val;
  874. iowrite32(TSNEP_CONTROL_RX_DISABLE, rx->addr + TSNEP_CONTROL);
  875. readx_poll_timeout(ioread32, rx->addr + TSNEP_CONTROL, val,
  876. ((val & TSNEP_CONTROL_RX_ENABLE) == 0), 10000,
  877. 1000000);
  878. }
  879. static int tsnep_rx_desc_available(struct tsnep_rx *rx)
  880. {
  881. if (rx->read <= rx->write)
  882. return TSNEP_RING_SIZE - rx->write + rx->read - 1;
  883. else
  884. return rx->read - rx->write - 1;
  885. }
  886. static void tsnep_rx_free_page_buffer(struct tsnep_rx *rx)
  887. {
  888. struct page **page;
  889. /* last entry of page_buffer is always zero, because ring cannot be
  890. * filled completely
  891. */
  892. page = rx->page_buffer;
  893. while (*page) {
  894. page_pool_put_full_page(rx->page_pool, *page, false);
  895. *page = NULL;
  896. page++;
  897. }
  898. }
  899. static int tsnep_rx_alloc_page_buffer(struct tsnep_rx *rx)
  900. {
  901. int i;
  902. /* alloc for all ring entries except the last one, because ring cannot
  903. * be filled completely
  904. */
  905. for (i = 0; i < TSNEP_RING_SIZE - 1; i++) {
  906. rx->page_buffer[i] = page_pool_dev_alloc_pages(rx->page_pool);
  907. if (!rx->page_buffer[i]) {
  908. tsnep_rx_free_page_buffer(rx);
  909. return -ENOMEM;
  910. }
  911. }
  912. return 0;
  913. }
  914. static void tsnep_rx_set_page(struct tsnep_rx *rx, struct tsnep_rx_entry *entry,
  915. struct page *page)
  916. {
  917. entry->page = page;
  918. entry->len = TSNEP_MAX_RX_BUF_SIZE;
  919. entry->dma = page_pool_get_dma_addr(entry->page);
  920. entry->desc->rx = __cpu_to_le64(entry->dma + TSNEP_RX_OFFSET);
  921. }
  922. static int tsnep_rx_alloc_buffer(struct tsnep_rx *rx, int index)
  923. {
  924. struct tsnep_rx_entry *entry = &rx->entry[index];
  925. struct page *page;
  926. page = page_pool_dev_alloc_pages(rx->page_pool);
  927. if (unlikely(!page))
  928. return -ENOMEM;
  929. tsnep_rx_set_page(rx, entry, page);
  930. return 0;
  931. }
  932. static void tsnep_rx_reuse_buffer(struct tsnep_rx *rx, int index)
  933. {
  934. struct tsnep_rx_entry *entry = &rx->entry[index];
  935. struct tsnep_rx_entry *read = &rx->entry[rx->read];
  936. tsnep_rx_set_page(rx, entry, read->page);
  937. read->page = NULL;
  938. }
  939. static void tsnep_rx_activate(struct tsnep_rx *rx, int index)
  940. {
  941. struct tsnep_rx_entry *entry = &rx->entry[index];
  942. /* TSNEP_MAX_RX_BUF_SIZE and TSNEP_XSK_RX_BUF_SIZE are multiple of 4 */
  943. entry->properties = entry->len & TSNEP_DESC_LENGTH_MASK;
  944. entry->properties |= TSNEP_DESC_INTERRUPT_FLAG;
  945. if (index == rx->increment_owner_counter) {
  946. rx->owner_counter++;
  947. if (rx->owner_counter == 4)
  948. rx->owner_counter = 1;
  949. rx->increment_owner_counter--;
  950. if (rx->increment_owner_counter < 0)
  951. rx->increment_owner_counter = TSNEP_RING_SIZE - 1;
  952. }
  953. entry->properties |=
  954. (rx->owner_counter << TSNEP_DESC_OWNER_COUNTER_SHIFT) &
  955. TSNEP_DESC_OWNER_COUNTER_MASK;
  956. /* descriptor properties shall be written last, because valid data is
  957. * signaled there
  958. */
  959. dma_wmb();
  960. entry->desc->properties = __cpu_to_le32(entry->properties);
  961. }
  962. static int tsnep_rx_alloc(struct tsnep_rx *rx, int count, bool reuse)
  963. {
  964. bool alloc_failed = false;
  965. int i, index;
  966. for (i = 0; i < count && !alloc_failed; i++) {
  967. index = (rx->write + i) & TSNEP_RING_MASK;
  968. if (unlikely(tsnep_rx_alloc_buffer(rx, index))) {
  969. rx->alloc_failed++;
  970. alloc_failed = true;
  971. /* reuse only if no other allocation was successful */
  972. if (i == 0 && reuse)
  973. tsnep_rx_reuse_buffer(rx, index);
  974. else
  975. break;
  976. }
  977. tsnep_rx_activate(rx, index);
  978. }
  979. if (i)
  980. rx->write = (rx->write + i) & TSNEP_RING_MASK;
  981. return i;
  982. }
  983. static int tsnep_rx_refill(struct tsnep_rx *rx, int count, bool reuse)
  984. {
  985. int desc_refilled;
  986. desc_refilled = tsnep_rx_alloc(rx, count, reuse);
  987. if (desc_refilled)
  988. tsnep_rx_enable(rx);
  989. return desc_refilled;
  990. }
  991. static void tsnep_rx_set_xdp(struct tsnep_rx *rx, struct tsnep_rx_entry *entry,
  992. struct xdp_buff *xdp)
  993. {
  994. entry->xdp = xdp;
  995. entry->len = TSNEP_XSK_RX_BUF_SIZE;
  996. entry->dma = xsk_buff_xdp_get_dma(entry->xdp);
  997. entry->desc->rx = __cpu_to_le64(entry->dma);
  998. }
  999. static void tsnep_rx_reuse_buffer_zc(struct tsnep_rx *rx, int index)
  1000. {
  1001. struct tsnep_rx_entry *entry = &rx->entry[index];
  1002. struct tsnep_rx_entry *read = &rx->entry[rx->read];
  1003. tsnep_rx_set_xdp(rx, entry, read->xdp);
  1004. read->xdp = NULL;
  1005. }
  1006. static int tsnep_rx_alloc_zc(struct tsnep_rx *rx, int count, bool reuse)
  1007. {
  1008. u32 allocated;
  1009. int i;
  1010. allocated = xsk_buff_alloc_batch(rx->xsk_pool, rx->xdp_batch, count);
  1011. for (i = 0; i < allocated; i++) {
  1012. int index = (rx->write + i) & TSNEP_RING_MASK;
  1013. struct tsnep_rx_entry *entry = &rx->entry[index];
  1014. tsnep_rx_set_xdp(rx, entry, rx->xdp_batch[i]);
  1015. tsnep_rx_activate(rx, index);
  1016. }
  1017. if (i == 0) {
  1018. rx->alloc_failed++;
  1019. if (reuse) {
  1020. tsnep_rx_reuse_buffer_zc(rx, rx->write);
  1021. tsnep_rx_activate(rx, rx->write);
  1022. }
  1023. }
  1024. if (i)
  1025. rx->write = (rx->write + i) & TSNEP_RING_MASK;
  1026. return i;
  1027. }
  1028. static void tsnep_rx_free_zc(struct tsnep_rx *rx)
  1029. {
  1030. int i;
  1031. for (i = 0; i < TSNEP_RING_SIZE; i++) {
  1032. struct tsnep_rx_entry *entry = &rx->entry[i];
  1033. if (entry->xdp)
  1034. xsk_buff_free(entry->xdp);
  1035. entry->xdp = NULL;
  1036. }
  1037. }
  1038. static int tsnep_rx_refill_zc(struct tsnep_rx *rx, int count, bool reuse)
  1039. {
  1040. int desc_refilled;
  1041. desc_refilled = tsnep_rx_alloc_zc(rx, count, reuse);
  1042. if (desc_refilled)
  1043. tsnep_rx_enable(rx);
  1044. return desc_refilled;
  1045. }
  1046. static void tsnep_xsk_rx_need_wakeup(struct tsnep_rx *rx, int desc_available)
  1047. {
  1048. if (desc_available)
  1049. xsk_set_rx_need_wakeup(rx->xsk_pool);
  1050. else
  1051. xsk_clear_rx_need_wakeup(rx->xsk_pool);
  1052. }
  1053. static bool tsnep_xdp_run_prog(struct tsnep_rx *rx, struct bpf_prog *prog,
  1054. struct xdp_buff *xdp, int *status,
  1055. struct netdev_queue *tx_nq, struct tsnep_tx *tx)
  1056. {
  1057. unsigned int length;
  1058. unsigned int sync;
  1059. u32 act;
  1060. length = xdp->data_end - xdp->data_hard_start - XDP_PACKET_HEADROOM;
  1061. act = bpf_prog_run_xdp(prog, xdp);
  1062. switch (act) {
  1063. case XDP_PASS:
  1064. return false;
  1065. case XDP_TX:
  1066. if (!tsnep_xdp_xmit_back(rx->adapter, xdp, tx_nq, tx, false))
  1067. goto out_failure;
  1068. *status |= TSNEP_XDP_TX;
  1069. return true;
  1070. case XDP_REDIRECT:
  1071. if (xdp_do_redirect(rx->adapter->netdev, xdp, prog) < 0)
  1072. goto out_failure;
  1073. *status |= TSNEP_XDP_REDIRECT;
  1074. return true;
  1075. default:
  1076. bpf_warn_invalid_xdp_action(rx->adapter->netdev, prog, act);
  1077. fallthrough;
  1078. case XDP_ABORTED:
  1079. out_failure:
  1080. trace_xdp_exception(rx->adapter->netdev, prog, act);
  1081. fallthrough;
  1082. case XDP_DROP:
  1083. /* Due xdp_adjust_tail: DMA sync for_device cover max len CPU
  1084. * touch
  1085. */
  1086. sync = xdp->data_end - xdp->data_hard_start -
  1087. XDP_PACKET_HEADROOM;
  1088. sync = max(sync, length);
  1089. page_pool_put_page(rx->page_pool, virt_to_head_page(xdp->data),
  1090. sync, true);
  1091. return true;
  1092. }
  1093. }
  1094. static bool tsnep_xdp_run_prog_zc(struct tsnep_rx *rx, struct bpf_prog *prog,
  1095. struct xdp_buff *xdp, int *status,
  1096. struct netdev_queue *tx_nq,
  1097. struct tsnep_tx *tx)
  1098. {
  1099. u32 act;
  1100. act = bpf_prog_run_xdp(prog, xdp);
  1101. /* XDP_REDIRECT is the main action for zero-copy */
  1102. if (likely(act == XDP_REDIRECT)) {
  1103. if (xdp_do_redirect(rx->adapter->netdev, xdp, prog) < 0)
  1104. goto out_failure;
  1105. *status |= TSNEP_XDP_REDIRECT;
  1106. return true;
  1107. }
  1108. switch (act) {
  1109. case XDP_PASS:
  1110. return false;
  1111. case XDP_TX:
  1112. if (!tsnep_xdp_xmit_back(rx->adapter, xdp, tx_nq, tx, true))
  1113. goto out_failure;
  1114. *status |= TSNEP_XDP_TX;
  1115. return true;
  1116. default:
  1117. bpf_warn_invalid_xdp_action(rx->adapter->netdev, prog, act);
  1118. fallthrough;
  1119. case XDP_ABORTED:
  1120. out_failure:
  1121. trace_xdp_exception(rx->adapter->netdev, prog, act);
  1122. fallthrough;
  1123. case XDP_DROP:
  1124. xsk_buff_free(xdp);
  1125. return true;
  1126. }
  1127. }
  1128. static void tsnep_finalize_xdp(struct tsnep_adapter *adapter, int status,
  1129. struct netdev_queue *tx_nq, struct tsnep_tx *tx)
  1130. {
  1131. if (status & TSNEP_XDP_TX) {
  1132. __netif_tx_lock(tx_nq, smp_processor_id());
  1133. tsnep_xdp_xmit_flush(tx);
  1134. __netif_tx_unlock(tx_nq);
  1135. }
  1136. if (status & TSNEP_XDP_REDIRECT)
  1137. xdp_do_flush();
  1138. }
  1139. static struct sk_buff *tsnep_build_skb(struct tsnep_rx *rx, struct page *page,
  1140. int length)
  1141. {
  1142. struct sk_buff *skb;
  1143. skb = napi_build_skb(page_address(page), PAGE_SIZE);
  1144. if (unlikely(!skb))
  1145. return NULL;
  1146. /* update pointers within the skb to store the data */
  1147. skb_reserve(skb, TSNEP_RX_OFFSET + TSNEP_RX_INLINE_METADATA_SIZE);
  1148. __skb_put(skb, length - ETH_FCS_LEN);
  1149. if (rx->adapter->hwtstamp_config.rx_filter == HWTSTAMP_FILTER_ALL) {
  1150. struct skb_shared_hwtstamps *hwtstamps = skb_hwtstamps(skb);
  1151. struct tsnep_rx_inline *rx_inline =
  1152. (struct tsnep_rx_inline *)(page_address(page) +
  1153. TSNEP_RX_OFFSET);
  1154. skb_shinfo(skb)->tx_flags |=
  1155. SKBTX_HW_TSTAMP_NETDEV;
  1156. memset(hwtstamps, 0, sizeof(*hwtstamps));
  1157. hwtstamps->netdev_data = rx_inline;
  1158. }
  1159. skb_record_rx_queue(skb, rx->queue_index);
  1160. skb->protocol = eth_type_trans(skb, rx->adapter->netdev);
  1161. return skb;
  1162. }
  1163. static void tsnep_rx_page(struct tsnep_rx *rx, struct napi_struct *napi,
  1164. struct page *page, int length)
  1165. {
  1166. struct sk_buff *skb;
  1167. skb = tsnep_build_skb(rx, page, length);
  1168. if (skb) {
  1169. skb_mark_for_recycle(skb);
  1170. rx->packets++;
  1171. rx->bytes += length;
  1172. if (skb->pkt_type == PACKET_MULTICAST)
  1173. rx->multicast++;
  1174. napi_gro_receive(napi, skb);
  1175. } else {
  1176. page_pool_recycle_direct(rx->page_pool, page);
  1177. rx->dropped++;
  1178. }
  1179. }
  1180. static int tsnep_rx_poll(struct tsnep_rx *rx, struct napi_struct *napi,
  1181. int budget)
  1182. {
  1183. struct device *dmadev = rx->adapter->dmadev;
  1184. enum dma_data_direction dma_dir;
  1185. struct tsnep_rx_entry *entry;
  1186. struct netdev_queue *tx_nq;
  1187. struct bpf_prog *prog;
  1188. struct xdp_buff xdp;
  1189. struct tsnep_tx *tx;
  1190. int desc_available;
  1191. int xdp_status = 0;
  1192. int done = 0;
  1193. int length;
  1194. desc_available = tsnep_rx_desc_available(rx);
  1195. dma_dir = page_pool_get_dma_dir(rx->page_pool);
  1196. prog = READ_ONCE(rx->adapter->xdp_prog);
  1197. if (prog) {
  1198. tx_nq = netdev_get_tx_queue(rx->adapter->netdev,
  1199. rx->tx_queue_index);
  1200. tx = &rx->adapter->tx[rx->tx_queue_index];
  1201. xdp_init_buff(&xdp, PAGE_SIZE, &rx->xdp_rxq);
  1202. }
  1203. while (likely(done < budget) && (rx->read != rx->write)) {
  1204. entry = &rx->entry[rx->read];
  1205. if ((__le32_to_cpu(entry->desc_wb->properties) &
  1206. TSNEP_DESC_OWNER_COUNTER_MASK) !=
  1207. (entry->properties & TSNEP_DESC_OWNER_COUNTER_MASK))
  1208. break;
  1209. done++;
  1210. if (desc_available >= TSNEP_RING_RX_REFILL) {
  1211. bool reuse = desc_available >= TSNEP_RING_RX_REUSE;
  1212. desc_available -= tsnep_rx_refill(rx, desc_available,
  1213. reuse);
  1214. if (!entry->page) {
  1215. /* buffer has been reused for refill to prevent
  1216. * empty RX ring, thus buffer cannot be used for
  1217. * RX processing
  1218. */
  1219. rx->read = (rx->read + 1) & TSNEP_RING_MASK;
  1220. desc_available++;
  1221. rx->dropped++;
  1222. continue;
  1223. }
  1224. }
  1225. /* descriptor properties shall be read first, because valid data
  1226. * is signaled there
  1227. */
  1228. dma_rmb();
  1229. prefetch(page_address(entry->page) + TSNEP_RX_OFFSET);
  1230. length = __le32_to_cpu(entry->desc_wb->properties) &
  1231. TSNEP_DESC_LENGTH_MASK;
  1232. dma_sync_single_range_for_cpu(dmadev, entry->dma,
  1233. TSNEP_RX_OFFSET, length, dma_dir);
  1234. /* RX metadata with timestamps is in front of actual data,
  1235. * subtract metadata size to get length of actual data and
  1236. * consider metadata size as offset of actual data during RX
  1237. * processing
  1238. */
  1239. length -= TSNEP_RX_INLINE_METADATA_SIZE;
  1240. rx->read = (rx->read + 1) & TSNEP_RING_MASK;
  1241. desc_available++;
  1242. if (prog) {
  1243. bool consume;
  1244. xdp_prepare_buff(&xdp, page_address(entry->page),
  1245. XDP_PACKET_HEADROOM + TSNEP_RX_INLINE_METADATA_SIZE,
  1246. length - ETH_FCS_LEN, false);
  1247. consume = tsnep_xdp_run_prog(rx, prog, &xdp,
  1248. &xdp_status, tx_nq, tx);
  1249. if (consume) {
  1250. rx->packets++;
  1251. rx->bytes += length;
  1252. entry->page = NULL;
  1253. continue;
  1254. }
  1255. }
  1256. tsnep_rx_page(rx, napi, entry->page, length);
  1257. entry->page = NULL;
  1258. }
  1259. if (xdp_status)
  1260. tsnep_finalize_xdp(rx->adapter, xdp_status, tx_nq, tx);
  1261. if (desc_available)
  1262. tsnep_rx_refill(rx, desc_available, false);
  1263. return done;
  1264. }
  1265. static int tsnep_rx_poll_zc(struct tsnep_rx *rx, struct napi_struct *napi,
  1266. int budget)
  1267. {
  1268. struct tsnep_rx_entry *entry;
  1269. struct netdev_queue *tx_nq;
  1270. struct bpf_prog *prog;
  1271. struct tsnep_tx *tx;
  1272. int desc_available;
  1273. int xdp_status = 0;
  1274. struct page *page;
  1275. int done = 0;
  1276. int length;
  1277. desc_available = tsnep_rx_desc_available(rx);
  1278. prog = READ_ONCE(rx->adapter->xdp_prog);
  1279. if (prog) {
  1280. tx_nq = netdev_get_tx_queue(rx->adapter->netdev,
  1281. rx->tx_queue_index);
  1282. tx = &rx->adapter->tx[rx->tx_queue_index];
  1283. }
  1284. while (likely(done < budget) && (rx->read != rx->write)) {
  1285. entry = &rx->entry[rx->read];
  1286. if ((__le32_to_cpu(entry->desc_wb->properties) &
  1287. TSNEP_DESC_OWNER_COUNTER_MASK) !=
  1288. (entry->properties & TSNEP_DESC_OWNER_COUNTER_MASK))
  1289. break;
  1290. done++;
  1291. if (desc_available >= TSNEP_RING_RX_REFILL) {
  1292. bool reuse = desc_available >= TSNEP_RING_RX_REUSE;
  1293. desc_available -= tsnep_rx_refill_zc(rx, desc_available,
  1294. reuse);
  1295. if (!entry->xdp) {
  1296. /* buffer has been reused for refill to prevent
  1297. * empty RX ring, thus buffer cannot be used for
  1298. * RX processing
  1299. */
  1300. rx->read = (rx->read + 1) & TSNEP_RING_MASK;
  1301. desc_available++;
  1302. rx->dropped++;
  1303. continue;
  1304. }
  1305. }
  1306. /* descriptor properties shall be read first, because valid data
  1307. * is signaled there
  1308. */
  1309. dma_rmb();
  1310. prefetch(entry->xdp->data);
  1311. length = __le32_to_cpu(entry->desc_wb->properties) &
  1312. TSNEP_DESC_LENGTH_MASK;
  1313. xsk_buff_set_size(entry->xdp, length - ETH_FCS_LEN);
  1314. xsk_buff_dma_sync_for_cpu(entry->xdp);
  1315. /* RX metadata with timestamps is in front of actual data,
  1316. * subtract metadata size to get length of actual data and
  1317. * consider metadata size as offset of actual data during RX
  1318. * processing
  1319. */
  1320. length -= TSNEP_RX_INLINE_METADATA_SIZE;
  1321. rx->read = (rx->read + 1) & TSNEP_RING_MASK;
  1322. desc_available++;
  1323. if (prog) {
  1324. bool consume;
  1325. entry->xdp->data += TSNEP_RX_INLINE_METADATA_SIZE;
  1326. entry->xdp->data_meta += TSNEP_RX_INLINE_METADATA_SIZE;
  1327. consume = tsnep_xdp_run_prog_zc(rx, prog, entry->xdp,
  1328. &xdp_status, tx_nq, tx);
  1329. if (consume) {
  1330. rx->packets++;
  1331. rx->bytes += length;
  1332. entry->xdp = NULL;
  1333. continue;
  1334. }
  1335. }
  1336. page = page_pool_dev_alloc_pages(rx->page_pool);
  1337. if (page) {
  1338. memcpy(page_address(page) + TSNEP_RX_OFFSET,
  1339. entry->xdp->data - TSNEP_RX_INLINE_METADATA_SIZE,
  1340. length + TSNEP_RX_INLINE_METADATA_SIZE);
  1341. tsnep_rx_page(rx, napi, page, length);
  1342. } else {
  1343. rx->dropped++;
  1344. }
  1345. xsk_buff_free(entry->xdp);
  1346. entry->xdp = NULL;
  1347. }
  1348. if (xdp_status)
  1349. tsnep_finalize_xdp(rx->adapter, xdp_status, tx_nq, tx);
  1350. if (desc_available)
  1351. desc_available -= tsnep_rx_refill_zc(rx, desc_available, false);
  1352. if (xsk_uses_need_wakeup(rx->xsk_pool)) {
  1353. tsnep_xsk_rx_need_wakeup(rx, desc_available);
  1354. return done;
  1355. }
  1356. return desc_available ? budget : done;
  1357. }
  1358. static bool tsnep_rx_pending(struct tsnep_rx *rx)
  1359. {
  1360. struct tsnep_rx_entry *entry;
  1361. if (rx->read != rx->write) {
  1362. entry = &rx->entry[rx->read];
  1363. if ((__le32_to_cpu(entry->desc_wb->properties) &
  1364. TSNEP_DESC_OWNER_COUNTER_MASK) ==
  1365. (entry->properties & TSNEP_DESC_OWNER_COUNTER_MASK))
  1366. return true;
  1367. }
  1368. return false;
  1369. }
  1370. static int tsnep_rx_open(struct tsnep_rx *rx)
  1371. {
  1372. int desc_available;
  1373. int retval;
  1374. retval = tsnep_rx_ring_create(rx);
  1375. if (retval)
  1376. return retval;
  1377. tsnep_rx_init(rx);
  1378. desc_available = tsnep_rx_desc_available(rx);
  1379. if (rx->xsk_pool)
  1380. retval = tsnep_rx_alloc_zc(rx, desc_available, false);
  1381. else
  1382. retval = tsnep_rx_alloc(rx, desc_available, false);
  1383. if (retval != desc_available) {
  1384. retval = -ENOMEM;
  1385. goto alloc_failed;
  1386. }
  1387. /* prealloc pages to prevent allocation failures when XSK pool is
  1388. * disabled at runtime
  1389. */
  1390. if (rx->xsk_pool) {
  1391. retval = tsnep_rx_alloc_page_buffer(rx);
  1392. if (retval)
  1393. goto alloc_failed;
  1394. }
  1395. return 0;
  1396. alloc_failed:
  1397. tsnep_rx_ring_cleanup(rx);
  1398. return retval;
  1399. }
  1400. static void tsnep_rx_close(struct tsnep_rx *rx)
  1401. {
  1402. if (rx->xsk_pool)
  1403. tsnep_rx_free_page_buffer(rx);
  1404. tsnep_rx_ring_cleanup(rx);
  1405. }
  1406. static void tsnep_rx_reopen(struct tsnep_rx *rx)
  1407. {
  1408. struct page **page = rx->page_buffer;
  1409. int i;
  1410. tsnep_rx_init(rx);
  1411. for (i = 0; i < TSNEP_RING_SIZE; i++) {
  1412. struct tsnep_rx_entry *entry = &rx->entry[i];
  1413. /* defined initial values for properties are required for
  1414. * correct owner counter checking
  1415. */
  1416. entry->desc->properties = 0;
  1417. entry->desc_wb->properties = 0;
  1418. /* prevent allocation failures by reusing kept pages */
  1419. if (*page) {
  1420. tsnep_rx_set_page(rx, entry, *page);
  1421. tsnep_rx_activate(rx, rx->write);
  1422. rx->write++;
  1423. *page = NULL;
  1424. page++;
  1425. }
  1426. }
  1427. }
  1428. static void tsnep_rx_reopen_xsk(struct tsnep_rx *rx)
  1429. {
  1430. struct page **page = rx->page_buffer;
  1431. u32 allocated;
  1432. int i;
  1433. tsnep_rx_init(rx);
  1434. /* alloc all ring entries except the last one, because ring cannot be
  1435. * filled completely, as many buffers as possible is enough as wakeup is
  1436. * done if new buffers are available
  1437. */
  1438. allocated = xsk_buff_alloc_batch(rx->xsk_pool, rx->xdp_batch,
  1439. TSNEP_RING_SIZE - 1);
  1440. for (i = 0; i < TSNEP_RING_SIZE; i++) {
  1441. struct tsnep_rx_entry *entry = &rx->entry[i];
  1442. /* keep pages to prevent allocation failures when xsk is
  1443. * disabled
  1444. */
  1445. if (entry->page) {
  1446. *page = entry->page;
  1447. entry->page = NULL;
  1448. page++;
  1449. }
  1450. /* defined initial values for properties are required for
  1451. * correct owner counter checking
  1452. */
  1453. entry->desc->properties = 0;
  1454. entry->desc_wb->properties = 0;
  1455. if (allocated) {
  1456. tsnep_rx_set_xdp(rx, entry,
  1457. rx->xdp_batch[allocated - 1]);
  1458. tsnep_rx_activate(rx, rx->write);
  1459. rx->write++;
  1460. allocated--;
  1461. }
  1462. }
  1463. /* set need wakeup flag immediately if ring is not filled completely,
  1464. * first polling would be too late as need wakeup signalisation would
  1465. * be delayed for an indefinite time
  1466. */
  1467. if (xsk_uses_need_wakeup(rx->xsk_pool))
  1468. tsnep_xsk_rx_need_wakeup(rx, tsnep_rx_desc_available(rx));
  1469. }
  1470. static bool tsnep_pending(struct tsnep_queue *queue)
  1471. {
  1472. if (queue->tx && tsnep_tx_pending(queue->tx))
  1473. return true;
  1474. if (queue->rx && tsnep_rx_pending(queue->rx))
  1475. return true;
  1476. return false;
  1477. }
  1478. static int tsnep_poll(struct napi_struct *napi, int budget)
  1479. {
  1480. struct tsnep_queue *queue = container_of(napi, struct tsnep_queue,
  1481. napi);
  1482. bool complete = true;
  1483. int done = 0;
  1484. if (queue->tx)
  1485. complete = tsnep_tx_poll(queue->tx, budget);
  1486. /* handle case where we are called by netpoll with a budget of 0 */
  1487. if (unlikely(budget <= 0))
  1488. return budget;
  1489. if (queue->rx) {
  1490. done = queue->rx->xsk_pool ?
  1491. tsnep_rx_poll_zc(queue->rx, napi, budget) :
  1492. tsnep_rx_poll(queue->rx, napi, budget);
  1493. if (done >= budget)
  1494. complete = false;
  1495. }
  1496. /* if all work not completed, return budget and keep polling */
  1497. if (!complete)
  1498. return budget;
  1499. if (likely(napi_complete_done(napi, done))) {
  1500. tsnep_enable_irq(queue->adapter, queue->irq_mask);
  1501. /* reschedule if work is already pending, prevent rotten packets
  1502. * which are transmitted or received after polling but before
  1503. * interrupt enable
  1504. */
  1505. if (tsnep_pending(queue)) {
  1506. tsnep_disable_irq(queue->adapter, queue->irq_mask);
  1507. napi_schedule(napi);
  1508. }
  1509. }
  1510. return min(done, budget - 1);
  1511. }
  1512. static int tsnep_request_irq(struct tsnep_queue *queue, bool first)
  1513. {
  1514. const char *name = netdev_name(queue->adapter->netdev);
  1515. irq_handler_t handler;
  1516. void *dev;
  1517. int retval;
  1518. if (first) {
  1519. sprintf(queue->name, "%s-mac", name);
  1520. handler = tsnep_irq;
  1521. dev = queue->adapter;
  1522. } else {
  1523. if (queue->tx && queue->rx)
  1524. snprintf(queue->name, sizeof(queue->name), "%s-txrx-%d",
  1525. name, queue->rx->queue_index);
  1526. else if (queue->tx)
  1527. snprintf(queue->name, sizeof(queue->name), "%s-tx-%d",
  1528. name, queue->tx->queue_index);
  1529. else
  1530. snprintf(queue->name, sizeof(queue->name), "%s-rx-%d",
  1531. name, queue->rx->queue_index);
  1532. handler = tsnep_irq_txrx;
  1533. dev = queue;
  1534. }
  1535. retval = request_irq(queue->irq, handler, 0, queue->name, dev);
  1536. if (retval) {
  1537. /* if name is empty, then interrupt won't be freed */
  1538. memset(queue->name, 0, sizeof(queue->name));
  1539. }
  1540. return retval;
  1541. }
  1542. static void tsnep_free_irq(struct tsnep_queue *queue, bool first)
  1543. {
  1544. void *dev;
  1545. if (!strlen(queue->name))
  1546. return;
  1547. if (first)
  1548. dev = queue->adapter;
  1549. else
  1550. dev = queue;
  1551. free_irq(queue->irq, dev);
  1552. memset(queue->name, 0, sizeof(queue->name));
  1553. }
  1554. static void tsnep_queue_close(struct tsnep_queue *queue, bool first)
  1555. {
  1556. struct tsnep_rx *rx = queue->rx;
  1557. tsnep_free_irq(queue, first);
  1558. if (rx) {
  1559. if (xdp_rxq_info_is_reg(&rx->xdp_rxq))
  1560. xdp_rxq_info_unreg(&rx->xdp_rxq);
  1561. if (xdp_rxq_info_is_reg(&rx->xdp_rxq_zc))
  1562. xdp_rxq_info_unreg(&rx->xdp_rxq_zc);
  1563. }
  1564. netif_napi_del(&queue->napi);
  1565. }
  1566. static int tsnep_queue_open(struct tsnep_adapter *adapter,
  1567. struct tsnep_queue *queue, bool first)
  1568. {
  1569. struct tsnep_rx *rx = queue->rx;
  1570. struct tsnep_tx *tx = queue->tx;
  1571. int retval;
  1572. netif_napi_add(adapter->netdev, &queue->napi, tsnep_poll);
  1573. if (rx) {
  1574. /* choose TX queue for XDP_TX */
  1575. if (tx)
  1576. rx->tx_queue_index = tx->queue_index;
  1577. else if (rx->queue_index < adapter->num_tx_queues)
  1578. rx->tx_queue_index = rx->queue_index;
  1579. else
  1580. rx->tx_queue_index = 0;
  1581. /* prepare both memory models to eliminate possible registration
  1582. * errors when memory model is switched between page pool and
  1583. * XSK pool during runtime
  1584. */
  1585. retval = xdp_rxq_info_reg(&rx->xdp_rxq, adapter->netdev,
  1586. rx->queue_index, queue->napi.napi_id);
  1587. if (retval)
  1588. goto failed;
  1589. retval = xdp_rxq_info_reg_mem_model(&rx->xdp_rxq,
  1590. MEM_TYPE_PAGE_POOL,
  1591. rx->page_pool);
  1592. if (retval)
  1593. goto failed;
  1594. retval = xdp_rxq_info_reg(&rx->xdp_rxq_zc, adapter->netdev,
  1595. rx->queue_index, queue->napi.napi_id);
  1596. if (retval)
  1597. goto failed;
  1598. retval = xdp_rxq_info_reg_mem_model(&rx->xdp_rxq_zc,
  1599. MEM_TYPE_XSK_BUFF_POOL,
  1600. NULL);
  1601. if (retval)
  1602. goto failed;
  1603. if (rx->xsk_pool)
  1604. xsk_pool_set_rxq_info(rx->xsk_pool, &rx->xdp_rxq_zc);
  1605. }
  1606. retval = tsnep_request_irq(queue, first);
  1607. if (retval) {
  1608. netif_err(adapter, drv, adapter->netdev,
  1609. "can't get assigned irq %d.\n", queue->irq);
  1610. goto failed;
  1611. }
  1612. return 0;
  1613. failed:
  1614. tsnep_queue_close(queue, first);
  1615. return retval;
  1616. }
  1617. static void tsnep_queue_enable(struct tsnep_queue *queue)
  1618. {
  1619. struct tsnep_adapter *adapter = queue->adapter;
  1620. netif_napi_set_irq(&queue->napi, queue->irq);
  1621. napi_enable(&queue->napi);
  1622. tsnep_enable_irq(adapter, queue->irq_mask);
  1623. if (queue->tx) {
  1624. netif_queue_set_napi(adapter->netdev, queue->tx->queue_index,
  1625. NETDEV_QUEUE_TYPE_TX, &queue->napi);
  1626. tsnep_tx_enable(queue->tx);
  1627. }
  1628. if (queue->rx) {
  1629. netif_queue_set_napi(adapter->netdev, queue->rx->queue_index,
  1630. NETDEV_QUEUE_TYPE_RX, &queue->napi);
  1631. tsnep_rx_enable(queue->rx);
  1632. }
  1633. }
  1634. static void tsnep_queue_disable(struct tsnep_queue *queue)
  1635. {
  1636. struct tsnep_adapter *adapter = queue->adapter;
  1637. if (queue->rx)
  1638. netif_queue_set_napi(adapter->netdev, queue->rx->queue_index,
  1639. NETDEV_QUEUE_TYPE_RX, NULL);
  1640. if (queue->tx) {
  1641. tsnep_tx_disable(queue->tx, &queue->napi);
  1642. netif_queue_set_napi(adapter->netdev, queue->tx->queue_index,
  1643. NETDEV_QUEUE_TYPE_TX, NULL);
  1644. }
  1645. napi_disable(&queue->napi);
  1646. tsnep_disable_irq(adapter, queue->irq_mask);
  1647. /* disable RX after NAPI polling has been disabled, because RX can be
  1648. * enabled during NAPI polling
  1649. */
  1650. if (queue->rx)
  1651. tsnep_rx_disable(queue->rx);
  1652. }
  1653. static int tsnep_netdev_open(struct net_device *netdev)
  1654. {
  1655. struct tsnep_adapter *adapter = netdev_priv(netdev);
  1656. int i, retval;
  1657. for (i = 0; i < adapter->num_queues; i++) {
  1658. if (adapter->queue[i].tx) {
  1659. retval = tsnep_tx_open(adapter->queue[i].tx);
  1660. if (retval)
  1661. goto failed;
  1662. }
  1663. if (adapter->queue[i].rx) {
  1664. retval = tsnep_rx_open(adapter->queue[i].rx);
  1665. if (retval)
  1666. goto failed;
  1667. }
  1668. retval = tsnep_queue_open(adapter, &adapter->queue[i], i == 0);
  1669. if (retval)
  1670. goto failed;
  1671. }
  1672. retval = netif_set_real_num_tx_queues(adapter->netdev,
  1673. adapter->num_tx_queues);
  1674. if (retval)
  1675. goto failed;
  1676. retval = netif_set_real_num_rx_queues(adapter->netdev,
  1677. adapter->num_rx_queues);
  1678. if (retval)
  1679. goto failed;
  1680. tsnep_enable_irq(adapter, ECM_INT_LINK);
  1681. retval = tsnep_phy_open(adapter);
  1682. if (retval)
  1683. goto phy_failed;
  1684. for (i = 0; i < adapter->num_queues; i++)
  1685. tsnep_queue_enable(&adapter->queue[i]);
  1686. return 0;
  1687. phy_failed:
  1688. tsnep_disable_irq(adapter, ECM_INT_LINK);
  1689. failed:
  1690. for (i = 0; i < adapter->num_queues; i++) {
  1691. tsnep_queue_close(&adapter->queue[i], i == 0);
  1692. if (adapter->queue[i].rx)
  1693. tsnep_rx_close(adapter->queue[i].rx);
  1694. if (adapter->queue[i].tx)
  1695. tsnep_tx_close(adapter->queue[i].tx);
  1696. }
  1697. return retval;
  1698. }
  1699. static int tsnep_netdev_close(struct net_device *netdev)
  1700. {
  1701. struct tsnep_adapter *adapter = netdev_priv(netdev);
  1702. int i;
  1703. tsnep_disable_irq(adapter, ECM_INT_LINK);
  1704. tsnep_phy_close(adapter);
  1705. for (i = 0; i < adapter->num_queues; i++) {
  1706. tsnep_queue_disable(&adapter->queue[i]);
  1707. tsnep_queue_close(&adapter->queue[i], i == 0);
  1708. if (adapter->queue[i].rx)
  1709. tsnep_rx_close(adapter->queue[i].rx);
  1710. if (adapter->queue[i].tx)
  1711. tsnep_tx_close(adapter->queue[i].tx);
  1712. }
  1713. return 0;
  1714. }
  1715. int tsnep_enable_xsk(struct tsnep_queue *queue, struct xsk_buff_pool *pool)
  1716. {
  1717. bool running = netif_running(queue->adapter->netdev);
  1718. u32 frame_size;
  1719. frame_size = xsk_pool_get_rx_frame_size(pool);
  1720. if (frame_size < TSNEP_XSK_RX_BUF_SIZE)
  1721. return -EOPNOTSUPP;
  1722. queue->rx->page_buffer = kzalloc_objs(*queue->rx->page_buffer,
  1723. TSNEP_RING_SIZE);
  1724. if (!queue->rx->page_buffer)
  1725. return -ENOMEM;
  1726. queue->rx->xdp_batch = kzalloc_objs(*queue->rx->xdp_batch,
  1727. TSNEP_RING_SIZE);
  1728. if (!queue->rx->xdp_batch) {
  1729. kfree(queue->rx->page_buffer);
  1730. queue->rx->page_buffer = NULL;
  1731. return -ENOMEM;
  1732. }
  1733. xsk_pool_set_rxq_info(pool, &queue->rx->xdp_rxq_zc);
  1734. if (running)
  1735. tsnep_queue_disable(queue);
  1736. queue->tx->xsk_pool = pool;
  1737. queue->rx->xsk_pool = pool;
  1738. if (running) {
  1739. tsnep_rx_reopen_xsk(queue->rx);
  1740. tsnep_queue_enable(queue);
  1741. }
  1742. return 0;
  1743. }
  1744. void tsnep_disable_xsk(struct tsnep_queue *queue)
  1745. {
  1746. bool running = netif_running(queue->adapter->netdev);
  1747. if (running)
  1748. tsnep_queue_disable(queue);
  1749. tsnep_rx_free_zc(queue->rx);
  1750. queue->rx->xsk_pool = NULL;
  1751. queue->tx->xsk_pool = NULL;
  1752. if (running) {
  1753. tsnep_rx_reopen(queue->rx);
  1754. tsnep_queue_enable(queue);
  1755. }
  1756. kfree(queue->rx->xdp_batch);
  1757. queue->rx->xdp_batch = NULL;
  1758. kfree(queue->rx->page_buffer);
  1759. queue->rx->page_buffer = NULL;
  1760. }
  1761. static netdev_tx_t tsnep_netdev_xmit_frame(struct sk_buff *skb,
  1762. struct net_device *netdev)
  1763. {
  1764. struct tsnep_adapter *adapter = netdev_priv(netdev);
  1765. u16 queue_mapping = skb_get_queue_mapping(skb);
  1766. if (queue_mapping >= adapter->num_tx_queues)
  1767. queue_mapping = 0;
  1768. return tsnep_xmit_frame_ring(skb, &adapter->tx[queue_mapping]);
  1769. }
  1770. static void tsnep_netdev_set_multicast(struct net_device *netdev)
  1771. {
  1772. struct tsnep_adapter *adapter = netdev_priv(netdev);
  1773. u16 rx_filter = 0;
  1774. /* configured MAC address and broadcasts are never filtered */
  1775. if (netdev->flags & IFF_PROMISC) {
  1776. rx_filter |= TSNEP_RX_FILTER_ACCEPT_ALL_MULTICASTS;
  1777. rx_filter |= TSNEP_RX_FILTER_ACCEPT_ALL_UNICASTS;
  1778. } else if (!netdev_mc_empty(netdev) || (netdev->flags & IFF_ALLMULTI)) {
  1779. rx_filter |= TSNEP_RX_FILTER_ACCEPT_ALL_MULTICASTS;
  1780. }
  1781. iowrite16(rx_filter, adapter->addr + TSNEP_RX_FILTER);
  1782. }
  1783. static void tsnep_netdev_get_stats64(struct net_device *netdev,
  1784. struct rtnl_link_stats64 *stats)
  1785. {
  1786. struct tsnep_adapter *adapter = netdev_priv(netdev);
  1787. u32 reg;
  1788. u32 val;
  1789. int i;
  1790. for (i = 0; i < adapter->num_tx_queues; i++) {
  1791. stats->tx_packets += adapter->tx[i].packets;
  1792. stats->tx_bytes += adapter->tx[i].bytes;
  1793. stats->tx_dropped += adapter->tx[i].dropped;
  1794. }
  1795. for (i = 0; i < adapter->num_rx_queues; i++) {
  1796. stats->rx_packets += adapter->rx[i].packets;
  1797. stats->rx_bytes += adapter->rx[i].bytes;
  1798. stats->rx_dropped += adapter->rx[i].dropped;
  1799. stats->multicast += adapter->rx[i].multicast;
  1800. reg = ioread32(adapter->addr + TSNEP_QUEUE(i) +
  1801. TSNEP_RX_STATISTIC);
  1802. val = (reg & TSNEP_RX_STATISTIC_NO_DESC_MASK) >>
  1803. TSNEP_RX_STATISTIC_NO_DESC_SHIFT;
  1804. stats->rx_dropped += val;
  1805. val = (reg & TSNEP_RX_STATISTIC_BUFFER_TOO_SMALL_MASK) >>
  1806. TSNEP_RX_STATISTIC_BUFFER_TOO_SMALL_SHIFT;
  1807. stats->rx_dropped += val;
  1808. val = (reg & TSNEP_RX_STATISTIC_FIFO_OVERFLOW_MASK) >>
  1809. TSNEP_RX_STATISTIC_FIFO_OVERFLOW_SHIFT;
  1810. stats->rx_errors += val;
  1811. stats->rx_fifo_errors += val;
  1812. val = (reg & TSNEP_RX_STATISTIC_INVALID_FRAME_MASK) >>
  1813. TSNEP_RX_STATISTIC_INVALID_FRAME_SHIFT;
  1814. stats->rx_errors += val;
  1815. stats->rx_frame_errors += val;
  1816. }
  1817. reg = ioread32(adapter->addr + ECM_STAT);
  1818. val = (reg & ECM_STAT_RX_ERR_MASK) >> ECM_STAT_RX_ERR_SHIFT;
  1819. stats->rx_errors += val;
  1820. val = (reg & ECM_STAT_INV_FRM_MASK) >> ECM_STAT_INV_FRM_SHIFT;
  1821. stats->rx_errors += val;
  1822. stats->rx_crc_errors += val;
  1823. val = (reg & ECM_STAT_FWD_RX_ERR_MASK) >> ECM_STAT_FWD_RX_ERR_SHIFT;
  1824. stats->rx_errors += val;
  1825. }
  1826. static void tsnep_mac_set_address(struct tsnep_adapter *adapter, u8 *addr)
  1827. {
  1828. iowrite32(*(u32 *)addr, adapter->addr + TSNEP_MAC_ADDRESS_LOW);
  1829. iowrite16(*(u16 *)(addr + sizeof(u32)),
  1830. adapter->addr + TSNEP_MAC_ADDRESS_HIGH);
  1831. ether_addr_copy(adapter->mac_address, addr);
  1832. netif_info(adapter, drv, adapter->netdev, "MAC address set to %pM\n",
  1833. addr);
  1834. }
  1835. static int tsnep_netdev_set_mac_address(struct net_device *netdev, void *addr)
  1836. {
  1837. struct tsnep_adapter *adapter = netdev_priv(netdev);
  1838. struct sockaddr *sock_addr = addr;
  1839. int retval;
  1840. retval = eth_prepare_mac_addr_change(netdev, sock_addr);
  1841. if (retval)
  1842. return retval;
  1843. eth_hw_addr_set(netdev, sock_addr->sa_data);
  1844. tsnep_mac_set_address(adapter, sock_addr->sa_data);
  1845. return 0;
  1846. }
  1847. static int tsnep_netdev_set_features(struct net_device *netdev,
  1848. netdev_features_t features)
  1849. {
  1850. struct tsnep_adapter *adapter = netdev_priv(netdev);
  1851. netdev_features_t changed = netdev->features ^ features;
  1852. bool enable;
  1853. int retval = 0;
  1854. if (changed & NETIF_F_LOOPBACK) {
  1855. enable = !!(features & NETIF_F_LOOPBACK);
  1856. retval = tsnep_phy_loopback(adapter, enable);
  1857. }
  1858. return retval;
  1859. }
  1860. static ktime_t tsnep_netdev_get_tstamp(struct net_device *netdev,
  1861. const struct skb_shared_hwtstamps *hwtstamps,
  1862. bool cycles)
  1863. {
  1864. struct tsnep_rx_inline *rx_inline = hwtstamps->netdev_data;
  1865. u64 timestamp;
  1866. if (cycles)
  1867. timestamp = __le64_to_cpu(rx_inline->counter);
  1868. else
  1869. timestamp = __le64_to_cpu(rx_inline->timestamp);
  1870. return ns_to_ktime(timestamp);
  1871. }
  1872. static int tsnep_netdev_bpf(struct net_device *dev, struct netdev_bpf *bpf)
  1873. {
  1874. struct tsnep_adapter *adapter = netdev_priv(dev);
  1875. switch (bpf->command) {
  1876. case XDP_SETUP_PROG:
  1877. return tsnep_xdp_setup_prog(adapter, bpf->prog, bpf->extack);
  1878. case XDP_SETUP_XSK_POOL:
  1879. return tsnep_xdp_setup_pool(adapter, bpf->xsk.pool,
  1880. bpf->xsk.queue_id);
  1881. default:
  1882. return -EOPNOTSUPP;
  1883. }
  1884. }
  1885. static struct tsnep_tx *tsnep_xdp_get_tx(struct tsnep_adapter *adapter, u32 cpu)
  1886. {
  1887. if (cpu >= TSNEP_MAX_QUEUES)
  1888. cpu &= TSNEP_MAX_QUEUES - 1;
  1889. while (cpu >= adapter->num_tx_queues)
  1890. cpu -= adapter->num_tx_queues;
  1891. return &adapter->tx[cpu];
  1892. }
  1893. static int tsnep_netdev_xdp_xmit(struct net_device *dev, int n,
  1894. struct xdp_frame **xdp, u32 flags)
  1895. {
  1896. struct tsnep_adapter *adapter = netdev_priv(dev);
  1897. u32 cpu = smp_processor_id();
  1898. struct netdev_queue *nq;
  1899. struct tsnep_tx *tx;
  1900. int nxmit;
  1901. bool xmit;
  1902. if (unlikely(flags & ~XDP_XMIT_FLAGS_MASK))
  1903. return -EINVAL;
  1904. tx = tsnep_xdp_get_tx(adapter, cpu);
  1905. nq = netdev_get_tx_queue(adapter->netdev, tx->queue_index);
  1906. __netif_tx_lock(nq, cpu);
  1907. for (nxmit = 0; nxmit < n; nxmit++) {
  1908. xmit = tsnep_xdp_xmit_frame_ring(xdp[nxmit], tx,
  1909. TSNEP_TX_TYPE_XDP_NDO);
  1910. if (!xmit)
  1911. break;
  1912. /* avoid transmit queue timeout since we share it with the slow
  1913. * path
  1914. */
  1915. txq_trans_cond_update(nq);
  1916. }
  1917. if (flags & XDP_XMIT_FLUSH)
  1918. tsnep_xdp_xmit_flush(tx);
  1919. __netif_tx_unlock(nq);
  1920. return nxmit;
  1921. }
  1922. static int tsnep_netdev_xsk_wakeup(struct net_device *dev, u32 queue_id,
  1923. u32 flags)
  1924. {
  1925. struct tsnep_adapter *adapter = netdev_priv(dev);
  1926. struct tsnep_queue *queue;
  1927. if (queue_id >= adapter->num_rx_queues ||
  1928. queue_id >= adapter->num_tx_queues)
  1929. return -EINVAL;
  1930. queue = &adapter->queue[queue_id];
  1931. if (!napi_if_scheduled_mark_missed(&queue->napi))
  1932. napi_schedule(&queue->napi);
  1933. return 0;
  1934. }
  1935. static const struct net_device_ops tsnep_netdev_ops = {
  1936. .ndo_open = tsnep_netdev_open,
  1937. .ndo_stop = tsnep_netdev_close,
  1938. .ndo_start_xmit = tsnep_netdev_xmit_frame,
  1939. .ndo_eth_ioctl = phy_do_ioctl_running,
  1940. .ndo_set_rx_mode = tsnep_netdev_set_multicast,
  1941. .ndo_get_stats64 = tsnep_netdev_get_stats64,
  1942. .ndo_set_mac_address = tsnep_netdev_set_mac_address,
  1943. .ndo_set_features = tsnep_netdev_set_features,
  1944. .ndo_get_tstamp = tsnep_netdev_get_tstamp,
  1945. .ndo_setup_tc = tsnep_tc_setup,
  1946. .ndo_bpf = tsnep_netdev_bpf,
  1947. .ndo_xdp_xmit = tsnep_netdev_xdp_xmit,
  1948. .ndo_xsk_wakeup = tsnep_netdev_xsk_wakeup,
  1949. .ndo_hwtstamp_get = tsnep_ptp_hwtstamp_get,
  1950. .ndo_hwtstamp_set = tsnep_ptp_hwtstamp_set,
  1951. };
  1952. static int tsnep_mac_init(struct tsnep_adapter *adapter)
  1953. {
  1954. int retval;
  1955. /* initialize RX filtering, at least configured MAC address and
  1956. * broadcast are not filtered
  1957. */
  1958. iowrite16(0, adapter->addr + TSNEP_RX_FILTER);
  1959. /* try to get MAC address in the following order:
  1960. * - device tree
  1961. * - valid MAC address already set
  1962. * - MAC address register if valid
  1963. * - random MAC address
  1964. */
  1965. retval = of_get_mac_address(adapter->pdev->dev.of_node,
  1966. adapter->mac_address);
  1967. if (retval == -EPROBE_DEFER)
  1968. return retval;
  1969. if (retval && !is_valid_ether_addr(adapter->mac_address)) {
  1970. *(u32 *)adapter->mac_address =
  1971. ioread32(adapter->addr + TSNEP_MAC_ADDRESS_LOW);
  1972. *(u16 *)(adapter->mac_address + sizeof(u32)) =
  1973. ioread16(adapter->addr + TSNEP_MAC_ADDRESS_HIGH);
  1974. if (!is_valid_ether_addr(adapter->mac_address))
  1975. eth_random_addr(adapter->mac_address);
  1976. }
  1977. tsnep_mac_set_address(adapter, adapter->mac_address);
  1978. eth_hw_addr_set(adapter->netdev, adapter->mac_address);
  1979. return 0;
  1980. }
  1981. static int tsnep_mdio_init(struct tsnep_adapter *adapter)
  1982. {
  1983. struct device_node *np = adapter->pdev->dev.of_node;
  1984. int retval;
  1985. if (np) {
  1986. np = of_get_child_by_name(np, "mdio");
  1987. if (!np)
  1988. return 0;
  1989. adapter->suppress_preamble =
  1990. of_property_read_bool(np, "suppress-preamble");
  1991. }
  1992. adapter->mdiobus = devm_mdiobus_alloc(&adapter->pdev->dev);
  1993. if (!adapter->mdiobus) {
  1994. retval = -ENOMEM;
  1995. goto out;
  1996. }
  1997. adapter->mdiobus->priv = (void *)adapter;
  1998. adapter->mdiobus->parent = &adapter->pdev->dev;
  1999. adapter->mdiobus->read = tsnep_mdiobus_read;
  2000. adapter->mdiobus->write = tsnep_mdiobus_write;
  2001. adapter->mdiobus->name = TSNEP "-mdiobus";
  2002. snprintf(adapter->mdiobus->id, MII_BUS_ID_SIZE, "%s",
  2003. adapter->pdev->name);
  2004. /* do not scan broadcast address */
  2005. adapter->mdiobus->phy_mask = 0x0000001;
  2006. retval = of_mdiobus_register(adapter->mdiobus, np);
  2007. out:
  2008. of_node_put(np);
  2009. return retval;
  2010. }
  2011. static int tsnep_phy_init(struct tsnep_adapter *adapter)
  2012. {
  2013. struct device_node *phy_node;
  2014. int retval;
  2015. retval = of_get_phy_mode(adapter->pdev->dev.of_node,
  2016. &adapter->phy_mode);
  2017. if (retval)
  2018. adapter->phy_mode = PHY_INTERFACE_MODE_GMII;
  2019. phy_node = of_parse_phandle(adapter->pdev->dev.of_node, "phy-handle",
  2020. 0);
  2021. adapter->phydev = of_phy_find_device(phy_node);
  2022. of_node_put(phy_node);
  2023. if (!adapter->phydev && adapter->mdiobus)
  2024. adapter->phydev = phy_find_first(adapter->mdiobus);
  2025. if (!adapter->phydev)
  2026. return -EIO;
  2027. return 0;
  2028. }
  2029. static int tsnep_queue_init(struct tsnep_adapter *adapter, int queue_count)
  2030. {
  2031. u32 irq_mask = ECM_INT_TX_0 | ECM_INT_RX_0;
  2032. char name[8];
  2033. int i;
  2034. int retval;
  2035. /* one TX/RX queue pair for netdev is mandatory */
  2036. if (platform_irq_count(adapter->pdev) == 1)
  2037. retval = platform_get_irq(adapter->pdev, 0);
  2038. else
  2039. retval = platform_get_irq_byname(adapter->pdev, "mac");
  2040. if (retval < 0)
  2041. return retval;
  2042. adapter->num_tx_queues = 1;
  2043. adapter->num_rx_queues = 1;
  2044. adapter->num_queues = 1;
  2045. adapter->queue[0].adapter = adapter;
  2046. adapter->queue[0].irq = retval;
  2047. adapter->queue[0].tx = &adapter->tx[0];
  2048. adapter->queue[0].tx->adapter = adapter;
  2049. adapter->queue[0].tx->addr = adapter->addr + TSNEP_QUEUE(0);
  2050. adapter->queue[0].tx->queue_index = 0;
  2051. adapter->queue[0].rx = &adapter->rx[0];
  2052. adapter->queue[0].rx->adapter = adapter;
  2053. adapter->queue[0].rx->addr = adapter->addr + TSNEP_QUEUE(0);
  2054. adapter->queue[0].rx->queue_index = 0;
  2055. adapter->queue[0].irq_mask = irq_mask;
  2056. adapter->queue[0].irq_delay_addr = adapter->addr + ECM_INT_DELAY;
  2057. retval = tsnep_set_irq_coalesce(&adapter->queue[0],
  2058. TSNEP_COALESCE_USECS_DEFAULT);
  2059. if (retval < 0)
  2060. return retval;
  2061. adapter->netdev->irq = adapter->queue[0].irq;
  2062. /* add additional TX/RX queue pairs only if dedicated interrupt is
  2063. * available
  2064. */
  2065. for (i = 1; i < queue_count; i++) {
  2066. sprintf(name, "txrx-%d", i);
  2067. retval = platform_get_irq_byname_optional(adapter->pdev, name);
  2068. if (retval < 0)
  2069. break;
  2070. adapter->num_tx_queues++;
  2071. adapter->num_rx_queues++;
  2072. adapter->num_queues++;
  2073. adapter->queue[i].adapter = adapter;
  2074. adapter->queue[i].irq = retval;
  2075. adapter->queue[i].tx = &adapter->tx[i];
  2076. adapter->queue[i].tx->adapter = adapter;
  2077. adapter->queue[i].tx->addr = adapter->addr + TSNEP_QUEUE(i);
  2078. adapter->queue[i].tx->queue_index = i;
  2079. adapter->queue[i].rx = &adapter->rx[i];
  2080. adapter->queue[i].rx->adapter = adapter;
  2081. adapter->queue[i].rx->addr = adapter->addr + TSNEP_QUEUE(i);
  2082. adapter->queue[i].rx->queue_index = i;
  2083. adapter->queue[i].irq_mask =
  2084. irq_mask << (ECM_INT_TXRX_SHIFT * i);
  2085. adapter->queue[i].irq_delay_addr =
  2086. adapter->addr + ECM_INT_DELAY + ECM_INT_DELAY_OFFSET * i;
  2087. retval = tsnep_set_irq_coalesce(&adapter->queue[i],
  2088. TSNEP_COALESCE_USECS_DEFAULT);
  2089. if (retval < 0)
  2090. return retval;
  2091. }
  2092. return 0;
  2093. }
  2094. static int tsnep_probe(struct platform_device *pdev)
  2095. {
  2096. struct tsnep_adapter *adapter;
  2097. struct net_device *netdev;
  2098. struct resource *io;
  2099. u32 type;
  2100. int revision;
  2101. int version;
  2102. int queue_count;
  2103. int retval;
  2104. netdev = devm_alloc_etherdev_mqs(&pdev->dev,
  2105. sizeof(struct tsnep_adapter),
  2106. TSNEP_MAX_QUEUES, TSNEP_MAX_QUEUES);
  2107. if (!netdev)
  2108. return -ENODEV;
  2109. SET_NETDEV_DEV(netdev, &pdev->dev);
  2110. adapter = netdev_priv(netdev);
  2111. platform_set_drvdata(pdev, adapter);
  2112. adapter->pdev = pdev;
  2113. adapter->dmadev = &pdev->dev;
  2114. adapter->netdev = netdev;
  2115. adapter->msg_enable = NETIF_MSG_DRV | NETIF_MSG_PROBE |
  2116. NETIF_MSG_LINK | NETIF_MSG_IFUP |
  2117. NETIF_MSG_IFDOWN | NETIF_MSG_TX_QUEUED;
  2118. netdev->min_mtu = ETH_MIN_MTU;
  2119. netdev->max_mtu = TSNEP_MAX_FRAME_SIZE;
  2120. mutex_init(&adapter->gate_control_lock);
  2121. mutex_init(&adapter->rxnfc_lock);
  2122. INIT_LIST_HEAD(&adapter->rxnfc_rules);
  2123. adapter->addr = devm_platform_get_and_ioremap_resource(pdev, 0, &io);
  2124. if (IS_ERR(adapter->addr))
  2125. return PTR_ERR(adapter->addr);
  2126. netdev->mem_start = io->start;
  2127. netdev->mem_end = io->end;
  2128. type = ioread32(adapter->addr + ECM_TYPE);
  2129. revision = (type & ECM_REVISION_MASK) >> ECM_REVISION_SHIFT;
  2130. version = (type & ECM_VERSION_MASK) >> ECM_VERSION_SHIFT;
  2131. queue_count = (type & ECM_QUEUE_COUNT_MASK) >> ECM_QUEUE_COUNT_SHIFT;
  2132. adapter->gate_control = type & ECM_GATE_CONTROL;
  2133. adapter->rxnfc_max = TSNEP_RX_ASSIGN_ETHER_TYPE_COUNT;
  2134. tsnep_disable_irq(adapter, ECM_INT_ALL);
  2135. retval = tsnep_queue_init(adapter, queue_count);
  2136. if (retval)
  2137. return retval;
  2138. retval = dma_set_mask_and_coherent(&adapter->pdev->dev,
  2139. DMA_BIT_MASK(64));
  2140. if (retval) {
  2141. dev_err(&adapter->pdev->dev, "no usable DMA configuration.\n");
  2142. return retval;
  2143. }
  2144. retval = tsnep_mac_init(adapter);
  2145. if (retval)
  2146. return retval;
  2147. retval = tsnep_mdio_init(adapter);
  2148. if (retval)
  2149. goto mdio_init_failed;
  2150. retval = tsnep_phy_init(adapter);
  2151. if (retval)
  2152. goto phy_init_failed;
  2153. retval = tsnep_ptp_init(adapter);
  2154. if (retval)
  2155. goto ptp_init_failed;
  2156. retval = tsnep_tc_init(adapter);
  2157. if (retval)
  2158. goto tc_init_failed;
  2159. retval = tsnep_rxnfc_init(adapter);
  2160. if (retval)
  2161. goto rxnfc_init_failed;
  2162. netdev->netdev_ops = &tsnep_netdev_ops;
  2163. netdev->ethtool_ops = &tsnep_ethtool_ops;
  2164. netdev->features = NETIF_F_SG;
  2165. netdev->hw_features = netdev->features | NETIF_F_LOOPBACK;
  2166. netdev->xdp_features = NETDEV_XDP_ACT_BASIC | NETDEV_XDP_ACT_REDIRECT |
  2167. NETDEV_XDP_ACT_NDO_XMIT |
  2168. NETDEV_XDP_ACT_NDO_XMIT_SG |
  2169. NETDEV_XDP_ACT_XSK_ZEROCOPY;
  2170. /* carrier off reporting is important to ethtool even BEFORE open */
  2171. netif_carrier_off(netdev);
  2172. retval = register_netdev(netdev);
  2173. if (retval)
  2174. goto register_failed;
  2175. dev_info(&adapter->pdev->dev, "device version %d.%02d\n", version,
  2176. revision);
  2177. if (adapter->gate_control)
  2178. dev_info(&adapter->pdev->dev, "gate control detected\n");
  2179. return 0;
  2180. register_failed:
  2181. tsnep_rxnfc_cleanup(adapter);
  2182. rxnfc_init_failed:
  2183. tsnep_tc_cleanup(adapter);
  2184. tc_init_failed:
  2185. tsnep_ptp_cleanup(adapter);
  2186. ptp_init_failed:
  2187. phy_init_failed:
  2188. if (adapter->mdiobus)
  2189. mdiobus_unregister(adapter->mdiobus);
  2190. mdio_init_failed:
  2191. return retval;
  2192. }
  2193. static void tsnep_remove(struct platform_device *pdev)
  2194. {
  2195. struct tsnep_adapter *adapter = platform_get_drvdata(pdev);
  2196. unregister_netdev(adapter->netdev);
  2197. tsnep_rxnfc_cleanup(adapter);
  2198. tsnep_tc_cleanup(adapter);
  2199. tsnep_ptp_cleanup(adapter);
  2200. if (adapter->mdiobus)
  2201. mdiobus_unregister(adapter->mdiobus);
  2202. tsnep_disable_irq(adapter, ECM_INT_ALL);
  2203. }
  2204. static const struct of_device_id tsnep_of_match[] = {
  2205. { .compatible = "engleder,tsnep", },
  2206. { },
  2207. };
  2208. MODULE_DEVICE_TABLE(of, tsnep_of_match);
  2209. static struct platform_driver tsnep_driver = {
  2210. .driver = {
  2211. .name = TSNEP,
  2212. .of_match_table = tsnep_of_match,
  2213. },
  2214. .probe = tsnep_probe,
  2215. .remove = tsnep_remove,
  2216. };
  2217. module_platform_driver(tsnep_driver);
  2218. MODULE_AUTHOR("Gerhard Engleder <gerhard@engleder-embedded.com>");
  2219. MODULE_DESCRIPTION("TSN endpoint Ethernet MAC driver");
  2220. MODULE_LICENSE("GPL");