tn40.c 52 KB

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  1. // SPDX-License-Identifier: GPL-2.0+
  2. /* Copyright (c) Tehuti Networks Ltd. */
  3. #include <linux/bitfield.h>
  4. #include <linux/ethtool.h>
  5. #include <linux/firmware.h>
  6. #include <linux/if_vlan.h>
  7. #include <linux/iopoll.h>
  8. #include <linux/netdevice.h>
  9. #include <linux/pci.h>
  10. #include <linux/phylink.h>
  11. #include <linux/vmalloc.h>
  12. #include <net/netdev_queues.h>
  13. #include <net/page_pool/helpers.h>
  14. #include "tn40.h"
  15. #define TN40_SHORT_PACKET_SIZE 60
  16. #define TN40_FIRMWARE_NAME "tehuti/bdx.bin"
  17. static void tn40_enable_interrupts(struct tn40_priv *priv)
  18. {
  19. tn40_write_reg(priv, TN40_REG_IMR, priv->isr_mask);
  20. }
  21. static void tn40_disable_interrupts(struct tn40_priv *priv)
  22. {
  23. tn40_write_reg(priv, TN40_REG_IMR, 0);
  24. }
  25. static int tn40_fifo_alloc(struct tn40_priv *priv, struct tn40_fifo *f,
  26. int fsz_type,
  27. u16 reg_cfg0, u16 reg_cfg1,
  28. u16 reg_rptr, u16 reg_wptr)
  29. {
  30. u16 memsz = TN40_FIFO_SIZE * (1 << fsz_type);
  31. u64 cfg_base;
  32. memset(f, 0, sizeof(struct tn40_fifo));
  33. /* 1K extra space is allocated at the end of the fifo to simplify
  34. * processing of descriptors that wraps around fifo's end.
  35. */
  36. f->va = dma_alloc_coherent(&priv->pdev->dev,
  37. memsz + TN40_FIFO_EXTRA_SPACE, &f->da,
  38. GFP_KERNEL);
  39. if (!f->va)
  40. return -ENOMEM;
  41. f->reg_cfg0 = reg_cfg0;
  42. f->reg_cfg1 = reg_cfg1;
  43. f->reg_rptr = reg_rptr;
  44. f->reg_wptr = reg_wptr;
  45. f->rptr = 0;
  46. f->wptr = 0;
  47. f->memsz = memsz;
  48. f->size_mask = memsz - 1;
  49. cfg_base = lower_32_bits((f->da & TN40_TX_RX_CFG0_BASE) | fsz_type);
  50. tn40_write_reg(priv, reg_cfg0, cfg_base);
  51. tn40_write_reg(priv, reg_cfg1, upper_32_bits(f->da));
  52. return 0;
  53. }
  54. static void tn40_fifo_free(struct tn40_priv *priv, struct tn40_fifo *f)
  55. {
  56. dma_free_coherent(&priv->pdev->dev,
  57. f->memsz + TN40_FIFO_EXTRA_SPACE, f->va, f->da);
  58. }
  59. static struct tn40_rxdb *tn40_rxdb_alloc(int nelem)
  60. {
  61. size_t size = sizeof(struct tn40_rxdb) + (nelem * sizeof(int)) +
  62. (nelem * sizeof(struct tn40_rx_map));
  63. struct tn40_rxdb *db;
  64. int i;
  65. db = vzalloc(size);
  66. if (db) {
  67. db->stack = (int *)(db + 1);
  68. db->elems = (void *)(db->stack + nelem);
  69. db->nelem = nelem;
  70. db->top = nelem;
  71. /* make the first alloc close to db struct */
  72. for (i = 0; i < nelem; i++)
  73. db->stack[i] = nelem - i - 1;
  74. }
  75. return db;
  76. }
  77. static void tn40_rxdb_free(struct tn40_rxdb *db)
  78. {
  79. vfree(db);
  80. }
  81. static int tn40_rxdb_alloc_elem(struct tn40_rxdb *db)
  82. {
  83. return db->stack[--db->top];
  84. }
  85. static void *tn40_rxdb_addr_elem(struct tn40_rxdb *db, unsigned int n)
  86. {
  87. return db->elems + n;
  88. }
  89. static int tn40_rxdb_available(struct tn40_rxdb *db)
  90. {
  91. return db->top;
  92. }
  93. static void tn40_rxdb_free_elem(struct tn40_rxdb *db, unsigned int n)
  94. {
  95. db->stack[db->top++] = n;
  96. }
  97. /**
  98. * tn40_create_rx_ring - Initialize RX all related HW and SW resources
  99. * @priv: NIC private structure
  100. *
  101. * create_rx_ring creates rxf and rxd fifos, updates the relevant HW registers,
  102. * preallocates skbs for rx. It assumes that Rx is disabled in HW funcs are
  103. * grouped for better cache usage
  104. *
  105. * RxD fifo is smaller then RxF fifo by design. Upon high load, RxD will be
  106. * filled and packets will be dropped by the NIC without getting into the host
  107. * or generating interrupts. In this situation the host has no chance of
  108. * processing all the packets. Dropping packets by the NIC is cheaper, since it
  109. * takes 0 CPU cycles.
  110. *
  111. * Return: 0 on success and negative value on error.
  112. */
  113. static int tn40_create_rx_ring(struct tn40_priv *priv)
  114. {
  115. struct page_pool_params pp = {
  116. .dev = &priv->pdev->dev,
  117. .napi = &priv->napi,
  118. .dma_dir = DMA_FROM_DEVICE,
  119. .netdev = priv->ndev,
  120. .flags = PP_FLAG_DMA_MAP | PP_FLAG_DMA_SYNC_DEV,
  121. .max_len = PAGE_SIZE,
  122. };
  123. int ret, pkt_size, nr;
  124. priv->page_pool = page_pool_create(&pp);
  125. if (IS_ERR(priv->page_pool))
  126. return PTR_ERR(priv->page_pool);
  127. ret = tn40_fifo_alloc(priv, &priv->rxd_fifo0.m, priv->rxd_size,
  128. TN40_REG_RXD_CFG0_0, TN40_REG_RXD_CFG1_0,
  129. TN40_REG_RXD_RPTR_0, TN40_REG_RXD_WPTR_0);
  130. if (ret)
  131. goto err_destroy_page_pool;
  132. ret = tn40_fifo_alloc(priv, &priv->rxf_fifo0.m, priv->rxf_size,
  133. TN40_REG_RXF_CFG0_0, TN40_REG_RXF_CFG1_0,
  134. TN40_REG_RXF_RPTR_0, TN40_REG_RXF_WPTR_0);
  135. if (ret)
  136. goto err_free_rxd;
  137. pkt_size = priv->ndev->mtu + VLAN_ETH_HLEN;
  138. priv->rxf_fifo0.m.pktsz = pkt_size;
  139. nr = priv->rxf_fifo0.m.memsz / sizeof(struct tn40_rxf_desc);
  140. priv->rxdb0 = tn40_rxdb_alloc(nr);
  141. if (!priv->rxdb0) {
  142. ret = -ENOMEM;
  143. goto err_free_rxf;
  144. }
  145. return 0;
  146. err_free_rxf:
  147. tn40_fifo_free(priv, &priv->rxf_fifo0.m);
  148. err_free_rxd:
  149. tn40_fifo_free(priv, &priv->rxd_fifo0.m);
  150. err_destroy_page_pool:
  151. page_pool_destroy(priv->page_pool);
  152. return ret;
  153. }
  154. static void tn40_rx_free_buffers(struct tn40_priv *priv)
  155. {
  156. struct tn40_rxdb *db = priv->rxdb0;
  157. struct tn40_rx_map *dm;
  158. u16 i;
  159. netdev_dbg(priv->ndev, "total =%d free =%d busy =%d\n", db->nelem,
  160. tn40_rxdb_available(db),
  161. db->nelem - tn40_rxdb_available(db));
  162. for (i = 0; i < db->nelem; i++) {
  163. dm = tn40_rxdb_addr_elem(db, i);
  164. if (dm->page)
  165. page_pool_put_full_page(priv->page_pool, dm->page,
  166. false);
  167. }
  168. }
  169. static void tn40_destroy_rx_ring(struct tn40_priv *priv)
  170. {
  171. if (priv->rxdb0) {
  172. tn40_rx_free_buffers(priv);
  173. tn40_rxdb_free(priv->rxdb0);
  174. priv->rxdb0 = NULL;
  175. }
  176. tn40_fifo_free(priv, &priv->rxf_fifo0.m);
  177. tn40_fifo_free(priv, &priv->rxd_fifo0.m);
  178. page_pool_destroy(priv->page_pool);
  179. }
  180. static void tn40_set_rx_desc(struct tn40_priv *priv, int idx, u64 dma)
  181. {
  182. struct tn40_rxf_fifo *f = &priv->rxf_fifo0;
  183. struct tn40_rxf_desc *rxfd;
  184. int delta;
  185. rxfd = (struct tn40_rxf_desc *)(f->m.va + f->m.wptr);
  186. rxfd->info = cpu_to_le32(0x10003); /* INFO =1 BC =3 */
  187. rxfd->va_lo = cpu_to_le32(idx);
  188. rxfd->pa_lo = cpu_to_le32(lower_32_bits(dma));
  189. rxfd->pa_hi = cpu_to_le32(upper_32_bits(dma));
  190. rxfd->len = cpu_to_le32(f->m.pktsz);
  191. f->m.wptr += sizeof(struct tn40_rxf_desc);
  192. delta = f->m.wptr - f->m.memsz;
  193. if (unlikely(delta >= 0)) {
  194. f->m.wptr = delta;
  195. if (delta > 0) {
  196. memcpy(f->m.va, f->m.va + f->m.memsz, delta);
  197. netdev_dbg(priv->ndev,
  198. "wrapped rxd descriptor\n");
  199. }
  200. }
  201. }
  202. /**
  203. * tn40_rx_alloc_buffers - Fill rxf fifo with buffers.
  204. *
  205. * @priv: NIC's private structure
  206. *
  207. * rx_alloc_buffers allocates buffers via the page pool API, builds rxf descs
  208. * and pushes them (rxf descr) into the rxf fifo. The pages are stored in rxdb.
  209. * To calculate the free space, we uses the cached values of RPTR and WPTR
  210. * when needed. This function also updates RPTR and WPTR.
  211. */
  212. static void tn40_rx_alloc_buffers(struct tn40_priv *priv)
  213. {
  214. struct tn40_rxf_fifo *f = &priv->rxf_fifo0;
  215. struct tn40_rxdb *db = priv->rxdb0;
  216. struct tn40_rx_map *dm;
  217. struct page *page;
  218. int dno, i, idx;
  219. dno = tn40_rxdb_available(db) - 1;
  220. for (i = dno; i > 0; i--) {
  221. page = page_pool_dev_alloc_pages(priv->page_pool);
  222. if (!page)
  223. break;
  224. idx = tn40_rxdb_alloc_elem(db);
  225. tn40_set_rx_desc(priv, idx, page_pool_get_dma_addr(page));
  226. dm = tn40_rxdb_addr_elem(db, idx);
  227. dm->page = page;
  228. }
  229. if (i != dno)
  230. tn40_write_reg(priv, f->m.reg_wptr,
  231. f->m.wptr & TN40_TXF_WPTR_WR_PTR);
  232. netdev_dbg(priv->ndev, "write_reg 0x%04x f->m.reg_wptr 0x%x\n",
  233. f->m.reg_wptr, f->m.wptr & TN40_TXF_WPTR_WR_PTR);
  234. netdev_dbg(priv->ndev, "read_reg 0x%04x f->m.reg_rptr=0x%x\n",
  235. f->m.reg_rptr, tn40_read_reg(priv, f->m.reg_rptr));
  236. netdev_dbg(priv->ndev, "write_reg 0x%04x f->m.reg_wptr=0x%x\n",
  237. f->m.reg_wptr, tn40_read_reg(priv, f->m.reg_wptr));
  238. }
  239. static void tn40_recycle_rx_buffer(struct tn40_priv *priv,
  240. struct tn40_rxd_desc *rxdd)
  241. {
  242. struct tn40_rxf_fifo *f = &priv->rxf_fifo0;
  243. struct tn40_rx_map *dm;
  244. int idx;
  245. idx = le32_to_cpu(rxdd->va_lo);
  246. dm = tn40_rxdb_addr_elem(priv->rxdb0, idx);
  247. tn40_set_rx_desc(priv, idx, page_pool_get_dma_addr(dm->page));
  248. tn40_write_reg(priv, f->m.reg_wptr, f->m.wptr & TN40_TXF_WPTR_WR_PTR);
  249. }
  250. static int tn40_rx_receive(struct tn40_priv *priv, int budget)
  251. {
  252. struct tn40_rxd_fifo *f = &priv->rxd_fifo0;
  253. u32 rxd_val1, rxd_err, pkt_id;
  254. int tmp_len, size, done = 0;
  255. struct tn40_rxdb *db = NULL;
  256. struct tn40_rxd_desc *rxdd;
  257. struct tn40_rx_map *dm;
  258. struct sk_buff *skb;
  259. u16 len, rxd_vlan;
  260. int idx;
  261. f->m.wptr = tn40_read_reg(priv, f->m.reg_wptr) & TN40_TXF_WPTR_WR_PTR;
  262. size = f->m.wptr - f->m.rptr;
  263. if (size < 0)
  264. size += f->m.memsz; /* Size is negative :-) */
  265. while (size > 0) {
  266. rxdd = (struct tn40_rxd_desc *)(f->m.va + f->m.rptr);
  267. db = priv->rxdb0;
  268. /* We have a chicken and egg problem here. If the
  269. * descriptor is wrapped we first need to copy the tail
  270. * of the descriptor to the end of the buffer before
  271. * extracting values from the descriptor. However in
  272. * order to know if the descriptor is wrapped we need to
  273. * obtain the length of the descriptor from (the
  274. * wrapped) descriptor. Luckily the length is the first
  275. * word of the descriptor. Descriptor lengths are
  276. * multiples of 8 bytes so in case of a wrapped
  277. * descriptor the first 8 bytes guaranteed to appear
  278. * before the end of the buffer. We first obtain the
  279. * length, we then copy the rest of the descriptor if
  280. * needed and then extract the rest of the values from
  281. * the descriptor.
  282. *
  283. * Do not change the order of operations as it will
  284. * break the code!!!
  285. */
  286. rxd_val1 = le32_to_cpu(rxdd->rxd_val1);
  287. tmp_len = TN40_GET_RXD_BC(rxd_val1) << 3;
  288. pkt_id = TN40_GET_RXD_PKT_ID(rxd_val1);
  289. size -= tmp_len;
  290. /* CHECK FOR A PARTIALLY ARRIVED DESCRIPTOR */
  291. if (size < 0) {
  292. netdev_dbg(priv->ndev,
  293. "%s partially arrived desc tmp_len %d\n",
  294. __func__, tmp_len);
  295. break;
  296. }
  297. /* make sure that the descriptor fully is arrived
  298. * before reading the rest of the descriptor.
  299. */
  300. rmb();
  301. /* A special treatment is given to non-contiguous
  302. * descriptors that start near the end, wraps around
  303. * and continue at the beginning. The second part is
  304. * copied right after the first, and then descriptor
  305. * is interpreted as normal. The fifo has an extra
  306. * space to allow such operations.
  307. */
  308. /* HAVE WE REACHED THE END OF THE QUEUE? */
  309. f->m.rptr += tmp_len;
  310. tmp_len = f->m.rptr - f->m.memsz;
  311. if (unlikely(tmp_len >= 0)) {
  312. f->m.rptr = tmp_len;
  313. if (tmp_len > 0) {
  314. /* COPY PARTIAL DESCRIPTOR
  315. * TO THE END OF THE QUEUE
  316. */
  317. netdev_dbg(priv->ndev,
  318. "wrapped desc rptr=%d tmp_len=%d\n",
  319. f->m.rptr, tmp_len);
  320. memcpy(f->m.va + f->m.memsz, f->m.va, tmp_len);
  321. }
  322. }
  323. idx = le32_to_cpu(rxdd->va_lo);
  324. dm = tn40_rxdb_addr_elem(db, idx);
  325. prefetch(dm);
  326. len = le16_to_cpu(rxdd->len);
  327. rxd_vlan = le16_to_cpu(rxdd->rxd_vlan);
  328. /* CHECK FOR ERRORS */
  329. rxd_err = TN40_GET_RXD_ERR(rxd_val1);
  330. if (unlikely(rxd_err)) {
  331. u64_stats_update_begin(&priv->syncp);
  332. priv->stats.rx_errors++;
  333. u64_stats_update_end(&priv->syncp);
  334. tn40_recycle_rx_buffer(priv, rxdd);
  335. continue;
  336. }
  337. skb = napi_build_skb(page_address(dm->page), PAGE_SIZE);
  338. if (!skb) {
  339. u64_stats_update_begin(&priv->syncp);
  340. priv->stats.rx_dropped++;
  341. priv->alloc_fail++;
  342. u64_stats_update_end(&priv->syncp);
  343. tn40_recycle_rx_buffer(priv, rxdd);
  344. break;
  345. }
  346. skb_mark_for_recycle(skb);
  347. skb_put(skb, len);
  348. skb->protocol = eth_type_trans(skb, priv->ndev);
  349. skb->ip_summed =
  350. (pkt_id == 0) ? CHECKSUM_NONE : CHECKSUM_UNNECESSARY;
  351. if (TN40_GET_RXD_VTAG(rxd_val1))
  352. __vlan_hwaccel_put_tag(skb, htons(ETH_P_8021Q),
  353. TN40_GET_RXD_VLAN_TCI(rxd_vlan));
  354. dm->page = NULL;
  355. tn40_rxdb_free_elem(db, idx);
  356. napi_gro_receive(&priv->napi, skb);
  357. u64_stats_update_begin(&priv->syncp);
  358. priv->stats.rx_bytes += len;
  359. u64_stats_update_end(&priv->syncp);
  360. if (unlikely(++done >= budget))
  361. break;
  362. }
  363. u64_stats_update_begin(&priv->syncp);
  364. priv->stats.rx_packets += done;
  365. u64_stats_update_end(&priv->syncp);
  366. /* FIXME: Do something to minimize pci accesses */
  367. tn40_write_reg(priv, f->m.reg_rptr, f->m.rptr & TN40_TXF_WPTR_WR_PTR);
  368. tn40_rx_alloc_buffers(priv);
  369. return done;
  370. }
  371. /* TX HW/SW interaction overview
  372. * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
  373. * There are 2 types of TX communication channels between driver and NIC.
  374. * 1) TX Free Fifo - TXF - Holds ack descriptors for sent packets.
  375. * 2) TX Data Fifo - TXD - Holds descriptors of full buffers.
  376. *
  377. * Currently the NIC supports TSO, checksumming and gather DMA
  378. * UFO and IP fragmentation is on the way.
  379. *
  380. * RX SW Data Structures
  381. * ~~~~~~~~~~~~~~~~~~~~~
  382. * TXDB is used to keep track of all skbs owned by SW and their DMA addresses.
  383. * For TX case, ownership lasts from getting the packet via hard_xmit and
  384. * until the HW acknowledges sending the packet by TXF descriptors.
  385. * TXDB is implemented as a cyclic buffer.
  386. *
  387. * FIFO objects keep info about the fifo's size and location, relevant HW
  388. * registers, usage and skb db. Each RXD and RXF fifo has their own fifo
  389. * structure. Implemented as simple struct.
  390. *
  391. * TX SW Execution Flow
  392. * ~~~~~~~~~~~~~~~~~~~~
  393. * OS calls the driver's hard_xmit method with a packet to send. The driver
  394. * creates DMA mappings, builds TXD descriptors and kicks the HW by updating
  395. * TXD WPTR.
  396. *
  397. * When a packet is sent, The HW write a TXF descriptor and the SW
  398. * frees the original skb. To prevent TXD fifo overflow without
  399. * reading HW registers every time, the SW deploys "tx level"
  400. * technique. Upon startup, the tx level is initialized to TXD fifo
  401. * length. For every sent packet, the SW gets its TXD descriptor size
  402. * (from a pre-calculated array) and subtracts it from tx level. The
  403. * size is also stored in txdb. When a TXF ack arrives, the SW fetched
  404. * the size of the original TXD descriptor from the txdb and adds it
  405. * to the tx level. When the Tx level drops below some predefined
  406. * threshold, the driver stops the TX queue. When the TX level rises
  407. * above that level, the tx queue is enabled again.
  408. *
  409. * This technique avoids excessive reading of RPTR and WPTR registers.
  410. * As our benchmarks shows, it adds 1.5 Gbit/sec to NIC's throughput.
  411. */
  412. static void tn40_do_tx_db_ptr_next(struct tn40_txdb *db,
  413. struct tn40_tx_map **pptr)
  414. {
  415. ++*pptr;
  416. if (unlikely(*pptr == db->end))
  417. *pptr = db->start;
  418. }
  419. static void tn40_tx_db_inc_rptr(struct tn40_txdb *db)
  420. {
  421. tn40_do_tx_db_ptr_next(db, &db->rptr);
  422. }
  423. static void tn40_tx_db_inc_wptr(struct tn40_txdb *db)
  424. {
  425. tn40_do_tx_db_ptr_next(db, &db->wptr);
  426. }
  427. static int tn40_tx_db_init(struct tn40_txdb *d, int sz_type)
  428. {
  429. int memsz = TN40_FIFO_SIZE * (1 << (sz_type + 1));
  430. d->start = vzalloc(memsz);
  431. if (!d->start)
  432. return -ENOMEM;
  433. /* In order to differentiate between an empty db state and a full db
  434. * state at least one element should always be empty in order to
  435. * avoid rptr == wptr, which means that the db is empty.
  436. */
  437. d->size = memsz / sizeof(struct tn40_tx_map) - 1;
  438. d->end = d->start + d->size + 1; /* just after last element */
  439. /* All dbs are created empty */
  440. d->rptr = d->start;
  441. d->wptr = d->start;
  442. return 0;
  443. }
  444. static void tn40_tx_db_close(struct tn40_txdb *d)
  445. {
  446. if (d->start) {
  447. vfree(d->start);
  448. d->start = NULL;
  449. }
  450. }
  451. /* Sizes of tx desc (including padding if needed) as function of the SKB's
  452. * frag number
  453. * 7 - is number of lwords in txd with one phys buffer
  454. * 3 - is number of lwords used for every additional phys buffer
  455. * for (i = 0; i < TN40_MAX_PBL; i++) {
  456. * lwords = 7 + (i * 3);
  457. * if (lwords & 1)
  458. * lwords++; pad it with 1 lword
  459. * tn40_txd_sizes[i].bytes = lwords << 2;
  460. * tn40_txd_sizes[i].qwords = lwords >> 1;
  461. * }
  462. */
  463. static struct {
  464. u16 bytes;
  465. u16 qwords; /* qword = 64 bit */
  466. } tn40_txd_sizes[] = {
  467. {0x20, 0x04},
  468. {0x28, 0x05},
  469. {0x38, 0x07},
  470. {0x40, 0x08},
  471. {0x50, 0x0a},
  472. {0x58, 0x0b},
  473. {0x68, 0x0d},
  474. {0x70, 0x0e},
  475. {0x80, 0x10},
  476. {0x88, 0x11},
  477. {0x98, 0x13},
  478. {0xa0, 0x14},
  479. {0xb0, 0x16},
  480. {0xb8, 0x17},
  481. {0xc8, 0x19},
  482. {0xd0, 0x1a},
  483. {0xe0, 0x1c},
  484. {0xe8, 0x1d},
  485. {0xf8, 0x1f},
  486. };
  487. static void tn40_pbl_set(struct tn40_pbl *pbl, dma_addr_t dma, int len)
  488. {
  489. pbl->len = cpu_to_le32(len);
  490. pbl->pa_lo = cpu_to_le32(lower_32_bits(dma));
  491. pbl->pa_hi = cpu_to_le32(upper_32_bits(dma));
  492. }
  493. static void tn40_txdb_set(struct tn40_txdb *db, dma_addr_t dma, int len)
  494. {
  495. db->wptr->len = len;
  496. db->wptr->addr.dma = dma;
  497. }
  498. struct tn40_mapping_info {
  499. dma_addr_t dma;
  500. size_t size;
  501. };
  502. /**
  503. * tn40_tx_map_skb - create and store DMA mappings for skb's data blocks
  504. * @priv: NIC private structure
  505. * @skb: socket buffer to map
  506. * @txdd: pointer to tx descriptor to be updated
  507. * @pkt_len: pointer to unsigned long value
  508. *
  509. * This function creates DMA mappings for skb's data blocks and writes them to
  510. * PBL of a new tx descriptor. It also stores them in the tx db, so they could
  511. * be unmapped after the data has been sent. It is the responsibility of the
  512. * caller to make sure that there is enough space in the txdb. The last
  513. * element holds a pointer to skb itself and is marked with a zero length.
  514. *
  515. * Return: 0 on success and negative value on error.
  516. */
  517. static int tn40_tx_map_skb(struct tn40_priv *priv, struct sk_buff *skb,
  518. struct tn40_txd_desc *txdd, unsigned int *pkt_len)
  519. {
  520. struct tn40_mapping_info info[TN40_MAX_PBL];
  521. int nr_frags = skb_shinfo(skb)->nr_frags;
  522. struct tn40_pbl *pbl = &txdd->pbl[0];
  523. struct tn40_txdb *db = &priv->txdb;
  524. unsigned int size;
  525. int i, len, ret;
  526. dma_addr_t dma;
  527. netdev_dbg(priv->ndev, "TX skb %p skbLen %d dataLen %d frags %d\n", skb,
  528. skb->len, skb->data_len, nr_frags);
  529. if (nr_frags > TN40_MAX_PBL - 1) {
  530. ret = skb_linearize(skb);
  531. if (ret)
  532. return ret;
  533. nr_frags = skb_shinfo(skb)->nr_frags;
  534. }
  535. /* initial skb */
  536. len = skb->len - skb->data_len;
  537. dma = dma_map_single(&priv->pdev->dev, skb->data, len,
  538. DMA_TO_DEVICE);
  539. ret = dma_mapping_error(&priv->pdev->dev, dma);
  540. if (ret)
  541. return ret;
  542. tn40_txdb_set(db, dma, len);
  543. tn40_pbl_set(pbl++, db->wptr->addr.dma, db->wptr->len);
  544. *pkt_len = db->wptr->len;
  545. for (i = 0; i < nr_frags; i++) {
  546. skb_frag_t *frag = &skb_shinfo(skb)->frags[i];
  547. size = skb_frag_size(frag);
  548. dma = skb_frag_dma_map(&priv->pdev->dev, frag, 0,
  549. size, DMA_TO_DEVICE);
  550. ret = dma_mapping_error(&priv->pdev->dev, dma);
  551. if (ret)
  552. goto mapping_error;
  553. info[i].dma = dma;
  554. info[i].size = size;
  555. }
  556. for (i = 0; i < nr_frags; i++) {
  557. tn40_tx_db_inc_wptr(db);
  558. tn40_txdb_set(db, info[i].dma, info[i].size);
  559. tn40_pbl_set(pbl++, db->wptr->addr.dma, db->wptr->len);
  560. *pkt_len += db->wptr->len;
  561. }
  562. /* SHORT_PKT_FIX */
  563. if (skb->len < TN40_SHORT_PACKET_SIZE)
  564. ++nr_frags;
  565. /* Add skb clean up info. */
  566. tn40_tx_db_inc_wptr(db);
  567. db->wptr->len = -tn40_txd_sizes[nr_frags].bytes;
  568. db->wptr->addr.skb = skb;
  569. tn40_tx_db_inc_wptr(db);
  570. return 0;
  571. mapping_error:
  572. dma_unmap_page(&priv->pdev->dev, db->wptr->addr.dma, db->wptr->len,
  573. DMA_TO_DEVICE);
  574. for (; i > 0; i--)
  575. dma_unmap_page(&priv->pdev->dev, info[i - 1].dma,
  576. info[i - 1].size, DMA_TO_DEVICE);
  577. return -ENOMEM;
  578. }
  579. static int tn40_create_tx_ring(struct tn40_priv *priv)
  580. {
  581. int ret;
  582. ret = tn40_fifo_alloc(priv, &priv->txd_fifo0.m, priv->txd_size,
  583. TN40_REG_TXD_CFG0_0, TN40_REG_TXD_CFG1_0,
  584. TN40_REG_TXD_RPTR_0, TN40_REG_TXD_WPTR_0);
  585. if (ret)
  586. return ret;
  587. ret = tn40_fifo_alloc(priv, &priv->txf_fifo0.m, priv->txf_size,
  588. TN40_REG_TXF_CFG0_0, TN40_REG_TXF_CFG1_0,
  589. TN40_REG_TXF_RPTR_0, TN40_REG_TXF_WPTR_0);
  590. if (ret)
  591. goto err_free_txd;
  592. /* The TX db has to keep mappings for all packets sent (on
  593. * TxD) and not yet reclaimed (on TxF).
  594. */
  595. ret = tn40_tx_db_init(&priv->txdb, max(priv->txd_size, priv->txf_size));
  596. if (ret)
  597. goto err_free_txf;
  598. /* SHORT_PKT_FIX */
  599. priv->b0_len = 64;
  600. priv->b0_va = dma_alloc_coherent(&priv->pdev->dev, priv->b0_len,
  601. &priv->b0_dma, GFP_KERNEL);
  602. if (!priv->b0_va)
  603. goto err_free_db;
  604. priv->tx_level = TN40_MAX_TX_LEVEL;
  605. priv->tx_update_mark = priv->tx_level - 1024;
  606. return 0;
  607. err_free_db:
  608. tn40_tx_db_close(&priv->txdb);
  609. err_free_txf:
  610. tn40_fifo_free(priv, &priv->txf_fifo0.m);
  611. err_free_txd:
  612. tn40_fifo_free(priv, &priv->txd_fifo0.m);
  613. return -ENOMEM;
  614. }
  615. /**
  616. * tn40_tx_space - Calculate the available space in the TX fifo.
  617. * @priv: NIC private structure
  618. *
  619. * Return: available space in TX fifo in bytes
  620. */
  621. static int tn40_tx_space(struct tn40_priv *priv)
  622. {
  623. struct tn40_txd_fifo *f = &priv->txd_fifo0;
  624. int fsize;
  625. f->m.rptr = tn40_read_reg(priv, f->m.reg_rptr) & TN40_TXF_WPTR_WR_PTR;
  626. fsize = f->m.rptr - f->m.wptr;
  627. if (fsize <= 0)
  628. fsize = f->m.memsz + fsize;
  629. return fsize;
  630. }
  631. #define TN40_TXD_FULL_CHECKSUM 7
  632. static netdev_tx_t tn40_start_xmit(struct sk_buff *skb, struct net_device *ndev)
  633. {
  634. struct tn40_priv *priv = netdev_priv(ndev);
  635. struct tn40_txd_fifo *f = &priv->txd_fifo0;
  636. int txd_checksum = TN40_TXD_FULL_CHECKSUM;
  637. struct tn40_txd_desc *txdd;
  638. int nr_frags, len, err;
  639. unsigned int pkt_len;
  640. int txd_vlan_id = 0;
  641. int txd_lgsnd = 0;
  642. int txd_vtag = 0;
  643. int txd_mss = 0;
  644. /* Build tx descriptor */
  645. txdd = (struct tn40_txd_desc *)(f->m.va + f->m.wptr);
  646. err = tn40_tx_map_skb(priv, skb, txdd, &pkt_len);
  647. if (err) {
  648. u64_stats_update_begin(&priv->syncp);
  649. priv->stats.tx_dropped++;
  650. u64_stats_update_end(&priv->syncp);
  651. dev_kfree_skb(skb);
  652. return NETDEV_TX_OK;
  653. }
  654. nr_frags = skb_shinfo(skb)->nr_frags;
  655. if (unlikely(skb->ip_summed != CHECKSUM_PARTIAL))
  656. txd_checksum = 0;
  657. if (skb_shinfo(skb)->gso_size) {
  658. txd_mss = skb_shinfo(skb)->gso_size;
  659. txd_lgsnd = 1;
  660. netdev_dbg(priv->ndev, "skb %p pkt len %d gso size = %d\n", skb,
  661. pkt_len, txd_mss);
  662. }
  663. if (skb_vlan_tag_present(skb)) {
  664. /* Don't cut VLAN ID to 12 bits */
  665. txd_vlan_id = skb_vlan_tag_get(skb);
  666. txd_vtag = 1;
  667. }
  668. txdd->va_hi = 0;
  669. txdd->va_lo = 0;
  670. txdd->length = cpu_to_le16(pkt_len);
  671. txdd->mss = cpu_to_le16(txd_mss);
  672. txdd->txd_val1 =
  673. cpu_to_le32(TN40_TXD_W1_VAL
  674. (tn40_txd_sizes[nr_frags].qwords, txd_checksum,
  675. txd_vtag, txd_lgsnd, txd_vlan_id));
  676. netdev_dbg(priv->ndev, "=== w1 qwords[%d] %d =====\n", nr_frags,
  677. tn40_txd_sizes[nr_frags].qwords);
  678. netdev_dbg(priv->ndev, "=== TxD desc =====================\n");
  679. netdev_dbg(priv->ndev, "=== w1: 0x%x ================\n",
  680. txdd->txd_val1);
  681. netdev_dbg(priv->ndev, "=== w2: mss 0x%x len 0x%x\n", txdd->mss,
  682. txdd->length);
  683. /* SHORT_PKT_FIX */
  684. if (pkt_len < TN40_SHORT_PACKET_SIZE) {
  685. struct tn40_pbl *pbl = &txdd->pbl[++nr_frags];
  686. txdd->length = cpu_to_le16(TN40_SHORT_PACKET_SIZE);
  687. txdd->txd_val1 =
  688. cpu_to_le32(TN40_TXD_W1_VAL
  689. (tn40_txd_sizes[nr_frags].qwords,
  690. txd_checksum, txd_vtag, txd_lgsnd,
  691. txd_vlan_id));
  692. pbl->len = cpu_to_le32(TN40_SHORT_PACKET_SIZE - pkt_len);
  693. pbl->pa_lo = cpu_to_le32(lower_32_bits(priv->b0_dma));
  694. pbl->pa_hi = cpu_to_le32(upper_32_bits(priv->b0_dma));
  695. netdev_dbg(priv->ndev, "=== SHORT_PKT_FIX ==============\n");
  696. netdev_dbg(priv->ndev, "=== nr_frags : %d ==============\n",
  697. nr_frags);
  698. }
  699. /* Increment TXD write pointer. In case of fifo wrapping copy
  700. * reminder of the descriptor to the beginning.
  701. */
  702. f->m.wptr += tn40_txd_sizes[nr_frags].bytes;
  703. len = f->m.wptr - f->m.memsz;
  704. if (unlikely(len >= 0)) {
  705. f->m.wptr = len;
  706. if (len > 0)
  707. memcpy(f->m.va, f->m.va + f->m.memsz, len);
  708. }
  709. /* Force memory writes to complete before letting the HW know
  710. * there are new descriptors to fetch.
  711. */
  712. wmb();
  713. priv->tx_level -= tn40_txd_sizes[nr_frags].bytes;
  714. if (priv->tx_level > priv->tx_update_mark) {
  715. tn40_write_reg(priv, f->m.reg_wptr,
  716. f->m.wptr & TN40_TXF_WPTR_WR_PTR);
  717. } else {
  718. if (priv->tx_noupd++ > TN40_NO_UPD_PACKETS) {
  719. priv->tx_noupd = 0;
  720. tn40_write_reg(priv, f->m.reg_wptr,
  721. f->m.wptr & TN40_TXF_WPTR_WR_PTR);
  722. }
  723. }
  724. u64_stats_update_begin(&priv->syncp);
  725. priv->stats.tx_packets++;
  726. priv->stats.tx_bytes += pkt_len;
  727. u64_stats_update_end(&priv->syncp);
  728. if (priv->tx_level < TN40_MIN_TX_LEVEL) {
  729. netdev_dbg(priv->ndev, "TX Q STOP level %d\n", priv->tx_level);
  730. netif_stop_queue(ndev);
  731. }
  732. return NETDEV_TX_OK;
  733. }
  734. static void tn40_tx_cleanup(struct tn40_priv *priv)
  735. {
  736. struct tn40_txf_fifo *f = &priv->txf_fifo0;
  737. struct tn40_txdb *db = &priv->txdb;
  738. int tx_level = 0;
  739. f->m.wptr = tn40_read_reg(priv, f->m.reg_wptr) & TN40_TXF_WPTR_MASK;
  740. netif_tx_lock(priv->ndev);
  741. while (f->m.wptr != f->m.rptr) {
  742. f->m.rptr += TN40_TXF_DESC_SZ;
  743. f->m.rptr &= f->m.size_mask;
  744. /* Unmap all fragments */
  745. /* First has to come tx_maps containing DMA */
  746. do {
  747. dma_addr_t addr = db->rptr->addr.dma;
  748. size_t size = db->rptr->len;
  749. netif_tx_unlock(priv->ndev);
  750. dma_unmap_page(&priv->pdev->dev, addr,
  751. size, DMA_TO_DEVICE);
  752. netif_tx_lock(priv->ndev);
  753. tn40_tx_db_inc_rptr(db);
  754. } while (db->rptr->len > 0);
  755. tx_level -= db->rptr->len; /* '-' Because the len is negative */
  756. /* Now should come skb pointer - free it */
  757. dev_kfree_skb_any(db->rptr->addr.skb);
  758. netdev_dbg(priv->ndev, "dev_kfree_skb_any %p %d\n",
  759. db->rptr->addr.skb, -db->rptr->len);
  760. tn40_tx_db_inc_rptr(db);
  761. }
  762. /* Let the HW know which TXF descriptors were cleaned */
  763. tn40_write_reg(priv, f->m.reg_rptr, f->m.rptr & TN40_TXF_WPTR_WR_PTR);
  764. /* We reclaimed resources, so in case the Q is stopped by xmit
  765. * callback, we resume the transmission and use tx_lock to
  766. * synchronize with xmit.
  767. */
  768. priv->tx_level += tx_level;
  769. if (priv->tx_noupd) {
  770. priv->tx_noupd = 0;
  771. tn40_write_reg(priv, priv->txd_fifo0.m.reg_wptr,
  772. priv->txd_fifo0.m.wptr & TN40_TXF_WPTR_WR_PTR);
  773. }
  774. if (unlikely(netif_queue_stopped(priv->ndev) &&
  775. netif_carrier_ok(priv->ndev) &&
  776. (priv->tx_level >= TN40_MAX_TX_LEVEL / 2))) {
  777. netdev_dbg(priv->ndev, "TX Q WAKE level %d\n", priv->tx_level);
  778. netif_wake_queue(priv->ndev);
  779. }
  780. netif_tx_unlock(priv->ndev);
  781. }
  782. static void tn40_tx_free_skbs(struct tn40_priv *priv)
  783. {
  784. struct tn40_txdb *db = &priv->txdb;
  785. while (db->rptr != db->wptr) {
  786. if (likely(db->rptr->len))
  787. dma_unmap_page(&priv->pdev->dev, db->rptr->addr.dma,
  788. db->rptr->len, DMA_TO_DEVICE);
  789. else
  790. dev_kfree_skb(db->rptr->addr.skb);
  791. tn40_tx_db_inc_rptr(db);
  792. }
  793. }
  794. static void tn40_destroy_tx_ring(struct tn40_priv *priv)
  795. {
  796. tn40_tx_free_skbs(priv);
  797. tn40_fifo_free(priv, &priv->txd_fifo0.m);
  798. tn40_fifo_free(priv, &priv->txf_fifo0.m);
  799. tn40_tx_db_close(&priv->txdb);
  800. /* SHORT_PKT_FIX */
  801. if (priv->b0_len) {
  802. dma_free_coherent(&priv->pdev->dev, priv->b0_len, priv->b0_va,
  803. priv->b0_dma);
  804. priv->b0_len = 0;
  805. }
  806. }
  807. /**
  808. * tn40_tx_push_desc - Push a descriptor to TxD fifo.
  809. *
  810. * @priv: NIC private structure
  811. * @data: desc's data
  812. * @size: desc's size
  813. *
  814. * This function pushes desc to TxD fifo and overlaps it if needed.
  815. *
  816. * This function does not check for available space, nor does it check
  817. * that the data size is smaller than the fifo size. Checking for
  818. * space is the responsibility of the caller.
  819. */
  820. static void tn40_tx_push_desc(struct tn40_priv *priv, void *data, int size)
  821. {
  822. struct tn40_txd_fifo *f = &priv->txd_fifo0;
  823. int i = f->m.memsz - f->m.wptr;
  824. if (size == 0)
  825. return;
  826. if (i > size) {
  827. memcpy(f->m.va + f->m.wptr, data, size);
  828. f->m.wptr += size;
  829. } else {
  830. memcpy(f->m.va + f->m.wptr, data, i);
  831. f->m.wptr = size - i;
  832. memcpy(f->m.va, data + i, f->m.wptr);
  833. }
  834. tn40_write_reg(priv, f->m.reg_wptr, f->m.wptr & TN40_TXF_WPTR_WR_PTR);
  835. }
  836. /**
  837. * tn40_tx_push_desc_safe - push descriptor to TxD fifo in a safe way.
  838. *
  839. * @priv: NIC private structure
  840. * @data: descriptor data
  841. * @size: descriptor size
  842. *
  843. * This function does check for available space and, if necessary,
  844. * waits for the NIC to read existing data before writing new data.
  845. */
  846. static void tn40_tx_push_desc_safe(struct tn40_priv *priv, void *data, int size)
  847. {
  848. int timer = 0;
  849. while (size > 0) {
  850. /* We subtract 8 because when the fifo is full rptr ==
  851. * wptr, which also means that fifo is empty, we can
  852. * understand the difference, but could the HW do the
  853. * same ???
  854. */
  855. int avail = tn40_tx_space(priv) - 8;
  856. if (avail <= 0) {
  857. if (timer++ > 300) /* Prevent endless loop */
  858. break;
  859. /* Give the HW a chance to clean the fifo */
  860. usleep_range(50, 60);
  861. continue;
  862. }
  863. avail = min(avail, size);
  864. netdev_dbg(priv->ndev,
  865. "about to push %d bytes starting %p size %d\n",
  866. avail, data, size);
  867. tn40_tx_push_desc(priv, data, avail);
  868. size -= avail;
  869. data += avail;
  870. }
  871. }
  872. int tn40_set_link_speed(struct tn40_priv *priv, u32 speed)
  873. {
  874. u32 val;
  875. int i;
  876. netdev_dbg(priv->ndev, "speed %d\n", speed);
  877. switch (speed) {
  878. case SPEED_10000:
  879. case SPEED_5000:
  880. case SPEED_2500:
  881. netdev_dbg(priv->ndev, "link_speed %d\n", speed);
  882. tn40_write_reg(priv, 0x1010, 0x217); /*ETHSD.REFCLK_CONF */
  883. tn40_write_reg(priv, 0x104c, 0x4c); /*ETHSD.L0_RX_PCNT */
  884. tn40_write_reg(priv, 0x1050, 0x4c); /*ETHSD.L1_RX_PCNT */
  885. tn40_write_reg(priv, 0x1054, 0x4c); /*ETHSD.L2_RX_PCNT */
  886. tn40_write_reg(priv, 0x1058, 0x4c); /*ETHSD.L3_RX_PCNT */
  887. tn40_write_reg(priv, 0x102c, 0x434); /*ETHSD.L0_TX_PCNT */
  888. tn40_write_reg(priv, 0x1030, 0x434); /*ETHSD.L1_TX_PCNT */
  889. tn40_write_reg(priv, 0x1034, 0x434); /*ETHSD.L2_TX_PCNT */
  890. tn40_write_reg(priv, 0x1038, 0x434); /*ETHSD.L3_TX_PCNT */
  891. tn40_write_reg(priv, 0x6300, 0x0400); /*MAC.PCS_CTRL */
  892. tn40_write_reg(priv, 0x1018, 0x00); /*Mike2 */
  893. udelay(5);
  894. tn40_write_reg(priv, 0x1018, 0x04); /*Mike2 */
  895. udelay(5);
  896. tn40_write_reg(priv, 0x1018, 0x06); /*Mike2 */
  897. udelay(5);
  898. /*MikeFix1 */
  899. /*L0: 0x103c , L1: 0x1040 , L2: 0x1044 , L3: 0x1048 =0x81644 */
  900. tn40_write_reg(priv, 0x103c, 0x81644); /*ETHSD.L0_TX_DCNT */
  901. tn40_write_reg(priv, 0x1040, 0x81644); /*ETHSD.L1_TX_DCNT */
  902. tn40_write_reg(priv, 0x1044, 0x81644); /*ETHSD.L2_TX_DCNT */
  903. tn40_write_reg(priv, 0x1048, 0x81644); /*ETHSD.L3_TX_DCNT */
  904. tn40_write_reg(priv, 0x1014, 0x043); /*ETHSD.INIT_STAT */
  905. for (i = 1000; i; i--) {
  906. usleep_range(50, 60);
  907. /*ETHSD.INIT_STAT */
  908. val = tn40_read_reg(priv, 0x1014);
  909. if (val & (1 << 9)) {
  910. /*ETHSD.INIT_STAT */
  911. tn40_write_reg(priv, 0x1014, 0x3);
  912. /*ETHSD.INIT_STAT */
  913. val = tn40_read_reg(priv, 0x1014);
  914. break;
  915. }
  916. }
  917. if (!i)
  918. netdev_err(priv->ndev, "MAC init timeout!\n");
  919. tn40_write_reg(priv, 0x6350, 0x0); /*MAC.PCS_IF_MODE */
  920. tn40_write_reg(priv, TN40_REG_CTRLST, 0xC13); /*0x93//0x13 */
  921. tn40_write_reg(priv, 0x111c, 0x7ff); /*MAC.MAC_RST_CNT */
  922. usleep_range(2000, 2100);
  923. tn40_write_reg(priv, 0x111c, 0x0); /*MAC.MAC_RST_CNT */
  924. break;
  925. case SPEED_1000:
  926. case SPEED_100:
  927. tn40_write_reg(priv, 0x1010, 0x613); /*ETHSD.REFCLK_CONF */
  928. tn40_write_reg(priv, 0x104c, 0x4d); /*ETHSD.L0_RX_PCNT */
  929. tn40_write_reg(priv, 0x1050, 0x0); /*ETHSD.L1_RX_PCNT */
  930. tn40_write_reg(priv, 0x1054, 0x0); /*ETHSD.L2_RX_PCNT */
  931. tn40_write_reg(priv, 0x1058, 0x0); /*ETHSD.L3_RX_PCNT */
  932. tn40_write_reg(priv, 0x102c, 0x35); /*ETHSD.L0_TX_PCNT */
  933. tn40_write_reg(priv, 0x1030, 0x0); /*ETHSD.L1_TX_PCNT */
  934. tn40_write_reg(priv, 0x1034, 0x0); /*ETHSD.L2_TX_PCNT */
  935. tn40_write_reg(priv, 0x1038, 0x0); /*ETHSD.L3_TX_PCNT */
  936. tn40_write_reg(priv, 0x6300, 0x01140); /*MAC.PCS_CTRL */
  937. tn40_write_reg(priv, 0x1014, 0x043); /*ETHSD.INIT_STAT */
  938. for (i = 1000; i; i--) {
  939. usleep_range(50, 60);
  940. val = tn40_read_reg(priv, 0x1014); /*ETHSD.INIT_STAT */
  941. if (val & (1 << 9)) {
  942. /*ETHSD.INIT_STAT */
  943. tn40_write_reg(priv, 0x1014, 0x3);
  944. /*ETHSD.INIT_STAT */
  945. val = tn40_read_reg(priv, 0x1014);
  946. break;
  947. }
  948. }
  949. if (!i)
  950. netdev_err(priv->ndev, "MAC init timeout!\n");
  951. tn40_write_reg(priv, 0x6350, 0x2b); /*MAC.PCS_IF_MODE 1g */
  952. tn40_write_reg(priv, 0x6310, 0x9801); /*MAC.PCS_DEV_AB */
  953. tn40_write_reg(priv, 0x6314, 0x1); /*MAC.PCS_PART_AB */
  954. tn40_write_reg(priv, 0x6348, 0xc8); /*MAC.PCS_LINK_LO */
  955. tn40_write_reg(priv, 0x634c, 0xc8); /*MAC.PCS_LINK_HI */
  956. usleep_range(50, 60);
  957. tn40_write_reg(priv, TN40_REG_CTRLST, 0xC13); /*0x93//0x13 */
  958. tn40_write_reg(priv, 0x111c, 0x7ff); /*MAC.MAC_RST_CNT */
  959. usleep_range(2000, 2100);
  960. tn40_write_reg(priv, 0x111c, 0x0); /*MAC.MAC_RST_CNT */
  961. tn40_write_reg(priv, 0x6300, 0x1140); /*MAC.PCS_CTRL */
  962. break;
  963. case 0: /* Link down */
  964. tn40_write_reg(priv, 0x104c, 0x0); /*ETHSD.L0_RX_PCNT */
  965. tn40_write_reg(priv, 0x1050, 0x0); /*ETHSD.L1_RX_PCNT */
  966. tn40_write_reg(priv, 0x1054, 0x0); /*ETHSD.L2_RX_PCNT */
  967. tn40_write_reg(priv, 0x1058, 0x0); /*ETHSD.L3_RX_PCNT */
  968. tn40_write_reg(priv, 0x102c, 0x0); /*ETHSD.L0_TX_PCNT */
  969. tn40_write_reg(priv, 0x1030, 0x0); /*ETHSD.L1_TX_PCNT */
  970. tn40_write_reg(priv, 0x1034, 0x0); /*ETHSD.L2_TX_PCNT */
  971. tn40_write_reg(priv, 0x1038, 0x0); /*ETHSD.L3_TX_PCNT */
  972. tn40_write_reg(priv, TN40_REG_CTRLST, 0x800);
  973. tn40_write_reg(priv, 0x111c, 0x7ff); /*MAC.MAC_RST_CNT */
  974. usleep_range(2000, 2100);
  975. tn40_write_reg(priv, 0x111c, 0x0); /*MAC.MAC_RST_CNT */
  976. break;
  977. default:
  978. netdev_err(priv->ndev,
  979. "Link speed was not identified yet (%d)\n", speed);
  980. speed = 0;
  981. break;
  982. }
  983. return speed;
  984. }
  985. static void tn40_link_changed(struct tn40_priv *priv)
  986. {
  987. u32 link = tn40_read_reg(priv,
  988. TN40_REG_MAC_LNK_STAT) & TN40_MAC_LINK_STAT;
  989. netdev_dbg(priv->ndev, "link changed %u\n", link);
  990. }
  991. static void tn40_isr_extra(struct tn40_priv *priv, u32 isr)
  992. {
  993. if (isr & (TN40_IR_LNKCHG0 | TN40_IR_LNKCHG1 | TN40_IR_TMR0)) {
  994. netdev_dbg(priv->ndev, "isr = 0x%x\n", isr);
  995. tn40_link_changed(priv);
  996. }
  997. }
  998. static irqreturn_t tn40_isr_napi(int irq, void *dev)
  999. {
  1000. struct tn40_priv *priv = netdev_priv((struct net_device *)dev);
  1001. u32 isr;
  1002. isr = tn40_read_reg(priv, TN40_REG_ISR_MSK0);
  1003. if (unlikely(!isr)) {
  1004. tn40_enable_interrupts(priv);
  1005. return IRQ_NONE; /* Not our interrupt */
  1006. }
  1007. if (isr & TN40_IR_EXTRA)
  1008. tn40_isr_extra(priv, isr);
  1009. if (isr & (TN40_IR_RX_DESC_0 | TN40_IR_TX_FREE_0 | TN40_IR_TMR1)) {
  1010. if (likely(napi_schedule_prep(&priv->napi))) {
  1011. __napi_schedule(&priv->napi);
  1012. return IRQ_HANDLED;
  1013. }
  1014. /* We get here if an interrupt has slept into the
  1015. * small time window between these lines in
  1016. * tn40_poll: tn40_enable_interrupts(priv); return 0;
  1017. *
  1018. * Currently interrupts are disabled (since we read
  1019. * the ISR register) and we have failed to register
  1020. * the next poll. So we read the regs to trigger the
  1021. * chip and allow further interrupts.
  1022. */
  1023. tn40_read_reg(priv, TN40_REG_TXF_WPTR_0);
  1024. tn40_read_reg(priv, TN40_REG_RXD_WPTR_0);
  1025. }
  1026. tn40_enable_interrupts(priv);
  1027. return IRQ_HANDLED;
  1028. }
  1029. static int tn40_poll(struct napi_struct *napi, int budget)
  1030. {
  1031. struct tn40_priv *priv = container_of(napi, struct tn40_priv, napi);
  1032. int work_done;
  1033. tn40_tx_cleanup(priv);
  1034. if (!budget)
  1035. return 0;
  1036. work_done = tn40_rx_receive(priv, budget);
  1037. if (work_done == budget)
  1038. return budget;
  1039. if (napi_complete_done(napi, work_done))
  1040. tn40_enable_interrupts(priv);
  1041. return work_done;
  1042. }
  1043. static int tn40_fw_load(struct tn40_priv *priv)
  1044. {
  1045. const struct firmware *fw = NULL;
  1046. int master, ret;
  1047. u32 val;
  1048. ret = request_firmware(&fw, TN40_FIRMWARE_NAME, &priv->pdev->dev);
  1049. if (ret)
  1050. return ret;
  1051. master = tn40_read_reg(priv, TN40_REG_INIT_SEMAPHORE);
  1052. if (!tn40_read_reg(priv, TN40_REG_INIT_STATUS) && master) {
  1053. netdev_dbg(priv->ndev, "Loading FW...\n");
  1054. tn40_tx_push_desc_safe(priv, (void *)fw->data, fw->size);
  1055. msleep(100);
  1056. }
  1057. ret = read_poll_timeout(tn40_read_reg, val, val, 2000, 400000, false,
  1058. priv, TN40_REG_INIT_STATUS);
  1059. if (master)
  1060. tn40_write_reg(priv, TN40_REG_INIT_SEMAPHORE, 1);
  1061. if (ret) {
  1062. netdev_err(priv->ndev, "firmware loading failed\n");
  1063. netdev_dbg(priv->ndev, "VPC: 0x%x VIC: 0x%x STATUS: 0x%xd\n",
  1064. tn40_read_reg(priv, TN40_REG_VPC),
  1065. tn40_read_reg(priv, TN40_REG_VIC),
  1066. tn40_read_reg(priv, TN40_REG_INIT_STATUS));
  1067. ret = -EIO;
  1068. } else {
  1069. netdev_dbg(priv->ndev, "firmware loading success\n");
  1070. }
  1071. release_firmware(fw);
  1072. return ret;
  1073. }
  1074. static void tn40_restore_mac(struct net_device *ndev, struct tn40_priv *priv)
  1075. {
  1076. u32 val;
  1077. netdev_dbg(priv->ndev, "mac0 =%x mac1 =%x mac2 =%x\n",
  1078. tn40_read_reg(priv, TN40_REG_UNC_MAC0_A),
  1079. tn40_read_reg(priv, TN40_REG_UNC_MAC1_A),
  1080. tn40_read_reg(priv, TN40_REG_UNC_MAC2_A));
  1081. val = (ndev->dev_addr[0] << 8) | (ndev->dev_addr[1]);
  1082. tn40_write_reg(priv, TN40_REG_UNC_MAC2_A, val);
  1083. val = (ndev->dev_addr[2] << 8) | (ndev->dev_addr[3]);
  1084. tn40_write_reg(priv, TN40_REG_UNC_MAC1_A, val);
  1085. val = (ndev->dev_addr[4] << 8) | (ndev->dev_addr[5]);
  1086. tn40_write_reg(priv, TN40_REG_UNC_MAC0_A, val);
  1087. /* More then IP MAC address */
  1088. tn40_write_reg(priv, TN40_REG_MAC_ADDR_0,
  1089. (ndev->dev_addr[3] << 24) | (ndev->dev_addr[2] << 16) |
  1090. (ndev->dev_addr[1] << 8) | (ndev->dev_addr[0]));
  1091. tn40_write_reg(priv, TN40_REG_MAC_ADDR_1,
  1092. (ndev->dev_addr[5] << 8) | (ndev->dev_addr[4]));
  1093. netdev_dbg(priv->ndev, "mac0 =%x mac1 =%x mac2 =%x\n",
  1094. tn40_read_reg(priv, TN40_REG_UNC_MAC0_A),
  1095. tn40_read_reg(priv, TN40_REG_UNC_MAC1_A),
  1096. tn40_read_reg(priv, TN40_REG_UNC_MAC2_A));
  1097. }
  1098. static void tn40_hw_start(struct tn40_priv *priv)
  1099. {
  1100. tn40_write_reg(priv, TN40_REG_FRM_LENGTH, 0X3FE0);
  1101. tn40_write_reg(priv, TN40_REG_GMAC_RXF_A, 0X10fd);
  1102. /*MikeFix1 */
  1103. /*L0: 0x103c , L1: 0x1040 , L2: 0x1044 , L3: 0x1048 =0x81644 */
  1104. tn40_write_reg(priv, 0x103c, 0x81644); /*ETHSD.L0_TX_DCNT */
  1105. tn40_write_reg(priv, 0x1040, 0x81644); /*ETHSD.L1_TX_DCNT */
  1106. tn40_write_reg(priv, 0x1044, 0x81644); /*ETHSD.L2_TX_DCNT */
  1107. tn40_write_reg(priv, 0x1048, 0x81644); /*ETHSD.L3_TX_DCNT */
  1108. tn40_write_reg(priv, TN40_REG_RX_FIFO_SECTION, 0x10);
  1109. tn40_write_reg(priv, TN40_REG_TX_FIFO_SECTION, 0xE00010);
  1110. tn40_write_reg(priv, TN40_REG_RX_FULLNESS, 0);
  1111. tn40_write_reg(priv, TN40_REG_TX_FULLNESS, 0);
  1112. tn40_write_reg(priv, TN40_REG_VGLB, 0);
  1113. tn40_write_reg(priv, TN40_REG_MAX_FRAME_A,
  1114. priv->rxf_fifo0.m.pktsz & TN40_MAX_FRAME_AB_VAL);
  1115. tn40_write_reg(priv, TN40_REG_RDINTCM0, priv->rdintcm);
  1116. tn40_write_reg(priv, TN40_REG_RDINTCM2, 0);
  1117. /* old val = 0x300064 */
  1118. tn40_write_reg(priv, TN40_REG_TDINTCM0, priv->tdintcm);
  1119. /* Enable timer interrupt once in 2 secs. */
  1120. tn40_restore_mac(priv->ndev, priv);
  1121. /* Pause frame */
  1122. tn40_write_reg(priv, 0x12E0, 0x28);
  1123. tn40_write_reg(priv, TN40_REG_PAUSE_QUANT, 0xFFFF);
  1124. tn40_write_reg(priv, 0x6064, 0xF);
  1125. tn40_write_reg(priv, TN40_REG_GMAC_RXF_A,
  1126. TN40_GMAC_RX_FILTER_OSEN | TN40_GMAC_RX_FILTER_TXFC |
  1127. TN40_GMAC_RX_FILTER_AM | TN40_GMAC_RX_FILTER_AB);
  1128. tn40_enable_interrupts(priv);
  1129. }
  1130. static int tn40_hw_reset(struct tn40_priv *priv)
  1131. {
  1132. u32 val;
  1133. /* Reset sequences: read, write 1, read, write 0 */
  1134. val = tn40_read_reg(priv, TN40_REG_CLKPLL);
  1135. tn40_write_reg(priv, TN40_REG_CLKPLL, (val | TN40_CLKPLL_SFTRST) + 0x8);
  1136. usleep_range(50, 60);
  1137. val = tn40_read_reg(priv, TN40_REG_CLKPLL);
  1138. tn40_write_reg(priv, TN40_REG_CLKPLL, val & ~TN40_CLKPLL_SFTRST);
  1139. /* Check that the PLLs are locked and reset ended */
  1140. val = read_poll_timeout(tn40_read_reg, val,
  1141. (val & TN40_CLKPLL_LKD) == TN40_CLKPLL_LKD,
  1142. 10000, 700000, false, priv, TN40_REG_CLKPLL);
  1143. if (val)
  1144. return -EIO;
  1145. usleep_range(50, 60);
  1146. /* Do any PCI-E read transaction */
  1147. tn40_read_reg(priv, TN40_REG_RXD_CFG0_0);
  1148. return 0;
  1149. }
  1150. static void tn40_sw_reset(struct tn40_priv *priv)
  1151. {
  1152. int i, ret;
  1153. u32 val;
  1154. /* 1. load MAC (obsolete) */
  1155. /* 2. disable Rx (and Tx) */
  1156. tn40_write_reg(priv, TN40_REG_GMAC_RXF_A, 0);
  1157. msleep(100);
  1158. /* 3. Disable port */
  1159. tn40_write_reg(priv, TN40_REG_DIS_PORT, 1);
  1160. /* 4. Disable queue */
  1161. tn40_write_reg(priv, TN40_REG_DIS_QU, 1);
  1162. /* 5. Wait until hw is disabled */
  1163. ret = read_poll_timeout(tn40_read_reg, val, val & 1, 10000, 500000,
  1164. false, priv, TN40_REG_RST_PORT);
  1165. if (ret)
  1166. netdev_err(priv->ndev, "SW reset timeout. continuing anyway\n");
  1167. /* 6. Disable interrupts */
  1168. tn40_write_reg(priv, TN40_REG_RDINTCM0, 0);
  1169. tn40_write_reg(priv, TN40_REG_TDINTCM0, 0);
  1170. tn40_write_reg(priv, TN40_REG_IMR, 0);
  1171. tn40_read_reg(priv, TN40_REG_ISR);
  1172. /* 7. Reset queue */
  1173. tn40_write_reg(priv, TN40_REG_RST_QU, 1);
  1174. /* 8. Reset port */
  1175. tn40_write_reg(priv, TN40_REG_RST_PORT, 1);
  1176. /* 9. Zero all read and write pointers */
  1177. for (i = TN40_REG_TXD_WPTR_0; i <= TN40_REG_TXF_RPTR_3; i += 0x10)
  1178. tn40_write_reg(priv, i, 0);
  1179. /* 10. Unset port disable */
  1180. tn40_write_reg(priv, TN40_REG_DIS_PORT, 0);
  1181. /* 11. Unset queue disable */
  1182. tn40_write_reg(priv, TN40_REG_DIS_QU, 0);
  1183. /* 12. Unset queue reset */
  1184. tn40_write_reg(priv, TN40_REG_RST_QU, 0);
  1185. /* 13. Unset port reset */
  1186. tn40_write_reg(priv, TN40_REG_RST_PORT, 0);
  1187. /* 14. Enable Rx */
  1188. /* Skipped. will be done later */
  1189. }
  1190. static int tn40_start(struct tn40_priv *priv)
  1191. {
  1192. int ret;
  1193. ret = tn40_create_tx_ring(priv);
  1194. if (ret) {
  1195. netdev_err(priv->ndev, "failed to tx init %d\n", ret);
  1196. return ret;
  1197. }
  1198. ret = tn40_create_rx_ring(priv);
  1199. if (ret) {
  1200. netdev_err(priv->ndev, "failed to rx init %d\n", ret);
  1201. goto err_tx_ring;
  1202. }
  1203. tn40_rx_alloc_buffers(priv);
  1204. if (tn40_rxdb_available(priv->rxdb0) != 1) {
  1205. ret = -ENOMEM;
  1206. netdev_err(priv->ndev, "failed to allocate rx buffers\n");
  1207. goto err_rx_ring;
  1208. }
  1209. ret = request_irq(priv->pdev->irq, &tn40_isr_napi, IRQF_SHARED,
  1210. priv->ndev->name, priv->ndev);
  1211. if (ret) {
  1212. netdev_err(priv->ndev, "failed to request irq %d\n", ret);
  1213. goto err_rx_ring;
  1214. }
  1215. tn40_hw_start(priv);
  1216. return 0;
  1217. err_rx_ring:
  1218. tn40_destroy_rx_ring(priv);
  1219. err_tx_ring:
  1220. tn40_destroy_tx_ring(priv);
  1221. return ret;
  1222. }
  1223. static void tn40_stop(struct tn40_priv *priv)
  1224. {
  1225. tn40_disable_interrupts(priv);
  1226. free_irq(priv->pdev->irq, priv->ndev);
  1227. tn40_sw_reset(priv);
  1228. tn40_destroy_tx_ring(priv);
  1229. tn40_destroy_rx_ring(priv);
  1230. }
  1231. static int tn40_close(struct net_device *ndev)
  1232. {
  1233. struct tn40_priv *priv = netdev_priv(ndev);
  1234. phylink_stop(priv->phylink);
  1235. phylink_disconnect_phy(priv->phylink);
  1236. napi_disable(&priv->napi);
  1237. netif_napi_del(&priv->napi);
  1238. tn40_stop(priv);
  1239. return 0;
  1240. }
  1241. static int tn40_open(struct net_device *dev)
  1242. {
  1243. struct tn40_priv *priv = netdev_priv(dev);
  1244. int ret;
  1245. ret = phylink_connect_phy(priv->phylink, priv->phydev);
  1246. if (ret) {
  1247. netdev_err(dev, "failed to connect to phy %d\n", ret);
  1248. return ret;
  1249. }
  1250. tn40_sw_reset(priv);
  1251. ret = tn40_start(priv);
  1252. if (ret) {
  1253. phylink_disconnect_phy(priv->phylink);
  1254. netdev_err(dev, "failed to start %d\n", ret);
  1255. return ret;
  1256. }
  1257. napi_enable(&priv->napi);
  1258. phylink_start(priv->phylink);
  1259. netif_start_queue(priv->ndev);
  1260. return 0;
  1261. }
  1262. static void __tn40_vlan_rx_vid(struct net_device *ndev, uint16_t vid,
  1263. int enable)
  1264. {
  1265. struct tn40_priv *priv = netdev_priv(ndev);
  1266. u32 reg, bit, val;
  1267. netdev_dbg(priv->ndev, "vid =%d value =%d\n", (int)vid, enable);
  1268. reg = TN40_REG_VLAN_0 + (vid / 32) * 4;
  1269. bit = 1 << vid % 32;
  1270. val = tn40_read_reg(priv, reg);
  1271. netdev_dbg(priv->ndev, "reg =%x, val =%x, bit =%d\n", reg, val, bit);
  1272. if (enable)
  1273. val |= bit;
  1274. else
  1275. val &= ~bit;
  1276. netdev_dbg(priv->ndev, "new val %x\n", val);
  1277. tn40_write_reg(priv, reg, val);
  1278. }
  1279. static int tn40_vlan_rx_add_vid(struct net_device *ndev,
  1280. __always_unused __be16 proto, u16 vid)
  1281. {
  1282. __tn40_vlan_rx_vid(ndev, vid, 1);
  1283. return 0;
  1284. }
  1285. static int tn40_vlan_rx_kill_vid(struct net_device *ndev,
  1286. __always_unused __be16 proto, u16 vid)
  1287. {
  1288. __tn40_vlan_rx_vid(ndev, vid, 0);
  1289. return 0;
  1290. }
  1291. static void tn40_setmulti(struct net_device *ndev)
  1292. {
  1293. u32 rxf_val = TN40_GMAC_RX_FILTER_AM | TN40_GMAC_RX_FILTER_AB |
  1294. TN40_GMAC_RX_FILTER_OSEN | TN40_GMAC_RX_FILTER_TXFC;
  1295. struct tn40_priv *priv = netdev_priv(ndev);
  1296. int i;
  1297. /* IMF - imperfect (hash) rx multicast filter */
  1298. /* PMF - perfect rx multicast filter */
  1299. /* FIXME: RXE(OFF) */
  1300. if (ndev->flags & IFF_PROMISC) {
  1301. rxf_val |= TN40_GMAC_RX_FILTER_PRM;
  1302. } else if (ndev->flags & IFF_ALLMULTI) {
  1303. /* set IMF to accept all multicast frames */
  1304. for (i = 0; i < TN40_MAC_MCST_HASH_NUM; i++)
  1305. tn40_write_reg(priv,
  1306. TN40_REG_RX_MCST_HASH0 + i * 4, ~0);
  1307. } else if (netdev_mc_count(ndev)) {
  1308. struct netdev_hw_addr *mclist;
  1309. u32 reg, val;
  1310. u8 hash;
  1311. /* Set IMF to deny all multicast frames */
  1312. for (i = 0; i < TN40_MAC_MCST_HASH_NUM; i++)
  1313. tn40_write_reg(priv,
  1314. TN40_REG_RX_MCST_HASH0 + i * 4, 0);
  1315. /* Set PMF to deny all multicast frames */
  1316. for (i = 0; i < TN40_MAC_MCST_NUM; i++) {
  1317. tn40_write_reg(priv,
  1318. TN40_REG_RX_MAC_MCST0 + i * 8, 0);
  1319. tn40_write_reg(priv,
  1320. TN40_REG_RX_MAC_MCST1 + i * 8, 0);
  1321. }
  1322. /* Use PMF to accept first MAC_MCST_NUM (15) addresses */
  1323. /* TBD: Sort the addresses and write them in ascending
  1324. * order into RX_MAC_MCST regs. we skip this phase now
  1325. * and accept ALL multicast frames through IMF. Accept
  1326. * the rest of addresses throw IMF.
  1327. */
  1328. netdev_for_each_mc_addr(mclist, ndev) {
  1329. hash = 0;
  1330. for (i = 0; i < ETH_ALEN; i++)
  1331. hash ^= mclist->addr[i];
  1332. reg = TN40_REG_RX_MCST_HASH0 + ((hash >> 5) << 2);
  1333. val = tn40_read_reg(priv, reg);
  1334. val |= (1 << (hash % 32));
  1335. tn40_write_reg(priv, reg, val);
  1336. }
  1337. } else {
  1338. rxf_val |= TN40_GMAC_RX_FILTER_AB;
  1339. }
  1340. tn40_write_reg(priv, TN40_REG_GMAC_RXF_A, rxf_val);
  1341. /* Enable RX */
  1342. /* FIXME: RXE(ON) */
  1343. }
  1344. static int tn40_set_mac(struct net_device *ndev, void *p)
  1345. {
  1346. struct tn40_priv *priv = netdev_priv(ndev);
  1347. struct sockaddr *addr = p;
  1348. eth_hw_addr_set(ndev, addr->sa_data);
  1349. tn40_restore_mac(ndev, priv);
  1350. return 0;
  1351. }
  1352. static void tn40_mac_init(struct tn40_priv *priv)
  1353. {
  1354. u8 addr[ETH_ALEN];
  1355. u64 val;
  1356. val = (u64)tn40_read_reg(priv, TN40_REG_UNC_MAC0_A);
  1357. val |= (u64)tn40_read_reg(priv, TN40_REG_UNC_MAC1_A) << 16;
  1358. val |= (u64)tn40_read_reg(priv, TN40_REG_UNC_MAC2_A) << 32;
  1359. u64_to_ether_addr(val, addr);
  1360. eth_hw_addr_set(priv->ndev, addr);
  1361. }
  1362. static void tn40_get_stats(struct net_device *ndev,
  1363. struct rtnl_link_stats64 *stats)
  1364. {
  1365. struct tn40_priv *priv = netdev_priv(ndev);
  1366. unsigned int start;
  1367. do {
  1368. start = u64_stats_fetch_begin(&priv->syncp);
  1369. stats->tx_packets = priv->stats.tx_packets;
  1370. stats->tx_bytes = priv->stats.tx_bytes;
  1371. stats->tx_dropped = priv->stats.tx_dropped;
  1372. stats->rx_packets = priv->stats.rx_packets;
  1373. stats->rx_bytes = priv->stats.rx_bytes;
  1374. stats->rx_dropped = priv->stats.rx_dropped;
  1375. stats->rx_errors = priv->stats.rx_errors;
  1376. } while (u64_stats_fetch_retry(&priv->syncp, start));
  1377. }
  1378. static const struct net_device_ops tn40_netdev_ops = {
  1379. .ndo_open = tn40_open,
  1380. .ndo_stop = tn40_close,
  1381. .ndo_start_xmit = tn40_start_xmit,
  1382. .ndo_validate_addr = eth_validate_addr,
  1383. .ndo_set_rx_mode = tn40_setmulti,
  1384. .ndo_get_stats64 = tn40_get_stats,
  1385. .ndo_set_mac_address = tn40_set_mac,
  1386. .ndo_vlan_rx_add_vid = tn40_vlan_rx_add_vid,
  1387. .ndo_vlan_rx_kill_vid = tn40_vlan_rx_kill_vid,
  1388. };
  1389. static int tn40_ethtool_get_link_ksettings(struct net_device *ndev,
  1390. struct ethtool_link_ksettings *cmd)
  1391. {
  1392. struct tn40_priv *priv = netdev_priv(ndev);
  1393. return phylink_ethtool_ksettings_get(priv->phylink, cmd);
  1394. }
  1395. static const struct ethtool_ops tn40_ethtool_ops = {
  1396. .get_link = ethtool_op_get_link,
  1397. .get_link_ksettings = tn40_ethtool_get_link_ksettings,
  1398. };
  1399. static void tn40_get_queue_stats_rx(struct net_device *ndev, int idx,
  1400. struct netdev_queue_stats_rx *stats)
  1401. {
  1402. struct tn40_priv *priv = netdev_priv(ndev);
  1403. unsigned int start;
  1404. do {
  1405. start = u64_stats_fetch_begin(&priv->syncp);
  1406. stats->packets = priv->stats.rx_packets;
  1407. stats->bytes = priv->stats.rx_bytes;
  1408. stats->alloc_fail = priv->alloc_fail;
  1409. } while (u64_stats_fetch_retry(&priv->syncp, start));
  1410. }
  1411. static void tn40_get_queue_stats_tx(struct net_device *ndev, int idx,
  1412. struct netdev_queue_stats_tx *stats)
  1413. {
  1414. struct tn40_priv *priv = netdev_priv(ndev);
  1415. unsigned int start;
  1416. do {
  1417. start = u64_stats_fetch_begin(&priv->syncp);
  1418. stats->packets = priv->stats.tx_packets;
  1419. stats->bytes = priv->stats.tx_bytes;
  1420. } while (u64_stats_fetch_retry(&priv->syncp, start));
  1421. }
  1422. static void tn40_get_base_stats(struct net_device *ndev,
  1423. struct netdev_queue_stats_rx *rx,
  1424. struct netdev_queue_stats_tx *tx)
  1425. {
  1426. rx->packets = 0;
  1427. rx->bytes = 0;
  1428. rx->alloc_fail = 0;
  1429. tx->packets = 0;
  1430. tx->bytes = 0;
  1431. }
  1432. static const struct netdev_stat_ops tn40_stat_ops = {
  1433. .get_queue_stats_rx = tn40_get_queue_stats_rx,
  1434. .get_queue_stats_tx = tn40_get_queue_stats_tx,
  1435. .get_base_stats = tn40_get_base_stats,
  1436. };
  1437. static int tn40_priv_init(struct tn40_priv *priv)
  1438. {
  1439. int ret;
  1440. tn40_set_link_speed(priv, 0);
  1441. /* Set GPIO[9:0] to output 0 */
  1442. tn40_write_reg(priv, 0x51E0, 0x30010006); /* GPIO_OE_ WR CMD */
  1443. tn40_write_reg(priv, 0x51F0, 0x0); /* GPIO_OE_ DATA */
  1444. tn40_write_reg(priv, TN40_REG_MDIO_CMD_STAT, 0x3ec8);
  1445. /* we use tx descriptors to load a firmware. */
  1446. ret = tn40_create_tx_ring(priv);
  1447. if (ret)
  1448. return ret;
  1449. ret = tn40_fw_load(priv);
  1450. tn40_destroy_tx_ring(priv);
  1451. return ret;
  1452. }
  1453. static struct net_device *tn40_netdev_alloc(struct pci_dev *pdev)
  1454. {
  1455. struct net_device *ndev;
  1456. ndev = devm_alloc_etherdev(&pdev->dev, sizeof(struct tn40_priv));
  1457. if (!ndev)
  1458. return NULL;
  1459. ndev->netdev_ops = &tn40_netdev_ops;
  1460. ndev->ethtool_ops = &tn40_ethtool_ops;
  1461. ndev->stat_ops = &tn40_stat_ops;
  1462. ndev->tx_queue_len = TN40_NDEV_TXQ_LEN;
  1463. ndev->mem_start = pci_resource_start(pdev, 0);
  1464. ndev->mem_end = pci_resource_end(pdev, 0);
  1465. ndev->min_mtu = ETH_ZLEN;
  1466. ndev->max_mtu = TN40_MAX_MTU;
  1467. ndev->features = NETIF_F_IP_CSUM |
  1468. NETIF_F_SG |
  1469. NETIF_F_FRAGLIST |
  1470. NETIF_F_TSO | NETIF_F_GRO |
  1471. NETIF_F_RXCSUM |
  1472. NETIF_F_RXHASH |
  1473. NETIF_F_HW_VLAN_CTAG_TX |
  1474. NETIF_F_HW_VLAN_CTAG_RX |
  1475. NETIF_F_HW_VLAN_CTAG_FILTER;
  1476. ndev->vlan_features = NETIF_F_IP_CSUM |
  1477. NETIF_F_SG |
  1478. NETIF_F_TSO | NETIF_F_GRO | NETIF_F_RXHASH;
  1479. if (dma_get_mask(&pdev->dev) == DMA_BIT_MASK(64)) {
  1480. ndev->features |= NETIF_F_HIGHDMA;
  1481. ndev->vlan_features |= NETIF_F_HIGHDMA;
  1482. }
  1483. ndev->hw_features |= ndev->features;
  1484. SET_NETDEV_DEV(ndev, &pdev->dev);
  1485. netif_stop_queue(ndev);
  1486. return ndev;
  1487. }
  1488. static int tn40_probe(struct pci_dev *pdev, const struct pci_device_id *ent)
  1489. {
  1490. struct net_device *ndev;
  1491. struct tn40_priv *priv;
  1492. unsigned int nvec = 1;
  1493. void __iomem *regs;
  1494. int ret;
  1495. ret = pci_enable_device(pdev);
  1496. if (ret)
  1497. return ret;
  1498. ret = dma_set_mask_and_coherent(&pdev->dev, DMA_BIT_MASK(64));
  1499. if (ret) {
  1500. dev_err(&pdev->dev, "failed to set DMA mask.\n");
  1501. goto err_disable_device;
  1502. }
  1503. ret = pci_request_regions(pdev, TN40_DRV_NAME);
  1504. if (ret) {
  1505. dev_err(&pdev->dev, "failed to request PCI regions.\n");
  1506. goto err_disable_device;
  1507. }
  1508. pci_set_master(pdev);
  1509. regs = pci_iomap(pdev, 0, TN40_REGS_SIZE);
  1510. if (!regs) {
  1511. ret = -EIO;
  1512. dev_err(&pdev->dev, "failed to map PCI bar.\n");
  1513. goto err_free_regions;
  1514. }
  1515. ndev = tn40_netdev_alloc(pdev);
  1516. if (!ndev) {
  1517. ret = -ENOMEM;
  1518. dev_err(&pdev->dev, "failed to allocate netdev.\n");
  1519. goto err_iounmap;
  1520. }
  1521. priv = netdev_priv(ndev);
  1522. pci_set_drvdata(pdev, priv);
  1523. netif_napi_add(ndev, &priv->napi, tn40_poll);
  1524. priv->regs = regs;
  1525. priv->pdev = pdev;
  1526. priv->ndev = ndev;
  1527. /* Initialize fifo sizes. */
  1528. priv->txd_size = 3;
  1529. priv->txf_size = 3;
  1530. priv->rxd_size = 3;
  1531. priv->rxf_size = 3;
  1532. /* Initialize the initial coalescing registers. */
  1533. priv->rdintcm = TN40_INT_REG_VAL(0x20, 1, 4, 12);
  1534. priv->tdintcm = TN40_INT_REG_VAL(0x20, 1, 0, 12);
  1535. ret = tn40_hw_reset(priv);
  1536. if (ret) {
  1537. dev_err(&pdev->dev, "failed to reset HW.\n");
  1538. goto err_unset_drvdata;
  1539. }
  1540. ret = pci_alloc_irq_vectors(pdev, 1, nvec, PCI_IRQ_MSI);
  1541. if (ret < 0) {
  1542. dev_err(&pdev->dev, "failed to allocate irq.\n");
  1543. goto err_unset_drvdata;
  1544. }
  1545. ret = tn40_mdiobus_init(priv);
  1546. if (ret) {
  1547. dev_err(&pdev->dev, "failed to initialize mdio bus.\n");
  1548. goto err_free_irq;
  1549. }
  1550. priv->stats_flag =
  1551. ((tn40_read_reg(priv, TN40_FPGA_VER) & 0xFFF) != 308);
  1552. u64_stats_init(&priv->syncp);
  1553. priv->isr_mask = TN40_IR_RX_FREE_0 | TN40_IR_LNKCHG0 | TN40_IR_PSE |
  1554. TN40_IR_TMR0 | TN40_IR_RX_DESC_0 | TN40_IR_TX_FREE_0 |
  1555. TN40_IR_TMR1;
  1556. tn40_mac_init(priv);
  1557. ret = tn40_phy_register(priv);
  1558. if (ret) {
  1559. dev_err(&pdev->dev, "failed to set up PHY.\n");
  1560. goto err_cleanup_swnodes;
  1561. }
  1562. ret = tn40_priv_init(priv);
  1563. if (ret) {
  1564. dev_err(&pdev->dev, "failed to initialize tn40_priv.\n");
  1565. goto err_unregister_phydev;
  1566. }
  1567. ret = register_netdev(ndev);
  1568. if (ret) {
  1569. dev_err(&pdev->dev, "failed to register netdev.\n");
  1570. goto err_unregister_phydev;
  1571. }
  1572. return 0;
  1573. err_unregister_phydev:
  1574. tn40_phy_unregister(priv);
  1575. err_cleanup_swnodes:
  1576. tn40_swnodes_cleanup(priv);
  1577. err_free_irq:
  1578. pci_free_irq_vectors(pdev);
  1579. err_unset_drvdata:
  1580. pci_set_drvdata(pdev, NULL);
  1581. err_iounmap:
  1582. iounmap(regs);
  1583. err_free_regions:
  1584. pci_release_regions(pdev);
  1585. err_disable_device:
  1586. pci_disable_device(pdev);
  1587. return ret;
  1588. }
  1589. static void tn40_remove(struct pci_dev *pdev)
  1590. {
  1591. struct tn40_priv *priv = pci_get_drvdata(pdev);
  1592. struct net_device *ndev = priv->ndev;
  1593. unregister_netdev(ndev);
  1594. tn40_phy_unregister(priv);
  1595. tn40_swnodes_cleanup(priv);
  1596. pci_free_irq_vectors(priv->pdev);
  1597. pci_set_drvdata(pdev, NULL);
  1598. iounmap(priv->regs);
  1599. pci_release_regions(pdev);
  1600. pci_disable_device(pdev);
  1601. }
  1602. static const struct pci_device_id tn40_id_table[] = {
  1603. { PCI_DEVICE_SUB(PCI_VENDOR_ID_TEHUTI, 0x4022,
  1604. PCI_VENDOR_ID_TEHUTI, 0x3015) },
  1605. { PCI_DEVICE_SUB(PCI_VENDOR_ID_TEHUTI, 0x4022,
  1606. PCI_VENDOR_ID_DLINK, 0x4d00) },
  1607. { PCI_DEVICE_SUB(PCI_VENDOR_ID_TEHUTI, 0x4022,
  1608. PCI_VENDOR_ID_ASUSTEK, 0x8709) },
  1609. { PCI_DEVICE_SUB(PCI_VENDOR_ID_TEHUTI, 0x4022,
  1610. PCI_VENDOR_ID_EDIMAX, 0x8103) },
  1611. { PCI_DEVICE_SUB(PCI_VENDOR_ID_TEHUTI, PCI_DEVICE_ID_TEHUTI_TN9510,
  1612. PCI_VENDOR_ID_TEHUTI, 0x3015) },
  1613. { PCI_DEVICE_SUB(PCI_VENDOR_ID_TEHUTI, PCI_DEVICE_ID_TEHUTI_TN9510,
  1614. PCI_VENDOR_ID_EDIMAX, 0x8102) },
  1615. { }
  1616. };
  1617. static struct pci_driver tn40_driver = {
  1618. .name = TN40_DRV_NAME,
  1619. .id_table = tn40_id_table,
  1620. .probe = tn40_probe,
  1621. .remove = tn40_remove,
  1622. };
  1623. module_pci_driver(tn40_driver);
  1624. MODULE_DEVICE_TABLE(pci, tn40_id_table);
  1625. MODULE_LICENSE("GPL");
  1626. MODULE_FIRMWARE(TN40_FIRMWARE_NAME);
  1627. MODULE_DESCRIPTION("Tehuti Network TN40xx Driver");