ax88179_178a.c 49 KB

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  1. // SPDX-License-Identifier: GPL-2.0-or-later
  2. /*
  3. * ASIX AX88179/178A USB 3.0/2.0 to Gigabit Ethernet Devices
  4. *
  5. * Copyright (C) 2011-2013 ASIX
  6. */
  7. #include <linux/module.h>
  8. #include <linux/etherdevice.h>
  9. #include <linux/mii.h>
  10. #include <linux/usb.h>
  11. #include <linux/crc32.h>
  12. #include <linux/usb/usbnet.h>
  13. #include <uapi/linux/mdio.h>
  14. #include <linux/mdio.h>
  15. #define AX88179_PHY_ID 0x03
  16. #define AX_EEPROM_LEN 0x100
  17. #define AX88179_EEPROM_MAGIC 0x17900b95
  18. #define AX_MCAST_FLTSIZE 8
  19. #define AX_MAX_MCAST 64
  20. #define AX_INT_PPLS_LINK ((u32)BIT(16))
  21. #define AX_RXHDR_L4_TYPE_MASK 0x1c
  22. #define AX_RXHDR_L4_TYPE_UDP 4
  23. #define AX_RXHDR_L4_TYPE_TCP 16
  24. #define AX_RXHDR_L3CSUM_ERR 2
  25. #define AX_RXHDR_L4CSUM_ERR 1
  26. #define AX_RXHDR_CRC_ERR ((u32)BIT(29))
  27. #define AX_RXHDR_DROP_ERR ((u32)BIT(31))
  28. #define AX_ACCESS_MAC 0x01
  29. #define AX_ACCESS_PHY 0x02
  30. #define AX_ACCESS_EEPROM 0x04
  31. #define AX_ACCESS_EFUS 0x05
  32. #define AX_RELOAD_EEPROM_EFUSE 0x06
  33. #define AX_PAUSE_WATERLVL_HIGH 0x54
  34. #define AX_PAUSE_WATERLVL_LOW 0x55
  35. #define PHYSICAL_LINK_STATUS 0x02
  36. #define AX_USB_SS 0x04
  37. #define AX_USB_HS 0x02
  38. #define GENERAL_STATUS 0x03
  39. /* Check AX88179 version. UA1:Bit2 = 0, UA2:Bit2 = 1 */
  40. #define AX_SECLD 0x04
  41. #define AX_SROM_ADDR 0x07
  42. #define AX_SROM_CMD 0x0a
  43. #define EEP_RD 0x04
  44. #define EEP_BUSY 0x10
  45. #define AX_SROM_DATA_LOW 0x08
  46. #define AX_SROM_DATA_HIGH 0x09
  47. #define AX_RX_CTL 0x0b
  48. #define AX_RX_CTL_DROPCRCERR 0x0100
  49. #define AX_RX_CTL_IPE 0x0200
  50. #define AX_RX_CTL_START 0x0080
  51. #define AX_RX_CTL_AP 0x0020
  52. #define AX_RX_CTL_AM 0x0010
  53. #define AX_RX_CTL_AB 0x0008
  54. #define AX_RX_CTL_AMALL 0x0002
  55. #define AX_RX_CTL_PRO 0x0001
  56. #define AX_RX_CTL_STOP 0x0000
  57. #define AX_NODE_ID 0x10
  58. #define AX_MULFLTARY 0x16
  59. #define AX_MEDIUM_STATUS_MODE 0x22
  60. #define AX_MEDIUM_GIGAMODE 0x01
  61. #define AX_MEDIUM_FULL_DUPLEX 0x02
  62. #define AX_MEDIUM_EN_125MHZ 0x08
  63. #define AX_MEDIUM_RXFLOW_CTRLEN 0x10
  64. #define AX_MEDIUM_TXFLOW_CTRLEN 0x20
  65. #define AX_MEDIUM_RECEIVE_EN 0x100
  66. #define AX_MEDIUM_PS 0x200
  67. #define AX_MEDIUM_JUMBO_EN 0x8040
  68. #define AX_MONITOR_MOD 0x24
  69. #define AX_MONITOR_MODE_RWLC 0x02
  70. #define AX_MONITOR_MODE_RWMP 0x04
  71. #define AX_MONITOR_MODE_PMEPOL 0x20
  72. #define AX_MONITOR_MODE_PMETYPE 0x40
  73. #define AX_GPIO_CTRL 0x25
  74. #define AX_GPIO_CTRL_GPIO3EN 0x80
  75. #define AX_GPIO_CTRL_GPIO2EN 0x40
  76. #define AX_GPIO_CTRL_GPIO1EN 0x20
  77. #define AX_PHYPWR_RSTCTL 0x26
  78. #define AX_PHYPWR_RSTCTL_BZ 0x0010
  79. #define AX_PHYPWR_RSTCTL_IPRL 0x0020
  80. #define AX_PHYPWR_RSTCTL_AT 0x1000
  81. #define AX_RX_BULKIN_QCTRL 0x2e
  82. #define AX_CLK_SELECT 0x33
  83. #define AX_CLK_SELECT_BCS 0x01
  84. #define AX_CLK_SELECT_ACS 0x02
  85. #define AX_CLK_SELECT_ULR 0x08
  86. #define AX_RXCOE_CTL 0x34
  87. #define AX_RXCOE_IP 0x01
  88. #define AX_RXCOE_TCP 0x02
  89. #define AX_RXCOE_UDP 0x04
  90. #define AX_RXCOE_TCPV6 0x20
  91. #define AX_RXCOE_UDPV6 0x40
  92. #define AX_TXCOE_CTL 0x35
  93. #define AX_TXCOE_IP 0x01
  94. #define AX_TXCOE_TCP 0x02
  95. #define AX_TXCOE_UDP 0x04
  96. #define AX_TXCOE_TCPV6 0x20
  97. #define AX_TXCOE_UDPV6 0x40
  98. #define AX_LEDCTRL 0x73
  99. #define GMII_PHY_PHYSR 0x11
  100. #define GMII_PHY_PHYSR_SMASK 0xc000
  101. #define GMII_PHY_PHYSR_GIGA 0x8000
  102. #define GMII_PHY_PHYSR_100 0x4000
  103. #define GMII_PHY_PHYSR_FULL 0x2000
  104. #define GMII_PHY_PHYSR_LINK 0x400
  105. #define GMII_LED_ACT 0x1a
  106. #define GMII_LED_ACTIVE_MASK 0xff8f
  107. #define GMII_LED0_ACTIVE BIT(4)
  108. #define GMII_LED1_ACTIVE BIT(5)
  109. #define GMII_LED2_ACTIVE BIT(6)
  110. #define GMII_LED_LINK 0x1c
  111. #define GMII_LED_LINK_MASK 0xf888
  112. #define GMII_LED0_LINK_10 BIT(0)
  113. #define GMII_LED0_LINK_100 BIT(1)
  114. #define GMII_LED0_LINK_1000 BIT(2)
  115. #define GMII_LED1_LINK_10 BIT(4)
  116. #define GMII_LED1_LINK_100 BIT(5)
  117. #define GMII_LED1_LINK_1000 BIT(6)
  118. #define GMII_LED2_LINK_10 BIT(8)
  119. #define GMII_LED2_LINK_100 BIT(9)
  120. #define GMII_LED2_LINK_1000 BIT(10)
  121. #define LED0_ACTIVE BIT(0)
  122. #define LED0_LINK_10 BIT(1)
  123. #define LED0_LINK_100 BIT(2)
  124. #define LED0_LINK_1000 BIT(3)
  125. #define LED0_FD BIT(4)
  126. #define LED0_USB3_MASK 0x001f
  127. #define LED1_ACTIVE BIT(5)
  128. #define LED1_LINK_10 BIT(6)
  129. #define LED1_LINK_100 BIT(7)
  130. #define LED1_LINK_1000 BIT(8)
  131. #define LED1_FD BIT(9)
  132. #define LED1_USB3_MASK 0x03e0
  133. #define LED2_ACTIVE BIT(10)
  134. #define LED2_LINK_1000 BIT(13)
  135. #define LED2_LINK_100 BIT(12)
  136. #define LED2_LINK_10 BIT(11)
  137. #define LED2_FD BIT(14)
  138. #define LED_VALID BIT(15)
  139. #define LED2_USB3_MASK 0x7c00
  140. #define GMII_PHYPAGE 0x1e
  141. #define GMII_PHY_PAGE_SELECT 0x1f
  142. #define GMII_PHY_PGSEL_EXT 0x0007
  143. #define GMII_PHY_PGSEL_PAGE0 0x0000
  144. #define GMII_PHY_PGSEL_PAGE3 0x0003
  145. #define GMII_PHY_PGSEL_PAGE5 0x0005
  146. static int ax88179_reset(struct usbnet *dev);
  147. struct ax88179_data {
  148. u8 eee_enabled;
  149. u8 eee_active;
  150. u16 rxctl;
  151. u8 in_pm;
  152. u32 wol_supported;
  153. u32 wolopts;
  154. u8 disconnecting;
  155. };
  156. struct ax88179_int_data {
  157. __le32 intdata1;
  158. __le32 intdata2;
  159. };
  160. static const struct {
  161. unsigned char ctrl, timer_l, timer_h, size, ifg;
  162. } AX88179_BULKIN_SIZE[] = {
  163. {7, 0x4f, 0, 0x12, 0xff},
  164. {7, 0x20, 3, 0x16, 0xff},
  165. {7, 0xae, 7, 0x18, 0xff},
  166. {7, 0xcc, 0x4c, 0x18, 8},
  167. };
  168. static void ax88179_set_pm_mode(struct usbnet *dev, bool pm_mode)
  169. {
  170. struct ax88179_data *ax179_data = dev->driver_priv;
  171. ax179_data->in_pm = pm_mode;
  172. }
  173. static int ax88179_in_pm(struct usbnet *dev)
  174. {
  175. struct ax88179_data *ax179_data = dev->driver_priv;
  176. return ax179_data->in_pm;
  177. }
  178. static int __ax88179_read_cmd(struct usbnet *dev, u8 cmd, u16 value, u16 index,
  179. u16 size, void *data)
  180. {
  181. int ret;
  182. int (*fn)(struct usbnet *, u8, u8, u16, u16, void *, u16);
  183. struct ax88179_data *ax179_data = dev->driver_priv;
  184. BUG_ON(!dev);
  185. if (!ax88179_in_pm(dev))
  186. fn = usbnet_read_cmd;
  187. else
  188. fn = usbnet_read_cmd_nopm;
  189. ret = fn(dev, cmd, USB_DIR_IN | USB_TYPE_VENDOR | USB_RECIP_DEVICE,
  190. value, index, data, size);
  191. if (unlikely((ret < 0) && !(ret == -ENODEV && ax179_data->disconnecting)))
  192. netdev_warn(dev->net, "Failed to read reg index 0x%04x: %d\n",
  193. index, ret);
  194. return ret;
  195. }
  196. static int __ax88179_write_cmd(struct usbnet *dev, u8 cmd, u16 value, u16 index,
  197. u16 size, const void *data)
  198. {
  199. int ret;
  200. int (*fn)(struct usbnet *, u8, u8, u16, u16, const void *, u16);
  201. struct ax88179_data *ax179_data = dev->driver_priv;
  202. BUG_ON(!dev);
  203. if (!ax88179_in_pm(dev))
  204. fn = usbnet_write_cmd;
  205. else
  206. fn = usbnet_write_cmd_nopm;
  207. ret = fn(dev, cmd, USB_DIR_OUT | USB_TYPE_VENDOR | USB_RECIP_DEVICE,
  208. value, index, data, size);
  209. if (unlikely((ret < 0) && !(ret == -ENODEV && ax179_data->disconnecting)))
  210. netdev_warn(dev->net, "Failed to write reg index 0x%04x: %d\n",
  211. index, ret);
  212. return ret;
  213. }
  214. static void ax88179_write_cmd_async(struct usbnet *dev, u8 cmd, u16 value,
  215. u16 index, u16 size, void *data)
  216. {
  217. u16 buf;
  218. if (2 == size) {
  219. buf = *((u16 *)data);
  220. cpu_to_le16s(&buf);
  221. usbnet_write_cmd_async(dev, cmd, USB_DIR_OUT | USB_TYPE_VENDOR |
  222. USB_RECIP_DEVICE, value, index, &buf,
  223. size);
  224. } else {
  225. usbnet_write_cmd_async(dev, cmd, USB_DIR_OUT | USB_TYPE_VENDOR |
  226. USB_RECIP_DEVICE, value, index, data,
  227. size);
  228. }
  229. }
  230. static int ax88179_read_cmd(struct usbnet *dev, u8 cmd, u16 value, u16 index,
  231. u16 size, void *data)
  232. {
  233. int ret;
  234. if (2 == size) {
  235. u16 buf = 0;
  236. ret = __ax88179_read_cmd(dev, cmd, value, index, size, &buf);
  237. le16_to_cpus(&buf);
  238. *((u16 *)data) = buf;
  239. } else if (4 == size) {
  240. u32 buf = 0;
  241. ret = __ax88179_read_cmd(dev, cmd, value, index, size, &buf);
  242. le32_to_cpus(&buf);
  243. *((u32 *)data) = buf;
  244. } else {
  245. ret = __ax88179_read_cmd(dev, cmd, value, index, size, data);
  246. }
  247. return ret;
  248. }
  249. static int ax88179_write_cmd(struct usbnet *dev, u8 cmd, u16 value, u16 index,
  250. u16 size, const void *data)
  251. {
  252. int ret;
  253. if (2 == size) {
  254. u16 buf;
  255. buf = *((u16 *)data);
  256. cpu_to_le16s(&buf);
  257. ret = __ax88179_write_cmd(dev, cmd, value, index,
  258. size, &buf);
  259. } else {
  260. ret = __ax88179_write_cmd(dev, cmd, value, index,
  261. size, data);
  262. }
  263. return ret;
  264. }
  265. static void ax88179_status(struct usbnet *dev, struct urb *urb)
  266. {
  267. struct ax88179_int_data *event;
  268. u32 link;
  269. if (urb->actual_length < 8)
  270. return;
  271. event = urb->transfer_buffer;
  272. le32_to_cpus((void *)&event->intdata1);
  273. link = (((__force u32)event->intdata1) & AX_INT_PPLS_LINK) >> 16;
  274. if (netif_carrier_ok(dev->net) != link) {
  275. usbnet_link_change(dev, link, 1);
  276. if (!link)
  277. netdev_info(dev->net, "ax88179 - Link status is: 0\n");
  278. }
  279. }
  280. static int ax88179_mdio_read(struct net_device *netdev, int phy_id, int loc)
  281. {
  282. struct usbnet *dev = netdev_priv(netdev);
  283. u16 res;
  284. ax88179_read_cmd(dev, AX_ACCESS_PHY, phy_id, (__u16)loc, 2, &res);
  285. return res;
  286. }
  287. static void ax88179_mdio_write(struct net_device *netdev, int phy_id, int loc,
  288. int val)
  289. {
  290. struct usbnet *dev = netdev_priv(netdev);
  291. u16 res = (u16) val;
  292. ax88179_write_cmd(dev, AX_ACCESS_PHY, phy_id, (__u16)loc, 2, &res);
  293. }
  294. static inline int ax88179_phy_mmd_indirect(struct usbnet *dev, u16 prtad,
  295. u16 devad)
  296. {
  297. u16 tmp16;
  298. int ret;
  299. tmp16 = devad;
  300. ret = ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  301. MII_MMD_CTRL, 2, &tmp16);
  302. tmp16 = prtad;
  303. ret = ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  304. MII_MMD_DATA, 2, &tmp16);
  305. tmp16 = devad | MII_MMD_CTRL_NOINCR;
  306. ret = ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  307. MII_MMD_CTRL, 2, &tmp16);
  308. return ret;
  309. }
  310. static int
  311. ax88179_phy_read_mmd_indirect(struct usbnet *dev, u16 prtad, u16 devad)
  312. {
  313. int ret;
  314. u16 tmp16;
  315. ax88179_phy_mmd_indirect(dev, prtad, devad);
  316. ret = ax88179_read_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  317. MII_MMD_DATA, 2, &tmp16);
  318. if (ret < 0)
  319. return ret;
  320. return tmp16;
  321. }
  322. static int
  323. ax88179_phy_write_mmd_indirect(struct usbnet *dev, u16 prtad, u16 devad,
  324. u16 data)
  325. {
  326. int ret;
  327. ax88179_phy_mmd_indirect(dev, prtad, devad);
  328. ret = ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  329. MII_MMD_DATA, 2, &data);
  330. if (ret < 0)
  331. return ret;
  332. return 0;
  333. }
  334. static int ax88179_suspend(struct usb_interface *intf, pm_message_t message)
  335. {
  336. struct usbnet *dev = usb_get_intfdata(intf);
  337. struct ax88179_data *priv = dev->driver_priv;
  338. u16 tmp16;
  339. u8 tmp8;
  340. ax88179_set_pm_mode(dev, true);
  341. usbnet_suspend(intf, message);
  342. /* Enable WoL */
  343. if (priv->wolopts) {
  344. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_MONITOR_MOD,
  345. 1, 1, &tmp8);
  346. if (priv->wolopts & WAKE_PHY)
  347. tmp8 |= AX_MONITOR_MODE_RWLC;
  348. if (priv->wolopts & WAKE_MAGIC)
  349. tmp8 |= AX_MONITOR_MODE_RWMP;
  350. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_MONITOR_MOD,
  351. 1, 1, &tmp8);
  352. }
  353. /* Disable RX path */
  354. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  355. 2, 2, &tmp16);
  356. tmp16 &= ~AX_MEDIUM_RECEIVE_EN;
  357. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  358. 2, 2, &tmp16);
  359. /* Force bulk-in zero length */
  360. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_PHYPWR_RSTCTL,
  361. 2, 2, &tmp16);
  362. tmp16 |= AX_PHYPWR_RSTCTL_BZ | AX_PHYPWR_RSTCTL_IPRL;
  363. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_PHYPWR_RSTCTL,
  364. 2, 2, &tmp16);
  365. /* change clock */
  366. tmp8 = 0;
  367. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_CLK_SELECT, 1, 1, &tmp8);
  368. /* Configure RX control register => stop operation */
  369. tmp16 = AX_RX_CTL_STOP;
  370. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_RX_CTL, 2, 2, &tmp16);
  371. ax88179_set_pm_mode(dev, false);
  372. return 0;
  373. }
  374. /* This function is used to enable the autodetach function. */
  375. /* This function is determined by offset 0x43 of EEPROM */
  376. static int ax88179_auto_detach(struct usbnet *dev)
  377. {
  378. u16 tmp16;
  379. u8 tmp8;
  380. if (ax88179_read_cmd(dev, AX_ACCESS_EEPROM, 0x43, 1, 2, &tmp16) < 0)
  381. return 0;
  382. if ((tmp16 == 0xFFFF) || (!(tmp16 & 0x0100)))
  383. return 0;
  384. /* Enable Auto Detach bit */
  385. tmp8 = 0;
  386. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_CLK_SELECT, 1, 1, &tmp8);
  387. tmp8 |= AX_CLK_SELECT_ULR;
  388. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_CLK_SELECT, 1, 1, &tmp8);
  389. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_PHYPWR_RSTCTL, 2, 2, &tmp16);
  390. tmp16 |= AX_PHYPWR_RSTCTL_AT;
  391. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_PHYPWR_RSTCTL, 2, 2, &tmp16);
  392. return 0;
  393. }
  394. static int ax88179_resume(struct usb_interface *intf)
  395. {
  396. struct usbnet *dev = usb_get_intfdata(intf);
  397. ax88179_set_pm_mode(dev, true);
  398. usbnet_link_change(dev, 0, 0);
  399. ax88179_reset(dev);
  400. ax88179_set_pm_mode(dev, false);
  401. return usbnet_resume(intf);
  402. }
  403. static void ax88179_disconnect(struct usb_interface *intf)
  404. {
  405. struct usbnet *dev = usb_get_intfdata(intf);
  406. struct ax88179_data *ax179_data;
  407. if (!dev)
  408. return;
  409. ax179_data = dev->driver_priv;
  410. ax179_data->disconnecting = 1;
  411. usbnet_disconnect(intf);
  412. }
  413. static void
  414. ax88179_get_wol(struct net_device *net, struct ethtool_wolinfo *wolinfo)
  415. {
  416. struct usbnet *dev = netdev_priv(net);
  417. struct ax88179_data *priv = dev->driver_priv;
  418. wolinfo->supported = priv->wol_supported;
  419. wolinfo->wolopts = priv->wolopts;
  420. }
  421. static int
  422. ax88179_set_wol(struct net_device *net, struct ethtool_wolinfo *wolinfo)
  423. {
  424. struct usbnet *dev = netdev_priv(net);
  425. struct ax88179_data *priv = dev->driver_priv;
  426. if (wolinfo->wolopts & ~(priv->wol_supported))
  427. return -EINVAL;
  428. priv->wolopts = wolinfo->wolopts;
  429. return 0;
  430. }
  431. static int ax88179_get_eeprom_len(struct net_device *net)
  432. {
  433. return AX_EEPROM_LEN;
  434. }
  435. static int
  436. ax88179_get_eeprom(struct net_device *net, struct ethtool_eeprom *eeprom,
  437. u8 *data)
  438. {
  439. struct usbnet *dev = netdev_priv(net);
  440. u16 *eeprom_buff;
  441. int first_word, last_word;
  442. int i, ret;
  443. if (eeprom->len == 0)
  444. return -EINVAL;
  445. eeprom->magic = AX88179_EEPROM_MAGIC;
  446. first_word = eeprom->offset >> 1;
  447. last_word = (eeprom->offset + eeprom->len - 1) >> 1;
  448. eeprom_buff = kmalloc_array(last_word - first_word + 1, sizeof(u16),
  449. GFP_KERNEL);
  450. if (!eeprom_buff)
  451. return -ENOMEM;
  452. /* ax88179/178A returns 2 bytes from eeprom on read */
  453. for (i = first_word; i <= last_word; i++) {
  454. ret = __ax88179_read_cmd(dev, AX_ACCESS_EEPROM, i, 1, 2,
  455. &eeprom_buff[i - first_word]);
  456. if (ret < 0) {
  457. kfree(eeprom_buff);
  458. return -EIO;
  459. }
  460. }
  461. memcpy(data, (u8 *)eeprom_buff + (eeprom->offset & 1), eeprom->len);
  462. kfree(eeprom_buff);
  463. return 0;
  464. }
  465. static int
  466. ax88179_set_eeprom(struct net_device *net, struct ethtool_eeprom *eeprom,
  467. u8 *data)
  468. {
  469. struct usbnet *dev = netdev_priv(net);
  470. u16 *eeprom_buff;
  471. int first_word;
  472. int last_word;
  473. int ret;
  474. int i;
  475. netdev_dbg(net, "write EEPROM len %d, offset %d, magic 0x%x\n",
  476. eeprom->len, eeprom->offset, eeprom->magic);
  477. if (eeprom->len == 0)
  478. return -EINVAL;
  479. if (eeprom->magic != AX88179_EEPROM_MAGIC)
  480. return -EINVAL;
  481. first_word = eeprom->offset >> 1;
  482. last_word = (eeprom->offset + eeprom->len - 1) >> 1;
  483. eeprom_buff = kmalloc_array(last_word - first_word + 1, sizeof(u16),
  484. GFP_KERNEL);
  485. if (!eeprom_buff)
  486. return -ENOMEM;
  487. /* align data to 16 bit boundaries, read the missing data from
  488. the EEPROM */
  489. if (eeprom->offset & 1) {
  490. ret = ax88179_read_cmd(dev, AX_ACCESS_EEPROM, first_word, 1, 2,
  491. &eeprom_buff[0]);
  492. if (ret < 0) {
  493. netdev_err(net, "Failed to read EEPROM at offset 0x%02x.\n", first_word);
  494. goto free;
  495. }
  496. }
  497. if ((eeprom->offset + eeprom->len) & 1) {
  498. ret = ax88179_read_cmd(dev, AX_ACCESS_EEPROM, last_word, 1, 2,
  499. &eeprom_buff[last_word - first_word]);
  500. if (ret < 0) {
  501. netdev_err(net, "Failed to read EEPROM at offset 0x%02x.\n", last_word);
  502. goto free;
  503. }
  504. }
  505. memcpy((u8 *)eeprom_buff + (eeprom->offset & 1), data, eeprom->len);
  506. for (i = first_word; i <= last_word; i++) {
  507. netdev_dbg(net, "write to EEPROM at offset 0x%02x, data 0x%04x\n",
  508. i, eeprom_buff[i - first_word]);
  509. ret = ax88179_write_cmd(dev, AX_ACCESS_EEPROM, i, 1, 2,
  510. &eeprom_buff[i - first_word]);
  511. if (ret < 0) {
  512. netdev_err(net, "Failed to write EEPROM at offset 0x%02x.\n", i);
  513. goto free;
  514. }
  515. msleep(20);
  516. }
  517. /* reload EEPROM data */
  518. ret = ax88179_write_cmd(dev, AX_RELOAD_EEPROM_EFUSE, 0x0000, 0, 0, NULL);
  519. if (ret < 0) {
  520. netdev_err(net, "Failed to reload EEPROM data\n");
  521. goto free;
  522. }
  523. ret = 0;
  524. free:
  525. kfree(eeprom_buff);
  526. return ret;
  527. }
  528. static int ax88179_get_link_ksettings(struct net_device *net,
  529. struct ethtool_link_ksettings *cmd)
  530. {
  531. struct usbnet *dev = netdev_priv(net);
  532. mii_ethtool_get_link_ksettings(&dev->mii, cmd);
  533. return 0;
  534. }
  535. static int ax88179_set_link_ksettings(struct net_device *net,
  536. const struct ethtool_link_ksettings *cmd)
  537. {
  538. struct usbnet *dev = netdev_priv(net);
  539. return mii_ethtool_set_link_ksettings(&dev->mii, cmd);
  540. }
  541. static int
  542. ax88179_ethtool_get_eee(struct usbnet *dev, struct ethtool_keee *data)
  543. {
  544. int val;
  545. /* Get Supported EEE */
  546. val = ax88179_phy_read_mmd_indirect(dev, MDIO_PCS_EEE_ABLE,
  547. MDIO_MMD_PCS);
  548. if (val < 0)
  549. return val;
  550. mii_eee_cap1_mod_linkmode_t(data->supported, val);
  551. /* Get advertisement EEE */
  552. val = ax88179_phy_read_mmd_indirect(dev, MDIO_AN_EEE_ADV,
  553. MDIO_MMD_AN);
  554. if (val < 0)
  555. return val;
  556. mii_eee_cap1_mod_linkmode_t(data->advertised, val);
  557. /* Get LP advertisement EEE */
  558. val = ax88179_phy_read_mmd_indirect(dev, MDIO_AN_EEE_LPABLE,
  559. MDIO_MMD_AN);
  560. if (val < 0)
  561. return val;
  562. mii_eee_cap1_mod_linkmode_t(data->lp_advertised, val);
  563. return 0;
  564. }
  565. static int
  566. ax88179_ethtool_set_eee(struct usbnet *dev, struct ethtool_keee *data)
  567. {
  568. u16 tmp16 = linkmode_to_mii_eee_cap1_t(data->advertised);
  569. return ax88179_phy_write_mmd_indirect(dev, MDIO_AN_EEE_ADV,
  570. MDIO_MMD_AN, tmp16);
  571. }
  572. static int ax88179_chk_eee(struct usbnet *dev)
  573. {
  574. struct ethtool_cmd ecmd = { .cmd = ETHTOOL_GSET };
  575. struct ax88179_data *priv = dev->driver_priv;
  576. mii_ethtool_gset(&dev->mii, &ecmd);
  577. if (ecmd.duplex & DUPLEX_FULL) {
  578. int eee_lp, eee_cap, eee_adv;
  579. u32 lp, cap, adv, supported = 0;
  580. eee_cap = ax88179_phy_read_mmd_indirect(dev,
  581. MDIO_PCS_EEE_ABLE,
  582. MDIO_MMD_PCS);
  583. if (eee_cap < 0) {
  584. priv->eee_active = 0;
  585. return false;
  586. }
  587. cap = mmd_eee_cap_to_ethtool_sup_t(eee_cap);
  588. if (!cap) {
  589. priv->eee_active = 0;
  590. return false;
  591. }
  592. eee_lp = ax88179_phy_read_mmd_indirect(dev,
  593. MDIO_AN_EEE_LPABLE,
  594. MDIO_MMD_AN);
  595. if (eee_lp < 0) {
  596. priv->eee_active = 0;
  597. return false;
  598. }
  599. eee_adv = ax88179_phy_read_mmd_indirect(dev,
  600. MDIO_AN_EEE_ADV,
  601. MDIO_MMD_AN);
  602. if (eee_adv < 0) {
  603. priv->eee_active = 0;
  604. return false;
  605. }
  606. adv = mmd_eee_adv_to_ethtool_adv_t(eee_adv);
  607. lp = mmd_eee_adv_to_ethtool_adv_t(eee_lp);
  608. supported = (ecmd.speed == SPEED_1000) ?
  609. SUPPORTED_1000baseT_Full :
  610. SUPPORTED_100baseT_Full;
  611. if (!(lp & adv & supported)) {
  612. priv->eee_active = 0;
  613. return false;
  614. }
  615. priv->eee_active = 1;
  616. return true;
  617. }
  618. priv->eee_active = 0;
  619. return false;
  620. }
  621. static void ax88179_disable_eee(struct usbnet *dev)
  622. {
  623. u16 tmp16;
  624. tmp16 = GMII_PHY_PGSEL_PAGE3;
  625. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  626. GMII_PHY_PAGE_SELECT, 2, &tmp16);
  627. tmp16 = 0x3246;
  628. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  629. MII_PHYADDR, 2, &tmp16);
  630. tmp16 = GMII_PHY_PGSEL_PAGE0;
  631. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  632. GMII_PHY_PAGE_SELECT, 2, &tmp16);
  633. }
  634. static void ax88179_enable_eee(struct usbnet *dev)
  635. {
  636. u16 tmp16;
  637. tmp16 = GMII_PHY_PGSEL_PAGE3;
  638. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  639. GMII_PHY_PAGE_SELECT, 2, &tmp16);
  640. tmp16 = 0x3247;
  641. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  642. MII_PHYADDR, 2, &tmp16);
  643. tmp16 = GMII_PHY_PGSEL_PAGE5;
  644. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  645. GMII_PHY_PAGE_SELECT, 2, &tmp16);
  646. tmp16 = 0x0680;
  647. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  648. MII_BMSR, 2, &tmp16);
  649. tmp16 = GMII_PHY_PGSEL_PAGE0;
  650. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  651. GMII_PHY_PAGE_SELECT, 2, &tmp16);
  652. }
  653. static int ax88179_get_eee(struct net_device *net, struct ethtool_keee *edata)
  654. {
  655. struct usbnet *dev = netdev_priv(net);
  656. struct ax88179_data *priv = dev->driver_priv;
  657. edata->eee_enabled = priv->eee_enabled;
  658. edata->eee_active = priv->eee_active;
  659. return ax88179_ethtool_get_eee(dev, edata);
  660. }
  661. static int ax88179_set_eee(struct net_device *net, struct ethtool_keee *edata)
  662. {
  663. struct usbnet *dev = netdev_priv(net);
  664. struct ax88179_data *priv = dev->driver_priv;
  665. int ret;
  666. priv->eee_enabled = edata->eee_enabled;
  667. if (!priv->eee_enabled) {
  668. ax88179_disable_eee(dev);
  669. } else {
  670. priv->eee_enabled = ax88179_chk_eee(dev);
  671. if (!priv->eee_enabled)
  672. return -EOPNOTSUPP;
  673. ax88179_enable_eee(dev);
  674. }
  675. ret = ax88179_ethtool_set_eee(dev, edata);
  676. if (ret)
  677. return ret;
  678. mii_nway_restart(&dev->mii);
  679. usbnet_link_change(dev, 0, 0);
  680. return ret;
  681. }
  682. static const struct ethtool_ops ax88179_ethtool_ops = {
  683. .get_link = ethtool_op_get_link,
  684. .get_msglevel = usbnet_get_msglevel,
  685. .set_msglevel = usbnet_set_msglevel,
  686. .get_wol = ax88179_get_wol,
  687. .set_wol = ax88179_set_wol,
  688. .get_eeprom_len = ax88179_get_eeprom_len,
  689. .get_eeprom = ax88179_get_eeprom,
  690. .set_eeprom = ax88179_set_eeprom,
  691. .get_eee = ax88179_get_eee,
  692. .set_eee = ax88179_set_eee,
  693. .nway_reset = usbnet_nway_reset,
  694. .get_link_ksettings = ax88179_get_link_ksettings,
  695. .set_link_ksettings = ax88179_set_link_ksettings,
  696. .get_ts_info = ethtool_op_get_ts_info,
  697. };
  698. static void ax88179_set_multicast(struct net_device *net)
  699. {
  700. struct usbnet *dev = netdev_priv(net);
  701. struct ax88179_data *data = dev->driver_priv;
  702. u8 *m_filter = ((u8 *)dev->data);
  703. data->rxctl = (AX_RX_CTL_START | AX_RX_CTL_AB | AX_RX_CTL_IPE);
  704. if (net->flags & IFF_PROMISC) {
  705. data->rxctl |= AX_RX_CTL_PRO;
  706. } else if (net->flags & IFF_ALLMULTI ||
  707. netdev_mc_count(net) > AX_MAX_MCAST) {
  708. data->rxctl |= AX_RX_CTL_AMALL;
  709. } else if (netdev_mc_empty(net)) {
  710. /* just broadcast and directed */
  711. } else {
  712. /* We use dev->data for our 8 byte filter buffer
  713. * to avoid allocating memory that is tricky to free later
  714. */
  715. u32 crc_bits;
  716. struct netdev_hw_addr *ha;
  717. memset(m_filter, 0, AX_MCAST_FLTSIZE);
  718. netdev_for_each_mc_addr(ha, net) {
  719. crc_bits = ether_crc(ETH_ALEN, ha->addr) >> 26;
  720. *(m_filter + (crc_bits >> 3)) |= (1 << (crc_bits & 7));
  721. }
  722. ax88179_write_cmd_async(dev, AX_ACCESS_MAC, AX_MULFLTARY,
  723. AX_MCAST_FLTSIZE, AX_MCAST_FLTSIZE,
  724. m_filter);
  725. data->rxctl |= AX_RX_CTL_AM;
  726. }
  727. ax88179_write_cmd_async(dev, AX_ACCESS_MAC, AX_RX_CTL,
  728. 2, 2, &data->rxctl);
  729. }
  730. static int
  731. ax88179_set_features(struct net_device *net, netdev_features_t features)
  732. {
  733. u8 tmp;
  734. struct usbnet *dev = netdev_priv(net);
  735. netdev_features_t changed = net->features ^ features;
  736. if (changed & NETIF_F_IP_CSUM) {
  737. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_TXCOE_CTL, 1, 1, &tmp);
  738. tmp ^= AX_TXCOE_TCP | AX_TXCOE_UDP;
  739. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_TXCOE_CTL, 1, 1, &tmp);
  740. }
  741. if (changed & NETIF_F_IPV6_CSUM) {
  742. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_TXCOE_CTL, 1, 1, &tmp);
  743. tmp ^= AX_TXCOE_TCPV6 | AX_TXCOE_UDPV6;
  744. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_TXCOE_CTL, 1, 1, &tmp);
  745. }
  746. if (changed & NETIF_F_RXCSUM) {
  747. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_RXCOE_CTL, 1, 1, &tmp);
  748. tmp ^= AX_RXCOE_IP | AX_RXCOE_TCP | AX_RXCOE_UDP |
  749. AX_RXCOE_TCPV6 | AX_RXCOE_UDPV6;
  750. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_RXCOE_CTL, 1, 1, &tmp);
  751. }
  752. return 0;
  753. }
  754. static int ax88179_change_mtu(struct net_device *net, int new_mtu)
  755. {
  756. struct usbnet *dev = netdev_priv(net);
  757. u16 tmp16;
  758. WRITE_ONCE(net->mtu, new_mtu);
  759. dev->hard_mtu = net->mtu + net->hard_header_len;
  760. if (net->mtu > 1500) {
  761. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  762. 2, 2, &tmp16);
  763. tmp16 |= AX_MEDIUM_JUMBO_EN;
  764. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  765. 2, 2, &tmp16);
  766. } else {
  767. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  768. 2, 2, &tmp16);
  769. tmp16 &= ~AX_MEDIUM_JUMBO_EN;
  770. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  771. 2, 2, &tmp16);
  772. }
  773. /* max qlen depend on hard_mtu and rx_urb_size */
  774. usbnet_update_max_qlen(dev);
  775. return 0;
  776. }
  777. static int ax88179_set_mac_addr(struct net_device *net, void *p)
  778. {
  779. struct usbnet *dev = netdev_priv(net);
  780. struct sockaddr *addr = p;
  781. int ret;
  782. if (netif_running(net))
  783. return -EBUSY;
  784. if (!is_valid_ether_addr(addr->sa_data))
  785. return -EADDRNOTAVAIL;
  786. eth_hw_addr_set(net, addr->sa_data);
  787. /* Set the MAC address */
  788. ret = ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_NODE_ID, ETH_ALEN,
  789. ETH_ALEN, net->dev_addr);
  790. if (ret < 0)
  791. return ret;
  792. return 0;
  793. }
  794. static const struct net_device_ops ax88179_netdev_ops = {
  795. .ndo_open = usbnet_open,
  796. .ndo_stop = usbnet_stop,
  797. .ndo_start_xmit = usbnet_start_xmit,
  798. .ndo_tx_timeout = usbnet_tx_timeout,
  799. .ndo_get_stats64 = dev_get_tstats64,
  800. .ndo_change_mtu = ax88179_change_mtu,
  801. .ndo_set_mac_address = ax88179_set_mac_addr,
  802. .ndo_validate_addr = eth_validate_addr,
  803. .ndo_eth_ioctl = usbnet_mii_ioctl,
  804. .ndo_set_rx_mode = ax88179_set_multicast,
  805. .ndo_set_features = ax88179_set_features,
  806. };
  807. static int ax88179_check_eeprom(struct usbnet *dev)
  808. {
  809. u8 i, buf, eeprom[20];
  810. u16 csum, delay = HZ / 10;
  811. unsigned long jtimeout;
  812. /* Read EEPROM content */
  813. for (i = 0; i < 6; i++) {
  814. buf = i;
  815. if (ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_SROM_ADDR,
  816. 1, 1, &buf) < 0)
  817. return -EINVAL;
  818. buf = EEP_RD;
  819. if (ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_SROM_CMD,
  820. 1, 1, &buf) < 0)
  821. return -EINVAL;
  822. jtimeout = jiffies + delay;
  823. do {
  824. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_SROM_CMD,
  825. 1, 1, &buf);
  826. if (time_after(jiffies, jtimeout))
  827. return -EINVAL;
  828. } while (buf & EEP_BUSY);
  829. __ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_SROM_DATA_LOW,
  830. 2, 2, &eeprom[i * 2]);
  831. if ((i == 0) && (eeprom[0] == 0xFF))
  832. return -EINVAL;
  833. }
  834. csum = eeprom[6] + eeprom[7] + eeprom[8] + eeprom[9];
  835. csum = (csum >> 8) + (csum & 0xff);
  836. if ((csum + eeprom[10]) != 0xff)
  837. return -EINVAL;
  838. return 0;
  839. }
  840. static int ax88179_check_efuse(struct usbnet *dev, u16 *ledmode)
  841. {
  842. u8 i;
  843. u8 efuse[64];
  844. u16 csum = 0;
  845. if (ax88179_read_cmd(dev, AX_ACCESS_EFUS, 0, 64, 64, efuse) < 0)
  846. return -EINVAL;
  847. if (*efuse == 0xFF)
  848. return -EINVAL;
  849. for (i = 0; i < 64; i++)
  850. csum = csum + efuse[i];
  851. while (csum > 255)
  852. csum = (csum & 0x00FF) + ((csum >> 8) & 0x00FF);
  853. if (csum != 0xFF)
  854. return -EINVAL;
  855. *ledmode = (efuse[51] << 8) | efuse[52];
  856. return 0;
  857. }
  858. static int ax88179_convert_old_led(struct usbnet *dev, u16 *ledvalue)
  859. {
  860. u16 led;
  861. /* Loaded the old eFuse LED Mode */
  862. if (ax88179_read_cmd(dev, AX_ACCESS_EEPROM, 0x3C, 1, 2, &led) < 0)
  863. return -EINVAL;
  864. led >>= 8;
  865. switch (led) {
  866. case 0xFF:
  867. led = LED0_ACTIVE | LED1_LINK_10 | LED1_LINK_100 |
  868. LED1_LINK_1000 | LED2_ACTIVE | LED2_LINK_10 |
  869. LED2_LINK_100 | LED2_LINK_1000 | LED_VALID;
  870. break;
  871. case 0xFE:
  872. led = LED0_ACTIVE | LED1_LINK_1000 | LED2_LINK_100 | LED_VALID;
  873. break;
  874. case 0xFD:
  875. led = LED0_ACTIVE | LED1_LINK_1000 | LED2_LINK_100 |
  876. LED2_LINK_10 | LED_VALID;
  877. break;
  878. case 0xFC:
  879. led = LED0_ACTIVE | LED1_ACTIVE | LED1_LINK_1000 | LED2_ACTIVE |
  880. LED2_LINK_100 | LED2_LINK_10 | LED_VALID;
  881. break;
  882. default:
  883. led = LED0_ACTIVE | LED1_LINK_10 | LED1_LINK_100 |
  884. LED1_LINK_1000 | LED2_ACTIVE | LED2_LINK_10 |
  885. LED2_LINK_100 | LED2_LINK_1000 | LED_VALID;
  886. break;
  887. }
  888. *ledvalue = led;
  889. return 0;
  890. }
  891. static int ax88179_led_setting(struct usbnet *dev)
  892. {
  893. u8 ledfd, value = 0;
  894. u16 tmp, ledact, ledlink, ledvalue = 0, delay = HZ / 10;
  895. unsigned long jtimeout;
  896. /* Check AX88179 version. UA1 or UA2*/
  897. ax88179_read_cmd(dev, AX_ACCESS_MAC, GENERAL_STATUS, 1, 1, &value);
  898. if (!(value & AX_SECLD)) { /* UA1 */
  899. value = AX_GPIO_CTRL_GPIO3EN | AX_GPIO_CTRL_GPIO2EN |
  900. AX_GPIO_CTRL_GPIO1EN;
  901. if (ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_GPIO_CTRL,
  902. 1, 1, &value) < 0)
  903. return -EINVAL;
  904. }
  905. /* Check EEPROM */
  906. if (!ax88179_check_eeprom(dev)) {
  907. value = 0x42;
  908. if (ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_SROM_ADDR,
  909. 1, 1, &value) < 0)
  910. return -EINVAL;
  911. value = EEP_RD;
  912. if (ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_SROM_CMD,
  913. 1, 1, &value) < 0)
  914. return -EINVAL;
  915. jtimeout = jiffies + delay;
  916. do {
  917. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_SROM_CMD,
  918. 1, 1, &value);
  919. if (time_after(jiffies, jtimeout))
  920. return -EINVAL;
  921. } while (value & EEP_BUSY);
  922. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_SROM_DATA_HIGH,
  923. 1, 1, &value);
  924. ledvalue = (value << 8);
  925. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_SROM_DATA_LOW,
  926. 1, 1, &value);
  927. ledvalue |= value;
  928. /* load internal ROM for defaule setting */
  929. if ((ledvalue == 0xFFFF) || ((ledvalue & LED_VALID) == 0))
  930. ax88179_convert_old_led(dev, &ledvalue);
  931. } else if (!ax88179_check_efuse(dev, &ledvalue)) {
  932. if ((ledvalue == 0xFFFF) || ((ledvalue & LED_VALID) == 0))
  933. ax88179_convert_old_led(dev, &ledvalue);
  934. } else {
  935. ax88179_convert_old_led(dev, &ledvalue);
  936. }
  937. tmp = GMII_PHY_PGSEL_EXT;
  938. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  939. GMII_PHY_PAGE_SELECT, 2, &tmp);
  940. tmp = 0x2c;
  941. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  942. GMII_PHYPAGE, 2, &tmp);
  943. ax88179_read_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  944. GMII_LED_ACT, 2, &ledact);
  945. ax88179_read_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  946. GMII_LED_LINK, 2, &ledlink);
  947. ledact &= GMII_LED_ACTIVE_MASK;
  948. ledlink &= GMII_LED_LINK_MASK;
  949. if (ledvalue & LED0_ACTIVE)
  950. ledact |= GMII_LED0_ACTIVE;
  951. if (ledvalue & LED1_ACTIVE)
  952. ledact |= GMII_LED1_ACTIVE;
  953. if (ledvalue & LED2_ACTIVE)
  954. ledact |= GMII_LED2_ACTIVE;
  955. if (ledvalue & LED0_LINK_10)
  956. ledlink |= GMII_LED0_LINK_10;
  957. if (ledvalue & LED1_LINK_10)
  958. ledlink |= GMII_LED1_LINK_10;
  959. if (ledvalue & LED2_LINK_10)
  960. ledlink |= GMII_LED2_LINK_10;
  961. if (ledvalue & LED0_LINK_100)
  962. ledlink |= GMII_LED0_LINK_100;
  963. if (ledvalue & LED1_LINK_100)
  964. ledlink |= GMII_LED1_LINK_100;
  965. if (ledvalue & LED2_LINK_100)
  966. ledlink |= GMII_LED2_LINK_100;
  967. if (ledvalue & LED0_LINK_1000)
  968. ledlink |= GMII_LED0_LINK_1000;
  969. if (ledvalue & LED1_LINK_1000)
  970. ledlink |= GMII_LED1_LINK_1000;
  971. if (ledvalue & LED2_LINK_1000)
  972. ledlink |= GMII_LED2_LINK_1000;
  973. tmp = ledact;
  974. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  975. GMII_LED_ACT, 2, &tmp);
  976. tmp = ledlink;
  977. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  978. GMII_LED_LINK, 2, &tmp);
  979. tmp = GMII_PHY_PGSEL_PAGE0;
  980. ax88179_write_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  981. GMII_PHY_PAGE_SELECT, 2, &tmp);
  982. /* LED full duplex setting */
  983. ledfd = 0;
  984. if (ledvalue & LED0_FD)
  985. ledfd |= 0x01;
  986. else if ((ledvalue & LED0_USB3_MASK) == 0)
  987. ledfd |= 0x02;
  988. if (ledvalue & LED1_FD)
  989. ledfd |= 0x04;
  990. else if ((ledvalue & LED1_USB3_MASK) == 0)
  991. ledfd |= 0x08;
  992. if (ledvalue & LED2_FD)
  993. ledfd |= 0x10;
  994. else if ((ledvalue & LED2_USB3_MASK) == 0)
  995. ledfd |= 0x20;
  996. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_LEDCTRL, 1, 1, &ledfd);
  997. return 0;
  998. }
  999. static void ax88179_get_mac_addr(struct usbnet *dev)
  1000. {
  1001. u8 mac[ETH_ALEN];
  1002. memset(mac, 0, sizeof(mac));
  1003. /* Maybe the boot loader passed the MAC address via device tree */
  1004. if (!eth_platform_get_mac_address(&dev->udev->dev, mac)) {
  1005. netif_dbg(dev, ifup, dev->net,
  1006. "MAC address read from device tree");
  1007. } else {
  1008. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_NODE_ID, ETH_ALEN,
  1009. ETH_ALEN, mac);
  1010. netif_dbg(dev, ifup, dev->net,
  1011. "MAC address read from ASIX chip");
  1012. }
  1013. if (is_valid_ether_addr(mac)) {
  1014. eth_hw_addr_set(dev->net, mac);
  1015. if (!is_local_ether_addr(mac))
  1016. dev->net->addr_assign_type = NET_ADDR_PERM;
  1017. } else {
  1018. netdev_info(dev->net, "invalid MAC address, using random\n");
  1019. }
  1020. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_NODE_ID, ETH_ALEN, ETH_ALEN,
  1021. dev->net->dev_addr);
  1022. }
  1023. static int ax88179_bind(struct usbnet *dev, struct usb_interface *intf)
  1024. {
  1025. struct ax88179_data *ax179_data;
  1026. int ret;
  1027. ret = usbnet_get_endpoints(dev, intf);
  1028. if (ret < 0)
  1029. return ret;
  1030. ax179_data = kzalloc_obj(*ax179_data);
  1031. if (!ax179_data)
  1032. return -ENOMEM;
  1033. dev->driver_priv = ax179_data;
  1034. dev->net->netdev_ops = &ax88179_netdev_ops;
  1035. dev->net->ethtool_ops = &ax88179_ethtool_ops;
  1036. dev->net->needed_headroom = 8;
  1037. dev->net->max_mtu = 4088;
  1038. /* Initialize MII structure */
  1039. dev->mii.dev = dev->net;
  1040. dev->mii.mdio_read = ax88179_mdio_read;
  1041. dev->mii.mdio_write = ax88179_mdio_write;
  1042. dev->mii.phy_id_mask = 0xff;
  1043. dev->mii.reg_num_mask = 0xff;
  1044. dev->mii.phy_id = 0x03;
  1045. dev->mii.supports_gmii = 1;
  1046. dev->net->features |= NETIF_F_SG | NETIF_F_IP_CSUM |
  1047. NETIF_F_IPV6_CSUM | NETIF_F_RXCSUM | NETIF_F_TSO;
  1048. dev->net->hw_features |= dev->net->features;
  1049. netif_set_tso_max_size(dev->net, 16384);
  1050. ax88179_reset(dev);
  1051. return 0;
  1052. }
  1053. static void ax88179_unbind(struct usbnet *dev, struct usb_interface *intf)
  1054. {
  1055. struct ax88179_data *ax179_data = dev->driver_priv;
  1056. u16 tmp16;
  1057. /* Configure RX control register => stop operation */
  1058. tmp16 = AX_RX_CTL_STOP;
  1059. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_RX_CTL, 2, 2, &tmp16);
  1060. tmp16 = 0;
  1061. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_CLK_SELECT, 1, 1, &tmp16);
  1062. /* Power down ethernet PHY */
  1063. tmp16 = 0;
  1064. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_PHYPWR_RSTCTL, 2, 2, &tmp16);
  1065. kfree(ax179_data);
  1066. }
  1067. static void
  1068. ax88179_rx_checksum(struct sk_buff *skb, u32 *pkt_hdr)
  1069. {
  1070. skb->ip_summed = CHECKSUM_NONE;
  1071. /* checksum error bit is set */
  1072. if ((*pkt_hdr & AX_RXHDR_L3CSUM_ERR) ||
  1073. (*pkt_hdr & AX_RXHDR_L4CSUM_ERR))
  1074. return;
  1075. /* It must be a TCP or UDP packet with a valid checksum */
  1076. if (((*pkt_hdr & AX_RXHDR_L4_TYPE_MASK) == AX_RXHDR_L4_TYPE_TCP) ||
  1077. ((*pkt_hdr & AX_RXHDR_L4_TYPE_MASK) == AX_RXHDR_L4_TYPE_UDP))
  1078. skb->ip_summed = CHECKSUM_UNNECESSARY;
  1079. }
  1080. static int ax88179_rx_fixup(struct usbnet *dev, struct sk_buff *skb)
  1081. {
  1082. struct sk_buff *ax_skb;
  1083. int pkt_cnt;
  1084. u32 rx_hdr;
  1085. u16 hdr_off;
  1086. u32 *pkt_hdr;
  1087. /* At the end of the SKB, there's a header telling us how many packets
  1088. * are bundled into this buffer and where we can find an array of
  1089. * per-packet metadata (which contains elements encoded into u16).
  1090. */
  1091. /* SKB contents for current firmware:
  1092. * <packet 1> <padding>
  1093. * ...
  1094. * <packet N> <padding>
  1095. * <per-packet metadata entry 1> <dummy header>
  1096. * ...
  1097. * <per-packet metadata entry N> <dummy header>
  1098. * <padding2> <rx_hdr>
  1099. *
  1100. * where:
  1101. * <packet N> contains pkt_len bytes:
  1102. * 2 bytes of IP alignment pseudo header
  1103. * packet received
  1104. * <per-packet metadata entry N> contains 4 bytes:
  1105. * pkt_len and fields AX_RXHDR_*
  1106. * <padding> 0-7 bytes to terminate at
  1107. * 8 bytes boundary (64-bit).
  1108. * <padding2> 4 bytes to make rx_hdr terminate at
  1109. * 8 bytes boundary (64-bit)
  1110. * <dummy-header> contains 4 bytes:
  1111. * pkt_len=0 and AX_RXHDR_DROP_ERR
  1112. * <rx-hdr> contains 4 bytes:
  1113. * pkt_cnt and hdr_off (offset of
  1114. * <per-packet metadata entry 1>)
  1115. *
  1116. * pkt_cnt is number of entrys in the per-packet metadata.
  1117. * In current firmware there is 2 entrys per packet.
  1118. * The first points to the packet and the
  1119. * second is a dummy header.
  1120. * This was done probably to align fields in 64-bit and
  1121. * maintain compatibility with old firmware.
  1122. * This code assumes that <dummy header> and <padding2> are
  1123. * optional.
  1124. */
  1125. if (skb->len < 4)
  1126. return 0;
  1127. skb_trim(skb, skb->len - 4);
  1128. rx_hdr = get_unaligned_le32(skb_tail_pointer(skb));
  1129. pkt_cnt = (u16)rx_hdr;
  1130. hdr_off = (u16)(rx_hdr >> 16);
  1131. if (pkt_cnt == 0)
  1132. return 0;
  1133. /* Make sure that the bounds of the metadata array are inside the SKB
  1134. * (and in front of the counter at the end).
  1135. */
  1136. if (pkt_cnt * 4 + hdr_off > skb->len)
  1137. return 0;
  1138. pkt_hdr = (u32 *)(skb->data + hdr_off);
  1139. /* Packets must not overlap the metadata array */
  1140. skb_trim(skb, hdr_off);
  1141. for (; pkt_cnt > 0; pkt_cnt--, pkt_hdr++) {
  1142. u16 pkt_len_plus_padd;
  1143. u16 pkt_len;
  1144. le32_to_cpus(pkt_hdr);
  1145. pkt_len = (*pkt_hdr >> 16) & 0x1fff;
  1146. pkt_len_plus_padd = (pkt_len + 7) & 0xfff8;
  1147. /* Skip dummy header used for alignment
  1148. */
  1149. if (pkt_len == 0)
  1150. continue;
  1151. if (pkt_len_plus_padd > skb->len)
  1152. return 0;
  1153. /* Check CRC or runt packet */
  1154. if ((*pkt_hdr & (AX_RXHDR_CRC_ERR | AX_RXHDR_DROP_ERR)) ||
  1155. pkt_len < 2 + ETH_HLEN) {
  1156. dev->net->stats.rx_errors++;
  1157. skb_pull(skb, pkt_len_plus_padd);
  1158. continue;
  1159. }
  1160. /* last packet */
  1161. if (pkt_len_plus_padd == skb->len) {
  1162. skb_trim(skb, pkt_len);
  1163. /* Skip IP alignment pseudo header */
  1164. skb_pull(skb, 2);
  1165. ax88179_rx_checksum(skb, pkt_hdr);
  1166. return 1;
  1167. }
  1168. ax_skb = netdev_alloc_skb_ip_align(dev->net, pkt_len);
  1169. if (!ax_skb)
  1170. return 0;
  1171. skb_put(ax_skb, pkt_len);
  1172. memcpy(ax_skb->data, skb->data + 2, pkt_len);
  1173. ax88179_rx_checksum(ax_skb, pkt_hdr);
  1174. usbnet_skb_return(dev, ax_skb);
  1175. skb_pull(skb, pkt_len_plus_padd);
  1176. }
  1177. return 0;
  1178. }
  1179. static struct sk_buff *
  1180. ax88179_tx_fixup(struct usbnet *dev, struct sk_buff *skb, gfp_t flags)
  1181. {
  1182. u32 tx_hdr1, tx_hdr2;
  1183. int frame_size = dev->maxpacket;
  1184. int headroom;
  1185. void *ptr;
  1186. tx_hdr1 = skb->len;
  1187. tx_hdr2 = skb_shinfo(skb)->gso_size; /* Set TSO mss */
  1188. if (((skb->len + 8) % frame_size) == 0)
  1189. tx_hdr2 |= 0x80008000; /* Enable padding */
  1190. headroom = skb_headroom(skb) - 8;
  1191. if ((dev->net->features & NETIF_F_SG) && skb_linearize(skb))
  1192. return NULL;
  1193. if ((skb_header_cloned(skb) || headroom < 0) &&
  1194. pskb_expand_head(skb, headroom < 0 ? 8 : 0, 0, GFP_ATOMIC)) {
  1195. dev_kfree_skb_any(skb);
  1196. return NULL;
  1197. }
  1198. ptr = skb_push(skb, 8);
  1199. put_unaligned_le32(tx_hdr1, ptr);
  1200. put_unaligned_le32(tx_hdr2, ptr + 4);
  1201. usbnet_set_skb_tx_stats(skb, (skb_shinfo(skb)->gso_segs ?: 1), 0);
  1202. return skb;
  1203. }
  1204. static int ax88179_link_reset(struct usbnet *dev)
  1205. {
  1206. struct ax88179_data *ax179_data = dev->driver_priv;
  1207. u8 tmp[5], link_sts;
  1208. u16 mode, tmp16, delay = HZ / 10;
  1209. u32 tmp32 = 0x40000000;
  1210. unsigned long jtimeout;
  1211. jtimeout = jiffies + delay;
  1212. while (tmp32 & 0x40000000) {
  1213. mode = 0;
  1214. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_RX_CTL, 2, 2, &mode);
  1215. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_RX_CTL, 2, 2,
  1216. &ax179_data->rxctl);
  1217. /*link up, check the usb device control TX FIFO full or empty*/
  1218. ax88179_read_cmd(dev, 0x81, 0x8c, 0, 4, &tmp32);
  1219. if (time_after(jiffies, jtimeout))
  1220. return 0;
  1221. }
  1222. mode = AX_MEDIUM_RECEIVE_EN | AX_MEDIUM_TXFLOW_CTRLEN |
  1223. AX_MEDIUM_RXFLOW_CTRLEN;
  1224. ax88179_read_cmd(dev, AX_ACCESS_MAC, PHYSICAL_LINK_STATUS,
  1225. 1, 1, &link_sts);
  1226. ax88179_read_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID,
  1227. GMII_PHY_PHYSR, 2, &tmp16);
  1228. if (!(tmp16 & GMII_PHY_PHYSR_LINK)) {
  1229. netdev_info(dev->net, "ax88179 - Link status is: 0\n");
  1230. return 0;
  1231. } else if (GMII_PHY_PHYSR_GIGA == (tmp16 & GMII_PHY_PHYSR_SMASK)) {
  1232. mode |= AX_MEDIUM_GIGAMODE | AX_MEDIUM_EN_125MHZ;
  1233. if (dev->net->mtu > 1500)
  1234. mode |= AX_MEDIUM_JUMBO_EN;
  1235. if (link_sts & AX_USB_SS)
  1236. memcpy(tmp, &AX88179_BULKIN_SIZE[0], 5);
  1237. else if (link_sts & AX_USB_HS)
  1238. memcpy(tmp, &AX88179_BULKIN_SIZE[1], 5);
  1239. else
  1240. memcpy(tmp, &AX88179_BULKIN_SIZE[3], 5);
  1241. } else if (GMII_PHY_PHYSR_100 == (tmp16 & GMII_PHY_PHYSR_SMASK)) {
  1242. mode |= AX_MEDIUM_PS;
  1243. if (link_sts & (AX_USB_SS | AX_USB_HS))
  1244. memcpy(tmp, &AX88179_BULKIN_SIZE[2], 5);
  1245. else
  1246. memcpy(tmp, &AX88179_BULKIN_SIZE[3], 5);
  1247. } else {
  1248. memcpy(tmp, &AX88179_BULKIN_SIZE[3], 5);
  1249. }
  1250. /* RX bulk configuration */
  1251. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_RX_BULKIN_QCTRL, 5, 5, tmp);
  1252. dev->rx_urb_size = (1024 * (tmp[3] + 2));
  1253. if (tmp16 & GMII_PHY_PHYSR_FULL)
  1254. mode |= AX_MEDIUM_FULL_DUPLEX;
  1255. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  1256. 2, 2, &mode);
  1257. ax179_data->eee_enabled = ax88179_chk_eee(dev);
  1258. netif_carrier_on(dev->net);
  1259. netdev_info(dev->net, "ax88179 - Link status is: 1\n");
  1260. return 0;
  1261. }
  1262. static int ax88179_reset(struct usbnet *dev)
  1263. {
  1264. u8 buf[5];
  1265. u16 *tmp16;
  1266. u8 *tmp;
  1267. struct ax88179_data *ax179_data = dev->driver_priv;
  1268. struct ethtool_keee eee_data;
  1269. tmp16 = (u16 *)buf;
  1270. tmp = (u8 *)buf;
  1271. /* Power up ethernet PHY */
  1272. *tmp16 = 0;
  1273. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_PHYPWR_RSTCTL, 2, 2, tmp16);
  1274. *tmp16 = AX_PHYPWR_RSTCTL_IPRL;
  1275. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_PHYPWR_RSTCTL, 2, 2, tmp16);
  1276. msleep(500);
  1277. *tmp = AX_CLK_SELECT_ACS | AX_CLK_SELECT_BCS;
  1278. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_CLK_SELECT, 1, 1, tmp);
  1279. msleep(200);
  1280. /* Ethernet PHY Auto Detach*/
  1281. ax88179_auto_detach(dev);
  1282. /* Read MAC address from DTB or asix chip */
  1283. ax88179_get_mac_addr(dev);
  1284. memcpy(dev->net->perm_addr, dev->net->dev_addr, ETH_ALEN);
  1285. /* RX bulk configuration */
  1286. memcpy(tmp, &AX88179_BULKIN_SIZE[0], 5);
  1287. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_RX_BULKIN_QCTRL, 5, 5, tmp);
  1288. dev->rx_urb_size = 1024 * 20;
  1289. *tmp = 0x34;
  1290. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_PAUSE_WATERLVL_LOW, 1, 1, tmp);
  1291. *tmp = 0x52;
  1292. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_PAUSE_WATERLVL_HIGH,
  1293. 1, 1, tmp);
  1294. /* Enable checksum offload */
  1295. *tmp = AX_RXCOE_IP | AX_RXCOE_TCP | AX_RXCOE_UDP |
  1296. AX_RXCOE_TCPV6 | AX_RXCOE_UDPV6;
  1297. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_RXCOE_CTL, 1, 1, tmp);
  1298. *tmp = AX_TXCOE_IP | AX_TXCOE_TCP | AX_TXCOE_UDP |
  1299. AX_TXCOE_TCPV6 | AX_TXCOE_UDPV6;
  1300. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_TXCOE_CTL, 1, 1, tmp);
  1301. /* Configure RX control register => start operation */
  1302. *tmp16 = AX_RX_CTL_DROPCRCERR | AX_RX_CTL_IPE | AX_RX_CTL_START |
  1303. AX_RX_CTL_AP | AX_RX_CTL_AMALL | AX_RX_CTL_AB;
  1304. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_RX_CTL, 2, 2, tmp16);
  1305. *tmp = AX_MONITOR_MODE_PMETYPE | AX_MONITOR_MODE_PMEPOL |
  1306. AX_MONITOR_MODE_RWMP;
  1307. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_MONITOR_MOD, 1, 1, tmp);
  1308. /* Configure default medium type => giga */
  1309. *tmp16 = AX_MEDIUM_RECEIVE_EN | AX_MEDIUM_TXFLOW_CTRLEN |
  1310. AX_MEDIUM_RXFLOW_CTRLEN | AX_MEDIUM_FULL_DUPLEX |
  1311. AX_MEDIUM_GIGAMODE;
  1312. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  1313. 2, 2, tmp16);
  1314. /* Check if WoL is supported */
  1315. ax179_data->wol_supported = 0;
  1316. if (ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_MONITOR_MOD,
  1317. 1, 1, &tmp) > 0)
  1318. ax179_data->wol_supported = WAKE_MAGIC | WAKE_PHY;
  1319. ax88179_led_setting(dev);
  1320. ax179_data->eee_enabled = 0;
  1321. ax179_data->eee_active = 0;
  1322. ax88179_disable_eee(dev);
  1323. ax88179_ethtool_get_eee(dev, &eee_data);
  1324. linkmode_zero(eee_data.advertised);
  1325. ax88179_ethtool_set_eee(dev, &eee_data);
  1326. /* Restart autoneg */
  1327. mii_nway_restart(&dev->mii);
  1328. usbnet_link_change(dev, 0, 0);
  1329. return 0;
  1330. }
  1331. static int ax88179_net_reset(struct usbnet *dev)
  1332. {
  1333. u16 tmp16;
  1334. ax88179_read_cmd(dev, AX_ACCESS_PHY, AX88179_PHY_ID, GMII_PHY_PHYSR,
  1335. 2, &tmp16);
  1336. if (tmp16) {
  1337. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  1338. 2, 2, &tmp16);
  1339. if (!(tmp16 & AX_MEDIUM_RECEIVE_EN)) {
  1340. tmp16 |= AX_MEDIUM_RECEIVE_EN;
  1341. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  1342. 2, 2, &tmp16);
  1343. }
  1344. } else {
  1345. ax88179_reset(dev);
  1346. }
  1347. return 0;
  1348. }
  1349. static int ax88179_stop(struct usbnet *dev)
  1350. {
  1351. u16 tmp16;
  1352. ax88179_read_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  1353. 2, 2, &tmp16);
  1354. tmp16 &= ~AX_MEDIUM_RECEIVE_EN;
  1355. ax88179_write_cmd(dev, AX_ACCESS_MAC, AX_MEDIUM_STATUS_MODE,
  1356. 2, 2, &tmp16);
  1357. return 0;
  1358. }
  1359. static const struct driver_info ax88179_info = {
  1360. .description = "ASIX AX88179 USB 3.0 Gigabit Ethernet",
  1361. .bind = ax88179_bind,
  1362. .unbind = ax88179_unbind,
  1363. .status = ax88179_status,
  1364. .link_reset = ax88179_link_reset,
  1365. .reset = ax88179_net_reset,
  1366. .stop = ax88179_stop,
  1367. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1368. .rx_fixup = ax88179_rx_fixup,
  1369. .tx_fixup = ax88179_tx_fixup,
  1370. };
  1371. static const struct driver_info ax88178a_info = {
  1372. .description = "ASIX AX88178A USB 2.0 Gigabit Ethernet",
  1373. .bind = ax88179_bind,
  1374. .unbind = ax88179_unbind,
  1375. .status = ax88179_status,
  1376. .link_reset = ax88179_link_reset,
  1377. .reset = ax88179_net_reset,
  1378. .stop = ax88179_stop,
  1379. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1380. .rx_fixup = ax88179_rx_fixup,
  1381. .tx_fixup = ax88179_tx_fixup,
  1382. };
  1383. static const struct driver_info cypress_GX3_info = {
  1384. .description = "Cypress GX3 SuperSpeed to Gigabit Ethernet Controller",
  1385. .bind = ax88179_bind,
  1386. .unbind = ax88179_unbind,
  1387. .status = ax88179_status,
  1388. .link_reset = ax88179_link_reset,
  1389. .reset = ax88179_net_reset,
  1390. .stop = ax88179_stop,
  1391. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1392. .rx_fixup = ax88179_rx_fixup,
  1393. .tx_fixup = ax88179_tx_fixup,
  1394. };
  1395. static const struct driver_info dlink_dub1312_info = {
  1396. .description = "D-Link DUB-1312 USB 3.0 to Gigabit Ethernet Adapter",
  1397. .bind = ax88179_bind,
  1398. .unbind = ax88179_unbind,
  1399. .status = ax88179_status,
  1400. .link_reset = ax88179_link_reset,
  1401. .reset = ax88179_net_reset,
  1402. .stop = ax88179_stop,
  1403. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1404. .rx_fixup = ax88179_rx_fixup,
  1405. .tx_fixup = ax88179_tx_fixup,
  1406. };
  1407. static const struct driver_info sitecom_info = {
  1408. .description = "Sitecom USB 3.0 to Gigabit Adapter",
  1409. .bind = ax88179_bind,
  1410. .unbind = ax88179_unbind,
  1411. .status = ax88179_status,
  1412. .link_reset = ax88179_link_reset,
  1413. .reset = ax88179_net_reset,
  1414. .stop = ax88179_stop,
  1415. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1416. .rx_fixup = ax88179_rx_fixup,
  1417. .tx_fixup = ax88179_tx_fixup,
  1418. };
  1419. static const struct driver_info samsung_info = {
  1420. .description = "Samsung USB Ethernet Adapter",
  1421. .bind = ax88179_bind,
  1422. .unbind = ax88179_unbind,
  1423. .status = ax88179_status,
  1424. .link_reset = ax88179_link_reset,
  1425. .reset = ax88179_net_reset,
  1426. .stop = ax88179_stop,
  1427. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1428. .rx_fixup = ax88179_rx_fixup,
  1429. .tx_fixup = ax88179_tx_fixup,
  1430. };
  1431. static const struct driver_info lenovo_info = {
  1432. .description = "Lenovo OneLinkDock Gigabit LAN",
  1433. .bind = ax88179_bind,
  1434. .unbind = ax88179_unbind,
  1435. .status = ax88179_status,
  1436. .link_reset = ax88179_link_reset,
  1437. .reset = ax88179_net_reset,
  1438. .stop = ax88179_stop,
  1439. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1440. .rx_fixup = ax88179_rx_fixup,
  1441. .tx_fixup = ax88179_tx_fixup,
  1442. };
  1443. static const struct driver_info belkin_info = {
  1444. .description = "Belkin USB Ethernet Adapter",
  1445. .bind = ax88179_bind,
  1446. .unbind = ax88179_unbind,
  1447. .status = ax88179_status,
  1448. .link_reset = ax88179_link_reset,
  1449. .reset = ax88179_net_reset,
  1450. .stop = ax88179_stop,
  1451. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1452. .rx_fixup = ax88179_rx_fixup,
  1453. .tx_fixup = ax88179_tx_fixup,
  1454. };
  1455. static const struct driver_info toshiba_info = {
  1456. .description = "Toshiba USB Ethernet Adapter",
  1457. .bind = ax88179_bind,
  1458. .unbind = ax88179_unbind,
  1459. .status = ax88179_status,
  1460. .link_reset = ax88179_link_reset,
  1461. .reset = ax88179_net_reset,
  1462. .stop = ax88179_stop,
  1463. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1464. .rx_fixup = ax88179_rx_fixup,
  1465. .tx_fixup = ax88179_tx_fixup,
  1466. };
  1467. static const struct driver_info mct_info = {
  1468. .description = "MCT USB 3.0 Gigabit Ethernet Adapter",
  1469. .bind = ax88179_bind,
  1470. .unbind = ax88179_unbind,
  1471. .status = ax88179_status,
  1472. .link_reset = ax88179_link_reset,
  1473. .reset = ax88179_net_reset,
  1474. .stop = ax88179_stop,
  1475. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1476. .rx_fixup = ax88179_rx_fixup,
  1477. .tx_fixup = ax88179_tx_fixup,
  1478. };
  1479. static const struct driver_info at_umc2000_info = {
  1480. .description = "AT-UMC2000 USB 3.0/USB 3.1 Gen 1 to Gigabit Ethernet Adapter",
  1481. .bind = ax88179_bind,
  1482. .unbind = ax88179_unbind,
  1483. .status = ax88179_status,
  1484. .link_reset = ax88179_link_reset,
  1485. .reset = ax88179_net_reset,
  1486. .stop = ax88179_stop,
  1487. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1488. .rx_fixup = ax88179_rx_fixup,
  1489. .tx_fixup = ax88179_tx_fixup,
  1490. };
  1491. static const struct driver_info at_umc200_info = {
  1492. .description = "AT-UMC200 USB 3.0/USB 3.1 Gen 1 to Fast Ethernet Adapter",
  1493. .bind = ax88179_bind,
  1494. .unbind = ax88179_unbind,
  1495. .status = ax88179_status,
  1496. .link_reset = ax88179_link_reset,
  1497. .reset = ax88179_net_reset,
  1498. .stop = ax88179_stop,
  1499. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1500. .rx_fixup = ax88179_rx_fixup,
  1501. .tx_fixup = ax88179_tx_fixup,
  1502. };
  1503. static const struct driver_info at_umc2000sp_info = {
  1504. .description = "AT-UMC2000/SP USB 3.0/USB 3.1 Gen 1 to Gigabit Ethernet Adapter",
  1505. .bind = ax88179_bind,
  1506. .unbind = ax88179_unbind,
  1507. .status = ax88179_status,
  1508. .link_reset = ax88179_link_reset,
  1509. .reset = ax88179_net_reset,
  1510. .stop = ax88179_stop,
  1511. .flags = FLAG_ETHER | FLAG_FRAMING_AX,
  1512. .rx_fixup = ax88179_rx_fixup,
  1513. .tx_fixup = ax88179_tx_fixup,
  1514. };
  1515. static const struct usb_device_id products[] = {
  1516. {
  1517. /* ASIX AX88179 10/100/1000 */
  1518. USB_DEVICE_AND_INTERFACE_INFO(0x0b95, 0x1790, 0xff, 0xff, 0),
  1519. .driver_info = (unsigned long)&ax88179_info,
  1520. }, {
  1521. /* ASIX AX88178A 10/100/1000 */
  1522. USB_DEVICE_AND_INTERFACE_INFO(0x0b95, 0x178a, 0xff, 0xff, 0),
  1523. .driver_info = (unsigned long)&ax88178a_info,
  1524. }, {
  1525. /* Cypress GX3 SuperSpeed to Gigabit Ethernet Bridge Controller */
  1526. USB_DEVICE_AND_INTERFACE_INFO(0x04b4, 0x3610, 0xff, 0xff, 0),
  1527. .driver_info = (unsigned long)&cypress_GX3_info,
  1528. }, {
  1529. /* D-Link DUB-1312 USB 3.0 to Gigabit Ethernet Adapter */
  1530. USB_DEVICE_AND_INTERFACE_INFO(0x2001, 0x4a00, 0xff, 0xff, 0),
  1531. .driver_info = (unsigned long)&dlink_dub1312_info,
  1532. }, {
  1533. /* Sitecom USB 3.0 to Gigabit Adapter */
  1534. USB_DEVICE_AND_INTERFACE_INFO(0x0df6, 0x0072, 0xff, 0xff, 0),
  1535. .driver_info = (unsigned long)&sitecom_info,
  1536. }, {
  1537. /* Samsung USB Ethernet Adapter */
  1538. USB_DEVICE_AND_INTERFACE_INFO(0x04e8, 0xa100, 0xff, 0xff, 0),
  1539. .driver_info = (unsigned long)&samsung_info,
  1540. }, {
  1541. /* Lenovo OneLinkDock Gigabit LAN */
  1542. USB_DEVICE_AND_INTERFACE_INFO(0x17ef, 0x304b, 0xff, 0xff, 0),
  1543. .driver_info = (unsigned long)&lenovo_info,
  1544. }, {
  1545. /* Belkin B2B128 USB 3.0 Hub + Gigabit Ethernet Adapter */
  1546. USB_DEVICE_AND_INTERFACE_INFO(0x050d, 0x0128, 0xff, 0xff, 0),
  1547. .driver_info = (unsigned long)&belkin_info,
  1548. }, {
  1549. /* Toshiba USB 3.0 GBit Ethernet Adapter */
  1550. USB_DEVICE_AND_INTERFACE_INFO(0x0930, 0x0a13, 0xff, 0xff, 0),
  1551. .driver_info = (unsigned long)&toshiba_info,
  1552. }, {
  1553. /* Magic Control Technology U3-A9003 USB 3.0 Gigabit Ethernet Adapter */
  1554. USB_DEVICE_AND_INTERFACE_INFO(0x0711, 0x0179, 0xff, 0xff, 0),
  1555. .driver_info = (unsigned long)&mct_info,
  1556. }, {
  1557. /* Allied Telesis AT-UMC2000 USB 3.0/USB 3.1 Gen 1 to Gigabit Ethernet Adapter */
  1558. USB_DEVICE_AND_INTERFACE_INFO(0x07c9, 0x000e, 0xff, 0xff, 0),
  1559. .driver_info = (unsigned long)&at_umc2000_info,
  1560. }, {
  1561. /* Allied Telesis AT-UMC200 USB 3.0/USB 3.1 Gen 1 to Fast Ethernet Adapter */
  1562. USB_DEVICE_AND_INTERFACE_INFO(0x07c9, 0x000f, 0xff, 0xff, 0),
  1563. .driver_info = (unsigned long)&at_umc200_info,
  1564. }, {
  1565. /* Allied Telesis AT-UMC2000/SP USB 3.0/USB 3.1 Gen 1 to Gigabit Ethernet Adapter */
  1566. USB_DEVICE_AND_INTERFACE_INFO(0x07c9, 0x0010, 0xff, 0xff, 0),
  1567. .driver_info = (unsigned long)&at_umc2000sp_info,
  1568. },
  1569. { },
  1570. };
  1571. MODULE_DEVICE_TABLE(usb, products);
  1572. static struct usb_driver ax88179_178a_driver = {
  1573. .name = "ax88179_178a",
  1574. .id_table = products,
  1575. .probe = usbnet_probe,
  1576. .suspend = ax88179_suspend,
  1577. .resume = ax88179_resume,
  1578. .reset_resume = ax88179_resume,
  1579. .disconnect = ax88179_disconnect,
  1580. .supports_autosuspend = 1,
  1581. .disable_hub_initiated_lpm = 1,
  1582. };
  1583. module_usb_driver(ax88179_178a_driver);
  1584. MODULE_DESCRIPTION("ASIX AX88179/178A based USB 3.0/2.0 Gigabit Ethernet Devices");
  1585. MODULE_LICENSE("GPL");