skge.c 106 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /*
  3. * New driver for Marvell Yukon chipset and SysKonnect Gigabit
  4. * Ethernet adapters. Based on earlier sk98lin, e100 and
  5. * FreeBSD if_sk drivers.
  6. *
  7. * This driver intentionally does not support all the features
  8. * of the original driver such as link fail-over and link management because
  9. * those should be done at higher levels.
  10. *
  11. * Copyright (C) 2004, 2005 Stephen Hemminger <shemminger@osdl.org>
  12. */
  13. #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
  14. #include <linux/in.h>
  15. #include <linux/kernel.h>
  16. #include <linux/module.h>
  17. #include <linux/moduleparam.h>
  18. #include <linux/netdevice.h>
  19. #include <linux/etherdevice.h>
  20. #include <linux/ethtool.h>
  21. #include <linux/pci.h>
  22. #include <linux/if_vlan.h>
  23. #include <linux/ip.h>
  24. #include <linux/delay.h>
  25. #include <linux/crc32.h>
  26. #include <linux/dma-mapping.h>
  27. #include <linux/debugfs.h>
  28. #include <linux/sched.h>
  29. #include <linux/seq_file.h>
  30. #include <linux/mii.h>
  31. #include <linux/slab.h>
  32. #include <linux/dmi.h>
  33. #include <linux/prefetch.h>
  34. #include <asm/irq.h>
  35. #include "skge.h"
  36. #define DRV_NAME "skge"
  37. #define DRV_VERSION "1.14"
  38. #define DEFAULT_TX_RING_SIZE 128
  39. #define DEFAULT_RX_RING_SIZE 512
  40. #define MAX_TX_RING_SIZE 1024
  41. #define TX_LOW_WATER (MAX_SKB_FRAGS + 1)
  42. #define MAX_RX_RING_SIZE 4096
  43. #define RX_COPY_THRESHOLD 128
  44. #define RX_BUF_SIZE 1536
  45. #define PHY_RETRIES 1000
  46. #define ETH_JUMBO_MTU 9000
  47. #define TX_WATCHDOG (5 * HZ)
  48. #define BLINK_MS 250
  49. #define LINK_HZ HZ
  50. #define SKGE_EEPROM_MAGIC 0x9933aabb
  51. MODULE_DESCRIPTION("SysKonnect Gigabit Ethernet driver");
  52. MODULE_AUTHOR("Stephen Hemminger <shemminger@linux-foundation.org>");
  53. MODULE_LICENSE("GPL");
  54. MODULE_VERSION(DRV_VERSION);
  55. static const u32 default_msg = (NETIF_MSG_DRV | NETIF_MSG_PROBE |
  56. NETIF_MSG_LINK | NETIF_MSG_IFUP |
  57. NETIF_MSG_IFDOWN);
  58. static int debug = -1; /* defaults above */
  59. module_param(debug, int, 0);
  60. MODULE_PARM_DESC(debug, "Debug level (0=none,...,16=all)");
  61. static const struct pci_device_id skge_id_table[] = {
  62. { PCI_DEVICE(PCI_VENDOR_ID_3COM, 0x1700) }, /* 3Com 3C940 */
  63. { PCI_DEVICE(PCI_VENDOR_ID_3COM, 0x80EB) }, /* 3Com 3C940B */
  64. #ifdef CONFIG_SKGE_GENESIS
  65. { PCI_DEVICE(PCI_VENDOR_ID_SYSKONNECT, 0x4300) }, /* SK-9xx */
  66. #endif
  67. { PCI_DEVICE(PCI_VENDOR_ID_SYSKONNECT, 0x4320) }, /* SK-98xx V2.0 */
  68. { PCI_DEVICE(PCI_VENDOR_ID_DLINK, 0x4b01) }, /* D-Link DGE-530T (rev.B) */
  69. { PCI_DEVICE(PCI_VENDOR_ID_DLINK, 0x4c00) }, /* D-Link DGE-530T */
  70. { PCI_DEVICE(PCI_VENDOR_ID_MARVELL, 0x4320) }, /* Marvell Yukon 88E8001/8003/8010 */
  71. { PCI_DEVICE(PCI_VENDOR_ID_MARVELL, 0x5005) }, /* Belkin */
  72. { PCI_DEVICE(PCI_VENDOR_ID_CNET, 0x434E) }, /* CNet PowerG-2000 */
  73. { PCI_DEVICE(PCI_VENDOR_ID_LINKSYS, 0x1064) }, /* Linksys EG1064 v2 */
  74. { PCI_VENDOR_ID_LINKSYS, 0x1032, PCI_ANY_ID, 0x0015 }, /* Linksys EG1032 v2 */
  75. { 0 }
  76. };
  77. MODULE_DEVICE_TABLE(pci, skge_id_table);
  78. static int skge_up(struct net_device *dev);
  79. static int skge_down(struct net_device *dev);
  80. static void skge_phy_reset(struct skge_port *skge);
  81. static void skge_tx_clean(struct net_device *dev);
  82. static int xm_phy_write(struct skge_hw *hw, int port, u16 reg, u16 val);
  83. static int gm_phy_write(struct skge_hw *hw, int port, u16 reg, u16 val);
  84. static void genesis_get_stats(struct skge_port *skge, u64 *data);
  85. static void yukon_get_stats(struct skge_port *skge, u64 *data);
  86. static void yukon_init(struct skge_hw *hw, int port);
  87. static void genesis_mac_init(struct skge_hw *hw, int port);
  88. static void genesis_link_up(struct skge_port *skge);
  89. static void skge_set_multicast(struct net_device *dev);
  90. static irqreturn_t skge_intr(int irq, void *dev_id);
  91. /* Avoid conditionals by using array */
  92. static const int txqaddr[] = { Q_XA1, Q_XA2 };
  93. static const int rxqaddr[] = { Q_R1, Q_R2 };
  94. static const u32 rxirqmask[] = { IS_R1_F, IS_R2_F };
  95. static const u32 txirqmask[] = { IS_XA1_F, IS_XA2_F };
  96. static const u32 napimask[] = { IS_R1_F|IS_XA1_F, IS_R2_F|IS_XA2_F };
  97. static const u32 portmask[] = { IS_PORT_1, IS_PORT_2 };
  98. static inline bool is_genesis(const struct skge_hw *hw)
  99. {
  100. #ifdef CONFIG_SKGE_GENESIS
  101. return hw->chip_id == CHIP_ID_GENESIS;
  102. #else
  103. return false;
  104. #endif
  105. }
  106. static int skge_get_regs_len(struct net_device *dev)
  107. {
  108. return 0x4000;
  109. }
  110. /*
  111. * Returns copy of whole control register region
  112. * Note: skip RAM address register because accessing it will
  113. * cause bus hangs!
  114. */
  115. static void skge_get_regs(struct net_device *dev, struct ethtool_regs *regs,
  116. void *p)
  117. {
  118. const struct skge_port *skge = netdev_priv(dev);
  119. const void __iomem *io = skge->hw->regs;
  120. regs->version = 1;
  121. memset(p, 0, regs->len);
  122. memcpy_fromio(p, io, B3_RAM_ADDR);
  123. if (regs->len > B3_RI_WTO_R1) {
  124. memcpy_fromio(p + B3_RI_WTO_R1, io + B3_RI_WTO_R1,
  125. regs->len - B3_RI_WTO_R1);
  126. }
  127. }
  128. /* Wake on Lan only supported on Yukon chips with rev 1 or above */
  129. static u32 wol_supported(const struct skge_hw *hw)
  130. {
  131. if (is_genesis(hw))
  132. return 0;
  133. if (hw->chip_id == CHIP_ID_YUKON && hw->chip_rev == 0)
  134. return 0;
  135. return WAKE_MAGIC | WAKE_PHY;
  136. }
  137. static void skge_wol_init(struct skge_port *skge)
  138. {
  139. struct skge_hw *hw = skge->hw;
  140. int port = skge->port;
  141. u16 ctrl;
  142. skge_write16(hw, B0_CTST, CS_RST_CLR);
  143. skge_write16(hw, SK_REG(port, GMAC_LINK_CTRL), GMLC_RST_CLR);
  144. /* Turn on Vaux */
  145. skge_write8(hw, B0_POWER_CTRL,
  146. PC_VAUX_ENA | PC_VCC_ENA | PC_VAUX_ON | PC_VCC_OFF);
  147. /* WA code for COMA mode -- clear PHY reset */
  148. if (hw->chip_id == CHIP_ID_YUKON_LITE &&
  149. hw->chip_rev >= CHIP_REV_YU_LITE_A3) {
  150. u32 reg = skge_read32(hw, B2_GP_IO);
  151. reg |= GP_DIR_9;
  152. reg &= ~GP_IO_9;
  153. skge_write32(hw, B2_GP_IO, reg);
  154. }
  155. skge_write32(hw, SK_REG(port, GPHY_CTRL),
  156. GPC_DIS_SLEEP |
  157. GPC_HWCFG_M_3 | GPC_HWCFG_M_2 | GPC_HWCFG_M_1 | GPC_HWCFG_M_0 |
  158. GPC_ANEG_1 | GPC_RST_SET);
  159. skge_write32(hw, SK_REG(port, GPHY_CTRL),
  160. GPC_DIS_SLEEP |
  161. GPC_HWCFG_M_3 | GPC_HWCFG_M_2 | GPC_HWCFG_M_1 | GPC_HWCFG_M_0 |
  162. GPC_ANEG_1 | GPC_RST_CLR);
  163. skge_write32(hw, SK_REG(port, GMAC_CTRL), GMC_RST_CLR);
  164. /* Force to 10/100 skge_reset will re-enable on resume */
  165. gm_phy_write(hw, port, PHY_MARV_AUNE_ADV,
  166. (PHY_AN_100FULL | PHY_AN_100HALF |
  167. PHY_AN_10FULL | PHY_AN_10HALF | PHY_AN_CSMA));
  168. /* no 1000 HD/FD */
  169. gm_phy_write(hw, port, PHY_MARV_1000T_CTRL, 0);
  170. gm_phy_write(hw, port, PHY_MARV_CTRL,
  171. PHY_CT_RESET | PHY_CT_SPS_LSB | PHY_CT_ANE |
  172. PHY_CT_RE_CFG | PHY_CT_DUP_MD);
  173. /* Set GMAC to no flow control and auto update for speed/duplex */
  174. gma_write16(hw, port, GM_GP_CTRL,
  175. GM_GPCR_FC_TX_DIS|GM_GPCR_TX_ENA|GM_GPCR_RX_ENA|
  176. GM_GPCR_DUP_FULL|GM_GPCR_FC_RX_DIS|GM_GPCR_AU_FCT_DIS);
  177. /* Set WOL address */
  178. memcpy_toio(hw->regs + WOL_REGS(port, WOL_MAC_ADDR),
  179. skge->netdev->dev_addr, ETH_ALEN);
  180. /* Turn on appropriate WOL control bits */
  181. skge_write16(hw, WOL_REGS(port, WOL_CTRL_STAT), WOL_CTL_CLEAR_RESULT);
  182. ctrl = 0;
  183. if (skge->wol & WAKE_PHY)
  184. ctrl |= WOL_CTL_ENA_PME_ON_LINK_CHG|WOL_CTL_ENA_LINK_CHG_UNIT;
  185. else
  186. ctrl |= WOL_CTL_DIS_PME_ON_LINK_CHG|WOL_CTL_DIS_LINK_CHG_UNIT;
  187. if (skge->wol & WAKE_MAGIC)
  188. ctrl |= WOL_CTL_ENA_PME_ON_MAGIC_PKT|WOL_CTL_ENA_MAGIC_PKT_UNIT;
  189. else
  190. ctrl |= WOL_CTL_DIS_PME_ON_MAGIC_PKT|WOL_CTL_DIS_MAGIC_PKT_UNIT;
  191. ctrl |= WOL_CTL_DIS_PME_ON_PATTERN|WOL_CTL_DIS_PATTERN_UNIT;
  192. skge_write16(hw, WOL_REGS(port, WOL_CTRL_STAT), ctrl);
  193. /* block receiver */
  194. skge_write8(hw, SK_REG(port, RX_GMF_CTRL_T), GMF_RST_SET);
  195. }
  196. static void skge_get_wol(struct net_device *dev, struct ethtool_wolinfo *wol)
  197. {
  198. struct skge_port *skge = netdev_priv(dev);
  199. wol->supported = wol_supported(skge->hw);
  200. wol->wolopts = skge->wol;
  201. }
  202. static int skge_set_wol(struct net_device *dev, struct ethtool_wolinfo *wol)
  203. {
  204. struct skge_port *skge = netdev_priv(dev);
  205. struct skge_hw *hw = skge->hw;
  206. if ((wol->wolopts & ~wol_supported(hw)) ||
  207. !device_can_wakeup(&hw->pdev->dev))
  208. return -EOPNOTSUPP;
  209. skge->wol = wol->wolopts;
  210. device_set_wakeup_enable(&hw->pdev->dev, skge->wol);
  211. return 0;
  212. }
  213. /* Determine supported/advertised modes based on hardware.
  214. * Note: ethtool ADVERTISED_xxx == SUPPORTED_xxx
  215. */
  216. static u32 skge_supported_modes(const struct skge_hw *hw)
  217. {
  218. u32 supported;
  219. if (hw->copper) {
  220. supported = (SUPPORTED_10baseT_Half |
  221. SUPPORTED_10baseT_Full |
  222. SUPPORTED_100baseT_Half |
  223. SUPPORTED_100baseT_Full |
  224. SUPPORTED_1000baseT_Half |
  225. SUPPORTED_1000baseT_Full |
  226. SUPPORTED_Autoneg |
  227. SUPPORTED_TP);
  228. if (is_genesis(hw))
  229. supported &= ~(SUPPORTED_10baseT_Half |
  230. SUPPORTED_10baseT_Full |
  231. SUPPORTED_100baseT_Half |
  232. SUPPORTED_100baseT_Full);
  233. else if (hw->chip_id == CHIP_ID_YUKON)
  234. supported &= ~SUPPORTED_1000baseT_Half;
  235. } else
  236. supported = (SUPPORTED_1000baseT_Full |
  237. SUPPORTED_1000baseT_Half |
  238. SUPPORTED_FIBRE |
  239. SUPPORTED_Autoneg);
  240. return supported;
  241. }
  242. static int skge_get_link_ksettings(struct net_device *dev,
  243. struct ethtool_link_ksettings *cmd)
  244. {
  245. struct skge_port *skge = netdev_priv(dev);
  246. struct skge_hw *hw = skge->hw;
  247. u32 supported, advertising;
  248. supported = skge_supported_modes(hw);
  249. if (hw->copper) {
  250. cmd->base.port = PORT_TP;
  251. cmd->base.phy_address = hw->phy_addr;
  252. } else
  253. cmd->base.port = PORT_FIBRE;
  254. advertising = skge->advertising;
  255. cmd->base.autoneg = skge->autoneg;
  256. cmd->base.speed = skge->speed;
  257. cmd->base.duplex = skge->duplex;
  258. ethtool_convert_legacy_u32_to_link_mode(cmd->link_modes.supported,
  259. supported);
  260. ethtool_convert_legacy_u32_to_link_mode(cmd->link_modes.advertising,
  261. advertising);
  262. return 0;
  263. }
  264. static int skge_set_link_ksettings(struct net_device *dev,
  265. const struct ethtool_link_ksettings *cmd)
  266. {
  267. struct skge_port *skge = netdev_priv(dev);
  268. const struct skge_hw *hw = skge->hw;
  269. u32 supported = skge_supported_modes(hw);
  270. int err = 0;
  271. u32 advertising;
  272. ethtool_convert_link_mode_to_legacy_u32(&advertising,
  273. cmd->link_modes.advertising);
  274. if (cmd->base.autoneg == AUTONEG_ENABLE) {
  275. advertising = supported;
  276. skge->duplex = -1;
  277. skge->speed = -1;
  278. } else {
  279. u32 setting;
  280. u32 speed = cmd->base.speed;
  281. switch (speed) {
  282. case SPEED_1000:
  283. if (cmd->base.duplex == DUPLEX_FULL)
  284. setting = SUPPORTED_1000baseT_Full;
  285. else if (cmd->base.duplex == DUPLEX_HALF)
  286. setting = SUPPORTED_1000baseT_Half;
  287. else
  288. return -EINVAL;
  289. break;
  290. case SPEED_100:
  291. if (cmd->base.duplex == DUPLEX_FULL)
  292. setting = SUPPORTED_100baseT_Full;
  293. else if (cmd->base.duplex == DUPLEX_HALF)
  294. setting = SUPPORTED_100baseT_Half;
  295. else
  296. return -EINVAL;
  297. break;
  298. case SPEED_10:
  299. if (cmd->base.duplex == DUPLEX_FULL)
  300. setting = SUPPORTED_10baseT_Full;
  301. else if (cmd->base.duplex == DUPLEX_HALF)
  302. setting = SUPPORTED_10baseT_Half;
  303. else
  304. return -EINVAL;
  305. break;
  306. default:
  307. return -EINVAL;
  308. }
  309. if ((setting & supported) == 0)
  310. return -EINVAL;
  311. skge->speed = speed;
  312. skge->duplex = cmd->base.duplex;
  313. }
  314. skge->autoneg = cmd->base.autoneg;
  315. skge->advertising = advertising;
  316. if (netif_running(dev)) {
  317. skge_down(dev);
  318. err = skge_up(dev);
  319. if (err) {
  320. dev_close(dev);
  321. return err;
  322. }
  323. }
  324. return 0;
  325. }
  326. static void skge_get_drvinfo(struct net_device *dev,
  327. struct ethtool_drvinfo *info)
  328. {
  329. struct skge_port *skge = netdev_priv(dev);
  330. strscpy(info->driver, DRV_NAME, sizeof(info->driver));
  331. strscpy(info->version, DRV_VERSION, sizeof(info->version));
  332. strscpy(info->bus_info, pci_name(skge->hw->pdev),
  333. sizeof(info->bus_info));
  334. }
  335. static const struct skge_stat {
  336. char name[ETH_GSTRING_LEN];
  337. u16 xmac_offset;
  338. u16 gma_offset;
  339. } skge_stats[] = {
  340. { "tx_bytes", XM_TXO_OK_HI, GM_TXO_OK_HI },
  341. { "rx_bytes", XM_RXO_OK_HI, GM_RXO_OK_HI },
  342. { "tx_broadcast", XM_TXF_BC_OK, GM_TXF_BC_OK },
  343. { "rx_broadcast", XM_RXF_BC_OK, GM_RXF_BC_OK },
  344. { "tx_multicast", XM_TXF_MC_OK, GM_TXF_MC_OK },
  345. { "rx_multicast", XM_RXF_MC_OK, GM_RXF_MC_OK },
  346. { "tx_unicast", XM_TXF_UC_OK, GM_TXF_UC_OK },
  347. { "rx_unicast", XM_RXF_UC_OK, GM_RXF_UC_OK },
  348. { "tx_mac_pause", XM_TXF_MPAUSE, GM_TXF_MPAUSE },
  349. { "rx_mac_pause", XM_RXF_MPAUSE, GM_RXF_MPAUSE },
  350. { "collisions", XM_TXF_SNG_COL, GM_TXF_SNG_COL },
  351. { "multi_collisions", XM_TXF_MUL_COL, GM_TXF_MUL_COL },
  352. { "aborted", XM_TXF_ABO_COL, GM_TXF_ABO_COL },
  353. { "late_collision", XM_TXF_LAT_COL, GM_TXF_LAT_COL },
  354. { "fifo_underrun", XM_TXE_FIFO_UR, GM_TXE_FIFO_UR },
  355. { "fifo_overflow", XM_RXE_FIFO_OV, GM_RXE_FIFO_OV },
  356. { "rx_toolong", XM_RXF_LNG_ERR, GM_RXF_LNG_ERR },
  357. { "rx_jabber", XM_RXF_JAB_PKT, GM_RXF_JAB_PKT },
  358. { "rx_runt", XM_RXE_RUNT, GM_RXE_FRAG },
  359. { "rx_too_long", XM_RXF_LNG_ERR, GM_RXF_LNG_ERR },
  360. { "rx_fcs_error", XM_RXF_FCS_ERR, GM_RXF_FCS_ERR },
  361. };
  362. static int skge_get_sset_count(struct net_device *dev, int sset)
  363. {
  364. switch (sset) {
  365. case ETH_SS_STATS:
  366. return ARRAY_SIZE(skge_stats);
  367. default:
  368. return -EOPNOTSUPP;
  369. }
  370. }
  371. static void skge_get_ethtool_stats(struct net_device *dev,
  372. struct ethtool_stats *stats, u64 *data)
  373. {
  374. struct skge_port *skge = netdev_priv(dev);
  375. if (is_genesis(skge->hw))
  376. genesis_get_stats(skge, data);
  377. else
  378. yukon_get_stats(skge, data);
  379. }
  380. /* Use hardware MIB variables for critical path statistics and
  381. * transmit feedback not reported at interrupt.
  382. * Other errors are accounted for in interrupt handler.
  383. */
  384. static struct net_device_stats *skge_get_stats(struct net_device *dev)
  385. {
  386. struct skge_port *skge = netdev_priv(dev);
  387. u64 data[ARRAY_SIZE(skge_stats)];
  388. if (is_genesis(skge->hw))
  389. genesis_get_stats(skge, data);
  390. else
  391. yukon_get_stats(skge, data);
  392. dev->stats.tx_bytes = data[0];
  393. dev->stats.rx_bytes = data[1];
  394. dev->stats.tx_packets = data[2] + data[4] + data[6];
  395. dev->stats.rx_packets = data[3] + data[5] + data[7];
  396. dev->stats.multicast = data[3] + data[5];
  397. dev->stats.collisions = data[10];
  398. dev->stats.tx_aborted_errors = data[12];
  399. return &dev->stats;
  400. }
  401. static void skge_get_strings(struct net_device *dev, u32 stringset, u8 *data)
  402. {
  403. int i;
  404. switch (stringset) {
  405. case ETH_SS_STATS:
  406. for (i = 0; i < ARRAY_SIZE(skge_stats); i++)
  407. ethtool_puts(&data, skge_stats[i].name);
  408. break;
  409. }
  410. }
  411. static void skge_get_ring_param(struct net_device *dev,
  412. struct ethtool_ringparam *p,
  413. struct kernel_ethtool_ringparam *kernel_p,
  414. struct netlink_ext_ack *extack)
  415. {
  416. struct skge_port *skge = netdev_priv(dev);
  417. p->rx_max_pending = MAX_RX_RING_SIZE;
  418. p->tx_max_pending = MAX_TX_RING_SIZE;
  419. p->rx_pending = skge->rx_ring.count;
  420. p->tx_pending = skge->tx_ring.count;
  421. }
  422. static int skge_set_ring_param(struct net_device *dev,
  423. struct ethtool_ringparam *p,
  424. struct kernel_ethtool_ringparam *kernel_p,
  425. struct netlink_ext_ack *extack)
  426. {
  427. struct skge_port *skge = netdev_priv(dev);
  428. int err = 0;
  429. if (p->rx_pending == 0 || p->rx_pending > MAX_RX_RING_SIZE ||
  430. p->tx_pending < TX_LOW_WATER || p->tx_pending > MAX_TX_RING_SIZE)
  431. return -EINVAL;
  432. skge->rx_ring.count = p->rx_pending;
  433. skge->tx_ring.count = p->tx_pending;
  434. if (netif_running(dev)) {
  435. skge_down(dev);
  436. err = skge_up(dev);
  437. if (err)
  438. dev_close(dev);
  439. }
  440. return err;
  441. }
  442. static u32 skge_get_msglevel(struct net_device *netdev)
  443. {
  444. struct skge_port *skge = netdev_priv(netdev);
  445. return skge->msg_enable;
  446. }
  447. static void skge_set_msglevel(struct net_device *netdev, u32 value)
  448. {
  449. struct skge_port *skge = netdev_priv(netdev);
  450. skge->msg_enable = value;
  451. }
  452. static int skge_nway_reset(struct net_device *dev)
  453. {
  454. struct skge_port *skge = netdev_priv(dev);
  455. if (skge->autoneg != AUTONEG_ENABLE || !netif_running(dev))
  456. return -EINVAL;
  457. skge_phy_reset(skge);
  458. return 0;
  459. }
  460. static void skge_get_pauseparam(struct net_device *dev,
  461. struct ethtool_pauseparam *ecmd)
  462. {
  463. struct skge_port *skge = netdev_priv(dev);
  464. ecmd->rx_pause = ((skge->flow_control == FLOW_MODE_SYMMETRIC) ||
  465. (skge->flow_control == FLOW_MODE_SYM_OR_REM));
  466. ecmd->tx_pause = (ecmd->rx_pause ||
  467. (skge->flow_control == FLOW_MODE_LOC_SEND));
  468. ecmd->autoneg = ecmd->rx_pause || ecmd->tx_pause;
  469. }
  470. static int skge_set_pauseparam(struct net_device *dev,
  471. struct ethtool_pauseparam *ecmd)
  472. {
  473. struct skge_port *skge = netdev_priv(dev);
  474. struct ethtool_pauseparam old;
  475. int err = 0;
  476. skge_get_pauseparam(dev, &old);
  477. if (ecmd->autoneg != old.autoneg)
  478. skge->flow_control = ecmd->autoneg ? FLOW_MODE_NONE : FLOW_MODE_SYMMETRIC;
  479. else {
  480. if (ecmd->rx_pause && ecmd->tx_pause)
  481. skge->flow_control = FLOW_MODE_SYMMETRIC;
  482. else if (ecmd->rx_pause && !ecmd->tx_pause)
  483. skge->flow_control = FLOW_MODE_SYM_OR_REM;
  484. else if (!ecmd->rx_pause && ecmd->tx_pause)
  485. skge->flow_control = FLOW_MODE_LOC_SEND;
  486. else
  487. skge->flow_control = FLOW_MODE_NONE;
  488. }
  489. if (netif_running(dev)) {
  490. skge_down(dev);
  491. err = skge_up(dev);
  492. if (err) {
  493. dev_close(dev);
  494. return err;
  495. }
  496. }
  497. return 0;
  498. }
  499. /* Chip internal frequency for clock calculations */
  500. static inline u32 hwkhz(const struct skge_hw *hw)
  501. {
  502. return is_genesis(hw) ? 53125 : 78125;
  503. }
  504. /* Chip HZ to microseconds */
  505. static inline u32 skge_clk2usec(const struct skge_hw *hw, u32 ticks)
  506. {
  507. return (ticks * 1000) / hwkhz(hw);
  508. }
  509. /* Microseconds to chip HZ */
  510. static inline u32 skge_usecs2clk(const struct skge_hw *hw, u32 usec)
  511. {
  512. return hwkhz(hw) * usec / 1000;
  513. }
  514. static int skge_get_coalesce(struct net_device *dev,
  515. struct ethtool_coalesce *ecmd,
  516. struct kernel_ethtool_coalesce *kernel_coal,
  517. struct netlink_ext_ack *extack)
  518. {
  519. struct skge_port *skge = netdev_priv(dev);
  520. struct skge_hw *hw = skge->hw;
  521. int port = skge->port;
  522. ecmd->rx_coalesce_usecs = 0;
  523. ecmd->tx_coalesce_usecs = 0;
  524. if (skge_read32(hw, B2_IRQM_CTRL) & TIM_START) {
  525. u32 delay = skge_clk2usec(hw, skge_read32(hw, B2_IRQM_INI));
  526. u32 msk = skge_read32(hw, B2_IRQM_MSK);
  527. if (msk & rxirqmask[port])
  528. ecmd->rx_coalesce_usecs = delay;
  529. if (msk & txirqmask[port])
  530. ecmd->tx_coalesce_usecs = delay;
  531. }
  532. return 0;
  533. }
  534. /* Note: interrupt timer is per board, but can turn on/off per port */
  535. static int skge_set_coalesce(struct net_device *dev,
  536. struct ethtool_coalesce *ecmd,
  537. struct kernel_ethtool_coalesce *kernel_coal,
  538. struct netlink_ext_ack *extack)
  539. {
  540. struct skge_port *skge = netdev_priv(dev);
  541. struct skge_hw *hw = skge->hw;
  542. int port = skge->port;
  543. u32 msk = skge_read32(hw, B2_IRQM_MSK);
  544. u32 delay = 25;
  545. if (ecmd->rx_coalesce_usecs == 0)
  546. msk &= ~rxirqmask[port];
  547. else if (ecmd->rx_coalesce_usecs < 25 ||
  548. ecmd->rx_coalesce_usecs > 33333)
  549. return -EINVAL;
  550. else {
  551. msk |= rxirqmask[port];
  552. delay = ecmd->rx_coalesce_usecs;
  553. }
  554. if (ecmd->tx_coalesce_usecs == 0)
  555. msk &= ~txirqmask[port];
  556. else if (ecmd->tx_coalesce_usecs < 25 ||
  557. ecmd->tx_coalesce_usecs > 33333)
  558. return -EINVAL;
  559. else {
  560. msk |= txirqmask[port];
  561. delay = min(delay, ecmd->rx_coalesce_usecs);
  562. }
  563. skge_write32(hw, B2_IRQM_MSK, msk);
  564. if (msk == 0)
  565. skge_write32(hw, B2_IRQM_CTRL, TIM_STOP);
  566. else {
  567. skge_write32(hw, B2_IRQM_INI, skge_usecs2clk(hw, delay));
  568. skge_write32(hw, B2_IRQM_CTRL, TIM_START);
  569. }
  570. return 0;
  571. }
  572. enum led_mode { LED_MODE_OFF, LED_MODE_ON, LED_MODE_TST };
  573. static void skge_led(struct skge_port *skge, enum led_mode mode)
  574. {
  575. struct skge_hw *hw = skge->hw;
  576. int port = skge->port;
  577. spin_lock_bh(&hw->phy_lock);
  578. if (is_genesis(hw)) {
  579. switch (mode) {
  580. case LED_MODE_OFF:
  581. if (hw->phy_type == SK_PHY_BCOM)
  582. xm_phy_write(hw, port, PHY_BCOM_P_EXT_CTRL, PHY_B_PEC_LED_OFF);
  583. else {
  584. skge_write32(hw, SK_REG(port, TX_LED_VAL), 0);
  585. skge_write8(hw, SK_REG(port, TX_LED_CTRL), LED_T_OFF);
  586. }
  587. skge_write8(hw, SK_REG(port, LNK_LED_REG), LINKLED_OFF);
  588. skge_write32(hw, SK_REG(port, RX_LED_VAL), 0);
  589. skge_write8(hw, SK_REG(port, RX_LED_CTRL), LED_T_OFF);
  590. break;
  591. case LED_MODE_ON:
  592. skge_write8(hw, SK_REG(port, LNK_LED_REG), LINKLED_ON);
  593. skge_write8(hw, SK_REG(port, LNK_LED_REG), LINKLED_LINKSYNC_ON);
  594. skge_write8(hw, SK_REG(port, RX_LED_CTRL), LED_START);
  595. skge_write8(hw, SK_REG(port, TX_LED_CTRL), LED_START);
  596. break;
  597. case LED_MODE_TST:
  598. skge_write8(hw, SK_REG(port, RX_LED_TST), LED_T_ON);
  599. skge_write32(hw, SK_REG(port, RX_LED_VAL), 100);
  600. skge_write8(hw, SK_REG(port, RX_LED_CTRL), LED_START);
  601. if (hw->phy_type == SK_PHY_BCOM)
  602. xm_phy_write(hw, port, PHY_BCOM_P_EXT_CTRL, PHY_B_PEC_LED_ON);
  603. else {
  604. skge_write8(hw, SK_REG(port, TX_LED_TST), LED_T_ON);
  605. skge_write32(hw, SK_REG(port, TX_LED_VAL), 100);
  606. skge_write8(hw, SK_REG(port, TX_LED_CTRL), LED_START);
  607. }
  608. }
  609. } else {
  610. switch (mode) {
  611. case LED_MODE_OFF:
  612. gm_phy_write(hw, port, PHY_MARV_LED_CTRL, 0);
  613. gm_phy_write(hw, port, PHY_MARV_LED_OVER,
  614. PHY_M_LED_MO_DUP(MO_LED_OFF) |
  615. PHY_M_LED_MO_10(MO_LED_OFF) |
  616. PHY_M_LED_MO_100(MO_LED_OFF) |
  617. PHY_M_LED_MO_1000(MO_LED_OFF) |
  618. PHY_M_LED_MO_RX(MO_LED_OFF));
  619. break;
  620. case LED_MODE_ON:
  621. gm_phy_write(hw, port, PHY_MARV_LED_CTRL,
  622. PHY_M_LED_PULS_DUR(PULS_170MS) |
  623. PHY_M_LED_BLINK_RT(BLINK_84MS) |
  624. PHY_M_LEDC_TX_CTRL |
  625. PHY_M_LEDC_DP_CTRL);
  626. gm_phy_write(hw, port, PHY_MARV_LED_OVER,
  627. PHY_M_LED_MO_RX(MO_LED_OFF) |
  628. (skge->speed == SPEED_100 ?
  629. PHY_M_LED_MO_100(MO_LED_ON) : 0));
  630. break;
  631. case LED_MODE_TST:
  632. gm_phy_write(hw, port, PHY_MARV_LED_CTRL, 0);
  633. gm_phy_write(hw, port, PHY_MARV_LED_OVER,
  634. PHY_M_LED_MO_DUP(MO_LED_ON) |
  635. PHY_M_LED_MO_10(MO_LED_ON) |
  636. PHY_M_LED_MO_100(MO_LED_ON) |
  637. PHY_M_LED_MO_1000(MO_LED_ON) |
  638. PHY_M_LED_MO_RX(MO_LED_ON));
  639. }
  640. }
  641. spin_unlock_bh(&hw->phy_lock);
  642. }
  643. /* blink LED's for finding board */
  644. static int skge_set_phys_id(struct net_device *dev,
  645. enum ethtool_phys_id_state state)
  646. {
  647. struct skge_port *skge = netdev_priv(dev);
  648. switch (state) {
  649. case ETHTOOL_ID_ACTIVE:
  650. return 2; /* cycle on/off twice per second */
  651. case ETHTOOL_ID_ON:
  652. skge_led(skge, LED_MODE_TST);
  653. break;
  654. case ETHTOOL_ID_OFF:
  655. skge_led(skge, LED_MODE_OFF);
  656. break;
  657. case ETHTOOL_ID_INACTIVE:
  658. /* back to regular LED state */
  659. skge_led(skge, netif_running(dev) ? LED_MODE_ON : LED_MODE_OFF);
  660. }
  661. return 0;
  662. }
  663. static int skge_get_eeprom_len(struct net_device *dev)
  664. {
  665. struct skge_port *skge = netdev_priv(dev);
  666. u32 reg2;
  667. pci_read_config_dword(skge->hw->pdev, PCI_DEV_REG2, &reg2);
  668. return 1 << (((reg2 & PCI_VPD_ROM_SZ) >> 14) + 8);
  669. }
  670. static u32 skge_vpd_read(struct pci_dev *pdev, int cap, u16 offset)
  671. {
  672. u32 val;
  673. pci_write_config_word(pdev, cap + PCI_VPD_ADDR, offset);
  674. do {
  675. pci_read_config_word(pdev, cap + PCI_VPD_ADDR, &offset);
  676. } while (!(offset & PCI_VPD_ADDR_F));
  677. pci_read_config_dword(pdev, cap + PCI_VPD_DATA, &val);
  678. return val;
  679. }
  680. static void skge_vpd_write(struct pci_dev *pdev, int cap, u16 offset, u32 val)
  681. {
  682. pci_write_config_dword(pdev, cap + PCI_VPD_DATA, val);
  683. pci_write_config_word(pdev, cap + PCI_VPD_ADDR,
  684. offset | PCI_VPD_ADDR_F);
  685. do {
  686. pci_read_config_word(pdev, cap + PCI_VPD_ADDR, &offset);
  687. } while (offset & PCI_VPD_ADDR_F);
  688. }
  689. static int skge_get_eeprom(struct net_device *dev, struct ethtool_eeprom *eeprom,
  690. u8 *data)
  691. {
  692. struct skge_port *skge = netdev_priv(dev);
  693. struct pci_dev *pdev = skge->hw->pdev;
  694. int cap = pci_find_capability(pdev, PCI_CAP_ID_VPD);
  695. int length = eeprom->len;
  696. u16 offset = eeprom->offset;
  697. if (!cap)
  698. return -EINVAL;
  699. eeprom->magic = SKGE_EEPROM_MAGIC;
  700. while (length > 0) {
  701. u32 val = skge_vpd_read(pdev, cap, offset);
  702. int n = min_t(int, length, sizeof(val));
  703. memcpy(data, &val, n);
  704. length -= n;
  705. data += n;
  706. offset += n;
  707. }
  708. return 0;
  709. }
  710. static int skge_set_eeprom(struct net_device *dev, struct ethtool_eeprom *eeprom,
  711. u8 *data)
  712. {
  713. struct skge_port *skge = netdev_priv(dev);
  714. struct pci_dev *pdev = skge->hw->pdev;
  715. int cap = pci_find_capability(pdev, PCI_CAP_ID_VPD);
  716. int length = eeprom->len;
  717. u16 offset = eeprom->offset;
  718. if (!cap)
  719. return -EINVAL;
  720. if (eeprom->magic != SKGE_EEPROM_MAGIC)
  721. return -EINVAL;
  722. while (length > 0) {
  723. u32 val;
  724. int n = min_t(int, length, sizeof(val));
  725. if (n < sizeof(val))
  726. val = skge_vpd_read(pdev, cap, offset);
  727. memcpy(&val, data, n);
  728. skge_vpd_write(pdev, cap, offset, val);
  729. length -= n;
  730. data += n;
  731. offset += n;
  732. }
  733. return 0;
  734. }
  735. static const struct ethtool_ops skge_ethtool_ops = {
  736. .supported_coalesce_params = ETHTOOL_COALESCE_USECS,
  737. .get_drvinfo = skge_get_drvinfo,
  738. .get_regs_len = skge_get_regs_len,
  739. .get_regs = skge_get_regs,
  740. .get_wol = skge_get_wol,
  741. .set_wol = skge_set_wol,
  742. .get_msglevel = skge_get_msglevel,
  743. .set_msglevel = skge_set_msglevel,
  744. .nway_reset = skge_nway_reset,
  745. .get_link = ethtool_op_get_link,
  746. .get_eeprom_len = skge_get_eeprom_len,
  747. .get_eeprom = skge_get_eeprom,
  748. .set_eeprom = skge_set_eeprom,
  749. .get_ringparam = skge_get_ring_param,
  750. .set_ringparam = skge_set_ring_param,
  751. .get_pauseparam = skge_get_pauseparam,
  752. .set_pauseparam = skge_set_pauseparam,
  753. .get_coalesce = skge_get_coalesce,
  754. .set_coalesce = skge_set_coalesce,
  755. .get_strings = skge_get_strings,
  756. .set_phys_id = skge_set_phys_id,
  757. .get_sset_count = skge_get_sset_count,
  758. .get_ethtool_stats = skge_get_ethtool_stats,
  759. .get_link_ksettings = skge_get_link_ksettings,
  760. .set_link_ksettings = skge_set_link_ksettings,
  761. };
  762. /*
  763. * Allocate ring elements and chain them together
  764. * One-to-one association of board descriptors with ring elements
  765. */
  766. static int skge_ring_alloc(struct skge_ring *ring, void *vaddr, u32 base)
  767. {
  768. struct skge_tx_desc *d;
  769. struct skge_element *e;
  770. int i;
  771. ring->start = kzalloc_objs(*e, ring->count);
  772. if (!ring->start)
  773. return -ENOMEM;
  774. for (i = 0, e = ring->start, d = vaddr; i < ring->count; i++, e++, d++) {
  775. e->desc = d;
  776. if (i == ring->count - 1) {
  777. e->next = ring->start;
  778. d->next_offset = base;
  779. } else {
  780. e->next = e + 1;
  781. d->next_offset = base + (i+1) * sizeof(*d);
  782. }
  783. }
  784. ring->to_use = ring->to_clean = ring->start;
  785. return 0;
  786. }
  787. /* Allocate and setup a new buffer for receiving */
  788. static int skge_rx_setup(struct skge_port *skge, struct skge_element *e,
  789. struct sk_buff *skb, unsigned int bufsize)
  790. {
  791. struct skge_rx_desc *rd = e->desc;
  792. dma_addr_t map;
  793. map = dma_map_single(&skge->hw->pdev->dev, skb->data, bufsize,
  794. DMA_FROM_DEVICE);
  795. if (dma_mapping_error(&skge->hw->pdev->dev, map))
  796. return -1;
  797. rd->dma_lo = lower_32_bits(map);
  798. rd->dma_hi = upper_32_bits(map);
  799. e->skb = skb;
  800. rd->csum1_start = ETH_HLEN;
  801. rd->csum2_start = ETH_HLEN;
  802. rd->csum1 = 0;
  803. rd->csum2 = 0;
  804. wmb();
  805. rd->control = BMU_OWN | BMU_STF | BMU_IRQ_EOF | BMU_TCP_CHECK | bufsize;
  806. dma_unmap_addr_set(e, mapaddr, map);
  807. dma_unmap_len_set(e, maplen, bufsize);
  808. return 0;
  809. }
  810. /* Resume receiving using existing skb,
  811. * Note: DMA address is not changed by chip.
  812. * MTU not changed while receiver active.
  813. */
  814. static inline void skge_rx_reuse(struct skge_element *e, unsigned int size)
  815. {
  816. struct skge_rx_desc *rd = e->desc;
  817. rd->csum2 = 0;
  818. rd->csum2_start = ETH_HLEN;
  819. wmb();
  820. rd->control = BMU_OWN | BMU_STF | BMU_IRQ_EOF | BMU_TCP_CHECK | size;
  821. }
  822. /* Free all buffers in receive ring, assumes receiver stopped */
  823. static void skge_rx_clean(struct skge_port *skge)
  824. {
  825. struct skge_hw *hw = skge->hw;
  826. struct skge_ring *ring = &skge->rx_ring;
  827. struct skge_element *e;
  828. e = ring->start;
  829. do {
  830. struct skge_rx_desc *rd = e->desc;
  831. rd->control = 0;
  832. if (e->skb) {
  833. dma_unmap_single(&hw->pdev->dev,
  834. dma_unmap_addr(e, mapaddr),
  835. dma_unmap_len(e, maplen),
  836. DMA_FROM_DEVICE);
  837. dev_kfree_skb(e->skb);
  838. e->skb = NULL;
  839. }
  840. } while ((e = e->next) != ring->start);
  841. }
  842. /* Allocate buffers for receive ring
  843. * For receive: to_clean is next received frame.
  844. */
  845. static int skge_rx_fill(struct net_device *dev)
  846. {
  847. struct skge_port *skge = netdev_priv(dev);
  848. struct skge_ring *ring = &skge->rx_ring;
  849. struct skge_element *e;
  850. e = ring->start;
  851. do {
  852. struct sk_buff *skb;
  853. skb = __netdev_alloc_skb(dev, skge->rx_buf_size + NET_IP_ALIGN,
  854. GFP_KERNEL);
  855. if (!skb)
  856. return -ENOMEM;
  857. skb_reserve(skb, NET_IP_ALIGN);
  858. if (skge_rx_setup(skge, e, skb, skge->rx_buf_size) < 0) {
  859. dev_kfree_skb(skb);
  860. return -EIO;
  861. }
  862. } while ((e = e->next) != ring->start);
  863. ring->to_clean = ring->start;
  864. return 0;
  865. }
  866. static const char *skge_pause(enum pause_status status)
  867. {
  868. switch (status) {
  869. case FLOW_STAT_NONE:
  870. return "none";
  871. case FLOW_STAT_REM_SEND:
  872. return "rx only";
  873. case FLOW_STAT_LOC_SEND:
  874. return "tx_only";
  875. case FLOW_STAT_SYMMETRIC: /* Both station may send PAUSE */
  876. return "both";
  877. default:
  878. return "indeterminated";
  879. }
  880. }
  881. static void skge_link_up(struct skge_port *skge)
  882. {
  883. skge_write8(skge->hw, SK_REG(skge->port, LNK_LED_REG),
  884. LED_BLK_OFF|LED_SYNC_OFF|LED_REG_ON);
  885. netif_carrier_on(skge->netdev);
  886. netif_wake_queue(skge->netdev);
  887. netif_info(skge, link, skge->netdev,
  888. "Link is up at %d Mbps, %s duplex, flow control %s\n",
  889. skge->speed,
  890. skge->duplex == DUPLEX_FULL ? "full" : "half",
  891. skge_pause(skge->flow_status));
  892. }
  893. static void skge_link_down(struct skge_port *skge)
  894. {
  895. skge_write8(skge->hw, SK_REG(skge->port, LNK_LED_REG), LED_REG_OFF);
  896. netif_carrier_off(skge->netdev);
  897. netif_stop_queue(skge->netdev);
  898. netif_info(skge, link, skge->netdev, "Link is down\n");
  899. }
  900. static void xm_link_down(struct skge_hw *hw, int port)
  901. {
  902. struct net_device *dev = hw->dev[port];
  903. struct skge_port *skge = netdev_priv(dev);
  904. xm_write16(hw, port, XM_IMSK, XM_IMSK_DISABLE);
  905. if (netif_carrier_ok(dev))
  906. skge_link_down(skge);
  907. }
  908. static int __xm_phy_read(struct skge_hw *hw, int port, u16 reg, u16 *val)
  909. {
  910. int i;
  911. xm_write16(hw, port, XM_PHY_ADDR, reg | hw->phy_addr);
  912. *val = xm_read16(hw, port, XM_PHY_DATA);
  913. if (hw->phy_type == SK_PHY_XMAC)
  914. goto ready;
  915. for (i = 0; i < PHY_RETRIES; i++) {
  916. if (xm_read16(hw, port, XM_MMU_CMD) & XM_MMU_PHY_RDY)
  917. goto ready;
  918. udelay(1);
  919. }
  920. return -ETIMEDOUT;
  921. ready:
  922. *val = xm_read16(hw, port, XM_PHY_DATA);
  923. return 0;
  924. }
  925. static u16 xm_phy_read(struct skge_hw *hw, int port, u16 reg)
  926. {
  927. u16 v = 0;
  928. if (__xm_phy_read(hw, port, reg, &v))
  929. pr_warn("%s: phy read timed out\n", hw->dev[port]->name);
  930. return v;
  931. }
  932. static int xm_phy_write(struct skge_hw *hw, int port, u16 reg, u16 val)
  933. {
  934. int i;
  935. xm_write16(hw, port, XM_PHY_ADDR, reg | hw->phy_addr);
  936. for (i = 0; i < PHY_RETRIES; i++) {
  937. if (!(xm_read16(hw, port, XM_MMU_CMD) & XM_MMU_PHY_BUSY))
  938. goto ready;
  939. udelay(1);
  940. }
  941. return -EIO;
  942. ready:
  943. xm_write16(hw, port, XM_PHY_DATA, val);
  944. for (i = 0; i < PHY_RETRIES; i++) {
  945. if (!(xm_read16(hw, port, XM_MMU_CMD) & XM_MMU_PHY_BUSY))
  946. return 0;
  947. udelay(1);
  948. }
  949. return -ETIMEDOUT;
  950. }
  951. static void genesis_init(struct skge_hw *hw)
  952. {
  953. /* set blink source counter */
  954. skge_write32(hw, B2_BSC_INI, (SK_BLK_DUR * SK_FACT_53) / 100);
  955. skge_write8(hw, B2_BSC_CTRL, BSC_START);
  956. /* configure mac arbiter */
  957. skge_write16(hw, B3_MA_TO_CTRL, MA_RST_CLR);
  958. /* configure mac arbiter timeout values */
  959. skge_write8(hw, B3_MA_TOINI_RX1, SK_MAC_TO_53);
  960. skge_write8(hw, B3_MA_TOINI_RX2, SK_MAC_TO_53);
  961. skge_write8(hw, B3_MA_TOINI_TX1, SK_MAC_TO_53);
  962. skge_write8(hw, B3_MA_TOINI_TX2, SK_MAC_TO_53);
  963. skge_write8(hw, B3_MA_RCINI_RX1, 0);
  964. skge_write8(hw, B3_MA_RCINI_RX2, 0);
  965. skge_write8(hw, B3_MA_RCINI_TX1, 0);
  966. skge_write8(hw, B3_MA_RCINI_TX2, 0);
  967. /* configure packet arbiter timeout */
  968. skge_write16(hw, B3_PA_CTRL, PA_RST_CLR);
  969. skge_write16(hw, B3_PA_TOINI_RX1, SK_PKT_TO_MAX);
  970. skge_write16(hw, B3_PA_TOINI_TX1, SK_PKT_TO_MAX);
  971. skge_write16(hw, B3_PA_TOINI_RX2, SK_PKT_TO_MAX);
  972. skge_write16(hw, B3_PA_TOINI_TX2, SK_PKT_TO_MAX);
  973. }
  974. static void genesis_reset(struct skge_hw *hw, int port)
  975. {
  976. static const u8 zero[8] = { 0 };
  977. u32 reg;
  978. skge_write8(hw, SK_REG(port, GMAC_IRQ_MSK), 0);
  979. /* reset the statistics module */
  980. xm_write32(hw, port, XM_GP_PORT, XM_GP_RES_STAT);
  981. xm_write16(hw, port, XM_IMSK, XM_IMSK_DISABLE);
  982. xm_write32(hw, port, XM_MODE, 0); /* clear Mode Reg */
  983. xm_write16(hw, port, XM_TX_CMD, 0); /* reset TX CMD Reg */
  984. xm_write16(hw, port, XM_RX_CMD, 0); /* reset RX CMD Reg */
  985. /* disable Broadcom PHY IRQ */
  986. if (hw->phy_type == SK_PHY_BCOM)
  987. xm_write16(hw, port, PHY_BCOM_INT_MASK, 0xffff);
  988. xm_outhash(hw, port, XM_HSM, zero);
  989. /* Flush TX and RX fifo */
  990. reg = xm_read32(hw, port, XM_MODE);
  991. xm_write32(hw, port, XM_MODE, reg | XM_MD_FTF);
  992. xm_write32(hw, port, XM_MODE, reg | XM_MD_FRF);
  993. }
  994. /* Convert mode to MII values */
  995. static const u16 phy_pause_map[] = {
  996. [FLOW_MODE_NONE] = 0,
  997. [FLOW_MODE_LOC_SEND] = PHY_AN_PAUSE_ASYM,
  998. [FLOW_MODE_SYMMETRIC] = PHY_AN_PAUSE_CAP,
  999. [FLOW_MODE_SYM_OR_REM] = PHY_AN_PAUSE_CAP | PHY_AN_PAUSE_ASYM,
  1000. };
  1001. /* special defines for FIBER (88E1011S only) */
  1002. static const u16 fiber_pause_map[] = {
  1003. [FLOW_MODE_NONE] = PHY_X_P_NO_PAUSE,
  1004. [FLOW_MODE_LOC_SEND] = PHY_X_P_ASYM_MD,
  1005. [FLOW_MODE_SYMMETRIC] = PHY_X_P_SYM_MD,
  1006. [FLOW_MODE_SYM_OR_REM] = PHY_X_P_BOTH_MD,
  1007. };
  1008. /* Check status of Broadcom phy link */
  1009. static void bcom_check_link(struct skge_hw *hw, int port)
  1010. {
  1011. struct net_device *dev = hw->dev[port];
  1012. struct skge_port *skge = netdev_priv(dev);
  1013. u16 status;
  1014. /* read twice because of latch */
  1015. xm_phy_read(hw, port, PHY_BCOM_STAT);
  1016. status = xm_phy_read(hw, port, PHY_BCOM_STAT);
  1017. if ((status & PHY_ST_LSYNC) == 0) {
  1018. xm_link_down(hw, port);
  1019. return;
  1020. }
  1021. if (skge->autoneg == AUTONEG_ENABLE) {
  1022. u16 lpa, aux;
  1023. if (!(status & PHY_ST_AN_OVER))
  1024. return;
  1025. lpa = xm_phy_read(hw, port, PHY_XMAC_AUNE_LP);
  1026. if (lpa & PHY_B_AN_RF) {
  1027. netdev_notice(dev, "remote fault\n");
  1028. return;
  1029. }
  1030. aux = xm_phy_read(hw, port, PHY_BCOM_AUX_STAT);
  1031. /* Check Duplex mismatch */
  1032. switch (aux & PHY_B_AS_AN_RES_MSK) {
  1033. case PHY_B_RES_1000FD:
  1034. skge->duplex = DUPLEX_FULL;
  1035. break;
  1036. case PHY_B_RES_1000HD:
  1037. skge->duplex = DUPLEX_HALF;
  1038. break;
  1039. default:
  1040. netdev_notice(dev, "duplex mismatch\n");
  1041. return;
  1042. }
  1043. /* We are using IEEE 802.3z/D5.0 Table 37-4 */
  1044. switch (aux & PHY_B_AS_PAUSE_MSK) {
  1045. case PHY_B_AS_PAUSE_MSK:
  1046. skge->flow_status = FLOW_STAT_SYMMETRIC;
  1047. break;
  1048. case PHY_B_AS_PRR:
  1049. skge->flow_status = FLOW_STAT_REM_SEND;
  1050. break;
  1051. case PHY_B_AS_PRT:
  1052. skge->flow_status = FLOW_STAT_LOC_SEND;
  1053. break;
  1054. default:
  1055. skge->flow_status = FLOW_STAT_NONE;
  1056. }
  1057. skge->speed = SPEED_1000;
  1058. }
  1059. if (!netif_carrier_ok(dev))
  1060. genesis_link_up(skge);
  1061. }
  1062. /* Broadcom 5400 only supports giagabit! SysKonnect did not put an additional
  1063. * Phy on for 100 or 10Mbit operation
  1064. */
  1065. static void bcom_phy_init(struct skge_port *skge)
  1066. {
  1067. struct skge_hw *hw = skge->hw;
  1068. int port = skge->port;
  1069. int i;
  1070. u16 id1, r, ext, ctl;
  1071. /* magic workaround patterns for Broadcom */
  1072. static const struct {
  1073. u16 reg;
  1074. u16 val;
  1075. } A1hack[] = {
  1076. { 0x18, 0x0c20 }, { 0x17, 0x0012 }, { 0x15, 0x1104 },
  1077. { 0x17, 0x0013 }, { 0x15, 0x0404 }, { 0x17, 0x8006 },
  1078. { 0x15, 0x0132 }, { 0x17, 0x8006 }, { 0x15, 0x0232 },
  1079. { 0x17, 0x800D }, { 0x15, 0x000F }, { 0x18, 0x0420 },
  1080. }, C0hack[] = {
  1081. { 0x18, 0x0c20 }, { 0x17, 0x0012 }, { 0x15, 0x1204 },
  1082. { 0x17, 0x0013 }, { 0x15, 0x0A04 }, { 0x18, 0x0420 },
  1083. };
  1084. /* read Id from external PHY (all have the same address) */
  1085. id1 = xm_phy_read(hw, port, PHY_XMAC_ID1);
  1086. /* Optimize MDIO transfer by suppressing preamble. */
  1087. r = xm_read16(hw, port, XM_MMU_CMD);
  1088. r |= XM_MMU_NO_PRE;
  1089. xm_write16(hw, port, XM_MMU_CMD, r);
  1090. switch (id1) {
  1091. case PHY_BCOM_ID1_C0:
  1092. /*
  1093. * Workaround BCOM Errata for the C0 type.
  1094. * Write magic patterns to reserved registers.
  1095. */
  1096. for (i = 0; i < ARRAY_SIZE(C0hack); i++)
  1097. xm_phy_write(hw, port,
  1098. C0hack[i].reg, C0hack[i].val);
  1099. break;
  1100. case PHY_BCOM_ID1_A1:
  1101. /*
  1102. * Workaround BCOM Errata for the A1 type.
  1103. * Write magic patterns to reserved registers.
  1104. */
  1105. for (i = 0; i < ARRAY_SIZE(A1hack); i++)
  1106. xm_phy_write(hw, port,
  1107. A1hack[i].reg, A1hack[i].val);
  1108. break;
  1109. }
  1110. /*
  1111. * Workaround BCOM Errata (#10523) for all BCom PHYs.
  1112. * Disable Power Management after reset.
  1113. */
  1114. r = xm_phy_read(hw, port, PHY_BCOM_AUX_CTRL);
  1115. r |= PHY_B_AC_DIS_PM;
  1116. xm_phy_write(hw, port, PHY_BCOM_AUX_CTRL, r);
  1117. /* Dummy read */
  1118. xm_read16(hw, port, XM_ISRC);
  1119. ext = PHY_B_PEC_EN_LTR; /* enable tx led */
  1120. ctl = PHY_CT_SP1000; /* always 1000mbit */
  1121. if (skge->autoneg == AUTONEG_ENABLE) {
  1122. /*
  1123. * Workaround BCOM Errata #1 for the C5 type.
  1124. * 1000Base-T Link Acquisition Failure in Slave Mode
  1125. * Set Repeater/DTE bit 10 of the 1000Base-T Control Register
  1126. */
  1127. u16 adv = PHY_B_1000C_RD;
  1128. if (skge->advertising & ADVERTISED_1000baseT_Half)
  1129. adv |= PHY_B_1000C_AHD;
  1130. if (skge->advertising & ADVERTISED_1000baseT_Full)
  1131. adv |= PHY_B_1000C_AFD;
  1132. xm_phy_write(hw, port, PHY_BCOM_1000T_CTRL, adv);
  1133. ctl |= PHY_CT_ANE | PHY_CT_RE_CFG;
  1134. } else {
  1135. if (skge->duplex == DUPLEX_FULL)
  1136. ctl |= PHY_CT_DUP_MD;
  1137. /* Force to slave */
  1138. xm_phy_write(hw, port, PHY_BCOM_1000T_CTRL, PHY_B_1000C_MSE);
  1139. }
  1140. /* Set autonegotiation pause parameters */
  1141. xm_phy_write(hw, port, PHY_BCOM_AUNE_ADV,
  1142. phy_pause_map[skge->flow_control] | PHY_AN_CSMA);
  1143. /* Handle Jumbo frames */
  1144. if (hw->dev[port]->mtu > ETH_DATA_LEN) {
  1145. xm_phy_write(hw, port, PHY_BCOM_AUX_CTRL,
  1146. PHY_B_AC_TX_TST | PHY_B_AC_LONG_PACK);
  1147. ext |= PHY_B_PEC_HIGH_LA;
  1148. }
  1149. xm_phy_write(hw, port, PHY_BCOM_P_EXT_CTRL, ext);
  1150. xm_phy_write(hw, port, PHY_BCOM_CTRL, ctl);
  1151. /* Use link status change interrupt */
  1152. xm_phy_write(hw, port, PHY_BCOM_INT_MASK, PHY_B_DEF_MSK);
  1153. }
  1154. static void xm_phy_init(struct skge_port *skge)
  1155. {
  1156. struct skge_hw *hw = skge->hw;
  1157. int port = skge->port;
  1158. u16 ctrl = 0;
  1159. if (skge->autoneg == AUTONEG_ENABLE) {
  1160. if (skge->advertising & ADVERTISED_1000baseT_Half)
  1161. ctrl |= PHY_X_AN_HD;
  1162. if (skge->advertising & ADVERTISED_1000baseT_Full)
  1163. ctrl |= PHY_X_AN_FD;
  1164. ctrl |= fiber_pause_map[skge->flow_control];
  1165. xm_phy_write(hw, port, PHY_XMAC_AUNE_ADV, ctrl);
  1166. /* Restart Auto-negotiation */
  1167. ctrl = PHY_CT_ANE | PHY_CT_RE_CFG;
  1168. } else {
  1169. /* Set DuplexMode in Config register */
  1170. if (skge->duplex == DUPLEX_FULL)
  1171. ctrl |= PHY_CT_DUP_MD;
  1172. /*
  1173. * Do NOT enable Auto-negotiation here. This would hold
  1174. * the link down because no IDLEs are transmitted
  1175. */
  1176. }
  1177. xm_phy_write(hw, port, PHY_XMAC_CTRL, ctrl);
  1178. /* Poll PHY for status changes */
  1179. mod_timer(&skge->link_timer, jiffies + LINK_HZ);
  1180. }
  1181. static int xm_check_link(struct net_device *dev)
  1182. {
  1183. struct skge_port *skge = netdev_priv(dev);
  1184. struct skge_hw *hw = skge->hw;
  1185. int port = skge->port;
  1186. u16 status;
  1187. /* read twice because of latch */
  1188. xm_phy_read(hw, port, PHY_XMAC_STAT);
  1189. status = xm_phy_read(hw, port, PHY_XMAC_STAT);
  1190. if ((status & PHY_ST_LSYNC) == 0) {
  1191. xm_link_down(hw, port);
  1192. return 0;
  1193. }
  1194. if (skge->autoneg == AUTONEG_ENABLE) {
  1195. u16 lpa, res;
  1196. if (!(status & PHY_ST_AN_OVER))
  1197. return 0;
  1198. lpa = xm_phy_read(hw, port, PHY_XMAC_AUNE_LP);
  1199. if (lpa & PHY_B_AN_RF) {
  1200. netdev_notice(dev, "remote fault\n");
  1201. return 0;
  1202. }
  1203. res = xm_phy_read(hw, port, PHY_XMAC_RES_ABI);
  1204. /* Check Duplex mismatch */
  1205. switch (res & (PHY_X_RS_HD | PHY_X_RS_FD)) {
  1206. case PHY_X_RS_FD:
  1207. skge->duplex = DUPLEX_FULL;
  1208. break;
  1209. case PHY_X_RS_HD:
  1210. skge->duplex = DUPLEX_HALF;
  1211. break;
  1212. default:
  1213. netdev_notice(dev, "duplex mismatch\n");
  1214. return 0;
  1215. }
  1216. /* We are using IEEE 802.3z/D5.0 Table 37-4 */
  1217. if ((skge->flow_control == FLOW_MODE_SYMMETRIC ||
  1218. skge->flow_control == FLOW_MODE_SYM_OR_REM) &&
  1219. (lpa & PHY_X_P_SYM_MD))
  1220. skge->flow_status = FLOW_STAT_SYMMETRIC;
  1221. else if (skge->flow_control == FLOW_MODE_SYM_OR_REM &&
  1222. (lpa & PHY_X_RS_PAUSE) == PHY_X_P_ASYM_MD)
  1223. /* Enable PAUSE receive, disable PAUSE transmit */
  1224. skge->flow_status = FLOW_STAT_REM_SEND;
  1225. else if (skge->flow_control == FLOW_MODE_LOC_SEND &&
  1226. (lpa & PHY_X_RS_PAUSE) == PHY_X_P_BOTH_MD)
  1227. /* Disable PAUSE receive, enable PAUSE transmit */
  1228. skge->flow_status = FLOW_STAT_LOC_SEND;
  1229. else
  1230. skge->flow_status = FLOW_STAT_NONE;
  1231. skge->speed = SPEED_1000;
  1232. }
  1233. if (!netif_carrier_ok(dev))
  1234. genesis_link_up(skge);
  1235. return 1;
  1236. }
  1237. /* Poll to check for link coming up.
  1238. *
  1239. * Since internal PHY is wired to a level triggered pin, can't
  1240. * get an interrupt when carrier is detected, need to poll for
  1241. * link coming up.
  1242. */
  1243. static void xm_link_timer(struct timer_list *t)
  1244. {
  1245. struct skge_port *skge = timer_container_of(skge, t, link_timer);
  1246. struct net_device *dev = skge->netdev;
  1247. struct skge_hw *hw = skge->hw;
  1248. int port = skge->port;
  1249. int i;
  1250. unsigned long flags;
  1251. if (!netif_running(dev))
  1252. return;
  1253. spin_lock_irqsave(&hw->phy_lock, flags);
  1254. /*
  1255. * Verify that the link by checking GPIO register three times.
  1256. * This pin has the signal from the link_sync pin connected to it.
  1257. */
  1258. for (i = 0; i < 3; i++) {
  1259. if (xm_read16(hw, port, XM_GP_PORT) & XM_GP_INP_ASS)
  1260. goto link_down;
  1261. }
  1262. /* Re-enable interrupt to detect link down */
  1263. if (xm_check_link(dev)) {
  1264. u16 msk = xm_read16(hw, port, XM_IMSK);
  1265. msk &= ~XM_IS_INP_ASS;
  1266. xm_write16(hw, port, XM_IMSK, msk);
  1267. xm_read16(hw, port, XM_ISRC);
  1268. } else {
  1269. link_down:
  1270. mod_timer(&skge->link_timer,
  1271. round_jiffies(jiffies + LINK_HZ));
  1272. }
  1273. spin_unlock_irqrestore(&hw->phy_lock, flags);
  1274. }
  1275. static void genesis_mac_init(struct skge_hw *hw, int port)
  1276. {
  1277. struct net_device *dev = hw->dev[port];
  1278. struct skge_port *skge = netdev_priv(dev);
  1279. int jumbo = hw->dev[port]->mtu > ETH_DATA_LEN;
  1280. int i;
  1281. u32 r;
  1282. static const u8 zero[6] = { 0 };
  1283. for (i = 0; i < 10; i++) {
  1284. skge_write16(hw, SK_REG(port, TX_MFF_CTRL1),
  1285. MFF_SET_MAC_RST);
  1286. if (skge_read16(hw, SK_REG(port, TX_MFF_CTRL1)) & MFF_SET_MAC_RST)
  1287. goto reset_ok;
  1288. udelay(1);
  1289. }
  1290. netdev_warn(dev, "genesis reset failed\n");
  1291. reset_ok:
  1292. /* Unreset the XMAC. */
  1293. skge_write16(hw, SK_REG(port, TX_MFF_CTRL1), MFF_CLR_MAC_RST);
  1294. /*
  1295. * Perform additional initialization for external PHYs,
  1296. * namely for the 1000baseTX cards that use the XMAC's
  1297. * GMII mode.
  1298. */
  1299. if (hw->phy_type != SK_PHY_XMAC) {
  1300. /* Take external Phy out of reset */
  1301. r = skge_read32(hw, B2_GP_IO);
  1302. if (port == 0)
  1303. r |= GP_DIR_0|GP_IO_0;
  1304. else
  1305. r |= GP_DIR_2|GP_IO_2;
  1306. skge_write32(hw, B2_GP_IO, r);
  1307. /* Enable GMII interface */
  1308. xm_write16(hw, port, XM_HW_CFG, XM_HW_GMII_MD);
  1309. }
  1310. switch (hw->phy_type) {
  1311. case SK_PHY_XMAC:
  1312. xm_phy_init(skge);
  1313. break;
  1314. case SK_PHY_BCOM:
  1315. bcom_phy_init(skge);
  1316. bcom_check_link(hw, port);
  1317. }
  1318. /* Set Station Address */
  1319. xm_outaddr(hw, port, XM_SA, dev->dev_addr);
  1320. /* We don't use match addresses so clear */
  1321. for (i = 1; i < 16; i++)
  1322. xm_outaddr(hw, port, XM_EXM(i), zero);
  1323. /* Clear MIB counters */
  1324. xm_write16(hw, port, XM_STAT_CMD,
  1325. XM_SC_CLR_RXC | XM_SC_CLR_TXC);
  1326. /* Clear two times according to Errata #3 */
  1327. xm_write16(hw, port, XM_STAT_CMD,
  1328. XM_SC_CLR_RXC | XM_SC_CLR_TXC);
  1329. /* configure Rx High Water Mark (XM_RX_HI_WM) */
  1330. xm_write16(hw, port, XM_RX_HI_WM, 1450);
  1331. /* We don't need the FCS appended to the packet. */
  1332. r = XM_RX_LENERR_OK | XM_RX_STRIP_FCS;
  1333. if (jumbo)
  1334. r |= XM_RX_BIG_PK_OK;
  1335. if (skge->duplex == DUPLEX_HALF) {
  1336. /*
  1337. * If in manual half duplex mode the other side might be in
  1338. * full duplex mode, so ignore if a carrier extension is not seen
  1339. * on frames received
  1340. */
  1341. r |= XM_RX_DIS_CEXT;
  1342. }
  1343. xm_write16(hw, port, XM_RX_CMD, r);
  1344. /* We want short frames padded to 60 bytes. */
  1345. xm_write16(hw, port, XM_TX_CMD, XM_TX_AUTO_PAD);
  1346. /* Increase threshold for jumbo frames on dual port */
  1347. if (hw->ports > 1 && jumbo)
  1348. xm_write16(hw, port, XM_TX_THR, 1020);
  1349. else
  1350. xm_write16(hw, port, XM_TX_THR, 512);
  1351. /*
  1352. * Enable the reception of all error frames. This is
  1353. * a necessary evil due to the design of the XMAC. The
  1354. * XMAC's receive FIFO is only 8K in size, however jumbo
  1355. * frames can be up to 9000 bytes in length. When bad
  1356. * frame filtering is enabled, the XMAC's RX FIFO operates
  1357. * in 'store and forward' mode. For this to work, the
  1358. * entire frame has to fit into the FIFO, but that means
  1359. * that jumbo frames larger than 8192 bytes will be
  1360. * truncated. Disabling all bad frame filtering causes
  1361. * the RX FIFO to operate in streaming mode, in which
  1362. * case the XMAC will start transferring frames out of the
  1363. * RX FIFO as soon as the FIFO threshold is reached.
  1364. */
  1365. xm_write32(hw, port, XM_MODE, XM_DEF_MODE);
  1366. /*
  1367. * Initialize the Receive Counter Event Mask (XM_RX_EV_MSK)
  1368. * - Enable all bits excepting 'Octets Rx OK Low CntOv'
  1369. * and 'Octets Rx OK Hi Cnt Ov'.
  1370. */
  1371. xm_write32(hw, port, XM_RX_EV_MSK, XMR_DEF_MSK);
  1372. /*
  1373. * Initialize the Transmit Counter Event Mask (XM_TX_EV_MSK)
  1374. * - Enable all bits excepting 'Octets Tx OK Low CntOv'
  1375. * and 'Octets Tx OK Hi Cnt Ov'.
  1376. */
  1377. xm_write32(hw, port, XM_TX_EV_MSK, XMT_DEF_MSK);
  1378. /* Configure MAC arbiter */
  1379. skge_write16(hw, B3_MA_TO_CTRL, MA_RST_CLR);
  1380. /* configure timeout values */
  1381. skge_write8(hw, B3_MA_TOINI_RX1, 72);
  1382. skge_write8(hw, B3_MA_TOINI_RX2, 72);
  1383. skge_write8(hw, B3_MA_TOINI_TX1, 72);
  1384. skge_write8(hw, B3_MA_TOINI_TX2, 72);
  1385. skge_write8(hw, B3_MA_RCINI_RX1, 0);
  1386. skge_write8(hw, B3_MA_RCINI_RX2, 0);
  1387. skge_write8(hw, B3_MA_RCINI_TX1, 0);
  1388. skge_write8(hw, B3_MA_RCINI_TX2, 0);
  1389. /* Configure Rx MAC FIFO */
  1390. skge_write8(hw, SK_REG(port, RX_MFF_CTRL2), MFF_RST_CLR);
  1391. skge_write16(hw, SK_REG(port, RX_MFF_CTRL1), MFF_ENA_TIM_PAT);
  1392. skge_write8(hw, SK_REG(port, RX_MFF_CTRL2), MFF_ENA_OP_MD);
  1393. /* Configure Tx MAC FIFO */
  1394. skge_write8(hw, SK_REG(port, TX_MFF_CTRL2), MFF_RST_CLR);
  1395. skge_write16(hw, SK_REG(port, TX_MFF_CTRL1), MFF_TX_CTRL_DEF);
  1396. skge_write8(hw, SK_REG(port, TX_MFF_CTRL2), MFF_ENA_OP_MD);
  1397. if (jumbo) {
  1398. /* Enable frame flushing if jumbo frames used */
  1399. skge_write16(hw, SK_REG(port, RX_MFF_CTRL1), MFF_ENA_FLUSH);
  1400. } else {
  1401. /* enable timeout timers if normal frames */
  1402. skge_write16(hw, B3_PA_CTRL,
  1403. (port == 0) ? PA_ENA_TO_TX1 : PA_ENA_TO_TX2);
  1404. }
  1405. }
  1406. static void genesis_stop(struct skge_port *skge)
  1407. {
  1408. struct skge_hw *hw = skge->hw;
  1409. int port = skge->port;
  1410. unsigned retries = 1000;
  1411. u16 cmd;
  1412. /* Disable Tx and Rx */
  1413. cmd = xm_read16(hw, port, XM_MMU_CMD);
  1414. cmd &= ~(XM_MMU_ENA_RX | XM_MMU_ENA_TX);
  1415. xm_write16(hw, port, XM_MMU_CMD, cmd);
  1416. genesis_reset(hw, port);
  1417. /* Clear Tx packet arbiter timeout IRQ */
  1418. skge_write16(hw, B3_PA_CTRL,
  1419. port == 0 ? PA_CLR_TO_TX1 : PA_CLR_TO_TX2);
  1420. /* Reset the MAC */
  1421. skge_write16(hw, SK_REG(port, TX_MFF_CTRL1), MFF_CLR_MAC_RST);
  1422. do {
  1423. skge_write16(hw, SK_REG(port, TX_MFF_CTRL1), MFF_SET_MAC_RST);
  1424. if (!(skge_read16(hw, SK_REG(port, TX_MFF_CTRL1)) & MFF_SET_MAC_RST))
  1425. break;
  1426. } while (--retries > 0);
  1427. /* For external PHYs there must be special handling */
  1428. if (hw->phy_type != SK_PHY_XMAC) {
  1429. u32 reg = skge_read32(hw, B2_GP_IO);
  1430. if (port == 0) {
  1431. reg |= GP_DIR_0;
  1432. reg &= ~GP_IO_0;
  1433. } else {
  1434. reg |= GP_DIR_2;
  1435. reg &= ~GP_IO_2;
  1436. }
  1437. skge_write32(hw, B2_GP_IO, reg);
  1438. skge_read32(hw, B2_GP_IO);
  1439. }
  1440. xm_write16(hw, port, XM_MMU_CMD,
  1441. xm_read16(hw, port, XM_MMU_CMD)
  1442. & ~(XM_MMU_ENA_RX | XM_MMU_ENA_TX));
  1443. xm_read16(hw, port, XM_MMU_CMD);
  1444. }
  1445. static void genesis_get_stats(struct skge_port *skge, u64 *data)
  1446. {
  1447. struct skge_hw *hw = skge->hw;
  1448. int port = skge->port;
  1449. int i;
  1450. unsigned long timeout = jiffies + HZ;
  1451. xm_write16(hw, port,
  1452. XM_STAT_CMD, XM_SC_SNP_TXC | XM_SC_SNP_RXC);
  1453. /* wait for update to complete */
  1454. while (xm_read16(hw, port, XM_STAT_CMD)
  1455. & (XM_SC_SNP_TXC | XM_SC_SNP_RXC)) {
  1456. if (time_after(jiffies, timeout))
  1457. break;
  1458. udelay(10);
  1459. }
  1460. /* special case for 64 bit octet counter */
  1461. data[0] = (u64) xm_read32(hw, port, XM_TXO_OK_HI) << 32
  1462. | xm_read32(hw, port, XM_TXO_OK_LO);
  1463. data[1] = (u64) xm_read32(hw, port, XM_RXO_OK_HI) << 32
  1464. | xm_read32(hw, port, XM_RXO_OK_LO);
  1465. for (i = 2; i < ARRAY_SIZE(skge_stats); i++)
  1466. data[i] = xm_read32(hw, port, skge_stats[i].xmac_offset);
  1467. }
  1468. static void genesis_mac_intr(struct skge_hw *hw, int port)
  1469. {
  1470. struct net_device *dev = hw->dev[port];
  1471. struct skge_port *skge = netdev_priv(dev);
  1472. u16 status = xm_read16(hw, port, XM_ISRC);
  1473. netif_printk(skge, intr, KERN_DEBUG, skge->netdev,
  1474. "mac interrupt status 0x%x\n", status);
  1475. if (hw->phy_type == SK_PHY_XMAC && (status & XM_IS_INP_ASS)) {
  1476. xm_link_down(hw, port);
  1477. mod_timer(&skge->link_timer, jiffies + 1);
  1478. }
  1479. if (status & XM_IS_TXF_UR) {
  1480. xm_write32(hw, port, XM_MODE, XM_MD_FTF);
  1481. ++dev->stats.tx_fifo_errors;
  1482. }
  1483. }
  1484. static void genesis_link_up(struct skge_port *skge)
  1485. {
  1486. struct skge_hw *hw = skge->hw;
  1487. int port = skge->port;
  1488. u16 cmd, msk;
  1489. u32 mode;
  1490. cmd = xm_read16(hw, port, XM_MMU_CMD);
  1491. /*
  1492. * enabling pause frame reception is required for 1000BT
  1493. * because the XMAC is not reset if the link is going down
  1494. */
  1495. if (skge->flow_status == FLOW_STAT_NONE ||
  1496. skge->flow_status == FLOW_STAT_LOC_SEND)
  1497. /* Disable Pause Frame Reception */
  1498. cmd |= XM_MMU_IGN_PF;
  1499. else
  1500. /* Enable Pause Frame Reception */
  1501. cmd &= ~XM_MMU_IGN_PF;
  1502. xm_write16(hw, port, XM_MMU_CMD, cmd);
  1503. mode = xm_read32(hw, port, XM_MODE);
  1504. if (skge->flow_status == FLOW_STAT_SYMMETRIC ||
  1505. skge->flow_status == FLOW_STAT_LOC_SEND) {
  1506. /*
  1507. * Configure Pause Frame Generation
  1508. * Use internal and external Pause Frame Generation.
  1509. * Sending pause frames is edge triggered.
  1510. * Send a Pause frame with the maximum pause time if
  1511. * internal oder external FIFO full condition occurs.
  1512. * Send a zero pause time frame to re-start transmission.
  1513. */
  1514. /* XM_PAUSE_DA = '010000C28001' (default) */
  1515. /* XM_MAC_PTIME = 0xffff (maximum) */
  1516. /* remember this value is defined in big endian (!) */
  1517. xm_write16(hw, port, XM_MAC_PTIME, 0xffff);
  1518. mode |= XM_PAUSE_MODE;
  1519. skge_write16(hw, SK_REG(port, RX_MFF_CTRL1), MFF_ENA_PAUSE);
  1520. } else {
  1521. /*
  1522. * disable pause frame generation is required for 1000BT
  1523. * because the XMAC is not reset if the link is going down
  1524. */
  1525. /* Disable Pause Mode in Mode Register */
  1526. mode &= ~XM_PAUSE_MODE;
  1527. skge_write16(hw, SK_REG(port, RX_MFF_CTRL1), MFF_DIS_PAUSE);
  1528. }
  1529. xm_write32(hw, port, XM_MODE, mode);
  1530. /* Turn on detection of Tx underrun */
  1531. msk = xm_read16(hw, port, XM_IMSK);
  1532. msk &= ~XM_IS_TXF_UR;
  1533. xm_write16(hw, port, XM_IMSK, msk);
  1534. xm_read16(hw, port, XM_ISRC);
  1535. /* get MMU Command Reg. */
  1536. cmd = xm_read16(hw, port, XM_MMU_CMD);
  1537. if (hw->phy_type != SK_PHY_XMAC && skge->duplex == DUPLEX_FULL)
  1538. cmd |= XM_MMU_GMII_FD;
  1539. /*
  1540. * Workaround BCOM Errata (#10523) for all BCom Phys
  1541. * Enable Power Management after link up
  1542. */
  1543. if (hw->phy_type == SK_PHY_BCOM) {
  1544. xm_phy_write(hw, port, PHY_BCOM_AUX_CTRL,
  1545. xm_phy_read(hw, port, PHY_BCOM_AUX_CTRL)
  1546. & ~PHY_B_AC_DIS_PM);
  1547. xm_phy_write(hw, port, PHY_BCOM_INT_MASK, PHY_B_DEF_MSK);
  1548. }
  1549. /* enable Rx/Tx */
  1550. xm_write16(hw, port, XM_MMU_CMD,
  1551. cmd | XM_MMU_ENA_RX | XM_MMU_ENA_TX);
  1552. skge_link_up(skge);
  1553. }
  1554. static inline void bcom_phy_intr(struct skge_port *skge)
  1555. {
  1556. struct skge_hw *hw = skge->hw;
  1557. int port = skge->port;
  1558. u16 isrc;
  1559. isrc = xm_phy_read(hw, port, PHY_BCOM_INT_STAT);
  1560. netif_printk(skge, intr, KERN_DEBUG, skge->netdev,
  1561. "phy interrupt status 0x%x\n", isrc);
  1562. if (isrc & PHY_B_IS_PSE)
  1563. pr_err("%s: uncorrectable pair swap error\n",
  1564. hw->dev[port]->name);
  1565. /* Workaround BCom Errata:
  1566. * enable and disable loopback mode if "NO HCD" occurs.
  1567. */
  1568. if (isrc & PHY_B_IS_NO_HDCL) {
  1569. u16 ctrl = xm_phy_read(hw, port, PHY_BCOM_CTRL);
  1570. xm_phy_write(hw, port, PHY_BCOM_CTRL,
  1571. ctrl | PHY_CT_LOOP);
  1572. xm_phy_write(hw, port, PHY_BCOM_CTRL,
  1573. ctrl & ~PHY_CT_LOOP);
  1574. }
  1575. if (isrc & (PHY_B_IS_AN_PR | PHY_B_IS_LST_CHANGE))
  1576. bcom_check_link(hw, port);
  1577. }
  1578. static int gm_phy_write(struct skge_hw *hw, int port, u16 reg, u16 val)
  1579. {
  1580. int i;
  1581. gma_write16(hw, port, GM_SMI_DATA, val);
  1582. gma_write16(hw, port, GM_SMI_CTRL,
  1583. GM_SMI_CT_PHY_AD(hw->phy_addr) | GM_SMI_CT_REG_AD(reg));
  1584. for (i = 0; i < PHY_RETRIES; i++) {
  1585. udelay(1);
  1586. if (!(gma_read16(hw, port, GM_SMI_CTRL) & GM_SMI_CT_BUSY))
  1587. return 0;
  1588. }
  1589. pr_warn("%s: phy write timeout\n", hw->dev[port]->name);
  1590. return -EIO;
  1591. }
  1592. static int __gm_phy_read(struct skge_hw *hw, int port, u16 reg, u16 *val)
  1593. {
  1594. int i;
  1595. gma_write16(hw, port, GM_SMI_CTRL,
  1596. GM_SMI_CT_PHY_AD(hw->phy_addr)
  1597. | GM_SMI_CT_REG_AD(reg) | GM_SMI_CT_OP_RD);
  1598. for (i = 0; i < PHY_RETRIES; i++) {
  1599. udelay(1);
  1600. if (gma_read16(hw, port, GM_SMI_CTRL) & GM_SMI_CT_RD_VAL)
  1601. goto ready;
  1602. }
  1603. return -ETIMEDOUT;
  1604. ready:
  1605. *val = gma_read16(hw, port, GM_SMI_DATA);
  1606. return 0;
  1607. }
  1608. static u16 gm_phy_read(struct skge_hw *hw, int port, u16 reg)
  1609. {
  1610. u16 v = 0;
  1611. if (__gm_phy_read(hw, port, reg, &v))
  1612. pr_warn("%s: phy read timeout\n", hw->dev[port]->name);
  1613. return v;
  1614. }
  1615. /* Marvell Phy Initialization */
  1616. static void yukon_init(struct skge_hw *hw, int port)
  1617. {
  1618. struct skge_port *skge = netdev_priv(hw->dev[port]);
  1619. u16 ctrl, ct1000, adv;
  1620. if (skge->autoneg == AUTONEG_ENABLE) {
  1621. u16 ectrl = gm_phy_read(hw, port, PHY_MARV_EXT_CTRL);
  1622. ectrl &= ~(PHY_M_EC_M_DSC_MSK | PHY_M_EC_S_DSC_MSK |
  1623. PHY_M_EC_MAC_S_MSK);
  1624. ectrl |= PHY_M_EC_MAC_S(MAC_TX_CLK_25_MHZ);
  1625. ectrl |= PHY_M_EC_M_DSC(0) | PHY_M_EC_S_DSC(1);
  1626. gm_phy_write(hw, port, PHY_MARV_EXT_CTRL, ectrl);
  1627. }
  1628. ctrl = gm_phy_read(hw, port, PHY_MARV_CTRL);
  1629. if (skge->autoneg == AUTONEG_DISABLE)
  1630. ctrl &= ~PHY_CT_ANE;
  1631. ctrl |= PHY_CT_RESET;
  1632. gm_phy_write(hw, port, PHY_MARV_CTRL, ctrl);
  1633. ctrl = 0;
  1634. ct1000 = 0;
  1635. adv = PHY_AN_CSMA;
  1636. if (skge->autoneg == AUTONEG_ENABLE) {
  1637. if (hw->copper) {
  1638. if (skge->advertising & ADVERTISED_1000baseT_Full)
  1639. ct1000 |= PHY_M_1000C_AFD;
  1640. if (skge->advertising & ADVERTISED_1000baseT_Half)
  1641. ct1000 |= PHY_M_1000C_AHD;
  1642. if (skge->advertising & ADVERTISED_100baseT_Full)
  1643. adv |= PHY_M_AN_100_FD;
  1644. if (skge->advertising & ADVERTISED_100baseT_Half)
  1645. adv |= PHY_M_AN_100_HD;
  1646. if (skge->advertising & ADVERTISED_10baseT_Full)
  1647. adv |= PHY_M_AN_10_FD;
  1648. if (skge->advertising & ADVERTISED_10baseT_Half)
  1649. adv |= PHY_M_AN_10_HD;
  1650. /* Set Flow-control capabilities */
  1651. adv |= phy_pause_map[skge->flow_control];
  1652. } else {
  1653. if (skge->advertising & ADVERTISED_1000baseT_Full)
  1654. adv |= PHY_M_AN_1000X_AFD;
  1655. if (skge->advertising & ADVERTISED_1000baseT_Half)
  1656. adv |= PHY_M_AN_1000X_AHD;
  1657. adv |= fiber_pause_map[skge->flow_control];
  1658. }
  1659. /* Restart Auto-negotiation */
  1660. ctrl |= PHY_CT_ANE | PHY_CT_RE_CFG;
  1661. } else {
  1662. /* forced speed/duplex settings */
  1663. ct1000 = PHY_M_1000C_MSE;
  1664. if (skge->duplex == DUPLEX_FULL)
  1665. ctrl |= PHY_CT_DUP_MD;
  1666. switch (skge->speed) {
  1667. case SPEED_1000:
  1668. ctrl |= PHY_CT_SP1000;
  1669. break;
  1670. case SPEED_100:
  1671. ctrl |= PHY_CT_SP100;
  1672. break;
  1673. }
  1674. ctrl |= PHY_CT_RESET;
  1675. }
  1676. gm_phy_write(hw, port, PHY_MARV_1000T_CTRL, ct1000);
  1677. gm_phy_write(hw, port, PHY_MARV_AUNE_ADV, adv);
  1678. gm_phy_write(hw, port, PHY_MARV_CTRL, ctrl);
  1679. /* Enable phy interrupt on autonegotiation complete (or link up) */
  1680. if (skge->autoneg == AUTONEG_ENABLE)
  1681. gm_phy_write(hw, port, PHY_MARV_INT_MASK, PHY_M_IS_AN_MSK);
  1682. else
  1683. gm_phy_write(hw, port, PHY_MARV_INT_MASK, PHY_M_IS_DEF_MSK);
  1684. }
  1685. static void yukon_reset(struct skge_hw *hw, int port)
  1686. {
  1687. gm_phy_write(hw, port, PHY_MARV_INT_MASK, 0);/* disable PHY IRQs */
  1688. gma_write16(hw, port, GM_MC_ADDR_H1, 0); /* clear MC hash */
  1689. gma_write16(hw, port, GM_MC_ADDR_H2, 0);
  1690. gma_write16(hw, port, GM_MC_ADDR_H3, 0);
  1691. gma_write16(hw, port, GM_MC_ADDR_H4, 0);
  1692. gma_write16(hw, port, GM_RX_CTRL,
  1693. gma_read16(hw, port, GM_RX_CTRL)
  1694. | GM_RXCR_UCF_ENA | GM_RXCR_MCF_ENA);
  1695. }
  1696. /* Apparently, early versions of Yukon-Lite had wrong chip_id? */
  1697. static int is_yukon_lite_a0(struct skge_hw *hw)
  1698. {
  1699. u32 reg;
  1700. int ret;
  1701. if (hw->chip_id != CHIP_ID_YUKON)
  1702. return 0;
  1703. reg = skge_read32(hw, B2_FAR);
  1704. skge_write8(hw, B2_FAR + 3, 0xff);
  1705. ret = (skge_read8(hw, B2_FAR + 3) != 0);
  1706. skge_write32(hw, B2_FAR, reg);
  1707. return ret;
  1708. }
  1709. static void yukon_mac_init(struct skge_hw *hw, int port)
  1710. {
  1711. struct skge_port *skge = netdev_priv(hw->dev[port]);
  1712. int i;
  1713. u32 reg;
  1714. const u8 *addr = hw->dev[port]->dev_addr;
  1715. /* WA code for COMA mode -- set PHY reset */
  1716. if (hw->chip_id == CHIP_ID_YUKON_LITE &&
  1717. hw->chip_rev >= CHIP_REV_YU_LITE_A3) {
  1718. reg = skge_read32(hw, B2_GP_IO);
  1719. reg |= GP_DIR_9 | GP_IO_9;
  1720. skge_write32(hw, B2_GP_IO, reg);
  1721. }
  1722. /* hard reset */
  1723. skge_write32(hw, SK_REG(port, GPHY_CTRL), GPC_RST_SET);
  1724. skge_write32(hw, SK_REG(port, GMAC_CTRL), GMC_RST_SET);
  1725. /* WA code for COMA mode -- clear PHY reset */
  1726. if (hw->chip_id == CHIP_ID_YUKON_LITE &&
  1727. hw->chip_rev >= CHIP_REV_YU_LITE_A3) {
  1728. reg = skge_read32(hw, B2_GP_IO);
  1729. reg |= GP_DIR_9;
  1730. reg &= ~GP_IO_9;
  1731. skge_write32(hw, B2_GP_IO, reg);
  1732. }
  1733. /* Set hardware config mode */
  1734. reg = GPC_INT_POL_HI | GPC_DIS_FC | GPC_DIS_SLEEP |
  1735. GPC_ENA_XC | GPC_ANEG_ADV_ALL_M | GPC_ENA_PAUSE;
  1736. reg |= hw->copper ? GPC_HWCFG_GMII_COP : GPC_HWCFG_GMII_FIB;
  1737. /* Clear GMC reset */
  1738. skge_write32(hw, SK_REG(port, GPHY_CTRL), reg | GPC_RST_SET);
  1739. skge_write32(hw, SK_REG(port, GPHY_CTRL), reg | GPC_RST_CLR);
  1740. skge_write32(hw, SK_REG(port, GMAC_CTRL), GMC_PAUSE_ON | GMC_RST_CLR);
  1741. if (skge->autoneg == AUTONEG_DISABLE) {
  1742. reg = GM_GPCR_AU_ALL_DIS;
  1743. gma_write16(hw, port, GM_GP_CTRL,
  1744. gma_read16(hw, port, GM_GP_CTRL) | reg);
  1745. switch (skge->speed) {
  1746. case SPEED_1000:
  1747. reg &= ~GM_GPCR_SPEED_100;
  1748. reg |= GM_GPCR_SPEED_1000;
  1749. break;
  1750. case SPEED_100:
  1751. reg &= ~GM_GPCR_SPEED_1000;
  1752. reg |= GM_GPCR_SPEED_100;
  1753. break;
  1754. case SPEED_10:
  1755. reg &= ~(GM_GPCR_SPEED_1000 | GM_GPCR_SPEED_100);
  1756. break;
  1757. }
  1758. if (skge->duplex == DUPLEX_FULL)
  1759. reg |= GM_GPCR_DUP_FULL;
  1760. } else
  1761. reg = GM_GPCR_SPEED_1000 | GM_GPCR_SPEED_100 | GM_GPCR_DUP_FULL;
  1762. switch (skge->flow_control) {
  1763. case FLOW_MODE_NONE:
  1764. skge_write32(hw, SK_REG(port, GMAC_CTRL), GMC_PAUSE_OFF);
  1765. reg |= GM_GPCR_FC_TX_DIS | GM_GPCR_FC_RX_DIS | GM_GPCR_AU_FCT_DIS;
  1766. break;
  1767. case FLOW_MODE_LOC_SEND:
  1768. /* disable Rx flow-control */
  1769. reg |= GM_GPCR_FC_RX_DIS | GM_GPCR_AU_FCT_DIS;
  1770. break;
  1771. case FLOW_MODE_SYMMETRIC:
  1772. case FLOW_MODE_SYM_OR_REM:
  1773. /* enable Tx & Rx flow-control */
  1774. break;
  1775. }
  1776. gma_write16(hw, port, GM_GP_CTRL, reg);
  1777. skge_read16(hw, SK_REG(port, GMAC_IRQ_SRC));
  1778. yukon_init(hw, port);
  1779. /* MIB clear */
  1780. reg = gma_read16(hw, port, GM_PHY_ADDR);
  1781. gma_write16(hw, port, GM_PHY_ADDR, reg | GM_PAR_MIB_CLR);
  1782. for (i = 0; i < GM_MIB_CNT_SIZE; i++)
  1783. gma_read16(hw, port, GM_MIB_CNT_BASE + 8*i);
  1784. gma_write16(hw, port, GM_PHY_ADDR, reg);
  1785. /* transmit control */
  1786. gma_write16(hw, port, GM_TX_CTRL, TX_COL_THR(TX_COL_DEF));
  1787. /* receive control reg: unicast + multicast + no FCS */
  1788. gma_write16(hw, port, GM_RX_CTRL,
  1789. GM_RXCR_UCF_ENA | GM_RXCR_CRC_DIS | GM_RXCR_MCF_ENA);
  1790. /* transmit flow control */
  1791. gma_write16(hw, port, GM_TX_FLOW_CTRL, 0xffff);
  1792. /* transmit parameter */
  1793. gma_write16(hw, port, GM_TX_PARAM,
  1794. TX_JAM_LEN_VAL(TX_JAM_LEN_DEF) |
  1795. TX_JAM_IPG_VAL(TX_JAM_IPG_DEF) |
  1796. TX_IPG_JAM_DATA(TX_IPG_JAM_DEF));
  1797. /* configure the Serial Mode Register */
  1798. reg = DATA_BLIND_VAL(DATA_BLIND_DEF)
  1799. | GM_SMOD_VLAN_ENA
  1800. | IPG_DATA_VAL(IPG_DATA_DEF);
  1801. if (hw->dev[port]->mtu > ETH_DATA_LEN)
  1802. reg |= GM_SMOD_JUMBO_ENA;
  1803. gma_write16(hw, port, GM_SERIAL_MODE, reg);
  1804. /* physical address: used for pause frames */
  1805. gma_set_addr(hw, port, GM_SRC_ADDR_1L, addr);
  1806. /* virtual address for data */
  1807. gma_set_addr(hw, port, GM_SRC_ADDR_2L, addr);
  1808. /* enable interrupt mask for counter overflows */
  1809. gma_write16(hw, port, GM_TX_IRQ_MSK, 0);
  1810. gma_write16(hw, port, GM_RX_IRQ_MSK, 0);
  1811. gma_write16(hw, port, GM_TR_IRQ_MSK, 0);
  1812. /* Initialize Mac Fifo */
  1813. /* Configure Rx MAC FIFO */
  1814. skge_write16(hw, SK_REG(port, RX_GMF_FL_MSK), RX_FF_FL_DEF_MSK);
  1815. reg = GMF_OPER_ON | GMF_RX_F_FL_ON;
  1816. /* disable Rx GMAC FIFO Flush for YUKON-Lite Rev. A0 only */
  1817. if (is_yukon_lite_a0(hw))
  1818. reg &= ~GMF_RX_F_FL_ON;
  1819. skge_write8(hw, SK_REG(port, RX_GMF_CTRL_T), GMF_RST_CLR);
  1820. skge_write16(hw, SK_REG(port, RX_GMF_CTRL_T), reg);
  1821. /*
  1822. * because Pause Packet Truncation in GMAC is not working
  1823. * we have to increase the Flush Threshold to 64 bytes
  1824. * in order to flush pause packets in Rx FIFO on Yukon-1
  1825. */
  1826. skge_write16(hw, SK_REG(port, RX_GMF_FL_THR), RX_GMF_FL_THR_DEF+1);
  1827. /* Configure Tx MAC FIFO */
  1828. skge_write8(hw, SK_REG(port, TX_GMF_CTRL_T), GMF_RST_CLR);
  1829. skge_write16(hw, SK_REG(port, TX_GMF_CTRL_T), GMF_OPER_ON);
  1830. }
  1831. /* Go into power down mode */
  1832. static void yukon_suspend(struct skge_hw *hw, int port)
  1833. {
  1834. u16 ctrl;
  1835. ctrl = gm_phy_read(hw, port, PHY_MARV_PHY_CTRL);
  1836. ctrl |= PHY_M_PC_POL_R_DIS;
  1837. gm_phy_write(hw, port, PHY_MARV_PHY_CTRL, ctrl);
  1838. ctrl = gm_phy_read(hw, port, PHY_MARV_CTRL);
  1839. ctrl |= PHY_CT_RESET;
  1840. gm_phy_write(hw, port, PHY_MARV_CTRL, ctrl);
  1841. /* switch IEEE compatible power down mode on */
  1842. ctrl = gm_phy_read(hw, port, PHY_MARV_CTRL);
  1843. ctrl |= PHY_CT_PDOWN;
  1844. gm_phy_write(hw, port, PHY_MARV_CTRL, ctrl);
  1845. }
  1846. static void yukon_stop(struct skge_port *skge)
  1847. {
  1848. struct skge_hw *hw = skge->hw;
  1849. int port = skge->port;
  1850. skge_write8(hw, SK_REG(port, GMAC_IRQ_MSK), 0);
  1851. yukon_reset(hw, port);
  1852. gma_write16(hw, port, GM_GP_CTRL,
  1853. gma_read16(hw, port, GM_GP_CTRL)
  1854. & ~(GM_GPCR_TX_ENA|GM_GPCR_RX_ENA));
  1855. gma_read16(hw, port, GM_GP_CTRL);
  1856. yukon_suspend(hw, port);
  1857. /* set GPHY Control reset */
  1858. skge_write8(hw, SK_REG(port, GPHY_CTRL), GPC_RST_SET);
  1859. skge_write8(hw, SK_REG(port, GMAC_CTRL), GMC_RST_SET);
  1860. }
  1861. static void yukon_get_stats(struct skge_port *skge, u64 *data)
  1862. {
  1863. struct skge_hw *hw = skge->hw;
  1864. int port = skge->port;
  1865. int i;
  1866. data[0] = (u64) gma_read32(hw, port, GM_TXO_OK_HI) << 32
  1867. | gma_read32(hw, port, GM_TXO_OK_LO);
  1868. data[1] = (u64) gma_read32(hw, port, GM_RXO_OK_HI) << 32
  1869. | gma_read32(hw, port, GM_RXO_OK_LO);
  1870. for (i = 2; i < ARRAY_SIZE(skge_stats); i++)
  1871. data[i] = gma_read32(hw, port,
  1872. skge_stats[i].gma_offset);
  1873. }
  1874. static void yukon_mac_intr(struct skge_hw *hw, int port)
  1875. {
  1876. struct net_device *dev = hw->dev[port];
  1877. struct skge_port *skge = netdev_priv(dev);
  1878. u8 status = skge_read8(hw, SK_REG(port, GMAC_IRQ_SRC));
  1879. netif_printk(skge, intr, KERN_DEBUG, skge->netdev,
  1880. "mac interrupt status 0x%x\n", status);
  1881. if (status & GM_IS_RX_FF_OR) {
  1882. ++dev->stats.rx_fifo_errors;
  1883. skge_write8(hw, SK_REG(port, RX_GMF_CTRL_T), GMF_CLI_RX_FO);
  1884. }
  1885. if (status & GM_IS_TX_FF_UR) {
  1886. ++dev->stats.tx_fifo_errors;
  1887. skge_write8(hw, SK_REG(port, TX_GMF_CTRL_T), GMF_CLI_TX_FU);
  1888. }
  1889. }
  1890. static u16 yukon_speed(const struct skge_hw *hw, u16 aux)
  1891. {
  1892. switch (aux & PHY_M_PS_SPEED_MSK) {
  1893. case PHY_M_PS_SPEED_1000:
  1894. return SPEED_1000;
  1895. case PHY_M_PS_SPEED_100:
  1896. return SPEED_100;
  1897. default:
  1898. return SPEED_10;
  1899. }
  1900. }
  1901. static void yukon_link_up(struct skge_port *skge)
  1902. {
  1903. struct skge_hw *hw = skge->hw;
  1904. int port = skge->port;
  1905. u16 reg;
  1906. /* Enable Transmit FIFO Underrun */
  1907. skge_write8(hw, SK_REG(port, GMAC_IRQ_MSK), GMAC_DEF_MSK);
  1908. reg = gma_read16(hw, port, GM_GP_CTRL);
  1909. if (skge->duplex == DUPLEX_FULL || skge->autoneg == AUTONEG_ENABLE)
  1910. reg |= GM_GPCR_DUP_FULL;
  1911. /* enable Rx/Tx */
  1912. reg |= GM_GPCR_RX_ENA | GM_GPCR_TX_ENA;
  1913. gma_write16(hw, port, GM_GP_CTRL, reg);
  1914. gm_phy_write(hw, port, PHY_MARV_INT_MASK, PHY_M_IS_DEF_MSK);
  1915. skge_link_up(skge);
  1916. }
  1917. static void yukon_link_down(struct skge_port *skge)
  1918. {
  1919. struct skge_hw *hw = skge->hw;
  1920. int port = skge->port;
  1921. u16 ctrl;
  1922. ctrl = gma_read16(hw, port, GM_GP_CTRL);
  1923. ctrl &= ~(GM_GPCR_RX_ENA | GM_GPCR_TX_ENA);
  1924. gma_write16(hw, port, GM_GP_CTRL, ctrl);
  1925. if (skge->flow_status == FLOW_STAT_REM_SEND) {
  1926. ctrl = gm_phy_read(hw, port, PHY_MARV_AUNE_ADV);
  1927. ctrl |= PHY_M_AN_ASP;
  1928. /* restore Asymmetric Pause bit */
  1929. gm_phy_write(hw, port, PHY_MARV_AUNE_ADV, ctrl);
  1930. }
  1931. skge_link_down(skge);
  1932. yukon_init(hw, port);
  1933. }
  1934. static void yukon_phy_intr(struct skge_port *skge)
  1935. {
  1936. struct skge_hw *hw = skge->hw;
  1937. int port = skge->port;
  1938. const char *reason = NULL;
  1939. u16 istatus, phystat;
  1940. istatus = gm_phy_read(hw, port, PHY_MARV_INT_STAT);
  1941. phystat = gm_phy_read(hw, port, PHY_MARV_PHY_STAT);
  1942. netif_printk(skge, intr, KERN_DEBUG, skge->netdev,
  1943. "phy interrupt status 0x%x 0x%x\n", istatus, phystat);
  1944. if (istatus & PHY_M_IS_AN_COMPL) {
  1945. if (gm_phy_read(hw, port, PHY_MARV_AUNE_LP)
  1946. & PHY_M_AN_RF) {
  1947. reason = "remote fault";
  1948. goto failed;
  1949. }
  1950. if (gm_phy_read(hw, port, PHY_MARV_1000T_STAT) & PHY_B_1000S_MSF) {
  1951. reason = "master/slave fault";
  1952. goto failed;
  1953. }
  1954. if (!(phystat & PHY_M_PS_SPDUP_RES)) {
  1955. reason = "speed/duplex";
  1956. goto failed;
  1957. }
  1958. skge->duplex = (phystat & PHY_M_PS_FULL_DUP)
  1959. ? DUPLEX_FULL : DUPLEX_HALF;
  1960. skge->speed = yukon_speed(hw, phystat);
  1961. /* We are using IEEE 802.3z/D5.0 Table 37-4 */
  1962. switch (phystat & PHY_M_PS_PAUSE_MSK) {
  1963. case PHY_M_PS_PAUSE_MSK:
  1964. skge->flow_status = FLOW_STAT_SYMMETRIC;
  1965. break;
  1966. case PHY_M_PS_RX_P_EN:
  1967. skge->flow_status = FLOW_STAT_REM_SEND;
  1968. break;
  1969. case PHY_M_PS_TX_P_EN:
  1970. skge->flow_status = FLOW_STAT_LOC_SEND;
  1971. break;
  1972. default:
  1973. skge->flow_status = FLOW_STAT_NONE;
  1974. }
  1975. if (skge->flow_status == FLOW_STAT_NONE ||
  1976. (skge->speed < SPEED_1000 && skge->duplex == DUPLEX_HALF))
  1977. skge_write8(hw, SK_REG(port, GMAC_CTRL), GMC_PAUSE_OFF);
  1978. else
  1979. skge_write8(hw, SK_REG(port, GMAC_CTRL), GMC_PAUSE_ON);
  1980. yukon_link_up(skge);
  1981. return;
  1982. }
  1983. if (istatus & PHY_M_IS_LSP_CHANGE)
  1984. skge->speed = yukon_speed(hw, phystat);
  1985. if (istatus & PHY_M_IS_DUP_CHANGE)
  1986. skge->duplex = (phystat & PHY_M_PS_FULL_DUP) ? DUPLEX_FULL : DUPLEX_HALF;
  1987. if (istatus & PHY_M_IS_LST_CHANGE) {
  1988. if (phystat & PHY_M_PS_LINK_UP)
  1989. yukon_link_up(skge);
  1990. else
  1991. yukon_link_down(skge);
  1992. }
  1993. return;
  1994. failed:
  1995. pr_err("%s: autonegotiation failed (%s)\n", skge->netdev->name, reason);
  1996. /* XXX restart autonegotiation? */
  1997. }
  1998. static void skge_phy_reset(struct skge_port *skge)
  1999. {
  2000. struct skge_hw *hw = skge->hw;
  2001. int port = skge->port;
  2002. struct net_device *dev = hw->dev[port];
  2003. netif_stop_queue(skge->netdev);
  2004. netif_carrier_off(skge->netdev);
  2005. spin_lock_bh(&hw->phy_lock);
  2006. if (is_genesis(hw)) {
  2007. genesis_reset(hw, port);
  2008. genesis_mac_init(hw, port);
  2009. } else {
  2010. yukon_reset(hw, port);
  2011. yukon_init(hw, port);
  2012. }
  2013. spin_unlock_bh(&hw->phy_lock);
  2014. skge_set_multicast(dev);
  2015. }
  2016. /* Basic MII support */
  2017. static int skge_ioctl(struct net_device *dev, struct ifreq *ifr, int cmd)
  2018. {
  2019. struct mii_ioctl_data *data = if_mii(ifr);
  2020. struct skge_port *skge = netdev_priv(dev);
  2021. struct skge_hw *hw = skge->hw;
  2022. int err = -EOPNOTSUPP;
  2023. if (!netif_running(dev))
  2024. return -ENODEV; /* Phy still in reset */
  2025. switch (cmd) {
  2026. case SIOCGMIIPHY:
  2027. data->phy_id = hw->phy_addr;
  2028. fallthrough;
  2029. case SIOCGMIIREG: {
  2030. u16 val = 0;
  2031. spin_lock_bh(&hw->phy_lock);
  2032. if (is_genesis(hw))
  2033. err = __xm_phy_read(hw, skge->port, data->reg_num & 0x1f, &val);
  2034. else
  2035. err = __gm_phy_read(hw, skge->port, data->reg_num & 0x1f, &val);
  2036. spin_unlock_bh(&hw->phy_lock);
  2037. data->val_out = val;
  2038. break;
  2039. }
  2040. case SIOCSMIIREG:
  2041. spin_lock_bh(&hw->phy_lock);
  2042. if (is_genesis(hw))
  2043. err = xm_phy_write(hw, skge->port, data->reg_num & 0x1f,
  2044. data->val_in);
  2045. else
  2046. err = gm_phy_write(hw, skge->port, data->reg_num & 0x1f,
  2047. data->val_in);
  2048. spin_unlock_bh(&hw->phy_lock);
  2049. break;
  2050. }
  2051. return err;
  2052. }
  2053. static void skge_ramset(struct skge_hw *hw, u16 q, u32 start, size_t len)
  2054. {
  2055. u32 end;
  2056. start /= 8;
  2057. len /= 8;
  2058. end = start + len - 1;
  2059. skge_write8(hw, RB_ADDR(q, RB_CTRL), RB_RST_CLR);
  2060. skge_write32(hw, RB_ADDR(q, RB_START), start);
  2061. skge_write32(hw, RB_ADDR(q, RB_WP), start);
  2062. skge_write32(hw, RB_ADDR(q, RB_RP), start);
  2063. skge_write32(hw, RB_ADDR(q, RB_END), end);
  2064. if (q == Q_R1 || q == Q_R2) {
  2065. /* Set thresholds on receive queue's */
  2066. skge_write32(hw, RB_ADDR(q, RB_RX_UTPP),
  2067. start + (2*len)/3);
  2068. skge_write32(hw, RB_ADDR(q, RB_RX_LTPP),
  2069. start + (len/3));
  2070. } else {
  2071. /* Enable store & forward on Tx queue's because
  2072. * Tx FIFO is only 4K on Genesis and 1K on Yukon
  2073. */
  2074. skge_write8(hw, RB_ADDR(q, RB_CTRL), RB_ENA_STFWD);
  2075. }
  2076. skge_write8(hw, RB_ADDR(q, RB_CTRL), RB_ENA_OP_MD);
  2077. }
  2078. /* Setup Bus Memory Interface */
  2079. static void skge_qset(struct skge_port *skge, u16 q,
  2080. const struct skge_element *e)
  2081. {
  2082. struct skge_hw *hw = skge->hw;
  2083. u32 watermark = 0x600;
  2084. u64 base = skge->dma + (e->desc - skge->mem);
  2085. /* optimization to reduce window on 32bit/33mhz */
  2086. if ((skge_read16(hw, B0_CTST) & (CS_BUS_CLOCK | CS_BUS_SLOT_SZ)) == 0)
  2087. watermark /= 2;
  2088. skge_write32(hw, Q_ADDR(q, Q_CSR), CSR_CLR_RESET);
  2089. skge_write32(hw, Q_ADDR(q, Q_F), watermark);
  2090. skge_write32(hw, Q_ADDR(q, Q_DA_H), (u32)(base >> 32));
  2091. skge_write32(hw, Q_ADDR(q, Q_DA_L), (u32)base);
  2092. }
  2093. static int skge_up(struct net_device *dev)
  2094. {
  2095. struct skge_port *skge = netdev_priv(dev);
  2096. struct skge_hw *hw = skge->hw;
  2097. int port = skge->port;
  2098. u32 chunk, ram_addr;
  2099. size_t rx_size, tx_size;
  2100. int err;
  2101. if (!is_valid_ether_addr(dev->dev_addr))
  2102. return -EINVAL;
  2103. netif_info(skge, ifup, skge->netdev, "enabling interface\n");
  2104. if (dev->mtu > RX_BUF_SIZE)
  2105. skge->rx_buf_size = dev->mtu + ETH_HLEN;
  2106. else
  2107. skge->rx_buf_size = RX_BUF_SIZE;
  2108. rx_size = skge->rx_ring.count * sizeof(struct skge_rx_desc);
  2109. tx_size = skge->tx_ring.count * sizeof(struct skge_tx_desc);
  2110. skge->mem_size = tx_size + rx_size;
  2111. skge->mem = dma_alloc_coherent(&hw->pdev->dev, skge->mem_size,
  2112. &skge->dma, GFP_KERNEL);
  2113. if (!skge->mem)
  2114. return -ENOMEM;
  2115. BUG_ON(skge->dma & 7);
  2116. if (upper_32_bits(skge->dma) != upper_32_bits(skge->dma + skge->mem_size)) {
  2117. dev_err(&hw->pdev->dev, "dma_alloc_coherent region crosses 4G boundary\n");
  2118. err = -EINVAL;
  2119. goto free_pci_mem;
  2120. }
  2121. err = skge_ring_alloc(&skge->rx_ring, skge->mem, skge->dma);
  2122. if (err)
  2123. goto free_pci_mem;
  2124. err = skge_rx_fill(dev);
  2125. if (err)
  2126. goto free_rx_ring;
  2127. err = skge_ring_alloc(&skge->tx_ring, skge->mem + rx_size,
  2128. skge->dma + rx_size);
  2129. if (err)
  2130. goto free_rx_ring;
  2131. if (hw->ports == 1) {
  2132. err = request_irq(hw->pdev->irq, skge_intr, IRQF_SHARED,
  2133. dev->name, hw);
  2134. if (err) {
  2135. netdev_err(dev, "Unable to allocate interrupt %d error: %d\n",
  2136. hw->pdev->irq, err);
  2137. goto free_tx_ring;
  2138. }
  2139. }
  2140. /* Initialize MAC */
  2141. netif_carrier_off(dev);
  2142. spin_lock_bh(&hw->phy_lock);
  2143. if (is_genesis(hw))
  2144. genesis_mac_init(hw, port);
  2145. else
  2146. yukon_mac_init(hw, port);
  2147. spin_unlock_bh(&hw->phy_lock);
  2148. /* Configure RAMbuffers - equally between ports and tx/rx */
  2149. chunk = (hw->ram_size - hw->ram_offset) / (hw->ports * 2);
  2150. ram_addr = hw->ram_offset + 2 * chunk * port;
  2151. skge_ramset(hw, rxqaddr[port], ram_addr, chunk);
  2152. skge_qset(skge, rxqaddr[port], skge->rx_ring.to_clean);
  2153. BUG_ON(skge->tx_ring.to_use != skge->tx_ring.to_clean);
  2154. skge_ramset(hw, txqaddr[port], ram_addr+chunk, chunk);
  2155. skge_qset(skge, txqaddr[port], skge->tx_ring.to_use);
  2156. /* Start receiver BMU */
  2157. wmb();
  2158. skge_write8(hw, Q_ADDR(rxqaddr[port], Q_CSR), CSR_START | CSR_IRQ_CL_F);
  2159. skge_led(skge, LED_MODE_ON);
  2160. spin_lock_irq(&hw->hw_lock);
  2161. hw->intr_mask |= portmask[port];
  2162. skge_write32(hw, B0_IMSK, hw->intr_mask);
  2163. skge_read32(hw, B0_IMSK);
  2164. spin_unlock_irq(&hw->hw_lock);
  2165. napi_enable(&skge->napi);
  2166. skge_set_multicast(dev);
  2167. return 0;
  2168. free_tx_ring:
  2169. kfree(skge->tx_ring.start);
  2170. free_rx_ring:
  2171. skge_rx_clean(skge);
  2172. kfree(skge->rx_ring.start);
  2173. free_pci_mem:
  2174. dma_free_coherent(&hw->pdev->dev, skge->mem_size, skge->mem,
  2175. skge->dma);
  2176. skge->mem = NULL;
  2177. return err;
  2178. }
  2179. /* stop receiver */
  2180. static void skge_rx_stop(struct skge_hw *hw, int port)
  2181. {
  2182. skge_write8(hw, Q_ADDR(rxqaddr[port], Q_CSR), CSR_STOP);
  2183. skge_write32(hw, RB_ADDR(port ? Q_R2 : Q_R1, RB_CTRL),
  2184. RB_RST_SET|RB_DIS_OP_MD);
  2185. skge_write32(hw, Q_ADDR(rxqaddr[port], Q_CSR), CSR_SET_RESET);
  2186. }
  2187. static int skge_down(struct net_device *dev)
  2188. {
  2189. struct skge_port *skge = netdev_priv(dev);
  2190. struct skge_hw *hw = skge->hw;
  2191. int port = skge->port;
  2192. if (!skge->mem)
  2193. return 0;
  2194. netif_info(skge, ifdown, skge->netdev, "disabling interface\n");
  2195. netif_tx_disable(dev);
  2196. if (is_genesis(hw) && hw->phy_type == SK_PHY_XMAC)
  2197. timer_delete_sync(&skge->link_timer);
  2198. napi_disable(&skge->napi);
  2199. netif_carrier_off(dev);
  2200. spin_lock_irq(&hw->hw_lock);
  2201. hw->intr_mask &= ~portmask[port];
  2202. skge_write32(hw, B0_IMSK, (hw->ports == 1) ? 0 : hw->intr_mask);
  2203. skge_read32(hw, B0_IMSK);
  2204. spin_unlock_irq(&hw->hw_lock);
  2205. if (hw->ports == 1)
  2206. free_irq(hw->pdev->irq, hw);
  2207. skge_write8(skge->hw, SK_REG(skge->port, LNK_LED_REG), LED_REG_OFF);
  2208. if (is_genesis(hw))
  2209. genesis_stop(skge);
  2210. else
  2211. yukon_stop(skge);
  2212. /* Stop transmitter */
  2213. skge_write8(hw, Q_ADDR(txqaddr[port], Q_CSR), CSR_STOP);
  2214. skge_write32(hw, RB_ADDR(txqaddr[port], RB_CTRL),
  2215. RB_RST_SET|RB_DIS_OP_MD);
  2216. /* Disable Force Sync bit and Enable Alloc bit */
  2217. skge_write8(hw, SK_REG(port, TXA_CTRL),
  2218. TXA_DIS_FSYNC | TXA_DIS_ALLOC | TXA_STOP_RC);
  2219. /* Stop Interval Timer and Limit Counter of Tx Arbiter */
  2220. skge_write32(hw, SK_REG(port, TXA_ITI_INI), 0L);
  2221. skge_write32(hw, SK_REG(port, TXA_LIM_INI), 0L);
  2222. /* Reset PCI FIFO */
  2223. skge_write32(hw, Q_ADDR(txqaddr[port], Q_CSR), CSR_SET_RESET);
  2224. skge_write32(hw, RB_ADDR(txqaddr[port], RB_CTRL), RB_RST_SET);
  2225. /* Reset the RAM Buffer async Tx queue */
  2226. skge_write8(hw, RB_ADDR(port == 0 ? Q_XA1 : Q_XA2, RB_CTRL), RB_RST_SET);
  2227. skge_rx_stop(hw, port);
  2228. if (is_genesis(hw)) {
  2229. skge_write8(hw, SK_REG(port, TX_MFF_CTRL2), MFF_RST_SET);
  2230. skge_write8(hw, SK_REG(port, RX_MFF_CTRL2), MFF_RST_SET);
  2231. } else {
  2232. skge_write8(hw, SK_REG(port, RX_GMF_CTRL_T), GMF_RST_SET);
  2233. skge_write8(hw, SK_REG(port, TX_GMF_CTRL_T), GMF_RST_SET);
  2234. }
  2235. skge_led(skge, LED_MODE_OFF);
  2236. netif_tx_lock_bh(dev);
  2237. skge_tx_clean(dev);
  2238. netif_tx_unlock_bh(dev);
  2239. skge_rx_clean(skge);
  2240. kfree(skge->rx_ring.start);
  2241. kfree(skge->tx_ring.start);
  2242. dma_free_coherent(&hw->pdev->dev, skge->mem_size, skge->mem,
  2243. skge->dma);
  2244. skge->mem = NULL;
  2245. return 0;
  2246. }
  2247. static inline int skge_avail(const struct skge_ring *ring)
  2248. {
  2249. smp_mb();
  2250. return ((ring->to_clean > ring->to_use) ? 0 : ring->count)
  2251. + (ring->to_clean - ring->to_use) - 1;
  2252. }
  2253. static netdev_tx_t skge_xmit_frame(struct sk_buff *skb,
  2254. struct net_device *dev)
  2255. {
  2256. struct skge_port *skge = netdev_priv(dev);
  2257. struct skge_hw *hw = skge->hw;
  2258. struct skge_element *e;
  2259. struct skge_tx_desc *td;
  2260. int i;
  2261. u32 control, len;
  2262. dma_addr_t map;
  2263. if (skb_padto(skb, ETH_ZLEN))
  2264. return NETDEV_TX_OK;
  2265. if (unlikely(skge_avail(&skge->tx_ring) < skb_shinfo(skb)->nr_frags + 1))
  2266. return NETDEV_TX_BUSY;
  2267. e = skge->tx_ring.to_use;
  2268. td = e->desc;
  2269. BUG_ON(td->control & BMU_OWN);
  2270. e->skb = skb;
  2271. len = skb_headlen(skb);
  2272. map = dma_map_single(&hw->pdev->dev, skb->data, len, DMA_TO_DEVICE);
  2273. if (dma_mapping_error(&hw->pdev->dev, map))
  2274. goto mapping_error;
  2275. dma_unmap_addr_set(e, mapaddr, map);
  2276. dma_unmap_len_set(e, maplen, len);
  2277. td->dma_lo = lower_32_bits(map);
  2278. td->dma_hi = upper_32_bits(map);
  2279. if (skb->ip_summed == CHECKSUM_PARTIAL) {
  2280. const int offset = skb_checksum_start_offset(skb);
  2281. /* This seems backwards, but it is what the sk98lin
  2282. * does. Looks like hardware is wrong?
  2283. */
  2284. if (ipip_hdr(skb)->protocol == IPPROTO_UDP &&
  2285. hw->chip_rev == 0 && hw->chip_id == CHIP_ID_YUKON)
  2286. control = BMU_TCP_CHECK;
  2287. else
  2288. control = BMU_UDP_CHECK;
  2289. td->csum_offs = 0;
  2290. td->csum_start = offset;
  2291. td->csum_write = offset + skb->csum_offset;
  2292. } else
  2293. control = BMU_CHECK;
  2294. if (!skb_shinfo(skb)->nr_frags) /* single buffer i.e. no fragments */
  2295. control |= BMU_EOF | BMU_IRQ_EOF;
  2296. else {
  2297. struct skge_tx_desc *tf = td;
  2298. control |= BMU_STFWD;
  2299. for (i = 0; i < skb_shinfo(skb)->nr_frags; i++) {
  2300. const skb_frag_t *frag = &skb_shinfo(skb)->frags[i];
  2301. map = skb_frag_dma_map(&hw->pdev->dev, frag, 0,
  2302. skb_frag_size(frag), DMA_TO_DEVICE);
  2303. if (dma_mapping_error(&hw->pdev->dev, map))
  2304. goto mapping_unwind;
  2305. e = e->next;
  2306. e->skb = skb;
  2307. tf = e->desc;
  2308. BUG_ON(tf->control & BMU_OWN);
  2309. tf->dma_lo = lower_32_bits(map);
  2310. tf->dma_hi = upper_32_bits(map);
  2311. dma_unmap_addr_set(e, mapaddr, map);
  2312. dma_unmap_len_set(e, maplen, skb_frag_size(frag));
  2313. tf->control = BMU_OWN | BMU_SW | control | skb_frag_size(frag);
  2314. }
  2315. tf->control |= BMU_EOF | BMU_IRQ_EOF;
  2316. }
  2317. /* Make sure all the descriptors written */
  2318. wmb();
  2319. td->control = BMU_OWN | BMU_SW | BMU_STF | control | len;
  2320. wmb();
  2321. netdev_sent_queue(dev, skb->len);
  2322. skge_write8(hw, Q_ADDR(txqaddr[skge->port], Q_CSR), CSR_START);
  2323. netif_printk(skge, tx_queued, KERN_DEBUG, skge->netdev,
  2324. "tx queued, slot %td, len %d\n",
  2325. e - skge->tx_ring.start, skb->len);
  2326. skge->tx_ring.to_use = e->next;
  2327. smp_wmb();
  2328. if (skge_avail(&skge->tx_ring) <= TX_LOW_WATER) {
  2329. netdev_dbg(dev, "transmit queue full\n");
  2330. netif_stop_queue(dev);
  2331. }
  2332. return NETDEV_TX_OK;
  2333. mapping_unwind:
  2334. e = skge->tx_ring.to_use;
  2335. dma_unmap_single(&hw->pdev->dev, dma_unmap_addr(e, mapaddr),
  2336. dma_unmap_len(e, maplen), DMA_TO_DEVICE);
  2337. while (i-- > 0) {
  2338. e = e->next;
  2339. dma_unmap_page(&hw->pdev->dev, dma_unmap_addr(e, mapaddr),
  2340. dma_unmap_len(e, maplen), DMA_TO_DEVICE);
  2341. }
  2342. mapping_error:
  2343. if (net_ratelimit())
  2344. dev_warn(&hw->pdev->dev, "%s: tx mapping error\n", dev->name);
  2345. dev_kfree_skb_any(skb);
  2346. return NETDEV_TX_OK;
  2347. }
  2348. /* Free resources associated with this reing element */
  2349. static inline void skge_tx_unmap(struct pci_dev *pdev, struct skge_element *e,
  2350. u32 control)
  2351. {
  2352. /* skb header vs. fragment */
  2353. if (control & BMU_STF)
  2354. dma_unmap_single(&pdev->dev, dma_unmap_addr(e, mapaddr),
  2355. dma_unmap_len(e, maplen), DMA_TO_DEVICE);
  2356. else
  2357. dma_unmap_page(&pdev->dev, dma_unmap_addr(e, mapaddr),
  2358. dma_unmap_len(e, maplen), DMA_TO_DEVICE);
  2359. }
  2360. /* Free all buffers in transmit ring */
  2361. static void skge_tx_clean(struct net_device *dev)
  2362. {
  2363. struct skge_port *skge = netdev_priv(dev);
  2364. struct skge_element *e;
  2365. for (e = skge->tx_ring.to_clean; e != skge->tx_ring.to_use; e = e->next) {
  2366. struct skge_tx_desc *td = e->desc;
  2367. skge_tx_unmap(skge->hw->pdev, e, td->control);
  2368. if (td->control & BMU_EOF)
  2369. dev_kfree_skb(e->skb);
  2370. td->control = 0;
  2371. }
  2372. netdev_reset_queue(dev);
  2373. skge->tx_ring.to_clean = e;
  2374. }
  2375. static void skge_tx_timeout(struct net_device *dev, unsigned int txqueue)
  2376. {
  2377. struct skge_port *skge = netdev_priv(dev);
  2378. netif_printk(skge, timer, KERN_DEBUG, skge->netdev, "tx timeout\n");
  2379. skge_write8(skge->hw, Q_ADDR(txqaddr[skge->port], Q_CSR), CSR_STOP);
  2380. skge_tx_clean(dev);
  2381. netif_wake_queue(dev);
  2382. }
  2383. static int skge_change_mtu(struct net_device *dev, int new_mtu)
  2384. {
  2385. int err;
  2386. if (!netif_running(dev)) {
  2387. WRITE_ONCE(dev->mtu, new_mtu);
  2388. return 0;
  2389. }
  2390. skge_down(dev);
  2391. WRITE_ONCE(dev->mtu, new_mtu);
  2392. err = skge_up(dev);
  2393. if (err)
  2394. dev_close(dev);
  2395. return err;
  2396. }
  2397. static const u8 pause_mc_addr[ETH_ALEN] = { 0x1, 0x80, 0xc2, 0x0, 0x0, 0x1 };
  2398. static void genesis_add_filter(u8 filter[8], const u8 *addr)
  2399. {
  2400. u32 crc, bit;
  2401. crc = ether_crc_le(ETH_ALEN, addr);
  2402. bit = ~crc & 0x3f;
  2403. filter[bit/8] |= 1 << (bit%8);
  2404. }
  2405. static void genesis_set_multicast(struct net_device *dev)
  2406. {
  2407. struct skge_port *skge = netdev_priv(dev);
  2408. struct skge_hw *hw = skge->hw;
  2409. int port = skge->port;
  2410. struct netdev_hw_addr *ha;
  2411. u32 mode;
  2412. u8 filter[8];
  2413. mode = xm_read32(hw, port, XM_MODE);
  2414. mode |= XM_MD_ENA_HASH;
  2415. if (dev->flags & IFF_PROMISC)
  2416. mode |= XM_MD_ENA_PROM;
  2417. else
  2418. mode &= ~XM_MD_ENA_PROM;
  2419. if (dev->flags & IFF_ALLMULTI)
  2420. memset(filter, 0xff, sizeof(filter));
  2421. else {
  2422. memset(filter, 0, sizeof(filter));
  2423. if (skge->flow_status == FLOW_STAT_REM_SEND ||
  2424. skge->flow_status == FLOW_STAT_SYMMETRIC)
  2425. genesis_add_filter(filter, pause_mc_addr);
  2426. netdev_for_each_mc_addr(ha, dev)
  2427. genesis_add_filter(filter, ha->addr);
  2428. }
  2429. xm_write32(hw, port, XM_MODE, mode);
  2430. xm_outhash(hw, port, XM_HSM, filter);
  2431. }
  2432. static void yukon_add_filter(u8 filter[8], const u8 *addr)
  2433. {
  2434. u32 bit = ether_crc(ETH_ALEN, addr) & 0x3f;
  2435. filter[bit / 8] |= 1 << (bit % 8);
  2436. }
  2437. static void yukon_set_multicast(struct net_device *dev)
  2438. {
  2439. struct skge_port *skge = netdev_priv(dev);
  2440. struct skge_hw *hw = skge->hw;
  2441. int port = skge->port;
  2442. struct netdev_hw_addr *ha;
  2443. int rx_pause = (skge->flow_status == FLOW_STAT_REM_SEND ||
  2444. skge->flow_status == FLOW_STAT_SYMMETRIC);
  2445. u16 reg;
  2446. u8 filter[8];
  2447. memset(filter, 0, sizeof(filter));
  2448. reg = gma_read16(hw, port, GM_RX_CTRL);
  2449. reg |= GM_RXCR_UCF_ENA;
  2450. if (dev->flags & IFF_PROMISC) /* promiscuous */
  2451. reg &= ~(GM_RXCR_UCF_ENA | GM_RXCR_MCF_ENA);
  2452. else if (dev->flags & IFF_ALLMULTI) /* all multicast */
  2453. memset(filter, 0xff, sizeof(filter));
  2454. else if (netdev_mc_empty(dev) && !rx_pause)/* no multicast */
  2455. reg &= ~GM_RXCR_MCF_ENA;
  2456. else {
  2457. reg |= GM_RXCR_MCF_ENA;
  2458. if (rx_pause)
  2459. yukon_add_filter(filter, pause_mc_addr);
  2460. netdev_for_each_mc_addr(ha, dev)
  2461. yukon_add_filter(filter, ha->addr);
  2462. }
  2463. gma_write16(hw, port, GM_MC_ADDR_H1,
  2464. (u16)filter[0] | ((u16)filter[1] << 8));
  2465. gma_write16(hw, port, GM_MC_ADDR_H2,
  2466. (u16)filter[2] | ((u16)filter[3] << 8));
  2467. gma_write16(hw, port, GM_MC_ADDR_H3,
  2468. (u16)filter[4] | ((u16)filter[5] << 8));
  2469. gma_write16(hw, port, GM_MC_ADDR_H4,
  2470. (u16)filter[6] | ((u16)filter[7] << 8));
  2471. gma_write16(hw, port, GM_RX_CTRL, reg);
  2472. }
  2473. static inline u16 phy_length(const struct skge_hw *hw, u32 status)
  2474. {
  2475. if (is_genesis(hw))
  2476. return status >> XMR_FS_LEN_SHIFT;
  2477. else
  2478. return status >> GMR_FS_LEN_SHIFT;
  2479. }
  2480. static inline int bad_phy_status(const struct skge_hw *hw, u32 status)
  2481. {
  2482. if (is_genesis(hw))
  2483. return (status & (XMR_FS_ERR | XMR_FS_2L_VLAN)) != 0;
  2484. else
  2485. return (status & GMR_FS_ANY_ERR) ||
  2486. (status & GMR_FS_RX_OK) == 0;
  2487. }
  2488. static void skge_set_multicast(struct net_device *dev)
  2489. {
  2490. struct skge_port *skge = netdev_priv(dev);
  2491. if (is_genesis(skge->hw))
  2492. genesis_set_multicast(dev);
  2493. else
  2494. yukon_set_multicast(dev);
  2495. }
  2496. /* Get receive buffer from descriptor.
  2497. * Handles copy of small buffers and reallocation failures
  2498. */
  2499. static struct sk_buff *skge_rx_get(struct net_device *dev,
  2500. struct skge_element *e,
  2501. u32 control, u32 status, u16 csum)
  2502. {
  2503. struct skge_port *skge = netdev_priv(dev);
  2504. struct sk_buff *skb;
  2505. u16 len = control & BMU_BBC;
  2506. netif_printk(skge, rx_status, KERN_DEBUG, skge->netdev,
  2507. "rx slot %td status 0x%x len %d\n",
  2508. e - skge->rx_ring.start, status, len);
  2509. if (len > skge->rx_buf_size)
  2510. goto error;
  2511. if ((control & (BMU_EOF|BMU_STF)) != (BMU_STF|BMU_EOF))
  2512. goto error;
  2513. if (bad_phy_status(skge->hw, status))
  2514. goto error;
  2515. if (phy_length(skge->hw, status) != len)
  2516. goto error;
  2517. if (len < RX_COPY_THRESHOLD) {
  2518. skb = netdev_alloc_skb_ip_align(dev, len);
  2519. if (!skb)
  2520. goto resubmit;
  2521. dma_sync_single_for_cpu(&skge->hw->pdev->dev,
  2522. dma_unmap_addr(e, mapaddr),
  2523. dma_unmap_len(e, maplen),
  2524. DMA_FROM_DEVICE);
  2525. skb_copy_from_linear_data(e->skb, skb->data, len);
  2526. dma_sync_single_for_device(&skge->hw->pdev->dev,
  2527. dma_unmap_addr(e, mapaddr),
  2528. dma_unmap_len(e, maplen),
  2529. DMA_FROM_DEVICE);
  2530. skge_rx_reuse(e, skge->rx_buf_size);
  2531. } else {
  2532. struct skge_element ee;
  2533. struct sk_buff *nskb;
  2534. nskb = netdev_alloc_skb_ip_align(dev, skge->rx_buf_size);
  2535. if (!nskb)
  2536. goto resubmit;
  2537. ee = *e;
  2538. skb = ee.skb;
  2539. prefetch(skb->data);
  2540. if (skge_rx_setup(skge, e, nskb, skge->rx_buf_size) < 0) {
  2541. dev_kfree_skb(nskb);
  2542. goto resubmit;
  2543. }
  2544. dma_unmap_single(&skge->hw->pdev->dev,
  2545. dma_unmap_addr(&ee, mapaddr),
  2546. dma_unmap_len(&ee, maplen), DMA_FROM_DEVICE);
  2547. }
  2548. skb_put(skb, len);
  2549. if (dev->features & NETIF_F_RXCSUM) {
  2550. skb->csum = le16_to_cpu(csum);
  2551. skb->ip_summed = CHECKSUM_COMPLETE;
  2552. }
  2553. skb->protocol = eth_type_trans(skb, dev);
  2554. return skb;
  2555. error:
  2556. netif_printk(skge, rx_err, KERN_DEBUG, skge->netdev,
  2557. "rx err, slot %td control 0x%x status 0x%x\n",
  2558. e - skge->rx_ring.start, control, status);
  2559. if (is_genesis(skge->hw)) {
  2560. if (status & (XMR_FS_RUNT|XMR_FS_LNG_ERR))
  2561. dev->stats.rx_length_errors++;
  2562. if (status & XMR_FS_FRA_ERR)
  2563. dev->stats.rx_frame_errors++;
  2564. if (status & XMR_FS_FCS_ERR)
  2565. dev->stats.rx_crc_errors++;
  2566. } else {
  2567. if (status & (GMR_FS_LONG_ERR|GMR_FS_UN_SIZE))
  2568. dev->stats.rx_length_errors++;
  2569. if (status & GMR_FS_FRAGMENT)
  2570. dev->stats.rx_frame_errors++;
  2571. if (status & GMR_FS_CRC_ERR)
  2572. dev->stats.rx_crc_errors++;
  2573. }
  2574. resubmit:
  2575. skge_rx_reuse(e, skge->rx_buf_size);
  2576. return NULL;
  2577. }
  2578. /* Free all buffers in Tx ring which are no longer owned by device */
  2579. static void skge_tx_done(struct net_device *dev)
  2580. {
  2581. struct skge_port *skge = netdev_priv(dev);
  2582. struct skge_ring *ring = &skge->tx_ring;
  2583. struct skge_element *e;
  2584. unsigned int bytes_compl = 0, pkts_compl = 0;
  2585. skge_write8(skge->hw, Q_ADDR(txqaddr[skge->port], Q_CSR), CSR_IRQ_CL_F);
  2586. for (e = ring->to_clean; e != ring->to_use; e = e->next) {
  2587. u32 control = ((const struct skge_tx_desc *) e->desc)->control;
  2588. if (control & BMU_OWN)
  2589. break;
  2590. skge_tx_unmap(skge->hw->pdev, e, control);
  2591. if (control & BMU_EOF) {
  2592. netif_printk(skge, tx_done, KERN_DEBUG, skge->netdev,
  2593. "tx done slot %td\n",
  2594. e - skge->tx_ring.start);
  2595. pkts_compl++;
  2596. bytes_compl += e->skb->len;
  2597. dev_consume_skb_any(e->skb);
  2598. }
  2599. }
  2600. netdev_completed_queue(dev, pkts_compl, bytes_compl);
  2601. skge->tx_ring.to_clean = e;
  2602. /* Can run lockless until we need to synchronize to restart queue. */
  2603. smp_mb();
  2604. if (unlikely(netif_queue_stopped(dev) &&
  2605. skge_avail(&skge->tx_ring) > TX_LOW_WATER)) {
  2606. netif_tx_lock(dev);
  2607. if (unlikely(netif_queue_stopped(dev) &&
  2608. skge_avail(&skge->tx_ring) > TX_LOW_WATER)) {
  2609. netif_wake_queue(dev);
  2610. }
  2611. netif_tx_unlock(dev);
  2612. }
  2613. }
  2614. static int skge_poll(struct napi_struct *napi, int budget)
  2615. {
  2616. struct skge_port *skge = container_of(napi, struct skge_port, napi);
  2617. struct net_device *dev = skge->netdev;
  2618. struct skge_hw *hw = skge->hw;
  2619. struct skge_ring *ring = &skge->rx_ring;
  2620. struct skge_element *e;
  2621. int work_done = 0;
  2622. skge_tx_done(dev);
  2623. skge_write8(hw, Q_ADDR(rxqaddr[skge->port], Q_CSR), CSR_IRQ_CL_F);
  2624. for (e = ring->to_clean; prefetch(e->next), work_done < budget; e = e->next) {
  2625. struct skge_rx_desc *rd = e->desc;
  2626. struct sk_buff *skb;
  2627. u32 control;
  2628. rmb();
  2629. control = rd->control;
  2630. if (control & BMU_OWN)
  2631. break;
  2632. skb = skge_rx_get(dev, e, control, rd->status, rd->csum2);
  2633. if (likely(skb)) {
  2634. napi_gro_receive(napi, skb);
  2635. ++work_done;
  2636. }
  2637. }
  2638. ring->to_clean = e;
  2639. /* restart receiver */
  2640. wmb();
  2641. skge_write8(hw, Q_ADDR(rxqaddr[skge->port], Q_CSR), CSR_START);
  2642. if (work_done < budget && napi_complete_done(napi, work_done)) {
  2643. unsigned long flags;
  2644. spin_lock_irqsave(&hw->hw_lock, flags);
  2645. hw->intr_mask |= napimask[skge->port];
  2646. skge_write32(hw, B0_IMSK, hw->intr_mask);
  2647. skge_read32(hw, B0_IMSK);
  2648. spin_unlock_irqrestore(&hw->hw_lock, flags);
  2649. }
  2650. return work_done;
  2651. }
  2652. /* Parity errors seem to happen when Genesis is connected to a switch
  2653. * with no other ports present. Heartbeat error??
  2654. */
  2655. static void skge_mac_parity(struct skge_hw *hw, int port)
  2656. {
  2657. struct net_device *dev = hw->dev[port];
  2658. ++dev->stats.tx_heartbeat_errors;
  2659. if (is_genesis(hw))
  2660. skge_write16(hw, SK_REG(port, TX_MFF_CTRL1),
  2661. MFF_CLR_PERR);
  2662. else
  2663. /* HW-Bug #8: cleared by GMF_CLI_TX_FC instead of GMF_CLI_TX_PE */
  2664. skge_write8(hw, SK_REG(port, TX_GMF_CTRL_T),
  2665. (hw->chip_id == CHIP_ID_YUKON && hw->chip_rev == 0)
  2666. ? GMF_CLI_TX_FC : GMF_CLI_TX_PE);
  2667. }
  2668. static void skge_mac_intr(struct skge_hw *hw, int port)
  2669. {
  2670. if (is_genesis(hw))
  2671. genesis_mac_intr(hw, port);
  2672. else
  2673. yukon_mac_intr(hw, port);
  2674. }
  2675. /* Handle device specific framing and timeout interrupts */
  2676. static void skge_error_irq(struct skge_hw *hw)
  2677. {
  2678. struct pci_dev *pdev = hw->pdev;
  2679. u32 hwstatus = skge_read32(hw, B0_HWE_ISRC);
  2680. if (is_genesis(hw)) {
  2681. /* clear xmac errors */
  2682. if (hwstatus & (IS_NO_STAT_M1|IS_NO_TIST_M1))
  2683. skge_write16(hw, RX_MFF_CTRL1, MFF_CLR_INSTAT);
  2684. if (hwstatus & (IS_NO_STAT_M2|IS_NO_TIST_M2))
  2685. skge_write16(hw, RX_MFF_CTRL2, MFF_CLR_INSTAT);
  2686. } else {
  2687. /* Timestamp (unused) overflow */
  2688. if (hwstatus & IS_IRQ_TIST_OV)
  2689. skge_write8(hw, GMAC_TI_ST_CTRL, GMT_ST_CLR_IRQ);
  2690. }
  2691. if (hwstatus & IS_RAM_RD_PAR) {
  2692. dev_err(&pdev->dev, "Ram read data parity error\n");
  2693. skge_write16(hw, B3_RI_CTRL, RI_CLR_RD_PERR);
  2694. }
  2695. if (hwstatus & IS_RAM_WR_PAR) {
  2696. dev_err(&pdev->dev, "Ram write data parity error\n");
  2697. skge_write16(hw, B3_RI_CTRL, RI_CLR_WR_PERR);
  2698. }
  2699. if (hwstatus & IS_M1_PAR_ERR)
  2700. skge_mac_parity(hw, 0);
  2701. if (hwstatus & IS_M2_PAR_ERR)
  2702. skge_mac_parity(hw, 1);
  2703. if (hwstatus & IS_R1_PAR_ERR) {
  2704. dev_err(&pdev->dev, "%s: receive queue parity error\n",
  2705. hw->dev[0]->name);
  2706. skge_write32(hw, B0_R1_CSR, CSR_IRQ_CL_P);
  2707. }
  2708. if (hwstatus & IS_R2_PAR_ERR) {
  2709. dev_err(&pdev->dev, "%s: receive queue parity error\n",
  2710. hw->dev[1]->name);
  2711. skge_write32(hw, B0_R2_CSR, CSR_IRQ_CL_P);
  2712. }
  2713. if (hwstatus & (IS_IRQ_MST_ERR|IS_IRQ_STAT)) {
  2714. u16 pci_status, pci_cmd;
  2715. pci_read_config_word(pdev, PCI_COMMAND, &pci_cmd);
  2716. pci_read_config_word(pdev, PCI_STATUS, &pci_status);
  2717. dev_err(&pdev->dev, "PCI error cmd=%#x status=%#x\n",
  2718. pci_cmd, pci_status);
  2719. /* Write the error bits back to clear them. */
  2720. pci_status &= PCI_STATUS_ERROR_BITS;
  2721. skge_write8(hw, B2_TST_CTRL1, TST_CFG_WRITE_ON);
  2722. pci_write_config_word(pdev, PCI_COMMAND,
  2723. pci_cmd | PCI_COMMAND_SERR | PCI_COMMAND_PARITY);
  2724. pci_write_config_word(pdev, PCI_STATUS, pci_status);
  2725. skge_write8(hw, B2_TST_CTRL1, TST_CFG_WRITE_OFF);
  2726. /* if error still set then just ignore it */
  2727. hwstatus = skge_read32(hw, B0_HWE_ISRC);
  2728. if (hwstatus & IS_IRQ_STAT) {
  2729. dev_warn(&hw->pdev->dev, "unable to clear error (so ignoring them)\n");
  2730. hw->intr_mask &= ~IS_HW_ERR;
  2731. }
  2732. }
  2733. }
  2734. /*
  2735. * Interrupt from PHY are handled in tasklet (softirq)
  2736. * because accessing phy registers requires spin wait which might
  2737. * cause excess interrupt latency.
  2738. */
  2739. static void skge_extirq(struct tasklet_struct *t)
  2740. {
  2741. struct skge_hw *hw = from_tasklet(hw, t, phy_task);
  2742. int port;
  2743. for (port = 0; port < hw->ports; port++) {
  2744. struct net_device *dev = hw->dev[port];
  2745. if (netif_running(dev)) {
  2746. struct skge_port *skge = netdev_priv(dev);
  2747. spin_lock(&hw->phy_lock);
  2748. if (!is_genesis(hw))
  2749. yukon_phy_intr(skge);
  2750. else if (hw->phy_type == SK_PHY_BCOM)
  2751. bcom_phy_intr(skge);
  2752. spin_unlock(&hw->phy_lock);
  2753. }
  2754. }
  2755. spin_lock_irq(&hw->hw_lock);
  2756. hw->intr_mask |= IS_EXT_REG;
  2757. skge_write32(hw, B0_IMSK, hw->intr_mask);
  2758. skge_read32(hw, B0_IMSK);
  2759. spin_unlock_irq(&hw->hw_lock);
  2760. }
  2761. static irqreturn_t skge_intr(int irq, void *dev_id)
  2762. {
  2763. struct skge_hw *hw = dev_id;
  2764. u32 status;
  2765. int handled = 0;
  2766. spin_lock(&hw->hw_lock);
  2767. /* Reading this register masks IRQ */
  2768. status = skge_read32(hw, B0_SP_ISRC);
  2769. if (status == 0 || status == ~0)
  2770. goto out;
  2771. handled = 1;
  2772. status &= hw->intr_mask;
  2773. if (status & IS_EXT_REG) {
  2774. hw->intr_mask &= ~IS_EXT_REG;
  2775. tasklet_schedule(&hw->phy_task);
  2776. }
  2777. if (status & (IS_XA1_F|IS_R1_F)) {
  2778. struct skge_port *skge = netdev_priv(hw->dev[0]);
  2779. hw->intr_mask &= ~(IS_XA1_F|IS_R1_F);
  2780. napi_schedule(&skge->napi);
  2781. }
  2782. if (status & IS_PA_TO_TX1)
  2783. skge_write16(hw, B3_PA_CTRL, PA_CLR_TO_TX1);
  2784. if (status & IS_PA_TO_RX1) {
  2785. ++hw->dev[0]->stats.rx_over_errors;
  2786. skge_write16(hw, B3_PA_CTRL, PA_CLR_TO_RX1);
  2787. }
  2788. if (status & IS_MAC1)
  2789. skge_mac_intr(hw, 0);
  2790. if (hw->dev[1]) {
  2791. struct skge_port *skge = netdev_priv(hw->dev[1]);
  2792. if (status & (IS_XA2_F|IS_R2_F)) {
  2793. hw->intr_mask &= ~(IS_XA2_F|IS_R2_F);
  2794. napi_schedule(&skge->napi);
  2795. }
  2796. if (status & IS_PA_TO_RX2) {
  2797. ++hw->dev[1]->stats.rx_over_errors;
  2798. skge_write16(hw, B3_PA_CTRL, PA_CLR_TO_RX2);
  2799. }
  2800. if (status & IS_PA_TO_TX2)
  2801. skge_write16(hw, B3_PA_CTRL, PA_CLR_TO_TX2);
  2802. if (status & IS_MAC2)
  2803. skge_mac_intr(hw, 1);
  2804. }
  2805. if (status & IS_HW_ERR)
  2806. skge_error_irq(hw);
  2807. out:
  2808. skge_write32(hw, B0_IMSK, hw->intr_mask);
  2809. skge_read32(hw, B0_IMSK);
  2810. spin_unlock(&hw->hw_lock);
  2811. return IRQ_RETVAL(handled);
  2812. }
  2813. #ifdef CONFIG_NET_POLL_CONTROLLER
  2814. static void skge_netpoll(struct net_device *dev)
  2815. {
  2816. struct skge_port *skge = netdev_priv(dev);
  2817. disable_irq(dev->irq);
  2818. skge_intr(dev->irq, skge->hw);
  2819. enable_irq(dev->irq);
  2820. }
  2821. #endif
  2822. static int skge_set_mac_address(struct net_device *dev, void *p)
  2823. {
  2824. struct skge_port *skge = netdev_priv(dev);
  2825. struct skge_hw *hw = skge->hw;
  2826. unsigned port = skge->port;
  2827. const struct sockaddr *addr = p;
  2828. u16 ctrl;
  2829. if (!is_valid_ether_addr(addr->sa_data))
  2830. return -EADDRNOTAVAIL;
  2831. eth_hw_addr_set(dev, addr->sa_data);
  2832. if (!netif_running(dev)) {
  2833. memcpy_toio(hw->regs + B2_MAC_1 + port*8, dev->dev_addr, ETH_ALEN);
  2834. memcpy_toio(hw->regs + B2_MAC_2 + port*8, dev->dev_addr, ETH_ALEN);
  2835. } else {
  2836. /* disable Rx */
  2837. spin_lock_bh(&hw->phy_lock);
  2838. ctrl = gma_read16(hw, port, GM_GP_CTRL);
  2839. gma_write16(hw, port, GM_GP_CTRL, ctrl & ~GM_GPCR_RX_ENA);
  2840. memcpy_toio(hw->regs + B2_MAC_1 + port*8, dev->dev_addr, ETH_ALEN);
  2841. memcpy_toio(hw->regs + B2_MAC_2 + port*8, dev->dev_addr, ETH_ALEN);
  2842. if (is_genesis(hw))
  2843. xm_outaddr(hw, port, XM_SA, dev->dev_addr);
  2844. else {
  2845. gma_set_addr(hw, port, GM_SRC_ADDR_1L, dev->dev_addr);
  2846. gma_set_addr(hw, port, GM_SRC_ADDR_2L, dev->dev_addr);
  2847. }
  2848. gma_write16(hw, port, GM_GP_CTRL, ctrl);
  2849. spin_unlock_bh(&hw->phy_lock);
  2850. }
  2851. return 0;
  2852. }
  2853. static const struct {
  2854. u8 id;
  2855. const char *name;
  2856. } skge_chips[] = {
  2857. { CHIP_ID_GENESIS, "Genesis" },
  2858. { CHIP_ID_YUKON, "Yukon" },
  2859. { CHIP_ID_YUKON_LITE, "Yukon-Lite"},
  2860. { CHIP_ID_YUKON_LP, "Yukon-LP"},
  2861. };
  2862. static const char *skge_board_name(const struct skge_hw *hw)
  2863. {
  2864. int i;
  2865. static char buf[16];
  2866. for (i = 0; i < ARRAY_SIZE(skge_chips); i++)
  2867. if (skge_chips[i].id == hw->chip_id)
  2868. return skge_chips[i].name;
  2869. snprintf(buf, sizeof(buf), "chipid 0x%x", hw->chip_id);
  2870. return buf;
  2871. }
  2872. /*
  2873. * Setup the board data structure, but don't bring up
  2874. * the port(s)
  2875. */
  2876. static int skge_reset(struct skge_hw *hw)
  2877. {
  2878. u32 reg;
  2879. u16 ctst, pci_status;
  2880. u8 t8, mac_cfg, pmd_type;
  2881. int i;
  2882. ctst = skge_read16(hw, B0_CTST);
  2883. /* do a SW reset */
  2884. skge_write8(hw, B0_CTST, CS_RST_SET);
  2885. skge_write8(hw, B0_CTST, CS_RST_CLR);
  2886. /* clear PCI errors, if any */
  2887. skge_write8(hw, B2_TST_CTRL1, TST_CFG_WRITE_ON);
  2888. skge_write8(hw, B2_TST_CTRL2, 0);
  2889. pci_read_config_word(hw->pdev, PCI_STATUS, &pci_status);
  2890. pci_write_config_word(hw->pdev, PCI_STATUS,
  2891. pci_status | PCI_STATUS_ERROR_BITS);
  2892. skge_write8(hw, B2_TST_CTRL1, TST_CFG_WRITE_OFF);
  2893. skge_write8(hw, B0_CTST, CS_MRST_CLR);
  2894. /* restore CLK_RUN bits (for Yukon-Lite) */
  2895. skge_write16(hw, B0_CTST,
  2896. ctst & (CS_CLK_RUN_HOT|CS_CLK_RUN_RST|CS_CLK_RUN_ENA));
  2897. hw->chip_id = skge_read8(hw, B2_CHIP_ID);
  2898. hw->phy_type = skge_read8(hw, B2_E_1) & 0xf;
  2899. pmd_type = skge_read8(hw, B2_PMD_TYP);
  2900. hw->copper = (pmd_type == 'T' || pmd_type == '1');
  2901. switch (hw->chip_id) {
  2902. case CHIP_ID_GENESIS:
  2903. #ifdef CONFIG_SKGE_GENESIS
  2904. switch (hw->phy_type) {
  2905. case SK_PHY_XMAC:
  2906. hw->phy_addr = PHY_ADDR_XMAC;
  2907. break;
  2908. case SK_PHY_BCOM:
  2909. hw->phy_addr = PHY_ADDR_BCOM;
  2910. break;
  2911. default:
  2912. dev_err(&hw->pdev->dev, "unsupported phy type 0x%x\n",
  2913. hw->phy_type);
  2914. return -EOPNOTSUPP;
  2915. }
  2916. break;
  2917. #else
  2918. dev_err(&hw->pdev->dev, "Genesis chip detected but not configured\n");
  2919. return -EOPNOTSUPP;
  2920. #endif
  2921. case CHIP_ID_YUKON:
  2922. case CHIP_ID_YUKON_LITE:
  2923. case CHIP_ID_YUKON_LP:
  2924. if (hw->phy_type < SK_PHY_MARV_COPPER && pmd_type != 'S')
  2925. hw->copper = 1;
  2926. hw->phy_addr = PHY_ADDR_MARV;
  2927. break;
  2928. default:
  2929. dev_err(&hw->pdev->dev, "unsupported chip type 0x%x\n",
  2930. hw->chip_id);
  2931. return -EOPNOTSUPP;
  2932. }
  2933. mac_cfg = skge_read8(hw, B2_MAC_CFG);
  2934. hw->ports = (mac_cfg & CFG_SNG_MAC) ? 1 : 2;
  2935. hw->chip_rev = (mac_cfg & CFG_CHIP_R_MSK) >> 4;
  2936. /* read the adapters RAM size */
  2937. t8 = skge_read8(hw, B2_E_0);
  2938. if (is_genesis(hw)) {
  2939. if (t8 == 3) {
  2940. /* special case: 4 x 64k x 36, offset = 0x80000 */
  2941. hw->ram_size = 0x100000;
  2942. hw->ram_offset = 0x80000;
  2943. } else
  2944. hw->ram_size = t8 * 512;
  2945. } else if (t8 == 0)
  2946. hw->ram_size = 0x20000;
  2947. else
  2948. hw->ram_size = t8 * 4096;
  2949. hw->intr_mask = IS_HW_ERR;
  2950. /* Use PHY IRQ for all but fiber based Genesis board */
  2951. if (!(is_genesis(hw) && hw->phy_type == SK_PHY_XMAC))
  2952. hw->intr_mask |= IS_EXT_REG;
  2953. if (is_genesis(hw))
  2954. genesis_init(hw);
  2955. else {
  2956. /* switch power to VCC (WA for VAUX problem) */
  2957. skge_write8(hw, B0_POWER_CTRL,
  2958. PC_VAUX_ENA | PC_VCC_ENA | PC_VAUX_OFF | PC_VCC_ON);
  2959. /* avoid boards with stuck Hardware error bits */
  2960. if ((skge_read32(hw, B0_ISRC) & IS_HW_ERR) &&
  2961. (skge_read32(hw, B0_HWE_ISRC) & IS_IRQ_SENSOR)) {
  2962. dev_warn(&hw->pdev->dev, "stuck hardware sensor bit\n");
  2963. hw->intr_mask &= ~IS_HW_ERR;
  2964. }
  2965. /* Clear PHY COMA */
  2966. skge_write8(hw, B2_TST_CTRL1, TST_CFG_WRITE_ON);
  2967. pci_read_config_dword(hw->pdev, PCI_DEV_REG1, &reg);
  2968. reg &= ~PCI_PHY_COMA;
  2969. pci_write_config_dword(hw->pdev, PCI_DEV_REG1, reg);
  2970. skge_write8(hw, B2_TST_CTRL1, TST_CFG_WRITE_OFF);
  2971. for (i = 0; i < hw->ports; i++) {
  2972. skge_write16(hw, SK_REG(i, GMAC_LINK_CTRL), GMLC_RST_SET);
  2973. skge_write16(hw, SK_REG(i, GMAC_LINK_CTRL), GMLC_RST_CLR);
  2974. }
  2975. }
  2976. /* turn off hardware timer (unused) */
  2977. skge_write8(hw, B2_TI_CTRL, TIM_STOP);
  2978. skge_write8(hw, B2_TI_CTRL, TIM_CLR_IRQ);
  2979. skge_write8(hw, B0_LED, LED_STAT_ON);
  2980. /* enable the Tx Arbiters */
  2981. for (i = 0; i < hw->ports; i++)
  2982. skge_write8(hw, SK_REG(i, TXA_CTRL), TXA_ENA_ARB);
  2983. /* Initialize ram interface */
  2984. skge_write16(hw, B3_RI_CTRL, RI_RST_CLR);
  2985. skge_write8(hw, B3_RI_WTO_R1, SK_RI_TO_53);
  2986. skge_write8(hw, B3_RI_WTO_XA1, SK_RI_TO_53);
  2987. skge_write8(hw, B3_RI_WTO_XS1, SK_RI_TO_53);
  2988. skge_write8(hw, B3_RI_RTO_R1, SK_RI_TO_53);
  2989. skge_write8(hw, B3_RI_RTO_XA1, SK_RI_TO_53);
  2990. skge_write8(hw, B3_RI_RTO_XS1, SK_RI_TO_53);
  2991. skge_write8(hw, B3_RI_WTO_R2, SK_RI_TO_53);
  2992. skge_write8(hw, B3_RI_WTO_XA2, SK_RI_TO_53);
  2993. skge_write8(hw, B3_RI_WTO_XS2, SK_RI_TO_53);
  2994. skge_write8(hw, B3_RI_RTO_R2, SK_RI_TO_53);
  2995. skge_write8(hw, B3_RI_RTO_XA2, SK_RI_TO_53);
  2996. skge_write8(hw, B3_RI_RTO_XS2, SK_RI_TO_53);
  2997. skge_write32(hw, B0_HWE_IMSK, IS_ERR_MSK);
  2998. /* Set interrupt moderation for Transmit only
  2999. * Receive interrupts avoided by NAPI
  3000. */
  3001. skge_write32(hw, B2_IRQM_MSK, IS_XA1_F|IS_XA2_F);
  3002. skge_write32(hw, B2_IRQM_INI, skge_usecs2clk(hw, 100));
  3003. skge_write32(hw, B2_IRQM_CTRL, TIM_START);
  3004. /* Leave irq disabled until first port is brought up. */
  3005. skge_write32(hw, B0_IMSK, 0);
  3006. for (i = 0; i < hw->ports; i++) {
  3007. if (is_genesis(hw))
  3008. genesis_reset(hw, i);
  3009. else
  3010. yukon_reset(hw, i);
  3011. }
  3012. return 0;
  3013. }
  3014. #ifdef CONFIG_SKGE_DEBUG
  3015. static struct dentry *skge_debug;
  3016. static int skge_debug_show(struct seq_file *seq, void *v)
  3017. {
  3018. struct net_device *dev = seq->private;
  3019. const struct skge_port *skge = netdev_priv(dev);
  3020. const struct skge_hw *hw = skge->hw;
  3021. const struct skge_element *e;
  3022. if (!netif_running(dev))
  3023. return -ENETDOWN;
  3024. seq_printf(seq, "IRQ src=%x mask=%x\n", skge_read32(hw, B0_ISRC),
  3025. skge_read32(hw, B0_IMSK));
  3026. seq_printf(seq, "Tx Ring: (%d)\n", skge_avail(&skge->tx_ring));
  3027. for (e = skge->tx_ring.to_clean; e != skge->tx_ring.to_use; e = e->next) {
  3028. const struct skge_tx_desc *t = e->desc;
  3029. seq_printf(seq, "%#x dma=%#x%08x %#x csum=%#x/%x/%x\n",
  3030. t->control, t->dma_hi, t->dma_lo, t->status,
  3031. t->csum_offs, t->csum_write, t->csum_start);
  3032. }
  3033. seq_puts(seq, "\nRx Ring:\n");
  3034. for (e = skge->rx_ring.to_clean; ; e = e->next) {
  3035. const struct skge_rx_desc *r = e->desc;
  3036. if (r->control & BMU_OWN)
  3037. break;
  3038. seq_printf(seq, "%#x dma=%#x%08x %#x %#x csum=%#x/%x\n",
  3039. r->control, r->dma_hi, r->dma_lo, r->status,
  3040. r->timestamp, r->csum1, r->csum1_start);
  3041. }
  3042. return 0;
  3043. }
  3044. DEFINE_SHOW_ATTRIBUTE(skge_debug);
  3045. /*
  3046. * Use network device events to create/remove/rename
  3047. * debugfs file entries
  3048. */
  3049. static int skge_device_event(struct notifier_block *unused,
  3050. unsigned long event, void *ptr)
  3051. {
  3052. struct net_device *dev = netdev_notifier_info_to_dev(ptr);
  3053. struct skge_port *skge;
  3054. if (dev->netdev_ops->ndo_open != &skge_up || !skge_debug)
  3055. goto done;
  3056. skge = netdev_priv(dev);
  3057. switch (event) {
  3058. case NETDEV_CHANGENAME:
  3059. debugfs_change_name(skge->debugfs, "%s", dev->name);
  3060. break;
  3061. case NETDEV_GOING_DOWN:
  3062. debugfs_remove(skge->debugfs);
  3063. skge->debugfs = NULL;
  3064. break;
  3065. case NETDEV_UP:
  3066. skge->debugfs = debugfs_create_file(dev->name, 0444, skge_debug,
  3067. dev, &skge_debug_fops);
  3068. break;
  3069. }
  3070. done:
  3071. return NOTIFY_DONE;
  3072. }
  3073. static struct notifier_block skge_notifier = {
  3074. .notifier_call = skge_device_event,
  3075. };
  3076. static __init void skge_debug_init(void)
  3077. {
  3078. skge_debug = debugfs_create_dir("skge", NULL);
  3079. register_netdevice_notifier(&skge_notifier);
  3080. }
  3081. static __exit void skge_debug_cleanup(void)
  3082. {
  3083. if (skge_debug) {
  3084. unregister_netdevice_notifier(&skge_notifier);
  3085. debugfs_remove(skge_debug);
  3086. skge_debug = NULL;
  3087. }
  3088. }
  3089. #else
  3090. #define skge_debug_init()
  3091. #define skge_debug_cleanup()
  3092. #endif
  3093. static const struct net_device_ops skge_netdev_ops = {
  3094. .ndo_open = skge_up,
  3095. .ndo_stop = skge_down,
  3096. .ndo_start_xmit = skge_xmit_frame,
  3097. .ndo_eth_ioctl = skge_ioctl,
  3098. .ndo_get_stats = skge_get_stats,
  3099. .ndo_tx_timeout = skge_tx_timeout,
  3100. .ndo_change_mtu = skge_change_mtu,
  3101. .ndo_validate_addr = eth_validate_addr,
  3102. .ndo_set_rx_mode = skge_set_multicast,
  3103. .ndo_set_mac_address = skge_set_mac_address,
  3104. #ifdef CONFIG_NET_POLL_CONTROLLER
  3105. .ndo_poll_controller = skge_netpoll,
  3106. #endif
  3107. };
  3108. /* Initialize network device */
  3109. static struct net_device *skge_devinit(struct skge_hw *hw, int port,
  3110. int highmem)
  3111. {
  3112. struct skge_port *skge;
  3113. struct net_device *dev = alloc_etherdev(sizeof(*skge));
  3114. u8 addr[ETH_ALEN];
  3115. if (!dev)
  3116. return NULL;
  3117. SET_NETDEV_DEV(dev, &hw->pdev->dev);
  3118. dev->netdev_ops = &skge_netdev_ops;
  3119. dev->ethtool_ops = &skge_ethtool_ops;
  3120. dev->watchdog_timeo = TX_WATCHDOG;
  3121. dev->irq = hw->pdev->irq;
  3122. /* MTU range: 60 - 9000 */
  3123. dev->min_mtu = ETH_ZLEN;
  3124. dev->max_mtu = ETH_JUMBO_MTU;
  3125. if (highmem)
  3126. dev->features |= NETIF_F_HIGHDMA;
  3127. skge = netdev_priv(dev);
  3128. netif_napi_add(dev, &skge->napi, skge_poll);
  3129. skge->netdev = dev;
  3130. skge->hw = hw;
  3131. skge->msg_enable = netif_msg_init(debug, default_msg);
  3132. skge->tx_ring.count = DEFAULT_TX_RING_SIZE;
  3133. skge->rx_ring.count = DEFAULT_RX_RING_SIZE;
  3134. /* Auto speed and flow control */
  3135. skge->autoneg = AUTONEG_ENABLE;
  3136. skge->flow_control = FLOW_MODE_SYM_OR_REM;
  3137. skge->duplex = -1;
  3138. skge->speed = -1;
  3139. skge->advertising = skge_supported_modes(hw);
  3140. if (device_can_wakeup(&hw->pdev->dev)) {
  3141. skge->wol = wol_supported(hw) & WAKE_MAGIC;
  3142. device_set_wakeup_enable(&hw->pdev->dev, skge->wol);
  3143. }
  3144. hw->dev[port] = dev;
  3145. skge->port = port;
  3146. /* Only used for Genesis XMAC */
  3147. if (is_genesis(hw))
  3148. timer_setup(&skge->link_timer, xm_link_timer, 0);
  3149. else {
  3150. dev->hw_features = NETIF_F_IP_CSUM | NETIF_F_SG |
  3151. NETIF_F_RXCSUM;
  3152. dev->features |= dev->hw_features;
  3153. }
  3154. /* read the mac address */
  3155. memcpy_fromio(addr, hw->regs + B2_MAC_1 + port*8, ETH_ALEN);
  3156. eth_hw_addr_set(dev, addr);
  3157. return dev;
  3158. }
  3159. static void skge_show_addr(struct net_device *dev)
  3160. {
  3161. const struct skge_port *skge = netdev_priv(dev);
  3162. netif_info(skge, probe, skge->netdev, "addr %pM\n", dev->dev_addr);
  3163. }
  3164. static int only_32bit_dma;
  3165. static int skge_probe(struct pci_dev *pdev, const struct pci_device_id *ent)
  3166. {
  3167. struct net_device *dev, *dev1;
  3168. struct skge_hw *hw;
  3169. int err, using_dac = 0;
  3170. err = pci_enable_device(pdev);
  3171. if (err) {
  3172. dev_err(&pdev->dev, "cannot enable PCI device\n");
  3173. goto err_out;
  3174. }
  3175. err = pci_request_regions(pdev, DRV_NAME);
  3176. if (err) {
  3177. dev_err(&pdev->dev, "cannot obtain PCI resources\n");
  3178. goto err_out_disable_pdev;
  3179. }
  3180. pci_set_master(pdev);
  3181. if (!only_32bit_dma && !dma_set_mask(&pdev->dev, DMA_BIT_MASK(64))) {
  3182. using_dac = 1;
  3183. err = dma_set_coherent_mask(&pdev->dev, DMA_BIT_MASK(64));
  3184. } else if (!(err = dma_set_mask(&pdev->dev, DMA_BIT_MASK(32)))) {
  3185. using_dac = 0;
  3186. err = dma_set_coherent_mask(&pdev->dev, DMA_BIT_MASK(32));
  3187. }
  3188. if (err) {
  3189. dev_err(&pdev->dev, "no usable DMA configuration\n");
  3190. goto err_out_free_regions;
  3191. }
  3192. #ifdef __BIG_ENDIAN
  3193. /* byte swap descriptors in hardware */
  3194. {
  3195. u32 reg;
  3196. pci_read_config_dword(pdev, PCI_DEV_REG2, &reg);
  3197. reg |= PCI_REV_DESC;
  3198. pci_write_config_dword(pdev, PCI_DEV_REG2, reg);
  3199. }
  3200. #endif
  3201. err = -ENOMEM;
  3202. /* space for skge@pci:0000:04:00.0 */
  3203. hw = kzalloc(sizeof(*hw) + strlen(DRV_NAME "@pci:")
  3204. + strlen(pci_name(pdev)) + 1, GFP_KERNEL);
  3205. if (!hw)
  3206. goto err_out_free_regions;
  3207. sprintf(hw->irq_name, DRV_NAME "@pci:%s", pci_name(pdev));
  3208. hw->pdev = pdev;
  3209. spin_lock_init(&hw->hw_lock);
  3210. spin_lock_init(&hw->phy_lock);
  3211. tasklet_setup(&hw->phy_task, skge_extirq);
  3212. hw->regs = ioremap(pci_resource_start(pdev, 0), 0x4000);
  3213. if (!hw->regs) {
  3214. dev_err(&pdev->dev, "cannot map device registers\n");
  3215. goto err_out_free_hw;
  3216. }
  3217. err = skge_reset(hw);
  3218. if (err)
  3219. goto err_out_iounmap;
  3220. pr_info("%s addr 0x%llx irq %d chip %s rev %d\n",
  3221. DRV_VERSION,
  3222. (unsigned long long)pci_resource_start(pdev, 0), pdev->irq,
  3223. skge_board_name(hw), hw->chip_rev);
  3224. dev = skge_devinit(hw, 0, using_dac);
  3225. if (!dev) {
  3226. err = -ENOMEM;
  3227. goto err_out_led_off;
  3228. }
  3229. /* Some motherboards are broken and has zero in ROM. */
  3230. if (!is_valid_ether_addr(dev->dev_addr))
  3231. dev_warn(&pdev->dev, "bad (zero?) ethernet address in rom\n");
  3232. err = register_netdev(dev);
  3233. if (err) {
  3234. dev_err(&pdev->dev, "cannot register net device\n");
  3235. goto err_out_free_netdev;
  3236. }
  3237. skge_show_addr(dev);
  3238. if (hw->ports > 1) {
  3239. dev1 = skge_devinit(hw, 1, using_dac);
  3240. if (!dev1) {
  3241. err = -ENOMEM;
  3242. goto err_out_unregister;
  3243. }
  3244. err = register_netdev(dev1);
  3245. if (err) {
  3246. dev_err(&pdev->dev, "cannot register second net device\n");
  3247. goto err_out_free_dev1;
  3248. }
  3249. err = request_irq(pdev->irq, skge_intr, IRQF_SHARED,
  3250. hw->irq_name, hw);
  3251. if (err) {
  3252. dev_err(&pdev->dev, "cannot assign irq %d\n",
  3253. pdev->irq);
  3254. goto err_out_unregister_dev1;
  3255. }
  3256. skge_show_addr(dev1);
  3257. }
  3258. pci_set_drvdata(pdev, hw);
  3259. return 0;
  3260. err_out_unregister_dev1:
  3261. unregister_netdev(dev1);
  3262. err_out_free_dev1:
  3263. free_netdev(dev1);
  3264. err_out_unregister:
  3265. unregister_netdev(dev);
  3266. err_out_free_netdev:
  3267. free_netdev(dev);
  3268. err_out_led_off:
  3269. skge_write16(hw, B0_LED, LED_STAT_OFF);
  3270. err_out_iounmap:
  3271. iounmap(hw->regs);
  3272. err_out_free_hw:
  3273. kfree(hw);
  3274. err_out_free_regions:
  3275. pci_release_regions(pdev);
  3276. err_out_disable_pdev:
  3277. pci_disable_device(pdev);
  3278. err_out:
  3279. return err;
  3280. }
  3281. static void skge_remove(struct pci_dev *pdev)
  3282. {
  3283. struct skge_hw *hw = pci_get_drvdata(pdev);
  3284. struct net_device *dev0, *dev1;
  3285. if (!hw)
  3286. return;
  3287. dev1 = hw->dev[1];
  3288. if (dev1)
  3289. unregister_netdev(dev1);
  3290. dev0 = hw->dev[0];
  3291. unregister_netdev(dev0);
  3292. tasklet_kill(&hw->phy_task);
  3293. spin_lock_irq(&hw->hw_lock);
  3294. hw->intr_mask = 0;
  3295. if (hw->ports > 1) {
  3296. skge_write32(hw, B0_IMSK, 0);
  3297. skge_read32(hw, B0_IMSK);
  3298. }
  3299. spin_unlock_irq(&hw->hw_lock);
  3300. skge_write16(hw, B0_LED, LED_STAT_OFF);
  3301. skge_write8(hw, B0_CTST, CS_RST_SET);
  3302. if (hw->ports > 1)
  3303. free_irq(pdev->irq, hw);
  3304. pci_release_regions(pdev);
  3305. pci_disable_device(pdev);
  3306. if (dev1)
  3307. free_netdev(dev1);
  3308. free_netdev(dev0);
  3309. iounmap(hw->regs);
  3310. kfree(hw);
  3311. }
  3312. #ifdef CONFIG_PM_SLEEP
  3313. static int skge_suspend(struct device *dev)
  3314. {
  3315. struct skge_hw *hw = dev_get_drvdata(dev);
  3316. int i;
  3317. if (!hw)
  3318. return 0;
  3319. for (i = 0; i < hw->ports; i++) {
  3320. struct net_device *dev = hw->dev[i];
  3321. struct skge_port *skge = netdev_priv(dev);
  3322. if (netif_running(dev))
  3323. skge_down(dev);
  3324. if (skge->wol)
  3325. skge_wol_init(skge);
  3326. }
  3327. skge_write32(hw, B0_IMSK, 0);
  3328. return 0;
  3329. }
  3330. static int skge_resume(struct device *dev)
  3331. {
  3332. struct skge_hw *hw = dev_get_drvdata(dev);
  3333. int i, err;
  3334. if (!hw)
  3335. return 0;
  3336. err = skge_reset(hw);
  3337. if (err)
  3338. goto out;
  3339. for (i = 0; i < hw->ports; i++) {
  3340. struct net_device *dev = hw->dev[i];
  3341. if (netif_running(dev)) {
  3342. err = skge_up(dev);
  3343. if (err) {
  3344. netdev_err(dev, "could not up: %d\n", err);
  3345. dev_close(dev);
  3346. goto out;
  3347. }
  3348. }
  3349. }
  3350. out:
  3351. return err;
  3352. }
  3353. static SIMPLE_DEV_PM_OPS(skge_pm_ops, skge_suspend, skge_resume);
  3354. #define SKGE_PM_OPS (&skge_pm_ops)
  3355. #else
  3356. #define SKGE_PM_OPS NULL
  3357. #endif /* CONFIG_PM_SLEEP */
  3358. static void skge_shutdown(struct pci_dev *pdev)
  3359. {
  3360. struct skge_hw *hw = pci_get_drvdata(pdev);
  3361. int i;
  3362. if (!hw)
  3363. return;
  3364. for (i = 0; i < hw->ports; i++) {
  3365. struct net_device *dev = hw->dev[i];
  3366. struct skge_port *skge = netdev_priv(dev);
  3367. if (skge->wol)
  3368. skge_wol_init(skge);
  3369. }
  3370. pci_wake_from_d3(pdev, device_may_wakeup(&pdev->dev));
  3371. pci_set_power_state(pdev, PCI_D3hot);
  3372. }
  3373. static struct pci_driver skge_driver = {
  3374. .name = DRV_NAME,
  3375. .id_table = skge_id_table,
  3376. .probe = skge_probe,
  3377. .remove = skge_remove,
  3378. .shutdown = skge_shutdown,
  3379. .driver.pm = SKGE_PM_OPS,
  3380. };
  3381. static const struct dmi_system_id skge_32bit_dma_boards[] = {
  3382. {
  3383. .ident = "Gigabyte nForce boards",
  3384. .matches = {
  3385. DMI_MATCH(DMI_BOARD_VENDOR, "Gigabyte Technology Co"),
  3386. DMI_MATCH(DMI_BOARD_NAME, "nForce"),
  3387. },
  3388. },
  3389. {
  3390. .ident = "ASUS P5NSLI",
  3391. .matches = {
  3392. DMI_MATCH(DMI_BOARD_VENDOR, "ASUSTeK Computer INC."),
  3393. DMI_MATCH(DMI_BOARD_NAME, "P5NSLI")
  3394. },
  3395. },
  3396. {
  3397. .ident = "FUJITSU SIEMENS A8NE-FM",
  3398. .matches = {
  3399. DMI_MATCH(DMI_BOARD_VENDOR, "ASUSTek Computer INC."),
  3400. DMI_MATCH(DMI_BOARD_NAME, "A8NE-FM")
  3401. },
  3402. },
  3403. {}
  3404. };
  3405. static int __init skge_init_module(void)
  3406. {
  3407. if (dmi_check_system(skge_32bit_dma_boards))
  3408. only_32bit_dma = 1;
  3409. skge_debug_init();
  3410. return pci_register_driver(&skge_driver);
  3411. }
  3412. static void __exit skge_cleanup_module(void)
  3413. {
  3414. pci_unregister_driver(&skge_driver);
  3415. skge_debug_cleanup();
  3416. }
  3417. module_init(skge_init_module);
  3418. module_exit(skge_cleanup_module);