niu.c 231 KB

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  1. // SPDX-License-Identifier: GPL-2.0
  2. /* niu.c: Neptune ethernet driver.
  3. *
  4. * Copyright (C) 2007, 2008 David S. Miller (davem@davemloft.net)
  5. */
  6. #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
  7. #include <linux/module.h>
  8. #include <linux/init.h>
  9. #include <linux/interrupt.h>
  10. #include <linux/pci.h>
  11. #include <linux/dma-mapping.h>
  12. #include <linux/netdevice.h>
  13. #include <linux/ethtool.h>
  14. #include <linux/etherdevice.h>
  15. #include <linux/platform_device.h>
  16. #include <linux/delay.h>
  17. #include <linux/bitops.h>
  18. #include <linux/mii.h>
  19. #include <linux/if.h>
  20. #include <linux/if_ether.h>
  21. #include <linux/if_vlan.h>
  22. #include <linux/ip.h>
  23. #include <linux/in.h>
  24. #include <linux/ipv6.h>
  25. #include <linux/log2.h>
  26. #include <linux/jiffies.h>
  27. #include <linux/crc32.h>
  28. #include <linux/list.h>
  29. #include <linux/slab.h>
  30. #include <linux/io.h>
  31. #include <linux/of.h>
  32. #include "niu.h"
  33. /* This driver wants to store a link to a "next page" within the
  34. * page struct itself by overloading the content of the "mapping"
  35. * member. This is not expected by the page API, but does currently
  36. * work. However, the randstruct plugin gets very bothered by this
  37. * case because "mapping" (struct address_space) is randomized, so
  38. * casts to/from it trigger warnings. Hide this by way of a union,
  39. * to create a typed alias of "mapping", since that's how it is
  40. * actually being used here.
  41. */
  42. union niu_page {
  43. struct page page;
  44. struct {
  45. unsigned long __flags; /* unused alias of "flags" */
  46. struct list_head __lru; /* unused alias of "lru" */
  47. struct page *next; /* alias of "mapping" */
  48. };
  49. };
  50. #define niu_next_page(p) container_of(p, union niu_page, page)->next
  51. #define DRV_MODULE_NAME "niu"
  52. #define DRV_MODULE_VERSION "1.1"
  53. #define DRV_MODULE_RELDATE "Apr 22, 2010"
  54. static char version[] =
  55. DRV_MODULE_NAME ".c:v" DRV_MODULE_VERSION " (" DRV_MODULE_RELDATE ")\n";
  56. MODULE_AUTHOR("David S. Miller <davem@davemloft.net>");
  57. MODULE_DESCRIPTION("NIU ethernet driver");
  58. MODULE_LICENSE("GPL");
  59. MODULE_VERSION(DRV_MODULE_VERSION);
  60. #ifndef readq
  61. static u64 readq(void __iomem *reg)
  62. {
  63. return ((u64) readl(reg)) | (((u64) readl(reg + 4UL)) << 32);
  64. }
  65. static void writeq(u64 val, void __iomem *reg)
  66. {
  67. writel(val & 0xffffffff, reg);
  68. writel(val >> 32, reg + 0x4UL);
  69. }
  70. #endif
  71. static const struct pci_device_id niu_pci_tbl[] = {
  72. {PCI_DEVICE(PCI_VENDOR_ID_SUN, 0xabcd)},
  73. {}
  74. };
  75. MODULE_DEVICE_TABLE(pci, niu_pci_tbl);
  76. #define NIU_TX_TIMEOUT (5 * HZ)
  77. #define nr64(reg) readq(np->regs + (reg))
  78. #define nw64(reg, val) writeq((val), np->regs + (reg))
  79. #define nr64_mac(reg) readq(np->mac_regs + (reg))
  80. #define nw64_mac(reg, val) writeq((val), np->mac_regs + (reg))
  81. #define nr64_ipp(reg) readq(np->regs + np->ipp_off + (reg))
  82. #define nw64_ipp(reg, val) writeq((val), np->regs + np->ipp_off + (reg))
  83. #define nr64_pcs(reg) readq(np->regs + np->pcs_off + (reg))
  84. #define nw64_pcs(reg, val) writeq((val), np->regs + np->pcs_off + (reg))
  85. #define nr64_xpcs(reg) readq(np->regs + np->xpcs_off + (reg))
  86. #define nw64_xpcs(reg, val) writeq((val), np->regs + np->xpcs_off + (reg))
  87. #define NIU_MSG_DEFAULT (NETIF_MSG_DRV | NETIF_MSG_PROBE | NETIF_MSG_LINK)
  88. static int niu_debug;
  89. static int debug = -1;
  90. module_param(debug, int, 0);
  91. MODULE_PARM_DESC(debug, "NIU debug level");
  92. #define niu_lock_parent(np, flags) \
  93. spin_lock_irqsave(&np->parent->lock, flags)
  94. #define niu_unlock_parent(np, flags) \
  95. spin_unlock_irqrestore(&np->parent->lock, flags)
  96. static int serdes_init_10g_serdes(struct niu *np);
  97. static int __niu_wait_bits_clear_mac(struct niu *np, unsigned long reg,
  98. u64 bits, int limit, int delay)
  99. {
  100. while (--limit >= 0) {
  101. u64 val = nr64_mac(reg);
  102. if (!(val & bits))
  103. break;
  104. udelay(delay);
  105. }
  106. if (limit < 0)
  107. return -ENODEV;
  108. return 0;
  109. }
  110. static int __niu_set_and_wait_clear_mac(struct niu *np, unsigned long reg,
  111. u64 bits, int limit, int delay,
  112. const char *reg_name)
  113. {
  114. int err;
  115. nw64_mac(reg, bits);
  116. err = __niu_wait_bits_clear_mac(np, reg, bits, limit, delay);
  117. if (err)
  118. netdev_err(np->dev, "bits (%llx) of register %s would not clear, val[%llx]\n",
  119. (unsigned long long)bits, reg_name,
  120. (unsigned long long)nr64_mac(reg));
  121. return err;
  122. }
  123. #define niu_set_and_wait_clear_mac(NP, REG, BITS, LIMIT, DELAY, REG_NAME) \
  124. ({ BUILD_BUG_ON(LIMIT <= 0 || DELAY < 0); \
  125. __niu_set_and_wait_clear_mac(NP, REG, BITS, LIMIT, DELAY, REG_NAME); \
  126. })
  127. static int __niu_wait_bits_clear_ipp(struct niu *np, unsigned long reg,
  128. u64 bits, int limit, int delay)
  129. {
  130. while (--limit >= 0) {
  131. u64 val = nr64_ipp(reg);
  132. if (!(val & bits))
  133. break;
  134. udelay(delay);
  135. }
  136. if (limit < 0)
  137. return -ENODEV;
  138. return 0;
  139. }
  140. static int __niu_set_and_wait_clear_ipp(struct niu *np, unsigned long reg,
  141. u64 bits, int limit, int delay,
  142. const char *reg_name)
  143. {
  144. int err;
  145. u64 val;
  146. val = nr64_ipp(reg);
  147. val |= bits;
  148. nw64_ipp(reg, val);
  149. err = __niu_wait_bits_clear_ipp(np, reg, bits, limit, delay);
  150. if (err)
  151. netdev_err(np->dev, "bits (%llx) of register %s would not clear, val[%llx]\n",
  152. (unsigned long long)bits, reg_name,
  153. (unsigned long long)nr64_ipp(reg));
  154. return err;
  155. }
  156. #define niu_set_and_wait_clear_ipp(NP, REG, BITS, LIMIT, DELAY, REG_NAME) \
  157. ({ BUILD_BUG_ON(LIMIT <= 0 || DELAY < 0); \
  158. __niu_set_and_wait_clear_ipp(NP, REG, BITS, LIMIT, DELAY, REG_NAME); \
  159. })
  160. static int __niu_wait_bits_clear(struct niu *np, unsigned long reg,
  161. u64 bits, int limit, int delay)
  162. {
  163. while (--limit >= 0) {
  164. u64 val = nr64(reg);
  165. if (!(val & bits))
  166. break;
  167. udelay(delay);
  168. }
  169. if (limit < 0)
  170. return -ENODEV;
  171. return 0;
  172. }
  173. #define niu_wait_bits_clear(NP, REG, BITS, LIMIT, DELAY) \
  174. ({ BUILD_BUG_ON(LIMIT <= 0 || DELAY < 0); \
  175. __niu_wait_bits_clear(NP, REG, BITS, LIMIT, DELAY); \
  176. })
  177. static int __niu_set_and_wait_clear(struct niu *np, unsigned long reg,
  178. u64 bits, int limit, int delay,
  179. const char *reg_name)
  180. {
  181. int err;
  182. nw64(reg, bits);
  183. err = __niu_wait_bits_clear(np, reg, bits, limit, delay);
  184. if (err)
  185. netdev_err(np->dev, "bits (%llx) of register %s would not clear, val[%llx]\n",
  186. (unsigned long long)bits, reg_name,
  187. (unsigned long long)nr64(reg));
  188. return err;
  189. }
  190. #define niu_set_and_wait_clear(NP, REG, BITS, LIMIT, DELAY, REG_NAME) \
  191. ({ BUILD_BUG_ON(LIMIT <= 0 || DELAY < 0); \
  192. __niu_set_and_wait_clear(NP, REG, BITS, LIMIT, DELAY, REG_NAME); \
  193. })
  194. static void niu_ldg_rearm(struct niu *np, struct niu_ldg *lp, int on)
  195. {
  196. u64 val = (u64) lp->timer;
  197. if (on)
  198. val |= LDG_IMGMT_ARM;
  199. nw64(LDG_IMGMT(lp->ldg_num), val);
  200. }
  201. static int niu_ldn_irq_enable(struct niu *np, int ldn, int on)
  202. {
  203. unsigned long mask_reg, bits;
  204. u64 val;
  205. if (ldn < 0 || ldn > LDN_MAX)
  206. return -EINVAL;
  207. if (ldn < 64) {
  208. mask_reg = LD_IM0(ldn);
  209. bits = LD_IM0_MASK;
  210. } else {
  211. mask_reg = LD_IM1(ldn - 64);
  212. bits = LD_IM1_MASK;
  213. }
  214. val = nr64(mask_reg);
  215. if (on)
  216. val &= ~bits;
  217. else
  218. val |= bits;
  219. nw64(mask_reg, val);
  220. return 0;
  221. }
  222. static int niu_enable_ldn_in_ldg(struct niu *np, struct niu_ldg *lp, int on)
  223. {
  224. struct niu_parent *parent = np->parent;
  225. int i;
  226. for (i = 0; i <= LDN_MAX; i++) {
  227. int err;
  228. if (parent->ldg_map[i] != lp->ldg_num)
  229. continue;
  230. err = niu_ldn_irq_enable(np, i, on);
  231. if (err)
  232. return err;
  233. }
  234. return 0;
  235. }
  236. static int niu_enable_interrupts(struct niu *np, int on)
  237. {
  238. int i;
  239. for (i = 0; i < np->num_ldg; i++) {
  240. struct niu_ldg *lp = &np->ldg[i];
  241. int err;
  242. err = niu_enable_ldn_in_ldg(np, lp, on);
  243. if (err)
  244. return err;
  245. }
  246. for (i = 0; i < np->num_ldg; i++)
  247. niu_ldg_rearm(np, &np->ldg[i], on);
  248. return 0;
  249. }
  250. static u32 phy_encode(u32 type, int port)
  251. {
  252. return type << (port * 2);
  253. }
  254. static u32 phy_decode(u32 val, int port)
  255. {
  256. return (val >> (port * 2)) & PORT_TYPE_MASK;
  257. }
  258. static int mdio_wait(struct niu *np)
  259. {
  260. int limit = 1000;
  261. u64 val;
  262. while (--limit > 0) {
  263. val = nr64(MIF_FRAME_OUTPUT);
  264. if ((val >> MIF_FRAME_OUTPUT_TA_SHIFT) & 0x1)
  265. return val & MIF_FRAME_OUTPUT_DATA;
  266. udelay(10);
  267. }
  268. return -ENODEV;
  269. }
  270. static int mdio_read(struct niu *np, int port, int dev, int reg)
  271. {
  272. int err;
  273. nw64(MIF_FRAME_OUTPUT, MDIO_ADDR_OP(port, dev, reg));
  274. err = mdio_wait(np);
  275. if (err < 0)
  276. return err;
  277. nw64(MIF_FRAME_OUTPUT, MDIO_READ_OP(port, dev));
  278. return mdio_wait(np);
  279. }
  280. static int mdio_write(struct niu *np, int port, int dev, int reg, int data)
  281. {
  282. int err;
  283. nw64(MIF_FRAME_OUTPUT, MDIO_ADDR_OP(port, dev, reg));
  284. err = mdio_wait(np);
  285. if (err < 0)
  286. return err;
  287. nw64(MIF_FRAME_OUTPUT, MDIO_WRITE_OP(port, dev, data));
  288. err = mdio_wait(np);
  289. if (err < 0)
  290. return err;
  291. return 0;
  292. }
  293. static int mii_read(struct niu *np, int port, int reg)
  294. {
  295. nw64(MIF_FRAME_OUTPUT, MII_READ_OP(port, reg));
  296. return mdio_wait(np);
  297. }
  298. static int mii_write(struct niu *np, int port, int reg, int data)
  299. {
  300. int err;
  301. nw64(MIF_FRAME_OUTPUT, MII_WRITE_OP(port, reg, data));
  302. err = mdio_wait(np);
  303. if (err < 0)
  304. return err;
  305. return 0;
  306. }
  307. static int esr2_set_tx_cfg(struct niu *np, unsigned long channel, u32 val)
  308. {
  309. int err;
  310. err = mdio_write(np, np->port, NIU_ESR2_DEV_ADDR,
  311. ESR2_TI_PLL_TX_CFG_L(channel),
  312. val & 0xffff);
  313. if (!err)
  314. err = mdio_write(np, np->port, NIU_ESR2_DEV_ADDR,
  315. ESR2_TI_PLL_TX_CFG_H(channel),
  316. val >> 16);
  317. return err;
  318. }
  319. static int esr2_set_rx_cfg(struct niu *np, unsigned long channel, u32 val)
  320. {
  321. int err;
  322. err = mdio_write(np, np->port, NIU_ESR2_DEV_ADDR,
  323. ESR2_TI_PLL_RX_CFG_L(channel),
  324. val & 0xffff);
  325. if (!err)
  326. err = mdio_write(np, np->port, NIU_ESR2_DEV_ADDR,
  327. ESR2_TI_PLL_RX_CFG_H(channel),
  328. val >> 16);
  329. return err;
  330. }
  331. /* Mode is always 10G fiber. */
  332. static int serdes_init_niu_10g_fiber(struct niu *np)
  333. {
  334. struct niu_link_config *lp = &np->link_config;
  335. u32 tx_cfg, rx_cfg;
  336. unsigned long i;
  337. tx_cfg = (PLL_TX_CFG_ENTX | PLL_TX_CFG_SWING_1375MV);
  338. rx_cfg = (PLL_RX_CFG_ENRX | PLL_RX_CFG_TERM_0P8VDDT |
  339. PLL_RX_CFG_ALIGN_ENA | PLL_RX_CFG_LOS_LTHRESH |
  340. PLL_RX_CFG_EQ_LP_ADAPTIVE);
  341. if (lp->loopback_mode == LOOPBACK_PHY) {
  342. u16 test_cfg = PLL_TEST_CFG_LOOPBACK_CML_DIS;
  343. mdio_write(np, np->port, NIU_ESR2_DEV_ADDR,
  344. ESR2_TI_PLL_TEST_CFG_L, test_cfg);
  345. tx_cfg |= PLL_TX_CFG_ENTEST;
  346. rx_cfg |= PLL_RX_CFG_ENTEST;
  347. }
  348. /* Initialize all 4 lanes of the SERDES. */
  349. for (i = 0; i < 4; i++) {
  350. int err = esr2_set_tx_cfg(np, i, tx_cfg);
  351. if (err)
  352. return err;
  353. }
  354. for (i = 0; i < 4; i++) {
  355. int err = esr2_set_rx_cfg(np, i, rx_cfg);
  356. if (err)
  357. return err;
  358. }
  359. return 0;
  360. }
  361. static int serdes_init_niu_1g_serdes(struct niu *np)
  362. {
  363. struct niu_link_config *lp = &np->link_config;
  364. u16 pll_cfg, pll_sts;
  365. int max_retry = 100;
  366. u64 sig, mask, val;
  367. u32 tx_cfg, rx_cfg;
  368. unsigned long i;
  369. int err;
  370. tx_cfg = (PLL_TX_CFG_ENTX | PLL_TX_CFG_SWING_1375MV |
  371. PLL_TX_CFG_RATE_HALF);
  372. rx_cfg = (PLL_RX_CFG_ENRX | PLL_RX_CFG_TERM_0P8VDDT |
  373. PLL_RX_CFG_ALIGN_ENA | PLL_RX_CFG_LOS_LTHRESH |
  374. PLL_RX_CFG_RATE_HALF);
  375. if (np->port == 0)
  376. rx_cfg |= PLL_RX_CFG_EQ_LP_ADAPTIVE;
  377. if (lp->loopback_mode == LOOPBACK_PHY) {
  378. u16 test_cfg = PLL_TEST_CFG_LOOPBACK_CML_DIS;
  379. mdio_write(np, np->port, NIU_ESR2_DEV_ADDR,
  380. ESR2_TI_PLL_TEST_CFG_L, test_cfg);
  381. tx_cfg |= PLL_TX_CFG_ENTEST;
  382. rx_cfg |= PLL_RX_CFG_ENTEST;
  383. }
  384. /* Initialize PLL for 1G */
  385. pll_cfg = (PLL_CFG_ENPLL | PLL_CFG_MPY_8X);
  386. err = mdio_write(np, np->port, NIU_ESR2_DEV_ADDR,
  387. ESR2_TI_PLL_CFG_L, pll_cfg);
  388. if (err) {
  389. netdev_err(np->dev, "NIU Port %d %s() mdio write to ESR2_TI_PLL_CFG_L failed\n",
  390. np->port, __func__);
  391. return err;
  392. }
  393. pll_sts = PLL_CFG_ENPLL;
  394. err = mdio_write(np, np->port, NIU_ESR2_DEV_ADDR,
  395. ESR2_TI_PLL_STS_L, pll_sts);
  396. if (err) {
  397. netdev_err(np->dev, "NIU Port %d %s() mdio write to ESR2_TI_PLL_STS_L failed\n",
  398. np->port, __func__);
  399. return err;
  400. }
  401. udelay(200);
  402. /* Initialize all 4 lanes of the SERDES. */
  403. for (i = 0; i < 4; i++) {
  404. err = esr2_set_tx_cfg(np, i, tx_cfg);
  405. if (err)
  406. return err;
  407. }
  408. for (i = 0; i < 4; i++) {
  409. err = esr2_set_rx_cfg(np, i, rx_cfg);
  410. if (err)
  411. return err;
  412. }
  413. switch (np->port) {
  414. case 0:
  415. val = (ESR_INT_SRDY0_P0 | ESR_INT_DET0_P0);
  416. mask = val;
  417. break;
  418. case 1:
  419. val = (ESR_INT_SRDY0_P1 | ESR_INT_DET0_P1);
  420. mask = val;
  421. break;
  422. default:
  423. return -EINVAL;
  424. }
  425. while (max_retry--) {
  426. sig = nr64(ESR_INT_SIGNALS);
  427. if ((sig & mask) == val)
  428. break;
  429. mdelay(500);
  430. }
  431. if ((sig & mask) != val) {
  432. netdev_err(np->dev, "Port %u signal bits [%08x] are not [%08x]\n",
  433. np->port, (int)(sig & mask), (int)val);
  434. return -ENODEV;
  435. }
  436. return 0;
  437. }
  438. static int serdes_init_niu_10g_serdes(struct niu *np)
  439. {
  440. struct niu_link_config *lp = &np->link_config;
  441. u32 tx_cfg, rx_cfg, pll_cfg, pll_sts;
  442. int max_retry = 100;
  443. u64 sig, mask, val;
  444. unsigned long i;
  445. int err;
  446. tx_cfg = (PLL_TX_CFG_ENTX | PLL_TX_CFG_SWING_1375MV);
  447. rx_cfg = (PLL_RX_CFG_ENRX | PLL_RX_CFG_TERM_0P8VDDT |
  448. PLL_RX_CFG_ALIGN_ENA | PLL_RX_CFG_LOS_LTHRESH |
  449. PLL_RX_CFG_EQ_LP_ADAPTIVE);
  450. if (lp->loopback_mode == LOOPBACK_PHY) {
  451. u16 test_cfg = PLL_TEST_CFG_LOOPBACK_CML_DIS;
  452. mdio_write(np, np->port, NIU_ESR2_DEV_ADDR,
  453. ESR2_TI_PLL_TEST_CFG_L, test_cfg);
  454. tx_cfg |= PLL_TX_CFG_ENTEST;
  455. rx_cfg |= PLL_RX_CFG_ENTEST;
  456. }
  457. /* Initialize PLL for 10G */
  458. pll_cfg = (PLL_CFG_ENPLL | PLL_CFG_MPY_10X);
  459. err = mdio_write(np, np->port, NIU_ESR2_DEV_ADDR,
  460. ESR2_TI_PLL_CFG_L, pll_cfg & 0xffff);
  461. if (err) {
  462. netdev_err(np->dev, "NIU Port %d %s() mdio write to ESR2_TI_PLL_CFG_L failed\n",
  463. np->port, __func__);
  464. return err;
  465. }
  466. pll_sts = PLL_CFG_ENPLL;
  467. err = mdio_write(np, np->port, NIU_ESR2_DEV_ADDR,
  468. ESR2_TI_PLL_STS_L, pll_sts & 0xffff);
  469. if (err) {
  470. netdev_err(np->dev, "NIU Port %d %s() mdio write to ESR2_TI_PLL_STS_L failed\n",
  471. np->port, __func__);
  472. return err;
  473. }
  474. udelay(200);
  475. /* Initialize all 4 lanes of the SERDES. */
  476. for (i = 0; i < 4; i++) {
  477. err = esr2_set_tx_cfg(np, i, tx_cfg);
  478. if (err)
  479. return err;
  480. }
  481. for (i = 0; i < 4; i++) {
  482. err = esr2_set_rx_cfg(np, i, rx_cfg);
  483. if (err)
  484. return err;
  485. }
  486. /* check if serdes is ready */
  487. switch (np->port) {
  488. case 0:
  489. mask = ESR_INT_SIGNALS_P0_BITS;
  490. val = (ESR_INT_SRDY0_P0 |
  491. ESR_INT_DET0_P0 |
  492. ESR_INT_XSRDY_P0 |
  493. ESR_INT_XDP_P0_CH3 |
  494. ESR_INT_XDP_P0_CH2 |
  495. ESR_INT_XDP_P0_CH1 |
  496. ESR_INT_XDP_P0_CH0);
  497. break;
  498. case 1:
  499. mask = ESR_INT_SIGNALS_P1_BITS;
  500. val = (ESR_INT_SRDY0_P1 |
  501. ESR_INT_DET0_P1 |
  502. ESR_INT_XSRDY_P1 |
  503. ESR_INT_XDP_P1_CH3 |
  504. ESR_INT_XDP_P1_CH2 |
  505. ESR_INT_XDP_P1_CH1 |
  506. ESR_INT_XDP_P1_CH0);
  507. break;
  508. default:
  509. return -EINVAL;
  510. }
  511. while (max_retry--) {
  512. sig = nr64(ESR_INT_SIGNALS);
  513. if ((sig & mask) == val)
  514. break;
  515. mdelay(500);
  516. }
  517. if ((sig & mask) != val) {
  518. pr_info("NIU Port %u signal bits [%08x] are not [%08x] for 10G...trying 1G\n",
  519. np->port, (int)(sig & mask), (int)val);
  520. /* 10G failed, try initializing at 1G */
  521. err = serdes_init_niu_1g_serdes(np);
  522. if (!err) {
  523. np->flags &= ~NIU_FLAGS_10G;
  524. np->mac_xcvr = MAC_XCVR_PCS;
  525. } else {
  526. netdev_err(np->dev, "Port %u 10G/1G SERDES Link Failed\n",
  527. np->port);
  528. return -ENODEV;
  529. }
  530. }
  531. return 0;
  532. }
  533. static int esr_read_rxtx_ctrl(struct niu *np, unsigned long chan, u32 *val)
  534. {
  535. int err;
  536. err = mdio_read(np, np->port, NIU_ESR_DEV_ADDR, ESR_RXTX_CTRL_L(chan));
  537. if (err >= 0) {
  538. *val = (err & 0xffff);
  539. err = mdio_read(np, np->port, NIU_ESR_DEV_ADDR,
  540. ESR_RXTX_CTRL_H(chan));
  541. if (err >= 0)
  542. *val |= ((err & 0xffff) << 16);
  543. err = 0;
  544. }
  545. return err;
  546. }
  547. static int esr_read_glue0(struct niu *np, unsigned long chan, u32 *val)
  548. {
  549. int err;
  550. err = mdio_read(np, np->port, NIU_ESR_DEV_ADDR,
  551. ESR_GLUE_CTRL0_L(chan));
  552. if (err >= 0) {
  553. *val = (err & 0xffff);
  554. err = mdio_read(np, np->port, NIU_ESR_DEV_ADDR,
  555. ESR_GLUE_CTRL0_H(chan));
  556. if (err >= 0) {
  557. *val |= ((err & 0xffff) << 16);
  558. err = 0;
  559. }
  560. }
  561. return err;
  562. }
  563. static int esr_read_reset(struct niu *np, u32 *val)
  564. {
  565. int err;
  566. err = mdio_read(np, np->port, NIU_ESR_DEV_ADDR,
  567. ESR_RXTX_RESET_CTRL_L);
  568. if (err >= 0) {
  569. *val = (err & 0xffff);
  570. err = mdio_read(np, np->port, NIU_ESR_DEV_ADDR,
  571. ESR_RXTX_RESET_CTRL_H);
  572. if (err >= 0) {
  573. *val |= ((err & 0xffff) << 16);
  574. err = 0;
  575. }
  576. }
  577. return err;
  578. }
  579. static int esr_write_rxtx_ctrl(struct niu *np, unsigned long chan, u32 val)
  580. {
  581. int err;
  582. err = mdio_write(np, np->port, NIU_ESR_DEV_ADDR,
  583. ESR_RXTX_CTRL_L(chan), val & 0xffff);
  584. if (!err)
  585. err = mdio_write(np, np->port, NIU_ESR_DEV_ADDR,
  586. ESR_RXTX_CTRL_H(chan), (val >> 16));
  587. return err;
  588. }
  589. static int esr_write_glue0(struct niu *np, unsigned long chan, u32 val)
  590. {
  591. int err;
  592. err = mdio_write(np, np->port, NIU_ESR_DEV_ADDR,
  593. ESR_GLUE_CTRL0_L(chan), val & 0xffff);
  594. if (!err)
  595. err = mdio_write(np, np->port, NIU_ESR_DEV_ADDR,
  596. ESR_GLUE_CTRL0_H(chan), (val >> 16));
  597. return err;
  598. }
  599. static int esr_reset(struct niu *np)
  600. {
  601. u32 reset;
  602. int err;
  603. err = mdio_write(np, np->port, NIU_ESR_DEV_ADDR,
  604. ESR_RXTX_RESET_CTRL_L, 0x0000);
  605. if (err)
  606. return err;
  607. err = mdio_write(np, np->port, NIU_ESR_DEV_ADDR,
  608. ESR_RXTX_RESET_CTRL_H, 0xffff);
  609. if (err)
  610. return err;
  611. udelay(200);
  612. err = mdio_write(np, np->port, NIU_ESR_DEV_ADDR,
  613. ESR_RXTX_RESET_CTRL_L, 0xffff);
  614. if (err)
  615. return err;
  616. udelay(200);
  617. err = mdio_write(np, np->port, NIU_ESR_DEV_ADDR,
  618. ESR_RXTX_RESET_CTRL_H, 0x0000);
  619. if (err)
  620. return err;
  621. udelay(200);
  622. err = esr_read_reset(np, &reset);
  623. if (err)
  624. return err;
  625. if (reset != 0) {
  626. netdev_err(np->dev, "Port %u ESR_RESET did not clear [%08x]\n",
  627. np->port, reset);
  628. return -ENODEV;
  629. }
  630. return 0;
  631. }
  632. static int serdes_init_10g(struct niu *np)
  633. {
  634. struct niu_link_config *lp = &np->link_config;
  635. unsigned long ctrl_reg, test_cfg_reg, i;
  636. u64 ctrl_val, test_cfg_val, sig, mask, val;
  637. int err;
  638. switch (np->port) {
  639. case 0:
  640. ctrl_reg = ENET_SERDES_0_CTRL_CFG;
  641. test_cfg_reg = ENET_SERDES_0_TEST_CFG;
  642. break;
  643. case 1:
  644. ctrl_reg = ENET_SERDES_1_CTRL_CFG;
  645. test_cfg_reg = ENET_SERDES_1_TEST_CFG;
  646. break;
  647. default:
  648. return -EINVAL;
  649. }
  650. ctrl_val = (ENET_SERDES_CTRL_SDET_0 |
  651. ENET_SERDES_CTRL_SDET_1 |
  652. ENET_SERDES_CTRL_SDET_2 |
  653. ENET_SERDES_CTRL_SDET_3 |
  654. (0x5 << ENET_SERDES_CTRL_EMPH_0_SHIFT) |
  655. (0x5 << ENET_SERDES_CTRL_EMPH_1_SHIFT) |
  656. (0x5 << ENET_SERDES_CTRL_EMPH_2_SHIFT) |
  657. (0x5 << ENET_SERDES_CTRL_EMPH_3_SHIFT) |
  658. (0x1 << ENET_SERDES_CTRL_LADJ_0_SHIFT) |
  659. (0x1 << ENET_SERDES_CTRL_LADJ_1_SHIFT) |
  660. (0x1 << ENET_SERDES_CTRL_LADJ_2_SHIFT) |
  661. (0x1 << ENET_SERDES_CTRL_LADJ_3_SHIFT));
  662. test_cfg_val = 0;
  663. if (lp->loopback_mode == LOOPBACK_PHY) {
  664. test_cfg_val |= ((ENET_TEST_MD_PAD_LOOPBACK <<
  665. ENET_SERDES_TEST_MD_0_SHIFT) |
  666. (ENET_TEST_MD_PAD_LOOPBACK <<
  667. ENET_SERDES_TEST_MD_1_SHIFT) |
  668. (ENET_TEST_MD_PAD_LOOPBACK <<
  669. ENET_SERDES_TEST_MD_2_SHIFT) |
  670. (ENET_TEST_MD_PAD_LOOPBACK <<
  671. ENET_SERDES_TEST_MD_3_SHIFT));
  672. }
  673. nw64(ctrl_reg, ctrl_val);
  674. nw64(test_cfg_reg, test_cfg_val);
  675. /* Initialize all 4 lanes of the SERDES. */
  676. for (i = 0; i < 4; i++) {
  677. u32 rxtx_ctrl, glue0;
  678. err = esr_read_rxtx_ctrl(np, i, &rxtx_ctrl);
  679. if (err)
  680. return err;
  681. err = esr_read_glue0(np, i, &glue0);
  682. if (err)
  683. return err;
  684. rxtx_ctrl &= ~(ESR_RXTX_CTRL_VMUXLO);
  685. rxtx_ctrl |= (ESR_RXTX_CTRL_ENSTRETCH |
  686. (2 << ESR_RXTX_CTRL_VMUXLO_SHIFT));
  687. glue0 &= ~(ESR_GLUE_CTRL0_SRATE |
  688. ESR_GLUE_CTRL0_THCNT |
  689. ESR_GLUE_CTRL0_BLTIME);
  690. glue0 |= (ESR_GLUE_CTRL0_RXLOSENAB |
  691. (0xf << ESR_GLUE_CTRL0_SRATE_SHIFT) |
  692. (0xff << ESR_GLUE_CTRL0_THCNT_SHIFT) |
  693. (BLTIME_300_CYCLES <<
  694. ESR_GLUE_CTRL0_BLTIME_SHIFT));
  695. err = esr_write_rxtx_ctrl(np, i, rxtx_ctrl);
  696. if (err)
  697. return err;
  698. err = esr_write_glue0(np, i, glue0);
  699. if (err)
  700. return err;
  701. }
  702. err = esr_reset(np);
  703. if (err)
  704. return err;
  705. sig = nr64(ESR_INT_SIGNALS);
  706. switch (np->port) {
  707. case 0:
  708. mask = ESR_INT_SIGNALS_P0_BITS;
  709. val = (ESR_INT_SRDY0_P0 |
  710. ESR_INT_DET0_P0 |
  711. ESR_INT_XSRDY_P0 |
  712. ESR_INT_XDP_P0_CH3 |
  713. ESR_INT_XDP_P0_CH2 |
  714. ESR_INT_XDP_P0_CH1 |
  715. ESR_INT_XDP_P0_CH0);
  716. break;
  717. case 1:
  718. mask = ESR_INT_SIGNALS_P1_BITS;
  719. val = (ESR_INT_SRDY0_P1 |
  720. ESR_INT_DET0_P1 |
  721. ESR_INT_XSRDY_P1 |
  722. ESR_INT_XDP_P1_CH3 |
  723. ESR_INT_XDP_P1_CH2 |
  724. ESR_INT_XDP_P1_CH1 |
  725. ESR_INT_XDP_P1_CH0);
  726. break;
  727. default:
  728. return -EINVAL;
  729. }
  730. if ((sig & mask) != val) {
  731. if (np->flags & NIU_FLAGS_HOTPLUG_PHY) {
  732. np->flags &= ~NIU_FLAGS_HOTPLUG_PHY_PRESENT;
  733. return 0;
  734. }
  735. netdev_err(np->dev, "Port %u signal bits [%08x] are not [%08x]\n",
  736. np->port, (int)(sig & mask), (int)val);
  737. return -ENODEV;
  738. }
  739. if (np->flags & NIU_FLAGS_HOTPLUG_PHY)
  740. np->flags |= NIU_FLAGS_HOTPLUG_PHY_PRESENT;
  741. return 0;
  742. }
  743. static int serdes_init_1g(struct niu *np)
  744. {
  745. u64 val;
  746. val = nr64(ENET_SERDES_1_PLL_CFG);
  747. val &= ~ENET_SERDES_PLL_FBDIV2;
  748. switch (np->port) {
  749. case 0:
  750. val |= ENET_SERDES_PLL_HRATE0;
  751. break;
  752. case 1:
  753. val |= ENET_SERDES_PLL_HRATE1;
  754. break;
  755. case 2:
  756. val |= ENET_SERDES_PLL_HRATE2;
  757. break;
  758. case 3:
  759. val |= ENET_SERDES_PLL_HRATE3;
  760. break;
  761. default:
  762. return -EINVAL;
  763. }
  764. nw64(ENET_SERDES_1_PLL_CFG, val);
  765. return 0;
  766. }
  767. static int serdes_init_1g_serdes(struct niu *np)
  768. {
  769. struct niu_link_config *lp = &np->link_config;
  770. unsigned long ctrl_reg, test_cfg_reg, pll_cfg, i;
  771. u64 ctrl_val, test_cfg_val, sig, mask, val;
  772. int err;
  773. u64 reset_val, val_rd;
  774. val = ENET_SERDES_PLL_HRATE0 | ENET_SERDES_PLL_HRATE1 |
  775. ENET_SERDES_PLL_HRATE2 | ENET_SERDES_PLL_HRATE3 |
  776. ENET_SERDES_PLL_FBDIV0;
  777. switch (np->port) {
  778. case 0:
  779. reset_val = ENET_SERDES_RESET_0;
  780. ctrl_reg = ENET_SERDES_0_CTRL_CFG;
  781. test_cfg_reg = ENET_SERDES_0_TEST_CFG;
  782. pll_cfg = ENET_SERDES_0_PLL_CFG;
  783. break;
  784. case 1:
  785. reset_val = ENET_SERDES_RESET_1;
  786. ctrl_reg = ENET_SERDES_1_CTRL_CFG;
  787. test_cfg_reg = ENET_SERDES_1_TEST_CFG;
  788. pll_cfg = ENET_SERDES_1_PLL_CFG;
  789. break;
  790. default:
  791. return -EINVAL;
  792. }
  793. ctrl_val = (ENET_SERDES_CTRL_SDET_0 |
  794. ENET_SERDES_CTRL_SDET_1 |
  795. ENET_SERDES_CTRL_SDET_2 |
  796. ENET_SERDES_CTRL_SDET_3 |
  797. (0x5 << ENET_SERDES_CTRL_EMPH_0_SHIFT) |
  798. (0x5 << ENET_SERDES_CTRL_EMPH_1_SHIFT) |
  799. (0x5 << ENET_SERDES_CTRL_EMPH_2_SHIFT) |
  800. (0x5 << ENET_SERDES_CTRL_EMPH_3_SHIFT) |
  801. (0x1 << ENET_SERDES_CTRL_LADJ_0_SHIFT) |
  802. (0x1 << ENET_SERDES_CTRL_LADJ_1_SHIFT) |
  803. (0x1 << ENET_SERDES_CTRL_LADJ_2_SHIFT) |
  804. (0x1 << ENET_SERDES_CTRL_LADJ_3_SHIFT));
  805. test_cfg_val = 0;
  806. if (lp->loopback_mode == LOOPBACK_PHY) {
  807. test_cfg_val |= ((ENET_TEST_MD_PAD_LOOPBACK <<
  808. ENET_SERDES_TEST_MD_0_SHIFT) |
  809. (ENET_TEST_MD_PAD_LOOPBACK <<
  810. ENET_SERDES_TEST_MD_1_SHIFT) |
  811. (ENET_TEST_MD_PAD_LOOPBACK <<
  812. ENET_SERDES_TEST_MD_2_SHIFT) |
  813. (ENET_TEST_MD_PAD_LOOPBACK <<
  814. ENET_SERDES_TEST_MD_3_SHIFT));
  815. }
  816. nw64(ENET_SERDES_RESET, reset_val);
  817. mdelay(20);
  818. val_rd = nr64(ENET_SERDES_RESET);
  819. val_rd &= ~reset_val;
  820. nw64(pll_cfg, val);
  821. nw64(ctrl_reg, ctrl_val);
  822. nw64(test_cfg_reg, test_cfg_val);
  823. nw64(ENET_SERDES_RESET, val_rd);
  824. mdelay(2000);
  825. /* Initialize all 4 lanes of the SERDES. */
  826. for (i = 0; i < 4; i++) {
  827. u32 rxtx_ctrl, glue0;
  828. err = esr_read_rxtx_ctrl(np, i, &rxtx_ctrl);
  829. if (err)
  830. return err;
  831. err = esr_read_glue0(np, i, &glue0);
  832. if (err)
  833. return err;
  834. rxtx_ctrl &= ~(ESR_RXTX_CTRL_VMUXLO);
  835. rxtx_ctrl |= (ESR_RXTX_CTRL_ENSTRETCH |
  836. (2 << ESR_RXTX_CTRL_VMUXLO_SHIFT));
  837. glue0 &= ~(ESR_GLUE_CTRL0_SRATE |
  838. ESR_GLUE_CTRL0_THCNT |
  839. ESR_GLUE_CTRL0_BLTIME);
  840. glue0 |= (ESR_GLUE_CTRL0_RXLOSENAB |
  841. (0xf << ESR_GLUE_CTRL0_SRATE_SHIFT) |
  842. (0xff << ESR_GLUE_CTRL0_THCNT_SHIFT) |
  843. (BLTIME_300_CYCLES <<
  844. ESR_GLUE_CTRL0_BLTIME_SHIFT));
  845. err = esr_write_rxtx_ctrl(np, i, rxtx_ctrl);
  846. if (err)
  847. return err;
  848. err = esr_write_glue0(np, i, glue0);
  849. if (err)
  850. return err;
  851. }
  852. sig = nr64(ESR_INT_SIGNALS);
  853. switch (np->port) {
  854. case 0:
  855. val = (ESR_INT_SRDY0_P0 | ESR_INT_DET0_P0);
  856. mask = val;
  857. break;
  858. case 1:
  859. val = (ESR_INT_SRDY0_P1 | ESR_INT_DET0_P1);
  860. mask = val;
  861. break;
  862. default:
  863. return -EINVAL;
  864. }
  865. if ((sig & mask) != val) {
  866. netdev_err(np->dev, "Port %u signal bits [%08x] are not [%08x]\n",
  867. np->port, (int)(sig & mask), (int)val);
  868. return -ENODEV;
  869. }
  870. return 0;
  871. }
  872. static int link_status_1g_serdes(struct niu *np, int *link_up_p)
  873. {
  874. struct niu_link_config *lp = &np->link_config;
  875. int link_up;
  876. u64 val;
  877. u16 current_speed;
  878. unsigned long flags;
  879. u8 current_duplex;
  880. link_up = 0;
  881. current_speed = SPEED_INVALID;
  882. current_duplex = DUPLEX_INVALID;
  883. spin_lock_irqsave(&np->lock, flags);
  884. val = nr64_pcs(PCS_MII_STAT);
  885. if (val & PCS_MII_STAT_LINK_STATUS) {
  886. link_up = 1;
  887. current_speed = SPEED_1000;
  888. current_duplex = DUPLEX_FULL;
  889. }
  890. lp->active_speed = current_speed;
  891. lp->active_duplex = current_duplex;
  892. spin_unlock_irqrestore(&np->lock, flags);
  893. *link_up_p = link_up;
  894. return 0;
  895. }
  896. static int link_status_10g_serdes(struct niu *np, int *link_up_p)
  897. {
  898. unsigned long flags;
  899. struct niu_link_config *lp = &np->link_config;
  900. int link_up = 0;
  901. int link_ok = 1;
  902. u64 val, val2;
  903. u16 current_speed;
  904. u8 current_duplex;
  905. if (!(np->flags & NIU_FLAGS_10G))
  906. return link_status_1g_serdes(np, link_up_p);
  907. current_speed = SPEED_INVALID;
  908. current_duplex = DUPLEX_INVALID;
  909. spin_lock_irqsave(&np->lock, flags);
  910. val = nr64_xpcs(XPCS_STATUS(0));
  911. val2 = nr64_mac(XMAC_INTER2);
  912. if (val2 & 0x01000000)
  913. link_ok = 0;
  914. if ((val & 0x1000ULL) && link_ok) {
  915. link_up = 1;
  916. current_speed = SPEED_10000;
  917. current_duplex = DUPLEX_FULL;
  918. }
  919. lp->active_speed = current_speed;
  920. lp->active_duplex = current_duplex;
  921. spin_unlock_irqrestore(&np->lock, flags);
  922. *link_up_p = link_up;
  923. return 0;
  924. }
  925. static int link_status_mii(struct niu *np, int *link_up_p)
  926. {
  927. struct niu_link_config *lp = &np->link_config;
  928. int err;
  929. int bmsr, advert, ctrl1000, stat1000, lpa, bmcr, estatus;
  930. int supported, advertising, active_speed, active_duplex;
  931. err = mii_read(np, np->phy_addr, MII_BMCR);
  932. if (unlikely(err < 0))
  933. return err;
  934. bmcr = err;
  935. err = mii_read(np, np->phy_addr, MII_BMSR);
  936. if (unlikely(err < 0))
  937. return err;
  938. bmsr = err;
  939. err = mii_read(np, np->phy_addr, MII_ADVERTISE);
  940. if (unlikely(err < 0))
  941. return err;
  942. advert = err;
  943. err = mii_read(np, np->phy_addr, MII_LPA);
  944. if (unlikely(err < 0))
  945. return err;
  946. lpa = err;
  947. if (likely(bmsr & BMSR_ESTATEN)) {
  948. err = mii_read(np, np->phy_addr, MII_ESTATUS);
  949. if (unlikely(err < 0))
  950. return err;
  951. estatus = err;
  952. err = mii_read(np, np->phy_addr, MII_CTRL1000);
  953. if (unlikely(err < 0))
  954. return err;
  955. ctrl1000 = err;
  956. err = mii_read(np, np->phy_addr, MII_STAT1000);
  957. if (unlikely(err < 0))
  958. return err;
  959. stat1000 = err;
  960. } else
  961. estatus = ctrl1000 = stat1000 = 0;
  962. supported = 0;
  963. if (bmsr & BMSR_ANEGCAPABLE)
  964. supported |= SUPPORTED_Autoneg;
  965. if (bmsr & BMSR_10HALF)
  966. supported |= SUPPORTED_10baseT_Half;
  967. if (bmsr & BMSR_10FULL)
  968. supported |= SUPPORTED_10baseT_Full;
  969. if (bmsr & BMSR_100HALF)
  970. supported |= SUPPORTED_100baseT_Half;
  971. if (bmsr & BMSR_100FULL)
  972. supported |= SUPPORTED_100baseT_Full;
  973. if (estatus & ESTATUS_1000_THALF)
  974. supported |= SUPPORTED_1000baseT_Half;
  975. if (estatus & ESTATUS_1000_TFULL)
  976. supported |= SUPPORTED_1000baseT_Full;
  977. lp->supported = supported;
  978. advertising = mii_adv_to_ethtool_adv_t(advert);
  979. advertising |= mii_ctrl1000_to_ethtool_adv_t(ctrl1000);
  980. if (bmcr & BMCR_ANENABLE) {
  981. int neg, neg1000;
  982. lp->active_autoneg = 1;
  983. advertising |= ADVERTISED_Autoneg;
  984. neg = advert & lpa;
  985. neg1000 = (ctrl1000 << 2) & stat1000;
  986. if (neg1000 & (LPA_1000FULL | LPA_1000HALF))
  987. active_speed = SPEED_1000;
  988. else if (neg & LPA_100)
  989. active_speed = SPEED_100;
  990. else if (neg & (LPA_10HALF | LPA_10FULL))
  991. active_speed = SPEED_10;
  992. else
  993. active_speed = SPEED_INVALID;
  994. if ((neg1000 & LPA_1000FULL) || (neg & LPA_DUPLEX))
  995. active_duplex = DUPLEX_FULL;
  996. else if (active_speed != SPEED_INVALID)
  997. active_duplex = DUPLEX_HALF;
  998. else
  999. active_duplex = DUPLEX_INVALID;
  1000. } else {
  1001. lp->active_autoneg = 0;
  1002. if ((bmcr & BMCR_SPEED1000) && !(bmcr & BMCR_SPEED100))
  1003. active_speed = SPEED_1000;
  1004. else if (bmcr & BMCR_SPEED100)
  1005. active_speed = SPEED_100;
  1006. else
  1007. active_speed = SPEED_10;
  1008. if (bmcr & BMCR_FULLDPLX)
  1009. active_duplex = DUPLEX_FULL;
  1010. else
  1011. active_duplex = DUPLEX_HALF;
  1012. }
  1013. lp->active_advertising = advertising;
  1014. lp->active_speed = active_speed;
  1015. lp->active_duplex = active_duplex;
  1016. *link_up_p = !!(bmsr & BMSR_LSTATUS);
  1017. return 0;
  1018. }
  1019. static int link_status_1g_rgmii(struct niu *np, int *link_up_p)
  1020. {
  1021. struct niu_link_config *lp = &np->link_config;
  1022. u16 current_speed, bmsr;
  1023. unsigned long flags;
  1024. u8 current_duplex;
  1025. int err, link_up;
  1026. link_up = 0;
  1027. current_speed = SPEED_INVALID;
  1028. current_duplex = DUPLEX_INVALID;
  1029. spin_lock_irqsave(&np->lock, flags);
  1030. err = mii_read(np, np->phy_addr, MII_BMSR);
  1031. if (err < 0)
  1032. goto out;
  1033. bmsr = err;
  1034. if (bmsr & BMSR_LSTATUS) {
  1035. link_up = 1;
  1036. current_speed = SPEED_1000;
  1037. current_duplex = DUPLEX_FULL;
  1038. }
  1039. lp->active_speed = current_speed;
  1040. lp->active_duplex = current_duplex;
  1041. err = 0;
  1042. out:
  1043. spin_unlock_irqrestore(&np->lock, flags);
  1044. *link_up_p = link_up;
  1045. return err;
  1046. }
  1047. static int link_status_1g(struct niu *np, int *link_up_p)
  1048. {
  1049. struct niu_link_config *lp = &np->link_config;
  1050. unsigned long flags;
  1051. int err;
  1052. spin_lock_irqsave(&np->lock, flags);
  1053. err = link_status_mii(np, link_up_p);
  1054. lp->supported |= SUPPORTED_TP;
  1055. lp->active_advertising |= ADVERTISED_TP;
  1056. spin_unlock_irqrestore(&np->lock, flags);
  1057. return err;
  1058. }
  1059. static int bcm8704_reset(struct niu *np)
  1060. {
  1061. int err, limit;
  1062. err = mdio_read(np, np->phy_addr,
  1063. BCM8704_PHYXS_DEV_ADDR, MII_BMCR);
  1064. if (err < 0 || err == 0xffff)
  1065. return err;
  1066. err |= BMCR_RESET;
  1067. err = mdio_write(np, np->phy_addr, BCM8704_PHYXS_DEV_ADDR,
  1068. MII_BMCR, err);
  1069. if (err)
  1070. return err;
  1071. limit = 1000;
  1072. while (--limit >= 0) {
  1073. err = mdio_read(np, np->phy_addr,
  1074. BCM8704_PHYXS_DEV_ADDR, MII_BMCR);
  1075. if (err < 0)
  1076. return err;
  1077. if (!(err & BMCR_RESET))
  1078. break;
  1079. }
  1080. if (limit < 0) {
  1081. netdev_err(np->dev, "Port %u PHY will not reset (bmcr=%04x)\n",
  1082. np->port, (err & 0xffff));
  1083. return -ENODEV;
  1084. }
  1085. return 0;
  1086. }
  1087. /* When written, certain PHY registers need to be read back twice
  1088. * in order for the bits to settle properly.
  1089. */
  1090. static int bcm8704_user_dev3_readback(struct niu *np, int reg)
  1091. {
  1092. int err = mdio_read(np, np->phy_addr, BCM8704_USER_DEV3_ADDR, reg);
  1093. if (err < 0)
  1094. return err;
  1095. err = mdio_read(np, np->phy_addr, BCM8704_USER_DEV3_ADDR, reg);
  1096. if (err < 0)
  1097. return err;
  1098. return 0;
  1099. }
  1100. static int bcm8706_init_user_dev3(struct niu *np)
  1101. {
  1102. int err;
  1103. err = mdio_read(np, np->phy_addr, BCM8704_USER_DEV3_ADDR,
  1104. BCM8704_USER_OPT_DIGITAL_CTRL);
  1105. if (err < 0)
  1106. return err;
  1107. err &= ~USER_ODIG_CTRL_GPIOS;
  1108. err |= (0x3 << USER_ODIG_CTRL_GPIOS_SHIFT);
  1109. err |= USER_ODIG_CTRL_RESV2;
  1110. err = mdio_write(np, np->phy_addr, BCM8704_USER_DEV3_ADDR,
  1111. BCM8704_USER_OPT_DIGITAL_CTRL, err);
  1112. if (err)
  1113. return err;
  1114. mdelay(1000);
  1115. return 0;
  1116. }
  1117. static int bcm8704_init_user_dev3(struct niu *np)
  1118. {
  1119. int err;
  1120. err = mdio_write(np, np->phy_addr,
  1121. BCM8704_USER_DEV3_ADDR, BCM8704_USER_CONTROL,
  1122. (USER_CONTROL_OPTXRST_LVL |
  1123. USER_CONTROL_OPBIASFLT_LVL |
  1124. USER_CONTROL_OBTMPFLT_LVL |
  1125. USER_CONTROL_OPPRFLT_LVL |
  1126. USER_CONTROL_OPTXFLT_LVL |
  1127. USER_CONTROL_OPRXLOS_LVL |
  1128. USER_CONTROL_OPRXFLT_LVL |
  1129. USER_CONTROL_OPTXON_LVL |
  1130. (0x3f << USER_CONTROL_RES1_SHIFT)));
  1131. if (err)
  1132. return err;
  1133. err = mdio_write(np, np->phy_addr,
  1134. BCM8704_USER_DEV3_ADDR, BCM8704_USER_PMD_TX_CONTROL,
  1135. (USER_PMD_TX_CTL_XFP_CLKEN |
  1136. (1 << USER_PMD_TX_CTL_TX_DAC_TXD_SH) |
  1137. (2 << USER_PMD_TX_CTL_TX_DAC_TXCK_SH) |
  1138. USER_PMD_TX_CTL_TSCK_LPWREN));
  1139. if (err)
  1140. return err;
  1141. err = bcm8704_user_dev3_readback(np, BCM8704_USER_CONTROL);
  1142. if (err)
  1143. return err;
  1144. err = bcm8704_user_dev3_readback(np, BCM8704_USER_PMD_TX_CONTROL);
  1145. if (err)
  1146. return err;
  1147. err = mdio_read(np, np->phy_addr, BCM8704_USER_DEV3_ADDR,
  1148. BCM8704_USER_OPT_DIGITAL_CTRL);
  1149. if (err < 0)
  1150. return err;
  1151. err &= ~USER_ODIG_CTRL_GPIOS;
  1152. err |= (0x3 << USER_ODIG_CTRL_GPIOS_SHIFT);
  1153. err = mdio_write(np, np->phy_addr, BCM8704_USER_DEV3_ADDR,
  1154. BCM8704_USER_OPT_DIGITAL_CTRL, err);
  1155. if (err)
  1156. return err;
  1157. mdelay(1000);
  1158. return 0;
  1159. }
  1160. static int mrvl88x2011_act_led(struct niu *np, int val)
  1161. {
  1162. int err;
  1163. err = mdio_read(np, np->phy_addr, MRVL88X2011_USER_DEV2_ADDR,
  1164. MRVL88X2011_LED_8_TO_11_CTL);
  1165. if (err < 0)
  1166. return err;
  1167. err &= ~MRVL88X2011_LED(MRVL88X2011_LED_ACT,MRVL88X2011_LED_CTL_MASK);
  1168. err |= MRVL88X2011_LED(MRVL88X2011_LED_ACT,val);
  1169. return mdio_write(np, np->phy_addr, MRVL88X2011_USER_DEV2_ADDR,
  1170. MRVL88X2011_LED_8_TO_11_CTL, err);
  1171. }
  1172. static int mrvl88x2011_led_blink_rate(struct niu *np, int rate)
  1173. {
  1174. int err;
  1175. err = mdio_read(np, np->phy_addr, MRVL88X2011_USER_DEV2_ADDR,
  1176. MRVL88X2011_LED_BLINK_CTL);
  1177. if (err >= 0) {
  1178. err &= ~MRVL88X2011_LED_BLKRATE_MASK;
  1179. err |= (rate << 4);
  1180. err = mdio_write(np, np->phy_addr, MRVL88X2011_USER_DEV2_ADDR,
  1181. MRVL88X2011_LED_BLINK_CTL, err);
  1182. }
  1183. return err;
  1184. }
  1185. static int xcvr_init_10g_mrvl88x2011(struct niu *np)
  1186. {
  1187. int err;
  1188. /* Set LED functions */
  1189. err = mrvl88x2011_led_blink_rate(np, MRVL88X2011_LED_BLKRATE_134MS);
  1190. if (err)
  1191. return err;
  1192. /* led activity */
  1193. err = mrvl88x2011_act_led(np, MRVL88X2011_LED_CTL_OFF);
  1194. if (err)
  1195. return err;
  1196. err = mdio_read(np, np->phy_addr, MRVL88X2011_USER_DEV3_ADDR,
  1197. MRVL88X2011_GENERAL_CTL);
  1198. if (err < 0)
  1199. return err;
  1200. err |= MRVL88X2011_ENA_XFPREFCLK;
  1201. err = mdio_write(np, np->phy_addr, MRVL88X2011_USER_DEV3_ADDR,
  1202. MRVL88X2011_GENERAL_CTL, err);
  1203. if (err < 0)
  1204. return err;
  1205. err = mdio_read(np, np->phy_addr, MRVL88X2011_USER_DEV1_ADDR,
  1206. MRVL88X2011_PMA_PMD_CTL_1);
  1207. if (err < 0)
  1208. return err;
  1209. if (np->link_config.loopback_mode == LOOPBACK_MAC)
  1210. err |= MRVL88X2011_LOOPBACK;
  1211. else
  1212. err &= ~MRVL88X2011_LOOPBACK;
  1213. err = mdio_write(np, np->phy_addr, MRVL88X2011_USER_DEV1_ADDR,
  1214. MRVL88X2011_PMA_PMD_CTL_1, err);
  1215. if (err < 0)
  1216. return err;
  1217. /* Enable PMD */
  1218. return mdio_write(np, np->phy_addr, MRVL88X2011_USER_DEV1_ADDR,
  1219. MRVL88X2011_10G_PMD_TX_DIS, MRVL88X2011_ENA_PMDTX);
  1220. }
  1221. static int xcvr_diag_bcm870x(struct niu *np)
  1222. {
  1223. u16 analog_stat0, tx_alarm_status;
  1224. int err = 0;
  1225. #if 1
  1226. err = mdio_read(np, np->phy_addr, BCM8704_PMA_PMD_DEV_ADDR,
  1227. MII_STAT1000);
  1228. if (err < 0)
  1229. return err;
  1230. pr_info("Port %u PMA_PMD(MII_STAT1000) [%04x]\n", np->port, err);
  1231. err = mdio_read(np, np->phy_addr, BCM8704_USER_DEV3_ADDR, 0x20);
  1232. if (err < 0)
  1233. return err;
  1234. pr_info("Port %u USER_DEV3(0x20) [%04x]\n", np->port, err);
  1235. err = mdio_read(np, np->phy_addr, BCM8704_PHYXS_DEV_ADDR,
  1236. MII_NWAYTEST);
  1237. if (err < 0)
  1238. return err;
  1239. pr_info("Port %u PHYXS(MII_NWAYTEST) [%04x]\n", np->port, err);
  1240. #endif
  1241. /* XXX dig this out it might not be so useful XXX */
  1242. err = mdio_read(np, np->phy_addr, BCM8704_USER_DEV3_ADDR,
  1243. BCM8704_USER_ANALOG_STATUS0);
  1244. if (err < 0)
  1245. return err;
  1246. err = mdio_read(np, np->phy_addr, BCM8704_USER_DEV3_ADDR,
  1247. BCM8704_USER_ANALOG_STATUS0);
  1248. if (err < 0)
  1249. return err;
  1250. analog_stat0 = err;
  1251. err = mdio_read(np, np->phy_addr, BCM8704_USER_DEV3_ADDR,
  1252. BCM8704_USER_TX_ALARM_STATUS);
  1253. if (err < 0)
  1254. return err;
  1255. err = mdio_read(np, np->phy_addr, BCM8704_USER_DEV3_ADDR,
  1256. BCM8704_USER_TX_ALARM_STATUS);
  1257. if (err < 0)
  1258. return err;
  1259. tx_alarm_status = err;
  1260. if (analog_stat0 != 0x03fc) {
  1261. if ((analog_stat0 == 0x43bc) && (tx_alarm_status != 0)) {
  1262. pr_info("Port %u cable not connected or bad cable\n",
  1263. np->port);
  1264. } else if (analog_stat0 == 0x639c) {
  1265. pr_info("Port %u optical module is bad or missing\n",
  1266. np->port);
  1267. }
  1268. }
  1269. return 0;
  1270. }
  1271. static int xcvr_10g_set_lb_bcm870x(struct niu *np)
  1272. {
  1273. struct niu_link_config *lp = &np->link_config;
  1274. int err;
  1275. err = mdio_read(np, np->phy_addr, BCM8704_PCS_DEV_ADDR,
  1276. MII_BMCR);
  1277. if (err < 0)
  1278. return err;
  1279. err &= ~BMCR_LOOPBACK;
  1280. if (lp->loopback_mode == LOOPBACK_MAC)
  1281. err |= BMCR_LOOPBACK;
  1282. err = mdio_write(np, np->phy_addr, BCM8704_PCS_DEV_ADDR,
  1283. MII_BMCR, err);
  1284. if (err)
  1285. return err;
  1286. return 0;
  1287. }
  1288. static int xcvr_init_10g_bcm8706(struct niu *np)
  1289. {
  1290. int err = 0;
  1291. u64 val;
  1292. if ((np->flags & NIU_FLAGS_HOTPLUG_PHY) &&
  1293. (np->flags & NIU_FLAGS_HOTPLUG_PHY_PRESENT) == 0)
  1294. return err;
  1295. val = nr64_mac(XMAC_CONFIG);
  1296. val &= ~XMAC_CONFIG_LED_POLARITY;
  1297. val |= XMAC_CONFIG_FORCE_LED_ON;
  1298. nw64_mac(XMAC_CONFIG, val);
  1299. val = nr64(MIF_CONFIG);
  1300. val |= MIF_CONFIG_INDIRECT_MODE;
  1301. nw64(MIF_CONFIG, val);
  1302. err = bcm8704_reset(np);
  1303. if (err)
  1304. return err;
  1305. err = xcvr_10g_set_lb_bcm870x(np);
  1306. if (err)
  1307. return err;
  1308. err = bcm8706_init_user_dev3(np);
  1309. if (err)
  1310. return err;
  1311. err = xcvr_diag_bcm870x(np);
  1312. if (err)
  1313. return err;
  1314. return 0;
  1315. }
  1316. static int xcvr_init_10g_bcm8704(struct niu *np)
  1317. {
  1318. int err;
  1319. err = bcm8704_reset(np);
  1320. if (err)
  1321. return err;
  1322. err = bcm8704_init_user_dev3(np);
  1323. if (err)
  1324. return err;
  1325. err = xcvr_10g_set_lb_bcm870x(np);
  1326. if (err)
  1327. return err;
  1328. err = xcvr_diag_bcm870x(np);
  1329. if (err)
  1330. return err;
  1331. return 0;
  1332. }
  1333. static int xcvr_init_10g(struct niu *np)
  1334. {
  1335. int phy_id, err;
  1336. u64 val;
  1337. val = nr64_mac(XMAC_CONFIG);
  1338. val &= ~XMAC_CONFIG_LED_POLARITY;
  1339. val |= XMAC_CONFIG_FORCE_LED_ON;
  1340. nw64_mac(XMAC_CONFIG, val);
  1341. /* XXX shared resource, lock parent XXX */
  1342. val = nr64(MIF_CONFIG);
  1343. val |= MIF_CONFIG_INDIRECT_MODE;
  1344. nw64(MIF_CONFIG, val);
  1345. phy_id = phy_decode(np->parent->port_phy, np->port);
  1346. phy_id = np->parent->phy_probe_info.phy_id[phy_id][np->port];
  1347. /* handle different phy types */
  1348. switch (phy_id & NIU_PHY_ID_MASK) {
  1349. case NIU_PHY_ID_MRVL88X2011:
  1350. err = xcvr_init_10g_mrvl88x2011(np);
  1351. break;
  1352. default: /* bcom 8704 */
  1353. err = xcvr_init_10g_bcm8704(np);
  1354. break;
  1355. }
  1356. return err;
  1357. }
  1358. static int mii_reset(struct niu *np)
  1359. {
  1360. int limit, err;
  1361. err = mii_write(np, np->phy_addr, MII_BMCR, BMCR_RESET);
  1362. if (err)
  1363. return err;
  1364. limit = 1000;
  1365. while (--limit >= 0) {
  1366. udelay(500);
  1367. err = mii_read(np, np->phy_addr, MII_BMCR);
  1368. if (err < 0)
  1369. return err;
  1370. if (!(err & BMCR_RESET))
  1371. break;
  1372. }
  1373. if (limit < 0) {
  1374. netdev_err(np->dev, "Port %u MII would not reset, bmcr[%04x]\n",
  1375. np->port, err);
  1376. return -ENODEV;
  1377. }
  1378. return 0;
  1379. }
  1380. static int xcvr_init_1g_rgmii(struct niu *np)
  1381. {
  1382. int err;
  1383. u64 val;
  1384. u16 bmcr, bmsr, estat;
  1385. val = nr64(MIF_CONFIG);
  1386. val &= ~MIF_CONFIG_INDIRECT_MODE;
  1387. nw64(MIF_CONFIG, val);
  1388. err = mii_reset(np);
  1389. if (err)
  1390. return err;
  1391. err = mii_read(np, np->phy_addr, MII_BMSR);
  1392. if (err < 0)
  1393. return err;
  1394. bmsr = err;
  1395. estat = 0;
  1396. if (bmsr & BMSR_ESTATEN) {
  1397. err = mii_read(np, np->phy_addr, MII_ESTATUS);
  1398. if (err < 0)
  1399. return err;
  1400. estat = err;
  1401. }
  1402. bmcr = 0;
  1403. err = mii_write(np, np->phy_addr, MII_BMCR, bmcr);
  1404. if (err)
  1405. return err;
  1406. if (bmsr & BMSR_ESTATEN) {
  1407. u16 ctrl1000 = 0;
  1408. if (estat & ESTATUS_1000_TFULL)
  1409. ctrl1000 |= ADVERTISE_1000FULL;
  1410. err = mii_write(np, np->phy_addr, MII_CTRL1000, ctrl1000);
  1411. if (err)
  1412. return err;
  1413. }
  1414. bmcr = (BMCR_SPEED1000 | BMCR_FULLDPLX);
  1415. err = mii_write(np, np->phy_addr, MII_BMCR, bmcr);
  1416. if (err)
  1417. return err;
  1418. err = mii_read(np, np->phy_addr, MII_BMCR);
  1419. if (err < 0)
  1420. return err;
  1421. bmcr = mii_read(np, np->phy_addr, MII_BMCR);
  1422. err = mii_read(np, np->phy_addr, MII_BMSR);
  1423. if (err < 0)
  1424. return err;
  1425. return 0;
  1426. }
  1427. static int mii_init_common(struct niu *np)
  1428. {
  1429. struct niu_link_config *lp = &np->link_config;
  1430. u16 bmcr, bmsr, adv, estat;
  1431. int err;
  1432. err = mii_reset(np);
  1433. if (err)
  1434. return err;
  1435. err = mii_read(np, np->phy_addr, MII_BMSR);
  1436. if (err < 0)
  1437. return err;
  1438. bmsr = err;
  1439. estat = 0;
  1440. if (bmsr & BMSR_ESTATEN) {
  1441. err = mii_read(np, np->phy_addr, MII_ESTATUS);
  1442. if (err < 0)
  1443. return err;
  1444. estat = err;
  1445. }
  1446. bmcr = 0;
  1447. err = mii_write(np, np->phy_addr, MII_BMCR, bmcr);
  1448. if (err)
  1449. return err;
  1450. if (lp->loopback_mode == LOOPBACK_MAC) {
  1451. bmcr |= BMCR_LOOPBACK;
  1452. if (lp->active_speed == SPEED_1000)
  1453. bmcr |= BMCR_SPEED1000;
  1454. if (lp->active_duplex == DUPLEX_FULL)
  1455. bmcr |= BMCR_FULLDPLX;
  1456. }
  1457. if (lp->loopback_mode == LOOPBACK_PHY) {
  1458. u16 aux;
  1459. aux = (BCM5464R_AUX_CTL_EXT_LB |
  1460. BCM5464R_AUX_CTL_WRITE_1);
  1461. err = mii_write(np, np->phy_addr, BCM5464R_AUX_CTL, aux);
  1462. if (err)
  1463. return err;
  1464. }
  1465. if (lp->autoneg) {
  1466. u16 ctrl1000;
  1467. adv = ADVERTISE_CSMA | ADVERTISE_PAUSE_CAP;
  1468. if ((bmsr & BMSR_10HALF) &&
  1469. (lp->advertising & ADVERTISED_10baseT_Half))
  1470. adv |= ADVERTISE_10HALF;
  1471. if ((bmsr & BMSR_10FULL) &&
  1472. (lp->advertising & ADVERTISED_10baseT_Full))
  1473. adv |= ADVERTISE_10FULL;
  1474. if ((bmsr & BMSR_100HALF) &&
  1475. (lp->advertising & ADVERTISED_100baseT_Half))
  1476. adv |= ADVERTISE_100HALF;
  1477. if ((bmsr & BMSR_100FULL) &&
  1478. (lp->advertising & ADVERTISED_100baseT_Full))
  1479. adv |= ADVERTISE_100FULL;
  1480. err = mii_write(np, np->phy_addr, MII_ADVERTISE, adv);
  1481. if (err)
  1482. return err;
  1483. if (likely(bmsr & BMSR_ESTATEN)) {
  1484. ctrl1000 = 0;
  1485. if ((estat & ESTATUS_1000_THALF) &&
  1486. (lp->advertising & ADVERTISED_1000baseT_Half))
  1487. ctrl1000 |= ADVERTISE_1000HALF;
  1488. if ((estat & ESTATUS_1000_TFULL) &&
  1489. (lp->advertising & ADVERTISED_1000baseT_Full))
  1490. ctrl1000 |= ADVERTISE_1000FULL;
  1491. err = mii_write(np, np->phy_addr,
  1492. MII_CTRL1000, ctrl1000);
  1493. if (err)
  1494. return err;
  1495. }
  1496. bmcr |= (BMCR_ANENABLE | BMCR_ANRESTART);
  1497. } else {
  1498. /* !lp->autoneg */
  1499. int fulldpx;
  1500. if (lp->duplex == DUPLEX_FULL) {
  1501. bmcr |= BMCR_FULLDPLX;
  1502. fulldpx = 1;
  1503. } else if (lp->duplex == DUPLEX_HALF)
  1504. fulldpx = 0;
  1505. else
  1506. return -EINVAL;
  1507. if (lp->speed == SPEED_1000) {
  1508. /* if X-full requested while not supported, or
  1509. X-half requested while not supported... */
  1510. if ((fulldpx && !(estat & ESTATUS_1000_TFULL)) ||
  1511. (!fulldpx && !(estat & ESTATUS_1000_THALF)))
  1512. return -EINVAL;
  1513. bmcr |= BMCR_SPEED1000;
  1514. } else if (lp->speed == SPEED_100) {
  1515. if ((fulldpx && !(bmsr & BMSR_100FULL)) ||
  1516. (!fulldpx && !(bmsr & BMSR_100HALF)))
  1517. return -EINVAL;
  1518. bmcr |= BMCR_SPEED100;
  1519. } else if (lp->speed == SPEED_10) {
  1520. if ((fulldpx && !(bmsr & BMSR_10FULL)) ||
  1521. (!fulldpx && !(bmsr & BMSR_10HALF)))
  1522. return -EINVAL;
  1523. } else
  1524. return -EINVAL;
  1525. }
  1526. err = mii_write(np, np->phy_addr, MII_BMCR, bmcr);
  1527. if (err)
  1528. return err;
  1529. #if 0
  1530. err = mii_read(np, np->phy_addr, MII_BMCR);
  1531. if (err < 0)
  1532. return err;
  1533. bmcr = err;
  1534. err = mii_read(np, np->phy_addr, MII_BMSR);
  1535. if (err < 0)
  1536. return err;
  1537. bmsr = err;
  1538. pr_info("Port %u after MII init bmcr[%04x] bmsr[%04x]\n",
  1539. np->port, bmcr, bmsr);
  1540. #endif
  1541. return 0;
  1542. }
  1543. static int xcvr_init_1g(struct niu *np)
  1544. {
  1545. u64 val;
  1546. /* XXX shared resource, lock parent XXX */
  1547. val = nr64(MIF_CONFIG);
  1548. val &= ~MIF_CONFIG_INDIRECT_MODE;
  1549. nw64(MIF_CONFIG, val);
  1550. return mii_init_common(np);
  1551. }
  1552. static int niu_xcvr_init(struct niu *np)
  1553. {
  1554. const struct niu_phy_ops *ops = np->phy_ops;
  1555. int err;
  1556. err = 0;
  1557. if (ops->xcvr_init)
  1558. err = ops->xcvr_init(np);
  1559. return err;
  1560. }
  1561. static int niu_serdes_init(struct niu *np)
  1562. {
  1563. const struct niu_phy_ops *ops = np->phy_ops;
  1564. int err;
  1565. err = 0;
  1566. if (ops->serdes_init)
  1567. err = ops->serdes_init(np);
  1568. return err;
  1569. }
  1570. static void niu_init_xif(struct niu *);
  1571. static void niu_handle_led(struct niu *, int status);
  1572. static int niu_link_status_common(struct niu *np, int link_up)
  1573. {
  1574. struct niu_link_config *lp = &np->link_config;
  1575. struct net_device *dev = np->dev;
  1576. unsigned long flags;
  1577. if (!netif_carrier_ok(dev) && link_up) {
  1578. netif_info(np, link, dev, "Link is up at %s, %s duplex\n",
  1579. lp->active_speed == SPEED_10000 ? "10Gb/sec" :
  1580. lp->active_speed == SPEED_1000 ? "1Gb/sec" :
  1581. lp->active_speed == SPEED_100 ? "100Mbit/sec" :
  1582. "10Mbit/sec",
  1583. lp->active_duplex == DUPLEX_FULL ? "full" : "half");
  1584. spin_lock_irqsave(&np->lock, flags);
  1585. niu_init_xif(np);
  1586. niu_handle_led(np, 1);
  1587. spin_unlock_irqrestore(&np->lock, flags);
  1588. netif_carrier_on(dev);
  1589. } else if (netif_carrier_ok(dev) && !link_up) {
  1590. netif_warn(np, link, dev, "Link is down\n");
  1591. spin_lock_irqsave(&np->lock, flags);
  1592. niu_handle_led(np, 0);
  1593. spin_unlock_irqrestore(&np->lock, flags);
  1594. netif_carrier_off(dev);
  1595. }
  1596. return 0;
  1597. }
  1598. static int link_status_10g_mrvl(struct niu *np, int *link_up_p)
  1599. {
  1600. int err, link_up, pma_status, pcs_status;
  1601. link_up = 0;
  1602. err = mdio_read(np, np->phy_addr, MRVL88X2011_USER_DEV1_ADDR,
  1603. MRVL88X2011_10G_PMD_STATUS_2);
  1604. if (err < 0)
  1605. goto out;
  1606. /* Check PMA/PMD Register: 1.0001.2 == 1 */
  1607. err = mdio_read(np, np->phy_addr, MRVL88X2011_USER_DEV1_ADDR,
  1608. MRVL88X2011_PMA_PMD_STATUS_1);
  1609. if (err < 0)
  1610. goto out;
  1611. pma_status = ((err & MRVL88X2011_LNK_STATUS_OK) ? 1 : 0);
  1612. /* Check PMC Register : 3.0001.2 == 1: read twice */
  1613. err = mdio_read(np, np->phy_addr, MRVL88X2011_USER_DEV3_ADDR,
  1614. MRVL88X2011_PMA_PMD_STATUS_1);
  1615. if (err < 0)
  1616. goto out;
  1617. err = mdio_read(np, np->phy_addr, MRVL88X2011_USER_DEV3_ADDR,
  1618. MRVL88X2011_PMA_PMD_STATUS_1);
  1619. if (err < 0)
  1620. goto out;
  1621. pcs_status = ((err & MRVL88X2011_LNK_STATUS_OK) ? 1 : 0);
  1622. /* Check XGXS Register : 4.0018.[0-3,12] */
  1623. err = mdio_read(np, np->phy_addr, MRVL88X2011_USER_DEV4_ADDR,
  1624. MRVL88X2011_10G_XGXS_LANE_STAT);
  1625. if (err < 0)
  1626. goto out;
  1627. if (err == (PHYXS_XGXS_LANE_STAT_ALINGED | PHYXS_XGXS_LANE_STAT_LANE3 |
  1628. PHYXS_XGXS_LANE_STAT_LANE2 | PHYXS_XGXS_LANE_STAT_LANE1 |
  1629. PHYXS_XGXS_LANE_STAT_LANE0 | PHYXS_XGXS_LANE_STAT_MAGIC |
  1630. 0x800))
  1631. link_up = (pma_status && pcs_status) ? 1 : 0;
  1632. np->link_config.active_speed = SPEED_10000;
  1633. np->link_config.active_duplex = DUPLEX_FULL;
  1634. err = 0;
  1635. out:
  1636. mrvl88x2011_act_led(np, (link_up ?
  1637. MRVL88X2011_LED_CTL_PCS_ACT :
  1638. MRVL88X2011_LED_CTL_OFF));
  1639. *link_up_p = link_up;
  1640. return err;
  1641. }
  1642. static int link_status_10g_bcm8706(struct niu *np, int *link_up_p)
  1643. {
  1644. int err, link_up;
  1645. link_up = 0;
  1646. err = mdio_read(np, np->phy_addr, BCM8704_PMA_PMD_DEV_ADDR,
  1647. BCM8704_PMD_RCV_SIGDET);
  1648. if (err < 0 || err == 0xffff)
  1649. goto out;
  1650. if (!(err & PMD_RCV_SIGDET_GLOBAL)) {
  1651. err = 0;
  1652. goto out;
  1653. }
  1654. err = mdio_read(np, np->phy_addr, BCM8704_PCS_DEV_ADDR,
  1655. BCM8704_PCS_10G_R_STATUS);
  1656. if (err < 0)
  1657. goto out;
  1658. if (!(err & PCS_10G_R_STATUS_BLK_LOCK)) {
  1659. err = 0;
  1660. goto out;
  1661. }
  1662. err = mdio_read(np, np->phy_addr, BCM8704_PHYXS_DEV_ADDR,
  1663. BCM8704_PHYXS_XGXS_LANE_STAT);
  1664. if (err < 0)
  1665. goto out;
  1666. if (err != (PHYXS_XGXS_LANE_STAT_ALINGED |
  1667. PHYXS_XGXS_LANE_STAT_MAGIC |
  1668. PHYXS_XGXS_LANE_STAT_PATTEST |
  1669. PHYXS_XGXS_LANE_STAT_LANE3 |
  1670. PHYXS_XGXS_LANE_STAT_LANE2 |
  1671. PHYXS_XGXS_LANE_STAT_LANE1 |
  1672. PHYXS_XGXS_LANE_STAT_LANE0)) {
  1673. err = 0;
  1674. np->link_config.active_speed = SPEED_INVALID;
  1675. np->link_config.active_duplex = DUPLEX_INVALID;
  1676. goto out;
  1677. }
  1678. link_up = 1;
  1679. np->link_config.active_speed = SPEED_10000;
  1680. np->link_config.active_duplex = DUPLEX_FULL;
  1681. err = 0;
  1682. out:
  1683. *link_up_p = link_up;
  1684. return err;
  1685. }
  1686. static int link_status_10g_bcom(struct niu *np, int *link_up_p)
  1687. {
  1688. int err, link_up;
  1689. link_up = 0;
  1690. err = mdio_read(np, np->phy_addr, BCM8704_PMA_PMD_DEV_ADDR,
  1691. BCM8704_PMD_RCV_SIGDET);
  1692. if (err < 0)
  1693. goto out;
  1694. if (!(err & PMD_RCV_SIGDET_GLOBAL)) {
  1695. err = 0;
  1696. goto out;
  1697. }
  1698. err = mdio_read(np, np->phy_addr, BCM8704_PCS_DEV_ADDR,
  1699. BCM8704_PCS_10G_R_STATUS);
  1700. if (err < 0)
  1701. goto out;
  1702. if (!(err & PCS_10G_R_STATUS_BLK_LOCK)) {
  1703. err = 0;
  1704. goto out;
  1705. }
  1706. err = mdio_read(np, np->phy_addr, BCM8704_PHYXS_DEV_ADDR,
  1707. BCM8704_PHYXS_XGXS_LANE_STAT);
  1708. if (err < 0)
  1709. goto out;
  1710. if (err != (PHYXS_XGXS_LANE_STAT_ALINGED |
  1711. PHYXS_XGXS_LANE_STAT_MAGIC |
  1712. PHYXS_XGXS_LANE_STAT_LANE3 |
  1713. PHYXS_XGXS_LANE_STAT_LANE2 |
  1714. PHYXS_XGXS_LANE_STAT_LANE1 |
  1715. PHYXS_XGXS_LANE_STAT_LANE0)) {
  1716. err = 0;
  1717. goto out;
  1718. }
  1719. link_up = 1;
  1720. np->link_config.active_speed = SPEED_10000;
  1721. np->link_config.active_duplex = DUPLEX_FULL;
  1722. err = 0;
  1723. out:
  1724. *link_up_p = link_up;
  1725. return err;
  1726. }
  1727. static int link_status_10g(struct niu *np, int *link_up_p)
  1728. {
  1729. unsigned long flags;
  1730. int err = -EINVAL;
  1731. spin_lock_irqsave(&np->lock, flags);
  1732. if (np->link_config.loopback_mode == LOOPBACK_DISABLED) {
  1733. int phy_id;
  1734. phy_id = phy_decode(np->parent->port_phy, np->port);
  1735. phy_id = np->parent->phy_probe_info.phy_id[phy_id][np->port];
  1736. /* handle different phy types */
  1737. switch (phy_id & NIU_PHY_ID_MASK) {
  1738. case NIU_PHY_ID_MRVL88X2011:
  1739. err = link_status_10g_mrvl(np, link_up_p);
  1740. break;
  1741. default: /* bcom 8704 */
  1742. err = link_status_10g_bcom(np, link_up_p);
  1743. break;
  1744. }
  1745. }
  1746. spin_unlock_irqrestore(&np->lock, flags);
  1747. return err;
  1748. }
  1749. static int niu_10g_phy_present(struct niu *np)
  1750. {
  1751. u64 sig, mask, val;
  1752. sig = nr64(ESR_INT_SIGNALS);
  1753. switch (np->port) {
  1754. case 0:
  1755. mask = ESR_INT_SIGNALS_P0_BITS;
  1756. val = (ESR_INT_SRDY0_P0 |
  1757. ESR_INT_DET0_P0 |
  1758. ESR_INT_XSRDY_P0 |
  1759. ESR_INT_XDP_P0_CH3 |
  1760. ESR_INT_XDP_P0_CH2 |
  1761. ESR_INT_XDP_P0_CH1 |
  1762. ESR_INT_XDP_P0_CH0);
  1763. break;
  1764. case 1:
  1765. mask = ESR_INT_SIGNALS_P1_BITS;
  1766. val = (ESR_INT_SRDY0_P1 |
  1767. ESR_INT_DET0_P1 |
  1768. ESR_INT_XSRDY_P1 |
  1769. ESR_INT_XDP_P1_CH3 |
  1770. ESR_INT_XDP_P1_CH2 |
  1771. ESR_INT_XDP_P1_CH1 |
  1772. ESR_INT_XDP_P1_CH0);
  1773. break;
  1774. default:
  1775. return 0;
  1776. }
  1777. if ((sig & mask) != val)
  1778. return 0;
  1779. return 1;
  1780. }
  1781. static int link_status_10g_hotplug(struct niu *np, int *link_up_p)
  1782. {
  1783. unsigned long flags;
  1784. int err = 0;
  1785. int phy_present;
  1786. int phy_present_prev;
  1787. spin_lock_irqsave(&np->lock, flags);
  1788. if (np->link_config.loopback_mode == LOOPBACK_DISABLED) {
  1789. phy_present_prev = (np->flags & NIU_FLAGS_HOTPLUG_PHY_PRESENT) ?
  1790. 1 : 0;
  1791. phy_present = niu_10g_phy_present(np);
  1792. if (phy_present != phy_present_prev) {
  1793. /* state change */
  1794. if (phy_present) {
  1795. /* A NEM was just plugged in */
  1796. np->flags |= NIU_FLAGS_HOTPLUG_PHY_PRESENT;
  1797. if (np->phy_ops->xcvr_init)
  1798. err = np->phy_ops->xcvr_init(np);
  1799. if (err) {
  1800. err = mdio_read(np, np->phy_addr,
  1801. BCM8704_PHYXS_DEV_ADDR, MII_BMCR);
  1802. if (err == 0xffff) {
  1803. /* No mdio, back-to-back XAUI */
  1804. goto out;
  1805. }
  1806. /* debounce */
  1807. np->flags &= ~NIU_FLAGS_HOTPLUG_PHY_PRESENT;
  1808. }
  1809. } else {
  1810. np->flags &= ~NIU_FLAGS_HOTPLUG_PHY_PRESENT;
  1811. *link_up_p = 0;
  1812. netif_warn(np, link, np->dev,
  1813. "Hotplug PHY Removed\n");
  1814. }
  1815. }
  1816. out:
  1817. if (np->flags & NIU_FLAGS_HOTPLUG_PHY_PRESENT) {
  1818. err = link_status_10g_bcm8706(np, link_up_p);
  1819. if (err == 0xffff) {
  1820. /* No mdio, back-to-back XAUI: it is C10NEM */
  1821. *link_up_p = 1;
  1822. np->link_config.active_speed = SPEED_10000;
  1823. np->link_config.active_duplex = DUPLEX_FULL;
  1824. }
  1825. }
  1826. }
  1827. spin_unlock_irqrestore(&np->lock, flags);
  1828. return 0;
  1829. }
  1830. static int niu_link_status(struct niu *np, int *link_up_p)
  1831. {
  1832. const struct niu_phy_ops *ops = np->phy_ops;
  1833. int err;
  1834. err = 0;
  1835. if (ops->link_status)
  1836. err = ops->link_status(np, link_up_p);
  1837. return err;
  1838. }
  1839. static void niu_timer(struct timer_list *t)
  1840. {
  1841. struct niu *np = timer_container_of(np, t, timer);
  1842. unsigned long off;
  1843. int err, link_up;
  1844. err = niu_link_status(np, &link_up);
  1845. if (!err)
  1846. niu_link_status_common(np, link_up);
  1847. if (netif_carrier_ok(np->dev))
  1848. off = 5 * HZ;
  1849. else
  1850. off = 1 * HZ;
  1851. np->timer.expires = jiffies + off;
  1852. add_timer(&np->timer);
  1853. }
  1854. static const struct niu_phy_ops phy_ops_10g_serdes = {
  1855. .serdes_init = serdes_init_10g_serdes,
  1856. .link_status = link_status_10g_serdes,
  1857. };
  1858. static const struct niu_phy_ops phy_ops_10g_serdes_niu = {
  1859. .serdes_init = serdes_init_niu_10g_serdes,
  1860. .link_status = link_status_10g_serdes,
  1861. };
  1862. static const struct niu_phy_ops phy_ops_1g_serdes_niu = {
  1863. .serdes_init = serdes_init_niu_1g_serdes,
  1864. .link_status = link_status_1g_serdes,
  1865. };
  1866. static const struct niu_phy_ops phy_ops_1g_rgmii = {
  1867. .xcvr_init = xcvr_init_1g_rgmii,
  1868. .link_status = link_status_1g_rgmii,
  1869. };
  1870. static const struct niu_phy_ops phy_ops_10g_fiber_niu = {
  1871. .serdes_init = serdes_init_niu_10g_fiber,
  1872. .xcvr_init = xcvr_init_10g,
  1873. .link_status = link_status_10g,
  1874. };
  1875. static const struct niu_phy_ops phy_ops_10g_fiber = {
  1876. .serdes_init = serdes_init_10g,
  1877. .xcvr_init = xcvr_init_10g,
  1878. .link_status = link_status_10g,
  1879. };
  1880. static const struct niu_phy_ops phy_ops_10g_fiber_hotplug = {
  1881. .serdes_init = serdes_init_10g,
  1882. .xcvr_init = xcvr_init_10g_bcm8706,
  1883. .link_status = link_status_10g_hotplug,
  1884. };
  1885. static const struct niu_phy_ops phy_ops_niu_10g_hotplug = {
  1886. .serdes_init = serdes_init_niu_10g_fiber,
  1887. .xcvr_init = xcvr_init_10g_bcm8706,
  1888. .link_status = link_status_10g_hotplug,
  1889. };
  1890. static const struct niu_phy_ops phy_ops_10g_copper = {
  1891. .serdes_init = serdes_init_10g,
  1892. .link_status = link_status_10g, /* XXX */
  1893. };
  1894. static const struct niu_phy_ops phy_ops_1g_fiber = {
  1895. .serdes_init = serdes_init_1g,
  1896. .xcvr_init = xcvr_init_1g,
  1897. .link_status = link_status_1g,
  1898. };
  1899. static const struct niu_phy_ops phy_ops_1g_copper = {
  1900. .xcvr_init = xcvr_init_1g,
  1901. .link_status = link_status_1g,
  1902. };
  1903. struct niu_phy_template {
  1904. const struct niu_phy_ops *ops;
  1905. u32 phy_addr_base;
  1906. };
  1907. static const struct niu_phy_template phy_template_niu_10g_fiber = {
  1908. .ops = &phy_ops_10g_fiber_niu,
  1909. .phy_addr_base = 16,
  1910. };
  1911. static const struct niu_phy_template phy_template_niu_10g_serdes = {
  1912. .ops = &phy_ops_10g_serdes_niu,
  1913. .phy_addr_base = 0,
  1914. };
  1915. static const struct niu_phy_template phy_template_niu_1g_serdes = {
  1916. .ops = &phy_ops_1g_serdes_niu,
  1917. .phy_addr_base = 0,
  1918. };
  1919. static const struct niu_phy_template phy_template_10g_fiber = {
  1920. .ops = &phy_ops_10g_fiber,
  1921. .phy_addr_base = 8,
  1922. };
  1923. static const struct niu_phy_template phy_template_10g_fiber_hotplug = {
  1924. .ops = &phy_ops_10g_fiber_hotplug,
  1925. .phy_addr_base = 8,
  1926. };
  1927. static const struct niu_phy_template phy_template_niu_10g_hotplug = {
  1928. .ops = &phy_ops_niu_10g_hotplug,
  1929. .phy_addr_base = 8,
  1930. };
  1931. static const struct niu_phy_template phy_template_10g_copper = {
  1932. .ops = &phy_ops_10g_copper,
  1933. .phy_addr_base = 10,
  1934. };
  1935. static const struct niu_phy_template phy_template_1g_fiber = {
  1936. .ops = &phy_ops_1g_fiber,
  1937. .phy_addr_base = 0,
  1938. };
  1939. static const struct niu_phy_template phy_template_1g_copper = {
  1940. .ops = &phy_ops_1g_copper,
  1941. .phy_addr_base = 0,
  1942. };
  1943. static const struct niu_phy_template phy_template_1g_rgmii = {
  1944. .ops = &phy_ops_1g_rgmii,
  1945. .phy_addr_base = 0,
  1946. };
  1947. static const struct niu_phy_template phy_template_10g_serdes = {
  1948. .ops = &phy_ops_10g_serdes,
  1949. .phy_addr_base = 0,
  1950. };
  1951. static int niu_atca_port_num[4] = {
  1952. 0, 0, 11, 10
  1953. };
  1954. static int serdes_init_10g_serdes(struct niu *np)
  1955. {
  1956. struct niu_link_config *lp = &np->link_config;
  1957. unsigned long ctrl_reg, test_cfg_reg, pll_cfg, i;
  1958. u64 ctrl_val, test_cfg_val, sig, mask, val;
  1959. switch (np->port) {
  1960. case 0:
  1961. ctrl_reg = ENET_SERDES_0_CTRL_CFG;
  1962. test_cfg_reg = ENET_SERDES_0_TEST_CFG;
  1963. pll_cfg = ENET_SERDES_0_PLL_CFG;
  1964. break;
  1965. case 1:
  1966. ctrl_reg = ENET_SERDES_1_CTRL_CFG;
  1967. test_cfg_reg = ENET_SERDES_1_TEST_CFG;
  1968. pll_cfg = ENET_SERDES_1_PLL_CFG;
  1969. break;
  1970. default:
  1971. return -EINVAL;
  1972. }
  1973. ctrl_val = (ENET_SERDES_CTRL_SDET_0 |
  1974. ENET_SERDES_CTRL_SDET_1 |
  1975. ENET_SERDES_CTRL_SDET_2 |
  1976. ENET_SERDES_CTRL_SDET_3 |
  1977. (0x5 << ENET_SERDES_CTRL_EMPH_0_SHIFT) |
  1978. (0x5 << ENET_SERDES_CTRL_EMPH_1_SHIFT) |
  1979. (0x5 << ENET_SERDES_CTRL_EMPH_2_SHIFT) |
  1980. (0x5 << ENET_SERDES_CTRL_EMPH_3_SHIFT) |
  1981. (0x1 << ENET_SERDES_CTRL_LADJ_0_SHIFT) |
  1982. (0x1 << ENET_SERDES_CTRL_LADJ_1_SHIFT) |
  1983. (0x1 << ENET_SERDES_CTRL_LADJ_2_SHIFT) |
  1984. (0x1 << ENET_SERDES_CTRL_LADJ_3_SHIFT));
  1985. test_cfg_val = 0;
  1986. if (lp->loopback_mode == LOOPBACK_PHY) {
  1987. test_cfg_val |= ((ENET_TEST_MD_PAD_LOOPBACK <<
  1988. ENET_SERDES_TEST_MD_0_SHIFT) |
  1989. (ENET_TEST_MD_PAD_LOOPBACK <<
  1990. ENET_SERDES_TEST_MD_1_SHIFT) |
  1991. (ENET_TEST_MD_PAD_LOOPBACK <<
  1992. ENET_SERDES_TEST_MD_2_SHIFT) |
  1993. (ENET_TEST_MD_PAD_LOOPBACK <<
  1994. ENET_SERDES_TEST_MD_3_SHIFT));
  1995. }
  1996. esr_reset(np);
  1997. nw64(pll_cfg, ENET_SERDES_PLL_FBDIV2);
  1998. nw64(ctrl_reg, ctrl_val);
  1999. nw64(test_cfg_reg, test_cfg_val);
  2000. /* Initialize all 4 lanes of the SERDES. */
  2001. for (i = 0; i < 4; i++) {
  2002. u32 rxtx_ctrl, glue0;
  2003. int err;
  2004. err = esr_read_rxtx_ctrl(np, i, &rxtx_ctrl);
  2005. if (err)
  2006. return err;
  2007. err = esr_read_glue0(np, i, &glue0);
  2008. if (err)
  2009. return err;
  2010. rxtx_ctrl &= ~(ESR_RXTX_CTRL_VMUXLO);
  2011. rxtx_ctrl |= (ESR_RXTX_CTRL_ENSTRETCH |
  2012. (2 << ESR_RXTX_CTRL_VMUXLO_SHIFT));
  2013. glue0 &= ~(ESR_GLUE_CTRL0_SRATE |
  2014. ESR_GLUE_CTRL0_THCNT |
  2015. ESR_GLUE_CTRL0_BLTIME);
  2016. glue0 |= (ESR_GLUE_CTRL0_RXLOSENAB |
  2017. (0xf << ESR_GLUE_CTRL0_SRATE_SHIFT) |
  2018. (0xff << ESR_GLUE_CTRL0_THCNT_SHIFT) |
  2019. (BLTIME_300_CYCLES <<
  2020. ESR_GLUE_CTRL0_BLTIME_SHIFT));
  2021. err = esr_write_rxtx_ctrl(np, i, rxtx_ctrl);
  2022. if (err)
  2023. return err;
  2024. err = esr_write_glue0(np, i, glue0);
  2025. if (err)
  2026. return err;
  2027. }
  2028. sig = nr64(ESR_INT_SIGNALS);
  2029. switch (np->port) {
  2030. case 0:
  2031. mask = ESR_INT_SIGNALS_P0_BITS;
  2032. val = (ESR_INT_SRDY0_P0 |
  2033. ESR_INT_DET0_P0 |
  2034. ESR_INT_XSRDY_P0 |
  2035. ESR_INT_XDP_P0_CH3 |
  2036. ESR_INT_XDP_P0_CH2 |
  2037. ESR_INT_XDP_P0_CH1 |
  2038. ESR_INT_XDP_P0_CH0);
  2039. break;
  2040. case 1:
  2041. mask = ESR_INT_SIGNALS_P1_BITS;
  2042. val = (ESR_INT_SRDY0_P1 |
  2043. ESR_INT_DET0_P1 |
  2044. ESR_INT_XSRDY_P1 |
  2045. ESR_INT_XDP_P1_CH3 |
  2046. ESR_INT_XDP_P1_CH2 |
  2047. ESR_INT_XDP_P1_CH1 |
  2048. ESR_INT_XDP_P1_CH0);
  2049. break;
  2050. default:
  2051. return -EINVAL;
  2052. }
  2053. if ((sig & mask) != val) {
  2054. int err;
  2055. err = serdes_init_1g_serdes(np);
  2056. if (!err) {
  2057. np->flags &= ~NIU_FLAGS_10G;
  2058. np->mac_xcvr = MAC_XCVR_PCS;
  2059. } else {
  2060. netdev_err(np->dev, "Port %u 10G/1G SERDES Link Failed\n",
  2061. np->port);
  2062. return -ENODEV;
  2063. }
  2064. }
  2065. return 0;
  2066. }
  2067. static int niu_determine_phy_disposition(struct niu *np)
  2068. {
  2069. struct niu_parent *parent = np->parent;
  2070. u8 plat_type = parent->plat_type;
  2071. const struct niu_phy_template *tp;
  2072. u32 phy_addr_off = 0;
  2073. if (plat_type == PLAT_TYPE_NIU) {
  2074. switch (np->flags &
  2075. (NIU_FLAGS_10G |
  2076. NIU_FLAGS_FIBER |
  2077. NIU_FLAGS_XCVR_SERDES)) {
  2078. case NIU_FLAGS_10G | NIU_FLAGS_XCVR_SERDES:
  2079. /* 10G Serdes */
  2080. tp = &phy_template_niu_10g_serdes;
  2081. break;
  2082. case NIU_FLAGS_XCVR_SERDES:
  2083. /* 1G Serdes */
  2084. tp = &phy_template_niu_1g_serdes;
  2085. break;
  2086. case NIU_FLAGS_10G | NIU_FLAGS_FIBER:
  2087. /* 10G Fiber */
  2088. default:
  2089. if (np->flags & NIU_FLAGS_HOTPLUG_PHY) {
  2090. tp = &phy_template_niu_10g_hotplug;
  2091. if (np->port == 0)
  2092. phy_addr_off = 8;
  2093. if (np->port == 1)
  2094. phy_addr_off = 12;
  2095. } else {
  2096. tp = &phy_template_niu_10g_fiber;
  2097. phy_addr_off += np->port;
  2098. }
  2099. break;
  2100. }
  2101. } else {
  2102. switch (np->flags &
  2103. (NIU_FLAGS_10G |
  2104. NIU_FLAGS_FIBER |
  2105. NIU_FLAGS_XCVR_SERDES)) {
  2106. case 0:
  2107. /* 1G copper */
  2108. tp = &phy_template_1g_copper;
  2109. if (plat_type == PLAT_TYPE_VF_P0)
  2110. phy_addr_off = 10;
  2111. else if (plat_type == PLAT_TYPE_VF_P1)
  2112. phy_addr_off = 26;
  2113. phy_addr_off += (np->port ^ 0x3);
  2114. break;
  2115. case NIU_FLAGS_10G:
  2116. /* 10G copper */
  2117. tp = &phy_template_10g_copper;
  2118. break;
  2119. case NIU_FLAGS_FIBER:
  2120. /* 1G fiber */
  2121. tp = &phy_template_1g_fiber;
  2122. break;
  2123. case NIU_FLAGS_10G | NIU_FLAGS_FIBER:
  2124. /* 10G fiber */
  2125. tp = &phy_template_10g_fiber;
  2126. if (plat_type == PLAT_TYPE_VF_P0 ||
  2127. plat_type == PLAT_TYPE_VF_P1)
  2128. phy_addr_off = 8;
  2129. phy_addr_off += np->port;
  2130. if (np->flags & NIU_FLAGS_HOTPLUG_PHY) {
  2131. tp = &phy_template_10g_fiber_hotplug;
  2132. if (np->port == 0)
  2133. phy_addr_off = 8;
  2134. if (np->port == 1)
  2135. phy_addr_off = 12;
  2136. }
  2137. break;
  2138. case NIU_FLAGS_10G | NIU_FLAGS_XCVR_SERDES:
  2139. case NIU_FLAGS_XCVR_SERDES | NIU_FLAGS_FIBER:
  2140. case NIU_FLAGS_XCVR_SERDES:
  2141. switch(np->port) {
  2142. case 0:
  2143. case 1:
  2144. tp = &phy_template_10g_serdes;
  2145. break;
  2146. case 2:
  2147. case 3:
  2148. tp = &phy_template_1g_rgmii;
  2149. break;
  2150. default:
  2151. return -EINVAL;
  2152. }
  2153. phy_addr_off = niu_atca_port_num[np->port];
  2154. break;
  2155. default:
  2156. return -EINVAL;
  2157. }
  2158. }
  2159. np->phy_ops = tp->ops;
  2160. np->phy_addr = tp->phy_addr_base + phy_addr_off;
  2161. return 0;
  2162. }
  2163. static int niu_init_link(struct niu *np)
  2164. {
  2165. struct niu_parent *parent = np->parent;
  2166. int err, ignore;
  2167. if (parent->plat_type == PLAT_TYPE_NIU) {
  2168. err = niu_xcvr_init(np);
  2169. if (err)
  2170. return err;
  2171. msleep(200);
  2172. }
  2173. err = niu_serdes_init(np);
  2174. if (err && !(np->flags & NIU_FLAGS_HOTPLUG_PHY))
  2175. return err;
  2176. msleep(200);
  2177. err = niu_xcvr_init(np);
  2178. if (!err || (np->flags & NIU_FLAGS_HOTPLUG_PHY))
  2179. niu_link_status(np, &ignore);
  2180. return 0;
  2181. }
  2182. static void niu_set_primary_mac(struct niu *np, const unsigned char *addr)
  2183. {
  2184. u16 reg0 = addr[4] << 8 | addr[5];
  2185. u16 reg1 = addr[2] << 8 | addr[3];
  2186. u16 reg2 = addr[0] << 8 | addr[1];
  2187. if (np->flags & NIU_FLAGS_XMAC) {
  2188. nw64_mac(XMAC_ADDR0, reg0);
  2189. nw64_mac(XMAC_ADDR1, reg1);
  2190. nw64_mac(XMAC_ADDR2, reg2);
  2191. } else {
  2192. nw64_mac(BMAC_ADDR0, reg0);
  2193. nw64_mac(BMAC_ADDR1, reg1);
  2194. nw64_mac(BMAC_ADDR2, reg2);
  2195. }
  2196. }
  2197. static int niu_num_alt_addr(struct niu *np)
  2198. {
  2199. if (np->flags & NIU_FLAGS_XMAC)
  2200. return XMAC_NUM_ALT_ADDR;
  2201. else
  2202. return BMAC_NUM_ALT_ADDR;
  2203. }
  2204. static int niu_set_alt_mac(struct niu *np, int index, unsigned char *addr)
  2205. {
  2206. u16 reg0 = addr[4] << 8 | addr[5];
  2207. u16 reg1 = addr[2] << 8 | addr[3];
  2208. u16 reg2 = addr[0] << 8 | addr[1];
  2209. if (index >= niu_num_alt_addr(np))
  2210. return -EINVAL;
  2211. if (np->flags & NIU_FLAGS_XMAC) {
  2212. nw64_mac(XMAC_ALT_ADDR0(index), reg0);
  2213. nw64_mac(XMAC_ALT_ADDR1(index), reg1);
  2214. nw64_mac(XMAC_ALT_ADDR2(index), reg2);
  2215. } else {
  2216. nw64_mac(BMAC_ALT_ADDR0(index), reg0);
  2217. nw64_mac(BMAC_ALT_ADDR1(index), reg1);
  2218. nw64_mac(BMAC_ALT_ADDR2(index), reg2);
  2219. }
  2220. return 0;
  2221. }
  2222. static int niu_enable_alt_mac(struct niu *np, int index, int on)
  2223. {
  2224. unsigned long reg;
  2225. u64 val, mask;
  2226. if (index >= niu_num_alt_addr(np))
  2227. return -EINVAL;
  2228. if (np->flags & NIU_FLAGS_XMAC) {
  2229. reg = XMAC_ADDR_CMPEN;
  2230. mask = 1 << index;
  2231. } else {
  2232. reg = BMAC_ADDR_CMPEN;
  2233. mask = 1 << (index + 1);
  2234. }
  2235. val = nr64_mac(reg);
  2236. if (on)
  2237. val |= mask;
  2238. else
  2239. val &= ~mask;
  2240. nw64_mac(reg, val);
  2241. return 0;
  2242. }
  2243. static void __set_rdc_table_num_hw(struct niu *np, unsigned long reg,
  2244. int num, int mac_pref)
  2245. {
  2246. u64 val = nr64_mac(reg);
  2247. val &= ~(HOST_INFO_MACRDCTBLN | HOST_INFO_MPR);
  2248. val |= num;
  2249. if (mac_pref)
  2250. val |= HOST_INFO_MPR;
  2251. nw64_mac(reg, val);
  2252. }
  2253. static int __set_rdc_table_num(struct niu *np,
  2254. int xmac_index, int bmac_index,
  2255. int rdc_table_num, int mac_pref)
  2256. {
  2257. unsigned long reg;
  2258. if (rdc_table_num & ~HOST_INFO_MACRDCTBLN)
  2259. return -EINVAL;
  2260. if (np->flags & NIU_FLAGS_XMAC)
  2261. reg = XMAC_HOST_INFO(xmac_index);
  2262. else
  2263. reg = BMAC_HOST_INFO(bmac_index);
  2264. __set_rdc_table_num_hw(np, reg, rdc_table_num, mac_pref);
  2265. return 0;
  2266. }
  2267. static int niu_set_primary_mac_rdc_table(struct niu *np, int table_num,
  2268. int mac_pref)
  2269. {
  2270. return __set_rdc_table_num(np, 17, 0, table_num, mac_pref);
  2271. }
  2272. static int niu_set_multicast_mac_rdc_table(struct niu *np, int table_num,
  2273. int mac_pref)
  2274. {
  2275. return __set_rdc_table_num(np, 16, 8, table_num, mac_pref);
  2276. }
  2277. static int niu_set_alt_mac_rdc_table(struct niu *np, int idx,
  2278. int table_num, int mac_pref)
  2279. {
  2280. if (idx >= niu_num_alt_addr(np))
  2281. return -EINVAL;
  2282. return __set_rdc_table_num(np, idx, idx + 1, table_num, mac_pref);
  2283. }
  2284. static u64 vlan_entry_set_parity(u64 reg_val)
  2285. {
  2286. u64 port01_mask;
  2287. u64 port23_mask;
  2288. port01_mask = 0x00ff;
  2289. port23_mask = 0xff00;
  2290. if (hweight64(reg_val & port01_mask) & 1)
  2291. reg_val |= ENET_VLAN_TBL_PARITY0;
  2292. else
  2293. reg_val &= ~ENET_VLAN_TBL_PARITY0;
  2294. if (hweight64(reg_val & port23_mask) & 1)
  2295. reg_val |= ENET_VLAN_TBL_PARITY1;
  2296. else
  2297. reg_val &= ~ENET_VLAN_TBL_PARITY1;
  2298. return reg_val;
  2299. }
  2300. static void vlan_tbl_write(struct niu *np, unsigned long index,
  2301. int port, int vpr, int rdc_table)
  2302. {
  2303. u64 reg_val = nr64(ENET_VLAN_TBL(index));
  2304. reg_val &= ~((ENET_VLAN_TBL_VPR |
  2305. ENET_VLAN_TBL_VLANRDCTBLN) <<
  2306. ENET_VLAN_TBL_SHIFT(port));
  2307. if (vpr)
  2308. reg_val |= (ENET_VLAN_TBL_VPR <<
  2309. ENET_VLAN_TBL_SHIFT(port));
  2310. reg_val |= (rdc_table << ENET_VLAN_TBL_SHIFT(port));
  2311. reg_val = vlan_entry_set_parity(reg_val);
  2312. nw64(ENET_VLAN_TBL(index), reg_val);
  2313. }
  2314. static void vlan_tbl_clear(struct niu *np)
  2315. {
  2316. int i;
  2317. for (i = 0; i < ENET_VLAN_TBL_NUM_ENTRIES; i++)
  2318. nw64(ENET_VLAN_TBL(i), 0);
  2319. }
  2320. static int tcam_wait_bit(struct niu *np, u64 bit)
  2321. {
  2322. int limit = 1000;
  2323. while (--limit > 0) {
  2324. if (nr64(TCAM_CTL) & bit)
  2325. break;
  2326. udelay(1);
  2327. }
  2328. if (limit <= 0)
  2329. return -ENODEV;
  2330. return 0;
  2331. }
  2332. static int tcam_flush(struct niu *np, int index)
  2333. {
  2334. nw64(TCAM_KEY_0, 0x00);
  2335. nw64(TCAM_KEY_MASK_0, 0xff);
  2336. nw64(TCAM_CTL, (TCAM_CTL_RWC_TCAM_WRITE | index));
  2337. return tcam_wait_bit(np, TCAM_CTL_STAT);
  2338. }
  2339. #if 0
  2340. static int tcam_read(struct niu *np, int index,
  2341. u64 *key, u64 *mask)
  2342. {
  2343. int err;
  2344. nw64(TCAM_CTL, (TCAM_CTL_RWC_TCAM_READ | index));
  2345. err = tcam_wait_bit(np, TCAM_CTL_STAT);
  2346. if (!err) {
  2347. key[0] = nr64(TCAM_KEY_0);
  2348. key[1] = nr64(TCAM_KEY_1);
  2349. key[2] = nr64(TCAM_KEY_2);
  2350. key[3] = nr64(TCAM_KEY_3);
  2351. mask[0] = nr64(TCAM_KEY_MASK_0);
  2352. mask[1] = nr64(TCAM_KEY_MASK_1);
  2353. mask[2] = nr64(TCAM_KEY_MASK_2);
  2354. mask[3] = nr64(TCAM_KEY_MASK_3);
  2355. }
  2356. return err;
  2357. }
  2358. #endif
  2359. static int tcam_write(struct niu *np, int index,
  2360. u64 *key, u64 *mask)
  2361. {
  2362. nw64(TCAM_KEY_0, key[0]);
  2363. nw64(TCAM_KEY_1, key[1]);
  2364. nw64(TCAM_KEY_2, key[2]);
  2365. nw64(TCAM_KEY_3, key[3]);
  2366. nw64(TCAM_KEY_MASK_0, mask[0]);
  2367. nw64(TCAM_KEY_MASK_1, mask[1]);
  2368. nw64(TCAM_KEY_MASK_2, mask[2]);
  2369. nw64(TCAM_KEY_MASK_3, mask[3]);
  2370. nw64(TCAM_CTL, (TCAM_CTL_RWC_TCAM_WRITE | index));
  2371. return tcam_wait_bit(np, TCAM_CTL_STAT);
  2372. }
  2373. #if 0
  2374. static int tcam_assoc_read(struct niu *np, int index, u64 *data)
  2375. {
  2376. int err;
  2377. nw64(TCAM_CTL, (TCAM_CTL_RWC_RAM_READ | index));
  2378. err = tcam_wait_bit(np, TCAM_CTL_STAT);
  2379. if (!err)
  2380. *data = nr64(TCAM_KEY_1);
  2381. return err;
  2382. }
  2383. #endif
  2384. static int tcam_assoc_write(struct niu *np, int index, u64 assoc_data)
  2385. {
  2386. nw64(TCAM_KEY_1, assoc_data);
  2387. nw64(TCAM_CTL, (TCAM_CTL_RWC_RAM_WRITE | index));
  2388. return tcam_wait_bit(np, TCAM_CTL_STAT);
  2389. }
  2390. static void tcam_enable(struct niu *np, int on)
  2391. {
  2392. u64 val = nr64(FFLP_CFG_1);
  2393. if (on)
  2394. val &= ~FFLP_CFG_1_TCAM_DIS;
  2395. else
  2396. val |= FFLP_CFG_1_TCAM_DIS;
  2397. nw64(FFLP_CFG_1, val);
  2398. }
  2399. static void tcam_set_lat_and_ratio(struct niu *np, u64 latency, u64 ratio)
  2400. {
  2401. u64 val = nr64(FFLP_CFG_1);
  2402. val &= ~(FFLP_CFG_1_FFLPINITDONE |
  2403. FFLP_CFG_1_CAMLAT |
  2404. FFLP_CFG_1_CAMRATIO);
  2405. val |= (latency << FFLP_CFG_1_CAMLAT_SHIFT);
  2406. val |= (ratio << FFLP_CFG_1_CAMRATIO_SHIFT);
  2407. nw64(FFLP_CFG_1, val);
  2408. val = nr64(FFLP_CFG_1);
  2409. val |= FFLP_CFG_1_FFLPINITDONE;
  2410. nw64(FFLP_CFG_1, val);
  2411. }
  2412. static int tcam_user_eth_class_enable(struct niu *np, unsigned long class,
  2413. int on)
  2414. {
  2415. unsigned long reg;
  2416. u64 val;
  2417. if (class < CLASS_CODE_ETHERTYPE1 ||
  2418. class > CLASS_CODE_ETHERTYPE2)
  2419. return -EINVAL;
  2420. reg = L2_CLS(class - CLASS_CODE_ETHERTYPE1);
  2421. val = nr64(reg);
  2422. if (on)
  2423. val |= L2_CLS_VLD;
  2424. else
  2425. val &= ~L2_CLS_VLD;
  2426. nw64(reg, val);
  2427. return 0;
  2428. }
  2429. #if 0
  2430. static int tcam_user_eth_class_set(struct niu *np, unsigned long class,
  2431. u64 ether_type)
  2432. {
  2433. unsigned long reg;
  2434. u64 val;
  2435. if (class < CLASS_CODE_ETHERTYPE1 ||
  2436. class > CLASS_CODE_ETHERTYPE2 ||
  2437. (ether_type & ~(u64)0xffff) != 0)
  2438. return -EINVAL;
  2439. reg = L2_CLS(class - CLASS_CODE_ETHERTYPE1);
  2440. val = nr64(reg);
  2441. val &= ~L2_CLS_ETYPE;
  2442. val |= (ether_type << L2_CLS_ETYPE_SHIFT);
  2443. nw64(reg, val);
  2444. return 0;
  2445. }
  2446. #endif
  2447. static int tcam_user_ip_class_enable(struct niu *np, unsigned long class,
  2448. int on)
  2449. {
  2450. unsigned long reg;
  2451. u64 val;
  2452. if (class < CLASS_CODE_USER_PROG1 ||
  2453. class > CLASS_CODE_USER_PROG4)
  2454. return -EINVAL;
  2455. reg = L3_CLS(class - CLASS_CODE_USER_PROG1);
  2456. val = nr64(reg);
  2457. if (on)
  2458. val |= L3_CLS_VALID;
  2459. else
  2460. val &= ~L3_CLS_VALID;
  2461. nw64(reg, val);
  2462. return 0;
  2463. }
  2464. static int tcam_user_ip_class_set(struct niu *np, unsigned long class,
  2465. int ipv6, u64 protocol_id,
  2466. u64 tos_mask, u64 tos_val)
  2467. {
  2468. unsigned long reg;
  2469. u64 val;
  2470. if (class < CLASS_CODE_USER_PROG1 ||
  2471. class > CLASS_CODE_USER_PROG4 ||
  2472. (protocol_id & ~(u64)0xff) != 0 ||
  2473. (tos_mask & ~(u64)0xff) != 0 ||
  2474. (tos_val & ~(u64)0xff) != 0)
  2475. return -EINVAL;
  2476. reg = L3_CLS(class - CLASS_CODE_USER_PROG1);
  2477. val = nr64(reg);
  2478. val &= ~(L3_CLS_IPVER | L3_CLS_PID |
  2479. L3_CLS_TOSMASK | L3_CLS_TOS);
  2480. if (ipv6)
  2481. val |= L3_CLS_IPVER;
  2482. val |= (protocol_id << L3_CLS_PID_SHIFT);
  2483. val |= (tos_mask << L3_CLS_TOSMASK_SHIFT);
  2484. val |= (tos_val << L3_CLS_TOS_SHIFT);
  2485. nw64(reg, val);
  2486. return 0;
  2487. }
  2488. static int tcam_early_init(struct niu *np)
  2489. {
  2490. unsigned long i;
  2491. int err;
  2492. tcam_enable(np, 0);
  2493. tcam_set_lat_and_ratio(np,
  2494. DEFAULT_TCAM_LATENCY,
  2495. DEFAULT_TCAM_ACCESS_RATIO);
  2496. for (i = CLASS_CODE_ETHERTYPE1; i <= CLASS_CODE_ETHERTYPE2; i++) {
  2497. err = tcam_user_eth_class_enable(np, i, 0);
  2498. if (err)
  2499. return err;
  2500. }
  2501. for (i = CLASS_CODE_USER_PROG1; i <= CLASS_CODE_USER_PROG4; i++) {
  2502. err = tcam_user_ip_class_enable(np, i, 0);
  2503. if (err)
  2504. return err;
  2505. }
  2506. return 0;
  2507. }
  2508. static int tcam_flush_all(struct niu *np)
  2509. {
  2510. unsigned long i;
  2511. for (i = 0; i < np->parent->tcam_num_entries; i++) {
  2512. int err = tcam_flush(np, i);
  2513. if (err)
  2514. return err;
  2515. }
  2516. return 0;
  2517. }
  2518. static u64 hash_addr_regval(unsigned long index, unsigned long num_entries)
  2519. {
  2520. return (u64)index | (num_entries == 1 ? HASH_TBL_ADDR_AUTOINC : 0);
  2521. }
  2522. #if 0
  2523. static int hash_read(struct niu *np, unsigned long partition,
  2524. unsigned long index, unsigned long num_entries,
  2525. u64 *data)
  2526. {
  2527. u64 val = hash_addr_regval(index, num_entries);
  2528. unsigned long i;
  2529. if (partition >= FCRAM_NUM_PARTITIONS ||
  2530. index + num_entries > FCRAM_SIZE)
  2531. return -EINVAL;
  2532. nw64(HASH_TBL_ADDR(partition), val);
  2533. for (i = 0; i < num_entries; i++)
  2534. data[i] = nr64(HASH_TBL_DATA(partition));
  2535. return 0;
  2536. }
  2537. #endif
  2538. static int hash_write(struct niu *np, unsigned long partition,
  2539. unsigned long index, unsigned long num_entries,
  2540. u64 *data)
  2541. {
  2542. u64 val = hash_addr_regval(index, num_entries);
  2543. unsigned long i;
  2544. if (partition >= FCRAM_NUM_PARTITIONS ||
  2545. index + (num_entries * 8) > FCRAM_SIZE)
  2546. return -EINVAL;
  2547. nw64(HASH_TBL_ADDR(partition), val);
  2548. for (i = 0; i < num_entries; i++)
  2549. nw64(HASH_TBL_DATA(partition), data[i]);
  2550. return 0;
  2551. }
  2552. static void fflp_reset(struct niu *np)
  2553. {
  2554. u64 val;
  2555. nw64(FFLP_CFG_1, FFLP_CFG_1_PIO_FIO_RST);
  2556. udelay(10);
  2557. nw64(FFLP_CFG_1, 0);
  2558. val = FFLP_CFG_1_FCRAMOUTDR_NORMAL | FFLP_CFG_1_FFLPINITDONE;
  2559. nw64(FFLP_CFG_1, val);
  2560. }
  2561. static void fflp_set_timings(struct niu *np)
  2562. {
  2563. u64 val = nr64(FFLP_CFG_1);
  2564. val &= ~FFLP_CFG_1_FFLPINITDONE;
  2565. val |= (DEFAULT_FCRAMRATIO << FFLP_CFG_1_FCRAMRATIO_SHIFT);
  2566. nw64(FFLP_CFG_1, val);
  2567. val = nr64(FFLP_CFG_1);
  2568. val |= FFLP_CFG_1_FFLPINITDONE;
  2569. nw64(FFLP_CFG_1, val);
  2570. val = nr64(FCRAM_REF_TMR);
  2571. val &= ~(FCRAM_REF_TMR_MAX | FCRAM_REF_TMR_MIN);
  2572. val |= (DEFAULT_FCRAM_REFRESH_MAX << FCRAM_REF_TMR_MAX_SHIFT);
  2573. val |= (DEFAULT_FCRAM_REFRESH_MIN << FCRAM_REF_TMR_MIN_SHIFT);
  2574. nw64(FCRAM_REF_TMR, val);
  2575. }
  2576. static int fflp_set_partition(struct niu *np, u64 partition,
  2577. u64 mask, u64 base, int enable)
  2578. {
  2579. unsigned long reg;
  2580. u64 val;
  2581. if (partition >= FCRAM_NUM_PARTITIONS ||
  2582. (mask & ~(u64)0x1f) != 0 ||
  2583. (base & ~(u64)0x1f) != 0)
  2584. return -EINVAL;
  2585. reg = FLW_PRT_SEL(partition);
  2586. val = nr64(reg);
  2587. val &= ~(FLW_PRT_SEL_EXT | FLW_PRT_SEL_MASK | FLW_PRT_SEL_BASE);
  2588. val |= (mask << FLW_PRT_SEL_MASK_SHIFT);
  2589. val |= (base << FLW_PRT_SEL_BASE_SHIFT);
  2590. if (enable)
  2591. val |= FLW_PRT_SEL_EXT;
  2592. nw64(reg, val);
  2593. return 0;
  2594. }
  2595. static int fflp_disable_all_partitions(struct niu *np)
  2596. {
  2597. unsigned long i;
  2598. for (i = 0; i < FCRAM_NUM_PARTITIONS; i++) {
  2599. int err = fflp_set_partition(np, 0, 0, 0, 0);
  2600. if (err)
  2601. return err;
  2602. }
  2603. return 0;
  2604. }
  2605. static void fflp_llcsnap_enable(struct niu *np, int on)
  2606. {
  2607. u64 val = nr64(FFLP_CFG_1);
  2608. if (on)
  2609. val |= FFLP_CFG_1_LLCSNAP;
  2610. else
  2611. val &= ~FFLP_CFG_1_LLCSNAP;
  2612. nw64(FFLP_CFG_1, val);
  2613. }
  2614. static void fflp_errors_enable(struct niu *np, int on)
  2615. {
  2616. u64 val = nr64(FFLP_CFG_1);
  2617. if (on)
  2618. val &= ~FFLP_CFG_1_ERRORDIS;
  2619. else
  2620. val |= FFLP_CFG_1_ERRORDIS;
  2621. nw64(FFLP_CFG_1, val);
  2622. }
  2623. static int fflp_hash_clear(struct niu *np)
  2624. {
  2625. struct fcram_hash_ipv4 ent;
  2626. unsigned long i;
  2627. /* IPV4 hash entry with valid bit clear, rest is don't care. */
  2628. memset(&ent, 0, sizeof(ent));
  2629. ent.header = HASH_HEADER_EXT;
  2630. for (i = 0; i < FCRAM_SIZE; i += sizeof(ent)) {
  2631. int err = hash_write(np, 0, i, 1, (u64 *) &ent);
  2632. if (err)
  2633. return err;
  2634. }
  2635. return 0;
  2636. }
  2637. static int fflp_early_init(struct niu *np)
  2638. {
  2639. struct niu_parent *parent;
  2640. unsigned long flags;
  2641. int err;
  2642. niu_lock_parent(np, flags);
  2643. parent = np->parent;
  2644. err = 0;
  2645. if (!(parent->flags & PARENT_FLGS_CLS_HWINIT)) {
  2646. if (np->parent->plat_type != PLAT_TYPE_NIU) {
  2647. fflp_reset(np);
  2648. fflp_set_timings(np);
  2649. err = fflp_disable_all_partitions(np);
  2650. if (err) {
  2651. netif_printk(np, probe, KERN_DEBUG, np->dev,
  2652. "fflp_disable_all_partitions failed, err=%d\n",
  2653. err);
  2654. goto out;
  2655. }
  2656. }
  2657. err = tcam_early_init(np);
  2658. if (err) {
  2659. netif_printk(np, probe, KERN_DEBUG, np->dev,
  2660. "tcam_early_init failed, err=%d\n", err);
  2661. goto out;
  2662. }
  2663. fflp_llcsnap_enable(np, 1);
  2664. fflp_errors_enable(np, 0);
  2665. nw64(H1POLY, 0);
  2666. nw64(H2POLY, 0);
  2667. err = tcam_flush_all(np);
  2668. if (err) {
  2669. netif_printk(np, probe, KERN_DEBUG, np->dev,
  2670. "tcam_flush_all failed, err=%d\n", err);
  2671. goto out;
  2672. }
  2673. if (np->parent->plat_type != PLAT_TYPE_NIU) {
  2674. err = fflp_hash_clear(np);
  2675. if (err) {
  2676. netif_printk(np, probe, KERN_DEBUG, np->dev,
  2677. "fflp_hash_clear failed, err=%d\n",
  2678. err);
  2679. goto out;
  2680. }
  2681. }
  2682. vlan_tbl_clear(np);
  2683. parent->flags |= PARENT_FLGS_CLS_HWINIT;
  2684. }
  2685. out:
  2686. niu_unlock_parent(np, flags);
  2687. return err;
  2688. }
  2689. static int niu_set_flow_key(struct niu *np, unsigned long class_code, u64 key)
  2690. {
  2691. if (class_code < CLASS_CODE_USER_PROG1 ||
  2692. class_code > CLASS_CODE_SCTP_IPV6)
  2693. return -EINVAL;
  2694. nw64(FLOW_KEY(class_code - CLASS_CODE_USER_PROG1), key);
  2695. return 0;
  2696. }
  2697. static int niu_set_tcam_key(struct niu *np, unsigned long class_code, u64 key)
  2698. {
  2699. if (class_code < CLASS_CODE_USER_PROG1 ||
  2700. class_code > CLASS_CODE_SCTP_IPV6)
  2701. return -EINVAL;
  2702. nw64(TCAM_KEY(class_code - CLASS_CODE_USER_PROG1), key);
  2703. return 0;
  2704. }
  2705. /* Entries for the ports are interleaved in the TCAM */
  2706. static u16 tcam_get_index(struct niu *np, u16 idx)
  2707. {
  2708. /* One entry reserved for IP fragment rule */
  2709. if (idx >= (np->clas.tcam_sz - 1))
  2710. idx = 0;
  2711. return np->clas.tcam_top + ((idx+1) * np->parent->num_ports);
  2712. }
  2713. static u16 tcam_get_size(struct niu *np)
  2714. {
  2715. /* One entry reserved for IP fragment rule */
  2716. return np->clas.tcam_sz - 1;
  2717. }
  2718. static u16 tcam_get_valid_entry_cnt(struct niu *np)
  2719. {
  2720. /* One entry reserved for IP fragment rule */
  2721. return np->clas.tcam_valid_entries - 1;
  2722. }
  2723. static void niu_rx_skb_append(struct sk_buff *skb, struct page *page,
  2724. u32 offset, u32 size, u32 truesize)
  2725. {
  2726. skb_fill_page_desc(skb, skb_shinfo(skb)->nr_frags, page, offset, size);
  2727. skb->len += size;
  2728. skb->data_len += size;
  2729. skb->truesize += truesize;
  2730. }
  2731. static unsigned int niu_hash_rxaddr(struct rx_ring_info *rp, u64 a)
  2732. {
  2733. a >>= PAGE_SHIFT;
  2734. a ^= (a >> ilog2(MAX_RBR_RING_SIZE));
  2735. return a & (MAX_RBR_RING_SIZE - 1);
  2736. }
  2737. static struct page *niu_find_rxpage(struct rx_ring_info *rp, u64 addr,
  2738. struct page ***link)
  2739. {
  2740. unsigned int h = niu_hash_rxaddr(rp, addr);
  2741. struct page *p, **pp;
  2742. addr &= PAGE_MASK;
  2743. pp = &rp->rxhash[h];
  2744. for (; (p = *pp) != NULL; pp = &niu_next_page(p)) {
  2745. if (p->private == addr) {
  2746. *link = pp;
  2747. goto found;
  2748. }
  2749. }
  2750. BUG();
  2751. found:
  2752. return p;
  2753. }
  2754. static void niu_hash_page(struct rx_ring_info *rp, struct page *page, u64 base)
  2755. {
  2756. unsigned int h = niu_hash_rxaddr(rp, base);
  2757. page->private = base;
  2758. niu_next_page(page) = rp->rxhash[h];
  2759. rp->rxhash[h] = page;
  2760. }
  2761. static int niu_rbr_add_page(struct niu *np, struct rx_ring_info *rp,
  2762. gfp_t mask, int start_index)
  2763. {
  2764. struct page *page;
  2765. u64 addr;
  2766. int i;
  2767. page = alloc_page(mask);
  2768. if (!page)
  2769. return -ENOMEM;
  2770. addr = np->ops->map_page(np->device, page, 0,
  2771. PAGE_SIZE, DMA_FROM_DEVICE);
  2772. if (np->ops->mapping_error(np->device, addr)) {
  2773. __free_page(page);
  2774. return -ENOMEM;
  2775. }
  2776. niu_hash_page(rp, page, addr);
  2777. if (rp->rbr_blocks_per_page > 1)
  2778. page_ref_add(page, rp->rbr_blocks_per_page - 1);
  2779. for (i = 0; i < rp->rbr_blocks_per_page; i++) {
  2780. __le32 *rbr = &rp->rbr[start_index + i];
  2781. *rbr = cpu_to_le32(addr >> RBR_DESCR_ADDR_SHIFT);
  2782. addr += rp->rbr_block_size;
  2783. }
  2784. return 0;
  2785. }
  2786. static void niu_rbr_refill(struct niu *np, struct rx_ring_info *rp, gfp_t mask)
  2787. {
  2788. int index = rp->rbr_index;
  2789. rp->rbr_pending++;
  2790. if ((rp->rbr_pending % rp->rbr_blocks_per_page) == 0) {
  2791. int err = niu_rbr_add_page(np, rp, mask, index);
  2792. if (unlikely(err)) {
  2793. rp->rbr_pending--;
  2794. return;
  2795. }
  2796. rp->rbr_index += rp->rbr_blocks_per_page;
  2797. BUG_ON(rp->rbr_index > rp->rbr_table_size);
  2798. if (rp->rbr_index == rp->rbr_table_size)
  2799. rp->rbr_index = 0;
  2800. if (rp->rbr_pending >= rp->rbr_kick_thresh) {
  2801. nw64(RBR_KICK(rp->rx_channel), rp->rbr_pending);
  2802. rp->rbr_pending = 0;
  2803. }
  2804. }
  2805. }
  2806. static int niu_rx_pkt_ignore(struct niu *np, struct rx_ring_info *rp)
  2807. {
  2808. unsigned int index = rp->rcr_index;
  2809. int num_rcr = 0;
  2810. rp->rx_dropped++;
  2811. while (1) {
  2812. struct page *page, **link;
  2813. u64 addr, val;
  2814. u32 rcr_size;
  2815. num_rcr++;
  2816. val = le64_to_cpup(&rp->rcr[index]);
  2817. addr = (val & RCR_ENTRY_PKT_BUF_ADDR) <<
  2818. RCR_ENTRY_PKT_BUF_ADDR_SHIFT;
  2819. page = niu_find_rxpage(rp, addr, &link);
  2820. rcr_size = rp->rbr_sizes[(val & RCR_ENTRY_PKTBUFSZ) >>
  2821. RCR_ENTRY_PKTBUFSZ_SHIFT];
  2822. if ((page->private + PAGE_SIZE) - rcr_size == addr) {
  2823. *link = niu_next_page(page);
  2824. np->ops->unmap_page(np->device, page->private,
  2825. PAGE_SIZE, DMA_FROM_DEVICE);
  2826. page->private = 0;
  2827. niu_next_page(page) = NULL;
  2828. __free_page(page);
  2829. rp->rbr_refill_pending++;
  2830. }
  2831. index = NEXT_RCR(rp, index);
  2832. if (!(val & RCR_ENTRY_MULTI))
  2833. break;
  2834. }
  2835. rp->rcr_index = index;
  2836. return num_rcr;
  2837. }
  2838. static int niu_process_rx_pkt(struct napi_struct *napi, struct niu *np,
  2839. struct rx_ring_info *rp)
  2840. {
  2841. unsigned int index = rp->rcr_index;
  2842. struct rx_pkt_hdr1 *rh;
  2843. struct sk_buff *skb;
  2844. int len, num_rcr;
  2845. skb = netdev_alloc_skb(np->dev, RX_SKB_ALLOC_SIZE);
  2846. if (unlikely(!skb))
  2847. return niu_rx_pkt_ignore(np, rp);
  2848. num_rcr = 0;
  2849. while (1) {
  2850. struct page *page, **link;
  2851. u32 rcr_size, append_size;
  2852. u64 addr, val, off;
  2853. num_rcr++;
  2854. val = le64_to_cpup(&rp->rcr[index]);
  2855. len = (val & RCR_ENTRY_L2_LEN) >>
  2856. RCR_ENTRY_L2_LEN_SHIFT;
  2857. append_size = len + ETH_HLEN + ETH_FCS_LEN;
  2858. addr = (val & RCR_ENTRY_PKT_BUF_ADDR) <<
  2859. RCR_ENTRY_PKT_BUF_ADDR_SHIFT;
  2860. page = niu_find_rxpage(rp, addr, &link);
  2861. rcr_size = rp->rbr_sizes[(val & RCR_ENTRY_PKTBUFSZ) >>
  2862. RCR_ENTRY_PKTBUFSZ_SHIFT];
  2863. off = addr & ~PAGE_MASK;
  2864. if (num_rcr == 1) {
  2865. int ptype;
  2866. ptype = (val >> RCR_ENTRY_PKT_TYPE_SHIFT);
  2867. if ((ptype == RCR_PKT_TYPE_TCP ||
  2868. ptype == RCR_PKT_TYPE_UDP) &&
  2869. !(val & (RCR_ENTRY_NOPORT |
  2870. RCR_ENTRY_ERROR)))
  2871. skb->ip_summed = CHECKSUM_UNNECESSARY;
  2872. else
  2873. skb_checksum_none_assert(skb);
  2874. } else if (!(val & RCR_ENTRY_MULTI))
  2875. append_size = append_size - skb->len;
  2876. niu_rx_skb_append(skb, page, off, append_size, rcr_size);
  2877. if ((page->private + rp->rbr_block_size) - rcr_size == addr) {
  2878. *link = niu_next_page(page);
  2879. np->ops->unmap_page(np->device, page->private,
  2880. PAGE_SIZE, DMA_FROM_DEVICE);
  2881. page->private = 0;
  2882. niu_next_page(page) = NULL;
  2883. rp->rbr_refill_pending++;
  2884. } else
  2885. get_page(page);
  2886. index = NEXT_RCR(rp, index);
  2887. if (!(val & RCR_ENTRY_MULTI))
  2888. break;
  2889. }
  2890. rp->rcr_index = index;
  2891. len += sizeof(*rh);
  2892. len = min_t(int, len, sizeof(*rh) + VLAN_ETH_HLEN);
  2893. __pskb_pull_tail(skb, len);
  2894. rh = (struct rx_pkt_hdr1 *) skb->data;
  2895. if (np->dev->features & NETIF_F_RXHASH)
  2896. skb_set_hash(skb,
  2897. ((u32)rh->hashval2_0 << 24 |
  2898. (u32)rh->hashval2_1 << 16 |
  2899. (u32)rh->hashval1_1 << 8 |
  2900. (u32)rh->hashval1_2 << 0),
  2901. PKT_HASH_TYPE_L3);
  2902. skb_pull(skb, sizeof(*rh));
  2903. rp->rx_packets++;
  2904. rp->rx_bytes += skb->len;
  2905. skb->protocol = eth_type_trans(skb, np->dev);
  2906. skb_record_rx_queue(skb, rp->rx_channel);
  2907. napi_gro_receive(napi, skb);
  2908. return num_rcr;
  2909. }
  2910. static int niu_rbr_fill(struct niu *np, struct rx_ring_info *rp, gfp_t mask)
  2911. {
  2912. int blocks_per_page = rp->rbr_blocks_per_page;
  2913. int err, index = rp->rbr_index;
  2914. err = 0;
  2915. while (index < (rp->rbr_table_size - blocks_per_page)) {
  2916. err = niu_rbr_add_page(np, rp, mask, index);
  2917. if (unlikely(err))
  2918. break;
  2919. index += blocks_per_page;
  2920. }
  2921. rp->rbr_index = index;
  2922. return err;
  2923. }
  2924. static void niu_rbr_free(struct niu *np, struct rx_ring_info *rp)
  2925. {
  2926. int i;
  2927. for (i = 0; i < MAX_RBR_RING_SIZE; i++) {
  2928. struct page *page;
  2929. page = rp->rxhash[i];
  2930. while (page) {
  2931. struct page *next = niu_next_page(page);
  2932. u64 base = page->private;
  2933. np->ops->unmap_page(np->device, base, PAGE_SIZE,
  2934. DMA_FROM_DEVICE);
  2935. page->private = 0;
  2936. niu_next_page(page) = NULL;
  2937. __free_page(page);
  2938. page = next;
  2939. }
  2940. }
  2941. for (i = 0; i < rp->rbr_table_size; i++)
  2942. rp->rbr[i] = cpu_to_le32(0);
  2943. rp->rbr_index = 0;
  2944. }
  2945. static int release_tx_packet(struct niu *np, struct tx_ring_info *rp, int idx)
  2946. {
  2947. struct tx_buff_info *tb = &rp->tx_buffs[idx];
  2948. struct sk_buff *skb = tb->skb;
  2949. struct tx_pkt_hdr *tp;
  2950. u64 tx_flags;
  2951. int i, len;
  2952. tp = (struct tx_pkt_hdr *) skb->data;
  2953. tx_flags = le64_to_cpup(&tp->flags);
  2954. rp->tx_packets++;
  2955. rp->tx_bytes += (((tx_flags & TXHDR_LEN) >> TXHDR_LEN_SHIFT) -
  2956. ((tx_flags & TXHDR_PAD) / 2));
  2957. len = skb_headlen(skb);
  2958. np->ops->unmap_single(np->device, tb->mapping,
  2959. len, DMA_TO_DEVICE);
  2960. if (le64_to_cpu(rp->descr[idx]) & TX_DESC_MARK)
  2961. rp->mark_pending--;
  2962. tb->skb = NULL;
  2963. do {
  2964. idx = NEXT_TX(rp, idx);
  2965. len -= MAX_TX_DESC_LEN;
  2966. } while (len > 0);
  2967. for (i = 0; i < skb_shinfo(skb)->nr_frags; i++) {
  2968. tb = &rp->tx_buffs[idx];
  2969. BUG_ON(tb->skb != NULL);
  2970. np->ops->unmap_page(np->device, tb->mapping,
  2971. skb_frag_size(&skb_shinfo(skb)->frags[i]),
  2972. DMA_TO_DEVICE);
  2973. idx = NEXT_TX(rp, idx);
  2974. }
  2975. dev_kfree_skb(skb);
  2976. return idx;
  2977. }
  2978. #define NIU_TX_WAKEUP_THRESH(rp) ((rp)->pending / 4)
  2979. static void niu_tx_work(struct niu *np, struct tx_ring_info *rp)
  2980. {
  2981. struct netdev_queue *txq;
  2982. u16 pkt_cnt, tmp;
  2983. int cons, index;
  2984. u64 cs;
  2985. index = (rp - np->tx_rings);
  2986. txq = netdev_get_tx_queue(np->dev, index);
  2987. cs = rp->tx_cs;
  2988. if (unlikely(!(cs & (TX_CS_MK | TX_CS_MMK))))
  2989. goto out;
  2990. tmp = pkt_cnt = (cs & TX_CS_PKT_CNT) >> TX_CS_PKT_CNT_SHIFT;
  2991. pkt_cnt = (pkt_cnt - rp->last_pkt_cnt) &
  2992. (TX_CS_PKT_CNT >> TX_CS_PKT_CNT_SHIFT);
  2993. rp->last_pkt_cnt = tmp;
  2994. cons = rp->cons;
  2995. netif_printk(np, tx_done, KERN_DEBUG, np->dev,
  2996. "%s() pkt_cnt[%u] cons[%d]\n", __func__, pkt_cnt, cons);
  2997. while (pkt_cnt--)
  2998. cons = release_tx_packet(np, rp, cons);
  2999. rp->cons = cons;
  3000. smp_mb();
  3001. out:
  3002. if (unlikely(netif_tx_queue_stopped(txq) &&
  3003. (niu_tx_avail(rp) > NIU_TX_WAKEUP_THRESH(rp)))) {
  3004. __netif_tx_lock(txq, smp_processor_id());
  3005. if (netif_tx_queue_stopped(txq) &&
  3006. (niu_tx_avail(rp) > NIU_TX_WAKEUP_THRESH(rp)))
  3007. netif_tx_wake_queue(txq);
  3008. __netif_tx_unlock(txq);
  3009. }
  3010. }
  3011. static inline void niu_sync_rx_discard_stats(struct niu *np,
  3012. struct rx_ring_info *rp,
  3013. const int limit)
  3014. {
  3015. /* This elaborate scheme is needed for reading the RX discard
  3016. * counters, as they are only 16-bit and can overflow quickly,
  3017. * and because the overflow indication bit is not usable as
  3018. * the counter value does not wrap, but remains at max value
  3019. * 0xFFFF.
  3020. *
  3021. * In theory and in practice counters can be lost in between
  3022. * reading nr64() and clearing the counter nw64(). For this
  3023. * reason, the number of counter clearings nw64() is
  3024. * limited/reduced though the limit parameter.
  3025. */
  3026. int rx_channel = rp->rx_channel;
  3027. u32 misc, wred;
  3028. /* RXMISC (Receive Miscellaneous Discard Count), covers the
  3029. * following discard events: IPP (Input Port Process),
  3030. * FFLP/TCAM, Full RCR (Receive Completion Ring) RBR (Receive
  3031. * Block Ring) prefetch buffer is empty.
  3032. */
  3033. misc = nr64(RXMISC(rx_channel));
  3034. if (unlikely((misc & RXMISC_COUNT) > limit)) {
  3035. nw64(RXMISC(rx_channel), 0);
  3036. rp->rx_errors += misc & RXMISC_COUNT;
  3037. if (unlikely(misc & RXMISC_OFLOW))
  3038. dev_err(np->device, "rx-%d: Counter overflow RXMISC discard\n",
  3039. rx_channel);
  3040. netif_printk(np, rx_err, KERN_DEBUG, np->dev,
  3041. "rx-%d: MISC drop=%u over=%u\n",
  3042. rx_channel, misc, misc-limit);
  3043. }
  3044. /* WRED (Weighted Random Early Discard) by hardware */
  3045. wred = nr64(RED_DIS_CNT(rx_channel));
  3046. if (unlikely((wred & RED_DIS_CNT_COUNT) > limit)) {
  3047. nw64(RED_DIS_CNT(rx_channel), 0);
  3048. rp->rx_dropped += wred & RED_DIS_CNT_COUNT;
  3049. if (unlikely(wred & RED_DIS_CNT_OFLOW))
  3050. dev_err(np->device, "rx-%d: Counter overflow WRED discard\n", rx_channel);
  3051. netif_printk(np, rx_err, KERN_DEBUG, np->dev,
  3052. "rx-%d: WRED drop=%u over=%u\n",
  3053. rx_channel, wred, wred-limit);
  3054. }
  3055. }
  3056. static int niu_rx_work(struct napi_struct *napi, struct niu *np,
  3057. struct rx_ring_info *rp, int budget)
  3058. {
  3059. int qlen, rcr_done = 0, work_done = 0;
  3060. struct rxdma_mailbox *mbox = rp->mbox;
  3061. u64 stat;
  3062. #if 1
  3063. stat = nr64(RX_DMA_CTL_STAT(rp->rx_channel));
  3064. qlen = nr64(RCRSTAT_A(rp->rx_channel)) & RCRSTAT_A_QLEN;
  3065. #else
  3066. stat = le64_to_cpup(&mbox->rx_dma_ctl_stat);
  3067. qlen = (le64_to_cpup(&mbox->rcrstat_a) & RCRSTAT_A_QLEN);
  3068. #endif
  3069. mbox->rx_dma_ctl_stat = 0;
  3070. mbox->rcrstat_a = 0;
  3071. netif_printk(np, rx_status, KERN_DEBUG, np->dev,
  3072. "%s(chan[%d]), stat[%llx] qlen=%d\n",
  3073. __func__, rp->rx_channel, (unsigned long long)stat, qlen);
  3074. rcr_done = work_done = 0;
  3075. qlen = min(qlen, budget);
  3076. while (work_done < qlen) {
  3077. rcr_done += niu_process_rx_pkt(napi, np, rp);
  3078. work_done++;
  3079. }
  3080. if (rp->rbr_refill_pending >= rp->rbr_kick_thresh) {
  3081. unsigned int i;
  3082. for (i = 0; i < rp->rbr_refill_pending; i++)
  3083. niu_rbr_refill(np, rp, GFP_ATOMIC);
  3084. rp->rbr_refill_pending = 0;
  3085. }
  3086. stat = (RX_DMA_CTL_STAT_MEX |
  3087. ((u64)work_done << RX_DMA_CTL_STAT_PKTREAD_SHIFT) |
  3088. ((u64)rcr_done << RX_DMA_CTL_STAT_PTRREAD_SHIFT));
  3089. nw64(RX_DMA_CTL_STAT(rp->rx_channel), stat);
  3090. /* Only sync discards stats when qlen indicate potential for drops */
  3091. if (qlen > 10)
  3092. niu_sync_rx_discard_stats(np, rp, 0x7FFF);
  3093. return work_done;
  3094. }
  3095. static int niu_poll_core(struct niu *np, struct niu_ldg *lp, int budget)
  3096. {
  3097. u64 v0 = lp->v0;
  3098. u32 tx_vec = (v0 >> 32);
  3099. u32 rx_vec = (v0 & 0xffffffff);
  3100. int i, work_done = 0;
  3101. netif_printk(np, intr, KERN_DEBUG, np->dev,
  3102. "%s() v0[%016llx]\n", __func__, (unsigned long long)v0);
  3103. for (i = 0; i < np->num_tx_rings; i++) {
  3104. struct tx_ring_info *rp = &np->tx_rings[i];
  3105. if (tx_vec & (1 << rp->tx_channel))
  3106. niu_tx_work(np, rp);
  3107. nw64(LD_IM0(LDN_TXDMA(rp->tx_channel)), 0);
  3108. }
  3109. for (i = 0; i < np->num_rx_rings; i++) {
  3110. struct rx_ring_info *rp = &np->rx_rings[i];
  3111. if (rx_vec & (1 << rp->rx_channel)) {
  3112. int this_work_done;
  3113. this_work_done = niu_rx_work(&lp->napi, np, rp,
  3114. budget);
  3115. budget -= this_work_done;
  3116. work_done += this_work_done;
  3117. }
  3118. nw64(LD_IM0(LDN_RXDMA(rp->rx_channel)), 0);
  3119. }
  3120. return work_done;
  3121. }
  3122. static int niu_poll(struct napi_struct *napi, int budget)
  3123. {
  3124. struct niu_ldg *lp = container_of(napi, struct niu_ldg, napi);
  3125. struct niu *np = lp->np;
  3126. int work_done;
  3127. work_done = niu_poll_core(np, lp, budget);
  3128. if (work_done < budget) {
  3129. napi_complete_done(napi, work_done);
  3130. niu_ldg_rearm(np, lp, 1);
  3131. }
  3132. return work_done;
  3133. }
  3134. static void niu_log_rxchan_errors(struct niu *np, struct rx_ring_info *rp,
  3135. u64 stat)
  3136. {
  3137. netdev_err(np->dev, "RX channel %u errors ( ", rp->rx_channel);
  3138. if (stat & RX_DMA_CTL_STAT_RBR_TMOUT)
  3139. pr_cont("RBR_TMOUT ");
  3140. if (stat & RX_DMA_CTL_STAT_RSP_CNT_ERR)
  3141. pr_cont("RSP_CNT ");
  3142. if (stat & RX_DMA_CTL_STAT_BYTE_EN_BUS)
  3143. pr_cont("BYTE_EN_BUS ");
  3144. if (stat & RX_DMA_CTL_STAT_RSP_DAT_ERR)
  3145. pr_cont("RSP_DAT ");
  3146. if (stat & RX_DMA_CTL_STAT_RCR_ACK_ERR)
  3147. pr_cont("RCR_ACK ");
  3148. if (stat & RX_DMA_CTL_STAT_RCR_SHA_PAR)
  3149. pr_cont("RCR_SHA_PAR ");
  3150. if (stat & RX_DMA_CTL_STAT_RBR_PRE_PAR)
  3151. pr_cont("RBR_PRE_PAR ");
  3152. if (stat & RX_DMA_CTL_STAT_CONFIG_ERR)
  3153. pr_cont("CONFIG ");
  3154. if (stat & RX_DMA_CTL_STAT_RCRINCON)
  3155. pr_cont("RCRINCON ");
  3156. if (stat & RX_DMA_CTL_STAT_RCRFULL)
  3157. pr_cont("RCRFULL ");
  3158. if (stat & RX_DMA_CTL_STAT_RBRFULL)
  3159. pr_cont("RBRFULL ");
  3160. if (stat & RX_DMA_CTL_STAT_RBRLOGPAGE)
  3161. pr_cont("RBRLOGPAGE ");
  3162. if (stat & RX_DMA_CTL_STAT_CFIGLOGPAGE)
  3163. pr_cont("CFIGLOGPAGE ");
  3164. if (stat & RX_DMA_CTL_STAT_DC_FIFO_ERR)
  3165. pr_cont("DC_FIDO ");
  3166. pr_cont(")\n");
  3167. }
  3168. static int niu_rx_error(struct niu *np, struct rx_ring_info *rp)
  3169. {
  3170. u64 stat = nr64(RX_DMA_CTL_STAT(rp->rx_channel));
  3171. int err = 0;
  3172. if (stat & (RX_DMA_CTL_STAT_CHAN_FATAL |
  3173. RX_DMA_CTL_STAT_PORT_FATAL))
  3174. err = -EINVAL;
  3175. if (err) {
  3176. netdev_err(np->dev, "RX channel %u error, stat[%llx]\n",
  3177. rp->rx_channel,
  3178. (unsigned long long) stat);
  3179. niu_log_rxchan_errors(np, rp, stat);
  3180. }
  3181. nw64(RX_DMA_CTL_STAT(rp->rx_channel),
  3182. stat & RX_DMA_CTL_WRITE_CLEAR_ERRS);
  3183. return err;
  3184. }
  3185. static void niu_log_txchan_errors(struct niu *np, struct tx_ring_info *rp,
  3186. u64 cs)
  3187. {
  3188. netdev_err(np->dev, "TX channel %u errors ( ", rp->tx_channel);
  3189. if (cs & TX_CS_MBOX_ERR)
  3190. pr_cont("MBOX ");
  3191. if (cs & TX_CS_PKT_SIZE_ERR)
  3192. pr_cont("PKT_SIZE ");
  3193. if (cs & TX_CS_TX_RING_OFLOW)
  3194. pr_cont("TX_RING_OFLOW ");
  3195. if (cs & TX_CS_PREF_BUF_PAR_ERR)
  3196. pr_cont("PREF_BUF_PAR ");
  3197. if (cs & TX_CS_NACK_PREF)
  3198. pr_cont("NACK_PREF ");
  3199. if (cs & TX_CS_NACK_PKT_RD)
  3200. pr_cont("NACK_PKT_RD ");
  3201. if (cs & TX_CS_CONF_PART_ERR)
  3202. pr_cont("CONF_PART ");
  3203. if (cs & TX_CS_PKT_PRT_ERR)
  3204. pr_cont("PKT_PTR ");
  3205. pr_cont(")\n");
  3206. }
  3207. static int niu_tx_error(struct niu *np, struct tx_ring_info *rp)
  3208. {
  3209. u64 cs, logh, logl;
  3210. cs = nr64(TX_CS(rp->tx_channel));
  3211. logh = nr64(TX_RNG_ERR_LOGH(rp->tx_channel));
  3212. logl = nr64(TX_RNG_ERR_LOGL(rp->tx_channel));
  3213. netdev_err(np->dev, "TX channel %u error, cs[%llx] logh[%llx] logl[%llx]\n",
  3214. rp->tx_channel,
  3215. (unsigned long long)cs,
  3216. (unsigned long long)logh,
  3217. (unsigned long long)logl);
  3218. niu_log_txchan_errors(np, rp, cs);
  3219. return -ENODEV;
  3220. }
  3221. static int niu_mif_interrupt(struct niu *np)
  3222. {
  3223. u64 mif_status = nr64(MIF_STATUS);
  3224. int phy_mdint = 0;
  3225. if (np->flags & NIU_FLAGS_XMAC) {
  3226. u64 xrxmac_stat = nr64_mac(XRXMAC_STATUS);
  3227. if (xrxmac_stat & XRXMAC_STATUS_PHY_MDINT)
  3228. phy_mdint = 1;
  3229. }
  3230. netdev_err(np->dev, "MIF interrupt, stat[%llx] phy_mdint(%d)\n",
  3231. (unsigned long long)mif_status, phy_mdint);
  3232. return -ENODEV;
  3233. }
  3234. static void niu_xmac_interrupt(struct niu *np)
  3235. {
  3236. struct niu_xmac_stats *mp = &np->mac_stats.xmac;
  3237. u64 val;
  3238. val = nr64_mac(XTXMAC_STATUS);
  3239. if (val & XTXMAC_STATUS_FRAME_CNT_EXP)
  3240. mp->tx_frames += TXMAC_FRM_CNT_COUNT;
  3241. if (val & XTXMAC_STATUS_BYTE_CNT_EXP)
  3242. mp->tx_bytes += TXMAC_BYTE_CNT_COUNT;
  3243. if (val & XTXMAC_STATUS_TXFIFO_XFR_ERR)
  3244. mp->tx_fifo_errors++;
  3245. if (val & XTXMAC_STATUS_TXMAC_OFLOW)
  3246. mp->tx_overflow_errors++;
  3247. if (val & XTXMAC_STATUS_MAX_PSIZE_ERR)
  3248. mp->tx_max_pkt_size_errors++;
  3249. if (val & XTXMAC_STATUS_TXMAC_UFLOW)
  3250. mp->tx_underflow_errors++;
  3251. val = nr64_mac(XRXMAC_STATUS);
  3252. if (val & XRXMAC_STATUS_LCL_FLT_STATUS)
  3253. mp->rx_local_faults++;
  3254. if (val & XRXMAC_STATUS_RFLT_DET)
  3255. mp->rx_remote_faults++;
  3256. if (val & XRXMAC_STATUS_LFLT_CNT_EXP)
  3257. mp->rx_link_faults += LINK_FAULT_CNT_COUNT;
  3258. if (val & XRXMAC_STATUS_ALIGNERR_CNT_EXP)
  3259. mp->rx_align_errors += RXMAC_ALIGN_ERR_CNT_COUNT;
  3260. if (val & XRXMAC_STATUS_RXFRAG_CNT_EXP)
  3261. mp->rx_frags += RXMAC_FRAG_CNT_COUNT;
  3262. if (val & XRXMAC_STATUS_RXMULTF_CNT_EXP)
  3263. mp->rx_mcasts += RXMAC_MC_FRM_CNT_COUNT;
  3264. if (val & XRXMAC_STATUS_RXBCAST_CNT_EXP)
  3265. mp->rx_bcasts += RXMAC_BC_FRM_CNT_COUNT;
  3266. if (val & XRXMAC_STATUS_RXHIST1_CNT_EXP)
  3267. mp->rx_hist_cnt1 += RXMAC_HIST_CNT1_COUNT;
  3268. if (val & XRXMAC_STATUS_RXHIST2_CNT_EXP)
  3269. mp->rx_hist_cnt2 += RXMAC_HIST_CNT2_COUNT;
  3270. if (val & XRXMAC_STATUS_RXHIST3_CNT_EXP)
  3271. mp->rx_hist_cnt3 += RXMAC_HIST_CNT3_COUNT;
  3272. if (val & XRXMAC_STATUS_RXHIST4_CNT_EXP)
  3273. mp->rx_hist_cnt4 += RXMAC_HIST_CNT4_COUNT;
  3274. if (val & XRXMAC_STATUS_RXHIST5_CNT_EXP)
  3275. mp->rx_hist_cnt5 += RXMAC_HIST_CNT5_COUNT;
  3276. if (val & XRXMAC_STATUS_RXHIST6_CNT_EXP)
  3277. mp->rx_hist_cnt6 += RXMAC_HIST_CNT6_COUNT;
  3278. if (val & XRXMAC_STATUS_RXHIST7_CNT_EXP)
  3279. mp->rx_hist_cnt7 += RXMAC_HIST_CNT7_COUNT;
  3280. if (val & XRXMAC_STATUS_RXOCTET_CNT_EXP)
  3281. mp->rx_octets += RXMAC_BT_CNT_COUNT;
  3282. if (val & XRXMAC_STATUS_CVIOLERR_CNT_EXP)
  3283. mp->rx_code_violations += RXMAC_CD_VIO_CNT_COUNT;
  3284. if (val & XRXMAC_STATUS_LENERR_CNT_EXP)
  3285. mp->rx_len_errors += RXMAC_MPSZER_CNT_COUNT;
  3286. if (val & XRXMAC_STATUS_CRCERR_CNT_EXP)
  3287. mp->rx_crc_errors += RXMAC_CRC_ER_CNT_COUNT;
  3288. if (val & XRXMAC_STATUS_RXUFLOW)
  3289. mp->rx_underflows++;
  3290. if (val & XRXMAC_STATUS_RXOFLOW)
  3291. mp->rx_overflows++;
  3292. val = nr64_mac(XMAC_FC_STAT);
  3293. if (val & XMAC_FC_STAT_TX_MAC_NPAUSE)
  3294. mp->pause_off_state++;
  3295. if (val & XMAC_FC_STAT_TX_MAC_PAUSE)
  3296. mp->pause_on_state++;
  3297. if (val & XMAC_FC_STAT_RX_MAC_RPAUSE)
  3298. mp->pause_received++;
  3299. }
  3300. static void niu_bmac_interrupt(struct niu *np)
  3301. {
  3302. struct niu_bmac_stats *mp = &np->mac_stats.bmac;
  3303. u64 val;
  3304. val = nr64_mac(BTXMAC_STATUS);
  3305. if (val & BTXMAC_STATUS_UNDERRUN)
  3306. mp->tx_underflow_errors++;
  3307. if (val & BTXMAC_STATUS_MAX_PKT_ERR)
  3308. mp->tx_max_pkt_size_errors++;
  3309. if (val & BTXMAC_STATUS_BYTE_CNT_EXP)
  3310. mp->tx_bytes += BTXMAC_BYTE_CNT_COUNT;
  3311. if (val & BTXMAC_STATUS_FRAME_CNT_EXP)
  3312. mp->tx_frames += BTXMAC_FRM_CNT_COUNT;
  3313. val = nr64_mac(BRXMAC_STATUS);
  3314. if (val & BRXMAC_STATUS_OVERFLOW)
  3315. mp->rx_overflows++;
  3316. if (val & BRXMAC_STATUS_FRAME_CNT_EXP)
  3317. mp->rx_frames += BRXMAC_FRAME_CNT_COUNT;
  3318. if (val & BRXMAC_STATUS_ALIGN_ERR_EXP)
  3319. mp->rx_align_errors += BRXMAC_ALIGN_ERR_CNT_COUNT;
  3320. if (val & BRXMAC_STATUS_CRC_ERR_EXP)
  3321. mp->rx_crc_errors += BRXMAC_ALIGN_ERR_CNT_COUNT;
  3322. if (val & BRXMAC_STATUS_LEN_ERR_EXP)
  3323. mp->rx_len_errors += BRXMAC_CODE_VIOL_ERR_CNT_COUNT;
  3324. val = nr64_mac(BMAC_CTRL_STATUS);
  3325. if (val & BMAC_CTRL_STATUS_NOPAUSE)
  3326. mp->pause_off_state++;
  3327. if (val & BMAC_CTRL_STATUS_PAUSE)
  3328. mp->pause_on_state++;
  3329. if (val & BMAC_CTRL_STATUS_PAUSE_RECV)
  3330. mp->pause_received++;
  3331. }
  3332. static int niu_mac_interrupt(struct niu *np)
  3333. {
  3334. if (np->flags & NIU_FLAGS_XMAC)
  3335. niu_xmac_interrupt(np);
  3336. else
  3337. niu_bmac_interrupt(np);
  3338. return 0;
  3339. }
  3340. static void niu_log_device_error(struct niu *np, u64 stat)
  3341. {
  3342. netdev_err(np->dev, "Core device errors ( ");
  3343. if (stat & SYS_ERR_MASK_META2)
  3344. pr_cont("META2 ");
  3345. if (stat & SYS_ERR_MASK_META1)
  3346. pr_cont("META1 ");
  3347. if (stat & SYS_ERR_MASK_PEU)
  3348. pr_cont("PEU ");
  3349. if (stat & SYS_ERR_MASK_TXC)
  3350. pr_cont("TXC ");
  3351. if (stat & SYS_ERR_MASK_RDMC)
  3352. pr_cont("RDMC ");
  3353. if (stat & SYS_ERR_MASK_TDMC)
  3354. pr_cont("TDMC ");
  3355. if (stat & SYS_ERR_MASK_ZCP)
  3356. pr_cont("ZCP ");
  3357. if (stat & SYS_ERR_MASK_FFLP)
  3358. pr_cont("FFLP ");
  3359. if (stat & SYS_ERR_MASK_IPP)
  3360. pr_cont("IPP ");
  3361. if (stat & SYS_ERR_MASK_MAC)
  3362. pr_cont("MAC ");
  3363. if (stat & SYS_ERR_MASK_SMX)
  3364. pr_cont("SMX ");
  3365. pr_cont(")\n");
  3366. }
  3367. static int niu_device_error(struct niu *np)
  3368. {
  3369. u64 stat = nr64(SYS_ERR_STAT);
  3370. netdev_err(np->dev, "Core device error, stat[%llx]\n",
  3371. (unsigned long long)stat);
  3372. niu_log_device_error(np, stat);
  3373. return -ENODEV;
  3374. }
  3375. static int niu_slowpath_interrupt(struct niu *np, struct niu_ldg *lp,
  3376. u64 v0, u64 v1, u64 v2)
  3377. {
  3378. int i, err = 0;
  3379. lp->v0 = v0;
  3380. lp->v1 = v1;
  3381. lp->v2 = v2;
  3382. if (v1 & 0x00000000ffffffffULL) {
  3383. u32 rx_vec = (v1 & 0xffffffff);
  3384. for (i = 0; i < np->num_rx_rings; i++) {
  3385. struct rx_ring_info *rp = &np->rx_rings[i];
  3386. if (rx_vec & (1 << rp->rx_channel)) {
  3387. int r = niu_rx_error(np, rp);
  3388. if (r) {
  3389. err = r;
  3390. } else {
  3391. if (!v0)
  3392. nw64(RX_DMA_CTL_STAT(rp->rx_channel),
  3393. RX_DMA_CTL_STAT_MEX);
  3394. }
  3395. }
  3396. }
  3397. }
  3398. if (v1 & 0x7fffffff00000000ULL) {
  3399. u32 tx_vec = (v1 >> 32) & 0x7fffffff;
  3400. for (i = 0; i < np->num_tx_rings; i++) {
  3401. struct tx_ring_info *rp = &np->tx_rings[i];
  3402. if (tx_vec & (1 << rp->tx_channel)) {
  3403. int r = niu_tx_error(np, rp);
  3404. if (r)
  3405. err = r;
  3406. }
  3407. }
  3408. }
  3409. if ((v0 | v1) & 0x8000000000000000ULL) {
  3410. int r = niu_mif_interrupt(np);
  3411. if (r)
  3412. err = r;
  3413. }
  3414. if (v2) {
  3415. if (v2 & 0x01ef) {
  3416. int r = niu_mac_interrupt(np);
  3417. if (r)
  3418. err = r;
  3419. }
  3420. if (v2 & 0x0210) {
  3421. int r = niu_device_error(np);
  3422. if (r)
  3423. err = r;
  3424. }
  3425. }
  3426. if (err)
  3427. niu_enable_interrupts(np, 0);
  3428. return err;
  3429. }
  3430. static void niu_rxchan_intr(struct niu *np, struct rx_ring_info *rp,
  3431. int ldn)
  3432. {
  3433. struct rxdma_mailbox *mbox = rp->mbox;
  3434. u64 stat_write, stat = le64_to_cpup(&mbox->rx_dma_ctl_stat);
  3435. stat_write = (RX_DMA_CTL_STAT_RCRTHRES |
  3436. RX_DMA_CTL_STAT_RCRTO);
  3437. nw64(RX_DMA_CTL_STAT(rp->rx_channel), stat_write);
  3438. netif_printk(np, intr, KERN_DEBUG, np->dev,
  3439. "%s() stat[%llx]\n", __func__, (unsigned long long)stat);
  3440. }
  3441. static void niu_txchan_intr(struct niu *np, struct tx_ring_info *rp,
  3442. int ldn)
  3443. {
  3444. rp->tx_cs = nr64(TX_CS(rp->tx_channel));
  3445. netif_printk(np, intr, KERN_DEBUG, np->dev,
  3446. "%s() cs[%llx]\n", __func__, (unsigned long long)rp->tx_cs);
  3447. }
  3448. static void __niu_fastpath_interrupt(struct niu *np, int ldg, u64 v0)
  3449. {
  3450. struct niu_parent *parent = np->parent;
  3451. u32 rx_vec, tx_vec;
  3452. int i;
  3453. tx_vec = (v0 >> 32);
  3454. rx_vec = (v0 & 0xffffffff);
  3455. for (i = 0; i < np->num_rx_rings; i++) {
  3456. struct rx_ring_info *rp = &np->rx_rings[i];
  3457. int ldn = LDN_RXDMA(rp->rx_channel);
  3458. if (parent->ldg_map[ldn] != ldg)
  3459. continue;
  3460. nw64(LD_IM0(ldn), LD_IM0_MASK);
  3461. if (rx_vec & (1 << rp->rx_channel))
  3462. niu_rxchan_intr(np, rp, ldn);
  3463. }
  3464. for (i = 0; i < np->num_tx_rings; i++) {
  3465. struct tx_ring_info *rp = &np->tx_rings[i];
  3466. int ldn = LDN_TXDMA(rp->tx_channel);
  3467. if (parent->ldg_map[ldn] != ldg)
  3468. continue;
  3469. nw64(LD_IM0(ldn), LD_IM0_MASK);
  3470. if (tx_vec & (1 << rp->tx_channel))
  3471. niu_txchan_intr(np, rp, ldn);
  3472. }
  3473. }
  3474. static void niu_schedule_napi(struct niu *np, struct niu_ldg *lp,
  3475. u64 v0, u64 v1, u64 v2)
  3476. {
  3477. if (likely(napi_schedule_prep(&lp->napi))) {
  3478. lp->v0 = v0;
  3479. lp->v1 = v1;
  3480. lp->v2 = v2;
  3481. __niu_fastpath_interrupt(np, lp->ldg_num, v0);
  3482. __napi_schedule(&lp->napi);
  3483. }
  3484. }
  3485. static irqreturn_t niu_interrupt(int irq, void *dev_id)
  3486. {
  3487. struct niu_ldg *lp = dev_id;
  3488. struct niu *np = lp->np;
  3489. int ldg = lp->ldg_num;
  3490. unsigned long flags;
  3491. u64 v0, v1, v2;
  3492. if (netif_msg_intr(np))
  3493. printk(KERN_DEBUG KBUILD_MODNAME ": " "%s() ldg[%p](%d)",
  3494. __func__, lp, ldg);
  3495. spin_lock_irqsave(&np->lock, flags);
  3496. v0 = nr64(LDSV0(ldg));
  3497. v1 = nr64(LDSV1(ldg));
  3498. v2 = nr64(LDSV2(ldg));
  3499. if (netif_msg_intr(np))
  3500. pr_cont(" v0[%llx] v1[%llx] v2[%llx]\n",
  3501. (unsigned long long) v0,
  3502. (unsigned long long) v1,
  3503. (unsigned long long) v2);
  3504. if (unlikely(!v0 && !v1 && !v2)) {
  3505. spin_unlock_irqrestore(&np->lock, flags);
  3506. return IRQ_NONE;
  3507. }
  3508. if (unlikely((v0 & ((u64)1 << LDN_MIF)) || v1 || v2)) {
  3509. int err = niu_slowpath_interrupt(np, lp, v0, v1, v2);
  3510. if (err)
  3511. goto out;
  3512. }
  3513. if (likely(v0 & ~((u64)1 << LDN_MIF)))
  3514. niu_schedule_napi(np, lp, v0, v1, v2);
  3515. else
  3516. niu_ldg_rearm(np, lp, 1);
  3517. out:
  3518. spin_unlock_irqrestore(&np->lock, flags);
  3519. return IRQ_HANDLED;
  3520. }
  3521. static void niu_free_rx_ring_info(struct niu *np, struct rx_ring_info *rp)
  3522. {
  3523. if (rp->mbox) {
  3524. np->ops->free_coherent(np->device,
  3525. sizeof(struct rxdma_mailbox),
  3526. rp->mbox, rp->mbox_dma);
  3527. rp->mbox = NULL;
  3528. }
  3529. if (rp->rcr) {
  3530. np->ops->free_coherent(np->device,
  3531. MAX_RCR_RING_SIZE * sizeof(__le64),
  3532. rp->rcr, rp->rcr_dma);
  3533. rp->rcr = NULL;
  3534. rp->rcr_table_size = 0;
  3535. rp->rcr_index = 0;
  3536. }
  3537. if (rp->rbr) {
  3538. niu_rbr_free(np, rp);
  3539. np->ops->free_coherent(np->device,
  3540. MAX_RBR_RING_SIZE * sizeof(__le32),
  3541. rp->rbr, rp->rbr_dma);
  3542. rp->rbr = NULL;
  3543. rp->rbr_table_size = 0;
  3544. rp->rbr_index = 0;
  3545. }
  3546. kfree(rp->rxhash);
  3547. rp->rxhash = NULL;
  3548. }
  3549. static void niu_free_tx_ring_info(struct niu *np, struct tx_ring_info *rp)
  3550. {
  3551. if (rp->mbox) {
  3552. np->ops->free_coherent(np->device,
  3553. sizeof(struct txdma_mailbox),
  3554. rp->mbox, rp->mbox_dma);
  3555. rp->mbox = NULL;
  3556. }
  3557. if (rp->descr) {
  3558. int i;
  3559. for (i = 0; i < MAX_TX_RING_SIZE; i++) {
  3560. if (rp->tx_buffs[i].skb)
  3561. (void) release_tx_packet(np, rp, i);
  3562. }
  3563. np->ops->free_coherent(np->device,
  3564. MAX_TX_RING_SIZE * sizeof(__le64),
  3565. rp->descr, rp->descr_dma);
  3566. rp->descr = NULL;
  3567. rp->pending = 0;
  3568. rp->prod = 0;
  3569. rp->cons = 0;
  3570. rp->wrap_bit = 0;
  3571. }
  3572. }
  3573. static void niu_free_channels(struct niu *np)
  3574. {
  3575. int i;
  3576. if (np->rx_rings) {
  3577. for (i = 0; i < np->num_rx_rings; i++) {
  3578. struct rx_ring_info *rp = &np->rx_rings[i];
  3579. niu_free_rx_ring_info(np, rp);
  3580. }
  3581. kfree(np->rx_rings);
  3582. np->rx_rings = NULL;
  3583. np->num_rx_rings = 0;
  3584. }
  3585. if (np->tx_rings) {
  3586. for (i = 0; i < np->num_tx_rings; i++) {
  3587. struct tx_ring_info *rp = &np->tx_rings[i];
  3588. niu_free_tx_ring_info(np, rp);
  3589. }
  3590. kfree(np->tx_rings);
  3591. np->tx_rings = NULL;
  3592. np->num_tx_rings = 0;
  3593. }
  3594. }
  3595. static int niu_alloc_rx_ring_info(struct niu *np,
  3596. struct rx_ring_info *rp)
  3597. {
  3598. BUILD_BUG_ON(sizeof(struct rxdma_mailbox) != 64);
  3599. rp->rxhash = kzalloc_objs(struct page *, MAX_RBR_RING_SIZE);
  3600. if (!rp->rxhash)
  3601. return -ENOMEM;
  3602. rp->mbox = np->ops->alloc_coherent(np->device,
  3603. sizeof(struct rxdma_mailbox),
  3604. &rp->mbox_dma, GFP_KERNEL);
  3605. if (!rp->mbox)
  3606. return -ENOMEM;
  3607. if ((unsigned long)rp->mbox & (64UL - 1)) {
  3608. netdev_err(np->dev, "Coherent alloc gives misaligned RXDMA mailbox %p\n",
  3609. rp->mbox);
  3610. return -EINVAL;
  3611. }
  3612. rp->rcr = np->ops->alloc_coherent(np->device,
  3613. MAX_RCR_RING_SIZE * sizeof(__le64),
  3614. &rp->rcr_dma, GFP_KERNEL);
  3615. if (!rp->rcr)
  3616. return -ENOMEM;
  3617. if ((unsigned long)rp->rcr & (64UL - 1)) {
  3618. netdev_err(np->dev, "Coherent alloc gives misaligned RXDMA RCR table %p\n",
  3619. rp->rcr);
  3620. return -EINVAL;
  3621. }
  3622. rp->rcr_table_size = MAX_RCR_RING_SIZE;
  3623. rp->rcr_index = 0;
  3624. rp->rbr = np->ops->alloc_coherent(np->device,
  3625. MAX_RBR_RING_SIZE * sizeof(__le32),
  3626. &rp->rbr_dma, GFP_KERNEL);
  3627. if (!rp->rbr)
  3628. return -ENOMEM;
  3629. if ((unsigned long)rp->rbr & (64UL - 1)) {
  3630. netdev_err(np->dev, "Coherent alloc gives misaligned RXDMA RBR table %p\n",
  3631. rp->rbr);
  3632. return -EINVAL;
  3633. }
  3634. rp->rbr_table_size = MAX_RBR_RING_SIZE;
  3635. rp->rbr_index = 0;
  3636. rp->rbr_pending = 0;
  3637. return 0;
  3638. }
  3639. static void niu_set_max_burst(struct niu *np, struct tx_ring_info *rp)
  3640. {
  3641. int mtu = np->dev->mtu;
  3642. /* These values are recommended by the HW designers for fair
  3643. * utilization of DRR amongst the rings.
  3644. */
  3645. rp->max_burst = mtu + 32;
  3646. if (rp->max_burst > 4096)
  3647. rp->max_burst = 4096;
  3648. }
  3649. static int niu_alloc_tx_ring_info(struct niu *np,
  3650. struct tx_ring_info *rp)
  3651. {
  3652. BUILD_BUG_ON(sizeof(struct txdma_mailbox) != 64);
  3653. rp->mbox = np->ops->alloc_coherent(np->device,
  3654. sizeof(struct txdma_mailbox),
  3655. &rp->mbox_dma, GFP_KERNEL);
  3656. if (!rp->mbox)
  3657. return -ENOMEM;
  3658. if ((unsigned long)rp->mbox & (64UL - 1)) {
  3659. netdev_err(np->dev, "Coherent alloc gives misaligned TXDMA mailbox %p\n",
  3660. rp->mbox);
  3661. return -EINVAL;
  3662. }
  3663. rp->descr = np->ops->alloc_coherent(np->device,
  3664. MAX_TX_RING_SIZE * sizeof(__le64),
  3665. &rp->descr_dma, GFP_KERNEL);
  3666. if (!rp->descr)
  3667. return -ENOMEM;
  3668. if ((unsigned long)rp->descr & (64UL - 1)) {
  3669. netdev_err(np->dev, "Coherent alloc gives misaligned TXDMA descr table %p\n",
  3670. rp->descr);
  3671. return -EINVAL;
  3672. }
  3673. rp->pending = MAX_TX_RING_SIZE;
  3674. rp->prod = 0;
  3675. rp->cons = 0;
  3676. rp->wrap_bit = 0;
  3677. /* XXX make these configurable... XXX */
  3678. rp->mark_freq = rp->pending / 4;
  3679. niu_set_max_burst(np, rp);
  3680. return 0;
  3681. }
  3682. static void niu_size_rbr(struct niu *np, struct rx_ring_info *rp)
  3683. {
  3684. u16 bss;
  3685. bss = min(PAGE_SHIFT, 15);
  3686. rp->rbr_block_size = 1 << bss;
  3687. rp->rbr_blocks_per_page = 1 << (PAGE_SHIFT-bss);
  3688. rp->rbr_sizes[0] = 256;
  3689. rp->rbr_sizes[1] = 1024;
  3690. if (np->dev->mtu > ETH_DATA_LEN) {
  3691. switch (PAGE_SIZE) {
  3692. case 4 * 1024:
  3693. rp->rbr_sizes[2] = 4096;
  3694. break;
  3695. default:
  3696. rp->rbr_sizes[2] = 8192;
  3697. break;
  3698. }
  3699. } else {
  3700. rp->rbr_sizes[2] = 2048;
  3701. }
  3702. rp->rbr_sizes[3] = rp->rbr_block_size;
  3703. }
  3704. static int niu_alloc_channels(struct niu *np)
  3705. {
  3706. struct niu_parent *parent = np->parent;
  3707. int first_rx_channel, first_tx_channel;
  3708. int num_rx_rings, num_tx_rings;
  3709. struct rx_ring_info *rx_rings;
  3710. struct tx_ring_info *tx_rings;
  3711. int i, port, err;
  3712. port = np->port;
  3713. first_rx_channel = first_tx_channel = 0;
  3714. for (i = 0; i < port; i++) {
  3715. first_rx_channel += parent->rxchan_per_port[i];
  3716. first_tx_channel += parent->txchan_per_port[i];
  3717. }
  3718. num_rx_rings = parent->rxchan_per_port[port];
  3719. num_tx_rings = parent->txchan_per_port[port];
  3720. rx_rings = kzalloc_objs(struct rx_ring_info, num_rx_rings);
  3721. err = -ENOMEM;
  3722. if (!rx_rings)
  3723. goto out_err;
  3724. np->num_rx_rings = num_rx_rings;
  3725. smp_wmb();
  3726. np->rx_rings = rx_rings;
  3727. netif_set_real_num_rx_queues(np->dev, num_rx_rings);
  3728. for (i = 0; i < np->num_rx_rings; i++) {
  3729. struct rx_ring_info *rp = &np->rx_rings[i];
  3730. rp->np = np;
  3731. rp->rx_channel = first_rx_channel + i;
  3732. err = niu_alloc_rx_ring_info(np, rp);
  3733. if (err)
  3734. goto out_err;
  3735. niu_size_rbr(np, rp);
  3736. /* XXX better defaults, configurable, etc... XXX */
  3737. rp->nonsyn_window = 64;
  3738. rp->nonsyn_threshold = rp->rcr_table_size - 64;
  3739. rp->syn_window = 64;
  3740. rp->syn_threshold = rp->rcr_table_size - 64;
  3741. rp->rcr_pkt_threshold = 16;
  3742. rp->rcr_timeout = 8;
  3743. rp->rbr_kick_thresh = RBR_REFILL_MIN;
  3744. if (rp->rbr_kick_thresh < rp->rbr_blocks_per_page)
  3745. rp->rbr_kick_thresh = rp->rbr_blocks_per_page;
  3746. err = niu_rbr_fill(np, rp, GFP_KERNEL);
  3747. if (err)
  3748. goto out_err;
  3749. }
  3750. tx_rings = kzalloc_objs(struct tx_ring_info, num_tx_rings);
  3751. err = -ENOMEM;
  3752. if (!tx_rings)
  3753. goto out_err;
  3754. np->num_tx_rings = num_tx_rings;
  3755. smp_wmb();
  3756. np->tx_rings = tx_rings;
  3757. netif_set_real_num_tx_queues(np->dev, num_tx_rings);
  3758. for (i = 0; i < np->num_tx_rings; i++) {
  3759. struct tx_ring_info *rp = &np->tx_rings[i];
  3760. rp->np = np;
  3761. rp->tx_channel = first_tx_channel + i;
  3762. err = niu_alloc_tx_ring_info(np, rp);
  3763. if (err)
  3764. goto out_err;
  3765. }
  3766. return 0;
  3767. out_err:
  3768. niu_free_channels(np);
  3769. return err;
  3770. }
  3771. static int niu_tx_cs_sng_poll(struct niu *np, int channel)
  3772. {
  3773. int limit = 1000;
  3774. while (--limit > 0) {
  3775. u64 val = nr64(TX_CS(channel));
  3776. if (val & TX_CS_SNG_STATE)
  3777. return 0;
  3778. }
  3779. return -ENODEV;
  3780. }
  3781. static int niu_tx_channel_stop(struct niu *np, int channel)
  3782. {
  3783. u64 val = nr64(TX_CS(channel));
  3784. val |= TX_CS_STOP_N_GO;
  3785. nw64(TX_CS(channel), val);
  3786. return niu_tx_cs_sng_poll(np, channel);
  3787. }
  3788. static int niu_tx_cs_reset_poll(struct niu *np, int channel)
  3789. {
  3790. int limit = 1000;
  3791. while (--limit > 0) {
  3792. u64 val = nr64(TX_CS(channel));
  3793. if (!(val & TX_CS_RST))
  3794. return 0;
  3795. }
  3796. return -ENODEV;
  3797. }
  3798. static int niu_tx_channel_reset(struct niu *np, int channel)
  3799. {
  3800. u64 val = nr64(TX_CS(channel));
  3801. int err;
  3802. val |= TX_CS_RST;
  3803. nw64(TX_CS(channel), val);
  3804. err = niu_tx_cs_reset_poll(np, channel);
  3805. if (!err)
  3806. nw64(TX_RING_KICK(channel), 0);
  3807. return err;
  3808. }
  3809. static int niu_tx_channel_lpage_init(struct niu *np, int channel)
  3810. {
  3811. u64 val;
  3812. nw64(TX_LOG_MASK1(channel), 0);
  3813. nw64(TX_LOG_VAL1(channel), 0);
  3814. nw64(TX_LOG_MASK2(channel), 0);
  3815. nw64(TX_LOG_VAL2(channel), 0);
  3816. nw64(TX_LOG_PAGE_RELO1(channel), 0);
  3817. nw64(TX_LOG_PAGE_RELO2(channel), 0);
  3818. nw64(TX_LOG_PAGE_HDL(channel), 0);
  3819. val = (u64)np->port << TX_LOG_PAGE_VLD_FUNC_SHIFT;
  3820. val |= (TX_LOG_PAGE_VLD_PAGE0 | TX_LOG_PAGE_VLD_PAGE1);
  3821. nw64(TX_LOG_PAGE_VLD(channel), val);
  3822. /* XXX TXDMA 32bit mode? XXX */
  3823. return 0;
  3824. }
  3825. static void niu_txc_enable_port(struct niu *np, int on)
  3826. {
  3827. unsigned long flags;
  3828. u64 val, mask;
  3829. niu_lock_parent(np, flags);
  3830. val = nr64(TXC_CONTROL);
  3831. mask = (u64)1 << np->port;
  3832. if (on) {
  3833. val |= TXC_CONTROL_ENABLE | mask;
  3834. } else {
  3835. val &= ~mask;
  3836. if ((val & ~TXC_CONTROL_ENABLE) == 0)
  3837. val &= ~TXC_CONTROL_ENABLE;
  3838. }
  3839. nw64(TXC_CONTROL, val);
  3840. niu_unlock_parent(np, flags);
  3841. }
  3842. static void niu_txc_set_imask(struct niu *np, u64 imask)
  3843. {
  3844. unsigned long flags;
  3845. u64 val;
  3846. niu_lock_parent(np, flags);
  3847. val = nr64(TXC_INT_MASK);
  3848. val &= ~TXC_INT_MASK_VAL(np->port);
  3849. val |= (imask << TXC_INT_MASK_VAL_SHIFT(np->port));
  3850. niu_unlock_parent(np, flags);
  3851. }
  3852. static void niu_txc_port_dma_enable(struct niu *np, int on)
  3853. {
  3854. u64 val = 0;
  3855. if (on) {
  3856. int i;
  3857. for (i = 0; i < np->num_tx_rings; i++)
  3858. val |= (1 << np->tx_rings[i].tx_channel);
  3859. }
  3860. nw64(TXC_PORT_DMA(np->port), val);
  3861. }
  3862. static int niu_init_one_tx_channel(struct niu *np, struct tx_ring_info *rp)
  3863. {
  3864. int err, channel = rp->tx_channel;
  3865. u64 val, ring_len;
  3866. err = niu_tx_channel_stop(np, channel);
  3867. if (err)
  3868. return err;
  3869. err = niu_tx_channel_reset(np, channel);
  3870. if (err)
  3871. return err;
  3872. err = niu_tx_channel_lpage_init(np, channel);
  3873. if (err)
  3874. return err;
  3875. nw64(TXC_DMA_MAX(channel), rp->max_burst);
  3876. nw64(TX_ENT_MSK(channel), 0);
  3877. if (rp->descr_dma & ~(TX_RNG_CFIG_STADDR_BASE |
  3878. TX_RNG_CFIG_STADDR)) {
  3879. netdev_err(np->dev, "TX ring channel %d DMA addr (%llx) is not aligned\n",
  3880. channel, (unsigned long long)rp->descr_dma);
  3881. return -EINVAL;
  3882. }
  3883. /* The length field in TX_RNG_CFIG is measured in 64-byte
  3884. * blocks. rp->pending is the number of TX descriptors in
  3885. * our ring, 8 bytes each, thus we divide by 8 bytes more
  3886. * to get the proper value the chip wants.
  3887. */
  3888. ring_len = (rp->pending / 8);
  3889. val = ((ring_len << TX_RNG_CFIG_LEN_SHIFT) |
  3890. rp->descr_dma);
  3891. nw64(TX_RNG_CFIG(channel), val);
  3892. if (((rp->mbox_dma >> 32) & ~TXDMA_MBH_MBADDR) ||
  3893. ((u32)rp->mbox_dma & ~TXDMA_MBL_MBADDR)) {
  3894. netdev_err(np->dev, "TX ring channel %d MBOX addr (%llx) has invalid bits\n",
  3895. channel, (unsigned long long)rp->mbox_dma);
  3896. return -EINVAL;
  3897. }
  3898. nw64(TXDMA_MBH(channel), rp->mbox_dma >> 32);
  3899. nw64(TXDMA_MBL(channel), rp->mbox_dma & TXDMA_MBL_MBADDR);
  3900. nw64(TX_CS(channel), 0);
  3901. rp->last_pkt_cnt = 0;
  3902. return 0;
  3903. }
  3904. static void niu_init_rdc_groups(struct niu *np)
  3905. {
  3906. struct niu_rdc_tables *tp = &np->parent->rdc_group_cfg[np->port];
  3907. int i, first_table_num = tp->first_table_num;
  3908. for (i = 0; i < tp->num_tables; i++) {
  3909. struct rdc_table *tbl = &tp->tables[i];
  3910. int this_table = first_table_num + i;
  3911. int slot;
  3912. for (slot = 0; slot < NIU_RDC_TABLE_SLOTS; slot++)
  3913. nw64(RDC_TBL(this_table, slot),
  3914. tbl->rxdma_channel[slot]);
  3915. }
  3916. nw64(DEF_RDC(np->port), np->parent->rdc_default[np->port]);
  3917. }
  3918. static void niu_init_drr_weight(struct niu *np)
  3919. {
  3920. int type = phy_decode(np->parent->port_phy, np->port);
  3921. u64 val;
  3922. switch (type) {
  3923. case PORT_TYPE_10G:
  3924. val = PT_DRR_WEIGHT_DEFAULT_10G;
  3925. break;
  3926. case PORT_TYPE_1G:
  3927. default:
  3928. val = PT_DRR_WEIGHT_DEFAULT_1G;
  3929. break;
  3930. }
  3931. nw64(PT_DRR_WT(np->port), val);
  3932. }
  3933. static int niu_init_hostinfo(struct niu *np)
  3934. {
  3935. struct niu_parent *parent = np->parent;
  3936. struct niu_rdc_tables *tp = &parent->rdc_group_cfg[np->port];
  3937. int i, err, num_alt = niu_num_alt_addr(np);
  3938. int first_rdc_table = tp->first_table_num;
  3939. err = niu_set_primary_mac_rdc_table(np, first_rdc_table, 1);
  3940. if (err)
  3941. return err;
  3942. err = niu_set_multicast_mac_rdc_table(np, first_rdc_table, 1);
  3943. if (err)
  3944. return err;
  3945. for (i = 0; i < num_alt; i++) {
  3946. err = niu_set_alt_mac_rdc_table(np, i, first_rdc_table, 1);
  3947. if (err)
  3948. return err;
  3949. }
  3950. return 0;
  3951. }
  3952. static int niu_rx_channel_reset(struct niu *np, int channel)
  3953. {
  3954. return niu_set_and_wait_clear(np, RXDMA_CFIG1(channel),
  3955. RXDMA_CFIG1_RST, 1000, 10,
  3956. "RXDMA_CFIG1");
  3957. }
  3958. static int niu_rx_channel_lpage_init(struct niu *np, int channel)
  3959. {
  3960. u64 val;
  3961. nw64(RX_LOG_MASK1(channel), 0);
  3962. nw64(RX_LOG_VAL1(channel), 0);
  3963. nw64(RX_LOG_MASK2(channel), 0);
  3964. nw64(RX_LOG_VAL2(channel), 0);
  3965. nw64(RX_LOG_PAGE_RELO1(channel), 0);
  3966. nw64(RX_LOG_PAGE_RELO2(channel), 0);
  3967. nw64(RX_LOG_PAGE_HDL(channel), 0);
  3968. val = (u64)np->port << RX_LOG_PAGE_VLD_FUNC_SHIFT;
  3969. val |= (RX_LOG_PAGE_VLD_PAGE0 | RX_LOG_PAGE_VLD_PAGE1);
  3970. nw64(RX_LOG_PAGE_VLD(channel), val);
  3971. return 0;
  3972. }
  3973. static void niu_rx_channel_wred_init(struct niu *np, struct rx_ring_info *rp)
  3974. {
  3975. u64 val;
  3976. val = (((u64)rp->nonsyn_window << RDC_RED_PARA_WIN_SHIFT) |
  3977. ((u64)rp->nonsyn_threshold << RDC_RED_PARA_THRE_SHIFT) |
  3978. ((u64)rp->syn_window << RDC_RED_PARA_WIN_SYN_SHIFT) |
  3979. ((u64)rp->syn_threshold << RDC_RED_PARA_THRE_SYN_SHIFT));
  3980. nw64(RDC_RED_PARA(rp->rx_channel), val);
  3981. }
  3982. static int niu_compute_rbr_cfig_b(struct rx_ring_info *rp, u64 *ret)
  3983. {
  3984. u64 val = 0;
  3985. *ret = 0;
  3986. switch (rp->rbr_block_size) {
  3987. case 4 * 1024:
  3988. val |= (RBR_BLKSIZE_4K << RBR_CFIG_B_BLKSIZE_SHIFT);
  3989. break;
  3990. case 8 * 1024:
  3991. val |= (RBR_BLKSIZE_8K << RBR_CFIG_B_BLKSIZE_SHIFT);
  3992. break;
  3993. case 16 * 1024:
  3994. val |= (RBR_BLKSIZE_16K << RBR_CFIG_B_BLKSIZE_SHIFT);
  3995. break;
  3996. case 32 * 1024:
  3997. val |= (RBR_BLKSIZE_32K << RBR_CFIG_B_BLKSIZE_SHIFT);
  3998. break;
  3999. default:
  4000. return -EINVAL;
  4001. }
  4002. val |= RBR_CFIG_B_VLD2;
  4003. switch (rp->rbr_sizes[2]) {
  4004. case 2 * 1024:
  4005. val |= (RBR_BUFSZ2_2K << RBR_CFIG_B_BUFSZ2_SHIFT);
  4006. break;
  4007. case 4 * 1024:
  4008. val |= (RBR_BUFSZ2_4K << RBR_CFIG_B_BUFSZ2_SHIFT);
  4009. break;
  4010. case 8 * 1024:
  4011. val |= (RBR_BUFSZ2_8K << RBR_CFIG_B_BUFSZ2_SHIFT);
  4012. break;
  4013. case 16 * 1024:
  4014. val |= (RBR_BUFSZ2_16K << RBR_CFIG_B_BUFSZ2_SHIFT);
  4015. break;
  4016. default:
  4017. return -EINVAL;
  4018. }
  4019. val |= RBR_CFIG_B_VLD1;
  4020. switch (rp->rbr_sizes[1]) {
  4021. case 1 * 1024:
  4022. val |= (RBR_BUFSZ1_1K << RBR_CFIG_B_BUFSZ1_SHIFT);
  4023. break;
  4024. case 2 * 1024:
  4025. val |= (RBR_BUFSZ1_2K << RBR_CFIG_B_BUFSZ1_SHIFT);
  4026. break;
  4027. case 4 * 1024:
  4028. val |= (RBR_BUFSZ1_4K << RBR_CFIG_B_BUFSZ1_SHIFT);
  4029. break;
  4030. case 8 * 1024:
  4031. val |= (RBR_BUFSZ1_8K << RBR_CFIG_B_BUFSZ1_SHIFT);
  4032. break;
  4033. default:
  4034. return -EINVAL;
  4035. }
  4036. val |= RBR_CFIG_B_VLD0;
  4037. switch (rp->rbr_sizes[0]) {
  4038. case 256:
  4039. val |= (RBR_BUFSZ0_256 << RBR_CFIG_B_BUFSZ0_SHIFT);
  4040. break;
  4041. case 512:
  4042. val |= (RBR_BUFSZ0_512 << RBR_CFIG_B_BUFSZ0_SHIFT);
  4043. break;
  4044. case 1 * 1024:
  4045. val |= (RBR_BUFSZ0_1K << RBR_CFIG_B_BUFSZ0_SHIFT);
  4046. break;
  4047. case 2 * 1024:
  4048. val |= (RBR_BUFSZ0_2K << RBR_CFIG_B_BUFSZ0_SHIFT);
  4049. break;
  4050. default:
  4051. return -EINVAL;
  4052. }
  4053. *ret = val;
  4054. return 0;
  4055. }
  4056. static int niu_enable_rx_channel(struct niu *np, int channel, int on)
  4057. {
  4058. u64 val = nr64(RXDMA_CFIG1(channel));
  4059. int limit;
  4060. if (on)
  4061. val |= RXDMA_CFIG1_EN;
  4062. else
  4063. val &= ~RXDMA_CFIG1_EN;
  4064. nw64(RXDMA_CFIG1(channel), val);
  4065. limit = 1000;
  4066. while (--limit > 0) {
  4067. if (nr64(RXDMA_CFIG1(channel)) & RXDMA_CFIG1_QST)
  4068. break;
  4069. udelay(10);
  4070. }
  4071. if (limit <= 0)
  4072. return -ENODEV;
  4073. return 0;
  4074. }
  4075. static int niu_init_one_rx_channel(struct niu *np, struct rx_ring_info *rp)
  4076. {
  4077. int err, channel = rp->rx_channel;
  4078. u64 val;
  4079. err = niu_rx_channel_reset(np, channel);
  4080. if (err)
  4081. return err;
  4082. err = niu_rx_channel_lpage_init(np, channel);
  4083. if (err)
  4084. return err;
  4085. niu_rx_channel_wred_init(np, rp);
  4086. nw64(RX_DMA_ENT_MSK(channel), RX_DMA_ENT_MSK_RBR_EMPTY);
  4087. nw64(RX_DMA_CTL_STAT(channel),
  4088. (RX_DMA_CTL_STAT_MEX |
  4089. RX_DMA_CTL_STAT_RCRTHRES |
  4090. RX_DMA_CTL_STAT_RCRTO |
  4091. RX_DMA_CTL_STAT_RBR_EMPTY));
  4092. nw64(RXDMA_CFIG1(channel), rp->mbox_dma >> 32);
  4093. nw64(RXDMA_CFIG2(channel),
  4094. ((rp->mbox_dma & RXDMA_CFIG2_MBADDR_L) |
  4095. RXDMA_CFIG2_FULL_HDR));
  4096. nw64(RBR_CFIG_A(channel),
  4097. ((u64)rp->rbr_table_size << RBR_CFIG_A_LEN_SHIFT) |
  4098. (rp->rbr_dma & (RBR_CFIG_A_STADDR_BASE | RBR_CFIG_A_STADDR)));
  4099. err = niu_compute_rbr_cfig_b(rp, &val);
  4100. if (err)
  4101. return err;
  4102. nw64(RBR_CFIG_B(channel), val);
  4103. nw64(RCRCFIG_A(channel),
  4104. ((u64)rp->rcr_table_size << RCRCFIG_A_LEN_SHIFT) |
  4105. (rp->rcr_dma & (RCRCFIG_A_STADDR_BASE | RCRCFIG_A_STADDR)));
  4106. nw64(RCRCFIG_B(channel),
  4107. ((u64)rp->rcr_pkt_threshold << RCRCFIG_B_PTHRES_SHIFT) |
  4108. RCRCFIG_B_ENTOUT |
  4109. ((u64)rp->rcr_timeout << RCRCFIG_B_TIMEOUT_SHIFT));
  4110. err = niu_enable_rx_channel(np, channel, 1);
  4111. if (err)
  4112. return err;
  4113. nw64(RBR_KICK(channel), rp->rbr_index);
  4114. val = nr64(RX_DMA_CTL_STAT(channel));
  4115. val |= RX_DMA_CTL_STAT_RBR_EMPTY;
  4116. nw64(RX_DMA_CTL_STAT(channel), val);
  4117. return 0;
  4118. }
  4119. static int niu_init_rx_channels(struct niu *np)
  4120. {
  4121. unsigned long flags;
  4122. u64 seed = jiffies_64;
  4123. int err, i;
  4124. niu_lock_parent(np, flags);
  4125. nw64(RX_DMA_CK_DIV, np->parent->rxdma_clock_divider);
  4126. nw64(RED_RAN_INIT, RED_RAN_INIT_OPMODE | (seed & RED_RAN_INIT_VAL));
  4127. niu_unlock_parent(np, flags);
  4128. /* XXX RXDMA 32bit mode? XXX */
  4129. niu_init_rdc_groups(np);
  4130. niu_init_drr_weight(np);
  4131. err = niu_init_hostinfo(np);
  4132. if (err)
  4133. return err;
  4134. for (i = 0; i < np->num_rx_rings; i++) {
  4135. struct rx_ring_info *rp = &np->rx_rings[i];
  4136. err = niu_init_one_rx_channel(np, rp);
  4137. if (err)
  4138. return err;
  4139. }
  4140. return 0;
  4141. }
  4142. static int niu_set_ip_frag_rule(struct niu *np)
  4143. {
  4144. struct niu_parent *parent = np->parent;
  4145. struct niu_classifier *cp = &np->clas;
  4146. struct niu_tcam_entry *tp;
  4147. int index, err;
  4148. index = cp->tcam_top;
  4149. tp = &parent->tcam[index];
  4150. /* Note that the noport bit is the same in both ipv4 and
  4151. * ipv6 format TCAM entries.
  4152. */
  4153. memset(tp, 0, sizeof(*tp));
  4154. tp->key[1] = TCAM_V4KEY1_NOPORT;
  4155. tp->key_mask[1] = TCAM_V4KEY1_NOPORT;
  4156. tp->assoc_data = (TCAM_ASSOCDATA_TRES_USE_OFFSET |
  4157. ((u64)0 << TCAM_ASSOCDATA_OFFSET_SHIFT));
  4158. err = tcam_write(np, index, tp->key, tp->key_mask);
  4159. if (err)
  4160. return err;
  4161. err = tcam_assoc_write(np, index, tp->assoc_data);
  4162. if (err)
  4163. return err;
  4164. tp->valid = 1;
  4165. cp->tcam_valid_entries++;
  4166. return 0;
  4167. }
  4168. static int niu_init_classifier_hw(struct niu *np)
  4169. {
  4170. struct niu_parent *parent = np->parent;
  4171. struct niu_classifier *cp = &np->clas;
  4172. int i, err;
  4173. nw64(H1POLY, cp->h1_init);
  4174. nw64(H2POLY, cp->h2_init);
  4175. err = niu_init_hostinfo(np);
  4176. if (err)
  4177. return err;
  4178. for (i = 0; i < ENET_VLAN_TBL_NUM_ENTRIES; i++) {
  4179. struct niu_vlan_rdc *vp = &cp->vlan_mappings[i];
  4180. vlan_tbl_write(np, i, np->port,
  4181. vp->vlan_pref, vp->rdc_num);
  4182. }
  4183. for (i = 0; i < cp->num_alt_mac_mappings; i++) {
  4184. struct niu_altmac_rdc *ap = &cp->alt_mac_mappings[i];
  4185. err = niu_set_alt_mac_rdc_table(np, ap->alt_mac_num,
  4186. ap->rdc_num, ap->mac_pref);
  4187. if (err)
  4188. return err;
  4189. }
  4190. for (i = CLASS_CODE_USER_PROG1; i <= CLASS_CODE_SCTP_IPV6; i++) {
  4191. int index = i - CLASS_CODE_USER_PROG1;
  4192. err = niu_set_tcam_key(np, i, parent->tcam_key[index]);
  4193. if (err)
  4194. return err;
  4195. err = niu_set_flow_key(np, i, parent->flow_key[index]);
  4196. if (err)
  4197. return err;
  4198. }
  4199. err = niu_set_ip_frag_rule(np);
  4200. if (err)
  4201. return err;
  4202. tcam_enable(np, 1);
  4203. return 0;
  4204. }
  4205. static int niu_zcp_write(struct niu *np, int index, u64 *data)
  4206. {
  4207. nw64(ZCP_RAM_DATA0, data[0]);
  4208. nw64(ZCP_RAM_DATA1, data[1]);
  4209. nw64(ZCP_RAM_DATA2, data[2]);
  4210. nw64(ZCP_RAM_DATA3, data[3]);
  4211. nw64(ZCP_RAM_DATA4, data[4]);
  4212. nw64(ZCP_RAM_BE, ZCP_RAM_BE_VAL);
  4213. nw64(ZCP_RAM_ACC,
  4214. (ZCP_RAM_ACC_WRITE |
  4215. (0 << ZCP_RAM_ACC_ZFCID_SHIFT) |
  4216. (ZCP_RAM_SEL_CFIFO(np->port) << ZCP_RAM_ACC_RAM_SEL_SHIFT)));
  4217. return niu_wait_bits_clear(np, ZCP_RAM_ACC, ZCP_RAM_ACC_BUSY,
  4218. 1000, 100);
  4219. }
  4220. static int niu_zcp_read(struct niu *np, int index, u64 *data)
  4221. {
  4222. int err;
  4223. err = niu_wait_bits_clear(np, ZCP_RAM_ACC, ZCP_RAM_ACC_BUSY,
  4224. 1000, 100);
  4225. if (err) {
  4226. netdev_err(np->dev, "ZCP read busy won't clear, ZCP_RAM_ACC[%llx]\n",
  4227. (unsigned long long)nr64(ZCP_RAM_ACC));
  4228. return err;
  4229. }
  4230. nw64(ZCP_RAM_ACC,
  4231. (ZCP_RAM_ACC_READ |
  4232. (0 << ZCP_RAM_ACC_ZFCID_SHIFT) |
  4233. (ZCP_RAM_SEL_CFIFO(np->port) << ZCP_RAM_ACC_RAM_SEL_SHIFT)));
  4234. err = niu_wait_bits_clear(np, ZCP_RAM_ACC, ZCP_RAM_ACC_BUSY,
  4235. 1000, 100);
  4236. if (err) {
  4237. netdev_err(np->dev, "ZCP read busy2 won't clear, ZCP_RAM_ACC[%llx]\n",
  4238. (unsigned long long)nr64(ZCP_RAM_ACC));
  4239. return err;
  4240. }
  4241. data[0] = nr64(ZCP_RAM_DATA0);
  4242. data[1] = nr64(ZCP_RAM_DATA1);
  4243. data[2] = nr64(ZCP_RAM_DATA2);
  4244. data[3] = nr64(ZCP_RAM_DATA3);
  4245. data[4] = nr64(ZCP_RAM_DATA4);
  4246. return 0;
  4247. }
  4248. static void niu_zcp_cfifo_reset(struct niu *np)
  4249. {
  4250. u64 val = nr64(RESET_CFIFO);
  4251. val |= RESET_CFIFO_RST(np->port);
  4252. nw64(RESET_CFIFO, val);
  4253. udelay(10);
  4254. val &= ~RESET_CFIFO_RST(np->port);
  4255. nw64(RESET_CFIFO, val);
  4256. }
  4257. static int niu_init_zcp(struct niu *np)
  4258. {
  4259. u64 data[5], rbuf[5];
  4260. int i, max, err;
  4261. if (np->parent->plat_type != PLAT_TYPE_NIU) {
  4262. if (np->port == 0 || np->port == 1)
  4263. max = ATLAS_P0_P1_CFIFO_ENTRIES;
  4264. else
  4265. max = ATLAS_P2_P3_CFIFO_ENTRIES;
  4266. } else
  4267. max = NIU_CFIFO_ENTRIES;
  4268. data[0] = 0;
  4269. data[1] = 0;
  4270. data[2] = 0;
  4271. data[3] = 0;
  4272. data[4] = 0;
  4273. for (i = 0; i < max; i++) {
  4274. err = niu_zcp_write(np, i, data);
  4275. if (err)
  4276. return err;
  4277. err = niu_zcp_read(np, i, rbuf);
  4278. if (err)
  4279. return err;
  4280. }
  4281. niu_zcp_cfifo_reset(np);
  4282. nw64(CFIFO_ECC(np->port), 0);
  4283. nw64(ZCP_INT_STAT, ZCP_INT_STAT_ALL);
  4284. (void) nr64(ZCP_INT_STAT);
  4285. nw64(ZCP_INT_MASK, ZCP_INT_MASK_ALL);
  4286. return 0;
  4287. }
  4288. static void niu_ipp_write(struct niu *np, int index, u64 *data)
  4289. {
  4290. u64 val = nr64_ipp(IPP_CFIG);
  4291. nw64_ipp(IPP_CFIG, val | IPP_CFIG_DFIFO_PIO_W);
  4292. nw64_ipp(IPP_DFIFO_WR_PTR, index);
  4293. nw64_ipp(IPP_DFIFO_WR0, data[0]);
  4294. nw64_ipp(IPP_DFIFO_WR1, data[1]);
  4295. nw64_ipp(IPP_DFIFO_WR2, data[2]);
  4296. nw64_ipp(IPP_DFIFO_WR3, data[3]);
  4297. nw64_ipp(IPP_DFIFO_WR4, data[4]);
  4298. nw64_ipp(IPP_CFIG, val & ~IPP_CFIG_DFIFO_PIO_W);
  4299. }
  4300. static void niu_ipp_read(struct niu *np, int index, u64 *data)
  4301. {
  4302. nw64_ipp(IPP_DFIFO_RD_PTR, index);
  4303. data[0] = nr64_ipp(IPP_DFIFO_RD0);
  4304. data[1] = nr64_ipp(IPP_DFIFO_RD1);
  4305. data[2] = nr64_ipp(IPP_DFIFO_RD2);
  4306. data[3] = nr64_ipp(IPP_DFIFO_RD3);
  4307. data[4] = nr64_ipp(IPP_DFIFO_RD4);
  4308. }
  4309. static int niu_ipp_reset(struct niu *np)
  4310. {
  4311. return niu_set_and_wait_clear_ipp(np, IPP_CFIG, IPP_CFIG_SOFT_RST,
  4312. 1000, 100, "IPP_CFIG");
  4313. }
  4314. static int niu_init_ipp(struct niu *np)
  4315. {
  4316. u64 data[5], rbuf[5], val;
  4317. int i, max, err;
  4318. if (np->parent->plat_type != PLAT_TYPE_NIU) {
  4319. if (np->port == 0 || np->port == 1)
  4320. max = ATLAS_P0_P1_DFIFO_ENTRIES;
  4321. else
  4322. max = ATLAS_P2_P3_DFIFO_ENTRIES;
  4323. } else
  4324. max = NIU_DFIFO_ENTRIES;
  4325. data[0] = 0;
  4326. data[1] = 0;
  4327. data[2] = 0;
  4328. data[3] = 0;
  4329. data[4] = 0;
  4330. for (i = 0; i < max; i++) {
  4331. niu_ipp_write(np, i, data);
  4332. niu_ipp_read(np, i, rbuf);
  4333. }
  4334. (void) nr64_ipp(IPP_INT_STAT);
  4335. (void) nr64_ipp(IPP_INT_STAT);
  4336. err = niu_ipp_reset(np);
  4337. if (err)
  4338. return err;
  4339. (void) nr64_ipp(IPP_PKT_DIS);
  4340. (void) nr64_ipp(IPP_BAD_CS_CNT);
  4341. (void) nr64_ipp(IPP_ECC);
  4342. (void) nr64_ipp(IPP_INT_STAT);
  4343. nw64_ipp(IPP_MSK, ~IPP_MSK_ALL);
  4344. val = nr64_ipp(IPP_CFIG);
  4345. val &= ~IPP_CFIG_IP_MAX_PKT;
  4346. val |= (IPP_CFIG_IPP_ENABLE |
  4347. IPP_CFIG_DFIFO_ECC_EN |
  4348. IPP_CFIG_DROP_BAD_CRC |
  4349. IPP_CFIG_CKSUM_EN |
  4350. (0x1ffff << IPP_CFIG_IP_MAX_PKT_SHIFT));
  4351. nw64_ipp(IPP_CFIG, val);
  4352. return 0;
  4353. }
  4354. static void niu_handle_led(struct niu *np, int status)
  4355. {
  4356. u64 val;
  4357. val = nr64_mac(XMAC_CONFIG);
  4358. if ((np->flags & NIU_FLAGS_10G) != 0 &&
  4359. (np->flags & NIU_FLAGS_FIBER) != 0) {
  4360. if (status) {
  4361. val |= XMAC_CONFIG_LED_POLARITY;
  4362. val &= ~XMAC_CONFIG_FORCE_LED_ON;
  4363. } else {
  4364. val |= XMAC_CONFIG_FORCE_LED_ON;
  4365. val &= ~XMAC_CONFIG_LED_POLARITY;
  4366. }
  4367. }
  4368. nw64_mac(XMAC_CONFIG, val);
  4369. }
  4370. static void niu_init_xif_xmac(struct niu *np)
  4371. {
  4372. struct niu_link_config *lp = &np->link_config;
  4373. u64 val;
  4374. if (np->flags & NIU_FLAGS_XCVR_SERDES) {
  4375. val = nr64(MIF_CONFIG);
  4376. val |= MIF_CONFIG_ATCA_GE;
  4377. nw64(MIF_CONFIG, val);
  4378. }
  4379. val = nr64_mac(XMAC_CONFIG);
  4380. val &= ~XMAC_CONFIG_SEL_POR_CLK_SRC;
  4381. val |= XMAC_CONFIG_TX_OUTPUT_EN;
  4382. if (lp->loopback_mode == LOOPBACK_MAC) {
  4383. val &= ~XMAC_CONFIG_SEL_POR_CLK_SRC;
  4384. val |= XMAC_CONFIG_LOOPBACK;
  4385. } else {
  4386. val &= ~XMAC_CONFIG_LOOPBACK;
  4387. }
  4388. if (np->flags & NIU_FLAGS_10G) {
  4389. val &= ~XMAC_CONFIG_LFS_DISABLE;
  4390. } else {
  4391. val |= XMAC_CONFIG_LFS_DISABLE;
  4392. if (!(np->flags & NIU_FLAGS_FIBER) &&
  4393. !(np->flags & NIU_FLAGS_XCVR_SERDES))
  4394. val |= XMAC_CONFIG_1G_PCS_BYPASS;
  4395. else
  4396. val &= ~XMAC_CONFIG_1G_PCS_BYPASS;
  4397. }
  4398. val &= ~XMAC_CONFIG_10G_XPCS_BYPASS;
  4399. if (lp->active_speed == SPEED_100)
  4400. val |= XMAC_CONFIG_SEL_CLK_25MHZ;
  4401. else
  4402. val &= ~XMAC_CONFIG_SEL_CLK_25MHZ;
  4403. nw64_mac(XMAC_CONFIG, val);
  4404. val = nr64_mac(XMAC_CONFIG);
  4405. val &= ~XMAC_CONFIG_MODE_MASK;
  4406. if (np->flags & NIU_FLAGS_10G) {
  4407. val |= XMAC_CONFIG_MODE_XGMII;
  4408. } else {
  4409. if (lp->active_speed == SPEED_1000)
  4410. val |= XMAC_CONFIG_MODE_GMII;
  4411. else
  4412. val |= XMAC_CONFIG_MODE_MII;
  4413. }
  4414. nw64_mac(XMAC_CONFIG, val);
  4415. }
  4416. static void niu_init_xif_bmac(struct niu *np)
  4417. {
  4418. struct niu_link_config *lp = &np->link_config;
  4419. u64 val;
  4420. val = BMAC_XIF_CONFIG_TX_OUTPUT_EN;
  4421. if (lp->loopback_mode == LOOPBACK_MAC)
  4422. val |= BMAC_XIF_CONFIG_MII_LOOPBACK;
  4423. else
  4424. val &= ~BMAC_XIF_CONFIG_MII_LOOPBACK;
  4425. if (lp->active_speed == SPEED_1000)
  4426. val |= BMAC_XIF_CONFIG_GMII_MODE;
  4427. else
  4428. val &= ~BMAC_XIF_CONFIG_GMII_MODE;
  4429. val &= ~(BMAC_XIF_CONFIG_LINK_LED |
  4430. BMAC_XIF_CONFIG_LED_POLARITY);
  4431. if (!(np->flags & NIU_FLAGS_10G) &&
  4432. !(np->flags & NIU_FLAGS_FIBER) &&
  4433. lp->active_speed == SPEED_100)
  4434. val |= BMAC_XIF_CONFIG_25MHZ_CLOCK;
  4435. else
  4436. val &= ~BMAC_XIF_CONFIG_25MHZ_CLOCK;
  4437. nw64_mac(BMAC_XIF_CONFIG, val);
  4438. }
  4439. static void niu_init_xif(struct niu *np)
  4440. {
  4441. if (np->flags & NIU_FLAGS_XMAC)
  4442. niu_init_xif_xmac(np);
  4443. else
  4444. niu_init_xif_bmac(np);
  4445. }
  4446. static void niu_pcs_mii_reset(struct niu *np)
  4447. {
  4448. int limit = 1000;
  4449. u64 val = nr64_pcs(PCS_MII_CTL);
  4450. val |= PCS_MII_CTL_RST;
  4451. nw64_pcs(PCS_MII_CTL, val);
  4452. while ((--limit >= 0) && (val & PCS_MII_CTL_RST)) {
  4453. udelay(100);
  4454. val = nr64_pcs(PCS_MII_CTL);
  4455. }
  4456. }
  4457. static void niu_xpcs_reset(struct niu *np)
  4458. {
  4459. int limit = 1000;
  4460. u64 val = nr64_xpcs(XPCS_CONTROL1);
  4461. val |= XPCS_CONTROL1_RESET;
  4462. nw64_xpcs(XPCS_CONTROL1, val);
  4463. while ((--limit >= 0) && (val & XPCS_CONTROL1_RESET)) {
  4464. udelay(100);
  4465. val = nr64_xpcs(XPCS_CONTROL1);
  4466. }
  4467. }
  4468. static int niu_init_pcs(struct niu *np)
  4469. {
  4470. struct niu_link_config *lp = &np->link_config;
  4471. u64 val;
  4472. switch (np->flags & (NIU_FLAGS_10G |
  4473. NIU_FLAGS_FIBER |
  4474. NIU_FLAGS_XCVR_SERDES)) {
  4475. case NIU_FLAGS_FIBER:
  4476. /* 1G fiber */
  4477. nw64_pcs(PCS_CONF, PCS_CONF_MASK | PCS_CONF_ENABLE);
  4478. nw64_pcs(PCS_DPATH_MODE, 0);
  4479. niu_pcs_mii_reset(np);
  4480. break;
  4481. case NIU_FLAGS_10G:
  4482. case NIU_FLAGS_10G | NIU_FLAGS_FIBER:
  4483. case NIU_FLAGS_10G | NIU_FLAGS_XCVR_SERDES:
  4484. /* 10G SERDES */
  4485. if (!(np->flags & NIU_FLAGS_XMAC))
  4486. return -EINVAL;
  4487. /* 10G copper or fiber */
  4488. val = nr64_mac(XMAC_CONFIG);
  4489. val &= ~XMAC_CONFIG_10G_XPCS_BYPASS;
  4490. nw64_mac(XMAC_CONFIG, val);
  4491. niu_xpcs_reset(np);
  4492. val = nr64_xpcs(XPCS_CONTROL1);
  4493. if (lp->loopback_mode == LOOPBACK_PHY)
  4494. val |= XPCS_CONTROL1_LOOPBACK;
  4495. else
  4496. val &= ~XPCS_CONTROL1_LOOPBACK;
  4497. nw64_xpcs(XPCS_CONTROL1, val);
  4498. nw64_xpcs(XPCS_DESKEW_ERR_CNT, 0);
  4499. (void) nr64_xpcs(XPCS_SYMERR_CNT01);
  4500. (void) nr64_xpcs(XPCS_SYMERR_CNT23);
  4501. break;
  4502. case NIU_FLAGS_XCVR_SERDES:
  4503. /* 1G SERDES */
  4504. niu_pcs_mii_reset(np);
  4505. nw64_pcs(PCS_CONF, PCS_CONF_MASK | PCS_CONF_ENABLE);
  4506. nw64_pcs(PCS_DPATH_MODE, 0);
  4507. break;
  4508. case 0:
  4509. /* 1G copper */
  4510. case NIU_FLAGS_XCVR_SERDES | NIU_FLAGS_FIBER:
  4511. /* 1G RGMII FIBER */
  4512. nw64_pcs(PCS_DPATH_MODE, PCS_DPATH_MODE_MII);
  4513. niu_pcs_mii_reset(np);
  4514. break;
  4515. default:
  4516. return -EINVAL;
  4517. }
  4518. return 0;
  4519. }
  4520. static int niu_reset_tx_xmac(struct niu *np)
  4521. {
  4522. return niu_set_and_wait_clear_mac(np, XTXMAC_SW_RST,
  4523. (XTXMAC_SW_RST_REG_RS |
  4524. XTXMAC_SW_RST_SOFT_RST),
  4525. 1000, 100, "XTXMAC_SW_RST");
  4526. }
  4527. static int niu_reset_tx_bmac(struct niu *np)
  4528. {
  4529. int limit;
  4530. nw64_mac(BTXMAC_SW_RST, BTXMAC_SW_RST_RESET);
  4531. limit = 1000;
  4532. while (--limit >= 0) {
  4533. if (!(nr64_mac(BTXMAC_SW_RST) & BTXMAC_SW_RST_RESET))
  4534. break;
  4535. udelay(100);
  4536. }
  4537. if (limit < 0) {
  4538. dev_err(np->device, "Port %u TX BMAC would not reset, BTXMAC_SW_RST[%llx]\n",
  4539. np->port,
  4540. (unsigned long long) nr64_mac(BTXMAC_SW_RST));
  4541. return -ENODEV;
  4542. }
  4543. return 0;
  4544. }
  4545. static int niu_reset_tx_mac(struct niu *np)
  4546. {
  4547. if (np->flags & NIU_FLAGS_XMAC)
  4548. return niu_reset_tx_xmac(np);
  4549. else
  4550. return niu_reset_tx_bmac(np);
  4551. }
  4552. static void niu_init_tx_xmac(struct niu *np, u64 min, u64 max)
  4553. {
  4554. u64 val;
  4555. val = nr64_mac(XMAC_MIN);
  4556. val &= ~(XMAC_MIN_TX_MIN_PKT_SIZE |
  4557. XMAC_MIN_RX_MIN_PKT_SIZE);
  4558. val |= (min << XMAC_MIN_RX_MIN_PKT_SIZE_SHFT);
  4559. val |= (min << XMAC_MIN_TX_MIN_PKT_SIZE_SHFT);
  4560. nw64_mac(XMAC_MIN, val);
  4561. nw64_mac(XMAC_MAX, max);
  4562. nw64_mac(XTXMAC_STAT_MSK, ~(u64)0);
  4563. val = nr64_mac(XMAC_IPG);
  4564. if (np->flags & NIU_FLAGS_10G) {
  4565. val &= ~XMAC_IPG_IPG_XGMII;
  4566. val |= (IPG_12_15_XGMII << XMAC_IPG_IPG_XGMII_SHIFT);
  4567. } else {
  4568. val &= ~XMAC_IPG_IPG_MII_GMII;
  4569. val |= (IPG_12_MII_GMII << XMAC_IPG_IPG_MII_GMII_SHIFT);
  4570. }
  4571. nw64_mac(XMAC_IPG, val);
  4572. val = nr64_mac(XMAC_CONFIG);
  4573. val &= ~(XMAC_CONFIG_ALWAYS_NO_CRC |
  4574. XMAC_CONFIG_STRETCH_MODE |
  4575. XMAC_CONFIG_VAR_MIN_IPG_EN |
  4576. XMAC_CONFIG_TX_ENABLE);
  4577. nw64_mac(XMAC_CONFIG, val);
  4578. nw64_mac(TXMAC_FRM_CNT, 0);
  4579. nw64_mac(TXMAC_BYTE_CNT, 0);
  4580. }
  4581. static void niu_init_tx_bmac(struct niu *np, u64 min, u64 max)
  4582. {
  4583. u64 val;
  4584. nw64_mac(BMAC_MIN_FRAME, min);
  4585. nw64_mac(BMAC_MAX_FRAME, max);
  4586. nw64_mac(BTXMAC_STATUS_MASK, ~(u64)0);
  4587. nw64_mac(BMAC_CTRL_TYPE, 0x8808);
  4588. nw64_mac(BMAC_PREAMBLE_SIZE, 7);
  4589. val = nr64_mac(BTXMAC_CONFIG);
  4590. val &= ~(BTXMAC_CONFIG_FCS_DISABLE |
  4591. BTXMAC_CONFIG_ENABLE);
  4592. nw64_mac(BTXMAC_CONFIG, val);
  4593. }
  4594. static void niu_init_tx_mac(struct niu *np)
  4595. {
  4596. u64 min, max;
  4597. min = 64;
  4598. if (np->dev->mtu > ETH_DATA_LEN)
  4599. max = 9216;
  4600. else
  4601. max = 1522;
  4602. /* The XMAC_MIN register only accepts values for TX min which
  4603. * have the low 3 bits cleared.
  4604. */
  4605. BUG_ON(min & 0x7);
  4606. if (np->flags & NIU_FLAGS_XMAC)
  4607. niu_init_tx_xmac(np, min, max);
  4608. else
  4609. niu_init_tx_bmac(np, min, max);
  4610. }
  4611. static int niu_reset_rx_xmac(struct niu *np)
  4612. {
  4613. int limit;
  4614. nw64_mac(XRXMAC_SW_RST,
  4615. XRXMAC_SW_RST_REG_RS | XRXMAC_SW_RST_SOFT_RST);
  4616. limit = 1000;
  4617. while (--limit >= 0) {
  4618. if (!(nr64_mac(XRXMAC_SW_RST) & (XRXMAC_SW_RST_REG_RS |
  4619. XRXMAC_SW_RST_SOFT_RST)))
  4620. break;
  4621. udelay(100);
  4622. }
  4623. if (limit < 0) {
  4624. dev_err(np->device, "Port %u RX XMAC would not reset, XRXMAC_SW_RST[%llx]\n",
  4625. np->port,
  4626. (unsigned long long) nr64_mac(XRXMAC_SW_RST));
  4627. return -ENODEV;
  4628. }
  4629. return 0;
  4630. }
  4631. static int niu_reset_rx_bmac(struct niu *np)
  4632. {
  4633. int limit;
  4634. nw64_mac(BRXMAC_SW_RST, BRXMAC_SW_RST_RESET);
  4635. limit = 1000;
  4636. while (--limit >= 0) {
  4637. if (!(nr64_mac(BRXMAC_SW_RST) & BRXMAC_SW_RST_RESET))
  4638. break;
  4639. udelay(100);
  4640. }
  4641. if (limit < 0) {
  4642. dev_err(np->device, "Port %u RX BMAC would not reset, BRXMAC_SW_RST[%llx]\n",
  4643. np->port,
  4644. (unsigned long long) nr64_mac(BRXMAC_SW_RST));
  4645. return -ENODEV;
  4646. }
  4647. return 0;
  4648. }
  4649. static int niu_reset_rx_mac(struct niu *np)
  4650. {
  4651. if (np->flags & NIU_FLAGS_XMAC)
  4652. return niu_reset_rx_xmac(np);
  4653. else
  4654. return niu_reset_rx_bmac(np);
  4655. }
  4656. static void niu_init_rx_xmac(struct niu *np)
  4657. {
  4658. struct niu_parent *parent = np->parent;
  4659. struct niu_rdc_tables *tp = &parent->rdc_group_cfg[np->port];
  4660. int first_rdc_table = tp->first_table_num;
  4661. unsigned long i;
  4662. u64 val;
  4663. nw64_mac(XMAC_ADD_FILT0, 0);
  4664. nw64_mac(XMAC_ADD_FILT1, 0);
  4665. nw64_mac(XMAC_ADD_FILT2, 0);
  4666. nw64_mac(XMAC_ADD_FILT12_MASK, 0);
  4667. nw64_mac(XMAC_ADD_FILT00_MASK, 0);
  4668. for (i = 0; i < MAC_NUM_HASH; i++)
  4669. nw64_mac(XMAC_HASH_TBL(i), 0);
  4670. nw64_mac(XRXMAC_STAT_MSK, ~(u64)0);
  4671. niu_set_primary_mac_rdc_table(np, first_rdc_table, 1);
  4672. niu_set_multicast_mac_rdc_table(np, first_rdc_table, 1);
  4673. val = nr64_mac(XMAC_CONFIG);
  4674. val &= ~(XMAC_CONFIG_RX_MAC_ENABLE |
  4675. XMAC_CONFIG_PROMISCUOUS |
  4676. XMAC_CONFIG_PROMISC_GROUP |
  4677. XMAC_CONFIG_ERR_CHK_DIS |
  4678. XMAC_CONFIG_RX_CRC_CHK_DIS |
  4679. XMAC_CONFIG_RESERVED_MULTICAST |
  4680. XMAC_CONFIG_RX_CODEV_CHK_DIS |
  4681. XMAC_CONFIG_ADDR_FILTER_EN |
  4682. XMAC_CONFIG_RCV_PAUSE_ENABLE |
  4683. XMAC_CONFIG_STRIP_CRC |
  4684. XMAC_CONFIG_PASS_FLOW_CTRL |
  4685. XMAC_CONFIG_MAC2IPP_PKT_CNT_EN);
  4686. val |= (XMAC_CONFIG_HASH_FILTER_EN);
  4687. nw64_mac(XMAC_CONFIG, val);
  4688. nw64_mac(RXMAC_BT_CNT, 0);
  4689. nw64_mac(RXMAC_BC_FRM_CNT, 0);
  4690. nw64_mac(RXMAC_MC_FRM_CNT, 0);
  4691. nw64_mac(RXMAC_FRAG_CNT, 0);
  4692. nw64_mac(RXMAC_HIST_CNT1, 0);
  4693. nw64_mac(RXMAC_HIST_CNT2, 0);
  4694. nw64_mac(RXMAC_HIST_CNT3, 0);
  4695. nw64_mac(RXMAC_HIST_CNT4, 0);
  4696. nw64_mac(RXMAC_HIST_CNT5, 0);
  4697. nw64_mac(RXMAC_HIST_CNT6, 0);
  4698. nw64_mac(RXMAC_HIST_CNT7, 0);
  4699. nw64_mac(RXMAC_MPSZER_CNT, 0);
  4700. nw64_mac(RXMAC_CRC_ER_CNT, 0);
  4701. nw64_mac(RXMAC_CD_VIO_CNT, 0);
  4702. nw64_mac(LINK_FAULT_CNT, 0);
  4703. }
  4704. static void niu_init_rx_bmac(struct niu *np)
  4705. {
  4706. struct niu_parent *parent = np->parent;
  4707. struct niu_rdc_tables *tp = &parent->rdc_group_cfg[np->port];
  4708. int first_rdc_table = tp->first_table_num;
  4709. unsigned long i;
  4710. u64 val;
  4711. nw64_mac(BMAC_ADD_FILT0, 0);
  4712. nw64_mac(BMAC_ADD_FILT1, 0);
  4713. nw64_mac(BMAC_ADD_FILT2, 0);
  4714. nw64_mac(BMAC_ADD_FILT12_MASK, 0);
  4715. nw64_mac(BMAC_ADD_FILT00_MASK, 0);
  4716. for (i = 0; i < MAC_NUM_HASH; i++)
  4717. nw64_mac(BMAC_HASH_TBL(i), 0);
  4718. niu_set_primary_mac_rdc_table(np, first_rdc_table, 1);
  4719. niu_set_multicast_mac_rdc_table(np, first_rdc_table, 1);
  4720. nw64_mac(BRXMAC_STATUS_MASK, ~(u64)0);
  4721. val = nr64_mac(BRXMAC_CONFIG);
  4722. val &= ~(BRXMAC_CONFIG_ENABLE |
  4723. BRXMAC_CONFIG_STRIP_PAD |
  4724. BRXMAC_CONFIG_STRIP_FCS |
  4725. BRXMAC_CONFIG_PROMISC |
  4726. BRXMAC_CONFIG_PROMISC_GRP |
  4727. BRXMAC_CONFIG_ADDR_FILT_EN |
  4728. BRXMAC_CONFIG_DISCARD_DIS);
  4729. val |= (BRXMAC_CONFIG_HASH_FILT_EN);
  4730. nw64_mac(BRXMAC_CONFIG, val);
  4731. val = nr64_mac(BMAC_ADDR_CMPEN);
  4732. val |= BMAC_ADDR_CMPEN_EN0;
  4733. nw64_mac(BMAC_ADDR_CMPEN, val);
  4734. }
  4735. static void niu_init_rx_mac(struct niu *np)
  4736. {
  4737. niu_set_primary_mac(np, np->dev->dev_addr);
  4738. if (np->flags & NIU_FLAGS_XMAC)
  4739. niu_init_rx_xmac(np);
  4740. else
  4741. niu_init_rx_bmac(np);
  4742. }
  4743. static void niu_enable_tx_xmac(struct niu *np, int on)
  4744. {
  4745. u64 val = nr64_mac(XMAC_CONFIG);
  4746. if (on)
  4747. val |= XMAC_CONFIG_TX_ENABLE;
  4748. else
  4749. val &= ~XMAC_CONFIG_TX_ENABLE;
  4750. nw64_mac(XMAC_CONFIG, val);
  4751. }
  4752. static void niu_enable_tx_bmac(struct niu *np, int on)
  4753. {
  4754. u64 val = nr64_mac(BTXMAC_CONFIG);
  4755. if (on)
  4756. val |= BTXMAC_CONFIG_ENABLE;
  4757. else
  4758. val &= ~BTXMAC_CONFIG_ENABLE;
  4759. nw64_mac(BTXMAC_CONFIG, val);
  4760. }
  4761. static void niu_enable_tx_mac(struct niu *np, int on)
  4762. {
  4763. if (np->flags & NIU_FLAGS_XMAC)
  4764. niu_enable_tx_xmac(np, on);
  4765. else
  4766. niu_enable_tx_bmac(np, on);
  4767. }
  4768. static void niu_enable_rx_xmac(struct niu *np, int on)
  4769. {
  4770. u64 val = nr64_mac(XMAC_CONFIG);
  4771. val &= ~(XMAC_CONFIG_HASH_FILTER_EN |
  4772. XMAC_CONFIG_PROMISCUOUS);
  4773. if (np->flags & NIU_FLAGS_MCAST)
  4774. val |= XMAC_CONFIG_HASH_FILTER_EN;
  4775. if (np->flags & NIU_FLAGS_PROMISC)
  4776. val |= XMAC_CONFIG_PROMISCUOUS;
  4777. if (on)
  4778. val |= XMAC_CONFIG_RX_MAC_ENABLE;
  4779. else
  4780. val &= ~XMAC_CONFIG_RX_MAC_ENABLE;
  4781. nw64_mac(XMAC_CONFIG, val);
  4782. }
  4783. static void niu_enable_rx_bmac(struct niu *np, int on)
  4784. {
  4785. u64 val = nr64_mac(BRXMAC_CONFIG);
  4786. val &= ~(BRXMAC_CONFIG_HASH_FILT_EN |
  4787. BRXMAC_CONFIG_PROMISC);
  4788. if (np->flags & NIU_FLAGS_MCAST)
  4789. val |= BRXMAC_CONFIG_HASH_FILT_EN;
  4790. if (np->flags & NIU_FLAGS_PROMISC)
  4791. val |= BRXMAC_CONFIG_PROMISC;
  4792. if (on)
  4793. val |= BRXMAC_CONFIG_ENABLE;
  4794. else
  4795. val &= ~BRXMAC_CONFIG_ENABLE;
  4796. nw64_mac(BRXMAC_CONFIG, val);
  4797. }
  4798. static void niu_enable_rx_mac(struct niu *np, int on)
  4799. {
  4800. if (np->flags & NIU_FLAGS_XMAC)
  4801. niu_enable_rx_xmac(np, on);
  4802. else
  4803. niu_enable_rx_bmac(np, on);
  4804. }
  4805. static int niu_init_mac(struct niu *np)
  4806. {
  4807. int err;
  4808. niu_init_xif(np);
  4809. err = niu_init_pcs(np);
  4810. if (err)
  4811. return err;
  4812. err = niu_reset_tx_mac(np);
  4813. if (err)
  4814. return err;
  4815. niu_init_tx_mac(np);
  4816. err = niu_reset_rx_mac(np);
  4817. if (err)
  4818. return err;
  4819. niu_init_rx_mac(np);
  4820. /* This looks hookey but the RX MAC reset we just did will
  4821. * undo some of the state we setup in niu_init_tx_mac() so we
  4822. * have to call it again. In particular, the RX MAC reset will
  4823. * set the XMAC_MAX register back to its default value.
  4824. */
  4825. niu_init_tx_mac(np);
  4826. niu_enable_tx_mac(np, 1);
  4827. niu_enable_rx_mac(np, 1);
  4828. return 0;
  4829. }
  4830. static void niu_stop_one_tx_channel(struct niu *np, struct tx_ring_info *rp)
  4831. {
  4832. (void) niu_tx_channel_stop(np, rp->tx_channel);
  4833. }
  4834. static void niu_stop_tx_channels(struct niu *np)
  4835. {
  4836. int i;
  4837. for (i = 0; i < np->num_tx_rings; i++) {
  4838. struct tx_ring_info *rp = &np->tx_rings[i];
  4839. niu_stop_one_tx_channel(np, rp);
  4840. }
  4841. }
  4842. static void niu_reset_one_tx_channel(struct niu *np, struct tx_ring_info *rp)
  4843. {
  4844. (void) niu_tx_channel_reset(np, rp->tx_channel);
  4845. }
  4846. static void niu_reset_tx_channels(struct niu *np)
  4847. {
  4848. int i;
  4849. for (i = 0; i < np->num_tx_rings; i++) {
  4850. struct tx_ring_info *rp = &np->tx_rings[i];
  4851. niu_reset_one_tx_channel(np, rp);
  4852. }
  4853. }
  4854. static void niu_stop_one_rx_channel(struct niu *np, struct rx_ring_info *rp)
  4855. {
  4856. (void) niu_enable_rx_channel(np, rp->rx_channel, 0);
  4857. }
  4858. static void niu_stop_rx_channels(struct niu *np)
  4859. {
  4860. int i;
  4861. for (i = 0; i < np->num_rx_rings; i++) {
  4862. struct rx_ring_info *rp = &np->rx_rings[i];
  4863. niu_stop_one_rx_channel(np, rp);
  4864. }
  4865. }
  4866. static void niu_reset_one_rx_channel(struct niu *np, struct rx_ring_info *rp)
  4867. {
  4868. int channel = rp->rx_channel;
  4869. (void) niu_rx_channel_reset(np, channel);
  4870. nw64(RX_DMA_ENT_MSK(channel), RX_DMA_ENT_MSK_ALL);
  4871. nw64(RX_DMA_CTL_STAT(channel), 0);
  4872. (void) niu_enable_rx_channel(np, channel, 0);
  4873. }
  4874. static void niu_reset_rx_channels(struct niu *np)
  4875. {
  4876. int i;
  4877. for (i = 0; i < np->num_rx_rings; i++) {
  4878. struct rx_ring_info *rp = &np->rx_rings[i];
  4879. niu_reset_one_rx_channel(np, rp);
  4880. }
  4881. }
  4882. static void niu_disable_ipp(struct niu *np)
  4883. {
  4884. u64 rd, wr, val;
  4885. int limit;
  4886. rd = nr64_ipp(IPP_DFIFO_RD_PTR);
  4887. wr = nr64_ipp(IPP_DFIFO_WR_PTR);
  4888. limit = 100;
  4889. while (--limit >= 0 && (rd != wr)) {
  4890. rd = nr64_ipp(IPP_DFIFO_RD_PTR);
  4891. wr = nr64_ipp(IPP_DFIFO_WR_PTR);
  4892. }
  4893. if (limit < 0 &&
  4894. (rd != 0 && wr != 1)) {
  4895. netdev_err(np->dev, "IPP would not quiesce, rd_ptr[%llx] wr_ptr[%llx]\n",
  4896. (unsigned long long)nr64_ipp(IPP_DFIFO_RD_PTR),
  4897. (unsigned long long)nr64_ipp(IPP_DFIFO_WR_PTR));
  4898. }
  4899. val = nr64_ipp(IPP_CFIG);
  4900. val &= ~(IPP_CFIG_IPP_ENABLE |
  4901. IPP_CFIG_DFIFO_ECC_EN |
  4902. IPP_CFIG_DROP_BAD_CRC |
  4903. IPP_CFIG_CKSUM_EN);
  4904. nw64_ipp(IPP_CFIG, val);
  4905. (void) niu_ipp_reset(np);
  4906. }
  4907. static int niu_init_hw(struct niu *np)
  4908. {
  4909. int i, err;
  4910. netif_printk(np, ifup, KERN_DEBUG, np->dev, "Initialize TXC\n");
  4911. niu_txc_enable_port(np, 1);
  4912. niu_txc_port_dma_enable(np, 1);
  4913. niu_txc_set_imask(np, 0);
  4914. netif_printk(np, ifup, KERN_DEBUG, np->dev, "Initialize TX channels\n");
  4915. for (i = 0; i < np->num_tx_rings; i++) {
  4916. struct tx_ring_info *rp = &np->tx_rings[i];
  4917. err = niu_init_one_tx_channel(np, rp);
  4918. if (err)
  4919. return err;
  4920. }
  4921. netif_printk(np, ifup, KERN_DEBUG, np->dev, "Initialize RX channels\n");
  4922. err = niu_init_rx_channels(np);
  4923. if (err)
  4924. goto out_uninit_tx_channels;
  4925. netif_printk(np, ifup, KERN_DEBUG, np->dev, "Initialize classifier\n");
  4926. err = niu_init_classifier_hw(np);
  4927. if (err)
  4928. goto out_uninit_rx_channels;
  4929. netif_printk(np, ifup, KERN_DEBUG, np->dev, "Initialize ZCP\n");
  4930. err = niu_init_zcp(np);
  4931. if (err)
  4932. goto out_uninit_rx_channels;
  4933. netif_printk(np, ifup, KERN_DEBUG, np->dev, "Initialize IPP\n");
  4934. err = niu_init_ipp(np);
  4935. if (err)
  4936. goto out_uninit_rx_channels;
  4937. netif_printk(np, ifup, KERN_DEBUG, np->dev, "Initialize MAC\n");
  4938. err = niu_init_mac(np);
  4939. if (err)
  4940. goto out_uninit_ipp;
  4941. return 0;
  4942. out_uninit_ipp:
  4943. netif_printk(np, ifup, KERN_DEBUG, np->dev, "Uninit IPP\n");
  4944. niu_disable_ipp(np);
  4945. out_uninit_rx_channels:
  4946. netif_printk(np, ifup, KERN_DEBUG, np->dev, "Uninit RX channels\n");
  4947. niu_stop_rx_channels(np);
  4948. niu_reset_rx_channels(np);
  4949. out_uninit_tx_channels:
  4950. netif_printk(np, ifup, KERN_DEBUG, np->dev, "Uninit TX channels\n");
  4951. niu_stop_tx_channels(np);
  4952. niu_reset_tx_channels(np);
  4953. return err;
  4954. }
  4955. static void niu_stop_hw(struct niu *np)
  4956. {
  4957. netif_printk(np, ifdown, KERN_DEBUG, np->dev, "Disable interrupts\n");
  4958. niu_enable_interrupts(np, 0);
  4959. netif_printk(np, ifdown, KERN_DEBUG, np->dev, "Disable RX MAC\n");
  4960. niu_enable_rx_mac(np, 0);
  4961. netif_printk(np, ifdown, KERN_DEBUG, np->dev, "Disable IPP\n");
  4962. niu_disable_ipp(np);
  4963. netif_printk(np, ifdown, KERN_DEBUG, np->dev, "Stop TX channels\n");
  4964. niu_stop_tx_channels(np);
  4965. netif_printk(np, ifdown, KERN_DEBUG, np->dev, "Stop RX channels\n");
  4966. niu_stop_rx_channels(np);
  4967. netif_printk(np, ifdown, KERN_DEBUG, np->dev, "Reset TX channels\n");
  4968. niu_reset_tx_channels(np);
  4969. netif_printk(np, ifdown, KERN_DEBUG, np->dev, "Reset RX channels\n");
  4970. niu_reset_rx_channels(np);
  4971. }
  4972. static void niu_set_irq_name(struct niu *np)
  4973. {
  4974. int port = np->port;
  4975. int i, j = 1;
  4976. sprintf(np->irq_name[0], "%s:MAC", np->dev->name);
  4977. if (port == 0) {
  4978. sprintf(np->irq_name[1], "%s:MIF", np->dev->name);
  4979. sprintf(np->irq_name[2], "%s:SYSERR", np->dev->name);
  4980. j = 3;
  4981. }
  4982. for (i = 0; i < np->num_ldg - j; i++) {
  4983. if (i < np->num_rx_rings)
  4984. sprintf(np->irq_name[i+j], "%s-rx-%d",
  4985. np->dev->name, i);
  4986. else if (i < np->num_tx_rings + np->num_rx_rings)
  4987. sprintf(np->irq_name[i+j], "%s-tx-%d", np->dev->name,
  4988. i - np->num_rx_rings);
  4989. }
  4990. }
  4991. static int niu_request_irq(struct niu *np)
  4992. {
  4993. int i, j, err;
  4994. niu_set_irq_name(np);
  4995. err = 0;
  4996. for (i = 0; i < np->num_ldg; i++) {
  4997. struct niu_ldg *lp = &np->ldg[i];
  4998. err = request_irq(lp->irq, niu_interrupt, IRQF_SHARED,
  4999. np->irq_name[i], lp);
  5000. if (err)
  5001. goto out_free_irqs;
  5002. }
  5003. return 0;
  5004. out_free_irqs:
  5005. for (j = 0; j < i; j++) {
  5006. struct niu_ldg *lp = &np->ldg[j];
  5007. free_irq(lp->irq, lp);
  5008. }
  5009. return err;
  5010. }
  5011. static void niu_free_irq(struct niu *np)
  5012. {
  5013. int i;
  5014. for (i = 0; i < np->num_ldg; i++) {
  5015. struct niu_ldg *lp = &np->ldg[i];
  5016. free_irq(lp->irq, lp);
  5017. }
  5018. }
  5019. static void niu_enable_napi(struct niu *np)
  5020. {
  5021. int i;
  5022. for (i = 0; i < np->num_ldg; i++)
  5023. napi_enable_locked(&np->ldg[i].napi);
  5024. }
  5025. static void niu_disable_napi(struct niu *np)
  5026. {
  5027. int i;
  5028. for (i = 0; i < np->num_ldg; i++)
  5029. napi_disable(&np->ldg[i].napi);
  5030. }
  5031. static int niu_open(struct net_device *dev)
  5032. {
  5033. struct niu *np = netdev_priv(dev);
  5034. int err;
  5035. netif_carrier_off(dev);
  5036. err = niu_alloc_channels(np);
  5037. if (err)
  5038. goto out_err;
  5039. err = niu_enable_interrupts(np, 0);
  5040. if (err)
  5041. goto out_free_channels;
  5042. err = niu_request_irq(np);
  5043. if (err)
  5044. goto out_free_channels;
  5045. netdev_lock(dev);
  5046. niu_enable_napi(np);
  5047. netdev_unlock(dev);
  5048. spin_lock_irq(&np->lock);
  5049. err = niu_init_hw(np);
  5050. if (!err) {
  5051. timer_setup(&np->timer, niu_timer, 0);
  5052. np->timer.expires = jiffies + HZ;
  5053. err = niu_enable_interrupts(np, 1);
  5054. if (err)
  5055. niu_stop_hw(np);
  5056. }
  5057. spin_unlock_irq(&np->lock);
  5058. if (err) {
  5059. niu_disable_napi(np);
  5060. goto out_free_irq;
  5061. }
  5062. netif_tx_start_all_queues(dev);
  5063. if (np->link_config.loopback_mode != LOOPBACK_DISABLED)
  5064. netif_carrier_on(dev);
  5065. add_timer(&np->timer);
  5066. return 0;
  5067. out_free_irq:
  5068. niu_free_irq(np);
  5069. out_free_channels:
  5070. niu_free_channels(np);
  5071. out_err:
  5072. return err;
  5073. }
  5074. static void niu_full_shutdown(struct niu *np, struct net_device *dev)
  5075. {
  5076. cancel_work_sync(&np->reset_task);
  5077. niu_disable_napi(np);
  5078. netif_tx_stop_all_queues(dev);
  5079. timer_delete_sync(&np->timer);
  5080. spin_lock_irq(&np->lock);
  5081. niu_stop_hw(np);
  5082. spin_unlock_irq(&np->lock);
  5083. }
  5084. static int niu_close(struct net_device *dev)
  5085. {
  5086. struct niu *np = netdev_priv(dev);
  5087. niu_full_shutdown(np, dev);
  5088. niu_free_irq(np);
  5089. niu_free_channels(np);
  5090. niu_handle_led(np, 0);
  5091. return 0;
  5092. }
  5093. static void niu_sync_xmac_stats(struct niu *np)
  5094. {
  5095. struct niu_xmac_stats *mp = &np->mac_stats.xmac;
  5096. mp->tx_frames += nr64_mac(TXMAC_FRM_CNT);
  5097. mp->tx_bytes += nr64_mac(TXMAC_BYTE_CNT);
  5098. mp->rx_link_faults += nr64_mac(LINK_FAULT_CNT);
  5099. mp->rx_align_errors += nr64_mac(RXMAC_ALIGN_ERR_CNT);
  5100. mp->rx_frags += nr64_mac(RXMAC_FRAG_CNT);
  5101. mp->rx_mcasts += nr64_mac(RXMAC_MC_FRM_CNT);
  5102. mp->rx_bcasts += nr64_mac(RXMAC_BC_FRM_CNT);
  5103. mp->rx_hist_cnt1 += nr64_mac(RXMAC_HIST_CNT1);
  5104. mp->rx_hist_cnt2 += nr64_mac(RXMAC_HIST_CNT2);
  5105. mp->rx_hist_cnt3 += nr64_mac(RXMAC_HIST_CNT3);
  5106. mp->rx_hist_cnt4 += nr64_mac(RXMAC_HIST_CNT4);
  5107. mp->rx_hist_cnt5 += nr64_mac(RXMAC_HIST_CNT5);
  5108. mp->rx_hist_cnt6 += nr64_mac(RXMAC_HIST_CNT6);
  5109. mp->rx_hist_cnt7 += nr64_mac(RXMAC_HIST_CNT7);
  5110. mp->rx_octets += nr64_mac(RXMAC_BT_CNT);
  5111. mp->rx_code_violations += nr64_mac(RXMAC_CD_VIO_CNT);
  5112. mp->rx_len_errors += nr64_mac(RXMAC_MPSZER_CNT);
  5113. mp->rx_crc_errors += nr64_mac(RXMAC_CRC_ER_CNT);
  5114. }
  5115. static void niu_sync_bmac_stats(struct niu *np)
  5116. {
  5117. struct niu_bmac_stats *mp = &np->mac_stats.bmac;
  5118. mp->tx_bytes += nr64_mac(BTXMAC_BYTE_CNT);
  5119. mp->tx_frames += nr64_mac(BTXMAC_FRM_CNT);
  5120. mp->rx_frames += nr64_mac(BRXMAC_FRAME_CNT);
  5121. mp->rx_align_errors += nr64_mac(BRXMAC_ALIGN_ERR_CNT);
  5122. mp->rx_crc_errors += nr64_mac(BRXMAC_ALIGN_ERR_CNT);
  5123. mp->rx_len_errors += nr64_mac(BRXMAC_CODE_VIOL_ERR_CNT);
  5124. }
  5125. static void niu_sync_mac_stats(struct niu *np)
  5126. {
  5127. if (np->flags & NIU_FLAGS_XMAC)
  5128. niu_sync_xmac_stats(np);
  5129. else
  5130. niu_sync_bmac_stats(np);
  5131. }
  5132. static void niu_get_rx_stats(struct niu *np,
  5133. struct rtnl_link_stats64 *stats)
  5134. {
  5135. u64 pkts, dropped, errors, bytes;
  5136. struct rx_ring_info *rx_rings;
  5137. int i;
  5138. pkts = dropped = errors = bytes = 0;
  5139. rx_rings = READ_ONCE(np->rx_rings);
  5140. if (!rx_rings)
  5141. goto no_rings;
  5142. for (i = 0; i < np->num_rx_rings; i++) {
  5143. struct rx_ring_info *rp = &rx_rings[i];
  5144. niu_sync_rx_discard_stats(np, rp, 0);
  5145. pkts += rp->rx_packets;
  5146. bytes += rp->rx_bytes;
  5147. dropped += rp->rx_dropped;
  5148. errors += rp->rx_errors;
  5149. }
  5150. no_rings:
  5151. stats->rx_packets = pkts;
  5152. stats->rx_bytes = bytes;
  5153. stats->rx_dropped = dropped;
  5154. stats->rx_errors = errors;
  5155. }
  5156. static void niu_get_tx_stats(struct niu *np,
  5157. struct rtnl_link_stats64 *stats)
  5158. {
  5159. u64 pkts, errors, bytes;
  5160. struct tx_ring_info *tx_rings;
  5161. int i;
  5162. pkts = errors = bytes = 0;
  5163. tx_rings = READ_ONCE(np->tx_rings);
  5164. if (!tx_rings)
  5165. goto no_rings;
  5166. for (i = 0; i < np->num_tx_rings; i++) {
  5167. struct tx_ring_info *rp = &tx_rings[i];
  5168. pkts += rp->tx_packets;
  5169. bytes += rp->tx_bytes;
  5170. errors += rp->tx_errors;
  5171. }
  5172. no_rings:
  5173. stats->tx_packets = pkts;
  5174. stats->tx_bytes = bytes;
  5175. stats->tx_errors = errors;
  5176. }
  5177. static void niu_get_stats(struct net_device *dev,
  5178. struct rtnl_link_stats64 *stats)
  5179. {
  5180. struct niu *np = netdev_priv(dev);
  5181. if (netif_running(dev)) {
  5182. niu_get_rx_stats(np, stats);
  5183. niu_get_tx_stats(np, stats);
  5184. }
  5185. }
  5186. static void niu_load_hash_xmac(struct niu *np, u16 *hash)
  5187. {
  5188. int i;
  5189. for (i = 0; i < 16; i++)
  5190. nw64_mac(XMAC_HASH_TBL(i), hash[i]);
  5191. }
  5192. static void niu_load_hash_bmac(struct niu *np, u16 *hash)
  5193. {
  5194. int i;
  5195. for (i = 0; i < 16; i++)
  5196. nw64_mac(BMAC_HASH_TBL(i), hash[i]);
  5197. }
  5198. static void niu_load_hash(struct niu *np, u16 *hash)
  5199. {
  5200. if (np->flags & NIU_FLAGS_XMAC)
  5201. niu_load_hash_xmac(np, hash);
  5202. else
  5203. niu_load_hash_bmac(np, hash);
  5204. }
  5205. static void niu_set_rx_mode(struct net_device *dev)
  5206. {
  5207. struct niu *np = netdev_priv(dev);
  5208. int i, alt_cnt, err;
  5209. struct netdev_hw_addr *ha;
  5210. unsigned long flags;
  5211. u16 hash[16] = { 0, };
  5212. spin_lock_irqsave(&np->lock, flags);
  5213. niu_enable_rx_mac(np, 0);
  5214. np->flags &= ~(NIU_FLAGS_MCAST | NIU_FLAGS_PROMISC);
  5215. if (dev->flags & IFF_PROMISC)
  5216. np->flags |= NIU_FLAGS_PROMISC;
  5217. if ((dev->flags & IFF_ALLMULTI) || (!netdev_mc_empty(dev)))
  5218. np->flags |= NIU_FLAGS_MCAST;
  5219. alt_cnt = netdev_uc_count(dev);
  5220. if (alt_cnt > niu_num_alt_addr(np)) {
  5221. alt_cnt = 0;
  5222. np->flags |= NIU_FLAGS_PROMISC;
  5223. }
  5224. if (alt_cnt) {
  5225. int index = 0;
  5226. netdev_for_each_uc_addr(ha, dev) {
  5227. err = niu_set_alt_mac(np, index, ha->addr);
  5228. if (err)
  5229. netdev_warn(dev, "Error %d adding alt mac %d\n",
  5230. err, index);
  5231. err = niu_enable_alt_mac(np, index, 1);
  5232. if (err)
  5233. netdev_warn(dev, "Error %d enabling alt mac %d\n",
  5234. err, index);
  5235. index++;
  5236. }
  5237. } else {
  5238. int alt_start;
  5239. if (np->flags & NIU_FLAGS_XMAC)
  5240. alt_start = 0;
  5241. else
  5242. alt_start = 1;
  5243. for (i = alt_start; i < niu_num_alt_addr(np); i++) {
  5244. err = niu_enable_alt_mac(np, i, 0);
  5245. if (err)
  5246. netdev_warn(dev, "Error %d disabling alt mac %d\n",
  5247. err, i);
  5248. }
  5249. }
  5250. if (dev->flags & IFF_ALLMULTI) {
  5251. for (i = 0; i < 16; i++)
  5252. hash[i] = 0xffff;
  5253. } else if (!netdev_mc_empty(dev)) {
  5254. netdev_for_each_mc_addr(ha, dev) {
  5255. u32 crc = ether_crc_le(ETH_ALEN, ha->addr);
  5256. crc >>= 24;
  5257. hash[crc >> 4] |= (1 << (15 - (crc & 0xf)));
  5258. }
  5259. }
  5260. if (np->flags & NIU_FLAGS_MCAST)
  5261. niu_load_hash(np, hash);
  5262. niu_enable_rx_mac(np, 1);
  5263. spin_unlock_irqrestore(&np->lock, flags);
  5264. }
  5265. static int niu_set_mac_addr(struct net_device *dev, void *p)
  5266. {
  5267. struct niu *np = netdev_priv(dev);
  5268. struct sockaddr *addr = p;
  5269. unsigned long flags;
  5270. if (!is_valid_ether_addr(addr->sa_data))
  5271. return -EADDRNOTAVAIL;
  5272. eth_hw_addr_set(dev, addr->sa_data);
  5273. if (!netif_running(dev))
  5274. return 0;
  5275. spin_lock_irqsave(&np->lock, flags);
  5276. niu_enable_rx_mac(np, 0);
  5277. niu_set_primary_mac(np, dev->dev_addr);
  5278. niu_enable_rx_mac(np, 1);
  5279. spin_unlock_irqrestore(&np->lock, flags);
  5280. return 0;
  5281. }
  5282. static int niu_ioctl(struct net_device *dev, struct ifreq *ifr, int cmd)
  5283. {
  5284. return -EOPNOTSUPP;
  5285. }
  5286. static void niu_netif_stop(struct niu *np)
  5287. {
  5288. netif_trans_update(np->dev); /* prevent tx timeout */
  5289. niu_disable_napi(np);
  5290. netif_tx_disable(np->dev);
  5291. }
  5292. static void niu_netif_start(struct niu *np)
  5293. {
  5294. /* NOTE: unconditional netif_wake_queue is only appropriate
  5295. * so long as all callers are assured to have free tx slots
  5296. * (such as after niu_init_hw).
  5297. */
  5298. netif_tx_wake_all_queues(np->dev);
  5299. niu_enable_napi(np);
  5300. niu_enable_interrupts(np, 1);
  5301. }
  5302. static void niu_reset_buffers(struct niu *np)
  5303. {
  5304. int i, j, k, err;
  5305. if (np->rx_rings) {
  5306. for (i = 0; i < np->num_rx_rings; i++) {
  5307. struct rx_ring_info *rp = &np->rx_rings[i];
  5308. for (j = 0, k = 0; j < MAX_RBR_RING_SIZE; j++) {
  5309. struct page *page;
  5310. page = rp->rxhash[j];
  5311. while (page) {
  5312. struct page *next = niu_next_page(page);
  5313. u64 base = page->private;
  5314. base = base >> RBR_DESCR_ADDR_SHIFT;
  5315. rp->rbr[k++] = cpu_to_le32(base);
  5316. page = next;
  5317. }
  5318. }
  5319. for (; k < MAX_RBR_RING_SIZE; k++) {
  5320. err = niu_rbr_add_page(np, rp, GFP_ATOMIC, k);
  5321. if (unlikely(err))
  5322. break;
  5323. }
  5324. rp->rbr_index = rp->rbr_table_size - 1;
  5325. rp->rcr_index = 0;
  5326. rp->rbr_pending = 0;
  5327. rp->rbr_refill_pending = 0;
  5328. }
  5329. }
  5330. if (np->tx_rings) {
  5331. for (i = 0; i < np->num_tx_rings; i++) {
  5332. struct tx_ring_info *rp = &np->tx_rings[i];
  5333. for (j = 0; j < MAX_TX_RING_SIZE; j++) {
  5334. if (rp->tx_buffs[j].skb)
  5335. (void) release_tx_packet(np, rp, j);
  5336. }
  5337. rp->pending = MAX_TX_RING_SIZE;
  5338. rp->prod = 0;
  5339. rp->cons = 0;
  5340. rp->wrap_bit = 0;
  5341. }
  5342. }
  5343. }
  5344. static void niu_reset_task(struct work_struct *work)
  5345. {
  5346. struct niu *np = container_of(work, struct niu, reset_task);
  5347. unsigned long flags;
  5348. int err;
  5349. spin_lock_irqsave(&np->lock, flags);
  5350. if (!netif_running(np->dev)) {
  5351. spin_unlock_irqrestore(&np->lock, flags);
  5352. return;
  5353. }
  5354. spin_unlock_irqrestore(&np->lock, flags);
  5355. timer_delete_sync(&np->timer);
  5356. niu_netif_stop(np);
  5357. spin_lock_irqsave(&np->lock, flags);
  5358. niu_stop_hw(np);
  5359. spin_unlock_irqrestore(&np->lock, flags);
  5360. niu_reset_buffers(np);
  5361. netdev_lock(np->dev);
  5362. spin_lock_irqsave(&np->lock, flags);
  5363. err = niu_init_hw(np);
  5364. if (!err) {
  5365. np->timer.expires = jiffies + HZ;
  5366. add_timer(&np->timer);
  5367. niu_netif_start(np);
  5368. }
  5369. spin_unlock_irqrestore(&np->lock, flags);
  5370. netdev_unlock(np->dev);
  5371. }
  5372. static void niu_tx_timeout(struct net_device *dev, unsigned int txqueue)
  5373. {
  5374. struct niu *np = netdev_priv(dev);
  5375. dev_err(np->device, "%s: Transmit timed out, resetting\n",
  5376. dev->name);
  5377. schedule_work(&np->reset_task);
  5378. }
  5379. static void niu_set_txd(struct tx_ring_info *rp, int index,
  5380. u64 mapping, u64 len, u64 mark,
  5381. u64 n_frags)
  5382. {
  5383. __le64 *desc = &rp->descr[index];
  5384. *desc = cpu_to_le64(mark |
  5385. (n_frags << TX_DESC_NUM_PTR_SHIFT) |
  5386. (len << TX_DESC_TR_LEN_SHIFT) |
  5387. (mapping & TX_DESC_SAD));
  5388. }
  5389. static u64 niu_compute_tx_flags(struct sk_buff *skb, struct ethhdr *ehdr,
  5390. u64 pad_bytes, u64 len)
  5391. {
  5392. u16 eth_proto, eth_proto_inner;
  5393. u64 csum_bits, l3off, ihl, ret;
  5394. u8 ip_proto;
  5395. int ipv6;
  5396. eth_proto = be16_to_cpu(ehdr->h_proto);
  5397. eth_proto_inner = eth_proto;
  5398. if (eth_proto == ETH_P_8021Q) {
  5399. struct vlan_ethhdr *vp = (struct vlan_ethhdr *) ehdr;
  5400. __be16 val = vp->h_vlan_encapsulated_proto;
  5401. eth_proto_inner = be16_to_cpu(val);
  5402. }
  5403. ipv6 = ihl = 0;
  5404. switch (skb->protocol) {
  5405. case cpu_to_be16(ETH_P_IP):
  5406. ip_proto = ip_hdr(skb)->protocol;
  5407. ihl = ip_hdr(skb)->ihl;
  5408. break;
  5409. case cpu_to_be16(ETH_P_IPV6):
  5410. ip_proto = ipv6_hdr(skb)->nexthdr;
  5411. ihl = (40 >> 2);
  5412. ipv6 = 1;
  5413. break;
  5414. default:
  5415. ip_proto = ihl = 0;
  5416. break;
  5417. }
  5418. csum_bits = TXHDR_CSUM_NONE;
  5419. if (skb->ip_summed == CHECKSUM_PARTIAL) {
  5420. u64 start, stuff;
  5421. csum_bits = (ip_proto == IPPROTO_TCP ?
  5422. TXHDR_CSUM_TCP :
  5423. (ip_proto == IPPROTO_UDP ?
  5424. TXHDR_CSUM_UDP : TXHDR_CSUM_SCTP));
  5425. start = skb_checksum_start_offset(skb) -
  5426. (pad_bytes + sizeof(struct tx_pkt_hdr));
  5427. stuff = start + skb->csum_offset;
  5428. csum_bits |= (start / 2) << TXHDR_L4START_SHIFT;
  5429. csum_bits |= (stuff / 2) << TXHDR_L4STUFF_SHIFT;
  5430. }
  5431. l3off = skb_network_offset(skb) -
  5432. (pad_bytes + sizeof(struct tx_pkt_hdr));
  5433. ret = (((pad_bytes / 2) << TXHDR_PAD_SHIFT) |
  5434. (len << TXHDR_LEN_SHIFT) |
  5435. ((l3off / 2) << TXHDR_L3START_SHIFT) |
  5436. (ihl << TXHDR_IHL_SHIFT) |
  5437. ((eth_proto_inner < ETH_P_802_3_MIN) ? TXHDR_LLC : 0) |
  5438. ((eth_proto == ETH_P_8021Q) ? TXHDR_VLAN : 0) |
  5439. (ipv6 ? TXHDR_IP_VER : 0) |
  5440. csum_bits);
  5441. return ret;
  5442. }
  5443. static netdev_tx_t niu_start_xmit(struct sk_buff *skb,
  5444. struct net_device *dev)
  5445. {
  5446. struct niu *np = netdev_priv(dev);
  5447. unsigned long align, headroom;
  5448. struct netdev_queue *txq;
  5449. struct tx_ring_info *rp;
  5450. struct tx_pkt_hdr *tp;
  5451. unsigned int len, nfg;
  5452. struct ethhdr *ehdr;
  5453. int prod, i, tlen;
  5454. u64 mapping, mrk;
  5455. i = skb_get_queue_mapping(skb);
  5456. rp = &np->tx_rings[i];
  5457. txq = netdev_get_tx_queue(dev, i);
  5458. if (niu_tx_avail(rp) <= (skb_shinfo(skb)->nr_frags + 1)) {
  5459. netif_tx_stop_queue(txq);
  5460. dev_err(np->device, "%s: BUG! Tx ring full when queue awake!\n", dev->name);
  5461. rp->tx_errors++;
  5462. return NETDEV_TX_BUSY;
  5463. }
  5464. if (eth_skb_pad(skb))
  5465. goto out;
  5466. len = sizeof(struct tx_pkt_hdr) + 15;
  5467. if (skb_headroom(skb) < len) {
  5468. struct sk_buff *skb_new;
  5469. skb_new = skb_realloc_headroom(skb, len);
  5470. if (!skb_new)
  5471. goto out_drop;
  5472. kfree_skb(skb);
  5473. skb = skb_new;
  5474. } else
  5475. skb_orphan(skb);
  5476. align = ((unsigned long) skb->data & (16 - 1));
  5477. headroom = align + sizeof(struct tx_pkt_hdr);
  5478. ehdr = (struct ethhdr *) skb->data;
  5479. tp = skb_push(skb, headroom);
  5480. len = skb->len - sizeof(struct tx_pkt_hdr);
  5481. tp->flags = cpu_to_le64(niu_compute_tx_flags(skb, ehdr, align, len));
  5482. tp->resv = 0;
  5483. len = skb_headlen(skb);
  5484. mapping = np->ops->map_single(np->device, skb->data,
  5485. len, DMA_TO_DEVICE);
  5486. if (np->ops->mapping_error(np->device, mapping))
  5487. goto out_drop;
  5488. prod = rp->prod;
  5489. rp->tx_buffs[prod].skb = skb;
  5490. rp->tx_buffs[prod].mapping = mapping;
  5491. mrk = TX_DESC_SOP;
  5492. if (++rp->mark_counter == rp->mark_freq) {
  5493. rp->mark_counter = 0;
  5494. mrk |= TX_DESC_MARK;
  5495. rp->mark_pending++;
  5496. }
  5497. tlen = len;
  5498. nfg = skb_shinfo(skb)->nr_frags;
  5499. while (tlen > 0) {
  5500. tlen -= MAX_TX_DESC_LEN;
  5501. nfg++;
  5502. }
  5503. while (len > 0) {
  5504. unsigned int this_len = len;
  5505. if (this_len > MAX_TX_DESC_LEN)
  5506. this_len = MAX_TX_DESC_LEN;
  5507. niu_set_txd(rp, prod, mapping, this_len, mrk, nfg);
  5508. mrk = nfg = 0;
  5509. prod = NEXT_TX(rp, prod);
  5510. mapping += this_len;
  5511. len -= this_len;
  5512. }
  5513. for (i = 0; i < skb_shinfo(skb)->nr_frags; i++) {
  5514. const skb_frag_t *frag = &skb_shinfo(skb)->frags[i];
  5515. len = skb_frag_size(frag);
  5516. mapping = np->ops->map_page(np->device, skb_frag_page(frag),
  5517. skb_frag_off(frag), len,
  5518. DMA_TO_DEVICE);
  5519. if (np->ops->mapping_error(np->device, mapping))
  5520. goto out_unmap;
  5521. rp->tx_buffs[prod].skb = NULL;
  5522. rp->tx_buffs[prod].mapping = mapping;
  5523. niu_set_txd(rp, prod, mapping, len, 0, 0);
  5524. prod = NEXT_TX(rp, prod);
  5525. }
  5526. if (prod < rp->prod)
  5527. rp->wrap_bit ^= TX_RING_KICK_WRAP;
  5528. rp->prod = prod;
  5529. nw64(TX_RING_KICK(rp->tx_channel), rp->wrap_bit | (prod << 3));
  5530. if (unlikely(niu_tx_avail(rp) <= (MAX_SKB_FRAGS + 1))) {
  5531. netif_tx_stop_queue(txq);
  5532. if (niu_tx_avail(rp) > NIU_TX_WAKEUP_THRESH(rp))
  5533. netif_tx_wake_queue(txq);
  5534. }
  5535. out:
  5536. return NETDEV_TX_OK;
  5537. out_unmap:
  5538. while (i--) {
  5539. const skb_frag_t *frag;
  5540. prod = PREVIOUS_TX(rp, prod);
  5541. frag = &skb_shinfo(skb)->frags[i];
  5542. np->ops->unmap_page(np->device, rp->tx_buffs[prod].mapping,
  5543. skb_frag_size(frag), DMA_TO_DEVICE);
  5544. }
  5545. np->ops->unmap_single(np->device, rp->tx_buffs[rp->prod].mapping,
  5546. skb_headlen(skb), DMA_TO_DEVICE);
  5547. out_drop:
  5548. rp->tx_errors++;
  5549. kfree_skb(skb);
  5550. goto out;
  5551. }
  5552. static int niu_change_mtu(struct net_device *dev, int new_mtu)
  5553. {
  5554. struct niu *np = netdev_priv(dev);
  5555. int err, orig_jumbo, new_jumbo;
  5556. orig_jumbo = (dev->mtu > ETH_DATA_LEN);
  5557. new_jumbo = (new_mtu > ETH_DATA_LEN);
  5558. WRITE_ONCE(dev->mtu, new_mtu);
  5559. if (!netif_running(dev) ||
  5560. (orig_jumbo == new_jumbo))
  5561. return 0;
  5562. niu_full_shutdown(np, dev);
  5563. niu_free_channels(np);
  5564. netdev_lock(dev);
  5565. niu_enable_napi(np);
  5566. netdev_unlock(dev);
  5567. err = niu_alloc_channels(np);
  5568. if (err)
  5569. return err;
  5570. spin_lock_irq(&np->lock);
  5571. err = niu_init_hw(np);
  5572. if (!err) {
  5573. timer_setup(&np->timer, niu_timer, 0);
  5574. np->timer.expires = jiffies + HZ;
  5575. err = niu_enable_interrupts(np, 1);
  5576. if (err)
  5577. niu_stop_hw(np);
  5578. }
  5579. spin_unlock_irq(&np->lock);
  5580. if (!err) {
  5581. netif_tx_start_all_queues(dev);
  5582. if (np->link_config.loopback_mode != LOOPBACK_DISABLED)
  5583. netif_carrier_on(dev);
  5584. add_timer(&np->timer);
  5585. }
  5586. return err;
  5587. }
  5588. static void niu_get_drvinfo(struct net_device *dev,
  5589. struct ethtool_drvinfo *info)
  5590. {
  5591. struct niu *np = netdev_priv(dev);
  5592. struct niu_vpd *vpd = &np->vpd;
  5593. strscpy(info->driver, DRV_MODULE_NAME, sizeof(info->driver));
  5594. strscpy(info->version, DRV_MODULE_VERSION, sizeof(info->version));
  5595. snprintf(info->fw_version, sizeof(info->fw_version), "%d.%d",
  5596. vpd->fcode_major, vpd->fcode_minor);
  5597. if (np->parent->plat_type != PLAT_TYPE_NIU)
  5598. strscpy(info->bus_info, pci_name(np->pdev),
  5599. sizeof(info->bus_info));
  5600. }
  5601. static int niu_get_link_ksettings(struct net_device *dev,
  5602. struct ethtool_link_ksettings *cmd)
  5603. {
  5604. struct niu *np = netdev_priv(dev);
  5605. struct niu_link_config *lp;
  5606. lp = &np->link_config;
  5607. memset(cmd, 0, sizeof(*cmd));
  5608. cmd->base.phy_address = np->phy_addr;
  5609. ethtool_convert_legacy_u32_to_link_mode(cmd->link_modes.supported,
  5610. lp->supported);
  5611. ethtool_convert_legacy_u32_to_link_mode(cmd->link_modes.advertising,
  5612. lp->active_advertising);
  5613. cmd->base.autoneg = lp->active_autoneg;
  5614. cmd->base.speed = lp->active_speed;
  5615. cmd->base.duplex = lp->active_duplex;
  5616. cmd->base.port = (np->flags & NIU_FLAGS_FIBER) ? PORT_FIBRE : PORT_TP;
  5617. return 0;
  5618. }
  5619. static int niu_set_link_ksettings(struct net_device *dev,
  5620. const struct ethtool_link_ksettings *cmd)
  5621. {
  5622. struct niu *np = netdev_priv(dev);
  5623. struct niu_link_config *lp = &np->link_config;
  5624. ethtool_convert_link_mode_to_legacy_u32(&lp->advertising,
  5625. cmd->link_modes.advertising);
  5626. lp->speed = cmd->base.speed;
  5627. lp->duplex = cmd->base.duplex;
  5628. lp->autoneg = cmd->base.autoneg;
  5629. return niu_init_link(np);
  5630. }
  5631. static u32 niu_get_msglevel(struct net_device *dev)
  5632. {
  5633. struct niu *np = netdev_priv(dev);
  5634. return np->msg_enable;
  5635. }
  5636. static void niu_set_msglevel(struct net_device *dev, u32 value)
  5637. {
  5638. struct niu *np = netdev_priv(dev);
  5639. np->msg_enable = value;
  5640. }
  5641. static int niu_nway_reset(struct net_device *dev)
  5642. {
  5643. struct niu *np = netdev_priv(dev);
  5644. if (np->link_config.autoneg)
  5645. return niu_init_link(np);
  5646. return 0;
  5647. }
  5648. static int niu_get_eeprom_len(struct net_device *dev)
  5649. {
  5650. struct niu *np = netdev_priv(dev);
  5651. return np->eeprom_len;
  5652. }
  5653. static int niu_get_eeprom(struct net_device *dev,
  5654. struct ethtool_eeprom *eeprom, u8 *data)
  5655. {
  5656. struct niu *np = netdev_priv(dev);
  5657. u32 offset, len, val;
  5658. offset = eeprom->offset;
  5659. len = eeprom->len;
  5660. if (offset + len < offset)
  5661. return -EINVAL;
  5662. if (offset >= np->eeprom_len)
  5663. return -EINVAL;
  5664. if (offset + len > np->eeprom_len)
  5665. len = eeprom->len = np->eeprom_len - offset;
  5666. if (offset & 3) {
  5667. u32 b_offset, b_count;
  5668. b_offset = offset & 3;
  5669. b_count = 4 - b_offset;
  5670. if (b_count > len)
  5671. b_count = len;
  5672. val = nr64(ESPC_NCR((offset - b_offset) / 4));
  5673. memcpy(data, ((char *)&val) + b_offset, b_count);
  5674. data += b_count;
  5675. len -= b_count;
  5676. offset += b_count;
  5677. }
  5678. while (len >= 4) {
  5679. val = nr64(ESPC_NCR(offset / 4));
  5680. memcpy(data, &val, 4);
  5681. data += 4;
  5682. len -= 4;
  5683. offset += 4;
  5684. }
  5685. if (len) {
  5686. val = nr64(ESPC_NCR(offset / 4));
  5687. memcpy(data, &val, len);
  5688. }
  5689. return 0;
  5690. }
  5691. static void niu_ethflow_to_l3proto(int flow_type, u8 *pid)
  5692. {
  5693. switch (flow_type) {
  5694. case TCP_V4_FLOW:
  5695. case TCP_V6_FLOW:
  5696. *pid = IPPROTO_TCP;
  5697. break;
  5698. case UDP_V4_FLOW:
  5699. case UDP_V6_FLOW:
  5700. *pid = IPPROTO_UDP;
  5701. break;
  5702. case SCTP_V4_FLOW:
  5703. case SCTP_V6_FLOW:
  5704. *pid = IPPROTO_SCTP;
  5705. break;
  5706. case AH_V4_FLOW:
  5707. case AH_V6_FLOW:
  5708. *pid = IPPROTO_AH;
  5709. break;
  5710. case ESP_V4_FLOW:
  5711. case ESP_V6_FLOW:
  5712. *pid = IPPROTO_ESP;
  5713. break;
  5714. default:
  5715. *pid = 0;
  5716. break;
  5717. }
  5718. }
  5719. static int niu_class_to_ethflow(u64 class, int *flow_type)
  5720. {
  5721. switch (class) {
  5722. case CLASS_CODE_TCP_IPV4:
  5723. *flow_type = TCP_V4_FLOW;
  5724. break;
  5725. case CLASS_CODE_UDP_IPV4:
  5726. *flow_type = UDP_V4_FLOW;
  5727. break;
  5728. case CLASS_CODE_AH_ESP_IPV4:
  5729. *flow_type = AH_V4_FLOW;
  5730. break;
  5731. case CLASS_CODE_SCTP_IPV4:
  5732. *flow_type = SCTP_V4_FLOW;
  5733. break;
  5734. case CLASS_CODE_TCP_IPV6:
  5735. *flow_type = TCP_V6_FLOW;
  5736. break;
  5737. case CLASS_CODE_UDP_IPV6:
  5738. *flow_type = UDP_V6_FLOW;
  5739. break;
  5740. case CLASS_CODE_AH_ESP_IPV6:
  5741. *flow_type = AH_V6_FLOW;
  5742. break;
  5743. case CLASS_CODE_SCTP_IPV6:
  5744. *flow_type = SCTP_V6_FLOW;
  5745. break;
  5746. case CLASS_CODE_USER_PROG1:
  5747. case CLASS_CODE_USER_PROG2:
  5748. case CLASS_CODE_USER_PROG3:
  5749. case CLASS_CODE_USER_PROG4:
  5750. *flow_type = IP_USER_FLOW;
  5751. break;
  5752. default:
  5753. return -EINVAL;
  5754. }
  5755. return 0;
  5756. }
  5757. static int niu_ethflow_to_class(int flow_type, u64 *class)
  5758. {
  5759. switch (flow_type) {
  5760. case TCP_V4_FLOW:
  5761. *class = CLASS_CODE_TCP_IPV4;
  5762. break;
  5763. case UDP_V4_FLOW:
  5764. *class = CLASS_CODE_UDP_IPV4;
  5765. break;
  5766. case AH_ESP_V4_FLOW:
  5767. case AH_V4_FLOW:
  5768. case ESP_V4_FLOW:
  5769. *class = CLASS_CODE_AH_ESP_IPV4;
  5770. break;
  5771. case SCTP_V4_FLOW:
  5772. *class = CLASS_CODE_SCTP_IPV4;
  5773. break;
  5774. case TCP_V6_FLOW:
  5775. *class = CLASS_CODE_TCP_IPV6;
  5776. break;
  5777. case UDP_V6_FLOW:
  5778. *class = CLASS_CODE_UDP_IPV6;
  5779. break;
  5780. case AH_ESP_V6_FLOW:
  5781. case AH_V6_FLOW:
  5782. case ESP_V6_FLOW:
  5783. *class = CLASS_CODE_AH_ESP_IPV6;
  5784. break;
  5785. case SCTP_V6_FLOW:
  5786. *class = CLASS_CODE_SCTP_IPV6;
  5787. break;
  5788. default:
  5789. return 0;
  5790. }
  5791. return 1;
  5792. }
  5793. static u64 niu_flowkey_to_ethflow(u64 flow_key)
  5794. {
  5795. u64 ethflow = 0;
  5796. if (flow_key & FLOW_KEY_L2DA)
  5797. ethflow |= RXH_L2DA;
  5798. if (flow_key & FLOW_KEY_VLAN)
  5799. ethflow |= RXH_VLAN;
  5800. if (flow_key & FLOW_KEY_IPSA)
  5801. ethflow |= RXH_IP_SRC;
  5802. if (flow_key & FLOW_KEY_IPDA)
  5803. ethflow |= RXH_IP_DST;
  5804. if (flow_key & FLOW_KEY_PROTO)
  5805. ethflow |= RXH_L3_PROTO;
  5806. if (flow_key & (FLOW_KEY_L4_BYTE12 << FLOW_KEY_L4_0_SHIFT))
  5807. ethflow |= RXH_L4_B_0_1;
  5808. if (flow_key & (FLOW_KEY_L4_BYTE12 << FLOW_KEY_L4_1_SHIFT))
  5809. ethflow |= RXH_L4_B_2_3;
  5810. return ethflow;
  5811. }
  5812. static int niu_ethflow_to_flowkey(u64 ethflow, u64 *flow_key)
  5813. {
  5814. u64 key = 0;
  5815. if (ethflow & RXH_L2DA)
  5816. key |= FLOW_KEY_L2DA;
  5817. if (ethflow & RXH_VLAN)
  5818. key |= FLOW_KEY_VLAN;
  5819. if (ethflow & RXH_IP_SRC)
  5820. key |= FLOW_KEY_IPSA;
  5821. if (ethflow & RXH_IP_DST)
  5822. key |= FLOW_KEY_IPDA;
  5823. if (ethflow & RXH_L3_PROTO)
  5824. key |= FLOW_KEY_PROTO;
  5825. if (ethflow & RXH_L4_B_0_1)
  5826. key |= (FLOW_KEY_L4_BYTE12 << FLOW_KEY_L4_0_SHIFT);
  5827. if (ethflow & RXH_L4_B_2_3)
  5828. key |= (FLOW_KEY_L4_BYTE12 << FLOW_KEY_L4_1_SHIFT);
  5829. *flow_key = key;
  5830. return 1;
  5831. }
  5832. static int niu_get_rxfh_fields(struct net_device *dev,
  5833. struct ethtool_rxfh_fields *nfc)
  5834. {
  5835. struct niu *np = netdev_priv(dev);
  5836. u64 class;
  5837. nfc->data = 0;
  5838. if (!niu_ethflow_to_class(nfc->flow_type, &class))
  5839. return -EINVAL;
  5840. if (np->parent->tcam_key[class - CLASS_CODE_USER_PROG1] &
  5841. TCAM_KEY_DISC)
  5842. nfc->data = RXH_DISCARD;
  5843. else
  5844. nfc->data = niu_flowkey_to_ethflow(np->parent->flow_key[class -
  5845. CLASS_CODE_USER_PROG1]);
  5846. return 0;
  5847. }
  5848. static void niu_get_ip4fs_from_tcam_key(struct niu_tcam_entry *tp,
  5849. struct ethtool_rx_flow_spec *fsp)
  5850. {
  5851. u32 tmp;
  5852. u16 prt;
  5853. tmp = (tp->key[3] & TCAM_V4KEY3_SADDR) >> TCAM_V4KEY3_SADDR_SHIFT;
  5854. fsp->h_u.tcp_ip4_spec.ip4src = cpu_to_be32(tmp);
  5855. tmp = (tp->key[3] & TCAM_V4KEY3_DADDR) >> TCAM_V4KEY3_DADDR_SHIFT;
  5856. fsp->h_u.tcp_ip4_spec.ip4dst = cpu_to_be32(tmp);
  5857. tmp = (tp->key_mask[3] & TCAM_V4KEY3_SADDR) >> TCAM_V4KEY3_SADDR_SHIFT;
  5858. fsp->m_u.tcp_ip4_spec.ip4src = cpu_to_be32(tmp);
  5859. tmp = (tp->key_mask[3] & TCAM_V4KEY3_DADDR) >> TCAM_V4KEY3_DADDR_SHIFT;
  5860. fsp->m_u.tcp_ip4_spec.ip4dst = cpu_to_be32(tmp);
  5861. fsp->h_u.tcp_ip4_spec.tos = (tp->key[2] & TCAM_V4KEY2_TOS) >>
  5862. TCAM_V4KEY2_TOS_SHIFT;
  5863. fsp->m_u.tcp_ip4_spec.tos = (tp->key_mask[2] & TCAM_V4KEY2_TOS) >>
  5864. TCAM_V4KEY2_TOS_SHIFT;
  5865. switch (fsp->flow_type) {
  5866. case TCP_V4_FLOW:
  5867. case UDP_V4_FLOW:
  5868. case SCTP_V4_FLOW:
  5869. prt = ((tp->key[2] & TCAM_V4KEY2_PORT_SPI) >>
  5870. TCAM_V4KEY2_PORT_SPI_SHIFT) >> 16;
  5871. fsp->h_u.tcp_ip4_spec.psrc = cpu_to_be16(prt);
  5872. prt = ((tp->key[2] & TCAM_V4KEY2_PORT_SPI) >>
  5873. TCAM_V4KEY2_PORT_SPI_SHIFT) & 0xffff;
  5874. fsp->h_u.tcp_ip4_spec.pdst = cpu_to_be16(prt);
  5875. prt = ((tp->key_mask[2] & TCAM_V4KEY2_PORT_SPI) >>
  5876. TCAM_V4KEY2_PORT_SPI_SHIFT) >> 16;
  5877. fsp->m_u.tcp_ip4_spec.psrc = cpu_to_be16(prt);
  5878. prt = ((tp->key_mask[2] & TCAM_V4KEY2_PORT_SPI) >>
  5879. TCAM_V4KEY2_PORT_SPI_SHIFT) & 0xffff;
  5880. fsp->m_u.tcp_ip4_spec.pdst = cpu_to_be16(prt);
  5881. break;
  5882. case AH_V4_FLOW:
  5883. case ESP_V4_FLOW:
  5884. tmp = (tp->key[2] & TCAM_V4KEY2_PORT_SPI) >>
  5885. TCAM_V4KEY2_PORT_SPI_SHIFT;
  5886. fsp->h_u.ah_ip4_spec.spi = cpu_to_be32(tmp);
  5887. tmp = (tp->key_mask[2] & TCAM_V4KEY2_PORT_SPI) >>
  5888. TCAM_V4KEY2_PORT_SPI_SHIFT;
  5889. fsp->m_u.ah_ip4_spec.spi = cpu_to_be32(tmp);
  5890. break;
  5891. case IP_USER_FLOW:
  5892. tmp = (tp->key[2] & TCAM_V4KEY2_PORT_SPI) >>
  5893. TCAM_V4KEY2_PORT_SPI_SHIFT;
  5894. fsp->h_u.usr_ip4_spec.l4_4_bytes = cpu_to_be32(tmp);
  5895. tmp = (tp->key_mask[2] & TCAM_V4KEY2_PORT_SPI) >>
  5896. TCAM_V4KEY2_PORT_SPI_SHIFT;
  5897. fsp->m_u.usr_ip4_spec.l4_4_bytes = cpu_to_be32(tmp);
  5898. fsp->h_u.usr_ip4_spec.proto =
  5899. (tp->key[2] & TCAM_V4KEY2_PROTO) >>
  5900. TCAM_V4KEY2_PROTO_SHIFT;
  5901. fsp->m_u.usr_ip4_spec.proto =
  5902. (tp->key_mask[2] & TCAM_V4KEY2_PROTO) >>
  5903. TCAM_V4KEY2_PROTO_SHIFT;
  5904. fsp->h_u.usr_ip4_spec.ip_ver = ETH_RX_NFC_IP4;
  5905. break;
  5906. default:
  5907. break;
  5908. }
  5909. }
  5910. static int niu_get_ethtool_tcam_entry(struct niu *np,
  5911. struct ethtool_rxnfc *nfc)
  5912. {
  5913. struct niu_parent *parent = np->parent;
  5914. struct niu_tcam_entry *tp;
  5915. struct ethtool_rx_flow_spec *fsp = &nfc->fs;
  5916. u16 idx;
  5917. u64 class;
  5918. int ret = 0;
  5919. idx = tcam_get_index(np, (u16)nfc->fs.location);
  5920. tp = &parent->tcam[idx];
  5921. if (!tp->valid) {
  5922. netdev_info(np->dev, "niu%d: entry [%d] invalid for idx[%d]\n",
  5923. parent->index, (u16)nfc->fs.location, idx);
  5924. return -EINVAL;
  5925. }
  5926. /* fill the flow spec entry */
  5927. class = (tp->key[0] & TCAM_V4KEY0_CLASS_CODE) >>
  5928. TCAM_V4KEY0_CLASS_CODE_SHIFT;
  5929. ret = niu_class_to_ethflow(class, &fsp->flow_type);
  5930. if (ret < 0) {
  5931. netdev_info(np->dev, "niu%d: niu_class_to_ethflow failed\n",
  5932. parent->index);
  5933. goto out;
  5934. }
  5935. if (fsp->flow_type == AH_V4_FLOW || fsp->flow_type == AH_V6_FLOW) {
  5936. u32 proto = (tp->key[2] & TCAM_V4KEY2_PROTO) >>
  5937. TCAM_V4KEY2_PROTO_SHIFT;
  5938. if (proto == IPPROTO_ESP) {
  5939. if (fsp->flow_type == AH_V4_FLOW)
  5940. fsp->flow_type = ESP_V4_FLOW;
  5941. else
  5942. fsp->flow_type = ESP_V6_FLOW;
  5943. }
  5944. }
  5945. switch (fsp->flow_type) {
  5946. case TCP_V4_FLOW:
  5947. case UDP_V4_FLOW:
  5948. case SCTP_V4_FLOW:
  5949. case AH_V4_FLOW:
  5950. case ESP_V4_FLOW:
  5951. niu_get_ip4fs_from_tcam_key(tp, fsp);
  5952. break;
  5953. case TCP_V6_FLOW:
  5954. case UDP_V6_FLOW:
  5955. case SCTP_V6_FLOW:
  5956. case AH_V6_FLOW:
  5957. case ESP_V6_FLOW:
  5958. /* Not yet implemented */
  5959. ret = -EINVAL;
  5960. break;
  5961. case IP_USER_FLOW:
  5962. niu_get_ip4fs_from_tcam_key(tp, fsp);
  5963. break;
  5964. default:
  5965. ret = -EINVAL;
  5966. break;
  5967. }
  5968. if (ret < 0)
  5969. goto out;
  5970. if (tp->assoc_data & TCAM_ASSOCDATA_DISC)
  5971. fsp->ring_cookie = RX_CLS_FLOW_DISC;
  5972. else
  5973. fsp->ring_cookie = (tp->assoc_data & TCAM_ASSOCDATA_OFFSET) >>
  5974. TCAM_ASSOCDATA_OFFSET_SHIFT;
  5975. /* put the tcam size here */
  5976. nfc->data = tcam_get_size(np);
  5977. out:
  5978. return ret;
  5979. }
  5980. static int niu_get_ethtool_tcam_all(struct niu *np,
  5981. struct ethtool_rxnfc *nfc,
  5982. u32 *rule_locs)
  5983. {
  5984. struct niu_parent *parent = np->parent;
  5985. struct niu_tcam_entry *tp;
  5986. int i, idx, cnt;
  5987. unsigned long flags;
  5988. int ret = 0;
  5989. /* put the tcam size here */
  5990. nfc->data = tcam_get_size(np);
  5991. niu_lock_parent(np, flags);
  5992. for (cnt = 0, i = 0; i < nfc->data; i++) {
  5993. idx = tcam_get_index(np, i);
  5994. tp = &parent->tcam[idx];
  5995. if (!tp->valid)
  5996. continue;
  5997. if (cnt == nfc->rule_cnt) {
  5998. ret = -EMSGSIZE;
  5999. break;
  6000. }
  6001. rule_locs[cnt] = i;
  6002. cnt++;
  6003. }
  6004. niu_unlock_parent(np, flags);
  6005. nfc->rule_cnt = cnt;
  6006. return ret;
  6007. }
  6008. static u32 niu_get_rx_ring_count(struct net_device *dev)
  6009. {
  6010. struct niu *np = netdev_priv(dev);
  6011. return np->num_rx_rings;
  6012. }
  6013. static int niu_get_nfc(struct net_device *dev, struct ethtool_rxnfc *cmd,
  6014. u32 *rule_locs)
  6015. {
  6016. struct niu *np = netdev_priv(dev);
  6017. int ret = 0;
  6018. switch (cmd->cmd) {
  6019. case ETHTOOL_GRXCLSRLCNT:
  6020. cmd->rule_cnt = tcam_get_valid_entry_cnt(np);
  6021. break;
  6022. case ETHTOOL_GRXCLSRULE:
  6023. ret = niu_get_ethtool_tcam_entry(np, cmd);
  6024. break;
  6025. case ETHTOOL_GRXCLSRLALL:
  6026. ret = niu_get_ethtool_tcam_all(np, cmd, rule_locs);
  6027. break;
  6028. default:
  6029. ret = -EINVAL;
  6030. break;
  6031. }
  6032. return ret;
  6033. }
  6034. static int niu_set_rxfh_fields(struct net_device *dev,
  6035. const struct ethtool_rxfh_fields *nfc,
  6036. struct netlink_ext_ack *extack)
  6037. {
  6038. struct niu *np = netdev_priv(dev);
  6039. u64 class;
  6040. u64 flow_key = 0;
  6041. unsigned long flags;
  6042. if (!niu_ethflow_to_class(nfc->flow_type, &class))
  6043. return -EINVAL;
  6044. if (class < CLASS_CODE_USER_PROG1 ||
  6045. class > CLASS_CODE_SCTP_IPV6)
  6046. return -EINVAL;
  6047. if (nfc->data & RXH_DISCARD) {
  6048. niu_lock_parent(np, flags);
  6049. flow_key = np->parent->tcam_key[class -
  6050. CLASS_CODE_USER_PROG1];
  6051. flow_key |= TCAM_KEY_DISC;
  6052. nw64(TCAM_KEY(class - CLASS_CODE_USER_PROG1), flow_key);
  6053. np->parent->tcam_key[class - CLASS_CODE_USER_PROG1] = flow_key;
  6054. niu_unlock_parent(np, flags);
  6055. return 0;
  6056. } else {
  6057. /* Discard was set before, but is not set now */
  6058. if (np->parent->tcam_key[class - CLASS_CODE_USER_PROG1] &
  6059. TCAM_KEY_DISC) {
  6060. niu_lock_parent(np, flags);
  6061. flow_key = np->parent->tcam_key[class -
  6062. CLASS_CODE_USER_PROG1];
  6063. flow_key &= ~TCAM_KEY_DISC;
  6064. nw64(TCAM_KEY(class - CLASS_CODE_USER_PROG1),
  6065. flow_key);
  6066. np->parent->tcam_key[class - CLASS_CODE_USER_PROG1] =
  6067. flow_key;
  6068. niu_unlock_parent(np, flags);
  6069. }
  6070. }
  6071. if (!niu_ethflow_to_flowkey(nfc->data, &flow_key))
  6072. return -EINVAL;
  6073. niu_lock_parent(np, flags);
  6074. nw64(FLOW_KEY(class - CLASS_CODE_USER_PROG1), flow_key);
  6075. np->parent->flow_key[class - CLASS_CODE_USER_PROG1] = flow_key;
  6076. niu_unlock_parent(np, flags);
  6077. return 0;
  6078. }
  6079. static void niu_get_tcamkey_from_ip4fs(struct ethtool_rx_flow_spec *fsp,
  6080. struct niu_tcam_entry *tp,
  6081. int l2_rdc_tab, u64 class)
  6082. {
  6083. u8 pid = 0;
  6084. u32 sip, dip, sipm, dipm, spi, spim;
  6085. u16 sport, dport, spm, dpm;
  6086. sip = be32_to_cpu(fsp->h_u.tcp_ip4_spec.ip4src);
  6087. sipm = be32_to_cpu(fsp->m_u.tcp_ip4_spec.ip4src);
  6088. dip = be32_to_cpu(fsp->h_u.tcp_ip4_spec.ip4dst);
  6089. dipm = be32_to_cpu(fsp->m_u.tcp_ip4_spec.ip4dst);
  6090. tp->key[0] = class << TCAM_V4KEY0_CLASS_CODE_SHIFT;
  6091. tp->key_mask[0] = TCAM_V4KEY0_CLASS_CODE;
  6092. tp->key[1] = (u64)l2_rdc_tab << TCAM_V4KEY1_L2RDCNUM_SHIFT;
  6093. tp->key_mask[1] = TCAM_V4KEY1_L2RDCNUM;
  6094. tp->key[3] = (u64)sip << TCAM_V4KEY3_SADDR_SHIFT;
  6095. tp->key[3] |= dip;
  6096. tp->key_mask[3] = (u64)sipm << TCAM_V4KEY3_SADDR_SHIFT;
  6097. tp->key_mask[3] |= dipm;
  6098. tp->key[2] |= ((u64)fsp->h_u.tcp_ip4_spec.tos <<
  6099. TCAM_V4KEY2_TOS_SHIFT);
  6100. tp->key_mask[2] |= ((u64)fsp->m_u.tcp_ip4_spec.tos <<
  6101. TCAM_V4KEY2_TOS_SHIFT);
  6102. switch (fsp->flow_type) {
  6103. case TCP_V4_FLOW:
  6104. case UDP_V4_FLOW:
  6105. case SCTP_V4_FLOW:
  6106. sport = be16_to_cpu(fsp->h_u.tcp_ip4_spec.psrc);
  6107. spm = be16_to_cpu(fsp->m_u.tcp_ip4_spec.psrc);
  6108. dport = be16_to_cpu(fsp->h_u.tcp_ip4_spec.pdst);
  6109. dpm = be16_to_cpu(fsp->m_u.tcp_ip4_spec.pdst);
  6110. tp->key[2] |= (((u64)sport << 16) | dport);
  6111. tp->key_mask[2] |= (((u64)spm << 16) | dpm);
  6112. niu_ethflow_to_l3proto(fsp->flow_type, &pid);
  6113. break;
  6114. case AH_V4_FLOW:
  6115. case ESP_V4_FLOW:
  6116. spi = be32_to_cpu(fsp->h_u.ah_ip4_spec.spi);
  6117. spim = be32_to_cpu(fsp->m_u.ah_ip4_spec.spi);
  6118. tp->key[2] |= spi;
  6119. tp->key_mask[2] |= spim;
  6120. niu_ethflow_to_l3proto(fsp->flow_type, &pid);
  6121. break;
  6122. case IP_USER_FLOW:
  6123. spi = be32_to_cpu(fsp->h_u.usr_ip4_spec.l4_4_bytes);
  6124. spim = be32_to_cpu(fsp->m_u.usr_ip4_spec.l4_4_bytes);
  6125. tp->key[2] |= spi;
  6126. tp->key_mask[2] |= spim;
  6127. pid = fsp->h_u.usr_ip4_spec.proto;
  6128. break;
  6129. default:
  6130. break;
  6131. }
  6132. tp->key[2] |= ((u64)pid << TCAM_V4KEY2_PROTO_SHIFT);
  6133. if (pid) {
  6134. tp->key_mask[2] |= TCAM_V4KEY2_PROTO;
  6135. }
  6136. }
  6137. static int niu_add_ethtool_tcam_entry(struct niu *np,
  6138. struct ethtool_rxnfc *nfc)
  6139. {
  6140. struct niu_parent *parent = np->parent;
  6141. struct niu_tcam_entry *tp;
  6142. struct ethtool_rx_flow_spec *fsp = &nfc->fs;
  6143. struct niu_rdc_tables *rdc_table = &parent->rdc_group_cfg[np->port];
  6144. int l2_rdc_table = rdc_table->first_table_num;
  6145. u16 idx;
  6146. u64 class;
  6147. unsigned long flags;
  6148. int err, ret;
  6149. ret = 0;
  6150. idx = nfc->fs.location;
  6151. if (idx >= tcam_get_size(np))
  6152. return -EINVAL;
  6153. if (fsp->flow_type == IP_USER_FLOW) {
  6154. int i;
  6155. int add_usr_cls = 0;
  6156. struct ethtool_usrip4_spec *uspec = &fsp->h_u.usr_ip4_spec;
  6157. struct ethtool_usrip4_spec *umask = &fsp->m_u.usr_ip4_spec;
  6158. if (uspec->ip_ver != ETH_RX_NFC_IP4)
  6159. return -EINVAL;
  6160. niu_lock_parent(np, flags);
  6161. for (i = 0; i < NIU_L3_PROG_CLS; i++) {
  6162. if (parent->l3_cls[i]) {
  6163. if (uspec->proto == parent->l3_cls_pid[i]) {
  6164. class = parent->l3_cls[i];
  6165. parent->l3_cls_refcnt[i]++;
  6166. add_usr_cls = 1;
  6167. break;
  6168. }
  6169. } else {
  6170. /* Program new user IP class */
  6171. switch (i) {
  6172. case 0:
  6173. class = CLASS_CODE_USER_PROG1;
  6174. break;
  6175. case 1:
  6176. class = CLASS_CODE_USER_PROG2;
  6177. break;
  6178. case 2:
  6179. class = CLASS_CODE_USER_PROG3;
  6180. break;
  6181. case 3:
  6182. class = CLASS_CODE_USER_PROG4;
  6183. break;
  6184. default:
  6185. class = CLASS_CODE_UNRECOG;
  6186. break;
  6187. }
  6188. ret = tcam_user_ip_class_set(np, class, 0,
  6189. uspec->proto,
  6190. uspec->tos,
  6191. umask->tos);
  6192. if (ret)
  6193. goto out;
  6194. ret = tcam_user_ip_class_enable(np, class, 1);
  6195. if (ret)
  6196. goto out;
  6197. parent->l3_cls[i] = class;
  6198. parent->l3_cls_pid[i] = uspec->proto;
  6199. parent->l3_cls_refcnt[i]++;
  6200. add_usr_cls = 1;
  6201. break;
  6202. }
  6203. }
  6204. if (!add_usr_cls) {
  6205. netdev_info(np->dev, "niu%d: %s(): Could not find/insert class for pid %d\n",
  6206. parent->index, __func__, uspec->proto);
  6207. ret = -EINVAL;
  6208. goto out;
  6209. }
  6210. niu_unlock_parent(np, flags);
  6211. } else {
  6212. if (!niu_ethflow_to_class(fsp->flow_type, &class)) {
  6213. return -EINVAL;
  6214. }
  6215. }
  6216. niu_lock_parent(np, flags);
  6217. idx = tcam_get_index(np, idx);
  6218. tp = &parent->tcam[idx];
  6219. memset(tp, 0, sizeof(*tp));
  6220. /* fill in the tcam key and mask */
  6221. switch (fsp->flow_type) {
  6222. case TCP_V4_FLOW:
  6223. case UDP_V4_FLOW:
  6224. case SCTP_V4_FLOW:
  6225. case AH_V4_FLOW:
  6226. case ESP_V4_FLOW:
  6227. niu_get_tcamkey_from_ip4fs(fsp, tp, l2_rdc_table, class);
  6228. break;
  6229. case TCP_V6_FLOW:
  6230. case UDP_V6_FLOW:
  6231. case SCTP_V6_FLOW:
  6232. case AH_V6_FLOW:
  6233. case ESP_V6_FLOW:
  6234. /* Not yet implemented */
  6235. netdev_info(np->dev, "niu%d: In %s(): flow %d for IPv6 not implemented\n",
  6236. parent->index, __func__, fsp->flow_type);
  6237. ret = -EINVAL;
  6238. goto out;
  6239. case IP_USER_FLOW:
  6240. niu_get_tcamkey_from_ip4fs(fsp, tp, l2_rdc_table, class);
  6241. break;
  6242. default:
  6243. netdev_info(np->dev, "niu%d: In %s(): Unknown flow type %d\n",
  6244. parent->index, __func__, fsp->flow_type);
  6245. ret = -EINVAL;
  6246. goto out;
  6247. }
  6248. /* fill in the assoc data */
  6249. if (fsp->ring_cookie == RX_CLS_FLOW_DISC) {
  6250. tp->assoc_data = TCAM_ASSOCDATA_DISC;
  6251. } else {
  6252. if (fsp->ring_cookie >= np->num_rx_rings) {
  6253. netdev_info(np->dev, "niu%d: In %s(): Invalid RX ring %lld\n",
  6254. parent->index, __func__,
  6255. (long long)fsp->ring_cookie);
  6256. ret = -EINVAL;
  6257. goto out;
  6258. }
  6259. tp->assoc_data = (TCAM_ASSOCDATA_TRES_USE_OFFSET |
  6260. (fsp->ring_cookie <<
  6261. TCAM_ASSOCDATA_OFFSET_SHIFT));
  6262. }
  6263. err = tcam_write(np, idx, tp->key, tp->key_mask);
  6264. if (err) {
  6265. ret = -EINVAL;
  6266. goto out;
  6267. }
  6268. err = tcam_assoc_write(np, idx, tp->assoc_data);
  6269. if (err) {
  6270. ret = -EINVAL;
  6271. goto out;
  6272. }
  6273. /* validate the entry */
  6274. tp->valid = 1;
  6275. np->clas.tcam_valid_entries++;
  6276. out:
  6277. niu_unlock_parent(np, flags);
  6278. return ret;
  6279. }
  6280. static int niu_del_ethtool_tcam_entry(struct niu *np, u32 loc)
  6281. {
  6282. struct niu_parent *parent = np->parent;
  6283. struct niu_tcam_entry *tp;
  6284. u16 idx;
  6285. unsigned long flags;
  6286. u64 class;
  6287. int ret = 0;
  6288. if (loc >= tcam_get_size(np))
  6289. return -EINVAL;
  6290. niu_lock_parent(np, flags);
  6291. idx = tcam_get_index(np, loc);
  6292. tp = &parent->tcam[idx];
  6293. /* if the entry is of a user defined class, then update*/
  6294. class = (tp->key[0] & TCAM_V4KEY0_CLASS_CODE) >>
  6295. TCAM_V4KEY0_CLASS_CODE_SHIFT;
  6296. if (class >= CLASS_CODE_USER_PROG1 && class <= CLASS_CODE_USER_PROG4) {
  6297. int i;
  6298. for (i = 0; i < NIU_L3_PROG_CLS; i++) {
  6299. if (parent->l3_cls[i] == class) {
  6300. parent->l3_cls_refcnt[i]--;
  6301. if (!parent->l3_cls_refcnt[i]) {
  6302. /* disable class */
  6303. ret = tcam_user_ip_class_enable(np,
  6304. class,
  6305. 0);
  6306. if (ret)
  6307. goto out;
  6308. parent->l3_cls[i] = 0;
  6309. parent->l3_cls_pid[i] = 0;
  6310. }
  6311. break;
  6312. }
  6313. }
  6314. if (i == NIU_L3_PROG_CLS) {
  6315. netdev_info(np->dev, "niu%d: In %s(): Usr class 0x%llx not found\n",
  6316. parent->index, __func__,
  6317. (unsigned long long)class);
  6318. ret = -EINVAL;
  6319. goto out;
  6320. }
  6321. }
  6322. ret = tcam_flush(np, idx);
  6323. if (ret)
  6324. goto out;
  6325. /* invalidate the entry */
  6326. tp->valid = 0;
  6327. np->clas.tcam_valid_entries--;
  6328. out:
  6329. niu_unlock_parent(np, flags);
  6330. return ret;
  6331. }
  6332. static int niu_set_nfc(struct net_device *dev, struct ethtool_rxnfc *cmd)
  6333. {
  6334. struct niu *np = netdev_priv(dev);
  6335. int ret = 0;
  6336. switch (cmd->cmd) {
  6337. case ETHTOOL_SRXCLSRLINS:
  6338. ret = niu_add_ethtool_tcam_entry(np, cmd);
  6339. break;
  6340. case ETHTOOL_SRXCLSRLDEL:
  6341. ret = niu_del_ethtool_tcam_entry(np, cmd->fs.location);
  6342. break;
  6343. default:
  6344. ret = -EINVAL;
  6345. break;
  6346. }
  6347. return ret;
  6348. }
  6349. static const struct {
  6350. const char string[ETH_GSTRING_LEN];
  6351. } niu_xmac_stat_keys[] = {
  6352. { "tx_frames" },
  6353. { "tx_bytes" },
  6354. { "tx_fifo_errors" },
  6355. { "tx_overflow_errors" },
  6356. { "tx_max_pkt_size_errors" },
  6357. { "tx_underflow_errors" },
  6358. { "rx_local_faults" },
  6359. { "rx_remote_faults" },
  6360. { "rx_link_faults" },
  6361. { "rx_align_errors" },
  6362. { "rx_frags" },
  6363. { "rx_mcasts" },
  6364. { "rx_bcasts" },
  6365. { "rx_hist_cnt1" },
  6366. { "rx_hist_cnt2" },
  6367. { "rx_hist_cnt3" },
  6368. { "rx_hist_cnt4" },
  6369. { "rx_hist_cnt5" },
  6370. { "rx_hist_cnt6" },
  6371. { "rx_hist_cnt7" },
  6372. { "rx_octets" },
  6373. { "rx_code_violations" },
  6374. { "rx_len_errors" },
  6375. { "rx_crc_errors" },
  6376. { "rx_underflows" },
  6377. { "rx_overflows" },
  6378. { "pause_off_state" },
  6379. { "pause_on_state" },
  6380. { "pause_received" },
  6381. };
  6382. #define NUM_XMAC_STAT_KEYS ARRAY_SIZE(niu_xmac_stat_keys)
  6383. static const struct {
  6384. const char string[ETH_GSTRING_LEN];
  6385. } niu_bmac_stat_keys[] = {
  6386. { "tx_underflow_errors" },
  6387. { "tx_max_pkt_size_errors" },
  6388. { "tx_bytes" },
  6389. { "tx_frames" },
  6390. { "rx_overflows" },
  6391. { "rx_frames" },
  6392. { "rx_align_errors" },
  6393. { "rx_crc_errors" },
  6394. { "rx_len_errors" },
  6395. { "pause_off_state" },
  6396. { "pause_on_state" },
  6397. { "pause_received" },
  6398. };
  6399. #define NUM_BMAC_STAT_KEYS ARRAY_SIZE(niu_bmac_stat_keys)
  6400. static const struct {
  6401. const char string[ETH_GSTRING_LEN];
  6402. } niu_rxchan_stat_keys[] = {
  6403. { "rx_channel" },
  6404. { "rx_packets" },
  6405. { "rx_bytes" },
  6406. { "rx_dropped" },
  6407. { "rx_errors" },
  6408. };
  6409. #define NUM_RXCHAN_STAT_KEYS ARRAY_SIZE(niu_rxchan_stat_keys)
  6410. static const struct {
  6411. const char string[ETH_GSTRING_LEN];
  6412. } niu_txchan_stat_keys[] = {
  6413. { "tx_channel" },
  6414. { "tx_packets" },
  6415. { "tx_bytes" },
  6416. { "tx_errors" },
  6417. };
  6418. #define NUM_TXCHAN_STAT_KEYS ARRAY_SIZE(niu_txchan_stat_keys)
  6419. static void niu_get_strings(struct net_device *dev, u32 stringset, u8 *data)
  6420. {
  6421. struct niu *np = netdev_priv(dev);
  6422. int i;
  6423. if (stringset != ETH_SS_STATS)
  6424. return;
  6425. if (np->flags & NIU_FLAGS_XMAC) {
  6426. memcpy(data, niu_xmac_stat_keys,
  6427. sizeof(niu_xmac_stat_keys));
  6428. data += sizeof(niu_xmac_stat_keys);
  6429. } else {
  6430. memcpy(data, niu_bmac_stat_keys,
  6431. sizeof(niu_bmac_stat_keys));
  6432. data += sizeof(niu_bmac_stat_keys);
  6433. }
  6434. for (i = 0; i < np->num_rx_rings; i++) {
  6435. memcpy(data, niu_rxchan_stat_keys,
  6436. sizeof(niu_rxchan_stat_keys));
  6437. data += sizeof(niu_rxchan_stat_keys);
  6438. }
  6439. for (i = 0; i < np->num_tx_rings; i++) {
  6440. memcpy(data, niu_txchan_stat_keys,
  6441. sizeof(niu_txchan_stat_keys));
  6442. data += sizeof(niu_txchan_stat_keys);
  6443. }
  6444. }
  6445. static int niu_get_sset_count(struct net_device *dev, int stringset)
  6446. {
  6447. struct niu *np = netdev_priv(dev);
  6448. if (stringset != ETH_SS_STATS)
  6449. return -EINVAL;
  6450. return (np->flags & NIU_FLAGS_XMAC ?
  6451. NUM_XMAC_STAT_KEYS :
  6452. NUM_BMAC_STAT_KEYS) +
  6453. (np->num_rx_rings * NUM_RXCHAN_STAT_KEYS) +
  6454. (np->num_tx_rings * NUM_TXCHAN_STAT_KEYS);
  6455. }
  6456. static void niu_get_ethtool_stats(struct net_device *dev,
  6457. struct ethtool_stats *stats, u64 *data)
  6458. {
  6459. struct niu *np = netdev_priv(dev);
  6460. int i;
  6461. niu_sync_mac_stats(np);
  6462. if (np->flags & NIU_FLAGS_XMAC) {
  6463. memcpy(data, &np->mac_stats.xmac,
  6464. sizeof(struct niu_xmac_stats));
  6465. data += (sizeof(struct niu_xmac_stats) / sizeof(u64));
  6466. } else {
  6467. memcpy(data, &np->mac_stats.bmac,
  6468. sizeof(struct niu_bmac_stats));
  6469. data += (sizeof(struct niu_bmac_stats) / sizeof(u64));
  6470. }
  6471. for (i = 0; i < np->num_rx_rings; i++) {
  6472. struct rx_ring_info *rp = &np->rx_rings[i];
  6473. niu_sync_rx_discard_stats(np, rp, 0);
  6474. data[0] = rp->rx_channel;
  6475. data[1] = rp->rx_packets;
  6476. data[2] = rp->rx_bytes;
  6477. data[3] = rp->rx_dropped;
  6478. data[4] = rp->rx_errors;
  6479. data += 5;
  6480. }
  6481. for (i = 0; i < np->num_tx_rings; i++) {
  6482. struct tx_ring_info *rp = &np->tx_rings[i];
  6483. data[0] = rp->tx_channel;
  6484. data[1] = rp->tx_packets;
  6485. data[2] = rp->tx_bytes;
  6486. data[3] = rp->tx_errors;
  6487. data += 4;
  6488. }
  6489. }
  6490. static u64 niu_led_state_save(struct niu *np)
  6491. {
  6492. if (np->flags & NIU_FLAGS_XMAC)
  6493. return nr64_mac(XMAC_CONFIG);
  6494. else
  6495. return nr64_mac(BMAC_XIF_CONFIG);
  6496. }
  6497. static void niu_led_state_restore(struct niu *np, u64 val)
  6498. {
  6499. if (np->flags & NIU_FLAGS_XMAC)
  6500. nw64_mac(XMAC_CONFIG, val);
  6501. else
  6502. nw64_mac(BMAC_XIF_CONFIG, val);
  6503. }
  6504. static void niu_force_led(struct niu *np, int on)
  6505. {
  6506. u64 val, reg, bit;
  6507. if (np->flags & NIU_FLAGS_XMAC) {
  6508. reg = XMAC_CONFIG;
  6509. bit = XMAC_CONFIG_FORCE_LED_ON;
  6510. } else {
  6511. reg = BMAC_XIF_CONFIG;
  6512. bit = BMAC_XIF_CONFIG_LINK_LED;
  6513. }
  6514. val = nr64_mac(reg);
  6515. if (on)
  6516. val |= bit;
  6517. else
  6518. val &= ~bit;
  6519. nw64_mac(reg, val);
  6520. }
  6521. static int niu_set_phys_id(struct net_device *dev,
  6522. enum ethtool_phys_id_state state)
  6523. {
  6524. struct niu *np = netdev_priv(dev);
  6525. if (!netif_running(dev))
  6526. return -EAGAIN;
  6527. switch (state) {
  6528. case ETHTOOL_ID_ACTIVE:
  6529. np->orig_led_state = niu_led_state_save(np);
  6530. return 1; /* cycle on/off once per second */
  6531. case ETHTOOL_ID_ON:
  6532. niu_force_led(np, 1);
  6533. break;
  6534. case ETHTOOL_ID_OFF:
  6535. niu_force_led(np, 0);
  6536. break;
  6537. case ETHTOOL_ID_INACTIVE:
  6538. niu_led_state_restore(np, np->orig_led_state);
  6539. }
  6540. return 0;
  6541. }
  6542. static const struct ethtool_ops niu_ethtool_ops = {
  6543. .get_drvinfo = niu_get_drvinfo,
  6544. .get_link = ethtool_op_get_link,
  6545. .get_msglevel = niu_get_msglevel,
  6546. .set_msglevel = niu_set_msglevel,
  6547. .nway_reset = niu_nway_reset,
  6548. .get_eeprom_len = niu_get_eeprom_len,
  6549. .get_eeprom = niu_get_eeprom,
  6550. .get_strings = niu_get_strings,
  6551. .get_sset_count = niu_get_sset_count,
  6552. .get_ethtool_stats = niu_get_ethtool_stats,
  6553. .set_phys_id = niu_set_phys_id,
  6554. .get_rxnfc = niu_get_nfc,
  6555. .set_rxnfc = niu_set_nfc,
  6556. .get_rx_ring_count = niu_get_rx_ring_count,
  6557. .get_rxfh_fields = niu_get_rxfh_fields,
  6558. .set_rxfh_fields = niu_set_rxfh_fields,
  6559. .get_link_ksettings = niu_get_link_ksettings,
  6560. .set_link_ksettings = niu_set_link_ksettings,
  6561. };
  6562. static int niu_ldg_assign_ldn(struct niu *np, struct niu_parent *parent,
  6563. int ldg, int ldn)
  6564. {
  6565. if (ldg < NIU_LDG_MIN || ldg > NIU_LDG_MAX)
  6566. return -EINVAL;
  6567. if (ldn < 0 || ldn > LDN_MAX)
  6568. return -EINVAL;
  6569. parent->ldg_map[ldn] = ldg;
  6570. if (np->parent->plat_type == PLAT_TYPE_NIU) {
  6571. /* On N2 NIU, the ldn-->ldg assignments are setup and fixed by
  6572. * the firmware, and we're not supposed to change them.
  6573. * Validate the mapping, because if it's wrong we probably
  6574. * won't get any interrupts and that's painful to debug.
  6575. */
  6576. if (nr64(LDG_NUM(ldn)) != ldg) {
  6577. dev_err(np->device, "Port %u, mismatched LDG assignment for ldn %d, should be %d is %llu\n",
  6578. np->port, ldn, ldg,
  6579. (unsigned long long) nr64(LDG_NUM(ldn)));
  6580. return -EINVAL;
  6581. }
  6582. } else
  6583. nw64(LDG_NUM(ldn), ldg);
  6584. return 0;
  6585. }
  6586. static int niu_set_ldg_timer_res(struct niu *np, int res)
  6587. {
  6588. if (res < 0 || res > LDG_TIMER_RES_VAL)
  6589. return -EINVAL;
  6590. nw64(LDG_TIMER_RES, res);
  6591. return 0;
  6592. }
  6593. static int niu_set_ldg_sid(struct niu *np, int ldg, int func, int vector)
  6594. {
  6595. if ((ldg < NIU_LDG_MIN || ldg > NIU_LDG_MAX) ||
  6596. (func < 0 || func > 3) ||
  6597. (vector < 0 || vector > 0x1f))
  6598. return -EINVAL;
  6599. nw64(SID(ldg), (func << SID_FUNC_SHIFT) | vector);
  6600. return 0;
  6601. }
  6602. static int niu_pci_eeprom_read(struct niu *np, u32 addr)
  6603. {
  6604. u64 frame, frame_base = (ESPC_PIO_STAT_READ_START |
  6605. (addr << ESPC_PIO_STAT_ADDR_SHIFT));
  6606. int limit;
  6607. if (addr > (ESPC_PIO_STAT_ADDR >> ESPC_PIO_STAT_ADDR_SHIFT))
  6608. return -EINVAL;
  6609. frame = frame_base;
  6610. nw64(ESPC_PIO_STAT, frame);
  6611. limit = 64;
  6612. do {
  6613. udelay(5);
  6614. frame = nr64(ESPC_PIO_STAT);
  6615. if (frame & ESPC_PIO_STAT_READ_END)
  6616. break;
  6617. } while (limit--);
  6618. if (!(frame & ESPC_PIO_STAT_READ_END)) {
  6619. dev_err(np->device, "EEPROM read timeout frame[%llx]\n",
  6620. (unsigned long long) frame);
  6621. return -ENODEV;
  6622. }
  6623. frame = frame_base;
  6624. nw64(ESPC_PIO_STAT, frame);
  6625. limit = 64;
  6626. do {
  6627. udelay(5);
  6628. frame = nr64(ESPC_PIO_STAT);
  6629. if (frame & ESPC_PIO_STAT_READ_END)
  6630. break;
  6631. } while (limit--);
  6632. if (!(frame & ESPC_PIO_STAT_READ_END)) {
  6633. dev_err(np->device, "EEPROM read timeout frame[%llx]\n",
  6634. (unsigned long long) frame);
  6635. return -ENODEV;
  6636. }
  6637. frame = nr64(ESPC_PIO_STAT);
  6638. return (frame & ESPC_PIO_STAT_DATA) >> ESPC_PIO_STAT_DATA_SHIFT;
  6639. }
  6640. static int niu_pci_eeprom_read16(struct niu *np, u32 off)
  6641. {
  6642. int err = niu_pci_eeprom_read(np, off);
  6643. u16 val;
  6644. if (err < 0)
  6645. return err;
  6646. val = (err << 8);
  6647. err = niu_pci_eeprom_read(np, off + 1);
  6648. if (err < 0)
  6649. return err;
  6650. val |= (err & 0xff);
  6651. return val;
  6652. }
  6653. static int niu_pci_eeprom_read16_swp(struct niu *np, u32 off)
  6654. {
  6655. int err = niu_pci_eeprom_read(np, off);
  6656. u16 val;
  6657. if (err < 0)
  6658. return err;
  6659. val = (err & 0xff);
  6660. err = niu_pci_eeprom_read(np, off + 1);
  6661. if (err < 0)
  6662. return err;
  6663. val |= (err & 0xff) << 8;
  6664. return val;
  6665. }
  6666. static int niu_pci_vpd_get_propname(struct niu *np, u32 off, char *namebuf,
  6667. int namebuf_len)
  6668. {
  6669. int i;
  6670. for (i = 0; i < namebuf_len; i++) {
  6671. int err = niu_pci_eeprom_read(np, off + i);
  6672. if (err < 0)
  6673. return err;
  6674. *namebuf++ = err;
  6675. if (!err)
  6676. break;
  6677. }
  6678. if (i >= namebuf_len)
  6679. return -EINVAL;
  6680. return i + 1;
  6681. }
  6682. static void niu_vpd_parse_version(struct niu *np)
  6683. {
  6684. struct niu_vpd *vpd = &np->vpd;
  6685. int len = strlen(vpd->version) + 1;
  6686. const char *s = vpd->version;
  6687. int i;
  6688. for (i = 0; i < len - 5; i++) {
  6689. if (!strncmp(s + i, "FCode ", 6))
  6690. break;
  6691. }
  6692. if (i >= len - 5)
  6693. return;
  6694. s += i + 5;
  6695. sscanf(s, "%d.%d", &vpd->fcode_major, &vpd->fcode_minor);
  6696. netif_printk(np, probe, KERN_DEBUG, np->dev,
  6697. "VPD_SCAN: FCODE major(%d) minor(%d)\n",
  6698. vpd->fcode_major, vpd->fcode_minor);
  6699. if (vpd->fcode_major > NIU_VPD_MIN_MAJOR ||
  6700. (vpd->fcode_major == NIU_VPD_MIN_MAJOR &&
  6701. vpd->fcode_minor >= NIU_VPD_MIN_MINOR))
  6702. np->flags |= NIU_FLAGS_VPD_VALID;
  6703. }
  6704. /* ESPC_PIO_EN_ENABLE must be set */
  6705. static int niu_pci_vpd_scan_props(struct niu *np, u32 start, u32 end)
  6706. {
  6707. unsigned int found_mask = 0;
  6708. #define FOUND_MASK_MODEL 0x00000001
  6709. #define FOUND_MASK_BMODEL 0x00000002
  6710. #define FOUND_MASK_VERS 0x00000004
  6711. #define FOUND_MASK_MAC 0x00000008
  6712. #define FOUND_MASK_NMAC 0x00000010
  6713. #define FOUND_MASK_PHY 0x00000020
  6714. #define FOUND_MASK_ALL 0x0000003f
  6715. netif_printk(np, probe, KERN_DEBUG, np->dev,
  6716. "VPD_SCAN: start[%x] end[%x]\n", start, end);
  6717. while (start < end) {
  6718. int len, err, prop_len;
  6719. char namebuf[64];
  6720. u8 *prop_buf;
  6721. int max_len;
  6722. if (found_mask == FOUND_MASK_ALL) {
  6723. niu_vpd_parse_version(np);
  6724. return 1;
  6725. }
  6726. err = niu_pci_eeprom_read(np, start + 2);
  6727. if (err < 0)
  6728. return err;
  6729. len = err;
  6730. start += 3;
  6731. prop_len = niu_pci_eeprom_read(np, start + 4);
  6732. if (prop_len < 0)
  6733. return prop_len;
  6734. err = niu_pci_vpd_get_propname(np, start + 5, namebuf, 64);
  6735. if (err < 0)
  6736. return err;
  6737. prop_buf = NULL;
  6738. max_len = 0;
  6739. if (!strcmp(namebuf, "model")) {
  6740. prop_buf = np->vpd.model;
  6741. max_len = NIU_VPD_MODEL_MAX;
  6742. found_mask |= FOUND_MASK_MODEL;
  6743. } else if (!strcmp(namebuf, "board-model")) {
  6744. prop_buf = np->vpd.board_model;
  6745. max_len = NIU_VPD_BD_MODEL_MAX;
  6746. found_mask |= FOUND_MASK_BMODEL;
  6747. } else if (!strcmp(namebuf, "version")) {
  6748. prop_buf = np->vpd.version;
  6749. max_len = NIU_VPD_VERSION_MAX;
  6750. found_mask |= FOUND_MASK_VERS;
  6751. } else if (!strcmp(namebuf, "local-mac-address")) {
  6752. prop_buf = np->vpd.local_mac;
  6753. max_len = ETH_ALEN;
  6754. found_mask |= FOUND_MASK_MAC;
  6755. } else if (!strcmp(namebuf, "num-mac-addresses")) {
  6756. prop_buf = &np->vpd.mac_num;
  6757. max_len = 1;
  6758. found_mask |= FOUND_MASK_NMAC;
  6759. } else if (!strcmp(namebuf, "phy-type")) {
  6760. prop_buf = np->vpd.phy_type;
  6761. max_len = NIU_VPD_PHY_TYPE_MAX;
  6762. found_mask |= FOUND_MASK_PHY;
  6763. }
  6764. if (max_len && prop_len > max_len) {
  6765. dev_err(np->device, "Property '%s' length (%d) is too long\n", namebuf, prop_len);
  6766. return -EINVAL;
  6767. }
  6768. if (prop_buf) {
  6769. u32 off = start + 5 + err;
  6770. int i;
  6771. netif_printk(np, probe, KERN_DEBUG, np->dev,
  6772. "VPD_SCAN: Reading in property [%s] len[%d]\n",
  6773. namebuf, prop_len);
  6774. for (i = 0; i < prop_len; i++) {
  6775. err = niu_pci_eeprom_read(np, off + i);
  6776. if (err < 0)
  6777. return err;
  6778. *prop_buf++ = err;
  6779. }
  6780. }
  6781. start += len;
  6782. }
  6783. return 0;
  6784. }
  6785. /* ESPC_PIO_EN_ENABLE must be set */
  6786. static int niu_pci_vpd_fetch(struct niu *np, u32 start)
  6787. {
  6788. u32 offset;
  6789. int err;
  6790. err = niu_pci_eeprom_read16_swp(np, start + 1);
  6791. if (err < 0)
  6792. return err;
  6793. offset = err + 3;
  6794. while (start + offset < ESPC_EEPROM_SIZE) {
  6795. u32 here = start + offset;
  6796. u32 end;
  6797. err = niu_pci_eeprom_read(np, here);
  6798. if (err < 0)
  6799. return err;
  6800. if (err != 0x90)
  6801. return -EINVAL;
  6802. err = niu_pci_eeprom_read16_swp(np, here + 1);
  6803. if (err < 0)
  6804. return err;
  6805. here = start + offset + 3;
  6806. end = start + offset + err;
  6807. offset += err;
  6808. err = niu_pci_vpd_scan_props(np, here, end);
  6809. if (err < 0)
  6810. return err;
  6811. /* ret == 1 is not an error */
  6812. if (err == 1)
  6813. return 0;
  6814. }
  6815. return 0;
  6816. }
  6817. /* ESPC_PIO_EN_ENABLE must be set */
  6818. static u32 niu_pci_vpd_offset(struct niu *np)
  6819. {
  6820. u32 start = 0, end = ESPC_EEPROM_SIZE, ret;
  6821. int err;
  6822. while (start < end) {
  6823. ret = start;
  6824. /* ROM header signature? */
  6825. err = niu_pci_eeprom_read16(np, start + 0);
  6826. if (err != 0x55aa)
  6827. return 0;
  6828. /* Apply offset to PCI data structure. */
  6829. err = niu_pci_eeprom_read16(np, start + 23);
  6830. if (err < 0)
  6831. return 0;
  6832. start += err;
  6833. /* Check for "PCIR" signature. */
  6834. err = niu_pci_eeprom_read16(np, start + 0);
  6835. if (err != 0x5043)
  6836. return 0;
  6837. err = niu_pci_eeprom_read16(np, start + 2);
  6838. if (err != 0x4952)
  6839. return 0;
  6840. /* Check for OBP image type. */
  6841. err = niu_pci_eeprom_read(np, start + 20);
  6842. if (err < 0)
  6843. return 0;
  6844. if (err != 0x01) {
  6845. err = niu_pci_eeprom_read(np, ret + 2);
  6846. if (err < 0)
  6847. return 0;
  6848. start = ret + (err * 512);
  6849. continue;
  6850. }
  6851. err = niu_pci_eeprom_read16_swp(np, start + 8);
  6852. if (err < 0)
  6853. return err;
  6854. ret += err;
  6855. err = niu_pci_eeprom_read(np, ret + 0);
  6856. if (err != 0x82)
  6857. return 0;
  6858. return ret;
  6859. }
  6860. return 0;
  6861. }
  6862. static int niu_phy_type_prop_decode(struct niu *np, const char *phy_prop)
  6863. {
  6864. if (!strcmp(phy_prop, "mif")) {
  6865. /* 1G copper, MII */
  6866. np->flags &= ~(NIU_FLAGS_FIBER |
  6867. NIU_FLAGS_10G);
  6868. np->mac_xcvr = MAC_XCVR_MII;
  6869. } else if (!strcmp(phy_prop, "xgf")) {
  6870. /* 10G fiber, XPCS */
  6871. np->flags |= (NIU_FLAGS_10G |
  6872. NIU_FLAGS_FIBER);
  6873. np->mac_xcvr = MAC_XCVR_XPCS;
  6874. } else if (!strcmp(phy_prop, "pcs")) {
  6875. /* 1G fiber, PCS */
  6876. np->flags &= ~NIU_FLAGS_10G;
  6877. np->flags |= NIU_FLAGS_FIBER;
  6878. np->mac_xcvr = MAC_XCVR_PCS;
  6879. } else if (!strcmp(phy_prop, "xgc")) {
  6880. /* 10G copper, XPCS */
  6881. np->flags |= NIU_FLAGS_10G;
  6882. np->flags &= ~NIU_FLAGS_FIBER;
  6883. np->mac_xcvr = MAC_XCVR_XPCS;
  6884. } else if (!strcmp(phy_prop, "xgsd") || !strcmp(phy_prop, "gsd")) {
  6885. /* 10G Serdes or 1G Serdes, default to 10G */
  6886. np->flags |= NIU_FLAGS_10G;
  6887. np->flags &= ~NIU_FLAGS_FIBER;
  6888. np->flags |= NIU_FLAGS_XCVR_SERDES;
  6889. np->mac_xcvr = MAC_XCVR_XPCS;
  6890. } else {
  6891. return -EINVAL;
  6892. }
  6893. return 0;
  6894. }
  6895. static int niu_pci_vpd_get_nports(struct niu *np)
  6896. {
  6897. int ports = 0;
  6898. if ((!strcmp(np->vpd.model, NIU_QGC_LP_MDL_STR)) ||
  6899. (!strcmp(np->vpd.model, NIU_QGC_PEM_MDL_STR)) ||
  6900. (!strcmp(np->vpd.model, NIU_MARAMBA_MDL_STR)) ||
  6901. (!strcmp(np->vpd.model, NIU_KIMI_MDL_STR)) ||
  6902. (!strcmp(np->vpd.model, NIU_ALONSO_MDL_STR))) {
  6903. ports = 4;
  6904. } else if ((!strcmp(np->vpd.model, NIU_2XGF_LP_MDL_STR)) ||
  6905. (!strcmp(np->vpd.model, NIU_2XGF_PEM_MDL_STR)) ||
  6906. (!strcmp(np->vpd.model, NIU_FOXXY_MDL_STR)) ||
  6907. (!strcmp(np->vpd.model, NIU_2XGF_MRVL_MDL_STR))) {
  6908. ports = 2;
  6909. }
  6910. return ports;
  6911. }
  6912. static void niu_pci_vpd_validate(struct niu *np)
  6913. {
  6914. struct net_device *dev = np->dev;
  6915. struct niu_vpd *vpd = &np->vpd;
  6916. u8 addr[ETH_ALEN];
  6917. u8 val8;
  6918. if (!is_valid_ether_addr(&vpd->local_mac[0])) {
  6919. dev_err(np->device, "VPD MAC invalid, falling back to SPROM\n");
  6920. np->flags &= ~NIU_FLAGS_VPD_VALID;
  6921. return;
  6922. }
  6923. if (!strcmp(np->vpd.model, NIU_ALONSO_MDL_STR) ||
  6924. !strcmp(np->vpd.model, NIU_KIMI_MDL_STR)) {
  6925. np->flags |= NIU_FLAGS_10G;
  6926. np->flags &= ~NIU_FLAGS_FIBER;
  6927. np->flags |= NIU_FLAGS_XCVR_SERDES;
  6928. np->mac_xcvr = MAC_XCVR_PCS;
  6929. if (np->port > 1) {
  6930. np->flags |= NIU_FLAGS_FIBER;
  6931. np->flags &= ~NIU_FLAGS_10G;
  6932. }
  6933. if (np->flags & NIU_FLAGS_10G)
  6934. np->mac_xcvr = MAC_XCVR_XPCS;
  6935. } else if (!strcmp(np->vpd.model, NIU_FOXXY_MDL_STR)) {
  6936. np->flags |= (NIU_FLAGS_10G | NIU_FLAGS_FIBER |
  6937. NIU_FLAGS_HOTPLUG_PHY);
  6938. } else if (niu_phy_type_prop_decode(np, np->vpd.phy_type)) {
  6939. dev_err(np->device, "Illegal phy string [%s]\n",
  6940. np->vpd.phy_type);
  6941. dev_err(np->device, "Falling back to SPROM\n");
  6942. np->flags &= ~NIU_FLAGS_VPD_VALID;
  6943. return;
  6944. }
  6945. ether_addr_copy(addr, vpd->local_mac);
  6946. val8 = addr[5];
  6947. addr[5] += np->port;
  6948. if (addr[5] < val8)
  6949. addr[4]++;
  6950. eth_hw_addr_set(dev, addr);
  6951. }
  6952. static int niu_pci_probe_sprom(struct niu *np)
  6953. {
  6954. struct net_device *dev = np->dev;
  6955. u8 addr[ETH_ALEN];
  6956. int len, i;
  6957. u64 val, sum;
  6958. u8 val8;
  6959. val = (nr64(ESPC_VER_IMGSZ) & ESPC_VER_IMGSZ_IMGSZ);
  6960. val >>= ESPC_VER_IMGSZ_IMGSZ_SHIFT;
  6961. len = val / 4;
  6962. np->eeprom_len = len;
  6963. netif_printk(np, probe, KERN_DEBUG, np->dev,
  6964. "SPROM: Image size %llu\n", (unsigned long long)val);
  6965. sum = 0;
  6966. for (i = 0; i < len; i++) {
  6967. val = nr64(ESPC_NCR(i));
  6968. sum += (val >> 0) & 0xff;
  6969. sum += (val >> 8) & 0xff;
  6970. sum += (val >> 16) & 0xff;
  6971. sum += (val >> 24) & 0xff;
  6972. }
  6973. netif_printk(np, probe, KERN_DEBUG, np->dev,
  6974. "SPROM: Checksum %x\n", (int)(sum & 0xff));
  6975. if ((sum & 0xff) != 0xab) {
  6976. dev_err(np->device, "Bad SPROM checksum (%x, should be 0xab)\n", (int)(sum & 0xff));
  6977. return -EINVAL;
  6978. }
  6979. val = nr64(ESPC_PHY_TYPE);
  6980. switch (np->port) {
  6981. case 0:
  6982. val8 = (val & ESPC_PHY_TYPE_PORT0) >>
  6983. ESPC_PHY_TYPE_PORT0_SHIFT;
  6984. break;
  6985. case 1:
  6986. val8 = (val & ESPC_PHY_TYPE_PORT1) >>
  6987. ESPC_PHY_TYPE_PORT1_SHIFT;
  6988. break;
  6989. case 2:
  6990. val8 = (val & ESPC_PHY_TYPE_PORT2) >>
  6991. ESPC_PHY_TYPE_PORT2_SHIFT;
  6992. break;
  6993. case 3:
  6994. val8 = (val & ESPC_PHY_TYPE_PORT3) >>
  6995. ESPC_PHY_TYPE_PORT3_SHIFT;
  6996. break;
  6997. default:
  6998. dev_err(np->device, "Bogus port number %u\n",
  6999. np->port);
  7000. return -EINVAL;
  7001. }
  7002. netif_printk(np, probe, KERN_DEBUG, np->dev,
  7003. "SPROM: PHY type %x\n", val8);
  7004. switch (val8) {
  7005. case ESPC_PHY_TYPE_1G_COPPER:
  7006. /* 1G copper, MII */
  7007. np->flags &= ~(NIU_FLAGS_FIBER |
  7008. NIU_FLAGS_10G);
  7009. np->mac_xcvr = MAC_XCVR_MII;
  7010. break;
  7011. case ESPC_PHY_TYPE_1G_FIBER:
  7012. /* 1G fiber, PCS */
  7013. np->flags &= ~NIU_FLAGS_10G;
  7014. np->flags |= NIU_FLAGS_FIBER;
  7015. np->mac_xcvr = MAC_XCVR_PCS;
  7016. break;
  7017. case ESPC_PHY_TYPE_10G_COPPER:
  7018. /* 10G copper, XPCS */
  7019. np->flags |= NIU_FLAGS_10G;
  7020. np->flags &= ~NIU_FLAGS_FIBER;
  7021. np->mac_xcvr = MAC_XCVR_XPCS;
  7022. break;
  7023. case ESPC_PHY_TYPE_10G_FIBER:
  7024. /* 10G fiber, XPCS */
  7025. np->flags |= (NIU_FLAGS_10G |
  7026. NIU_FLAGS_FIBER);
  7027. np->mac_xcvr = MAC_XCVR_XPCS;
  7028. break;
  7029. default:
  7030. dev_err(np->device, "Bogus SPROM phy type %u\n", val8);
  7031. return -EINVAL;
  7032. }
  7033. val = nr64(ESPC_MAC_ADDR0);
  7034. netif_printk(np, probe, KERN_DEBUG, np->dev,
  7035. "SPROM: MAC_ADDR0[%08llx]\n", (unsigned long long)val);
  7036. addr[0] = (val >> 0) & 0xff;
  7037. addr[1] = (val >> 8) & 0xff;
  7038. addr[2] = (val >> 16) & 0xff;
  7039. addr[3] = (val >> 24) & 0xff;
  7040. val = nr64(ESPC_MAC_ADDR1);
  7041. netif_printk(np, probe, KERN_DEBUG, np->dev,
  7042. "SPROM: MAC_ADDR1[%08llx]\n", (unsigned long long)val);
  7043. addr[4] = (val >> 0) & 0xff;
  7044. addr[5] = (val >> 8) & 0xff;
  7045. if (!is_valid_ether_addr(addr)) {
  7046. dev_err(np->device, "SPROM MAC address invalid [ %pM ]\n",
  7047. addr);
  7048. return -EINVAL;
  7049. }
  7050. val8 = addr[5];
  7051. addr[5] += np->port;
  7052. if (addr[5] < val8)
  7053. addr[4]++;
  7054. eth_hw_addr_set(dev, addr);
  7055. val = nr64(ESPC_MOD_STR_LEN);
  7056. netif_printk(np, probe, KERN_DEBUG, np->dev,
  7057. "SPROM: MOD_STR_LEN[%llu]\n", (unsigned long long)val);
  7058. if (val >= 8 * 4)
  7059. return -EINVAL;
  7060. for (i = 0; i < val; i += 4) {
  7061. u64 tmp = nr64(ESPC_NCR(5 + (i / 4)));
  7062. np->vpd.model[i + 3] = (tmp >> 0) & 0xff;
  7063. np->vpd.model[i + 2] = (tmp >> 8) & 0xff;
  7064. np->vpd.model[i + 1] = (tmp >> 16) & 0xff;
  7065. np->vpd.model[i + 0] = (tmp >> 24) & 0xff;
  7066. }
  7067. np->vpd.model[val] = '\0';
  7068. val = nr64(ESPC_BD_MOD_STR_LEN);
  7069. netif_printk(np, probe, KERN_DEBUG, np->dev,
  7070. "SPROM: BD_MOD_STR_LEN[%llu]\n", (unsigned long long)val);
  7071. if (val >= 4 * 4)
  7072. return -EINVAL;
  7073. for (i = 0; i < val; i += 4) {
  7074. u64 tmp = nr64(ESPC_NCR(14 + (i / 4)));
  7075. np->vpd.board_model[i + 3] = (tmp >> 0) & 0xff;
  7076. np->vpd.board_model[i + 2] = (tmp >> 8) & 0xff;
  7077. np->vpd.board_model[i + 1] = (tmp >> 16) & 0xff;
  7078. np->vpd.board_model[i + 0] = (tmp >> 24) & 0xff;
  7079. }
  7080. np->vpd.board_model[val] = '\0';
  7081. np->vpd.mac_num =
  7082. nr64(ESPC_NUM_PORTS_MACS) & ESPC_NUM_PORTS_MACS_VAL;
  7083. netif_printk(np, probe, KERN_DEBUG, np->dev,
  7084. "SPROM: NUM_PORTS_MACS[%d]\n", np->vpd.mac_num);
  7085. return 0;
  7086. }
  7087. static int niu_get_and_validate_port(struct niu *np)
  7088. {
  7089. struct niu_parent *parent = np->parent;
  7090. if (np->port <= 1)
  7091. np->flags |= NIU_FLAGS_XMAC;
  7092. if (!parent->num_ports) {
  7093. if (parent->plat_type == PLAT_TYPE_NIU) {
  7094. parent->num_ports = 2;
  7095. } else {
  7096. parent->num_ports = niu_pci_vpd_get_nports(np);
  7097. if (!parent->num_ports) {
  7098. /* Fall back to SPROM as last resort.
  7099. * This will fail on most cards.
  7100. */
  7101. parent->num_ports = nr64(ESPC_NUM_PORTS_MACS) &
  7102. ESPC_NUM_PORTS_MACS_VAL;
  7103. /* All of the current probing methods fail on
  7104. * Maramba on-board parts.
  7105. */
  7106. if (!parent->num_ports)
  7107. parent->num_ports = 4;
  7108. }
  7109. }
  7110. }
  7111. if (np->port >= parent->num_ports)
  7112. return -ENODEV;
  7113. return 0;
  7114. }
  7115. static int phy_record(struct niu_parent *parent, struct phy_probe_info *p,
  7116. int dev_id_1, int dev_id_2, u8 phy_port, int type)
  7117. {
  7118. u32 id = (dev_id_1 << 16) | dev_id_2;
  7119. u8 idx;
  7120. if (dev_id_1 < 0 || dev_id_2 < 0)
  7121. return 0;
  7122. if (type == PHY_TYPE_PMA_PMD || type == PHY_TYPE_PCS) {
  7123. /* Because of the NIU_PHY_ID_MASK being applied, the 8704
  7124. * test covers the 8706 as well.
  7125. */
  7126. if (((id & NIU_PHY_ID_MASK) != NIU_PHY_ID_BCM8704) &&
  7127. ((id & NIU_PHY_ID_MASK) != NIU_PHY_ID_MRVL88X2011))
  7128. return 0;
  7129. } else {
  7130. if ((id & NIU_PHY_ID_MASK) != NIU_PHY_ID_BCM5464R)
  7131. return 0;
  7132. }
  7133. pr_info("niu%d: Found PHY %08x type %s at phy_port %u\n",
  7134. parent->index, id,
  7135. type == PHY_TYPE_PMA_PMD ? "PMA/PMD" :
  7136. type == PHY_TYPE_PCS ? "PCS" : "MII",
  7137. phy_port);
  7138. if (p->cur[type] >= NIU_MAX_PORTS) {
  7139. pr_err("Too many PHY ports\n");
  7140. return -EINVAL;
  7141. }
  7142. idx = p->cur[type];
  7143. p->phy_id[type][idx] = id;
  7144. p->phy_port[type][idx] = phy_port;
  7145. p->cur[type] = idx + 1;
  7146. return 0;
  7147. }
  7148. static int port_has_10g(struct phy_probe_info *p, int port)
  7149. {
  7150. int i;
  7151. for (i = 0; i < p->cur[PHY_TYPE_PMA_PMD]; i++) {
  7152. if (p->phy_port[PHY_TYPE_PMA_PMD][i] == port)
  7153. return 1;
  7154. }
  7155. for (i = 0; i < p->cur[PHY_TYPE_PCS]; i++) {
  7156. if (p->phy_port[PHY_TYPE_PCS][i] == port)
  7157. return 1;
  7158. }
  7159. return 0;
  7160. }
  7161. static int count_10g_ports(struct phy_probe_info *p, int *lowest)
  7162. {
  7163. int port, cnt;
  7164. cnt = 0;
  7165. *lowest = 32;
  7166. for (port = 8; port < 32; port++) {
  7167. if (port_has_10g(p, port)) {
  7168. if (!cnt)
  7169. *lowest = port;
  7170. cnt++;
  7171. }
  7172. }
  7173. return cnt;
  7174. }
  7175. static int count_1g_ports(struct phy_probe_info *p, int *lowest)
  7176. {
  7177. *lowest = 32;
  7178. if (p->cur[PHY_TYPE_MII])
  7179. *lowest = p->phy_port[PHY_TYPE_MII][0];
  7180. return p->cur[PHY_TYPE_MII];
  7181. }
  7182. static void niu_n2_divide_channels(struct niu_parent *parent)
  7183. {
  7184. int num_ports = parent->num_ports;
  7185. int i;
  7186. for (i = 0; i < num_ports; i++) {
  7187. parent->rxchan_per_port[i] = (16 / num_ports);
  7188. parent->txchan_per_port[i] = (16 / num_ports);
  7189. pr_info("niu%d: Port %u [%u RX chans] [%u TX chans]\n",
  7190. parent->index, i,
  7191. parent->rxchan_per_port[i],
  7192. parent->txchan_per_port[i]);
  7193. }
  7194. }
  7195. static void niu_divide_channels(struct niu_parent *parent,
  7196. int num_10g, int num_1g)
  7197. {
  7198. int num_ports = parent->num_ports;
  7199. int rx_chans_per_10g, rx_chans_per_1g;
  7200. int tx_chans_per_10g, tx_chans_per_1g;
  7201. int i, tot_rx, tot_tx;
  7202. if (!num_10g || !num_1g) {
  7203. rx_chans_per_10g = rx_chans_per_1g =
  7204. (NIU_NUM_RXCHAN / num_ports);
  7205. tx_chans_per_10g = tx_chans_per_1g =
  7206. (NIU_NUM_TXCHAN / num_ports);
  7207. } else {
  7208. rx_chans_per_1g = NIU_NUM_RXCHAN / 8;
  7209. rx_chans_per_10g = (NIU_NUM_RXCHAN -
  7210. (rx_chans_per_1g * num_1g)) /
  7211. num_10g;
  7212. tx_chans_per_1g = NIU_NUM_TXCHAN / 6;
  7213. tx_chans_per_10g = (NIU_NUM_TXCHAN -
  7214. (tx_chans_per_1g * num_1g)) /
  7215. num_10g;
  7216. }
  7217. tot_rx = tot_tx = 0;
  7218. for (i = 0; i < num_ports; i++) {
  7219. int type = phy_decode(parent->port_phy, i);
  7220. if (type == PORT_TYPE_10G) {
  7221. parent->rxchan_per_port[i] = rx_chans_per_10g;
  7222. parent->txchan_per_port[i] = tx_chans_per_10g;
  7223. } else {
  7224. parent->rxchan_per_port[i] = rx_chans_per_1g;
  7225. parent->txchan_per_port[i] = tx_chans_per_1g;
  7226. }
  7227. pr_info("niu%d: Port %u [%u RX chans] [%u TX chans]\n",
  7228. parent->index, i,
  7229. parent->rxchan_per_port[i],
  7230. parent->txchan_per_port[i]);
  7231. tot_rx += parent->rxchan_per_port[i];
  7232. tot_tx += parent->txchan_per_port[i];
  7233. }
  7234. if (tot_rx > NIU_NUM_RXCHAN) {
  7235. pr_err("niu%d: Too many RX channels (%d), resetting to one per port\n",
  7236. parent->index, tot_rx);
  7237. for (i = 0; i < num_ports; i++)
  7238. parent->rxchan_per_port[i] = 1;
  7239. }
  7240. if (tot_tx > NIU_NUM_TXCHAN) {
  7241. pr_err("niu%d: Too many TX channels (%d), resetting to one per port\n",
  7242. parent->index, tot_tx);
  7243. for (i = 0; i < num_ports; i++)
  7244. parent->txchan_per_port[i] = 1;
  7245. }
  7246. if (tot_rx < NIU_NUM_RXCHAN || tot_tx < NIU_NUM_TXCHAN) {
  7247. pr_warn("niu%d: Driver bug, wasted channels, RX[%d] TX[%d]\n",
  7248. parent->index, tot_rx, tot_tx);
  7249. }
  7250. }
  7251. static void niu_divide_rdc_groups(struct niu_parent *parent,
  7252. int num_10g, int num_1g)
  7253. {
  7254. int i, num_ports = parent->num_ports;
  7255. int rdc_group, rdc_groups_per_port;
  7256. int rdc_channel_base;
  7257. rdc_group = 0;
  7258. rdc_groups_per_port = NIU_NUM_RDC_TABLES / num_ports;
  7259. rdc_channel_base = 0;
  7260. for (i = 0; i < num_ports; i++) {
  7261. struct niu_rdc_tables *tp = &parent->rdc_group_cfg[i];
  7262. int grp, num_channels = parent->rxchan_per_port[i];
  7263. int this_channel_offset;
  7264. tp->first_table_num = rdc_group;
  7265. tp->num_tables = rdc_groups_per_port;
  7266. this_channel_offset = 0;
  7267. for (grp = 0; grp < tp->num_tables; grp++) {
  7268. struct rdc_table *rt = &tp->tables[grp];
  7269. int slot;
  7270. pr_info("niu%d: Port %d RDC tbl(%d) [ ",
  7271. parent->index, i, tp->first_table_num + grp);
  7272. for (slot = 0; slot < NIU_RDC_TABLE_SLOTS; slot++) {
  7273. rt->rxdma_channel[slot] =
  7274. rdc_channel_base + this_channel_offset;
  7275. pr_cont("%d ", rt->rxdma_channel[slot]);
  7276. if (++this_channel_offset == num_channels)
  7277. this_channel_offset = 0;
  7278. }
  7279. pr_cont("]\n");
  7280. }
  7281. parent->rdc_default[i] = rdc_channel_base;
  7282. rdc_channel_base += num_channels;
  7283. rdc_group += rdc_groups_per_port;
  7284. }
  7285. }
  7286. static int fill_phy_probe_info(struct niu *np, struct niu_parent *parent,
  7287. struct phy_probe_info *info)
  7288. {
  7289. unsigned long flags;
  7290. int port, err;
  7291. memset(info, 0, sizeof(*info));
  7292. /* Port 0 to 7 are reserved for onboard Serdes, probe the rest. */
  7293. niu_lock_parent(np, flags);
  7294. err = 0;
  7295. for (port = 8; port < 32; port++) {
  7296. int dev_id_1, dev_id_2;
  7297. dev_id_1 = mdio_read(np, port,
  7298. NIU_PMA_PMD_DEV_ADDR, MII_PHYSID1);
  7299. dev_id_2 = mdio_read(np, port,
  7300. NIU_PMA_PMD_DEV_ADDR, MII_PHYSID2);
  7301. err = phy_record(parent, info, dev_id_1, dev_id_2, port,
  7302. PHY_TYPE_PMA_PMD);
  7303. if (err)
  7304. break;
  7305. dev_id_1 = mdio_read(np, port,
  7306. NIU_PCS_DEV_ADDR, MII_PHYSID1);
  7307. dev_id_2 = mdio_read(np, port,
  7308. NIU_PCS_DEV_ADDR, MII_PHYSID2);
  7309. err = phy_record(parent, info, dev_id_1, dev_id_2, port,
  7310. PHY_TYPE_PCS);
  7311. if (err)
  7312. break;
  7313. dev_id_1 = mii_read(np, port, MII_PHYSID1);
  7314. dev_id_2 = mii_read(np, port, MII_PHYSID2);
  7315. err = phy_record(parent, info, dev_id_1, dev_id_2, port,
  7316. PHY_TYPE_MII);
  7317. if (err)
  7318. break;
  7319. }
  7320. niu_unlock_parent(np, flags);
  7321. return err;
  7322. }
  7323. static int walk_phys(struct niu *np, struct niu_parent *parent)
  7324. {
  7325. struct phy_probe_info *info = &parent->phy_probe_info;
  7326. int lowest_10g, lowest_1g;
  7327. int num_10g, num_1g;
  7328. u32 val;
  7329. int err;
  7330. num_10g = num_1g = 0;
  7331. if (!strcmp(np->vpd.model, NIU_ALONSO_MDL_STR) ||
  7332. !strcmp(np->vpd.model, NIU_KIMI_MDL_STR)) {
  7333. num_10g = 0;
  7334. num_1g = 2;
  7335. parent->plat_type = PLAT_TYPE_ATCA_CP3220;
  7336. parent->num_ports = 4;
  7337. val = (phy_encode(PORT_TYPE_1G, 0) |
  7338. phy_encode(PORT_TYPE_1G, 1) |
  7339. phy_encode(PORT_TYPE_1G, 2) |
  7340. phy_encode(PORT_TYPE_1G, 3));
  7341. } else if (!strcmp(np->vpd.model, NIU_FOXXY_MDL_STR)) {
  7342. num_10g = 2;
  7343. num_1g = 0;
  7344. parent->num_ports = 2;
  7345. val = (phy_encode(PORT_TYPE_10G, 0) |
  7346. phy_encode(PORT_TYPE_10G, 1));
  7347. } else if ((np->flags & NIU_FLAGS_XCVR_SERDES) &&
  7348. (parent->plat_type == PLAT_TYPE_NIU)) {
  7349. /* this is the Monza case */
  7350. if (np->flags & NIU_FLAGS_10G) {
  7351. val = (phy_encode(PORT_TYPE_10G, 0) |
  7352. phy_encode(PORT_TYPE_10G, 1));
  7353. } else {
  7354. val = (phy_encode(PORT_TYPE_1G, 0) |
  7355. phy_encode(PORT_TYPE_1G, 1));
  7356. }
  7357. } else {
  7358. err = fill_phy_probe_info(np, parent, info);
  7359. if (err)
  7360. return err;
  7361. num_10g = count_10g_ports(info, &lowest_10g);
  7362. num_1g = count_1g_ports(info, &lowest_1g);
  7363. switch ((num_10g << 4) | num_1g) {
  7364. case 0x24:
  7365. if (lowest_1g == 10)
  7366. parent->plat_type = PLAT_TYPE_VF_P0;
  7367. else if (lowest_1g == 26)
  7368. parent->plat_type = PLAT_TYPE_VF_P1;
  7369. else
  7370. goto unknown_vg_1g_port;
  7371. fallthrough;
  7372. case 0x22:
  7373. val = (phy_encode(PORT_TYPE_10G, 0) |
  7374. phy_encode(PORT_TYPE_10G, 1) |
  7375. phy_encode(PORT_TYPE_1G, 2) |
  7376. phy_encode(PORT_TYPE_1G, 3));
  7377. break;
  7378. case 0x20:
  7379. val = (phy_encode(PORT_TYPE_10G, 0) |
  7380. phy_encode(PORT_TYPE_10G, 1));
  7381. break;
  7382. case 0x10:
  7383. val = phy_encode(PORT_TYPE_10G, np->port);
  7384. break;
  7385. case 0x14:
  7386. if (lowest_1g == 10)
  7387. parent->plat_type = PLAT_TYPE_VF_P0;
  7388. else if (lowest_1g == 26)
  7389. parent->plat_type = PLAT_TYPE_VF_P1;
  7390. else
  7391. goto unknown_vg_1g_port;
  7392. fallthrough;
  7393. case 0x13:
  7394. if ((lowest_10g & 0x7) == 0)
  7395. val = (phy_encode(PORT_TYPE_10G, 0) |
  7396. phy_encode(PORT_TYPE_1G, 1) |
  7397. phy_encode(PORT_TYPE_1G, 2) |
  7398. phy_encode(PORT_TYPE_1G, 3));
  7399. else
  7400. val = (phy_encode(PORT_TYPE_1G, 0) |
  7401. phy_encode(PORT_TYPE_10G, 1) |
  7402. phy_encode(PORT_TYPE_1G, 2) |
  7403. phy_encode(PORT_TYPE_1G, 3));
  7404. break;
  7405. case 0x04:
  7406. if (lowest_1g == 10)
  7407. parent->plat_type = PLAT_TYPE_VF_P0;
  7408. else if (lowest_1g == 26)
  7409. parent->plat_type = PLAT_TYPE_VF_P1;
  7410. else
  7411. goto unknown_vg_1g_port;
  7412. val = (phy_encode(PORT_TYPE_1G, 0) |
  7413. phy_encode(PORT_TYPE_1G, 1) |
  7414. phy_encode(PORT_TYPE_1G, 2) |
  7415. phy_encode(PORT_TYPE_1G, 3));
  7416. break;
  7417. default:
  7418. pr_err("Unsupported port config 10G[%d] 1G[%d]\n",
  7419. num_10g, num_1g);
  7420. return -EINVAL;
  7421. }
  7422. }
  7423. parent->port_phy = val;
  7424. if (parent->plat_type == PLAT_TYPE_NIU)
  7425. niu_n2_divide_channels(parent);
  7426. else
  7427. niu_divide_channels(parent, num_10g, num_1g);
  7428. niu_divide_rdc_groups(parent, num_10g, num_1g);
  7429. return 0;
  7430. unknown_vg_1g_port:
  7431. pr_err("Cannot identify platform type, 1gport=%d\n", lowest_1g);
  7432. return -EINVAL;
  7433. }
  7434. static int niu_probe_ports(struct niu *np)
  7435. {
  7436. struct niu_parent *parent = np->parent;
  7437. int err, i;
  7438. if (parent->port_phy == PORT_PHY_UNKNOWN) {
  7439. err = walk_phys(np, parent);
  7440. if (err)
  7441. return err;
  7442. niu_set_ldg_timer_res(np, 2);
  7443. for (i = 0; i <= LDN_MAX; i++)
  7444. niu_ldn_irq_enable(np, i, 0);
  7445. }
  7446. if (parent->port_phy == PORT_PHY_INVALID)
  7447. return -EINVAL;
  7448. return 0;
  7449. }
  7450. static int niu_classifier_swstate_init(struct niu *np)
  7451. {
  7452. struct niu_classifier *cp = &np->clas;
  7453. cp->tcam_top = (u16) np->port;
  7454. cp->tcam_sz = np->parent->tcam_num_entries / np->parent->num_ports;
  7455. cp->h1_init = 0xffffffff;
  7456. cp->h2_init = 0xffff;
  7457. return fflp_early_init(np);
  7458. }
  7459. static void niu_link_config_init(struct niu *np)
  7460. {
  7461. struct niu_link_config *lp = &np->link_config;
  7462. lp->advertising = (ADVERTISED_10baseT_Half |
  7463. ADVERTISED_10baseT_Full |
  7464. ADVERTISED_100baseT_Half |
  7465. ADVERTISED_100baseT_Full |
  7466. ADVERTISED_1000baseT_Half |
  7467. ADVERTISED_1000baseT_Full |
  7468. ADVERTISED_10000baseT_Full |
  7469. ADVERTISED_Autoneg);
  7470. lp->speed = lp->active_speed = SPEED_INVALID;
  7471. lp->duplex = DUPLEX_FULL;
  7472. lp->active_duplex = DUPLEX_INVALID;
  7473. lp->autoneg = 1;
  7474. #if 0
  7475. lp->loopback_mode = LOOPBACK_MAC;
  7476. lp->active_speed = SPEED_10000;
  7477. lp->active_duplex = DUPLEX_FULL;
  7478. #else
  7479. lp->loopback_mode = LOOPBACK_DISABLED;
  7480. #endif
  7481. }
  7482. static int niu_init_mac_ipp_pcs_base(struct niu *np)
  7483. {
  7484. switch (np->port) {
  7485. case 0:
  7486. np->mac_regs = np->regs + XMAC_PORT0_OFF;
  7487. np->ipp_off = 0x00000;
  7488. np->pcs_off = 0x04000;
  7489. np->xpcs_off = 0x02000;
  7490. break;
  7491. case 1:
  7492. np->mac_regs = np->regs + XMAC_PORT1_OFF;
  7493. np->ipp_off = 0x08000;
  7494. np->pcs_off = 0x0a000;
  7495. np->xpcs_off = 0x08000;
  7496. break;
  7497. case 2:
  7498. np->mac_regs = np->regs + BMAC_PORT2_OFF;
  7499. np->ipp_off = 0x04000;
  7500. np->pcs_off = 0x0e000;
  7501. np->xpcs_off = ~0UL;
  7502. break;
  7503. case 3:
  7504. np->mac_regs = np->regs + BMAC_PORT3_OFF;
  7505. np->ipp_off = 0x0c000;
  7506. np->pcs_off = 0x12000;
  7507. np->xpcs_off = ~0UL;
  7508. break;
  7509. default:
  7510. dev_err(np->device, "Port %u is invalid, cannot compute MAC block offset\n", np->port);
  7511. return -EINVAL;
  7512. }
  7513. return 0;
  7514. }
  7515. static void niu_try_msix(struct niu *np, u8 *ldg_num_map)
  7516. {
  7517. struct msix_entry msi_vec[NIU_NUM_LDG];
  7518. struct niu_parent *parent = np->parent;
  7519. struct pci_dev *pdev = np->pdev;
  7520. int i, num_irqs;
  7521. u8 first_ldg;
  7522. first_ldg = (NIU_NUM_LDG / parent->num_ports) * np->port;
  7523. for (i = 0; i < (NIU_NUM_LDG / parent->num_ports); i++)
  7524. ldg_num_map[i] = first_ldg + i;
  7525. num_irqs = (parent->rxchan_per_port[np->port] +
  7526. parent->txchan_per_port[np->port] +
  7527. (np->port == 0 ? 3 : 1));
  7528. BUG_ON(num_irqs > (NIU_NUM_LDG / parent->num_ports));
  7529. for (i = 0; i < num_irqs; i++) {
  7530. msi_vec[i].vector = 0;
  7531. msi_vec[i].entry = i;
  7532. }
  7533. pdev->dev_flags |= PCI_DEV_FLAGS_MSIX_TOUCH_ENTRY_DATA_FIRST;
  7534. num_irqs = pci_enable_msix_range(pdev, msi_vec, 1, num_irqs);
  7535. if (num_irqs < 0) {
  7536. np->flags &= ~NIU_FLAGS_MSIX;
  7537. return;
  7538. }
  7539. np->flags |= NIU_FLAGS_MSIX;
  7540. for (i = 0; i < num_irqs; i++)
  7541. np->ldg[i].irq = msi_vec[i].vector;
  7542. np->num_ldg = num_irqs;
  7543. }
  7544. static int niu_n2_irq_init(struct niu *np, u8 *ldg_num_map)
  7545. {
  7546. #ifdef CONFIG_SPARC64
  7547. struct platform_device *op = np->op;
  7548. const u32 *int_prop;
  7549. int i;
  7550. int_prop = of_get_property(op->dev.of_node, "interrupts", NULL);
  7551. if (!int_prop)
  7552. return -ENODEV;
  7553. for (i = 0; i < op->archdata.num_irqs; i++) {
  7554. ldg_num_map[i] = int_prop[i];
  7555. np->ldg[i].irq = op->archdata.irqs[i];
  7556. }
  7557. np->num_ldg = op->archdata.num_irqs;
  7558. return 0;
  7559. #else
  7560. return -EINVAL;
  7561. #endif
  7562. }
  7563. static int niu_ldg_init(struct niu *np)
  7564. {
  7565. struct niu_parent *parent = np->parent;
  7566. u8 ldg_num_map[NIU_NUM_LDG];
  7567. int first_chan, num_chan;
  7568. int i, err, ldg_rotor;
  7569. u8 port;
  7570. np->num_ldg = 1;
  7571. np->ldg[0].irq = np->dev->irq;
  7572. if (parent->plat_type == PLAT_TYPE_NIU) {
  7573. err = niu_n2_irq_init(np, ldg_num_map);
  7574. if (err)
  7575. return err;
  7576. } else
  7577. niu_try_msix(np, ldg_num_map);
  7578. port = np->port;
  7579. for (i = 0; i < np->num_ldg; i++) {
  7580. struct niu_ldg *lp = &np->ldg[i];
  7581. netif_napi_add(np->dev, &lp->napi, niu_poll);
  7582. lp->np = np;
  7583. lp->ldg_num = ldg_num_map[i];
  7584. lp->timer = 2; /* XXX */
  7585. /* On N2 NIU the firmware has setup the SID mappings so they go
  7586. * to the correct values that will route the LDG to the proper
  7587. * interrupt in the NCU interrupt table.
  7588. */
  7589. if (np->parent->plat_type != PLAT_TYPE_NIU) {
  7590. err = niu_set_ldg_sid(np, lp->ldg_num, port, i);
  7591. if (err)
  7592. return err;
  7593. }
  7594. }
  7595. /* We adopt the LDG assignment ordering used by the N2 NIU
  7596. * 'interrupt' properties because that simplifies a lot of
  7597. * things. This ordering is:
  7598. *
  7599. * MAC
  7600. * MIF (if port zero)
  7601. * SYSERR (if port zero)
  7602. * RX channels
  7603. * TX channels
  7604. */
  7605. ldg_rotor = 0;
  7606. err = niu_ldg_assign_ldn(np, parent, ldg_num_map[ldg_rotor],
  7607. LDN_MAC(port));
  7608. if (err)
  7609. return err;
  7610. ldg_rotor++;
  7611. if (ldg_rotor == np->num_ldg)
  7612. ldg_rotor = 0;
  7613. if (port == 0) {
  7614. err = niu_ldg_assign_ldn(np, parent,
  7615. ldg_num_map[ldg_rotor],
  7616. LDN_MIF);
  7617. if (err)
  7618. return err;
  7619. ldg_rotor++;
  7620. if (ldg_rotor == np->num_ldg)
  7621. ldg_rotor = 0;
  7622. err = niu_ldg_assign_ldn(np, parent,
  7623. ldg_num_map[ldg_rotor],
  7624. LDN_DEVICE_ERROR);
  7625. if (err)
  7626. return err;
  7627. ldg_rotor++;
  7628. if (ldg_rotor == np->num_ldg)
  7629. ldg_rotor = 0;
  7630. }
  7631. first_chan = 0;
  7632. for (i = 0; i < port; i++)
  7633. first_chan += parent->rxchan_per_port[i];
  7634. num_chan = parent->rxchan_per_port[port];
  7635. for (i = first_chan; i < (first_chan + num_chan); i++) {
  7636. err = niu_ldg_assign_ldn(np, parent,
  7637. ldg_num_map[ldg_rotor],
  7638. LDN_RXDMA(i));
  7639. if (err)
  7640. return err;
  7641. ldg_rotor++;
  7642. if (ldg_rotor == np->num_ldg)
  7643. ldg_rotor = 0;
  7644. }
  7645. first_chan = 0;
  7646. for (i = 0; i < port; i++)
  7647. first_chan += parent->txchan_per_port[i];
  7648. num_chan = parent->txchan_per_port[port];
  7649. for (i = first_chan; i < (first_chan + num_chan); i++) {
  7650. err = niu_ldg_assign_ldn(np, parent,
  7651. ldg_num_map[ldg_rotor],
  7652. LDN_TXDMA(i));
  7653. if (err)
  7654. return err;
  7655. ldg_rotor++;
  7656. if (ldg_rotor == np->num_ldg)
  7657. ldg_rotor = 0;
  7658. }
  7659. return 0;
  7660. }
  7661. static void niu_ldg_free(struct niu *np)
  7662. {
  7663. if (np->flags & NIU_FLAGS_MSIX)
  7664. pci_disable_msix(np->pdev);
  7665. }
  7666. static int niu_get_of_props(struct niu *np)
  7667. {
  7668. #ifdef CONFIG_SPARC64
  7669. struct net_device *dev = np->dev;
  7670. struct device_node *dp;
  7671. const char *phy_type;
  7672. const u8 *mac_addr;
  7673. const char *model;
  7674. int prop_len;
  7675. if (np->parent->plat_type == PLAT_TYPE_NIU)
  7676. dp = np->op->dev.of_node;
  7677. else
  7678. dp = pci_device_to_OF_node(np->pdev);
  7679. phy_type = of_get_property(dp, "phy-type", NULL);
  7680. if (!phy_type) {
  7681. netdev_err(dev, "%pOF: OF node lacks phy-type property\n", dp);
  7682. return -EINVAL;
  7683. }
  7684. if (!strcmp(phy_type, "none"))
  7685. return -ENODEV;
  7686. strcpy(np->vpd.phy_type, phy_type);
  7687. if (niu_phy_type_prop_decode(np, np->vpd.phy_type)) {
  7688. netdev_err(dev, "%pOF: Illegal phy string [%s]\n",
  7689. dp, np->vpd.phy_type);
  7690. return -EINVAL;
  7691. }
  7692. mac_addr = of_get_property(dp, "local-mac-address", &prop_len);
  7693. if (!mac_addr) {
  7694. netdev_err(dev, "%pOF: OF node lacks local-mac-address property\n",
  7695. dp);
  7696. return -EINVAL;
  7697. }
  7698. if (prop_len != dev->addr_len) {
  7699. netdev_err(dev, "%pOF: OF MAC address prop len (%d) is wrong\n",
  7700. dp, prop_len);
  7701. }
  7702. eth_hw_addr_set(dev, mac_addr);
  7703. if (!is_valid_ether_addr(&dev->dev_addr[0])) {
  7704. netdev_err(dev, "%pOF: OF MAC address is invalid\n", dp);
  7705. netdev_err(dev, "%pOF: [ %pM ]\n", dp, dev->dev_addr);
  7706. return -EINVAL;
  7707. }
  7708. model = of_get_property(dp, "model", NULL);
  7709. if (model)
  7710. strcpy(np->vpd.model, model);
  7711. if (of_property_read_bool(dp, "hot-swappable-phy")) {
  7712. np->flags |= (NIU_FLAGS_10G | NIU_FLAGS_FIBER |
  7713. NIU_FLAGS_HOTPLUG_PHY);
  7714. }
  7715. return 0;
  7716. #else
  7717. return -EINVAL;
  7718. #endif
  7719. }
  7720. static int niu_get_invariants(struct niu *np)
  7721. {
  7722. int err, have_props;
  7723. u32 offset;
  7724. err = niu_get_of_props(np);
  7725. if (err == -ENODEV)
  7726. return err;
  7727. have_props = !err;
  7728. err = niu_init_mac_ipp_pcs_base(np);
  7729. if (err)
  7730. return err;
  7731. if (have_props) {
  7732. err = niu_get_and_validate_port(np);
  7733. if (err)
  7734. return err;
  7735. } else {
  7736. if (np->parent->plat_type == PLAT_TYPE_NIU)
  7737. return -EINVAL;
  7738. nw64(ESPC_PIO_EN, ESPC_PIO_EN_ENABLE);
  7739. offset = niu_pci_vpd_offset(np);
  7740. netif_printk(np, probe, KERN_DEBUG, np->dev,
  7741. "%s() VPD offset [%08x]\n", __func__, offset);
  7742. if (offset) {
  7743. err = niu_pci_vpd_fetch(np, offset);
  7744. if (err < 0)
  7745. return err;
  7746. }
  7747. nw64(ESPC_PIO_EN, 0);
  7748. if (np->flags & NIU_FLAGS_VPD_VALID) {
  7749. niu_pci_vpd_validate(np);
  7750. err = niu_get_and_validate_port(np);
  7751. if (err)
  7752. return err;
  7753. }
  7754. if (!(np->flags & NIU_FLAGS_VPD_VALID)) {
  7755. err = niu_get_and_validate_port(np);
  7756. if (err)
  7757. return err;
  7758. err = niu_pci_probe_sprom(np);
  7759. if (err)
  7760. return err;
  7761. }
  7762. }
  7763. err = niu_probe_ports(np);
  7764. if (err)
  7765. return err;
  7766. niu_ldg_init(np);
  7767. niu_classifier_swstate_init(np);
  7768. niu_link_config_init(np);
  7769. err = niu_determine_phy_disposition(np);
  7770. if (!err)
  7771. err = niu_init_link(np);
  7772. return err;
  7773. }
  7774. static LIST_HEAD(niu_parent_list);
  7775. static DEFINE_MUTEX(niu_parent_lock);
  7776. static int niu_parent_index;
  7777. static ssize_t show_port_phy(struct device *dev,
  7778. struct device_attribute *attr, char *buf)
  7779. {
  7780. struct platform_device *plat_dev = to_platform_device(dev);
  7781. struct niu_parent *p = dev_get_platdata(&plat_dev->dev);
  7782. u32 port_phy = p->port_phy;
  7783. char *orig_buf = buf;
  7784. int i;
  7785. if (port_phy == PORT_PHY_UNKNOWN ||
  7786. port_phy == PORT_PHY_INVALID)
  7787. return 0;
  7788. for (i = 0; i < p->num_ports; i++) {
  7789. const char *type_str;
  7790. int type;
  7791. type = phy_decode(port_phy, i);
  7792. if (type == PORT_TYPE_10G)
  7793. type_str = "10G";
  7794. else
  7795. type_str = "1G";
  7796. buf += sprintf(buf,
  7797. (i == 0) ? "%s" : " %s",
  7798. type_str);
  7799. }
  7800. buf += sprintf(buf, "\n");
  7801. return buf - orig_buf;
  7802. }
  7803. static ssize_t show_plat_type(struct device *dev,
  7804. struct device_attribute *attr, char *buf)
  7805. {
  7806. struct platform_device *plat_dev = to_platform_device(dev);
  7807. struct niu_parent *p = dev_get_platdata(&plat_dev->dev);
  7808. const char *type_str;
  7809. switch (p->plat_type) {
  7810. case PLAT_TYPE_ATLAS:
  7811. type_str = "atlas";
  7812. break;
  7813. case PLAT_TYPE_NIU:
  7814. type_str = "niu";
  7815. break;
  7816. case PLAT_TYPE_VF_P0:
  7817. type_str = "vf_p0";
  7818. break;
  7819. case PLAT_TYPE_VF_P1:
  7820. type_str = "vf_p1";
  7821. break;
  7822. default:
  7823. type_str = "unknown";
  7824. break;
  7825. }
  7826. return sprintf(buf, "%s\n", type_str);
  7827. }
  7828. static ssize_t __show_chan_per_port(struct device *dev,
  7829. struct device_attribute *attr, char *buf,
  7830. int rx)
  7831. {
  7832. struct platform_device *plat_dev = to_platform_device(dev);
  7833. struct niu_parent *p = dev_get_platdata(&plat_dev->dev);
  7834. char *orig_buf = buf;
  7835. u8 *arr;
  7836. int i;
  7837. arr = (rx ? p->rxchan_per_port : p->txchan_per_port);
  7838. for (i = 0; i < p->num_ports; i++) {
  7839. buf += sprintf(buf,
  7840. (i == 0) ? "%d" : " %d",
  7841. arr[i]);
  7842. }
  7843. buf += sprintf(buf, "\n");
  7844. return buf - orig_buf;
  7845. }
  7846. static ssize_t show_rxchan_per_port(struct device *dev,
  7847. struct device_attribute *attr, char *buf)
  7848. {
  7849. return __show_chan_per_port(dev, attr, buf, 1);
  7850. }
  7851. static ssize_t show_txchan_per_port(struct device *dev,
  7852. struct device_attribute *attr, char *buf)
  7853. {
  7854. return __show_chan_per_port(dev, attr, buf, 1);
  7855. }
  7856. static ssize_t show_num_ports(struct device *dev,
  7857. struct device_attribute *attr, char *buf)
  7858. {
  7859. struct platform_device *plat_dev = to_platform_device(dev);
  7860. struct niu_parent *p = dev_get_platdata(&plat_dev->dev);
  7861. return sprintf(buf, "%d\n", p->num_ports);
  7862. }
  7863. static struct device_attribute niu_parent_attributes[] = {
  7864. __ATTR(port_phy, 0444, show_port_phy, NULL),
  7865. __ATTR(plat_type, 0444, show_plat_type, NULL),
  7866. __ATTR(rxchan_per_port, 0444, show_rxchan_per_port, NULL),
  7867. __ATTR(txchan_per_port, 0444, show_txchan_per_port, NULL),
  7868. __ATTR(num_ports, 0444, show_num_ports, NULL),
  7869. {}
  7870. };
  7871. static struct niu_parent *niu_new_parent(struct niu *np,
  7872. union niu_parent_id *id, u8 ptype)
  7873. {
  7874. struct platform_device *plat_dev;
  7875. struct niu_parent *p;
  7876. int i;
  7877. plat_dev = platform_device_register_simple("niu-board", niu_parent_index,
  7878. NULL, 0);
  7879. if (IS_ERR(plat_dev))
  7880. return NULL;
  7881. for (i = 0; niu_parent_attributes[i].attr.name; i++) {
  7882. int err = device_create_file(&plat_dev->dev,
  7883. &niu_parent_attributes[i]);
  7884. if (err)
  7885. goto fail_unregister;
  7886. }
  7887. p = kzalloc_obj(*p);
  7888. if (!p)
  7889. goto fail_unregister;
  7890. p->index = niu_parent_index++;
  7891. plat_dev->dev.platform_data = p;
  7892. p->plat_dev = plat_dev;
  7893. memcpy(&p->id, id, sizeof(*id));
  7894. p->plat_type = ptype;
  7895. INIT_LIST_HEAD(&p->list);
  7896. atomic_set(&p->refcnt, 0);
  7897. list_add(&p->list, &niu_parent_list);
  7898. spin_lock_init(&p->lock);
  7899. p->rxdma_clock_divider = 7500;
  7900. p->tcam_num_entries = NIU_PCI_TCAM_ENTRIES;
  7901. if (p->plat_type == PLAT_TYPE_NIU)
  7902. p->tcam_num_entries = NIU_NONPCI_TCAM_ENTRIES;
  7903. for (i = CLASS_CODE_USER_PROG1; i <= CLASS_CODE_SCTP_IPV6; i++) {
  7904. int index = i - CLASS_CODE_USER_PROG1;
  7905. p->tcam_key[index] = TCAM_KEY_TSEL;
  7906. p->flow_key[index] = (FLOW_KEY_IPSA |
  7907. FLOW_KEY_IPDA |
  7908. FLOW_KEY_PROTO |
  7909. (FLOW_KEY_L4_BYTE12 <<
  7910. FLOW_KEY_L4_0_SHIFT) |
  7911. (FLOW_KEY_L4_BYTE12 <<
  7912. FLOW_KEY_L4_1_SHIFT));
  7913. }
  7914. for (i = 0; i < LDN_MAX + 1; i++)
  7915. p->ldg_map[i] = LDG_INVALID;
  7916. return p;
  7917. fail_unregister:
  7918. platform_device_unregister(plat_dev);
  7919. return NULL;
  7920. }
  7921. static struct niu_parent *niu_get_parent(struct niu *np,
  7922. union niu_parent_id *id, u8 ptype)
  7923. {
  7924. struct niu_parent *p, *tmp;
  7925. int port = np->port;
  7926. mutex_lock(&niu_parent_lock);
  7927. p = NULL;
  7928. list_for_each_entry(tmp, &niu_parent_list, list) {
  7929. if (!memcmp(id, &tmp->id, sizeof(*id))) {
  7930. p = tmp;
  7931. break;
  7932. }
  7933. }
  7934. if (!p)
  7935. p = niu_new_parent(np, id, ptype);
  7936. if (p) {
  7937. char port_name[8];
  7938. int err;
  7939. sprintf(port_name, "port%d", port);
  7940. err = sysfs_create_link(&p->plat_dev->dev.kobj,
  7941. &np->device->kobj,
  7942. port_name);
  7943. if (!err) {
  7944. p->ports[port] = np;
  7945. atomic_inc(&p->refcnt);
  7946. }
  7947. }
  7948. mutex_unlock(&niu_parent_lock);
  7949. return p;
  7950. }
  7951. static void niu_put_parent(struct niu *np)
  7952. {
  7953. struct niu_parent *p = np->parent;
  7954. u8 port = np->port;
  7955. char port_name[8];
  7956. BUG_ON(!p || p->ports[port] != np);
  7957. netif_printk(np, probe, KERN_DEBUG, np->dev,
  7958. "%s() port[%u]\n", __func__, port);
  7959. sprintf(port_name, "port%d", port);
  7960. mutex_lock(&niu_parent_lock);
  7961. sysfs_remove_link(&p->plat_dev->dev.kobj, port_name);
  7962. p->ports[port] = NULL;
  7963. np->parent = NULL;
  7964. if (atomic_dec_and_test(&p->refcnt)) {
  7965. list_del(&p->list);
  7966. platform_device_unregister(p->plat_dev);
  7967. }
  7968. mutex_unlock(&niu_parent_lock);
  7969. }
  7970. static void *niu_pci_alloc_coherent(struct device *dev, size_t size,
  7971. u64 *handle, gfp_t flag)
  7972. {
  7973. dma_addr_t dh;
  7974. void *ret;
  7975. ret = dma_alloc_coherent(dev, size, &dh, flag);
  7976. if (ret)
  7977. *handle = dh;
  7978. return ret;
  7979. }
  7980. static void niu_pci_free_coherent(struct device *dev, size_t size,
  7981. void *cpu_addr, u64 handle)
  7982. {
  7983. dma_free_coherent(dev, size, cpu_addr, handle);
  7984. }
  7985. static u64 niu_pci_map_page(struct device *dev, struct page *page,
  7986. unsigned long offset, size_t size,
  7987. enum dma_data_direction direction)
  7988. {
  7989. return dma_map_page(dev, page, offset, size, direction);
  7990. }
  7991. static void niu_pci_unmap_page(struct device *dev, u64 dma_address,
  7992. size_t size, enum dma_data_direction direction)
  7993. {
  7994. dma_unmap_page(dev, dma_address, size, direction);
  7995. }
  7996. static u64 niu_pci_map_single(struct device *dev, void *cpu_addr,
  7997. size_t size,
  7998. enum dma_data_direction direction)
  7999. {
  8000. return dma_map_single(dev, cpu_addr, size, direction);
  8001. }
  8002. static void niu_pci_unmap_single(struct device *dev, u64 dma_address,
  8003. size_t size,
  8004. enum dma_data_direction direction)
  8005. {
  8006. dma_unmap_single(dev, dma_address, size, direction);
  8007. }
  8008. static int niu_pci_mapping_error(struct device *dev, u64 addr)
  8009. {
  8010. return dma_mapping_error(dev, addr);
  8011. }
  8012. static const struct niu_ops niu_pci_ops = {
  8013. .alloc_coherent = niu_pci_alloc_coherent,
  8014. .free_coherent = niu_pci_free_coherent,
  8015. .map_page = niu_pci_map_page,
  8016. .unmap_page = niu_pci_unmap_page,
  8017. .map_single = niu_pci_map_single,
  8018. .unmap_single = niu_pci_unmap_single,
  8019. .mapping_error = niu_pci_mapping_error,
  8020. };
  8021. static void niu_driver_version(void)
  8022. {
  8023. static int niu_version_printed;
  8024. if (niu_version_printed++ == 0)
  8025. pr_info("%s", version);
  8026. }
  8027. static struct net_device *niu_alloc_and_init(struct device *gen_dev,
  8028. struct pci_dev *pdev,
  8029. struct platform_device *op,
  8030. const struct niu_ops *ops, u8 port)
  8031. {
  8032. struct net_device *dev;
  8033. struct niu *np;
  8034. dev = alloc_etherdev_mq(sizeof(struct niu), NIU_NUM_TXCHAN);
  8035. if (!dev)
  8036. return NULL;
  8037. SET_NETDEV_DEV(dev, gen_dev);
  8038. np = netdev_priv(dev);
  8039. np->dev = dev;
  8040. np->pdev = pdev;
  8041. np->op = op;
  8042. np->device = gen_dev;
  8043. np->ops = ops;
  8044. np->msg_enable = niu_debug;
  8045. spin_lock_init(&np->lock);
  8046. INIT_WORK(&np->reset_task, niu_reset_task);
  8047. np->port = port;
  8048. return dev;
  8049. }
  8050. static const struct net_device_ops niu_netdev_ops = {
  8051. .ndo_open = niu_open,
  8052. .ndo_stop = niu_close,
  8053. .ndo_start_xmit = niu_start_xmit,
  8054. .ndo_get_stats64 = niu_get_stats,
  8055. .ndo_set_rx_mode = niu_set_rx_mode,
  8056. .ndo_validate_addr = eth_validate_addr,
  8057. .ndo_set_mac_address = niu_set_mac_addr,
  8058. .ndo_eth_ioctl = niu_ioctl,
  8059. .ndo_tx_timeout = niu_tx_timeout,
  8060. .ndo_change_mtu = niu_change_mtu,
  8061. };
  8062. static void niu_assign_netdev_ops(struct net_device *dev)
  8063. {
  8064. dev->netdev_ops = &niu_netdev_ops;
  8065. dev->ethtool_ops = &niu_ethtool_ops;
  8066. dev->watchdog_timeo = NIU_TX_TIMEOUT;
  8067. }
  8068. static void niu_device_announce(struct niu *np)
  8069. {
  8070. struct net_device *dev = np->dev;
  8071. pr_info("%s: NIU Ethernet %pM\n", dev->name, dev->dev_addr);
  8072. if (np->parent->plat_type == PLAT_TYPE_ATCA_CP3220) {
  8073. pr_info("%s: Port type[%s] mode[%s:%s] XCVR[%s] phy[%s]\n",
  8074. dev->name,
  8075. (np->flags & NIU_FLAGS_XMAC ? "XMAC" : "BMAC"),
  8076. (np->flags & NIU_FLAGS_10G ? "10G" : "1G"),
  8077. (np->flags & NIU_FLAGS_FIBER ? "RGMII FIBER" : "SERDES"),
  8078. (np->mac_xcvr == MAC_XCVR_MII ? "MII" :
  8079. (np->mac_xcvr == MAC_XCVR_PCS ? "PCS" : "XPCS")),
  8080. np->vpd.phy_type);
  8081. } else {
  8082. pr_info("%s: Port type[%s] mode[%s:%s] XCVR[%s] phy[%s]\n",
  8083. dev->name,
  8084. (np->flags & NIU_FLAGS_XMAC ? "XMAC" : "BMAC"),
  8085. (np->flags & NIU_FLAGS_10G ? "10G" : "1G"),
  8086. (np->flags & NIU_FLAGS_FIBER ? "FIBER" :
  8087. (np->flags & NIU_FLAGS_XCVR_SERDES ? "SERDES" :
  8088. "COPPER")),
  8089. (np->mac_xcvr == MAC_XCVR_MII ? "MII" :
  8090. (np->mac_xcvr == MAC_XCVR_PCS ? "PCS" : "XPCS")),
  8091. np->vpd.phy_type);
  8092. }
  8093. }
  8094. static void niu_set_basic_features(struct net_device *dev)
  8095. {
  8096. dev->hw_features = NETIF_F_SG | NETIF_F_HW_CSUM | NETIF_F_RXHASH;
  8097. dev->features |= dev->hw_features | NETIF_F_RXCSUM;
  8098. }
  8099. static int niu_pci_init_one(struct pci_dev *pdev,
  8100. const struct pci_device_id *ent)
  8101. {
  8102. union niu_parent_id parent_id;
  8103. struct net_device *dev;
  8104. struct niu *np;
  8105. int err;
  8106. niu_driver_version();
  8107. err = pci_enable_device(pdev);
  8108. if (err) {
  8109. dev_err(&pdev->dev, "Cannot enable PCI device, aborting\n");
  8110. return err;
  8111. }
  8112. if (!(pci_resource_flags(pdev, 0) & IORESOURCE_MEM) ||
  8113. !(pci_resource_flags(pdev, 2) & IORESOURCE_MEM)) {
  8114. dev_err(&pdev->dev, "Cannot find proper PCI device base addresses, aborting\n");
  8115. err = -ENODEV;
  8116. goto err_out_disable_pdev;
  8117. }
  8118. err = pci_request_regions(pdev, DRV_MODULE_NAME);
  8119. if (err) {
  8120. dev_err(&pdev->dev, "Cannot obtain PCI resources, aborting\n");
  8121. goto err_out_disable_pdev;
  8122. }
  8123. if (!pci_is_pcie(pdev)) {
  8124. dev_err(&pdev->dev, "Cannot find PCI Express capability, aborting\n");
  8125. err = -ENODEV;
  8126. goto err_out_free_res;
  8127. }
  8128. dev = niu_alloc_and_init(&pdev->dev, pdev, NULL,
  8129. &niu_pci_ops, PCI_FUNC(pdev->devfn));
  8130. if (!dev) {
  8131. err = -ENOMEM;
  8132. goto err_out_free_res;
  8133. }
  8134. np = netdev_priv(dev);
  8135. memset(&parent_id, 0, sizeof(parent_id));
  8136. parent_id.pci.domain = pci_domain_nr(pdev->bus);
  8137. parent_id.pci.bus = pdev->bus->number;
  8138. parent_id.pci.device = PCI_SLOT(pdev->devfn);
  8139. np->parent = niu_get_parent(np, &parent_id,
  8140. PLAT_TYPE_ATLAS);
  8141. if (!np->parent) {
  8142. err = -ENOMEM;
  8143. goto err_out_free_dev;
  8144. }
  8145. pcie_capability_clear_and_set_word(pdev, PCI_EXP_DEVCTL,
  8146. PCI_EXP_DEVCTL_NOSNOOP_EN,
  8147. PCI_EXP_DEVCTL_CERE | PCI_EXP_DEVCTL_NFERE |
  8148. PCI_EXP_DEVCTL_FERE | PCI_EXP_DEVCTL_URRE |
  8149. PCI_EXP_DEVCTL_RELAX_EN);
  8150. err = dma_set_mask_and_coherent(&pdev->dev, DMA_BIT_MASK(44));
  8151. if (!err)
  8152. dev->features |= NETIF_F_HIGHDMA;
  8153. if (err) {
  8154. err = dma_set_mask(&pdev->dev, DMA_BIT_MASK(32));
  8155. if (err) {
  8156. dev_err(&pdev->dev, "No usable DMA configuration, aborting\n");
  8157. goto err_out_release_parent;
  8158. }
  8159. }
  8160. niu_set_basic_features(dev);
  8161. dev->priv_flags |= IFF_UNICAST_FLT;
  8162. np->regs = pci_ioremap_bar(pdev, 0);
  8163. if (!np->regs) {
  8164. dev_err(&pdev->dev, "Cannot map device registers, aborting\n");
  8165. err = -ENOMEM;
  8166. goto err_out_release_parent;
  8167. }
  8168. pci_set_master(pdev);
  8169. pci_save_state(pdev);
  8170. dev->irq = pdev->irq;
  8171. /* MTU range: 68 - 9216 */
  8172. dev->min_mtu = ETH_MIN_MTU;
  8173. dev->max_mtu = NIU_MAX_MTU;
  8174. niu_assign_netdev_ops(dev);
  8175. err = niu_get_invariants(np);
  8176. if (err) {
  8177. if (err != -ENODEV)
  8178. dev_err(&pdev->dev, "Problem fetching invariants of chip, aborting\n");
  8179. goto err_out_iounmap;
  8180. }
  8181. err = register_netdev(dev);
  8182. if (err) {
  8183. dev_err(&pdev->dev, "Cannot register net device, aborting\n");
  8184. goto err_out_iounmap;
  8185. }
  8186. pci_set_drvdata(pdev, dev);
  8187. niu_device_announce(np);
  8188. return 0;
  8189. err_out_iounmap:
  8190. if (np->regs) {
  8191. iounmap(np->regs);
  8192. np->regs = NULL;
  8193. }
  8194. err_out_release_parent:
  8195. niu_put_parent(np);
  8196. err_out_free_dev:
  8197. free_netdev(dev);
  8198. err_out_free_res:
  8199. pci_release_regions(pdev);
  8200. err_out_disable_pdev:
  8201. pci_disable_device(pdev);
  8202. return err;
  8203. }
  8204. static void niu_pci_remove_one(struct pci_dev *pdev)
  8205. {
  8206. struct net_device *dev = pci_get_drvdata(pdev);
  8207. if (dev) {
  8208. struct niu *np = netdev_priv(dev);
  8209. unregister_netdev(dev);
  8210. if (np->regs) {
  8211. iounmap(np->regs);
  8212. np->regs = NULL;
  8213. }
  8214. niu_ldg_free(np);
  8215. niu_put_parent(np);
  8216. free_netdev(dev);
  8217. pci_release_regions(pdev);
  8218. pci_disable_device(pdev);
  8219. }
  8220. }
  8221. static int __maybe_unused niu_suspend(struct device *dev_d)
  8222. {
  8223. struct net_device *dev = dev_get_drvdata(dev_d);
  8224. struct niu *np = netdev_priv(dev);
  8225. unsigned long flags;
  8226. if (!netif_running(dev))
  8227. return 0;
  8228. flush_work(&np->reset_task);
  8229. niu_netif_stop(np);
  8230. timer_delete_sync(&np->timer);
  8231. spin_lock_irqsave(&np->lock, flags);
  8232. niu_enable_interrupts(np, 0);
  8233. spin_unlock_irqrestore(&np->lock, flags);
  8234. netif_device_detach(dev);
  8235. spin_lock_irqsave(&np->lock, flags);
  8236. niu_stop_hw(np);
  8237. spin_unlock_irqrestore(&np->lock, flags);
  8238. return 0;
  8239. }
  8240. static int __maybe_unused niu_resume(struct device *dev_d)
  8241. {
  8242. struct net_device *dev = dev_get_drvdata(dev_d);
  8243. struct niu *np = netdev_priv(dev);
  8244. unsigned long flags;
  8245. int err;
  8246. if (!netif_running(dev))
  8247. return 0;
  8248. netif_device_attach(dev);
  8249. spin_lock_irqsave(&np->lock, flags);
  8250. netdev_lock(dev);
  8251. err = niu_init_hw(np);
  8252. if (!err) {
  8253. np->timer.expires = jiffies + HZ;
  8254. add_timer(&np->timer);
  8255. niu_netif_start(np);
  8256. }
  8257. spin_unlock_irqrestore(&np->lock, flags);
  8258. netdev_unlock(dev);
  8259. return err;
  8260. }
  8261. static SIMPLE_DEV_PM_OPS(niu_pm_ops, niu_suspend, niu_resume);
  8262. static struct pci_driver niu_pci_driver = {
  8263. .name = DRV_MODULE_NAME,
  8264. .id_table = niu_pci_tbl,
  8265. .probe = niu_pci_init_one,
  8266. .remove = niu_pci_remove_one,
  8267. .driver.pm = &niu_pm_ops,
  8268. };
  8269. #ifdef CONFIG_SPARC64
  8270. static void *niu_phys_alloc_coherent(struct device *dev, size_t size,
  8271. u64 *dma_addr, gfp_t flag)
  8272. {
  8273. unsigned long order = get_order(size);
  8274. unsigned long page = __get_free_pages(flag, order);
  8275. if (page == 0UL)
  8276. return NULL;
  8277. memset((char *)page, 0, PAGE_SIZE << order);
  8278. *dma_addr = __pa(page);
  8279. return (void *) page;
  8280. }
  8281. static void niu_phys_free_coherent(struct device *dev, size_t size,
  8282. void *cpu_addr, u64 handle)
  8283. {
  8284. unsigned long order = get_order(size);
  8285. free_pages((unsigned long) cpu_addr, order);
  8286. }
  8287. static u64 niu_phys_map_page(struct device *dev, struct page *page,
  8288. unsigned long offset, size_t size,
  8289. enum dma_data_direction direction)
  8290. {
  8291. return page_to_phys(page) + offset;
  8292. }
  8293. static void niu_phys_unmap_page(struct device *dev, u64 dma_address,
  8294. size_t size, enum dma_data_direction direction)
  8295. {
  8296. /* Nothing to do. */
  8297. }
  8298. static u64 niu_phys_map_single(struct device *dev, void *cpu_addr,
  8299. size_t size,
  8300. enum dma_data_direction direction)
  8301. {
  8302. return __pa(cpu_addr);
  8303. }
  8304. static void niu_phys_unmap_single(struct device *dev, u64 dma_address,
  8305. size_t size,
  8306. enum dma_data_direction direction)
  8307. {
  8308. /* Nothing to do. */
  8309. }
  8310. static int niu_phys_mapping_error(struct device *dev, u64 dma_address)
  8311. {
  8312. return false;
  8313. }
  8314. static const struct niu_ops niu_phys_ops = {
  8315. .alloc_coherent = niu_phys_alloc_coherent,
  8316. .free_coherent = niu_phys_free_coherent,
  8317. .map_page = niu_phys_map_page,
  8318. .unmap_page = niu_phys_unmap_page,
  8319. .map_single = niu_phys_map_single,
  8320. .unmap_single = niu_phys_unmap_single,
  8321. .mapping_error = niu_phys_mapping_error,
  8322. };
  8323. static int niu_of_probe(struct platform_device *op)
  8324. {
  8325. union niu_parent_id parent_id;
  8326. struct net_device *dev;
  8327. struct niu *np;
  8328. const u32 *reg;
  8329. int err;
  8330. niu_driver_version();
  8331. reg = of_get_property(op->dev.of_node, "reg", NULL);
  8332. if (!reg) {
  8333. dev_err(&op->dev, "%pOF: No 'reg' property, aborting\n",
  8334. op->dev.of_node);
  8335. return -ENODEV;
  8336. }
  8337. dev = niu_alloc_and_init(&op->dev, NULL, op,
  8338. &niu_phys_ops, reg[0] & 0x1);
  8339. if (!dev) {
  8340. err = -ENOMEM;
  8341. goto err_out;
  8342. }
  8343. np = netdev_priv(dev);
  8344. memset(&parent_id, 0, sizeof(parent_id));
  8345. parent_id.of = of_get_parent(op->dev.of_node);
  8346. np->parent = niu_get_parent(np, &parent_id,
  8347. PLAT_TYPE_NIU);
  8348. if (!np->parent) {
  8349. err = -ENOMEM;
  8350. goto err_out_free_dev;
  8351. }
  8352. niu_set_basic_features(dev);
  8353. np->regs = of_ioremap(&op->resource[1], 0,
  8354. resource_size(&op->resource[1]),
  8355. "niu regs");
  8356. if (!np->regs) {
  8357. dev_err(&op->dev, "Cannot map device registers, aborting\n");
  8358. err = -ENOMEM;
  8359. goto err_out_release_parent;
  8360. }
  8361. np->vir_regs_1 = of_ioremap(&op->resource[2], 0,
  8362. resource_size(&op->resource[2]),
  8363. "niu vregs-1");
  8364. if (!np->vir_regs_1) {
  8365. dev_err(&op->dev, "Cannot map device vir registers 1, aborting\n");
  8366. err = -ENOMEM;
  8367. goto err_out_iounmap;
  8368. }
  8369. np->vir_regs_2 = of_ioremap(&op->resource[3], 0,
  8370. resource_size(&op->resource[3]),
  8371. "niu vregs-2");
  8372. if (!np->vir_regs_2) {
  8373. dev_err(&op->dev, "Cannot map device vir registers 2, aborting\n");
  8374. err = -ENOMEM;
  8375. goto err_out_iounmap;
  8376. }
  8377. niu_assign_netdev_ops(dev);
  8378. err = niu_get_invariants(np);
  8379. if (err) {
  8380. if (err != -ENODEV)
  8381. dev_err(&op->dev, "Problem fetching invariants of chip, aborting\n");
  8382. goto err_out_iounmap;
  8383. }
  8384. err = register_netdev(dev);
  8385. if (err) {
  8386. dev_err(&op->dev, "Cannot register net device, aborting\n");
  8387. goto err_out_iounmap;
  8388. }
  8389. platform_set_drvdata(op, dev);
  8390. niu_device_announce(np);
  8391. return 0;
  8392. err_out_iounmap:
  8393. if (np->vir_regs_1) {
  8394. of_iounmap(&op->resource[2], np->vir_regs_1,
  8395. resource_size(&op->resource[2]));
  8396. np->vir_regs_1 = NULL;
  8397. }
  8398. if (np->vir_regs_2) {
  8399. of_iounmap(&op->resource[3], np->vir_regs_2,
  8400. resource_size(&op->resource[3]));
  8401. np->vir_regs_2 = NULL;
  8402. }
  8403. if (np->regs) {
  8404. of_iounmap(&op->resource[1], np->regs,
  8405. resource_size(&op->resource[1]));
  8406. np->regs = NULL;
  8407. }
  8408. err_out_release_parent:
  8409. niu_put_parent(np);
  8410. err_out_free_dev:
  8411. free_netdev(dev);
  8412. err_out:
  8413. return err;
  8414. }
  8415. static void niu_of_remove(struct platform_device *op)
  8416. {
  8417. struct net_device *dev = platform_get_drvdata(op);
  8418. if (dev) {
  8419. struct niu *np = netdev_priv(dev);
  8420. unregister_netdev(dev);
  8421. if (np->vir_regs_1) {
  8422. of_iounmap(&op->resource[2], np->vir_regs_1,
  8423. resource_size(&op->resource[2]));
  8424. np->vir_regs_1 = NULL;
  8425. }
  8426. if (np->vir_regs_2) {
  8427. of_iounmap(&op->resource[3], np->vir_regs_2,
  8428. resource_size(&op->resource[3]));
  8429. np->vir_regs_2 = NULL;
  8430. }
  8431. if (np->regs) {
  8432. of_iounmap(&op->resource[1], np->regs,
  8433. resource_size(&op->resource[1]));
  8434. np->regs = NULL;
  8435. }
  8436. niu_ldg_free(np);
  8437. niu_put_parent(np);
  8438. free_netdev(dev);
  8439. }
  8440. }
  8441. static const struct of_device_id niu_match[] = {
  8442. {
  8443. .name = "network",
  8444. .compatible = "SUNW,niusl",
  8445. },
  8446. {},
  8447. };
  8448. MODULE_DEVICE_TABLE(of, niu_match);
  8449. static struct platform_driver niu_of_driver = {
  8450. .driver = {
  8451. .name = "niu",
  8452. .of_match_table = niu_match,
  8453. },
  8454. .probe = niu_of_probe,
  8455. .remove = niu_of_remove,
  8456. };
  8457. #endif /* CONFIG_SPARC64 */
  8458. static int __init niu_init(void)
  8459. {
  8460. int err = 0;
  8461. BUILD_BUG_ON(PAGE_SIZE < 4 * 1024);
  8462. BUILD_BUG_ON(offsetof(struct page, mapping) !=
  8463. offsetof(union niu_page, next));
  8464. niu_debug = netif_msg_init(debug, NIU_MSG_DEFAULT);
  8465. #ifdef CONFIG_SPARC64
  8466. err = platform_driver_register(&niu_of_driver);
  8467. #endif
  8468. if (!err) {
  8469. err = pci_register_driver(&niu_pci_driver);
  8470. #ifdef CONFIG_SPARC64
  8471. if (err)
  8472. platform_driver_unregister(&niu_of_driver);
  8473. #endif
  8474. }
  8475. return err;
  8476. }
  8477. static void __exit niu_exit(void)
  8478. {
  8479. pci_unregister_driver(&niu_pci_driver);
  8480. #ifdef CONFIG_SPARC64
  8481. platform_driver_unregister(&niu_of_driver);
  8482. #endif
  8483. }
  8484. module_init(niu_init);
  8485. module_exit(niu_exit);