airoha_eth.c 87 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /*
  3. * Copyright (c) 2024 AIROHA Inc
  4. * Author: Lorenzo Bianconi <lorenzo@kernel.org>
  5. */
  6. #include <linux/of.h>
  7. #include <linux/of_net.h>
  8. #include <linux/of_reserved_mem.h>
  9. #include <linux/platform_device.h>
  10. #include <linux/tcp.h>
  11. #include <linux/u64_stats_sync.h>
  12. #include <net/dst_metadata.h>
  13. #include <net/page_pool/helpers.h>
  14. #include <net/pkt_cls.h>
  15. #include <uapi/linux/ppp_defs.h>
  16. #include "airoha_regs.h"
  17. #include "airoha_eth.h"
  18. u32 airoha_rr(void __iomem *base, u32 offset)
  19. {
  20. return readl(base + offset);
  21. }
  22. void airoha_wr(void __iomem *base, u32 offset, u32 val)
  23. {
  24. writel(val, base + offset);
  25. }
  26. u32 airoha_rmw(void __iomem *base, u32 offset, u32 mask, u32 val)
  27. {
  28. val |= (airoha_rr(base, offset) & ~mask);
  29. airoha_wr(base, offset, val);
  30. return val;
  31. }
  32. static void airoha_qdma_set_irqmask(struct airoha_irq_bank *irq_bank,
  33. int index, u32 clear, u32 set)
  34. {
  35. struct airoha_qdma *qdma = irq_bank->qdma;
  36. int bank = irq_bank - &qdma->irq_banks[0];
  37. unsigned long flags;
  38. if (WARN_ON_ONCE(index >= ARRAY_SIZE(irq_bank->irqmask)))
  39. return;
  40. spin_lock_irqsave(&irq_bank->irq_lock, flags);
  41. irq_bank->irqmask[index] &= ~clear;
  42. irq_bank->irqmask[index] |= set;
  43. airoha_qdma_wr(qdma, REG_INT_ENABLE(bank, index),
  44. irq_bank->irqmask[index]);
  45. /* Read irq_enable register in order to guarantee the update above
  46. * completes in the spinlock critical section.
  47. */
  48. airoha_qdma_rr(qdma, REG_INT_ENABLE(bank, index));
  49. spin_unlock_irqrestore(&irq_bank->irq_lock, flags);
  50. }
  51. static void airoha_qdma_irq_enable(struct airoha_irq_bank *irq_bank,
  52. int index, u32 mask)
  53. {
  54. airoha_qdma_set_irqmask(irq_bank, index, 0, mask);
  55. }
  56. static void airoha_qdma_irq_disable(struct airoha_irq_bank *irq_bank,
  57. int index, u32 mask)
  58. {
  59. airoha_qdma_set_irqmask(irq_bank, index, mask, 0);
  60. }
  61. static void airoha_set_macaddr(struct airoha_gdm_port *port, const u8 *addr)
  62. {
  63. struct airoha_eth *eth = port->qdma->eth;
  64. u32 val, reg;
  65. reg = airhoa_is_lan_gdm_port(port) ? REG_FE_LAN_MAC_H
  66. : REG_FE_WAN_MAC_H;
  67. val = (addr[0] << 16) | (addr[1] << 8) | addr[2];
  68. airoha_fe_wr(eth, reg, val);
  69. val = (addr[3] << 16) | (addr[4] << 8) | addr[5];
  70. airoha_fe_wr(eth, REG_FE_MAC_LMIN(reg), val);
  71. airoha_fe_wr(eth, REG_FE_MAC_LMAX(reg), val);
  72. airoha_ppe_init_upd_mem(port);
  73. }
  74. static void airoha_set_gdm_port_fwd_cfg(struct airoha_eth *eth, u32 addr,
  75. u32 val)
  76. {
  77. airoha_fe_rmw(eth, addr, GDM_OCFQ_MASK,
  78. FIELD_PREP(GDM_OCFQ_MASK, val));
  79. airoha_fe_rmw(eth, addr, GDM_MCFQ_MASK,
  80. FIELD_PREP(GDM_MCFQ_MASK, val));
  81. airoha_fe_rmw(eth, addr, GDM_BCFQ_MASK,
  82. FIELD_PREP(GDM_BCFQ_MASK, val));
  83. airoha_fe_rmw(eth, addr, GDM_UCFQ_MASK,
  84. FIELD_PREP(GDM_UCFQ_MASK, val));
  85. }
  86. static int airoha_set_vip_for_gdm_port(struct airoha_gdm_port *port,
  87. bool enable)
  88. {
  89. struct airoha_eth *eth = port->qdma->eth;
  90. u32 vip_port;
  91. switch (port->id) {
  92. case AIROHA_GDM3_IDX:
  93. /* FIXME: handle XSI_PCIE1_PORT */
  94. vip_port = XSI_PCIE0_VIP_PORT_MASK;
  95. break;
  96. case AIROHA_GDM4_IDX:
  97. /* FIXME: handle XSI_USB_PORT */
  98. vip_port = XSI_ETH_VIP_PORT_MASK;
  99. break;
  100. default:
  101. return 0;
  102. }
  103. if (enable) {
  104. airoha_fe_set(eth, REG_FE_VIP_PORT_EN, vip_port);
  105. airoha_fe_set(eth, REG_FE_IFC_PORT_EN, vip_port);
  106. } else {
  107. airoha_fe_clear(eth, REG_FE_VIP_PORT_EN, vip_port);
  108. airoha_fe_clear(eth, REG_FE_IFC_PORT_EN, vip_port);
  109. }
  110. return 0;
  111. }
  112. static void airoha_fe_maccr_init(struct airoha_eth *eth)
  113. {
  114. int p;
  115. for (p = 1; p <= ARRAY_SIZE(eth->ports); p++)
  116. airoha_fe_set(eth, REG_GDM_FWD_CFG(p),
  117. GDM_TCP_CKSUM_MASK | GDM_UDP_CKSUM_MASK |
  118. GDM_IP4_CKSUM_MASK | GDM_DROP_CRC_ERR_MASK);
  119. airoha_fe_rmw(eth, REG_CDM_VLAN_CTRL(1), CDM_VLAN_MASK,
  120. FIELD_PREP(CDM_VLAN_MASK, 0x8100));
  121. airoha_fe_set(eth, REG_FE_CPORT_CFG, FE_CPORT_PAD);
  122. }
  123. static void airoha_fe_vip_setup(struct airoha_eth *eth)
  124. {
  125. airoha_fe_wr(eth, REG_FE_VIP_PATN(3), ETH_P_PPP_DISC);
  126. airoha_fe_wr(eth, REG_FE_VIP_EN(3), PATN_FCPU_EN_MASK | PATN_EN_MASK);
  127. airoha_fe_wr(eth, REG_FE_VIP_PATN(4), PPP_LCP);
  128. airoha_fe_wr(eth, REG_FE_VIP_EN(4),
  129. PATN_FCPU_EN_MASK | FIELD_PREP(PATN_TYPE_MASK, 1) |
  130. PATN_EN_MASK);
  131. airoha_fe_wr(eth, REG_FE_VIP_PATN(6), PPP_IPCP);
  132. airoha_fe_wr(eth, REG_FE_VIP_EN(6),
  133. PATN_FCPU_EN_MASK | FIELD_PREP(PATN_TYPE_MASK, 1) |
  134. PATN_EN_MASK);
  135. airoha_fe_wr(eth, REG_FE_VIP_PATN(7), PPP_CHAP);
  136. airoha_fe_wr(eth, REG_FE_VIP_EN(7),
  137. PATN_FCPU_EN_MASK | FIELD_PREP(PATN_TYPE_MASK, 1) |
  138. PATN_EN_MASK);
  139. /* BOOTP (0x43) */
  140. airoha_fe_wr(eth, REG_FE_VIP_PATN(8), 0x43);
  141. airoha_fe_wr(eth, REG_FE_VIP_EN(8),
  142. PATN_FCPU_EN_MASK | PATN_SP_EN_MASK |
  143. FIELD_PREP(PATN_TYPE_MASK, 4) | PATN_EN_MASK);
  144. /* BOOTP (0x44) */
  145. airoha_fe_wr(eth, REG_FE_VIP_PATN(9), 0x44);
  146. airoha_fe_wr(eth, REG_FE_VIP_EN(9),
  147. PATN_FCPU_EN_MASK | PATN_SP_EN_MASK |
  148. FIELD_PREP(PATN_TYPE_MASK, 4) | PATN_EN_MASK);
  149. /* ISAKMP */
  150. airoha_fe_wr(eth, REG_FE_VIP_PATN(10), 0x1f401f4);
  151. airoha_fe_wr(eth, REG_FE_VIP_EN(10),
  152. PATN_FCPU_EN_MASK | PATN_DP_EN_MASK | PATN_SP_EN_MASK |
  153. FIELD_PREP(PATN_TYPE_MASK, 4) | PATN_EN_MASK);
  154. airoha_fe_wr(eth, REG_FE_VIP_PATN(11), PPP_IPV6CP);
  155. airoha_fe_wr(eth, REG_FE_VIP_EN(11),
  156. PATN_FCPU_EN_MASK | FIELD_PREP(PATN_TYPE_MASK, 1) |
  157. PATN_EN_MASK);
  158. /* DHCPv6 */
  159. airoha_fe_wr(eth, REG_FE_VIP_PATN(12), 0x2220223);
  160. airoha_fe_wr(eth, REG_FE_VIP_EN(12),
  161. PATN_FCPU_EN_MASK | PATN_DP_EN_MASK | PATN_SP_EN_MASK |
  162. FIELD_PREP(PATN_TYPE_MASK, 4) | PATN_EN_MASK);
  163. airoha_fe_wr(eth, REG_FE_VIP_PATN(19), PPP_PAP);
  164. airoha_fe_wr(eth, REG_FE_VIP_EN(19),
  165. PATN_FCPU_EN_MASK | FIELD_PREP(PATN_TYPE_MASK, 1) |
  166. PATN_EN_MASK);
  167. /* ETH->ETH_P_1905 (0x893a) */
  168. airoha_fe_wr(eth, REG_FE_VIP_PATN(20), 0x893a);
  169. airoha_fe_wr(eth, REG_FE_VIP_EN(20),
  170. PATN_FCPU_EN_MASK | PATN_EN_MASK);
  171. airoha_fe_wr(eth, REG_FE_VIP_PATN(21), ETH_P_LLDP);
  172. airoha_fe_wr(eth, REG_FE_VIP_EN(21),
  173. PATN_FCPU_EN_MASK | PATN_EN_MASK);
  174. }
  175. static u32 airoha_fe_get_pse_queue_rsv_pages(struct airoha_eth *eth,
  176. u32 port, u32 queue)
  177. {
  178. u32 val;
  179. airoha_fe_rmw(eth, REG_FE_PSE_QUEUE_CFG_WR,
  180. PSE_CFG_PORT_ID_MASK | PSE_CFG_QUEUE_ID_MASK,
  181. FIELD_PREP(PSE_CFG_PORT_ID_MASK, port) |
  182. FIELD_PREP(PSE_CFG_QUEUE_ID_MASK, queue));
  183. val = airoha_fe_rr(eth, REG_FE_PSE_QUEUE_CFG_VAL);
  184. return FIELD_GET(PSE_CFG_OQ_RSV_MASK, val);
  185. }
  186. static void airoha_fe_set_pse_queue_rsv_pages(struct airoha_eth *eth,
  187. u32 port, u32 queue, u32 val)
  188. {
  189. airoha_fe_rmw(eth, REG_FE_PSE_QUEUE_CFG_VAL, PSE_CFG_OQ_RSV_MASK,
  190. FIELD_PREP(PSE_CFG_OQ_RSV_MASK, val));
  191. airoha_fe_rmw(eth, REG_FE_PSE_QUEUE_CFG_WR,
  192. PSE_CFG_PORT_ID_MASK | PSE_CFG_QUEUE_ID_MASK |
  193. PSE_CFG_WR_EN_MASK | PSE_CFG_OQRSV_SEL_MASK,
  194. FIELD_PREP(PSE_CFG_PORT_ID_MASK, port) |
  195. FIELD_PREP(PSE_CFG_QUEUE_ID_MASK, queue) |
  196. PSE_CFG_WR_EN_MASK | PSE_CFG_OQRSV_SEL_MASK);
  197. }
  198. static u32 airoha_fe_get_pse_all_rsv(struct airoha_eth *eth)
  199. {
  200. u32 val = airoha_fe_rr(eth, REG_FE_PSE_BUF_SET);
  201. return FIELD_GET(PSE_ALLRSV_MASK, val);
  202. }
  203. static int airoha_fe_set_pse_oq_rsv(struct airoha_eth *eth,
  204. u32 port, u32 queue, u32 val)
  205. {
  206. u32 orig_val = airoha_fe_get_pse_queue_rsv_pages(eth, port, queue);
  207. u32 tmp, all_rsv, fq_limit;
  208. airoha_fe_set_pse_queue_rsv_pages(eth, port, queue, val);
  209. /* modify all rsv */
  210. all_rsv = airoha_fe_get_pse_all_rsv(eth);
  211. all_rsv += (val - orig_val);
  212. airoha_fe_rmw(eth, REG_FE_PSE_BUF_SET, PSE_ALLRSV_MASK,
  213. FIELD_PREP(PSE_ALLRSV_MASK, all_rsv));
  214. /* modify hthd */
  215. tmp = airoha_fe_rr(eth, PSE_FQ_CFG);
  216. fq_limit = FIELD_GET(PSE_FQ_LIMIT_MASK, tmp);
  217. tmp = fq_limit - all_rsv - 0x20;
  218. airoha_fe_rmw(eth, REG_PSE_SHARE_USED_THD,
  219. PSE_SHARE_USED_HTHD_MASK,
  220. FIELD_PREP(PSE_SHARE_USED_HTHD_MASK, tmp));
  221. tmp = fq_limit - all_rsv - 0x100;
  222. airoha_fe_rmw(eth, REG_PSE_SHARE_USED_THD,
  223. PSE_SHARE_USED_MTHD_MASK,
  224. FIELD_PREP(PSE_SHARE_USED_MTHD_MASK, tmp));
  225. tmp = (3 * tmp) >> 2;
  226. airoha_fe_rmw(eth, REG_FE_PSE_BUF_SET,
  227. PSE_SHARE_USED_LTHD_MASK,
  228. FIELD_PREP(PSE_SHARE_USED_LTHD_MASK, tmp));
  229. return 0;
  230. }
  231. static void airoha_fe_pse_ports_init(struct airoha_eth *eth)
  232. {
  233. const u32 pse_port_num_queues[] = {
  234. [FE_PSE_PORT_CDM1] = 6,
  235. [FE_PSE_PORT_GDM1] = 6,
  236. [FE_PSE_PORT_GDM2] = 32,
  237. [FE_PSE_PORT_GDM3] = 6,
  238. [FE_PSE_PORT_PPE1] = 4,
  239. [FE_PSE_PORT_CDM2] = 6,
  240. [FE_PSE_PORT_CDM3] = 8,
  241. [FE_PSE_PORT_CDM4] = 10,
  242. [FE_PSE_PORT_PPE2] = 4,
  243. [FE_PSE_PORT_GDM4] = 2,
  244. [FE_PSE_PORT_CDM5] = 2,
  245. };
  246. u32 all_rsv;
  247. int q;
  248. all_rsv = airoha_fe_get_pse_all_rsv(eth);
  249. if (airoha_ppe_is_enabled(eth, 1)) {
  250. /* hw misses PPE2 oq rsv */
  251. all_rsv += PSE_RSV_PAGES *
  252. pse_port_num_queues[FE_PSE_PORT_PPE2];
  253. }
  254. airoha_fe_set(eth, REG_FE_PSE_BUF_SET, all_rsv);
  255. /* CMD1 */
  256. for (q = 0; q < pse_port_num_queues[FE_PSE_PORT_CDM1]; q++)
  257. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_CDM1, q,
  258. PSE_QUEUE_RSV_PAGES);
  259. /* GMD1 */
  260. for (q = 0; q < pse_port_num_queues[FE_PSE_PORT_GDM1]; q++)
  261. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_GDM1, q,
  262. PSE_QUEUE_RSV_PAGES);
  263. /* GMD2 */
  264. for (q = 6; q < pse_port_num_queues[FE_PSE_PORT_GDM2]; q++)
  265. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_GDM2, q, 0);
  266. /* GMD3 */
  267. for (q = 0; q < pse_port_num_queues[FE_PSE_PORT_GDM3]; q++)
  268. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_GDM3, q,
  269. PSE_QUEUE_RSV_PAGES);
  270. /* PPE1 */
  271. for (q = 0; q < pse_port_num_queues[FE_PSE_PORT_PPE1]; q++) {
  272. if (q < pse_port_num_queues[FE_PSE_PORT_PPE1])
  273. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_PPE1, q,
  274. PSE_QUEUE_RSV_PAGES);
  275. else
  276. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_PPE1, q, 0);
  277. }
  278. /* CDM2 */
  279. for (q = 0; q < pse_port_num_queues[FE_PSE_PORT_CDM2]; q++)
  280. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_CDM2, q,
  281. PSE_QUEUE_RSV_PAGES);
  282. /* CDM3 */
  283. for (q = 0; q < pse_port_num_queues[FE_PSE_PORT_CDM3] - 1; q++)
  284. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_CDM3, q, 0);
  285. /* CDM4 */
  286. for (q = 4; q < pse_port_num_queues[FE_PSE_PORT_CDM4]; q++)
  287. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_CDM4, q,
  288. PSE_QUEUE_RSV_PAGES);
  289. if (airoha_ppe_is_enabled(eth, 1)) {
  290. /* PPE2 */
  291. for (q = 0; q < pse_port_num_queues[FE_PSE_PORT_PPE2]; q++) {
  292. if (q < pse_port_num_queues[FE_PSE_PORT_PPE2] / 2)
  293. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_PPE2,
  294. q,
  295. PSE_QUEUE_RSV_PAGES);
  296. else
  297. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_PPE2,
  298. q, 0);
  299. }
  300. }
  301. /* GMD4 */
  302. for (q = 0; q < pse_port_num_queues[FE_PSE_PORT_GDM4]; q++)
  303. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_GDM4, q,
  304. PSE_QUEUE_RSV_PAGES);
  305. /* CDM5 */
  306. for (q = 0; q < pse_port_num_queues[FE_PSE_PORT_CDM5]; q++)
  307. airoha_fe_set_pse_oq_rsv(eth, FE_PSE_PORT_CDM5, q,
  308. PSE_QUEUE_RSV_PAGES);
  309. }
  310. static int airoha_fe_mc_vlan_clear(struct airoha_eth *eth)
  311. {
  312. int i;
  313. for (i = 0; i < AIROHA_FE_MC_MAX_VLAN_TABLE; i++) {
  314. int err, j;
  315. u32 val;
  316. airoha_fe_wr(eth, REG_MC_VLAN_DATA, 0x0);
  317. val = FIELD_PREP(MC_VLAN_CFG_TABLE_ID_MASK, i) |
  318. MC_VLAN_CFG_TABLE_SEL_MASK | MC_VLAN_CFG_RW_MASK;
  319. airoha_fe_wr(eth, REG_MC_VLAN_CFG, val);
  320. err = read_poll_timeout(airoha_fe_rr, val,
  321. val & MC_VLAN_CFG_CMD_DONE_MASK,
  322. USEC_PER_MSEC, 5 * USEC_PER_MSEC,
  323. false, eth, REG_MC_VLAN_CFG);
  324. if (err)
  325. return err;
  326. for (j = 0; j < AIROHA_FE_MC_MAX_VLAN_PORT; j++) {
  327. airoha_fe_wr(eth, REG_MC_VLAN_DATA, 0x0);
  328. val = FIELD_PREP(MC_VLAN_CFG_TABLE_ID_MASK, i) |
  329. FIELD_PREP(MC_VLAN_CFG_PORT_ID_MASK, j) |
  330. MC_VLAN_CFG_RW_MASK;
  331. airoha_fe_wr(eth, REG_MC_VLAN_CFG, val);
  332. err = read_poll_timeout(airoha_fe_rr, val,
  333. val & MC_VLAN_CFG_CMD_DONE_MASK,
  334. USEC_PER_MSEC,
  335. 5 * USEC_PER_MSEC, false, eth,
  336. REG_MC_VLAN_CFG);
  337. if (err)
  338. return err;
  339. }
  340. }
  341. return 0;
  342. }
  343. static void airoha_fe_crsn_qsel_init(struct airoha_eth *eth)
  344. {
  345. /* CDM1_CRSN_QSEL */
  346. airoha_fe_rmw(eth, REG_CDM_CRSN_QSEL(1, CRSN_22 >> 2),
  347. CDM_CRSN_QSEL_REASON_MASK(CRSN_22),
  348. FIELD_PREP(CDM_CRSN_QSEL_REASON_MASK(CRSN_22),
  349. CDM_CRSN_QSEL_Q1));
  350. airoha_fe_rmw(eth, REG_CDM_CRSN_QSEL(1, CRSN_08 >> 2),
  351. CDM_CRSN_QSEL_REASON_MASK(CRSN_08),
  352. FIELD_PREP(CDM_CRSN_QSEL_REASON_MASK(CRSN_08),
  353. CDM_CRSN_QSEL_Q1));
  354. airoha_fe_rmw(eth, REG_CDM_CRSN_QSEL(1, CRSN_21 >> 2),
  355. CDM_CRSN_QSEL_REASON_MASK(CRSN_21),
  356. FIELD_PREP(CDM_CRSN_QSEL_REASON_MASK(CRSN_21),
  357. CDM_CRSN_QSEL_Q1));
  358. airoha_fe_rmw(eth, REG_CDM_CRSN_QSEL(1, CRSN_24 >> 2),
  359. CDM_CRSN_QSEL_REASON_MASK(CRSN_24),
  360. FIELD_PREP(CDM_CRSN_QSEL_REASON_MASK(CRSN_24),
  361. CDM_CRSN_QSEL_Q6));
  362. airoha_fe_rmw(eth, REG_CDM_CRSN_QSEL(1, CRSN_25 >> 2),
  363. CDM_CRSN_QSEL_REASON_MASK(CRSN_25),
  364. FIELD_PREP(CDM_CRSN_QSEL_REASON_MASK(CRSN_25),
  365. CDM_CRSN_QSEL_Q1));
  366. /* CDM2_CRSN_QSEL */
  367. airoha_fe_rmw(eth, REG_CDM_CRSN_QSEL(2, CRSN_08 >> 2),
  368. CDM_CRSN_QSEL_REASON_MASK(CRSN_08),
  369. FIELD_PREP(CDM_CRSN_QSEL_REASON_MASK(CRSN_08),
  370. CDM_CRSN_QSEL_Q1));
  371. airoha_fe_rmw(eth, REG_CDM_CRSN_QSEL(2, CRSN_21 >> 2),
  372. CDM_CRSN_QSEL_REASON_MASK(CRSN_21),
  373. FIELD_PREP(CDM_CRSN_QSEL_REASON_MASK(CRSN_21),
  374. CDM_CRSN_QSEL_Q1));
  375. airoha_fe_rmw(eth, REG_CDM_CRSN_QSEL(2, CRSN_22 >> 2),
  376. CDM_CRSN_QSEL_REASON_MASK(CRSN_22),
  377. FIELD_PREP(CDM_CRSN_QSEL_REASON_MASK(CRSN_22),
  378. CDM_CRSN_QSEL_Q1));
  379. airoha_fe_rmw(eth, REG_CDM_CRSN_QSEL(2, CRSN_24 >> 2),
  380. CDM_CRSN_QSEL_REASON_MASK(CRSN_24),
  381. FIELD_PREP(CDM_CRSN_QSEL_REASON_MASK(CRSN_24),
  382. CDM_CRSN_QSEL_Q6));
  383. airoha_fe_rmw(eth, REG_CDM_CRSN_QSEL(2, CRSN_25 >> 2),
  384. CDM_CRSN_QSEL_REASON_MASK(CRSN_25),
  385. FIELD_PREP(CDM_CRSN_QSEL_REASON_MASK(CRSN_25),
  386. CDM_CRSN_QSEL_Q1));
  387. }
  388. static int airoha_fe_init(struct airoha_eth *eth)
  389. {
  390. airoha_fe_maccr_init(eth);
  391. /* PSE IQ reserve */
  392. airoha_fe_rmw(eth, REG_PSE_IQ_REV1, PSE_IQ_RES1_P2_MASK,
  393. FIELD_PREP(PSE_IQ_RES1_P2_MASK, 0x10));
  394. airoha_fe_rmw(eth, REG_PSE_IQ_REV2,
  395. PSE_IQ_RES2_P5_MASK | PSE_IQ_RES2_P4_MASK,
  396. FIELD_PREP(PSE_IQ_RES2_P5_MASK, 0x40) |
  397. FIELD_PREP(PSE_IQ_RES2_P4_MASK, 0x34));
  398. /* enable FE copy engine for MC/KA/DPI */
  399. airoha_fe_wr(eth, REG_FE_PCE_CFG,
  400. PCE_DPI_EN_MASK | PCE_KA_EN_MASK | PCE_MC_EN_MASK);
  401. /* set vip queue selection to ring 1 */
  402. airoha_fe_rmw(eth, REG_CDM_FWD_CFG(1), CDM_VIP_QSEL_MASK,
  403. FIELD_PREP(CDM_VIP_QSEL_MASK, 0x4));
  404. airoha_fe_rmw(eth, REG_CDM_FWD_CFG(2), CDM_VIP_QSEL_MASK,
  405. FIELD_PREP(CDM_VIP_QSEL_MASK, 0x4));
  406. /* set GDM4 source interface offset to 8 */
  407. airoha_fe_rmw(eth, REG_GDM_SRC_PORT_SET(4),
  408. GDM_SPORT_OFF2_MASK |
  409. GDM_SPORT_OFF1_MASK |
  410. GDM_SPORT_OFF0_MASK,
  411. FIELD_PREP(GDM_SPORT_OFF2_MASK, 8) |
  412. FIELD_PREP(GDM_SPORT_OFF1_MASK, 8) |
  413. FIELD_PREP(GDM_SPORT_OFF0_MASK, 8));
  414. /* set PSE Page as 128B */
  415. airoha_fe_rmw(eth, REG_FE_DMA_GLO_CFG,
  416. FE_DMA_GLO_L2_SPACE_MASK | FE_DMA_GLO_PG_SZ_MASK,
  417. FIELD_PREP(FE_DMA_GLO_L2_SPACE_MASK, 2) |
  418. FE_DMA_GLO_PG_SZ_MASK);
  419. airoha_fe_wr(eth, REG_FE_RST_GLO_CFG,
  420. FE_RST_CORE_MASK | FE_RST_GDM3_MBI_ARB_MASK |
  421. FE_RST_GDM4_MBI_ARB_MASK);
  422. usleep_range(1000, 2000);
  423. /* connect RxRing1 and RxRing15 to PSE Port0 OQ-1
  424. * connect other rings to PSE Port0 OQ-0
  425. */
  426. airoha_fe_wr(eth, REG_FE_CDM1_OQ_MAP0, BIT(4));
  427. airoha_fe_wr(eth, REG_FE_CDM1_OQ_MAP1, BIT(28));
  428. airoha_fe_wr(eth, REG_FE_CDM1_OQ_MAP2, BIT(4));
  429. airoha_fe_wr(eth, REG_FE_CDM1_OQ_MAP3, BIT(28));
  430. airoha_fe_vip_setup(eth);
  431. airoha_fe_pse_ports_init(eth);
  432. airoha_fe_set(eth, REG_GDM_MISC_CFG,
  433. GDM2_RDM_ACK_WAIT_PREF_MASK |
  434. GDM2_CHN_VLD_MODE_MASK);
  435. airoha_fe_rmw(eth, REG_CDM_FWD_CFG(2), CDM_OAM_QSEL_MASK,
  436. FIELD_PREP(CDM_OAM_QSEL_MASK, 15));
  437. /* init fragment and assemble Force Port */
  438. /* NPU Core-3, NPU Bridge Channel-3 */
  439. airoha_fe_rmw(eth, REG_IP_FRAG_FP,
  440. IP_FRAGMENT_PORT_MASK | IP_FRAGMENT_NBQ_MASK,
  441. FIELD_PREP(IP_FRAGMENT_PORT_MASK, 6) |
  442. FIELD_PREP(IP_FRAGMENT_NBQ_MASK, 3));
  443. /* QDMA LAN, RX Ring-22 */
  444. airoha_fe_rmw(eth, REG_IP_FRAG_FP,
  445. IP_ASSEMBLE_PORT_MASK | IP_ASSEMBLE_NBQ_MASK,
  446. FIELD_PREP(IP_ASSEMBLE_PORT_MASK, 0) |
  447. FIELD_PREP(IP_ASSEMBLE_NBQ_MASK, 22));
  448. airoha_fe_set(eth, REG_GDM_FWD_CFG(AIROHA_GDM3_IDX), GDM_PAD_EN_MASK);
  449. airoha_fe_set(eth, REG_GDM_FWD_CFG(AIROHA_GDM4_IDX), GDM_PAD_EN_MASK);
  450. airoha_fe_crsn_qsel_init(eth);
  451. airoha_fe_clear(eth, REG_FE_CPORT_CFG, FE_CPORT_QUEUE_XFC_MASK);
  452. airoha_fe_set(eth, REG_FE_CPORT_CFG, FE_CPORT_PORT_XFC_MASK);
  453. /* default aging mode for mbi unlock issue */
  454. airoha_fe_rmw(eth, REG_GDM_CHN_RLS(2),
  455. MBI_RX_AGE_SEL_MASK | MBI_TX_AGE_SEL_MASK,
  456. FIELD_PREP(MBI_RX_AGE_SEL_MASK, 3) |
  457. FIELD_PREP(MBI_TX_AGE_SEL_MASK, 3));
  458. /* disable IFC by default */
  459. airoha_fe_clear(eth, REG_FE_CSR_IFC_CFG, FE_IFC_EN_MASK);
  460. /* enable 1:N vlan action, init vlan table */
  461. airoha_fe_set(eth, REG_MC_VLAN_EN, MC_VLAN_EN_MASK);
  462. return airoha_fe_mc_vlan_clear(eth);
  463. }
  464. static int airoha_qdma_fill_rx_queue(struct airoha_queue *q)
  465. {
  466. struct airoha_qdma *qdma = q->qdma;
  467. int qid = q - &qdma->q_rx[0];
  468. int nframes = 0;
  469. while (q->queued < q->ndesc - 1) {
  470. struct airoha_queue_entry *e = &q->entry[q->head];
  471. struct airoha_qdma_desc *desc = &q->desc[q->head];
  472. struct page *page;
  473. int offset;
  474. u32 val;
  475. page = page_pool_dev_alloc_frag(q->page_pool, &offset,
  476. q->buf_size);
  477. if (!page)
  478. break;
  479. q->head = (q->head + 1) % q->ndesc;
  480. q->queued++;
  481. nframes++;
  482. e->buf = page_address(page) + offset;
  483. e->dma_addr = page_pool_get_dma_addr(page) + offset;
  484. e->dma_len = SKB_WITH_OVERHEAD(q->buf_size);
  485. val = FIELD_PREP(QDMA_DESC_LEN_MASK, e->dma_len);
  486. WRITE_ONCE(desc->ctrl, cpu_to_le32(val));
  487. WRITE_ONCE(desc->addr, cpu_to_le32(e->dma_addr));
  488. val = FIELD_PREP(QDMA_DESC_NEXT_ID_MASK, q->head);
  489. WRITE_ONCE(desc->data, cpu_to_le32(val));
  490. WRITE_ONCE(desc->msg0, 0);
  491. WRITE_ONCE(desc->msg1, 0);
  492. WRITE_ONCE(desc->msg2, 0);
  493. WRITE_ONCE(desc->msg3, 0);
  494. airoha_qdma_rmw(qdma, REG_RX_CPU_IDX(qid),
  495. RX_RING_CPU_IDX_MASK,
  496. FIELD_PREP(RX_RING_CPU_IDX_MASK, q->head));
  497. }
  498. return nframes;
  499. }
  500. static int airoha_qdma_get_gdm_port(struct airoha_eth *eth,
  501. struct airoha_qdma_desc *desc)
  502. {
  503. u32 port, sport, msg1 = le32_to_cpu(desc->msg1);
  504. sport = FIELD_GET(QDMA_ETH_RXMSG_SPORT_MASK, msg1);
  505. switch (sport) {
  506. case 0x10 ... 0x14:
  507. port = 0;
  508. break;
  509. case 0x2 ... 0x4:
  510. port = sport - 1;
  511. break;
  512. default:
  513. return -EINVAL;
  514. }
  515. return port >= ARRAY_SIZE(eth->ports) ? -EINVAL : port;
  516. }
  517. static int airoha_qdma_rx_process(struct airoha_queue *q, int budget)
  518. {
  519. enum dma_data_direction dir = page_pool_get_dma_dir(q->page_pool);
  520. struct airoha_qdma *qdma = q->qdma;
  521. struct airoha_eth *eth = qdma->eth;
  522. int qid = q - &qdma->q_rx[0];
  523. int done = 0;
  524. while (done < budget) {
  525. struct airoha_queue_entry *e = &q->entry[q->tail];
  526. struct airoha_qdma_desc *desc = &q->desc[q->tail];
  527. u32 hash, reason, msg1 = le32_to_cpu(desc->msg1);
  528. struct page *page = virt_to_head_page(e->buf);
  529. u32 desc_ctrl = le32_to_cpu(desc->ctrl);
  530. struct airoha_gdm_port *port;
  531. int data_len, len, p;
  532. if (!(desc_ctrl & QDMA_DESC_DONE_MASK))
  533. break;
  534. q->tail = (q->tail + 1) % q->ndesc;
  535. q->queued--;
  536. dma_sync_single_for_cpu(eth->dev, e->dma_addr,
  537. SKB_WITH_OVERHEAD(q->buf_size), dir);
  538. len = FIELD_GET(QDMA_DESC_LEN_MASK, desc_ctrl);
  539. data_len = q->skb ? q->buf_size
  540. : SKB_WITH_OVERHEAD(q->buf_size);
  541. if (!len || data_len < len)
  542. goto free_frag;
  543. p = airoha_qdma_get_gdm_port(eth, desc);
  544. if (p < 0 || !eth->ports[p])
  545. goto free_frag;
  546. port = eth->ports[p];
  547. if (!q->skb) { /* first buffer */
  548. q->skb = napi_build_skb(e->buf, q->buf_size);
  549. if (!q->skb)
  550. goto free_frag;
  551. __skb_put(q->skb, len);
  552. skb_mark_for_recycle(q->skb);
  553. q->skb->dev = port->dev;
  554. q->skb->protocol = eth_type_trans(q->skb, port->dev);
  555. q->skb->ip_summed = CHECKSUM_UNNECESSARY;
  556. skb_record_rx_queue(q->skb, qid);
  557. } else { /* scattered frame */
  558. struct skb_shared_info *shinfo = skb_shinfo(q->skb);
  559. int nr_frags = shinfo->nr_frags;
  560. if (nr_frags >= ARRAY_SIZE(shinfo->frags))
  561. goto free_frag;
  562. skb_add_rx_frag(q->skb, nr_frags, page,
  563. e->buf - page_address(page), len,
  564. q->buf_size);
  565. }
  566. if (FIELD_GET(QDMA_DESC_MORE_MASK, desc_ctrl))
  567. continue;
  568. if (netdev_uses_dsa(port->dev)) {
  569. /* PPE module requires untagged packets to work
  570. * properly and it provides DSA port index via the
  571. * DMA descriptor. Report DSA tag to the DSA stack
  572. * via skb dst info.
  573. */
  574. u32 sptag = FIELD_GET(QDMA_ETH_RXMSG_SPTAG,
  575. le32_to_cpu(desc->msg0));
  576. if (sptag < ARRAY_SIZE(port->dsa_meta) &&
  577. port->dsa_meta[sptag])
  578. skb_dst_set_noref(q->skb,
  579. &port->dsa_meta[sptag]->dst);
  580. }
  581. hash = FIELD_GET(AIROHA_RXD4_FOE_ENTRY, msg1);
  582. if (hash != AIROHA_RXD4_FOE_ENTRY)
  583. skb_set_hash(q->skb, jhash_1word(hash, 0),
  584. PKT_HASH_TYPE_L4);
  585. reason = FIELD_GET(AIROHA_RXD4_PPE_CPU_REASON, msg1);
  586. if (reason == PPE_CPU_REASON_HIT_UNBIND_RATE_REACHED)
  587. airoha_ppe_check_skb(&eth->ppe->dev, q->skb, hash,
  588. false);
  589. done++;
  590. napi_gro_receive(&q->napi, q->skb);
  591. q->skb = NULL;
  592. continue;
  593. free_frag:
  594. if (q->skb) {
  595. dev_kfree_skb(q->skb);
  596. q->skb = NULL;
  597. }
  598. page_pool_put_full_page(q->page_pool, page, true);
  599. }
  600. airoha_qdma_fill_rx_queue(q);
  601. return done;
  602. }
  603. static int airoha_qdma_rx_napi_poll(struct napi_struct *napi, int budget)
  604. {
  605. struct airoha_queue *q = container_of(napi, struct airoha_queue, napi);
  606. int cur, done = 0;
  607. do {
  608. cur = airoha_qdma_rx_process(q, budget - done);
  609. done += cur;
  610. } while (cur && done < budget);
  611. if (done < budget && napi_complete(napi)) {
  612. struct airoha_qdma *qdma = q->qdma;
  613. int i, qid = q - &qdma->q_rx[0];
  614. int intr_reg = qid < RX_DONE_HIGH_OFFSET ? QDMA_INT_REG_IDX1
  615. : QDMA_INT_REG_IDX2;
  616. for (i = 0; i < ARRAY_SIZE(qdma->irq_banks); i++) {
  617. if (!(BIT(qid) & RX_IRQ_BANK_PIN_MASK(i)))
  618. continue;
  619. airoha_qdma_irq_enable(&qdma->irq_banks[i], intr_reg,
  620. BIT(qid % RX_DONE_HIGH_OFFSET));
  621. }
  622. }
  623. return done;
  624. }
  625. static int airoha_qdma_init_rx_queue(struct airoha_queue *q,
  626. struct airoha_qdma *qdma, int ndesc)
  627. {
  628. const struct page_pool_params pp_params = {
  629. .order = 0,
  630. .pool_size = 256,
  631. .flags = PP_FLAG_DMA_MAP | PP_FLAG_DMA_SYNC_DEV,
  632. .dma_dir = DMA_FROM_DEVICE,
  633. .max_len = PAGE_SIZE,
  634. .nid = NUMA_NO_NODE,
  635. .dev = qdma->eth->dev,
  636. .napi = &q->napi,
  637. };
  638. struct airoha_eth *eth = qdma->eth;
  639. int qid = q - &qdma->q_rx[0], thr;
  640. dma_addr_t dma_addr;
  641. q->buf_size = PAGE_SIZE / 2;
  642. q->ndesc = ndesc;
  643. q->qdma = qdma;
  644. q->entry = devm_kzalloc(eth->dev, q->ndesc * sizeof(*q->entry),
  645. GFP_KERNEL);
  646. if (!q->entry)
  647. return -ENOMEM;
  648. q->page_pool = page_pool_create(&pp_params);
  649. if (IS_ERR(q->page_pool)) {
  650. int err = PTR_ERR(q->page_pool);
  651. q->page_pool = NULL;
  652. return err;
  653. }
  654. q->desc = dmam_alloc_coherent(eth->dev, q->ndesc * sizeof(*q->desc),
  655. &dma_addr, GFP_KERNEL);
  656. if (!q->desc)
  657. return -ENOMEM;
  658. netif_napi_add(eth->napi_dev, &q->napi, airoha_qdma_rx_napi_poll);
  659. airoha_qdma_wr(qdma, REG_RX_RING_BASE(qid), dma_addr);
  660. airoha_qdma_rmw(qdma, REG_RX_RING_SIZE(qid),
  661. RX_RING_SIZE_MASK,
  662. FIELD_PREP(RX_RING_SIZE_MASK, ndesc));
  663. thr = clamp(ndesc >> 3, 1, 32);
  664. airoha_qdma_rmw(qdma, REG_RX_RING_SIZE(qid), RX_RING_THR_MASK,
  665. FIELD_PREP(RX_RING_THR_MASK, thr));
  666. airoha_qdma_rmw(qdma, REG_RX_DMA_IDX(qid), RX_RING_DMA_IDX_MASK,
  667. FIELD_PREP(RX_RING_DMA_IDX_MASK, q->head));
  668. airoha_qdma_set(qdma, REG_RX_SCATTER_CFG(qid), RX_RING_SG_EN_MASK);
  669. airoha_qdma_fill_rx_queue(q);
  670. return 0;
  671. }
  672. static void airoha_qdma_cleanup_rx_queue(struct airoha_queue *q)
  673. {
  674. struct airoha_qdma *qdma = q->qdma;
  675. struct airoha_eth *eth = qdma->eth;
  676. int qid = q - &qdma->q_rx[0];
  677. while (q->queued) {
  678. struct airoha_queue_entry *e = &q->entry[q->tail];
  679. struct airoha_qdma_desc *desc = &q->desc[q->tail];
  680. struct page *page = virt_to_head_page(e->buf);
  681. dma_sync_single_for_cpu(eth->dev, e->dma_addr, e->dma_len,
  682. page_pool_get_dma_dir(q->page_pool));
  683. page_pool_put_full_page(q->page_pool, page, false);
  684. /* Reset DMA descriptor */
  685. WRITE_ONCE(desc->ctrl, 0);
  686. WRITE_ONCE(desc->addr, 0);
  687. WRITE_ONCE(desc->data, 0);
  688. WRITE_ONCE(desc->msg0, 0);
  689. WRITE_ONCE(desc->msg1, 0);
  690. WRITE_ONCE(desc->msg2, 0);
  691. WRITE_ONCE(desc->msg3, 0);
  692. q->tail = (q->tail + 1) % q->ndesc;
  693. q->queued--;
  694. }
  695. q->head = q->tail;
  696. airoha_qdma_rmw(qdma, REG_RX_DMA_IDX(qid), RX_RING_DMA_IDX_MASK,
  697. FIELD_PREP(RX_RING_DMA_IDX_MASK, q->tail));
  698. }
  699. static int airoha_qdma_init_rx(struct airoha_qdma *qdma)
  700. {
  701. int i;
  702. for (i = 0; i < ARRAY_SIZE(qdma->q_rx); i++) {
  703. int err;
  704. if (!(RX_DONE_INT_MASK & BIT(i))) {
  705. /* rx-queue not binded to irq */
  706. continue;
  707. }
  708. err = airoha_qdma_init_rx_queue(&qdma->q_rx[i], qdma,
  709. RX_DSCP_NUM(i));
  710. if (err)
  711. return err;
  712. }
  713. return 0;
  714. }
  715. static int airoha_qdma_tx_napi_poll(struct napi_struct *napi, int budget)
  716. {
  717. struct airoha_tx_irq_queue *irq_q;
  718. int id, done = 0, irq_queued;
  719. struct airoha_qdma *qdma;
  720. struct airoha_eth *eth;
  721. u32 status, head;
  722. irq_q = container_of(napi, struct airoha_tx_irq_queue, napi);
  723. qdma = irq_q->qdma;
  724. id = irq_q - &qdma->q_tx_irq[0];
  725. eth = qdma->eth;
  726. status = airoha_qdma_rr(qdma, REG_IRQ_STATUS(id));
  727. head = FIELD_GET(IRQ_HEAD_IDX_MASK, status);
  728. head = head % irq_q->size;
  729. irq_queued = FIELD_GET(IRQ_ENTRY_LEN_MASK, status);
  730. while (irq_queued > 0 && done < budget) {
  731. u32 qid, val = irq_q->q[head];
  732. struct airoha_qdma_desc *desc;
  733. struct airoha_queue_entry *e;
  734. struct airoha_queue *q;
  735. u32 index, desc_ctrl;
  736. struct sk_buff *skb;
  737. if (val == 0xff)
  738. break;
  739. irq_q->q[head] = 0xff; /* mark as done */
  740. head = (head + 1) % irq_q->size;
  741. irq_queued--;
  742. done++;
  743. qid = FIELD_GET(IRQ_RING_IDX_MASK, val);
  744. if (qid >= ARRAY_SIZE(qdma->q_tx))
  745. continue;
  746. q = &qdma->q_tx[qid];
  747. if (!q->ndesc)
  748. continue;
  749. index = FIELD_GET(IRQ_DESC_IDX_MASK, val);
  750. if (index >= q->ndesc)
  751. continue;
  752. spin_lock_bh(&q->lock);
  753. if (!q->queued)
  754. goto unlock;
  755. desc = &q->desc[index];
  756. desc_ctrl = le32_to_cpu(desc->ctrl);
  757. if (!(desc_ctrl & QDMA_DESC_DONE_MASK) &&
  758. !(desc_ctrl & QDMA_DESC_DROP_MASK))
  759. goto unlock;
  760. e = &q->entry[index];
  761. skb = e->skb;
  762. dma_unmap_single(eth->dev, e->dma_addr, e->dma_len,
  763. DMA_TO_DEVICE);
  764. e->dma_addr = 0;
  765. list_add_tail(&e->list, &q->tx_list);
  766. WRITE_ONCE(desc->msg0, 0);
  767. WRITE_ONCE(desc->msg1, 0);
  768. q->queued--;
  769. if (skb) {
  770. u16 queue = skb_get_queue_mapping(skb);
  771. struct netdev_queue *txq;
  772. txq = netdev_get_tx_queue(skb->dev, queue);
  773. netdev_tx_completed_queue(txq, 1, skb->len);
  774. if (netif_tx_queue_stopped(txq) &&
  775. q->ndesc - q->queued >= q->free_thr)
  776. netif_tx_wake_queue(txq);
  777. dev_kfree_skb_any(skb);
  778. }
  779. unlock:
  780. spin_unlock_bh(&q->lock);
  781. }
  782. if (done) {
  783. int i, len = done >> 7;
  784. for (i = 0; i < len; i++)
  785. airoha_qdma_rmw(qdma, REG_IRQ_CLEAR_LEN(id),
  786. IRQ_CLEAR_LEN_MASK, 0x80);
  787. airoha_qdma_rmw(qdma, REG_IRQ_CLEAR_LEN(id),
  788. IRQ_CLEAR_LEN_MASK, (done & 0x7f));
  789. }
  790. if (done < budget && napi_complete(napi))
  791. airoha_qdma_irq_enable(&qdma->irq_banks[0], QDMA_INT_REG_IDX0,
  792. TX_DONE_INT_MASK(id));
  793. return done;
  794. }
  795. static int airoha_qdma_init_tx_queue(struct airoha_queue *q,
  796. struct airoha_qdma *qdma, int size)
  797. {
  798. struct airoha_eth *eth = qdma->eth;
  799. int i, qid = q - &qdma->q_tx[0];
  800. dma_addr_t dma_addr;
  801. spin_lock_init(&q->lock);
  802. q->ndesc = size;
  803. q->qdma = qdma;
  804. q->free_thr = 1 + MAX_SKB_FRAGS;
  805. INIT_LIST_HEAD(&q->tx_list);
  806. q->entry = devm_kzalloc(eth->dev, q->ndesc * sizeof(*q->entry),
  807. GFP_KERNEL);
  808. if (!q->entry)
  809. return -ENOMEM;
  810. q->desc = dmam_alloc_coherent(eth->dev, q->ndesc * sizeof(*q->desc),
  811. &dma_addr, GFP_KERNEL);
  812. if (!q->desc)
  813. return -ENOMEM;
  814. for (i = 0; i < q->ndesc; i++) {
  815. u32 val = FIELD_PREP(QDMA_DESC_DONE_MASK, 1);
  816. list_add_tail(&q->entry[i].list, &q->tx_list);
  817. WRITE_ONCE(q->desc[i].ctrl, cpu_to_le32(val));
  818. }
  819. /* xmit ring drop default setting */
  820. airoha_qdma_set(qdma, REG_TX_RING_BLOCKING(qid),
  821. TX_RING_IRQ_BLOCKING_TX_DROP_EN_MASK);
  822. airoha_qdma_wr(qdma, REG_TX_RING_BASE(qid), dma_addr);
  823. airoha_qdma_rmw(qdma, REG_TX_CPU_IDX(qid), TX_RING_CPU_IDX_MASK,
  824. FIELD_PREP(TX_RING_CPU_IDX_MASK, 0));
  825. airoha_qdma_rmw(qdma, REG_TX_DMA_IDX(qid), TX_RING_DMA_IDX_MASK,
  826. FIELD_PREP(TX_RING_DMA_IDX_MASK, 0));
  827. return 0;
  828. }
  829. static int airoha_qdma_tx_irq_init(struct airoha_tx_irq_queue *irq_q,
  830. struct airoha_qdma *qdma, int size)
  831. {
  832. int id = irq_q - &qdma->q_tx_irq[0];
  833. struct airoha_eth *eth = qdma->eth;
  834. dma_addr_t dma_addr;
  835. netif_napi_add_tx(eth->napi_dev, &irq_q->napi,
  836. airoha_qdma_tx_napi_poll);
  837. irq_q->q = dmam_alloc_coherent(eth->dev, size * sizeof(u32),
  838. &dma_addr, GFP_KERNEL);
  839. if (!irq_q->q)
  840. return -ENOMEM;
  841. memset(irq_q->q, 0xff, size * sizeof(u32));
  842. irq_q->size = size;
  843. irq_q->qdma = qdma;
  844. airoha_qdma_wr(qdma, REG_TX_IRQ_BASE(id), dma_addr);
  845. airoha_qdma_rmw(qdma, REG_TX_IRQ_CFG(id), TX_IRQ_DEPTH_MASK,
  846. FIELD_PREP(TX_IRQ_DEPTH_MASK, size));
  847. airoha_qdma_rmw(qdma, REG_TX_IRQ_CFG(id), TX_IRQ_THR_MASK,
  848. FIELD_PREP(TX_IRQ_THR_MASK, 1));
  849. return 0;
  850. }
  851. static int airoha_qdma_init_tx(struct airoha_qdma *qdma)
  852. {
  853. int i, err;
  854. for (i = 0; i < ARRAY_SIZE(qdma->q_tx_irq); i++) {
  855. err = airoha_qdma_tx_irq_init(&qdma->q_tx_irq[i], qdma,
  856. IRQ_QUEUE_LEN(i));
  857. if (err)
  858. return err;
  859. }
  860. for (i = 0; i < ARRAY_SIZE(qdma->q_tx); i++) {
  861. err = airoha_qdma_init_tx_queue(&qdma->q_tx[i], qdma,
  862. TX_DSCP_NUM);
  863. if (err)
  864. return err;
  865. }
  866. return 0;
  867. }
  868. static void airoha_qdma_cleanup_tx_queue(struct airoha_queue *q)
  869. {
  870. struct airoha_eth *eth = q->qdma->eth;
  871. int i;
  872. spin_lock_bh(&q->lock);
  873. for (i = 0; i < q->ndesc; i++) {
  874. struct airoha_queue_entry *e = &q->entry[i];
  875. if (!e->dma_addr)
  876. continue;
  877. dma_unmap_single(eth->dev, e->dma_addr, e->dma_len,
  878. DMA_TO_DEVICE);
  879. dev_kfree_skb_any(e->skb);
  880. e->dma_addr = 0;
  881. e->skb = NULL;
  882. list_add_tail(&e->list, &q->tx_list);
  883. q->queued--;
  884. }
  885. spin_unlock_bh(&q->lock);
  886. }
  887. static int airoha_qdma_init_hfwd_queues(struct airoha_qdma *qdma)
  888. {
  889. int size, index, num_desc = HW_DSCP_NUM;
  890. struct airoha_eth *eth = qdma->eth;
  891. int id = qdma - &eth->qdma[0];
  892. u32 status, buf_size;
  893. dma_addr_t dma_addr;
  894. const char *name;
  895. name = devm_kasprintf(eth->dev, GFP_KERNEL, "qdma%d-buf", id);
  896. if (!name)
  897. return -ENOMEM;
  898. buf_size = id ? AIROHA_MAX_PACKET_SIZE / 2 : AIROHA_MAX_PACKET_SIZE;
  899. index = of_property_match_string(eth->dev->of_node,
  900. "memory-region-names", name);
  901. if (index >= 0) {
  902. struct reserved_mem *rmem;
  903. struct device_node *np;
  904. /* Consume reserved memory for hw forwarding buffers queue if
  905. * available in the DTS
  906. */
  907. np = of_parse_phandle(eth->dev->of_node, "memory-region",
  908. index);
  909. if (!np)
  910. return -ENODEV;
  911. rmem = of_reserved_mem_lookup(np);
  912. of_node_put(np);
  913. dma_addr = rmem->base;
  914. /* Compute the number of hw descriptors according to the
  915. * reserved memory size and the payload buffer size
  916. */
  917. num_desc = div_u64(rmem->size, buf_size);
  918. } else {
  919. size = buf_size * num_desc;
  920. if (!dmam_alloc_coherent(eth->dev, size, &dma_addr,
  921. GFP_KERNEL))
  922. return -ENOMEM;
  923. }
  924. airoha_qdma_wr(qdma, REG_FWD_BUF_BASE, dma_addr);
  925. size = num_desc * sizeof(struct airoha_qdma_fwd_desc);
  926. if (!dmam_alloc_coherent(eth->dev, size, &dma_addr, GFP_KERNEL))
  927. return -ENOMEM;
  928. airoha_qdma_wr(qdma, REG_FWD_DSCP_BASE, dma_addr);
  929. /* QDMA0: 2KB. QDMA1: 1KB */
  930. airoha_qdma_rmw(qdma, REG_HW_FWD_DSCP_CFG,
  931. HW_FWD_DSCP_PAYLOAD_SIZE_MASK,
  932. FIELD_PREP(HW_FWD_DSCP_PAYLOAD_SIZE_MASK, !!id));
  933. airoha_qdma_rmw(qdma, REG_FWD_DSCP_LOW_THR, FWD_DSCP_LOW_THR_MASK,
  934. FIELD_PREP(FWD_DSCP_LOW_THR_MASK, 128));
  935. airoha_qdma_rmw(qdma, REG_LMGR_INIT_CFG,
  936. LMGR_INIT_START | LMGR_SRAM_MODE_MASK |
  937. HW_FWD_DESC_NUM_MASK,
  938. FIELD_PREP(HW_FWD_DESC_NUM_MASK, num_desc) |
  939. LMGR_INIT_START | LMGR_SRAM_MODE_MASK);
  940. return read_poll_timeout(airoha_qdma_rr, status,
  941. !(status & LMGR_INIT_START), USEC_PER_MSEC,
  942. 30 * USEC_PER_MSEC, true, qdma,
  943. REG_LMGR_INIT_CFG);
  944. }
  945. static void airoha_qdma_init_qos(struct airoha_qdma *qdma)
  946. {
  947. airoha_qdma_clear(qdma, REG_TXWRR_MODE_CFG, TWRR_WEIGHT_SCALE_MASK);
  948. airoha_qdma_set(qdma, REG_TXWRR_MODE_CFG, TWRR_WEIGHT_BASE_MASK);
  949. airoha_qdma_clear(qdma, REG_PSE_BUF_USAGE_CFG,
  950. PSE_BUF_ESTIMATE_EN_MASK);
  951. airoha_qdma_set(qdma, REG_EGRESS_RATE_METER_CFG,
  952. EGRESS_RATE_METER_EN_MASK |
  953. EGRESS_RATE_METER_EQ_RATE_EN_MASK);
  954. /* 2047us x 31 = 63.457ms */
  955. airoha_qdma_rmw(qdma, REG_EGRESS_RATE_METER_CFG,
  956. EGRESS_RATE_METER_WINDOW_SZ_MASK,
  957. FIELD_PREP(EGRESS_RATE_METER_WINDOW_SZ_MASK, 0x1f));
  958. airoha_qdma_rmw(qdma, REG_EGRESS_RATE_METER_CFG,
  959. EGRESS_RATE_METER_TIMESLICE_MASK,
  960. FIELD_PREP(EGRESS_RATE_METER_TIMESLICE_MASK, 0x7ff));
  961. /* ratelimit init */
  962. airoha_qdma_set(qdma, REG_GLB_TRTCM_CFG, GLB_TRTCM_EN_MASK);
  963. /* fast-tick 25us */
  964. airoha_qdma_rmw(qdma, REG_GLB_TRTCM_CFG, GLB_FAST_TICK_MASK,
  965. FIELD_PREP(GLB_FAST_TICK_MASK, 25));
  966. airoha_qdma_rmw(qdma, REG_GLB_TRTCM_CFG, GLB_SLOW_TICK_RATIO_MASK,
  967. FIELD_PREP(GLB_SLOW_TICK_RATIO_MASK, 40));
  968. airoha_qdma_set(qdma, REG_EGRESS_TRTCM_CFG, EGRESS_TRTCM_EN_MASK);
  969. airoha_qdma_rmw(qdma, REG_EGRESS_TRTCM_CFG, EGRESS_FAST_TICK_MASK,
  970. FIELD_PREP(EGRESS_FAST_TICK_MASK, 25));
  971. airoha_qdma_rmw(qdma, REG_EGRESS_TRTCM_CFG,
  972. EGRESS_SLOW_TICK_RATIO_MASK,
  973. FIELD_PREP(EGRESS_SLOW_TICK_RATIO_MASK, 40));
  974. airoha_qdma_set(qdma, REG_INGRESS_TRTCM_CFG, INGRESS_TRTCM_EN_MASK);
  975. airoha_qdma_clear(qdma, REG_INGRESS_TRTCM_CFG,
  976. INGRESS_TRTCM_MODE_MASK);
  977. airoha_qdma_rmw(qdma, REG_INGRESS_TRTCM_CFG, INGRESS_FAST_TICK_MASK,
  978. FIELD_PREP(INGRESS_FAST_TICK_MASK, 125));
  979. airoha_qdma_rmw(qdma, REG_INGRESS_TRTCM_CFG,
  980. INGRESS_SLOW_TICK_RATIO_MASK,
  981. FIELD_PREP(INGRESS_SLOW_TICK_RATIO_MASK, 8));
  982. airoha_qdma_set(qdma, REG_SLA_TRTCM_CFG, SLA_TRTCM_EN_MASK);
  983. airoha_qdma_rmw(qdma, REG_SLA_TRTCM_CFG, SLA_FAST_TICK_MASK,
  984. FIELD_PREP(SLA_FAST_TICK_MASK, 25));
  985. airoha_qdma_rmw(qdma, REG_SLA_TRTCM_CFG, SLA_SLOW_TICK_RATIO_MASK,
  986. FIELD_PREP(SLA_SLOW_TICK_RATIO_MASK, 40));
  987. }
  988. static void airoha_qdma_init_qos_stats(struct airoha_qdma *qdma)
  989. {
  990. int i;
  991. for (i = 0; i < AIROHA_NUM_QOS_CHANNELS; i++) {
  992. /* Tx-cpu transferred count */
  993. airoha_qdma_wr(qdma, REG_CNTR_VAL(i << 1), 0);
  994. airoha_qdma_wr(qdma, REG_CNTR_CFG(i << 1),
  995. CNTR_EN_MASK | CNTR_ALL_QUEUE_EN_MASK |
  996. CNTR_ALL_DSCP_RING_EN_MASK |
  997. FIELD_PREP(CNTR_CHAN_MASK, i));
  998. /* Tx-fwd transferred count */
  999. airoha_qdma_wr(qdma, REG_CNTR_VAL((i << 1) + 1), 0);
  1000. airoha_qdma_wr(qdma, REG_CNTR_CFG(i << 1),
  1001. CNTR_EN_MASK | CNTR_ALL_QUEUE_EN_MASK |
  1002. CNTR_ALL_DSCP_RING_EN_MASK |
  1003. FIELD_PREP(CNTR_SRC_MASK, 1) |
  1004. FIELD_PREP(CNTR_CHAN_MASK, i));
  1005. }
  1006. }
  1007. static int airoha_qdma_hw_init(struct airoha_qdma *qdma)
  1008. {
  1009. int i;
  1010. for (i = 0; i < ARRAY_SIZE(qdma->irq_banks); i++) {
  1011. /* clear pending irqs */
  1012. airoha_qdma_wr(qdma, REG_INT_STATUS(i), 0xffffffff);
  1013. /* setup rx irqs */
  1014. airoha_qdma_irq_enable(&qdma->irq_banks[i], QDMA_INT_REG_IDX0,
  1015. INT_RX0_MASK(RX_IRQ_BANK_PIN_MASK(i)));
  1016. airoha_qdma_irq_enable(&qdma->irq_banks[i], QDMA_INT_REG_IDX1,
  1017. INT_RX1_MASK(RX_IRQ_BANK_PIN_MASK(i)));
  1018. airoha_qdma_irq_enable(&qdma->irq_banks[i], QDMA_INT_REG_IDX2,
  1019. INT_RX2_MASK(RX_IRQ_BANK_PIN_MASK(i)));
  1020. airoha_qdma_irq_enable(&qdma->irq_banks[i], QDMA_INT_REG_IDX3,
  1021. INT_RX3_MASK(RX_IRQ_BANK_PIN_MASK(i)));
  1022. }
  1023. /* setup tx irqs */
  1024. airoha_qdma_irq_enable(&qdma->irq_banks[0], QDMA_INT_REG_IDX0,
  1025. TX_COHERENT_LOW_INT_MASK | INT_TX_MASK);
  1026. airoha_qdma_irq_enable(&qdma->irq_banks[0], QDMA_INT_REG_IDX4,
  1027. TX_COHERENT_HIGH_INT_MASK);
  1028. /* setup irq binding */
  1029. for (i = 0; i < ARRAY_SIZE(qdma->q_tx); i++) {
  1030. if (!qdma->q_tx[i].ndesc)
  1031. continue;
  1032. if (TX_RING_IRQ_BLOCKING_MAP_MASK & BIT(i))
  1033. airoha_qdma_set(qdma, REG_TX_RING_BLOCKING(i),
  1034. TX_RING_IRQ_BLOCKING_CFG_MASK);
  1035. else
  1036. airoha_qdma_clear(qdma, REG_TX_RING_BLOCKING(i),
  1037. TX_RING_IRQ_BLOCKING_CFG_MASK);
  1038. }
  1039. airoha_qdma_wr(qdma, REG_QDMA_GLOBAL_CFG,
  1040. FIELD_PREP(GLOBAL_CFG_DMA_PREFERENCE_MASK, 3) |
  1041. GLOBAL_CFG_CPU_TXR_RR_MASK |
  1042. GLOBAL_CFG_PAYLOAD_BYTE_SWAP_MASK |
  1043. GLOBAL_CFG_MULTICAST_MODIFY_FP_MASK |
  1044. GLOBAL_CFG_MULTICAST_EN_MASK |
  1045. GLOBAL_CFG_IRQ0_EN_MASK | GLOBAL_CFG_IRQ1_EN_MASK |
  1046. GLOBAL_CFG_TX_WB_DONE_MASK |
  1047. FIELD_PREP(GLOBAL_CFG_MAX_ISSUE_NUM_MASK, 2));
  1048. airoha_qdma_init_qos(qdma);
  1049. /* disable qdma rx delay interrupt */
  1050. for (i = 0; i < ARRAY_SIZE(qdma->q_rx); i++) {
  1051. if (!qdma->q_rx[i].ndesc)
  1052. continue;
  1053. airoha_qdma_clear(qdma, REG_RX_DELAY_INT_IDX(i),
  1054. RX_DELAY_INT_MASK);
  1055. }
  1056. airoha_qdma_set(qdma, REG_TXQ_CNGST_CFG,
  1057. TXQ_CNGST_DROP_EN | TXQ_CNGST_DEI_DROP_EN);
  1058. airoha_qdma_init_qos_stats(qdma);
  1059. return 0;
  1060. }
  1061. static irqreturn_t airoha_irq_handler(int irq, void *dev_instance)
  1062. {
  1063. struct airoha_irq_bank *irq_bank = dev_instance;
  1064. struct airoha_qdma *qdma = irq_bank->qdma;
  1065. u32 rx_intr_mask = 0, rx_intr1, rx_intr2;
  1066. u32 intr[ARRAY_SIZE(irq_bank->irqmask)];
  1067. int i;
  1068. for (i = 0; i < ARRAY_SIZE(intr); i++) {
  1069. intr[i] = airoha_qdma_rr(qdma, REG_INT_STATUS(i));
  1070. intr[i] &= irq_bank->irqmask[i];
  1071. airoha_qdma_wr(qdma, REG_INT_STATUS(i), intr[i]);
  1072. }
  1073. if (!test_bit(DEV_STATE_INITIALIZED, &qdma->eth->state))
  1074. return IRQ_NONE;
  1075. rx_intr1 = intr[1] & RX_DONE_LOW_INT_MASK;
  1076. if (rx_intr1) {
  1077. airoha_qdma_irq_disable(irq_bank, QDMA_INT_REG_IDX1, rx_intr1);
  1078. rx_intr_mask |= rx_intr1;
  1079. }
  1080. rx_intr2 = intr[2] & RX_DONE_HIGH_INT_MASK;
  1081. if (rx_intr2) {
  1082. airoha_qdma_irq_disable(irq_bank, QDMA_INT_REG_IDX2, rx_intr2);
  1083. rx_intr_mask |= (rx_intr2 << 16);
  1084. }
  1085. for (i = 0; rx_intr_mask && i < ARRAY_SIZE(qdma->q_rx); i++) {
  1086. if (!qdma->q_rx[i].ndesc)
  1087. continue;
  1088. if (rx_intr_mask & BIT(i))
  1089. napi_schedule(&qdma->q_rx[i].napi);
  1090. }
  1091. if (intr[0] & INT_TX_MASK) {
  1092. for (i = 0; i < ARRAY_SIZE(qdma->q_tx_irq); i++) {
  1093. if (!(intr[0] & TX_DONE_INT_MASK(i)))
  1094. continue;
  1095. airoha_qdma_irq_disable(irq_bank, QDMA_INT_REG_IDX0,
  1096. TX_DONE_INT_MASK(i));
  1097. napi_schedule(&qdma->q_tx_irq[i].napi);
  1098. }
  1099. }
  1100. return IRQ_HANDLED;
  1101. }
  1102. static int airoha_qdma_init_irq_banks(struct platform_device *pdev,
  1103. struct airoha_qdma *qdma)
  1104. {
  1105. struct airoha_eth *eth = qdma->eth;
  1106. int i, id = qdma - &eth->qdma[0];
  1107. for (i = 0; i < ARRAY_SIZE(qdma->irq_banks); i++) {
  1108. struct airoha_irq_bank *irq_bank = &qdma->irq_banks[i];
  1109. int err, irq_index = 4 * id + i;
  1110. const char *name;
  1111. spin_lock_init(&irq_bank->irq_lock);
  1112. irq_bank->qdma = qdma;
  1113. irq_bank->irq = platform_get_irq(pdev, irq_index);
  1114. if (irq_bank->irq < 0)
  1115. return irq_bank->irq;
  1116. name = devm_kasprintf(eth->dev, GFP_KERNEL,
  1117. KBUILD_MODNAME ".%d", irq_index);
  1118. if (!name)
  1119. return -ENOMEM;
  1120. err = devm_request_irq(eth->dev, irq_bank->irq,
  1121. airoha_irq_handler, IRQF_SHARED, name,
  1122. irq_bank);
  1123. if (err)
  1124. return err;
  1125. }
  1126. return 0;
  1127. }
  1128. static int airoha_qdma_init(struct platform_device *pdev,
  1129. struct airoha_eth *eth,
  1130. struct airoha_qdma *qdma)
  1131. {
  1132. int err, id = qdma - &eth->qdma[0];
  1133. const char *res;
  1134. qdma->eth = eth;
  1135. res = devm_kasprintf(eth->dev, GFP_KERNEL, "qdma%d", id);
  1136. if (!res)
  1137. return -ENOMEM;
  1138. qdma->regs = devm_platform_ioremap_resource_byname(pdev, res);
  1139. if (IS_ERR(qdma->regs))
  1140. return dev_err_probe(eth->dev, PTR_ERR(qdma->regs),
  1141. "failed to iomap qdma%d regs\n", id);
  1142. err = airoha_qdma_init_irq_banks(pdev, qdma);
  1143. if (err)
  1144. return err;
  1145. err = airoha_qdma_init_rx(qdma);
  1146. if (err)
  1147. return err;
  1148. err = airoha_qdma_init_tx(qdma);
  1149. if (err)
  1150. return err;
  1151. err = airoha_qdma_init_hfwd_queues(qdma);
  1152. if (err)
  1153. return err;
  1154. return airoha_qdma_hw_init(qdma);
  1155. }
  1156. static int airoha_hw_init(struct platform_device *pdev,
  1157. struct airoha_eth *eth)
  1158. {
  1159. int err, i;
  1160. /* disable xsi */
  1161. err = reset_control_bulk_assert(eth->soc->num_xsi_rsts, eth->xsi_rsts);
  1162. if (err)
  1163. return err;
  1164. err = reset_control_bulk_assert(ARRAY_SIZE(eth->rsts), eth->rsts);
  1165. if (err)
  1166. return err;
  1167. msleep(20);
  1168. err = reset_control_bulk_deassert(ARRAY_SIZE(eth->rsts), eth->rsts);
  1169. if (err)
  1170. return err;
  1171. msleep(20);
  1172. err = airoha_fe_init(eth);
  1173. if (err)
  1174. return err;
  1175. for (i = 0; i < ARRAY_SIZE(eth->qdma); i++) {
  1176. err = airoha_qdma_init(pdev, eth, &eth->qdma[i]);
  1177. if (err)
  1178. return err;
  1179. }
  1180. err = airoha_ppe_init(eth);
  1181. if (err)
  1182. return err;
  1183. set_bit(DEV_STATE_INITIALIZED, &eth->state);
  1184. return 0;
  1185. }
  1186. static void airoha_hw_cleanup(struct airoha_qdma *qdma)
  1187. {
  1188. int i;
  1189. for (i = 0; i < ARRAY_SIZE(qdma->q_rx); i++) {
  1190. if (!qdma->q_rx[i].ndesc)
  1191. continue;
  1192. netif_napi_del(&qdma->q_rx[i].napi);
  1193. airoha_qdma_cleanup_rx_queue(&qdma->q_rx[i]);
  1194. if (qdma->q_rx[i].page_pool)
  1195. page_pool_destroy(qdma->q_rx[i].page_pool);
  1196. }
  1197. for (i = 0; i < ARRAY_SIZE(qdma->q_tx_irq); i++)
  1198. netif_napi_del(&qdma->q_tx_irq[i].napi);
  1199. for (i = 0; i < ARRAY_SIZE(qdma->q_tx); i++) {
  1200. if (!qdma->q_tx[i].ndesc)
  1201. continue;
  1202. airoha_qdma_cleanup_tx_queue(&qdma->q_tx[i]);
  1203. }
  1204. }
  1205. static void airoha_qdma_start_napi(struct airoha_qdma *qdma)
  1206. {
  1207. int i;
  1208. for (i = 0; i < ARRAY_SIZE(qdma->q_tx_irq); i++)
  1209. napi_enable(&qdma->q_tx_irq[i].napi);
  1210. for (i = 0; i < ARRAY_SIZE(qdma->q_rx); i++) {
  1211. if (!qdma->q_rx[i].ndesc)
  1212. continue;
  1213. napi_enable(&qdma->q_rx[i].napi);
  1214. }
  1215. }
  1216. static void airoha_qdma_stop_napi(struct airoha_qdma *qdma)
  1217. {
  1218. int i;
  1219. for (i = 0; i < ARRAY_SIZE(qdma->q_tx_irq); i++)
  1220. napi_disable(&qdma->q_tx_irq[i].napi);
  1221. for (i = 0; i < ARRAY_SIZE(qdma->q_rx); i++) {
  1222. if (!qdma->q_rx[i].ndesc)
  1223. continue;
  1224. napi_disable(&qdma->q_rx[i].napi);
  1225. }
  1226. }
  1227. static void airoha_update_hw_stats(struct airoha_gdm_port *port)
  1228. {
  1229. struct airoha_eth *eth = port->qdma->eth;
  1230. u32 val, i = 0;
  1231. spin_lock(&port->stats.lock);
  1232. u64_stats_update_begin(&port->stats.syncp);
  1233. /* TX */
  1234. val = airoha_fe_rr(eth, REG_FE_GDM_TX_OK_PKT_CNT_H(port->id));
  1235. port->stats.tx_ok_pkts += ((u64)val << 32);
  1236. val = airoha_fe_rr(eth, REG_FE_GDM_TX_OK_PKT_CNT_L(port->id));
  1237. port->stats.tx_ok_pkts += val;
  1238. val = airoha_fe_rr(eth, REG_FE_GDM_TX_OK_BYTE_CNT_H(port->id));
  1239. port->stats.tx_ok_bytes += ((u64)val << 32);
  1240. val = airoha_fe_rr(eth, REG_FE_GDM_TX_OK_BYTE_CNT_L(port->id));
  1241. port->stats.tx_ok_bytes += val;
  1242. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_DROP_CNT(port->id));
  1243. port->stats.tx_drops += val;
  1244. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_BC_CNT(port->id));
  1245. port->stats.tx_broadcast += val;
  1246. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_MC_CNT(port->id));
  1247. port->stats.tx_multicast += val;
  1248. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_RUNT_CNT(port->id));
  1249. port->stats.tx_len[i] += val;
  1250. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_E64_CNT_H(port->id));
  1251. port->stats.tx_len[i] += ((u64)val << 32);
  1252. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_E64_CNT_L(port->id));
  1253. port->stats.tx_len[i++] += val;
  1254. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_L64_CNT_H(port->id));
  1255. port->stats.tx_len[i] += ((u64)val << 32);
  1256. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_L64_CNT_L(port->id));
  1257. port->stats.tx_len[i++] += val;
  1258. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_L127_CNT_H(port->id));
  1259. port->stats.tx_len[i] += ((u64)val << 32);
  1260. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_L127_CNT_L(port->id));
  1261. port->stats.tx_len[i++] += val;
  1262. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_L255_CNT_H(port->id));
  1263. port->stats.tx_len[i] += ((u64)val << 32);
  1264. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_L255_CNT_L(port->id));
  1265. port->stats.tx_len[i++] += val;
  1266. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_L511_CNT_H(port->id));
  1267. port->stats.tx_len[i] += ((u64)val << 32);
  1268. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_L511_CNT_L(port->id));
  1269. port->stats.tx_len[i++] += val;
  1270. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_L1023_CNT_H(port->id));
  1271. port->stats.tx_len[i] += ((u64)val << 32);
  1272. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_L1023_CNT_L(port->id));
  1273. port->stats.tx_len[i++] += val;
  1274. val = airoha_fe_rr(eth, REG_FE_GDM_TX_ETH_LONG_CNT(port->id));
  1275. port->stats.tx_len[i++] += val;
  1276. /* RX */
  1277. val = airoha_fe_rr(eth, REG_FE_GDM_RX_OK_PKT_CNT_H(port->id));
  1278. port->stats.rx_ok_pkts += ((u64)val << 32);
  1279. val = airoha_fe_rr(eth, REG_FE_GDM_RX_OK_PKT_CNT_L(port->id));
  1280. port->stats.rx_ok_pkts += val;
  1281. val = airoha_fe_rr(eth, REG_FE_GDM_RX_OK_BYTE_CNT_H(port->id));
  1282. port->stats.rx_ok_bytes += ((u64)val << 32);
  1283. val = airoha_fe_rr(eth, REG_FE_GDM_RX_OK_BYTE_CNT_L(port->id));
  1284. port->stats.rx_ok_bytes += val;
  1285. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_DROP_CNT(port->id));
  1286. port->stats.rx_drops += val;
  1287. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_BC_CNT(port->id));
  1288. port->stats.rx_broadcast += val;
  1289. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_MC_CNT(port->id));
  1290. port->stats.rx_multicast += val;
  1291. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ERROR_DROP_CNT(port->id));
  1292. port->stats.rx_errors += val;
  1293. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_CRC_ERR_CNT(port->id));
  1294. port->stats.rx_crc_error += val;
  1295. val = airoha_fe_rr(eth, REG_FE_GDM_RX_OVERFLOW_DROP_CNT(port->id));
  1296. port->stats.rx_over_errors += val;
  1297. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_FRAG_CNT(port->id));
  1298. port->stats.rx_fragment += val;
  1299. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_JABBER_CNT(port->id));
  1300. port->stats.rx_jabber += val;
  1301. i = 0;
  1302. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_RUNT_CNT(port->id));
  1303. port->stats.rx_len[i] += val;
  1304. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_E64_CNT_H(port->id));
  1305. port->stats.rx_len[i] += ((u64)val << 32);
  1306. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_E64_CNT_L(port->id));
  1307. port->stats.rx_len[i++] += val;
  1308. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_L64_CNT_H(port->id));
  1309. port->stats.rx_len[i] += ((u64)val << 32);
  1310. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_L64_CNT_L(port->id));
  1311. port->stats.rx_len[i++] += val;
  1312. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_L127_CNT_H(port->id));
  1313. port->stats.rx_len[i] += ((u64)val << 32);
  1314. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_L127_CNT_L(port->id));
  1315. port->stats.rx_len[i++] += val;
  1316. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_L255_CNT_H(port->id));
  1317. port->stats.rx_len[i] += ((u64)val << 32);
  1318. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_L255_CNT_L(port->id));
  1319. port->stats.rx_len[i++] += val;
  1320. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_L511_CNT_H(port->id));
  1321. port->stats.rx_len[i] += ((u64)val << 32);
  1322. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_L511_CNT_L(port->id));
  1323. port->stats.rx_len[i++] += val;
  1324. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_L1023_CNT_H(port->id));
  1325. port->stats.rx_len[i] += ((u64)val << 32);
  1326. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_L1023_CNT_L(port->id));
  1327. port->stats.rx_len[i++] += val;
  1328. val = airoha_fe_rr(eth, REG_FE_GDM_RX_ETH_LONG_CNT(port->id));
  1329. port->stats.rx_len[i++] += val;
  1330. /* reset mib counters */
  1331. airoha_fe_set(eth, REG_FE_GDM_MIB_CLEAR(port->id),
  1332. FE_GDM_MIB_RX_CLEAR_MASK | FE_GDM_MIB_TX_CLEAR_MASK);
  1333. u64_stats_update_end(&port->stats.syncp);
  1334. spin_unlock(&port->stats.lock);
  1335. }
  1336. static int airoha_dev_open(struct net_device *dev)
  1337. {
  1338. int err, len = ETH_HLEN + dev->mtu + ETH_FCS_LEN;
  1339. struct airoha_gdm_port *port = netdev_priv(dev);
  1340. struct airoha_qdma *qdma = port->qdma;
  1341. netif_tx_start_all_queues(dev);
  1342. err = airoha_set_vip_for_gdm_port(port, true);
  1343. if (err)
  1344. return err;
  1345. if (netdev_uses_dsa(dev))
  1346. airoha_fe_set(qdma->eth, REG_GDM_INGRESS_CFG(port->id),
  1347. GDM_STAG_EN_MASK);
  1348. else
  1349. airoha_fe_clear(qdma->eth, REG_GDM_INGRESS_CFG(port->id),
  1350. GDM_STAG_EN_MASK);
  1351. airoha_fe_rmw(qdma->eth, REG_GDM_LEN_CFG(port->id),
  1352. GDM_SHORT_LEN_MASK | GDM_LONG_LEN_MASK,
  1353. FIELD_PREP(GDM_SHORT_LEN_MASK, 60) |
  1354. FIELD_PREP(GDM_LONG_LEN_MASK, len));
  1355. airoha_qdma_set(qdma, REG_QDMA_GLOBAL_CFG,
  1356. GLOBAL_CFG_TX_DMA_EN_MASK |
  1357. GLOBAL_CFG_RX_DMA_EN_MASK);
  1358. atomic_inc(&qdma->users);
  1359. return 0;
  1360. }
  1361. static int airoha_dev_stop(struct net_device *dev)
  1362. {
  1363. struct airoha_gdm_port *port = netdev_priv(dev);
  1364. struct airoha_qdma *qdma = port->qdma;
  1365. int i, err;
  1366. netif_tx_disable(dev);
  1367. err = airoha_set_vip_for_gdm_port(port, false);
  1368. if (err)
  1369. return err;
  1370. for (i = 0; i < ARRAY_SIZE(qdma->q_tx); i++)
  1371. netdev_tx_reset_subqueue(dev, i);
  1372. if (atomic_dec_and_test(&qdma->users)) {
  1373. airoha_qdma_clear(qdma, REG_QDMA_GLOBAL_CFG,
  1374. GLOBAL_CFG_TX_DMA_EN_MASK |
  1375. GLOBAL_CFG_RX_DMA_EN_MASK);
  1376. for (i = 0; i < ARRAY_SIZE(qdma->q_tx); i++) {
  1377. if (!qdma->q_tx[i].ndesc)
  1378. continue;
  1379. airoha_qdma_cleanup_tx_queue(&qdma->q_tx[i]);
  1380. }
  1381. }
  1382. return 0;
  1383. }
  1384. static int airoha_dev_set_macaddr(struct net_device *dev, void *p)
  1385. {
  1386. struct airoha_gdm_port *port = netdev_priv(dev);
  1387. int err;
  1388. err = eth_mac_addr(dev, p);
  1389. if (err)
  1390. return err;
  1391. airoha_set_macaddr(port, dev->dev_addr);
  1392. return 0;
  1393. }
  1394. static int airhoha_set_gdm2_loopback(struct airoha_gdm_port *port)
  1395. {
  1396. struct airoha_eth *eth = port->qdma->eth;
  1397. u32 val, pse_port, chan, nbq;
  1398. int src_port;
  1399. /* Forward the traffic to the proper GDM port */
  1400. pse_port = port->id == AIROHA_GDM3_IDX ? FE_PSE_PORT_GDM3
  1401. : FE_PSE_PORT_GDM4;
  1402. airoha_set_gdm_port_fwd_cfg(eth, REG_GDM_FWD_CFG(AIROHA_GDM2_IDX),
  1403. pse_port);
  1404. airoha_fe_clear(eth, REG_GDM_FWD_CFG(AIROHA_GDM2_IDX),
  1405. GDM_STRIP_CRC_MASK);
  1406. /* Enable GDM2 loopback */
  1407. airoha_fe_wr(eth, REG_GDM_TXCHN_EN(AIROHA_GDM2_IDX), 0xffffffff);
  1408. airoha_fe_wr(eth, REG_GDM_RXCHN_EN(AIROHA_GDM2_IDX), 0xffff);
  1409. chan = port->id == AIROHA_GDM3_IDX ? airoha_is_7581(eth) ? 4 : 3 : 0;
  1410. airoha_fe_rmw(eth, REG_GDM_LPBK_CFG(AIROHA_GDM2_IDX),
  1411. LPBK_CHAN_MASK | LPBK_MODE_MASK | LPBK_EN_MASK,
  1412. FIELD_PREP(LPBK_CHAN_MASK, chan) |
  1413. LBK_GAP_MODE_MASK | LBK_LEN_MODE_MASK |
  1414. LBK_CHAN_MODE_MASK | LPBK_EN_MASK);
  1415. airoha_fe_rmw(eth, REG_GDM_LEN_CFG(AIROHA_GDM2_IDX),
  1416. GDM_SHORT_LEN_MASK | GDM_LONG_LEN_MASK,
  1417. FIELD_PREP(GDM_SHORT_LEN_MASK, 60) |
  1418. FIELD_PREP(GDM_LONG_LEN_MASK, AIROHA_MAX_MTU));
  1419. /* Disable VIP and IFC for GDM2 */
  1420. airoha_fe_clear(eth, REG_FE_VIP_PORT_EN, BIT(AIROHA_GDM2_IDX));
  1421. airoha_fe_clear(eth, REG_FE_IFC_PORT_EN, BIT(AIROHA_GDM2_IDX));
  1422. /* XXX: handle XSI_USB_PORT and XSI_PCE1_PORT */
  1423. nbq = port->id == AIROHA_GDM3_IDX && airoha_is_7581(eth) ? 4 : 0;
  1424. src_port = eth->soc->ops.get_src_port_id(port, nbq);
  1425. if (src_port < 0)
  1426. return src_port;
  1427. airoha_fe_rmw(eth, REG_FE_WAN_PORT,
  1428. WAN1_EN_MASK | WAN1_MASK | WAN0_MASK,
  1429. FIELD_PREP(WAN0_MASK, src_port));
  1430. val = src_port & SP_CPORT_DFT_MASK;
  1431. airoha_fe_rmw(eth,
  1432. REG_SP_DFT_CPORT(src_port >> fls(SP_CPORT_DFT_MASK)),
  1433. SP_CPORT_MASK(val),
  1434. FE_PSE_PORT_CDM2 << __ffs(SP_CPORT_MASK(val)));
  1435. if (port->id != AIROHA_GDM3_IDX && airoha_is_7581(eth))
  1436. airoha_fe_rmw(eth, REG_SRC_PORT_FC_MAP6,
  1437. FC_ID_OF_SRC_PORT24_MASK,
  1438. FIELD_PREP(FC_ID_OF_SRC_PORT24_MASK, 2));
  1439. return 0;
  1440. }
  1441. static int airoha_dev_init(struct net_device *dev)
  1442. {
  1443. struct airoha_gdm_port *port = netdev_priv(dev);
  1444. struct airoha_qdma *qdma = port->qdma;
  1445. struct airoha_eth *eth = qdma->eth;
  1446. u32 pse_port, fe_cpu_port;
  1447. u8 ppe_id;
  1448. airoha_set_macaddr(port, dev->dev_addr);
  1449. switch (port->id) {
  1450. case AIROHA_GDM3_IDX:
  1451. case AIROHA_GDM4_IDX:
  1452. /* If GDM2 is active we can't enable loopback */
  1453. if (!eth->ports[1]) {
  1454. int err;
  1455. err = airhoha_set_gdm2_loopback(port);
  1456. if (err)
  1457. return err;
  1458. }
  1459. fallthrough;
  1460. case AIROHA_GDM2_IDX:
  1461. if (airoha_ppe_is_enabled(eth, 1)) {
  1462. /* For PPE2 always use secondary cpu port. */
  1463. fe_cpu_port = FE_PSE_PORT_CDM2;
  1464. pse_port = FE_PSE_PORT_PPE2;
  1465. break;
  1466. }
  1467. fallthrough;
  1468. default: {
  1469. u8 qdma_id = qdma - &eth->qdma[0];
  1470. /* For PPE1 select cpu port according to the running QDMA. */
  1471. fe_cpu_port = qdma_id ? FE_PSE_PORT_CDM2 : FE_PSE_PORT_CDM1;
  1472. pse_port = FE_PSE_PORT_PPE1;
  1473. break;
  1474. }
  1475. }
  1476. airoha_set_gdm_port_fwd_cfg(eth, REG_GDM_FWD_CFG(port->id), pse_port);
  1477. ppe_id = pse_port == FE_PSE_PORT_PPE2 ? 1 : 0;
  1478. airoha_fe_rmw(eth, REG_PPE_DFT_CPORT0(ppe_id),
  1479. DFT_CPORT_MASK(port->id),
  1480. fe_cpu_port << __ffs(DFT_CPORT_MASK(port->id)));
  1481. return 0;
  1482. }
  1483. static void airoha_dev_get_stats64(struct net_device *dev,
  1484. struct rtnl_link_stats64 *storage)
  1485. {
  1486. struct airoha_gdm_port *port = netdev_priv(dev);
  1487. unsigned int start;
  1488. airoha_update_hw_stats(port);
  1489. do {
  1490. start = u64_stats_fetch_begin(&port->stats.syncp);
  1491. storage->rx_packets = port->stats.rx_ok_pkts;
  1492. storage->tx_packets = port->stats.tx_ok_pkts;
  1493. storage->rx_bytes = port->stats.rx_ok_bytes;
  1494. storage->tx_bytes = port->stats.tx_ok_bytes;
  1495. storage->multicast = port->stats.rx_multicast;
  1496. storage->rx_errors = port->stats.rx_errors;
  1497. storage->rx_dropped = port->stats.rx_drops;
  1498. storage->tx_dropped = port->stats.tx_drops;
  1499. storage->rx_crc_errors = port->stats.rx_crc_error;
  1500. storage->rx_over_errors = port->stats.rx_over_errors;
  1501. } while (u64_stats_fetch_retry(&port->stats.syncp, start));
  1502. }
  1503. static int airoha_dev_change_mtu(struct net_device *dev, int mtu)
  1504. {
  1505. struct airoha_gdm_port *port = netdev_priv(dev);
  1506. struct airoha_eth *eth = port->qdma->eth;
  1507. u32 len = ETH_HLEN + mtu + ETH_FCS_LEN;
  1508. airoha_fe_rmw(eth, REG_GDM_LEN_CFG(port->id),
  1509. GDM_LONG_LEN_MASK,
  1510. FIELD_PREP(GDM_LONG_LEN_MASK, len));
  1511. WRITE_ONCE(dev->mtu, mtu);
  1512. return 0;
  1513. }
  1514. static u16 airoha_dev_select_queue(struct net_device *dev, struct sk_buff *skb,
  1515. struct net_device *sb_dev)
  1516. {
  1517. struct airoha_gdm_port *port = netdev_priv(dev);
  1518. int queue, channel;
  1519. /* For dsa device select QoS channel according to the dsa user port
  1520. * index, rely on port id otherwise. Select QoS queue based on the
  1521. * skb priority.
  1522. */
  1523. channel = netdev_uses_dsa(dev) ? skb_get_queue_mapping(skb) : port->id;
  1524. channel = channel % AIROHA_NUM_QOS_CHANNELS;
  1525. queue = (skb->priority - 1) % AIROHA_NUM_QOS_QUEUES; /* QoS queue */
  1526. queue = channel * AIROHA_NUM_QOS_QUEUES + queue;
  1527. return queue < dev->num_tx_queues ? queue : 0;
  1528. }
  1529. static u32 airoha_get_dsa_tag(struct sk_buff *skb, struct net_device *dev)
  1530. {
  1531. #if IS_ENABLED(CONFIG_NET_DSA)
  1532. struct ethhdr *ehdr;
  1533. u8 xmit_tpid;
  1534. u16 tag;
  1535. if (!netdev_uses_dsa(dev))
  1536. return 0;
  1537. if (dev->dsa_ptr->tag_ops->proto != DSA_TAG_PROTO_MTK)
  1538. return 0;
  1539. if (skb_cow_head(skb, 0))
  1540. return 0;
  1541. ehdr = (struct ethhdr *)skb->data;
  1542. tag = be16_to_cpu(ehdr->h_proto);
  1543. xmit_tpid = tag >> 8;
  1544. switch (xmit_tpid) {
  1545. case MTK_HDR_XMIT_TAGGED_TPID_8100:
  1546. ehdr->h_proto = cpu_to_be16(ETH_P_8021Q);
  1547. tag &= ~(MTK_HDR_XMIT_TAGGED_TPID_8100 << 8);
  1548. break;
  1549. case MTK_HDR_XMIT_TAGGED_TPID_88A8:
  1550. ehdr->h_proto = cpu_to_be16(ETH_P_8021AD);
  1551. tag &= ~(MTK_HDR_XMIT_TAGGED_TPID_88A8 << 8);
  1552. break;
  1553. default:
  1554. /* PPE module requires untagged DSA packets to work properly,
  1555. * so move DSA tag to DMA descriptor.
  1556. */
  1557. memmove(skb->data + MTK_HDR_LEN, skb->data, 2 * ETH_ALEN);
  1558. __skb_pull(skb, MTK_HDR_LEN);
  1559. break;
  1560. }
  1561. return tag;
  1562. #else
  1563. return 0;
  1564. #endif
  1565. }
  1566. static int airoha_get_fe_port(struct airoha_gdm_port *port)
  1567. {
  1568. struct airoha_qdma *qdma = port->qdma;
  1569. struct airoha_eth *eth = qdma->eth;
  1570. switch (eth->soc->version) {
  1571. case 0x7583:
  1572. return port->id == AIROHA_GDM3_IDX ? FE_PSE_PORT_GDM3
  1573. : port->id;
  1574. case 0x7581:
  1575. default:
  1576. return port->id == AIROHA_GDM4_IDX ? FE_PSE_PORT_GDM4
  1577. : port->id;
  1578. }
  1579. }
  1580. static netdev_tx_t airoha_dev_xmit(struct sk_buff *skb,
  1581. struct net_device *dev)
  1582. {
  1583. struct airoha_gdm_port *port = netdev_priv(dev);
  1584. struct airoha_qdma *qdma = port->qdma;
  1585. u32 nr_frags, tag, msg0, msg1, len;
  1586. struct airoha_queue_entry *e;
  1587. struct netdev_queue *txq;
  1588. struct airoha_queue *q;
  1589. LIST_HEAD(tx_list);
  1590. void *data;
  1591. int i, qid;
  1592. u16 index;
  1593. u8 fport;
  1594. qid = skb_get_queue_mapping(skb) % ARRAY_SIZE(qdma->q_tx);
  1595. tag = airoha_get_dsa_tag(skb, dev);
  1596. msg0 = FIELD_PREP(QDMA_ETH_TXMSG_CHAN_MASK,
  1597. qid / AIROHA_NUM_QOS_QUEUES) |
  1598. FIELD_PREP(QDMA_ETH_TXMSG_QUEUE_MASK,
  1599. qid % AIROHA_NUM_QOS_QUEUES) |
  1600. FIELD_PREP(QDMA_ETH_TXMSG_SP_TAG_MASK, tag);
  1601. if (skb->ip_summed == CHECKSUM_PARTIAL)
  1602. msg0 |= FIELD_PREP(QDMA_ETH_TXMSG_TCO_MASK, 1) |
  1603. FIELD_PREP(QDMA_ETH_TXMSG_UCO_MASK, 1) |
  1604. FIELD_PREP(QDMA_ETH_TXMSG_ICO_MASK, 1);
  1605. /* TSO: fill MSS info in tcp checksum field */
  1606. if (skb_is_gso(skb)) {
  1607. if (skb_cow_head(skb, 0))
  1608. goto error;
  1609. if (skb_shinfo(skb)->gso_type & (SKB_GSO_TCPV4 |
  1610. SKB_GSO_TCPV6)) {
  1611. __be16 csum = cpu_to_be16(skb_shinfo(skb)->gso_size);
  1612. tcp_hdr(skb)->check = (__force __sum16)csum;
  1613. msg0 |= FIELD_PREP(QDMA_ETH_TXMSG_TSO_MASK, 1);
  1614. }
  1615. }
  1616. fport = airoha_get_fe_port(port);
  1617. msg1 = FIELD_PREP(QDMA_ETH_TXMSG_FPORT_MASK, fport) |
  1618. FIELD_PREP(QDMA_ETH_TXMSG_METER_MASK, 0x7f);
  1619. q = &qdma->q_tx[qid];
  1620. if (WARN_ON_ONCE(!q->ndesc))
  1621. goto error;
  1622. spin_lock_bh(&q->lock);
  1623. txq = netdev_get_tx_queue(dev, qid);
  1624. nr_frags = 1 + skb_shinfo(skb)->nr_frags;
  1625. if (q->queued + nr_frags >= q->ndesc) {
  1626. /* not enough space in the queue */
  1627. netif_tx_stop_queue(txq);
  1628. spin_unlock_bh(&q->lock);
  1629. return NETDEV_TX_BUSY;
  1630. }
  1631. len = skb_headlen(skb);
  1632. data = skb->data;
  1633. e = list_first_entry(&q->tx_list, struct airoha_queue_entry,
  1634. list);
  1635. index = e - q->entry;
  1636. for (i = 0; i < nr_frags; i++) {
  1637. struct airoha_qdma_desc *desc = &q->desc[index];
  1638. skb_frag_t *frag = &skb_shinfo(skb)->frags[i];
  1639. dma_addr_t addr;
  1640. u32 val;
  1641. addr = dma_map_single(dev->dev.parent, data, len,
  1642. DMA_TO_DEVICE);
  1643. if (unlikely(dma_mapping_error(dev->dev.parent, addr)))
  1644. goto error_unmap;
  1645. list_move_tail(&e->list, &tx_list);
  1646. e->skb = i ? NULL : skb;
  1647. e->dma_addr = addr;
  1648. e->dma_len = len;
  1649. e = list_first_entry(&q->tx_list, struct airoha_queue_entry,
  1650. list);
  1651. index = e - q->entry;
  1652. val = FIELD_PREP(QDMA_DESC_LEN_MASK, len);
  1653. if (i < nr_frags - 1)
  1654. val |= FIELD_PREP(QDMA_DESC_MORE_MASK, 1);
  1655. WRITE_ONCE(desc->ctrl, cpu_to_le32(val));
  1656. WRITE_ONCE(desc->addr, cpu_to_le32(addr));
  1657. val = FIELD_PREP(QDMA_DESC_NEXT_ID_MASK, index);
  1658. WRITE_ONCE(desc->data, cpu_to_le32(val));
  1659. WRITE_ONCE(desc->msg0, cpu_to_le32(msg0));
  1660. WRITE_ONCE(desc->msg1, cpu_to_le32(msg1));
  1661. WRITE_ONCE(desc->msg2, cpu_to_le32(0xffff));
  1662. data = skb_frag_address(frag);
  1663. len = skb_frag_size(frag);
  1664. }
  1665. q->queued += i;
  1666. skb_tx_timestamp(skb);
  1667. netdev_tx_sent_queue(txq, skb->len);
  1668. if (netif_xmit_stopped(txq) || !netdev_xmit_more())
  1669. airoha_qdma_rmw(qdma, REG_TX_CPU_IDX(qid),
  1670. TX_RING_CPU_IDX_MASK,
  1671. FIELD_PREP(TX_RING_CPU_IDX_MASK, index));
  1672. if (q->ndesc - q->queued < q->free_thr)
  1673. netif_tx_stop_queue(txq);
  1674. spin_unlock_bh(&q->lock);
  1675. return NETDEV_TX_OK;
  1676. error_unmap:
  1677. while (!list_empty(&tx_list)) {
  1678. e = list_first_entry(&tx_list, struct airoha_queue_entry,
  1679. list);
  1680. dma_unmap_single(dev->dev.parent, e->dma_addr, e->dma_len,
  1681. DMA_TO_DEVICE);
  1682. e->dma_addr = 0;
  1683. list_move_tail(&e->list, &q->tx_list);
  1684. }
  1685. spin_unlock_bh(&q->lock);
  1686. error:
  1687. dev_kfree_skb_any(skb);
  1688. dev->stats.tx_dropped++;
  1689. return NETDEV_TX_OK;
  1690. }
  1691. static void airoha_ethtool_get_drvinfo(struct net_device *dev,
  1692. struct ethtool_drvinfo *info)
  1693. {
  1694. struct airoha_gdm_port *port = netdev_priv(dev);
  1695. struct airoha_eth *eth = port->qdma->eth;
  1696. strscpy(info->driver, eth->dev->driver->name, sizeof(info->driver));
  1697. strscpy(info->bus_info, dev_name(eth->dev), sizeof(info->bus_info));
  1698. }
  1699. static void airoha_ethtool_get_mac_stats(struct net_device *dev,
  1700. struct ethtool_eth_mac_stats *stats)
  1701. {
  1702. struct airoha_gdm_port *port = netdev_priv(dev);
  1703. unsigned int start;
  1704. airoha_update_hw_stats(port);
  1705. do {
  1706. start = u64_stats_fetch_begin(&port->stats.syncp);
  1707. stats->FramesTransmittedOK = port->stats.tx_ok_pkts;
  1708. stats->OctetsTransmittedOK = port->stats.tx_ok_bytes;
  1709. stats->MulticastFramesXmittedOK = port->stats.tx_multicast;
  1710. stats->BroadcastFramesXmittedOK = port->stats.tx_broadcast;
  1711. stats->FramesReceivedOK = port->stats.rx_ok_pkts;
  1712. stats->OctetsReceivedOK = port->stats.rx_ok_bytes;
  1713. stats->BroadcastFramesReceivedOK = port->stats.rx_broadcast;
  1714. } while (u64_stats_fetch_retry(&port->stats.syncp, start));
  1715. }
  1716. static const struct ethtool_rmon_hist_range airoha_ethtool_rmon_ranges[] = {
  1717. { 0, 64 },
  1718. { 65, 127 },
  1719. { 128, 255 },
  1720. { 256, 511 },
  1721. { 512, 1023 },
  1722. { 1024, 1518 },
  1723. { 1519, 10239 },
  1724. {},
  1725. };
  1726. static void
  1727. airoha_ethtool_get_rmon_stats(struct net_device *dev,
  1728. struct ethtool_rmon_stats *stats,
  1729. const struct ethtool_rmon_hist_range **ranges)
  1730. {
  1731. struct airoha_gdm_port *port = netdev_priv(dev);
  1732. struct airoha_hw_stats *hw_stats = &port->stats;
  1733. unsigned int start;
  1734. BUILD_BUG_ON(ARRAY_SIZE(airoha_ethtool_rmon_ranges) !=
  1735. ARRAY_SIZE(hw_stats->tx_len) + 1);
  1736. BUILD_BUG_ON(ARRAY_SIZE(airoha_ethtool_rmon_ranges) !=
  1737. ARRAY_SIZE(hw_stats->rx_len) + 1);
  1738. *ranges = airoha_ethtool_rmon_ranges;
  1739. airoha_update_hw_stats(port);
  1740. do {
  1741. int i;
  1742. start = u64_stats_fetch_begin(&port->stats.syncp);
  1743. stats->fragments = hw_stats->rx_fragment;
  1744. stats->jabbers = hw_stats->rx_jabber;
  1745. for (i = 0; i < ARRAY_SIZE(airoha_ethtool_rmon_ranges) - 1;
  1746. i++) {
  1747. stats->hist[i] = hw_stats->rx_len[i];
  1748. stats->hist_tx[i] = hw_stats->tx_len[i];
  1749. }
  1750. } while (u64_stats_fetch_retry(&port->stats.syncp, start));
  1751. }
  1752. static int airoha_qdma_set_chan_tx_sched(struct airoha_gdm_port *port,
  1753. int channel, enum tx_sched_mode mode,
  1754. const u16 *weights, u8 n_weights)
  1755. {
  1756. int i;
  1757. for (i = 0; i < AIROHA_NUM_TX_RING; i++)
  1758. airoha_qdma_clear(port->qdma, REG_QUEUE_CLOSE_CFG(channel),
  1759. TXQ_DISABLE_CHAN_QUEUE_MASK(channel, i));
  1760. for (i = 0; i < n_weights; i++) {
  1761. u32 status;
  1762. int err;
  1763. airoha_qdma_wr(port->qdma, REG_TXWRR_WEIGHT_CFG,
  1764. TWRR_RW_CMD_MASK |
  1765. FIELD_PREP(TWRR_CHAN_IDX_MASK, channel) |
  1766. FIELD_PREP(TWRR_QUEUE_IDX_MASK, i) |
  1767. FIELD_PREP(TWRR_VALUE_MASK, weights[i]));
  1768. err = read_poll_timeout(airoha_qdma_rr, status,
  1769. status & TWRR_RW_CMD_DONE,
  1770. USEC_PER_MSEC, 10 * USEC_PER_MSEC,
  1771. true, port->qdma,
  1772. REG_TXWRR_WEIGHT_CFG);
  1773. if (err)
  1774. return err;
  1775. }
  1776. airoha_qdma_rmw(port->qdma, REG_CHAN_QOS_MODE(channel >> 3),
  1777. CHAN_QOS_MODE_MASK(channel),
  1778. mode << __ffs(CHAN_QOS_MODE_MASK(channel)));
  1779. return 0;
  1780. }
  1781. static int airoha_qdma_set_tx_prio_sched(struct airoha_gdm_port *port,
  1782. int channel)
  1783. {
  1784. static const u16 w[AIROHA_NUM_QOS_QUEUES] = {};
  1785. return airoha_qdma_set_chan_tx_sched(port, channel, TC_SCH_SP, w,
  1786. ARRAY_SIZE(w));
  1787. }
  1788. static int airoha_qdma_set_tx_ets_sched(struct airoha_gdm_port *port,
  1789. int channel,
  1790. struct tc_ets_qopt_offload *opt)
  1791. {
  1792. struct tc_ets_qopt_offload_replace_params *p = &opt->replace_params;
  1793. enum tx_sched_mode mode = TC_SCH_SP;
  1794. u16 w[AIROHA_NUM_QOS_QUEUES] = {};
  1795. int i, nstrict = 0;
  1796. if (p->bands > AIROHA_NUM_QOS_QUEUES)
  1797. return -EINVAL;
  1798. for (i = 0; i < p->bands; i++) {
  1799. if (!p->quanta[i])
  1800. nstrict++;
  1801. }
  1802. /* this configuration is not supported by the hw */
  1803. if (nstrict == AIROHA_NUM_QOS_QUEUES - 1)
  1804. return -EINVAL;
  1805. /* EN7581 SoC supports fixed QoS band priority where WRR queues have
  1806. * lowest priorities with respect to SP ones.
  1807. * e.g: WRR0, WRR1, .., WRRm, SP0, SP1, .., SPn
  1808. */
  1809. for (i = 0; i < nstrict; i++) {
  1810. if (p->priomap[p->bands - i - 1] != i)
  1811. return -EINVAL;
  1812. }
  1813. for (i = 0; i < p->bands - nstrict; i++) {
  1814. if (p->priomap[i] != nstrict + i)
  1815. return -EINVAL;
  1816. w[i] = p->weights[nstrict + i];
  1817. }
  1818. if (!nstrict)
  1819. mode = TC_SCH_WRR8;
  1820. else if (nstrict < AIROHA_NUM_QOS_QUEUES - 1)
  1821. mode = nstrict + 1;
  1822. return airoha_qdma_set_chan_tx_sched(port, channel, mode, w,
  1823. ARRAY_SIZE(w));
  1824. }
  1825. static int airoha_qdma_get_tx_ets_stats(struct airoha_gdm_port *port,
  1826. int channel,
  1827. struct tc_ets_qopt_offload *opt)
  1828. {
  1829. u64 cpu_tx_packets = airoha_qdma_rr(port->qdma,
  1830. REG_CNTR_VAL(channel << 1));
  1831. u64 fwd_tx_packets = airoha_qdma_rr(port->qdma,
  1832. REG_CNTR_VAL((channel << 1) + 1));
  1833. u64 tx_packets = (cpu_tx_packets - port->cpu_tx_packets) +
  1834. (fwd_tx_packets - port->fwd_tx_packets);
  1835. _bstats_update(opt->stats.bstats, 0, tx_packets);
  1836. port->cpu_tx_packets = cpu_tx_packets;
  1837. port->fwd_tx_packets = fwd_tx_packets;
  1838. return 0;
  1839. }
  1840. static int airoha_tc_setup_qdisc_ets(struct airoha_gdm_port *port,
  1841. struct tc_ets_qopt_offload *opt)
  1842. {
  1843. int channel;
  1844. if (opt->parent == TC_H_ROOT)
  1845. return -EINVAL;
  1846. channel = TC_H_MAJ(opt->handle) >> 16;
  1847. channel = channel % AIROHA_NUM_QOS_CHANNELS;
  1848. switch (opt->command) {
  1849. case TC_ETS_REPLACE:
  1850. return airoha_qdma_set_tx_ets_sched(port, channel, opt);
  1851. case TC_ETS_DESTROY:
  1852. /* PRIO is default qdisc scheduler */
  1853. return airoha_qdma_set_tx_prio_sched(port, channel);
  1854. case TC_ETS_STATS:
  1855. return airoha_qdma_get_tx_ets_stats(port, channel, opt);
  1856. default:
  1857. return -EOPNOTSUPP;
  1858. }
  1859. }
  1860. static int airoha_qdma_get_rl_param(struct airoha_qdma *qdma, int queue_id,
  1861. u32 addr, enum trtcm_param_type param,
  1862. u32 *val_low, u32 *val_high)
  1863. {
  1864. u32 idx = QDMA_METER_IDX(queue_id), group = QDMA_METER_GROUP(queue_id);
  1865. u32 val, config = FIELD_PREP(RATE_LIMIT_PARAM_TYPE_MASK, param) |
  1866. FIELD_PREP(RATE_LIMIT_METER_GROUP_MASK, group) |
  1867. FIELD_PREP(RATE_LIMIT_PARAM_INDEX_MASK, idx);
  1868. airoha_qdma_wr(qdma, REG_TRTCM_CFG_PARAM(addr), config);
  1869. if (read_poll_timeout(airoha_qdma_rr, val,
  1870. val & RATE_LIMIT_PARAM_RW_DONE_MASK,
  1871. USEC_PER_MSEC, 10 * USEC_PER_MSEC, true, qdma,
  1872. REG_TRTCM_CFG_PARAM(addr)))
  1873. return -ETIMEDOUT;
  1874. *val_low = airoha_qdma_rr(qdma, REG_TRTCM_DATA_LOW(addr));
  1875. if (val_high)
  1876. *val_high = airoha_qdma_rr(qdma, REG_TRTCM_DATA_HIGH(addr));
  1877. return 0;
  1878. }
  1879. static int airoha_qdma_set_rl_param(struct airoha_qdma *qdma, int queue_id,
  1880. u32 addr, enum trtcm_param_type param,
  1881. u32 val)
  1882. {
  1883. u32 idx = QDMA_METER_IDX(queue_id), group = QDMA_METER_GROUP(queue_id);
  1884. u32 config = RATE_LIMIT_PARAM_RW_MASK |
  1885. FIELD_PREP(RATE_LIMIT_PARAM_TYPE_MASK, param) |
  1886. FIELD_PREP(RATE_LIMIT_METER_GROUP_MASK, group) |
  1887. FIELD_PREP(RATE_LIMIT_PARAM_INDEX_MASK, idx);
  1888. airoha_qdma_wr(qdma, REG_TRTCM_DATA_LOW(addr), val);
  1889. airoha_qdma_wr(qdma, REG_TRTCM_CFG_PARAM(addr), config);
  1890. return read_poll_timeout(airoha_qdma_rr, val,
  1891. val & RATE_LIMIT_PARAM_RW_DONE_MASK,
  1892. USEC_PER_MSEC, 10 * USEC_PER_MSEC, true,
  1893. qdma, REG_TRTCM_CFG_PARAM(addr));
  1894. }
  1895. static int airoha_qdma_set_rl_config(struct airoha_qdma *qdma, int queue_id,
  1896. u32 addr, bool enable, u32 enable_mask)
  1897. {
  1898. u32 val;
  1899. int err;
  1900. err = airoha_qdma_get_rl_param(qdma, queue_id, addr, TRTCM_MISC_MODE,
  1901. &val, NULL);
  1902. if (err)
  1903. return err;
  1904. val = enable ? val | enable_mask : val & ~enable_mask;
  1905. return airoha_qdma_set_rl_param(qdma, queue_id, addr, TRTCM_MISC_MODE,
  1906. val);
  1907. }
  1908. static int airoha_qdma_set_rl_token_bucket(struct airoha_qdma *qdma,
  1909. int queue_id, u32 rate_val,
  1910. u32 bucket_size)
  1911. {
  1912. u32 val, config, tick, unit, rate, rate_frac;
  1913. int err;
  1914. err = airoha_qdma_get_rl_param(qdma, queue_id, REG_INGRESS_TRTCM_CFG,
  1915. TRTCM_MISC_MODE, &config, NULL);
  1916. if (err)
  1917. return err;
  1918. val = airoha_qdma_rr(qdma, REG_INGRESS_TRTCM_CFG);
  1919. tick = FIELD_GET(INGRESS_FAST_TICK_MASK, val);
  1920. if (config & TRTCM_TICK_SEL)
  1921. tick *= FIELD_GET(INGRESS_SLOW_TICK_RATIO_MASK, val);
  1922. if (!tick)
  1923. return -EINVAL;
  1924. unit = (config & TRTCM_PKT_MODE) ? 1000000 / tick : 8000 / tick;
  1925. if (!unit)
  1926. return -EINVAL;
  1927. rate = rate_val / unit;
  1928. rate_frac = rate_val % unit;
  1929. rate_frac = FIELD_PREP(TRTCM_TOKEN_RATE_MASK, rate_frac) / unit;
  1930. rate = FIELD_PREP(TRTCM_TOKEN_RATE_MASK, rate) |
  1931. FIELD_PREP(TRTCM_TOKEN_RATE_FRACTION_MASK, rate_frac);
  1932. err = airoha_qdma_set_rl_param(qdma, queue_id, REG_INGRESS_TRTCM_CFG,
  1933. TRTCM_TOKEN_RATE_MODE, rate);
  1934. if (err)
  1935. return err;
  1936. val = bucket_size;
  1937. if (!(config & TRTCM_PKT_MODE))
  1938. val = max_t(u32, val, MIN_TOKEN_SIZE);
  1939. val = min_t(u32, __fls(val), MAX_TOKEN_SIZE_OFFSET);
  1940. return airoha_qdma_set_rl_param(qdma, queue_id, REG_INGRESS_TRTCM_CFG,
  1941. TRTCM_BUCKETSIZE_SHIFT_MODE, val);
  1942. }
  1943. static int airoha_qdma_init_rl_config(struct airoha_qdma *qdma, int queue_id,
  1944. bool enable, enum trtcm_unit_type unit)
  1945. {
  1946. bool tick_sel = queue_id == 0 || queue_id == 2 || queue_id == 8;
  1947. enum trtcm_param mode = TRTCM_METER_MODE;
  1948. int err;
  1949. mode |= unit == TRTCM_PACKET_UNIT ? TRTCM_PKT_MODE : 0;
  1950. err = airoha_qdma_set_rl_config(qdma, queue_id, REG_INGRESS_TRTCM_CFG,
  1951. enable, mode);
  1952. if (err)
  1953. return err;
  1954. return airoha_qdma_set_rl_config(qdma, queue_id, REG_INGRESS_TRTCM_CFG,
  1955. tick_sel, TRTCM_TICK_SEL);
  1956. }
  1957. static int airoha_qdma_get_trtcm_param(struct airoha_qdma *qdma, int channel,
  1958. u32 addr, enum trtcm_param_type param,
  1959. enum trtcm_mode_type mode,
  1960. u32 *val_low, u32 *val_high)
  1961. {
  1962. u32 idx = QDMA_METER_IDX(channel), group = QDMA_METER_GROUP(channel);
  1963. u32 val, config = FIELD_PREP(TRTCM_PARAM_TYPE_MASK, param) |
  1964. FIELD_PREP(TRTCM_METER_GROUP_MASK, group) |
  1965. FIELD_PREP(TRTCM_PARAM_INDEX_MASK, idx) |
  1966. FIELD_PREP(TRTCM_PARAM_RATE_TYPE_MASK, mode);
  1967. airoha_qdma_wr(qdma, REG_TRTCM_CFG_PARAM(addr), config);
  1968. if (read_poll_timeout(airoha_qdma_rr, val,
  1969. val & TRTCM_PARAM_RW_DONE_MASK,
  1970. USEC_PER_MSEC, 10 * USEC_PER_MSEC, true,
  1971. qdma, REG_TRTCM_CFG_PARAM(addr)))
  1972. return -ETIMEDOUT;
  1973. *val_low = airoha_qdma_rr(qdma, REG_TRTCM_DATA_LOW(addr));
  1974. if (val_high)
  1975. *val_high = airoha_qdma_rr(qdma, REG_TRTCM_DATA_HIGH(addr));
  1976. return 0;
  1977. }
  1978. static int airoha_qdma_set_trtcm_param(struct airoha_qdma *qdma, int channel,
  1979. u32 addr, enum trtcm_param_type param,
  1980. enum trtcm_mode_type mode, u32 val)
  1981. {
  1982. u32 idx = QDMA_METER_IDX(channel), group = QDMA_METER_GROUP(channel);
  1983. u32 config = TRTCM_PARAM_RW_MASK |
  1984. FIELD_PREP(TRTCM_PARAM_TYPE_MASK, param) |
  1985. FIELD_PREP(TRTCM_METER_GROUP_MASK, group) |
  1986. FIELD_PREP(TRTCM_PARAM_INDEX_MASK, idx) |
  1987. FIELD_PREP(TRTCM_PARAM_RATE_TYPE_MASK, mode);
  1988. airoha_qdma_wr(qdma, REG_TRTCM_DATA_LOW(addr), val);
  1989. airoha_qdma_wr(qdma, REG_TRTCM_CFG_PARAM(addr), config);
  1990. return read_poll_timeout(airoha_qdma_rr, val,
  1991. val & TRTCM_PARAM_RW_DONE_MASK,
  1992. USEC_PER_MSEC, 10 * USEC_PER_MSEC, true,
  1993. qdma, REG_TRTCM_CFG_PARAM(addr));
  1994. }
  1995. static int airoha_qdma_set_trtcm_config(struct airoha_qdma *qdma, int channel,
  1996. u32 addr, enum trtcm_mode_type mode,
  1997. bool enable, u32 enable_mask)
  1998. {
  1999. u32 val;
  2000. if (airoha_qdma_get_trtcm_param(qdma, channel, addr, TRTCM_MISC_MODE,
  2001. mode, &val, NULL))
  2002. return -EINVAL;
  2003. val = enable ? val | enable_mask : val & ~enable_mask;
  2004. return airoha_qdma_set_trtcm_param(qdma, channel, addr, TRTCM_MISC_MODE,
  2005. mode, val);
  2006. }
  2007. static int airoha_qdma_set_trtcm_token_bucket(struct airoha_qdma *qdma,
  2008. int channel, u32 addr,
  2009. enum trtcm_mode_type mode,
  2010. u32 rate_val, u32 bucket_size)
  2011. {
  2012. u32 val, config, tick, unit, rate, rate_frac;
  2013. int err;
  2014. if (airoha_qdma_get_trtcm_param(qdma, channel, addr, TRTCM_MISC_MODE,
  2015. mode, &config, NULL))
  2016. return -EINVAL;
  2017. val = airoha_qdma_rr(qdma, addr);
  2018. tick = FIELD_GET(INGRESS_FAST_TICK_MASK, val);
  2019. if (config & TRTCM_TICK_SEL)
  2020. tick *= FIELD_GET(INGRESS_SLOW_TICK_RATIO_MASK, val);
  2021. if (!tick)
  2022. return -EINVAL;
  2023. unit = (config & TRTCM_PKT_MODE) ? 1000000 / tick : 8000 / tick;
  2024. if (!unit)
  2025. return -EINVAL;
  2026. rate = rate_val / unit;
  2027. rate_frac = rate_val % unit;
  2028. rate_frac = FIELD_PREP(TRTCM_TOKEN_RATE_MASK, rate_frac) / unit;
  2029. rate = FIELD_PREP(TRTCM_TOKEN_RATE_MASK, rate) |
  2030. FIELD_PREP(TRTCM_TOKEN_RATE_FRACTION_MASK, rate_frac);
  2031. err = airoha_qdma_set_trtcm_param(qdma, channel, addr,
  2032. TRTCM_TOKEN_RATE_MODE, mode, rate);
  2033. if (err)
  2034. return err;
  2035. val = max_t(u32, bucket_size, MIN_TOKEN_SIZE);
  2036. val = min_t(u32, __fls(val), MAX_TOKEN_SIZE_OFFSET);
  2037. return airoha_qdma_set_trtcm_param(qdma, channel, addr,
  2038. TRTCM_BUCKETSIZE_SHIFT_MODE,
  2039. mode, val);
  2040. }
  2041. static int airoha_qdma_set_tx_rate_limit(struct airoha_gdm_port *port,
  2042. int channel, u32 rate,
  2043. u32 bucket_size)
  2044. {
  2045. int i, err;
  2046. for (i = 0; i <= TRTCM_PEAK_MODE; i++) {
  2047. err = airoha_qdma_set_trtcm_config(port->qdma, channel,
  2048. REG_EGRESS_TRTCM_CFG, i,
  2049. !!rate, TRTCM_METER_MODE);
  2050. if (err)
  2051. return err;
  2052. err = airoha_qdma_set_trtcm_token_bucket(port->qdma, channel,
  2053. REG_EGRESS_TRTCM_CFG,
  2054. i, rate, bucket_size);
  2055. if (err)
  2056. return err;
  2057. }
  2058. return 0;
  2059. }
  2060. static int airoha_tc_htb_alloc_leaf_queue(struct airoha_gdm_port *port,
  2061. struct tc_htb_qopt_offload *opt)
  2062. {
  2063. u32 channel = TC_H_MIN(opt->classid) % AIROHA_NUM_QOS_CHANNELS;
  2064. u32 rate = div_u64(opt->rate, 1000) << 3; /* kbps */
  2065. struct net_device *dev = port->dev;
  2066. int num_tx_queues = dev->real_num_tx_queues;
  2067. int err;
  2068. if (opt->parent_classid != TC_HTB_CLASSID_ROOT) {
  2069. NL_SET_ERR_MSG_MOD(opt->extack, "invalid parent classid");
  2070. return -EINVAL;
  2071. }
  2072. err = airoha_qdma_set_tx_rate_limit(port, channel, rate, opt->quantum);
  2073. if (err) {
  2074. NL_SET_ERR_MSG_MOD(opt->extack,
  2075. "failed configuring htb offload");
  2076. return err;
  2077. }
  2078. if (opt->command == TC_HTB_NODE_MODIFY)
  2079. return 0;
  2080. err = netif_set_real_num_tx_queues(dev, num_tx_queues + 1);
  2081. if (err) {
  2082. airoha_qdma_set_tx_rate_limit(port, channel, 0, opt->quantum);
  2083. NL_SET_ERR_MSG_MOD(opt->extack,
  2084. "failed setting real_num_tx_queues");
  2085. return err;
  2086. }
  2087. set_bit(channel, port->qos_sq_bmap);
  2088. opt->qid = AIROHA_NUM_TX_RING + channel;
  2089. return 0;
  2090. }
  2091. static int airoha_qdma_set_rx_meter(struct airoha_gdm_port *port,
  2092. u32 rate, u32 bucket_size,
  2093. enum trtcm_unit_type unit_type)
  2094. {
  2095. struct airoha_qdma *qdma = port->qdma;
  2096. int i;
  2097. for (i = 0; i < ARRAY_SIZE(qdma->q_rx); i++) {
  2098. int err;
  2099. if (!qdma->q_rx[i].ndesc)
  2100. continue;
  2101. err = airoha_qdma_init_rl_config(qdma, i, !!rate, unit_type);
  2102. if (err)
  2103. return err;
  2104. err = airoha_qdma_set_rl_token_bucket(qdma, i, rate,
  2105. bucket_size);
  2106. if (err)
  2107. return err;
  2108. }
  2109. return 0;
  2110. }
  2111. static int airoha_tc_matchall_act_validate(struct tc_cls_matchall_offload *f)
  2112. {
  2113. const struct flow_action *actions = &f->rule->action;
  2114. const struct flow_action_entry *act;
  2115. if (!flow_action_has_entries(actions)) {
  2116. NL_SET_ERR_MSG_MOD(f->common.extack,
  2117. "filter run with no actions");
  2118. return -EINVAL;
  2119. }
  2120. if (!flow_offload_has_one_action(actions)) {
  2121. NL_SET_ERR_MSG_MOD(f->common.extack,
  2122. "only once action per filter is supported");
  2123. return -EOPNOTSUPP;
  2124. }
  2125. act = &actions->entries[0];
  2126. if (act->id != FLOW_ACTION_POLICE) {
  2127. NL_SET_ERR_MSG_MOD(f->common.extack, "unsupported action");
  2128. return -EOPNOTSUPP;
  2129. }
  2130. if (act->police.exceed.act_id != FLOW_ACTION_DROP) {
  2131. NL_SET_ERR_MSG_MOD(f->common.extack,
  2132. "invalid exceed action id");
  2133. return -EOPNOTSUPP;
  2134. }
  2135. if (act->police.notexceed.act_id != FLOW_ACTION_ACCEPT) {
  2136. NL_SET_ERR_MSG_MOD(f->common.extack,
  2137. "invalid notexceed action id");
  2138. return -EOPNOTSUPP;
  2139. }
  2140. if (act->police.notexceed.act_id == FLOW_ACTION_ACCEPT &&
  2141. !flow_action_is_last_entry(actions, act)) {
  2142. NL_SET_ERR_MSG_MOD(f->common.extack,
  2143. "action accept must be last");
  2144. return -EOPNOTSUPP;
  2145. }
  2146. if (act->police.peakrate_bytes_ps || act->police.avrate ||
  2147. act->police.overhead || act->police.mtu) {
  2148. NL_SET_ERR_MSG_MOD(f->common.extack,
  2149. "peakrate/avrate/overhead/mtu unsupported");
  2150. return -EOPNOTSUPP;
  2151. }
  2152. return 0;
  2153. }
  2154. static int airoha_dev_tc_matchall(struct net_device *dev,
  2155. struct tc_cls_matchall_offload *f)
  2156. {
  2157. enum trtcm_unit_type unit_type = TRTCM_BYTE_UNIT;
  2158. struct airoha_gdm_port *port = netdev_priv(dev);
  2159. u32 rate = 0, bucket_size = 0;
  2160. switch (f->command) {
  2161. case TC_CLSMATCHALL_REPLACE: {
  2162. const struct flow_action_entry *act;
  2163. int err;
  2164. err = airoha_tc_matchall_act_validate(f);
  2165. if (err)
  2166. return err;
  2167. act = &f->rule->action.entries[0];
  2168. if (act->police.rate_pkt_ps) {
  2169. rate = act->police.rate_pkt_ps;
  2170. bucket_size = act->police.burst_pkt;
  2171. unit_type = TRTCM_PACKET_UNIT;
  2172. } else {
  2173. rate = div_u64(act->police.rate_bytes_ps, 1000);
  2174. rate = rate << 3; /* Kbps */
  2175. bucket_size = act->police.burst;
  2176. }
  2177. fallthrough;
  2178. }
  2179. case TC_CLSMATCHALL_DESTROY:
  2180. return airoha_qdma_set_rx_meter(port, rate, bucket_size,
  2181. unit_type);
  2182. default:
  2183. return -EOPNOTSUPP;
  2184. }
  2185. }
  2186. static int airoha_dev_setup_tc_block_cb(enum tc_setup_type type,
  2187. void *type_data, void *cb_priv)
  2188. {
  2189. struct net_device *dev = cb_priv;
  2190. struct airoha_gdm_port *port = netdev_priv(dev);
  2191. struct airoha_eth *eth = port->qdma->eth;
  2192. if (!tc_can_offload(dev))
  2193. return -EOPNOTSUPP;
  2194. switch (type) {
  2195. case TC_SETUP_CLSFLOWER:
  2196. return airoha_ppe_setup_tc_block_cb(&eth->ppe->dev, type_data);
  2197. case TC_SETUP_CLSMATCHALL:
  2198. return airoha_dev_tc_matchall(dev, type_data);
  2199. default:
  2200. return -EOPNOTSUPP;
  2201. }
  2202. }
  2203. static int airoha_dev_setup_tc_block(struct airoha_gdm_port *port,
  2204. struct flow_block_offload *f)
  2205. {
  2206. flow_setup_cb_t *cb = airoha_dev_setup_tc_block_cb;
  2207. static LIST_HEAD(block_cb_list);
  2208. struct flow_block_cb *block_cb;
  2209. if (f->binder_type != FLOW_BLOCK_BINDER_TYPE_CLSACT_INGRESS)
  2210. return -EOPNOTSUPP;
  2211. f->driver_block_list = &block_cb_list;
  2212. switch (f->command) {
  2213. case FLOW_BLOCK_BIND:
  2214. block_cb = flow_block_cb_lookup(f->block, cb, port->dev);
  2215. if (block_cb) {
  2216. flow_block_cb_incref(block_cb);
  2217. return 0;
  2218. }
  2219. block_cb = flow_block_cb_alloc(cb, port->dev, port->dev, NULL);
  2220. if (IS_ERR(block_cb))
  2221. return PTR_ERR(block_cb);
  2222. flow_block_cb_incref(block_cb);
  2223. flow_block_cb_add(block_cb, f);
  2224. list_add_tail(&block_cb->driver_list, &block_cb_list);
  2225. return 0;
  2226. case FLOW_BLOCK_UNBIND:
  2227. block_cb = flow_block_cb_lookup(f->block, cb, port->dev);
  2228. if (!block_cb)
  2229. return -ENOENT;
  2230. if (!flow_block_cb_decref(block_cb)) {
  2231. flow_block_cb_remove(block_cb, f);
  2232. list_del(&block_cb->driver_list);
  2233. }
  2234. return 0;
  2235. default:
  2236. return -EOPNOTSUPP;
  2237. }
  2238. }
  2239. static void airoha_tc_remove_htb_queue(struct airoha_gdm_port *port, int queue)
  2240. {
  2241. struct net_device *dev = port->dev;
  2242. netif_set_real_num_tx_queues(dev, dev->real_num_tx_queues - 1);
  2243. airoha_qdma_set_tx_rate_limit(port, queue + 1, 0, 0);
  2244. clear_bit(queue, port->qos_sq_bmap);
  2245. }
  2246. static int airoha_tc_htb_delete_leaf_queue(struct airoha_gdm_port *port,
  2247. struct tc_htb_qopt_offload *opt)
  2248. {
  2249. u32 channel = TC_H_MIN(opt->classid) % AIROHA_NUM_QOS_CHANNELS;
  2250. if (!test_bit(channel, port->qos_sq_bmap)) {
  2251. NL_SET_ERR_MSG_MOD(opt->extack, "invalid queue id");
  2252. return -EINVAL;
  2253. }
  2254. airoha_tc_remove_htb_queue(port, channel);
  2255. return 0;
  2256. }
  2257. static int airoha_tc_htb_destroy(struct airoha_gdm_port *port)
  2258. {
  2259. int q;
  2260. for_each_set_bit(q, port->qos_sq_bmap, AIROHA_NUM_QOS_CHANNELS)
  2261. airoha_tc_remove_htb_queue(port, q);
  2262. return 0;
  2263. }
  2264. static int airoha_tc_get_htb_get_leaf_queue(struct airoha_gdm_port *port,
  2265. struct tc_htb_qopt_offload *opt)
  2266. {
  2267. u32 channel = TC_H_MIN(opt->classid) % AIROHA_NUM_QOS_CHANNELS;
  2268. if (!test_bit(channel, port->qos_sq_bmap)) {
  2269. NL_SET_ERR_MSG_MOD(opt->extack, "invalid queue id");
  2270. return -EINVAL;
  2271. }
  2272. opt->qid = AIROHA_NUM_TX_RING + channel;
  2273. return 0;
  2274. }
  2275. static int airoha_tc_setup_qdisc_htb(struct airoha_gdm_port *port,
  2276. struct tc_htb_qopt_offload *opt)
  2277. {
  2278. switch (opt->command) {
  2279. case TC_HTB_CREATE:
  2280. break;
  2281. case TC_HTB_DESTROY:
  2282. return airoha_tc_htb_destroy(port);
  2283. case TC_HTB_NODE_MODIFY:
  2284. case TC_HTB_LEAF_ALLOC_QUEUE:
  2285. return airoha_tc_htb_alloc_leaf_queue(port, opt);
  2286. case TC_HTB_LEAF_DEL:
  2287. case TC_HTB_LEAF_DEL_LAST:
  2288. case TC_HTB_LEAF_DEL_LAST_FORCE:
  2289. return airoha_tc_htb_delete_leaf_queue(port, opt);
  2290. case TC_HTB_LEAF_QUERY_QUEUE:
  2291. return airoha_tc_get_htb_get_leaf_queue(port, opt);
  2292. default:
  2293. return -EOPNOTSUPP;
  2294. }
  2295. return 0;
  2296. }
  2297. static int airoha_dev_tc_setup(struct net_device *dev, enum tc_setup_type type,
  2298. void *type_data)
  2299. {
  2300. struct airoha_gdm_port *port = netdev_priv(dev);
  2301. switch (type) {
  2302. case TC_SETUP_QDISC_ETS:
  2303. return airoha_tc_setup_qdisc_ets(port, type_data);
  2304. case TC_SETUP_QDISC_HTB:
  2305. return airoha_tc_setup_qdisc_htb(port, type_data);
  2306. case TC_SETUP_BLOCK:
  2307. case TC_SETUP_FT:
  2308. return airoha_dev_setup_tc_block(port, type_data);
  2309. default:
  2310. return -EOPNOTSUPP;
  2311. }
  2312. }
  2313. static const struct net_device_ops airoha_netdev_ops = {
  2314. .ndo_init = airoha_dev_init,
  2315. .ndo_open = airoha_dev_open,
  2316. .ndo_stop = airoha_dev_stop,
  2317. .ndo_change_mtu = airoha_dev_change_mtu,
  2318. .ndo_select_queue = airoha_dev_select_queue,
  2319. .ndo_start_xmit = airoha_dev_xmit,
  2320. .ndo_get_stats64 = airoha_dev_get_stats64,
  2321. .ndo_set_mac_address = airoha_dev_set_macaddr,
  2322. .ndo_setup_tc = airoha_dev_tc_setup,
  2323. };
  2324. static const struct ethtool_ops airoha_ethtool_ops = {
  2325. .get_drvinfo = airoha_ethtool_get_drvinfo,
  2326. .get_eth_mac_stats = airoha_ethtool_get_mac_stats,
  2327. .get_rmon_stats = airoha_ethtool_get_rmon_stats,
  2328. .get_link_ksettings = phy_ethtool_get_link_ksettings,
  2329. .get_link = ethtool_op_get_link,
  2330. };
  2331. static int airoha_metadata_dst_alloc(struct airoha_gdm_port *port)
  2332. {
  2333. int i;
  2334. for (i = 0; i < ARRAY_SIZE(port->dsa_meta); i++) {
  2335. struct metadata_dst *md_dst;
  2336. md_dst = metadata_dst_alloc(0, METADATA_HW_PORT_MUX,
  2337. GFP_KERNEL);
  2338. if (!md_dst)
  2339. return -ENOMEM;
  2340. md_dst->u.port_info.port_id = i;
  2341. port->dsa_meta[i] = md_dst;
  2342. }
  2343. return 0;
  2344. }
  2345. static void airoha_metadata_dst_free(struct airoha_gdm_port *port)
  2346. {
  2347. int i;
  2348. for (i = 0; i < ARRAY_SIZE(port->dsa_meta); i++) {
  2349. if (!port->dsa_meta[i])
  2350. continue;
  2351. metadata_dst_free(port->dsa_meta[i]);
  2352. }
  2353. }
  2354. bool airoha_is_valid_gdm_port(struct airoha_eth *eth,
  2355. struct airoha_gdm_port *port)
  2356. {
  2357. int i;
  2358. for (i = 0; i < ARRAY_SIZE(eth->ports); i++) {
  2359. if (eth->ports[i] == port)
  2360. return true;
  2361. }
  2362. return false;
  2363. }
  2364. static int airoha_alloc_gdm_port(struct airoha_eth *eth,
  2365. struct device_node *np, int index)
  2366. {
  2367. const __be32 *id_ptr = of_get_property(np, "reg", NULL);
  2368. struct airoha_gdm_port *port;
  2369. struct airoha_qdma *qdma;
  2370. struct net_device *dev;
  2371. int err, p;
  2372. u32 id;
  2373. if (!id_ptr) {
  2374. dev_err(eth->dev, "missing gdm port id\n");
  2375. return -EINVAL;
  2376. }
  2377. id = be32_to_cpup(id_ptr);
  2378. p = id - 1;
  2379. if (!id || id > ARRAY_SIZE(eth->ports)) {
  2380. dev_err(eth->dev, "invalid gdm port id: %d\n", id);
  2381. return -EINVAL;
  2382. }
  2383. if (eth->ports[p]) {
  2384. dev_err(eth->dev, "duplicate gdm port id: %d\n", id);
  2385. return -EINVAL;
  2386. }
  2387. dev = devm_alloc_etherdev_mqs(eth->dev, sizeof(*port),
  2388. AIROHA_NUM_NETDEV_TX_RINGS,
  2389. AIROHA_NUM_RX_RING);
  2390. if (!dev) {
  2391. dev_err(eth->dev, "alloc_etherdev failed\n");
  2392. return -ENOMEM;
  2393. }
  2394. qdma = &eth->qdma[index % AIROHA_MAX_NUM_QDMA];
  2395. dev->netdev_ops = &airoha_netdev_ops;
  2396. dev->ethtool_ops = &airoha_ethtool_ops;
  2397. dev->max_mtu = AIROHA_MAX_MTU;
  2398. dev->watchdog_timeo = 5 * HZ;
  2399. dev->hw_features = NETIF_F_IP_CSUM | NETIF_F_RXCSUM |
  2400. NETIF_F_TSO6 | NETIF_F_IPV6_CSUM |
  2401. NETIF_F_SG | NETIF_F_TSO |
  2402. NETIF_F_HW_TC;
  2403. dev->features |= dev->hw_features;
  2404. dev->vlan_features = dev->hw_features;
  2405. dev->dev.of_node = np;
  2406. dev->irq = qdma->irq_banks[0].irq;
  2407. SET_NETDEV_DEV(dev, eth->dev);
  2408. /* reserve hw queues for HTB offloading */
  2409. err = netif_set_real_num_tx_queues(dev, AIROHA_NUM_TX_RING);
  2410. if (err)
  2411. return err;
  2412. err = of_get_ethdev_address(np, dev);
  2413. if (err) {
  2414. if (err == -EPROBE_DEFER)
  2415. return err;
  2416. eth_hw_addr_random(dev);
  2417. dev_info(eth->dev, "generated random MAC address %pM\n",
  2418. dev->dev_addr);
  2419. }
  2420. port = netdev_priv(dev);
  2421. u64_stats_init(&port->stats.syncp);
  2422. spin_lock_init(&port->stats.lock);
  2423. port->qdma = qdma;
  2424. port->dev = dev;
  2425. port->id = id;
  2426. eth->ports[p] = port;
  2427. return airoha_metadata_dst_alloc(port);
  2428. }
  2429. static int airoha_register_gdm_devices(struct airoha_eth *eth)
  2430. {
  2431. int i;
  2432. for (i = 0; i < ARRAY_SIZE(eth->ports); i++) {
  2433. struct airoha_gdm_port *port = eth->ports[i];
  2434. int err;
  2435. if (!port)
  2436. continue;
  2437. err = register_netdev(port->dev);
  2438. if (err)
  2439. return err;
  2440. }
  2441. set_bit(DEV_STATE_REGISTERED, &eth->state);
  2442. return 0;
  2443. }
  2444. static int airoha_probe(struct platform_device *pdev)
  2445. {
  2446. struct reset_control_bulk_data *xsi_rsts;
  2447. struct device_node *np;
  2448. struct airoha_eth *eth;
  2449. int i, err;
  2450. eth = devm_kzalloc(&pdev->dev, sizeof(*eth), GFP_KERNEL);
  2451. if (!eth)
  2452. return -ENOMEM;
  2453. eth->soc = of_device_get_match_data(&pdev->dev);
  2454. if (!eth->soc)
  2455. return -EINVAL;
  2456. eth->dev = &pdev->dev;
  2457. err = dma_set_mask_and_coherent(eth->dev, DMA_BIT_MASK(32));
  2458. if (err) {
  2459. dev_err(eth->dev, "failed configuring DMA mask\n");
  2460. return err;
  2461. }
  2462. eth->fe_regs = devm_platform_ioremap_resource_byname(pdev, "fe");
  2463. if (IS_ERR(eth->fe_regs))
  2464. return dev_err_probe(eth->dev, PTR_ERR(eth->fe_regs),
  2465. "failed to iomap fe regs\n");
  2466. eth->rsts[0].id = "fe";
  2467. eth->rsts[1].id = "pdma";
  2468. eth->rsts[2].id = "qdma";
  2469. err = devm_reset_control_bulk_get_exclusive(eth->dev,
  2470. ARRAY_SIZE(eth->rsts),
  2471. eth->rsts);
  2472. if (err) {
  2473. dev_err(eth->dev, "failed to get bulk reset lines\n");
  2474. return err;
  2475. }
  2476. xsi_rsts = devm_kcalloc(eth->dev,
  2477. eth->soc->num_xsi_rsts, sizeof(*xsi_rsts),
  2478. GFP_KERNEL);
  2479. if (!xsi_rsts)
  2480. return -ENOMEM;
  2481. eth->xsi_rsts = xsi_rsts;
  2482. for (i = 0; i < eth->soc->num_xsi_rsts; i++)
  2483. eth->xsi_rsts[i].id = eth->soc->xsi_rsts_names[i];
  2484. err = devm_reset_control_bulk_get_exclusive(eth->dev,
  2485. eth->soc->num_xsi_rsts,
  2486. eth->xsi_rsts);
  2487. if (err) {
  2488. dev_err(eth->dev, "failed to get bulk xsi reset lines\n");
  2489. return err;
  2490. }
  2491. eth->napi_dev = alloc_netdev_dummy(0);
  2492. if (!eth->napi_dev)
  2493. return -ENOMEM;
  2494. /* Enable threaded NAPI by default */
  2495. eth->napi_dev->threaded = true;
  2496. strscpy(eth->napi_dev->name, "qdma_eth", sizeof(eth->napi_dev->name));
  2497. platform_set_drvdata(pdev, eth);
  2498. err = airoha_hw_init(pdev, eth);
  2499. if (err)
  2500. goto error_hw_cleanup;
  2501. for (i = 0; i < ARRAY_SIZE(eth->qdma); i++)
  2502. airoha_qdma_start_napi(&eth->qdma[i]);
  2503. i = 0;
  2504. for_each_child_of_node(pdev->dev.of_node, np) {
  2505. if (!of_device_is_compatible(np, "airoha,eth-mac"))
  2506. continue;
  2507. if (!of_device_is_available(np))
  2508. continue;
  2509. err = airoha_alloc_gdm_port(eth, np, i++);
  2510. if (err) {
  2511. of_node_put(np);
  2512. goto error_napi_stop;
  2513. }
  2514. }
  2515. err = airoha_register_gdm_devices(eth);
  2516. if (err)
  2517. goto error_napi_stop;
  2518. return 0;
  2519. error_napi_stop:
  2520. for (i = 0; i < ARRAY_SIZE(eth->qdma); i++)
  2521. airoha_qdma_stop_napi(&eth->qdma[i]);
  2522. airoha_ppe_deinit(eth);
  2523. error_hw_cleanup:
  2524. for (i = 0; i < ARRAY_SIZE(eth->qdma); i++)
  2525. airoha_hw_cleanup(&eth->qdma[i]);
  2526. for (i = 0; i < ARRAY_SIZE(eth->ports); i++) {
  2527. struct airoha_gdm_port *port = eth->ports[i];
  2528. if (!port)
  2529. continue;
  2530. if (port->dev->reg_state == NETREG_REGISTERED)
  2531. unregister_netdev(port->dev);
  2532. airoha_metadata_dst_free(port);
  2533. }
  2534. free_netdev(eth->napi_dev);
  2535. platform_set_drvdata(pdev, NULL);
  2536. return err;
  2537. }
  2538. static void airoha_remove(struct platform_device *pdev)
  2539. {
  2540. struct airoha_eth *eth = platform_get_drvdata(pdev);
  2541. int i;
  2542. for (i = 0; i < ARRAY_SIZE(eth->qdma); i++) {
  2543. airoha_qdma_stop_napi(&eth->qdma[i]);
  2544. airoha_hw_cleanup(&eth->qdma[i]);
  2545. }
  2546. for (i = 0; i < ARRAY_SIZE(eth->ports); i++) {
  2547. struct airoha_gdm_port *port = eth->ports[i];
  2548. if (!port)
  2549. continue;
  2550. unregister_netdev(port->dev);
  2551. airoha_metadata_dst_free(port);
  2552. }
  2553. free_netdev(eth->napi_dev);
  2554. airoha_ppe_deinit(eth);
  2555. platform_set_drvdata(pdev, NULL);
  2556. }
  2557. static const char * const en7581_xsi_rsts_names[] = {
  2558. "xsi-mac",
  2559. "hsi0-mac",
  2560. "hsi1-mac",
  2561. "hsi-mac",
  2562. "xfp-mac",
  2563. };
  2564. static int airoha_en7581_get_src_port_id(struct airoha_gdm_port *port, int nbq)
  2565. {
  2566. switch (port->id) {
  2567. case AIROHA_GDM3_IDX:
  2568. /* 7581 SoC supports PCIe serdes on GDM3 port */
  2569. if (nbq == 4)
  2570. return HSGMII_LAN_7581_PCIE0_SRCPORT;
  2571. if (nbq == 5)
  2572. return HSGMII_LAN_7581_PCIE1_SRCPORT;
  2573. break;
  2574. case AIROHA_GDM4_IDX:
  2575. /* 7581 SoC supports eth and usb serdes on GDM4 port */
  2576. if (!nbq)
  2577. return HSGMII_LAN_7581_ETH_SRCPORT;
  2578. if (nbq == 1)
  2579. return HSGMII_LAN_7581_USB_SRCPORT;
  2580. break;
  2581. default:
  2582. break;
  2583. }
  2584. return -EINVAL;
  2585. }
  2586. static const char * const an7583_xsi_rsts_names[] = {
  2587. "xsi-mac",
  2588. "hsi0-mac",
  2589. "hsi1-mac",
  2590. "xfp-mac",
  2591. };
  2592. static int airoha_an7583_get_src_port_id(struct airoha_gdm_port *port, int nbq)
  2593. {
  2594. switch (port->id) {
  2595. case AIROHA_GDM3_IDX:
  2596. /* 7583 SoC supports eth serdes on GDM3 port */
  2597. if (!nbq)
  2598. return HSGMII_LAN_7583_ETH_SRCPORT;
  2599. break;
  2600. case AIROHA_GDM4_IDX:
  2601. /* 7583 SoC supports PCIe and USB serdes on GDM4 port */
  2602. if (!nbq)
  2603. return HSGMII_LAN_7583_PCIE_SRCPORT;
  2604. if (nbq == 1)
  2605. return HSGMII_LAN_7583_USB_SRCPORT;
  2606. break;
  2607. default:
  2608. break;
  2609. }
  2610. return -EINVAL;
  2611. }
  2612. static const struct airoha_eth_soc_data en7581_soc_data = {
  2613. .version = 0x7581,
  2614. .xsi_rsts_names = en7581_xsi_rsts_names,
  2615. .num_xsi_rsts = ARRAY_SIZE(en7581_xsi_rsts_names),
  2616. .num_ppe = 2,
  2617. .ops = {
  2618. .get_src_port_id = airoha_en7581_get_src_port_id,
  2619. },
  2620. };
  2621. static const struct airoha_eth_soc_data an7583_soc_data = {
  2622. .version = 0x7583,
  2623. .xsi_rsts_names = an7583_xsi_rsts_names,
  2624. .num_xsi_rsts = ARRAY_SIZE(an7583_xsi_rsts_names),
  2625. .num_ppe = 1,
  2626. .ops = {
  2627. .get_src_port_id = airoha_an7583_get_src_port_id,
  2628. },
  2629. };
  2630. static const struct of_device_id of_airoha_match[] = {
  2631. { .compatible = "airoha,en7581-eth", .data = &en7581_soc_data },
  2632. { .compatible = "airoha,an7583-eth", .data = &an7583_soc_data },
  2633. { /* sentinel */ }
  2634. };
  2635. MODULE_DEVICE_TABLE(of, of_airoha_match);
  2636. static struct platform_driver airoha_driver = {
  2637. .probe = airoha_probe,
  2638. .remove = airoha_remove,
  2639. .driver = {
  2640. .name = KBUILD_MODNAME,
  2641. .of_match_table = of_airoha_match,
  2642. },
  2643. };
  2644. module_platform_driver(airoha_driver);
  2645. MODULE_LICENSE("GPL");
  2646. MODULE_AUTHOR("Lorenzo Bianconi <lorenzo@kernel.org>");
  2647. MODULE_DESCRIPTION("Ethernet driver for Airoha SoC");