qmi.c 102 KB

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  1. // SPDX-License-Identifier: BSD-3-Clause-Clear
  2. /*
  3. * Copyright (c) 2018-2021 The Linux Foundation. All rights reserved.
  4. * Copyright (c) Qualcomm Technologies, Inc. and/or its subsidiaries.
  5. */
  6. #include <linux/elf.h>
  7. #include "qmi.h"
  8. #include "core.h"
  9. #include "debug.h"
  10. #include <linux/of.h>
  11. #include <linux/firmware.h>
  12. #include <linux/of_address.h>
  13. #include <linux/ioport.h>
  14. #define SLEEP_CLOCK_SELECT_INTERNAL_BIT 0x02
  15. #define HOST_CSTATE_BIT 0x04
  16. #define PLATFORM_CAP_PCIE_GLOBAL_RESET 0x08
  17. #define ATH12K_QMI_MAX_CHUNK_SIZE 2097152
  18. static const struct qmi_elem_info wlfw_host_mlo_chip_info_s_v01_ei[] = {
  19. {
  20. .data_type = QMI_UNSIGNED_1_BYTE,
  21. .elem_len = 1,
  22. .elem_size = sizeof(u8),
  23. .array_type = NO_ARRAY,
  24. .tlv_type = 0,
  25. .offset = offsetof(struct wlfw_host_mlo_chip_info_s_v01,
  26. chip_id),
  27. },
  28. {
  29. .data_type = QMI_UNSIGNED_1_BYTE,
  30. .elem_len = 1,
  31. .elem_size = sizeof(u8),
  32. .array_type = NO_ARRAY,
  33. .tlv_type = 0,
  34. .offset = offsetof(struct wlfw_host_mlo_chip_info_s_v01,
  35. num_local_links),
  36. },
  37. {
  38. .data_type = QMI_UNSIGNED_1_BYTE,
  39. .elem_len = QMI_WLFW_MAX_NUM_MLO_LINKS_PER_CHIP_V01,
  40. .elem_size = sizeof(u8),
  41. .array_type = STATIC_ARRAY,
  42. .tlv_type = 0,
  43. .offset = offsetof(struct wlfw_host_mlo_chip_info_s_v01,
  44. hw_link_id),
  45. },
  46. {
  47. .data_type = QMI_UNSIGNED_1_BYTE,
  48. .elem_len = QMI_WLFW_MAX_NUM_MLO_LINKS_PER_CHIP_V01,
  49. .elem_size = sizeof(u8),
  50. .array_type = STATIC_ARRAY,
  51. .tlv_type = 0,
  52. .offset = offsetof(struct wlfw_host_mlo_chip_info_s_v01,
  53. valid_mlo_link_id),
  54. },
  55. {
  56. .data_type = QMI_EOTI,
  57. .array_type = NO_ARRAY,
  58. .tlv_type = QMI_COMMON_TLV_TYPE,
  59. },
  60. };
  61. static const struct qmi_elem_info qmi_wlanfw_host_cap_req_msg_v01_ei[] = {
  62. {
  63. .data_type = QMI_OPT_FLAG,
  64. .elem_len = 1,
  65. .elem_size = sizeof(u8),
  66. .array_type = NO_ARRAY,
  67. .tlv_type = 0x10,
  68. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  69. num_clients_valid),
  70. },
  71. {
  72. .data_type = QMI_UNSIGNED_4_BYTE,
  73. .elem_len = 1,
  74. .elem_size = sizeof(u32),
  75. .array_type = NO_ARRAY,
  76. .tlv_type = 0x10,
  77. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  78. num_clients),
  79. },
  80. {
  81. .data_type = QMI_OPT_FLAG,
  82. .elem_len = 1,
  83. .elem_size = sizeof(u8),
  84. .array_type = NO_ARRAY,
  85. .tlv_type = 0x11,
  86. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  87. wake_msi_valid),
  88. },
  89. {
  90. .data_type = QMI_UNSIGNED_4_BYTE,
  91. .elem_len = 1,
  92. .elem_size = sizeof(u32),
  93. .array_type = NO_ARRAY,
  94. .tlv_type = 0x11,
  95. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  96. wake_msi),
  97. },
  98. {
  99. .data_type = QMI_OPT_FLAG,
  100. .elem_len = 1,
  101. .elem_size = sizeof(u8),
  102. .array_type = NO_ARRAY,
  103. .tlv_type = 0x12,
  104. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  105. gpios_valid),
  106. },
  107. {
  108. .data_type = QMI_DATA_LEN,
  109. .elem_len = 1,
  110. .elem_size = sizeof(u8),
  111. .array_type = NO_ARRAY,
  112. .tlv_type = 0x12,
  113. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  114. gpios_len),
  115. },
  116. {
  117. .data_type = QMI_UNSIGNED_4_BYTE,
  118. .elem_len = QMI_WLFW_MAX_NUM_GPIO_V01,
  119. .elem_size = sizeof(u32),
  120. .array_type = VAR_LEN_ARRAY,
  121. .tlv_type = 0x12,
  122. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  123. gpios),
  124. },
  125. {
  126. .data_type = QMI_OPT_FLAG,
  127. .elem_len = 1,
  128. .elem_size = sizeof(u8),
  129. .array_type = NO_ARRAY,
  130. .tlv_type = 0x13,
  131. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  132. nm_modem_valid),
  133. },
  134. {
  135. .data_type = QMI_UNSIGNED_1_BYTE,
  136. .elem_len = 1,
  137. .elem_size = sizeof(u8),
  138. .array_type = NO_ARRAY,
  139. .tlv_type = 0x13,
  140. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  141. nm_modem),
  142. },
  143. {
  144. .data_type = QMI_OPT_FLAG,
  145. .elem_len = 1,
  146. .elem_size = sizeof(u8),
  147. .array_type = NO_ARRAY,
  148. .tlv_type = 0x14,
  149. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  150. bdf_support_valid),
  151. },
  152. {
  153. .data_type = QMI_UNSIGNED_1_BYTE,
  154. .elem_len = 1,
  155. .elem_size = sizeof(u8),
  156. .array_type = NO_ARRAY,
  157. .tlv_type = 0x14,
  158. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  159. bdf_support),
  160. },
  161. {
  162. .data_type = QMI_OPT_FLAG,
  163. .elem_len = 1,
  164. .elem_size = sizeof(u8),
  165. .array_type = NO_ARRAY,
  166. .tlv_type = 0x15,
  167. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  168. bdf_cache_support_valid),
  169. },
  170. {
  171. .data_type = QMI_UNSIGNED_1_BYTE,
  172. .elem_len = 1,
  173. .elem_size = sizeof(u8),
  174. .array_type = NO_ARRAY,
  175. .tlv_type = 0x15,
  176. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  177. bdf_cache_support),
  178. },
  179. {
  180. .data_type = QMI_OPT_FLAG,
  181. .elem_len = 1,
  182. .elem_size = sizeof(u8),
  183. .array_type = NO_ARRAY,
  184. .tlv_type = 0x16,
  185. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  186. m3_support_valid),
  187. },
  188. {
  189. .data_type = QMI_UNSIGNED_1_BYTE,
  190. .elem_len = 1,
  191. .elem_size = sizeof(u8),
  192. .array_type = NO_ARRAY,
  193. .tlv_type = 0x16,
  194. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  195. m3_support),
  196. },
  197. {
  198. .data_type = QMI_OPT_FLAG,
  199. .elem_len = 1,
  200. .elem_size = sizeof(u8),
  201. .array_type = NO_ARRAY,
  202. .tlv_type = 0x17,
  203. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  204. m3_cache_support_valid),
  205. },
  206. {
  207. .data_type = QMI_UNSIGNED_1_BYTE,
  208. .elem_len = 1,
  209. .elem_size = sizeof(u8),
  210. .array_type = NO_ARRAY,
  211. .tlv_type = 0x17,
  212. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  213. m3_cache_support),
  214. },
  215. {
  216. .data_type = QMI_OPT_FLAG,
  217. .elem_len = 1,
  218. .elem_size = sizeof(u8),
  219. .array_type = NO_ARRAY,
  220. .tlv_type = 0x18,
  221. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  222. cal_filesys_support_valid),
  223. },
  224. {
  225. .data_type = QMI_UNSIGNED_1_BYTE,
  226. .elem_len = 1,
  227. .elem_size = sizeof(u8),
  228. .array_type = NO_ARRAY,
  229. .tlv_type = 0x18,
  230. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  231. cal_filesys_support),
  232. },
  233. {
  234. .data_type = QMI_OPT_FLAG,
  235. .elem_len = 1,
  236. .elem_size = sizeof(u8),
  237. .array_type = NO_ARRAY,
  238. .tlv_type = 0x19,
  239. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  240. cal_cache_support_valid),
  241. },
  242. {
  243. .data_type = QMI_UNSIGNED_1_BYTE,
  244. .elem_len = 1,
  245. .elem_size = sizeof(u8),
  246. .array_type = NO_ARRAY,
  247. .tlv_type = 0x19,
  248. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  249. cal_cache_support),
  250. },
  251. {
  252. .data_type = QMI_OPT_FLAG,
  253. .elem_len = 1,
  254. .elem_size = sizeof(u8),
  255. .array_type = NO_ARRAY,
  256. .tlv_type = 0x1A,
  257. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  258. cal_done_valid),
  259. },
  260. {
  261. .data_type = QMI_UNSIGNED_1_BYTE,
  262. .elem_len = 1,
  263. .elem_size = sizeof(u8),
  264. .array_type = NO_ARRAY,
  265. .tlv_type = 0x1A,
  266. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  267. cal_done),
  268. },
  269. {
  270. .data_type = QMI_OPT_FLAG,
  271. .elem_len = 1,
  272. .elem_size = sizeof(u8),
  273. .array_type = NO_ARRAY,
  274. .tlv_type = 0x1B,
  275. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  276. mem_bucket_valid),
  277. },
  278. {
  279. .data_type = QMI_UNSIGNED_4_BYTE,
  280. .elem_len = 1,
  281. .elem_size = sizeof(u32),
  282. .array_type = NO_ARRAY,
  283. .tlv_type = 0x1B,
  284. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  285. mem_bucket),
  286. },
  287. {
  288. .data_type = QMI_OPT_FLAG,
  289. .elem_len = 1,
  290. .elem_size = sizeof(u8),
  291. .array_type = NO_ARRAY,
  292. .tlv_type = 0x1C,
  293. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  294. mem_cfg_mode_valid),
  295. },
  296. {
  297. .data_type = QMI_UNSIGNED_1_BYTE,
  298. .elem_len = 1,
  299. .elem_size = sizeof(u8),
  300. .array_type = NO_ARRAY,
  301. .tlv_type = 0x1C,
  302. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  303. mem_cfg_mode),
  304. },
  305. {
  306. .data_type = QMI_OPT_FLAG,
  307. .elem_len = 1,
  308. .elem_size = sizeof(u8),
  309. .array_type = NO_ARRAY,
  310. .tlv_type = 0x1D,
  311. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  312. cal_duration_valid),
  313. },
  314. {
  315. .data_type = QMI_UNSIGNED_2_BYTE,
  316. .elem_len = 1,
  317. .elem_size = sizeof(u16),
  318. .array_type = NO_ARRAY,
  319. .tlv_type = 0x1D,
  320. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  321. cal_duraiton),
  322. },
  323. {
  324. .data_type = QMI_OPT_FLAG,
  325. .elem_len = 1,
  326. .elem_size = sizeof(u8),
  327. .array_type = NO_ARRAY,
  328. .tlv_type = 0x1E,
  329. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  330. platform_name_valid),
  331. },
  332. {
  333. .data_type = QMI_STRING,
  334. .elem_len = QMI_WLANFW_MAX_PLATFORM_NAME_LEN_V01 + 1,
  335. .elem_size = sizeof(char),
  336. .array_type = NO_ARRAY,
  337. .tlv_type = 0x1E,
  338. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  339. platform_name),
  340. },
  341. {
  342. .data_type = QMI_OPT_FLAG,
  343. .elem_len = 1,
  344. .elem_size = sizeof(u8),
  345. .array_type = NO_ARRAY,
  346. .tlv_type = 0x1F,
  347. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  348. ddr_range_valid),
  349. },
  350. {
  351. .data_type = QMI_STRUCT,
  352. .elem_len = QMI_WLANFW_MAX_HOST_DDR_RANGE_SIZE_V01,
  353. .elem_size = sizeof(struct qmi_wlanfw_host_ddr_range),
  354. .array_type = STATIC_ARRAY,
  355. .tlv_type = 0x1F,
  356. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  357. ddr_range),
  358. },
  359. {
  360. .data_type = QMI_OPT_FLAG,
  361. .elem_len = 1,
  362. .elem_size = sizeof(u8),
  363. .array_type = NO_ARRAY,
  364. .tlv_type = 0x20,
  365. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  366. host_build_type_valid),
  367. },
  368. {
  369. .data_type = QMI_SIGNED_4_BYTE_ENUM,
  370. .elem_len = 1,
  371. .elem_size = sizeof(enum qmi_wlanfw_host_build_type),
  372. .array_type = NO_ARRAY,
  373. .tlv_type = 0x20,
  374. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  375. host_build_type),
  376. },
  377. {
  378. .data_type = QMI_OPT_FLAG,
  379. .elem_len = 1,
  380. .elem_size = sizeof(u8),
  381. .array_type = NO_ARRAY,
  382. .tlv_type = 0x21,
  383. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  384. mlo_capable_valid),
  385. },
  386. {
  387. .data_type = QMI_UNSIGNED_1_BYTE,
  388. .elem_len = 1,
  389. .elem_size = sizeof(u8),
  390. .array_type = NO_ARRAY,
  391. .tlv_type = 0x21,
  392. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  393. mlo_capable),
  394. },
  395. {
  396. .data_type = QMI_OPT_FLAG,
  397. .elem_len = 1,
  398. .elem_size = sizeof(u8),
  399. .array_type = NO_ARRAY,
  400. .tlv_type = 0x22,
  401. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  402. mlo_chip_id_valid),
  403. },
  404. {
  405. .data_type = QMI_UNSIGNED_2_BYTE,
  406. .elem_len = 1,
  407. .elem_size = sizeof(u16),
  408. .array_type = NO_ARRAY,
  409. .tlv_type = 0x22,
  410. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  411. mlo_chip_id),
  412. },
  413. {
  414. .data_type = QMI_OPT_FLAG,
  415. .elem_len = 1,
  416. .elem_size = sizeof(u8),
  417. .array_type = NO_ARRAY,
  418. .tlv_type = 0x23,
  419. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  420. mlo_group_id_valid),
  421. },
  422. {
  423. .data_type = QMI_UNSIGNED_1_BYTE,
  424. .elem_len = 1,
  425. .elem_size = sizeof(u8),
  426. .array_type = NO_ARRAY,
  427. .tlv_type = 0x23,
  428. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  429. mlo_group_id),
  430. },
  431. {
  432. .data_type = QMI_OPT_FLAG,
  433. .elem_len = 1,
  434. .elem_size = sizeof(u8),
  435. .array_type = NO_ARRAY,
  436. .tlv_type = 0x24,
  437. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  438. max_mlo_peer_valid),
  439. },
  440. {
  441. .data_type = QMI_UNSIGNED_2_BYTE,
  442. .elem_len = 1,
  443. .elem_size = sizeof(u16),
  444. .array_type = NO_ARRAY,
  445. .tlv_type = 0x24,
  446. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  447. max_mlo_peer),
  448. },
  449. {
  450. .data_type = QMI_OPT_FLAG,
  451. .elem_len = 1,
  452. .elem_size = sizeof(u8),
  453. .array_type = NO_ARRAY,
  454. .tlv_type = 0x25,
  455. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  456. mlo_num_chips_valid),
  457. },
  458. {
  459. .data_type = QMI_UNSIGNED_1_BYTE,
  460. .elem_len = 1,
  461. .elem_size = sizeof(u8),
  462. .array_type = NO_ARRAY,
  463. .tlv_type = 0x25,
  464. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  465. mlo_num_chips),
  466. },
  467. {
  468. .data_type = QMI_OPT_FLAG,
  469. .elem_len = 1,
  470. .elem_size = sizeof(u8),
  471. .array_type = NO_ARRAY,
  472. .tlv_type = 0x26,
  473. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  474. mlo_chip_info_valid),
  475. },
  476. {
  477. .data_type = QMI_STRUCT,
  478. .elem_len = QMI_WLFW_MAX_NUM_MLO_CHIPS_V01,
  479. .elem_size = sizeof(struct wlfw_host_mlo_chip_info_s_v01),
  480. .array_type = STATIC_ARRAY,
  481. .tlv_type = 0x26,
  482. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  483. mlo_chip_info),
  484. .ei_array = wlfw_host_mlo_chip_info_s_v01_ei,
  485. },
  486. {
  487. .data_type = QMI_OPT_FLAG,
  488. .elem_len = 1,
  489. .elem_size = sizeof(u8),
  490. .array_type = NO_ARRAY,
  491. .tlv_type = 0x27,
  492. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  493. feature_list_valid),
  494. },
  495. {
  496. .data_type = QMI_UNSIGNED_8_BYTE,
  497. .elem_len = 1,
  498. .elem_size = sizeof(u64),
  499. .array_type = NO_ARRAY,
  500. .tlv_type = 0x27,
  501. .offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
  502. feature_list),
  503. },
  504. {
  505. .data_type = QMI_EOTI,
  506. .array_type = NO_ARRAY,
  507. .tlv_type = QMI_COMMON_TLV_TYPE,
  508. },
  509. };
  510. static const struct qmi_elem_info qmi_wlanfw_host_cap_resp_msg_v01_ei[] = {
  511. {
  512. .data_type = QMI_STRUCT,
  513. .elem_len = 1,
  514. .elem_size = sizeof(struct qmi_response_type_v01),
  515. .array_type = NO_ARRAY,
  516. .tlv_type = 0x02,
  517. .offset = offsetof(struct qmi_wlanfw_host_cap_resp_msg_v01, resp),
  518. .ei_array = qmi_response_type_v01_ei,
  519. },
  520. {
  521. .data_type = QMI_EOTI,
  522. .array_type = NO_ARRAY,
  523. .tlv_type = QMI_COMMON_TLV_TYPE,
  524. },
  525. };
  526. static const struct qmi_elem_info qmi_wlanfw_phy_cap_req_msg_v01_ei[] = {
  527. {
  528. .data_type = QMI_EOTI,
  529. .array_type = NO_ARRAY,
  530. .tlv_type = QMI_COMMON_TLV_TYPE,
  531. },
  532. };
  533. static const struct qmi_elem_info qmi_wlanfw_phy_cap_resp_msg_v01_ei[] = {
  534. {
  535. .data_type = QMI_STRUCT,
  536. .elem_len = 1,
  537. .elem_size = sizeof(struct qmi_response_type_v01),
  538. .array_type = NO_ARRAY,
  539. .tlv_type = 0x02,
  540. .offset = offsetof(struct qmi_wlanfw_phy_cap_resp_msg_v01, resp),
  541. .ei_array = qmi_response_type_v01_ei,
  542. },
  543. {
  544. .data_type = QMI_OPT_FLAG,
  545. .elem_len = 1,
  546. .elem_size = sizeof(u8),
  547. .array_type = NO_ARRAY,
  548. .tlv_type = 0x10,
  549. .offset = offsetof(struct qmi_wlanfw_phy_cap_resp_msg_v01,
  550. num_phy_valid),
  551. },
  552. {
  553. .data_type = QMI_UNSIGNED_1_BYTE,
  554. .elem_len = 1,
  555. .elem_size = sizeof(u8),
  556. .array_type = NO_ARRAY,
  557. .tlv_type = 0x10,
  558. .offset = offsetof(struct qmi_wlanfw_phy_cap_resp_msg_v01,
  559. num_phy),
  560. },
  561. {
  562. .data_type = QMI_OPT_FLAG,
  563. .elem_len = 1,
  564. .elem_size = sizeof(u8),
  565. .array_type = NO_ARRAY,
  566. .tlv_type = 0x11,
  567. .offset = offsetof(struct qmi_wlanfw_phy_cap_resp_msg_v01,
  568. board_id_valid),
  569. },
  570. {
  571. .data_type = QMI_UNSIGNED_4_BYTE,
  572. .elem_len = 1,
  573. .elem_size = sizeof(u32),
  574. .array_type = NO_ARRAY,
  575. .tlv_type = 0x11,
  576. .offset = offsetof(struct qmi_wlanfw_phy_cap_resp_msg_v01,
  577. board_id),
  578. },
  579. {
  580. .data_type = QMI_OPT_FLAG,
  581. .elem_len = 1,
  582. .elem_size = sizeof(u8),
  583. .array_type = NO_ARRAY,
  584. .tlv_type = 0x13,
  585. .offset = offsetof(struct qmi_wlanfw_phy_cap_resp_msg_v01,
  586. single_chip_mlo_support_valid),
  587. },
  588. {
  589. .data_type = QMI_UNSIGNED_1_BYTE,
  590. .elem_len = 1,
  591. .elem_size = sizeof(u8),
  592. .array_type = NO_ARRAY,
  593. .tlv_type = 0x13,
  594. .offset = offsetof(struct qmi_wlanfw_phy_cap_resp_msg_v01,
  595. single_chip_mlo_support),
  596. },
  597. {
  598. .data_type = QMI_EOTI,
  599. .array_type = NO_ARRAY,
  600. .tlv_type = QMI_COMMON_TLV_TYPE,
  601. },
  602. };
  603. static const struct qmi_elem_info qmi_wlanfw_ind_register_req_msg_v01_ei[] = {
  604. {
  605. .data_type = QMI_OPT_FLAG,
  606. .elem_len = 1,
  607. .elem_size = sizeof(u8),
  608. .array_type = NO_ARRAY,
  609. .tlv_type = 0x10,
  610. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  611. fw_ready_enable_valid),
  612. },
  613. {
  614. .data_type = QMI_UNSIGNED_1_BYTE,
  615. .elem_len = 1,
  616. .elem_size = sizeof(u8),
  617. .array_type = NO_ARRAY,
  618. .tlv_type = 0x10,
  619. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  620. fw_ready_enable),
  621. },
  622. {
  623. .data_type = QMI_OPT_FLAG,
  624. .elem_len = 1,
  625. .elem_size = sizeof(u8),
  626. .array_type = NO_ARRAY,
  627. .tlv_type = 0x11,
  628. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  629. initiate_cal_download_enable_valid),
  630. },
  631. {
  632. .data_type = QMI_UNSIGNED_1_BYTE,
  633. .elem_len = 1,
  634. .elem_size = sizeof(u8),
  635. .array_type = NO_ARRAY,
  636. .tlv_type = 0x11,
  637. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  638. initiate_cal_download_enable),
  639. },
  640. {
  641. .data_type = QMI_OPT_FLAG,
  642. .elem_len = 1,
  643. .elem_size = sizeof(u8),
  644. .array_type = NO_ARRAY,
  645. .tlv_type = 0x12,
  646. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  647. initiate_cal_update_enable_valid),
  648. },
  649. {
  650. .data_type = QMI_UNSIGNED_1_BYTE,
  651. .elem_len = 1,
  652. .elem_size = sizeof(u8),
  653. .array_type = NO_ARRAY,
  654. .tlv_type = 0x12,
  655. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  656. initiate_cal_update_enable),
  657. },
  658. {
  659. .data_type = QMI_OPT_FLAG,
  660. .elem_len = 1,
  661. .elem_size = sizeof(u8),
  662. .array_type = NO_ARRAY,
  663. .tlv_type = 0x13,
  664. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  665. msa_ready_enable_valid),
  666. },
  667. {
  668. .data_type = QMI_UNSIGNED_1_BYTE,
  669. .elem_len = 1,
  670. .elem_size = sizeof(u8),
  671. .array_type = NO_ARRAY,
  672. .tlv_type = 0x13,
  673. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  674. msa_ready_enable),
  675. },
  676. {
  677. .data_type = QMI_OPT_FLAG,
  678. .elem_len = 1,
  679. .elem_size = sizeof(u8),
  680. .array_type = NO_ARRAY,
  681. .tlv_type = 0x14,
  682. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  683. pin_connect_result_enable_valid),
  684. },
  685. {
  686. .data_type = QMI_UNSIGNED_1_BYTE,
  687. .elem_len = 1,
  688. .elem_size = sizeof(u8),
  689. .array_type = NO_ARRAY,
  690. .tlv_type = 0x14,
  691. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  692. pin_connect_result_enable),
  693. },
  694. {
  695. .data_type = QMI_OPT_FLAG,
  696. .elem_len = 1,
  697. .elem_size = sizeof(u8),
  698. .array_type = NO_ARRAY,
  699. .tlv_type = 0x15,
  700. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  701. client_id_valid),
  702. },
  703. {
  704. .data_type = QMI_UNSIGNED_4_BYTE,
  705. .elem_len = 1,
  706. .elem_size = sizeof(u32),
  707. .array_type = NO_ARRAY,
  708. .tlv_type = 0x15,
  709. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  710. client_id),
  711. },
  712. {
  713. .data_type = QMI_OPT_FLAG,
  714. .elem_len = 1,
  715. .elem_size = sizeof(u8),
  716. .array_type = NO_ARRAY,
  717. .tlv_type = 0x16,
  718. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  719. request_mem_enable_valid),
  720. },
  721. {
  722. .data_type = QMI_UNSIGNED_1_BYTE,
  723. .elem_len = 1,
  724. .elem_size = sizeof(u8),
  725. .array_type = NO_ARRAY,
  726. .tlv_type = 0x16,
  727. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  728. request_mem_enable),
  729. },
  730. {
  731. .data_type = QMI_OPT_FLAG,
  732. .elem_len = 1,
  733. .elem_size = sizeof(u8),
  734. .array_type = NO_ARRAY,
  735. .tlv_type = 0x17,
  736. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  737. fw_mem_ready_enable_valid),
  738. },
  739. {
  740. .data_type = QMI_UNSIGNED_1_BYTE,
  741. .elem_len = 1,
  742. .elem_size = sizeof(u8),
  743. .array_type = NO_ARRAY,
  744. .tlv_type = 0x17,
  745. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  746. fw_mem_ready_enable),
  747. },
  748. {
  749. .data_type = QMI_OPT_FLAG,
  750. .elem_len = 1,
  751. .elem_size = sizeof(u8),
  752. .array_type = NO_ARRAY,
  753. .tlv_type = 0x18,
  754. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  755. fw_init_done_enable_valid),
  756. },
  757. {
  758. .data_type = QMI_UNSIGNED_1_BYTE,
  759. .elem_len = 1,
  760. .elem_size = sizeof(u8),
  761. .array_type = NO_ARRAY,
  762. .tlv_type = 0x18,
  763. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  764. fw_init_done_enable),
  765. },
  766. {
  767. .data_type = QMI_OPT_FLAG,
  768. .elem_len = 1,
  769. .elem_size = sizeof(u8),
  770. .array_type = NO_ARRAY,
  771. .tlv_type = 0x19,
  772. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  773. rejuvenate_enable_valid),
  774. },
  775. {
  776. .data_type = QMI_UNSIGNED_1_BYTE,
  777. .elem_len = 1,
  778. .elem_size = sizeof(u8),
  779. .array_type = NO_ARRAY,
  780. .tlv_type = 0x19,
  781. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  782. rejuvenate_enable),
  783. },
  784. {
  785. .data_type = QMI_OPT_FLAG,
  786. .elem_len = 1,
  787. .elem_size = sizeof(u8),
  788. .array_type = NO_ARRAY,
  789. .tlv_type = 0x1A,
  790. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  791. xo_cal_enable_valid),
  792. },
  793. {
  794. .data_type = QMI_UNSIGNED_1_BYTE,
  795. .elem_len = 1,
  796. .elem_size = sizeof(u8),
  797. .array_type = NO_ARRAY,
  798. .tlv_type = 0x1A,
  799. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  800. xo_cal_enable),
  801. },
  802. {
  803. .data_type = QMI_OPT_FLAG,
  804. .elem_len = 1,
  805. .elem_size = sizeof(u8),
  806. .array_type = NO_ARRAY,
  807. .tlv_type = 0x1B,
  808. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  809. cal_done_enable_valid),
  810. },
  811. {
  812. .data_type = QMI_UNSIGNED_1_BYTE,
  813. .elem_len = 1,
  814. .elem_size = sizeof(u8),
  815. .array_type = NO_ARRAY,
  816. .tlv_type = 0x1B,
  817. .offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
  818. cal_done_enable),
  819. },
  820. {
  821. .data_type = QMI_EOTI,
  822. .array_type = NO_ARRAY,
  823. .tlv_type = QMI_COMMON_TLV_TYPE,
  824. },
  825. };
  826. static const struct qmi_elem_info qmi_wlanfw_ind_register_resp_msg_v01_ei[] = {
  827. {
  828. .data_type = QMI_STRUCT,
  829. .elem_len = 1,
  830. .elem_size = sizeof(struct qmi_response_type_v01),
  831. .array_type = NO_ARRAY,
  832. .tlv_type = 0x02,
  833. .offset = offsetof(struct qmi_wlanfw_ind_register_resp_msg_v01,
  834. resp),
  835. .ei_array = qmi_response_type_v01_ei,
  836. },
  837. {
  838. .data_type = QMI_OPT_FLAG,
  839. .elem_len = 1,
  840. .elem_size = sizeof(u8),
  841. .array_type = NO_ARRAY,
  842. .tlv_type = 0x10,
  843. .offset = offsetof(struct qmi_wlanfw_ind_register_resp_msg_v01,
  844. fw_status_valid),
  845. },
  846. {
  847. .data_type = QMI_UNSIGNED_8_BYTE,
  848. .elem_len = 1,
  849. .elem_size = sizeof(u64),
  850. .array_type = NO_ARRAY,
  851. .tlv_type = 0x10,
  852. .offset = offsetof(struct qmi_wlanfw_ind_register_resp_msg_v01,
  853. fw_status),
  854. },
  855. {
  856. .data_type = QMI_EOTI,
  857. .array_type = NO_ARRAY,
  858. .tlv_type = QMI_COMMON_TLV_TYPE,
  859. },
  860. };
  861. static const struct qmi_elem_info qmi_wlanfw_mem_cfg_s_v01_ei[] = {
  862. {
  863. .data_type = QMI_UNSIGNED_8_BYTE,
  864. .elem_len = 1,
  865. .elem_size = sizeof(u64),
  866. .array_type = NO_ARRAY,
  867. .tlv_type = 0,
  868. .offset = offsetof(struct qmi_wlanfw_mem_cfg_s_v01, offset),
  869. },
  870. {
  871. .data_type = QMI_UNSIGNED_4_BYTE,
  872. .elem_len = 1,
  873. .elem_size = sizeof(u32),
  874. .array_type = NO_ARRAY,
  875. .tlv_type = 0,
  876. .offset = offsetof(struct qmi_wlanfw_mem_cfg_s_v01, size),
  877. },
  878. {
  879. .data_type = QMI_UNSIGNED_1_BYTE,
  880. .elem_len = 1,
  881. .elem_size = sizeof(u8),
  882. .array_type = NO_ARRAY,
  883. .tlv_type = 0,
  884. .offset = offsetof(struct qmi_wlanfw_mem_cfg_s_v01, secure_flag),
  885. },
  886. {
  887. .data_type = QMI_EOTI,
  888. .array_type = NO_ARRAY,
  889. .tlv_type = QMI_COMMON_TLV_TYPE,
  890. },
  891. };
  892. static const struct qmi_elem_info qmi_wlanfw_mem_seg_s_v01_ei[] = {
  893. {
  894. .data_type = QMI_UNSIGNED_4_BYTE,
  895. .elem_len = 1,
  896. .elem_size = sizeof(u32),
  897. .array_type = NO_ARRAY,
  898. .tlv_type = 0,
  899. .offset = offsetof(struct qmi_wlanfw_mem_seg_s_v01,
  900. size),
  901. },
  902. {
  903. .data_type = QMI_SIGNED_4_BYTE_ENUM,
  904. .elem_len = 1,
  905. .elem_size = sizeof(enum qmi_wlanfw_mem_type_enum_v01),
  906. .array_type = NO_ARRAY,
  907. .tlv_type = 0,
  908. .offset = offsetof(struct qmi_wlanfw_mem_seg_s_v01, type),
  909. },
  910. {
  911. .data_type = QMI_DATA_LEN,
  912. .elem_len = 1,
  913. .elem_size = sizeof(u8),
  914. .array_type = NO_ARRAY,
  915. .tlv_type = 0,
  916. .offset = offsetof(struct qmi_wlanfw_mem_seg_s_v01, mem_cfg_len),
  917. },
  918. {
  919. .data_type = QMI_STRUCT,
  920. .elem_len = QMI_WLANFW_MAX_NUM_MEM_CFG_V01,
  921. .elem_size = sizeof(struct qmi_wlanfw_mem_cfg_s_v01),
  922. .array_type = VAR_LEN_ARRAY,
  923. .tlv_type = 0,
  924. .offset = offsetof(struct qmi_wlanfw_mem_seg_s_v01, mem_cfg),
  925. .ei_array = qmi_wlanfw_mem_cfg_s_v01_ei,
  926. },
  927. {
  928. .data_type = QMI_EOTI,
  929. .array_type = NO_ARRAY,
  930. .tlv_type = QMI_COMMON_TLV_TYPE,
  931. },
  932. };
  933. static const struct qmi_elem_info qmi_wlanfw_request_mem_ind_msg_v01_ei[] = {
  934. {
  935. .data_type = QMI_DATA_LEN,
  936. .elem_len = 1,
  937. .elem_size = sizeof(u8),
  938. .array_type = NO_ARRAY,
  939. .tlv_type = 0x01,
  940. .offset = offsetof(struct qmi_wlanfw_request_mem_ind_msg_v01,
  941. mem_seg_len),
  942. },
  943. {
  944. .data_type = QMI_STRUCT,
  945. .elem_len = ATH12K_QMI_WLANFW_MAX_NUM_MEM_SEG_V01,
  946. .elem_size = sizeof(struct qmi_wlanfw_mem_seg_s_v01),
  947. .array_type = VAR_LEN_ARRAY,
  948. .tlv_type = 0x01,
  949. .offset = offsetof(struct qmi_wlanfw_request_mem_ind_msg_v01,
  950. mem_seg),
  951. .ei_array = qmi_wlanfw_mem_seg_s_v01_ei,
  952. },
  953. {
  954. .data_type = QMI_EOTI,
  955. .array_type = NO_ARRAY,
  956. .tlv_type = QMI_COMMON_TLV_TYPE,
  957. },
  958. };
  959. static const struct qmi_elem_info qmi_wlanfw_mem_seg_resp_s_v01_ei[] = {
  960. {
  961. .data_type = QMI_UNSIGNED_8_BYTE,
  962. .elem_len = 1,
  963. .elem_size = sizeof(u64),
  964. .array_type = NO_ARRAY,
  965. .tlv_type = 0,
  966. .offset = offsetof(struct qmi_wlanfw_mem_seg_resp_s_v01, addr),
  967. },
  968. {
  969. .data_type = QMI_UNSIGNED_4_BYTE,
  970. .elem_len = 1,
  971. .elem_size = sizeof(u32),
  972. .array_type = NO_ARRAY,
  973. .tlv_type = 0,
  974. .offset = offsetof(struct qmi_wlanfw_mem_seg_resp_s_v01, size),
  975. },
  976. {
  977. .data_type = QMI_SIGNED_4_BYTE_ENUM,
  978. .elem_len = 1,
  979. .elem_size = sizeof(enum qmi_wlanfw_mem_type_enum_v01),
  980. .array_type = NO_ARRAY,
  981. .tlv_type = 0,
  982. .offset = offsetof(struct qmi_wlanfw_mem_seg_resp_s_v01, type),
  983. },
  984. {
  985. .data_type = QMI_UNSIGNED_1_BYTE,
  986. .elem_len = 1,
  987. .elem_size = sizeof(u8),
  988. .array_type = NO_ARRAY,
  989. .tlv_type = 0,
  990. .offset = offsetof(struct qmi_wlanfw_mem_seg_resp_s_v01, restore),
  991. },
  992. {
  993. .data_type = QMI_EOTI,
  994. .array_type = NO_ARRAY,
  995. .tlv_type = QMI_COMMON_TLV_TYPE,
  996. },
  997. };
  998. static const struct qmi_elem_info qmi_wlanfw_respond_mem_req_msg_v01_ei[] = {
  999. {
  1000. .data_type = QMI_DATA_LEN,
  1001. .elem_len = 1,
  1002. .elem_size = sizeof(u8),
  1003. .array_type = NO_ARRAY,
  1004. .tlv_type = 0x01,
  1005. .offset = offsetof(struct qmi_wlanfw_respond_mem_req_msg_v01,
  1006. mem_seg_len),
  1007. },
  1008. {
  1009. .data_type = QMI_STRUCT,
  1010. .elem_len = ATH12K_QMI_WLANFW_MAX_NUM_MEM_SEG_V01,
  1011. .elem_size = sizeof(struct qmi_wlanfw_mem_seg_resp_s_v01),
  1012. .array_type = VAR_LEN_ARRAY,
  1013. .tlv_type = 0x01,
  1014. .offset = offsetof(struct qmi_wlanfw_respond_mem_req_msg_v01,
  1015. mem_seg),
  1016. .ei_array = qmi_wlanfw_mem_seg_resp_s_v01_ei,
  1017. },
  1018. {
  1019. .data_type = QMI_EOTI,
  1020. .array_type = NO_ARRAY,
  1021. .tlv_type = QMI_COMMON_TLV_TYPE,
  1022. },
  1023. };
  1024. static const struct qmi_elem_info qmi_wlanfw_respond_mem_resp_msg_v01_ei[] = {
  1025. {
  1026. .data_type = QMI_STRUCT,
  1027. .elem_len = 1,
  1028. .elem_size = sizeof(struct qmi_response_type_v01),
  1029. .array_type = NO_ARRAY,
  1030. .tlv_type = 0x02,
  1031. .offset = offsetof(struct qmi_wlanfw_respond_mem_resp_msg_v01,
  1032. resp),
  1033. .ei_array = qmi_response_type_v01_ei,
  1034. },
  1035. {
  1036. .data_type = QMI_EOTI,
  1037. .array_type = NO_ARRAY,
  1038. .tlv_type = QMI_COMMON_TLV_TYPE,
  1039. },
  1040. };
  1041. static const struct qmi_elem_info qmi_wlanfw_cap_req_msg_v01_ei[] = {
  1042. {
  1043. .data_type = QMI_EOTI,
  1044. .array_type = NO_ARRAY,
  1045. .tlv_type = QMI_COMMON_TLV_TYPE,
  1046. },
  1047. };
  1048. static const struct qmi_elem_info qmi_wlanfw_rf_chip_info_s_v01_ei[] = {
  1049. {
  1050. .data_type = QMI_UNSIGNED_4_BYTE,
  1051. .elem_len = 1,
  1052. .elem_size = sizeof(u32),
  1053. .array_type = NO_ARRAY,
  1054. .tlv_type = 0,
  1055. .offset = offsetof(struct qmi_wlanfw_rf_chip_info_s_v01,
  1056. chip_id),
  1057. },
  1058. {
  1059. .data_type = QMI_UNSIGNED_4_BYTE,
  1060. .elem_len = 1,
  1061. .elem_size = sizeof(u32),
  1062. .array_type = NO_ARRAY,
  1063. .tlv_type = 0,
  1064. .offset = offsetof(struct qmi_wlanfw_rf_chip_info_s_v01,
  1065. chip_family),
  1066. },
  1067. {
  1068. .data_type = QMI_EOTI,
  1069. .array_type = NO_ARRAY,
  1070. .tlv_type = QMI_COMMON_TLV_TYPE,
  1071. },
  1072. };
  1073. static const struct qmi_elem_info qmi_wlanfw_rf_board_info_s_v01_ei[] = {
  1074. {
  1075. .data_type = QMI_UNSIGNED_4_BYTE,
  1076. .elem_len = 1,
  1077. .elem_size = sizeof(u32),
  1078. .array_type = NO_ARRAY,
  1079. .tlv_type = 0,
  1080. .offset = offsetof(struct qmi_wlanfw_rf_board_info_s_v01,
  1081. board_id),
  1082. },
  1083. {
  1084. .data_type = QMI_EOTI,
  1085. .array_type = NO_ARRAY,
  1086. .tlv_type = QMI_COMMON_TLV_TYPE,
  1087. },
  1088. };
  1089. static const struct qmi_elem_info qmi_wlanfw_soc_info_s_v01_ei[] = {
  1090. {
  1091. .data_type = QMI_UNSIGNED_4_BYTE,
  1092. .elem_len = 1,
  1093. .elem_size = sizeof(u32),
  1094. .array_type = NO_ARRAY,
  1095. .tlv_type = 0,
  1096. .offset = offsetof(struct qmi_wlanfw_soc_info_s_v01, soc_id),
  1097. },
  1098. {
  1099. .data_type = QMI_EOTI,
  1100. .array_type = NO_ARRAY,
  1101. .tlv_type = QMI_COMMON_TLV_TYPE,
  1102. },
  1103. };
  1104. static const struct qmi_elem_info qmi_wlanfw_dev_mem_info_s_v01_ei[] = {
  1105. {
  1106. .data_type = QMI_UNSIGNED_8_BYTE,
  1107. .elem_len = 1,
  1108. .elem_size = sizeof(u64),
  1109. .array_type = NO_ARRAY,
  1110. .tlv_type = 0,
  1111. .offset = offsetof(struct qmi_wlanfw_dev_mem_info_s_v01,
  1112. start),
  1113. },
  1114. {
  1115. .data_type = QMI_UNSIGNED_8_BYTE,
  1116. .elem_len = 1,
  1117. .elem_size = sizeof(u64),
  1118. .array_type = NO_ARRAY,
  1119. .tlv_type = 0,
  1120. .offset = offsetof(struct qmi_wlanfw_dev_mem_info_s_v01,
  1121. size),
  1122. },
  1123. {
  1124. .data_type = QMI_EOTI,
  1125. .array_type = NO_ARRAY,
  1126. .tlv_type = QMI_COMMON_TLV_TYPE,
  1127. },
  1128. };
  1129. static const struct qmi_elem_info qmi_wlanfw_fw_version_info_s_v01_ei[] = {
  1130. {
  1131. .data_type = QMI_UNSIGNED_4_BYTE,
  1132. .elem_len = 1,
  1133. .elem_size = sizeof(u32),
  1134. .array_type = NO_ARRAY,
  1135. .tlv_type = 0,
  1136. .offset = offsetof(struct qmi_wlanfw_fw_version_info_s_v01,
  1137. fw_version),
  1138. },
  1139. {
  1140. .data_type = QMI_STRING,
  1141. .elem_len = ATH12K_QMI_WLANFW_MAX_TIMESTAMP_LEN_V01 + 1,
  1142. .elem_size = sizeof(char),
  1143. .array_type = NO_ARRAY,
  1144. .tlv_type = 0,
  1145. .offset = offsetof(struct qmi_wlanfw_fw_version_info_s_v01,
  1146. fw_build_timestamp),
  1147. },
  1148. {
  1149. .data_type = QMI_EOTI,
  1150. .array_type = NO_ARRAY,
  1151. .tlv_type = QMI_COMMON_TLV_TYPE,
  1152. },
  1153. };
  1154. static const struct qmi_elem_info qmi_wlanfw_cap_resp_msg_v01_ei[] = {
  1155. {
  1156. .data_type = QMI_STRUCT,
  1157. .elem_len = 1,
  1158. .elem_size = sizeof(struct qmi_response_type_v01),
  1159. .array_type = NO_ARRAY,
  1160. .tlv_type = 0x02,
  1161. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01, resp),
  1162. .ei_array = qmi_response_type_v01_ei,
  1163. },
  1164. {
  1165. .data_type = QMI_OPT_FLAG,
  1166. .elem_len = 1,
  1167. .elem_size = sizeof(u8),
  1168. .array_type = NO_ARRAY,
  1169. .tlv_type = 0x10,
  1170. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1171. chip_info_valid),
  1172. },
  1173. {
  1174. .data_type = QMI_STRUCT,
  1175. .elem_len = 1,
  1176. .elem_size = sizeof(struct qmi_wlanfw_rf_chip_info_s_v01),
  1177. .array_type = NO_ARRAY,
  1178. .tlv_type = 0x10,
  1179. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1180. chip_info),
  1181. .ei_array = qmi_wlanfw_rf_chip_info_s_v01_ei,
  1182. },
  1183. {
  1184. .data_type = QMI_OPT_FLAG,
  1185. .elem_len = 1,
  1186. .elem_size = sizeof(u8),
  1187. .array_type = NO_ARRAY,
  1188. .tlv_type = 0x11,
  1189. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1190. board_info_valid),
  1191. },
  1192. {
  1193. .data_type = QMI_STRUCT,
  1194. .elem_len = 1,
  1195. .elem_size = sizeof(struct qmi_wlanfw_rf_board_info_s_v01),
  1196. .array_type = NO_ARRAY,
  1197. .tlv_type = 0x11,
  1198. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1199. board_info),
  1200. .ei_array = qmi_wlanfw_rf_board_info_s_v01_ei,
  1201. },
  1202. {
  1203. .data_type = QMI_OPT_FLAG,
  1204. .elem_len = 1,
  1205. .elem_size = sizeof(u8),
  1206. .array_type = NO_ARRAY,
  1207. .tlv_type = 0x12,
  1208. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1209. soc_info_valid),
  1210. },
  1211. {
  1212. .data_type = QMI_STRUCT,
  1213. .elem_len = 1,
  1214. .elem_size = sizeof(struct qmi_wlanfw_soc_info_s_v01),
  1215. .array_type = NO_ARRAY,
  1216. .tlv_type = 0x12,
  1217. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1218. soc_info),
  1219. .ei_array = qmi_wlanfw_soc_info_s_v01_ei,
  1220. },
  1221. {
  1222. .data_type = QMI_OPT_FLAG,
  1223. .elem_len = 1,
  1224. .elem_size = sizeof(u8),
  1225. .array_type = NO_ARRAY,
  1226. .tlv_type = 0x13,
  1227. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1228. fw_version_info_valid),
  1229. },
  1230. {
  1231. .data_type = QMI_STRUCT,
  1232. .elem_len = 1,
  1233. .elem_size = sizeof(struct qmi_wlanfw_fw_version_info_s_v01),
  1234. .array_type = NO_ARRAY,
  1235. .tlv_type = 0x13,
  1236. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1237. fw_version_info),
  1238. .ei_array = qmi_wlanfw_fw_version_info_s_v01_ei,
  1239. },
  1240. {
  1241. .data_type = QMI_OPT_FLAG,
  1242. .elem_len = 1,
  1243. .elem_size = sizeof(u8),
  1244. .array_type = NO_ARRAY,
  1245. .tlv_type = 0x14,
  1246. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1247. fw_build_id_valid),
  1248. },
  1249. {
  1250. .data_type = QMI_STRING,
  1251. .elem_len = ATH12K_QMI_WLANFW_MAX_BUILD_ID_LEN_V01 + 1,
  1252. .elem_size = sizeof(char),
  1253. .array_type = NO_ARRAY,
  1254. .tlv_type = 0x14,
  1255. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1256. fw_build_id),
  1257. },
  1258. {
  1259. .data_type = QMI_OPT_FLAG,
  1260. .elem_len = 1,
  1261. .elem_size = sizeof(u8),
  1262. .array_type = NO_ARRAY,
  1263. .tlv_type = 0x15,
  1264. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1265. num_macs_valid),
  1266. },
  1267. {
  1268. .data_type = QMI_UNSIGNED_1_BYTE,
  1269. .elem_len = 1,
  1270. .elem_size = sizeof(u8),
  1271. .array_type = NO_ARRAY,
  1272. .tlv_type = 0x15,
  1273. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1274. num_macs),
  1275. },
  1276. {
  1277. .data_type = QMI_OPT_FLAG,
  1278. .elem_len = 1,
  1279. .elem_size = sizeof(u8),
  1280. .array_type = NO_ARRAY,
  1281. .tlv_type = 0x16,
  1282. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1283. voltage_mv_valid),
  1284. },
  1285. {
  1286. .data_type = QMI_UNSIGNED_4_BYTE,
  1287. .elem_len = 1,
  1288. .elem_size = sizeof(u32),
  1289. .array_type = NO_ARRAY,
  1290. .tlv_type = 0x16,
  1291. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1292. voltage_mv),
  1293. },
  1294. {
  1295. .data_type = QMI_OPT_FLAG,
  1296. .elem_len = 1,
  1297. .elem_size = sizeof(u8),
  1298. .array_type = NO_ARRAY,
  1299. .tlv_type = 0x17,
  1300. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1301. time_freq_hz_valid),
  1302. },
  1303. {
  1304. .data_type = QMI_UNSIGNED_4_BYTE,
  1305. .elem_len = 1,
  1306. .elem_size = sizeof(u32),
  1307. .array_type = NO_ARRAY,
  1308. .tlv_type = 0x17,
  1309. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1310. time_freq_hz),
  1311. },
  1312. {
  1313. .data_type = QMI_OPT_FLAG,
  1314. .elem_len = 1,
  1315. .elem_size = sizeof(u8),
  1316. .array_type = NO_ARRAY,
  1317. .tlv_type = 0x18,
  1318. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1319. otp_version_valid),
  1320. },
  1321. {
  1322. .data_type = QMI_UNSIGNED_4_BYTE,
  1323. .elem_len = 1,
  1324. .elem_size = sizeof(u32),
  1325. .array_type = NO_ARRAY,
  1326. .tlv_type = 0x18,
  1327. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1328. otp_version),
  1329. },
  1330. {
  1331. .data_type = QMI_OPT_FLAG,
  1332. .elem_len = 1,
  1333. .elem_size = sizeof(u8),
  1334. .array_type = NO_ARRAY,
  1335. .tlv_type = 0x19,
  1336. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1337. eeprom_caldata_read_timeout_valid),
  1338. },
  1339. {
  1340. .data_type = QMI_UNSIGNED_4_BYTE,
  1341. .elem_len = 1,
  1342. .elem_size = sizeof(u32),
  1343. .array_type = NO_ARRAY,
  1344. .tlv_type = 0x19,
  1345. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1346. eeprom_caldata_read_timeout),
  1347. },
  1348. {
  1349. .data_type = QMI_OPT_FLAG,
  1350. .elem_len = 1,
  1351. .elem_size = sizeof(u8),
  1352. .array_type = NO_ARRAY,
  1353. .tlv_type = 0x1A,
  1354. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1355. fw_caps_valid),
  1356. },
  1357. {
  1358. .data_type = QMI_UNSIGNED_8_BYTE,
  1359. .elem_len = 1,
  1360. .elem_size = sizeof(u64),
  1361. .array_type = NO_ARRAY,
  1362. .tlv_type = 0x1A,
  1363. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01, fw_caps),
  1364. },
  1365. {
  1366. .data_type = QMI_OPT_FLAG,
  1367. .elem_len = 1,
  1368. .elem_size = sizeof(u8),
  1369. .array_type = NO_ARRAY,
  1370. .tlv_type = 0x1B,
  1371. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1372. rd_card_chain_cap_valid),
  1373. },
  1374. {
  1375. .data_type = QMI_UNSIGNED_4_BYTE,
  1376. .elem_len = 1,
  1377. .elem_size = sizeof(u32),
  1378. .array_type = NO_ARRAY,
  1379. .tlv_type = 0x1B,
  1380. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1381. rd_card_chain_cap),
  1382. },
  1383. {
  1384. .data_type = QMI_OPT_FLAG,
  1385. .elem_len = 1,
  1386. .elem_size = sizeof(u8),
  1387. .array_type = NO_ARRAY,
  1388. .tlv_type = 0x1C,
  1389. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
  1390. dev_mem_info_valid),
  1391. },
  1392. {
  1393. .data_type = QMI_STRUCT,
  1394. .elem_len = ATH12K_QMI_WLFW_MAX_DEV_MEM_NUM_V01,
  1395. .elem_size = sizeof(struct qmi_wlanfw_dev_mem_info_s_v01),
  1396. .array_type = STATIC_ARRAY,
  1397. .tlv_type = 0x1C,
  1398. .offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01, dev_mem),
  1399. .ei_array = qmi_wlanfw_dev_mem_info_s_v01_ei,
  1400. },
  1401. {
  1402. .data_type = QMI_EOTI,
  1403. .array_type = NO_ARRAY,
  1404. .tlv_type = QMI_COMMON_TLV_TYPE,
  1405. },
  1406. };
  1407. static const struct qmi_elem_info qmi_wlanfw_bdf_download_req_msg_v01_ei[] = {
  1408. {
  1409. .data_type = QMI_UNSIGNED_1_BYTE,
  1410. .elem_len = 1,
  1411. .elem_size = sizeof(u8),
  1412. .array_type = NO_ARRAY,
  1413. .tlv_type = 0x01,
  1414. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1415. valid),
  1416. },
  1417. {
  1418. .data_type = QMI_OPT_FLAG,
  1419. .elem_len = 1,
  1420. .elem_size = sizeof(u8),
  1421. .array_type = NO_ARRAY,
  1422. .tlv_type = 0x10,
  1423. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1424. file_id_valid),
  1425. },
  1426. {
  1427. .data_type = QMI_SIGNED_4_BYTE_ENUM,
  1428. .elem_len = 1,
  1429. .elem_size = sizeof(enum qmi_wlanfw_cal_temp_id_enum_v01),
  1430. .array_type = NO_ARRAY,
  1431. .tlv_type = 0x10,
  1432. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1433. file_id),
  1434. },
  1435. {
  1436. .data_type = QMI_OPT_FLAG,
  1437. .elem_len = 1,
  1438. .elem_size = sizeof(u8),
  1439. .array_type = NO_ARRAY,
  1440. .tlv_type = 0x11,
  1441. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1442. total_size_valid),
  1443. },
  1444. {
  1445. .data_type = QMI_UNSIGNED_4_BYTE,
  1446. .elem_len = 1,
  1447. .elem_size = sizeof(u32),
  1448. .array_type = NO_ARRAY,
  1449. .tlv_type = 0x11,
  1450. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1451. total_size),
  1452. },
  1453. {
  1454. .data_type = QMI_OPT_FLAG,
  1455. .elem_len = 1,
  1456. .elem_size = sizeof(u8),
  1457. .array_type = NO_ARRAY,
  1458. .tlv_type = 0x12,
  1459. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1460. seg_id_valid),
  1461. },
  1462. {
  1463. .data_type = QMI_UNSIGNED_4_BYTE,
  1464. .elem_len = 1,
  1465. .elem_size = sizeof(u32),
  1466. .array_type = NO_ARRAY,
  1467. .tlv_type = 0x12,
  1468. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1469. seg_id),
  1470. },
  1471. {
  1472. .data_type = QMI_OPT_FLAG,
  1473. .elem_len = 1,
  1474. .elem_size = sizeof(u8),
  1475. .array_type = NO_ARRAY,
  1476. .tlv_type = 0x13,
  1477. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1478. data_valid),
  1479. },
  1480. {
  1481. .data_type = QMI_DATA_LEN,
  1482. .elem_len = 1,
  1483. .elem_size = sizeof(u16),
  1484. .array_type = NO_ARRAY,
  1485. .tlv_type = 0x13,
  1486. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1487. data_len),
  1488. },
  1489. {
  1490. .data_type = QMI_UNSIGNED_1_BYTE,
  1491. .elem_len = QMI_WLANFW_MAX_DATA_SIZE_V01,
  1492. .elem_size = sizeof(u8),
  1493. .array_type = VAR_LEN_ARRAY,
  1494. .tlv_type = 0x13,
  1495. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1496. data),
  1497. },
  1498. {
  1499. .data_type = QMI_OPT_FLAG,
  1500. .elem_len = 1,
  1501. .elem_size = sizeof(u8),
  1502. .array_type = NO_ARRAY,
  1503. .tlv_type = 0x14,
  1504. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1505. end_valid),
  1506. },
  1507. {
  1508. .data_type = QMI_UNSIGNED_1_BYTE,
  1509. .elem_len = 1,
  1510. .elem_size = sizeof(u8),
  1511. .array_type = NO_ARRAY,
  1512. .tlv_type = 0x14,
  1513. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1514. end),
  1515. },
  1516. {
  1517. .data_type = QMI_OPT_FLAG,
  1518. .elem_len = 1,
  1519. .elem_size = sizeof(u8),
  1520. .array_type = NO_ARRAY,
  1521. .tlv_type = 0x15,
  1522. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1523. bdf_type_valid),
  1524. },
  1525. {
  1526. .data_type = QMI_UNSIGNED_1_BYTE,
  1527. .elem_len = 1,
  1528. .elem_size = sizeof(u8),
  1529. .array_type = NO_ARRAY,
  1530. .tlv_type = 0x15,
  1531. .offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
  1532. bdf_type),
  1533. },
  1534. {
  1535. .data_type = QMI_EOTI,
  1536. .array_type = NO_ARRAY,
  1537. .tlv_type = QMI_COMMON_TLV_TYPE,
  1538. },
  1539. };
  1540. static const struct qmi_elem_info qmi_wlanfw_bdf_download_resp_msg_v01_ei[] = {
  1541. {
  1542. .data_type = QMI_STRUCT,
  1543. .elem_len = 1,
  1544. .elem_size = sizeof(struct qmi_response_type_v01),
  1545. .array_type = NO_ARRAY,
  1546. .tlv_type = 0x02,
  1547. .offset = offsetof(struct qmi_wlanfw_bdf_download_resp_msg_v01,
  1548. resp),
  1549. .ei_array = qmi_response_type_v01_ei,
  1550. },
  1551. {
  1552. .data_type = QMI_EOTI,
  1553. .array_type = NO_ARRAY,
  1554. .tlv_type = QMI_COMMON_TLV_TYPE,
  1555. },
  1556. };
  1557. static const struct qmi_elem_info qmi_wlanfw_m3_info_req_msg_v01_ei[] = {
  1558. {
  1559. .data_type = QMI_UNSIGNED_8_BYTE,
  1560. .elem_len = 1,
  1561. .elem_size = sizeof(u64),
  1562. .array_type = NO_ARRAY,
  1563. .tlv_type = 0x01,
  1564. .offset = offsetof(struct qmi_wlanfw_m3_info_req_msg_v01, addr),
  1565. },
  1566. {
  1567. .data_type = QMI_UNSIGNED_4_BYTE,
  1568. .elem_len = 1,
  1569. .elem_size = sizeof(u32),
  1570. .array_type = NO_ARRAY,
  1571. .tlv_type = 0x02,
  1572. .offset = offsetof(struct qmi_wlanfw_m3_info_req_msg_v01, size),
  1573. },
  1574. {
  1575. .data_type = QMI_EOTI,
  1576. .array_type = NO_ARRAY,
  1577. .tlv_type = QMI_COMMON_TLV_TYPE,
  1578. },
  1579. };
  1580. static const struct qmi_elem_info qmi_wlanfw_m3_info_resp_msg_v01_ei[] = {
  1581. {
  1582. .data_type = QMI_STRUCT,
  1583. .elem_len = 1,
  1584. .elem_size = sizeof(struct qmi_response_type_v01),
  1585. .array_type = NO_ARRAY,
  1586. .tlv_type = 0x02,
  1587. .offset = offsetof(struct qmi_wlanfw_m3_info_resp_msg_v01, resp),
  1588. .ei_array = qmi_response_type_v01_ei,
  1589. },
  1590. {
  1591. .data_type = QMI_EOTI,
  1592. .array_type = NO_ARRAY,
  1593. .tlv_type = QMI_COMMON_TLV_TYPE,
  1594. },
  1595. };
  1596. static const struct qmi_elem_info qmi_wlanfw_aux_uc_info_req_msg_v01_ei[] = {
  1597. {
  1598. .data_type = QMI_UNSIGNED_8_BYTE,
  1599. .elem_len = 1,
  1600. .elem_size = sizeof(u64),
  1601. .array_type = NO_ARRAY,
  1602. .tlv_type = 0x01,
  1603. .offset = offsetof(struct qmi_wlanfw_aux_uc_info_req_msg_v01, addr),
  1604. },
  1605. {
  1606. .data_type = QMI_UNSIGNED_4_BYTE,
  1607. .elem_len = 1,
  1608. .elem_size = sizeof(u32),
  1609. .array_type = NO_ARRAY,
  1610. .tlv_type = 0x02,
  1611. .offset = offsetof(struct qmi_wlanfw_aux_uc_info_req_msg_v01, size),
  1612. },
  1613. {
  1614. .data_type = QMI_EOTI,
  1615. .array_type = NO_ARRAY,
  1616. .tlv_type = QMI_COMMON_TLV_TYPE,
  1617. },
  1618. };
  1619. static const struct qmi_elem_info qmi_wlanfw_aux_uc_info_resp_msg_v01_ei[] = {
  1620. {
  1621. .data_type = QMI_STRUCT,
  1622. .elem_len = 1,
  1623. .elem_size = sizeof(struct qmi_response_type_v01),
  1624. .array_type = NO_ARRAY,
  1625. .tlv_type = 0x02,
  1626. .offset = offsetof(struct qmi_wlanfw_aux_uc_info_resp_msg_v01, resp),
  1627. .ei_array = qmi_response_type_v01_ei,
  1628. },
  1629. {
  1630. .data_type = QMI_EOTI,
  1631. .array_type = NO_ARRAY,
  1632. .tlv_type = QMI_COMMON_TLV_TYPE,
  1633. },
  1634. };
  1635. static const struct qmi_elem_info qmi_wlanfw_ce_tgt_pipe_cfg_s_v01_ei[] = {
  1636. {
  1637. .data_type = QMI_UNSIGNED_4_BYTE,
  1638. .elem_len = 1,
  1639. .elem_size = sizeof(u32),
  1640. .array_type = NO_ARRAY,
  1641. .tlv_type = 0,
  1642. .offset = offsetof(struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01,
  1643. pipe_num),
  1644. },
  1645. {
  1646. .data_type = QMI_SIGNED_4_BYTE_ENUM,
  1647. .elem_len = 1,
  1648. .elem_size = sizeof(enum qmi_wlanfw_pipedir_enum_v01),
  1649. .array_type = NO_ARRAY,
  1650. .tlv_type = 0,
  1651. .offset = offsetof(struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01,
  1652. pipe_dir),
  1653. },
  1654. {
  1655. .data_type = QMI_UNSIGNED_4_BYTE,
  1656. .elem_len = 1,
  1657. .elem_size = sizeof(u32),
  1658. .array_type = NO_ARRAY,
  1659. .tlv_type = 0,
  1660. .offset = offsetof(struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01,
  1661. nentries),
  1662. },
  1663. {
  1664. .data_type = QMI_UNSIGNED_4_BYTE,
  1665. .elem_len = 1,
  1666. .elem_size = sizeof(u32),
  1667. .array_type = NO_ARRAY,
  1668. .tlv_type = 0,
  1669. .offset = offsetof(struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01,
  1670. nbytes_max),
  1671. },
  1672. {
  1673. .data_type = QMI_UNSIGNED_4_BYTE,
  1674. .elem_len = 1,
  1675. .elem_size = sizeof(u32),
  1676. .array_type = NO_ARRAY,
  1677. .tlv_type = 0,
  1678. .offset = offsetof(struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01,
  1679. flags),
  1680. },
  1681. {
  1682. .data_type = QMI_EOTI,
  1683. .array_type = NO_ARRAY,
  1684. .tlv_type = QMI_COMMON_TLV_TYPE,
  1685. },
  1686. };
  1687. static const struct qmi_elem_info qmi_wlanfw_ce_svc_pipe_cfg_s_v01_ei[] = {
  1688. {
  1689. .data_type = QMI_UNSIGNED_4_BYTE,
  1690. .elem_len = 1,
  1691. .elem_size = sizeof(u32),
  1692. .array_type = NO_ARRAY,
  1693. .tlv_type = 0,
  1694. .offset = offsetof(struct qmi_wlanfw_ce_svc_pipe_cfg_s_v01,
  1695. service_id),
  1696. },
  1697. {
  1698. .data_type = QMI_SIGNED_4_BYTE_ENUM,
  1699. .elem_len = 1,
  1700. .elem_size = sizeof(enum qmi_wlanfw_pipedir_enum_v01),
  1701. .array_type = NO_ARRAY,
  1702. .tlv_type = 0,
  1703. .offset = offsetof(struct qmi_wlanfw_ce_svc_pipe_cfg_s_v01,
  1704. pipe_dir),
  1705. },
  1706. {
  1707. .data_type = QMI_UNSIGNED_4_BYTE,
  1708. .elem_len = 1,
  1709. .elem_size = sizeof(u32),
  1710. .array_type = NO_ARRAY,
  1711. .tlv_type = 0,
  1712. .offset = offsetof(struct qmi_wlanfw_ce_svc_pipe_cfg_s_v01,
  1713. pipe_num),
  1714. },
  1715. {
  1716. .data_type = QMI_EOTI,
  1717. .array_type = NO_ARRAY,
  1718. .tlv_type = QMI_COMMON_TLV_TYPE,
  1719. },
  1720. };
  1721. static const struct qmi_elem_info qmi_wlanfw_shadow_reg_cfg_s_v01_ei[] = {
  1722. {
  1723. .data_type = QMI_UNSIGNED_2_BYTE,
  1724. .elem_len = 1,
  1725. .elem_size = sizeof(u16),
  1726. .array_type = NO_ARRAY,
  1727. .tlv_type = 0,
  1728. .offset = offsetof(struct qmi_wlanfw_shadow_reg_cfg_s_v01, id),
  1729. },
  1730. {
  1731. .data_type = QMI_UNSIGNED_2_BYTE,
  1732. .elem_len = 1,
  1733. .elem_size = sizeof(u16),
  1734. .array_type = NO_ARRAY,
  1735. .tlv_type = 0,
  1736. .offset = offsetof(struct qmi_wlanfw_shadow_reg_cfg_s_v01,
  1737. offset),
  1738. },
  1739. {
  1740. .data_type = QMI_EOTI,
  1741. .array_type = QMI_COMMON_TLV_TYPE,
  1742. },
  1743. };
  1744. static const struct qmi_elem_info qmi_wlanfw_shadow_reg_v3_cfg_s_v01_ei[] = {
  1745. {
  1746. .data_type = QMI_UNSIGNED_4_BYTE,
  1747. .elem_len = 1,
  1748. .elem_size = sizeof(u32),
  1749. .array_type = NO_ARRAY,
  1750. .tlv_type = 0,
  1751. .offset = offsetof(struct qmi_wlanfw_shadow_reg_v3_cfg_s_v01,
  1752. addr),
  1753. },
  1754. {
  1755. .data_type = QMI_EOTI,
  1756. .array_type = NO_ARRAY,
  1757. .tlv_type = QMI_COMMON_TLV_TYPE,
  1758. },
  1759. };
  1760. static const struct qmi_elem_info qmi_wlanfw_wlan_mode_req_msg_v01_ei[] = {
  1761. {
  1762. .data_type = QMI_UNSIGNED_4_BYTE,
  1763. .elem_len = 1,
  1764. .elem_size = sizeof(u32),
  1765. .array_type = NO_ARRAY,
  1766. .tlv_type = 0x01,
  1767. .offset = offsetof(struct qmi_wlanfw_wlan_mode_req_msg_v01,
  1768. mode),
  1769. },
  1770. {
  1771. .data_type = QMI_OPT_FLAG,
  1772. .elem_len = 1,
  1773. .elem_size = sizeof(u8),
  1774. .array_type = NO_ARRAY,
  1775. .tlv_type = 0x10,
  1776. .offset = offsetof(struct qmi_wlanfw_wlan_mode_req_msg_v01,
  1777. hw_debug_valid),
  1778. },
  1779. {
  1780. .data_type = QMI_UNSIGNED_1_BYTE,
  1781. .elem_len = 1,
  1782. .elem_size = sizeof(u8),
  1783. .array_type = NO_ARRAY,
  1784. .tlv_type = 0x10,
  1785. .offset = offsetof(struct qmi_wlanfw_wlan_mode_req_msg_v01,
  1786. hw_debug),
  1787. },
  1788. {
  1789. .data_type = QMI_EOTI,
  1790. .array_type = NO_ARRAY,
  1791. .tlv_type = QMI_COMMON_TLV_TYPE,
  1792. },
  1793. };
  1794. static const struct qmi_elem_info qmi_wlanfw_wlan_mode_resp_msg_v01_ei[] = {
  1795. {
  1796. .data_type = QMI_STRUCT,
  1797. .elem_len = 1,
  1798. .elem_size = sizeof(struct qmi_response_type_v01),
  1799. .array_type = NO_ARRAY,
  1800. .tlv_type = 0x02,
  1801. .offset = offsetof(struct qmi_wlanfw_wlan_mode_resp_msg_v01,
  1802. resp),
  1803. .ei_array = qmi_response_type_v01_ei,
  1804. },
  1805. {
  1806. .data_type = QMI_EOTI,
  1807. .array_type = NO_ARRAY,
  1808. .tlv_type = QMI_COMMON_TLV_TYPE,
  1809. },
  1810. };
  1811. static const struct qmi_elem_info qmi_wlanfw_wlan_cfg_req_msg_v01_ei[] = {
  1812. {
  1813. .data_type = QMI_OPT_FLAG,
  1814. .elem_len = 1,
  1815. .elem_size = sizeof(u8),
  1816. .array_type = NO_ARRAY,
  1817. .tlv_type = 0x10,
  1818. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1819. host_version_valid),
  1820. },
  1821. {
  1822. .data_type = QMI_STRING,
  1823. .elem_len = QMI_WLANFW_MAX_STR_LEN_V01 + 1,
  1824. .elem_size = sizeof(char),
  1825. .array_type = NO_ARRAY,
  1826. .tlv_type = 0x10,
  1827. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1828. host_version),
  1829. },
  1830. {
  1831. .data_type = QMI_OPT_FLAG,
  1832. .elem_len = 1,
  1833. .elem_size = sizeof(u8),
  1834. .array_type = NO_ARRAY,
  1835. .tlv_type = 0x11,
  1836. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1837. tgt_cfg_valid),
  1838. },
  1839. {
  1840. .data_type = QMI_DATA_LEN,
  1841. .elem_len = 1,
  1842. .elem_size = sizeof(u8),
  1843. .array_type = NO_ARRAY,
  1844. .tlv_type = 0x11,
  1845. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1846. tgt_cfg_len),
  1847. },
  1848. {
  1849. .data_type = QMI_STRUCT,
  1850. .elem_len = QMI_WLANFW_MAX_NUM_CE_V01,
  1851. .elem_size = sizeof(struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01),
  1852. .array_type = VAR_LEN_ARRAY,
  1853. .tlv_type = 0x11,
  1854. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1855. tgt_cfg),
  1856. .ei_array = qmi_wlanfw_ce_tgt_pipe_cfg_s_v01_ei,
  1857. },
  1858. {
  1859. .data_type = QMI_OPT_FLAG,
  1860. .elem_len = 1,
  1861. .elem_size = sizeof(u8),
  1862. .array_type = NO_ARRAY,
  1863. .tlv_type = 0x12,
  1864. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1865. svc_cfg_valid),
  1866. },
  1867. {
  1868. .data_type = QMI_DATA_LEN,
  1869. .elem_len = 1,
  1870. .elem_size = sizeof(u8),
  1871. .array_type = NO_ARRAY,
  1872. .tlv_type = 0x12,
  1873. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1874. svc_cfg_len),
  1875. },
  1876. {
  1877. .data_type = QMI_STRUCT,
  1878. .elem_len = QMI_WLANFW_MAX_NUM_SVC_V01,
  1879. .elem_size = sizeof(struct qmi_wlanfw_ce_svc_pipe_cfg_s_v01),
  1880. .array_type = VAR_LEN_ARRAY,
  1881. .tlv_type = 0x12,
  1882. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1883. svc_cfg),
  1884. .ei_array = qmi_wlanfw_ce_svc_pipe_cfg_s_v01_ei,
  1885. },
  1886. {
  1887. .data_type = QMI_OPT_FLAG,
  1888. .elem_len = 1,
  1889. .elem_size = sizeof(u8),
  1890. .array_type = NO_ARRAY,
  1891. .tlv_type = 0x13,
  1892. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1893. shadow_reg_valid),
  1894. },
  1895. {
  1896. .data_type = QMI_DATA_LEN,
  1897. .elem_len = 1,
  1898. .elem_size = sizeof(u8),
  1899. .array_type = NO_ARRAY,
  1900. .tlv_type = 0x13,
  1901. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1902. shadow_reg_len),
  1903. },
  1904. {
  1905. .data_type = QMI_STRUCT,
  1906. .elem_len = QMI_WLANFW_MAX_NUM_SHADOW_REG_V01,
  1907. .elem_size = sizeof(struct qmi_wlanfw_shadow_reg_cfg_s_v01),
  1908. .array_type = VAR_LEN_ARRAY,
  1909. .tlv_type = 0x13,
  1910. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1911. shadow_reg),
  1912. .ei_array = qmi_wlanfw_shadow_reg_cfg_s_v01_ei,
  1913. },
  1914. {
  1915. .data_type = QMI_OPT_FLAG,
  1916. .elem_len = 1,
  1917. .elem_size = sizeof(u8),
  1918. .array_type = NO_ARRAY,
  1919. .tlv_type = 0x17,
  1920. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1921. shadow_reg_v3_valid),
  1922. },
  1923. {
  1924. .data_type = QMI_DATA_LEN,
  1925. .elem_len = 1,
  1926. .elem_size = sizeof(u8),
  1927. .array_type = NO_ARRAY,
  1928. .tlv_type = 0x17,
  1929. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1930. shadow_reg_v3_len),
  1931. },
  1932. {
  1933. .data_type = QMI_STRUCT,
  1934. .elem_len = QMI_WLANFW_MAX_NUM_SHADOW_REG_V3_V01,
  1935. .elem_size = sizeof(struct qmi_wlanfw_shadow_reg_v3_cfg_s_v01),
  1936. .array_type = VAR_LEN_ARRAY,
  1937. .tlv_type = 0x17,
  1938. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
  1939. shadow_reg_v3),
  1940. .ei_array = qmi_wlanfw_shadow_reg_v3_cfg_s_v01_ei,
  1941. },
  1942. {
  1943. .data_type = QMI_EOTI,
  1944. .array_type = NO_ARRAY,
  1945. .tlv_type = QMI_COMMON_TLV_TYPE,
  1946. },
  1947. };
  1948. static const struct qmi_elem_info qmi_wlanfw_wlan_cfg_resp_msg_v01_ei[] = {
  1949. {
  1950. .data_type = QMI_STRUCT,
  1951. .elem_len = 1,
  1952. .elem_size = sizeof(struct qmi_response_type_v01),
  1953. .array_type = NO_ARRAY,
  1954. .tlv_type = 0x02,
  1955. .offset = offsetof(struct qmi_wlanfw_wlan_cfg_resp_msg_v01, resp),
  1956. .ei_array = qmi_response_type_v01_ei,
  1957. },
  1958. {
  1959. .data_type = QMI_EOTI,
  1960. .array_type = NO_ARRAY,
  1961. .tlv_type = QMI_COMMON_TLV_TYPE,
  1962. },
  1963. };
  1964. static const struct qmi_elem_info qmi_wlanfw_mem_ready_ind_msg_v01_ei[] = {
  1965. {
  1966. .data_type = QMI_EOTI,
  1967. .array_type = NO_ARRAY,
  1968. },
  1969. };
  1970. static const struct qmi_elem_info qmi_wlanfw_fw_ready_ind_msg_v01_ei[] = {
  1971. {
  1972. .data_type = QMI_EOTI,
  1973. .array_type = NO_ARRAY,
  1974. },
  1975. };
  1976. static const struct qmi_elem_info qmi_wlanfw_wlan_ini_req_msg_v01_ei[] = {
  1977. {
  1978. .data_type = QMI_OPT_FLAG,
  1979. .elem_len = 1,
  1980. .elem_size = sizeof(u8),
  1981. .array_type = NO_ARRAY,
  1982. .tlv_type = 0x10,
  1983. .offset = offsetof(struct qmi_wlanfw_wlan_ini_req_msg_v01,
  1984. enable_fwlog_valid),
  1985. },
  1986. {
  1987. .data_type = QMI_UNSIGNED_1_BYTE,
  1988. .elem_len = 1,
  1989. .elem_size = sizeof(u8),
  1990. .array_type = NO_ARRAY,
  1991. .tlv_type = 0x10,
  1992. .offset = offsetof(struct qmi_wlanfw_wlan_ini_req_msg_v01,
  1993. enable_fwlog),
  1994. },
  1995. {
  1996. .data_type = QMI_EOTI,
  1997. .array_type = NO_ARRAY,
  1998. .tlv_type = QMI_COMMON_TLV_TYPE,
  1999. },
  2000. };
  2001. static const struct qmi_elem_info qmi_wlanfw_wlan_ini_resp_msg_v01_ei[] = {
  2002. {
  2003. .data_type = QMI_STRUCT,
  2004. .elem_len = 1,
  2005. .elem_size = sizeof(struct qmi_response_type_v01),
  2006. .array_type = NO_ARRAY,
  2007. .tlv_type = 0x02,
  2008. .offset = offsetof(struct qmi_wlanfw_wlan_ini_resp_msg_v01,
  2009. resp),
  2010. .ei_array = qmi_response_type_v01_ei,
  2011. },
  2012. {
  2013. .data_type = QMI_EOTI,
  2014. .array_type = NO_ARRAY,
  2015. .tlv_type = QMI_COMMON_TLV_TYPE,
  2016. },
  2017. };
  2018. static void ath12k_host_cap_hw_link_id_init(struct ath12k_hw_group *ag)
  2019. {
  2020. struct ath12k_base *ab, *partner_ab;
  2021. int i, j, hw_id_base;
  2022. for (i = 0; i < ag->num_devices; i++) {
  2023. hw_id_base = 0;
  2024. ab = ag->ab[i];
  2025. for (j = 0; j < ag->num_devices; j++) {
  2026. partner_ab = ag->ab[j];
  2027. if (partner_ab->wsi_info.index >= ab->wsi_info.index)
  2028. continue;
  2029. hw_id_base += partner_ab->qmi.num_radios;
  2030. }
  2031. ab->wsi_info.hw_link_id_base = hw_id_base;
  2032. }
  2033. ag->hw_link_id_init_done = true;
  2034. }
  2035. static int ath12k_host_cap_parse_mlo(struct ath12k_base *ab,
  2036. struct qmi_wlanfw_host_cap_req_msg_v01 *req)
  2037. {
  2038. struct wlfw_host_mlo_chip_info_s_v01 *info;
  2039. struct ath12k_hw_group *ag = ab->ag;
  2040. struct ath12k_base *partner_ab;
  2041. u8 hw_link_id = 0;
  2042. int i, j, ret;
  2043. if (!ag->mlo_capable) {
  2044. ath12k_dbg(ab, ATH12K_DBG_QMI,
  2045. "MLO is disabled hence skip QMI MLO cap");
  2046. return 0;
  2047. }
  2048. if (!ab->qmi.num_radios || ab->qmi.num_radios == U8_MAX) {
  2049. ag->mlo_capable = false;
  2050. ath12k_dbg(ab, ATH12K_DBG_QMI,
  2051. "skip QMI MLO cap due to invalid num_radio %d\n",
  2052. ab->qmi.num_radios);
  2053. return 0;
  2054. }
  2055. if (ab->device_id == ATH12K_INVALID_DEVICE_ID) {
  2056. ath12k_err(ab, "failed to send MLO cap due to invalid device id\n");
  2057. return -EINVAL;
  2058. }
  2059. req->mlo_capable_valid = 1;
  2060. req->mlo_capable = 1;
  2061. req->mlo_chip_id_valid = 1;
  2062. req->mlo_chip_id = ab->device_id;
  2063. req->mlo_group_id_valid = 1;
  2064. req->mlo_group_id = ag->id;
  2065. req->max_mlo_peer_valid = 1;
  2066. /* Max peer number generally won't change for the same device
  2067. * but needs to be synced with host driver.
  2068. */
  2069. req->max_mlo_peer = ab->hw_params->max_mlo_peer;
  2070. req->mlo_num_chips_valid = 1;
  2071. req->mlo_num_chips = ag->num_devices;
  2072. ath12k_dbg(ab, ATH12K_DBG_QMI, "mlo capability advertisement device_id %d group_id %d num_devices %d",
  2073. req->mlo_chip_id, req->mlo_group_id, req->mlo_num_chips);
  2074. mutex_lock(&ag->mutex);
  2075. if (!ag->hw_link_id_init_done)
  2076. ath12k_host_cap_hw_link_id_init(ag);
  2077. for (i = 0; i < ag->num_devices; i++) {
  2078. info = &req->mlo_chip_info[i];
  2079. partner_ab = ag->ab[i];
  2080. if (partner_ab->device_id == ATH12K_INVALID_DEVICE_ID) {
  2081. ath12k_err(ab, "failed to send MLO cap due to invalid partner device id\n");
  2082. ret = -EINVAL;
  2083. goto device_cleanup;
  2084. }
  2085. info->chip_id = partner_ab->device_id;
  2086. info->num_local_links = partner_ab->qmi.num_radios;
  2087. ath12k_dbg(ab, ATH12K_DBG_QMI, "mlo device id %d num_link %d\n",
  2088. info->chip_id, info->num_local_links);
  2089. for (j = 0; j < info->num_local_links; j++) {
  2090. info->hw_link_id[j] = partner_ab->wsi_info.hw_link_id_base + j;
  2091. info->valid_mlo_link_id[j] = 1;
  2092. ath12k_dbg(ab, ATH12K_DBG_QMI, "mlo hw_link_id %d\n",
  2093. info->hw_link_id[j]);
  2094. hw_link_id++;
  2095. }
  2096. }
  2097. if (hw_link_id <= 0)
  2098. ag->mlo_capable = false;
  2099. req->mlo_chip_info_valid = 1;
  2100. mutex_unlock(&ag->mutex);
  2101. return 0;
  2102. device_cleanup:
  2103. for (i = i - 1; i >= 0; i--) {
  2104. info = &req->mlo_chip_info[i];
  2105. memset(info, 0, sizeof(*info));
  2106. }
  2107. req->mlo_num_chips = 0;
  2108. req->mlo_num_chips_valid = 0;
  2109. req->max_mlo_peer = 0;
  2110. req->max_mlo_peer_valid = 0;
  2111. req->mlo_group_id = 0;
  2112. req->mlo_group_id_valid = 0;
  2113. req->mlo_chip_id = 0;
  2114. req->mlo_chip_id_valid = 0;
  2115. req->mlo_capable = 0;
  2116. req->mlo_capable_valid = 0;
  2117. ag->mlo_capable = false;
  2118. mutex_unlock(&ag->mutex);
  2119. return ret;
  2120. }
  2121. /* clang stack usage explodes if this is inlined */
  2122. static noinline_for_stack
  2123. int ath12k_qmi_host_cap_send(struct ath12k_base *ab)
  2124. {
  2125. struct qmi_wlanfw_host_cap_req_msg_v01 req = {};
  2126. struct qmi_wlanfw_host_cap_resp_msg_v01 resp = {};
  2127. struct qmi_txn txn;
  2128. int ret = 0;
  2129. req.num_clients_valid = 1;
  2130. req.num_clients = 1;
  2131. req.mem_cfg_mode = ab->qmi.target_mem_mode;
  2132. req.mem_cfg_mode_valid = 1;
  2133. req.bdf_support_valid = 1;
  2134. req.bdf_support = 1;
  2135. if (ab->hw_params->fw.m3_loader == ath12k_m3_fw_loader_driver) {
  2136. req.m3_support_valid = 1;
  2137. req.m3_support = 1;
  2138. req.m3_cache_support_valid = 1;
  2139. req.m3_cache_support = 1;
  2140. }
  2141. req.cal_done_valid = 1;
  2142. req.cal_done = ab->qmi.cal_done;
  2143. if (ab->hw_params->qmi_cnss_feature_bitmap) {
  2144. req.feature_list_valid = 1;
  2145. req.feature_list = ab->hw_params->qmi_cnss_feature_bitmap;
  2146. }
  2147. /* BRINGUP: here we are piggybacking a lot of stuff using
  2148. * internal_sleep_clock, should it be split?
  2149. */
  2150. if (ab->hw_params->internal_sleep_clock) {
  2151. req.nm_modem_valid = 1;
  2152. /* Notify firmware that this is non-qualcomm platform. */
  2153. req.nm_modem |= HOST_CSTATE_BIT;
  2154. /* Notify firmware about the sleep clock selection,
  2155. * nm_modem_bit[1] is used for this purpose. Host driver on
  2156. * non-qualcomm platforms should select internal sleep
  2157. * clock.
  2158. */
  2159. req.nm_modem |= SLEEP_CLOCK_SELECT_INTERNAL_BIT;
  2160. req.nm_modem |= PLATFORM_CAP_PCIE_GLOBAL_RESET;
  2161. }
  2162. ret = ath12k_host_cap_parse_mlo(ab, &req);
  2163. if (ret < 0)
  2164. goto out;
  2165. ret = qmi_txn_init(&ab->qmi.handle, &txn,
  2166. qmi_wlanfw_host_cap_resp_msg_v01_ei, &resp);
  2167. if (ret < 0)
  2168. goto out;
  2169. ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
  2170. QMI_WLANFW_HOST_CAP_REQ_V01,
  2171. QMI_WLANFW_HOST_CAP_REQ_MSG_V01_MAX_LEN,
  2172. qmi_wlanfw_host_cap_req_msg_v01_ei, &req);
  2173. if (ret < 0) {
  2174. qmi_txn_cancel(&txn);
  2175. ath12k_warn(ab, "Failed to send host capability request,err = %d\n", ret);
  2176. goto out;
  2177. }
  2178. ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH12K_QMI_WLANFW_TIMEOUT_MS));
  2179. if (ret < 0)
  2180. goto out;
  2181. if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
  2182. ath12k_warn(ab, "Host capability request failed, result: %d, err: %d\n",
  2183. resp.resp.result, resp.resp.error);
  2184. ret = -EINVAL;
  2185. goto out;
  2186. }
  2187. out:
  2188. return ret;
  2189. }
  2190. static void ath12k_qmi_phy_cap_send(struct ath12k_base *ab)
  2191. {
  2192. struct qmi_wlanfw_phy_cap_req_msg_v01 req = {};
  2193. struct qmi_wlanfw_phy_cap_resp_msg_v01 resp = {};
  2194. struct qmi_txn txn;
  2195. int ret;
  2196. ret = qmi_txn_init(&ab->qmi.handle, &txn,
  2197. qmi_wlanfw_phy_cap_resp_msg_v01_ei, &resp);
  2198. if (ret < 0)
  2199. goto out;
  2200. ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
  2201. QMI_WLANFW_PHY_CAP_REQ_V01,
  2202. QMI_WLANFW_PHY_CAP_REQ_MSG_V01_MAX_LEN,
  2203. qmi_wlanfw_phy_cap_req_msg_v01_ei, &req);
  2204. if (ret < 0) {
  2205. qmi_txn_cancel(&txn);
  2206. ath12k_warn(ab, "failed to send phy capability request: %d\n", ret);
  2207. goto out;
  2208. }
  2209. ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH12K_QMI_WLANFW_TIMEOUT_MS));
  2210. if (ret < 0)
  2211. goto out;
  2212. if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
  2213. ret = -EOPNOTSUPP;
  2214. goto out;
  2215. }
  2216. if (resp.single_chip_mlo_support_valid && resp.single_chip_mlo_support)
  2217. ab->single_chip_mlo_support = true;
  2218. if (!resp.num_phy_valid) {
  2219. ret = -ENODATA;
  2220. goto out;
  2221. }
  2222. ab->qmi.num_radios = resp.num_phy;
  2223. ath12k_dbg(ab, ATH12K_DBG_QMI,
  2224. "phy capability resp valid %d single_chip_mlo_support %d valid %d num_phy %d valid %d board_id %d\n",
  2225. resp.single_chip_mlo_support_valid, resp.single_chip_mlo_support,
  2226. resp.num_phy_valid, resp.num_phy,
  2227. resp.board_id_valid, resp.board_id);
  2228. return;
  2229. out:
  2230. /* If PHY capability not advertised then rely on default num link */
  2231. ab->qmi.num_radios = ab->hw_params->def_num_link;
  2232. ath12k_dbg(ab, ATH12K_DBG_QMI,
  2233. "no valid response from PHY capability, choose default num_phy %d\n",
  2234. ab->qmi.num_radios);
  2235. }
  2236. static int ath12k_qmi_fw_ind_register_send(struct ath12k_base *ab)
  2237. {
  2238. struct qmi_wlanfw_ind_register_req_msg_v01 *req;
  2239. struct qmi_wlanfw_ind_register_resp_msg_v01 *resp;
  2240. struct qmi_handle *handle = &ab->qmi.handle;
  2241. struct qmi_txn txn;
  2242. int ret;
  2243. req = kzalloc_obj(*req);
  2244. if (!req)
  2245. return -ENOMEM;
  2246. resp = kzalloc_obj(*resp);
  2247. if (!resp) {
  2248. ret = -ENOMEM;
  2249. goto resp_out;
  2250. }
  2251. req->client_id_valid = 1;
  2252. req->client_id = QMI_WLANFW_CLIENT_ID;
  2253. req->fw_ready_enable_valid = 1;
  2254. req->fw_ready_enable = 1;
  2255. req->request_mem_enable_valid = 1;
  2256. req->request_mem_enable = 1;
  2257. req->fw_mem_ready_enable_valid = 1;
  2258. req->fw_mem_ready_enable = 1;
  2259. req->cal_done_enable_valid = 1;
  2260. req->cal_done_enable = 1;
  2261. req->fw_init_done_enable_valid = 1;
  2262. req->fw_init_done_enable = 1;
  2263. req->pin_connect_result_enable_valid = 0;
  2264. req->pin_connect_result_enable = 0;
  2265. ret = qmi_txn_init(handle, &txn,
  2266. qmi_wlanfw_ind_register_resp_msg_v01_ei, resp);
  2267. if (ret < 0)
  2268. goto out;
  2269. ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
  2270. QMI_WLANFW_IND_REGISTER_REQ_V01,
  2271. QMI_WLANFW_IND_REGISTER_REQ_MSG_V01_MAX_LEN,
  2272. qmi_wlanfw_ind_register_req_msg_v01_ei, req);
  2273. if (ret < 0) {
  2274. qmi_txn_cancel(&txn);
  2275. ath12k_warn(ab, "Failed to send indication register request, err = %d\n",
  2276. ret);
  2277. goto out;
  2278. }
  2279. ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH12K_QMI_WLANFW_TIMEOUT_MS));
  2280. if (ret < 0) {
  2281. ath12k_warn(ab, "failed to register fw indication %d\n", ret);
  2282. goto out;
  2283. }
  2284. if (resp->resp.result != QMI_RESULT_SUCCESS_V01) {
  2285. ath12k_warn(ab, "FW Ind register request failed, result: %d, err: %d\n",
  2286. resp->resp.result, resp->resp.error);
  2287. ret = -EINVAL;
  2288. goto out;
  2289. }
  2290. out:
  2291. kfree(resp);
  2292. resp_out:
  2293. kfree(req);
  2294. return ret;
  2295. }
  2296. /* clang stack usage explodes if this is inlined */
  2297. static noinline_for_stack
  2298. int ath12k_qmi_respond_fw_mem_request(struct ath12k_base *ab)
  2299. {
  2300. struct qmi_wlanfw_respond_mem_req_msg_v01 *req;
  2301. struct qmi_wlanfw_respond_mem_resp_msg_v01 resp = {};
  2302. struct qmi_txn txn;
  2303. int ret = 0, i;
  2304. bool delayed;
  2305. req = kzalloc_obj(*req);
  2306. if (!req)
  2307. return -ENOMEM;
  2308. /* Some targets by default request a block of big contiguous
  2309. * DMA memory, it's hard to allocate from kernel. So host returns
  2310. * failure to firmware and firmware then request multiple blocks of
  2311. * small chunk size memory.
  2312. */
  2313. if (!test_bit(ATH12K_FLAG_FIXED_MEM_REGION, &ab->dev_flags) &&
  2314. ab->qmi.target_mem_delayed) {
  2315. delayed = true;
  2316. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi delays mem_request %d\n",
  2317. ab->qmi.mem_seg_count);
  2318. } else {
  2319. delayed = false;
  2320. req->mem_seg_len = ab->qmi.mem_seg_count;
  2321. for (i = 0; i < req->mem_seg_len ; i++) {
  2322. req->mem_seg[i].addr = ab->qmi.target_mem[i].paddr;
  2323. req->mem_seg[i].size = ab->qmi.target_mem[i].size;
  2324. req->mem_seg[i].type = ab->qmi.target_mem[i].type;
  2325. ath12k_dbg(ab, ATH12K_DBG_QMI,
  2326. "qmi req mem_seg[%d] %pad %u %u\n", i,
  2327. &ab->qmi.target_mem[i].paddr,
  2328. ab->qmi.target_mem[i].size,
  2329. ab->qmi.target_mem[i].type);
  2330. }
  2331. }
  2332. ret = qmi_txn_init(&ab->qmi.handle, &txn,
  2333. qmi_wlanfw_respond_mem_resp_msg_v01_ei, &resp);
  2334. if (ret < 0)
  2335. goto out;
  2336. ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
  2337. QMI_WLANFW_RESPOND_MEM_REQ_V01,
  2338. QMI_WLANFW_RESPOND_MEM_REQ_MSG_V01_MAX_LEN,
  2339. qmi_wlanfw_respond_mem_req_msg_v01_ei, req);
  2340. if (ret < 0) {
  2341. qmi_txn_cancel(&txn);
  2342. ath12k_warn(ab, "qmi failed to respond memory request, err = %d\n",
  2343. ret);
  2344. goto out;
  2345. }
  2346. ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH12K_QMI_WLANFW_TIMEOUT_MS));
  2347. if (ret < 0) {
  2348. ath12k_warn(ab, "qmi failed memory request, err = %d\n", ret);
  2349. goto out;
  2350. }
  2351. if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
  2352. /* the error response is expected when
  2353. * target_mem_delayed is true.
  2354. */
  2355. if (delayed && resp.resp.error == 0)
  2356. goto out;
  2357. ath12k_warn(ab, "Respond mem req failed, result: %d, err: %d\n",
  2358. resp.resp.result, resp.resp.error);
  2359. ret = -EINVAL;
  2360. goto out;
  2361. }
  2362. out:
  2363. kfree(req);
  2364. return ret;
  2365. }
  2366. void ath12k_qmi_reset_mlo_mem(struct ath12k_hw_group *ag)
  2367. {
  2368. struct target_mem_chunk *mlo_chunk;
  2369. int i;
  2370. lockdep_assert_held(&ag->mutex);
  2371. if (!ag->mlo_mem.init_done || ag->num_started)
  2372. return;
  2373. for (i = 0; i < ARRAY_SIZE(ag->mlo_mem.chunk); i++) {
  2374. mlo_chunk = &ag->mlo_mem.chunk[i];
  2375. if (mlo_chunk->v.addr)
  2376. /* TODO: Mode 0 recovery is the default mode hence resetting the
  2377. * whole memory region for now. Once Mode 1 support is added, this
  2378. * needs to be handled properly
  2379. */
  2380. memset(mlo_chunk->v.addr, 0, mlo_chunk->size);
  2381. }
  2382. }
  2383. static void ath12k_qmi_free_mlo_mem_chunk(struct ath12k_base *ab,
  2384. struct target_mem_chunk *chunk,
  2385. int idx)
  2386. {
  2387. struct ath12k_hw_group *ag = ab->ag;
  2388. struct target_mem_chunk *mlo_chunk;
  2389. bool fixed_mem;
  2390. lockdep_assert_held(&ag->mutex);
  2391. if (!ag->mlo_mem.init_done || ag->num_started)
  2392. return;
  2393. if (idx >= ARRAY_SIZE(ag->mlo_mem.chunk)) {
  2394. ath12k_warn(ab, "invalid index for MLO memory chunk free: %d\n", idx);
  2395. return;
  2396. }
  2397. fixed_mem = test_bit(ATH12K_FLAG_FIXED_MEM_REGION, &ab->dev_flags);
  2398. mlo_chunk = &ag->mlo_mem.chunk[idx];
  2399. if (fixed_mem && mlo_chunk->v.ioaddr) {
  2400. iounmap(mlo_chunk->v.ioaddr);
  2401. mlo_chunk->v.ioaddr = NULL;
  2402. } else if (mlo_chunk->v.addr) {
  2403. dma_free_coherent(ab->dev,
  2404. mlo_chunk->size,
  2405. mlo_chunk->v.addr,
  2406. mlo_chunk->paddr);
  2407. mlo_chunk->v.addr = NULL;
  2408. }
  2409. mlo_chunk->paddr = 0;
  2410. mlo_chunk->size = 0;
  2411. if (fixed_mem)
  2412. chunk->v.ioaddr = NULL;
  2413. else
  2414. chunk->v.addr = NULL;
  2415. chunk->paddr = 0;
  2416. chunk->size = 0;
  2417. }
  2418. static void ath12k_qmi_free_target_mem_chunk(struct ath12k_base *ab)
  2419. {
  2420. struct ath12k_hw_group *ag = ab->ag;
  2421. int i, mlo_idx;
  2422. for (i = 0, mlo_idx = 0; i < ab->qmi.mem_seg_count; i++) {
  2423. if (ab->qmi.target_mem[i].type == MLO_GLOBAL_MEM_REGION_TYPE) {
  2424. ath12k_qmi_free_mlo_mem_chunk(ab,
  2425. &ab->qmi.target_mem[i],
  2426. mlo_idx++);
  2427. } else {
  2428. if (test_bit(ATH12K_FLAG_FIXED_MEM_REGION, &ab->dev_flags) &&
  2429. ab->qmi.target_mem[i].v.ioaddr) {
  2430. iounmap(ab->qmi.target_mem[i].v.ioaddr);
  2431. ab->qmi.target_mem[i].v.ioaddr = NULL;
  2432. } else {
  2433. if (!ab->qmi.target_mem[i].v.addr)
  2434. continue;
  2435. dma_free_coherent(ab->dev,
  2436. ab->qmi.target_mem[i].prev_size,
  2437. ab->qmi.target_mem[i].v.addr,
  2438. ab->qmi.target_mem[i].paddr);
  2439. ab->qmi.target_mem[i].v.addr = NULL;
  2440. }
  2441. }
  2442. }
  2443. if (!ag->num_started && ag->mlo_mem.init_done) {
  2444. ag->mlo_mem.init_done = false;
  2445. ag->mlo_mem.mlo_mem_size = 0;
  2446. }
  2447. }
  2448. static int ath12k_qmi_alloc_chunk(struct ath12k_base *ab,
  2449. struct target_mem_chunk *chunk)
  2450. {
  2451. /* Firmware reloads in recovery/resume.
  2452. * In such cases, no need to allocate memory for FW again.
  2453. */
  2454. if (chunk->v.addr) {
  2455. if (chunk->prev_type == chunk->type &&
  2456. chunk->prev_size == chunk->size)
  2457. goto this_chunk_done;
  2458. /* cannot reuse the existing chunk */
  2459. dma_free_coherent(ab->dev, chunk->prev_size,
  2460. chunk->v.addr, chunk->paddr);
  2461. chunk->v.addr = NULL;
  2462. }
  2463. chunk->v.addr = dma_alloc_coherent(ab->dev,
  2464. chunk->size,
  2465. &chunk->paddr,
  2466. GFP_KERNEL | __GFP_NOWARN);
  2467. if (!chunk->v.addr) {
  2468. if (chunk->size > ATH12K_QMI_MAX_CHUNK_SIZE) {
  2469. ab->qmi.target_mem_delayed = true;
  2470. ath12k_warn(ab,
  2471. "qmi dma allocation failed (%d B type %u), will try later with small size\n",
  2472. chunk->size,
  2473. chunk->type);
  2474. ath12k_qmi_free_target_mem_chunk(ab);
  2475. return -EAGAIN;
  2476. }
  2477. ath12k_warn(ab, "memory allocation failure for %u size: %d\n",
  2478. chunk->type, chunk->size);
  2479. return -ENOMEM;
  2480. }
  2481. chunk->prev_type = chunk->type;
  2482. chunk->prev_size = chunk->size;
  2483. this_chunk_done:
  2484. return 0;
  2485. }
  2486. static int ath12k_qmi_alloc_target_mem_chunk(struct ath12k_base *ab)
  2487. {
  2488. struct target_mem_chunk *chunk, *mlo_chunk;
  2489. struct ath12k_hw_group *ag = ab->ag;
  2490. int i, mlo_idx, ret;
  2491. int mlo_size = 0;
  2492. mutex_lock(&ag->mutex);
  2493. if (!ag->mlo_mem.init_done) {
  2494. memset(ag->mlo_mem.chunk, 0, sizeof(ag->mlo_mem.chunk));
  2495. ag->mlo_mem.init_done = true;
  2496. }
  2497. ab->qmi.target_mem_delayed = false;
  2498. for (i = 0, mlo_idx = 0; i < ab->qmi.mem_seg_count; i++) {
  2499. chunk = &ab->qmi.target_mem[i];
  2500. /* Allocate memory for the region and the functionality supported
  2501. * on the host. For the non-supported memory region, host does not
  2502. * allocate memory, assigns NULL and FW will handle this without crashing.
  2503. */
  2504. switch (chunk->type) {
  2505. case HOST_DDR_REGION_TYPE:
  2506. case M3_DUMP_REGION_TYPE:
  2507. case PAGEABLE_MEM_REGION_TYPE:
  2508. case CALDB_MEM_REGION_TYPE:
  2509. case LPASS_SHARED_V01_REGION_TYPE:
  2510. ret = ath12k_qmi_alloc_chunk(ab, chunk);
  2511. if (ret)
  2512. goto err;
  2513. break;
  2514. case MLO_GLOBAL_MEM_REGION_TYPE:
  2515. mlo_size += chunk->size;
  2516. if (ag->mlo_mem.mlo_mem_size &&
  2517. mlo_size > ag->mlo_mem.mlo_mem_size) {
  2518. ath12k_err(ab, "QMI MLO memory allocation failure, requested size %d is more than allocated size %d",
  2519. mlo_size, ag->mlo_mem.mlo_mem_size);
  2520. ret = -EINVAL;
  2521. goto err;
  2522. }
  2523. mlo_chunk = &ag->mlo_mem.chunk[mlo_idx];
  2524. if (mlo_chunk->paddr) {
  2525. if (chunk->size != mlo_chunk->size) {
  2526. ath12k_err(ab, "QMI MLO chunk memory allocation failure for index %d, requested size %d is more than allocated size %d",
  2527. mlo_idx, chunk->size, mlo_chunk->size);
  2528. ret = -EINVAL;
  2529. goto err;
  2530. }
  2531. } else {
  2532. mlo_chunk->size = chunk->size;
  2533. mlo_chunk->type = chunk->type;
  2534. ret = ath12k_qmi_alloc_chunk(ab, mlo_chunk);
  2535. if (ret)
  2536. goto err;
  2537. memset(mlo_chunk->v.addr, 0, mlo_chunk->size);
  2538. }
  2539. chunk->paddr = mlo_chunk->paddr;
  2540. chunk->v.addr = mlo_chunk->v.addr;
  2541. mlo_idx++;
  2542. break;
  2543. default:
  2544. ath12k_warn(ab, "memory type %u not supported\n",
  2545. chunk->type);
  2546. chunk->paddr = 0;
  2547. chunk->v.addr = NULL;
  2548. break;
  2549. }
  2550. }
  2551. if (!ag->mlo_mem.mlo_mem_size) {
  2552. ag->mlo_mem.mlo_mem_size = mlo_size;
  2553. } else if (ag->mlo_mem.mlo_mem_size != mlo_size) {
  2554. ath12k_err(ab, "QMI MLO memory size error, expected size is %d but requested size is %d",
  2555. ag->mlo_mem.mlo_mem_size, mlo_size);
  2556. ret = -EINVAL;
  2557. goto err;
  2558. }
  2559. mutex_unlock(&ag->mutex);
  2560. return 0;
  2561. err:
  2562. ath12k_qmi_free_target_mem_chunk(ab);
  2563. mutex_unlock(&ag->mutex);
  2564. /* The firmware will attempt to request memory in smaller chunks
  2565. * on the next try. However, the current caller should be notified
  2566. * that this instance of request parsing was successful.
  2567. * Therefore, return 0 only.
  2568. */
  2569. if (ret == -EAGAIN)
  2570. ret = 0;
  2571. return ret;
  2572. }
  2573. static int ath12k_qmi_assign_target_mem_chunk(struct ath12k_base *ab)
  2574. {
  2575. struct reserved_mem *rmem;
  2576. size_t avail_rmem_size;
  2577. int i, idx, ret;
  2578. for (i = 0, idx = 0; i < ab->qmi.mem_seg_count; i++) {
  2579. switch (ab->qmi.target_mem[i].type) {
  2580. case HOST_DDR_REGION_TYPE:
  2581. rmem = ath12k_core_get_reserved_mem(ab, 0);
  2582. if (!rmem) {
  2583. ret = -ENODEV;
  2584. goto out;
  2585. }
  2586. avail_rmem_size = rmem->size;
  2587. if (avail_rmem_size < ab->qmi.target_mem[i].size) {
  2588. ath12k_dbg(ab, ATH12K_DBG_QMI,
  2589. "failed to assign mem type %u req size %u avail size %zu\n",
  2590. ab->qmi.target_mem[i].type,
  2591. ab->qmi.target_mem[i].size,
  2592. avail_rmem_size);
  2593. ret = -EINVAL;
  2594. goto out;
  2595. }
  2596. ab->qmi.target_mem[idx].paddr = rmem->base;
  2597. ab->qmi.target_mem[idx].v.ioaddr =
  2598. ioremap(ab->qmi.target_mem[idx].paddr,
  2599. ab->qmi.target_mem[i].size);
  2600. if (!ab->qmi.target_mem[idx].v.ioaddr) {
  2601. ret = -EIO;
  2602. goto out;
  2603. }
  2604. ab->qmi.target_mem[idx].size = ab->qmi.target_mem[i].size;
  2605. ab->qmi.target_mem[idx].type = ab->qmi.target_mem[i].type;
  2606. idx++;
  2607. break;
  2608. case BDF_MEM_REGION_TYPE:
  2609. rmem = ath12k_core_get_reserved_mem(ab, 0);
  2610. if (!rmem) {
  2611. ret = -ENODEV;
  2612. goto out;
  2613. }
  2614. avail_rmem_size = rmem->size - ab->hw_params->bdf_addr_offset;
  2615. if (avail_rmem_size < ab->qmi.target_mem[i].size) {
  2616. ath12k_dbg(ab, ATH12K_DBG_QMI,
  2617. "failed to assign mem type %u req size %u avail size %zu\n",
  2618. ab->qmi.target_mem[i].type,
  2619. ab->qmi.target_mem[i].size,
  2620. avail_rmem_size);
  2621. ret = -EINVAL;
  2622. goto out;
  2623. }
  2624. ab->qmi.target_mem[idx].paddr =
  2625. rmem->base + ab->hw_params->bdf_addr_offset;
  2626. ab->qmi.target_mem[idx].v.ioaddr =
  2627. ioremap(ab->qmi.target_mem[idx].paddr,
  2628. ab->qmi.target_mem[i].size);
  2629. if (!ab->qmi.target_mem[idx].v.ioaddr) {
  2630. ret = -EIO;
  2631. goto out;
  2632. }
  2633. ab->qmi.target_mem[idx].size = ab->qmi.target_mem[i].size;
  2634. ab->qmi.target_mem[idx].type = ab->qmi.target_mem[i].type;
  2635. idx++;
  2636. break;
  2637. case CALDB_MEM_REGION_TYPE:
  2638. /* Cold boot calibration is not enabled in Ath12k. Hence,
  2639. * assign paddr = 0.
  2640. * Once cold boot calibration is enabled add support to
  2641. * assign reserved memory from DT.
  2642. */
  2643. ab->qmi.target_mem[idx].paddr = 0;
  2644. ab->qmi.target_mem[idx].v.ioaddr = NULL;
  2645. ab->qmi.target_mem[idx].size = ab->qmi.target_mem[i].size;
  2646. ab->qmi.target_mem[idx].type = ab->qmi.target_mem[i].type;
  2647. idx++;
  2648. break;
  2649. case M3_DUMP_REGION_TYPE:
  2650. rmem = ath12k_core_get_reserved_mem(ab, 1);
  2651. if (!rmem) {
  2652. ret = -EINVAL;
  2653. goto out;
  2654. }
  2655. avail_rmem_size = rmem->size;
  2656. if (avail_rmem_size < ab->qmi.target_mem[i].size) {
  2657. ath12k_dbg(ab, ATH12K_DBG_QMI,
  2658. "failed to assign mem type %u req size %u avail size %zu\n",
  2659. ab->qmi.target_mem[i].type,
  2660. ab->qmi.target_mem[i].size,
  2661. avail_rmem_size);
  2662. ret = -EINVAL;
  2663. goto out;
  2664. }
  2665. ab->qmi.target_mem[idx].paddr = rmem->base;
  2666. ab->qmi.target_mem[idx].v.ioaddr =
  2667. ioremap(ab->qmi.target_mem[idx].paddr,
  2668. ab->qmi.target_mem[i].size);
  2669. if (!ab->qmi.target_mem[idx].v.ioaddr) {
  2670. ret = -EIO;
  2671. goto out;
  2672. }
  2673. ab->qmi.target_mem[idx].size = ab->qmi.target_mem[i].size;
  2674. ab->qmi.target_mem[idx].type = ab->qmi.target_mem[i].type;
  2675. idx++;
  2676. break;
  2677. default:
  2678. ath12k_warn(ab, "qmi ignore invalid mem req type %u\n",
  2679. ab->qmi.target_mem[i].type);
  2680. break;
  2681. }
  2682. }
  2683. ab->qmi.mem_seg_count = idx;
  2684. return 0;
  2685. out:
  2686. ath12k_qmi_free_target_mem_chunk(ab);
  2687. return ret;
  2688. }
  2689. /* clang stack usage explodes if this is inlined */
  2690. static noinline_for_stack
  2691. int ath12k_qmi_request_target_cap(struct ath12k_base *ab)
  2692. {
  2693. struct qmi_wlanfw_cap_req_msg_v01 req = {};
  2694. struct qmi_wlanfw_cap_resp_msg_v01 resp = {};
  2695. struct qmi_txn txn;
  2696. unsigned int board_id = ATH12K_BOARD_ID_DEFAULT;
  2697. int ret = 0;
  2698. int r;
  2699. int i;
  2700. ret = qmi_txn_init(&ab->qmi.handle, &txn,
  2701. qmi_wlanfw_cap_resp_msg_v01_ei, &resp);
  2702. if (ret < 0)
  2703. goto out;
  2704. ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
  2705. QMI_WLANFW_CAP_REQ_V01,
  2706. QMI_WLANFW_CAP_REQ_MSG_V01_MAX_LEN,
  2707. qmi_wlanfw_cap_req_msg_v01_ei, &req);
  2708. if (ret < 0) {
  2709. qmi_txn_cancel(&txn);
  2710. ath12k_warn(ab, "qmi failed to send target cap request, err = %d\n",
  2711. ret);
  2712. goto out;
  2713. }
  2714. ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH12K_QMI_WLANFW_TIMEOUT_MS));
  2715. if (ret < 0) {
  2716. ath12k_warn(ab, "qmi failed target cap request %d\n", ret);
  2717. goto out;
  2718. }
  2719. if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
  2720. ath12k_warn(ab, "qmi targetcap req failed, result: %d, err: %d\n",
  2721. resp.resp.result, resp.resp.error);
  2722. ret = -EINVAL;
  2723. goto out;
  2724. }
  2725. if (resp.chip_info_valid) {
  2726. ab->qmi.target.chip_id = resp.chip_info.chip_id;
  2727. ab->qmi.target.chip_family = resp.chip_info.chip_family;
  2728. }
  2729. if (resp.board_info_valid)
  2730. ab->qmi.target.board_id = resp.board_info.board_id;
  2731. else
  2732. ab->qmi.target.board_id = board_id;
  2733. if (resp.soc_info_valid)
  2734. ab->qmi.target.soc_id = resp.soc_info.soc_id;
  2735. if (resp.fw_version_info_valid) {
  2736. ab->qmi.target.fw_version = resp.fw_version_info.fw_version;
  2737. strscpy(ab->qmi.target.fw_build_timestamp,
  2738. resp.fw_version_info.fw_build_timestamp,
  2739. sizeof(ab->qmi.target.fw_build_timestamp));
  2740. }
  2741. if (resp.fw_build_id_valid)
  2742. strscpy(ab->qmi.target.fw_build_id, resp.fw_build_id,
  2743. sizeof(ab->qmi.target.fw_build_id));
  2744. if (resp.dev_mem_info_valid) {
  2745. for (i = 0; i < ATH12K_QMI_WLFW_MAX_DEV_MEM_NUM_V01; i++) {
  2746. ab->qmi.dev_mem[i].start =
  2747. resp.dev_mem[i].start;
  2748. ab->qmi.dev_mem[i].size =
  2749. resp.dev_mem[i].size;
  2750. ath12k_dbg(ab, ATH12K_DBG_QMI,
  2751. "devmem [%d] start 0x%llx size %llu\n", i,
  2752. ab->qmi.dev_mem[i].start,
  2753. ab->qmi.dev_mem[i].size);
  2754. }
  2755. }
  2756. if (resp.eeprom_caldata_read_timeout_valid) {
  2757. ab->qmi.target.eeprom_caldata = resp.eeprom_caldata_read_timeout;
  2758. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi cal data supported from eeprom\n");
  2759. }
  2760. ath12k_info(ab, "chip_id 0x%x chip_family 0x%x board_id 0x%x soc_id 0x%x\n",
  2761. ab->qmi.target.chip_id, ab->qmi.target.chip_family,
  2762. ab->qmi.target.board_id, ab->qmi.target.soc_id);
  2763. ath12k_info(ab, "fw_version 0x%x fw_build_timestamp %s fw_build_id %s",
  2764. ab->qmi.target.fw_version,
  2765. ab->qmi.target.fw_build_timestamp,
  2766. ab->qmi.target.fw_build_id);
  2767. r = ath12k_core_check_smbios(ab);
  2768. if (r)
  2769. ath12k_dbg(ab, ATH12K_DBG_QMI, "SMBIOS bdf variant name not set.\n");
  2770. r = ath12k_acpi_start(ab);
  2771. if (r)
  2772. /* ACPI is optional so continue in case of an error */
  2773. ath12k_dbg(ab, ATH12K_DBG_BOOT, "acpi failed: %d\n", r);
  2774. r = ath12k_acpi_check_bdf_variant_name(ab);
  2775. if (r)
  2776. ath12k_dbg(ab, ATH12K_DBG_BOOT, "ACPI bdf variant name not set.\n");
  2777. out:
  2778. return ret;
  2779. }
  2780. static int ath12k_qmi_load_file_target_mem(struct ath12k_base *ab,
  2781. const u8 *data, u32 len, u8 type)
  2782. {
  2783. struct qmi_wlanfw_bdf_download_req_msg_v01 *req;
  2784. struct qmi_wlanfw_bdf_download_resp_msg_v01 resp = {};
  2785. struct qmi_txn txn;
  2786. const u8 *temp = data;
  2787. int ret = 0;
  2788. u32 remaining = len;
  2789. req = kzalloc_obj(*req);
  2790. if (!req)
  2791. return -ENOMEM;
  2792. while (remaining) {
  2793. req->valid = 1;
  2794. req->file_id_valid = 1;
  2795. req->file_id = ab->qmi.target.board_id;
  2796. req->total_size_valid = 1;
  2797. req->total_size = remaining;
  2798. req->seg_id_valid = 1;
  2799. req->data_valid = 1;
  2800. req->bdf_type = type;
  2801. req->bdf_type_valid = 1;
  2802. req->end_valid = 1;
  2803. req->end = 0;
  2804. if (remaining > QMI_WLANFW_MAX_DATA_SIZE_V01) {
  2805. req->data_len = QMI_WLANFW_MAX_DATA_SIZE_V01;
  2806. } else {
  2807. req->data_len = remaining;
  2808. req->end = 1;
  2809. }
  2810. if (type == ATH12K_QMI_FILE_TYPE_EEPROM) {
  2811. req->data_valid = 0;
  2812. req->end = 1;
  2813. req->data_len = ATH12K_QMI_MAX_BDF_FILE_NAME_SIZE;
  2814. } else {
  2815. memcpy(req->data, temp, req->data_len);
  2816. }
  2817. ret = qmi_txn_init(&ab->qmi.handle, &txn,
  2818. qmi_wlanfw_bdf_download_resp_msg_v01_ei,
  2819. &resp);
  2820. if (ret < 0)
  2821. goto out;
  2822. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi bdf download req fixed addr type %d\n",
  2823. type);
  2824. ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
  2825. QMI_WLANFW_BDF_DOWNLOAD_REQ_V01,
  2826. QMI_WLANFW_BDF_DOWNLOAD_REQ_MSG_V01_MAX_LEN,
  2827. qmi_wlanfw_bdf_download_req_msg_v01_ei, req);
  2828. if (ret < 0) {
  2829. qmi_txn_cancel(&txn);
  2830. goto out;
  2831. }
  2832. ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH12K_QMI_WLANFW_TIMEOUT_MS));
  2833. if (ret < 0)
  2834. goto out;
  2835. if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
  2836. ath12k_warn(ab, "qmi BDF download failed, result: %d, err: %d\n",
  2837. resp.resp.result, resp.resp.error);
  2838. ret = -EINVAL;
  2839. goto out;
  2840. }
  2841. if (type == ATH12K_QMI_FILE_TYPE_EEPROM) {
  2842. remaining = 0;
  2843. } else {
  2844. remaining -= req->data_len;
  2845. temp += req->data_len;
  2846. req->seg_id++;
  2847. ath12k_dbg(ab, ATH12K_DBG_QMI,
  2848. "qmi bdf download request remaining %i\n",
  2849. remaining);
  2850. }
  2851. }
  2852. out:
  2853. kfree(req);
  2854. return ret;
  2855. }
  2856. /* clang stack usage explodes if this is inlined */
  2857. static noinline_for_stack
  2858. int ath12k_qmi_load_bdf_qmi(struct ath12k_base *ab,
  2859. enum ath12k_qmi_bdf_type type)
  2860. {
  2861. struct device *dev = ab->dev;
  2862. char filename[ATH12K_QMI_MAX_BDF_FILE_NAME_SIZE];
  2863. const struct firmware *fw_entry;
  2864. struct ath12k_board_data bd;
  2865. u32 fw_size, file_type;
  2866. int ret = 0;
  2867. const u8 *tmp;
  2868. memset(&bd, 0, sizeof(bd));
  2869. switch (type) {
  2870. case ATH12K_QMI_BDF_TYPE_ELF:
  2871. ret = ath12k_core_fetch_bdf(ab, &bd);
  2872. if (ret) {
  2873. ath12k_warn(ab, "qmi failed to load bdf:\n");
  2874. goto out;
  2875. }
  2876. if (bd.len >= SELFMAG && memcmp(bd.data, ELFMAG, SELFMAG) == 0)
  2877. type = ATH12K_QMI_BDF_TYPE_ELF;
  2878. else
  2879. type = ATH12K_QMI_BDF_TYPE_BIN;
  2880. break;
  2881. case ATH12K_QMI_BDF_TYPE_REGDB:
  2882. ret = ath12k_core_fetch_regdb(ab, &bd);
  2883. if (ret) {
  2884. ath12k_warn(ab, "qmi failed to load regdb bin:\n");
  2885. goto out;
  2886. }
  2887. break;
  2888. case ATH12K_QMI_BDF_TYPE_CALIBRATION:
  2889. if (ab->qmi.target.eeprom_caldata) {
  2890. file_type = ATH12K_QMI_FILE_TYPE_EEPROM;
  2891. tmp = filename;
  2892. fw_size = ATH12K_QMI_MAX_BDF_FILE_NAME_SIZE;
  2893. } else {
  2894. file_type = ATH12K_QMI_FILE_TYPE_CALDATA;
  2895. /* cal-<bus>-<id>.bin */
  2896. snprintf(filename, sizeof(filename), "cal-%s-%s.bin",
  2897. ath12k_bus_str(ab->hif.bus), dev_name(dev));
  2898. fw_entry = ath12k_core_firmware_request(ab, filename);
  2899. if (!IS_ERR(fw_entry))
  2900. goto success;
  2901. fw_entry = ath12k_core_firmware_request(ab,
  2902. ATH12K_DEFAULT_CAL_FILE);
  2903. if (IS_ERR(fw_entry)) {
  2904. ret = PTR_ERR(fw_entry);
  2905. ath12k_warn(ab,
  2906. "qmi failed to load CAL data file:%s\n",
  2907. filename);
  2908. goto out;
  2909. }
  2910. success:
  2911. fw_size = min_t(u32, ab->hw_params->fw.board_size,
  2912. fw_entry->size);
  2913. tmp = fw_entry->data;
  2914. }
  2915. ret = ath12k_qmi_load_file_target_mem(ab, tmp, fw_size, file_type);
  2916. if (ret < 0) {
  2917. ath12k_warn(ab, "qmi failed to load caldata\n");
  2918. goto out_qmi_cal;
  2919. }
  2920. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi caldata downloaded: type: %u\n",
  2921. file_type);
  2922. out_qmi_cal:
  2923. if (!ab->qmi.target.eeprom_caldata)
  2924. release_firmware(fw_entry);
  2925. return ret;
  2926. default:
  2927. ath12k_warn(ab, "unknown file type for load %d", type);
  2928. goto out;
  2929. }
  2930. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi bdf_type %d\n", type);
  2931. fw_size = min_t(u32, ab->hw_params->fw.board_size, bd.len);
  2932. ret = ath12k_qmi_load_file_target_mem(ab, bd.data, fw_size, type);
  2933. if (ret < 0)
  2934. ath12k_warn(ab, "qmi failed to load bdf file\n");
  2935. out:
  2936. ath12k_core_free_bdf(ab, &bd);
  2937. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi BDF download sequence completed\n");
  2938. return ret;
  2939. }
  2940. static void ath12k_qmi_m3_free(struct ath12k_base *ab)
  2941. {
  2942. struct m3_mem_region *m3_mem = &ab->qmi.m3_mem;
  2943. if (ab->hw_params->fw.m3_loader == ath12k_m3_fw_loader_remoteproc)
  2944. return;
  2945. if (!m3_mem->vaddr)
  2946. return;
  2947. dma_free_coherent(ab->dev, m3_mem->total_size,
  2948. m3_mem->vaddr, m3_mem->paddr);
  2949. m3_mem->vaddr = NULL;
  2950. m3_mem->total_size = 0;
  2951. m3_mem->size = 0;
  2952. }
  2953. static int ath12k_qmi_m3_load(struct ath12k_base *ab)
  2954. {
  2955. struct m3_mem_region *m3_mem = &ab->qmi.m3_mem;
  2956. const struct firmware *fw = NULL;
  2957. const void *m3_data;
  2958. char path[100];
  2959. size_t m3_len;
  2960. int ret;
  2961. if (ab->fw.m3_data && ab->fw.m3_len > 0) {
  2962. /* firmware-N.bin had a m3 firmware file so use that */
  2963. m3_data = ab->fw.m3_data;
  2964. m3_len = ab->fw.m3_len;
  2965. } else {
  2966. /* No m3 file in firmware-N.bin so try to request old
  2967. * separate m3.bin.
  2968. */
  2969. fw = ath12k_core_firmware_request(ab, ATH12K_M3_FILE);
  2970. if (IS_ERR(fw)) {
  2971. ret = PTR_ERR(fw);
  2972. ath12k_core_create_firmware_path(ab, ATH12K_M3_FILE,
  2973. path, sizeof(path));
  2974. ath12k_err(ab, "failed to load %s: %d\n", path, ret);
  2975. return ret;
  2976. }
  2977. m3_data = fw->data;
  2978. m3_len = fw->size;
  2979. }
  2980. /* In recovery/resume cases, M3 buffer is not freed, try to reuse that */
  2981. if (m3_mem->vaddr) {
  2982. if (m3_mem->total_size >= m3_len)
  2983. goto skip_m3_alloc;
  2984. /* Old buffer is too small, free and reallocate */
  2985. ath12k_qmi_m3_free(ab);
  2986. }
  2987. m3_mem->vaddr = dma_alloc_coherent(ab->dev,
  2988. m3_len, &m3_mem->paddr,
  2989. GFP_KERNEL);
  2990. if (!m3_mem->vaddr) {
  2991. ath12k_err(ab, "failed to allocate memory for M3 with size %zu\n",
  2992. m3_len);
  2993. ret = -ENOMEM;
  2994. goto out;
  2995. }
  2996. m3_mem->total_size = m3_len;
  2997. skip_m3_alloc:
  2998. memcpy(m3_mem->vaddr, m3_data, m3_len);
  2999. m3_mem->size = m3_len;
  3000. ret = 0;
  3001. out:
  3002. release_firmware(fw);
  3003. return ret;
  3004. }
  3005. /* clang stack usage explodes if this is inlined */
  3006. static noinline_for_stack
  3007. int ath12k_qmi_wlanfw_m3_info_send(struct ath12k_base *ab)
  3008. {
  3009. struct m3_mem_region *m3_mem = &ab->qmi.m3_mem;
  3010. struct qmi_wlanfw_m3_info_req_msg_v01 req = {};
  3011. struct qmi_wlanfw_m3_info_resp_msg_v01 resp = {};
  3012. struct qmi_txn txn;
  3013. int ret = 0;
  3014. if (ab->hw_params->fw.m3_loader == ath12k_m3_fw_loader_driver) {
  3015. ret = ath12k_qmi_m3_load(ab);
  3016. if (ret) {
  3017. ath12k_err(ab, "failed to load m3 firmware: %d", ret);
  3018. return ret;
  3019. }
  3020. req.addr = m3_mem->paddr;
  3021. req.size = m3_mem->size;
  3022. }
  3023. ret = qmi_txn_init(&ab->qmi.handle, &txn,
  3024. qmi_wlanfw_m3_info_resp_msg_v01_ei, &resp);
  3025. if (ret < 0)
  3026. goto out;
  3027. ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
  3028. QMI_WLANFW_M3_INFO_REQ_V01,
  3029. QMI_WLANFW_M3_INFO_REQ_MSG_V01_MAX_MSG_LEN,
  3030. qmi_wlanfw_m3_info_req_msg_v01_ei, &req);
  3031. if (ret < 0) {
  3032. qmi_txn_cancel(&txn);
  3033. ath12k_warn(ab, "qmi failed to send M3 information request, err = %d\n",
  3034. ret);
  3035. goto out;
  3036. }
  3037. ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH12K_QMI_WLANFW_TIMEOUT_MS));
  3038. if (ret < 0) {
  3039. ath12k_warn(ab, "qmi failed M3 information request %d\n", ret);
  3040. goto out;
  3041. }
  3042. if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
  3043. ath12k_warn(ab, "qmi M3 info request failed, result: %d, err: %d\n",
  3044. resp.resp.result, resp.resp.error);
  3045. ret = -EINVAL;
  3046. goto out;
  3047. }
  3048. out:
  3049. return ret;
  3050. }
  3051. static void ath12k_qmi_aux_uc_free(struct ath12k_base *ab)
  3052. {
  3053. struct m3_mem_region *aux_uc_mem = &ab->qmi.aux_uc_mem;
  3054. if (!aux_uc_mem->vaddr)
  3055. return;
  3056. dma_free_coherent(ab->dev, aux_uc_mem->total_size,
  3057. aux_uc_mem->vaddr, aux_uc_mem->paddr);
  3058. aux_uc_mem->vaddr = NULL;
  3059. aux_uc_mem->total_size = 0;
  3060. aux_uc_mem->size = 0;
  3061. }
  3062. static int ath12k_qmi_aux_uc_load(struct ath12k_base *ab)
  3063. {
  3064. struct m3_mem_region *aux_uc_mem = &ab->qmi.aux_uc_mem;
  3065. const struct firmware *fw = NULL;
  3066. const void *aux_uc_data;
  3067. char path[100];
  3068. size_t aux_uc_len;
  3069. int ret;
  3070. if (ab->fw.aux_uc_data && ab->fw.aux_uc_len > 0) {
  3071. /* firmware-N.bin had a aux_uc firmware file so use that */
  3072. aux_uc_data = ab->fw.aux_uc_data;
  3073. aux_uc_len = ab->fw.aux_uc_len;
  3074. } else {
  3075. /*
  3076. * No aux_uc file in firmware-N.bin so try to request old
  3077. * separate aux_ucode.bin.
  3078. */
  3079. fw = ath12k_core_firmware_request(ab, ATH12K_AUX_UC_FILE);
  3080. if (IS_ERR(fw)) {
  3081. ret = PTR_ERR(fw);
  3082. ath12k_core_create_firmware_path(ab, ATH12K_AUX_UC_FILE,
  3083. path, sizeof(path));
  3084. ath12k_err(ab, "failed to load %s: %d\n", path, ret);
  3085. return ret;
  3086. }
  3087. aux_uc_data = fw->data;
  3088. aux_uc_len = fw->size;
  3089. }
  3090. /* In recovery/resume cases, AUX_UC buffer is not freed, try to reuse that */
  3091. if (aux_uc_mem->vaddr) {
  3092. if (aux_uc_mem->total_size >= aux_uc_len)
  3093. goto copy;
  3094. /* Old buffer is too small, free and reallocate */
  3095. ath12k_qmi_aux_uc_free(ab);
  3096. }
  3097. aux_uc_mem->vaddr = dma_alloc_coherent(ab->dev, aux_uc_len,
  3098. &aux_uc_mem->paddr, GFP_KERNEL);
  3099. if (!aux_uc_mem->vaddr) {
  3100. ret = -ENOMEM;
  3101. goto out;
  3102. }
  3103. aux_uc_mem->total_size = aux_uc_len;
  3104. copy:
  3105. memcpy(aux_uc_mem->vaddr, aux_uc_data, aux_uc_len);
  3106. aux_uc_mem->size = aux_uc_len;
  3107. ret = 0;
  3108. out:
  3109. release_firmware(fw);
  3110. return ret;
  3111. }
  3112. static noinline_for_stack
  3113. int ath12k_qmi_wlanfw_aux_uc_info_send(struct ath12k_base *ab)
  3114. {
  3115. struct m3_mem_region *aux_uc_mem = &ab->qmi.aux_uc_mem;
  3116. struct qmi_wlanfw_aux_uc_info_req_msg_v01 req = {};
  3117. struct qmi_wlanfw_aux_uc_info_resp_msg_v01 resp = {};
  3118. struct qmi_txn txn;
  3119. int ret = 0;
  3120. ret = ath12k_qmi_aux_uc_load(ab);
  3121. if (ret) {
  3122. ath12k_err(ab, "failed to load aux_uc firmware: %d", ret);
  3123. return ret;
  3124. }
  3125. req.addr = aux_uc_mem->paddr;
  3126. req.size = aux_uc_mem->size;
  3127. ret = qmi_txn_init(&ab->qmi.handle, &txn,
  3128. qmi_wlanfw_aux_uc_info_resp_msg_v01_ei, &resp);
  3129. if (ret < 0)
  3130. goto out;
  3131. ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
  3132. QMI_WLANFW_AUX_UC_INFO_REQ_V01,
  3133. QMI_WLANFW_AUX_UC_INFO_REQ_MSG_V01_MAX_MSG_LEN,
  3134. qmi_wlanfw_aux_uc_info_req_msg_v01_ei, &req);
  3135. if (ret < 0) {
  3136. qmi_txn_cancel(&txn);
  3137. ath12k_warn(ab, "qmi failed to send AUX_UC information request, err = %d\n",
  3138. ret);
  3139. goto out;
  3140. }
  3141. ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH12K_QMI_WLANFW_TIMEOUT_MS));
  3142. if (ret < 0) {
  3143. ath12k_warn(ab, "qmi failed AUX_UC information request %d\n", ret);
  3144. goto out;
  3145. }
  3146. if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
  3147. ath12k_warn(ab, "qmi AUX_UC info request failed, result: %d, err: %d\n",
  3148. resp.resp.result, resp.resp.error);
  3149. ret = -EINVAL;
  3150. goto out;
  3151. }
  3152. out:
  3153. return ret;
  3154. }
  3155. static int ath12k_qmi_wlanfw_mode_send(struct ath12k_base *ab,
  3156. u32 mode)
  3157. {
  3158. struct qmi_wlanfw_wlan_mode_req_msg_v01 req = {};
  3159. struct qmi_wlanfw_wlan_mode_resp_msg_v01 resp = {};
  3160. struct qmi_txn txn;
  3161. int ret = 0;
  3162. req.mode = mode;
  3163. req.hw_debug_valid = 1;
  3164. req.hw_debug = 0;
  3165. ret = qmi_txn_init(&ab->qmi.handle, &txn,
  3166. qmi_wlanfw_wlan_mode_resp_msg_v01_ei, &resp);
  3167. if (ret < 0)
  3168. goto out;
  3169. ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
  3170. QMI_WLANFW_WLAN_MODE_REQ_V01,
  3171. QMI_WLANFW_WLAN_MODE_REQ_MSG_V01_MAX_LEN,
  3172. qmi_wlanfw_wlan_mode_req_msg_v01_ei, &req);
  3173. if (ret < 0) {
  3174. qmi_txn_cancel(&txn);
  3175. ath12k_warn(ab, "qmi failed to send mode request, mode: %d, err = %d\n",
  3176. mode, ret);
  3177. goto out;
  3178. }
  3179. ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH12K_QMI_WLANFW_TIMEOUT_MS));
  3180. if (ret < 0) {
  3181. if (mode == ATH12K_FIRMWARE_MODE_OFF && ret == -ENETRESET) {
  3182. ath12k_warn(ab, "WLFW service is dis-connected\n");
  3183. return 0;
  3184. }
  3185. ath12k_warn(ab, "qmi failed set mode request, mode: %d, err = %d\n",
  3186. mode, ret);
  3187. goto out;
  3188. }
  3189. if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
  3190. ath12k_warn(ab, "Mode request failed, mode: %d, result: %d err: %d\n",
  3191. mode, resp.resp.result, resp.resp.error);
  3192. ret = -EINVAL;
  3193. goto out;
  3194. }
  3195. out:
  3196. return ret;
  3197. }
  3198. static int ath12k_qmi_wlanfw_wlan_cfg_send(struct ath12k_base *ab)
  3199. {
  3200. struct qmi_wlanfw_wlan_cfg_req_msg_v01 *req;
  3201. struct qmi_wlanfw_wlan_cfg_resp_msg_v01 resp = {};
  3202. struct ce_pipe_config *ce_cfg;
  3203. struct service_to_pipe *svc_cfg;
  3204. struct qmi_txn txn;
  3205. int ret = 0, pipe_num;
  3206. ce_cfg = (struct ce_pipe_config *)ab->qmi.ce_cfg.tgt_ce;
  3207. svc_cfg = (struct service_to_pipe *)ab->qmi.ce_cfg.svc_to_ce_map;
  3208. req = kzalloc_obj(*req);
  3209. if (!req)
  3210. return -ENOMEM;
  3211. req->host_version_valid = 1;
  3212. strscpy(req->host_version, ATH12K_HOST_VERSION_STRING,
  3213. sizeof(req->host_version));
  3214. req->tgt_cfg_valid = 1;
  3215. /* This is number of CE configs */
  3216. req->tgt_cfg_len = ab->qmi.ce_cfg.tgt_ce_len;
  3217. for (pipe_num = 0; pipe_num < req->tgt_cfg_len ; pipe_num++) {
  3218. req->tgt_cfg[pipe_num].pipe_num =
  3219. __le32_to_cpu(ce_cfg[pipe_num].pipenum);
  3220. req->tgt_cfg[pipe_num].pipe_dir =
  3221. __le32_to_cpu(ce_cfg[pipe_num].pipedir);
  3222. req->tgt_cfg[pipe_num].nentries =
  3223. __le32_to_cpu(ce_cfg[pipe_num].nentries);
  3224. req->tgt_cfg[pipe_num].nbytes_max =
  3225. __le32_to_cpu(ce_cfg[pipe_num].nbytes_max);
  3226. req->tgt_cfg[pipe_num].flags =
  3227. __le32_to_cpu(ce_cfg[pipe_num].flags);
  3228. }
  3229. req->svc_cfg_valid = 1;
  3230. /* This is number of Service/CE configs */
  3231. req->svc_cfg_len = ab->qmi.ce_cfg.svc_to_ce_map_len;
  3232. for (pipe_num = 0; pipe_num < req->svc_cfg_len; pipe_num++) {
  3233. req->svc_cfg[pipe_num].service_id =
  3234. __le32_to_cpu(svc_cfg[pipe_num].service_id);
  3235. req->svc_cfg[pipe_num].pipe_dir =
  3236. __le32_to_cpu(svc_cfg[pipe_num].pipedir);
  3237. req->svc_cfg[pipe_num].pipe_num =
  3238. __le32_to_cpu(svc_cfg[pipe_num].pipenum);
  3239. }
  3240. /* set shadow v3 configuration */
  3241. if (ab->hw_params->supports_shadow_regs) {
  3242. req->shadow_reg_v3_valid = 1;
  3243. req->shadow_reg_v3_len = min_t(u32,
  3244. ab->qmi.ce_cfg.shadow_reg_v3_len,
  3245. QMI_WLANFW_MAX_NUM_SHADOW_REG_V3_V01);
  3246. memcpy(&req->shadow_reg_v3, ab->qmi.ce_cfg.shadow_reg_v3,
  3247. sizeof(u32) * req->shadow_reg_v3_len);
  3248. } else {
  3249. req->shadow_reg_v3_valid = 0;
  3250. }
  3251. ret = qmi_txn_init(&ab->qmi.handle, &txn,
  3252. qmi_wlanfw_wlan_cfg_resp_msg_v01_ei, &resp);
  3253. if (ret < 0)
  3254. goto out;
  3255. ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
  3256. QMI_WLANFW_WLAN_CFG_REQ_V01,
  3257. QMI_WLANFW_WLAN_CFG_REQ_MSG_V01_MAX_LEN,
  3258. qmi_wlanfw_wlan_cfg_req_msg_v01_ei, req);
  3259. if (ret < 0) {
  3260. qmi_txn_cancel(&txn);
  3261. ath12k_warn(ab, "qmi failed to send wlan config request, err = %d\n",
  3262. ret);
  3263. goto out;
  3264. }
  3265. ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH12K_QMI_WLANFW_TIMEOUT_MS));
  3266. if (ret < 0) {
  3267. ath12k_warn(ab, "qmi failed wlan config request, err = %d\n", ret);
  3268. goto out;
  3269. }
  3270. if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
  3271. ath12k_warn(ab, "qmi wlan config request failed, result: %d, err: %d\n",
  3272. resp.resp.result, resp.resp.error);
  3273. ret = -EINVAL;
  3274. goto out;
  3275. }
  3276. out:
  3277. kfree(req);
  3278. return ret;
  3279. }
  3280. static int ath12k_qmi_wlanfw_wlan_ini_send(struct ath12k_base *ab)
  3281. {
  3282. struct qmi_wlanfw_wlan_ini_resp_msg_v01 resp = {};
  3283. struct qmi_wlanfw_wlan_ini_req_msg_v01 req = {};
  3284. struct qmi_txn txn;
  3285. int ret;
  3286. req.enable_fwlog_valid = true;
  3287. req.enable_fwlog = 1;
  3288. ret = qmi_txn_init(&ab->qmi.handle, &txn,
  3289. qmi_wlanfw_wlan_ini_resp_msg_v01_ei, &resp);
  3290. if (ret < 0)
  3291. goto out;
  3292. ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
  3293. ATH12K_QMI_WLANFW_WLAN_INI_REQ_V01,
  3294. QMI_WLANFW_WLAN_INI_REQ_MSG_V01_MAX_LEN,
  3295. qmi_wlanfw_wlan_ini_req_msg_v01_ei, &req);
  3296. if (ret < 0) {
  3297. qmi_txn_cancel(&txn);
  3298. ath12k_warn(ab, "failed to send QMI wlan ini request: %d\n",
  3299. ret);
  3300. goto out;
  3301. }
  3302. ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH12K_QMI_WLANFW_TIMEOUT_MS));
  3303. if (ret < 0) {
  3304. ath12k_warn(ab, "failed to receive QMI wlan ini request: %d\n", ret);
  3305. goto out;
  3306. }
  3307. if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
  3308. ath12k_warn(ab, "QMI wlan ini response failure: %d %d\n",
  3309. resp.resp.result, resp.resp.error);
  3310. ret = -EINVAL;
  3311. goto out;
  3312. }
  3313. out:
  3314. return ret;
  3315. }
  3316. void ath12k_qmi_firmware_stop(struct ath12k_base *ab)
  3317. {
  3318. int ret;
  3319. clear_bit(ATH12K_FLAG_QMI_FW_READY_COMPLETE, &ab->dev_flags);
  3320. ret = ath12k_qmi_wlanfw_mode_send(ab, ATH12K_FIRMWARE_MODE_OFF);
  3321. if (ret < 0) {
  3322. ath12k_warn(ab, "qmi failed to send wlan mode off\n");
  3323. return;
  3324. }
  3325. }
  3326. int ath12k_qmi_firmware_start(struct ath12k_base *ab,
  3327. u32 mode)
  3328. {
  3329. int ret;
  3330. ret = ath12k_qmi_wlanfw_wlan_ini_send(ab);
  3331. if (ret < 0) {
  3332. ath12k_warn(ab, "qmi failed to send wlan fw ini: %d\n", ret);
  3333. return ret;
  3334. }
  3335. ret = ath12k_qmi_wlanfw_wlan_cfg_send(ab);
  3336. if (ret < 0) {
  3337. ath12k_warn(ab, "qmi failed to send wlan cfg:%d\n", ret);
  3338. return ret;
  3339. }
  3340. ret = ath12k_qmi_wlanfw_mode_send(ab, mode);
  3341. if (ret < 0) {
  3342. ath12k_warn(ab, "qmi failed to send wlan fw mode:%d\n", ret);
  3343. return ret;
  3344. }
  3345. return 0;
  3346. }
  3347. static int
  3348. ath12k_qmi_driver_event_post(struct ath12k_qmi *qmi,
  3349. enum ath12k_qmi_event_type type,
  3350. void *data)
  3351. {
  3352. struct ath12k_qmi_driver_event *event;
  3353. event = kzalloc_obj(*event, GFP_ATOMIC);
  3354. if (!event)
  3355. return -ENOMEM;
  3356. event->type = type;
  3357. event->data = data;
  3358. spin_lock(&qmi->event_lock);
  3359. list_add_tail(&event->list, &qmi->event_list);
  3360. spin_unlock(&qmi->event_lock);
  3361. queue_work(qmi->event_wq, &qmi->event_work);
  3362. return 0;
  3363. }
  3364. void ath12k_qmi_trigger_host_cap(struct ath12k_base *ab)
  3365. {
  3366. struct ath12k_qmi *qmi = &ab->qmi;
  3367. spin_lock(&qmi->event_lock);
  3368. if (ath12k_qmi_get_event_block(qmi))
  3369. ath12k_qmi_set_event_block(qmi, false);
  3370. spin_unlock(&qmi->event_lock);
  3371. ath12k_dbg(ab, ATH12K_DBG_QMI, "trigger host cap for device id %d\n",
  3372. ab->device_id);
  3373. ath12k_qmi_driver_event_post(qmi, ATH12K_QMI_EVENT_HOST_CAP, NULL);
  3374. }
  3375. static bool ath12k_qmi_hw_group_host_cap_ready(struct ath12k_hw_group *ag)
  3376. {
  3377. struct ath12k_base *ab;
  3378. int i;
  3379. for (i = 0; i < ag->num_devices; i++) {
  3380. ab = ag->ab[i];
  3381. if (!(ab && ab->qmi.num_radios != U8_MAX))
  3382. return false;
  3383. }
  3384. return true;
  3385. }
  3386. static struct ath12k_base *ath12k_qmi_hw_group_find_blocked(struct ath12k_hw_group *ag)
  3387. {
  3388. struct ath12k_base *ab;
  3389. int i;
  3390. lockdep_assert_held(&ag->mutex);
  3391. for (i = 0; i < ag->num_devices; i++) {
  3392. ab = ag->ab[i];
  3393. if (!ab)
  3394. continue;
  3395. spin_lock(&ab->qmi.event_lock);
  3396. if (ath12k_qmi_get_event_block(&ab->qmi)) {
  3397. spin_unlock(&ab->qmi.event_lock);
  3398. return ab;
  3399. }
  3400. spin_unlock(&ab->qmi.event_lock);
  3401. }
  3402. return NULL;
  3403. }
  3404. /* clang stack usage explodes if this is inlined */
  3405. static noinline_for_stack
  3406. int ath12k_qmi_event_server_arrive(struct ath12k_qmi *qmi)
  3407. {
  3408. struct ath12k_base *ab = qmi->ab, *block_ab;
  3409. struct ath12k_hw_group *ag = ab->ag;
  3410. int ret;
  3411. ath12k_qmi_phy_cap_send(ab);
  3412. ret = ath12k_qmi_fw_ind_register_send(ab);
  3413. if (ret < 0) {
  3414. ath12k_warn(ab, "qmi failed to send FW indication QMI:%d\n", ret);
  3415. return ret;
  3416. }
  3417. spin_lock(&qmi->event_lock);
  3418. ath12k_qmi_set_event_block(qmi, true);
  3419. spin_unlock(&qmi->event_lock);
  3420. mutex_lock(&ag->mutex);
  3421. if (ath12k_qmi_hw_group_host_cap_ready(ag)) {
  3422. ath12k_core_hw_group_set_mlo_capable(ag);
  3423. block_ab = ath12k_qmi_hw_group_find_blocked(ag);
  3424. if (block_ab)
  3425. ath12k_qmi_trigger_host_cap(block_ab);
  3426. }
  3427. mutex_unlock(&ag->mutex);
  3428. return ret;
  3429. }
  3430. /* clang stack usage explodes if this is inlined */
  3431. static noinline_for_stack
  3432. int ath12k_qmi_event_mem_request(struct ath12k_qmi *qmi)
  3433. {
  3434. struct ath12k_base *ab = qmi->ab;
  3435. int ret;
  3436. ret = ath12k_qmi_respond_fw_mem_request(ab);
  3437. if (ret < 0) {
  3438. ath12k_warn(ab, "qmi failed to respond fw mem req:%d\n", ret);
  3439. return ret;
  3440. }
  3441. return ret;
  3442. }
  3443. /* clang stack usage explodes if this is inlined */
  3444. static noinline_for_stack
  3445. int ath12k_qmi_event_load_bdf(struct ath12k_qmi *qmi)
  3446. {
  3447. struct ath12k_base *ab = qmi->ab;
  3448. const struct ath12k_hw_params *hw_params = ab->hw_params;
  3449. int ret;
  3450. ret = ath12k_qmi_request_target_cap(ab);
  3451. if (ret < 0) {
  3452. ath12k_warn(ab, "qmi failed to req target capabilities:%d\n", ret);
  3453. return ret;
  3454. }
  3455. ret = ath12k_qmi_load_bdf_qmi(ab, ATH12K_QMI_BDF_TYPE_REGDB);
  3456. if (ret < 0) {
  3457. ath12k_warn(ab, "qmi failed to load regdb file:%d\n", ret);
  3458. return ret;
  3459. }
  3460. ret = ath12k_qmi_load_bdf_qmi(ab, ATH12K_QMI_BDF_TYPE_ELF);
  3461. if (ret < 0) {
  3462. ath12k_warn(ab, "qmi failed to load board data file:%d\n", ret);
  3463. return ret;
  3464. }
  3465. if (hw_params->download_calib) {
  3466. ret = ath12k_qmi_load_bdf_qmi(ab, ATH12K_QMI_BDF_TYPE_CALIBRATION);
  3467. if (ret < 0)
  3468. ath12k_warn(ab, "qmi failed to load calibrated data :%d\n", ret);
  3469. }
  3470. ret = ath12k_qmi_wlanfw_m3_info_send(ab);
  3471. if (ret < 0) {
  3472. ath12k_warn(ab, "qmi failed to send m3 info req:%d\n", ret);
  3473. return ret;
  3474. }
  3475. if (hw_params->fw.download_aux_ucode) {
  3476. ret = ath12k_qmi_wlanfw_aux_uc_info_send(ab);
  3477. if (ret < 0) {
  3478. ath12k_warn(ab, "qmi failed to send aux_uc info req: %d\n", ret);
  3479. return ret;
  3480. }
  3481. }
  3482. return ret;
  3483. }
  3484. static void ath12k_qmi_msg_mem_request_cb(struct qmi_handle *qmi_hdl,
  3485. struct sockaddr_qrtr *sq,
  3486. struct qmi_txn *txn,
  3487. const void *data)
  3488. {
  3489. struct ath12k_qmi *qmi = container_of(qmi_hdl, struct ath12k_qmi, handle);
  3490. struct ath12k_base *ab = qmi->ab;
  3491. const struct qmi_wlanfw_request_mem_ind_msg_v01 *msg = data;
  3492. int i, ret;
  3493. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi firmware request memory request\n");
  3494. if (msg->mem_seg_len == 0 ||
  3495. msg->mem_seg_len > ATH12K_QMI_WLANFW_MAX_NUM_MEM_SEG_V01)
  3496. ath12k_warn(ab, "Invalid memory segment length: %u\n",
  3497. msg->mem_seg_len);
  3498. ab->qmi.mem_seg_count = msg->mem_seg_len;
  3499. for (i = 0; i < qmi->mem_seg_count ; i++) {
  3500. ab->qmi.target_mem[i].type = msg->mem_seg[i].type;
  3501. ab->qmi.target_mem[i].size = msg->mem_seg[i].size;
  3502. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi mem seg type %d size %d\n",
  3503. msg->mem_seg[i].type, msg->mem_seg[i].size);
  3504. }
  3505. if (test_bit(ATH12K_FLAG_FIXED_MEM_REGION, &ab->dev_flags)) {
  3506. ret = ath12k_qmi_assign_target_mem_chunk(ab);
  3507. if (ret) {
  3508. ath12k_warn(ab, "failed to assign qmi target memory: %d\n",
  3509. ret);
  3510. return;
  3511. }
  3512. } else {
  3513. ret = ath12k_qmi_alloc_target_mem_chunk(ab);
  3514. if (ret) {
  3515. ath12k_warn(ab, "qmi failed to alloc target memory: %d\n",
  3516. ret);
  3517. return;
  3518. }
  3519. }
  3520. ath12k_qmi_driver_event_post(qmi, ATH12K_QMI_EVENT_REQUEST_MEM, NULL);
  3521. }
  3522. static void ath12k_qmi_msg_mem_ready_cb(struct qmi_handle *qmi_hdl,
  3523. struct sockaddr_qrtr *sq,
  3524. struct qmi_txn *txn,
  3525. const void *decoded)
  3526. {
  3527. struct ath12k_qmi *qmi = container_of(qmi_hdl, struct ath12k_qmi, handle);
  3528. struct ath12k_base *ab = qmi->ab;
  3529. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi firmware memory ready indication\n");
  3530. ath12k_qmi_driver_event_post(qmi, ATH12K_QMI_EVENT_FW_MEM_READY, NULL);
  3531. }
  3532. static void ath12k_qmi_msg_fw_ready_cb(struct qmi_handle *qmi_hdl,
  3533. struct sockaddr_qrtr *sq,
  3534. struct qmi_txn *txn,
  3535. const void *decoded)
  3536. {
  3537. struct ath12k_qmi *qmi = container_of(qmi_hdl, struct ath12k_qmi, handle);
  3538. struct ath12k_base *ab = qmi->ab;
  3539. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi firmware ready\n");
  3540. ath12k_qmi_driver_event_post(qmi, ATH12K_QMI_EVENT_FW_READY, NULL);
  3541. }
  3542. static const struct qmi_msg_handler ath12k_qmi_msg_handlers[] = {
  3543. {
  3544. .type = QMI_INDICATION,
  3545. .msg_id = QMI_WLFW_REQUEST_MEM_IND_V01,
  3546. .ei = qmi_wlanfw_request_mem_ind_msg_v01_ei,
  3547. .decoded_size = sizeof(struct qmi_wlanfw_request_mem_ind_msg_v01),
  3548. .fn = ath12k_qmi_msg_mem_request_cb,
  3549. },
  3550. {
  3551. .type = QMI_INDICATION,
  3552. .msg_id = QMI_WLFW_FW_MEM_READY_IND_V01,
  3553. .ei = qmi_wlanfw_mem_ready_ind_msg_v01_ei,
  3554. .decoded_size = sizeof(struct qmi_wlanfw_fw_mem_ready_ind_msg_v01),
  3555. .fn = ath12k_qmi_msg_mem_ready_cb,
  3556. },
  3557. {
  3558. .type = QMI_INDICATION,
  3559. .msg_id = QMI_WLFW_FW_READY_IND_V01,
  3560. .ei = qmi_wlanfw_fw_ready_ind_msg_v01_ei,
  3561. .decoded_size = sizeof(struct qmi_wlanfw_fw_ready_ind_msg_v01),
  3562. .fn = ath12k_qmi_msg_fw_ready_cb,
  3563. },
  3564. /* end of list */
  3565. {},
  3566. };
  3567. static int ath12k_qmi_ops_new_server(struct qmi_handle *qmi_hdl,
  3568. struct qmi_service *service)
  3569. {
  3570. struct ath12k_qmi *qmi = container_of(qmi_hdl, struct ath12k_qmi, handle);
  3571. struct ath12k_base *ab = qmi->ab;
  3572. struct sockaddr_qrtr *sq = &qmi->sq;
  3573. int ret;
  3574. sq->sq_family = AF_QIPCRTR;
  3575. sq->sq_node = service->node;
  3576. sq->sq_port = service->port;
  3577. ret = kernel_connect(qmi_hdl->sock, (struct sockaddr_unsized *)sq,
  3578. sizeof(*sq), 0);
  3579. if (ret) {
  3580. ath12k_warn(ab, "qmi failed to connect to remote service %d\n", ret);
  3581. return ret;
  3582. }
  3583. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi wifi fw qmi service connected\n");
  3584. ath12k_qmi_driver_event_post(qmi, ATH12K_QMI_EVENT_SERVER_ARRIVE, NULL);
  3585. return ret;
  3586. }
  3587. static void ath12k_qmi_ops_del_server(struct qmi_handle *qmi_hdl,
  3588. struct qmi_service *service)
  3589. {
  3590. struct ath12k_qmi *qmi = container_of(qmi_hdl, struct ath12k_qmi, handle);
  3591. struct ath12k_base *ab = qmi->ab;
  3592. ath12k_dbg(ab, ATH12K_DBG_QMI, "qmi wifi fw del server\n");
  3593. ath12k_qmi_driver_event_post(qmi, ATH12K_QMI_EVENT_SERVER_EXIT, NULL);
  3594. }
  3595. static const struct qmi_ops ath12k_qmi_ops = {
  3596. .new_server = ath12k_qmi_ops_new_server,
  3597. .del_server = ath12k_qmi_ops_del_server,
  3598. };
  3599. static int ath12k_qmi_event_host_cap(struct ath12k_qmi *qmi)
  3600. {
  3601. struct ath12k_base *ab = qmi->ab;
  3602. int ret;
  3603. ret = ath12k_qmi_host_cap_send(ab);
  3604. if (ret < 0) {
  3605. ath12k_warn(ab, "failed to send qmi host cap for device id %d: %d\n",
  3606. ab->device_id, ret);
  3607. return ret;
  3608. }
  3609. return ret;
  3610. }
  3611. static void ath12k_qmi_driver_event_work(struct work_struct *work)
  3612. {
  3613. struct ath12k_qmi *qmi = container_of(work, struct ath12k_qmi,
  3614. event_work);
  3615. struct ath12k_qmi_driver_event *event;
  3616. struct ath12k_base *ab = qmi->ab;
  3617. int ret;
  3618. spin_lock(&qmi->event_lock);
  3619. while (!list_empty(&qmi->event_list)) {
  3620. event = list_first_entry(&qmi->event_list,
  3621. struct ath12k_qmi_driver_event, list);
  3622. list_del(&event->list);
  3623. spin_unlock(&qmi->event_lock);
  3624. if (test_bit(ATH12K_FLAG_UNREGISTERING, &ab->dev_flags))
  3625. goto skip;
  3626. switch (event->type) {
  3627. case ATH12K_QMI_EVENT_SERVER_ARRIVE:
  3628. ret = ath12k_qmi_event_server_arrive(qmi);
  3629. if (ret < 0)
  3630. set_bit(ATH12K_FLAG_QMI_FAIL, &ab->dev_flags);
  3631. break;
  3632. case ATH12K_QMI_EVENT_SERVER_EXIT:
  3633. set_bit(ATH12K_FLAG_CRASH_FLUSH, &ab->dev_flags);
  3634. break;
  3635. case ATH12K_QMI_EVENT_REQUEST_MEM:
  3636. ret = ath12k_qmi_event_mem_request(qmi);
  3637. if (ret < 0)
  3638. set_bit(ATH12K_FLAG_QMI_FAIL, &ab->dev_flags);
  3639. break;
  3640. case ATH12K_QMI_EVENT_FW_MEM_READY:
  3641. ret = ath12k_qmi_event_load_bdf(qmi);
  3642. if (ret < 0)
  3643. set_bit(ATH12K_FLAG_QMI_FAIL, &ab->dev_flags);
  3644. break;
  3645. case ATH12K_QMI_EVENT_FW_READY:
  3646. clear_bit(ATH12K_FLAG_QMI_FAIL, &ab->dev_flags);
  3647. if (test_bit(ATH12K_FLAG_QMI_FW_READY_COMPLETE, &ab->dev_flags)) {
  3648. if (ab->is_reset)
  3649. ath12k_hal_dump_srng_stats(ab);
  3650. set_bit(ATH12K_FLAG_RECOVERY, &ab->dev_flags);
  3651. queue_work(ab->workqueue, &ab->restart_work);
  3652. break;
  3653. }
  3654. clear_bit(ATH12K_FLAG_CRASH_FLUSH,
  3655. &ab->dev_flags);
  3656. ret = ath12k_core_qmi_firmware_ready(ab);
  3657. if (!ret)
  3658. set_bit(ATH12K_FLAG_QMI_FW_READY_COMPLETE,
  3659. &ab->dev_flags);
  3660. break;
  3661. case ATH12K_QMI_EVENT_HOST_CAP:
  3662. ret = ath12k_qmi_event_host_cap(qmi);
  3663. if (ret < 0)
  3664. set_bit(ATH12K_FLAG_QMI_FAIL, &ab->dev_flags);
  3665. break;
  3666. default:
  3667. ath12k_warn(ab, "invalid event type: %d", event->type);
  3668. break;
  3669. }
  3670. skip:
  3671. kfree(event);
  3672. spin_lock(&qmi->event_lock);
  3673. }
  3674. spin_unlock(&qmi->event_lock);
  3675. }
  3676. int ath12k_qmi_init_service(struct ath12k_base *ab)
  3677. {
  3678. int ret;
  3679. memset(&ab->qmi.target, 0, sizeof(struct target_info));
  3680. memset(&ab->qmi.target_mem, 0, sizeof(struct target_mem_chunk));
  3681. ab->qmi.ab = ab;
  3682. ab->qmi.target_mem_mode = ab->target_mem_mode;
  3683. ret = qmi_handle_init(&ab->qmi.handle, ATH12K_QMI_RESP_LEN_MAX,
  3684. &ath12k_qmi_ops, ath12k_qmi_msg_handlers);
  3685. if (ret < 0) {
  3686. ath12k_warn(ab, "failed to initialize qmi handle\n");
  3687. return ret;
  3688. }
  3689. ab->qmi.event_wq = alloc_ordered_workqueue("ath12k_qmi_driver_event", 0);
  3690. if (!ab->qmi.event_wq) {
  3691. ath12k_err(ab, "failed to allocate workqueue\n");
  3692. return -EFAULT;
  3693. }
  3694. INIT_LIST_HEAD(&ab->qmi.event_list);
  3695. spin_lock_init(&ab->qmi.event_lock);
  3696. INIT_WORK(&ab->qmi.event_work, ath12k_qmi_driver_event_work);
  3697. ret = qmi_add_lookup(&ab->qmi.handle, ATH12K_QMI_WLFW_SERVICE_ID_V01,
  3698. ATH12K_QMI_WLFW_SERVICE_VERS_V01,
  3699. ab->qmi.service_ins_id);
  3700. if (ret < 0) {
  3701. ath12k_warn(ab, "failed to add qmi lookup\n");
  3702. destroy_workqueue(ab->qmi.event_wq);
  3703. return ret;
  3704. }
  3705. return ret;
  3706. }
  3707. void ath12k_qmi_deinit_service(struct ath12k_base *ab)
  3708. {
  3709. if (!ab->qmi.ab)
  3710. return;
  3711. qmi_handle_release(&ab->qmi.handle);
  3712. cancel_work_sync(&ab->qmi.event_work);
  3713. destroy_workqueue(ab->qmi.event_wq);
  3714. ath12k_qmi_aux_uc_free(ab);
  3715. ath12k_qmi_m3_free(ab);
  3716. ath12k_qmi_free_target_mem_chunk(ab);
  3717. ab->qmi.ab = NULL;
  3718. }
  3719. void ath12k_qmi_free_resource(struct ath12k_base *ab)
  3720. {
  3721. ath12k_qmi_free_target_mem_chunk(ab);
  3722. ath12k_qmi_aux_uc_free(ab);
  3723. ath12k_qmi_m3_free(ab);
  3724. }