hal.c 43 KB

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  1. // SPDX-License-Identifier: BSD-3-Clause-Clear
  2. /*
  3. * Copyright (c) 2018-2019 The Linux Foundation. All rights reserved.
  4. * Copyright (c) Qualcomm Technologies, Inc. and/or its subsidiaries.
  5. */
  6. #include <linux/dma-mapping.h>
  7. #include <linux/export.h>
  8. #include "hal_tx.h"
  9. #include "debug.h"
  10. #include "hal_desc.h"
  11. #include "hif.h"
  12. static const struct hal_srng_config hw_srng_config_template[] = {
  13. /* TODO: max_rings can populated by querying HW capabilities */
  14. { /* REO_DST */
  15. .start_ring_id = HAL_SRNG_RING_ID_REO2SW1,
  16. .max_rings = 4,
  17. .entry_size = sizeof(struct hal_reo_dest_ring) >> 2,
  18. .lmac_ring = false,
  19. .ring_dir = HAL_SRNG_DIR_DST,
  20. .max_size = HAL_REO_REO2SW1_RING_BASE_MSB_RING_SIZE,
  21. },
  22. { /* REO_EXCEPTION */
  23. /* Designating REO2TCL ring as exception ring. This ring is
  24. * similar to other REO2SW rings though it is named as REO2TCL.
  25. * Any of theREO2SW rings can be used as exception ring.
  26. */
  27. .start_ring_id = HAL_SRNG_RING_ID_REO2TCL,
  28. .max_rings = 1,
  29. .entry_size = sizeof(struct hal_reo_dest_ring) >> 2,
  30. .lmac_ring = false,
  31. .ring_dir = HAL_SRNG_DIR_DST,
  32. .max_size = HAL_REO_REO2TCL_RING_BASE_MSB_RING_SIZE,
  33. },
  34. { /* REO_REINJECT */
  35. .start_ring_id = HAL_SRNG_RING_ID_SW2REO,
  36. .max_rings = 1,
  37. .entry_size = sizeof(struct hal_reo_entrance_ring) >> 2,
  38. .lmac_ring = false,
  39. .ring_dir = HAL_SRNG_DIR_SRC,
  40. .max_size = HAL_REO_SW2REO_RING_BASE_MSB_RING_SIZE,
  41. },
  42. { /* REO_CMD */
  43. .start_ring_id = HAL_SRNG_RING_ID_REO_CMD,
  44. .max_rings = 1,
  45. .entry_size = (sizeof(struct hal_tlv_hdr) +
  46. sizeof(struct hal_reo_get_queue_stats)) >> 2,
  47. .lmac_ring = false,
  48. .ring_dir = HAL_SRNG_DIR_SRC,
  49. .max_size = HAL_REO_CMD_RING_BASE_MSB_RING_SIZE,
  50. },
  51. { /* REO_STATUS */
  52. .start_ring_id = HAL_SRNG_RING_ID_REO_STATUS,
  53. .max_rings = 1,
  54. .entry_size = (sizeof(struct hal_tlv_hdr) +
  55. sizeof(struct hal_reo_get_queue_stats_status)) >> 2,
  56. .lmac_ring = false,
  57. .ring_dir = HAL_SRNG_DIR_DST,
  58. .max_size = HAL_REO_STATUS_RING_BASE_MSB_RING_SIZE,
  59. },
  60. { /* TCL_DATA */
  61. .start_ring_id = HAL_SRNG_RING_ID_SW2TCL1,
  62. .max_rings = 3,
  63. .entry_size = (sizeof(struct hal_tlv_hdr) +
  64. sizeof(struct hal_tcl_data_cmd)) >> 2,
  65. .lmac_ring = false,
  66. .ring_dir = HAL_SRNG_DIR_SRC,
  67. .max_size = HAL_SW2TCL1_RING_BASE_MSB_RING_SIZE,
  68. },
  69. { /* TCL_CMD */
  70. .start_ring_id = HAL_SRNG_RING_ID_SW2TCL_CMD,
  71. .max_rings = 1,
  72. .entry_size = (sizeof(struct hal_tlv_hdr) +
  73. sizeof(struct hal_tcl_gse_cmd)) >> 2,
  74. .lmac_ring = false,
  75. .ring_dir = HAL_SRNG_DIR_SRC,
  76. .max_size = HAL_SW2TCL1_CMD_RING_BASE_MSB_RING_SIZE,
  77. },
  78. { /* TCL_STATUS */
  79. .start_ring_id = HAL_SRNG_RING_ID_TCL_STATUS,
  80. .max_rings = 1,
  81. .entry_size = (sizeof(struct hal_tlv_hdr) +
  82. sizeof(struct hal_tcl_status_ring)) >> 2,
  83. .lmac_ring = false,
  84. .ring_dir = HAL_SRNG_DIR_DST,
  85. .max_size = HAL_TCL_STATUS_RING_BASE_MSB_RING_SIZE,
  86. },
  87. { /* CE_SRC */
  88. .start_ring_id = HAL_SRNG_RING_ID_CE0_SRC,
  89. .max_rings = 12,
  90. .entry_size = sizeof(struct hal_ce_srng_src_desc) >> 2,
  91. .lmac_ring = false,
  92. .ring_dir = HAL_SRNG_DIR_SRC,
  93. .max_size = HAL_CE_SRC_RING_BASE_MSB_RING_SIZE,
  94. },
  95. { /* CE_DST */
  96. .start_ring_id = HAL_SRNG_RING_ID_CE0_DST,
  97. .max_rings = 12,
  98. .entry_size = sizeof(struct hal_ce_srng_dest_desc) >> 2,
  99. .lmac_ring = false,
  100. .ring_dir = HAL_SRNG_DIR_SRC,
  101. .max_size = HAL_CE_DST_RING_BASE_MSB_RING_SIZE,
  102. },
  103. { /* CE_DST_STATUS */
  104. .start_ring_id = HAL_SRNG_RING_ID_CE0_DST_STATUS,
  105. .max_rings = 12,
  106. .entry_size = sizeof(struct hal_ce_srng_dst_status_desc) >> 2,
  107. .lmac_ring = false,
  108. .ring_dir = HAL_SRNG_DIR_DST,
  109. .max_size = HAL_CE_DST_STATUS_RING_BASE_MSB_RING_SIZE,
  110. },
  111. { /* WBM_IDLE_LINK */
  112. .start_ring_id = HAL_SRNG_RING_ID_WBM_IDLE_LINK,
  113. .max_rings = 1,
  114. .entry_size = sizeof(struct hal_wbm_link_desc) >> 2,
  115. .lmac_ring = false,
  116. .ring_dir = HAL_SRNG_DIR_SRC,
  117. .max_size = HAL_WBM_IDLE_LINK_RING_BASE_MSB_RING_SIZE,
  118. },
  119. { /* SW2WBM_RELEASE */
  120. .start_ring_id = HAL_SRNG_RING_ID_WBM_SW_RELEASE,
  121. .max_rings = 1,
  122. .entry_size = sizeof(struct hal_wbm_release_ring) >> 2,
  123. .lmac_ring = false,
  124. .ring_dir = HAL_SRNG_DIR_SRC,
  125. .max_size = HAL_SW2WBM_RELEASE_RING_BASE_MSB_RING_SIZE,
  126. },
  127. { /* WBM2SW_RELEASE */
  128. .start_ring_id = HAL_SRNG_RING_ID_WBM2SW0_RELEASE,
  129. .max_rings = 5,
  130. .entry_size = sizeof(struct hal_wbm_release_ring) >> 2,
  131. .lmac_ring = false,
  132. .ring_dir = HAL_SRNG_DIR_DST,
  133. .max_size = HAL_WBM2SW_RELEASE_RING_BASE_MSB_RING_SIZE,
  134. },
  135. { /* RXDMA_BUF */
  136. .start_ring_id = HAL_SRNG_RING_ID_WMAC1_SW2RXDMA0_BUF,
  137. .max_rings = 2,
  138. .entry_size = sizeof(struct hal_wbm_buffer_ring) >> 2,
  139. .lmac_ring = true,
  140. .ring_dir = HAL_SRNG_DIR_SRC,
  141. .max_size = HAL_RXDMA_RING_MAX_SIZE,
  142. },
  143. { /* RXDMA_DST */
  144. .start_ring_id = HAL_SRNG_RING_ID_WMAC1_RXDMA2SW0,
  145. .max_rings = 1,
  146. .entry_size = sizeof(struct hal_reo_entrance_ring) >> 2,
  147. .lmac_ring = true,
  148. .ring_dir = HAL_SRNG_DIR_DST,
  149. .max_size = HAL_RXDMA_RING_MAX_SIZE,
  150. },
  151. { /* RXDMA_MONITOR_BUF */
  152. .start_ring_id = HAL_SRNG_RING_ID_WMAC1_SW2RXDMA2_BUF,
  153. .max_rings = 1,
  154. .entry_size = sizeof(struct hal_wbm_buffer_ring) >> 2,
  155. .lmac_ring = true,
  156. .ring_dir = HAL_SRNG_DIR_SRC,
  157. .max_size = HAL_RXDMA_RING_MAX_SIZE,
  158. },
  159. { /* RXDMA_MONITOR_STATUS */
  160. .start_ring_id = HAL_SRNG_RING_ID_WMAC1_SW2RXDMA1_STATBUF,
  161. .max_rings = 1,
  162. .entry_size = sizeof(struct hal_wbm_buffer_ring) >> 2,
  163. .lmac_ring = true,
  164. .ring_dir = HAL_SRNG_DIR_SRC,
  165. .max_size = HAL_RXDMA_RING_MAX_SIZE,
  166. },
  167. { /* RXDMA_MONITOR_DST */
  168. .start_ring_id = HAL_SRNG_RING_ID_WMAC1_RXDMA2SW1,
  169. .max_rings = 1,
  170. .entry_size = sizeof(struct hal_reo_entrance_ring) >> 2,
  171. .lmac_ring = true,
  172. .ring_dir = HAL_SRNG_DIR_DST,
  173. .max_size = HAL_RXDMA_RING_MAX_SIZE,
  174. },
  175. { /* RXDMA_MONITOR_DESC */
  176. .start_ring_id = HAL_SRNG_RING_ID_WMAC1_SW2RXDMA1_DESC,
  177. .max_rings = 1,
  178. .entry_size = sizeof(struct hal_wbm_buffer_ring) >> 2,
  179. .lmac_ring = true,
  180. .ring_dir = HAL_SRNG_DIR_SRC,
  181. .max_size = HAL_RXDMA_RING_MAX_SIZE,
  182. },
  183. { /* RXDMA DIR BUF */
  184. .start_ring_id = HAL_SRNG_RING_ID_RXDMA_DIR_BUF,
  185. .max_rings = 2,
  186. .entry_size = 8 >> 2, /* TODO: Define the struct */
  187. .lmac_ring = true,
  188. .ring_dir = HAL_SRNG_DIR_SRC,
  189. .max_size = HAL_RXDMA_RING_MAX_SIZE,
  190. },
  191. };
  192. static int ath11k_hal_alloc_cont_rdp(struct ath11k_base *ab)
  193. {
  194. struct ath11k_hal *hal = &ab->hal;
  195. size_t size;
  196. size = sizeof(u32) * HAL_SRNG_RING_ID_MAX;
  197. hal->rdp.vaddr = dma_alloc_coherent(ab->dev, size, &hal->rdp.paddr,
  198. GFP_KERNEL);
  199. if (!hal->rdp.vaddr)
  200. return -ENOMEM;
  201. return 0;
  202. }
  203. static void ath11k_hal_free_cont_rdp(struct ath11k_base *ab)
  204. {
  205. struct ath11k_hal *hal = &ab->hal;
  206. size_t size;
  207. if (!hal->rdp.vaddr)
  208. return;
  209. size = sizeof(u32) * HAL_SRNG_RING_ID_MAX;
  210. dma_free_coherent(ab->dev, size,
  211. hal->rdp.vaddr, hal->rdp.paddr);
  212. hal->rdp.vaddr = NULL;
  213. }
  214. static int ath11k_hal_alloc_cont_wrp(struct ath11k_base *ab)
  215. {
  216. struct ath11k_hal *hal = &ab->hal;
  217. size_t size;
  218. size = sizeof(u32) * HAL_SRNG_NUM_LMAC_RINGS;
  219. hal->wrp.vaddr = dma_alloc_coherent(ab->dev, size, &hal->wrp.paddr,
  220. GFP_KERNEL);
  221. if (!hal->wrp.vaddr)
  222. return -ENOMEM;
  223. return 0;
  224. }
  225. static void ath11k_hal_free_cont_wrp(struct ath11k_base *ab)
  226. {
  227. struct ath11k_hal *hal = &ab->hal;
  228. size_t size;
  229. if (!hal->wrp.vaddr)
  230. return;
  231. size = sizeof(u32) * HAL_SRNG_NUM_LMAC_RINGS;
  232. dma_free_coherent(ab->dev, size,
  233. hal->wrp.vaddr, hal->wrp.paddr);
  234. hal->wrp.vaddr = NULL;
  235. }
  236. static void ath11k_hal_ce_dst_setup(struct ath11k_base *ab,
  237. struct hal_srng *srng, int ring_num)
  238. {
  239. struct hal_srng_config *srng_config = &ab->hal.srng_config[HAL_CE_DST];
  240. u32 addr;
  241. u32 val;
  242. addr = HAL_CE_DST_RING_CTRL +
  243. srng_config->reg_start[HAL_SRNG_REG_GRP_R0] +
  244. ring_num * srng_config->reg_size[HAL_SRNG_REG_GRP_R0];
  245. val = ath11k_hif_read32(ab, addr);
  246. val &= ~HAL_CE_DST_R0_DEST_CTRL_MAX_LEN;
  247. val |= FIELD_PREP(HAL_CE_DST_R0_DEST_CTRL_MAX_LEN,
  248. srng->u.dst_ring.max_buffer_length);
  249. ath11k_hif_write32(ab, addr, val);
  250. }
  251. static void ath11k_hal_srng_dst_hw_init(struct ath11k_base *ab,
  252. struct hal_srng *srng)
  253. {
  254. struct ath11k_hal *hal = &ab->hal;
  255. u32 val;
  256. u64 hp_addr;
  257. u32 reg_base;
  258. reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R0];
  259. if (srng->flags & HAL_SRNG_FLAGS_MSI_INTR) {
  260. ath11k_hif_write32(ab, reg_base +
  261. HAL_REO1_RING_MSI1_BASE_LSB_OFFSET(ab),
  262. srng->msi_addr);
  263. val = FIELD_PREP(HAL_REO1_RING_MSI1_BASE_MSB_ADDR,
  264. ((u64)srng->msi_addr >>
  265. HAL_ADDR_MSB_REG_SHIFT)) |
  266. HAL_REO1_RING_MSI1_BASE_MSB_MSI1_ENABLE;
  267. ath11k_hif_write32(ab, reg_base +
  268. HAL_REO1_RING_MSI1_BASE_MSB_OFFSET(ab), val);
  269. ath11k_hif_write32(ab,
  270. reg_base + HAL_REO1_RING_MSI1_DATA_OFFSET(ab),
  271. srng->msi_data);
  272. }
  273. ath11k_hif_write32(ab, reg_base, srng->ring_base_paddr);
  274. val = FIELD_PREP(HAL_REO1_RING_BASE_MSB_RING_BASE_ADDR_MSB,
  275. ((u64)srng->ring_base_paddr >>
  276. HAL_ADDR_MSB_REG_SHIFT)) |
  277. FIELD_PREP(HAL_REO1_RING_BASE_MSB_RING_SIZE,
  278. (srng->entry_size * srng->num_entries));
  279. ath11k_hif_write32(ab, reg_base + HAL_REO1_RING_BASE_MSB_OFFSET(ab), val);
  280. val = FIELD_PREP(HAL_REO1_RING_ID_RING_ID, srng->ring_id) |
  281. FIELD_PREP(HAL_REO1_RING_ID_ENTRY_SIZE, srng->entry_size);
  282. ath11k_hif_write32(ab, reg_base + HAL_REO1_RING_ID_OFFSET(ab), val);
  283. /* interrupt setup */
  284. val = FIELD_PREP(HAL_REO1_RING_PRDR_INT_SETUP_INTR_TMR_THOLD,
  285. (srng->intr_timer_thres_us >> 3));
  286. val |= FIELD_PREP(HAL_REO1_RING_PRDR_INT_SETUP_BATCH_COUNTER_THOLD,
  287. (srng->intr_batch_cntr_thres_entries *
  288. srng->entry_size));
  289. ath11k_hif_write32(ab,
  290. reg_base + HAL_REO1_RING_PRODUCER_INT_SETUP_OFFSET(ab),
  291. val);
  292. hp_addr = hal->rdp.paddr +
  293. ((unsigned long)srng->u.dst_ring.hp_addr -
  294. (unsigned long)hal->rdp.vaddr);
  295. ath11k_hif_write32(ab, reg_base + HAL_REO1_RING_HP_ADDR_LSB_OFFSET(ab),
  296. hp_addr & HAL_ADDR_LSB_REG_MASK);
  297. ath11k_hif_write32(ab, reg_base + HAL_REO1_RING_HP_ADDR_MSB_OFFSET(ab),
  298. hp_addr >> HAL_ADDR_MSB_REG_SHIFT);
  299. /* Initialize head and tail pointers to indicate ring is empty */
  300. reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R2];
  301. ath11k_hif_write32(ab, reg_base, 0);
  302. ath11k_hif_write32(ab, reg_base + HAL_REO1_RING_TP_OFFSET(ab), 0);
  303. *srng->u.dst_ring.hp_addr = 0;
  304. reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R0];
  305. val = 0;
  306. if (srng->flags & HAL_SRNG_FLAGS_DATA_TLV_SWAP)
  307. val |= HAL_REO1_RING_MISC_DATA_TLV_SWAP;
  308. if (srng->flags & HAL_SRNG_FLAGS_RING_PTR_SWAP)
  309. val |= HAL_REO1_RING_MISC_HOST_FW_SWAP;
  310. if (srng->flags & HAL_SRNG_FLAGS_MSI_SWAP)
  311. val |= HAL_REO1_RING_MISC_MSI_SWAP;
  312. val |= HAL_REO1_RING_MISC_SRNG_ENABLE;
  313. ath11k_hif_write32(ab, reg_base + HAL_REO1_RING_MISC_OFFSET(ab), val);
  314. }
  315. static void ath11k_hal_srng_src_hw_init(struct ath11k_base *ab,
  316. struct hal_srng *srng)
  317. {
  318. struct ath11k_hal *hal = &ab->hal;
  319. u32 val;
  320. u64 tp_addr;
  321. u32 reg_base;
  322. reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R0];
  323. if (srng->flags & HAL_SRNG_FLAGS_MSI_INTR) {
  324. ath11k_hif_write32(ab, reg_base +
  325. HAL_TCL1_RING_MSI1_BASE_LSB_OFFSET(ab),
  326. srng->msi_addr);
  327. val = FIELD_PREP(HAL_TCL1_RING_MSI1_BASE_MSB_ADDR,
  328. ((u64)srng->msi_addr >>
  329. HAL_ADDR_MSB_REG_SHIFT)) |
  330. HAL_TCL1_RING_MSI1_BASE_MSB_MSI1_ENABLE;
  331. ath11k_hif_write32(ab, reg_base +
  332. HAL_TCL1_RING_MSI1_BASE_MSB_OFFSET(ab),
  333. val);
  334. ath11k_hif_write32(ab, reg_base +
  335. HAL_TCL1_RING_MSI1_DATA_OFFSET(ab),
  336. srng->msi_data);
  337. }
  338. ath11k_hif_write32(ab, reg_base, srng->ring_base_paddr);
  339. val = FIELD_PREP(HAL_TCL1_RING_BASE_MSB_RING_BASE_ADDR_MSB,
  340. ((u64)srng->ring_base_paddr >>
  341. HAL_ADDR_MSB_REG_SHIFT)) |
  342. FIELD_PREP(HAL_TCL1_RING_BASE_MSB_RING_SIZE,
  343. (srng->entry_size * srng->num_entries));
  344. ath11k_hif_write32(ab, reg_base + HAL_TCL1_RING_BASE_MSB_OFFSET(ab), val);
  345. val = FIELD_PREP(HAL_REO1_RING_ID_ENTRY_SIZE, srng->entry_size);
  346. ath11k_hif_write32(ab, reg_base + HAL_TCL1_RING_ID_OFFSET(ab), val);
  347. if (srng->ring_id == HAL_SRNG_RING_ID_WBM_IDLE_LINK) {
  348. ath11k_hif_write32(ab, reg_base, (u32)srng->ring_base_paddr);
  349. val = FIELD_PREP(HAL_TCL1_RING_BASE_MSB_RING_BASE_ADDR_MSB,
  350. ((u64)srng->ring_base_paddr >>
  351. HAL_ADDR_MSB_REG_SHIFT)) |
  352. FIELD_PREP(HAL_TCL1_RING_BASE_MSB_RING_SIZE,
  353. (srng->entry_size * srng->num_entries));
  354. ath11k_hif_write32(ab, reg_base + HAL_TCL1_RING_BASE_MSB_OFFSET(ab), val);
  355. }
  356. /* interrupt setup */
  357. /* NOTE: IPQ8074 v2 requires the interrupt timer threshold in the
  358. * unit of 8 usecs instead of 1 usec (as required by v1).
  359. */
  360. val = FIELD_PREP(HAL_TCL1_RING_CONSR_INT_SETUP_IX0_INTR_TMR_THOLD,
  361. srng->intr_timer_thres_us);
  362. val |= FIELD_PREP(HAL_TCL1_RING_CONSR_INT_SETUP_IX0_BATCH_COUNTER_THOLD,
  363. (srng->intr_batch_cntr_thres_entries *
  364. srng->entry_size));
  365. ath11k_hif_write32(ab,
  366. reg_base + HAL_TCL1_RING_CONSR_INT_SETUP_IX0_OFFSET(ab),
  367. val);
  368. val = 0;
  369. if (srng->flags & HAL_SRNG_FLAGS_LOW_THRESH_INTR_EN) {
  370. val |= FIELD_PREP(HAL_TCL1_RING_CONSR_INT_SETUP_IX1_LOW_THOLD,
  371. srng->u.src_ring.low_threshold);
  372. }
  373. ath11k_hif_write32(ab,
  374. reg_base + HAL_TCL1_RING_CONSR_INT_SETUP_IX1_OFFSET(ab),
  375. val);
  376. if (srng->ring_id != HAL_SRNG_RING_ID_WBM_IDLE_LINK) {
  377. tp_addr = hal->rdp.paddr +
  378. ((unsigned long)srng->u.src_ring.tp_addr -
  379. (unsigned long)hal->rdp.vaddr);
  380. ath11k_hif_write32(ab,
  381. reg_base + HAL_TCL1_RING_TP_ADDR_LSB_OFFSET(ab),
  382. tp_addr & HAL_ADDR_LSB_REG_MASK);
  383. ath11k_hif_write32(ab,
  384. reg_base + HAL_TCL1_RING_TP_ADDR_MSB_OFFSET(ab),
  385. tp_addr >> HAL_ADDR_MSB_REG_SHIFT);
  386. }
  387. /* Initialize head and tail pointers to indicate ring is empty */
  388. reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R2];
  389. ath11k_hif_write32(ab, reg_base, 0);
  390. ath11k_hif_write32(ab, reg_base + HAL_TCL1_RING_TP_OFFSET, 0);
  391. *srng->u.src_ring.tp_addr = 0;
  392. reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R0];
  393. val = 0;
  394. if (srng->flags & HAL_SRNG_FLAGS_DATA_TLV_SWAP)
  395. val |= HAL_TCL1_RING_MISC_DATA_TLV_SWAP;
  396. if (srng->flags & HAL_SRNG_FLAGS_RING_PTR_SWAP)
  397. val |= HAL_TCL1_RING_MISC_HOST_FW_SWAP;
  398. if (srng->flags & HAL_SRNG_FLAGS_MSI_SWAP)
  399. val |= HAL_TCL1_RING_MISC_MSI_SWAP;
  400. /* Loop count is not used for SRC rings */
  401. val |= HAL_TCL1_RING_MISC_MSI_LOOPCNT_DISABLE;
  402. val |= HAL_TCL1_RING_MISC_SRNG_ENABLE;
  403. ath11k_hif_write32(ab, reg_base + HAL_TCL1_RING_MISC_OFFSET(ab), val);
  404. }
  405. static void ath11k_hal_srng_hw_init(struct ath11k_base *ab,
  406. struct hal_srng *srng)
  407. {
  408. if (srng->ring_dir == HAL_SRNG_DIR_SRC)
  409. ath11k_hal_srng_src_hw_init(ab, srng);
  410. else
  411. ath11k_hal_srng_dst_hw_init(ab, srng);
  412. }
  413. static int ath11k_hal_srng_get_ring_id(struct ath11k_base *ab,
  414. enum hal_ring_type type,
  415. int ring_num, int mac_id)
  416. {
  417. struct hal_srng_config *srng_config = &ab->hal.srng_config[type];
  418. int ring_id;
  419. if (ring_num >= srng_config->max_rings) {
  420. ath11k_warn(ab, "invalid ring number :%d\n", ring_num);
  421. return -EINVAL;
  422. }
  423. ring_id = srng_config->start_ring_id + ring_num;
  424. if (srng_config->lmac_ring)
  425. ring_id += mac_id * HAL_SRNG_RINGS_PER_LMAC;
  426. if (WARN_ON(ring_id >= HAL_SRNG_RING_ID_MAX))
  427. return -EINVAL;
  428. return ring_id;
  429. }
  430. int ath11k_hal_srng_get_entrysize(struct ath11k_base *ab, u32 ring_type)
  431. {
  432. struct hal_srng_config *srng_config;
  433. if (WARN_ON(ring_type >= HAL_MAX_RING_TYPES))
  434. return -EINVAL;
  435. srng_config = &ab->hal.srng_config[ring_type];
  436. return (srng_config->entry_size << 2);
  437. }
  438. int ath11k_hal_srng_get_max_entries(struct ath11k_base *ab, u32 ring_type)
  439. {
  440. struct hal_srng_config *srng_config;
  441. if (WARN_ON(ring_type >= HAL_MAX_RING_TYPES))
  442. return -EINVAL;
  443. srng_config = &ab->hal.srng_config[ring_type];
  444. return (srng_config->max_size / srng_config->entry_size);
  445. }
  446. void ath11k_hal_srng_get_params(struct ath11k_base *ab, struct hal_srng *srng,
  447. struct hal_srng_params *params)
  448. {
  449. params->ring_base_paddr = srng->ring_base_paddr;
  450. params->ring_base_vaddr = srng->ring_base_vaddr;
  451. params->num_entries = srng->num_entries;
  452. params->intr_timer_thres_us = srng->intr_timer_thres_us;
  453. params->intr_batch_cntr_thres_entries =
  454. srng->intr_batch_cntr_thres_entries;
  455. params->low_threshold = srng->u.src_ring.low_threshold;
  456. params->msi_addr = srng->msi_addr;
  457. params->msi_data = srng->msi_data;
  458. params->flags = srng->flags;
  459. }
  460. dma_addr_t ath11k_hal_srng_get_hp_addr(struct ath11k_base *ab,
  461. struct hal_srng *srng)
  462. {
  463. if (!(srng->flags & HAL_SRNG_FLAGS_LMAC_RING))
  464. return 0;
  465. if (srng->ring_dir == HAL_SRNG_DIR_SRC)
  466. return ab->hal.wrp.paddr +
  467. ((unsigned long)srng->u.src_ring.hp_addr -
  468. (unsigned long)ab->hal.wrp.vaddr);
  469. else
  470. return ab->hal.rdp.paddr +
  471. ((unsigned long)srng->u.dst_ring.hp_addr -
  472. (unsigned long)ab->hal.rdp.vaddr);
  473. }
  474. dma_addr_t ath11k_hal_srng_get_tp_addr(struct ath11k_base *ab,
  475. struct hal_srng *srng)
  476. {
  477. if (!(srng->flags & HAL_SRNG_FLAGS_LMAC_RING))
  478. return 0;
  479. if (srng->ring_dir == HAL_SRNG_DIR_SRC)
  480. return ab->hal.rdp.paddr +
  481. ((unsigned long)srng->u.src_ring.tp_addr -
  482. (unsigned long)ab->hal.rdp.vaddr);
  483. else
  484. return ab->hal.wrp.paddr +
  485. ((unsigned long)srng->u.dst_ring.tp_addr -
  486. (unsigned long)ab->hal.wrp.vaddr);
  487. }
  488. u32 ath11k_hal_ce_get_desc_size(enum hal_ce_desc type)
  489. {
  490. switch (type) {
  491. case HAL_CE_DESC_SRC:
  492. return sizeof(struct hal_ce_srng_src_desc);
  493. case HAL_CE_DESC_DST:
  494. return sizeof(struct hal_ce_srng_dest_desc);
  495. case HAL_CE_DESC_DST_STATUS:
  496. return sizeof(struct hal_ce_srng_dst_status_desc);
  497. }
  498. return 0;
  499. }
  500. void ath11k_hal_ce_src_set_desc(void *buf, dma_addr_t paddr, u32 len, u32 id,
  501. u8 byte_swap_data)
  502. {
  503. struct hal_ce_srng_src_desc *desc = buf;
  504. desc->buffer_addr_low = paddr & HAL_ADDR_LSB_REG_MASK;
  505. desc->buffer_addr_info =
  506. FIELD_PREP(HAL_CE_SRC_DESC_ADDR_INFO_ADDR_HI,
  507. ((u64)paddr >> HAL_ADDR_MSB_REG_SHIFT)) |
  508. FIELD_PREP(HAL_CE_SRC_DESC_ADDR_INFO_BYTE_SWAP,
  509. byte_swap_data) |
  510. FIELD_PREP(HAL_CE_SRC_DESC_ADDR_INFO_GATHER, 0) |
  511. FIELD_PREP(HAL_CE_SRC_DESC_ADDR_INFO_LEN, len);
  512. desc->meta_info = FIELD_PREP(HAL_CE_SRC_DESC_META_INFO_DATA, id);
  513. }
  514. void ath11k_hal_ce_dst_set_desc(void *buf, dma_addr_t paddr)
  515. {
  516. struct hal_ce_srng_dest_desc *desc = buf;
  517. desc->buffer_addr_low = paddr & HAL_ADDR_LSB_REG_MASK;
  518. desc->buffer_addr_info =
  519. FIELD_PREP(HAL_CE_DEST_DESC_ADDR_INFO_ADDR_HI,
  520. ((u64)paddr >> HAL_ADDR_MSB_REG_SHIFT));
  521. }
  522. u32 ath11k_hal_ce_dst_status_get_length(void *buf)
  523. {
  524. struct hal_ce_srng_dst_status_desc *desc = buf;
  525. u32 len;
  526. len = FIELD_GET(HAL_CE_DST_STATUS_DESC_FLAGS_LEN, desc->flags);
  527. desc->flags &= ~HAL_CE_DST_STATUS_DESC_FLAGS_LEN;
  528. return len;
  529. }
  530. void ath11k_hal_set_link_desc_addr(struct hal_wbm_link_desc *desc, u32 cookie,
  531. dma_addr_t paddr)
  532. {
  533. desc->buf_addr_info.info0 = FIELD_PREP(BUFFER_ADDR_INFO0_ADDR,
  534. (paddr & HAL_ADDR_LSB_REG_MASK));
  535. desc->buf_addr_info.info1 = FIELD_PREP(BUFFER_ADDR_INFO1_ADDR,
  536. ((u64)paddr >> HAL_ADDR_MSB_REG_SHIFT)) |
  537. FIELD_PREP(BUFFER_ADDR_INFO1_RET_BUF_MGR, 1) |
  538. FIELD_PREP(BUFFER_ADDR_INFO1_SW_COOKIE, cookie);
  539. }
  540. u32 *ath11k_hal_srng_dst_peek(struct ath11k_base *ab, struct hal_srng *srng)
  541. {
  542. lockdep_assert_held(&srng->lock);
  543. if (srng->u.dst_ring.tp != srng->u.dst_ring.cached_hp)
  544. return (srng->ring_base_vaddr + srng->u.dst_ring.tp);
  545. return NULL;
  546. }
  547. static u32 *ath11k_hal_srng_dst_peek_with_dma(struct ath11k_base *ab,
  548. struct hal_srng *srng, dma_addr_t *paddr)
  549. {
  550. lockdep_assert_held(&srng->lock);
  551. if (srng->u.dst_ring.tp != srng->u.dst_ring.cached_hp) {
  552. *paddr = srng->ring_base_paddr +
  553. sizeof(*srng->ring_base_vaddr) * srng->u.dst_ring.tp;
  554. return srng->ring_base_vaddr + srng->u.dst_ring.tp;
  555. }
  556. return NULL;
  557. }
  558. static void ath11k_hal_srng_prefetch_desc(struct ath11k_base *ab,
  559. struct hal_srng *srng)
  560. {
  561. dma_addr_t desc_paddr;
  562. u32 *desc;
  563. /* prefetch only if desc is available */
  564. desc = ath11k_hal_srng_dst_peek_with_dma(ab, srng, &desc_paddr);
  565. if (likely(desc)) {
  566. dma_sync_single_for_cpu(ab->dev, desc_paddr,
  567. (srng->entry_size * sizeof(u32)),
  568. DMA_FROM_DEVICE);
  569. prefetch(desc);
  570. }
  571. }
  572. u32 *ath11k_hal_srng_dst_get_next_entry(struct ath11k_base *ab,
  573. struct hal_srng *srng)
  574. {
  575. u32 *desc;
  576. lockdep_assert_held(&srng->lock);
  577. if (srng->u.dst_ring.tp == srng->u.dst_ring.cached_hp)
  578. return NULL;
  579. desc = srng->ring_base_vaddr + srng->u.dst_ring.tp;
  580. srng->u.dst_ring.tp += srng->entry_size;
  581. /* wrap around to start of ring*/
  582. if (srng->u.dst_ring.tp == srng->ring_size)
  583. srng->u.dst_ring.tp = 0;
  584. /* Try to prefetch the next descriptor in the ring */
  585. if (srng->flags & HAL_SRNG_FLAGS_CACHED)
  586. ath11k_hal_srng_prefetch_desc(ab, srng);
  587. return desc;
  588. }
  589. int ath11k_hal_srng_dst_num_free(struct ath11k_base *ab, struct hal_srng *srng,
  590. bool sync_hw_ptr)
  591. {
  592. u32 tp, hp;
  593. lockdep_assert_held(&srng->lock);
  594. tp = srng->u.dst_ring.tp;
  595. if (sync_hw_ptr) {
  596. hp = *srng->u.dst_ring.hp_addr;
  597. srng->u.dst_ring.cached_hp = hp;
  598. } else {
  599. hp = srng->u.dst_ring.cached_hp;
  600. }
  601. if (hp >= tp)
  602. return (hp - tp) / srng->entry_size;
  603. else
  604. return (srng->ring_size - tp + hp) / srng->entry_size;
  605. }
  606. /* Returns number of available entries in src ring */
  607. int ath11k_hal_srng_src_num_free(struct ath11k_base *ab, struct hal_srng *srng,
  608. bool sync_hw_ptr)
  609. {
  610. u32 tp, hp;
  611. lockdep_assert_held(&srng->lock);
  612. hp = srng->u.src_ring.hp;
  613. if (sync_hw_ptr) {
  614. tp = *srng->u.src_ring.tp_addr;
  615. srng->u.src_ring.cached_tp = tp;
  616. } else {
  617. tp = srng->u.src_ring.cached_tp;
  618. }
  619. if (tp > hp)
  620. return ((tp - hp) / srng->entry_size) - 1;
  621. else
  622. return ((srng->ring_size - hp + tp) / srng->entry_size) - 1;
  623. }
  624. u32 *ath11k_hal_srng_src_get_next_entry(struct ath11k_base *ab,
  625. struct hal_srng *srng)
  626. {
  627. u32 *desc;
  628. u32 next_hp;
  629. lockdep_assert_held(&srng->lock);
  630. /* TODO: Using % is expensive, but we have to do this since size of some
  631. * SRNG rings is not power of 2 (due to descriptor sizes). Need to see
  632. * if separate function is defined for rings having power of 2 ring size
  633. * (TCL2SW, REO2SW, SW2RXDMA and CE rings) so that we can avoid the
  634. * overhead of % by using mask (with &).
  635. */
  636. next_hp = (srng->u.src_ring.hp + srng->entry_size) % srng->ring_size;
  637. if (next_hp == srng->u.src_ring.cached_tp)
  638. return NULL;
  639. desc = srng->ring_base_vaddr + srng->u.src_ring.hp;
  640. srng->u.src_ring.hp = next_hp;
  641. /* TODO: Reap functionality is not used by all rings. If particular
  642. * ring does not use reap functionality, we need not update reap_hp
  643. * with next_hp pointer. Need to make sure a separate function is used
  644. * before doing any optimization by removing below code updating
  645. * reap_hp.
  646. */
  647. srng->u.src_ring.reap_hp = next_hp;
  648. return desc;
  649. }
  650. u32 *ath11k_hal_srng_src_reap_next(struct ath11k_base *ab,
  651. struct hal_srng *srng)
  652. {
  653. u32 *desc;
  654. u32 next_reap_hp;
  655. lockdep_assert_held(&srng->lock);
  656. next_reap_hp = (srng->u.src_ring.reap_hp + srng->entry_size) %
  657. srng->ring_size;
  658. if (next_reap_hp == srng->u.src_ring.cached_tp)
  659. return NULL;
  660. desc = srng->ring_base_vaddr + next_reap_hp;
  661. srng->u.src_ring.reap_hp = next_reap_hp;
  662. return desc;
  663. }
  664. u32 *ath11k_hal_srng_src_get_next_reaped(struct ath11k_base *ab,
  665. struct hal_srng *srng)
  666. {
  667. u32 *desc;
  668. lockdep_assert_held(&srng->lock);
  669. if (srng->u.src_ring.hp == srng->u.src_ring.reap_hp)
  670. return NULL;
  671. desc = srng->ring_base_vaddr + srng->u.src_ring.hp;
  672. srng->u.src_ring.hp = (srng->u.src_ring.hp + srng->entry_size) %
  673. srng->ring_size;
  674. return desc;
  675. }
  676. u32 *ath11k_hal_srng_src_next_peek(struct ath11k_base *ab, struct hal_srng *srng)
  677. {
  678. u32 next_hp;
  679. lockdep_assert_held(&srng->lock);
  680. next_hp = (srng->u.src_ring.hp + srng->entry_size) % srng->ring_size;
  681. if (next_hp != srng->u.src_ring.cached_tp)
  682. return srng->ring_base_vaddr + next_hp;
  683. return NULL;
  684. }
  685. u32 *ath11k_hal_srng_src_peek(struct ath11k_base *ab, struct hal_srng *srng)
  686. {
  687. lockdep_assert_held(&srng->lock);
  688. if (((srng->u.src_ring.hp + srng->entry_size) % srng->ring_size) ==
  689. srng->u.src_ring.cached_tp)
  690. return NULL;
  691. return srng->ring_base_vaddr + srng->u.src_ring.hp;
  692. }
  693. void ath11k_hal_srng_access_begin(struct ath11k_base *ab, struct hal_srng *srng)
  694. {
  695. u32 hp;
  696. lockdep_assert_held(&srng->lock);
  697. if (srng->ring_dir == HAL_SRNG_DIR_SRC) {
  698. srng->u.src_ring.cached_tp =
  699. *(volatile u32 *)srng->u.src_ring.tp_addr;
  700. } else {
  701. hp = READ_ONCE(*srng->u.dst_ring.hp_addr);
  702. if (hp != srng->u.dst_ring.cached_hp) {
  703. srng->u.dst_ring.cached_hp = hp;
  704. /* Make sure descriptor is read after the head
  705. * pointer.
  706. */
  707. dma_rmb();
  708. }
  709. /* Try to prefetch the next descriptor in the ring */
  710. if (srng->flags & HAL_SRNG_FLAGS_CACHED)
  711. ath11k_hal_srng_prefetch_desc(ab, srng);
  712. }
  713. }
  714. /* Update cached ring head/tail pointers to HW. ath11k_hal_srng_access_begin()
  715. * should have been called before this.
  716. */
  717. void ath11k_hal_srng_access_end(struct ath11k_base *ab, struct hal_srng *srng)
  718. {
  719. lockdep_assert_held(&srng->lock);
  720. if (srng->flags & HAL_SRNG_FLAGS_LMAC_RING) {
  721. /* For LMAC rings, ring pointer updates are done through FW and
  722. * hence written to a shared memory location that is read by FW
  723. */
  724. if (srng->ring_dir == HAL_SRNG_DIR_SRC) {
  725. srng->u.src_ring.last_tp =
  726. *(volatile u32 *)srng->u.src_ring.tp_addr;
  727. /* Make sure descriptor is written before updating the
  728. * head pointer.
  729. */
  730. dma_wmb();
  731. WRITE_ONCE(*srng->u.src_ring.hp_addr, srng->u.src_ring.hp);
  732. } else {
  733. srng->u.dst_ring.last_hp = *srng->u.dst_ring.hp_addr;
  734. /* Make sure descriptor is read before updating the
  735. * tail pointer.
  736. */
  737. dma_mb();
  738. WRITE_ONCE(*srng->u.dst_ring.tp_addr, srng->u.dst_ring.tp);
  739. }
  740. } else {
  741. if (srng->ring_dir == HAL_SRNG_DIR_SRC) {
  742. srng->u.src_ring.last_tp =
  743. *(volatile u32 *)srng->u.src_ring.tp_addr;
  744. /* Assume implementation use an MMIO write accessor
  745. * which has the required wmb() so that the descriptor
  746. * is written before the updating the head pointer.
  747. */
  748. ath11k_hif_write32(ab,
  749. (unsigned long)srng->u.src_ring.hp_addr -
  750. (unsigned long)ab->mem,
  751. srng->u.src_ring.hp);
  752. } else {
  753. srng->u.dst_ring.last_hp = *srng->u.dst_ring.hp_addr;
  754. /* Make sure descriptor is read before updating the
  755. * tail pointer.
  756. */
  757. mb();
  758. ath11k_hif_write32(ab,
  759. (unsigned long)srng->u.dst_ring.tp_addr -
  760. (unsigned long)ab->mem,
  761. srng->u.dst_ring.tp);
  762. }
  763. }
  764. srng->timestamp = jiffies;
  765. }
  766. void ath11k_hal_setup_link_idle_list(struct ath11k_base *ab,
  767. struct hal_wbm_idle_scatter_list *sbuf,
  768. u32 nsbufs, u32 tot_link_desc,
  769. u32 end_offset)
  770. {
  771. struct ath11k_buffer_addr *link_addr;
  772. int i;
  773. u32 reg_scatter_buf_sz = HAL_WBM_IDLE_SCATTER_BUF_SIZE / 64;
  774. link_addr = (void *)sbuf[0].vaddr + HAL_WBM_IDLE_SCATTER_BUF_SIZE;
  775. for (i = 1; i < nsbufs; i++) {
  776. link_addr->info0 = sbuf[i].paddr & HAL_ADDR_LSB_REG_MASK;
  777. link_addr->info1 = FIELD_PREP(
  778. HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_39_32,
  779. (u64)sbuf[i].paddr >> HAL_ADDR_MSB_REG_SHIFT) |
  780. FIELD_PREP(
  781. HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_MATCH_TAG,
  782. BASE_ADDR_MATCH_TAG_VAL);
  783. link_addr = (void *)sbuf[i].vaddr +
  784. HAL_WBM_IDLE_SCATTER_BUF_SIZE;
  785. }
  786. ath11k_hif_write32(ab,
  787. HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_R0_IDLE_LIST_CONTROL_ADDR,
  788. FIELD_PREP(HAL_WBM_SCATTER_BUFFER_SIZE, reg_scatter_buf_sz) |
  789. FIELD_PREP(HAL_WBM_LINK_DESC_IDLE_LIST_MODE, 0x1));
  790. ath11k_hif_write32(ab,
  791. HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_R0_IDLE_LIST_SIZE_ADDR,
  792. FIELD_PREP(HAL_WBM_SCATTER_RING_SIZE_OF_IDLE_LINK_DESC_LIST,
  793. reg_scatter_buf_sz * nsbufs));
  794. ath11k_hif_write32(ab,
  795. HAL_SEQ_WCSS_UMAC_WBM_REG +
  796. HAL_WBM_SCATTERED_RING_BASE_LSB,
  797. FIELD_PREP(BUFFER_ADDR_INFO0_ADDR,
  798. sbuf[0].paddr & HAL_ADDR_LSB_REG_MASK));
  799. ath11k_hif_write32(ab,
  800. HAL_SEQ_WCSS_UMAC_WBM_REG +
  801. HAL_WBM_SCATTERED_RING_BASE_MSB,
  802. FIELD_PREP(
  803. HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_39_32,
  804. (u64)sbuf[0].paddr >> HAL_ADDR_MSB_REG_SHIFT) |
  805. FIELD_PREP(
  806. HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_MATCH_TAG,
  807. BASE_ADDR_MATCH_TAG_VAL));
  808. /* Setup head and tail pointers for the idle list */
  809. ath11k_hif_write32(ab,
  810. HAL_SEQ_WCSS_UMAC_WBM_REG +
  811. HAL_WBM_SCATTERED_DESC_PTR_HEAD_INFO_IX0,
  812. FIELD_PREP(BUFFER_ADDR_INFO0_ADDR,
  813. sbuf[nsbufs - 1].paddr));
  814. ath11k_hif_write32(ab,
  815. HAL_SEQ_WCSS_UMAC_WBM_REG +
  816. HAL_WBM_SCATTERED_DESC_PTR_HEAD_INFO_IX1,
  817. FIELD_PREP(
  818. HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_39_32,
  819. ((u64)sbuf[nsbufs - 1].paddr >>
  820. HAL_ADDR_MSB_REG_SHIFT)) |
  821. FIELD_PREP(HAL_WBM_SCATTERED_DESC_HEAD_P_OFFSET_IX1,
  822. (end_offset >> 2)));
  823. ath11k_hif_write32(ab,
  824. HAL_SEQ_WCSS_UMAC_WBM_REG +
  825. HAL_WBM_SCATTERED_DESC_PTR_HEAD_INFO_IX0,
  826. FIELD_PREP(BUFFER_ADDR_INFO0_ADDR,
  827. sbuf[0].paddr));
  828. ath11k_hif_write32(ab,
  829. HAL_SEQ_WCSS_UMAC_WBM_REG +
  830. HAL_WBM_SCATTERED_DESC_PTR_TAIL_INFO_IX0,
  831. FIELD_PREP(BUFFER_ADDR_INFO0_ADDR,
  832. sbuf[0].paddr));
  833. ath11k_hif_write32(ab,
  834. HAL_SEQ_WCSS_UMAC_WBM_REG +
  835. HAL_WBM_SCATTERED_DESC_PTR_TAIL_INFO_IX1,
  836. FIELD_PREP(
  837. HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_39_32,
  838. ((u64)sbuf[0].paddr >> HAL_ADDR_MSB_REG_SHIFT)) |
  839. FIELD_PREP(HAL_WBM_SCATTERED_DESC_TAIL_P_OFFSET_IX1,
  840. 0));
  841. ath11k_hif_write32(ab,
  842. HAL_SEQ_WCSS_UMAC_WBM_REG +
  843. HAL_WBM_SCATTERED_DESC_PTR_HP_ADDR,
  844. 2 * tot_link_desc);
  845. /* Enable the SRNG */
  846. ath11k_hif_write32(ab,
  847. HAL_SEQ_WCSS_UMAC_WBM_REG +
  848. HAL_WBM_IDLE_LINK_RING_MISC_ADDR(ab), 0x40);
  849. }
  850. int ath11k_hal_srng_setup(struct ath11k_base *ab, enum hal_ring_type type,
  851. int ring_num, int mac_id,
  852. struct hal_srng_params *params)
  853. {
  854. struct ath11k_hal *hal = &ab->hal;
  855. struct hal_srng_config *srng_config = &ab->hal.srng_config[type];
  856. struct hal_srng *srng;
  857. int ring_id;
  858. u32 lmac_idx;
  859. int i;
  860. u32 reg_base;
  861. ring_id = ath11k_hal_srng_get_ring_id(ab, type, ring_num, mac_id);
  862. if (ring_id < 0)
  863. return ring_id;
  864. srng = &hal->srng_list[ring_id];
  865. srng->ring_id = ring_id;
  866. srng->ring_dir = srng_config->ring_dir;
  867. srng->ring_base_paddr = params->ring_base_paddr;
  868. srng->ring_base_vaddr = params->ring_base_vaddr;
  869. srng->entry_size = srng_config->entry_size;
  870. srng->num_entries = params->num_entries;
  871. srng->ring_size = srng->entry_size * srng->num_entries;
  872. srng->intr_batch_cntr_thres_entries =
  873. params->intr_batch_cntr_thres_entries;
  874. srng->intr_timer_thres_us = params->intr_timer_thres_us;
  875. srng->flags = params->flags;
  876. srng->msi_addr = params->msi_addr;
  877. srng->msi_data = params->msi_data;
  878. srng->initialized = 1;
  879. spin_lock_init(&srng->lock);
  880. lockdep_set_class(&srng->lock, hal->srng_key + ring_id);
  881. for (i = 0; i < HAL_SRNG_NUM_REG_GRP; i++) {
  882. srng->hwreg_base[i] = srng_config->reg_start[i] +
  883. (ring_num * srng_config->reg_size[i]);
  884. }
  885. memset(srng->ring_base_vaddr, 0,
  886. (srng->entry_size * srng->num_entries) << 2);
  887. /* TODO: Add comments on these swap configurations */
  888. if (IS_ENABLED(CONFIG_CPU_BIG_ENDIAN))
  889. srng->flags |= HAL_SRNG_FLAGS_MSI_SWAP | HAL_SRNG_FLAGS_DATA_TLV_SWAP |
  890. HAL_SRNG_FLAGS_RING_PTR_SWAP;
  891. reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R2];
  892. if (srng->ring_dir == HAL_SRNG_DIR_SRC) {
  893. srng->u.src_ring.hp = 0;
  894. srng->u.src_ring.cached_tp = 0;
  895. srng->u.src_ring.reap_hp = srng->ring_size - srng->entry_size;
  896. srng->u.src_ring.tp_addr = (void *)(hal->rdp.vaddr + ring_id);
  897. srng->u.src_ring.low_threshold = params->low_threshold *
  898. srng->entry_size;
  899. if (srng_config->lmac_ring) {
  900. lmac_idx = ring_id - HAL_SRNG_RING_ID_LMAC1_ID_START;
  901. srng->u.src_ring.hp_addr = (void *)(hal->wrp.vaddr +
  902. lmac_idx);
  903. srng->flags |= HAL_SRNG_FLAGS_LMAC_RING;
  904. } else {
  905. if (!ab->hw_params.supports_shadow_regs)
  906. srng->u.src_ring.hp_addr =
  907. (u32 *)((unsigned long)ab->mem + reg_base);
  908. else
  909. ath11k_dbg(ab, ATH11K_DBG_HAL,
  910. "type %d ring_num %d reg_base 0x%x shadow 0x%lx\n",
  911. type, ring_num,
  912. reg_base,
  913. (unsigned long)srng->u.src_ring.hp_addr -
  914. (unsigned long)ab->mem);
  915. }
  916. } else {
  917. /* During initialization loop count in all the descriptors
  918. * will be set to zero, and HW will set it to 1 on completing
  919. * descriptor update in first loop, and increments it by 1 on
  920. * subsequent loops (loop count wraps around after reaching
  921. * 0xffff). The 'loop_cnt' in SW ring state is the expected
  922. * loop count in descriptors updated by HW (to be processed
  923. * by SW).
  924. */
  925. srng->u.dst_ring.loop_cnt = 1;
  926. srng->u.dst_ring.tp = 0;
  927. srng->u.dst_ring.cached_hp = 0;
  928. srng->u.dst_ring.hp_addr = (void *)(hal->rdp.vaddr + ring_id);
  929. if (srng_config->lmac_ring) {
  930. /* For LMAC rings, tail pointer updates will be done
  931. * through FW by writing to a shared memory location
  932. */
  933. lmac_idx = ring_id - HAL_SRNG_RING_ID_LMAC1_ID_START;
  934. srng->u.dst_ring.tp_addr = (void *)(hal->wrp.vaddr +
  935. lmac_idx);
  936. srng->flags |= HAL_SRNG_FLAGS_LMAC_RING;
  937. } else {
  938. if (!ab->hw_params.supports_shadow_regs)
  939. srng->u.dst_ring.tp_addr =
  940. (u32 *)((unsigned long)ab->mem + reg_base +
  941. (HAL_REO1_RING_TP(ab) - HAL_REO1_RING_HP(ab)));
  942. else
  943. ath11k_dbg(ab, ATH11K_DBG_HAL,
  944. "type %d ring_num %d target_reg 0x%x shadow 0x%lx\n",
  945. type, ring_num,
  946. reg_base + (HAL_REO1_RING_TP(ab) -
  947. HAL_REO1_RING_HP(ab)),
  948. (unsigned long)srng->u.dst_ring.tp_addr -
  949. (unsigned long)ab->mem);
  950. }
  951. }
  952. if (srng_config->lmac_ring)
  953. return ring_id;
  954. ath11k_hal_srng_hw_init(ab, srng);
  955. if (type == HAL_CE_DST) {
  956. srng->u.dst_ring.max_buffer_length = params->max_buffer_len;
  957. ath11k_hal_ce_dst_setup(ab, srng, ring_num);
  958. }
  959. return ring_id;
  960. }
  961. static void ath11k_hal_srng_update_hp_tp_addr(struct ath11k_base *ab,
  962. int shadow_cfg_idx,
  963. enum hal_ring_type ring_type,
  964. int ring_num)
  965. {
  966. struct hal_srng *srng;
  967. struct ath11k_hal *hal = &ab->hal;
  968. int ring_id;
  969. struct hal_srng_config *srng_config = &hal->srng_config[ring_type];
  970. ring_id = ath11k_hal_srng_get_ring_id(ab, ring_type, ring_num, 0);
  971. if (ring_id < 0)
  972. return;
  973. srng = &hal->srng_list[ring_id];
  974. if (srng_config->ring_dir == HAL_SRNG_DIR_DST)
  975. srng->u.dst_ring.tp_addr = (u32 *)(HAL_SHADOW_REG(ab, shadow_cfg_idx) +
  976. (unsigned long)ab->mem);
  977. else
  978. srng->u.src_ring.hp_addr = (u32 *)(HAL_SHADOW_REG(ab, shadow_cfg_idx) +
  979. (unsigned long)ab->mem);
  980. }
  981. int ath11k_hal_srng_update_shadow_config(struct ath11k_base *ab,
  982. enum hal_ring_type ring_type,
  983. int ring_num)
  984. {
  985. struct ath11k_hal *hal = &ab->hal;
  986. struct hal_srng_config *srng_config = &hal->srng_config[ring_type];
  987. int shadow_cfg_idx = hal->num_shadow_reg_configured;
  988. u32 target_reg;
  989. if (shadow_cfg_idx >= HAL_SHADOW_NUM_REGS)
  990. return -EINVAL;
  991. hal->num_shadow_reg_configured++;
  992. target_reg = srng_config->reg_start[HAL_HP_OFFSET_IN_REG_START];
  993. target_reg += srng_config->reg_size[HAL_HP_OFFSET_IN_REG_START] *
  994. ring_num;
  995. /* For destination ring, shadow the TP */
  996. if (srng_config->ring_dir == HAL_SRNG_DIR_DST)
  997. target_reg += HAL_OFFSET_FROM_HP_TO_TP;
  998. hal->shadow_reg_addr[shadow_cfg_idx] = target_reg;
  999. /* update hp/tp addr to hal structure*/
  1000. ath11k_hal_srng_update_hp_tp_addr(ab, shadow_cfg_idx, ring_type,
  1001. ring_num);
  1002. ath11k_dbg(ab, ATH11K_DBG_HAL,
  1003. "update shadow config target_reg %x shadow reg 0x%x shadow_idx 0x%x ring_type %d ring num %d",
  1004. target_reg,
  1005. HAL_SHADOW_REG(ab, shadow_cfg_idx),
  1006. shadow_cfg_idx,
  1007. ring_type, ring_num);
  1008. return 0;
  1009. }
  1010. void ath11k_hal_srng_shadow_config(struct ath11k_base *ab)
  1011. {
  1012. struct ath11k_hal *hal = &ab->hal;
  1013. int ring_type, ring_num;
  1014. /* update all the non-CE srngs. */
  1015. for (ring_type = 0; ring_type < HAL_MAX_RING_TYPES; ring_type++) {
  1016. struct hal_srng_config *srng_config = &hal->srng_config[ring_type];
  1017. if (ring_type == HAL_CE_SRC ||
  1018. ring_type == HAL_CE_DST ||
  1019. ring_type == HAL_CE_DST_STATUS)
  1020. continue;
  1021. if (srng_config->lmac_ring)
  1022. continue;
  1023. for (ring_num = 0; ring_num < srng_config->max_rings; ring_num++)
  1024. ath11k_hal_srng_update_shadow_config(ab, ring_type, ring_num);
  1025. }
  1026. }
  1027. void ath11k_hal_srng_get_shadow_config(struct ath11k_base *ab,
  1028. u32 **cfg, u32 *len)
  1029. {
  1030. struct ath11k_hal *hal = &ab->hal;
  1031. *len = hal->num_shadow_reg_configured;
  1032. *cfg = hal->shadow_reg_addr;
  1033. }
  1034. void ath11k_hal_srng_shadow_update_hp_tp(struct ath11k_base *ab,
  1035. struct hal_srng *srng)
  1036. {
  1037. lockdep_assert_held(&srng->lock);
  1038. /* check whether the ring is empty. Update the shadow
  1039. * HP only when then ring isn't empty.
  1040. */
  1041. if (srng->ring_dir == HAL_SRNG_DIR_SRC &&
  1042. *srng->u.src_ring.tp_addr != srng->u.src_ring.hp)
  1043. ath11k_hal_srng_access_end(ab, srng);
  1044. }
  1045. static int ath11k_hal_srng_create_config(struct ath11k_base *ab)
  1046. {
  1047. struct ath11k_hal *hal = &ab->hal;
  1048. struct hal_srng_config *s;
  1049. hal->srng_config = kmemdup(hw_srng_config_template,
  1050. sizeof(hw_srng_config_template),
  1051. GFP_KERNEL);
  1052. if (!hal->srng_config)
  1053. return -ENOMEM;
  1054. s = &hal->srng_config[HAL_REO_DST];
  1055. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO1_RING_BASE_LSB(ab);
  1056. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO1_RING_HP(ab);
  1057. s->reg_size[0] = HAL_REO2_RING_BASE_LSB(ab) - HAL_REO1_RING_BASE_LSB(ab);
  1058. s->reg_size[1] = HAL_REO2_RING_HP(ab) - HAL_REO1_RING_HP(ab);
  1059. s = &hal->srng_config[HAL_REO_EXCEPTION];
  1060. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_TCL_RING_BASE_LSB(ab);
  1061. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_TCL_RING_HP(ab);
  1062. s = &hal->srng_config[HAL_REO_REINJECT];
  1063. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_REO_REG + HAL_SW2REO_RING_BASE_LSB(ab);
  1064. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_REO_REG + HAL_SW2REO_RING_HP(ab);
  1065. s = &hal->srng_config[HAL_REO_CMD];
  1066. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_CMD_RING_BASE_LSB(ab);
  1067. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_CMD_HP(ab);
  1068. s = &hal->srng_config[HAL_REO_STATUS];
  1069. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_STATUS_RING_BASE_LSB(ab);
  1070. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_STATUS_HP(ab);
  1071. s = &hal->srng_config[HAL_TCL_DATA];
  1072. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL1_RING_BASE_LSB(ab);
  1073. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL1_RING_HP;
  1074. s->reg_size[0] = HAL_TCL2_RING_BASE_LSB(ab) - HAL_TCL1_RING_BASE_LSB(ab);
  1075. s->reg_size[1] = HAL_TCL2_RING_HP - HAL_TCL1_RING_HP;
  1076. s = &hal->srng_config[HAL_TCL_CMD];
  1077. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL_RING_BASE_LSB(ab);
  1078. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL_RING_HP;
  1079. s = &hal->srng_config[HAL_TCL_STATUS];
  1080. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL_STATUS_RING_BASE_LSB(ab);
  1081. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL_STATUS_RING_HP;
  1082. s = &hal->srng_config[HAL_CE_SRC];
  1083. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_CE0_SRC_REG(ab) + HAL_CE_DST_RING_BASE_LSB +
  1084. ATH11K_CE_OFFSET(ab);
  1085. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_CE0_SRC_REG(ab) + HAL_CE_DST_RING_HP +
  1086. ATH11K_CE_OFFSET(ab);
  1087. s->reg_size[0] = HAL_SEQ_WCSS_UMAC_CE1_SRC_REG(ab) -
  1088. HAL_SEQ_WCSS_UMAC_CE0_SRC_REG(ab);
  1089. s->reg_size[1] = HAL_SEQ_WCSS_UMAC_CE1_SRC_REG(ab) -
  1090. HAL_SEQ_WCSS_UMAC_CE0_SRC_REG(ab);
  1091. s = &hal->srng_config[HAL_CE_DST];
  1092. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_CE0_DST_REG(ab) + HAL_CE_DST_RING_BASE_LSB +
  1093. ATH11K_CE_OFFSET(ab);
  1094. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_CE0_DST_REG(ab) + HAL_CE_DST_RING_HP +
  1095. ATH11K_CE_OFFSET(ab);
  1096. s->reg_size[0] = HAL_SEQ_WCSS_UMAC_CE1_DST_REG(ab) -
  1097. HAL_SEQ_WCSS_UMAC_CE0_DST_REG(ab);
  1098. s->reg_size[1] = HAL_SEQ_WCSS_UMAC_CE1_DST_REG(ab) -
  1099. HAL_SEQ_WCSS_UMAC_CE0_DST_REG(ab);
  1100. s = &hal->srng_config[HAL_CE_DST_STATUS];
  1101. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_CE0_DST_REG(ab) +
  1102. HAL_CE_DST_STATUS_RING_BASE_LSB + ATH11K_CE_OFFSET(ab);
  1103. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_CE0_DST_REG(ab) + HAL_CE_DST_STATUS_RING_HP +
  1104. ATH11K_CE_OFFSET(ab);
  1105. s->reg_size[0] = HAL_SEQ_WCSS_UMAC_CE1_DST_REG(ab) -
  1106. HAL_SEQ_WCSS_UMAC_CE0_DST_REG(ab);
  1107. s->reg_size[1] = HAL_SEQ_WCSS_UMAC_CE1_DST_REG(ab) -
  1108. HAL_SEQ_WCSS_UMAC_CE0_DST_REG(ab);
  1109. s = &hal->srng_config[HAL_WBM_IDLE_LINK];
  1110. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_IDLE_LINK_RING_BASE_LSB(ab);
  1111. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_IDLE_LINK_RING_HP;
  1112. s = &hal->srng_config[HAL_SW2WBM_RELEASE];
  1113. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_RELEASE_RING_BASE_LSB(ab);
  1114. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_RELEASE_RING_HP;
  1115. s = &hal->srng_config[HAL_WBM2SW_RELEASE];
  1116. s->reg_start[0] = HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM0_RELEASE_RING_BASE_LSB(ab);
  1117. s->reg_start[1] = HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM0_RELEASE_RING_HP;
  1118. s->reg_size[0] = HAL_WBM1_RELEASE_RING_BASE_LSB(ab) -
  1119. HAL_WBM0_RELEASE_RING_BASE_LSB(ab);
  1120. s->reg_size[1] = HAL_WBM1_RELEASE_RING_HP - HAL_WBM0_RELEASE_RING_HP;
  1121. return 0;
  1122. }
  1123. static void ath11k_hal_register_srng_key(struct ath11k_base *ab)
  1124. {
  1125. struct ath11k_hal *hal = &ab->hal;
  1126. u32 ring_id;
  1127. for (ring_id = 0; ring_id < HAL_SRNG_RING_ID_MAX; ring_id++)
  1128. lockdep_register_key(hal->srng_key + ring_id);
  1129. }
  1130. static void ath11k_hal_unregister_srng_key(struct ath11k_base *ab)
  1131. {
  1132. struct ath11k_hal *hal = &ab->hal;
  1133. u32 ring_id;
  1134. for (ring_id = 0; ring_id < HAL_SRNG_RING_ID_MAX; ring_id++)
  1135. lockdep_unregister_key(hal->srng_key + ring_id);
  1136. }
  1137. int ath11k_hal_srng_init(struct ath11k_base *ab)
  1138. {
  1139. struct ath11k_hal *hal = &ab->hal;
  1140. int ret;
  1141. memset(hal, 0, sizeof(*hal));
  1142. ret = ath11k_hal_srng_create_config(ab);
  1143. if (ret)
  1144. goto err_hal;
  1145. ret = ath11k_hal_alloc_cont_rdp(ab);
  1146. if (ret)
  1147. goto err_hal;
  1148. ret = ath11k_hal_alloc_cont_wrp(ab);
  1149. if (ret)
  1150. goto err_free_cont_rdp;
  1151. ath11k_hal_register_srng_key(ab);
  1152. return 0;
  1153. err_free_cont_rdp:
  1154. ath11k_hal_free_cont_rdp(ab);
  1155. err_hal:
  1156. return ret;
  1157. }
  1158. EXPORT_SYMBOL(ath11k_hal_srng_init);
  1159. void ath11k_hal_srng_deinit(struct ath11k_base *ab)
  1160. {
  1161. struct ath11k_hal *hal = &ab->hal;
  1162. int i;
  1163. for (i = 0; i < HAL_SRNG_RING_ID_MAX; i++)
  1164. ab->hal.srng_list[i].initialized = 0;
  1165. ath11k_hal_unregister_srng_key(ab);
  1166. ath11k_hal_free_cont_rdp(ab);
  1167. ath11k_hal_free_cont_wrp(ab);
  1168. kfree(hal->srng_config);
  1169. hal->srng_config = NULL;
  1170. }
  1171. EXPORT_SYMBOL(ath11k_hal_srng_deinit);
  1172. void ath11k_hal_srng_clear(struct ath11k_base *ab)
  1173. {
  1174. /* No need to memset rdp and wrp memory since each individual
  1175. * segment would get cleared in ath11k_hal_srng_src_hw_init()
  1176. * and ath11k_hal_srng_dst_hw_init().
  1177. */
  1178. memset(ab->hal.srng_list, 0,
  1179. sizeof(ab->hal.srng_list));
  1180. memset(ab->hal.shadow_reg_addr, 0,
  1181. sizeof(ab->hal.shadow_reg_addr));
  1182. ab->hal.avail_blk_resource = 0;
  1183. ab->hal.current_blk_index = 0;
  1184. ab->hal.num_shadow_reg_configured = 0;
  1185. }
  1186. EXPORT_SYMBOL(ath11k_hal_srng_clear);
  1187. void ath11k_hal_dump_srng_stats(struct ath11k_base *ab)
  1188. {
  1189. struct hal_srng *srng;
  1190. struct ath11k_ext_irq_grp *irq_grp;
  1191. struct ath11k_ce_pipe *ce_pipe;
  1192. int i;
  1193. ath11k_err(ab, "Last interrupt received for each CE:\n");
  1194. for (i = 0; i < ab->hw_params.ce_count; i++) {
  1195. ce_pipe = &ab->ce.ce_pipe[i];
  1196. if (ath11k_ce_get_attr_flags(ab, i) & CE_ATTR_DIS_INTR)
  1197. continue;
  1198. ath11k_err(ab, "CE_id %d pipe_num %d %ums before\n",
  1199. i, ce_pipe->pipe_num,
  1200. jiffies_to_msecs(jiffies - ce_pipe->timestamp));
  1201. }
  1202. ath11k_err(ab, "\nLast interrupt received for each group:\n");
  1203. for (i = 0; i < ATH11K_EXT_IRQ_GRP_NUM_MAX; i++) {
  1204. irq_grp = &ab->ext_irq_grp[i];
  1205. ath11k_err(ab, "group_id %d %ums before\n",
  1206. irq_grp->grp_id,
  1207. jiffies_to_msecs(jiffies - irq_grp->timestamp));
  1208. }
  1209. for (i = 0; i < HAL_SRNG_RING_ID_MAX; i++) {
  1210. srng = &ab->hal.srng_list[i];
  1211. if (!srng->initialized)
  1212. continue;
  1213. if (srng->ring_dir == HAL_SRNG_DIR_SRC)
  1214. ath11k_err(ab,
  1215. "src srng id %u hp %u, reap_hp %u, cur tp %u, cached tp %u last tp %u napi processed before %ums\n",
  1216. srng->ring_id, srng->u.src_ring.hp,
  1217. srng->u.src_ring.reap_hp,
  1218. *srng->u.src_ring.tp_addr, srng->u.src_ring.cached_tp,
  1219. srng->u.src_ring.last_tp,
  1220. jiffies_to_msecs(jiffies - srng->timestamp));
  1221. else if (srng->ring_dir == HAL_SRNG_DIR_DST)
  1222. ath11k_err(ab,
  1223. "dst srng id %u tp %u, cur hp %u, cached hp %u last hp %u napi processed before %ums\n",
  1224. srng->ring_id, srng->u.dst_ring.tp,
  1225. *srng->u.dst_ring.hp_addr,
  1226. srng->u.dst_ring.cached_hp,
  1227. srng->u.dst_ring.last_hp,
  1228. jiffies_to_msecs(jiffies - srng->timestamp));
  1229. }
  1230. }