qcom_q6v5_mss.c 64 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /*
  3. * Qualcomm self-authenticating modem subsystem remoteproc driver
  4. *
  5. * Copyright (C) 2016 Linaro Ltd.
  6. * Copyright (C) 2014 Sony Mobile Communications AB
  7. * Copyright (c) 2012-2013, The Linux Foundation. All rights reserved.
  8. */
  9. #include <linux/clk.h>
  10. #include <linux/delay.h>
  11. #include <linux/devcoredump.h>
  12. #include <linux/dma-mapping.h>
  13. #include <linux/interrupt.h>
  14. #include <linux/kernel.h>
  15. #include <linux/mfd/syscon.h>
  16. #include <linux/module.h>
  17. #include <linux/of.h>
  18. #include <linux/of_reserved_mem.h>
  19. #include <linux/of_platform.h>
  20. #include <linux/platform_device.h>
  21. #include <linux/pm_domain.h>
  22. #include <linux/pm_runtime.h>
  23. #include <linux/regmap.h>
  24. #include <linux/regulator/consumer.h>
  25. #include <linux/remoteproc.h>
  26. #include <linux/reset.h>
  27. #include <linux/soc/qcom/mdt_loader.h>
  28. #include <linux/iopoll.h>
  29. #include <linux/slab.h>
  30. #include "remoteproc_internal.h"
  31. #include "qcom_common.h"
  32. #include "qcom_pil_info.h"
  33. #include "qcom_q6v5.h"
  34. #include <linux/firmware/qcom/qcom_scm.h>
  35. #define MPSS_CRASH_REASON_SMEM 421
  36. #define MBA_LOG_SIZE SZ_4K
  37. #define MPSS_PAS_ID 5
  38. /* RMB Status Register Values */
  39. #define RMB_PBL_SUCCESS 0x1
  40. #define RMB_MBA_XPU_UNLOCKED 0x1
  41. #define RMB_MBA_XPU_UNLOCKED_SCRIBBLED 0x2
  42. #define RMB_MBA_META_DATA_AUTH_SUCCESS 0x3
  43. #define RMB_MBA_AUTH_COMPLETE 0x4
  44. /* PBL/MBA interface registers */
  45. #define RMB_MBA_IMAGE_REG 0x00
  46. #define RMB_PBL_STATUS_REG 0x04
  47. #define RMB_MBA_COMMAND_REG 0x08
  48. #define RMB_MBA_STATUS_REG 0x0C
  49. #define RMB_PMI_META_DATA_REG 0x10
  50. #define RMB_PMI_CODE_START_REG 0x14
  51. #define RMB_PMI_CODE_LENGTH_REG 0x18
  52. #define RMB_MBA_MSS_STATUS 0x40
  53. #define RMB_MBA_ALT_RESET 0x44
  54. #define RMB_CMD_META_DATA_READY 0x1
  55. #define RMB_CMD_LOAD_READY 0x2
  56. /* QDSP6SS Register Offsets */
  57. #define QDSP6SS_RESET_REG 0x014
  58. #define QDSP6SS_GFMUX_CTL_REG 0x020
  59. #define QDSP6SS_PWR_CTL_REG 0x030
  60. #define QDSP6SS_MEM_PWR_CTL 0x0B0
  61. #define QDSP6V6SS_MEM_PWR_CTL 0x034
  62. #define QDSP6SS_STRAP_ACC 0x110
  63. #define QDSP6V62SS_BHS_STATUS 0x0C4
  64. /* AXI Halt Register Offsets */
  65. #define AXI_HALTREQ_REG 0x0
  66. #define AXI_HALTACK_REG 0x4
  67. #define AXI_IDLE_REG 0x8
  68. #define AXI_GATING_VALID_OVERRIDE BIT(0)
  69. #define HALT_ACK_TIMEOUT_US 100000
  70. /* QACCEPT Register Offsets */
  71. #define QACCEPT_ACCEPT_REG 0x0
  72. #define QACCEPT_ACTIVE_REG 0x4
  73. #define QACCEPT_DENY_REG 0x8
  74. #define QACCEPT_REQ_REG 0xC
  75. #define QACCEPT_TIMEOUT_US 50
  76. /* QDSP6SS_RESET */
  77. #define Q6SS_STOP_CORE BIT(0)
  78. #define Q6SS_CORE_ARES BIT(1)
  79. #define Q6SS_BUS_ARES_ENABLE BIT(2)
  80. /* QDSP6SS CBCR */
  81. #define Q6SS_CBCR_CLKEN BIT(0)
  82. #define Q6SS_CBCR_CLKOFF BIT(31)
  83. #define Q6SS_CBCR_TIMEOUT_US 200
  84. /* QDSP6SS_GFMUX_CTL */
  85. #define Q6SS_CLK_ENABLE BIT(1)
  86. /* QDSP6SS_PWR_CTL */
  87. #define Q6SS_L2DATA_SLP_NRET_N_0 BIT(0)
  88. #define Q6SS_L2DATA_SLP_NRET_N_1 BIT(1)
  89. #define Q6SS_L2DATA_SLP_NRET_N_2 BIT(2)
  90. #define Q6SS_L2TAG_SLP_NRET_N BIT(16)
  91. #define Q6SS_ETB_SLP_NRET_N BIT(17)
  92. #define Q6SS_L2DATA_STBY_N BIT(18)
  93. #define Q6SS_SLP_RET_N BIT(19)
  94. #define Q6SS_CLAMP_IO BIT(20)
  95. #define QDSS_BHS_ON BIT(21)
  96. #define QDSS_LDO_BYP BIT(22)
  97. /* QDSP6v55 parameters */
  98. #define QDSP6V55_MEM_BITS GENMASK(16, 8)
  99. /* QDSP6v56 parameters */
  100. #define QDSP6v56_LDO_BYP BIT(25)
  101. #define QDSP6v56_BHS_ON BIT(24)
  102. #define QDSP6v56_CLAMP_WL BIT(21)
  103. #define QDSP6v56_CLAMP_QMC_MEM BIT(22)
  104. #define QDSP6SS_XO_CBCR 0x0038
  105. #define QDSP6SS_ACC_OVERRIDE_VAL 0x20
  106. #define QDSP6v55_BHS_EN_REST_ACK BIT(0)
  107. /* QDSP6v65 parameters */
  108. #define QDSP6SS_CORE_CBCR 0x20
  109. #define QDSP6SS_SLEEP 0x3C
  110. #define QDSP6SS_BOOT_CORE_START 0x400
  111. #define QDSP6SS_BOOT_CMD 0x404
  112. #define BOOT_FSM_TIMEOUT 10000
  113. #define BHS_CHECK_MAX_LOOPS 200
  114. /* External power block headswitch */
  115. #define EXTERNAL_BHS_ON BIT(0)
  116. #define EXTERNAL_BHS_STATUS BIT(4)
  117. #define EXTERNAL_BHS_TIMEOUT_US 50
  118. struct reg_info {
  119. struct regulator *reg;
  120. int uV;
  121. int uA;
  122. };
  123. struct qcom_mss_reg_res {
  124. const char *supply;
  125. int uV;
  126. int uA;
  127. };
  128. struct rproc_hexagon_res {
  129. const char *hexagon_mba_image;
  130. struct qcom_mss_reg_res *proxy_supply;
  131. struct qcom_mss_reg_res *fallback_proxy_supply;
  132. struct qcom_mss_reg_res *active_supply;
  133. char **proxy_clk_names;
  134. char **reset_clk_names;
  135. char **active_clk_names;
  136. char **proxy_pd_names;
  137. int version;
  138. bool need_mem_protection;
  139. bool has_alt_reset;
  140. bool has_mba_logs;
  141. bool has_spare_reg;
  142. bool has_qaccept_regs;
  143. bool has_ext_bhs_reg;
  144. bool has_ext_cntl_regs;
  145. bool has_vq6;
  146. };
  147. struct q6v5 {
  148. struct device *dev;
  149. struct rproc *rproc;
  150. void __iomem *reg_base;
  151. void __iomem *rmb_base;
  152. struct regmap *halt_map;
  153. struct regmap *conn_map;
  154. u32 halt_q6;
  155. u32 halt_modem;
  156. u32 halt_nc;
  157. u32 halt_vq6;
  158. u32 conn_box;
  159. u32 ext_bhs;
  160. u32 qaccept_mdm;
  161. u32 qaccept_cx;
  162. u32 qaccept_axi;
  163. u32 axim1_clk_off;
  164. u32 crypto_clk_off;
  165. u32 force_clk_on;
  166. u32 rscc_disable;
  167. struct reset_control *mss_restart;
  168. struct reset_control *pdc_reset;
  169. struct qcom_q6v5 q6v5;
  170. struct clk *active_clks[8];
  171. struct clk *reset_clks[4];
  172. struct clk *proxy_clks[4];
  173. struct device *proxy_pds[3];
  174. int active_clk_count;
  175. int reset_clk_count;
  176. int proxy_clk_count;
  177. int proxy_pd_count;
  178. struct reg_info active_regs[1];
  179. struct reg_info proxy_regs[1];
  180. struct reg_info fallback_proxy_regs[2];
  181. int active_reg_count;
  182. int proxy_reg_count;
  183. int fallback_proxy_reg_count;
  184. bool dump_mba_loaded;
  185. size_t current_dump_size;
  186. size_t total_dump_size;
  187. phys_addr_t mba_phys;
  188. size_t mba_size;
  189. size_t dp_size;
  190. phys_addr_t mdata_phys;
  191. size_t mdata_size;
  192. phys_addr_t mpss_phys;
  193. phys_addr_t mpss_reloc;
  194. size_t mpss_size;
  195. struct qcom_rproc_glink glink_subdev;
  196. struct qcom_rproc_subdev smd_subdev;
  197. struct qcom_rproc_pdm pdm_subdev;
  198. struct qcom_rproc_ssr ssr_subdev;
  199. struct qcom_sysmon *sysmon;
  200. struct platform_device *bam_dmux;
  201. bool need_mem_protection;
  202. bool has_alt_reset;
  203. bool has_mba_logs;
  204. bool has_spare_reg;
  205. bool has_qaccept_regs;
  206. bool has_ext_bhs_reg;
  207. bool has_ext_cntl_regs;
  208. bool has_vq6;
  209. u64 mpss_perm;
  210. u64 mba_perm;
  211. const char *hexagon_mdt_image;
  212. int version;
  213. };
  214. enum {
  215. MSS_MSM8226,
  216. MSS_MSM8909,
  217. MSS_MSM8916,
  218. MSS_MSM8926,
  219. MSS_MSM8953,
  220. MSS_MSM8974,
  221. MSS_MSM8996,
  222. MSS_MSM8998,
  223. MSS_SC7180,
  224. MSS_SC7280,
  225. MSS_SDM660,
  226. MSS_SDM845,
  227. };
  228. static int q6v5_regulator_init(struct device *dev, struct reg_info *regs,
  229. const struct qcom_mss_reg_res *reg_res)
  230. {
  231. int i;
  232. if (!reg_res)
  233. return 0;
  234. for (i = 0; reg_res[i].supply; i++) {
  235. regs[i].reg = devm_regulator_get(dev, reg_res[i].supply);
  236. if (IS_ERR(regs[i].reg))
  237. return dev_err_probe(dev, PTR_ERR(regs[i].reg),
  238. "Failed to get %s\n regulator",
  239. reg_res[i].supply);
  240. regs[i].uV = reg_res[i].uV;
  241. regs[i].uA = reg_res[i].uA;
  242. }
  243. return i;
  244. }
  245. static int q6v5_regulator_enable(struct q6v5 *qproc,
  246. struct reg_info *regs, int count)
  247. {
  248. int ret;
  249. int i;
  250. for (i = 0; i < count; i++) {
  251. if (regs[i].uV > 0) {
  252. ret = regulator_set_voltage(regs[i].reg,
  253. regs[i].uV, INT_MAX);
  254. if (ret) {
  255. dev_err(qproc->dev,
  256. "Failed to request voltage for %d.\n",
  257. i);
  258. goto err;
  259. }
  260. }
  261. if (regs[i].uA > 0) {
  262. ret = regulator_set_load(regs[i].reg,
  263. regs[i].uA);
  264. if (ret < 0) {
  265. dev_err(qproc->dev,
  266. "Failed to set regulator mode\n");
  267. goto err;
  268. }
  269. }
  270. ret = regulator_enable(regs[i].reg);
  271. if (ret) {
  272. dev_err(qproc->dev, "Regulator enable failed\n");
  273. goto err;
  274. }
  275. }
  276. return 0;
  277. err:
  278. for (; i >= 0; i--) {
  279. if (regs[i].uV > 0)
  280. regulator_set_voltage(regs[i].reg, 0, INT_MAX);
  281. if (regs[i].uA > 0)
  282. regulator_set_load(regs[i].reg, 0);
  283. regulator_disable(regs[i].reg);
  284. }
  285. return ret;
  286. }
  287. static void q6v5_regulator_disable(struct q6v5 *qproc,
  288. struct reg_info *regs, int count)
  289. {
  290. int i;
  291. for (i = 0; i < count; i++) {
  292. if (regs[i].uV > 0)
  293. regulator_set_voltage(regs[i].reg, 0, INT_MAX);
  294. if (regs[i].uA > 0)
  295. regulator_set_load(regs[i].reg, 0);
  296. regulator_disable(regs[i].reg);
  297. }
  298. }
  299. static int q6v5_clk_enable(struct device *dev,
  300. struct clk **clks, int count)
  301. {
  302. int rc;
  303. int i;
  304. for (i = 0; i < count; i++) {
  305. rc = clk_prepare_enable(clks[i]);
  306. if (rc) {
  307. dev_err(dev, "Clock enable failed\n");
  308. goto err;
  309. }
  310. }
  311. return 0;
  312. err:
  313. for (i--; i >= 0; i--)
  314. clk_disable_unprepare(clks[i]);
  315. return rc;
  316. }
  317. static void q6v5_clk_disable(struct device *dev,
  318. struct clk **clks, int count)
  319. {
  320. int i;
  321. for (i = 0; i < count; i++)
  322. clk_disable_unprepare(clks[i]);
  323. }
  324. static int q6v5_pds_enable(struct q6v5 *qproc, struct device **pds,
  325. size_t pd_count)
  326. {
  327. int ret;
  328. int i;
  329. for (i = 0; i < pd_count; i++) {
  330. dev_pm_genpd_set_performance_state(pds[i], INT_MAX);
  331. ret = pm_runtime_get_sync(pds[i]);
  332. if (ret < 0) {
  333. pm_runtime_put_noidle(pds[i]);
  334. dev_pm_genpd_set_performance_state(pds[i], 0);
  335. goto unroll_pd_votes;
  336. }
  337. }
  338. return 0;
  339. unroll_pd_votes:
  340. for (i--; i >= 0; i--) {
  341. dev_pm_genpd_set_performance_state(pds[i], 0);
  342. pm_runtime_put(pds[i]);
  343. }
  344. return ret;
  345. }
  346. static void q6v5_pds_disable(struct q6v5 *qproc, struct device **pds,
  347. size_t pd_count)
  348. {
  349. int i;
  350. for (i = 0; i < pd_count; i++) {
  351. dev_pm_genpd_set_performance_state(pds[i], 0);
  352. pm_runtime_put(pds[i]);
  353. }
  354. }
  355. static int q6v5_external_bhs_enable(struct q6v5 *qproc)
  356. {
  357. u32 val;
  358. int ret = 0;
  359. /*
  360. * Enable external power block headswitch and wait for it to
  361. * stabilize
  362. */
  363. regmap_set_bits(qproc->conn_map, qproc->ext_bhs, EXTERNAL_BHS_ON);
  364. ret = regmap_read_poll_timeout(qproc->conn_map, qproc->ext_bhs,
  365. val, val & EXTERNAL_BHS_STATUS,
  366. 1, EXTERNAL_BHS_TIMEOUT_US);
  367. if (ret) {
  368. dev_err(qproc->dev, "External BHS timed out\n");
  369. ret = -ETIMEDOUT;
  370. }
  371. return ret;
  372. }
  373. static void q6v5_external_bhs_disable(struct q6v5 *qproc)
  374. {
  375. regmap_clear_bits(qproc->conn_map, qproc->ext_bhs, EXTERNAL_BHS_ON);
  376. }
  377. static int q6v5_xfer_mem_ownership(struct q6v5 *qproc, u64 *current_perm,
  378. bool local, bool remote, phys_addr_t addr,
  379. size_t size)
  380. {
  381. struct qcom_scm_vmperm next[2];
  382. int perms = 0;
  383. if (!qproc->need_mem_protection)
  384. return 0;
  385. if (local == !!(*current_perm & BIT(QCOM_SCM_VMID_HLOS)) &&
  386. remote == !!(*current_perm & BIT(QCOM_SCM_VMID_MSS_MSA)))
  387. return 0;
  388. if (local) {
  389. next[perms].vmid = QCOM_SCM_VMID_HLOS;
  390. next[perms].perm = QCOM_SCM_PERM_RWX;
  391. perms++;
  392. }
  393. if (remote) {
  394. next[perms].vmid = QCOM_SCM_VMID_MSS_MSA;
  395. next[perms].perm = QCOM_SCM_PERM_RW;
  396. perms++;
  397. }
  398. return qcom_scm_assign_mem(addr, ALIGN(size, SZ_4K),
  399. current_perm, next, perms);
  400. }
  401. static void q6v5_debug_policy_load(struct q6v5 *qproc, void *mba_region)
  402. {
  403. const struct firmware *dp_fw;
  404. if (request_firmware_direct(&dp_fw, "msadp", qproc->dev))
  405. return;
  406. if (SZ_1M + dp_fw->size <= qproc->mba_size) {
  407. memcpy(mba_region + SZ_1M, dp_fw->data, dp_fw->size);
  408. qproc->dp_size = dp_fw->size;
  409. }
  410. release_firmware(dp_fw);
  411. }
  412. #define MSM8974_B00_OFFSET 0x1000
  413. static int q6v5_load(struct rproc *rproc, const struct firmware *fw)
  414. {
  415. struct q6v5 *qproc = rproc->priv;
  416. void *mba_region;
  417. /* MBA is restricted to a maximum size of 1M */
  418. if (fw->size > qproc->mba_size || fw->size > SZ_1M) {
  419. dev_err(qproc->dev, "MBA firmware load failed\n");
  420. return -EINVAL;
  421. }
  422. mba_region = memremap(qproc->mba_phys, qproc->mba_size, MEMREMAP_WC);
  423. if (!mba_region) {
  424. dev_err(qproc->dev, "unable to map memory region: %pa+%zx\n",
  425. &qproc->mba_phys, qproc->mba_size);
  426. return -EBUSY;
  427. }
  428. if ((qproc->version == MSS_MSM8974 ||
  429. qproc->version == MSS_MSM8226 ||
  430. qproc->version == MSS_MSM8926) &&
  431. fw->size > MSM8974_B00_OFFSET &&
  432. !memcmp(fw->data, ELFMAG, SELFMAG))
  433. memcpy(mba_region, fw->data + MSM8974_B00_OFFSET, fw->size - MSM8974_B00_OFFSET);
  434. else
  435. memcpy(mba_region, fw->data, fw->size);
  436. q6v5_debug_policy_load(qproc, mba_region);
  437. memunmap(mba_region);
  438. return 0;
  439. }
  440. static int q6v5_reset_assert(struct q6v5 *qproc)
  441. {
  442. int ret;
  443. if (qproc->has_alt_reset) {
  444. reset_control_assert(qproc->pdc_reset);
  445. ret = reset_control_reset(qproc->mss_restart);
  446. reset_control_deassert(qproc->pdc_reset);
  447. } else if (qproc->has_spare_reg) {
  448. /*
  449. * When the AXI pipeline is being reset with the Q6 modem partly
  450. * operational there is possibility of AXI valid signal to
  451. * glitch, leading to spurious transactions and Q6 hangs. A work
  452. * around is employed by asserting the AXI_GATING_VALID_OVERRIDE
  453. * BIT before triggering Q6 MSS reset. AXI_GATING_VALID_OVERRIDE
  454. * is withdrawn post MSS assert followed by a MSS deassert,
  455. * while holding the PDC reset.
  456. */
  457. reset_control_assert(qproc->pdc_reset);
  458. regmap_update_bits(qproc->conn_map, qproc->conn_box,
  459. AXI_GATING_VALID_OVERRIDE, 1);
  460. reset_control_assert(qproc->mss_restart);
  461. reset_control_deassert(qproc->pdc_reset);
  462. regmap_update_bits(qproc->conn_map, qproc->conn_box,
  463. AXI_GATING_VALID_OVERRIDE, 0);
  464. ret = reset_control_deassert(qproc->mss_restart);
  465. } else if (qproc->has_ext_cntl_regs) {
  466. regmap_write(qproc->conn_map, qproc->rscc_disable, 0);
  467. reset_control_assert(qproc->pdc_reset);
  468. reset_control_assert(qproc->mss_restart);
  469. reset_control_deassert(qproc->pdc_reset);
  470. ret = reset_control_deassert(qproc->mss_restart);
  471. } else {
  472. ret = reset_control_assert(qproc->mss_restart);
  473. }
  474. return ret;
  475. }
  476. static int q6v5_reset_deassert(struct q6v5 *qproc)
  477. {
  478. int ret;
  479. if (qproc->has_alt_reset) {
  480. reset_control_assert(qproc->pdc_reset);
  481. writel(1, qproc->rmb_base + RMB_MBA_ALT_RESET);
  482. ret = reset_control_reset(qproc->mss_restart);
  483. writel(0, qproc->rmb_base + RMB_MBA_ALT_RESET);
  484. reset_control_deassert(qproc->pdc_reset);
  485. } else if (qproc->has_spare_reg || qproc->has_ext_cntl_regs) {
  486. ret = reset_control_reset(qproc->mss_restart);
  487. } else {
  488. ret = reset_control_deassert(qproc->mss_restart);
  489. }
  490. return ret;
  491. }
  492. static int q6v5_rmb_pbl_wait(struct q6v5 *qproc, int ms)
  493. {
  494. unsigned long timeout;
  495. s32 val;
  496. timeout = jiffies + msecs_to_jiffies(ms);
  497. for (;;) {
  498. val = readl(qproc->rmb_base + RMB_PBL_STATUS_REG);
  499. if (val)
  500. break;
  501. if (time_after(jiffies, timeout))
  502. return -ETIMEDOUT;
  503. msleep(1);
  504. }
  505. return val;
  506. }
  507. static int q6v5_rmb_mba_wait(struct q6v5 *qproc, u32 status, int ms)
  508. {
  509. unsigned long timeout;
  510. s32 val;
  511. timeout = jiffies + msecs_to_jiffies(ms);
  512. for (;;) {
  513. val = readl(qproc->rmb_base + RMB_MBA_STATUS_REG);
  514. if (val < 0)
  515. break;
  516. if (!status && val)
  517. break;
  518. else if (status && val == status)
  519. break;
  520. if (time_after(jiffies, timeout))
  521. return -ETIMEDOUT;
  522. msleep(1);
  523. }
  524. return val;
  525. }
  526. static void q6v5_dump_mba_logs(struct q6v5 *qproc)
  527. {
  528. struct rproc *rproc = qproc->rproc;
  529. void *data;
  530. void *mba_region;
  531. if (!qproc->has_mba_logs)
  532. return;
  533. if (q6v5_xfer_mem_ownership(qproc, &qproc->mba_perm, true, false, qproc->mba_phys,
  534. qproc->mba_size))
  535. return;
  536. mba_region = memremap(qproc->mba_phys, qproc->mba_size, MEMREMAP_WC);
  537. if (!mba_region)
  538. return;
  539. data = vmalloc(MBA_LOG_SIZE);
  540. if (data) {
  541. memcpy(data, mba_region, MBA_LOG_SIZE);
  542. dev_coredumpv(&rproc->dev, data, MBA_LOG_SIZE, GFP_KERNEL);
  543. }
  544. memunmap(mba_region);
  545. }
  546. static int q6v5proc_reset(struct q6v5 *qproc)
  547. {
  548. u32 val;
  549. int ret;
  550. int i;
  551. if (qproc->version == MSS_SDM845) {
  552. val = readl(qproc->reg_base + QDSP6SS_SLEEP);
  553. val |= Q6SS_CBCR_CLKEN;
  554. writel(val, qproc->reg_base + QDSP6SS_SLEEP);
  555. ret = readl_poll_timeout(qproc->reg_base + QDSP6SS_SLEEP,
  556. val, !(val & Q6SS_CBCR_CLKOFF), 1,
  557. Q6SS_CBCR_TIMEOUT_US);
  558. if (ret) {
  559. dev_err(qproc->dev, "QDSP6SS Sleep clock timed out\n");
  560. return -ETIMEDOUT;
  561. }
  562. /* De-assert QDSP6 stop core */
  563. writel(1, qproc->reg_base + QDSP6SS_BOOT_CORE_START);
  564. /* Trigger boot FSM */
  565. writel(1, qproc->reg_base + QDSP6SS_BOOT_CMD);
  566. ret = readl_poll_timeout(qproc->rmb_base + RMB_MBA_MSS_STATUS,
  567. val, (val & BIT(0)) != 0, 10, BOOT_FSM_TIMEOUT);
  568. if (ret) {
  569. dev_err(qproc->dev, "Boot FSM failed to complete.\n");
  570. /* Reset the modem so that boot FSM is in reset state */
  571. q6v5_reset_deassert(qproc);
  572. return ret;
  573. }
  574. goto pbl_wait;
  575. } else if (qproc->version == MSS_SC7180 || qproc->version == MSS_SC7280) {
  576. val = readl(qproc->reg_base + QDSP6SS_SLEEP);
  577. val |= Q6SS_CBCR_CLKEN;
  578. writel(val, qproc->reg_base + QDSP6SS_SLEEP);
  579. ret = readl_poll_timeout(qproc->reg_base + QDSP6SS_SLEEP,
  580. val, !(val & Q6SS_CBCR_CLKOFF), 1,
  581. Q6SS_CBCR_TIMEOUT_US);
  582. if (ret) {
  583. dev_err(qproc->dev, "QDSP6SS Sleep clock timed out\n");
  584. return -ETIMEDOUT;
  585. }
  586. /* Turn on the XO clock needed for PLL setup */
  587. val = readl(qproc->reg_base + QDSP6SS_XO_CBCR);
  588. val |= Q6SS_CBCR_CLKEN;
  589. writel(val, qproc->reg_base + QDSP6SS_XO_CBCR);
  590. ret = readl_poll_timeout(qproc->reg_base + QDSP6SS_XO_CBCR,
  591. val, !(val & Q6SS_CBCR_CLKOFF), 1,
  592. Q6SS_CBCR_TIMEOUT_US);
  593. if (ret) {
  594. dev_err(qproc->dev, "QDSP6SS XO clock timed out\n");
  595. return -ETIMEDOUT;
  596. }
  597. /* Configure Q6 core CBCR to auto-enable after reset sequence */
  598. val = readl(qproc->reg_base + QDSP6SS_CORE_CBCR);
  599. val |= Q6SS_CBCR_CLKEN;
  600. writel(val, qproc->reg_base + QDSP6SS_CORE_CBCR);
  601. /* De-assert the Q6 stop core signal */
  602. writel(1, qproc->reg_base + QDSP6SS_BOOT_CORE_START);
  603. /* Wait for 10 us for any staggering logic to settle */
  604. usleep_range(10, 20);
  605. /* Trigger the boot FSM to start the Q6 out-of-reset sequence */
  606. writel(1, qproc->reg_base + QDSP6SS_BOOT_CMD);
  607. /* Poll the MSS_STATUS for FSM completion */
  608. ret = readl_poll_timeout(qproc->rmb_base + RMB_MBA_MSS_STATUS,
  609. val, (val & BIT(0)) != 0, 10, BOOT_FSM_TIMEOUT);
  610. if (ret) {
  611. dev_err(qproc->dev, "Boot FSM failed to complete.\n");
  612. /* Reset the modem so that boot FSM is in reset state */
  613. q6v5_reset_deassert(qproc);
  614. return ret;
  615. }
  616. goto pbl_wait;
  617. } else if (qproc->version == MSS_MSM8909 ||
  618. qproc->version == MSS_MSM8953 ||
  619. qproc->version == MSS_MSM8996 ||
  620. qproc->version == MSS_MSM8998 ||
  621. qproc->version == MSS_SDM660) {
  622. if (qproc->version != MSS_MSM8909 &&
  623. qproc->version != MSS_MSM8953)
  624. /* Override the ACC value if required */
  625. writel(QDSP6SS_ACC_OVERRIDE_VAL,
  626. qproc->reg_base + QDSP6SS_STRAP_ACC);
  627. /* Assert resets, stop core */
  628. val = readl(qproc->reg_base + QDSP6SS_RESET_REG);
  629. val |= Q6SS_CORE_ARES | Q6SS_BUS_ARES_ENABLE | Q6SS_STOP_CORE;
  630. writel(val, qproc->reg_base + QDSP6SS_RESET_REG);
  631. /* BHS require xo cbcr to be enabled */
  632. val = readl(qproc->reg_base + QDSP6SS_XO_CBCR);
  633. val |= Q6SS_CBCR_CLKEN;
  634. writel(val, qproc->reg_base + QDSP6SS_XO_CBCR);
  635. /* Read CLKOFF bit to go low indicating CLK is enabled */
  636. ret = readl_poll_timeout(qproc->reg_base + QDSP6SS_XO_CBCR,
  637. val, !(val & Q6SS_CBCR_CLKOFF), 1,
  638. Q6SS_CBCR_TIMEOUT_US);
  639. if (ret) {
  640. dev_err(qproc->dev,
  641. "xo cbcr enabling timed out (rc:%d)\n", ret);
  642. return ret;
  643. }
  644. /* Enable power block headswitch and wait for it to stabilize */
  645. val = readl(qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  646. val |= QDSP6v56_BHS_ON;
  647. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  648. val |= readl(qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  649. udelay(1);
  650. if (qproc->version == MSS_SDM660) {
  651. ret = readl_relaxed_poll_timeout(qproc->reg_base + QDSP6V62SS_BHS_STATUS,
  652. i, (i & QDSP6v55_BHS_EN_REST_ACK),
  653. 1, BHS_CHECK_MAX_LOOPS);
  654. if (ret == -ETIMEDOUT) {
  655. dev_err(qproc->dev, "BHS_EN_REST_ACK not set!\n");
  656. return -ETIMEDOUT;
  657. }
  658. }
  659. /* Put LDO in bypass mode */
  660. val |= QDSP6v56_LDO_BYP;
  661. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  662. if (qproc->version != MSS_MSM8909) {
  663. int mem_pwr_ctl;
  664. /* Deassert QDSP6 compiler memory clamp */
  665. val = readl(qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  666. val &= ~QDSP6v56_CLAMP_QMC_MEM;
  667. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  668. /* Deassert memory peripheral sleep and L2 memory standby */
  669. val |= Q6SS_L2DATA_STBY_N | Q6SS_SLP_RET_N;
  670. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  671. /* Turn on L1, L2, ETB and JU memories 1 at a time */
  672. if (qproc->version == MSS_MSM8953 ||
  673. qproc->version == MSS_MSM8996) {
  674. mem_pwr_ctl = QDSP6SS_MEM_PWR_CTL;
  675. i = 19;
  676. } else {
  677. /* MSS_MSM8998, MSS_SDM660 */
  678. mem_pwr_ctl = QDSP6V6SS_MEM_PWR_CTL;
  679. i = 28;
  680. }
  681. val = readl(qproc->reg_base + mem_pwr_ctl);
  682. for (; i >= 0; i--) {
  683. val |= BIT(i);
  684. writel(val, qproc->reg_base + mem_pwr_ctl);
  685. /*
  686. * Read back value to ensure the write is done then
  687. * wait for 1us for both memory peripheral and data
  688. * array to turn on.
  689. */
  690. val |= readl(qproc->reg_base + mem_pwr_ctl);
  691. udelay(1);
  692. }
  693. } else {
  694. /* Turn on memories */
  695. val = readl(qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  696. val |= Q6SS_SLP_RET_N | Q6SS_L2DATA_STBY_N |
  697. Q6SS_ETB_SLP_NRET_N | QDSP6V55_MEM_BITS;
  698. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  699. /* Turn on L2 banks 1 at a time */
  700. for (i = 0; i <= 7; i++) {
  701. val |= BIT(i);
  702. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  703. }
  704. }
  705. /* Remove word line clamp */
  706. val = readl(qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  707. val &= ~QDSP6v56_CLAMP_WL;
  708. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  709. } else {
  710. /* Assert resets, stop core */
  711. val = readl(qproc->reg_base + QDSP6SS_RESET_REG);
  712. val |= Q6SS_CORE_ARES | Q6SS_BUS_ARES_ENABLE | Q6SS_STOP_CORE;
  713. writel(val, qproc->reg_base + QDSP6SS_RESET_REG);
  714. /* Enable power block headswitch and wait for it to stabilize */
  715. val = readl(qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  716. val |= QDSS_BHS_ON | QDSS_LDO_BYP;
  717. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  718. val |= readl(qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  719. udelay(1);
  720. /*
  721. * Turn on memories. L2 banks should be done individually
  722. * to minimize inrush current.
  723. */
  724. val = readl(qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  725. val |= Q6SS_SLP_RET_N | Q6SS_L2TAG_SLP_NRET_N |
  726. Q6SS_ETB_SLP_NRET_N | Q6SS_L2DATA_STBY_N;
  727. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  728. val |= Q6SS_L2DATA_SLP_NRET_N_2;
  729. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  730. val |= Q6SS_L2DATA_SLP_NRET_N_1;
  731. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  732. val |= Q6SS_L2DATA_SLP_NRET_N_0;
  733. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  734. }
  735. /* Remove IO clamp */
  736. val &= ~Q6SS_CLAMP_IO;
  737. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  738. /* Bring core out of reset */
  739. val = readl(qproc->reg_base + QDSP6SS_RESET_REG);
  740. val &= ~Q6SS_CORE_ARES;
  741. writel(val, qproc->reg_base + QDSP6SS_RESET_REG);
  742. /* Turn on core clock */
  743. val = readl(qproc->reg_base + QDSP6SS_GFMUX_CTL_REG);
  744. val |= Q6SS_CLK_ENABLE;
  745. writel(val, qproc->reg_base + QDSP6SS_GFMUX_CTL_REG);
  746. /* Start core execution */
  747. val = readl(qproc->reg_base + QDSP6SS_RESET_REG);
  748. val &= ~Q6SS_STOP_CORE;
  749. writel(val, qproc->reg_base + QDSP6SS_RESET_REG);
  750. pbl_wait:
  751. /* Wait for PBL status */
  752. ret = q6v5_rmb_pbl_wait(qproc, 1000);
  753. if (ret == -ETIMEDOUT) {
  754. dev_err(qproc->dev, "PBL boot timed out\n");
  755. } else if (ret != RMB_PBL_SUCCESS) {
  756. dev_err(qproc->dev, "PBL returned unexpected status %d\n", ret);
  757. ret = -EINVAL;
  758. } else {
  759. ret = 0;
  760. }
  761. return ret;
  762. }
  763. static int q6v5proc_enable_qchannel(struct q6v5 *qproc, struct regmap *map, u32 offset)
  764. {
  765. unsigned int val;
  766. int ret;
  767. if (!qproc->has_qaccept_regs)
  768. return 0;
  769. if (qproc->has_ext_cntl_regs) {
  770. regmap_write(qproc->conn_map, qproc->rscc_disable, 0);
  771. regmap_write(qproc->conn_map, qproc->force_clk_on, 1);
  772. ret = regmap_read_poll_timeout(qproc->halt_map, qproc->axim1_clk_off, val,
  773. !val, 1, Q6SS_CBCR_TIMEOUT_US);
  774. if (ret) {
  775. dev_err(qproc->dev, "failed to enable axim1 clock\n");
  776. return -ETIMEDOUT;
  777. }
  778. }
  779. regmap_write(map, offset + QACCEPT_REQ_REG, 1);
  780. /* Wait for accept */
  781. ret = regmap_read_poll_timeout(map, offset + QACCEPT_ACCEPT_REG, val, val, 5,
  782. QACCEPT_TIMEOUT_US);
  783. if (ret) {
  784. dev_err(qproc->dev, "qchannel enable failed\n");
  785. return -ETIMEDOUT;
  786. }
  787. return 0;
  788. }
  789. static void q6v5proc_disable_qchannel(struct q6v5 *qproc, struct regmap *map, u32 offset)
  790. {
  791. int ret;
  792. unsigned int val, retry;
  793. unsigned int nretry = 10;
  794. bool takedown_complete = false;
  795. if (!qproc->has_qaccept_regs)
  796. return;
  797. while (!takedown_complete && nretry) {
  798. nretry--;
  799. /* Wait for active transactions to complete */
  800. regmap_read_poll_timeout(map, offset + QACCEPT_ACTIVE_REG, val, !val, 5,
  801. QACCEPT_TIMEOUT_US);
  802. /* Request Q-channel transaction takedown */
  803. regmap_write(map, offset + QACCEPT_REQ_REG, 0);
  804. /*
  805. * If the request is denied, reset the Q-channel takedown request,
  806. * wait for active transactions to complete and retry takedown.
  807. */
  808. retry = 10;
  809. while (retry) {
  810. usleep_range(5, 10);
  811. retry--;
  812. ret = regmap_read(map, offset + QACCEPT_DENY_REG, &val);
  813. if (!ret && val) {
  814. regmap_write(map, offset + QACCEPT_REQ_REG, 1);
  815. break;
  816. }
  817. ret = regmap_read(map, offset + QACCEPT_ACCEPT_REG, &val);
  818. if (!ret && !val) {
  819. takedown_complete = true;
  820. break;
  821. }
  822. }
  823. if (!retry)
  824. break;
  825. }
  826. /* Rely on mss_restart to clear out pending transactions on takedown failure */
  827. if (!takedown_complete)
  828. dev_err(qproc->dev, "qchannel takedown failed\n");
  829. }
  830. static void q6v5proc_halt_axi_port(struct q6v5 *qproc,
  831. struct regmap *halt_map,
  832. u32 offset)
  833. {
  834. unsigned int val;
  835. int ret;
  836. /* Check if we're already idle */
  837. ret = regmap_read(halt_map, offset + AXI_IDLE_REG, &val);
  838. if (!ret && val)
  839. return;
  840. /* Assert halt request */
  841. regmap_write(halt_map, offset + AXI_HALTREQ_REG, 1);
  842. /* Wait for halt */
  843. regmap_read_poll_timeout(halt_map, offset + AXI_HALTACK_REG, val,
  844. val, 1000, HALT_ACK_TIMEOUT_US);
  845. ret = regmap_read(halt_map, offset + AXI_IDLE_REG, &val);
  846. if (ret || !val)
  847. dev_err(qproc->dev, "port failed halt\n");
  848. /* Clear halt request (port will remain halted until reset) */
  849. regmap_write(halt_map, offset + AXI_HALTREQ_REG, 0);
  850. }
  851. static int q6v5_mpss_init_image(struct q6v5 *qproc, const struct firmware *fw,
  852. const char *fw_name)
  853. {
  854. unsigned long dma_attrs = DMA_ATTR_FORCE_CONTIGUOUS;
  855. dma_addr_t phys;
  856. void *metadata;
  857. u64 mdata_perm;
  858. int xferop_ret;
  859. size_t size;
  860. void *ptr;
  861. int ret;
  862. metadata = qcom_mdt_read_metadata(fw, &size, fw_name, qproc->dev);
  863. if (IS_ERR(metadata))
  864. return PTR_ERR(metadata);
  865. if (qproc->mdata_phys) {
  866. if (size > qproc->mdata_size) {
  867. ret = -EINVAL;
  868. dev_err(qproc->dev, "metadata size outside memory range\n");
  869. goto free_metadata;
  870. }
  871. phys = qproc->mdata_phys;
  872. ptr = memremap(qproc->mdata_phys, size, MEMREMAP_WC);
  873. if (!ptr) {
  874. ret = -EBUSY;
  875. dev_err(qproc->dev, "unable to map memory region: %pa+%zx\n",
  876. &qproc->mdata_phys, size);
  877. goto free_metadata;
  878. }
  879. } else {
  880. ptr = dma_alloc_attrs(qproc->dev, size, &phys, GFP_KERNEL, dma_attrs);
  881. if (!ptr) {
  882. ret = -ENOMEM;
  883. dev_err(qproc->dev, "failed to allocate mdt buffer\n");
  884. goto free_metadata;
  885. }
  886. }
  887. memcpy(ptr, metadata, size);
  888. if (qproc->mdata_phys)
  889. memunmap(ptr);
  890. /* Hypervisor mapping to access metadata by modem */
  891. mdata_perm = BIT(QCOM_SCM_VMID_HLOS);
  892. ret = q6v5_xfer_mem_ownership(qproc, &mdata_perm, false, true,
  893. phys, size);
  894. if (ret) {
  895. dev_err(qproc->dev,
  896. "assigning Q6 access to metadata failed: %d\n", ret);
  897. ret = -EAGAIN;
  898. goto free_dma_attrs;
  899. }
  900. writel(phys, qproc->rmb_base + RMB_PMI_META_DATA_REG);
  901. writel(RMB_CMD_META_DATA_READY, qproc->rmb_base + RMB_MBA_COMMAND_REG);
  902. ret = q6v5_rmb_mba_wait(qproc, RMB_MBA_META_DATA_AUTH_SUCCESS, 1000);
  903. if (ret == -ETIMEDOUT)
  904. dev_err(qproc->dev, "MPSS header authentication timed out\n");
  905. else if (ret < 0)
  906. dev_err(qproc->dev, "MPSS header authentication failed: %d\n", ret);
  907. /* Metadata authentication done, remove modem access */
  908. xferop_ret = q6v5_xfer_mem_ownership(qproc, &mdata_perm, true, false,
  909. phys, size);
  910. if (xferop_ret)
  911. dev_warn(qproc->dev,
  912. "mdt buffer not reclaimed system may become unstable\n");
  913. free_dma_attrs:
  914. if (!qproc->mdata_phys)
  915. dma_free_attrs(qproc->dev, size, ptr, phys, dma_attrs);
  916. free_metadata:
  917. kfree(metadata);
  918. return ret < 0 ? ret : 0;
  919. }
  920. static bool q6v5_phdr_valid(const struct elf32_phdr *phdr)
  921. {
  922. if (phdr->p_type != PT_LOAD)
  923. return false;
  924. if ((phdr->p_flags & QCOM_MDT_TYPE_MASK) == QCOM_MDT_TYPE_HASH)
  925. return false;
  926. if (!phdr->p_memsz)
  927. return false;
  928. return true;
  929. }
  930. static int q6v5_mba_load(struct q6v5 *qproc)
  931. {
  932. int ret;
  933. int xfermemop_ret;
  934. bool mba_load_err = false;
  935. ret = qcom_q6v5_prepare(&qproc->q6v5);
  936. if (ret)
  937. return ret;
  938. ret = q6v5_pds_enable(qproc, qproc->proxy_pds, qproc->proxy_pd_count);
  939. if (ret < 0) {
  940. dev_err(qproc->dev, "failed to enable proxy power domains\n");
  941. goto disable_irqs;
  942. }
  943. ret = q6v5_regulator_enable(qproc, qproc->fallback_proxy_regs,
  944. qproc->fallback_proxy_reg_count);
  945. if (ret) {
  946. dev_err(qproc->dev, "failed to enable fallback proxy supplies\n");
  947. goto disable_proxy_pds;
  948. }
  949. ret = q6v5_regulator_enable(qproc, qproc->proxy_regs,
  950. qproc->proxy_reg_count);
  951. if (ret) {
  952. dev_err(qproc->dev, "failed to enable proxy supplies\n");
  953. goto disable_fallback_proxy_reg;
  954. }
  955. ret = q6v5_clk_enable(qproc->dev, qproc->proxy_clks,
  956. qproc->proxy_clk_count);
  957. if (ret) {
  958. dev_err(qproc->dev, "failed to enable proxy clocks\n");
  959. goto disable_proxy_reg;
  960. }
  961. ret = q6v5_regulator_enable(qproc, qproc->active_regs,
  962. qproc->active_reg_count);
  963. if (ret) {
  964. dev_err(qproc->dev, "failed to enable supplies\n");
  965. goto disable_proxy_clk;
  966. }
  967. if (qproc->has_ext_bhs_reg) {
  968. ret = q6v5_external_bhs_enable(qproc);
  969. if (ret < 0)
  970. goto disable_vdd;
  971. }
  972. ret = q6v5_clk_enable(qproc->dev, qproc->reset_clks,
  973. qproc->reset_clk_count);
  974. if (ret) {
  975. dev_err(qproc->dev, "failed to enable reset clocks\n");
  976. goto disable_ext_bhs;
  977. }
  978. ret = q6v5_reset_deassert(qproc);
  979. if (ret) {
  980. dev_err(qproc->dev, "failed to deassert mss restart\n");
  981. goto disable_reset_clks;
  982. }
  983. ret = q6v5_clk_enable(qproc->dev, qproc->active_clks,
  984. qproc->active_clk_count);
  985. if (ret) {
  986. dev_err(qproc->dev, "failed to enable clocks\n");
  987. goto assert_reset;
  988. }
  989. ret = q6v5proc_enable_qchannel(qproc, qproc->halt_map, qproc->qaccept_axi);
  990. if (ret) {
  991. dev_err(qproc->dev, "failed to enable axi bridge\n");
  992. goto disable_active_clks;
  993. }
  994. /*
  995. * Some versions of the MBA firmware will upon boot wipe the MPSS region as well, so provide
  996. * the Q6 access to this region.
  997. */
  998. ret = q6v5_xfer_mem_ownership(qproc, &qproc->mpss_perm, false, true,
  999. qproc->mpss_phys, qproc->mpss_size);
  1000. if (ret) {
  1001. dev_err(qproc->dev, "assigning Q6 access to mpss memory failed: %d\n", ret);
  1002. goto disable_active_clks;
  1003. }
  1004. /* Assign MBA image access in DDR to q6 */
  1005. ret = q6v5_xfer_mem_ownership(qproc, &qproc->mba_perm, false, true,
  1006. qproc->mba_phys, qproc->mba_size);
  1007. if (ret) {
  1008. dev_err(qproc->dev,
  1009. "assigning Q6 access to mba memory failed: %d\n", ret);
  1010. goto disable_active_clks;
  1011. }
  1012. if (qproc->has_mba_logs)
  1013. qcom_pil_info_store("mba", qproc->mba_phys, MBA_LOG_SIZE);
  1014. writel(qproc->mba_phys, qproc->rmb_base + RMB_MBA_IMAGE_REG);
  1015. if (qproc->dp_size) {
  1016. writel(qproc->mba_phys + SZ_1M, qproc->rmb_base + RMB_PMI_CODE_START_REG);
  1017. writel(qproc->dp_size, qproc->rmb_base + RMB_PMI_CODE_LENGTH_REG);
  1018. }
  1019. ret = q6v5proc_reset(qproc);
  1020. if (ret)
  1021. goto reclaim_mba;
  1022. ret = q6v5_rmb_mba_wait(qproc, 0, 5000);
  1023. if (ret == -ETIMEDOUT) {
  1024. dev_err(qproc->dev, "MBA boot timed out\n");
  1025. goto halt_axi_ports;
  1026. } else if (ret != RMB_MBA_XPU_UNLOCKED &&
  1027. ret != RMB_MBA_XPU_UNLOCKED_SCRIBBLED) {
  1028. dev_err(qproc->dev, "MBA returned unexpected status %d\n", ret);
  1029. ret = -EINVAL;
  1030. goto halt_axi_ports;
  1031. }
  1032. qproc->dump_mba_loaded = true;
  1033. return 0;
  1034. halt_axi_ports:
  1035. q6v5proc_halt_axi_port(qproc, qproc->halt_map, qproc->halt_q6);
  1036. if (qproc->has_vq6)
  1037. q6v5proc_halt_axi_port(qproc, qproc->halt_map, qproc->halt_vq6);
  1038. q6v5proc_halt_axi_port(qproc, qproc->halt_map, qproc->halt_modem);
  1039. q6v5proc_halt_axi_port(qproc, qproc->halt_map, qproc->halt_nc);
  1040. q6v5proc_disable_qchannel(qproc, qproc->halt_map, qproc->qaccept_mdm);
  1041. q6v5proc_disable_qchannel(qproc, qproc->halt_map, qproc->qaccept_cx);
  1042. q6v5proc_disable_qchannel(qproc, qproc->halt_map, qproc->qaccept_axi);
  1043. mba_load_err = true;
  1044. reclaim_mba:
  1045. xfermemop_ret = q6v5_xfer_mem_ownership(qproc, &qproc->mba_perm, true,
  1046. false, qproc->mba_phys,
  1047. qproc->mba_size);
  1048. if (xfermemop_ret) {
  1049. dev_err(qproc->dev,
  1050. "Failed to reclaim mba buffer, system may become unstable\n");
  1051. } else if (mba_load_err) {
  1052. q6v5_dump_mba_logs(qproc);
  1053. }
  1054. disable_active_clks:
  1055. q6v5_clk_disable(qproc->dev, qproc->active_clks,
  1056. qproc->active_clk_count);
  1057. assert_reset:
  1058. q6v5_reset_assert(qproc);
  1059. disable_reset_clks:
  1060. q6v5_clk_disable(qproc->dev, qproc->reset_clks,
  1061. qproc->reset_clk_count);
  1062. disable_ext_bhs:
  1063. if (qproc->has_ext_bhs_reg)
  1064. q6v5_external_bhs_disable(qproc);
  1065. disable_vdd:
  1066. q6v5_regulator_disable(qproc, qproc->active_regs,
  1067. qproc->active_reg_count);
  1068. disable_proxy_clk:
  1069. q6v5_clk_disable(qproc->dev, qproc->proxy_clks,
  1070. qproc->proxy_clk_count);
  1071. disable_proxy_reg:
  1072. q6v5_regulator_disable(qproc, qproc->proxy_regs,
  1073. qproc->proxy_reg_count);
  1074. disable_fallback_proxy_reg:
  1075. q6v5_regulator_disable(qproc, qproc->fallback_proxy_regs,
  1076. qproc->fallback_proxy_reg_count);
  1077. disable_proxy_pds:
  1078. q6v5_pds_disable(qproc, qproc->proxy_pds, qproc->proxy_pd_count);
  1079. disable_irqs:
  1080. qcom_q6v5_unprepare(&qproc->q6v5);
  1081. return ret;
  1082. }
  1083. static void q6v5_mba_reclaim(struct q6v5 *qproc)
  1084. {
  1085. int ret;
  1086. u32 val;
  1087. qproc->dump_mba_loaded = false;
  1088. qproc->dp_size = 0;
  1089. q6v5proc_halt_axi_port(qproc, qproc->halt_map, qproc->halt_q6);
  1090. if (qproc->has_vq6)
  1091. q6v5proc_halt_axi_port(qproc, qproc->halt_map, qproc->halt_vq6);
  1092. q6v5proc_halt_axi_port(qproc, qproc->halt_map, qproc->halt_modem);
  1093. q6v5proc_halt_axi_port(qproc, qproc->halt_map, qproc->halt_nc);
  1094. if (qproc->version == MSS_MSM8996) {
  1095. /*
  1096. * To avoid high MX current during LPASS/MSS restart.
  1097. */
  1098. val = readl(qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  1099. val |= Q6SS_CLAMP_IO | QDSP6v56_CLAMP_WL |
  1100. QDSP6v56_CLAMP_QMC_MEM;
  1101. writel(val, qproc->reg_base + QDSP6SS_PWR_CTL_REG);
  1102. }
  1103. if (qproc->has_ext_cntl_regs) {
  1104. regmap_write(qproc->conn_map, qproc->rscc_disable, 1);
  1105. ret = regmap_read_poll_timeout(qproc->halt_map, qproc->axim1_clk_off, val,
  1106. !val, 1, Q6SS_CBCR_TIMEOUT_US);
  1107. if (ret)
  1108. dev_err(qproc->dev, "failed to enable axim1 clock\n");
  1109. ret = regmap_read_poll_timeout(qproc->halt_map, qproc->crypto_clk_off, val,
  1110. !val, 1, Q6SS_CBCR_TIMEOUT_US);
  1111. if (ret)
  1112. dev_err(qproc->dev, "failed to enable crypto clock\n");
  1113. }
  1114. q6v5proc_disable_qchannel(qproc, qproc->halt_map, qproc->qaccept_mdm);
  1115. q6v5proc_disable_qchannel(qproc, qproc->halt_map, qproc->qaccept_cx);
  1116. q6v5proc_disable_qchannel(qproc, qproc->halt_map, qproc->qaccept_axi);
  1117. q6v5_reset_assert(qproc);
  1118. q6v5_clk_disable(qproc->dev, qproc->reset_clks,
  1119. qproc->reset_clk_count);
  1120. q6v5_clk_disable(qproc->dev, qproc->active_clks,
  1121. qproc->active_clk_count);
  1122. if (qproc->has_ext_bhs_reg)
  1123. q6v5_external_bhs_disable(qproc);
  1124. q6v5_regulator_disable(qproc, qproc->active_regs,
  1125. qproc->active_reg_count);
  1126. /* In case of failure or coredump scenario where reclaiming MBA memory
  1127. * could not happen reclaim it here.
  1128. */
  1129. ret = q6v5_xfer_mem_ownership(qproc, &qproc->mba_perm, true, false,
  1130. qproc->mba_phys,
  1131. qproc->mba_size);
  1132. WARN_ON(ret);
  1133. ret = qcom_q6v5_unprepare(&qproc->q6v5);
  1134. if (ret) {
  1135. q6v5_pds_disable(qproc, qproc->proxy_pds,
  1136. qproc->proxy_pd_count);
  1137. q6v5_clk_disable(qproc->dev, qproc->proxy_clks,
  1138. qproc->proxy_clk_count);
  1139. q6v5_regulator_disable(qproc, qproc->fallback_proxy_regs,
  1140. qproc->fallback_proxy_reg_count);
  1141. q6v5_regulator_disable(qproc, qproc->proxy_regs,
  1142. qproc->proxy_reg_count);
  1143. }
  1144. }
  1145. static int q6v5_reload_mba(struct rproc *rproc)
  1146. {
  1147. struct q6v5 *qproc = rproc->priv;
  1148. const struct firmware *fw;
  1149. int ret;
  1150. ret = request_firmware(&fw, rproc->firmware, qproc->dev);
  1151. if (ret < 0)
  1152. return ret;
  1153. q6v5_load(rproc, fw);
  1154. ret = q6v5_mba_load(qproc);
  1155. release_firmware(fw);
  1156. return ret;
  1157. }
  1158. static int q6v5_mpss_load(struct q6v5 *qproc)
  1159. {
  1160. const struct elf32_phdr *phdrs;
  1161. const struct elf32_phdr *phdr;
  1162. const struct firmware *seg_fw;
  1163. const struct firmware *fw;
  1164. struct elf32_hdr *ehdr;
  1165. phys_addr_t mpss_reloc;
  1166. phys_addr_t boot_addr;
  1167. phys_addr_t min_addr = PHYS_ADDR_MAX;
  1168. phys_addr_t max_addr = 0;
  1169. u32 code_length;
  1170. bool relocate = false;
  1171. char *fw_name;
  1172. size_t fw_name_len;
  1173. ssize_t offset;
  1174. size_t size = 0;
  1175. void *ptr;
  1176. int ret;
  1177. int i;
  1178. fw_name_len = strlen(qproc->hexagon_mdt_image);
  1179. if (fw_name_len <= 4)
  1180. return -EINVAL;
  1181. fw_name = kstrdup(qproc->hexagon_mdt_image, GFP_KERNEL);
  1182. if (!fw_name)
  1183. return -ENOMEM;
  1184. ret = request_firmware(&fw, fw_name, qproc->dev);
  1185. if (ret < 0) {
  1186. dev_err(qproc->dev, "unable to load %s\n", fw_name);
  1187. goto out;
  1188. }
  1189. /* Initialize the RMB validator */
  1190. writel(0, qproc->rmb_base + RMB_PMI_CODE_LENGTH_REG);
  1191. ret = q6v5_mpss_init_image(qproc, fw, qproc->hexagon_mdt_image);
  1192. if (ret)
  1193. goto release_firmware;
  1194. ehdr = (struct elf32_hdr *)fw->data;
  1195. phdrs = (struct elf32_phdr *)(ehdr + 1);
  1196. for (i = 0; i < ehdr->e_phnum; i++) {
  1197. phdr = &phdrs[i];
  1198. if (!q6v5_phdr_valid(phdr))
  1199. continue;
  1200. if (phdr->p_flags & QCOM_MDT_RELOCATABLE)
  1201. relocate = true;
  1202. if (phdr->p_paddr < min_addr)
  1203. min_addr = phdr->p_paddr;
  1204. if (phdr->p_paddr + phdr->p_memsz > max_addr)
  1205. max_addr = ALIGN(phdr->p_paddr + phdr->p_memsz, SZ_4K);
  1206. }
  1207. if (qproc->version == MSS_MSM8953) {
  1208. ret = qcom_scm_pas_mem_setup(MPSS_PAS_ID, qproc->mpss_phys, qproc->mpss_size);
  1209. if (ret) {
  1210. dev_err(qproc->dev,
  1211. "setting up mpss memory failed: %d\n", ret);
  1212. goto release_firmware;
  1213. }
  1214. }
  1215. /*
  1216. * In case of a modem subsystem restart on secure devices, the modem
  1217. * memory can be reclaimed only after MBA is loaded.
  1218. */
  1219. q6v5_xfer_mem_ownership(qproc, &qproc->mpss_perm, true, false,
  1220. qproc->mpss_phys, qproc->mpss_size);
  1221. /* Share ownership between Linux and MSS, during segment loading */
  1222. ret = q6v5_xfer_mem_ownership(qproc, &qproc->mpss_perm, true, true,
  1223. qproc->mpss_phys, qproc->mpss_size);
  1224. if (ret) {
  1225. dev_err(qproc->dev,
  1226. "assigning Q6 access to mpss memory failed: %d\n", ret);
  1227. ret = -EAGAIN;
  1228. goto release_firmware;
  1229. }
  1230. mpss_reloc = relocate ? min_addr : qproc->mpss_phys;
  1231. qproc->mpss_reloc = mpss_reloc;
  1232. /* Load firmware segments */
  1233. for (i = 0; i < ehdr->e_phnum; i++) {
  1234. phdr = &phdrs[i];
  1235. if (!q6v5_phdr_valid(phdr))
  1236. continue;
  1237. offset = phdr->p_paddr - mpss_reloc;
  1238. if (offset < 0 || offset + phdr->p_memsz > qproc->mpss_size) {
  1239. dev_err(qproc->dev, "segment outside memory range\n");
  1240. ret = -EINVAL;
  1241. goto release_firmware;
  1242. }
  1243. if (phdr->p_filesz > phdr->p_memsz) {
  1244. dev_err(qproc->dev,
  1245. "refusing to load segment %d with p_filesz > p_memsz\n",
  1246. i);
  1247. ret = -EINVAL;
  1248. goto release_firmware;
  1249. }
  1250. ptr = memremap(qproc->mpss_phys + offset, phdr->p_memsz, MEMREMAP_WC);
  1251. if (!ptr) {
  1252. dev_err(qproc->dev,
  1253. "unable to map memory region: %pa+%zx-%x\n",
  1254. &qproc->mpss_phys, offset, phdr->p_memsz);
  1255. goto release_firmware;
  1256. }
  1257. if (phdr->p_filesz && phdr->p_offset < fw->size) {
  1258. /* Firmware is large enough to be non-split */
  1259. if (phdr->p_offset + phdr->p_filesz > fw->size) {
  1260. dev_err(qproc->dev,
  1261. "failed to load segment %d from truncated file %s\n",
  1262. i, fw_name);
  1263. ret = -EINVAL;
  1264. memunmap(ptr);
  1265. goto release_firmware;
  1266. }
  1267. memcpy(ptr, fw->data + phdr->p_offset, phdr->p_filesz);
  1268. } else if (phdr->p_filesz) {
  1269. /* Replace "xxx.xxx" with "xxx.bxx" */
  1270. sprintf(fw_name + fw_name_len - 3, "b%02d", i);
  1271. ret = request_firmware_into_buf(&seg_fw, fw_name, qproc->dev,
  1272. ptr, phdr->p_filesz);
  1273. if (ret) {
  1274. dev_err(qproc->dev, "failed to load %s\n", fw_name);
  1275. memunmap(ptr);
  1276. goto release_firmware;
  1277. }
  1278. if (seg_fw->size != phdr->p_filesz) {
  1279. dev_err(qproc->dev,
  1280. "failed to load segment %d from truncated file %s\n",
  1281. i, fw_name);
  1282. ret = -EINVAL;
  1283. release_firmware(seg_fw);
  1284. memunmap(ptr);
  1285. goto release_firmware;
  1286. }
  1287. release_firmware(seg_fw);
  1288. }
  1289. if (phdr->p_memsz > phdr->p_filesz) {
  1290. memset(ptr + phdr->p_filesz, 0,
  1291. phdr->p_memsz - phdr->p_filesz);
  1292. }
  1293. memunmap(ptr);
  1294. size += phdr->p_memsz;
  1295. code_length = readl(qproc->rmb_base + RMB_PMI_CODE_LENGTH_REG);
  1296. if (!code_length) {
  1297. boot_addr = relocate ? qproc->mpss_phys : min_addr;
  1298. writel(boot_addr, qproc->rmb_base + RMB_PMI_CODE_START_REG);
  1299. writel(RMB_CMD_LOAD_READY, qproc->rmb_base + RMB_MBA_COMMAND_REG);
  1300. }
  1301. writel(size, qproc->rmb_base + RMB_PMI_CODE_LENGTH_REG);
  1302. ret = readl(qproc->rmb_base + RMB_MBA_STATUS_REG);
  1303. if (ret < 0) {
  1304. dev_err(qproc->dev, "MPSS authentication failed: %d\n",
  1305. ret);
  1306. goto release_firmware;
  1307. }
  1308. }
  1309. /* Transfer ownership of modem ddr region to q6 */
  1310. ret = q6v5_xfer_mem_ownership(qproc, &qproc->mpss_perm, false, true,
  1311. qproc->mpss_phys, qproc->mpss_size);
  1312. if (ret) {
  1313. dev_err(qproc->dev,
  1314. "assigning Q6 access to mpss memory failed: %d\n", ret);
  1315. ret = -EAGAIN;
  1316. goto release_firmware;
  1317. }
  1318. ret = q6v5_rmb_mba_wait(qproc, RMB_MBA_AUTH_COMPLETE, 10000);
  1319. if (ret == -ETIMEDOUT)
  1320. dev_err(qproc->dev, "MPSS authentication timed out\n");
  1321. else if (ret < 0)
  1322. dev_err(qproc->dev, "MPSS authentication failed: %d\n", ret);
  1323. qcom_pil_info_store("modem", qproc->mpss_phys, qproc->mpss_size);
  1324. release_firmware:
  1325. release_firmware(fw);
  1326. out:
  1327. kfree(fw_name);
  1328. return ret < 0 ? ret : 0;
  1329. }
  1330. static void qcom_q6v5_dump_segment(struct rproc *rproc,
  1331. struct rproc_dump_segment *segment,
  1332. void *dest, size_t cp_offset, size_t size)
  1333. {
  1334. int ret = 0;
  1335. struct q6v5 *qproc = rproc->priv;
  1336. int offset = segment->da - qproc->mpss_reloc;
  1337. void *ptr = NULL;
  1338. /* Unlock mba before copying segments */
  1339. if (!qproc->dump_mba_loaded) {
  1340. ret = q6v5_reload_mba(rproc);
  1341. if (!ret) {
  1342. /* Reset ownership back to Linux to copy segments */
  1343. ret = q6v5_xfer_mem_ownership(qproc, &qproc->mpss_perm,
  1344. true, false,
  1345. qproc->mpss_phys,
  1346. qproc->mpss_size);
  1347. }
  1348. }
  1349. if (!ret)
  1350. ptr = memremap(qproc->mpss_phys + offset + cp_offset, size, MEMREMAP_WC);
  1351. if (ptr) {
  1352. memcpy(dest, ptr, size);
  1353. memunmap(ptr);
  1354. } else {
  1355. memset(dest, 0xff, size);
  1356. }
  1357. qproc->current_dump_size += size;
  1358. /* Reclaim mba after copying segments */
  1359. if (qproc->current_dump_size == qproc->total_dump_size) {
  1360. if (qproc->dump_mba_loaded) {
  1361. /* Try to reset ownership back to Q6 */
  1362. q6v5_xfer_mem_ownership(qproc, &qproc->mpss_perm,
  1363. false, true,
  1364. qproc->mpss_phys,
  1365. qproc->mpss_size);
  1366. q6v5_mba_reclaim(qproc);
  1367. }
  1368. }
  1369. }
  1370. static int q6v5_start(struct rproc *rproc)
  1371. {
  1372. struct q6v5 *qproc = rproc->priv;
  1373. int xfermemop_ret;
  1374. int ret;
  1375. ret = q6v5_mba_load(qproc);
  1376. if (ret)
  1377. return ret;
  1378. dev_info(qproc->dev, "MBA booted with%s debug policy, loading mpss\n",
  1379. qproc->dp_size ? "" : "out");
  1380. ret = q6v5_mpss_load(qproc);
  1381. if (ret)
  1382. goto reclaim_mpss;
  1383. ret = qcom_q6v5_wait_for_start(&qproc->q6v5, msecs_to_jiffies(5000));
  1384. if (ret == -ETIMEDOUT) {
  1385. dev_err(qproc->dev, "start timed out\n");
  1386. goto reclaim_mpss;
  1387. }
  1388. xfermemop_ret = q6v5_xfer_mem_ownership(qproc, &qproc->mba_perm, true,
  1389. false, qproc->mba_phys,
  1390. qproc->mba_size);
  1391. if (xfermemop_ret)
  1392. dev_err(qproc->dev,
  1393. "Failed to reclaim mba buffer system may become unstable\n");
  1394. /* Reset Dump Segment Mask */
  1395. qproc->current_dump_size = 0;
  1396. return 0;
  1397. reclaim_mpss:
  1398. q6v5_mba_reclaim(qproc);
  1399. q6v5_dump_mba_logs(qproc);
  1400. return ret;
  1401. }
  1402. static int q6v5_stop(struct rproc *rproc)
  1403. {
  1404. struct q6v5 *qproc = rproc->priv;
  1405. int ret;
  1406. ret = qcom_q6v5_request_stop(&qproc->q6v5, qproc->sysmon);
  1407. if (ret == -ETIMEDOUT)
  1408. dev_err(qproc->dev, "timed out on wait\n");
  1409. q6v5_mba_reclaim(qproc);
  1410. return 0;
  1411. }
  1412. static int qcom_q6v5_register_dump_segments(struct rproc *rproc,
  1413. const struct firmware *mba_fw)
  1414. {
  1415. const struct firmware *fw;
  1416. const struct elf32_phdr *phdrs;
  1417. const struct elf32_phdr *phdr;
  1418. const struct elf32_hdr *ehdr;
  1419. struct q6v5 *qproc = rproc->priv;
  1420. unsigned long i;
  1421. int ret;
  1422. ret = request_firmware(&fw, qproc->hexagon_mdt_image, qproc->dev);
  1423. if (ret < 0) {
  1424. dev_err(qproc->dev, "unable to load %s\n",
  1425. qproc->hexagon_mdt_image);
  1426. return ret;
  1427. }
  1428. rproc_coredump_set_elf_info(rproc, ELFCLASS32, EM_NONE);
  1429. ehdr = (struct elf32_hdr *)fw->data;
  1430. phdrs = (struct elf32_phdr *)(ehdr + 1);
  1431. qproc->total_dump_size = 0;
  1432. for (i = 0; i < ehdr->e_phnum; i++) {
  1433. phdr = &phdrs[i];
  1434. if (!q6v5_phdr_valid(phdr))
  1435. continue;
  1436. ret = rproc_coredump_add_custom_segment(rproc, phdr->p_paddr,
  1437. phdr->p_memsz,
  1438. qcom_q6v5_dump_segment,
  1439. NULL);
  1440. if (ret)
  1441. break;
  1442. qproc->total_dump_size += phdr->p_memsz;
  1443. }
  1444. release_firmware(fw);
  1445. return ret;
  1446. }
  1447. static unsigned long q6v5_panic(struct rproc *rproc)
  1448. {
  1449. struct q6v5 *qproc = rproc->priv;
  1450. return qcom_q6v5_panic(&qproc->q6v5);
  1451. }
  1452. static const struct rproc_ops q6v5_ops = {
  1453. .start = q6v5_start,
  1454. .stop = q6v5_stop,
  1455. .parse_fw = qcom_q6v5_register_dump_segments,
  1456. .load = q6v5_load,
  1457. .panic = q6v5_panic,
  1458. };
  1459. static void qcom_msa_handover(struct qcom_q6v5 *q6v5)
  1460. {
  1461. struct q6v5 *qproc = container_of(q6v5, struct q6v5, q6v5);
  1462. q6v5_clk_disable(qproc->dev, qproc->proxy_clks,
  1463. qproc->proxy_clk_count);
  1464. q6v5_regulator_disable(qproc, qproc->proxy_regs,
  1465. qproc->proxy_reg_count);
  1466. q6v5_regulator_disable(qproc, qproc->fallback_proxy_regs,
  1467. qproc->fallback_proxy_reg_count);
  1468. q6v5_pds_disable(qproc, qproc->proxy_pds, qproc->proxy_pd_count);
  1469. }
  1470. static int q6v5_init_mem(struct q6v5 *qproc, struct platform_device *pdev)
  1471. {
  1472. struct of_phandle_args args;
  1473. int halt_cell_cnt = 3;
  1474. int ret;
  1475. qproc->reg_base = devm_platform_ioremap_resource_byname(pdev, "qdsp6");
  1476. if (IS_ERR(qproc->reg_base))
  1477. return PTR_ERR(qproc->reg_base);
  1478. qproc->rmb_base = devm_platform_ioremap_resource_byname(pdev, "rmb");
  1479. if (IS_ERR(qproc->rmb_base))
  1480. return PTR_ERR(qproc->rmb_base);
  1481. if (qproc->has_vq6)
  1482. halt_cell_cnt++;
  1483. ret = of_parse_phandle_with_fixed_args(pdev->dev.of_node,
  1484. "qcom,halt-regs", halt_cell_cnt, 0, &args);
  1485. if (ret < 0) {
  1486. dev_err(&pdev->dev, "failed to parse qcom,halt-regs\n");
  1487. return -EINVAL;
  1488. }
  1489. qproc->halt_map = syscon_node_to_regmap(args.np);
  1490. of_node_put(args.np);
  1491. if (IS_ERR(qproc->halt_map))
  1492. return PTR_ERR(qproc->halt_map);
  1493. qproc->halt_q6 = args.args[0];
  1494. qproc->halt_modem = args.args[1];
  1495. qproc->halt_nc = args.args[2];
  1496. if (qproc->has_vq6)
  1497. qproc->halt_vq6 = args.args[3];
  1498. if (qproc->has_qaccept_regs) {
  1499. ret = of_parse_phandle_with_fixed_args(pdev->dev.of_node,
  1500. "qcom,qaccept-regs",
  1501. 3, 0, &args);
  1502. if (ret < 0) {
  1503. dev_err(&pdev->dev, "failed to parse qaccept-regs\n");
  1504. return -EINVAL;
  1505. }
  1506. qproc->qaccept_mdm = args.args[0];
  1507. qproc->qaccept_cx = args.args[1];
  1508. qproc->qaccept_axi = args.args[2];
  1509. }
  1510. if (qproc->has_ext_bhs_reg) {
  1511. ret = of_parse_phandle_with_fixed_args(pdev->dev.of_node,
  1512. "qcom,ext-bhs-reg",
  1513. 1, 0, &args);
  1514. if (ret < 0) {
  1515. dev_err(&pdev->dev, "failed to parse ext-bhs-reg index 0\n");
  1516. return -EINVAL;
  1517. }
  1518. qproc->conn_map = syscon_node_to_regmap(args.np);
  1519. of_node_put(args.np);
  1520. if (IS_ERR(qproc->conn_map))
  1521. return PTR_ERR(qproc->conn_map);
  1522. qproc->ext_bhs = args.args[0];
  1523. }
  1524. if (qproc->has_ext_cntl_regs) {
  1525. ret = of_parse_phandle_with_fixed_args(pdev->dev.of_node,
  1526. "qcom,ext-regs",
  1527. 2, 0, &args);
  1528. if (ret < 0) {
  1529. dev_err(&pdev->dev, "failed to parse ext-regs index 0\n");
  1530. return -EINVAL;
  1531. }
  1532. qproc->conn_map = syscon_node_to_regmap(args.np);
  1533. of_node_put(args.np);
  1534. if (IS_ERR(qproc->conn_map))
  1535. return PTR_ERR(qproc->conn_map);
  1536. qproc->force_clk_on = args.args[0];
  1537. qproc->rscc_disable = args.args[1];
  1538. ret = of_parse_phandle_with_fixed_args(pdev->dev.of_node,
  1539. "qcom,ext-regs",
  1540. 2, 1, &args);
  1541. if (ret < 0) {
  1542. dev_err(&pdev->dev, "failed to parse ext-regs index 1\n");
  1543. return -EINVAL;
  1544. }
  1545. qproc->axim1_clk_off = args.args[0];
  1546. qproc->crypto_clk_off = args.args[1];
  1547. }
  1548. if (qproc->has_spare_reg) {
  1549. ret = of_parse_phandle_with_fixed_args(pdev->dev.of_node,
  1550. "qcom,spare-regs",
  1551. 1, 0, &args);
  1552. if (ret < 0) {
  1553. dev_err(&pdev->dev, "failed to parse spare-regs\n");
  1554. return -EINVAL;
  1555. }
  1556. qproc->conn_map = syscon_node_to_regmap(args.np);
  1557. of_node_put(args.np);
  1558. if (IS_ERR(qproc->conn_map))
  1559. return PTR_ERR(qproc->conn_map);
  1560. qproc->conn_box = args.args[0];
  1561. }
  1562. return 0;
  1563. }
  1564. static int q6v5_init_clocks(struct device *dev, struct clk **clks,
  1565. char **clk_names)
  1566. {
  1567. int i;
  1568. if (!clk_names)
  1569. return 0;
  1570. for (i = 0; clk_names[i]; i++) {
  1571. clks[i] = devm_clk_get(dev, clk_names[i]);
  1572. if (IS_ERR(clks[i]))
  1573. return dev_err_probe(dev, PTR_ERR(clks[i]),
  1574. "Failed to get %s clock\n",
  1575. clk_names[i]);
  1576. }
  1577. return i;
  1578. }
  1579. static int q6v5_pds_attach(struct device *dev, struct device **devs,
  1580. char **pd_names)
  1581. {
  1582. size_t num_pds = 0;
  1583. int ret;
  1584. int i;
  1585. if (!pd_names)
  1586. return 0;
  1587. while (pd_names[num_pds])
  1588. num_pds++;
  1589. /* Handle single power domain */
  1590. if (num_pds == 1 && dev->pm_domain) {
  1591. devs[0] = dev;
  1592. pm_runtime_enable(dev);
  1593. return 1;
  1594. }
  1595. for (i = 0; i < num_pds; i++) {
  1596. devs[i] = dev_pm_domain_attach_by_name(dev, pd_names[i]);
  1597. if (IS_ERR_OR_NULL(devs[i])) {
  1598. ret = PTR_ERR(devs[i]) ? : -ENODATA;
  1599. goto unroll_attach;
  1600. }
  1601. }
  1602. return num_pds;
  1603. unroll_attach:
  1604. for (i--; i >= 0; i--)
  1605. dev_pm_domain_detach(devs[i], false);
  1606. return ret;
  1607. }
  1608. static void q6v5_pds_detach(struct q6v5 *qproc, struct device **pds,
  1609. size_t pd_count)
  1610. {
  1611. struct device *dev = qproc->dev;
  1612. int i;
  1613. /* Handle single power domain */
  1614. if (pd_count == 1 && dev->pm_domain) {
  1615. pm_runtime_disable(dev);
  1616. return;
  1617. }
  1618. for (i = 0; i < pd_count; i++)
  1619. dev_pm_domain_detach(pds[i], false);
  1620. }
  1621. static int q6v5_init_reset(struct q6v5 *qproc)
  1622. {
  1623. qproc->mss_restart = devm_reset_control_get_exclusive(qproc->dev,
  1624. "mss_restart");
  1625. if (IS_ERR(qproc->mss_restart)) {
  1626. dev_err(qproc->dev, "failed to acquire mss restart\n");
  1627. return PTR_ERR(qproc->mss_restart);
  1628. }
  1629. if (qproc->has_alt_reset || qproc->has_spare_reg || qproc->has_ext_cntl_regs) {
  1630. qproc->pdc_reset = devm_reset_control_get_exclusive(qproc->dev,
  1631. "pdc_reset");
  1632. if (IS_ERR(qproc->pdc_reset)) {
  1633. dev_err(qproc->dev, "failed to acquire pdc reset\n");
  1634. return PTR_ERR(qproc->pdc_reset);
  1635. }
  1636. }
  1637. return 0;
  1638. }
  1639. static int q6v5_alloc_memory_region(struct q6v5 *qproc)
  1640. {
  1641. struct device_node *child;
  1642. struct resource res;
  1643. int ret;
  1644. /*
  1645. * In the absence of mba/mpss sub-child, extract the mba and mpss
  1646. * reserved memory regions from device's memory-region property.
  1647. */
  1648. child = of_get_child_by_name(qproc->dev->of_node, "mba");
  1649. if (!child) {
  1650. ret = of_reserved_mem_region_to_resource(qproc->dev->of_node, 0, &res);
  1651. } else {
  1652. ret = of_reserved_mem_region_to_resource(child, 0, &res);
  1653. of_node_put(child);
  1654. }
  1655. if (ret) {
  1656. dev_err(qproc->dev, "unable to resolve mba region\n");
  1657. return ret;
  1658. }
  1659. qproc->mba_phys = res.start;
  1660. qproc->mba_size = resource_size(&res);
  1661. if (!child) {
  1662. ret = of_reserved_mem_region_to_resource(qproc->dev->of_node, 1, &res);
  1663. } else {
  1664. child = of_get_child_by_name(qproc->dev->of_node, "mpss");
  1665. ret = of_reserved_mem_region_to_resource(child, 0, &res);
  1666. of_node_put(child);
  1667. }
  1668. if (ret) {
  1669. dev_err(qproc->dev, "unable to resolve mpss region\n");
  1670. return ret;
  1671. }
  1672. qproc->mpss_phys = qproc->mpss_reloc = res.start;
  1673. qproc->mpss_size = resource_size(&res);
  1674. if (!child) {
  1675. ret = of_reserved_mem_region_to_resource(qproc->dev->of_node, 2, &res);
  1676. } else {
  1677. child = of_get_child_by_name(qproc->dev->of_node, "metadata");
  1678. ret = of_reserved_mem_region_to_resource(child, 0, &res);
  1679. of_node_put(child);
  1680. }
  1681. if (ret)
  1682. return 0;
  1683. qproc->mdata_phys = res.start;
  1684. qproc->mdata_size = resource_size(&res);
  1685. return 0;
  1686. }
  1687. static int q6v5_probe(struct platform_device *pdev)
  1688. {
  1689. const struct rproc_hexagon_res *desc;
  1690. struct device_node *node;
  1691. struct q6v5 *qproc;
  1692. struct rproc *rproc;
  1693. const char *mba_image;
  1694. int ret;
  1695. desc = of_device_get_match_data(&pdev->dev);
  1696. if (!desc)
  1697. return -EINVAL;
  1698. if (desc->need_mem_protection && !qcom_scm_is_available())
  1699. return -EPROBE_DEFER;
  1700. mba_image = desc->hexagon_mba_image;
  1701. ret = of_property_read_string_index(pdev->dev.of_node, "firmware-name",
  1702. 0, &mba_image);
  1703. if (ret < 0 && ret != -EINVAL) {
  1704. dev_err(&pdev->dev, "unable to read mba firmware-name\n");
  1705. return ret;
  1706. }
  1707. rproc = devm_rproc_alloc(&pdev->dev, pdev->name, &q6v5_ops,
  1708. mba_image, sizeof(*qproc));
  1709. if (!rproc) {
  1710. dev_err(&pdev->dev, "failed to allocate rproc\n");
  1711. return -ENOMEM;
  1712. }
  1713. rproc->auto_boot = false;
  1714. rproc_coredump_set_elf_info(rproc, ELFCLASS32, EM_NONE);
  1715. qproc = rproc->priv;
  1716. qproc->dev = &pdev->dev;
  1717. qproc->rproc = rproc;
  1718. qproc->hexagon_mdt_image = "modem.mdt";
  1719. ret = of_property_read_string_index(pdev->dev.of_node, "firmware-name",
  1720. 1, &qproc->hexagon_mdt_image);
  1721. if (ret < 0 && ret != -EINVAL) {
  1722. dev_err(&pdev->dev, "unable to read mpss firmware-name\n");
  1723. return ret;
  1724. }
  1725. platform_set_drvdata(pdev, qproc);
  1726. qproc->has_qaccept_regs = desc->has_qaccept_regs;
  1727. qproc->has_ext_bhs_reg = desc->has_ext_bhs_reg;
  1728. qproc->has_ext_cntl_regs = desc->has_ext_cntl_regs;
  1729. qproc->has_vq6 = desc->has_vq6;
  1730. qproc->has_spare_reg = desc->has_spare_reg;
  1731. ret = q6v5_init_mem(qproc, pdev);
  1732. if (ret)
  1733. return ret;
  1734. ret = q6v5_alloc_memory_region(qproc);
  1735. if (ret)
  1736. return ret;
  1737. ret = q6v5_init_clocks(&pdev->dev, qproc->proxy_clks,
  1738. desc->proxy_clk_names);
  1739. if (ret < 0)
  1740. return ret;
  1741. qproc->proxy_clk_count = ret;
  1742. ret = q6v5_init_clocks(&pdev->dev, qproc->reset_clks,
  1743. desc->reset_clk_names);
  1744. if (ret < 0)
  1745. return ret;
  1746. qproc->reset_clk_count = ret;
  1747. ret = q6v5_init_clocks(&pdev->dev, qproc->active_clks,
  1748. desc->active_clk_names);
  1749. if (ret < 0)
  1750. return ret;
  1751. qproc->active_clk_count = ret;
  1752. ret = q6v5_regulator_init(&pdev->dev, qproc->proxy_regs,
  1753. desc->proxy_supply);
  1754. if (ret < 0)
  1755. return ret;
  1756. qproc->proxy_reg_count = ret;
  1757. ret = q6v5_regulator_init(&pdev->dev, qproc->active_regs,
  1758. desc->active_supply);
  1759. if (ret < 0)
  1760. return ret;
  1761. qproc->active_reg_count = ret;
  1762. ret = q6v5_pds_attach(&pdev->dev, qproc->proxy_pds,
  1763. desc->proxy_pd_names);
  1764. /* Fallback to regulators for old device trees */
  1765. if (ret == -ENODATA && desc->fallback_proxy_supply) {
  1766. ret = q6v5_regulator_init(&pdev->dev,
  1767. qproc->fallback_proxy_regs,
  1768. desc->fallback_proxy_supply);
  1769. if (ret < 0)
  1770. return ret;
  1771. qproc->fallback_proxy_reg_count = ret;
  1772. } else if (ret < 0) {
  1773. dev_err(&pdev->dev, "Failed to init power domains\n");
  1774. return ret;
  1775. } else {
  1776. qproc->proxy_pd_count = ret;
  1777. }
  1778. qproc->has_alt_reset = desc->has_alt_reset;
  1779. ret = q6v5_init_reset(qproc);
  1780. if (ret)
  1781. goto detach_proxy_pds;
  1782. qproc->version = desc->version;
  1783. qproc->need_mem_protection = desc->need_mem_protection;
  1784. qproc->has_mba_logs = desc->has_mba_logs;
  1785. ret = qcom_q6v5_init(&qproc->q6v5, pdev, rproc, MPSS_CRASH_REASON_SMEM, "modem",
  1786. qcom_msa_handover);
  1787. if (ret)
  1788. goto detach_proxy_pds;
  1789. qproc->mpss_perm = BIT(QCOM_SCM_VMID_HLOS);
  1790. qproc->mba_perm = BIT(QCOM_SCM_VMID_HLOS);
  1791. qcom_add_glink_subdev(rproc, &qproc->glink_subdev, "mpss");
  1792. qcom_add_smd_subdev(rproc, &qproc->smd_subdev);
  1793. qcom_add_pdm_subdev(rproc, &qproc->pdm_subdev);
  1794. qcom_add_ssr_subdev(rproc, &qproc->ssr_subdev, "mpss");
  1795. qproc->sysmon = qcom_add_sysmon_subdev(rproc, "modem", 0x12);
  1796. if (IS_ERR(qproc->sysmon)) {
  1797. ret = PTR_ERR(qproc->sysmon);
  1798. goto remove_subdevs;
  1799. }
  1800. ret = rproc_add(rproc);
  1801. if (ret)
  1802. goto remove_sysmon_subdev;
  1803. node = of_get_compatible_child(pdev->dev.of_node, "qcom,bam-dmux");
  1804. qproc->bam_dmux = of_platform_device_create(node, NULL, &pdev->dev);
  1805. of_node_put(node);
  1806. return 0;
  1807. remove_sysmon_subdev:
  1808. qcom_remove_sysmon_subdev(qproc->sysmon);
  1809. remove_subdevs:
  1810. qcom_remove_ssr_subdev(rproc, &qproc->ssr_subdev);
  1811. qcom_remove_smd_subdev(rproc, &qproc->smd_subdev);
  1812. qcom_remove_glink_subdev(rproc, &qproc->glink_subdev);
  1813. detach_proxy_pds:
  1814. q6v5_pds_detach(qproc, qproc->proxy_pds, qproc->proxy_pd_count);
  1815. return ret;
  1816. }
  1817. static void q6v5_remove(struct platform_device *pdev)
  1818. {
  1819. struct q6v5 *qproc = platform_get_drvdata(pdev);
  1820. struct rproc *rproc = qproc->rproc;
  1821. if (qproc->bam_dmux)
  1822. of_platform_device_destroy(&qproc->bam_dmux->dev, NULL);
  1823. rproc_del(rproc);
  1824. qcom_q6v5_deinit(&qproc->q6v5);
  1825. qcom_remove_sysmon_subdev(qproc->sysmon);
  1826. qcom_remove_ssr_subdev(rproc, &qproc->ssr_subdev);
  1827. qcom_remove_pdm_subdev(rproc, &qproc->pdm_subdev);
  1828. qcom_remove_smd_subdev(rproc, &qproc->smd_subdev);
  1829. qcom_remove_glink_subdev(rproc, &qproc->glink_subdev);
  1830. q6v5_pds_detach(qproc, qproc->proxy_pds, qproc->proxy_pd_count);
  1831. }
  1832. static const struct rproc_hexagon_res sc7180_mss = {
  1833. .hexagon_mba_image = "mba.mbn",
  1834. .proxy_clk_names = (char*[]){
  1835. "xo",
  1836. NULL
  1837. },
  1838. .reset_clk_names = (char*[]){
  1839. "iface",
  1840. "bus",
  1841. "snoc_axi",
  1842. NULL
  1843. },
  1844. .active_clk_names = (char*[]){
  1845. "mnoc_axi",
  1846. "nav",
  1847. NULL
  1848. },
  1849. .proxy_pd_names = (char*[]){
  1850. "cx",
  1851. "mx",
  1852. "mss",
  1853. NULL
  1854. },
  1855. .need_mem_protection = true,
  1856. .has_alt_reset = false,
  1857. .has_mba_logs = true,
  1858. .has_spare_reg = true,
  1859. .has_qaccept_regs = false,
  1860. .has_ext_bhs_reg = false,
  1861. .has_ext_cntl_regs = false,
  1862. .has_vq6 = false,
  1863. .version = MSS_SC7180,
  1864. };
  1865. static const struct rproc_hexagon_res sc7280_mss = {
  1866. .hexagon_mba_image = "mba.mbn",
  1867. .proxy_clk_names = (char*[]){
  1868. "xo",
  1869. "pka",
  1870. NULL
  1871. },
  1872. .active_clk_names = (char*[]){
  1873. "iface",
  1874. "offline",
  1875. "snoc_axi",
  1876. NULL
  1877. },
  1878. .proxy_pd_names = (char*[]){
  1879. "cx",
  1880. "mss",
  1881. NULL
  1882. },
  1883. .need_mem_protection = true,
  1884. .has_alt_reset = false,
  1885. .has_mba_logs = true,
  1886. .has_spare_reg = false,
  1887. .has_qaccept_regs = true,
  1888. .has_ext_bhs_reg = false,
  1889. .has_ext_cntl_regs = true,
  1890. .has_vq6 = true,
  1891. .version = MSS_SC7280,
  1892. };
  1893. static const struct rproc_hexagon_res sdm660_mss = {
  1894. .hexagon_mba_image = "mba.mbn",
  1895. .proxy_clk_names = (char*[]){
  1896. "xo",
  1897. "qdss",
  1898. "mem",
  1899. NULL
  1900. },
  1901. .active_clk_names = (char*[]){
  1902. "iface",
  1903. "bus",
  1904. "gpll0_mss",
  1905. "mnoc_axi",
  1906. "snoc_axi",
  1907. NULL
  1908. },
  1909. .proxy_pd_names = (char*[]){
  1910. "cx",
  1911. "mx",
  1912. NULL
  1913. },
  1914. .need_mem_protection = true,
  1915. .has_alt_reset = false,
  1916. .has_mba_logs = false,
  1917. .has_spare_reg = false,
  1918. .has_qaccept_regs = false,
  1919. .has_ext_bhs_reg = false,
  1920. .has_ext_cntl_regs = false,
  1921. .has_vq6 = false,
  1922. .version = MSS_SDM660,
  1923. };
  1924. static const struct rproc_hexagon_res sdm845_mss = {
  1925. .hexagon_mba_image = "mba.mbn",
  1926. .proxy_clk_names = (char*[]){
  1927. "xo",
  1928. "prng",
  1929. NULL
  1930. },
  1931. .reset_clk_names = (char*[]){
  1932. "iface",
  1933. "snoc_axi",
  1934. NULL
  1935. },
  1936. .active_clk_names = (char*[]){
  1937. "bus",
  1938. "mem",
  1939. "gpll0_mss",
  1940. "mnoc_axi",
  1941. NULL
  1942. },
  1943. .proxy_pd_names = (char*[]){
  1944. "cx",
  1945. "mx",
  1946. "mss",
  1947. NULL
  1948. },
  1949. .need_mem_protection = true,
  1950. .has_alt_reset = true,
  1951. .has_mba_logs = false,
  1952. .has_spare_reg = false,
  1953. .has_qaccept_regs = false,
  1954. .has_ext_bhs_reg = false,
  1955. .has_ext_cntl_regs = false,
  1956. .has_vq6 = false,
  1957. .version = MSS_SDM845,
  1958. };
  1959. static const struct rproc_hexagon_res msm8998_mss = {
  1960. .hexagon_mba_image = "mba.mbn",
  1961. .proxy_clk_names = (char*[]){
  1962. "xo",
  1963. "qdss",
  1964. "mem",
  1965. NULL
  1966. },
  1967. .active_clk_names = (char*[]){
  1968. "iface",
  1969. "bus",
  1970. "gpll0_mss",
  1971. "mnoc_axi",
  1972. "snoc_axi",
  1973. NULL
  1974. },
  1975. .proxy_pd_names = (char*[]){
  1976. "cx",
  1977. "mx",
  1978. NULL
  1979. },
  1980. .need_mem_protection = true,
  1981. .has_alt_reset = false,
  1982. .has_mba_logs = false,
  1983. .has_spare_reg = false,
  1984. .has_qaccept_regs = false,
  1985. .has_ext_bhs_reg = false,
  1986. .has_ext_cntl_regs = false,
  1987. .has_vq6 = false,
  1988. .version = MSS_MSM8998,
  1989. };
  1990. static const struct rproc_hexagon_res msm8996_mss = {
  1991. .hexagon_mba_image = "mba.mbn",
  1992. .proxy_supply = (struct qcom_mss_reg_res[]) {
  1993. {
  1994. .supply = "pll",
  1995. .uA = 100000,
  1996. },
  1997. {}
  1998. },
  1999. .proxy_clk_names = (char*[]){
  2000. "xo",
  2001. "qdss",
  2002. NULL
  2003. },
  2004. .active_clk_names = (char*[]){
  2005. "iface",
  2006. "bus",
  2007. "mem",
  2008. "gpll0_mss",
  2009. "snoc_axi",
  2010. "mnoc_axi",
  2011. NULL
  2012. },
  2013. .proxy_pd_names = (char*[]){
  2014. "mx",
  2015. "cx",
  2016. NULL
  2017. },
  2018. .need_mem_protection = true,
  2019. .has_alt_reset = false,
  2020. .has_mba_logs = false,
  2021. .has_spare_reg = false,
  2022. .has_qaccept_regs = false,
  2023. .has_ext_bhs_reg = false,
  2024. .has_ext_cntl_regs = false,
  2025. .has_vq6 = false,
  2026. .version = MSS_MSM8996,
  2027. };
  2028. static const struct rproc_hexagon_res msm8909_mss = {
  2029. .hexagon_mba_image = "mba.mbn",
  2030. .proxy_supply = (struct qcom_mss_reg_res[]) {
  2031. {
  2032. .supply = "pll",
  2033. .uA = 100000,
  2034. },
  2035. {}
  2036. },
  2037. .proxy_clk_names = (char*[]){
  2038. "xo",
  2039. NULL
  2040. },
  2041. .active_clk_names = (char*[]){
  2042. "iface",
  2043. "bus",
  2044. "mem",
  2045. NULL
  2046. },
  2047. .proxy_pd_names = (char*[]){
  2048. "mx",
  2049. "cx",
  2050. NULL
  2051. },
  2052. .need_mem_protection = false,
  2053. .has_alt_reset = false,
  2054. .has_mba_logs = false,
  2055. .has_spare_reg = false,
  2056. .has_qaccept_regs = false,
  2057. .has_ext_bhs_reg = false,
  2058. .has_ext_cntl_regs = false,
  2059. .has_vq6 = false,
  2060. .version = MSS_MSM8909,
  2061. };
  2062. static const struct rproc_hexagon_res msm8916_mss = {
  2063. .hexagon_mba_image = "mba.mbn",
  2064. .proxy_supply = (struct qcom_mss_reg_res[]) {
  2065. {
  2066. .supply = "pll",
  2067. .uA = 100000,
  2068. },
  2069. {}
  2070. },
  2071. .fallback_proxy_supply = (struct qcom_mss_reg_res[]) {
  2072. {
  2073. .supply = "mx",
  2074. .uV = 1050000,
  2075. },
  2076. {
  2077. .supply = "cx",
  2078. .uA = 100000,
  2079. },
  2080. {}
  2081. },
  2082. .proxy_clk_names = (char*[]){
  2083. "xo",
  2084. NULL
  2085. },
  2086. .active_clk_names = (char*[]){
  2087. "iface",
  2088. "bus",
  2089. "mem",
  2090. NULL
  2091. },
  2092. .proxy_pd_names = (char*[]){
  2093. "mx",
  2094. "cx",
  2095. NULL
  2096. },
  2097. .need_mem_protection = false,
  2098. .has_alt_reset = false,
  2099. .has_mba_logs = false,
  2100. .has_spare_reg = false,
  2101. .has_qaccept_regs = false,
  2102. .has_ext_bhs_reg = false,
  2103. .has_ext_cntl_regs = false,
  2104. .has_vq6 = false,
  2105. .version = MSS_MSM8916,
  2106. };
  2107. static const struct rproc_hexagon_res msm8953_mss = {
  2108. .hexagon_mba_image = "mba.mbn",
  2109. .proxy_supply = (struct qcom_mss_reg_res[]) {
  2110. {
  2111. .supply = "pll",
  2112. .uA = 100000,
  2113. },
  2114. {}
  2115. },
  2116. .proxy_clk_names = (char*[]){
  2117. "xo",
  2118. NULL
  2119. },
  2120. .active_clk_names = (char*[]){
  2121. "iface",
  2122. "bus",
  2123. "mem",
  2124. NULL
  2125. },
  2126. .proxy_pd_names = (char*[]) {
  2127. "cx",
  2128. "mx",
  2129. "mss",
  2130. NULL
  2131. },
  2132. .need_mem_protection = false,
  2133. .has_alt_reset = false,
  2134. .has_mba_logs = false,
  2135. .has_spare_reg = false,
  2136. .has_qaccept_regs = false,
  2137. .has_ext_bhs_reg = false,
  2138. .has_ext_cntl_regs = false,
  2139. .has_vq6 = false,
  2140. .version = MSS_MSM8953,
  2141. };
  2142. static const struct rproc_hexagon_res msm8974_mss = {
  2143. .hexagon_mba_image = "mba.b00",
  2144. .proxy_supply = (struct qcom_mss_reg_res[]) {
  2145. {
  2146. .supply = "pll",
  2147. .uA = 100000,
  2148. },
  2149. {
  2150. .supply = "mx",
  2151. .uV = 1050000,
  2152. },
  2153. {}
  2154. },
  2155. .fallback_proxy_supply = (struct qcom_mss_reg_res[]) {
  2156. {
  2157. .supply = "cx",
  2158. .uA = 100000,
  2159. },
  2160. {}
  2161. },
  2162. .active_supply = (struct qcom_mss_reg_res[]) {
  2163. {
  2164. .supply = "mss",
  2165. .uV = 1050000,
  2166. .uA = 100000,
  2167. },
  2168. {}
  2169. },
  2170. .proxy_clk_names = (char*[]){
  2171. "xo",
  2172. NULL
  2173. },
  2174. .active_clk_names = (char*[]){
  2175. "iface",
  2176. "bus",
  2177. "mem",
  2178. NULL
  2179. },
  2180. .proxy_pd_names = (char*[]){
  2181. "cx",
  2182. NULL
  2183. },
  2184. .need_mem_protection = false,
  2185. .has_alt_reset = false,
  2186. .has_mba_logs = false,
  2187. .has_spare_reg = false,
  2188. .has_qaccept_regs = false,
  2189. .has_ext_bhs_reg = false,
  2190. .has_ext_cntl_regs = false,
  2191. .has_vq6 = false,
  2192. .version = MSS_MSM8974,
  2193. };
  2194. static const struct rproc_hexagon_res msm8226_mss = {
  2195. .hexagon_mba_image = "mba.b00",
  2196. .proxy_supply = (struct qcom_mss_reg_res[]) {
  2197. {
  2198. .supply = "pll",
  2199. .uA = 100000,
  2200. },
  2201. {
  2202. .supply = "mx",
  2203. .uV = 1050000,
  2204. },
  2205. {}
  2206. },
  2207. .proxy_clk_names = (char*[]){
  2208. "xo",
  2209. NULL
  2210. },
  2211. .active_clk_names = (char*[]){
  2212. "iface",
  2213. "bus",
  2214. "mem",
  2215. NULL
  2216. },
  2217. .proxy_pd_names = (char*[]){
  2218. "cx",
  2219. NULL
  2220. },
  2221. .need_mem_protection = false,
  2222. .has_alt_reset = false,
  2223. .has_mba_logs = false,
  2224. .has_spare_reg = false,
  2225. .has_qaccept_regs = false,
  2226. .has_ext_bhs_reg = true,
  2227. .has_ext_cntl_regs = false,
  2228. .has_vq6 = false,
  2229. .version = MSS_MSM8226,
  2230. };
  2231. static const struct rproc_hexagon_res msm8926_mss = {
  2232. .hexagon_mba_image = "mba.b00",
  2233. .proxy_supply = (struct qcom_mss_reg_res[]) {
  2234. {
  2235. .supply = "pll",
  2236. .uA = 100000,
  2237. },
  2238. {
  2239. .supply = "mx",
  2240. .uV = 1050000,
  2241. },
  2242. {}
  2243. },
  2244. .active_supply = (struct qcom_mss_reg_res[]) {
  2245. {
  2246. .supply = "mss",
  2247. .uV = 1050000,
  2248. .uA = 100000,
  2249. },
  2250. {}
  2251. },
  2252. .proxy_clk_names = (char*[]){
  2253. "xo",
  2254. NULL
  2255. },
  2256. .active_clk_names = (char*[]){
  2257. "iface",
  2258. "bus",
  2259. "mem",
  2260. NULL
  2261. },
  2262. .proxy_pd_names = (char*[]){
  2263. "cx",
  2264. NULL
  2265. },
  2266. .need_mem_protection = false,
  2267. .has_alt_reset = false,
  2268. .has_mba_logs = false,
  2269. .has_spare_reg = false,
  2270. .has_qaccept_regs = false,
  2271. .has_ext_bhs_reg = false,
  2272. .has_ext_cntl_regs = false,
  2273. .has_vq6 = false,
  2274. .version = MSS_MSM8926,
  2275. };
  2276. static const struct of_device_id q6v5_of_match[] = {
  2277. { .compatible = "qcom,q6v5-pil", .data = &msm8916_mss},
  2278. { .compatible = "qcom,msm8226-mss-pil", .data = &msm8226_mss},
  2279. { .compatible = "qcom,msm8909-mss-pil", .data = &msm8909_mss},
  2280. { .compatible = "qcom,msm8916-mss-pil", .data = &msm8916_mss},
  2281. { .compatible = "qcom,msm8926-mss-pil", .data = &msm8926_mss},
  2282. { .compatible = "qcom,msm8953-mss-pil", .data = &msm8953_mss},
  2283. { .compatible = "qcom,msm8974-mss-pil", .data = &msm8974_mss},
  2284. { .compatible = "qcom,msm8996-mss-pil", .data = &msm8996_mss},
  2285. { .compatible = "qcom,msm8998-mss-pil", .data = &msm8998_mss},
  2286. { .compatible = "qcom,sc7180-mss-pil", .data = &sc7180_mss},
  2287. { .compatible = "qcom,sc7280-mss-pil", .data = &sc7280_mss},
  2288. { .compatible = "qcom,sdm660-mss-pil", .data = &sdm660_mss},
  2289. { .compatible = "qcom,sdm845-mss-pil", .data = &sdm845_mss},
  2290. { },
  2291. };
  2292. MODULE_DEVICE_TABLE(of, q6v5_of_match);
  2293. static struct platform_driver q6v5_driver = {
  2294. .probe = q6v5_probe,
  2295. .remove = q6v5_remove,
  2296. .driver = {
  2297. .name = "qcom-q6v5-mss",
  2298. .of_match_table = q6v5_of_match,
  2299. },
  2300. };
  2301. module_platform_driver(q6v5_driver);
  2302. MODULE_DESCRIPTION("Qualcomm Self-authenticating modem remoteproc driver");
  2303. MODULE_LICENSE("GPL v2");