clk-rpm.c 15 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /*
  3. * Copyright (c) 2016, Linaro Limited
  4. * Copyright (c) 2014, The Linux Foundation. All rights reserved.
  5. */
  6. #include <linux/cleanup.h>
  7. #include <linux/clk-provider.h>
  8. #include <linux/err.h>
  9. #include <linux/export.h>
  10. #include <linux/init.h>
  11. #include <linux/kernel.h>
  12. #include <linux/module.h>
  13. #include <linux/mutex.h>
  14. #include <linux/mfd/qcom_rpm.h>
  15. #include <linux/of.h>
  16. #include <linux/platform_device.h>
  17. #include <dt-bindings/mfd/qcom-rpm.h>
  18. #include <dt-bindings/clock/qcom,rpmcc.h>
  19. #define QCOM_RPM_MISC_CLK_TYPE 0x306b6c63
  20. #define QCOM_RPM_SCALING_ENABLE_ID 0x2
  21. #define QCOM_RPM_XO_MODE_ON 0x2
  22. static const struct clk_parent_data gcc_pxo[] = {
  23. { .fw_name = "pxo", .name = "pxo_board" },
  24. };
  25. static const struct clk_parent_data gcc_cxo[] = {
  26. { .fw_name = "cxo", .name = "cxo_board" },
  27. };
  28. #define DEFINE_CLK_RPM(_name, r_id) \
  29. static struct clk_rpm clk_rpm_##_name##_a_clk; \
  30. static struct clk_rpm clk_rpm_##_name##_clk = { \
  31. .rpm_clk_id = (r_id), \
  32. .peer = &clk_rpm_##_name##_a_clk, \
  33. .rate = INT_MAX, \
  34. .hw.init = &(struct clk_init_data){ \
  35. .ops = &clk_rpm_ops, \
  36. .name = #_name "_clk", \
  37. .parent_data = gcc_pxo, \
  38. .num_parents = ARRAY_SIZE(gcc_pxo), \
  39. }, \
  40. }; \
  41. static struct clk_rpm clk_rpm_##_name##_a_clk = { \
  42. .rpm_clk_id = (r_id), \
  43. .peer = &clk_rpm_##_name##_clk, \
  44. .active_only = true, \
  45. .rate = INT_MAX, \
  46. .hw.init = &(struct clk_init_data){ \
  47. .ops = &clk_rpm_ops, \
  48. .name = #_name "_a_clk", \
  49. .parent_data = gcc_pxo, \
  50. .num_parents = ARRAY_SIZE(gcc_pxo), \
  51. }, \
  52. }
  53. #define DEFINE_CLK_RPM_XO_BUFFER(_name, offset) \
  54. static struct clk_rpm clk_rpm_##_name##_clk = { \
  55. .rpm_clk_id = QCOM_RPM_CXO_BUFFERS, \
  56. .xo_offset = (offset), \
  57. .hw.init = &(struct clk_init_data){ \
  58. .ops = &clk_rpm_xo_ops, \
  59. .name = #_name "_clk", \
  60. .parent_data = gcc_cxo, \
  61. .num_parents = ARRAY_SIZE(gcc_cxo), \
  62. }, \
  63. }
  64. #define DEFINE_CLK_RPM_FIXED(_name, r_id, r) \
  65. static struct clk_rpm clk_rpm_##_name##_clk = { \
  66. .rpm_clk_id = (r_id), \
  67. .rate = (r), \
  68. .hw.init = &(struct clk_init_data){ \
  69. .ops = &clk_rpm_fixed_ops, \
  70. .name = #_name "_clk", \
  71. .parent_data = gcc_pxo, \
  72. .num_parents = ARRAY_SIZE(gcc_pxo), \
  73. }, \
  74. }
  75. #define to_clk_rpm(_hw) container_of(_hw, struct clk_rpm, hw)
  76. struct rpm_cc;
  77. struct clk_rpm {
  78. const int rpm_clk_id;
  79. const int xo_offset;
  80. const bool active_only;
  81. unsigned long rate;
  82. bool enabled;
  83. bool branch;
  84. struct clk_rpm *peer;
  85. struct clk_hw hw;
  86. struct qcom_rpm *rpm;
  87. struct rpm_cc *rpm_cc;
  88. };
  89. struct rpm_cc {
  90. struct clk_rpm **clks;
  91. size_t num_clks;
  92. u32 xo_buffer_value;
  93. struct mutex xo_lock;
  94. };
  95. struct rpm_clk_desc {
  96. struct clk_rpm **clks;
  97. size_t num_clks;
  98. };
  99. static DEFINE_MUTEX(rpm_clk_lock);
  100. static int clk_rpm_handoff(struct clk_rpm *r)
  101. {
  102. int ret;
  103. u32 value = INT_MAX;
  104. /*
  105. * The vendor tree simply reads the status for this
  106. * RPM clock.
  107. */
  108. if (r->rpm_clk_id == QCOM_RPM_PLL_4 ||
  109. r->rpm_clk_id == QCOM_RPM_CXO_BUFFERS)
  110. return 0;
  111. ret = qcom_rpm_write(r->rpm, QCOM_RPM_ACTIVE_STATE,
  112. r->rpm_clk_id, &value, 1);
  113. if (ret)
  114. return ret;
  115. ret = qcom_rpm_write(r->rpm, QCOM_RPM_SLEEP_STATE,
  116. r->rpm_clk_id, &value, 1);
  117. if (ret)
  118. return ret;
  119. return 0;
  120. }
  121. static int clk_rpm_set_rate_active(struct clk_rpm *r, unsigned long rate)
  122. {
  123. u32 value = DIV_ROUND_UP(rate, 1000); /* to kHz */
  124. return qcom_rpm_write(r->rpm, QCOM_RPM_ACTIVE_STATE,
  125. r->rpm_clk_id, &value, 1);
  126. }
  127. static int clk_rpm_set_rate_sleep(struct clk_rpm *r, unsigned long rate)
  128. {
  129. u32 value = DIV_ROUND_UP(rate, 1000); /* to kHz */
  130. return qcom_rpm_write(r->rpm, QCOM_RPM_SLEEP_STATE,
  131. r->rpm_clk_id, &value, 1);
  132. }
  133. static void to_active_sleep(struct clk_rpm *r, unsigned long rate,
  134. unsigned long *active, unsigned long *sleep)
  135. {
  136. *active = rate;
  137. /*
  138. * Active-only clocks don't care what the rate is during sleep. So,
  139. * they vote for zero.
  140. */
  141. if (r->active_only)
  142. *sleep = 0;
  143. else
  144. *sleep = *active;
  145. }
  146. static int clk_rpm_prepare(struct clk_hw *hw)
  147. {
  148. struct clk_rpm *r = to_clk_rpm(hw);
  149. struct clk_rpm *peer = r->peer;
  150. unsigned long this_rate = 0, this_sleep_rate = 0;
  151. unsigned long peer_rate = 0, peer_sleep_rate = 0;
  152. unsigned long active_rate, sleep_rate;
  153. int ret = 0;
  154. mutex_lock(&rpm_clk_lock);
  155. /* Don't send requests to the RPM if the rate has not been set. */
  156. if (!r->rate)
  157. goto out;
  158. to_active_sleep(r, r->rate, &this_rate, &this_sleep_rate);
  159. /* Take peer clock's rate into account only if it's enabled. */
  160. if (peer->enabled)
  161. to_active_sleep(peer, peer->rate,
  162. &peer_rate, &peer_sleep_rate);
  163. active_rate = max(this_rate, peer_rate);
  164. if (r->branch)
  165. active_rate = !!active_rate;
  166. ret = clk_rpm_set_rate_active(r, active_rate);
  167. if (ret)
  168. goto out;
  169. sleep_rate = max(this_sleep_rate, peer_sleep_rate);
  170. if (r->branch)
  171. sleep_rate = !!sleep_rate;
  172. ret = clk_rpm_set_rate_sleep(r, sleep_rate);
  173. if (ret)
  174. /* Undo the active set vote and restore it */
  175. ret = clk_rpm_set_rate_active(r, peer_rate);
  176. out:
  177. if (!ret)
  178. r->enabled = true;
  179. mutex_unlock(&rpm_clk_lock);
  180. return ret;
  181. }
  182. static void clk_rpm_unprepare(struct clk_hw *hw)
  183. {
  184. struct clk_rpm *r = to_clk_rpm(hw);
  185. struct clk_rpm *peer = r->peer;
  186. unsigned long peer_rate = 0, peer_sleep_rate = 0;
  187. unsigned long active_rate, sleep_rate;
  188. int ret;
  189. guard(mutex)(&rpm_clk_lock);
  190. if (!r->rate)
  191. return;
  192. /* Take peer clock's rate into account only if it's enabled. */
  193. if (peer->enabled)
  194. to_active_sleep(peer, peer->rate, &peer_rate,
  195. &peer_sleep_rate);
  196. active_rate = r->branch ? !!peer_rate : peer_rate;
  197. ret = clk_rpm_set_rate_active(r, active_rate);
  198. if (ret)
  199. return;
  200. sleep_rate = r->branch ? !!peer_sleep_rate : peer_sleep_rate;
  201. ret = clk_rpm_set_rate_sleep(r, sleep_rate);
  202. if (ret)
  203. return;
  204. r->enabled = false;
  205. }
  206. static int clk_rpm_xo_prepare(struct clk_hw *hw)
  207. {
  208. struct clk_rpm *r = to_clk_rpm(hw);
  209. struct rpm_cc *rcc = r->rpm_cc;
  210. int ret, clk_id = r->rpm_clk_id;
  211. u32 value;
  212. mutex_lock(&rcc->xo_lock);
  213. value = rcc->xo_buffer_value | (QCOM_RPM_XO_MODE_ON << r->xo_offset);
  214. ret = qcom_rpm_write(r->rpm, QCOM_RPM_ACTIVE_STATE, clk_id, &value, 1);
  215. if (!ret) {
  216. r->enabled = true;
  217. rcc->xo_buffer_value = value;
  218. }
  219. mutex_unlock(&rcc->xo_lock);
  220. return ret;
  221. }
  222. static void clk_rpm_xo_unprepare(struct clk_hw *hw)
  223. {
  224. struct clk_rpm *r = to_clk_rpm(hw);
  225. struct rpm_cc *rcc = r->rpm_cc;
  226. int ret, clk_id = r->rpm_clk_id;
  227. u32 value;
  228. mutex_lock(&rcc->xo_lock);
  229. value = rcc->xo_buffer_value & ~(QCOM_RPM_XO_MODE_ON << r->xo_offset);
  230. ret = qcom_rpm_write(r->rpm, QCOM_RPM_ACTIVE_STATE, clk_id, &value, 1);
  231. if (!ret) {
  232. r->enabled = false;
  233. rcc->xo_buffer_value = value;
  234. }
  235. mutex_unlock(&rcc->xo_lock);
  236. }
  237. static int clk_rpm_fixed_prepare(struct clk_hw *hw)
  238. {
  239. struct clk_rpm *r = to_clk_rpm(hw);
  240. u32 value = 1;
  241. int ret;
  242. ret = qcom_rpm_write(r->rpm, QCOM_RPM_ACTIVE_STATE,
  243. r->rpm_clk_id, &value, 1);
  244. if (!ret)
  245. r->enabled = true;
  246. return ret;
  247. }
  248. static void clk_rpm_fixed_unprepare(struct clk_hw *hw)
  249. {
  250. struct clk_rpm *r = to_clk_rpm(hw);
  251. u32 value = 0;
  252. int ret;
  253. ret = qcom_rpm_write(r->rpm, QCOM_RPM_ACTIVE_STATE,
  254. r->rpm_clk_id, &value, 1);
  255. if (!ret)
  256. r->enabled = false;
  257. }
  258. static int clk_rpm_set_rate(struct clk_hw *hw,
  259. unsigned long rate, unsigned long parent_rate)
  260. {
  261. struct clk_rpm *r = to_clk_rpm(hw);
  262. struct clk_rpm *peer = r->peer;
  263. unsigned long active_rate, sleep_rate;
  264. unsigned long this_rate = 0, this_sleep_rate = 0;
  265. unsigned long peer_rate = 0, peer_sleep_rate = 0;
  266. int ret;
  267. guard(mutex)(&rpm_clk_lock);
  268. if (!r->enabled)
  269. return 0;
  270. to_active_sleep(r, rate, &this_rate, &this_sleep_rate);
  271. /* Take peer clock's rate into account only if it's enabled. */
  272. if (peer->enabled)
  273. to_active_sleep(peer, peer->rate,
  274. &peer_rate, &peer_sleep_rate);
  275. active_rate = max(this_rate, peer_rate);
  276. ret = clk_rpm_set_rate_active(r, active_rate);
  277. if (ret)
  278. return ret;
  279. sleep_rate = max(this_sleep_rate, peer_sleep_rate);
  280. ret = clk_rpm_set_rate_sleep(r, sleep_rate);
  281. if (ret)
  282. return ret;
  283. r->rate = rate;
  284. return 0;
  285. }
  286. static int clk_rpm_determine_rate(struct clk_hw *hw,
  287. struct clk_rate_request *req)
  288. {
  289. /*
  290. * RPM handles rate rounding and we don't have a way to
  291. * know what the rate will be, so just return whatever
  292. * rate is requested.
  293. */
  294. return 0;
  295. }
  296. static unsigned long clk_rpm_recalc_rate(struct clk_hw *hw,
  297. unsigned long parent_rate)
  298. {
  299. struct clk_rpm *r = to_clk_rpm(hw);
  300. /*
  301. * RPM handles rate rounding and we don't have a way to
  302. * know what the rate will be, so just return whatever
  303. * rate was set.
  304. */
  305. return r->rate;
  306. }
  307. static const struct clk_ops clk_rpm_xo_ops = {
  308. .prepare = clk_rpm_xo_prepare,
  309. .unprepare = clk_rpm_xo_unprepare,
  310. };
  311. static const struct clk_ops clk_rpm_fixed_ops = {
  312. .prepare = clk_rpm_fixed_prepare,
  313. .unprepare = clk_rpm_fixed_unprepare,
  314. .determine_rate = clk_rpm_determine_rate,
  315. .recalc_rate = clk_rpm_recalc_rate,
  316. };
  317. static const struct clk_ops clk_rpm_ops = {
  318. .prepare = clk_rpm_prepare,
  319. .unprepare = clk_rpm_unprepare,
  320. .set_rate = clk_rpm_set_rate,
  321. .determine_rate = clk_rpm_determine_rate,
  322. .recalc_rate = clk_rpm_recalc_rate,
  323. };
  324. DEFINE_CLK_RPM(afab, QCOM_RPM_APPS_FABRIC_CLK);
  325. DEFINE_CLK_RPM(sfab, QCOM_RPM_SYS_FABRIC_CLK);
  326. DEFINE_CLK_RPM(mmfab, QCOM_RPM_MM_FABRIC_CLK);
  327. DEFINE_CLK_RPM(daytona, QCOM_RPM_DAYTONA_FABRIC_CLK);
  328. DEFINE_CLK_RPM(sfpb, QCOM_RPM_SFPB_CLK);
  329. DEFINE_CLK_RPM(cfpb, QCOM_RPM_CFPB_CLK);
  330. DEFINE_CLK_RPM(mmfpb, QCOM_RPM_MMFPB_CLK);
  331. DEFINE_CLK_RPM(smi, QCOM_RPM_SMI_CLK);
  332. DEFINE_CLK_RPM(ebi1, QCOM_RPM_EBI1_CLK);
  333. DEFINE_CLK_RPM(qdss, QCOM_RPM_QDSS_CLK);
  334. DEFINE_CLK_RPM(nss_fabric_0, QCOM_RPM_NSS_FABRIC_0_CLK);
  335. DEFINE_CLK_RPM(nss_fabric_1, QCOM_RPM_NSS_FABRIC_1_CLK);
  336. DEFINE_CLK_RPM_FIXED(pll4, QCOM_RPM_PLL_4, 540672000);
  337. DEFINE_CLK_RPM_XO_BUFFER(xo_d0, 0);
  338. DEFINE_CLK_RPM_XO_BUFFER(xo_d1, 8);
  339. DEFINE_CLK_RPM_XO_BUFFER(xo_a0, 16);
  340. DEFINE_CLK_RPM_XO_BUFFER(xo_a1, 24);
  341. DEFINE_CLK_RPM_XO_BUFFER(xo_a2, 28);
  342. static struct clk_rpm *msm8660_clks[] = {
  343. [RPM_APPS_FABRIC_CLK] = &clk_rpm_afab_clk,
  344. [RPM_APPS_FABRIC_A_CLK] = &clk_rpm_afab_a_clk,
  345. [RPM_SYS_FABRIC_CLK] = &clk_rpm_sfab_clk,
  346. [RPM_SYS_FABRIC_A_CLK] = &clk_rpm_sfab_a_clk,
  347. [RPM_MM_FABRIC_CLK] = &clk_rpm_mmfab_clk,
  348. [RPM_MM_FABRIC_A_CLK] = &clk_rpm_mmfab_a_clk,
  349. [RPM_DAYTONA_FABRIC_CLK] = &clk_rpm_daytona_clk,
  350. [RPM_DAYTONA_FABRIC_A_CLK] = &clk_rpm_daytona_a_clk,
  351. [RPM_SFPB_CLK] = &clk_rpm_sfpb_clk,
  352. [RPM_SFPB_A_CLK] = &clk_rpm_sfpb_a_clk,
  353. [RPM_CFPB_CLK] = &clk_rpm_cfpb_clk,
  354. [RPM_CFPB_A_CLK] = &clk_rpm_cfpb_a_clk,
  355. [RPM_MMFPB_CLK] = &clk_rpm_mmfpb_clk,
  356. [RPM_MMFPB_A_CLK] = &clk_rpm_mmfpb_a_clk,
  357. [RPM_SMI_CLK] = &clk_rpm_smi_clk,
  358. [RPM_SMI_A_CLK] = &clk_rpm_smi_a_clk,
  359. [RPM_EBI1_CLK] = &clk_rpm_ebi1_clk,
  360. [RPM_EBI1_A_CLK] = &clk_rpm_ebi1_a_clk,
  361. [RPM_PLL4_CLK] = &clk_rpm_pll4_clk,
  362. };
  363. static const struct rpm_clk_desc rpm_clk_msm8660 = {
  364. .clks = msm8660_clks,
  365. .num_clks = ARRAY_SIZE(msm8660_clks),
  366. };
  367. static struct clk_rpm *apq8064_clks[] = {
  368. [RPM_APPS_FABRIC_CLK] = &clk_rpm_afab_clk,
  369. [RPM_APPS_FABRIC_A_CLK] = &clk_rpm_afab_a_clk,
  370. [RPM_CFPB_CLK] = &clk_rpm_cfpb_clk,
  371. [RPM_CFPB_A_CLK] = &clk_rpm_cfpb_a_clk,
  372. [RPM_DAYTONA_FABRIC_CLK] = &clk_rpm_daytona_clk,
  373. [RPM_DAYTONA_FABRIC_A_CLK] = &clk_rpm_daytona_a_clk,
  374. [RPM_EBI1_CLK] = &clk_rpm_ebi1_clk,
  375. [RPM_EBI1_A_CLK] = &clk_rpm_ebi1_a_clk,
  376. [RPM_MM_FABRIC_CLK] = &clk_rpm_mmfab_clk,
  377. [RPM_MM_FABRIC_A_CLK] = &clk_rpm_mmfab_a_clk,
  378. [RPM_MMFPB_CLK] = &clk_rpm_mmfpb_clk,
  379. [RPM_MMFPB_A_CLK] = &clk_rpm_mmfpb_a_clk,
  380. [RPM_SYS_FABRIC_CLK] = &clk_rpm_sfab_clk,
  381. [RPM_SYS_FABRIC_A_CLK] = &clk_rpm_sfab_a_clk,
  382. [RPM_SFPB_CLK] = &clk_rpm_sfpb_clk,
  383. [RPM_SFPB_A_CLK] = &clk_rpm_sfpb_a_clk,
  384. [RPM_QDSS_CLK] = &clk_rpm_qdss_clk,
  385. [RPM_QDSS_A_CLK] = &clk_rpm_qdss_a_clk,
  386. [RPM_XO_D0] = &clk_rpm_xo_d0_clk,
  387. [RPM_XO_D1] = &clk_rpm_xo_d1_clk,
  388. [RPM_XO_A0] = &clk_rpm_xo_a0_clk,
  389. [RPM_XO_A1] = &clk_rpm_xo_a1_clk,
  390. [RPM_XO_A2] = &clk_rpm_xo_a2_clk,
  391. };
  392. static const struct rpm_clk_desc rpm_clk_apq8064 = {
  393. .clks = apq8064_clks,
  394. .num_clks = ARRAY_SIZE(apq8064_clks),
  395. };
  396. static struct clk_rpm *ipq806x_clks[] = {
  397. [RPM_APPS_FABRIC_CLK] = &clk_rpm_afab_clk,
  398. [RPM_APPS_FABRIC_A_CLK] = &clk_rpm_afab_a_clk,
  399. [RPM_CFPB_CLK] = &clk_rpm_cfpb_clk,
  400. [RPM_CFPB_A_CLK] = &clk_rpm_cfpb_a_clk,
  401. [RPM_DAYTONA_FABRIC_CLK] = &clk_rpm_daytona_clk,
  402. [RPM_DAYTONA_FABRIC_A_CLK] = &clk_rpm_daytona_a_clk,
  403. [RPM_EBI1_CLK] = &clk_rpm_ebi1_clk,
  404. [RPM_EBI1_A_CLK] = &clk_rpm_ebi1_a_clk,
  405. [RPM_SYS_FABRIC_CLK] = &clk_rpm_sfab_clk,
  406. [RPM_SYS_FABRIC_A_CLK] = &clk_rpm_sfab_a_clk,
  407. [RPM_SFPB_CLK] = &clk_rpm_sfpb_clk,
  408. [RPM_SFPB_A_CLK] = &clk_rpm_sfpb_a_clk,
  409. [RPM_NSS_FABRIC_0_CLK] = &clk_rpm_nss_fabric_0_clk,
  410. [RPM_NSS_FABRIC_0_A_CLK] = &clk_rpm_nss_fabric_0_a_clk,
  411. [RPM_NSS_FABRIC_1_CLK] = &clk_rpm_nss_fabric_1_clk,
  412. [RPM_NSS_FABRIC_1_A_CLK] = &clk_rpm_nss_fabric_1_a_clk,
  413. };
  414. static const struct rpm_clk_desc rpm_clk_ipq806x = {
  415. .clks = ipq806x_clks,
  416. .num_clks = ARRAY_SIZE(ipq806x_clks),
  417. };
  418. static const struct of_device_id rpm_clk_match_table[] = {
  419. { .compatible = "qcom,rpmcc-msm8660", .data = &rpm_clk_msm8660 },
  420. { .compatible = "qcom,rpmcc-apq8060", .data = &rpm_clk_msm8660 },
  421. { .compatible = "qcom,rpmcc-apq8064", .data = &rpm_clk_apq8064 },
  422. { .compatible = "qcom,rpmcc-ipq806x", .data = &rpm_clk_ipq806x },
  423. { }
  424. };
  425. MODULE_DEVICE_TABLE(of, rpm_clk_match_table);
  426. static struct clk_hw *qcom_rpm_clk_hw_get(struct of_phandle_args *clkspec,
  427. void *data)
  428. {
  429. struct rpm_cc *rcc = data;
  430. unsigned int idx = clkspec->args[0];
  431. if (idx >= rcc->num_clks) {
  432. pr_err("%s: invalid index %u\n", __func__, idx);
  433. return ERR_PTR(-EINVAL);
  434. }
  435. return rcc->clks[idx] ? &rcc->clks[idx]->hw : ERR_PTR(-ENOENT);
  436. }
  437. static int rpm_clk_probe(struct platform_device *pdev)
  438. {
  439. struct rpm_cc *rcc;
  440. int ret;
  441. size_t num_clks, i;
  442. struct qcom_rpm *rpm;
  443. struct clk_rpm **rpm_clks;
  444. const struct rpm_clk_desc *desc;
  445. rpm = dev_get_drvdata(pdev->dev.parent);
  446. if (!rpm) {
  447. dev_err(&pdev->dev, "Unable to retrieve handle to RPM\n");
  448. return -ENODEV;
  449. }
  450. desc = of_device_get_match_data(&pdev->dev);
  451. if (!desc)
  452. return -EINVAL;
  453. rpm_clks = desc->clks;
  454. num_clks = desc->num_clks;
  455. rcc = devm_kzalloc(&pdev->dev, sizeof(*rcc), GFP_KERNEL);
  456. if (!rcc)
  457. return -ENOMEM;
  458. rcc->clks = rpm_clks;
  459. rcc->num_clks = num_clks;
  460. mutex_init(&rcc->xo_lock);
  461. for (i = 0; i < num_clks; i++) {
  462. if (!rpm_clks[i])
  463. continue;
  464. rpm_clks[i]->rpm = rpm;
  465. rpm_clks[i]->rpm_cc = rcc;
  466. ret = clk_rpm_handoff(rpm_clks[i]);
  467. if (ret)
  468. goto err;
  469. }
  470. for (i = 0; i < num_clks; i++) {
  471. if (!rpm_clks[i])
  472. continue;
  473. ret = devm_clk_hw_register(&pdev->dev, &rpm_clks[i]->hw);
  474. if (ret)
  475. goto err;
  476. }
  477. ret = devm_of_clk_add_hw_provider(&pdev->dev, qcom_rpm_clk_hw_get,
  478. rcc);
  479. if (ret)
  480. goto err;
  481. return 0;
  482. err:
  483. dev_err(&pdev->dev, "Error registering RPM Clock driver (%d)\n", ret);
  484. return ret;
  485. }
  486. static struct platform_driver rpm_clk_driver = {
  487. .driver = {
  488. .name = "qcom-clk-rpm",
  489. .of_match_table = rpm_clk_match_table,
  490. },
  491. .probe = rpm_clk_probe,
  492. };
  493. static int __init rpm_clk_init(void)
  494. {
  495. return platform_driver_register(&rpm_clk_driver);
  496. }
  497. core_initcall(rpm_clk_init);
  498. static void __exit rpm_clk_exit(void)
  499. {
  500. platform_driver_unregister(&rpm_clk_driver);
  501. }
  502. module_exit(rpm_clk_exit);
  503. MODULE_DESCRIPTION("Qualcomm RPM Clock Controller Driver");
  504. MODULE_LICENSE("GPL v2");
  505. MODULE_ALIAS("platform:qcom-clk-rpm");