clk-pll.c 11 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /*
  3. * Copyright (c) 2014 MediaTek Inc.
  4. * Author: James Liao <jamesjj.liao@mediatek.com>
  5. */
  6. #include <linux/clk-provider.h>
  7. #include <linux/container_of.h>
  8. #include <linux/delay.h>
  9. #include <linux/err.h>
  10. #include <linux/io.h>
  11. #include <linux/module.h>
  12. #include <linux/of_address.h>
  13. #include <linux/platform_device.h>
  14. #include <linux/slab.h>
  15. #include "clk-pll.h"
  16. #define MHZ (1000 * 1000)
  17. #define REG_CON0 0
  18. #define REG_CON1 4
  19. #define CON0_BASE_EN BIT(0)
  20. #define CON0_PWR_ON BIT(0)
  21. #define CON0_ISO_EN BIT(1)
  22. #define PCW_CHG_BIT 31
  23. #define AUDPLL_TUNER_EN BIT(31)
  24. /* default 7 bits integer, can be overridden with pcwibits. */
  25. #define INTEGER_BITS 7
  26. int mtk_pll_is_prepared(struct clk_hw *hw)
  27. {
  28. struct mtk_clk_pll *pll = to_mtk_clk_pll(hw);
  29. return (readl(pll->en_addr) & BIT(pll->data->pll_en_bit)) != 0;
  30. }
  31. static int mtk_pll_fenc_is_prepared(struct clk_hw *hw)
  32. {
  33. struct mtk_clk_pll *pll = to_mtk_clk_pll(hw);
  34. return !!(readl(pll->fenc_addr) & BIT(pll->data->fenc_sta_bit));
  35. }
  36. static unsigned long __mtk_pll_recalc_rate(struct mtk_clk_pll *pll, u32 fin,
  37. u32 pcw, int postdiv)
  38. {
  39. int pcwbits = pll->data->pcwbits;
  40. int pcwfbits = 0;
  41. int ibits;
  42. u64 vco;
  43. u8 c = 0;
  44. /* The fractional part of the PLL divider. */
  45. ibits = pll->data->pcwibits ? pll->data->pcwibits : INTEGER_BITS;
  46. if (pcwbits > ibits)
  47. pcwfbits = pcwbits - ibits;
  48. vco = (u64)fin * pcw;
  49. if (pcwfbits && (vco & GENMASK(pcwfbits - 1, 0)))
  50. c = 1;
  51. vco >>= pcwfbits;
  52. if (c)
  53. vco++;
  54. return ((unsigned long)vco + postdiv - 1) / postdiv;
  55. }
  56. static void __mtk_pll_tuner_enable(struct mtk_clk_pll *pll)
  57. {
  58. u32 r;
  59. if (pll->tuner_en_addr) {
  60. r = readl(pll->tuner_en_addr) | BIT(pll->data->tuner_en_bit);
  61. writel(r, pll->tuner_en_addr);
  62. } else if (pll->tuner_addr) {
  63. r = readl(pll->tuner_addr) | AUDPLL_TUNER_EN;
  64. writel(r, pll->tuner_addr);
  65. }
  66. }
  67. static void __mtk_pll_tuner_disable(struct mtk_clk_pll *pll)
  68. {
  69. u32 r;
  70. if (pll->tuner_en_addr) {
  71. r = readl(pll->tuner_en_addr) & ~BIT(pll->data->tuner_en_bit);
  72. writel(r, pll->tuner_en_addr);
  73. } else if (pll->tuner_addr) {
  74. r = readl(pll->tuner_addr) & ~AUDPLL_TUNER_EN;
  75. writel(r, pll->tuner_addr);
  76. }
  77. }
  78. static void mtk_pll_set_rate_regs(struct mtk_clk_pll *pll, u32 pcw,
  79. int postdiv)
  80. {
  81. u32 chg, val;
  82. /* disable tuner */
  83. __mtk_pll_tuner_disable(pll);
  84. /* set postdiv */
  85. val = readl(pll->pd_addr);
  86. val &= ~(POSTDIV_MASK << pll->data->pd_shift);
  87. val |= (ffs(postdiv) - 1) << pll->data->pd_shift;
  88. /* postdiv and pcw need to set at the same time if on same register */
  89. if (pll->pd_addr != pll->pcw_addr) {
  90. writel(val, pll->pd_addr);
  91. val = readl(pll->pcw_addr);
  92. }
  93. /* set pcw */
  94. val &= ~GENMASK(pll->data->pcw_shift + pll->data->pcwbits - 1,
  95. pll->data->pcw_shift);
  96. val |= pcw << pll->data->pcw_shift;
  97. writel(val, pll->pcw_addr);
  98. chg = readl(pll->pcw_chg_addr) |
  99. BIT(pll->data->pcw_chg_bit ? : PCW_CHG_BIT);
  100. writel(chg, pll->pcw_chg_addr);
  101. if (pll->tuner_addr)
  102. writel(val + 1, pll->tuner_addr);
  103. /* restore tuner_en */
  104. __mtk_pll_tuner_enable(pll);
  105. udelay(20);
  106. }
  107. /*
  108. * mtk_pll_calc_values - calculate good values for a given input frequency.
  109. * @pll: The pll
  110. * @pcw: The pcw value (output)
  111. * @postdiv: The post divider (output)
  112. * @freq: The desired target frequency
  113. * @fin: The input frequency
  114. *
  115. */
  116. void mtk_pll_calc_values(struct mtk_clk_pll *pll, u32 *pcw, u32 *postdiv,
  117. u32 freq, u32 fin)
  118. {
  119. unsigned long fmin = pll->data->fmin ? pll->data->fmin : (1000 * MHZ);
  120. const struct mtk_pll_div_table *div_table = pll->data->div_table;
  121. u64 _pcw;
  122. int ibits;
  123. u32 val;
  124. if (freq > pll->data->fmax)
  125. freq = pll->data->fmax;
  126. if (div_table) {
  127. if (freq > div_table[0].freq)
  128. freq = div_table[0].freq;
  129. for (val = 0; div_table[val + 1].freq != 0; val++) {
  130. if (freq > div_table[val + 1].freq)
  131. break;
  132. }
  133. *postdiv = 1 << val;
  134. } else {
  135. for (val = 0; val < 5; val++) {
  136. *postdiv = 1 << val;
  137. if ((u64)freq * *postdiv >= fmin)
  138. break;
  139. }
  140. }
  141. /* _pcw = freq * postdiv / fin * 2^pcwfbits */
  142. ibits = pll->data->pcwibits ? pll->data->pcwibits : INTEGER_BITS;
  143. _pcw = ((u64)freq << val) << (pll->data->pcwbits - ibits);
  144. do_div(_pcw, fin);
  145. *pcw = (u32)_pcw;
  146. }
  147. int mtk_pll_set_rate(struct clk_hw *hw, unsigned long rate,
  148. unsigned long parent_rate)
  149. {
  150. struct mtk_clk_pll *pll = to_mtk_clk_pll(hw);
  151. u32 pcw = 0;
  152. u32 postdiv;
  153. mtk_pll_calc_values(pll, &pcw, &postdiv, rate, parent_rate);
  154. mtk_pll_set_rate_regs(pll, pcw, postdiv);
  155. return 0;
  156. }
  157. unsigned long mtk_pll_recalc_rate(struct clk_hw *hw, unsigned long parent_rate)
  158. {
  159. struct mtk_clk_pll *pll = to_mtk_clk_pll(hw);
  160. u32 postdiv;
  161. u32 pcw;
  162. postdiv = (readl(pll->pd_addr) >> pll->data->pd_shift) & POSTDIV_MASK;
  163. postdiv = 1 << postdiv;
  164. pcw = readl(pll->pcw_addr) >> pll->data->pcw_shift;
  165. pcw &= GENMASK(pll->data->pcwbits - 1, 0);
  166. return __mtk_pll_recalc_rate(pll, parent_rate, pcw, postdiv);
  167. }
  168. int mtk_pll_determine_rate(struct clk_hw *hw, struct clk_rate_request *req)
  169. {
  170. struct mtk_clk_pll *pll = to_mtk_clk_pll(hw);
  171. u32 pcw = 0;
  172. int postdiv;
  173. mtk_pll_calc_values(pll, &pcw, &postdiv, req->rate,
  174. req->best_parent_rate);
  175. req->rate = __mtk_pll_recalc_rate(pll, req->best_parent_rate, pcw,
  176. postdiv);
  177. return 0;
  178. }
  179. int mtk_pll_prepare(struct clk_hw *hw)
  180. {
  181. struct mtk_clk_pll *pll = to_mtk_clk_pll(hw);
  182. u32 r;
  183. r = readl(pll->pwr_addr) | CON0_PWR_ON;
  184. writel(r, pll->pwr_addr);
  185. udelay(1);
  186. r = readl(pll->pwr_addr) & ~CON0_ISO_EN;
  187. writel(r, pll->pwr_addr);
  188. udelay(1);
  189. r = readl(pll->en_addr) | BIT(pll->data->pll_en_bit);
  190. writel(r, pll->en_addr);
  191. if (pll->data->en_mask) {
  192. r = readl(pll->base_addr + REG_CON0) | pll->data->en_mask;
  193. writel(r, pll->base_addr + REG_CON0);
  194. }
  195. __mtk_pll_tuner_enable(pll);
  196. udelay(20);
  197. if (pll->data->flags & HAVE_RST_BAR) {
  198. r = readl(pll->base_addr + REG_CON0);
  199. r |= pll->data->rst_bar_mask;
  200. writel(r, pll->base_addr + REG_CON0);
  201. }
  202. return 0;
  203. }
  204. void mtk_pll_unprepare(struct clk_hw *hw)
  205. {
  206. struct mtk_clk_pll *pll = to_mtk_clk_pll(hw);
  207. u32 r;
  208. if (pll->data->flags & HAVE_RST_BAR) {
  209. r = readl(pll->base_addr + REG_CON0);
  210. r &= ~pll->data->rst_bar_mask;
  211. writel(r, pll->base_addr + REG_CON0);
  212. }
  213. __mtk_pll_tuner_disable(pll);
  214. if (pll->data->en_mask) {
  215. r = readl(pll->base_addr + REG_CON0) & ~pll->data->en_mask;
  216. writel(r, pll->base_addr + REG_CON0);
  217. }
  218. r = readl(pll->en_addr) & ~BIT(pll->data->pll_en_bit);
  219. writel(r, pll->en_addr);
  220. r = readl(pll->pwr_addr) | CON0_ISO_EN;
  221. writel(r, pll->pwr_addr);
  222. r = readl(pll->pwr_addr) & ~CON0_PWR_ON;
  223. writel(r, pll->pwr_addr);
  224. }
  225. static int mtk_pll_prepare_setclr(struct clk_hw *hw)
  226. {
  227. struct mtk_clk_pll *pll = to_mtk_clk_pll(hw);
  228. writel(BIT(pll->data->pll_en_bit), pll->en_set_addr);
  229. /* Wait 20us after enable for the PLL to stabilize */
  230. udelay(20);
  231. return 0;
  232. }
  233. static void mtk_pll_unprepare_setclr(struct clk_hw *hw)
  234. {
  235. struct mtk_clk_pll *pll = to_mtk_clk_pll(hw);
  236. writel(BIT(pll->data->pll_en_bit), pll->en_clr_addr);
  237. }
  238. const struct clk_ops mtk_pll_ops = {
  239. .is_prepared = mtk_pll_is_prepared,
  240. .prepare = mtk_pll_prepare,
  241. .unprepare = mtk_pll_unprepare,
  242. .recalc_rate = mtk_pll_recalc_rate,
  243. .determine_rate = mtk_pll_determine_rate,
  244. .set_rate = mtk_pll_set_rate,
  245. };
  246. const struct clk_ops mtk_pll_fenc_clr_set_ops = {
  247. .is_prepared = mtk_pll_fenc_is_prepared,
  248. .prepare = mtk_pll_prepare_setclr,
  249. .unprepare = mtk_pll_unprepare_setclr,
  250. .recalc_rate = mtk_pll_recalc_rate,
  251. .determine_rate = mtk_pll_determine_rate,
  252. .set_rate = mtk_pll_set_rate,
  253. };
  254. EXPORT_SYMBOL_GPL(mtk_pll_fenc_clr_set_ops);
  255. struct clk_hw *mtk_clk_register_pll_ops(struct mtk_clk_pll *pll,
  256. const struct mtk_pll_data *data,
  257. void __iomem *base,
  258. const struct clk_ops *pll_ops)
  259. {
  260. struct clk_init_data init = {};
  261. int ret;
  262. const char *parent_name = "clk26m";
  263. pll->base_addr = base + data->reg;
  264. pll->pwr_addr = base + data->pwr_reg;
  265. pll->pd_addr = base + data->pd_reg;
  266. pll->pcw_addr = base + data->pcw_reg;
  267. if (data->pcw_chg_reg)
  268. pll->pcw_chg_addr = base + data->pcw_chg_reg;
  269. else
  270. pll->pcw_chg_addr = pll->base_addr + REG_CON1;
  271. if (data->tuner_reg)
  272. pll->tuner_addr = base + data->tuner_reg;
  273. if (data->tuner_en_reg || data->tuner_en_bit)
  274. pll->tuner_en_addr = base + data->tuner_en_reg;
  275. if (data->en_reg)
  276. pll->en_addr = base + data->en_reg;
  277. else
  278. pll->en_addr = pll->base_addr + REG_CON0;
  279. if (data->en_set_reg)
  280. pll->en_set_addr = base + data->en_set_reg;
  281. if (data->en_clr_reg)
  282. pll->en_clr_addr = base + data->en_clr_reg;
  283. pll->hw.init = &init;
  284. pll->data = data;
  285. pll->fenc_addr = base + data->fenc_sta_ofs;
  286. init.name = data->name;
  287. init.flags = (data->flags & PLL_AO) ? CLK_IS_CRITICAL : 0;
  288. if (data->flags & PLL_PARENT_EN)
  289. init.flags |= CLK_OPS_PARENT_ENABLE;
  290. init.ops = pll_ops;
  291. if (data->parent_name)
  292. init.parent_names = &data->parent_name;
  293. else
  294. init.parent_names = &parent_name;
  295. init.num_parents = 1;
  296. ret = clk_hw_register(pll->dev, &pll->hw);
  297. if (ret)
  298. return ERR_PTR(ret);
  299. return &pll->hw;
  300. }
  301. struct clk_hw *mtk_clk_register_pll(struct device *dev,
  302. const struct mtk_pll_data *data,
  303. void __iomem *base)
  304. {
  305. struct mtk_clk_pll *pll;
  306. struct clk_hw *hw;
  307. const struct clk_ops *pll_ops = data->ops ? data->ops : &mtk_pll_ops;
  308. pll = kzalloc_obj(*pll);
  309. if (!pll)
  310. return ERR_PTR(-ENOMEM);
  311. pll->dev = dev;
  312. hw = mtk_clk_register_pll_ops(pll, data, base, pll_ops);
  313. if (IS_ERR(hw))
  314. kfree(pll);
  315. return hw;
  316. }
  317. void mtk_clk_unregister_pll(struct clk_hw *hw)
  318. {
  319. struct mtk_clk_pll *pll;
  320. if (!hw)
  321. return;
  322. pll = to_mtk_clk_pll(hw);
  323. clk_hw_unregister(hw);
  324. kfree(pll);
  325. }
  326. int mtk_clk_register_plls(struct device *dev,
  327. const struct mtk_pll_data *plls, int num_plls,
  328. struct clk_hw_onecell_data *clk_data)
  329. {
  330. void __iomem *base;
  331. int i;
  332. struct clk_hw *hw;
  333. base = of_iomap(dev->of_node, 0);
  334. if (!base) {
  335. pr_err("%s(): ioremap failed\n", __func__);
  336. return -EINVAL;
  337. }
  338. for (i = 0; i < num_plls; i++) {
  339. const struct mtk_pll_data *pll = &plls[i];
  340. if (!IS_ERR_OR_NULL(clk_data->hws[pll->id])) {
  341. pr_warn("%pOF: Trying to register duplicate clock ID: %d\n",
  342. dev->of_node, pll->id);
  343. continue;
  344. }
  345. hw = mtk_clk_register_pll(dev, pll, base);
  346. if (IS_ERR(hw)) {
  347. pr_err("Failed to register clk %s: %pe\n", pll->name,
  348. hw);
  349. goto err;
  350. }
  351. clk_data->hws[pll->id] = hw;
  352. }
  353. return 0;
  354. err:
  355. while (--i >= 0) {
  356. const struct mtk_pll_data *pll = &plls[i];
  357. mtk_clk_unregister_pll(clk_data->hws[pll->id]);
  358. clk_data->hws[pll->id] = ERR_PTR(-ENOENT);
  359. }
  360. iounmap(base);
  361. return PTR_ERR(hw);
  362. }
  363. EXPORT_SYMBOL_GPL(mtk_clk_register_plls);
  364. __iomem void *mtk_clk_pll_get_base(struct clk_hw *hw,
  365. const struct mtk_pll_data *data)
  366. {
  367. struct mtk_clk_pll *pll = to_mtk_clk_pll(hw);
  368. return pll->base_addr - data->reg;
  369. }
  370. void mtk_clk_unregister_plls(const struct mtk_pll_data *plls, int num_plls,
  371. struct clk_hw_onecell_data *clk_data)
  372. {
  373. __iomem void *base = NULL;
  374. int i;
  375. if (!clk_data)
  376. return;
  377. for (i = num_plls; i > 0; i--) {
  378. const struct mtk_pll_data *pll = &plls[i - 1];
  379. if (IS_ERR_OR_NULL(clk_data->hws[pll->id]))
  380. continue;
  381. /*
  382. * This is quite ugly but unfortunately the clks don't have
  383. * any device tied to them, so there's no place to store the
  384. * pointer to the I/O region base address. We have to fetch
  385. * it from one of the registered clks.
  386. */
  387. base = mtk_clk_pll_get_base(clk_data->hws[pll->id], pll);
  388. mtk_clk_unregister_pll(clk_data->hws[pll->id]);
  389. clk_data->hws[pll->id] = ERR_PTR(-ENOENT);
  390. }
  391. iounmap(base);
  392. }
  393. EXPORT_SYMBOL_GPL(mtk_clk_unregister_plls);
  394. MODULE_LICENSE("GPL");