ltc4282.c 44 KB

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  1. // SPDX-License-Identifier: GPL-2.0
  2. /*
  3. * Analog Devices LTC4282 I2C High Current Hot Swap Controller over I2C
  4. *
  5. * Copyright 2023 Analog Devices Inc.
  6. */
  7. #include <linux/bitfield.h>
  8. #include <linux/cleanup.h>
  9. #include <linux/clk.h>
  10. #include <linux/clk-provider.h>
  11. #include <linux/debugfs.h>
  12. #include <linux/delay.h>
  13. #include <linux/device.h>
  14. #include <linux/hwmon.h>
  15. #include <linux/i2c.h>
  16. #include <linux/math.h>
  17. #include <linux/minmax.h>
  18. #include <linux/module.h>
  19. #include <linux/mod_devicetable.h>
  20. #include <linux/regmap.h>
  21. #include <linux/property.h>
  22. #include <linux/string.h>
  23. #include <linux/units.h>
  24. #include <linux/util_macros.h>
  25. #define LTC4282_CTRL_LSB 0x00
  26. #define LTC4282_CTRL_OV_RETRY_MASK BIT(0)
  27. #define LTC4282_CTRL_UV_RETRY_MASK BIT(1)
  28. #define LTC4282_CTRL_OC_RETRY_MASK BIT(2)
  29. #define LTC4282_CTRL_ON_ACTIVE_LOW_MASK BIT(5)
  30. #define LTC4282_CTRL_ON_DELAY_MASK BIT(6)
  31. #define LTC4282_CTRL_MSB 0x01
  32. #define LTC4282_CTRL_VIN_MODE_MASK GENMASK(1, 0)
  33. #define LTC4282_CTRL_OV_MODE_MASK GENMASK(3, 2)
  34. #define LTC4282_CTRL_UV_MODE_MASK GENMASK(5, 4)
  35. #define LTC4282_FAULT_LOG 0x04
  36. #define LTC4282_OV_FAULT_MASK BIT(0)
  37. #define LTC4282_UV_FAULT_MASK BIT(1)
  38. #define LTC4282_VDD_FAULT_MASK \
  39. (LTC4282_OV_FAULT_MASK | LTC4282_UV_FAULT_MASK)
  40. #define LTC4282_OC_FAULT_MASK BIT(2)
  41. #define LTC4282_POWER_BAD_FAULT_MASK BIT(3)
  42. #define LTC4282_FET_SHORT_FAULT_MASK BIT(5)
  43. #define LTC4282_FET_BAD_FAULT_MASK BIT(6)
  44. #define LTC4282_FET_FAILURE_FAULT_MASK \
  45. (LTC4282_FET_SHORT_FAULT_MASK | LTC4282_FET_BAD_FAULT_MASK)
  46. #define LTC4282_ADC_ALERT_LOG 0x05
  47. #define LTC4282_GPIO_ALARM_L_MASK BIT(0)
  48. #define LTC4282_GPIO_ALARM_H_MASK BIT(1)
  49. #define LTC4282_VSOURCE_ALARM_L_MASK BIT(2)
  50. #define LTC4282_VSOURCE_ALARM_H_MASK BIT(3)
  51. #define LTC4282_VSENSE_ALARM_L_MASK BIT(4)
  52. #define LTC4282_VSENSE_ALARM_H_MASK BIT(5)
  53. #define LTC4282_POWER_ALARM_L_MASK BIT(6)
  54. #define LTC4282_POWER_ALARM_H_MASK BIT(7)
  55. #define LTC4282_FET_BAD_FAULT_TIMEOUT 0x06
  56. #define LTC4282_FET_BAD_MAX_TIMEOUT 255
  57. #define LTC4282_GPIO_CONFIG 0x07
  58. #define LTC4282_GPIO_2_FET_STRESS_MASK BIT(1)
  59. #define LTC4282_GPIO_1_CONFIG_MASK GENMASK(5, 4)
  60. #define LTC4282_VGPIO_MIN 0x08
  61. #define LTC4282_VGPIO_MAX 0x09
  62. #define LTC4282_VSOURCE_MIN 0x0a
  63. #define LTC4282_VSOURCE_MAX 0x0b
  64. #define LTC4282_VSENSE_MIN 0x0c
  65. #define LTC4282_VSENSE_MAX 0x0d
  66. #define LTC4282_POWER_MIN 0x0e
  67. #define LTC4282_POWER_MAX 0x0f
  68. #define LTC4282_CLK_DIV 0x10
  69. #define LTC4282_CLK_DIV_MASK GENMASK(4, 0)
  70. #define LTC4282_CLKOUT_MASK GENMASK(6, 5)
  71. #define LTC4282_ILIM_ADJUST 0x11
  72. #define LTC4282_GPIO_MODE_MASK BIT(1)
  73. #define LTC4282_VDD_MONITOR_MASK BIT(2)
  74. #define LTC4282_FOLDBACK_MODE_MASK GENMASK(4, 3)
  75. #define LTC4282_ILIM_ADJUST_MASK GENMASK(7, 5)
  76. #define LTC4282_ENERGY 0x12
  77. #define LTC4282_TIME_COUNTER 0x18
  78. #define LTC4282_ALERT_CTRL 0x1c
  79. #define LTC4282_ALERT_OUT_MASK BIT(6)
  80. #define LTC4282_ADC_CTRL 0x1d
  81. #define LTC4282_FAULT_LOG_EN_MASK BIT(2)
  82. #define LTC4282_METER_HALT_MASK BIT(5)
  83. #define LTC4282_METER_RESET_MASK BIT(6)
  84. #define LTC4282_RESET_MASK BIT(7)
  85. #define LTC4282_STATUS_LSB 0x1e
  86. #define LTC4282_OV_STATUS_MASK BIT(0)
  87. #define LTC4282_UV_STATUS_MASK BIT(1)
  88. #define LTC4282_VDD_STATUS_MASK \
  89. (LTC4282_OV_STATUS_MASK | LTC4282_UV_STATUS_MASK)
  90. #define LTC4282_OC_STATUS_MASK BIT(2)
  91. #define LTC4282_POWER_GOOD_MASK BIT(3)
  92. #define LTC4282_FET_FAILURE_MASK GENMASK(6, 5)
  93. #define LTC4282_STATUS_MSB 0x1f
  94. #define LTC4282_RESERVED_1 0x32
  95. #define LTC4282_RESERVED_2 0x33
  96. #define LTC4282_VGPIO 0x34
  97. #define LTC4282_VGPIO_LOWEST 0x36
  98. #define LTC4282_VGPIO_HIGHEST 0x38
  99. #define LTC4282_VSOURCE 0x3a
  100. #define LTC4282_VSOURCE_LOWEST 0x3c
  101. #define LTC4282_VSOURCE_HIGHEST 0x3e
  102. #define LTC4282_VSENSE 0x40
  103. #define LTC4282_VSENSE_LOWEST 0x42
  104. #define LTC4282_VSENSE_HIGHEST 0x44
  105. #define LTC4282_POWER 0x46
  106. #define LTC4282_POWER_LOWEST 0x48
  107. #define LTC4282_POWER_HIGHEST 0x4a
  108. #define LTC4282_RESERVED_3 0x50
  109. #define LTC4282_CLKIN_MIN (250 * KILO)
  110. #define LTC4282_CLKIN_MAX (15500 * KILO)
  111. #define LTC4282_CLKIN_RANGE (LTC4282_CLKIN_MAX - LTC4282_CLKIN_MIN + 1)
  112. #define LTC4282_CLKOUT_SYSTEM (250 * KILO)
  113. #define LTC4282_CLKOUT_CNV 15
  114. enum {
  115. LTC4282_CHAN_VSOURCE,
  116. LTC4282_CHAN_VDD,
  117. LTC4282_CHAN_VGPIO,
  118. };
  119. struct ltc4282_cache {
  120. u32 in_max_raw;
  121. u32 in_min_raw;
  122. long in_highest;
  123. long in_lowest;
  124. bool en;
  125. };
  126. struct ltc4282_state {
  127. struct regmap *map;
  128. struct clk_hw clk_hw;
  129. /*
  130. * Used to cache values for VDD/VSOURCE depending which will be used
  131. * when hwmon is not enabled for that channel. Needed because they share
  132. * the same registers.
  133. */
  134. struct ltc4282_cache in0_1_cache[LTC4282_CHAN_VGPIO];
  135. u32 vsense_max;
  136. long power_max;
  137. u32 rsense;
  138. u16 vdd;
  139. u16 vfs_out;
  140. bool energy_en;
  141. };
  142. enum {
  143. LTC4282_CLKOUT_NONE,
  144. LTC4282_CLKOUT_INT,
  145. LTC4282_CLKOUT_TICK,
  146. };
  147. static int ltc4282_set_rate(struct clk_hw *hw,
  148. unsigned long rate, unsigned long parent_rate)
  149. {
  150. struct ltc4282_state *st = container_of(hw, struct ltc4282_state,
  151. clk_hw);
  152. u32 val = LTC4282_CLKOUT_INT;
  153. if (rate == LTC4282_CLKOUT_CNV)
  154. val = LTC4282_CLKOUT_TICK;
  155. return regmap_update_bits(st->map, LTC4282_CLK_DIV, LTC4282_CLKOUT_MASK,
  156. FIELD_PREP(LTC4282_CLKOUT_MASK, val));
  157. }
  158. /*
  159. * Note the 15HZ conversion rate assumes 12bit ADC which is what we are
  160. * supporting for now.
  161. */
  162. static const unsigned int ltc4282_out_rates[] = {
  163. LTC4282_CLKOUT_CNV, LTC4282_CLKOUT_SYSTEM
  164. };
  165. static int ltc4282_determine_rate(struct clk_hw *hw,
  166. struct clk_rate_request *req)
  167. {
  168. int idx = find_closest(req->rate, ltc4282_out_rates,
  169. ARRAY_SIZE(ltc4282_out_rates));
  170. req->rate = ltc4282_out_rates[idx];
  171. return 0;
  172. }
  173. static unsigned long ltc4282_recalc_rate(struct clk_hw *hw,
  174. unsigned long parent)
  175. {
  176. struct ltc4282_state *st = container_of(hw, struct ltc4282_state,
  177. clk_hw);
  178. u32 clkdiv;
  179. int ret;
  180. ret = regmap_read(st->map, LTC4282_CLK_DIV, &clkdiv);
  181. if (ret)
  182. return 0;
  183. clkdiv = FIELD_GET(LTC4282_CLKOUT_MASK, clkdiv);
  184. if (!clkdiv)
  185. return 0;
  186. if (clkdiv == LTC4282_CLKOUT_INT)
  187. return LTC4282_CLKOUT_SYSTEM;
  188. return LTC4282_CLKOUT_CNV;
  189. }
  190. static void ltc4282_disable(struct clk_hw *clk_hw)
  191. {
  192. struct ltc4282_state *st = container_of(clk_hw, struct ltc4282_state,
  193. clk_hw);
  194. regmap_clear_bits(st->map, LTC4282_CLK_DIV, LTC4282_CLKOUT_MASK);
  195. }
  196. static int ltc4282_read_voltage_word(const struct ltc4282_state *st, u32 reg,
  197. u32 fs, long *val)
  198. {
  199. __be16 in;
  200. int ret;
  201. ret = regmap_bulk_read(st->map, reg, &in, sizeof(in));
  202. if (ret)
  203. return ret;
  204. /*
  205. * This is also used to calculate current in which case fs comes in
  206. * 10 * uV. Hence the ULL usage.
  207. */
  208. *val = DIV_ROUND_CLOSEST_ULL(be16_to_cpu(in) * (u64)fs, U16_MAX);
  209. return 0;
  210. }
  211. static int ltc4282_read_voltage_byte_cached(const struct ltc4282_state *st,
  212. u32 reg, u32 fs, long *val,
  213. u32 *cached_raw)
  214. {
  215. int ret;
  216. u32 in;
  217. if (cached_raw) {
  218. in = *cached_raw;
  219. } else {
  220. ret = regmap_read(st->map, reg, &in);
  221. if (ret)
  222. return ret;
  223. }
  224. *val = DIV_ROUND_CLOSEST(in * fs, U8_MAX);
  225. return 0;
  226. }
  227. static int ltc4282_read_voltage_byte(const struct ltc4282_state *st, u32 reg,
  228. u32 fs, long *val)
  229. {
  230. return ltc4282_read_voltage_byte_cached(st, reg, fs, val, NULL);
  231. }
  232. static int __ltc4282_read_alarm(struct ltc4282_state *st, u32 reg, u32 mask,
  233. long *val)
  234. {
  235. u32 alarm;
  236. int ret;
  237. ret = regmap_read(st->map, reg, &alarm);
  238. if (ret)
  239. return ret;
  240. *val = !!(alarm & mask);
  241. /* if not status/fault logs, clear the alarm after reading it */
  242. if (reg != LTC4282_STATUS_LSB && reg != LTC4282_FAULT_LOG)
  243. return regmap_clear_bits(st->map, reg, mask);
  244. return 0;
  245. }
  246. static int ltc4282_read_alarm(struct ltc4282_state *st, u32 reg, u32 mask,
  247. long *val)
  248. {
  249. return __ltc4282_read_alarm(st, reg, mask, val);
  250. }
  251. static int ltc4282_vdd_source_read_in(struct ltc4282_state *st, u32 channel,
  252. long *val)
  253. {
  254. if (!st->in0_1_cache[channel].en)
  255. return -ENODATA;
  256. return ltc4282_read_voltage_word(st, LTC4282_VSOURCE, st->vfs_out, val);
  257. }
  258. static int ltc4282_vdd_source_read_hist(struct ltc4282_state *st, u32 reg,
  259. u32 channel, long *cached, long *val)
  260. {
  261. int ret;
  262. if (!st->in0_1_cache[channel].en) {
  263. *val = *cached;
  264. return 0;
  265. }
  266. ret = ltc4282_read_voltage_word(st, reg, st->vfs_out, val);
  267. if (ret)
  268. return ret;
  269. *cached = *val;
  270. return 0;
  271. }
  272. static int ltc4282_vdd_source_read_lim(struct ltc4282_state *st, u32 reg,
  273. u32 channel, u32 *cached, long *val)
  274. {
  275. if (!st->in0_1_cache[channel].en)
  276. return ltc4282_read_voltage_byte_cached(st, reg, st->vfs_out,
  277. val, cached);
  278. return ltc4282_read_voltage_byte(st, reg, st->vfs_out, val);
  279. }
  280. static int ltc4282_vdd_source_read_alm(struct ltc4282_state *st, u32 mask,
  281. u32 channel, long *val)
  282. {
  283. if (!st->in0_1_cache[channel].en) {
  284. /*
  285. * Do this otherwise alarms can get confused because we clear
  286. * them after reading them. So, if someone mistakenly reads
  287. * VSOURCE right before VDD (or the other way around), we might
  288. * get no alarm just because it was cleared when reading VSOURCE
  289. * and had no time for a new conversion and thus having the
  290. * alarm again.
  291. */
  292. *val = 0;
  293. return 0;
  294. }
  295. return __ltc4282_read_alarm(st, LTC4282_ADC_ALERT_LOG, mask, val);
  296. }
  297. static int ltc4282_read_in(struct ltc4282_state *st, u32 attr, long *val,
  298. u32 channel)
  299. {
  300. switch (attr) {
  301. case hwmon_in_input:
  302. if (channel == LTC4282_CHAN_VGPIO)
  303. return ltc4282_read_voltage_word(st, LTC4282_VGPIO,
  304. 1280, val);
  305. return ltc4282_vdd_source_read_in(st, channel, val);
  306. case hwmon_in_highest:
  307. if (channel == LTC4282_CHAN_VGPIO)
  308. return ltc4282_read_voltage_word(st,
  309. LTC4282_VGPIO_HIGHEST,
  310. 1280, val);
  311. return ltc4282_vdd_source_read_hist(st, LTC4282_VSOURCE_HIGHEST,
  312. channel,
  313. &st->in0_1_cache[channel].in_highest, val);
  314. case hwmon_in_lowest:
  315. if (channel == LTC4282_CHAN_VGPIO)
  316. return ltc4282_read_voltage_word(st, LTC4282_VGPIO_LOWEST,
  317. 1280, val);
  318. return ltc4282_vdd_source_read_hist(st, LTC4282_VSOURCE_LOWEST,
  319. channel,
  320. &st->in0_1_cache[channel].in_lowest, val);
  321. case hwmon_in_max_alarm:
  322. if (channel == LTC4282_CHAN_VGPIO)
  323. return ltc4282_read_alarm(st, LTC4282_ADC_ALERT_LOG,
  324. LTC4282_GPIO_ALARM_H_MASK,
  325. val);
  326. return ltc4282_vdd_source_read_alm(st,
  327. LTC4282_VSOURCE_ALARM_H_MASK,
  328. channel, val);
  329. case hwmon_in_min_alarm:
  330. if (channel == LTC4282_CHAN_VGPIO)
  331. ltc4282_read_alarm(st, LTC4282_ADC_ALERT_LOG,
  332. LTC4282_GPIO_ALARM_L_MASK, val);
  333. return ltc4282_vdd_source_read_alm(st,
  334. LTC4282_VSOURCE_ALARM_L_MASK,
  335. channel, val);
  336. case hwmon_in_crit_alarm:
  337. return ltc4282_read_alarm(st, LTC4282_STATUS_LSB,
  338. LTC4282_OV_STATUS_MASK, val);
  339. case hwmon_in_lcrit_alarm:
  340. return ltc4282_read_alarm(st, LTC4282_STATUS_LSB,
  341. LTC4282_UV_STATUS_MASK, val);
  342. case hwmon_in_max:
  343. if (channel == LTC4282_CHAN_VGPIO)
  344. return ltc4282_read_voltage_byte(st, LTC4282_VGPIO_MAX,
  345. 1280, val);
  346. return ltc4282_vdd_source_read_lim(st, LTC4282_VSOURCE_MAX,
  347. channel,
  348. &st->in0_1_cache[channel].in_max_raw, val);
  349. case hwmon_in_min:
  350. if (channel == LTC4282_CHAN_VGPIO)
  351. return ltc4282_read_voltage_byte(st, LTC4282_VGPIO_MIN,
  352. 1280, val);
  353. return ltc4282_vdd_source_read_lim(st, LTC4282_VSOURCE_MIN,
  354. channel,
  355. &st->in0_1_cache[channel].in_min_raw, val);
  356. case hwmon_in_enable:
  357. *val = st->in0_1_cache[channel].en;
  358. return 0;
  359. case hwmon_in_fault:
  360. /*
  361. * We report failure if we detect either a fer_bad or a
  362. * fet_short in the status register.
  363. */
  364. return ltc4282_read_alarm(st, LTC4282_STATUS_LSB,
  365. LTC4282_FET_FAILURE_MASK, val);
  366. default:
  367. return -EOPNOTSUPP;
  368. }
  369. }
  370. static int ltc4282_read_current_word(const struct ltc4282_state *st, u32 reg,
  371. long *val)
  372. {
  373. long in;
  374. int ret;
  375. /*
  376. * We pass in full scale in 10 * micro (note that 40 is already
  377. * millivolt) so we have better approximations to calculate current.
  378. */
  379. ret = ltc4282_read_voltage_word(st, reg, DECA * 40 * MILLI, &in);
  380. if (ret)
  381. return ret;
  382. *val = DIV_ROUND_CLOSEST(in * MILLI, st->rsense);
  383. return 0;
  384. }
  385. static int ltc4282_read_current_byte(const struct ltc4282_state *st, u32 reg,
  386. long *val)
  387. {
  388. long in;
  389. int ret;
  390. ret = ltc4282_read_voltage_byte(st, reg, DECA * 40 * MILLI, &in);
  391. if (ret)
  392. return ret;
  393. *val = DIV_ROUND_CLOSEST(in * MILLI, st->rsense);
  394. return 0;
  395. }
  396. static int ltc4282_read_curr(struct ltc4282_state *st, const u32 attr,
  397. long *val)
  398. {
  399. switch (attr) {
  400. case hwmon_curr_input:
  401. return ltc4282_read_current_word(st, LTC4282_VSENSE, val);
  402. case hwmon_curr_highest:
  403. return ltc4282_read_current_word(st, LTC4282_VSENSE_HIGHEST,
  404. val);
  405. case hwmon_curr_lowest:
  406. return ltc4282_read_current_word(st, LTC4282_VSENSE_LOWEST,
  407. val);
  408. case hwmon_curr_max:
  409. return ltc4282_read_current_byte(st, LTC4282_VSENSE_MAX, val);
  410. case hwmon_curr_min:
  411. return ltc4282_read_current_byte(st, LTC4282_VSENSE_MIN, val);
  412. case hwmon_curr_max_alarm:
  413. return ltc4282_read_alarm(st, LTC4282_ADC_ALERT_LOG,
  414. LTC4282_VSENSE_ALARM_H_MASK, val);
  415. case hwmon_curr_min_alarm:
  416. return ltc4282_read_alarm(st, LTC4282_ADC_ALERT_LOG,
  417. LTC4282_VSENSE_ALARM_L_MASK, val);
  418. case hwmon_curr_crit_alarm:
  419. return ltc4282_read_alarm(st, LTC4282_STATUS_LSB,
  420. LTC4282_OC_STATUS_MASK, val);
  421. default:
  422. return -EOPNOTSUPP;
  423. }
  424. }
  425. static int ltc4282_read_power_word(const struct ltc4282_state *st, u32 reg,
  426. long *val)
  427. {
  428. u64 temp = DECA * 40ULL * st->vfs_out * BIT(16), temp_2;
  429. __be16 raw;
  430. u16 power;
  431. int ret;
  432. ret = regmap_bulk_read(st->map, reg, &raw, sizeof(raw));
  433. if (ret)
  434. return ret;
  435. power = be16_to_cpu(raw);
  436. /*
  437. * Power is given by:
  438. * P = CODE(16b) * 0.040 * Vfs(out) * 2^16 / ((2^16 - 1)^2 * Rsense)
  439. */
  440. if (check_mul_overflow(power * temp, MICRO, &temp_2)) {
  441. temp = DIV_ROUND_CLOSEST_ULL(power * temp, U16_MAX);
  442. *val = DIV64_U64_ROUND_CLOSEST(temp * MICRO,
  443. U16_MAX * (u64)st->rsense);
  444. return 0;
  445. }
  446. *val = DIV64_U64_ROUND_CLOSEST(temp_2,
  447. st->rsense * int_pow(U16_MAX, 2));
  448. return 0;
  449. }
  450. static int ltc4282_read_power_byte(const struct ltc4282_state *st, u32 reg,
  451. long *val)
  452. {
  453. u32 power;
  454. u64 temp;
  455. int ret;
  456. ret = regmap_read(st->map, reg, &power);
  457. if (ret)
  458. return ret;
  459. temp = power * 40 * DECA * st->vfs_out * BIT_ULL(8);
  460. *val = DIV64_U64_ROUND_CLOSEST(temp * MICRO,
  461. int_pow(U8_MAX, 2) * st->rsense);
  462. return 0;
  463. }
  464. static int ltc4282_read_energy(const struct ltc4282_state *st, s64 *val)
  465. {
  466. u64 temp, energy;
  467. __be64 raw;
  468. int ret;
  469. ret = regmap_bulk_read(st->map, LTC4282_ENERGY, &raw, 6);
  470. if (ret)
  471. return ret;
  472. energy = be64_to_cpu(raw) >> 16;
  473. /*
  474. * The formula for energy is given by:
  475. * E = CODE(48b) * 0.040 * Vfs(out) * Tconv * 256 /
  476. * ((2^16 - 1)^2 * Rsense)
  477. *
  478. * Since we only support 12bit ADC, Tconv = 0.065535s. Passing Vfs(out)
  479. * and 0.040 to mV and Tconv to us, we can simplify the formula to:
  480. * E = CODE(48b) * 40 * Vfs(out) * 256 / (U16_MAX * Rsense)
  481. *
  482. * As Rsense can have tenths of micro-ohm resolution, we need to
  483. * multiply by DECA to get microujoule.
  484. */
  485. if (check_mul_overflow(DECA * st->vfs_out * 40 * BIT(8), energy, &temp)) {
  486. temp = DIV_ROUND_CLOSEST(DECA * st->vfs_out * 40 * BIT(8), U16_MAX);
  487. *val = DIV_ROUND_CLOSEST_ULL(temp * energy, st->rsense);
  488. return 0;
  489. }
  490. *val = DIV64_U64_ROUND_CLOSEST(temp, U16_MAX * (u64)st->rsense);
  491. return 0;
  492. }
  493. static int ltc4282_read_power(struct ltc4282_state *st, const u32 attr,
  494. long *val)
  495. {
  496. switch (attr) {
  497. case hwmon_power_input:
  498. return ltc4282_read_power_word(st, LTC4282_POWER, val);
  499. case hwmon_power_input_highest:
  500. return ltc4282_read_power_word(st, LTC4282_POWER_HIGHEST, val);
  501. case hwmon_power_input_lowest:
  502. return ltc4282_read_power_word(st, LTC4282_POWER_LOWEST, val);
  503. case hwmon_power_max_alarm:
  504. return ltc4282_read_alarm(st, LTC4282_ADC_ALERT_LOG,
  505. LTC4282_POWER_ALARM_H_MASK, val);
  506. case hwmon_power_min_alarm:
  507. return ltc4282_read_alarm(st, LTC4282_ADC_ALERT_LOG,
  508. LTC4282_POWER_ALARM_L_MASK, val);
  509. case hwmon_power_max:
  510. return ltc4282_read_power_byte(st, LTC4282_POWER_MAX, val);
  511. case hwmon_power_min:
  512. return ltc4282_read_power_byte(st, LTC4282_POWER_MIN, val);
  513. default:
  514. return -EOPNOTSUPP;
  515. }
  516. }
  517. static int ltc4282_read(struct device *dev, enum hwmon_sensor_types type,
  518. u32 attr, int channel, long *val)
  519. {
  520. struct ltc4282_state *st = dev_get_drvdata(dev);
  521. switch (type) {
  522. case hwmon_in:
  523. return ltc4282_read_in(st, attr, val, channel);
  524. case hwmon_curr:
  525. return ltc4282_read_curr(st, attr, val);
  526. case hwmon_power:
  527. return ltc4282_read_power(st, attr, val);
  528. case hwmon_energy:
  529. *val = st->energy_en;
  530. return 0;
  531. case hwmon_energy64:
  532. if (st->energy_en)
  533. return ltc4282_read_energy(st, (s64 *)val);
  534. return -ENODATA;
  535. default:
  536. return -EOPNOTSUPP;
  537. }
  538. }
  539. static int ltc4282_write_power_byte(const struct ltc4282_state *st, u32 reg,
  540. long val)
  541. {
  542. u32 power;
  543. u64 temp;
  544. if (val > st->power_max)
  545. val = st->power_max;
  546. temp = val * int_pow(U8_MAX, 2) * st->rsense;
  547. power = DIV64_U64_ROUND_CLOSEST(temp,
  548. MICRO * DECA * 256ULL * st->vfs_out * 40);
  549. return regmap_write(st->map, reg, power);
  550. }
  551. static int ltc4282_write_power_word(const struct ltc4282_state *st, u32 reg,
  552. long val)
  553. {
  554. u64 temp = int_pow(U16_MAX, 2) * st->rsense, temp_2;
  555. __be16 __raw;
  556. u16 code;
  557. if (check_mul_overflow(temp, val, &temp_2)) {
  558. temp = DIV_ROUND_CLOSEST_ULL(temp, DECA * MICRO);
  559. code = DIV64_U64_ROUND_CLOSEST(temp * val,
  560. 40ULL * BIT(16) * st->vfs_out);
  561. } else {
  562. temp = DECA * MICRO * 40ULL * BIT(16) * st->vfs_out;
  563. code = DIV64_U64_ROUND_CLOSEST(temp_2, temp);
  564. }
  565. __raw = cpu_to_be16(code);
  566. return regmap_bulk_write(st->map, reg, &__raw, sizeof(__raw));
  567. }
  568. static int __ltc4282_in_write_history(const struct ltc4282_state *st, u32 reg,
  569. long lowest, long highest, u32 fs)
  570. {
  571. __be16 __raw;
  572. u16 tmp;
  573. int ret;
  574. tmp = DIV_ROUND_CLOSEST(U16_MAX * lowest, fs);
  575. __raw = cpu_to_be16(tmp);
  576. ret = regmap_bulk_write(st->map, reg, &__raw, 2);
  577. if (ret)
  578. return ret;
  579. tmp = DIV_ROUND_CLOSEST(U16_MAX * highest, fs);
  580. __raw = cpu_to_be16(tmp);
  581. return regmap_bulk_write(st->map, reg + 2, &__raw, 2);
  582. }
  583. static int ltc4282_in_write_history(struct ltc4282_state *st, u32 reg,
  584. long lowest, long highest, u32 fs)
  585. {
  586. return __ltc4282_in_write_history(st, reg, lowest, highest, fs);
  587. }
  588. static int ltc4282_power_reset_hist(struct ltc4282_state *st)
  589. {
  590. int ret;
  591. ret = ltc4282_write_power_word(st, LTC4282_POWER_LOWEST,
  592. st->power_max);
  593. if (ret)
  594. return ret;
  595. ret = ltc4282_write_power_word(st, LTC4282_POWER_HIGHEST, 0);
  596. if (ret)
  597. return ret;
  598. /* now, let's also clear possible power_bad fault logs */
  599. return regmap_clear_bits(st->map, LTC4282_FAULT_LOG,
  600. LTC4282_POWER_BAD_FAULT_MASK);
  601. }
  602. static int ltc4282_write_power(struct ltc4282_state *st, u32 attr,
  603. long val)
  604. {
  605. switch (attr) {
  606. case hwmon_power_max:
  607. return ltc4282_write_power_byte(st, LTC4282_POWER_MAX, val);
  608. case hwmon_power_min:
  609. return ltc4282_write_power_byte(st, LTC4282_POWER_MIN, val);
  610. case hwmon_power_reset_history:
  611. return ltc4282_power_reset_hist(st);
  612. default:
  613. return -EOPNOTSUPP;
  614. }
  615. }
  616. static int ltc4282_write_voltage_byte_cached(const struct ltc4282_state *st,
  617. u32 reg, u32 fs, long val,
  618. u32 *cache_raw)
  619. {
  620. u32 in;
  621. val = clamp_val(val, 0, fs);
  622. in = DIV_ROUND_CLOSEST(val * U8_MAX, fs);
  623. if (cache_raw) {
  624. *cache_raw = in;
  625. return 0;
  626. }
  627. return regmap_write(st->map, reg, in);
  628. }
  629. static int ltc4282_write_voltage_byte(const struct ltc4282_state *st, u32 reg,
  630. u32 fs, long val)
  631. {
  632. return ltc4282_write_voltage_byte_cached(st, reg, fs, val, NULL);
  633. }
  634. static int ltc4282_cache_history(struct ltc4282_state *st, u32 channel)
  635. {
  636. long val;
  637. int ret;
  638. ret = ltc4282_read_voltage_word(st, LTC4282_VSOURCE_LOWEST, st->vfs_out,
  639. &val);
  640. if (ret)
  641. return ret;
  642. st->in0_1_cache[channel].in_lowest = val;
  643. ret = ltc4282_read_voltage_word(st, LTC4282_VSOURCE_HIGHEST,
  644. st->vfs_out, &val);
  645. if (ret)
  646. return ret;
  647. st->in0_1_cache[channel].in_highest = val;
  648. ret = regmap_read(st->map, LTC4282_VSOURCE_MIN,
  649. &st->in0_1_cache[channel].in_min_raw);
  650. if (ret)
  651. return ret;
  652. return regmap_read(st->map, LTC4282_VSOURCE_MAX,
  653. &st->in0_1_cache[channel].in_max_raw);
  654. }
  655. static int ltc4282_cache_sync(struct ltc4282_state *st, u32 channel)
  656. {
  657. int ret;
  658. ret = __ltc4282_in_write_history(st, LTC4282_VSOURCE_LOWEST,
  659. st->in0_1_cache[channel].in_lowest,
  660. st->in0_1_cache[channel].in_highest,
  661. st->vfs_out);
  662. if (ret)
  663. return ret;
  664. ret = regmap_write(st->map, LTC4282_VSOURCE_MIN,
  665. st->in0_1_cache[channel].in_min_raw);
  666. if (ret)
  667. return ret;
  668. return regmap_write(st->map, LTC4282_VSOURCE_MAX,
  669. st->in0_1_cache[channel].in_max_raw);
  670. }
  671. static int ltc4282_vdd_source_write_lim(struct ltc4282_state *st, u32 reg,
  672. int channel, u32 *cache, long val)
  673. {
  674. int ret;
  675. if (st->in0_1_cache[channel].en)
  676. ret = ltc4282_write_voltage_byte(st, reg, st->vfs_out, val);
  677. else
  678. ret = ltc4282_write_voltage_byte_cached(st, reg, st->vfs_out,
  679. val, cache);
  680. return ret;
  681. }
  682. static int ltc4282_vdd_source_reset_hist(struct ltc4282_state *st, int channel)
  683. {
  684. long lowest = st->vfs_out;
  685. int ret;
  686. if (channel == LTC4282_CHAN_VDD)
  687. lowest = st->vdd;
  688. if (st->in0_1_cache[channel].en) {
  689. ret = __ltc4282_in_write_history(st, LTC4282_VSOURCE_LOWEST,
  690. lowest, 0, st->vfs_out);
  691. if (ret)
  692. return ret;
  693. }
  694. st->in0_1_cache[channel].in_lowest = lowest;
  695. st->in0_1_cache[channel].in_highest = 0;
  696. /*
  697. * We are also clearing possible fault logs in reset_history. Clearing
  698. * the logs might be important when the auto retry bits are not enabled
  699. * as the chip only enables the output again after having these logs
  700. * cleared. As some of these logs are related to limits, it makes sense
  701. * to clear them in here. For VDD, we need to clear under/over voltage
  702. * events. For VSOURCE, fet_short and fet_bad...
  703. */
  704. if (channel == LTC4282_CHAN_VSOURCE)
  705. return regmap_clear_bits(st->map, LTC4282_FAULT_LOG,
  706. LTC4282_FET_FAILURE_FAULT_MASK);
  707. return regmap_clear_bits(st->map, LTC4282_FAULT_LOG,
  708. LTC4282_VDD_FAULT_MASK);
  709. }
  710. /*
  711. * We need to mux between VSOURCE and VDD which means they are mutually
  712. * exclusive. Moreover, we can't really disable both VDD and VSOURCE as the ADC
  713. * is continuously running (we cannot independently halt it without also
  714. * stopping VGPIO). Hence, the logic is that disabling or enabling VDD will
  715. * automatically have the reverse effect on VSOURCE and vice-versa.
  716. */
  717. static int ltc4282_vdd_source_enable(struct ltc4282_state *st, int channel,
  718. long val)
  719. {
  720. int ret, other_chan = ~channel & 0x1;
  721. u8 __val = val;
  722. if (st->in0_1_cache[channel].en == !!val)
  723. return 0;
  724. /* clearing the bit makes the ADC to monitor VDD */
  725. if (channel == LTC4282_CHAN_VDD)
  726. __val = !__val;
  727. ret = regmap_update_bits(st->map, LTC4282_ILIM_ADJUST,
  728. LTC4282_VDD_MONITOR_MASK,
  729. FIELD_PREP(LTC4282_VDD_MONITOR_MASK, !!__val));
  730. if (ret)
  731. return ret;
  732. st->in0_1_cache[channel].en = !!val;
  733. st->in0_1_cache[other_chan].en = !val;
  734. if (st->in0_1_cache[channel].en) {
  735. /*
  736. * Then, we are disabling @other_chan. Let's save it's current
  737. * history.
  738. */
  739. ret = ltc4282_cache_history(st, other_chan);
  740. if (ret)
  741. return ret;
  742. return ltc4282_cache_sync(st, channel);
  743. }
  744. /*
  745. * Then, we are enabling @other_chan. We need to do the opposite from
  746. * above.
  747. */
  748. ret = ltc4282_cache_history(st, channel);
  749. if (ret)
  750. return ret;
  751. return ltc4282_cache_sync(st, other_chan);
  752. }
  753. static int ltc4282_write_in(struct ltc4282_state *st, u32 attr, long val,
  754. int channel)
  755. {
  756. switch (attr) {
  757. case hwmon_in_max:
  758. if (channel == LTC4282_CHAN_VGPIO)
  759. return ltc4282_write_voltage_byte(st, LTC4282_VGPIO_MAX,
  760. 1280, val);
  761. return ltc4282_vdd_source_write_lim(st, LTC4282_VSOURCE_MAX,
  762. channel,
  763. &st->in0_1_cache[channel].in_max_raw, val);
  764. case hwmon_in_min:
  765. if (channel == LTC4282_CHAN_VGPIO)
  766. return ltc4282_write_voltage_byte(st, LTC4282_VGPIO_MIN,
  767. 1280, val);
  768. return ltc4282_vdd_source_write_lim(st, LTC4282_VSOURCE_MIN,
  769. channel,
  770. &st->in0_1_cache[channel].in_min_raw, val);
  771. case hwmon_in_reset_history:
  772. if (channel == LTC4282_CHAN_VGPIO)
  773. return ltc4282_in_write_history(st,
  774. LTC4282_VGPIO_LOWEST,
  775. 1280, 0, 1280);
  776. return ltc4282_vdd_source_reset_hist(st, channel);
  777. case hwmon_in_enable:
  778. return ltc4282_vdd_source_enable(st, channel, val);
  779. default:
  780. return -EOPNOTSUPP;
  781. }
  782. }
  783. static int ltc4282_curr_reset_hist(struct ltc4282_state *st)
  784. {
  785. int ret;
  786. ret = __ltc4282_in_write_history(st, LTC4282_VSENSE_LOWEST,
  787. st->vsense_max, 0, 40 * MILLI);
  788. if (ret)
  789. return ret;
  790. /* now, let's also clear possible overcurrent fault logs */
  791. return regmap_clear_bits(st->map, LTC4282_FAULT_LOG,
  792. LTC4282_OC_FAULT_MASK);
  793. }
  794. static int ltc4282_write_curr(struct ltc4282_state *st, u32 attr,
  795. long val)
  796. {
  797. /* need to pass it in millivolt */
  798. u32 in = DIV_ROUND_CLOSEST_ULL((u64)val * st->rsense, DECA * MICRO);
  799. switch (attr) {
  800. case hwmon_curr_max:
  801. return ltc4282_write_voltage_byte(st, LTC4282_VSENSE_MAX, 40,
  802. in);
  803. case hwmon_curr_min:
  804. return ltc4282_write_voltage_byte(st, LTC4282_VSENSE_MIN, 40,
  805. in);
  806. case hwmon_curr_reset_history:
  807. return ltc4282_curr_reset_hist(st);
  808. default:
  809. return -EOPNOTSUPP;
  810. }
  811. }
  812. static int ltc4282_energy_enable_set(struct ltc4282_state *st, long val)
  813. {
  814. int ret;
  815. /* setting the bit halts the meter */
  816. ret = regmap_update_bits(st->map, LTC4282_ADC_CTRL,
  817. LTC4282_METER_HALT_MASK,
  818. FIELD_PREP(LTC4282_METER_HALT_MASK, !val));
  819. if (ret)
  820. return ret;
  821. st->energy_en = !!val;
  822. return 0;
  823. }
  824. static int ltc4282_write(struct device *dev,
  825. enum hwmon_sensor_types type,
  826. u32 attr, int channel, long val)
  827. {
  828. struct ltc4282_state *st = dev_get_drvdata(dev);
  829. switch (type) {
  830. case hwmon_power:
  831. return ltc4282_write_power(st, attr, val);
  832. case hwmon_in:
  833. return ltc4282_write_in(st, attr, val, channel);
  834. case hwmon_curr:
  835. return ltc4282_write_curr(st, attr, val);
  836. case hwmon_energy:
  837. return ltc4282_energy_enable_set(st, val);
  838. default:
  839. return -EOPNOTSUPP;
  840. }
  841. }
  842. static umode_t ltc4282_in_is_visible(const struct ltc4282_state *st, u32 attr)
  843. {
  844. switch (attr) {
  845. case hwmon_in_input:
  846. case hwmon_in_highest:
  847. case hwmon_in_lowest:
  848. case hwmon_in_max_alarm:
  849. case hwmon_in_min_alarm:
  850. case hwmon_in_label:
  851. case hwmon_in_lcrit_alarm:
  852. case hwmon_in_crit_alarm:
  853. case hwmon_in_fault:
  854. return 0444;
  855. case hwmon_in_max:
  856. case hwmon_in_min:
  857. case hwmon_in_enable:
  858. return 0644;
  859. case hwmon_in_reset_history:
  860. return 0200;
  861. default:
  862. return 0;
  863. }
  864. }
  865. static umode_t ltc4282_curr_is_visible(u32 attr)
  866. {
  867. switch (attr) {
  868. case hwmon_curr_input:
  869. case hwmon_curr_highest:
  870. case hwmon_curr_lowest:
  871. case hwmon_curr_max_alarm:
  872. case hwmon_curr_min_alarm:
  873. case hwmon_curr_crit_alarm:
  874. case hwmon_curr_label:
  875. return 0444;
  876. case hwmon_curr_max:
  877. case hwmon_curr_min:
  878. return 0644;
  879. case hwmon_curr_reset_history:
  880. return 0200;
  881. default:
  882. return 0;
  883. }
  884. }
  885. static umode_t ltc4282_power_is_visible(u32 attr)
  886. {
  887. switch (attr) {
  888. case hwmon_power_input:
  889. case hwmon_power_input_highest:
  890. case hwmon_power_input_lowest:
  891. case hwmon_power_label:
  892. case hwmon_power_max_alarm:
  893. case hwmon_power_min_alarm:
  894. return 0444;
  895. case hwmon_power_max:
  896. case hwmon_power_min:
  897. return 0644;
  898. case hwmon_power_reset_history:
  899. return 0200;
  900. default:
  901. return 0;
  902. }
  903. }
  904. static umode_t ltc4282_is_visible(const void *data,
  905. enum hwmon_sensor_types type,
  906. u32 attr, int channel)
  907. {
  908. switch (type) {
  909. case hwmon_in:
  910. return ltc4282_in_is_visible(data, attr);
  911. case hwmon_curr:
  912. return ltc4282_curr_is_visible(attr);
  913. case hwmon_power:
  914. return ltc4282_power_is_visible(attr);
  915. case hwmon_energy:
  916. /* hwmon_energy_enable */
  917. return 0644;
  918. case hwmon_energy64:
  919. /* hwmon_energy_input */
  920. return 0444;
  921. default:
  922. return 0;
  923. }
  924. }
  925. static const char * const ltc4282_in_strs[] = {
  926. "VSOURCE", "VDD", "VGPIO"
  927. };
  928. static int ltc4282_read_labels(struct device *dev,
  929. enum hwmon_sensor_types type,
  930. u32 attr, int channel, const char **str)
  931. {
  932. switch (type) {
  933. case hwmon_in:
  934. *str = ltc4282_in_strs[channel];
  935. return 0;
  936. case hwmon_curr:
  937. *str = "ISENSE";
  938. return 0;
  939. case hwmon_power:
  940. *str = "Power";
  941. return 0;
  942. default:
  943. return -EOPNOTSUPP;
  944. }
  945. }
  946. static const struct clk_ops ltc4282_ops = {
  947. .recalc_rate = ltc4282_recalc_rate,
  948. .determine_rate = ltc4282_determine_rate,
  949. .set_rate = ltc4282_set_rate,
  950. .disable = ltc4282_disable,
  951. };
  952. static int ltc428_clk_provider_setup(struct ltc4282_state *st,
  953. struct device *dev)
  954. {
  955. struct clk_init_data init;
  956. int ret;
  957. if (!IS_ENABLED(CONFIG_COMMON_CLK))
  958. return 0;
  959. init.name = devm_kasprintf(dev, GFP_KERNEL, "%s-clk",
  960. fwnode_get_name(dev_fwnode(dev)));
  961. if (!init.name)
  962. return -ENOMEM;
  963. init.ops = &ltc4282_ops;
  964. init.flags = CLK_GET_RATE_NOCACHE;
  965. st->clk_hw.init = &init;
  966. ret = devm_clk_hw_register(dev, &st->clk_hw);
  967. if (ret)
  968. return ret;
  969. return devm_of_clk_add_hw_provider(dev, of_clk_hw_simple_get,
  970. &st->clk_hw);
  971. }
  972. static int ltc428_clks_setup(struct ltc4282_state *st, struct device *dev)
  973. {
  974. unsigned long rate;
  975. struct clk *clkin;
  976. u32 val;
  977. int ret;
  978. ret = ltc428_clk_provider_setup(st, dev);
  979. if (ret)
  980. return ret;
  981. clkin = devm_clk_get_optional_enabled(dev, NULL);
  982. if (IS_ERR(clkin))
  983. return dev_err_probe(dev, PTR_ERR(clkin),
  984. "Failed to get clkin");
  985. if (!clkin)
  986. return 0;
  987. rate = clk_get_rate(clkin);
  988. if (!in_range(rate, LTC4282_CLKIN_MIN, LTC4282_CLKIN_RANGE))
  989. return dev_err_probe(dev, -EINVAL,
  990. "Invalid clkin range(%lu) [%lu %lu]\n",
  991. rate, LTC4282_CLKIN_MIN,
  992. LTC4282_CLKIN_MAX);
  993. /*
  994. * Clocks faster than 250KHZ should be reduced to 250KHZ. The clock
  995. * frequency is divided by twice the value in the register.
  996. */
  997. val = rate / (2 * LTC4282_CLKIN_MIN);
  998. return regmap_update_bits(st->map, LTC4282_CLK_DIV,
  999. LTC4282_CLK_DIV_MASK,
  1000. FIELD_PREP(LTC4282_CLK_DIV_MASK, val));
  1001. }
  1002. static const int ltc4282_curr_lim_uv[] = {
  1003. 12500, 15625, 18750, 21875, 25000, 28125, 31250, 34375
  1004. };
  1005. static int ltc4282_get_defaults(struct ltc4282_state *st, u32 *vin_mode)
  1006. {
  1007. u32 reg_val, ilm_adjust;
  1008. int ret;
  1009. ret = regmap_read(st->map, LTC4282_ADC_CTRL, &reg_val);
  1010. if (ret)
  1011. return ret;
  1012. st->energy_en = !FIELD_GET(LTC4282_METER_HALT_MASK, reg_val);
  1013. ret = regmap_read(st->map, LTC4282_CTRL_MSB, &reg_val);
  1014. if (ret)
  1015. return ret;
  1016. *vin_mode = FIELD_GET(LTC4282_CTRL_VIN_MODE_MASK, reg_val);
  1017. ret = regmap_read(st->map, LTC4282_ILIM_ADJUST, &reg_val);
  1018. if (ret)
  1019. return ret;
  1020. ilm_adjust = FIELD_GET(LTC4282_ILIM_ADJUST_MASK, reg_val);
  1021. st->vsense_max = ltc4282_curr_lim_uv[ilm_adjust];
  1022. st->in0_1_cache[LTC4282_CHAN_VSOURCE].en = FIELD_GET(LTC4282_VDD_MONITOR_MASK,
  1023. ilm_adjust);
  1024. if (!st->in0_1_cache[LTC4282_CHAN_VSOURCE].en) {
  1025. st->in0_1_cache[LTC4282_CHAN_VDD].en = true;
  1026. return regmap_read(st->map, LTC4282_VSOURCE_MAX,
  1027. &st->in0_1_cache[LTC4282_CHAN_VSOURCE].in_max_raw);
  1028. }
  1029. return regmap_read(st->map, LTC4282_VSOURCE_MAX,
  1030. &st->in0_1_cache[LTC4282_CHAN_VDD].in_max_raw);
  1031. }
  1032. /*
  1033. * Set max limits for ISENSE and Power as that depends on the max voltage on
  1034. * rsense that is defined in ILIM_ADJUST. This is specially important for power
  1035. * because for some rsense and vfsout values, if we allow the default raw 255
  1036. * value, that would overflow long in 32bit archs when reading back the max
  1037. * power limit.
  1038. *
  1039. * Also set meaningful historic values for VDD and VSOURCE
  1040. * (0 would not mean much).
  1041. */
  1042. static int ltc4282_set_max_limits(struct ltc4282_state *st)
  1043. {
  1044. int ret;
  1045. ret = ltc4282_write_voltage_byte(st, LTC4282_VSENSE_MAX, 40 * MILLI,
  1046. st->vsense_max);
  1047. if (ret)
  1048. return ret;
  1049. /* Power is given by ISENSE * Vout. */
  1050. st->power_max = DIV_ROUND_CLOSEST(st->vsense_max * DECA * MILLI, st->rsense) * st->vfs_out;
  1051. ret = ltc4282_write_power_byte(st, LTC4282_POWER_MAX, st->power_max);
  1052. if (ret)
  1053. return ret;
  1054. if (st->in0_1_cache[LTC4282_CHAN_VDD].en) {
  1055. st->in0_1_cache[LTC4282_CHAN_VSOURCE].in_lowest = st->vfs_out;
  1056. return __ltc4282_in_write_history(st, LTC4282_VSOURCE_LOWEST,
  1057. st->vdd, 0, st->vfs_out);
  1058. }
  1059. st->in0_1_cache[LTC4282_CHAN_VDD].in_lowest = st->vdd;
  1060. return __ltc4282_in_write_history(st, LTC4282_VSOURCE_LOWEST,
  1061. st->vfs_out, 0, st->vfs_out);
  1062. }
  1063. static const char * const ltc4282_gpio1_modes[] = {
  1064. "power_bad", "power_good"
  1065. };
  1066. static const char * const ltc4282_gpio2_modes[] = {
  1067. "adc_input", "stress_fet"
  1068. };
  1069. static int ltc4282_gpio_setup(struct ltc4282_state *st, struct device *dev)
  1070. {
  1071. const char *func = NULL;
  1072. int ret;
  1073. ret = device_property_read_string(dev, "adi,gpio1-mode", &func);
  1074. if (!ret) {
  1075. ret = match_string(ltc4282_gpio1_modes,
  1076. ARRAY_SIZE(ltc4282_gpio1_modes), func);
  1077. if (ret < 0)
  1078. return dev_err_probe(dev, ret,
  1079. "Invalid func(%s) for gpio1\n",
  1080. func);
  1081. ret = regmap_update_bits(st->map, LTC4282_GPIO_CONFIG,
  1082. LTC4282_GPIO_1_CONFIG_MASK,
  1083. FIELD_PREP(LTC4282_GPIO_1_CONFIG_MASK, ret));
  1084. if (ret)
  1085. return ret;
  1086. }
  1087. ret = device_property_read_string(dev, "adi,gpio2-mode", &func);
  1088. if (!ret) {
  1089. ret = match_string(ltc4282_gpio2_modes,
  1090. ARRAY_SIZE(ltc4282_gpio2_modes), func);
  1091. if (ret < 0)
  1092. return dev_err_probe(dev, ret,
  1093. "Invalid func(%s) for gpio2\n",
  1094. func);
  1095. if (!ret) {
  1096. /* setting the bit to 1 so the ADC to monitors GPIO2 */
  1097. ret = regmap_set_bits(st->map, LTC4282_ILIM_ADJUST,
  1098. LTC4282_GPIO_MODE_MASK);
  1099. } else {
  1100. ret = regmap_update_bits(st->map, LTC4282_GPIO_CONFIG,
  1101. LTC4282_GPIO_2_FET_STRESS_MASK,
  1102. FIELD_PREP(LTC4282_GPIO_2_FET_STRESS_MASK, 1));
  1103. }
  1104. if (ret)
  1105. return ret;
  1106. }
  1107. if (!device_property_read_bool(dev, "adi,gpio3-monitor-enable"))
  1108. return 0;
  1109. if (func && !strcmp(func, "adc_input"))
  1110. return dev_err_probe(dev, -EINVAL,
  1111. "Cannot have both gpio2 and gpio3 muxed into the ADC");
  1112. return regmap_clear_bits(st->map, LTC4282_ILIM_ADJUST,
  1113. LTC4282_GPIO_MODE_MASK);
  1114. }
  1115. static const char * const ltc4282_dividers[] = {
  1116. "external", "vdd_5_percent", "vdd_10_percent", "vdd_15_percent"
  1117. };
  1118. /* This maps the Vout full scale for the given Vin mode */
  1119. static const u16 ltc4282_vfs_milli[] = { 5540, 8320, 16640, 33280 };
  1120. static const u16 ltc4282_vdd_milli[] = { 3300, 5000, 12000, 24000 };
  1121. enum {
  1122. LTC4282_VIN_3_3V,
  1123. LTC4282_VIN_5V,
  1124. LTC4282_VIN_12V,
  1125. LTC4282_VIN_24V,
  1126. };
  1127. static int ltc4282_setup(struct ltc4282_state *st, struct device *dev)
  1128. {
  1129. const char *divider;
  1130. u32 val, vin_mode;
  1131. int ret;
  1132. /* The part has an eeprom so let's get the needed defaults from it */
  1133. ret = ltc4282_get_defaults(st, &vin_mode);
  1134. if (ret)
  1135. return ret;
  1136. ret = device_property_read_u32(dev, "adi,rsense-nano-ohms",
  1137. &st->rsense);
  1138. if (ret)
  1139. return dev_err_probe(dev, ret,
  1140. "Failed to read adi,rsense-nano-ohms\n");
  1141. if (st->rsense < CENTI)
  1142. return dev_err_probe(dev, -EINVAL,
  1143. "adi,rsense-nano-ohms too small (< %lu)\n",
  1144. CENTI);
  1145. /*
  1146. * The resolution for rsense is tenths of micro (eg: 62.5 uOhm) which
  1147. * means we need nano in the bindings. However, to make things easier to
  1148. * handle (with respect to overflows) we divide it by 100 as we don't
  1149. * really need the last two digits.
  1150. */
  1151. st->rsense /= CENTI;
  1152. val = vin_mode;
  1153. ret = device_property_read_u32(dev, "adi,vin-mode-microvolt", &val);
  1154. if (!ret) {
  1155. switch (val) {
  1156. case 3300000:
  1157. val = LTC4282_VIN_3_3V;
  1158. break;
  1159. case 5000000:
  1160. val = LTC4282_VIN_5V;
  1161. break;
  1162. case 12000000:
  1163. val = LTC4282_VIN_12V;
  1164. break;
  1165. case 24000000:
  1166. val = LTC4282_VIN_24V;
  1167. break;
  1168. default:
  1169. return dev_err_probe(dev, -EINVAL,
  1170. "Invalid val(%u) for vin-mode-microvolt\n",
  1171. val);
  1172. }
  1173. ret = regmap_update_bits(st->map, LTC4282_CTRL_MSB,
  1174. LTC4282_CTRL_VIN_MODE_MASK,
  1175. FIELD_PREP(LTC4282_CTRL_VIN_MODE_MASK, val));
  1176. if (ret)
  1177. return ret;
  1178. /* Foldback mode should also be set to the input voltage */
  1179. ret = regmap_update_bits(st->map, LTC4282_ILIM_ADJUST,
  1180. LTC4282_FOLDBACK_MODE_MASK,
  1181. FIELD_PREP(LTC4282_FOLDBACK_MODE_MASK, val));
  1182. if (ret)
  1183. return ret;
  1184. }
  1185. st->vfs_out = ltc4282_vfs_milli[val];
  1186. st->vdd = ltc4282_vdd_milli[val];
  1187. ret = device_property_read_u32(dev, "adi,current-limit-sense-microvolt",
  1188. &st->vsense_max);
  1189. if (!ret) {
  1190. int reg_val;
  1191. switch (val) {
  1192. case 12500:
  1193. reg_val = 0;
  1194. break;
  1195. case 15625:
  1196. reg_val = 1;
  1197. break;
  1198. case 18750:
  1199. reg_val = 2;
  1200. break;
  1201. case 21875:
  1202. reg_val = 3;
  1203. break;
  1204. case 25000:
  1205. reg_val = 4;
  1206. break;
  1207. case 28125:
  1208. reg_val = 5;
  1209. break;
  1210. case 31250:
  1211. reg_val = 6;
  1212. break;
  1213. case 34375:
  1214. reg_val = 7;
  1215. break;
  1216. default:
  1217. return dev_err_probe(dev, -EINVAL,
  1218. "Invalid val(%u) for adi,current-limit-microvolt\n",
  1219. st->vsense_max);
  1220. }
  1221. ret = regmap_update_bits(st->map, LTC4282_ILIM_ADJUST,
  1222. LTC4282_ILIM_ADJUST_MASK,
  1223. FIELD_PREP(LTC4282_ILIM_ADJUST_MASK, reg_val));
  1224. if (ret)
  1225. return ret;
  1226. }
  1227. ret = ltc4282_set_max_limits(st);
  1228. if (ret)
  1229. return ret;
  1230. ret = device_property_read_string(dev, "adi,overvoltage-dividers",
  1231. &divider);
  1232. if (!ret) {
  1233. int div = match_string(ltc4282_dividers,
  1234. ARRAY_SIZE(ltc4282_dividers), divider);
  1235. if (div < 0)
  1236. return dev_err_probe(dev, -EINVAL,
  1237. "Invalid val(%s) for adi,overvoltage-divider\n",
  1238. divider);
  1239. ret = regmap_update_bits(st->map, LTC4282_CTRL_MSB,
  1240. LTC4282_CTRL_OV_MODE_MASK,
  1241. FIELD_PREP(LTC4282_CTRL_OV_MODE_MASK, div));
  1242. }
  1243. ret = device_property_read_string(dev, "adi,undervoltage-dividers",
  1244. &divider);
  1245. if (!ret) {
  1246. int div = match_string(ltc4282_dividers,
  1247. ARRAY_SIZE(ltc4282_dividers), divider);
  1248. if (div < 0)
  1249. return dev_err_probe(dev, -EINVAL,
  1250. "Invalid val(%s) for adi,undervoltage-divider\n",
  1251. divider);
  1252. ret = regmap_update_bits(st->map, LTC4282_CTRL_MSB,
  1253. LTC4282_CTRL_UV_MODE_MASK,
  1254. FIELD_PREP(LTC4282_CTRL_UV_MODE_MASK, div));
  1255. }
  1256. if (device_property_read_bool(dev, "adi,overcurrent-retry")) {
  1257. ret = regmap_set_bits(st->map, LTC4282_CTRL_LSB,
  1258. LTC4282_CTRL_OC_RETRY_MASK);
  1259. if (ret)
  1260. return ret;
  1261. }
  1262. if (device_property_read_bool(dev, "adi,overvoltage-retry-disable")) {
  1263. ret = regmap_clear_bits(st->map, LTC4282_CTRL_LSB,
  1264. LTC4282_CTRL_OV_RETRY_MASK);
  1265. if (ret)
  1266. return ret;
  1267. }
  1268. if (device_property_read_bool(dev, "adi,undervoltage-retry-disable")) {
  1269. ret = regmap_clear_bits(st->map, LTC4282_CTRL_LSB,
  1270. LTC4282_CTRL_UV_RETRY_MASK);
  1271. if (ret)
  1272. return ret;
  1273. }
  1274. if (device_property_read_bool(dev, "adi,fault-log-enable")) {
  1275. ret = regmap_set_bits(st->map, LTC4282_ADC_CTRL, LTC4282_FAULT_LOG_EN_MASK);
  1276. if (ret)
  1277. return ret;
  1278. }
  1279. ret = device_property_read_u32(dev, "adi,fet-bad-timeout-ms", &val);
  1280. if (!ret) {
  1281. if (val > LTC4282_FET_BAD_MAX_TIMEOUT)
  1282. return dev_err_probe(dev, -EINVAL,
  1283. "Invalid value(%u) for adi,fet-bad-timeout-ms",
  1284. val);
  1285. ret = regmap_write(st->map, LTC4282_FET_BAD_FAULT_TIMEOUT, val);
  1286. if (ret)
  1287. return ret;
  1288. }
  1289. return ltc4282_gpio_setup(st, dev);
  1290. }
  1291. static bool ltc4282_readable_reg(struct device *dev, unsigned int reg)
  1292. {
  1293. if (reg == LTC4282_RESERVED_1 || reg == LTC4282_RESERVED_2)
  1294. return false;
  1295. return true;
  1296. }
  1297. static bool ltc4282_writable_reg(struct device *dev, unsigned int reg)
  1298. {
  1299. if (reg == LTC4282_STATUS_LSB || reg == LTC4282_STATUS_MSB)
  1300. return false;
  1301. if (reg == LTC4282_RESERVED_1 || reg == LTC4282_RESERVED_2)
  1302. return false;
  1303. return true;
  1304. }
  1305. static const struct regmap_config ltc4282_regmap_config = {
  1306. .reg_bits = 8,
  1307. .val_bits = 8,
  1308. .max_register = LTC4282_RESERVED_3,
  1309. .readable_reg = ltc4282_readable_reg,
  1310. .writeable_reg = ltc4282_writable_reg,
  1311. };
  1312. static const struct hwmon_channel_info * const ltc4282_info[] = {
  1313. HWMON_CHANNEL_INFO(in,
  1314. HWMON_I_INPUT | HWMON_I_LOWEST | HWMON_I_HIGHEST |
  1315. HWMON_I_MAX | HWMON_I_MIN | HWMON_I_MIN_ALARM |
  1316. HWMON_I_MAX_ALARM | HWMON_I_ENABLE |
  1317. HWMON_I_RESET_HISTORY | HWMON_I_FAULT |
  1318. HWMON_I_LABEL,
  1319. HWMON_I_INPUT | HWMON_I_LOWEST | HWMON_I_HIGHEST |
  1320. HWMON_I_MAX | HWMON_I_MIN | HWMON_I_MIN_ALARM |
  1321. HWMON_I_MAX_ALARM | HWMON_I_LCRIT_ALARM |
  1322. HWMON_I_CRIT_ALARM | HWMON_I_ENABLE |
  1323. HWMON_I_RESET_HISTORY | HWMON_I_LABEL,
  1324. HWMON_I_INPUT | HWMON_I_LOWEST | HWMON_I_HIGHEST |
  1325. HWMON_I_MAX | HWMON_I_MIN | HWMON_I_MIN_ALARM |
  1326. HWMON_I_RESET_HISTORY | HWMON_I_MAX_ALARM |
  1327. HWMON_I_LABEL),
  1328. HWMON_CHANNEL_INFO(curr,
  1329. HWMON_C_INPUT | HWMON_C_LOWEST | HWMON_C_HIGHEST |
  1330. HWMON_C_MAX | HWMON_C_MIN | HWMON_C_MIN_ALARM |
  1331. HWMON_C_MAX_ALARM | HWMON_C_CRIT_ALARM |
  1332. HWMON_C_RESET_HISTORY | HWMON_C_LABEL),
  1333. HWMON_CHANNEL_INFO(power,
  1334. HWMON_P_INPUT | HWMON_P_INPUT_LOWEST |
  1335. HWMON_P_INPUT_HIGHEST | HWMON_P_MAX | HWMON_P_MIN |
  1336. HWMON_P_MAX_ALARM | HWMON_P_MIN_ALARM |
  1337. HWMON_P_RESET_HISTORY | HWMON_P_LABEL),
  1338. HWMON_CHANNEL_INFO(energy,
  1339. HWMON_E_ENABLE),
  1340. HWMON_CHANNEL_INFO(energy64,
  1341. HWMON_E_INPUT),
  1342. NULL
  1343. };
  1344. static const struct hwmon_ops ltc4282_hwmon_ops = {
  1345. .read = ltc4282_read,
  1346. .write = ltc4282_write,
  1347. .is_visible = ltc4282_is_visible,
  1348. .read_string = ltc4282_read_labels,
  1349. };
  1350. static const struct hwmon_chip_info ltc4282_chip_info = {
  1351. .ops = &ltc4282_hwmon_ops,
  1352. .info = ltc4282_info,
  1353. };
  1354. static int ltc4282_show_fault_log(void *arg, u64 *val, u32 mask)
  1355. {
  1356. struct ltc4282_state *st = arg;
  1357. long alarm;
  1358. int ret;
  1359. ret = ltc4282_read_alarm(st, LTC4282_FAULT_LOG, mask, &alarm);
  1360. if (ret)
  1361. return ret;
  1362. *val = alarm;
  1363. return 0;
  1364. }
  1365. static int ltc4282_show_curr1_crit_fault_log(void *arg, u64 *val)
  1366. {
  1367. return ltc4282_show_fault_log(arg, val, LTC4282_OC_FAULT_MASK);
  1368. }
  1369. DEFINE_DEBUGFS_ATTRIBUTE(ltc4282_curr1_crit_fault_log,
  1370. ltc4282_show_curr1_crit_fault_log, NULL, "%llu\n");
  1371. static int ltc4282_show_in1_lcrit_fault_log(void *arg, u64 *val)
  1372. {
  1373. return ltc4282_show_fault_log(arg, val, LTC4282_UV_FAULT_MASK);
  1374. }
  1375. DEFINE_DEBUGFS_ATTRIBUTE(ltc4282_in1_lcrit_fault_log,
  1376. ltc4282_show_in1_lcrit_fault_log, NULL, "%llu\n");
  1377. static int ltc4282_show_in1_crit_fault_log(void *arg, u64 *val)
  1378. {
  1379. return ltc4282_show_fault_log(arg, val, LTC4282_OV_FAULT_MASK);
  1380. }
  1381. DEFINE_DEBUGFS_ATTRIBUTE(ltc4282_in1_crit_fault_log,
  1382. ltc4282_show_in1_crit_fault_log, NULL, "%llu\n");
  1383. static int ltc4282_show_fet_bad_fault_log(void *arg, u64 *val)
  1384. {
  1385. return ltc4282_show_fault_log(arg, val, LTC4282_FET_BAD_FAULT_MASK);
  1386. }
  1387. DEFINE_DEBUGFS_ATTRIBUTE(ltc4282_fet_bad_fault_log,
  1388. ltc4282_show_fet_bad_fault_log, NULL, "%llu\n");
  1389. static int ltc4282_show_fet_short_fault_log(void *arg, u64 *val)
  1390. {
  1391. return ltc4282_show_fault_log(arg, val, LTC4282_FET_SHORT_FAULT_MASK);
  1392. }
  1393. DEFINE_DEBUGFS_ATTRIBUTE(ltc4282_fet_short_fault_log,
  1394. ltc4282_show_fet_short_fault_log, NULL, "%llu\n");
  1395. static int ltc4282_show_power1_bad_fault_log(void *arg, u64 *val)
  1396. {
  1397. return ltc4282_show_fault_log(arg, val, LTC4282_POWER_BAD_FAULT_MASK);
  1398. }
  1399. DEFINE_DEBUGFS_ATTRIBUTE(ltc4282_power1_bad_fault_log,
  1400. ltc4282_show_power1_bad_fault_log, NULL, "%llu\n");
  1401. static void ltc4282_debugfs_init(struct ltc4282_state *st, struct i2c_client *i2c)
  1402. {
  1403. debugfs_create_file_unsafe("power1_bad_fault_log", 0400, i2c->debugfs, st,
  1404. &ltc4282_power1_bad_fault_log);
  1405. debugfs_create_file_unsafe("in0_fet_short_fault_log", 0400, i2c->debugfs, st,
  1406. &ltc4282_fet_short_fault_log);
  1407. debugfs_create_file_unsafe("in0_fet_bad_fault_log", 0400, i2c->debugfs, st,
  1408. &ltc4282_fet_bad_fault_log);
  1409. debugfs_create_file_unsafe("in1_crit_fault_log", 0400, i2c->debugfs, st,
  1410. &ltc4282_in1_crit_fault_log);
  1411. debugfs_create_file_unsafe("in1_lcrit_fault_log", 0400, i2c->debugfs, st,
  1412. &ltc4282_in1_lcrit_fault_log);
  1413. debugfs_create_file_unsafe("curr1_crit_fault_log", 0400, i2c->debugfs, st,
  1414. &ltc4282_curr1_crit_fault_log);
  1415. }
  1416. static int ltc4282_probe(struct i2c_client *i2c)
  1417. {
  1418. struct device *dev = &i2c->dev, *hwmon;
  1419. struct ltc4282_state *st;
  1420. int ret;
  1421. st = devm_kzalloc(dev, sizeof(*st), GFP_KERNEL);
  1422. if (!st)
  1423. return -ENOMEM;
  1424. st->map = devm_regmap_init_i2c(i2c, &ltc4282_regmap_config);
  1425. if (IS_ERR(st->map))
  1426. return dev_err_probe(dev, PTR_ERR(st->map),
  1427. "failed regmap init\n");
  1428. /* Soft reset */
  1429. ret = regmap_set_bits(st->map, LTC4282_ADC_CTRL, LTC4282_RESET_MASK);
  1430. if (ret)
  1431. return ret;
  1432. /* Yes, it's big but it is as specified in the datasheet */
  1433. msleep(3200);
  1434. ret = ltc428_clks_setup(st, dev);
  1435. if (ret)
  1436. return ret;
  1437. ret = ltc4282_setup(st, dev);
  1438. if (ret)
  1439. return ret;
  1440. hwmon = devm_hwmon_device_register_with_info(dev, "ltc4282", st,
  1441. &ltc4282_chip_info, NULL);
  1442. if (IS_ERR(hwmon))
  1443. return PTR_ERR(hwmon);
  1444. ltc4282_debugfs_init(st, i2c);
  1445. return 0;
  1446. }
  1447. static const struct of_device_id ltc4282_of_match[] = {
  1448. { .compatible = "adi,ltc4282" },
  1449. {}
  1450. };
  1451. MODULE_DEVICE_TABLE(of, ltc4282_of_match);
  1452. static struct i2c_driver ltc4282_driver = {
  1453. .driver = {
  1454. .name = "ltc4282",
  1455. .of_match_table = ltc4282_of_match,
  1456. },
  1457. .probe = ltc4282_probe,
  1458. };
  1459. module_i2c_driver(ltc4282_driver);
  1460. MODULE_AUTHOR("Nuno Sa <nuno.sa@analog.com>");
  1461. MODULE_DESCRIPTION("LTC4282 I2C High Current Hot Swap Controller");
  1462. MODULE_LICENSE("GPL");