rtc-ds1307.c 50 KB

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  1. // SPDX-License-Identifier: GPL-2.0-only
  2. /*
  3. * rtc-ds1307.c - RTC driver for some mostly-compatible I2C chips.
  4. *
  5. * Copyright (C) 2005 James Chapman (ds1337 core)
  6. * Copyright (C) 2006 David Brownell
  7. * Copyright (C) 2009 Matthias Fuchs (rx8025 support)
  8. * Copyright (C) 2012 Bertrand Achard (nvram access fixes)
  9. */
  10. #include <linux/bcd.h>
  11. #include <linux/i2c.h>
  12. #include <linux/init.h>
  13. #include <linux/kstrtox.h>
  14. #include <linux/mod_devicetable.h>
  15. #include <linux/module.h>
  16. #include <linux/property.h>
  17. #include <linux/rtc/ds1307.h>
  18. #include <linux/rtc.h>
  19. #include <linux/slab.h>
  20. #include <linux/string.h>
  21. #include <linux/hwmon.h>
  22. #include <linux/hwmon-sysfs.h>
  23. #include <linux/clk-provider.h>
  24. #include <linux/regmap.h>
  25. #include <linux/watchdog.h>
  26. /*
  27. * We can't determine type by probing, but if we expect pre-Linux code
  28. * to have set the chip up as a clock (turning on the oscillator and
  29. * setting the date and time), Linux can ignore the non-clock features.
  30. * That's a natural job for a factory or repair bench.
  31. */
  32. enum ds_type {
  33. unknown_ds_type, /* always first and 0 */
  34. ds_1307,
  35. ds_1308,
  36. ds_1337,
  37. ds_1338,
  38. ds_1339,
  39. ds_1340,
  40. ds_1341,
  41. ds_1388,
  42. ds_3231,
  43. m41t0,
  44. m41t00,
  45. m41t11,
  46. mcp794xx,
  47. rx_8025,
  48. rx_8130,
  49. last_ds_type /* always last */
  50. /* rs5c372 too? different address... */
  51. };
  52. /* RTC registers don't differ much, except for the century flag */
  53. #define DS1307_REG_SECS 0x00 /* 00-59 */
  54. # define DS1307_BIT_CH 0x80
  55. # define DS1340_BIT_nEOSC 0x80
  56. # define MCP794XX_BIT_ST 0x80
  57. #define DS1307_REG_MIN 0x01 /* 00-59 */
  58. # define M41T0_BIT_OF 0x80
  59. #define DS1307_REG_HOUR 0x02 /* 00-23, or 1-12{am,pm} */
  60. # define DS1307_BIT_12HR 0x40 /* in REG_HOUR */
  61. # define DS1307_BIT_PM 0x20 /* in REG_HOUR */
  62. # define DS1340_BIT_CENTURY_EN 0x80 /* in REG_HOUR */
  63. # define DS1340_BIT_CENTURY 0x40 /* in REG_HOUR */
  64. #define DS1307_REG_WDAY 0x03 /* 01-07 */
  65. # define MCP794XX_BIT_OSCRUN BIT(5)
  66. # define MCP794XX_BIT_VBATEN 0x08
  67. #define DS1307_REG_MDAY 0x04 /* 01-31 */
  68. #define DS1307_REG_MONTH 0x05 /* 01-12 */
  69. # define DS1337_BIT_CENTURY 0x80 /* in REG_MONTH */
  70. #define DS1307_REG_YEAR 0x06 /* 00-99 */
  71. /*
  72. * Other registers (control, status, alarms, trickle charge, NVRAM, etc)
  73. * start at 7, and they differ a LOT. Only control and status matter for
  74. * basic RTC date and time functionality; be careful using them.
  75. */
  76. #define DS1307_REG_CONTROL 0x07 /* or ds1338 */
  77. # define DS1307_BIT_OUT 0x80
  78. # define DS1338_BIT_OSF 0x20
  79. # define DS1307_BIT_SQWE 0x10
  80. # define DS1307_BIT_RS1 0x02
  81. # define DS1307_BIT_RS0 0x01
  82. #define DS1337_REG_CONTROL 0x0e
  83. # define DS1337_BIT_nEOSC 0x80
  84. # define DS1339_BIT_BBSQI 0x20
  85. # define DS3231_BIT_BBSQW 0x40 /* same as BBSQI */
  86. # define DS1337_BIT_RS2 0x10
  87. # define DS1337_BIT_RS1 0x08
  88. # define DS1337_BIT_INTCN 0x04
  89. # define DS1337_BIT_A2IE 0x02
  90. # define DS1337_BIT_A1IE 0x01
  91. #define DS1340_REG_CONTROL 0x07
  92. # define DS1340_BIT_OUT 0x80
  93. # define DS1340_BIT_FT 0x40
  94. # define DS1340_BIT_CALIB_SIGN 0x20
  95. # define DS1340_M_CALIBRATION 0x1f
  96. #define DS1340_REG_FLAG 0x09
  97. # define DS1340_BIT_OSF 0x80
  98. #define DS1337_REG_STATUS 0x0f
  99. # define DS1337_BIT_OSF 0x80
  100. # define DS3231_BIT_EN32KHZ 0x08
  101. # define DS1337_BIT_A2I 0x02
  102. # define DS1337_BIT_A1I 0x01
  103. #define DS1339_REG_ALARM1_SECS 0x07
  104. #define DS13XX_TRICKLE_CHARGER_MAGIC 0xa0
  105. #define RX8025_REG_CTRL1 0x0e
  106. # define RX8025_BIT_2412 0x20
  107. #define RX8025_REG_CTRL2 0x0f
  108. # define RX8025_BIT_PON 0x10
  109. # define RX8025_BIT_VDET 0x40
  110. # define RX8025_BIT_XST 0x20
  111. #define RX8130_REG_ALARM_MIN 0x17
  112. #define RX8130_REG_ALARM_HOUR 0x18
  113. #define RX8130_REG_ALARM_WEEK_OR_DAY 0x19
  114. #define RX8130_REG_EXTENSION 0x1c
  115. #define RX8130_REG_EXTENSION_WADA BIT(3)
  116. #define RX8130_REG_FLAG 0x1d
  117. #define RX8130_REG_FLAG_VLF BIT(1)
  118. #define RX8130_REG_FLAG_AF BIT(3)
  119. #define RX8130_REG_CONTROL0 0x1e
  120. #define RX8130_REG_CONTROL0_AIE BIT(3)
  121. #define RX8130_REG_CONTROL1 0x1f
  122. #define RX8130_REG_CONTROL1_INIEN BIT(4)
  123. #define RX8130_REG_CONTROL1_CHGEN BIT(5)
  124. #define MCP794XX_REG_CONTROL 0x07
  125. # define MCP794XX_BIT_ALM0_EN 0x10
  126. # define MCP794XX_BIT_ALM1_EN 0x20
  127. #define MCP794XX_REG_ALARM0_BASE 0x0a
  128. #define MCP794XX_REG_ALARM0_CTRL 0x0d
  129. #define MCP794XX_REG_ALARM1_BASE 0x11
  130. #define MCP794XX_REG_ALARM1_CTRL 0x14
  131. # define MCP794XX_BIT_ALMX_IF BIT(3)
  132. # define MCP794XX_BIT_ALMX_C0 BIT(4)
  133. # define MCP794XX_BIT_ALMX_C1 BIT(5)
  134. # define MCP794XX_BIT_ALMX_C2 BIT(6)
  135. # define MCP794XX_BIT_ALMX_POL BIT(7)
  136. # define MCP794XX_MSK_ALMX_MATCH (MCP794XX_BIT_ALMX_C0 | \
  137. MCP794XX_BIT_ALMX_C1 | \
  138. MCP794XX_BIT_ALMX_C2)
  139. #define M41TXX_REG_CONTROL 0x07
  140. # define M41TXX_BIT_OUT BIT(7)
  141. # define M41TXX_BIT_FT BIT(6)
  142. # define M41TXX_BIT_CALIB_SIGN BIT(5)
  143. # define M41TXX_M_CALIBRATION GENMASK(4, 0)
  144. #define DS1388_REG_WDOG_HUN_SECS 0x08
  145. #define DS1388_REG_WDOG_SECS 0x09
  146. #define DS1388_REG_FLAG 0x0b
  147. # define DS1388_BIT_WF BIT(6)
  148. # define DS1388_BIT_OSF BIT(7)
  149. #define DS1388_REG_CONTROL 0x0c
  150. # define DS1388_BIT_RST BIT(0)
  151. # define DS1388_BIT_WDE BIT(1)
  152. # define DS1388_BIT_nEOSC BIT(7)
  153. /* negative offset step is -2.034ppm */
  154. #define M41TXX_NEG_OFFSET_STEP_PPB 2034
  155. /* positive offset step is +4.068ppm */
  156. #define M41TXX_POS_OFFSET_STEP_PPB 4068
  157. /* Min and max values supported with 'offset' interface by M41TXX */
  158. #define M41TXX_MIN_OFFSET ((-31) * M41TXX_NEG_OFFSET_STEP_PPB)
  159. #define M41TXX_MAX_OFFSET ((31) * M41TXX_POS_OFFSET_STEP_PPB)
  160. struct ds1307 {
  161. enum ds_type type;
  162. struct device *dev;
  163. struct regmap *regmap;
  164. const char *name;
  165. struct rtc_device *rtc;
  166. #ifdef CONFIG_COMMON_CLK
  167. struct clk_hw clks[2];
  168. #endif
  169. };
  170. struct chip_desc {
  171. unsigned alarm:1;
  172. u16 nvram_offset;
  173. u16 nvram_size;
  174. u8 offset; /* register's offset */
  175. u8 century_reg;
  176. u8 century_enable_bit;
  177. u8 century_bit;
  178. u8 bbsqi_bit;
  179. irq_handler_t irq_handler;
  180. const struct rtc_class_ops *rtc_ops;
  181. u16 trickle_charger_reg;
  182. u8 (*do_trickle_setup)(struct ds1307 *, u32,
  183. bool);
  184. /* Does the RTC require trickle-resistor-ohms to select the value of
  185. * the resistor between Vcc and Vbackup?
  186. */
  187. bool requires_trickle_resistor;
  188. /* Some RTC's batteries and supercaps were charged by default, others
  189. * allow charging but were not configured previously to do so.
  190. * Remember this behavior to stay backwards compatible.
  191. */
  192. bool charge_default;
  193. };
  194. static const struct chip_desc chips[last_ds_type];
  195. static int ds1307_get_time(struct device *dev, struct rtc_time *t)
  196. {
  197. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  198. int tmp, ret;
  199. const struct chip_desc *chip = &chips[ds1307->type];
  200. u8 regs[7];
  201. if (ds1307->type == rx_8130) {
  202. unsigned int regflag;
  203. ret = regmap_read(ds1307->regmap, RX8130_REG_FLAG, &regflag);
  204. if (ret) {
  205. dev_err(dev, "%s error %d\n", "read", ret);
  206. return ret;
  207. }
  208. if (regflag & RX8130_REG_FLAG_VLF) {
  209. dev_warn_once(dev, "oscillator failed, set time!\n");
  210. return -EINVAL;
  211. }
  212. }
  213. /* read the RTC date and time registers all at once */
  214. ret = regmap_bulk_read(ds1307->regmap, chip->offset, regs,
  215. sizeof(regs));
  216. if (ret) {
  217. dev_err(dev, "%s error %d\n", "read", ret);
  218. return ret;
  219. }
  220. dev_dbg(dev, "%s: %7ph\n", "read", regs);
  221. /* if oscillator fail bit is set, no data can be trusted */
  222. if (ds1307->type == m41t0 &&
  223. regs[DS1307_REG_MIN] & M41T0_BIT_OF) {
  224. dev_warn_once(dev, "oscillator failed, set time!\n");
  225. return -EINVAL;
  226. } else if (ds1307->type == mcp794xx &&
  227. !(regs[DS1307_REG_WDAY] & MCP794XX_BIT_OSCRUN)) {
  228. dev_warn_once(dev, "oscillator failed, set time!\n");
  229. return -EINVAL;
  230. }
  231. tmp = regs[DS1307_REG_SECS];
  232. switch (ds1307->type) {
  233. case ds_1307:
  234. case m41t0:
  235. case m41t00:
  236. case m41t11:
  237. if (tmp & DS1307_BIT_CH)
  238. return -EINVAL;
  239. break;
  240. case ds_1308:
  241. case ds_1338:
  242. if (tmp & DS1307_BIT_CH)
  243. return -EINVAL;
  244. ret = regmap_read(ds1307->regmap, DS1307_REG_CONTROL, &tmp);
  245. if (ret)
  246. return ret;
  247. if (tmp & DS1338_BIT_OSF)
  248. return -EINVAL;
  249. break;
  250. case ds_1340:
  251. if (tmp & DS1340_BIT_nEOSC)
  252. return -EINVAL;
  253. ret = regmap_read(ds1307->regmap, DS1340_REG_FLAG, &tmp);
  254. if (ret)
  255. return ret;
  256. if (tmp & DS1340_BIT_OSF)
  257. return -EINVAL;
  258. break;
  259. case ds_1341:
  260. ret = regmap_read(ds1307->regmap, DS1337_REG_STATUS, &tmp);
  261. if (ret)
  262. return ret;
  263. if (tmp & DS1337_BIT_OSF)
  264. return -EINVAL;
  265. break;
  266. case ds_1388:
  267. ret = regmap_read(ds1307->regmap, DS1388_REG_FLAG, &tmp);
  268. if (ret)
  269. return ret;
  270. if (tmp & DS1388_BIT_OSF)
  271. return -EINVAL;
  272. break;
  273. case mcp794xx:
  274. if (!(tmp & MCP794XX_BIT_ST))
  275. return -EINVAL;
  276. break;
  277. default:
  278. break;
  279. }
  280. t->tm_sec = bcd2bin(regs[DS1307_REG_SECS] & 0x7f);
  281. t->tm_min = bcd2bin(regs[DS1307_REG_MIN] & 0x7f);
  282. tmp = regs[DS1307_REG_HOUR] & 0x3f;
  283. t->tm_hour = bcd2bin(tmp);
  284. /* rx8130 is bit position, not BCD */
  285. if (ds1307->type == rx_8130)
  286. t->tm_wday = fls(regs[DS1307_REG_WDAY] & 0x7f);
  287. else
  288. t->tm_wday = bcd2bin(regs[DS1307_REG_WDAY] & 0x07) - 1;
  289. t->tm_mday = bcd2bin(regs[DS1307_REG_MDAY] & 0x3f);
  290. tmp = regs[DS1307_REG_MONTH] & 0x1f;
  291. t->tm_mon = bcd2bin(tmp) - 1;
  292. t->tm_year = bcd2bin(regs[DS1307_REG_YEAR]) + 100;
  293. if (regs[chip->century_reg] & chip->century_bit &&
  294. IS_ENABLED(CONFIG_RTC_DRV_DS1307_CENTURY))
  295. t->tm_year += 100;
  296. dev_dbg(dev, "%s secs=%d, mins=%d, "
  297. "hours=%d, mday=%d, mon=%d, year=%d, wday=%d\n",
  298. "read", t->tm_sec, t->tm_min,
  299. t->tm_hour, t->tm_mday,
  300. t->tm_mon, t->tm_year, t->tm_wday);
  301. return 0;
  302. }
  303. static int ds1307_set_time(struct device *dev, struct rtc_time *t)
  304. {
  305. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  306. const struct chip_desc *chip = &chips[ds1307->type];
  307. int result;
  308. int tmp;
  309. u8 regs[7];
  310. dev_dbg(dev, "%s secs=%d, mins=%d, "
  311. "hours=%d, mday=%d, mon=%d, year=%d, wday=%d\n",
  312. "write", t->tm_sec, t->tm_min,
  313. t->tm_hour, t->tm_mday,
  314. t->tm_mon, t->tm_year, t->tm_wday);
  315. if (t->tm_year < 100)
  316. return -EINVAL;
  317. #ifdef CONFIG_RTC_DRV_DS1307_CENTURY
  318. if (t->tm_year > (chip->century_bit ? 299 : 199))
  319. return -EINVAL;
  320. #else
  321. if (t->tm_year > 199)
  322. return -EINVAL;
  323. #endif
  324. regs[DS1307_REG_SECS] = bin2bcd(t->tm_sec);
  325. regs[DS1307_REG_MIN] = bin2bcd(t->tm_min);
  326. regs[DS1307_REG_HOUR] = bin2bcd(t->tm_hour);
  327. /* rx8130 is bit position, not BCD */
  328. if (ds1307->type == rx_8130)
  329. regs[DS1307_REG_WDAY] = 1 << t->tm_wday;
  330. else
  331. regs[DS1307_REG_WDAY] = bin2bcd(t->tm_wday + 1);
  332. regs[DS1307_REG_MDAY] = bin2bcd(t->tm_mday);
  333. regs[DS1307_REG_MONTH] = bin2bcd(t->tm_mon + 1);
  334. /* assume 20YY not 19YY */
  335. tmp = t->tm_year % 100;
  336. regs[DS1307_REG_YEAR] = bin2bcd(tmp);
  337. if (chip->century_enable_bit)
  338. regs[chip->century_reg] |= chip->century_enable_bit;
  339. if (t->tm_year > 199 && chip->century_bit)
  340. regs[chip->century_reg] |= chip->century_bit;
  341. switch (ds1307->type) {
  342. case ds_1308:
  343. case ds_1338:
  344. regmap_update_bits(ds1307->regmap, DS1307_REG_CONTROL,
  345. DS1338_BIT_OSF, 0);
  346. break;
  347. case ds_1340:
  348. regmap_update_bits(ds1307->regmap, DS1340_REG_FLAG,
  349. DS1340_BIT_OSF, 0);
  350. break;
  351. case ds_1341:
  352. regmap_update_bits(ds1307->regmap, DS1337_REG_STATUS,
  353. DS1337_BIT_OSF, 0);
  354. break;
  355. case ds_1388:
  356. regmap_update_bits(ds1307->regmap, DS1388_REG_FLAG,
  357. DS1388_BIT_OSF, 0);
  358. break;
  359. case mcp794xx:
  360. /*
  361. * these bits were cleared when preparing the date/time
  362. * values and need to be set again before writing the
  363. * regsfer out to the device.
  364. */
  365. regs[DS1307_REG_SECS] |= MCP794XX_BIT_ST;
  366. regs[DS1307_REG_WDAY] |= MCP794XX_BIT_VBATEN;
  367. break;
  368. default:
  369. break;
  370. }
  371. dev_dbg(dev, "%s: %7ph\n", "write", regs);
  372. result = regmap_bulk_write(ds1307->regmap, chip->offset, regs,
  373. sizeof(regs));
  374. if (result) {
  375. dev_err(dev, "%s error %d\n", "write", result);
  376. return result;
  377. }
  378. if (ds1307->type == rx_8130) {
  379. /* clear Voltage Loss Flag as data is available now */
  380. result = regmap_write(ds1307->regmap, RX8130_REG_FLAG,
  381. ~(u8)RX8130_REG_FLAG_VLF);
  382. if (result) {
  383. dev_err(dev, "%s error %d\n", "write", result);
  384. return result;
  385. }
  386. }
  387. return 0;
  388. }
  389. static int ds1337_read_alarm(struct device *dev, struct rtc_wkalrm *t)
  390. {
  391. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  392. int ret;
  393. u8 regs[9];
  394. /* read all ALARM1, ALARM2, and status registers at once */
  395. ret = regmap_bulk_read(ds1307->regmap, DS1339_REG_ALARM1_SECS,
  396. regs, sizeof(regs));
  397. if (ret) {
  398. dev_err(dev, "%s error %d\n", "alarm read", ret);
  399. return ret;
  400. }
  401. dev_dbg(dev, "%s: %4ph, %3ph, %2ph\n", "alarm read",
  402. &regs[0], &regs[4], &regs[7]);
  403. /*
  404. * report alarm time (ALARM1); assume 24 hour and day-of-month modes,
  405. * and that all four fields are checked matches
  406. */
  407. t->time.tm_sec = bcd2bin(regs[0] & 0x7f);
  408. t->time.tm_min = bcd2bin(regs[1] & 0x7f);
  409. t->time.tm_hour = bcd2bin(regs[2] & 0x3f);
  410. t->time.tm_mday = bcd2bin(regs[3] & 0x3f);
  411. /* ... and status */
  412. t->enabled = !!(regs[7] & DS1337_BIT_A1IE);
  413. t->pending = !!(regs[8] & DS1337_BIT_A1I);
  414. dev_dbg(dev, "%s secs=%d, mins=%d, "
  415. "hours=%d, mday=%d, enabled=%d, pending=%d\n",
  416. "alarm read", t->time.tm_sec, t->time.tm_min,
  417. t->time.tm_hour, t->time.tm_mday,
  418. t->enabled, t->pending);
  419. return 0;
  420. }
  421. static int ds1337_set_alarm(struct device *dev, struct rtc_wkalrm *t)
  422. {
  423. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  424. unsigned char regs[9];
  425. u8 control, status;
  426. int ret;
  427. dev_dbg(dev, "%s secs=%d, mins=%d, "
  428. "hours=%d, mday=%d, enabled=%d, pending=%d\n",
  429. "alarm set", t->time.tm_sec, t->time.tm_min,
  430. t->time.tm_hour, t->time.tm_mday,
  431. t->enabled, t->pending);
  432. /* read current status of both alarms and the chip */
  433. ret = regmap_bulk_read(ds1307->regmap, DS1339_REG_ALARM1_SECS, regs,
  434. sizeof(regs));
  435. if (ret) {
  436. dev_err(dev, "%s error %d\n", "alarm write", ret);
  437. return ret;
  438. }
  439. control = regs[7];
  440. status = regs[8];
  441. dev_dbg(dev, "%s: %4ph, %3ph, %02x %02x\n", "alarm set (old status)",
  442. &regs[0], &regs[4], control, status);
  443. /* set ALARM1, using 24 hour and day-of-month modes */
  444. regs[0] = bin2bcd(t->time.tm_sec);
  445. regs[1] = bin2bcd(t->time.tm_min);
  446. regs[2] = bin2bcd(t->time.tm_hour);
  447. regs[3] = bin2bcd(t->time.tm_mday);
  448. /* set ALARM2 to non-garbage */
  449. regs[4] = 0;
  450. regs[5] = 0;
  451. regs[6] = 0;
  452. /* disable alarms */
  453. regs[7] = control & ~(DS1337_BIT_A1IE | DS1337_BIT_A2IE);
  454. regs[8] = status & ~(DS1337_BIT_A1I | DS1337_BIT_A2I);
  455. ret = regmap_bulk_write(ds1307->regmap, DS1339_REG_ALARM1_SECS, regs,
  456. sizeof(regs));
  457. if (ret) {
  458. dev_err(dev, "can't set alarm time\n");
  459. return ret;
  460. }
  461. /* optionally enable ALARM1 */
  462. if (t->enabled) {
  463. dev_dbg(dev, "alarm IRQ armed\n");
  464. regs[7] |= DS1337_BIT_A1IE; /* only ALARM1 is used */
  465. regmap_write(ds1307->regmap, DS1337_REG_CONTROL, regs[7]);
  466. }
  467. return 0;
  468. }
  469. static int ds1307_alarm_irq_enable(struct device *dev, unsigned int enabled)
  470. {
  471. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  472. return regmap_update_bits(ds1307->regmap, DS1337_REG_CONTROL,
  473. DS1337_BIT_A1IE,
  474. enabled ? DS1337_BIT_A1IE : 0);
  475. }
  476. static u8 do_trickle_setup_ds1339(struct ds1307 *ds1307, u32 ohms, bool diode)
  477. {
  478. u8 setup = (diode) ? DS1307_TRICKLE_CHARGER_DIODE :
  479. DS1307_TRICKLE_CHARGER_NO_DIODE;
  480. setup |= DS13XX_TRICKLE_CHARGER_MAGIC;
  481. switch (ohms) {
  482. case 250:
  483. setup |= DS1307_TRICKLE_CHARGER_250_OHM;
  484. break;
  485. case 2000:
  486. setup |= DS1307_TRICKLE_CHARGER_2K_OHM;
  487. break;
  488. case 4000:
  489. setup |= DS1307_TRICKLE_CHARGER_4K_OHM;
  490. break;
  491. default:
  492. dev_warn(ds1307->dev,
  493. "Unsupported ohm value %u in dt\n", ohms);
  494. return 0;
  495. }
  496. return setup;
  497. }
  498. static u8 do_trickle_setup_rx8130(struct ds1307 *ds1307, u32 ohms, bool diode)
  499. {
  500. /* make sure that the backup battery is enabled */
  501. u8 setup = RX8130_REG_CONTROL1_INIEN;
  502. if (diode)
  503. setup |= RX8130_REG_CONTROL1_CHGEN;
  504. return setup;
  505. }
  506. static irqreturn_t rx8130_irq(int irq, void *dev_id)
  507. {
  508. struct ds1307 *ds1307 = dev_id;
  509. u8 ctl[3];
  510. int ret;
  511. rtc_lock(ds1307->rtc);
  512. /* Read control registers. */
  513. ret = regmap_bulk_read(ds1307->regmap, RX8130_REG_EXTENSION, ctl,
  514. sizeof(ctl));
  515. if (ret < 0)
  516. goto out;
  517. if (!(ctl[1] & RX8130_REG_FLAG_AF))
  518. goto out;
  519. ctl[1] &= ~RX8130_REG_FLAG_AF;
  520. ctl[2] &= ~RX8130_REG_CONTROL0_AIE;
  521. ret = regmap_bulk_write(ds1307->regmap, RX8130_REG_EXTENSION, ctl,
  522. sizeof(ctl));
  523. if (ret < 0)
  524. goto out;
  525. rtc_update_irq(ds1307->rtc, 1, RTC_AF | RTC_IRQF);
  526. out:
  527. rtc_unlock(ds1307->rtc);
  528. return IRQ_HANDLED;
  529. }
  530. static int rx8130_read_alarm(struct device *dev, struct rtc_wkalrm *t)
  531. {
  532. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  533. u8 ald[3], ctl[3];
  534. int ret;
  535. /* Read alarm registers. */
  536. ret = regmap_bulk_read(ds1307->regmap, RX8130_REG_ALARM_MIN, ald,
  537. sizeof(ald));
  538. if (ret < 0)
  539. return ret;
  540. /* Read control registers. */
  541. ret = regmap_bulk_read(ds1307->regmap, RX8130_REG_EXTENSION, ctl,
  542. sizeof(ctl));
  543. if (ret < 0)
  544. return ret;
  545. t->enabled = !!(ctl[2] & RX8130_REG_CONTROL0_AIE);
  546. t->pending = !!(ctl[1] & RX8130_REG_FLAG_AF);
  547. /* Report alarm 0 time assuming 24-hour and day-of-month modes. */
  548. t->time.tm_sec = -1;
  549. t->time.tm_min = bcd2bin(ald[0] & 0x7f);
  550. t->time.tm_hour = bcd2bin(ald[1] & 0x7f);
  551. t->time.tm_wday = -1;
  552. t->time.tm_mday = bcd2bin(ald[2] & 0x7f);
  553. t->time.tm_mon = -1;
  554. t->time.tm_year = -1;
  555. t->time.tm_yday = -1;
  556. t->time.tm_isdst = -1;
  557. dev_dbg(dev, "%s, sec=%d min=%d hour=%d wday=%d mday=%d mon=%d enabled=%d\n",
  558. __func__, t->time.tm_sec, t->time.tm_min, t->time.tm_hour,
  559. t->time.tm_wday, t->time.tm_mday, t->time.tm_mon, t->enabled);
  560. return 0;
  561. }
  562. static int rx8130_set_alarm(struct device *dev, struct rtc_wkalrm *t)
  563. {
  564. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  565. u8 ald[3], ctl[3];
  566. int ret;
  567. dev_dbg(dev, "%s, sec=%d min=%d hour=%d wday=%d mday=%d mon=%d "
  568. "enabled=%d pending=%d\n", __func__,
  569. t->time.tm_sec, t->time.tm_min, t->time.tm_hour,
  570. t->time.tm_wday, t->time.tm_mday, t->time.tm_mon,
  571. t->enabled, t->pending);
  572. /* Read control registers. */
  573. ret = regmap_bulk_read(ds1307->regmap, RX8130_REG_EXTENSION, ctl,
  574. sizeof(ctl));
  575. if (ret < 0)
  576. return ret;
  577. ctl[0] &= RX8130_REG_EXTENSION_WADA;
  578. ctl[1] &= ~RX8130_REG_FLAG_AF;
  579. ctl[2] &= ~RX8130_REG_CONTROL0_AIE;
  580. ret = regmap_bulk_write(ds1307->regmap, RX8130_REG_EXTENSION, ctl,
  581. sizeof(ctl));
  582. if (ret < 0)
  583. return ret;
  584. /* Hardware alarm precision is 1 minute! */
  585. ald[0] = bin2bcd(t->time.tm_min);
  586. ald[1] = bin2bcd(t->time.tm_hour);
  587. ald[2] = bin2bcd(t->time.tm_mday);
  588. ret = regmap_bulk_write(ds1307->regmap, RX8130_REG_ALARM_MIN, ald,
  589. sizeof(ald));
  590. if (ret < 0)
  591. return ret;
  592. if (!t->enabled)
  593. return 0;
  594. ctl[2] |= RX8130_REG_CONTROL0_AIE;
  595. return regmap_write(ds1307->regmap, RX8130_REG_CONTROL0, ctl[2]);
  596. }
  597. static int rx8130_alarm_irq_enable(struct device *dev, unsigned int enabled)
  598. {
  599. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  600. int ret, reg;
  601. ret = regmap_read(ds1307->regmap, RX8130_REG_CONTROL0, &reg);
  602. if (ret < 0)
  603. return ret;
  604. if (enabled)
  605. reg |= RX8130_REG_CONTROL0_AIE;
  606. else
  607. reg &= ~RX8130_REG_CONTROL0_AIE;
  608. return regmap_write(ds1307->regmap, RX8130_REG_CONTROL0, reg);
  609. }
  610. static irqreturn_t mcp794xx_irq(int irq, void *dev_id)
  611. {
  612. struct ds1307 *ds1307 = dev_id;
  613. struct mutex *lock = &ds1307->rtc->ops_lock;
  614. int reg, ret;
  615. mutex_lock(lock);
  616. /* Check and clear alarm 0 interrupt flag. */
  617. ret = regmap_read(ds1307->regmap, MCP794XX_REG_ALARM0_CTRL, &reg);
  618. if (ret)
  619. goto out;
  620. if (!(reg & MCP794XX_BIT_ALMX_IF))
  621. goto out;
  622. reg &= ~MCP794XX_BIT_ALMX_IF;
  623. ret = regmap_write(ds1307->regmap, MCP794XX_REG_ALARM0_CTRL, reg);
  624. if (ret)
  625. goto out;
  626. /* Disable alarm 0. */
  627. ret = regmap_update_bits(ds1307->regmap, MCP794XX_REG_CONTROL,
  628. MCP794XX_BIT_ALM0_EN, 0);
  629. if (ret)
  630. goto out;
  631. rtc_update_irq(ds1307->rtc, 1, RTC_AF | RTC_IRQF);
  632. out:
  633. mutex_unlock(lock);
  634. return IRQ_HANDLED;
  635. }
  636. static int mcp794xx_read_alarm(struct device *dev, struct rtc_wkalrm *t)
  637. {
  638. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  639. u8 regs[10];
  640. int ret;
  641. /* Read control and alarm 0 registers. */
  642. ret = regmap_bulk_read(ds1307->regmap, MCP794XX_REG_CONTROL, regs,
  643. sizeof(regs));
  644. if (ret)
  645. return ret;
  646. t->enabled = !!(regs[0] & MCP794XX_BIT_ALM0_EN);
  647. /* Report alarm 0 time assuming 24-hour and day-of-month modes. */
  648. t->time.tm_sec = bcd2bin(regs[3] & 0x7f);
  649. t->time.tm_min = bcd2bin(regs[4] & 0x7f);
  650. t->time.tm_hour = bcd2bin(regs[5] & 0x3f);
  651. t->time.tm_wday = bcd2bin(regs[6] & 0x7) - 1;
  652. t->time.tm_mday = bcd2bin(regs[7] & 0x3f);
  653. t->time.tm_mon = bcd2bin(regs[8] & 0x1f) - 1;
  654. t->time.tm_year = -1;
  655. t->time.tm_yday = -1;
  656. t->time.tm_isdst = -1;
  657. dev_dbg(dev, "%s, sec=%d min=%d hour=%d wday=%d mday=%d mon=%d "
  658. "enabled=%d polarity=%d irq=%d match=%lu\n", __func__,
  659. t->time.tm_sec, t->time.tm_min, t->time.tm_hour,
  660. t->time.tm_wday, t->time.tm_mday, t->time.tm_mon, t->enabled,
  661. !!(regs[6] & MCP794XX_BIT_ALMX_POL),
  662. !!(regs[6] & MCP794XX_BIT_ALMX_IF),
  663. (regs[6] & MCP794XX_MSK_ALMX_MATCH) >> 4);
  664. return 0;
  665. }
  666. /*
  667. * We may have a random RTC weekday, therefore calculate alarm weekday based
  668. * on current weekday we read from the RTC timekeeping regs
  669. */
  670. static int mcp794xx_alm_weekday(struct device *dev, struct rtc_time *tm_alarm)
  671. {
  672. struct rtc_time tm_now;
  673. int days_now, days_alarm, ret;
  674. ret = ds1307_get_time(dev, &tm_now);
  675. if (ret)
  676. return ret;
  677. days_now = div_s64(rtc_tm_to_time64(&tm_now), 24 * 60 * 60);
  678. days_alarm = div_s64(rtc_tm_to_time64(tm_alarm), 24 * 60 * 60);
  679. return (tm_now.tm_wday + days_alarm - days_now) % 7 + 1;
  680. }
  681. static int mcp794xx_set_alarm(struct device *dev, struct rtc_wkalrm *t)
  682. {
  683. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  684. unsigned char regs[10];
  685. int wday, ret;
  686. wday = mcp794xx_alm_weekday(dev, &t->time);
  687. if (wday < 0)
  688. return wday;
  689. dev_dbg(dev, "%s, sec=%d min=%d hour=%d wday=%d mday=%d mon=%d "
  690. "enabled=%d pending=%d\n", __func__,
  691. t->time.tm_sec, t->time.tm_min, t->time.tm_hour,
  692. t->time.tm_wday, t->time.tm_mday, t->time.tm_mon,
  693. t->enabled, t->pending);
  694. /* Read control and alarm 0 registers. */
  695. ret = regmap_bulk_read(ds1307->regmap, MCP794XX_REG_CONTROL, regs,
  696. sizeof(regs));
  697. if (ret)
  698. return ret;
  699. /* Set alarm 0, using 24-hour and day-of-month modes. */
  700. regs[3] = bin2bcd(t->time.tm_sec);
  701. regs[4] = bin2bcd(t->time.tm_min);
  702. regs[5] = bin2bcd(t->time.tm_hour);
  703. regs[6] = wday;
  704. regs[7] = bin2bcd(t->time.tm_mday);
  705. regs[8] = bin2bcd(t->time.tm_mon + 1);
  706. /* Clear the alarm 0 interrupt flag. */
  707. regs[6] &= ~MCP794XX_BIT_ALMX_IF;
  708. /* Set alarm match: second, minute, hour, day, date, month. */
  709. regs[6] |= MCP794XX_MSK_ALMX_MATCH;
  710. /* Disable interrupt. We will not enable until completely programmed */
  711. regs[0] &= ~MCP794XX_BIT_ALM0_EN;
  712. ret = regmap_bulk_write(ds1307->regmap, MCP794XX_REG_CONTROL, regs,
  713. sizeof(regs));
  714. if (ret)
  715. return ret;
  716. if (!t->enabled)
  717. return 0;
  718. regs[0] |= MCP794XX_BIT_ALM0_EN;
  719. return regmap_write(ds1307->regmap, MCP794XX_REG_CONTROL, regs[0]);
  720. }
  721. static int mcp794xx_alarm_irq_enable(struct device *dev, unsigned int enabled)
  722. {
  723. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  724. return regmap_update_bits(ds1307->regmap, MCP794XX_REG_CONTROL,
  725. MCP794XX_BIT_ALM0_EN,
  726. enabled ? MCP794XX_BIT_ALM0_EN : 0);
  727. }
  728. static int m41txx_rtc_read_offset(struct device *dev, long *offset)
  729. {
  730. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  731. unsigned int ctrl_reg;
  732. u8 val;
  733. regmap_read(ds1307->regmap, M41TXX_REG_CONTROL, &ctrl_reg);
  734. val = ctrl_reg & M41TXX_M_CALIBRATION;
  735. /* check if positive */
  736. if (ctrl_reg & M41TXX_BIT_CALIB_SIGN)
  737. *offset = (val * M41TXX_POS_OFFSET_STEP_PPB);
  738. else
  739. *offset = -(val * M41TXX_NEG_OFFSET_STEP_PPB);
  740. return 0;
  741. }
  742. static int m41txx_rtc_set_offset(struct device *dev, long offset)
  743. {
  744. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  745. unsigned int ctrl_reg;
  746. if ((offset < M41TXX_MIN_OFFSET) || (offset > M41TXX_MAX_OFFSET))
  747. return -ERANGE;
  748. if (offset >= 0) {
  749. ctrl_reg = DIV_ROUND_CLOSEST(offset,
  750. M41TXX_POS_OFFSET_STEP_PPB);
  751. ctrl_reg |= M41TXX_BIT_CALIB_SIGN;
  752. } else {
  753. ctrl_reg = DIV_ROUND_CLOSEST(abs(offset),
  754. M41TXX_NEG_OFFSET_STEP_PPB);
  755. }
  756. return regmap_update_bits(ds1307->regmap, M41TXX_REG_CONTROL,
  757. M41TXX_M_CALIBRATION | M41TXX_BIT_CALIB_SIGN,
  758. ctrl_reg);
  759. }
  760. #ifdef CONFIG_WATCHDOG_CORE
  761. static int ds1388_wdt_start(struct watchdog_device *wdt_dev)
  762. {
  763. struct ds1307 *ds1307 = watchdog_get_drvdata(wdt_dev);
  764. u8 regs[2];
  765. int ret;
  766. ret = regmap_update_bits(ds1307->regmap, DS1388_REG_FLAG,
  767. DS1388_BIT_WF, 0);
  768. if (ret)
  769. return ret;
  770. ret = regmap_update_bits(ds1307->regmap, DS1388_REG_CONTROL,
  771. DS1388_BIT_WDE | DS1388_BIT_RST, 0);
  772. if (ret)
  773. return ret;
  774. /*
  775. * watchdog timeouts are measured in seconds. So ignore hundredths of
  776. * seconds field.
  777. */
  778. regs[0] = 0;
  779. regs[1] = bin2bcd(wdt_dev->timeout);
  780. ret = regmap_bulk_write(ds1307->regmap, DS1388_REG_WDOG_HUN_SECS, regs,
  781. sizeof(regs));
  782. if (ret)
  783. return ret;
  784. return regmap_update_bits(ds1307->regmap, DS1388_REG_CONTROL,
  785. DS1388_BIT_WDE | DS1388_BIT_RST,
  786. DS1388_BIT_WDE | DS1388_BIT_RST);
  787. }
  788. static int ds1388_wdt_stop(struct watchdog_device *wdt_dev)
  789. {
  790. struct ds1307 *ds1307 = watchdog_get_drvdata(wdt_dev);
  791. return regmap_update_bits(ds1307->regmap, DS1388_REG_CONTROL,
  792. DS1388_BIT_WDE | DS1388_BIT_RST, 0);
  793. }
  794. static int ds1388_wdt_ping(struct watchdog_device *wdt_dev)
  795. {
  796. struct ds1307 *ds1307 = watchdog_get_drvdata(wdt_dev);
  797. u8 regs[2];
  798. return regmap_bulk_read(ds1307->regmap, DS1388_REG_WDOG_HUN_SECS, regs,
  799. sizeof(regs));
  800. }
  801. static int ds1388_wdt_set_timeout(struct watchdog_device *wdt_dev,
  802. unsigned int val)
  803. {
  804. struct ds1307 *ds1307 = watchdog_get_drvdata(wdt_dev);
  805. u8 regs[2];
  806. wdt_dev->timeout = val;
  807. regs[0] = 0;
  808. regs[1] = bin2bcd(wdt_dev->timeout);
  809. return regmap_bulk_write(ds1307->regmap, DS1388_REG_WDOG_HUN_SECS, regs,
  810. sizeof(regs));
  811. }
  812. #endif
  813. static const struct rtc_class_ops rx8130_rtc_ops = {
  814. .read_time = ds1307_get_time,
  815. .set_time = ds1307_set_time,
  816. .read_alarm = rx8130_read_alarm,
  817. .set_alarm = rx8130_set_alarm,
  818. .alarm_irq_enable = rx8130_alarm_irq_enable,
  819. };
  820. static const struct rtc_class_ops mcp794xx_rtc_ops = {
  821. .read_time = ds1307_get_time,
  822. .set_time = ds1307_set_time,
  823. .read_alarm = mcp794xx_read_alarm,
  824. .set_alarm = mcp794xx_set_alarm,
  825. .alarm_irq_enable = mcp794xx_alarm_irq_enable,
  826. };
  827. static const struct rtc_class_ops m41txx_rtc_ops = {
  828. .read_time = ds1307_get_time,
  829. .set_time = ds1307_set_time,
  830. .read_alarm = ds1337_read_alarm,
  831. .set_alarm = ds1337_set_alarm,
  832. .alarm_irq_enable = ds1307_alarm_irq_enable,
  833. .read_offset = m41txx_rtc_read_offset,
  834. .set_offset = m41txx_rtc_set_offset,
  835. };
  836. static const struct chip_desc chips[last_ds_type] = {
  837. [ds_1307] = {
  838. .nvram_offset = 8,
  839. .nvram_size = 56,
  840. },
  841. [ds_1308] = {
  842. .nvram_offset = 8,
  843. .nvram_size = 56,
  844. },
  845. [ds_1337] = {
  846. .alarm = 1,
  847. .century_reg = DS1307_REG_MONTH,
  848. .century_bit = DS1337_BIT_CENTURY,
  849. },
  850. [ds_1338] = {
  851. .nvram_offset = 8,
  852. .nvram_size = 56,
  853. },
  854. [ds_1339] = {
  855. .alarm = 1,
  856. .century_reg = DS1307_REG_MONTH,
  857. .century_bit = DS1337_BIT_CENTURY,
  858. .bbsqi_bit = DS1339_BIT_BBSQI,
  859. .trickle_charger_reg = 0x10,
  860. .do_trickle_setup = &do_trickle_setup_ds1339,
  861. .requires_trickle_resistor = true,
  862. .charge_default = true,
  863. },
  864. [ds_1340] = {
  865. .century_reg = DS1307_REG_HOUR,
  866. .century_enable_bit = DS1340_BIT_CENTURY_EN,
  867. .century_bit = DS1340_BIT_CENTURY,
  868. .do_trickle_setup = &do_trickle_setup_ds1339,
  869. .trickle_charger_reg = 0x08,
  870. .requires_trickle_resistor = true,
  871. .charge_default = true,
  872. },
  873. [ds_1341] = {
  874. .century_reg = DS1307_REG_MONTH,
  875. .century_bit = DS1337_BIT_CENTURY,
  876. },
  877. [ds_1388] = {
  878. .offset = 1,
  879. .trickle_charger_reg = 0x0a,
  880. },
  881. [ds_3231] = {
  882. .alarm = 1,
  883. .century_reg = DS1307_REG_MONTH,
  884. .century_bit = DS1337_BIT_CENTURY,
  885. .bbsqi_bit = DS3231_BIT_BBSQW,
  886. },
  887. [rx_8130] = {
  888. .alarm = 1,
  889. /* this is battery backed SRAM */
  890. .nvram_offset = 0x20,
  891. .nvram_size = 4, /* 32bit (4 word x 8 bit) */
  892. .offset = 0x10,
  893. .irq_handler = rx8130_irq,
  894. .rtc_ops = &rx8130_rtc_ops,
  895. .trickle_charger_reg = RX8130_REG_CONTROL1,
  896. .do_trickle_setup = &do_trickle_setup_rx8130,
  897. },
  898. [m41t0] = {
  899. .rtc_ops = &m41txx_rtc_ops,
  900. },
  901. [m41t00] = {
  902. .rtc_ops = &m41txx_rtc_ops,
  903. },
  904. [m41t11] = {
  905. /* this is battery backed SRAM */
  906. .nvram_offset = 8,
  907. .nvram_size = 56,
  908. .rtc_ops = &m41txx_rtc_ops,
  909. },
  910. [mcp794xx] = {
  911. .alarm = 1,
  912. /* this is battery backed SRAM */
  913. .nvram_offset = 0x20,
  914. .nvram_size = 0x40,
  915. .irq_handler = mcp794xx_irq,
  916. .rtc_ops = &mcp794xx_rtc_ops,
  917. },
  918. };
  919. static const struct i2c_device_id ds1307_id[] = {
  920. { "ds1307", ds_1307 },
  921. { "ds1308", ds_1308 },
  922. { "ds1337", ds_1337 },
  923. { "ds1338", ds_1338 },
  924. { "ds1339", ds_1339 },
  925. { "ds1388", ds_1388 },
  926. { "ds1340", ds_1340 },
  927. { "ds1341", ds_1341 },
  928. { "ds3231", ds_3231 },
  929. { "m41t0", m41t0 },
  930. { "m41t00", m41t00 },
  931. { "m41t11", m41t11 },
  932. { "mcp7940x", mcp794xx },
  933. { "mcp7941x", mcp794xx },
  934. { "pt7c4338", ds_1307 },
  935. { "rx8025", rx_8025 },
  936. { "isl12057", ds_1337 },
  937. { "rx8130", rx_8130 },
  938. { }
  939. };
  940. MODULE_DEVICE_TABLE(i2c, ds1307_id);
  941. static const struct of_device_id ds1307_of_match[] = {
  942. {
  943. .compatible = "dallas,ds1307",
  944. .data = (void *)ds_1307
  945. },
  946. {
  947. .compatible = "dallas,ds1308",
  948. .data = (void *)ds_1308
  949. },
  950. {
  951. .compatible = "dallas,ds1337",
  952. .data = (void *)ds_1337
  953. },
  954. {
  955. .compatible = "dallas,ds1338",
  956. .data = (void *)ds_1338
  957. },
  958. {
  959. .compatible = "dallas,ds1339",
  960. .data = (void *)ds_1339
  961. },
  962. {
  963. .compatible = "dallas,ds1388",
  964. .data = (void *)ds_1388
  965. },
  966. {
  967. .compatible = "dallas,ds1340",
  968. .data = (void *)ds_1340
  969. },
  970. {
  971. .compatible = "dallas,ds1341",
  972. .data = (void *)ds_1341
  973. },
  974. {
  975. .compatible = "maxim,ds3231",
  976. .data = (void *)ds_3231
  977. },
  978. {
  979. .compatible = "st,m41t0",
  980. .data = (void *)m41t0
  981. },
  982. {
  983. .compatible = "st,m41t00",
  984. .data = (void *)m41t00
  985. },
  986. {
  987. .compatible = "st,m41t11",
  988. .data = (void *)m41t11
  989. },
  990. {
  991. .compatible = "microchip,mcp7940x",
  992. .data = (void *)mcp794xx
  993. },
  994. {
  995. .compatible = "microchip,mcp7941x",
  996. .data = (void *)mcp794xx
  997. },
  998. {
  999. .compatible = "pericom,pt7c4338",
  1000. .data = (void *)ds_1307
  1001. },
  1002. {
  1003. .compatible = "epson,rx8025",
  1004. .data = (void *)rx_8025
  1005. },
  1006. {
  1007. .compatible = "isil,isl12057",
  1008. .data = (void *)ds_1337
  1009. },
  1010. {
  1011. .compatible = "epson,rx8130",
  1012. .data = (void *)rx_8130
  1013. },
  1014. { }
  1015. };
  1016. MODULE_DEVICE_TABLE(of, ds1307_of_match);
  1017. /*
  1018. * The ds1337 and ds1339 both have two alarms, but we only use the first
  1019. * one (with a "seconds" field). For ds1337 we expect nINTA is our alarm
  1020. * signal; ds1339 chips have only one alarm signal.
  1021. */
  1022. static irqreturn_t ds1307_irq(int irq, void *dev_id)
  1023. {
  1024. struct ds1307 *ds1307 = dev_id;
  1025. struct mutex *lock = &ds1307->rtc->ops_lock;
  1026. int stat, ret;
  1027. mutex_lock(lock);
  1028. ret = regmap_read(ds1307->regmap, DS1337_REG_STATUS, &stat);
  1029. if (ret)
  1030. goto out;
  1031. if (stat & DS1337_BIT_A1I) {
  1032. stat &= ~DS1337_BIT_A1I;
  1033. regmap_write(ds1307->regmap, DS1337_REG_STATUS, stat);
  1034. ret = regmap_update_bits(ds1307->regmap, DS1337_REG_CONTROL,
  1035. DS1337_BIT_A1IE, 0);
  1036. if (ret)
  1037. goto out;
  1038. rtc_update_irq(ds1307->rtc, 1, RTC_AF | RTC_IRQF);
  1039. }
  1040. out:
  1041. mutex_unlock(lock);
  1042. return IRQ_HANDLED;
  1043. }
  1044. /*----------------------------------------------------------------------*/
  1045. static const struct rtc_class_ops ds13xx_rtc_ops = {
  1046. .read_time = ds1307_get_time,
  1047. .set_time = ds1307_set_time,
  1048. .read_alarm = ds1337_read_alarm,
  1049. .set_alarm = ds1337_set_alarm,
  1050. .alarm_irq_enable = ds1307_alarm_irq_enable,
  1051. };
  1052. static ssize_t frequency_test_store(struct device *dev,
  1053. struct device_attribute *attr,
  1054. const char *buf, size_t count)
  1055. {
  1056. struct ds1307 *ds1307 = dev_get_drvdata(dev->parent);
  1057. bool freq_test_en;
  1058. int ret;
  1059. ret = kstrtobool(buf, &freq_test_en);
  1060. if (ret) {
  1061. dev_err(dev, "Failed to store RTC Frequency Test attribute\n");
  1062. return ret;
  1063. }
  1064. regmap_update_bits(ds1307->regmap, M41TXX_REG_CONTROL, M41TXX_BIT_FT,
  1065. freq_test_en ? M41TXX_BIT_FT : 0);
  1066. return count;
  1067. }
  1068. static ssize_t frequency_test_show(struct device *dev,
  1069. struct device_attribute *attr,
  1070. char *buf)
  1071. {
  1072. struct ds1307 *ds1307 = dev_get_drvdata(dev->parent);
  1073. unsigned int ctrl_reg;
  1074. regmap_read(ds1307->regmap, M41TXX_REG_CONTROL, &ctrl_reg);
  1075. return sysfs_emit(buf, (ctrl_reg & M41TXX_BIT_FT) ? "on\n" : "off\n");
  1076. }
  1077. static DEVICE_ATTR_RW(frequency_test);
  1078. static struct attribute *rtc_freq_test_attrs[] = {
  1079. &dev_attr_frequency_test.attr,
  1080. NULL,
  1081. };
  1082. static const struct attribute_group rtc_freq_test_attr_group = {
  1083. .attrs = rtc_freq_test_attrs,
  1084. };
  1085. static int ds1307_add_frequency_test(struct ds1307 *ds1307)
  1086. {
  1087. int err;
  1088. switch (ds1307->type) {
  1089. case m41t0:
  1090. case m41t00:
  1091. case m41t11:
  1092. err = rtc_add_group(ds1307->rtc, &rtc_freq_test_attr_group);
  1093. if (err)
  1094. return err;
  1095. break;
  1096. default:
  1097. break;
  1098. }
  1099. return 0;
  1100. }
  1101. /*----------------------------------------------------------------------*/
  1102. static int ds1307_nvram_read(void *priv, unsigned int offset, void *val,
  1103. size_t bytes)
  1104. {
  1105. struct ds1307 *ds1307 = priv;
  1106. const struct chip_desc *chip = &chips[ds1307->type];
  1107. return regmap_bulk_read(ds1307->regmap, chip->nvram_offset + offset,
  1108. val, bytes);
  1109. }
  1110. static int ds1307_nvram_write(void *priv, unsigned int offset, void *val,
  1111. size_t bytes)
  1112. {
  1113. struct ds1307 *ds1307 = priv;
  1114. const struct chip_desc *chip = &chips[ds1307->type];
  1115. return regmap_bulk_write(ds1307->regmap, chip->nvram_offset + offset,
  1116. val, bytes);
  1117. }
  1118. /*----------------------------------------------------------------------*/
  1119. static u8 ds1307_trickle_init(struct ds1307 *ds1307,
  1120. const struct chip_desc *chip)
  1121. {
  1122. u32 ohms, chargeable;
  1123. bool diode = chip->charge_default;
  1124. if (!chip->do_trickle_setup)
  1125. return 0;
  1126. if (device_property_read_u32(ds1307->dev, "trickle-resistor-ohms",
  1127. &ohms) && chip->requires_trickle_resistor)
  1128. return 0;
  1129. /* aux-voltage-chargeable takes precedence over the deprecated
  1130. * trickle-diode-disable
  1131. */
  1132. if (!device_property_read_u32(ds1307->dev, "aux-voltage-chargeable",
  1133. &chargeable)) {
  1134. switch (chargeable) {
  1135. case 0:
  1136. diode = false;
  1137. break;
  1138. case 1:
  1139. diode = true;
  1140. break;
  1141. default:
  1142. dev_warn(ds1307->dev,
  1143. "unsupported aux-voltage-chargeable value\n");
  1144. break;
  1145. }
  1146. } else if (device_property_read_bool(ds1307->dev,
  1147. "trickle-diode-disable")) {
  1148. diode = false;
  1149. }
  1150. return chip->do_trickle_setup(ds1307, ohms, diode);
  1151. }
  1152. /*----------------------------------------------------------------------*/
  1153. #if IS_REACHABLE(CONFIG_HWMON)
  1154. /*
  1155. * Temperature sensor support for ds3231 devices.
  1156. */
  1157. #define DS3231_REG_TEMPERATURE 0x11
  1158. /*
  1159. * A user-initiated temperature conversion is not started by this function,
  1160. * so the temperature is updated once every 64 seconds.
  1161. */
  1162. static int ds3231_hwmon_read_temp(struct device *dev, s32 *mC)
  1163. {
  1164. struct ds1307 *ds1307 = dev_get_drvdata(dev);
  1165. u8 temp_buf[2];
  1166. s16 temp;
  1167. int ret;
  1168. ret = regmap_bulk_read(ds1307->regmap, DS3231_REG_TEMPERATURE,
  1169. temp_buf, sizeof(temp_buf));
  1170. if (ret)
  1171. return ret;
  1172. /*
  1173. * Temperature is represented as a 10-bit code with a resolution of
  1174. * 0.25 degree celsius and encoded in two's complement format.
  1175. */
  1176. temp = (temp_buf[0] << 8) | temp_buf[1];
  1177. temp >>= 6;
  1178. *mC = temp * 250;
  1179. return 0;
  1180. }
  1181. static ssize_t ds3231_hwmon_show_temp(struct device *dev,
  1182. struct device_attribute *attr, char *buf)
  1183. {
  1184. int ret;
  1185. s32 temp;
  1186. ret = ds3231_hwmon_read_temp(dev, &temp);
  1187. if (ret)
  1188. return ret;
  1189. return sprintf(buf, "%d\n", temp);
  1190. }
  1191. static SENSOR_DEVICE_ATTR(temp1_input, 0444, ds3231_hwmon_show_temp,
  1192. NULL, 0);
  1193. static struct attribute *ds3231_hwmon_attrs[] = {
  1194. &sensor_dev_attr_temp1_input.dev_attr.attr,
  1195. NULL,
  1196. };
  1197. ATTRIBUTE_GROUPS(ds3231_hwmon);
  1198. static void ds1307_hwmon_register(struct ds1307 *ds1307)
  1199. {
  1200. struct device *dev;
  1201. if (ds1307->type != ds_3231)
  1202. return;
  1203. dev = devm_hwmon_device_register_with_groups(ds1307->dev, ds1307->name,
  1204. ds1307,
  1205. ds3231_hwmon_groups);
  1206. if (IS_ERR(dev)) {
  1207. dev_warn(ds1307->dev, "unable to register hwmon device %ld\n",
  1208. PTR_ERR(dev));
  1209. }
  1210. }
  1211. #else
  1212. static void ds1307_hwmon_register(struct ds1307 *ds1307)
  1213. {
  1214. }
  1215. #endif /* CONFIG_RTC_DRV_DS1307_HWMON */
  1216. /*----------------------------------------------------------------------*/
  1217. /*
  1218. * Square-wave output support for DS3231
  1219. * Datasheet: https://datasheets.maximintegrated.com/en/ds/DS3231.pdf
  1220. */
  1221. #ifdef CONFIG_COMMON_CLK
  1222. enum {
  1223. DS3231_CLK_SQW = 0,
  1224. DS3231_CLK_32KHZ,
  1225. };
  1226. #define clk_sqw_to_ds1307(clk) \
  1227. container_of(clk, struct ds1307, clks[DS3231_CLK_SQW])
  1228. #define clk_32khz_to_ds1307(clk) \
  1229. container_of(clk, struct ds1307, clks[DS3231_CLK_32KHZ])
  1230. static int ds3231_clk_sqw_rates[] = {
  1231. 1,
  1232. 1024,
  1233. 4096,
  1234. 8192,
  1235. };
  1236. static int ds1337_write_control(struct ds1307 *ds1307, u8 mask, u8 value)
  1237. {
  1238. struct mutex *lock = &ds1307->rtc->ops_lock;
  1239. int ret;
  1240. mutex_lock(lock);
  1241. ret = regmap_update_bits(ds1307->regmap, DS1337_REG_CONTROL,
  1242. mask, value);
  1243. mutex_unlock(lock);
  1244. return ret;
  1245. }
  1246. static unsigned long ds3231_clk_sqw_recalc_rate(struct clk_hw *hw,
  1247. unsigned long parent_rate)
  1248. {
  1249. struct ds1307 *ds1307 = clk_sqw_to_ds1307(hw);
  1250. int control, ret;
  1251. int rate_sel = 0;
  1252. ret = regmap_read(ds1307->regmap, DS1337_REG_CONTROL, &control);
  1253. if (ret)
  1254. return ret;
  1255. if (control & DS1337_BIT_RS1)
  1256. rate_sel += 1;
  1257. if (control & DS1337_BIT_RS2)
  1258. rate_sel += 2;
  1259. return ds3231_clk_sqw_rates[rate_sel];
  1260. }
  1261. static int ds3231_clk_sqw_determine_rate(struct clk_hw *hw,
  1262. struct clk_rate_request *req)
  1263. {
  1264. int i;
  1265. for (i = ARRAY_SIZE(ds3231_clk_sqw_rates) - 1; i >= 0; i--) {
  1266. if (ds3231_clk_sqw_rates[i] <= req->rate) {
  1267. req->rate = ds3231_clk_sqw_rates[i];
  1268. return 0;
  1269. }
  1270. }
  1271. req->rate = ds3231_clk_sqw_rates[ARRAY_SIZE(ds3231_clk_sqw_rates) - 1];
  1272. return 0;
  1273. }
  1274. static int ds3231_clk_sqw_set_rate(struct clk_hw *hw, unsigned long rate,
  1275. unsigned long parent_rate)
  1276. {
  1277. struct ds1307 *ds1307 = clk_sqw_to_ds1307(hw);
  1278. int control = 0;
  1279. int rate_sel;
  1280. for (rate_sel = 0; rate_sel < ARRAY_SIZE(ds3231_clk_sqw_rates);
  1281. rate_sel++) {
  1282. if (ds3231_clk_sqw_rates[rate_sel] == rate)
  1283. break;
  1284. }
  1285. if (rate_sel == ARRAY_SIZE(ds3231_clk_sqw_rates))
  1286. return -EINVAL;
  1287. if (rate_sel & 1)
  1288. control |= DS1337_BIT_RS1;
  1289. if (rate_sel & 2)
  1290. control |= DS1337_BIT_RS2;
  1291. return ds1337_write_control(ds1307, DS1337_BIT_RS1 | DS1337_BIT_RS2,
  1292. control);
  1293. }
  1294. static int ds3231_clk_sqw_prepare(struct clk_hw *hw)
  1295. {
  1296. struct ds1307 *ds1307 = clk_sqw_to_ds1307(hw);
  1297. return ds1337_write_control(ds1307, DS1337_BIT_INTCN, 0);
  1298. }
  1299. static void ds3231_clk_sqw_unprepare(struct clk_hw *hw)
  1300. {
  1301. struct ds1307 *ds1307 = clk_sqw_to_ds1307(hw);
  1302. ds1337_write_control(ds1307, DS1337_BIT_INTCN, DS1337_BIT_INTCN);
  1303. }
  1304. static int ds3231_clk_sqw_is_prepared(struct clk_hw *hw)
  1305. {
  1306. struct ds1307 *ds1307 = clk_sqw_to_ds1307(hw);
  1307. int control, ret;
  1308. ret = regmap_read(ds1307->regmap, DS1337_REG_CONTROL, &control);
  1309. if (ret)
  1310. return ret;
  1311. return !(control & DS1337_BIT_INTCN);
  1312. }
  1313. static const struct clk_ops ds3231_clk_sqw_ops = {
  1314. .prepare = ds3231_clk_sqw_prepare,
  1315. .unprepare = ds3231_clk_sqw_unprepare,
  1316. .is_prepared = ds3231_clk_sqw_is_prepared,
  1317. .recalc_rate = ds3231_clk_sqw_recalc_rate,
  1318. .determine_rate = ds3231_clk_sqw_determine_rate,
  1319. .set_rate = ds3231_clk_sqw_set_rate,
  1320. };
  1321. static unsigned long ds3231_clk_32khz_recalc_rate(struct clk_hw *hw,
  1322. unsigned long parent_rate)
  1323. {
  1324. return 32768;
  1325. }
  1326. static int ds3231_clk_32khz_control(struct ds1307 *ds1307, bool enable)
  1327. {
  1328. struct mutex *lock = &ds1307->rtc->ops_lock;
  1329. int ret;
  1330. mutex_lock(lock);
  1331. ret = regmap_update_bits(ds1307->regmap, DS1337_REG_STATUS,
  1332. DS3231_BIT_EN32KHZ,
  1333. enable ? DS3231_BIT_EN32KHZ : 0);
  1334. mutex_unlock(lock);
  1335. return ret;
  1336. }
  1337. static int ds3231_clk_32khz_prepare(struct clk_hw *hw)
  1338. {
  1339. struct ds1307 *ds1307 = clk_32khz_to_ds1307(hw);
  1340. return ds3231_clk_32khz_control(ds1307, true);
  1341. }
  1342. static void ds3231_clk_32khz_unprepare(struct clk_hw *hw)
  1343. {
  1344. struct ds1307 *ds1307 = clk_32khz_to_ds1307(hw);
  1345. ds3231_clk_32khz_control(ds1307, false);
  1346. }
  1347. static int ds3231_clk_32khz_is_prepared(struct clk_hw *hw)
  1348. {
  1349. struct ds1307 *ds1307 = clk_32khz_to_ds1307(hw);
  1350. int status, ret;
  1351. ret = regmap_read(ds1307->regmap, DS1337_REG_STATUS, &status);
  1352. if (ret)
  1353. return ret;
  1354. return !!(status & DS3231_BIT_EN32KHZ);
  1355. }
  1356. static const struct clk_ops ds3231_clk_32khz_ops = {
  1357. .prepare = ds3231_clk_32khz_prepare,
  1358. .unprepare = ds3231_clk_32khz_unprepare,
  1359. .is_prepared = ds3231_clk_32khz_is_prepared,
  1360. .recalc_rate = ds3231_clk_32khz_recalc_rate,
  1361. };
  1362. static const char *ds3231_clks_names[] = {
  1363. [DS3231_CLK_SQW] = "ds3231_clk_sqw",
  1364. [DS3231_CLK_32KHZ] = "ds3231_clk_32khz",
  1365. };
  1366. static struct clk_init_data ds3231_clks_init[] = {
  1367. [DS3231_CLK_SQW] = {
  1368. .ops = &ds3231_clk_sqw_ops,
  1369. },
  1370. [DS3231_CLK_32KHZ] = {
  1371. .ops = &ds3231_clk_32khz_ops,
  1372. },
  1373. };
  1374. static int ds3231_clks_register(struct ds1307 *ds1307)
  1375. {
  1376. struct device_node *node = ds1307->dev->of_node;
  1377. struct clk_onecell_data *onecell;
  1378. int i;
  1379. onecell = devm_kzalloc(ds1307->dev, sizeof(*onecell), GFP_KERNEL);
  1380. if (!onecell)
  1381. return -ENOMEM;
  1382. onecell->clk_num = ARRAY_SIZE(ds3231_clks_init);
  1383. onecell->clks = devm_kcalloc(ds1307->dev, onecell->clk_num,
  1384. sizeof(onecell->clks[0]), GFP_KERNEL);
  1385. if (!onecell->clks)
  1386. return -ENOMEM;
  1387. /* optional override of the clockname */
  1388. device_property_read_string_array(ds1307->dev, "clock-output-names",
  1389. ds3231_clks_names,
  1390. ARRAY_SIZE(ds3231_clks_names));
  1391. for (i = 0; i < ARRAY_SIZE(ds3231_clks_init); i++) {
  1392. struct clk_init_data init = ds3231_clks_init[i];
  1393. /*
  1394. * Interrupt signal due to alarm conditions and square-wave
  1395. * output share same pin, so don't initialize both.
  1396. */
  1397. if (i == DS3231_CLK_SQW && test_bit(RTC_FEATURE_ALARM, ds1307->rtc->features))
  1398. continue;
  1399. init.name = ds3231_clks_names[i];
  1400. ds1307->clks[i].init = &init;
  1401. onecell->clks[i] = devm_clk_register(ds1307->dev,
  1402. &ds1307->clks[i]);
  1403. if (IS_ERR(onecell->clks[i]))
  1404. return PTR_ERR(onecell->clks[i]);
  1405. }
  1406. if (node)
  1407. of_clk_add_provider(node, of_clk_src_onecell_get, onecell);
  1408. return 0;
  1409. }
  1410. static void ds1307_clks_register(struct ds1307 *ds1307)
  1411. {
  1412. int ret;
  1413. if (ds1307->type != ds_3231)
  1414. return;
  1415. ret = ds3231_clks_register(ds1307);
  1416. if (ret) {
  1417. dev_warn(ds1307->dev, "unable to register clock device %d\n",
  1418. ret);
  1419. }
  1420. }
  1421. #else
  1422. static void ds1307_clks_register(struct ds1307 *ds1307)
  1423. {
  1424. }
  1425. #endif /* CONFIG_COMMON_CLK */
  1426. #ifdef CONFIG_WATCHDOG_CORE
  1427. static const struct watchdog_info ds1388_wdt_info = {
  1428. .options = WDIOF_SETTIMEOUT | WDIOF_KEEPALIVEPING | WDIOF_MAGICCLOSE,
  1429. .identity = "DS1388 watchdog",
  1430. };
  1431. static const struct watchdog_ops ds1388_wdt_ops = {
  1432. .owner = THIS_MODULE,
  1433. .start = ds1388_wdt_start,
  1434. .stop = ds1388_wdt_stop,
  1435. .ping = ds1388_wdt_ping,
  1436. .set_timeout = ds1388_wdt_set_timeout,
  1437. };
  1438. static void ds1307_wdt_register(struct ds1307 *ds1307)
  1439. {
  1440. struct watchdog_device *wdt;
  1441. int err;
  1442. int val;
  1443. if (ds1307->type != ds_1388)
  1444. return;
  1445. wdt = devm_kzalloc(ds1307->dev, sizeof(*wdt), GFP_KERNEL);
  1446. if (!wdt)
  1447. return;
  1448. err = regmap_read(ds1307->regmap, DS1388_REG_FLAG, &val);
  1449. if (!err && val & DS1388_BIT_WF)
  1450. wdt->bootstatus = WDIOF_CARDRESET;
  1451. wdt->info = &ds1388_wdt_info;
  1452. wdt->ops = &ds1388_wdt_ops;
  1453. wdt->timeout = 99;
  1454. wdt->max_timeout = 99;
  1455. wdt->min_timeout = 1;
  1456. watchdog_init_timeout(wdt, 0, ds1307->dev);
  1457. watchdog_set_drvdata(wdt, ds1307);
  1458. devm_watchdog_register_device(ds1307->dev, wdt);
  1459. }
  1460. #else
  1461. static void ds1307_wdt_register(struct ds1307 *ds1307)
  1462. {
  1463. }
  1464. #endif /* CONFIG_WATCHDOG_CORE */
  1465. static const struct regmap_config regmap_config = {
  1466. .reg_bits = 8,
  1467. .val_bits = 8,
  1468. };
  1469. static int ds1307_probe(struct i2c_client *client)
  1470. {
  1471. const struct i2c_device_id *id = i2c_client_get_device_id(client);
  1472. struct ds1307 *ds1307;
  1473. const void *match;
  1474. int err = -ENODEV;
  1475. int tmp;
  1476. const struct chip_desc *chip;
  1477. bool want_irq;
  1478. bool ds1307_can_wakeup_device = false;
  1479. unsigned char regs[8];
  1480. struct ds1307_platform_data *pdata = dev_get_platdata(&client->dev);
  1481. u8 trickle_charger_setup = 0;
  1482. ds1307 = devm_kzalloc(&client->dev, sizeof(struct ds1307), GFP_KERNEL);
  1483. if (!ds1307)
  1484. return -ENOMEM;
  1485. dev_set_drvdata(&client->dev, ds1307);
  1486. ds1307->dev = &client->dev;
  1487. ds1307->name = client->name;
  1488. ds1307->regmap = devm_regmap_init_i2c(client, &regmap_config);
  1489. if (IS_ERR(ds1307->regmap)) {
  1490. dev_err(ds1307->dev, "regmap allocation failed\n");
  1491. return PTR_ERR(ds1307->regmap);
  1492. }
  1493. i2c_set_clientdata(client, ds1307);
  1494. match = device_get_match_data(&client->dev);
  1495. if (match) {
  1496. ds1307->type = (uintptr_t)match;
  1497. chip = &chips[ds1307->type];
  1498. } else if (id) {
  1499. chip = &chips[id->driver_data];
  1500. ds1307->type = id->driver_data;
  1501. } else {
  1502. return -ENODEV;
  1503. }
  1504. want_irq = client->irq > 0 && chip->alarm;
  1505. if (!pdata)
  1506. trickle_charger_setup = ds1307_trickle_init(ds1307, chip);
  1507. else if (pdata->trickle_charger_setup)
  1508. trickle_charger_setup = pdata->trickle_charger_setup;
  1509. if (trickle_charger_setup && chip->trickle_charger_reg) {
  1510. dev_dbg(ds1307->dev,
  1511. "writing trickle charger info 0x%x to 0x%x\n",
  1512. trickle_charger_setup, chip->trickle_charger_reg);
  1513. regmap_write(ds1307->regmap, chip->trickle_charger_reg,
  1514. trickle_charger_setup);
  1515. }
  1516. /*
  1517. * For devices with no IRQ directly connected to the SoC, the RTC chip
  1518. * can be forced as a wakeup source by stating that explicitly in
  1519. * the device's .dts file using the "wakeup-source" boolean property.
  1520. * If the "wakeup-source" property is set, don't request an IRQ.
  1521. * This will guarantee the 'wakealarm' sysfs entry is available on the device,
  1522. * if supported by the RTC.
  1523. */
  1524. if (chip->alarm && device_property_read_bool(&client->dev, "wakeup-source"))
  1525. ds1307_can_wakeup_device = true;
  1526. switch (ds1307->type) {
  1527. case ds_1337:
  1528. case ds_1339:
  1529. case ds_1341:
  1530. case ds_3231:
  1531. /* get registers that the "rtc" read below won't read... */
  1532. err = regmap_bulk_read(ds1307->regmap, DS1337_REG_CONTROL,
  1533. regs, 2);
  1534. if (err) {
  1535. dev_dbg(ds1307->dev, "read error %d\n", err);
  1536. goto exit;
  1537. }
  1538. /* oscillator off? turn it on, so clock can tick. */
  1539. if (regs[0] & DS1337_BIT_nEOSC)
  1540. regs[0] &= ~DS1337_BIT_nEOSC;
  1541. /*
  1542. * Using IRQ or defined as wakeup-source?
  1543. * Disable the square wave and both alarms.
  1544. * For some variants, be sure alarms can trigger when we're
  1545. * running on Vbackup (BBSQI/BBSQW)
  1546. */
  1547. if (want_irq || ds1307_can_wakeup_device)
  1548. regs[0] |= DS1337_BIT_INTCN | chip->bbsqi_bit;
  1549. regmap_write(ds1307->regmap, DS1337_REG_CONTROL,
  1550. regs[0]);
  1551. /* oscillator fault? warn */
  1552. if (regs[1] & DS1337_BIT_OSF) {
  1553. dev_warn(ds1307->dev, "SET TIME!\n");
  1554. }
  1555. break;
  1556. case rx_8025:
  1557. err = regmap_bulk_read(ds1307->regmap,
  1558. RX8025_REG_CTRL1 << 4 | 0x08, regs, 2);
  1559. if (err) {
  1560. dev_dbg(ds1307->dev, "read error %d\n", err);
  1561. goto exit;
  1562. }
  1563. /* oscillator off? turn it on, so clock can tick. */
  1564. if (!(regs[1] & RX8025_BIT_XST)) {
  1565. regs[1] |= RX8025_BIT_XST;
  1566. regmap_write(ds1307->regmap,
  1567. RX8025_REG_CTRL2 << 4 | 0x08,
  1568. regs[1]);
  1569. dev_warn(ds1307->dev,
  1570. "oscillator stop detected - SET TIME!\n");
  1571. }
  1572. if (regs[1] & RX8025_BIT_PON) {
  1573. regs[1] &= ~RX8025_BIT_PON;
  1574. regmap_write(ds1307->regmap,
  1575. RX8025_REG_CTRL2 << 4 | 0x08,
  1576. regs[1]);
  1577. dev_warn(ds1307->dev, "power-on detected\n");
  1578. }
  1579. if (regs[1] & RX8025_BIT_VDET) {
  1580. regs[1] &= ~RX8025_BIT_VDET;
  1581. regmap_write(ds1307->regmap,
  1582. RX8025_REG_CTRL2 << 4 | 0x08,
  1583. regs[1]);
  1584. dev_warn(ds1307->dev, "voltage drop detected\n");
  1585. }
  1586. /* make sure we are running in 24hour mode */
  1587. if (!(regs[0] & RX8025_BIT_2412)) {
  1588. u8 hour;
  1589. /* switch to 24 hour mode */
  1590. regmap_write(ds1307->regmap,
  1591. RX8025_REG_CTRL1 << 4 | 0x08,
  1592. regs[0] | RX8025_BIT_2412);
  1593. err = regmap_bulk_read(ds1307->regmap,
  1594. RX8025_REG_CTRL1 << 4 | 0x08,
  1595. regs, 2);
  1596. if (err) {
  1597. dev_dbg(ds1307->dev, "read error %d\n", err);
  1598. goto exit;
  1599. }
  1600. /* correct hour */
  1601. hour = bcd2bin(regs[DS1307_REG_HOUR]);
  1602. if (hour == 12)
  1603. hour = 0;
  1604. if (regs[DS1307_REG_HOUR] & DS1307_BIT_PM)
  1605. hour += 12;
  1606. regmap_write(ds1307->regmap,
  1607. DS1307_REG_HOUR << 4 | 0x08, hour);
  1608. }
  1609. break;
  1610. case ds_1388:
  1611. err = regmap_read(ds1307->regmap, DS1388_REG_CONTROL, &tmp);
  1612. if (err) {
  1613. dev_dbg(ds1307->dev, "read error %d\n", err);
  1614. goto exit;
  1615. }
  1616. /* oscillator off? turn it on, so clock can tick. */
  1617. if (tmp & DS1388_BIT_nEOSC) {
  1618. tmp &= ~DS1388_BIT_nEOSC;
  1619. regmap_write(ds1307->regmap, DS1388_REG_CONTROL, tmp);
  1620. }
  1621. break;
  1622. default:
  1623. break;
  1624. }
  1625. /* read RTC registers */
  1626. err = regmap_bulk_read(ds1307->regmap, chip->offset, regs,
  1627. sizeof(regs));
  1628. if (err) {
  1629. dev_dbg(ds1307->dev, "read error %d\n", err);
  1630. goto exit;
  1631. }
  1632. if (ds1307->type == mcp794xx &&
  1633. !(regs[DS1307_REG_WDAY] & MCP794XX_BIT_VBATEN)) {
  1634. regmap_write(ds1307->regmap, DS1307_REG_WDAY,
  1635. regs[DS1307_REG_WDAY] |
  1636. MCP794XX_BIT_VBATEN);
  1637. }
  1638. tmp = regs[DS1307_REG_HOUR];
  1639. switch (ds1307->type) {
  1640. case ds_1340:
  1641. case m41t0:
  1642. case m41t00:
  1643. case m41t11:
  1644. /*
  1645. * NOTE: ignores century bits; fix before deploying
  1646. * systems that will run through year 2100.
  1647. */
  1648. break;
  1649. case rx_8025:
  1650. break;
  1651. default:
  1652. if (!(tmp & DS1307_BIT_12HR))
  1653. break;
  1654. /*
  1655. * Be sure we're in 24 hour mode. Multi-master systems
  1656. * take note...
  1657. */
  1658. tmp = bcd2bin(tmp & 0x1f);
  1659. if (tmp == 12)
  1660. tmp = 0;
  1661. if (regs[DS1307_REG_HOUR] & DS1307_BIT_PM)
  1662. tmp += 12;
  1663. regmap_write(ds1307->regmap, chip->offset + DS1307_REG_HOUR,
  1664. bin2bcd(tmp));
  1665. }
  1666. ds1307->rtc = devm_rtc_allocate_device(ds1307->dev);
  1667. if (IS_ERR(ds1307->rtc))
  1668. return PTR_ERR(ds1307->rtc);
  1669. if (want_irq || ds1307_can_wakeup_device)
  1670. device_set_wakeup_capable(ds1307->dev, true);
  1671. else
  1672. clear_bit(RTC_FEATURE_ALARM, ds1307->rtc->features);
  1673. if (ds1307_can_wakeup_device && !want_irq) {
  1674. dev_info(ds1307->dev,
  1675. "'wakeup-source' is set, request for an IRQ is disabled!\n");
  1676. /* We cannot support UIE mode if we do not have an IRQ line */
  1677. clear_bit(RTC_FEATURE_UPDATE_INTERRUPT, ds1307->rtc->features);
  1678. }
  1679. if (want_irq) {
  1680. err = devm_request_threaded_irq(ds1307->dev, client->irq, NULL,
  1681. chip->irq_handler ?: ds1307_irq,
  1682. IRQF_SHARED | IRQF_ONESHOT,
  1683. ds1307->name, ds1307);
  1684. if (err) {
  1685. client->irq = 0;
  1686. device_set_wakeup_capable(ds1307->dev, false);
  1687. clear_bit(RTC_FEATURE_ALARM, ds1307->rtc->features);
  1688. dev_err(ds1307->dev, "unable to request IRQ!\n");
  1689. } else {
  1690. dev_dbg(ds1307->dev, "got IRQ %d\n", client->irq);
  1691. }
  1692. }
  1693. ds1307->rtc->ops = chip->rtc_ops ?: &ds13xx_rtc_ops;
  1694. err = ds1307_add_frequency_test(ds1307);
  1695. if (err)
  1696. return err;
  1697. err = devm_rtc_register_device(ds1307->rtc);
  1698. if (err)
  1699. return err;
  1700. if (chip->nvram_size) {
  1701. struct nvmem_config nvmem_cfg = {
  1702. .name = "ds1307_nvram",
  1703. .word_size = 1,
  1704. .stride = 1,
  1705. .size = chip->nvram_size,
  1706. .reg_read = ds1307_nvram_read,
  1707. .reg_write = ds1307_nvram_write,
  1708. .priv = ds1307,
  1709. };
  1710. devm_rtc_nvmem_register(ds1307->rtc, &nvmem_cfg);
  1711. }
  1712. ds1307_hwmon_register(ds1307);
  1713. ds1307_clks_register(ds1307);
  1714. ds1307_wdt_register(ds1307);
  1715. return 0;
  1716. exit:
  1717. return err;
  1718. }
  1719. static struct i2c_driver ds1307_driver = {
  1720. .driver = {
  1721. .name = "rtc-ds1307",
  1722. .of_match_table = ds1307_of_match,
  1723. },
  1724. .probe = ds1307_probe,
  1725. .id_table = ds1307_id,
  1726. };
  1727. module_i2c_driver(ds1307_driver);
  1728. MODULE_DESCRIPTION("RTC driver for DS1307 and similar chips");
  1729. MODULE_LICENSE("GPL");