acpi_tad.c 16 KB

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  1. // SPDX-License-Identifier: GPL-2.0
  2. /*
  3. * ACPI Time and Alarm (TAD) Device Driver
  4. *
  5. * Copyright (C) 2018 Intel Corporation
  6. * Author: Rafael J. Wysocki <rafael.j.wysocki@intel.com>
  7. *
  8. * This driver is based on Section 9.18 of the ACPI 6.2 specification revision.
  9. *
  10. * It only supports the system wakeup capabilities of the TAD.
  11. *
  12. * Provided are sysfs attributes, available under the TAD platform device,
  13. * allowing user space to manage the AC and DC wakeup timers of the TAD:
  14. * set and read their values, set and check their expire timer wake policies,
  15. * check and clear their status and check the capabilities of the TAD reported
  16. * by AML. The DC timer attributes are only present if the TAD supports a
  17. * separate DC alarm timer.
  18. *
  19. * The wakeup events handling and power management of the TAD is expected to
  20. * be taken care of by the ACPI PM domain attached to its platform device.
  21. */
  22. #include <linux/acpi.h>
  23. #include <linux/kernel.h>
  24. #include <linux/module.h>
  25. #include <linux/platform_device.h>
  26. #include <linux/pm_runtime.h>
  27. #include <linux/suspend.h>
  28. MODULE_DESCRIPTION("ACPI Time and Alarm (TAD) Device Driver");
  29. MODULE_LICENSE("GPL v2");
  30. MODULE_AUTHOR("Rafael J. Wysocki");
  31. /* ACPI TAD capability flags (ACPI 6.2, Section 9.18.2) */
  32. #define ACPI_TAD_AC_WAKE BIT(0)
  33. #define ACPI_TAD_DC_WAKE BIT(1)
  34. #define ACPI_TAD_RT BIT(2)
  35. #define ACPI_TAD_RT_IN_MS BIT(3)
  36. #define ACPI_TAD_S4_S5__GWS BIT(4)
  37. #define ACPI_TAD_AC_S4_WAKE BIT(5)
  38. #define ACPI_TAD_AC_S5_WAKE BIT(6)
  39. #define ACPI_TAD_DC_S4_WAKE BIT(7)
  40. #define ACPI_TAD_DC_S5_WAKE BIT(8)
  41. /* ACPI TAD alarm timer selection */
  42. #define ACPI_TAD_AC_TIMER (u32)0
  43. #define ACPI_TAD_DC_TIMER (u32)1
  44. /* Special value for disabled timer or expired timer wake policy. */
  45. #define ACPI_TAD_WAKE_DISABLED (~(u32)0)
  46. struct acpi_tad_driver_data {
  47. u32 capabilities;
  48. };
  49. struct acpi_tad_rt {
  50. u16 year; /* 1900 - 9999 */
  51. u8 month; /* 1 - 12 */
  52. u8 day; /* 1 - 31 */
  53. u8 hour; /* 0 - 23 */
  54. u8 minute; /* 0 - 59 */
  55. u8 second; /* 0 - 59 */
  56. u8 valid; /* 0 (failed) or 1 (success) for reads, 0 for writes */
  57. u16 msec; /* 1 - 1000 */
  58. s16 tz; /* -1440 to 1440 or 2047 (unspecified) */
  59. u8 daylight;
  60. u8 padding[3]; /* must be 0 */
  61. } __packed;
  62. static int acpi_tad_set_real_time(struct device *dev, struct acpi_tad_rt *rt)
  63. {
  64. acpi_handle handle = ACPI_HANDLE(dev);
  65. union acpi_object args[] = {
  66. { .type = ACPI_TYPE_BUFFER, },
  67. };
  68. struct acpi_object_list arg_list = {
  69. .pointer = args,
  70. .count = ARRAY_SIZE(args),
  71. };
  72. unsigned long long retval;
  73. acpi_status status;
  74. if (rt->year < 1900 || rt->year > 9999 ||
  75. rt->month < 1 || rt->month > 12 ||
  76. rt->hour > 23 || rt->minute > 59 || rt->second > 59 ||
  77. rt->tz < -1440 || (rt->tz > 1440 && rt->tz != 2047) ||
  78. rt->daylight > 3)
  79. return -ERANGE;
  80. args[0].buffer.pointer = (u8 *)rt;
  81. args[0].buffer.length = sizeof(*rt);
  82. PM_RUNTIME_ACQUIRE(dev, pm);
  83. if (PM_RUNTIME_ACQUIRE_ERR(&pm))
  84. return -ENXIO;
  85. status = acpi_evaluate_integer(handle, "_SRT", &arg_list, &retval);
  86. if (ACPI_FAILURE(status) || retval)
  87. return -EIO;
  88. return 0;
  89. }
  90. static int acpi_tad_evaluate_grt(struct device *dev, struct acpi_tad_rt *rt)
  91. {
  92. acpi_handle handle = ACPI_HANDLE(dev);
  93. struct acpi_buffer output = { ACPI_ALLOCATE_BUFFER };
  94. union acpi_object *out_obj;
  95. struct acpi_tad_rt *data;
  96. acpi_status status;
  97. int ret = -EIO;
  98. status = acpi_evaluate_object(handle, "_GRT", NULL, &output);
  99. if (ACPI_FAILURE(status))
  100. goto out_free;
  101. out_obj = output.pointer;
  102. if (out_obj->type != ACPI_TYPE_BUFFER)
  103. goto out_free;
  104. if (out_obj->buffer.length != sizeof(*rt))
  105. goto out_free;
  106. data = (struct acpi_tad_rt *)(out_obj->buffer.pointer);
  107. if (!data->valid)
  108. goto out_free;
  109. memcpy(rt, data, sizeof(*rt));
  110. ret = 0;
  111. out_free:
  112. ACPI_FREE(output.pointer);
  113. return ret;
  114. }
  115. static int acpi_tad_get_real_time(struct device *dev, struct acpi_tad_rt *rt)
  116. {
  117. int ret;
  118. PM_RUNTIME_ACQUIRE(dev, pm);
  119. if (PM_RUNTIME_ACQUIRE_ERR(&pm))
  120. return -ENXIO;
  121. ret = acpi_tad_evaluate_grt(dev, rt);
  122. if (ret)
  123. return ret;
  124. return 0;
  125. }
  126. static char *acpi_tad_rt_next_field(char *s, int *val)
  127. {
  128. char *p;
  129. p = strchr(s, ':');
  130. if (!p)
  131. return NULL;
  132. *p = '\0';
  133. if (kstrtoint(s, 10, val))
  134. return NULL;
  135. return p + 1;
  136. }
  137. static ssize_t time_store(struct device *dev, struct device_attribute *attr,
  138. const char *buf, size_t count)
  139. {
  140. struct acpi_tad_rt rt;
  141. char *str, *s;
  142. int val, ret = -ENODATA;
  143. str = kmemdup_nul(buf, count, GFP_KERNEL);
  144. if (!str)
  145. return -ENOMEM;
  146. s = acpi_tad_rt_next_field(str, &val);
  147. if (!s)
  148. goto out_free;
  149. rt.year = val;
  150. s = acpi_tad_rt_next_field(s, &val);
  151. if (!s)
  152. goto out_free;
  153. rt.month = val;
  154. s = acpi_tad_rt_next_field(s, &val);
  155. if (!s)
  156. goto out_free;
  157. rt.day = val;
  158. s = acpi_tad_rt_next_field(s, &val);
  159. if (!s)
  160. goto out_free;
  161. rt.hour = val;
  162. s = acpi_tad_rt_next_field(s, &val);
  163. if (!s)
  164. goto out_free;
  165. rt.minute = val;
  166. s = acpi_tad_rt_next_field(s, &val);
  167. if (!s)
  168. goto out_free;
  169. rt.second = val;
  170. s = acpi_tad_rt_next_field(s, &val);
  171. if (!s)
  172. goto out_free;
  173. rt.tz = val;
  174. if (kstrtoint(s, 10, &val))
  175. goto out_free;
  176. rt.daylight = val;
  177. rt.valid = 0;
  178. rt.msec = 0;
  179. memset(rt.padding, 0, 3);
  180. ret = acpi_tad_set_real_time(dev, &rt);
  181. out_free:
  182. kfree(str);
  183. return ret ? ret : count;
  184. }
  185. static ssize_t time_show(struct device *dev, struct device_attribute *attr,
  186. char *buf)
  187. {
  188. struct acpi_tad_rt rt;
  189. int ret;
  190. ret = acpi_tad_get_real_time(dev, &rt);
  191. if (ret)
  192. return ret;
  193. return sysfs_emit(buf, "%u:%u:%u:%u:%u:%u:%d:%u\n",
  194. rt.year, rt.month, rt.day, rt.hour, rt.minute, rt.second,
  195. rt.tz, rt.daylight);
  196. }
  197. static DEVICE_ATTR_RW(time);
  198. static struct attribute *acpi_tad_time_attrs[] = {
  199. &dev_attr_time.attr,
  200. NULL,
  201. };
  202. static const struct attribute_group acpi_tad_time_attr_group = {
  203. .attrs = acpi_tad_time_attrs,
  204. };
  205. static int acpi_tad_wake_set(struct device *dev, char *method, u32 timer_id,
  206. u32 value)
  207. {
  208. acpi_handle handle = ACPI_HANDLE(dev);
  209. union acpi_object args[] = {
  210. { .type = ACPI_TYPE_INTEGER, },
  211. { .type = ACPI_TYPE_INTEGER, },
  212. };
  213. struct acpi_object_list arg_list = {
  214. .pointer = args,
  215. .count = ARRAY_SIZE(args),
  216. };
  217. unsigned long long retval;
  218. acpi_status status;
  219. args[0].integer.value = timer_id;
  220. args[1].integer.value = value;
  221. PM_RUNTIME_ACQUIRE(dev, pm);
  222. if (PM_RUNTIME_ACQUIRE_ERR(&pm))
  223. return -ENXIO;
  224. status = acpi_evaluate_integer(handle, method, &arg_list, &retval);
  225. if (ACPI_FAILURE(status) || retval)
  226. return -EIO;
  227. return 0;
  228. }
  229. static int acpi_tad_wake_write(struct device *dev, const char *buf, char *method,
  230. u32 timer_id, const char *specval)
  231. {
  232. u32 value;
  233. if (sysfs_streq(buf, specval)) {
  234. value = ACPI_TAD_WAKE_DISABLED;
  235. } else {
  236. int ret = kstrtou32(buf, 0, &value);
  237. if (ret)
  238. return ret;
  239. if (value == ACPI_TAD_WAKE_DISABLED)
  240. return -EINVAL;
  241. }
  242. return acpi_tad_wake_set(dev, method, timer_id, value);
  243. }
  244. static ssize_t acpi_tad_wake_read(struct device *dev, char *buf, char *method,
  245. u32 timer_id, const char *specval)
  246. {
  247. acpi_handle handle = ACPI_HANDLE(dev);
  248. union acpi_object args[] = {
  249. { .type = ACPI_TYPE_INTEGER, },
  250. };
  251. struct acpi_object_list arg_list = {
  252. .pointer = args,
  253. .count = ARRAY_SIZE(args),
  254. };
  255. unsigned long long retval;
  256. acpi_status status;
  257. args[0].integer.value = timer_id;
  258. PM_RUNTIME_ACQUIRE(dev, pm);
  259. if (PM_RUNTIME_ACQUIRE_ERR(&pm))
  260. return -ENXIO;
  261. status = acpi_evaluate_integer(handle, method, &arg_list, &retval);
  262. if (ACPI_FAILURE(status))
  263. return -EIO;
  264. if ((u32)retval == ACPI_TAD_WAKE_DISABLED)
  265. return sprintf(buf, "%s\n", specval);
  266. return sprintf(buf, "%u\n", (u32)retval);
  267. }
  268. static const char *alarm_specval = "disabled";
  269. static int acpi_tad_alarm_write(struct device *dev, const char *buf,
  270. u32 timer_id)
  271. {
  272. return acpi_tad_wake_write(dev, buf, "_STV", timer_id, alarm_specval);
  273. }
  274. static ssize_t acpi_tad_alarm_read(struct device *dev, char *buf, u32 timer_id)
  275. {
  276. return acpi_tad_wake_read(dev, buf, "_TIV", timer_id, alarm_specval);
  277. }
  278. static const char *policy_specval = "never";
  279. static int acpi_tad_policy_write(struct device *dev, const char *buf,
  280. u32 timer_id)
  281. {
  282. return acpi_tad_wake_write(dev, buf, "_STP", timer_id, policy_specval);
  283. }
  284. static ssize_t acpi_tad_policy_read(struct device *dev, char *buf, u32 timer_id)
  285. {
  286. return acpi_tad_wake_read(dev, buf, "_TIP", timer_id, policy_specval);
  287. }
  288. static int acpi_tad_clear_status(struct device *dev, u32 timer_id)
  289. {
  290. acpi_handle handle = ACPI_HANDLE(dev);
  291. union acpi_object args[] = {
  292. { .type = ACPI_TYPE_INTEGER, },
  293. };
  294. struct acpi_object_list arg_list = {
  295. .pointer = args,
  296. .count = ARRAY_SIZE(args),
  297. };
  298. unsigned long long retval;
  299. acpi_status status;
  300. args[0].integer.value = timer_id;
  301. PM_RUNTIME_ACQUIRE(dev, pm);
  302. if (PM_RUNTIME_ACQUIRE_ERR(&pm))
  303. return -ENXIO;
  304. status = acpi_evaluate_integer(handle, "_CWS", &arg_list, &retval);
  305. if (ACPI_FAILURE(status) || retval)
  306. return -EIO;
  307. return 0;
  308. }
  309. static int acpi_tad_status_write(struct device *dev, const char *buf, u32 timer_id)
  310. {
  311. int ret, value;
  312. ret = kstrtoint(buf, 0, &value);
  313. if (ret)
  314. return ret;
  315. if (value)
  316. return -EINVAL;
  317. return acpi_tad_clear_status(dev, timer_id);
  318. }
  319. static ssize_t acpi_tad_status_read(struct device *dev, char *buf, u32 timer_id)
  320. {
  321. acpi_handle handle = ACPI_HANDLE(dev);
  322. union acpi_object args[] = {
  323. { .type = ACPI_TYPE_INTEGER, },
  324. };
  325. struct acpi_object_list arg_list = {
  326. .pointer = args,
  327. .count = ARRAY_SIZE(args),
  328. };
  329. unsigned long long retval;
  330. acpi_status status;
  331. args[0].integer.value = timer_id;
  332. PM_RUNTIME_ACQUIRE(dev, pm);
  333. if (PM_RUNTIME_ACQUIRE_ERR(&pm))
  334. return -ENXIO;
  335. status = acpi_evaluate_integer(handle, "_GWS", &arg_list, &retval);
  336. if (ACPI_FAILURE(status))
  337. return -EIO;
  338. return sprintf(buf, "0x%02X\n", (u32)retval);
  339. }
  340. static ssize_t caps_show(struct device *dev, struct device_attribute *attr,
  341. char *buf)
  342. {
  343. struct acpi_tad_driver_data *dd = dev_get_drvdata(dev);
  344. return sysfs_emit(buf, "0x%02X\n", dd->capabilities);
  345. }
  346. static DEVICE_ATTR_RO(caps);
  347. static ssize_t ac_alarm_store(struct device *dev, struct device_attribute *attr,
  348. const char *buf, size_t count)
  349. {
  350. int ret = acpi_tad_alarm_write(dev, buf, ACPI_TAD_AC_TIMER);
  351. return ret ? ret : count;
  352. }
  353. static ssize_t ac_alarm_show(struct device *dev, struct device_attribute *attr,
  354. char *buf)
  355. {
  356. return acpi_tad_alarm_read(dev, buf, ACPI_TAD_AC_TIMER);
  357. }
  358. static DEVICE_ATTR_RW(ac_alarm);
  359. static ssize_t ac_policy_store(struct device *dev, struct device_attribute *attr,
  360. const char *buf, size_t count)
  361. {
  362. int ret = acpi_tad_policy_write(dev, buf, ACPI_TAD_AC_TIMER);
  363. return ret ? ret : count;
  364. }
  365. static ssize_t ac_policy_show(struct device *dev, struct device_attribute *attr,
  366. char *buf)
  367. {
  368. return acpi_tad_policy_read(dev, buf, ACPI_TAD_AC_TIMER);
  369. }
  370. static DEVICE_ATTR_RW(ac_policy);
  371. static ssize_t ac_status_store(struct device *dev, struct device_attribute *attr,
  372. const char *buf, size_t count)
  373. {
  374. int ret = acpi_tad_status_write(dev, buf, ACPI_TAD_AC_TIMER);
  375. return ret ? ret : count;
  376. }
  377. static ssize_t ac_status_show(struct device *dev, struct device_attribute *attr,
  378. char *buf)
  379. {
  380. return acpi_tad_status_read(dev, buf, ACPI_TAD_AC_TIMER);
  381. }
  382. static DEVICE_ATTR_RW(ac_status);
  383. static struct attribute *acpi_tad_attrs[] = {
  384. &dev_attr_caps.attr,
  385. &dev_attr_ac_alarm.attr,
  386. &dev_attr_ac_policy.attr,
  387. &dev_attr_ac_status.attr,
  388. NULL,
  389. };
  390. static const struct attribute_group acpi_tad_attr_group = {
  391. .attrs = acpi_tad_attrs,
  392. };
  393. static ssize_t dc_alarm_store(struct device *dev, struct device_attribute *attr,
  394. const char *buf, size_t count)
  395. {
  396. int ret = acpi_tad_alarm_write(dev, buf, ACPI_TAD_DC_TIMER);
  397. return ret ? ret : count;
  398. }
  399. static ssize_t dc_alarm_show(struct device *dev, struct device_attribute *attr,
  400. char *buf)
  401. {
  402. return acpi_tad_alarm_read(dev, buf, ACPI_TAD_DC_TIMER);
  403. }
  404. static DEVICE_ATTR_RW(dc_alarm);
  405. static ssize_t dc_policy_store(struct device *dev, struct device_attribute *attr,
  406. const char *buf, size_t count)
  407. {
  408. int ret = acpi_tad_policy_write(dev, buf, ACPI_TAD_DC_TIMER);
  409. return ret ? ret : count;
  410. }
  411. static ssize_t dc_policy_show(struct device *dev, struct device_attribute *attr,
  412. char *buf)
  413. {
  414. return acpi_tad_policy_read(dev, buf, ACPI_TAD_DC_TIMER);
  415. }
  416. static DEVICE_ATTR_RW(dc_policy);
  417. static ssize_t dc_status_store(struct device *dev, struct device_attribute *attr,
  418. const char *buf, size_t count)
  419. {
  420. int ret = acpi_tad_status_write(dev, buf, ACPI_TAD_DC_TIMER);
  421. return ret ? ret : count;
  422. }
  423. static ssize_t dc_status_show(struct device *dev, struct device_attribute *attr,
  424. char *buf)
  425. {
  426. return acpi_tad_status_read(dev, buf, ACPI_TAD_DC_TIMER);
  427. }
  428. static DEVICE_ATTR_RW(dc_status);
  429. static struct attribute *acpi_tad_dc_attrs[] = {
  430. &dev_attr_dc_alarm.attr,
  431. &dev_attr_dc_policy.attr,
  432. &dev_attr_dc_status.attr,
  433. NULL,
  434. };
  435. static const struct attribute_group acpi_tad_dc_attr_group = {
  436. .attrs = acpi_tad_dc_attrs,
  437. };
  438. static int acpi_tad_disable_timer(struct device *dev, u32 timer_id)
  439. {
  440. return acpi_tad_wake_set(dev, "_STV", timer_id, ACPI_TAD_WAKE_DISABLED);
  441. }
  442. static void acpi_tad_remove(struct platform_device *pdev)
  443. {
  444. struct device *dev = &pdev->dev;
  445. acpi_handle handle = ACPI_HANDLE(dev);
  446. struct acpi_tad_driver_data *dd = dev_get_drvdata(dev);
  447. device_init_wakeup(dev, false);
  448. if (dd->capabilities & ACPI_TAD_RT)
  449. sysfs_remove_group(&dev->kobj, &acpi_tad_time_attr_group);
  450. if (dd->capabilities & ACPI_TAD_DC_WAKE)
  451. sysfs_remove_group(&dev->kobj, &acpi_tad_dc_attr_group);
  452. sysfs_remove_group(&dev->kobj, &acpi_tad_attr_group);
  453. scoped_guard(pm_runtime_noresume, dev) {
  454. acpi_tad_disable_timer(dev, ACPI_TAD_AC_TIMER);
  455. acpi_tad_clear_status(dev, ACPI_TAD_AC_TIMER);
  456. if (dd->capabilities & ACPI_TAD_DC_WAKE) {
  457. acpi_tad_disable_timer(dev, ACPI_TAD_DC_TIMER);
  458. acpi_tad_clear_status(dev, ACPI_TAD_DC_TIMER);
  459. }
  460. }
  461. pm_runtime_suspend(dev);
  462. pm_runtime_disable(dev);
  463. acpi_remove_cmos_rtc_space_handler(handle);
  464. }
  465. static int acpi_tad_probe(struct platform_device *pdev)
  466. {
  467. struct device *dev = &pdev->dev;
  468. acpi_handle handle = ACPI_HANDLE(dev);
  469. struct acpi_tad_driver_data *dd;
  470. acpi_status status;
  471. unsigned long long caps;
  472. int ret;
  473. ret = acpi_install_cmos_rtc_space_handler(handle);
  474. if (ret < 0) {
  475. dev_info(dev, "Unable to install space handler\n");
  476. return -ENODEV;
  477. }
  478. /*
  479. * Initialization failure messages are mostly about firmware issues, so
  480. * print them at the "info" level.
  481. */
  482. status = acpi_evaluate_integer(handle, "_GCP", NULL, &caps);
  483. if (ACPI_FAILURE(status)) {
  484. dev_info(dev, "Unable to get capabilities\n");
  485. ret = -ENODEV;
  486. goto remove_handler;
  487. }
  488. if (!(caps & ACPI_TAD_AC_WAKE)) {
  489. dev_info(dev, "Unsupported capabilities\n");
  490. ret = -ENODEV;
  491. goto remove_handler;
  492. }
  493. if (!acpi_has_method(handle, "_PRW")) {
  494. dev_info(dev, "Missing _PRW\n");
  495. ret = -ENODEV;
  496. goto remove_handler;
  497. }
  498. dd = devm_kzalloc(dev, sizeof(*dd), GFP_KERNEL);
  499. if (!dd) {
  500. ret = -ENOMEM;
  501. goto remove_handler;
  502. }
  503. dd->capabilities = caps;
  504. dev_set_drvdata(dev, dd);
  505. /*
  506. * Assume that the ACPI PM domain has been attached to the device and
  507. * simply enable system wakeup and runtime PM and put the device into
  508. * runtime suspend. Everything else should be taken care of by the ACPI
  509. * PM domain callbacks.
  510. */
  511. device_init_wakeup(dev, true);
  512. dev_pm_set_driver_flags(dev, DPM_FLAG_SMART_SUSPEND |
  513. DPM_FLAG_MAY_SKIP_RESUME);
  514. /*
  515. * The platform bus type layer tells the ACPI PM domain powers up the
  516. * device, so set the runtime PM status of it to "active".
  517. */
  518. pm_runtime_set_active(dev);
  519. pm_runtime_enable(dev);
  520. pm_runtime_suspend(dev);
  521. ret = sysfs_create_group(&dev->kobj, &acpi_tad_attr_group);
  522. if (ret)
  523. goto fail;
  524. if (caps & ACPI_TAD_DC_WAKE) {
  525. ret = sysfs_create_group(&dev->kobj, &acpi_tad_dc_attr_group);
  526. if (ret)
  527. goto fail;
  528. }
  529. if (caps & ACPI_TAD_RT) {
  530. ret = sysfs_create_group(&dev->kobj, &acpi_tad_time_attr_group);
  531. if (ret)
  532. goto fail;
  533. }
  534. return 0;
  535. fail:
  536. acpi_tad_remove(pdev);
  537. /* Don't fallthrough because cmos rtc space handler is removed in acpi_tad_remove() */
  538. return ret;
  539. remove_handler:
  540. acpi_remove_cmos_rtc_space_handler(handle);
  541. return ret;
  542. }
  543. static const struct acpi_device_id acpi_tad_ids[] = {
  544. {"ACPI000E", 0},
  545. {}
  546. };
  547. static struct platform_driver acpi_tad_driver = {
  548. .driver = {
  549. .name = "acpi-tad",
  550. .acpi_match_table = acpi_tad_ids,
  551. },
  552. .probe = acpi_tad_probe,
  553. .remove = acpi_tad_remove,
  554. };
  555. MODULE_DEVICE_TABLE(acpi, acpi_tad_ids);
  556. module_platform_driver(acpi_tad_driver);