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Diffstat (limited to 'sys-utils/hwclock.c')
-rw-r--r-- | sys-utils/hwclock.c | 1693 |
1 files changed, 1693 insertions, 0 deletions
diff --git a/sys-utils/hwclock.c b/sys-utils/hwclock.c new file mode 100644 index 0000000..2a18443 --- /dev/null +++ b/sys-utils/hwclock.c @@ -0,0 +1,1693 @@ +/* + * SPDX-License-Identifier: GPL-2.0-or-later + * + * Since 7a3000f7ba548cf7d74ac77cc63fe8de228a669e (v2.30) hwclock is linked + * with parse_date.y from gnullib. This gnulib code is distributed with GPLv3. + * Use --disable-hwclock-gplv3 to exclude this code. + * + * + * clock.c was written by Charles Hedrick, hedrick@cs.rutgers.edu, Apr 1992 + * Modified for clock adjustments - Rob Hooft <hooft@chem.ruu.nl>, Nov 1992 + * Improvements by Harald Koenig <koenig@nova.tat.physik.uni-tuebingen.de> + * and Alan Modra <alan@spri.levels.unisa.edu.au>. + * + * Major rewrite by Bryan Henderson <bryanh@giraffe-data.com>, 96.09.19. + * The new program is called hwclock. New features: + * + * - You can set the hardware clock without also modifying the system + * clock. + * - You can read and set the clock with finer than 1 second precision. + * - When you set the clock, hwclock automatically refigures the drift + * rate, based on how far off the clock was before you set it. + * + * Reshuffled things, added sparc code, and re-added alpha stuff + * by David Mosberger <davidm@azstarnet.com> + * and Jay Estabrook <jestabro@amt.tay1.dec.com> + * and Martin Ostermann <ost@comnets.rwth-aachen.de>, aeb@cwi.nl, 990212. + * + * Fix for Award 2094 bug, Dave Coffin (dcoffin@shore.net) 11/12/98 + * Change of local time handling, Stefan Ring <e9725446@stud3.tuwien.ac.at> + * Change of adjtime handling, James P. Rutledge <ao112@rgfn.epcc.edu>. + * + * + */ +/* + * Explanation of `adjusting' (Rob Hooft): + * + * The problem with my machine is that its CMOS clock is 10 seconds + * per day slow. With this version of clock.c, and my '/etc/rc.local' + * reading '/etc/clock -au' instead of '/etc/clock -u -s', this error + * is automatically corrected at every boot. + * + * To do this job, the program reads and writes the file '/etc/adjtime' + * to determine the correction, and to save its data. In this file are + * three numbers: + * + * 1) the correction in seconds per day. (So if your clock runs 5 + * seconds per day fast, the first number should read -5.0) + * 2) the number of seconds since 1/1/1970 the last time the program + * was used + * 3) the remaining part of a second which was leftover after the last + * adjustment + * + * Installation and use of this program: + * + * a) create a file '/etc/adjtime' containing as the first and only + * line: '0.0 0 0.0' + * b) run 'clock -au' or 'clock -a', depending on whether your cmos is + * in universal or local time. This updates the second number. + * c) set your system time using the 'date' command. + * d) update your cmos time using 'clock -wu' or 'clock -w' + * e) replace the first number in /etc/adjtime by your correction. + * f) put the command 'clock -au' or 'clock -a' in your '/etc/rc.local' + */ + +#include <errno.h> +#include <getopt.h> +#include <limits.h> +#include <math.h> +#include <stdio.h> +#include <stdlib.h> +#include <string.h> +#include <sys/stat.h> +#include <sys/time.h> +#ifdef HAVE_SYS_SYSCALL_H +#include <sys/syscall.h> +#endif +#include <time.h> +#include <unistd.h> +#include <inttypes.h> + +#include "c.h" +#include "closestream.h" +#include "nls.h" +#include "optutils.h" +#include "pathnames.h" +#include "hwclock.h" +#include "timeutils.h" +#include "env.h" +#include "xalloc.h" +#include "path.h" +#include "strutils.h" + +#ifdef HAVE_LIBAUDIT +#include <libaudit.h> +static int hwaudit_fd = -1; +#endif + +UL_DEBUG_DEFINE_MASK(hwclock); +UL_DEBUG_DEFINE_MASKNAMES(hwclock) = UL_DEBUG_EMPTY_MASKNAMES; + +/* The struct that holds our hardware access routines */ +static const struct clock_ops *ur; + +/* Maximal clock adjustment in seconds per day. + (adjtime() glibc call has 2145 seconds limit on i386, so it is good enough for us as well, + 43219 is a maximal safe value preventing exact_adjustment overflow.) */ +#define MAX_DRIFT 2145.0 + +struct adjtime { + /* + * This is information we keep in the adjtime file that tells us how + * to do drift corrections. Elements are all straight from the + * adjtime file, so see documentation of that file for details. + * Exception is <dirty>, which is an indication that what's in this + * structure is not what's in the disk file (because it has been + * updated since read from the disk file). + */ + int dirty; + /* line 1 */ + double drift_factor; + time_t last_adj_time; + double not_adjusted; + /* line 2 */ + time_t last_calib_time; + /* + * The most recent time that we set the clock from an external + * authority (as opposed to just doing a drift adjustment) + */ + /* line 3 */ + enum a_local_utc { UTC = 0, LOCAL, UNKNOWN } local_utc; + /* + * To which time zone, local or UTC, we most recently set the + * hardware clock. + */ +}; + +static void hwclock_init_debug(const char *str) +{ + __UL_INIT_DEBUG_FROM_STRING(hwclock, HWCLOCK_DEBUG_, 0, str); + + DBG(INIT, ul_debug("hwclock debug mask: 0x%04x", hwclock_debug_mask)); + DBG(INIT, ul_debug("hwclock version: %s", PACKAGE_STRING)); +} + +/* FOR TESTING ONLY: inject random delays of up to 1000ms */ +static void up_to_1000ms_sleep(void) +{ + int usec = random() % 1000000; + + DBG(RANDOM_SLEEP, ul_debug("sleeping ~%d usec", usec)); + xusleep(usec); +} + +/* + * time_t to timeval conversion. + */ +static struct timeval t2tv(time_t timet) +{ + struct timeval rettimeval; + + rettimeval.tv_sec = timet; + rettimeval.tv_usec = 0; + return rettimeval; +} + +/* + * The difference in seconds between two times in "timeval" format. + */ +double time_diff(struct timeval subtrahend, struct timeval subtractor) +{ + return (subtrahend.tv_sec - subtractor.tv_sec) + + (subtrahend.tv_usec - subtractor.tv_usec) / 1E6; +} + +/* + * The time, in "timeval" format, which is <increment> seconds after the + * time <addend>. Of course, <increment> may be negative. + */ +static struct timeval time_inc(struct timeval addend, double increment) +{ + struct timeval newtime; + + newtime.tv_sec = addend.tv_sec + (time_t)increment; + newtime.tv_usec = addend.tv_usec + (increment - (time_t)increment) * 1E6; + + /* + * Now adjust it so that the microsecond value is between 0 and 1 + * million. + */ + if (newtime.tv_usec < 0) { + newtime.tv_usec += 1E6; + newtime.tv_sec -= 1; + } else if (newtime.tv_usec >= 1E6) { + newtime.tv_usec -= 1E6; + newtime.tv_sec += 1; + } + return newtime; +} + +static int +hw_clock_is_utc(const struct hwclock_control *ctl, + const struct adjtime *adjtime) +{ + int ret; + + if (ctl->utc) + ret = 1; /* --utc explicitly given on command line */ + else if (ctl->local_opt) + ret = 0; /* --localtime explicitly given */ + else + /* get info from adjtime file - default is UTC */ + ret = (adjtime->local_utc != LOCAL); + + if (ctl->verbose) + printf(_("Assuming hardware clock is kept in %s time.\n"), + ret ? _("UTC") : _("local")); + return ret; +} + +/* + * Read the adjustment parameters out of the /etc/adjtime file. + * + * Return them as the adjtime structure <*adjtime_p>. Its defaults are + * initialized in main(). + */ +static int read_adjtime(const struct hwclock_control *ctl, + struct adjtime *adjtime_p) +{ + FILE *adjfile; + char line1[81]; /* String: first line of adjtime file */ + char line2[81]; /* String: second line of adjtime file */ + char line3[81]; /* String: third line of adjtime file */ + int64_t last_adj_time; + int64_t last_calib_time; + + if (access(ctl->adj_file_name, R_OK) != 0) + return EXIT_SUCCESS; + + adjfile = fopen(ctl->adj_file_name, "r"); /* open file for reading */ + if (adjfile == NULL) { + warn(_("cannot open %s"), ctl->adj_file_name); + return EXIT_FAILURE; + } + + if (!fgets(line1, sizeof(line1), adjfile)) + line1[0] = '\0'; /* In case fgets fails */ + if (!fgets(line2, sizeof(line2), adjfile)) + line2[0] = '\0'; /* In case fgets fails */ + if (!fgets(line3, sizeof(line3), adjfile)) + line3[0] = '\0'; /* In case fgets fails */ + + fclose(adjfile); + + if (sscanf(line1, "%lf %"SCNd64" %lf", + &adjtime_p->drift_factor, + &last_adj_time, + &adjtime_p->not_adjusted) != 3) + warnx(_("Warning: unrecognized line in adjtime file: %s"), line1); + + if (sscanf(line2, "%"SCNd64, &last_calib_time) != 1) + warnx(_("Warning: unrecognized line in adjtime file: %s"), line2); + + adjtime_p->last_adj_time = (time_t)last_adj_time; + adjtime_p->last_calib_time = (time_t)last_calib_time; + + if (!strcmp(line3, "UTC\n")) { + adjtime_p->local_utc = UTC; + } else if (!strcmp(line3, "LOCAL\n")) { + adjtime_p->local_utc = LOCAL; + } else { + adjtime_p->local_utc = UNKNOWN; + if (line3[0]) { + warnx(_("Warning: unrecognized third line in adjtime file\n" + "(Expected: `UTC' or `LOCAL' or nothing.)")); + } + } + + if (ctl->verbose) { + printf(_("Last drift adjustment done at %"PRId64" seconds after 1969\n"), + (int64_t)adjtime_p->last_adj_time); + printf(_("Last calibration done at %"PRId64" seconds after 1969\n"), + (int64_t)adjtime_p->last_calib_time); + printf(_("Hardware clock is on %s time\n"), + (adjtime_p->local_utc == + LOCAL) ? _("local") : (adjtime_p->local_utc == + UTC) ? _("UTC") : _("unknown")); + } + + return EXIT_SUCCESS; +} + +/* + * Wait until the falling edge of the Hardware Clock's update flag so that + * any time that is read from the clock immediately after we return will be + * exact. + * + * The clock only has 1 second precision, so it gives the exact time only + * once per second, right on the falling edge of the update flag. + * + * We wait (up to one second) either blocked waiting for an rtc device or in + * a CPU spin loop. The former is probably not very accurate. + * + * Return 0 if it worked, nonzero if it didn't. + */ +static int synchronize_to_clock_tick(const struct hwclock_control *ctl) +{ + int rc; + + if (ctl->verbose) + printf(_("Waiting for clock tick...\n")); + + rc = ur->synchronize_to_clock_tick(ctl); + + if (ctl->verbose) { + if (rc) + printf(_("...synchronization failed\n")); + else + printf(_("...got clock tick\n")); + } + + return rc; +} + +/* + * Convert a time in broken down format (hours, minutes, etc.) into standard + * unix time (seconds into epoch). Return it as *systime_p. + * + * The broken down time is argument <tm>. This broken down time is either + * in local time zone or UTC, depending on value of logical argument + * "universal". True means it is in UTC. + * + * If the argument contains values that do not constitute a valid time, and + * mktime() recognizes this, return *valid_p == false and *systime_p + * undefined. However, mktime() sometimes goes ahead and computes a + * fictional time "as if" the input values were valid, e.g. if they indicate + * the 31st day of April, mktime() may compute the time of May 1. In such a + * case, we return the same fictional value mktime() does as *systime_p and + * return *valid_p == true. + */ +static int +mktime_tz(const struct hwclock_control *ctl, struct tm tm, + time_t *systime_p) +{ + int valid; + + if (ctl->universal) + *systime_p = timegm(&tm); + else + *systime_p = mktime(&tm); + if (*systime_p == -1) { + /* + * This apparently (not specified in mktime() documentation) + * means the 'tm' structure does not contain valid values + * (however, not containing valid values does _not_ imply + * mktime() returns -1). + */ + valid = 0; + if (ctl->verbose) + printf(_("Invalid values in hardware clock: " + "%4d/%.2d/%.2d %.2d:%.2d:%.2d\n"), + tm.tm_year + 1900, tm.tm_mon + 1, tm.tm_mday, + tm.tm_hour, tm.tm_min, tm.tm_sec); + } else { + valid = 1; + if (ctl->verbose) + printf(_("Hw clock time : %4d/%.2d/%.2d %.2d:%.2d:%.2d = " + "%"PRId64" seconds since 1969\n"), tm.tm_year + 1900, + tm.tm_mon + 1, tm.tm_mday, tm.tm_hour, tm.tm_min, + tm.tm_sec, (int64_t)*systime_p); + } + return valid; +} + +/* + * Read the hardware clock and return the current time via <tm> argument. + * + * Use the method indicated by <method> argument to access the hardware + * clock. + */ +static int +read_hardware_clock(const struct hwclock_control *ctl, + int *valid_p, time_t *systime_p) +{ + struct tm tm = { 0 }; + int err; + + err = ur->read_hardware_clock(ctl, &tm); + if (err) + return err; + + if (ctl->verbose) + printf(_("Time read from Hardware Clock: %4d/%.2d/%.2d %02d:%02d:%02d\n"), + tm.tm_year + 1900, tm.tm_mon + 1, tm.tm_mday, tm.tm_hour, + tm.tm_min, tm.tm_sec); + *valid_p = mktime_tz(ctl, tm, systime_p); + + return 0; +} + +/* + * Set the Hardware Clock to the time <newtime>, in local time zone or UTC, + * according to <universal>. + */ +static void +set_hardware_clock(const struct hwclock_control *ctl, const time_t newtime) +{ + struct tm new_broken_time = { 0 }; + /* + * Time to which we will set Hardware Clock, in broken down format, + * in the time zone of caller's choice + */ + + if (ctl->universal) + gmtime_r(&newtime, &new_broken_time); + else + localtime_r(&newtime, &new_broken_time); + + if (ctl->verbose) + printf(_("Setting Hardware Clock to %.2d:%.2d:%.2d " + "= %"PRId64" seconds since 1969\n"), + new_broken_time.tm_hour, new_broken_time.tm_min, + new_broken_time.tm_sec, (int64_t)newtime); + + if (!ctl->testing) + ur->set_hardware_clock(ctl, &new_broken_time); +} + +static double +get_hardware_delay(const struct hwclock_control *ctl) +{ + const char *devpath, *rtcname; + char name[128 + 1]; + struct path_cxt *pc; + int rc; + + devpath = ur->get_device_path(); + if (!devpath) + goto unknown; + + rtcname = strrchr(devpath, '/'); + if (!rtcname || !*(rtcname + 1)) + goto unknown; + rtcname++; + + pc = ul_new_path("/sys/class/rtc/%s", rtcname); + if (!pc) + goto unknown; + rc = ul_path_scanf(pc, "name", "%128[^\n ]", name); + ul_unref_path(pc); + + if (rc != 1 || !*name) + goto unknown; + + if (ctl->verbose) + printf(_("RTC type: '%s'\n"), name); + + /* MC146818A-compatible (x86) */ + if (strcmp(name, "rtc_cmos") == 0) + return 0.5; + + /* Another HW */ + return 0; +unknown: + /* Let's be backwardly compatible */ + return 0.5; +} + + +/* + * Set the Hardware Clock to the time "sethwtime", in local time zone or + * UTC, according to "universal". + * + * Wait for a fraction of a second so that "sethwtime" is the value of the + * Hardware Clock as of system time "refsystime", which is in the past. For + * example, if "sethwtime" is 14:03:05 and "refsystime" is 12:10:04.5 and + * the current system time is 12:10:06.0: Wait .5 seconds (to make exactly 2 + * seconds since "refsystime") and then set the Hardware Clock to 14:03:07, + * thus getting a precise and retroactive setting of the clock. The .5 delay is + * default on x86, see --delay and get_hardware_delay(). + * + * (Don't be confused by the fact that the system clock and the Hardware + * Clock differ by two hours in the above example. That's just to remind you + * that there are two independent time scales here). + * + * This function ought to be able to accept set times as fractional times. + * Idea for future enhancement. + */ +static void +set_hardware_clock_exact(const struct hwclock_control *ctl, + const time_t sethwtime, + const struct timeval refsystime) +{ + /* + * The Hardware Clock can only be set to any integer time plus one + * half second. The integer time is required because there is no + * interface to set or get a fractional second. The additional half + * second is because the Hardware Clock updates to the following + * second precisely 500 ms (not 1 second!) after you release the + * divider reset (after setting the new time) - see description of + * DV2, DV1, DV0 in Register A in the MC146818A data sheet (and note + * that although that document doesn't say so, real-world code seems + * to expect that the SET bit in Register B functions the same way). + * That means that, e.g., when you set the clock to 1:02:03, it + * effectively really sets it to 1:02:03.5, because it will update to + * 1:02:04 only half a second later. Our caller passes the desired + * integer Hardware Clock time in sethwtime, and the corresponding + * system time (which may have a fractional part, and which may or may + * not be the same!) in refsystime. In an ideal situation, we would + * then apply sethwtime to the Hardware Clock at refsystime+500ms, so + * that when the Hardware Clock ticks forward to sethwtime+1s half a + * second later at refsystime+1000ms, everything is in sync. So we + * spin, waiting for gettimeofday() to return a time at or after that + * time (refsystime+500ms) up to a tolerance value, initially 1ms. If + * we miss that time due to being preempted for some other process, + * then we increase the margin a little bit (initially 1ms, doubling + * each time), add 1 second (or more, if needed to get a time that is + * in the future) to both the time for which we are waiting and the + * time that we will apply to the Hardware Clock, and start waiting + * again. + * + * For example, the caller requests that we set the Hardware Clock to + * 1:02:03, with reference time (current system time) = 6:07:08.250. + * We want the Hardware Clock to update to 1:02:04 at 6:07:09.250 on + * the system clock, and the first such update will occur 0.500 + * seconds after we write to the Hardware Clock, so we spin until the + * system clock reads 6:07:08.750. If we get there, great, but let's + * imagine the system is so heavily loaded that our process is + * preempted and by the time we get to run again, the system clock + * reads 6:07:11.990. We now want to wait until the next xx:xx:xx.750 + * time, which is 6:07:12.750 (4.5 seconds after the reference time), + * at which point we will set the Hardware Clock to 1:02:07 (4 seconds + * after the originally requested time). If we do that successfully, + * then at 6:07:13.250 (5 seconds after the reference time), the + * Hardware Clock will update to 1:02:08 (5 seconds after the + * originally requested time), and all is well thereafter. + */ + + time_t newhwtime = sethwtime; + double target_time_tolerance_secs = 0.001; /* initial value */ + double tolerance_incr_secs = 0.001; /* initial value */ + double delay; + struct timeval rtc_set_delay_tv; + + struct timeval targetsystime; + struct timeval nowsystime; + struct timeval prevsystime = refsystime; + double deltavstarget; + + if (ctl->rtc_delay != -1.0) /* --delay specified */ + delay = ctl->rtc_delay; + else + delay = get_hardware_delay(ctl); + + if (ctl->verbose) + printf(_("Using delay: %.6f seconds\n"), delay); + + rtc_set_delay_tv.tv_sec = 0; + rtc_set_delay_tv.tv_usec = delay * 1E6; + + timeradd(&refsystime, &rtc_set_delay_tv, &targetsystime); + + while (1) { + double ticksize; + + ON_DBG(RANDOM_SLEEP, up_to_1000ms_sleep()); + + gettimeofday(&nowsystime, NULL); + deltavstarget = time_diff(nowsystime, targetsystime); + ticksize = time_diff(nowsystime, prevsystime); + prevsystime = nowsystime; + + if (ticksize < 0) { + if (ctl->verbose) + printf(_("time jumped backward %.6f seconds " + "to %"PRId64".%06"PRId64" - retargeting\n"), + ticksize, (int64_t)nowsystime.tv_sec, + (int64_t)nowsystime.tv_usec); + /* The retarget is handled at the end of the loop. */ + } else if (deltavstarget < 0) { + /* deltavstarget < 0 if current time < target time */ + DBG(DELTA_VS_TARGET, + ul_debug("%"PRId64".%06"PRId64" < %"PRId64".%06"PRId64" (%.6f)", + (int64_t)nowsystime.tv_sec, (int64_t)nowsystime.tv_usec, + (int64_t)targetsystime.tv_sec, + (int64_t)targetsystime.tv_usec, deltavstarget)); + continue; /* not there yet - keep spinning */ + } else if (deltavstarget <= target_time_tolerance_secs) { + /* Close enough to the target time; done waiting. */ + break; + } else /* (deltavstarget > target_time_tolerance_secs) */ { + /* + * We missed our window. Increase the tolerance and + * aim for the next opportunity. + */ + if (ctl->verbose) + printf(_("missed it - %"PRId64".%06"PRId64" is too far " + "past %"PRId64".%06"PRId64" (%.6f > %.6f)\n"), + (int64_t)nowsystime.tv_sec, + (int64_t)nowsystime.tv_usec, + (int64_t)targetsystime.tv_sec, + (int64_t)targetsystime.tv_usec, + deltavstarget, + target_time_tolerance_secs); + target_time_tolerance_secs += tolerance_incr_secs; + tolerance_incr_secs *= 2; + } + + /* + * Aim for the same offset (tv_usec) within the second in + * either the current second (if that offset hasn't arrived + * yet), or the next second. + */ + if (nowsystime.tv_usec < targetsystime.tv_usec) + targetsystime.tv_sec = nowsystime.tv_sec; + else + targetsystime.tv_sec = nowsystime.tv_sec + 1; + } + + newhwtime = sethwtime + + ceil(time_diff(nowsystime, refsystime) + - delay /* don't count this */); + if (ctl->verbose) + printf(_("%"PRId64".%06"PRId64" is close enough to %"PRId64".%06"PRId64" (%.6f < %.6f)\n" + "Set RTC to %"PRId64" (%"PRId64" + %d; refsystime = %"PRId64".%06"PRId64")\n"), + (int64_t)nowsystime.tv_sec, (int64_t)nowsystime.tv_usec, + (int64_t)targetsystime.tv_sec, (int64_t)targetsystime.tv_usec, + deltavstarget, target_time_tolerance_secs, + (int64_t)newhwtime, (int64_t)sethwtime, + (int)((int64_t)newhwtime - (int64_t)sethwtime), + (int64_t)refsystime.tv_sec, (int64_t)refsystime.tv_usec); + + set_hardware_clock(ctl, newhwtime); +} + +static int +display_time(struct timeval hwctime) +{ + char buf[ISO_BUFSIZ]; + + if (strtimeval_iso(&hwctime, ISO_TIMESTAMP_DOT, buf, sizeof(buf))) + return EXIT_FAILURE; + + printf("%s\n", buf); + return EXIT_SUCCESS; +} + +/* + * Adjusts System time, sets the kernel's timezone and RTC timescale. + * + * The kernel warp_clock function adjusts the System time according to the + * tz.tz_minuteswest argument and sets PCIL (see below). At boot settimeofday(2) + * has one-shot access to this function as shown in the table below. + * + * +-------------------------------------------------------------------------+ + * | settimeofday(tv, tz) | + * |-------------------------------------------------------------------------| + * | Arguments | System Time | TZ | PCIL | | warp_clock | + * | tv | tz | set | warped | set | set | firsttime | locked | + * |---------|---------|---------------|-----|------|-----------|------------| + * | pointer | NULL | yes | no | no | no | 1 | no | + * | NULL | ptr2utc | no | no | yes | no | 0 | yes | + * | NULL | pointer | no | yes | yes | yes | 0 | yes | + * +-------------------------------------------------------------------------+ + * ptr2utc: tz.tz_minuteswest is zero (UTC). + * PCIL: persistent_clock_is_local, sets the "11 minute mode" timescale. + * firsttime: locks the warp_clock function (initialized to 1 at boot). + * + * +---------------------------------------------------------------------------+ + * | op | RTC scale | settimeofday calls | + * |---------|-----------|-----------------------------------------------------| + * | systz | Local | 1) warps system time*, sets PCIL* and kernel tz | + * | systz | UTC | 1st) locks warp_clock* 2nd) sets kernel tz | + * | hctosys | Local | 1st) sets PCIL* & kernel tz 2nd) sets system time | + * | hctosys | UTC | 1st) locks warp* 2nd) sets tz 3rd) sets system time | + * +---------------------------------------------------------------------------+ + * * only on first call after boot + * + * POSIX 2008 marked TZ in settimeofday() as deprecated. Unfortunately, + * different C libraries react to this deprecation in a different way. Since + * glibc v2.31 settimeofday() will fail if both args are not NULL, Musl-C + * ignores TZ at all, etc. We use __set_time() and __set_timezone() to hide + * these portability issues and to keep code readable. + */ +#define __set_time(_tv) settimeofday(_tv, NULL) + +#ifndef SYS_settimeofday +# ifdef __NR_settimeofday +# define SYS_settimeofday __NR_settimeofday +# elif defined(__NR_settimeofday_time32) +# define SYS_settimeofday __NR_settimeofday_time32 +# endif +#endif + +static inline int __set_timezone(const struct timezone *tz) +{ +#ifdef SYS_settimeofday + errno = 0; + return syscall(SYS_settimeofday, NULL, tz); +#else + return settimeofday(NULL, tz); +#endif +} + +static int +set_system_clock(const struct hwclock_control *ctl, + const struct timeval newtime) +{ + struct tm broken = { 0 }; + int minuteswest; + int rc = 0; + + localtime_r(&newtime.tv_sec, &broken); + minuteswest = -get_gmtoff(&broken) / 60; + + if (ctl->verbose) { + if (ctl->universal) { + puts(_("Calling settimeofday(NULL, 0) " + "to lock the warp_clock function.")); + if (!( ctl->universal && !minuteswest )) + printf(_("Calling settimeofday(NULL, %d) " + "to set the kernel timezone.\n"), + minuteswest); + } else + printf(_("Calling settimeofday(NULL, %d) to warp " + "System time, set PCIL and the kernel tz.\n"), + minuteswest); + + if (ctl->hctosys) + printf(_("Calling settimeofday(%"PRId64".%06"PRId64", NULL) " + "to set the System time.\n"), + (int64_t)newtime.tv_sec, (int64_t)newtime.tv_usec); + } + + if (!ctl->testing) { + const struct timezone tz_utc = { 0 }; + const struct timezone tz = { minuteswest }; + + /* If UTC RTC: lock warp_clock and PCIL */ + if (ctl->universal) + rc = __set_timezone(&tz_utc); + + /* Set kernel tz; if localtime RTC: warp_clock and set PCIL */ + if (!rc && !( ctl->universal && !minuteswest )) + rc = __set_timezone(&tz); + + /* Set the System Clock */ + if ((!rc || errno == ENOSYS) && ctl->hctosys) + rc = __set_time(&newtime); + + if (rc) { + warn(_("settimeofday() failed")); + return EXIT_FAILURE; + } + } + return EXIT_SUCCESS; +} + +/* + * Refresh the last calibrated and last adjusted timestamps in <*adjtime_p> + * to facilitate future drift calculations based on this set point. + * + * With the --update-drift option: + * Update the drift factor in <*adjtime_p> based on the fact that the + * Hardware Clock was just calibrated to <nowtime> and before that was + * set to the <hclocktime> time scale. + */ +static void +adjust_drift_factor(const struct hwclock_control *ctl, + struct adjtime *adjtime_p, + const struct timeval nowtime, + const struct timeval hclocktime) +{ + if (!ctl->update) { + if (ctl->verbose) + printf(_("Not adjusting drift factor because the " + "--update-drift option was not used.\n")); + } else if (adjtime_p->last_calib_time == 0) { + if (ctl->verbose) + printf(_("Not adjusting drift factor because last " + "calibration time is zero,\n" + "so history is bad and calibration startover " + "is necessary.\n")); + } else if ((hclocktime.tv_sec - adjtime_p->last_calib_time) < 4 * 60 * 60) { + if (ctl->verbose) + printf(_("Not adjusting drift factor because it has " + "been less than four hours since the last " + "calibration.\n")); + } else { + /* + * At adjustment time we drift correct the hardware clock + * according to the contents of the adjtime file and refresh + * its last adjusted timestamp. + * + * At calibration time we set the Hardware Clock and refresh + * both timestamps in <*adjtime_p>. + * + * Here, with the --update-drift option, we also update the + * drift factor in <*adjtime_p>. + * + * Let us do computation in doubles. (Floats almost suffice, + * but 195 days + 1 second equals 195 days in floats.) + */ + const double sec_per_day = 24.0 * 60.0 * 60.0; + double factor_adjust; + double drift_factor; + struct timeval last_calib; + + last_calib = t2tv(adjtime_p->last_calib_time); + /* + * Correction to apply to the current drift factor. + * + * Simplified: uncorrected_drift / days_since_calibration. + * + * hclocktime is fully corrected with the current drift factor. + * Its difference from nowtime is the missed drift correction. + */ + factor_adjust = time_diff(nowtime, hclocktime) / + (time_diff(nowtime, last_calib) / sec_per_day); + + drift_factor = adjtime_p->drift_factor + factor_adjust; + if (fabs(drift_factor) > MAX_DRIFT) { + if (ctl->verbose) + printf(_("Clock drift factor was calculated as " + "%f seconds/day.\n" + "It is far too much. Resetting to zero.\n"), + drift_factor); + drift_factor = 0; + } else { + if (ctl->verbose) + printf(_("Clock drifted %f seconds in the past " + "%f seconds\nin spite of a drift factor of " + "%f seconds/day.\n" + "Adjusting drift factor by %f seconds/day\n"), + time_diff(nowtime, hclocktime), + time_diff(nowtime, last_calib), + adjtime_p->drift_factor, factor_adjust); + } + + adjtime_p->drift_factor = drift_factor; + } + adjtime_p->last_calib_time = nowtime.tv_sec; + + adjtime_p->last_adj_time = nowtime.tv_sec; + + adjtime_p->not_adjusted = 0; + + adjtime_p->dirty = 1; +} + +/* + * Calculate the drift correction currently needed for the + * Hardware Clock based on the last time it was adjusted, + * and the current drift factor, as stored in the adjtime file. + * + * The total drift adjustment needed is stored at tdrift_p. + * + */ +static void +calculate_adjustment(const struct hwclock_control *ctl, + const double factor, + const time_t last_time, + const double not_adjusted, + const time_t systime, struct timeval *tdrift_p) +{ + double exact_adjustment; + + exact_adjustment = + ((double)(systime - last_time)) * factor / (24 * 60 * 60) + + not_adjusted; + tdrift_p->tv_sec = (time_t) floor(exact_adjustment); + tdrift_p->tv_usec = (exact_adjustment - + (double)tdrift_p->tv_sec) * 1E6; + if (ctl->verbose) { + printf(P_("Time since last adjustment is %"PRId64" second\n", + "Time since last adjustment is %"PRId64" seconds\n", + ((int64_t)systime - (int64_t)last_time)), + ((int64_t)systime - (int64_t)last_time)); + printf(_("Calculated Hardware Clock drift is %"PRId64".%06"PRId64" seconds\n"), + (int64_t)tdrift_p->tv_sec, (int64_t)tdrift_p->tv_usec); + } +} + +/* + * Write the contents of the <adjtime> structure to its disk file. + * + * But if the contents are clean (unchanged since read from disk), don't + * bother. + */ +static int save_adjtime(const struct hwclock_control *ctl, + const struct adjtime *adjtime) +{ + char *content; /* Stuff to write to disk file */ + FILE *fp; + + xasprintf(&content, "%f %"PRId64" %f\n%"PRId64"\n%s\n", + adjtime->drift_factor, + (int64_t)adjtime->last_adj_time, + adjtime->not_adjusted, + (int64_t)adjtime->last_calib_time, + (adjtime->local_utc == LOCAL) ? "LOCAL" : "UTC"); + + if (ctl->verbose){ + printf(_("New %s data:\n%s"), + ctl->adj_file_name, content); + } + + if (!ctl->testing) { + int rc; + + fp = fopen(ctl->adj_file_name, "w"); + if (fp == NULL) { + warn(_("cannot open %s"), ctl->adj_file_name); + return EXIT_FAILURE; + } + + rc = fputs(content, fp) < 0; + rc += close_stream(fp); + + if (rc) { + warn(_("cannot update %s"), ctl->adj_file_name); + return EXIT_FAILURE; + } + } + return EXIT_SUCCESS; +} + +/* + * Do the adjustment requested, by 1) setting the Hardware Clock (if + * necessary), and 2) updating the last-adjusted time in the adjtime + * structure. + * + * Do not update anything if the Hardware Clock does not currently present a + * valid time. + * + * <hclocktime> is the drift corrected time read from the Hardware Clock. + * + * <read_time> was the system time when the <hclocktime> was read, which due + * to computational delay could be a short time ago. It is used to define a + * trigger point for setting the Hardware Clock. The fractional part of the + * Hardware clock set time is subtracted from read_time to 'refer back', or + * delay, the trigger point. Fractional parts must be accounted for in this + * way, because the Hardware Clock can only be set to a whole second. + * + * <universal>: the Hardware Clock is kept in UTC. + * + * <testing>: We are running in test mode (no updating of clock). + * + */ +static void +do_adjustment(const struct hwclock_control *ctl, struct adjtime *adjtime_p, + const struct timeval hclocktime, + const struct timeval read_time) +{ + if (adjtime_p->last_adj_time == 0) { + if (ctl->verbose) + printf(_("Not setting clock because last adjustment time is zero, " + "so history is bad.\n")); + } else if (fabs(adjtime_p->drift_factor) > MAX_DRIFT) { + if (ctl->verbose) + printf(_("Not setting clock because drift factor %f is far too high.\n"), + adjtime_p->drift_factor); + } else { + set_hardware_clock_exact(ctl, hclocktime.tv_sec, + time_inc(read_time, + -(hclocktime.tv_usec / 1E6))); + adjtime_p->last_adj_time = hclocktime.tv_sec; + adjtime_p->not_adjusted = 0; + adjtime_p->dirty = 1; + } +} + +static void determine_clock_access_method(const struct hwclock_control *ctl) +{ + ur = NULL; + +#ifdef USE_HWCLOCK_CMOS + if (ctl->directisa) + ur = probe_for_cmos_clock(); +#endif +#ifdef __linux__ + if (!ur) + ur = probe_for_rtc_clock(ctl); +#endif + if (ur) { + if (ctl->verbose) + puts(ur->interface_name); + + } else { + if (ctl->verbose) + printf(_("No usable clock interface found.\n")); + + warnx(_("Cannot access the Hardware Clock via " + "any known method.")); + + if (!ctl->verbose) + warnx(_("Use the --verbose option to see the " + "details of our search for an access " + "method.")); + hwclock_exit(ctl, EXIT_FAILURE); + } +} + +/* Do all the normal work of hwclock - read, set clock, etc. */ +static int +manipulate_clock(const struct hwclock_control *ctl, const time_t set_time, + const struct timeval startup_time, struct adjtime *adjtime) +{ + /* The time at which we read the Hardware Clock */ + struct timeval read_time = { 0 }; + /* + * The Hardware Clock gives us a valid time, or at + * least something close enough to fool mktime(). + */ + int hclock_valid = 0; + /* + * Tick synchronized time read from the Hardware Clock and + * then drift corrected for all operations except --show. + */ + struct timeval hclocktime = { 0 }; + /* + * hclocktime correlated to startup_time. That is, what drift + * corrected Hardware Clock time would have been at start up. + */ + struct timeval startup_hclocktime = { 0 }; + /* Total Hardware Clock drift correction needed. */ + struct timeval tdrift = { 0 }; + + if ((ctl->set || ctl->systohc || ctl->adjust) && + (adjtime->local_utc == UTC) != ctl->universal) { + adjtime->local_utc = ctl->universal ? UTC : LOCAL; + adjtime->dirty = 1; + } + /* + * Negate the drift correction, because we want to 'predict' a + * Hardware Clock time that includes drift. + */ + if (ctl->predict) { + hclocktime = t2tv(set_time); + calculate_adjustment(ctl, adjtime->drift_factor, + adjtime->last_adj_time, + adjtime->not_adjusted, + hclocktime.tv_sec, &tdrift); + hclocktime = time_inc(hclocktime, (double) + -(tdrift.tv_sec + tdrift.tv_usec / 1E6)); + if (ctl->verbose) { + printf(_("Target date: %"PRId64"\n"), (int64_t)set_time); + printf(_("Predicted RTC: %"PRId64"\n"), (int64_t)hclocktime.tv_sec); + } + return display_time(hclocktime); + } + + if (ctl->systz) + return set_system_clock(ctl, startup_time); + + if (ur->get_permissions()) + return EXIT_FAILURE; + + /* + * Read and drift correct RTC time; except for RTC set functions + * without the --update-drift option because: 1) it's not needed; + * 2) it enables setting a corrupted RTC without reading it first; + * 3) it significantly reduces system shutdown time. + */ + if ( ! ((ctl->set || ctl->systohc) && !ctl->update)) { + /* + * Timing critical - do not change the order of, or put + * anything between the follow three statements. + * Synchronization failure MUST exit, because all drift + * operations are invalid without it. + */ + if (synchronize_to_clock_tick(ctl)) + return EXIT_FAILURE; + read_hardware_clock(ctl, &hclock_valid, &hclocktime.tv_sec); + gettimeofday(&read_time, NULL); + + if (!hclock_valid) { + warnx(_("RTC read returned an invalid value.")); + return EXIT_FAILURE; + } + /* + * Calculate and apply drift correction to the Hardware Clock + * time for everything except --show + */ + calculate_adjustment(ctl, adjtime->drift_factor, + adjtime->last_adj_time, + adjtime->not_adjusted, + hclocktime.tv_sec, &tdrift); + if (!ctl->show) + hclocktime = time_inc(tdrift, hclocktime.tv_sec); + + startup_hclocktime = + time_inc(hclocktime, time_diff(startup_time, read_time)); + } + if (ctl->show || ctl->get) { + return display_time(startup_hclocktime); + } + + if (ctl->set) { + set_hardware_clock_exact(ctl, set_time, startup_time); + if (!ctl->noadjfile) + adjust_drift_factor(ctl, adjtime, t2tv(set_time), + startup_hclocktime); + } else if (ctl->adjust) { + if (tdrift.tv_sec > 0 || tdrift.tv_sec < -1) + do_adjustment(ctl, adjtime, hclocktime, read_time); + else + printf(_("Needed adjustment is less than one second, " + "so not setting clock.\n")); + } else if (ctl->systohc) { + struct timeval nowtime, reftime; + /* + * We can only set_hardware_clock_exact to a + * whole seconds time, so we set it with + * reference to the most recent whole + * seconds time. + */ + gettimeofday(&nowtime, NULL); + reftime.tv_sec = nowtime.tv_sec; + reftime.tv_usec = 0; + set_hardware_clock_exact(ctl, (time_t) reftime.tv_sec, reftime); + if (!ctl->noadjfile) + adjust_drift_factor(ctl, adjtime, nowtime, + hclocktime); + } else if (ctl->hctosys) { + return set_system_clock(ctl, hclocktime); + } + if (!ctl->noadjfile && adjtime->dirty) + return save_adjtime(ctl, adjtime); + return EXIT_SUCCESS; +} + +/** + * Get or set the kernel RTC driver's epoch on Alpha machines. + * ISA machines are hard coded for 1900. + */ +#if defined(__linux__) && defined(__alpha__) +static void +manipulate_epoch(const struct hwclock_control *ctl) +{ + if (ctl->getepoch) { + unsigned long epoch; + + if (get_epoch_rtc(ctl, &epoch)) + warnx(_("unable to read the RTC epoch.")); + else + printf(_("The RTC epoch is set to %lu.\n"), epoch); + } else if (ctl->setepoch) { + if (!ctl->epoch_option) + warnx(_("--epoch is required for --setepoch.")); + else if (!ctl->testing) + if (set_epoch_rtc(ctl)) + warnx(_("unable to set the RTC epoch.")); + } +} +#endif /* __linux__ __alpha__ */ + +#ifdef __linux__ +static int +manipulate_rtc_param(const struct hwclock_control *ctl) +{ + if (ctl->param_get_option) { + uint64_t id = 0, value = 0; + + if (get_param_rtc(ctl, ctl->param_get_option, &id, &value)) { + warnx(_("unable to read the RTC parameter %s"), + ctl->param_get_option); + return 1; + } + + printf(_("The RTC parameter 0x%jx is set to 0x%jx.\n"), + (uintmax_t) id, (uintmax_t) value); + return 0; + + } else if (ctl->param_set_option) { + if (ctl->testing) + return 0; + + return set_param_rtc(ctl, ctl->param_set_option); + } + + return 1; +} +#endif + +static void out_version(void) +{ + printf(UTIL_LINUX_VERSION); +} + +static void __attribute__((__noreturn__)) +usage(void) +{ +#ifdef __linux__ + const struct hwclock_param *param = get_hwclock_params(); +#endif + + fputs(USAGE_HEADER, stdout); + printf(_(" %s [function] [option...]\n"), program_invocation_short_name); + + fputs(USAGE_SEPARATOR, stdout); + puts(_("Time clocks utility.")); + + fputs(USAGE_FUNCTIONS, stdout); + puts(_(" -r, --show display the RTC time")); + puts(_(" --get display drift corrected RTC time")); + puts(_(" --set set the RTC according to --date")); + puts(_(" -s, --hctosys set the system time from the RTC")); + puts(_(" -w, --systohc set the RTC from the system time")); + puts(_(" --systz send timescale configurations to the kernel")); + puts(_(" -a, --adjust adjust the RTC to account for systematic drift")); +#if defined(__linux__) && defined(__alpha__) + puts(_(" --getepoch display the RTC epoch")); + puts(_(" --setepoch set the RTC epoch according to --epoch")); +#endif +#ifdef __linux__ + puts(_(" --param-get <param> display the RTC parameter")); + puts(_(" --param-set <param>=<value> set the RTC parameter")); +#endif + puts(_(" --predict predict the drifted RTC time according to --date")); + fputs(USAGE_OPTIONS, stdout); + puts(_(" -u, --utc the RTC timescale is UTC")); + puts(_(" -l, --localtime the RTC timescale is Local")); +#ifdef __linux__ + printf(_( + " -f, --rtc <file> use an alternate file to %1$s\n"), _PATH_RTC_DEV); +#endif + printf(_( + " --directisa use the ISA bus instead of %1$s access\n"), _PATH_RTC_DEV); + puts(_(" --date <time> date/time input for --set and --predict")); + puts(_(" --delay <sec> delay used when set new RTC time")); +#if defined(__linux__) && defined(__alpha__) + puts(_(" --epoch <year> epoch input for --setepoch")); +#endif + puts(_(" --update-drift update the RTC drift factor")); + printf(_( + " --noadjfile do not use %1$s\n"), _PATH_ADJTIME); + printf(_( + " --adjfile <file> use an alternate file to %1$s\n"), _PATH_ADJTIME); + puts(_(" --test dry run; implies --verbose")); + puts(_(" -v, --verbose display more details")); + + fputs(USAGE_SEPARATOR, stdout); + printf(USAGE_HELP_OPTIONS(33)); + +#ifdef __linux__ + fputs(USAGE_ARGUMENTS, stdout); + puts(_(" <param> is either a numeric RTC parameter value or one of these aliases:")); + + while (param->name) { + printf(_(" - %1$s: %2$s (0x%3$x)\n"), param->name, param->help, param->id); + param++; + } + + puts(_(" See Kernel's include/uapi/linux/rtc.h for parameters and values.")); + fputs(USAGE_ARG_SEPARATOR, stdout); + puts(_(" <param> and <value> accept hexadecimal values if prefixed with 0x, otherwise decimal.")); +#endif + printf(USAGE_MAN_TAIL("hwclock(8)")); + exit(EXIT_SUCCESS); +} + +int main(int argc, char **argv) +{ + struct hwclock_control ctl = { + .show = 1, /* default op is show */ + .rtc_delay = -1.0 /* unspecified */ + }; + struct timeval startup_time; + struct adjtime adjtime = { 0 }; + /* + * The time we started up, in seconds into the epoch, including + * fractions. + */ + time_t set_time = 0; /* Time to which user said to set Hardware Clock */ + int rc, c; + + /* Long only options. */ + enum { + OPT_ADJFILE = CHAR_MAX + 1, + OPT_DATE, + OPT_DELAY, + OPT_DIRECTISA, + OPT_EPOCH, + OPT_GET, + OPT_GETEPOCH, + OPT_NOADJFILE, + OPT_PARAM_GET, + OPT_PARAM_SET, + OPT_PREDICT, + OPT_SET, + OPT_SETEPOCH, + OPT_SYSTZ, + OPT_TEST, + OPT_UPDATE + }; + + static const struct option longopts[] = { + { "adjust", no_argument, NULL, 'a' }, + { "help", no_argument, NULL, 'h' }, + { "localtime", no_argument, NULL, 'l' }, + { "show", no_argument, NULL, 'r' }, + { "hctosys", no_argument, NULL, 's' }, + { "utc", no_argument, NULL, 'u' }, + { "version", no_argument, NULL, 'V' }, + { "systohc", no_argument, NULL, 'w' }, + { "debug", no_argument, NULL, 'D' }, + { "ul-debug", required_argument, NULL, 'd' }, + { "verbose", no_argument, NULL, 'v' }, + { "set", no_argument, NULL, OPT_SET }, +#if defined(__linux__) && defined(__alpha__) + { "getepoch", no_argument, NULL, OPT_GETEPOCH }, + { "setepoch", no_argument, NULL, OPT_SETEPOCH }, + { "epoch", required_argument, NULL, OPT_EPOCH }, +#endif +#ifdef __linux__ + { "param-get", required_argument, NULL, OPT_PARAM_GET }, + { "param-set", required_argument, NULL, OPT_PARAM_SET }, +#endif + { "noadjfile", no_argument, NULL, OPT_NOADJFILE }, + { "directisa", no_argument, NULL, OPT_DIRECTISA }, + { "test", no_argument, NULL, OPT_TEST }, + { "date", required_argument, NULL, OPT_DATE }, + { "delay", required_argument, NULL, OPT_DELAY }, +#ifdef __linux__ + { "rtc", required_argument, NULL, 'f' }, +#endif + { "adjfile", required_argument, NULL, OPT_ADJFILE }, + { "systz", no_argument, NULL, OPT_SYSTZ }, + { "predict", no_argument, NULL, OPT_PREDICT }, + { "get", no_argument, NULL, OPT_GET }, + { "update-drift", no_argument, NULL, OPT_UPDATE }, + { NULL, 0, NULL, 0 } + }; + + static const ul_excl_t excl[] = { /* rows and cols in ASCII order */ + { 'a','r','s','w', + OPT_GET, OPT_GETEPOCH, OPT_PREDICT, + OPT_SET, OPT_SETEPOCH, OPT_SYSTZ }, + { 'l', 'u' }, + { OPT_ADJFILE, OPT_NOADJFILE }, + { OPT_NOADJFILE, OPT_UPDATE }, + { 0 } + }; + int excl_st[ARRAY_SIZE(excl)] = UL_EXCL_STATUS_INIT; + + /* Remember what time we were invoked */ + gettimeofday(&startup_time, NULL); + +#ifdef HAVE_LIBAUDIT + hwaudit_fd = audit_open(); + if (hwaudit_fd < 0 && !(errno == EINVAL || errno == EPROTONOSUPPORT || + errno == EAFNOSUPPORT)) { + /* + * You get these error codes only when the kernel doesn't + * have audit compiled in. + */ + warnx(_("Unable to connect to audit system")); + return EXIT_FAILURE; + } +#endif + setlocale(LC_ALL, ""); +#ifdef LC_NUMERIC + /* + * We need LC_CTYPE and LC_TIME and LC_MESSAGES, but must avoid + * LC_NUMERIC since it gives problems when we write to /etc/adjtime. + * - gqueri@mail.dotcom.fr + */ + setlocale(LC_NUMERIC, "C"); +#endif + bindtextdomain(PACKAGE, LOCALEDIR); + textdomain(PACKAGE); + close_stdout_atexit(); + + while ((c = getopt_long(argc, argv, + "hvVDd:alrsuwf:", longopts, NULL)) != -1) { + + err_exclusive_options(c, longopts, excl, excl_st); + + switch (c) { + case 'D': + warnx(_("use --verbose, --debug has been deprecated.")); + break; + case 'v': + ctl.verbose = 1; + break; + case 'd': + hwclock_init_debug(optarg); + break; + case 'a': + ctl.adjust = 1; + ctl.show = 0; + ctl.hwaudit_on = 1; + break; + case 'l': + ctl.local_opt = 1; /* --localtime */ + break; + case 'r': + ctl.show = 1; + break; + case 's': + ctl.hctosys = 1; + ctl.show = 0; + ctl.hwaudit_on = 1; + break; + case 'u': + ctl.utc = 1; + break; + case 'w': + ctl.systohc = 1; + ctl.show = 0; + ctl.hwaudit_on = 1; + break; + case OPT_SET: + ctl.set = 1; + ctl.show = 0; + ctl.hwaudit_on = 1; + break; +#if defined(__linux__) && defined(__alpha__) + case OPT_GETEPOCH: + ctl.getepoch = 1; + ctl.show = 0; + break; + case OPT_SETEPOCH: + ctl.setepoch = 1; + ctl.show = 0; + ctl.hwaudit_on = 1; + break; + case OPT_EPOCH: + ctl.epoch_option = optarg; /* --epoch */ + break; +#endif +#ifdef __linux__ + case OPT_PARAM_GET: + ctl.param_get_option = optarg; + ctl.show = 0; + break; + case OPT_PARAM_SET: + ctl.param_set_option = optarg; + ctl.show = 0; + ctl.hwaudit_on = 1; + break; +#endif + case OPT_NOADJFILE: + ctl.noadjfile = 1; + break; + case OPT_DIRECTISA: + ctl.directisa = 1; + break; + case OPT_TEST: + ctl.testing = 1; /* --test */ + ctl.verbose = 1; + break; + case OPT_DATE: + ctl.date_opt = optarg; /* --date */ + break; + case OPT_DELAY: + ctl.rtc_delay = strtod_or_err(optarg, "invalid --delay argument"); + break; + case OPT_ADJFILE: + ctl.adj_file_name = optarg; /* --adjfile */ + break; + case OPT_SYSTZ: + ctl.systz = 1; /* --systz */ + ctl.show = 0; + ctl.hwaudit_on = 1; + break; + case OPT_PREDICT: + ctl.predict = 1; /* --predict */ + ctl.show = 0; + break; + case OPT_GET: + ctl.get = 1; /* --get */ + ctl.show = 0; + break; + case OPT_UPDATE: + ctl.update = 1; /* --update-drift */ + break; +#ifdef __linux__ + case 'f': + ctl.rtc_dev_name = optarg; /* --rtc */ + break; +#endif + + case 'V': /* --version */ + print_version(EXIT_SUCCESS); + case 'h': /* --help */ + usage(); + default: + errtryhelp(EXIT_FAILURE); + } + } + + if (argc -= optind) { + warnx(_("%d too many arguments given"), argc); + errtryhelp(EXIT_FAILURE); + } + + if (!ctl.adj_file_name) + ctl.adj_file_name = _PATH_ADJTIME; + + if (ctl.update && !ctl.set && !ctl.systohc) { + warnx(_("--update-drift requires --set or --systohc")); + exit(EXIT_FAILURE); + } + + if (ctl.noadjfile && !ctl.utc && !ctl.local_opt) { + warnx(_("With --noadjfile, you must specify " + "either --utc or --localtime")); + exit(EXIT_FAILURE); + } + + if (ctl.set || ctl.predict) { + if (!ctl.date_opt) { + warnx(_("--date is required for --set or --predict")); + exit(EXIT_FAILURE); + } +#ifdef USE_HWCLOCK_GPLv3_DATETIME + /* date(1) compatible GPLv3 parser */ + struct timespec when = { 0 }; + + if (parse_date(&when, ctl.date_opt, NULL)) + set_time = when.tv_sec; +#else + /* minimalistic GPLv2 based parser */ + usec_t usec; + + if (parse_timestamp(ctl.date_opt, &usec) == 0) + set_time = (time_t) (usec / 1000000); +#endif + else { + warnx(_("invalid date '%s'"), ctl.date_opt); + exit(EXIT_FAILURE); + } + } + +#ifdef __linux__ + if (ctl.param_get_option || ctl.param_set_option) { + if (manipulate_rtc_param(&ctl)) + hwclock_exit(&ctl, EXIT_FAILURE); + + hwclock_exit(&ctl, EXIT_SUCCESS); + } +#endif + +#if defined(__linux__) && defined(__alpha__) + if (ctl.getepoch || ctl.setepoch) { + manipulate_epoch(&ctl); + hwclock_exit(&ctl, EXIT_SUCCESS); + } +#endif + + if (ctl.verbose) { + out_version(); + printf(_("System Time: %"PRId64".%06"PRId64"\n"), + (int64_t)startup_time.tv_sec, (int64_t)startup_time.tv_usec); + } + + if (!ctl.systz && !ctl.predict) + determine_clock_access_method(&ctl); + + if (!ctl.noadjfile && !(ctl.systz && (ctl.utc || ctl.local_opt))) { + if ((rc = read_adjtime(&ctl, &adjtime)) != 0) + hwclock_exit(&ctl, rc); + } else + /* Avoid writing adjtime file if we don't have to. */ + adjtime.dirty = 0; + + ctl.universal = hw_clock_is_utc(&ctl, &adjtime); + rc = manipulate_clock(&ctl, set_time, startup_time, &adjtime); + if (ctl.testing) + puts(_("Test mode: nothing was changed.")); + hwclock_exit(&ctl, rc); + return rc; /* Not reached */ +} + +void +hwclock_exit(const struct hwclock_control *ctl +#ifndef HAVE_LIBAUDIT + __attribute__((__unused__)) +#endif + , int status) +{ +#ifdef HAVE_LIBAUDIT + if (ctl->hwaudit_on && !ctl->testing) { + audit_log_user_message(hwaudit_fd, AUDIT_USYS_CONFIG, + "op=change-system-time", NULL, NULL, NULL, + status == EXIT_SUCCESS ? 1 : 0); + } + close(hwaudit_fd); +#endif + exit(status); +} + +/* + * History of this program: + * + * 98.08.12 BJH Version 2.4 + * + * Don't use century byte from Hardware Clock. Add comments telling why. + * + * 98.06.20 BJH Version 2.3. + * + * Make --hctosys set the kernel timezone from TZ environment variable + * and/or /usr/lib/zoneinfo. From Klaus Ripke (klaus@ripke.com). + * + * 98.03.05 BJH. Version 2.2. + * + * Add --getepoch and --setepoch. + * + * Fix some word length things so it works on Alpha. + * + * Make it work when /dev/rtc doesn't have the interrupt functions. In this + * case, busywait for the top of a second instead of blocking and waiting + * for the update complete interrupt. + * + * Fix a bunch of bugs too numerous to mention. + * + * 97.06.01: BJH. Version 2.1. Read and write the century byte (Byte 50) of + * the ISA Hardware Clock when using direct ISA I/O. Problem discovered by + * job (jei@iclnl.icl.nl). + * + * Use the rtc clock access method in preference to the KDGHWCLK method. + * Problem discovered by Andreas Schwab <schwab@LS5.informatik.uni-dortmund.de>. + * + * November 1996: Version 2.0.1. Modifications by Nicolai Langfeldt + * (janl@math.uio.no) to make it compile on linux 1.2 machines as well as + * more recent versions of the kernel. Introduced the NO_CLOCK access method + * and wrote feature test code to detect absence of rtc headers. + * + *************************************************************************** + * Maintenance notes + * + * To compile this, you must use GNU compiler optimization (-O option) in + * order to make the "extern inline" functions from asm/io.h (inb(), etc.) + * compile. If you don't optimize, which means the compiler will generate no + * inline functions, the references to these functions in this program will + * be compiled as external references. Since you probably won't be linking + * with any functions by these names, you will have unresolved external + * references when you link. + * + * Here's some info on how we must deal with the time that elapses while + * this program runs: There are two major delays as we run: + * + * 1) Waiting up to 1 second for a transition of the Hardware Clock so + * we are synchronized to the Hardware Clock. + * 2) Running the "date" program to interpret the value of our --date + * option. + * + * Reading the /etc/adjtime file is the next biggest source of delay and + * uncertainty. + * + * The user wants to know what time it was at the moment they invoked us, not + * some arbitrary time later. And in setting the clock, they are giving us the + * time at the moment we are invoked, so if we set the clock some time + * later, we have to add some time to that. + * + * So we check the system time as soon as we start up, then run "date" and + * do file I/O if necessary, then wait to synchronize with a Hardware Clock + * edge, then check the system time again to see how much time we spent. We + * immediately read the clock then and (if appropriate) report that time, + * and additionally, the delay we measured. + * + * If we're setting the clock to a time given by the user, we wait some more + * so that the total delay is an integral number of seconds, then set the + * Hardware Clock to the time the user requested plus that integral number + * of seconds. N.B. The Hardware Clock can only be set in integral seconds. + * + * If we're setting the clock to the system clock value, we wait for the + * system clock to reach the top of a second, and then set the Hardware + * Clock to the system clock's value. + * + * Here's an interesting point about setting the Hardware Clock: On my + * machine, when you set it, it sets to that precise time. But one can + * imagine another clock whose update oscillator marches on a steady one + * second period, so updating the clock between any two oscillator ticks is + * the same as updating it right at the earlier tick. To avoid any + * complications that might cause, we set the clock as soon as possible + * after an oscillator tick. + * + * About synchronizing to the Hardware Clock when reading the time: The + * precision of the Hardware Clock counters themselves is one second. You + * can't read the counters and find out that is 12:01:02.5. But if you + * consider the location in time of the counter's ticks as part of its + * value, then its precision is as infinite as time is continuous! What I'm + * saying is this: To find out the _exact_ time in the hardware clock, we + * wait until the next clock tick (the next time the second counter changes) + * and measure how long we had to wait. We then read the value of the clock + * counters and subtract the wait time and we know precisely what time it + * was when we set out to query the time. + * + * hwclock uses this method, and considers the Hardware Clock to have + * infinite precision. + */ |