package/busybox/busybox-1.16.1-hwclock.patch - buildroot - Git at Google

 diff -urpN busybox-1.16.1/util-linux/hwclock.c busybox-1.16.1-hwclock/util-linux/hwclock.c
 --- busybox-1.16.1/util-linux/hwclock.c	2010-03-19 19:58:07.000000000 -0700
 +++ busybox-1.16.1-hwclock/util-linux/hwclock.c	2010-04-14 09:29:37.889208237 -0700
 @@ -109,10 +109,53 @@ static void to_sys_clock(const char **pp

  static void from_sys_clock(const char **pp_rtcname, int utc)
  {
 -#define TWEAK_USEC 200
 -	struct tm tm_time;
 +#if 1
  	struct timeval tv;
 +	struct tm tm_time;
 +	int rtc;
 +
 +	rtc = rtc_xopen(pp_rtcname, O_WRONLY);
 +	gettimeofday(&tv, NULL);
 +	/* Prepare tm_time */
 +	if (sizeof(time_t) == sizeof(tv.tv_sec)) {
 +		if (utc)
 +			gmtime_r((time_t*)&tv.tv_sec, &tm_time);
 +		else
 +			localtime_r((time_t*)&tv.tv_sec, &tm_time);
 +	} else {
 +		time_t t = tv.tv_sec;
 +		if (utc)
 +			gmtime_r(&t, &tm_time);
 +		else
 +			localtime_r(&t, &tm_time);
 +	}
 +#else
 +/* Bloated code which tries to set hw clock with better precision.
 + * On x86, even though code does set hw clock within <1ms of exact
 + * whole seconds, apparently hw clock (at least on some machines)
 + * doesn't reset internal fractional seconds to 0,
 + * making all this a pointless excercise.
 + */
 +	/* If we see that we are N usec away from whole second,
 +	 * we'll sleep for N-ADJ usecs. ADJ corrects for the fact
 +	 * that CPU is not infinitely fast.
 +	 * On infinitely fast CPU, next wakeup would be
 +	 * on (exactly_next_whole_second - ADJ). On real CPUs,
 +	 * this difference between current time and whole second
 +	 * is less than ADJ (assuming system isn't heavily loaded).
 +	 */
 +	/* Small value of 256us gives very precise sync for 2+ GHz CPUs.
 +	 * Slower CPUs will fail to sync and will go to bigger
 +	 * ADJ values. qemu-emulated armv4tl with ~100 MHz
 +	 * performance ends up using ADJ ~= 4*1024 and it takes
 +	 * 2+ secs (2 tries with successively larger ADJ)
 +	 * to sync. Even straced one on the same qemu (very slow)
 +	 * takes only 4 tries.
 +	 */
 +#define TWEAK_USEC 256
  	unsigned adj = TWEAK_USEC;
 +	struct tm tm_time;
 +	struct timeval tv;
  	int rtc = rtc_xopen(pp_rtcname, O_WRONLY);

  	/* Try to catch the moment when whole second is close */
 @@ -124,55 +167,64 @@ static void from_sys_clock(const char **

  		t = tv.tv_sec;
  		rem_usec = 1000000 - tv.tv_usec;
 -		if (rem_usec < 1024) {
 -			/* Less than 1ms to next second. Good enough */
 +		if (rem_usec < adj) {
 +			/* Close enough */
   small_rem:
  			t++;
  		}

 -		/* Prepare tm */
 +		/* Prepare tm_time from t */
  		if (utc)
  			gmtime_r(&t, &tm_time); /* may read /etc/xxx (it takes time) */
  		else
  			localtime_r(&t, &tm_time); /* same */
 -		tm_time.tm_isdst = 0;
 +
 +		if (adj >= 32*1024) {
 +			break; /* 32 ms diff and still no luck?? give up trying to sync */
 +		}

  		/* gmtime/localtime took some time, re-get cur time */
  		gettimeofday(&tv, NULL);

 -		if (tv.tv_sec < t /* may happen if rem_usec was < 1024 */
 -		 || (tv.tv_sec == t && tv.tv_usec < 1024)
 +		if (tv.tv_sec < t /* we are still in old second */
 +		 || (tv.tv_sec == t && tv.tv_usec < adj) /* not too far into next second */
  		) {
 -			/* We are not too far into next second. Good. */
 -			break;
 -		}
 -		adj += 32; /* 2^(10-5) = 2^5 = 32 iterations max */
 -		if (adj >= 1024) {
 -			/* Give up trying to sync */
 -			break;
 +			break; /* good, we are in sync! */
  		}

 -		/* Try to sync up by sleeping */
  		rem_usec = 1000000 - tv.tv_usec;
 -		if (rem_usec < 1024) {
 -			goto small_rem; /* already close, don't sleep */
 +		if (rem_usec < adj) {
 +			t = tv.tv_sec;
 +			goto small_rem; /* already close to next sec, don't sleep */
  		}
 -		/* Need to sleep.
 -		 * Note that small adj on slow processors can make us
 -		 * to always overshoot tv.tv_usec < 1024 check on next
 -		 * iteration. That's why adj is increased on each iteration.
 -		 * This also allows it to be reused as a loop limiter.
 -		 */
 -		usleep(rem_usec - adj);
 -	}

 -	xioctl(rtc, RTC_SET_TIME, &tm_time);
 +		/* Try to sync up by sleeping */
 +		usleep(rem_usec - adj);

 -	/* Debug aid to find "good" TWEAK_USEC.
 +		/* Jump to 1ms diff, then increase fast (x2): EVERY loop
 +		 * takes ~1 sec, people won't like slowly converging code here!
 +		 */
 +	//bb_error_msg("adj:%d tv.tv_usec:%d", adj, (int)tv.tv_usec);
 +		if (adj < 512)
 +			adj = 512;
 +		/* ... and if last "overshoot" does not look insanely big,
 +		 * just use it as adj increment. This makes convergence faster.
 +		 */
 +		if (tv.tv_usec < adj * 8) {
 +			adj += tv.tv_usec;
 +			continue;
 +		}
 +		adj *= 2;
 +	}
 +	/* Debug aid to find "optimal" TWEAK_USEC with nearly exact sync.
  	 * Look for a value which makes tv_usec close to 999999 or 0.
 -	 * for 2.20GHz Intel Core 2: TWEAK_USEC ~= 200
 +	 * For 2.20GHz Intel Core 2: optimal TWEAK_USEC ~= 200
  	 */
 -	//bb_error_msg("tv.tv_usec:%d adj:%d", (int)tv.tv_usec, adj);
 +	//bb_error_msg("tv.tv_usec:%d", (int)tv.tv_usec);
 +#endif
 +
 +	tm_time.tm_isdst = 0;
 +	xioctl(rtc, RTC_SET_TIME, &tm_time);

  	if (ENABLE_FEATURE_CLEAN_UP)
  		close(rtc);
	diff -urpN busybox-1.16.1/util-linux/hwclock.c busybox-1.16.1-hwclock/util-linux/hwclock.c
	--- busybox-1.16.1/util-linux/hwclock.c 2010-03-19 19:58:07.000000000 -0700
	+++ busybox-1.16.1-hwclock/util-linux/hwclock.c 2010-04-14 09:29:37.889208237 -0700
	@@ -109,10 +109,53 @@ static void to_sys_clock(const char **pp

	static void from_sys_clock(const char **pp_rtcname, int utc)
	{
	-#define TWEAK_USEC 200
	- struct tm tm_time;
	+#if 1
	struct timeval tv;
	+ struct tm tm_time;
	+ int rtc;
	+
	+ rtc = rtc_xopen(pp_rtcname, O_WRONLY);
	+ gettimeofday(&tv, NULL);
	+ /* Prepare tm_time */
	+ if (sizeof(time_t) == sizeof(tv.tv_sec)) {
	+ if (utc)
	+ gmtime_r((time_t*)&tv.tv_sec, &tm_time);
	+ else
	+ localtime_r((time_t*)&tv.tv_sec, &tm_time);
	+ } else {
	+ time_t t = tv.tv_sec;
	+ if (utc)
	+ gmtime_r(&t, &tm_time);
	+ else
	+ localtime_r(&t, &tm_time);
	+ }
	+#else
	+/* Bloated code which tries to set hw clock with better precision.
	+ * On x86, even though code does set hw clock within <1ms of exact
	+ * whole seconds, apparently hw clock (at least on some machines)
	+ * doesn't reset internal fractional seconds to 0,
	+ * making all this a pointless excercise.
	+ */
	+ /* If we see that we are N usec away from whole second,
	+ * we'll sleep for N-ADJ usecs. ADJ corrects for the fact
	+ * that CPU is not infinitely fast.
	+ * On infinitely fast CPU, next wakeup would be
	+ * on (exactly_next_whole_second - ADJ). On real CPUs,
	+ * this difference between current time and whole second
	+ * is less than ADJ (assuming system isn't heavily loaded).
	+ */
	+ /* Small value of 256us gives very precise sync for 2+ GHz CPUs.
	+ * Slower CPUs will fail to sync and will go to bigger
	+ * ADJ values. qemu-emulated armv4tl with ~100 MHz
	+ * performance ends up using ADJ ~= 4*1024 and it takes
	+ * 2+ secs (2 tries with successively larger ADJ)
	+ * to sync. Even straced one on the same qemu (very slow)
	+ * takes only 4 tries.
	+ */
	+#define TWEAK_USEC 256
	unsigned adj = TWEAK_USEC;
	+ struct tm tm_time;
	+ struct timeval tv;
	int rtc = rtc_xopen(pp_rtcname, O_WRONLY);

	/* Try to catch the moment when whole second is close */
	@@ -124,55 +167,64 @@ static void from_sys_clock(const char **

	t = tv.tv_sec;
	rem_usec = 1000000 - tv.tv_usec;
	- if (rem_usec < 1024) {
	- /* Less than 1ms to next second. Good enough */
	+ if (rem_usec < adj) {
	+ /* Close enough */
	small_rem:
	t++;
	}

	- /* Prepare tm */
	+ /* Prepare tm_time from t */
	if (utc)
	gmtime_r(&t, &tm_time); /* may read /etc/xxx (it takes time) */
	else
	localtime_r(&t, &tm_time); /* same */
	- tm_time.tm_isdst = 0;
	+
	+ if (adj >= 32*1024) {
	+ break; /* 32 ms diff and still no luck?? give up trying to sync */
	+ }

	/* gmtime/localtime took some time, re-get cur time */
	gettimeofday(&tv, NULL);

	- if (tv.tv_sec < t /* may happen if rem_usec was < 1024 */
	- \|\| (tv.tv_sec == t && tv.tv_usec < 1024)
	+ if (tv.tv_sec < t /* we are still in old second */
	+ \|\| (tv.tv_sec == t && tv.tv_usec < adj) /* not too far into next second */
	) {
	- /* We are not too far into next second. Good. */
	- break;
	- }
	- adj += 32; /* 2^(10-5) = 2^5 = 32 iterations max */
	- if (adj >= 1024) {
	- /* Give up trying to sync */
	- break;
	+ break; /* good, we are in sync! */
	}

	- /* Try to sync up by sleeping */
	rem_usec = 1000000 - tv.tv_usec;
	- if (rem_usec < 1024) {
	- goto small_rem; /* already close, don't sleep */
	+ if (rem_usec < adj) {
	+ t = tv.tv_sec;
	+ goto small_rem; /* already close to next sec, don't sleep */
	}
	- /* Need to sleep.
	- * Note that small adj on slow processors can make us
	- * to always overshoot tv.tv_usec < 1024 check on next
	- * iteration. That's why adj is increased on each iteration.
	- * This also allows it to be reused as a loop limiter.
	- */
	- usleep(rem_usec - adj);
	- }

	- xioctl(rtc, RTC_SET_TIME, &tm_time);
	+ /* Try to sync up by sleeping */
	+ usleep(rem_usec - adj);

	- /* Debug aid to find "good" TWEAK_USEC.
	+ /* Jump to 1ms diff, then increase fast (x2): EVERY loop
	+ * takes ~1 sec, people won't like slowly converging code here!
	+ */
	+ //bb_error_msg("adj:%d tv.tv_usec:%d", adj, (int)tv.tv_usec);
	+ if (adj < 512)
	+ adj = 512;
	+ /* ... and if last "overshoot" does not look insanely big,
	+ * just use it as adj increment. This makes convergence faster.
	+ */
	+ if (tv.tv_usec < adj * 8) {
	+ adj += tv.tv_usec;
	+ continue;
	+ }
	+ adj *= 2;
	+ }
	+ /* Debug aid to find "optimal" TWEAK_USEC with nearly exact sync.
	* Look for a value which makes tv_usec close to 999999 or 0.
	- * for 2.20GHz Intel Core 2: TWEAK_USEC ~= 200
	+ * For 2.20GHz Intel Core 2: optimal TWEAK_USEC ~= 200
	*/
	- //bb_error_msg("tv.tv_usec:%d adj:%d", (int)tv.tv_usec, adj);
	+ //bb_error_msg("tv.tv_usec:%d", (int)tv.tv_usec);
	+#endif
	+
	+ tm_time.tm_isdst = 0;
	+ xioctl(rtc, RTC_SET_TIME, &tm_time);

	if (ENABLE_FEATURE_CLEAN_UP)
	close(rtc);