Let's start by looking at the first two:
54 FE C0 72 =(25-oct-13 20:34:58)
54 FE C0 78 =(25-oct-13 20:35:04)
These two dates are 6 seconds apart, and the values differ by 6. So we know that at least the last byte specifies seconds.
55 01 DC 8B =(26-oct-13 22:34:51)
55 01 E3 93 =(26-oct-13 23:04:51)
Similarly, these two are are 30 minutes (1800 seconds) apart, and the values differ by 1800. So at least the last two bytes specify seconds.
54 FE C0 78 =(25-oct-13 20:35:04)
55 01 DC 8B =(26-oct-13 22:34:51)
There's a larger range in the values, but note that the last two bytes seem to be fairly close in value. Taking DC8Bh - C078h gives us 1C13h = 7187d. That's a difference of 2 hours (7200 seconds) minus 13 seconds, which is how far apart the time portions of the two dates are. So it looks like the last two bytes specify the time. However, there are 86400 seconds in a day, and C078h = 49272d which would be closer to around 13:00:00 than 20:35:04, that and the largest value you can store in 16 bits is 65535. Also, the first two bytes differ by 3 but the dates differ by 1. Let's come back to that in a bit.
55 01 DC 8B =(26-oct-13 22:34:51)
57 01 DC 8B =(14-Apr-14 14:34:51)
Note here that the last two bytes are the same, and that the minutes and seconds are the same, although the hours differ by 8. So perhaps the last two bytes specify seconds in part of a day. Going back to the prior example, the first two bytes differed by 3 when the dates differed by 1. So perhaps the first two bytes specify an 8 hour interval. This would account for the last two bytes being the same when the time differs by 8 or 16 hours. If we take 5701h - 5501h we get 200h = 512d. Dividing by 3 we get 169 2/3 days. The two dates above differ by 170 days, and if you take the hours into account it's about 169 2/3.
So now we have dates. 5501h is the third 8-hour interval in 26-oct-13, so the start of the day is 54FFh = 21759d. Dividing by 3 gives us 7253. Counting back days, that gives us an epoch date of 1993-12-17.
Now lets go back to the time. Assuming the last two bytes are seconds in an 8-hour interval. That gives us a maximum value of 28800d. Note that this value only needs 15 bits to store. DC8Bh has the highest bit set, so let's see what we get if we mask that bit out. That gives us 5C8Bh = 23691d, and 23691 seconds is 6 hours 34 minutes 51 seconds. That matches the third and fifth examples with a difference of 8 hours.
As for the most significant bit in the third byte, my guess is that is specifies DST. All the examples have this bit set, and all the dates are when DST is active.
So to summarize:
- The first two bytes divided by 3 is number of days since 1993-12-17.
- The first two bytes mod 3 is the 8-hour interval in the day. Multiply this value by 28800 (i.e. seconds in 8 hours) to set the initial time in seconds.
- The last two bytes with the most significant bit masked out are seconds from the start of the 8-hour interval. Add this value to the value from the prior step to get seconds from midnight.
- Check the most significant bit in the third byte to set the DST flag.
EDIT:
So it seems the result this algorithm gives for 57 01 DC 8B =(14-Apr-14 14:34:51) is ahead by one day. Let's look at one of the new examples:
42 23 8F 96 =(02-Jun-09 17:06:30)
Our algorithm give a date of 30-May-09, so it's behind by 3 days. This is interesting because it differs from what we got for 25-Oct-13 and 26-Oct-13 by about 4 years. What's different is that there's a leap year in between. So perhaps this encoding is assuming all years have 366 days. If we go back to the epoch date of 1993-12-17, we see that there are 15 non-leap years from 1994 to 2013 inclusive. That give us a new epoch date of 1994-1-1, which makes more sense. So after doing the initial conversion with 1994-1-1 as the epoch, we need to count the number of non-leap years and subtract that many days.
Now let's look at this one:
3A F4 28 49 =(12-Oct-99 18:51:53)
The time is still correct, but the date is way off. Notice however that the most significant bit of byte 3 is NOT set. This seems to indicate a different epoch. The start of 12-Oct-99 is 3AF2h = 15090d. Dividing by 3 gives us 5030. Counting backward gives us an epoch of 1986-01-03. But then there's this:
00000000 = 1-Jan-1986
00030000 = 1-jan-1986
So it looks like 1986-1-1 is the epoch, but there's a special case in place for this date, so the actual epoch is 1985-12-31.
But, we're off by 3 days. If all years had 366 days, this would not be the case. It would work however if all years had 365 days. This means that for the 1985-12-31 epoch, we need to count the number of leap years and add that many days. This is the opposite of what we need to do with the 1994-1-1 epoch.
This now works for almost everything. Everything except these:
3C F5 28 4B= (31-Mar-00 18:51:55)
1C567004=15-aug-92 07:57:56
But it does work for this:
2B067004=21-jan-96 15:57:56
So it looks like this encoding does do a leap year check, but only for the current year.
Taking these changes to the algorithm and applying them to the code provided by LPs, we now have this:
#include <stdlib.h>
#include <string.h>
#include <stdint.h>
#include <time.h>
int isleap(int year)
{
if (year % 4 != 0) return 0;
if (year % 100 != 0) return 1;
if (year % 400 != 0) return 0;
return 1;
}
int main(int argc, char *argv[])
{
// Read encoding from command line
uint32_t datetime = strtoul(argv[1],NULL,16);
uint16_t mydate = datetime >> 16;
uint16_t mytime = datetime & 0xFFFF;
int new_encoding = (mytime & 0x8000) != 0;
// Calculate days
time_t linuxSeconds = (mydate/3);
// Calculate the 8 hours on current day of date
uint8_t third_Count = mydate % 3;
// Add days from 1/1/1970, that is the base of time in linux
if (new_encoding)
{
// Days between 1970-1-1 and 1994-1-1 minus 1
linuxSeconds += 8765;
}
else
{
// Days between 1970-1-1 and 1986-1-1 minus 1
linuxSeconds += 5843;
}
// Calculate total amount of hours
linuxSeconds *= 24;
// Calculate total amount of seconds
linuxSeconds *= 3600;
// Add seconds of last 8 hours group
linuxSeconds += (mytime & 0x7FFF);
// Add alla seconds of grups of 8 hours of date
linuxSeconds += (third_Count * 28800);
// Add or subtract days depending on whether new_encoding is set
struct tm *mytm = gmtime(&linuxSeconds);
int daydiff = 0, year;
for (year = new_encoding ? 1994 : 1986; year <= mytm->tm_year + 1900; year++) {
if (year < mytm->tm_year + 1900) {
if (new_encoding) {
// remove a day for non-leap years
if (!isleap(year)) {
daydiff--;
}
} else {
// add a day for leap years unless it's the current year
if (year != (mytm->tm_year + 1900) && isleap(year)) {
daydiff++;
}
}
}
}
if (mydate < 0x0003) {
// special case for day 0
linuxSeconds += 86400;
} else {
linuxSeconds += daydiff * 86400;
}
// Print the date with actual GMT
printf(ctime(&linuxSeconds));
// Print Greenwich time
printf(asctime(gmtime(&linuxSeconds)));
return 0;
}
One caveat about this code: if it's run on a system where time_t is 32-bit, it won't be able to properly display dates after 2038. If time_t is 64-bit, those dates will display properly.
EDIT 2:
There was an issue with code 30068000 being one day ahead. There was a bug in the code when checking the current month. The tm_mon field in struct tm ranges from 0 to 11, not 1 to 12. Fixed.
EDIT 3:
So it seems the month/day check when adding/subtracting days was just plain wrong, as it was causing Feb 28 to appear twice. When I removed that, I found that the 1994 scheme was a day ahead, so it looks like it has the same special case for day 0 that the 1986 scheme has. Fixed again.
