I am building a embedded project which displays the time retrieved from a GPS module on a display, but I would also like to display the current date. I currently have the time as a unix time stamp and the progject is written in C.

I am looking for a way to calculate the current UTC date from the timestamp, taking leap years into account? Remember, this is for an embedded project where there is no FPU, so floating point math is emulated, avoiding it as much as possible for performance is required.


After looking at @R...'s code, I decided to have a go a writing this myself and came up with the following.

void calcDate(struct tm *tm)
  uint32_t seconds, minutes, hours, days, year, month;
  uint32_t dayOfWeek;
  seconds = gpsGetEpoch();

  /* calculate minutes */
  minutes  = seconds / 60;
  seconds -= minutes * 60;
  /* calculate hours */
  hours    = minutes / 60;
  minutes -= hours   * 60;
  /* calculate days */
  days     = hours   / 24;
  hours   -= days    * 24;

  /* Unix time starts in 1970 on a Thursday */
  year      = 1970;
  dayOfWeek = 4;

    bool     leapYear   = (year % 4 == 0 && (year % 100 != 0 || year % 400 == 0));
    uint16_t daysInYear = leapYear ? 366 : 365;
    if (days >= daysInYear)
      dayOfWeek += leapYear ? 2 : 1;
      days      -= daysInYear;
      if (dayOfWeek >= 7)
        dayOfWeek -= 7;
      tm->tm_yday = days;
      dayOfWeek  += days;
      dayOfWeek  %= 7;

      /* calculate the month and day */
      static const uint8_t daysInMonth[12] = {31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31};
      for(month = 0; month < 12; ++month)
        uint8_t dim = daysInMonth[month];

        /* add a day to feburary if this is a leap year */
        if (month == 1 && leapYear)

        if (days >= dim)
          days -= dim;

  tm->tm_sec  = seconds;
  tm->tm_min  = minutes;
  tm->tm_hour = hours;
  tm->tm_mday = days + 1;
  tm->tm_mon  = month;
  tm->tm_year = year;
  tm->tm_wday = dayOfWeek;
  • What about leap seconds? – wonce Feb 6 '14 at 4:00
  • Only if the absence of their calculation will cause a large margin of error (which I doubt). – Geoffrey Feb 6 '14 at 4:02
  • UTC and GPS time are 16 seconds different right now due to leap seconds. This will not vary quickly. In other words, if you're just displaying the current date, you can ignore leap seconds. – kmort Feb 6 '14 at 4:21
  • If the epoch time is derived from the GPS module, it will probably have leap seconds accounted for - GPS transmits the difference between GPS and UTC time every 13.5 minutes, the standard NMEA0183 RMC sentence time is defined as UTC time, not GPS time, the module should apply the offset before output. GLONASS (Russian GNSS) tracks leap seconds and transmits UTC time directly from the constellation. – Clifford Feb 6 '14 at 19:48
  • @Clifford - I am not using NMEA, but the SiRF binary protocol. It seems that the 16 seconds are also accounted for here as the timestamp I derive from the module is only 1-2 seconds out with my NTP synced time on my PC. – Geoffrey Feb 6 '14 at 22:27

First divide by 86400; the remainder can be used trivially to get the HH:MM:SS part of your result. Now, you're left with a number of days since Jan 1 1970. I would then adjust that by a constant to be the number of days (possibly negative) since Mar 1 2000; this is because 2000 is a multiple of 400, the leap year cycle, making it easy (or at least easier) to count how many leap years have passed using division.

Rather than trying to explain this in more detail, I'll refer you to my implementation:


  • 1
    +1 for shift the the beginning of the year to March 1. That makes Oct ober the 8th month and Dec ember the 10th month - as it was long ago. – chux Feb 6 '14 at 16:31
  • I never even thought of that part. I just think it makes handling leap years in units of days easier, since the extra day is exactly at the end of the year rather than in the middle. – R.. Feb 6 '14 at 20:27
  • The Romans put Leap day in the traditional last month (February). They also shifted the 1st day of the year from sometime in March to January 1st. – chux Feb 6 '14 at 20:58

It is not clear why you cannot use the standard library; if size is an issue, only the library components used by your code will be linked, and time_t to struct tm conversion will be pretty small, but more importantly correct and eficient.

However a better question is why you would not use the data directly from the GPS module? It is in the eighth field of the standard RMC sentence that is almost certainly output by the device.

Example for 25 November 2011:


  • Because my GPS module is not returning NMEA data but is returning SiRF binary protocol, which returns a number of weeks, and the seconds since the start of the week. Also, I can not use the standard library simply because it is not implemented in the environment I need to use. – Geoffrey Feb 6 '14 at 22:25
  • Fair enough, but perhaps the problem you need to solve is the lack of standard library? – Clifford Feb 7 '14 at 18:09
  • I don't know about SiRF, but uBlox can output both UBX and NMEA mixed. While SiRF is proprietary NMEA is ubiquitous, so using NMEA will give you wider portability too. – Clifford Feb 7 '14 at 18:14
  • This is a one off project, portability is not desired. Also, while NMEA is portable, it is also a text based protocol, which wastes resources, SiRF is binary and is much easier processor wise to handle. – Geoffrey Feb 14 '14 at 0:21
  • @Geoffrey: Fair enough. I think my answer remains useful to anyone else handling GPS data - I'll leave it in if you don't mind? I suggest however that using a C library is still an option - there are a number of portable implementations. Newlib for example - you could even just use the source code for mktime directly, and discard the rest. – Clifford Feb 14 '14 at 6:56

Here's a portable implementation of mktime(). It includes support for DST that you might remove in order reduce the size somewhat for UTC only. It also normalizes the data (so if for example you had 65 seconds, it would increment the minute and set the seconds to 5, so perhaps has some overhead that you don't need.

It seems somewhat more complex than the solution you have arrived at already; you may want to consider whether there is a reason for that? I would perhaps implement both as a test (on a PC rather than embedded) and iterate through a large range of epoch time values and compare the results with the PC compiler's own std::mktime (using C++ will avoid the name clash without having to rename). If they all produce identical results, then use the fastest/smallest implementation as required, otherwise use the one that is correct!

I think that the typical library mktime performs a binary convergence comparing the return of localtime() with the target. This is less efficient than a direct calendrical calculation, but I presume is done to ensure that a round-trip conversion from struct tm to time_t (or vice versa) and back produces the same result. The portable implementation I suggested above uses the same convergence technique but replaces localtime() to remove library dependencies. On reflection therefore, I suspect that the direct calculation method is preferable in your case since you don't need reversibility - so long as it is correct of course.

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