I have a struct:

typedef struct {
  uint8_t month;  //  1..12 [4 bits]
  uint8_t date;   //  1..31 [5 bits]
  uint8_t hour;   // 00..23 [5 bits]
  uint8_t minute; // 00..59 [6 bits]
  uint8_t second; // 00..59 [6 bits]
} TimeStamp;

but I would like to pack it so it only consumes four bytes instead of five.

Is there a way of shifting the bits to create a tighter struct?

It might not seem much, but it is going into EEPROM, so one byte saved is an extra 512 bytes in a 4 KB page (and I can use those extra six bits left over for something else too).

  • 3
    You could save some bytes in data but how many bytes are you using in code to pack and unpack the data and how much longer does the code take to run.
    – cup
    May 25 '18 at 18:26
  • 2
    I am kinda surprised this isn't a duplicate.
    – IS4
    May 25 '18 at 19:46
  • I do not like packing mapping fields into non-byte bounded boundaries. But if I must I would leave the struct as-is and write a pack function to pack the fields into the smaller data array/field. I would also write an unpack function. This way if something goes wrong, I can trace it and it is repeatable and testable. I would not try to create a packed struct first ... simply create a normal struct and pack that. I think the answer provided by @Laurijssen is a very good one and you can write a function around his answer.
    – Xofo
    May 26 '18 at 15:25
  • @cup As I asked in my question, the data is stored in an EEPROM, not data (RAM) so speed and a few extra bytes used in code are not so important here.
    – Kent
    May 27 '18 at 21:54
  • The timestamp comes from an MCP79411 RTCC which outputs date/time in BCD format. MCU is an ATMEGA2560 (hence 4k EEPROM).
    – Kent
    May 27 '18 at 22:16

You're looking for bitfields.

They look like this:

typedef struct {
  uint32_t month  : 4;   // 1..12 [4 bits]
  uint32_t date   : 5;   // 1..31 [5 bits]
  uint32_t hour   : 5;   // 00..23 [5 bits]
  uint32_t minute : 6;   // 00..59 [6 bits]
  uint32_t second : 6;   // 00..59 [6 bits]
} TimeStamp;

Depending on your compiler, in order to fit into four bytes with no padding, the size of the members must be four bytes (i.e. uint32_t) in this case. Otherwise, the struct members will get padded to not overflow on each byte boundary, resulting in a struct of five bytes, if using uint8_t. Using this as a general rule should help prevent compiler discrepancies.

Here's an MSDN link that goes a bit in depth into bitfields:

C++ Bit Fields

  • 4
    Since you linked to MSDN, it's worth mentioning that different compilers may also apply additional restrictions: my experience has been that VS will add a new storage unit on a change of declared type, whereas GCC (which Arduino uses) will continue to pack fields of different types into the same storage unit as long as they don't overrun. Always using the same type is still better for consistency of course.
    – Leushenko
    May 25 '18 at 9:54
  • 5
    Only bitfields of unsigned int, singed int, and _Bool are guaranteed to be supported by all C compilers (int is allowed as well, but in the context of bitfields, int can be signed or unsigned, depending on the implementation, so there's no point in really using it). GCC supports other types as an extension. uint32_t is likely a typedef for unsigned int, so this is probably compliant (still better to be explicit and use unsigned int). Also, the alignment is unspecified, so in this example, without the last bitfield, there could be 12 bits of padding.
    – SJL
    May 25 '18 at 14:02
  • 1
    @SJL seeing as this question is tagged C++, that's irrelevant. In C++, any integral or enumeration type is allowed: en.cppreference.com/w/cpp/language/bit_field
    – Justin
    May 25 '18 at 17:25
  • 6
    @Cubic Also the "singed int". Not enough cooling on the processor...?
    – Graham
    May 25 '18 at 17:43
  • 1
    @Cubic "Better be correct and use unsigned int" would've been more accurate, but I think SJL saying "explicit" here was a reasonable (though poor) gloss for the idea "explicitly choose the type that is actually correct". Using one of the fixed-size ints doesn't even make semantic sense here, because it's saying: "I want a 32-bit unsigned integer but make it 4 bits", which is like saying "I want a red line but make it blue".
    – mtraceur
    May 25 '18 at 20:29

Bitfields are one "right" way to do this in general, but why not just store seconds since the start of the year instead? 4 bytes is enough to comfortably store these; in fact, 4 bytes are enough to store the seconds between 1970 and 2038. Getting the other information out of it is then a simple exercise as long as you know the current year (which you could store together with the rest of the information as long as the range of times you're interested in covers less than 70 years (and even then you could just group timestamps into 68 year ranges and store an offset for each range).

  • 3
    one problem with storing seconds like that is that it'll be expensive to calculate the real date, esp. in embedded systems when you don't have hardware division or even multiplication
    – phuclv
    May 25 '18 at 14:03
  • @LưuVĩnhPhúc: If one wants to do any kind of arithmetic involving times (e.g. figure out what the date/time will be 48 minutes from now), having one routine to convert "calendar format" into linear seconds and one to convert linear seconds into calendar format is likely to be more efficient than trying to do calculations with calendar format. If you use March 1, 2003 as a base date, find the calendar date associated with date d by initializing year to 3, then while d is at least 1461 subtract 1461 and add 4 to year. Then while d is greater than 365, subtract 365 and add 1...
    – supercat
    May 25 '18 at 20:29
  • to year. Then subtract out the number of days in each month (starting with March) until d goes negative, keeping track of which month caused that to happen. Add 1 to d and add 1 to the year if the month was January or February and you're done. As I think about it, some further efficiency improvements may be possible, but the operations involved are well within the range of even a tiny micro.
    – supercat
    May 25 '18 at 20:34
  • [upon further consideration, my intended 2003 simplification doesn't work quite right, so using March 1, 2000 as I did for code I've been using since around 2002 is probably better].
    – supercat
    May 25 '18 at 20:43
  • @supercat - You mean a variant of Zeller's congruence. Use 30.61 for the month multiplier - 30.6 has rounding errors. Always starts on March 1.
    – cup
    May 29 '18 at 12:16

Another solution is to store the values in one 32 bits variable and retrieve the individual items with bitshifting.

uint32_t timestamp = xxxx;

uint8_t month = timestamp & 0x0F;
uint8_t date = (timestamp & 0x1F0) >> 4;
uint8_t hour = (timestamp & 0x3E00) >> 9;
uint8_t minute = (timestamp & 0xFC000) >> 14;
uint8_t second = (timestamp & 0x3F00000) >> 20;
  • 3
    Which is programmer-driven bitfields. :)
    – Eric Brown
    May 25 '18 at 20:30
  • And don't forget that changing the value of a bitfield with this approach will require twice the number of manual actions: 1) mask destination, and only 2) or in the value. And many of those magic constants will require changing if you e.g. expand a single field. In other words, maintenance nightmare.
    – Ruslan
    May 26 '18 at 6:55
  • A nice approach. In C++ I think you can automate which numbers to "and" and shift with by templates to avoid the potential maintenance nightmares pointed out by @Ruslan. May 26 '18 at 8:18
  • Or you can just use bitfields.
    – Sneftel
    May 26 '18 at 8:25
  • I think this is the -most- correct and safe way to do it. From my experience, this method is much more easily tested (in unit testing), and is portable. With a bitfield I would be concerned if the compiler does something different or if an optimization messes something up.
    – Xofo
    May 26 '18 at 15:28

If you can deal with two-second accuracy, the MS-DOS timestamp format used 16 bits to hold the date (year-1980 as 7 bits, month as 4, day as 5) and 16 bits for the time (hour as five, minute as six, seconds as five). On a processor like the Arduino, it may be possible to write code that splits values across a 16-bit boundary, but I think code will be more efficient if you can avoid such a split (as MS-DOS did by accepting two-second accuracy).

Otherwise, as was noted in another answer, using a 32-bit number of seconds since some base time will often be more efficient than trying to keep track of things in "calendar format". If all you ever need to do is advance from one calendar-format date to the next, the code to do that may be simpler than code to convert between calendar dates and linear dates, but if you need to do much of anything else (even step backward from a date to the previous one) you'll likely be better off converting dates to/from linear format when they're input or displayed, and otherwise simply work with linear numbers of seconds.

Working with linear numbers of seconds can be made more convenient if you pick as a baseline date March 1 of a leap year. Then while the date exceeds 1461, subtract that from the date and add 4 to the year (16-bit comparison and subtraction are efficient on the Arduino, and even in 2040 the loop may still take less time than a single 16x16 division). If the date exceeds 364, subtract 365 and increment the year, and try that up to twice more [if the date is 365 after the third subtraction, leave it].

Some care is needed to ensure that all corner cases work correctly, but even on a little 8-bit or 16-bit micro, conversions can be surprisingly efficient.

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