I read that the order of bit fields within a struct is platform specific. What about if I use different compiler-specific packing options, will this guarantee data is stored in the proper order as they are written? For example:

struct Message
  unsigned int version : 3;
  unsigned int type : 1;
  unsigned int id : 5;
  unsigned int data : 6;
} __attribute__ ((__packed__));

On an Intel processor with the GCC compiler, the fields were laid out in memory as they are shown. Message.version was the first 3 bits in the buffer, and Message.type followed. If I find equivalent struct packing options for various compilers, will this be cross-platform?

  • 21
    Since a buffer is a set of bytes, not bits, "the first 3 bits in the buffer" isn't a precise concept. Would you consider the 3 lowest-order bits of the first byte to be the first 3 bits, or the 3 highest-order bits?
    – caf
    Sep 29, 2009 at 3:07
  • 2
    When transiting on the network, "The first 3 bits in the buffer" turns out to be very well defined.
    – Joshua
    Dec 12, 2011 at 19:02
  • 3
    @Joshua IIRC, Ethernet transmits the least-significant bit of each byte first (which is why the broadcast bit is where it is).
    – tc.
    Jan 8, 2014 at 1:31
  • 1
    When you say "portable" and "cross-platform" which do you mean? The executable will correctly access the order regardless of target OS -- or -- the code will compile regardless of toolchain? Aug 8, 2019 at 21:16

7 Answers 7


No, it will not be fully-portable. Packing options for structs are extensions, and are themselves not fully portable. In addition to that, C99 §, paragraph 10 says: "The order of allocation of bit-fields within a unit (high-order to low-order or low-order to high-order) is implementation-defined."

Even a single compiler might lay the bit field out differently depending on the endianness of the target platform, for example.

  • 3
    Yeah, the GCC, for instance, specifically notes that bitfields are arranged as per the ABI, not the implementation. So, just staying on a single compiler is not sufficient to guarantee ordering. The architecture has to be checked, too. A bit of a nightmare for portability, really. Jan 5, 2016 at 13:34
  • 13
    Why didn't the C standard guarantee an order for bit fields? Mar 14, 2016 at 23:01
  • 10
    It's difficult to consistently and portably define "order" of bits within bytes, much less the order of bits that may cross byte boundaries. Any definition the you settle on will fail to match a considerable amount of existing practice. Mar 14, 2016 at 23:20
  • 4
    implementaiton-defined allows for platform-specific optimization. On some platforms, padding between the bit fields can improve access, imagine four seven-bit fields in a 32 bit int: aligning them at every 8th bit is a significant improvement for platforms that have byte reads.
    – peterchen
    Sep 9, 2016 at 13:48
  • does packed enforce ordering: stackoverflow.com/questions/1756811/… how to enforce bit ordering: stackoverflow.com/questions/6728218/gcc-compiler-bit-order Jul 30, 2017 at 11:10

Bit fields vary widely from compiler to compiler, sorry.

With GCC, big endian machines lay out the bits big end first and little endian machines lay out the bits little end first.

K&R says "Adjacent [bit-]field members of structures are packed into implementation-dependent storage units in an implementation-dependent direction. When a field following another field will not fit ... it may be split between units or the unit may be padded. An unnamed field of width 0 forces this padding..."

Therefore, if you need machine independent binary layout you must do it yourself.

This last statement also applies to non-bitfields due to padding -- however all compilers seem to have some way of forcing byte packing of a structure, as I see you already discovered for GCC.

  • 1
    Is K&R really considered a useful reference, given that it was pre-standardisation and has (I assume?) probably been superseded in many areas? Jan 5, 2016 at 13:33
  • 2
    My K&R is post-ANSI.
    – Joshua
    Jan 5, 2016 at 16:13
  • 2
    Now that is embarrassing: I didn't realise they'd released a post-ANSI revision. My bad! Jan 5, 2016 at 16:15

Bitfields should be avoided - they aren't very portable between compilers even for the same platform. from the C99 standard - "Structure and union specifiers" (there's similar wording in the C90 standard):

An implementation may allocate any addressable storage unit large enough to hold a bitfield. If enough space remains, a bit-field that immediately follows another bit-field in a structure shall be packed into adjacent bits of the same unit. If insufficient space remains, whether a bit-field that does not fit is put into the next unit or overlaps adjacent units is implementation-defined. The order of allocation of bit-fields within a unit (high-order to low-order or low-order to high-order) is implementation-defined. The alignment of the addressable storage unit is unspecified.

You cannot guarantee whether a bit field will 'span' an int boundary or not and you can't specify whether a bitfield starts at the low-end of the int or the high end of the int (this is independant of whether the processor is big-endian or little-endian).

Prefer bitmasks. Use inlines (or even macros) to set, clear and test the bits.

  • 3
    The order of bitfields can be determined at compile time. Jul 26, 2013 at 18:37
  • 10
    Also, bitfields are highly preferred when dealing with bit flags that have no external representation outside the program (i.e. on disk or in registers or in memory accessed by other programs, etc). Jul 26, 2013 at 18:38
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    @GregA.Woods: If this really is the case, please provide an answer describing how. I could not find anything but your comment when googling for it...
    – mozzbozz
    Dec 11, 2014 at 13:57
  • 1
    @GregA.Woods: Sorry, should have written to which comment I referred. I meant: You say that "The order of bitfields can be determined at compile time.". I cannot anything about it and how to do it.
    – mozzbozz
    Jan 5, 2015 at 11:53
  • 2
    @mozzbozz Have a look at planix.com/~woods/projects/wsg2000.c and search for definitions and use of _BIT_FIELDS_LTOH and _BIT_FIELDS_HTOL Jan 12, 2015 at 22:22

endianness are talking about byte orders not bit orders. Nowadays , it is 99% sure that bit orders are fixed. However, when using bitfields, endianness should be taken in count. See the example below.

#include <stdio.h>

typedef struct tagT{

    int a:4;
    int b:4;
    int c:8;
    int d:16;

int main()
    char data[]={0x12,0x34,0x56,0x78};
    T *t = (T*)data;
    printf("a =0x%x\n" ,t->a);
    printf("b =0x%x\n" ,t->b);
    printf("c =0x%x\n" ,t->c);
    printf("d =0x%x\n" ,t->d);

    return 0;

//- big endian :  mips24k-linux-gcc (GCC) 4.2.3 - big endian
a =0x1
b =0x2
c =0x34
d =0x5678
 1   2   3   4   5   6   7   8
\_/ \_/ \_____/ \_____________/
 a   b     c           d

// - little endian : gcc (Ubuntu 4.3.2-1ubuntu11) 4.3.2
a =0x2
b =0x1
c =0x34
d =0x7856
 7   8   5   6   3   4   1   2
\_____________/ \_____/ \_/ \_/
       d           c     b   a
  • 8
    The output of a and b indicates that endianness is still talking about bit orders AND byte orders. Sep 29, 2009 at 5:03
  • wonderful example with bit ordering and byte ordering problematics
    – Jonathan
    Nov 4, 2016 at 11:16
  • 2
    Did you actually compile and run the code? The values for "a" and "b" don't seem logical to me: you are basically saying that the compiler will swap the nibbles within a byte because of endianness. In the case of "d", endiannes should not affect the byte order within char arrays (assuming char is 1 byte long); if the compiler did that, we wouldn't be able to iterate through an array using pointers. If, on the other hand you had used an array of two 16 bit integers e.g.: uint16 data[]={0x1234,0x5678}; then d would definitely be 0x7856 in little endian systems.
    – Krauss
    Sep 12, 2017 at 10:25
  • 1
    if the standard says "implementation-defined" then all bets are off.
    – kbro
    Jun 29, 2021 at 12:06

Most of the time, probably, but don't bet the farm on it, because if you're wrong, you'll lose big.

If you really, really need to have identical binary information, you'll need to create bitfields with bitmasks - e.g. you use an unsigned short (16 bit) for Message, and then make things like versionMask = 0xE000 to represent the three topmost bits.

There's a similar problem with alignment within structs. For instance, Sparc, PowerPC, and 680x0 CPUs are all big-endian, and the common default for Sparc and PowerPC compilers is to align struct members on 4-byte boundaries. However, one compiler I used for 680x0 only aligned on 2-byte boundaries - and there was no option to change the alignment!

So for some structs, the sizes on Sparc and PowerPC are identical, but smaller on 680x0, and some of the members are in different memory offsets within the struct.

This was a problem with one project I worked on, because a server process running on Sparc would query a client and find out it was big-endian, and assume it could just squirt binary structs out on the network and the client could cope. And that worked fine on PowerPC clients, and crashed big-time on 680x0 clients. I didn't write the code, and it took quite a while to find the problem. But it was easy to fix once I did.


Thanks @BenVoigt for your very useful comment starting

No, they were created to save memory.

Linux source does use a bit field to match to an external structure: /usr/include/linux/ip.h has this code for the first byte of an IP datagram

struct iphdr {
        __u8    ihl:4,
#elif defined (__BIG_ENDIAN_BITFIELD)
        __u8    version:4,
#error  "Please fix <asm/byteorder.h>"

However in light of your comment I'm giving up trying to get this to work for the multi-byte bit field frag_off.


Of course the best answer is to use a class which reads/writes bit fields as a stream. Using the C bit field structure is just not guaranteed. Not to mention it is considered unprofessional/lazy/stupid to use this in real world coding.

  • 6
    I think it is wrong to state that it is stupid to use bit fields since it provide a very clean way to represent hardware registers, which it was created to model, in C.
    – trondd
    Aug 11, 2011 at 6:26
  • 15
    @trondd: No, they were created to save memory. Bitfields aren't intended to map to outside data structures, such as memory-mapped hardware registers, network protocols, or file formats. If they were intended to map to outside data structures, the packing order would have been standardized.
    – Ben Voigt
    Jan 22, 2013 at 16:16
  • 4
    Using bits saves memory. Using bit fields increases readability. Using less memory is faster. Using bits allows for more complex atomic operations. In out applications in the real world, there is need for performance and complex atomic operations. This answer wouldn't work for us. Jul 27, 2015 at 17:07
  • 3
    @BenVoigt probably true, but if a programmer is willing to confirm that the ordering of their compiler/ABI matches what they need, and sacrifice quick portability accordingly - then they certainly can fulfil that role. As for 9*, which authoritative mass of "real world coders" consider all use of bitfields to be "unprofessional/lazy/stupid" and where did they state this? Jan 5, 2016 at 13:44
  • 5
    Using less memory is not always faster; it is often more efficient to use more memory and reduce post-read operations, and the processor/processor mode can make that even more true. Sep 27, 2018 at 14:17

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