6

Is it possible to write a macro in C which takes an uint32_t and converts it to big endian representation no matter if the target system is little or big endian such that the macro can be evaluated at compile-time for a constant?

I found this question: endianness conversion, regardless of endianness, however, the answers only provide functions. My situation is that I would like a compile-time expression to be able to write something like this:

const uint32_t magic_number = BIGENDIAN32(0x12345678);
3
  • Do you want that the macro outputs an integer that is stored always the same way in memory, ie. 0x12 in lowest address, then 0x34 in address+1, etc... ? Sep 17, 2019 at 14:01
  • 2
    If you need a magic number (so something that has no numerical meaning), why not declare an array of 4 bytes ? Sep 17, 2019 at 14:05
  • @GuillaumePetitjean Yes, that is correct. For the storage, I could of course declare it as an array, but I would also need to compare the value by an integer comparison. Besides, I started wondering if this is possible as described.
    – nielsen
    Sep 17, 2019 at 14:22

3 Answers 3

4

You can use a union, which is endianess-dependent, together with bit shifts that don't depend on endianess. Run-time version:

uint32_t big_endian (uint32_t n)
{
  union
  {
    uint32_t u32;
    uint8_t  u8 [4];
  } be;

  for(size_t i=0; i<4; i++)
  {
    size_t shift = (4-1-i) * 8;
    be.u8[i] = (n >> shift) & 0xFFu;
  }
  return be.u32;
}

u8[0] will always contain the MS byte on big endian machines. However, n >> shift will grab the relevant byte portably. Notably the whole function is just overhead bloat when running on a big endian machine.

Converting this to an ugly compile-time macro would be something like this:

typedef union
{
  uint32_t u32;
  uint8_t  u8 [4];
} be_t;


#define BIG_ENDIAN(n) ( _Generic((n), uint32_t: (void)0), \
  (be_t){ .u8 = { ((n) >> 24)&0xFFu,                      \
                  ((n) >> 16)&0xFFu,                      \
                  ((n) >>  8)&0xFFu,                      \
                   (n)&0xFFu } }.u32)

The _Generic check + , operator is just for type safety and can be removed if stuck with non-standard C. The macro uses a temporary union in the form of a compound literal (outer {}), initializes the u8 array (inner {}) then returns a uint32_t value.

Trying BIG_ENDIAN(0x12345678) on little endian x86 and disassembling, I get:

mov     esi, 2018915346

2018915346 dec = 0x78563412

10
  • (gcc -O3 for PowerPC gives me hogwash though, no idea why. I only have accesses to older gcc ports < 5.0. Specifically, it spits out lis 9,0x1234 + ori 9,9,22136 which seems senseless 22136=0x5678.)
    – Lundin
    Sep 17, 2019 at 14:30
  • It is a nice solution, I can build it as C++, but if I build it is C, I get an error "error: initializer element is not constant" (even if I remove the _Generic check). I cannot really figure out why the compiler says that, but it does.
    – nielsen
    Sep 17, 2019 at 14:40
  • @nielsen You asked for a C solution in C11 so that would be why. This won't work at all in C++ since that language does not support union type punning.
    – Lundin
    Sep 17, 2019 at 14:41
  • Right, but I get the error message from gcc when building with -std=c11.
    – nielsen
    Sep 17, 2019 at 14:51
  • 1
    @nielsen The problem might be that you place the variable at file scope. I don't think the union/compound literal go-between is regarded as a constant expression. The macro might have to be rewritten if you intend to use it as a file scope variable initializer.
    – Lundin
    Sep 18, 2019 at 6:37
1

Consider a compound literal of a union.

#define BIGENDIAN32(x) (((union { uint8_t  u8[4]; uint32_t u32; }) \
    { {((uint32_t)(x)>>24)&255, ((uint32_t)(x)>>16)&255, \
       ((uint32_t)(x)>> 8)&255,  (uint32_t)(x)&255} }).u32) \
//    MSbyte first                                 LSByte last

int main(void) {
  const uint32_t magic_number = BIGENDIAN32(0x12345678u);
  return (int) magic_number;
}
7
  • @Lundin Hmm Certainly similar. The wrapping in _Generic and creation of be_t seems unnecessary and for me obfuscated that your answer used a compound literal. Delete this now wiki answer if you see too much commonality. Sep 17, 2019 at 14:58
  • Yeah well it's because I wrote the run-time version first. The _Generic is quite needed however, you don't wanna be right shifting signed int or everything will break upon arithmetic right shift.
    – Lundin
    Sep 17, 2019 at 15:00
  • @Lundin True, coping with a non-unsigned x makes sense. A simply cast to uint32_t would handle the concern. Sep 17, 2019 at 15:05
  • But then you create a macro which silently accepts accidental wrong types. Arrays, pointers etc.
    – Lundin
    Sep 18, 2019 at 6:33
  • When compared with bit-shifting, using union seems costly to me. See by yourself: godbolt.org/z/WKa98esd4.
    – gberth
    Aug 30, 2021 at 20:17
0

If you are using GCC you can do something like:

#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
#define BIGENDIAN32(_a_)    __builtin_bswap32 (_a_)
#else
#define BIGENDIAN32(_a_)    (_a_)
#endif

Note: doesn't take into account PDP endianness but you've got the idea

If you want the code to be portable to other compilers you have to replace the line:

#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__

by one of the macro suggested by the smart contributors of this thread and define a macro for the byte inversion builtins.

1
  • It is a good idea, though in the linked thread I am not sure anyone actually accomplished to determine endianness at compile-time (even though they thought they did :-) ).
    – nielsen
    Sep 17, 2019 at 15:06

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