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Is there a safe, portable way to determine (during compile time) the endianness of the platform that my program is being compiled on? I'm writing in C.

[EDIT] Thanks for the answers, I decided to stick with the runtime solution!

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might be your solution… to detect it runtime – khachik Nov 21 '10 at 20:00
possible duplicate of Detecting endianness programmatically in a C++ program – Kirill V. Lyadvinsky Nov 21 '10 at 20:13
See my answer which should do it at compile-time, as long as you don't mind requiring (at least partial) C99 support in the compiler. – R.. Nov 21 '10 at 20:46
What's wrong with just using #ifdef __LITTLE_ENDIAN__ etc ? – Paul R Nov 21 '10 at 21:43
@Paul: Who says __LITTLE_ENDIAN__ is an indicator that the machine is little endian and not one of two macros (along with __BIG_ENDIAN__) which are possible values for __BYTE_ORDER__? You can't know. As soon as you start inspecting macro names that were reserved for the implementation, your're on the road to the dark world of UB. Good code never directly inspects macros beginning with _[A-Z_] but instead uses a configure script or similar to work out its environment then uses #include "config.h" and #ifdef HAVE_FOO etc. – R.. Nov 22 '10 at 6:20
up vote 26 down vote accepted

This is for compile time checking

You could use information from the boost header file endian.hpp, which covers many platforms.

edit for runtime checking

bool isLittleEndian()
    short int number = 0x1;
    char *numPtr = (char*)&number;
    return (numPtr[0] == 1);

Create an integer, and read its first byte (least significant byte). If that byte is 1, then the system is little endian, otherwise it's big endian.

edit Thinking about it

Yes you could run into a potential issue in some platforms (can't think of any) where sizeof(char) == sizeof(short int). You could use fixed width multi-byte integral types available in <stdint.h>, or if your platform doesn't have it, again you could adapt a boost header for your use: stdint.hpp

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+1 for the cleanest function. – Rafe Kettler Nov 21 '10 at 20:04
This does not answer the question; it's a runtime check, not a compiletime check. – R.. Nov 21 '10 at 20:42
@R. The sentence at the top is about endian.hpp which would allow you to do compile time checks via macro checks. – birryree Nov 21 '10 at 22:17
Nod. By the way, if sizeof(char)==sizeof(short), then uint8_t cannot exist on the implementation. C99 requires uint8_t to have no padding and be exactly 8 bits, and also defines the representation of types in terms of char/bytes, so uint8_t can only exist if CHAR_BIT==8. But then short could not hold the required minimum range. :-) – R.. Nov 22 '10 at 6:17
reading the documentation of endian.hpp: it's not compile time checking the endianess. it's extracting the endianess from headers, if they're exposed. so it's not guaranteed to work. – Alex Jun 23 '14 at 0:46

With C99, you can perform the check as:

#define I_AM_LITTLE (((union { unsigned x; unsigned char c; }){1}).c)

Conditionals like if (I_AM_LITTLE) will be evaluated at compile-time and allow the compiler to optimize out whole blocks.

I don't have the reference right off for whether this is strictly speaking a constant expression in C99 (which would allow it to be used in initializers for static-storage-duration data), but if not, it's the next best thing.

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No, it isn't, not even when you give it a const for the type. – Jens Gustedt Nov 21 '10 at 21:55
Can you possibly explain why this works? – einpoklum Apr 15 at 9:13

To answer the original question of a compile-time check, there's no standardized way to do it that will work across all existing and all future compilers, because none of the existing C, C++, and POSIX standards define macros for detecting endianness.

But, if you're willing to limit yourself to some known set of compilers, you can look up each of those compilers' documentations to find out which predefined macros (if any) they use to define endianness. This page lists several macros you can look for, so here's some code which would work for those:

#if defined(__BYTE_ORDER) && __BYTE_ORDER == __BIG_ENDIAN || \
    defined(__BIG_ENDIAN__) || \
    defined(__ARMEB__) || \
    defined(__THUMBEB__) || \
    defined(__AARCH64EB__) || \
    defined(_MIBSEB) || defined(__MIBSEB) || defined(__MIBSEB__)
// It's a big-endian target architecture
#elif defined(__BYTE_ORDER) && __BYTE_ORDER == __LITTLE_ENDIAN || \
    defined(__LITTLE_ENDIAN__) || \
    defined(__ARMEL__) || \
    defined(__THUMBEL__) || \
    defined(__AARCH64EL__) || \
    defined(_MIPSEL) || defined(__MIPSEL) || defined(__MIPSEL__)
// It's a little-endian target architecture
#error "I don't know what architecture this is!"

If you can't find what predefined macros your compiler uses from its documentation, you can also try coercing it to spit out its full list of predefined macros and guess from there what will work (look for anything with ENDIAN, ORDER, or the processor architecture name in it). This page lists a number of methods for doing that in different compilers:

Compiler                   C macros                         C++ macros
Clang/LLVM                 clang -dM -E -x c /dev/null      clang++ -dM -E -x c++ /dev/null
GNU GCC/G++                gcc   -dM -E -x c /dev/null      g++     -dM -E -x c++ /dev/null
Hewlett-Packard C/aC++     cc    -dM -E -x c /dev/null      aCC     -dM -E -x c++ /dev/null
IBM XL C/C++               xlc   -qshowmacros -E /dev/null  xlc++   -qshowmacros -E /dev/null
Intel ICC/ICPC             icc   -dM -E -x c /dev/null      icpc    -dM -E -x c++ /dev/null
Microsoft Visual Studio (none)                              (none)
Oracle Solaris Studio      cc    -xdumpmacros -E /dev/null  CC      -xdumpmacros -E /dev/null
Portland Group PGCC/PGCPP  pgcc  -dM -E                     (none)

Finally, to round it out, the Microsoft Visual C/C++ compilers are the odd ones out and don't have any of the above. Fortunately, they have documented their predefined macros here, and you can use the target processor architecture to infer the endianness. While all of the currently supported processors in Windows are little-endian (_M_IX86, _M_X64, _M_IA64, and _M_ARM are little-endian), some historically supported processors like the PowerPC (_M_PPC) were big-endian. But more relevantly, the Xbox 360 is a big-endian PowerPC machine, so if you're writing a cross-platform library header, it can't hurt to check for _M_PPC.

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I'm not familiar with Microsoft's compilers, but ARM could potentially run in either endian mode. I'm not sure if it is possible to check at compile time for it. – Tyzoid Mar 10 at 21:53
So, do you feel the snippet you provided is general enough? For all the compilers you listed at least? – einpoklum Apr 15 at 9:18

I would like to extend the answers for providing a constexpr function for C++

union Mix {
    int sdat;
    char cdat[4];
static constexpr Mix mix { 0x1 };
constexpr bool isLittleEndian() {
    return mix.cdat[0] == 1;

Since mix is constexpr too it is compile time and can be used in constexpr bool isLittleEndian(). Should be safe to use.


As @Cheersandhth pointed out below, these seems to be problematic.

The reason is, that it is not C++11-Standard conform, where type punning is forbidden. There can always only one union member be active at a time. With a standard conforming compiler you will get an error.

So, don't use it in C++. It seems, you can do it in C though. I leave my answer in for educational purposes :-) and because the question is about C...

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+1. This is a really cute solution! – xmllmx Jul 11 '14 at 3:52
Ehem... "cute"? ;-) – towi Jul 18 '14 at 13:04
Aren't all these type-punning techniques implementation defined behaviour (or even undefined behaviour)? I currently don't know of implementations where reading a union meber different from the one written last really fails, but I guess strictly speaking it is non portable. – Drunix Apr 13 '15 at 16:20
–1 Fails to compile with clang (it's clever and a few weeks ago I thought it would work, then tested with clang and learned). – Cheers and hth. - Alf Feb 23 at 1:12
You can type pun by copying to a char array and back, but not through a union. – Alexandre C. Feb 25 at 13:54

Not during compile time, but perhaps during runtime. Here's a C function I wrote to determine endianness:

/*  Returns 1 if LITTLE-ENDIAN or 0 if BIG-ENDIAN  */
#include <inttypes.h>
int endianness()
  union { uint8_t c[4]; uint32_t i; } data;
  data.i = 0x12345678;
  return (data.c[0] == 0x78);
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Birryree's answer and mine overlapped, but each of our examples appears to do pretty much the same thing. – pr1268 Nov 21 '10 at 20:04
Invokes UB, you can only read from the last union member that was written to. – GManNickG Nov 21 '10 at 21:50
@GMan: I agree it's ambiguous, but that seems to conflict with other parts of the standard that explicitly allow you to access an object's representation as an overlaid char array. – R.. Nov 22 '10 at 6:13
@R: Good point. Had it been a char that would have been fine, but uint8_t isn't (necessarily) a char. (Does that mean the behavior in this case is strictly implementation-defined, instead of undefined?) – GManNickG Nov 22 '10 at 6:21

Interesting read from the C FAQ:

You probably can't. The usual techniques for detecting endianness involve pointers or arrays of char, or maybe unions, but preprocessor arithmetic uses only long integers, and there is no concept of addressing. Another tempting possibility is something like

  #if 'ABCD' == 0x41424344

but this isn't reliable, either.

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Why is this not reliable? A multi-character constant is indeed the only valid way of doing it (in C++, C99 allows the union thing). The result is of course implementation defined, but that's what it has to be since the order of bytes (which is just what you're trying to figure out!) is implementation-defined. Every other method is either undefined behavior (unions, type-punned pointers, etc), or total shit (using Boost, which is nothing but platform detection via #ifdef followed by a hand-coded #define). – Damon Feb 10 at 15:01
One might be tempted to try with wide character literals in C++14 instead (I actually did try, since GCC annoyingly warns about multi-character literals) but it turns out that the standard is pretty prohibitive in what you can cast them to, and anything I tried fails with an error. Something like if( (char[4])(U'A')[0] == 65) would do, if the cast was legal. But the multi-character constant is indeed completely legal as-is. – Damon Feb 10 at 15:05

I once used a construct like this one:

uint16_t  HI_BYTE  = 0,
          LO_BYTE  = 1;
uint16_t  s = 1;

if(*(uint8_t *) &s == 1) {   
   HI_BYTE = 1;
   LO_BYTE = 0;

pByte[HI_BYTE] = 0x10;
pByte[LO_BYTE] = 0x20;

gcc with -O2 was able to make it completely compile time. That means, the HI_BYTE and LO_BYTE variables were replaced entirely and even the pByte acces was replaced in the assembler by the equivalent of *(unit16_t *pByte) = 0x1020;.

It's as compile time as it gets.

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To my knowledge no, not during compile time.

At run-time, you can do trivial checks such as setting a multi-byte value to a known bit string and inspect what bytes that results in. For instance using a union,

typedef union {
    uint32_t word;
    uint8_t bytes[4];
} byte_check;

or casting,

uint32_t word;
uint8_t * bytes = &word;

Please note that for completely portable endianness checks, you need to take into account both big-endian, little-endian and mixed-endian systems.

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what about runtime then? :) – user500944 Nov 21 '10 at 19:58
hmm, it's not too difficult to do in runtime I guess... using some pointer casting, like so: char p[] = {0, 1}; short* ptr = (short*)p; if(*ptr == 1){ we're big endian}, am I right? – user500944 Nov 21 '10 at 20:01

EDIT2: This method doesn't work. The representation of multibyte constant is compiler/platform specific and can not be reliably used. The link interjay gave ( gives an example where it fails. On Solaris/SPARC the same compiler gcc 4.3.3 gives the right answer, but SUNStudio 12 compiler will have the same behaviour as the gcc 4.3.4 on x86 used at that link.

So, we can conclude, still no good use of multibyte character

Found this new method which has the advantage of being simple and compile time.

switch('AB') {
  case 0x4142: printf("ASCII  Big endian\n"); break;
  case 0x4241: printf("ASCII  Little endian\n"); break;
  case 0xC1C2: printf("EBCDIC Big endian\n"); break;
  case 0xC2C1: printf("EBCDIC Little endian\n"); break;


Found even a way to make it in the pre-processor:

#if 'AB' == 0x4142
#error "ASCII  Big endian\n"
#elif 'AB' == 0x4241
#error "ASCII  Little endian\n"
#elif 'AB' == 0xC1C2
#error "EBCDIC Big endian\n"
#elif 'AB' == 0xC2C1
#error "EBCDIC Little endian\n"
#error "unknown coding and endianness\n"

And before someone asks, multibyte character constants are ANSI-C (even C90) but are implementation defined. Here's the first useful application I've found for them.

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Nice idea, but unfortunately it doesn't work. See test here: – interjay May 21 '11 at 13:44

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