Is there a one line macro definition to determine the endianness of the machine? I am using the following code but converting it to macro would be too long:

unsigned char test_endian( void )
    int test_var = 1;
    unsigned char *test_endian = (unsigned char*)&test_var;

    return (test_endian[0] == 0);
  • 2
    Why not include the same code into a macro?
    – sharptooth
    Jan 20, 2010 at 9:46
  • 4
    You can't portably determine endianness with the C preprocessor alone. You also want 0 instead of NULL in your final test, and change one of the test_endian objects to something else :-). Jan 20, 2010 at 9:48
  • 2
    Also why is a macro necessary? Inline function would do the same and is much safer.
    – sharptooth
    Jan 20, 2010 at 9:49
  • 15
    @Sharptooth, a macro is appealing because its value may be known at compile time, meaning you could use your platform's endianness to control template instantiation, for example, or maybe even select different blocks of code with an #if directive. Apr 8, 2010 at 5:08
  • 4
    That's true, but inefficient. If I have a little-endian cpu, and I'm writing little-endian data to the wire or to a file, I'd much rather avoid unpacking and repacking data to no purpose. I used to write video drivers for a living. It is extremely important when writing pixels to a video card to optimize every place you can. Sep 5, 2016 at 16:26

22 Answers 22


Code supporting arbitrary byte orders, ready to be put into a file called order32.h:

#ifndef ORDER32_H
#define ORDER32_H

#include <limits.h>
#include <stdint.h>

#if CHAR_BIT != 8
#error "unsupported char size"

    O32_LITTLE_ENDIAN = 0x03020100ul,
    O32_BIG_ENDIAN = 0x00010203ul,
    O32_PDP_ENDIAN = 0x01000302ul,      /* DEC PDP-11 (aka ENDIAN_LITTLE_WORD) */
    O32_HONEYWELL_ENDIAN = 0x02030001ul /* Honeywell 316 (aka ENDIAN_BIG_WORD) */

static const union { unsigned char bytes[4]; uint32_t value; } o32_host_order =
    { { 0, 1, 2, 3 } };

#define O32_HOST_ORDER (o32_host_order.value)


You would check for little endian systems via

  • 12
    This doesn't let you decide endian-ness until runtime though. The following fails to compile because. /** isLittleEndian::result --> 0 or 1 */ struct isLittleEndian { enum isLittleEndianResult { result = (O32_HOST_ORDER == O32_LITTLE_ENDIAN) }; };
    – user48956
    Aug 13, 2010 at 17:54
  • 4
    Is it imposiible to get result until runtime?
    – k06a
    Dec 26, 2010 at 12:03
  • 9
    Why char? Better use uint8_t and fail if this type isn't available (which can be checked by #if UINT8_MAX). Note that CHAR_BIT is independent from uint8_t. Oct 31, 2012 at 11:33
  • 2
    This is UB in c++: stackoverflow.com/questions/11373203/…
    – user3624760
    Jul 1, 2016 at 8:55
  • 4
    Let me toss one more into the mix, for completeness: O32_HONEYWELL_ENDIAN = 0x02030001ul /* Honeywell 316 */ Sep 5, 2016 at 17:10

If you have a compiler that supports C99 compound literals:

#define IS_BIG_ENDIAN (!*(unsigned char *)&(uint16_t){1})


#define IS_BIG_ENDIAN (!(union { uint16_t u16; unsigned char c; }){ .u16 = 1 }.c)

In general though, you should try to write code that does not depend on the endianness of the host platform.

Example of host-endianness-independent implementation of ntohl():

uint32_t ntohl(uint32_t n)
    unsigned char *np = (unsigned char *)&n;

    return ((uint32_t)np[0] << 24) |
        ((uint32_t)np[1] << 16) |
        ((uint32_t)np[2] << 8) |
  • 4
    "you should try to write code that does not depend on the endianness of the host platform". Unfortunately my plea, "I know we're writing a POSIX compatibility layer, but I don't want to implement ntoh, because it depends on the endianness of the host platform" always fell on deaf ears ;-). Graphics format handling and conversion code is the other main candidate I've seen - you don't want to base everything off calling ntohl all the time. Jan 20, 2010 at 13:03
  • 8
    You can implement ntohl in a way that does not depend on the endianness of the host platform.
    – caf
    Jan 20, 2010 at 13:13
  • 1
    @caf how would you write ntohl in an host-endianness-independent way? Mar 1, 2012 at 12:39
  • 4
    @AliVeli: I've added an example implementation to the answer.
    – caf
    Mar 1, 2012 at 21:12
  • 6
    I should also add for the record, that "(*(uint16_t *)"\0\xff" < 0x100)" won't compile into a constant, no matter how much I optimize, at least with gcc 4.5.2. It always creates executable code. Jul 11, 2012 at 20:29

There is no standard, but on many systems including <endian.h> will give you some defines to look for.

  • 35
    Test the endianness with #if __BYTE_ORDER == __LITTLE_ENDIAN and #elif __BYTE_ORDER == __BIG_ENDIAN. And generate an #error elsewise.
    – To1ne
    May 4, 2011 at 7:43
  • 7
    <endian.h> is not available on Windows
    – rustyx
    Nov 2, 2016 at 15:27
  • 2
    Android and Chromium projects use endian.h unless __APPLE__ or _WIN32 is defined. Nov 11, 2016 at 13:42
  • 1
    In OpenBSD 6.3, <endian.h> provides #if BYTE_ORDER == LITTLE_ENDIAN(or BIG_ENDIAN) with no underscores before the names. _BYTE_ORDER is only for system headers. __BYTE_ORDER does not exist. Apr 6, 2018 at 4:11
  • 2
    @To1ne I doubt that Endianness is relevant for Windows, as Windows (at least currently) runs only on x86 and ARM machines. x86 always being LE and ARM being configurable to use either architecture.
    – SimonC
    Dec 19, 2018 at 8:13

To detect endianness at run time, you have to be able to refer to memory. If you stick to standard C, declarating a variable in memory requires a statement, but returning a value requires an expression. I don't know how to do this in a single macro—this is why gcc has extensions :-)

If you're willing to have a .h file, you can define

static uint32_t endianness = 0xdeadbeef; 
enum endianness { BIG, LITTLE };

#define ENDIANNESS ( *(const char *)&endianness == 0xef ? LITTLE \
                   : *(const char *)&endianness == 0xde ? BIG \
                   : assert(0))

and then you can use the ENDIANNESS macro as you will.

  • 6
    I like this because it acknowledges the existence of endianness other than little and big. Jan 20, 2010 at 9:58
  • 8
    Speaking of which, it might be worth calling the macro INT_ENDIANNESS, or even UINT32_T_ENDIANNESS, since it only tests the storage representation of one type. There's an ARM ABI where integral types are little-endian, but doubles are middle-endian (each word is little-endian, but the word with the sign bit in it comes before the other word). That caused some excitement among the compiler team for a day or so, I can tell you. Jan 20, 2010 at 12:56

If you want to only rely on the preprocessor, you have to figure out the list of predefined symbols. Preprocessor arithmetics has no concept of addressing.

GCC on Mac defines __LITTLE_ENDIAN__ or __BIG_ENDIAN__

$ gcc -E -dM - < /dev/null |grep ENDIAN
#define __LITTLE_ENDIAN__ 1

Then, you can add more preprocessor conditional directives based on platform detection like #ifdef _WIN32 etc.

  • 6
    GCC 4.1.2 on Linux doesn't appear to define those macros, although GCC 4.0.1 and 4.2.1 define them on Macintosh. So it's not a reliable method for cross-platform development, even when you're allowed to dictate which compiler to use. Apr 8, 2010 at 3:02
  • 1
    oh yeah it's because it's only defined by GCC on Mac. Aug 8, 2011 at 2:18
  • Note: My GCC (on Mac) defines #define __BIG_ENDIAN__ 1 and #define _BIG_ENDIAN 1.
    – user1985657
    Sep 28, 2014 at 16:16
  • clang 5.0.1 for OpenBSD/amd64 has #define __LITTLE_ENDIAN__ 1. This macro seems to be a clang feature, not a gcc feature. The gcc command in some Macs isn't gcc, it's clang. Apr 6, 2018 at 4:05
  • GCC 4.2.1 on Mac was GCC back then Apr 6, 2018 at 11:30

I believe this is what was asked for. I only tested this on a little endian machine under msvc. Someone plese confirm on a big endian machine.

    #define LITTLE_ENDIAN 0x41424344UL 
    #define BIG_ENDIAN    0x44434241UL
    #define PDP_ENDIAN    0x42414443UL
    #define ENDIAN_ORDER  ('ABCD') 

        #error "machine is little endian"
        #error "machine is big endian"
        #error "jeez, machine is PDP!"
        #error "What kind of hardware is this?!"

As a side note (compiler specific), with an aggressive compiler you can use "dead code elimination" optimization to achieve the same effect as a compile time #if like so:

    unsigned yourOwnEndianSpecific_htonl(unsigned n)
        static unsigned long signature= 0x01020304UL; 
        if (1 == (unsigned char&)signature) // big endian
            return n;
        if (2 == (unsigned char&)signature) // the PDP style
            n = ((n << 8) & 0xFF00FF00UL) | ((n>>8) & 0x00FF00FFUL);
            return n;
        if (4 == (unsigned char&)signature) // little endian
            n = (n << 16) | (n >> 16);
            n = ((n << 8) & 0xFF00FF00UL) | ((n>>8) & 0x00FF00FFUL);
            return n;
        // only weird machines get here
        return n; // ?

The above relies on the fact that the compiler recognizes the constant values at compile time, entirely removes the code within if (false) { ... } and replaces code like if (true) { foo(); } with foo(); The worst case scenario: the compiler does not do the optimization, you still get correct code but a bit slower.

  • I like this method, but correct me if I'm wrong: this only works when you're compiling on the machine you're building for, correct? Mar 31, 2012 at 19:24
  • 3
    gcc also throws an error due to multi-character character constants. Thus, not portable. Jul 11, 2012 at 20:34
  • 2
    what compiler is letting you write 'ABCD' ? Aug 19, 2014 at 20:19
  • 2
    Many compilers will allow multibyte character constants in relaxed compliance modes, but run the top part with clang -Wpedantic -Werror -Wall -ansi foo.c and it will error. (Clang and this specifically: -Wfour-char-constants -Werror)
    – user246672
    Dec 3, 2014 at 20:25
  • @Edward Falk It is not an error to have a multi-character constant in code. It is implementation-defined behavior C11 10. gcc and other may/may not warn/error depending on settings, but it is not a C error. It certainly is not popular to use multi-character character constants. Mar 2, 2016 at 22:16

If you are looking for a compile time test and you are using gcc, you can do:


See gcc documentation for more information.

  • 3
    This is definitely the best answer for anyone using gcc
    – rtpax
    Jul 21, 2017 at 13:27
  • 2
    __BYTE_ORDER__ is available since GCC 4.6 Mar 30, 2018 at 7:17

You can in fact access the memory of a temporary object by using a compound literal (C99):

#define IS_LITTLE_ENDIAN (1 == *(unsigned char *)&(const int){1})

Which GCC will evaluate at compile time.

  • I like it. Is there a portable, compile-time way to know that you're compiling under C99? Sep 5, 2016 at 16:44
  • 2
    Oh, and what if it's not GCC? Sep 7, 2016 at 15:27
  • 1
    @EdwardFalk Yes. #if __STDC_VERSION__ >= 199901L.
    – Jens
    Feb 19, 2018 at 20:03

The 'C network library' offers functions to handle endian'ness. Namely htons(), htonl(), ntohs() and ntohl() ...where n is "network" (ie. big-endian) and h is "host" (ie. the endian'ness of the machine running the code).

These apparent 'functions' are (commonly) defined as macros [see <netinet/in.h>], so there is no runtime overhead for using them.

The following macros use these 'functions' to evaluate endian'ness.

#include <arpa/inet.h>
#define  IS_BIG_ENDIAN     (1 == htons(1))

In addition:

The only time I ever need to know the endian'ness of a system is when I write-out a variable [to a file/other] which may be read-in by another system of unknown endian'ness (for cross-platform compatability) ...In cases such as these, you may prefer to use the endian functions directly:

#include <arpa/inet.h>

#define JPEG_MAGIC  (('J'<<24) | ('F'<<16) | ('I'<<8) | 'F')

// Result will be in 'host' byte-order
unsigned long  jpeg_magic = JPEG_MAGIC;

// Result will be in 'network' byte-order (IE. Big-Endian/Human-Readable)
unsigned long  jpeg_magic = htonl(JPEG_MAGIC);
  • This doesn't really answer the question which was looking for a quick way to determine endianness.
    – Oren
    Jun 12, 2013 at 0:50
  • @Oren : With respect to your valid criticism, I have prepended detail which addresses the original question more directly.
    – BlueChip
    Jun 13, 2013 at 6:09

Use an inline function rather than a macro. Besides, you need to store something in memory which is a not-so-nice side effect of a macro.

You could convert it to a short macro using a static or global variable, like this:

static int s_endianess = 0;
#define ENDIANESS() ((s_endianess = 1), (*(unsigned char*) &s_endianess) == 0)
  • i think this is the best since it is the simplest. however it does not test against mixed endian Mar 1, 2012 at 12:43
  • 1
    Why isn't s_endianess set to 1 to start with? Jan 19, 2018 at 21:05

Whilst there is no portable #define or something to rely upon, platforms do provide standard functions for converting to and from your 'host' endian.

Generally, you do storage - to disk, or network - using 'network endian', which is BIG endian, and local computation using host endian (which on x86 is LITTLE endian). You use htons() and ntohs() and friends to convert between the two.


If you dump the preprocessor #defines

gcc -dM -E - < /dev/null
g++ -dM -E -x c++ - < /dev/null

You can usually find stuff that will help you. With compile time logic.

#define __LITTLE_ENDIAN__ 1

Various compilers may have different defines however.

#include <stdint.h>
#define IS_LITTLE_ENDIAN (*(uint16_t*)"\0\1">>8)
#define IS_BIG_ENDIAN (*(uint16_t*)"\1\0">>8)
  • 6
    This also generates executable code, not a constant. You couldn't do "#if IS_BIG_ENDIAN" Jul 11, 2012 at 20:32
  • 1
    I like this solution since it doesn't rely on C/C++ standards undefined behavior, as far as I understand. It's not compile time but the only standard solution for that is waiting for c++20 std::endian
    – ceztko
    Apr 13, 2020 at 10:36

Don't forget that endianness is not the whole story - the size of char might not be 8 bits (e.g. DSP's), two's complement negation is not guaranteed (e.g. Cray), strict alignment might be required (e.g. SPARC, also ARM springs into middle-endian when unaligned), etc, etc.

It might be a better idea to target a specific CPU architecture instead.

For example:

#if defined(__i386__) || defined(_M_IX86) || defined(_M_IX64)

void my_func()
  // Intel x86-optimized, LE implementation
  // slow but safe implementation

Note that this solution is also not ultra-portable unfortunately, as it depends on compiler-specific definitions (there is no standard, but here's a nice compilation of such definitions).


Try this:

int x=1;
#define TEST (*(char*)&(x)==1)?printf("little endian"):printf("Big endian")
int main()


Please pay attention that most of the answers here are not portable, since compilers today will evaluate those answers in compilation time (depends on the optimization) and return a specific value based on a specific endianness, while the actual machine endianness can differ. The values on which the endianness is tested, won't never reach the system memory thus the real executed code will return the same result regardless of the actual endianness.

For example, in ARM Cortex-M3 the implemented endianness will reflect in a status bit AIRCR.ENDIANNESS and compiler cannot know this value in compile time.

Compilation output for some of the answers suggested here:

https://godbolt.org/z/GJGNE2 for this answer,

https://godbolt.org/z/Yv-pyJ for this answer, and so on.

To solve it you will need to use the volatile qualifier. Yogeesh H T's answer is the closest one for today's real life usage, but since Christoph suggests more comprehensive solution, a slight fix to his answer would make the answer complete, just add volatile to the union declaration: static const volatile union.

This would assure storing and reading from memory, which is needed to determine endianness.


This question is actual for cpp too, so I asked here.

ONLY #if __cplusplus > 201703L

#include <bit>
#include <iostream>

using namespace std;

int main()
    if constexpr (endian::native == endian::big)
        cout << "big-endian";
    else if constexpr (endian::native == endian::little)
        cout << "little-endian";
        cout << "mixed-endian";

For more info: https://en.cppreference.com/w/cpp/types/endian


If your compiler supports compound literals and you are pointedly not using C++ you can use

#define BIG_ENDIAN      ((*(const char*)&(const int){0x01020304}) == 0x01)
#define LITTLE_ENDIAN   ((*(const char*)&(const int){0x01020304}) == 0x04)

This doesn't require the declaration of any runtime variables, which I think makes it a good deal cleaner than most of the other solutions

  • but it's runtime and not compile time, which means the expression will be evaluated many times in the program's lifetime and may be inefficient
    – phuclv
    Mar 18 at 16:13

If boost is available then you can use Boost.Predef which contains various predefined macros for the target platform including endianness (BOOST_ENDIAN_*). Yes boost is often thought as a C++ library, but this one is a preprocessor header that works with C as well! It allows you to detect endian in compile time portably

This library defines a set of compiler, architecture, operating system, library, and other version numbers from the information it can gather of C, C++, Objective C, and Objective C++ predefined macros or those defined in generally available headers. The idea for this library grew out of a proposal to extend the Boost Config library to provide more, and consistent, information than the feature definitions it supports. What follows is an edited version of that brief proposal.

For example

#include <boost/predef.h>
// or just include the necessary header
// #include <boost/predef/other/endian.h>


More details can be found in BOOST_ENDIAN_* section

Demo on Godbolt

Note that it obviously can't detect bi-endian platforms where the endian can be changed during runtime

The detection is conservative in that it only identifies endianness that it knows for certain. In particular bi-endianness is not indicated as is it not practically possible to determine the endianness from anything but an operating system provided header. And the currently known headers do not define that programatic bi-endianness is available.


My answer is not as asked but It is really simple to find if your system is little endian or big endian?



int main()
  int a = 1;
  char *b;

  b = (char *)&a;
  if (*b)
    printf("Little Endian\n");
    printf("Big Endian\n");

C Code for checking whether a system is little-endian or big-indian.

int i = 7;
char* pc = (char*)(&i);
if (pc[0] == '\x7') // aliasing through char is ok
    puts("This system is little-endian");
    puts("This system is big-endian");

Macro to find endiannes

#define ENDIANNES() ((1 && 1 == 0) ? printf("Big-Endian"):printf("Little-Endian"))


#include <stdio.h>

#define ENDIAN() { \
volatile unsigned long ul = 1;\
volatile unsigned char *p;\
p = (volatile unsigned char *)&ul;\
if (*p == 1)\
puts("Little endian.");\
else if (*(p+(sizeof(unsigned long)-1)) == 1)\
puts("Big endian.");\
else puts("Unknown endian.");\

int main(void) 
       return 0;
  • 3
    The first macro is incorrect and will always return "Big-Endian". Bit shifting is not affected by endianness - endianness only affect reads and stores to the memory.
    – GaspardP
    Jan 28, 2016 at 16:58

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