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The man pages for htonl() seem to suggest that you can only use it for up to 32 bit values. (In reality, ntohl() is defined for unsigned long, which on my platform is 32 bits. I suppose if the unsigned long were 8 bytes, it would work for 64 bit ints).

My problem is that I need to convert 64 bit integers (in my case, this is an unsigned long long) from big endian to little endian. Right now, I need to do that specific conversion. But it would be even nicer if the function (like ntohl()) would NOT convert my 64 bit value if the target platform WAS big endian. (I'd rather avoid adding my own preprocessor magic to do this).

What can I use? I would like something that is standard if it exists, but I am open to implementation suggestions. I have seen this type of conversion done in the past using unions. I suppose I could have a union with an unsigned long long and a char[8]. Then swap the bytes around accordingly. (Obviously would break on platforms that were big endian).

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What is your platform? Most systems have platform-specific BE to LE conversion routines. Failing that, you could easily write one. –  Jason Coco May 1 '09 at 1:55
Take a look at my reply at this other question –  winden May 17 '09 at 20:46
Just my 2cts, it is written clearly in the C standard (dont know which one, 89 or 99), that a long should be enough to store a pointer. A phrase, that does not appear in C++ standard however. Linux compilers that I have seen respects that, a long is 64 bits on 64 bits builds. However Microsoft has chosen a weird solution where long is 32 bits everywhere. –  v.oddou Nov 1 '13 at 6:19

13 Answers 13

Documentation: man htobe64 on Linux (glibc >= 2.9) or FreeBSD.

Unfortunately OpenBSD, FreeBSD and glibc (Linux) did not quite work together smoothly to create one (non-kernel-API) libc standard for this, during an attempt in 2009.

Currently, this short bit of preprocessor code:

#if defined(__linux__)
#  include <endian.h>
#elif defined(__FreeBSD__) || defined(__NetBSD__)
#  include <sys/endian.h>
#elif defined(__OpenBSD__)
#  include <sys/types.h>
#  define be16toh(x) betoh16(x)
#  define be32toh(x) betoh32(x)
#  define be64toh(x) betoh64(x)

(tested on Linux and OpenBSD) should hide the differences. It gives you the Linux/FreeBSD-style macros on those 4 platforms.

Use example:

  #include <stdint.h>    // For 'uint64_t'

  uint64_t  host_int = 123;
  uint64_t  big_endian;

  big_endian = htobe64( host_int );
  host_int = be64toh( big_endian );

It's the most "standard C library"-ish approach available at the moment.

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This doesn't work with android (which defines __linux__ but provides the openbsd api) –  Stefan Jul 12 '13 at 13:46

To detect your endian-ness, use the following union:

union {
    unsigned long long ull;
    char c[8];
} x;
x.ull = 0x0123456789abcdef; // may need special suffix for ULL.

Then you can check the contents of x.c[] to detect where each byte went.

To do the conversion, I would use that detection code once to see what endian-ness the platform is using, then write my own function to do the swaps.

You could make it dynamic so that the code will run on any platform (detect once then use a switch inside your conversion code to choose the right conversion) but, if you're only going to be using one platform, I'd just do the detection once in a separate program then code up a simple conversion routine, making sure you document that it only runs (or has been tested) on that platform.

Here's some sample code I whipped up to illustrate it. It's been tested though not in a thorough manner, but should be enough to get you started.

#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#define TYP_INIT 0
#define TYP_SMLE 1
#define TYP_BIGE 2

static unsigned long long cvt(unsigned long long src) {
    static int typ = TYP_INIT;
    unsigned char c;
    union {
        unsigned long long ull;
        unsigned char c[8];
    } x;

    if (typ == TYP_INIT) {
        x.ull = 0x01;
        typ = (x.c[7] == 0x01) ? TYP_BIGE : TYP_SMLE;


    if (typ == TYP_SMLE)
        return src;

    x.ull = src;
    c = x.c[0]; x.c[0] = x.c[7]; x.c[7] = c;
    c = x.c[1]; x.c[1] = x.c[6]; x.c[6] = c;
    c = x.c[2]; x.c[2] = x.c[5]; x.c[5] = c;
    c = x.c[3]; x.c[3] = x.c[4]; x.c[4] = c;
    return x.ull;

int main (void) {
    unsigned long long ull = 1;
    ull = cvt (ull);
    printf ("%llu\n",ull);
    return 0;

Keep in mind that this just checks for pure big/little endian. If you have some weird variant where the bytes are stored in, for example, {5,2,3,1,0,7,6,4} order, cvt() will be a tad more complex. Such an architecture doesn't deserve to exist, but I'm not discounting the lunacy of our friends in the microprocessor industry :-)

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"may need special suffix for ULL" - and neither C89 nor C++ defines one that's portable. However, you can do x.ull = ((unsigned long long) 0x01234567) << 32 + 0x89abcdef; provided that long long really is 64bit. –  Steve Jessop May 1 '09 at 2:19
Thanks, onebyone, I ended up just using 0x01 and detecting that. –  paxdiablo May 1 '09 at 2:20
Actually "return src" should be done for big-endian architectures, not little-endian. Also, a more concise way to do the conversion on a little-endian CPU would be to compute the upper 32 bits of the result by using htonl() on the lower 32 bits of src and the lower 32 bits of the result by using htonl() on the upper 32 bits of src (hope that makes some sense...). –  Lance Richardson May 1 '09 at 2:51
That's not right, is it, Lance? The question asked for the value in little endian - that means leave it alone on little-endian systems and swap it on big-endian systems. –  paxdiablo May 1 '09 at 2:58
Lance is right... I am on a little endian system and I am dealing with a big endian number. I like that suggestion Lance. You should write it up as an answer so it can be upvoted, and possibly accepted :). I will make a decision soon on what to do and post more and hand out reputation. –  Tom May 1 '09 at 3:04

some BSD systems has betoh64 which does what you need.

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Linux (glibc) too. It's found in the <endian.h> header. –  ephemient May 1 '09 at 3:06
Hmm... I can't find the function in any of the endian.h headers. I am on my intel mac right now (running leopard). I also need to get this to work on Linux machines at school. I'm not sure which distro is running, but I am fairly certain they are i386 machines, little endian, and sizeof(unsigned long long) == 8. Also, the function I would need is be64toh(). Any suggestions? I would prefer this solution to the other one. –  Tom May 1 '09 at 4:29
my fault - what yo want should be betoh64. on FreeBSD, it's in /usr/include/sys/endian.h . The man page is byteorder(9). According to FreeBSD notes, these were originally from NetBSD, and appear on FreeBSD after 5.x. As I know, MacOSX is using lots of FreeBSD files as its backend (darwin) base - so there's a big chance that you may be able to use it. –  Francis May 1 '09 at 5:28
@Francis: My sources indicate that it is present even in 4.3BSD. @Tom: Autoconf looks for endian.h, sys/endian.h, and machinfo/endian.h; you may have to use different include paths on different platforms. –  ephemient May 1 '09 at 15:36

I would recommend reading this: http://commandcenter.blogspot.com/2012/04/byte-order-fallacy.html

#include <stdio.h>
#include <stdint.h>
#include <inttypes.h>

ntoh64(const uint64_t *input)
    uint64_t rval;
    uint8_t *data = (uint8_t *)&rval;

    data[0] = *input >> 56;
    data[1] = *input >> 48;
    data[2] = *input >> 40;
    data[3] = *input >> 32;
    data[4] = *input >> 24;
    data[5] = *input >> 16;
    data[6] = *input >> 8;
    data[7] = *input >> 0;

    return rval;

hton64(const uint64_t *input)
    return (ntoh64(input));

    uint64_t ull;

    ull = 1;
    printf("%"PRIu64"\n", ull);

    ull = ntoh64(&ull);
    printf("%"PRIu64"\n", ull);

    ull = hton64(&ull);
    printf("%"PRIu64"\n", ull);

    return 0;

Will show the following output:


You can test this with ntohl() if you drop the upper 4 bytes.

Also You can turn this into a nice templated function in C++ that will work on any size integer:

template <typename T>
static inline T
hton_any(const T &input)
    T output(0);
    const std::size_t size = sizeof(input) - 1;
    uint8_t *data = reinterpret_cast<uint8_t *>(&output);

    for (std::size_t i = 0; i < size; i++) {
        data[i] = input >> ((size - i) * 8);

    return output;

Now your 128 bit safe too!

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I think your template version is broken, it ignores the last byte. To fix it I changed size = sizeof(T); and input >> ((size-i-1)*8). –  Michael Anderson Jun 13 '13 at 3:11
it is pure speculation on how the compiler abstraction for types that are larger than the register size will store the parts in memory. Who says they want to strictly respect little endian or big endian ? it could even be a design that is not platform dependent, such like it will be natural on an architecture, and unnatural in another. it does not matter because the "loading" code of the big integer into the registers is the same, and portable. But this choice is compiler dependent. –  v.oddou Nov 1 '13 at 6:27

one line macro for 64bit swap on little endian machines.

#define bswap64(y) (((uint64_t)ntohl(y)) << 32 | ntohl(y>>32))
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This won't work on platforms that are big-endian. –  Bjorn Roche Sep 26 '13 at 15:56
@BjornRoche It will be easy to construct similar macro for big endian machines. #include <endian.h> #if __BYTE_ORDER == __LITTLE_ENDIAN to tidy up the bswap64() API and make it platform independent. –  Sandeep May 16 '14 at 13:40

How about a generic version, which doesn't depend on the input size (some of the implementations above assume that unsigned long long is 64 bits, which is not necessarily always true):

    // converts an arbitrary large integer (preferrably >=64 bits) from big endian to host machine endian
    template<typename T> static inline T bigen2host(const T& x)
        static const int one = 1;
        static const char sig = *(char*)&one; 

        if (sig == 0) return x; // for big endian machine just return the input

        T ret;
        int size = sizeof(T);
        char* src = (char*)&x + sizeof(T) - 1;
        char* dst = (char*)&ret;

        while (size-- > 0) *dst++ = *src--;

        return ret;
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Best solution so far. I would just replace the while with for, so the compiler can rely on the sizeof(T) to unroll the loop. –  Ben-Uri Oct 6 '12 at 19:33
uint32_t SwapShort(uint16_t a)
  a = ((a & 0x00FF) << 8) | ((a & 0xFF00) >> 8);
  return a;

uint32_t SwapWord(uint32_t a)
  a = ((a & 0x000000FF) << 24) |
      ((a & 0x0000FF00) <<  8) |
      ((a & 0x00FF0000) >>  8) |
      ((a & 0xFF000000) >> 24);
  return a;

uint64_t SwapDWord(uint64_t a)
  a = ((a & 0x00000000000000FFULL) << 56) | 
      ((a & 0x000000000000FF00ULL) << 40) | 
      ((a & 0x0000000000FF0000ULL) << 24) | 
      ((a & 0x00000000FF000000ULL) <<  8) | 
      ((a & 0x000000FF00000000ULL) >>  8) | 
      ((a & 0x0000FF0000000000ULL) >> 24) | 
      ((a & 0x00FF000000000000ULL) >> 40) | 
      ((a & 0xFF00000000000000ULL) >> 56);
  return a;
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Why is the 16 bit function returning a 32 bit int? –  mafu Nov 14 '12 at 15:33

How about:

#define ntohll(x) ( ( (uint64_t)(ntohl( (uint32_t)((x << 32) >> 32) )) << 32) | 
    ntohl( ((uint32_t)(x >> 32)) ) )                                        
#define htonll(x) ntohll(x)
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I like the union answer, pretty neat. Typically I just bit shift to convert between little and big endian, although I think the union solution has fewer assignments and may be faster:

//note UINT64_C_LITERAL is a macro that appends the correct prefix
//for the literal on that platform
inline void endianFlip(unsigned long long& Value)
   ((Value &   UINT64_C_LITERAL(0x00000000000000FF)) << 56) |
   ((Value &   UINT64_C_LITERAL(0x000000000000FF00)) << 40) |
   ((Value &   UINT64_C_LITERAL(0x0000000000FF0000)) << 24) |
   ((Value &   UINT64_C_LITERAL(0x00000000FF000000)) << 8)  |
   ((Value &   UINT64_C_LITERAL(0x000000FF00000000)) >> 8)  | 
   ((Value &   UINT64_C_LITERAL(0x0000FF0000000000)) >> 24) |
   ((Value &   UINT64_C_LITERAL(0x00FF000000000000)) >> 40) |
   ((Value &   UINT64_C_LITERAL(0xFF00000000000000)) >> 56);

Then to detect if you even need to do your flip without macro magic, you can do a similiar thing as Pax, where when a short is assigned to 0x0001 it will be 0x0100 on the opposite endian system.


unsigned long long numberToSystemEndian
    unsigned long long In, 
    unsigned short SourceEndian
   if (SourceEndian != 1)
      //from an opposite endian system
   return In;

So to use this, you'd need SourceEndian to be an indicator to communicate the endianness of the input number. This could be stored in the file (if this is a serialization problem), or communicated over the network (if it's a network serialization issue).

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An easy way would be to use ntohl on the two parts seperately:

unsigned long long htonll(unsigned long long v) {
    union { unsigned long lv[2]; unsigned long long llv; } u;
    u.lv[0] = htonl(v >> 32);
    u.lv[1] = htonl(v & 0xFFFFFFFFULL);
    return u.llv;

unsigned long long ntohll(unsigned long long v) {
    union { unsigned long lv[2]; unsigned long long llv; } u;
    u.llv = v;
    return ((unsigned long long)ntohl(u.lv[0]) << 32) | (unsigned long long)ntohl(u.lv[1]);
share|improve this answer
your first function is htonll and uses ntohl() internally. both functions are interchangeable, correct? if so why are they implemented differently? –  Marius Apr 29 '10 at 16:13
Oops, fixed. Strictly speaking, there are other options for endianness than big or little-endian - while you don't see them much anymore, on some very old systems, htonl() and ntohl() might behave differently. –  bdonlan May 6 '10 at 20:58
template <typename T>
static T ntoh_any(T t)
    static const unsigned char int_bytes[sizeof(int)] = {0xFF};
    static const int msb_0xFF = 0xFF << (sizeof(int) - 1) * CHAR_BIT;
    static bool host_is_big_endian = (*(reinterpret_cast<const int *>(int_bytes)) & msb_0xFF ) != 0;
    if (host_is_big_endian) { return t; }

    unsigned char * ptr = reinterpret_cast<unsigned char *>(&t);
    std::reverse(ptr, ptr + sizeof(t) );
    return t;

Works for 2 bytes, 4-bytes, 8-bytes, and 16-bytes(if you have 128-bits integer). Should be OS/platform independent.

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C++11 constexpr template function

#include <endian.h>    // __BYTE_ORDER
#include <algorithm>   // std::reverse

template <typename T>
constexpr T htonT( T value, char* ptr=0 ) noexcept
     ptr = reinterpret_cast<char*>(& value), 
     std::reverse( ptr, ptr + sizeof(T) ),

No compilation warning on both clang-3.5 and GCC-4.9 using -Wall -Wextra -pedantic
=> See compilation and run output on coliru.

C++11 constexpr template functions pseudo-specialized

However the above version does not allow to create constexpr variable as:

constexpr int32_t hton_six = htonT( int32_t(6) );

Finally we need to separate (specialize) the functions depending on 16/32/64 bits.
But we can still keep generic functions.
=> See the full snippet on coliru.

template <typename T>
constexpr typename std::enable_if< sizeof(T) == 2, T >::type
htonT( T value ) noexcept
   return   ((value & 0x00FF) << 8)
          | ((value & 0xFF00) >> 8);

template <typename T>
constexpr typename std::enable_if< sizeof(T) == 4, T >::type
htonT( T value ) noexcept
   return   ((value & 0x000000FF) << 24)
          | ((value & 0x0000FF00) <<  8)
          | ((value & 0x00FF0000) >>  8)
          | ((value & 0xFF000000) >> 24);

template <typename T>
constexpr typename std::enable_if< sizeof(T) == 8, T >::type
htonT( T value ) noexcept
   return   ((value & 0xFF00000000000000ull) >> 56)
          | ((value & 0x00FF000000000000ull) >> 40)
          | ((value & 0x0000FF0000000000ull) >> 24)
          | ((value & 0x000000FF00000000ull) >>  8)
          | ((value & 0x00000000FF000000ull) <<  8)
          | ((value & 0x0000000000FF0000ull) << 24)
          | ((value & 0x000000000000FF00ull) << 40)
          | ((value & 0x00000000000000FFull) << 56);

Or an even-shorter version based on built-in compiler macros:

template <typename T>
constexpr typename std::enable_if< sizeof(T) == 2, T >::type
htonT( T value ) noexcept
    return __bswap_constant_16(value);

template <typename T>
constexpr typename std::enable_if< sizeof(T) == 4, T >::type
htonT( T value ) noexcept
    return __bswap_constant_32(value);

template <typename T>
constexpr typename std::enable_if< sizeof(T) == 8, T >::type
htonT( T value ) noexcept
    return __bswap_constant_64(value);

Test code of the first version

std::uint8_t uc = 'B';                  std::cout <<std::setw(16)<< uc <<'\n';
uc = htonT( uc );                       std::cout <<std::setw(16)<< uc <<'\n';

std::uint16_t us = 0x1122;              std::cout <<std::setw(16)<< us <<'\n';
us = htonT( us );                       std::cout <<std::setw(16)<< us <<'\n';

std::uint32_t ul = 0x11223344;          std::cout <<std::setw(16)<< ul <<'\n';
ul = htonT( ul );                       std::cout <<std::setw(16)<< ul <<'\n';

std::uint64_t uL = 0x1122334455667788; std::cout <<std::setw(16)<< uL <<'\n';
uL = htonT( uL );                      std::cout <<std::setw(16)<< uL <<'\n';

Test code of the second version

constexpr uint8_t  a1 = 'B';               std::cout<<std::setw(16)<<a1<<'\n';
constexpr auto     b1 = htonT(a1);         std::cout<<std::setw(16)<<b1<<'\n';

constexpr uint16_t a2 = 0x1122;            std::cout<<std::setw(16)<<a2<<'\n';
constexpr auto     b2 = htonT(a2);         std::cout<<std::setw(16)<<b2<<'\n';

constexpr uint32_t a4 = 0x11223344;        std::cout<<std::setw(16)<<a4<<'\n';
constexpr auto     b4 = htonT(a4);         std::cout<<std::setw(16)<<b4<<'\n';

constexpr uint64_t a8 = 0x1122334455667788;std::cout<<std::setw(16)<<a8<<'\n';
constexpr auto     b8 = htonT(a8);         std::cout<<std::setw(16)<<b8<<'\n';



EDIT: My original answer was not C++11-constexpr compliant.

This answer is in Public Domain CC0 1.0 Universal

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It isn't in general necessary to know the endianness of a machine to convert a host integer into network order. Unfortunately that only holds if you write out your net-order value in bytes, rather than as another integer:

static inline void short_to_network_order(uchar *output, uint16_t in)
    output[0] = in>>8&0xff;
    output[1] = in&0xff;

(extend as required for larger numbers).

This will (a) work on any architecture, because at no point do I use special knowledge about the way an integer is laid out in memory and (b) should mostly optimise away in big-endian architectures because modern compilers aren't stupid.

The disadvantage is, of course, that this is not the same, standard interface as htonl() and friends (which I don't see as a disadvantage, because the design of htonl() was a poor choice imo).

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