I want a 128 bit integer because I want to store results of multiplication of two 64 bit numbers. Is there any such thing in gcc 4.4 and above?

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    Take a look: stackoverflow.com/questions/3329541/… Apr 18, 2013 at 16:28
  • @chux: Why did you reopen this? The top answer here is wrong, claiming that uint128_t is defined when in fact gcc provides unsigned __int128 or __uint128_t. And currently only on 64-bit targets where 128-bit only takes 2 integer registers. Feb 21, 2019 at 18:39
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    @PeterCordes I VTO as the 2 dupes listed did not answer the question. My VTO was not related to any answers. Feb 22, 2019 at 5:25
  • @chux: ok that's fair, but wasn't it closed as a dup of Does gcc support 128-bit int on amd64?? That looks like a duplicate to me. Feb 22, 2019 at 5:28
  • @PeterCordes This question was closed due to 2 dupes: question was narrower and so not a dupe of this question - and another. That answer addresses gcc in general 4.6 and before, but not this question's about 4.4 onward. Certainly these and many other relates questions are similar and on the border of being sufficiently similar/different Feb 22, 2019 at 5:38

3 Answers 3


For GCC before C23, a primitive 128-bit integer type is only ever available on 64-bit targets, so you need to check for availability even if you have already detected a recent GCC version. In theory gcc could support TImode integers on machines where it would take 4x 32-bit registers to hold one, but I don't think there are any cases where it does.

In C++, consider a library such as boost::multiprecision::int128_t which hopefully uses compiler built-in wide types if available, for zero overhead vs. using your own typedef (like GCC's __int128 or Clang's _BitInt(128)). See also @phuclv's answer on another question.

ISO C23 will let you typedef unsigned _BitInt(128) u128, modeled on clang's feature originally called _ExtInt() which works even on 32-bit machines; see a brief intro to it. Current GCC -std=gnu2x doesn't even support that syntax yet.

GCC 4.6 and later has a __int128 / unsigned __int128 defined as a built-in type. Use
#ifdef __SIZEOF_INT128__ to detect it.

GCC 4.1 and later define __int128_t and __uint128_t as built-in types. (You don't need #include <stdint.h> for these, either. Proof on Godbolt.)

I tested on the Godbolt compiler explorer for the first versions of compilers to support each of these 3 things (on x86-64). Godbolt only goes back to gcc4.1, ICC13, and clang3.0, so I've used <= 4.1 to indicate that the actual first support might have been even earlier.

         legacy               recommended(?)    |  One way of detecting support
        __uint128_t   |  [unsigned]  __int128   |  #ifdef __SIZEOF_INT128__
gcc        <=  4.1    |       4.6               |     4.6
clang      <=  3.0    |       3.1               |     3.3
ICC        <=  13     |     <= 13               |     16.  (Godbolt doesn't have 14 or 15)

If you compile for a 32-bit architecture like ARM, or x86 with -m32, no 128-bit integer type is supported with even the newest version of any of these compilers. So you need to detect support before using, if it's possible for your code to work at all without it.

The only direct CPP macro I'm aware of for detecting it is __SIZEOF_INT128__, but unfortunately some old compiler versions support it without defining it. (And there's no macro for __uint128_t, only the gcc4.6 style unsigned __int128). How to know if __uint128_t is defined

Some people still use ancient compiler versions like gcc4.4 on RHEL (RedHat Enterprise Linux), or similar crusty old systems. If you care about obsolete gcc versions like that, you probably want to stick to __uint128_t. And maybe detect 64-bitness in terms of sizeof(void*) == 8 as a fallback for __SIZEOF_INT128__ no being defined. (I think GNU systems always have CHAR_BIT==8, although I might be wrong about some DSPs). That will give a false negative on ILP32 ABIs on 64-bit ISAs (like x86-64 Linux x32, or AArch64 ILP32), but this is already just a fallback / bonus for people using old compilers that don't define __SIZEOF_INT128__.

There might be some 64-bit ISAs where gcc doesn't define __int128, or maybe even some 32-bit ISAs where gcc does define __int128, but I'm not aware of any.

The GCC internals are integer TI mode (GCC internals manual). (Tetra-integer = 4x width of a 32-bit int, vs. DImode = double width vs. SImode = plain int.) As the GCC manual points out, __int128 is supported on targets that support a 128-bit integer mode (TImode).

// __uint128_t is pre-defined equivalently to this
typedef unsigned uint128 __attribute__ ((mode (TI)));

There is an OImode in the manual, oct-int = 32 bytes, but current GCC for x86-64 complains "unable to emulate 'OI'" if you attempt to use it.

Random fact: ICC19 and g++/clang++ -E -dM define:

#define __GLIBCXX_TYPE_INT_N_0 __int128
#define __GLIBCXX_BITSIZE_INT_N_0 128

@MarcGlisse commented that's the way you tell libstdc++ to handle extra integer types (overload abs, specialize type traits, etc)

icpc defines that even with -xc (to compile as C, not C++), while g++ -xc and clang++ -xc don't. But compiling with actual icc (e.g. select C instead of C++ in the Godbolt language dropdown) doesn't define this macro.

The test function was:

#include <stdint.h>   // for uint64_t

#define uint128_t __uint128_t
//#define uint128_t unsigned __int128

uint128_t mul64(uint64_t a, uint64_t b) {
    return (uint128_t)a * b;

compilers that support it all compile it efficiently, to

    mov       rax, rdi
    mul       rsi
    ret                  # return in RDX:RAX which mul uses implicitly
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    unsigned __int128 - full division is the worst. Frequently (especially with div / mod arithmetic routines) we know the quotient will fit in a 64-bit result, but the C run-time can't assume it. I wrote a reference 'modexp' (64-bit base, exponent, modulus), using __int128 ... vs. a version using 64-bit intrinsics, reciprocal division, etc., for an 18x speed-up! 3x or 4x are respectable, but remember that there's always call overhead, and the [u]int128 functions can't make the algorithmic assertions that we can!
    – Brett Hale
    Jul 1, 2019 at 17:12
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    @BrettHale: interesting. gcc's helper function maybe only checks that the upper half is zero instead of (for unsigned) checking that divisor > high_half_dividend. Jul 1, 2019 at 20:51
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    Fast types aren't a good way to find out about an architecture's bitness. E.g., musl's {,u}int_fast{16,32}_ts on x86_64 are 32 bits, glibc's are 64 (also not good to include in an API for that matter).
    – PSkocik
    Jan 19, 2020 at 8:33
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    @PSkocik: IDK why I even suggested that in the first place. I think I had been hoping to find something that would even work on ILP32 ABIs like x86-64 Linux's x32, or AArch64 ILP32, but that is not the case. Glad to hear MUSL makes it 32-bit on x86-64; that makes more sense to me. I hadn't realized it wasn't nailed down by the ABI and therefore not suitable for use in an API. Jan 19, 2020 at 9:26
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    @PSkocik: 64-bit integers can sometimes save an instruction for sign-extension when used as array indices, but otherwise are strictly worse. Large code-size (REX prefixes), and much slower div on Intel CPUs (~2.5x). On AMD before Zen, 64-bit mul/imul is slower than 32-bit. Also 64-bit popcnt is slower on some CPUs. (All of these are compared to 32-bit, the default operand-size in x86-64 machine code, which zero-extends to 64-bit for free.) Jan 19, 2020 at 10:23

Ah, big integers are not C's forte.

GCC does have an unsigned __int128/__int128 type, starting from version 4.something (not sure here). I do seem to recall, however, that there was a __int128_t def before that.

These are only available on 64-bit targets.

(Editor's note: this answer used to claim that gcc defined uint128_t and int128_t. None of the versions I tested on the Godbolt compiler explorer define those types without leading __, from gcc4.1 to 8.2 , or clang or ICC.)

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    long long int is 64 bits in every implementation I've used, including GCC for x86-64. And I believe that GCC's 128-bit int is only available on 64-bit platforms.
    – interjay
    Apr 18, 2013 at 16:34
  • I just tried it in 2 systems, and they stand by your results. I've removed the assertion of it going up to 128 bits long.
    – slezica
    Apr 18, 2013 at 16:52
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    gcc 4.7.2 on Linux x86_64 doesn't have []int128_t. I suppose it's possible gcc 4.8.0 might have it. Apr 18, 2013 at 17:51
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    Try typedef int really_long __attribute__ ((mode (TI)));. It has worked for a long time (on architectures with native 64-bit). Apr 18, 2013 at 20:39
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    gcc-4.1 -m64 and above support __uint128_t out-of-the-box, and they also support the following typedef: typedef unsigned uint128_t __attribute__ ((mode (TI)));.
    – pts
    Jan 1, 2014 at 21:54

You could use a library which handles arbitrary or large precision values, such as the GNU MP Bignum Library.

  • Reed gave a perfectly valid answer for non-64-bit machines. This question is the number one response to a search for "C int128", so having a general answer for any platform is a good thing. Maybe next time if you feel so strong about this subject write an answer instead of tearing someone else down (that way you can reap the rep benefits as well).
    – CrazyCasta
    Oct 29, 2020 at 5:35
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    @CrazyCasta having an arbitrary-precision library just for a 128-bit type is just too wasteful, and the overhead is just too big. A fixed-width library like Boost.Multiprecision or calccrypto/uint128_t will be much smaller and faster
    – phuclv
    Jan 12, 2021 at 9:24

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