When I try to assign an 128-bit integer in gcc 4.9.1, I get a warning: integer constant is too large for its type.

Example Code

int main(void) {
  __uint128_t p = 47942806932686753431;

  return 0;


I'm compiling with gcc -std=c11 -o test test.c and I get:

test.c: In function ‘main’:
test.c:2:19: warning: integer constant is too large for its type
   __uint128_t p = 47942806932686753431;

Am I doing something wrong or is this a bug in gcc?

  • Also see "Why isn't there int128_t?" answer. Commented Jul 16, 2015 at 18:13
  • 15
    ((__uint128_t)47942806*1000000+932686)*1000000+753431 Commented Jul 16, 2015 at 18:15
  • BTW, you should probably replace instances of __uint128_t with unsigned __int128. The former appears to be 'deprecated'.
    – Brett Hale
    Commented Jul 16, 2015 at 19:26
  • "When I try to assign an 128 bit integer" Whoops, nope, that's not what you're doing. You're trying to assign to an 128 bit integer, but the thing you're assigning to it is not one! Commented Oct 25, 2015 at 15:29
  • There are 128 bit integers now? Right. 128-bit. Exponential growth. Is this to do with encryption?! Commented Jul 13, 2018 at 13:20

4 Answers 4


Am I doing something wrong or is this a bug in gcc?

The problem is in 47942806932686753431 part, not in __uint128_t p. According to gcc docs there's no way to declare 128 bit constant:

There is no support in GCC for expressing an integer constant of type __int128 for targets with long long integer less than 128 bits wide.

So, it seems that while you can have 128 bit variables, you cannot have 128 bit constants, unless your long long is 128 bit wide.

The workaround could be to construct 128 bit value from "narrower" integral constants using basic arithmetic operations, and hope for compiler to perform constant folding.

  • 2
    Maybe "cannot have 128 bit integer constants, unless your intmax_t is at least 128 bit wide"? Commented Jul 16, 2015 at 18:07
  • I'm not sure. The quoted docs mention "long long integer" type specifically. Commented Jul 16, 2015 at 18:14
  • In reader the C11 draft spec, it is clear that integer constants must have at least the range of long long/unsigned long long. It is not clear if integer constants must have at least the range of intmax_t/uintmax_t. I would think it would be required. Commented Jul 16, 2015 at 18:32
  • @chux, these types are extensions and not covered by the standard. For the intmax_t types the standard provides the corresponding macros INTMAX_C that are guaranteed to create constants of the correct type. Commented Jul 16, 2015 at 18:48
  • 5
    @el.pescado, while there is no direct support, you still can have constant expressions of that type. E.g ((__int128_t)1000000000000*HIGH)+LOW could be a way of constructing such an expression for a large value, where HIGH and LOW are the higher and lower digits of the number. Commented Jul 16, 2015 at 18:51

Have you tried this?

__int128 p = *(__int128*) "\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c\x0d\x0e\x0f";

EDIT Nov. 25

Sorry for the poor clarification on previous post. Seriously, I didn't post this answer as a joke. Though the GCC doc states there's no way to express a 128-bit integer constant, this post simply provides a workaround for those who wants to assign values to __uint128_t variables with ease.

You may try to compile the code below with GCC (7.2.0) or Clang (5.0.0). It prints desired results.

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

int main()
    __uint128_t p = *(__int128*) "\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c\x0d\x0e\x0f";
    printf("HIGH %016llx\n", (uint64_t) (p >> 64));
    printf("LOW  %016llx\n", (uint64_t) p);
    return 0;

The stdout:

HIGH 0f0e0d0c0b0a0908
LOW  0706050403020100

This is only regarded as a workaround since it plays tricks on pointers by placing the "value" in .rodata section (if you objdump it), and it's not portable (x86_64 and aarch64 are fine but not arm and x86). I think it's been enough for those coding on desktop machines.

  • 3
    Is this intended to be a joke? Commented Oct 25, 2015 at 15:29
  • 7
    Even assuming the string value is correct for whatever endianness is needed, that will likely result in a SIGBUS for any architecture that has alignment restrictions on __int128 variables. Commented Oct 25, 2015 at 15:33
  • 1
    I found it actually works for gcc 5.2.0 on x86_64. Even with int n = *(int*) "1234";. Maybe Andrew is right. The string constant is not guaranteed to be aligned and thus this trick may not work on archs other than x86.
    – jerry73204
    Commented Oct 27, 2015 at 7:05
  • @jerry73204 : in my case, the compiler is complaining in C99 about the pointer with error: expression must have a constant value __int128 llong_min=(*((char *){"\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xfd"})); ^ Commented Jun 15, 2020 at 23:58
  • 2
    Apart from alignment, the solution in this answer also has problems with strict aliasing, but something like __uint128_t q = (union { unsigned char r[16]; __uint128_t i; }) {00,01,02,03,04,05,06,07,8,9,0xa,0xb,0xc,0xd,0xe,0xf}.i; works. It assumes the endianness and the width of char as 8 bits, but so does the answer above this comment. Commented Oct 19, 2020 at 11:20

I'd suggest a simple macro to combine two 64-bit values:

#define UINT128(hi, lo) (((__uint128_t) (hi)) << 64 | (lo))

Example usage:

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

#define UINT128(hi, lo) (((__uint128_t) (hi)) << 64 | (lo))

int main() {
  // Creates constant 0x010203040506070890a0b0c0d0e0f10
  __uint128_t x = UINT128(0x0102030405060708, 0x090a0b0c0d0e0f10);

  // Prints 1, 2, 3, 4, .. 15, 16
  for (int i = 0; i < 16; ++i) {
    printf("%d ", (int)((x >> (120 - 8*i)) & 255));

Alternatively, you could move the 0x prefix into the macro (not recommended):

#define UINT128(hi, lo) (((__uint128_t) (0x##hi)) << 64 | (0x##lo))

So you can do UINT128(0102030405060708, 090a0b0c0d0e0f10) which is slightly shorter, but that might mess up syntax highlighting, because 0102030405060708 could be misinterpreted as an octal constant, and 090a0b0c0d0e0f10 is not a valid token by itself, which is why I wouldn't recommend this.


I had same issue and cooked up a solution using user-defined literals. Here is how you instantiate the user-defined literal _xxl:

int main(int argc, char** argv) {

    auto a = 0xF0000000000000000000000000000000LLU;
    auto b = 0xF0000000000000000000000000000000_xxl;
    printf("sizeof(a): %zu\n", sizeof(a));
    printf("sizeof(b): %zu\n", sizeof(b));

    printf("a == 0? %s\n", a==0 ? "true":"false");
    printf("b == 0? %s\n", b==0 ? "true":"false");

    printf("b >> 124 = %x\n", b >> 124);

    return 0;


sizeof(a): 8
sizeof(b): 16
a == 0? true
b == 0? false
b >> 124 = f

Here is the implementation for the user-defined literal _xxl

#pragma once

#include <stdint.h>

#ifdef __SIZEOF_INT128__
    using uint_xxl_t = __uint128_t;
    using sint_xxl_t = __int128_t;
namespace detail_xxl
    constexpr uint8_t hexval(char c) 
    { return c>='a' ? (10+c-'a') : c>='A' ? (10+c-'A') : c-'0'; }

    template <int BASE, uint_xxl_t V>
    constexpr uint_xxl_t lit_eval() { return V; }
    template <int BASE, uint_xxl_t V, char C, char... Cs>
    constexpr uint_xxl_t lit_eval() {
        static_assert( BASE!=16 || sizeof...(Cs) <=  32-1, "Literal too large for BASE=16");
        static_assert( BASE!=10 || sizeof...(Cs) <=  39-1, "Literal too large for BASE=10");
        static_assert( BASE!=8  || sizeof...(Cs) <=  44-1, "Literal too large for BASE=8");
        static_assert( BASE!=2  || sizeof...(Cs) <= 128-1, "Literal too large for BASE=2");
        return lit_eval<BASE, BASE*V + hexval(C), Cs...>();
    template<char... Cs > struct LitEval 
    {static constexpr uint_xxl_t eval() {return lit_eval<10,0,Cs...>();} };

    template<char... Cs> struct LitEval<'0','x',Cs...> 
    {static constexpr uint_xxl_t eval() {return lit_eval<16,0,Cs...>();} };

    template<char... Cs> struct LitEval<'0','b',Cs...> 
    {static constexpr uint_xxl_t eval() {return lit_eval<2,0,Cs...>();} };

    template<char... Cs> struct LitEval<'0',Cs...> 
    {static constexpr uint_xxl_t eval() {return lit_eval<8,0,Cs...>();} };
    template<char... Cs> 
    constexpr uint_xxl_t operator "" _xxl() {return LitEval<Cs...>::eval();}

template<char... Cs> 
constexpr uint_xxl_t operator "" _xxl() {return ::detail_xxl::operator "" _xxl<Cs...>();}
#endif // __SIZEOF_INT128__

It can be used in constexpr just like normal integer constants:

static_assert(   0_xxl == 0, "_xxl error" );
static_assert( 0b0_xxl == 0, "_xxl error" );
static_assert(  00_xxl == 0, "_xxl error" );
static_assert( 0x0_xxl == 0, "_xxl error" );

static_assert(   1_xxl == 1, "_xxl error" );
static_assert( 0b1_xxl == 1, "_xxl error" );
static_assert(  01_xxl == 1, "_xxl error" );
static_assert( 0x1_xxl == 1, "_xxl error" );

static_assert(      2_xxl == 2, "_xxl error" );
static_assert(   0b10_xxl == 2, "_xxl error" );
static_assert(     02_xxl == 2, "_xxl error" );
static_assert(    0x2_xxl == 2, "_xxl error" );

static_assert(      9_xxl == 9, "_xxl error" );
static_assert( 0b1001_xxl == 9, "_xxl error" );
static_assert(    011_xxl == 9, "_xxl error" );
static_assert(    0x9_xxl == 9, "_xxl error" );

static_assert(     10_xxl == 10, "_xxl error" );
static_assert(    0xa_xxl == 10, "_xxl error" );
static_assert(    0xA_xxl == 10, "_xxl error" );

static_assert( 0xABCDEF_xxl == 0xABCDEF, "_xxl error" );
static_assert( 1122334455667788_xxl == 1122334455667788LLu, "_xxl error" );
static_assert(0x80000000000000000000000000000000_xxl >> 126 == 0b10, "_xxl error");
static_assert(0x80000000000000000000000000000000_xxl >> 127 == 0b01, "_xxl error");
static_assert( 0xF000000000000000B000000000000000_xxl > 0xB000000000000000, "_xxl error" );
  • 4
    Thanks for the answer and for your time, but your code is C++, not C.
    – iblue
    Commented Dec 27, 2019 at 9:25
  • ups... I didn't notice that Commented Dec 28, 2019 at 11:25
  • Still, nice answer Commented Apr 21, 2022 at 2:07

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