Modern CPU's can perform extended multiplication between two native-size words and store the low and high result in separate registers. Similarly, when performing division, they store the quotient and the remainder in two different registers instead of discarding the unwanted part.

Is there some sort of portable gcc intrinsic which would take the following signature:

void extmul(size_t a, size_t b, size_t *lo, size_t *hi);

Or something like that, and for division:

void extdiv(size_t a, size_t b, size_t *q, size_t *r);

I know I could do it myself with inline assembly and shoehorn portability into it by throwing #ifdef's in the code, or I could emulate the multiplication part using partial sums (which would be significantly slower) but I would like to avoid that for readability. Surely there exists some built-in function to do this?

  • But when optimizing with -O3 GCC will probably emit the right processor-specific extended multiplication or division (perhaps even using both modulus & remainder, if your program use both), so I would not bother about that in your code. Commented Nov 2, 2012 at 0:37
  • @BasileStarynkevitch But you'd need 128-bit integer-support - which GCC does not have for x64. There's no way you can "trick" GCC into emitting a 64x64 -> 128-bit multiply or a 128-bit/64-bit -> 64-bit divide using just 64-bit integers in C.
    – Mysticial
    Commented Nov 2, 2012 at 0:41
  • If you need 128-bit, gcc might have some extended type like __int128 or something that could get you the effects you want without cpu-specific code. For 64-bit (on 32-bit machines), just using long long works fine. Commented Nov 2, 2012 at 0:43
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    FWIW, MSVC has an intrinsic for the extended multiply that you're looking for (64x64 ->128). In GCC x64, I just use an inline assembly macro.
    – Mysticial
    Commented Nov 2, 2012 at 0:48
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    @Mystical The "integer mode" in the link you gave does not correspond to the native integer width, it is rather the "machine mode". Most 64 bit targets do actually support QImode, which is 128 bit. Especially on x86_64 128bit ints work just fine. Commented Nov 2, 2012 at 1:23

2 Answers 2


For gcc since version 4.6 you can use __int128. This works on most 64 bit hardware. For instance

To get the 128 bit result of a 64x64 bit multiplication just use

void extmul(size_t a, size_t b, size_t *lo, size_t *hi) {
    __int128 result = (__int128)a * (__int128)b;
    *lo = (size_t)result;
    *hi = result >> 64;

On x86_64 gcc is smart enough to compile this to

   0:   48 89 f8                mov    %rdi,%rax
   3:   49 89 d0                mov    %rdx,%r8
   6:   48 f7 e6                mul    %rsi
   9:   49 89 00                mov    %rax,(%r8)
   c:   48 89 11                mov    %rdx,(%rcx)
   f:   c3                      retq   

No native 128 bit support or similar required, and after inlining only the mul instruction remains.

Edit: On a 32 bit arch this works in a similar way, you need to replace __int128_t by uint64_t and the shift width by 32. The optimization will work on even older gccs.

  • So is there really no way to make this work in general for any word size (not just 64-bit) without resorting to a bunch of #ifdef's? If not, I will accept this answer..
    – Thomas
    Commented Nov 2, 2012 at 1:01
  • This will work on a 32 bit arch in a similar way if you you need the two 32 bit parts of the 64 bit result. You need to make the shift width 32 bit - I am sure there is an appropriate macro somewhere defined in the stdlib Commented Nov 2, 2012 at 1:03
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    @Thomas What is probably missing though is something like dsize_t which would be a double width size_t type - like the __int128 or uint64_t on 64/32 bit arches. Commented Nov 2, 2012 at 1:11
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    @BasileStarynkevitch Just tested it, gcc-4.5 does not know 128bit ints, gcc-4.6 does. Commented Nov 2, 2012 at 8:20
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    For completeness: Intel ICC version 13.0 recognizes __int128 (and/or __int128_t) as well, ICC 12.1 and below doesn't know it.
    – FrankH.
    Commented Nov 9, 2012 at 11:29

For those wondering about the other half of the question (division), gcc does not provide an intrinsic for that because the processor division instructions don't conform to the standard.

This is true both with 128-bit dividends on 64-bit x86 targets and 64-bit dividends on 32-bit x86 targets. The problem is that DIV will cause divide overflow exceptions in cases where the standard says the result should be truncated. For example (unsigned long long) (((unsigned _int128) 1 << 64) / 1) should evaluate to 0, but would cause divide overflow exception if evaluated with DIV.

(Thanks to @ross-ridge for this info)

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    This is a reason for not optimizing 64/32 into idiv, not a reason for not providing an intrinsic. There are many __builtin functions of GCC that invokes undefined behavior with some arguments.
    – user202729
    Commented Jan 11, 2020 at 2:35
  • It's more because the 64 bit mul instruction returns the results in two registers, one for high part and one for the low part, the arguments are still 64 bit (it's similar for 32bit CPUs with 64 bit result). For division the dividend and divisor would have to be passed in as two registers, and there is no instruction like that (there is partial one for dividing 128 bit with 64 bit, at least on x86_64). Commented Jul 25, 2022 at 19:26

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