64

I need to store a 128 bits long UUID in a variable. Is there a 128-bit datatype in C++? I do not need arithmetic operations, I just want to easily store and read the value very fast.

A new feature from C++11 would be fine, too.

  • std::bitset might be useful. – ilent2 Aug 26 '13 at 8:11
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    There's libuuid for linux available BTW. – πάντα ῥεῖ Aug 26 '13 at 8:18
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    You're asking two different questions ... a 128-bit datatype doesn't need to be a 128-bit integer. Just use a struct consisting of two 64-bit integers, or any other combination that adds up to 128 bits. – Jim Balter Aug 26 '13 at 8:40
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    @JimBalter: If a user-defined struct is a standard type, what exactly would qualify as a non-standard type? – Benjamin Lindley Aug 26 '13 at 8:53
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    Definitely an XY problem. Simply said, a "128 bit integer type" is a "128 bit type with the usual integer arithmetic operators". UUID's do not need arithmetic operators; UUID * 42 does not make sense. However, operator== is relevant. – MSalters Aug 26 '13 at 9:43
38

GCC and Clang support __int128

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  • 5
    only for 64-bit architectures, though. See gcc.gnu.org/onlinedocs/gcc/_005f_005fint128.html – user3342339 Feb 26 '16 at 19:41
  • Non 64-bit desktops are very rare and if your arduino would totally ever need 128bits to store a single value that's a different topic. @user3342339 – Sahsahae Dec 5 '19 at 17:34
  • Is there a preprocessor define such as HAVE_INT_128_T or something similar we could check? – einpoklum Feb 10 at 23:01
48

Although GCC does provide __int128, it is supported only for targets (processors) which have an integer mode wide enough to hold 128 bits. On a given system, sizeof() intmax_t and uintmax_t determine the maximum value that the compiler and the platform support.

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    Upvoted because it points out an issue with the accepted answer. – CppNoob Feb 2 '16 at 11:36
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    This isn't quite correct: __int128_t is supported on x86-64 (but not i386). It's implemented in 64bit integer registers using addition-with-carry, and extended-precision code for shifts, multiplies, and so on. (The 128b SSE vector registers aren't useful for anything except boolean (AND/OR/XOR), because they can't do a single 128b add. SSE can do two 64b adds, or multiple smaller elements). – Peter Cordes Feb 14 '16 at 22:48
39

Checkout boost's implementation:

#include <boost/multiprecision/cpp_int.hpp>

using namespace boost::multiprecision;

int128_t v = 1;

This is better than strings and arrays, especially if you need to do arithmetic operations with it.

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  • 14
    Boost also has a uuid library btw. – Jesse Good Aug 26 '13 at 8:26
  • @JesseGood I may use that library, but I'd like store the ids in a standard type. – danijar Aug 26 '13 at 8:35
  • Regarding boost, you can also have a look at this post: stackoverflow.com/a/16218841/52568 – Kurt Pattyn Aug 26 '13 at 8:41
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    @danijar: What "standard"? boost uses uint8_t data[16]; while libuuid is unsigned char data[16];, all libraries I know use arrays. – Jesse Good Aug 26 '13 at 8:43
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    @danijar: That's not too difficult, see the answer here. – Jesse Good Aug 26 '13 at 9:28
9

Your question has two parts.

1.128-bin integer. As suggested by @PatrikBeck boost::multiprecision is good way for really big integers.

2.Variable to store UUID / GUID / CLSID or whatever you call it. In this case boost::multiprecision is not a good idea. You need GUID structure which is designed for that purpose. As cross-platform tag added, you can simply copy that structure to your code and make it like:

struct GUID
{
    uint32_t Data1;
    uint16_t Data2;
    uint16_t Data3;
    uint8_t Data4[8];
};

This format is defined by Microsoft because of some inner reasons, you can even simplify it to:

struct GUID
{
    uint8_t Data[16];
};

You will get better performance having simple structure rather than object that can handle bunch of different stuff. Anyway you don't need to do math with GUIDS, so you don't need any fancy object.

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4

There is no 128-bit integer in Visual-C++ because the Microsoft calling convention only allows returning of 2 32-bit values in the RAX:EAX pair. The presents a constant headache because when you multiply two integers together with the result is a two-word integer. Most load-and-store machines support working with two CPU word-sized integers but working with 4 requires software hack, so a 32-bit CPU cannot process 128-bit integers and 8-bit and 16-bit CPUs can't do 64-bit integers without a rather costly software hack. 64-bit CPUs can and regularly do work with 128-bit because if you multiply two 64-bit integers you get a 128-bit integer so GCC version 4.6 does support 128-bit integers. This presents a problem with writing portable code because you have to do an ugly hack where you return one 64-bit word in the return register and you pass the other in using a reference. For example, in order to print a floating-point number fast with Grisu we use 128-bit unsigned multiplication as follows:

#include <cstdint>
#if defined(_MSC_VER) && defined(_M_AMD64)
#define USING_VISUAL_CPP_X64 1
#include <intrin.h>
#include <intrin0.h>
#pragma intrinsic(_umul128)
#elif (__GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 6))
#define USING_GCC 1
#if defined(__x86_64__)
#define COMPILER_SUPPORTS_128_BIT_INTEGERS 1
#endif
#endif

#if USING_VISUAL_CPP_X64
    UI8 h;
    UI8 l = _umul128(f, rhs_f, &h);
    if (l & (UI8(1) << 63))  // rounding
      h++;
    return TBinary(h, e + rhs_e + 64);
#elif USING_GCC
    UIH p = static_cast<UIH>(f) * static_cast<UIH>(rhs_f);
    UI8 h = p >> 64;
    UI8 l = static_cast<UI8>(p);
    if (l & (UI8(1) << 63))  // rounding
      h++;
    return TBinary(h, e + rhs_e + 64);
#else
    const UI8 M32 = 0xFFFFFFFF;
    const UI8 a = f >> 32;
    const UI8 b = f & M32;
    const UI8 c = rhs_f >> 32;
    const UI8 d = rhs_f & M32;
    const UI8 ac = a * c;
    const UI8 bc = b * c;
    const UI8 ad = a * d;
    const UI8 bd = b * d;
    UI8 tmp = (bd >> 32) + (ad & M32) + (bc & M32);
    tmp += 1U << 31;  /// mult_round
    return TBinary(ac + (ad >> 32) + (bc >> 32) + (tmp >> 32), e + rhs_e + 64);
#endif
  }
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  • 1
    the pair is EDX:EAX or RDX:RAX. There's no RAX:EAX pair. – phuclv Mar 7 at 7:53
2

I would recommend using std::bitset<128> (you can always do something like using UUID = std::bitset<128>;). It will probably have a similar memory layout to the custom struct proposed in the other answers, but you won't need to define your own comparison operators, hash etc.

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0

use the TBigInteger template and set any bit range in the template array like this TBigInt<128,true> for being a signed 128 bit integer or TBigInt<128,false> for being an unsigned 128 bit integer. Hope that helps maybe a late reply and someone else found this method already.

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  • 5
    There is no such template in the standard library. What library are you talking about? – HolyBlackCat Dec 15 '18 at 21:33

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