This question may sound like for beginners, however when I found that out I thought I'm either a beginner or my comp is missing something:

int main()
    cout << sizeof(double) << endl;
    cout << sizeof(long double) << endl;

    cout << DBL_DIG << endl;
    cout << LDBL_DIG << endl;

    return 0;






I thought long double is 10 bytes and has 18 decimal digits while double is 8 bytes and has 15 digits but it seems I was wrong.

Why is that so?

Using MSVC 2010 on 64bit machine.


2 Answers 2


In MSVC++, long double is a synonym for double as you've found out. Apparently this is to take advantage of SSE/SSE2/SSE3 instruction sets which are limited to 64-bit operations.

See also here for more information.

  • Frightening that they'd decrease the size in a 64-bit version. Quick double-check, looks correct: I had to double-check: msdn.microsoft.com/en-us/library/9cx8xs15.aspx Jan 19, 2012 at 10:00
  • 3
    Well, it isn't a synonym, it maps to the same hardware but it is still a different type that you can overload functions on. Jan 23, 2013 at 10:05
  • This sounds like "signed char is a synonym of char, which is also actually false. Whatever the internal representation is, long double is always a different nominal type than double, mandated by the standard. As said before, overloading counts. Plus there is an explicit std::numeric_limits<long double> specialization instead of the alias of std::numeric_limits<double>, and various macros specific to both types named differently.
    – FrankHB
    Dec 5, 2021 at 1:40

The size of all of the basic types is implementation defined, with minimums. In particular, all that you are guaranteed is that double doesn't have less precision and range than float, and that long double doesn't have less precision and range than double.

From a quality of implementation point of view, the compiler should give you the best that the hardware offers. Many (most?) architectures only have two hardware supported floating point types; on such architectures, double and long double will normally be identical. On some architectures, it might make sense to have all three identical. On Intel, a quality implementation will have three different types, because that's what the hardware offers (but an implementation would still be compliant even if all three floating point types were identical). On the other hand, you can argue different sizes for long double: 10 (never seen), 12 (g++) or 16 bytes, for alignment reasons (with some of the bytes unused). An implementation for Intel where long double and double are identical is, however, simply poor quality, and not non-conformant.

  • non-conformant? Also the x87 FPU is deprecated in 64-bit mode (or is it completely inaccessible, even?), so when targeting 64-bit mode, I'd expect double and long double to be identical
    – jalf
    Jan 19, 2012 at 8:35
  • @jalf I don't know about 64-bit mode, but g++ gives sizeof(long double) as 16, and std::numeric_limits<long double>::digits == 64, which looks like what I would expect. (In 32 bit mode, sizeof(long double) is 12, but all of the other values are identical.) If the hardware supports three different sizes of floating point (apparently the case), and the compiler doesn't allow access to them, then this is a serious quality of implementation issue. Jan 19, 2012 at 9:14
  • In 16-bit x86 implementations, sizeof(long double) is generally 10 bytes. Actually, even if individual long doubles are padded to 12 or 16 bytes each, it would seem like it might be helpful to have a ten-byte "packed long double" type which could be placed in a structure, especially if one could pad groups of three (e.g. an XYZ coordinate) to 32 bytes.
    – supercat
    Jun 9, 2012 at 23:19
  • @supercat Yes. The real issue on an x86 architecture is how to align the long double (which affects its size, since the size must be a multiple of the alignment). The size of the actual data is 10 bytes, but depending on the architecture, this can lead to various alignment problems, slowing things down considerably. Jun 11, 2012 at 8:14
  • @JamesKanze: My understanding is that the speed of data access on many processors is only affected by alignment in cases where it affects the number of 'chunk boundaries' an item spans. If data is transferred in 128-bit chunks, a randomly-byte-aligned collection of 64-bit doubles would be likely to have half of the items contained therein span a 128-bit boundary. If one has a collection of 80-bit doubles which are padded out to 128 bits, I would think access should be equally fast whether the padding is at the front or rear. Besides...
    – supercat
    Jun 11, 2012 at 14:54

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