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When reading Lua's source code, I noticed that Lua uses a macro to round a double to a 32-bit int. I extracted the macro, and it looks like this:

union i_cast {double d; int i[2]};
#define double2int(i, d, t)  \
    {volatile union i_cast u; u.d = (d) + 6755399441055744.0; \
    (i) = (t)u.i[ENDIANLOC];}

Here ENDIANLOC is defined as endianness, 0 for little endian, 1 for big endian. Lua carefully handles endianness. t stands for the integer type, like int or unsigned int.

I did a little research and there's a simpler format of macro that uses the same thought:

#define double2int(i, d) \
    {double t = ((d) + 6755399441055744.0); i = *((int *)(&t));}

Or in a C++-style:

inline int double2int(double d)
    d += 6755399441055744.0;
    return reinterpret_cast<int&>(d);

This trick can work on any machine using IEEE 754 (which means pretty much every machine today). It works for both positive and negative numbers, and the rounding follows Banker's Rule. (This is not suprising, since it follows IEEE 754.)

I wrote a little program to test it:

int main()
    double d = -12345678.9;
    int i;
    double2int(i, d)
    printf("%d\n", i);
    return 0;

And it outputs -12345679, as expected.

I would like to get into detail how this tricky macro works. The magic number 6755399441055744.0 is actually 2^51 + 2^52, or 1.5 * 2^52, and 1.5 in binary can be represented as 1.1. When any 32-bit integer is added to this magic number, well, I'm lost from here. How does this trick work?

P.S: This is in Lua source code, Llimits.h.


  1. As @Mysticial points out, this method doesn't limit itself to a 32-bit int, it can also be expanded to a 64-bit int as long as the number is in the range of 2^52. (The macro needs some modification.)
  2. Some materials say this method can't be used in Direct3D.
  3. When working with Microsoft assembler for x86, there's an even faster macro written in assembly (this is also extracted from Lua source):

    #define double2int(i,n)  __asm {__asm fld n   __asm fistp i}
  4. There is a similar magic number for single precision number: 1.5 * 2 ^23

share|improve this question
"fast" compared to what? – Cory Nelson Jun 11 '13 at 2:18
@CoryNelson Fast compared to a simple cast. This method, when implemented properly (with SSE intrinsics) is quite literally a hundred times faster than a cast. (which invokes a nasty function call to a rather expensive conversion code) – Mysticial Jun 11 '13 at 2:22
Right -- I can see it being faster than ftoi. But if you're talking SSE, why not just use the single instruction CVTTSD2SI? – Cory Nelson Jun 11 '13 at 2:38
@tmyklebu Many of the use cases that go double -> int64 are indeed within the 2^52 range. These are particularly common when performing integer convolutions using floating-point FFTs. – Mysticial Jun 11 '13 at 3:55
@MSalters Not necessarily true. A cast must live up to the language's specification - including proper handling of overflow and NAN cases. (or whatever the compiler specifies in the case IB or UB) These checks tend to be very expensive. The trick mentioned in this question completely ignores such corner cases. So if you want the speed and your application doesn't care (or never encounters) such corner cases, then this hack is perfectly appropriate. – Mysticial Jun 11 '13 at 15:15
up vote 152 down vote accepted

A double is represented like this:

double representation

and it can be seen as two 32-bit integers; now, the int taken in all the versions of your code (supposing it's a 32-bit int) is the one on the right in the figure, so what you are doing in the end is just taking the lowest 32 bits of mantissa.

Now, to the magic number; as you correctly stated, 6755399441055744 is 2^51 + 2^52; adding such a number forces the double to go into the "sweet range" between 2^52 and 2^53, which, as explained by Wikipedia here, has an interesting property:

Between 252=4,503,599,627,370,496 and 253=9,007,199,254,740,992 the representable numbers are exactly the integers

This follows from the fact that the mantissa is 52 bits wide.

The other interesting fact about adding 251+252 is that it affects the mantissa only in the two highest bits - which are discarded anyway, since we are taking only its lowest 32 bits.

Last but not least: the sign.

IEEE 754 floating point uses a magnitude and sign representation, while integers on "normal" machines use 2's complement arithmetic; how is this handled here?

We talked only about positive integers; now suppose we are dealing with a negative number in the range representable by a 32-bit int, so less (in absolute value) than (-2^31+1); call it -a. Such a number is obviously made positive by adding the magic number, and the resulting value is 252+251+(-a).

Now, what do we get if we interpret the mantissa in 2's complement representation? It must be the result of 2's complement sum of (252+251) and (-a). Again, the first term affects only the upper two bits, what remains in the bits 0~50 is the 2's complement representation of (-a) (again, minus the upper two bits).

Since reduction of a 2's complement number to a smaller width is done just by cutting away the extra bits on the left, taking the lower 32 bits gives us correctly (-a) in 32 bit, 2's complement arithmetic.

share|improve this answer
"""The other interesting fact about adding 2^51+2^52 is that it affects the mantissa only in the two highest bits - which are discarded anyway, since we are taking only its lowest 32 bits""" What is that ? Adding this may shift all the mantissa ! – John Optional Smith Jun 11 '13 at 18:40
@John: of course, the whole point of adding them is to force the value to be in that range, which obviously can result in shift the mantissa (between the other things) in respect to the original value. What I was saying here is that, once you are in that range, the only bits that differ from the corresponding 53 bits integer are bit 51 and 52, which are discarded anyway. – Matteo Italia Jun 11 '13 at 21:37

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