19

I'm looking to take an IEEE double and remove any integer part of it in the most efficient manner possible.

I want

1035 ->0
1045.23->0.23
253e-23=253e-23

I do not care about properly handling denormals, infinities, or NaNs. I do not mind bit twiddling, as I know I am working with IEEE doubles, so it should work across machines.

Branchless code would be much preferred.

My first thought is (in pseudo code)

char exp=d.exponent;
(set the last bit of the exponent to 1)
d<<=exp*(exp>0);
(& mask the last 52 bits of d)
(shift d left until the last bit of the exponent is zero, decrementing exp each time)
d.exponent=exp;

But the problem is that I can't think of an efficient way to shift d left until the last bit of the exponent is zero, plus it seems it would need to output zero if all of the last bits weren't set. This seems to be related to the base 2 logarithm problem.

Help with this algorithm or any better ones would be much appreciated.

I should probably note that the reason I want branchless code is because I want it to efficiently vectorize.

34

How about something simple?

double fraction = whole - ((long)whole);

This just subtracts the integer portion of the double from the value itself, the remainder should be the fractional component. It's possible, of course, this could have some representation issues.

  • Not sure how the speed compares, but you can also do double fraction = whole%1; – jberg Apr 8 '11 at 1:16
  • 1
    @jberg: See my answer. % doesn't work. – Mehrdad Apr 8 '11 at 1:16
  • 2
    Actually, duh, this is the answer. If it's too big for a long, I can detect that and just set the fractional part to zero. Accepted. – Jeremy Salwen Apr 8 '11 at 1:59
  • 8
    Indeed, any value that big cannot have a fractional part. But you should use int64_t, not long. long might be only 32 bits, in which case the values you need won't fit. – R.. Apr 8 '11 at 3:30
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    @R..: floor would be a better choice than a cast to integer here, I think, at least for modern CPUs (x86 with SSE4 roundpd). Implementing this way requires the compiler to make code that will fail if the double is outside the range of representable long values. A round-trip from FP to integer and back can be slower than rounding. I tried both versions on the Godbolt compiler explorer. floor didn't inline with just -fno-math-errno, unfortunately, so I used -ffast-math. If you can't do that, and can't assume SSE4, casting looks good. – Peter Cordes Jul 23 '16 at 3:36
12

The optimal implementation depends entirely on the target architecture.

On recent Intel processors, this can be achieved with two instructions: roundsd and subsd, but that can't be expressed in portable C code.

On some processors, the fastest way to do this is with integer operations on the floating point representation. Early Atom and many ARM CPUs come to mind.

On some other processors, the fastest thing is to cast to integer and back, then subtract, branching to protect large values.

If you're going to be handling lots of values, you can set the rounding mode to round-to-zero, then add and subtract +/-2^52 to the number truncated to integer, then subtract from the original value to get the fraction. If you don't have SSE4.1, but do have an otherwise modern Intel CPU and want to vectorize, this is typically the best you can do. It only makes sense if you have many values to process, however, because changing the rounding mode is somewhat expensive.

On other architectures, other implementations are optimal. In general, it doesn't make sense to talk about "efficiency" of C programs; only the efficiency of a specific implementation on a specific architecture.

  • Perhaps I should have been more specific about efficiency. I mean efficient portable C99 code which GCC will vectorize. In the sense of mean squared running time on processors weighted by popularity of PC model ownership. – Jeremy Salwen Apr 8 '11 at 9:01
  • I'm found of add/subtract 2^52 (with proper copysign) and round to zero mode, original and neat. – aka.nice Aug 15 '12 at 20:57
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    Can't you express the desired semantics with floor() and the - operator? Then a compiler targeting SSE4 can use roundsd / roundpd to implement those semantics. (But I guess you might need -fno-math-errno or maybe the full -ffast-math to let it actually vectorize floor() to roundpd.) – Peter Cordes Jul 23 '16 at 3:22
10
#include <math.h>
double fraction = fmod(d, 1.0);
  • 1
    I'm specifically asking because this is not efficient enough for my purposes. Obviously I could strip the NaN, infinity handling, and integer part calculation from some implementation of fmod, but it still has more branching in it than I like. – Jeremy Salwen Apr 8 '11 at 1:22
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    @Jeremy: next time tell us that information in the question. – Mark Elliot Apr 8 '11 at 1:24
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    @Jeremy: Ah, I see... how about subtracting the floor? That shouldn't require any branching. – Mehrdad Apr 8 '11 at 1:24
  • That's a good point. Floor may be vectorizable. I will look into that. – Jeremy Salwen Apr 8 '11 at 1:29
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    @Jeremy: _mm_floor_pd might help. – Mehrdad Apr 8 '11 at 1:32
7

Proposal

The function remainder computes the remainder, but not the integer part like modf does:

#include <math.h>

double fracpart(double input)
{
    return remainder(input, 1.);
}

This is the most efficient (and portable) way, as it doesn't compute unnecessary values to do the job (cf. modf, (long), fmod, etc.)


Benchmark

As Mattew suggested in the comments, I wrote some benchmark code to compare this solution to all the other ones offered on this page.

Please find below the time measurements for 65536 computations (compiled with Clang with optimizations turned off):

method 1 took 0.002389 seconds (using remainder)
method 2 took 0.000193 seconds (casting to long)
method 3 took 0.000209 seconds (using floor)
method 4 took 0.000257 seconds (using modf)
method 5 took 0.010178 seconds (using fmod)

Again with Clang, this time using the -O3 flag:

method 1 took 0.002222 seconds (using remainder)
method 2 took 0.000000 seconds (casting to long)
method 3 took 0.000000 seconds (using floor)
method 4 took 0.000223 seconds (using modf)
method 5 took 0.010131 seconds (using fmod)

Turns out the simplest solution seems to give the best results on most platforms, and the specific methods to perform that task (fmod, modf, remainder) are actually super-slow!

  • 1
    Won't this be a problem since remainder() rounds to nearest integral value? fmod() would be ok though. – shadow_map May 12 '15 at 12:29
  • I'd be interested to see how this efficiency compares to others. – Matthew D. Scholefield Jul 4 '16 at 3:45
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    compiled with Clang with optimizations turned off. Then your results are meaningless. Optimization doesn't speed everything up by the same percent. See my answer on this question about an assignment where they had to optimize for -O0. – Peter Cordes Jul 23 '16 at 3:25
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    0.000000 seconds. Sounds like your benchmark optimized away. I do expect that floor or casting to long are going to be very efficient, based on the fact that they only take a couple of fast asm instructions on x86 (vs. slow FP division), but this doesn't demonstrate anything. – Peter Cordes Aug 3 '16 at 15:11
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    If there was a case for merging answers this would be it. – Xofo Dec 20 '18 at 19:31
3

Standard library function modf solves this problem quite neatly.

#include <math.h>
/*...*/
double somenumber;
double integralPart;
double fractionalPart = modf(somenumber, &integralPart);

This should do what you have asked, is portable, and reasonably efficient.

An undocumented detail is whether the second argument could be NULL and then avoid the integral part temporary, which would be desirable in uses such as that you have described.

Unfortunately it seams many implementations do not support NULL for the second argument, so will have to use a temporary whether or not you use this value.

3

Some profiling and experimentation using C++ in Microsoft Visual Studio 2015 indicates that the best method for positive numbers is:

double n;
// ...
double fractional_part = n - floor(n);

It's faster than modf, and, as has already been mentioned, the remainder function rounds to the nearest integer, and therefore isn't of use.

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