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Our server application does a lot of integer tests in a hot code path, currently we use the following function:

inline int IsInteger(double n)
    return n-floor(n) < 1e-8

This function is very hot in our workload, so I want it to be as fast as possible. I also want to eliminate the "floor" library call if I can. Any suggestions?

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Shouldn't n - floor(n) be exactly 0 if n is an integer? Are you working with very large integers that might exceed the precision of a double? –  Asher Dunn Dec 22 '09 at 4:16
floor should typically be implemented as intrinsic, meaning there is no actual function call in the output. You should check the optimized assembly output to be sure. –  Pavel Minaev Dec 22 '09 at 4:42
do you mean Integer (as in no fractional part) or do you mean int (as in a value between MAX_INT and MIN_INT) –  John Knoeller Dec 22 '09 at 5:00
It would be helpful if you would share the compiler output with us. –  John Knoeller Dec 22 '09 at 5:28
Out of curiosity, what sort of problem domain requires such tests? I would have expected that you would need round rather than floor. E.g. fabs(n-round(n)) < 1e-8. Otherwise you could try using the modf function. –  Craig McQueen Dec 22 '09 at 5:29

5 Answers 5

up vote 8 down vote accepted

A while back I ran a bunch of timings on the most efficient way to convert between floats and integers, and wrote them up. I also timed techniques for rounding.

The short story for you is: converting from a float to an int, or using union hacks, is unlikely to be an improvement due to a CPU hazard called a load-hit-store -- unless the floats are coming from RAM and not a register.

Because it is an intrinsic, abs(floor(x)-eps) is probably the fastest solution. But because this is all very sensitive to the particular architecture of your CPU -- depending on very sensitive things like pipeline depth and store forwarding -- you'll need to time a variety of solutions to find one that is really optimal.

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Thanks! Very good article. –  Long Cheng Dec 22 '09 at 6:27
Thank you. But again I emphasize: you need to precisely time the solutions you are considering with your particular compiler and CPU. This sort of microoptimzation is extremely sensitive to the quirks of a particular CPU stepping's internal design. –  Crashworks Dec 22 '09 at 6:31

Another alternative:

inline int IsInteger(double n)
    double dummy;
    return modf(n, &dummy) == 0.0;
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Here are a couple of answers:

#include <stdint.h>
#include <stdio.h>
#include <math.h>

int IsInteger1(double n)
        uint64_t i;
        double d;
  } u;
  u.d = n;

  int exponent = ((u.i >> 52) & 0x7FF) - 1023;
  uint64_t mantissa = (u.i & 0x000FFFFFFFFFFFFFllu);

  return n == 0.0 ||
        exponent >= 52 ||
        (exponent >= 0 && (mantissa << (12 + exponent)) == 0);

int IsInteger2(double n)
  return n - (double)(int)n == 0.0;

int IsInteger3(double n)
  return n - floor(n) == 0.0;

And a test harness:

#include <stdio.h>
#include <stdlib.h>
#include <sys/time.h>

int IsInteger1(double);
int IsInteger2(double);
int IsInteger3(double);

#define TIMEIT(expr, N) \
  gettimeofday(&start, NULL); \
  for(i = 0; i < N; i++) \
  { \
    expr; \
  } \
  gettimeofday(&end, NULL); \
  printf("%s: %f\n", #expr, (end.tv_sec - start.tv_sec) + 0.000001 * (end.tv_usec - start.tv_usec))

int main(int argc, char **argv)
  const int N = 100000000;
  struct timeval start, end;
  int i;

  double d = strtod(argv[1], NULL);
  printf("d=%lf %d %d %d\n", d, IsInteger(d), IsInteger2(d), IsInteger3(d));

  TIMEIT((void)0, N);
  TIMEIT(IsInteger1(d), N);
  TIMEIT(IsInteger2(d), N);
  TIMEIT(IsInteger3(d), N);

  return 0;

Compile as:

gcc isinteger.c -O3 -c -o isinteger.o
gcc main.c isinteger.o -o isinteger

My results, on an Intel Core Duo:

$ ./isinteger 12345
d=12345.000000 1 1 1
(void)0: 0.357215
IsInteger1(d): 2.017716
IsInteger2(d): 1.158590
IsInteger3(d): 2.746216

Conclusion: the bit twiddling isn't as fast as I might have guessed. The extra branches are probably what kills it, even though it avoids floating-point operations. FPUs are fast enough these days that doing a double-to-int conversion or a floor really isn't that slow.

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Glory be, hard numbers! Any reason why you didn't just write the test in IsInteger2 as n == (double)(int)n? –  caf Dec 22 '09 at 6:02
We do not test for "exactly equal to integer number". A number with fraction part small enough is recognized as integer number in our application, such as "1.000000001". –  Long Cheng Dec 22 '09 at 6:06
In gcc 4.5.0 (20090912), -O2 and -O3 both optimize away the floor call, apparently. –  Nick Presta Dec 22 '09 at 6:25
I carefully checked again and neither -O3 nor -O3 optmized away the "floor" call, I'm using gcc version 4.3.2 (Debian 4.3.2-1.1). –  Long Cheng Dec 22 '09 at 6:32

If doubles on your machine are IEEE-754 compliant, this union describes the double's layout.

   double d;
       int sign     :1
       int exponent :11
       int mantissa :52
} double_breakdown;

This will tell you if the double represents an integer.

Disclaimer 1: I'm saying integer, and not int, as a double can represent numbers that are integers but whose magnitudes are too great to store in an int.

Disclaimer 2: Doubles will hold the closest possible value that they can to any real number. So this can only possibly return whether the represented digits form an integer. Extremely large doubles, for example, are always integers because they don't have enough significant digits to represent any fractional value.

bool is_integer( double d )
    const int exponent_offset = 1023;
    const int mantissa_bits = 52;

    double_breakdown *db = &d;

    // See if exponent is too large to hold a decimal value.
    if ( db->exponent >= exponent_offset + mantissa_bits )
       return true;  // d can't represent non-integers

    // See if exponent is too small to hold a magnitude greater than 1.0.
    if ( db->exponent <= exponent_offset )
       return false; // d can't represent integers

    // Return whether any mantissa bits below the decimal point are set.
    return ( db->mantissa << db->exponent - exponent_offset == 0 );
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Clever, but that looks a lot slower than the OP's existing code... –  Asher Dunn Dec 22 '09 at 4:47
I don't see that it's necessarily slower; floor and (int)n are masking a lot of complexity. –  benzado Dec 22 '09 at 4:58
There is only one way to know for sure: compare assembly output. It's hard to beat compilers at micro-optimizations now. –  Alex B Dec 22 '09 at 5:13
the main cost of this code is the branches, which will only be costly if the branch predictor has trouble predicting. other than that its 2 adds, 3 compares, and some masking implied by the the use of the bitfields. In my experience, compilers do a better job optimizing explicit masks rather than bitfield stuff. But this looks pretty fast to me. –  John Knoeller Dec 22 '09 at 5:25
Definatelay faster than floor() and int(). But perhaps could be speeded up with a couple of && and || bit comparisons on the rather than the >= which would require some bit shifting before the comparison could take place. –  James Anderson Dec 22 '09 at 5:28

If you really want to get hackish, see the IEEE 754 spec. Floating point numbers are implemented as a significand and an exponent. I'm not sure exactly how to do it, but you could probably do something like:

union {
    float f;
    unsigned int i;

This would get you bitwise access to both the significand and exponent. Then you could bit-twiddle your way around.

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What's wrong with this? He asked for a fast, but not necessarily portable way. –  dsimcha Dec 22 '09 at 4:34
Un;ess the number is normalized, I'm not sure this will help a lot, to be honest. –  Pavel Minaev Dec 22 '09 at 4:41
This method does assume that the floating point is normalised. It probably would be, but it's still an assumption. –  dreamlax Dec 22 '09 at 5:38

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