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This a very simple question, but an important one since it affects my whole project tremendously.

Suppose I have the following code snipet:

unsigned int x = 0xffffffff;
float f = (float)((double)x * (double)2.328306436538696e-010); //  x/2^32

I would expect that f be something like 0.99999, but instead, it rounds up to 1, since it's the closest float approximation. That's not good since I need float values on the interval of [0,1), not [0,1]. I'm sure it's something simple, but I'd appreciate some help.

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5 Answers 5

In C (since C99), you can change the rounding direction with fesetround from libm

#include <stdio.h>
#include <fenv.h>
int main()
{
    #pragma STDC FENV_ACCESS ON
    fesetround(FE_DOWNWARD);
    // volatile -- uncomment for GNU gcc and whoever else doesn't support FENV
    unsigned long x = 0xffffffff;
    float f = (float)((double)x * (double)2.328306436538696e-010); //  x/2^32
    printf("%.50f\n", f);
}

Tested with IBM XL, Sun Studio, clang, GNU gcc. This gives me 0.99999994039535522460937500000000000000000000000000 in all cases

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Is this a C++11 function? –  Mark B Aug 6 '13 at 16:49
    
@MarkB C99 function, included in C++11 –  Cubbi Aug 6 '13 at 16:53
    
@EricPostpischil thanks for pointing out, rewrote in C –  Cubbi Aug 6 '13 at 17:16
1  
+1 for #pragma STDC FENV_ACCESS ON and // volatile -- … –  Pascal Cuoq Aug 6 '13 at 17:38
    
Would it be possible to make this code put the rounding direction back immediately after doing the conversion? –  Patricia Shanahan Aug 7 '13 at 16:22

The value above which a double rounds to 1 or more when converted to float in the default IEEE 754 rounding mode is 0x1.ffffffp-1 (in C99's hexadecimal notation, since your question is tagged “C”).

Your options are:

  1. turn the FPU rounding mode to round-downward before the conversion, or
  2. multiply by (0x1.ffffffp-1 / 0xffffffffp0) (give or take one ULP) to exploit the full single-precision range [0, 1) without getting the value 1.0f.

Method 2 leads to use the constant 0x1.ffffff01fffffp-33:

double factor = nextafter(0x1.ffffffp-1 / 0xffffffffp0, 0.0);
unsigned int x = 0xffffffff;
float f = (float)((double)x * factor);
printf("factor:%a\nunrounded:%a\nresult:%a\n", factor, (double)x * factor, f);

Prints:

factor:0x1.ffffff01fffffp-33
unrounded:0x1.fffffefffffffp-1
result:0x1.fffffep-1
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You could just truncate the value to maximum precision (keeping the 24 high bits) and divide by 2^24 to get the closest value a float can represent without being rounded to 1;

unsigned int i = 0xffffffff;
float value = (float)(i>>8)/(1<<24);

printf("%.20f\n", value);
printf("%a\n", value);

>>> 0.99999994039535522461
>>> 0x1.fffffep-1
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This may be a good approach, if rounding every value toward zero (not just the ones near 1) suits the OP. The hack for illustration is unnecessary; we can use the %a format specifier to display floating-point numbers in a way that illustrates their composition. –  Eric Postpischil Aug 6 '13 at 17:01
    
@EricPostpischil Thanks for the %a format, did not know about that. –  Joachim Isaksson Aug 6 '13 at 17:06

There's not much you can do - your int holds 32 bits but the mantissa of a float holds only 24. Rounding is going to happen. You could change the processor rounding mode to round down instead of to nearest, but that is going to cause some side effects that you want to avoid especially if you don't restore the rounding mode when you are finished.

There's nothing wrong with the formula you're using, it's producing the most accurate answer possible for the given input. There's just an end case that's failing a hard requirement. There's nothing wrong with testing for the specific end case and replacing it with the closest value that meets the requirement:

if (f >= 1.0f)
    f = 0.99999994f;

0.999999940395355224609375 is the closest value that an IEEE-754 float can take without being equal to 1.0.

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1  
This is not a helpful answer. As other answers have shown (and they have shown how), there are things you can do. –  Eric Postpischil Aug 6 '13 at 17:02
    
@EricPostpischil, how is it not helpful? It provides a working solution to the problem, without leaving a rounding mode in effect which will change all intermediate and subsequent calculations. –  Mark Ransom Aug 6 '13 at 17:23
    
The statement “There’s not much you can do” is misleading and needlessly discouraging. The statement about bits in an int and a float is irrelevant; the OP does not expect an exact map. They are not asking to avoid rounding, just to control it. –  Eric Postpischil Aug 6 '13 at 17:33
    
@EricPostpischil, I asserted that there will be rounding because the problem definition makes it unavoidable, and I gave my reasoning. You can change the nature of the rounding but you can't avoid it. Mine is the only answer which handles the edge case while maintaining the highest possible accuracy in all other cases. –  Mark Ransom Aug 6 '13 at 18:58
up vote 0 down vote accepted

My eventual solution was to just shrink the size of my constant multiplier. It was probably the best solution since there was no point in multiplying by a double anyway. The precision was not seen after conversion to a float.

so 2.328306436538696e-010 was changed to 2.3283063

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