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I have this very simple code:

#include <cstdio>
#include <cmath>

int main(int argc, const char * argv[])
    printf("%2.21f", atan2f(0.f, -1.f));

    return 0;

With next output on Intel CPUs:

Visual Studio 2010: 3.141592741012573200000
GCC 4.8.1         : 3.141592741012573242188
Xcode 5           : 3.141592502593994140625

After reading Appple manual pages for atan2f, I expect the printed value to be near 3.14159265359, as they say they will return +pi for special values like the one I'm using now. As you can see the difference is quite big from the value returned on Xcode and expected value.

Is this a know issue? If yes, is there any workaround to solve this?

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2 Answers 2

up vote 5 down vote accepted

A single-precision floating point number has only about 7 digits of decimal precision. Your test value of 3.14159265359 has 12. If you want better precision, use double or long double and atan2 or atan2l to match.

Likely the reason you're getting "better" results from VS and GCC is that the compiler is noticing your function has constant arguments and is precalculating the result at higher-than-single precision. Check the generated code for proof.

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I'm making the tests in debug mode. In asm code there is a call to atan2f() functions on all platforms. –  Felics Sep 23 '13 at 21:35
So does atan2f on VS and/or GCC convert up to higher precision numbers? –  Carl Norum Sep 23 '13 at 21:37
The correct digits in the results are 3.141592. The digits after that in all three approximations are wrong; they are an artifact of floating-point representation. –  Joni Sep 23 '13 at 21:55
I checked the assembly generated by Visual Studio and the call goes to atan2 with higher precision arguments(cs.smith.edu/~thiebaut/ArtOfAssembly/CH14/…) –  Felics Sep 23 '13 at 21:58

The knee-jerk workaround is to use atan2. Casting that down to float gave me 3.141592741012573242188 just like your GCC 4.8.1 test.

I would assume atan2f gives an answer not quite as precise as a float could hold because it arrives at its answer by some means that means that estimating the output precision is a smarter way to go.

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