7

HI,

I developed some mixed C/C++ code, with some intensive numerical calculations. When compiled in Linux and Mac OS X I get very similar results after the simulation ends. In Windows the program compiles as well but I get very different results and sometimes the program does not seem to work.

I used GNU compilers in all systems. Some friend recommend me to add -frounding-math and now the windows version seems to work more stable, but Linux and Os X, their results, do not change at all.

Could you recommend another options to get more concordance between Win and Linux/OSX versions?

Thanks

P.D. I also tried -O0 (no optimizations) and specified -m32

  • Linux and OS X both use GCC, so I would expect exactly the same results - provided both ran on the same processor architecture. Did you really just get 'similar' results there? If so, some randomness seems to get injected into your computations. Any uninitialized variables?! – Carsten Kuckuk Dec 25 '09 at 16:58
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I can't speak to the implementation in Windows, but Intel chips contain 80-bit floating point registers, and can give greater precision than that specified in the IEEE-754 floating point standard. You can try calling this routine in the main() of your application (on Intel chip platforms):

inline void fpu_round_to_IEEE_double()
{
   unsigned short cw = 0;
   _FPU_GETCW(cw);        // Get the FPU control word
   cw &= ~_FPU_EXTENDED;  // mask out '80-bit' register precision
   cw |= _FPU_DOUBLE;     // Mask in '64-bit' register precision
   _FPU_SETCW(cw);        // Set the FPU control word
}

I think this is distinct from the rounding modes discussed by @Alok.

  • 2
    +1 for mentioning 80-bit registers. I didn't know about _FPU_*. – Alok Singhal Dec 25 '09 at 17:40
  • and that's on x87, which shouldn't be used anymore. SSE math is much faster – phuclv May 30 '14 at 2:59
9

There are four different types of rounding for floating-point numbers: round toward zero, round up, round down, and round to the nearest number. Depending upon compiler/operating system, the default may be different on different systems. For programmatically changing the rounding method, see fesetround. It is specified by C99 standard, but may be available to you.

You can also try -ffloat-store gcc option. This will try to prevent gcc from using 80-bit floating-point values in registers.

Also, if your results change depending upon the rounding method, and the differences are significant, it means that your calculations may not be stable. Please consider doing interval analysis, or using some other method to find the problem. For more information, see How Futile are Mindless Assessments of Roundoff in Floating-Point Computation? (pdf) and The pitfalls of verifying floating-point computations (ACM link, but you can get PDF from a lot of places if that doesn't work for you).

  • +1 for numerical stability: If results vary substantially based on rounding, there's something wrong with the computations. And just to rule out the obvious: You did use 'double' and not just 'float' for your variables?! – Carsten Kuckuk Dec 25 '09 at 16:55
1

In addition to the runtime rounding settings that people mentioned, you can control the Visual Studio compiler settings in Properties > C++ > Code Generation > Floating Point Model. I've seen cases where setting this to "Fast" may cause some bad numerical behavior (e.g. iterative methods fail to converge).

The settings are explained here: http://msdn.microsoft.com/en-us/library/e7s85ffb%28VS.80%29.aspx

  • This gets at the same problem though. The VC++ floating point model setting can be set to force the 80-bit internal representations to be rounded to their 64-bit equivalents at well-defined times, and that should make the results consistent with other implementations that use 64-bit all the way through. – Adrian McCarthy Aug 18 '11 at 20:31
0

The IEEE and C/C++ standards leave some aspects of floating-point math unspecified. Yes, the precise result of adding to floats is determined, but any more complicated calculation is not. For instance, if you add three floats then the compiler can do the evaluation at float precision, double precision, or higher. Similarly, if you add three doubles then the compiler may do the evaluation at double precision or higher.

VC++ defaults to setting the x87 FPUs precision to double. I believe that gcc leaves it at 80-bit precision. Neither is clearly better, but they can easily give different results, especially if there is any instability in your calculations. In particular 'tiny + large - large' may give very different results if you have extra bits of precision (or if the order of evaluation changes). The implications of varying intermediate precision are discussed here:

http://randomascii.wordpress.com/2012/03/21/intermediate-floating-point-precision/

The challenges of deterministic floating-point are discussed here:

http://randomascii.wordpress.com/2013/07/16/floating-point-determinism/

Floating-point math is tricky. You need to find out when your calculations diverge and examine the generated code to understand why. Only then can you decide what actions to take.

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