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If I compile following c lines on windows and linux(ubuntu) I get different results. I would like to avoid. How can I do it?

 double a = DBL_EPSILON;
 double b = sqrt(a);
 printf("eps = %.20e\tsqrt(eps) = %.20e\n", a, b);

linux output:

eps = 2.22044604925031308085e-16        sqrt(eps) = 1.49011611938476562500e-08

windows output:

eps = 2.22044604925031310000e-016       sqrt(eps) = 1.49011611938476560000e-008

On linux tested with gcc and clang on 32-bit and 64-bit system same result. On windows tested with gcc-mingw on 32-bit and visual-studio with 32-bit and 64-bit, also same results.

share|improve this question
What is the underlying architecture of each system? – Mike Nov 26 '12 at 18:44
The printf implementations of the used c libraries differ. The Windows one prints only 17 significant digits or so, and fills with zeros if more are requested. glibc's prints the correctly rounded value. – Daniel Fischer Nov 26 '12 at 18:44
but for me it doesn't seem that it's just an issue of printing, my numerical algorithm also return slightly different results. And I pointed this lines, since I assumed they are the source of differences.# – Will Nov 26 '12 at 19:11
A double variable typically has about 16 significant decimal digits of precision. It's pointless to print or compare digits past that. – Blastfurnace Nov 26 '12 at 19:17
@Blastfurnace: It is not pointless to print digits beyond 16. It may require 54 decimal digits to represent the exact value of a 64-bit IEEE 754 binary floating-point number, and one might want to see the exact value for a variety of reasons, such as transferring values to mathematical software capable of handling more precision or for debugging. – Eric Postpischil Nov 26 '12 at 20:26
up vote 7 down vote accepted

In the example you give, it seems both programs have the same floating-point numbers. They just print them differently. The simplest solution around this particular issue is to write your own floating-point printing function. If you are not expecting too nice an output, you could use the function here as pseudocode for writing your own in C. It is not correctly rounded, but it works for what it is intended for (that is, reproducible and readable outputs).

A deeper issue that your question hints you are encountering is floating-point computations giving different results on different platforms. This is a result of the C standard(s) not forcing compilers to implement the IEEE 754 floating-point standard exactly, specifically, allowing higher precision for intermediate results. And this relative leniency of the C standard(s) is caused at least in part by the historical x86 floating-point instructions making it expensive to implement the exact IEEE 754 semantics.

On Linux, assuming you are using GCC, try the -msse2 compilation option. EDIT: the OP commented that -msse2 -mfpmath=sse worked for him. This makes GCC generate modern SSE2 instructions that give the exact IEEE 754 floating-point semantics. If on Windows you are using GCC too, use the same option there.

If you are using Visual C: Visual C uses another trick to force the historical floating-point instructions to match IEEE 754 semantics: it tells the old 80-bit floating-point hardware to use only as many significand bits as IEEE 754 double-precision has. That gives an accurate simulation of double-precision numbers, except for a few corner cases that you will not be encountering. In this case it would help(*) if your program used only double-precision numbers (the C double type).

(*) The Visual C compiler could theoretically generate code that computes exact single-precision arithmetics by rounding each intermediate result from double to single precision, but this would be expensive and I doubt it does this.

share|improve this answer
I don't know if I would call overflow and underflow "corner case[s] that you will not be encountering"; they occur surprising often in real code. – Stephen Canon Nov 26 '12 at 23:36
@StephenCanon You caught me, I may not have been entirely honest: underflow and overflow can happen. My problem is that I do not have any solution to offer if they do happen, short of manually inserting in the program, everywhere they may happen, intermediate_result = intermediate_result >= 0x1.0p+1024 ? inf : intermediate_result;. And the story is even worse for underflow, for which I do not see any portable code to truncate the significand. If the programmer knows that he is using x87, then two calls to ldexp() should do it, but this will flush denormals to zero on IEEE 754 hardware – Pascal Cuoq Nov 26 '12 at 23:56
@StephenCanon Also, the “two calls to ldexp()` solution introduces double rounding. – Pascal Cuoq Nov 26 '12 at 23:57
Yes, it's an incredibly thorny issue; let's hope that the questioner is lucky enough to avoid it. – Stephen Canon Nov 26 '12 at 23:59
It seem that for gcc "-msse2 -mfpmath=sse" works for my issue. Thanks! – Will Nov 28 '12 at 0:12

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