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I'm using sqrt() function from math library, when I build for 64 bit using -m64 I'm getting correct result but when I build for 32 bit I have very inconsistent behaviour.

For example on 64bit

double dx = 0x1.fffffffffffffp+1023;
sqrt(dx); // => 0x1.fffffffffffffp+511
sqrt(0x1.fffffffffffffp+1023);// => 0x1.fffffffffffffp+511

(which I believe is the correctly rounded result, verified with mpfr)

But on 32 bit same input value it behaves differently.

double dx = 0x1.fffffffffffffp+1023;
sqrt(dx); // => 0x1.0p+512
sqrt(0x1.fffffffffffffp+1023); // => 0x1.fffffffffffffp+511

When the same value passed in a variable I'm getting wrong result. I checked rounding mode before and after each call and all are set to round to nearest. What the reason? I'm using gcc 4.6 on a 64bit machine, and options are -mfpmath=sse and -march=pentium for both x86 nad x64 cases.

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There seems to be one bug open on this at, even when I use -msse2 for 32bit i386 code is the one that gets executed. – kanna May 30 '12 at 15:13

2 Answers 2

up vote 6 down vote accepted

You haven't said which compiler or architecure you're using, but assuming gcc on x86 / x86-64 then the difference is likely down to the fact that by default gcc uses 387 floating point instructions on 32 bit x86, whereas it uses SSE instructions on x86-64.

The 387 floating point registers are 80 bits wide, whereas double is 64 bits wide. This means that intermediate results can have higher precision using the 387 instructions, which can result in a slightly different answer after rounding. (The SSE2 instructions operate on packed 64 bit doubles).

There's a few ways to change the way the compiler operates, depending on what you want:

  • If you use the -ffloat-store option on x86 builds, the compiler will discard extra precision whenever you store a value in a double variable;
  • If you use the -mfpmath=sse options on x86 builds, along with -msse2 or an -march= switch that specifies an SSE2-supporting architecture, the compiler will use SSE instructions for floating point just as on x86-64. The code will only run on CPUs that support SSE2, though (Pentium-M / Pentium 4 and later).
  • If you use the -mfpmath=387 option on x86-64 builds, the compiler will use 387 instructions for floating point just as on x86. This isn't recommended, though - the x86-64 ABI specifies that floating point values are passed in SSE registers, so the compiler has to do a lot of shuffling between 387 and SSE registers with this option.
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I'm using gcc 4.6 on a 64bit machine, and options are -mfpmath=sse and -march=pentium for both x86 nad x64 cases. Shoudln't I be getting same result from both cases? I'm mostly interested in 32 bit build so I guess -mfpmath=387 might give me correct result if there are no other problems – kanna May 30 '12 at 1:23
@giridhart: -march=pentium only enables SSE1, which only does single-precision - for double-precision it has to fall back to 387 which has the bonus precision. You want -msse2 or -march=pentium-m or similar along with -mfpmath=sse. – caf May 30 '12 at 1:38
Actually I use -mfpmath=sse and -msse, Now I changed to -mfpmath=sse2 but I still getting wrong result. please suggest correct option for fixing this. Thanks – kanna May 30 '12 at 11:16

Certain compilers, such as gcc, when they see certain math library functions performed on static literals, actually calculate the value during compile time, where-as with the variable, it's by necessity calculated at run-time. The compile-time value is typically calculated by the compiler using a math library like MPFR, GNU MP, etc., so the results will be more accurate, or at least as accurate as possible from platform-to-platform.

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I also seem to remember that gcc is willing to do compile-time math on literals using 80-bit precision on x86, while a value that's stored into a double has to be reduced to 64-bit precision. – hobbs May 30 '12 at 0:47
Yep, that too ... – Jason May 30 '12 at 0:47
Yes, I think that the reason for correct result when constant is used. Is there a way to fix problem with 32bit library? There is a similar problem listed on stack overflow but it is with C#… – kanna May 30 '12 at 1:08
@giridhart : From your post it looks as though your 32-bit and 64-bit result with the literal are the same ... are you saying they are different? – Jason May 30 '12 at 1:19
@Jason yeah, I should have added both cases for x64. On x64 both literal and variable case give correct result where as on x86 only the literal case – kanna May 30 '12 at 1:27

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