I'm developing a unit test for my application, but I'm faced with a strange problem I don't understand.

The code is:

double res = BytesTool::convertSize(1, BytesTool::Byte, BytesTool::KiloByte);
double tmp = pow((double)1000, -1);
QVERIFY(res == tmp);

I'm compiling from a Linux machine (host 64bits) for Linux 64bits with gcc (host 64bits) and cross compiling for Windows 32bits with Linux's mingw32 compiler.

The program is working fine (assertion success) with the Linux compilation in debug and release mode. For the Windows version, it is working fine in the debug version, but not for the release version; the assertion fails.

The strange part is, if I insert a trace, the test works in Windows:

double res = BytesTool::convertSize(1, BytesTool::Byte, BytesTool::KiloByte);
double tmp = pow((double)1000, -1);
QVERIFY(res == tmp); // Is TRUE when printf("test") is present, FALSE otherwise

I'm lost and I really don't understand what is happening. Why does printf make it work?

Thank for your help.

  • 1
    Can you post the relevant asm code? – Sebastian Hoffmann Mar 3 '14 at 16:52
  • 1
    It's hard to understand what your code is doing since you are using things that are not plain C++. How are BytesTool and QVERIFY defined? – R Sahu Mar 3 '14 at 16:56
  • @Paranaix I agree with your thought, -O3 is optimizing some step out but the printf() restores the behavior. – JayInNyc Mar 3 '14 at 16:57
  • Obligatory: floating-point-gui.de – n.m. Mar 3 '14 at 17:09
  • Thank you but i got enough information from perh. – SaiyanRiku Mar 3 '14 at 17:29

printf will cause it to work because the floating point number will be converted from the internal FPU 80-bit representation (assuming x86 "old-style" math) to the 64-bit that is saved in a double.

The reason for this is that the register value has to be moved to the stack when you call another function (again, assuming x86 old-style FPU calling conventions), which will cause it to be rounded to 64bits of precision.

Your other compilations most likely works because they are using SSE2+ math, which has a native 64-bit floating point type.

== tests that the floats are identical, which is almost never the correct thing to do with floating point numbers.

In this case it is not since the internal CPU representation differs from the one that is stored in a double.

When comparing floating point numbers, always check if they are close enough to each other instead of being equal.

#include <math.h>

QVERIFY( fabs(res-tmp) < DBL_EPSILON )
  • Thank you very much! This help to find the problem. Actually, i already tried with the use of DBL_EPSILON throught a function but i n but it wasn't working in all case. This because i declared it inline. This was i think avoiding the register move of the value, and i wans't comparing double with the same bit size. – SaiyanRiku Mar 3 '14 at 17:28

It will be off by a tiny bit. The Double works the same as floating point and this explains it well https://www.youtube.com/watch?v=PZRI1IfStY0

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