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I've written a code that perform mathematical calculations using IIR filters and histograms. The code is supposed to be 100% portable, is reentrant, makes no system call (but memset), has double precision const and initialized variables, and only includes math.h, string.h, stdint.h and stddef.h. It's been made to run in an embedded processor.

When compiling and running the code using Windows MinGW GCC or Borland C++ it will pass all the unit tests. That doesn't happen on the Linux64 GCC platform. Further investigation has shown that the algorithm becomes lightly unstable and the output value doesn't converge to a stable result, instead, the result goes slowly to infinite, so one of the tests will fail.

Most of the code is using double floating-point precision, it also uses single precision in some variables.

I need help on how to approach this problem, I must guarantee the fully portability of code, and I don't know where to look. Also, the code is big enough to be posted here, so, if you can point directions I'll follow.

This is the compile line of the module on Linux:

gcc -O3 -g3 -Wall -c -fmessage-length=0 -MMD -MP -MF"src/flickerModule.d" -MT"src/flickerModule.d" -o "src/flickerModule.o" "../src/flickerModule.c"

This is the compile line of the module on Windows:

gcc -O0 -g3 -Wall -c -fmessage-length=0 -o src\flickerModule.o ..\src\flickerModule.c

Here I show all the dependencies of the code:

fanl@fanl-STI:~/WorkFelipe/Codigos/re7k_eclipsewkspace/flicker_unittest/src$ grep -H -n -E 'mem|sqrt|floor' flickerModule.c
flickerModule.c:76: memset(filt, 0x00, sizeof(struct s_filter));
flickerModule.c:81: memset(filt, 0x00, sizeof(struct s_filter));
flickerModule.c:89: memset(&histo->buf, 0x00, sizeof(uint32_t) * NUM_CLASSES);
flickerModule.c:162:    return (floorf(x + 0.5));
flickerModule.c:189:            memset(&histn, 0x00, sizeof(float) * NUM_CLASSES);
flickerModule.c:262:        hp->Urms_meio_ciclo = sqrt(hp->Acc_Urms_meio_ciclo / NUM_AMOSTRAS_MEIO_CICLO_60Hz);
flickerModule.c:370:        return (sqrtf(saida));
flickerModule.c:393:        p->GanhoNormalizaEntradaFlickerMeter = 1.0 / (p->halfPeriod.Urms_meio_ciclo * sqrt(2));
flickerModule.c:419:            dbg->Prms = sqrt(dbg->Acc_Prms / (NUM_AMOSTRAS_1MIN / FATOR_DOWN1));
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closed as off-topic by David Heffernan, talonmies, wildplasser, Pascal Cuoq, Rubens Jul 5 '13 at 20:13

This question appears to be off-topic. The users who voted to close gave this specific reason:

  • "Questions concerning problems with code you've written must describe the specific problem — and include valid code to reproduce it — in the question itself. See SSCCE.org for guidance." – David Heffernan, talonmies, wildplasser, Rubens
If this question can be reworded to fit the rules in the help center, please edit the question.

Can you post the specific portions of the code that cause the problems? –  Kninnug Jul 4 '13 at 19:24
Do you, by any chance, link DirectX to your code under Windows? –  liori Jul 4 '13 at 19:27
One suggestion, try it with all optimizations disabled (-O0) and see if you still see the same behavior. –  cobbal Jul 4 '13 at 19:30
0) do you compile with a C++ compiler ? 1) are all automatic variables initialised correctly ? 2) does gcc compile cleanly with maximal warnings enabled (-Wall -pedantic, IIRC) ? –  wildplasser Jul 4 '13 at 19:31
@wildplasser Off-topic, questions about code you have written need an SSCCE –  David Heffernan Jul 4 '13 at 20:35

3 Answers 3

up vote 3 down vote accepted

Your linux build is using -O3 (lots of optimisations) and your Windows build is using -O0 (no optimisation). Optimising floating point code is really hard and there is often a trade off between accuracy and speed. Try using -O0 on the linux build. Here's an article about some of the issues regarding optimising floating point code in the VS compiler, and the gcc compiler will face similar issues.

On the IA32, the FPU works at 80bits precision internally, regardless of float or double, and precision is lost when data is written to RAM as the size if reduced from 80bits to 32/64 bits. You can also modify the precision of the transcendental functions, but this is a programmer option and is usually set to highest precision.

Some optimisers will use the SSE registers for manipulating floats and doubles and these work at 32 and 64 bit precision internally. The advantage being that the optimiser could vectorise the code and perform operations in parallel, there are several functions available in the SSE that aren't in the FPU and the programming model of the SSE (CPU style registers) is easier to work with than the FPU (stack based registers). The downside is that the results can be slightly different to those you get from using the FPU due to the reduced precision.

So try compiling both versions using the debug build options and see if there's any difference there.

If you want them to work exactly the same, you may need to consider hand crafting the floating point code to eliminate any peculiarities of the compiler.

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“On the IA32, the FPU works at 80bits precision internally” Only if you do not tell the compiler not to use SSE2 instructions, for the case it is executed on a 10-year-old processor. –  Pascal Cuoq Jul 4 '13 at 22:11
@PascalCuoq: I did mention that SSE registers are used by some compilers. Those 10 year old processors are still used a lot. As you say though, you can stop the compiler from using the SSE registers. –  Skizz Jul 5 '13 at 7:54
Adding -msse2 -mfpmath=sse flags to both compilers made Windows and Linux behaves identically. Now I just have to check how the target platform handles double precision. –  fanl Jul 5 '13 at 16:34

Have you tried running static analysis, using tools such as LDRA/Lint/etc.? Tools like these can often pinpoint areas of concern also does your code compile with maximum warnings turned on without giving any warnings. The compiler will often highlight potential problems as well. Personally I find it good practice in gcc to use -Wall -Werror.

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No error or warning using cppcheck, I'll try Lint. –  fanl Jul 4 '13 at 19:50
Lint is clean, It output some global exposed only. –  fanl Jul 4 '13 at 20:37

(NoTE: this is not an answer, but I need the formatting). You could try to replace all the sizeof (type) lines by the corresponding sizeof expr versions. This is not a panaccea, but more a stylistic hint, leading to more robust code. For a start, you could change:

memset(filt, 0x00, sizeof(struct s_filter));

memset(&histo->buf, 0x00, sizeof(uint32_t) * NUM_CLASSES);

memset(&histn, 0x00, sizeof(float) * NUM_CLASSES);


memset(filt,0, sizeof *filt);

memset(&histo->buf, 0, sizeof histo->buf * NUM_CLASSES);
return (floorf(x + 0.5));
memset(&histn, 0, sizeof histn * NUM_CLASSES);

This could be wrong, just assuming, since I don't know the actual sizes, since you didn't show the struct definitions. BTW: you do not need the hex constant 0x00; it is just zero anyway.

UPDATE: Just to rule out things (arrest the ususal suspects :: differential diagnosis) : try a test run of the code in a single thread. Threading mechanisms may differ between platforms.

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