296

It is well-known that NaNs propagate in arithmetic, but I couldn't find any demonstrations, so I wrote a small test:

#include <limits>
#include <cstdio>

int main(int argc, char* argv[]) {
    float qNaN = std::numeric_limits<float>::quiet_NaN();

    float neg = -qNaN;

    float sub1 = 6.0f - qNaN;
    float sub2 = qNaN - 6.0f;
    float sub3 = qNaN - qNaN;

    float add1 = 6.0f + qNaN;
    float add2 = qNaN + qNaN;

    float div1 = 6.0f / qNaN;
    float div2 = qNaN / 6.0f;
    float div3 = qNaN / qNaN;

    float mul1 = 6.0f * qNaN;
    float mul2 = qNaN * qNaN;

    printf(
        "neg: %f\nsub: %f %f %f\nadd: %f %f\ndiv: %f %f %f\nmul: %f %f\n",
        neg, sub1,sub2,sub3, add1,add2, div1,div2,div3, mul1,mul2
    );

    return 0;
}

The example (running live here) produces basically what I would expect (the negative is a little weird, but it kind of makes sense):

neg: -nan
sub: nan nan nan
add: nan nan
div: nan nan nan
mul: nan nan

MSVC 2015 produces something similar. However, Intel C++ 15 produces:

neg: -nan(ind)
sub: nan nan 0.000000
add: nan nan
div: nan nan nan
mul: nan nan

Specifically, qNaN - qNaN == 0.0.

This... can't be right, right? What do the relevant standards (ISO C, ISO C++, IEEE 754) say about this, and why is there a difference in behavior between the compilers?

  • 18
    Javascript and Python(numpy) do not have this behavior. Nan-NaN is NaN. Perl and Scala also behave similarly. – Paul Aug 25 '15 at 5:18
  • 33
    Maybe you enabled unsafe math optimizations (the equivalent of -ffast-math on gcc)? – Matteo Italia Aug 25 '15 at 5:21
  • 5
    @n.m.: Not true. Annex F, which is optional but normative when supported, and necessary to have floating point behavior specified at all, essentially incorporates IEEE 754 into C. – R.. Aug 25 '15 at 5:25
  • 5
    If you want to ask about the IEEE 754 standard, mention it somewhere in the question. – n.m. Aug 25 '15 at 5:27
  • 68
    I was sure this question was about JavaScript from the title. – MikeTheLiar Aug 25 '15 at 12:51
296

The default floating point handling in Intel C++ compiler is /fp:fast, which handles NaN's unsafely (which also results in NaN == NaN being true for example). Try specifying /fp:strict or /fp:precise and see if that helps.

  • 15
    I was just trying this myself. Indeed, specifying either precise or strict fixes the problem. – imallett Aug 25 '15 at 5:30
  • 65
    I'd like to endorse Intel's decision to default to /fp:fast: if you want something safe, you should probably better avoid NaNs turning up in the first place, and generally don't use == with floating-point numbers. Relying on the weird semantics that IEEE754 assigns to NaN is asking for trouble. – leftaroundabout Aug 25 '15 at 14:24
  • 10
    @leftaroundabout: What do you find weird about NaN, aside from the IMHO horrible decision to have NaN!=NaN return true? – supercat Aug 25 '15 at 16:41
  • 21
    NaNs have important uses - they can detect exceptional situations without requiring tests after every calculation. Not every floating-point developer needs them but don't dismiss them. – Bruce Dawson Aug 25 '15 at 17:03
  • 6
    @supercat Out of curiosity, do you agree with the decision to have NaN==NaN return false? – Kyle Strand Aug 25 '15 at 18:52
52

This . . . can't be right, right? My question: what do the relevant standards (ISO C, ISO C++, IEEE 754) say about this?

Petr Abdulin already answered why the compiler gives a 0.0 answer.

Here is what IEEE-754:2008 says:

(6.2 Operations with NaNs) "[...] For an operation with quiet NaN inputs, other than maximum and minimum operations, if a floating-point result is to be delivered the result shall be a quiet NaN which should be one of the input NaNs."

So the only valid result for the subtraction of two quiet NaN operand is a quiet NaN; any other result is not valid.

The C Standard says:

(C11, F.9.2 Expression transformations p1) "[...]

x − x → 0. 0 "The expressions x − x and 0. 0 are not equivalent if x is a NaN or infinite"

(where here NaN denotes a quiet NaN as per F.2.1p1 "This specification does not define the behavior of signaling NaNs. It generally uses the term NaN to denote quiet NaNs")

19

Since I see an answer impugning the standards compliance of Intel's compiler, and no one else has mentioned this, I will point out that both GCC and Clang have a mode in which they do something quite similar. Their default behavior is IEEE-compliant —

$ g++ -O2 test.cc && ./a.out 
neg: -nan
sub: nan nan nan
add: nan nan
div: nan nan nan
mul: nan nan

$ clang++ -O2 test.cc && ./a.out 
neg: -nan
sub: -nan nan nan
add: nan nan
div: nan nan nan
mul: nan nan

— but if you ask for speed at the expense of correctness, you get what you ask for —

$ g++ -O2 -ffast-math test.cc && ./a.out 
neg: -nan
sub: nan nan 0.000000
add: nan nan
div: nan nan 1.000000
mul: nan nan

$ clang++ -O2 -ffast-math test.cc && ./a.out 
neg: -nan
sub: -nan nan 0.000000
add: nan nan
div: nan nan nan
mul: nan nan

I think it is entirely fair to criticize ICC's choice of default, but I would not read the entire Unix wars back into that decision.

  • Notice that with -ffast-math, gcc is not complying to ISO 9899:2011 with respect to floating point arithmetic any more. – fuz Sep 1 '15 at 11:12
  • 1
    @FUZxxl Yes, the point is that both compilers have a noncompliant floating-point mode, it's just that icc defaults to that mode and gcc doesn't. – zwol Sep 1 '15 at 22:06
  • 4
    Just to throw fuel in the fire, I really like Intel's choice to enable fast math by default. The whole point of using floats is to get high throughput. – Navin Sep 14 '15 at 8:44

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