352

Is there an isnan() function?

PS.: I'm in MinGW (if that makes a difference).

I had this solved by using isnan() from <math.h>, which doesn't exist in <cmath>, which I was #includeing at first.

  • 2
    I not pure you can do it portably. Who says C++ requires IEEE754? – David Heffernan Mar 26 '11 at 8:32
  • See also: how do I make a portable isnan/isinf function – bobobobo Jun 30 '13 at 21:53
  • Just a note, 1 oz of prevention is better than 1 lb of cure. In other words, preventing 0.f/0.f from ever being executed is far better than retroactively checking for nan's in your code. nan is can be terribly destructive to your program, if allowed to proliferate it can introduce hard to find bugs. This is because nan is toxic, (5*nan=nan), nan is not equal to anything (nan != nan), nan not greater than anything (nan !> 0), nan is not less than anything (nan !< 0). – bobobobo Aug 16 '13 at 22:31
  • 1
    @bobobobo: That's a feature, allowing centralized error checking. Just like exceptions vs return values. – Ben Voigt Jan 12 '15 at 3:41
  • 1
    Why doesn't <cmath> have isnan()? It's in std:: – frankliuao Jul 2 '17 at 18:12

20 Answers 20

334

According to the IEEE standard, NaN values have the odd property that comparisons involving them are always false. That is, for a float f, f != f will be true only if f is NaN.

Note that, as some comments below have pointed out, not all compilers respect this when optimizing code.

For any compiler which claims to use IEEE floating point, this trick should work. But I can't guarantee that it will work in practice. Check with your compiler, if in doubt.

  • 4
    The compiler had better not remove this if running in an IEEE mode. Check the documentation for your compiler, of course... – dmckee Feb 20 '09 at 19:21
  • 37
    -1 only works in theory, not in practice: compilers such as g++ (with -fastmath) screw that up. the only general way, until c++0x, is to test for bitpattern. – Cheers and hth. - Alf Mar 26 '11 at 9:15
  • 60
    @Alf: The documentation for the -ffast-math option explicitly says that it can result in incorrect output for programs which depend on an exact implementation if IEEE or ISO rules/specifications for math functions. Without that option enabled, using x != x is a perfectly valid and portable way of testing for NaN. – Adam Rosenfield Mar 26 '11 at 22:37
  • 6
    @Adam: the documentation does openly state that it's non-conforming, yes. and yes i have encountered that argument before, discussing this at length with Gabriel Dos Reis. it's commonly used to defend the design, in a circular argument (i don't know if you intended to associate to that, but worth knowing about -- it's flame war stuff). your conclusion that x != x is valid without that option does not follow logically. it might be true for a particular version of g++, or not. anyway, you generally have no way to guarantee that fastmath option will not be used. – Cheers and hth. - Alf Mar 27 '11 at 4:48
  • 7
    @Alf: No I was not aware of your discussion with Gabriel Dos Reis. Steve Jessop made a great point in the other question about assuming IEEE representation. If you assume IEEE 754 and that the compiler is operating in a conforming manner (i.e. without the -ffast-math option), then x != x is a valid and portable solution. You can even test for -ffast-math by testing for the __FAST_MATH__ macro and switch to a different implementation in that case (e.g. use unions and bit twiddling). – Adam Rosenfield Mar 27 '11 at 23:45
217

There is no isnan() function available in current C++ Standard Library. It was introduced in C99 and defined as a macro not a function. Elements of standard library defined by C99 are not part of current C++ standard ISO/IEC 14882:1998 neither its update ISO/IEC 14882:2003.

In 2005 Technical Report 1 was proposed. The TR1 brings compatibility with C99 to C++. In spite of the fact it has never been officially adopted to become C++ standard, many (GCC 4.0+ or Visual C++ 9.0+ C++ implementations do provide TR1 features, all of them or only some (Visual C++ 9.0 does not provide C99 math functions).

If TR1 is available, then cmath includes C99 elements like isnan(), isfinite(), etc. but they are defined as functions, not macros, usually in std::tr1:: namespace, though many implementations (i.e. GCC 4+ on Linux or in XCode on Mac OS X 10.5+) inject them directly to std::, so std::isnan is well defined.

Moreover, some implementations of C++ still make C99 isnan() macro available for C++ (included through cmath or math.h), what may cause more confusions and developers may assume it's a standard behaviour.

A note about Viusal C++, as mentioned above, it does not provide std::isnan neither std::tr1::isnan, but it provides an extension function defined as _isnan() which has been available since Visual C++ 6.0

On XCode, there is even more fun. As mentioned, GCC 4+ defines std::isnan. For older versions of compiler and library form XCode, it seems (here is relevant discussion), haven't had chance to check myself) two functions are defined, __inline_isnand() on Intel and __isnand() on Power PC.

  • 4
    I wish your answer appear at the top of that page... – Anton Daneyko Apr 12 '11 at 16:20
  • 19
    Everybody wants these functions like isNan or isInfinity. Why do the people in charge not simply include in their standards???? - I will try to find out how to get in charge and put my vote in for this. Seriously. – shuhalo Oct 5 '11 at 9:04
  • 11
    @Martin: it is part of C++11 en.cppreference.com/w/cpp/numeric/math/isnan – BlueTrin May 30 '13 at 13:29
  • 7
    @shuhalo In charge yet? – Tomáš Zato Feb 8 '16 at 9:15
  • 10
    This answer should be updated since std::isnan is now part of the C++11 standard and support has spread out. std::isnan was implemented in Visual Studio starting with Visual Studio 2013. Maybe @shuhalo got in charge :-) – aberaud May 14 '16 at 17:58
153

First solution: if you are using C++11

Since this was asked there were a bit of new developments: it is important to know that std::isnan() is part of C++11

Synopsis

Defined in header <cmath>

bool isnan( float arg ); (since C++11)
bool isnan( double arg ); (since C++11)
bool isnan( long double arg ); (since C++11)

Determines if the given floating point number arg is not-a-number (NaN).

Parameters

arg: floating point value

Return value

true if arg is NaN, false otherwise

Reference

http://en.cppreference.com/w/cpp/numeric/math/isnan

Please note that this is incompatible with -fast-math if you use g++, see below for other suggestions.


Other solutions: if you using non C++11 compliant tools

For C99, in C, this is implemented as a macro isnan(c)that returns an int value. The type of x shall be float, double or long double.

Various vendors may or may not include or not a function isnan().

The supposedly portable way to check for NaN is to use the IEEE 754 property that NaN is not equal to itself: i.e. x == x will be false for x being NaN.

However the last option may not work with every compiler and some settings (particularly optimisation settings), so in last resort, you can always check the bit pattern ...

  • 8
    Definitely deserves to be the accepted answer and deserves more upvotes. Thanks for the tip – LBes Sep 4 '15 at 16:31
  • 3
    −1 std::isnan is still an ungood recommendation as of Feb 2017, since it doesn't work with g++'s floating point optimization. – Cheers and hth. - Alf Feb 9 '17 at 15:33
  • @Cheersandhth.-Alf: is this option IEEE compliant ? The answer has been edited – BlueTrin Feb 16 '17 at 9:59
  • @BlueTrin: Both x != x and isnan are required to work for IEEE 754 compliance. Regarding the latter, the IEEE 754-2008 standard states that “Implementations shall provide the following non-computational operations for all supported arithmetic formats” and “isNaN(x) is true if and only if x is a NaN”. For checking conformance that standard requires is754version1985() and is754version2008(), where C++ instead offers std::numeric_limits<Fp>::is_iec559() (IEC 559 is the same standard). Unfortunately with -ffast-math optimization, e.g. g++ claims conformance but is non-conforming. – Cheers and hth. - Alf Feb 16 '17 at 15:02
  • 0 Removing my downvote since the added comment makes that issue clear to a reader. :) – Cheers and hth. - Alf Feb 16 '17 at 15:04
82

There is also a header-only library present in Boost that have neat tools to deal with floating point datatypes

#include <boost/math/special_functions/fpclassify.hpp>

You get the following functions:

template <class T> bool isfinite(T z);
template <class T> bool isinf(T t);
template <class T> bool isnan(T t);
template <class T> bool isnormal(T t);

If you have time then have a look at whole Math toolkit from Boost, it has many useful tools and is growing quickly.

Also when dealing with floating and non-floating points it might be a good idea to look at the Numeric Conversions.

  • 1
    Thanks! Just what I was looking for. – Dr. Watson Apr 27 '11 at 19:37
  • it was added in Boost 1.35 (I've just found my program doesn't compile on old linux distro). – marcin May 20 '12 at 20:38
  • 2
    if you compile with the option --fast-math then this function will not work as expected. – Gaetano Mendola Nov 16 '12 at 10:59
43

There are three "official" ways: posix isnan macro, c++0x isnan function template, or visual c++ _isnan function.

Unfortunately it's rather impractical to detect which of those to use.

And unfortunately, there's no reliable way to detect whether you have IEEE 754 representation with NaNs. The standard library offers an official such way (numeric_limits<double>::is_iec559). But in practice compilers such as g++ screw that up.

In theory one could use simply x != x, but compilers such as g++ and visual c++ screw that up.

So in the end, test for the specific NaN bitpatterns, assuming (and hopefully enforcing, at some point!) a particular representation such as IEEE 754.


EDIT: as an example of "compilers such as g++ … screw that up", consider

#include <limits>
#include <assert.h>

void foo( double a, double b )
{
    assert( a != b );
}

int main()
{
    typedef std::numeric_limits<double> Info;
    double const nan1 = Info::quiet_NaN();
    double const nan2 = Info::quiet_NaN();
    foo( nan1, nan2 );
}

Compiling with g++ (TDM-2 mingw32) 4.4.1:

C:\test> type "C:\Program Files\@commands\gnuc.bat"
@rem -finput-charset=windows-1252
@g++ -O -pedantic -std=c++98 -Wall -Wwrite-strings %* -Wno-long-long

C:\test> gnuc x.cpp

C:\test> a && echo works... || echo !failed
works...

C:\test> gnuc x.cpp --fast-math

C:\test> a && echo works... || echo !failed
Assertion failed: a != b, file x.cpp, line 6

This application has requested the Runtime to terminate it in an unusual way.
Please contact the application's support team for more information.
!failed

C:\test> _
  • 4
    @Alf: Your example works as expected for me on both Mac OS X and Linux on various versions of g++ between 4.0 and 4.5. The documentation for the -ffast-math option explicitly says that it can result in incorrect output for programs which depend on an exact implementation if IEEE or ISO rules/specifications for math functions. Without that option enabled, using x != x is a perfectly valid and portable way of testing for NaN. – Adam Rosenfield Mar 26 '11 at 22:34
  • 6
    @Adam: What you're missing is that the C++ standard doesn't require IEEE representation or math for floats. As far as the man page tells you, gcc -ffast-math is still a conforming C++ implementation (well, assuming it gets numeric_limits::is_iec559 right, it is, although Alf suggests above that it doesn't): C++ code relying on IEEE is not portable C++ and has no right to expect implementations to provide it. – Steve Jessop Mar 26 '11 at 23:52
  • 5
    And Alf's right, quick test on gcc 4.3.4 and is_iec559 is true with -ffast-math. So the problem here is that GCC's docs for -ffast-math only say that it's non-IEEE/ISO for math functions, whereas they should say that it's non-C++, because its implementation of numeric_limits is borked. I would guess that GCC can't always tell at the time that template is defined, whether the eventual backend actually has conforming floats, and so doesn't even try. IIRC there are similar issues in the outstanding bug list for GCC's C99 conformance. – Steve Jessop Mar 27 '11 at 0:05
  • 1
    @Alf, @Steve, I didn't know C++ standard has no specification about floating-point values. It's pretty shocking to me. It looks better handling IEEE 754 and NaN as a platform specific extension instead of standard. Isn't it? And can I expect the any kind of isnan() or IEEE754 added in C++0x? – Eonil Mar 27 '11 at 0:14
  • 3
    @Eonil: C++0x still has for example "The value representation of floating-point types is implementation-defined". C and C++ both aim to support implementations on machines with no floating-point hardware, and proper IEEE 754 floats can be quite a bit slower to emulate than reasonably-accurate alternatives. The theory is you can assert is_iec559 if you need IEEE, in practice that doesn't appear to work on GCC. C++0x does have an isnan function, but since GCC doesn't correctly implement is_iec559 now, I guess it won't in C++0x either, and -ffast-math might well break its isnan. – Steve Jessop Mar 27 '11 at 10:40
38

There is an std::isnan if you compiler supports c99 extensions, but I'm not sure if mingw does.

Here is a small function which should work if your compiler doesn't have the standard function:

bool custom_isnan(double var)
{
    volatile double d = var;
    return d != d;
}
  • 6
    why not just var != var? – Brian R. Bondy Feb 20 '09 at 18:42
  • 8
    When doing that their is a chance the compiler will optimize the comparison out, always returning true. – CTT Feb 20 '09 at 18:49
  • 23
    No there isn't. A compiler that does that is broken. You might as well say that there's a chance that the standard library isnan returns the wrong result. Technically true, the compiler could be buggy, but in practice, Not Gonna Happen. Same as var != var. It works because that's how IEEE floating point values are defined. – jalf Jan 23 '10 at 16:30
  • 29
    if -ffast-math is set, isnan() will fail to return the correct result for gcc. Of course, this optimization is documented as breaking IEEE semantics... – Matthew Herrmann Jan 24 '11 at 1:06
  • If -ffast-math is set, then the compiler is buggy. Or rather, if -ffast-math is set, all bets are off and you can't rely on NaNs anyway. – Adrian Ratnapala Jul 21 '15 at 13:45
25

You can use numeric_limits<float>::quiet_NaN( ) defined in the limits standard library to test with. There's a separate constant defined for double.

#include <iostream>
#include <math.h>
#include <limits>

using namespace std;

int main( )
{
   cout << "The quiet NaN for type float is:  "
        << numeric_limits<float>::quiet_NaN( )
        << endl;

   float f_nan = numeric_limits<float>::quiet_NaN();

   if( isnan(f_nan) )
   {
       cout << "Float was Not a Number: " << f_nan << endl;
   }

   return 0;
}

I don't know if this works on all platforms, as I only tested with g++ on Linux.

  • 2
    Watch out, though--there appears to be a bug in numeric_limits in GCC version 3.2.3, since it returns 0.0 for quiet_NaN. Later versions of GCC are okay in my experience. – Nathan Kitchen Apr 30 '09 at 21:12
  • @Nathan: Good to know. I'm using version 4.3.2, so I'm well out of the woods. – Bill the Lizard Apr 30 '09 at 21:48
17

You can use the isnan() function, but you need to include the C math library.

#include <cmath>

As this function is part of C99, it is not available everywhere. If your vendor does not supply the function, you can also define your own variant for compatibility.

inline bool isnan(double x) {
    return x != x;
}
  • I was using <cmath> and there's no isnan in it! incidentally I found out that there is an isnan in <math.h> – hasen Feb 20 '09 at 18:41
  • 1
    As I said, this is part of C99. As C99 is not part of any current C++ standard, I provided the alternative. But as it is likely that isnan() will be included in an upcoming C++ standard, I put a #ifndef directive around it. – raimue Feb 21 '09 at 1:31
12

nan prevention

My answer to this question is don't use retroactive checks for nan. Use preventive checks for divisions of the form 0.0/0.0 instead.

#include <float.h>
float x=0.f ;             // I'm gonna divide by x!
if( !x )                  // Wait! Let me check if x is 0
  x = FLT_MIN ;           // oh, since x was 0, i'll just make it really small instead.
float y = 0.f / x ;       // whew, `nan` didn't appear.

nan results from the operation 0.f/0.f, or 0.0/0.0. nan is a terrible nemesis to the stability of your code that must be detected and prevented very carefully1. The properties of nan that are different from normal numbers:

  • nan is toxic, (5*nan=nan)
  • nan is not equal to anything, not even itself (nan != nan)
  • nan not greater than anything (nan !> 0)
  • nan is not less than anything (nan !< 0)

The last 2 properties listed are counter-logical and will result in odd behavior of code that relies on comparisons with a nan number (the 3rd last property is odd too but you're probably not ever going to see x != x ? in your code (unless you are checking for nan (unreliably))).

In my own code, I noticed that nan values tend to produce difficult to find bugs. (Note how this is not the case for inf or -inf. (-inf < 0) returns TRUE, ( 0 < inf ) returns TRUE, and even (-inf < inf) returns TRUE. So, in my experience, the behavior of the code is often still as desired).

what to do under nan

What you want to happen under 0.0/0.0 must be handled as a special case, but what you do must depend on the numbers you expect to come out of the code.

In the example above, the result of (0.f/FLT_MIN) will be 0, basically. You may want 0.0/0.0 to generate HUGE instead. So,

float x=0.f, y=0.f, z;
if( !x && !y )    // 0.f/0.f case
  z = FLT_MAX ;   // biggest float possible
else
  z = y/x ;       // regular division.

So in the above, if x were 0.f, inf would result (which has pretty good/nondestructive behavior as mentioned above actually).

Remember, integer division by 0 causes a runtime exception. So you must always check for integer division by 0. Just because 0.0/0.0 quietly evaluates to nan doesn't mean you can be lazy and not check for 0.0/0.0 before it happens.

1 Checks for nan via x != x are sometimes unreliable (x != x being stripped out by some optimizing compilers that break IEEE compliance, specifically when the -ffast-math switch is enabled).

  • Thanks for pointing this out; programming like that would definitely help with the problem as such. But next time, please try not to abuse the text formatting features too much. Switching font sizes, weight and style like that are making it really hard to read. – Magnus Oct 16 '13 at 13:03
  • 4
    Note that 0.0/0.0 is not the only operation that might result in a NaN. The square root of a negative number returns NaN. The cosine of +infinity returns NaN as well. the operation acos(x) where x is not in the range [0,pi] can also results in NaN. In a nutshell, one has to be extra careful to also look at these potentially risky operations, not only to 0.0/0.0. – Boris Dalstein Oct 28 '14 at 22:20
  • Totally agree with Boris. In my experience, NaN practically always came from something like sqrt(-1.302e-53), i.e. close-to-zero intermediate computation results being fed into sqrt without checking for negativity. – hans_meine Sep 15 '16 at 9:41
11

The following code uses the definition of NAN (all exponent bits set, at least one fractional bit set) and assumes that sizeof(int) = sizeof(float) = 4. You can look up NAN in Wikipedia for the details.

bool IsNan( float value ) { return ((*(UINT*)&value) & 0x7fffffff) > 0x7f800000; }

  • 13
    This only works on little endian. – kralyk Nov 19 '11 at 14:13
  • I believe this would also work on big endian platforms. The literal 0x7fffffff would simply sit in memory as ff ff ff 7f. value has the same ordering as does 0x7f800000, so all the operations line up (there's no swapping of bytes). I'd be interested if someone could test this on a big endian platform. – Bryan W. Wagner Sep 6 '18 at 18:15
8

As of C++14 there are a number of ways to test if a floating point number value is a NaN.

Of these ways, only checking of the bits of the number's representation, works reliably, as noted in my original answer. In particular, std::isnan and the often proposed check v != v, do not work reliably and should not be used, lest your code stops working correctly when someone decides that floating point optimization is needed, and asks the compiler to do that. This situation can change, compilers can get more conforming, but for this issue that hasn't happened in the 6 years since the original answer.

For about 6 years my original answer was the selected solution for this question, which was OK. But recently a highly upvoted answer recommending the unreliable v != v test has been selected. Hence this additional more up-to-date answer (we now have the C++11 and C++14 standards, and C++17 on the horizon).


The main ways to check for NaN-ness, as of C++14, are:

  • std::isnan(value) )
    is the intended standard library way since C++11. isnan apparently conflicts with the Posix macro of the same name, but in practice that isn't a problem. The main problem is that when floating point arithmetic optimization is requested, then with at least one main compiler, namely g++, std::isnan returns false for NaN argument.

  • (fpclassify(value) == FP_NAN) )
    Suffers from the same problem as std::isnan, i.e., is not reliable.

  • (value != value) )
    Recommended in many SO answers. Suffers from the same problem as std::isnan, i.e., is not reliable.

  • (value == Fp_info::quiet_NaN()) )
    This is a test that with standard behavior should not detect NaNs, but that with the optimized behavior maybe could detect NaNs (due to optimized code just comparing the bitlevel representations directly), and perhaps combined with another way to cover the standard un-optimized behavior, could reliably detect NaN. Unfortunately it turned out to not work reliably.

  • (ilogb(value) == FP_ILOGBNAN) )
    Suffers from the same problem as std::isnan, i.e., is not reliable.

  • isunordered(1.2345, value) )
    Suffers from the same problem as std::isnan, i.e., is not reliable.

  • is_ieee754_nan( value ) )
    This isn't a standard function. It's checking of the bits according to the IEEE 754 standard. It's completely reliable but the code is somewhat system-dependent.


In the following complete test code “success” is whether an expression reports Nan-ness of the value. For most expressions this measure of success, the goal of detecting NaNs and only NaNs, corresponds to their standard semantics. For the (value == Fp_info::quiet_NaN()) ) expression, however, the standard behavior is that it doesn't work as a NaN-detector.

#include <cmath>        // std::isnan, std::fpclassify
#include <iostream>
#include <iomanip>      // std::setw
#include <limits>
#include <limits.h>     // CHAR_BIT
#include <sstream>
#include <stdint.h>     // uint64_t
using namespace std;

#define TEST( x, expr, expected ) \
    [&](){ \
        const auto value = x; \
        const bool result = expr; \
        ostringstream stream; \
        stream << boolalpha << #x " = " << x << ", (" #expr ") = " << result; \
        cout \
            << setw( 60 ) << stream.str() << "  " \
            << (result == expected? "Success" : "FAILED") \
            << endl; \
    }()

#define TEST_ALL_VARIABLES( expression ) \
    TEST( v, expression, true ); \
    TEST( u, expression, false ); \
    TEST( w, expression, false )

using Fp_info = numeric_limits<double>;

inline auto is_ieee754_nan( double const x )
    -> bool
{
    static constexpr bool   is_claimed_ieee754  = Fp_info::is_iec559;
    static constexpr int    n_bits_per_byte     = CHAR_BIT;
    using Byte = unsigned char;

    static_assert( is_claimed_ieee754, "!" );
    static_assert( n_bits_per_byte == 8, "!" );
    static_assert( sizeof( x ) == sizeof( uint64_t ), "!" );

    #ifdef _MSC_VER
        uint64_t const bits = reinterpret_cast<uint64_t const&>( x );
    #else
        Byte bytes[sizeof(x)];
        memcpy( bytes, &x, sizeof( x ) );
        uint64_t int_value;
        memcpy( &int_value, bytes, sizeof( x ) );
        uint64_t const& bits = int_value;
    #endif

    static constexpr uint64_t   sign_mask       = 0x8000000000000000;
    static constexpr uint64_t   exp_mask        = 0x7FF0000000000000;
    static constexpr uint64_t   mantissa_mask   = 0x000FFFFFFFFFFFFF;

    (void) sign_mask;
    return (bits & exp_mask) == exp_mask and (bits & mantissa_mask) != 0;
}

auto main()
    -> int
{
    double const v = Fp_info::quiet_NaN();
    double const u = 3.14;
    double const w = Fp_info::infinity();

    cout << boolalpha << left;
    cout << "Compiler claims IEEE 754 = " << Fp_info::is_iec559 << endl;
    cout << endl;;
    TEST_ALL_VARIABLES( std::isnan(value) );                    cout << endl;
    TEST_ALL_VARIABLES( (fpclassify(value) == FP_NAN) );        cout << endl;
    TEST_ALL_VARIABLES( (value != value) );                     cout << endl;
    TEST_ALL_VARIABLES( (value == Fp_info::quiet_NaN()) );      cout << endl;
    TEST_ALL_VARIABLES( (ilogb(value) == FP_ILOGBNAN) );        cout << endl;
    TEST_ALL_VARIABLES( isunordered(1.2345, value) );           cout << endl;
    TEST_ALL_VARIABLES( is_ieee754_nan( value ) );
}

Results with g++ (note again that the standard behavior of (value == Fp_info::quiet_NaN()) is that it doesn't work as a NaN-detector, it's just very much of practical interest here):

[C:\my\forums\so\282  (detect NaN)]
> g++ --version | find "++"
g++ (x86_64-win32-sjlj-rev1, Built by MinGW-W64 project) 6.3.0

[C:\my\forums\so\282  (detect NaN)]
> g++ foo.cpp && a
Compiler claims IEEE 754 = true

v = nan, (std::isnan(value)) = true                           Success
u = 3.14, (std::isnan(value)) = false                         Success
w = inf, (std::isnan(value)) = false                          Success

v = nan, ((fpclassify(value) == 0x0100)) = true               Success
u = 3.14, ((fpclassify(value) == 0x0100)) = false             Success
w = inf, ((fpclassify(value) == 0x0100)) = false              Success

v = nan, ((value != value)) = true                            Success
u = 3.14, ((value != value)) = false                          Success
w = inf, ((value != value)) = false                           Success

v = nan, ((value == Fp_info::quiet_NaN())) = false            FAILED
u = 3.14, ((value == Fp_info::quiet_NaN())) = false           Success
w = inf, ((value == Fp_info::quiet_NaN())) = false            Success

v = nan, ((ilogb(value) == ((int)0x80000000))) = true         Success
u = 3.14, ((ilogb(value) == ((int)0x80000000))) = false       Success
w = inf, ((ilogb(value) == ((int)0x80000000))) = false        Success

v = nan, (isunordered(1.2345, value)) = true                  Success
u = 3.14, (isunordered(1.2345, value)) = false                Success
w = inf, (isunordered(1.2345, value)) = false                 Success

v = nan, (is_ieee754_nan( value )) = true                     Success
u = 3.14, (is_ieee754_nan( value )) = false                   Success
w = inf, (is_ieee754_nan( value )) = false                    Success

[C:\my\forums\so\282  (detect NaN)]
> g++ foo.cpp -ffast-math && a
Compiler claims IEEE 754 = true

v = nan, (std::isnan(value)) = false                          FAILED
u = 3.14, (std::isnan(value)) = false                         Success
w = inf, (std::isnan(value)) = false                          Success

v = nan, ((fpclassify(value) == 0x0100)) = false              FAILED
u = 3.14, ((fpclassify(value) == 0x0100)) = false             Success
w = inf, ((fpclassify(value) == 0x0100)) = false              Success

v = nan, ((value != value)) = false                           FAILED
u = 3.14, ((value != value)) = false                          Success
w = inf, ((value != value)) = false                           Success

v = nan, ((value == Fp_info::quiet_NaN())) = true             Success
u = 3.14, ((value == Fp_info::quiet_NaN())) = true            FAILED
w = inf, ((value == Fp_info::quiet_NaN())) = true             FAILED

v = nan, ((ilogb(value) == ((int)0x80000000))) = true         Success
u = 3.14, ((ilogb(value) == ((int)0x80000000))) = false       Success
w = inf, ((ilogb(value) == ((int)0x80000000))) = false        Success

v = nan, (isunordered(1.2345, value)) = false                 FAILED
u = 3.14, (isunordered(1.2345, value)) = false                Success
w = inf, (isunordered(1.2345, value)) = false                 Success

v = nan, (is_ieee754_nan( value )) = true                     Success
u = 3.14, (is_ieee754_nan( value )) = false                   Success
w = inf, (is_ieee754_nan( value )) = false                    Success

[C:\my\forums\so\282  (detect NaN)]
> _

Results with Visual C++:

[C:\my\forums\so\282  (detect NaN)]
> cl /nologo- 2>&1 | find "++"
Microsoft (R) C/C++ Optimizing Compiler Version 19.00.23725 for x86

[C:\my\forums\so\282  (detect NaN)]
> cl foo.cpp /Feb && b
foo.cpp
Compiler claims IEEE 754 = true

v = nan, (std::isnan(value)) = true                           Success
u = 3.14, (std::isnan(value)) = false                         Success
w = inf, (std::isnan(value)) = false                          Success

v = nan, ((fpclassify(value) == 2)) = true                    Success
u = 3.14, ((fpclassify(value) == 2)) = false                  Success
w = inf, ((fpclassify(value) == 2)) = false                   Success

v = nan, ((value != value)) = true                            Success
u = 3.14, ((value != value)) = false                          Success
w = inf, ((value != value)) = false                           Success

v = nan, ((value == Fp_info::quiet_NaN())) = false            FAILED
u = 3.14, ((value == Fp_info::quiet_NaN())) = false           Success
w = inf, ((value == Fp_info::quiet_NaN())) = false            Success

v = nan, ((ilogb(value) == 0x7fffffff)) = true                Success
u = 3.14, ((ilogb(value) == 0x7fffffff)) = false              Success
w = inf, ((ilogb(value) == 0x7fffffff)) = true                FAILED

v = nan, (isunordered(1.2345, value)) = true                  Success
u = 3.14, (isunordered(1.2345, value)) = false                Success
w = inf, (isunordered(1.2345, value)) = false                 Success

v = nan, (is_ieee754_nan( value )) = true                     Success
u = 3.14, (is_ieee754_nan( value )) = false                   Success
w = inf, (is_ieee754_nan( value )) = false                    Success

[C:\my\forums\so\282  (detect NaN)]
> cl foo.cpp /Feb /fp:fast && b
foo.cpp
Compiler claims IEEE 754 = true

v = nan, (std::isnan(value)) = true                           Success
u = 3.14, (std::isnan(value)) = false                         Success
w = inf, (std::isnan(value)) = false                          Success

v = nan, ((fpclassify(value) == 2)) = true                    Success
u = 3.14, ((fpclassify(value) == 2)) = false                  Success
w = inf, ((fpclassify(value) == 2)) = false                   Success

v = nan, ((value != value)) = true                            Success
u = 3.14, ((value != value)) = false                          Success
w = inf, ((value != value)) = false                           Success

v = nan, ((value == Fp_info::quiet_NaN())) = false            FAILED
u = 3.14, ((value == Fp_info::quiet_NaN())) = false           Success
w = inf, ((value == Fp_info::quiet_NaN())) = false            Success

v = nan, ((ilogb(value) == 0x7fffffff)) = true                Success
u = 3.14, ((ilogb(value) == 0x7fffffff)) = false              Success
w = inf, ((ilogb(value) == 0x7fffffff)) = true                FAILED

v = nan, (isunordered(1.2345, value)) = true                  Success
u = 3.14, (isunordered(1.2345, value)) = false                Success
w = inf, (isunordered(1.2345, value)) = false                 Success

v = nan, (is_ieee754_nan( value )) = true                     Success
u = 3.14, (is_ieee754_nan( value )) = false                   Success
w = inf, (is_ieee754_nan( value )) = false                    Success

[C:\my\forums\so\282  (detect NaN)]
> _

Summing up the above results, only direct testing of the bit-level representation, using the is_ieee754_nan function defined in this test program, worked reliably in all cases with both g++ and Visual C++.


Addendum:
After posting the above I became aware of yet another possible to test for NaN, mentioned in another answer here, namely ((value < 0) == (value >= 0)). That turned out to work fine with Visual C++ but failed with g++'s -ffast-math option. Only direct bitpattern testing works reliably.

7
inline bool IsNan(float f)
{
    const uint32 u = *(uint32*)&f;
    return (u&0x7F800000) == 0x7F800000 && (u&0x7FFFFF);    // Both NaN and qNan.
}

inline bool IsNan(double d)
{
    const uint64 u = *(uint64*)&d;
    return (u&0x7FF0000000000000ULL) == 0x7FF0000000000000ULL && (u&0xFFFFFFFFFFFFFULL);
}

This works if sizeof(int) is 4 and sizeof(long long) is 8.

During run time it is only comparison, castings do not take any time. It just changes comparison flags configuration to check equality.

  • Also note, it's limited to IEEE 754 representation. – Cheers and hth. - Alf Feb 9 '17 at 15:41
  • Note that this cast breaks the strict aliasing rule of g++, and that compiler has been known to do Unmentionable Things™ when it detects formal UB. Instead of efficient casts, with g++ you need to use memcpy, through a byte array to be sure. Code for that in my #2 answer. – Cheers and hth. - Alf Feb 16 '17 at 15:50
4

A possible solution that would not depend on the specific IEEE representation for NaN used would be the following:

template<class T>
bool isnan( T f ) {
    T _nan =  (T)0.0/(T)0.0;
    return 0 == memcmp( (void*)&f, (void*)&_nan, sizeof(T) );
}
4

As for me the solution could be a macro to make it explicitly inline and thus fast enough. It also works for any float type. It bases on the fact that the only case when a value is not equals itself is when the value is not a number.

#ifndef isnan
  #define isnan(a) (a != a)
#endif
  • This is one of the best answers to this question! Thank you for sharing. – Henri Menke Sep 6 '13 at 11:13
  • 2
    Some compilers may optimize it out of code. – ST3 Oct 3 '13 at 10:32
  • 2
    Other answers indicate that this can fail with the -ffast-math option set. – Technophile Jan 29 '16 at 22:23
4

Considering that (x != x) is not always guaranteed for NaN (such as if using the -ffast-math option), I've been using:

#define IS_NAN(x) (((x) < 0) == ((x) >= 0))

Numbers can't be both < 0 and >= 0, so really this check only passes if the number is neither less than, nor greater than or equal to zero. Which is basically no number at all, or NaN.

You could also use this if you prefer:

#define IS_NAN(x) (!((x)<0) && !((x)>=0)

I'm not sure how this is affected by -ffast-math though, so your mileage may vary.

  • This is actually flawed the same way f != f is flawed too. I have seen llvm optimising an almost identical piece of code away. The optimizer can propagate the information about the first comparison and figure out that the second comparsion may never be true if the first one is. (if the compiler strictly obeys IEEE rules f != f is much simpler anyway) – Markus Mar 21 '16 at 19:06
  • Doesn't work with g++'s -ffast-math option. Works with Visual C++. See (stackoverflow.com/a/42138465/464581). – Cheers and hth. - Alf Feb 9 '17 at 15:39
3

This works:

#include <iostream>
#include <math.h>
using namespace std;

int main ()
{
  char ch='a';
  double val = nan(&ch);
  if(isnan(val))
     cout << "isnan" << endl;

  return 0;
}

output: isnan

1

It seems to me that the best truly cross-platform approach would be to use a union and to test the bit pattern of the double to check for NaNs.

I have not thoroughly tested this solution, and there may be a more efficient way of working with the bit patterns, but I think that it should work.

#include <stdint.h>
#include <stdio.h>

union NaN
{
    uint64_t bits;
    double num;
};

int main()
{
    //Test if a double is NaN
    double d = 0.0 / 0.0;
    union NaN n;
    n.num = d;
    if((n.bits | 0x800FFFFFFFFFFFFF) == 0xFFFFFFFFFFFFFFFF)
    {
        printf("NaN: %f", d);
    }

    return 0;
}
  • Note that "it's undefined behavior to read from the member of the union that wasn't most recently written". So this use of a union to type-pun between two types may not work as desired (:sad_panda:). The correct (albeit not actually quite as portable as desired) way would be to avoid the union altogether, and do a memcpy from the double into a different uint64_t variable, then do the test using that helper variable. – Eljay May 13 at 19:36
1

The IEEE standard says when the exponent is all 1s and the mantissa is not zero, the number is a NaN. Double is 1 sign bit, 11 exponent bits and 52 mantissa bits. Do a bit check.

0

This detects infinity and also NaN in Visual Studio by checking it is within double limits:

//#include <float.h>
double x, y = -1.1; x = sqrt(y);
if (x >= DBL_MIN && x <= DBL_MAX )
    cout << "DETECTOR-2 of errors FAILS" << endl;
else
    cout << "DETECTOR-2 of errors OK" << endl;
-3

As comments above state a != a will not work in g++ and some other compilers, but this trick should. It may not be as efficient, but it's still a way:

bool IsNan(float a)
{
    char s[4];
    sprintf(s, "%.3f", a);
    if (s[0]=='n') return true;
    else return false;
}

Basically, in g++ (I am not sure about others though) printf prints 'nan' on %d or %.f formats if variable is not a valid integer/float. Therefore this code is checking for the first character of string to be 'n' (as in "nan")

  • 2
    Wouldn't that cause a buffer overflow if a = 234324.0f ? – Mazyod Aug 16 '13 at 2:18
  • Yes t'will, or 340282346638528859811704183484516925440.000 if a=FLT_MAX. He'd have to use char s[7]; sprintf(s, "%.0g", a);, which'll be 6 chrs if a=-FLT_MAX, or -3e+38 – bobobobo Aug 17 '13 at 0:32

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