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I know that some values are unable to be easily defined in floats, and are only 'approximated', making direct 'equals' comparisons frequently not work.

Can std::numeric_limits::max be stored in a float accurately, and will this code function as expected?

float myFloat = std::numeric_limits<float>::max();

if(myFloat == std::numeric_limits<float>::max())
    //...myFloat hasn't changed...
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ideone.com/LeRcUt – Rapptz Feb 24 '13 at 23:45
max is a function, you probably want max() there... – K-ballo Feb 24 '13 at 23:45
Thanks, fixed the question. – Jamin Grey Feb 25 '13 at 0:33
up vote 3 down vote accepted

For a given (non-NaN) float variable, f, it is guaranteed that f == f is always true. Since myFloat gets set to some float value, of course it will compare equal to that same value.

You are apparently thinking of cases such as:

float f1 = 0.1;
float f2 = 1.0/10;
assert( f1 == f2 );

which might fail, but this will not fail:

float f1 = 0.1;
float f2 = 0.1;
assert( f1 == f2 );

Although the value stored in the variables may not be exactly equal to 0.1 but may have a different value instead, you will get the same value for both variables, and so they will compare equal.

Whatever value numeric_limits<float>::max() happens to return, it is a fixed value that will compare equal to itself.

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Thanks, this answered my question. You said, "it is guaranteed that f == f". Could you post what part of the standard? Regardless, marked as the accepted answer since it addresses the question the most directly. – Jamin Grey Feb 25 '13 at 1:05
Seriously?! The standard just says operator== "shall yield true if the specified relationship is true and false if it is false." Obviously a variable's value equals itself, because by definition it holds the same value as itself, it can't hold more than one value! (This doesn't apply to NaN values, which always return false even when compared to themselves, but NaNs are special) – Jonathan Wakely Feb 25 '13 at 1:10
But I'm not comparing it to itself. I'm comparing the result of a compiler-implemented static function returning a floating point value, to a later execution of the same function, and I've already expressed ignorance of floating-point implementations. Yes, "varA == varA" is guaranteed to be true, but I thought your comment was "<original floating point value> == <original floating point value>" after approximations (I misread your post). Is that guaranteed by the standard? My mistake if this is a stupid question! – Jamin Grey Feb 25 '13 at 1:16
Technically I think that's implementation defined, but most implementations follow IEEE 754, which says yes. Floating point operations are inexact, but not non-deterministic. – Jonathan Wakely Feb 26 '13 at 9:17
@JaminGrey In practice, you will likely find that f==f is always true but complicated_expr()==complicated_expr() is very rarely false. Many compilers, either intentionally (gcc -ffast-math) or accidentally, sometimes allow themselves to do floating-point math at a different precision from the requested. For example, if f holds 0.1, then a not-quite-smart-enough compiler might optimize f==f into f==0.1 and perform the comparison at double-precision (perhaps because that's faster on whatever target it cares most about), so it ends up being equivalent to 0.1f==0.1, which is false. – Quuxplusone Dec 4 '13 at 22:02


numeric limits is a class template and max is a static method:

  template <class T> class numeric_limits {
  static T max() throw(); //constexpr if using C++11

So for type float you will actually be using std::numeric_limits<float>::max() and simply comparing two floats of equal value (so long as you have not operated on myFloat prior to the comparison). The value from max() is going to be a consistent float for your platform and will have an equivalent binary representation to itself.

The main trouble you would have is trying to serialize and deserialize across platforms with a different floating point binary representation. So if you were to try and serialize your myFloat variable and on some other machine you try to compare the result of the deserialized value directly to numeric_limits::max():

if( myFloat == std::numeric_limits<float>::max() )

The result may no longer hold true. You would then need to encode your concept of "MAX" in your binary representation and interpret it explicitly how you want.

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Good point about the serialization - thankfully that doesn't harm my project. Thanks for the answer. Ignoring the differences in representation Is it reasonably safe to assume that std::numeric_limits<float>::max() will always be accurately represented in different representations/platforms/compilers, even if each is different? – Jamin Grey Feb 25 '13 at 0:39
The question makes no sense. numeric_limits<float>::max() returns some float value. Whatever that value is must be "accurately represented" because it is already stored in a float! You cannot store 0.1 in a float accurately, but whatever value is returned by numeric_limits<float>::max() returns is already stored in a float, i.e. as the answer above says, it "will have an equivalent binary representation to itself" – Jonathan Wakely Feb 25 '13 at 0:53
That is definitely a reasonable assumption. All floating point representations have a maximum representable number. If this number was fuzzy it wouldn't be representable. floats are just binary numbers like any other under the covers simply interpreted differently based on the representation. You can't rely much on how operations will affect the float value (unless you know the details of the representation) but you can be sure that any number is equal to itself. At the point you can inspect the return value of max it is a representable float. – Matthew Sanders Feb 25 '13 at 0:56
@JonathanWakely: Good point. That's kinda what I'm trying to validate though, floating point representations isn't a subject I've truly learned. I get what you're saying - if 0.1 happens to becomes 0.09324242 or whatever, the next time I use 0.1 it'll also become 0.09324242. – Jamin Grey Feb 25 '13 at 1:03

Yes, but

myFloat += someSmallFloat;

may not change the value of myFloat.

If you'd like to understand more, there's a great tutorial on floating point representations called What Every Computer Scientist Should Know About Floating-Point Arithmetic.

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