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The relevant IEEE standard defines a numeric constant NaN (not a number) and prescribes that NaN should compare as not equal to itself. Why is that?

All the languages I'm familiar with implement this rule. But it often causes significant problems, for example unexpected behavior when NaN is stored in a container, when NaN is in the data that is being sorted, etc. Not to mention, the vast majority of programmers expect any object to be equal to itself (before they learn about NaN), so surprising them adds to the bugs and confusion.

IEEE standards are well thought out, so I am sure there is a good reason why NaN comparing as equal to itself would be bad. I just can't figure out what it is.

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marked as duplicate by Mark Bertenshaw, Max Lybbert, Yahel, Greg, Michael Papile May 14 at 23:24

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

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The IEEE standards were designed by engineers, not programmers, computer vendors, or authors of math libraries, for whom the NaN rule is a disaster. –  Jim Balter Apr 8 at 7:20

6 Answers 6

Well, log(-1) gives NaN, and acos(2) also gives NaN. Does that mean that log(-1) == acos(2)? Clearly not. Hence it makes perfect sense that NaN is not equal to itself.

Revisiting this almost two years later, here's a "NaN-safe" comparison function:

function compare(a,b) {
    return a == b || (isNaN(a) && isNaN(b));
}
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Well, if you were looking for an intersection between the log function and the acos function, then all negative values past -1 would be considered an intersection. Interestingly, Infinity == Infinity is true, despite the fact that the same can't be said in actual mathematics. –  Niet the Dark Absol Apr 5 '12 at 19:05
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Given that Inf == Inf, and given that one might just as easily argue that an object should be equal to itself, I suspect there was some other, very specific and very strong, rationale behind the IEEE choice... –  max Apr 5 '12 at 20:04
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1 + 3 = 4 and 2 + 2 = 4 . Does that mean that 1 + 3 = 2 + 2 ? Clearly yes. Hence your answer does not make perfect sense. –  borisdiakur Jul 20 '12 at 21:33
7  
But log(-1) != log(-1) does not make sense. So neither NaN equals NaN nor NaN does not equal NaN makes sense in all cases. Arguably, it'd make more sense if NaN == NaN evalutated to something representing unknown, but then == wouldn't return a boolean. –  Tim Goodman Jun 28 '13 at 16:39
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Your NaN-safe comparison function returns true if you supply two different numbers which aren't equal to each other. Something like return a == b || (isNaN(a) && isNaN(b)) should work? –  mmitchell May 14 at 22:45

The accepted answer by max is 100% positively absolutely without question WRONG. Not halfway wrong or even slightly wrong. It is glaringly obviously massively wrong. I fear it is going to confuse and mislead programmers for a long time to come as this question pops up in searches.

NaN is designed to propagate through all calculations, infecting them like a virus, so if somewhere in your deep, complex calculations you hit upon a NaN, you don't bubble out a seemingly sensible answer. Otherwise by identity NaN/NaN should equal 1, along with all the other consequences like (NaN/NaN)==1, (NaN*1)==NaN, etc. If you imagine that your calculations went wrong somewhere (rounding produced a zero denominator, yielding NaN), etc then you could get wildly incorrect (or worse: subtly incorrect) results from your calculations with no obvious indicator as to why.

There are also really good reasons for NaNs in calculations when probing the value of a mathemetical function; one of the examples given in the linked document is finding the zeros of a function f(), zero(f). It is entirely possible that in the process of probing the function with guess values that you will probe one where the function f() yields no sensible result. This allows zeros() to see the NaN and continue its work.

The alternative to NaN is to trigger an exception as soon as an illegal operation is encountered (also called a signal or a trap). Besides the massive performance penalties you might encounter, at the time there was no guarantee that the CPUs would support it in hardware or the OS/language would support it in software. IEEE decided to explicitly handle it in software as the NaN values so it would be portable across any OS or programming language. Correct floating point algorithms are generally correct across all floating point implementations, whether that be node.js or COBOL (hah).

In theory, you don't have to set specific #pragma directives, set crazy compiler flags, catch the correct exceptions, or install special signal handlers to make what appears to be the identical algorithm actually work correctly. Unfortunately some language designers and compiler writers have been really busy undoing this feature to the best of their abilities.

Please read some of the information about the history of IEEE 754 floating point. Also this answer on a similar question where a member of the committee responded: What is the rationale for all comparisons returning false for IEEE754 NaN values?

"An Interview with the Old Man of Floating-Point"

"History of IEEE Floating-Point Format"

What every computer scientist should know about floating point arithmetic

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I also like NaN to propagate "like a virus". Unfortunately, it doesn't. The moment you compare, for example, NaN + 1 != 0, or NaN * 1 > 0, it returns True or False as if everything was fine. Therefore, you can't rely on NaN protecting you from problems if you plan to use comparison operators. Given that comparisons won't help you "propagate" NaNs, why not at least make them sensical? As things stand, they mess up the use cases of NaN in dictionaries, they make sort unstable, etc. Also, a minor mistake in your answer. NaN/NaN == 1 would not evaluate True if I had my way. –  max May 17 at 11:03
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Also, you claim that my answer is 100% positively absolutely WRONG. However, the person on the IEEE committee whom you quoted actually stated in the very post you quoted: ` Many commenters have argued that it would be more useful to preserve reflexivity of equality and trichotomy on the grounds that adopting NaN != NaN doesn’t seem to preserve any familiar axiom. I confess to having some sympathy for this viewpoint, so I thought I would revisit this answer and provide a bit more context.` So maybe, dear Sir, you might consider being a bit less forceful in your statements. –  max May 17 at 11:16
    
I understand, but I wanted it to be 100% clear to new developers or those not interested in the details of floating point that your statement that the committee made a "mistake" was incorrect - the design was deliberate. –  xenadu May 24 at 3:49
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I never said the design wasn't deliberate. A deliberate design guided by poor logic or poor understanding of the problem is still a mistake. But this discussion is pointless. You clearly possess the knowledge of the ultimate truth, and your job is to preach it to the uneducated masses like myself. Enjoy the priesthood. –  max May 28 at 11:07
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Ignoring your snark, I explained the decision to you: at the time there was little chance of uniform handling of exceptions/signals across languages, compilers, hardware, and operating systems. The decision was made to handle NaN as a bit pattern so it would be completely portable, since it is useful in actual calculations. I think that's the correct decision, you disagree, but the decision was not guided by poor logic or poor understanding. –  xenadu May 29 at 2:50
up vote 16 down vote accepted

I am sorry, much as I appreciate the thought that went into the top-voted answer, I disagree with it. NaN does not mean "undefined" - see http://www.cs.berkeley.edu/~wkahan/ieee754status/IEEE754.PDF, page 7 (search for the word "undefined"). As that document confirms, NaN is a well-defined concept.

Furthermore, IEEE approach was to follow the regular mathematics rules as much as possible, and when they couldn't, follow the rule of "least surprise" - see http://stackoverflow.com/a/1573715/336527. Any mathematical object is equal to itself, so the rules of mathematics would imply that that NaN == NaN should be True. I cannot see any valid and powerful reason to deviate from such a major mathematical principle (not to mention the less important rules of trichotomy of comparison, etc.).

As a result, my conclusion is as follows.

IEEE committee members did not think this through very clearly, and made a mistake. Since very few people understood the IEEE committee approach, or cared about what exactly the standard says about NaN (to wit: most compilers' treatment of NaN violates the IEEE standard anyway), nobody raised an alarm. Hence, this mistake is now embedded in the standard. It is unlikely to be fixed, since such a fix would break a lot of existing code.

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IMHO, having NaN violate trichotomy makes sense, but like you I see no reasonable semantic justification for not having == define an equivalence relation when its operands are both of the same type (going a little further, I think languages should explicitly disallow comparisons between things of different types--even when implicit conversions exist--if such comparisons cannot implement an equivalence relation). The concept of an equivalence relations is so fundamental in both programming and mathematics, it seems crazy to violate it. –  supercat Sep 18 '13 at 19:40
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You might read on; Kahan says elsewhere in that document "NaNs must conform to mathematically consistent rules that were deduced, not invented arbitrarily[.]" I will agree that he doesn't mention how NaN != NaN is deduced beyond saying it's needed to distinguish NaN from non-NaNs absent library support like isnan(). –  tmyklebu Feb 13 at 19:59
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@EamonNerbonne: Having NaN==NaN return something other than true or false would have been problematic, but given that (a<b) does not necessarily equal !(a>=b), I see no reason that (a==b) must necessarily equal !(a!=b). Having NaN==NaN and Nan!=NaN both return false would allow code which needs either definition of equality to use the one it needs. –  supercat Apr 29 at 23:28
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This answer is WRONG WRONG WRONG! See my answer below. –  xenadu May 14 at 22:47
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I am not aware of any axiom or postulate that states a mathematical object (how do you even define a mathematical object????) has to equal itself. –  Transcendence May 14 at 23:23

Try this:

var a = 'asdf';
var b = null;

var intA = parseInt(a);
var intB = parseInt(b);

console.log(intA); //logs NaN
console.log(intB); //logs NaN
console.log(intA==intB);// logs false

If intA == intB were true, that might lead you to conclude that a==b, which it clearly isn't.

Another way to look at it is that NaN just gives you information about what something ISN'T, not what it is. For example, if I say 'an apple is not a gorilla' and 'an orange is not a gorilla', would you conclude that 'an apple'=='an orange'?

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"that might lead you to conclude that a==b" -- But that would simply be an invalid conclusion -- strtol("010") == strtol("8"), for instance. –  Jim Balter Apr 8 at 7:42
    
I don't follow your logic. Given a=16777216f, b=0.25, and c=0.125, should the fact that a+b == a+c be taken to imply that b==c? Or merely that the two calculations yield indistinguishable results? Why should not sqrt(-1) and (0.0/0.0) be considered indistinguishable, absent a means of distinguishing them? –  supercat Apr 29 at 23:25
    
If you are implying that indistinguishable things should be considered equal, I don't agree with that. Equality implies that you DO have a means of distinguishing two subjects of comparison, not just an identical lack of knowledge about them. If you have no means of distinguishing them, then they may be equal or they may not be. I could see NaN==NaN returning 'undefined', but not true. –  Mike C Apr 30 at 12:15

Actually, there is a concept in mathematics known as “unity” values. These values are extensions that are carefully constructed to reconcile outlying problems in a system. For example, you can think of ring at infinity in the complex plane as being a point or a set of points, and some formerly pretentious problems go away. There are other examples of this with respect to cardinalities of sets where you can demonstrate that you can pick the structure of the continuum of infinities so long as |P(A)| > |A| and nothing breaks.

DISCLAIMER: I am only working with my vague memory of my some interesting caveats during my math studies. I apologize if I did a woeful job of representing the concepts I alluded to above.

If you want to believe that NaN is a solitary value, then you are probably going to be unhappy with some of the results like the equality operator not working the way you expect/want. However, if you choose to believe that NaN is more of a continuum of “badness” represented by a solitary placeholder, then you are perfectly happy with the behavior of the equality operator. In other words, you lose sight of the fish you caught in the sea but you catch another that looks the same but is just as smelly.

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Yes, in math you can add infinity and similar values. However, they will never break the equivalence relationship. Programmers' equality represents an equivalence relation in math, which is by definition reflexive. A bad programmer can define == that is not reflexive, symmetric and transitive; it's unfortunate that Python won't stop him. But when Python itself makes == non-reflexive, and you can't even override it, this is a complete disaster from both practical viewpoint (container membership) and elegance/mental clarity viewpoint –  max Mar 19 '13 at 20:42

A nice property is: if x == x returns false, then x is NaN.

(one can use this property to check if x is NaN or not.)

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One could have that property and still have (Nan != Nan) also return false. Had the IEEE done that, code which wanted to test an equivalence relation between a and b could have used !(a != b). –  supercat Feb 11 at 0:38

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