# Why does Double.NaN==Double.NaN return false?

I was just studying OCPJP questions and I found this strange code:

``````public static void main(String a[]) {
System.out.println(Double.NaN==Double.NaN);
System.out.println(Double.NaN!=Double.NaN);
}
``````

When I ran the code, I got:

``````false
true
``````

How is the output `false` when we're comparing two things that look the same as each other? What does `NaN` mean?

• This is really weird. Because Double.NaN is static final, the comparision with == should return true. +1 for the question. – Stephan Jan 11 '12 at 14:10
• The same is true in python: `In [1]: NaN==NaN Out[1]: False` – tdc Jan 11 '12 at 15:29
• The same is true in all languages that correctly follow the IEEE 754 standard. – zzzzBov Jan 11 '12 at 16:13
• Intuition: "Hello" is not a number, true (boolean) is also not a number. NaN != NaN for the same reason "Hello" != true – Kevin Jan 12 '12 at 23:01
• @Stephan: The comparison with `Double.NaN==Double.NaN` should indeed return true if `Double.NaN` were of type `java.lang.Double`. However, its type is the primitive `double`, and the operator rules for `double` apply (which demand this inequality for conformance with IEEE 754, as explained in the answers). – sleske Jan 13 '12 at 12:48

NaN means "Not a Number".

An operation that overflows produces a signed infinity, an operation that underflows produces a denormalized value or a signed zero, and an operation that has no mathematically definite result produces NaN. All numeric operations with NaN as an operand produce NaN as a result. As has already been described, NaN is unordered, so a numeric comparison operation involving one or two NaNs returns `false` and any `!=` comparison involving NaN returns `true`, including `x!=x` when `x` is NaN.

• It is not just Java; it is in the floating point standard. – nibot Jan 11 '12 at 16:46
• @nibot: Mostly true. Any comparison with an IEEE-conforming float will produce `false`. So that standard differs from Java in that IEEE demands that `(NAN != NAN) == false`. – Drew Dormann Jan 17 '12 at 19:57
• Opening up this Pandora's box - where do you see that "IEEE demands that (NAN != NAN) == false"? – Supervisor Jan 26 '16 at 21:30

NaN is by definition not equal to any number including NaN. This is part of the IEEE 754 standard and implemented by the CPU/FPU. It is not something the JVM has to add any logic to support.

http://en.wikipedia.org/wiki/NaN

A comparison with a NaN always returns an unordered result even when comparing with itself. ... The equality and inequality predicates are non-signaling so x = x returning false can be used to test if x is a quiet NaN.

Java treats all NaN as quiet NaN.

• Is it implemented by the CPU, or is it hard-wired in the JVM as Bohemian mentions? – Naweed Chougle Jan 11 '12 at 16:56
• The JVM has to call whatever will implement it correctly. On a PC, the CPU does all the work as such. On a machine without this support the JVM has to implement it. (I don't know of any such machine) – Peter Lawrey Jan 11 '12 at 17:05
• Back in the day when the 8087 was an option, the C library contained an FP emulator. Programs like the JVM wouldn't have to worry about it either way. – user207421 Mar 26 '15 at 18:14

Why that logic

`NaN` means `Not a Number`. What is not a number? Anything. You can have anything in one side and anything in the other side, so nothing guarantees that both are equals. `NaN` is calculated with `Double.longBitsToDouble(0x7ff8000000000000L)` and as you can see in the documentation of `longBitsToDouble`:

If the argument is any value in the range `0x7ff0000000000001L` through `0x7fffffffffffffffL` or in the range `0xfff0000000000001L` through `0xffffffffffffffffL`, the result is a `NaN`.

Also, `NaN` is logically treated inside the API.

Documentation

``````/**
* A constant holding a Not-a-Number (NaN) value of type
* {@code double}. It is equivalent to the value returned by
* {@code Double.longBitsToDouble(0x7ff8000000000000L)}.
*/
public static final double NaN = 0.0d / 0.0;
``````

By the way, `NaN` is tested as your code sample:

``````/**
* Returns {@code true} if the specified number is a
* Not-a-Number (NaN) value, {@code false} otherwise.
*
* @param   v   the value to be tested.
* @return  {@code true} if the value of the argument is NaN;
*          {@code false} otherwise.
*/
static public boolean isNaN(double v) {
return (v != v);
}
``````

Solution

What you can do is use `compare`/`compareTo`:

`Double.NaN` is considered by this method to be equal to itself and greater than all other `double` values (including `Double.POSITIVE_INFINITY`).

``````Double.compare(Double.NaN, Double.NaN);
Double.NaN.compareTo(Double.NaN);
``````

Or, `equals`:

If `this` and `argument` both represent `Double.NaN`, then the `equals` method returns `true`, even though `Double.NaN==Double.NaN` has the value `false`.

``````Double.NaN.equals(Double.NaN);
``````
• Do you know of any case where having `NaN != NaN` be false would make programs more complicated than having `NaN != NaN` be true? I know IEEE made the decision ages ago, but from a practical perspective, I've never seen cases where it's useful. If an operation is supposed to run until consecutive iterations yield the same result, having two consecutive iterations yield NaN would be "naturally" detected as an exit condition were it not for that behavior. – supercat Sep 7 '13 at 20:33
• @supercat How can you say that two random non number are naturally equal? Or say, primitively equal? Think of NaN as an instance, not something primitive. Each different abnormal result is a different instance of something strange and even if both should represent the same, using == for different instances must return false. On the other hand, when using equals it can be handled properly as you intend. [docs.oracle.com/javase/7/docs/api/java/lang/… – falsarella Sep 9 '13 at 11:52
• @falsarella: The issue isn't whether two random numbers should be considered "definitely equal", but rather in what cases is it useful to have any number compare as "definitely unequal" to itself. If one is trying to compute the limit of `f(f(f...f(x)))`, and one finds a `y=f[n](x)` for some `n` such that the result of `f(y)` is indistinguishable from `y`, then `y` will be indistinguishable from the result of any more-deeply-nested `f(f(f(...f(y)))`. Even if one wanted `NaN==NaN` to be false, having `Nan!=Nan` also be false would be less "surprising" than having `x!=x` be true for some x. – supercat Sep 11 '13 at 16:36
• @falsarella: I believe the type of `Double.NaN` is not `Double`, but `double`, so the question is one related to the behavior of `double`. Though there exist functions which can test for an equivalence relation involving `double` values, the only compelling answer I know of for "why" (which is part of the original question) is "because some people at the IEEE didn't think equality-testing should define an equivalence relation". BTW, is there any concise idiomatic way to test `x` and `y` for equivalence using only primitive-operators? All formulations I know of are rather clunky. – supercat Sep 11 '13 at 18:08
• best and simple answer. Thank you – Tarun Nagpal Jul 5 '16 at 15:58

It might not be a direct answer to the question. But if you want to check if something is equal to `Double.NaN` you should use this:

``````double d = Double.NaN
Double.isNaN(d);
``````

This will return `true`

The javadoc for Double.NaN says it all:

A constant holding a Not-a-Number (NaN) value of type `double`. It is equivalent to the value returned by `Double.longBitsToDouble(0x7ff8000000000000L)`.

Interestingly, the source for `Double` defines `NaN` thus:

``````public static final double NaN = 0.0d / 0.0;
``````

The special behaviour you describe is hard-wired into the JVM.

• Is it hard wired in the JVM, or is it implemented by the CPU as Peter mentions? – Naweed Chougle Jan 11 '12 at 16:54

NaN is a special value that denotes "not a number"; it's the result of certain invalid arithmetic operations, such as `sqrt(-1)`, and has the (sometimes annoying) property that `NaN != NaN`.

as per, The IEEE standard for floating point arithmetic for Double Precision numbers,

The IEEE double precision floating point standard representation requires a 64 bit word, which may be represented as numbered from 0 to 63, left to right

where,

``````S: Sign – 1 bit
E: Exponent – 11 bits
F: Fraction – 52 bits
``````

If `E=2047` (all `E` are `1`) and `F` is nonzero, then `V=NaN` ("Not a number")

Which means,

If all `E` bits are 1, and if there is any non-zero bit in `F` then the number is `NaN`.

therefore, among others, all following numbers are `NaN`,

``````0 11111111 0000000000000000010000000000000000000000000000000000 = NaN
1 11111111 0000010000000000010001000000000000001000000000000000 = NaN
1 11111111 0000010000011000010001000000000000001000000000000000 = NaN
``````

In particular, you cannot test

``````if (x == Double.NaN)
``````

to check whether a particular result equals `Double.NaN`, because all “not a number” values are considered distinct. However, you can use the `Double.isNaN` method:

``````if (Double.isNaN(x)) // check whether x is "not a number"
``````

Not a number represents the result of operations whose result is not representable with a number. The most famous operation is 0/0, whose result is not known.

• -1: It does not represent the result of `0/0`. `0/0` is always NaN, but NaN can be the result of other operations - such as `2+NaN`: `an operation that has no mathematically definite result produces NaN`, as per the answer by @AdrianMitev – ANeves Jan 11 '12 at 19:02
According to this link, it has various situations and difficult to remember. This is how I remember and distinguish them. `NaN` means "mathematically undefined" for example: "the result of 0 divided by 0 is undefined" and because it is undefined, so "comparison related to undefined is of course undefined". Besides, it works more like mathematical premises. On the other hand, both positive and negative infinite is predefined and definitive, for example "positive or negative infinite large is well defined mathematically".