When I write something like

double a = 0.0;
double b = 0.0;
double c = a/b;

The result is Double.NaN, but when I try the same for integers, it produces an ArithmeticException. So, why isn't there a Integer.NaN?


3 Answers 3


The answer has very little to do with Java. Infinity or undefined numbers are not a part of the integer set, so they are excluded from Integer, whereas floating point types represent real numbers as well as complex numbers, so to deal with these, NaN has been included with floating point types.

  • Trivia(l?): int i = (int)Float.NaN; // 0
    – TWiStErRob
    Commented Sep 9, 2014 at 13:26

For the same reason that there is no integer NaN in any other language.

Modern computers use 2's complement binary representation for integers, and that representation doesn't have a NaN value. (All values in the domain of the representation type represent definite integers.)

It follows that computer integer arithmetic hardware does not recognize any NaN representation.

In theory, someone could invent an alternative representation for integers that includes NaN (or INF, or some other exotic value). However, arithmetic using such a representation would not be supported by the hardware. While it would be possible to implement it in software, it would be prohibitively expensive1... and undesirable in other respects too to include this support in the Java language.

1 - It is of course relative, but I'd anticipate that a software implementation of NaNs would be (at least) an order of magnitude slower than hardware. If you actually, really, needed this, then that would be acceptable. But the vast majority of integer arithmetic codes don't need this. In most cases throwing an exception for "divide by zero" is just fine, and an order of magnitude slow down in all integer arithmetic operations is ... not acceptable.

By contrast:

  • the "unused" values in the representation space already exist
  • NaN and INF values are part of the IEE floating point standard, and
  • they are (typically) implemented by the native hardware implementation of floating point arithmetic
  • 1
    I disagree about "prohibitively expensive" - that's a relative term, it may be cheaper than the cost of coding around the issue. And undesirable - dunno, maybe. I would say that if the concept exists for double, it could be usaful for ints. It's only because the underlying implementation of int doesn't provide for it that it isn't done, which practically implies that since double's internal representation and range does allow for it that it's a good idea that needs a different implementation to exist.
    – Bohemian
    Commented Jul 12, 2013 at 23:45
  • 1
    @Bohemian - we are talking about it being prohibitively expensive to make NaN integers part of "the language". Obviously, if an application really needs NaNs, it it is not prohibitively expensive for them. But most don't.
    – Stephen C
    Commented Jul 13, 2013 at 0:12
  • Yes, I know what you meant. But that "expense" (apart from the effort to change the language, which doesn't affect us programmers) would ultimately translate into higher CPU usage when dealing with ints, and it is that cost (which may be converted to dollars) that I am comparing the "cost" of the extra functionality gained (again convertable to dollars). Whether it is "prohibitive" or not depends on those dollar cost. I actually doubt very much whether it would be "prohibitive" - we are talking about changing, or rather adding to, the underlying implementation, which should be left "hidden",
    – Bohemian
    Commented Jul 13, 2013 at 3:16
  • @Bohemian - That's only one of the costs. Others include increased space to represent integers (or reduction in the size of the effective value space), changes to code, more fodder for the "Java slow" crew, ... And besides, a 10% slowdown in all Java programs does amount to a very large dollar cost ... in buying more kit, bigger data centre power bills etc. We could be talking billions of dollars, world-wide.
    – Stephen C
    Commented Jul 13, 2013 at 6:07
  • 1
    This answer overstates its case. The use of two’s complement for integer representations does not preclude setting aside one of the values for use as a NaN. Taking the extreme negative value for this use would restore a nice symmetry to the integer types (they would be closed under negation). The reason non-NaN integer formats prevailed over others is due more to desirable properties such as convenient modulo/wrapping than to implementation costs (which could be moved into hardware rather than software, in spite of this answer’s prejudice otherwise). Commented Jul 13, 2013 at 21:53

As noted in other comments, it's largely because NaN is a standard value for floating point numbers. You can read about the reasons NaN would be returned on Wikipedia here:


Notice that only one of these reasons exists for integer numbers (divide by zero). There is also both a positive and a negative infinity value for floating point numbers that integers don't have and is closely linked to NaN in the floating point specification.

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