# How can I accurately determine if a double is an integer? [duplicate]

This question already has an answer here:

Specifically in Java, how can I determine if a `double` is an integer? To clarify, I want to know how I can determine that the double does not in fact contain any fractions or decimals.

I am concerned essentially with the nature of floating-point numbers. The methods I thought of (and the ones I found via Google) follow basically this format:

``````double d = 1.0;
if((int)d == d) {
//do stuff
}
else {
// ...
}
``````

I'm certainly no expert on floating-point numbers and how they behave, but I am under the impression that because the `double` stores only an approximation of the number, the `if()` conditional will only enter some of the time (perhaps even a majority of the time). But I am looking for a method which is guaranteed to work 100% of the time, regardless of how the `double` value is stored in the system.

Is this possible? If so, how and why?

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Can you use BigDecimal instead of double? –  Disco 3 Aug 22 '12 at 16:47
How about `(x == Math.floor(x))`? –  Mike Christensen Aug 22 '12 at 16:49
perhaps `if((d-(int)d)>0)` ..... –  perilbrain Aug 22 '12 at 16:49
"is an integer" means can be converted to an int or has a null fraction part? There's a slight difference, for example 1.0e100 has a null fraction part but cannot be converted to an int (overflow). –  aka.nice Aug 22 '12 at 16:53
If it means "has a null fraction part" then (int)d==d DOES NOT work fine for all d (especially those >=2^31 or <-2^31), you should rather use Math.floor(d) == d as proposed by Eric Postpischil rather than accepted answer. –  aka.nice Aug 22 '12 at 17:49
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## marked as duplicate by Łukasz 웃 L ツ, tkanzakic, flavian, Yan Sklyarenko, fglezMay 14 '13 at 8:21

`double` can store an exact representation of certain values, such as small integers and (negative or positive) powers of two.

If it does indeed store an exact integer, then `((int)d == d)` works fine. And indeed, for any 32-bit integer i, `(int)((double)i) == i` since a double can exactly represent it.

Note that for very large numbers (greater than about 2**52 in magnitude), a double will always appear to be an integer, as it will no longer be able to store any fractional part. This has implications if you are trying to cast to a Java `long`, for instance.

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+1 `double` which has a 53-bit mantissa can represent every 32-bit `int` without error. It can represent most `long` values, but not all. Casting to `(long)` may be preferable. e.g. `(int) 3e9` is negative. ;) –  Peter Lawrey Aug 22 '12 at 16:52
Thanks for your answer. What happens if an integer is "too large", and what would the range for which a double is capable of storing a value exactly be? –  Jeff Gohlke Aug 22 '12 at 16:52
@JeffGohlke: Per the Java specification, conversion to an int of a double that is too large yields the largest value of int. In this case, the test `(int) d == d` fails to indicate that the value of d is an integer. I suggest `Math.floor(d) == d` as an alternative. –  Eric Postpischil Aug 22 '12 at 17:02
More precisely: If, represented in scientific base-2, the binary value is terminating and has less than 52 bits (and an exponent within -1023 to +1023), a double can store it exactly. Otherwise, the value may have to be truncated. In particular, powers of two are represented exactly, as are integers less than 2**52. However, values like 0.1 have repeating (non-terminating) representations in binary so they cannot be represented exactly. –  nneonneo Aug 22 '12 at 17:04
@nneonneo: That should say “less than 54 significant bits”, not “less than 52”. The significand of a double has 53 bits (1 implicit, 52 explicit). The low end of the normal exponent range is -1022, not -1023. (Denormals extend to -1074.) The condition “the binary value is terminating” is redundant, since non-terminating numerals do not have fewer than 54 bits. Values are commonly rounded, not truncated. –  Eric Postpischil Aug 22 '12 at 17:18
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``````if(new BigDecimal(d).scale() <= 0) {
//do stuff
}
``````
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Your method of using `if((int)d == d)` should always work for any 32-bit integer. To make it work up to 64 bits, you can use `if((long)d == d`, which is effectively the same except that it accounts for larger magnitude numbers. If `d` is greater than the maximum `long` value (or less than the minimum), then it is guaranteed to be an exact integer. A function that tests whether `d` is an integer can then be constructed as follows:

``````boolean isInteger(double d){
if(d > Long.MAX_VALUE || d < Long.MIN_VALUE){
return true;
} else if((long)d == d){
return true;
} else {
return false;
}
}
``````

If a floating point number is an integer, then it is an exact representation of that integer.

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That's not precisely correct. A double can be an integer, but may be the floating-point representation of multiple integers due to truncation error; this happens with integers around 2**52 and larger. –  nneonneo Aug 22 '12 at 16:58
Can you elaborate? I wouldn't be surprised if I missed something, but I don't see it –  murgatroid99 Aug 22 '12 at 16:58
`Math.floor(d) == d` performs the test entirely in floating point, avoiding the problems of conversion to integer. –  Eric Postpischil Aug 22 '12 at 17:03
I don't see the problem with converting to an integer –  murgatroid99 Aug 22 '12 at 17:08
@murgatroid99: I think you did see the problem with converting to an integer, since you added tests to work around the problem. However, I think the Long.MAX_VALUE version was better. Although that might not have worked the way you intended (Long.MAX_VALUE was implicitly converted to double for comparison, which changed the value, which made the test false when d is 2^63. But the `(long) d == d` test succeeds because of the same change!), but it worked. I expect the version with `1<<52` to fail because `1` has type int, so `1<<52` uses only the low five bits of 52. –  Eric Postpischil Aug 22 '12 at 17:47
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`````` if(d % 1 == 0)
``````

This works because all integers are 0 modulo 1.

Edit To all those who object to this on the grounds of it being slow, I profiled it, and found it to be about 3.5 times slower than casting. Unless this is in a tight loop, I'd say this is a preferable way of working it out, because it's extremely clear what you're testing, and doesn't require any though about the semantics of integer casting.

I profiled it by running time on javac of

``````class modulo {
public static void main(String[] args) {
long successes = 0;
for(double i = 0.0; i < Integer.MAX_VALUE; i+= 0.125) {
if(i % 1 == 0)
successes++;
}
System.out.println(successes);
}
}
``````

VS

``````class cast {
public static void main(String[] args) {
long successes = 0;
for(double i = 0.0; i < Integer.MAX_VALUE; i+= 0.125) {
if((int)i == i)
successes++;
}
System.out.println(successes);
}
}
``````

Both printed 2147483647 at the end.
Modulo took 189.99s on my machine - Cast took 54.75s.

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But this ignores how doubles and floating point numbers work. Not a good suggestion. –  Hovercraft Full Of Eels Aug 22 '12 at 16:48
I'm sorry, why is this not a good suggestion? It doesn't ignore how doubles and floats work. When I say integers, I mean the mathematical objects, not the data type. –  MrBones Aug 22 '12 at 16:50
It is fine with regard to floating-point correctness (up to issues with NaNs and infinities that other answers also have). I would not recommend it because division (and remainder) is slow on typical processors. –  Eric Postpischil Aug 22 '12 at 18:36