# Some Java Modulo / Remainder operator questions

I've been playing with some bigger values with Java, and I'm running across something I don't understand. For some reason, Java seems to like giving me bum data (although, it's far more likely I'm telling it to give me bum data)

Here's a snippet, edited for clarity:

``````        System.out.println(
"2 == " + (Math.pow(51, 13) % (77))
);
``````

Which, according to both Wolfram Alpha (See link below), and the rest of my algorithm is wrong.

(Output:)

``````  2 == 70.0
``````

http://www.wolframalpha.com/input/?i=51^13+mod+77

Any ideas?

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I believe it's because of a precision issue. `double`s are only precise up to 15 or so digits. `Math.pow(51,13)` is a huge number (~20 digits) so when you try modding it by 77, you're going to have numerical errors.

For arbitrary precision arithmetic, take a look at BigInteger and BigDecimal.

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I thought so too, but double has a MAX_VALUE of (2-2^52)·2^1023, which I think is greater then my number. Thoughts? –  paultag Jul 21 '11 at 17:23
It's not a range issue, it's a precision issue. So for example, instead if storing the number 0.12345678987654321, a `double` might truncate it to just 0.123456789. Likewise for large numbers, 12345678987654321 might be truncated to 12345678900000000. Clearly this messes up the accuracy of the subsequent mod. –  tskuzzy Jul 21 '11 at 17:27
That sounds totally sane. Thank you! –  paultag Jul 21 '11 at 17:33

Definitely this is a double precision problem. Using java.math.BigInteger works:

``````groovy:000> b = new BigInteger("51")
===> 51
groovy:000> b = b.pow(13)
===> 15791096563156692195651
groovy:000> b = b.remainder(77)
===> 2
``````
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