# In scala, why could remainder (%) operator return a negative number?

For example, `(-3) % 2` will return `-1` instead of `1`.

What is the preferred way to get the positive remainder in Scala? Such as `(((-3) % 2) + 2) % 2`, or `abs(-3 % 2)`?

In scala, why could remainder (%) operator return a negative number?

There are different conventions for the sign of the result of a modulo operation; Wikipedia has a good article on it. Scala, like most but by no means all programming languages, has the result take the sign of the dividend (the `-3` in your case).

What is the preferred way to get the positive remainder in Scala?

I doubt there's a generally-agreed preferred way; if it were me, either use `Math.floorMod`, which gives a result with the sign of the divisor (`2` in your example) instead of the dividend (this doesn't just mean the same value as `%` with a different sign, see the linked JavaDoc for details). Or just an `if` afterward (`if (result < 0) { result += M; }` [where `M` is the divisor, `2` in your example]).

• That's not the right formula! For example, 5 is not congruent to -12 mod 7, 2 is! It should be `if (result < 0) result += M` where `M` is the base of the modulus. – Rex Kerr May 2 '15 at 19:19
• @RexKerr: Edits are welcome. :-) I have to admit I'm not a big maths guy. I've copied that into the above, but perhaps you could edit further to explain what the "base of the modulus" is in the OP's specific example; the descriptions I've seen talk about a divisor and a dividend, not a base, and I assume you don't mean the number base... I think you mean divisor, looking at the docs for `floorMod`, so that's the edit I've made. – T.J. Crowder May 3 '15 at 9:12

The correct way to get the positive modulus is to add the divisor to the negative modulus:

``````(-18 % 5) + 5
``````

Taking the absolute value will give you the wrong solution in this case, though it will work if the divisor happens to be 2.

If you don't know the sign of the dividend, you can do something like this:

``````((dividend % divisor) + divisor) % divisor
``````
• small nit: 'r = dividend % divisor; if (r < 0) r + divisor else r' is somewhat more efficient than taking another % – yonil Jul 12 '15 at 9:53
• @yonil: Eh... I'm skeptical. While the modulo operator is not as efficient as (for example) addition, I find it hard to believe that it is materially slower than a conditional branch. Regardless, your compiler should be smart enough to transform either version into the other as appropriate. – Kevin Dec 15 '17 at 7:09
• There is no branch there. It gets compiled to CPU instructions that perform bitwise manipulation – yonil Dec 16 '17 at 14:32
• Also, I would not trust the compiler to understand the second modulo operation can be eliminated, because it requires reasoning about the actual arithmetic (e.g. won't happen, unless a suitable optimization rule was added specifically to handle expressions of this form) – yonil Dec 16 '17 at 14:40
• @yonil: Compilers are pretty smart these days. I suspect it would break each modulo apart into "if the dividend is positive" and "if the dividend is negative" cases and analyze them separately. That's an obvious peephole optimization that I thought of in five minutes. Surely compiler writers are aware of it. – Kevin Dec 16 '17 at 15:45

Using `math.abs(-x % y)` does not usually yield the same behavior as returning a positive modulus:

``````scala> math.abs(-7 % 3)
res46: Int = 1
``````

But that's not what python (a language that returns a positive modulus) says:

``````In [14]: -7 % 3
Out[14]: 2
``````

If we look at increments of 3 from -7:

``````-7, -4, -1, 2, ..
``````

`scala` stops at `-1`, and `python` stops at `2`.

I would like to add something to the existing answers. My preferred way to get the positive remainder is to add a new method to the Int type as follows:

``````object Extensions
{
implicit class ExtendedInt (val i: Int) extends AnyVal {
def positiveMod (m: Int) = {val x = i % m; if (x < 0) x + m else x}
}
}
``````

In the file where you want to use the method, import the implicit class with:

``````import Extensions._
``````

Now you can do:

``````(-3).positiveMod(2)
``````

You could also put the implicit class in a package object so you don't need to import when calling the function from the same package.

For example, if you want to filter out all odd elements from an array, ignoring negative or positive, you can do like this:

arr.filter{x => Math.abs(x%2)==1}