Am I doing modulus wrong? Because in Java 13 % 64
is supposed to evaluate to 13
but I get 51
.
Both definitions of modulus of negative numbers are in use  some languages use one definition and some the other.
If you want to get a negative number for negative inputs then you can use this:
int r = x % n;
if (r > 0 && x < 0)
{
r = n;
}
Likewise if you were using a language that returns a negative number on a negative input and you would prefer positive:
int r = x % n;
if (r < 0)
{
r += n;
}

3This doesn't work good if n is negative. If you user same example from Java 7 Lang Spec (Section 15.17.3): (5) % (3) = 2. Adding 3 will not work. You should add absolute value of n if you want to be sure that value is positive. – partlov Jul 2 '14 at 10:35

5In Java negative modulo does not change anything, if you use an Abs() anyway, just write r = x % abs(n). I don't like if statement, I'd rather write r = ((x%n) + n) % n. Concerning power of 2 modulo (2,4,8,16,etc..) and positive answer, consider binary mask r = x & 63. – Fabyen Nov 17 '14 at 13:43

3In the context of Java (as per question tag) this answer is essentially "wrong". Given the expression
x % y
, A) ifx
is negative the remainder is negative, iex % y == (x % y)
. B) the sign ofy
has no effect iex % y == x % y
– Bohemian♦ Oct 16 '16 at 14:55
Since "mathematically" both are correct:
13 % 64 = 13 (on modulus 64)
13 % 64 = 51 (on modulus 64)
One of the options had to be chosen by Java language developers and they chose:
the sign of the result equals the sign of the dividend.
Says it in Java specs:
https://docs.oracle.com/javase/specs/jls/se7/html/jls15.html#jls15.17.3

7The question is "why does Java give me
13 % 64 = 51
when I was expecting13
?". – Pascal Cuoq Dec 9 '10 at 22:06 
5@pascal: java gives you the right definition in math and the way it has been implemented to do that not the thing you expecting from it. – user415789 Dec 9 '10 at 22:12

8The mathematically sane behavior is available in Java 8: Math.floorMod – Jesse Glick Jun 2 '15 at 19:50

1Something in their 15.17.3. Remainder Operator % examples isn't clear.
int result = (5) % 3;
gives 2.int result = (3) % 5;
gives 3. In general,int result = (a) % b;
gives the right answer when a > b. In order to get the proper result when a < b we should wrap the divisor.int result = ((a) % b) + b;
for negative a orint result = (((a) % b) + b) % b;
for positive or negative a – Oz Edri Nov 28 '15 at 23:43
Are you sure you are working in Java? 'cause Java gives 13 % 64 = 13 as expected. The sign of dividend!
Your result is wrong for Java. Please provide some context how you arrived at it (your program, implementation and version of Java).
From the Java Language Specification
15.17.3 Remainder Operator %
[...]
The remainder operation for operands that are integers after binary numeric promotion (§5.6.2) produces a result value such that (a/b)*b+(a%b) is equal to a.
15.17.2 Division Operator /
[...]
Integer division rounds toward 0.
Since / is rounded towards zero (resulting in zero), the result of % should be negative in this case.

Something in their 15.17.3. Remainder Operator % examples isn't clear.
int result = (5) % 3;
gives 2int result = (3) % 5;
gives 3 In general,int result = (a) % b;
gives the right answer when a > b In order to get the proper result when a < b we should wrap the divisor.int result = ((a) % b) + b;
for negative a orint result = (((a) % b) + b) % b;
for positive or negative a. – Oz Edri Nov 28 '15 at 23:22 
1Your comment is quite unclear. The section defines the correct result, and the examples agree with that definition. For your example
(3) % 5
the correct result according to the definition is3
, and a correct implementation of Java should produce that result. – starblue Dec 10 '15 at 14:12 
I guess I didn't explain myself correctly. What I meant by "the right answer" when a<b is that in order to get a positive result we should "wrap" the given result from a%b by adding b to it. In my example,
(3)%5
indeed gives3
, and if we want the positive remainder we should add 5 to it, and then the result will be2
– Oz Edri Dec 12 '15 at 12:29
you can use
(x % n)  (x < 0 ? n : 0);

1@ruslik You can also do:
((x % k) + k) % k
. (Though yours is probably more readable.) – John Kurlak Oct 28 '14 at 18:36 
1@JohnKurlak You version works like this: 4 % 3 = 1 OR 4 % 3 = 2 OR 4 % 3 = 2 OR 4 % 3 = 1 but the one from ruslik works like this: 4 % 3 = 1 OR 4 % 3 = 1 OR 4 % 3 = 4 OR 4 % 3 = 2 – Joschua Jun 27 '16 at 12:23

@Joschua Thanks for pointing this out. My code is helpful for when you want the modulus result to be in the range of
[0, sign(divisor) * divisor)
instead of[0, sign(dividend) * divisor)
. – John Kurlak Jun 27 '16 at 15:56
Your answer is in wikipedia: modulo operation
It says, that in Java the sign on modulo operation is the same as that of dividend. and since we're talking about the rest of the division operation is just fine, that it returns 13 in your case, since 13/64 = 0. 130 = 13.
EDIT: Sorry, misunderstood your question...You're right, java should give 13. Can you provide more surrounding code?
Modulo arithmetic with negative operands is defined by the language designer, who might leave it to the language implementation, who might defer the definition to the CPU architecture.
I wasn't able to find a Java language definition.
Thanks Ishtar, Java Language Specification for the Remainder Operator % says that the sign of the result is the same as the sign of the numerator.
To overcome this, you could add 64
(or whatever your modulus base is) to the negative value until it is positive
int k = 13;
int modbase = 64;
while (k < 0) {
k += modbase;
}
int result = k % modbase;
The result will still be in the same equivalence class.
x = x + m = x  m
in modulus m
.
so 13 = 13 + 64
in modulus 64
and 13 = 51
in modulus 64
.
assume Z = X * d + r
, if 0 < r < X
then in division Z/X
we call r
the remainder.
Z % X
returns the remainder of Z/X
.
The mod function is defined as the amount by which a number exceeds the largest integer multiple of the divisor that is not greater than that number. So in your case of
13 % 64
the largest integer multiple of 64 that does not exceed 13 is 64. Now, when you subtract 13 from 64 it equals 51 13  (64) = 13 + 64 = 51
In my version of Java JDK 1.8.0_05 13%64=13
you could try 13(int(13/64)) in other words do division cast to an integer to get rid of the fraction part then subtract from numerator So numerator(int(numerator/denominator)) should give the correct remainder & sign
In Java latest versions you get 13%64 = 13
. The answer will always have sign of numerator.


In java 7 it clearly mentions that mod will have sign of numerator :) – vsn harish rayasam Oct 8 '15 at 10:46

According to section 15.17.3 of the JLS, "The remainder operation for operands that are integers after binary numeric promotion produces a result value such that (a/b)*b+(a%b) is equal to a. This identity holds even in the special case that the dividend is the negative integer of largest possible magnitude for its type and the divisor is 1 (the remainder is 0)."
Hope that helps.
I don't think Java returns 51 in this case. I am running Java 8 on a Mac and I get:
13 % 64 = 13
Program:
public class Test {
public static void main(String[] args) {
int i = 13;
int j = 64;
System.out.println(i % j);
}
}

4@XaverKapeller, no ! Many people pointed out that mathematically speaking 13 and 51 are correct. In Java, 13 is the expected answer, and it's what I got too, so I don't know how submitter got 51, it's mystery. Mode details about the context could help to answer correctly this question. – Fabyen Nov 17 '14 at 13:32

@Xaver Kapeller: How can 51 and 13 both can be correct ? Java would return just one value .. – ceprateek Jul 23 '15 at 17:53

@XaverKapeller How can an answer that documents what Java actually does possibly be wrong? – user207421 May 17 '17 at 0:46

@EJP I think 3 years ago when I wrote this I was dumb enough to value mathematical accuracy more than the simple reality of how java deals with this. Thanks for reminding me to remove my stupid comment :D – Xaver Kapeller May 17 '17 at 11:42
%
is a remainder operator. – user207421 Feb 7 '16 at 1:02