164

I'm trying to mod an integer to get an array position so that it will loop round. Doing i % arrayLength works fine for positive numbers but for negative numbers it all goes wrong.

 4 % 3 == 1
 3 % 3 == 0
 2 % 3 == 2
 1 % 3 == 1
 0 % 3 == 0
-1 % 3 == -1
-2 % 3 == -2
-3 % 3 == 0
-4 % 3 == -1

so i need an implementation of

int GetArrayIndex(int i, int arrayLength)

such that

GetArrayIndex( 4, 3) == 1
GetArrayIndex( 3, 3) == 0
GetArrayIndex( 2, 3) == 2
GetArrayIndex( 1, 3) == 1
GetArrayIndex( 0, 3) == 0
GetArrayIndex(-1, 3) == 2
GetArrayIndex(-2, 3) == 1
GetArrayIndex(-3, 3) == 0
GetArrayIndex(-4, 3) == 2

I've done this before but for some reason it's melting my brain today :(

10 Answers 10

252

I always use my own mod function, defined as

int mod(int x, int m) {
    return (x%m + m)%m;
}

Of course, if you're bothered about having two calls to the modulus operation, you could write it as

int mod(int x, int m) {
    int r = x%m;
    return r<0 ? r+m : r;
}

or variants thereof.

The reason it works is that "x%m" is always in the range [-m+1, m-1]. So if at all it is negative, adding m to it will put it in the positive range without changing its value modulo m.

  • 7
    Note: for complete number-theoretic completeness, you might want to add a line at the top saying "if(m<0) m=-m;" although in this case it doesn't matter as "arrayLength" is presumably always positive. – ShreevatsaR Jul 4 '09 at 20:47
  • 4
    If you are going to check the value of m, you should also exclude zero. – billpg Aug 25 '09 at 9:52
  • 3
    @billpg: mod is not defined for m=0, so there's really nothing that the function can be expected to do for that case. IMHO, it's the caller's responsibility to check that. (No one should even want something mod 0.) OTOH, mod is defined for negative m, so I suggested fixing that bug in the code if the function may be called with negative m. Anyway, where error-checking/handling should be done is a perennial question :p – ShreevatsaR Apr 2 '12 at 5:49
  • 5
    @RuudLenders: No. If x = -5 and m = 2, then r = x%m is -1, after which r+m is 1. The while loop is not needed. The point is that (as I wrote in the answer), x%m is always strictly greater than -m, so you need to add m at most once to make it positive. – ShreevatsaR Jan 25 '13 at 14:15
  • 7
    +1. I don't care what any individual language does for a negative modulus - the 'least non-negative residue' exhibits a mathematical regularity and removes any ambiguity. – Brett Hale Jan 9 '14 at 22:55
70

Please note that C# and C++'s % operator is actually NOT a modulo, it's remainder. The formula for modulo that you want, in your case, is:

float nfmod(float a,float b)
{
    return a - b * floor(a / b);
}

You have to recode this in C# (or C++) but this is the way you get modulo and not a remainder.

  • 16
    "Please note that C++'s % operator is actually NOT a modulo, it's remainder. " Thanks, it makes sense now, always wonder why it never worked properly with negative numbers. – leetNightshade Apr 1 '12 at 23:36
  • 2
    "Please note that C++'s % operator is actually NOT a modulo, it's remainder. " I don't think this is accurate and I don't see why a modulo is any different from remainder. That's what it also says on the Modulo Operation Wikipedia page. It's just that programming languages treat negative numbers differently. The modulo operator in C# obviously counts remainders "from" zero (-9%4 = -1, because 4*-2 is -8 with a difference of -1) while another definition would consider -9%4 as +3, because -4*3 is -12, remainder +3 (such as in Google's search function, not sure of the back-end language there). – Tyress Aug 6 '14 at 7:12
  • 12
    Tyress, there is a difference between modulus and remainder. For example: -21 mod 4 is 3 because -21 + 4 x 6 is 3. But -21 divided by 4 gives -5 with a remainder of -1. For positive values, there is no difference. So please inform yourself about these differences. And do not trust Wikipedia all the time :) – Петър Петров Aug 6 '14 at 8:50
  • 2
    Why would anyone want to use the remainder function instead of a modulo? Why did they make % remainder? – Aaron Franke Jan 26 '18 at 22:20
  • 2
    @AaronFranke - its a legacy from earlier cpus that had division hardware to quickly produce a quotient and a remainder - and this is what that hardware did given a negative dividend. The language simply mirrored the hardware. Most of the time programmers were working with positive dividends, and ignored this quirk. Speed was paramount. – ToolmakerSteve Jan 23 at 22:45
13

Single-line implementation using % only once:

int mod(int k, int n) {  return ((k %= n) < 0) ? k+n : k;  }
  • 1
    is this correct? as I do not see it as accepted by anyone, nor any comments to it. For example. mod(-10,6) will return 6. Is that correct? should it not return 4? – John Demetriou Feb 13 '17 at 11:41
  • 3
    @JohnDemetriou Your numbers are both wrong: (A) it should return 2 and (B) it does return 2; try running the code. Item (A): to find mod(-10, 6) by hand, you either add or subtract 6 repetitively until the answer is in the range [0, 6). This notation means "inclusive on the left, and exclusive on the right". In our case, we add 6 twice, giving 2. The code is quite simple, and it's easy to see that it's right: first, it does the equivalent of adding/subtracting n as above, except that it stops one n short, if approaching from the negative side. In that case we fix it. There: comments :) – Evgeni Sergeev Mar 20 '17 at 1:03
  • 1
    By the way, here's a reason why using a single % might be a good idea. See the table What things cost in managed code in the article Writing Faster Managed Code: Know What Things Cost. Using % is similarly expensive to int div listed in the table: about 36 times more expensive than adding or subtracting, and about 13 times more expensive than multiplying. Of course, no big deal unless this is at the core of what your code is doing. – Evgeni Sergeev Mar 20 '17 at 1:16
  • 2
    But is a single % more expensive than a test and jump, especially if it can't easily be predicted? – Medinoc Oct 25 '17 at 13:58
5

ShreevatsaR's answer won't work for all cases, even if you add "if(m<0) m=-m;", if you account for negative dividends/divisors.

For example, -12 mod -10 will be 8, and it should be -2.

The following implementation will work for both positive and negative dividends / divisors and complies with other implementations (namely, Java, Python, Ruby, Scala, Scheme, Javascript and Google's Calculator):

internal static class IntExtensions
{
    internal static int Mod(this int a, int n)
    {
        if (n == 0)
            throw new ArgumentOutOfRangeException("n", "(a mod 0) is undefined.");

        //puts a in the [-n+1, n-1] range using the remainder operator
        int remainder = a%n;

        //if the remainder is less than zero, add n to put it in the [0, n-1] range if n is positive
        //if the remainder is greater than zero, add n to put it in the [n-1, 0] range if n is negative
        if ((n > 0 && remainder < 0) ||
            (n < 0 && remainder > 0))
            return remainder + n;
        return remainder;
    }
}

Test suite using xUnit:

    [Theory]
    [PropertyData("GetTestData")]
    public void Mod_ReturnsCorrectModulo(int dividend, int divisor, int expectedMod)
    {
        Assert.Equal(expectedMod, dividend.Mod(divisor));
    }

    [Fact]
    public void Mod_ThrowsException_IfDivisorIsZero()
    {
        Assert.Throws<ArgumentOutOfRangeException>(() => 1.Mod(0));
    }

    public static IEnumerable<object[]> GetTestData
    {
        get
        {
            yield return new object[] {1, 1, 0};
            yield return new object[] {0, 1, 0};
            yield return new object[] {2, 10, 2};
            yield return new object[] {12, 10, 2};
            yield return new object[] {22, 10, 2};
            yield return new object[] {-2, 10, 8};
            yield return new object[] {-12, 10, 8};
            yield return new object[] {-22, 10, 8};
            yield return new object[] { 2, -10, -8 };
            yield return new object[] { 12, -10, -8 };
            yield return new object[] { 22, -10, -8 };
            yield return new object[] { -2, -10, -2 };
            yield return new object[] { -12, -10, -2 };
            yield return new object[] { -22, -10, -2 };
        }
    }
  • Firstly, a mod function is usually called with positive modulus (note the variable arrayLength in the original question that is being answered here, which is presumably never negative), so the function doesn't really need to be made to work for negative modulus. (That is why I mention the treatment of negative modulus in a comment on my answer, not in the answer itself.) (contd...) – ShreevatsaR Jan 5 '14 at 3:52
  • 3
    (...contd) Secondly, what to do for a negative modulus is a matter of convention. See e.g. Wikipedia. "Usually, in number theory, the positive remainder is always chosen", and this is how I learnt it as well (in Burton's Elementary Number Theory). Knuth also defines it that way (specifically, r = a - b floor(a/b) is always positive). Even among computer systems, Pascal and Maple for instance, define it to be always positive. – ShreevatsaR Jan 5 '14 at 3:52
  • @ShreevatsaR I know that the Euclidian definition states that the result will always be positive - but I am under the impression that most modern mod implementations will return a value in the [n+1, 0] range for a negative divisor "n", which means that -12 mod -10 = -2. Ive looked into Google Calculator, Python, Ruby and Scala, and they all follow this convention. – dcastro Jan 7 '14 at 1:22
  • Also, to add to the list: Scheme and Javascript – dcastro Jan 7 '14 at 1:37
  • 1
    Again, this is still a good read. The "always positive" definition (my answer) is consistent with ALGOL, Dart, Maple, Pascal, Z3, etc. The "sign of divisor" (this answer) is consistent with: APL, COBOL, J, Lua, Mathematica, MS Excel, Perl, Python, R, Ruby, Tcl, etc. Both are inconsistent with "sign of dividend" as in: AWK, bash, bc, C99, C++11, C#, D, Eiffel, Erlang, Go, Java, OCaml, PHP, Rust, Scala, Swift, VB, x86 assembly, etc. I really don't see how you can claim one convention is "correct" and others "wrong". – ShreevatsaR Mar 23 '17 at 18:02
5

For the more performance aware devs

uint wrap(int k, int n) ((uint)k)%n

A small performance comparison

Modulo: 00:00:07.2661827 ((n%x)+x)%x)
Cast:   00:00:03.2202334 ((uint)k)%n
If:     00:00:13.5378989 ((k %= n) < 0) ? k+n : k

As for performance cost of cast to uint have a look here

  • 3
    Methinks that -3 % 10 should either be -3 or 7. Since a non-negative result is wanted, 7 would be the answer. Your implementation returns 3. You should change both parameters to uint and remove the cast. – Vive la déraison Oct 5 '15 at 13:55
  • 3
    Unsigned arithmetic is only equivalent if n is a power of two, in which case you can simply use a logical and ((uint)k & (n - 1)) instead, if the compiler doesn't already do it for you (compilers are often smart enough to figure this out). – j_schultz Apr 11 '17 at 19:10
5

Adding some understanding.

By Euclidean definition the mod result must be always positive.

Ex:

 int n = 5;
 int x = -3;

 int mod(int n, int x)
 {
     return ((n%x)+x)%x;
 }

Output:

 -1
  • 12
    I'm confused... you say that the result should always be positive, but then list the output as -1? – Jeff Bridgman Oct 2 '15 at 21:42
  • @JeffBridgman I have stated that based on Euclidean definition. ` there are two possible choices for the remainder, one negative and the other positive, and there are also two possible choices for the quotient. Usually, in number theory, the positive remainder is always chosen, but programming languages choose depending on the language and the signs of a and/or n.[5] Standard Pascal and Algol68 give a positive remainder (or 0) even for negative divisors, and some programming languages, such as C90, leave it up to the implementation when either of n or a is negative.` – Abin Mathew Oct 5 '15 at 15:19
4

Just add your modulus (arrayLength) to the negative result of % and you'll be fine.

2

I like the trick presented by Peter N Lewis on this thread: "If n has a limited range, then you can get the result you want simply by adding a known constant multiple of [the divisor] that is greater that the absolute value of the minimum."

So if I have a value d that is in degrees and I want to take

d % 180f

and I want to avoid the problems if d is negative, then instead I just do this:

(d + 720f) % 180f

This assumes that although d may be negative, it is known that it will never be more negative than -720.

  • 2
    -1: not general enough, (and it is very easy to give a more general solution). – Evgeni Sergeev Apr 22 '14 at 7:32
  • 2
    This is actually very helpful. when you have meaningful range, this can simplify computation. in my case math.stackexchange.com/questions/2279751/… – M.kazem Akhgary May 14 '17 at 5:23
  • Exactly, just used this for dayOfWeek calculation (known range of -6 to +6) and it saved having two %. – NetMage Apr 10 at 17:57
2

Comparing two predominant answers

(x%m + m)%m;

and

int r = x%m;
return r<0 ? r+m : r;

Nobody actually mentioned the fact that the first one may throw an OverflowException while the second one won't. Even worse, with default unchecked context, the first answer may return the wrong answer (see mod(int.MaxValue - 1, int.MaxValue) for example). So the second answer not only seems to be faster, but also more correct.

0

All of the answers here work great if your divisor is positive, but it's not quite complete. Here is my implementation which always returns on a range of [0, b), such that the sign of the output is the same as the sign of the divisor, allowing for negative divisors as the endpoint for the output range.

PosMod(5, 3) returns 2
PosMod(-5, 3) returns 1
PosMod(5, -3) returns -1
PosMod(-5, -3) returns -2

    /// <summary>
    /// Performs a canonical Modulus operation, where the output is on the range [0, b).
    /// </summary>
    public static real_t PosMod(real_t a, real_t b)
    {
        real_t c = a % b;
        if ((c < 0 && b > 0) || (c > 0 && b < 0)) 
        {
            c += b;
        }
        return c;
    }

(where real_t can be any number type)

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